diff --git a/go.mod b/go.mod
index e7d41eaebed0..f1c4707fb36a 100644
--- a/go.mod
+++ b/go.mod
@@ -18,6 +18,7 @@ require (
github.com/golang/glog v1.2.1
github.com/golang/mock v1.6.0
github.com/golang/protobuf v1.5.4
+ github.com/google/cel-go v0.21.0
github.com/google/go-github/v32 v32.0.0
github.com/google/goexpect v0.0.0-20190425035906-112704a48083
github.com/google/gofuzz v1.2.0
@@ -67,6 +68,7 @@ require (
k8s.io/api v0.31.0
k8s.io/apiextensions-apiserver v0.31.0
k8s.io/apimachinery v0.31.0
+ k8s.io/apiserver v0.31.0
k8s.io/client-go v12.0.0+incompatible
k8s.io/klog/v2 v2.130.1
k8s.io/kube-aggregator v0.26.4
@@ -86,8 +88,10 @@ require (
require (
github.com/VividCortex/ewma v1.2.0 // indirect
+ github.com/antlr4-go/antlr/v4 v4.13.0 // indirect
github.com/asaskevich/govalidator v0.0.0-20200907205600-7a23bdc65eef // indirect
github.com/beorn7/perks v1.0.1 // indirect
+ github.com/blang/semver/v4 v4.0.0 // indirect
github.com/cespare/xxhash/v2 v2.3.0 // indirect
github.com/cilium/ebpf v0.7.0 // indirect
github.com/coreos/go-systemd/v22 v22.5.0 // indirect
@@ -139,14 +143,17 @@ require (
github.com/rivo/uniseg v0.2.0 // indirect
github.com/seccomp/libseccomp-golang v0.10.0 // indirect
github.com/sirupsen/logrus v1.9.3 // indirect
+ github.com/stoewer/go-strcase v1.3.0 // indirect
github.com/u-root/uio v0.0.0-20230220225925-ffce2a382923 // indirect
github.com/vishvananda/netns v0.0.4 // indirect
github.com/x448/float16 v0.8.4 // indirect
go.mongodb.org/mongo-driver v1.8.4 // indirect
+ golang.org/x/exp v0.0.0-20231006140011-7918f672742d // indirect
golang.org/x/exp/typeparams v0.0.0-20230203172020-98cc5a0785f9 // indirect
golang.org/x/mod v0.20.0 // indirect
golang.org/x/oauth2 v0.21.0 // indirect
golang.org/x/text v0.17.0 // indirect
+ google.golang.org/genproto/googleapis/api v0.0.0-20240528184218-531527333157 // indirect
google.golang.org/genproto/googleapis/rpc v0.0.0-20240701130421-f6361c86f094 // indirect
google.golang.org/protobuf v1.34.2 // indirect
gopkg.in/evanphx/json-patch.v4 v4.12.0 // indirect
@@ -154,7 +161,7 @@ require (
gopkg.in/tomb.v1 v1.0.0-20141024135613-dd632973f1e7 // indirect
gopkg.in/yaml.v2 v2.4.0 // indirect
gopkg.in/yaml.v3 v3.0.1 // indirect
- k8s.io/apiserver v0.31.0 // indirect
+ k8s.io/component-base v0.31.0 // indirect
kubevirt.io/controller-lifecycle-operator-sdk/api v0.0.0-20220329064328-f3cc58c6ed90 // indirect
mvdan.cc/editorconfig v0.2.1-0.20231228180347-1925077f8eb2 // indirect
sigs.k8s.io/structured-merge-diff/v4 v4.4.1 // indirect
diff --git a/go.sum b/go.sum
index cc6b3cc21f19..cfba71e72520 100644
--- a/go.sum
+++ b/go.sum
@@ -1354,6 +1354,7 @@ github.com/andreyvit/diff v0.0.0-20170406064948-c7f18ee00883/go.mod h1:rCTlJbsFo
github.com/andybalholm/brotli v1.0.4/go.mod h1:fO7iG3H7G2nSZ7m0zPUDn85XEX2GTukHGRSepvi9Eig=
github.com/andybalholm/brotli v1.0.5/go.mod h1:fO7iG3H7G2nSZ7m0zPUDn85XEX2GTukHGRSepvi9Eig=
github.com/antihax/optional v1.0.0/go.mod h1:uupD/76wgC+ih3iEmQUL+0Ugr19nfwCT1kdvxnR2qWY=
+github.com/antlr4-go/antlr/v4 v4.13.0 h1:lxCg3LAv+EUK6t1i0y1V6/SLeUi0eKEKdhQAlS8TVTI=
github.com/antlr4-go/antlr/v4 v4.13.0/go.mod h1:pfChB/xh/Unjila75QW7+VU4TSnWnnk9UTnmpPaOR2g=
github.com/apache/arrow/go/v10 v10.0.1/go.mod h1:YvhnlEePVnBS4+0z3fhPfUy7W1Ikj0Ih0vcRo/gZ1M0=
github.com/apache/arrow/go/v11 v11.0.0/go.mod h1:Eg5OsL5H+e299f7u5ssuXsuHQVEGC4xei5aX110hRiI=
@@ -1382,6 +1383,7 @@ github.com/bgentry/speakeasy v0.1.0/go.mod h1:+zsyZBPWlz7T6j88CTgSN5bM796AkVf0kB
github.com/bketelsen/crypt v0.0.3-0.20200106085610-5cbc8cc4026c/go.mod h1:MKsuJmJgSg28kpZDP6UIiPt0e0Oz0kqKNGyRaWEPv84=
github.com/blang/semver v3.5.1+incompatible h1:cQNTCjp13qL8KC3Nbxr/y2Bqb63oX6wdnnjpJbkM4JQ=
github.com/blang/semver v3.5.1+incompatible/go.mod h1:kRBLl5iJ+tD4TcOOxsy/0fnwebNt5EWlYSAyrTnjyyk=
+github.com/blang/semver/v4 v4.0.0 h1:1PFHFE6yCCTv8C1TeyNNarDzntLi7wMI5i/pzqYIsAM=
github.com/blang/semver/v4 v4.0.0/go.mod h1:IbckMUScFkM3pff0VJDNKRiT6TG/YpiHIM2yvyW5YoQ=
github.com/boombuler/barcode v1.0.0/go.mod h1:paBWMcWSl3LHKBqUq+rly7CNSldXjb2rDl3JlRe0mD8=
github.com/boombuler/barcode v1.0.1/go.mod h1:paBWMcWSl3LHKBqUq+rly7CNSldXjb2rDl3JlRe0mD8=
@@ -1764,6 +1766,8 @@ github.com/google/btree v0.0.0-20180813153112-4030bb1f1f0c/go.mod h1:lNA+9X1NB3Z
github.com/google/btree v1.0.0/go.mod h1:lNA+9X1NB3Zf8V7Ke586lFgjr2dZNuvo3lPJSGZ5JPQ=
github.com/google/btree v1.0.1/go.mod h1:xXMiIv4Fb/0kKde4SpL7qlzvu5cMJDRkFDxJfI9uaxA=
github.com/google/cel-go v0.20.1/go.mod h1:kWcIzTsPX0zmQ+H3TirHstLLf9ep5QTsZBN9u4dOYLg=
+github.com/google/cel-go v0.21.0 h1:cl6uW/gxN+Hy50tNYvI691+sXxioCnstFzLp2WO4GCI=
+github.com/google/cel-go v0.21.0/go.mod h1:rHUlWCcBKgyEk+eV03RPdZUekPp6YcJwV0FxuUksYxc=
github.com/google/flatbuffers v2.0.8+incompatible/go.mod h1:1AeVuKshWv4vARoZatz6mlQ0JxURH0Kv5+zNeJKJCa8=
github.com/google/flatbuffers v23.5.26+incompatible/go.mod h1:1AeVuKshWv4vARoZatz6mlQ0JxURH0Kv5+zNeJKJCa8=
github.com/google/gnostic-models v0.6.8 h1:yo/ABAfM5IMRsS1VnXjTBvUb61tFIHozhlYvRgGre9I=
@@ -2301,6 +2305,7 @@ github.com/spf13/pflag v1.0.5 h1:iy+VFUOCP1a+8yFto/drg2CJ5u0yRoB7fZw3DKv/JXA=
github.com/spf13/pflag v1.0.5/go.mod h1:McXfInJRrz4CZXVZOBLb0bTZqETkiAhM9Iw0y3An2Bg=
github.com/spf13/viper v1.7.0/go.mod h1:8WkrPz2fc9jxqZNCJI/76HCieCp4Q8HaLFoCha5qpdg=
github.com/stoewer/go-strcase v1.2.0/go.mod h1:IBiWB2sKIp3wVVQ3Y035++gc+knqhUQag1KpM8ahLw8=
+github.com/stoewer/go-strcase v1.3.0 h1:g0eASXYtp+yvN9fK8sH94oCIk0fau9uV1/ZdJ0AVEzs=
github.com/stoewer/go-strcase v1.3.0/go.mod h1:fAH5hQ5pehh+j3nZfvwdk2RgEgQjAoM8wodgtPmh1xo=
github.com/stretchr/objx v0.1.0/go.mod h1:HFkY916IF+rwdDfMAkV7OtwuqBVzrE8GR6GFx+wExME=
github.com/stretchr/objx v0.1.1/go.mod h1:HFkY916IF+rwdDfMAkV7OtwuqBVzrE8GR6GFx+wExME=
@@ -2522,6 +2527,7 @@ golang.org/x/exp v0.0.0-20200224162631-6cc2880d07d6/go.mod h1:3jZMyOhIsHpP37uCMk
golang.org/x/exp v0.0.0-20220827204233-334a2380cb91/go.mod h1:cyybsKvd6eL0RnXn6p/Grxp8F5bW7iYuBgsNCOHpMYE=
golang.org/x/exp v0.0.0-20230206171751-46f607a40771/go.mod h1:CxIveKay+FTh1D0yPZemJVgC/95VzuuOLq5Qi4xnoYc=
golang.org/x/exp v0.0.0-20230515195305-f3d0a9c9a5cc/go.mod h1:V1LtkGg67GoY2N1AnLN78QLrzxkLyJw7RJb1gzOOz9w=
+golang.org/x/exp v0.0.0-20231006140011-7918f672742d h1:jtJma62tbqLibJ5sFQz8bKtEM8rJBtfilJ2qTU199MI=
golang.org/x/exp v0.0.0-20231006140011-7918f672742d/go.mod h1:ldy0pHrwJyGW56pPQzzkH36rKxoZW1tw7ZJpeKx+hdo=
golang.org/x/exp/typeparams v0.0.0-20220428152302-39d4317da171/go.mod h1:AbB0pIl9nAr9wVwH+Z2ZpaocVmF5I4GyWCDIsVjR0bk=
golang.org/x/exp/typeparams v0.0.0-20230203172020-98cc5a0785f9 h1:6WHiuFL9FNjg8RljAaT7FNUuKDbvMqS1i5cr2OE2sLQ=
@@ -3319,6 +3325,7 @@ google.golang.org/genproto/googleapis/api v0.0.0-20240311132316-a219d84964c2/go.
google.golang.org/genproto/googleapis/api v0.0.0-20240318140521-94a12d6c2237/go.mod h1:Z5Iiy3jtmioajWHDGFk7CeugTyHtPvMHA4UTmUkyalE=
google.golang.org/genproto/googleapis/api v0.0.0-20240513163218-0867130af1f8/go.mod h1:vPrPUTsDCYxXWjP7clS81mZ6/803D8K4iM9Ma27VKas=
google.golang.org/genproto/googleapis/api v0.0.0-20240520151616-dc85e6b867a5/go.mod h1:RGnPtTG7r4i8sPlNyDeikXF99hMM+hN6QMm4ooG9g2g=
+google.golang.org/genproto/googleapis/api v0.0.0-20240528184218-531527333157 h1:7whR9kGa5LUwFtpLm2ArCEejtnxlGeLbAyjFY8sGNFw=
google.golang.org/genproto/googleapis/api v0.0.0-20240528184218-531527333157/go.mod h1:99sLkeliLXfdj2J75X3Ho+rrVCaJze0uwN7zDDkjPVU=
google.golang.org/genproto/googleapis/bytestream v0.0.0-20230530153820-e85fd2cbaebc/go.mod h1:ylj+BE99M198VPbBh6A8d9n3w8fChvyLK3wwBOjXBFA=
google.golang.org/genproto/googleapis/bytestream v0.0.0-20230807174057-1744710a1577/go.mod h1:NjCQG/D8JandXxM57PZbAJL1DCNL6EypA0vPPwfsc7c=
@@ -3512,6 +3519,7 @@ k8s.io/apiserver v0.31.0/go.mod h1:KI9ox5Yu902iBnnyMmy7ajonhKnkeZYJhTZ/YI+WEMk=
k8s.io/client-go v0.31.0 h1:QqEJzNjbN2Yv1H79SsS+SWnXkBgVu4Pj3CJQgbx0gI8=
k8s.io/client-go v0.31.0/go.mod h1:Y9wvC76g4fLjmU0BA+rV+h2cncoadjvjjkkIGoTLcGU=
k8s.io/code-generator v0.31.0/go.mod h1:84y4w3es8rOJOUUP1rLsIiGlO1JuEaPFXQPA9e/K6U0=
+k8s.io/component-base v0.31.0 h1:/KIzGM5EvPNQcYgwq5NwoQBaOlVFrghoVGr8lG6vNRs=
k8s.io/component-base v0.31.0/go.mod h1:TYVuzI1QmN4L5ItVdMSXKvH7/DtvIuas5/mm8YT3rTo=
k8s.io/gengo v0.0.0-20181113154421-fd15ee9cc2f7/go.mod h1:ezvh/TsK7cY6rbqRK0oQQ8IAqLxYwwyPxAX1Pzy0ii0=
k8s.io/gengo v0.0.0-20211129171323-c02415ce4185/go.mod h1:FiNAH4ZV3gBg2Kwh89tzAEV2be7d5xI0vBa/VySYy3E=
diff --git a/pkg/virt-operator/resource/generate/components/BUILD.bazel b/pkg/virt-operator/resource/generate/components/BUILD.bazel
index b64d17e6d61b..b798149da6c5 100644
--- a/pkg/virt-operator/resource/generate/components/BUILD.bazel
+++ b/pkg/virt-operator/resource/generate/components/BUILD.bazel
@@ -86,6 +86,7 @@ go_test(
"//pkg/certificates/triple/cert:go_default_library",
"//staging/src/kubevirt.io/api/core/v1:go_default_library",
"//staging/src/kubevirt.io/client-go/testutils:go_default_library",
+ "//vendor/github.com/google/cel-go/cel:go_default_library",
"//vendor/github.com/onsi/ginkgo/v2:go_default_library",
"//vendor/github.com/onsi/gomega:go_default_library",
"//vendor/github.com/openshift/api/route/v1:go_default_library",
@@ -94,5 +95,7 @@ go_test(
"//vendor/k8s.io/api/core/v1:go_default_library",
"//vendor/k8s.io/apiextensions-apiserver/pkg/apis/apiextensions/v1:go_default_library",
"//vendor/k8s.io/apimachinery/pkg/apis/meta/v1:go_default_library",
+ "//vendor/k8s.io/apiserver/pkg/admission/plugin/cel:go_default_library",
+ "//vendor/k8s.io/apiserver/pkg/cel/environment:go_default_library",
],
)
diff --git a/pkg/virt-operator/resource/generate/components/validatingadmissionpolicy_test.go b/pkg/virt-operator/resource/generate/components/validatingadmissionpolicy_test.go
index 39cb37d6f412..24bbe482688a 100644
--- a/pkg/virt-operator/resource/generate/components/validatingadmissionpolicy_test.go
+++ b/pkg/virt-operator/resource/generate/components/validatingadmissionpolicy_test.go
@@ -22,13 +22,30 @@ package components_test
import (
"fmt"
+ celgo "github.com/google/cel-go/cel"
. "github.com/onsi/ginkgo/v2"
. "github.com/onsi/gomega"
+ "k8s.io/apiserver/pkg/cel/environment"
+
+ admissionregistrationv1 "k8s.io/api/admissionregistration/v1"
+ metav1 "k8s.io/apimachinery/pkg/apis/meta/v1"
+ "k8s.io/apiserver/pkg/admission/plugin/cel"
"kubevirt.io/kubevirt/pkg/virt-operator/resource/generate/components"
)
var _ = Describe("Validation Admission Policy", func() {
+ Context("ValidatingAdmissionPolicyBinding", func() {
+ It("should generate the expected policy binding", func() {
+ const userName = "system:serviceaccount:kubevirt-ns:kubevirt-handler"
+ validatingAdmissionPolicy := components.NewHandlerV1ValidatingAdmissionPolicy(userName)
+ validatingAdmissionPolicyBinding := components.NewHandlerV1ValidatingAdmissionPolicyBinding()
+
+ Expect(validatingAdmissionPolicyBinding.Spec.PolicyName).To(Equal(validatingAdmissionPolicy.Name))
+ Expect(validatingAdmissionPolicyBinding.Kind).ToNot(BeEmpty())
+ })
+ })
+
Context("ValidatingAdmissionPolicy", func() {
It("should generate the expected policy", func() {
const userName = "system:serviceaccount:kubevirt-ns:kubevirt-handler"
@@ -38,16 +55,82 @@ var _ = Describe("Validation Admission Policy", func() {
Expect(validatingAdmissionPolicy.Spec.MatchConditions[0].Expression).To(Equal(expectedMatchConditionExpression))
Expect(validatingAdmissionPolicy.Kind).ToNot(BeEmpty())
})
- })
- Context("ValidatingAdmissionPolicyBinding", func() {
- It("should generate the expected policy binding", func() {
- const userName = "system:serviceaccount:kubevirt-ns:kubevirt-handler"
- validatingAdmissionPolicy := components.NewHandlerV1ValidatingAdmissionPolicy(userName)
- validatingAdmissionPolicyBinding := components.NewHandlerV1ValidatingAdmissionPolicyBinding()
+ Context("Validation Compile test", func() {
+ var celCompiler *cel.CompositedCompiler
+ BeforeEach(func() {
+ compositionEnvTemplateWithoutStrictCost, err := cel.NewCompositionEnv(cel.VariablesTypeName, environment.MustBaseEnvSet(environment.DefaultCompatibilityVersion(), false))
+ Expect(err).ToNot(HaveOccurred())
+ celCompiler = cel.NewCompositedCompilerFromTemplate(compositionEnvTemplateWithoutStrictCost)
+ })
- Expect(validatingAdmissionPolicyBinding.Spec.PolicyName).To(Equal(validatingAdmissionPolicy.Name))
- Expect(validatingAdmissionPolicyBinding.Kind).ToNot(BeEmpty())
+ It("succeed compiling all the policy validations", func() {
+ const userName = "system:serviceaccount:kubevirt-ns:kubevirt-handler"
+ validatingAdmissionPolicy := components.NewHandlerV1ValidatingAdmissionPolicy(userName)
+
+ options := cel.OptionalVariableDeclarations{
+ HasParams: false,
+ HasAuthorizer: false,
+ }
+ mode := environment.NewExpressions
+ celCompiler.CompileAndStoreVariables(convertV1Variables(validatingAdmissionPolicy.Spec.Variables), options, mode)
+
+ for _, validation := range validatingAdmissionPolicy.Spec.Validations {
+ compilationResult := celCompiler.CompileCELExpression(convertV1Validation(validation), options, mode)
+ Expect(compilationResult).ToNot(BeNil())
+ Expect(compilationResult.Error).To(BeNil())
+ }
+ })
})
})
+
})
+
+// Variable is a named expression for composition.
+type Variable struct {
+ Name string
+ Expression string
+}
+
+func (v *Variable) GetExpression() string {
+ return v.Expression
+}
+
+func (v *Variable) ReturnTypes() []*celgo.Type {
+ return []*celgo.Type{celgo.AnyType, celgo.DynType}
+}
+
+func (v *Variable) GetName() string {
+ return v.Name
+}
+
+func convertV1Variables(variables []admissionregistrationv1.Variable) []cel.NamedExpressionAccessor {
+ namedExpressions := make([]cel.NamedExpressionAccessor, len(variables))
+ for i, variable := range variables {
+ namedExpressions[i] = &Variable{Name: variable.Name, Expression: variable.Expression}
+ }
+ return namedExpressions
+}
+
+// ValidationCondition contains the inputs needed to compile, evaluate and validate a cel expression
+type ValidationCondition struct {
+ Expression string
+ Message string
+ Reason *metav1.StatusReason
+}
+
+func (v *ValidationCondition) GetExpression() string {
+ return v.Expression
+}
+
+func (v *ValidationCondition) ReturnTypes() []*celgo.Type {
+ return []*celgo.Type{celgo.BoolType}
+}
+
+func convertV1Validation(validation admissionregistrationv1.Validation) cel.ExpressionAccessor {
+ return &ValidationCondition{
+ Expression: validation.Expression,
+ Message: validation.Message,
+ Reason: validation.Reason,
+ }
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/.gitignore b/vendor/github.com/antlr4-go/antlr/v4/.gitignore
new file mode 100644
index 000000000000..38ea34ff513d
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/.gitignore
@@ -0,0 +1,18 @@
+### Go template
+
+# Binaries for programs and plugins
+*.exe
+*.exe~
+*.dll
+*.so
+*.dylib
+
+# Test binary, built with `go test -c`
+*.test
+
+
+# Go workspace file
+go.work
+
+# No Goland stuff in this repo
+.idea
diff --git a/vendor/github.com/antlr4-go/antlr/v4/BUILD.bazel b/vendor/github.com/antlr4-go/antlr/v4/BUILD.bazel
new file mode 100644
index 000000000000..f65f2f0373d0
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/BUILD.bazel
@@ -0,0 +1,62 @@
+load("@io_bazel_rules_go//go:def.bzl", "go_library")
+
+go_library(
+ name = "go_default_library",
+ srcs = [
+ "antlrdoc.go",
+ "atn.go",
+ "atn_config.go",
+ "atn_config_set.go",
+ "atn_deserialization_options.go",
+ "atn_deserializer.go",
+ "atn_simulator.go",
+ "atn_state.go",
+ "atn_type.go",
+ "char_stream.go",
+ "common_token_factory.go",
+ "common_token_stream.go",
+ "comparators.go",
+ "configuration.go",
+ "dfa.go",
+ "dfa_serializer.go",
+ "dfa_state.go",
+ "diagnostic_error_listener.go",
+ "error_listener.go",
+ "error_strategy.go",
+ "errors.go",
+ "file_stream.go",
+ "input_stream.go",
+ "int_stream.go",
+ "interval_set.go",
+ "jcollect.go",
+ "lexer.go",
+ "lexer_action.go",
+ "lexer_action_executor.go",
+ "lexer_atn_simulator.go",
+ "ll1_analyzer.go",
+ "nostatistics.go",
+ "parser.go",
+ "parser_atn_simulator.go",
+ "parser_rule_context.go",
+ "prediction_context.go",
+ "prediction_context_cache.go",
+ "prediction_mode.go",
+ "recognizer.go",
+ "rule_context.go",
+ "semantic_context.go",
+ "stats_data.go",
+ "token.go",
+ "token_source.go",
+ "token_stream.go",
+ "tokenstream_rewriter.go",
+ "trace_listener.go",
+ "transition.go",
+ "tree.go",
+ "trees.go",
+ "utils.go",
+ ],
+ importmap = "kubevirt.io/kubevirt/vendor/github.com/antlr4-go/antlr/v4",
+ importpath = "github.com/antlr4-go/antlr/v4",
+ visibility = ["//visibility:public"],
+ deps = ["//vendor/golang.org/x/exp/slices:go_default_library"],
+)
diff --git a/vendor/github.com/antlr4-go/antlr/v4/LICENSE b/vendor/github.com/antlr4-go/antlr/v4/LICENSE
new file mode 100644
index 000000000000..a22292eb5aee
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/LICENSE
@@ -0,0 +1,28 @@
+Copyright (c) 2012-2023 The ANTLR Project. All rights reserved.
+
+Redistribution and use in source and binary forms, with or without
+modification, are permitted provided that the following conditions
+are met:
+
+1. Redistributions of source code must retain the above copyright
+notice, this list of conditions and the following disclaimer.
+
+2. Redistributions in binary form must reproduce the above copyright
+notice, this list of conditions and the following disclaimer in the
+documentation and/or other materials provided with the distribution.
+
+3. Neither name of copyright holders nor the names of its contributors
+may be used to endorse or promote products derived from this software
+without specific prior written permission.
+
+THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
+``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
+LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
+A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR
+CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
+EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
+PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
+PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
+LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
+NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
+SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
diff --git a/vendor/github.com/antlr4-go/antlr/v4/README.md b/vendor/github.com/antlr4-go/antlr/v4/README.md
new file mode 100644
index 000000000000..03e5b83eb1b6
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/README.md
@@ -0,0 +1,54 @@
+[](https://goreportcard.com/report/github.com/antlr4-go/antlr)
+[](https://pkg.go.dev/github.com/antlr4-go/antlr)
+[](https://github.com/antlr4-go/antlr/releases/latest)
+[](https://github.com/antlr4-go/antlr/releases/latest)
+[](https://github.com/antlr4-go/antlr/commit-activity)
+[](https://opensource.org/licenses/BSD-3-Clause)
+[](https://GitHub.com/Naereen/StrapDown.js/stargazers/)
+# ANTLR4 Go Runtime Module Repo
+
+IMPORTANT: Please submit PRs via a clone of the https://github.com/antlr/antlr4 repo, and not here.
+
+ - Do not submit PRs or any change requests to this repo
+ - This repo is read only and is updated by the ANTLR team to create a new release of the Go Runtime for ANTLR
+ - This repo contains the Go runtime that your generated projects should import
+
+## Introduction
+
+This repo contains the official modules for the Go Runtime for ANTLR. It is a copy of the runtime maintained
+at: https://github.com/antlr/antlr4/tree/master/runtime/Go/antlr and is automatically updated by the ANTLR team to create
+the official Go runtime release only. No development work is carried out in this repo and PRs are not accepted here.
+
+The dev branch of this repo is kept in sync with the dev branch of the main ANTLR repo and is updated periodically.
+
+### Why?
+
+The `go get` command is unable to retrieve the Go runtime when it is embedded so
+deeply in the main repo. A `go get` against the `antlr/antlr4` repo, while retrieving the correct source code for the runtime,
+does not correctly resolve tags and will create a reference in your `go.mod` file that is unclear, will not upgrade smoothly and
+causes confusion.
+
+For instance, the current Go runtime release, which is tagged with v4.13.0 in `antlr/antlr4` is retrieved by go get as:
+
+```sh
+require (
+ github.com/antlr/antlr4/runtime/Go/antlr/v4 v4.0.0-20230219212500-1f9a474cc2dc
+)
+```
+
+Where you would expect to see:
+
+```sh
+require (
+ github.com/antlr/antlr4/runtime/Go/antlr/v4 v4.13.0
+)
+```
+
+The decision was taken to create a separate org in a separate repo to hold the official Go runtime for ANTLR and
+from whence users can expect `go get` to behave as expected.
+
+
+# Documentation
+Please read the official documentation at: https://github.com/antlr/antlr4/blob/master/doc/index.md for tips on
+migrating existing projects to use the new module location and for information on how to use the Go runtime in
+general.
diff --git a/vendor/github.com/antlr4-go/antlr/v4/antlrdoc.go b/vendor/github.com/antlr4-go/antlr/v4/antlrdoc.go
new file mode 100644
index 000000000000..3bb4fd7c4e0a
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/antlrdoc.go
@@ -0,0 +1,102 @@
+/*
+Package antlr implements the Go version of the ANTLR 4 runtime.
+
+# The ANTLR Tool
+
+ANTLR (ANother Tool for Language Recognition) is a powerful parser generator for reading, processing, executing,
+or translating structured text or binary files. It's widely used to build languages, tools, and frameworks.
+From a grammar, ANTLR generates a parser that can build parse trees and also generates a listener interface
+(or visitor) that makes it easy to respond to the recognition of phrases of interest.
+
+# Go Runtime
+
+At version 4.11.x and prior, the Go runtime was not properly versioned for go modules. After this point, the runtime
+source code to be imported was held in the `runtime/Go/antlr/v4` directory, and the go.mod file was updated to reflect the version of
+ANTLR4 that it is compatible with (I.E. uses the /v4 path).
+
+However, this was found to be problematic, as it meant that with the runtime embedded so far underneath the root
+of the repo, the `go get` and related commands could not properly resolve the location of the go runtime source code.
+This meant that the reference to the runtime in your `go.mod` file would refer to the correct source code, but would not
+list the release tag such as @4.12.0 - this was confusing, to say the least.
+
+As of 4.12.1, the runtime is now available as a go module in its own repo, and can be imported as `github.com/antlr4-go/antlr`
+(the go get command should also be used with this path). See the main documentation for the ANTLR4 project for more information,
+which is available at [ANTLR docs]. The documentation for using the Go runtime is available at [Go runtime docs].
+
+This means that if you are using the source code without modules, you should also use the source code in the [new repo].
+Though we highly recommend that you use go modules, as they are now idiomatic for Go.
+
+I am aware that this change will prove Hyrum's Law, but am prepared to live with it for the common good.
+
+Go runtime author: [Jim Idle] jimi@idle.ws
+
+# Code Generation
+
+ANTLR supports the generation of code in a number of [target languages], and the generated code is supported by a
+runtime library, written specifically to support the generated code in the target language. This library is the
+runtime for the Go target.
+
+To generate code for the go target, it is generally recommended to place the source grammar files in a package of
+their own, and use the `.sh` script method of generating code, using the go generate directive. In that same directory
+it is usual, though not required, to place the antlr tool that should be used to generate the code. That does mean
+that the antlr tool JAR file will be checked in to your source code control though, so you are, of course, free to use any other
+way of specifying the version of the ANTLR tool to use, such as aliasing in `.zshrc` or equivalent, or a profile in
+your IDE, or configuration in your CI system. Checking in the jar does mean that it is easy to reproduce the build as
+it was at any point in its history.
+
+Here is a general/recommended template for an ANTLR based recognizer in Go:
+
+ .
+ ├── parser
+ │ ├── mygrammar.g4
+ │ ├── antlr-4.12.1-complete.jar
+ │ ├── generate.go
+ │ └── generate.sh
+ ├── parsing - generated code goes here
+ │ └── error_listeners.go
+ ├── go.mod
+ ├── go.sum
+ ├── main.go
+ └── main_test.go
+
+Make sure that the package statement in your grammar file(s) reflects the go package the generated code will exist in.
+
+The generate.go file then looks like this:
+
+ package parser
+
+ //go:generate ./generate.sh
+
+And the generate.sh file will look similar to this:
+
+ #!/bin/sh
+
+ alias antlr4='java -Xmx500M -cp "./antlr4-4.12.1-complete.jar:$CLASSPATH" org.antlr.v4.Tool'
+ antlr4 -Dlanguage=Go -no-visitor -package parsing *.g4
+
+depending on whether you want visitors or listeners or any other ANTLR options. Not that another option here
+is to generate the code into a
+
+From the command line at the root of your source package (location of go.mo)d) you can then simply issue the command:
+
+ go generate ./...
+
+Which will generate the code for the parser, and place it in the parsing package. You can then use the generated code
+by importing the parsing package.
+
+There are no hard and fast rules on this. It is just a recommendation. You can generate the code in any way and to anywhere you like.
+
+# Copyright Notice
+
+Copyright (c) 2012-2023 The ANTLR Project. All rights reserved.
+
+Use of this file is governed by the BSD 3-clause license, which can be found in the [LICENSE.txt] file in the project root.
+
+[target languages]: https://github.com/antlr/antlr4/tree/master/runtime
+[LICENSE.txt]: https://github.com/antlr/antlr4/blob/master/LICENSE.txt
+[ANTLR docs]: https://github.com/antlr/antlr4/blob/master/doc/index.md
+[new repo]: https://github.com/antlr4-go/antlr
+[Jim Idle]: https://github.com/jimidle
+[Go runtime docs]: https://github.com/antlr/antlr4/blob/master/doc/go-target.md
+*/
+package antlr
diff --git a/vendor/github.com/antlr4-go/antlr/v4/atn.go b/vendor/github.com/antlr4-go/antlr/v4/atn.go
new file mode 100644
index 000000000000..cdeefed24789
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/atn.go
@@ -0,0 +1,179 @@
+// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
+// Use of this file is governed by the BSD 3-clause license that
+// can be found in the LICENSE.txt file in the project root.
+
+package antlr
+
+import "sync"
+
+// ATNInvalidAltNumber is used to represent an ALT number that has yet to be calculated or
+// which is invalid for a particular struct such as [*antlr.BaseRuleContext]
+var ATNInvalidAltNumber int
+
+// ATN represents an “[Augmented Transition Network]”, though general in ANTLR the term
+// “Augmented Recursive Transition Network” though there are some descriptions of “[Recursive Transition Network]”
+// in existence.
+//
+// ATNs represent the main networks in the system and are serialized by the code generator and support [ALL(*)].
+//
+// [Augmented Transition Network]: https://en.wikipedia.org/wiki/Augmented_transition_network
+// [ALL(*)]: https://www.antlr.org/papers/allstar-techreport.pdf
+// [Recursive Transition Network]: https://en.wikipedia.org/wiki/Recursive_transition_network
+type ATN struct {
+
+ // DecisionToState is the decision points for all rules, sub-rules, optional
+ // blocks, ()+, ()*, etc. Each sub-rule/rule is a decision point, and we must track them, so we
+ // can go back later and build DFA predictors for them. This includes
+ // all the rules, sub-rules, optional blocks, ()+, ()* etc...
+ DecisionToState []DecisionState
+
+ // grammarType is the ATN type and is used for deserializing ATNs from strings.
+ grammarType int
+
+ // lexerActions is referenced by action transitions in the ATN for lexer ATNs.
+ lexerActions []LexerAction
+
+ // maxTokenType is the maximum value for any symbol recognized by a transition in the ATN.
+ maxTokenType int
+
+ modeNameToStartState map[string]*TokensStartState
+
+ modeToStartState []*TokensStartState
+
+ // ruleToStartState maps from rule index to starting state number.
+ ruleToStartState []*RuleStartState
+
+ // ruleToStopState maps from rule index to stop state number.
+ ruleToStopState []*RuleStopState
+
+ // ruleToTokenType maps the rule index to the resulting token type for lexer
+ // ATNs. For parser ATNs, it maps the rule index to the generated bypass token
+ // type if ATNDeserializationOptions.isGenerateRuleBypassTransitions was
+ // specified, and otherwise is nil.
+ ruleToTokenType []int
+
+ // ATNStates is a list of all states in the ATN, ordered by state number.
+ //
+ states []ATNState
+
+ mu sync.Mutex
+ stateMu sync.RWMutex
+ edgeMu sync.RWMutex
+}
+
+// NewATN returns a new ATN struct representing the given grammarType and is used
+// for runtime deserialization of ATNs from the code generated by the ANTLR tool
+func NewATN(grammarType int, maxTokenType int) *ATN {
+ return &ATN{
+ grammarType: grammarType,
+ maxTokenType: maxTokenType,
+ modeNameToStartState: make(map[string]*TokensStartState),
+ }
+}
+
+// NextTokensInContext computes and returns the set of valid tokens that can occur starting
+// in state s. If ctx is nil, the set of tokens will not include what can follow
+// the rule surrounding s. In other words, the set will be restricted to tokens
+// reachable staying within the rule of s.
+func (a *ATN) NextTokensInContext(s ATNState, ctx RuleContext) *IntervalSet {
+ return NewLL1Analyzer(a).Look(s, nil, ctx)
+}
+
+// NextTokensNoContext computes and returns the set of valid tokens that can occur starting
+// in state s and staying in same rule. [antlr.Token.EPSILON] is in set if we reach end of
+// rule.
+func (a *ATN) NextTokensNoContext(s ATNState) *IntervalSet {
+ a.mu.Lock()
+ defer a.mu.Unlock()
+ iset := s.GetNextTokenWithinRule()
+ if iset == nil {
+ iset = a.NextTokensInContext(s, nil)
+ iset.readOnly = true
+ s.SetNextTokenWithinRule(iset)
+ }
+ return iset
+}
+
+// NextTokens computes and returns the set of valid tokens starting in state s, by
+// calling either [NextTokensNoContext] (ctx == nil) or [NextTokensInContext] (ctx != nil).
+func (a *ATN) NextTokens(s ATNState, ctx RuleContext) *IntervalSet {
+ if ctx == nil {
+ return a.NextTokensNoContext(s)
+ }
+
+ return a.NextTokensInContext(s, ctx)
+}
+
+func (a *ATN) addState(state ATNState) {
+ if state != nil {
+ state.SetATN(a)
+ state.SetStateNumber(len(a.states))
+ }
+
+ a.states = append(a.states, state)
+}
+
+func (a *ATN) removeState(state ATNState) {
+ a.states[state.GetStateNumber()] = nil // Just free the memory; don't shift states in the slice
+}
+
+func (a *ATN) defineDecisionState(s DecisionState) int {
+ a.DecisionToState = append(a.DecisionToState, s)
+ s.setDecision(len(a.DecisionToState) - 1)
+
+ return s.getDecision()
+}
+
+func (a *ATN) getDecisionState(decision int) DecisionState {
+ if len(a.DecisionToState) == 0 {
+ return nil
+ }
+
+ return a.DecisionToState[decision]
+}
+
+// getExpectedTokens computes the set of input symbols which could follow ATN
+// state number stateNumber in the specified full parse context ctx and returns
+// the set of potentially valid input symbols which could follow the specified
+// state in the specified context. This method considers the complete parser
+// context, but does not evaluate semantic predicates (i.e. all predicates
+// encountered during the calculation are assumed true). If a path in the ATN
+// exists from the starting state to the RuleStopState of the outermost context
+// without Matching any symbols, Token.EOF is added to the returned set.
+//
+// A nil ctx defaults to ParserRuleContext.EMPTY.
+//
+// It panics if the ATN does not contain state stateNumber.
+func (a *ATN) getExpectedTokens(stateNumber int, ctx RuleContext) *IntervalSet {
+ if stateNumber < 0 || stateNumber >= len(a.states) {
+ panic("Invalid state number.")
+ }
+
+ s := a.states[stateNumber]
+ following := a.NextTokens(s, nil)
+
+ if !following.contains(TokenEpsilon) {
+ return following
+ }
+
+ expected := NewIntervalSet()
+
+ expected.addSet(following)
+ expected.removeOne(TokenEpsilon)
+
+ for ctx != nil && ctx.GetInvokingState() >= 0 && following.contains(TokenEpsilon) {
+ invokingState := a.states[ctx.GetInvokingState()]
+ rt := invokingState.GetTransitions()[0]
+
+ following = a.NextTokens(rt.(*RuleTransition).followState, nil)
+ expected.addSet(following)
+ expected.removeOne(TokenEpsilon)
+ ctx = ctx.GetParent().(RuleContext)
+ }
+
+ if following.contains(TokenEpsilon) {
+ expected.addOne(TokenEOF)
+ }
+
+ return expected
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/atn_config.go b/vendor/github.com/antlr4-go/antlr/v4/atn_config.go
new file mode 100644
index 000000000000..a83f25d3492e
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/atn_config.go
@@ -0,0 +1,335 @@
+// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
+// Use of this file is governed by the BSD 3-clause license that
+// can be found in the LICENSE.txt file in the project root.
+
+package antlr
+
+import (
+ "fmt"
+)
+
+const (
+ lexerConfig = iota // Indicates that this ATNConfig is for a lexer
+ parserConfig // Indicates that this ATNConfig is for a parser
+)
+
+// ATNConfig is a tuple: (ATN state, predicted alt, syntactic, semantic
+// context). The syntactic context is a graph-structured stack node whose
+// path(s) to the root is the rule invocation(s) chain used to arrive in the
+// state. The semantic context is the tree of semantic predicates encountered
+// before reaching an ATN state.
+type ATNConfig struct {
+ precedenceFilterSuppressed bool
+ state ATNState
+ alt int
+ context *PredictionContext
+ semanticContext SemanticContext
+ reachesIntoOuterContext int
+ cType int // lexerConfig or parserConfig
+ lexerActionExecutor *LexerActionExecutor
+ passedThroughNonGreedyDecision bool
+}
+
+// NewATNConfig6 creates a new ATNConfig instance given a state, alt and context only
+func NewATNConfig6(state ATNState, alt int, context *PredictionContext) *ATNConfig {
+ return NewATNConfig5(state, alt, context, SemanticContextNone)
+}
+
+// NewATNConfig5 creates a new ATNConfig instance given a state, alt, context and semantic context
+func NewATNConfig5(state ATNState, alt int, context *PredictionContext, semanticContext SemanticContext) *ATNConfig {
+ if semanticContext == nil {
+ panic("semanticContext cannot be nil") // TODO: Necessary?
+ }
+
+ pac := &ATNConfig{}
+ pac.state = state
+ pac.alt = alt
+ pac.context = context
+ pac.semanticContext = semanticContext
+ pac.cType = parserConfig
+ return pac
+}
+
+// NewATNConfig4 creates a new ATNConfig instance given an existing config, and a state only
+func NewATNConfig4(c *ATNConfig, state ATNState) *ATNConfig {
+ return NewATNConfig(c, state, c.GetContext(), c.GetSemanticContext())
+}
+
+// NewATNConfig3 creates a new ATNConfig instance given an existing config, a state and a semantic context
+func NewATNConfig3(c *ATNConfig, state ATNState, semanticContext SemanticContext) *ATNConfig {
+ return NewATNConfig(c, state, c.GetContext(), semanticContext)
+}
+
+// NewATNConfig2 creates a new ATNConfig instance given an existing config, and a context only
+func NewATNConfig2(c *ATNConfig, semanticContext SemanticContext) *ATNConfig {
+ return NewATNConfig(c, c.GetState(), c.GetContext(), semanticContext)
+}
+
+// NewATNConfig1 creates a new ATNConfig instance given an existing config, a state, and a context only
+func NewATNConfig1(c *ATNConfig, state ATNState, context *PredictionContext) *ATNConfig {
+ return NewATNConfig(c, state, context, c.GetSemanticContext())
+}
+
+// NewATNConfig creates a new ATNConfig instance given an existing config, a state, a context and a semantic context, other 'constructors'
+// are just wrappers around this one.
+func NewATNConfig(c *ATNConfig, state ATNState, context *PredictionContext, semanticContext SemanticContext) *ATNConfig {
+ if semanticContext == nil {
+ panic("semanticContext cannot be nil") // TODO: Remove this - probably put here for some bug that is now fixed
+ }
+ b := &ATNConfig{}
+ b.InitATNConfig(c, state, c.GetAlt(), context, semanticContext)
+ b.cType = parserConfig
+ return b
+}
+
+func (a *ATNConfig) InitATNConfig(c *ATNConfig, state ATNState, alt int, context *PredictionContext, semanticContext SemanticContext) {
+
+ a.state = state
+ a.alt = alt
+ a.context = context
+ a.semanticContext = semanticContext
+ a.reachesIntoOuterContext = c.GetReachesIntoOuterContext()
+ a.precedenceFilterSuppressed = c.getPrecedenceFilterSuppressed()
+}
+
+func (a *ATNConfig) getPrecedenceFilterSuppressed() bool {
+ return a.precedenceFilterSuppressed
+}
+
+func (a *ATNConfig) setPrecedenceFilterSuppressed(v bool) {
+ a.precedenceFilterSuppressed = v
+}
+
+// GetState returns the ATN state associated with this configuration
+func (a *ATNConfig) GetState() ATNState {
+ return a.state
+}
+
+// GetAlt returns the alternative associated with this configuration
+func (a *ATNConfig) GetAlt() int {
+ return a.alt
+}
+
+// SetContext sets the rule invocation stack associated with this configuration
+func (a *ATNConfig) SetContext(v *PredictionContext) {
+ a.context = v
+}
+
+// GetContext returns the rule invocation stack associated with this configuration
+func (a *ATNConfig) GetContext() *PredictionContext {
+ return a.context
+}
+
+// GetSemanticContext returns the semantic context associated with this configuration
+func (a *ATNConfig) GetSemanticContext() SemanticContext {
+ return a.semanticContext
+}
+
+// GetReachesIntoOuterContext returns the count of references to an outer context from this configuration
+func (a *ATNConfig) GetReachesIntoOuterContext() int {
+ return a.reachesIntoOuterContext
+}
+
+// SetReachesIntoOuterContext sets the count of references to an outer context from this configuration
+func (a *ATNConfig) SetReachesIntoOuterContext(v int) {
+ a.reachesIntoOuterContext = v
+}
+
+// Equals is the default comparison function for an ATNConfig when no specialist implementation is required
+// for a collection.
+//
+// An ATN configuration is equal to another if both have the same state, they
+// predict the same alternative, and syntactic/semantic contexts are the same.
+func (a *ATNConfig) Equals(o Collectable[*ATNConfig]) bool {
+ switch a.cType {
+ case lexerConfig:
+ return a.LEquals(o)
+ case parserConfig:
+ return a.PEquals(o)
+ default:
+ panic("Invalid ATNConfig type")
+ }
+}
+
+// PEquals is the default comparison function for a Parser ATNConfig when no specialist implementation is required
+// for a collection.
+//
+// An ATN configuration is equal to another if both have the same state, they
+// predict the same alternative, and syntactic/semantic contexts are the same.
+func (a *ATNConfig) PEquals(o Collectable[*ATNConfig]) bool {
+ var other, ok = o.(*ATNConfig)
+
+ if !ok {
+ return false
+ }
+ if a == other {
+ return true
+ } else if other == nil {
+ return false
+ }
+
+ var equal bool
+
+ if a.context == nil {
+ equal = other.context == nil
+ } else {
+ equal = a.context.Equals(other.context)
+ }
+
+ var (
+ nums = a.state.GetStateNumber() == other.state.GetStateNumber()
+ alts = a.alt == other.alt
+ cons = a.semanticContext.Equals(other.semanticContext)
+ sups = a.precedenceFilterSuppressed == other.precedenceFilterSuppressed
+ )
+
+ return nums && alts && cons && sups && equal
+}
+
+// Hash is the default hash function for a parser ATNConfig, when no specialist hash function
+// is required for a collection
+func (a *ATNConfig) Hash() int {
+ switch a.cType {
+ case lexerConfig:
+ return a.LHash()
+ case parserConfig:
+ return a.PHash()
+ default:
+ panic("Invalid ATNConfig type")
+ }
+}
+
+// PHash is the default hash function for a parser ATNConfig, when no specialist hash function
+// is required for a collection
+func (a *ATNConfig) PHash() int {
+ var c int
+ if a.context != nil {
+ c = a.context.Hash()
+ }
+
+ h := murmurInit(7)
+ h = murmurUpdate(h, a.state.GetStateNumber())
+ h = murmurUpdate(h, a.alt)
+ h = murmurUpdate(h, c)
+ h = murmurUpdate(h, a.semanticContext.Hash())
+ return murmurFinish(h, 4)
+}
+
+// String returns a string representation of the ATNConfig, usually used for debugging purposes
+func (a *ATNConfig) String() string {
+ var s1, s2, s3 string
+
+ if a.context != nil {
+ s1 = ",[" + fmt.Sprint(a.context) + "]"
+ }
+
+ if a.semanticContext != SemanticContextNone {
+ s2 = "," + fmt.Sprint(a.semanticContext)
+ }
+
+ if a.reachesIntoOuterContext > 0 {
+ s3 = ",up=" + fmt.Sprint(a.reachesIntoOuterContext)
+ }
+
+ return fmt.Sprintf("(%v,%v%v%v%v)", a.state, a.alt, s1, s2, s3)
+}
+
+func NewLexerATNConfig6(state ATNState, alt int, context *PredictionContext) *ATNConfig {
+ lac := &ATNConfig{}
+ lac.state = state
+ lac.alt = alt
+ lac.context = context
+ lac.semanticContext = SemanticContextNone
+ lac.cType = lexerConfig
+ return lac
+}
+
+func NewLexerATNConfig4(c *ATNConfig, state ATNState) *ATNConfig {
+ lac := &ATNConfig{}
+ lac.lexerActionExecutor = c.lexerActionExecutor
+ lac.passedThroughNonGreedyDecision = checkNonGreedyDecision(c, state)
+ lac.InitATNConfig(c, state, c.GetAlt(), c.GetContext(), c.GetSemanticContext())
+ lac.cType = lexerConfig
+ return lac
+}
+
+func NewLexerATNConfig3(c *ATNConfig, state ATNState, lexerActionExecutor *LexerActionExecutor) *ATNConfig {
+ lac := &ATNConfig{}
+ lac.lexerActionExecutor = lexerActionExecutor
+ lac.passedThroughNonGreedyDecision = checkNonGreedyDecision(c, state)
+ lac.InitATNConfig(c, state, c.GetAlt(), c.GetContext(), c.GetSemanticContext())
+ lac.cType = lexerConfig
+ return lac
+}
+
+func NewLexerATNConfig2(c *ATNConfig, state ATNState, context *PredictionContext) *ATNConfig {
+ lac := &ATNConfig{}
+ lac.lexerActionExecutor = c.lexerActionExecutor
+ lac.passedThroughNonGreedyDecision = checkNonGreedyDecision(c, state)
+ lac.InitATNConfig(c, state, c.GetAlt(), context, c.GetSemanticContext())
+ lac.cType = lexerConfig
+ return lac
+}
+
+//goland:noinspection GoUnusedExportedFunction
+func NewLexerATNConfig1(state ATNState, alt int, context *PredictionContext) *ATNConfig {
+ lac := &ATNConfig{}
+ lac.state = state
+ lac.alt = alt
+ lac.context = context
+ lac.semanticContext = SemanticContextNone
+ lac.cType = lexerConfig
+ return lac
+}
+
+// LHash is the default hash function for Lexer ATNConfig objects, it can be used directly or via
+// the default comparator [ObjEqComparator].
+func (a *ATNConfig) LHash() int {
+ var f int
+ if a.passedThroughNonGreedyDecision {
+ f = 1
+ } else {
+ f = 0
+ }
+ h := murmurInit(7)
+ h = murmurUpdate(h, a.state.GetStateNumber())
+ h = murmurUpdate(h, a.alt)
+ h = murmurUpdate(h, a.context.Hash())
+ h = murmurUpdate(h, a.semanticContext.Hash())
+ h = murmurUpdate(h, f)
+ h = murmurUpdate(h, a.lexerActionExecutor.Hash())
+ h = murmurFinish(h, 6)
+ return h
+}
+
+// LEquals is the default comparison function for Lexer ATNConfig objects, it can be used directly or via
+// the default comparator [ObjEqComparator].
+func (a *ATNConfig) LEquals(other Collectable[*ATNConfig]) bool {
+ var otherT, ok = other.(*ATNConfig)
+ if !ok {
+ return false
+ } else if a == otherT {
+ return true
+ } else if a.passedThroughNonGreedyDecision != otherT.passedThroughNonGreedyDecision {
+ return false
+ }
+
+ switch {
+ case a.lexerActionExecutor == nil && otherT.lexerActionExecutor == nil:
+ return true
+ case a.lexerActionExecutor != nil && otherT.lexerActionExecutor != nil:
+ if !a.lexerActionExecutor.Equals(otherT.lexerActionExecutor) {
+ return false
+ }
+ default:
+ return false // One but not both, are nil
+ }
+
+ return a.PEquals(otherT)
+}
+
+func checkNonGreedyDecision(source *ATNConfig, target ATNState) bool {
+ var ds, ok = target.(DecisionState)
+
+ return source.passedThroughNonGreedyDecision || (ok && ds.getNonGreedy())
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/atn_config_set.go b/vendor/github.com/antlr4-go/antlr/v4/atn_config_set.go
new file mode 100644
index 000000000000..52dbaf8064f0
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/atn_config_set.go
@@ -0,0 +1,301 @@
+// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
+// Use of this file is governed by the BSD 3-clause license that
+// can be found in the LICENSE.txt file in the project root.
+
+package antlr
+
+import (
+ "fmt"
+)
+
+// ATNConfigSet is a specialized set of ATNConfig that tracks information
+// about its elements and can combine similar configurations using a
+// graph-structured stack.
+type ATNConfigSet struct {
+ cachedHash int
+
+ // configLookup is used to determine whether two ATNConfigSets are equal. We
+ // need all configurations with the same (s, i, _, semctx) to be equal. A key
+ // effectively doubles the number of objects associated with ATNConfigs. All
+ // keys are hashed by (s, i, _, pi), not including the context. Wiped out when
+ // read-only because a set becomes a DFA state.
+ configLookup *JStore[*ATNConfig, Comparator[*ATNConfig]]
+
+ // configs is the added elements that did not match an existing key in configLookup
+ configs []*ATNConfig
+
+ // TODO: These fields make me pretty uncomfortable, but it is nice to pack up
+ // info together because it saves re-computation. Can we track conflicts as they
+ // are added to save scanning configs later?
+ conflictingAlts *BitSet
+
+ // dipsIntoOuterContext is used by parsers and lexers. In a lexer, it indicates
+ // we hit a pred while computing a closure operation. Do not make a DFA state
+ // from the ATNConfigSet in this case. TODO: How is this used by parsers?
+ dipsIntoOuterContext bool
+
+ // fullCtx is whether it is part of a full context LL prediction. Used to
+ // determine how to merge $. It is a wildcard with SLL, but not for an LL
+ // context merge.
+ fullCtx bool
+
+ // Used in parser and lexer. In lexer, it indicates we hit a pred
+ // while computing a closure operation. Don't make a DFA state from this set.
+ hasSemanticContext bool
+
+ // readOnly is whether it is read-only. Do not
+ // allow any code to manipulate the set if true because DFA states will point at
+ // sets and those must not change. It not, protect other fields; conflictingAlts
+ // in particular, which is assigned after readOnly.
+ readOnly bool
+
+ // TODO: These fields make me pretty uncomfortable, but it is nice to pack up
+ // info together because it saves re-computation. Can we track conflicts as they
+ // are added to save scanning configs later?
+ uniqueAlt int
+}
+
+// Alts returns the combined set of alts for all the configurations in this set.
+func (b *ATNConfigSet) Alts() *BitSet {
+ alts := NewBitSet()
+ for _, it := range b.configs {
+ alts.add(it.GetAlt())
+ }
+ return alts
+}
+
+// NewATNConfigSet creates a new ATNConfigSet instance.
+func NewATNConfigSet(fullCtx bool) *ATNConfigSet {
+ return &ATNConfigSet{
+ cachedHash: -1,
+ configLookup: NewJStore[*ATNConfig, Comparator[*ATNConfig]](aConfCompInst, ATNConfigLookupCollection, "NewATNConfigSet()"),
+ fullCtx: fullCtx,
+ }
+}
+
+// Add merges contexts with existing configs for (s, i, pi, _),
+// where 's' is the ATNConfig.state, 'i' is the ATNConfig.alt, and
+// 'pi' is the [ATNConfig].semanticContext.
+//
+// We use (s,i,pi) as the key.
+// Updates dipsIntoOuterContext and hasSemanticContext when necessary.
+func (b *ATNConfigSet) Add(config *ATNConfig, mergeCache *JPCMap) bool {
+ if b.readOnly {
+ panic("set is read-only")
+ }
+
+ if config.GetSemanticContext() != SemanticContextNone {
+ b.hasSemanticContext = true
+ }
+
+ if config.GetReachesIntoOuterContext() > 0 {
+ b.dipsIntoOuterContext = true
+ }
+
+ existing, present := b.configLookup.Put(config)
+
+ // The config was not already in the set
+ //
+ if !present {
+ b.cachedHash = -1
+ b.configs = append(b.configs, config) // Track order here
+ return true
+ }
+
+ // Merge a previous (s, i, pi, _) with it and save the result
+ rootIsWildcard := !b.fullCtx
+ merged := merge(existing.GetContext(), config.GetContext(), rootIsWildcard, mergeCache)
+
+ // No need to check for existing.context because config.context is in the cache,
+ // since the only way to create new graphs is the "call rule" and here. We cache
+ // at both places.
+ existing.SetReachesIntoOuterContext(intMax(existing.GetReachesIntoOuterContext(), config.GetReachesIntoOuterContext()))
+
+ // Preserve the precedence filter suppression during the merge
+ if config.getPrecedenceFilterSuppressed() {
+ existing.setPrecedenceFilterSuppressed(true)
+ }
+
+ // Replace the context because there is no need to do alt mapping
+ existing.SetContext(merged)
+
+ return true
+}
+
+// GetStates returns the set of states represented by all configurations in this config set
+func (b *ATNConfigSet) GetStates() *JStore[ATNState, Comparator[ATNState]] {
+
+ // states uses the standard comparator and Hash() provided by the ATNState instance
+ //
+ states := NewJStore[ATNState, Comparator[ATNState]](aStateEqInst, ATNStateCollection, "ATNConfigSet.GetStates()")
+
+ for i := 0; i < len(b.configs); i++ {
+ states.Put(b.configs[i].GetState())
+ }
+
+ return states
+}
+
+func (b *ATNConfigSet) GetPredicates() []SemanticContext {
+ predicates := make([]SemanticContext, 0)
+
+ for i := 0; i < len(b.configs); i++ {
+ c := b.configs[i].GetSemanticContext()
+
+ if c != SemanticContextNone {
+ predicates = append(predicates, c)
+ }
+ }
+
+ return predicates
+}
+
+func (b *ATNConfigSet) OptimizeConfigs(interpreter *BaseATNSimulator) {
+ if b.readOnly {
+ panic("set is read-only")
+ }
+
+ // Empty indicate no optimization is possible
+ if b.configLookup == nil || b.configLookup.Len() == 0 {
+ return
+ }
+
+ for i := 0; i < len(b.configs); i++ {
+ config := b.configs[i]
+ config.SetContext(interpreter.getCachedContext(config.GetContext()))
+ }
+}
+
+func (b *ATNConfigSet) AddAll(coll []*ATNConfig) bool {
+ for i := 0; i < len(coll); i++ {
+ b.Add(coll[i], nil)
+ }
+
+ return false
+}
+
+// Compare The configs are only equal if they are in the same order and their Equals function returns true.
+// Java uses ArrayList.equals(), which requires the same order.
+func (b *ATNConfigSet) Compare(bs *ATNConfigSet) bool {
+ if len(b.configs) != len(bs.configs) {
+ return false
+ }
+ for i := 0; i < len(b.configs); i++ {
+ if !b.configs[i].Equals(bs.configs[i]) {
+ return false
+ }
+ }
+
+ return true
+}
+
+func (b *ATNConfigSet) Equals(other Collectable[ATNConfig]) bool {
+ if b == other {
+ return true
+ } else if _, ok := other.(*ATNConfigSet); !ok {
+ return false
+ }
+
+ other2 := other.(*ATNConfigSet)
+ var eca bool
+ switch {
+ case b.conflictingAlts == nil && other2.conflictingAlts == nil:
+ eca = true
+ case b.conflictingAlts != nil && other2.conflictingAlts != nil:
+ eca = b.conflictingAlts.equals(other2.conflictingAlts)
+ }
+ return b.configs != nil &&
+ b.fullCtx == other2.fullCtx &&
+ b.uniqueAlt == other2.uniqueAlt &&
+ eca &&
+ b.hasSemanticContext == other2.hasSemanticContext &&
+ b.dipsIntoOuterContext == other2.dipsIntoOuterContext &&
+ b.Compare(other2)
+}
+
+func (b *ATNConfigSet) Hash() int {
+ if b.readOnly {
+ if b.cachedHash == -1 {
+ b.cachedHash = b.hashCodeConfigs()
+ }
+
+ return b.cachedHash
+ }
+
+ return b.hashCodeConfigs()
+}
+
+func (b *ATNConfigSet) hashCodeConfigs() int {
+ h := 1
+ for _, config := range b.configs {
+ h = 31*h + config.Hash()
+ }
+ return h
+}
+
+func (b *ATNConfigSet) Contains(item *ATNConfig) bool {
+ if b.readOnly {
+ panic("not implemented for read-only sets")
+ }
+ if b.configLookup == nil {
+ return false
+ }
+ return b.configLookup.Contains(item)
+}
+
+func (b *ATNConfigSet) ContainsFast(item *ATNConfig) bool {
+ return b.Contains(item)
+}
+
+func (b *ATNConfigSet) Clear() {
+ if b.readOnly {
+ panic("set is read-only")
+ }
+ b.configs = make([]*ATNConfig, 0)
+ b.cachedHash = -1
+ b.configLookup = NewJStore[*ATNConfig, Comparator[*ATNConfig]](aConfCompInst, ATNConfigLookupCollection, "NewATNConfigSet()")
+}
+
+func (b *ATNConfigSet) String() string {
+
+ s := "["
+
+ for i, c := range b.configs {
+ s += c.String()
+
+ if i != len(b.configs)-1 {
+ s += ", "
+ }
+ }
+
+ s += "]"
+
+ if b.hasSemanticContext {
+ s += ",hasSemanticContext=" + fmt.Sprint(b.hasSemanticContext)
+ }
+
+ if b.uniqueAlt != ATNInvalidAltNumber {
+ s += ",uniqueAlt=" + fmt.Sprint(b.uniqueAlt)
+ }
+
+ if b.conflictingAlts != nil {
+ s += ",conflictingAlts=" + b.conflictingAlts.String()
+ }
+
+ if b.dipsIntoOuterContext {
+ s += ",dipsIntoOuterContext"
+ }
+
+ return s
+}
+
+// NewOrderedATNConfigSet creates a config set with a slightly different Hash/Equal pair
+// for use in lexers.
+func NewOrderedATNConfigSet() *ATNConfigSet {
+ return &ATNConfigSet{
+ cachedHash: -1,
+ // This set uses the standard Hash() and Equals() from ATNConfig
+ configLookup: NewJStore[*ATNConfig, Comparator[*ATNConfig]](aConfEqInst, ATNConfigCollection, "ATNConfigSet.NewOrderedATNConfigSet()"),
+ fullCtx: false,
+ }
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/atn_deserialization_options.go b/vendor/github.com/antlr4-go/antlr/v4/atn_deserialization_options.go
new file mode 100644
index 000000000000..bdb30b362292
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/atn_deserialization_options.go
@@ -0,0 +1,62 @@
+// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
+// Use of this file is governed by the BSD 3-clause license that
+// can be found in the LICENSE.txt file in the project root.
+
+package antlr
+
+import "errors"
+
+var defaultATNDeserializationOptions = ATNDeserializationOptions{true, true, false}
+
+type ATNDeserializationOptions struct {
+ readOnly bool
+ verifyATN bool
+ generateRuleBypassTransitions bool
+}
+
+func (opts *ATNDeserializationOptions) ReadOnly() bool {
+ return opts.readOnly
+}
+
+func (opts *ATNDeserializationOptions) SetReadOnly(readOnly bool) {
+ if opts.readOnly {
+ panic(errors.New("cannot mutate read only ATNDeserializationOptions"))
+ }
+ opts.readOnly = readOnly
+}
+
+func (opts *ATNDeserializationOptions) VerifyATN() bool {
+ return opts.verifyATN
+}
+
+func (opts *ATNDeserializationOptions) SetVerifyATN(verifyATN bool) {
+ if opts.readOnly {
+ panic(errors.New("cannot mutate read only ATNDeserializationOptions"))
+ }
+ opts.verifyATN = verifyATN
+}
+
+func (opts *ATNDeserializationOptions) GenerateRuleBypassTransitions() bool {
+ return opts.generateRuleBypassTransitions
+}
+
+func (opts *ATNDeserializationOptions) SetGenerateRuleBypassTransitions(generateRuleBypassTransitions bool) {
+ if opts.readOnly {
+ panic(errors.New("cannot mutate read only ATNDeserializationOptions"))
+ }
+ opts.generateRuleBypassTransitions = generateRuleBypassTransitions
+}
+
+//goland:noinspection GoUnusedExportedFunction
+func DefaultATNDeserializationOptions() *ATNDeserializationOptions {
+ return NewATNDeserializationOptions(&defaultATNDeserializationOptions)
+}
+
+func NewATNDeserializationOptions(other *ATNDeserializationOptions) *ATNDeserializationOptions {
+ o := new(ATNDeserializationOptions)
+ if other != nil {
+ *o = *other
+ o.readOnly = false
+ }
+ return o
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/atn_deserializer.go b/vendor/github.com/antlr4-go/antlr/v4/atn_deserializer.go
new file mode 100644
index 000000000000..2dcb9ae11b6a
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/atn_deserializer.go
@@ -0,0 +1,684 @@
+// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
+// Use of this file is governed by the BSD 3-clause license that
+// can be found in the LICENSE.txt file in the project root.
+
+package antlr
+
+import (
+ "fmt"
+ "strconv"
+)
+
+const serializedVersion = 4
+
+type loopEndStateIntPair struct {
+ item0 *LoopEndState
+ item1 int
+}
+
+type blockStartStateIntPair struct {
+ item0 BlockStartState
+ item1 int
+}
+
+type ATNDeserializer struct {
+ options *ATNDeserializationOptions
+ data []int32
+ pos int
+}
+
+func NewATNDeserializer(options *ATNDeserializationOptions) *ATNDeserializer {
+ if options == nil {
+ options = &defaultATNDeserializationOptions
+ }
+
+ return &ATNDeserializer{options: options}
+}
+
+//goland:noinspection GoUnusedFunction
+func stringInSlice(a string, list []string) int {
+ for i, b := range list {
+ if b == a {
+ return i
+ }
+ }
+
+ return -1
+}
+
+func (a *ATNDeserializer) Deserialize(data []int32) *ATN {
+ a.data = data
+ a.pos = 0
+ a.checkVersion()
+
+ atn := a.readATN()
+
+ a.readStates(atn)
+ a.readRules(atn)
+ a.readModes(atn)
+
+ sets := a.readSets(atn, nil)
+
+ a.readEdges(atn, sets)
+ a.readDecisions(atn)
+ a.readLexerActions(atn)
+ a.markPrecedenceDecisions(atn)
+ a.verifyATN(atn)
+
+ if a.options.GenerateRuleBypassTransitions() && atn.grammarType == ATNTypeParser {
+ a.generateRuleBypassTransitions(atn)
+ // Re-verify after modification
+ a.verifyATN(atn)
+ }
+
+ return atn
+
+}
+
+func (a *ATNDeserializer) checkVersion() {
+ version := a.readInt()
+
+ if version != serializedVersion {
+ panic("Could not deserialize ATN with version " + strconv.Itoa(version) + " (expected " + strconv.Itoa(serializedVersion) + ").")
+ }
+}
+
+func (a *ATNDeserializer) readATN() *ATN {
+ grammarType := a.readInt()
+ maxTokenType := a.readInt()
+
+ return NewATN(grammarType, maxTokenType)
+}
+
+func (a *ATNDeserializer) readStates(atn *ATN) {
+ nstates := a.readInt()
+
+ // Allocate worst case size.
+ loopBackStateNumbers := make([]loopEndStateIntPair, 0, nstates)
+ endStateNumbers := make([]blockStartStateIntPair, 0, nstates)
+
+ // Preallocate states slice.
+ atn.states = make([]ATNState, 0, nstates)
+
+ for i := 0; i < nstates; i++ {
+ stype := a.readInt()
+
+ // Ignore bad types of states
+ if stype == ATNStateInvalidType {
+ atn.addState(nil)
+ continue
+ }
+
+ ruleIndex := a.readInt()
+
+ s := a.stateFactory(stype, ruleIndex)
+
+ if stype == ATNStateLoopEnd {
+ loopBackStateNumber := a.readInt()
+
+ loopBackStateNumbers = append(loopBackStateNumbers, loopEndStateIntPair{s.(*LoopEndState), loopBackStateNumber})
+ } else if s2, ok := s.(BlockStartState); ok {
+ endStateNumber := a.readInt()
+
+ endStateNumbers = append(endStateNumbers, blockStartStateIntPair{s2, endStateNumber})
+ }
+
+ atn.addState(s)
+ }
+
+ // Delay the assignment of loop back and end states until we know all the state
+ // instances have been initialized
+ for _, pair := range loopBackStateNumbers {
+ pair.item0.loopBackState = atn.states[pair.item1]
+ }
+
+ for _, pair := range endStateNumbers {
+ pair.item0.setEndState(atn.states[pair.item1].(*BlockEndState))
+ }
+
+ numNonGreedyStates := a.readInt()
+ for j := 0; j < numNonGreedyStates; j++ {
+ stateNumber := a.readInt()
+
+ atn.states[stateNumber].(DecisionState).setNonGreedy(true)
+ }
+
+ numPrecedenceStates := a.readInt()
+ for j := 0; j < numPrecedenceStates; j++ {
+ stateNumber := a.readInt()
+
+ atn.states[stateNumber].(*RuleStartState).isPrecedenceRule = true
+ }
+}
+
+func (a *ATNDeserializer) readRules(atn *ATN) {
+ nrules := a.readInt()
+
+ if atn.grammarType == ATNTypeLexer {
+ atn.ruleToTokenType = make([]int, nrules)
+ }
+
+ atn.ruleToStartState = make([]*RuleStartState, nrules)
+
+ for i := range atn.ruleToStartState {
+ s := a.readInt()
+ startState := atn.states[s].(*RuleStartState)
+
+ atn.ruleToStartState[i] = startState
+
+ if atn.grammarType == ATNTypeLexer {
+ tokenType := a.readInt()
+
+ atn.ruleToTokenType[i] = tokenType
+ }
+ }
+
+ atn.ruleToStopState = make([]*RuleStopState, nrules)
+
+ for _, state := range atn.states {
+ if s2, ok := state.(*RuleStopState); ok {
+ atn.ruleToStopState[s2.ruleIndex] = s2
+ atn.ruleToStartState[s2.ruleIndex].stopState = s2
+ }
+ }
+}
+
+func (a *ATNDeserializer) readModes(atn *ATN) {
+ nmodes := a.readInt()
+ atn.modeToStartState = make([]*TokensStartState, nmodes)
+
+ for i := range atn.modeToStartState {
+ s := a.readInt()
+
+ atn.modeToStartState[i] = atn.states[s].(*TokensStartState)
+ }
+}
+
+func (a *ATNDeserializer) readSets(_ *ATN, sets []*IntervalSet) []*IntervalSet {
+ m := a.readInt()
+
+ // Preallocate the needed capacity.
+ if cap(sets)-len(sets) < m {
+ isets := make([]*IntervalSet, len(sets), len(sets)+m)
+ copy(isets, sets)
+ sets = isets
+ }
+
+ for i := 0; i < m; i++ {
+ iset := NewIntervalSet()
+
+ sets = append(sets, iset)
+
+ n := a.readInt()
+ containsEOF := a.readInt()
+
+ if containsEOF != 0 {
+ iset.addOne(-1)
+ }
+
+ for j := 0; j < n; j++ {
+ i1 := a.readInt()
+ i2 := a.readInt()
+
+ iset.addRange(i1, i2)
+ }
+ }
+
+ return sets
+}
+
+func (a *ATNDeserializer) readEdges(atn *ATN, sets []*IntervalSet) {
+ nedges := a.readInt()
+
+ for i := 0; i < nedges; i++ {
+ var (
+ src = a.readInt()
+ trg = a.readInt()
+ ttype = a.readInt()
+ arg1 = a.readInt()
+ arg2 = a.readInt()
+ arg3 = a.readInt()
+ trans = a.edgeFactory(atn, ttype, src, trg, arg1, arg2, arg3, sets)
+ srcState = atn.states[src]
+ )
+
+ srcState.AddTransition(trans, -1)
+ }
+
+ // Edges for rule stop states can be derived, so they are not serialized
+ for _, state := range atn.states {
+ for _, t := range state.GetTransitions() {
+ var rt, ok = t.(*RuleTransition)
+
+ if !ok {
+ continue
+ }
+
+ outermostPrecedenceReturn := -1
+
+ if atn.ruleToStartState[rt.getTarget().GetRuleIndex()].isPrecedenceRule {
+ if rt.precedence == 0 {
+ outermostPrecedenceReturn = rt.getTarget().GetRuleIndex()
+ }
+ }
+
+ trans := NewEpsilonTransition(rt.followState, outermostPrecedenceReturn)
+
+ atn.ruleToStopState[rt.getTarget().GetRuleIndex()].AddTransition(trans, -1)
+ }
+ }
+
+ for _, state := range atn.states {
+ if s2, ok := state.(BlockStartState); ok {
+ // We need to know the end state to set its start state
+ if s2.getEndState() == nil {
+ panic("IllegalState")
+ }
+
+ // Block end states can only be associated to a single block start state
+ if s2.getEndState().startState != nil {
+ panic("IllegalState")
+ }
+
+ s2.getEndState().startState = state
+ }
+
+ if s2, ok := state.(*PlusLoopbackState); ok {
+ for _, t := range s2.GetTransitions() {
+ if t2, ok := t.getTarget().(*PlusBlockStartState); ok {
+ t2.loopBackState = state
+ }
+ }
+ } else if s2, ok := state.(*StarLoopbackState); ok {
+ for _, t := range s2.GetTransitions() {
+ if t2, ok := t.getTarget().(*StarLoopEntryState); ok {
+ t2.loopBackState = state
+ }
+ }
+ }
+ }
+}
+
+func (a *ATNDeserializer) readDecisions(atn *ATN) {
+ ndecisions := a.readInt()
+
+ for i := 0; i < ndecisions; i++ {
+ s := a.readInt()
+ decState := atn.states[s].(DecisionState)
+
+ atn.DecisionToState = append(atn.DecisionToState, decState)
+ decState.setDecision(i)
+ }
+}
+
+func (a *ATNDeserializer) readLexerActions(atn *ATN) {
+ if atn.grammarType == ATNTypeLexer {
+ count := a.readInt()
+
+ atn.lexerActions = make([]LexerAction, count)
+
+ for i := range atn.lexerActions {
+ actionType := a.readInt()
+ data1 := a.readInt()
+ data2 := a.readInt()
+ atn.lexerActions[i] = a.lexerActionFactory(actionType, data1, data2)
+ }
+ }
+}
+
+func (a *ATNDeserializer) generateRuleBypassTransitions(atn *ATN) {
+ count := len(atn.ruleToStartState)
+
+ for i := 0; i < count; i++ {
+ atn.ruleToTokenType[i] = atn.maxTokenType + i + 1
+ }
+
+ for i := 0; i < count; i++ {
+ a.generateRuleBypassTransition(atn, i)
+ }
+}
+
+func (a *ATNDeserializer) generateRuleBypassTransition(atn *ATN, idx int) {
+ bypassStart := NewBasicBlockStartState()
+
+ bypassStart.ruleIndex = idx
+ atn.addState(bypassStart)
+
+ bypassStop := NewBlockEndState()
+
+ bypassStop.ruleIndex = idx
+ atn.addState(bypassStop)
+
+ bypassStart.endState = bypassStop
+
+ atn.defineDecisionState(&bypassStart.BaseDecisionState)
+
+ bypassStop.startState = bypassStart
+
+ var excludeTransition Transition
+ var endState ATNState
+
+ if atn.ruleToStartState[idx].isPrecedenceRule {
+ // Wrap from the beginning of the rule to the StarLoopEntryState
+ endState = nil
+
+ for i := 0; i < len(atn.states); i++ {
+ state := atn.states[i]
+
+ if a.stateIsEndStateFor(state, idx) != nil {
+ endState = state
+ excludeTransition = state.(*StarLoopEntryState).loopBackState.GetTransitions()[0]
+
+ break
+ }
+ }
+
+ if excludeTransition == nil {
+ panic("Couldn't identify final state of the precedence rule prefix section.")
+ }
+ } else {
+ endState = atn.ruleToStopState[idx]
+ }
+
+ // All non-excluded transitions that currently target end state need to target
+ // blockEnd instead
+ for i := 0; i < len(atn.states); i++ {
+ state := atn.states[i]
+
+ for j := 0; j < len(state.GetTransitions()); j++ {
+ transition := state.GetTransitions()[j]
+
+ if transition == excludeTransition {
+ continue
+ }
+
+ if transition.getTarget() == endState {
+ transition.setTarget(bypassStop)
+ }
+ }
+ }
+
+ // All transitions leaving the rule start state need to leave blockStart instead
+ ruleToStartState := atn.ruleToStartState[idx]
+ count := len(ruleToStartState.GetTransitions())
+
+ for count > 0 {
+ bypassStart.AddTransition(ruleToStartState.GetTransitions()[count-1], -1)
+ ruleToStartState.SetTransitions([]Transition{ruleToStartState.GetTransitions()[len(ruleToStartState.GetTransitions())-1]})
+ }
+
+ // Link the new states
+ atn.ruleToStartState[idx].AddTransition(NewEpsilonTransition(bypassStart, -1), -1)
+ bypassStop.AddTransition(NewEpsilonTransition(endState, -1), -1)
+
+ MatchState := NewBasicState()
+
+ atn.addState(MatchState)
+ MatchState.AddTransition(NewAtomTransition(bypassStop, atn.ruleToTokenType[idx]), -1)
+ bypassStart.AddTransition(NewEpsilonTransition(MatchState, -1), -1)
+}
+
+func (a *ATNDeserializer) stateIsEndStateFor(state ATNState, idx int) ATNState {
+ if state.GetRuleIndex() != idx {
+ return nil
+ }
+
+ if _, ok := state.(*StarLoopEntryState); !ok {
+ return nil
+ }
+
+ maybeLoopEndState := state.GetTransitions()[len(state.GetTransitions())-1].getTarget()
+
+ if _, ok := maybeLoopEndState.(*LoopEndState); !ok {
+ return nil
+ }
+
+ var _, ok = maybeLoopEndState.GetTransitions()[0].getTarget().(*RuleStopState)
+
+ if maybeLoopEndState.(*LoopEndState).epsilonOnlyTransitions && ok {
+ return state
+ }
+
+ return nil
+}
+
+// markPrecedenceDecisions analyzes the StarLoopEntryState states in the
+// specified ATN to set the StarLoopEntryState.precedenceRuleDecision field to
+// the correct value.
+func (a *ATNDeserializer) markPrecedenceDecisions(atn *ATN) {
+ for _, state := range atn.states {
+ if _, ok := state.(*StarLoopEntryState); !ok {
+ continue
+ }
+
+ // We analyze the [ATN] to determine if an ATN decision state is the
+ // decision for the closure block that determines whether a
+ // precedence rule should continue or complete.
+ if atn.ruleToStartState[state.GetRuleIndex()].isPrecedenceRule {
+ maybeLoopEndState := state.GetTransitions()[len(state.GetTransitions())-1].getTarget()
+
+ if s3, ok := maybeLoopEndState.(*LoopEndState); ok {
+ var _, ok2 = maybeLoopEndState.GetTransitions()[0].getTarget().(*RuleStopState)
+
+ if s3.epsilonOnlyTransitions && ok2 {
+ state.(*StarLoopEntryState).precedenceRuleDecision = true
+ }
+ }
+ }
+ }
+}
+
+func (a *ATNDeserializer) verifyATN(atn *ATN) {
+ if !a.options.VerifyATN() {
+ return
+ }
+
+ // Verify assumptions
+ for _, state := range atn.states {
+ if state == nil {
+ continue
+ }
+
+ a.checkCondition(state.GetEpsilonOnlyTransitions() || len(state.GetTransitions()) <= 1, "")
+
+ switch s2 := state.(type) {
+ case *PlusBlockStartState:
+ a.checkCondition(s2.loopBackState != nil, "")
+
+ case *StarLoopEntryState:
+ a.checkCondition(s2.loopBackState != nil, "")
+ a.checkCondition(len(s2.GetTransitions()) == 2, "")
+
+ switch s2.transitions[0].getTarget().(type) {
+ case *StarBlockStartState:
+ _, ok := s2.transitions[1].getTarget().(*LoopEndState)
+
+ a.checkCondition(ok, "")
+ a.checkCondition(!s2.nonGreedy, "")
+
+ case *LoopEndState:
+ var _, ok = s2.transitions[1].getTarget().(*StarBlockStartState)
+
+ a.checkCondition(ok, "")
+ a.checkCondition(s2.nonGreedy, "")
+
+ default:
+ panic("IllegalState")
+ }
+
+ case *StarLoopbackState:
+ a.checkCondition(len(state.GetTransitions()) == 1, "")
+
+ var _, ok = state.GetTransitions()[0].getTarget().(*StarLoopEntryState)
+
+ a.checkCondition(ok, "")
+
+ case *LoopEndState:
+ a.checkCondition(s2.loopBackState != nil, "")
+
+ case *RuleStartState:
+ a.checkCondition(s2.stopState != nil, "")
+
+ case BlockStartState:
+ a.checkCondition(s2.getEndState() != nil, "")
+
+ case *BlockEndState:
+ a.checkCondition(s2.startState != nil, "")
+
+ case DecisionState:
+ a.checkCondition(len(s2.GetTransitions()) <= 1 || s2.getDecision() >= 0, "")
+
+ default:
+ var _, ok = s2.(*RuleStopState)
+
+ a.checkCondition(len(s2.GetTransitions()) <= 1 || ok, "")
+ }
+ }
+}
+
+func (a *ATNDeserializer) checkCondition(condition bool, message string) {
+ if !condition {
+ if message == "" {
+ message = "IllegalState"
+ }
+
+ panic(message)
+ }
+}
+
+func (a *ATNDeserializer) readInt() int {
+ v := a.data[a.pos]
+
+ a.pos++
+
+ return int(v) // data is 32 bits but int is at least that big
+}
+
+func (a *ATNDeserializer) edgeFactory(atn *ATN, typeIndex, _, trg, arg1, arg2, arg3 int, sets []*IntervalSet) Transition {
+ target := atn.states[trg]
+
+ switch typeIndex {
+ case TransitionEPSILON:
+ return NewEpsilonTransition(target, -1)
+
+ case TransitionRANGE:
+ if arg3 != 0 {
+ return NewRangeTransition(target, TokenEOF, arg2)
+ }
+
+ return NewRangeTransition(target, arg1, arg2)
+
+ case TransitionRULE:
+ return NewRuleTransition(atn.states[arg1], arg2, arg3, target)
+
+ case TransitionPREDICATE:
+ return NewPredicateTransition(target, arg1, arg2, arg3 != 0)
+
+ case TransitionPRECEDENCE:
+ return NewPrecedencePredicateTransition(target, arg1)
+
+ case TransitionATOM:
+ if arg3 != 0 {
+ return NewAtomTransition(target, TokenEOF)
+ }
+
+ return NewAtomTransition(target, arg1)
+
+ case TransitionACTION:
+ return NewActionTransition(target, arg1, arg2, arg3 != 0)
+
+ case TransitionSET:
+ return NewSetTransition(target, sets[arg1])
+
+ case TransitionNOTSET:
+ return NewNotSetTransition(target, sets[arg1])
+
+ case TransitionWILDCARD:
+ return NewWildcardTransition(target)
+ }
+
+ panic("The specified transition type is not valid.")
+}
+
+func (a *ATNDeserializer) stateFactory(typeIndex, ruleIndex int) ATNState {
+ var s ATNState
+
+ switch typeIndex {
+ case ATNStateInvalidType:
+ return nil
+
+ case ATNStateBasic:
+ s = NewBasicState()
+
+ case ATNStateRuleStart:
+ s = NewRuleStartState()
+
+ case ATNStateBlockStart:
+ s = NewBasicBlockStartState()
+
+ case ATNStatePlusBlockStart:
+ s = NewPlusBlockStartState()
+
+ case ATNStateStarBlockStart:
+ s = NewStarBlockStartState()
+
+ case ATNStateTokenStart:
+ s = NewTokensStartState()
+
+ case ATNStateRuleStop:
+ s = NewRuleStopState()
+
+ case ATNStateBlockEnd:
+ s = NewBlockEndState()
+
+ case ATNStateStarLoopBack:
+ s = NewStarLoopbackState()
+
+ case ATNStateStarLoopEntry:
+ s = NewStarLoopEntryState()
+
+ case ATNStatePlusLoopBack:
+ s = NewPlusLoopbackState()
+
+ case ATNStateLoopEnd:
+ s = NewLoopEndState()
+
+ default:
+ panic(fmt.Sprintf("state type %d is invalid", typeIndex))
+ }
+
+ s.SetRuleIndex(ruleIndex)
+
+ return s
+}
+
+func (a *ATNDeserializer) lexerActionFactory(typeIndex, data1, data2 int) LexerAction {
+ switch typeIndex {
+ case LexerActionTypeChannel:
+ return NewLexerChannelAction(data1)
+
+ case LexerActionTypeCustom:
+ return NewLexerCustomAction(data1, data2)
+
+ case LexerActionTypeMode:
+ return NewLexerModeAction(data1)
+
+ case LexerActionTypeMore:
+ return LexerMoreActionINSTANCE
+
+ case LexerActionTypePopMode:
+ return LexerPopModeActionINSTANCE
+
+ case LexerActionTypePushMode:
+ return NewLexerPushModeAction(data1)
+
+ case LexerActionTypeSkip:
+ return LexerSkipActionINSTANCE
+
+ case LexerActionTypeType:
+ return NewLexerTypeAction(data1)
+
+ default:
+ panic(fmt.Sprintf("lexer action %d is invalid", typeIndex))
+ }
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/atn_simulator.go b/vendor/github.com/antlr4-go/antlr/v4/atn_simulator.go
new file mode 100644
index 000000000000..afe6c9f809a2
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/atn_simulator.go
@@ -0,0 +1,41 @@
+// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
+// Use of this file is governed by the BSD 3-clause license that
+// can be found in the LICENSE.txt file in the project root.
+
+package antlr
+
+var ATNSimulatorError = NewDFAState(0x7FFFFFFF, NewATNConfigSet(false))
+
+type IATNSimulator interface {
+ SharedContextCache() *PredictionContextCache
+ ATN() *ATN
+ DecisionToDFA() []*DFA
+}
+
+type BaseATNSimulator struct {
+ atn *ATN
+ sharedContextCache *PredictionContextCache
+ decisionToDFA []*DFA
+}
+
+func (b *BaseATNSimulator) getCachedContext(context *PredictionContext) *PredictionContext {
+ if b.sharedContextCache == nil {
+ return context
+ }
+
+ //visited := NewJMap[*PredictionContext, *PredictionContext, Comparator[*PredictionContext]](pContextEqInst, PredictionVisitedCollection, "Visit map in getCachedContext()")
+ visited := NewVisitRecord()
+ return getCachedBasePredictionContext(context, b.sharedContextCache, visited)
+}
+
+func (b *BaseATNSimulator) SharedContextCache() *PredictionContextCache {
+ return b.sharedContextCache
+}
+
+func (b *BaseATNSimulator) ATN() *ATN {
+ return b.atn
+}
+
+func (b *BaseATNSimulator) DecisionToDFA() []*DFA {
+ return b.decisionToDFA
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/atn_state.go b/vendor/github.com/antlr4-go/antlr/v4/atn_state.go
new file mode 100644
index 000000000000..2ae5807cdb84
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/atn_state.go
@@ -0,0 +1,461 @@
+// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
+// Use of this file is governed by the BSD 3-clause license that
+// can be found in the LICENSE.txt file in the project root.
+
+package antlr
+
+import (
+ "fmt"
+ "os"
+ "strconv"
+)
+
+// Constants for serialization.
+const (
+ ATNStateInvalidType = 0
+ ATNStateBasic = 1
+ ATNStateRuleStart = 2
+ ATNStateBlockStart = 3
+ ATNStatePlusBlockStart = 4
+ ATNStateStarBlockStart = 5
+ ATNStateTokenStart = 6
+ ATNStateRuleStop = 7
+ ATNStateBlockEnd = 8
+ ATNStateStarLoopBack = 9
+ ATNStateStarLoopEntry = 10
+ ATNStatePlusLoopBack = 11
+ ATNStateLoopEnd = 12
+
+ ATNStateInvalidStateNumber = -1
+)
+
+//goland:noinspection GoUnusedGlobalVariable
+var ATNStateInitialNumTransitions = 4
+
+type ATNState interface {
+ GetEpsilonOnlyTransitions() bool
+
+ GetRuleIndex() int
+ SetRuleIndex(int)
+
+ GetNextTokenWithinRule() *IntervalSet
+ SetNextTokenWithinRule(*IntervalSet)
+
+ GetATN() *ATN
+ SetATN(*ATN)
+
+ GetStateType() int
+
+ GetStateNumber() int
+ SetStateNumber(int)
+
+ GetTransitions() []Transition
+ SetTransitions([]Transition)
+ AddTransition(Transition, int)
+
+ String() string
+ Hash() int
+ Equals(Collectable[ATNState]) bool
+}
+
+type BaseATNState struct {
+ // NextTokenWithinRule caches lookahead during parsing. Not used during construction.
+ NextTokenWithinRule *IntervalSet
+
+ // atn is the current ATN.
+ atn *ATN
+
+ epsilonOnlyTransitions bool
+
+ // ruleIndex tracks the Rule index because there are no Rule objects at runtime.
+ ruleIndex int
+
+ stateNumber int
+
+ stateType int
+
+ // Track the transitions emanating from this ATN state.
+ transitions []Transition
+}
+
+func NewATNState() *BaseATNState {
+ return &BaseATNState{stateNumber: ATNStateInvalidStateNumber, stateType: ATNStateInvalidType}
+}
+
+func (as *BaseATNState) GetRuleIndex() int {
+ return as.ruleIndex
+}
+
+func (as *BaseATNState) SetRuleIndex(v int) {
+ as.ruleIndex = v
+}
+func (as *BaseATNState) GetEpsilonOnlyTransitions() bool {
+ return as.epsilonOnlyTransitions
+}
+
+func (as *BaseATNState) GetATN() *ATN {
+ return as.atn
+}
+
+func (as *BaseATNState) SetATN(atn *ATN) {
+ as.atn = atn
+}
+
+func (as *BaseATNState) GetTransitions() []Transition {
+ return as.transitions
+}
+
+func (as *BaseATNState) SetTransitions(t []Transition) {
+ as.transitions = t
+}
+
+func (as *BaseATNState) GetStateType() int {
+ return as.stateType
+}
+
+func (as *BaseATNState) GetStateNumber() int {
+ return as.stateNumber
+}
+
+func (as *BaseATNState) SetStateNumber(stateNumber int) {
+ as.stateNumber = stateNumber
+}
+
+func (as *BaseATNState) GetNextTokenWithinRule() *IntervalSet {
+ return as.NextTokenWithinRule
+}
+
+func (as *BaseATNState) SetNextTokenWithinRule(v *IntervalSet) {
+ as.NextTokenWithinRule = v
+}
+
+func (as *BaseATNState) Hash() int {
+ return as.stateNumber
+}
+
+func (as *BaseATNState) String() string {
+ return strconv.Itoa(as.stateNumber)
+}
+
+func (as *BaseATNState) Equals(other Collectable[ATNState]) bool {
+ if ot, ok := other.(ATNState); ok {
+ return as.stateNumber == ot.GetStateNumber()
+ }
+
+ return false
+}
+
+func (as *BaseATNState) isNonGreedyExitState() bool {
+ return false
+}
+
+func (as *BaseATNState) AddTransition(trans Transition, index int) {
+ if len(as.transitions) == 0 {
+ as.epsilonOnlyTransitions = trans.getIsEpsilon()
+ } else if as.epsilonOnlyTransitions != trans.getIsEpsilon() {
+ _, _ = fmt.Fprintf(os.Stdin, "ATN state %d has both epsilon and non-epsilon transitions.\n", as.stateNumber)
+ as.epsilonOnlyTransitions = false
+ }
+
+ // TODO: Check code for already present compared to the Java equivalent
+ //alreadyPresent := false
+ //for _, t := range as.transitions {
+ // if t.getTarget().GetStateNumber() == trans.getTarget().GetStateNumber() {
+ // if t.getLabel() != nil && trans.getLabel() != nil && trans.getLabel().Equals(t.getLabel()) {
+ // alreadyPresent = true
+ // break
+ // }
+ // } else if t.getIsEpsilon() && trans.getIsEpsilon() {
+ // alreadyPresent = true
+ // break
+ // }
+ //}
+ //if !alreadyPresent {
+ if index == -1 {
+ as.transitions = append(as.transitions, trans)
+ } else {
+ as.transitions = append(as.transitions[:index], append([]Transition{trans}, as.transitions[index:]...)...)
+ // TODO: as.transitions.splice(index, 1, trans)
+ }
+ //} else {
+ // _, _ = fmt.Fprintf(os.Stderr, "Transition already present in state %d\n", as.stateNumber)
+ //}
+}
+
+type BasicState struct {
+ BaseATNState
+}
+
+func NewBasicState() *BasicState {
+ return &BasicState{
+ BaseATNState: BaseATNState{
+ stateNumber: ATNStateInvalidStateNumber,
+ stateType: ATNStateBasic,
+ },
+ }
+}
+
+type DecisionState interface {
+ ATNState
+
+ getDecision() int
+ setDecision(int)
+
+ getNonGreedy() bool
+ setNonGreedy(bool)
+}
+
+type BaseDecisionState struct {
+ BaseATNState
+ decision int
+ nonGreedy bool
+}
+
+func NewBaseDecisionState() *BaseDecisionState {
+ return &BaseDecisionState{
+ BaseATNState: BaseATNState{
+ stateNumber: ATNStateInvalidStateNumber,
+ stateType: ATNStateBasic,
+ },
+ decision: -1,
+ }
+}
+
+func (s *BaseDecisionState) getDecision() int {
+ return s.decision
+}
+
+func (s *BaseDecisionState) setDecision(b int) {
+ s.decision = b
+}
+
+func (s *BaseDecisionState) getNonGreedy() bool {
+ return s.nonGreedy
+}
+
+func (s *BaseDecisionState) setNonGreedy(b bool) {
+ s.nonGreedy = b
+}
+
+type BlockStartState interface {
+ DecisionState
+
+ getEndState() *BlockEndState
+ setEndState(*BlockEndState)
+}
+
+// BaseBlockStartState is the start of a regular (...) block.
+type BaseBlockStartState struct {
+ BaseDecisionState
+ endState *BlockEndState
+}
+
+func NewBlockStartState() *BaseBlockStartState {
+ return &BaseBlockStartState{
+ BaseDecisionState: BaseDecisionState{
+ BaseATNState: BaseATNState{
+ stateNumber: ATNStateInvalidStateNumber,
+ stateType: ATNStateBasic,
+ },
+ decision: -1,
+ },
+ }
+}
+
+func (s *BaseBlockStartState) getEndState() *BlockEndState {
+ return s.endState
+}
+
+func (s *BaseBlockStartState) setEndState(b *BlockEndState) {
+ s.endState = b
+}
+
+type BasicBlockStartState struct {
+ BaseBlockStartState
+}
+
+func NewBasicBlockStartState() *BasicBlockStartState {
+ return &BasicBlockStartState{
+ BaseBlockStartState: BaseBlockStartState{
+ BaseDecisionState: BaseDecisionState{
+ BaseATNState: BaseATNState{
+ stateNumber: ATNStateInvalidStateNumber,
+ stateType: ATNStateBlockStart,
+ },
+ },
+ },
+ }
+}
+
+var _ BlockStartState = &BasicBlockStartState{}
+
+// BlockEndState is a terminal node of a simple (a|b|c) block.
+type BlockEndState struct {
+ BaseATNState
+ startState ATNState
+}
+
+func NewBlockEndState() *BlockEndState {
+ return &BlockEndState{
+ BaseATNState: BaseATNState{
+ stateNumber: ATNStateInvalidStateNumber,
+ stateType: ATNStateBlockEnd,
+ },
+ startState: nil,
+ }
+}
+
+// RuleStopState is the last node in the ATN for a rule, unless that rule is the
+// start symbol. In that case, there is one transition to EOF. Later, we might
+// encode references to all calls to this rule to compute FOLLOW sets for error
+// handling.
+type RuleStopState struct {
+ BaseATNState
+}
+
+func NewRuleStopState() *RuleStopState {
+ return &RuleStopState{
+ BaseATNState: BaseATNState{
+ stateNumber: ATNStateInvalidStateNumber,
+ stateType: ATNStateRuleStop,
+ },
+ }
+}
+
+type RuleStartState struct {
+ BaseATNState
+ stopState ATNState
+ isPrecedenceRule bool
+}
+
+func NewRuleStartState() *RuleStartState {
+ return &RuleStartState{
+ BaseATNState: BaseATNState{
+ stateNumber: ATNStateInvalidStateNumber,
+ stateType: ATNStateRuleStart,
+ },
+ }
+}
+
+// PlusLoopbackState is a decision state for A+ and (A|B)+. It has two
+// transitions: one to the loop back to start of the block, and one to exit.
+type PlusLoopbackState struct {
+ BaseDecisionState
+}
+
+func NewPlusLoopbackState() *PlusLoopbackState {
+ return &PlusLoopbackState{
+ BaseDecisionState: BaseDecisionState{
+ BaseATNState: BaseATNState{
+ stateNumber: ATNStateInvalidStateNumber,
+ stateType: ATNStatePlusLoopBack,
+ },
+ },
+ }
+}
+
+// PlusBlockStartState is the start of a (A|B|...)+ loop. Technically it is a
+// decision state; we don't use it for code generation. Somebody might need it,
+// it is included for completeness. In reality, PlusLoopbackState is the real
+// decision-making node for A+.
+type PlusBlockStartState struct {
+ BaseBlockStartState
+ loopBackState ATNState
+}
+
+func NewPlusBlockStartState() *PlusBlockStartState {
+ return &PlusBlockStartState{
+ BaseBlockStartState: BaseBlockStartState{
+ BaseDecisionState: BaseDecisionState{
+ BaseATNState: BaseATNState{
+ stateNumber: ATNStateInvalidStateNumber,
+ stateType: ATNStatePlusBlockStart,
+ },
+ },
+ },
+ }
+}
+
+var _ BlockStartState = &PlusBlockStartState{}
+
+// StarBlockStartState is the block that begins a closure loop.
+type StarBlockStartState struct {
+ BaseBlockStartState
+}
+
+func NewStarBlockStartState() *StarBlockStartState {
+ return &StarBlockStartState{
+ BaseBlockStartState: BaseBlockStartState{
+ BaseDecisionState: BaseDecisionState{
+ BaseATNState: BaseATNState{
+ stateNumber: ATNStateInvalidStateNumber,
+ stateType: ATNStateStarBlockStart,
+ },
+ },
+ },
+ }
+}
+
+var _ BlockStartState = &StarBlockStartState{}
+
+type StarLoopbackState struct {
+ BaseATNState
+}
+
+func NewStarLoopbackState() *StarLoopbackState {
+ return &StarLoopbackState{
+ BaseATNState: BaseATNState{
+ stateNumber: ATNStateInvalidStateNumber,
+ stateType: ATNStateStarLoopBack,
+ },
+ }
+}
+
+type StarLoopEntryState struct {
+ BaseDecisionState
+ loopBackState ATNState
+ precedenceRuleDecision bool
+}
+
+func NewStarLoopEntryState() *StarLoopEntryState {
+ // False precedenceRuleDecision indicates whether s state can benefit from a precedence DFA during SLL decision making.
+ return &StarLoopEntryState{
+ BaseDecisionState: BaseDecisionState{
+ BaseATNState: BaseATNState{
+ stateNumber: ATNStateInvalidStateNumber,
+ stateType: ATNStateStarLoopEntry,
+ },
+ },
+ }
+}
+
+// LoopEndState marks the end of a * or + loop.
+type LoopEndState struct {
+ BaseATNState
+ loopBackState ATNState
+}
+
+func NewLoopEndState() *LoopEndState {
+ return &LoopEndState{
+ BaseATNState: BaseATNState{
+ stateNumber: ATNStateInvalidStateNumber,
+ stateType: ATNStateLoopEnd,
+ },
+ }
+}
+
+// TokensStartState is the Tokens rule start state linking to each lexer rule start state.
+type TokensStartState struct {
+ BaseDecisionState
+}
+
+func NewTokensStartState() *TokensStartState {
+ return &TokensStartState{
+ BaseDecisionState: BaseDecisionState{
+ BaseATNState: BaseATNState{
+ stateNumber: ATNStateInvalidStateNumber,
+ stateType: ATNStateTokenStart,
+ },
+ },
+ }
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/atn_type.go b/vendor/github.com/antlr4-go/antlr/v4/atn_type.go
new file mode 100644
index 000000000000..3a515a145f46
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/atn_type.go
@@ -0,0 +1,11 @@
+// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
+// Use of this file is governed by the BSD 3-clause license that
+// can be found in the LICENSE.txt file in the project root.
+
+package antlr
+
+// Represent the type of recognizer an ATN applies to.
+const (
+ ATNTypeLexer = 0
+ ATNTypeParser = 1
+)
diff --git a/vendor/github.com/antlr4-go/antlr/v4/char_stream.go b/vendor/github.com/antlr4-go/antlr/v4/char_stream.go
new file mode 100644
index 000000000000..bd8127b6b54f
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/char_stream.go
@@ -0,0 +1,12 @@
+// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
+// Use of this file is governed by the BSD 3-clause license that
+// can be found in the LICENSE.txt file in the project root.
+
+package antlr
+
+type CharStream interface {
+ IntStream
+ GetText(int, int) string
+ GetTextFromTokens(start, end Token) string
+ GetTextFromInterval(Interval) string
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/common_token_factory.go b/vendor/github.com/antlr4-go/antlr/v4/common_token_factory.go
new file mode 100644
index 000000000000..1bb0314ea09c
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/common_token_factory.go
@@ -0,0 +1,56 @@
+// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
+// Use of this file is governed by the BSD 3-clause license that
+// can be found in the LICENSE.txt file in the project root.
+
+package antlr
+
+// TokenFactory creates CommonToken objects.
+type TokenFactory interface {
+ Create(source *TokenSourceCharStreamPair, ttype int, text string, channel, start, stop, line, column int) Token
+}
+
+// CommonTokenFactory is the default TokenFactory implementation.
+type CommonTokenFactory struct {
+ // copyText indicates whether CommonToken.setText should be called after
+ // constructing tokens to explicitly set the text. This is useful for cases
+ // where the input stream might not be able to provide arbitrary substrings of
+ // text from the input after the lexer creates a token (e.g. the
+ // implementation of CharStream.GetText in UnbufferedCharStream panics an
+ // UnsupportedOperationException). Explicitly setting the token text allows
+ // Token.GetText to be called at any time regardless of the input stream
+ // implementation.
+ //
+ // The default value is false to avoid the performance and memory overhead of
+ // copying text for every token unless explicitly requested.
+ copyText bool
+}
+
+func NewCommonTokenFactory(copyText bool) *CommonTokenFactory {
+ return &CommonTokenFactory{copyText: copyText}
+}
+
+// CommonTokenFactoryDEFAULT is the default CommonTokenFactory. It does not
+// explicitly copy token text when constructing tokens.
+var CommonTokenFactoryDEFAULT = NewCommonTokenFactory(false)
+
+func (c *CommonTokenFactory) Create(source *TokenSourceCharStreamPair, ttype int, text string, channel, start, stop, line, column int) Token {
+ t := NewCommonToken(source, ttype, channel, start, stop)
+
+ t.line = line
+ t.column = column
+
+ if text != "" {
+ t.SetText(text)
+ } else if c.copyText && source.charStream != nil {
+ t.SetText(source.charStream.GetTextFromInterval(NewInterval(start, stop)))
+ }
+
+ return t
+}
+
+func (c *CommonTokenFactory) createThin(ttype int, text string) Token {
+ t := NewCommonToken(nil, ttype, TokenDefaultChannel, -1, -1)
+ t.SetText(text)
+
+ return t
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/common_token_stream.go b/vendor/github.com/antlr4-go/antlr/v4/common_token_stream.go
new file mode 100644
index 000000000000..b75da9df08e0
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/common_token_stream.go
@@ -0,0 +1,450 @@
+// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
+// Use of this file is governed by the BSD 3-clause license that
+// can be found in the LICENSE.txt file in the project root.
+
+package antlr
+
+import (
+ "strconv"
+)
+
+// CommonTokenStream is an implementation of TokenStream that loads tokens from
+// a TokenSource on-demand and places the tokens in a buffer to provide access
+// to any previous token by index. This token stream ignores the value of
+// Token.getChannel. If your parser requires the token stream filter tokens to
+// only those on a particular channel, such as Token.DEFAULT_CHANNEL or
+// Token.HIDDEN_CHANNEL, use a filtering token stream such a CommonTokenStream.
+type CommonTokenStream struct {
+ channel int
+
+ // fetchedEOF indicates whether the Token.EOF token has been fetched from
+ // tokenSource and added to tokens. This field improves performance for the
+ // following cases:
+ //
+ // consume: The lookahead check in consume to preven consuming the EOF symbol is
+ // optimized by checking the values of fetchedEOF and p instead of calling LA.
+ //
+ // fetch: The check to prevent adding multiple EOF symbols into tokens is
+ // trivial with bt field.
+ fetchedEOF bool
+
+ // index into [tokens] of the current token (next token to consume).
+ // tokens[p] should be LT(1). It is set to -1 when the stream is first
+ // constructed or when SetTokenSource is called, indicating that the first token
+ // has not yet been fetched from the token source. For additional information,
+ // see the documentation of [IntStream] for a description of initializing methods.
+ index int
+
+ // tokenSource is the [TokenSource] from which tokens for the bt stream are
+ // fetched.
+ tokenSource TokenSource
+
+ // tokens contains all tokens fetched from the token source. The list is considered a
+ // complete view of the input once fetchedEOF is set to true.
+ tokens []Token
+}
+
+// NewCommonTokenStream creates a new CommonTokenStream instance using the supplied lexer to produce
+// tokens and will pull tokens from the given lexer channel.
+func NewCommonTokenStream(lexer Lexer, channel int) *CommonTokenStream {
+ return &CommonTokenStream{
+ channel: channel,
+ index: -1,
+ tokenSource: lexer,
+ tokens: make([]Token, 0),
+ }
+}
+
+// GetAllTokens returns all tokens currently pulled from the token source.
+func (c *CommonTokenStream) GetAllTokens() []Token {
+ return c.tokens
+}
+
+func (c *CommonTokenStream) Mark() int {
+ return 0
+}
+
+func (c *CommonTokenStream) Release(_ int) {}
+
+func (c *CommonTokenStream) Reset() {
+ c.fetchedEOF = false
+ c.tokens = make([]Token, 0)
+ c.Seek(0)
+}
+
+func (c *CommonTokenStream) Seek(index int) {
+ c.lazyInit()
+ c.index = c.adjustSeekIndex(index)
+}
+
+func (c *CommonTokenStream) Get(index int) Token {
+ c.lazyInit()
+
+ return c.tokens[index]
+}
+
+func (c *CommonTokenStream) Consume() {
+ SkipEOFCheck := false
+
+ if c.index >= 0 {
+ if c.fetchedEOF {
+ // The last token in tokens is EOF. Skip the check if p indexes any fetched.
+ // token except the last.
+ SkipEOFCheck = c.index < len(c.tokens)-1
+ } else {
+ // No EOF token in tokens. Skip the check if p indexes a fetched token.
+ SkipEOFCheck = c.index < len(c.tokens)
+ }
+ } else {
+ // Not yet initialized
+ SkipEOFCheck = false
+ }
+
+ if !SkipEOFCheck && c.LA(1) == TokenEOF {
+ panic("cannot consume EOF")
+ }
+
+ if c.Sync(c.index + 1) {
+ c.index = c.adjustSeekIndex(c.index + 1)
+ }
+}
+
+// Sync makes sure index i in tokens has a token and returns true if a token is
+// located at index i and otherwise false.
+func (c *CommonTokenStream) Sync(i int) bool {
+ n := i - len(c.tokens) + 1 // How many more elements do we need?
+
+ if n > 0 {
+ fetched := c.fetch(n)
+ return fetched >= n
+ }
+
+ return true
+}
+
+// fetch adds n elements to buffer and returns the actual number of elements
+// added to the buffer.
+func (c *CommonTokenStream) fetch(n int) int {
+ if c.fetchedEOF {
+ return 0
+ }
+
+ for i := 0; i < n; i++ {
+ t := c.tokenSource.NextToken()
+
+ t.SetTokenIndex(len(c.tokens))
+ c.tokens = append(c.tokens, t)
+
+ if t.GetTokenType() == TokenEOF {
+ c.fetchedEOF = true
+
+ return i + 1
+ }
+ }
+
+ return n
+}
+
+// GetTokens gets all tokens from start to stop inclusive.
+func (c *CommonTokenStream) GetTokens(start int, stop int, types *IntervalSet) []Token {
+ if start < 0 || stop < 0 {
+ return nil
+ }
+
+ c.lazyInit()
+
+ subset := make([]Token, 0)
+
+ if stop >= len(c.tokens) {
+ stop = len(c.tokens) - 1
+ }
+
+ for i := start; i < stop; i++ {
+ t := c.tokens[i]
+
+ if t.GetTokenType() == TokenEOF {
+ break
+ }
+
+ if types == nil || types.contains(t.GetTokenType()) {
+ subset = append(subset, t)
+ }
+ }
+
+ return subset
+}
+
+func (c *CommonTokenStream) LA(i int) int {
+ return c.LT(i).GetTokenType()
+}
+
+func (c *CommonTokenStream) lazyInit() {
+ if c.index == -1 {
+ c.setup()
+ }
+}
+
+func (c *CommonTokenStream) setup() {
+ c.Sync(0)
+ c.index = c.adjustSeekIndex(0)
+}
+
+func (c *CommonTokenStream) GetTokenSource() TokenSource {
+ return c.tokenSource
+}
+
+// SetTokenSource resets the c token stream by setting its token source.
+func (c *CommonTokenStream) SetTokenSource(tokenSource TokenSource) {
+ c.tokenSource = tokenSource
+ c.tokens = make([]Token, 0)
+ c.index = -1
+ c.fetchedEOF = false
+}
+
+// NextTokenOnChannel returns the index of the next token on channel given a
+// starting index. Returns i if tokens[i] is on channel. Returns -1 if there are
+// no tokens on channel between 'i' and [TokenEOF].
+func (c *CommonTokenStream) NextTokenOnChannel(i, _ int) int {
+ c.Sync(i)
+
+ if i >= len(c.tokens) {
+ return -1
+ }
+
+ token := c.tokens[i]
+
+ for token.GetChannel() != c.channel {
+ if token.GetTokenType() == TokenEOF {
+ return -1
+ }
+
+ i++
+ c.Sync(i)
+ token = c.tokens[i]
+ }
+
+ return i
+}
+
+// previousTokenOnChannel returns the index of the previous token on channel
+// given a starting index. Returns i if tokens[i] is on channel. Returns -1 if
+// there are no tokens on channel between i and 0.
+func (c *CommonTokenStream) previousTokenOnChannel(i, channel int) int {
+ for i >= 0 && c.tokens[i].GetChannel() != channel {
+ i--
+ }
+
+ return i
+}
+
+// GetHiddenTokensToRight collects all tokens on a specified channel to the
+// right of the current token up until we see a token on DEFAULT_TOKEN_CHANNEL
+// or EOF. If channel is -1, it finds any non-default channel token.
+func (c *CommonTokenStream) GetHiddenTokensToRight(tokenIndex, channel int) []Token {
+ c.lazyInit()
+
+ if tokenIndex < 0 || tokenIndex >= len(c.tokens) {
+ panic(strconv.Itoa(tokenIndex) + " not in 0.." + strconv.Itoa(len(c.tokens)-1))
+ }
+
+ nextOnChannel := c.NextTokenOnChannel(tokenIndex+1, LexerDefaultTokenChannel)
+ from := tokenIndex + 1
+
+ // If no onChannel to the right, then nextOnChannel == -1, so set 'to' to the last token
+ var to int
+
+ if nextOnChannel == -1 {
+ to = len(c.tokens) - 1
+ } else {
+ to = nextOnChannel
+ }
+
+ return c.filterForChannel(from, to, channel)
+}
+
+// GetHiddenTokensToLeft collects all tokens on channel to the left of the
+// current token until we see a token on DEFAULT_TOKEN_CHANNEL. If channel is
+// -1, it finds any non default channel token.
+func (c *CommonTokenStream) GetHiddenTokensToLeft(tokenIndex, channel int) []Token {
+ c.lazyInit()
+
+ if tokenIndex < 0 || tokenIndex >= len(c.tokens) {
+ panic(strconv.Itoa(tokenIndex) + " not in 0.." + strconv.Itoa(len(c.tokens)-1))
+ }
+
+ prevOnChannel := c.previousTokenOnChannel(tokenIndex-1, LexerDefaultTokenChannel)
+
+ if prevOnChannel == tokenIndex-1 {
+ return nil
+ }
+
+ // If there are none on channel to the left and prevOnChannel == -1 then from = 0
+ from := prevOnChannel + 1
+ to := tokenIndex - 1
+
+ return c.filterForChannel(from, to, channel)
+}
+
+func (c *CommonTokenStream) filterForChannel(left, right, channel int) []Token {
+ hidden := make([]Token, 0)
+
+ for i := left; i < right+1; i++ {
+ t := c.tokens[i]
+
+ if channel == -1 {
+ if t.GetChannel() != LexerDefaultTokenChannel {
+ hidden = append(hidden, t)
+ }
+ } else if t.GetChannel() == channel {
+ hidden = append(hidden, t)
+ }
+ }
+
+ if len(hidden) == 0 {
+ return nil
+ }
+
+ return hidden
+}
+
+func (c *CommonTokenStream) GetSourceName() string {
+ return c.tokenSource.GetSourceName()
+}
+
+func (c *CommonTokenStream) Size() int {
+ return len(c.tokens)
+}
+
+func (c *CommonTokenStream) Index() int {
+ return c.index
+}
+
+func (c *CommonTokenStream) GetAllText() string {
+ c.Fill()
+ return c.GetTextFromInterval(NewInterval(0, len(c.tokens)-1))
+}
+
+func (c *CommonTokenStream) GetTextFromTokens(start, end Token) string {
+ if start == nil || end == nil {
+ return ""
+ }
+
+ return c.GetTextFromInterval(NewInterval(start.GetTokenIndex(), end.GetTokenIndex()))
+}
+
+func (c *CommonTokenStream) GetTextFromRuleContext(interval RuleContext) string {
+ return c.GetTextFromInterval(interval.GetSourceInterval())
+}
+
+func (c *CommonTokenStream) GetTextFromInterval(interval Interval) string {
+ c.lazyInit()
+ c.Sync(interval.Stop)
+
+ start := interval.Start
+ stop := interval.Stop
+
+ if start < 0 || stop < 0 {
+ return ""
+ }
+
+ if stop >= len(c.tokens) {
+ stop = len(c.tokens) - 1
+ }
+
+ s := ""
+
+ for i := start; i < stop+1; i++ {
+ t := c.tokens[i]
+
+ if t.GetTokenType() == TokenEOF {
+ break
+ }
+
+ s += t.GetText()
+ }
+
+ return s
+}
+
+// Fill gets all tokens from the lexer until EOF.
+func (c *CommonTokenStream) Fill() {
+ c.lazyInit()
+
+ for c.fetch(1000) == 1000 {
+ continue
+ }
+}
+
+func (c *CommonTokenStream) adjustSeekIndex(i int) int {
+ return c.NextTokenOnChannel(i, c.channel)
+}
+
+func (c *CommonTokenStream) LB(k int) Token {
+ if k == 0 || c.index-k < 0 {
+ return nil
+ }
+
+ i := c.index
+ n := 1
+
+ // Find k good tokens looking backward
+ for n <= k {
+ // Skip off-channel tokens
+ i = c.previousTokenOnChannel(i-1, c.channel)
+ n++
+ }
+
+ if i < 0 {
+ return nil
+ }
+
+ return c.tokens[i]
+}
+
+func (c *CommonTokenStream) LT(k int) Token {
+ c.lazyInit()
+
+ if k == 0 {
+ return nil
+ }
+
+ if k < 0 {
+ return c.LB(-k)
+ }
+
+ i := c.index
+ n := 1 // We know tokens[n] is valid
+
+ // Find k good tokens
+ for n < k {
+ // Skip off-channel tokens, but make sure to not look past EOF
+ if c.Sync(i + 1) {
+ i = c.NextTokenOnChannel(i+1, c.channel)
+ }
+
+ n++
+ }
+
+ return c.tokens[i]
+}
+
+// getNumberOfOnChannelTokens counts EOF once.
+func (c *CommonTokenStream) getNumberOfOnChannelTokens() int {
+ var n int
+
+ c.Fill()
+
+ for i := 0; i < len(c.tokens); i++ {
+ t := c.tokens[i]
+
+ if t.GetChannel() == c.channel {
+ n++
+ }
+
+ if t.GetTokenType() == TokenEOF {
+ break
+ }
+ }
+
+ return n
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/comparators.go b/vendor/github.com/antlr4-go/antlr/v4/comparators.go
new file mode 100644
index 000000000000..7467e9b43db3
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/comparators.go
@@ -0,0 +1,150 @@
+package antlr
+
+// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
+// Use of this file is governed by the BSD 3-clause license that
+// can be found in the LICENSE.txt file in the project root.
+
+// This file contains all the implementations of custom comparators used for generic collections when the
+// Hash() and Equals() funcs supplied by the struct objects themselves need to be overridden. Normally, we would
+// put the comparators in the source file for the struct themselves, but given the organization of this code is
+// sorta kinda based upon the Java code, I found it confusing trying to find out which comparator was where and used by
+// which instantiation of a collection. For instance, an Array2DHashSet in the Java source, when used with ATNConfig
+// collections requires three different comparators depending on what the collection is being used for. Collecting - pun intended -
+// all the comparators here, makes it much easier to see which implementation of hash and equals is used by which collection.
+// It also makes it easy to verify that the Hash() and Equals() functions marry up with the Java implementations.
+
+// ObjEqComparator is the equivalent of the Java ObjectEqualityComparator, which is the default instance of
+// Equality comparator. We do not have inheritance in Go, only interfaces, so we use generics to enforce some
+// type safety and avoid having to implement this for every type that we want to perform comparison on.
+//
+// This comparator works by using the standard Hash() and Equals() methods of the type T that is being compared. Which
+// allows us to use it in any collection instance that does not require a special hash or equals implementation.
+type ObjEqComparator[T Collectable[T]] struct{}
+
+var (
+ aStateEqInst = &ObjEqComparator[ATNState]{}
+ aConfEqInst = &ObjEqComparator[*ATNConfig]{}
+
+ // aConfCompInst is the comparator used for the ATNConfigSet for the configLookup cache
+ aConfCompInst = &ATNConfigComparator[*ATNConfig]{}
+ atnConfCompInst = &BaseATNConfigComparator[*ATNConfig]{}
+ dfaStateEqInst = &ObjEqComparator[*DFAState]{}
+ semctxEqInst = &ObjEqComparator[SemanticContext]{}
+ atnAltCfgEqInst = &ATNAltConfigComparator[*ATNConfig]{}
+ pContextEqInst = &ObjEqComparator[*PredictionContext]{}
+)
+
+// Equals2 delegates to the Equals() method of type T
+func (c *ObjEqComparator[T]) Equals2(o1, o2 T) bool {
+ return o1.Equals(o2)
+}
+
+// Hash1 delegates to the Hash() method of type T
+func (c *ObjEqComparator[T]) Hash1(o T) int {
+
+ return o.Hash()
+}
+
+type SemCComparator[T Collectable[T]] struct{}
+
+// ATNConfigComparator is used as the comparator for the configLookup field of an ATNConfigSet
+// and has a custom Equals() and Hash() implementation, because equality is not based on the
+// standard Hash() and Equals() methods of the ATNConfig type.
+type ATNConfigComparator[T Collectable[T]] struct {
+}
+
+// Equals2 is a custom comparator for ATNConfigs specifically for configLookup
+func (c *ATNConfigComparator[T]) Equals2(o1, o2 *ATNConfig) bool {
+
+ // Same pointer, must be equal, even if both nil
+ //
+ if o1 == o2 {
+ return true
+
+ }
+
+ // If either are nil, but not both, then the result is false
+ //
+ if o1 == nil || o2 == nil {
+ return false
+ }
+
+ return o1.GetState().GetStateNumber() == o2.GetState().GetStateNumber() &&
+ o1.GetAlt() == o2.GetAlt() &&
+ o1.GetSemanticContext().Equals(o2.GetSemanticContext())
+}
+
+// Hash1 is custom hash implementation for ATNConfigs specifically for configLookup
+func (c *ATNConfigComparator[T]) Hash1(o *ATNConfig) int {
+
+ hash := 7
+ hash = 31*hash + o.GetState().GetStateNumber()
+ hash = 31*hash + o.GetAlt()
+ hash = 31*hash + o.GetSemanticContext().Hash()
+ return hash
+}
+
+// ATNAltConfigComparator is used as the comparator for mapping configs to Alt Bitsets
+type ATNAltConfigComparator[T Collectable[T]] struct {
+}
+
+// Equals2 is a custom comparator for ATNConfigs specifically for configLookup
+func (c *ATNAltConfigComparator[T]) Equals2(o1, o2 *ATNConfig) bool {
+
+ // Same pointer, must be equal, even if both nil
+ //
+ if o1 == o2 {
+ return true
+
+ }
+
+ // If either are nil, but not both, then the result is false
+ //
+ if o1 == nil || o2 == nil {
+ return false
+ }
+
+ return o1.GetState().GetStateNumber() == o2.GetState().GetStateNumber() &&
+ o1.GetContext().Equals(o2.GetContext())
+}
+
+// Hash1 is custom hash implementation for ATNConfigs specifically for configLookup
+func (c *ATNAltConfigComparator[T]) Hash1(o *ATNConfig) int {
+ h := murmurInit(7)
+ h = murmurUpdate(h, o.GetState().GetStateNumber())
+ h = murmurUpdate(h, o.GetContext().Hash())
+ return murmurFinish(h, 2)
+}
+
+// BaseATNConfigComparator is used as the comparator for the configLookup field of a ATNConfigSet
+// and has a custom Equals() and Hash() implementation, because equality is not based on the
+// standard Hash() and Equals() methods of the ATNConfig type.
+type BaseATNConfigComparator[T Collectable[T]] struct {
+}
+
+// Equals2 is a custom comparator for ATNConfigs specifically for baseATNConfigSet
+func (c *BaseATNConfigComparator[T]) Equals2(o1, o2 *ATNConfig) bool {
+
+ // Same pointer, must be equal, even if both nil
+ //
+ if o1 == o2 {
+ return true
+
+ }
+
+ // If either are nil, but not both, then the result is false
+ //
+ if o1 == nil || o2 == nil {
+ return false
+ }
+
+ return o1.GetState().GetStateNumber() == o2.GetState().GetStateNumber() &&
+ o1.GetAlt() == o2.GetAlt() &&
+ o1.GetSemanticContext().Equals(o2.GetSemanticContext())
+}
+
+// Hash1 is custom hash implementation for ATNConfigs specifically for configLookup, but in fact just
+// delegates to the standard Hash() method of the ATNConfig type.
+func (c *BaseATNConfigComparator[T]) Hash1(o *ATNConfig) int {
+ return o.Hash()
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/configuration.go b/vendor/github.com/antlr4-go/antlr/v4/configuration.go
new file mode 100644
index 000000000000..c2b724514d4e
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/configuration.go
@@ -0,0 +1,214 @@
+package antlr
+
+type runtimeConfiguration struct {
+ statsTraceStacks bool
+ lexerATNSimulatorDebug bool
+ lexerATNSimulatorDFADebug bool
+ parserATNSimulatorDebug bool
+ parserATNSimulatorTraceATNSim bool
+ parserATNSimulatorDFADebug bool
+ parserATNSimulatorRetryDebug bool
+ lRLoopEntryBranchOpt bool
+ memoryManager bool
+}
+
+// Global runtime configuration
+var runtimeConfig = runtimeConfiguration{
+ lRLoopEntryBranchOpt: true,
+}
+
+type runtimeOption func(*runtimeConfiguration) error
+
+// ConfigureRuntime allows the runtime to be configured globally setting things like trace and statistics options.
+// It uses the functional options pattern for go. This is a package global function as it operates on the runtime
+// configuration regardless of the instantiation of anything higher up such as a parser or lexer. Generally this is
+// used for debugging/tracing/statistics options, which are usually used by the runtime maintainers (or rather the
+// only maintainer). However, it is possible that you might want to use this to set a global option concerning the
+// memory allocation type used by the runtime such as sync.Pool or not.
+//
+// The options are applied in the order they are passed in, so the last option will override any previous options.
+//
+// For example, if you want to turn on the collection create point stack flag to true, you can do:
+//
+// antlr.ConfigureRuntime(antlr.WithStatsTraceStacks(true))
+//
+// If you want to turn it off, you can do:
+//
+// antlr.ConfigureRuntime(antlr.WithStatsTraceStacks(false))
+func ConfigureRuntime(options ...runtimeOption) error {
+ for _, option := range options {
+ err := option(&runtimeConfig)
+ if err != nil {
+ return err
+ }
+ }
+ return nil
+}
+
+// WithStatsTraceStacks sets the global flag indicating whether to collect stack traces at the create-point of
+// certain structs, such as collections, or the use point of certain methods such as Put().
+// Because this can be expensive, it is turned off by default. However, it
+// can be useful to track down exactly where memory is being created and used.
+//
+// Use:
+//
+// antlr.ConfigureRuntime(antlr.WithStatsTraceStacks(true))
+//
+// You can turn it off at any time using:
+//
+// antlr.ConfigureRuntime(antlr.WithStatsTraceStacks(false))
+func WithStatsTraceStacks(trace bool) runtimeOption {
+ return func(config *runtimeConfiguration) error {
+ config.statsTraceStacks = trace
+ return nil
+ }
+}
+
+// WithLexerATNSimulatorDebug sets the global flag indicating whether to log debug information from the lexer [ATN]
+// simulator. This is useful for debugging lexer issues by comparing the output with the Java runtime. Only useful
+// to the runtime maintainers.
+//
+// Use:
+//
+// antlr.ConfigureRuntime(antlr.WithLexerATNSimulatorDebug(true))
+//
+// You can turn it off at any time using:
+//
+// antlr.ConfigureRuntime(antlr.WithLexerATNSimulatorDebug(false))
+func WithLexerATNSimulatorDebug(debug bool) runtimeOption {
+ return func(config *runtimeConfiguration) error {
+ config.lexerATNSimulatorDebug = debug
+ return nil
+ }
+}
+
+// WithLexerATNSimulatorDFADebug sets the global flag indicating whether to log debug information from the lexer [ATN] [DFA]
+// simulator. This is useful for debugging lexer issues by comparing the output with the Java runtime. Only useful
+// to the runtime maintainers.
+//
+// Use:
+//
+// antlr.ConfigureRuntime(antlr.WithLexerATNSimulatorDFADebug(true))
+//
+// You can turn it off at any time using:
+//
+// antlr.ConfigureRuntime(antlr.WithLexerATNSimulatorDFADebug(false))
+func WithLexerATNSimulatorDFADebug(debug bool) runtimeOption {
+ return func(config *runtimeConfiguration) error {
+ config.lexerATNSimulatorDFADebug = debug
+ return nil
+ }
+}
+
+// WithParserATNSimulatorDebug sets the global flag indicating whether to log debug information from the parser [ATN]
+// simulator. This is useful for debugging parser issues by comparing the output with the Java runtime. Only useful
+// to the runtime maintainers.
+//
+// Use:
+//
+// antlr.ConfigureRuntime(antlr.WithParserATNSimulatorDebug(true))
+//
+// You can turn it off at any time using:
+//
+// antlr.ConfigureRuntime(antlr.WithParserATNSimulatorDebug(false))
+func WithParserATNSimulatorDebug(debug bool) runtimeOption {
+ return func(config *runtimeConfiguration) error {
+ config.parserATNSimulatorDebug = debug
+ return nil
+ }
+}
+
+// WithParserATNSimulatorTraceATNSim sets the global flag indicating whether to log trace information from the parser [ATN] simulator
+// [DFA]. This is useful for debugging parser issues by comparing the output with the Java runtime. Only useful
+// to the runtime maintainers.
+//
+// Use:
+//
+// antlr.ConfigureRuntime(antlr.WithParserATNSimulatorTraceATNSim(true))
+//
+// You can turn it off at any time using:
+//
+// antlr.ConfigureRuntime(antlr.WithParserATNSimulatorTraceATNSim(false))
+func WithParserATNSimulatorTraceATNSim(trace bool) runtimeOption {
+ return func(config *runtimeConfiguration) error {
+ config.parserATNSimulatorTraceATNSim = trace
+ return nil
+ }
+}
+
+// WithParserATNSimulatorDFADebug sets the global flag indicating whether to log debug information from the parser [ATN] [DFA]
+// simulator. This is useful for debugging parser issues by comparing the output with the Java runtime. Only useful
+// to the runtime maintainers.
+//
+// Use:
+//
+// antlr.ConfigureRuntime(antlr.WithParserATNSimulatorDFADebug(true))
+//
+// You can turn it off at any time using:
+//
+// antlr.ConfigureRuntime(antlr.WithParserATNSimulatorDFADebug(false))
+func WithParserATNSimulatorDFADebug(debug bool) runtimeOption {
+ return func(config *runtimeConfiguration) error {
+ config.parserATNSimulatorDFADebug = debug
+ return nil
+ }
+}
+
+// WithParserATNSimulatorRetryDebug sets the global flag indicating whether to log debug information from the parser [ATN] [DFA]
+// simulator when retrying a decision. This is useful for debugging parser issues by comparing the output with the Java runtime.
+// Only useful to the runtime maintainers.
+//
+// Use:
+//
+// antlr.ConfigureRuntime(antlr.WithParserATNSimulatorRetryDebug(true))
+//
+// You can turn it off at any time using:
+//
+// antlr.ConfigureRuntime(antlr.WithParserATNSimulatorRetryDebug(false))
+func WithParserATNSimulatorRetryDebug(debug bool) runtimeOption {
+ return func(config *runtimeConfiguration) error {
+ config.parserATNSimulatorRetryDebug = debug
+ return nil
+ }
+}
+
+// WithLRLoopEntryBranchOpt sets the global flag indicating whether let recursive loop operations should be
+// optimized or not. This is useful for debugging parser issues by comparing the output with the Java runtime.
+// It turns off the functionality of [canDropLoopEntryEdgeInLeftRecursiveRule] in [ParserATNSimulator].
+//
+// Note that default is to use this optimization.
+//
+// Use:
+//
+// antlr.ConfigureRuntime(antlr.WithLRLoopEntryBranchOpt(true))
+//
+// You can turn it off at any time using:
+//
+// antlr.ConfigureRuntime(antlr.WithLRLoopEntryBranchOpt(false))
+func WithLRLoopEntryBranchOpt(off bool) runtimeOption {
+ return func(config *runtimeConfiguration) error {
+ config.lRLoopEntryBranchOpt = off
+ return nil
+ }
+}
+
+// WithMemoryManager sets the global flag indicating whether to use the memory manager or not. This is useful
+// for poorly constructed grammars that create a lot of garbage. It turns on the functionality of [memoryManager], which
+// will intercept garbage collection and cause available memory to be reused. At the end of the day, this is no substitute
+// for fixing your grammar by ridding yourself of extreme ambiguity. BUt if you are just trying to reuse an opensource
+// grammar, this may help make it more practical.
+//
+// Note that default is to use normal Go memory allocation and not pool memory.
+//
+// Use:
+//
+// antlr.ConfigureRuntime(antlr.WithMemoryManager(true))
+//
+// Note that if you turn this on, you should probably leave it on. You should use only one memory strategy or the other
+// and should remember to nil out any references to the parser or lexer when you are done with them.
+func WithMemoryManager(use bool) runtimeOption {
+ return func(config *runtimeConfiguration) error {
+ config.memoryManager = use
+ return nil
+ }
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/dfa.go b/vendor/github.com/antlr4-go/antlr/v4/dfa.go
new file mode 100644
index 000000000000..6b63eb1589b2
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/dfa.go
@@ -0,0 +1,175 @@
+// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
+// Use of this file is governed by the BSD 3-clause license that
+// can be found in the LICENSE.txt file in the project root.
+
+package antlr
+
+// DFA represents the Deterministic Finite Automaton used by the recognizer, including all the states it can
+// reach and the transitions between them.
+type DFA struct {
+ // atnStartState is the ATN state in which this was created
+ atnStartState DecisionState
+
+ decision int
+
+ // states is all the DFA states. Use Map to get the old state back; Set can only
+ // indicate whether it is there. Go maps implement key hash collisions and so on and are very
+ // good, but the DFAState is an object and can't be used directly as the key as it can in say Java
+ // amd C#, whereby if the hashcode is the same for two objects, then Equals() is called against them
+ // to see if they really are the same object. Hence, we have our own map storage.
+ //
+ states *JStore[*DFAState, *ObjEqComparator[*DFAState]]
+
+ numstates int
+
+ s0 *DFAState
+
+ // precedenceDfa is the backing field for isPrecedenceDfa and setPrecedenceDfa.
+ // True if the DFA is for a precedence decision and false otherwise.
+ precedenceDfa bool
+}
+
+func NewDFA(atnStartState DecisionState, decision int) *DFA {
+ dfa := &DFA{
+ atnStartState: atnStartState,
+ decision: decision,
+ states: nil, // Lazy initialize
+ }
+ if s, ok := atnStartState.(*StarLoopEntryState); ok && s.precedenceRuleDecision {
+ dfa.precedenceDfa = true
+ dfa.s0 = NewDFAState(-1, NewATNConfigSet(false))
+ dfa.s0.isAcceptState = false
+ dfa.s0.requiresFullContext = false
+ }
+ return dfa
+}
+
+// getPrecedenceStartState gets the start state for the current precedence and
+// returns the start state corresponding to the specified precedence if a start
+// state exists for the specified precedence and nil otherwise. d must be a
+// precedence DFA. See also isPrecedenceDfa.
+func (d *DFA) getPrecedenceStartState(precedence int) *DFAState {
+ if !d.getPrecedenceDfa() {
+ panic("only precedence DFAs may contain a precedence start state")
+ }
+
+ // s0.edges is never nil for a precedence DFA
+ if precedence < 0 || precedence >= len(d.getS0().getEdges()) {
+ return nil
+ }
+
+ return d.getS0().getIthEdge(precedence)
+}
+
+// setPrecedenceStartState sets the start state for the current precedence. d
+// must be a precedence DFA. See also isPrecedenceDfa.
+func (d *DFA) setPrecedenceStartState(precedence int, startState *DFAState) {
+ if !d.getPrecedenceDfa() {
+ panic("only precedence DFAs may contain a precedence start state")
+ }
+
+ if precedence < 0 {
+ return
+ }
+
+ // Synchronization on s0 here is ok. When the DFA is turned into a
+ // precedence DFA, s0 will be initialized once and not updated again. s0.edges
+ // is never nil for a precedence DFA.
+ s0 := d.getS0()
+ if precedence >= s0.numEdges() {
+ edges := append(s0.getEdges(), make([]*DFAState, precedence+1-s0.numEdges())...)
+ s0.setEdges(edges)
+ d.setS0(s0)
+ }
+
+ s0.setIthEdge(precedence, startState)
+}
+
+func (d *DFA) getPrecedenceDfa() bool {
+ return d.precedenceDfa
+}
+
+// setPrecedenceDfa sets whether d is a precedence DFA. If precedenceDfa differs
+// from the current DFA configuration, then d.states is cleared, the initial
+// state s0 is set to a new DFAState with an empty outgoing DFAState.edges to
+// store the start states for individual precedence values if precedenceDfa is
+// true or nil otherwise, and d.precedenceDfa is updated.
+func (d *DFA) setPrecedenceDfa(precedenceDfa bool) {
+ if d.getPrecedenceDfa() != precedenceDfa {
+ d.states = nil // Lazy initialize
+ d.numstates = 0
+
+ if precedenceDfa {
+ precedenceState := NewDFAState(-1, NewATNConfigSet(false))
+ precedenceState.setEdges(make([]*DFAState, 0))
+ precedenceState.isAcceptState = false
+ precedenceState.requiresFullContext = false
+ d.setS0(precedenceState)
+ } else {
+ d.setS0(nil)
+ }
+
+ d.precedenceDfa = precedenceDfa
+ }
+}
+
+// Len returns the number of states in d. We use this instead of accessing states directly so that we can implement lazy
+// instantiation of the states JMap.
+func (d *DFA) Len() int {
+ if d.states == nil {
+ return 0
+ }
+ return d.states.Len()
+}
+
+// Get returns a state that matches s if it is present in the DFA state set. We defer to this
+// function instead of accessing states directly so that we can implement lazy instantiation of the states JMap.
+func (d *DFA) Get(s *DFAState) (*DFAState, bool) {
+ if d.states == nil {
+ return nil, false
+ }
+ return d.states.Get(s)
+}
+
+func (d *DFA) Put(s *DFAState) (*DFAState, bool) {
+ if d.states == nil {
+ d.states = NewJStore[*DFAState, *ObjEqComparator[*DFAState]](dfaStateEqInst, DFAStateCollection, "DFA via DFA.Put")
+ }
+ return d.states.Put(s)
+}
+
+func (d *DFA) getS0() *DFAState {
+ return d.s0
+}
+
+func (d *DFA) setS0(s *DFAState) {
+ d.s0 = s
+}
+
+// sortedStates returns the states in d sorted by their state number, or an empty set if d.states is nil.
+func (d *DFA) sortedStates() []*DFAState {
+ if d.states == nil {
+ return []*DFAState{}
+ }
+ vs := d.states.SortedSlice(func(i, j *DFAState) bool {
+ return i.stateNumber < j.stateNumber
+ })
+
+ return vs
+}
+
+func (d *DFA) String(literalNames []string, symbolicNames []string) string {
+ if d.getS0() == nil {
+ return ""
+ }
+
+ return NewDFASerializer(d, literalNames, symbolicNames).String()
+}
+
+func (d *DFA) ToLexerString() string {
+ if d.getS0() == nil {
+ return ""
+ }
+
+ return NewLexerDFASerializer(d).String()
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/dfa_serializer.go b/vendor/github.com/antlr4-go/antlr/v4/dfa_serializer.go
new file mode 100644
index 000000000000..0e11009899c9
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/dfa_serializer.go
@@ -0,0 +1,158 @@
+// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
+// Use of this file is governed by the BSD 3-clause license that
+// can be found in the LICENSE.txt file in the project root.
+
+package antlr
+
+import (
+ "fmt"
+ "strconv"
+ "strings"
+)
+
+// DFASerializer is a DFA walker that knows how to dump the DFA states to serialized
+// strings.
+type DFASerializer struct {
+ dfa *DFA
+ literalNames []string
+ symbolicNames []string
+}
+
+func NewDFASerializer(dfa *DFA, literalNames, symbolicNames []string) *DFASerializer {
+ if literalNames == nil {
+ literalNames = make([]string, 0)
+ }
+
+ if symbolicNames == nil {
+ symbolicNames = make([]string, 0)
+ }
+
+ return &DFASerializer{
+ dfa: dfa,
+ literalNames: literalNames,
+ symbolicNames: symbolicNames,
+ }
+}
+
+func (d *DFASerializer) String() string {
+ if d.dfa.getS0() == nil {
+ return ""
+ }
+
+ buf := ""
+ states := d.dfa.sortedStates()
+
+ for _, s := range states {
+ if s.edges != nil {
+ n := len(s.edges)
+
+ for j := 0; j < n; j++ {
+ t := s.edges[j]
+
+ if t != nil && t.stateNumber != 0x7FFFFFFF {
+ buf += d.GetStateString(s)
+ buf += "-"
+ buf += d.getEdgeLabel(j)
+ buf += "->"
+ buf += d.GetStateString(t)
+ buf += "\n"
+ }
+ }
+ }
+ }
+
+ if len(buf) == 0 {
+ return ""
+ }
+
+ return buf
+}
+
+func (d *DFASerializer) getEdgeLabel(i int) string {
+ if i == 0 {
+ return "EOF"
+ } else if d.literalNames != nil && i-1 < len(d.literalNames) {
+ return d.literalNames[i-1]
+ } else if d.symbolicNames != nil && i-1 < len(d.symbolicNames) {
+ return d.symbolicNames[i-1]
+ }
+
+ return strconv.Itoa(i - 1)
+}
+
+func (d *DFASerializer) GetStateString(s *DFAState) string {
+ var a, b string
+
+ if s.isAcceptState {
+ a = ":"
+ }
+
+ if s.requiresFullContext {
+ b = "^"
+ }
+
+ baseStateStr := a + "s" + strconv.Itoa(s.stateNumber) + b
+
+ if s.isAcceptState {
+ if s.predicates != nil {
+ return baseStateStr + "=>" + fmt.Sprint(s.predicates)
+ }
+
+ return baseStateStr + "=>" + fmt.Sprint(s.prediction)
+ }
+
+ return baseStateStr
+}
+
+type LexerDFASerializer struct {
+ *DFASerializer
+}
+
+func NewLexerDFASerializer(dfa *DFA) *LexerDFASerializer {
+ return &LexerDFASerializer{DFASerializer: NewDFASerializer(dfa, nil, nil)}
+}
+
+func (l *LexerDFASerializer) getEdgeLabel(i int) string {
+ var sb strings.Builder
+ sb.Grow(6)
+ sb.WriteByte('\'')
+ sb.WriteRune(rune(i))
+ sb.WriteByte('\'')
+ return sb.String()
+}
+
+func (l *LexerDFASerializer) String() string {
+ if l.dfa.getS0() == nil {
+ return ""
+ }
+
+ buf := ""
+ states := l.dfa.sortedStates()
+
+ for i := 0; i < len(states); i++ {
+ s := states[i]
+
+ if s.edges != nil {
+ n := len(s.edges)
+
+ for j := 0; j < n; j++ {
+ t := s.edges[j]
+
+ if t != nil && t.stateNumber != 0x7FFFFFFF {
+ buf += l.GetStateString(s)
+ buf += "-"
+ buf += l.getEdgeLabel(j)
+ buf += "->"
+ buf += l.GetStateString(t)
+ buf += "\n"
+ }
+ }
+ }
+ }
+
+ if len(buf) == 0 {
+ return ""
+ }
+
+ return buf
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/dfa_state.go b/vendor/github.com/antlr4-go/antlr/v4/dfa_state.go
new file mode 100644
index 000000000000..6541430745ff
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/dfa_state.go
@@ -0,0 +1,170 @@
+// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
+// Use of this file is governed by the BSD 3-clause license that
+// can be found in the LICENSE.txt file in the project root.
+
+package antlr
+
+import (
+ "fmt"
+)
+
+// PredPrediction maps a predicate to a predicted alternative.
+type PredPrediction struct {
+ alt int
+ pred SemanticContext
+}
+
+func NewPredPrediction(pred SemanticContext, alt int) *PredPrediction {
+ return &PredPrediction{alt: alt, pred: pred}
+}
+
+func (p *PredPrediction) String() string {
+ return "(" + fmt.Sprint(p.pred) + ", " + fmt.Sprint(p.alt) + ")"
+}
+
+// DFAState represents a set of possible [ATN] configurations. As Aho, Sethi,
+// Ullman p. 117 says: "The DFA uses its state to keep track of all possible
+// states the ATN can be in after reading each input symbol. That is to say,
+// after reading input a1, a2,..an, the DFA is in a state that represents the
+// subset T of the states of the ATN that are reachable from the ATN's start
+// state along some path labeled a1a2..an."
+//
+// In conventional NFA-to-DFA conversion, therefore, the subset T would be a bitset representing the set of
+// states the [ATN] could be in. We need to track the alt predicted by each state
+// as well, however. More importantly, we need to maintain a stack of states,
+// tracking the closure operations as they jump from rule to rule, emulating
+// rule invocations (method calls). I have to add a stack to simulate the proper
+// lookahead sequences for the underlying LL grammar from which the ATN was
+// derived.
+//
+// I use a set of [ATNConfig] objects, not simple states. An [ATNConfig] is both a
+// state (ala normal conversion) and a [RuleContext] describing the chain of rules
+// (if any) followed to arrive at that state.
+//
+// A [DFAState] may have multiple references to a particular state, but with
+// different [ATN] contexts (with same or different alts) meaning that state was
+// reached via a different set of rule invocations.
+type DFAState struct {
+ stateNumber int
+ configs *ATNConfigSet
+
+ // edges elements point to the target of the symbol. Shift up by 1 so (-1)
+ // Token.EOF maps to the first element.
+ edges []*DFAState
+
+ isAcceptState bool
+
+ // prediction is the 'ttype' we match or alt we predict if the state is 'accept'.
+ // Set to ATN.INVALID_ALT_NUMBER when predicates != nil or
+ // requiresFullContext.
+ prediction int
+
+ lexerActionExecutor *LexerActionExecutor
+
+ // requiresFullContext indicates it was created during an SLL prediction that
+ // discovered a conflict between the configurations in the state. Future
+ // ParserATNSimulator.execATN invocations immediately jump doing
+ // full context prediction if true.
+ requiresFullContext bool
+
+ // predicates is the predicates associated with the ATN configurations of the
+ // DFA state during SLL parsing. When we have predicates, requiresFullContext
+ // is false, since full context prediction evaluates predicates on-the-fly. If
+ // d is
+ // not nil, then prediction is ATN.INVALID_ALT_NUMBER.
+ //
+ // We only use these for non-requiresFullContext but conflicting states. That
+ // means we know from the context (it's $ or we don't dip into outer context)
+ // that it's an ambiguity not a conflict.
+ //
+ // This list is computed by
+ // ParserATNSimulator.predicateDFAState.
+ predicates []*PredPrediction
+}
+
+func NewDFAState(stateNumber int, configs *ATNConfigSet) *DFAState {
+ if configs == nil {
+ configs = NewATNConfigSet(false)
+ }
+
+ return &DFAState{configs: configs, stateNumber: stateNumber}
+}
+
+// GetAltSet gets the set of all alts mentioned by all ATN configurations in d.
+func (d *DFAState) GetAltSet() []int {
+ var alts []int
+
+ if d.configs != nil {
+ for _, c := range d.configs.configs {
+ alts = append(alts, c.GetAlt())
+ }
+ }
+
+ if len(alts) == 0 {
+ return nil
+ }
+
+ return alts
+}
+
+func (d *DFAState) getEdges() []*DFAState {
+ return d.edges
+}
+
+func (d *DFAState) numEdges() int {
+ return len(d.edges)
+}
+
+func (d *DFAState) getIthEdge(i int) *DFAState {
+ return d.edges[i]
+}
+
+func (d *DFAState) setEdges(newEdges []*DFAState) {
+ d.edges = newEdges
+}
+
+func (d *DFAState) setIthEdge(i int, edge *DFAState) {
+ d.edges[i] = edge
+}
+
+func (d *DFAState) setPrediction(v int) {
+ d.prediction = v
+}
+
+func (d *DFAState) String() string {
+ var s string
+ if d.isAcceptState {
+ if d.predicates != nil {
+ s = "=>" + fmt.Sprint(d.predicates)
+ } else {
+ s = "=>" + fmt.Sprint(d.prediction)
+ }
+ }
+
+ return fmt.Sprintf("%d:%s%s", d.stateNumber, fmt.Sprint(d.configs), s)
+}
+
+func (d *DFAState) Hash() int {
+ h := murmurInit(7)
+ h = murmurUpdate(h, d.configs.Hash())
+ return murmurFinish(h, 1)
+}
+
+// Equals returns whether d equals other. Two DFAStates are equal if their ATN
+// configuration sets are the same. This method is used to see if a state
+// already exists.
+//
+// Because the number of alternatives and number of ATN configurations are
+// finite, there is a finite number of DFA states that can be processed. This is
+// necessary to show that the algorithm terminates.
+//
+// Cannot test the DFA state numbers here because in
+// ParserATNSimulator.addDFAState we need to know if any other state exists that
+// has d exact set of ATN configurations. The stateNumber is irrelevant.
+func (d *DFAState) Equals(o Collectable[*DFAState]) bool {
+ if d == o {
+ return true
+ }
+
+ return d.configs.Equals(o.(*DFAState).configs)
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/diagnostic_error_listener.go b/vendor/github.com/antlr4-go/antlr/v4/diagnostic_error_listener.go
new file mode 100644
index 000000000000..bd2cd8bc3a86
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/diagnostic_error_listener.go
@@ -0,0 +1,110 @@
+// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
+// Use of this file is governed by the BSD 3-clause license that
+// can be found in the LICENSE.txt file in the project root.
+
+package antlr
+
+import (
+ "strconv"
+)
+
+//
+// This implementation of {@link ANTLRErrorListener} can be used to identify
+// certain potential correctness and performance problems in grammars. "reports"
+// are made by calling {@link Parser//NotifyErrorListeners} with the appropriate
+// message.
+//
+//
+//
Ambiguities: These are cases where more than one path through the
+// grammar can Match the input.
+//
Weak context sensitivity: These are cases where full-context
+// prediction resolved an SLL conflict to a unique alternative which equaled the
+// minimum alternative of the SLL conflict.
+//
Strong (forced) context sensitivity: These are cases where the
+// full-context prediction resolved an SLL conflict to a unique alternative,
+// and the minimum alternative of the SLL conflict was found to not be
+// a truly viable alternative. Two-stage parsing cannot be used for inputs where
+// d situation occurs.
+//
+
+type DiagnosticErrorListener struct {
+ *DefaultErrorListener
+
+ exactOnly bool
+}
+
+//goland:noinspection GoUnusedExportedFunction
+func NewDiagnosticErrorListener(exactOnly bool) *DiagnosticErrorListener {
+
+ n := new(DiagnosticErrorListener)
+
+ // whether all ambiguities or only exact ambiguities are Reported.
+ n.exactOnly = exactOnly
+ return n
+}
+
+func (d *DiagnosticErrorListener) ReportAmbiguity(recognizer Parser, dfa *DFA, startIndex, stopIndex int, exact bool, ambigAlts *BitSet, configs *ATNConfigSet) {
+ if d.exactOnly && !exact {
+ return
+ }
+ msg := "reportAmbiguity d=" +
+ d.getDecisionDescription(recognizer, dfa) +
+ ": ambigAlts=" +
+ d.getConflictingAlts(ambigAlts, configs).String() +
+ ", input='" +
+ recognizer.GetTokenStream().GetTextFromInterval(NewInterval(startIndex, stopIndex)) + "'"
+ recognizer.NotifyErrorListeners(msg, nil, nil)
+}
+
+func (d *DiagnosticErrorListener) ReportAttemptingFullContext(recognizer Parser, dfa *DFA, startIndex, stopIndex int, _ *BitSet, _ *ATNConfigSet) {
+
+ msg := "reportAttemptingFullContext d=" +
+ d.getDecisionDescription(recognizer, dfa) +
+ ", input='" +
+ recognizer.GetTokenStream().GetTextFromInterval(NewInterval(startIndex, stopIndex)) + "'"
+ recognizer.NotifyErrorListeners(msg, nil, nil)
+}
+
+func (d *DiagnosticErrorListener) ReportContextSensitivity(recognizer Parser, dfa *DFA, startIndex, stopIndex, _ int, _ *ATNConfigSet) {
+ msg := "reportContextSensitivity d=" +
+ d.getDecisionDescription(recognizer, dfa) +
+ ", input='" +
+ recognizer.GetTokenStream().GetTextFromInterval(NewInterval(startIndex, stopIndex)) + "'"
+ recognizer.NotifyErrorListeners(msg, nil, nil)
+}
+
+func (d *DiagnosticErrorListener) getDecisionDescription(recognizer Parser, dfa *DFA) string {
+ decision := dfa.decision
+ ruleIndex := dfa.atnStartState.GetRuleIndex()
+
+ ruleNames := recognizer.GetRuleNames()
+ if ruleIndex < 0 || ruleIndex >= len(ruleNames) {
+ return strconv.Itoa(decision)
+ }
+ ruleName := ruleNames[ruleIndex]
+ if ruleName == "" {
+ return strconv.Itoa(decision)
+ }
+ return strconv.Itoa(decision) + " (" + ruleName + ")"
+}
+
+// Computes the set of conflicting or ambiguous alternatives from a
+// configuration set, if that information was not already provided by the
+// parser.
+//
+// @param ReportedAlts The set of conflicting or ambiguous alternatives, as
+// Reported by the parser.
+// @param configs The conflicting or ambiguous configuration set.
+// @return Returns {@code ReportedAlts} if it is not {@code nil}, otherwise
+// returns the set of alternatives represented in {@code configs}.
+func (d *DiagnosticErrorListener) getConflictingAlts(ReportedAlts *BitSet, set *ATNConfigSet) *BitSet {
+ if ReportedAlts != nil {
+ return ReportedAlts
+ }
+ result := NewBitSet()
+ for _, c := range set.configs {
+ result.add(c.GetAlt())
+ }
+
+ return result
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/error_listener.go b/vendor/github.com/antlr4-go/antlr/v4/error_listener.go
new file mode 100644
index 000000000000..21a0216434e2
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/error_listener.go
@@ -0,0 +1,100 @@
+// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
+// Use of this file is governed by the BSD 3-clause license that
+// can be found in the LICENSE.txt file in the project root.
+
+package antlr
+
+import (
+ "fmt"
+ "os"
+ "strconv"
+)
+
+// Provides an empty default implementation of {@link ANTLRErrorListener}. The
+// default implementation of each method does nothing, but can be overridden as
+// necessary.
+
+type ErrorListener interface {
+ SyntaxError(recognizer Recognizer, offendingSymbol interface{}, line, column int, msg string, e RecognitionException)
+ ReportAmbiguity(recognizer Parser, dfa *DFA, startIndex, stopIndex int, exact bool, ambigAlts *BitSet, configs *ATNConfigSet)
+ ReportAttemptingFullContext(recognizer Parser, dfa *DFA, startIndex, stopIndex int, conflictingAlts *BitSet, configs *ATNConfigSet)
+ ReportContextSensitivity(recognizer Parser, dfa *DFA, startIndex, stopIndex, prediction int, configs *ATNConfigSet)
+}
+
+type DefaultErrorListener struct {
+}
+
+//goland:noinspection GoUnusedExportedFunction
+func NewDefaultErrorListener() *DefaultErrorListener {
+ return new(DefaultErrorListener)
+}
+
+func (d *DefaultErrorListener) SyntaxError(_ Recognizer, _ interface{}, _, _ int, _ string, _ RecognitionException) {
+}
+
+func (d *DefaultErrorListener) ReportAmbiguity(_ Parser, _ *DFA, _, _ int, _ bool, _ *BitSet, _ *ATNConfigSet) {
+}
+
+func (d *DefaultErrorListener) ReportAttemptingFullContext(_ Parser, _ *DFA, _, _ int, _ *BitSet, _ *ATNConfigSet) {
+}
+
+func (d *DefaultErrorListener) ReportContextSensitivity(_ Parser, _ *DFA, _, _, _ int, _ *ATNConfigSet) {
+}
+
+type ConsoleErrorListener struct {
+ *DefaultErrorListener
+}
+
+func NewConsoleErrorListener() *ConsoleErrorListener {
+ return new(ConsoleErrorListener)
+}
+
+// ConsoleErrorListenerINSTANCE provides a default instance of {@link ConsoleErrorListener}.
+var ConsoleErrorListenerINSTANCE = NewConsoleErrorListener()
+
+// SyntaxError prints messages to System.err containing the
+// values of line, charPositionInLine, and msg using
+// the following format:
+//
+// line :
+func (c *ConsoleErrorListener) SyntaxError(_ Recognizer, _ interface{}, line, column int, msg string, _ RecognitionException) {
+ _, _ = fmt.Fprintln(os.Stderr, "line "+strconv.Itoa(line)+":"+strconv.Itoa(column)+" "+msg)
+}
+
+type ProxyErrorListener struct {
+ *DefaultErrorListener
+ delegates []ErrorListener
+}
+
+func NewProxyErrorListener(delegates []ErrorListener) *ProxyErrorListener {
+ if delegates == nil {
+ panic("delegates is not provided")
+ }
+ l := new(ProxyErrorListener)
+ l.delegates = delegates
+ return l
+}
+
+func (p *ProxyErrorListener) SyntaxError(recognizer Recognizer, offendingSymbol interface{}, line, column int, msg string, e RecognitionException) {
+ for _, d := range p.delegates {
+ d.SyntaxError(recognizer, offendingSymbol, line, column, msg, e)
+ }
+}
+
+func (p *ProxyErrorListener) ReportAmbiguity(recognizer Parser, dfa *DFA, startIndex, stopIndex int, exact bool, ambigAlts *BitSet, configs *ATNConfigSet) {
+ for _, d := range p.delegates {
+ d.ReportAmbiguity(recognizer, dfa, startIndex, stopIndex, exact, ambigAlts, configs)
+ }
+}
+
+func (p *ProxyErrorListener) ReportAttemptingFullContext(recognizer Parser, dfa *DFA, startIndex, stopIndex int, conflictingAlts *BitSet, configs *ATNConfigSet) {
+ for _, d := range p.delegates {
+ d.ReportAttemptingFullContext(recognizer, dfa, startIndex, stopIndex, conflictingAlts, configs)
+ }
+}
+
+func (p *ProxyErrorListener) ReportContextSensitivity(recognizer Parser, dfa *DFA, startIndex, stopIndex, prediction int, configs *ATNConfigSet) {
+ for _, d := range p.delegates {
+ d.ReportContextSensitivity(recognizer, dfa, startIndex, stopIndex, prediction, configs)
+ }
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/error_strategy.go b/vendor/github.com/antlr4-go/antlr/v4/error_strategy.go
new file mode 100644
index 000000000000..9db2be1c7485
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/error_strategy.go
@@ -0,0 +1,702 @@
+// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
+// Use of this file is governed by the BSD 3-clause license that
+// can be found in the LICENSE.txt file in the project root.
+
+package antlr
+
+import (
+ "fmt"
+ "reflect"
+ "strconv"
+ "strings"
+)
+
+type ErrorStrategy interface {
+ reset(Parser)
+ RecoverInline(Parser) Token
+ Recover(Parser, RecognitionException)
+ Sync(Parser)
+ InErrorRecoveryMode(Parser) bool
+ ReportError(Parser, RecognitionException)
+ ReportMatch(Parser)
+}
+
+// DefaultErrorStrategy is the default implementation of ANTLRErrorStrategy used for
+// error reporting and recovery in ANTLR parsers.
+type DefaultErrorStrategy struct {
+ errorRecoveryMode bool
+ lastErrorIndex int
+ lastErrorStates *IntervalSet
+}
+
+var _ ErrorStrategy = &DefaultErrorStrategy{}
+
+func NewDefaultErrorStrategy() *DefaultErrorStrategy {
+
+ d := new(DefaultErrorStrategy)
+
+ // Indicates whether the error strategy is currently "recovering from an
+ // error". This is used to suppress Reporting multiple error messages while
+ // attempting to recover from a detected syntax error.
+ //
+ // @see //InErrorRecoveryMode
+ //
+ d.errorRecoveryMode = false
+
+ // The index into the input stream where the last error occurred.
+ // This is used to prevent infinite loops where an error is found
+ // but no token is consumed during recovery...another error is found,
+ // ad nauseam. This is a failsafe mechanism to guarantee that at least
+ // one token/tree node is consumed for two errors.
+ //
+ d.lastErrorIndex = -1
+ d.lastErrorStates = nil
+ return d
+}
+
+//
The default implementation simply calls {@link //endErrorCondition} to
+// ensure that the handler is not in error recovery mode.
+func (d *DefaultErrorStrategy) reset(recognizer Parser) {
+ d.endErrorCondition(recognizer)
+}
+
+// This method is called to enter error recovery mode when a recognition
+// exception is Reported.
+func (d *DefaultErrorStrategy) beginErrorCondition(_ Parser) {
+ d.errorRecoveryMode = true
+}
+
+func (d *DefaultErrorStrategy) InErrorRecoveryMode(_ Parser) bool {
+ return d.errorRecoveryMode
+}
+
+// This method is called to leave error recovery mode after recovering from
+// a recognition exception.
+func (d *DefaultErrorStrategy) endErrorCondition(_ Parser) {
+ d.errorRecoveryMode = false
+ d.lastErrorStates = nil
+ d.lastErrorIndex = -1
+}
+
+// ReportMatch is the default implementation of error matching and simply calls endErrorCondition.
+func (d *DefaultErrorStrategy) ReportMatch(recognizer Parser) {
+ d.endErrorCondition(recognizer)
+}
+
+// ReportError is the default implementation of error reporting.
+// It returns immediately if the handler is already
+// in error recovery mode. Otherwise, it calls [beginErrorCondition]
+// and dispatches the Reporting task based on the runtime type of e
+// according to the following table.
+//
+// [NoViableAltException] : Dispatches the call to [ReportNoViableAlternative]
+// [InputMisMatchException] : Dispatches the call to [ReportInputMisMatch]
+// [FailedPredicateException] : Dispatches the call to [ReportFailedPredicate]
+// All other types : Calls [NotifyErrorListeners] to Report the exception
+func (d *DefaultErrorStrategy) ReportError(recognizer Parser, e RecognitionException) {
+ // if we've already Reported an error and have not Matched a token
+ // yet successfully, don't Report any errors.
+ if d.InErrorRecoveryMode(recognizer) {
+ return // don't Report spurious errors
+ }
+ d.beginErrorCondition(recognizer)
+
+ switch t := e.(type) {
+ default:
+ fmt.Println("unknown recognition error type: " + reflect.TypeOf(e).Name())
+ // fmt.Println(e.stack)
+ recognizer.NotifyErrorListeners(e.GetMessage(), e.GetOffendingToken(), e)
+ case *NoViableAltException:
+ d.ReportNoViableAlternative(recognizer, t)
+ case *InputMisMatchException:
+ d.ReportInputMisMatch(recognizer, t)
+ case *FailedPredicateException:
+ d.ReportFailedPredicate(recognizer, t)
+ }
+}
+
+// Recover is the default recovery implementation.
+// It reSynchronizes the parser by consuming tokens until we find one in the reSynchronization set -
+// loosely the set of tokens that can follow the current rule.
+func (d *DefaultErrorStrategy) Recover(recognizer Parser, _ RecognitionException) {
+
+ if d.lastErrorIndex == recognizer.GetInputStream().Index() &&
+ d.lastErrorStates != nil && d.lastErrorStates.contains(recognizer.GetState()) {
+ // uh oh, another error at same token index and previously-Visited
+ // state in ATN must be a case where LT(1) is in the recovery
+ // token set so nothing got consumed. Consume a single token
+ // at least to prevent an infinite loop d is a failsafe.
+ recognizer.Consume()
+ }
+ d.lastErrorIndex = recognizer.GetInputStream().Index()
+ if d.lastErrorStates == nil {
+ d.lastErrorStates = NewIntervalSet()
+ }
+ d.lastErrorStates.addOne(recognizer.GetState())
+ followSet := d.GetErrorRecoverySet(recognizer)
+ d.consumeUntil(recognizer, followSet)
+}
+
+// Sync is the default implementation of error strategy synchronization.
+//
+// This Sync makes sure that the current lookahead symbol is consistent with what were expecting
+// at this point in the [ATN]. You can call this anytime but ANTLR only
+// generates code to check before sub-rules/loops and each iteration.
+//
+// Implements [Jim Idle]'s magic Sync mechanism in closures and optional
+// sub-rules. E.g.:
+//
+// a : Sync ( stuff Sync )*
+// Sync : {consume to what can follow Sync}
+//
+// At the start of a sub-rule upon error, Sync performs single
+// token deletion, if possible. If it can't do that, it bails on the current
+// rule and uses the default error recovery, which consumes until the
+// reSynchronization set of the current rule.
+//
+// If the sub-rule is optional
+//
+// ({@code (...)?}, {@code (...)*},
+//
+// or a block with an empty alternative), then the expected set includes what follows
+// the sub-rule.
+//
+// During loop iteration, it consumes until it sees a token that can start a
+// sub-rule or what follows loop. Yes, that is pretty aggressive. We opt to
+// stay in the loop as long as possible.
+//
+// # Origins
+//
+// Previous versions of ANTLR did a poor job of their recovery within loops.
+// A single mismatch token or missing token would force the parser to bail
+// out of the entire rules surrounding the loop. So, for rule:
+//
+// classfunc : 'class' ID '{' member* '}'
+//
+// input with an extra token between members would force the parser to
+// consume until it found the next class definition rather than the next
+// member definition of the current class.
+//
+// This functionality cost a bit of effort because the parser has to
+// compare the token set at the start of the loop and at each iteration. If for
+// some reason speed is suffering for you, you can turn off this
+// functionality by simply overriding this method as empty:
+//
+// { }
+//
+// [Jim Idle]: https://github.com/jimidle
+func (d *DefaultErrorStrategy) Sync(recognizer Parser) {
+ // If already recovering, don't try to Sync
+ if d.InErrorRecoveryMode(recognizer) {
+ return
+ }
+
+ s := recognizer.GetInterpreter().atn.states[recognizer.GetState()]
+ la := recognizer.GetTokenStream().LA(1)
+
+ // try cheaper subset first might get lucky. seems to shave a wee bit off
+ nextTokens := recognizer.GetATN().NextTokens(s, nil)
+ if nextTokens.contains(TokenEpsilon) || nextTokens.contains(la) {
+ return
+ }
+
+ switch s.GetStateType() {
+ case ATNStateBlockStart, ATNStateStarBlockStart, ATNStatePlusBlockStart, ATNStateStarLoopEntry:
+ // Report error and recover if possible
+ if d.SingleTokenDeletion(recognizer) != nil {
+ return
+ }
+ recognizer.SetError(NewInputMisMatchException(recognizer))
+ case ATNStatePlusLoopBack, ATNStateStarLoopBack:
+ d.ReportUnwantedToken(recognizer)
+ expecting := NewIntervalSet()
+ expecting.addSet(recognizer.GetExpectedTokens())
+ whatFollowsLoopIterationOrRule := expecting.addSet(d.GetErrorRecoverySet(recognizer))
+ d.consumeUntil(recognizer, whatFollowsLoopIterationOrRule)
+ default:
+ // do nothing if we can't identify the exact kind of ATN state
+ }
+}
+
+// ReportNoViableAlternative is called by [ReportError] when the exception is a [NoViableAltException].
+//
+// See also [ReportError]
+func (d *DefaultErrorStrategy) ReportNoViableAlternative(recognizer Parser, e *NoViableAltException) {
+ tokens := recognizer.GetTokenStream()
+ var input string
+ if tokens != nil {
+ if e.startToken.GetTokenType() == TokenEOF {
+ input = ""
+ } else {
+ input = tokens.GetTextFromTokens(e.startToken, e.offendingToken)
+ }
+ } else {
+ input = ""
+ }
+ msg := "no viable alternative at input " + d.escapeWSAndQuote(input)
+ recognizer.NotifyErrorListeners(msg, e.offendingToken, e)
+}
+
+// ReportInputMisMatch is called by [ReportError] when the exception is an [InputMisMatchException]
+//
+// See also: [ReportError]
+func (d *DefaultErrorStrategy) ReportInputMisMatch(recognizer Parser, e *InputMisMatchException) {
+ msg := "mismatched input " + d.GetTokenErrorDisplay(e.offendingToken) +
+ " expecting " + e.getExpectedTokens().StringVerbose(recognizer.GetLiteralNames(), recognizer.GetSymbolicNames(), false)
+ recognizer.NotifyErrorListeners(msg, e.offendingToken, e)
+}
+
+// ReportFailedPredicate is called by [ReportError] when the exception is a [FailedPredicateException].
+//
+// See also: [ReportError]
+func (d *DefaultErrorStrategy) ReportFailedPredicate(recognizer Parser, e *FailedPredicateException) {
+ ruleName := recognizer.GetRuleNames()[recognizer.GetParserRuleContext().GetRuleIndex()]
+ msg := "rule " + ruleName + " " + e.message
+ recognizer.NotifyErrorListeners(msg, e.offendingToken, e)
+}
+
+// ReportUnwantedToken is called to report a syntax error that requires the removal
+// of a token from the input stream. At the time d method is called, the
+// erroneous symbol is the current LT(1) symbol and has not yet been
+// removed from the input stream. When this method returns,
+// recognizer is in error recovery mode.
+//
+// This method is called when singleTokenDeletion identifies
+// single-token deletion as a viable recovery strategy for a mismatched
+// input error.
+//
+// The default implementation simply returns if the handler is already in
+// error recovery mode. Otherwise, it calls beginErrorCondition to
+// enter error recovery mode, followed by calling
+// [NotifyErrorListeners]
+func (d *DefaultErrorStrategy) ReportUnwantedToken(recognizer Parser) {
+ if d.InErrorRecoveryMode(recognizer) {
+ return
+ }
+ d.beginErrorCondition(recognizer)
+ t := recognizer.GetCurrentToken()
+ tokenName := d.GetTokenErrorDisplay(t)
+ expecting := d.GetExpectedTokens(recognizer)
+ msg := "extraneous input " + tokenName + " expecting " +
+ expecting.StringVerbose(recognizer.GetLiteralNames(), recognizer.GetSymbolicNames(), false)
+ recognizer.NotifyErrorListeners(msg, t, nil)
+}
+
+// ReportMissingToken is called to report a syntax error which requires the
+// insertion of a missing token into the input stream. At the time this
+// method is called, the missing token has not yet been inserted. When this
+// method returns, recognizer is in error recovery mode.
+//
+// This method is called when singleTokenInsertion identifies
+// single-token insertion as a viable recovery strategy for a mismatched
+// input error.
+//
+// The default implementation simply returns if the handler is already in
+// error recovery mode. Otherwise, it calls beginErrorCondition to
+// enter error recovery mode, followed by calling [NotifyErrorListeners]
+func (d *DefaultErrorStrategy) ReportMissingToken(recognizer Parser) {
+ if d.InErrorRecoveryMode(recognizer) {
+ return
+ }
+ d.beginErrorCondition(recognizer)
+ t := recognizer.GetCurrentToken()
+ expecting := d.GetExpectedTokens(recognizer)
+ msg := "missing " + expecting.StringVerbose(recognizer.GetLiteralNames(), recognizer.GetSymbolicNames(), false) +
+ " at " + d.GetTokenErrorDisplay(t)
+ recognizer.NotifyErrorListeners(msg, t, nil)
+}
+
+// The RecoverInline default implementation attempts to recover from the mismatched input
+// by using single token insertion and deletion as described below. If the
+// recovery attempt fails, this method panics with [InputMisMatchException}.
+// TODO: Not sure that panic() is the right thing to do here - JI
+//
+// # EXTRA TOKEN (single token deletion)
+//
+// LA(1) is not what we are looking for. If LA(2) has the
+// right token, however, then assume LA(1) is some extra spurious
+// token and delete it. Then consume and return the next token (which was
+// the LA(2) token) as the successful result of the Match operation.
+//
+// # This recovery strategy is implemented by singleTokenDeletion
+//
+// # MISSING TOKEN (single token insertion)
+//
+// If current token -at LA(1) - is consistent with what could come
+// after the expected LA(1) token, then assume the token is missing
+// and use the parser's [TokenFactory] to create it on the fly. The
+// “insertion” is performed by returning the created token as the successful
+// result of the Match operation.
+//
+// This recovery strategy is implemented by [SingleTokenInsertion].
+//
+// # Example
+//
+// For example, Input i=(3 is clearly missing the ')'. When
+// the parser returns from the nested call to expr, it will have
+// call the chain:
+//
+// stat → expr → atom
+//
+// and it will be trying to Match the ')' at this point in the
+// derivation:
+//
+// : ID '=' '(' INT ')' ('+' atom)* ';'
+// ^
+//
+// The attempt to [Match] ')' will fail when it sees ';' and
+// call [RecoverInline]. To recover, it sees that LA(1)==';'
+// is in the set of tokens that can follow the ')' token reference
+// in rule atom. It can assume that you forgot the ')'.
+func (d *DefaultErrorStrategy) RecoverInline(recognizer Parser) Token {
+ // SINGLE TOKEN DELETION
+ MatchedSymbol := d.SingleTokenDeletion(recognizer)
+ if MatchedSymbol != nil {
+ // we have deleted the extra token.
+ // now, move past ttype token as if all were ok
+ recognizer.Consume()
+ return MatchedSymbol
+ }
+ // SINGLE TOKEN INSERTION
+ if d.SingleTokenInsertion(recognizer) {
+ return d.GetMissingSymbol(recognizer)
+ }
+ // even that didn't work must panic the exception
+ recognizer.SetError(NewInputMisMatchException(recognizer))
+ return nil
+}
+
+// SingleTokenInsertion implements the single-token insertion inline error recovery
+// strategy. It is called by [RecoverInline] if the single-token
+// deletion strategy fails to recover from the mismatched input. If this
+// method returns {@code true}, {@code recognizer} will be in error recovery
+// mode.
+//
+// This method determines whether single-token insertion is viable by
+// checking if the LA(1) input symbol could be successfully Matched
+// if it were instead the LA(2) symbol. If this method returns
+// {@code true}, the caller is responsible for creating and inserting a
+// token with the correct type to produce this behavior.
+//
+// This func returns true if single-token insertion is a viable recovery
+// strategy for the current mismatched input.
+func (d *DefaultErrorStrategy) SingleTokenInsertion(recognizer Parser) bool {
+ currentSymbolType := recognizer.GetTokenStream().LA(1)
+ // if current token is consistent with what could come after current
+ // ATN state, then we know we're missing a token error recovery
+ // is free to conjure up and insert the missing token
+ atn := recognizer.GetInterpreter().atn
+ currentState := atn.states[recognizer.GetState()]
+ next := currentState.GetTransitions()[0].getTarget()
+ expectingAtLL2 := atn.NextTokens(next, recognizer.GetParserRuleContext())
+ if expectingAtLL2.contains(currentSymbolType) {
+ d.ReportMissingToken(recognizer)
+ return true
+ }
+
+ return false
+}
+
+// SingleTokenDeletion implements the single-token deletion inline error recovery
+// strategy. It is called by [RecoverInline] to attempt to recover
+// from mismatched input. If this method returns nil, the parser and error
+// handler state will not have changed. If this method returns non-nil,
+// recognizer will not be in error recovery mode since the
+// returned token was a successful Match.
+//
+// If the single-token deletion is successful, this method calls
+// [ReportUnwantedToken] to Report the error, followed by
+// [Consume] to actually “delete” the extraneous token. Then,
+// before returning, [ReportMatch] is called to signal a successful
+// Match.
+//
+// The func returns the successfully Matched [Token] instance if single-token
+// deletion successfully recovers from the mismatched input, otherwise nil.
+func (d *DefaultErrorStrategy) SingleTokenDeletion(recognizer Parser) Token {
+ NextTokenType := recognizer.GetTokenStream().LA(2)
+ expecting := d.GetExpectedTokens(recognizer)
+ if expecting.contains(NextTokenType) {
+ d.ReportUnwantedToken(recognizer)
+ // print("recoverFromMisMatchedToken deleting " \
+ // + str(recognizer.GetTokenStream().LT(1)) \
+ // + " since " + str(recognizer.GetTokenStream().LT(2)) \
+ // + " is what we want", file=sys.stderr)
+ recognizer.Consume() // simply delete extra token
+ // we want to return the token we're actually Matching
+ MatchedSymbol := recognizer.GetCurrentToken()
+ d.ReportMatch(recognizer) // we know current token is correct
+ return MatchedSymbol
+ }
+
+ return nil
+}
+
+// GetMissingSymbol conjures up a missing token during error recovery.
+//
+// The recognizer attempts to recover from single missing
+// symbols. But, actions might refer to that missing symbol.
+// For example:
+//
+// x=ID {f($x)}.
+//
+// The action clearly assumes
+// that there has been an identifier Matched previously and that
+// $x points at that token. If that token is missing, but
+// the next token in the stream is what we want we assume that
+// this token is missing, and we keep going. Because we
+// have to return some token to replace the missing token,
+// we have to conjure one up. This method gives the user control
+// over the tokens returned for missing tokens. Mostly,
+// you will want to create something special for identifier
+// tokens. For literals such as '{' and ',', the default
+// action in the parser or tree parser works. It simply creates
+// a [CommonToken] of the appropriate type. The text will be the token name.
+// If you need to change which tokens must be created by the lexer,
+// override this method to create the appropriate tokens.
+func (d *DefaultErrorStrategy) GetMissingSymbol(recognizer Parser) Token {
+ currentSymbol := recognizer.GetCurrentToken()
+ expecting := d.GetExpectedTokens(recognizer)
+ expectedTokenType := expecting.first()
+ var tokenText string
+
+ if expectedTokenType == TokenEOF {
+ tokenText = ""
+ } else {
+ ln := recognizer.GetLiteralNames()
+ if expectedTokenType > 0 && expectedTokenType < len(ln) {
+ tokenText = ""
+ } else {
+ tokenText = "" // TODO: matches the JS impl
+ }
+ }
+ current := currentSymbol
+ lookback := recognizer.GetTokenStream().LT(-1)
+ if current.GetTokenType() == TokenEOF && lookback != nil {
+ current = lookback
+ }
+
+ tf := recognizer.GetTokenFactory()
+
+ return tf.Create(current.GetSource(), expectedTokenType, tokenText, TokenDefaultChannel, -1, -1, current.GetLine(), current.GetColumn())
+}
+
+func (d *DefaultErrorStrategy) GetExpectedTokens(recognizer Parser) *IntervalSet {
+ return recognizer.GetExpectedTokens()
+}
+
+// GetTokenErrorDisplay determines how a token should be displayed in an error message.
+// The default is to display just the text, but during development you might
+// want to have a lot of information spit out. Override this func in that case
+// to use t.String() (which, for [CommonToken], dumps everything about
+// the token). This is better than forcing you to override a method in
+// your token objects because you don't have to go modify your lexer
+// so that it creates a new type.
+func (d *DefaultErrorStrategy) GetTokenErrorDisplay(t Token) string {
+ if t == nil {
+ return ""
+ }
+ s := t.GetText()
+ if s == "" {
+ if t.GetTokenType() == TokenEOF {
+ s = ""
+ } else {
+ s = "<" + strconv.Itoa(t.GetTokenType()) + ">"
+ }
+ }
+ return d.escapeWSAndQuote(s)
+}
+
+func (d *DefaultErrorStrategy) escapeWSAndQuote(s string) string {
+ s = strings.Replace(s, "\t", "\\t", -1)
+ s = strings.Replace(s, "\n", "\\n", -1)
+ s = strings.Replace(s, "\r", "\\r", -1)
+ return "'" + s + "'"
+}
+
+// GetErrorRecoverySet computes the error recovery set for the current rule. During
+// rule invocation, the parser pushes the set of tokens that can
+// follow that rule reference on the stack. This amounts to
+// computing FIRST of what follows the rule reference in the
+// enclosing rule. See LinearApproximator.FIRST().
+//
+// This local follow set only includes tokens
+// from within the rule i.e., the FIRST computation done by
+// ANTLR stops at the end of a rule.
+//
+// # Example
+//
+// When you find a "no viable alt exception", the input is not
+// consistent with any of the alternatives for rule r. The best
+// thing to do is to consume tokens until you see something that
+// can legally follow a call to r or any rule that called r.
+// You don't want the exact set of viable next tokens because the
+// input might just be missing a token--you might consume the
+// rest of the input looking for one of the missing tokens.
+//
+// Consider the grammar:
+//
+// a : '[' b ']'
+// | '(' b ')'
+// ;
+//
+// b : c '^' INT
+// ;
+//
+// c : ID
+// | INT
+// ;
+//
+// At each rule invocation, the set of tokens that could follow
+// that rule is pushed on a stack. Here are the various
+// context-sensitive follow sets:
+//
+// FOLLOW(b1_in_a) = FIRST(']') = ']'
+// FOLLOW(b2_in_a) = FIRST(')') = ')'
+// FOLLOW(c_in_b) = FIRST('^') = '^'
+//
+// Upon erroneous input “[]”, the call chain is
+//
+// a → b → c
+//
+// and, hence, the follow context stack is:
+//
+// Depth Follow set Start of rule execution
+// 0 a (from main())
+// 1 ']' b
+// 2 '^' c
+//
+// Notice that ')' is not included, because b would have to have
+// been called from a different context in rule a for ')' to be
+// included.
+//
+// For error recovery, we cannot consider FOLLOW(c)
+// (context-sensitive or otherwise). We need the combined set of
+// all context-sensitive FOLLOW sets - the set of all tokens that
+// could follow any reference in the call chain. We need to
+// reSync to one of those tokens. Note that FOLLOW(c)='^' and if
+// we reSync'd to that token, we'd consume until EOF. We need to
+// Sync to context-sensitive FOLLOWs for a, b, and c:
+//
+// {']','^'}
+//
+// In this case, for input "[]", LA(1) is ']' and in the set, so we would
+// not consume anything. After printing an error, rule c would
+// return normally. Rule b would not find the required '^' though.
+// At this point, it gets a mismatched token error and panics an
+// exception (since LA(1) is not in the viable following token
+// set). The rule exception handler tries to recover, but finds
+// the same recovery set and doesn't consume anything. Rule b
+// exits normally returning to rule a. Now it finds the ']' (and
+// with the successful Match exits errorRecovery mode).
+//
+// So, you can see that the parser walks up the call chain looking
+// for the token that was a member of the recovery set.
+//
+// Errors are not generated in errorRecovery mode.
+//
+// ANTLR's error recovery mechanism is based upon original ideas:
+//
+// [Algorithms + Data Structures = Programs] by Niklaus Wirth and
+// [A note on error recovery in recursive descent parsers].
+//
+// Later, Josef Grosch had some good ideas in [Efficient and Comfortable Error Recovery in Recursive Descent
+// Parsers]
+//
+// Like Grosch I implement context-sensitive FOLLOW sets that are combined at run-time upon error to avoid overhead
+// during parsing. Later, the runtime Sync was improved for loops/sub-rules see [Sync] docs
+//
+// [A note on error recovery in recursive descent parsers]: http://portal.acm.org/citation.cfm?id=947902.947905
+// [Algorithms + Data Structures = Programs]: https://t.ly/5QzgE
+// [Efficient and Comfortable Error Recovery in Recursive Descent Parsers]: ftp://www.cocolab.com/products/cocktail/doca4.ps/ell.ps.zip
+func (d *DefaultErrorStrategy) GetErrorRecoverySet(recognizer Parser) *IntervalSet {
+ atn := recognizer.GetInterpreter().atn
+ ctx := recognizer.GetParserRuleContext()
+ recoverSet := NewIntervalSet()
+ for ctx != nil && ctx.GetInvokingState() >= 0 {
+ // compute what follows who invoked us
+ invokingState := atn.states[ctx.GetInvokingState()]
+ rt := invokingState.GetTransitions()[0]
+ follow := atn.NextTokens(rt.(*RuleTransition).followState, nil)
+ recoverSet.addSet(follow)
+ ctx = ctx.GetParent().(ParserRuleContext)
+ }
+ recoverSet.removeOne(TokenEpsilon)
+ return recoverSet
+}
+
+// Consume tokens until one Matches the given token set.//
+func (d *DefaultErrorStrategy) consumeUntil(recognizer Parser, set *IntervalSet) {
+ ttype := recognizer.GetTokenStream().LA(1)
+ for ttype != TokenEOF && !set.contains(ttype) {
+ recognizer.Consume()
+ ttype = recognizer.GetTokenStream().LA(1)
+ }
+}
+
+// The BailErrorStrategy implementation of ANTLRErrorStrategy responds to syntax errors
+// by immediately canceling the parse operation with a
+// [ParseCancellationException]. The implementation ensures that the
+// [ParserRuleContext//exception] field is set for all parse tree nodes
+// that were not completed prior to encountering the error.
+//
+// This error strategy is useful in the following scenarios.
+//
+// - Two-stage parsing: This error strategy allows the first
+// stage of two-stage parsing to immediately terminate if an error is
+// encountered, and immediately fall back to the second stage. In addition to
+// avoiding wasted work by attempting to recover from errors here, the empty
+// implementation of [BailErrorStrategy.Sync] improves the performance of
+// the first stage.
+//
+// - Silent validation: When syntax errors are not being
+// Reported or logged, and the parse result is simply ignored if errors occur,
+// the [BailErrorStrategy] avoids wasting work on recovering from errors
+// when the result will be ignored either way.
+//
+// myparser.SetErrorHandler(NewBailErrorStrategy())
+//
+// See also: [Parser.SetErrorHandler(ANTLRErrorStrategy)]
+type BailErrorStrategy struct {
+ *DefaultErrorStrategy
+}
+
+var _ ErrorStrategy = &BailErrorStrategy{}
+
+//goland:noinspection GoUnusedExportedFunction
+func NewBailErrorStrategy() *BailErrorStrategy {
+
+ b := new(BailErrorStrategy)
+
+ b.DefaultErrorStrategy = NewDefaultErrorStrategy()
+
+ return b
+}
+
+// Recover Instead of recovering from exception e, re-panic it wrapped
+// in a [ParseCancellationException] so it is not caught by the
+// rule func catches. Use Exception.GetCause() to get the
+// original [RecognitionException].
+func (b *BailErrorStrategy) Recover(recognizer Parser, e RecognitionException) {
+ context := recognizer.GetParserRuleContext()
+ for context != nil {
+ context.SetException(e)
+ if parent, ok := context.GetParent().(ParserRuleContext); ok {
+ context = parent
+ } else {
+ context = nil
+ }
+ }
+ recognizer.SetError(NewParseCancellationException()) // TODO: we don't emit e properly
+}
+
+// RecoverInline makes sure we don't attempt to recover inline if the parser
+// successfully recovers, it won't panic an exception.
+func (b *BailErrorStrategy) RecoverInline(recognizer Parser) Token {
+ b.Recover(recognizer, NewInputMisMatchException(recognizer))
+
+ return nil
+}
+
+// Sync makes sure we don't attempt to recover from problems in sub-rules.
+func (b *BailErrorStrategy) Sync(_ Parser) {
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/errors.go b/vendor/github.com/antlr4-go/antlr/v4/errors.go
new file mode 100644
index 000000000000..8f0f2f601fde
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/errors.go
@@ -0,0 +1,259 @@
+// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
+// Use of this file is governed by the BSD 3-clause license that
+// can be found in the LICENSE.txt file in the project root.
+
+package antlr
+
+// The root of the ANTLR exception hierarchy. In general, ANTLR tracks just
+// 3 kinds of errors: prediction errors, failed predicate errors, and
+// mismatched input errors. In each case, the parser knows where it is
+// in the input, where it is in the ATN, the rule invocation stack,
+// and what kind of problem occurred.
+
+type RecognitionException interface {
+ GetOffendingToken() Token
+ GetMessage() string
+ GetInputStream() IntStream
+}
+
+type BaseRecognitionException struct {
+ message string
+ recognizer Recognizer
+ offendingToken Token
+ offendingState int
+ ctx RuleContext
+ input IntStream
+}
+
+func NewBaseRecognitionException(message string, recognizer Recognizer, input IntStream, ctx RuleContext) *BaseRecognitionException {
+
+ // todo
+ // Error.call(this)
+ //
+ // if (!!Error.captureStackTrace) {
+ // Error.captureStackTrace(this, RecognitionException)
+ // } else {
+ // stack := NewError().stack
+ // }
+ // TODO: may be able to use - "runtime" func Stack(buf []byte, all bool) int
+
+ t := new(BaseRecognitionException)
+
+ t.message = message
+ t.recognizer = recognizer
+ t.input = input
+ t.ctx = ctx
+
+ // The current Token when an error occurred. Since not all streams
+ // support accessing symbols by index, we have to track the {@link Token}
+ // instance itself.
+ //
+ t.offendingToken = nil
+
+ // Get the ATN state number the parser was in at the time the error
+ // occurred. For NoViableAltException and LexerNoViableAltException exceptions, this is the
+ // DecisionState number. For others, it is the state whose outgoing edge we couldn't Match.
+ //
+ t.offendingState = -1
+ if t.recognizer != nil {
+ t.offendingState = t.recognizer.GetState()
+ }
+
+ return t
+}
+
+func (b *BaseRecognitionException) GetMessage() string {
+ return b.message
+}
+
+func (b *BaseRecognitionException) GetOffendingToken() Token {
+ return b.offendingToken
+}
+
+func (b *BaseRecognitionException) GetInputStream() IntStream {
+ return b.input
+}
+
+//
If the state number is not known, b method returns -1.
+
+// getExpectedTokens gets the set of input symbols which could potentially follow the
+// previously Matched symbol at the time this exception was raised.
+//
+// If the set of expected tokens is not known and could not be computed,
+// this method returns nil.
+//
+// The func returns the set of token types that could potentially follow the current
+// state in the {ATN}, or nil if the information is not available.
+
+func (b *BaseRecognitionException) getExpectedTokens() *IntervalSet {
+ if b.recognizer != nil {
+ return b.recognizer.GetATN().getExpectedTokens(b.offendingState, b.ctx)
+ }
+
+ return nil
+}
+
+func (b *BaseRecognitionException) String() string {
+ return b.message
+}
+
+type LexerNoViableAltException struct {
+ *BaseRecognitionException
+
+ startIndex int
+ deadEndConfigs *ATNConfigSet
+}
+
+func NewLexerNoViableAltException(lexer Lexer, input CharStream, startIndex int, deadEndConfigs *ATNConfigSet) *LexerNoViableAltException {
+
+ l := new(LexerNoViableAltException)
+
+ l.BaseRecognitionException = NewBaseRecognitionException("", lexer, input, nil)
+
+ l.startIndex = startIndex
+ l.deadEndConfigs = deadEndConfigs
+
+ return l
+}
+
+func (l *LexerNoViableAltException) String() string {
+ symbol := ""
+ if l.startIndex >= 0 && l.startIndex < l.input.Size() {
+ symbol = l.input.(CharStream).GetTextFromInterval(NewInterval(l.startIndex, l.startIndex))
+ }
+ return "LexerNoViableAltException" + symbol
+}
+
+type NoViableAltException struct {
+ *BaseRecognitionException
+
+ startToken Token
+ offendingToken Token
+ ctx ParserRuleContext
+ deadEndConfigs *ATNConfigSet
+}
+
+// NewNoViableAltException creates an exception indicating that the parser could not decide which of two or more paths
+// to take based upon the remaining input. It tracks the starting token
+// of the offending input and also knows where the parser was
+// in the various paths when the error.
+//
+// Reported by [ReportNoViableAlternative]
+func NewNoViableAltException(recognizer Parser, input TokenStream, startToken Token, offendingToken Token, deadEndConfigs *ATNConfigSet, ctx ParserRuleContext) *NoViableAltException {
+
+ if ctx == nil {
+ ctx = recognizer.GetParserRuleContext()
+ }
+
+ if offendingToken == nil {
+ offendingToken = recognizer.GetCurrentToken()
+ }
+
+ if startToken == nil {
+ startToken = recognizer.GetCurrentToken()
+ }
+
+ if input == nil {
+ input = recognizer.GetInputStream().(TokenStream)
+ }
+
+ n := new(NoViableAltException)
+ n.BaseRecognitionException = NewBaseRecognitionException("", recognizer, input, ctx)
+
+ // Which configurations did we try at input.Index() that couldn't Match
+ // input.LT(1)
+ n.deadEndConfigs = deadEndConfigs
+
+ // The token object at the start index the input stream might
+ // not be buffering tokens so get a reference to it.
+ //
+ // At the time the error occurred, of course the stream needs to keep a
+ // buffer of all the tokens, but later we might not have access to those.
+ n.startToken = startToken
+ n.offendingToken = offendingToken
+
+ return n
+}
+
+type InputMisMatchException struct {
+ *BaseRecognitionException
+}
+
+// NewInputMisMatchException creates an exception that signifies any kind of mismatched input exceptions such as
+// when the current input does not Match the expected token.
+func NewInputMisMatchException(recognizer Parser) *InputMisMatchException {
+
+ i := new(InputMisMatchException)
+ i.BaseRecognitionException = NewBaseRecognitionException("", recognizer, recognizer.GetInputStream(), recognizer.GetParserRuleContext())
+
+ i.offendingToken = recognizer.GetCurrentToken()
+
+ return i
+
+}
+
+// FailedPredicateException indicates that a semantic predicate failed during validation. Validation of predicates
+// occurs when normally parsing the alternative just like Matching a token.
+// Disambiguating predicate evaluation occurs when we test a predicate during
+// prediction.
+type FailedPredicateException struct {
+ *BaseRecognitionException
+
+ ruleIndex int
+ predicateIndex int
+ predicate string
+}
+
+//goland:noinspection GoUnusedExportedFunction
+func NewFailedPredicateException(recognizer Parser, predicate string, message string) *FailedPredicateException {
+
+ f := new(FailedPredicateException)
+
+ f.BaseRecognitionException = NewBaseRecognitionException(f.formatMessage(predicate, message), recognizer, recognizer.GetInputStream(), recognizer.GetParserRuleContext())
+
+ s := recognizer.GetInterpreter().atn.states[recognizer.GetState()]
+ trans := s.GetTransitions()[0]
+ if trans2, ok := trans.(*PredicateTransition); ok {
+ f.ruleIndex = trans2.ruleIndex
+ f.predicateIndex = trans2.predIndex
+ } else {
+ f.ruleIndex = 0
+ f.predicateIndex = 0
+ }
+ f.predicate = predicate
+ f.offendingToken = recognizer.GetCurrentToken()
+
+ return f
+}
+
+func (f *FailedPredicateException) formatMessage(predicate, message string) string {
+ if message != "" {
+ return message
+ }
+
+ return "failed predicate: {" + predicate + "}?"
+}
+
+type ParseCancellationException struct {
+}
+
+func (p ParseCancellationException) GetOffendingToken() Token {
+ //TODO implement me
+ panic("implement me")
+}
+
+func (p ParseCancellationException) GetMessage() string {
+ //TODO implement me
+ panic("implement me")
+}
+
+func (p ParseCancellationException) GetInputStream() IntStream {
+ //TODO implement me
+ panic("implement me")
+}
+
+func NewParseCancellationException() *ParseCancellationException {
+ // Error.call(this)
+ // Error.captureStackTrace(this, ParseCancellationException)
+ return new(ParseCancellationException)
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/file_stream.go b/vendor/github.com/antlr4-go/antlr/v4/file_stream.go
new file mode 100644
index 000000000000..5f65f809be5e
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/file_stream.go
@@ -0,0 +1,67 @@
+// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
+// Use of this file is governed by the BSD 3-clause license that
+// can be found in the LICENSE.txt file in the project root.
+
+package antlr
+
+import (
+ "bufio"
+ "os"
+)
+
+// This is an InputStream that is loaded from a file all at once
+// when you construct the object.
+
+type FileStream struct {
+ InputStream
+ filename string
+}
+
+//goland:noinspection GoUnusedExportedFunction
+func NewFileStream(fileName string) (*FileStream, error) {
+
+ f, err := os.Open(fileName)
+ if err != nil {
+ return nil, err
+ }
+
+ defer func(f *os.File) {
+ errF := f.Close()
+ if errF != nil {
+ }
+ }(f)
+
+ reader := bufio.NewReader(f)
+ fInfo, err := f.Stat()
+ if err != nil {
+ return nil, err
+ }
+
+ fs := &FileStream{
+ InputStream: InputStream{
+ index: 0,
+ name: fileName,
+ },
+ filename: fileName,
+ }
+
+ // Pre-build the buffer and read runes efficiently
+ //
+ fs.data = make([]rune, 0, fInfo.Size())
+ for {
+ r, _, err := reader.ReadRune()
+ if err != nil {
+ break
+ }
+ fs.data = append(fs.data, r)
+ }
+ fs.size = len(fs.data) // Size in runes
+
+ // All done.
+ //
+ return fs, nil
+}
+
+func (f *FileStream) GetSourceName() string {
+ return f.filename
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/input_stream.go b/vendor/github.com/antlr4-go/antlr/v4/input_stream.go
new file mode 100644
index 000000000000..b737fe85fbd0
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/input_stream.go
@@ -0,0 +1,157 @@
+// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
+// Use of this file is governed by the BSD 3-clause license that
+// can be found in the LICENSE.txt file in the project root.
+
+package antlr
+
+import (
+ "bufio"
+ "io"
+)
+
+type InputStream struct {
+ name string
+ index int
+ data []rune
+ size int
+}
+
+// NewIoStream creates a new input stream from the given io.Reader reader.
+// Note that the reader is read completely into memory and so it must actually
+// have a stopping point - you cannot pass in a reader on an open-ended source such
+// as a socket for instance.
+func NewIoStream(reader io.Reader) *InputStream {
+
+ rReader := bufio.NewReader(reader)
+
+ is := &InputStream{
+ name: "",
+ index: 0,
+ }
+
+ // Pre-build the buffer and read runes reasonably efficiently given that
+ // we don't exactly know how big the input is.
+ //
+ is.data = make([]rune, 0, 512)
+ for {
+ r, _, err := rReader.ReadRune()
+ if err != nil {
+ break
+ }
+ is.data = append(is.data, r)
+ }
+ is.size = len(is.data) // number of runes
+ return is
+}
+
+// NewInputStream creates a new input stream from the given string
+func NewInputStream(data string) *InputStream {
+
+ is := &InputStream{
+ name: "",
+ index: 0,
+ data: []rune(data), // This is actually the most efficient way
+ }
+ is.size = len(is.data) // number of runes, but we could also use len(data), which is efficient too
+ return is
+}
+
+func (is *InputStream) reset() {
+ is.index = 0
+}
+
+// Consume moves the input pointer to the next character in the input stream
+func (is *InputStream) Consume() {
+ if is.index >= is.size {
+ // assert is.LA(1) == TokenEOF
+ panic("cannot consume EOF")
+ }
+ is.index++
+}
+
+// LA returns the character at the given offset from the start of the input stream
+func (is *InputStream) LA(offset int) int {
+
+ if offset == 0 {
+ return 0 // nil
+ }
+ if offset < 0 {
+ offset++ // e.g., translate LA(-1) to use offset=0
+ }
+ pos := is.index + offset - 1
+
+ if pos < 0 || pos >= is.size { // invalid
+ return TokenEOF
+ }
+
+ return int(is.data[pos])
+}
+
+// LT returns the character at the given offset from the start of the input stream
+func (is *InputStream) LT(offset int) int {
+ return is.LA(offset)
+}
+
+// Index returns the current offset in to the input stream
+func (is *InputStream) Index() int {
+ return is.index
+}
+
+// Size returns the total number of characters in the input stream
+func (is *InputStream) Size() int {
+ return is.size
+}
+
+// Mark does nothing here as we have entire buffer
+func (is *InputStream) Mark() int {
+ return -1
+}
+
+// Release does nothing here as we have entire buffer
+func (is *InputStream) Release(_ int) {
+}
+
+// Seek the input point to the provided index offset
+func (is *InputStream) Seek(index int) {
+ if index <= is.index {
+ is.index = index // just jump don't update stream state (line,...)
+ return
+ }
+ // seek forward
+ is.index = intMin(index, is.size)
+}
+
+// GetText returns the text from the input stream from the start to the stop index
+func (is *InputStream) GetText(start int, stop int) string {
+ if stop >= is.size {
+ stop = is.size - 1
+ }
+ if start >= is.size {
+ return ""
+ }
+
+ return string(is.data[start : stop+1])
+}
+
+// GetTextFromTokens returns the text from the input stream from the first character of the start token to the last
+// character of the stop token
+func (is *InputStream) GetTextFromTokens(start, stop Token) string {
+ if start != nil && stop != nil {
+ return is.GetTextFromInterval(NewInterval(start.GetTokenIndex(), stop.GetTokenIndex()))
+ }
+
+ return ""
+}
+
+func (is *InputStream) GetTextFromInterval(i Interval) string {
+ return is.GetText(i.Start, i.Stop)
+}
+
+func (*InputStream) GetSourceName() string {
+ return ""
+}
+
+// String returns the entire input stream as a string
+func (is *InputStream) String() string {
+ return string(is.data)
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/int_stream.go b/vendor/github.com/antlr4-go/antlr/v4/int_stream.go
new file mode 100644
index 000000000000..4778878bd0db
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/int_stream.go
@@ -0,0 +1,16 @@
+// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
+// Use of this file is governed by the BSD 3-clause license that
+// can be found in the LICENSE.txt file in the project root.
+
+package antlr
+
+type IntStream interface {
+ Consume()
+ LA(int) int
+ Mark() int
+ Release(marker int)
+ Index() int
+ Seek(index int)
+ Size() int
+ GetSourceName() string
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/interval_set.go b/vendor/github.com/antlr4-go/antlr/v4/interval_set.go
new file mode 100644
index 000000000000..cc5066067a2c
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/interval_set.go
@@ -0,0 +1,330 @@
+// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
+// Use of this file is governed by the BSD 3-clause license that
+// can be found in the LICENSE.txt file in the project root.
+
+package antlr
+
+import (
+ "strconv"
+ "strings"
+)
+
+type Interval struct {
+ Start int
+ Stop int
+}
+
+// NewInterval creates a new interval with the given start and stop values.
+func NewInterval(start, stop int) Interval {
+ return Interval{
+ Start: start,
+ Stop: stop,
+ }
+}
+
+// Contains returns true if the given item is contained within the interval.
+func (i Interval) Contains(item int) bool {
+ return item >= i.Start && item < i.Stop
+}
+
+// String generates a string representation of the interval.
+func (i Interval) String() string {
+ if i.Start == i.Stop-1 {
+ return strconv.Itoa(i.Start)
+ }
+
+ return strconv.Itoa(i.Start) + ".." + strconv.Itoa(i.Stop-1)
+}
+
+// Length returns the length of the interval.
+func (i Interval) Length() int {
+ return i.Stop - i.Start
+}
+
+// IntervalSet represents a collection of [Intervals], which may be read-only.
+type IntervalSet struct {
+ intervals []Interval
+ readOnly bool
+}
+
+// NewIntervalSet creates a new empty, writable, interval set.
+func NewIntervalSet() *IntervalSet {
+
+ i := new(IntervalSet)
+
+ i.intervals = nil
+ i.readOnly = false
+
+ return i
+}
+
+func (i *IntervalSet) Equals(other *IntervalSet) bool {
+ if len(i.intervals) != len(other.intervals) {
+ return false
+ }
+
+ for k, v := range i.intervals {
+ if v.Start != other.intervals[k].Start || v.Stop != other.intervals[k].Stop {
+ return false
+ }
+ }
+
+ return true
+}
+
+func (i *IntervalSet) first() int {
+ if len(i.intervals) == 0 {
+ return TokenInvalidType
+ }
+
+ return i.intervals[0].Start
+}
+
+func (i *IntervalSet) addOne(v int) {
+ i.addInterval(NewInterval(v, v+1))
+}
+
+func (i *IntervalSet) addRange(l, h int) {
+ i.addInterval(NewInterval(l, h+1))
+}
+
+func (i *IntervalSet) addInterval(v Interval) {
+ if i.intervals == nil {
+ i.intervals = make([]Interval, 0)
+ i.intervals = append(i.intervals, v)
+ } else {
+ // find insert pos
+ for k, interval := range i.intervals {
+ // distinct range -> insert
+ if v.Stop < interval.Start {
+ i.intervals = append(i.intervals[0:k], append([]Interval{v}, i.intervals[k:]...)...)
+ return
+ } else if v.Stop == interval.Start {
+ i.intervals[k].Start = v.Start
+ return
+ } else if v.Start <= interval.Stop {
+ i.intervals[k] = NewInterval(intMin(interval.Start, v.Start), intMax(interval.Stop, v.Stop))
+
+ // if not applying to end, merge potential overlaps
+ if k < len(i.intervals)-1 {
+ l := i.intervals[k]
+ r := i.intervals[k+1]
+ // if r contained in l
+ if l.Stop >= r.Stop {
+ i.intervals = append(i.intervals[0:k+1], i.intervals[k+2:]...)
+ } else if l.Stop >= r.Start { // partial overlap
+ i.intervals[k] = NewInterval(l.Start, r.Stop)
+ i.intervals = append(i.intervals[0:k+1], i.intervals[k+2:]...)
+ }
+ }
+ return
+ }
+ }
+ // greater than any exiting
+ i.intervals = append(i.intervals, v)
+ }
+}
+
+func (i *IntervalSet) addSet(other *IntervalSet) *IntervalSet {
+ if other.intervals != nil {
+ for k := 0; k < len(other.intervals); k++ {
+ i2 := other.intervals[k]
+ i.addInterval(NewInterval(i2.Start, i2.Stop))
+ }
+ }
+ return i
+}
+
+func (i *IntervalSet) complement(start int, stop int) *IntervalSet {
+ result := NewIntervalSet()
+ result.addInterval(NewInterval(start, stop+1))
+ for j := 0; j < len(i.intervals); j++ {
+ result.removeRange(i.intervals[j])
+ }
+ return result
+}
+
+func (i *IntervalSet) contains(item int) bool {
+ if i.intervals == nil {
+ return false
+ }
+ for k := 0; k < len(i.intervals); k++ {
+ if i.intervals[k].Contains(item) {
+ return true
+ }
+ }
+ return false
+}
+
+func (i *IntervalSet) length() int {
+ iLen := 0
+
+ for _, v := range i.intervals {
+ iLen += v.Length()
+ }
+
+ return iLen
+}
+
+func (i *IntervalSet) removeRange(v Interval) {
+ if v.Start == v.Stop-1 {
+ i.removeOne(v.Start)
+ } else if i.intervals != nil {
+ k := 0
+ for n := 0; n < len(i.intervals); n++ {
+ ni := i.intervals[k]
+ // intervals are ordered
+ if v.Stop <= ni.Start {
+ return
+ } else if v.Start > ni.Start && v.Stop < ni.Stop {
+ i.intervals[k] = NewInterval(ni.Start, v.Start)
+ x := NewInterval(v.Stop, ni.Stop)
+ // i.intervals.splice(k, 0, x)
+ i.intervals = append(i.intervals[0:k], append([]Interval{x}, i.intervals[k:]...)...)
+ return
+ } else if v.Start <= ni.Start && v.Stop >= ni.Stop {
+ // i.intervals.splice(k, 1)
+ i.intervals = append(i.intervals[0:k], i.intervals[k+1:]...)
+ k = k - 1 // need another pass
+ } else if v.Start < ni.Stop {
+ i.intervals[k] = NewInterval(ni.Start, v.Start)
+ } else if v.Stop < ni.Stop {
+ i.intervals[k] = NewInterval(v.Stop, ni.Stop)
+ }
+ k++
+ }
+ }
+}
+
+func (i *IntervalSet) removeOne(v int) {
+ if i.intervals != nil {
+ for k := 0; k < len(i.intervals); k++ {
+ ki := i.intervals[k]
+ // intervals i ordered
+ if v < ki.Start {
+ return
+ } else if v == ki.Start && v == ki.Stop-1 {
+ // i.intervals.splice(k, 1)
+ i.intervals = append(i.intervals[0:k], i.intervals[k+1:]...)
+ return
+ } else if v == ki.Start {
+ i.intervals[k] = NewInterval(ki.Start+1, ki.Stop)
+ return
+ } else if v == ki.Stop-1 {
+ i.intervals[k] = NewInterval(ki.Start, ki.Stop-1)
+ return
+ } else if v < ki.Stop-1 {
+ x := NewInterval(ki.Start, v)
+ ki.Start = v + 1
+ // i.intervals.splice(k, 0, x)
+ i.intervals = append(i.intervals[0:k], append([]Interval{x}, i.intervals[k:]...)...)
+ return
+ }
+ }
+ }
+}
+
+func (i *IntervalSet) String() string {
+ return i.StringVerbose(nil, nil, false)
+}
+
+func (i *IntervalSet) StringVerbose(literalNames []string, symbolicNames []string, elemsAreChar bool) string {
+
+ if i.intervals == nil {
+ return "{}"
+ } else if literalNames != nil || symbolicNames != nil {
+ return i.toTokenString(literalNames, symbolicNames)
+ } else if elemsAreChar {
+ return i.toCharString()
+ }
+
+ return i.toIndexString()
+}
+
+func (i *IntervalSet) GetIntervals() []Interval {
+ return i.intervals
+}
+
+func (i *IntervalSet) toCharString() string {
+ names := make([]string, len(i.intervals))
+
+ var sb strings.Builder
+
+ for j := 0; j < len(i.intervals); j++ {
+ v := i.intervals[j]
+ if v.Stop == v.Start+1 {
+ if v.Start == TokenEOF {
+ names = append(names, "")
+ } else {
+ sb.WriteByte('\'')
+ sb.WriteRune(rune(v.Start))
+ sb.WriteByte('\'')
+ names = append(names, sb.String())
+ sb.Reset()
+ }
+ } else {
+ sb.WriteByte('\'')
+ sb.WriteRune(rune(v.Start))
+ sb.WriteString("'..'")
+ sb.WriteRune(rune(v.Stop - 1))
+ sb.WriteByte('\'')
+ names = append(names, sb.String())
+ sb.Reset()
+ }
+ }
+ if len(names) > 1 {
+ return "{" + strings.Join(names, ", ") + "}"
+ }
+
+ return names[0]
+}
+
+func (i *IntervalSet) toIndexString() string {
+
+ names := make([]string, 0)
+ for j := 0; j < len(i.intervals); j++ {
+ v := i.intervals[j]
+ if v.Stop == v.Start+1 {
+ if v.Start == TokenEOF {
+ names = append(names, "")
+ } else {
+ names = append(names, strconv.Itoa(v.Start))
+ }
+ } else {
+ names = append(names, strconv.Itoa(v.Start)+".."+strconv.Itoa(v.Stop-1))
+ }
+ }
+ if len(names) > 1 {
+ return "{" + strings.Join(names, ", ") + "}"
+ }
+
+ return names[0]
+}
+
+func (i *IntervalSet) toTokenString(literalNames []string, symbolicNames []string) string {
+ names := make([]string, 0)
+ for _, v := range i.intervals {
+ for j := v.Start; j < v.Stop; j++ {
+ names = append(names, i.elementName(literalNames, symbolicNames, j))
+ }
+ }
+ if len(names) > 1 {
+ return "{" + strings.Join(names, ", ") + "}"
+ }
+
+ return names[0]
+}
+
+func (i *IntervalSet) elementName(literalNames []string, symbolicNames []string, a int) string {
+ if a == TokenEOF {
+ return ""
+ } else if a == TokenEpsilon {
+ return ""
+ } else {
+ if a < len(literalNames) && literalNames[a] != "" {
+ return literalNames[a]
+ }
+
+ return symbolicNames[a]
+ }
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/jcollect.go b/vendor/github.com/antlr4-go/antlr/v4/jcollect.go
new file mode 100644
index 000000000000..ceccd96d2584
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/jcollect.go
@@ -0,0 +1,685 @@
+package antlr
+
+// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
+// Use of this file is governed by the BSD 3-clause license that
+// can be found in the LICENSE.txt file in the project root.
+
+import (
+ "container/list"
+ "runtime/debug"
+ "sort"
+ "sync"
+)
+
+// Collectable is an interface that a struct should implement if it is to be
+// usable as a key in these collections.
+type Collectable[T any] interface {
+ Hash() int
+ Equals(other Collectable[T]) bool
+}
+
+type Comparator[T any] interface {
+ Hash1(o T) int
+ Equals2(T, T) bool
+}
+
+type CollectionSource int
+type CollectionDescriptor struct {
+ SybolicName string
+ Description string
+}
+
+const (
+ UnknownCollection CollectionSource = iota
+ ATNConfigLookupCollection
+ ATNStateCollection
+ DFAStateCollection
+ ATNConfigCollection
+ PredictionContextCollection
+ SemanticContextCollection
+ ClosureBusyCollection
+ PredictionVisitedCollection
+ MergeCacheCollection
+ PredictionContextCacheCollection
+ AltSetCollection
+ ReachSetCollection
+)
+
+var CollectionDescriptors = map[CollectionSource]CollectionDescriptor{
+ UnknownCollection: {
+ SybolicName: "UnknownCollection",
+ Description: "Unknown collection type. Only used if the target author thought it was an unimportant collection.",
+ },
+ ATNConfigCollection: {
+ SybolicName: "ATNConfigCollection",
+ Description: "ATNConfig collection. Used to store the ATNConfigs for a particular state in the ATN." +
+ "For instance, it is used to store the results of the closure() operation in the ATN.",
+ },
+ ATNConfigLookupCollection: {
+ SybolicName: "ATNConfigLookupCollection",
+ Description: "ATNConfigLookup collection. Used to store the ATNConfigs for a particular state in the ATN." +
+ "This is used to prevent duplicating equivalent states in an ATNConfigurationSet.",
+ },
+ ATNStateCollection: {
+ SybolicName: "ATNStateCollection",
+ Description: "ATNState collection. This is used to store the states of the ATN.",
+ },
+ DFAStateCollection: {
+ SybolicName: "DFAStateCollection",
+ Description: "DFAState collection. This is used to store the states of the DFA.",
+ },
+ PredictionContextCollection: {
+ SybolicName: "PredictionContextCollection",
+ Description: "PredictionContext collection. This is used to store the prediction contexts of the ATN and cache computes.",
+ },
+ SemanticContextCollection: {
+ SybolicName: "SemanticContextCollection",
+ Description: "SemanticContext collection. This is used to store the semantic contexts of the ATN.",
+ },
+ ClosureBusyCollection: {
+ SybolicName: "ClosureBusyCollection",
+ Description: "ClosureBusy collection. This is used to check and prevent infinite recursion right recursive rules." +
+ "It stores ATNConfigs that are currently being processed in the closure() operation.",
+ },
+ PredictionVisitedCollection: {
+ SybolicName: "PredictionVisitedCollection",
+ Description: "A map that records whether we have visited a particular context when searching through cached entries.",
+ },
+ MergeCacheCollection: {
+ SybolicName: "MergeCacheCollection",
+ Description: "A map that records whether we have already merged two particular contexts and can save effort by not repeating it.",
+ },
+ PredictionContextCacheCollection: {
+ SybolicName: "PredictionContextCacheCollection",
+ Description: "A map that records whether we have already created a particular context and can save effort by not computing it again.",
+ },
+ AltSetCollection: {
+ SybolicName: "AltSetCollection",
+ Description: "Used to eliminate duplicate alternatives in an ATN config set.",
+ },
+ ReachSetCollection: {
+ SybolicName: "ReachSetCollection",
+ Description: "Used as merge cache to prevent us needing to compute the merge of two states if we have already done it.",
+ },
+}
+
+// JStore implements a container that allows the use of a struct to calculate the key
+// for a collection of values akin to map. This is not meant to be a full-blown HashMap but just
+// serve the needs of the ANTLR Go runtime.
+//
+// For ease of porting the logic of the runtime from the master target (Java), this collection
+// operates in a similar way to Java, in that it can use any struct that supplies a Hash() and Equals()
+// function as the key. The values are stored in a standard go map which internally is a form of hashmap
+// itself, the key for the go map is the hash supplied by the key object. The collection is able to deal with
+// hash conflicts by using a simple slice of values associated with the hash code indexed bucket. That isn't
+// particularly efficient, but it is simple, and it works. As this is specifically for the ANTLR runtime, and
+// we understand the requirements, then this is fine - this is not a general purpose collection.
+type JStore[T any, C Comparator[T]] struct {
+ store map[int][]T
+ len int
+ comparator Comparator[T]
+ stats *JStatRec
+}
+
+func NewJStore[T any, C Comparator[T]](comparator Comparator[T], cType CollectionSource, desc string) *JStore[T, C] {
+
+ if comparator == nil {
+ panic("comparator cannot be nil")
+ }
+
+ s := &JStore[T, C]{
+ store: make(map[int][]T, 1),
+ comparator: comparator,
+ }
+ if collectStats {
+ s.stats = &JStatRec{
+ Source: cType,
+ Description: desc,
+ }
+
+ // Track where we created it from if we are being asked to do so
+ if runtimeConfig.statsTraceStacks {
+ s.stats.CreateStack = debug.Stack()
+ }
+ Statistics.AddJStatRec(s.stats)
+ }
+ return s
+}
+
+// Put will store given value in the collection. Note that the key for storage is generated from
+// the value itself - this is specifically because that is what ANTLR needs - this would not be useful
+// as any kind of general collection.
+//
+// If the key has a hash conflict, then the value will be added to the slice of values associated with the
+// hash, unless the value is already in the slice, in which case the existing value is returned. Value equivalence is
+// tested by calling the equals() method on the key.
+//
+// # If the given value is already present in the store, then the existing value is returned as v and exists is set to true
+//
+// If the given value is not present in the store, then the value is added to the store and returned as v and exists is set to false.
+func (s *JStore[T, C]) Put(value T) (v T, exists bool) {
+
+ if collectStats {
+ s.stats.Puts++
+ }
+ kh := s.comparator.Hash1(value)
+
+ var hClash bool
+ for _, v1 := range s.store[kh] {
+ hClash = true
+ if s.comparator.Equals2(value, v1) {
+ if collectStats {
+ s.stats.PutHits++
+ s.stats.PutHashConflicts++
+ }
+ return v1, true
+ }
+ if collectStats {
+ s.stats.PutMisses++
+ }
+ }
+ if collectStats && hClash {
+ s.stats.PutHashConflicts++
+ }
+ s.store[kh] = append(s.store[kh], value)
+
+ if collectStats {
+ if len(s.store[kh]) > s.stats.MaxSlotSize {
+ s.stats.MaxSlotSize = len(s.store[kh])
+ }
+ }
+ s.len++
+ if collectStats {
+ s.stats.CurSize = s.len
+ if s.len > s.stats.MaxSize {
+ s.stats.MaxSize = s.len
+ }
+ }
+ return value, false
+}
+
+// Get will return the value associated with the key - the type of the key is the same type as the value
+// which would not generally be useful, but this is a specific thing for ANTLR where the key is
+// generated using the object we are going to store.
+func (s *JStore[T, C]) Get(key T) (T, bool) {
+ if collectStats {
+ s.stats.Gets++
+ }
+ kh := s.comparator.Hash1(key)
+ var hClash bool
+ for _, v := range s.store[kh] {
+ hClash = true
+ if s.comparator.Equals2(key, v) {
+ if collectStats {
+ s.stats.GetHits++
+ s.stats.GetHashConflicts++
+ }
+ return v, true
+ }
+ if collectStats {
+ s.stats.GetMisses++
+ }
+ }
+ if collectStats {
+ if hClash {
+ s.stats.GetHashConflicts++
+ }
+ s.stats.GetNoEnt++
+ }
+ return key, false
+}
+
+// Contains returns true if the given key is present in the store
+func (s *JStore[T, C]) Contains(key T) bool {
+ _, present := s.Get(key)
+ return present
+}
+
+func (s *JStore[T, C]) SortedSlice(less func(i, j T) bool) []T {
+ vs := make([]T, 0, len(s.store))
+ for _, v := range s.store {
+ vs = append(vs, v...)
+ }
+ sort.Slice(vs, func(i, j int) bool {
+ return less(vs[i], vs[j])
+ })
+
+ return vs
+}
+
+func (s *JStore[T, C]) Each(f func(T) bool) {
+ for _, e := range s.store {
+ for _, v := range e {
+ f(v)
+ }
+ }
+}
+
+func (s *JStore[T, C]) Len() int {
+ return s.len
+}
+
+func (s *JStore[T, C]) Values() []T {
+ vs := make([]T, 0, len(s.store))
+ for _, e := range s.store {
+ vs = append(vs, e...)
+ }
+ return vs
+}
+
+type entry[K, V any] struct {
+ key K
+ val V
+}
+
+type JMap[K, V any, C Comparator[K]] struct {
+ store map[int][]*entry[K, V]
+ len int
+ comparator Comparator[K]
+ stats *JStatRec
+}
+
+func NewJMap[K, V any, C Comparator[K]](comparator Comparator[K], cType CollectionSource, desc string) *JMap[K, V, C] {
+ m := &JMap[K, V, C]{
+ store: make(map[int][]*entry[K, V], 1),
+ comparator: comparator,
+ }
+ if collectStats {
+ m.stats = &JStatRec{
+ Source: cType,
+ Description: desc,
+ }
+ // Track where we created it from if we are being asked to do so
+ if runtimeConfig.statsTraceStacks {
+ m.stats.CreateStack = debug.Stack()
+ }
+ Statistics.AddJStatRec(m.stats)
+ }
+ return m
+}
+
+func (m *JMap[K, V, C]) Put(key K, val V) (V, bool) {
+ if collectStats {
+ m.stats.Puts++
+ }
+ kh := m.comparator.Hash1(key)
+
+ var hClash bool
+ for _, e := range m.store[kh] {
+ hClash = true
+ if m.comparator.Equals2(e.key, key) {
+ if collectStats {
+ m.stats.PutHits++
+ m.stats.PutHashConflicts++
+ }
+ return e.val, true
+ }
+ if collectStats {
+ m.stats.PutMisses++
+ }
+ }
+ if collectStats {
+ if hClash {
+ m.stats.PutHashConflicts++
+ }
+ }
+ m.store[kh] = append(m.store[kh], &entry[K, V]{key, val})
+ if collectStats {
+ if len(m.store[kh]) > m.stats.MaxSlotSize {
+ m.stats.MaxSlotSize = len(m.store[kh])
+ }
+ }
+ m.len++
+ if collectStats {
+ m.stats.CurSize = m.len
+ if m.len > m.stats.MaxSize {
+ m.stats.MaxSize = m.len
+ }
+ }
+ return val, false
+}
+
+func (m *JMap[K, V, C]) Values() []V {
+ vs := make([]V, 0, len(m.store))
+ for _, e := range m.store {
+ for _, v := range e {
+ vs = append(vs, v.val)
+ }
+ }
+ return vs
+}
+
+func (m *JMap[K, V, C]) Get(key K) (V, bool) {
+ if collectStats {
+ m.stats.Gets++
+ }
+ var none V
+ kh := m.comparator.Hash1(key)
+ var hClash bool
+ for _, e := range m.store[kh] {
+ hClash = true
+ if m.comparator.Equals2(e.key, key) {
+ if collectStats {
+ m.stats.GetHits++
+ m.stats.GetHashConflicts++
+ }
+ return e.val, true
+ }
+ if collectStats {
+ m.stats.GetMisses++
+ }
+ }
+ if collectStats {
+ if hClash {
+ m.stats.GetHashConflicts++
+ }
+ m.stats.GetNoEnt++
+ }
+ return none, false
+}
+
+func (m *JMap[K, V, C]) Len() int {
+ return m.len
+}
+
+func (m *JMap[K, V, C]) Delete(key K) {
+ kh := m.comparator.Hash1(key)
+ for i, e := range m.store[kh] {
+ if m.comparator.Equals2(e.key, key) {
+ m.store[kh] = append(m.store[kh][:i], m.store[kh][i+1:]...)
+ m.len--
+ return
+ }
+ }
+}
+
+func (m *JMap[K, V, C]) Clear() {
+ m.store = make(map[int][]*entry[K, V])
+}
+
+type JPCMap struct {
+ store *JMap[*PredictionContext, *JMap[*PredictionContext, *PredictionContext, *ObjEqComparator[*PredictionContext]], *ObjEqComparator[*PredictionContext]]
+ size int
+ stats *JStatRec
+}
+
+func NewJPCMap(cType CollectionSource, desc string) *JPCMap {
+ m := &JPCMap{
+ store: NewJMap[*PredictionContext, *JMap[*PredictionContext, *PredictionContext, *ObjEqComparator[*PredictionContext]], *ObjEqComparator[*PredictionContext]](pContextEqInst, cType, desc),
+ }
+ if collectStats {
+ m.stats = &JStatRec{
+ Source: cType,
+ Description: desc,
+ }
+ // Track where we created it from if we are being asked to do so
+ if runtimeConfig.statsTraceStacks {
+ m.stats.CreateStack = debug.Stack()
+ }
+ Statistics.AddJStatRec(m.stats)
+ }
+ return m
+}
+
+func (pcm *JPCMap) Get(k1, k2 *PredictionContext) (*PredictionContext, bool) {
+ if collectStats {
+ pcm.stats.Gets++
+ }
+ // Do we have a map stored by k1?
+ //
+ m2, present := pcm.store.Get(k1)
+ if present {
+ if collectStats {
+ pcm.stats.GetHits++
+ }
+ // We found a map of values corresponding to k1, so now we need to look up k2 in that map
+ //
+ return m2.Get(k2)
+ }
+ if collectStats {
+ pcm.stats.GetMisses++
+ }
+ return nil, false
+}
+
+func (pcm *JPCMap) Put(k1, k2, v *PredictionContext) {
+
+ if collectStats {
+ pcm.stats.Puts++
+ }
+ // First does a map already exist for k1?
+ //
+ if m2, present := pcm.store.Get(k1); present {
+ if collectStats {
+ pcm.stats.PutHits++
+ }
+ _, present = m2.Put(k2, v)
+ if !present {
+ pcm.size++
+ if collectStats {
+ pcm.stats.CurSize = pcm.size
+ if pcm.size > pcm.stats.MaxSize {
+ pcm.stats.MaxSize = pcm.size
+ }
+ }
+ }
+ } else {
+ // No map found for k1, so we create it, add in our value, then store is
+ //
+ if collectStats {
+ pcm.stats.PutMisses++
+ m2 = NewJMap[*PredictionContext, *PredictionContext, *ObjEqComparator[*PredictionContext]](pContextEqInst, pcm.stats.Source, pcm.stats.Description+" map entry")
+ } else {
+ m2 = NewJMap[*PredictionContext, *PredictionContext, *ObjEqComparator[*PredictionContext]](pContextEqInst, PredictionContextCacheCollection, "map entry")
+ }
+
+ m2.Put(k2, v)
+ pcm.store.Put(k1, m2)
+ pcm.size++
+ }
+}
+
+type JPCMap2 struct {
+ store map[int][]JPCEntry
+ size int
+ stats *JStatRec
+}
+
+type JPCEntry struct {
+ k1, k2, v *PredictionContext
+}
+
+func NewJPCMap2(cType CollectionSource, desc string) *JPCMap2 {
+ m := &JPCMap2{
+ store: make(map[int][]JPCEntry, 1000),
+ }
+ if collectStats {
+ m.stats = &JStatRec{
+ Source: cType,
+ Description: desc,
+ }
+ // Track where we created it from if we are being asked to do so
+ if runtimeConfig.statsTraceStacks {
+ m.stats.CreateStack = debug.Stack()
+ }
+ Statistics.AddJStatRec(m.stats)
+ }
+ return m
+}
+
+func dHash(k1, k2 *PredictionContext) int {
+ return k1.cachedHash*31 + k2.cachedHash
+}
+
+func (pcm *JPCMap2) Get(k1, k2 *PredictionContext) (*PredictionContext, bool) {
+ if collectStats {
+ pcm.stats.Gets++
+ }
+
+ h := dHash(k1, k2)
+ var hClash bool
+ for _, e := range pcm.store[h] {
+ hClash = true
+ if e.k1.Equals(k1) && e.k2.Equals(k2) {
+ if collectStats {
+ pcm.stats.GetHits++
+ pcm.stats.GetHashConflicts++
+ }
+ return e.v, true
+ }
+ if collectStats {
+ pcm.stats.GetMisses++
+ }
+ }
+ if collectStats {
+ if hClash {
+ pcm.stats.GetHashConflicts++
+ }
+ pcm.stats.GetNoEnt++
+ }
+ return nil, false
+}
+
+func (pcm *JPCMap2) Put(k1, k2, v *PredictionContext) (*PredictionContext, bool) {
+ if collectStats {
+ pcm.stats.Puts++
+ }
+ h := dHash(k1, k2)
+ var hClash bool
+ for _, e := range pcm.store[h] {
+ hClash = true
+ if e.k1.Equals(k1) && e.k2.Equals(k2) {
+ if collectStats {
+ pcm.stats.PutHits++
+ pcm.stats.PutHashConflicts++
+ }
+ return e.v, true
+ }
+ if collectStats {
+ pcm.stats.PutMisses++
+ }
+ }
+ if collectStats {
+ if hClash {
+ pcm.stats.PutHashConflicts++
+ }
+ }
+ pcm.store[h] = append(pcm.store[h], JPCEntry{k1, k2, v})
+ pcm.size++
+ if collectStats {
+ pcm.stats.CurSize = pcm.size
+ if pcm.size > pcm.stats.MaxSize {
+ pcm.stats.MaxSize = pcm.size
+ }
+ }
+ return nil, false
+}
+
+type VisitEntry struct {
+ k *PredictionContext
+ v *PredictionContext
+}
+type VisitRecord struct {
+ store map[*PredictionContext]*PredictionContext
+ len int
+ stats *JStatRec
+}
+
+type VisitList struct {
+ cache *list.List
+ lock sync.RWMutex
+}
+
+var visitListPool = VisitList{
+ cache: list.New(),
+ lock: sync.RWMutex{},
+}
+
+// NewVisitRecord returns a new VisitRecord instance from the pool if available.
+// Note that this "map" uses a pointer as a key because we are emulating the behavior of
+// IdentityHashMap in Java, which uses the `==` operator to compare whether the keys are equal,
+// which means is the key the same reference to an object rather than is it .equals() to another
+// object.
+func NewVisitRecord() *VisitRecord {
+ visitListPool.lock.Lock()
+ el := visitListPool.cache.Front()
+ defer visitListPool.lock.Unlock()
+ var vr *VisitRecord
+ if el == nil {
+ vr = &VisitRecord{
+ store: make(map[*PredictionContext]*PredictionContext),
+ }
+ if collectStats {
+ vr.stats = &JStatRec{
+ Source: PredictionContextCacheCollection,
+ Description: "VisitRecord",
+ }
+ // Track where we created it from if we are being asked to do so
+ if runtimeConfig.statsTraceStacks {
+ vr.stats.CreateStack = debug.Stack()
+ }
+ }
+ } else {
+ vr = el.Value.(*VisitRecord)
+ visitListPool.cache.Remove(el)
+ vr.store = make(map[*PredictionContext]*PredictionContext)
+ }
+ if collectStats {
+ Statistics.AddJStatRec(vr.stats)
+ }
+ return vr
+}
+
+func (vr *VisitRecord) Release() {
+ vr.len = 0
+ vr.store = nil
+ if collectStats {
+ vr.stats.MaxSize = 0
+ vr.stats.CurSize = 0
+ vr.stats.Gets = 0
+ vr.stats.GetHits = 0
+ vr.stats.GetMisses = 0
+ vr.stats.GetHashConflicts = 0
+ vr.stats.GetNoEnt = 0
+ vr.stats.Puts = 0
+ vr.stats.PutHits = 0
+ vr.stats.PutMisses = 0
+ vr.stats.PutHashConflicts = 0
+ vr.stats.MaxSlotSize = 0
+ }
+ visitListPool.lock.Lock()
+ visitListPool.cache.PushBack(vr)
+ visitListPool.lock.Unlock()
+}
+
+func (vr *VisitRecord) Get(k *PredictionContext) (*PredictionContext, bool) {
+ if collectStats {
+ vr.stats.Gets++
+ }
+ v := vr.store[k]
+ if v != nil {
+ if collectStats {
+ vr.stats.GetHits++
+ }
+ return v, true
+ }
+ if collectStats {
+ vr.stats.GetNoEnt++
+ }
+ return nil, false
+}
+
+func (vr *VisitRecord) Put(k, v *PredictionContext) (*PredictionContext, bool) {
+ if collectStats {
+ vr.stats.Puts++
+ }
+ vr.store[k] = v
+ vr.len++
+ if collectStats {
+ vr.stats.CurSize = vr.len
+ if vr.len > vr.stats.MaxSize {
+ vr.stats.MaxSize = vr.len
+ }
+ }
+ return v, false
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/lexer.go b/vendor/github.com/antlr4-go/antlr/v4/lexer.go
new file mode 100644
index 000000000000..3c7896a9183d
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/lexer.go
@@ -0,0 +1,426 @@
+// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
+// Use of this file is governed by the BSD 3-clause license that
+// can be found in the LICENSE.txt file in the project root.
+
+package antlr
+
+import (
+ "fmt"
+ "strconv"
+)
+
+// A lexer is recognizer that draws input symbols from a character stream.
+// lexer grammars result in a subclass of this object. A Lexer object
+// uses simplified Match() and error recovery mechanisms in the interest
+// of speed.
+///
+
+type Lexer interface {
+ TokenSource
+ Recognizer
+
+ Emit() Token
+
+ SetChannel(int)
+ PushMode(int)
+ PopMode() int
+ SetType(int)
+ SetMode(int)
+}
+
+type BaseLexer struct {
+ *BaseRecognizer
+
+ Interpreter ILexerATNSimulator
+ TokenStartCharIndex int
+ TokenStartLine int
+ TokenStartColumn int
+ ActionType int
+ Virt Lexer // The most derived lexer implementation. Allows virtual method calls.
+
+ input CharStream
+ factory TokenFactory
+ tokenFactorySourcePair *TokenSourceCharStreamPair
+ token Token
+ hitEOF bool
+ channel int
+ thetype int
+ modeStack IntStack
+ mode int
+ text string
+}
+
+func NewBaseLexer(input CharStream) *BaseLexer {
+
+ lexer := new(BaseLexer)
+
+ lexer.BaseRecognizer = NewBaseRecognizer()
+
+ lexer.input = input
+ lexer.factory = CommonTokenFactoryDEFAULT
+ lexer.tokenFactorySourcePair = &TokenSourceCharStreamPair{lexer, input}
+
+ lexer.Virt = lexer
+
+ lexer.Interpreter = nil // child classes must populate it
+
+ // The goal of all lexer rules/methods is to create a token object.
+ // l is an instance variable as multiple rules may collaborate to
+ // create a single token. NextToken will return l object after
+ // Matching lexer rule(s). If you subclass to allow multiple token
+ // emissions, then set l to the last token to be Matched or
+ // something non nil so that the auto token emit mechanism will not
+ // emit another token.
+ lexer.token = nil
+
+ // What character index in the stream did the current token start at?
+ // Needed, for example, to get the text for current token. Set at
+ // the start of NextToken.
+ lexer.TokenStartCharIndex = -1
+
+ // The line on which the first character of the token resides///
+ lexer.TokenStartLine = -1
+
+ // The character position of first character within the line///
+ lexer.TokenStartColumn = -1
+
+ // Once we see EOF on char stream, next token will be EOF.
+ // If you have DONE : EOF then you see DONE EOF.
+ lexer.hitEOF = false
+
+ // The channel number for the current token///
+ lexer.channel = TokenDefaultChannel
+
+ // The token type for the current token///
+ lexer.thetype = TokenInvalidType
+
+ lexer.modeStack = make([]int, 0)
+ lexer.mode = LexerDefaultMode
+
+ // You can set the text for the current token to override what is in
+ // the input char buffer. Use setText() or can set l instance var.
+ // /
+ lexer.text = ""
+
+ return lexer
+}
+
+const (
+ LexerDefaultMode = 0
+ LexerMore = -2
+ LexerSkip = -3
+)
+
+//goland:noinspection GoUnusedConst
+const (
+ LexerDefaultTokenChannel = TokenDefaultChannel
+ LexerHidden = TokenHiddenChannel
+ LexerMinCharValue = 0x0000
+ LexerMaxCharValue = 0x10FFFF
+)
+
+func (b *BaseLexer) Reset() {
+ // wack Lexer state variables
+ if b.input != nil {
+ b.input.Seek(0) // rewind the input
+ }
+ b.token = nil
+ b.thetype = TokenInvalidType
+ b.channel = TokenDefaultChannel
+ b.TokenStartCharIndex = -1
+ b.TokenStartColumn = -1
+ b.TokenStartLine = -1
+ b.text = ""
+
+ b.hitEOF = false
+ b.mode = LexerDefaultMode
+ b.modeStack = make([]int, 0)
+
+ b.Interpreter.reset()
+}
+
+func (b *BaseLexer) GetInterpreter() ILexerATNSimulator {
+ return b.Interpreter
+}
+
+func (b *BaseLexer) GetInputStream() CharStream {
+ return b.input
+}
+
+func (b *BaseLexer) GetSourceName() string {
+ return b.GrammarFileName
+}
+
+func (b *BaseLexer) SetChannel(v int) {
+ b.channel = v
+}
+
+func (b *BaseLexer) GetTokenFactory() TokenFactory {
+ return b.factory
+}
+
+func (b *BaseLexer) setTokenFactory(f TokenFactory) {
+ b.factory = f
+}
+
+func (b *BaseLexer) safeMatch() (ret int) {
+ defer func() {
+ if e := recover(); e != nil {
+ if re, ok := e.(RecognitionException); ok {
+ b.notifyListeners(re) // Report error
+ b.Recover(re)
+ ret = LexerSkip // default
+ }
+ }
+ }()
+
+ return b.Interpreter.Match(b.input, b.mode)
+}
+
+// NextToken returns a token from the lexer input source i.e., Match a token on the source char stream.
+func (b *BaseLexer) NextToken() Token {
+ if b.input == nil {
+ panic("NextToken requires a non-nil input stream.")
+ }
+
+ tokenStartMarker := b.input.Mark()
+
+ // previously in finally block
+ defer func() {
+ // make sure we release marker after Match or
+ // unbuffered char stream will keep buffering
+ b.input.Release(tokenStartMarker)
+ }()
+
+ for {
+ if b.hitEOF {
+ b.EmitEOF()
+ return b.token
+ }
+ b.token = nil
+ b.channel = TokenDefaultChannel
+ b.TokenStartCharIndex = b.input.Index()
+ b.TokenStartColumn = b.Interpreter.GetCharPositionInLine()
+ b.TokenStartLine = b.Interpreter.GetLine()
+ b.text = ""
+ continueOuter := false
+ for {
+ b.thetype = TokenInvalidType
+
+ ttype := b.safeMatch()
+
+ if b.input.LA(1) == TokenEOF {
+ b.hitEOF = true
+ }
+ if b.thetype == TokenInvalidType {
+ b.thetype = ttype
+ }
+ if b.thetype == LexerSkip {
+ continueOuter = true
+ break
+ }
+ if b.thetype != LexerMore {
+ break
+ }
+ }
+
+ if continueOuter {
+ continue
+ }
+ if b.token == nil {
+ b.Virt.Emit()
+ }
+ return b.token
+ }
+}
+
+// Skip instructs the lexer to Skip creating a token for current lexer rule
+// and look for another token. [NextToken] knows to keep looking when
+// a lexer rule finishes with token set to [SKIPTOKEN]. Recall that
+// if token==nil at end of any token rule, it creates one for you
+// and emits it.
+func (b *BaseLexer) Skip() {
+ b.thetype = LexerSkip
+}
+
+func (b *BaseLexer) More() {
+ b.thetype = LexerMore
+}
+
+// SetMode changes the lexer to a new mode. The lexer will use this mode from hereon in and the rules for that mode
+// will be in force.
+func (b *BaseLexer) SetMode(m int) {
+ b.mode = m
+}
+
+// PushMode saves the current lexer mode so that it can be restored later. See [PopMode], then sets the
+// current lexer mode to the supplied mode m.
+func (b *BaseLexer) PushMode(m int) {
+ if runtimeConfig.lexerATNSimulatorDebug {
+ fmt.Println("pushMode " + strconv.Itoa(m))
+ }
+ b.modeStack.Push(b.mode)
+ b.mode = m
+}
+
+// PopMode restores the lexer mode saved by a call to [PushMode]. It is a panic error if there is no saved mode to
+// return to.
+func (b *BaseLexer) PopMode() int {
+ if len(b.modeStack) == 0 {
+ panic("Empty Stack")
+ }
+ if runtimeConfig.lexerATNSimulatorDebug {
+ fmt.Println("popMode back to " + fmt.Sprint(b.modeStack[0:len(b.modeStack)-1]))
+ }
+ i, _ := b.modeStack.Pop()
+ b.mode = i
+ return b.mode
+}
+
+func (b *BaseLexer) inputStream() CharStream {
+ return b.input
+}
+
+// SetInputStream resets the lexer input stream and associated lexer state.
+func (b *BaseLexer) SetInputStream(input CharStream) {
+ b.input = nil
+ b.tokenFactorySourcePair = &TokenSourceCharStreamPair{b, b.input}
+ b.Reset()
+ b.input = input
+ b.tokenFactorySourcePair = &TokenSourceCharStreamPair{b, b.input}
+}
+
+func (b *BaseLexer) GetTokenSourceCharStreamPair() *TokenSourceCharStreamPair {
+ return b.tokenFactorySourcePair
+}
+
+// EmitToken by default does not support multiple emits per [NextToken] invocation
+// for efficiency reasons. Subclass and override this func, [NextToken],
+// and [GetToken] (to push tokens into a list and pull from that list
+// rather than a single variable as this implementation does).
+func (b *BaseLexer) EmitToken(token Token) {
+ b.token = token
+}
+
+// Emit is the standard method called to automatically emit a token at the
+// outermost lexical rule. The token object should point into the
+// char buffer start..stop. If there is a text override in 'text',
+// use that to set the token's text. Override this method to emit
+// custom [Token] objects or provide a new factory.
+// /
+func (b *BaseLexer) Emit() Token {
+ t := b.factory.Create(b.tokenFactorySourcePair, b.thetype, b.text, b.channel, b.TokenStartCharIndex, b.GetCharIndex()-1, b.TokenStartLine, b.TokenStartColumn)
+ b.EmitToken(t)
+ return t
+}
+
+// EmitEOF emits an EOF token. By default, this is the last token emitted
+func (b *BaseLexer) EmitEOF() Token {
+ cpos := b.GetCharPositionInLine()
+ lpos := b.GetLine()
+ eof := b.factory.Create(b.tokenFactorySourcePair, TokenEOF, "", TokenDefaultChannel, b.input.Index(), b.input.Index()-1, lpos, cpos)
+ b.EmitToken(eof)
+ return eof
+}
+
+// GetCharPositionInLine returns the current position in the current line as far as the lexer is concerned.
+func (b *BaseLexer) GetCharPositionInLine() int {
+ return b.Interpreter.GetCharPositionInLine()
+}
+
+func (b *BaseLexer) GetLine() int {
+ return b.Interpreter.GetLine()
+}
+
+func (b *BaseLexer) GetType() int {
+ return b.thetype
+}
+
+func (b *BaseLexer) SetType(t int) {
+ b.thetype = t
+}
+
+// GetCharIndex returns the index of the current character of lookahead
+func (b *BaseLexer) GetCharIndex() int {
+ return b.input.Index()
+}
+
+// GetText returns the text Matched so far for the current token or any text override.
+func (b *BaseLexer) GetText() string {
+ if b.text != "" {
+ return b.text
+ }
+
+ return b.Interpreter.GetText(b.input)
+}
+
+// SetText sets the complete text of this token; it wipes any previous changes to the text.
+func (b *BaseLexer) SetText(text string) {
+ b.text = text
+}
+
+// GetATN returns the ATN used by the lexer.
+func (b *BaseLexer) GetATN() *ATN {
+ return b.Interpreter.ATN()
+}
+
+// GetAllTokens returns a list of all [Token] objects in input char stream.
+// Forces a load of all tokens that can be made from the input char stream.
+//
+// Does not include EOF token.
+func (b *BaseLexer) GetAllTokens() []Token {
+ vl := b.Virt
+ tokens := make([]Token, 0)
+ t := vl.NextToken()
+ for t.GetTokenType() != TokenEOF {
+ tokens = append(tokens, t)
+ t = vl.NextToken()
+ }
+ return tokens
+}
+
+func (b *BaseLexer) notifyListeners(e RecognitionException) {
+ start := b.TokenStartCharIndex
+ stop := b.input.Index()
+ text := b.input.GetTextFromInterval(NewInterval(start, stop))
+ msg := "token recognition error at: '" + text + "'"
+ listener := b.GetErrorListenerDispatch()
+ listener.SyntaxError(b, nil, b.TokenStartLine, b.TokenStartColumn, msg, e)
+}
+
+func (b *BaseLexer) getErrorDisplayForChar(c rune) string {
+ if c == TokenEOF {
+ return ""
+ } else if c == '\n' {
+ return "\\n"
+ } else if c == '\t' {
+ return "\\t"
+ } else if c == '\r' {
+ return "\\r"
+ } else {
+ return string(c)
+ }
+}
+
+func (b *BaseLexer) getCharErrorDisplay(c rune) string {
+ return "'" + b.getErrorDisplayForChar(c) + "'"
+}
+
+// Recover can normally Match any char in its vocabulary after Matching
+// a token, so here we do the easy thing and just kill a character and hope
+// it all works out. You can instead use the rule invocation stack
+// to do sophisticated error recovery if you are in a fragment rule.
+//
+// In general, lexers should not need to recover and should have rules that cover any eventuality, such as
+// a character that makes no sense to the recognizer.
+func (b *BaseLexer) Recover(re RecognitionException) {
+ if b.input.LA(1) != TokenEOF {
+ if _, ok := re.(*LexerNoViableAltException); ok {
+ // Skip a char and try again
+ b.Interpreter.Consume(b.input)
+ } else {
+ // TODO: Do we lose character or line position information?
+ b.input.Consume()
+ }
+ }
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/lexer_action.go b/vendor/github.com/antlr4-go/antlr/v4/lexer_action.go
new file mode 100644
index 000000000000..eaa7393e06f7
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/lexer_action.go
@@ -0,0 +1,452 @@
+// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
+// Use of this file is governed by the BSD 3-clause license that
+// can be found in the LICENSE.txt file in the project root.
+
+package antlr
+
+import "strconv"
+
+const (
+ // LexerActionTypeChannel represents a [LexerChannelAction] action.
+ LexerActionTypeChannel = 0
+
+ // LexerActionTypeCustom represents a [LexerCustomAction] action.
+ LexerActionTypeCustom = 1
+
+ // LexerActionTypeMode represents a [LexerModeAction] action.
+ LexerActionTypeMode = 2
+
+ // LexerActionTypeMore represents a [LexerMoreAction] action.
+ LexerActionTypeMore = 3
+
+ // LexerActionTypePopMode represents a [LexerPopModeAction] action.
+ LexerActionTypePopMode = 4
+
+ // LexerActionTypePushMode represents a [LexerPushModeAction] action.
+ LexerActionTypePushMode = 5
+
+ // LexerActionTypeSkip represents a [LexerSkipAction] action.
+ LexerActionTypeSkip = 6
+
+ // LexerActionTypeType represents a [LexerTypeAction] action.
+ LexerActionTypeType = 7
+)
+
+type LexerAction interface {
+ getActionType() int
+ getIsPositionDependent() bool
+ execute(lexer Lexer)
+ Hash() int
+ Equals(other LexerAction) bool
+}
+
+type BaseLexerAction struct {
+ actionType int
+ isPositionDependent bool
+}
+
+func NewBaseLexerAction(action int) *BaseLexerAction {
+ la := new(BaseLexerAction)
+
+ la.actionType = action
+ la.isPositionDependent = false
+
+ return la
+}
+
+func (b *BaseLexerAction) execute(_ Lexer) {
+ panic("Not implemented")
+}
+
+func (b *BaseLexerAction) getActionType() int {
+ return b.actionType
+}
+
+func (b *BaseLexerAction) getIsPositionDependent() bool {
+ return b.isPositionDependent
+}
+
+func (b *BaseLexerAction) Hash() int {
+ h := murmurInit(0)
+ h = murmurUpdate(h, b.actionType)
+ return murmurFinish(h, 1)
+}
+
+func (b *BaseLexerAction) Equals(other LexerAction) bool {
+ return b.actionType == other.getActionType()
+}
+
+// LexerSkipAction implements the [BaseLexerAction.Skip] lexer action by calling [Lexer.Skip].
+//
+// The Skip command does not have any parameters, so this action is
+// implemented as a singleton instance exposed by the [LexerSkipActionINSTANCE].
+type LexerSkipAction struct {
+ *BaseLexerAction
+}
+
+func NewLexerSkipAction() *LexerSkipAction {
+ la := new(LexerSkipAction)
+ la.BaseLexerAction = NewBaseLexerAction(LexerActionTypeSkip)
+ return la
+}
+
+// LexerSkipActionINSTANCE provides a singleton instance of this parameterless lexer action.
+var LexerSkipActionINSTANCE = NewLexerSkipAction()
+
+func (l *LexerSkipAction) execute(lexer Lexer) {
+ lexer.Skip()
+}
+
+// String returns a string representation of the current [LexerSkipAction].
+func (l *LexerSkipAction) String() string {
+ return "skip"
+}
+
+func (b *LexerSkipAction) Equals(other LexerAction) bool {
+ return other.getActionType() == LexerActionTypeSkip
+}
+
+// Implements the {@code type} lexer action by calling {@link Lexer//setType}
+//
+// with the assigned type.
+type LexerTypeAction struct {
+ *BaseLexerAction
+
+ thetype int
+}
+
+func NewLexerTypeAction(thetype int) *LexerTypeAction {
+ l := new(LexerTypeAction)
+ l.BaseLexerAction = NewBaseLexerAction(LexerActionTypeType)
+ l.thetype = thetype
+ return l
+}
+
+func (l *LexerTypeAction) execute(lexer Lexer) {
+ lexer.SetType(l.thetype)
+}
+
+func (l *LexerTypeAction) Hash() int {
+ h := murmurInit(0)
+ h = murmurUpdate(h, l.actionType)
+ h = murmurUpdate(h, l.thetype)
+ return murmurFinish(h, 2)
+}
+
+func (l *LexerTypeAction) Equals(other LexerAction) bool {
+ if l == other {
+ return true
+ } else if _, ok := other.(*LexerTypeAction); !ok {
+ return false
+ } else {
+ return l.thetype == other.(*LexerTypeAction).thetype
+ }
+}
+
+func (l *LexerTypeAction) String() string {
+ return "actionType(" + strconv.Itoa(l.thetype) + ")"
+}
+
+// LexerPushModeAction implements the pushMode lexer action by calling
+// [Lexer.pushMode] with the assigned mode.
+type LexerPushModeAction struct {
+ *BaseLexerAction
+ mode int
+}
+
+func NewLexerPushModeAction(mode int) *LexerPushModeAction {
+
+ l := new(LexerPushModeAction)
+ l.BaseLexerAction = NewBaseLexerAction(LexerActionTypePushMode)
+
+ l.mode = mode
+ return l
+}
+
+//
This action is implemented by calling {@link Lexer//pushMode} with the
+// value provided by {@link //getMode}.
+func (l *LexerPushModeAction) execute(lexer Lexer) {
+ lexer.PushMode(l.mode)
+}
+
+func (l *LexerPushModeAction) Hash() int {
+ h := murmurInit(0)
+ h = murmurUpdate(h, l.actionType)
+ h = murmurUpdate(h, l.mode)
+ return murmurFinish(h, 2)
+}
+
+func (l *LexerPushModeAction) Equals(other LexerAction) bool {
+ if l == other {
+ return true
+ } else if _, ok := other.(*LexerPushModeAction); !ok {
+ return false
+ } else {
+ return l.mode == other.(*LexerPushModeAction).mode
+ }
+}
+
+func (l *LexerPushModeAction) String() string {
+ return "pushMode(" + strconv.Itoa(l.mode) + ")"
+}
+
+// LexerPopModeAction implements the popMode lexer action by calling [Lexer.popMode].
+//
+// The popMode command does not have any parameters, so this action is
+// implemented as a singleton instance exposed by [LexerPopModeActionINSTANCE]
+type LexerPopModeAction struct {
+ *BaseLexerAction
+}
+
+func NewLexerPopModeAction() *LexerPopModeAction {
+
+ l := new(LexerPopModeAction)
+
+ l.BaseLexerAction = NewBaseLexerAction(LexerActionTypePopMode)
+
+ return l
+}
+
+var LexerPopModeActionINSTANCE = NewLexerPopModeAction()
+
+//
This action is implemented by calling {@link Lexer//popMode}.
This action is implemented by calling {@link Lexer//popMode}.
+func (l *LexerMoreAction) execute(lexer Lexer) {
+ lexer.More()
+}
+
+func (l *LexerMoreAction) String() string {
+ return "more"
+}
+
+// LexerModeAction implements the mode lexer action by calling [Lexer.mode] with
+// the assigned mode.
+type LexerModeAction struct {
+ *BaseLexerAction
+ mode int
+}
+
+func NewLexerModeAction(mode int) *LexerModeAction {
+ l := new(LexerModeAction)
+ l.BaseLexerAction = NewBaseLexerAction(LexerActionTypeMode)
+ l.mode = mode
+ return l
+}
+
+//
This action is implemented by calling {@link Lexer//mode} with the
+// value provided by {@link //getMode}.
+func (l *LexerModeAction) execute(lexer Lexer) {
+ lexer.SetMode(l.mode)
+}
+
+func (l *LexerModeAction) Hash() int {
+ h := murmurInit(0)
+ h = murmurUpdate(h, l.actionType)
+ h = murmurUpdate(h, l.mode)
+ return murmurFinish(h, 2)
+}
+
+func (l *LexerModeAction) Equals(other LexerAction) bool {
+ if l == other {
+ return true
+ } else if _, ok := other.(*LexerModeAction); !ok {
+ return false
+ } else {
+ return l.mode == other.(*LexerModeAction).mode
+ }
+}
+
+func (l *LexerModeAction) String() string {
+ return "mode(" + strconv.Itoa(l.mode) + ")"
+}
+
+// Executes a custom lexer action by calling {@link Recognizer//action} with the
+// rule and action indexes assigned to the custom action. The implementation of
+// a custom action is added to the generated code for the lexer in an override
+// of {@link Recognizer//action} when the grammar is compiled.
+//
+//
This class may represent embedded actions created with the {...}
+// syntax in ANTLR 4, as well as actions created for lexer commands where the
+// command argument could not be evaluated when the grammar was compiled.
+
+// Constructs a custom lexer action with the specified rule and action
+// indexes.
+//
+// @param ruleIndex The rule index to use for calls to
+// {@link Recognizer//action}.
+// @param actionIndex The action index to use for calls to
+// {@link Recognizer//action}.
+
+type LexerCustomAction struct {
+ *BaseLexerAction
+ ruleIndex, actionIndex int
+}
+
+func NewLexerCustomAction(ruleIndex, actionIndex int) *LexerCustomAction {
+ l := new(LexerCustomAction)
+ l.BaseLexerAction = NewBaseLexerAction(LexerActionTypeCustom)
+ l.ruleIndex = ruleIndex
+ l.actionIndex = actionIndex
+ l.isPositionDependent = true
+ return l
+}
+
+//
Custom actions are implemented by calling {@link Lexer//action} with the
+// appropriate rule and action indexes.
+func (l *LexerCustomAction) execute(lexer Lexer) {
+ lexer.Action(nil, l.ruleIndex, l.actionIndex)
+}
+
+func (l *LexerCustomAction) Hash() int {
+ h := murmurInit(0)
+ h = murmurUpdate(h, l.actionType)
+ h = murmurUpdate(h, l.ruleIndex)
+ h = murmurUpdate(h, l.actionIndex)
+ return murmurFinish(h, 3)
+}
+
+func (l *LexerCustomAction) Equals(other LexerAction) bool {
+ if l == other {
+ return true
+ } else if _, ok := other.(*LexerCustomAction); !ok {
+ return false
+ } else {
+ return l.ruleIndex == other.(*LexerCustomAction).ruleIndex &&
+ l.actionIndex == other.(*LexerCustomAction).actionIndex
+ }
+}
+
+// LexerChannelAction implements the channel lexer action by calling
+// [Lexer.setChannel] with the assigned channel.
+//
+// Constructs a new channel action with the specified channel value.
+type LexerChannelAction struct {
+ *BaseLexerAction
+ channel int
+}
+
+// NewLexerChannelAction creates a channel lexer action by calling
+// [Lexer.setChannel] with the assigned channel.
+//
+// Constructs a new channel action with the specified channel value.
+func NewLexerChannelAction(channel int) *LexerChannelAction {
+ l := new(LexerChannelAction)
+ l.BaseLexerAction = NewBaseLexerAction(LexerActionTypeChannel)
+ l.channel = channel
+ return l
+}
+
+//
This action is implemented by calling {@link Lexer//setChannel} with the
+// value provided by {@link //getChannel}.
+func (l *LexerChannelAction) execute(lexer Lexer) {
+ lexer.SetChannel(l.channel)
+}
+
+func (l *LexerChannelAction) Hash() int {
+ h := murmurInit(0)
+ h = murmurUpdate(h, l.actionType)
+ h = murmurUpdate(h, l.channel)
+ return murmurFinish(h, 2)
+}
+
+func (l *LexerChannelAction) Equals(other LexerAction) bool {
+ if l == other {
+ return true
+ } else if _, ok := other.(*LexerChannelAction); !ok {
+ return false
+ } else {
+ return l.channel == other.(*LexerChannelAction).channel
+ }
+}
+
+func (l *LexerChannelAction) String() string {
+ return "channel(" + strconv.Itoa(l.channel) + ")"
+}
+
+// This implementation of {@link LexerAction} is used for tracking input offsets
+// for position-dependent actions within a {@link LexerActionExecutor}.
+//
+//
This action is not serialized as part of the ATN, and is only required for
+// position-dependent lexer actions which appear at a location other than the
+// end of a rule. For more information about DFA optimizations employed for
+// lexer actions, see {@link LexerActionExecutor//append} and
+// {@link LexerActionExecutor//fixOffsetBeforeMatch}.
+
+type LexerIndexedCustomAction struct {
+ *BaseLexerAction
+ offset int
+ lexerAction LexerAction
+ isPositionDependent bool
+}
+
+// NewLexerIndexedCustomAction constructs a new indexed custom action by associating a character offset
+// with a [LexerAction].
+//
+// Note: This class is only required for lexer actions for which
+// [LexerAction.isPositionDependent] returns true.
+//
+// The offset points into the input [CharStream], relative to
+// the token start index, at which the specified lexerAction should be
+// executed.
+func NewLexerIndexedCustomAction(offset int, lexerAction LexerAction) *LexerIndexedCustomAction {
+
+ l := new(LexerIndexedCustomAction)
+ l.BaseLexerAction = NewBaseLexerAction(lexerAction.getActionType())
+
+ l.offset = offset
+ l.lexerAction = lexerAction
+ l.isPositionDependent = true
+
+ return l
+}
+
+//
This method calls {@link //execute} on the result of {@link //getAction}
+// using the provided {@code lexer}.
+func (l *LexerIndexedCustomAction) execute(lexer Lexer) {
+ // assume the input stream position was properly set by the calling code
+ l.lexerAction.execute(lexer)
+}
+
+func (l *LexerIndexedCustomAction) Hash() int {
+ h := murmurInit(0)
+ h = murmurUpdate(h, l.offset)
+ h = murmurUpdate(h, l.lexerAction.Hash())
+ return murmurFinish(h, 2)
+}
+
+func (l *LexerIndexedCustomAction) equals(other LexerAction) bool {
+ if l == other {
+ return true
+ } else if _, ok := other.(*LexerIndexedCustomAction); !ok {
+ return false
+ } else {
+ return l.offset == other.(*LexerIndexedCustomAction).offset &&
+ l.lexerAction.Equals(other.(*LexerIndexedCustomAction).lexerAction)
+ }
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/lexer_action_executor.go b/vendor/github.com/antlr4-go/antlr/v4/lexer_action_executor.go
new file mode 100644
index 000000000000..dfc28c32b30e
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/lexer_action_executor.go
@@ -0,0 +1,173 @@
+// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
+// Use of this file is governed by the BSD 3-clause license that
+// can be found in the LICENSE.txt file in the project root.
+
+package antlr
+
+import "golang.org/x/exp/slices"
+
+// Represents an executor for a sequence of lexer actions which traversed during
+// the Matching operation of a lexer rule (token).
+//
+//
The executor tracks position information for position-dependent lexer actions
+// efficiently, ensuring that actions appearing only at the end of the rule do
+// not cause bloating of the {@link DFA} created for the lexer.
+
+type LexerActionExecutor struct {
+ lexerActions []LexerAction
+ cachedHash int
+}
+
+func NewLexerActionExecutor(lexerActions []LexerAction) *LexerActionExecutor {
+
+ if lexerActions == nil {
+ lexerActions = make([]LexerAction, 0)
+ }
+
+ l := new(LexerActionExecutor)
+
+ l.lexerActions = lexerActions
+
+ // Caches the result of {@link //hashCode} since the hash code is an element
+ // of the performance-critical {@link ATNConfig//hashCode} operation.
+ l.cachedHash = murmurInit(0)
+ for _, a := range lexerActions {
+ l.cachedHash = murmurUpdate(l.cachedHash, a.Hash())
+ }
+ l.cachedHash = murmurFinish(l.cachedHash, len(lexerActions))
+
+ return l
+}
+
+// LexerActionExecutorappend creates a [LexerActionExecutor] which executes the actions for
+// the input [LexerActionExecutor] followed by a specified
+// [LexerAction].
+// TODO: This does not match the Java code
+func LexerActionExecutorappend(lexerActionExecutor *LexerActionExecutor, lexerAction LexerAction) *LexerActionExecutor {
+ if lexerActionExecutor == nil {
+ return NewLexerActionExecutor([]LexerAction{lexerAction})
+ }
+
+ return NewLexerActionExecutor(append(lexerActionExecutor.lexerActions, lexerAction))
+}
+
+// fixOffsetBeforeMatch creates a [LexerActionExecutor] which encodes the current offset
+// for position-dependent lexer actions.
+//
+// Normally, when the executor encounters lexer actions where
+// [LexerAction.isPositionDependent] returns true, it calls
+// [IntStream.Seek] on the input [CharStream] to set the input
+// position to the end of the current token. This behavior provides
+// for efficient [DFA] representation of lexer actions which appear at the end
+// of a lexer rule, even when the lexer rule Matches a variable number of
+// characters.
+//
+// Prior to traversing a Match transition in the [ATN], the current offset
+// from the token start index is assigned to all position-dependent lexer
+// actions which have not already been assigned a fixed offset. By storing
+// the offsets relative to the token start index, the [DFA] representation of
+// lexer actions which appear in the middle of tokens remains efficient due
+// to sharing among tokens of the same Length, regardless of their absolute
+// position in the input stream.
+//
+// If the current executor already has offsets assigned to all
+// position-dependent lexer actions, the method returns this instance.
+//
+// The offset is assigned to all position-dependent
+// lexer actions which do not already have offsets assigned.
+//
+// The func returns a [LexerActionExecutor] that stores input stream offsets
+// for all position-dependent lexer actions.
+func (l *LexerActionExecutor) fixOffsetBeforeMatch(offset int) *LexerActionExecutor {
+ var updatedLexerActions []LexerAction
+ for i := 0; i < len(l.lexerActions); i++ {
+ _, ok := l.lexerActions[i].(*LexerIndexedCustomAction)
+ if l.lexerActions[i].getIsPositionDependent() && !ok {
+ if updatedLexerActions == nil {
+ updatedLexerActions = make([]LexerAction, 0, len(l.lexerActions))
+ updatedLexerActions = append(updatedLexerActions, l.lexerActions...)
+ }
+ updatedLexerActions[i] = NewLexerIndexedCustomAction(offset, l.lexerActions[i])
+ }
+ }
+ if updatedLexerActions == nil {
+ return l
+ }
+
+ return NewLexerActionExecutor(updatedLexerActions)
+}
+
+// Execute the actions encapsulated by l executor within the context of a
+// particular {@link Lexer}.
+//
+//
This method calls {@link IntStream//seek} to set the position of the
+// {@code input} {@link CharStream} prior to calling
+// {@link LexerAction//execute} on a position-dependent action. Before the
+// method returns, the input position will be restored to the same position
+// it was in when the method was invoked.
+//
+// @param lexer The lexer instance.
+// @param input The input stream which is the source for the current token.
+// When l method is called, the current {@link IntStream//index} for
+// {@code input} should be the start of the following token, i.e. 1
+// character past the end of the current token.
+// @param startIndex The token start index. This value may be passed to
+// {@link IntStream//seek} to set the {@code input} position to the beginning
+// of the token.
+// /
+func (l *LexerActionExecutor) execute(lexer Lexer, input CharStream, startIndex int) {
+ requiresSeek := false
+ stopIndex := input.Index()
+
+ defer func() {
+ if requiresSeek {
+ input.Seek(stopIndex)
+ }
+ }()
+
+ for i := 0; i < len(l.lexerActions); i++ {
+ lexerAction := l.lexerActions[i]
+ if la, ok := lexerAction.(*LexerIndexedCustomAction); ok {
+ offset := la.offset
+ input.Seek(startIndex + offset)
+ lexerAction = la.lexerAction
+ requiresSeek = (startIndex + offset) != stopIndex
+ } else if lexerAction.getIsPositionDependent() {
+ input.Seek(stopIndex)
+ requiresSeek = false
+ }
+ lexerAction.execute(lexer)
+ }
+}
+
+func (l *LexerActionExecutor) Hash() int {
+ if l == nil {
+ // TODO: Why is this here? l should not be nil
+ return 61
+ }
+
+ // TODO: This is created from the action itself when the struct is created - will this be an issue at some point? Java uses the runtime assign hashcode
+ return l.cachedHash
+}
+
+func (l *LexerActionExecutor) Equals(other interface{}) bool {
+ if l == other {
+ return true
+ }
+ othert, ok := other.(*LexerActionExecutor)
+ if !ok {
+ return false
+ }
+ if othert == nil {
+ return false
+ }
+ if l.cachedHash != othert.cachedHash {
+ return false
+ }
+ if len(l.lexerActions) != len(othert.lexerActions) {
+ return false
+ }
+ return slices.EqualFunc(l.lexerActions, othert.lexerActions, func(i, j LexerAction) bool {
+ return i.Equals(j)
+ })
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/lexer_atn_simulator.go b/vendor/github.com/antlr4-go/antlr/v4/lexer_atn_simulator.go
new file mode 100644
index 000000000000..fe938b0259a0
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/lexer_atn_simulator.go
@@ -0,0 +1,677 @@
+// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
+// Use of this file is governed by the BSD 3-clause license that
+// can be found in the LICENSE.txt file in the project root.
+
+package antlr
+
+import (
+ "fmt"
+ "strconv"
+ "strings"
+)
+
+//goland:noinspection GoUnusedGlobalVariable
+var (
+ LexerATNSimulatorMinDFAEdge = 0
+ LexerATNSimulatorMaxDFAEdge = 127 // forces unicode to stay in ATN
+
+ LexerATNSimulatorMatchCalls = 0
+)
+
+type ILexerATNSimulator interface {
+ IATNSimulator
+
+ reset()
+ Match(input CharStream, mode int) int
+ GetCharPositionInLine() int
+ GetLine() int
+ GetText(input CharStream) string
+ Consume(input CharStream)
+}
+
+type LexerATNSimulator struct {
+ BaseATNSimulator
+
+ recog Lexer
+ predictionMode int
+ mergeCache *JPCMap2
+ startIndex int
+ Line int
+ CharPositionInLine int
+ mode int
+ prevAccept *SimState
+ MatchCalls int
+}
+
+func NewLexerATNSimulator(recog Lexer, atn *ATN, decisionToDFA []*DFA, sharedContextCache *PredictionContextCache) *LexerATNSimulator {
+ l := &LexerATNSimulator{
+ BaseATNSimulator: BaseATNSimulator{
+ atn: atn,
+ sharedContextCache: sharedContextCache,
+ },
+ }
+
+ l.decisionToDFA = decisionToDFA
+ l.recog = recog
+
+ // The current token's starting index into the character stream.
+ // Shared across DFA to ATN simulation in case the ATN fails and the
+ // DFA did not have a previous accept state. In l case, we use the
+ // ATN-generated exception object.
+ l.startIndex = -1
+
+ // line number 1..n within the input
+ l.Line = 1
+
+ // The index of the character relative to the beginning of the line
+ // 0..n-1
+ l.CharPositionInLine = 0
+
+ l.mode = LexerDefaultMode
+
+ // Used during DFA/ATN exec to record the most recent accept configuration
+ // info
+ l.prevAccept = NewSimState()
+
+ return l
+}
+
+func (l *LexerATNSimulator) copyState(simulator *LexerATNSimulator) {
+ l.CharPositionInLine = simulator.CharPositionInLine
+ l.Line = simulator.Line
+ l.mode = simulator.mode
+ l.startIndex = simulator.startIndex
+}
+
+func (l *LexerATNSimulator) Match(input CharStream, mode int) int {
+ l.MatchCalls++
+ l.mode = mode
+ mark := input.Mark()
+
+ defer func() {
+ input.Release(mark)
+ }()
+
+ l.startIndex = input.Index()
+ l.prevAccept.reset()
+
+ dfa := l.decisionToDFA[mode]
+
+ var s0 *DFAState
+ l.atn.stateMu.RLock()
+ s0 = dfa.getS0()
+ l.atn.stateMu.RUnlock()
+
+ if s0 == nil {
+ return l.MatchATN(input)
+ }
+
+ return l.execATN(input, s0)
+}
+
+func (l *LexerATNSimulator) reset() {
+ l.prevAccept.reset()
+ l.startIndex = -1
+ l.Line = 1
+ l.CharPositionInLine = 0
+ l.mode = LexerDefaultMode
+}
+
+func (l *LexerATNSimulator) MatchATN(input CharStream) int {
+ startState := l.atn.modeToStartState[l.mode]
+
+ if runtimeConfig.lexerATNSimulatorDebug {
+ fmt.Println("MatchATN mode " + strconv.Itoa(l.mode) + " start: " + startState.String())
+ }
+ oldMode := l.mode
+ s0Closure := l.computeStartState(input, startState)
+ suppressEdge := s0Closure.hasSemanticContext
+ s0Closure.hasSemanticContext = false
+
+ next := l.addDFAState(s0Closure, suppressEdge)
+
+ predict := l.execATN(input, next)
+
+ if runtimeConfig.lexerATNSimulatorDebug {
+ fmt.Println("DFA after MatchATN: " + l.decisionToDFA[oldMode].ToLexerString())
+ }
+ return predict
+}
+
+func (l *LexerATNSimulator) execATN(input CharStream, ds0 *DFAState) int {
+
+ if runtimeConfig.lexerATNSimulatorDebug {
+ fmt.Println("start state closure=" + ds0.configs.String())
+ }
+ if ds0.isAcceptState {
+ // allow zero-Length tokens
+ l.captureSimState(l.prevAccept, input, ds0)
+ }
+ t := input.LA(1)
+ s := ds0 // s is current/from DFA state
+
+ for { // while more work
+ if runtimeConfig.lexerATNSimulatorDebug {
+ fmt.Println("execATN loop starting closure: " + s.configs.String())
+ }
+
+ // As we move src->trg, src->trg, we keep track of the previous trg to
+ // avoid looking up the DFA state again, which is expensive.
+ // If the previous target was already part of the DFA, we might
+ // be able to avoid doing a reach operation upon t. If s!=nil,
+ // it means that semantic predicates didn't prevent us from
+ // creating a DFA state. Once we know s!=nil, we check to see if
+ // the DFA state has an edge already for t. If so, we can just reuse
+ // it's configuration set there's no point in re-computing it.
+ // This is kind of like doing DFA simulation within the ATN
+ // simulation because DFA simulation is really just a way to avoid
+ // computing reach/closure sets. Technically, once we know that
+ // we have a previously added DFA state, we could jump over to
+ // the DFA simulator. But, that would mean popping back and forth
+ // a lot and making things more complicated algorithmically.
+ // This optimization makes a lot of sense for loops within DFA.
+ // A character will take us back to an existing DFA state
+ // that already has lots of edges out of it. e.g., .* in comments.
+ target := l.getExistingTargetState(s, t)
+ if target == nil {
+ target = l.computeTargetState(input, s, t)
+ // print("Computed:" + str(target))
+ }
+ if target == ATNSimulatorError {
+ break
+ }
+ // If l is a consumable input element, make sure to consume before
+ // capturing the accept state so the input index, line, and char
+ // position accurately reflect the state of the interpreter at the
+ // end of the token.
+ if t != TokenEOF {
+ l.Consume(input)
+ }
+ if target.isAcceptState {
+ l.captureSimState(l.prevAccept, input, target)
+ if t == TokenEOF {
+ break
+ }
+ }
+ t = input.LA(1)
+ s = target // flip current DFA target becomes new src/from state
+ }
+
+ return l.failOrAccept(l.prevAccept, input, s.configs, t)
+}
+
+// Get an existing target state for an edge in the DFA. If the target state
+// for the edge has not yet been computed or is otherwise not available,
+// l method returns {@code nil}.
+//
+// @param s The current DFA state
+// @param t The next input symbol
+// @return The existing target DFA state for the given input symbol
+// {@code t}, or {@code nil} if the target state for l edge is not
+// already cached
+func (l *LexerATNSimulator) getExistingTargetState(s *DFAState, t int) *DFAState {
+ if t < LexerATNSimulatorMinDFAEdge || t > LexerATNSimulatorMaxDFAEdge {
+ return nil
+ }
+
+ l.atn.edgeMu.RLock()
+ defer l.atn.edgeMu.RUnlock()
+ if s.getEdges() == nil {
+ return nil
+ }
+ target := s.getIthEdge(t - LexerATNSimulatorMinDFAEdge)
+ if runtimeConfig.lexerATNSimulatorDebug && target != nil {
+ fmt.Println("reuse state " + strconv.Itoa(s.stateNumber) + " edge to " + strconv.Itoa(target.stateNumber))
+ }
+ return target
+}
+
+// computeTargetState computes a target state for an edge in the [DFA], and attempt to add the
+// computed state and corresponding edge to the [DFA].
+//
+// The func returns the computed target [DFA] state for the given input symbol t.
+// If this does not lead to a valid [DFA] state, this method
+// returns ATNSimulatorError.
+func (l *LexerATNSimulator) computeTargetState(input CharStream, s *DFAState, t int) *DFAState {
+ reach := NewOrderedATNConfigSet()
+
+ // if we don't find an existing DFA state
+ // Fill reach starting from closure, following t transitions
+ l.getReachableConfigSet(input, s.configs, reach, t)
+
+ if len(reach.configs) == 0 { // we got nowhere on t from s
+ if !reach.hasSemanticContext {
+ // we got nowhere on t, don't panic out l knowledge it'd
+ // cause a fail-over from DFA later.
+ l.addDFAEdge(s, t, ATNSimulatorError, nil)
+ }
+ // stop when we can't Match any more char
+ return ATNSimulatorError
+ }
+ // Add an edge from s to target DFA found/created for reach
+ return l.addDFAEdge(s, t, nil, reach)
+}
+
+func (l *LexerATNSimulator) failOrAccept(prevAccept *SimState, input CharStream, reach *ATNConfigSet, t int) int {
+ if l.prevAccept.dfaState != nil {
+ lexerActionExecutor := prevAccept.dfaState.lexerActionExecutor
+ l.accept(input, lexerActionExecutor, l.startIndex, prevAccept.index, prevAccept.line, prevAccept.column)
+ return prevAccept.dfaState.prediction
+ }
+
+ // if no accept and EOF is first char, return EOF
+ if t == TokenEOF && input.Index() == l.startIndex {
+ return TokenEOF
+ }
+
+ panic(NewLexerNoViableAltException(l.recog, input, l.startIndex, reach))
+}
+
+// getReachableConfigSet when given a starting configuration set, figures out all [ATN] configurations
+// we can reach upon input t.
+//
+// Parameter reach is a return parameter.
+func (l *LexerATNSimulator) getReachableConfigSet(input CharStream, closure *ATNConfigSet, reach *ATNConfigSet, t int) {
+ // l is used to Skip processing for configs which have a lower priority
+ // than a runtimeConfig that already reached an accept state for the same rule
+ SkipAlt := ATNInvalidAltNumber
+
+ for _, cfg := range closure.configs {
+ currentAltReachedAcceptState := cfg.GetAlt() == SkipAlt
+ if currentAltReachedAcceptState && cfg.passedThroughNonGreedyDecision {
+ continue
+ }
+
+ if runtimeConfig.lexerATNSimulatorDebug {
+
+ fmt.Printf("testing %s at %s\n", l.GetTokenName(t), cfg.String())
+ }
+
+ for _, trans := range cfg.GetState().GetTransitions() {
+ target := l.getReachableTarget(trans, t)
+ if target != nil {
+ lexerActionExecutor := cfg.lexerActionExecutor
+ if lexerActionExecutor != nil {
+ lexerActionExecutor = lexerActionExecutor.fixOffsetBeforeMatch(input.Index() - l.startIndex)
+ }
+ treatEOFAsEpsilon := t == TokenEOF
+ config := NewLexerATNConfig3(cfg, target, lexerActionExecutor)
+ if l.closure(input, config, reach,
+ currentAltReachedAcceptState, true, treatEOFAsEpsilon) {
+ // any remaining configs for l alt have a lower priority
+ // than the one that just reached an accept state.
+ SkipAlt = cfg.GetAlt()
+ }
+ }
+ }
+ }
+}
+
+func (l *LexerATNSimulator) accept(input CharStream, lexerActionExecutor *LexerActionExecutor, startIndex, index, line, charPos int) {
+ if runtimeConfig.lexerATNSimulatorDebug {
+ fmt.Printf("ACTION %v\n", lexerActionExecutor)
+ }
+ // seek to after last char in token
+ input.Seek(index)
+ l.Line = line
+ l.CharPositionInLine = charPos
+ if lexerActionExecutor != nil && l.recog != nil {
+ lexerActionExecutor.execute(l.recog, input, startIndex)
+ }
+}
+
+func (l *LexerATNSimulator) getReachableTarget(trans Transition, t int) ATNState {
+ if trans.Matches(t, 0, LexerMaxCharValue) {
+ return trans.getTarget()
+ }
+
+ return nil
+}
+
+func (l *LexerATNSimulator) computeStartState(input CharStream, p ATNState) *ATNConfigSet {
+ configs := NewOrderedATNConfigSet()
+ for i := 0; i < len(p.GetTransitions()); i++ {
+ target := p.GetTransitions()[i].getTarget()
+ cfg := NewLexerATNConfig6(target, i+1, BasePredictionContextEMPTY)
+ l.closure(input, cfg, configs, false, false, false)
+ }
+
+ return configs
+}
+
+// closure since the alternatives within any lexer decision are ordered by
+// preference, this method stops pursuing the closure as soon as an accept
+// state is reached. After the first accept state is reached by depth-first
+// search from runtimeConfig, all other (potentially reachable) states for
+// this rule would have a lower priority.
+//
+// The func returns true if an accept state is reached.
+func (l *LexerATNSimulator) closure(input CharStream, config *ATNConfig, configs *ATNConfigSet,
+ currentAltReachedAcceptState, speculative, treatEOFAsEpsilon bool) bool {
+
+ if runtimeConfig.lexerATNSimulatorDebug {
+ fmt.Println("closure(" + config.String() + ")")
+ }
+
+ _, ok := config.state.(*RuleStopState)
+ if ok {
+
+ if runtimeConfig.lexerATNSimulatorDebug {
+ if l.recog != nil {
+ fmt.Printf("closure at %s rule stop %s\n", l.recog.GetRuleNames()[config.state.GetRuleIndex()], config)
+ } else {
+ fmt.Printf("closure at rule stop %s\n", config)
+ }
+ }
+
+ if config.context == nil || config.context.hasEmptyPath() {
+ if config.context == nil || config.context.isEmpty() {
+ configs.Add(config, nil)
+ return true
+ }
+
+ configs.Add(NewLexerATNConfig2(config, config.state, BasePredictionContextEMPTY), nil)
+ currentAltReachedAcceptState = true
+ }
+ if config.context != nil && !config.context.isEmpty() {
+ for i := 0; i < config.context.length(); i++ {
+ if config.context.getReturnState(i) != BasePredictionContextEmptyReturnState {
+ newContext := config.context.GetParent(i) // "pop" return state
+ returnState := l.atn.states[config.context.getReturnState(i)]
+ cfg := NewLexerATNConfig2(config, returnState, newContext)
+ currentAltReachedAcceptState = l.closure(input, cfg, configs, currentAltReachedAcceptState, speculative, treatEOFAsEpsilon)
+ }
+ }
+ }
+ return currentAltReachedAcceptState
+ }
+ // optimization
+ if !config.state.GetEpsilonOnlyTransitions() {
+ if !currentAltReachedAcceptState || !config.passedThroughNonGreedyDecision {
+ configs.Add(config, nil)
+ }
+ }
+ for j := 0; j < len(config.state.GetTransitions()); j++ {
+ trans := config.state.GetTransitions()[j]
+ cfg := l.getEpsilonTarget(input, config, trans, configs, speculative, treatEOFAsEpsilon)
+ if cfg != nil {
+ currentAltReachedAcceptState = l.closure(input, cfg, configs,
+ currentAltReachedAcceptState, speculative, treatEOFAsEpsilon)
+ }
+ }
+ return currentAltReachedAcceptState
+}
+
+// side-effect: can alter configs.hasSemanticContext
+func (l *LexerATNSimulator) getEpsilonTarget(input CharStream, config *ATNConfig, trans Transition,
+ configs *ATNConfigSet, speculative, treatEOFAsEpsilon bool) *ATNConfig {
+
+ var cfg *ATNConfig
+
+ if trans.getSerializationType() == TransitionRULE {
+
+ rt := trans.(*RuleTransition)
+ newContext := SingletonBasePredictionContextCreate(config.context, rt.followState.GetStateNumber())
+ cfg = NewLexerATNConfig2(config, trans.getTarget(), newContext)
+
+ } else if trans.getSerializationType() == TransitionPRECEDENCE {
+ panic("Precedence predicates are not supported in lexers.")
+ } else if trans.getSerializationType() == TransitionPREDICATE {
+ // Track traversing semantic predicates. If we traverse,
+ // we cannot add a DFA state for l "reach" computation
+ // because the DFA would not test the predicate again in the
+ // future. Rather than creating collections of semantic predicates
+ // like v3 and testing them on prediction, v4 will test them on the
+ // fly all the time using the ATN not the DFA. This is slower but
+ // semantically it's not used that often. One of the key elements to
+ // l predicate mechanism is not adding DFA states that see
+ // predicates immediately afterwards in the ATN. For example,
+
+ // a : ID {p1}? | ID {p2}?
+
+ // should create the start state for rule 'a' (to save start state
+ // competition), but should not create target of ID state. The
+ // collection of ATN states the following ID references includes
+ // states reached by traversing predicates. Since l is when we
+ // test them, we cannot cash the DFA state target of ID.
+
+ pt := trans.(*PredicateTransition)
+
+ if runtimeConfig.lexerATNSimulatorDebug {
+ fmt.Println("EVAL rule " + strconv.Itoa(trans.(*PredicateTransition).ruleIndex) + ":" + strconv.Itoa(pt.predIndex))
+ }
+ configs.hasSemanticContext = true
+ if l.evaluatePredicate(input, pt.ruleIndex, pt.predIndex, speculative) {
+ cfg = NewLexerATNConfig4(config, trans.getTarget())
+ }
+ } else if trans.getSerializationType() == TransitionACTION {
+ if config.context == nil || config.context.hasEmptyPath() {
+ // execute actions anywhere in the start rule for a token.
+ //
+ // TODO: if the entry rule is invoked recursively, some
+ // actions may be executed during the recursive call. The
+ // problem can appear when hasEmptyPath() is true but
+ // isEmpty() is false. In this case, the config needs to be
+ // split into two contexts - one with just the empty path
+ // and another with everything but the empty path.
+ // Unfortunately, the current algorithm does not allow
+ // getEpsilonTarget to return two configurations, so
+ // additional modifications are needed before we can support
+ // the split operation.
+ lexerActionExecutor := LexerActionExecutorappend(config.lexerActionExecutor, l.atn.lexerActions[trans.(*ActionTransition).actionIndex])
+ cfg = NewLexerATNConfig3(config, trans.getTarget(), lexerActionExecutor)
+ } else {
+ // ignore actions in referenced rules
+ cfg = NewLexerATNConfig4(config, trans.getTarget())
+ }
+ } else if trans.getSerializationType() == TransitionEPSILON {
+ cfg = NewLexerATNConfig4(config, trans.getTarget())
+ } else if trans.getSerializationType() == TransitionATOM ||
+ trans.getSerializationType() == TransitionRANGE ||
+ trans.getSerializationType() == TransitionSET {
+ if treatEOFAsEpsilon {
+ if trans.Matches(TokenEOF, 0, LexerMaxCharValue) {
+ cfg = NewLexerATNConfig4(config, trans.getTarget())
+ }
+ }
+ }
+ return cfg
+}
+
+// evaluatePredicate eEvaluates a predicate specified in the lexer.
+//
+// If speculative is true, this method was called before
+// [consume] for the Matched character. This method should call
+// [consume] before evaluating the predicate to ensure position
+// sensitive values, including [GetText], [GetLine],
+// and [GetColumn], properly reflect the current
+// lexer state. This method should restore input and the simulator
+// to the original state before returning, i.e. undo the actions made by the
+// call to [Consume].
+//
+// The func returns true if the specified predicate evaluates to true.
+func (l *LexerATNSimulator) evaluatePredicate(input CharStream, ruleIndex, predIndex int, speculative bool) bool {
+ // assume true if no recognizer was provided
+ if l.recog == nil {
+ return true
+ }
+ if !speculative {
+ return l.recog.Sempred(nil, ruleIndex, predIndex)
+ }
+ savedcolumn := l.CharPositionInLine
+ savedLine := l.Line
+ index := input.Index()
+ marker := input.Mark()
+
+ defer func() {
+ l.CharPositionInLine = savedcolumn
+ l.Line = savedLine
+ input.Seek(index)
+ input.Release(marker)
+ }()
+
+ l.Consume(input)
+ return l.recog.Sempred(nil, ruleIndex, predIndex)
+}
+
+func (l *LexerATNSimulator) captureSimState(settings *SimState, input CharStream, dfaState *DFAState) {
+ settings.index = input.Index()
+ settings.line = l.Line
+ settings.column = l.CharPositionInLine
+ settings.dfaState = dfaState
+}
+
+func (l *LexerATNSimulator) addDFAEdge(from *DFAState, tk int, to *DFAState, cfgs *ATNConfigSet) *DFAState {
+ if to == nil && cfgs != nil {
+ // leading to l call, ATNConfigSet.hasSemanticContext is used as a
+ // marker indicating dynamic predicate evaluation makes l edge
+ // dependent on the specific input sequence, so the static edge in the
+ // DFA should be omitted. The target DFAState is still created since
+ // execATN has the ability to reSynchronize with the DFA state cache
+ // following the predicate evaluation step.
+ //
+ // TJP notes: next time through the DFA, we see a pred again and eval.
+ // If that gets us to a previously created (but dangling) DFA
+ // state, we can continue in pure DFA mode from there.
+ //
+ suppressEdge := cfgs.hasSemanticContext
+ cfgs.hasSemanticContext = false
+ to = l.addDFAState(cfgs, true)
+
+ if suppressEdge {
+ return to
+ }
+ }
+ // add the edge
+ if tk < LexerATNSimulatorMinDFAEdge || tk > LexerATNSimulatorMaxDFAEdge {
+ // Only track edges within the DFA bounds
+ return to
+ }
+ if runtimeConfig.lexerATNSimulatorDebug {
+ fmt.Println("EDGE " + from.String() + " -> " + to.String() + " upon " + strconv.Itoa(tk))
+ }
+ l.atn.edgeMu.Lock()
+ defer l.atn.edgeMu.Unlock()
+ if from.getEdges() == nil {
+ // make room for tokens 1..n and -1 masquerading as index 0
+ from.setEdges(make([]*DFAState, LexerATNSimulatorMaxDFAEdge-LexerATNSimulatorMinDFAEdge+1))
+ }
+ from.setIthEdge(tk-LexerATNSimulatorMinDFAEdge, to) // connect
+
+ return to
+}
+
+// Add a NewDFA state if there isn't one with l set of
+// configurations already. This method also detects the first
+// configuration containing an ATN rule stop state. Later, when
+// traversing the DFA, we will know which rule to accept.
+func (l *LexerATNSimulator) addDFAState(configs *ATNConfigSet, suppressEdge bool) *DFAState {
+
+ proposed := NewDFAState(-1, configs)
+ var firstConfigWithRuleStopState *ATNConfig
+
+ for _, cfg := range configs.configs {
+ _, ok := cfg.GetState().(*RuleStopState)
+
+ if ok {
+ firstConfigWithRuleStopState = cfg
+ break
+ }
+ }
+ if firstConfigWithRuleStopState != nil {
+ proposed.isAcceptState = true
+ proposed.lexerActionExecutor = firstConfigWithRuleStopState.lexerActionExecutor
+ proposed.setPrediction(l.atn.ruleToTokenType[firstConfigWithRuleStopState.GetState().GetRuleIndex()])
+ }
+ dfa := l.decisionToDFA[l.mode]
+
+ l.atn.stateMu.Lock()
+ defer l.atn.stateMu.Unlock()
+ existing, present := dfa.Get(proposed)
+ if present {
+
+ // This state was already present, so just return it.
+ //
+ proposed = existing
+ } else {
+
+ // We need to add the new state
+ //
+ proposed.stateNumber = dfa.Len()
+ configs.readOnly = true
+ configs.configLookup = nil // Not needed now
+ proposed.configs = configs
+ dfa.Put(proposed)
+ }
+ if !suppressEdge {
+ dfa.setS0(proposed)
+ }
+ return proposed
+}
+
+func (l *LexerATNSimulator) getDFA(mode int) *DFA {
+ return l.decisionToDFA[mode]
+}
+
+// GetText returns the text [Match]ed so far for the current token.
+func (l *LexerATNSimulator) GetText(input CharStream) string {
+ // index is first lookahead char, don't include.
+ return input.GetTextFromInterval(NewInterval(l.startIndex, input.Index()-1))
+}
+
+func (l *LexerATNSimulator) Consume(input CharStream) {
+ curChar := input.LA(1)
+ if curChar == int('\n') {
+ l.Line++
+ l.CharPositionInLine = 0
+ } else {
+ l.CharPositionInLine++
+ }
+ input.Consume()
+}
+
+func (l *LexerATNSimulator) GetCharPositionInLine() int {
+ return l.CharPositionInLine
+}
+
+func (l *LexerATNSimulator) GetLine() int {
+ return l.Line
+}
+
+func (l *LexerATNSimulator) GetTokenName(tt int) string {
+ if tt == -1 {
+ return "EOF"
+ }
+
+ var sb strings.Builder
+ sb.Grow(6)
+ sb.WriteByte('\'')
+ sb.WriteRune(rune(tt))
+ sb.WriteByte('\'')
+
+ return sb.String()
+}
+
+func resetSimState(sim *SimState) {
+ sim.index = -1
+ sim.line = 0
+ sim.column = -1
+ sim.dfaState = nil
+}
+
+type SimState struct {
+ index int
+ line int
+ column int
+ dfaState *DFAState
+}
+
+func NewSimState() *SimState {
+ s := new(SimState)
+ resetSimState(s)
+ return s
+}
+
+func (s *SimState) reset() {
+ resetSimState(s)
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/ll1_analyzer.go b/vendor/github.com/antlr4-go/antlr/v4/ll1_analyzer.go
new file mode 100644
index 000000000000..4955ac876f97
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/ll1_analyzer.go
@@ -0,0 +1,218 @@
+// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
+// Use of this file is governed by the BSD 3-clause license that
+// can be found in the LICENSE.txt file in the project root.
+
+package antlr
+
+type LL1Analyzer struct {
+ atn *ATN
+}
+
+func NewLL1Analyzer(atn *ATN) *LL1Analyzer {
+ la := new(LL1Analyzer)
+ la.atn = atn
+ return la
+}
+
+const (
+ // LL1AnalyzerHitPred is a special value added to the lookahead sets to indicate that we hit
+ // a predicate during analysis if
+ //
+ // seeThruPreds==false
+ LL1AnalyzerHitPred = TokenInvalidType
+)
+
+// *
+// Calculates the SLL(1) expected lookahead set for each outgoing transition
+// of an {@link ATNState}. The returned array has one element for each
+// outgoing transition in {@code s}. If the closure from transition
+// i leads to a semantic predicate before Matching a symbol, the
+// element at index i of the result will be {@code nil}.
+//
+// @param s the ATN state
+// @return the expected symbols for each outgoing transition of {@code s}.
+func (la *LL1Analyzer) getDecisionLookahead(s ATNState) []*IntervalSet {
+ if s == nil {
+ return nil
+ }
+ count := len(s.GetTransitions())
+ look := make([]*IntervalSet, count)
+ for alt := 0; alt < count; alt++ {
+
+ look[alt] = NewIntervalSet()
+ lookBusy := NewJStore[*ATNConfig, Comparator[*ATNConfig]](aConfEqInst, ClosureBusyCollection, "LL1Analyzer.getDecisionLookahead for lookBusy")
+ la.look1(s.GetTransitions()[alt].getTarget(), nil, BasePredictionContextEMPTY, look[alt], lookBusy, NewBitSet(), false, false)
+
+ // Wipe out lookahead for la alternative if we found nothing,
+ // or we had a predicate when we !seeThruPreds
+ if look[alt].length() == 0 || look[alt].contains(LL1AnalyzerHitPred) {
+ look[alt] = nil
+ }
+ }
+ return look
+}
+
+// Look computes the set of tokens that can follow s in the [ATN] in the
+// specified ctx.
+//
+// If ctx is nil and the end of the rule containing
+// s is reached, [EPSILON] is added to the result set.
+//
+// If ctx is not nil and the end of the outermost rule is
+// reached, [EOF] is added to the result set.
+//
+// Parameter s the ATN state, and stopState is the ATN state to stop at. This can be a
+// [BlockEndState] to detect epsilon paths through a closure.
+//
+// Parameter ctx is the complete parser context, or nil if the context
+// should be ignored
+//
+// The func returns the set of tokens that can follow s in the [ATN] in the
+// specified ctx.
+func (la *LL1Analyzer) Look(s, stopState ATNState, ctx RuleContext) *IntervalSet {
+ r := NewIntervalSet()
+ var lookContext *PredictionContext
+ if ctx != nil {
+ lookContext = predictionContextFromRuleContext(s.GetATN(), ctx)
+ }
+ la.look1(s, stopState, lookContext, r, NewJStore[*ATNConfig, Comparator[*ATNConfig]](aConfEqInst, ClosureBusyCollection, "LL1Analyzer.Look for la.look1()"),
+ NewBitSet(), true, true)
+ return r
+}
+
+//*
+// Compute set of tokens that can follow {@code s} in the ATN in the
+// specified {@code ctx}.
+//
+//
If {@code ctx} is {@code nil} and {@code stopState} or the end of the
+// rule containing {@code s} is reached, {@link Token//EPSILON} is added to
+// the result set. If {@code ctx} is not {@code nil} and {@code addEOF} is
+// {@code true} and {@code stopState} or the end of the outermost rule is
+// reached, {@link Token//EOF} is added to the result set.
+//
+// @param s the ATN state.
+// @param stopState the ATN state to stop at. This can be a
+// {@link BlockEndState} to detect epsilon paths through a closure.
+// @param ctx The outer context, or {@code nil} if the outer context should
+// not be used.
+// @param look The result lookahead set.
+// @param lookBusy A set used for preventing epsilon closures in the ATN
+// from causing a stack overflow. Outside code should pass
+// {@code NewSet} for la argument.
+// @param calledRuleStack A set used for preventing left recursion in the
+// ATN from causing a stack overflow. Outside code should pass
+// {@code NewBitSet()} for la argument.
+// @param seeThruPreds {@code true} to true semantic predicates as
+// implicitly {@code true} and "see through them", otherwise {@code false}
+// to treat semantic predicates as opaque and add {@link //HitPred} to the
+// result if one is encountered.
+// @param addEOF Add {@link Token//EOF} to the result if the end of the
+// outermost context is reached. This parameter has no effect if {@code ctx}
+// is {@code nil}.
+
+func (la *LL1Analyzer) look2(_, stopState ATNState, ctx *PredictionContext, look *IntervalSet, lookBusy *JStore[*ATNConfig, Comparator[*ATNConfig]],
+ calledRuleStack *BitSet, seeThruPreds, addEOF bool, i int) {
+
+ returnState := la.atn.states[ctx.getReturnState(i)]
+ la.look1(returnState, stopState, ctx.GetParent(i), look, lookBusy, calledRuleStack, seeThruPreds, addEOF)
+
+}
+
+func (la *LL1Analyzer) look1(s, stopState ATNState, ctx *PredictionContext, look *IntervalSet, lookBusy *JStore[*ATNConfig, Comparator[*ATNConfig]], calledRuleStack *BitSet, seeThruPreds, addEOF bool) {
+
+ c := NewATNConfig6(s, 0, ctx)
+
+ if lookBusy.Contains(c) {
+ return
+ }
+
+ _, present := lookBusy.Put(c)
+ if present {
+ return
+
+ }
+ if s == stopState {
+ if ctx == nil {
+ look.addOne(TokenEpsilon)
+ return
+ } else if ctx.isEmpty() && addEOF {
+ look.addOne(TokenEOF)
+ return
+ }
+ }
+
+ _, ok := s.(*RuleStopState)
+
+ if ok {
+ if ctx == nil {
+ look.addOne(TokenEpsilon)
+ return
+ } else if ctx.isEmpty() && addEOF {
+ look.addOne(TokenEOF)
+ return
+ }
+
+ if ctx.pcType != PredictionContextEmpty {
+ removed := calledRuleStack.contains(s.GetRuleIndex())
+ defer func() {
+ if removed {
+ calledRuleStack.add(s.GetRuleIndex())
+ }
+ }()
+ calledRuleStack.remove(s.GetRuleIndex())
+ // run thru all possible stack tops in ctx
+ for i := 0; i < ctx.length(); i++ {
+ returnState := la.atn.states[ctx.getReturnState(i)]
+ la.look2(returnState, stopState, ctx, look, lookBusy, calledRuleStack, seeThruPreds, addEOF, i)
+ }
+ return
+ }
+ }
+
+ n := len(s.GetTransitions())
+
+ for i := 0; i < n; i++ {
+ t := s.GetTransitions()[i]
+
+ if t1, ok := t.(*RuleTransition); ok {
+ if calledRuleStack.contains(t1.getTarget().GetRuleIndex()) {
+ continue
+ }
+
+ newContext := SingletonBasePredictionContextCreate(ctx, t1.followState.GetStateNumber())
+ la.look3(stopState, newContext, look, lookBusy, calledRuleStack, seeThruPreds, addEOF, t1)
+ } else if t2, ok := t.(AbstractPredicateTransition); ok {
+ if seeThruPreds {
+ la.look1(t2.getTarget(), stopState, ctx, look, lookBusy, calledRuleStack, seeThruPreds, addEOF)
+ } else {
+ look.addOne(LL1AnalyzerHitPred)
+ }
+ } else if t.getIsEpsilon() {
+ la.look1(t.getTarget(), stopState, ctx, look, lookBusy, calledRuleStack, seeThruPreds, addEOF)
+ } else if _, ok := t.(*WildcardTransition); ok {
+ look.addRange(TokenMinUserTokenType, la.atn.maxTokenType)
+ } else {
+ set := t.getLabel()
+ if set != nil {
+ if _, ok := t.(*NotSetTransition); ok {
+ set = set.complement(TokenMinUserTokenType, la.atn.maxTokenType)
+ }
+ look.addSet(set)
+ }
+ }
+ }
+}
+
+func (la *LL1Analyzer) look3(stopState ATNState, ctx *PredictionContext, look *IntervalSet, lookBusy *JStore[*ATNConfig, Comparator[*ATNConfig]],
+ calledRuleStack *BitSet, seeThruPreds, addEOF bool, t1 *RuleTransition) {
+
+ newContext := SingletonBasePredictionContextCreate(ctx, t1.followState.GetStateNumber())
+
+ defer func() {
+ calledRuleStack.remove(t1.getTarget().GetRuleIndex())
+ }()
+
+ calledRuleStack.add(t1.getTarget().GetRuleIndex())
+ la.look1(t1.getTarget(), stopState, newContext, look, lookBusy, calledRuleStack, seeThruPreds, addEOF)
+
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/nostatistics.go b/vendor/github.com/antlr4-go/antlr/v4/nostatistics.go
new file mode 100644
index 000000000000..923c7b52c47c
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/nostatistics.go
@@ -0,0 +1,47 @@
+//go:build !antlr.stats
+
+package antlr
+
+// This file is compiled when the build configuration antlr.stats is not enabled.
+// which then allows the compiler to optimize out all the code that is not used.
+const collectStats = false
+
+// goRunStats is a dummy struct used when build configuration antlr.stats is not enabled.
+type goRunStats struct {
+}
+
+var Statistics = &goRunStats{}
+
+func (s *goRunStats) AddJStatRec(_ *JStatRec) {
+ // Do nothing - compiler will optimize this out (hopefully)
+}
+
+func (s *goRunStats) CollectionAnomalies() {
+ // Do nothing - compiler will optimize this out (hopefully)
+}
+
+func (s *goRunStats) Reset() {
+ // Do nothing - compiler will optimize this out (hopefully)
+}
+
+func (s *goRunStats) Report(dir string, prefix string) error {
+ // Do nothing - compiler will optimize this out (hopefully)
+ return nil
+}
+
+func (s *goRunStats) Analyze() {
+ // Do nothing - compiler will optimize this out (hopefully)
+}
+
+type statsOption func(*goRunStats) error
+
+func (s *goRunStats) Configure(options ...statsOption) error {
+ // Do nothing - compiler will optimize this out (hopefully)
+ return nil
+}
+
+func WithTopN(topN int) statsOption {
+ return func(s *goRunStats) error {
+ return nil
+ }
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/parser.go b/vendor/github.com/antlr4-go/antlr/v4/parser.go
new file mode 100644
index 000000000000..fb57ac15db70
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/parser.go
@@ -0,0 +1,700 @@
+// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
+// Use of this file is governed by the BSD 3-clause license that
+// can be found in the LICENSE.txt file in the project root.
+
+package antlr
+
+import (
+ "fmt"
+ "strconv"
+)
+
+type Parser interface {
+ Recognizer
+
+ GetInterpreter() *ParserATNSimulator
+
+ GetTokenStream() TokenStream
+ GetTokenFactory() TokenFactory
+ GetParserRuleContext() ParserRuleContext
+ SetParserRuleContext(ParserRuleContext)
+ Consume() Token
+ GetParseListeners() []ParseTreeListener
+
+ GetErrorHandler() ErrorStrategy
+ SetErrorHandler(ErrorStrategy)
+ GetInputStream() IntStream
+ GetCurrentToken() Token
+ GetExpectedTokens() *IntervalSet
+ NotifyErrorListeners(string, Token, RecognitionException)
+ IsExpectedToken(int) bool
+ GetPrecedence() int
+ GetRuleInvocationStack(ParserRuleContext) []string
+}
+
+type BaseParser struct {
+ *BaseRecognizer
+
+ Interpreter *ParserATNSimulator
+ BuildParseTrees bool
+
+ input TokenStream
+ errHandler ErrorStrategy
+ precedenceStack IntStack
+ ctx ParserRuleContext
+
+ tracer *TraceListener
+ parseListeners []ParseTreeListener
+ _SyntaxErrors int
+}
+
+// NewBaseParser contains all the parsing support code to embed in parsers. Essentially most of it is error
+// recovery stuff.
+//
+//goland:noinspection GoUnusedExportedFunction
+func NewBaseParser(input TokenStream) *BaseParser {
+
+ p := new(BaseParser)
+
+ p.BaseRecognizer = NewBaseRecognizer()
+
+ // The input stream.
+ p.input = nil
+
+ // The error handling strategy for the parser. The default value is a new
+ // instance of {@link DefaultErrorStrategy}.
+ p.errHandler = NewDefaultErrorStrategy()
+ p.precedenceStack = make([]int, 0)
+ p.precedenceStack.Push(0)
+
+ // The ParserRuleContext object for the currently executing rule.
+ // p.is always non-nil during the parsing process.
+ p.ctx = nil
+
+ // Specifies whether the parser should construct a parse tree during
+ // the parsing process. The default value is {@code true}.
+ p.BuildParseTrees = true
+
+ // When setTrace(true) is called, a reference to the
+ // TraceListener is stored here, so it can be easily removed in a
+ // later call to setTrace(false). The listener itself is
+ // implemented as a parser listener so p.field is not directly used by
+ // other parser methods.
+ p.tracer = nil
+
+ // The list of ParseTreeListener listeners registered to receive
+ // events during the parse.
+ p.parseListeners = nil
+
+ // The number of syntax errors Reported during parsing. p.value is
+ // incremented each time NotifyErrorListeners is called.
+ p._SyntaxErrors = 0
+ p.SetInputStream(input)
+
+ return p
+}
+
+// This field maps from the serialized ATN string to the deserialized [ATN] with
+// bypass alternatives.
+//
+// [ATNDeserializationOptions.isGenerateRuleBypassTransitions]
+//
+//goland:noinspection GoUnusedGlobalVariable
+var bypassAltsAtnCache = make(map[string]int)
+
+// reset the parser's state//
+func (p *BaseParser) reset() {
+ if p.input != nil {
+ p.input.Seek(0)
+ }
+ p.errHandler.reset(p)
+ p.ctx = nil
+ p._SyntaxErrors = 0
+ p.SetTrace(nil)
+ p.precedenceStack = make([]int, 0)
+ p.precedenceStack.Push(0)
+ if p.Interpreter != nil {
+ p.Interpreter.reset()
+ }
+}
+
+func (p *BaseParser) GetErrorHandler() ErrorStrategy {
+ return p.errHandler
+}
+
+func (p *BaseParser) SetErrorHandler(e ErrorStrategy) {
+ p.errHandler = e
+}
+
+// Match current input symbol against {@code ttype}. If the symbol type
+// Matches, {@link ANTLRErrorStrategy//ReportMatch} and {@link //consume} are
+// called to complete the Match process.
+//
+//
If the symbol type does not Match,
+// {@link ANTLRErrorStrategy//recoverInline} is called on the current error
+// strategy to attempt recovery. If {@link //getBuildParseTree} is
+// {@code true} and the token index of the symbol returned by
+// {@link ANTLRErrorStrategy//recoverInline} is -1, the symbol is added to
+// the parse tree by calling {@link ParserRuleContext//addErrorNode}.
+//
+// @param ttype the token type to Match
+// @return the Matched symbol
+// @panics RecognitionException if the current input symbol did not Match
+// {@code ttype} and the error strategy could not recover from the
+// mismatched symbol
+
+func (p *BaseParser) Match(ttype int) Token {
+
+ t := p.GetCurrentToken()
+
+ if t.GetTokenType() == ttype {
+ p.errHandler.ReportMatch(p)
+ p.Consume()
+ } else {
+ t = p.errHandler.RecoverInline(p)
+ if p.HasError() {
+ return nil
+ }
+ if p.BuildParseTrees && t.GetTokenIndex() == -1 {
+
+ // we must have conjured up a new token during single token
+ // insertion if it's not the current symbol
+ p.ctx.AddErrorNode(t)
+ }
+ }
+
+ return t
+}
+
+// Match current input symbol as a wildcard. If the symbol type Matches
+// (i.e. has a value greater than 0), {@link ANTLRErrorStrategy//ReportMatch}
+// and {@link //consume} are called to complete the Match process.
+//
+//
If the symbol type does not Match,
+// {@link ANTLRErrorStrategy//recoverInline} is called on the current error
+// strategy to attempt recovery. If {@link //getBuildParseTree} is
+// {@code true} and the token index of the symbol returned by
+// {@link ANTLRErrorStrategy//recoverInline} is -1, the symbol is added to
+// the parse tree by calling {@link ParserRuleContext//addErrorNode}.
+//
+// @return the Matched symbol
+// @panics RecognitionException if the current input symbol did not Match
+// a wildcard and the error strategy could not recover from the mismatched
+// symbol
+
+func (p *BaseParser) MatchWildcard() Token {
+ t := p.GetCurrentToken()
+ if t.GetTokenType() > 0 {
+ p.errHandler.ReportMatch(p)
+ p.Consume()
+ } else {
+ t = p.errHandler.RecoverInline(p)
+ if p.BuildParseTrees && t.GetTokenIndex() == -1 {
+ // we must have conjured up a new token during single token
+ // insertion if it's not the current symbol
+ p.ctx.AddErrorNode(t)
+ }
+ }
+ return t
+}
+
+func (p *BaseParser) GetParserRuleContext() ParserRuleContext {
+ return p.ctx
+}
+
+func (p *BaseParser) SetParserRuleContext(v ParserRuleContext) {
+ p.ctx = v
+}
+
+func (p *BaseParser) GetParseListeners() []ParseTreeListener {
+ if p.parseListeners == nil {
+ return make([]ParseTreeListener, 0)
+ }
+ return p.parseListeners
+}
+
+// AddParseListener registers listener to receive events during the parsing process.
+//
+// To support output-preserving grammar transformations (including but not
+// limited to left-recursion removal, automated left-factoring, and
+// optimized code generation), calls to listener methods during the parse
+// may differ substantially from calls made by
+// [ParseTreeWalker.DEFAULT] used after the parse is complete. In
+// particular, rule entry and exit events may occur in a different order
+// during the parse than after the parser. In addition, calls to certain
+// rule entry methods may be omitted.
+//
+// With the following specific exceptions, calls to listener events are
+// deterministic, i.e. for identical input the calls to listener
+// methods will be the same.
+//
+// - Alterations to the grammar used to generate code may change the
+// behavior of the listener calls.
+// - Alterations to the command line options passed to ANTLR 4 when
+// generating the parser may change the behavior of the listener calls.
+// - Changing the version of the ANTLR Tool used to generate the parser
+// may change the behavior of the listener calls.
+func (p *BaseParser) AddParseListener(listener ParseTreeListener) {
+ if listener == nil {
+ panic("listener")
+ }
+ if p.parseListeners == nil {
+ p.parseListeners = make([]ParseTreeListener, 0)
+ }
+ p.parseListeners = append(p.parseListeners, listener)
+}
+
+// RemoveParseListener removes listener from the list of parse listeners.
+//
+// If listener is nil or has not been added as a parse
+// listener, this func does nothing.
+func (p *BaseParser) RemoveParseListener(listener ParseTreeListener) {
+
+ if p.parseListeners != nil {
+
+ idx := -1
+ for i, v := range p.parseListeners {
+ if v == listener {
+ idx = i
+ break
+ }
+ }
+
+ if idx == -1 {
+ return
+ }
+
+ // remove the listener from the slice
+ p.parseListeners = append(p.parseListeners[0:idx], p.parseListeners[idx+1:]...)
+
+ if len(p.parseListeners) == 0 {
+ p.parseListeners = nil
+ }
+ }
+}
+
+// Remove all parse listeners.
+func (p *BaseParser) removeParseListeners() {
+ p.parseListeners = nil
+}
+
+// TriggerEnterRuleEvent notifies all parse listeners of an enter rule event.
+func (p *BaseParser) TriggerEnterRuleEvent() {
+ if p.parseListeners != nil {
+ ctx := p.ctx
+ for _, listener := range p.parseListeners {
+ listener.EnterEveryRule(ctx)
+ ctx.EnterRule(listener)
+ }
+ }
+}
+
+// TriggerExitRuleEvent notifies any parse listeners of an exit rule event.
+func (p *BaseParser) TriggerExitRuleEvent() {
+ if p.parseListeners != nil {
+ // reverse order walk of listeners
+ ctx := p.ctx
+ l := len(p.parseListeners) - 1
+
+ for i := range p.parseListeners {
+ listener := p.parseListeners[l-i]
+ ctx.ExitRule(listener)
+ listener.ExitEveryRule(ctx)
+ }
+ }
+}
+
+func (p *BaseParser) GetInterpreter() *ParserATNSimulator {
+ return p.Interpreter
+}
+
+func (p *BaseParser) GetATN() *ATN {
+ return p.Interpreter.atn
+}
+
+func (p *BaseParser) GetTokenFactory() TokenFactory {
+ return p.input.GetTokenSource().GetTokenFactory()
+}
+
+// setTokenFactory is used to tell our token source and error strategy about a new way to create tokens.
+func (p *BaseParser) setTokenFactory(factory TokenFactory) {
+ p.input.GetTokenSource().setTokenFactory(factory)
+}
+
+// GetATNWithBypassAlts - the ATN with bypass alternatives is expensive to create, so we create it
+// lazily.
+func (p *BaseParser) GetATNWithBypassAlts() {
+
+ // TODO - Implement this?
+ panic("Not implemented!")
+
+ // serializedAtn := p.getSerializedATN()
+ // if (serializedAtn == nil) {
+ // panic("The current parser does not support an ATN with bypass alternatives.")
+ // }
+ // result := p.bypassAltsAtnCache[serializedAtn]
+ // if (result == nil) {
+ // deserializationOptions := NewATNDeserializationOptions(nil)
+ // deserializationOptions.generateRuleBypassTransitions = true
+ // result = NewATNDeserializer(deserializationOptions).deserialize(serializedAtn)
+ // p.bypassAltsAtnCache[serializedAtn] = result
+ // }
+ // return result
+}
+
+// The preferred method of getting a tree pattern. For example, here's a
+// sample use:
+//
+//
+// ParseTree t = parser.expr()
+// ParseTreePattern p = parser.compileParseTreePattern("<ID>+0",
+// MyParser.RULE_expr)
+// ParseTreeMatch m = p.Match(t)
+// String id = m.Get("ID")
+//
+
+//goland:noinspection GoUnusedParameter
+func (p *BaseParser) compileParseTreePattern(pattern, patternRuleIndex, lexer Lexer) {
+
+ panic("NewParseTreePatternMatcher not implemented!")
+ //
+ // if (lexer == nil) {
+ // if (p.GetTokenStream() != nil) {
+ // tokenSource := p.GetTokenStream().GetTokenSource()
+ // if _, ok := tokenSource.(ILexer); ok {
+ // lexer = tokenSource
+ // }
+ // }
+ // }
+ // if (lexer == nil) {
+ // panic("Parser can't discover a lexer to use")
+ // }
+
+ // m := NewParseTreePatternMatcher(lexer, p)
+ // return m.compile(pattern, patternRuleIndex)
+}
+
+func (p *BaseParser) GetInputStream() IntStream {
+ return p.GetTokenStream()
+}
+
+func (p *BaseParser) SetInputStream(input TokenStream) {
+ p.SetTokenStream(input)
+}
+
+func (p *BaseParser) GetTokenStream() TokenStream {
+ return p.input
+}
+
+// SetTokenStream installs input as the token stream and resets the parser.
+func (p *BaseParser) SetTokenStream(input TokenStream) {
+ p.input = nil
+ p.reset()
+ p.input = input
+}
+
+// GetCurrentToken returns the current token at LT(1).
+//
+// [Match] needs to return the current input symbol, which gets put
+// into the label for the associated token ref e.g., x=ID.
+func (p *BaseParser) GetCurrentToken() Token {
+ return p.input.LT(1)
+}
+
+func (p *BaseParser) NotifyErrorListeners(msg string, offendingToken Token, err RecognitionException) {
+ if offendingToken == nil {
+ offendingToken = p.GetCurrentToken()
+ }
+ p._SyntaxErrors++
+ line := offendingToken.GetLine()
+ column := offendingToken.GetColumn()
+ listener := p.GetErrorListenerDispatch()
+ listener.SyntaxError(p, offendingToken, line, column, msg, err)
+}
+
+func (p *BaseParser) Consume() Token {
+ o := p.GetCurrentToken()
+ if o.GetTokenType() != TokenEOF {
+ p.GetInputStream().Consume()
+ }
+ hasListener := p.parseListeners != nil && len(p.parseListeners) > 0
+ if p.BuildParseTrees || hasListener {
+ if p.errHandler.InErrorRecoveryMode(p) {
+ node := p.ctx.AddErrorNode(o)
+ if p.parseListeners != nil {
+ for _, l := range p.parseListeners {
+ l.VisitErrorNode(node)
+ }
+ }
+
+ } else {
+ node := p.ctx.AddTokenNode(o)
+ if p.parseListeners != nil {
+ for _, l := range p.parseListeners {
+ l.VisitTerminal(node)
+ }
+ }
+ }
+ // node.invokingState = p.state
+ }
+
+ return o
+}
+
+func (p *BaseParser) addContextToParseTree() {
+ // add current context to parent if we have a parent
+ if p.ctx.GetParent() != nil {
+ p.ctx.GetParent().(ParserRuleContext).AddChild(p.ctx)
+ }
+}
+
+func (p *BaseParser) EnterRule(localctx ParserRuleContext, state, _ int) {
+ p.SetState(state)
+ p.ctx = localctx
+ p.ctx.SetStart(p.input.LT(1))
+ if p.BuildParseTrees {
+ p.addContextToParseTree()
+ }
+ if p.parseListeners != nil {
+ p.TriggerEnterRuleEvent()
+ }
+}
+
+func (p *BaseParser) ExitRule() {
+ p.ctx.SetStop(p.input.LT(-1))
+ // trigger event on ctx, before it reverts to parent
+ if p.parseListeners != nil {
+ p.TriggerExitRuleEvent()
+ }
+ p.SetState(p.ctx.GetInvokingState())
+ if p.ctx.GetParent() != nil {
+ p.ctx = p.ctx.GetParent().(ParserRuleContext)
+ } else {
+ p.ctx = nil
+ }
+}
+
+func (p *BaseParser) EnterOuterAlt(localctx ParserRuleContext, altNum int) {
+ localctx.SetAltNumber(altNum)
+ // if we have a new localctx, make sure we replace existing ctx
+ // that is previous child of parse tree
+ if p.BuildParseTrees && p.ctx != localctx {
+ if p.ctx.GetParent() != nil {
+ p.ctx.GetParent().(ParserRuleContext).RemoveLastChild()
+ p.ctx.GetParent().(ParserRuleContext).AddChild(localctx)
+ }
+ }
+ p.ctx = localctx
+}
+
+// Get the precedence level for the top-most precedence rule.
+//
+// @return The precedence level for the top-most precedence rule, or -1 if
+// the parser context is not nested within a precedence rule.
+
+func (p *BaseParser) GetPrecedence() int {
+ if len(p.precedenceStack) == 0 {
+ return -1
+ }
+
+ return p.precedenceStack[len(p.precedenceStack)-1]
+}
+
+func (p *BaseParser) EnterRecursionRule(localctx ParserRuleContext, state, _, precedence int) {
+ p.SetState(state)
+ p.precedenceStack.Push(precedence)
+ p.ctx = localctx
+ p.ctx.SetStart(p.input.LT(1))
+ if p.parseListeners != nil {
+ p.TriggerEnterRuleEvent() // simulates rule entry for
+ // left-recursive rules
+ }
+}
+
+//
+// Like {@link //EnterRule} but for recursive rules.
+
+func (p *BaseParser) PushNewRecursionContext(localctx ParserRuleContext, state, _ int) {
+ previous := p.ctx
+ previous.SetParent(localctx)
+ previous.SetInvokingState(state)
+ previous.SetStop(p.input.LT(-1))
+
+ p.ctx = localctx
+ p.ctx.SetStart(previous.GetStart())
+ if p.BuildParseTrees {
+ p.ctx.AddChild(previous)
+ }
+ if p.parseListeners != nil {
+ p.TriggerEnterRuleEvent() // simulates rule entry for
+ // left-recursive rules
+ }
+}
+
+func (p *BaseParser) UnrollRecursionContexts(parentCtx ParserRuleContext) {
+ _, _ = p.precedenceStack.Pop()
+ p.ctx.SetStop(p.input.LT(-1))
+ retCtx := p.ctx // save current ctx (return value)
+ // unroll so ctx is as it was before call to recursive method
+ if p.parseListeners != nil {
+ for p.ctx != parentCtx {
+ p.TriggerExitRuleEvent()
+ p.ctx = p.ctx.GetParent().(ParserRuleContext)
+ }
+ } else {
+ p.ctx = parentCtx
+ }
+ // hook into tree
+ retCtx.SetParent(parentCtx)
+ if p.BuildParseTrees && parentCtx != nil {
+ // add return ctx into invoking rule's tree
+ parentCtx.AddChild(retCtx)
+ }
+}
+
+func (p *BaseParser) GetInvokingContext(ruleIndex int) ParserRuleContext {
+ ctx := p.ctx
+ for ctx != nil {
+ if ctx.GetRuleIndex() == ruleIndex {
+ return ctx
+ }
+ ctx = ctx.GetParent().(ParserRuleContext)
+ }
+ return nil
+}
+
+func (p *BaseParser) Precpred(_ RuleContext, precedence int) bool {
+ return precedence >= p.precedenceStack[len(p.precedenceStack)-1]
+}
+
+//goland:noinspection GoUnusedParameter
+func (p *BaseParser) inContext(context ParserRuleContext) bool {
+ // TODO: useful in parser?
+ return false
+}
+
+// IsExpectedToken checks whether symbol can follow the current state in the
+// {ATN}. The behavior of p.method is equivalent to the following, but is
+// implemented such that the complete context-sensitive follow set does not
+// need to be explicitly constructed.
+//
+// return getExpectedTokens().contains(symbol)
+func (p *BaseParser) IsExpectedToken(symbol int) bool {
+ atn := p.Interpreter.atn
+ ctx := p.ctx
+ s := atn.states[p.state]
+ following := atn.NextTokens(s, nil)
+ if following.contains(symbol) {
+ return true
+ }
+ if !following.contains(TokenEpsilon) {
+ return false
+ }
+ for ctx != nil && ctx.GetInvokingState() >= 0 && following.contains(TokenEpsilon) {
+ invokingState := atn.states[ctx.GetInvokingState()]
+ rt := invokingState.GetTransitions()[0]
+ following = atn.NextTokens(rt.(*RuleTransition).followState, nil)
+ if following.contains(symbol) {
+ return true
+ }
+ ctx = ctx.GetParent().(ParserRuleContext)
+ }
+ if following.contains(TokenEpsilon) && symbol == TokenEOF {
+ return true
+ }
+
+ return false
+}
+
+// GetExpectedTokens and returns the set of input symbols which could follow the current parser
+// state and context, as given by [GetState] and [GetContext],
+// respectively.
+func (p *BaseParser) GetExpectedTokens() *IntervalSet {
+ return p.Interpreter.atn.getExpectedTokens(p.state, p.ctx)
+}
+
+func (p *BaseParser) GetExpectedTokensWithinCurrentRule() *IntervalSet {
+ atn := p.Interpreter.atn
+ s := atn.states[p.state]
+ return atn.NextTokens(s, nil)
+}
+
+// GetRuleIndex get a rule's index (i.e., RULE_ruleName field) or -1 if not found.
+func (p *BaseParser) GetRuleIndex(ruleName string) int {
+ var ruleIndex, ok = p.GetRuleIndexMap()[ruleName]
+ if ok {
+ return ruleIndex
+ }
+
+ return -1
+}
+
+// GetRuleInvocationStack returns a list of the rule names in your parser instance
+// leading up to a call to the current rule. You could override if
+// you want more details such as the file/line info of where
+// in the ATN a rule is invoked.
+func (p *BaseParser) GetRuleInvocationStack(c ParserRuleContext) []string {
+ if c == nil {
+ c = p.ctx
+ }
+ stack := make([]string, 0)
+ for c != nil {
+ // compute what follows who invoked us
+ ruleIndex := c.GetRuleIndex()
+ if ruleIndex < 0 {
+ stack = append(stack, "n/a")
+ } else {
+ stack = append(stack, p.GetRuleNames()[ruleIndex])
+ }
+
+ vp := c.GetParent()
+
+ if vp == nil {
+ break
+ }
+
+ c = vp.(ParserRuleContext)
+ }
+ return stack
+}
+
+// GetDFAStrings returns a list of all DFA states used for debugging purposes
+func (p *BaseParser) GetDFAStrings() string {
+ return fmt.Sprint(p.Interpreter.decisionToDFA)
+}
+
+// DumpDFA prints the whole of the DFA for debugging
+func (p *BaseParser) DumpDFA() {
+ seenOne := false
+ for _, dfa := range p.Interpreter.decisionToDFA {
+ if dfa.Len() > 0 {
+ if seenOne {
+ fmt.Println()
+ }
+ fmt.Println("Decision " + strconv.Itoa(dfa.decision) + ":")
+ fmt.Print(dfa.String(p.LiteralNames, p.SymbolicNames))
+ seenOne = true
+ }
+ }
+}
+
+func (p *BaseParser) GetSourceName() string {
+ return p.GrammarFileName
+}
+
+// SetTrace installs a trace listener for the parse.
+//
+// During a parse it is sometimes useful to listen in on the rule entry and exit
+// events as well as token Matches. This is for quick and dirty debugging.
+func (p *BaseParser) SetTrace(trace *TraceListener) {
+ if trace == nil {
+ p.RemoveParseListener(p.tracer)
+ p.tracer = nil
+ } else {
+ if p.tracer != nil {
+ p.RemoveParseListener(p.tracer)
+ }
+ p.tracer = NewTraceListener(p)
+ p.AddParseListener(p.tracer)
+ }
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/parser_atn_simulator.go b/vendor/github.com/antlr4-go/antlr/v4/parser_atn_simulator.go
new file mode 100644
index 000000000000..ae2869692a67
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/parser_atn_simulator.go
@@ -0,0 +1,1668 @@
+// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
+// Use of this file is governed by the BSD 3-clause license that
+// can be found in the LICENSE.txt file in the project root.
+
+package antlr
+
+import (
+ "fmt"
+ "strconv"
+ "strings"
+)
+
+var ()
+
+// ClosureBusy is a store of ATNConfigs and is a tiny abstraction layer over
+// a standard JStore so that we can use Lazy instantiation of the JStore, mostly
+// to avoid polluting the stats module with a ton of JStore instances with nothing in them.
+type ClosureBusy struct {
+ bMap *JStore[*ATNConfig, Comparator[*ATNConfig]]
+ desc string
+}
+
+// NewClosureBusy creates a new ClosureBusy instance used to avoid infinite recursion for right-recursive rules
+func NewClosureBusy(desc string) *ClosureBusy {
+ return &ClosureBusy{
+ desc: desc,
+ }
+}
+
+func (c *ClosureBusy) Put(config *ATNConfig) (*ATNConfig, bool) {
+ if c.bMap == nil {
+ c.bMap = NewJStore[*ATNConfig, Comparator[*ATNConfig]](aConfEqInst, ClosureBusyCollection, c.desc)
+ }
+ return c.bMap.Put(config)
+}
+
+type ParserATNSimulator struct {
+ BaseATNSimulator
+
+ parser Parser
+ predictionMode int
+ input TokenStream
+ startIndex int
+ dfa *DFA
+ mergeCache *JPCMap
+ outerContext ParserRuleContext
+}
+
+//goland:noinspection GoUnusedExportedFunction
+func NewParserATNSimulator(parser Parser, atn *ATN, decisionToDFA []*DFA, sharedContextCache *PredictionContextCache) *ParserATNSimulator {
+
+ p := &ParserATNSimulator{
+ BaseATNSimulator: BaseATNSimulator{
+ atn: atn,
+ sharedContextCache: sharedContextCache,
+ },
+ }
+
+ p.parser = parser
+ p.decisionToDFA = decisionToDFA
+ // SLL, LL, or LL + exact ambig detection?//
+ p.predictionMode = PredictionModeLL
+ // LAME globals to avoid parameters!!!!! I need these down deep in predTransition
+ p.input = nil
+ p.startIndex = 0
+ p.outerContext = nil
+ p.dfa = nil
+ // Each prediction operation uses a cache for merge of prediction contexts.
+ // Don't keep around as it wastes huge amounts of memory. [JPCMap]
+ // isn't Synchronized, but we're ok since two threads shouldn't reuse same
+ // parser/atn-simulator object because it can only handle one input at a time.
+ // This maps graphs a and b to merged result c. (a,b) -> c. We can avoid
+ // the merge if we ever see a and b again. Note that (b,a) -> c should
+ // also be examined during cache lookup.
+ //
+ p.mergeCache = nil
+
+ return p
+}
+
+func (p *ParserATNSimulator) GetPredictionMode() int {
+ return p.predictionMode
+}
+
+func (p *ParserATNSimulator) SetPredictionMode(v int) {
+ p.predictionMode = v
+}
+
+func (p *ParserATNSimulator) reset() {
+}
+
+//goland:noinspection GoBoolExpressions
+func (p *ParserATNSimulator) AdaptivePredict(parser *BaseParser, input TokenStream, decision int, outerContext ParserRuleContext) int {
+ if runtimeConfig.parserATNSimulatorDebug || runtimeConfig.parserATNSimulatorTraceATNSim {
+ fmt.Println("adaptivePredict decision " + strconv.Itoa(decision) +
+ " exec LA(1)==" + p.getLookaheadName(input) +
+ " line " + strconv.Itoa(input.LT(1).GetLine()) + ":" +
+ strconv.Itoa(input.LT(1).GetColumn()))
+ }
+ p.input = input
+ p.startIndex = input.Index()
+ p.outerContext = outerContext
+
+ dfa := p.decisionToDFA[decision]
+ p.dfa = dfa
+ m := input.Mark()
+ index := input.Index()
+
+ defer func() {
+ p.dfa = nil
+ p.mergeCache = nil // whack cache after each prediction
+ // Do not attempt to run a GC now that we're done with the cache as makes the
+ // GC overhead terrible for badly formed grammars and has little effect on well formed
+ // grammars.
+ // I have made some extra effort to try and reduce memory pressure by reusing allocations when
+ // possible. However, it can only have a limited effect. The real solution is to encourage grammar
+ // authors to think more carefully about their grammar and to use the new antlr.stats tag to inspect
+ // what is happening at runtime, along with using the error listener to report ambiguities.
+
+ input.Seek(index)
+ input.Release(m)
+ }()
+
+ // Now we are certain to have a specific decision's DFA
+ // But, do we still need an initial state?
+ var s0 *DFAState
+ p.atn.stateMu.RLock()
+ if dfa.getPrecedenceDfa() {
+ p.atn.edgeMu.RLock()
+ // the start state for a precedence DFA depends on the current
+ // parser precedence, and is provided by a DFA method.
+ s0 = dfa.getPrecedenceStartState(p.parser.GetPrecedence())
+ p.atn.edgeMu.RUnlock()
+ } else {
+ // the start state for a "regular" DFA is just s0
+ s0 = dfa.getS0()
+ }
+ p.atn.stateMu.RUnlock()
+
+ if s0 == nil {
+ if outerContext == nil {
+ outerContext = ParserRuleContextEmpty
+ }
+ if runtimeConfig.parserATNSimulatorDebug {
+ fmt.Println("predictATN decision " + strconv.Itoa(dfa.decision) +
+ " exec LA(1)==" + p.getLookaheadName(input) +
+ ", outerContext=" + outerContext.String(p.parser.GetRuleNames(), nil))
+ }
+ fullCtx := false
+ s0Closure := p.computeStartState(dfa.atnStartState, ParserRuleContextEmpty, fullCtx)
+
+ p.atn.stateMu.Lock()
+ if dfa.getPrecedenceDfa() {
+ // If p is a precedence DFA, we use applyPrecedenceFilter
+ // to convert the computed start state to a precedence start
+ // state. We then use DFA.setPrecedenceStartState to set the
+ // appropriate start state for the precedence level rather
+ // than simply setting DFA.s0.
+ //
+ dfa.s0.configs = s0Closure
+ s0Closure = p.applyPrecedenceFilter(s0Closure)
+ s0 = p.addDFAState(dfa, NewDFAState(-1, s0Closure))
+ p.atn.edgeMu.Lock()
+ dfa.setPrecedenceStartState(p.parser.GetPrecedence(), s0)
+ p.atn.edgeMu.Unlock()
+ } else {
+ s0 = p.addDFAState(dfa, NewDFAState(-1, s0Closure))
+ dfa.setS0(s0)
+ }
+ p.atn.stateMu.Unlock()
+ }
+
+ alt, re := p.execATN(dfa, s0, input, index, outerContext)
+ parser.SetError(re)
+ if runtimeConfig.parserATNSimulatorDebug {
+ fmt.Println("DFA after predictATN: " + dfa.String(p.parser.GetLiteralNames(), nil))
+ }
+ return alt
+
+}
+
+// execATN performs ATN simulation to compute a predicted alternative based
+// upon the remaining input, but also updates the DFA cache to avoid
+// having to traverse the ATN again for the same input sequence.
+//
+// There are some key conditions we're looking for after computing a new
+// set of ATN configs (proposed DFA state):
+//
+// - If the set is empty, there is no viable alternative for current symbol
+// - Does the state uniquely predict an alternative?
+// - Does the state have a conflict that would prevent us from
+// putting it on the work list?
+//
+// We also have some key operations to do:
+//
+// - Add an edge from previous DFA state to potentially NewDFA state, D,
+// - Upon current symbol but only if adding to work list, which means in all
+// cases except no viable alternative (and possibly non-greedy decisions?)
+// - Collecting predicates and adding semantic context to DFA accept states
+// - adding rule context to context-sensitive DFA accept states
+// - Consuming an input symbol
+// - Reporting a conflict
+// - Reporting an ambiguity
+// - Reporting a context sensitivity
+// - Reporting insufficient predicates
+//
+// Cover these cases:
+//
+// - dead end
+// - single alt
+// - single alt + predicates
+// - conflict
+// - conflict + predicates
+//
+//goland:noinspection GoBoolExpressions
+func (p *ParserATNSimulator) execATN(dfa *DFA, s0 *DFAState, input TokenStream, startIndex int, outerContext ParserRuleContext) (int, RecognitionException) {
+
+ if runtimeConfig.parserATNSimulatorDebug || runtimeConfig.parserATNSimulatorTraceATNSim {
+ fmt.Println("execATN decision " + strconv.Itoa(dfa.decision) +
+ ", DFA state " + s0.String() +
+ ", LA(1)==" + p.getLookaheadName(input) +
+ " line " + strconv.Itoa(input.LT(1).GetLine()) + ":" + strconv.Itoa(input.LT(1).GetColumn()))
+ }
+
+ previousD := s0
+
+ if runtimeConfig.parserATNSimulatorDebug {
+ fmt.Println("s0 = " + s0.String())
+ }
+ t := input.LA(1)
+ for { // for more work
+ D := p.getExistingTargetState(previousD, t)
+ if D == nil {
+ D = p.computeTargetState(dfa, previousD, t)
+ }
+ if D == ATNSimulatorError {
+ // if any configs in previous dipped into outer context, that
+ // means that input up to t actually finished entry rule
+ // at least for SLL decision. Full LL doesn't dip into outer
+ // so don't need special case.
+ // We will get an error no matter what so delay until after
+ // decision better error message. Also, no reachable target
+ // ATN states in SLL implies LL will also get nowhere.
+ // If conflict in states that dip out, choose min since we
+ // will get error no matter what.
+ e := p.noViableAlt(input, outerContext, previousD.configs, startIndex)
+ input.Seek(startIndex)
+ alt := p.getSynValidOrSemInvalidAltThatFinishedDecisionEntryRule(previousD.configs, outerContext)
+ if alt != ATNInvalidAltNumber {
+ return alt, nil
+ }
+ p.parser.SetError(e)
+ return ATNInvalidAltNumber, e
+ }
+ if D.requiresFullContext && p.predictionMode != PredictionModeSLL {
+ // IF PREDS, MIGHT RESOLVE TO SINGLE ALT => SLL (or syntax error)
+ conflictingAlts := D.configs.conflictingAlts
+ if D.predicates != nil {
+ if runtimeConfig.parserATNSimulatorDebug {
+ fmt.Println("DFA state has preds in DFA sim LL fail-over")
+ }
+ conflictIndex := input.Index()
+ if conflictIndex != startIndex {
+ input.Seek(startIndex)
+ }
+ conflictingAlts = p.evalSemanticContext(D.predicates, outerContext, true)
+ if conflictingAlts.length() == 1 {
+ if runtimeConfig.parserATNSimulatorDebug {
+ fmt.Println("Full LL avoided")
+ }
+ return conflictingAlts.minValue(), nil
+ }
+ if conflictIndex != startIndex {
+ // restore the index so Reporting the fallback to full
+ // context occurs with the index at the correct spot
+ input.Seek(conflictIndex)
+ }
+ }
+ if runtimeConfig.parserATNSimulatorDFADebug {
+ fmt.Println("ctx sensitive state " + outerContext.String(nil, nil) + " in " + D.String())
+ }
+ fullCtx := true
+ s0Closure := p.computeStartState(dfa.atnStartState, outerContext, fullCtx)
+ p.ReportAttemptingFullContext(dfa, conflictingAlts, D.configs, startIndex, input.Index())
+ alt, re := p.execATNWithFullContext(dfa, D, s0Closure, input, startIndex, outerContext)
+ return alt, re
+ }
+ if D.isAcceptState {
+ if D.predicates == nil {
+ return D.prediction, nil
+ }
+ stopIndex := input.Index()
+ input.Seek(startIndex)
+ alts := p.evalSemanticContext(D.predicates, outerContext, true)
+
+ switch alts.length() {
+ case 0:
+ return ATNInvalidAltNumber, p.noViableAlt(input, outerContext, D.configs, startIndex)
+ case 1:
+ return alts.minValue(), nil
+ default:
+ // Report ambiguity after predicate evaluation to make sure the correct set of ambig alts is Reported.
+ p.ReportAmbiguity(dfa, D, startIndex, stopIndex, false, alts, D.configs)
+ return alts.minValue(), nil
+ }
+ }
+ previousD = D
+
+ if t != TokenEOF {
+ input.Consume()
+ t = input.LA(1)
+ }
+ }
+}
+
+// Get an existing target state for an edge in the DFA. If the target state
+// for the edge has not yet been computed or is otherwise not available,
+// p method returns {@code nil}.
+//
+// @param previousD The current DFA state
+// @param t The next input symbol
+// @return The existing target DFA state for the given input symbol
+// {@code t}, or {@code nil} if the target state for p edge is not
+// already cached
+
+func (p *ParserATNSimulator) getExistingTargetState(previousD *DFAState, t int) *DFAState {
+ if t+1 < 0 {
+ return nil
+ }
+
+ p.atn.edgeMu.RLock()
+ defer p.atn.edgeMu.RUnlock()
+ edges := previousD.getEdges()
+ if edges == nil || t+1 >= len(edges) {
+ return nil
+ }
+ return previousD.getIthEdge(t + 1)
+}
+
+// Compute a target state for an edge in the DFA, and attempt to add the
+// computed state and corresponding edge to the DFA.
+//
+// @param dfa The DFA
+// @param previousD The current DFA state
+// @param t The next input symbol
+//
+// @return The computed target DFA state for the given input symbol
+// {@code t}. If {@code t} does not lead to a valid DFA state, p method
+// returns {@link //ERROR}.
+//
+//goland:noinspection GoBoolExpressions
+func (p *ParserATNSimulator) computeTargetState(dfa *DFA, previousD *DFAState, t int) *DFAState {
+ reach := p.computeReachSet(previousD.configs, t, false)
+
+ if reach == nil {
+ p.addDFAEdge(dfa, previousD, t, ATNSimulatorError)
+ return ATNSimulatorError
+ }
+ // create new target state we'll add to DFA after it's complete
+ D := NewDFAState(-1, reach)
+
+ predictedAlt := p.getUniqueAlt(reach)
+
+ if runtimeConfig.parserATNSimulatorDebug {
+ altSubSets := PredictionModegetConflictingAltSubsets(reach)
+ fmt.Println("SLL altSubSets=" + fmt.Sprint(altSubSets) +
+ ", previous=" + previousD.configs.String() +
+ ", configs=" + reach.String() +
+ ", predict=" + strconv.Itoa(predictedAlt) +
+ ", allSubsetsConflict=" +
+ fmt.Sprint(PredictionModeallSubsetsConflict(altSubSets)) +
+ ", conflictingAlts=" + p.getConflictingAlts(reach).String())
+ }
+ if predictedAlt != ATNInvalidAltNumber {
+ // NO CONFLICT, UNIQUELY PREDICTED ALT
+ D.isAcceptState = true
+ D.configs.uniqueAlt = predictedAlt
+ D.setPrediction(predictedAlt)
+ } else if PredictionModehasSLLConflictTerminatingPrediction(p.predictionMode, reach) {
+ // MORE THAN ONE VIABLE ALTERNATIVE
+ D.configs.conflictingAlts = p.getConflictingAlts(reach)
+ D.requiresFullContext = true
+ // in SLL-only mode, we will stop at p state and return the minimum alt
+ D.isAcceptState = true
+ D.setPrediction(D.configs.conflictingAlts.minValue())
+ }
+ if D.isAcceptState && D.configs.hasSemanticContext {
+ p.predicateDFAState(D, p.atn.getDecisionState(dfa.decision))
+ if D.predicates != nil {
+ D.setPrediction(ATNInvalidAltNumber)
+ }
+ }
+ // all adds to dfa are done after we've created full D state
+ D = p.addDFAEdge(dfa, previousD, t, D)
+ return D
+}
+
+func (p *ParserATNSimulator) predicateDFAState(dfaState *DFAState, decisionState DecisionState) {
+ // We need to test all predicates, even in DFA states that
+ // uniquely predict alternative.
+ nalts := len(decisionState.GetTransitions())
+ // Update DFA so reach becomes accept state with (predicate,alt)
+ // pairs if preds found for conflicting alts
+ altsToCollectPredsFrom := p.getConflictingAltsOrUniqueAlt(dfaState.configs)
+ altToPred := p.getPredsForAmbigAlts(altsToCollectPredsFrom, dfaState.configs, nalts)
+ if altToPred != nil {
+ dfaState.predicates = p.getPredicatePredictions(altsToCollectPredsFrom, altToPred)
+ dfaState.setPrediction(ATNInvalidAltNumber) // make sure we use preds
+ } else {
+ // There are preds in configs but they might go away
+ // when OR'd together like {p}? || NONE == NONE. If neither
+ // alt has preds, resolve to min alt
+ dfaState.setPrediction(altsToCollectPredsFrom.minValue())
+ }
+}
+
+// comes back with reach.uniqueAlt set to a valid alt
+//
+//goland:noinspection GoBoolExpressions
+func (p *ParserATNSimulator) execATNWithFullContext(dfa *DFA, D *DFAState, s0 *ATNConfigSet, input TokenStream, startIndex int, outerContext ParserRuleContext) (int, RecognitionException) {
+
+ if runtimeConfig.parserATNSimulatorDebug || runtimeConfig.parserATNSimulatorTraceATNSim {
+ fmt.Println("execATNWithFullContext " + s0.String())
+ }
+
+ fullCtx := true
+ foundExactAmbig := false
+ var reach *ATNConfigSet
+ previous := s0
+ input.Seek(startIndex)
+ t := input.LA(1)
+ predictedAlt := -1
+
+ for { // for more work
+ reach = p.computeReachSet(previous, t, fullCtx)
+ if reach == nil {
+ // if any configs in previous dipped into outer context, that
+ // means that input up to t actually finished entry rule
+ // at least for LL decision. Full LL doesn't dip into outer
+ // so don't need special case.
+ // We will get an error no matter what so delay until after
+ // decision better error message. Also, no reachable target
+ // ATN states in SLL implies LL will also get nowhere.
+ // If conflict in states that dip out, choose min since we
+ // will get error no matter what.
+ input.Seek(startIndex)
+ alt := p.getSynValidOrSemInvalidAltThatFinishedDecisionEntryRule(previous, outerContext)
+ if alt != ATNInvalidAltNumber {
+ return alt, nil
+ }
+ return alt, p.noViableAlt(input, outerContext, previous, startIndex)
+ }
+ altSubSets := PredictionModegetConflictingAltSubsets(reach)
+ if runtimeConfig.parserATNSimulatorDebug {
+ fmt.Println("LL altSubSets=" + fmt.Sprint(altSubSets) + ", predict=" +
+ strconv.Itoa(PredictionModegetUniqueAlt(altSubSets)) + ", resolvesToJustOneViableAlt=" +
+ fmt.Sprint(PredictionModeresolvesToJustOneViableAlt(altSubSets)))
+ }
+ reach.uniqueAlt = p.getUniqueAlt(reach)
+ // unique prediction?
+ if reach.uniqueAlt != ATNInvalidAltNumber {
+ predictedAlt = reach.uniqueAlt
+ break
+ }
+ if p.predictionMode != PredictionModeLLExactAmbigDetection {
+ predictedAlt = PredictionModeresolvesToJustOneViableAlt(altSubSets)
+ if predictedAlt != ATNInvalidAltNumber {
+ break
+ }
+ } else {
+ // In exact ambiguity mode, we never try to terminate early.
+ // Just keeps scarfing until we know what the conflict is
+ if PredictionModeallSubsetsConflict(altSubSets) && PredictionModeallSubsetsEqual(altSubSets) {
+ foundExactAmbig = true
+ predictedAlt = PredictionModegetSingleViableAlt(altSubSets)
+ break
+ }
+ // else there are multiple non-conflicting subsets or
+ // we're not sure what the ambiguity is yet.
+ // So, keep going.
+ }
+ previous = reach
+ if t != TokenEOF {
+ input.Consume()
+ t = input.LA(1)
+ }
+ }
+ // If the configuration set uniquely predicts an alternative,
+ // without conflict, then we know that it's a full LL decision
+ // not SLL.
+ if reach.uniqueAlt != ATNInvalidAltNumber {
+ p.ReportContextSensitivity(dfa, predictedAlt, reach, startIndex, input.Index())
+ return predictedAlt, nil
+ }
+ // We do not check predicates here because we have checked them
+ // on-the-fly when doing full context prediction.
+
+ //
+ // In non-exact ambiguity detection mode, we might actually be able to
+ // detect an exact ambiguity, but I'm not going to spend the cycles
+ // needed to check. We only emit ambiguity warnings in exact ambiguity
+ // mode.
+ //
+ // For example, we might know that we have conflicting configurations.
+ // But, that does not mean that there is no way forward without a
+ // conflict. It's possible to have non-conflicting alt subsets as in:
+ //
+ // altSubSets=[{1, 2}, {1, 2}, {1}, {1, 2}]
+ //
+ // from
+ //
+ // [(17,1,[5 $]), (13,1,[5 10 $]), (21,1,[5 10 $]), (11,1,[$]),
+ // (13,2,[5 10 $]), (21,2,[5 10 $]), (11,2,[$])]
+ //
+ // In p case, (17,1,[5 $]) indicates there is some next sequence that
+ // would resolve p without conflict to alternative 1. Any other viable
+ // next sequence, however, is associated with a conflict. We stop
+ // looking for input because no amount of further lookahead will alter
+ // the fact that we should predict alternative 1. We just can't say for
+ // sure that there is an ambiguity without looking further.
+
+ p.ReportAmbiguity(dfa, D, startIndex, input.Index(), foundExactAmbig, reach.Alts(), reach)
+
+ return predictedAlt, nil
+}
+
+//goland:noinspection GoBoolExpressions
+func (p *ParserATNSimulator) computeReachSet(closure *ATNConfigSet, t int, fullCtx bool) *ATNConfigSet {
+ if p.mergeCache == nil {
+ p.mergeCache = NewJPCMap(ReachSetCollection, "Merge cache for computeReachSet()")
+ }
+ intermediate := NewATNConfigSet(fullCtx)
+
+ // Configurations already in a rule stop state indicate reaching the end
+ // of the decision rule (local context) or end of the start rule (full
+ // context). Once reached, these configurations are never updated by a
+ // closure operation, so they are handled separately for the performance
+ // advantage of having a smaller intermediate set when calling closure.
+ //
+ // For full-context reach operations, separate handling is required to
+ // ensure that the alternative Matching the longest overall sequence is
+ // chosen when multiple such configurations can Match the input.
+
+ var skippedStopStates []*ATNConfig
+
+ // First figure out where we can reach on input t
+ for _, c := range closure.configs {
+ if runtimeConfig.parserATNSimulatorDebug {
+ fmt.Println("testing " + p.GetTokenName(t) + " at " + c.String())
+ }
+
+ if _, ok := c.GetState().(*RuleStopState); ok {
+ if fullCtx || t == TokenEOF {
+ skippedStopStates = append(skippedStopStates, c)
+ if runtimeConfig.parserATNSimulatorDebug {
+ fmt.Println("added " + c.String() + " to SkippedStopStates")
+ }
+ }
+ continue
+ }
+
+ for _, trans := range c.GetState().GetTransitions() {
+ target := p.getReachableTarget(trans, t)
+ if target != nil {
+ cfg := NewATNConfig4(c, target)
+ intermediate.Add(cfg, p.mergeCache)
+ if runtimeConfig.parserATNSimulatorDebug {
+ fmt.Println("added " + cfg.String() + " to intermediate")
+ }
+ }
+ }
+ }
+
+ // Now figure out where the reach operation can take us...
+ var reach *ATNConfigSet
+
+ // This block optimizes the reach operation for intermediate sets which
+ // trivially indicate a termination state for the overall
+ // AdaptivePredict operation.
+ //
+ // The conditions assume that intermediate
+ // contains all configurations relevant to the reach set, but p
+ // condition is not true when one or more configurations have been
+ // withheld in SkippedStopStates, or when the current symbol is EOF.
+ //
+ if skippedStopStates == nil && t != TokenEOF {
+ if len(intermediate.configs) == 1 {
+ // Don't pursue the closure if there is just one state.
+ // It can only have one alternative just add to result
+ // Also don't pursue the closure if there is unique alternative
+ // among the configurations.
+ reach = intermediate
+ } else if p.getUniqueAlt(intermediate) != ATNInvalidAltNumber {
+ // Also don't pursue the closure if there is unique alternative
+ // among the configurations.
+ reach = intermediate
+ }
+ }
+ // If the reach set could not be trivially determined, perform a closure
+ // operation on the intermediate set to compute its initial value.
+ //
+ if reach == nil {
+ reach = NewATNConfigSet(fullCtx)
+ closureBusy := NewClosureBusy("ParserATNSimulator.computeReachSet() make a closureBusy")
+ treatEOFAsEpsilon := t == TokenEOF
+ amount := len(intermediate.configs)
+ for k := 0; k < amount; k++ {
+ p.closure(intermediate.configs[k], reach, closureBusy, false, fullCtx, treatEOFAsEpsilon)
+ }
+ }
+ if t == TokenEOF {
+ // After consuming EOF no additional input is possible, so we are
+ // only interested in configurations which reached the end of the
+ // decision rule (local context) or end of the start rule (full
+ // context). Update reach to contain only these configurations. This
+ // handles both explicit EOF transitions in the grammar and implicit
+ // EOF transitions following the end of the decision or start rule.
+ //
+ // When reach==intermediate, no closure operation was performed. In
+ // p case, removeAllConfigsNotInRuleStopState needs to check for
+ // reachable rule stop states as well as configurations already in
+ // a rule stop state.
+ //
+ // This is handled before the configurations in SkippedStopStates,
+ // because any configurations potentially added from that list are
+ // already guaranteed to meet this condition whether it's
+ // required.
+ //
+ reach = p.removeAllConfigsNotInRuleStopState(reach, reach.Equals(intermediate))
+ }
+ // If SkippedStopStates!=nil, then it contains at least one
+ // configuration. For full-context reach operations, these
+ // configurations reached the end of the start rule, in which case we
+ // only add them back to reach if no configuration during the current
+ // closure operation reached such a state. This ensures AdaptivePredict
+ // chooses an alternative Matching the longest overall sequence when
+ // multiple alternatives are viable.
+ //
+ if skippedStopStates != nil && ((!fullCtx) || (!PredictionModehasConfigInRuleStopState(reach))) {
+ for l := 0; l < len(skippedStopStates); l++ {
+ reach.Add(skippedStopStates[l], p.mergeCache)
+ }
+ }
+
+ if runtimeConfig.parserATNSimulatorTraceATNSim {
+ fmt.Println("computeReachSet " + closure.String() + " -> " + reach.String())
+ }
+
+ if len(reach.configs) == 0 {
+ return nil
+ }
+
+ return reach
+}
+
+// removeAllConfigsNotInRuleStopState returns a configuration set containing only the configurations from
+// configs which are in a [RuleStopState]. If all
+// configurations in configs are already in a rule stop state, this
+// method simply returns configs.
+//
+// When lookToEndOfRule is true, this method uses
+// [ATN].[NextTokens] for each configuration in configs which is
+// not already in a rule stop state to see if a rule stop state is reachable
+// from the configuration via epsilon-only transitions.
+//
+// When lookToEndOfRule is true, this method checks for rule stop states
+// reachable by epsilon-only transitions from each configuration in
+// configs.
+//
+// The func returns configs if all configurations in configs are in a
+// rule stop state, otherwise it returns a new configuration set containing only
+// the configurations from configs which are in a rule stop state
+func (p *ParserATNSimulator) removeAllConfigsNotInRuleStopState(configs *ATNConfigSet, lookToEndOfRule bool) *ATNConfigSet {
+ if PredictionModeallConfigsInRuleStopStates(configs) {
+ return configs
+ }
+ result := NewATNConfigSet(configs.fullCtx)
+ for _, config := range configs.configs {
+ if _, ok := config.GetState().(*RuleStopState); ok {
+ result.Add(config, p.mergeCache)
+ continue
+ }
+ if lookToEndOfRule && config.GetState().GetEpsilonOnlyTransitions() {
+ NextTokens := p.atn.NextTokens(config.GetState(), nil)
+ if NextTokens.contains(TokenEpsilon) {
+ endOfRuleState := p.atn.ruleToStopState[config.GetState().GetRuleIndex()]
+ result.Add(NewATNConfig4(config, endOfRuleState), p.mergeCache)
+ }
+ }
+ }
+ return result
+}
+
+//goland:noinspection GoBoolExpressions
+func (p *ParserATNSimulator) computeStartState(a ATNState, ctx RuleContext, fullCtx bool) *ATNConfigSet {
+ // always at least the implicit call to start rule
+ initialContext := predictionContextFromRuleContext(p.atn, ctx)
+ configs := NewATNConfigSet(fullCtx)
+ if runtimeConfig.parserATNSimulatorDebug || runtimeConfig.parserATNSimulatorTraceATNSim {
+ fmt.Println("computeStartState from ATN state " + a.String() +
+ " initialContext=" + initialContext.String())
+ }
+
+ for i := 0; i < len(a.GetTransitions()); i++ {
+ target := a.GetTransitions()[i].getTarget()
+ c := NewATNConfig6(target, i+1, initialContext)
+ closureBusy := NewClosureBusy("ParserATNSimulator.computeStartState() make a closureBusy")
+ p.closure(c, configs, closureBusy, true, fullCtx, false)
+ }
+ return configs
+}
+
+// applyPrecedenceFilter transforms the start state computed by
+// [computeStartState] to the special start state used by a
+// precedence [DFA] for a particular precedence value. The transformation
+// process applies the following changes to the start state's configuration
+// set.
+//
+// 1. Evaluate the precedence predicates for each configuration using
+// [SemanticContext].evalPrecedence.
+// 2. Remove all configurations which predict an alternative greater than
+// 1, for which another configuration that predicts alternative 1 is in the
+// same ATN state with the same prediction context.
+//
+// Transformation 2 is valid for the following reasons:
+//
+// - The closure block cannot contain any epsilon transitions which bypass
+// the body of the closure, so all states reachable via alternative 1 are
+// part of the precedence alternatives of the transformed left-recursive
+// rule.
+// - The "primary" portion of a left recursive rule cannot contain an
+// epsilon transition, so the only way an alternative other than 1 can exist
+// in a state that is also reachable via alternative 1 is by nesting calls
+// to the left-recursive rule, with the outer calls not being at the
+// preferred precedence level.
+//
+// The prediction context must be considered by this filter to address
+// situations like the following:
+//
+// grammar TA
+// prog: statement* EOF
+// statement: letterA | statement letterA 'b'
+// letterA: 'a'
+//
+// In the above grammar, the [ATN] state immediately before the token
+// reference 'a' in letterA is reachable from the left edge
+// of both the primary and closure blocks of the left-recursive rule
+// statement. The prediction context associated with each of these
+// configurations distinguishes between them, and prevents the alternative
+// which stepped out to prog, and then back in to statement
+// from being eliminated by the filter.
+//
+// The func returns the transformed configuration set representing the start state
+// for a precedence [DFA] at a particular precedence level (determined by
+// calling [Parser].getPrecedence).
+func (p *ParserATNSimulator) applyPrecedenceFilter(configs *ATNConfigSet) *ATNConfigSet {
+
+ statesFromAlt1 := make(map[int]*PredictionContext)
+ configSet := NewATNConfigSet(configs.fullCtx)
+
+ for _, config := range configs.configs {
+ // handle alt 1 first
+ if config.GetAlt() != 1 {
+ continue
+ }
+ updatedContext := config.GetSemanticContext().evalPrecedence(p.parser, p.outerContext)
+ if updatedContext == nil {
+ // the configuration was eliminated
+ continue
+ }
+ statesFromAlt1[config.GetState().GetStateNumber()] = config.GetContext()
+ if updatedContext != config.GetSemanticContext() {
+ configSet.Add(NewATNConfig2(config, updatedContext), p.mergeCache)
+ } else {
+ configSet.Add(config, p.mergeCache)
+ }
+ }
+ for _, config := range configs.configs {
+
+ if config.GetAlt() == 1 {
+ // already handled
+ continue
+ }
+ // In the future, p elimination step could be updated to also
+ // filter the prediction context for alternatives predicting alt>1
+ // (basically a graph subtraction algorithm).
+ if !config.getPrecedenceFilterSuppressed() {
+ context := statesFromAlt1[config.GetState().GetStateNumber()]
+ if context != nil && context.Equals(config.GetContext()) {
+ // eliminated
+ continue
+ }
+ }
+ configSet.Add(config, p.mergeCache)
+ }
+ return configSet
+}
+
+func (p *ParserATNSimulator) getReachableTarget(trans Transition, ttype int) ATNState {
+ if trans.Matches(ttype, 0, p.atn.maxTokenType) {
+ return trans.getTarget()
+ }
+
+ return nil
+}
+
+//goland:noinspection GoBoolExpressions
+func (p *ParserATNSimulator) getPredsForAmbigAlts(ambigAlts *BitSet, configs *ATNConfigSet, nalts int) []SemanticContext {
+
+ altToPred := make([]SemanticContext, nalts+1)
+ for _, c := range configs.configs {
+ if ambigAlts.contains(c.GetAlt()) {
+ altToPred[c.GetAlt()] = SemanticContextorContext(altToPred[c.GetAlt()], c.GetSemanticContext())
+ }
+ }
+ nPredAlts := 0
+ for i := 1; i <= nalts; i++ {
+ pred := altToPred[i]
+ if pred == nil {
+ altToPred[i] = SemanticContextNone
+ } else if pred != SemanticContextNone {
+ nPredAlts++
+ }
+ }
+ // unambiguous alts are nil in altToPred
+ if nPredAlts == 0 {
+ altToPred = nil
+ }
+ if runtimeConfig.parserATNSimulatorDebug {
+ fmt.Println("getPredsForAmbigAlts result " + fmt.Sprint(altToPred))
+ }
+ return altToPred
+}
+
+func (p *ParserATNSimulator) getPredicatePredictions(ambigAlts *BitSet, altToPred []SemanticContext) []*PredPrediction {
+ pairs := make([]*PredPrediction, 0)
+ containsPredicate := false
+ for i := 1; i < len(altToPred); i++ {
+ pred := altToPred[i]
+ // un-predicated is indicated by SemanticContextNONE
+ if ambigAlts != nil && ambigAlts.contains(i) {
+ pairs = append(pairs, NewPredPrediction(pred, i))
+ }
+ if pred != SemanticContextNone {
+ containsPredicate = true
+ }
+ }
+ if !containsPredicate {
+ return nil
+ }
+ return pairs
+}
+
+// getSynValidOrSemInvalidAltThatFinishedDecisionEntryRule is used to improve the localization of error messages by
+// choosing an alternative rather than panic a NoViableAltException in particular prediction scenarios where the
+// Error state was reached during [ATN] simulation.
+//
+// The default implementation of this method uses the following
+// algorithm to identify an [ATN] configuration which successfully parsed the
+// decision entry rule. Choosing such an alternative ensures that the
+// [ParserRuleContext] returned by the calling rule will be complete
+// and valid, and the syntax error will be Reported later at a more
+// localized location.
+//
+// - If a syntactically valid path or paths reach the end of the decision rule, and
+// they are semantically valid if predicated, return the min associated alt.
+// - Else, if a semantically invalid but syntactically valid path exist
+// or paths exist, return the minimum associated alt.
+// - Otherwise, return [ATNInvalidAltNumber].
+//
+// In some scenarios, the algorithm described above could predict an
+// alternative which will result in a [FailedPredicateException] in
+// the parser. Specifically, this could occur if the only configuration
+// capable of successfully parsing to the end of the decision rule is
+// blocked by a semantic predicate. By choosing this alternative within
+// [AdaptivePredict] instead of panic a [NoViableAltException], the resulting
+// [FailedPredicateException] in the parser will identify the specific
+// predicate which is preventing the parser from successfully parsing the
+// decision rule, which helps developers identify and correct logic errors
+// in semantic predicates.
+//
+// pass in the configs holding ATN configurations which were valid immediately before
+// the ERROR state was reached, outerContext as the initial parser context from the paper
+// or the parser stack at the instant before prediction commences.
+//
+// Teh func returns the value to return from [AdaptivePredict], or
+// [ATNInvalidAltNumber] if a suitable alternative was not
+// identified and [AdaptivePredict] should report an error instead.
+func (p *ParserATNSimulator) getSynValidOrSemInvalidAltThatFinishedDecisionEntryRule(configs *ATNConfigSet, outerContext ParserRuleContext) int {
+ cfgs := p.splitAccordingToSemanticValidity(configs, outerContext)
+ semValidConfigs := cfgs[0]
+ semInvalidConfigs := cfgs[1]
+ alt := p.GetAltThatFinishedDecisionEntryRule(semValidConfigs)
+ if alt != ATNInvalidAltNumber { // semantically/syntactically viable path exists
+ return alt
+ }
+ // Is there a syntactically valid path with a failed pred?
+ if len(semInvalidConfigs.configs) > 0 {
+ alt = p.GetAltThatFinishedDecisionEntryRule(semInvalidConfigs)
+ if alt != ATNInvalidAltNumber { // syntactically viable path exists
+ return alt
+ }
+ }
+ return ATNInvalidAltNumber
+}
+
+func (p *ParserATNSimulator) GetAltThatFinishedDecisionEntryRule(configs *ATNConfigSet) int {
+ alts := NewIntervalSet()
+
+ for _, c := range configs.configs {
+ _, ok := c.GetState().(*RuleStopState)
+
+ if c.GetReachesIntoOuterContext() > 0 || (ok && c.GetContext().hasEmptyPath()) {
+ alts.addOne(c.GetAlt())
+ }
+ }
+ if alts.length() == 0 {
+ return ATNInvalidAltNumber
+ }
+
+ return alts.first()
+}
+
+// Walk the list of configurations and split them according to
+// those that have preds evaluating to true/false. If no pred, assume
+// true pred and include in succeeded set. Returns Pair of sets.
+//
+// Create a NewSet so as not to alter the incoming parameter.
+//
+// Assumption: the input stream has been restored to the starting point
+// prediction, which is where predicates need to evaluate.
+
+type ATNConfigSetPair struct {
+ item0, item1 *ATNConfigSet
+}
+
+func (p *ParserATNSimulator) splitAccordingToSemanticValidity(configs *ATNConfigSet, outerContext ParserRuleContext) []*ATNConfigSet {
+ succeeded := NewATNConfigSet(configs.fullCtx)
+ failed := NewATNConfigSet(configs.fullCtx)
+
+ for _, c := range configs.configs {
+ if c.GetSemanticContext() != SemanticContextNone {
+ predicateEvaluationResult := c.GetSemanticContext().evaluate(p.parser, outerContext)
+ if predicateEvaluationResult {
+ succeeded.Add(c, nil)
+ } else {
+ failed.Add(c, nil)
+ }
+ } else {
+ succeeded.Add(c, nil)
+ }
+ }
+ return []*ATNConfigSet{succeeded, failed}
+}
+
+// evalSemanticContext looks through a list of predicate/alt pairs, returning alts for the
+// pairs that win. A [SemanticContextNone] predicate indicates an alt containing an
+// un-predicated runtimeConfig which behaves as "always true." If !complete
+// then we stop at the first predicate that evaluates to true. This
+// includes pairs with nil predicates.
+//
+//goland:noinspection GoBoolExpressions
+func (p *ParserATNSimulator) evalSemanticContext(predPredictions []*PredPrediction, outerContext ParserRuleContext, complete bool) *BitSet {
+ predictions := NewBitSet()
+ for i := 0; i < len(predPredictions); i++ {
+ pair := predPredictions[i]
+ if pair.pred == SemanticContextNone {
+ predictions.add(pair.alt)
+ if !complete {
+ break
+ }
+ continue
+ }
+
+ predicateEvaluationResult := pair.pred.evaluate(p.parser, outerContext)
+ if runtimeConfig.parserATNSimulatorDebug || runtimeConfig.parserATNSimulatorDFADebug {
+ fmt.Println("eval pred " + pair.String() + "=" + fmt.Sprint(predicateEvaluationResult))
+ }
+ if predicateEvaluationResult {
+ if runtimeConfig.parserATNSimulatorDebug || runtimeConfig.parserATNSimulatorDFADebug {
+ fmt.Println("PREDICT " + fmt.Sprint(pair.alt))
+ }
+ predictions.add(pair.alt)
+ if !complete {
+ break
+ }
+ }
+ }
+ return predictions
+}
+
+func (p *ParserATNSimulator) closure(config *ATNConfig, configs *ATNConfigSet, closureBusy *ClosureBusy, collectPredicates, fullCtx, treatEOFAsEpsilon bool) {
+ initialDepth := 0
+ p.closureCheckingStopState(config, configs, closureBusy, collectPredicates,
+ fullCtx, initialDepth, treatEOFAsEpsilon)
+}
+
+func (p *ParserATNSimulator) closureCheckingStopState(config *ATNConfig, configs *ATNConfigSet, closureBusy *ClosureBusy, collectPredicates, fullCtx bool, depth int, treatEOFAsEpsilon bool) {
+ if runtimeConfig.parserATNSimulatorTraceATNSim {
+ fmt.Println("closure(" + config.String() + ")")
+ }
+
+ var stack []*ATNConfig
+ visited := make(map[*ATNConfig]bool)
+
+ stack = append(stack, config)
+
+ for len(stack) > 0 {
+ currConfig := stack[len(stack)-1]
+ stack = stack[:len(stack)-1]
+
+ if _, ok := visited[currConfig]; ok {
+ continue
+ }
+ visited[currConfig] = true
+
+ if _, ok := currConfig.GetState().(*RuleStopState); ok {
+ // We hit rule end. If we have context info, use it
+ // run thru all possible stack tops in ctx
+ if !currConfig.GetContext().isEmpty() {
+ for i := 0; i < currConfig.GetContext().length(); i++ {
+ if currConfig.GetContext().getReturnState(i) == BasePredictionContextEmptyReturnState {
+ if fullCtx {
+ nb := NewATNConfig1(currConfig, currConfig.GetState(), BasePredictionContextEMPTY)
+ configs.Add(nb, p.mergeCache)
+ continue
+ } else {
+ // we have no context info, just chase follow links (if greedy)
+ if runtimeConfig.parserATNSimulatorDebug {
+ fmt.Println("FALLING off rule " + p.getRuleName(currConfig.GetState().GetRuleIndex()))
+ }
+ p.closureWork(currConfig, configs, closureBusy, collectPredicates, fullCtx, depth, treatEOFAsEpsilon)
+ }
+ continue
+ }
+ returnState := p.atn.states[currConfig.GetContext().getReturnState(i)]
+ newContext := currConfig.GetContext().GetParent(i) // "pop" return state
+
+ c := NewATNConfig5(returnState, currConfig.GetAlt(), newContext, currConfig.GetSemanticContext())
+ // While we have context to pop back from, we may have
+ // gotten that context AFTER having falling off a rule.
+ // Make sure we track that we are now out of context.
+ c.SetReachesIntoOuterContext(currConfig.GetReachesIntoOuterContext())
+
+ stack = append(stack, c)
+ }
+ continue
+ } else if fullCtx {
+ // reached end of start rule
+ configs.Add(currConfig, p.mergeCache)
+ continue
+ } else {
+ // else if we have no context info, just chase follow links (if greedy)
+ if runtimeConfig.parserATNSimulatorDebug {
+ fmt.Println("FALLING off rule " + p.getRuleName(currConfig.GetState().GetRuleIndex()))
+ }
+ }
+ }
+
+ p.closureWork(currConfig, configs, closureBusy, collectPredicates, fullCtx, depth, treatEOFAsEpsilon)
+ }
+}
+
+//goland:noinspection GoBoolExpressions
+func (p *ParserATNSimulator) closureCheckingStopStateRecursive(config *ATNConfig, configs *ATNConfigSet, closureBusy *ClosureBusy, collectPredicates, fullCtx bool, depth int, treatEOFAsEpsilon bool) {
+ if runtimeConfig.parserATNSimulatorTraceATNSim {
+ fmt.Println("closure(" + config.String() + ")")
+ }
+
+ if _, ok := config.GetState().(*RuleStopState); ok {
+ // We hit rule end. If we have context info, use it
+ // run thru all possible stack tops in ctx
+ if !config.GetContext().isEmpty() {
+ for i := 0; i < config.GetContext().length(); i++ {
+ if config.GetContext().getReturnState(i) == BasePredictionContextEmptyReturnState {
+ if fullCtx {
+ nb := NewATNConfig1(config, config.GetState(), BasePredictionContextEMPTY)
+ configs.Add(nb, p.mergeCache)
+ continue
+ } else {
+ // we have no context info, just chase follow links (if greedy)
+ if runtimeConfig.parserATNSimulatorDebug {
+ fmt.Println("FALLING off rule " + p.getRuleName(config.GetState().GetRuleIndex()))
+ }
+ p.closureWork(config, configs, closureBusy, collectPredicates, fullCtx, depth, treatEOFAsEpsilon)
+ }
+ continue
+ }
+ returnState := p.atn.states[config.GetContext().getReturnState(i)]
+ newContext := config.GetContext().GetParent(i) // "pop" return state
+
+ c := NewATNConfig5(returnState, config.GetAlt(), newContext, config.GetSemanticContext())
+ // While we have context to pop back from, we may have
+ // gotten that context AFTER having falling off a rule.
+ // Make sure we track that we are now out of context.
+ c.SetReachesIntoOuterContext(config.GetReachesIntoOuterContext())
+ p.closureCheckingStopState(c, configs, closureBusy, collectPredicates, fullCtx, depth-1, treatEOFAsEpsilon)
+ }
+ return
+ } else if fullCtx {
+ // reached end of start rule
+ configs.Add(config, p.mergeCache)
+ return
+ } else {
+ // else if we have no context info, just chase follow links (if greedy)
+ if runtimeConfig.parserATNSimulatorDebug {
+ fmt.Println("FALLING off rule " + p.getRuleName(config.GetState().GetRuleIndex()))
+ }
+ }
+ }
+ p.closureWork(config, configs, closureBusy, collectPredicates, fullCtx, depth, treatEOFAsEpsilon)
+}
+
+// Do the actual work of walking epsilon edges
+//
+//goland:noinspection GoBoolExpressions
+func (p *ParserATNSimulator) closureWork(config *ATNConfig, configs *ATNConfigSet, closureBusy *ClosureBusy, collectPredicates, fullCtx bool, depth int, treatEOFAsEpsilon bool) {
+ state := config.GetState()
+ // optimization
+ if !state.GetEpsilonOnlyTransitions() {
+ configs.Add(config, p.mergeCache)
+ // make sure to not return here, because EOF transitions can act as
+ // both epsilon transitions and non-epsilon transitions.
+ }
+ for i := 0; i < len(state.GetTransitions()); i++ {
+ if i == 0 && p.canDropLoopEntryEdgeInLeftRecursiveRule(config) {
+ continue
+ }
+
+ t := state.GetTransitions()[i]
+ _, ok := t.(*ActionTransition)
+ continueCollecting := collectPredicates && !ok
+ c := p.getEpsilonTarget(config, t, continueCollecting, depth == 0, fullCtx, treatEOFAsEpsilon)
+ if c != nil {
+ newDepth := depth
+
+ if _, ok := config.GetState().(*RuleStopState); ok {
+ // target fell off end of rule mark resulting c as having dipped into outer context
+ // We can't get here if incoming config was rule stop and we had context
+ // track how far we dip into outer context. Might
+ // come in handy and we avoid evaluating context dependent
+ // preds if this is > 0.
+
+ if p.dfa != nil && p.dfa.getPrecedenceDfa() {
+ if t.(*EpsilonTransition).outermostPrecedenceReturn == p.dfa.atnStartState.GetRuleIndex() {
+ c.setPrecedenceFilterSuppressed(true)
+ }
+ }
+
+ c.SetReachesIntoOuterContext(c.GetReachesIntoOuterContext() + 1)
+
+ _, present := closureBusy.Put(c)
+ if present {
+ // avoid infinite recursion for right-recursive rules
+ continue
+ }
+
+ configs.dipsIntoOuterContext = true // TODO: can remove? only care when we add to set per middle of this method
+ newDepth--
+ if runtimeConfig.parserATNSimulatorDebug {
+ fmt.Println("dips into outer ctx: " + c.String())
+ }
+ } else {
+
+ if !t.getIsEpsilon() {
+ _, present := closureBusy.Put(c)
+ if present {
+ // avoid infinite recursion for EOF* and EOF+
+ continue
+ }
+ }
+ if _, ok := t.(*RuleTransition); ok {
+ // latch when newDepth goes negative - once we step out of the entry context we can't return
+ if newDepth >= 0 {
+ newDepth++
+ }
+ }
+ }
+ p.closureCheckingStopState(c, configs, closureBusy, continueCollecting, fullCtx, newDepth, treatEOFAsEpsilon)
+ }
+ }
+}
+
+//goland:noinspection GoBoolExpressions
+func (p *ParserATNSimulator) canDropLoopEntryEdgeInLeftRecursiveRule(config *ATNConfig) bool {
+ if !runtimeConfig.lRLoopEntryBranchOpt {
+ return false
+ }
+
+ _p := config.GetState()
+
+ // First check to see if we are in StarLoopEntryState generated during
+ // left-recursion elimination. For efficiency, also check if
+ // the context has an empty stack case. If so, it would mean
+ // global FOLLOW so we can't perform optimization
+ if _p.GetStateType() != ATNStateStarLoopEntry {
+ return false
+ }
+ startLoop, ok := _p.(*StarLoopEntryState)
+ if !ok {
+ return false
+ }
+ if !startLoop.precedenceRuleDecision ||
+ config.GetContext().isEmpty() ||
+ config.GetContext().hasEmptyPath() {
+ return false
+ }
+
+ // Require all return states to return back to the same rule
+ // that p is in.
+ numCtxs := config.GetContext().length()
+ for i := 0; i < numCtxs; i++ {
+ returnState := p.atn.states[config.GetContext().getReturnState(i)]
+ if returnState.GetRuleIndex() != _p.GetRuleIndex() {
+ return false
+ }
+ }
+ x := _p.GetTransitions()[0].getTarget()
+ decisionStartState := x.(BlockStartState)
+ blockEndStateNum := decisionStartState.getEndState().stateNumber
+ blockEndState := p.atn.states[blockEndStateNum].(*BlockEndState)
+
+ // Verify that the top of each stack context leads to loop entry/exit
+ // state through epsilon edges and w/o leaving rule.
+
+ for i := 0; i < numCtxs; i++ { // for each stack context
+ returnStateNumber := config.GetContext().getReturnState(i)
+ returnState := p.atn.states[returnStateNumber]
+
+ // all states must have single outgoing epsilon edge
+ if len(returnState.GetTransitions()) != 1 || !returnState.GetTransitions()[0].getIsEpsilon() {
+ return false
+ }
+
+ // Look for prefix op case like 'not expr', (' type ')' expr
+ returnStateTarget := returnState.GetTransitions()[0].getTarget()
+ if returnState.GetStateType() == ATNStateBlockEnd && returnStateTarget == _p {
+ continue
+ }
+
+ // Look for 'expr op expr' or case where expr's return state is block end
+ // of (...)* internal block; the block end points to loop back
+ // which points to p but we don't need to check that
+ if returnState == blockEndState {
+ continue
+ }
+
+ // Look for ternary expr ? expr : expr. The return state points at block end,
+ // which points at loop entry state
+ if returnStateTarget == blockEndState {
+ continue
+ }
+
+ // Look for complex prefix 'between expr and expr' case where 2nd expr's
+ // return state points at block end state of (...)* internal block
+ if returnStateTarget.GetStateType() == ATNStateBlockEnd &&
+ len(returnStateTarget.GetTransitions()) == 1 &&
+ returnStateTarget.GetTransitions()[0].getIsEpsilon() &&
+ returnStateTarget.GetTransitions()[0].getTarget() == _p {
+ continue
+ }
+
+ // anything else ain't conforming
+ return false
+ }
+
+ return true
+}
+
+func (p *ParserATNSimulator) getRuleName(index int) string {
+ if p.parser != nil && index >= 0 {
+ return p.parser.GetRuleNames()[index]
+ }
+ var sb strings.Builder
+ sb.Grow(32)
+
+ sb.WriteString("')
+ return sb.String()
+}
+
+func (p *ParserATNSimulator) getEpsilonTarget(config *ATNConfig, t Transition, collectPredicates, inContext, fullCtx, treatEOFAsEpsilon bool) *ATNConfig {
+
+ switch t.getSerializationType() {
+ case TransitionRULE:
+ return p.ruleTransition(config, t.(*RuleTransition))
+ case TransitionPRECEDENCE:
+ return p.precedenceTransition(config, t.(*PrecedencePredicateTransition), collectPredicates, inContext, fullCtx)
+ case TransitionPREDICATE:
+ return p.predTransition(config, t.(*PredicateTransition), collectPredicates, inContext, fullCtx)
+ case TransitionACTION:
+ return p.actionTransition(config, t.(*ActionTransition))
+ case TransitionEPSILON:
+ return NewATNConfig4(config, t.getTarget())
+ case TransitionATOM, TransitionRANGE, TransitionSET:
+ // EOF transitions act like epsilon transitions after the first EOF
+ // transition is traversed
+ if treatEOFAsEpsilon {
+ if t.Matches(TokenEOF, 0, 1) {
+ return NewATNConfig4(config, t.getTarget())
+ }
+ }
+ return nil
+ default:
+ return nil
+ }
+}
+
+//goland:noinspection GoBoolExpressions
+func (p *ParserATNSimulator) actionTransition(config *ATNConfig, t *ActionTransition) *ATNConfig {
+ if runtimeConfig.parserATNSimulatorDebug {
+ fmt.Println("ACTION edge " + strconv.Itoa(t.ruleIndex) + ":" + strconv.Itoa(t.actionIndex))
+ }
+ return NewATNConfig4(config, t.getTarget())
+}
+
+//goland:noinspection GoBoolExpressions
+func (p *ParserATNSimulator) precedenceTransition(config *ATNConfig,
+ pt *PrecedencePredicateTransition, collectPredicates, inContext, fullCtx bool) *ATNConfig {
+
+ if runtimeConfig.parserATNSimulatorDebug {
+ fmt.Println("PRED (collectPredicates=" + fmt.Sprint(collectPredicates) + ") " +
+ strconv.Itoa(pt.precedence) + ">=_p, ctx dependent=true")
+ if p.parser != nil {
+ fmt.Println("context surrounding pred is " + fmt.Sprint(p.parser.GetRuleInvocationStack(nil)))
+ }
+ }
+ var c *ATNConfig
+ if collectPredicates && inContext {
+ if fullCtx {
+ // In full context mode, we can evaluate predicates on-the-fly
+ // during closure, which dramatically reduces the size of
+ // the runtimeConfig sets. It also obviates the need to test predicates
+ // later during conflict resolution.
+ currentPosition := p.input.Index()
+ p.input.Seek(p.startIndex)
+ predSucceeds := pt.getPredicate().evaluate(p.parser, p.outerContext)
+ p.input.Seek(currentPosition)
+ if predSucceeds {
+ c = NewATNConfig4(config, pt.getTarget()) // no pred context
+ }
+ } else {
+ newSemCtx := SemanticContextandContext(config.GetSemanticContext(), pt.getPredicate())
+ c = NewATNConfig3(config, pt.getTarget(), newSemCtx)
+ }
+ } else {
+ c = NewATNConfig4(config, pt.getTarget())
+ }
+ if runtimeConfig.parserATNSimulatorDebug {
+ fmt.Println("runtimeConfig from pred transition=" + c.String())
+ }
+ return c
+}
+
+//goland:noinspection GoBoolExpressions
+func (p *ParserATNSimulator) predTransition(config *ATNConfig, pt *PredicateTransition, collectPredicates, inContext, fullCtx bool) *ATNConfig {
+
+ if runtimeConfig.parserATNSimulatorDebug {
+ fmt.Println("PRED (collectPredicates=" + fmt.Sprint(collectPredicates) + ") " + strconv.Itoa(pt.ruleIndex) +
+ ":" + strconv.Itoa(pt.predIndex) + ", ctx dependent=" + fmt.Sprint(pt.isCtxDependent))
+ if p.parser != nil {
+ fmt.Println("context surrounding pred is " + fmt.Sprint(p.parser.GetRuleInvocationStack(nil)))
+ }
+ }
+ var c *ATNConfig
+ if collectPredicates && (!pt.isCtxDependent || inContext) {
+ if fullCtx {
+ // In full context mode, we can evaluate predicates on-the-fly
+ // during closure, which dramatically reduces the size of
+ // the config sets. It also obviates the need to test predicates
+ // later during conflict resolution.
+ currentPosition := p.input.Index()
+ p.input.Seek(p.startIndex)
+ predSucceeds := pt.getPredicate().evaluate(p.parser, p.outerContext)
+ p.input.Seek(currentPosition)
+ if predSucceeds {
+ c = NewATNConfig4(config, pt.getTarget()) // no pred context
+ }
+ } else {
+ newSemCtx := SemanticContextandContext(config.GetSemanticContext(), pt.getPredicate())
+ c = NewATNConfig3(config, pt.getTarget(), newSemCtx)
+ }
+ } else {
+ c = NewATNConfig4(config, pt.getTarget())
+ }
+ if runtimeConfig.parserATNSimulatorDebug {
+ fmt.Println("config from pred transition=" + c.String())
+ }
+ return c
+}
+
+//goland:noinspection GoBoolExpressions
+func (p *ParserATNSimulator) ruleTransition(config *ATNConfig, t *RuleTransition) *ATNConfig {
+ if runtimeConfig.parserATNSimulatorDebug {
+ fmt.Println("CALL rule " + p.getRuleName(t.getTarget().GetRuleIndex()) + ", ctx=" + config.GetContext().String())
+ }
+ returnState := t.followState
+ newContext := SingletonBasePredictionContextCreate(config.GetContext(), returnState.GetStateNumber())
+ return NewATNConfig1(config, t.getTarget(), newContext)
+}
+
+func (p *ParserATNSimulator) getConflictingAlts(configs *ATNConfigSet) *BitSet {
+ altsets := PredictionModegetConflictingAltSubsets(configs)
+ return PredictionModeGetAlts(altsets)
+}
+
+// getConflictingAltsOrUniqueAlt Sam pointed out a problem with the previous definition, v3, of
+// ambiguous states. If we have another state associated with conflicting
+// alternatives, we should keep going. For example, the following grammar
+//
+// s : (ID | ID ID?) ;
+//
+// When the [ATN] simulation reaches the state before ;, it has a [DFA]
+// state that looks like:
+//
+// [12|1|[], 6|2|[], 12|2|[]].
+//
+// Naturally
+//
+// 12|1|[] and 12|2|[]
+//
+// conflict, but we cannot stop processing this node
+// because alternative to has another way to continue, via
+//
+// [6|2|[]].
+//
+// The key is that we have a single state that has config's only associated
+// with a single alternative, 2, and crucially the state transitions
+// among the configurations are all non-epsilon transitions. That means
+// we don't consider any conflicts that include alternative 2. So, we
+// ignore the conflict between alts 1 and 2. We ignore a set of
+// conflicting alts when there is an intersection with an alternative
+// associated with a single alt state in the state config-list map.
+//
+// It's also the case that we might have two conflicting configurations but
+// also a 3rd non-conflicting configuration for a different alternative:
+//
+// [1|1|[], 1|2|[], 8|3|[]].
+//
+// This can come about from grammar:
+//
+// a : A | A | A B
+//
+// After Matching input A, we reach the stop state for rule A, state 1.
+// State 8 is the state right before B. Clearly alternatives 1 and 2
+// conflict and no amount of further lookahead will separate the two.
+// However, alternative 3 will be able to continue, so we do not
+// stop working on this state.
+//
+// In the previous example, we're concerned
+// with states associated with the conflicting alternatives. Here alt
+// 3 is not associated with the conflicting configs, but since we can continue
+// looking for input reasonably, I don't declare the state done. We
+// ignore a set of conflicting alts when we have an alternative
+// that we still need to pursue.
+func (p *ParserATNSimulator) getConflictingAltsOrUniqueAlt(configs *ATNConfigSet) *BitSet {
+ var conflictingAlts *BitSet
+ if configs.uniqueAlt != ATNInvalidAltNumber {
+ conflictingAlts = NewBitSet()
+ conflictingAlts.add(configs.uniqueAlt)
+ } else {
+ conflictingAlts = configs.conflictingAlts
+ }
+ return conflictingAlts
+}
+
+func (p *ParserATNSimulator) GetTokenName(t int) string {
+ if t == TokenEOF {
+ return "EOF"
+ }
+
+ if p.parser != nil && p.parser.GetLiteralNames() != nil && t < len(p.parser.GetLiteralNames()) {
+ return p.parser.GetLiteralNames()[t] + "<" + strconv.Itoa(t) + ">"
+ }
+
+ if p.parser != nil && p.parser.GetLiteralNames() != nil && t < len(p.parser.GetSymbolicNames()) {
+ return p.parser.GetSymbolicNames()[t] + "<" + strconv.Itoa(t) + ">"
+ }
+
+ return strconv.Itoa(t)
+}
+
+func (p *ParserATNSimulator) getLookaheadName(input TokenStream) string {
+ return p.GetTokenName(input.LA(1))
+}
+
+// Used for debugging in [AdaptivePredict] around [execATN], but I cut
+// it out for clarity now that alg. works well. We can leave this
+// "dead" code for a bit.
+func (p *ParserATNSimulator) dumpDeadEndConfigs(_ *NoViableAltException) {
+
+ panic("Not implemented")
+
+ // fmt.Println("dead end configs: ")
+ // var decs = nvae.deadEndConfigs
+ //
+ // for i:=0; i0) {
+ // var t = c.state.GetTransitions()[0]
+ // if t2, ok := t.(*AtomTransition); ok {
+ // trans = "Atom "+ p.GetTokenName(t2.label)
+ // } else if t3, ok := t.(SetTransition); ok {
+ // _, ok := t.(*NotSetTransition)
+ //
+ // var s string
+ // if (ok){
+ // s = "~"
+ // }
+ //
+ // trans = s + "Set " + t3.set
+ // }
+ // }
+ // fmt.Errorf(c.String(p.parser, true) + ":" + trans)
+ // }
+}
+
+func (p *ParserATNSimulator) noViableAlt(input TokenStream, outerContext ParserRuleContext, configs *ATNConfigSet, startIndex int) *NoViableAltException {
+ return NewNoViableAltException(p.parser, input, input.Get(startIndex), input.LT(1), configs, outerContext)
+}
+
+func (p *ParserATNSimulator) getUniqueAlt(configs *ATNConfigSet) int {
+ alt := ATNInvalidAltNumber
+ for _, c := range configs.configs {
+ if alt == ATNInvalidAltNumber {
+ alt = c.GetAlt() // found first alt
+ } else if c.GetAlt() != alt {
+ return ATNInvalidAltNumber
+ }
+ }
+ return alt
+}
+
+// Add an edge to the DFA, if possible. This method calls
+// {@link //addDFAState} to ensure the {@code to} state is present in the
+// DFA. If {@code from} is {@code nil}, or if {@code t} is outside the
+// range of edges that can be represented in the DFA tables, p method
+// returns without adding the edge to the DFA.
+//
+//
If {@code to} is {@code nil}, p method returns {@code nil}.
+// Otherwise, p method returns the {@link DFAState} returned by calling
+// {@link //addDFAState} for the {@code to} state.
+//
+// @param dfa The DFA
+// @param from The source state for the edge
+// @param t The input symbol
+// @param to The target state for the edge
+//
+// @return If {@code to} is {@code nil}, p method returns {@code nil}
+// otherwise p method returns the result of calling {@link //addDFAState}
+// on {@code to}
+//
+//goland:noinspection GoBoolExpressions
+func (p *ParserATNSimulator) addDFAEdge(dfa *DFA, from *DFAState, t int, to *DFAState) *DFAState {
+ if runtimeConfig.parserATNSimulatorDebug {
+ fmt.Println("EDGE " + from.String() + " -> " + to.String() + " upon " + p.GetTokenName(t))
+ }
+ if to == nil {
+ return nil
+ }
+ p.atn.stateMu.Lock()
+ to = p.addDFAState(dfa, to) // used existing if possible not incoming
+ p.atn.stateMu.Unlock()
+ if from == nil || t < -1 || t > p.atn.maxTokenType {
+ return to
+ }
+ p.atn.edgeMu.Lock()
+ if from.getEdges() == nil {
+ from.setEdges(make([]*DFAState, p.atn.maxTokenType+1+1))
+ }
+ from.setIthEdge(t+1, to) // connect
+ p.atn.edgeMu.Unlock()
+
+ if runtimeConfig.parserATNSimulatorDebug {
+ var names []string
+ if p.parser != nil {
+ names = p.parser.GetLiteralNames()
+ }
+
+ fmt.Println("DFA=\n" + dfa.String(names, nil))
+ }
+ return to
+}
+
+// addDFAState adds state D to the [DFA] if it is not already present, and returns
+// the actual instance stored in the [DFA]. If a state equivalent to D
+// is already in the [DFA], the existing state is returned. Otherwise, this
+// method returns D after adding it to the [DFA].
+//
+// If D is [ATNSimulatorError], this method returns [ATNSimulatorError] and
+// does not change the DFA.
+//
+//goland:noinspection GoBoolExpressions
+func (p *ParserATNSimulator) addDFAState(dfa *DFA, d *DFAState) *DFAState {
+ if d == ATNSimulatorError {
+ return d
+ }
+
+ existing, present := dfa.Get(d)
+ if present {
+ if runtimeConfig.parserATNSimulatorTraceATNSim {
+ fmt.Print("addDFAState " + d.String() + " exists")
+ }
+ return existing
+ }
+
+ // The state will be added if not already there or we will be given back the existing state struct
+ // if it is present.
+ //
+ d.stateNumber = dfa.Len()
+ if !d.configs.readOnly {
+ d.configs.OptimizeConfigs(&p.BaseATNSimulator)
+ d.configs.readOnly = true
+ d.configs.configLookup = nil
+ }
+ dfa.Put(d)
+
+ if runtimeConfig.parserATNSimulatorTraceATNSim {
+ fmt.Println("addDFAState new " + d.String())
+ }
+
+ return d
+}
+
+//goland:noinspection GoBoolExpressions
+func (p *ParserATNSimulator) ReportAttemptingFullContext(dfa *DFA, conflictingAlts *BitSet, configs *ATNConfigSet, startIndex, stopIndex int) {
+ if runtimeConfig.parserATNSimulatorDebug || runtimeConfig.parserATNSimulatorRetryDebug {
+ interval := NewInterval(startIndex, stopIndex+1)
+ fmt.Println("ReportAttemptingFullContext decision=" + strconv.Itoa(dfa.decision) + ":" + configs.String() +
+ ", input=" + p.parser.GetTokenStream().GetTextFromInterval(interval))
+ }
+ if p.parser != nil {
+ p.parser.GetErrorListenerDispatch().ReportAttemptingFullContext(p.parser, dfa, startIndex, stopIndex, conflictingAlts, configs)
+ }
+}
+
+//goland:noinspection GoBoolExpressions
+func (p *ParserATNSimulator) ReportContextSensitivity(dfa *DFA, prediction int, configs *ATNConfigSet, startIndex, stopIndex int) {
+ if runtimeConfig.parserATNSimulatorDebug || runtimeConfig.parserATNSimulatorRetryDebug {
+ interval := NewInterval(startIndex, stopIndex+1)
+ fmt.Println("ReportContextSensitivity decision=" + strconv.Itoa(dfa.decision) + ":" + configs.String() +
+ ", input=" + p.parser.GetTokenStream().GetTextFromInterval(interval))
+ }
+ if p.parser != nil {
+ p.parser.GetErrorListenerDispatch().ReportContextSensitivity(p.parser, dfa, startIndex, stopIndex, prediction, configs)
+ }
+}
+
+// ReportAmbiguity reports and ambiguity in the parse, which shows that the parser will explore a different route.
+//
+// If context-sensitive parsing, we know it's an ambiguity not a conflict or error, but we can report it to the developer
+// so that they can see that this is happening and can take action if they want to.
+//
+//goland:noinspection GoBoolExpressions
+func (p *ParserATNSimulator) ReportAmbiguity(dfa *DFA, _ *DFAState, startIndex, stopIndex int,
+ exact bool, ambigAlts *BitSet, configs *ATNConfigSet) {
+ if runtimeConfig.parserATNSimulatorDebug || runtimeConfig.parserATNSimulatorRetryDebug {
+ interval := NewInterval(startIndex, stopIndex+1)
+ fmt.Println("ReportAmbiguity " + ambigAlts.String() + ":" + configs.String() +
+ ", input=" + p.parser.GetTokenStream().GetTextFromInterval(interval))
+ }
+ if p.parser != nil {
+ p.parser.GetErrorListenerDispatch().ReportAmbiguity(p.parser, dfa, startIndex, stopIndex, exact, ambigAlts, configs)
+ }
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/parser_rule_context.go b/vendor/github.com/antlr4-go/antlr/v4/parser_rule_context.go
new file mode 100644
index 000000000000..c249bc1385c9
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/parser_rule_context.go
@@ -0,0 +1,421 @@
+// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
+// Use of this file is governed by the BSD 3-clause license that
+// can be found in the LICENSE.txt file in the project root.
+
+package antlr
+
+import (
+ "reflect"
+ "strconv"
+)
+
+type ParserRuleContext interface {
+ RuleContext
+
+ SetException(RecognitionException)
+
+ AddTokenNode(token Token) *TerminalNodeImpl
+ AddErrorNode(badToken Token) *ErrorNodeImpl
+
+ EnterRule(listener ParseTreeListener)
+ ExitRule(listener ParseTreeListener)
+
+ SetStart(Token)
+ GetStart() Token
+
+ SetStop(Token)
+ GetStop() Token
+
+ AddChild(child RuleContext) RuleContext
+ RemoveLastChild()
+}
+
+type BaseParserRuleContext struct {
+ parentCtx RuleContext
+ invokingState int
+ RuleIndex int
+
+ start, stop Token
+ exception RecognitionException
+ children []Tree
+}
+
+func NewBaseParserRuleContext(parent ParserRuleContext, invokingStateNumber int) *BaseParserRuleContext {
+ prc := new(BaseParserRuleContext)
+ InitBaseParserRuleContext(prc, parent, invokingStateNumber)
+ return prc
+}
+
+func InitBaseParserRuleContext(prc *BaseParserRuleContext, parent ParserRuleContext, invokingStateNumber int) {
+ // What context invoked b rule?
+ prc.parentCtx = parent
+
+ // What state invoked the rule associated with b context?
+ // The "return address" is the followState of invokingState
+ // If parent is nil, b should be -1.
+ if parent == nil {
+ prc.invokingState = -1
+ } else {
+ prc.invokingState = invokingStateNumber
+ }
+
+ prc.RuleIndex = -1
+ // * If we are debugging or building a parse tree for a Visitor,
+ // we need to track all of the tokens and rule invocations associated
+ // with prc rule's context. This is empty for parsing w/o tree constr.
+ // operation because we don't the need to track the details about
+ // how we parse prc rule.
+ // /
+ prc.children = nil
+ prc.start = nil
+ prc.stop = nil
+ // The exception that forced prc rule to return. If the rule successfully
+ // completed, prc is {@code nil}.
+ prc.exception = nil
+}
+
+func (prc *BaseParserRuleContext) SetException(e RecognitionException) {
+ prc.exception = e
+}
+
+func (prc *BaseParserRuleContext) GetChildren() []Tree {
+ return prc.children
+}
+
+func (prc *BaseParserRuleContext) CopyFrom(ctx *BaseParserRuleContext) {
+ // from RuleContext
+ prc.parentCtx = ctx.parentCtx
+ prc.invokingState = ctx.invokingState
+ prc.children = nil
+ prc.start = ctx.start
+ prc.stop = ctx.stop
+}
+
+func (prc *BaseParserRuleContext) GetText() string {
+ if prc.GetChildCount() == 0 {
+ return ""
+ }
+
+ var s string
+ for _, child := range prc.children {
+ s += child.(ParseTree).GetText()
+ }
+
+ return s
+}
+
+// EnterRule is called when any rule is entered.
+func (prc *BaseParserRuleContext) EnterRule(_ ParseTreeListener) {
+}
+
+// ExitRule is called when any rule is exited.
+func (prc *BaseParserRuleContext) ExitRule(_ ParseTreeListener) {
+}
+
+// * Does not set parent link other add methods do that
+func (prc *BaseParserRuleContext) addTerminalNodeChild(child TerminalNode) TerminalNode {
+ if prc.children == nil {
+ prc.children = make([]Tree, 0)
+ }
+ if child == nil {
+ panic("Child may not be null")
+ }
+ prc.children = append(prc.children, child)
+ return child
+}
+
+func (prc *BaseParserRuleContext) AddChild(child RuleContext) RuleContext {
+ if prc.children == nil {
+ prc.children = make([]Tree, 0)
+ }
+ if child == nil {
+ panic("Child may not be null")
+ }
+ prc.children = append(prc.children, child)
+ return child
+}
+
+// RemoveLastChild is used by [EnterOuterAlt] to toss out a [RuleContext] previously added as
+// we entered a rule. If we have a label, we will need to remove
+// the generic ruleContext object.
+func (prc *BaseParserRuleContext) RemoveLastChild() {
+ if prc.children != nil && len(prc.children) > 0 {
+ prc.children = prc.children[0 : len(prc.children)-1]
+ }
+}
+
+func (prc *BaseParserRuleContext) AddTokenNode(token Token) *TerminalNodeImpl {
+
+ node := NewTerminalNodeImpl(token)
+ prc.addTerminalNodeChild(node)
+ node.parentCtx = prc
+ return node
+
+}
+
+func (prc *BaseParserRuleContext) AddErrorNode(badToken Token) *ErrorNodeImpl {
+ node := NewErrorNodeImpl(badToken)
+ prc.addTerminalNodeChild(node)
+ node.parentCtx = prc
+ return node
+}
+
+func (prc *BaseParserRuleContext) GetChild(i int) Tree {
+ if prc.children != nil && len(prc.children) >= i {
+ return prc.children[i]
+ }
+
+ return nil
+}
+
+func (prc *BaseParserRuleContext) GetChildOfType(i int, childType reflect.Type) RuleContext {
+ if childType == nil {
+ return prc.GetChild(i).(RuleContext)
+ }
+
+ for j := 0; j < len(prc.children); j++ {
+ child := prc.children[j]
+ if reflect.TypeOf(child) == childType {
+ if i == 0 {
+ return child.(RuleContext)
+ }
+
+ i--
+ }
+ }
+
+ return nil
+}
+
+func (prc *BaseParserRuleContext) ToStringTree(ruleNames []string, recog Recognizer) string {
+ return TreesStringTree(prc, ruleNames, recog)
+}
+
+func (prc *BaseParserRuleContext) GetRuleContext() RuleContext {
+ return prc
+}
+
+func (prc *BaseParserRuleContext) Accept(visitor ParseTreeVisitor) interface{} {
+ return visitor.VisitChildren(prc)
+}
+
+func (prc *BaseParserRuleContext) SetStart(t Token) {
+ prc.start = t
+}
+
+func (prc *BaseParserRuleContext) GetStart() Token {
+ return prc.start
+}
+
+func (prc *BaseParserRuleContext) SetStop(t Token) {
+ prc.stop = t
+}
+
+func (prc *BaseParserRuleContext) GetStop() Token {
+ return prc.stop
+}
+
+func (prc *BaseParserRuleContext) GetToken(ttype int, i int) TerminalNode {
+
+ for j := 0; j < len(prc.children); j++ {
+ child := prc.children[j]
+ if c2, ok := child.(TerminalNode); ok {
+ if c2.GetSymbol().GetTokenType() == ttype {
+ if i == 0 {
+ return c2
+ }
+
+ i--
+ }
+ }
+ }
+ return nil
+}
+
+func (prc *BaseParserRuleContext) GetTokens(ttype int) []TerminalNode {
+ if prc.children == nil {
+ return make([]TerminalNode, 0)
+ }
+
+ tokens := make([]TerminalNode, 0)
+
+ for j := 0; j < len(prc.children); j++ {
+ child := prc.children[j]
+ if tchild, ok := child.(TerminalNode); ok {
+ if tchild.GetSymbol().GetTokenType() == ttype {
+ tokens = append(tokens, tchild)
+ }
+ }
+ }
+
+ return tokens
+}
+
+func (prc *BaseParserRuleContext) GetPayload() interface{} {
+ return prc
+}
+
+func (prc *BaseParserRuleContext) getChild(ctxType reflect.Type, i int) RuleContext {
+ if prc.children == nil || i < 0 || i >= len(prc.children) {
+ return nil
+ }
+
+ j := -1 // what element have we found with ctxType?
+ for _, o := range prc.children {
+
+ childType := reflect.TypeOf(o)
+
+ if childType.Implements(ctxType) {
+ j++
+ if j == i {
+ return o.(RuleContext)
+ }
+ }
+ }
+ return nil
+}
+
+// Go lacks generics, so it's not possible for us to return the child with the correct type, but we do
+// check for convertibility
+
+func (prc *BaseParserRuleContext) GetTypedRuleContext(ctxType reflect.Type, i int) RuleContext {
+ return prc.getChild(ctxType, i)
+}
+
+func (prc *BaseParserRuleContext) GetTypedRuleContexts(ctxType reflect.Type) []RuleContext {
+ if prc.children == nil {
+ return make([]RuleContext, 0)
+ }
+
+ contexts := make([]RuleContext, 0)
+
+ for _, child := range prc.children {
+ childType := reflect.TypeOf(child)
+
+ if childType.ConvertibleTo(ctxType) {
+ contexts = append(contexts, child.(RuleContext))
+ }
+ }
+ return contexts
+}
+
+func (prc *BaseParserRuleContext) GetChildCount() int {
+ if prc.children == nil {
+ return 0
+ }
+
+ return len(prc.children)
+}
+
+func (prc *BaseParserRuleContext) GetSourceInterval() Interval {
+ if prc.start == nil || prc.stop == nil {
+ return TreeInvalidInterval
+ }
+
+ return NewInterval(prc.start.GetTokenIndex(), prc.stop.GetTokenIndex())
+}
+
+//need to manage circular dependencies, so export now
+
+// Print out a whole tree, not just a node, in LISP format
+// (root child1 .. childN). Print just a node if b is a leaf.
+//
+
+func (prc *BaseParserRuleContext) String(ruleNames []string, stop RuleContext) string {
+
+ var p ParserRuleContext = prc
+ s := "["
+ for p != nil && p != stop {
+ if ruleNames == nil {
+ if !p.IsEmpty() {
+ s += strconv.Itoa(p.GetInvokingState())
+ }
+ } else {
+ ri := p.GetRuleIndex()
+ var ruleName string
+ if ri >= 0 && ri < len(ruleNames) {
+ ruleName = ruleNames[ri]
+ } else {
+ ruleName = strconv.Itoa(ri)
+ }
+ s += ruleName
+ }
+ if p.GetParent() != nil && (ruleNames != nil || !p.GetParent().(ParserRuleContext).IsEmpty()) {
+ s += " "
+ }
+ pi := p.GetParent()
+ if pi != nil {
+ p = pi.(ParserRuleContext)
+ } else {
+ p = nil
+ }
+ }
+ s += "]"
+ return s
+}
+
+func (prc *BaseParserRuleContext) SetParent(v Tree) {
+ if v == nil {
+ prc.parentCtx = nil
+ } else {
+ prc.parentCtx = v.(RuleContext)
+ }
+}
+
+func (prc *BaseParserRuleContext) GetInvokingState() int {
+ return prc.invokingState
+}
+
+func (prc *BaseParserRuleContext) SetInvokingState(t int) {
+ prc.invokingState = t
+}
+
+func (prc *BaseParserRuleContext) GetRuleIndex() int {
+ return prc.RuleIndex
+}
+
+func (prc *BaseParserRuleContext) GetAltNumber() int {
+ return ATNInvalidAltNumber
+}
+
+func (prc *BaseParserRuleContext) SetAltNumber(_ int) {}
+
+// IsEmpty returns true if the context of b is empty.
+//
+// A context is empty if there is no invoking state, meaning nobody calls
+// current context.
+func (prc *BaseParserRuleContext) IsEmpty() bool {
+ return prc.invokingState == -1
+}
+
+// GetParent returns the combined text of all child nodes. This method only considers
+// tokens which have been added to the parse tree.
+//
+// Since tokens on hidden channels (e.g. whitespace or comments) are not
+// added to the parse trees, they will not appear in the output of this
+// method.
+func (prc *BaseParserRuleContext) GetParent() Tree {
+ return prc.parentCtx
+}
+
+var ParserRuleContextEmpty = NewBaseParserRuleContext(nil, -1)
+
+type InterpreterRuleContext interface {
+ ParserRuleContext
+}
+
+type BaseInterpreterRuleContext struct {
+ *BaseParserRuleContext
+}
+
+//goland:noinspection GoUnusedExportedFunction
+func NewBaseInterpreterRuleContext(parent BaseInterpreterRuleContext, invokingStateNumber, ruleIndex int) *BaseInterpreterRuleContext {
+
+ prc := new(BaseInterpreterRuleContext)
+
+ prc.BaseParserRuleContext = NewBaseParserRuleContext(parent, invokingStateNumber)
+
+ prc.RuleIndex = ruleIndex
+
+ return prc
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/prediction_context.go b/vendor/github.com/antlr4-go/antlr/v4/prediction_context.go
new file mode 100644
index 000000000000..c1b80cc1f0fd
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/prediction_context.go
@@ -0,0 +1,727 @@
+// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
+// Use of this file is governed by the BSD 3-clause license that
+// can be found in the LICENSE.txt file in the project root.
+
+package antlr
+
+import (
+ "fmt"
+ "golang.org/x/exp/slices"
+ "strconv"
+)
+
+var _emptyPredictionContextHash int
+
+func init() {
+ _emptyPredictionContextHash = murmurInit(1)
+ _emptyPredictionContextHash = murmurFinish(_emptyPredictionContextHash, 0)
+}
+
+func calculateEmptyHash() int {
+ return _emptyPredictionContextHash
+}
+
+const (
+ // BasePredictionContextEmptyReturnState represents {@code $} in an array in full context mode, $
+ // doesn't mean wildcard:
+ //
+ // $ + x = [$,x]
+ //
+ // Here,
+ //
+ // $ = EmptyReturnState
+ BasePredictionContextEmptyReturnState = 0x7FFFFFFF
+)
+
+// TODO: JI These are meant to be atomics - this does not seem to match the Java runtime here
+//
+//goland:noinspection GoUnusedGlobalVariable
+var (
+ BasePredictionContextglobalNodeCount = 1
+ BasePredictionContextid = BasePredictionContextglobalNodeCount
+)
+
+const (
+ PredictionContextEmpty = iota
+ PredictionContextSingleton
+ PredictionContextArray
+)
+
+// PredictionContext is a go idiomatic implementation of PredictionContext that does not rty to
+// emulate inheritance from Java, and can be used without an interface definition. An interface
+// is not required because no user code will ever need to implement this interface.
+type PredictionContext struct {
+ cachedHash int
+ pcType int
+ parentCtx *PredictionContext
+ returnState int
+ parents []*PredictionContext
+ returnStates []int
+}
+
+func NewEmptyPredictionContext() *PredictionContext {
+ nep := &PredictionContext{}
+ nep.cachedHash = calculateEmptyHash()
+ nep.pcType = PredictionContextEmpty
+ nep.returnState = BasePredictionContextEmptyReturnState
+ return nep
+}
+
+func NewBaseSingletonPredictionContext(parent *PredictionContext, returnState int) *PredictionContext {
+ pc := &PredictionContext{}
+ pc.pcType = PredictionContextSingleton
+ pc.returnState = returnState
+ pc.parentCtx = parent
+ if parent != nil {
+ pc.cachedHash = calculateHash(parent, returnState)
+ } else {
+ pc.cachedHash = calculateEmptyHash()
+ }
+ return pc
+}
+
+func SingletonBasePredictionContextCreate(parent *PredictionContext, returnState int) *PredictionContext {
+ if returnState == BasePredictionContextEmptyReturnState && parent == nil {
+ // someone can pass in the bits of an array ctx that mean $
+ return BasePredictionContextEMPTY
+ }
+ return NewBaseSingletonPredictionContext(parent, returnState)
+}
+
+func NewArrayPredictionContext(parents []*PredictionContext, returnStates []int) *PredictionContext {
+ // Parent can be nil only if full ctx mode and we make an array
+ // from {@link //EMPTY} and non-empty. We merge {@link //EMPTY} by using
+ // nil parent and
+ // returnState == {@link //EmptyReturnState}.
+ hash := murmurInit(1)
+ for _, parent := range parents {
+ hash = murmurUpdate(hash, parent.Hash())
+ }
+ for _, returnState := range returnStates {
+ hash = murmurUpdate(hash, returnState)
+ }
+ hash = murmurFinish(hash, len(parents)<<1)
+
+ nec := &PredictionContext{}
+ nec.cachedHash = hash
+ nec.pcType = PredictionContextArray
+ nec.parents = parents
+ nec.returnStates = returnStates
+ return nec
+}
+
+func (p *PredictionContext) Hash() int {
+ return p.cachedHash
+}
+
+func (p *PredictionContext) Equals(other Collectable[*PredictionContext]) bool {
+ switch p.pcType {
+ case PredictionContextEmpty:
+ otherP := other.(*PredictionContext)
+ return other == nil || otherP == nil || otherP.isEmpty()
+ case PredictionContextSingleton:
+ return p.SingletonEquals(other)
+ case PredictionContextArray:
+ return p.ArrayEquals(other)
+ }
+ return false
+}
+
+func (p *PredictionContext) ArrayEquals(o Collectable[*PredictionContext]) bool {
+ if o == nil {
+ return false
+ }
+ other := o.(*PredictionContext)
+ if other == nil || other.pcType != PredictionContextArray {
+ return false
+ }
+ if p.cachedHash != other.Hash() {
+ return false // can't be same if hash is different
+ }
+
+ // Must compare the actual array elements and not just the array address
+ //
+ return slices.Equal(p.returnStates, other.returnStates) &&
+ slices.EqualFunc(p.parents, other.parents, func(x, y *PredictionContext) bool {
+ return x.Equals(y)
+ })
+}
+
+func (p *PredictionContext) SingletonEquals(other Collectable[*PredictionContext]) bool {
+ if other == nil {
+ return false
+ }
+ otherP := other.(*PredictionContext)
+ if otherP == nil {
+ return false
+ }
+
+ if p.cachedHash != otherP.Hash() {
+ return false // Can't be same if hash is different
+ }
+
+ if p.returnState != otherP.getReturnState(0) {
+ return false
+ }
+
+ // Both parents must be nil if one is
+ if p.parentCtx == nil {
+ return otherP.parentCtx == nil
+ }
+
+ return p.parentCtx.Equals(otherP.parentCtx)
+}
+
+func (p *PredictionContext) GetParent(i int) *PredictionContext {
+ switch p.pcType {
+ case PredictionContextEmpty:
+ return nil
+ case PredictionContextSingleton:
+ return p.parentCtx
+ case PredictionContextArray:
+ return p.parents[i]
+ }
+ return nil
+}
+
+func (p *PredictionContext) getReturnState(i int) int {
+ switch p.pcType {
+ case PredictionContextArray:
+ return p.returnStates[i]
+ default:
+ return p.returnState
+ }
+}
+
+func (p *PredictionContext) GetReturnStates() []int {
+ switch p.pcType {
+ case PredictionContextArray:
+ return p.returnStates
+ default:
+ return []int{p.returnState}
+ }
+}
+
+func (p *PredictionContext) length() int {
+ switch p.pcType {
+ case PredictionContextArray:
+ return len(p.returnStates)
+ default:
+ return 1
+ }
+}
+
+func (p *PredictionContext) hasEmptyPath() bool {
+ switch p.pcType {
+ case PredictionContextSingleton:
+ return p.returnState == BasePredictionContextEmptyReturnState
+ }
+ return p.getReturnState(p.length()-1) == BasePredictionContextEmptyReturnState
+}
+
+func (p *PredictionContext) String() string {
+ switch p.pcType {
+ case PredictionContextEmpty:
+ return "$"
+ case PredictionContextSingleton:
+ var up string
+
+ if p.parentCtx == nil {
+ up = ""
+ } else {
+ up = p.parentCtx.String()
+ }
+
+ if len(up) == 0 {
+ if p.returnState == BasePredictionContextEmptyReturnState {
+ return "$"
+ }
+
+ return strconv.Itoa(p.returnState)
+ }
+
+ return strconv.Itoa(p.returnState) + " " + up
+ case PredictionContextArray:
+ if p.isEmpty() {
+ return "[]"
+ }
+
+ s := "["
+ for i := 0; i < len(p.returnStates); i++ {
+ if i > 0 {
+ s = s + ", "
+ }
+ if p.returnStates[i] == BasePredictionContextEmptyReturnState {
+ s = s + "$"
+ continue
+ }
+ s = s + strconv.Itoa(p.returnStates[i])
+ if !p.parents[i].isEmpty() {
+ s = s + " " + p.parents[i].String()
+ } else {
+ s = s + "nil"
+ }
+ }
+ return s + "]"
+
+ default:
+ return "unknown"
+ }
+}
+
+func (p *PredictionContext) isEmpty() bool {
+ switch p.pcType {
+ case PredictionContextEmpty:
+ return true
+ case PredictionContextArray:
+ // since EmptyReturnState can only appear in the last position, we
+ // don't need to verify that size==1
+ return p.returnStates[0] == BasePredictionContextEmptyReturnState
+ default:
+ return false
+ }
+}
+
+func (p *PredictionContext) Type() int {
+ return p.pcType
+}
+
+func calculateHash(parent *PredictionContext, returnState int) int {
+ h := murmurInit(1)
+ h = murmurUpdate(h, parent.Hash())
+ h = murmurUpdate(h, returnState)
+ return murmurFinish(h, 2)
+}
+
+// Convert a {@link RuleContext} tree to a {@link BasePredictionContext} graph.
+// Return {@link //EMPTY} if {@code outerContext} is empty or nil.
+// /
+func predictionContextFromRuleContext(a *ATN, outerContext RuleContext) *PredictionContext {
+ if outerContext == nil {
+ outerContext = ParserRuleContextEmpty
+ }
+ // if we are in RuleContext of start rule, s, then BasePredictionContext
+ // is EMPTY. Nobody called us. (if we are empty, return empty)
+ if outerContext.GetParent() == nil || outerContext == ParserRuleContextEmpty {
+ return BasePredictionContextEMPTY
+ }
+ // If we have a parent, convert it to a BasePredictionContext graph
+ parent := predictionContextFromRuleContext(a, outerContext.GetParent().(RuleContext))
+ state := a.states[outerContext.GetInvokingState()]
+ transition := state.GetTransitions()[0]
+
+ return SingletonBasePredictionContextCreate(parent, transition.(*RuleTransition).followState.GetStateNumber())
+}
+
+func merge(a, b *PredictionContext, rootIsWildcard bool, mergeCache *JPCMap) *PredictionContext {
+
+ // Share same graph if both same
+ //
+ if a == b || a.Equals(b) {
+ return a
+ }
+
+ if a.pcType == PredictionContextSingleton && b.pcType == PredictionContextSingleton {
+ return mergeSingletons(a, b, rootIsWildcard, mergeCache)
+ }
+ // At least one of a or b is array
+ // If one is $ and rootIsWildcard, return $ as wildcard
+ if rootIsWildcard {
+ if a.isEmpty() {
+ return a
+ }
+ if b.isEmpty() {
+ return b
+ }
+ }
+
+ // Convert either Singleton or Empty to arrays, so that we can merge them
+ //
+ ara := convertToArray(a)
+ arb := convertToArray(b)
+ return mergeArrays(ara, arb, rootIsWildcard, mergeCache)
+}
+
+func convertToArray(pc *PredictionContext) *PredictionContext {
+ switch pc.Type() {
+ case PredictionContextEmpty:
+ return NewArrayPredictionContext([]*PredictionContext{}, []int{})
+ case PredictionContextSingleton:
+ return NewArrayPredictionContext([]*PredictionContext{pc.GetParent(0)}, []int{pc.getReturnState(0)})
+ default:
+ // Already an array
+ }
+ return pc
+}
+
+// mergeSingletons merges two Singleton [PredictionContext] instances.
+//
+// Stack tops equal, parents merge is same return left graph.
+//
+//
+//
Same stack top, parents differ merge parents giving array node, then
+// remainders of those graphs. A new root node is created to point to the
+// merged parents.
+//
+//
+//
Different stack tops pointing to same parent. Make array node for the
+// root where both element in the root point to the same (original)
+// parent.
+//
+//
+//
Different stack tops pointing to different parents. Make array node for
+// the root where each element points to the corresponding original
+// parent.
+//
+//
+// @param a the first {@link SingletonBasePredictionContext}
+// @param b the second {@link SingletonBasePredictionContext}
+// @param rootIsWildcard {@code true} if this is a local-context merge,
+// otherwise false to indicate a full-context merge
+// @param mergeCache
+// /
+func mergeSingletons(a, b *PredictionContext, rootIsWildcard bool, mergeCache *JPCMap) *PredictionContext {
+ if mergeCache != nil {
+ previous, present := mergeCache.Get(a, b)
+ if present {
+ return previous
+ }
+ previous, present = mergeCache.Get(b, a)
+ if present {
+ return previous
+ }
+ }
+
+ rootMerge := mergeRoot(a, b, rootIsWildcard)
+ if rootMerge != nil {
+ if mergeCache != nil {
+ mergeCache.Put(a, b, rootMerge)
+ }
+ return rootMerge
+ }
+ if a.returnState == b.returnState {
+ parent := merge(a.parentCtx, b.parentCtx, rootIsWildcard, mergeCache)
+ // if parent is same as existing a or b parent or reduced to a parent,
+ // return it
+ if parent.Equals(a.parentCtx) {
+ return a // ax + bx = ax, if a=b
+ }
+ if parent.Equals(b.parentCtx) {
+ return b // ax + bx = bx, if a=b
+ }
+ // else: ax + ay = a'[x,y]
+ // merge parents x and y, giving array node with x,y then remainders
+ // of those graphs. dup a, a' points at merged array.
+ // New joined parent so create a new singleton pointing to it, a'
+ spc := SingletonBasePredictionContextCreate(parent, a.returnState)
+ if mergeCache != nil {
+ mergeCache.Put(a, b, spc)
+ }
+ return spc
+ }
+ // a != b payloads differ
+ // see if we can collapse parents due to $+x parents if local ctx
+ var singleParent *PredictionContext
+ if a.Equals(b) || (a.parentCtx != nil && a.parentCtx.Equals(b.parentCtx)) { // ax +
+ // bx =
+ // [a,b]x
+ singleParent = a.parentCtx
+ }
+ if singleParent != nil { // parents are same
+ // sort payloads and use same parent
+ payloads := []int{a.returnState, b.returnState}
+ if a.returnState > b.returnState {
+ payloads[0] = b.returnState
+ payloads[1] = a.returnState
+ }
+ parents := []*PredictionContext{singleParent, singleParent}
+ apc := NewArrayPredictionContext(parents, payloads)
+ if mergeCache != nil {
+ mergeCache.Put(a, b, apc)
+ }
+ return apc
+ }
+ // parents differ and can't merge them. Just pack together
+ // into array can't merge.
+ // ax + by = [ax,by]
+ payloads := []int{a.returnState, b.returnState}
+ parents := []*PredictionContext{a.parentCtx, b.parentCtx}
+ if a.returnState > b.returnState { // sort by payload
+ payloads[0] = b.returnState
+ payloads[1] = a.returnState
+ parents = []*PredictionContext{b.parentCtx, a.parentCtx}
+ }
+ apc := NewArrayPredictionContext(parents, payloads)
+ if mergeCache != nil {
+ mergeCache.Put(a, b, apc)
+ }
+ return apc
+}
+
+// Handle case where at least one of {@code a} or {@code b} is
+// {@link //EMPTY}. In the following diagrams, the symbol {@code $} is used
+// to represent {@link //EMPTY}.
+//
+//
Local-Context Merges
+//
+//
These local-context merge operations are used when {@code rootIsWildcard}
+// is true.
+//
+//
{@link //EMPTY} is superset of any graph return {@link //EMPTY}.
+//
+//
+//
{@link //EMPTY} and anything is {@code //EMPTY}, so merged parent is
+// {@code //EMPTY} return left graph.
+//
+//
+//
Special case of last merge if local context.
+//
+//
+//
Full-Context Merges
+//
+//
These full-context merge operations are used when {@code rootIsWildcard}
+// is false.
+//
+//
+//
+//
Must keep all contexts {@link //EMPTY} in array is a special value (and
+// nil parent).
+//
+//
+//
+//
+// @param a the first {@link SingletonBasePredictionContext}
+// @param b the second {@link SingletonBasePredictionContext}
+// @param rootIsWildcard {@code true} if this is a local-context merge,
+// otherwise false to indicate a full-context merge
+// /
+func mergeRoot(a, b *PredictionContext, rootIsWildcard bool) *PredictionContext {
+ if rootIsWildcard {
+ if a.pcType == PredictionContextEmpty {
+ return BasePredictionContextEMPTY // // + b =//
+ }
+ if b.pcType == PredictionContextEmpty {
+ return BasePredictionContextEMPTY // a +// =//
+ }
+ } else {
+ if a.isEmpty() && b.isEmpty() {
+ return BasePredictionContextEMPTY // $ + $ = $
+ } else if a.isEmpty() { // $ + x = [$,x]
+ payloads := []int{b.getReturnState(-1), BasePredictionContextEmptyReturnState}
+ parents := []*PredictionContext{b.GetParent(-1), nil}
+ return NewArrayPredictionContext(parents, payloads)
+ } else if b.isEmpty() { // x + $ = [$,x] ($ is always first if present)
+ payloads := []int{a.getReturnState(-1), BasePredictionContextEmptyReturnState}
+ parents := []*PredictionContext{a.GetParent(-1), nil}
+ return NewArrayPredictionContext(parents, payloads)
+ }
+ }
+ return nil
+}
+
+// Merge two {@link ArrayBasePredictionContext} instances.
+//
+//
Different tops, different parents.
+//
+//
+//
Shared top, same parents.
+//
+//
+//
Shared top, different parents.
+//
+//
+//
Shared top, all shared parents.
+//
+//
+//
Equal tops, merge parents and reduce top to
+// {@link SingletonBasePredictionContext}.
+//
+//
+//goland:noinspection GoBoolExpressions
+func mergeArrays(a, b *PredictionContext, rootIsWildcard bool, mergeCache *JPCMap) *PredictionContext {
+ if mergeCache != nil {
+ previous, present := mergeCache.Get(a, b)
+ if present {
+ if runtimeConfig.parserATNSimulatorTraceATNSim {
+ fmt.Println("mergeArrays a=" + a.String() + ",b=" + b.String() + " -> previous")
+ }
+ return previous
+ }
+ previous, present = mergeCache.Get(b, a)
+ if present {
+ if runtimeConfig.parserATNSimulatorTraceATNSim {
+ fmt.Println("mergeArrays a=" + a.String() + ",b=" + b.String() + " -> previous")
+ }
+ return previous
+ }
+ }
+ // merge sorted payloads a + b => M
+ i := 0 // walks a
+ j := 0 // walks b
+ k := 0 // walks target M array
+
+ mergedReturnStates := make([]int, len(a.returnStates)+len(b.returnStates))
+ mergedParents := make([]*PredictionContext, len(a.returnStates)+len(b.returnStates))
+ // walk and merge to yield mergedParents, mergedReturnStates
+ for i < len(a.returnStates) && j < len(b.returnStates) {
+ aParent := a.parents[i]
+ bParent := b.parents[j]
+ if a.returnStates[i] == b.returnStates[j] {
+ // same payload (stack tops are equal), must yield merged singleton
+ payload := a.returnStates[i]
+ // $+$ = $
+ bothDollars := payload == BasePredictionContextEmptyReturnState && aParent == nil && bParent == nil
+ axAX := aParent != nil && bParent != nil && aParent.Equals(bParent) // ax+ax
+ // ->
+ // ax
+ if bothDollars || axAX {
+ mergedParents[k] = aParent // choose left
+ mergedReturnStates[k] = payload
+ } else { // ax+ay -> a'[x,y]
+ mergedParent := merge(aParent, bParent, rootIsWildcard, mergeCache)
+ mergedParents[k] = mergedParent
+ mergedReturnStates[k] = payload
+ }
+ i++ // hop over left one as usual
+ j++ // but also Skip one in right side since we merge
+ } else if a.returnStates[i] < b.returnStates[j] { // copy a[i] to M
+ mergedParents[k] = aParent
+ mergedReturnStates[k] = a.returnStates[i]
+ i++
+ } else { // b > a, copy b[j] to M
+ mergedParents[k] = bParent
+ mergedReturnStates[k] = b.returnStates[j]
+ j++
+ }
+ k++
+ }
+ // copy over any payloads remaining in either array
+ if i < len(a.returnStates) {
+ for p := i; p < len(a.returnStates); p++ {
+ mergedParents[k] = a.parents[p]
+ mergedReturnStates[k] = a.returnStates[p]
+ k++
+ }
+ } else {
+ for p := j; p < len(b.returnStates); p++ {
+ mergedParents[k] = b.parents[p]
+ mergedReturnStates[k] = b.returnStates[p]
+ k++
+ }
+ }
+ // trim merged if we combined a few that had same stack tops
+ if k < len(mergedParents) { // write index < last position trim
+ if k == 1 { // for just one merged element, return singleton top
+ pc := SingletonBasePredictionContextCreate(mergedParents[0], mergedReturnStates[0])
+ if mergeCache != nil {
+ mergeCache.Put(a, b, pc)
+ }
+ return pc
+ }
+ mergedParents = mergedParents[0:k]
+ mergedReturnStates = mergedReturnStates[0:k]
+ }
+
+ M := NewArrayPredictionContext(mergedParents, mergedReturnStates)
+
+ // if we created same array as a or b, return that instead
+ // TODO: JI track whether this is possible above during merge sort for speed and possibly avoid an allocation
+ if M.Equals(a) {
+ if mergeCache != nil {
+ mergeCache.Put(a, b, a)
+ }
+ if runtimeConfig.parserATNSimulatorTraceATNSim {
+ fmt.Println("mergeArrays a=" + a.String() + ",b=" + b.String() + " -> a")
+ }
+ return a
+ }
+ if M.Equals(b) {
+ if mergeCache != nil {
+ mergeCache.Put(a, b, b)
+ }
+ if runtimeConfig.parserATNSimulatorTraceATNSim {
+ fmt.Println("mergeArrays a=" + a.String() + ",b=" + b.String() + " -> b")
+ }
+ return b
+ }
+ combineCommonParents(&mergedParents)
+
+ if mergeCache != nil {
+ mergeCache.Put(a, b, M)
+ }
+ if runtimeConfig.parserATNSimulatorTraceATNSim {
+ fmt.Println("mergeArrays a=" + a.String() + ",b=" + b.String() + " -> " + M.String())
+ }
+ return M
+}
+
+// Make pass over all M parents and merge any Equals() ones.
+// Note that we pass a pointer to the slice as we want to modify it in place.
+//
+//goland:noinspection GoUnusedFunction
+func combineCommonParents(parents *[]*PredictionContext) {
+ uniqueParents := NewJStore[*PredictionContext, Comparator[*PredictionContext]](pContextEqInst, PredictionContextCollection, "combineCommonParents for PredictionContext")
+
+ for p := 0; p < len(*parents); p++ {
+ parent := (*parents)[p]
+ _, _ = uniqueParents.Put(parent)
+ }
+ for q := 0; q < len(*parents); q++ {
+ pc, _ := uniqueParents.Get((*parents)[q])
+ (*parents)[q] = pc
+ }
+}
+
+func getCachedBasePredictionContext(context *PredictionContext, contextCache *PredictionContextCache, visited *VisitRecord) *PredictionContext {
+ if context.isEmpty() {
+ return context
+ }
+ existing, present := visited.Get(context)
+ if present {
+ return existing
+ }
+
+ existing, present = contextCache.Get(context)
+ if present {
+ visited.Put(context, existing)
+ return existing
+ }
+ changed := false
+ parents := make([]*PredictionContext, context.length())
+ for i := 0; i < len(parents); i++ {
+ parent := getCachedBasePredictionContext(context.GetParent(i), contextCache, visited)
+ if changed || !parent.Equals(context.GetParent(i)) {
+ if !changed {
+ parents = make([]*PredictionContext, context.length())
+ for j := 0; j < context.length(); j++ {
+ parents[j] = context.GetParent(j)
+ }
+ changed = true
+ }
+ parents[i] = parent
+ }
+ }
+ if !changed {
+ contextCache.add(context)
+ visited.Put(context, context)
+ return context
+ }
+ var updated *PredictionContext
+ if len(parents) == 0 {
+ updated = BasePredictionContextEMPTY
+ } else if len(parents) == 1 {
+ updated = SingletonBasePredictionContextCreate(parents[0], context.getReturnState(0))
+ } else {
+ updated = NewArrayPredictionContext(parents, context.GetReturnStates())
+ }
+ contextCache.add(updated)
+ visited.Put(updated, updated)
+ visited.Put(context, updated)
+
+ return updated
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/prediction_context_cache.go b/vendor/github.com/antlr4-go/antlr/v4/prediction_context_cache.go
new file mode 100644
index 000000000000..25dfb11e8ffb
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/prediction_context_cache.go
@@ -0,0 +1,48 @@
+package antlr
+
+var BasePredictionContextEMPTY = &PredictionContext{
+ cachedHash: calculateEmptyHash(),
+ pcType: PredictionContextEmpty,
+ returnState: BasePredictionContextEmptyReturnState,
+}
+
+// PredictionContextCache is Used to cache [PredictionContext] objects. It is used for the shared
+// context cash associated with contexts in DFA states. This cache
+// can be used for both lexers and parsers.
+type PredictionContextCache struct {
+ cache *JMap[*PredictionContext, *PredictionContext, Comparator[*PredictionContext]]
+}
+
+func NewPredictionContextCache() *PredictionContextCache {
+ return &PredictionContextCache{
+ cache: NewJMap[*PredictionContext, *PredictionContext, Comparator[*PredictionContext]](pContextEqInst, PredictionContextCacheCollection, "NewPredictionContextCache()"),
+ }
+}
+
+// Add a context to the cache and return it. If the context already exists,
+// return that one instead and do not add a new context to the cache.
+// Protect shared cache from unsafe thread access.
+func (p *PredictionContextCache) add(ctx *PredictionContext) *PredictionContext {
+ if ctx.isEmpty() {
+ return BasePredictionContextEMPTY
+ }
+
+ // Put will return the existing entry if it is present (note this is done via Equals, not whether it is
+ // the same pointer), otherwise it will add the new entry and return that.
+ //
+ existing, present := p.cache.Get(ctx)
+ if present {
+ return existing
+ }
+ p.cache.Put(ctx, ctx)
+ return ctx
+}
+
+func (p *PredictionContextCache) Get(ctx *PredictionContext) (*PredictionContext, bool) {
+ pc, exists := p.cache.Get(ctx)
+ return pc, exists
+}
+
+func (p *PredictionContextCache) length() int {
+ return p.cache.Len()
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/prediction_mode.go b/vendor/github.com/antlr4-go/antlr/v4/prediction_mode.go
new file mode 100644
index 000000000000..3f85a6a520b2
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/prediction_mode.go
@@ -0,0 +1,536 @@
+// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
+// Use of this file is governed by the BSD 3-clause license that
+// can be found in the LICENSE.txt file in the project root.
+
+package antlr
+
+// This enumeration defines the prediction modes available in ANTLR 4 along with
+// utility methods for analyzing configuration sets for conflicts and/or
+// ambiguities.
+
+const (
+ // PredictionModeSLL represents the SLL(*) prediction mode.
+ // This prediction mode ignores the current
+ // parser context when making predictions. This is the fastest prediction
+ // mode, and provides correct results for many grammars. This prediction
+ // mode is more powerful than the prediction mode provided by ANTLR 3, but
+ // may result in syntax errors for grammar and input combinations which are
+ // not SLL.
+ //
+ // When using this prediction mode, the parser will either return a correct
+ // parse tree (i.e. the same parse tree that would be returned with the
+ // [PredictionModeLL] prediction mode), or it will Report a syntax error. If a
+ // syntax error is encountered when using the SLL prediction mode,
+ // it may be due to either an actual syntax error in the input or indicate
+ // that the particular combination of grammar and input requires the more
+ // powerful LL prediction abilities to complete successfully.
+ //
+ // This prediction mode does not provide any guarantees for prediction
+ // behavior for syntactically-incorrect inputs.
+ //
+ PredictionModeSLL = 0
+
+ // PredictionModeLL represents the LL(*) prediction mode.
+ // This prediction mode allows the current parser
+ // context to be used for resolving SLL conflicts that occur during
+ // prediction. This is the fastest prediction mode that guarantees correct
+ // parse results for all combinations of grammars with syntactically correct
+ // inputs.
+ //
+ // When using this prediction mode, the parser will make correct decisions
+ // for all syntactically-correct grammar and input combinations. However, in
+ // cases where the grammar is truly ambiguous this prediction mode might not
+ // report a precise answer for exactly which alternatives are
+ // ambiguous.
+ //
+ // This prediction mode does not provide any guarantees for prediction
+ // behavior for syntactically-incorrect inputs.
+ //
+ PredictionModeLL = 1
+
+ // PredictionModeLLExactAmbigDetection represents the LL(*) prediction mode
+ // with exact ambiguity detection.
+ //
+ // In addition to the correctness guarantees provided by the [PredictionModeLL] prediction mode,
+ // this prediction mode instructs the prediction algorithm to determine the
+ // complete and exact set of ambiguous alternatives for every ambiguous
+ // decision encountered while parsing.
+ //
+ // This prediction mode may be used for diagnosing ambiguities during
+ // grammar development. Due to the performance overhead of calculating sets
+ // of ambiguous alternatives, this prediction mode should be avoided when
+ // the exact results are not necessary.
+ //
+ // This prediction mode does not provide any guarantees for prediction
+ // behavior for syntactically-incorrect inputs.
+ //
+ PredictionModeLLExactAmbigDetection = 2
+)
+
+// PredictionModehasSLLConflictTerminatingPrediction computes the SLL prediction termination condition.
+//
+// This method computes the SLL prediction termination condition for both of
+// the following cases:
+//
+// - The usual SLL+LL fallback upon SLL conflict
+// - Pure SLL without LL fallback
+//
+// # Combined SLL+LL Parsing
+//
+// When LL-fallback is enabled upon SLL conflict, correct predictions are
+// ensured regardless of how the termination condition is computed by this
+// method. Due to the substantially higher cost of LL prediction, the
+// prediction should only fall back to LL when the additional lookahead
+// cannot lead to a unique SLL prediction.
+//
+// Assuming combined SLL+LL parsing, an SLL configuration set with only
+// conflicting subsets should fall back to full LL, even if the
+// configuration sets don't resolve to the same alternative, e.g.
+//
+// {1,2} and {3,4}
+//
+// If there is at least one non-conflicting
+// configuration, SLL could continue with the hopes that more lookahead will
+// resolve via one of those non-conflicting configurations.
+//
+// Here's the prediction termination rule them: SLL (for SLL+LL parsing)
+// stops when it sees only conflicting configuration subsets. In contrast,
+// full LL keeps going when there is uncertainty.
+//
+// # Heuristic
+//
+// As a heuristic, we stop prediction when we see any conflicting subset
+// unless we see a state that only has one alternative associated with it.
+// The single-alt-state thing lets prediction continue upon rules like
+// (otherwise, it would admit defeat too soon):
+//
+// [12|1|[], 6|2|[], 12|2|[]]. s : (ID | ID ID?) ;
+//
+// When the [ATN] simulation reaches the state before ';', it has a
+// [DFA] state that looks like:
+//
+// [12|1|[], 6|2|[], 12|2|[]]
+//
+// Naturally
+//
+// 12|1|[] and 12|2|[]
+//
+// conflict, but we cannot stop processing this node because alternative to has another way to continue,
+// via
+//
+// [6|2|[]]
+//
+// It also let's us continue for this rule:
+//
+// [1|1|[], 1|2|[], 8|3|[]] a : A | A | A B ;
+//
+// After Matching input A, we reach the stop state for rule A, state 1.
+// State 8 is the state immediately before B. Clearly alternatives 1 and 2
+// conflict and no amount of further lookahead will separate the two.
+// However, alternative 3 will be able to continue, and so we do not stop
+// working on this state. In the previous example, we're concerned with
+// states associated with the conflicting alternatives. Here alt 3 is not
+// associated with the conflicting configs, but since we can continue
+// looking for input reasonably, don't declare the state done.
+//
+// # Pure SLL Parsing
+//
+// To handle pure SLL parsing, all we have to do is make sure that we
+// combine stack contexts for configurations that differ only by semantic
+// predicate. From there, we can do the usual SLL termination heuristic.
+//
+// # Predicates in SLL+LL Parsing
+//
+// SLL decisions don't evaluate predicates until after they reach [DFA] stop
+// states because they need to create the [DFA] cache that works in all
+// semantic situations. In contrast, full LL evaluates predicates collected
+// during start state computation, so it can ignore predicates thereafter.
+// This means that SLL termination detection can totally ignore semantic
+// predicates.
+//
+// Implementation-wise, [ATNConfigSet] combines stack contexts but not
+// semantic predicate contexts, so we might see two configurations like the
+// following:
+//
+// (s, 1, x, {}), (s, 1, x', {p})
+//
+// Before testing these configurations against others, we have to merge
+// x and x' (without modifying the existing configurations).
+// For example, we test (x+x')==x” when looking for conflicts in
+// the following configurations:
+//
+// (s, 1, x, {}), (s, 1, x', {p}), (s, 2, x”, {})
+//
+// If the configuration set has predicates (as indicated by
+// [ATNConfigSet.hasSemanticContext]), this algorithm makes a copy of
+// the configurations to strip out all the predicates so that a standard
+// [ATNConfigSet] will merge everything ignoring predicates.
+func PredictionModehasSLLConflictTerminatingPrediction(mode int, configs *ATNConfigSet) bool {
+
+ // Configs in rule stop states indicate reaching the end of the decision
+ // rule (local context) or end of start rule (full context). If all
+ // configs meet this condition, then none of the configurations is able
+ // to Match additional input, so we terminate prediction.
+ //
+ if PredictionModeallConfigsInRuleStopStates(configs) {
+ return true
+ }
+
+ // pure SLL mode parsing
+ if mode == PredictionModeSLL {
+ // Don't bother with combining configs from different semantic
+ // contexts if we can fail over to full LL costs more time
+ // since we'll often fail over anyway.
+ if configs.hasSemanticContext {
+ // dup configs, tossing out semantic predicates
+ dup := NewATNConfigSet(false)
+ for _, c := range configs.configs {
+
+ // NewATNConfig({semanticContext:}, c)
+ c = NewATNConfig2(c, SemanticContextNone)
+ dup.Add(c, nil)
+ }
+ configs = dup
+ }
+ // now we have combined contexts for configs with dissimilar predicates
+ }
+ // pure SLL or combined SLL+LL mode parsing
+ altsets := PredictionModegetConflictingAltSubsets(configs)
+ return PredictionModehasConflictingAltSet(altsets) && !PredictionModehasStateAssociatedWithOneAlt(configs)
+}
+
+// PredictionModehasConfigInRuleStopState checks if any configuration in the given configs is in a
+// [RuleStopState]. Configurations meeting this condition have reached
+// the end of the decision rule (local context) or end of start rule (full
+// context).
+//
+// The func returns true if any configuration in the supplied configs is in a [RuleStopState]
+func PredictionModehasConfigInRuleStopState(configs *ATNConfigSet) bool {
+ for _, c := range configs.configs {
+ if _, ok := c.GetState().(*RuleStopState); ok {
+ return true
+ }
+ }
+ return false
+}
+
+// PredictionModeallConfigsInRuleStopStates checks if all configurations in configs are in a
+// [RuleStopState]. Configurations meeting this condition have reached
+// the end of the decision rule (local context) or end of start rule (full
+// context).
+//
+// the func returns true if all configurations in configs are in a
+// [RuleStopState]
+func PredictionModeallConfigsInRuleStopStates(configs *ATNConfigSet) bool {
+
+ for _, c := range configs.configs {
+ if _, ok := c.GetState().(*RuleStopState); !ok {
+ return false
+ }
+ }
+ return true
+}
+
+// PredictionModeresolvesToJustOneViableAlt checks full LL prediction termination.
+//
+// Can we stop looking ahead during [ATN] simulation or is there some
+// uncertainty as to which alternative we will ultimately pick, after
+// consuming more input? Even if there are partial conflicts, we might know
+// that everything is going to resolve to the same minimum alternative. That
+// means we can stop since no more lookahead will change that fact. On the
+// other hand, there might be multiple conflicts that resolve to different
+// minimums. That means we need more look ahead to decide which of those
+// alternatives we should predict.
+//
+// The basic idea is to split the set of configurations 'C', into
+// conflicting subsets (s, _, ctx, _) and singleton subsets with
+// non-conflicting configurations. Two configurations conflict if they have
+// identical [ATNConfig].state and [ATNConfig].context values
+// but a different [ATNConfig].alt value, e.g.
+//
+// (s, i, ctx, _)
+//
+// and
+//
+// (s, j, ctx, _) ; for i != j
+//
+// Reduce these configuration subsets to the set of possible alternatives.
+// You can compute the alternative subsets in one pass as follows:
+//
+// A_s,ctx = {i | (s, i, ctx, _)}
+//
+// for each configuration in C holding s and ctx fixed.
+//
+// Or in pseudo-code:
+//
+// for each configuration c in C:
+// map[c] U = c.ATNConfig.alt alt // map hash/equals uses s and x, not alt and not pred
+//
+// The values in map are the set of
+//
+// A_s,ctx
+//
+// sets.
+//
+// If
+//
+// |A_s,ctx| = 1
+//
+// then there is no conflict associated with s and ctx.
+//
+// Reduce the subsets to singletons by choosing a minimum of each subset. If
+// the union of these alternative subsets is a singleton, then no amount of
+// further lookahead will help us. We will always pick that alternative. If,
+// however, there is more than one alternative, then we are uncertain which
+// alternative to predict and must continue looking for resolution. We may
+// or may not discover an ambiguity in the future, even if there are no
+// conflicting subsets this round.
+//
+// The biggest sin is to terminate early because it means we've made a
+// decision but were uncertain as to the eventual outcome. We haven't used
+// enough lookahead. On the other hand, announcing a conflict too late is no
+// big deal; you will still have the conflict. It's just inefficient. It
+// might even look until the end of file.
+//
+// No special consideration for semantic predicates is required because
+// predicates are evaluated on-the-fly for full LL prediction, ensuring that
+// no configuration contains a semantic context during the termination
+// check.
+//
+// # Conflicting Configs
+//
+// Two configurations:
+//
+// (s, i, x) and (s, j, x')
+//
+// conflict when i != j but x = x'. Because we merge all
+// (s, i, _) configurations together, that means that there are at
+// most n configurations associated with state s for
+// n possible alternatives in the decision. The merged stacks
+// complicate the comparison of configuration contexts x and x'.
+//
+// Sam checks to see if one is a subset of the other by calling
+// merge and checking to see if the merged result is either x or x'.
+// If the x associated with lowest alternative i
+// is the superset, then i is the only possible prediction since the
+// others resolve to min(i) as well. However, if x is
+// associated with j > i then at least one stack configuration for
+// j is not in conflict with alternative i. The algorithm
+// should keep going, looking for more lookahead due to the uncertainty.
+//
+// For simplicity, I'm doing an equality check between x and
+// x', which lets the algorithm continue to consume lookahead longer
+// than necessary. The reason I like the equality is of course the
+// simplicity but also because that is the test you need to detect the
+// alternatives that are actually in conflict.
+//
+// # Continue/Stop Rule
+//
+// Continue if the union of resolved alternative sets from non-conflicting and
+// conflicting alternative subsets has more than one alternative. We are
+// uncertain about which alternative to predict.
+//
+// The complete set of alternatives,
+//
+// [i for (_, i, _)]
+//
+// tells us which alternatives are still in the running for the amount of input we've
+// consumed at this point. The conflicting sets let us to strip away
+// configurations that won't lead to more states because we resolve
+// conflicts to the configuration with a minimum alternate for the
+// conflicting set.
+//
+// Cases
+//
+// - no conflicts and more than 1 alternative in set => continue
+// - (s, 1, x), (s, 2, x), (s, 3, z), (s', 1, y), (s', 2, y) yields non-conflicting set
+// {3} ∪ conflicting sets min({1,2}) ∪ min({1,2}) = {1,3} => continue
+// - (s, 1, x), (s, 2, x), (s', 1, y), (s', 2, y), (s”, 1, z) yields non-conflicting set
+// {1} ∪ conflicting sets min({1,2}) ∪ min({1,2}) = {1} => stop and predict 1
+// - (s, 1, x), (s, 2, x), (s', 1, y), (s', 2, y) yields conflicting, reduced sets
+// {1} ∪ {1} = {1} => stop and predict 1, can announce ambiguity {1,2}
+// - (s, 1, x), (s, 2, x), (s', 2, y), (s', 3, y) yields conflicting, reduced sets
+// {1} ∪ {2} = {1,2} => continue
+// - (s, 1, x), (s, 2, x), (s', 2, y), (s', 3, y) yields conflicting, reduced sets
+// {1} ∪ {2} = {1,2} => continue
+// - (s, 1, x), (s, 2, x), (s', 3, y), (s', 4, y) yields conflicting, reduced sets
+// {1} ∪ {3} = {1,3} => continue
+//
+// # Exact Ambiguity Detection
+//
+// If all states report the same conflicting set of alternatives, then we
+// know we have the exact ambiguity set:
+//
+// |A_i| > 1
+//
+// and
+//
+// A_i = A_j ; for all i, j
+//
+// In other words, we continue examining lookahead until all A_i
+// have more than one alternative and all A_i are the same. If
+//
+// A={{1,2}, {1,3}}
+//
+// then regular LL prediction would terminate because the resolved set is {1}.
+// To determine what the real ambiguity is, we have to know whether the ambiguity is between one and
+// two or one and three so we keep going. We can only stop prediction when
+// we need exact ambiguity detection when the sets look like:
+//
+// A={{1,2}}
+//
+// or
+//
+// {{1,2},{1,2}}, etc...
+func PredictionModeresolvesToJustOneViableAlt(altsets []*BitSet) int {
+ return PredictionModegetSingleViableAlt(altsets)
+}
+
+// PredictionModeallSubsetsConflict determines if every alternative subset in altsets contains more
+// than one alternative.
+//
+// The func returns true if every [BitSet] in altsets has
+// [BitSet].cardinality cardinality > 1
+func PredictionModeallSubsetsConflict(altsets []*BitSet) bool {
+ return !PredictionModehasNonConflictingAltSet(altsets)
+}
+
+// PredictionModehasNonConflictingAltSet determines if any single alternative subset in altsets contains
+// exactly one alternative.
+//
+// The func returns true if altsets contains at least one [BitSet] with
+// [BitSet].cardinality cardinality 1
+func PredictionModehasNonConflictingAltSet(altsets []*BitSet) bool {
+ for i := 0; i < len(altsets); i++ {
+ alts := altsets[i]
+ if alts.length() == 1 {
+ return true
+ }
+ }
+ return false
+}
+
+// PredictionModehasConflictingAltSet determines if any single alternative subset in altsets contains
+// more than one alternative.
+//
+// The func returns true if altsets contains a [BitSet] with
+// [BitSet].cardinality cardinality > 1, otherwise false
+func PredictionModehasConflictingAltSet(altsets []*BitSet) bool {
+ for i := 0; i < len(altsets); i++ {
+ alts := altsets[i]
+ if alts.length() > 1 {
+ return true
+ }
+ }
+ return false
+}
+
+// PredictionModeallSubsetsEqual determines if every alternative subset in altsets is equivalent.
+//
+// The func returns true if every member of altsets is equal to the others.
+func PredictionModeallSubsetsEqual(altsets []*BitSet) bool {
+ var first *BitSet
+
+ for i := 0; i < len(altsets); i++ {
+ alts := altsets[i]
+ if first == nil {
+ first = alts
+ } else if alts != first {
+ return false
+ }
+ }
+
+ return true
+}
+
+// PredictionModegetUniqueAlt returns the unique alternative predicted by all alternative subsets in
+// altsets. If no such alternative exists, this method returns
+// [ATNInvalidAltNumber].
+//
+// @param altsets a collection of alternative subsets
+func PredictionModegetUniqueAlt(altsets []*BitSet) int {
+ all := PredictionModeGetAlts(altsets)
+ if all.length() == 1 {
+ return all.minValue()
+ }
+
+ return ATNInvalidAltNumber
+}
+
+// PredictionModeGetAlts returns the complete set of represented alternatives for a collection of
+// alternative subsets. This method returns the union of each [BitSet]
+// in altsets, being the set of represented alternatives in altsets.
+func PredictionModeGetAlts(altsets []*BitSet) *BitSet {
+ all := NewBitSet()
+ for _, alts := range altsets {
+ all.or(alts)
+ }
+ return all
+}
+
+// PredictionModegetConflictingAltSubsets gets the conflicting alt subsets from a configuration set.
+//
+// for each configuration c in configs:
+// map[c] U= c.ATNConfig.alt // map hash/equals uses s and x, not alt and not pred
+func PredictionModegetConflictingAltSubsets(configs *ATNConfigSet) []*BitSet {
+ configToAlts := NewJMap[*ATNConfig, *BitSet, *ATNAltConfigComparator[*ATNConfig]](atnAltCfgEqInst, AltSetCollection, "PredictionModegetConflictingAltSubsets()")
+
+ for _, c := range configs.configs {
+
+ alts, ok := configToAlts.Get(c)
+ if !ok {
+ alts = NewBitSet()
+ configToAlts.Put(c, alts)
+ }
+ alts.add(c.GetAlt())
+ }
+
+ return configToAlts.Values()
+}
+
+// PredictionModeGetStateToAltMap gets a map from state to alt subset from a configuration set.
+//
+// for each configuration c in configs:
+// map[c.ATNConfig.state] U= c.ATNConfig.alt}
+func PredictionModeGetStateToAltMap(configs *ATNConfigSet) *AltDict {
+ m := NewAltDict()
+
+ for _, c := range configs.configs {
+ alts := m.Get(c.GetState().String())
+ if alts == nil {
+ alts = NewBitSet()
+ m.put(c.GetState().String(), alts)
+ }
+ alts.(*BitSet).add(c.GetAlt())
+ }
+ return m
+}
+
+func PredictionModehasStateAssociatedWithOneAlt(configs *ATNConfigSet) bool {
+ values := PredictionModeGetStateToAltMap(configs).values()
+ for i := 0; i < len(values); i++ {
+ if values[i].(*BitSet).length() == 1 {
+ return true
+ }
+ }
+ return false
+}
+
+// PredictionModegetSingleViableAlt gets the single alternative predicted by all alternative subsets in altsets
+// if there is one.
+//
+// TODO: JI - Review this code - it does not seem to do the same thing as the Java code - maybe because [BitSet] is not like the Java utils BitSet
+func PredictionModegetSingleViableAlt(altsets []*BitSet) int {
+ result := ATNInvalidAltNumber
+
+ for i := 0; i < len(altsets); i++ {
+ alts := altsets[i]
+ minAlt := alts.minValue()
+ if result == ATNInvalidAltNumber {
+ result = minAlt
+ } else if result != minAlt { // more than 1 viable alt
+ return ATNInvalidAltNumber
+ }
+ }
+ return result
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/recognizer.go b/vendor/github.com/antlr4-go/antlr/v4/recognizer.go
new file mode 100644
index 000000000000..2e0b504fb3db
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/recognizer.go
@@ -0,0 +1,241 @@
+// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
+// Use of this file is governed by the BSD 3-clause license that
+// can be found in the LICENSE.txt file in the project root.
+
+package antlr
+
+import (
+ "fmt"
+ "strings"
+
+ "strconv"
+)
+
+type Recognizer interface {
+ GetLiteralNames() []string
+ GetSymbolicNames() []string
+ GetRuleNames() []string
+
+ Sempred(RuleContext, int, int) bool
+ Precpred(RuleContext, int) bool
+
+ GetState() int
+ SetState(int)
+ Action(RuleContext, int, int)
+ AddErrorListener(ErrorListener)
+ RemoveErrorListeners()
+ GetATN() *ATN
+ GetErrorListenerDispatch() ErrorListener
+ HasError() bool
+ GetError() RecognitionException
+ SetError(RecognitionException)
+}
+
+type BaseRecognizer struct {
+ listeners []ErrorListener
+ state int
+
+ RuleNames []string
+ LiteralNames []string
+ SymbolicNames []string
+ GrammarFileName string
+ SynErr RecognitionException
+}
+
+func NewBaseRecognizer() *BaseRecognizer {
+ rec := new(BaseRecognizer)
+ rec.listeners = []ErrorListener{ConsoleErrorListenerINSTANCE}
+ rec.state = -1
+ return rec
+}
+
+//goland:noinspection GoUnusedGlobalVariable
+var tokenTypeMapCache = make(map[string]int)
+
+//goland:noinspection GoUnusedGlobalVariable
+var ruleIndexMapCache = make(map[string]int)
+
+func (b *BaseRecognizer) checkVersion(toolVersion string) {
+ runtimeVersion := "4.12.0"
+ if runtimeVersion != toolVersion {
+ fmt.Println("ANTLR runtime and generated code versions disagree: " + runtimeVersion + "!=" + toolVersion)
+ }
+}
+
+func (b *BaseRecognizer) SetError(err RecognitionException) {
+ b.SynErr = err
+}
+
+func (b *BaseRecognizer) HasError() bool {
+ return b.SynErr != nil
+}
+
+func (b *BaseRecognizer) GetError() RecognitionException {
+ return b.SynErr
+}
+
+func (b *BaseRecognizer) Action(_ RuleContext, _, _ int) {
+ panic("action not implemented on Recognizer!")
+}
+
+func (b *BaseRecognizer) AddErrorListener(listener ErrorListener) {
+ b.listeners = append(b.listeners, listener)
+}
+
+func (b *BaseRecognizer) RemoveErrorListeners() {
+ b.listeners = make([]ErrorListener, 0)
+}
+
+func (b *BaseRecognizer) GetRuleNames() []string {
+ return b.RuleNames
+}
+
+func (b *BaseRecognizer) GetTokenNames() []string {
+ return b.LiteralNames
+}
+
+func (b *BaseRecognizer) GetSymbolicNames() []string {
+ return b.SymbolicNames
+}
+
+func (b *BaseRecognizer) GetLiteralNames() []string {
+ return b.LiteralNames
+}
+
+func (b *BaseRecognizer) GetState() int {
+ return b.state
+}
+
+func (b *BaseRecognizer) SetState(v int) {
+ b.state = v
+}
+
+//func (b *Recognizer) GetTokenTypeMap() {
+// var tokenNames = b.GetTokenNames()
+// if (tokenNames==nil) {
+// panic("The current recognizer does not provide a list of token names.")
+// }
+// var result = tokenTypeMapCache[tokenNames]
+// if(result==nil) {
+// result = tokenNames.reduce(function(o, k, i) { o[k] = i })
+// result.EOF = TokenEOF
+// tokenTypeMapCache[tokenNames] = result
+// }
+// return result
+//}
+
+// GetRuleIndexMap Get a map from rule names to rule indexes.
+//
+// Used for XPath and tree pattern compilation.
+//
+// TODO: JI This is not yet implemented in the Go runtime. Maybe not needed.
+func (b *BaseRecognizer) GetRuleIndexMap() map[string]int {
+
+ panic("Method not defined!")
+ // var ruleNames = b.GetRuleNames()
+ // if (ruleNames==nil) {
+ // panic("The current recognizer does not provide a list of rule names.")
+ // }
+ //
+ // var result = ruleIndexMapCache[ruleNames]
+ // if(result==nil) {
+ // result = ruleNames.reduce(function(o, k, i) { o[k] = i })
+ // ruleIndexMapCache[ruleNames] = result
+ // }
+ // return result
+}
+
+// GetTokenType get the token type based upon its name
+func (b *BaseRecognizer) GetTokenType(_ string) int {
+ panic("Method not defined!")
+ // var ttype = b.GetTokenTypeMap()[tokenName]
+ // if (ttype !=nil) {
+ // return ttype
+ // } else {
+ // return TokenInvalidType
+ // }
+}
+
+//func (b *Recognizer) GetTokenTypeMap() map[string]int {
+// Vocabulary vocabulary = getVocabulary()
+//
+// Synchronized (tokenTypeMapCache) {
+// Map result = tokenTypeMapCache.Get(vocabulary)
+// if (result == null) {
+// result = new HashMap()
+// for (int i = 0; i < GetATN().maxTokenType; i++) {
+// String literalName = vocabulary.getLiteralName(i)
+// if (literalName != null) {
+// result.put(literalName, i)
+// }
+//
+// String symbolicName = vocabulary.GetSymbolicName(i)
+// if (symbolicName != null) {
+// result.put(symbolicName, i)
+// }
+// }
+//
+// result.put("EOF", Token.EOF)
+// result = Collections.unmodifiableMap(result)
+// tokenTypeMapCache.put(vocabulary, result)
+// }
+//
+// return result
+// }
+//}
+
+// GetErrorHeader returns the error header, normally line/character position information.
+//
+// Can be overridden in sub structs embedding BaseRecognizer.
+func (b *BaseRecognizer) GetErrorHeader(e RecognitionException) string {
+ line := e.GetOffendingToken().GetLine()
+ column := e.GetOffendingToken().GetColumn()
+ return "line " + strconv.Itoa(line) + ":" + strconv.Itoa(column)
+}
+
+// GetTokenErrorDisplay shows how a token should be displayed in an error message.
+//
+// The default is to display just the text, but during development you might
+// want to have a lot of information spit out. Override in that case
+// to use t.String() (which, for CommonToken, dumps everything about
+// the token). This is better than forcing you to override a method in
+// your token objects because you don't have to go modify your lexer
+// so that it creates a NewJava type.
+//
+// Deprecated: This method is not called by the ANTLR 4 Runtime. Specific
+// implementations of [ANTLRErrorStrategy] may provide a similar
+// feature when necessary. For example, see [DefaultErrorStrategy].GetTokenErrorDisplay()
+func (b *BaseRecognizer) GetTokenErrorDisplay(t Token) string {
+ if t == nil {
+ return ""
+ }
+ s := t.GetText()
+ if s == "" {
+ if t.GetTokenType() == TokenEOF {
+ s = ""
+ } else {
+ s = "<" + strconv.Itoa(t.GetTokenType()) + ">"
+ }
+ }
+ s = strings.Replace(s, "\t", "\\t", -1)
+ s = strings.Replace(s, "\n", "\\n", -1)
+ s = strings.Replace(s, "\r", "\\r", -1)
+
+ return "'" + s + "'"
+}
+
+func (b *BaseRecognizer) GetErrorListenerDispatch() ErrorListener {
+ return NewProxyErrorListener(b.listeners)
+}
+
+// Sempred embedding structs need to override this if there are sempreds or actions
+// that the ATN interpreter needs to execute
+func (b *BaseRecognizer) Sempred(_ RuleContext, _ int, _ int) bool {
+ return true
+}
+
+// Precpred embedding structs need to override this if there are preceding predicates
+// that the ATN interpreter needs to execute
+func (b *BaseRecognizer) Precpred(_ RuleContext, _ int) bool {
+ return true
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/rule_context.go b/vendor/github.com/antlr4-go/antlr/v4/rule_context.go
new file mode 100644
index 000000000000..f2ad04793e1b
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/rule_context.go
@@ -0,0 +1,40 @@
+// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
+// Use of this file is governed by the BSD 3-clause license that
+// can be found in the LICENSE.txt file in the project root.
+
+package antlr
+
+// RuleContext is a record of a single rule invocation. It knows
+// which context invoked it, if any. If there is no parent context, then
+// naturally the invoking state is not valid. The parent link
+// provides a chain upwards from the current rule invocation to the root
+// of the invocation tree, forming a stack.
+//
+// We actually carry no information about the rule associated with this context (except
+// when parsing). We keep only the state number of the invoking state from
+// the [ATN] submachine that invoked this. Contrast this with the s
+// pointer inside [ParserRuleContext] that tracks the current state
+// being "executed" for the current rule.
+//
+// The parent contexts are useful for computing lookahead sets and
+// getting error information.
+//
+// These objects are used during parsing and prediction.
+// For the special case of parsers, we use the struct
+// [ParserRuleContext], which embeds a RuleContext.
+//
+// @see ParserRuleContext
+type RuleContext interface {
+ RuleNode
+
+ GetInvokingState() int
+ SetInvokingState(int)
+
+ GetRuleIndex() int
+ IsEmpty() bool
+
+ GetAltNumber() int
+ SetAltNumber(altNumber int)
+
+ String([]string, RuleContext) string
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/semantic_context.go b/vendor/github.com/antlr4-go/antlr/v4/semantic_context.go
new file mode 100644
index 000000000000..68cb9061eb64
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/semantic_context.go
@@ -0,0 +1,464 @@
+// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
+// Use of this file is governed by the BSD 3-clause license that
+// can be found in the LICENSE.txt file in the project root.
+
+package antlr
+
+import (
+ "fmt"
+ "strconv"
+)
+
+// SemanticContext is a tree structure used to record the semantic context in which
+//
+// an ATN configuration is valid. It's either a single predicate,
+// a conjunction p1 && p2, or a sum of products p1 || p2.
+//
+// I have scoped the AND, OR, and Predicate subclasses of
+// [SemanticContext] within the scope of this outer ``class''
+type SemanticContext interface {
+ Equals(other Collectable[SemanticContext]) bool
+ Hash() int
+
+ evaluate(parser Recognizer, outerContext RuleContext) bool
+ evalPrecedence(parser Recognizer, outerContext RuleContext) SemanticContext
+
+ String() string
+}
+
+func SemanticContextandContext(a, b SemanticContext) SemanticContext {
+ if a == nil || a == SemanticContextNone {
+ return b
+ }
+ if b == nil || b == SemanticContextNone {
+ return a
+ }
+ result := NewAND(a, b)
+ if len(result.opnds) == 1 {
+ return result.opnds[0]
+ }
+
+ return result
+}
+
+func SemanticContextorContext(a, b SemanticContext) SemanticContext {
+ if a == nil {
+ return b
+ }
+ if b == nil {
+ return a
+ }
+ if a == SemanticContextNone || b == SemanticContextNone {
+ return SemanticContextNone
+ }
+ result := NewOR(a, b)
+ if len(result.opnds) == 1 {
+ return result.opnds[0]
+ }
+
+ return result
+}
+
+type Predicate struct {
+ ruleIndex int
+ predIndex int
+ isCtxDependent bool
+}
+
+func NewPredicate(ruleIndex, predIndex int, isCtxDependent bool) *Predicate {
+ p := new(Predicate)
+
+ p.ruleIndex = ruleIndex
+ p.predIndex = predIndex
+ p.isCtxDependent = isCtxDependent // e.g., $i ref in pred
+ return p
+}
+
+//The default {@link SemanticContext}, which is semantically equivalent to
+//a predicate of the form {@code {true}?}.
+
+var SemanticContextNone = NewPredicate(-1, -1, false)
+
+func (p *Predicate) evalPrecedence(_ Recognizer, _ RuleContext) SemanticContext {
+ return p
+}
+
+func (p *Predicate) evaluate(parser Recognizer, outerContext RuleContext) bool {
+
+ var localctx RuleContext
+
+ if p.isCtxDependent {
+ localctx = outerContext
+ }
+
+ return parser.Sempred(localctx, p.ruleIndex, p.predIndex)
+}
+
+func (p *Predicate) Equals(other Collectable[SemanticContext]) bool {
+ if p == other {
+ return true
+ } else if _, ok := other.(*Predicate); !ok {
+ return false
+ } else {
+ return p.ruleIndex == other.(*Predicate).ruleIndex &&
+ p.predIndex == other.(*Predicate).predIndex &&
+ p.isCtxDependent == other.(*Predicate).isCtxDependent
+ }
+}
+
+func (p *Predicate) Hash() int {
+ h := murmurInit(0)
+ h = murmurUpdate(h, p.ruleIndex)
+ h = murmurUpdate(h, p.predIndex)
+ if p.isCtxDependent {
+ h = murmurUpdate(h, 1)
+ } else {
+ h = murmurUpdate(h, 0)
+ }
+ return murmurFinish(h, 3)
+}
+
+func (p *Predicate) String() string {
+ return "{" + strconv.Itoa(p.ruleIndex) + ":" + strconv.Itoa(p.predIndex) + "}?"
+}
+
+type PrecedencePredicate struct {
+ precedence int
+}
+
+func NewPrecedencePredicate(precedence int) *PrecedencePredicate {
+
+ p := new(PrecedencePredicate)
+ p.precedence = precedence
+
+ return p
+}
+
+func (p *PrecedencePredicate) evaluate(parser Recognizer, outerContext RuleContext) bool {
+ return parser.Precpred(outerContext, p.precedence)
+}
+
+func (p *PrecedencePredicate) evalPrecedence(parser Recognizer, outerContext RuleContext) SemanticContext {
+ if parser.Precpred(outerContext, p.precedence) {
+ return SemanticContextNone
+ }
+
+ return nil
+}
+
+func (p *PrecedencePredicate) compareTo(other *PrecedencePredicate) int {
+ return p.precedence - other.precedence
+}
+
+func (p *PrecedencePredicate) Equals(other Collectable[SemanticContext]) bool {
+
+ var op *PrecedencePredicate
+ var ok bool
+ if op, ok = other.(*PrecedencePredicate); !ok {
+ return false
+ }
+
+ if p == op {
+ return true
+ }
+
+ return p.precedence == other.(*PrecedencePredicate).precedence
+}
+
+func (p *PrecedencePredicate) Hash() int {
+ h := uint32(1)
+ h = 31*h + uint32(p.precedence)
+ return int(h)
+}
+
+func (p *PrecedencePredicate) String() string {
+ return "{" + strconv.Itoa(p.precedence) + ">=prec}?"
+}
+
+func PrecedencePredicatefilterPrecedencePredicates(set *JStore[SemanticContext, Comparator[SemanticContext]]) []*PrecedencePredicate {
+ result := make([]*PrecedencePredicate, 0)
+
+ set.Each(func(v SemanticContext) bool {
+ if c2, ok := v.(*PrecedencePredicate); ok {
+ result = append(result, c2)
+ }
+ return true
+ })
+
+ return result
+}
+
+// A semantic context which is true whenever none of the contained contexts
+// is false.`
+
+type AND struct {
+ opnds []SemanticContext
+}
+
+func NewAND(a, b SemanticContext) *AND {
+
+ operands := NewJStore[SemanticContext, Comparator[SemanticContext]](semctxEqInst, SemanticContextCollection, "NewAND() operands")
+ if aa, ok := a.(*AND); ok {
+ for _, o := range aa.opnds {
+ operands.Put(o)
+ }
+ } else {
+ operands.Put(a)
+ }
+
+ if ba, ok := b.(*AND); ok {
+ for _, o := range ba.opnds {
+ operands.Put(o)
+ }
+ } else {
+ operands.Put(b)
+ }
+ precedencePredicates := PrecedencePredicatefilterPrecedencePredicates(operands)
+ if len(precedencePredicates) > 0 {
+ // interested in the transition with the lowest precedence
+ var reduced *PrecedencePredicate
+
+ for _, p := range precedencePredicates {
+ if reduced == nil || p.precedence < reduced.precedence {
+ reduced = p
+ }
+ }
+
+ operands.Put(reduced)
+ }
+
+ vs := operands.Values()
+ opnds := make([]SemanticContext, len(vs))
+ copy(opnds, vs)
+
+ and := new(AND)
+ and.opnds = opnds
+
+ return and
+}
+
+func (a *AND) Equals(other Collectable[SemanticContext]) bool {
+ if a == other {
+ return true
+ }
+ if _, ok := other.(*AND); !ok {
+ return false
+ } else {
+ for i, v := range other.(*AND).opnds {
+ if !a.opnds[i].Equals(v) {
+ return false
+ }
+ }
+ return true
+ }
+}
+
+// {@inheritDoc}
+//
+//
+// The evaluation of predicates by a context is short-circuiting, but
+// unordered.
+func (a *AND) evaluate(parser Recognizer, outerContext RuleContext) bool {
+ for i := 0; i < len(a.opnds); i++ {
+ if !a.opnds[i].evaluate(parser, outerContext) {
+ return false
+ }
+ }
+ return true
+}
+
+func (a *AND) evalPrecedence(parser Recognizer, outerContext RuleContext) SemanticContext {
+ differs := false
+ operands := make([]SemanticContext, 0)
+
+ for i := 0; i < len(a.opnds); i++ {
+ context := a.opnds[i]
+ evaluated := context.evalPrecedence(parser, outerContext)
+ differs = differs || (evaluated != context)
+ if evaluated == nil {
+ // The AND context is false if any element is false
+ return nil
+ } else if evaluated != SemanticContextNone {
+ // Reduce the result by Skipping true elements
+ operands = append(operands, evaluated)
+ }
+ }
+ if !differs {
+ return a
+ }
+
+ if len(operands) == 0 {
+ // all elements were true, so the AND context is true
+ return SemanticContextNone
+ }
+
+ var result SemanticContext
+
+ for _, o := range operands {
+ if result == nil {
+ result = o
+ } else {
+ result = SemanticContextandContext(result, o)
+ }
+ }
+
+ return result
+}
+
+func (a *AND) Hash() int {
+ h := murmurInit(37) // Init with a value different from OR
+ for _, op := range a.opnds {
+ h = murmurUpdate(h, op.Hash())
+ }
+ return murmurFinish(h, len(a.opnds))
+}
+
+func (o *OR) Hash() int {
+ h := murmurInit(41) // Init with o value different from AND
+ for _, op := range o.opnds {
+ h = murmurUpdate(h, op.Hash())
+ }
+ return murmurFinish(h, len(o.opnds))
+}
+
+func (a *AND) String() string {
+ s := ""
+
+ for _, o := range a.opnds {
+ s += "&& " + fmt.Sprint(o)
+ }
+
+ if len(s) > 3 {
+ return s[0:3]
+ }
+
+ return s
+}
+
+//
+// A semantic context which is true whenever at least one of the contained
+// contexts is true.
+//
+
+type OR struct {
+ opnds []SemanticContext
+}
+
+func NewOR(a, b SemanticContext) *OR {
+
+ operands := NewJStore[SemanticContext, Comparator[SemanticContext]](semctxEqInst, SemanticContextCollection, "NewOR() operands")
+ if aa, ok := a.(*OR); ok {
+ for _, o := range aa.opnds {
+ operands.Put(o)
+ }
+ } else {
+ operands.Put(a)
+ }
+
+ if ba, ok := b.(*OR); ok {
+ for _, o := range ba.opnds {
+ operands.Put(o)
+ }
+ } else {
+ operands.Put(b)
+ }
+ precedencePredicates := PrecedencePredicatefilterPrecedencePredicates(operands)
+ if len(precedencePredicates) > 0 {
+ // interested in the transition with the lowest precedence
+ var reduced *PrecedencePredicate
+
+ for _, p := range precedencePredicates {
+ if reduced == nil || p.precedence > reduced.precedence {
+ reduced = p
+ }
+ }
+
+ operands.Put(reduced)
+ }
+
+ vs := operands.Values()
+
+ opnds := make([]SemanticContext, len(vs))
+ copy(opnds, vs)
+
+ o := new(OR)
+ o.opnds = opnds
+
+ return o
+}
+
+func (o *OR) Equals(other Collectable[SemanticContext]) bool {
+ if o == other {
+ return true
+ } else if _, ok := other.(*OR); !ok {
+ return false
+ } else {
+ for i, v := range other.(*OR).opnds {
+ if !o.opnds[i].Equals(v) {
+ return false
+ }
+ }
+ return true
+ }
+}
+
+//
+// The evaluation of predicates by o context is short-circuiting, but
+// unordered.
+func (o *OR) evaluate(parser Recognizer, outerContext RuleContext) bool {
+ for i := 0; i < len(o.opnds); i++ {
+ if o.opnds[i].evaluate(parser, outerContext) {
+ return true
+ }
+ }
+ return false
+}
+
+func (o *OR) evalPrecedence(parser Recognizer, outerContext RuleContext) SemanticContext {
+ differs := false
+ operands := make([]SemanticContext, 0)
+ for i := 0; i < len(o.opnds); i++ {
+ context := o.opnds[i]
+ evaluated := context.evalPrecedence(parser, outerContext)
+ differs = differs || (evaluated != context)
+ if evaluated == SemanticContextNone {
+ // The OR context is true if any element is true
+ return SemanticContextNone
+ } else if evaluated != nil {
+ // Reduce the result by Skipping false elements
+ operands = append(operands, evaluated)
+ }
+ }
+ if !differs {
+ return o
+ }
+ if len(operands) == 0 {
+ // all elements were false, so the OR context is false
+ return nil
+ }
+ var result SemanticContext
+
+ for _, o := range operands {
+ if result == nil {
+ result = o
+ } else {
+ result = SemanticContextorContext(result, o)
+ }
+ }
+
+ return result
+}
+
+func (o *OR) String() string {
+ s := ""
+
+ for _, o := range o.opnds {
+ s += "|| " + fmt.Sprint(o)
+ }
+
+ if len(s) > 3 {
+ return s[0:3]
+ }
+
+ return s
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/statistics.go b/vendor/github.com/antlr4-go/antlr/v4/statistics.go
new file mode 100644
index 000000000000..70c0673a0f6b
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/statistics.go
@@ -0,0 +1,281 @@
+//go:build antlr.stats
+
+package antlr
+
+import (
+ "fmt"
+ "log"
+ "os"
+ "path/filepath"
+ "sort"
+ "strconv"
+ "sync"
+)
+
+// This file allows the user to collect statistics about the runtime of the ANTLR runtime. It is not enabled by default
+// and so incurs no time penalty. To enable it, you must build the runtime with the antlr.stats build tag.
+//
+
+// Tells various components to collect statistics - because it is only true when this file is included, it will
+// allow the compiler to completely eliminate all the code that is only used when collecting statistics.
+const collectStats = true
+
+// goRunStats is a collection of all the various data the ANTLR runtime has collected about a particular run.
+// It is exported so that it can be used by others to look for things that are not already looked for in the
+// runtime statistics.
+type goRunStats struct {
+
+ // jStats is a slice of all the [JStatRec] records that have been created, which is one for EVERY collection created
+ // during a run. It is exported so that it can be used by others to look for things that are not already looked for
+ // within this package.
+ //
+ jStats []*JStatRec
+ jStatsLock sync.RWMutex
+ topN int
+ topNByMax []*JStatRec
+ topNByUsed []*JStatRec
+ unusedCollections map[CollectionSource]int
+ counts map[CollectionSource]int
+}
+
+const (
+ collectionsFile = "collections"
+)
+
+var (
+ Statistics = &goRunStats{
+ topN: 10,
+ }
+)
+
+type statsOption func(*goRunStats) error
+
+// Configure allows the statistics system to be configured as the user wants and override the defaults
+func (s *goRunStats) Configure(options ...statsOption) error {
+ for _, option := range options {
+ err := option(s)
+ if err != nil {
+ return err
+ }
+ }
+ return nil
+}
+
+// WithTopN sets the number of things to list in the report when we are concerned with the top N things.
+//
+// For example, if you want to see the top 20 collections by size, you can do:
+//
+// antlr.Statistics.Configure(antlr.WithTopN(20))
+func WithTopN(topN int) statsOption {
+ return func(s *goRunStats) error {
+ s.topN = topN
+ return nil
+ }
+}
+
+// Analyze looks through all the statistical records and computes all the outputs that might be useful to the user.
+//
+// The function gathers and analyzes a number of statistics about any particular run of
+// an ANTLR generated recognizer. In the vast majority of cases, the statistics are only
+// useful to maintainers of ANTLR itself, but they can be useful to users as well. They may be
+// especially useful in tracking down bugs or performance problems when an ANTLR user could
+// supply the output from this package, but cannot supply the grammar file(s) they are using, even
+// privately to the maintainers.
+//
+// The statistics are gathered by the runtime itself, and are not gathered by the parser or lexer, but the user
+// must call this function their selves to analyze the statistics. This is because none of the infrastructure is
+// extant unless the calling program is built with the antlr.stats tag like so:
+//
+// go build -tags antlr.stats .
+//
+// When a program is built with the antlr.stats tag, the Statistics object is created and available outside
+// the package. The user can then call the [Statistics.Analyze] function to analyze the statistics and then call the
+// [Statistics.Report] function to report the statistics.
+//
+// Please forward any questions about this package to the ANTLR discussion groups on GitHub or send to them to
+// me [Jim Idle] directly at jimi@idle.ws
+//
+// [Jim Idle]: https:://github.com/jim-idle
+func (s *goRunStats) Analyze() {
+
+ // Look for anything that looks strange and record it in our local maps etc for the report to present it
+ //
+ s.CollectionAnomalies()
+ s.TopNCollections()
+}
+
+// TopNCollections looks through all the statistical records and gathers the top ten collections by size.
+func (s *goRunStats) TopNCollections() {
+
+ // Let's sort the stat records by MaxSize
+ //
+ sort.Slice(s.jStats, func(i, j int) bool {
+ return s.jStats[i].MaxSize > s.jStats[j].MaxSize
+ })
+
+ for i := 0; i < len(s.jStats) && i < s.topN; i++ {
+ s.topNByMax = append(s.topNByMax, s.jStats[i])
+ }
+
+ // Sort by the number of times used
+ //
+ sort.Slice(s.jStats, func(i, j int) bool {
+ return s.jStats[i].Gets+s.jStats[i].Puts > s.jStats[j].Gets+s.jStats[j].Puts
+ })
+ for i := 0; i < len(s.jStats) && i < s.topN; i++ {
+ s.topNByUsed = append(s.topNByUsed, s.jStats[i])
+ }
+}
+
+// Report dumps a markdown formatted report of all the statistics collected during a run to the given dir output
+// path, which should represent a directory. Generated files will be prefixed with the given prefix and will be
+// given a type name such as `anomalies` and a time stamp such as `2021-09-01T12:34:56` and a .md suffix.
+func (s *goRunStats) Report(dir string, prefix string) error {
+
+ isDir, err := isDirectory(dir)
+ switch {
+ case err != nil:
+ return err
+ case !isDir:
+ return fmt.Errorf("output directory `%s` is not a directory", dir)
+ }
+ s.reportCollections(dir, prefix)
+
+ // Clean out any old data in case the user forgets
+ //
+ s.Reset()
+ return nil
+}
+
+func (s *goRunStats) Reset() {
+ s.jStats = nil
+ s.topNByUsed = nil
+ s.topNByMax = nil
+}
+
+func (s *goRunStats) reportCollections(dir, prefix string) {
+ cname := filepath.Join(dir, ".asciidoctor")
+ // If the file doesn't exist, create it, or append to the file
+ f, err := os.OpenFile(cname, os.O_APPEND|os.O_CREATE|os.O_WRONLY, 0644)
+ if err != nil {
+ log.Fatal(err)
+ }
+ _, _ = f.WriteString(`// .asciidoctorconfig
+++++
+
+++++`)
+ _ = f.Close()
+
+ fname := filepath.Join(dir, prefix+"_"+"_"+collectionsFile+"_"+".adoc")
+ // If the file doesn't exist, create it, or append to the file
+ f, err = os.OpenFile(fname, os.O_APPEND|os.O_CREATE|os.O_WRONLY, 0644)
+ if err != nil {
+ log.Fatal(err)
+ }
+ defer func(f *os.File) {
+ err := f.Close()
+ if err != nil {
+ log.Fatal(err)
+ }
+ }(f)
+ _, _ = f.WriteString("= Collections for " + prefix + "\n\n")
+
+ _, _ = f.WriteString("== Summary\n")
+
+ if s.unusedCollections != nil {
+ _, _ = f.WriteString("=== Unused Collections\n")
+ _, _ = f.WriteString("Unused collections incur a penalty for allocation that makes them a candidate for either\n")
+ _, _ = f.WriteString(" removal or optimization. If you are using a collection that is not used, you should\n")
+ _, _ = f.WriteString(" consider removing it. If you are using a collection that is used, but not very often,\n")
+ _, _ = f.WriteString(" you should consider using lazy initialization to defer the allocation until it is\n")
+ _, _ = f.WriteString(" actually needed.\n\n")
+
+ _, _ = f.WriteString("\n.Unused collections\n")
+ _, _ = f.WriteString(`[cols="<3,>1"]` + "\n\n")
+ _, _ = f.WriteString("|===\n")
+ _, _ = f.WriteString("| Type | Count\n")
+
+ for k, v := range s.unusedCollections {
+ _, _ = f.WriteString("| " + CollectionDescriptors[k].SybolicName + " | " + strconv.Itoa(v) + "\n")
+ }
+ f.WriteString("|===\n\n")
+ }
+
+ _, _ = f.WriteString("\n.Summary of Collections\n")
+ _, _ = f.WriteString(`[cols="<3,>1"]` + "\n\n")
+ _, _ = f.WriteString("|===\n")
+ _, _ = f.WriteString("| Type | Count\n")
+ for k, v := range s.counts {
+ _, _ = f.WriteString("| " + CollectionDescriptors[k].SybolicName + " | " + strconv.Itoa(v) + "\n")
+ }
+ _, _ = f.WriteString("| Total | " + strconv.Itoa(len(s.jStats)) + "\n")
+ _, _ = f.WriteString("|===\n\n")
+
+ _, _ = f.WriteString("\n.Summary of Top " + strconv.Itoa(s.topN) + " Collections by MaxSize\n")
+ _, _ = f.WriteString(`[cols="<1,<3,>1,>1,>1,>1"]` + "\n\n")
+ _, _ = f.WriteString("|===\n")
+ _, _ = f.WriteString("| Source | Description | MaxSize | EndSize | Puts | Gets\n")
+ for _, c := range s.topNByMax {
+ _, _ = f.WriteString("| " + CollectionDescriptors[c.Source].SybolicName + "\n")
+ _, _ = f.WriteString("| " + c.Description + "\n")
+ _, _ = f.WriteString("| " + strconv.Itoa(c.MaxSize) + "\n")
+ _, _ = f.WriteString("| " + strconv.Itoa(c.CurSize) + "\n")
+ _, _ = f.WriteString("| " + strconv.Itoa(c.Puts) + "\n")
+ _, _ = f.WriteString("| " + strconv.Itoa(c.Gets) + "\n")
+ _, _ = f.WriteString("\n")
+ }
+ _, _ = f.WriteString("|===\n\n")
+
+ _, _ = f.WriteString("\n.Summary of Top " + strconv.Itoa(s.topN) + " Collections by Access\n")
+ _, _ = f.WriteString(`[cols="<1,<3,>1,>1,>1,>1,>1"]` + "\n\n")
+ _, _ = f.WriteString("|===\n")
+ _, _ = f.WriteString("| Source | Description | MaxSize | EndSize | Puts | Gets | P+G\n")
+ for _, c := range s.topNByUsed {
+ _, _ = f.WriteString("| " + CollectionDescriptors[c.Source].SybolicName + "\n")
+ _, _ = f.WriteString("| " + c.Description + "\n")
+ _, _ = f.WriteString("| " + strconv.Itoa(c.MaxSize) + "\n")
+ _, _ = f.WriteString("| " + strconv.Itoa(c.CurSize) + "\n")
+ _, _ = f.WriteString("| " + strconv.Itoa(c.Puts) + "\n")
+ _, _ = f.WriteString("| " + strconv.Itoa(c.Gets) + "\n")
+ _, _ = f.WriteString("| " + strconv.Itoa(c.Gets+c.Puts) + "\n")
+ _, _ = f.WriteString("\n")
+ }
+ _, _ = f.WriteString("|===\n\n")
+}
+
+// AddJStatRec adds a [JStatRec] record to the [goRunStats] collection when build runtimeConfig antlr.stats is enabled.
+func (s *goRunStats) AddJStatRec(rec *JStatRec) {
+ s.jStatsLock.Lock()
+ defer s.jStatsLock.Unlock()
+ s.jStats = append(s.jStats, rec)
+}
+
+// CollectionAnomalies looks through all the statistical records and gathers any anomalies that have been found.
+func (s *goRunStats) CollectionAnomalies() {
+ s.jStatsLock.RLock()
+ defer s.jStatsLock.RUnlock()
+ s.counts = make(map[CollectionSource]int, len(s.jStats))
+ for _, c := range s.jStats {
+
+ // Accumlate raw counts
+ //
+ s.counts[c.Source]++
+
+ // Look for allocated but unused collections and count them
+ if c.MaxSize == 0 && c.Puts == 0 {
+ if s.unusedCollections == nil {
+ s.unusedCollections = make(map[CollectionSource]int)
+ }
+ s.unusedCollections[c.Source]++
+ }
+ if c.MaxSize > 6000 {
+ fmt.Println("Collection ", c.Description, "accumulated a max size of ", c.MaxSize, " - this is probably too large and indicates a poorly formed grammar")
+ }
+ }
+
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/stats_data.go b/vendor/github.com/antlr4-go/antlr/v4/stats_data.go
new file mode 100644
index 000000000000..4d9eb94e5fa0
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/stats_data.go
@@ -0,0 +1,23 @@
+package antlr
+
+// A JStatRec is a record of a particular use of a [JStore], [JMap] or JPCMap] collection. Typically, it will be
+// used to look for unused collections that wre allocated anyway, problems with hash bucket clashes, and anomalies
+// such as huge numbers of Gets with no entries found GetNoEnt. You can refer to the CollectionAnomalies() function
+// for ideas on what can be gleaned from these statistics about collections.
+type JStatRec struct {
+ Source CollectionSource
+ MaxSize int
+ CurSize int
+ Gets int
+ GetHits int
+ GetMisses int
+ GetHashConflicts int
+ GetNoEnt int
+ Puts int
+ PutHits int
+ PutMisses int
+ PutHashConflicts int
+ MaxSlotSize int
+ Description string
+ CreateStack []byte
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/token.go b/vendor/github.com/antlr4-go/antlr/v4/token.go
new file mode 100644
index 000000000000..9670efb829e4
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/token.go
@@ -0,0 +1,213 @@
+// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
+// Use of this file is governed by the BSD 3-clause license that
+// can be found in the LICENSE.txt file in the project root.
+
+package antlr
+
+import (
+ "strconv"
+ "strings"
+)
+
+type TokenSourceCharStreamPair struct {
+ tokenSource TokenSource
+ charStream CharStream
+}
+
+// A token has properties: text, type, line, character position in the line
+// (so we can ignore tabs), token channel, index, and source from which
+// we obtained this token.
+
+type Token interface {
+ GetSource() *TokenSourceCharStreamPair
+ GetTokenType() int
+ GetChannel() int
+ GetStart() int
+ GetStop() int
+ GetLine() int
+ GetColumn() int
+
+ GetText() string
+ SetText(s string)
+
+ GetTokenIndex() int
+ SetTokenIndex(v int)
+
+ GetTokenSource() TokenSource
+ GetInputStream() CharStream
+
+ String() string
+}
+
+type BaseToken struct {
+ source *TokenSourceCharStreamPair
+ tokenType int // token type of the token
+ channel int // The parser ignores everything not on DEFAULT_CHANNEL
+ start int // optional return -1 if not implemented.
+ stop int // optional return -1 if not implemented.
+ tokenIndex int // from 0..n-1 of the token object in the input stream
+ line int // line=1..n of the 1st character
+ column int // beginning of the line at which it occurs, 0..n-1
+ text string // text of the token.
+ readOnly bool
+}
+
+const (
+ TokenInvalidType = 0
+
+ // TokenEpsilon - during lookahead operations, this "token" signifies we hit the rule end [ATN] state
+ // and did not follow it despite needing to.
+ TokenEpsilon = -2
+
+ TokenMinUserTokenType = 1
+
+ TokenEOF = -1
+
+ // TokenDefaultChannel is the default channel upon which tokens are sent to the parser.
+ //
+ // All tokens go to the parser (unless [Skip] is called in the lexer rule)
+ // on a particular "channel". The parser tunes to a particular channel
+ // so that whitespace etc... can go to the parser on a "hidden" channel.
+ TokenDefaultChannel = 0
+
+ // TokenHiddenChannel defines the normal hidden channel - the parser wil not see tokens that are not on [TokenDefaultChannel].
+ //
+ // Anything on a different channel than TokenDefaultChannel is not parsed by parser.
+ TokenHiddenChannel = 1
+)
+
+func (b *BaseToken) GetChannel() int {
+ return b.channel
+}
+
+func (b *BaseToken) GetStart() int {
+ return b.start
+}
+
+func (b *BaseToken) GetStop() int {
+ return b.stop
+}
+
+func (b *BaseToken) GetLine() int {
+ return b.line
+}
+
+func (b *BaseToken) GetColumn() int {
+ return b.column
+}
+
+func (b *BaseToken) GetTokenType() int {
+ return b.tokenType
+}
+
+func (b *BaseToken) GetSource() *TokenSourceCharStreamPair {
+ return b.source
+}
+
+func (b *BaseToken) GetTokenIndex() int {
+ return b.tokenIndex
+}
+
+func (b *BaseToken) SetTokenIndex(v int) {
+ b.tokenIndex = v
+}
+
+func (b *BaseToken) GetTokenSource() TokenSource {
+ return b.source.tokenSource
+}
+
+func (b *BaseToken) GetInputStream() CharStream {
+ return b.source.charStream
+}
+
+type CommonToken struct {
+ BaseToken
+}
+
+func NewCommonToken(source *TokenSourceCharStreamPair, tokenType, channel, start, stop int) *CommonToken {
+
+ t := &CommonToken{
+ BaseToken: BaseToken{
+ source: source,
+ tokenType: tokenType,
+ channel: channel,
+ start: start,
+ stop: stop,
+ tokenIndex: -1,
+ },
+ }
+
+ if t.source.tokenSource != nil {
+ t.line = source.tokenSource.GetLine()
+ t.column = source.tokenSource.GetCharPositionInLine()
+ } else {
+ t.column = -1
+ }
+ return t
+}
+
+// An empty {@link Pair} which is used as the default value of
+// {@link //source} for tokens that do not have a source.
+
+//CommonToken.EMPTY_SOURCE = [ nil, nil ]
+
+// Constructs a New{@link CommonToken} as a copy of another {@link Token}.
+//
+//
+// If {@code oldToken} is also a {@link CommonToken} instance, the newly
+// constructed token will share a reference to the {@link //text} field and
+// the {@link Pair} stored in {@link //source}. Otherwise, {@link //text} will
+// be assigned the result of calling {@link //GetText}, and {@link //source}
+// will be constructed from the result of {@link Token//GetTokenSource} and
+// {@link Token//GetInputStream}.
+//
+// @param oldToken The token to copy.
+func (c *CommonToken) clone() *CommonToken {
+ t := NewCommonToken(c.source, c.tokenType, c.channel, c.start, c.stop)
+ t.tokenIndex = c.GetTokenIndex()
+ t.line = c.GetLine()
+ t.column = c.GetColumn()
+ t.text = c.GetText()
+ return t
+}
+
+func (c *CommonToken) GetText() string {
+ if c.text != "" {
+ return c.text
+ }
+ input := c.GetInputStream()
+ if input == nil {
+ return ""
+ }
+ n := input.Size()
+ if c.start < n && c.stop < n {
+ return input.GetTextFromInterval(NewInterval(c.start, c.stop))
+ }
+ return ""
+}
+
+func (c *CommonToken) SetText(text string) {
+ c.text = text
+}
+
+func (c *CommonToken) String() string {
+ txt := c.GetText()
+ if txt != "" {
+ txt = strings.Replace(txt, "\n", "\\n", -1)
+ txt = strings.Replace(txt, "\r", "\\r", -1)
+ txt = strings.Replace(txt, "\t", "\\t", -1)
+ } else {
+ txt = ""
+ }
+
+ var ch string
+ if c.channel > 0 {
+ ch = ",channel=" + strconv.Itoa(c.channel)
+ } else {
+ ch = ""
+ }
+
+ return "[@" + strconv.Itoa(c.tokenIndex) + "," + strconv.Itoa(c.start) + ":" + strconv.Itoa(c.stop) + "='" +
+ txt + "',<" + strconv.Itoa(c.tokenType) + ">" +
+ ch + "," + strconv.Itoa(c.line) + ":" + strconv.Itoa(c.column) + "]"
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/token_source.go b/vendor/github.com/antlr4-go/antlr/v4/token_source.go
new file mode 100644
index 000000000000..a3f36eaa67f9
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/token_source.go
@@ -0,0 +1,17 @@
+// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
+// Use of this file is governed by the BSD 3-clause license that
+// can be found in the LICENSE.txt file in the project root.
+
+package antlr
+
+type TokenSource interface {
+ NextToken() Token
+ Skip()
+ More()
+ GetLine() int
+ GetCharPositionInLine() int
+ GetInputStream() CharStream
+ GetSourceName() string
+ setTokenFactory(factory TokenFactory)
+ GetTokenFactory() TokenFactory
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/token_stream.go b/vendor/github.com/antlr4-go/antlr/v4/token_stream.go
new file mode 100644
index 000000000000..bf4ff6633e80
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/token_stream.go
@@ -0,0 +1,21 @@
+// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
+// Use of this file is governed by the BSD 3-clause license that
+// can be found in the LICENSE.txt file in the project root.
+
+package antlr
+
+type TokenStream interface {
+ IntStream
+
+ LT(k int) Token
+ Reset()
+
+ Get(index int) Token
+ GetTokenSource() TokenSource
+ SetTokenSource(TokenSource)
+
+ GetAllText() string
+ GetTextFromInterval(Interval) string
+ GetTextFromRuleContext(RuleContext) string
+ GetTextFromTokens(Token, Token) string
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/tokenstream_rewriter.go b/vendor/github.com/antlr4-go/antlr/v4/tokenstream_rewriter.go
new file mode 100644
index 000000000000..ccf59b465c57
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/tokenstream_rewriter.go
@@ -0,0 +1,662 @@
+// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
+// Use of this file is governed by the BSD 3-clause license that
+// can be found in the LICENSE.txt file in the project root.
+
+package antlr
+
+import (
+ "bytes"
+ "fmt"
+)
+
+//
+// Useful for rewriting out a buffered input token stream after doing some
+// augmentation or other manipulations on it.
+
+//
+// You can insert stuff, replace, and delete chunks. Note that the operations
+// are done lazily--only if you convert the buffer to a {@link String} with
+// {@link TokenStream#getText()}. This is very efficient because you are not
+// moving data around all the time. As the buffer of tokens is converted to
+// strings, the {@link #getText()} method(s) scan the input token stream and
+// check to see if there is an operation at the current index. If so, the
+// operation is done and then normal {@link String} rendering continues on the
+// buffer. This is like having multiple Turing machine instruction streams
+// (programs) operating on a single input tape. :)
+//
+
+// This rewriter makes no modifications to the token stream. It does not ask the
+// stream to fill itself up nor does it advance the input cursor. The token
+// stream {@link TokenStream#index()} will return the same value before and
+// after any {@link #getText()} call.
+
+//
+// The rewriter only works on tokens that you have in the buffer and ignores the
+// current input cursor. If you are buffering tokens on-demand, calling
+// {@link #getText()} halfway through the input will only do rewrites for those
+// tokens in the first half of the file.
+
+//
+// Since the operations are done lazily at {@link #getText}-time, operations do
+// not screw up the token index values. That is, an insert operation at token
+// index {@code i} does not change the index values for tokens
+// {@code i}+1..n-1.
+
+//
+// Because operations never actually alter the buffer, you may always get the
+// original token stream back without undoing anything. Since the instructions
+// are queued up, you can easily simulate transactions and roll back any changes
+// if there is an error just by removing instructions. For example,
+
+//
+// CharStream input = new ANTLRFileStream("input");
+// TLexer lex = new TLexer(input);
+// CommonTokenStream tokens = new CommonTokenStream(lex);
+// T parser = new T(tokens);
+// TokenStreamRewriter rewriter = new TokenStreamRewriter(tokens);
+// parser.startRule();
+//
+
+//
+// Then in the rules, you can execute (assuming rewriter is visible):
+
+//
+// Token t,u;
+// ...
+// rewriter.insertAfter(t, "text to put after t");}
+// rewriter.insertAfter(u, "text after u");}
+// System.out.println(rewriter.getText());
+//
+
+//
+// You can also have multiple "instruction streams" and get multiple rewrites
+// from a single pass over the input. Just name the instruction streams and use
+// that name again when printing the buffer. This could be useful for generating
+// a C file and also its header file--all from the same buffer:
+
+//
+// rewriter.insertAfter("pass1", t, "text to put after t");}
+// rewriter.insertAfter("pass2", u, "text after u");}
+// System.out.println(rewriter.getText("pass1"));
+// System.out.println(rewriter.getText("pass2"));
+//
+
+//
+// If you don't use named rewrite streams, a "default" stream is used as the
+// first example shows.
+
+const (
+ DefaultProgramName = "default"
+ ProgramInitSize = 100
+ MinTokenIndex = 0
+)
+
+// Define the rewrite operation hierarchy
+
+type RewriteOperation interface {
+
+ // Execute the rewrite operation by possibly adding to the buffer.
+ // Return the index of the next token to operate on.
+ Execute(buffer *bytes.Buffer) int
+ String() string
+ GetInstructionIndex() int
+ GetIndex() int
+ GetText() string
+ GetOpName() string
+ GetTokens() TokenStream
+ SetInstructionIndex(val int)
+ SetIndex(int)
+ SetText(string)
+ SetOpName(string)
+ SetTokens(TokenStream)
+}
+
+type BaseRewriteOperation struct {
+ //Current index of rewrites list
+ instructionIndex int
+ //Token buffer index
+ index int
+ //Substitution text
+ text string
+ //Actual operation name
+ opName string
+ //Pointer to token steam
+ tokens TokenStream
+}
+
+func (op *BaseRewriteOperation) GetInstructionIndex() int {
+ return op.instructionIndex
+}
+
+func (op *BaseRewriteOperation) GetIndex() int {
+ return op.index
+}
+
+func (op *BaseRewriteOperation) GetText() string {
+ return op.text
+}
+
+func (op *BaseRewriteOperation) GetOpName() string {
+ return op.opName
+}
+
+func (op *BaseRewriteOperation) GetTokens() TokenStream {
+ return op.tokens
+}
+
+func (op *BaseRewriteOperation) SetInstructionIndex(val int) {
+ op.instructionIndex = val
+}
+
+func (op *BaseRewriteOperation) SetIndex(val int) {
+ op.index = val
+}
+
+func (op *BaseRewriteOperation) SetText(val string) {
+ op.text = val
+}
+
+func (op *BaseRewriteOperation) SetOpName(val string) {
+ op.opName = val
+}
+
+func (op *BaseRewriteOperation) SetTokens(val TokenStream) {
+ op.tokens = val
+}
+
+func (op *BaseRewriteOperation) Execute(_ *bytes.Buffer) int {
+ return op.index
+}
+
+func (op *BaseRewriteOperation) String() string {
+ return fmt.Sprintf("<%s@%d:\"%s\">",
+ op.opName,
+ op.tokens.Get(op.GetIndex()),
+ op.text,
+ )
+
+}
+
+type InsertBeforeOp struct {
+ BaseRewriteOperation
+}
+
+func NewInsertBeforeOp(index int, text string, stream TokenStream) *InsertBeforeOp {
+ return &InsertBeforeOp{BaseRewriteOperation: BaseRewriteOperation{
+ index: index,
+ text: text,
+ opName: "InsertBeforeOp",
+ tokens: stream,
+ }}
+}
+
+func (op *InsertBeforeOp) Execute(buffer *bytes.Buffer) int {
+ buffer.WriteString(op.text)
+ if op.tokens.Get(op.index).GetTokenType() != TokenEOF {
+ buffer.WriteString(op.tokens.Get(op.index).GetText())
+ }
+ return op.index + 1
+}
+
+func (op *InsertBeforeOp) String() string {
+ return op.BaseRewriteOperation.String()
+}
+
+// InsertAfterOp distinguishes between insert after/before to do the "insert after" instructions
+// first and then the "insert before" instructions at same index. Implementation
+// of "insert after" is "insert before index+1".
+type InsertAfterOp struct {
+ BaseRewriteOperation
+}
+
+func NewInsertAfterOp(index int, text string, stream TokenStream) *InsertAfterOp {
+ return &InsertAfterOp{
+ BaseRewriteOperation: BaseRewriteOperation{
+ index: index + 1,
+ text: text,
+ tokens: stream,
+ },
+ }
+}
+
+func (op *InsertAfterOp) Execute(buffer *bytes.Buffer) int {
+ buffer.WriteString(op.text)
+ if op.tokens.Get(op.index).GetTokenType() != TokenEOF {
+ buffer.WriteString(op.tokens.Get(op.index).GetText())
+ }
+ return op.index + 1
+}
+
+func (op *InsertAfterOp) String() string {
+ return op.BaseRewriteOperation.String()
+}
+
+// ReplaceOp tries to replace range from x..y with (y-x)+1 ReplaceOp
+// instructions.
+type ReplaceOp struct {
+ BaseRewriteOperation
+ LastIndex int
+}
+
+func NewReplaceOp(from, to int, text string, stream TokenStream) *ReplaceOp {
+ return &ReplaceOp{
+ BaseRewriteOperation: BaseRewriteOperation{
+ index: from,
+ text: text,
+ opName: "ReplaceOp",
+ tokens: stream,
+ },
+ LastIndex: to,
+ }
+}
+
+func (op *ReplaceOp) Execute(buffer *bytes.Buffer) int {
+ if op.text != "" {
+ buffer.WriteString(op.text)
+ }
+ return op.LastIndex + 1
+}
+
+func (op *ReplaceOp) String() string {
+ if op.text == "" {
+ return fmt.Sprintf("",
+ op.tokens.Get(op.index), op.tokens.Get(op.LastIndex))
+ }
+ return fmt.Sprintf("",
+ op.tokens.Get(op.index), op.tokens.Get(op.LastIndex), op.text)
+}
+
+type TokenStreamRewriter struct {
+ //Our source stream
+ tokens TokenStream
+ // You may have multiple, named streams of rewrite operations.
+ // I'm calling these things "programs."
+ // Maps String (name) → rewrite (List)
+ programs map[string][]RewriteOperation
+ lastRewriteTokenIndexes map[string]int
+}
+
+func NewTokenStreamRewriter(tokens TokenStream) *TokenStreamRewriter {
+ return &TokenStreamRewriter{
+ tokens: tokens,
+ programs: map[string][]RewriteOperation{
+ DefaultProgramName: make([]RewriteOperation, 0, ProgramInitSize),
+ },
+ lastRewriteTokenIndexes: map[string]int{},
+ }
+}
+
+func (tsr *TokenStreamRewriter) GetTokenStream() TokenStream {
+ return tsr.tokens
+}
+
+// Rollback the instruction stream for a program so that
+// the indicated instruction (via instructionIndex) is no
+// longer in the stream. UNTESTED!
+func (tsr *TokenStreamRewriter) Rollback(programName string, instructionIndex int) {
+ is, ok := tsr.programs[programName]
+ if ok {
+ tsr.programs[programName] = is[MinTokenIndex:instructionIndex]
+ }
+}
+
+func (tsr *TokenStreamRewriter) RollbackDefault(instructionIndex int) {
+ tsr.Rollback(DefaultProgramName, instructionIndex)
+}
+
+// DeleteProgram Reset the program so that no instructions exist
+func (tsr *TokenStreamRewriter) DeleteProgram(programName string) {
+ tsr.Rollback(programName, MinTokenIndex) //TODO: double test on that cause lower bound is not included
+}
+
+func (tsr *TokenStreamRewriter) DeleteProgramDefault() {
+ tsr.DeleteProgram(DefaultProgramName)
+}
+
+func (tsr *TokenStreamRewriter) InsertAfter(programName string, index int, text string) {
+ // to insert after, just insert before next index (even if past end)
+ var op RewriteOperation = NewInsertAfterOp(index, text, tsr.tokens)
+ rewrites := tsr.GetProgram(programName)
+ op.SetInstructionIndex(len(rewrites))
+ tsr.AddToProgram(programName, op)
+}
+
+func (tsr *TokenStreamRewriter) InsertAfterDefault(index int, text string) {
+ tsr.InsertAfter(DefaultProgramName, index, text)
+}
+
+func (tsr *TokenStreamRewriter) InsertAfterToken(programName string, token Token, text string) {
+ tsr.InsertAfter(programName, token.GetTokenIndex(), text)
+}
+
+func (tsr *TokenStreamRewriter) InsertBefore(programName string, index int, text string) {
+ var op RewriteOperation = NewInsertBeforeOp(index, text, tsr.tokens)
+ rewrites := tsr.GetProgram(programName)
+ op.SetInstructionIndex(len(rewrites))
+ tsr.AddToProgram(programName, op)
+}
+
+func (tsr *TokenStreamRewriter) InsertBeforeDefault(index int, text string) {
+ tsr.InsertBefore(DefaultProgramName, index, text)
+}
+
+func (tsr *TokenStreamRewriter) InsertBeforeToken(programName string, token Token, text string) {
+ tsr.InsertBefore(programName, token.GetTokenIndex(), text)
+}
+
+func (tsr *TokenStreamRewriter) Replace(programName string, from, to int, text string) {
+ if from > to || from < 0 || to < 0 || to >= tsr.tokens.Size() {
+ panic(fmt.Sprintf("replace: range invalid: %d..%d(size=%d)",
+ from, to, tsr.tokens.Size()))
+ }
+ var op RewriteOperation = NewReplaceOp(from, to, text, tsr.tokens)
+ rewrites := tsr.GetProgram(programName)
+ op.SetInstructionIndex(len(rewrites))
+ tsr.AddToProgram(programName, op)
+}
+
+func (tsr *TokenStreamRewriter) ReplaceDefault(from, to int, text string) {
+ tsr.Replace(DefaultProgramName, from, to, text)
+}
+
+func (tsr *TokenStreamRewriter) ReplaceDefaultPos(index int, text string) {
+ tsr.ReplaceDefault(index, index, text)
+}
+
+func (tsr *TokenStreamRewriter) ReplaceToken(programName string, from, to Token, text string) {
+ tsr.Replace(programName, from.GetTokenIndex(), to.GetTokenIndex(), text)
+}
+
+func (tsr *TokenStreamRewriter) ReplaceTokenDefault(from, to Token, text string) {
+ tsr.ReplaceToken(DefaultProgramName, from, to, text)
+}
+
+func (tsr *TokenStreamRewriter) ReplaceTokenDefaultPos(index Token, text string) {
+ tsr.ReplaceTokenDefault(index, index, text)
+}
+
+func (tsr *TokenStreamRewriter) Delete(programName string, from, to int) {
+ tsr.Replace(programName, from, to, "")
+}
+
+func (tsr *TokenStreamRewriter) DeleteDefault(from, to int) {
+ tsr.Delete(DefaultProgramName, from, to)
+}
+
+func (tsr *TokenStreamRewriter) DeleteDefaultPos(index int) {
+ tsr.DeleteDefault(index, index)
+}
+
+func (tsr *TokenStreamRewriter) DeleteToken(programName string, from, to Token) {
+ tsr.ReplaceToken(programName, from, to, "")
+}
+
+func (tsr *TokenStreamRewriter) DeleteTokenDefault(from, to Token) {
+ tsr.DeleteToken(DefaultProgramName, from, to)
+}
+
+func (tsr *TokenStreamRewriter) GetLastRewriteTokenIndex(programName string) int {
+ i, ok := tsr.lastRewriteTokenIndexes[programName]
+ if !ok {
+ return -1
+ }
+ return i
+}
+
+func (tsr *TokenStreamRewriter) GetLastRewriteTokenIndexDefault() int {
+ return tsr.GetLastRewriteTokenIndex(DefaultProgramName)
+}
+
+func (tsr *TokenStreamRewriter) SetLastRewriteTokenIndex(programName string, i int) {
+ tsr.lastRewriteTokenIndexes[programName] = i
+}
+
+func (tsr *TokenStreamRewriter) InitializeProgram(name string) []RewriteOperation {
+ is := make([]RewriteOperation, 0, ProgramInitSize)
+ tsr.programs[name] = is
+ return is
+}
+
+func (tsr *TokenStreamRewriter) AddToProgram(name string, op RewriteOperation) {
+ is := tsr.GetProgram(name)
+ is = append(is, op)
+ tsr.programs[name] = is
+}
+
+func (tsr *TokenStreamRewriter) GetProgram(name string) []RewriteOperation {
+ is, ok := tsr.programs[name]
+ if !ok {
+ is = tsr.InitializeProgram(name)
+ }
+ return is
+}
+
+// GetTextDefault returns the text from the original tokens altered per the
+// instructions given to this rewriter.
+func (tsr *TokenStreamRewriter) GetTextDefault() string {
+ return tsr.GetText(
+ DefaultProgramName,
+ NewInterval(0, tsr.tokens.Size()-1))
+}
+
+// GetText returns the text from the original tokens altered per the
+// instructions given to this rewriter.
+func (tsr *TokenStreamRewriter) GetText(programName string, interval Interval) string {
+ rewrites := tsr.programs[programName]
+ start := interval.Start
+ stop := interval.Stop
+ // ensure start/end are in range
+ stop = min(stop, tsr.tokens.Size()-1)
+ start = max(start, 0)
+ if len(rewrites) == 0 {
+ return tsr.tokens.GetTextFromInterval(interval) // no instructions to execute
+ }
+ buf := bytes.Buffer{}
+ // First, optimize instruction stream
+ indexToOp := reduceToSingleOperationPerIndex(rewrites)
+ // Walk buffer, executing instructions and emitting tokens
+ for i := start; i <= stop && i < tsr.tokens.Size(); {
+ op := indexToOp[i]
+ delete(indexToOp, i) // remove so any left have index size-1
+ t := tsr.tokens.Get(i)
+ if op == nil {
+ // no operation at that index, just dump token
+ if t.GetTokenType() != TokenEOF {
+ buf.WriteString(t.GetText())
+ }
+ i++ // move to next token
+ } else {
+ i = op.Execute(&buf) // execute operation and skip
+ }
+ }
+ // include stuff after end if it's last index in buffer
+ // So, if they did an insertAfter(lastValidIndex, "foo"), include
+ // foo if end==lastValidIndex.
+ if stop == tsr.tokens.Size()-1 {
+ // Scan any remaining operations after last token
+ // should be included (they will be inserts).
+ for _, op := range indexToOp {
+ if op.GetIndex() >= tsr.tokens.Size()-1 {
+ buf.WriteString(op.GetText())
+ }
+ }
+ }
+ return buf.String()
+}
+
+// reduceToSingleOperationPerIndex combines operations and report invalid operations (like
+// overlapping replaces that are not completed nested). Inserts to
+// same index need to be combined etc...
+//
+// Here are the cases:
+//
+// I.i.u I.j.v leave alone, non-overlapping
+// I.i.u I.i.v combine: Iivu
+//
+// R.i-j.u R.x-y.v | i-j in x-y delete first R
+// R.i-j.u R.i-j.v delete first R
+// R.i-j.u R.x-y.v | x-y in i-j ERROR
+// R.i-j.u R.x-y.v | boundaries overlap ERROR
+//
+// Delete special case of replace (text==null):
+// D.i-j.u D.x-y.v | boundaries overlap combine to max(min)..max(right)
+//
+// I.i.u R.x-y.v | i in (x+1)-y delete I (since insert before
+// we're not deleting i)
+// I.i.u R.x-y.v | i not in (x+1)-y leave alone, non-overlapping
+// R.x-y.v I.i.u | i in x-y ERROR
+// R.x-y.v I.x.u R.x-y.uv (combine, delete I)
+// R.x-y.v I.i.u | i not in x-y leave alone, non-overlapping
+//
+// I.i.u = insert u before op @ index i
+// R.x-y.u = replace x-y indexed tokens with u
+//
+// First we need to examine replaces. For any replace op:
+//
+// 1. wipe out any insertions before op within that range.
+// 2. Drop any replace op before that is contained completely within
+// that range.
+// 3. Throw exception upon boundary overlap with any previous replace.
+//
+// Then we can deal with inserts:
+//
+// 1. for any inserts to same index, combine even if not adjacent.
+// 2. for any prior replace with same left boundary, combine this
+// insert with replace and delete this 'replace'.
+// 3. throw exception if index in same range as previous replace
+//
+// Don't actually delete; make op null in list. Easier to walk list.
+// Later we can throw as we add to index → op map.
+//
+// Note that I.2 R.2-2 will wipe out I.2 even though, technically, the
+// inserted stuff would be before the 'replace' range. But, if you
+// add tokens in front of a method body '{' and then delete the method
+// body, I think the stuff before the '{' you added should disappear too.
+//
+// The func returns a map from token index to operation.
+func reduceToSingleOperationPerIndex(rewrites []RewriteOperation) map[int]RewriteOperation {
+ // WALK REPLACES
+ for i := 0; i < len(rewrites); i++ {
+ op := rewrites[i]
+ if op == nil {
+ continue
+ }
+ rop, ok := op.(*ReplaceOp)
+ if !ok {
+ continue
+ }
+ // Wipe prior inserts within range
+ for j := 0; j < i && j < len(rewrites); j++ {
+ if iop, ok := rewrites[j].(*InsertBeforeOp); ok {
+ if iop.index == rop.index {
+ // E.g., insert before 2, delete 2..2; update replace
+ // text to include insert before, kill insert
+ rewrites[iop.instructionIndex] = nil
+ if rop.text != "" {
+ rop.text = iop.text + rop.text
+ } else {
+ rop.text = iop.text
+ }
+ } else if iop.index > rop.index && iop.index <= rop.LastIndex {
+ // delete insert as it's a no-op.
+ rewrites[iop.instructionIndex] = nil
+ }
+ }
+ }
+ // Drop any prior replaces contained within
+ for j := 0; j < i && j < len(rewrites); j++ {
+ if prevop, ok := rewrites[j].(*ReplaceOp); ok {
+ if prevop.index >= rop.index && prevop.LastIndex <= rop.LastIndex {
+ // delete replace as it's a no-op.
+ rewrites[prevop.instructionIndex] = nil
+ continue
+ }
+ // throw exception unless disjoint or identical
+ disjoint := prevop.LastIndex < rop.index || prevop.index > rop.LastIndex
+ // Delete special case of replace (text==null):
+ // D.i-j.u D.x-y.v | boundaries overlap combine to max(min)..max(right)
+ if prevop.text == "" && rop.text == "" && !disjoint {
+ rewrites[prevop.instructionIndex] = nil
+ rop.index = min(prevop.index, rop.index)
+ rop.LastIndex = max(prevop.LastIndex, rop.LastIndex)
+ } else if !disjoint {
+ panic("replace op boundaries of " + rop.String() + " overlap with previous " + prevop.String())
+ }
+ }
+ }
+ }
+ // WALK INSERTS
+ for i := 0; i < len(rewrites); i++ {
+ op := rewrites[i]
+ if op == nil {
+ continue
+ }
+ //hack to replicate inheritance in composition
+ _, iok := rewrites[i].(*InsertBeforeOp)
+ _, aok := rewrites[i].(*InsertAfterOp)
+ if !iok && !aok {
+ continue
+ }
+ iop := rewrites[i]
+ // combine current insert with prior if any at same index
+ // deviating a bit from TokenStreamRewriter.java - hard to incorporate inheritance logic
+ for j := 0; j < i && j < len(rewrites); j++ {
+ if nextIop, ok := rewrites[j].(*InsertAfterOp); ok {
+ if nextIop.index == iop.GetIndex() {
+ iop.SetText(nextIop.text + iop.GetText())
+ rewrites[j] = nil
+ }
+ }
+ if prevIop, ok := rewrites[j].(*InsertBeforeOp); ok {
+ if prevIop.index == iop.GetIndex() {
+ iop.SetText(iop.GetText() + prevIop.text)
+ rewrites[prevIop.instructionIndex] = nil
+ }
+ }
+ }
+ // look for replaces where iop.index is in range; error
+ for j := 0; j < i && j < len(rewrites); j++ {
+ if rop, ok := rewrites[j].(*ReplaceOp); ok {
+ if iop.GetIndex() == rop.index {
+ rop.text = iop.GetText() + rop.text
+ rewrites[i] = nil
+ continue
+ }
+ if iop.GetIndex() >= rop.index && iop.GetIndex() <= rop.LastIndex {
+ panic("insert op " + iop.String() + " within boundaries of previous " + rop.String())
+ }
+ }
+ }
+ }
+ m := map[int]RewriteOperation{}
+ for i := 0; i < len(rewrites); i++ {
+ op := rewrites[i]
+ if op == nil {
+ continue
+ }
+ if _, ok := m[op.GetIndex()]; ok {
+ panic("should only be one op per index")
+ }
+ m[op.GetIndex()] = op
+ }
+ return m
+}
+
+/*
+ Quick fixing Go lack of overloads
+*/
+
+func max(a, b int) int {
+ if a > b {
+ return a
+ } else {
+ return b
+ }
+}
+func min(a, b int) int {
+ if a < b {
+ return a
+ } else {
+ return b
+ }
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/trace_listener.go b/vendor/github.com/antlr4-go/antlr/v4/trace_listener.go
new file mode 100644
index 000000000000..7b663bf849f6
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/trace_listener.go
@@ -0,0 +1,32 @@
+// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
+// Use of this file is governed by the BSD 3-clause license that
+// can be found in the LICENSE.txt file in the project root.
+
+package antlr
+
+import "fmt"
+
+type TraceListener struct {
+ parser *BaseParser
+}
+
+func NewTraceListener(parser *BaseParser) *TraceListener {
+ tl := new(TraceListener)
+ tl.parser = parser
+ return tl
+}
+
+func (t *TraceListener) VisitErrorNode(_ ErrorNode) {
+}
+
+func (t *TraceListener) EnterEveryRule(ctx ParserRuleContext) {
+ fmt.Println("enter " + t.parser.GetRuleNames()[ctx.GetRuleIndex()] + ", LT(1)=" + t.parser.input.LT(1).GetText())
+}
+
+func (t *TraceListener) VisitTerminal(node TerminalNode) {
+ fmt.Println("consume " + fmt.Sprint(node.GetSymbol()) + " rule " + t.parser.GetRuleNames()[t.parser.ctx.GetRuleIndex()])
+}
+
+func (t *TraceListener) ExitEveryRule(ctx ParserRuleContext) {
+ fmt.Println("exit " + t.parser.GetRuleNames()[ctx.GetRuleIndex()] + ", LT(1)=" + t.parser.input.LT(1).GetText())
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/transition.go b/vendor/github.com/antlr4-go/antlr/v4/transition.go
new file mode 100644
index 000000000000..313b0fc127fb
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/transition.go
@@ -0,0 +1,439 @@
+// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
+// Use of this file is governed by the BSD 3-clause license that
+// can be found in the LICENSE.txt file in the project root.
+
+package antlr
+
+import (
+ "fmt"
+ "strconv"
+ "strings"
+)
+
+// atom, set, epsilon, action, predicate, rule transitions.
+//
+//
This is a one way link. It emanates from a state (usually via a list of
+// transitions) and has a target state.
+//
+//
Since we never have to change the ATN transitions once we construct it,
+// the states. We'll use the term Edge for the DFA to distinguish them from
+// ATN transitions.
+
+type Transition interface {
+ getTarget() ATNState
+ setTarget(ATNState)
+ getIsEpsilon() bool
+ getLabel() *IntervalSet
+ getSerializationType() int
+ Matches(int, int, int) bool
+}
+
+type BaseTransition struct {
+ target ATNState
+ isEpsilon bool
+ label int
+ intervalSet *IntervalSet
+ serializationType int
+}
+
+func NewBaseTransition(target ATNState) *BaseTransition {
+
+ if target == nil {
+ panic("target cannot be nil.")
+ }
+
+ t := new(BaseTransition)
+
+ t.target = target
+ // Are we epsilon, action, sempred?
+ t.isEpsilon = false
+ t.intervalSet = nil
+
+ return t
+}
+
+func (t *BaseTransition) getTarget() ATNState {
+ return t.target
+}
+
+func (t *BaseTransition) setTarget(s ATNState) {
+ t.target = s
+}
+
+func (t *BaseTransition) getIsEpsilon() bool {
+ return t.isEpsilon
+}
+
+func (t *BaseTransition) getLabel() *IntervalSet {
+ return t.intervalSet
+}
+
+func (t *BaseTransition) getSerializationType() int {
+ return t.serializationType
+}
+
+func (t *BaseTransition) Matches(_, _, _ int) bool {
+ panic("Not implemented")
+}
+
+const (
+ TransitionEPSILON = 1
+ TransitionRANGE = 2
+ TransitionRULE = 3
+ TransitionPREDICATE = 4 // e.g., {isType(input.LT(1))}?
+ TransitionATOM = 5
+ TransitionACTION = 6
+ TransitionSET = 7 // ~(A|B) or ~atom, wildcard, which convert to next 2
+ TransitionNOTSET = 8
+ TransitionWILDCARD = 9
+ TransitionPRECEDENCE = 10
+)
+
+//goland:noinspection GoUnusedGlobalVariable
+var TransitionserializationNames = []string{
+ "INVALID",
+ "EPSILON",
+ "RANGE",
+ "RULE",
+ "PREDICATE",
+ "ATOM",
+ "ACTION",
+ "SET",
+ "NOT_SET",
+ "WILDCARD",
+ "PRECEDENCE",
+}
+
+//var TransitionserializationTypes struct {
+// EpsilonTransition int
+// RangeTransition int
+// RuleTransition int
+// PredicateTransition int
+// AtomTransition int
+// ActionTransition int
+// SetTransition int
+// NotSetTransition int
+// WildcardTransition int
+// PrecedencePredicateTransition int
+//}{
+// TransitionEPSILON,
+// TransitionRANGE,
+// TransitionRULE,
+// TransitionPREDICATE,
+// TransitionATOM,
+// TransitionACTION,
+// TransitionSET,
+// TransitionNOTSET,
+// TransitionWILDCARD,
+// TransitionPRECEDENCE
+//}
+
+// AtomTransition
+// TODO: make all transitions sets? no, should remove set edges
+type AtomTransition struct {
+ BaseTransition
+}
+
+func NewAtomTransition(target ATNState, intervalSet int) *AtomTransition {
+ t := &AtomTransition{
+ BaseTransition: BaseTransition{
+ target: target,
+ serializationType: TransitionATOM,
+ label: intervalSet,
+ isEpsilon: false,
+ },
+ }
+ t.intervalSet = t.makeLabel()
+
+ return t
+}
+
+func (t *AtomTransition) makeLabel() *IntervalSet {
+ s := NewIntervalSet()
+ s.addOne(t.label)
+ return s
+}
+
+func (t *AtomTransition) Matches(symbol, _, _ int) bool {
+ return t.label == symbol
+}
+
+func (t *AtomTransition) String() string {
+ return strconv.Itoa(t.label)
+}
+
+type RuleTransition struct {
+ BaseTransition
+ followState ATNState
+ ruleIndex, precedence int
+}
+
+func NewRuleTransition(ruleStart ATNState, ruleIndex, precedence int, followState ATNState) *RuleTransition {
+ return &RuleTransition{
+ BaseTransition: BaseTransition{
+ target: ruleStart,
+ isEpsilon: true,
+ serializationType: TransitionRULE,
+ },
+ ruleIndex: ruleIndex,
+ precedence: precedence,
+ followState: followState,
+ }
+}
+
+func (t *RuleTransition) Matches(_, _, _ int) bool {
+ return false
+}
+
+type EpsilonTransition struct {
+ BaseTransition
+ outermostPrecedenceReturn int
+}
+
+func NewEpsilonTransition(target ATNState, outermostPrecedenceReturn int) *EpsilonTransition {
+ return &EpsilonTransition{
+ BaseTransition: BaseTransition{
+ target: target,
+ serializationType: TransitionEPSILON,
+ isEpsilon: true,
+ },
+ outermostPrecedenceReturn: outermostPrecedenceReturn,
+ }
+}
+
+func (t *EpsilonTransition) Matches(_, _, _ int) bool {
+ return false
+}
+
+func (t *EpsilonTransition) String() string {
+ return "epsilon"
+}
+
+type RangeTransition struct {
+ BaseTransition
+ start, stop int
+}
+
+func NewRangeTransition(target ATNState, start, stop int) *RangeTransition {
+ t := &RangeTransition{
+ BaseTransition: BaseTransition{
+ target: target,
+ serializationType: TransitionRANGE,
+ isEpsilon: false,
+ },
+ start: start,
+ stop: stop,
+ }
+ t.intervalSet = t.makeLabel()
+ return t
+}
+
+func (t *RangeTransition) makeLabel() *IntervalSet {
+ s := NewIntervalSet()
+ s.addRange(t.start, t.stop)
+ return s
+}
+
+func (t *RangeTransition) Matches(symbol, _, _ int) bool {
+ return symbol >= t.start && symbol <= t.stop
+}
+
+func (t *RangeTransition) String() string {
+ var sb strings.Builder
+ sb.WriteByte('\'')
+ sb.WriteRune(rune(t.start))
+ sb.WriteString("'..'")
+ sb.WriteRune(rune(t.stop))
+ sb.WriteByte('\'')
+ return sb.String()
+}
+
+type AbstractPredicateTransition interface {
+ Transition
+ IAbstractPredicateTransitionFoo()
+}
+
+type BaseAbstractPredicateTransition struct {
+ BaseTransition
+}
+
+func NewBasePredicateTransition(target ATNState) *BaseAbstractPredicateTransition {
+ return &BaseAbstractPredicateTransition{
+ BaseTransition: BaseTransition{
+ target: target,
+ },
+ }
+}
+
+func (a *BaseAbstractPredicateTransition) IAbstractPredicateTransitionFoo() {}
+
+type PredicateTransition struct {
+ BaseAbstractPredicateTransition
+ isCtxDependent bool
+ ruleIndex, predIndex int
+}
+
+func NewPredicateTransition(target ATNState, ruleIndex, predIndex int, isCtxDependent bool) *PredicateTransition {
+ return &PredicateTransition{
+ BaseAbstractPredicateTransition: BaseAbstractPredicateTransition{
+ BaseTransition: BaseTransition{
+ target: target,
+ serializationType: TransitionPREDICATE,
+ isEpsilon: true,
+ },
+ },
+ isCtxDependent: isCtxDependent,
+ ruleIndex: ruleIndex,
+ predIndex: predIndex,
+ }
+}
+
+func (t *PredicateTransition) Matches(_, _, _ int) bool {
+ return false
+}
+
+func (t *PredicateTransition) getPredicate() *Predicate {
+ return NewPredicate(t.ruleIndex, t.predIndex, t.isCtxDependent)
+}
+
+func (t *PredicateTransition) String() string {
+ return "pred_" + strconv.Itoa(t.ruleIndex) + ":" + strconv.Itoa(t.predIndex)
+}
+
+type ActionTransition struct {
+ BaseTransition
+ isCtxDependent bool
+ ruleIndex, actionIndex, predIndex int
+}
+
+func NewActionTransition(target ATNState, ruleIndex, actionIndex int, isCtxDependent bool) *ActionTransition {
+ return &ActionTransition{
+ BaseTransition: BaseTransition{
+ target: target,
+ serializationType: TransitionACTION,
+ isEpsilon: true,
+ },
+ isCtxDependent: isCtxDependent,
+ ruleIndex: ruleIndex,
+ actionIndex: actionIndex,
+ }
+}
+
+func (t *ActionTransition) Matches(_, _, _ int) bool {
+ return false
+}
+
+func (t *ActionTransition) String() string {
+ return "action_" + strconv.Itoa(t.ruleIndex) + ":" + strconv.Itoa(t.actionIndex)
+}
+
+type SetTransition struct {
+ BaseTransition
+}
+
+func NewSetTransition(target ATNState, set *IntervalSet) *SetTransition {
+ t := &SetTransition{
+ BaseTransition: BaseTransition{
+ target: target,
+ serializationType: TransitionSET,
+ },
+ }
+
+ if set != nil {
+ t.intervalSet = set
+ } else {
+ t.intervalSet = NewIntervalSet()
+ t.intervalSet.addOne(TokenInvalidType)
+ }
+ return t
+}
+
+func (t *SetTransition) Matches(symbol, _, _ int) bool {
+ return t.intervalSet.contains(symbol)
+}
+
+func (t *SetTransition) String() string {
+ return t.intervalSet.String()
+}
+
+type NotSetTransition struct {
+ SetTransition
+}
+
+func NewNotSetTransition(target ATNState, set *IntervalSet) *NotSetTransition {
+ t := &NotSetTransition{
+ SetTransition: SetTransition{
+ BaseTransition: BaseTransition{
+ target: target,
+ serializationType: TransitionNOTSET,
+ },
+ },
+ }
+ if set != nil {
+ t.intervalSet = set
+ } else {
+ t.intervalSet = NewIntervalSet()
+ t.intervalSet.addOne(TokenInvalidType)
+ }
+
+ return t
+}
+
+func (t *NotSetTransition) Matches(symbol, minVocabSymbol, maxVocabSymbol int) bool {
+ return symbol >= minVocabSymbol && symbol <= maxVocabSymbol && !t.intervalSet.contains(symbol)
+}
+
+func (t *NotSetTransition) String() string {
+ return "~" + t.intervalSet.String()
+}
+
+type WildcardTransition struct {
+ BaseTransition
+}
+
+func NewWildcardTransition(target ATNState) *WildcardTransition {
+ return &WildcardTransition{
+ BaseTransition: BaseTransition{
+ target: target,
+ serializationType: TransitionWILDCARD,
+ },
+ }
+}
+
+func (t *WildcardTransition) Matches(symbol, minVocabSymbol, maxVocabSymbol int) bool {
+ return symbol >= minVocabSymbol && symbol <= maxVocabSymbol
+}
+
+func (t *WildcardTransition) String() string {
+ return "."
+}
+
+type PrecedencePredicateTransition struct {
+ BaseAbstractPredicateTransition
+ precedence int
+}
+
+func NewPrecedencePredicateTransition(target ATNState, precedence int) *PrecedencePredicateTransition {
+ return &PrecedencePredicateTransition{
+ BaseAbstractPredicateTransition: BaseAbstractPredicateTransition{
+ BaseTransition: BaseTransition{
+ target: target,
+ serializationType: TransitionPRECEDENCE,
+ isEpsilon: true,
+ },
+ },
+ precedence: precedence,
+ }
+}
+
+func (t *PrecedencePredicateTransition) Matches(_, _, _ int) bool {
+ return false
+}
+
+func (t *PrecedencePredicateTransition) getPredicate() *PrecedencePredicate {
+ return NewPrecedencePredicate(t.precedence)
+}
+
+func (t *PrecedencePredicateTransition) String() string {
+ return fmt.Sprint(t.precedence) + " >= _p"
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/tree.go b/vendor/github.com/antlr4-go/antlr/v4/tree.go
new file mode 100644
index 000000000000..c288420fb20d
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/tree.go
@@ -0,0 +1,304 @@
+// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
+// Use of this file is governed by the BSD 3-clause license that
+// can be found in the LICENSE.txt file in the project root.
+
+package antlr
+
+// The basic notion of a tree has a parent, a payload, and a list of children.
+// It is the most abstract interface for all the trees used by ANTLR.
+///
+
+var TreeInvalidInterval = NewInterval(-1, -2)
+
+type Tree interface {
+ GetParent() Tree
+ SetParent(Tree)
+ GetPayload() interface{}
+ GetChild(i int) Tree
+ GetChildCount() int
+ GetChildren() []Tree
+}
+
+type SyntaxTree interface {
+ Tree
+ GetSourceInterval() Interval
+}
+
+type ParseTree interface {
+ SyntaxTree
+ Accept(Visitor ParseTreeVisitor) interface{}
+ GetText() string
+ ToStringTree([]string, Recognizer) string
+}
+
+type RuleNode interface {
+ ParseTree
+ GetRuleContext() RuleContext
+}
+
+type TerminalNode interface {
+ ParseTree
+ GetSymbol() Token
+}
+
+type ErrorNode interface {
+ TerminalNode
+
+ errorNode()
+}
+
+type ParseTreeVisitor interface {
+ Visit(tree ParseTree) interface{}
+ VisitChildren(node RuleNode) interface{}
+ VisitTerminal(node TerminalNode) interface{}
+ VisitErrorNode(node ErrorNode) interface{}
+}
+
+type BaseParseTreeVisitor struct{}
+
+var _ ParseTreeVisitor = &BaseParseTreeVisitor{}
+
+func (v *BaseParseTreeVisitor) Visit(tree ParseTree) interface{} { return tree.Accept(v) }
+func (v *BaseParseTreeVisitor) VisitChildren(_ RuleNode) interface{} { return nil }
+func (v *BaseParseTreeVisitor) VisitTerminal(_ TerminalNode) interface{} { return nil }
+func (v *BaseParseTreeVisitor) VisitErrorNode(_ ErrorNode) interface{} { return nil }
+
+// TODO: Implement this?
+//func (this ParseTreeVisitor) Visit(ctx) {
+// if (Utils.isArray(ctx)) {
+// self := this
+// return ctx.map(function(child) { return VisitAtom(self, child)})
+// } else {
+// return VisitAtom(this, ctx)
+// }
+//}
+//
+//func VisitAtom(Visitor, ctx) {
+// if (ctx.parser == nil) { //is terminal
+// return
+// }
+//
+// name := ctx.parser.ruleNames[ctx.ruleIndex]
+// funcName := "Visit" + Utils.titleCase(name)
+//
+// return Visitor[funcName](ctx)
+//}
+
+type ParseTreeListener interface {
+ VisitTerminal(node TerminalNode)
+ VisitErrorNode(node ErrorNode)
+ EnterEveryRule(ctx ParserRuleContext)
+ ExitEveryRule(ctx ParserRuleContext)
+}
+
+type BaseParseTreeListener struct{}
+
+var _ ParseTreeListener = &BaseParseTreeListener{}
+
+func (l *BaseParseTreeListener) VisitTerminal(_ TerminalNode) {}
+func (l *BaseParseTreeListener) VisitErrorNode(_ ErrorNode) {}
+func (l *BaseParseTreeListener) EnterEveryRule(_ ParserRuleContext) {}
+func (l *BaseParseTreeListener) ExitEveryRule(_ ParserRuleContext) {}
+
+type TerminalNodeImpl struct {
+ parentCtx RuleContext
+ symbol Token
+}
+
+var _ TerminalNode = &TerminalNodeImpl{}
+
+func NewTerminalNodeImpl(symbol Token) *TerminalNodeImpl {
+ tn := new(TerminalNodeImpl)
+
+ tn.parentCtx = nil
+ tn.symbol = symbol
+
+ return tn
+}
+
+func (t *TerminalNodeImpl) GetChild(_ int) Tree {
+ return nil
+}
+
+func (t *TerminalNodeImpl) GetChildren() []Tree {
+ return nil
+}
+
+func (t *TerminalNodeImpl) SetChildren(_ []Tree) {
+ panic("Cannot set children on terminal node")
+}
+
+func (t *TerminalNodeImpl) GetSymbol() Token {
+ return t.symbol
+}
+
+func (t *TerminalNodeImpl) GetParent() Tree {
+ return t.parentCtx
+}
+
+func (t *TerminalNodeImpl) SetParent(tree Tree) {
+ t.parentCtx = tree.(RuleContext)
+}
+
+func (t *TerminalNodeImpl) GetPayload() interface{} {
+ return t.symbol
+}
+
+func (t *TerminalNodeImpl) GetSourceInterval() Interval {
+ if t.symbol == nil {
+ return TreeInvalidInterval
+ }
+ tokenIndex := t.symbol.GetTokenIndex()
+ return NewInterval(tokenIndex, tokenIndex)
+}
+
+func (t *TerminalNodeImpl) GetChildCount() int {
+ return 0
+}
+
+func (t *TerminalNodeImpl) Accept(v ParseTreeVisitor) interface{} {
+ return v.VisitTerminal(t)
+}
+
+func (t *TerminalNodeImpl) GetText() string {
+ return t.symbol.GetText()
+}
+
+func (t *TerminalNodeImpl) String() string {
+ if t.symbol.GetTokenType() == TokenEOF {
+ return ""
+ }
+
+ return t.symbol.GetText()
+}
+
+func (t *TerminalNodeImpl) ToStringTree(_ []string, _ Recognizer) string {
+ return t.String()
+}
+
+// Represents a token that was consumed during reSynchronization
+// rather than during a valid Match operation. For example,
+// we will create this kind of a node during single token insertion
+// and deletion as well as during "consume until error recovery set"
+// upon no viable alternative exceptions.
+
+type ErrorNodeImpl struct {
+ *TerminalNodeImpl
+}
+
+var _ ErrorNode = &ErrorNodeImpl{}
+
+func NewErrorNodeImpl(token Token) *ErrorNodeImpl {
+ en := new(ErrorNodeImpl)
+ en.TerminalNodeImpl = NewTerminalNodeImpl(token)
+ return en
+}
+
+func (e *ErrorNodeImpl) errorNode() {}
+
+func (e *ErrorNodeImpl) Accept(v ParseTreeVisitor) interface{} {
+ return v.VisitErrorNode(e)
+}
+
+type ParseTreeWalker struct {
+}
+
+func NewParseTreeWalker() *ParseTreeWalker {
+ return new(ParseTreeWalker)
+}
+
+// Walk performs a walk on the given parse tree starting at the root and going down recursively
+// with depth-first search. On each node, [EnterRule] is called before
+// recursively walking down into child nodes, then [ExitRule] is called after the recursive call to wind up.
+func (p *ParseTreeWalker) Walk(listener ParseTreeListener, t Tree) {
+ switch tt := t.(type) {
+ case ErrorNode:
+ listener.VisitErrorNode(tt)
+ case TerminalNode:
+ listener.VisitTerminal(tt)
+ default:
+ p.EnterRule(listener, t.(RuleNode))
+ for i := 0; i < t.GetChildCount(); i++ {
+ child := t.GetChild(i)
+ p.Walk(listener, child)
+ }
+ p.ExitRule(listener, t.(RuleNode))
+ }
+}
+
+// EnterRule enters a grammar rule by first triggering the generic event [ParseTreeListener].[EnterEveryRule]
+// then by triggering the event specific to the given parse tree node
+func (p *ParseTreeWalker) EnterRule(listener ParseTreeListener, r RuleNode) {
+ ctx := r.GetRuleContext().(ParserRuleContext)
+ listener.EnterEveryRule(ctx)
+ ctx.EnterRule(listener)
+}
+
+// ExitRule exits a grammar rule by first triggering the event specific to the given parse tree node
+// then by triggering the generic event [ParseTreeListener].ExitEveryRule
+func (p *ParseTreeWalker) ExitRule(listener ParseTreeListener, r RuleNode) {
+ ctx := r.GetRuleContext().(ParserRuleContext)
+ ctx.ExitRule(listener)
+ listener.ExitEveryRule(ctx)
+}
+
+//goland:noinspection GoUnusedGlobalVariable
+var ParseTreeWalkerDefault = NewParseTreeWalker()
+
+type IterativeParseTreeWalker struct {
+ *ParseTreeWalker
+}
+
+//goland:noinspection GoUnusedExportedFunction
+func NewIterativeParseTreeWalker() *IterativeParseTreeWalker {
+ return new(IterativeParseTreeWalker)
+}
+
+func (i *IterativeParseTreeWalker) Walk(listener ParseTreeListener, t Tree) {
+ var stack []Tree
+ var indexStack []int
+ currentNode := t
+ currentIndex := 0
+
+ for currentNode != nil {
+ // pre-order visit
+ switch tt := currentNode.(type) {
+ case ErrorNode:
+ listener.VisitErrorNode(tt)
+ case TerminalNode:
+ listener.VisitTerminal(tt)
+ default:
+ i.EnterRule(listener, currentNode.(RuleNode))
+ }
+ // Move down to first child, if exists
+ if currentNode.GetChildCount() > 0 {
+ stack = append(stack, currentNode)
+ indexStack = append(indexStack, currentIndex)
+ currentIndex = 0
+ currentNode = currentNode.GetChild(0)
+ continue
+ }
+
+ for {
+ // post-order visit
+ if ruleNode, ok := currentNode.(RuleNode); ok {
+ i.ExitRule(listener, ruleNode)
+ }
+ // No parent, so no siblings
+ if len(stack) == 0 {
+ currentNode = nil
+ currentIndex = 0
+ break
+ }
+ // Move to next sibling if possible
+ currentIndex++
+ if stack[len(stack)-1].GetChildCount() > currentIndex {
+ currentNode = stack[len(stack)-1].GetChild(currentIndex)
+ break
+ }
+ // No next, sibling, so move up
+ currentNode, stack = stack[len(stack)-1], stack[:len(stack)-1]
+ currentIndex, indexStack = indexStack[len(indexStack)-1], indexStack[:len(indexStack)-1]
+ }
+ }
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/trees.go b/vendor/github.com/antlr4-go/antlr/v4/trees.go
new file mode 100644
index 000000000000..f44c05d81114
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/trees.go
@@ -0,0 +1,142 @@
+// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
+// Use of this file is governed by the BSD 3-clause license that
+// can be found in the LICENSE.txt file in the project root.
+
+package antlr
+
+import "fmt"
+
+/** A set of utility routines useful for all kinds of ANTLR trees. */
+
+// TreesStringTree prints out a whole tree in LISP form. [getNodeText] is used on the
+// node payloads to get the text for the nodes. Detects parse trees and extracts data appropriately.
+func TreesStringTree(tree Tree, ruleNames []string, recog Recognizer) string {
+
+ if recog != nil {
+ ruleNames = recog.GetRuleNames()
+ }
+
+ s := TreesGetNodeText(tree, ruleNames, nil)
+
+ s = EscapeWhitespace(s, false)
+ c := tree.GetChildCount()
+ if c == 0 {
+ return s
+ }
+ res := "(" + s + " "
+ if c > 0 {
+ s = TreesStringTree(tree.GetChild(0), ruleNames, nil)
+ res += s
+ }
+ for i := 1; i < c; i++ {
+ s = TreesStringTree(tree.GetChild(i), ruleNames, nil)
+ res += " " + s
+ }
+ res += ")"
+ return res
+}
+
+func TreesGetNodeText(t Tree, ruleNames []string, recog Parser) string {
+ if recog != nil {
+ ruleNames = recog.GetRuleNames()
+ }
+
+ if ruleNames != nil {
+ switch t2 := t.(type) {
+ case RuleNode:
+ t3 := t2.GetRuleContext()
+ altNumber := t3.GetAltNumber()
+
+ if altNumber != ATNInvalidAltNumber {
+ return fmt.Sprintf("%s:%d", ruleNames[t3.GetRuleIndex()], altNumber)
+ }
+ return ruleNames[t3.GetRuleIndex()]
+ case ErrorNode:
+ return fmt.Sprint(t2)
+ case TerminalNode:
+ if t2.GetSymbol() != nil {
+ return t2.GetSymbol().GetText()
+ }
+ }
+ }
+
+ // no recognition for rule names
+ payload := t.GetPayload()
+ if p2, ok := payload.(Token); ok {
+ return p2.GetText()
+ }
+
+ return fmt.Sprint(t.GetPayload())
+}
+
+// TreesGetChildren returns am ordered list of all children of this node
+//
+//goland:noinspection GoUnusedExportedFunction
+func TreesGetChildren(t Tree) []Tree {
+ list := make([]Tree, 0)
+ for i := 0; i < t.GetChildCount(); i++ {
+ list = append(list, t.GetChild(i))
+ }
+ return list
+}
+
+// TreesgetAncestors returns a list of all ancestors of this node. The first node of list is the root
+// and the last node is the parent of this node.
+//
+//goland:noinspection GoUnusedExportedFunction
+func TreesgetAncestors(t Tree) []Tree {
+ ancestors := make([]Tree, 0)
+ t = t.GetParent()
+ for t != nil {
+ f := []Tree{t}
+ ancestors = append(f, ancestors...)
+ t = t.GetParent()
+ }
+ return ancestors
+}
+
+//goland:noinspection GoUnusedExportedFunction
+func TreesFindAllTokenNodes(t ParseTree, ttype int) []ParseTree {
+ return TreesfindAllNodes(t, ttype, true)
+}
+
+//goland:noinspection GoUnusedExportedFunction
+func TreesfindAllRuleNodes(t ParseTree, ruleIndex int) []ParseTree {
+ return TreesfindAllNodes(t, ruleIndex, false)
+}
+
+func TreesfindAllNodes(t ParseTree, index int, findTokens bool) []ParseTree {
+ nodes := make([]ParseTree, 0)
+ treesFindAllNodes(t, index, findTokens, &nodes)
+ return nodes
+}
+
+func treesFindAllNodes(t ParseTree, index int, findTokens bool, nodes *[]ParseTree) {
+ // check this node (the root) first
+
+ t2, ok := t.(TerminalNode)
+ t3, ok2 := t.(ParserRuleContext)
+
+ if findTokens && ok {
+ if t2.GetSymbol().GetTokenType() == index {
+ *nodes = append(*nodes, t2)
+ }
+ } else if !findTokens && ok2 {
+ if t3.GetRuleIndex() == index {
+ *nodes = append(*nodes, t3)
+ }
+ }
+ // check children
+ for i := 0; i < t.GetChildCount(); i++ {
+ treesFindAllNodes(t.GetChild(i).(ParseTree), index, findTokens, nodes)
+ }
+}
+
+//goland:noinspection GoUnusedExportedFunction
+func TreesDescendants(t ParseTree) []ParseTree {
+ nodes := []ParseTree{t}
+ for i := 0; i < t.GetChildCount(); i++ {
+ nodes = append(nodes, TreesDescendants(t.GetChild(i).(ParseTree))...)
+ }
+ return nodes
+}
diff --git a/vendor/github.com/antlr4-go/antlr/v4/utils.go b/vendor/github.com/antlr4-go/antlr/v4/utils.go
new file mode 100644
index 000000000000..733d7df9dc74
--- /dev/null
+++ b/vendor/github.com/antlr4-go/antlr/v4/utils.go
@@ -0,0 +1,328 @@
+// Copyright (c) 2012-2022 The ANTLR Project. All rights reserved.
+// Use of this file is governed by the BSD 3-clause license that
+// can be found in the LICENSE.txt file in the project root.
+
+package antlr
+
+import (
+ "bytes"
+ "errors"
+ "fmt"
+ "math/bits"
+ "os"
+ "strconv"
+ "strings"
+ "syscall"
+)
+
+func intMin(a, b int) int {
+ if a < b {
+ return a
+ }
+ return b
+}
+
+func intMax(a, b int) int {
+ if a > b {
+ return a
+ }
+ return b
+}
+
+// A simple integer stack
+
+type IntStack []int
+
+var ErrEmptyStack = errors.New("stack is empty")
+
+func (s *IntStack) Pop() (int, error) {
+ l := len(*s) - 1
+ if l < 0 {
+ return 0, ErrEmptyStack
+ }
+ v := (*s)[l]
+ *s = (*s)[0:l]
+ return v, nil
+}
+
+func (s *IntStack) Push(e int) {
+ *s = append(*s, e)
+}
+
+const bitsPerWord = 64
+
+func indexForBit(bit int) int {
+ return bit / bitsPerWord
+}
+
+//goland:noinspection GoUnusedExportedFunction,GoUnusedFunction
+func wordForBit(data []uint64, bit int) uint64 {
+ idx := indexForBit(bit)
+ if idx >= len(data) {
+ return 0
+ }
+ return data[idx]
+}
+
+func maskForBit(bit int) uint64 {
+ return uint64(1) << (bit % bitsPerWord)
+}
+
+func wordsNeeded(bit int) int {
+ return indexForBit(bit) + 1
+}
+
+type BitSet struct {
+ data []uint64
+}
+
+// NewBitSet creates a new bitwise set
+// TODO: See if we can replace with the standard library's BitSet
+func NewBitSet() *BitSet {
+ return &BitSet{}
+}
+
+func (b *BitSet) add(value int) {
+ idx := indexForBit(value)
+ if idx >= len(b.data) {
+ size := wordsNeeded(value)
+ data := make([]uint64, size)
+ copy(data, b.data)
+ b.data = data
+ }
+ b.data[idx] |= maskForBit(value)
+}
+
+func (b *BitSet) clear(index int) {
+ idx := indexForBit(index)
+ if idx >= len(b.data) {
+ return
+ }
+ b.data[idx] &= ^maskForBit(index)
+}
+
+func (b *BitSet) or(set *BitSet) {
+ // Get min size necessary to represent the bits in both sets.
+ bLen := b.minLen()
+ setLen := set.minLen()
+ maxLen := intMax(bLen, setLen)
+ if maxLen > len(b.data) {
+ // Increase the size of len(b.data) to represent the bits in both sets.
+ data := make([]uint64, maxLen)
+ copy(data, b.data)
+ b.data = data
+ }
+ // len(b.data) is at least setLen.
+ for i := 0; i < setLen; i++ {
+ b.data[i] |= set.data[i]
+ }
+}
+
+func (b *BitSet) remove(value int) {
+ b.clear(value)
+}
+
+func (b *BitSet) contains(value int) bool {
+ idx := indexForBit(value)
+ if idx >= len(b.data) {
+ return false
+ }
+ return (b.data[idx] & maskForBit(value)) != 0
+}
+
+func (b *BitSet) minValue() int {
+ for i, v := range b.data {
+ if v == 0 {
+ continue
+ }
+ return i*bitsPerWord + bits.TrailingZeros64(v)
+ }
+ return 2147483647
+}
+
+func (b *BitSet) equals(other interface{}) bool {
+ otherBitSet, ok := other.(*BitSet)
+ if !ok {
+ return false
+ }
+
+ if b == otherBitSet {
+ return true
+ }
+
+ // We only compare set bits, so we cannot rely on the two slices having the same size. Its
+ // possible for two BitSets to have different slice lengths but the same set bits. So we only
+ // compare the relevant words and ignore the trailing zeros.
+ bLen := b.minLen()
+ otherLen := otherBitSet.minLen()
+
+ if bLen != otherLen {
+ return false
+ }
+
+ for i := 0; i < bLen; i++ {
+ if b.data[i] != otherBitSet.data[i] {
+ return false
+ }
+ }
+
+ return true
+}
+
+func (b *BitSet) minLen() int {
+ for i := len(b.data); i > 0; i-- {
+ if b.data[i-1] != 0 {
+ return i
+ }
+ }
+ return 0
+}
+
+func (b *BitSet) length() int {
+ cnt := 0
+ for _, val := range b.data {
+ cnt += bits.OnesCount64(val)
+ }
+ return cnt
+}
+
+func (b *BitSet) String() string {
+ vals := make([]string, 0, b.length())
+
+ for i, v := range b.data {
+ for v != 0 {
+ n := bits.TrailingZeros64(v)
+ vals = append(vals, strconv.Itoa(i*bitsPerWord+n))
+ v &= ^(uint64(1) << n)
+ }
+ }
+
+ return "{" + strings.Join(vals, ", ") + "}"
+}
+
+type AltDict struct {
+ data map[string]interface{}
+}
+
+func NewAltDict() *AltDict {
+ d := new(AltDict)
+ d.data = make(map[string]interface{})
+ return d
+}
+
+func (a *AltDict) Get(key string) interface{} {
+ key = "k-" + key
+ return a.data[key]
+}
+
+func (a *AltDict) put(key string, value interface{}) {
+ key = "k-" + key
+ a.data[key] = value
+}
+
+func (a *AltDict) values() []interface{} {
+ vs := make([]interface{}, len(a.data))
+ i := 0
+ for _, v := range a.data {
+ vs[i] = v
+ i++
+ }
+ return vs
+}
+
+func EscapeWhitespace(s string, escapeSpaces bool) string {
+
+ s = strings.Replace(s, "\t", "\\t", -1)
+ s = strings.Replace(s, "\n", "\\n", -1)
+ s = strings.Replace(s, "\r", "\\r", -1)
+ if escapeSpaces {
+ s = strings.Replace(s, " ", "\u00B7", -1)
+ }
+ return s
+}
+
+//goland:noinspection GoUnusedExportedFunction
+func TerminalNodeToStringArray(sa []TerminalNode) []string {
+ st := make([]string, len(sa))
+
+ for i, s := range sa {
+ st[i] = fmt.Sprintf("%v", s)
+ }
+
+ return st
+}
+
+//goland:noinspection GoUnusedExportedFunction
+func PrintArrayJavaStyle(sa []string) string {
+ var buffer bytes.Buffer
+
+ buffer.WriteString("[")
+
+ for i, s := range sa {
+ buffer.WriteString(s)
+ if i != len(sa)-1 {
+ buffer.WriteString(", ")
+ }
+ }
+
+ buffer.WriteString("]")
+
+ return buffer.String()
+}
+
+// murmur hash
+func murmurInit(seed int) int {
+ return seed
+}
+
+func murmurUpdate(h int, value int) int {
+ const c1 uint32 = 0xCC9E2D51
+ const c2 uint32 = 0x1B873593
+ const r1 uint32 = 15
+ const r2 uint32 = 13
+ const m uint32 = 5
+ const n uint32 = 0xE6546B64
+
+ k := uint32(value)
+ k *= c1
+ k = (k << r1) | (k >> (32 - r1))
+ k *= c2
+
+ hash := uint32(h) ^ k
+ hash = (hash << r2) | (hash >> (32 - r2))
+ hash = hash*m + n
+ return int(hash)
+}
+
+func murmurFinish(h int, numberOfWords int) int {
+ var hash = uint32(h)
+ hash ^= uint32(numberOfWords) << 2
+ hash ^= hash >> 16
+ hash *= 0x85ebca6b
+ hash ^= hash >> 13
+ hash *= 0xc2b2ae35
+ hash ^= hash >> 16
+
+ return int(hash)
+}
+
+func isDirectory(dir string) (bool, error) {
+ fileInfo, err := os.Stat(dir)
+ if err != nil {
+ switch {
+ case errors.Is(err, syscall.ENOENT):
+ // The given directory does not exist, so we will try to create it
+ //
+ err = os.MkdirAll(dir, 0755)
+ if err != nil {
+ return false, err
+ }
+
+ return true, nil
+ case err != nil:
+ return false, err
+ default:
+ }
+ }
+ return fileInfo.IsDir(), err
+}
diff --git a/vendor/github.com/blang/semver/v4/BUILD.bazel b/vendor/github.com/blang/semver/v4/BUILD.bazel
new file mode 100644
index 000000000000..f44c397c96c5
--- /dev/null
+++ b/vendor/github.com/blang/semver/v4/BUILD.bazel
@@ -0,0 +1,15 @@
+load("@io_bazel_rules_go//go:def.bzl", "go_library")
+
+go_library(
+ name = "go_default_library",
+ srcs = [
+ "json.go",
+ "range.go",
+ "semver.go",
+ "sort.go",
+ "sql.go",
+ ],
+ importmap = "kubevirt.io/kubevirt/vendor/github.com/blang/semver/v4",
+ importpath = "github.com/blang/semver/v4",
+ visibility = ["//visibility:public"],
+)
diff --git a/vendor/github.com/blang/semver/v4/LICENSE b/vendor/github.com/blang/semver/v4/LICENSE
new file mode 100644
index 000000000000..5ba5c86fcb02
--- /dev/null
+++ b/vendor/github.com/blang/semver/v4/LICENSE
@@ -0,0 +1,22 @@
+The MIT License
+
+Copyright (c) 2014 Benedikt Lang
+
+Permission is hereby granted, free of charge, to any person obtaining a copy
+of this software and associated documentation files (the "Software"), to deal
+in the Software without restriction, including without limitation the rights
+to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
+copies of the Software, and to permit persons to whom the Software is
+furnished to do so, subject to the following conditions:
+
+The above copyright notice and this permission notice shall be included in
+all copies or substantial portions of the Software.
+
+THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
+IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
+FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
+AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
+LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
+OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
+THE SOFTWARE.
+
diff --git a/vendor/github.com/blang/semver/v4/json.go b/vendor/github.com/blang/semver/v4/json.go
new file mode 100644
index 000000000000..a74bf7c44940
--- /dev/null
+++ b/vendor/github.com/blang/semver/v4/json.go
@@ -0,0 +1,23 @@
+package semver
+
+import (
+ "encoding/json"
+)
+
+// MarshalJSON implements the encoding/json.Marshaler interface.
+func (v Version) MarshalJSON() ([]byte, error) {
+ return json.Marshal(v.String())
+}
+
+// UnmarshalJSON implements the encoding/json.Unmarshaler interface.
+func (v *Version) UnmarshalJSON(data []byte) (err error) {
+ var versionString string
+
+ if err = json.Unmarshal(data, &versionString); err != nil {
+ return
+ }
+
+ *v, err = Parse(versionString)
+
+ return
+}
diff --git a/vendor/github.com/blang/semver/v4/range.go b/vendor/github.com/blang/semver/v4/range.go
new file mode 100644
index 000000000000..95f7139b9770
--- /dev/null
+++ b/vendor/github.com/blang/semver/v4/range.go
@@ -0,0 +1,416 @@
+package semver
+
+import (
+ "fmt"
+ "strconv"
+ "strings"
+ "unicode"
+)
+
+type wildcardType int
+
+const (
+ noneWildcard wildcardType = iota
+ majorWildcard wildcardType = 1
+ minorWildcard wildcardType = 2
+ patchWildcard wildcardType = 3
+)
+
+func wildcardTypefromInt(i int) wildcardType {
+ switch i {
+ case 1:
+ return majorWildcard
+ case 2:
+ return minorWildcard
+ case 3:
+ return patchWildcard
+ default:
+ return noneWildcard
+ }
+}
+
+type comparator func(Version, Version) bool
+
+var (
+ compEQ comparator = func(v1 Version, v2 Version) bool {
+ return v1.Compare(v2) == 0
+ }
+ compNE = func(v1 Version, v2 Version) bool {
+ return v1.Compare(v2) != 0
+ }
+ compGT = func(v1 Version, v2 Version) bool {
+ return v1.Compare(v2) == 1
+ }
+ compGE = func(v1 Version, v2 Version) bool {
+ return v1.Compare(v2) >= 0
+ }
+ compLT = func(v1 Version, v2 Version) bool {
+ return v1.Compare(v2) == -1
+ }
+ compLE = func(v1 Version, v2 Version) bool {
+ return v1.Compare(v2) <= 0
+ }
+)
+
+type versionRange struct {
+ v Version
+ c comparator
+}
+
+// rangeFunc creates a Range from the given versionRange.
+func (vr *versionRange) rangeFunc() Range {
+ return Range(func(v Version) bool {
+ return vr.c(v, vr.v)
+ })
+}
+
+// Range represents a range of versions.
+// A Range can be used to check if a Version satisfies it:
+//
+// range, err := semver.ParseRange(">1.0.0 <2.0.0")
+// range(semver.MustParse("1.1.1") // returns true
+type Range func(Version) bool
+
+// OR combines the existing Range with another Range using logical OR.
+func (rf Range) OR(f Range) Range {
+ return Range(func(v Version) bool {
+ return rf(v) || f(v)
+ })
+}
+
+// AND combines the existing Range with another Range using logical AND.
+func (rf Range) AND(f Range) Range {
+ return Range(func(v Version) bool {
+ return rf(v) && f(v)
+ })
+}
+
+// ParseRange parses a range and returns a Range.
+// If the range could not be parsed an error is returned.
+//
+// Valid ranges are:
+// - "<1.0.0"
+// - "<=1.0.0"
+// - ">1.0.0"
+// - ">=1.0.0"
+// - "1.0.0", "=1.0.0", "==1.0.0"
+// - "!1.0.0", "!=1.0.0"
+//
+// A Range can consist of multiple ranges separated by space:
+// Ranges can be linked by logical AND:
+// - ">1.0.0 <2.0.0" would match between both ranges, so "1.1.1" and "1.8.7" but not "1.0.0" or "2.0.0"
+// - ">1.0.0 <3.0.0 !2.0.3-beta.2" would match every version between 1.0.0 and 3.0.0 except 2.0.3-beta.2
+//
+// Ranges can also be linked by logical OR:
+// - "<2.0.0 || >=3.0.0" would match "1.x.x" and "3.x.x" but not "2.x.x"
+//
+// AND has a higher precedence than OR. It's not possible to use brackets.
+//
+// Ranges can be combined by both AND and OR
+//
+// - `>1.0.0 <2.0.0 || >3.0.0 !4.2.1` would match `1.2.3`, `1.9.9`, `3.1.1`, but not `4.2.1`, `2.1.1`
+func ParseRange(s string) (Range, error) {
+ parts := splitAndTrim(s)
+ orParts, err := splitORParts(parts)
+ if err != nil {
+ return nil, err
+ }
+ expandedParts, err := expandWildcardVersion(orParts)
+ if err != nil {
+ return nil, err
+ }
+ var orFn Range
+ for _, p := range expandedParts {
+ var andFn Range
+ for _, ap := range p {
+ opStr, vStr, err := splitComparatorVersion(ap)
+ if err != nil {
+ return nil, err
+ }
+ vr, err := buildVersionRange(opStr, vStr)
+ if err != nil {
+ return nil, fmt.Errorf("Could not parse Range %q: %s", ap, err)
+ }
+ rf := vr.rangeFunc()
+
+ // Set function
+ if andFn == nil {
+ andFn = rf
+ } else { // Combine with existing function
+ andFn = andFn.AND(rf)
+ }
+ }
+ if orFn == nil {
+ orFn = andFn
+ } else {
+ orFn = orFn.OR(andFn)
+ }
+
+ }
+ return orFn, nil
+}
+
+// splitORParts splits the already cleaned parts by '||'.
+// Checks for invalid positions of the operator and returns an
+// error if found.
+func splitORParts(parts []string) ([][]string, error) {
+ var ORparts [][]string
+ last := 0
+ for i, p := range parts {
+ if p == "||" {
+ if i == 0 {
+ return nil, fmt.Errorf("First element in range is '||'")
+ }
+ ORparts = append(ORparts, parts[last:i])
+ last = i + 1
+ }
+ }
+ if last == len(parts) {
+ return nil, fmt.Errorf("Last element in range is '||'")
+ }
+ ORparts = append(ORparts, parts[last:])
+ return ORparts, nil
+}
+
+// buildVersionRange takes a slice of 2: operator and version
+// and builds a versionRange, otherwise an error.
+func buildVersionRange(opStr, vStr string) (*versionRange, error) {
+ c := parseComparator(opStr)
+ if c == nil {
+ return nil, fmt.Errorf("Could not parse comparator %q in %q", opStr, strings.Join([]string{opStr, vStr}, ""))
+ }
+ v, err := Parse(vStr)
+ if err != nil {
+ return nil, fmt.Errorf("Could not parse version %q in %q: %s", vStr, strings.Join([]string{opStr, vStr}, ""), err)
+ }
+
+ return &versionRange{
+ v: v,
+ c: c,
+ }, nil
+
+}
+
+// inArray checks if a byte is contained in an array of bytes
+func inArray(s byte, list []byte) bool {
+ for _, el := range list {
+ if el == s {
+ return true
+ }
+ }
+ return false
+}
+
+// splitAndTrim splits a range string by spaces and cleans whitespaces
+func splitAndTrim(s string) (result []string) {
+ last := 0
+ var lastChar byte
+ excludeFromSplit := []byte{'>', '<', '='}
+ for i := 0; i < len(s); i++ {
+ if s[i] == ' ' && !inArray(lastChar, excludeFromSplit) {
+ if last < i-1 {
+ result = append(result, s[last:i])
+ }
+ last = i + 1
+ } else if s[i] != ' ' {
+ lastChar = s[i]
+ }
+ }
+ if last < len(s)-1 {
+ result = append(result, s[last:])
+ }
+
+ for i, v := range result {
+ result[i] = strings.Replace(v, " ", "", -1)
+ }
+
+ // parts := strings.Split(s, " ")
+ // for _, x := range parts {
+ // if s := strings.TrimSpace(x); len(s) != 0 {
+ // result = append(result, s)
+ // }
+ // }
+ return
+}
+
+// splitComparatorVersion splits the comparator from the version.
+// Input must be free of leading or trailing spaces.
+func splitComparatorVersion(s string) (string, string, error) {
+ i := strings.IndexFunc(s, unicode.IsDigit)
+ if i == -1 {
+ return "", "", fmt.Errorf("Could not get version from string: %q", s)
+ }
+ return strings.TrimSpace(s[0:i]), s[i:], nil
+}
+
+// getWildcardType will return the type of wildcard that the
+// passed version contains
+func getWildcardType(vStr string) wildcardType {
+ parts := strings.Split(vStr, ".")
+ nparts := len(parts)
+ wildcard := parts[nparts-1]
+
+ possibleWildcardType := wildcardTypefromInt(nparts)
+ if wildcard == "x" {
+ return possibleWildcardType
+ }
+
+ return noneWildcard
+}
+
+// createVersionFromWildcard will convert a wildcard version
+// into a regular version, replacing 'x's with '0's, handling
+// special cases like '1.x.x' and '1.x'
+func createVersionFromWildcard(vStr string) string {
+ // handle 1.x.x
+ vStr2 := strings.Replace(vStr, ".x.x", ".x", 1)
+ vStr2 = strings.Replace(vStr2, ".x", ".0", 1)
+ parts := strings.Split(vStr2, ".")
+
+ // handle 1.x
+ if len(parts) == 2 {
+ return vStr2 + ".0"
+ }
+
+ return vStr2
+}
+
+// incrementMajorVersion will increment the major version
+// of the passed version
+func incrementMajorVersion(vStr string) (string, error) {
+ parts := strings.Split(vStr, ".")
+ i, err := strconv.Atoi(parts[0])
+ if err != nil {
+ return "", err
+ }
+ parts[0] = strconv.Itoa(i + 1)
+
+ return strings.Join(parts, "."), nil
+}
+
+// incrementMajorVersion will increment the minor version
+// of the passed version
+func incrementMinorVersion(vStr string) (string, error) {
+ parts := strings.Split(vStr, ".")
+ i, err := strconv.Atoi(parts[1])
+ if err != nil {
+ return "", err
+ }
+ parts[1] = strconv.Itoa(i + 1)
+
+ return strings.Join(parts, "."), nil
+}
+
+// expandWildcardVersion will expand wildcards inside versions
+// following these rules:
+//
+// * when dealing with patch wildcards:
+// >= 1.2.x will become >= 1.2.0
+// <= 1.2.x will become < 1.3.0
+// > 1.2.x will become >= 1.3.0
+// < 1.2.x will become < 1.2.0
+// != 1.2.x will become < 1.2.0 >= 1.3.0
+//
+// * when dealing with minor wildcards:
+// >= 1.x will become >= 1.0.0
+// <= 1.x will become < 2.0.0
+// > 1.x will become >= 2.0.0
+// < 1.0 will become < 1.0.0
+// != 1.x will become < 1.0.0 >= 2.0.0
+//
+// * when dealing with wildcards without
+// version operator:
+// 1.2.x will become >= 1.2.0 < 1.3.0
+// 1.x will become >= 1.0.0 < 2.0.0
+func expandWildcardVersion(parts [][]string) ([][]string, error) {
+ var expandedParts [][]string
+ for _, p := range parts {
+ var newParts []string
+ for _, ap := range p {
+ if strings.Contains(ap, "x") {
+ opStr, vStr, err := splitComparatorVersion(ap)
+ if err != nil {
+ return nil, err
+ }
+
+ versionWildcardType := getWildcardType(vStr)
+ flatVersion := createVersionFromWildcard(vStr)
+
+ var resultOperator string
+ var shouldIncrementVersion bool
+ switch opStr {
+ case ">":
+ resultOperator = ">="
+ shouldIncrementVersion = true
+ case ">=":
+ resultOperator = ">="
+ case "<":
+ resultOperator = "<"
+ case "<=":
+ resultOperator = "<"
+ shouldIncrementVersion = true
+ case "", "=", "==":
+ newParts = append(newParts, ">="+flatVersion)
+ resultOperator = "<"
+ shouldIncrementVersion = true
+ case "!=", "!":
+ newParts = append(newParts, "<"+flatVersion)
+ resultOperator = ">="
+ shouldIncrementVersion = true
+ }
+
+ var resultVersion string
+ if shouldIncrementVersion {
+ switch versionWildcardType {
+ case patchWildcard:
+ resultVersion, _ = incrementMinorVersion(flatVersion)
+ case minorWildcard:
+ resultVersion, _ = incrementMajorVersion(flatVersion)
+ }
+ } else {
+ resultVersion = flatVersion
+ }
+
+ ap = resultOperator + resultVersion
+ }
+ newParts = append(newParts, ap)
+ }
+ expandedParts = append(expandedParts, newParts)
+ }
+
+ return expandedParts, nil
+}
+
+func parseComparator(s string) comparator {
+ switch s {
+ case "==":
+ fallthrough
+ case "":
+ fallthrough
+ case "=":
+ return compEQ
+ case ">":
+ return compGT
+ case ">=":
+ return compGE
+ case "<":
+ return compLT
+ case "<=":
+ return compLE
+ case "!":
+ fallthrough
+ case "!=":
+ return compNE
+ }
+
+ return nil
+}
+
+// MustParseRange is like ParseRange but panics if the range cannot be parsed.
+func MustParseRange(s string) Range {
+ r, err := ParseRange(s)
+ if err != nil {
+ panic(`semver: ParseRange(` + s + `): ` + err.Error())
+ }
+ return r
+}
diff --git a/vendor/github.com/blang/semver/v4/semver.go b/vendor/github.com/blang/semver/v4/semver.go
new file mode 100644
index 000000000000..307de610f927
--- /dev/null
+++ b/vendor/github.com/blang/semver/v4/semver.go
@@ -0,0 +1,476 @@
+package semver
+
+import (
+ "errors"
+ "fmt"
+ "strconv"
+ "strings"
+)
+
+const (
+ numbers string = "0123456789"
+ alphas = "abcdefghijklmnopqrstuvwxyzABCDEFGHIJKLMNOPQRSTUVWXYZ-"
+ alphanum = alphas + numbers
+)
+
+// SpecVersion is the latest fully supported spec version of semver
+var SpecVersion = Version{
+ Major: 2,
+ Minor: 0,
+ Patch: 0,
+}
+
+// Version represents a semver compatible version
+type Version struct {
+ Major uint64
+ Minor uint64
+ Patch uint64
+ Pre []PRVersion
+ Build []string //No Precedence
+}
+
+// Version to string
+func (v Version) String() string {
+ b := make([]byte, 0, 5)
+ b = strconv.AppendUint(b, v.Major, 10)
+ b = append(b, '.')
+ b = strconv.AppendUint(b, v.Minor, 10)
+ b = append(b, '.')
+ b = strconv.AppendUint(b, v.Patch, 10)
+
+ if len(v.Pre) > 0 {
+ b = append(b, '-')
+ b = append(b, v.Pre[0].String()...)
+
+ for _, pre := range v.Pre[1:] {
+ b = append(b, '.')
+ b = append(b, pre.String()...)
+ }
+ }
+
+ if len(v.Build) > 0 {
+ b = append(b, '+')
+ b = append(b, v.Build[0]...)
+
+ for _, build := range v.Build[1:] {
+ b = append(b, '.')
+ b = append(b, build...)
+ }
+ }
+
+ return string(b)
+}
+
+// FinalizeVersion discards prerelease and build number and only returns
+// major, minor and patch number.
+func (v Version) FinalizeVersion() string {
+ b := make([]byte, 0, 5)
+ b = strconv.AppendUint(b, v.Major, 10)
+ b = append(b, '.')
+ b = strconv.AppendUint(b, v.Minor, 10)
+ b = append(b, '.')
+ b = strconv.AppendUint(b, v.Patch, 10)
+ return string(b)
+}
+
+// Equals checks if v is equal to o.
+func (v Version) Equals(o Version) bool {
+ return (v.Compare(o) == 0)
+}
+
+// EQ checks if v is equal to o.
+func (v Version) EQ(o Version) bool {
+ return (v.Compare(o) == 0)
+}
+
+// NE checks if v is not equal to o.
+func (v Version) NE(o Version) bool {
+ return (v.Compare(o) != 0)
+}
+
+// GT checks if v is greater than o.
+func (v Version) GT(o Version) bool {
+ return (v.Compare(o) == 1)
+}
+
+// GTE checks if v is greater than or equal to o.
+func (v Version) GTE(o Version) bool {
+ return (v.Compare(o) >= 0)
+}
+
+// GE checks if v is greater than or equal to o.
+func (v Version) GE(o Version) bool {
+ return (v.Compare(o) >= 0)
+}
+
+// LT checks if v is less than o.
+func (v Version) LT(o Version) bool {
+ return (v.Compare(o) == -1)
+}
+
+// LTE checks if v is less than or equal to o.
+func (v Version) LTE(o Version) bool {
+ return (v.Compare(o) <= 0)
+}
+
+// LE checks if v is less than or equal to o.
+func (v Version) LE(o Version) bool {
+ return (v.Compare(o) <= 0)
+}
+
+// Compare compares Versions v to o:
+// -1 == v is less than o
+// 0 == v is equal to o
+// 1 == v is greater than o
+func (v Version) Compare(o Version) int {
+ if v.Major != o.Major {
+ if v.Major > o.Major {
+ return 1
+ }
+ return -1
+ }
+ if v.Minor != o.Minor {
+ if v.Minor > o.Minor {
+ return 1
+ }
+ return -1
+ }
+ if v.Patch != o.Patch {
+ if v.Patch > o.Patch {
+ return 1
+ }
+ return -1
+ }
+
+ // Quick comparison if a version has no prerelease versions
+ if len(v.Pre) == 0 && len(o.Pre) == 0 {
+ return 0
+ } else if len(v.Pre) == 0 && len(o.Pre) > 0 {
+ return 1
+ } else if len(v.Pre) > 0 && len(o.Pre) == 0 {
+ return -1
+ }
+
+ i := 0
+ for ; i < len(v.Pre) && i < len(o.Pre); i++ {
+ if comp := v.Pre[i].Compare(o.Pre[i]); comp == 0 {
+ continue
+ } else if comp == 1 {
+ return 1
+ } else {
+ return -1
+ }
+ }
+
+ // If all pr versions are the equal but one has further prversion, this one greater
+ if i == len(v.Pre) && i == len(o.Pre) {
+ return 0
+ } else if i == len(v.Pre) && i < len(o.Pre) {
+ return -1
+ } else {
+ return 1
+ }
+
+}
+
+// IncrementPatch increments the patch version
+func (v *Version) IncrementPatch() error {
+ v.Patch++
+ return nil
+}
+
+// IncrementMinor increments the minor version
+func (v *Version) IncrementMinor() error {
+ v.Minor++
+ v.Patch = 0
+ return nil
+}
+
+// IncrementMajor increments the major version
+func (v *Version) IncrementMajor() error {
+ v.Major++
+ v.Minor = 0
+ v.Patch = 0
+ return nil
+}
+
+// Validate validates v and returns error in case
+func (v Version) Validate() error {
+ // Major, Minor, Patch already validated using uint64
+
+ for _, pre := range v.Pre {
+ if !pre.IsNum { //Numeric prerelease versions already uint64
+ if len(pre.VersionStr) == 0 {
+ return fmt.Errorf("Prerelease can not be empty %q", pre.VersionStr)
+ }
+ if !containsOnly(pre.VersionStr, alphanum) {
+ return fmt.Errorf("Invalid character(s) found in prerelease %q", pre.VersionStr)
+ }
+ }
+ }
+
+ for _, build := range v.Build {
+ if len(build) == 0 {
+ return fmt.Errorf("Build meta data can not be empty %q", build)
+ }
+ if !containsOnly(build, alphanum) {
+ return fmt.Errorf("Invalid character(s) found in build meta data %q", build)
+ }
+ }
+
+ return nil
+}
+
+// New is an alias for Parse and returns a pointer, parses version string and returns a validated Version or error
+func New(s string) (*Version, error) {
+ v, err := Parse(s)
+ vp := &v
+ return vp, err
+}
+
+// Make is an alias for Parse, parses version string and returns a validated Version or error
+func Make(s string) (Version, error) {
+ return Parse(s)
+}
+
+// ParseTolerant allows for certain version specifications that do not strictly adhere to semver
+// specs to be parsed by this library. It does so by normalizing versions before passing them to
+// Parse(). It currently trims spaces, removes a "v" prefix, adds a 0 patch number to versions
+// with only major and minor components specified, and removes leading 0s.
+func ParseTolerant(s string) (Version, error) {
+ s = strings.TrimSpace(s)
+ s = strings.TrimPrefix(s, "v")
+
+ // Split into major.minor.(patch+pr+meta)
+ parts := strings.SplitN(s, ".", 3)
+ // Remove leading zeros.
+ for i, p := range parts {
+ if len(p) > 1 {
+ p = strings.TrimLeft(p, "0")
+ if len(p) == 0 || !strings.ContainsAny(p[0:1], "0123456789") {
+ p = "0" + p
+ }
+ parts[i] = p
+ }
+ }
+ // Fill up shortened versions.
+ if len(parts) < 3 {
+ if strings.ContainsAny(parts[len(parts)-1], "+-") {
+ return Version{}, errors.New("Short version cannot contain PreRelease/Build meta data")
+ }
+ for len(parts) < 3 {
+ parts = append(parts, "0")
+ }
+ }
+ s = strings.Join(parts, ".")
+
+ return Parse(s)
+}
+
+// Parse parses version string and returns a validated Version or error
+func Parse(s string) (Version, error) {
+ if len(s) == 0 {
+ return Version{}, errors.New("Version string empty")
+ }
+
+ // Split into major.minor.(patch+pr+meta)
+ parts := strings.SplitN(s, ".", 3)
+ if len(parts) != 3 {
+ return Version{}, errors.New("No Major.Minor.Patch elements found")
+ }
+
+ // Major
+ if !containsOnly(parts[0], numbers) {
+ return Version{}, fmt.Errorf("Invalid character(s) found in major number %q", parts[0])
+ }
+ if hasLeadingZeroes(parts[0]) {
+ return Version{}, fmt.Errorf("Major number must not contain leading zeroes %q", parts[0])
+ }
+ major, err := strconv.ParseUint(parts[0], 10, 64)
+ if err != nil {
+ return Version{}, err
+ }
+
+ // Minor
+ if !containsOnly(parts[1], numbers) {
+ return Version{}, fmt.Errorf("Invalid character(s) found in minor number %q", parts[1])
+ }
+ if hasLeadingZeroes(parts[1]) {
+ return Version{}, fmt.Errorf("Minor number must not contain leading zeroes %q", parts[1])
+ }
+ minor, err := strconv.ParseUint(parts[1], 10, 64)
+ if err != nil {
+ return Version{}, err
+ }
+
+ v := Version{}
+ v.Major = major
+ v.Minor = minor
+
+ var build, prerelease []string
+ patchStr := parts[2]
+
+ if buildIndex := strings.IndexRune(patchStr, '+'); buildIndex != -1 {
+ build = strings.Split(patchStr[buildIndex+1:], ".")
+ patchStr = patchStr[:buildIndex]
+ }
+
+ if preIndex := strings.IndexRune(patchStr, '-'); preIndex != -1 {
+ prerelease = strings.Split(patchStr[preIndex+1:], ".")
+ patchStr = patchStr[:preIndex]
+ }
+
+ if !containsOnly(patchStr, numbers) {
+ return Version{}, fmt.Errorf("Invalid character(s) found in patch number %q", patchStr)
+ }
+ if hasLeadingZeroes(patchStr) {
+ return Version{}, fmt.Errorf("Patch number must not contain leading zeroes %q", patchStr)
+ }
+ patch, err := strconv.ParseUint(patchStr, 10, 64)
+ if err != nil {
+ return Version{}, err
+ }
+
+ v.Patch = patch
+
+ // Prerelease
+ for _, prstr := range prerelease {
+ parsedPR, err := NewPRVersion(prstr)
+ if err != nil {
+ return Version{}, err
+ }
+ v.Pre = append(v.Pre, parsedPR)
+ }
+
+ // Build meta data
+ for _, str := range build {
+ if len(str) == 0 {
+ return Version{}, errors.New("Build meta data is empty")
+ }
+ if !containsOnly(str, alphanum) {
+ return Version{}, fmt.Errorf("Invalid character(s) found in build meta data %q", str)
+ }
+ v.Build = append(v.Build, str)
+ }
+
+ return v, nil
+}
+
+// MustParse is like Parse but panics if the version cannot be parsed.
+func MustParse(s string) Version {
+ v, err := Parse(s)
+ if err != nil {
+ panic(`semver: Parse(` + s + `): ` + err.Error())
+ }
+ return v
+}
+
+// PRVersion represents a PreRelease Version
+type PRVersion struct {
+ VersionStr string
+ VersionNum uint64
+ IsNum bool
+}
+
+// NewPRVersion creates a new valid prerelease version
+func NewPRVersion(s string) (PRVersion, error) {
+ if len(s) == 0 {
+ return PRVersion{}, errors.New("Prerelease is empty")
+ }
+ v := PRVersion{}
+ if containsOnly(s, numbers) {
+ if hasLeadingZeroes(s) {
+ return PRVersion{}, fmt.Errorf("Numeric PreRelease version must not contain leading zeroes %q", s)
+ }
+ num, err := strconv.ParseUint(s, 10, 64)
+
+ // Might never be hit, but just in case
+ if err != nil {
+ return PRVersion{}, err
+ }
+ v.VersionNum = num
+ v.IsNum = true
+ } else if containsOnly(s, alphanum) {
+ v.VersionStr = s
+ v.IsNum = false
+ } else {
+ return PRVersion{}, fmt.Errorf("Invalid character(s) found in prerelease %q", s)
+ }
+ return v, nil
+}
+
+// IsNumeric checks if prerelease-version is numeric
+func (v PRVersion) IsNumeric() bool {
+ return v.IsNum
+}
+
+// Compare compares two PreRelease Versions v and o:
+// -1 == v is less than o
+// 0 == v is equal to o
+// 1 == v is greater than o
+func (v PRVersion) Compare(o PRVersion) int {
+ if v.IsNum && !o.IsNum {
+ return -1
+ } else if !v.IsNum && o.IsNum {
+ return 1
+ } else if v.IsNum && o.IsNum {
+ if v.VersionNum == o.VersionNum {
+ return 0
+ } else if v.VersionNum > o.VersionNum {
+ return 1
+ } else {
+ return -1
+ }
+ } else { // both are Alphas
+ if v.VersionStr == o.VersionStr {
+ return 0
+ } else if v.VersionStr > o.VersionStr {
+ return 1
+ } else {
+ return -1
+ }
+ }
+}
+
+// PreRelease version to string
+func (v PRVersion) String() string {
+ if v.IsNum {
+ return strconv.FormatUint(v.VersionNum, 10)
+ }
+ return v.VersionStr
+}
+
+func containsOnly(s string, set string) bool {
+ return strings.IndexFunc(s, func(r rune) bool {
+ return !strings.ContainsRune(set, r)
+ }) == -1
+}
+
+func hasLeadingZeroes(s string) bool {
+ return len(s) > 1 && s[0] == '0'
+}
+
+// NewBuildVersion creates a new valid build version
+func NewBuildVersion(s string) (string, error) {
+ if len(s) == 0 {
+ return "", errors.New("Buildversion is empty")
+ }
+ if !containsOnly(s, alphanum) {
+ return "", fmt.Errorf("Invalid character(s) found in build meta data %q", s)
+ }
+ return s, nil
+}
+
+// FinalizeVersion returns the major, minor and patch number only and discards
+// prerelease and build number.
+func FinalizeVersion(s string) (string, error) {
+ v, err := Parse(s)
+ if err != nil {
+ return "", err
+ }
+ v.Pre = nil
+ v.Build = nil
+
+ finalVer := v.String()
+ return finalVer, nil
+}
diff --git a/vendor/github.com/blang/semver/v4/sort.go b/vendor/github.com/blang/semver/v4/sort.go
new file mode 100644
index 000000000000..e18f880826ab
--- /dev/null
+++ b/vendor/github.com/blang/semver/v4/sort.go
@@ -0,0 +1,28 @@
+package semver
+
+import (
+ "sort"
+)
+
+// Versions represents multiple versions.
+type Versions []Version
+
+// Len returns length of version collection
+func (s Versions) Len() int {
+ return len(s)
+}
+
+// Swap swaps two versions inside the collection by its indices
+func (s Versions) Swap(i, j int) {
+ s[i], s[j] = s[j], s[i]
+}
+
+// Less checks if version at index i is less than version at index j
+func (s Versions) Less(i, j int) bool {
+ return s[i].LT(s[j])
+}
+
+// Sort sorts a slice of versions
+func Sort(versions []Version) {
+ sort.Sort(Versions(versions))
+}
diff --git a/vendor/github.com/blang/semver/v4/sql.go b/vendor/github.com/blang/semver/v4/sql.go
new file mode 100644
index 000000000000..db958134f3b4
--- /dev/null
+++ b/vendor/github.com/blang/semver/v4/sql.go
@@ -0,0 +1,30 @@
+package semver
+
+import (
+ "database/sql/driver"
+ "fmt"
+)
+
+// Scan implements the database/sql.Scanner interface.
+func (v *Version) Scan(src interface{}) (err error) {
+ var str string
+ switch src := src.(type) {
+ case string:
+ str = src
+ case []byte:
+ str = string(src)
+ default:
+ return fmt.Errorf("version.Scan: cannot convert %T to string", src)
+ }
+
+ if t, err := Parse(str); err == nil {
+ *v = t
+ }
+
+ return
+}
+
+// Value implements the database/sql/driver.Valuer interface.
+func (v Version) Value() (driver.Value, error) {
+ return v.String(), nil
+}
diff --git a/vendor/github.com/google/cel-go/LICENSE b/vendor/github.com/google/cel-go/LICENSE
new file mode 100644
index 000000000000..2493ed2eb4e9
--- /dev/null
+++ b/vendor/github.com/google/cel-go/LICENSE
@@ -0,0 +1,233 @@
+
+ Apache License
+ Version 2.0, January 2004
+ http://www.apache.org/licenses/
+
+ TERMS AND CONDITIONS FOR USE, REPRODUCTION, AND DISTRIBUTION
+
+ 1. Definitions.
+
+ "License" shall mean the terms and conditions for use, reproduction,
+ and distribution as defined by Sections 1 through 9 of this document.
+
+ "Licensor" shall mean the copyright owner or entity authorized by
+ the copyright owner that is granting the License.
+
+ "Legal Entity" shall mean the union of the acting entity and all
+ other entities that control, are controlled by, or are under common
+ control with that entity. For the purposes of this definition,
+ "control" means (i) the power, direct or indirect, to cause the
+ direction or management of such entity, whether by contract or
+ otherwise, or (ii) ownership of fifty percent (50%) or more of the
+ outstanding shares, or (iii) beneficial ownership of such entity.
+
+ "You" (or "Your") shall mean an individual or Legal Entity
+ exercising permissions granted by this License.
+
+ "Source" form shall mean the preferred form for making modifications,
+ including but not limited to software source code, documentation
+ source, and configuration files.
+
+ "Object" form shall mean any form resulting from mechanical
+ transformation or translation of a Source form, including but
+ not limited to compiled object code, generated documentation,
+ and conversions to other media types.
+
+ "Work" shall mean the work of authorship, whether in Source or
+ Object form, made available under the License, as indicated by a
+ copyright notice that is included in or attached to the work
+ (an example is provided in the Appendix below).
+
+ "Derivative Works" shall mean any work, whether in Source or Object
+ form, that is based on (or derived from) the Work and for which the
+ editorial revisions, annotations, elaborations, or other modifications
+ represent, as a whole, an original work of authorship. For the purposes
+ of this License, Derivative Works shall not include works that remain
+ separable from, or merely link (or bind by name) to the interfaces of,
+ the Work and Derivative Works thereof.
+
+ "Contribution" shall mean any work of authorship, including
+ the original version of the Work and any modifications or additions
+ to that Work or Derivative Works thereof, that is intentionally
+ submitted to Licensor for inclusion in the Work by the copyright owner
+ or by an individual or Legal Entity authorized to submit on behalf of
+ the copyright owner. For the purposes of this definition, "submitted"
+ means any form of electronic, verbal, or written communication sent
+ to the Licensor or its representatives, including but not limited to
+ communication on electronic mailing lists, source code control systems,
+ and issue tracking systems that are managed by, or on behalf of, the
+ Licensor for the purpose of discussing and improving the Work, but
+ excluding communication that is conspicuously marked or otherwise
+ designated in writing by the copyright owner as "Not a Contribution."
+
+ "Contributor" shall mean Licensor and any individual or Legal Entity
+ on behalf of whom a Contribution has been received by Licensor and
+ subsequently incorporated within the Work.
+
+ 2. Grant of Copyright License. Subject to the terms and conditions of
+ this License, each Contributor hereby grants to You a perpetual,
+ worldwide, non-exclusive, no-charge, royalty-free, irrevocable
+ copyright license to reproduce, prepare Derivative Works of,
+ publicly display, publicly perform, sublicense, and distribute the
+ Work and such Derivative Works in Source or Object form.
+
+ 3. Grant of Patent License. Subject to the terms and conditions of
+ this License, each Contributor hereby grants to You a perpetual,
+ worldwide, non-exclusive, no-charge, royalty-free, irrevocable
+ (except as stated in this section) patent license to make, have made,
+ use, offer to sell, sell, import, and otherwise transfer the Work,
+ where such license applies only to those patent claims licensable
+ by such Contributor that are necessarily infringed by their
+ Contribution(s) alone or by combination of their Contribution(s)
+ with the Work to which such Contribution(s) was submitted. If You
+ institute patent litigation against any entity (including a
+ cross-claim or counterclaim in a lawsuit) alleging that the Work
+ or a Contribution incorporated within the Work constitutes direct
+ or contributory patent infringement, then any patent licenses
+ granted to You under this License for that Work shall terminate
+ as of the date such litigation is filed.
+
+ 4. Redistribution. You may reproduce and distribute copies of the
+ Work or Derivative Works thereof in any medium, with or without
+ modifications, and in Source or Object form, provided that You
+ meet the following conditions:
+
+ (a) You must give any other recipients of the Work or
+ Derivative Works a copy of this License; and
+
+ (b) You must cause any modified files to carry prominent notices
+ stating that You changed the files; and
+
+ (c) You must retain, in the Source form of any Derivative Works
+ that You distribute, all copyright, patent, trademark, and
+ attribution notices from the Source form of the Work,
+ excluding those notices that do not pertain to any part of
+ the Derivative Works; and
+
+ (d) If the Work includes a "NOTICE" text file as part of its
+ distribution, then any Derivative Works that You distribute must
+ include a readable copy of the attribution notices contained
+ within such NOTICE file, excluding those notices that do not
+ pertain to any part of the Derivative Works, in at least one
+ of the following places: within a NOTICE text file distributed
+ as part of the Derivative Works; within the Source form or
+ documentation, if provided along with the Derivative Works; or,
+ within a display generated by the Derivative Works, if and
+ wherever such third-party notices normally appear. The contents
+ of the NOTICE file are for informational purposes only and
+ do not modify the License. You may add Your own attribution
+ notices within Derivative Works that You distribute, alongside
+ or as an addendum to the NOTICE text from the Work, provided
+ that such additional attribution notices cannot be construed
+ as modifying the License.
+
+ You may add Your own copyright statement to Your modifications and
+ may provide additional or different license terms and conditions
+ for use, reproduction, or distribution of Your modifications, or
+ for any such Derivative Works as a whole, provided Your use,
+ reproduction, and distribution of the Work otherwise complies with
+ the conditions stated in this License.
+
+ 5. Submission of Contributions. Unless You explicitly state otherwise,
+ any Contribution intentionally submitted for inclusion in the Work
+ by You to the Licensor shall be under the terms and conditions of
+ this License, without any additional terms or conditions.
+ Notwithstanding the above, nothing herein shall supersede or modify
+ the terms of any separate license agreement you may have executed
+ with Licensor regarding such Contributions.
+
+ 6. Trademarks. This License does not grant permission to use the trade
+ names, trademarks, service marks, or product names of the Licensor,
+ except as required for reasonable and customary use in describing the
+ origin of the Work and reproducing the content of the NOTICE file.
+
+ 7. Disclaimer of Warranty. Unless required by applicable law or
+ agreed to in writing, Licensor provides the Work (and each
+ Contributor provides its Contributions) on an "AS IS" BASIS,
+ WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or
+ implied, including, without limitation, any warranties or conditions
+ of TITLE, NON-INFRINGEMENT, MERCHANTABILITY, or FITNESS FOR A
+ PARTICULAR PURPOSE. You are solely responsible for determining the
+ appropriateness of using or redistributing the Work and assume any
+ risks associated with Your exercise of permissions under this License.
+
+ 8. Limitation of Liability. In no event and under no legal theory,
+ whether in tort (including negligence), contract, or otherwise,
+ unless required by applicable law (such as deliberate and grossly
+ negligent acts) or agreed to in writing, shall any Contributor be
+ liable to You for damages, including any direct, indirect, special,
+ incidental, or consequential damages of any character arising as a
+ result of this License or out of the use or inability to use the
+ Work (including but not limited to damages for loss of goodwill,
+ work stoppage, computer failure or malfunction, or any and all
+ other commercial damages or losses), even if such Contributor
+ has been advised of the possibility of such damages.
+
+ 9. Accepting Warranty or Additional Liability. While redistributing
+ the Work or Derivative Works thereof, You may choose to offer,
+ and charge a fee for, acceptance of support, warranty, indemnity,
+ or other liability obligations and/or rights consistent with this
+ License. However, in accepting such obligations, You may act only
+ on Your own behalf and on Your sole responsibility, not on behalf
+ of any other Contributor, and only if You agree to indemnify,
+ defend, and hold each Contributor harmless for any liability
+ incurred by, or claims asserted against, such Contributor by reason
+ of your accepting any such warranty or additional liability.
+
+ END OF TERMS AND CONDITIONS
+
+ APPENDIX: How to apply the Apache License to your work.
+
+ To apply the Apache License to your work, attach the following
+ boilerplate notice, with the fields enclosed by brackets "[]"
+ replaced with your own identifying information. (Don't include
+ the brackets!) The text should be enclosed in the appropriate
+ comment syntax for the file format. We also recommend that a
+ file or class name and description of purpose be included on the
+ same "printed page" as the copyright notice for easier
+ identification within third-party archives.
+
+ Copyright [yyyy] [name of copyright owner]
+
+ Licensed under the Apache License, Version 2.0 (the "License");
+ you may not use this file except in compliance with the License.
+ You may obtain a copy of the License at
+
+ http://www.apache.org/licenses/LICENSE-2.0
+
+ Unless required by applicable law or agreed to in writing, software
+ distributed under the License is distributed on an "AS IS" BASIS,
+ WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+ See the License for the specific language governing permissions and
+ limitations under the License.
+
+===========================================================================
+The common/types/pb/equal.go modification of proto.Equal logic
+===========================================================================
+Copyright (c) 2018 The Go Authors. All rights reserved.
+
+Redistribution and use in source and binary forms, with or without
+modification, are permitted provided that the following conditions are
+met:
+
+ * Redistributions of source code must retain the above copyright
+notice, this list of conditions and the following disclaimer.
+ * Redistributions in binary form must reproduce the above
+copyright notice, this list of conditions and the following disclaimer
+in the documentation and/or other materials provided with the
+distribution.
+ * Neither the name of Google Inc. nor the names of its
+contributors may be used to endorse or promote products derived from
+this software without specific prior written permission.
+
+THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
+"AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
+LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
+A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
+OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
+SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
+LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
+DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
+THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
+(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
+OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
diff --git a/vendor/github.com/google/cel-go/cel/BUILD.bazel b/vendor/github.com/google/cel-go/cel/BUILD.bazel
new file mode 100644
index 000000000000..cb0895f92a88
--- /dev/null
+++ b/vendor/github.com/google/cel-go/cel/BUILD.bazel
@@ -0,0 +1,52 @@
+load("@io_bazel_rules_go//go:def.bzl", "go_library")
+
+package(
+ licenses = ["notice"], # Apache 2.0
+)
+
+go_library(
+ name = "go_default_library",
+ srcs = [
+ "cel.go",
+ "decls.go",
+ "env.go",
+ "folding.go",
+ "inlining.go",
+ "io.go",
+ "library.go",
+ "macro.go",
+ "optimizer.go",
+ "options.go",
+ "program.go",
+ "validator.go",
+ ],
+ importmap = "kubevirt.io/kubevirt/vendor/github.com/google/cel-go/cel",
+ importpath = "github.com/google/cel-go/cel",
+ visibility = ["//visibility:public"],
+ deps = [
+ "//vendor/github.com/google/cel-go/checker:go_default_library",
+ "//vendor/github.com/google/cel-go/checker/decls:go_default_library",
+ "//vendor/github.com/google/cel-go/common:go_default_library",
+ "//vendor/github.com/google/cel-go/common/ast:go_default_library",
+ "//vendor/github.com/google/cel-go/common/containers:go_default_library",
+ "//vendor/github.com/google/cel-go/common/decls:go_default_library",
+ "//vendor/github.com/google/cel-go/common/functions:go_default_library",
+ "//vendor/github.com/google/cel-go/common/operators:go_default_library",
+ "//vendor/github.com/google/cel-go/common/overloads:go_default_library",
+ "//vendor/github.com/google/cel-go/common/stdlib:go_default_library",
+ "//vendor/github.com/google/cel-go/common/types:go_default_library",
+ "//vendor/github.com/google/cel-go/common/types/pb:go_default_library",
+ "//vendor/github.com/google/cel-go/common/types/ref:go_default_library",
+ "//vendor/github.com/google/cel-go/common/types/traits:go_default_library",
+ "//vendor/github.com/google/cel-go/interpreter:go_default_library",
+ "//vendor/github.com/google/cel-go/parser:go_default_library",
+ "//vendor/google.golang.org/genproto/googleapis/api/expr/v1alpha1:go_default_library",
+ "//vendor/google.golang.org/protobuf/proto:go_default_library",
+ "//vendor/google.golang.org/protobuf/reflect/protodesc:go_default_library",
+ "//vendor/google.golang.org/protobuf/reflect/protoreflect:go_default_library",
+ "//vendor/google.golang.org/protobuf/reflect/protoregistry:go_default_library",
+ "//vendor/google.golang.org/protobuf/types/descriptorpb:go_default_library",
+ "//vendor/google.golang.org/protobuf/types/dynamicpb:go_default_library",
+ "//vendor/google.golang.org/protobuf/types/known/anypb:go_default_library",
+ ],
+)
diff --git a/vendor/github.com/google/cel-go/cel/cel.go b/vendor/github.com/google/cel-go/cel/cel.go
new file mode 100644
index 000000000000..eb5a9f4cc520
--- /dev/null
+++ b/vendor/github.com/google/cel-go/cel/cel.go
@@ -0,0 +1,19 @@
+// Copyright 2019 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+// Package cel defines the top-level interface for the Common Expression Language (CEL).
+//
+// CEL is a non-Turing complete expression language designed to parse, check, and evaluate
+// expressions against user-defined environments.
+package cel
diff --git a/vendor/github.com/google/cel-go/cel/decls.go b/vendor/github.com/google/cel-go/cel/decls.go
new file mode 100644
index 000000000000..b59e3708de6a
--- /dev/null
+++ b/vendor/github.com/google/cel-go/cel/decls.go
@@ -0,0 +1,355 @@
+// Copyright 2022 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package cel
+
+import (
+ "fmt"
+
+ "github.com/google/cel-go/common/ast"
+ "github.com/google/cel-go/common/decls"
+ "github.com/google/cel-go/common/functions"
+ "github.com/google/cel-go/common/types"
+ "github.com/google/cel-go/common/types/ref"
+
+ exprpb "google.golang.org/genproto/googleapis/api/expr/v1alpha1"
+)
+
+// Kind indicates a CEL type's kind which is used to differentiate quickly between simple and complex types.
+type Kind = types.Kind
+
+const (
+ // DynKind represents a dynamic type. This kind only exists at type-check time.
+ DynKind Kind = types.DynKind
+
+ // AnyKind represents a google.protobuf.Any type. This kind only exists at type-check time.
+ AnyKind = types.AnyKind
+
+ // BoolKind represents a boolean type.
+ BoolKind = types.BoolKind
+
+ // BytesKind represents a bytes type.
+ BytesKind = types.BytesKind
+
+ // DoubleKind represents a double type.
+ DoubleKind = types.DoubleKind
+
+ // DurationKind represents a CEL duration type.
+ DurationKind = types.DurationKind
+
+ // IntKind represents an integer type.
+ IntKind = types.IntKind
+
+ // ListKind represents a list type.
+ ListKind = types.ListKind
+
+ // MapKind represents a map type.
+ MapKind = types.MapKind
+
+ // NullTypeKind represents a null type.
+ NullTypeKind = types.NullTypeKind
+
+ // OpaqueKind represents an abstract type which has no accessible fields.
+ OpaqueKind = types.OpaqueKind
+
+ // StringKind represents a string type.
+ StringKind = types.StringKind
+
+ // StructKind represents a structured object with typed fields.
+ StructKind = types.StructKind
+
+ // TimestampKind represents a a CEL time type.
+ TimestampKind = types.TimestampKind
+
+ // TypeKind represents the CEL type.
+ TypeKind = types.TypeKind
+
+ // TypeParamKind represents a parameterized type whose type name will be resolved at type-check time, if possible.
+ TypeParamKind = types.TypeParamKind
+
+ // UintKind represents a uint type.
+ UintKind = types.UintKind
+)
+
+var (
+ // AnyType represents the google.protobuf.Any type.
+ AnyType = types.AnyType
+ // BoolType represents the bool type.
+ BoolType = types.BoolType
+ // BytesType represents the bytes type.
+ BytesType = types.BytesType
+ // DoubleType represents the double type.
+ DoubleType = types.DoubleType
+ // DurationType represents the CEL duration type.
+ DurationType = types.DurationType
+ // DynType represents a dynamic CEL type whose type will be determined at runtime from context.
+ DynType = types.DynType
+ // IntType represents the int type.
+ IntType = types.IntType
+ // NullType represents the type of a null value.
+ NullType = types.NullType
+ // StringType represents the string type.
+ StringType = types.StringType
+ // TimestampType represents the time type.
+ TimestampType = types.TimestampType
+ // TypeType represents a CEL type
+ TypeType = types.TypeType
+ // UintType represents a uint type.
+ UintType = types.UintType
+
+ // function references for instantiating new types.
+
+ // ListType creates an instances of a list type value with the provided element type.
+ ListType = types.NewListType
+ // MapType creates an instance of a map type value with the provided key and value types.
+ MapType = types.NewMapType
+ // NullableType creates an instance of a nullable type with the provided wrapped type.
+ //
+ // Note: only primitive types are supported as wrapped types.
+ NullableType = types.NewNullableType
+ // OptionalType creates an abstract parameterized type instance corresponding to CEL's notion of optional.
+ OptionalType = types.NewOptionalType
+ // OpaqueType creates an abstract parameterized type with a given name.
+ OpaqueType = types.NewOpaqueType
+ // ObjectType creates a type references to an externally defined type, e.g. a protobuf message type.
+ ObjectType = types.NewObjectType
+ // TypeParamType creates a parameterized type instance.
+ TypeParamType = types.NewTypeParamType
+)
+
+// Type holds a reference to a runtime type with an optional type-checked set of type parameters.
+type Type = types.Type
+
+// Constant creates an instances of an identifier declaration with a variable name, type, and value.
+func Constant(name string, t *Type, v ref.Val) EnvOption {
+ return func(e *Env) (*Env, error) {
+ e.variables = append(e.variables, decls.NewConstant(name, t, v))
+ return e, nil
+ }
+}
+
+// Variable creates an instance of a variable declaration with a variable name and type.
+func Variable(name string, t *Type) EnvOption {
+ return func(e *Env) (*Env, error) {
+ e.variables = append(e.variables, decls.NewVariable(name, t))
+ return e, nil
+ }
+}
+
+// Function defines a function and overloads with optional singleton or per-overload bindings.
+//
+// Using Function is roughly equivalent to calling Declarations() to declare the function signatures
+// and Functions() to define the function bindings, if they have been defined. Specifying the
+// same function name more than once will result in the aggregation of the function overloads. If any
+// signatures conflict between the existing and new function definition an error will be raised.
+// However, if the signatures are identical and the overload ids are the same, the redefinition will
+// be considered a no-op.
+//
+// One key difference with using Function() is that each FunctionDecl provided will handle dynamic
+// dispatch based on the type-signatures of the overloads provided which means overload resolution at
+// runtime is handled out of the box rather than via a custom binding for overload resolution via
+// Functions():
+//
+// - Overloads are searched in the order they are declared
+// - Dynamic dispatch for lists and maps is limited by inspection of the list and map contents
+//
+// at runtime. Empty lists and maps will result in a 'default dispatch'
+//
+// - In the event that a default dispatch occurs, the first overload provided is the one invoked
+//
+// If you intend to use overloads which differentiate based on the key or element type of a list or
+// map, consider using a generic function instead: e.g. func(list(T)) or func(map(K, V)) as this
+// will allow your implementation to determine how best to handle dispatch and the default behavior
+// for empty lists and maps whose contents cannot be inspected.
+//
+// For functions which use parameterized opaque types (abstract types), consider using a singleton
+// function which is capable of inspecting the contents of the type and resolving the appropriate
+// overload as CEL can only make inferences by type-name regarding such types.
+func Function(name string, opts ...FunctionOpt) EnvOption {
+ return func(e *Env) (*Env, error) {
+ fn, err := decls.NewFunction(name, opts...)
+ if err != nil {
+ return nil, err
+ }
+ if existing, found := e.functions[fn.Name()]; found {
+ fn, err = existing.Merge(fn)
+ if err != nil {
+ return nil, err
+ }
+ }
+ e.functions[fn.Name()] = fn
+ return e, nil
+ }
+}
+
+// FunctionOpt defines a functional option for configuring a function declaration.
+type FunctionOpt = decls.FunctionOpt
+
+// SingletonUnaryBinding creates a singleton function definition to be used for all function overloads.
+//
+// Note, this approach works well if operand is expected to have a specific trait which it implements,
+// e.g. traits.ContainerType. Otherwise, prefer per-overload function bindings.
+func SingletonUnaryBinding(fn functions.UnaryOp, traits ...int) FunctionOpt {
+ return decls.SingletonUnaryBinding(fn, traits...)
+}
+
+// SingletonBinaryImpl creates a singleton function definition to be used with all function overloads.
+//
+// Note, this approach works well if operand is expected to have a specific trait which it implements,
+// e.g. traits.ContainerType. Otherwise, prefer per-overload function bindings.
+//
+// Deprecated: use SingletonBinaryBinding
+func SingletonBinaryImpl(fn functions.BinaryOp, traits ...int) FunctionOpt {
+ return decls.SingletonBinaryBinding(fn, traits...)
+}
+
+// SingletonBinaryBinding creates a singleton function definition to be used with all function overloads.
+//
+// Note, this approach works well if operand is expected to have a specific trait which it implements,
+// e.g. traits.ContainerType. Otherwise, prefer per-overload function bindings.
+func SingletonBinaryBinding(fn functions.BinaryOp, traits ...int) FunctionOpt {
+ return decls.SingletonBinaryBinding(fn, traits...)
+}
+
+// SingletonFunctionImpl creates a singleton function definition to be used with all function overloads.
+//
+// Note, this approach works well if operand is expected to have a specific trait which it implements,
+// e.g. traits.ContainerType. Otherwise, prefer per-overload function bindings.
+//
+// Deprecated: use SingletonFunctionBinding
+func SingletonFunctionImpl(fn functions.FunctionOp, traits ...int) FunctionOpt {
+ return decls.SingletonFunctionBinding(fn, traits...)
+}
+
+// SingletonFunctionBinding creates a singleton function definition to be used with all function overloads.
+//
+// Note, this approach works well if operand is expected to have a specific trait which it implements,
+// e.g. traits.ContainerType. Otherwise, prefer per-overload function bindings.
+func SingletonFunctionBinding(fn functions.FunctionOp, traits ...int) FunctionOpt {
+ return decls.SingletonFunctionBinding(fn, traits...)
+}
+
+// DisableDeclaration disables the function signatures, effectively removing them from the type-check
+// environment while preserving the runtime bindings.
+func DisableDeclaration(value bool) FunctionOpt {
+ return decls.DisableDeclaration(value)
+}
+
+// Overload defines a new global overload with an overload id, argument types, and result type. Through the
+// use of OverloadOpt options, the overload may also be configured with a binding, an operand trait, and to
+// be non-strict.
+//
+// Note: function bindings should be commonly configured with Overload instances whereas operand traits and
+// strict-ness should be rare occurrences.
+func Overload(overloadID string, args []*Type, resultType *Type, opts ...OverloadOpt) FunctionOpt {
+ return decls.Overload(overloadID, args, resultType, opts...)
+}
+
+// MemberOverload defines a new receiver-style overload (or member function) with an overload id, argument types,
+// and result type. Through the use of OverloadOpt options, the overload may also be configured with a binding,
+// an operand trait, and to be non-strict.
+//
+// Note: function bindings should be commonly configured with Overload instances whereas operand traits and
+// strict-ness should be rare occurrences.
+func MemberOverload(overloadID string, args []*Type, resultType *Type, opts ...OverloadOpt) FunctionOpt {
+ return decls.MemberOverload(overloadID, args, resultType, opts...)
+}
+
+// OverloadOpt is a functional option for configuring a function overload.
+type OverloadOpt = decls.OverloadOpt
+
+// UnaryBinding provides the implementation of a unary overload. The provided function is protected by a runtime
+// type-guard which ensures runtime type agreement between the overload signature and runtime argument types.
+func UnaryBinding(binding functions.UnaryOp) OverloadOpt {
+ return decls.UnaryBinding(binding)
+}
+
+// BinaryBinding provides the implementation of a binary overload. The provided function is protected by a runtime
+// type-guard which ensures runtime type agreement between the overload signature and runtime argument types.
+func BinaryBinding(binding functions.BinaryOp) OverloadOpt {
+ return decls.BinaryBinding(binding)
+}
+
+// FunctionBinding provides the implementation of a variadic overload. The provided function is protected by a runtime
+// type-guard which ensures runtime type agreement between the overload signature and runtime argument types.
+func FunctionBinding(binding functions.FunctionOp) OverloadOpt {
+ return decls.FunctionBinding(binding)
+}
+
+// OverloadIsNonStrict enables the function to be called with error and unknown argument values.
+//
+// Note: do not use this option unless absoluately necessary as it should be an uncommon feature.
+func OverloadIsNonStrict() OverloadOpt {
+ return decls.OverloadIsNonStrict()
+}
+
+// OverloadOperandTrait configures a set of traits which the first argument to the overload must implement in order to be
+// successfully invoked.
+func OverloadOperandTrait(trait int) OverloadOpt {
+ return decls.OverloadOperandTrait(trait)
+}
+
+// TypeToExprType converts a CEL-native type representation to a protobuf CEL Type representation.
+func TypeToExprType(t *Type) (*exprpb.Type, error) {
+ return types.TypeToExprType(t)
+}
+
+// ExprTypeToType converts a protobuf CEL type representation to a CEL-native type representation.
+func ExprTypeToType(t *exprpb.Type) (*Type, error) {
+ return types.ExprTypeToType(t)
+}
+
+// ExprDeclToDeclaration converts a protobuf CEL declaration to a CEL-native declaration, either a Variable or Function.
+func ExprDeclToDeclaration(d *exprpb.Decl) (EnvOption, error) {
+ switch d.GetDeclKind().(type) {
+ case *exprpb.Decl_Function:
+ overloads := d.GetFunction().GetOverloads()
+ opts := make([]FunctionOpt, len(overloads))
+ for i, o := range overloads {
+ args := make([]*Type, len(o.GetParams()))
+ for j, p := range o.GetParams() {
+ a, err := types.ExprTypeToType(p)
+ if err != nil {
+ return nil, err
+ }
+ args[j] = a
+ }
+ res, err := types.ExprTypeToType(o.GetResultType())
+ if err != nil {
+ return nil, err
+ }
+ if o.IsInstanceFunction {
+ opts[i] = decls.MemberOverload(o.GetOverloadId(), args, res)
+ } else {
+ opts[i] = decls.Overload(o.GetOverloadId(), args, res)
+ }
+ }
+ return Function(d.GetName(), opts...), nil
+ case *exprpb.Decl_Ident:
+ t, err := types.ExprTypeToType(d.GetIdent().GetType())
+ if err != nil {
+ return nil, err
+ }
+ if d.GetIdent().GetValue() == nil {
+ return Variable(d.GetName(), t), nil
+ }
+ val, err := ast.ConstantToVal(d.GetIdent().GetValue())
+ if err != nil {
+ return nil, err
+ }
+ return Constant(d.GetName(), t, val), nil
+ default:
+ return nil, fmt.Errorf("unsupported decl: %v", d)
+ }
+}
diff --git a/vendor/github.com/google/cel-go/cel/env.go b/vendor/github.com/google/cel-go/cel/env.go
new file mode 100644
index 000000000000..a8650c4e9fd4
--- /dev/null
+++ b/vendor/github.com/google/cel-go/cel/env.go
@@ -0,0 +1,888 @@
+// Copyright 2019 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package cel
+
+import (
+ "errors"
+ "sync"
+
+ "github.com/google/cel-go/checker"
+ chkdecls "github.com/google/cel-go/checker/decls"
+ "github.com/google/cel-go/common"
+ celast "github.com/google/cel-go/common/ast"
+ "github.com/google/cel-go/common/containers"
+ "github.com/google/cel-go/common/decls"
+ "github.com/google/cel-go/common/types"
+ "github.com/google/cel-go/common/types/ref"
+ "github.com/google/cel-go/interpreter"
+ "github.com/google/cel-go/parser"
+
+ exprpb "google.golang.org/genproto/googleapis/api/expr/v1alpha1"
+)
+
+// Source interface representing a user-provided expression.
+type Source = common.Source
+
+// Ast representing the checked or unchecked expression, its source, and related metadata such as
+// source position information.
+type Ast struct {
+ source Source
+ impl *celast.AST
+}
+
+// NativeRep converts the AST to a Go-native representation.
+func (ast *Ast) NativeRep() *celast.AST {
+ if ast == nil {
+ return nil
+ }
+ return ast.impl
+}
+
+// Expr returns the proto serializable instance of the parsed/checked expression.
+//
+// Deprecated: prefer cel.AstToCheckedExpr() or cel.AstToParsedExpr() and call GetExpr()
+// the result instead.
+func (ast *Ast) Expr() *exprpb.Expr {
+ if ast == nil {
+ return nil
+ }
+ pbExpr, _ := celast.ExprToProto(ast.NativeRep().Expr())
+ return pbExpr
+}
+
+// IsChecked returns whether the Ast value has been successfully type-checked.
+func (ast *Ast) IsChecked() bool {
+ return ast.NativeRep().IsChecked()
+}
+
+// SourceInfo returns character offset and newline position information about expression elements.
+func (ast *Ast) SourceInfo() *exprpb.SourceInfo {
+ if ast == nil {
+ return nil
+ }
+ pbInfo, _ := celast.SourceInfoToProto(ast.NativeRep().SourceInfo())
+ return pbInfo
+}
+
+// ResultType returns the output type of the expression if the Ast has been type-checked, else
+// returns chkdecls.Dyn as the parse step cannot infer the type.
+//
+// Deprecated: use OutputType
+func (ast *Ast) ResultType() *exprpb.Type {
+ out := ast.OutputType()
+ t, err := TypeToExprType(out)
+ if err != nil {
+ return chkdecls.Dyn
+ }
+ return t
+}
+
+// OutputType returns the output type of the expression if the Ast has been type-checked, else
+// returns cel.DynType as the parse step cannot infer types.
+func (ast *Ast) OutputType() *Type {
+ if ast == nil {
+ return types.ErrorType
+ }
+ return ast.NativeRep().GetType(ast.NativeRep().Expr().ID())
+}
+
+// Source returns a view of the input used to create the Ast. This source may be complete or
+// constructed from the SourceInfo.
+func (ast *Ast) Source() Source {
+ if ast == nil {
+ return nil
+ }
+ return ast.source
+}
+
+// FormatType converts a type message into a string representation.
+//
+// Deprecated: prefer FormatCELType
+func FormatType(t *exprpb.Type) string {
+ return checker.FormatCheckedType(t)
+}
+
+// FormatCELType formats a cel.Type value to a string representation.
+//
+// The type formatting is identical to FormatType.
+func FormatCELType(t *Type) string {
+ return checker.FormatCELType(t)
+}
+
+// Env encapsulates the context necessary to perform parsing, type checking, or generation of
+// evaluable programs for different expressions.
+type Env struct {
+ Container *containers.Container
+ variables []*decls.VariableDecl
+ functions map[string]*decls.FunctionDecl
+ macros []parser.Macro
+ adapter types.Adapter
+ provider types.Provider
+ features map[int]bool
+ appliedFeatures map[int]bool
+ libraries map[string]bool
+ validators []ASTValidator
+ costOptions []checker.CostOption
+
+ // Internal parser representation
+ prsr *parser.Parser
+ prsrOpts []parser.Option
+
+ // Internal checker representation
+ chkMutex sync.Mutex
+ chk *checker.Env
+ chkErr error
+ chkOnce sync.Once
+ chkOpts []checker.Option
+
+ // Program options tied to the environment
+ progOpts []ProgramOption
+}
+
+// NewEnv creates a program environment configured with the standard library of CEL functions and
+// macros. The Env value returned can parse and check any CEL program which builds upon the core
+// features documented in the CEL specification.
+//
+// See the EnvOption helper functions for the options that can be used to configure the
+// environment.
+func NewEnv(opts ...EnvOption) (*Env, error) {
+ // Extend the statically configured standard environment, disabling eager validation to ensure
+ // the cost of setup for the environment is still just as cheap as it is in v0.11.x and earlier
+ // releases. The user provided options can easily re-enable the eager validation as they are
+ // processed after this default option.
+ stdOpts := append([]EnvOption{EagerlyValidateDeclarations(false)}, opts...)
+ env, err := getStdEnv()
+ if err != nil {
+ return nil, err
+ }
+ return env.Extend(stdOpts...)
+}
+
+// NewCustomEnv creates a custom program environment which is not automatically configured with the
+// standard library of functions and macros documented in the CEL spec.
+//
+// The purpose for using a custom environment might be for subsetting the standard library produced
+// by the cel.StdLib() function. Subsetting CEL is a core aspect of its design that allows users to
+// limit the compute and memory impact of a CEL program by controlling the functions and macros
+// that may appear in a given expression.
+//
+// See the EnvOption helper functions for the options that can be used to configure the
+// environment.
+func NewCustomEnv(opts ...EnvOption) (*Env, error) {
+ registry, err := types.NewRegistry()
+ if err != nil {
+ return nil, err
+ }
+ return (&Env{
+ variables: []*decls.VariableDecl{},
+ functions: map[string]*decls.FunctionDecl{},
+ macros: []parser.Macro{},
+ Container: containers.DefaultContainer,
+ adapter: registry,
+ provider: registry,
+ features: map[int]bool{},
+ appliedFeatures: map[int]bool{},
+ libraries: map[string]bool{},
+ validators: []ASTValidator{},
+ progOpts: []ProgramOption{},
+ costOptions: []checker.CostOption{},
+ }).configure(opts)
+}
+
+// Check performs type-checking on the input Ast and yields a checked Ast and/or set of Issues.
+// If any `ASTValidators` are configured on the environment, they will be applied after a valid
+// type-check result. If any issues are detected, the validators will provide them on the
+// output Issues object.
+//
+// Either checking or validation has failed if the returned Issues value and its Issues.Err()
+// value are non-nil. Issues should be inspected if they are non-nil, but may not represent a
+// fatal error.
+//
+// It is possible to have both non-nil Ast and Issues values returned from this call: however,
+// the mere presence of an Ast does not imply that it is valid for use.
+func (e *Env) Check(ast *Ast) (*Ast, *Issues) {
+ // Construct the internal checker env, erroring if there is an issue adding the declarations.
+ chk, err := e.initChecker()
+ if err != nil {
+ errs := common.NewErrors(ast.Source())
+ errs.ReportError(common.NoLocation, err.Error())
+ return nil, NewIssuesWithSourceInfo(errs, ast.NativeRep().SourceInfo())
+ }
+
+ checked, errs := checker.Check(ast.NativeRep(), ast.Source(), chk)
+ if len(errs.GetErrors()) > 0 {
+ return nil, NewIssuesWithSourceInfo(errs, ast.NativeRep().SourceInfo())
+ }
+ // Manually create the Ast to ensure that the Ast source information (which may be more
+ // detailed than the information provided by Check), is returned to the caller.
+ ast = &Ast{
+ source: ast.Source(),
+ impl: checked}
+
+ // Avoid creating a validator config if it's not needed.
+ if len(e.validators) == 0 {
+ return ast, nil
+ }
+
+ // Generate a validator configuration from the set of configured validators.
+ vConfig := newValidatorConfig()
+ for _, v := range e.validators {
+ if cv, ok := v.(ASTValidatorConfigurer); ok {
+ cv.Configure(vConfig)
+ }
+ }
+ // Apply additional validators on the type-checked result.
+ iss := NewIssuesWithSourceInfo(errs, ast.NativeRep().SourceInfo())
+ for _, v := range e.validators {
+ v.Validate(e, vConfig, checked, iss)
+ }
+ if iss.Err() != nil {
+ return nil, iss
+ }
+ return ast, nil
+}
+
+// Compile combines the Parse and Check phases CEL program compilation to produce an Ast and
+// associated issues.
+//
+// If an error is encountered during parsing the Compile step will not continue with the Check
+// phase. If non-error issues are encountered during Parse, they may be combined with any issues
+// discovered during Check.
+//
+// Note, for parse-only uses of CEL use Parse.
+func (e *Env) Compile(txt string) (*Ast, *Issues) {
+ return e.CompileSource(common.NewTextSource(txt))
+}
+
+// CompileSource combines the Parse and Check phases CEL program compilation to produce an Ast and
+// associated issues.
+//
+// If an error is encountered during parsing the CompileSource step will not continue with the
+// Check phase. If non-error issues are encountered during Parse, they may be combined with any
+// issues discovered during Check.
+//
+// Note, for parse-only uses of CEL use Parse.
+func (e *Env) CompileSource(src Source) (*Ast, *Issues) {
+ ast, iss := e.ParseSource(src)
+ if iss.Err() != nil {
+ return nil, iss
+ }
+ checked, iss2 := e.Check(ast)
+ if iss2.Err() != nil {
+ return nil, iss2
+ }
+ return checked, iss2
+}
+
+// Extend the current environment with additional options to produce a new Env.
+//
+// Note, the extended Env value should not share memory with the original. It is possible, however,
+// that a CustomTypeAdapter or CustomTypeProvider options could provide values which are mutable.
+// To ensure separation of state between extended environments either make sure the TypeAdapter and
+// TypeProvider are immutable, or that their underlying implementations are based on the
+// ref.TypeRegistry which provides a Copy method which will be invoked by this method.
+func (e *Env) Extend(opts ...EnvOption) (*Env, error) {
+ chk, chkErr := e.getCheckerOrError()
+ if chkErr != nil {
+ return nil, chkErr
+ }
+
+ prsrOptsCopy := make([]parser.Option, len(e.prsrOpts))
+ copy(prsrOptsCopy, e.prsrOpts)
+
+ // The type-checker is configured with Declarations. The declarations may either be provided
+ // as options which have not yet been validated, or may come from a previous checker instance
+ // whose types have already been validated.
+ chkOptsCopy := make([]checker.Option, len(e.chkOpts))
+ copy(chkOptsCopy, e.chkOpts)
+
+ // Copy the declarations if needed.
+ if chk != nil {
+ // If the type-checker has already been instantiated, then the e.declarations have been
+ // validated within the chk instance.
+ chkOptsCopy = append(chkOptsCopy, checker.ValidatedDeclarations(chk))
+ }
+ varsCopy := make([]*decls.VariableDecl, len(e.variables))
+ copy(varsCopy, e.variables)
+
+ // Copy macros and program options
+ macsCopy := make([]parser.Macro, len(e.macros))
+ progOptsCopy := make([]ProgramOption, len(e.progOpts))
+ copy(macsCopy, e.macros)
+ copy(progOptsCopy, e.progOpts)
+
+ // Copy the adapter / provider if they appear to be mutable.
+ adapter := e.adapter
+ provider := e.provider
+ adapterReg, isAdapterReg := e.adapter.(*types.Registry)
+ providerReg, isProviderReg := e.provider.(*types.Registry)
+ // In most cases the provider and adapter will be a ref.TypeRegistry;
+ // however, in the rare cases where they are not, they are assumed to
+ // be immutable. Since it is possible to set the TypeProvider separately
+ // from the TypeAdapter, the possible configurations which could use a
+ // TypeRegistry as the base implementation are captured below.
+ if isAdapterReg && isProviderReg {
+ reg := providerReg.Copy()
+ provider = reg
+ // If the adapter and provider are the same object, set the adapter
+ // to the same ref.TypeRegistry as the provider.
+ if adapterReg == providerReg {
+ adapter = reg
+ } else {
+ // Otherwise, make a copy of the adapter.
+ adapter = adapterReg.Copy()
+ }
+ } else if isProviderReg {
+ provider = providerReg.Copy()
+ } else if isAdapterReg {
+ adapter = adapterReg.Copy()
+ }
+
+ featuresCopy := make(map[int]bool, len(e.features))
+ for k, v := range e.features {
+ featuresCopy[k] = v
+ }
+ appliedFeaturesCopy := make(map[int]bool, len(e.appliedFeatures))
+ for k, v := range e.appliedFeatures {
+ appliedFeaturesCopy[k] = v
+ }
+ funcsCopy := make(map[string]*decls.FunctionDecl, len(e.functions))
+ for k, v := range e.functions {
+ funcsCopy[k] = v
+ }
+ libsCopy := make(map[string]bool, len(e.libraries))
+ for k, v := range e.libraries {
+ libsCopy[k] = v
+ }
+ validatorsCopy := make([]ASTValidator, len(e.validators))
+ copy(validatorsCopy, e.validators)
+ costOptsCopy := make([]checker.CostOption, len(e.costOptions))
+ copy(costOptsCopy, e.costOptions)
+
+ ext := &Env{
+ Container: e.Container,
+ variables: varsCopy,
+ functions: funcsCopy,
+ macros: macsCopy,
+ progOpts: progOptsCopy,
+ adapter: adapter,
+ features: featuresCopy,
+ appliedFeatures: appliedFeaturesCopy,
+ libraries: libsCopy,
+ validators: validatorsCopy,
+ provider: provider,
+ chkOpts: chkOptsCopy,
+ prsrOpts: prsrOptsCopy,
+ costOptions: costOptsCopy,
+ }
+ return ext.configure(opts)
+}
+
+// HasFeature checks whether the environment enables the given feature
+// flag, as enumerated in options.go.
+func (e *Env) HasFeature(flag int) bool {
+ enabled, has := e.features[flag]
+ return has && enabled
+}
+
+// HasLibrary returns whether a specific SingletonLibrary has been configured in the environment.
+func (e *Env) HasLibrary(libName string) bool {
+ configured, exists := e.libraries[libName]
+ return exists && configured
+}
+
+// Libraries returns a list of SingletonLibrary that have been configured in the environment.
+func (e *Env) Libraries() []string {
+ libraries := make([]string, 0, len(e.libraries))
+ for libName := range e.libraries {
+ libraries = append(libraries, libName)
+ }
+ return libraries
+}
+
+// HasFunction returns whether a specific function has been configured in the environment
+func (e *Env) HasFunction(functionName string) bool {
+ _, ok := e.functions[functionName]
+ return ok
+}
+
+// Functions returns map of Functions, keyed by function name, that have been configured in the environment.
+func (e *Env) Functions() map[string]*decls.FunctionDecl {
+ return e.functions
+}
+
+// HasValidator returns whether a specific ASTValidator has been configured in the environment.
+func (e *Env) HasValidator(name string) bool {
+ for _, v := range e.validators {
+ if v.Name() == name {
+ return true
+ }
+ }
+ return false
+}
+
+// Parse parses the input expression value `txt` to a Ast and/or a set of Issues.
+//
+// This form of Parse creates a Source value for the input `txt` and forwards to the
+// ParseSource method.
+func (e *Env) Parse(txt string) (*Ast, *Issues) {
+ src := common.NewTextSource(txt)
+ return e.ParseSource(src)
+}
+
+// ParseSource parses the input source to an Ast and/or set of Issues.
+//
+// Parsing has failed if the returned Issues value and its Issues.Err() value is non-nil.
+// Issues should be inspected if they are non-nil, but may not represent a fatal error.
+//
+// It is possible to have both non-nil Ast and Issues values returned from this call; however,
+// the mere presence of an Ast does not imply that it is valid for use.
+func (e *Env) ParseSource(src Source) (*Ast, *Issues) {
+ parsed, errs := e.prsr.Parse(src)
+ if len(errs.GetErrors()) > 0 {
+ return nil, &Issues{errs: errs}
+ }
+ return &Ast{source: src, impl: parsed}, nil
+}
+
+// Program generates an evaluable instance of the Ast within the environment (Env).
+func (e *Env) Program(ast *Ast, opts ...ProgramOption) (Program, error) {
+ optSet := e.progOpts
+ if len(opts) != 0 {
+ mergedOpts := []ProgramOption{}
+ mergedOpts = append(mergedOpts, e.progOpts...)
+ mergedOpts = append(mergedOpts, opts...)
+ optSet = mergedOpts
+ }
+ return newProgram(e, ast, optSet)
+}
+
+// CELTypeAdapter returns the `types.Adapter` configured for the environment.
+func (e *Env) CELTypeAdapter() types.Adapter {
+ return e.adapter
+}
+
+// CELTypeProvider returns the `types.Provider` configured for the environment.
+func (e *Env) CELTypeProvider() types.Provider {
+ return e.provider
+}
+
+// TypeAdapter returns the `ref.TypeAdapter` configured for the environment.
+//
+// Deprecated: use CELTypeAdapter()
+func (e *Env) TypeAdapter() ref.TypeAdapter {
+ return e.adapter
+}
+
+// TypeProvider returns the `ref.TypeProvider` configured for the environment.
+//
+// Deprecated: use CELTypeProvider()
+func (e *Env) TypeProvider() ref.TypeProvider {
+ if legacyProvider, ok := e.provider.(ref.TypeProvider); ok {
+ return legacyProvider
+ }
+ return &interopLegacyTypeProvider{Provider: e.provider}
+}
+
+// UnknownVars returns an interpreter.PartialActivation which marks all variables declared in the
+// Env as unknown AttributePattern values.
+//
+// Note, the UnknownVars will behave the same as an interpreter.EmptyActivation unless the
+// PartialAttributes option is provided as a ProgramOption.
+func (e *Env) UnknownVars() interpreter.PartialActivation {
+ act := interpreter.EmptyActivation()
+ part, _ := PartialVars(act, e.computeUnknownVars(act)...)
+ return part
+}
+
+// PartialVars returns an interpreter.PartialActivation where all variables not in the input variable
+// set, but which have been configured in the environment, are marked as unknown.
+//
+// The `vars` value may either be an interpreter.Activation or any valid input to the
+// interpreter.NewActivation call.
+//
+// Note, this is equivalent to calling cel.PartialVars and manually configuring the set of unknown
+// variables. For more advanced use cases of partial state where portions of an object graph, rather
+// than top-level variables, are missing the PartialVars() method may be a more suitable choice.
+//
+// Note, the PartialVars will behave the same as an interpreter.EmptyActivation unless the
+// PartialAttributes option is provided as a ProgramOption.
+func (e *Env) PartialVars(vars any) (interpreter.PartialActivation, error) {
+ act, err := interpreter.NewActivation(vars)
+ if err != nil {
+ return nil, err
+ }
+ return PartialVars(act, e.computeUnknownVars(act)...)
+}
+
+// ResidualAst takes an Ast and its EvalDetails to produce a new Ast which only contains the
+// attribute references which are unknown.
+//
+// Residual expressions are beneficial in a few scenarios:
+//
+// - Optimizing constant expression evaluations away.
+// - Indexing and pruning expressions based on known input arguments.
+// - Surfacing additional requirements that are needed in order to complete an evaluation.
+// - Sharing the evaluation of an expression across multiple machines/nodes.
+//
+// For example, if an expression targets a 'resource' and 'request' attribute and the possible
+// values for the resource are known, a PartialActivation could mark the 'request' as an unknown
+// interpreter.AttributePattern and the resulting ResidualAst would be reduced to only the parts
+// of the expression that reference the 'request'.
+//
+// Note, the expression ids within the residual AST generated through this method have no
+// correlation to the expression ids of the original AST.
+//
+// See the PartialVars helper for how to construct a PartialActivation.
+//
+// TODO: Consider adding an option to generate a Program.Residual to avoid round-tripping to an
+// Ast format and then Program again.
+func (e *Env) ResidualAst(a *Ast, details *EvalDetails) (*Ast, error) {
+ pruned := interpreter.PruneAst(a.impl.Expr(), a.impl.SourceInfo().MacroCalls(), details.State())
+ newAST := &Ast{source: a.Source(), impl: pruned}
+ expr, err := AstToString(newAST)
+ if err != nil {
+ return nil, err
+ }
+ parsed, iss := e.Parse(expr)
+ if iss != nil && iss.Err() != nil {
+ return nil, iss.Err()
+ }
+ if !a.IsChecked() {
+ return parsed, nil
+ }
+ checked, iss := e.Check(parsed)
+ if iss != nil && iss.Err() != nil {
+ return nil, iss.Err()
+ }
+ return checked, nil
+}
+
+// EstimateCost estimates the cost of a type checked CEL expression using the length estimates of input data and
+// extension functions provided by estimator.
+func (e *Env) EstimateCost(ast *Ast, estimator checker.CostEstimator, opts ...checker.CostOption) (checker.CostEstimate, error) {
+ extendedOpts := make([]checker.CostOption, 0, len(e.costOptions))
+ extendedOpts = append(extendedOpts, opts...)
+ extendedOpts = append(extendedOpts, e.costOptions...)
+ return checker.Cost(ast.impl, estimator, extendedOpts...)
+}
+
+// configure applies a series of EnvOptions to the current environment.
+func (e *Env) configure(opts []EnvOption) (*Env, error) {
+ // Customized the environment using the provided EnvOption values. If an error is
+ // generated at any step this, will be returned as a nil Env with a non-nil error.
+ var err error
+ for _, opt := range opts {
+ e, err = opt(e)
+ if err != nil {
+ return nil, err
+ }
+ }
+
+ // If the default UTC timezone fix has been enabled, make sure the library is configured
+ e, err = e.maybeApplyFeature(featureDefaultUTCTimeZone, Lib(timeUTCLibrary{}))
+ if err != nil {
+ return nil, err
+ }
+
+ // Configure the parser.
+ prsrOpts := []parser.Option{}
+ prsrOpts = append(prsrOpts, e.prsrOpts...)
+ prsrOpts = append(prsrOpts, parser.Macros(e.macros...))
+
+ if e.HasFeature(featureEnableMacroCallTracking) {
+ prsrOpts = append(prsrOpts, parser.PopulateMacroCalls(true))
+ }
+ if e.HasFeature(featureVariadicLogicalASTs) {
+ prsrOpts = append(prsrOpts, parser.EnableVariadicOperatorASTs(true))
+ }
+ e.prsr, err = parser.NewParser(prsrOpts...)
+ if err != nil {
+ return nil, err
+ }
+
+ // Ensure that the checker init happens eagerly rather than lazily.
+ if e.HasFeature(featureEagerlyValidateDeclarations) {
+ _, err := e.initChecker()
+ if err != nil {
+ return nil, err
+ }
+ }
+
+ return e, nil
+}
+
+func (e *Env) initChecker() (*checker.Env, error) {
+ e.chkOnce.Do(func() {
+ chkOpts := []checker.Option{}
+ chkOpts = append(chkOpts, e.chkOpts...)
+ chkOpts = append(chkOpts,
+ checker.CrossTypeNumericComparisons(
+ e.HasFeature(featureCrossTypeNumericComparisons)))
+
+ ce, err := checker.NewEnv(e.Container, e.provider, chkOpts...)
+ if err != nil {
+ e.setCheckerOrError(nil, err)
+ return
+ }
+ // Add the statically configured declarations.
+ err = ce.AddIdents(e.variables...)
+ if err != nil {
+ e.setCheckerOrError(nil, err)
+ return
+ }
+ // Add the function declarations which are derived from the FunctionDecl instances.
+ for _, fn := range e.functions {
+ if fn.IsDeclarationDisabled() {
+ continue
+ }
+ err = ce.AddFunctions(fn)
+ if err != nil {
+ e.setCheckerOrError(nil, err)
+ return
+ }
+ }
+ // Add function declarations here separately.
+ e.setCheckerOrError(ce, nil)
+ })
+ return e.getCheckerOrError()
+}
+
+// setCheckerOrError sets the checker.Env or error state in a concurrency-safe manner
+func (e *Env) setCheckerOrError(chk *checker.Env, chkErr error) {
+ e.chkMutex.Lock()
+ e.chk = chk
+ e.chkErr = chkErr
+ e.chkMutex.Unlock()
+}
+
+// getCheckerOrError gets the checker.Env or error state in a concurrency-safe manner
+func (e *Env) getCheckerOrError() (*checker.Env, error) {
+ e.chkMutex.Lock()
+ defer e.chkMutex.Unlock()
+ return e.chk, e.chkErr
+}
+
+// maybeApplyFeature determines whether the feature-guarded option is enabled, and if so applies
+// the feature if it has not already been enabled.
+func (e *Env) maybeApplyFeature(feature int, option EnvOption) (*Env, error) {
+ if !e.HasFeature(feature) {
+ return e, nil
+ }
+ _, applied := e.appliedFeatures[feature]
+ if applied {
+ return e, nil
+ }
+ e, err := option(e)
+ if err != nil {
+ return nil, err
+ }
+ // record that the feature has been applied since it will generate declarations
+ // and functions which will be propagated on Extend() calls and which should only
+ // be registered once.
+ e.appliedFeatures[feature] = true
+ return e, nil
+}
+
+// computeUnknownVars determines a set of missing variables based on the input activation and the
+// environment's configured declaration set.
+func (e *Env) computeUnknownVars(vars interpreter.Activation) []*interpreter.AttributePattern {
+ var unknownPatterns []*interpreter.AttributePattern
+ for _, v := range e.variables {
+ varName := v.Name()
+ if _, found := vars.ResolveName(varName); found {
+ continue
+ }
+ unknownPatterns = append(unknownPatterns, interpreter.NewAttributePattern(varName))
+ }
+ return unknownPatterns
+}
+
+// Error type which references an expression id, a location within source, and a message.
+type Error = common.Error
+
+// Issues defines methods for inspecting the error details of parse and check calls.
+//
+// Note: in the future, non-fatal warnings and notices may be inspectable via the Issues struct.
+type Issues struct {
+ errs *common.Errors
+ info *celast.SourceInfo
+}
+
+// NewIssues returns an Issues struct from a common.Errors object.
+func NewIssues(errs *common.Errors) *Issues {
+ return NewIssuesWithSourceInfo(errs, nil)
+}
+
+// NewIssuesWithSourceInfo returns an Issues struct from a common.Errors object with SourceInfo metatata
+// which can be used with the `ReportErrorAtID` method for additional error reports within the context
+// information that's inferred from an expression id.
+func NewIssuesWithSourceInfo(errs *common.Errors, info *celast.SourceInfo) *Issues {
+ return &Issues{
+ errs: errs,
+ info: info,
+ }
+}
+
+// Err returns an error value if the issues list contains one or more errors.
+func (i *Issues) Err() error {
+ if i == nil {
+ return nil
+ }
+ if len(i.Errors()) > 0 {
+ return errors.New(i.String())
+ }
+ return nil
+}
+
+// Errors returns the collection of errors encountered in more granular detail.
+func (i *Issues) Errors() []*Error {
+ if i == nil {
+ return []*Error{}
+ }
+ return i.errs.GetErrors()
+}
+
+// Append collects the issues from another Issues struct into a new Issues object.
+func (i *Issues) Append(other *Issues) *Issues {
+ if i == nil {
+ return other
+ }
+ if other == nil || i == other {
+ return i
+ }
+ return NewIssuesWithSourceInfo(i.errs.Append(other.errs.GetErrors()), i.info)
+}
+
+// String converts the issues to a suitable display string.
+func (i *Issues) String() string {
+ if i == nil {
+ return ""
+ }
+ return i.errs.ToDisplayString()
+}
+
+// ReportErrorAtID reports an error message with an optional set of formatting arguments.
+//
+// The source metadata for the expression at `id`, if present, is attached to the error report.
+// To ensure that source metadata is attached to error reports, use NewIssuesWithSourceInfo.
+func (i *Issues) ReportErrorAtID(id int64, message string, args ...any) {
+ i.errs.ReportErrorAtID(id, i.info.GetStartLocation(id), message, args...)
+}
+
+// getStdEnv lazy initializes the CEL standard environment.
+func getStdEnv() (*Env, error) {
+ stdEnvInit.Do(func() {
+ stdEnv, stdEnvErr = NewCustomEnv(StdLib(), EagerlyValidateDeclarations(true))
+ })
+ return stdEnv, stdEnvErr
+}
+
+// interopCELTypeProvider layers support for the types.Provider interface on top of a ref.TypeProvider.
+type interopCELTypeProvider struct {
+ ref.TypeProvider
+}
+
+// FindStructType returns a types.Type instance for the given fully-qualified typeName if one exists.
+//
+// This method proxies to the underlying ref.TypeProvider's FindType method and converts protobuf type
+// into a native type representation. If the conversion fails, the type is listed as not found.
+func (p *interopCELTypeProvider) FindStructType(typeName string) (*types.Type, bool) {
+ if et, found := p.FindType(typeName); found {
+ t, err := types.ExprTypeToType(et)
+ if err != nil {
+ return nil, false
+ }
+ return t, true
+ }
+ return nil, false
+}
+
+// FindStructFieldNames returns an empty set of field for the interop provider.
+//
+// To inspect the field names, migrate to a `types.Provider` implementation.
+func (p *interopCELTypeProvider) FindStructFieldNames(typeName string) ([]string, bool) {
+ return []string{}, false
+}
+
+// FindStructFieldType returns a types.FieldType instance for the given fully-qualified typeName and field
+// name, if one exists.
+//
+// This method proxies to the underlying ref.TypeProvider's FindFieldType method and converts protobuf type
+// into a native type representation. If the conversion fails, the type is listed as not found.
+func (p *interopCELTypeProvider) FindStructFieldType(structType, fieldName string) (*types.FieldType, bool) {
+ if ft, found := p.FindFieldType(structType, fieldName); found {
+ t, err := types.ExprTypeToType(ft.Type)
+ if err != nil {
+ return nil, false
+ }
+ return &types.FieldType{
+ Type: t,
+ IsSet: ft.IsSet,
+ GetFrom: ft.GetFrom,
+ }, true
+ }
+ return nil, false
+}
+
+// interopLegacyTypeProvider layers support for the ref.TypeProvider interface on top of a types.Provider.
+type interopLegacyTypeProvider struct {
+ types.Provider
+}
+
+// FindType retruns the protobuf Type representation for the input type name if one exists.
+//
+// This method proxies to the underlying types.Provider FindStructType method and converts the types.Type
+// value to a protobuf Type representation.
+//
+// Failure to convert the type will result in the type not being found.
+func (p *interopLegacyTypeProvider) FindType(typeName string) (*exprpb.Type, bool) {
+ if t, found := p.FindStructType(typeName); found {
+ et, err := types.TypeToExprType(t)
+ if err != nil {
+ return nil, false
+ }
+ return et, true
+ }
+ return nil, false
+}
+
+// FindFieldType returns the protobuf-based FieldType representation for the input type name and field,
+// if one exists.
+//
+// This call proxies to the types.Provider FindStructFieldType method and converts the types.FIeldType
+// value to a protobuf-based ref.FieldType representation if found.
+//
+// Failure to convert the FieldType will result in the field not being found.
+func (p *interopLegacyTypeProvider) FindFieldType(structType, fieldName string) (*ref.FieldType, bool) {
+ if cft, found := p.FindStructFieldType(structType, fieldName); found {
+ et, err := types.TypeToExprType(cft.Type)
+ if err != nil {
+ return nil, false
+ }
+ return &ref.FieldType{
+ Type: et,
+ IsSet: cft.IsSet,
+ GetFrom: cft.GetFrom,
+ }, true
+ }
+ return nil, false
+}
+
+var (
+ stdEnvInit sync.Once
+ stdEnv *Env
+ stdEnvErr error
+)
diff --git a/vendor/github.com/google/cel-go/cel/folding.go b/vendor/github.com/google/cel-go/cel/folding.go
new file mode 100644
index 000000000000..d7060896d37e
--- /dev/null
+++ b/vendor/github.com/google/cel-go/cel/folding.go
@@ -0,0 +1,559 @@
+// Copyright 2023 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package cel
+
+import (
+ "fmt"
+
+ "github.com/google/cel-go/common/ast"
+ "github.com/google/cel-go/common/operators"
+ "github.com/google/cel-go/common/overloads"
+ "github.com/google/cel-go/common/types"
+ "github.com/google/cel-go/common/types/ref"
+ "github.com/google/cel-go/common/types/traits"
+)
+
+// ConstantFoldingOption defines a functional option for configuring constant folding.
+type ConstantFoldingOption func(opt *constantFoldingOptimizer) (*constantFoldingOptimizer, error)
+
+// MaxConstantFoldIterations limits the number of times literals may be folding during optimization.
+//
+// Defaults to 100 if not set.
+func MaxConstantFoldIterations(limit int) ConstantFoldingOption {
+ return func(opt *constantFoldingOptimizer) (*constantFoldingOptimizer, error) {
+ opt.maxFoldIterations = limit
+ return opt, nil
+ }
+}
+
+// NewConstantFoldingOptimizer creates an optimizer which inlines constant scalar an aggregate
+// literal values within function calls and select statements with their evaluated result.
+func NewConstantFoldingOptimizer(opts ...ConstantFoldingOption) (ASTOptimizer, error) {
+ folder := &constantFoldingOptimizer{
+ maxFoldIterations: defaultMaxConstantFoldIterations,
+ }
+ var err error
+ for _, o := range opts {
+ folder, err = o(folder)
+ if err != nil {
+ return nil, err
+ }
+ }
+ return folder, nil
+}
+
+type constantFoldingOptimizer struct {
+ maxFoldIterations int
+}
+
+// Optimize queries the expression graph for scalar and aggregate literal expressions within call and
+// select statements and then evaluates them and replaces the call site with the literal result.
+//
+// Note: only values which can be represented as literals in CEL syntax are supported.
+func (opt *constantFoldingOptimizer) Optimize(ctx *OptimizerContext, a *ast.AST) *ast.AST {
+ root := ast.NavigateAST(a)
+
+ // Walk the list of foldable expression and continue to fold until there are no more folds left.
+ // All of the fold candidates returned by the constantExprMatcher should succeed unless there's
+ // a logic bug with the selection of expressions.
+ foldableExprs := ast.MatchDescendants(root, constantExprMatcher)
+ foldCount := 0
+ for len(foldableExprs) != 0 && foldCount < opt.maxFoldIterations {
+ for _, fold := range foldableExprs {
+ // If the expression could be folded because it's a non-strict call, and the
+ // branches are pruned, continue to the next fold.
+ if fold.Kind() == ast.CallKind && maybePruneBranches(ctx, fold) {
+ continue
+ }
+ // Otherwise, assume all context is needed to evaluate the expression.
+ err := tryFold(ctx, a, fold)
+ if err != nil {
+ ctx.ReportErrorAtID(fold.ID(), "constant-folding evaluation failed: %v", err.Error())
+ return a
+ }
+ }
+ foldCount++
+ foldableExprs = ast.MatchDescendants(root, constantExprMatcher)
+ }
+ // Once all of the constants have been folded, try to run through the remaining comprehensions
+ // one last time. In this case, there's no guarantee they'll run, so we only update the
+ // target comprehension node with the literal value if the evaluation succeeds.
+ for _, compre := range ast.MatchDescendants(root, ast.KindMatcher(ast.ComprehensionKind)) {
+ tryFold(ctx, a, compre)
+ }
+
+ // If the output is a list, map, or struct which contains optional entries, then prune it
+ // to make sure that the optionals, if resolved, do not surface in the output literal.
+ pruneOptionalElements(ctx, root)
+
+ // Ensure that all intermediate values in the folded expression can be represented as valid
+ // CEL literals within the AST structure. Use `PostOrderVisit` rather than `MatchDescendents`
+ // to avoid extra allocations during this final pass through the AST.
+ ast.PostOrderVisit(root, ast.NewExprVisitor(func(e ast.Expr) {
+ if e.Kind() != ast.LiteralKind {
+ return
+ }
+ val := e.AsLiteral()
+ adapted, err := adaptLiteral(ctx, val)
+ if err != nil {
+ ctx.ReportErrorAtID(root.ID(), "constant-folding evaluation failed: %v", err.Error())
+ return
+ }
+ ctx.UpdateExpr(e, adapted)
+ }))
+
+ return a
+}
+
+// tryFold attempts to evaluate a sub-expression to a literal.
+//
+// If the evaluation succeeds, the input expr value will be modified to become a literal, otherwise
+// the method will return an error.
+func tryFold(ctx *OptimizerContext, a *ast.AST, expr ast.Expr) error {
+ // Assume all context is needed to evaluate the expression.
+ subAST := &Ast{
+ impl: ast.NewCheckedAST(ast.NewAST(expr, a.SourceInfo()), a.TypeMap(), a.ReferenceMap()),
+ }
+ prg, err := ctx.Program(subAST)
+ if err != nil {
+ return err
+ }
+ out, _, err := prg.Eval(NoVars())
+ if err != nil {
+ return err
+ }
+ // Update the fold expression to be a literal.
+ ctx.UpdateExpr(expr, ctx.NewLiteral(out))
+ return nil
+}
+
+// maybePruneBranches inspects the non-strict call expression to determine whether
+// a branch can be removed. Evaluation will naturally prune logical and / or calls,
+// but conditional will not be pruned cleanly, so this is one small area where the
+// constant folding step reimplements a portion of the evaluator.
+func maybePruneBranches(ctx *OptimizerContext, expr ast.NavigableExpr) bool {
+ call := expr.AsCall()
+ args := call.Args()
+ switch call.FunctionName() {
+ case operators.LogicalAnd, operators.LogicalOr:
+ return maybeShortcircuitLogic(ctx, call.FunctionName(), args, expr)
+ case operators.Conditional:
+ cond := args[0]
+ truthy := args[1]
+ falsy := args[2]
+ if cond.Kind() != ast.LiteralKind {
+ return false
+ }
+ if cond.AsLiteral() == types.True {
+ ctx.UpdateExpr(expr, truthy)
+ } else {
+ ctx.UpdateExpr(expr, falsy)
+ }
+ return true
+ case operators.In:
+ haystack := args[1]
+ if haystack.Kind() == ast.ListKind && haystack.AsList().Size() == 0 {
+ ctx.UpdateExpr(expr, ctx.NewLiteral(types.False))
+ return true
+ }
+ needle := args[0]
+ if needle.Kind() == ast.LiteralKind && haystack.Kind() == ast.ListKind {
+ needleValue := needle.AsLiteral()
+ list := haystack.AsList()
+ for _, e := range list.Elements() {
+ if e.Kind() == ast.LiteralKind && e.AsLiteral().Equal(needleValue) == types.True {
+ ctx.UpdateExpr(expr, ctx.NewLiteral(types.True))
+ return true
+ }
+ }
+ }
+ }
+ return false
+}
+
+func maybeShortcircuitLogic(ctx *OptimizerContext, function string, args []ast.Expr, expr ast.NavigableExpr) bool {
+ shortcircuit := types.False
+ skip := types.True
+ if function == operators.LogicalOr {
+ shortcircuit = types.True
+ skip = types.False
+ }
+ newArgs := []ast.Expr{}
+ for _, arg := range args {
+ if arg.Kind() != ast.LiteralKind {
+ newArgs = append(newArgs, arg)
+ continue
+ }
+ if arg.AsLiteral() == skip {
+ continue
+ }
+ if arg.AsLiteral() == shortcircuit {
+ ctx.UpdateExpr(expr, arg)
+ return true
+ }
+ }
+ if len(newArgs) == 0 {
+ newArgs = append(newArgs, args[0])
+ ctx.UpdateExpr(expr, newArgs[0])
+ return true
+ }
+ if len(newArgs) == 1 {
+ ctx.UpdateExpr(expr, newArgs[0])
+ return true
+ }
+ ctx.UpdateExpr(expr, ctx.NewCall(function, newArgs...))
+ return true
+}
+
+// pruneOptionalElements works from the bottom up to resolve optional elements within
+// aggregate literals.
+//
+// Note, many aggregate literals will be resolved as arguments to functions or select
+// statements, so this method exists to handle the case where the literal could not be
+// fully resolved or exists outside of a call, select, or comprehension context.
+func pruneOptionalElements(ctx *OptimizerContext, root ast.NavigableExpr) {
+ aggregateLiterals := ast.MatchDescendants(root, aggregateLiteralMatcher)
+ for _, lit := range aggregateLiterals {
+ switch lit.Kind() {
+ case ast.ListKind:
+ pruneOptionalListElements(ctx, lit)
+ case ast.MapKind:
+ pruneOptionalMapEntries(ctx, lit)
+ case ast.StructKind:
+ pruneOptionalStructFields(ctx, lit)
+ }
+ }
+}
+
+func pruneOptionalListElements(ctx *OptimizerContext, e ast.Expr) {
+ l := e.AsList()
+ elems := l.Elements()
+ optIndices := l.OptionalIndices()
+ if len(optIndices) == 0 {
+ return
+ }
+ updatedElems := []ast.Expr{}
+ updatedIndices := []int32{}
+ newOptIndex := -1
+ for _, e := range elems {
+ newOptIndex++
+ if !l.IsOptional(int32(newOptIndex)) {
+ updatedElems = append(updatedElems, e)
+ continue
+ }
+ if e.Kind() != ast.LiteralKind {
+ updatedElems = append(updatedElems, e)
+ updatedIndices = append(updatedIndices, int32(newOptIndex))
+ continue
+ }
+ optElemVal, ok := e.AsLiteral().(*types.Optional)
+ if !ok {
+ updatedElems = append(updatedElems, e)
+ updatedIndices = append(updatedIndices, int32(newOptIndex))
+ continue
+ }
+ if !optElemVal.HasValue() {
+ newOptIndex-- // Skipping causes the list to get smaller.
+ continue
+ }
+ ctx.UpdateExpr(e, ctx.NewLiteral(optElemVal.GetValue()))
+ updatedElems = append(updatedElems, e)
+ }
+ ctx.UpdateExpr(e, ctx.NewList(updatedElems, updatedIndices))
+}
+
+func pruneOptionalMapEntries(ctx *OptimizerContext, e ast.Expr) {
+ m := e.AsMap()
+ entries := m.Entries()
+ updatedEntries := []ast.EntryExpr{}
+ modified := false
+ for _, e := range entries {
+ entry := e.AsMapEntry()
+ key := entry.Key()
+ val := entry.Value()
+ // If the entry is not optional, or the value-side of the optional hasn't
+ // been resolved to a literal, then preserve the entry as-is.
+ if !entry.IsOptional() || val.Kind() != ast.LiteralKind {
+ updatedEntries = append(updatedEntries, e)
+ continue
+ }
+ optElemVal, ok := val.AsLiteral().(*types.Optional)
+ if !ok {
+ updatedEntries = append(updatedEntries, e)
+ continue
+ }
+ // When the key is not a literal, but the value is, then it needs to be
+ // restored to an optional value.
+ if key.Kind() != ast.LiteralKind {
+ undoOptVal, err := adaptLiteral(ctx, optElemVal)
+ if err != nil {
+ ctx.ReportErrorAtID(val.ID(), "invalid map value literal %v: %v", optElemVal, err)
+ }
+ ctx.UpdateExpr(val, undoOptVal)
+ updatedEntries = append(updatedEntries, e)
+ continue
+ }
+ modified = true
+ if !optElemVal.HasValue() {
+ continue
+ }
+ ctx.UpdateExpr(val, ctx.NewLiteral(optElemVal.GetValue()))
+ updatedEntry := ctx.NewMapEntry(key, val, false)
+ updatedEntries = append(updatedEntries, updatedEntry)
+ }
+ if modified {
+ ctx.UpdateExpr(e, ctx.NewMap(updatedEntries))
+ }
+}
+
+func pruneOptionalStructFields(ctx *OptimizerContext, e ast.Expr) {
+ s := e.AsStruct()
+ fields := s.Fields()
+ updatedFields := []ast.EntryExpr{}
+ modified := false
+ for _, f := range fields {
+ field := f.AsStructField()
+ val := field.Value()
+ if !field.IsOptional() || val.Kind() != ast.LiteralKind {
+ updatedFields = append(updatedFields, f)
+ continue
+ }
+ optElemVal, ok := val.AsLiteral().(*types.Optional)
+ if !ok {
+ updatedFields = append(updatedFields, f)
+ continue
+ }
+ modified = true
+ if !optElemVal.HasValue() {
+ continue
+ }
+ ctx.UpdateExpr(val, ctx.NewLiteral(optElemVal.GetValue()))
+ updatedField := ctx.NewStructField(field.Name(), val, false)
+ updatedFields = append(updatedFields, updatedField)
+ }
+ if modified {
+ ctx.UpdateExpr(e, ctx.NewStruct(s.TypeName(), updatedFields))
+ }
+}
+
+// adaptLiteral converts a runtime CEL value to its equivalent literal expression.
+//
+// For strongly typed values, the type-provider will be used to reconstruct the fields
+// which are present in the literal and their equivalent initialization values.
+func adaptLiteral(ctx *OptimizerContext, val ref.Val) (ast.Expr, error) {
+ switch t := val.Type().(type) {
+ case *types.Type:
+ switch t {
+ case types.BoolType, types.BytesType, types.DoubleType, types.IntType,
+ types.NullType, types.StringType, types.UintType:
+ return ctx.NewLiteral(val), nil
+ case types.DurationType:
+ return ctx.NewCall(
+ overloads.TypeConvertDuration,
+ ctx.NewLiteral(val.ConvertToType(types.StringType)),
+ ), nil
+ case types.TimestampType:
+ return ctx.NewCall(
+ overloads.TypeConvertTimestamp,
+ ctx.NewLiteral(val.ConvertToType(types.StringType)),
+ ), nil
+ case types.OptionalType:
+ opt := val.(*types.Optional)
+ if !opt.HasValue() {
+ return ctx.NewCall("optional.none"), nil
+ }
+ target, err := adaptLiteral(ctx, opt.GetValue())
+ if err != nil {
+ return nil, err
+ }
+ return ctx.NewCall("optional.of", target), nil
+ case types.TypeType:
+ return ctx.NewIdent(val.(*types.Type).TypeName()), nil
+ case types.ListType:
+ l, ok := val.(traits.Lister)
+ if !ok {
+ return nil, fmt.Errorf("failed to adapt %v to literal", val)
+ }
+ elems := make([]ast.Expr, l.Size().(types.Int))
+ idx := 0
+ it := l.Iterator()
+ for it.HasNext() == types.True {
+ elemVal := it.Next()
+ elemExpr, err := adaptLiteral(ctx, elemVal)
+ if err != nil {
+ return nil, err
+ }
+ elems[idx] = elemExpr
+ idx++
+ }
+ return ctx.NewList(elems, []int32{}), nil
+ case types.MapType:
+ m, ok := val.(traits.Mapper)
+ if !ok {
+ return nil, fmt.Errorf("failed to adapt %v to literal", val)
+ }
+ entries := make([]ast.EntryExpr, m.Size().(types.Int))
+ idx := 0
+ it := m.Iterator()
+ for it.HasNext() == types.True {
+ keyVal := it.Next()
+ keyExpr, err := adaptLiteral(ctx, keyVal)
+ if err != nil {
+ return nil, err
+ }
+ valVal := m.Get(keyVal)
+ valExpr, err := adaptLiteral(ctx, valVal)
+ if err != nil {
+ return nil, err
+ }
+ entries[idx] = ctx.NewMapEntry(keyExpr, valExpr, false)
+ idx++
+ }
+ return ctx.NewMap(entries), nil
+ default:
+ provider := ctx.CELTypeProvider()
+ fields, found := provider.FindStructFieldNames(t.TypeName())
+ if !found {
+ return nil, fmt.Errorf("failed to adapt %v to literal", val)
+ }
+ tester := val.(traits.FieldTester)
+ indexer := val.(traits.Indexer)
+ fieldInits := []ast.EntryExpr{}
+ for _, f := range fields {
+ field := types.String(f)
+ if tester.IsSet(field) != types.True {
+ continue
+ }
+ fieldVal := indexer.Get(field)
+ fieldExpr, err := adaptLiteral(ctx, fieldVal)
+ if err != nil {
+ return nil, err
+ }
+ fieldInits = append(fieldInits, ctx.NewStructField(f, fieldExpr, false))
+ }
+ return ctx.NewStruct(t.TypeName(), fieldInits), nil
+ }
+ }
+ return nil, fmt.Errorf("failed to adapt %v to literal", val)
+}
+
+// constantExprMatcher matches calls, select statements, and comprehensions whose arguments
+// are all constant scalar or aggregate literal values.
+//
+// Only comprehensions which are not nested are included as possible constant folds, and only
+// if all variables referenced in the comprehension stack exist are only iteration or
+// accumulation variables.
+func constantExprMatcher(e ast.NavigableExpr) bool {
+ switch e.Kind() {
+ case ast.CallKind:
+ return constantCallMatcher(e)
+ case ast.SelectKind:
+ sel := e.AsSelect() // guaranteed to be a navigable value
+ return constantMatcher(sel.Operand().(ast.NavigableExpr))
+ case ast.ComprehensionKind:
+ if isNestedComprehension(e) {
+ return false
+ }
+ vars := map[string]bool{}
+ constantExprs := true
+ visitor := ast.NewExprVisitor(func(e ast.Expr) {
+ if e.Kind() == ast.ComprehensionKind {
+ nested := e.AsComprehension()
+ vars[nested.AccuVar()] = true
+ vars[nested.IterVar()] = true
+ }
+ if e.Kind() == ast.IdentKind && !vars[e.AsIdent()] {
+ constantExprs = false
+ }
+ })
+ ast.PreOrderVisit(e, visitor)
+ return constantExprs
+ default:
+ return false
+ }
+}
+
+// constantCallMatcher identifies strict and non-strict calls which can be folded.
+func constantCallMatcher(e ast.NavigableExpr) bool {
+ call := e.AsCall()
+ children := e.Children()
+ fnName := call.FunctionName()
+ if fnName == operators.LogicalAnd {
+ for _, child := range children {
+ if child.Kind() == ast.LiteralKind {
+ return true
+ }
+ }
+ }
+ if fnName == operators.LogicalOr {
+ for _, child := range children {
+ if child.Kind() == ast.LiteralKind {
+ return true
+ }
+ }
+ }
+ if fnName == operators.Conditional {
+ cond := children[0]
+ if cond.Kind() == ast.LiteralKind && cond.AsLiteral().Type() == types.BoolType {
+ return true
+ }
+ }
+ if fnName == operators.In {
+ haystack := children[1]
+ if haystack.Kind() == ast.ListKind && haystack.AsList().Size() == 0 {
+ return true
+ }
+ needle := children[0]
+ if needle.Kind() == ast.LiteralKind && haystack.Kind() == ast.ListKind {
+ needleValue := needle.AsLiteral()
+ list := haystack.AsList()
+ for _, e := range list.Elements() {
+ if e.Kind() == ast.LiteralKind && e.AsLiteral().Equal(needleValue) == types.True {
+ return true
+ }
+ }
+ }
+ }
+ // convert all other calls with constant arguments
+ for _, child := range children {
+ if !constantMatcher(child) {
+ return false
+ }
+ }
+ return true
+}
+
+func isNestedComprehension(e ast.NavigableExpr) bool {
+ parent, found := e.Parent()
+ for found {
+ if parent.Kind() == ast.ComprehensionKind {
+ return true
+ }
+ parent, found = parent.Parent()
+ }
+ return false
+}
+
+func aggregateLiteralMatcher(e ast.NavigableExpr) bool {
+ return e.Kind() == ast.ListKind || e.Kind() == ast.MapKind || e.Kind() == ast.StructKind
+}
+
+var (
+ constantMatcher = ast.ConstantValueMatcher()
+)
+
+const (
+ defaultMaxConstantFoldIterations = 100
+)
diff --git a/vendor/github.com/google/cel-go/cel/inlining.go b/vendor/github.com/google/cel-go/cel/inlining.go
new file mode 100644
index 000000000000..78d5bea65b15
--- /dev/null
+++ b/vendor/github.com/google/cel-go/cel/inlining.go
@@ -0,0 +1,228 @@
+// Copyright 2023 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package cel
+
+import (
+ "github.com/google/cel-go/common/ast"
+ "github.com/google/cel-go/common/containers"
+ "github.com/google/cel-go/common/operators"
+ "github.com/google/cel-go/common/overloads"
+ "github.com/google/cel-go/common/types"
+ "github.com/google/cel-go/common/types/traits"
+)
+
+// InlineVariable holds a variable name to be matched and an AST representing
+// the expression graph which should be used to replace it.
+type InlineVariable struct {
+ name string
+ alias string
+ def *ast.AST
+}
+
+// Name returns the qualified variable or field selection to replace.
+func (v *InlineVariable) Name() string {
+ return v.name
+}
+
+// Alias returns the alias to use when performing cel.bind() calls during inlining.
+func (v *InlineVariable) Alias() string {
+ return v.alias
+}
+
+// Expr returns the inlined expression value.
+func (v *InlineVariable) Expr() ast.Expr {
+ return v.def.Expr()
+}
+
+// Type indicates the inlined expression type.
+func (v *InlineVariable) Type() *Type {
+ return v.def.GetType(v.def.Expr().ID())
+}
+
+// NewInlineVariable declares a variable name to be replaced by a checked expression.
+func NewInlineVariable(name string, definition *Ast) *InlineVariable {
+ return NewInlineVariableWithAlias(name, name, definition)
+}
+
+// NewInlineVariableWithAlias declares a variable name to be replaced by a checked expression.
+// If the variable occurs more than once, the provided alias will be used to replace the expressions
+// where the variable name occurs.
+func NewInlineVariableWithAlias(name, alias string, definition *Ast) *InlineVariable {
+ return &InlineVariable{name: name, alias: alias, def: definition.impl}
+}
+
+// NewInliningOptimizer creates and optimizer which replaces variables with expression definitions.
+//
+// If a variable occurs one time, the variable is replaced by the inline definition. If the
+// variable occurs more than once, the variable occurences are replaced by a cel.bind() call.
+func NewInliningOptimizer(inlineVars ...*InlineVariable) ASTOptimizer {
+ return &inliningOptimizer{variables: inlineVars}
+}
+
+type inliningOptimizer struct {
+ variables []*InlineVariable
+}
+
+func (opt *inliningOptimizer) Optimize(ctx *OptimizerContext, a *ast.AST) *ast.AST {
+ root := ast.NavigateAST(a)
+ for _, inlineVar := range opt.variables {
+ matches := ast.MatchDescendants(root, opt.matchVariable(inlineVar.Name()))
+ // Skip cases where the variable isn't in the expression graph
+ if len(matches) == 0 {
+ continue
+ }
+
+ // For a single match, do a direct replacement of the expression sub-graph.
+ if len(matches) == 1 || !isBindable(matches, inlineVar.Expr(), inlineVar.Type()) {
+ for _, match := range matches {
+ // Copy the inlined AST expr and source info.
+ copyExpr := ctx.CopyASTAndMetadata(inlineVar.def)
+ opt.inlineExpr(ctx, match, copyExpr, inlineVar.Type())
+ }
+ continue
+ }
+
+ // For multiple matches, find the least common ancestor (lca) and insert the
+ // variable as a cel.bind() macro.
+ var lca ast.NavigableExpr = root
+ lcaAncestorCount := 0
+ ancestors := map[int64]int{}
+ for _, match := range matches {
+ // Update the identifier matches with the provided alias.
+ parent, found := match, true
+ for found {
+ ancestorCount, hasAncestor := ancestors[parent.ID()]
+ if !hasAncestor {
+ ancestors[parent.ID()] = 1
+ parent, found = parent.Parent()
+ continue
+ }
+ if lcaAncestorCount < ancestorCount || (lcaAncestorCount == ancestorCount && lca.Depth() < parent.Depth()) {
+ lca = parent
+ lcaAncestorCount = ancestorCount
+ }
+ ancestors[parent.ID()] = ancestorCount + 1
+ parent, found = parent.Parent()
+ }
+ aliasExpr := ctx.NewIdent(inlineVar.Alias())
+ opt.inlineExpr(ctx, match, aliasExpr, inlineVar.Type())
+ }
+
+ // Copy the inlined AST expr and source info.
+ copyExpr := ctx.CopyASTAndMetadata(inlineVar.def)
+ // Update the least common ancestor by inserting a cel.bind() call to the alias.
+ inlined, bindMacro := ctx.NewBindMacro(lca.ID(), inlineVar.Alias(), copyExpr, lca)
+ opt.inlineExpr(ctx, lca, inlined, inlineVar.Type())
+ ctx.SetMacroCall(lca.ID(), bindMacro)
+ }
+ return a
+}
+
+// inlineExpr replaces the current expression with the inlined one, unless the location of the inlining
+// happens within a presence test, e.g. has(a.b.c) -> inline alpha for a.b.c in which case an attempt is
+// made to determine whether the inlined value can be presence or existence tested.
+func (opt *inliningOptimizer) inlineExpr(ctx *OptimizerContext, prev ast.NavigableExpr, inlined ast.Expr, inlinedType *Type) {
+ switch prev.Kind() {
+ case ast.SelectKind:
+ sel := prev.AsSelect()
+ if !sel.IsTestOnly() {
+ ctx.UpdateExpr(prev, inlined)
+ return
+ }
+ opt.rewritePresenceExpr(ctx, prev, inlined, inlinedType)
+ default:
+ ctx.UpdateExpr(prev, inlined)
+ }
+}
+
+// rewritePresenceExpr converts the inlined expression, when it occurs within a has() macro, to type-safe
+// expression appropriate for the inlined type, if possible.
+//
+// If the rewrite is not possible an error is reported at the inline expression site.
+func (opt *inliningOptimizer) rewritePresenceExpr(ctx *OptimizerContext, prev, inlined ast.Expr, inlinedType *Type) {
+ // If the input inlined expression is not a select expression it won't work with the has()
+ // macro. Attempt to rewrite the presence test in terms of the typed input, otherwise error.
+ if inlined.Kind() == ast.SelectKind {
+ presenceTest, hasMacro := ctx.NewHasMacro(prev.ID(), inlined)
+ ctx.UpdateExpr(prev, presenceTest)
+ ctx.SetMacroCall(prev.ID(), hasMacro)
+ return
+ }
+
+ ctx.ClearMacroCall(prev.ID())
+ if inlinedType.IsAssignableType(NullType) {
+ ctx.UpdateExpr(prev,
+ ctx.NewCall(operators.NotEquals,
+ inlined,
+ ctx.NewLiteral(types.NullValue),
+ ))
+ return
+ }
+ if inlinedType.HasTrait(traits.SizerType) {
+ ctx.UpdateExpr(prev,
+ ctx.NewCall(operators.NotEquals,
+ ctx.NewMemberCall(overloads.Size, inlined),
+ ctx.NewLiteral(types.IntZero),
+ ))
+ return
+ }
+ ctx.ReportErrorAtID(prev.ID(), "unable to inline expression type %v into presence test", inlinedType)
+}
+
+// isBindable indicates whether the inlined type can be used within a cel.bind() if the expression
+// being replaced occurs within a presence test. Value types with a size() method or field selection
+// support can be bound.
+//
+// In future iterations, support may also be added for indexer types which can be rewritten as an `in`
+// expression; however, this would imply a rewrite of the inlined expression that may not be necessary
+// in most cases.
+func isBindable(matches []ast.NavigableExpr, inlined ast.Expr, inlinedType *Type) bool {
+ if inlinedType.IsAssignableType(NullType) ||
+ inlinedType.HasTrait(traits.SizerType) {
+ return true
+ }
+ for _, m := range matches {
+ if m.Kind() != ast.SelectKind {
+ continue
+ }
+ sel := m.AsSelect()
+ if sel.IsTestOnly() {
+ return false
+ }
+ }
+ return true
+}
+
+// matchVariable matches simple identifiers, select expressions, and presence test expressions
+// which match the (potentially) qualified variable name provided as input.
+//
+// Note, this function does not support inlining against select expressions which includes optional
+// field selection. This may be a future refinement.
+func (opt *inliningOptimizer) matchVariable(varName string) ast.ExprMatcher {
+ return func(e ast.NavigableExpr) bool {
+ if e.Kind() == ast.IdentKind && e.AsIdent() == varName {
+ return true
+ }
+ if e.Kind() == ast.SelectKind {
+ sel := e.AsSelect()
+ // While the `ToQualifiedName` call could take the select directly, this
+ // would skip presence tests from possible matches, which we would like
+ // to include.
+ qualName, found := containers.ToQualifiedName(sel.Operand())
+ return found && qualName+"."+sel.FieldName() == varName
+ }
+ return false
+ }
+}
diff --git a/vendor/github.com/google/cel-go/cel/io.go b/vendor/github.com/google/cel-go/cel/io.go
new file mode 100644
index 000000000000..3133fb9d7d6f
--- /dev/null
+++ b/vendor/github.com/google/cel-go/cel/io.go
@@ -0,0 +1,252 @@
+// Copyright 2019 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package cel
+
+import (
+ "errors"
+ "fmt"
+ "reflect"
+
+ "google.golang.org/protobuf/proto"
+
+ "github.com/google/cel-go/common"
+ "github.com/google/cel-go/common/ast"
+ "github.com/google/cel-go/common/types"
+ "github.com/google/cel-go/common/types/ref"
+ "github.com/google/cel-go/common/types/traits"
+ "github.com/google/cel-go/parser"
+
+ exprpb "google.golang.org/genproto/googleapis/api/expr/v1alpha1"
+ anypb "google.golang.org/protobuf/types/known/anypb"
+)
+
+// CheckedExprToAst converts a checked expression proto message to an Ast.
+func CheckedExprToAst(checkedExpr *exprpb.CheckedExpr) *Ast {
+ checked, _ := CheckedExprToAstWithSource(checkedExpr, nil)
+ return checked
+}
+
+// CheckedExprToAstWithSource converts a checked expression proto message to an Ast,
+// using the provided Source as the textual contents.
+//
+// In general the source is not necessary unless the AST has been modified between the
+// `Parse` and `Check` calls as an `Ast` created from the `Parse` step will carry the source
+// through future calls.
+//
+// Prefer CheckedExprToAst if loading expressions from storage.
+func CheckedExprToAstWithSource(checkedExpr *exprpb.CheckedExpr, src Source) (*Ast, error) {
+ checked, err := ast.ToAST(checkedExpr)
+ if err != nil {
+ return nil, err
+ }
+ return &Ast{source: src, impl: checked}, nil
+}
+
+// AstToCheckedExpr converts an Ast to an protobuf CheckedExpr value.
+//
+// If the Ast.IsChecked() returns false, this conversion method will return an error.
+func AstToCheckedExpr(a *Ast) (*exprpb.CheckedExpr, error) {
+ if !a.IsChecked() {
+ return nil, fmt.Errorf("cannot convert unchecked ast")
+ }
+ return ast.ToProto(a.impl)
+}
+
+// ParsedExprToAst converts a parsed expression proto message to an Ast.
+func ParsedExprToAst(parsedExpr *exprpb.ParsedExpr) *Ast {
+ return ParsedExprToAstWithSource(parsedExpr, nil)
+}
+
+// ParsedExprToAstWithSource converts a parsed expression proto message to an Ast,
+// using the provided Source as the textual contents.
+//
+// In general you only need this if you need to recheck a previously checked
+// expression, or if you need to separately check a subset of an expression.
+//
+// Prefer ParsedExprToAst if loading expressions from storage.
+func ParsedExprToAstWithSource(parsedExpr *exprpb.ParsedExpr, src Source) *Ast {
+ info, _ := ast.ProtoToSourceInfo(parsedExpr.GetSourceInfo())
+ if src == nil {
+ src = common.NewInfoSource(parsedExpr.GetSourceInfo())
+ }
+ e, _ := ast.ProtoToExpr(parsedExpr.GetExpr())
+ return &Ast{source: src, impl: ast.NewAST(e, info)}
+}
+
+// AstToParsedExpr converts an Ast to an protobuf ParsedExpr value.
+func AstToParsedExpr(a *Ast) (*exprpb.ParsedExpr, error) {
+ return &exprpb.ParsedExpr{
+ Expr: a.Expr(),
+ SourceInfo: a.SourceInfo(),
+ }, nil
+}
+
+// AstToString converts an Ast back to a string if possible.
+//
+// Note, the conversion may not be an exact replica of the original expression, but will produce
+// a string that is semantically equivalent and whose textual representation is stable.
+func AstToString(a *Ast) (string, error) {
+ return parser.Unparse(a.impl.Expr(), a.impl.SourceInfo())
+}
+
+// RefValueToValue converts between ref.Val and api.expr.Value.
+// The result Value is the serialized proto form. The ref.Val must not be error or unknown.
+func RefValueToValue(res ref.Val) (*exprpb.Value, error) {
+ switch res.Type() {
+ case types.BoolType:
+ return &exprpb.Value{
+ Kind: &exprpb.Value_BoolValue{BoolValue: res.Value().(bool)}}, nil
+ case types.BytesType:
+ return &exprpb.Value{
+ Kind: &exprpb.Value_BytesValue{BytesValue: res.Value().([]byte)}}, nil
+ case types.DoubleType:
+ return &exprpb.Value{
+ Kind: &exprpb.Value_DoubleValue{DoubleValue: res.Value().(float64)}}, nil
+ case types.IntType:
+ return &exprpb.Value{
+ Kind: &exprpb.Value_Int64Value{Int64Value: res.Value().(int64)}}, nil
+ case types.ListType:
+ l := res.(traits.Lister)
+ sz := l.Size().(types.Int)
+ elts := make([]*exprpb.Value, 0, int64(sz))
+ for i := types.Int(0); i < sz; i++ {
+ v, err := RefValueToValue(l.Get(i))
+ if err != nil {
+ return nil, err
+ }
+ elts = append(elts, v)
+ }
+ return &exprpb.Value{
+ Kind: &exprpb.Value_ListValue{
+ ListValue: &exprpb.ListValue{Values: elts}}}, nil
+ case types.MapType:
+ mapper := res.(traits.Mapper)
+ sz := mapper.Size().(types.Int)
+ entries := make([]*exprpb.MapValue_Entry, 0, int64(sz))
+ for it := mapper.Iterator(); it.HasNext().(types.Bool); {
+ k := it.Next()
+ v := mapper.Get(k)
+ kv, err := RefValueToValue(k)
+ if err != nil {
+ return nil, err
+ }
+ vv, err := RefValueToValue(v)
+ if err != nil {
+ return nil, err
+ }
+ entries = append(entries, &exprpb.MapValue_Entry{Key: kv, Value: vv})
+ }
+ return &exprpb.Value{
+ Kind: &exprpb.Value_MapValue{
+ MapValue: &exprpb.MapValue{Entries: entries}}}, nil
+ case types.NullType:
+ return &exprpb.Value{
+ Kind: &exprpb.Value_NullValue{}}, nil
+ case types.StringType:
+ return &exprpb.Value{
+ Kind: &exprpb.Value_StringValue{StringValue: res.Value().(string)}}, nil
+ case types.TypeType:
+ typeName := res.(ref.Type).TypeName()
+ return &exprpb.Value{Kind: &exprpb.Value_TypeValue{TypeValue: typeName}}, nil
+ case types.UintType:
+ return &exprpb.Value{
+ Kind: &exprpb.Value_Uint64Value{Uint64Value: res.Value().(uint64)}}, nil
+ default:
+ any, err := res.ConvertToNative(anyPbType)
+ if err != nil {
+ return nil, err
+ }
+ return &exprpb.Value{
+ Kind: &exprpb.Value_ObjectValue{ObjectValue: any.(*anypb.Any)}}, nil
+ }
+}
+
+var (
+ typeNameToTypeValue = map[string]ref.Val{
+ "bool": types.BoolType,
+ "bytes": types.BytesType,
+ "double": types.DoubleType,
+ "null_type": types.NullType,
+ "int": types.IntType,
+ "list": types.ListType,
+ "map": types.MapType,
+ "string": types.StringType,
+ "type": types.TypeType,
+ "uint": types.UintType,
+ }
+
+ anyPbType = reflect.TypeOf(&anypb.Any{})
+)
+
+// ValueToRefValue converts between exprpb.Value and ref.Val.
+func ValueToRefValue(adapter types.Adapter, v *exprpb.Value) (ref.Val, error) {
+ switch v.Kind.(type) {
+ case *exprpb.Value_NullValue:
+ return types.NullValue, nil
+ case *exprpb.Value_BoolValue:
+ return types.Bool(v.GetBoolValue()), nil
+ case *exprpb.Value_Int64Value:
+ return types.Int(v.GetInt64Value()), nil
+ case *exprpb.Value_Uint64Value:
+ return types.Uint(v.GetUint64Value()), nil
+ case *exprpb.Value_DoubleValue:
+ return types.Double(v.GetDoubleValue()), nil
+ case *exprpb.Value_StringValue:
+ return types.String(v.GetStringValue()), nil
+ case *exprpb.Value_BytesValue:
+ return types.Bytes(v.GetBytesValue()), nil
+ case *exprpb.Value_ObjectValue:
+ any := v.GetObjectValue()
+ msg, err := anypb.UnmarshalNew(any, proto.UnmarshalOptions{DiscardUnknown: true})
+ if err != nil {
+ return nil, err
+ }
+ return adapter.NativeToValue(msg), nil
+ case *exprpb.Value_MapValue:
+ m := v.GetMapValue()
+ entries := make(map[ref.Val]ref.Val)
+ for _, entry := range m.Entries {
+ key, err := ValueToRefValue(adapter, entry.Key)
+ if err != nil {
+ return nil, err
+ }
+ pb, err := ValueToRefValue(adapter, entry.Value)
+ if err != nil {
+ return nil, err
+ }
+ entries[key] = pb
+ }
+ return adapter.NativeToValue(entries), nil
+ case *exprpb.Value_ListValue:
+ l := v.GetListValue()
+ elts := make([]ref.Val, len(l.Values))
+ for i, e := range l.Values {
+ rv, err := ValueToRefValue(adapter, e)
+ if err != nil {
+ return nil, err
+ }
+ elts[i] = rv
+ }
+ return adapter.NativeToValue(elts), nil
+ case *exprpb.Value_TypeValue:
+ typeName := v.GetTypeValue()
+ tv, ok := typeNameToTypeValue[typeName]
+ if ok {
+ return tv, nil
+ }
+ return types.NewObjectTypeValue(typeName), nil
+ }
+ return nil, errors.New("unknown value")
+}
diff --git a/vendor/github.com/google/cel-go/cel/library.go b/vendor/github.com/google/cel-go/cel/library.go
new file mode 100644
index 000000000000..be59f1b0284c
--- /dev/null
+++ b/vendor/github.com/google/cel-go/cel/library.go
@@ -0,0 +1,790 @@
+// Copyright 2020 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package cel
+
+import (
+ "math"
+ "strconv"
+ "strings"
+ "time"
+
+ "github.com/google/cel-go/common/ast"
+ "github.com/google/cel-go/common/operators"
+ "github.com/google/cel-go/common/overloads"
+ "github.com/google/cel-go/common/stdlib"
+ "github.com/google/cel-go/common/types"
+ "github.com/google/cel-go/common/types/ref"
+ "github.com/google/cel-go/common/types/traits"
+ "github.com/google/cel-go/interpreter"
+ "github.com/google/cel-go/parser"
+)
+
+const (
+ optMapMacro = "optMap"
+ optFlatMapMacro = "optFlatMap"
+ hasValueFunc = "hasValue"
+ optionalNoneFunc = "optional.none"
+ optionalOfFunc = "optional.of"
+ optionalOfNonZeroValueFunc = "optional.ofNonZeroValue"
+ valueFunc = "value"
+ unusedIterVar = "#unused"
+)
+
+// Library provides a collection of EnvOption and ProgramOption values used to configure a CEL
+// environment for a particular use case or with a related set of functionality.
+//
+// Note, the ProgramOption values provided by a library are expected to be static and not vary
+// between calls to Env.Program(). If there is a need for such dynamic configuration, prefer to
+// configure these options outside the Library and within the Env.Program() call directly.
+type Library interface {
+ // CompileOptions returns a collection of functional options for configuring the Parse / Check
+ // environment.
+ CompileOptions() []EnvOption
+
+ // ProgramOptions returns a collection of functional options which should be included in every
+ // Program generated from the Env.Program() call.
+ ProgramOptions() []ProgramOption
+}
+
+// SingletonLibrary refines the Library interface to ensure that libraries in this format are only
+// configured once within the environment.
+type SingletonLibrary interface {
+ Library
+
+ // LibraryName provides a namespaced name which is used to check whether the library has already
+ // been configured in the environment.
+ LibraryName() string
+}
+
+// Lib creates an EnvOption out of a Library, allowing libraries to be provided as functional args,
+// and to be linked to each other.
+func Lib(l Library) EnvOption {
+ singleton, isSingleton := l.(SingletonLibrary)
+ return func(e *Env) (*Env, error) {
+ if isSingleton {
+ if e.HasLibrary(singleton.LibraryName()) {
+ return e, nil
+ }
+ e.libraries[singleton.LibraryName()] = true
+ }
+ var err error
+ for _, opt := range l.CompileOptions() {
+ e, err = opt(e)
+ if err != nil {
+ return nil, err
+ }
+ }
+ e.progOpts = append(e.progOpts, l.ProgramOptions()...)
+ return e, nil
+ }
+}
+
+// StdLib returns an EnvOption for the standard library of CEL functions and macros.
+func StdLib() EnvOption {
+ return Lib(stdLibrary{})
+}
+
+// stdLibrary implements the Library interface and provides functional options for the core CEL
+// features documented in the specification.
+type stdLibrary struct{}
+
+// LibraryName implements the SingletonLibrary interface method.
+func (stdLibrary) LibraryName() string {
+ return "cel.lib.std"
+}
+
+// CompileOptions returns options for the standard CEL function declarations and macros.
+func (stdLibrary) CompileOptions() []EnvOption {
+ return []EnvOption{
+ func(e *Env) (*Env, error) {
+ var err error
+ for _, fn := range stdlib.Functions() {
+ existing, found := e.functions[fn.Name()]
+ if found {
+ fn, err = existing.Merge(fn)
+ if err != nil {
+ return nil, err
+ }
+ }
+ e.functions[fn.Name()] = fn
+ }
+ return e, nil
+ },
+ func(e *Env) (*Env, error) {
+ e.variables = append(e.variables, stdlib.Types()...)
+ return e, nil
+ },
+ Macros(StandardMacros...),
+ }
+}
+
+// ProgramOptions returns function implementations for the standard CEL functions.
+func (stdLibrary) ProgramOptions() []ProgramOption {
+ return []ProgramOption{}
+}
+
+// OptionalTypes enable support for optional syntax and types in CEL.
+//
+// The optional value type makes it possible to express whether variables have
+// been provided, whether a result has been computed, and in the future whether
+// an object field path, map key value, or list index has a value.
+//
+// # Syntax Changes
+//
+// OptionalTypes are unlike other CEL extensions because they modify the CEL
+// syntax itself, notably through the use of a `?` preceding a field name or
+// index value.
+//
+// ## Field Selection
+//
+// The optional syntax in field selection is denoted as `obj.?field`. In other
+// words, if a field is set, return `optional.of(obj.field)“, else
+// `optional.none()`. The optional field selection is viral in the sense that
+// after the first optional selection all subsequent selections or indices
+// are treated as optional, i.e. the following expressions are equivalent:
+//
+// obj.?field.subfield
+// obj.?field.?subfield
+//
+// ## Indexing
+//
+// Similar to field selection, the optional syntax can be used in index
+// expressions on maps and lists:
+//
+// list[?0]
+// map[?key]
+//
+// ## Optional Field Setting
+//
+// When creating map or message literals, if a field may be optionally set
+// based on its presence, then placing a `?` before the field name or key
+// will ensure the type on the right-hand side must be optional(T) where T
+// is the type of the field or key-value.
+//
+// The following returns a map with the key expression set only if the
+// subfield is present, otherwise an empty map is created:
+//
+// {?key: obj.?field.subfield}
+//
+// ## Optional Element Setting
+//
+// When creating list literals, an element in the list may be optionally added
+// when the element expression is preceded by a `?`:
+//
+// [a, ?b, ?c] // return a list with either [a], [a, b], [a, b, c], or [a, c]
+//
+// # Optional.Of
+//
+// Create an optional(T) value of a given value with type T.
+//
+// optional.of(10)
+//
+// # Optional.OfNonZeroValue
+//
+// Create an optional(T) value of a given value with type T if it is not a
+// zero-value. A zero-value the default empty value for any given CEL type,
+// including empty protobuf message types. If the value is empty, the result
+// of this call will be optional.none().
+//
+// optional.ofNonZeroValue([1, 2, 3]) // optional(list(int))
+// optional.ofNonZeroValue([]) // optional.none()
+// optional.ofNonZeroValue(0) // optional.none()
+// optional.ofNonZeroValue("") // optional.none()
+//
+// # Optional.None
+//
+// Create an empty optional value.
+//
+// # HasValue
+//
+// Determine whether the optional contains a value.
+//
+// optional.of(b'hello').hasValue() // true
+// optional.ofNonZeroValue({}).hasValue() // false
+//
+// # Value
+//
+// Get the value contained by the optional. If the optional does not have a
+// value, the result will be a CEL error.
+//
+// optional.of(b'hello').value() // b'hello'
+// optional.ofNonZeroValue({}).value() // error
+//
+// # Or
+//
+// If the value on the left-hand side is optional.none(), the optional value
+// on the right hand side is returned. If the value on the left-hand set is
+// valued, then it is returned. This operation is short-circuiting and will
+// only evaluate as many links in the `or` chain as are needed to return a
+// non-empty optional value.
+//
+// obj.?field.or(m[?key])
+// l[?index].or(obj.?field.subfield).or(obj.?other)
+//
+// # OrValue
+//
+// Either return the value contained within the optional on the left-hand side
+// or return the alternative value on the right hand side.
+//
+// m[?key].orValue("none")
+//
+// # OptMap
+//
+// Apply a transformation to the optional's underlying value if it is not empty
+// and return an optional typed result based on the transformation. The
+// transformation expression type must return a type T which is wrapped into
+// an optional.
+//
+// msg.?elements.optMap(e, e.size()).orValue(0)
+//
+// # OptFlatMap
+//
+// Introduced in version: 1
+//
+// Apply a transformation to the optional's underlying value if it is not empty
+// and return the result. The transform expression must return an optional(T)
+// rather than type T. This can be useful when dealing with zero values and
+// conditionally generating an empty or non-empty result in ways which cannot
+// be expressed with `optMap`.
+//
+// msg.?elements.optFlatMap(e, e[?0]) // return the first element if present.
+func OptionalTypes(opts ...OptionalTypesOption) EnvOption {
+ lib := &optionalLib{version: math.MaxUint32}
+ for _, opt := range opts {
+ lib = opt(lib)
+ }
+ return Lib(lib)
+}
+
+type optionalLib struct {
+ version uint32
+}
+
+// OptionalTypesOption is a functional interface for configuring the strings library.
+type OptionalTypesOption func(*optionalLib) *optionalLib
+
+// OptionalTypesVersion configures the version of the optional type library.
+//
+// The version limits which functions are available. Only functions introduced
+// below or equal to the given version included in the library. If this option
+// is not set, all functions are available.
+//
+// See the library documentation to determine which version a function was introduced.
+// If the documentation does not state which version a function was introduced, it can
+// be assumed to be introduced at version 0, when the library was first created.
+func OptionalTypesVersion(version uint32) OptionalTypesOption {
+ return func(lib *optionalLib) *optionalLib {
+ lib.version = version
+ return lib
+ }
+}
+
+// LibraryName implements the SingletonLibrary interface method.
+func (lib *optionalLib) LibraryName() string {
+ return "cel.lib.optional"
+}
+
+// CompileOptions implements the Library interface method.
+func (lib *optionalLib) CompileOptions() []EnvOption {
+ paramTypeK := TypeParamType("K")
+ paramTypeV := TypeParamType("V")
+ optionalTypeV := OptionalType(paramTypeV)
+ listTypeV := ListType(paramTypeV)
+ mapTypeKV := MapType(paramTypeK, paramTypeV)
+
+ opts := []EnvOption{
+ // Enable the optional syntax in the parser.
+ enableOptionalSyntax(),
+
+ // Introduce the optional type.
+ Types(types.OptionalType),
+
+ // Configure the optMap and optFlatMap macros.
+ Macros(ReceiverMacro(optMapMacro, 2, optMap)),
+
+ // Global and member functions for working with optional values.
+ Function(optionalOfFunc,
+ Overload("optional_of", []*Type{paramTypeV}, optionalTypeV,
+ UnaryBinding(func(value ref.Val) ref.Val {
+ return types.OptionalOf(value)
+ }))),
+ Function(optionalOfNonZeroValueFunc,
+ Overload("optional_ofNonZeroValue", []*Type{paramTypeV}, optionalTypeV,
+ UnaryBinding(func(value ref.Val) ref.Val {
+ v, isZeroer := value.(traits.Zeroer)
+ if !isZeroer || !v.IsZeroValue() {
+ return types.OptionalOf(value)
+ }
+ return types.OptionalNone
+ }))),
+ Function(optionalNoneFunc,
+ Overload("optional_none", []*Type{}, optionalTypeV,
+ FunctionBinding(func(values ...ref.Val) ref.Val {
+ return types.OptionalNone
+ }))),
+ Function(valueFunc,
+ MemberOverload("optional_value", []*Type{optionalTypeV}, paramTypeV,
+ UnaryBinding(func(value ref.Val) ref.Val {
+ opt := value.(*types.Optional)
+ return opt.GetValue()
+ }))),
+ Function(hasValueFunc,
+ MemberOverload("optional_hasValue", []*Type{optionalTypeV}, BoolType,
+ UnaryBinding(func(value ref.Val) ref.Val {
+ opt := value.(*types.Optional)
+ return types.Bool(opt.HasValue())
+ }))),
+
+ // Implementation of 'or' and 'orValue' are special-cased to support short-circuiting in the
+ // evaluation chain.
+ Function("or",
+ MemberOverload("optional_or_optional", []*Type{optionalTypeV, optionalTypeV}, optionalTypeV)),
+ Function("orValue",
+ MemberOverload("optional_orValue_value", []*Type{optionalTypeV, paramTypeV}, paramTypeV)),
+
+ // OptSelect is handled specially by the type-checker, so the receiver's field type is used to determine the
+ // optput type.
+ Function(operators.OptSelect,
+ Overload("select_optional_field", []*Type{DynType, StringType}, optionalTypeV)),
+
+ // OptIndex is handled mostly like any other indexing operation on a list or map, so the type-checker can use
+ // these signatures to determine type-agreement without any special handling.
+ Function(operators.OptIndex,
+ Overload("list_optindex_optional_int", []*Type{listTypeV, IntType}, optionalTypeV),
+ Overload("optional_list_optindex_optional_int", []*Type{OptionalType(listTypeV), IntType}, optionalTypeV),
+ Overload("map_optindex_optional_value", []*Type{mapTypeKV, paramTypeK}, optionalTypeV),
+ Overload("optional_map_optindex_optional_value", []*Type{OptionalType(mapTypeKV), paramTypeK}, optionalTypeV)),
+
+ // Index overloads to accommodate using an optional value as the operand.
+ Function(operators.Index,
+ Overload("optional_list_index_int", []*Type{OptionalType(listTypeV), IntType}, optionalTypeV),
+ Overload("optional_map_index_value", []*Type{OptionalType(mapTypeKV), paramTypeK}, optionalTypeV)),
+ }
+ if lib.version >= 1 {
+ opts = append(opts, Macros(ReceiverMacro(optFlatMapMacro, 2, optFlatMap)))
+ }
+ return opts
+}
+
+// ProgramOptions implements the Library interface method.
+func (lib *optionalLib) ProgramOptions() []ProgramOption {
+ return []ProgramOption{
+ CustomDecorator(decorateOptionalOr),
+ }
+}
+
+func optMap(meh MacroExprFactory, target ast.Expr, args []ast.Expr) (ast.Expr, *Error) {
+ varIdent := args[0]
+ varName := ""
+ switch varIdent.Kind() {
+ case ast.IdentKind:
+ varName = varIdent.AsIdent()
+ default:
+ return nil, meh.NewError(varIdent.ID(), "optMap() variable name must be a simple identifier")
+ }
+ mapExpr := args[1]
+ return meh.NewCall(
+ operators.Conditional,
+ meh.NewMemberCall(hasValueFunc, target),
+ meh.NewCall(optionalOfFunc,
+ meh.NewComprehension(
+ meh.NewList(),
+ unusedIterVar,
+ varName,
+ meh.NewMemberCall(valueFunc, meh.Copy(target)),
+ meh.NewLiteral(types.False),
+ meh.NewIdent(varName),
+ mapExpr,
+ ),
+ ),
+ meh.NewCall(optionalNoneFunc),
+ ), nil
+}
+
+func optFlatMap(meh MacroExprFactory, target ast.Expr, args []ast.Expr) (ast.Expr, *Error) {
+ varIdent := args[0]
+ varName := ""
+ switch varIdent.Kind() {
+ case ast.IdentKind:
+ varName = varIdent.AsIdent()
+ default:
+ return nil, meh.NewError(varIdent.ID(), "optFlatMap() variable name must be a simple identifier")
+ }
+ mapExpr := args[1]
+ return meh.NewCall(
+ operators.Conditional,
+ meh.NewMemberCall(hasValueFunc, target),
+ meh.NewComprehension(
+ meh.NewList(),
+ unusedIterVar,
+ varName,
+ meh.NewMemberCall(valueFunc, meh.Copy(target)),
+ meh.NewLiteral(types.False),
+ meh.NewIdent(varName),
+ mapExpr,
+ ),
+ meh.NewCall(optionalNoneFunc),
+ ), nil
+}
+
+func enableOptionalSyntax() EnvOption {
+ return func(e *Env) (*Env, error) {
+ e.prsrOpts = append(e.prsrOpts, parser.EnableOptionalSyntax(true))
+ return e, nil
+ }
+}
+
+// EnableErrorOnBadPresenceTest enables error generation when a presence test or optional field
+// selection is performed on a primitive type.
+func EnableErrorOnBadPresenceTest(value bool) EnvOption {
+ return features(featureEnableErrorOnBadPresenceTest, value)
+}
+
+func decorateOptionalOr(i interpreter.Interpretable) (interpreter.Interpretable, error) {
+ call, ok := i.(interpreter.InterpretableCall)
+ if !ok {
+ return i, nil
+ }
+ args := call.Args()
+ if len(args) != 2 {
+ return i, nil
+ }
+ switch call.Function() {
+ case "or":
+ if call.OverloadID() != "" && call.OverloadID() != "optional_or_optional" {
+ return i, nil
+ }
+ return &evalOptionalOr{
+ id: call.ID(),
+ lhs: args[0],
+ rhs: args[1],
+ }, nil
+ case "orValue":
+ if call.OverloadID() != "" && call.OverloadID() != "optional_orValue_value" {
+ return i, nil
+ }
+ return &evalOptionalOrValue{
+ id: call.ID(),
+ lhs: args[0],
+ rhs: args[1],
+ }, nil
+ default:
+ return i, nil
+ }
+}
+
+// evalOptionalOr selects between two optional values, either the first if it has a value, or
+// the second optional expression is evaluated and returned.
+type evalOptionalOr struct {
+ id int64
+ lhs interpreter.Interpretable
+ rhs interpreter.Interpretable
+}
+
+// ID implements the Interpretable interface method.
+func (opt *evalOptionalOr) ID() int64 {
+ return opt.id
+}
+
+// Eval evaluates the left-hand side optional to determine whether it contains a value, else
+// proceeds with the right-hand side evaluation.
+func (opt *evalOptionalOr) Eval(ctx interpreter.Activation) ref.Val {
+ // short-circuit lhs.
+ optLHS := opt.lhs.Eval(ctx)
+ optVal, ok := optLHS.(*types.Optional)
+ if !ok {
+ return optLHS
+ }
+ if optVal.HasValue() {
+ return optVal
+ }
+ return opt.rhs.Eval(ctx)
+}
+
+// evalOptionalOrValue selects between an optional or a concrete value. If the optional has a value,
+// its value is returned, otherwise the alternative value expression is evaluated and returned.
+type evalOptionalOrValue struct {
+ id int64
+ lhs interpreter.Interpretable
+ rhs interpreter.Interpretable
+}
+
+// ID implements the Interpretable interface method.
+func (opt *evalOptionalOrValue) ID() int64 {
+ return opt.id
+}
+
+// Eval evaluates the left-hand side optional to determine whether it contains a value, else
+// proceeds with the right-hand side evaluation.
+func (opt *evalOptionalOrValue) Eval(ctx interpreter.Activation) ref.Val {
+ // short-circuit lhs.
+ optLHS := opt.lhs.Eval(ctx)
+ optVal, ok := optLHS.(*types.Optional)
+ if !ok {
+ return optLHS
+ }
+ if optVal.HasValue() {
+ return optVal.GetValue()
+ }
+ return opt.rhs.Eval(ctx)
+}
+
+type timeUTCLibrary struct{}
+
+func (timeUTCLibrary) CompileOptions() []EnvOption {
+ return timeOverloadDeclarations
+}
+
+func (timeUTCLibrary) ProgramOptions() []ProgramOption {
+ return []ProgramOption{}
+}
+
+// Declarations and functions which enable using UTC on time.Time inputs when the timezone is unspecified
+// in the CEL expression.
+var (
+ utcTZ = types.String("UTC")
+
+ timeOverloadDeclarations = []EnvOption{
+ Function(overloads.TimeGetHours,
+ MemberOverload(overloads.DurationToHours, []*Type{DurationType}, IntType,
+ UnaryBinding(types.DurationGetHours))),
+ Function(overloads.TimeGetMinutes,
+ MemberOverload(overloads.DurationToMinutes, []*Type{DurationType}, IntType,
+ UnaryBinding(types.DurationGetMinutes))),
+ Function(overloads.TimeGetSeconds,
+ MemberOverload(overloads.DurationToSeconds, []*Type{DurationType}, IntType,
+ UnaryBinding(types.DurationGetSeconds))),
+ Function(overloads.TimeGetMilliseconds,
+ MemberOverload(overloads.DurationToMilliseconds, []*Type{DurationType}, IntType,
+ UnaryBinding(types.DurationGetMilliseconds))),
+ Function(overloads.TimeGetFullYear,
+ MemberOverload(overloads.TimestampToYear, []*Type{TimestampType}, IntType,
+ UnaryBinding(func(ts ref.Val) ref.Val {
+ return timestampGetFullYear(ts, utcTZ)
+ }),
+ ),
+ MemberOverload(overloads.TimestampToYearWithTz, []*Type{TimestampType, StringType}, IntType,
+ BinaryBinding(timestampGetFullYear),
+ ),
+ ),
+ Function(overloads.TimeGetMonth,
+ MemberOverload(overloads.TimestampToMonth, []*Type{TimestampType}, IntType,
+ UnaryBinding(func(ts ref.Val) ref.Val {
+ return timestampGetMonth(ts, utcTZ)
+ }),
+ ),
+ MemberOverload(overloads.TimestampToMonthWithTz, []*Type{TimestampType, StringType}, IntType,
+ BinaryBinding(timestampGetMonth),
+ ),
+ ),
+ Function(overloads.TimeGetDayOfYear,
+ MemberOverload(overloads.TimestampToDayOfYear, []*Type{TimestampType}, IntType,
+ UnaryBinding(func(ts ref.Val) ref.Val {
+ return timestampGetDayOfYear(ts, utcTZ)
+ }),
+ ),
+ MemberOverload(overloads.TimestampToDayOfYearWithTz, []*Type{TimestampType, StringType}, IntType,
+ BinaryBinding(func(ts, tz ref.Val) ref.Val {
+ return timestampGetDayOfYear(ts, tz)
+ }),
+ ),
+ ),
+ Function(overloads.TimeGetDayOfMonth,
+ MemberOverload(overloads.TimestampToDayOfMonthZeroBased, []*Type{TimestampType}, IntType,
+ UnaryBinding(func(ts ref.Val) ref.Val {
+ return timestampGetDayOfMonthZeroBased(ts, utcTZ)
+ }),
+ ),
+ MemberOverload(overloads.TimestampToDayOfMonthZeroBasedWithTz, []*Type{TimestampType, StringType}, IntType,
+ BinaryBinding(timestampGetDayOfMonthZeroBased),
+ ),
+ ),
+ Function(overloads.TimeGetDate,
+ MemberOverload(overloads.TimestampToDayOfMonthOneBased, []*Type{TimestampType}, IntType,
+ UnaryBinding(func(ts ref.Val) ref.Val {
+ return timestampGetDayOfMonthOneBased(ts, utcTZ)
+ }),
+ ),
+ MemberOverload(overloads.TimestampToDayOfMonthOneBasedWithTz, []*Type{TimestampType, StringType}, IntType,
+ BinaryBinding(timestampGetDayOfMonthOneBased),
+ ),
+ ),
+ Function(overloads.TimeGetDayOfWeek,
+ MemberOverload(overloads.TimestampToDayOfWeek, []*Type{TimestampType}, IntType,
+ UnaryBinding(func(ts ref.Val) ref.Val {
+ return timestampGetDayOfWeek(ts, utcTZ)
+ }),
+ ),
+ MemberOverload(overloads.TimestampToDayOfWeekWithTz, []*Type{TimestampType, StringType}, IntType,
+ BinaryBinding(timestampGetDayOfWeek),
+ ),
+ ),
+ Function(overloads.TimeGetHours,
+ MemberOverload(overloads.TimestampToHours, []*Type{TimestampType}, IntType,
+ UnaryBinding(func(ts ref.Val) ref.Val {
+ return timestampGetHours(ts, utcTZ)
+ }),
+ ),
+ MemberOverload(overloads.TimestampToHoursWithTz, []*Type{TimestampType, StringType}, IntType,
+ BinaryBinding(timestampGetHours),
+ ),
+ ),
+ Function(overloads.TimeGetMinutes,
+ MemberOverload(overloads.TimestampToMinutes, []*Type{TimestampType}, IntType,
+ UnaryBinding(func(ts ref.Val) ref.Val {
+ return timestampGetMinutes(ts, utcTZ)
+ }),
+ ),
+ MemberOverload(overloads.TimestampToMinutesWithTz, []*Type{TimestampType, StringType}, IntType,
+ BinaryBinding(timestampGetMinutes),
+ ),
+ ),
+ Function(overloads.TimeGetSeconds,
+ MemberOverload(overloads.TimestampToSeconds, []*Type{TimestampType}, IntType,
+ UnaryBinding(func(ts ref.Val) ref.Val {
+ return timestampGetSeconds(ts, utcTZ)
+ }),
+ ),
+ MemberOverload(overloads.TimestampToSecondsWithTz, []*Type{TimestampType, StringType}, IntType,
+ BinaryBinding(timestampGetSeconds),
+ ),
+ ),
+ Function(overloads.TimeGetMilliseconds,
+ MemberOverload(overloads.TimestampToMilliseconds, []*Type{TimestampType}, IntType,
+ UnaryBinding(func(ts ref.Val) ref.Val {
+ return timestampGetMilliseconds(ts, utcTZ)
+ }),
+ ),
+ MemberOverload(overloads.TimestampToMillisecondsWithTz, []*Type{TimestampType, StringType}, IntType,
+ BinaryBinding(timestampGetMilliseconds),
+ ),
+ ),
+ }
+)
+
+func timestampGetFullYear(ts, tz ref.Val) ref.Val {
+ t, err := inTimeZone(ts, tz)
+ if err != nil {
+ return types.NewErr(err.Error())
+ }
+ return types.Int(t.Year())
+}
+
+func timestampGetMonth(ts, tz ref.Val) ref.Val {
+ t, err := inTimeZone(ts, tz)
+ if err != nil {
+ return types.NewErr(err.Error())
+ }
+ // CEL spec indicates that the month should be 0-based, but the Time value
+ // for Month() is 1-based.
+ return types.Int(t.Month() - 1)
+}
+
+func timestampGetDayOfYear(ts, tz ref.Val) ref.Val {
+ t, err := inTimeZone(ts, tz)
+ if err != nil {
+ return types.NewErr(err.Error())
+ }
+ return types.Int(t.YearDay() - 1)
+}
+
+func timestampGetDayOfMonthZeroBased(ts, tz ref.Val) ref.Val {
+ t, err := inTimeZone(ts, tz)
+ if err != nil {
+ return types.NewErr(err.Error())
+ }
+ return types.Int(t.Day() - 1)
+}
+
+func timestampGetDayOfMonthOneBased(ts, tz ref.Val) ref.Val {
+ t, err := inTimeZone(ts, tz)
+ if err != nil {
+ return types.NewErr(err.Error())
+ }
+ return types.Int(t.Day())
+}
+
+func timestampGetDayOfWeek(ts, tz ref.Val) ref.Val {
+ t, err := inTimeZone(ts, tz)
+ if err != nil {
+ return types.NewErr(err.Error())
+ }
+ return types.Int(t.Weekday())
+}
+
+func timestampGetHours(ts, tz ref.Val) ref.Val {
+ t, err := inTimeZone(ts, tz)
+ if err != nil {
+ return types.NewErr(err.Error())
+ }
+ return types.Int(t.Hour())
+}
+
+func timestampGetMinutes(ts, tz ref.Val) ref.Val {
+ t, err := inTimeZone(ts, tz)
+ if err != nil {
+ return types.NewErr(err.Error())
+ }
+ return types.Int(t.Minute())
+}
+
+func timestampGetSeconds(ts, tz ref.Val) ref.Val {
+ t, err := inTimeZone(ts, tz)
+ if err != nil {
+ return types.NewErr(err.Error())
+ }
+ return types.Int(t.Second())
+}
+
+func timestampGetMilliseconds(ts, tz ref.Val) ref.Val {
+ t, err := inTimeZone(ts, tz)
+ if err != nil {
+ return types.NewErr(err.Error())
+ }
+ return types.Int(t.Nanosecond() / 1000000)
+}
+
+func inTimeZone(ts, tz ref.Val) (time.Time, error) {
+ t := ts.(types.Timestamp)
+ val := string(tz.(types.String))
+ ind := strings.Index(val, ":")
+ if ind == -1 {
+ loc, err := time.LoadLocation(val)
+ if err != nil {
+ return time.Time{}, err
+ }
+ return t.In(loc), nil
+ }
+
+ // If the input is not the name of a timezone (for example, 'US/Central'), it should be a numerical offset from UTC
+ // in the format ^(+|-)(0[0-9]|1[0-4]):[0-5][0-9]$. The numerical input is parsed in terms of hours and minutes.
+ hr, err := strconv.Atoi(string(val[0:ind]))
+ if err != nil {
+ return time.Time{}, err
+ }
+ min, err := strconv.Atoi(string(val[ind+1:]))
+ if err != nil {
+ return time.Time{}, err
+ }
+ var offset int
+ if string(val[0]) == "-" {
+ offset = hr*60 - min
+ } else {
+ offset = hr*60 + min
+ }
+ secondsEastOfUTC := int((time.Duration(offset) * time.Minute).Seconds())
+ timezone := time.FixedZone("", secondsEastOfUTC)
+ return t.In(timezone), nil
+}
diff --git a/vendor/github.com/google/cel-go/cel/macro.go b/vendor/github.com/google/cel-go/cel/macro.go
new file mode 100644
index 000000000000..4db1fd57a9cc
--- /dev/null
+++ b/vendor/github.com/google/cel-go/cel/macro.go
@@ -0,0 +1,576 @@
+// Copyright 2022 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package cel
+
+import (
+ "fmt"
+
+ "github.com/google/cel-go/common"
+ "github.com/google/cel-go/common/ast"
+ "github.com/google/cel-go/common/types"
+ "github.com/google/cel-go/parser"
+
+ exprpb "google.golang.org/genproto/googleapis/api/expr/v1alpha1"
+)
+
+// Macro describes a function signature to match and the MacroExpander to apply.
+//
+// Note: when a Macro should apply to multiple overloads (based on arg count) of a given function,
+// a Macro should be created per arg-count or as a var arg macro.
+type Macro = parser.Macro
+
+// MacroFactory defines an expansion function which converts a call and its arguments to a cel.Expr value.
+type MacroFactory = parser.MacroExpander
+
+// MacroExprFactory assists with the creation of Expr values in a manner which is consistent
+// the internal semantics and id generation behaviors of the parser and checker libraries.
+type MacroExprFactory = parser.ExprHelper
+
+// MacroExpander converts a call and its associated arguments into a protobuf Expr representation.
+//
+// If the MacroExpander determines within the implementation that an expansion is not needed it may return
+// a nil Expr value to indicate a non-match. However, if an expansion is to be performed, but the arguments
+// are not well-formed, the result of the expansion will be an error.
+//
+// The MacroExpander accepts as arguments a MacroExprHelper as well as the arguments used in the function call
+// and produces as output an Expr ast node.
+//
+// Note: when the Macro.IsReceiverStyle() method returns true, the target argument will be nil.
+type MacroExpander func(eh MacroExprHelper, target *exprpb.Expr, args []*exprpb.Expr) (*exprpb.Expr, *Error)
+
+// MacroExprHelper exposes helper methods for creating new expressions within a CEL abstract syntax tree.
+// ExprHelper assists with the manipulation of proto-based Expr values in a manner which is
+// consistent with the source position and expression id generation code leveraged by both
+// the parser and type-checker.
+type MacroExprHelper interface {
+ // Copy the input expression with a brand new set of identifiers.
+ Copy(*exprpb.Expr) *exprpb.Expr
+
+ // LiteralBool creates an Expr value for a bool literal.
+ LiteralBool(value bool) *exprpb.Expr
+
+ // LiteralBytes creates an Expr value for a byte literal.
+ LiteralBytes(value []byte) *exprpb.Expr
+
+ // LiteralDouble creates an Expr value for double literal.
+ LiteralDouble(value float64) *exprpb.Expr
+
+ // LiteralInt creates an Expr value for an int literal.
+ LiteralInt(value int64) *exprpb.Expr
+
+ // LiteralString creates am Expr value for a string literal.
+ LiteralString(value string) *exprpb.Expr
+
+ // LiteralUint creates an Expr value for a uint literal.
+ LiteralUint(value uint64) *exprpb.Expr
+
+ // NewList creates a CreateList instruction where the list is comprised of the optional set
+ // of elements provided as arguments.
+ NewList(elems ...*exprpb.Expr) *exprpb.Expr
+
+ // NewMap creates a CreateStruct instruction for a map where the map is comprised of the
+ // optional set of key, value entries.
+ NewMap(entries ...*exprpb.Expr_CreateStruct_Entry) *exprpb.Expr
+
+ // NewMapEntry creates a Map Entry for the key, value pair.
+ NewMapEntry(key *exprpb.Expr, val *exprpb.Expr, optional bool) *exprpb.Expr_CreateStruct_Entry
+
+ // NewObject creates a CreateStruct instruction for an object with a given type name and
+ // optional set of field initializers.
+ NewObject(typeName string, fieldInits ...*exprpb.Expr_CreateStruct_Entry) *exprpb.Expr
+
+ // NewObjectFieldInit creates a new Object field initializer from the field name and value.
+ NewObjectFieldInit(field string, init *exprpb.Expr, optional bool) *exprpb.Expr_CreateStruct_Entry
+
+ // Fold creates a fold comprehension instruction.
+ //
+ // - iterVar is the iteration variable name.
+ // - iterRange represents the expression that resolves to a list or map where the elements or
+ // keys (respectively) will be iterated over.
+ // - accuVar is the accumulation variable name, typically parser.AccumulatorName.
+ // - accuInit is the initial expression whose value will be set for the accuVar prior to
+ // folding.
+ // - condition is the expression to test to determine whether to continue folding.
+ // - step is the expression to evaluation at the conclusion of a single fold iteration.
+ // - result is the computation to evaluate at the conclusion of the fold.
+ //
+ // The accuVar should not shadow variable names that you would like to reference within the
+ // environment in the step and condition expressions. Presently, the name __result__ is commonly
+ // used by built-in macros but this may change in the future.
+ Fold(iterVar string,
+ iterRange *exprpb.Expr,
+ accuVar string,
+ accuInit *exprpb.Expr,
+ condition *exprpb.Expr,
+ step *exprpb.Expr,
+ result *exprpb.Expr) *exprpb.Expr
+
+ // Ident creates an identifier Expr value.
+ Ident(name string) *exprpb.Expr
+
+ // AccuIdent returns an accumulator identifier for use with comprehension results.
+ AccuIdent() *exprpb.Expr
+
+ // GlobalCall creates a function call Expr value for a global (free) function.
+ GlobalCall(function string, args ...*exprpb.Expr) *exprpb.Expr
+
+ // ReceiverCall creates a function call Expr value for a receiver-style function.
+ ReceiverCall(function string, target *exprpb.Expr, args ...*exprpb.Expr) *exprpb.Expr
+
+ // PresenceTest creates a Select TestOnly Expr value for modelling has() semantics.
+ PresenceTest(operand *exprpb.Expr, field string) *exprpb.Expr
+
+ // Select create a field traversal Expr value.
+ Select(operand *exprpb.Expr, field string) *exprpb.Expr
+
+ // OffsetLocation returns the Location of the expression identifier.
+ OffsetLocation(exprID int64) common.Location
+
+ // NewError associates an error message with a given expression id.
+ NewError(exprID int64, message string) *Error
+}
+
+// GlobalMacro creates a Macro for a global function with the specified arg count.
+func GlobalMacro(function string, argCount int, factory MacroFactory) Macro {
+ return parser.NewGlobalMacro(function, argCount, factory)
+}
+
+// ReceiverMacro creates a Macro for a receiver function matching the specified arg count.
+func ReceiverMacro(function string, argCount int, factory MacroFactory) Macro {
+ return parser.NewReceiverMacro(function, argCount, factory)
+}
+
+// GlobalVarArgMacro creates a Macro for a global function with a variable arg count.
+func GlobalVarArgMacro(function string, factory MacroFactory) Macro {
+ return parser.NewGlobalVarArgMacro(function, factory)
+}
+
+// ReceiverVarArgMacro creates a Macro for a receiver function matching a variable arg count.
+func ReceiverVarArgMacro(function string, factory MacroFactory) Macro {
+ return parser.NewReceiverVarArgMacro(function, factory)
+}
+
+// NewGlobalMacro creates a Macro for a global function with the specified arg count.
+//
+// Deprecated: use GlobalMacro
+func NewGlobalMacro(function string, argCount int, expander MacroExpander) Macro {
+ expand := adaptingExpander{expander}
+ return parser.NewGlobalMacro(function, argCount, expand.Expander)
+}
+
+// NewReceiverMacro creates a Macro for a receiver function matching the specified arg count.
+//
+// Deprecated: use ReceiverMacro
+func NewReceiverMacro(function string, argCount int, expander MacroExpander) Macro {
+ expand := adaptingExpander{expander}
+ return parser.NewReceiverMacro(function, argCount, expand.Expander)
+}
+
+// NewGlobalVarArgMacro creates a Macro for a global function with a variable arg count.
+//
+// Deprecated: use GlobalVarArgMacro
+func NewGlobalVarArgMacro(function string, expander MacroExpander) Macro {
+ expand := adaptingExpander{expander}
+ return parser.NewGlobalVarArgMacro(function, expand.Expander)
+}
+
+// NewReceiverVarArgMacro creates a Macro for a receiver function matching a variable arg count.
+//
+// Deprecated: use ReceiverVarArgMacro
+func NewReceiverVarArgMacro(function string, expander MacroExpander) Macro {
+ expand := adaptingExpander{expander}
+ return parser.NewReceiverVarArgMacro(function, expand.Expander)
+}
+
+// HasMacroExpander expands the input call arguments into a presence test, e.g. has(.field)
+func HasMacroExpander(meh MacroExprHelper, target *exprpb.Expr, args []*exprpb.Expr) (*exprpb.Expr, *Error) {
+ ph, err := toParserHelper(meh)
+ if err != nil {
+ return nil, err
+ }
+ arg, err := adaptToExpr(args[0])
+ if err != nil {
+ return nil, err
+ }
+ if arg.Kind() == ast.SelectKind {
+ s := arg.AsSelect()
+ return adaptToProto(ph.NewPresenceTest(s.Operand(), s.FieldName()))
+ }
+ return nil, ph.NewError(arg.ID(), "invalid argument to has() macro")
+}
+
+// ExistsMacroExpander expands the input call arguments into a comprehension that returns true if any of the
+// elements in the range match the predicate expressions:
+// .exists(, )
+func ExistsMacroExpander(meh MacroExprHelper, target *exprpb.Expr, args []*exprpb.Expr) (*exprpb.Expr, *Error) {
+ ph, err := toParserHelper(meh)
+ if err != nil {
+ return nil, err
+ }
+ out, err := parser.MakeExists(ph, mustAdaptToExpr(target), mustAdaptToExprs(args))
+ if err != nil {
+ return nil, err
+ }
+ return adaptToProto(out)
+}
+
+// ExistsOneMacroExpander expands the input call arguments into a comprehension that returns true if exactly
+// one of the elements in the range match the predicate expressions:
+// .exists_one(, )
+func ExistsOneMacroExpander(meh MacroExprHelper, target *exprpb.Expr, args []*exprpb.Expr) (*exprpb.Expr, *Error) {
+ ph, err := toParserHelper(meh)
+ if err != nil {
+ return nil, err
+ }
+ out, err := parser.MakeExistsOne(ph, mustAdaptToExpr(target), mustAdaptToExprs(args))
+ if err != nil {
+ return nil, err
+ }
+ return adaptToProto(out)
+}
+
+// MapMacroExpander expands the input call arguments into a comprehension that transforms each element in the
+// input to produce an output list.
+//
+// There are two call patterns supported by map:
+//
+// .map(, )
+// .map(, , )
+//
+// In the second form only iterVar values which return true when provided to the predicate expression
+// are transformed.
+func MapMacroExpander(meh MacroExprHelper, target *exprpb.Expr, args []*exprpb.Expr) (*exprpb.Expr, *Error) {
+ ph, err := toParserHelper(meh)
+ if err != nil {
+ return nil, err
+ }
+ out, err := parser.MakeMap(ph, mustAdaptToExpr(target), mustAdaptToExprs(args))
+ if err != nil {
+ return nil, err
+ }
+ return adaptToProto(out)
+}
+
+// FilterMacroExpander expands the input call arguments into a comprehension which produces a list which contains
+// only elements which match the provided predicate expression:
+// .filter(, )
+func FilterMacroExpander(meh MacroExprHelper, target *exprpb.Expr, args []*exprpb.Expr) (*exprpb.Expr, *Error) {
+ ph, err := toParserHelper(meh)
+ if err != nil {
+ return nil, err
+ }
+ out, err := parser.MakeFilter(ph, mustAdaptToExpr(target), mustAdaptToExprs(args))
+ if err != nil {
+ return nil, err
+ }
+ return adaptToProto(out)
+}
+
+var (
+ // Aliases to each macro in the CEL standard environment.
+ // Note: reassigning these macro variables may result in undefined behavior.
+
+ // HasMacro expands "has(m.f)" which tests the presence of a field, avoiding the need to
+ // specify the field as a string.
+ HasMacro = parser.HasMacro
+
+ // AllMacro expands "range.all(var, predicate)" into a comprehension which ensures that all
+ // elements in the range satisfy the predicate.
+ AllMacro = parser.AllMacro
+
+ // ExistsMacro expands "range.exists(var, predicate)" into a comprehension which ensures that
+ // some element in the range satisfies the predicate.
+ ExistsMacro = parser.ExistsMacro
+
+ // ExistsOneMacro expands "range.exists_one(var, predicate)", which is true if for exactly one
+ // element in range the predicate holds.
+ ExistsOneMacro = parser.ExistsOneMacro
+
+ // MapMacro expands "range.map(var, function)" into a comprehension which applies the function
+ // to each element in the range to produce a new list.
+ MapMacro = parser.MapMacro
+
+ // MapFilterMacro expands "range.map(var, predicate, function)" into a comprehension which
+ // first filters the elements in the range by the predicate, then applies the transform function
+ // to produce a new list.
+ MapFilterMacro = parser.MapFilterMacro
+
+ // FilterMacro expands "range.filter(var, predicate)" into a comprehension which filters
+ // elements in the range, producing a new list from the elements that satisfy the predicate.
+ FilterMacro = parser.FilterMacro
+
+ // StandardMacros provides an alias to all the CEL macros defined in the standard environment.
+ StandardMacros = []Macro{
+ HasMacro, AllMacro, ExistsMacro, ExistsOneMacro, MapMacro, MapFilterMacro, FilterMacro,
+ }
+
+ // NoMacros provides an alias to an empty list of macros
+ NoMacros = []Macro{}
+)
+
+type adaptingExpander struct {
+ legacyExpander MacroExpander
+}
+
+func (adapt *adaptingExpander) Expander(eh parser.ExprHelper, target ast.Expr, args []ast.Expr) (ast.Expr, *common.Error) {
+ var legacyTarget *exprpb.Expr = nil
+ var err *Error = nil
+ if target != nil {
+ legacyTarget, err = adaptToProto(target)
+ if err != nil {
+ return nil, err
+ }
+ }
+ legacyArgs := make([]*exprpb.Expr, len(args))
+ for i, arg := range args {
+ legacyArgs[i], err = adaptToProto(arg)
+ if err != nil {
+ return nil, err
+ }
+ }
+ ah := &adaptingHelper{modernHelper: eh}
+ legacyExpr, err := adapt.legacyExpander(ah, legacyTarget, legacyArgs)
+ if err != nil {
+ return nil, err
+ }
+ ex, err := adaptToExpr(legacyExpr)
+ if err != nil {
+ return nil, err
+ }
+ return ex, nil
+}
+
+func wrapErr(id int64, message string, err error) *common.Error {
+ return &common.Error{
+ Location: common.NoLocation,
+ Message: fmt.Sprintf("%s: %v", message, err),
+ ExprID: id,
+ }
+}
+
+type adaptingHelper struct {
+ modernHelper parser.ExprHelper
+}
+
+// Copy the input expression with a brand new set of identifiers.
+func (ah *adaptingHelper) Copy(e *exprpb.Expr) *exprpb.Expr {
+ return mustAdaptToProto(ah.modernHelper.Copy(mustAdaptToExpr(e)))
+}
+
+// LiteralBool creates an Expr value for a bool literal.
+func (ah *adaptingHelper) LiteralBool(value bool) *exprpb.Expr {
+ return mustAdaptToProto(ah.modernHelper.NewLiteral(types.Bool(value)))
+}
+
+// LiteralBytes creates an Expr value for a byte literal.
+func (ah *adaptingHelper) LiteralBytes(value []byte) *exprpb.Expr {
+ return mustAdaptToProto(ah.modernHelper.NewLiteral(types.Bytes(value)))
+}
+
+// LiteralDouble creates an Expr value for double literal.
+func (ah *adaptingHelper) LiteralDouble(value float64) *exprpb.Expr {
+ return mustAdaptToProto(ah.modernHelper.NewLiteral(types.Double(value)))
+}
+
+// LiteralInt creates an Expr value for an int literal.
+func (ah *adaptingHelper) LiteralInt(value int64) *exprpb.Expr {
+ return mustAdaptToProto(ah.modernHelper.NewLiteral(types.Int(value)))
+}
+
+// LiteralString creates am Expr value for a string literal.
+func (ah *adaptingHelper) LiteralString(value string) *exprpb.Expr {
+ return mustAdaptToProto(ah.modernHelper.NewLiteral(types.String(value)))
+}
+
+// LiteralUint creates an Expr value for a uint literal.
+func (ah *adaptingHelper) LiteralUint(value uint64) *exprpb.Expr {
+ return mustAdaptToProto(ah.modernHelper.NewLiteral(types.Uint(value)))
+}
+
+// NewList creates a CreateList instruction where the list is comprised of the optional set
+// of elements provided as arguments.
+func (ah *adaptingHelper) NewList(elems ...*exprpb.Expr) *exprpb.Expr {
+ return mustAdaptToProto(ah.modernHelper.NewList(mustAdaptToExprs(elems)...))
+}
+
+// NewMap creates a CreateStruct instruction for a map where the map is comprised of the
+// optional set of key, value entries.
+func (ah *adaptingHelper) NewMap(entries ...*exprpb.Expr_CreateStruct_Entry) *exprpb.Expr {
+ adaptedEntries := make([]ast.EntryExpr, len(entries))
+ for i, e := range entries {
+ adaptedEntries[i] = mustAdaptToEntryExpr(e)
+ }
+ return mustAdaptToProto(ah.modernHelper.NewMap(adaptedEntries...))
+}
+
+// NewMapEntry creates a Map Entry for the key, value pair.
+func (ah *adaptingHelper) NewMapEntry(key *exprpb.Expr, val *exprpb.Expr, optional bool) *exprpb.Expr_CreateStruct_Entry {
+ return mustAdaptToProtoEntry(
+ ah.modernHelper.NewMapEntry(mustAdaptToExpr(key), mustAdaptToExpr(val), optional))
+}
+
+// NewObject creates a CreateStruct instruction for an object with a given type name and
+// optional set of field initializers.
+func (ah *adaptingHelper) NewObject(typeName string, fieldInits ...*exprpb.Expr_CreateStruct_Entry) *exprpb.Expr {
+ adaptedEntries := make([]ast.EntryExpr, len(fieldInits))
+ for i, e := range fieldInits {
+ adaptedEntries[i] = mustAdaptToEntryExpr(e)
+ }
+ return mustAdaptToProto(ah.modernHelper.NewStruct(typeName, adaptedEntries...))
+}
+
+// NewObjectFieldInit creates a new Object field initializer from the field name and value.
+func (ah *adaptingHelper) NewObjectFieldInit(field string, init *exprpb.Expr, optional bool) *exprpb.Expr_CreateStruct_Entry {
+ return mustAdaptToProtoEntry(
+ ah.modernHelper.NewStructField(field, mustAdaptToExpr(init), optional))
+}
+
+// Fold creates a fold comprehension instruction.
+//
+// - iterVar is the iteration variable name.
+// - iterRange represents the expression that resolves to a list or map where the elements or
+// keys (respectively) will be iterated over.
+// - accuVar is the accumulation variable name, typically parser.AccumulatorName.
+// - accuInit is the initial expression whose value will be set for the accuVar prior to
+// folding.
+// - condition is the expression to test to determine whether to continue folding.
+// - step is the expression to evaluation at the conclusion of a single fold iteration.
+// - result is the computation to evaluate at the conclusion of the fold.
+//
+// The accuVar should not shadow variable names that you would like to reference within the
+// environment in the step and condition expressions. Presently, the name __result__ is commonly
+// used by built-in macros but this may change in the future.
+func (ah *adaptingHelper) Fold(iterVar string,
+ iterRange *exprpb.Expr,
+ accuVar string,
+ accuInit *exprpb.Expr,
+ condition *exprpb.Expr,
+ step *exprpb.Expr,
+ result *exprpb.Expr) *exprpb.Expr {
+ return mustAdaptToProto(
+ ah.modernHelper.NewComprehension(
+ mustAdaptToExpr(iterRange),
+ iterVar,
+ accuVar,
+ mustAdaptToExpr(accuInit),
+ mustAdaptToExpr(condition),
+ mustAdaptToExpr(step),
+ mustAdaptToExpr(result),
+ ),
+ )
+}
+
+// Ident creates an identifier Expr value.
+func (ah *adaptingHelper) Ident(name string) *exprpb.Expr {
+ return mustAdaptToProto(ah.modernHelper.NewIdent(name))
+}
+
+// AccuIdent returns an accumulator identifier for use with comprehension results.
+func (ah *adaptingHelper) AccuIdent() *exprpb.Expr {
+ return mustAdaptToProto(ah.modernHelper.NewAccuIdent())
+}
+
+// GlobalCall creates a function call Expr value for a global (free) function.
+func (ah *adaptingHelper) GlobalCall(function string, args ...*exprpb.Expr) *exprpb.Expr {
+ return mustAdaptToProto(ah.modernHelper.NewCall(function, mustAdaptToExprs(args)...))
+}
+
+// ReceiverCall creates a function call Expr value for a receiver-style function.
+func (ah *adaptingHelper) ReceiverCall(function string, target *exprpb.Expr, args ...*exprpb.Expr) *exprpb.Expr {
+ return mustAdaptToProto(
+ ah.modernHelper.NewMemberCall(function, mustAdaptToExpr(target), mustAdaptToExprs(args)...))
+}
+
+// PresenceTest creates a Select TestOnly Expr value for modelling has() semantics.
+func (ah *adaptingHelper) PresenceTest(operand *exprpb.Expr, field string) *exprpb.Expr {
+ op := mustAdaptToExpr(operand)
+ return mustAdaptToProto(ah.modernHelper.NewPresenceTest(op, field))
+}
+
+// Select create a field traversal Expr value.
+func (ah *adaptingHelper) Select(operand *exprpb.Expr, field string) *exprpb.Expr {
+ op := mustAdaptToExpr(operand)
+ return mustAdaptToProto(ah.modernHelper.NewSelect(op, field))
+}
+
+// OffsetLocation returns the Location of the expression identifier.
+func (ah *adaptingHelper) OffsetLocation(exprID int64) common.Location {
+ return ah.modernHelper.OffsetLocation(exprID)
+}
+
+// NewError associates an error message with a given expression id.
+func (ah *adaptingHelper) NewError(exprID int64, message string) *Error {
+ return ah.modernHelper.NewError(exprID, message)
+}
+
+func mustAdaptToExprs(exprs []*exprpb.Expr) []ast.Expr {
+ adapted := make([]ast.Expr, len(exprs))
+ for i, e := range exprs {
+ adapted[i] = mustAdaptToExpr(e)
+ }
+ return adapted
+}
+
+func mustAdaptToExpr(e *exprpb.Expr) ast.Expr {
+ out, _ := adaptToExpr(e)
+ return out
+}
+
+func adaptToExpr(e *exprpb.Expr) (ast.Expr, *Error) {
+ if e == nil {
+ return nil, nil
+ }
+ out, err := ast.ProtoToExpr(e)
+ if err != nil {
+ return nil, wrapErr(e.GetId(), "proto conversion failure", err)
+ }
+ return out, nil
+}
+
+func mustAdaptToEntryExpr(e *exprpb.Expr_CreateStruct_Entry) ast.EntryExpr {
+ out, _ := ast.ProtoToEntryExpr(e)
+ return out
+}
+
+func mustAdaptToProto(e ast.Expr) *exprpb.Expr {
+ out, _ := adaptToProto(e)
+ return out
+}
+
+func adaptToProto(e ast.Expr) (*exprpb.Expr, *Error) {
+ if e == nil {
+ return nil, nil
+ }
+ out, err := ast.ExprToProto(e)
+ if err != nil {
+ return nil, wrapErr(e.ID(), "expr conversion failure", err)
+ }
+ return out, nil
+}
+
+func mustAdaptToProtoEntry(e ast.EntryExpr) *exprpb.Expr_CreateStruct_Entry {
+ out, _ := ast.EntryExprToProto(e)
+ return out
+}
+
+func toParserHelper(meh MacroExprHelper) (parser.ExprHelper, *Error) {
+ ah, ok := meh.(*adaptingHelper)
+ if !ok {
+ return nil, common.NewError(0,
+ fmt.Sprintf("unsupported macro helper: %v (%T)", meh, meh),
+ common.NoLocation)
+ }
+ return ah.modernHelper, nil
+}
diff --git a/vendor/github.com/google/cel-go/cel/optimizer.go b/vendor/github.com/google/cel-go/cel/optimizer.go
new file mode 100644
index 000000000000..ec02773a458e
--- /dev/null
+++ b/vendor/github.com/google/cel-go/cel/optimizer.go
@@ -0,0 +1,525 @@
+// Copyright 2023 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package cel
+
+import (
+ "sort"
+
+ "github.com/google/cel-go/common"
+ "github.com/google/cel-go/common/ast"
+ "github.com/google/cel-go/common/types"
+ "github.com/google/cel-go/common/types/ref"
+)
+
+// StaticOptimizer contains a sequence of ASTOptimizer instances which will be applied in order.
+//
+// The static optimizer normalizes expression ids and type-checking run between optimization
+// passes to ensure that the final optimized output is a valid expression with metadata consistent
+// with what would have been generated from a parsed and checked expression.
+//
+// Note: source position information is best-effort and likely wrong, but optimized expressions
+// should be suitable for calls to parser.Unparse.
+type StaticOptimizer struct {
+ optimizers []ASTOptimizer
+}
+
+// NewStaticOptimizer creates a StaticOptimizer with a sequence of ASTOptimizer's to be applied
+// to a checked expression.
+func NewStaticOptimizer(optimizers ...ASTOptimizer) *StaticOptimizer {
+ return &StaticOptimizer{
+ optimizers: optimizers,
+ }
+}
+
+// Optimize applies a sequence of optimizations to an Ast within a given environment.
+//
+// If issues are encountered, the Issues.Err() return value will be non-nil.
+func (opt *StaticOptimizer) Optimize(env *Env, a *Ast) (*Ast, *Issues) {
+ // Make a copy of the AST to be optimized.
+ optimized := ast.Copy(a.impl)
+ ids := newIDGenerator(ast.MaxID(a.impl))
+
+ // Create the optimizer context, could be pooled in the future.
+ issues := NewIssues(common.NewErrors(a.Source()))
+ baseFac := ast.NewExprFactory()
+ exprFac := &optimizerExprFactory{
+ idGenerator: ids,
+ fac: baseFac,
+ sourceInfo: optimized.SourceInfo(),
+ }
+ ctx := &OptimizerContext{
+ optimizerExprFactory: exprFac,
+ Env: env,
+ Issues: issues,
+ }
+
+ // Apply the optimizations sequentially.
+ for _, o := range opt.optimizers {
+ optimized = o.Optimize(ctx, optimized)
+ if issues.Err() != nil {
+ return nil, issues
+ }
+ // Normalize expression id metadata including coordination with macro call metadata.
+ freshIDGen := newIDGenerator(0)
+ info := optimized.SourceInfo()
+ expr := optimized.Expr()
+ normalizeIDs(freshIDGen.renumberStable, expr, info)
+ cleanupMacroRefs(expr, info)
+
+ // Recheck the updated expression for any possible type-agreement or validation errors.
+ parsed := &Ast{
+ source: a.Source(),
+ impl: ast.NewAST(expr, info)}
+ checked, iss := ctx.Check(parsed)
+ if iss.Err() != nil {
+ return nil, iss
+ }
+ optimized = checked.impl
+ }
+
+ // Return the optimized result.
+ return &Ast{
+ source: a.Source(),
+ impl: optimized,
+ }, nil
+}
+
+// normalizeIDs ensures that the metadata present with an AST is reset in a manner such
+// that the ids within the expression correspond to the ids within macros.
+func normalizeIDs(idGen ast.IDGenerator, optimized ast.Expr, info *ast.SourceInfo) {
+ optimized.RenumberIDs(idGen)
+ if len(info.MacroCalls()) == 0 {
+ return
+ }
+
+ // Sort the macro ids to make sure that the renumbering of macro-specific variables
+ // is stable across normalization calls.
+ sortedMacroIDs := []int64{}
+ for id := range info.MacroCalls() {
+ sortedMacroIDs = append(sortedMacroIDs, id)
+ }
+ sort.Slice(sortedMacroIDs, func(i, j int) bool { return sortedMacroIDs[i] < sortedMacroIDs[j] })
+
+ // First, update the macro call ids themselves.
+ callIDMap := map[int64]int64{}
+ for _, id := range sortedMacroIDs {
+ callIDMap[id] = idGen(id)
+ }
+ // Then update the macro call definitions which refer to these ids, but
+ // ensure that the updates don't collide and remove macro entries which haven't
+ // been visited / updated yet.
+ type macroUpdate struct {
+ id int64
+ call ast.Expr
+ }
+ macroUpdates := []macroUpdate{}
+ for _, oldID := range sortedMacroIDs {
+ newID := callIDMap[oldID]
+ call, found := info.GetMacroCall(oldID)
+ if !found {
+ continue
+ }
+ call.RenumberIDs(idGen)
+ macroUpdates = append(macroUpdates, macroUpdate{id: newID, call: call})
+ info.ClearMacroCall(oldID)
+ }
+ for _, u := range macroUpdates {
+ info.SetMacroCall(u.id, u.call)
+ }
+}
+
+func cleanupMacroRefs(expr ast.Expr, info *ast.SourceInfo) {
+ if len(info.MacroCalls()) == 0 {
+ return
+ }
+
+ // Sanitize the macro call references once the optimized expression has been computed
+ // and the ids normalized between the expression and the macros.
+ exprRefMap := make(map[int64]struct{})
+ ast.PostOrderVisit(expr, ast.NewExprVisitor(func(e ast.Expr) {
+ if e.ID() == 0 {
+ return
+ }
+ exprRefMap[e.ID()] = struct{}{}
+ }))
+ // Update the macro call id references to ensure that macro pointers are
+ // updated consistently across macros.
+ for _, call := range info.MacroCalls() {
+ ast.PostOrderVisit(call, ast.NewExprVisitor(func(e ast.Expr) {
+ if e.ID() == 0 {
+ return
+ }
+ exprRefMap[e.ID()] = struct{}{}
+ }))
+ }
+ for id := range info.MacroCalls() {
+ if _, found := exprRefMap[id]; !found {
+ info.ClearMacroCall(id)
+ }
+ }
+}
+
+// newIDGenerator ensures that new ids are only created the first time they are encountered.
+func newIDGenerator(seed int64) *idGenerator {
+ return &idGenerator{
+ idMap: make(map[int64]int64),
+ seed: seed,
+ }
+}
+
+type idGenerator struct {
+ idMap map[int64]int64
+ seed int64
+}
+
+func (gen *idGenerator) nextID() int64 {
+ gen.seed++
+ return gen.seed
+}
+
+func (gen *idGenerator) renumberStable(id int64) int64 {
+ if id == 0 {
+ return 0
+ }
+ if newID, found := gen.idMap[id]; found {
+ return newID
+ }
+ nextID := gen.nextID()
+ gen.idMap[id] = nextID
+ return nextID
+}
+
+// OptimizerContext embeds Env and Issues instances to make it easy to type-check and evaluate
+// subexpressions and report any errors encountered along the way. The context also embeds the
+// optimizerExprFactory which can be used to generate new sub-expressions with expression ids
+// consistent with the expectations of a parsed expression.
+type OptimizerContext struct {
+ *Env
+ *optimizerExprFactory
+ *Issues
+}
+
+// ASTOptimizer applies an optimization over an AST and returns the optimized result.
+type ASTOptimizer interface {
+ // Optimize optimizes a type-checked AST within an Environment and accumulates any issues.
+ Optimize(*OptimizerContext, *ast.AST) *ast.AST
+}
+
+type optimizerExprFactory struct {
+ *idGenerator
+ fac ast.ExprFactory
+ sourceInfo *ast.SourceInfo
+}
+
+// NewAST creates an AST from the current expression using the tracked source info which
+// is modified and managed by the OptimizerContext.
+func (opt *optimizerExprFactory) NewAST(expr ast.Expr) *ast.AST {
+ return ast.NewAST(expr, opt.sourceInfo)
+}
+
+// CopyAST creates a renumbered copy of `Expr` and `SourceInfo` values of the input AST, where the
+// renumbering uses the same scheme as the core optimizer logic ensuring there are no collisions
+// between copies.
+//
+// Use this method before attempting to merge the expression from AST into another.
+func (opt *optimizerExprFactory) CopyAST(a *ast.AST) (ast.Expr, *ast.SourceInfo) {
+ idGen := newIDGenerator(opt.nextID())
+ defer func() { opt.seed = idGen.nextID() }()
+ copyExpr := opt.fac.CopyExpr(a.Expr())
+ copyInfo := ast.CopySourceInfo(a.SourceInfo())
+ normalizeIDs(idGen.renumberStable, copyExpr, copyInfo)
+ return copyExpr, copyInfo
+}
+
+// CopyASTAndMetadata copies the input AST and propagates the macro metadata into the AST being
+// optimized.
+func (opt *optimizerExprFactory) CopyASTAndMetadata(a *ast.AST) ast.Expr {
+ copyExpr, copyInfo := opt.CopyAST(a)
+ for macroID, call := range copyInfo.MacroCalls() {
+ opt.SetMacroCall(macroID, call)
+ }
+ return copyExpr
+}
+
+// ClearMacroCall clears the macro at the given expression id.
+func (opt *optimizerExprFactory) ClearMacroCall(id int64) {
+ opt.sourceInfo.ClearMacroCall(id)
+}
+
+// SetMacroCall sets the macro call metadata for the given macro id within the tracked source info
+// metadata.
+func (opt *optimizerExprFactory) SetMacroCall(id int64, expr ast.Expr) {
+ opt.sourceInfo.SetMacroCall(id, expr)
+}
+
+// MacroCalls returns the map of macro calls currently in the context.
+func (opt *optimizerExprFactory) MacroCalls() map[int64]ast.Expr {
+ return opt.sourceInfo.MacroCalls()
+}
+
+// NewBindMacro creates an AST expression representing the expanded bind() macro, and a macro expression
+// representing the unexpanded call signature to be inserted into the source info macro call metadata.
+func (opt *optimizerExprFactory) NewBindMacro(macroID int64, varName string, varInit, remaining ast.Expr) (astExpr, macroExpr ast.Expr) {
+ varID := opt.nextID()
+ remainingID := opt.nextID()
+ remaining = opt.fac.CopyExpr(remaining)
+ remaining.RenumberIDs(func(id int64) int64 {
+ if id == macroID {
+ return remainingID
+ }
+ return id
+ })
+ if call, exists := opt.sourceInfo.GetMacroCall(macroID); exists {
+ opt.SetMacroCall(remainingID, opt.fac.CopyExpr(call))
+ }
+
+ astExpr = opt.fac.NewComprehension(macroID,
+ opt.fac.NewList(opt.nextID(), []ast.Expr{}, []int32{}),
+ "#unused",
+ varName,
+ opt.fac.CopyExpr(varInit),
+ opt.fac.NewLiteral(opt.nextID(), types.False),
+ opt.fac.NewIdent(varID, varName),
+ remaining)
+
+ macroExpr = opt.fac.NewMemberCall(0, "bind",
+ opt.fac.NewIdent(opt.nextID(), "cel"),
+ opt.fac.NewIdent(varID, varName),
+ opt.fac.CopyExpr(varInit),
+ opt.fac.CopyExpr(remaining))
+ opt.sanitizeMacro(macroID, macroExpr)
+ return
+}
+
+// NewCall creates a global function call invocation expression.
+//
+// Example:
+//
+// countByField(list, fieldName)
+// - function: countByField
+// - args: [list, fieldName]
+func (opt *optimizerExprFactory) NewCall(function string, args ...ast.Expr) ast.Expr {
+ return opt.fac.NewCall(opt.nextID(), function, args...)
+}
+
+// NewMemberCall creates a member function call invocation expression where 'target' is the receiver of the call.
+//
+// Example:
+//
+// list.countByField(fieldName)
+// - function: countByField
+// - target: list
+// - args: [fieldName]
+func (opt *optimizerExprFactory) NewMemberCall(function string, target ast.Expr, args ...ast.Expr) ast.Expr {
+ return opt.fac.NewMemberCall(opt.nextID(), function, target, args...)
+}
+
+// NewIdent creates a new identifier expression.
+//
+// Examples:
+//
+// - simple_var_name
+// - qualified.subpackage.var_name
+func (opt *optimizerExprFactory) NewIdent(name string) ast.Expr {
+ return opt.fac.NewIdent(opt.nextID(), name)
+}
+
+// NewLiteral creates a new literal expression value.
+//
+// The range of valid values for a literal generated during optimization is different than for expressions
+// generated via parsing / type-checking, as the ref.Val may be _any_ CEL value so long as the value can
+// be converted back to a literal-like form.
+func (opt *optimizerExprFactory) NewLiteral(value ref.Val) ast.Expr {
+ return opt.fac.NewLiteral(opt.nextID(), value)
+}
+
+// NewList creates a list expression with a set of optional indices.
+//
+// Examples:
+//
+// [a, b]
+// - elems: [a, b]
+// - optIndices: []
+//
+// [a, ?b, ?c]
+// - elems: [a, b, c]
+// - optIndices: [1, 2]
+func (opt *optimizerExprFactory) NewList(elems []ast.Expr, optIndices []int32) ast.Expr {
+ return opt.fac.NewList(opt.nextID(), elems, optIndices)
+}
+
+// NewMap creates a map from a set of entry expressions which contain a key and value expression.
+func (opt *optimizerExprFactory) NewMap(entries []ast.EntryExpr) ast.Expr {
+ return opt.fac.NewMap(opt.nextID(), entries)
+}
+
+// NewMapEntry creates a map entry with a key and value expression and a flag to indicate whether the
+// entry is optional.
+//
+// Examples:
+//
+// {a: b}
+// - key: a
+// - value: b
+// - optional: false
+//
+// {?a: ?b}
+// - key: a
+// - value: b
+// - optional: true
+func (opt *optimizerExprFactory) NewMapEntry(key, value ast.Expr, isOptional bool) ast.EntryExpr {
+ return opt.fac.NewMapEntry(opt.nextID(), key, value, isOptional)
+}
+
+// NewHasMacro generates a test-only select expression to be included within an AST and an unexpanded
+// has() macro call signature to be inserted into the source info macro call metadata.
+func (opt *optimizerExprFactory) NewHasMacro(macroID int64, s ast.Expr) (astExpr, macroExpr ast.Expr) {
+ sel := s.AsSelect()
+ astExpr = opt.fac.NewPresenceTest(macroID, sel.Operand(), sel.FieldName())
+ macroExpr = opt.fac.NewCall(0, "has",
+ opt.NewSelect(opt.fac.CopyExpr(sel.Operand()), sel.FieldName()))
+ opt.sanitizeMacro(macroID, macroExpr)
+ return
+}
+
+// NewSelect creates a select expression where a field value is selected from an operand.
+//
+// Example:
+//
+// msg.field_name
+// - operand: msg
+// - field: field_name
+func (opt *optimizerExprFactory) NewSelect(operand ast.Expr, field string) ast.Expr {
+ return opt.fac.NewSelect(opt.nextID(), operand, field)
+}
+
+// NewStruct creates a new typed struct value with an set of field initializations.
+//
+// Example:
+//
+// pkg.TypeName{field: value}
+// - typeName: pkg.TypeName
+// - fields: [{field: value}]
+func (opt *optimizerExprFactory) NewStruct(typeName string, fields []ast.EntryExpr) ast.Expr {
+ return opt.fac.NewStruct(opt.nextID(), typeName, fields)
+}
+
+// NewStructField creates a struct field initialization.
+//
+// Examples:
+//
+// {count: 3u}
+// - field: count
+// - value: 3u
+// - optional: false
+//
+// {?count: x}
+// - field: count
+// - value: x
+// - optional: true
+func (opt *optimizerExprFactory) NewStructField(field string, value ast.Expr, isOptional bool) ast.EntryExpr {
+ return opt.fac.NewStructField(opt.nextID(), field, value, isOptional)
+}
+
+// UpdateExpr updates the target expression with the updated content while preserving macro metadata.
+//
+// There are four scenarios during the update to consider:
+// 1. target is not macro, updated is not macro
+// 2. target is macro, updated is not macro
+// 3. target is macro, updated is macro
+// 4. target is not macro, updated is macro
+//
+// When the target is a macro already, it may either be updated to a new macro function
+// body if the update is also a macro, or it may be removed altogether if the update is
+// a macro.
+//
+// When the update is a macro, then the target references within other macros must be
+// updated to point to the new updated macro. Otherwise, other macros which pointed to
+// the target body must be replaced with copies of the updated expression body.
+func (opt *optimizerExprFactory) UpdateExpr(target, updated ast.Expr) {
+ // Update the expression
+ target.SetKindCase(updated)
+
+ // Early return if there's no macros present sa the source info reflects the
+ // macro set from the target and updated expressions.
+ if len(opt.sourceInfo.MacroCalls()) == 0 {
+ return
+ }
+ // Determine whether the target expression was a macro.
+ _, targetIsMacro := opt.sourceInfo.GetMacroCall(target.ID())
+
+ // Determine whether the updated expression was a macro.
+ updatedMacro, updatedIsMacro := opt.sourceInfo.GetMacroCall(updated.ID())
+
+ if updatedIsMacro {
+ // If the updated call was a macro, then updated id maps to target id,
+ // and the updated macro moves into the target id slot.
+ opt.sourceInfo.ClearMacroCall(updated.ID())
+ opt.sourceInfo.SetMacroCall(target.ID(), updatedMacro)
+ } else if targetIsMacro {
+ // Otherwise if the target expr was a macro, but is no longer, clear
+ // the macro reference.
+ opt.sourceInfo.ClearMacroCall(target.ID())
+ }
+
+ // Punch holes in the updated value where macros references exist.
+ macroExpr := opt.fac.CopyExpr(target)
+ macroRefVisitor := ast.NewExprVisitor(func(e ast.Expr) {
+ if _, exists := opt.sourceInfo.GetMacroCall(e.ID()); exists {
+ e.SetKindCase(nil)
+ }
+ })
+ ast.PostOrderVisit(macroExpr, macroRefVisitor)
+
+ // Update any references to the expression within a macro
+ macroVisitor := ast.NewExprVisitor(func(call ast.Expr) {
+ // Update the target expression to point to the macro expression which
+ // will be empty if the updated expression was a macro.
+ if call.ID() == target.ID() {
+ call.SetKindCase(opt.fac.CopyExpr(macroExpr))
+ }
+ // Update the macro call expression if it refers to the updated expression
+ // id which has since been remapped to the target id.
+ if call.ID() == updated.ID() {
+ // Either ensure the expression is a macro reference or a populated with
+ // the relevant sub-expression if the updated expr was not a macro.
+ if updatedIsMacro {
+ call.SetKindCase(nil)
+ } else {
+ call.SetKindCase(opt.fac.CopyExpr(macroExpr))
+ }
+ // Since SetKindCase does not renumber the id, ensure the references to
+ // the old 'updated' id are mapped to the target id.
+ call.RenumberIDs(func(id int64) int64 {
+ if id == updated.ID() {
+ return target.ID()
+ }
+ return id
+ })
+ }
+ })
+ for _, call := range opt.sourceInfo.MacroCalls() {
+ ast.PostOrderVisit(call, macroVisitor)
+ }
+}
+
+func (opt *optimizerExprFactory) sanitizeMacro(macroID int64, macroExpr ast.Expr) {
+ macroRefVisitor := ast.NewExprVisitor(func(e ast.Expr) {
+ if _, exists := opt.sourceInfo.GetMacroCall(e.ID()); exists && e.ID() != macroID {
+ e.SetKindCase(nil)
+ }
+ })
+ ast.PostOrderVisit(macroExpr, macroRefVisitor)
+}
diff --git a/vendor/github.com/google/cel-go/cel/options.go b/vendor/github.com/google/cel-go/cel/options.go
new file mode 100644
index 000000000000..69c69426348e
--- /dev/null
+++ b/vendor/github.com/google/cel-go/cel/options.go
@@ -0,0 +1,667 @@
+// Copyright 2019 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package cel
+
+import (
+ "fmt"
+
+ "google.golang.org/protobuf/proto"
+ "google.golang.org/protobuf/reflect/protodesc"
+ "google.golang.org/protobuf/reflect/protoreflect"
+ "google.golang.org/protobuf/reflect/protoregistry"
+ "google.golang.org/protobuf/types/dynamicpb"
+
+ "github.com/google/cel-go/checker"
+ "github.com/google/cel-go/common/containers"
+ "github.com/google/cel-go/common/functions"
+ "github.com/google/cel-go/common/types"
+ "github.com/google/cel-go/common/types/pb"
+ "github.com/google/cel-go/common/types/ref"
+ "github.com/google/cel-go/interpreter"
+ "github.com/google/cel-go/parser"
+
+ exprpb "google.golang.org/genproto/googleapis/api/expr/v1alpha1"
+ descpb "google.golang.org/protobuf/types/descriptorpb"
+)
+
+// These constants beginning with "Feature" enable optional behavior in
+// the library. See the documentation for each constant to see its
+// effects, compatibility restrictions, and standard conformance.
+const (
+ _ = iota
+
+ // Enable the tracking of function call expressions replaced by macros.
+ featureEnableMacroCallTracking
+
+ // Enable the use of cross-type numeric comparisons at the type-checker.
+ featureCrossTypeNumericComparisons
+
+ // Enable eager validation of declarations to ensure that Env values created
+ // with `Extend` inherit a validated list of declarations from the parent Env.
+ featureEagerlyValidateDeclarations
+
+ // Enable the use of the default UTC timezone when a timezone is not specified
+ // on a CEL timestamp operation. This fixes the scenario where the input time
+ // is not already in UTC.
+ featureDefaultUTCTimeZone
+
+ // Enable the serialization of logical operator ASTs as variadic calls, thus
+ // compressing the logic graph to a single call when multiple like-operator
+ // expressions occur: e.g. a && b && c && d -> call(_&&_, [a, b, c, d])
+ featureVariadicLogicalASTs
+
+ // Enable error generation when a presence test or optional field selection is
+ // performed on a primitive type.
+ featureEnableErrorOnBadPresenceTest
+)
+
+// EnvOption is a functional interface for configuring the environment.
+type EnvOption func(e *Env) (*Env, error)
+
+// ClearMacros options clears all parser macros.
+//
+// Clearing macros will ensure CEL expressions can only contain linear evaluation paths, as
+// comprehensions such as `all` and `exists` are enabled only via macros.
+func ClearMacros() EnvOption {
+ return func(e *Env) (*Env, error) {
+ e.macros = NoMacros
+ return e, nil
+ }
+}
+
+// CustomTypeAdapter swaps the default types.Adapter implementation with a custom one.
+//
+// Note: This option must be specified before the Types and TypeDescs options when used together.
+func CustomTypeAdapter(adapter types.Adapter) EnvOption {
+ return func(e *Env) (*Env, error) {
+ e.adapter = adapter
+ return e, nil
+ }
+}
+
+// CustomTypeProvider replaces the types.Provider implementation with a custom one.
+//
+// The `provider` variable type may either be types.Provider or ref.TypeProvider (deprecated)
+//
+// Note: This option must be specified before the Types and TypeDescs options when used together.
+func CustomTypeProvider(provider any) EnvOption {
+ return func(e *Env) (*Env, error) {
+ var err error
+ e.provider, err = maybeInteropProvider(provider)
+ return e, err
+ }
+}
+
+// Declarations option extends the declaration set configured in the environment.
+//
+// Note: Declarations will by default be appended to the pre-existing declaration set configured
+// for the environment. The NewEnv call builds on top of the standard CEL declarations. For a
+// purely custom set of declarations use NewCustomEnv.
+func Declarations(decls ...*exprpb.Decl) EnvOption {
+ declOpts := []EnvOption{}
+ var err error
+ var opt EnvOption
+ // Convert the declarations to `EnvOption` values ahead of time.
+ // Surface any errors in conversion when the options are applied.
+ for _, d := range decls {
+ opt, err = ExprDeclToDeclaration(d)
+ if err != nil {
+ break
+ }
+ declOpts = append(declOpts, opt)
+ }
+ return func(e *Env) (*Env, error) {
+ if err != nil {
+ return nil, err
+ }
+ for _, o := range declOpts {
+ e, err = o(e)
+ if err != nil {
+ return nil, err
+ }
+ }
+ return e, nil
+ }
+}
+
+// EagerlyValidateDeclarations ensures that any collisions between configured declarations are caught
+// at the time of the `NewEnv` call.
+//
+// Eagerly validating declarations is also useful for bootstrapping a base `cel.Env` value.
+// Calls to base `Env.Extend()` will be significantly faster when declarations are eagerly validated
+// as declarations will be collision-checked at most once and only incrementally by way of `Extend`
+//
+// Disabled by default as not all environments are used for type-checking.
+func EagerlyValidateDeclarations(enabled bool) EnvOption {
+ return features(featureEagerlyValidateDeclarations, enabled)
+}
+
+// HomogeneousAggregateLiterals disables mixed type list and map literal values.
+//
+// Note, it is still possible to have heterogeneous aggregates when provided as variables to the
+// expression, as well as via conversion of well-known dynamic types, or with unchecked
+// expressions.
+func HomogeneousAggregateLiterals() EnvOption {
+ return ASTValidators(ValidateHomogeneousAggregateLiterals())
+}
+
+// variadicLogicalOperatorASTs flatten like-operator chained logical expressions into a single
+// variadic call with N-terms. This behavior is useful when serializing to a protocol buffer as
+// it will reduce the number of recursive calls needed to deserialize the AST later.
+//
+// For example, given the following expression the call graph will be rendered accordingly:
+//
+// expression: a && b && c && (d || e)
+// ast: call(_&&_, [a, b, c, call(_||_, [d, e])])
+func variadicLogicalOperatorASTs() EnvOption {
+ return features(featureVariadicLogicalASTs, true)
+}
+
+// Macros option extends the macro set configured in the environment.
+//
+// Note: This option must be specified after ClearMacros if used together.
+func Macros(macros ...Macro) EnvOption {
+ return func(e *Env) (*Env, error) {
+ e.macros = append(e.macros, macros...)
+ return e, nil
+ }
+}
+
+// Container sets the container for resolving variable names. Defaults to an empty container.
+//
+// If all references within an expression are relative to a protocol buffer package, then
+// specifying a container of `google.type` would make it possible to write expressions such as
+// `Expr{expression: 'a < b'}` instead of having to write `google.type.Expr{...}`.
+func Container(name string) EnvOption {
+ return func(e *Env) (*Env, error) {
+ cont, err := e.Container.Extend(containers.Name(name))
+ if err != nil {
+ return nil, err
+ }
+ e.Container = cont
+ return e, nil
+ }
+}
+
+// Abbrevs configures a set of simple names as abbreviations for fully-qualified names.
+//
+// An abbreviation (abbrev for short) is a simple name that expands to a fully-qualified name.
+// Abbreviations can be useful when working with variables, functions, and especially types from
+// multiple namespaces:
+//
+// // CEL object construction
+// qual.pkg.version.ObjTypeName{
+// field: alt.container.ver.FieldTypeName{value: ...}
+// }
+//
+// Only one the qualified names above may be used as the CEL container, so at least one of these
+// references must be a long qualified name within an otherwise short CEL program. Using the
+// following abbreviations, the program becomes much simpler:
+//
+// // CEL Go option
+// Abbrevs("qual.pkg.version.ObjTypeName", "alt.container.ver.FieldTypeName")
+// // Simplified Object construction
+// ObjTypeName{field: FieldTypeName{value: ...}}
+//
+// There are a few rules for the qualified names and the simple abbreviations generated from them:
+// - Qualified names must be dot-delimited, e.g. `package.subpkg.name`.
+// - The last element in the qualified name is the abbreviation.
+// - Abbreviations must not collide with each other.
+// - The abbreviation must not collide with unqualified names in use.
+//
+// Abbreviations are distinct from container-based references in the following important ways:
+// - Abbreviations must expand to a fully-qualified name.
+// - Expanded abbreviations do not participate in namespace resolution.
+// - Abbreviation expansion is done instead of the container search for a matching identifier.
+// - Containers follow C++ namespace resolution rules with searches from the most qualified name
+//
+// to the least qualified name.
+//
+// - Container references within the CEL program may be relative, and are resolved to fully
+//
+// qualified names at either type-check time or program plan time, whichever comes first.
+//
+// If there is ever a case where an identifier could be in both the container and as an
+// abbreviation, the abbreviation wins as this will ensure that the meaning of a program is
+// preserved between compilations even as the container evolves.
+func Abbrevs(qualifiedNames ...string) EnvOption {
+ return func(e *Env) (*Env, error) {
+ cont, err := e.Container.Extend(containers.Abbrevs(qualifiedNames...))
+ if err != nil {
+ return nil, err
+ }
+ e.Container = cont
+ return e, nil
+ }
+}
+
+// customTypeRegistry is an internal-only interface containing the minimum methods required to support
+// custom types. It is a subset of methods from ref.TypeRegistry.
+type customTypeRegistry interface {
+ RegisterDescriptor(protoreflect.FileDescriptor) error
+ RegisterType(...ref.Type) error
+}
+
+// Types adds one or more type declarations to the environment, allowing for construction of
+// type-literals whose definitions are included in the common expression built-in set.
+//
+// The input types may either be instances of `proto.Message` or `ref.Type`. Any other type
+// provided to this option will result in an error.
+//
+// Well-known protobuf types within the `google.protobuf.*` package are included in the standard
+// environment by default.
+//
+// Note: This option must be specified after the CustomTypeProvider option when used together.
+func Types(addTypes ...any) EnvOption {
+ return func(e *Env) (*Env, error) {
+ reg, isReg := e.provider.(customTypeRegistry)
+ if !isReg {
+ return nil, fmt.Errorf("custom types not supported by provider: %T", e.provider)
+ }
+ for _, t := range addTypes {
+ switch v := t.(type) {
+ case proto.Message:
+ fdMap := pb.CollectFileDescriptorSet(v)
+ for _, fd := range fdMap {
+ err := reg.RegisterDescriptor(fd)
+ if err != nil {
+ return nil, err
+ }
+ }
+ case ref.Type:
+ err := reg.RegisterType(v)
+ if err != nil {
+ return nil, err
+ }
+ default:
+ return nil, fmt.Errorf("unsupported type: %T", t)
+ }
+ }
+ return e, nil
+ }
+}
+
+// TypeDescs adds type declarations from any protoreflect.FileDescriptor, protoregistry.Files,
+// google.protobuf.FileDescriptorProto or google.protobuf.FileDescriptorSet provided.
+//
+// Note that messages instantiated from these descriptors will be *dynamicpb.Message values
+// rather than the concrete message type.
+//
+// TypeDescs are hermetic to a single Env object, but may be copied to other Env values via
+// extension or by re-using the same EnvOption with another NewEnv() call.
+func TypeDescs(descs ...any) EnvOption {
+ return func(e *Env) (*Env, error) {
+ reg, isReg := e.provider.(customTypeRegistry)
+ if !isReg {
+ return nil, fmt.Errorf("custom types not supported by provider: %T", e.provider)
+ }
+ // Scan the input descriptors for FileDescriptorProto messages and accumulate them into a
+ // synthetic FileDescriptorSet as the FileDescriptorProto messages may refer to each other
+ // and will not resolve properly unless they are part of the same set.
+ var fds *descpb.FileDescriptorSet
+ for _, d := range descs {
+ switch f := d.(type) {
+ case *descpb.FileDescriptorProto:
+ if fds == nil {
+ fds = &descpb.FileDescriptorSet{
+ File: []*descpb.FileDescriptorProto{},
+ }
+ }
+ fds.File = append(fds.File, f)
+ }
+ }
+ if fds != nil {
+ if err := registerFileSet(reg, fds); err != nil {
+ return nil, err
+ }
+ }
+ for _, d := range descs {
+ switch f := d.(type) {
+ case *protoregistry.Files:
+ if err := registerFiles(reg, f); err != nil {
+ return nil, err
+ }
+ case protoreflect.FileDescriptor:
+ if err := reg.RegisterDescriptor(f); err != nil {
+ return nil, err
+ }
+ case *descpb.FileDescriptorSet:
+ if err := registerFileSet(reg, f); err != nil {
+ return nil, err
+ }
+ case *descpb.FileDescriptorProto:
+ // skip, handled as a synthetic file descriptor set.
+ default:
+ return nil, fmt.Errorf("unsupported type descriptor: %T", d)
+ }
+ }
+ return e, nil
+ }
+}
+
+func registerFileSet(reg customTypeRegistry, fileSet *descpb.FileDescriptorSet) error {
+ files, err := protodesc.NewFiles(fileSet)
+ if err != nil {
+ return fmt.Errorf("protodesc.NewFiles(%v) failed: %v", fileSet, err)
+ }
+ return registerFiles(reg, files)
+}
+
+func registerFiles(reg customTypeRegistry, files *protoregistry.Files) error {
+ var err error
+ files.RangeFiles(func(fd protoreflect.FileDescriptor) bool {
+ err = reg.RegisterDescriptor(fd)
+ return err == nil
+ })
+ return err
+}
+
+// ProgramOption is a functional interface for configuring evaluation bindings and behaviors.
+type ProgramOption func(p *prog) (*prog, error)
+
+// CustomDecorator appends an InterpreterDecorator to the program.
+//
+// InterpretableDecorators can be used to inspect, alter, or replace the Program plan.
+func CustomDecorator(dec interpreter.InterpretableDecorator) ProgramOption {
+ return func(p *prog) (*prog, error) {
+ p.decorators = append(p.decorators, dec)
+ return p, nil
+ }
+}
+
+// Functions adds function overloads that extend or override the set of CEL built-ins.
+//
+// Deprecated: use Function() instead to declare the function, its overload signatures,
+// and the overload implementations.
+func Functions(funcs ...*functions.Overload) ProgramOption {
+ return func(p *prog) (*prog, error) {
+ if err := p.dispatcher.Add(funcs...); err != nil {
+ return nil, err
+ }
+ return p, nil
+ }
+}
+
+// Globals sets the global variable values for a given program. These values may be shadowed by
+// variables with the same name provided to the Eval() call. If Globals is used in a Library with
+// a Lib EnvOption, vars may shadow variables provided by previously added libraries.
+//
+// The vars value may either be an `interpreter.Activation` instance or a `map[string]any`.
+func Globals(vars any) ProgramOption {
+ return func(p *prog) (*prog, error) {
+ defaultVars, err := interpreter.NewActivation(vars)
+ if err != nil {
+ return nil, err
+ }
+ if p.defaultVars != nil {
+ defaultVars = interpreter.NewHierarchicalActivation(p.defaultVars, defaultVars)
+ }
+ p.defaultVars = defaultVars
+ return p, nil
+ }
+}
+
+// OptimizeRegex provides a way to replace the InterpretableCall for regex functions. This can be used
+// to compile regex string constants at program creation time and report any errors and then use the
+// compiled regex for all regex function invocations.
+func OptimizeRegex(regexOptimizations ...*interpreter.RegexOptimization) ProgramOption {
+ return func(p *prog) (*prog, error) {
+ p.regexOptimizations = append(p.regexOptimizations, regexOptimizations...)
+ return p, nil
+ }
+}
+
+// EvalOption indicates an evaluation option that may affect the evaluation behavior or information
+// in the output result.
+type EvalOption int
+
+const (
+ // OptTrackState will cause the runtime to return an immutable EvalState value in the Result.
+ OptTrackState EvalOption = 1 << iota
+
+ // OptExhaustiveEval causes the runtime to disable short-circuits and track state.
+ OptExhaustiveEval EvalOption = 1< 0 {
+ decorators = append(decorators, interpreter.InterruptableEval())
+ }
+ // Enable constant folding first.
+ if p.evalOpts&OptOptimize == OptOptimize {
+ decorators = append(decorators, interpreter.Optimize())
+ p.regexOptimizations = append(p.regexOptimizations, interpreter.MatchesRegexOptimization)
+ }
+ // Enable regex compilation of constants immediately after folding constants.
+ if len(p.regexOptimizations) > 0 {
+ decorators = append(decorators, interpreter.CompileRegexConstants(p.regexOptimizations...))
+ }
+
+ // Enable exhaustive eval, state tracking and cost tracking last since they require a factory.
+ if p.evalOpts&(OptExhaustiveEval|OptTrackState|OptTrackCost) != 0 {
+ factory := func(state interpreter.EvalState, costTracker *interpreter.CostTracker) (Program, error) {
+ costTracker.Estimator = p.callCostEstimator
+ costTracker.Limit = p.costLimit
+ for _, costOpt := range p.costOptions {
+ err := costOpt(costTracker)
+ if err != nil {
+ return nil, err
+ }
+ }
+ // Limit capacity to guarantee a reallocation when calling 'append(decs, ...)' below. This
+ // prevents the underlying memory from being shared between factory function calls causing
+ // undesired mutations.
+ decs := decorators[:len(decorators):len(decorators)]
+ var observers []interpreter.EvalObserver
+
+ if p.evalOpts&(OptExhaustiveEval|OptTrackState) != 0 {
+ // EvalStateObserver is required for OptExhaustiveEval.
+ observers = append(observers, interpreter.EvalStateObserver(state))
+ }
+ if p.evalOpts&OptTrackCost == OptTrackCost {
+ observers = append(observers, interpreter.CostObserver(costTracker))
+ }
+
+ // Enable exhaustive eval over a basic observer since it offers a superset of features.
+ if p.evalOpts&OptExhaustiveEval == OptExhaustiveEval {
+ decs = append(decs, interpreter.ExhaustiveEval(), interpreter.Observe(observers...))
+ } else if len(observers) > 0 {
+ decs = append(decs, interpreter.Observe(observers...))
+ }
+
+ return p.clone().initInterpretable(a, decs)
+ }
+ return newProgGen(factory)
+ }
+ return p.initInterpretable(a, decorators)
+}
+
+func (p *prog) initInterpretable(a *Ast, decs []interpreter.InterpretableDecorator) (*prog, error) {
+ // When the AST has been exprAST it contains metadata that can be used to speed up program execution.
+ interpretable, err := p.interpreter.NewInterpretable(a.impl, decs...)
+ if err != nil {
+ return nil, err
+ }
+ p.interpretable = interpretable
+ return p, nil
+}
+
+// Eval implements the Program interface method.
+func (p *prog) Eval(input any) (v ref.Val, det *EvalDetails, err error) {
+ // Configure error recovery for unexpected panics during evaluation. Note, the use of named
+ // return values makes it possible to modify the error response during the recovery
+ // function.
+ defer func() {
+ if r := recover(); r != nil {
+ switch t := r.(type) {
+ case interpreter.EvalCancelledError:
+ err = t
+ default:
+ err = fmt.Errorf("internal error: %v", r)
+ }
+ }
+ }()
+ // Build a hierarchical activation if there are default vars set.
+ var vars interpreter.Activation
+ switch v := input.(type) {
+ case interpreter.Activation:
+ vars = v
+ case map[string]any:
+ vars = activationPool.Setup(v)
+ defer activationPool.Put(vars)
+ default:
+ return nil, nil, fmt.Errorf("invalid input, wanted Activation or map[string]any, got: (%T)%v", input, input)
+ }
+ if p.defaultVars != nil {
+ vars = interpreter.NewHierarchicalActivation(p.defaultVars, vars)
+ }
+ v = p.interpretable.Eval(vars)
+ // The output of an internal Eval may have a value (`v`) that is a types.Err. This step
+ // translates the CEL value to a Go error response. This interface does not quite match the
+ // RPC signature which allows for multiple errors to be returned, but should be sufficient.
+ if types.IsError(v) {
+ err = v.(*types.Err)
+ }
+ return
+}
+
+// ContextEval implements the Program interface.
+func (p *prog) ContextEval(ctx context.Context, input any) (ref.Val, *EvalDetails, error) {
+ if ctx == nil {
+ return nil, nil, fmt.Errorf("context can not be nil")
+ }
+ // Configure the input, making sure to wrap Activation inputs in the special ctxActivation which
+ // exposes the #interrupted variable and manages rate-limited checks of the ctx.Done() state.
+ var vars interpreter.Activation
+ switch v := input.(type) {
+ case interpreter.Activation:
+ vars = ctxActivationPool.Setup(v, ctx.Done(), p.interruptCheckFrequency)
+ defer ctxActivationPool.Put(vars)
+ case map[string]any:
+ rawVars := activationPool.Setup(v)
+ defer activationPool.Put(rawVars)
+ vars = ctxActivationPool.Setup(rawVars, ctx.Done(), p.interruptCheckFrequency)
+ defer ctxActivationPool.Put(vars)
+ default:
+ return nil, nil, fmt.Errorf("invalid input, wanted Activation or map[string]any, got: (%T)%v", input, input)
+ }
+ return p.Eval(vars)
+}
+
+// progFactory is a helper alias for marking a program creation factory function.
+type progFactory func(interpreter.EvalState, *interpreter.CostTracker) (Program, error)
+
+// progGen holds a reference to a progFactory instance and implements the Program interface.
+type progGen struct {
+ factory progFactory
+}
+
+// newProgGen tests the factory object by calling it once and returns a factory-based Program if
+// the test is successful.
+func newProgGen(factory progFactory) (Program, error) {
+ // Test the factory to make sure that configuration errors are spotted at config
+ tracker, err := interpreter.NewCostTracker(nil)
+ if err != nil {
+ return nil, err
+ }
+ _, err = factory(interpreter.NewEvalState(), tracker)
+ if err != nil {
+ return nil, err
+ }
+ return &progGen{factory: factory}, nil
+}
+
+// Eval implements the Program interface method.
+func (gen *progGen) Eval(input any) (ref.Val, *EvalDetails, error) {
+ // The factory based Eval() differs from the standard evaluation model in that it generates a
+ // new EvalState instance for each call to ensure that unique evaluations yield unique stateful
+ // results.
+ state := interpreter.NewEvalState()
+ costTracker, err := interpreter.NewCostTracker(nil)
+ if err != nil {
+ return nil, nil, err
+ }
+ det := &EvalDetails{state: state, costTracker: costTracker}
+
+ // Generate a new instance of the interpretable using the factory configured during the call to
+ // newProgram(). It is incredibly unlikely that the factory call will generate an error given
+ // the factory test performed within the Program() call.
+ p, err := gen.factory(state, costTracker)
+ if err != nil {
+ return nil, det, err
+ }
+
+ // Evaluate the input, returning the result and the 'state' within EvalDetails.
+ v, _, err := p.Eval(input)
+ if err != nil {
+ return v, det, err
+ }
+ return v, det, nil
+}
+
+// ContextEval implements the Program interface method.
+func (gen *progGen) ContextEval(ctx context.Context, input any) (ref.Val, *EvalDetails, error) {
+ if ctx == nil {
+ return nil, nil, fmt.Errorf("context can not be nil")
+ }
+ // The factory based Eval() differs from the standard evaluation model in that it generates a
+ // new EvalState instance for each call to ensure that unique evaluations yield unique stateful
+ // results.
+ state := interpreter.NewEvalState()
+ costTracker, err := interpreter.NewCostTracker(nil)
+ if err != nil {
+ return nil, nil, err
+ }
+ det := &EvalDetails{state: state, costTracker: costTracker}
+
+ // Generate a new instance of the interpretable using the factory configured during the call to
+ // newProgram(). It is incredibly unlikely that the factory call will generate an error given
+ // the factory test performed within the Program() call.
+ p, err := gen.factory(state, costTracker)
+ if err != nil {
+ return nil, det, err
+ }
+
+ // Evaluate the input, returning the result and the 'state' within EvalDetails.
+ v, _, err := p.ContextEval(ctx, input)
+ if err != nil {
+ return v, det, err
+ }
+ return v, det, nil
+}
+
+type ctxEvalActivation struct {
+ parent interpreter.Activation
+ interrupt <-chan struct{}
+ interruptCheckCount uint
+ interruptCheckFrequency uint
+}
+
+// ResolveName implements the Activation interface method, but adds a special #interrupted variable
+// which is capable of testing whether a 'done' signal is provided from a context.Context channel.
+func (a *ctxEvalActivation) ResolveName(name string) (any, bool) {
+ if name == "#interrupted" {
+ a.interruptCheckCount++
+ if a.interruptCheckCount%a.interruptCheckFrequency == 0 {
+ select {
+ case <-a.interrupt:
+ return true, true
+ default:
+ return nil, false
+ }
+ }
+ return nil, false
+ }
+ return a.parent.ResolveName(name)
+}
+
+func (a *ctxEvalActivation) Parent() interpreter.Activation {
+ return a.parent
+}
+
+func newCtxEvalActivationPool() *ctxEvalActivationPool {
+ return &ctxEvalActivationPool{
+ Pool: sync.Pool{
+ New: func() any {
+ return &ctxEvalActivation{}
+ },
+ },
+ }
+}
+
+type ctxEvalActivationPool struct {
+ sync.Pool
+}
+
+// Setup initializes a pooled Activation with the ability check for context.Context cancellation
+func (p *ctxEvalActivationPool) Setup(vars interpreter.Activation, done <-chan struct{}, interruptCheckRate uint) *ctxEvalActivation {
+ a := p.Pool.Get().(*ctxEvalActivation)
+ a.parent = vars
+ a.interrupt = done
+ a.interruptCheckCount = 0
+ a.interruptCheckFrequency = interruptCheckRate
+ return a
+}
+
+type evalActivation struct {
+ vars map[string]any
+ lazyVars map[string]any
+}
+
+// ResolveName looks up the value of the input variable name, if found.
+//
+// Lazy bindings may be supplied within the map-based input in either of the following forms:
+// - func() any
+// - func() ref.Val
+//
+// The lazy binding will only be invoked once per evaluation.
+//
+// Values which are not represented as ref.Val types on input may be adapted to a ref.Val using
+// the types.Adapter configured in the environment.
+func (a *evalActivation) ResolveName(name string) (any, bool) {
+ v, found := a.vars[name]
+ if !found {
+ return nil, false
+ }
+ switch obj := v.(type) {
+ case func() ref.Val:
+ if resolved, found := a.lazyVars[name]; found {
+ return resolved, true
+ }
+ lazy := obj()
+ a.lazyVars[name] = lazy
+ return lazy, true
+ case func() any:
+ if resolved, found := a.lazyVars[name]; found {
+ return resolved, true
+ }
+ lazy := obj()
+ a.lazyVars[name] = lazy
+ return lazy, true
+ default:
+ return obj, true
+ }
+}
+
+// Parent implements the interpreter.Activation interface
+func (a *evalActivation) Parent() interpreter.Activation {
+ return nil
+}
+
+func newEvalActivationPool() *evalActivationPool {
+ return &evalActivationPool{
+ Pool: sync.Pool{
+ New: func() any {
+ return &evalActivation{lazyVars: make(map[string]any)}
+ },
+ },
+ }
+}
+
+type evalActivationPool struct {
+ sync.Pool
+}
+
+// Setup initializes a pooled Activation object with the map input.
+func (p *evalActivationPool) Setup(vars map[string]any) *evalActivation {
+ a := p.Pool.Get().(*evalActivation)
+ a.vars = vars
+ return a
+}
+
+func (p *evalActivationPool) Put(value any) {
+ a := value.(*evalActivation)
+ for k := range a.lazyVars {
+ delete(a.lazyVars, k)
+ }
+ p.Pool.Put(a)
+}
+
+var (
+ // activationPool is an internally managed pool of Activation values that wrap map[string]any inputs
+ activationPool = newEvalActivationPool()
+
+ // ctxActivationPool is an internally managed pool of Activation values that expose a special #interrupted variable
+ ctxActivationPool = newCtxEvalActivationPool()
+)
diff --git a/vendor/github.com/google/cel-go/cel/validator.go b/vendor/github.com/google/cel-go/cel/validator.go
new file mode 100644
index 000000000000..b50c674520a7
--- /dev/null
+++ b/vendor/github.com/google/cel-go/cel/validator.go
@@ -0,0 +1,375 @@
+// Copyright 2023 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package cel
+
+import (
+ "fmt"
+ "reflect"
+ "regexp"
+
+ "github.com/google/cel-go/common/ast"
+ "github.com/google/cel-go/common/overloads"
+)
+
+const (
+ homogeneousValidatorName = "cel.lib.std.validate.types.homogeneous"
+
+ // HomogeneousAggregateLiteralExemptFunctions is the ValidatorConfig key used to configure
+ // the set of function names which are exempt from homogeneous type checks. The expected type
+ // is a string list of function names.
+ //
+ // As an example, the `.format([args])` call expects the input arguments list to be
+ // comprised of a variety of types which correspond to the types expected by the format control
+ // clauses; however, all other uses of a mixed element type list, would be unexpected.
+ HomogeneousAggregateLiteralExemptFunctions = homogeneousValidatorName + ".exempt"
+)
+
+// ASTValidators configures a set of ASTValidator instances into the target environment.
+//
+// Validators are applied in the order in which the are specified and are treated as singletons.
+// The same ASTValidator with a given name will not be applied more than once.
+func ASTValidators(validators ...ASTValidator) EnvOption {
+ return func(e *Env) (*Env, error) {
+ for _, v := range validators {
+ if !e.HasValidator(v.Name()) {
+ e.validators = append(e.validators, v)
+ }
+ }
+ return e, nil
+ }
+}
+
+// ASTValidator defines a singleton interface for validating a type-checked Ast against an environment.
+//
+// Note: the Issues argument is mutable in the sense that it is intended to collect errors which will be
+// reported to the caller.
+type ASTValidator interface {
+ // Name returns the name of the validator. Names must be unique.
+ Name() string
+
+ // Validate validates a given Ast within an Environment and collects a set of potential issues.
+ //
+ // The ValidatorConfig is generated from the set of ASTValidatorConfigurer instances prior to
+ // the invocation of the Validate call. The expectation is that the validator configuration
+ // is created in sequence and immutable once provided to the Validate call.
+ //
+ // See individual validators for more information on their configuration keys and configuration
+ // properties.
+ Validate(*Env, ValidatorConfig, *ast.AST, *Issues)
+}
+
+// ValidatorConfig provides an accessor method for querying validator configuration state.
+type ValidatorConfig interface {
+ GetOrDefault(name string, value any) any
+}
+
+// MutableValidatorConfig provides mutation methods for querying and updating validator configuration
+// settings.
+type MutableValidatorConfig interface {
+ ValidatorConfig
+ Set(name string, value any) error
+}
+
+// ASTValidatorConfigurer indicates that this object, currently expected to be an ASTValidator,
+// participates in validator configuration settings.
+//
+// This interface may be split from the expectation of being an ASTValidator instance in the future.
+type ASTValidatorConfigurer interface {
+ Configure(MutableValidatorConfig) error
+}
+
+// validatorConfig implements the ValidatorConfig and MutableValidatorConfig interfaces.
+type validatorConfig struct {
+ data map[string]any
+}
+
+// newValidatorConfig initializes the validator config with default values for core CEL validators.
+func newValidatorConfig() *validatorConfig {
+ return &validatorConfig{
+ data: map[string]any{
+ HomogeneousAggregateLiteralExemptFunctions: []string{},
+ },
+ }
+}
+
+// GetOrDefault returns the configured value for the name, if present, else the input default value.
+//
+// Note, the type-agreement between the input default and configured value is not checked on read.
+func (config *validatorConfig) GetOrDefault(name string, value any) any {
+ v, found := config.data[name]
+ if !found {
+ return value
+ }
+ return v
+}
+
+// Set configures a validator option with the given name and value.
+//
+// If the value had previously been set, the new value must have the same reflection type as the old one,
+// or the call will error.
+func (config *validatorConfig) Set(name string, value any) error {
+ v, found := config.data[name]
+ if found && reflect.TypeOf(v) != reflect.TypeOf(value) {
+ return fmt.Errorf("incompatible configuration type for %s, got %T, wanted %T", name, value, v)
+ }
+ config.data[name] = value
+ return nil
+}
+
+// ExtendedValidations collects a set of common AST validations which reduce the likelihood of runtime errors.
+//
+// - Validate duration and timestamp literals
+// - Ensure regex strings are valid
+// - Disable mixed type list and map literals
+func ExtendedValidations() EnvOption {
+ return ASTValidators(
+ ValidateDurationLiterals(),
+ ValidateTimestampLiterals(),
+ ValidateRegexLiterals(),
+ ValidateHomogeneousAggregateLiterals(),
+ )
+}
+
+// ValidateDurationLiterals ensures that duration literal arguments are valid immediately after type-check.
+func ValidateDurationLiterals() ASTValidator {
+ return newFormatValidator(overloads.TypeConvertDuration, 0, evalCall)
+}
+
+// ValidateTimestampLiterals ensures that timestamp literal arguments are valid immediately after type-check.
+func ValidateTimestampLiterals() ASTValidator {
+ return newFormatValidator(overloads.TypeConvertTimestamp, 0, evalCall)
+}
+
+// ValidateRegexLiterals ensures that regex patterns are validated after type-check.
+func ValidateRegexLiterals() ASTValidator {
+ return newFormatValidator(overloads.Matches, 0, compileRegex)
+}
+
+// ValidateHomogeneousAggregateLiterals checks that all list and map literals entries have the same types, i.e.
+// no mixed list element types or mixed map key or map value types.
+//
+// Note: the string format call relies on a mixed element type list for ease of use, so this check skips all
+// literals which occur within string format calls.
+func ValidateHomogeneousAggregateLiterals() ASTValidator {
+ return homogeneousAggregateLiteralValidator{}
+}
+
+// ValidateComprehensionNestingLimit ensures that comprehension nesting does not exceed the specified limit.
+//
+// This validator can be useful for preventing arbitrarily nested comprehensions which can take high polynomial
+// time to complete.
+//
+// Note, this limit does not apply to comprehensions with an empty iteration range, as these comprehensions have
+// no actual looping cost. The cel.bind() utilizes the comprehension structure to perform local variable
+// assignments and supplies an empty iteration range, so they won't count against the nesting limit either.
+func ValidateComprehensionNestingLimit(limit int) ASTValidator {
+ return nestingLimitValidator{limit: limit}
+}
+
+type argChecker func(env *Env, call, arg ast.Expr) error
+
+func newFormatValidator(funcName string, argNum int, check argChecker) formatValidator {
+ return formatValidator{
+ funcName: funcName,
+ check: check,
+ argNum: argNum,
+ }
+}
+
+type formatValidator struct {
+ funcName string
+ argNum int
+ check argChecker
+}
+
+// Name returns the unique name of this function format validator.
+func (v formatValidator) Name() string {
+ return fmt.Sprintf("cel.lib.std.validate.functions.%s", v.funcName)
+}
+
+// Validate searches the AST for uses of a given function name with a constant argument and performs a check
+// on whether the argument is a valid literal value.
+func (v formatValidator) Validate(e *Env, _ ValidatorConfig, a *ast.AST, iss *Issues) {
+ root := ast.NavigateAST(a)
+ funcCalls := ast.MatchDescendants(root, ast.FunctionMatcher(v.funcName))
+ for _, call := range funcCalls {
+ callArgs := call.AsCall().Args()
+ if len(callArgs) <= v.argNum {
+ continue
+ }
+ litArg := callArgs[v.argNum]
+ if litArg.Kind() != ast.LiteralKind {
+ continue
+ }
+ if err := v.check(e, call, litArg); err != nil {
+ iss.ReportErrorAtID(litArg.ID(), "invalid %s argument", v.funcName)
+ }
+ }
+}
+
+func evalCall(env *Env, call, arg ast.Expr) error {
+ ast := &Ast{impl: ast.NewAST(call, ast.NewSourceInfo(nil))}
+ prg, err := env.Program(ast)
+ if err != nil {
+ return err
+ }
+ _, _, err = prg.Eval(NoVars())
+ return err
+}
+
+func compileRegex(_ *Env, _, arg ast.Expr) error {
+ pattern := arg.AsLiteral().Value().(string)
+ _, err := regexp.Compile(pattern)
+ return err
+}
+
+type homogeneousAggregateLiteralValidator struct{}
+
+// Name returns the unique name of the homogeneous type validator.
+func (homogeneousAggregateLiteralValidator) Name() string {
+ return homogeneousValidatorName
+}
+
+// Validate validates that all lists and map literals have homogeneous types, i.e. don't contain dyn types.
+//
+// This validator makes an exception for list and map literals which occur at any level of nesting within
+// string format calls.
+func (v homogeneousAggregateLiteralValidator) Validate(_ *Env, c ValidatorConfig, a *ast.AST, iss *Issues) {
+ var exemptedFunctions []string
+ exemptedFunctions = c.GetOrDefault(HomogeneousAggregateLiteralExemptFunctions, exemptedFunctions).([]string)
+ root := ast.NavigateAST(a)
+ listExprs := ast.MatchDescendants(root, ast.KindMatcher(ast.ListKind))
+ for _, listExpr := range listExprs {
+ if inExemptFunction(listExpr, exemptedFunctions) {
+ continue
+ }
+ l := listExpr.AsList()
+ elements := l.Elements()
+ optIndices := l.OptionalIndices()
+ var elemType *Type
+ for i, e := range elements {
+ et := a.GetType(e.ID())
+ if isOptionalIndex(i, optIndices) {
+ et = et.Parameters()[0]
+ }
+ if elemType == nil {
+ elemType = et
+ continue
+ }
+ if !elemType.IsEquivalentType(et) {
+ v.typeMismatch(iss, e.ID(), elemType, et)
+ break
+ }
+ }
+ }
+ mapExprs := ast.MatchDescendants(root, ast.KindMatcher(ast.MapKind))
+ for _, mapExpr := range mapExprs {
+ if inExemptFunction(mapExpr, exemptedFunctions) {
+ continue
+ }
+ m := mapExpr.AsMap()
+ entries := m.Entries()
+ var keyType, valType *Type
+ for _, e := range entries {
+ mapEntry := e.AsMapEntry()
+ key, val := mapEntry.Key(), mapEntry.Value()
+ kt, vt := a.GetType(key.ID()), a.GetType(val.ID())
+ if mapEntry.IsOptional() {
+ vt = vt.Parameters()[0]
+ }
+ if keyType == nil && valType == nil {
+ keyType, valType = kt, vt
+ continue
+ }
+ if !keyType.IsEquivalentType(kt) {
+ v.typeMismatch(iss, key.ID(), keyType, kt)
+ }
+ if !valType.IsEquivalentType(vt) {
+ v.typeMismatch(iss, val.ID(), valType, vt)
+ }
+ }
+ }
+}
+
+func inExemptFunction(e ast.NavigableExpr, exemptFunctions []string) bool {
+ parent, found := e.Parent()
+ for found {
+ if parent.Kind() == ast.CallKind {
+ fnName := parent.AsCall().FunctionName()
+ for _, exempt := range exemptFunctions {
+ if exempt == fnName {
+ return true
+ }
+ }
+ }
+ parent, found = parent.Parent()
+ }
+ return false
+}
+
+func isOptionalIndex(i int, optIndices []int32) bool {
+ for _, optInd := range optIndices {
+ if i == int(optInd) {
+ return true
+ }
+ }
+ return false
+}
+
+func (homogeneousAggregateLiteralValidator) typeMismatch(iss *Issues, id int64, expected, actual *Type) {
+ iss.ReportErrorAtID(id, "expected type '%s' but found '%s'", FormatCELType(expected), FormatCELType(actual))
+}
+
+type nestingLimitValidator struct {
+ limit int
+}
+
+func (v nestingLimitValidator) Name() string {
+ return "cel.lib.std.validate.comprehension_nesting_limit"
+}
+
+func (v nestingLimitValidator) Validate(e *Env, _ ValidatorConfig, a *ast.AST, iss *Issues) {
+ root := ast.NavigateAST(a)
+ comprehensions := ast.MatchDescendants(root, ast.KindMatcher(ast.ComprehensionKind))
+ if len(comprehensions) <= v.limit {
+ return
+ }
+ for _, comp := range comprehensions {
+ count := 0
+ e := comp
+ hasParent := true
+ for hasParent {
+ // When the expression is not a comprehension, continue to the next ancestor.
+ if e.Kind() != ast.ComprehensionKind {
+ e, hasParent = e.Parent()
+ continue
+ }
+ // When the comprehension has an empty range, continue to the next ancestor
+ // as this comprehension does not have any associated cost.
+ iterRange := e.AsComprehension().IterRange()
+ if iterRange.Kind() == ast.ListKind && iterRange.AsList().Size() == 0 {
+ e, hasParent = e.Parent()
+ continue
+ }
+ // Otherwise check the nesting limit.
+ count++
+ if count > v.limit {
+ iss.ReportErrorAtID(comp.ID(), "comprehension exceeds nesting limit")
+ break
+ }
+ e, hasParent = e.Parent()
+ }
+ }
+}
diff --git a/vendor/github.com/google/cel-go/checker/BUILD.bazel b/vendor/github.com/google/cel-go/checker/BUILD.bazel
new file mode 100644
index 000000000000..0b9f9ba36648
--- /dev/null
+++ b/vendor/github.com/google/cel-go/checker/BUILD.bazel
@@ -0,0 +1,38 @@
+load("@io_bazel_rules_go//go:def.bzl", "go_library")
+
+package(
+ licenses = ["notice"], # Apache 2.0
+)
+
+go_library(
+ name = "go_default_library",
+ srcs = [
+ "checker.go",
+ "cost.go",
+ "env.go",
+ "errors.go",
+ "format.go",
+ "mapping.go",
+ "options.go",
+ "printer.go",
+ "scopes.go",
+ "types.go",
+ ],
+ importmap = "kubevirt.io/kubevirt/vendor/github.com/google/cel-go/checker",
+ importpath = "github.com/google/cel-go/checker",
+ visibility = ["//visibility:public"],
+ deps = [
+ "//vendor/github.com/google/cel-go/checker/decls:go_default_library",
+ "//vendor/github.com/google/cel-go/common:go_default_library",
+ "//vendor/github.com/google/cel-go/common/ast:go_default_library",
+ "//vendor/github.com/google/cel-go/common/containers:go_default_library",
+ "//vendor/github.com/google/cel-go/common/debug:go_default_library",
+ "//vendor/github.com/google/cel-go/common/decls:go_default_library",
+ "//vendor/github.com/google/cel-go/common/operators:go_default_library",
+ "//vendor/github.com/google/cel-go/common/overloads:go_default_library",
+ "//vendor/github.com/google/cel-go/common/types:go_default_library",
+ "//vendor/github.com/google/cel-go/common/types/ref:go_default_library",
+ "//vendor/github.com/google/cel-go/parser:go_default_library",
+ "//vendor/google.golang.org/genproto/googleapis/api/expr/v1alpha1:go_default_library",
+ ],
+)
diff --git a/vendor/github.com/google/cel-go/checker/checker.go b/vendor/github.com/google/cel-go/checker/checker.go
new file mode 100644
index 000000000000..57fb3ce5ea15
--- /dev/null
+++ b/vendor/github.com/google/cel-go/checker/checker.go
@@ -0,0 +1,696 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+// Package checker defines functions to type-checked a parsed expression
+// against a set of identifier and function declarations.
+package checker
+
+import (
+ "fmt"
+ "reflect"
+
+ "github.com/google/cel-go/common"
+ "github.com/google/cel-go/common/ast"
+ "github.com/google/cel-go/common/containers"
+ "github.com/google/cel-go/common/decls"
+ "github.com/google/cel-go/common/operators"
+ "github.com/google/cel-go/common/types"
+ "github.com/google/cel-go/common/types/ref"
+)
+
+type checker struct {
+ *ast.AST
+ ast.ExprFactory
+ env *Env
+ errors *typeErrors
+ mappings *mapping
+ freeTypeVarCounter int
+}
+
+// Check performs type checking, giving a typed AST.
+//
+// The input is a parsed AST and an env which encapsulates type binding of variables,
+// declarations of built-in functions, descriptions of protocol buffers, and a registry for
+// errors.
+//
+// Returns a type-checked AST, which might not be usable if there are errors in the error
+// registry.
+func Check(parsed *ast.AST, source common.Source, env *Env) (*ast.AST, *common.Errors) {
+ errs := common.NewErrors(source)
+ typeMap := make(map[int64]*types.Type)
+ refMap := make(map[int64]*ast.ReferenceInfo)
+ c := checker{
+ AST: ast.NewCheckedAST(parsed, typeMap, refMap),
+ ExprFactory: ast.NewExprFactory(),
+ env: env,
+ errors: &typeErrors{errs: errs},
+ mappings: newMapping(),
+ freeTypeVarCounter: 0,
+ }
+ c.check(c.Expr())
+
+ // Walk over the final type map substituting any type parameters either by their bound value
+ // or by DYN.
+ for id, t := range c.TypeMap() {
+ c.SetType(id, substitute(c.mappings, t, true))
+ }
+ return c.AST, errs
+}
+
+func (c *checker) check(e ast.Expr) {
+ if e == nil {
+ return
+ }
+ switch e.Kind() {
+ case ast.LiteralKind:
+ literal := ref.Val(e.AsLiteral())
+ switch literal.Type() {
+ case types.BoolType, types.BytesType, types.DoubleType, types.IntType,
+ types.NullType, types.StringType, types.UintType:
+ c.setType(e, literal.Type().(*types.Type))
+ default:
+ c.errors.unexpectedASTType(e.ID(), c.location(e), "literal", literal.Type().TypeName())
+ }
+ case ast.IdentKind:
+ c.checkIdent(e)
+ case ast.SelectKind:
+ c.checkSelect(e)
+ case ast.CallKind:
+ c.checkCall(e)
+ case ast.ListKind:
+ c.checkCreateList(e)
+ case ast.MapKind:
+ c.checkCreateMap(e)
+ case ast.StructKind:
+ c.checkCreateStruct(e)
+ case ast.ComprehensionKind:
+ c.checkComprehension(e)
+ default:
+ c.errors.unexpectedASTType(e.ID(), c.location(e), "unspecified", reflect.TypeOf(e).Name())
+ }
+}
+
+func (c *checker) checkIdent(e ast.Expr) {
+ identName := e.AsIdent()
+ // Check to see if the identifier is declared.
+ if ident := c.env.LookupIdent(identName); ident != nil {
+ c.setType(e, ident.Type())
+ c.setReference(e, ast.NewIdentReference(ident.Name(), ident.Value()))
+ // Overwrite the identifier with its fully qualified name.
+ e.SetKindCase(c.NewIdent(e.ID(), ident.Name()))
+ return
+ }
+
+ c.setType(e, types.ErrorType)
+ c.errors.undeclaredReference(e.ID(), c.location(e), c.env.container.Name(), identName)
+}
+
+func (c *checker) checkSelect(e ast.Expr) {
+ sel := e.AsSelect()
+ // Before traversing down the tree, try to interpret as qualified name.
+ qname, found := containers.ToQualifiedName(e)
+ if found {
+ ident := c.env.LookupIdent(qname)
+ if ident != nil {
+ // We don't check for a TestOnly expression here since the `found` result is
+ // always going to be false for TestOnly expressions.
+
+ // Rewrite the node to be a variable reference to the resolved fully-qualified
+ // variable name.
+ c.setType(e, ident.Type())
+ c.setReference(e, ast.NewIdentReference(ident.Name(), ident.Value()))
+ e.SetKindCase(c.NewIdent(e.ID(), ident.Name()))
+ return
+ }
+ }
+
+ resultType := c.checkSelectField(e, sel.Operand(), sel.FieldName(), false)
+ if sel.IsTestOnly() {
+ resultType = types.BoolType
+ }
+ c.setType(e, substitute(c.mappings, resultType, false))
+}
+
+func (c *checker) checkOptSelect(e ast.Expr) {
+ // Collect metadata related to the opt select call packaged by the parser.
+ call := e.AsCall()
+ operand := call.Args()[0]
+ field := call.Args()[1]
+ fieldName, isString := maybeUnwrapString(field)
+ if !isString {
+ c.errors.notAnOptionalFieldSelection(field.ID(), c.location(field), field)
+ return
+ }
+
+ // Perform type-checking using the field selection logic.
+ resultType := c.checkSelectField(e, operand, fieldName, true)
+ c.setType(e, substitute(c.mappings, resultType, false))
+ c.setReference(e, ast.NewFunctionReference("select_optional_field"))
+}
+
+func (c *checker) checkSelectField(e, operand ast.Expr, field string, optional bool) *types.Type {
+ // Interpret as field selection, first traversing down the operand.
+ c.check(operand)
+ operandType := substitute(c.mappings, c.getType(operand), false)
+
+ // If the target type is 'optional', unwrap it for the sake of this check.
+ targetType, isOpt := maybeUnwrapOptional(operandType)
+
+ // Assume error type by default as most types do not support field selection.
+ resultType := types.ErrorType
+ switch targetType.Kind() {
+ case types.MapKind:
+ // Maps yield their value type as the selection result type.
+ resultType = targetType.Parameters()[1]
+ case types.StructKind:
+ // Objects yield their field type declaration as the selection result type, but only if
+ // the field is defined.
+ messageType := targetType
+ if fieldType, found := c.lookupFieldType(e.ID(), messageType.TypeName(), field); found {
+ resultType = fieldType
+ }
+ case types.TypeParamKind:
+ // Set the operand type to DYN to prevent assignment to a potentially incorrect type
+ // at a later point in type-checking. The isAssignable call will update the type
+ // substitutions for the type param under the covers.
+ c.isAssignable(types.DynType, targetType)
+ // Also, set the result type to DYN.
+ resultType = types.DynType
+ default:
+ // Dynamic / error values are treated as DYN type. Errors are handled this way as well
+ // in order to allow forward progress on the check.
+ if !isDynOrError(targetType) {
+ c.errors.typeDoesNotSupportFieldSelection(e.ID(), c.location(e), targetType)
+ }
+ resultType = types.DynType
+ }
+
+ // If the target type was optional coming in, then the result must be optional going out.
+ if isOpt || optional {
+ return types.NewOptionalType(resultType)
+ }
+ return resultType
+}
+
+func (c *checker) checkCall(e ast.Expr) {
+ // Note: similar logic exists within the `interpreter/planner.go`. If making changes here
+ // please consider the impact on planner.go and consolidate implementations or mirror code
+ // as appropriate.
+ call := e.AsCall()
+ fnName := call.FunctionName()
+ if fnName == operators.OptSelect {
+ c.checkOptSelect(e)
+ return
+ }
+
+ args := call.Args()
+ // Traverse arguments.
+ for _, arg := range args {
+ c.check(arg)
+ }
+
+ // Regular static call with simple name.
+ if !call.IsMemberFunction() {
+ // Check for the existence of the function.
+ fn := c.env.LookupFunction(fnName)
+ if fn == nil {
+ c.errors.undeclaredReference(e.ID(), c.location(e), c.env.container.Name(), fnName)
+ c.setType(e, types.ErrorType)
+ return
+ }
+ // Overwrite the function name with its fully qualified resolved name.
+ e.SetKindCase(c.NewCall(e.ID(), fn.Name(), args...))
+ // Check to see whether the overload resolves.
+ c.resolveOverloadOrError(e, fn, nil, args)
+ return
+ }
+
+ // If a receiver 'target' is present, it may either be a receiver function, or a namespaced
+ // function, but not both. Given a.b.c() either a.b.c is a function or c is a function with
+ // target a.b.
+ //
+ // Check whether the target is a namespaced function name.
+ target := call.Target()
+ qualifiedPrefix, maybeQualified := containers.ToQualifiedName(target)
+ if maybeQualified {
+ maybeQualifiedName := qualifiedPrefix + "." + fnName
+ fn := c.env.LookupFunction(maybeQualifiedName)
+ if fn != nil {
+ // The function name is namespaced and so preserving the target operand would
+ // be an inaccurate representation of the desired evaluation behavior.
+ // Overwrite with fully-qualified resolved function name sans receiver target.
+ e.SetKindCase(c.NewCall(e.ID(), fn.Name(), args...))
+ c.resolveOverloadOrError(e, fn, nil, args)
+ return
+ }
+ }
+
+ // Regular instance call.
+ c.check(target)
+ fn := c.env.LookupFunction(fnName)
+ // Function found, attempt overload resolution.
+ if fn != nil {
+ c.resolveOverloadOrError(e, fn, target, args)
+ return
+ }
+ // Function name not declared, record error.
+ c.setType(e, types.ErrorType)
+ c.errors.undeclaredReference(e.ID(), c.location(e), c.env.container.Name(), fnName)
+}
+
+func (c *checker) resolveOverloadOrError(
+ e ast.Expr, fn *decls.FunctionDecl, target ast.Expr, args []ast.Expr) {
+ // Attempt to resolve the overload.
+ resolution := c.resolveOverload(e, fn, target, args)
+ // No such overload, error noted in the resolveOverload call, type recorded here.
+ if resolution == nil {
+ c.setType(e, types.ErrorType)
+ return
+ }
+ // Overload found.
+ c.setType(e, resolution.Type)
+ c.setReference(e, resolution.Reference)
+}
+
+func (c *checker) resolveOverload(
+ call ast.Expr, fn *decls.FunctionDecl, target ast.Expr, args []ast.Expr) *overloadResolution {
+
+ var argTypes []*types.Type
+ if target != nil {
+ argTypes = append(argTypes, c.getType(target))
+ }
+ for _, arg := range args {
+ argTypes = append(argTypes, c.getType(arg))
+ }
+
+ var resultType *types.Type
+ var checkedRef *ast.ReferenceInfo
+ for _, overload := range fn.OverloadDecls() {
+ // Determine whether the overload is currently considered.
+ if c.env.isOverloadDisabled(overload.ID()) {
+ continue
+ }
+
+ // Ensure the call style for the overload matches.
+ if (target == nil && overload.IsMemberFunction()) ||
+ (target != nil && !overload.IsMemberFunction()) {
+ // not a compatible call style.
+ continue
+ }
+
+ // Alternative type-checking behavior when the logical operators are compacted into
+ // variadic AST representations.
+ if fn.Name() == operators.LogicalAnd || fn.Name() == operators.LogicalOr {
+ checkedRef = ast.NewFunctionReference(overload.ID())
+ for i, argType := range argTypes {
+ if !c.isAssignable(argType, types.BoolType) {
+ c.errors.typeMismatch(
+ args[i].ID(),
+ c.locationByID(args[i].ID()),
+ types.BoolType,
+ argType)
+ resultType = types.ErrorType
+ }
+ }
+ if isError(resultType) {
+ return nil
+ }
+ return newResolution(checkedRef, types.BoolType)
+ }
+
+ overloadType := newFunctionType(overload.ResultType(), overload.ArgTypes()...)
+ typeParams := overload.TypeParams()
+ if len(typeParams) != 0 {
+ // Instantiate overload's type with fresh type variables.
+ substitutions := newMapping()
+ for _, typePar := range typeParams {
+ substitutions.add(types.NewTypeParamType(typePar), c.newTypeVar())
+ }
+ overloadType = substitute(substitutions, overloadType, false)
+ }
+
+ candidateArgTypes := overloadType.Parameters()[1:]
+ if c.isAssignableList(argTypes, candidateArgTypes) {
+ if checkedRef == nil {
+ checkedRef = ast.NewFunctionReference(overload.ID())
+ } else {
+ checkedRef.AddOverload(overload.ID())
+ }
+
+ // First matching overload, determines result type.
+ fnResultType := substitute(c.mappings, overloadType.Parameters()[0], false)
+ if resultType == nil {
+ resultType = fnResultType
+ } else if !isDyn(resultType) && !fnResultType.IsExactType(resultType) {
+ resultType = types.DynType
+ }
+ }
+ }
+
+ if resultType == nil {
+ for i, argType := range argTypes {
+ argTypes[i] = substitute(c.mappings, argType, true)
+ }
+ c.errors.noMatchingOverload(call.ID(), c.location(call), fn.Name(), argTypes, target != nil)
+ return nil
+ }
+
+ return newResolution(checkedRef, resultType)
+}
+
+func (c *checker) checkCreateList(e ast.Expr) {
+ create := e.AsList()
+ var elemsType *types.Type
+ optionalIndices := create.OptionalIndices()
+ optionals := make(map[int32]bool, len(optionalIndices))
+ for _, optInd := range optionalIndices {
+ optionals[optInd] = true
+ }
+ for i, e := range create.Elements() {
+ c.check(e)
+ elemType := c.getType(e)
+ if optionals[int32(i)] {
+ var isOptional bool
+ elemType, isOptional = maybeUnwrapOptional(elemType)
+ if !isOptional && !isDyn(elemType) {
+ c.errors.typeMismatch(e.ID(), c.location(e), types.NewOptionalType(elemType), elemType)
+ }
+ }
+ elemsType = c.joinTypes(e, elemsType, elemType)
+ }
+ if elemsType == nil {
+ // If the list is empty, assign free type var to elem type.
+ elemsType = c.newTypeVar()
+ }
+ c.setType(e, types.NewListType(elemsType))
+}
+
+func (c *checker) checkCreateMap(e ast.Expr) {
+ mapVal := e.AsMap()
+ var mapKeyType *types.Type
+ var mapValueType *types.Type
+ for _, e := range mapVal.Entries() {
+ entry := e.AsMapEntry()
+ key := entry.Key()
+ c.check(key)
+ mapKeyType = c.joinTypes(key, mapKeyType, c.getType(key))
+
+ val := entry.Value()
+ c.check(val)
+ valType := c.getType(val)
+ if entry.IsOptional() {
+ var isOptional bool
+ valType, isOptional = maybeUnwrapOptional(valType)
+ if !isOptional && !isDyn(valType) {
+ c.errors.typeMismatch(val.ID(), c.location(val), types.NewOptionalType(valType), valType)
+ }
+ }
+ mapValueType = c.joinTypes(val, mapValueType, valType)
+ }
+ if mapKeyType == nil {
+ // If the map is empty, assign free type variables to typeKey and value type.
+ mapKeyType = c.newTypeVar()
+ mapValueType = c.newTypeVar()
+ }
+ c.setType(e, types.NewMapType(mapKeyType, mapValueType))
+}
+
+func (c *checker) checkCreateStruct(e ast.Expr) {
+ msgVal := e.AsStruct()
+ // Determine the type of the message.
+ resultType := types.ErrorType
+ ident := c.env.LookupIdent(msgVal.TypeName())
+ if ident == nil {
+ c.errors.undeclaredReference(
+ e.ID(), c.location(e), c.env.container.Name(), msgVal.TypeName())
+ c.setType(e, types.ErrorType)
+ return
+ }
+ // Ensure the type name is fully qualified in the AST.
+ typeName := ident.Name()
+ if msgVal.TypeName() != typeName {
+ e.SetKindCase(c.NewStruct(e.ID(), typeName, msgVal.Fields()))
+ msgVal = e.AsStruct()
+ }
+ c.setReference(e, ast.NewIdentReference(typeName, nil))
+ identKind := ident.Type().Kind()
+ if identKind != types.ErrorKind {
+ if identKind != types.TypeKind {
+ c.errors.notAType(e.ID(), c.location(e), ident.Type().DeclaredTypeName())
+ } else {
+ resultType = ident.Type().Parameters()[0]
+ // Backwards compatibility test between well-known types and message types
+ // In this context, the type is being instantiated by its protobuf name which
+ // is not ideal or recommended, but some users expect this to work.
+ if isWellKnownType(resultType) {
+ typeName = getWellKnownTypeName(resultType)
+ } else if resultType.Kind() == types.StructKind {
+ typeName = resultType.DeclaredTypeName()
+ } else {
+ c.errors.notAMessageType(e.ID(), c.location(e), resultType.DeclaredTypeName())
+ resultType = types.ErrorType
+ }
+ }
+ }
+ c.setType(e, resultType)
+
+ // Check the field initializers.
+ for _, f := range msgVal.Fields() {
+ field := f.AsStructField()
+ fieldName := field.Name()
+ value := field.Value()
+ c.check(value)
+
+ fieldType := types.ErrorType
+ ft, found := c.lookupFieldType(f.ID(), typeName, fieldName)
+ if found {
+ fieldType = ft
+ }
+
+ valType := c.getType(value)
+ if field.IsOptional() {
+ var isOptional bool
+ valType, isOptional = maybeUnwrapOptional(valType)
+ if !isOptional && !isDyn(valType) {
+ c.errors.typeMismatch(value.ID(), c.location(value), types.NewOptionalType(valType), valType)
+ }
+ }
+ if !c.isAssignable(fieldType, valType) {
+ c.errors.fieldTypeMismatch(f.ID(), c.locationByID(f.ID()), fieldName, fieldType, valType)
+ }
+ }
+}
+
+func (c *checker) checkComprehension(e ast.Expr) {
+ comp := e.AsComprehension()
+ c.check(comp.IterRange())
+ c.check(comp.AccuInit())
+ accuType := c.getType(comp.AccuInit())
+ rangeType := substitute(c.mappings, c.getType(comp.IterRange()), false)
+ var varType *types.Type
+
+ switch rangeType.Kind() {
+ case types.ListKind:
+ varType = rangeType.Parameters()[0]
+ case types.MapKind:
+ // Ranges over the keys.
+ varType = rangeType.Parameters()[0]
+ case types.DynKind, types.ErrorKind, types.TypeParamKind:
+ // Set the range type to DYN to prevent assignment to a potentially incorrect type
+ // at a later point in type-checking. The isAssignable call will update the type
+ // substitutions for the type param under the covers.
+ c.isAssignable(types.DynType, rangeType)
+ // Set the range iteration variable to type DYN as well.
+ varType = types.DynType
+ default:
+ c.errors.notAComprehensionRange(comp.IterRange().ID(), c.location(comp.IterRange()), rangeType)
+ varType = types.ErrorType
+ }
+
+ // Create a scope for the comprehension since it has a local accumulation variable.
+ // This scope will contain the accumulation variable used to compute the result.
+ c.env = c.env.enterScope()
+ c.env.AddIdents(decls.NewVariable(comp.AccuVar(), accuType))
+ // Create a block scope for the loop.
+ c.env = c.env.enterScope()
+ c.env.AddIdents(decls.NewVariable(comp.IterVar(), varType))
+ // Check the variable references in the condition and step.
+ c.check(comp.LoopCondition())
+ c.assertType(comp.LoopCondition(), types.BoolType)
+ c.check(comp.LoopStep())
+ c.assertType(comp.LoopStep(), accuType)
+ // Exit the loop's block scope before checking the result.
+ c.env = c.env.exitScope()
+ c.check(comp.Result())
+ // Exit the comprehension scope.
+ c.env = c.env.exitScope()
+ c.setType(e, substitute(c.mappings, c.getType(comp.Result()), false))
+}
+
+// Checks compatibility of joined types, and returns the most general common type.
+func (c *checker) joinTypes(e ast.Expr, previous, current *types.Type) *types.Type {
+ if previous == nil {
+ return current
+ }
+ if c.isAssignable(previous, current) {
+ return mostGeneral(previous, current)
+ }
+ if c.dynAggregateLiteralElementTypesEnabled() {
+ return types.DynType
+ }
+ c.errors.typeMismatch(e.ID(), c.location(e), previous, current)
+ return types.ErrorType
+}
+
+func (c *checker) dynAggregateLiteralElementTypesEnabled() bool {
+ return c.env.aggLitElemType == dynElementType
+}
+
+func (c *checker) newTypeVar() *types.Type {
+ id := c.freeTypeVarCounter
+ c.freeTypeVarCounter++
+ return types.NewTypeParamType(fmt.Sprintf("_var%d", id))
+}
+
+func (c *checker) isAssignable(t1, t2 *types.Type) bool {
+ subs := isAssignable(c.mappings, t1, t2)
+ if subs != nil {
+ c.mappings = subs
+ return true
+ }
+
+ return false
+}
+
+func (c *checker) isAssignableList(l1, l2 []*types.Type) bool {
+ subs := isAssignableList(c.mappings, l1, l2)
+ if subs != nil {
+ c.mappings = subs
+ return true
+ }
+
+ return false
+}
+
+func maybeUnwrapString(e ast.Expr) (string, bool) {
+ switch e.Kind() {
+ case ast.LiteralKind:
+ literal := e.AsLiteral()
+ switch v := literal.(type) {
+ case types.String:
+ return string(v), true
+ }
+ }
+ return "", false
+}
+
+func (c *checker) setType(e ast.Expr, t *types.Type) {
+ if old, found := c.TypeMap()[e.ID()]; found && !old.IsExactType(t) {
+ c.errors.incompatibleType(e.ID(), c.location(e), e, old, t)
+ return
+ }
+ c.SetType(e.ID(), t)
+}
+
+func (c *checker) getType(e ast.Expr) *types.Type {
+ return c.TypeMap()[e.ID()]
+}
+
+func (c *checker) setReference(e ast.Expr, r *ast.ReferenceInfo) {
+ if old, found := c.ReferenceMap()[e.ID()]; found && !old.Equals(r) {
+ c.errors.referenceRedefinition(e.ID(), c.location(e), e, old, r)
+ return
+ }
+ c.SetReference(e.ID(), r)
+}
+
+func (c *checker) assertType(e ast.Expr, t *types.Type) {
+ if !c.isAssignable(t, c.getType(e)) {
+ c.errors.typeMismatch(e.ID(), c.location(e), t, c.getType(e))
+ }
+}
+
+type overloadResolution struct {
+ Type *types.Type
+ Reference *ast.ReferenceInfo
+}
+
+func newResolution(r *ast.ReferenceInfo, t *types.Type) *overloadResolution {
+ return &overloadResolution{
+ Reference: r,
+ Type: t,
+ }
+}
+
+func (c *checker) location(e ast.Expr) common.Location {
+ return c.locationByID(e.ID())
+}
+
+func (c *checker) locationByID(id int64) common.Location {
+ return c.SourceInfo().GetStartLocation(id)
+}
+
+func (c *checker) lookupFieldType(exprID int64, structType, fieldName string) (*types.Type, bool) {
+ if _, found := c.env.provider.FindStructType(structType); !found {
+ // This should not happen, anyway, report an error.
+ c.errors.unexpectedFailedResolution(exprID, c.locationByID(exprID), structType)
+ return nil, false
+ }
+
+ if ft, found := c.env.provider.FindStructFieldType(structType, fieldName); found {
+ return ft.Type, found
+ }
+
+ c.errors.undefinedField(exprID, c.locationByID(exprID), fieldName)
+ return nil, false
+}
+
+func isWellKnownType(t *types.Type) bool {
+ switch t.Kind() {
+ case types.AnyKind, types.TimestampKind, types.DurationKind, types.DynKind, types.NullTypeKind:
+ return true
+ case types.BoolKind, types.BytesKind, types.DoubleKind, types.IntKind, types.StringKind, types.UintKind:
+ return t.IsAssignableType(types.NullType)
+ case types.ListKind:
+ return t.Parameters()[0] == types.DynType
+ case types.MapKind:
+ return t.Parameters()[0] == types.StringType && t.Parameters()[1] == types.DynType
+ }
+ return false
+}
+
+func getWellKnownTypeName(t *types.Type) string {
+ if name, found := wellKnownTypes[t.Kind()]; found {
+ return name
+ }
+ return ""
+}
+
+var (
+ wellKnownTypes = map[types.Kind]string{
+ types.AnyKind: "google.protobuf.Any",
+ types.BoolKind: "google.protobuf.BoolValue",
+ types.BytesKind: "google.protobuf.BytesValue",
+ types.DoubleKind: "google.protobuf.DoubleValue",
+ types.DurationKind: "google.protobuf.Duration",
+ types.DynKind: "google.protobuf.Value",
+ types.IntKind: "google.protobuf.Int64Value",
+ types.ListKind: "google.protobuf.ListValue",
+ types.NullTypeKind: "google.protobuf.NullValue",
+ types.MapKind: "google.protobuf.Struct",
+ types.StringKind: "google.protobuf.StringValue",
+ types.TimestampKind: "google.protobuf.Timestamp",
+ types.UintKind: "google.protobuf.UInt64Value",
+ }
+)
diff --git a/vendor/github.com/google/cel-go/checker/cost.go b/vendor/github.com/google/cel-go/checker/cost.go
new file mode 100644
index 000000000000..04244694d818
--- /dev/null
+++ b/vendor/github.com/google/cel-go/checker/cost.go
@@ -0,0 +1,705 @@
+// Copyright 2022 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package checker
+
+import (
+ "math"
+
+ "github.com/google/cel-go/common"
+ "github.com/google/cel-go/common/ast"
+ "github.com/google/cel-go/common/overloads"
+ "github.com/google/cel-go/common/types"
+ "github.com/google/cel-go/parser"
+)
+
+// WARNING: Any changes to cost calculations in this file require a corresponding change in interpreter/runtimecost.go
+
+// CostEstimator estimates the sizes of variable length input data and the costs of functions.
+type CostEstimator interface {
+ // EstimateSize returns a SizeEstimate for the given AstNode, or nil if
+ // the estimator has no estimate to provide. The size is equivalent to the result of the CEL `size()` function:
+ // length of strings and bytes, number of map entries or number of list items.
+ // EstimateSize is only called for AstNodes where
+ // CEL does not know the size; EstimateSize is not called for values defined inline in CEL where the size
+ // is already obvious to CEL.
+ EstimateSize(element AstNode) *SizeEstimate
+ // EstimateCallCost returns the estimated cost of an invocation, or nil if
+ // the estimator has no estimate to provide.
+ EstimateCallCost(function, overloadID string, target *AstNode, args []AstNode) *CallEstimate
+}
+
+// CallEstimate includes a CostEstimate for the call, and an optional estimate of the result object size.
+// The ResultSize should only be provided if the call results in a map, list, string or bytes.
+type CallEstimate struct {
+ CostEstimate
+ ResultSize *SizeEstimate
+}
+
+// AstNode represents an AST node for the purpose of cost estimations.
+type AstNode interface {
+ // Path returns a field path through the provided type declarations to the type of the AstNode, or nil if the AstNode does not
+ // represent type directly reachable from the provided type declarations.
+ // The first path element is a variable. All subsequent path elements are one of: field name, '@items', '@keys', '@values'.
+ Path() []string
+ // Type returns the deduced type of the AstNode.
+ Type() *types.Type
+ // Expr returns the expression of the AstNode.
+ Expr() ast.Expr
+ // ComputedSize returns a size estimate of the AstNode derived from information available in the CEL expression.
+ // For constants and inline list and map declarations, the exact size is returned. For concatenated list, strings
+ // and bytes, the size is derived from the size estimates of the operands. nil is returned if there is no
+ // computed size available.
+ ComputedSize() *SizeEstimate
+}
+
+type astNode struct {
+ path []string
+ t *types.Type
+ expr ast.Expr
+ derivedSize *SizeEstimate
+}
+
+func (e astNode) Path() []string {
+ return e.path
+}
+
+func (e astNode) Type() *types.Type {
+ return e.t
+}
+
+func (e astNode) Expr() ast.Expr {
+ return e.expr
+}
+
+func (e astNode) ComputedSize() *SizeEstimate {
+ if e.derivedSize != nil {
+ return e.derivedSize
+ }
+ var v uint64
+ switch e.expr.Kind() {
+ case ast.LiteralKind:
+ switch ck := e.expr.AsLiteral().(type) {
+ case types.String:
+ // converting to runes here is an O(n) operation, but
+ // this is consistent with how size is computed at runtime,
+ // and how the language definition defines string size
+ v = uint64(len([]rune(ck)))
+ case types.Bytes:
+ v = uint64(len(ck))
+ case types.Bool, types.Double, types.Duration,
+ types.Int, types.Timestamp, types.Uint,
+ types.Null:
+ v = uint64(1)
+ default:
+ return nil
+ }
+ case ast.ListKind:
+ v = uint64(e.expr.AsList().Size())
+ case ast.MapKind:
+ v = uint64(e.expr.AsMap().Size())
+ default:
+ return nil
+ }
+
+ return &SizeEstimate{Min: v, Max: v}
+}
+
+// SizeEstimate represents an estimated size of a variable length string, bytes, map or list.
+type SizeEstimate struct {
+ Min, Max uint64
+}
+
+// Add adds to another SizeEstimate and returns the sum.
+// If add would result in an uint64 overflow, the result is math.MaxUint64.
+func (se SizeEstimate) Add(sizeEstimate SizeEstimate) SizeEstimate {
+ return SizeEstimate{
+ addUint64NoOverflow(se.Min, sizeEstimate.Min),
+ addUint64NoOverflow(se.Max, sizeEstimate.Max),
+ }
+}
+
+// Multiply multiplies by another SizeEstimate and returns the product.
+// If multiply would result in an uint64 overflow, the result is math.MaxUint64.
+func (se SizeEstimate) Multiply(sizeEstimate SizeEstimate) SizeEstimate {
+ return SizeEstimate{
+ multiplyUint64NoOverflow(se.Min, sizeEstimate.Min),
+ multiplyUint64NoOverflow(se.Max, sizeEstimate.Max),
+ }
+}
+
+// MultiplyByCostFactor multiplies a SizeEstimate by a cost factor and returns the CostEstimate with the
+// nearest integer of the result, rounded up.
+func (se SizeEstimate) MultiplyByCostFactor(costPerUnit float64) CostEstimate {
+ return CostEstimate{
+ multiplyByCostFactor(se.Min, costPerUnit),
+ multiplyByCostFactor(se.Max, costPerUnit),
+ }
+}
+
+// MultiplyByCost multiplies by the cost and returns the product.
+// If multiply would result in an uint64 overflow, the result is math.MaxUint64.
+func (se SizeEstimate) MultiplyByCost(cost CostEstimate) CostEstimate {
+ return CostEstimate{
+ multiplyUint64NoOverflow(se.Min, cost.Min),
+ multiplyUint64NoOverflow(se.Max, cost.Max),
+ }
+}
+
+// Union returns a SizeEstimate that encompasses both input the SizeEstimate.
+func (se SizeEstimate) Union(size SizeEstimate) SizeEstimate {
+ result := se
+ if size.Min < result.Min {
+ result.Min = size.Min
+ }
+ if size.Max > result.Max {
+ result.Max = size.Max
+ }
+ return result
+}
+
+// CostEstimate represents an estimated cost range and provides add and multiply operations
+// that do not overflow.
+type CostEstimate struct {
+ Min, Max uint64
+}
+
+// Add adds the costs and returns the sum.
+// If add would result in an uint64 overflow for the min or max, the value is set to math.MaxUint64.
+func (ce CostEstimate) Add(cost CostEstimate) CostEstimate {
+ return CostEstimate{
+ addUint64NoOverflow(ce.Min, cost.Min),
+ addUint64NoOverflow(ce.Max, cost.Max),
+ }
+}
+
+// Multiply multiplies by the cost and returns the product.
+// If multiply would result in an uint64 overflow, the result is math.MaxUint64.
+func (ce CostEstimate) Multiply(cost CostEstimate) CostEstimate {
+ return CostEstimate{
+ multiplyUint64NoOverflow(ce.Min, cost.Min),
+ multiplyUint64NoOverflow(ce.Max, cost.Max),
+ }
+}
+
+// MultiplyByCostFactor multiplies a CostEstimate by a cost factor and returns the CostEstimate with the
+// nearest integer of the result, rounded up.
+func (ce CostEstimate) MultiplyByCostFactor(costPerUnit float64) CostEstimate {
+ return CostEstimate{
+ multiplyByCostFactor(ce.Min, costPerUnit),
+ multiplyByCostFactor(ce.Max, costPerUnit),
+ }
+}
+
+// Union returns a CostEstimate that encompasses both input the CostEstimates.
+func (ce CostEstimate) Union(size CostEstimate) CostEstimate {
+ result := ce
+ if size.Min < result.Min {
+ result.Min = size.Min
+ }
+ if size.Max > result.Max {
+ result.Max = size.Max
+ }
+ return result
+}
+
+// addUint64NoOverflow adds non-negative ints. If the result is exceeds math.MaxUint64, math.MaxUint64
+// is returned.
+func addUint64NoOverflow(x, y uint64) uint64 {
+ if y > 0 && x > math.MaxUint64-y {
+ return math.MaxUint64
+ }
+ return x + y
+}
+
+// multiplyUint64NoOverflow multiplies non-negative ints. If the result is exceeds math.MaxUint64, math.MaxUint64
+// is returned.
+func multiplyUint64NoOverflow(x, y uint64) uint64 {
+ if y != 0 && x > math.MaxUint64/y {
+ return math.MaxUint64
+ }
+ return x * y
+}
+
+// multiplyByFactor multiplies an integer by a cost factor float and returns the nearest integer value, rounded up.
+func multiplyByCostFactor(x uint64, y float64) uint64 {
+ xFloat := float64(x)
+ if xFloat > 0 && y > 0 && xFloat > math.MaxUint64/y {
+ return math.MaxUint64
+ }
+ ceil := math.Ceil(xFloat * y)
+ if ceil >= doubleTwoTo64 {
+ return math.MaxUint64
+ }
+ return uint64(ceil)
+}
+
+var (
+ selectAndIdentCost = CostEstimate{Min: common.SelectAndIdentCost, Max: common.SelectAndIdentCost}
+ constCost = CostEstimate{Min: common.ConstCost, Max: common.ConstCost}
+
+ createListBaseCost = CostEstimate{Min: common.ListCreateBaseCost, Max: common.ListCreateBaseCost}
+ createMapBaseCost = CostEstimate{Min: common.MapCreateBaseCost, Max: common.MapCreateBaseCost}
+ createMessageBaseCost = CostEstimate{Min: common.StructCreateBaseCost, Max: common.StructCreateBaseCost}
+)
+
+type coster struct {
+ // exprPath maps from Expr Id to field path.
+ exprPath map[int64][]string
+ // iterRanges tracks the iterRange of each iterVar.
+ iterRanges iterRangeScopes
+ // computedSizes tracks the computed sizes of call results.
+ computedSizes map[int64]SizeEstimate
+ checkedAST *ast.AST
+ estimator CostEstimator
+ overloadEstimators map[string]FunctionEstimator
+ // presenceTestCost will either be a zero or one based on whether has() macros count against cost computations.
+ presenceTestCost CostEstimate
+}
+
+// Use a stack of iterVar -> iterRange Expr Ids to handle shadowed variable names.
+type iterRangeScopes map[string][]int64
+
+func (vs iterRangeScopes) push(varName string, expr ast.Expr) {
+ vs[varName] = append(vs[varName], expr.ID())
+}
+
+func (vs iterRangeScopes) pop(varName string) {
+ varStack := vs[varName]
+ vs[varName] = varStack[:len(varStack)-1]
+}
+
+func (vs iterRangeScopes) peek(varName string) (int64, bool) {
+ varStack := vs[varName]
+ if len(varStack) > 0 {
+ return varStack[len(varStack)-1], true
+ }
+ return 0, false
+}
+
+// CostOption configures flags which affect cost computations.
+type CostOption func(*coster) error
+
+// PresenceTestHasCost determines whether presence testing has a cost of one or zero.
+//
+// Defaults to presence test has a cost of one.
+func PresenceTestHasCost(hasCost bool) CostOption {
+ return func(c *coster) error {
+ if hasCost {
+ c.presenceTestCost = selectAndIdentCost
+ return nil
+ }
+ c.presenceTestCost = CostEstimate{Min: 0, Max: 0}
+ return nil
+ }
+}
+
+// FunctionEstimator provides a CallEstimate given the target and arguments for a specific function, overload pair.
+type FunctionEstimator func(estimator CostEstimator, target *AstNode, args []AstNode) *CallEstimate
+
+// OverloadCostEstimate binds a FunctionCoster to a specific function overload ID.
+//
+// When a OverloadCostEstimate is provided, it will override the cost calculation of the CostEstimator provided to
+// the Cost() call.
+func OverloadCostEstimate(overloadID string, functionCoster FunctionEstimator) CostOption {
+ return func(c *coster) error {
+ c.overloadEstimators[overloadID] = functionCoster
+ return nil
+ }
+}
+
+// Cost estimates the cost of the parsed and type checked CEL expression.
+func Cost(checked *ast.AST, estimator CostEstimator, opts ...CostOption) (CostEstimate, error) {
+ c := &coster{
+ checkedAST: checked,
+ estimator: estimator,
+ overloadEstimators: map[string]FunctionEstimator{},
+ exprPath: map[int64][]string{},
+ iterRanges: map[string][]int64{},
+ computedSizes: map[int64]SizeEstimate{},
+ presenceTestCost: CostEstimate{Min: 1, Max: 1},
+ }
+ for _, opt := range opts {
+ err := opt(c)
+ if err != nil {
+ return CostEstimate{}, err
+ }
+ }
+ return c.cost(checked.Expr()), nil
+}
+
+func (c *coster) cost(e ast.Expr) CostEstimate {
+ if e == nil {
+ return CostEstimate{}
+ }
+ var cost CostEstimate
+ switch e.Kind() {
+ case ast.LiteralKind:
+ cost = constCost
+ case ast.IdentKind:
+ cost = c.costIdent(e)
+ case ast.SelectKind:
+ cost = c.costSelect(e)
+ case ast.CallKind:
+ cost = c.costCall(e)
+ case ast.ListKind:
+ cost = c.costCreateList(e)
+ case ast.MapKind:
+ cost = c.costCreateMap(e)
+ case ast.StructKind:
+ cost = c.costCreateStruct(e)
+ case ast.ComprehensionKind:
+ cost = c.costComprehension(e)
+ default:
+ return CostEstimate{}
+ }
+ return cost
+}
+
+func (c *coster) costIdent(e ast.Expr) CostEstimate {
+ identName := e.AsIdent()
+ // build and track the field path
+ if iterRange, ok := c.iterRanges.peek(identName); ok {
+ switch c.checkedAST.GetType(iterRange).Kind() {
+ case types.ListKind:
+ c.addPath(e, append(c.exprPath[iterRange], "@items"))
+ case types.MapKind:
+ c.addPath(e, append(c.exprPath[iterRange], "@keys"))
+ }
+ } else {
+ c.addPath(e, []string{identName})
+ }
+
+ return selectAndIdentCost
+}
+
+func (c *coster) costSelect(e ast.Expr) CostEstimate {
+ sel := e.AsSelect()
+ var sum CostEstimate
+ if sel.IsTestOnly() {
+ // recurse, but do not add any cost
+ // this is equivalent to how evalTestOnly increments the runtime cost counter
+ // but does not add any additional cost for the qualifier, except here we do
+ // the reverse (ident adds cost)
+ sum = sum.Add(c.presenceTestCost)
+ sum = sum.Add(c.cost(sel.Operand()))
+ return sum
+ }
+ sum = sum.Add(c.cost(sel.Operand()))
+ targetType := c.getType(sel.Operand())
+ switch targetType.Kind() {
+ case types.MapKind, types.StructKind, types.TypeParamKind:
+ sum = sum.Add(selectAndIdentCost)
+ }
+
+ // build and track the field path
+ c.addPath(e, append(c.getPath(sel.Operand()), sel.FieldName()))
+
+ return sum
+}
+
+func (c *coster) costCall(e ast.Expr) CostEstimate {
+ call := e.AsCall()
+ args := call.Args()
+
+ var sum CostEstimate
+
+ argTypes := make([]AstNode, len(args))
+ argCosts := make([]CostEstimate, len(args))
+ for i, arg := range args {
+ argCosts[i] = c.cost(arg)
+ argTypes[i] = c.newAstNode(arg)
+ }
+
+ overloadIDs := c.checkedAST.GetOverloadIDs(e.ID())
+ if len(overloadIDs) == 0 {
+ return CostEstimate{}
+ }
+ var targetType AstNode
+ if call.IsMemberFunction() {
+ sum = sum.Add(c.cost(call.Target()))
+ targetType = c.newAstNode(call.Target())
+ }
+ // Pick a cost estimate range that covers all the overload cost estimation ranges
+ fnCost := CostEstimate{Min: uint64(math.MaxUint64), Max: 0}
+ var resultSize *SizeEstimate
+ for _, overload := range overloadIDs {
+ overloadCost := c.functionCost(call.FunctionName(), overload, &targetType, argTypes, argCosts)
+ fnCost = fnCost.Union(overloadCost.CostEstimate)
+ if overloadCost.ResultSize != nil {
+ if resultSize == nil {
+ resultSize = overloadCost.ResultSize
+ } else {
+ size := resultSize.Union(*overloadCost.ResultSize)
+ resultSize = &size
+ }
+ }
+ // build and track the field path for index operations
+ switch overload {
+ case overloads.IndexList:
+ if len(args) > 0 {
+ c.addPath(e, append(c.getPath(args[0]), "@items"))
+ }
+ case overloads.IndexMap:
+ if len(args) > 0 {
+ c.addPath(e, append(c.getPath(args[0]), "@values"))
+ }
+ }
+ }
+ if resultSize != nil {
+ c.computedSizes[e.ID()] = *resultSize
+ }
+ return sum.Add(fnCost)
+}
+
+func (c *coster) costCreateList(e ast.Expr) CostEstimate {
+ create := e.AsList()
+ var sum CostEstimate
+ for _, e := range create.Elements() {
+ sum = sum.Add(c.cost(e))
+ }
+ return sum.Add(createListBaseCost)
+}
+
+func (c *coster) costCreateMap(e ast.Expr) CostEstimate {
+ mapVal := e.AsMap()
+ var sum CostEstimate
+ for _, ent := range mapVal.Entries() {
+ entry := ent.AsMapEntry()
+ sum = sum.Add(c.cost(entry.Key()))
+ sum = sum.Add(c.cost(entry.Value()))
+ }
+ return sum.Add(createMapBaseCost)
+}
+
+func (c *coster) costCreateStruct(e ast.Expr) CostEstimate {
+ msgVal := e.AsStruct()
+ var sum CostEstimate
+ for _, ent := range msgVal.Fields() {
+ field := ent.AsStructField()
+ sum = sum.Add(c.cost(field.Value()))
+ }
+ return sum.Add(createMessageBaseCost)
+}
+
+func (c *coster) costComprehension(e ast.Expr) CostEstimate {
+ comp := e.AsComprehension()
+ var sum CostEstimate
+ sum = sum.Add(c.cost(comp.IterRange()))
+ sum = sum.Add(c.cost(comp.AccuInit()))
+
+ // Track the iterRange of each IterVar for field path construction
+ c.iterRanges.push(comp.IterVar(), comp.IterRange())
+ loopCost := c.cost(comp.LoopCondition())
+ stepCost := c.cost(comp.LoopStep())
+ c.iterRanges.pop(comp.IterVar())
+ sum = sum.Add(c.cost(comp.Result()))
+ rangeCnt := c.sizeEstimate(c.newAstNode(comp.IterRange()))
+
+ c.computedSizes[e.ID()] = rangeCnt
+
+ rangeCost := rangeCnt.MultiplyByCost(stepCost.Add(loopCost))
+ sum = sum.Add(rangeCost)
+
+ return sum
+}
+
+func (c *coster) sizeEstimate(t AstNode) SizeEstimate {
+ if l := t.ComputedSize(); l != nil {
+ return *l
+ }
+ if l := c.estimator.EstimateSize(t); l != nil {
+ return *l
+ }
+ // return an estimate of 1 for return types of set
+ // lengths, since strings/bytes/more complex objects could be of
+ // variable length
+ if isScalar(t.Type()) {
+ // TODO: since the logic for size estimation is split between
+ // ComputedSize and isScalar, changing one will likely require changing
+ // the other, so they should be merged in the future if possible
+ return SizeEstimate{Min: 1, Max: 1}
+ }
+ return SizeEstimate{Min: 0, Max: math.MaxUint64}
+}
+
+func (c *coster) functionCost(function, overloadID string, target *AstNode, args []AstNode, argCosts []CostEstimate) CallEstimate {
+ argCostSum := func() CostEstimate {
+ var sum CostEstimate
+ for _, a := range argCosts {
+ sum = sum.Add(a)
+ }
+ return sum
+ }
+ if len(c.overloadEstimators) != 0 {
+ if estimator, found := c.overloadEstimators[overloadID]; found {
+ if est := estimator(c.estimator, target, args); est != nil {
+ callEst := *est
+ return CallEstimate{CostEstimate: callEst.Add(argCostSum()), ResultSize: est.ResultSize}
+ }
+ }
+ }
+ if est := c.estimator.EstimateCallCost(function, overloadID, target, args); est != nil {
+ callEst := *est
+ return CallEstimate{CostEstimate: callEst.Add(argCostSum()), ResultSize: est.ResultSize}
+ }
+ switch overloadID {
+ // O(n) functions
+ case overloads.ExtFormatString:
+ if target != nil {
+ // ResultSize not calculated because we can't bound the max size.
+ return CallEstimate{CostEstimate: c.sizeEstimate(*target).MultiplyByCostFactor(common.StringTraversalCostFactor).Add(argCostSum())}
+ }
+ case overloads.StringToBytes:
+ if len(args) == 1 {
+ sz := c.sizeEstimate(args[0])
+ // ResultSize max is when each char converts to 4 bytes.
+ return CallEstimate{CostEstimate: sz.MultiplyByCostFactor(common.StringTraversalCostFactor).Add(argCostSum()), ResultSize: &SizeEstimate{Min: sz.Min, Max: sz.Max * 4}}
+ }
+ case overloads.BytesToString:
+ if len(args) == 1 {
+ sz := c.sizeEstimate(args[0])
+ // ResultSize min is when 4 bytes convert to 1 char.
+ return CallEstimate{CostEstimate: sz.MultiplyByCostFactor(common.StringTraversalCostFactor).Add(argCostSum()), ResultSize: &SizeEstimate{Min: sz.Min / 4, Max: sz.Max}}
+ }
+ case overloads.ExtQuoteString:
+ if len(args) == 1 {
+ sz := c.sizeEstimate(args[0])
+ // ResultSize max is when each char is escaped. 2 quote chars always added.
+ return CallEstimate{CostEstimate: sz.MultiplyByCostFactor(common.StringTraversalCostFactor).Add(argCostSum()), ResultSize: &SizeEstimate{Min: sz.Min + 2, Max: sz.Max*2 + 2}}
+ }
+ case overloads.StartsWithString, overloads.EndsWithString:
+ if len(args) == 1 {
+ return CallEstimate{CostEstimate: c.sizeEstimate(args[0]).MultiplyByCostFactor(common.StringTraversalCostFactor).Add(argCostSum())}
+ }
+ case overloads.InList:
+ // If a list is composed entirely of constant values this is O(1), but we don't account for that here.
+ // We just assume all list containment checks are O(n).
+ if len(args) == 2 {
+ return CallEstimate{CostEstimate: c.sizeEstimate(args[1]).MultiplyByCostFactor(1).Add(argCostSum())}
+ }
+ // O(nm) functions
+ case overloads.MatchesString:
+ // https://swtch.com/~rsc/regexp/regexp1.html applies to RE2 implementation supported by CEL
+ if target != nil && len(args) == 1 {
+ // Add one to string length for purposes of cost calculation to prevent product of string and regex to be 0
+ // in case where string is empty but regex is still expensive.
+ strCost := c.sizeEstimate(*target).Add(SizeEstimate{Min: 1, Max: 1}).MultiplyByCostFactor(common.StringTraversalCostFactor)
+ // We don't know how many expressions are in the regex, just the string length (a huge
+ // improvement here would be to somehow get a count the number of expressions in the regex or
+ // how many states are in the regex state machine and use that to measure regex cost).
+ // For now, we're making a guess that each expression in a regex is typically at least 4 chars
+ // in length.
+ regexCost := c.sizeEstimate(args[0]).MultiplyByCostFactor(common.RegexStringLengthCostFactor)
+ return CallEstimate{CostEstimate: strCost.Multiply(regexCost).Add(argCostSum())}
+ }
+ case overloads.ContainsString:
+ if target != nil && len(args) == 1 {
+ strCost := c.sizeEstimate(*target).MultiplyByCostFactor(common.StringTraversalCostFactor)
+ substrCost := c.sizeEstimate(args[0]).MultiplyByCostFactor(common.StringTraversalCostFactor)
+ return CallEstimate{CostEstimate: strCost.Multiply(substrCost).Add(argCostSum())}
+ }
+ case overloads.LogicalOr, overloads.LogicalAnd:
+ lhs := argCosts[0]
+ rhs := argCosts[1]
+ // min cost is min of LHS for short circuited && or ||
+ argCost := CostEstimate{Min: lhs.Min, Max: lhs.Add(rhs).Max}
+ return CallEstimate{CostEstimate: argCost}
+ case overloads.Conditional:
+ size := c.sizeEstimate(args[1]).Union(c.sizeEstimate(args[2]))
+ conditionalCost := argCosts[0]
+ ifTrueCost := argCosts[1]
+ ifFalseCost := argCosts[2]
+ argCost := conditionalCost.Add(ifTrueCost.Union(ifFalseCost))
+ return CallEstimate{CostEstimate: argCost, ResultSize: &size}
+ case overloads.AddString, overloads.AddBytes, overloads.AddList:
+ if len(args) == 2 {
+ lhsSize := c.sizeEstimate(args[0])
+ rhsSize := c.sizeEstimate(args[1])
+ resultSize := lhsSize.Add(rhsSize)
+ switch overloadID {
+ case overloads.AddList:
+ // list concatenation is O(1), but we handle it here to track size
+ return CallEstimate{CostEstimate: CostEstimate{Min: 1, Max: 1}.Add(argCostSum()), ResultSize: &resultSize}
+ default:
+ return CallEstimate{CostEstimate: resultSize.MultiplyByCostFactor(common.StringTraversalCostFactor).Add(argCostSum()), ResultSize: &resultSize}
+ }
+ }
+ case overloads.LessString, overloads.GreaterString, overloads.LessEqualsString, overloads.GreaterEqualsString,
+ overloads.LessBytes, overloads.GreaterBytes, overloads.LessEqualsBytes, overloads.GreaterEqualsBytes,
+ overloads.Equals, overloads.NotEquals:
+ lhsCost := c.sizeEstimate(args[0])
+ rhsCost := c.sizeEstimate(args[1])
+ min := uint64(0)
+ smallestMax := lhsCost.Max
+ if rhsCost.Max < smallestMax {
+ smallestMax = rhsCost.Max
+ }
+ if smallestMax > 0 {
+ min = 1
+ }
+ // equality of 2 scalar values results in a cost of 1
+ return CallEstimate{CostEstimate: CostEstimate{Min: min, Max: smallestMax}.MultiplyByCostFactor(common.StringTraversalCostFactor).Add(argCostSum())}
+ }
+ // O(1) functions
+ // See CostTracker.costCall for more details about O(1) cost calculations
+
+ // Benchmarks suggest that most of the other operations take +/- 50% of a base cost unit
+ // which on an Intel xeon 2.20GHz CPU is 50ns.
+ return CallEstimate{CostEstimate: CostEstimate{Min: 1, Max: 1}.Add(argCostSum())}
+}
+
+func (c *coster) getType(e ast.Expr) *types.Type {
+ return c.checkedAST.GetType(e.ID())
+}
+
+func (c *coster) getPath(e ast.Expr) []string {
+ return c.exprPath[e.ID()]
+}
+
+func (c *coster) addPath(e ast.Expr, path []string) {
+ c.exprPath[e.ID()] = path
+}
+
+func (c *coster) newAstNode(e ast.Expr) *astNode {
+ path := c.getPath(e)
+ if len(path) > 0 && path[0] == parser.AccumulatorName {
+ // only provide paths to root vars; omit accumulator vars
+ path = nil
+ }
+ var derivedSize *SizeEstimate
+ if size, ok := c.computedSizes[e.ID()]; ok {
+ derivedSize = &size
+ }
+ return &astNode{
+ path: path,
+ t: c.getType(e),
+ expr: e,
+ derivedSize: derivedSize}
+}
+
+// isScalar returns true if the given type is known to be of a constant size at
+// compile time. isScalar will return false for strings (they are variable-width)
+// in addition to protobuf.Any and protobuf.Value (their size is not knowable at compile time).
+func isScalar(t *types.Type) bool {
+ switch t.Kind() {
+ case types.BoolKind, types.DoubleKind, types.DurationKind, types.IntKind, types.TimestampKind, types.UintKind:
+ return true
+ }
+ return false
+}
+
+var (
+ doubleTwoTo64 = math.Ldexp(1.0, 64)
+)
diff --git a/vendor/github.com/google/cel-go/checker/decls/BUILD.bazel b/vendor/github.com/google/cel-go/checker/decls/BUILD.bazel
new file mode 100644
index 000000000000..fe8fb8e1a7b7
--- /dev/null
+++ b/vendor/github.com/google/cel-go/checker/decls/BUILD.bazel
@@ -0,0 +1,18 @@
+load("@io_bazel_rules_go//go:def.bzl", "go_library")
+
+package(
+ default_visibility = ["//visibility:public"],
+ licenses = ["notice"], # Apache 2.0
+)
+
+go_library(
+ name = "go_default_library",
+ srcs = ["decls.go"],
+ importmap = "kubevirt.io/kubevirt/vendor/github.com/google/cel-go/checker/decls",
+ importpath = "github.com/google/cel-go/checker/decls",
+ deps = [
+ "//vendor/google.golang.org/genproto/googleapis/api/expr/v1alpha1:go_default_library",
+ "//vendor/google.golang.org/protobuf/types/known/emptypb:go_default_library",
+ "//vendor/google.golang.org/protobuf/types/known/structpb:go_default_library",
+ ],
+)
diff --git a/vendor/github.com/google/cel-go/checker/decls/decls.go b/vendor/github.com/google/cel-go/checker/decls/decls.go
new file mode 100644
index 000000000000..c0e5de469f58
--- /dev/null
+++ b/vendor/github.com/google/cel-go/checker/decls/decls.go
@@ -0,0 +1,237 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+// Package decls provides helpers for creating variable and function declarations.
+package decls
+
+import (
+ exprpb "google.golang.org/genproto/googleapis/api/expr/v1alpha1"
+ emptypb "google.golang.org/protobuf/types/known/emptypb"
+ structpb "google.golang.org/protobuf/types/known/structpb"
+)
+
+var (
+ // Error type used to communicate issues during type-checking.
+ Error = &exprpb.Type{
+ TypeKind: &exprpb.Type_Error{
+ Error: &emptypb.Empty{}}}
+
+ // Dyn is a top-type used to represent any value.
+ Dyn = &exprpb.Type{
+ TypeKind: &exprpb.Type_Dyn{
+ Dyn: &emptypb.Empty{}}}
+)
+
+// Commonly used types.
+var (
+ Bool = NewPrimitiveType(exprpb.Type_BOOL)
+ Bytes = NewPrimitiveType(exprpb.Type_BYTES)
+ Double = NewPrimitiveType(exprpb.Type_DOUBLE)
+ Int = NewPrimitiveType(exprpb.Type_INT64)
+ Null = &exprpb.Type{
+ TypeKind: &exprpb.Type_Null{
+ Null: structpb.NullValue_NULL_VALUE}}
+ String = NewPrimitiveType(exprpb.Type_STRING)
+ Uint = NewPrimitiveType(exprpb.Type_UINT64)
+)
+
+// Well-known types.
+// TODO: Replace with an abstract type registry.
+var (
+ Any = NewWellKnownType(exprpb.Type_ANY)
+ Duration = NewWellKnownType(exprpb.Type_DURATION)
+ Timestamp = NewWellKnownType(exprpb.Type_TIMESTAMP)
+)
+
+// NewAbstractType creates an abstract type declaration which references a proto
+// message name and may also include type parameters.
+func NewAbstractType(name string, paramTypes ...*exprpb.Type) *exprpb.Type {
+ return &exprpb.Type{
+ TypeKind: &exprpb.Type_AbstractType_{
+ AbstractType: &exprpb.Type_AbstractType{
+ Name: name,
+ ParameterTypes: paramTypes}}}
+}
+
+// NewOptionalType constructs an abstract type indicating that the parameterized type
+// may be contained within the object.
+func NewOptionalType(paramType *exprpb.Type) *exprpb.Type {
+ return NewAbstractType("optional_type", paramType)
+}
+
+// NewFunctionType creates a function invocation contract, typically only used
+// by type-checking steps after overload resolution.
+func NewFunctionType(resultType *exprpb.Type,
+ argTypes ...*exprpb.Type) *exprpb.Type {
+ return &exprpb.Type{
+ TypeKind: &exprpb.Type_Function{
+ Function: &exprpb.Type_FunctionType{
+ ResultType: resultType,
+ ArgTypes: argTypes}}}
+}
+
+// NewFunction creates a named function declaration with one or more overloads.
+func NewFunction(name string,
+ overloads ...*exprpb.Decl_FunctionDecl_Overload) *exprpb.Decl {
+ return &exprpb.Decl{
+ Name: name,
+ DeclKind: &exprpb.Decl_Function{
+ Function: &exprpb.Decl_FunctionDecl{
+ Overloads: overloads}}}
+}
+
+// NewIdent creates a named identifier declaration with an optional literal
+// value.
+//
+// Literal values are typically only associated with enum identifiers.
+//
+// Deprecated: Use NewVar or NewConst instead.
+func NewIdent(name string, t *exprpb.Type, v *exprpb.Constant) *exprpb.Decl {
+ return &exprpb.Decl{
+ Name: name,
+ DeclKind: &exprpb.Decl_Ident{
+ Ident: &exprpb.Decl_IdentDecl{
+ Type: t,
+ Value: v}}}
+}
+
+// NewConst creates a constant identifier with a CEL constant literal value.
+func NewConst(name string, t *exprpb.Type, v *exprpb.Constant) *exprpb.Decl {
+ return NewIdent(name, t, v)
+}
+
+// NewVar creates a variable identifier.
+func NewVar(name string, t *exprpb.Type) *exprpb.Decl {
+ return NewIdent(name, t, nil)
+}
+
+// NewInstanceOverload creates a instance function overload contract.
+// First element of argTypes is instance.
+func NewInstanceOverload(id string, argTypes []*exprpb.Type,
+ resultType *exprpb.Type) *exprpb.Decl_FunctionDecl_Overload {
+ return &exprpb.Decl_FunctionDecl_Overload{
+ OverloadId: id,
+ ResultType: resultType,
+ Params: argTypes,
+ IsInstanceFunction: true}
+}
+
+// NewListType generates a new list with elements of a certain type.
+func NewListType(elem *exprpb.Type) *exprpb.Type {
+ return &exprpb.Type{
+ TypeKind: &exprpb.Type_ListType_{
+ ListType: &exprpb.Type_ListType{
+ ElemType: elem}}}
+}
+
+// NewMapType generates a new map with typed keys and values.
+func NewMapType(key *exprpb.Type, value *exprpb.Type) *exprpb.Type {
+ return &exprpb.Type{
+ TypeKind: &exprpb.Type_MapType_{
+ MapType: &exprpb.Type_MapType{
+ KeyType: key,
+ ValueType: value}}}
+}
+
+// NewObjectType creates an object type for a qualified type name.
+func NewObjectType(typeName string) *exprpb.Type {
+ return &exprpb.Type{
+ TypeKind: &exprpb.Type_MessageType{
+ MessageType: typeName}}
+}
+
+// NewOverload creates a function overload declaration which contains a unique
+// overload id as well as the expected argument and result types. Overloads
+// must be aggregated within a Function declaration.
+func NewOverload(id string, argTypes []*exprpb.Type,
+ resultType *exprpb.Type) *exprpb.Decl_FunctionDecl_Overload {
+ return &exprpb.Decl_FunctionDecl_Overload{
+ OverloadId: id,
+ ResultType: resultType,
+ Params: argTypes,
+ IsInstanceFunction: false}
+}
+
+// NewParameterizedInstanceOverload creates a parametric function instance overload type.
+func NewParameterizedInstanceOverload(id string,
+ argTypes []*exprpb.Type,
+ resultType *exprpb.Type,
+ typeParams []string) *exprpb.Decl_FunctionDecl_Overload {
+ return &exprpb.Decl_FunctionDecl_Overload{
+ OverloadId: id,
+ ResultType: resultType,
+ Params: argTypes,
+ TypeParams: typeParams,
+ IsInstanceFunction: true}
+}
+
+// NewParameterizedOverload creates a parametric function overload type.
+func NewParameterizedOverload(id string,
+ argTypes []*exprpb.Type,
+ resultType *exprpb.Type,
+ typeParams []string) *exprpb.Decl_FunctionDecl_Overload {
+ return &exprpb.Decl_FunctionDecl_Overload{
+ OverloadId: id,
+ ResultType: resultType,
+ Params: argTypes,
+ TypeParams: typeParams,
+ IsInstanceFunction: false}
+}
+
+// NewPrimitiveType creates a type for a primitive value. See the var declarations
+// for Int, Uint, etc.
+func NewPrimitiveType(primitive exprpb.Type_PrimitiveType) *exprpb.Type {
+ return &exprpb.Type{
+ TypeKind: &exprpb.Type_Primitive{
+ Primitive: primitive}}
+}
+
+// NewTypeType creates a new type designating a type.
+func NewTypeType(nested *exprpb.Type) *exprpb.Type {
+ if nested == nil {
+ // must set the nested field for a valid oneof option
+ nested = &exprpb.Type{}
+ }
+ return &exprpb.Type{
+ TypeKind: &exprpb.Type_Type{
+ Type: nested}}
+}
+
+// NewTypeParamType creates a type corresponding to a named, contextual parameter.
+func NewTypeParamType(name string) *exprpb.Type {
+ return &exprpb.Type{
+ TypeKind: &exprpb.Type_TypeParam{
+ TypeParam: name}}
+}
+
+// NewWellKnownType creates a type corresponding to a protobuf well-known type
+// value.
+func NewWellKnownType(wellKnown exprpb.Type_WellKnownType) *exprpb.Type {
+ return &exprpb.Type{
+ TypeKind: &exprpb.Type_WellKnown{
+ WellKnown: wellKnown}}
+}
+
+// NewWrapperType creates a wrapped primitive type instance. Wrapped types
+// are roughly equivalent to a nullable, or optionally valued type.
+func NewWrapperType(wrapped *exprpb.Type) *exprpb.Type {
+ primitive := wrapped.GetPrimitive()
+ if primitive == exprpb.Type_PRIMITIVE_TYPE_UNSPECIFIED {
+ // TODO: return an error
+ panic("Wrapped type must be a primitive")
+ }
+ return &exprpb.Type{
+ TypeKind: &exprpb.Type_Wrapper{
+ Wrapper: primitive}}
+}
diff --git a/vendor/github.com/google/cel-go/checker/env.go b/vendor/github.com/google/cel-go/checker/env.go
new file mode 100644
index 000000000000..d5ac05014ee4
--- /dev/null
+++ b/vendor/github.com/google/cel-go/checker/env.go
@@ -0,0 +1,284 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package checker
+
+import (
+ "fmt"
+ "strings"
+
+ "github.com/google/cel-go/common/containers"
+ "github.com/google/cel-go/common/decls"
+ "github.com/google/cel-go/common/overloads"
+ "github.com/google/cel-go/common/types"
+ "github.com/google/cel-go/parser"
+)
+
+type aggregateLiteralElementType int
+
+const (
+ dynElementType aggregateLiteralElementType = iota
+ homogenousElementType aggregateLiteralElementType = 1 << iota
+)
+
+var (
+ crossTypeNumericComparisonOverloads = map[string]struct{}{
+ // double <-> int | uint
+ overloads.LessDoubleInt64: {},
+ overloads.LessDoubleUint64: {},
+ overloads.LessEqualsDoubleInt64: {},
+ overloads.LessEqualsDoubleUint64: {},
+ overloads.GreaterDoubleInt64: {},
+ overloads.GreaterDoubleUint64: {},
+ overloads.GreaterEqualsDoubleInt64: {},
+ overloads.GreaterEqualsDoubleUint64: {},
+ // int <-> double | uint
+ overloads.LessInt64Double: {},
+ overloads.LessInt64Uint64: {},
+ overloads.LessEqualsInt64Double: {},
+ overloads.LessEqualsInt64Uint64: {},
+ overloads.GreaterInt64Double: {},
+ overloads.GreaterInt64Uint64: {},
+ overloads.GreaterEqualsInt64Double: {},
+ overloads.GreaterEqualsInt64Uint64: {},
+ // uint <-> double | int
+ overloads.LessUint64Double: {},
+ overloads.LessUint64Int64: {},
+ overloads.LessEqualsUint64Double: {},
+ overloads.LessEqualsUint64Int64: {},
+ overloads.GreaterUint64Double: {},
+ overloads.GreaterUint64Int64: {},
+ overloads.GreaterEqualsUint64Double: {},
+ overloads.GreaterEqualsUint64Int64: {},
+ }
+)
+
+// Env is the environment for type checking.
+//
+// The Env is comprised of a container, type provider, declarations, and other related objects
+// which can be used to assist with type-checking.
+type Env struct {
+ container *containers.Container
+ provider types.Provider
+ declarations *Scopes
+ aggLitElemType aggregateLiteralElementType
+ filteredOverloadIDs map[string]struct{}
+}
+
+// NewEnv returns a new *Env with the given parameters.
+func NewEnv(container *containers.Container, provider types.Provider, opts ...Option) (*Env, error) {
+ declarations := newScopes()
+ declarations.Push()
+
+ envOptions := &options{}
+ for _, opt := range opts {
+ if err := opt(envOptions); err != nil {
+ return nil, err
+ }
+ }
+ aggLitElemType := dynElementType
+ if envOptions.homogeneousAggregateLiterals {
+ aggLitElemType = homogenousElementType
+ }
+ filteredOverloadIDs := crossTypeNumericComparisonOverloads
+ if envOptions.crossTypeNumericComparisons {
+ filteredOverloadIDs = make(map[string]struct{})
+ }
+ if envOptions.validatedDeclarations != nil {
+ declarations = envOptions.validatedDeclarations.Copy()
+ }
+ return &Env{
+ container: container,
+ provider: provider,
+ declarations: declarations,
+ aggLitElemType: aggLitElemType,
+ filteredOverloadIDs: filteredOverloadIDs,
+ }, nil
+}
+
+// AddIdents configures the checker with a list of variable declarations.
+//
+// If there are overlapping declarations, the method will error.
+func (e *Env) AddIdents(declarations ...*decls.VariableDecl) error {
+ errMsgs := make([]errorMsg, 0)
+ for _, d := range declarations {
+ errMsgs = append(errMsgs, e.addIdent(d))
+ }
+ return formatError(errMsgs)
+}
+
+// AddFunctions configures the checker with a list of function declarations.
+//
+// If there are overlapping declarations, the method will error.
+func (e *Env) AddFunctions(declarations ...*decls.FunctionDecl) error {
+ errMsgs := make([]errorMsg, 0)
+ for _, d := range declarations {
+ errMsgs = append(errMsgs, e.setFunction(d)...)
+ }
+ return formatError(errMsgs)
+}
+
+// LookupIdent returns a Decl proto for typeName as an identifier in the Env.
+// Returns nil if no such identifier is found in the Env.
+func (e *Env) LookupIdent(name string) *decls.VariableDecl {
+ for _, candidate := range e.container.ResolveCandidateNames(name) {
+ if ident := e.declarations.FindIdent(candidate); ident != nil {
+ return ident
+ }
+
+ // Next try to import the name as a reference to a message type. If found,
+ // the declaration is added to the outest (global) scope of the
+ // environment, so next time we can access it faster.
+ if t, found := e.provider.FindStructType(candidate); found {
+ decl := decls.NewVariable(candidate, t)
+ e.declarations.AddIdent(decl)
+ return decl
+ }
+
+ if i, found := e.provider.FindIdent(candidate); found {
+ if t, ok := i.(*types.Type); ok {
+ decl := decls.NewVariable(candidate, types.NewTypeTypeWithParam(t))
+ e.declarations.AddIdent(decl)
+ return decl
+ }
+ }
+
+ // Next try to import this as an enum value by splitting the name in a type prefix and
+ // the enum inside.
+ if enumValue := e.provider.EnumValue(candidate); enumValue.Type() != types.ErrType {
+ decl := decls.NewConstant(candidate, types.IntType, enumValue)
+ e.declarations.AddIdent(decl)
+ return decl
+ }
+ }
+ return nil
+}
+
+// LookupFunction returns a Decl proto for typeName as a function in env.
+// Returns nil if no such function is found in env.
+func (e *Env) LookupFunction(name string) *decls.FunctionDecl {
+ for _, candidate := range e.container.ResolveCandidateNames(name) {
+ if fn := e.declarations.FindFunction(candidate); fn != nil {
+ return fn
+ }
+ }
+ return nil
+}
+
+// setFunction adds the function Decl to the Env.
+// Adds a function decl if one doesn't already exist, then adds all overloads from the Decl.
+// If overload overlaps with an existing overload, adds to the errors in the Env instead.
+func (e *Env) setFunction(fn *decls.FunctionDecl) []errorMsg {
+ errMsgs := make([]errorMsg, 0)
+ current := e.declarations.FindFunction(fn.Name())
+ if current != nil {
+ var err error
+ current, err = current.Merge(fn)
+ if err != nil {
+ return append(errMsgs, errorMsg(err.Error()))
+ }
+ } else {
+ current = fn
+ }
+ for _, overload := range current.OverloadDecls() {
+ for _, macro := range parser.AllMacros {
+ if macro.Function() == current.Name() &&
+ macro.IsReceiverStyle() == overload.IsMemberFunction() &&
+ macro.ArgCount() == len(overload.ArgTypes()) {
+ errMsgs = append(errMsgs, overlappingMacroError(current.Name(), macro.ArgCount()))
+ }
+ }
+ if len(errMsgs) > 0 {
+ return errMsgs
+ }
+ }
+ e.declarations.SetFunction(current)
+ return errMsgs
+}
+
+// addIdent adds the Decl to the declarations in the Env.
+// Returns a non-empty errorMsg if the identifier is already declared in the scope.
+func (e *Env) addIdent(decl *decls.VariableDecl) errorMsg {
+ current := e.declarations.FindIdentInScope(decl.Name())
+ if current != nil {
+ if current.DeclarationIsEquivalent(decl) {
+ return ""
+ }
+ return overlappingIdentifierError(decl.Name())
+ }
+ e.declarations.AddIdent(decl)
+ return ""
+}
+
+// isOverloadDisabled returns whether the overloadID is disabled in the current environment.
+func (e *Env) isOverloadDisabled(overloadID string) bool {
+ _, found := e.filteredOverloadIDs[overloadID]
+ return found
+}
+
+// validatedDeclarations returns a reference to the validated variable and function declaration scope stack.
+// must be copied before use.
+func (e *Env) validatedDeclarations() *Scopes {
+ return e.declarations
+}
+
+// enterScope creates a new Env instance with a new innermost declaration scope.
+func (e *Env) enterScope() *Env {
+ childDecls := e.declarations.Push()
+ return &Env{
+ declarations: childDecls,
+ container: e.container,
+ provider: e.provider,
+ aggLitElemType: e.aggLitElemType,
+ }
+}
+
+// exitScope creates a new Env instance with the nearest outer declaration scope.
+func (e *Env) exitScope() *Env {
+ parentDecls := e.declarations.Pop()
+ return &Env{
+ declarations: parentDecls,
+ container: e.container,
+ provider: e.provider,
+ aggLitElemType: e.aggLitElemType,
+ }
+}
+
+// errorMsg is a type alias meant to represent error-based return values which
+// may be accumulated into an error at a later point in execution.
+type errorMsg string
+
+func overlappingIdentifierError(name string) errorMsg {
+ return errorMsg(fmt.Sprintf("overlapping identifier for name '%s'", name))
+}
+
+func overlappingMacroError(name string, argCount int) errorMsg {
+ return errorMsg(fmt.Sprintf(
+ "overlapping macro for name '%s' with %d args", name, argCount))
+}
+
+func formatError(errMsgs []errorMsg) error {
+ errStrs := make([]string, 0)
+ if len(errMsgs) > 0 {
+ for i := 0; i < len(errMsgs); i++ {
+ if errMsgs[i] != "" {
+ errStrs = append(errStrs, string(errMsgs[i]))
+ }
+ }
+ }
+ if len(errStrs) > 0 {
+ return fmt.Errorf("%s", strings.Join(errStrs, "\n"))
+ }
+ return nil
+}
diff --git a/vendor/github.com/google/cel-go/checker/errors.go b/vendor/github.com/google/cel-go/checker/errors.go
new file mode 100644
index 000000000000..8b3bf0b8b642
--- /dev/null
+++ b/vendor/github.com/google/cel-go/checker/errors.go
@@ -0,0 +1,88 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package checker
+
+import (
+ "github.com/google/cel-go/common"
+ "github.com/google/cel-go/common/ast"
+ "github.com/google/cel-go/common/types"
+)
+
+// typeErrors is a specialization of Errors.
+type typeErrors struct {
+ errs *common.Errors
+}
+
+func (e *typeErrors) fieldTypeMismatch(id int64, l common.Location, name string, field, value *types.Type) {
+ e.errs.ReportErrorAtID(id, l, "expected type of field '%s' is '%s' but provided type is '%s'",
+ name, FormatCELType(field), FormatCELType(value))
+}
+
+func (e *typeErrors) incompatibleType(id int64, l common.Location, ex ast.Expr, prev, next *types.Type) {
+ e.errs.ReportErrorAtID(id, l,
+ "incompatible type already exists for expression: %v(%d) old:%v, new:%v", ex, ex.ID(), prev, next)
+}
+
+func (e *typeErrors) noMatchingOverload(id int64, l common.Location, name string, args []*types.Type, isInstance bool) {
+ signature := formatFunctionDeclType(nil, args, isInstance)
+ e.errs.ReportErrorAtID(id, l, "found no matching overload for '%s' applied to '%s'", name, signature)
+}
+
+func (e *typeErrors) notAComprehensionRange(id int64, l common.Location, t *types.Type) {
+ e.errs.ReportErrorAtID(id, l, "expression of type '%s' cannot be range of a comprehension (must be list, map, or dynamic)",
+ FormatCELType(t))
+}
+
+func (e *typeErrors) notAnOptionalFieldSelection(id int64, l common.Location, field ast.Expr) {
+ e.errs.ReportErrorAtID(id, l, "unsupported optional field selection: %v", field)
+}
+
+func (e *typeErrors) notAType(id int64, l common.Location, typeName string) {
+ e.errs.ReportErrorAtID(id, l, "'%s' is not a type", typeName)
+}
+
+func (e *typeErrors) notAMessageType(id int64, l common.Location, typeName string) {
+ e.errs.ReportErrorAtID(id, l, "'%s' is not a message type", typeName)
+}
+
+func (e *typeErrors) referenceRedefinition(id int64, l common.Location, ex ast.Expr, prev, next *ast.ReferenceInfo) {
+ e.errs.ReportErrorAtID(id, l,
+ "reference already exists for expression: %v(%d) old:%v, new:%v", ex, ex.ID(), prev, next)
+}
+
+func (e *typeErrors) typeDoesNotSupportFieldSelection(id int64, l common.Location, t *types.Type) {
+ e.errs.ReportErrorAtID(id, l, "type '%s' does not support field selection", FormatCELType(t))
+}
+
+func (e *typeErrors) typeMismatch(id int64, l common.Location, expected, actual *types.Type) {
+ e.errs.ReportErrorAtID(id, l, "expected type '%s' but found '%s'",
+ FormatCELType(expected), FormatCELType(actual))
+}
+
+func (e *typeErrors) undefinedField(id int64, l common.Location, field string) {
+ e.errs.ReportErrorAtID(id, l, "undefined field '%s'", field)
+}
+
+func (e *typeErrors) undeclaredReference(id int64, l common.Location, container string, name string) {
+ e.errs.ReportErrorAtID(id, l, "undeclared reference to '%s' (in container '%s')", name, container)
+}
+
+func (e *typeErrors) unexpectedFailedResolution(id int64, l common.Location, typeName string) {
+ e.errs.ReportErrorAtID(id, l, "unexpected failed resolution of '%s'", typeName)
+}
+
+func (e *typeErrors) unexpectedASTType(id int64, l common.Location, kind, typeName string) {
+ e.errs.ReportErrorAtID(id, l, "unexpected %s type: %v", kind, typeName)
+}
diff --git a/vendor/github.com/google/cel-go/checker/format.go b/vendor/github.com/google/cel-go/checker/format.go
new file mode 100644
index 000000000000..95842905e6d5
--- /dev/null
+++ b/vendor/github.com/google/cel-go/checker/format.go
@@ -0,0 +1,216 @@
+// Copyright 2023 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package checker
+
+import (
+ "fmt"
+ "strings"
+
+ chkdecls "github.com/google/cel-go/checker/decls"
+ "github.com/google/cel-go/common/types"
+
+ exprpb "google.golang.org/genproto/googleapis/api/expr/v1alpha1"
+)
+
+const (
+ kindUnknown = iota + 1
+ kindError
+ kindFunction
+ kindDyn
+ kindPrimitive
+ kindWellKnown
+ kindWrapper
+ kindNull
+ kindAbstract
+ kindType
+ kindList
+ kindMap
+ kindObject
+ kindTypeParam
+)
+
+// FormatCheckedType converts a type message into a string representation.
+func FormatCheckedType(t *exprpb.Type) string {
+ switch kindOf(t) {
+ case kindDyn:
+ return "dyn"
+ case kindFunction:
+ return formatFunctionExprType(t.GetFunction().GetResultType(),
+ t.GetFunction().GetArgTypes(),
+ false)
+ case kindList:
+ return fmt.Sprintf("list(%s)", FormatCheckedType(t.GetListType().GetElemType()))
+ case kindObject:
+ return t.GetMessageType()
+ case kindMap:
+ return fmt.Sprintf("map(%s, %s)",
+ FormatCheckedType(t.GetMapType().GetKeyType()),
+ FormatCheckedType(t.GetMapType().GetValueType()))
+ case kindNull:
+ return "null"
+ case kindPrimitive:
+ switch t.GetPrimitive() {
+ case exprpb.Type_UINT64:
+ return "uint"
+ case exprpb.Type_INT64:
+ return "int"
+ }
+ return strings.Trim(strings.ToLower(t.GetPrimitive().String()), " ")
+ case kindType:
+ if t.GetType() == nil || t.GetType().GetTypeKind() == nil {
+ return "type"
+ }
+ return fmt.Sprintf("type(%s)", FormatCheckedType(t.GetType()))
+ case kindWellKnown:
+ switch t.GetWellKnown() {
+ case exprpb.Type_ANY:
+ return "any"
+ case exprpb.Type_DURATION:
+ return "duration"
+ case exprpb.Type_TIMESTAMP:
+ return "timestamp"
+ }
+ case kindWrapper:
+ return fmt.Sprintf("wrapper(%s)",
+ FormatCheckedType(chkdecls.NewPrimitiveType(t.GetWrapper())))
+ case kindError:
+ return "!error!"
+ case kindTypeParam:
+ return t.GetTypeParam()
+ case kindAbstract:
+ at := t.GetAbstractType()
+ params := at.GetParameterTypes()
+ paramStrs := make([]string, len(params))
+ for i, p := range params {
+ paramStrs[i] = FormatCheckedType(p)
+ }
+ return fmt.Sprintf("%s(%s)", at.GetName(), strings.Join(paramStrs, ", "))
+ }
+ return t.String()
+}
+
+type formatter func(any) string
+
+// FormatCELType formats a types.Type value to a string representation.
+//
+// The type formatting is identical to FormatCheckedType.
+func FormatCELType(t any) string {
+ dt := t.(*types.Type)
+ switch dt.Kind() {
+ case types.AnyKind:
+ return "any"
+ case types.DurationKind:
+ return "duration"
+ case types.ErrorKind:
+ return "!error!"
+ case types.NullTypeKind:
+ return "null"
+ case types.TimestampKind:
+ return "timestamp"
+ case types.TypeParamKind:
+ return dt.TypeName()
+ case types.OpaqueKind:
+ if dt.TypeName() == "function" {
+ // There is no explicit function type in the new types representation, so information like
+ // whether the function is a member function is absent.
+ return formatFunctionDeclType(dt.Parameters()[0], dt.Parameters()[1:], false)
+ }
+ case types.UnspecifiedKind:
+ return ""
+ }
+ if len(dt.Parameters()) == 0 {
+ return dt.DeclaredTypeName()
+ }
+ paramTypeNames := make([]string, 0, len(dt.Parameters()))
+ for _, p := range dt.Parameters() {
+ paramTypeNames = append(paramTypeNames, FormatCELType(p))
+ }
+ return fmt.Sprintf("%s(%s)", dt.TypeName(), strings.Join(paramTypeNames, ", "))
+}
+
+func formatExprType(t any) string {
+ if t == nil {
+ return ""
+ }
+ return FormatCheckedType(t.(*exprpb.Type))
+}
+
+func formatFunctionExprType(resultType *exprpb.Type, argTypes []*exprpb.Type, isInstance bool) string {
+ return formatFunctionInternal[*exprpb.Type](resultType, argTypes, isInstance, formatExprType)
+}
+
+func formatFunctionDeclType(resultType *types.Type, argTypes []*types.Type, isInstance bool) string {
+ return formatFunctionInternal[*types.Type](resultType, argTypes, isInstance, FormatCELType)
+}
+
+func formatFunctionInternal[T any](resultType T, argTypes []T, isInstance bool, format formatter) string {
+ result := ""
+ if isInstance {
+ target := argTypes[0]
+ argTypes = argTypes[1:]
+ result += format(target)
+ result += "."
+ }
+ result += "("
+ for i, arg := range argTypes {
+ if i > 0 {
+ result += ", "
+ }
+ result += format(arg)
+ }
+ result += ")"
+ rt := format(resultType)
+ if rt != "" {
+ result += " -> "
+ result += rt
+ }
+ return result
+}
+
+// kindOf returns the kind of the type as defined in the checked.proto.
+func kindOf(t *exprpb.Type) int {
+ if t == nil || t.TypeKind == nil {
+ return kindUnknown
+ }
+ switch t.GetTypeKind().(type) {
+ case *exprpb.Type_Error:
+ return kindError
+ case *exprpb.Type_Function:
+ return kindFunction
+ case *exprpb.Type_Dyn:
+ return kindDyn
+ case *exprpb.Type_Primitive:
+ return kindPrimitive
+ case *exprpb.Type_WellKnown:
+ return kindWellKnown
+ case *exprpb.Type_Wrapper:
+ return kindWrapper
+ case *exprpb.Type_Null:
+ return kindNull
+ case *exprpb.Type_Type:
+ return kindType
+ case *exprpb.Type_ListType_:
+ return kindList
+ case *exprpb.Type_MapType_:
+ return kindMap
+ case *exprpb.Type_MessageType:
+ return kindObject
+ case *exprpb.Type_TypeParam:
+ return kindTypeParam
+ case *exprpb.Type_AbstractType_:
+ return kindAbstract
+ }
+ return kindUnknown
+}
diff --git a/vendor/github.com/google/cel-go/checker/mapping.go b/vendor/github.com/google/cel-go/checker/mapping.go
new file mode 100644
index 000000000000..8163a908a5f2
--- /dev/null
+++ b/vendor/github.com/google/cel-go/checker/mapping.go
@@ -0,0 +1,49 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package checker
+
+import (
+ "github.com/google/cel-go/common/types"
+)
+
+type mapping struct {
+ mapping map[string]*types.Type
+}
+
+func newMapping() *mapping {
+ return &mapping{
+ mapping: make(map[string]*types.Type),
+ }
+}
+
+func (m *mapping) add(from, to *types.Type) {
+ m.mapping[FormatCELType(from)] = to
+}
+
+func (m *mapping) find(from *types.Type) (*types.Type, bool) {
+ if r, found := m.mapping[FormatCELType(from)]; found {
+ return r, found
+ }
+ return nil, false
+}
+
+func (m *mapping) copy() *mapping {
+ c := newMapping()
+
+ for k, v := range m.mapping {
+ c.mapping[k] = v
+ }
+ return c
+}
diff --git a/vendor/github.com/google/cel-go/checker/options.go b/vendor/github.com/google/cel-go/checker/options.go
new file mode 100644
index 000000000000..0560c3813cf1
--- /dev/null
+++ b/vendor/github.com/google/cel-go/checker/options.go
@@ -0,0 +1,42 @@
+// Copyright 2022 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package checker
+
+type options struct {
+ crossTypeNumericComparisons bool
+ homogeneousAggregateLiterals bool
+ validatedDeclarations *Scopes
+}
+
+// Option is a functional option for configuring the type-checker
+type Option func(*options) error
+
+// CrossTypeNumericComparisons toggles type-checker support for numeric comparisons across type
+// See https://github.com/google/cel-spec/wiki/proposal-210 for more details.
+func CrossTypeNumericComparisons(enabled bool) Option {
+ return func(opts *options) error {
+ opts.crossTypeNumericComparisons = enabled
+ return nil
+ }
+}
+
+// ValidatedDeclarations provides a references to validated declarations which will be copied
+// into new checker instances.
+func ValidatedDeclarations(env *Env) Option {
+ return func(opts *options) error {
+ opts.validatedDeclarations = env.validatedDeclarations()
+ return nil
+ }
+}
diff --git a/vendor/github.com/google/cel-go/checker/printer.go b/vendor/github.com/google/cel-go/checker/printer.go
new file mode 100644
index 000000000000..7a3984f02ce5
--- /dev/null
+++ b/vendor/github.com/google/cel-go/checker/printer.go
@@ -0,0 +1,74 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package checker
+
+import (
+ "sort"
+
+ "github.com/google/cel-go/common/ast"
+ "github.com/google/cel-go/common/debug"
+)
+
+type semanticAdorner struct {
+ checked *ast.AST
+}
+
+var _ debug.Adorner = &semanticAdorner{}
+
+func (a *semanticAdorner) GetMetadata(elem any) string {
+ result := ""
+ e, isExpr := elem.(ast.Expr)
+ if !isExpr {
+ return result
+ }
+ t := a.checked.TypeMap()[e.ID()]
+ if t != nil {
+ result += "~"
+ result += FormatCELType(t)
+ }
+
+ switch e.Kind() {
+ case ast.IdentKind,
+ ast.CallKind,
+ ast.ListKind,
+ ast.StructKind,
+ ast.SelectKind:
+ if ref, found := a.checked.ReferenceMap()[e.ID()]; found {
+ if len(ref.OverloadIDs) == 0 {
+ result += "^" + ref.Name
+ } else {
+ sort.Strings(ref.OverloadIDs)
+ for i, overload := range ref.OverloadIDs {
+ if i == 0 {
+ result += "^"
+ } else {
+ result += "|"
+ }
+ result += overload
+ }
+ }
+ }
+ }
+
+ return result
+}
+
+// Print returns a string representation of the Expr message,
+// annotated with types from the CheckedExpr. The Expr must
+// be a sub-expression embedded in the CheckedExpr.
+func Print(e ast.Expr, checked *ast.AST) string {
+ a := &semanticAdorner{checked: checked}
+ return debug.ToAdornedDebugString(e, a)
+}
diff --git a/vendor/github.com/google/cel-go/checker/scopes.go b/vendor/github.com/google/cel-go/checker/scopes.go
new file mode 100644
index 000000000000..8bb73ddb6a29
--- /dev/null
+++ b/vendor/github.com/google/cel-go/checker/scopes.go
@@ -0,0 +1,147 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package checker
+
+import (
+ "github.com/google/cel-go/common/decls"
+)
+
+// Scopes represents nested Decl sets where the Scopes value contains a Groups containing all
+// identifiers in scope and an optional parent representing outer scopes.
+// Each Groups value is a mapping of names to Decls in the ident and function namespaces.
+// Lookups are performed such that bindings in inner scopes shadow those in outer scopes.
+type Scopes struct {
+ parent *Scopes
+ scopes *Group
+}
+
+// newScopes creates a new, empty Scopes.
+// Some operations can't be safely performed until a Group is added with Push.
+func newScopes() *Scopes {
+ return &Scopes{
+ scopes: newGroup(),
+ }
+}
+
+// Copy creates a copy of the current Scopes values, including a copy of its parent if non-nil.
+func (s *Scopes) Copy() *Scopes {
+ cpy := newScopes()
+ if s == nil {
+ return cpy
+ }
+ if s.parent != nil {
+ cpy.parent = s.parent.Copy()
+ }
+ cpy.scopes = s.scopes.copy()
+ return cpy
+}
+
+// Push creates a new Scopes value which references the current Scope as its parent.
+func (s *Scopes) Push() *Scopes {
+ return &Scopes{
+ parent: s,
+ scopes: newGroup(),
+ }
+}
+
+// Pop returns the parent Scopes value for the current scope, or the current scope if the parent
+// is nil.
+func (s *Scopes) Pop() *Scopes {
+ if s.parent != nil {
+ return s.parent
+ }
+ // TODO: Consider whether this should be an error / panic.
+ return s
+}
+
+// AddIdent adds the ident Decl in the current scope.
+// Note: If the name collides with an existing identifier in the scope, the Decl is overwritten.
+func (s *Scopes) AddIdent(decl *decls.VariableDecl) {
+ s.scopes.idents[decl.Name()] = decl
+}
+
+// FindIdent finds the first ident Decl with a matching name in Scopes, or nil if one cannot be
+// found.
+// Note: The search is performed from innermost to outermost.
+func (s *Scopes) FindIdent(name string) *decls.VariableDecl {
+ if ident, found := s.scopes.idents[name]; found {
+ return ident
+ }
+ if s.parent != nil {
+ return s.parent.FindIdent(name)
+ }
+ return nil
+}
+
+// FindIdentInScope finds the first ident Decl with a matching name in the current Scopes value, or
+// nil if one does not exist.
+// Note: The search is only performed on the current scope and does not search outer scopes.
+func (s *Scopes) FindIdentInScope(name string) *decls.VariableDecl {
+ if ident, found := s.scopes.idents[name]; found {
+ return ident
+ }
+ return nil
+}
+
+// SetFunction adds the function Decl to the current scope.
+// Note: Any previous entry for a function in the current scope with the same name is overwritten.
+func (s *Scopes) SetFunction(fn *decls.FunctionDecl) {
+ s.scopes.functions[fn.Name()] = fn
+}
+
+// FindFunction finds the first function Decl with a matching name in Scopes.
+// The search is performed from innermost to outermost.
+// Returns nil if no such function in Scopes.
+func (s *Scopes) FindFunction(name string) *decls.FunctionDecl {
+ if fn, found := s.scopes.functions[name]; found {
+ return fn
+ }
+ if s.parent != nil {
+ return s.parent.FindFunction(name)
+ }
+ return nil
+}
+
+// Group is a set of Decls that is pushed on or popped off a Scopes as a unit.
+// Contains separate namespaces for identifier and function Decls.
+// (Should be named "Scope" perhaps?)
+type Group struct {
+ idents map[string]*decls.VariableDecl
+ functions map[string]*decls.FunctionDecl
+}
+
+// copy creates a new Group instance with a shallow copy of the variables and functions.
+// If callers need to mutate the exprpb.Decl definitions for a Function, they should copy-on-write.
+func (g *Group) copy() *Group {
+ cpy := &Group{
+ idents: make(map[string]*decls.VariableDecl, len(g.idents)),
+ functions: make(map[string]*decls.FunctionDecl, len(g.functions)),
+ }
+ for n, id := range g.idents {
+ cpy.idents[n] = id
+ }
+ for n, fn := range g.functions {
+ cpy.functions[n] = fn
+ }
+ return cpy
+}
+
+// newGroup creates a new Group with empty maps for identifiers and functions.
+func newGroup() *Group {
+ return &Group{
+ idents: make(map[string]*decls.VariableDecl),
+ functions: make(map[string]*decls.FunctionDecl),
+ }
+}
diff --git a/vendor/github.com/google/cel-go/checker/types.go b/vendor/github.com/google/cel-go/checker/types.go
new file mode 100644
index 000000000000..4c65b2737cda
--- /dev/null
+++ b/vendor/github.com/google/cel-go/checker/types.go
@@ -0,0 +1,314 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package checker
+
+import (
+ "github.com/google/cel-go/common/types"
+)
+
+// isDyn returns true if the input t is either type DYN or a well-known ANY message.
+func isDyn(t *types.Type) bool {
+ // Note: object type values that are well-known and map to a DYN value in practice
+ // are sanitized prior to being added to the environment.
+ switch t.Kind() {
+ case types.DynKind, types.AnyKind:
+ return true
+ default:
+ return false
+ }
+}
+
+// isDynOrError returns true if the input is either an Error, DYN, or well-known ANY message.
+func isDynOrError(t *types.Type) bool {
+ return isError(t) || isDyn(t)
+}
+
+func isError(t *types.Type) bool {
+ return t.Kind() == types.ErrorKind
+}
+
+func isOptional(t *types.Type) bool {
+ if t.Kind() == types.OpaqueKind {
+ return t.TypeName() == "optional_type"
+ }
+ return false
+}
+
+func maybeUnwrapOptional(t *types.Type) (*types.Type, bool) {
+ if isOptional(t) {
+ return t.Parameters()[0], true
+ }
+ return t, false
+}
+
+// isEqualOrLessSpecific checks whether one type is equal or less specific than the other one.
+// A type is less specific if it matches the other type using the DYN type.
+func isEqualOrLessSpecific(t1, t2 *types.Type) bool {
+ kind1, kind2 := t1.Kind(), t2.Kind()
+ // The first type is less specific.
+ if isDyn(t1) || kind1 == types.TypeParamKind {
+ return true
+ }
+ // The first type is not less specific.
+ if isDyn(t2) || kind2 == types.TypeParamKind {
+ return false
+ }
+ // Types must be of the same kind to be equal.
+ if kind1 != kind2 {
+ return false
+ }
+
+ // With limited exceptions for ANY and JSON values, the types must agree and be equivalent in
+ // order to return true.
+ switch kind1 {
+ case types.OpaqueKind:
+ if t1.TypeName() != t2.TypeName() ||
+ len(t1.Parameters()) != len(t2.Parameters()) {
+ return false
+ }
+ for i, p1 := range t1.Parameters() {
+ if !isEqualOrLessSpecific(p1, t2.Parameters()[i]) {
+ return false
+ }
+ }
+ return true
+ case types.ListKind:
+ return isEqualOrLessSpecific(t1.Parameters()[0], t2.Parameters()[0])
+ case types.MapKind:
+ return isEqualOrLessSpecific(t1.Parameters()[0], t2.Parameters()[0]) &&
+ isEqualOrLessSpecific(t1.Parameters()[1], t2.Parameters()[1])
+ case types.TypeKind:
+ return true
+ default:
+ return t1.IsExactType(t2)
+ }
+}
+
+// / internalIsAssignable returns true if t1 is assignable to t2.
+func internalIsAssignable(m *mapping, t1, t2 *types.Type) bool {
+ // Process type parameters.
+ kind1, kind2 := t1.Kind(), t2.Kind()
+ if kind2 == types.TypeParamKind {
+ // If t2 is a valid type substitution for t1, return true.
+ valid, t2HasSub := isValidTypeSubstitution(m, t1, t2)
+ if valid {
+ return true
+ }
+ // If t2 is not a valid type sub for t1, and already has a known substitution return false
+ // since it is not possible for t1 to be a substitution for t2.
+ if !valid && t2HasSub {
+ return false
+ }
+ // Otherwise, fall through to check whether t1 is a possible substitution for t2.
+ }
+ if kind1 == types.TypeParamKind {
+ // Return whether t1 is a valid substitution for t2. If not, do no additional checks as the
+ // possible type substitutions have been searched in both directions.
+ valid, _ := isValidTypeSubstitution(m, t2, t1)
+ return valid
+ }
+
+ // Next check for wildcard types.
+ if isDynOrError(t1) || isDynOrError(t2) {
+ return true
+ }
+ // Preserve the nullness checks of the legacy type-checker.
+ if kind1 == types.NullTypeKind {
+ return internalIsAssignableNull(t2)
+ }
+ if kind2 == types.NullTypeKind {
+ return internalIsAssignableNull(t1)
+ }
+
+ // Test for when the types do not need to agree, but are more specific than dyn.
+ switch kind1 {
+ case types.BoolKind, types.BytesKind, types.DoubleKind, types.IntKind, types.StringKind, types.UintKind,
+ types.AnyKind, types.DurationKind, types.TimestampKind,
+ types.StructKind:
+ // Test whether t2 is assignable from t1. The order of this check won't usually matter;
+ // however, there may be cases where type capabilities are expanded beyond what is supported
+ // in the current common/types package. For example, an interface designation for a group of
+ // Struct types.
+ return t2.IsAssignableType(t1)
+ case types.TypeKind:
+ return kind2 == types.TypeKind
+ case types.OpaqueKind, types.ListKind, types.MapKind:
+ return t1.Kind() == t2.Kind() && t1.TypeName() == t2.TypeName() &&
+ internalIsAssignableList(m, t1.Parameters(), t2.Parameters())
+ default:
+ return false
+ }
+}
+
+// isValidTypeSubstitution returns whether t2 (or its type substitution) is a valid type
+// substitution for t1, and whether t2 has a type substitution in mapping m.
+//
+// The type t2 is a valid substitution for t1 if any of the following statements is true
+// - t2 has a type substitution (t2sub) equal to t1
+// - t2 has a type substitution (t2sub) assignable to t1
+// - t2 does not occur within t1.
+func isValidTypeSubstitution(m *mapping, t1, t2 *types.Type) (valid, hasSub bool) {
+ // Early return if the t1 and t2 are the same instance.
+ kind1, kind2 := t1.Kind(), t2.Kind()
+ if kind1 == kind2 && t1.IsExactType(t2) {
+ return true, true
+ }
+ if t2Sub, found := m.find(t2); found {
+ // Early return if t1 and t2Sub are the same instance as otherwise the mapping
+ // might mark a type as being a subtitution for itself.
+ if kind1 == t2Sub.Kind() && t1.IsExactType(t2Sub) {
+ return true, true
+ }
+ // If the types are compatible, pick the more general type and return true
+ if internalIsAssignable(m, t1, t2Sub) {
+ t2New := mostGeneral(t1, t2Sub)
+ // only update the type reference map if the target type does not occur within it.
+ if notReferencedIn(m, t2, t2New) {
+ m.add(t2, t2New)
+ }
+ // acknowledge the type agreement, and that the substitution is already tracked.
+ return true, true
+ }
+ return false, true
+ }
+ if notReferencedIn(m, t2, t1) {
+ m.add(t2, t1)
+ return true, false
+ }
+ return false, false
+}
+
+// internalIsAssignableList returns true if the element types at each index in the list are
+// assignable from l1[i] to l2[i]. The list lengths must also agree for the lists to be
+// assignable.
+func internalIsAssignableList(m *mapping, l1, l2 []*types.Type) bool {
+ if len(l1) != len(l2) {
+ return false
+ }
+ for i, t1 := range l1 {
+ if !internalIsAssignable(m, t1, l2[i]) {
+ return false
+ }
+ }
+ return true
+}
+
+// internalIsAssignableNull returns true if the type is nullable.
+func internalIsAssignableNull(t *types.Type) bool {
+ return isLegacyNullable(t) || t.IsAssignableType(types.NullType)
+}
+
+// isLegacyNullable preserves the null-ness compatibility of the original type-checker implementation.
+func isLegacyNullable(t *types.Type) bool {
+ switch t.Kind() {
+ case types.OpaqueKind, types.StructKind, types.AnyKind, types.DurationKind, types.TimestampKind:
+ return true
+ }
+ return false
+}
+
+// isAssignable returns an updated type substitution mapping if t1 is assignable to t2.
+func isAssignable(m *mapping, t1, t2 *types.Type) *mapping {
+ mCopy := m.copy()
+ if internalIsAssignable(mCopy, t1, t2) {
+ return mCopy
+ }
+ return nil
+}
+
+// isAssignableList returns an updated type substitution mapping if l1 is assignable to l2.
+func isAssignableList(m *mapping, l1, l2 []*types.Type) *mapping {
+ mCopy := m.copy()
+ if internalIsAssignableList(mCopy, l1, l2) {
+ return mCopy
+ }
+ return nil
+}
+
+// mostGeneral returns the more general of two types which are known to unify.
+func mostGeneral(t1, t2 *types.Type) *types.Type {
+ if isEqualOrLessSpecific(t1, t2) {
+ return t1
+ }
+ return t2
+}
+
+// notReferencedIn checks whether the type doesn't appear directly or transitively within the other
+// type. This is a standard requirement for type unification, commonly referred to as the "occurs
+// check".
+func notReferencedIn(m *mapping, t, withinType *types.Type) bool {
+ if t.IsExactType(withinType) {
+ return false
+ }
+ withinKind := withinType.Kind()
+ switch withinKind {
+ case types.TypeParamKind:
+ wtSub, found := m.find(withinType)
+ if !found {
+ return true
+ }
+ return notReferencedIn(m, t, wtSub)
+ case types.OpaqueKind, types.ListKind, types.MapKind, types.TypeKind:
+ for _, pt := range withinType.Parameters() {
+ if !notReferencedIn(m, t, pt) {
+ return false
+ }
+ }
+ return true
+ default:
+ return true
+ }
+}
+
+// substitute replaces all direct and indirect occurrences of bound type parameters. Unbound type
+// parameters are replaced by DYN if typeParamToDyn is true.
+func substitute(m *mapping, t *types.Type, typeParamToDyn bool) *types.Type {
+ if tSub, found := m.find(t); found {
+ return substitute(m, tSub, typeParamToDyn)
+ }
+ kind := t.Kind()
+ if typeParamToDyn && kind == types.TypeParamKind {
+ return types.DynType
+ }
+ switch kind {
+ case types.OpaqueKind:
+ return types.NewOpaqueType(t.TypeName(), substituteParams(m, t.Parameters(), typeParamToDyn)...)
+ case types.ListKind:
+ return types.NewListType(substitute(m, t.Parameters()[0], typeParamToDyn))
+ case types.MapKind:
+ return types.NewMapType(substitute(m, t.Parameters()[0], typeParamToDyn),
+ substitute(m, t.Parameters()[1], typeParamToDyn))
+ case types.TypeKind:
+ if len(t.Parameters()) > 0 {
+ tParam := t.Parameters()[0]
+ return types.NewTypeTypeWithParam(substitute(m, tParam, typeParamToDyn))
+ }
+ return t
+ default:
+ return t
+ }
+}
+
+func substituteParams(m *mapping, typeParams []*types.Type, typeParamToDyn bool) []*types.Type {
+ subParams := make([]*types.Type, len(typeParams))
+ for i, tp := range typeParams {
+ subParams[i] = substitute(m, tp, typeParamToDyn)
+ }
+ return subParams
+}
+
+func newFunctionType(resultType *types.Type, argTypes ...*types.Type) *types.Type {
+ return types.NewOpaqueType("function", append([]*types.Type{resultType}, argTypes...)...)
+}
diff --git a/vendor/github.com/google/cel-go/common/BUILD.bazel b/vendor/github.com/google/cel-go/common/BUILD.bazel
new file mode 100644
index 000000000000..4692b416e706
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/BUILD.bazel
@@ -0,0 +1,24 @@
+load("@io_bazel_rules_go//go:def.bzl", "go_library")
+
+package(
+ default_visibility = ["//visibility:public"],
+ licenses = ["notice"], # Apache 2.0
+)
+
+go_library(
+ name = "go_default_library",
+ srcs = [
+ "cost.go",
+ "doc.go",
+ "error.go",
+ "errors.go",
+ "location.go",
+ "source.go",
+ ],
+ importmap = "kubevirt.io/kubevirt/vendor/github.com/google/cel-go/common",
+ importpath = "github.com/google/cel-go/common",
+ deps = [
+ "//vendor/github.com/google/cel-go/common/runes:go_default_library",
+ "//vendor/google.golang.org/genproto/googleapis/api/expr/v1alpha1:go_default_library",
+ ],
+)
diff --git a/vendor/github.com/google/cel-go/common/ast/BUILD.bazel b/vendor/github.com/google/cel-go/common/ast/BUILD.bazel
new file mode 100644
index 000000000000..2e90aa3d7472
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/ast/BUILD.bazel
@@ -0,0 +1,26 @@
+load("@io_bazel_rules_go//go:def.bzl", "go_library")
+
+package(
+ default_visibility = ["//visibility:public"],
+ licenses = ["notice"], # Apache 2.0
+)
+
+go_library(
+ name = "go_default_library",
+ srcs = [
+ "ast.go",
+ "conversion.go",
+ "expr.go",
+ "factory.go",
+ "navigable.go",
+ ],
+ importmap = "kubevirt.io/kubevirt/vendor/github.com/google/cel-go/common/ast",
+ importpath = "github.com/google/cel-go/common/ast",
+ deps = [
+ "//vendor/github.com/google/cel-go/common:go_default_library",
+ "//vendor/github.com/google/cel-go/common/types:go_default_library",
+ "//vendor/github.com/google/cel-go/common/types/ref:go_default_library",
+ "//vendor/google.golang.org/genproto/googleapis/api/expr/v1alpha1:go_default_library",
+ "//vendor/google.golang.org/protobuf/types/known/structpb:go_default_library",
+ ],
+)
diff --git a/vendor/github.com/google/cel-go/common/ast/ast.go b/vendor/github.com/google/cel-go/common/ast/ast.go
new file mode 100644
index 000000000000..b807669d49c0
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/ast/ast.go
@@ -0,0 +1,457 @@
+// Copyright 2023 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+// Package ast declares data structures useful for parsed and checked abstract syntax trees
+package ast
+
+import (
+ "github.com/google/cel-go/common"
+ "github.com/google/cel-go/common/types"
+ "github.com/google/cel-go/common/types/ref"
+)
+
+// AST contains a protobuf expression and source info along with CEL-native type and reference information.
+type AST struct {
+ expr Expr
+ sourceInfo *SourceInfo
+ typeMap map[int64]*types.Type
+ refMap map[int64]*ReferenceInfo
+}
+
+// Expr returns the root ast.Expr value in the AST.
+func (a *AST) Expr() Expr {
+ if a == nil {
+ return nilExpr
+ }
+ return a.expr
+}
+
+// SourceInfo returns the source metadata associated with the parse / type-check passes.
+func (a *AST) SourceInfo() *SourceInfo {
+ if a == nil {
+ return nil
+ }
+ return a.sourceInfo
+}
+
+// GetType returns the type for the expression at the given id, if one exists, else types.DynType.
+func (a *AST) GetType(id int64) *types.Type {
+ if t, found := a.TypeMap()[id]; found {
+ return t
+ }
+ return types.DynType
+}
+
+// SetType sets the type of the expression node at the given id.
+func (a *AST) SetType(id int64, t *types.Type) {
+ if a == nil {
+ return
+ }
+ a.typeMap[id] = t
+}
+
+// TypeMap returns the map of expression ids to type-checked types.
+//
+// If the AST is not type-checked, the map will be empty.
+func (a *AST) TypeMap() map[int64]*types.Type {
+ if a == nil {
+ return map[int64]*types.Type{}
+ }
+ return a.typeMap
+}
+
+// GetOverloadIDs returns the set of overload function names for a given expression id.
+//
+// If the expression id is not a function call, or the AST is not type-checked, the result will be empty.
+func (a *AST) GetOverloadIDs(id int64) []string {
+ if ref, found := a.ReferenceMap()[id]; found {
+ return ref.OverloadIDs
+ }
+ return []string{}
+}
+
+// ReferenceMap returns the map of expression id to identifier, constant, and function references.
+func (a *AST) ReferenceMap() map[int64]*ReferenceInfo {
+ if a == nil {
+ return map[int64]*ReferenceInfo{}
+ }
+ return a.refMap
+}
+
+// SetReference adds a reference to the checked AST type map.
+func (a *AST) SetReference(id int64, r *ReferenceInfo) {
+ if a == nil {
+ return
+ }
+ a.refMap[id] = r
+}
+
+// IsChecked returns whether the AST is type-checked.
+func (a *AST) IsChecked() bool {
+ return a != nil && len(a.TypeMap()) > 0
+}
+
+// NewAST creates a base AST instance with an ast.Expr and ast.SourceInfo value.
+func NewAST(e Expr, sourceInfo *SourceInfo) *AST {
+ if e == nil {
+ e = nilExpr
+ }
+ return &AST{
+ expr: e,
+ sourceInfo: sourceInfo,
+ typeMap: make(map[int64]*types.Type),
+ refMap: make(map[int64]*ReferenceInfo),
+ }
+}
+
+// NewCheckedAST wraps an parsed AST and augments it with type and reference metadata.
+func NewCheckedAST(parsed *AST, typeMap map[int64]*types.Type, refMap map[int64]*ReferenceInfo) *AST {
+ return &AST{
+ expr: parsed.Expr(),
+ sourceInfo: parsed.SourceInfo(),
+ typeMap: typeMap,
+ refMap: refMap,
+ }
+}
+
+// Copy creates a deep copy of the Expr and SourceInfo values in the input AST.
+//
+// Copies of the Expr value are generated using an internal default ExprFactory.
+func Copy(a *AST) *AST {
+ if a == nil {
+ return nil
+ }
+ e := defaultFactory.CopyExpr(a.expr)
+ if !a.IsChecked() {
+ return NewAST(e, CopySourceInfo(a.SourceInfo()))
+ }
+ typesCopy := make(map[int64]*types.Type, len(a.typeMap))
+ for id, t := range a.typeMap {
+ typesCopy[id] = t
+ }
+ refsCopy := make(map[int64]*ReferenceInfo, len(a.refMap))
+ for id, r := range a.refMap {
+ refsCopy[id] = r
+ }
+ return NewCheckedAST(NewAST(e, CopySourceInfo(a.SourceInfo())), typesCopy, refsCopy)
+}
+
+// MaxID returns the upper-bound, non-inclusive, of ids present within the AST's Expr value.
+func MaxID(a *AST) int64 {
+ visitor := &maxIDVisitor{maxID: 1}
+ PostOrderVisit(a.Expr(), visitor)
+ for id, call := range a.SourceInfo().MacroCalls() {
+ PostOrderVisit(call, visitor)
+ if id > visitor.maxID {
+ visitor.maxID = id + 1
+ }
+ }
+ return visitor.maxID + 1
+}
+
+// NewSourceInfo creates a simple SourceInfo object from an input common.Source value.
+func NewSourceInfo(src common.Source) *SourceInfo {
+ var lineOffsets []int32
+ var desc string
+ baseLine := int32(0)
+ baseCol := int32(0)
+ if src != nil {
+ desc = src.Description()
+ lineOffsets = src.LineOffsets()
+ // Determine whether the source metadata should be computed relative
+ // to a base line and column value. This can be determined by requesting
+ // the location for offset 0 from the source object.
+ if loc, found := src.OffsetLocation(0); found {
+ baseLine = int32(loc.Line()) - 1
+ baseCol = int32(loc.Column())
+ }
+ }
+ return &SourceInfo{
+ desc: desc,
+ lines: lineOffsets,
+ baseLine: baseLine,
+ baseCol: baseCol,
+ offsetRanges: make(map[int64]OffsetRange),
+ macroCalls: make(map[int64]Expr),
+ }
+}
+
+// CopySourceInfo creates a deep copy of the MacroCalls within the input SourceInfo.
+//
+// Copies of macro Expr values are generated using an internal default ExprFactory.
+func CopySourceInfo(info *SourceInfo) *SourceInfo {
+ if info == nil {
+ return nil
+ }
+ rangesCopy := make(map[int64]OffsetRange, len(info.offsetRanges))
+ for id, off := range info.offsetRanges {
+ rangesCopy[id] = off
+ }
+ callsCopy := make(map[int64]Expr, len(info.macroCalls))
+ for id, call := range info.macroCalls {
+ callsCopy[id] = defaultFactory.CopyExpr(call)
+ }
+ return &SourceInfo{
+ syntax: info.syntax,
+ desc: info.desc,
+ lines: info.lines,
+ baseLine: info.baseLine,
+ baseCol: info.baseCol,
+ offsetRanges: rangesCopy,
+ macroCalls: callsCopy,
+ }
+}
+
+// SourceInfo records basic information about the expression as a textual input and
+// as a parsed expression value.
+type SourceInfo struct {
+ syntax string
+ desc string
+ lines []int32
+ baseLine int32
+ baseCol int32
+ offsetRanges map[int64]OffsetRange
+ macroCalls map[int64]Expr
+}
+
+// SyntaxVersion returns the syntax version associated with the text expression.
+func (s *SourceInfo) SyntaxVersion() string {
+ if s == nil {
+ return ""
+ }
+ return s.syntax
+}
+
+// Description provides information about where the expression came from.
+func (s *SourceInfo) Description() string {
+ if s == nil {
+ return ""
+ }
+ return s.desc
+}
+
+// LineOffsets returns a list of the 0-based character offsets in the input text where newlines appear.
+func (s *SourceInfo) LineOffsets() []int32 {
+ if s == nil {
+ return []int32{}
+ }
+ return s.lines
+}
+
+// MacroCalls returns a map of expression id to ast.Expr value where the id represents the expression
+// node where the macro was inserted into the AST, and the ast.Expr value represents the original call
+// signature which was replaced.
+func (s *SourceInfo) MacroCalls() map[int64]Expr {
+ if s == nil {
+ return map[int64]Expr{}
+ }
+ return s.macroCalls
+}
+
+// GetMacroCall returns the original ast.Expr value for the given expression if it was generated via
+// a macro replacement.
+//
+// Note, parsing options must be enabled to track macro calls before this method will return a value.
+func (s *SourceInfo) GetMacroCall(id int64) (Expr, bool) {
+ e, found := s.MacroCalls()[id]
+ return e, found
+}
+
+// SetMacroCall records a macro call at a specific location.
+func (s *SourceInfo) SetMacroCall(id int64, e Expr) {
+ if s != nil {
+ s.macroCalls[id] = e
+ }
+}
+
+// ClearMacroCall removes the macro call at the given expression id.
+func (s *SourceInfo) ClearMacroCall(id int64) {
+ if s != nil {
+ delete(s.macroCalls, id)
+ }
+}
+
+// OffsetRanges returns a map of expression id to OffsetRange values where the range indicates either:
+// the start and end position in the input stream where the expression occurs, or the start position
+// only. If the range only captures start position, the stop position of the range will be equal to
+// the start.
+func (s *SourceInfo) OffsetRanges() map[int64]OffsetRange {
+ if s == nil {
+ return map[int64]OffsetRange{}
+ }
+ return s.offsetRanges
+}
+
+// GetOffsetRange retrieves an OffsetRange for the given expression id if one exists.
+func (s *SourceInfo) GetOffsetRange(id int64) (OffsetRange, bool) {
+ if s == nil {
+ return OffsetRange{}, false
+ }
+ o, found := s.offsetRanges[id]
+ return o, found
+}
+
+// SetOffsetRange sets the OffsetRange for the given expression id.
+func (s *SourceInfo) SetOffsetRange(id int64, o OffsetRange) {
+ if s == nil {
+ return
+ }
+ s.offsetRanges[id] = o
+}
+
+// ClearOffsetRange removes the OffsetRange for the given expression id.
+func (s *SourceInfo) ClearOffsetRange(id int64) {
+ if s != nil {
+ delete(s.offsetRanges, id)
+ }
+}
+
+// GetStartLocation calculates the human-readable 1-based line and 0-based column of the first character
+// of the expression node at the id.
+func (s *SourceInfo) GetStartLocation(id int64) common.Location {
+ if o, found := s.GetOffsetRange(id); found {
+ return s.GetLocationByOffset(o.Start)
+ }
+ return common.NoLocation
+}
+
+// GetStopLocation calculates the human-readable 1-based line and 0-based column of the last character for
+// the expression node at the given id.
+//
+// If the SourceInfo was generated from a serialized protobuf representation, the stop location will
+// be identical to the start location for the expression.
+func (s *SourceInfo) GetStopLocation(id int64) common.Location {
+ if o, found := s.GetOffsetRange(id); found {
+ return s.GetLocationByOffset(o.Stop)
+ }
+ return common.NoLocation
+}
+
+// GetLocationByOffset returns the line and column information for a given character offset.
+func (s *SourceInfo) GetLocationByOffset(offset int32) common.Location {
+ line := 1
+ col := int(offset)
+ for _, lineOffset := range s.LineOffsets() {
+ if lineOffset > offset {
+ break
+ }
+ line++
+ col = int(offset - lineOffset)
+ }
+ return common.NewLocation(line, col)
+}
+
+// ComputeOffset calculates the 0-based character offset from a 1-based line and 0-based column.
+func (s *SourceInfo) ComputeOffset(line, col int32) int32 {
+ if s != nil {
+ line = s.baseLine + line
+ col = s.baseCol + col
+ }
+ if line == 1 {
+ return col
+ }
+ if line < 1 || line > int32(len(s.LineOffsets())) {
+ return -1
+ }
+ offset := s.LineOffsets()[line-2]
+ return offset + col
+}
+
+// OffsetRange captures the start and stop positions of a section of text in the input expression.
+type OffsetRange struct {
+ Start int32
+ Stop int32
+}
+
+// ReferenceInfo contains a CEL native representation of an identifier reference which may refer to
+// either a qualified identifier name, a set of overload ids, or a constant value from an enum.
+type ReferenceInfo struct {
+ Name string
+ OverloadIDs []string
+ Value ref.Val
+}
+
+// NewIdentReference creates a ReferenceInfo instance for an identifier with an optional constant value.
+func NewIdentReference(name string, value ref.Val) *ReferenceInfo {
+ return &ReferenceInfo{Name: name, Value: value}
+}
+
+// NewFunctionReference creates a ReferenceInfo instance for a set of function overloads.
+func NewFunctionReference(overloads ...string) *ReferenceInfo {
+ info := &ReferenceInfo{}
+ for _, id := range overloads {
+ info.AddOverload(id)
+ }
+ return info
+}
+
+// AddOverload appends a function overload ID to the ReferenceInfo.
+func (r *ReferenceInfo) AddOverload(overloadID string) {
+ for _, id := range r.OverloadIDs {
+ if id == overloadID {
+ return
+ }
+ }
+ r.OverloadIDs = append(r.OverloadIDs, overloadID)
+}
+
+// Equals returns whether two references are identical to each other.
+func (r *ReferenceInfo) Equals(other *ReferenceInfo) bool {
+ if r.Name != other.Name {
+ return false
+ }
+ if len(r.OverloadIDs) != len(other.OverloadIDs) {
+ return false
+ }
+ if len(r.OverloadIDs) != 0 {
+ overloadMap := make(map[string]struct{}, len(r.OverloadIDs))
+ for _, id := range r.OverloadIDs {
+ overloadMap[id] = struct{}{}
+ }
+ for _, id := range other.OverloadIDs {
+ _, found := overloadMap[id]
+ if !found {
+ return false
+ }
+ }
+ }
+ if r.Value == nil && other.Value == nil {
+ return true
+ }
+ if r.Value == nil && other.Value != nil ||
+ r.Value != nil && other.Value == nil ||
+ r.Value.Equal(other.Value) != types.True {
+ return false
+ }
+ return true
+}
+
+type maxIDVisitor struct {
+ maxID int64
+ *baseVisitor
+}
+
+// VisitExpr updates the max identifier if the incoming expression id is greater than previously observed.
+func (v *maxIDVisitor) VisitExpr(e Expr) {
+ if v.maxID < e.ID() {
+ v.maxID = e.ID()
+ }
+}
+
+// VisitEntryExpr updates the max identifier if the incoming entry id is greater than previously observed.
+func (v *maxIDVisitor) VisitEntryExpr(e EntryExpr) {
+ if v.maxID < e.ID() {
+ v.maxID = e.ID()
+ }
+}
diff --git a/vendor/github.com/google/cel-go/common/ast/conversion.go b/vendor/github.com/google/cel-go/common/ast/conversion.go
new file mode 100644
index 000000000000..8f2c4bd1e64b
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/ast/conversion.go
@@ -0,0 +1,632 @@
+// Copyright 2023 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package ast
+
+import (
+ "fmt"
+
+ "github.com/google/cel-go/common/types"
+ "github.com/google/cel-go/common/types/ref"
+
+ structpb "google.golang.org/protobuf/types/known/structpb"
+
+ exprpb "google.golang.org/genproto/googleapis/api/expr/v1alpha1"
+)
+
+// ToProto converts an AST to a CheckedExpr protobouf.
+func ToProto(ast *AST) (*exprpb.CheckedExpr, error) {
+ refMap := make(map[int64]*exprpb.Reference, len(ast.ReferenceMap()))
+ for id, ref := range ast.ReferenceMap() {
+ r, err := ReferenceInfoToProto(ref)
+ if err != nil {
+ return nil, err
+ }
+ refMap[id] = r
+ }
+ typeMap := make(map[int64]*exprpb.Type, len(ast.TypeMap()))
+ for id, typ := range ast.TypeMap() {
+ t, err := types.TypeToExprType(typ)
+ if err != nil {
+ return nil, err
+ }
+ typeMap[id] = t
+ }
+ e, err := ExprToProto(ast.Expr())
+ if err != nil {
+ return nil, err
+ }
+ info, err := SourceInfoToProto(ast.SourceInfo())
+ if err != nil {
+ return nil, err
+ }
+ return &exprpb.CheckedExpr{
+ Expr: e,
+ SourceInfo: info,
+ ReferenceMap: refMap,
+ TypeMap: typeMap,
+ }, nil
+}
+
+// ToAST converts a CheckedExpr protobuf to an AST instance.
+func ToAST(checked *exprpb.CheckedExpr) (*AST, error) {
+ refMap := make(map[int64]*ReferenceInfo, len(checked.GetReferenceMap()))
+ for id, ref := range checked.GetReferenceMap() {
+ r, err := ProtoToReferenceInfo(ref)
+ if err != nil {
+ return nil, err
+ }
+ refMap[id] = r
+ }
+ typeMap := make(map[int64]*types.Type, len(checked.GetTypeMap()))
+ for id, typ := range checked.GetTypeMap() {
+ t, err := types.ExprTypeToType(typ)
+ if err != nil {
+ return nil, err
+ }
+ typeMap[id] = t
+ }
+ info, err := ProtoToSourceInfo(checked.GetSourceInfo())
+ if err != nil {
+ return nil, err
+ }
+ root, err := ProtoToExpr(checked.GetExpr())
+ if err != nil {
+ return nil, err
+ }
+ ast := NewCheckedAST(NewAST(root, info), typeMap, refMap)
+ return ast, nil
+}
+
+// ProtoToExpr converts a protobuf Expr value to an ast.Expr value.
+func ProtoToExpr(e *exprpb.Expr) (Expr, error) {
+ factory := NewExprFactory()
+ return exprInternal(factory, e)
+}
+
+// ProtoToEntryExpr converts a protobuf struct/map entry to an ast.EntryExpr
+func ProtoToEntryExpr(e *exprpb.Expr_CreateStruct_Entry) (EntryExpr, error) {
+ factory := NewExprFactory()
+ switch e.GetKeyKind().(type) {
+ case *exprpb.Expr_CreateStruct_Entry_FieldKey:
+ return exprStructField(factory, e.GetId(), e)
+ case *exprpb.Expr_CreateStruct_Entry_MapKey:
+ return exprMapEntry(factory, e.GetId(), e)
+ }
+ return nil, fmt.Errorf("unsupported expr entry kind: %v", e)
+}
+
+func exprInternal(factory ExprFactory, e *exprpb.Expr) (Expr, error) {
+ id := e.GetId()
+ switch e.GetExprKind().(type) {
+ case *exprpb.Expr_CallExpr:
+ return exprCall(factory, id, e.GetCallExpr())
+ case *exprpb.Expr_ComprehensionExpr:
+ return exprComprehension(factory, id, e.GetComprehensionExpr())
+ case *exprpb.Expr_ConstExpr:
+ return exprLiteral(factory, id, e.GetConstExpr())
+ case *exprpb.Expr_IdentExpr:
+ return exprIdent(factory, id, e.GetIdentExpr())
+ case *exprpb.Expr_ListExpr:
+ return exprList(factory, id, e.GetListExpr())
+ case *exprpb.Expr_SelectExpr:
+ return exprSelect(factory, id, e.GetSelectExpr())
+ case *exprpb.Expr_StructExpr:
+ s := e.GetStructExpr()
+ if s.GetMessageName() != "" {
+ return exprStruct(factory, id, s)
+ }
+ return exprMap(factory, id, s)
+ }
+ return factory.NewUnspecifiedExpr(id), nil
+}
+
+func exprCall(factory ExprFactory, id int64, call *exprpb.Expr_Call) (Expr, error) {
+ var err error
+ args := make([]Expr, len(call.GetArgs()))
+ for i, a := range call.GetArgs() {
+ args[i], err = exprInternal(factory, a)
+ if err != nil {
+ return nil, err
+ }
+ }
+ if call.GetTarget() == nil {
+ return factory.NewCall(id, call.GetFunction(), args...), nil
+ }
+
+ target, err := exprInternal(factory, call.GetTarget())
+ if err != nil {
+ return nil, err
+ }
+ return factory.NewMemberCall(id, call.GetFunction(), target, args...), nil
+}
+
+func exprComprehension(factory ExprFactory, id int64, comp *exprpb.Expr_Comprehension) (Expr, error) {
+ iterRange, err := exprInternal(factory, comp.GetIterRange())
+ if err != nil {
+ return nil, err
+ }
+ accuInit, err := exprInternal(factory, comp.GetAccuInit())
+ if err != nil {
+ return nil, err
+ }
+ loopCond, err := exprInternal(factory, comp.GetLoopCondition())
+ if err != nil {
+ return nil, err
+ }
+ loopStep, err := exprInternal(factory, comp.GetLoopStep())
+ if err != nil {
+ return nil, err
+ }
+ result, err := exprInternal(factory, comp.GetResult())
+ if err != nil {
+ return nil, err
+ }
+ return factory.NewComprehension(id,
+ iterRange,
+ comp.GetIterVar(),
+ comp.GetAccuVar(),
+ accuInit,
+ loopCond,
+ loopStep,
+ result), nil
+}
+
+func exprLiteral(factory ExprFactory, id int64, c *exprpb.Constant) (Expr, error) {
+ val, err := ConstantToVal(c)
+ if err != nil {
+ return nil, err
+ }
+ return factory.NewLiteral(id, val), nil
+}
+
+func exprIdent(factory ExprFactory, id int64, i *exprpb.Expr_Ident) (Expr, error) {
+ return factory.NewIdent(id, i.GetName()), nil
+}
+
+func exprList(factory ExprFactory, id int64, l *exprpb.Expr_CreateList) (Expr, error) {
+ elems := make([]Expr, len(l.GetElements()))
+ for i, e := range l.GetElements() {
+ elem, err := exprInternal(factory, e)
+ if err != nil {
+ return nil, err
+ }
+ elems[i] = elem
+ }
+ return factory.NewList(id, elems, l.GetOptionalIndices()), nil
+}
+
+func exprMap(factory ExprFactory, id int64, s *exprpb.Expr_CreateStruct) (Expr, error) {
+ entries := make([]EntryExpr, len(s.GetEntries()))
+ var err error
+ for i, entry := range s.GetEntries() {
+ entries[i], err = exprMapEntry(factory, entry.GetId(), entry)
+ if err != nil {
+ return nil, err
+ }
+ }
+ return factory.NewMap(id, entries), nil
+}
+
+func exprMapEntry(factory ExprFactory, id int64, e *exprpb.Expr_CreateStruct_Entry) (EntryExpr, error) {
+ k, err := exprInternal(factory, e.GetMapKey())
+ if err != nil {
+ return nil, err
+ }
+ v, err := exprInternal(factory, e.GetValue())
+ if err != nil {
+ return nil, err
+ }
+ return factory.NewMapEntry(id, k, v, e.GetOptionalEntry()), nil
+}
+
+func exprSelect(factory ExprFactory, id int64, s *exprpb.Expr_Select) (Expr, error) {
+ op, err := exprInternal(factory, s.GetOperand())
+ if err != nil {
+ return nil, err
+ }
+ if s.GetTestOnly() {
+ return factory.NewPresenceTest(id, op, s.GetField()), nil
+ }
+ return factory.NewSelect(id, op, s.GetField()), nil
+}
+
+func exprStruct(factory ExprFactory, id int64, s *exprpb.Expr_CreateStruct) (Expr, error) {
+ fields := make([]EntryExpr, len(s.GetEntries()))
+ var err error
+ for i, field := range s.GetEntries() {
+ fields[i], err = exprStructField(factory, field.GetId(), field)
+ if err != nil {
+ return nil, err
+ }
+ }
+ return factory.NewStruct(id, s.GetMessageName(), fields), nil
+}
+
+func exprStructField(factory ExprFactory, id int64, f *exprpb.Expr_CreateStruct_Entry) (EntryExpr, error) {
+ v, err := exprInternal(factory, f.GetValue())
+ if err != nil {
+ return nil, err
+ }
+ return factory.NewStructField(id, f.GetFieldKey(), v, f.GetOptionalEntry()), nil
+}
+
+// ExprToProto serializes an ast.Expr value to a protobuf Expr representation.
+func ExprToProto(e Expr) (*exprpb.Expr, error) {
+ if e == nil {
+ return &exprpb.Expr{}, nil
+ }
+ switch e.Kind() {
+ case CallKind:
+ return protoCall(e.ID(), e.AsCall())
+ case ComprehensionKind:
+ return protoComprehension(e.ID(), e.AsComprehension())
+ case IdentKind:
+ return protoIdent(e.ID(), e.AsIdent())
+ case ListKind:
+ return protoList(e.ID(), e.AsList())
+ case LiteralKind:
+ return protoLiteral(e.ID(), e.AsLiteral())
+ case MapKind:
+ return protoMap(e.ID(), e.AsMap())
+ case SelectKind:
+ return protoSelect(e.ID(), e.AsSelect())
+ case StructKind:
+ return protoStruct(e.ID(), e.AsStruct())
+ case UnspecifiedExprKind:
+ // Handle the case where a macro reference may be getting translated.
+ // A nested macro 'pointer' is a non-zero expression id with no kind set.
+ if e.ID() != 0 {
+ return &exprpb.Expr{Id: e.ID()}, nil
+ }
+ return &exprpb.Expr{}, nil
+ }
+ return nil, fmt.Errorf("unsupported expr kind: %v", e)
+}
+
+// EntryExprToProto converts an ast.EntryExpr to a protobuf CreateStruct entry
+func EntryExprToProto(e EntryExpr) (*exprpb.Expr_CreateStruct_Entry, error) {
+ switch e.Kind() {
+ case MapEntryKind:
+ return protoMapEntry(e.ID(), e.AsMapEntry())
+ case StructFieldKind:
+ return protoStructField(e.ID(), e.AsStructField())
+ case UnspecifiedEntryExprKind:
+ return &exprpb.Expr_CreateStruct_Entry{}, nil
+ }
+ return nil, fmt.Errorf("unsupported expr entry kind: %v", e)
+}
+
+func protoCall(id int64, call CallExpr) (*exprpb.Expr, error) {
+ var err error
+ var target *exprpb.Expr
+ if call.IsMemberFunction() {
+ target, err = ExprToProto(call.Target())
+ if err != nil {
+ return nil, err
+ }
+ }
+ callArgs := call.Args()
+ args := make([]*exprpb.Expr, len(callArgs))
+ for i, a := range callArgs {
+ args[i], err = ExprToProto(a)
+ if err != nil {
+ return nil, err
+ }
+ }
+ return &exprpb.Expr{
+ Id: id,
+ ExprKind: &exprpb.Expr_CallExpr{
+ CallExpr: &exprpb.Expr_Call{
+ Function: call.FunctionName(),
+ Target: target,
+ Args: args,
+ },
+ },
+ }, nil
+}
+
+func protoComprehension(id int64, comp ComprehensionExpr) (*exprpb.Expr, error) {
+ iterRange, err := ExprToProto(comp.IterRange())
+ if err != nil {
+ return nil, err
+ }
+ accuInit, err := ExprToProto(comp.AccuInit())
+ if err != nil {
+ return nil, err
+ }
+ loopCond, err := ExprToProto(comp.LoopCondition())
+ if err != nil {
+ return nil, err
+ }
+ loopStep, err := ExprToProto(comp.LoopStep())
+ if err != nil {
+ return nil, err
+ }
+ result, err := ExprToProto(comp.Result())
+ if err != nil {
+ return nil, err
+ }
+ return &exprpb.Expr{
+ Id: id,
+ ExprKind: &exprpb.Expr_ComprehensionExpr{
+ ComprehensionExpr: &exprpb.Expr_Comprehension{
+ IterVar: comp.IterVar(),
+ IterRange: iterRange,
+ AccuVar: comp.AccuVar(),
+ AccuInit: accuInit,
+ LoopCondition: loopCond,
+ LoopStep: loopStep,
+ Result: result,
+ },
+ },
+ }, nil
+}
+
+func protoIdent(id int64, name string) (*exprpb.Expr, error) {
+ return &exprpb.Expr{
+ Id: id,
+ ExprKind: &exprpb.Expr_IdentExpr{
+ IdentExpr: &exprpb.Expr_Ident{
+ Name: name,
+ },
+ },
+ }, nil
+}
+
+func protoList(id int64, list ListExpr) (*exprpb.Expr, error) {
+ var err error
+ elems := make([]*exprpb.Expr, list.Size())
+ for i, e := range list.Elements() {
+ elems[i], err = ExprToProto(e)
+ if err != nil {
+ return nil, err
+ }
+ }
+ return &exprpb.Expr{
+ Id: id,
+ ExprKind: &exprpb.Expr_ListExpr{
+ ListExpr: &exprpb.Expr_CreateList{
+ Elements: elems,
+ OptionalIndices: list.OptionalIndices(),
+ },
+ },
+ }, nil
+}
+
+func protoLiteral(id int64, val ref.Val) (*exprpb.Expr, error) {
+ c, err := ValToConstant(val)
+ if err != nil {
+ return nil, err
+ }
+ return &exprpb.Expr{
+ Id: id,
+ ExprKind: &exprpb.Expr_ConstExpr{
+ ConstExpr: c,
+ },
+ }, nil
+}
+
+func protoMap(id int64, m MapExpr) (*exprpb.Expr, error) {
+ entries := make([]*exprpb.Expr_CreateStruct_Entry, len(m.Entries()))
+ var err error
+ for i, e := range m.Entries() {
+ entries[i], err = EntryExprToProto(e)
+ if err != nil {
+ return nil, err
+ }
+ }
+ return &exprpb.Expr{
+ Id: id,
+ ExprKind: &exprpb.Expr_StructExpr{
+ StructExpr: &exprpb.Expr_CreateStruct{
+ Entries: entries,
+ },
+ },
+ }, nil
+}
+
+func protoMapEntry(id int64, e MapEntry) (*exprpb.Expr_CreateStruct_Entry, error) {
+ k, err := ExprToProto(e.Key())
+ if err != nil {
+ return nil, err
+ }
+ v, err := ExprToProto(e.Value())
+ if err != nil {
+ return nil, err
+ }
+ return &exprpb.Expr_CreateStruct_Entry{
+ Id: id,
+ KeyKind: &exprpb.Expr_CreateStruct_Entry_MapKey{
+ MapKey: k,
+ },
+ Value: v,
+ OptionalEntry: e.IsOptional(),
+ }, nil
+}
+
+func protoSelect(id int64, s SelectExpr) (*exprpb.Expr, error) {
+ op, err := ExprToProto(s.Operand())
+ if err != nil {
+ return nil, err
+ }
+ return &exprpb.Expr{
+ Id: id,
+ ExprKind: &exprpb.Expr_SelectExpr{
+ SelectExpr: &exprpb.Expr_Select{
+ Operand: op,
+ Field: s.FieldName(),
+ TestOnly: s.IsTestOnly(),
+ },
+ },
+ }, nil
+}
+
+func protoStruct(id int64, s StructExpr) (*exprpb.Expr, error) {
+ entries := make([]*exprpb.Expr_CreateStruct_Entry, len(s.Fields()))
+ var err error
+ for i, e := range s.Fields() {
+ entries[i], err = EntryExprToProto(e)
+ if err != nil {
+ return nil, err
+ }
+ }
+ return &exprpb.Expr{
+ Id: id,
+ ExprKind: &exprpb.Expr_StructExpr{
+ StructExpr: &exprpb.Expr_CreateStruct{
+ MessageName: s.TypeName(),
+ Entries: entries,
+ },
+ },
+ }, nil
+}
+
+func protoStructField(id int64, f StructField) (*exprpb.Expr_CreateStruct_Entry, error) {
+ v, err := ExprToProto(f.Value())
+ if err != nil {
+ return nil, err
+ }
+ return &exprpb.Expr_CreateStruct_Entry{
+ Id: id,
+ KeyKind: &exprpb.Expr_CreateStruct_Entry_FieldKey{
+ FieldKey: f.Name(),
+ },
+ Value: v,
+ OptionalEntry: f.IsOptional(),
+ }, nil
+}
+
+// SourceInfoToProto serializes an ast.SourceInfo value to a protobuf SourceInfo object.
+func SourceInfoToProto(info *SourceInfo) (*exprpb.SourceInfo, error) {
+ if info == nil {
+ return &exprpb.SourceInfo{}, nil
+ }
+ sourceInfo := &exprpb.SourceInfo{
+ SyntaxVersion: info.SyntaxVersion(),
+ Location: info.Description(),
+ LineOffsets: info.LineOffsets(),
+ Positions: make(map[int64]int32, len(info.OffsetRanges())),
+ MacroCalls: make(map[int64]*exprpb.Expr, len(info.MacroCalls())),
+ }
+ for id, offset := range info.OffsetRanges() {
+ sourceInfo.Positions[id] = offset.Start
+ }
+ for id, e := range info.MacroCalls() {
+ call, err := ExprToProto(e)
+ if err != nil {
+ return nil, err
+ }
+ sourceInfo.MacroCalls[id] = call
+ }
+ return sourceInfo, nil
+}
+
+// ProtoToSourceInfo deserializes the protobuf into a native SourceInfo value.
+func ProtoToSourceInfo(info *exprpb.SourceInfo) (*SourceInfo, error) {
+ sourceInfo := &SourceInfo{
+ syntax: info.GetSyntaxVersion(),
+ desc: info.GetLocation(),
+ lines: info.GetLineOffsets(),
+ offsetRanges: make(map[int64]OffsetRange, len(info.GetPositions())),
+ macroCalls: make(map[int64]Expr, len(info.GetMacroCalls())),
+ }
+ for id, offset := range info.GetPositions() {
+ sourceInfo.SetOffsetRange(id, OffsetRange{Start: offset, Stop: offset})
+ }
+ for id, e := range info.GetMacroCalls() {
+ call, err := ProtoToExpr(e)
+ if err != nil {
+ return nil, err
+ }
+ sourceInfo.SetMacroCall(id, call)
+ }
+ return sourceInfo, nil
+}
+
+// ReferenceInfoToProto converts a ReferenceInfo instance to a protobuf Reference suitable for serialization.
+func ReferenceInfoToProto(info *ReferenceInfo) (*exprpb.Reference, error) {
+ c, err := ValToConstant(info.Value)
+ if err != nil {
+ return nil, err
+ }
+ return &exprpb.Reference{
+ Name: info.Name,
+ OverloadId: info.OverloadIDs,
+ Value: c,
+ }, nil
+}
+
+// ProtoToReferenceInfo converts a protobuf Reference into a CEL-native ReferenceInfo instance.
+func ProtoToReferenceInfo(ref *exprpb.Reference) (*ReferenceInfo, error) {
+ v, err := ConstantToVal(ref.GetValue())
+ if err != nil {
+ return nil, err
+ }
+ return &ReferenceInfo{
+ Name: ref.GetName(),
+ OverloadIDs: ref.GetOverloadId(),
+ Value: v,
+ }, nil
+}
+
+// ValToConstant converts a CEL-native ref.Val to a protobuf Constant.
+//
+// Only simple scalar types are supported by this method.
+func ValToConstant(v ref.Val) (*exprpb.Constant, error) {
+ if v == nil {
+ return nil, nil
+ }
+ switch v.Type() {
+ case types.BoolType:
+ return &exprpb.Constant{ConstantKind: &exprpb.Constant_BoolValue{BoolValue: v.Value().(bool)}}, nil
+ case types.BytesType:
+ return &exprpb.Constant{ConstantKind: &exprpb.Constant_BytesValue{BytesValue: v.Value().([]byte)}}, nil
+ case types.DoubleType:
+ return &exprpb.Constant{ConstantKind: &exprpb.Constant_DoubleValue{DoubleValue: v.Value().(float64)}}, nil
+ case types.IntType:
+ return &exprpb.Constant{ConstantKind: &exprpb.Constant_Int64Value{Int64Value: v.Value().(int64)}}, nil
+ case types.NullType:
+ return &exprpb.Constant{ConstantKind: &exprpb.Constant_NullValue{NullValue: structpb.NullValue_NULL_VALUE}}, nil
+ case types.StringType:
+ return &exprpb.Constant{ConstantKind: &exprpb.Constant_StringValue{StringValue: v.Value().(string)}}, nil
+ case types.UintType:
+ return &exprpb.Constant{ConstantKind: &exprpb.Constant_Uint64Value{Uint64Value: v.Value().(uint64)}}, nil
+ }
+ return nil, fmt.Errorf("unsupported constant kind: %v", v.Type())
+}
+
+// ConstantToVal converts a protobuf Constant to a CEL-native ref.Val.
+func ConstantToVal(c *exprpb.Constant) (ref.Val, error) {
+ if c == nil {
+ return nil, nil
+ }
+ switch c.GetConstantKind().(type) {
+ case *exprpb.Constant_BoolValue:
+ return types.Bool(c.GetBoolValue()), nil
+ case *exprpb.Constant_BytesValue:
+ return types.Bytes(c.GetBytesValue()), nil
+ case *exprpb.Constant_DoubleValue:
+ return types.Double(c.GetDoubleValue()), nil
+ case *exprpb.Constant_Int64Value:
+ return types.Int(c.GetInt64Value()), nil
+ case *exprpb.Constant_NullValue:
+ return types.NullValue, nil
+ case *exprpb.Constant_StringValue:
+ return types.String(c.GetStringValue()), nil
+ case *exprpb.Constant_Uint64Value:
+ return types.Uint(c.GetUint64Value()), nil
+ }
+ return nil, fmt.Errorf("unsupported constant kind: %v", c.GetConstantKind())
+}
diff --git a/vendor/github.com/google/cel-go/common/ast/expr.go b/vendor/github.com/google/cel-go/common/ast/expr.go
new file mode 100644
index 000000000000..7b043a15bb3d
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/ast/expr.go
@@ -0,0 +1,860 @@
+// Copyright 2023 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package ast
+
+import (
+ "github.com/google/cel-go/common/types/ref"
+)
+
+// ExprKind represents the expression node kind.
+type ExprKind int
+
+const (
+ // UnspecifiedExprKind represents an unset expression with no specified properties.
+ UnspecifiedExprKind ExprKind = iota
+
+ // CallKind represents a function call.
+ CallKind
+
+ // ComprehensionKind represents a comprehension expression generated by a macro.
+ ComprehensionKind
+
+ // IdentKind represents a simple variable, constant, or type identifier.
+ IdentKind
+
+ // ListKind represents a list literal expression.
+ ListKind
+
+ // LiteralKind represents a primitive scalar literal.
+ LiteralKind
+
+ // MapKind represents a map literal expression.
+ MapKind
+
+ // SelectKind represents a field selection expression.
+ SelectKind
+
+ // StructKind represents a struct literal expression.
+ StructKind
+)
+
+// Expr represents the base expression node in a CEL abstract syntax tree.
+//
+// Depending on the `Kind()` value, the Expr may be converted to a concrete expression types
+// as indicated by the `As` methods.
+type Expr interface {
+ // ID of the expression as it appears in the AST
+ ID() int64
+
+ // Kind of the expression node. See ExprKind for the valid enum values.
+ Kind() ExprKind
+
+ // AsCall adapts the expr into a CallExpr
+ //
+ // The Kind() must be equal to a CallKind for the conversion to be well-defined.
+ AsCall() CallExpr
+
+ // AsComprehension adapts the expr into a ComprehensionExpr.
+ //
+ // The Kind() must be equal to a ComprehensionKind for the conversion to be well-defined.
+ AsComprehension() ComprehensionExpr
+
+ // AsIdent adapts the expr into an identifier string.
+ //
+ // The Kind() must be equal to an IdentKind for the conversion to be well-defined.
+ AsIdent() string
+
+ // AsLiteral adapts the expr into a constant ref.Val.
+ //
+ // The Kind() must be equal to a LiteralKind for the conversion to be well-defined.
+ AsLiteral() ref.Val
+
+ // AsList adapts the expr into a ListExpr.
+ //
+ // The Kind() must be equal to a ListKind for the conversion to be well-defined.
+ AsList() ListExpr
+
+ // AsMap adapts the expr into a MapExpr.
+ //
+ // The Kind() must be equal to a MapKind for the conversion to be well-defined.
+ AsMap() MapExpr
+
+ // AsSelect adapts the expr into a SelectExpr.
+ //
+ // The Kind() must be equal to a SelectKind for the conversion to be well-defined.
+ AsSelect() SelectExpr
+
+ // AsStruct adapts the expr into a StructExpr.
+ //
+ // The Kind() must be equal to a StructKind for the conversion to be well-defined.
+ AsStruct() StructExpr
+
+ // RenumberIDs performs an in-place update of the expression and all of its descendents numeric ids.
+ RenumberIDs(IDGenerator)
+
+ // SetKindCase replaces the contents of the current expression with the contents of the other.
+ //
+ // The SetKindCase takes ownership of any expression instances references within the input Expr.
+ // A shallow copy is made of the Expr value itself, but not a deep one.
+ //
+ // This method should only be used during AST rewrites using temporary Expr values.
+ SetKindCase(Expr)
+
+ // isExpr is a marker interface.
+ isExpr()
+}
+
+// EntryExprKind represents the possible EntryExpr kinds.
+type EntryExprKind int
+
+const (
+ // UnspecifiedEntryExprKind indicates that the entry expr is not set.
+ UnspecifiedEntryExprKind EntryExprKind = iota
+
+ // MapEntryKind indicates that the entry is a MapEntry type with key and value expressions.
+ MapEntryKind
+
+ // StructFieldKind indicates that the entry is a StructField with a field name and initializer
+ // expression.
+ StructFieldKind
+)
+
+// EntryExpr represents the base entry expression in a CEL map or struct literal.
+type EntryExpr interface {
+ // ID of the entry as it appears in the AST.
+ ID() int64
+
+ // Kind of the entry expression node. See EntryExprKind for valid enum values.
+ Kind() EntryExprKind
+
+ // AsMapEntry casts the EntryExpr to a MapEntry.
+ //
+ // The Kind() must be equal to MapEntryKind for the conversion to be well-defined.
+ AsMapEntry() MapEntry
+
+ // AsStructField casts the EntryExpr to a StructField
+ //
+ // The Kind() must be equal to StructFieldKind for the conversion to be well-defined.
+ AsStructField() StructField
+
+ // RenumberIDs performs an in-place update of the expression and all of its descendents numeric ids.
+ RenumberIDs(IDGenerator)
+
+ isEntryExpr()
+}
+
+// IDGenerator produces unique ids suitable for tagging expression nodes
+type IDGenerator func(originalID int64) int64
+
+// CallExpr defines an interface for inspecting a function call and its arguments.
+type CallExpr interface {
+ // FunctionName returns the name of the function.
+ FunctionName() string
+
+ // IsMemberFunction returns whether the call has a non-nil target indicating it is a member function
+ IsMemberFunction() bool
+
+ // Target returns the target of the expression if one is present.
+ Target() Expr
+
+ // Args returns the list of call arguments, excluding the target.
+ Args() []Expr
+
+ // marker interface method
+ isExpr()
+}
+
+// ListExpr defines an interface for inspecting a list literal expression.
+type ListExpr interface {
+ // Elements returns the list elements as navigable expressions.
+ Elements() []Expr
+
+ // OptionalIndicies returns the list of optional indices in the list literal.
+ OptionalIndices() []int32
+
+ // IsOptional indicates whether the given element index is optional.
+ IsOptional(int32) bool
+
+ // Size returns the number of elements in the list.
+ Size() int
+
+ // marker interface method
+ isExpr()
+}
+
+// SelectExpr defines an interface for inspecting a select expression.
+type SelectExpr interface {
+ // Operand returns the selection operand expression.
+ Operand() Expr
+
+ // FieldName returns the field name being selected from the operand.
+ FieldName() string
+
+ // IsTestOnly indicates whether the select expression is a presence test generated by a macro.
+ IsTestOnly() bool
+
+ // marker interface method
+ isExpr()
+}
+
+// MapExpr defines an interface for inspecting a map expression.
+type MapExpr interface {
+ // Entries returns the map key value pairs as EntryExpr values.
+ Entries() []EntryExpr
+
+ // Size returns the number of entries in the map.
+ Size() int
+
+ // marker interface method
+ isExpr()
+}
+
+// MapEntry defines an interface for inspecting a map entry.
+type MapEntry interface {
+ // Key returns the map entry key expression.
+ Key() Expr
+
+ // Value returns the map entry value expression.
+ Value() Expr
+
+ // IsOptional returns whether the entry is optional.
+ IsOptional() bool
+
+ // marker interface method
+ isEntryExpr()
+}
+
+// StructExpr defines an interfaces for inspecting a struct and its field initializers.
+type StructExpr interface {
+ // TypeName returns the struct type name.
+ TypeName() string
+
+ // Fields returns the set of field initializers in the struct expression as EntryExpr values.
+ Fields() []EntryExpr
+
+ // marker interface method
+ isExpr()
+}
+
+// StructField defines an interface for inspecting a struct field initialization.
+type StructField interface {
+ // Name returns the name of the field.
+ Name() string
+
+ // Value returns the field initialization expression.
+ Value() Expr
+
+ // IsOptional returns whether the field is optional.
+ IsOptional() bool
+
+ // marker interface method
+ isEntryExpr()
+}
+
+// ComprehensionExpr defines an interface for inspecting a comprehension expression.
+type ComprehensionExpr interface {
+ // IterRange returns the iteration range expression.
+ IterRange() Expr
+
+ // IterVar returns the iteration variable name.
+ IterVar() string
+
+ // AccuVar returns the accumulation variable name.
+ AccuVar() string
+
+ // AccuInit returns the accumulation variable initialization expression.
+ AccuInit() Expr
+
+ // LoopCondition returns the loop condition expression.
+ LoopCondition() Expr
+
+ // LoopStep returns the loop step expression.
+ LoopStep() Expr
+
+ // Result returns the comprehension result expression.
+ Result() Expr
+
+ // marker interface method
+ isExpr()
+}
+
+var _ Expr = &expr{}
+
+type expr struct {
+ id int64
+ exprKindCase
+}
+
+type exprKindCase interface {
+ Kind() ExprKind
+
+ renumberIDs(IDGenerator)
+
+ isExpr()
+}
+
+func (e *expr) ID() int64 {
+ if e == nil {
+ return 0
+ }
+ return e.id
+}
+
+func (e *expr) Kind() ExprKind {
+ if e == nil || e.exprKindCase == nil {
+ return UnspecifiedExprKind
+ }
+ return e.exprKindCase.Kind()
+}
+
+func (e *expr) AsCall() CallExpr {
+ if e.Kind() != CallKind {
+ return nilCall
+ }
+ return e.exprKindCase.(CallExpr)
+}
+
+func (e *expr) AsComprehension() ComprehensionExpr {
+ if e.Kind() != ComprehensionKind {
+ return nilCompre
+ }
+ return e.exprKindCase.(ComprehensionExpr)
+}
+
+func (e *expr) AsIdent() string {
+ if e.Kind() != IdentKind {
+ return ""
+ }
+ return string(e.exprKindCase.(baseIdentExpr))
+}
+
+func (e *expr) AsLiteral() ref.Val {
+ if e.Kind() != LiteralKind {
+ return nil
+ }
+ return e.exprKindCase.(*baseLiteral).Val
+}
+
+func (e *expr) AsList() ListExpr {
+ if e.Kind() != ListKind {
+ return nilList
+ }
+ return e.exprKindCase.(ListExpr)
+}
+
+func (e *expr) AsMap() MapExpr {
+ if e.Kind() != MapKind {
+ return nilMap
+ }
+ return e.exprKindCase.(MapExpr)
+}
+
+func (e *expr) AsSelect() SelectExpr {
+ if e.Kind() != SelectKind {
+ return nilSel
+ }
+ return e.exprKindCase.(SelectExpr)
+}
+
+func (e *expr) AsStruct() StructExpr {
+ if e.Kind() != StructKind {
+ return nilStruct
+ }
+ return e.exprKindCase.(StructExpr)
+}
+
+func (e *expr) SetKindCase(other Expr) {
+ if e == nil {
+ return
+ }
+ if other == nil {
+ e.exprKindCase = nil
+ return
+ }
+ switch other.Kind() {
+ case CallKind:
+ c := other.AsCall()
+ e.exprKindCase = &baseCallExpr{
+ function: c.FunctionName(),
+ target: c.Target(),
+ args: c.Args(),
+ isMember: c.IsMemberFunction(),
+ }
+ case ComprehensionKind:
+ c := other.AsComprehension()
+ e.exprKindCase = &baseComprehensionExpr{
+ iterRange: c.IterRange(),
+ iterVar: c.IterVar(),
+ accuVar: c.AccuVar(),
+ accuInit: c.AccuInit(),
+ loopCond: c.LoopCondition(),
+ loopStep: c.LoopStep(),
+ result: c.Result(),
+ }
+ case IdentKind:
+ e.exprKindCase = baseIdentExpr(other.AsIdent())
+ case ListKind:
+ l := other.AsList()
+ optIndexMap := make(map[int32]struct{}, len(l.OptionalIndices()))
+ for _, idx := range l.OptionalIndices() {
+ optIndexMap[idx] = struct{}{}
+ }
+ e.exprKindCase = &baseListExpr{
+ elements: l.Elements(),
+ optIndices: l.OptionalIndices(),
+ optIndexMap: optIndexMap,
+ }
+ case LiteralKind:
+ e.exprKindCase = &baseLiteral{Val: other.AsLiteral()}
+ case MapKind:
+ e.exprKindCase = &baseMapExpr{
+ entries: other.AsMap().Entries(),
+ }
+ case SelectKind:
+ s := other.AsSelect()
+ e.exprKindCase = &baseSelectExpr{
+ operand: s.Operand(),
+ field: s.FieldName(),
+ testOnly: s.IsTestOnly(),
+ }
+ case StructKind:
+ s := other.AsStruct()
+ e.exprKindCase = &baseStructExpr{
+ typeName: s.TypeName(),
+ fields: s.Fields(),
+ }
+ case UnspecifiedExprKind:
+ e.exprKindCase = nil
+ }
+}
+
+func (e *expr) RenumberIDs(idGen IDGenerator) {
+ if e == nil {
+ return
+ }
+ e.id = idGen(e.id)
+ if e.exprKindCase != nil {
+ e.exprKindCase.renumberIDs(idGen)
+ }
+}
+
+type baseCallExpr struct {
+ function string
+ target Expr
+ args []Expr
+ isMember bool
+}
+
+func (*baseCallExpr) Kind() ExprKind {
+ return CallKind
+}
+
+func (e *baseCallExpr) FunctionName() string {
+ if e == nil {
+ return ""
+ }
+ return e.function
+}
+
+func (e *baseCallExpr) IsMemberFunction() bool {
+ if e == nil {
+ return false
+ }
+ return e.isMember
+}
+
+func (e *baseCallExpr) Target() Expr {
+ if e == nil || !e.IsMemberFunction() {
+ return nilExpr
+ }
+ return e.target
+}
+
+func (e *baseCallExpr) Args() []Expr {
+ if e == nil {
+ return []Expr{}
+ }
+ return e.args
+}
+
+func (e *baseCallExpr) renumberIDs(idGen IDGenerator) {
+ if e.IsMemberFunction() {
+ e.Target().RenumberIDs(idGen)
+ }
+ for _, arg := range e.Args() {
+ arg.RenumberIDs(idGen)
+ }
+}
+
+func (*baseCallExpr) isExpr() {}
+
+var _ ComprehensionExpr = &baseComprehensionExpr{}
+
+type baseComprehensionExpr struct {
+ iterRange Expr
+ iterVar string
+ accuVar string
+ accuInit Expr
+ loopCond Expr
+ loopStep Expr
+ result Expr
+}
+
+func (*baseComprehensionExpr) Kind() ExprKind {
+ return ComprehensionKind
+}
+
+func (e *baseComprehensionExpr) IterRange() Expr {
+ if e == nil {
+ return nilExpr
+ }
+ return e.iterRange
+}
+
+func (e *baseComprehensionExpr) IterVar() string {
+ return e.iterVar
+}
+
+func (e *baseComprehensionExpr) AccuVar() string {
+ return e.accuVar
+}
+
+func (e *baseComprehensionExpr) AccuInit() Expr {
+ if e == nil {
+ return nilExpr
+ }
+ return e.accuInit
+}
+
+func (e *baseComprehensionExpr) LoopCondition() Expr {
+ if e == nil {
+ return nilExpr
+ }
+ return e.loopCond
+}
+
+func (e *baseComprehensionExpr) LoopStep() Expr {
+ if e == nil {
+ return nilExpr
+ }
+ return e.loopStep
+}
+
+func (e *baseComprehensionExpr) Result() Expr {
+ if e == nil {
+ return nilExpr
+ }
+ return e.result
+}
+
+func (e *baseComprehensionExpr) renumberIDs(idGen IDGenerator) {
+ e.IterRange().RenumberIDs(idGen)
+ e.AccuInit().RenumberIDs(idGen)
+ e.LoopCondition().RenumberIDs(idGen)
+ e.LoopStep().RenumberIDs(idGen)
+ e.Result().RenumberIDs(idGen)
+}
+
+func (*baseComprehensionExpr) isExpr() {}
+
+var _ exprKindCase = baseIdentExpr("")
+
+type baseIdentExpr string
+
+func (baseIdentExpr) Kind() ExprKind {
+ return IdentKind
+}
+
+func (e baseIdentExpr) renumberIDs(IDGenerator) {}
+
+func (baseIdentExpr) isExpr() {}
+
+var _ exprKindCase = &baseLiteral{}
+var _ ref.Val = &baseLiteral{}
+
+type baseLiteral struct {
+ ref.Val
+}
+
+func (*baseLiteral) Kind() ExprKind {
+ return LiteralKind
+}
+
+func (l *baseLiteral) renumberIDs(IDGenerator) {}
+
+func (*baseLiteral) isExpr() {}
+
+var _ ListExpr = &baseListExpr{}
+
+type baseListExpr struct {
+ elements []Expr
+ optIndices []int32
+ optIndexMap map[int32]struct{}
+}
+
+func (*baseListExpr) Kind() ExprKind {
+ return ListKind
+}
+
+func (e *baseListExpr) Elements() []Expr {
+ if e == nil {
+ return []Expr{}
+ }
+ return e.elements
+}
+
+func (e *baseListExpr) IsOptional(index int32) bool {
+ _, found := e.optIndexMap[index]
+ return found
+}
+
+func (e *baseListExpr) OptionalIndices() []int32 {
+ if e == nil {
+ return []int32{}
+ }
+ return e.optIndices
+}
+
+func (e *baseListExpr) Size() int {
+ return len(e.Elements())
+}
+
+func (e *baseListExpr) renumberIDs(idGen IDGenerator) {
+ for _, elem := range e.Elements() {
+ elem.RenumberIDs(idGen)
+ }
+}
+
+func (*baseListExpr) isExpr() {}
+
+type baseMapExpr struct {
+ entries []EntryExpr
+}
+
+func (*baseMapExpr) Kind() ExprKind {
+ return MapKind
+}
+
+func (e *baseMapExpr) Entries() []EntryExpr {
+ if e == nil {
+ return []EntryExpr{}
+ }
+ return e.entries
+}
+
+func (e *baseMapExpr) Size() int {
+ return len(e.Entries())
+}
+
+func (e *baseMapExpr) renumberIDs(idGen IDGenerator) {
+ for _, entry := range e.Entries() {
+ entry.RenumberIDs(idGen)
+ }
+}
+
+func (*baseMapExpr) isExpr() {}
+
+type baseSelectExpr struct {
+ operand Expr
+ field string
+ testOnly bool
+}
+
+func (*baseSelectExpr) Kind() ExprKind {
+ return SelectKind
+}
+
+func (e *baseSelectExpr) Operand() Expr {
+ if e == nil || e.operand == nil {
+ return nilExpr
+ }
+ return e.operand
+}
+
+func (e *baseSelectExpr) FieldName() string {
+ if e == nil {
+ return ""
+ }
+ return e.field
+}
+
+func (e *baseSelectExpr) IsTestOnly() bool {
+ if e == nil {
+ return false
+ }
+ return e.testOnly
+}
+
+func (e *baseSelectExpr) renumberIDs(idGen IDGenerator) {
+ e.Operand().RenumberIDs(idGen)
+}
+
+func (*baseSelectExpr) isExpr() {}
+
+type baseStructExpr struct {
+ typeName string
+ fields []EntryExpr
+}
+
+func (*baseStructExpr) Kind() ExprKind {
+ return StructKind
+}
+
+func (e *baseStructExpr) TypeName() string {
+ if e == nil {
+ return ""
+ }
+ return e.typeName
+}
+
+func (e *baseStructExpr) Fields() []EntryExpr {
+ if e == nil {
+ return []EntryExpr{}
+ }
+ return e.fields
+}
+
+func (e *baseStructExpr) renumberIDs(idGen IDGenerator) {
+ for _, f := range e.Fields() {
+ f.RenumberIDs(idGen)
+ }
+}
+
+func (*baseStructExpr) isExpr() {}
+
+type entryExprKindCase interface {
+ Kind() EntryExprKind
+
+ renumberIDs(IDGenerator)
+
+ isEntryExpr()
+}
+
+var _ EntryExpr = &entryExpr{}
+
+type entryExpr struct {
+ id int64
+ entryExprKindCase
+}
+
+func (e *entryExpr) ID() int64 {
+ return e.id
+}
+
+func (e *entryExpr) AsMapEntry() MapEntry {
+ if e.Kind() != MapEntryKind {
+ return nilMapEntry
+ }
+ return e.entryExprKindCase.(MapEntry)
+}
+
+func (e *entryExpr) AsStructField() StructField {
+ if e.Kind() != StructFieldKind {
+ return nilStructField
+ }
+ return e.entryExprKindCase.(StructField)
+}
+
+func (e *entryExpr) RenumberIDs(idGen IDGenerator) {
+ e.id = idGen(e.id)
+ e.entryExprKindCase.renumberIDs(idGen)
+}
+
+type baseMapEntry struct {
+ key Expr
+ value Expr
+ isOptional bool
+}
+
+func (e *baseMapEntry) Kind() EntryExprKind {
+ return MapEntryKind
+}
+
+func (e *baseMapEntry) Key() Expr {
+ if e == nil {
+ return nilExpr
+ }
+ return e.key
+}
+
+func (e *baseMapEntry) Value() Expr {
+ if e == nil {
+ return nilExpr
+ }
+ return e.value
+}
+
+func (e *baseMapEntry) IsOptional() bool {
+ if e == nil {
+ return false
+ }
+ return e.isOptional
+}
+
+func (e *baseMapEntry) renumberIDs(idGen IDGenerator) {
+ e.Key().RenumberIDs(idGen)
+ e.Value().RenumberIDs(idGen)
+}
+
+func (*baseMapEntry) isEntryExpr() {}
+
+type baseStructField struct {
+ field string
+ value Expr
+ isOptional bool
+}
+
+func (f *baseStructField) Kind() EntryExprKind {
+ return StructFieldKind
+}
+
+func (f *baseStructField) Name() string {
+ if f == nil {
+ return ""
+ }
+ return f.field
+}
+
+func (f *baseStructField) Value() Expr {
+ if f == nil {
+ return nilExpr
+ }
+ return f.value
+}
+
+func (f *baseStructField) IsOptional() bool {
+ if f == nil {
+ return false
+ }
+ return f.isOptional
+}
+
+func (f *baseStructField) renumberIDs(idGen IDGenerator) {
+ f.Value().RenumberIDs(idGen)
+}
+
+func (*baseStructField) isEntryExpr() {}
+
+var (
+ nilExpr *expr = nil
+ nilCall *baseCallExpr = nil
+ nilCompre *baseComprehensionExpr = nil
+ nilList *baseListExpr = nil
+ nilMap *baseMapExpr = nil
+ nilMapEntry *baseMapEntry = nil
+ nilSel *baseSelectExpr = nil
+ nilStruct *baseStructExpr = nil
+ nilStructField *baseStructField = nil
+)
diff --git a/vendor/github.com/google/cel-go/common/ast/factory.go b/vendor/github.com/google/cel-go/common/ast/factory.go
new file mode 100644
index 000000000000..b7f36e72a49b
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/ast/factory.go
@@ -0,0 +1,303 @@
+// Copyright 2023 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package ast
+
+import "github.com/google/cel-go/common/types/ref"
+
+// ExprFactory interfaces defines a set of methods necessary for building native expression values.
+type ExprFactory interface {
+ // CopyExpr creates a deep copy of the input Expr value.
+ CopyExpr(Expr) Expr
+
+ // CopyEntryExpr creates a deep copy of the input EntryExpr value.
+ CopyEntryExpr(EntryExpr) EntryExpr
+
+ // NewCall creates an Expr value representing a global function call.
+ NewCall(id int64, function string, args ...Expr) Expr
+
+ // NewComprehension creates an Expr value representing a comprehension over a value range.
+ NewComprehension(id int64, iterRange Expr, iterVar, accuVar string, accuInit, loopCondition, loopStep, result Expr) Expr
+
+ // NewMemberCall creates an Expr value representing a member function call.
+ NewMemberCall(id int64, function string, receiver Expr, args ...Expr) Expr
+
+ // NewIdent creates an Expr value representing an identifier.
+ NewIdent(id int64, name string) Expr
+
+ // NewAccuIdent creates an Expr value representing an accumulator identifier within a
+ //comprehension.
+ NewAccuIdent(id int64) Expr
+
+ // NewLiteral creates an Expr value representing a literal value, such as a string or integer.
+ NewLiteral(id int64, value ref.Val) Expr
+
+ // NewList creates an Expr value representing a list literal expression with optional indices.
+ //
+ // Optional indicies will typically be empty unless the CEL optional types are enabled.
+ NewList(id int64, elems []Expr, optIndices []int32) Expr
+
+ // NewMap creates an Expr value representing a map literal expression
+ NewMap(id int64, entries []EntryExpr) Expr
+
+ // NewMapEntry creates a MapEntry with a given key, value, and a flag indicating whether
+ // the key is optionally set.
+ NewMapEntry(id int64, key, value Expr, isOptional bool) EntryExpr
+
+ // NewPresenceTest creates an Expr representing a field presence test on an operand expression.
+ NewPresenceTest(id int64, operand Expr, field string) Expr
+
+ // NewSelect creates an Expr representing a field selection on an operand expression.
+ NewSelect(id int64, operand Expr, field string) Expr
+
+ // NewStruct creates an Expr value representing a struct literal with a given type name and a
+ // set of field initializers.
+ NewStruct(id int64, typeName string, fields []EntryExpr) Expr
+
+ // NewStructField creates a StructField with a given field name, value, and a flag indicating
+ // whether the field is optionally set.
+ NewStructField(id int64, field string, value Expr, isOptional bool) EntryExpr
+
+ // NewUnspecifiedExpr creates an empty expression node.
+ NewUnspecifiedExpr(id int64) Expr
+
+ isExprFactory()
+}
+
+type baseExprFactory struct{}
+
+// NewExprFactory creates an ExprFactory instance.
+func NewExprFactory() ExprFactory {
+ return &baseExprFactory{}
+}
+
+func (fac *baseExprFactory) NewCall(id int64, function string, args ...Expr) Expr {
+ if len(args) == 0 {
+ args = []Expr{}
+ }
+ return fac.newExpr(
+ id,
+ &baseCallExpr{
+ function: function,
+ target: nilExpr,
+ args: args,
+ isMember: false,
+ })
+}
+
+func (fac *baseExprFactory) NewMemberCall(id int64, function string, target Expr, args ...Expr) Expr {
+ if len(args) == 0 {
+ args = []Expr{}
+ }
+ return fac.newExpr(
+ id,
+ &baseCallExpr{
+ function: function,
+ target: target,
+ args: args,
+ isMember: true,
+ })
+}
+
+func (fac *baseExprFactory) NewComprehension(id int64, iterRange Expr, iterVar, accuVar string, accuInit, loopCond, loopStep, result Expr) Expr {
+ return fac.newExpr(
+ id,
+ &baseComprehensionExpr{
+ iterRange: iterRange,
+ iterVar: iterVar,
+ accuVar: accuVar,
+ accuInit: accuInit,
+ loopCond: loopCond,
+ loopStep: loopStep,
+ result: result,
+ })
+}
+
+func (fac *baseExprFactory) NewIdent(id int64, name string) Expr {
+ return fac.newExpr(id, baseIdentExpr(name))
+}
+
+func (fac *baseExprFactory) NewAccuIdent(id int64) Expr {
+ return fac.NewIdent(id, "__result__")
+}
+
+func (fac *baseExprFactory) NewLiteral(id int64, value ref.Val) Expr {
+ return fac.newExpr(id, &baseLiteral{Val: value})
+}
+
+func (fac *baseExprFactory) NewList(id int64, elems []Expr, optIndices []int32) Expr {
+ optIndexMap := make(map[int32]struct{}, len(optIndices))
+ for _, idx := range optIndices {
+ optIndexMap[idx] = struct{}{}
+ }
+ return fac.newExpr(id,
+ &baseListExpr{
+ elements: elems,
+ optIndices: optIndices,
+ optIndexMap: optIndexMap,
+ })
+}
+
+func (fac *baseExprFactory) NewMap(id int64, entries []EntryExpr) Expr {
+ return fac.newExpr(id, &baseMapExpr{entries: entries})
+}
+
+func (fac *baseExprFactory) NewMapEntry(id int64, key, value Expr, isOptional bool) EntryExpr {
+ return fac.newEntryExpr(
+ id,
+ &baseMapEntry{
+ key: key,
+ value: value,
+ isOptional: isOptional,
+ })
+}
+
+func (fac *baseExprFactory) NewPresenceTest(id int64, operand Expr, field string) Expr {
+ return fac.newExpr(
+ id,
+ &baseSelectExpr{
+ operand: operand,
+ field: field,
+ testOnly: true,
+ })
+}
+
+func (fac *baseExprFactory) NewSelect(id int64, operand Expr, field string) Expr {
+ return fac.newExpr(
+ id,
+ &baseSelectExpr{
+ operand: operand,
+ field: field,
+ })
+}
+
+func (fac *baseExprFactory) NewStruct(id int64, typeName string, fields []EntryExpr) Expr {
+ return fac.newExpr(
+ id,
+ &baseStructExpr{
+ typeName: typeName,
+ fields: fields,
+ })
+}
+
+func (fac *baseExprFactory) NewStructField(id int64, field string, value Expr, isOptional bool) EntryExpr {
+ return fac.newEntryExpr(
+ id,
+ &baseStructField{
+ field: field,
+ value: value,
+ isOptional: isOptional,
+ })
+}
+
+func (fac *baseExprFactory) NewUnspecifiedExpr(id int64) Expr {
+ return fac.newExpr(id, nil)
+}
+
+func (fac *baseExprFactory) CopyExpr(e Expr) Expr {
+ // unwrap navigable expressions to avoid unnecessary allocations during copying.
+ if nav, ok := e.(*navigableExprImpl); ok {
+ e = nav.Expr
+ }
+ switch e.Kind() {
+ case CallKind:
+ c := e.AsCall()
+ argsCopy := make([]Expr, len(c.Args()))
+ for i, arg := range c.Args() {
+ argsCopy[i] = fac.CopyExpr(arg)
+ }
+ if !c.IsMemberFunction() {
+ return fac.NewCall(e.ID(), c.FunctionName(), argsCopy...)
+ }
+ return fac.NewMemberCall(e.ID(), c.FunctionName(), fac.CopyExpr(c.Target()), argsCopy...)
+ case ComprehensionKind:
+ compre := e.AsComprehension()
+ return fac.NewComprehension(e.ID(),
+ fac.CopyExpr(compre.IterRange()),
+ compre.IterVar(),
+ compre.AccuVar(),
+ fac.CopyExpr(compre.AccuInit()),
+ fac.CopyExpr(compre.LoopCondition()),
+ fac.CopyExpr(compre.LoopStep()),
+ fac.CopyExpr(compre.Result()))
+ case IdentKind:
+ return fac.NewIdent(e.ID(), e.AsIdent())
+ case ListKind:
+ l := e.AsList()
+ elemsCopy := make([]Expr, l.Size())
+ for i, elem := range l.Elements() {
+ elemsCopy[i] = fac.CopyExpr(elem)
+ }
+ return fac.NewList(e.ID(), elemsCopy, l.OptionalIndices())
+ case LiteralKind:
+ return fac.NewLiteral(e.ID(), e.AsLiteral())
+ case MapKind:
+ m := e.AsMap()
+ entriesCopy := make([]EntryExpr, m.Size())
+ for i, entry := range m.Entries() {
+ entriesCopy[i] = fac.CopyEntryExpr(entry)
+ }
+ return fac.NewMap(e.ID(), entriesCopy)
+ case SelectKind:
+ s := e.AsSelect()
+ if s.IsTestOnly() {
+ return fac.NewPresenceTest(e.ID(), fac.CopyExpr(s.Operand()), s.FieldName())
+ }
+ return fac.NewSelect(e.ID(), fac.CopyExpr(s.Operand()), s.FieldName())
+ case StructKind:
+ s := e.AsStruct()
+ fieldsCopy := make([]EntryExpr, len(s.Fields()))
+ for i, field := range s.Fields() {
+ fieldsCopy[i] = fac.CopyEntryExpr(field)
+ }
+ return fac.NewStruct(e.ID(), s.TypeName(), fieldsCopy)
+ default:
+ return fac.NewUnspecifiedExpr(e.ID())
+ }
+}
+
+func (fac *baseExprFactory) CopyEntryExpr(e EntryExpr) EntryExpr {
+ switch e.Kind() {
+ case MapEntryKind:
+ entry := e.AsMapEntry()
+ return fac.NewMapEntry(e.ID(),
+ fac.CopyExpr(entry.Key()), fac.CopyExpr(entry.Value()), entry.IsOptional())
+ case StructFieldKind:
+ field := e.AsStructField()
+ return fac.NewStructField(e.ID(),
+ field.Name(), fac.CopyExpr(field.Value()), field.IsOptional())
+ default:
+ return fac.newEntryExpr(e.ID(), nil)
+ }
+}
+
+func (*baseExprFactory) isExprFactory() {}
+
+func (fac *baseExprFactory) newExpr(id int64, e exprKindCase) Expr {
+ return &expr{
+ id: id,
+ exprKindCase: e,
+ }
+}
+
+func (fac *baseExprFactory) newEntryExpr(id int64, e entryExprKindCase) EntryExpr {
+ return &entryExpr{
+ id: id,
+ entryExprKindCase: e,
+ }
+}
+
+var (
+ defaultFactory = &baseExprFactory{}
+)
diff --git a/vendor/github.com/google/cel-go/common/ast/navigable.go b/vendor/github.com/google/cel-go/common/ast/navigable.go
new file mode 100644
index 000000000000..f5ddf6aac666
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/ast/navigable.go
@@ -0,0 +1,652 @@
+// Copyright 2023 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package ast
+
+import (
+ "github.com/google/cel-go/common/types"
+ "github.com/google/cel-go/common/types/ref"
+)
+
+// NavigableExpr represents the base navigable expression value with methods to inspect the
+// parent and child expressions.
+type NavigableExpr interface {
+ Expr
+
+ // Type of the expression.
+ //
+ // If the expression is type-checked, the type check metadata is returned. If the expression
+ // has not been type-checked, the types.DynType value is returned.
+ Type() *types.Type
+
+ // Parent returns the parent expression node, if one exists.
+ Parent() (NavigableExpr, bool)
+
+ // Children returns a list of child expression nodes.
+ Children() []NavigableExpr
+
+ // Depth indicates the depth in the expression tree.
+ //
+ // The root expression has depth 0.
+ Depth() int
+}
+
+// NavigateAST converts an AST to a NavigableExpr
+func NavigateAST(ast *AST) NavigableExpr {
+ return NavigateExpr(ast, ast.Expr())
+}
+
+// NavigateExpr creates a NavigableExpr whose type information is backed by the input AST.
+//
+// If the expression is already a NavigableExpr, the parent and depth information will be
+// propagated on the new NavigableExpr value; otherwise, the expr value will be treated
+// as though it is the root of the expression graph with a depth of 0.
+func NavigateExpr(ast *AST, expr Expr) NavigableExpr {
+ depth := 0
+ var parent NavigableExpr = nil
+ if nav, ok := expr.(NavigableExpr); ok {
+ depth = nav.Depth()
+ parent, _ = nav.Parent()
+ }
+ return newNavigableExpr(ast, parent, expr, depth)
+}
+
+// ExprMatcher takes a NavigableExpr in and indicates whether the value is a match.
+//
+// This function type should be use with the `Match` and `MatchList` calls.
+type ExprMatcher func(NavigableExpr) bool
+
+// ConstantValueMatcher returns an ExprMatcher which will return true if the input NavigableExpr
+// is comprised of all constant values, such as a simple literal or even list and map literal.
+func ConstantValueMatcher() ExprMatcher {
+ return matchIsConstantValue
+}
+
+// KindMatcher returns an ExprMatcher which will return true if the input NavigableExpr.Kind() matches
+// the specified `kind`.
+func KindMatcher(kind ExprKind) ExprMatcher {
+ return func(e NavigableExpr) bool {
+ return e.Kind() == kind
+ }
+}
+
+// FunctionMatcher returns an ExprMatcher which will match NavigableExpr nodes of CallKind type whose
+// function name is equal to `funcName`.
+func FunctionMatcher(funcName string) ExprMatcher {
+ return func(e NavigableExpr) bool {
+ if e.Kind() != CallKind {
+ return false
+ }
+ return e.AsCall().FunctionName() == funcName
+ }
+}
+
+// AllMatcher returns true for all descendants of a NavigableExpr, effectively flattening them into a list.
+//
+// Such a result would work well with subsequent MatchList calls.
+func AllMatcher() ExprMatcher {
+ return func(NavigableExpr) bool {
+ return true
+ }
+}
+
+// MatchDescendants takes a NavigableExpr and ExprMatcher and produces a list of NavigableExpr values
+// matching the input criteria in post-order (bottom up).
+func MatchDescendants(expr NavigableExpr, matcher ExprMatcher) []NavigableExpr {
+ matches := []NavigableExpr{}
+ navVisitor := &baseVisitor{
+ visitExpr: func(e Expr) {
+ nav := e.(NavigableExpr)
+ if matcher(nav) {
+ matches = append(matches, nav)
+ }
+ },
+ }
+ visit(expr, navVisitor, postOrder, 0, 0)
+ return matches
+}
+
+// MatchSubset applies an ExprMatcher to a list of NavigableExpr values and their descendants, producing a
+// subset of NavigableExpr values which match.
+func MatchSubset(exprs []NavigableExpr, matcher ExprMatcher) []NavigableExpr {
+ matches := []NavigableExpr{}
+ navVisitor := &baseVisitor{
+ visitExpr: func(e Expr) {
+ nav := e.(NavigableExpr)
+ if matcher(nav) {
+ matches = append(matches, nav)
+ }
+ },
+ }
+ for _, expr := range exprs {
+ visit(expr, navVisitor, postOrder, 0, 1)
+ }
+ return matches
+}
+
+// Visitor defines an object for visiting Expr and EntryExpr nodes within an expression graph.
+type Visitor interface {
+ // VisitExpr visits the input expression.
+ VisitExpr(Expr)
+
+ // VisitEntryExpr visits the input entry expression, i.e. a struct field or map entry.
+ VisitEntryExpr(EntryExpr)
+}
+
+type baseVisitor struct {
+ visitExpr func(Expr)
+ visitEntryExpr func(EntryExpr)
+}
+
+// VisitExpr visits the Expr if the internal expr visitor has been configured.
+func (v *baseVisitor) VisitExpr(e Expr) {
+ if v.visitExpr != nil {
+ v.visitExpr(e)
+ }
+}
+
+// VisitEntryExpr visits the entry if the internal expr entry visitor has been configured.
+func (v *baseVisitor) VisitEntryExpr(e EntryExpr) {
+ if v.visitEntryExpr != nil {
+ v.visitEntryExpr(e)
+ }
+}
+
+// NewExprVisitor creates a visitor which only visits expression nodes.
+func NewExprVisitor(v func(Expr)) Visitor {
+ return &baseVisitor{
+ visitExpr: v,
+ visitEntryExpr: nil,
+ }
+}
+
+// PostOrderVisit walks the expression graph and calls the visitor in post-order (bottom-up).
+func PostOrderVisit(expr Expr, visitor Visitor) {
+ visit(expr, visitor, postOrder, 0, 0)
+}
+
+// PreOrderVisit walks the expression graph and calls the visitor in pre-order (top-down).
+func PreOrderVisit(expr Expr, visitor Visitor) {
+ visit(expr, visitor, preOrder, 0, 0)
+}
+
+type visitOrder int
+
+const (
+ preOrder = iota + 1
+ postOrder
+)
+
+// TODO: consider exposing a way to configure a limit for the max visit depth.
+// It's possible that we could want to configure this on the NewExprVisitor()
+// and through MatchDescendents() / MaxID().
+func visit(expr Expr, visitor Visitor, order visitOrder, depth, maxDepth int) {
+ if maxDepth > 0 && depth == maxDepth {
+ return
+ }
+ if order == preOrder {
+ visitor.VisitExpr(expr)
+ }
+ switch expr.Kind() {
+ case CallKind:
+ c := expr.AsCall()
+ if c.IsMemberFunction() {
+ visit(c.Target(), visitor, order, depth+1, maxDepth)
+ }
+ for _, arg := range c.Args() {
+ visit(arg, visitor, order, depth+1, maxDepth)
+ }
+ case ComprehensionKind:
+ c := expr.AsComprehension()
+ visit(c.IterRange(), visitor, order, depth+1, maxDepth)
+ visit(c.AccuInit(), visitor, order, depth+1, maxDepth)
+ visit(c.LoopCondition(), visitor, order, depth+1, maxDepth)
+ visit(c.LoopStep(), visitor, order, depth+1, maxDepth)
+ visit(c.Result(), visitor, order, depth+1, maxDepth)
+ case ListKind:
+ l := expr.AsList()
+ for _, elem := range l.Elements() {
+ visit(elem, visitor, order, depth+1, maxDepth)
+ }
+ case MapKind:
+ m := expr.AsMap()
+ for _, e := range m.Entries() {
+ if order == preOrder {
+ visitor.VisitEntryExpr(e)
+ }
+ entry := e.AsMapEntry()
+ visit(entry.Key(), visitor, order, depth+1, maxDepth)
+ visit(entry.Value(), visitor, order, depth+1, maxDepth)
+ if order == postOrder {
+ visitor.VisitEntryExpr(e)
+ }
+ }
+ case SelectKind:
+ visit(expr.AsSelect().Operand(), visitor, order, depth+1, maxDepth)
+ case StructKind:
+ s := expr.AsStruct()
+ for _, f := range s.Fields() {
+ visitor.VisitEntryExpr(f)
+ visit(f.AsStructField().Value(), visitor, order, depth+1, maxDepth)
+ }
+ }
+ if order == postOrder {
+ visitor.VisitExpr(expr)
+ }
+}
+
+func matchIsConstantValue(e NavigableExpr) bool {
+ if e.Kind() == LiteralKind {
+ return true
+ }
+ if e.Kind() == StructKind || e.Kind() == MapKind || e.Kind() == ListKind {
+ for _, child := range e.Children() {
+ if !matchIsConstantValue(child) {
+ return false
+ }
+ }
+ return true
+ }
+ return false
+}
+
+func newNavigableExpr(ast *AST, parent NavigableExpr, expr Expr, depth int) NavigableExpr {
+ // Reduce navigable expression nesting by unwrapping the embedded Expr value.
+ if nav, ok := expr.(*navigableExprImpl); ok {
+ expr = nav.Expr
+ }
+ nav := &navigableExprImpl{
+ Expr: expr,
+ depth: depth,
+ ast: ast,
+ parent: parent,
+ createChildren: getChildFactory(expr),
+ }
+ return nav
+}
+
+type navigableExprImpl struct {
+ Expr
+ depth int
+ ast *AST
+ parent NavigableExpr
+ createChildren childFactory
+}
+
+func (nav *navigableExprImpl) Parent() (NavigableExpr, bool) {
+ if nav.parent != nil {
+ return nav.parent, true
+ }
+ return nil, false
+}
+
+func (nav *navigableExprImpl) ID() int64 {
+ return nav.Expr.ID()
+}
+
+func (nav *navigableExprImpl) Kind() ExprKind {
+ return nav.Expr.Kind()
+}
+
+func (nav *navigableExprImpl) Type() *types.Type {
+ return nav.ast.GetType(nav.ID())
+}
+
+func (nav *navigableExprImpl) Children() []NavigableExpr {
+ return nav.createChildren(nav)
+}
+
+func (nav *navigableExprImpl) Depth() int {
+ return nav.depth
+}
+
+func (nav *navigableExprImpl) AsCall() CallExpr {
+ return navigableCallImpl{navigableExprImpl: nav}
+}
+
+func (nav *navigableExprImpl) AsComprehension() ComprehensionExpr {
+ return navigableComprehensionImpl{navigableExprImpl: nav}
+}
+
+func (nav *navigableExprImpl) AsIdent() string {
+ return nav.Expr.AsIdent()
+}
+
+func (nav *navigableExprImpl) AsList() ListExpr {
+ return navigableListImpl{navigableExprImpl: nav}
+}
+
+func (nav *navigableExprImpl) AsLiteral() ref.Val {
+ return nav.Expr.AsLiteral()
+}
+
+func (nav *navigableExprImpl) AsMap() MapExpr {
+ return navigableMapImpl{navigableExprImpl: nav}
+}
+
+func (nav *navigableExprImpl) AsSelect() SelectExpr {
+ return navigableSelectImpl{navigableExprImpl: nav}
+}
+
+func (nav *navigableExprImpl) AsStruct() StructExpr {
+ return navigableStructImpl{navigableExprImpl: nav}
+}
+
+func (nav *navigableExprImpl) createChild(e Expr) NavigableExpr {
+ return newNavigableExpr(nav.ast, nav, e, nav.depth+1)
+}
+
+func (nav *navigableExprImpl) isExpr() {}
+
+type navigableCallImpl struct {
+ *navigableExprImpl
+}
+
+func (call navigableCallImpl) FunctionName() string {
+ return call.Expr.AsCall().FunctionName()
+}
+
+func (call navigableCallImpl) IsMemberFunction() bool {
+ return call.Expr.AsCall().IsMemberFunction()
+}
+
+func (call navigableCallImpl) Target() Expr {
+ t := call.Expr.AsCall().Target()
+ if t != nil {
+ return call.createChild(t)
+ }
+ return nil
+}
+
+func (call navigableCallImpl) Args() []Expr {
+ args := call.Expr.AsCall().Args()
+ navArgs := make([]Expr, len(args))
+ for i, a := range args {
+ navArgs[i] = call.createChild(a)
+ }
+ return navArgs
+}
+
+type navigableComprehensionImpl struct {
+ *navigableExprImpl
+}
+
+func (comp navigableComprehensionImpl) IterRange() Expr {
+ return comp.createChild(comp.Expr.AsComprehension().IterRange())
+}
+
+func (comp navigableComprehensionImpl) IterVar() string {
+ return comp.Expr.AsComprehension().IterVar()
+}
+
+func (comp navigableComprehensionImpl) AccuVar() string {
+ return comp.Expr.AsComprehension().AccuVar()
+}
+
+func (comp navigableComprehensionImpl) AccuInit() Expr {
+ return comp.createChild(comp.Expr.AsComprehension().AccuInit())
+}
+
+func (comp navigableComprehensionImpl) LoopCondition() Expr {
+ return comp.createChild(comp.Expr.AsComprehension().LoopCondition())
+}
+
+func (comp navigableComprehensionImpl) LoopStep() Expr {
+ return comp.createChild(comp.Expr.AsComprehension().LoopStep())
+}
+
+func (comp navigableComprehensionImpl) Result() Expr {
+ return comp.createChild(comp.Expr.AsComprehension().Result())
+}
+
+type navigableListImpl struct {
+ *navigableExprImpl
+}
+
+func (l navigableListImpl) Elements() []Expr {
+ pbElems := l.Expr.AsList().Elements()
+ elems := make([]Expr, len(pbElems))
+ for i := 0; i < len(pbElems); i++ {
+ elems[i] = l.createChild(pbElems[i])
+ }
+ return elems
+}
+
+func (l navigableListImpl) IsOptional(index int32) bool {
+ return l.Expr.AsList().IsOptional(index)
+}
+
+func (l navigableListImpl) OptionalIndices() []int32 {
+ return l.Expr.AsList().OptionalIndices()
+}
+
+func (l navigableListImpl) Size() int {
+ return l.Expr.AsList().Size()
+}
+
+type navigableMapImpl struct {
+ *navigableExprImpl
+}
+
+func (m navigableMapImpl) Entries() []EntryExpr {
+ mapExpr := m.Expr.AsMap()
+ entries := make([]EntryExpr, len(mapExpr.Entries()))
+ for i, e := range mapExpr.Entries() {
+ entry := e.AsMapEntry()
+ entries[i] = &entryExpr{
+ id: e.ID(),
+ entryExprKindCase: navigableEntryImpl{
+ key: m.createChild(entry.Key()),
+ val: m.createChild(entry.Value()),
+ isOpt: entry.IsOptional(),
+ },
+ }
+ }
+ return entries
+}
+
+func (m navigableMapImpl) Size() int {
+ return m.Expr.AsMap().Size()
+}
+
+type navigableEntryImpl struct {
+ key NavigableExpr
+ val NavigableExpr
+ isOpt bool
+}
+
+func (e navigableEntryImpl) Kind() EntryExprKind {
+ return MapEntryKind
+}
+
+func (e navigableEntryImpl) Key() Expr {
+ return e.key
+}
+
+func (e navigableEntryImpl) Value() Expr {
+ return e.val
+}
+
+func (e navigableEntryImpl) IsOptional() bool {
+ return e.isOpt
+}
+
+func (e navigableEntryImpl) renumberIDs(IDGenerator) {}
+
+func (e navigableEntryImpl) isEntryExpr() {}
+
+type navigableSelectImpl struct {
+ *navigableExprImpl
+}
+
+func (sel navigableSelectImpl) FieldName() string {
+ return sel.Expr.AsSelect().FieldName()
+}
+
+func (sel navigableSelectImpl) IsTestOnly() bool {
+ return sel.Expr.AsSelect().IsTestOnly()
+}
+
+func (sel navigableSelectImpl) Operand() Expr {
+ return sel.createChild(sel.Expr.AsSelect().Operand())
+}
+
+type navigableStructImpl struct {
+ *navigableExprImpl
+}
+
+func (s navigableStructImpl) TypeName() string {
+ return s.Expr.AsStruct().TypeName()
+}
+
+func (s navigableStructImpl) Fields() []EntryExpr {
+ fieldInits := s.Expr.AsStruct().Fields()
+ fields := make([]EntryExpr, len(fieldInits))
+ for i, f := range fieldInits {
+ field := f.AsStructField()
+ fields[i] = &entryExpr{
+ id: f.ID(),
+ entryExprKindCase: navigableFieldImpl{
+ name: field.Name(),
+ val: s.createChild(field.Value()),
+ isOpt: field.IsOptional(),
+ },
+ }
+ }
+ return fields
+}
+
+type navigableFieldImpl struct {
+ name string
+ val NavigableExpr
+ isOpt bool
+}
+
+func (f navigableFieldImpl) Kind() EntryExprKind {
+ return StructFieldKind
+}
+
+func (f navigableFieldImpl) Name() string {
+ return f.name
+}
+
+func (f navigableFieldImpl) Value() Expr {
+ return f.val
+}
+
+func (f navigableFieldImpl) IsOptional() bool {
+ return f.isOpt
+}
+
+func (f navigableFieldImpl) renumberIDs(IDGenerator) {}
+
+func (f navigableFieldImpl) isEntryExpr() {}
+
+func getChildFactory(expr Expr) childFactory {
+ if expr == nil {
+ return noopFactory
+ }
+ switch expr.Kind() {
+ case LiteralKind:
+ return noopFactory
+ case IdentKind:
+ return noopFactory
+ case SelectKind:
+ return selectFactory
+ case CallKind:
+ return callArgFactory
+ case ListKind:
+ return listElemFactory
+ case MapKind:
+ return mapEntryFactory
+ case StructKind:
+ return structEntryFactory
+ case ComprehensionKind:
+ return comprehensionFactory
+ default:
+ return noopFactory
+ }
+}
+
+type childFactory func(*navigableExprImpl) []NavigableExpr
+
+func noopFactory(*navigableExprImpl) []NavigableExpr {
+ return nil
+}
+
+func selectFactory(nav *navigableExprImpl) []NavigableExpr {
+ return []NavigableExpr{nav.createChild(nav.AsSelect().Operand())}
+}
+
+func callArgFactory(nav *navigableExprImpl) []NavigableExpr {
+ call := nav.Expr.AsCall()
+ argCount := len(call.Args())
+ if call.IsMemberFunction() {
+ argCount++
+ }
+ navExprs := make([]NavigableExpr, argCount)
+ i := 0
+ if call.IsMemberFunction() {
+ navExprs[i] = nav.createChild(call.Target())
+ i++
+ }
+ for _, arg := range call.Args() {
+ navExprs[i] = nav.createChild(arg)
+ i++
+ }
+ return navExprs
+}
+
+func listElemFactory(nav *navigableExprImpl) []NavigableExpr {
+ l := nav.Expr.AsList()
+ navExprs := make([]NavigableExpr, len(l.Elements()))
+ for i, e := range l.Elements() {
+ navExprs[i] = nav.createChild(e)
+ }
+ return navExprs
+}
+
+func structEntryFactory(nav *navigableExprImpl) []NavigableExpr {
+ s := nav.Expr.AsStruct()
+ entries := make([]NavigableExpr, len(s.Fields()))
+ for i, e := range s.Fields() {
+ f := e.AsStructField()
+ entries[i] = nav.createChild(f.Value())
+ }
+ return entries
+}
+
+func mapEntryFactory(nav *navigableExprImpl) []NavigableExpr {
+ m := nav.Expr.AsMap()
+ entries := make([]NavigableExpr, len(m.Entries())*2)
+ j := 0
+ for _, e := range m.Entries() {
+ mapEntry := e.AsMapEntry()
+ entries[j] = nav.createChild(mapEntry.Key())
+ entries[j+1] = nav.createChild(mapEntry.Value())
+ j += 2
+ }
+ return entries
+}
+
+func comprehensionFactory(nav *navigableExprImpl) []NavigableExpr {
+ compre := nav.Expr.AsComprehension()
+ return []NavigableExpr{
+ nav.createChild(compre.IterRange()),
+ nav.createChild(compre.AccuInit()),
+ nav.createChild(compre.LoopCondition()),
+ nav.createChild(compre.LoopStep()),
+ nav.createChild(compre.Result()),
+ }
+}
diff --git a/vendor/github.com/google/cel-go/common/containers/BUILD.bazel b/vendor/github.com/google/cel-go/common/containers/BUILD.bazel
new file mode 100644
index 000000000000..b2cf20fdb9db
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/containers/BUILD.bazel
@@ -0,0 +1,16 @@
+load("@io_bazel_rules_go//go:def.bzl", "go_library")
+
+package(
+ default_visibility = ["//visibility:public"],
+ licenses = ["notice"], # Apache 2.0
+)
+
+go_library(
+ name = "go_default_library",
+ srcs = ["container.go"],
+ importmap = "kubevirt.io/kubevirt/vendor/github.com/google/cel-go/common/containers",
+ importpath = "github.com/google/cel-go/common/containers",
+ deps = [
+ "//vendor/github.com/google/cel-go/common/ast:go_default_library",
+ ],
+)
diff --git a/vendor/github.com/google/cel-go/common/containers/container.go b/vendor/github.com/google/cel-go/common/containers/container.go
new file mode 100644
index 000000000000..52153d4cd18b
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/containers/container.go
@@ -0,0 +1,316 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+// Package containers defines types and functions for resolving qualified names within a namespace
+// or type provided to CEL.
+package containers
+
+import (
+ "fmt"
+ "strings"
+
+ "github.com/google/cel-go/common/ast"
+)
+
+var (
+ // DefaultContainer has an empty container name.
+ DefaultContainer *Container = nil
+
+ // Empty map to search for aliases when needed.
+ noAliases = make(map[string]string)
+)
+
+// NewContainer creates a new Container with the fully-qualified name.
+func NewContainer(opts ...ContainerOption) (*Container, error) {
+ var c *Container
+ var err error
+ for _, opt := range opts {
+ c, err = opt(c)
+ if err != nil {
+ return nil, err
+ }
+ }
+ return c, nil
+}
+
+// Container holds a reference to an optional qualified container name and set of aliases.
+//
+// The program container can be used to simplify variable, function, and type specification within
+// CEL programs and behaves more or less like a C++ namespace. See ResolveCandidateNames for more
+// details.
+type Container struct {
+ name string
+ aliases map[string]string
+}
+
+// Extend creates a new Container with the existing settings and applies a series of
+// ContainerOptions to further configure the new container.
+func (c *Container) Extend(opts ...ContainerOption) (*Container, error) {
+ if c == nil {
+ return NewContainer(opts...)
+ }
+ // Copy the name and aliases of the existing container.
+ ext := &Container{name: c.Name()}
+ if len(c.aliasSet()) > 0 {
+ aliasSet := make(map[string]string, len(c.aliasSet()))
+ for k, v := range c.aliasSet() {
+ aliasSet[k] = v
+ }
+ ext.aliases = aliasSet
+ }
+ // Apply the new options to the container.
+ var err error
+ for _, opt := range opts {
+ ext, err = opt(ext)
+ if err != nil {
+ return nil, err
+ }
+ }
+ return ext, nil
+}
+
+// Name returns the fully-qualified name of the container.
+//
+// The name may conceptually be a namespace, package, or type.
+func (c *Container) Name() string {
+ if c == nil {
+ return ""
+ }
+ return c.name
+}
+
+// ResolveCandidateNames returns the candidates name of namespaced identifiers in C++ resolution
+// order.
+//
+// Names which shadow other names are returned first. If a name includes a leading dot ('.'),
+// the name is treated as an absolute identifier which cannot be shadowed.
+//
+// Given a container name a.b.c.M.N and a type name R.s, this will deliver in order:
+//
+// a.b.c.M.N.R.s
+// a.b.c.M.R.s
+// a.b.c.R.s
+// a.b.R.s
+// a.R.s
+// R.s
+//
+// If aliases or abbreviations are configured for the container, then alias names will take
+// precedence over containerized names.
+func (c *Container) ResolveCandidateNames(name string) []string {
+ if strings.HasPrefix(name, ".") {
+ qn := name[1:]
+ alias, isAlias := c.findAlias(qn)
+ if isAlias {
+ return []string{alias}
+ }
+ return []string{qn}
+ }
+ alias, isAlias := c.findAlias(name)
+ if isAlias {
+ return []string{alias}
+ }
+ if c.Name() == "" {
+ return []string{name}
+ }
+ nextCont := c.Name()
+ candidates := []string{nextCont + "." + name}
+ for i := strings.LastIndex(nextCont, "."); i >= 0; i = strings.LastIndex(nextCont, ".") {
+ nextCont = nextCont[:i]
+ candidates = append(candidates, nextCont+"."+name)
+ }
+ return append(candidates, name)
+}
+
+// aliasSet returns the alias to fully-qualified name mapping stored in the container.
+func (c *Container) aliasSet() map[string]string {
+ if c == nil || c.aliases == nil {
+ return noAliases
+ }
+ return c.aliases
+}
+
+// findAlias takes a name as input and returns an alias expansion if one exists.
+//
+// If the name is qualified, the first component of the qualified name is checked against known
+// aliases. Any alias that is found in a qualified name is expanded in the result:
+//
+// alias: R -> my.alias.R
+// name: R.S.T
+// output: my.alias.R.S.T
+//
+// Note, the name must not have a leading dot.
+func (c *Container) findAlias(name string) (string, bool) {
+ // If an alias exists for the name, ensure it is searched last.
+ simple := name
+ qualifier := ""
+ dot := strings.Index(name, ".")
+ if dot >= 0 {
+ simple = name[0:dot]
+ qualifier = name[dot:]
+ }
+ alias, found := c.aliasSet()[simple]
+ if !found {
+ return "", false
+ }
+ return alias + qualifier, true
+}
+
+// ContainerOption specifies a functional configuration option for a Container.
+//
+// Note, ContainerOption implementations must be able to handle nil container inputs.
+type ContainerOption func(*Container) (*Container, error)
+
+// Abbrevs configures a set of simple names as abbreviations for fully-qualified names.
+//
+// An abbreviation (abbrev for short) is a simple name that expands to a fully-qualified name.
+// Abbreviations can be useful when working with variables, functions, and especially types from
+// multiple namespaces:
+//
+// // CEL object construction
+// qual.pkg.version.ObjTypeName{
+// field: alt.container.ver.FieldTypeName{value: ...}
+// }
+//
+// Only one the qualified names above may be used as the CEL container, so at least one of these
+// references must be a long qualified name within an otherwise short CEL program. Using the
+// following abbreviations, the program becomes much simpler:
+//
+// // CEL Go option
+// Abbrevs("qual.pkg.version.ObjTypeName", "alt.container.ver.FieldTypeName")
+// // Simplified Object construction
+// ObjTypeName{field: FieldTypeName{value: ...}}
+//
+// There are a few rules for the qualified names and the simple abbreviations generated from them:
+// - Qualified names must be dot-delimited, e.g. `package.subpkg.name`.
+// - The last element in the qualified name is the abbreviation.
+// - Abbreviations must not collide with each other.
+// - The abbreviation must not collide with unqualified names in use.
+//
+// Abbreviations are distinct from container-based references in the following important ways:
+// - Abbreviations must expand to a fully-qualified name.
+// - Expanded abbreviations do not participate in namespace resolution.
+// - Abbreviation expansion is done instead of the container search for a matching identifier.
+// - Containers follow C++ namespace resolution rules with searches from the most qualified name
+// to the least qualified name.
+// - Container references within the CEL program may be relative, and are resolved to fully
+// qualified names at either type-check time or program plan time, whichever comes first.
+//
+// If there is ever a case where an identifier could be in both the container and as an
+// abbreviation, the abbreviation wins as this will ensure that the meaning of a program is
+// preserved between compilations even as the container evolves.
+func Abbrevs(qualifiedNames ...string) ContainerOption {
+ return func(c *Container) (*Container, error) {
+ for _, qn := range qualifiedNames {
+ ind := strings.LastIndex(qn, ".")
+ if ind <= 0 || ind >= len(qn)-1 {
+ return nil, fmt.Errorf(
+ "invalid qualified name: %s, wanted name of the form 'qualified.name'", qn)
+ }
+ alias := qn[ind+1:]
+ var err error
+ c, err = aliasAs("abbreviation", qn, alias)(c)
+ if err != nil {
+ return nil, err
+ }
+ }
+ return c, nil
+ }
+}
+
+// Alias associates a fully-qualified name with a user-defined alias.
+//
+// In general, Abbrevs is preferred to Alias since the names generated from the Abbrevs option
+// are more easily traced back to source code. The Alias option is useful for propagating alias
+// configuration from one Container instance to another, and may also be useful for remapping
+// poorly chosen protobuf message / package names.
+//
+// Note: all of the rules that apply to Abbrevs also apply to Alias.
+func Alias(qualifiedName, alias string) ContainerOption {
+ return aliasAs("alias", qualifiedName, alias)
+}
+
+func aliasAs(kind, qualifiedName, alias string) ContainerOption {
+ return func(c *Container) (*Container, error) {
+ if len(alias) == 0 || strings.Contains(alias, ".") {
+ return nil, fmt.Errorf(
+ "%s must be non-empty and simple (not qualified): %s=%s", kind, kind, alias)
+ }
+
+ if qualifiedName[0:1] == "." {
+ return nil, fmt.Errorf("qualified name must not begin with a leading '.': %s",
+ qualifiedName)
+ }
+ ind := strings.LastIndex(qualifiedName, ".")
+ if ind <= 0 || ind == len(qualifiedName)-1 {
+ return nil, fmt.Errorf("%s must refer to a valid qualified name: %s",
+ kind, qualifiedName)
+ }
+ aliasRef, found := c.aliasSet()[alias]
+ if found {
+ return nil, fmt.Errorf(
+ "%s collides with existing reference: name=%s, %s=%s, existing=%s",
+ kind, qualifiedName, kind, alias, aliasRef)
+ }
+ if strings.HasPrefix(c.Name(), alias+".") || c.Name() == alias {
+ return nil, fmt.Errorf(
+ "%s collides with container name: name=%s, %s=%s, container=%s",
+ kind, qualifiedName, kind, alias, c.Name())
+ }
+ if c == nil {
+ c = &Container{}
+ }
+ if c.aliases == nil {
+ c.aliases = make(map[string]string)
+ }
+ c.aliases[alias] = qualifiedName
+ return c, nil
+ }
+}
+
+// Name sets the fully-qualified name of the Container.
+func Name(name string) ContainerOption {
+ return func(c *Container) (*Container, error) {
+ if len(name) > 0 && name[0:1] == "." {
+ return nil, fmt.Errorf("container name must not contain a leading '.': %s", name)
+ }
+ if c.Name() == name {
+ return c, nil
+ }
+ if c == nil {
+ return &Container{name: name}, nil
+ }
+ c.name = name
+ return c, nil
+ }
+}
+
+// ToQualifiedName converts an expression AST into a qualified name if possible, with a boolean
+// 'found' value that indicates if the conversion is successful.
+func ToQualifiedName(e ast.Expr) (string, bool) {
+ switch e.Kind() {
+ case ast.IdentKind:
+ id := e.AsIdent()
+ return id, true
+ case ast.SelectKind:
+ sel := e.AsSelect()
+ // Test only expressions are not valid as qualified names.
+ if sel.IsTestOnly() {
+ return "", false
+ }
+ if qual, found := ToQualifiedName(sel.Operand()); found {
+ return qual + "." + sel.FieldName(), true
+ }
+ }
+ return "", false
+}
diff --git a/vendor/github.com/google/cel-go/common/cost.go b/vendor/github.com/google/cel-go/common/cost.go
new file mode 100644
index 000000000000..5e24bd0f47a0
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/cost.go
@@ -0,0 +1,40 @@
+// Copyright 2022 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package common
+
+const (
+ // SelectAndIdentCost is the cost of an operation that accesses an identifier or performs a select.
+ SelectAndIdentCost = 1
+
+ // ConstCost is the cost of an operation that accesses a constant.
+ ConstCost = 0
+
+ // ListCreateBaseCost is the base cost of any operation that creates a new list.
+ ListCreateBaseCost = 10
+
+ // MapCreateBaseCost is the base cost of any operation that creates a new map.
+ MapCreateBaseCost = 30
+
+ // StructCreateBaseCost is the base cost of any operation that creates a new struct.
+ StructCreateBaseCost = 40
+
+ // StringTraversalCostFactor is multiplied to a length of a string when computing the cost of traversing the entire
+ // string once.
+ StringTraversalCostFactor = 0.1
+
+ // RegexStringLengthCostFactor is multiplied ot the length of a regex string pattern when computing the cost of
+ // applying the regex to a string of unit cost.
+ RegexStringLengthCostFactor = 0.25
+)
diff --git a/vendor/github.com/google/cel-go/common/debug/BUILD.bazel b/vendor/github.com/google/cel-go/common/debug/BUILD.bazel
new file mode 100644
index 000000000000..7c152fdbfd52
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/debug/BUILD.bazel
@@ -0,0 +1,18 @@
+load("@io_bazel_rules_go//go:def.bzl", "go_library")
+
+package(
+ default_visibility = ["//visibility:public"],
+ licenses = ["notice"], # Apache 2.0
+)
+
+go_library(
+ name = "go_default_library",
+ srcs = ["debug.go"],
+ importmap = "kubevirt.io/kubevirt/vendor/github.com/google/cel-go/common/debug",
+ importpath = "github.com/google/cel-go/common/debug",
+ deps = [
+ "//vendor/github.com/google/cel-go/common/ast:go_default_library",
+ "//vendor/github.com/google/cel-go/common/types:go_default_library",
+ "//vendor/github.com/google/cel-go/common/types/ref:go_default_library",
+ ],
+)
diff --git a/vendor/github.com/google/cel-go/common/debug/debug.go b/vendor/github.com/google/cel-go/common/debug/debug.go
new file mode 100644
index 000000000000..e4c01ac6ed2b
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/debug/debug.go
@@ -0,0 +1,309 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+// Package debug provides tools to print a parsed expression graph and
+// adorn each expression element with additional metadata.
+package debug
+
+import (
+ "bytes"
+ "fmt"
+ "strconv"
+ "strings"
+
+ "github.com/google/cel-go/common/ast"
+ "github.com/google/cel-go/common/types"
+ "github.com/google/cel-go/common/types/ref"
+)
+
+// Adorner returns debug metadata that will be tacked on to the string
+// representation of an expression.
+type Adorner interface {
+ // GetMetadata for the input context.
+ GetMetadata(ctx any) string
+}
+
+// Writer manages writing expressions to an internal string.
+type Writer interface {
+ fmt.Stringer
+
+ // Buffer pushes an expression into an internal queue of expressions to
+ // write to a string.
+ Buffer(e ast.Expr)
+}
+
+type emptyDebugAdorner struct {
+}
+
+var emptyAdorner Adorner = &emptyDebugAdorner{}
+
+func (a *emptyDebugAdorner) GetMetadata(e any) string {
+ return ""
+}
+
+// ToDebugString gives the unadorned string representation of the Expr.
+func ToDebugString(e ast.Expr) string {
+ return ToAdornedDebugString(e, emptyAdorner)
+}
+
+// ToAdornedDebugString gives the adorned string representation of the Expr.
+func ToAdornedDebugString(e ast.Expr, adorner Adorner) string {
+ w := newDebugWriter(adorner)
+ w.Buffer(e)
+ return w.String()
+}
+
+// debugWriter is used to print out pretty-printed debug strings.
+type debugWriter struct {
+ adorner Adorner
+ buffer bytes.Buffer
+ indent int
+ lineStart bool
+}
+
+func newDebugWriter(a Adorner) *debugWriter {
+ return &debugWriter{
+ adorner: a,
+ indent: 0,
+ lineStart: true,
+ }
+}
+
+func (w *debugWriter) Buffer(e ast.Expr) {
+ if e == nil {
+ return
+ }
+ switch e.Kind() {
+ case ast.LiteralKind:
+ w.append(formatLiteral(e.AsLiteral()))
+ case ast.IdentKind:
+ w.append(e.AsIdent())
+ case ast.SelectKind:
+ w.appendSelect(e.AsSelect())
+ case ast.CallKind:
+ w.appendCall(e.AsCall())
+ case ast.ListKind:
+ w.appendList(e.AsList())
+ case ast.MapKind:
+ w.appendMap(e.AsMap())
+ case ast.StructKind:
+ w.appendStruct(e.AsStruct())
+ case ast.ComprehensionKind:
+ w.appendComprehension(e.AsComprehension())
+ }
+ w.adorn(e)
+}
+
+func (w *debugWriter) appendSelect(sel ast.SelectExpr) {
+ w.Buffer(sel.Operand())
+ w.append(".")
+ w.append(sel.FieldName())
+ if sel.IsTestOnly() {
+ w.append("~test-only~")
+ }
+}
+
+func (w *debugWriter) appendCall(call ast.CallExpr) {
+ if call.IsMemberFunction() {
+ w.Buffer(call.Target())
+ w.append(".")
+ }
+ w.append(call.FunctionName())
+ w.append("(")
+ if len(call.Args()) > 0 {
+ w.addIndent()
+ w.appendLine()
+ for i, arg := range call.Args() {
+ if i > 0 {
+ w.append(",")
+ w.appendLine()
+ }
+ w.Buffer(arg)
+ }
+ w.removeIndent()
+ w.appendLine()
+ }
+ w.append(")")
+}
+
+func (w *debugWriter) appendList(list ast.ListExpr) {
+ w.append("[")
+ if len(list.Elements()) > 0 {
+ w.appendLine()
+ w.addIndent()
+ for i, elem := range list.Elements() {
+ if i > 0 {
+ w.append(",")
+ w.appendLine()
+ }
+ w.Buffer(elem)
+ }
+ w.removeIndent()
+ w.appendLine()
+ }
+ w.append("]")
+}
+
+func (w *debugWriter) appendStruct(obj ast.StructExpr) {
+ w.append(obj.TypeName())
+ w.append("{")
+ if len(obj.Fields()) > 0 {
+ w.appendLine()
+ w.addIndent()
+ for i, f := range obj.Fields() {
+ field := f.AsStructField()
+ if i > 0 {
+ w.append(",")
+ w.appendLine()
+ }
+ if field.IsOptional() {
+ w.append("?")
+ }
+ w.append(field.Name())
+ w.append(":")
+ w.Buffer(field.Value())
+ w.adorn(f)
+ }
+ w.removeIndent()
+ w.appendLine()
+ }
+ w.append("}")
+}
+
+func (w *debugWriter) appendMap(m ast.MapExpr) {
+ w.append("{")
+ if m.Size() > 0 {
+ w.appendLine()
+ w.addIndent()
+ for i, e := range m.Entries() {
+ entry := e.AsMapEntry()
+ if i > 0 {
+ w.append(",")
+ w.appendLine()
+ }
+ if entry.IsOptional() {
+ w.append("?")
+ }
+ w.Buffer(entry.Key())
+ w.append(":")
+ w.Buffer(entry.Value())
+ w.adorn(e)
+ }
+ w.removeIndent()
+ w.appendLine()
+ }
+ w.append("}")
+}
+
+func (w *debugWriter) appendComprehension(comprehension ast.ComprehensionExpr) {
+ w.append("__comprehension__(")
+ w.addIndent()
+ w.appendLine()
+ w.append("// Variable")
+ w.appendLine()
+ w.append(comprehension.IterVar())
+ w.append(",")
+ w.appendLine()
+ w.append("// Target")
+ w.appendLine()
+ w.Buffer(comprehension.IterRange())
+ w.append(",")
+ w.appendLine()
+ w.append("// Accumulator")
+ w.appendLine()
+ w.append(comprehension.AccuVar())
+ w.append(",")
+ w.appendLine()
+ w.append("// Init")
+ w.appendLine()
+ w.Buffer(comprehension.AccuInit())
+ w.append(",")
+ w.appendLine()
+ w.append("// LoopCondition")
+ w.appendLine()
+ w.Buffer(comprehension.LoopCondition())
+ w.append(",")
+ w.appendLine()
+ w.append("// LoopStep")
+ w.appendLine()
+ w.Buffer(comprehension.LoopStep())
+ w.append(",")
+ w.appendLine()
+ w.append("// Result")
+ w.appendLine()
+ w.Buffer(comprehension.Result())
+ w.append(")")
+ w.removeIndent()
+}
+
+func formatLiteral(c ref.Val) string {
+ switch v := c.(type) {
+ case types.Bool:
+ return fmt.Sprintf("%t", v)
+ case types.Bytes:
+ return fmt.Sprintf("b\"%s\"", string(v))
+ case types.Double:
+ return fmt.Sprintf("%v", float64(v))
+ case types.Int:
+ return fmt.Sprintf("%d", int64(v))
+ case types.String:
+ return strconv.Quote(string(v))
+ case types.Uint:
+ return fmt.Sprintf("%du", uint64(v))
+ case types.Null:
+ return "null"
+ default:
+ panic("Unknown constant type")
+ }
+}
+
+func (w *debugWriter) append(s string) {
+ w.doIndent()
+ w.buffer.WriteString(s)
+}
+
+func (w *debugWriter) appendFormat(f string, args ...any) {
+ w.append(fmt.Sprintf(f, args...))
+}
+
+func (w *debugWriter) doIndent() {
+ if w.lineStart {
+ w.lineStart = false
+ w.buffer.WriteString(strings.Repeat(" ", w.indent))
+ }
+}
+
+func (w *debugWriter) adorn(e any) {
+ w.append(w.adorner.GetMetadata(e))
+}
+
+func (w *debugWriter) appendLine() {
+ w.buffer.WriteString("\n")
+ w.lineStart = true
+}
+
+func (w *debugWriter) addIndent() {
+ w.indent++
+}
+
+func (w *debugWriter) removeIndent() {
+ w.indent--
+ if w.indent < 0 {
+ panic("negative indent")
+ }
+}
+
+func (w *debugWriter) String() string {
+ return w.buffer.String()
+}
diff --git a/vendor/github.com/google/cel-go/common/decls/BUILD.bazel b/vendor/github.com/google/cel-go/common/decls/BUILD.bazel
new file mode 100644
index 000000000000..d99f32c6122b
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/decls/BUILD.bazel
@@ -0,0 +1,20 @@
+load("@io_bazel_rules_go//go:def.bzl", "go_library")
+
+package(
+ default_visibility = ["//visibility:public"],
+ licenses = ["notice"], # Apache 2.0
+)
+
+go_library(
+ name = "go_default_library",
+ srcs = ["decls.go"],
+ importmap = "kubevirt.io/kubevirt/vendor/github.com/google/cel-go/common/decls",
+ importpath = "github.com/google/cel-go/common/decls",
+ deps = [
+ "//vendor/github.com/google/cel-go/checker/decls:go_default_library",
+ "//vendor/github.com/google/cel-go/common/functions:go_default_library",
+ "//vendor/github.com/google/cel-go/common/types:go_default_library",
+ "//vendor/github.com/google/cel-go/common/types/ref:go_default_library",
+ "//vendor/google.golang.org/genproto/googleapis/api/expr/v1alpha1:go_default_library",
+ ],
+)
diff --git a/vendor/github.com/google/cel-go/common/decls/decls.go b/vendor/github.com/google/cel-go/common/decls/decls.go
new file mode 100644
index 000000000000..0a42f81d404e
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/decls/decls.go
@@ -0,0 +1,846 @@
+// Copyright 2023 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+// Package decls contains function and variable declaration structs and helper methods.
+package decls
+
+import (
+ "fmt"
+ "strings"
+
+ chkdecls "github.com/google/cel-go/checker/decls"
+ "github.com/google/cel-go/common/functions"
+ "github.com/google/cel-go/common/types"
+ "github.com/google/cel-go/common/types/ref"
+
+ exprpb "google.golang.org/genproto/googleapis/api/expr/v1alpha1"
+)
+
+// NewFunction creates a new function declaration with a set of function options to configure overloads
+// and function definitions (implementations).
+//
+// Functions are checked for name collisions and singleton redefinition.
+func NewFunction(name string, opts ...FunctionOpt) (*FunctionDecl, error) {
+ fn := &FunctionDecl{
+ name: name,
+ overloads: map[string]*OverloadDecl{},
+ overloadOrdinals: []string{},
+ }
+ var err error
+ for _, opt := range opts {
+ fn, err = opt(fn)
+ if err != nil {
+ return nil, err
+ }
+ }
+ if len(fn.overloads) == 0 {
+ return nil, fmt.Errorf("function %s must have at least one overload", name)
+ }
+ return fn, nil
+}
+
+// FunctionDecl defines a function name, overload set, and optionally a singleton definition for all
+// overload instances.
+type FunctionDecl struct {
+ name string
+
+ // overloads associated with the function name.
+ overloads map[string]*OverloadDecl
+
+ // singleton implementation of the function for all overloads.
+ //
+ // If this option is set, an error will occur if any overloads specify a per-overload implementation
+ // or if another function with the same name attempts to redefine the singleton.
+ singleton *functions.Overload
+
+ // disableTypeGuards is a performance optimization to disable detailed runtime type checks which could
+ // add overhead on common operations. Setting this option true leaves error checks and argument checks
+ // intact.
+ disableTypeGuards bool
+
+ // state indicates that the binding should be provided as a declaration, as a runtime binding, or both.
+ state declarationState
+
+ // overloadOrdinals indicates the order in which the overload was declared.
+ overloadOrdinals []string
+}
+
+type declarationState int
+
+const (
+ declarationStateUnset declarationState = iota
+ declarationDisabled
+ declarationEnabled
+)
+
+// Name returns the function name in human-readable terms, e.g. 'contains' of 'math.least'
+func (f *FunctionDecl) Name() string {
+ if f == nil {
+ return ""
+ }
+ return f.name
+}
+
+// IsDeclarationDisabled indicates that the function implementation should be added to the dispatcher, but the
+// declaration should not be exposed for use in expressions.
+func (f *FunctionDecl) IsDeclarationDisabled() bool {
+ return f.state == declarationDisabled
+}
+
+// Merge combines an existing function declaration with another.
+//
+// If a function is extended, by say adding new overloads to an existing function, then it is merged with the
+// prior definition of the function at which point its overloads must not collide with pre-existing overloads
+// and its bindings (singleton, or per-overload) must not conflict with previous definitions either.
+func (f *FunctionDecl) Merge(other *FunctionDecl) (*FunctionDecl, error) {
+ if f == other {
+ return f, nil
+ }
+ if f.Name() != other.Name() {
+ return nil, fmt.Errorf("cannot merge unrelated functions. %s and %s", f.Name(), other.Name())
+ }
+ merged := &FunctionDecl{
+ name: f.Name(),
+ overloads: make(map[string]*OverloadDecl, len(f.overloads)),
+ singleton: f.singleton,
+ overloadOrdinals: make([]string, len(f.overloads)),
+ // if one function is expecting type-guards and the other is not, then they
+ // must not be disabled.
+ disableTypeGuards: f.disableTypeGuards && other.disableTypeGuards,
+ // default to the current functions declaration state.
+ state: f.state,
+ }
+ // If the other state indicates that the declaration should be explicitly enabled or
+ // disabled, then update the merged state with the most recent value.
+ if other.state != declarationStateUnset {
+ merged.state = other.state
+ }
+ // baseline copy of the overloads and their ordinals
+ copy(merged.overloadOrdinals, f.overloadOrdinals)
+ for oID, o := range f.overloads {
+ merged.overloads[oID] = o
+ }
+ // overloads and their ordinals are added from the left
+ for _, oID := range other.overloadOrdinals {
+ o := other.overloads[oID]
+ err := merged.AddOverload(o)
+ if err != nil {
+ return nil, fmt.Errorf("function declaration merge failed: %v", err)
+ }
+ }
+ if other.singleton != nil {
+ if merged.singleton != nil && merged.singleton != other.singleton {
+ return nil, fmt.Errorf("function already has a singleton binding: %s", f.Name())
+ }
+ merged.singleton = other.singleton
+ }
+ return merged, nil
+}
+
+// AddOverload ensures that the new overload does not collide with an existing overload signature;
+// however, if the function signatures are identical, the implementation may be rewritten as its
+// difficult to compare functions by object identity.
+func (f *FunctionDecl) AddOverload(overload *OverloadDecl) error {
+ if f == nil {
+ return fmt.Errorf("nil function cannot add overload: %s", overload.ID())
+ }
+ for oID, o := range f.overloads {
+ if oID != overload.ID() && o.SignatureOverlaps(overload) {
+ return fmt.Errorf("overload signature collision in function %s: %s collides with %s", f.Name(), oID, overload.ID())
+ }
+ if oID == overload.ID() {
+ if o.SignatureEquals(overload) && o.IsNonStrict() == overload.IsNonStrict() {
+ // Allow redefinition of an overload implementation so long as the signatures match.
+ if overload.hasBinding() {
+ f.overloads[oID] = overload
+ }
+ return nil
+ }
+ return fmt.Errorf("overload redefinition in function. %s: %s has multiple definitions", f.Name(), oID)
+ }
+ }
+ f.overloadOrdinals = append(f.overloadOrdinals, overload.ID())
+ f.overloads[overload.ID()] = overload
+ return nil
+}
+
+// OverloadDecls returns the overload declarations in the order in which they were declared.
+func (f *FunctionDecl) OverloadDecls() []*OverloadDecl {
+ if f == nil {
+ return []*OverloadDecl{}
+ }
+ overloads := make([]*OverloadDecl, 0, len(f.overloads))
+ for _, oID := range f.overloadOrdinals {
+ overloads = append(overloads, f.overloads[oID])
+ }
+ return overloads
+}
+
+// Bindings produces a set of function bindings, if any are defined.
+func (f *FunctionDecl) Bindings() ([]*functions.Overload, error) {
+ if f == nil {
+ return []*functions.Overload{}, nil
+ }
+ overloads := []*functions.Overload{}
+ nonStrict := false
+ for _, oID := range f.overloadOrdinals {
+ o := f.overloads[oID]
+ if o.hasBinding() {
+ overload := &functions.Overload{
+ Operator: o.ID(),
+ Unary: o.guardedUnaryOp(f.Name(), f.disableTypeGuards),
+ Binary: o.guardedBinaryOp(f.Name(), f.disableTypeGuards),
+ Function: o.guardedFunctionOp(f.Name(), f.disableTypeGuards),
+ OperandTrait: o.OperandTrait(),
+ NonStrict: o.IsNonStrict(),
+ }
+ overloads = append(overloads, overload)
+ nonStrict = nonStrict || o.IsNonStrict()
+ }
+ }
+ if f.singleton != nil {
+ if len(overloads) != 0 {
+ return nil, fmt.Errorf("singleton function incompatible with specialized overloads: %s", f.Name())
+ }
+ overloads = []*functions.Overload{
+ {
+ Operator: f.Name(),
+ Unary: f.singleton.Unary,
+ Binary: f.singleton.Binary,
+ Function: f.singleton.Function,
+ OperandTrait: f.singleton.OperandTrait,
+ },
+ }
+ // fall-through to return single overload case.
+ }
+ if len(overloads) == 0 {
+ return overloads, nil
+ }
+ // Single overload. Replicate an entry for it using the function name as well.
+ if len(overloads) == 1 {
+ if overloads[0].Operator == f.Name() {
+ return overloads, nil
+ }
+ return append(overloads, &functions.Overload{
+ Operator: f.Name(),
+ Unary: overloads[0].Unary,
+ Binary: overloads[0].Binary,
+ Function: overloads[0].Function,
+ NonStrict: overloads[0].NonStrict,
+ OperandTrait: overloads[0].OperandTrait,
+ }), nil
+ }
+ // All of the defined overloads are wrapped into a top-level function which
+ // performs dynamic dispatch to the proper overload based on the argument types.
+ bindings := append([]*functions.Overload{}, overloads...)
+ funcDispatch := func(args ...ref.Val) ref.Val {
+ for _, oID := range f.overloadOrdinals {
+ o := f.overloads[oID]
+ // During dynamic dispatch over multiple functions, signature agreement checks
+ // are preserved in order to assist with the function resolution step.
+ switch len(args) {
+ case 1:
+ if o.unaryOp != nil && o.matchesRuntimeSignature( /* disableTypeGuards=*/ false, args...) {
+ return o.unaryOp(args[0])
+ }
+ case 2:
+ if o.binaryOp != nil && o.matchesRuntimeSignature( /* disableTypeGuards=*/ false, args...) {
+ return o.binaryOp(args[0], args[1])
+ }
+ }
+ if o.functionOp != nil && o.matchesRuntimeSignature( /* disableTypeGuards=*/ false, args...) {
+ return o.functionOp(args...)
+ }
+ // eventually this will fall through to the noSuchOverload below.
+ }
+ return MaybeNoSuchOverload(f.Name(), args...)
+ }
+ function := &functions.Overload{
+ Operator: f.Name(),
+ Function: funcDispatch,
+ NonStrict: nonStrict,
+ }
+ return append(bindings, function), nil
+}
+
+// MaybeNoSuchOverload determines whether to propagate an error if one is provided as an argument, or
+// to return an unknown set, or to produce a new error for a missing function signature.
+func MaybeNoSuchOverload(funcName string, args ...ref.Val) ref.Val {
+ argTypes := make([]string, len(args))
+ var unk *types.Unknown = nil
+ for i, arg := range args {
+ if types.IsError(arg) {
+ return arg
+ }
+ if types.IsUnknown(arg) {
+ unk = types.MergeUnknowns(arg.(*types.Unknown), unk)
+ }
+ argTypes[i] = arg.Type().TypeName()
+ }
+ if unk != nil {
+ return unk
+ }
+ signature := strings.Join(argTypes, ", ")
+ return types.NewErr("no such overload: %s(%s)", funcName, signature)
+}
+
+// FunctionOpt defines a functional option for mutating a function declaration.
+type FunctionOpt func(*FunctionDecl) (*FunctionDecl, error)
+
+// DisableTypeGuards disables automatically generated function invocation guards on direct overload calls.
+// Type guards remain on during dynamic dispatch for parsed-only expressions.
+func DisableTypeGuards(value bool) FunctionOpt {
+ return func(fn *FunctionDecl) (*FunctionDecl, error) {
+ fn.disableTypeGuards = value
+ return fn, nil
+ }
+}
+
+// DisableDeclaration indicates that the function declaration should be disabled, but the runtime function
+// binding should be provided. Marking a function as runtime-only is a safe way to manage deprecations
+// of function declarations while still preserving the runtime behavior for previously compiled expressions.
+func DisableDeclaration(value bool) FunctionOpt {
+ return func(fn *FunctionDecl) (*FunctionDecl, error) {
+ if value {
+ fn.state = declarationDisabled
+ } else {
+ fn.state = declarationEnabled
+ }
+ return fn, nil
+ }
+}
+
+// SingletonUnaryBinding creates a singleton function definition to be used for all function overloads.
+//
+// Note, this approach works well if operand is expected to have a specific trait which it implements,
+// e.g. traits.ContainerType. Otherwise, prefer per-overload function bindings.
+func SingletonUnaryBinding(fn functions.UnaryOp, traits ...int) FunctionOpt {
+ trait := 0
+ for _, t := range traits {
+ trait = trait | t
+ }
+ return func(f *FunctionDecl) (*FunctionDecl, error) {
+ if f.singleton != nil {
+ return nil, fmt.Errorf("function already has a singleton binding: %s", f.Name())
+ }
+ f.singleton = &functions.Overload{
+ Operator: f.Name(),
+ Unary: fn,
+ OperandTrait: trait,
+ }
+ return f, nil
+ }
+}
+
+// SingletonBinaryBinding creates a singleton function definition to be used with all function overloads.
+//
+// Note, this approach works well if operand is expected to have a specific trait which it implements,
+// e.g. traits.ContainerType. Otherwise, prefer per-overload function bindings.
+func SingletonBinaryBinding(fn functions.BinaryOp, traits ...int) FunctionOpt {
+ trait := 0
+ for _, t := range traits {
+ trait = trait | t
+ }
+ return func(f *FunctionDecl) (*FunctionDecl, error) {
+ if f.singleton != nil {
+ return nil, fmt.Errorf("function already has a singleton binding: %s", f.Name())
+ }
+ f.singleton = &functions.Overload{
+ Operator: f.Name(),
+ Binary: fn,
+ OperandTrait: trait,
+ }
+ return f, nil
+ }
+}
+
+// SingletonFunctionBinding creates a singleton function definition to be used with all function overloads.
+//
+// Note, this approach works well if operand is expected to have a specific trait which it implements,
+// e.g. traits.ContainerType. Otherwise, prefer per-overload function bindings.
+func SingletonFunctionBinding(fn functions.FunctionOp, traits ...int) FunctionOpt {
+ trait := 0
+ for _, t := range traits {
+ trait = trait | t
+ }
+ return func(f *FunctionDecl) (*FunctionDecl, error) {
+ if f.singleton != nil {
+ return nil, fmt.Errorf("function already has a singleton binding: %s", f.Name())
+ }
+ f.singleton = &functions.Overload{
+ Operator: f.Name(),
+ Function: fn,
+ OperandTrait: trait,
+ }
+ return f, nil
+ }
+}
+
+// Overload defines a new global overload with an overload id, argument types, and result type. Through the
+// use of OverloadOpt options, the overload may also be configured with a binding, an operand trait, and to
+// be non-strict.
+//
+// Note: function bindings should be commonly configured with Overload instances whereas operand traits and
+// strict-ness should be rare occurrences.
+func Overload(overloadID string,
+ args []*types.Type, resultType *types.Type,
+ opts ...OverloadOpt) FunctionOpt {
+ return newOverload(overloadID, false, args, resultType, opts...)
+}
+
+// MemberOverload defines a new receiver-style overload (or member function) with an overload id, argument types,
+// and result type. Through the use of OverloadOpt options, the overload may also be configured with a binding,
+// an operand trait, and to be non-strict.
+//
+// Note: function bindings should be commonly configured with Overload instances whereas operand traits and
+// strict-ness should be rare occurrences.
+func MemberOverload(overloadID string,
+ args []*types.Type, resultType *types.Type,
+ opts ...OverloadOpt) FunctionOpt {
+ return newOverload(overloadID, true, args, resultType, opts...)
+}
+
+func newOverload(overloadID string,
+ memberFunction bool, args []*types.Type, resultType *types.Type,
+ opts ...OverloadOpt) FunctionOpt {
+ return func(f *FunctionDecl) (*FunctionDecl, error) {
+ overload, err := newOverloadInternal(overloadID, memberFunction, args, resultType, opts...)
+ if err != nil {
+ return nil, err
+ }
+ err = f.AddOverload(overload)
+ if err != nil {
+ return nil, err
+ }
+ return f, nil
+ }
+}
+
+func newOverloadInternal(overloadID string,
+ memberFunction bool, args []*types.Type, resultType *types.Type,
+ opts ...OverloadOpt) (*OverloadDecl, error) {
+ overload := &OverloadDecl{
+ id: overloadID,
+ argTypes: args,
+ resultType: resultType,
+ isMemberFunction: memberFunction,
+ }
+ var err error
+ for _, opt := range opts {
+ overload, err = opt(overload)
+ if err != nil {
+ return nil, err
+ }
+ }
+ return overload, nil
+}
+
+// OverloadDecl contains the definition of a single overload id with a specific signature, and an optional
+// implementation.
+type OverloadDecl struct {
+ id string
+ argTypes []*types.Type
+ resultType *types.Type
+ isMemberFunction bool
+ // nonStrict indicates that the function will accept error and unknown arguments as inputs.
+ nonStrict bool
+ // operandTrait indicates whether the member argument should have a specific type-trait.
+ //
+ // This is useful for creating overloads which operate on a type-interface rather than a concrete type.
+ operandTrait int
+
+ // Function implementation options. Optional, but encouraged.
+ // unaryOp is a function binding that takes a single argument.
+ unaryOp functions.UnaryOp
+ // binaryOp is a function binding that takes two arguments.
+ binaryOp functions.BinaryOp
+ // functionOp is a catch-all for zero-arity and three-plus arity functions.
+ functionOp functions.FunctionOp
+}
+
+// ID mirrors the overload signature and provides a unique id which may be referenced within the type-checker
+// and interpreter to optimize performance.
+//
+// The ID format is usually one of two styles:
+// global: __
+// member: ___
+func (o *OverloadDecl) ID() string {
+ if o == nil {
+ return ""
+ }
+ return o.id
+}
+
+// ArgTypes contains the set of argument types expected by the overload.
+//
+// For member functions ArgTypes[0] represents the member operand type.
+func (o *OverloadDecl) ArgTypes() []*types.Type {
+ if o == nil {
+ return emptyArgs
+ }
+ return o.argTypes
+}
+
+// IsMemberFunction indicates whether the overload is a member function
+func (o *OverloadDecl) IsMemberFunction() bool {
+ if o == nil {
+ return false
+ }
+ return o.isMemberFunction
+}
+
+// IsNonStrict returns whether the overload accepts errors and unknown values as arguments.
+func (o *OverloadDecl) IsNonStrict() bool {
+ if o == nil {
+ return false
+ }
+ return o.nonStrict
+}
+
+// OperandTrait returns the trait mask of the first operand to the overload call, e.g.
+// `traits.Indexer`
+func (o *OverloadDecl) OperandTrait() int {
+ if o == nil {
+ return 0
+ }
+ return o.operandTrait
+}
+
+// ResultType indicates the output type from calling the function.
+func (o *OverloadDecl) ResultType() *types.Type {
+ if o == nil {
+ // *types.Type is nil-safe
+ return nil
+ }
+ return o.resultType
+}
+
+// TypeParams returns the type parameter names associated with the overload.
+func (o *OverloadDecl) TypeParams() []string {
+ typeParams := map[string]struct{}{}
+ collectParamNames(typeParams, o.ResultType())
+ for _, arg := range o.ArgTypes() {
+ collectParamNames(typeParams, arg)
+ }
+ params := make([]string, 0, len(typeParams))
+ for param := range typeParams {
+ params = append(params, param)
+ }
+ return params
+}
+
+// SignatureEquals determines whether the incoming overload declaration signature is equal to the current signature.
+//
+// Result type, operand trait, and strict-ness are not considered as part of signature equality.
+func (o *OverloadDecl) SignatureEquals(other *OverloadDecl) bool {
+ if o == other {
+ return true
+ }
+ if o.ID() != other.ID() || o.IsMemberFunction() != other.IsMemberFunction() || len(o.ArgTypes()) != len(other.ArgTypes()) {
+ return false
+ }
+ for i, at := range o.ArgTypes() {
+ oat := other.ArgTypes()[i]
+ if !at.IsEquivalentType(oat) {
+ return false
+ }
+ }
+ return o.ResultType().IsEquivalentType(other.ResultType())
+}
+
+// SignatureOverlaps indicates whether two functions have non-equal, but overloapping function signatures.
+//
+// For example, list(dyn) collides with list(string) since the 'dyn' type can contain a 'string' type.
+func (o *OverloadDecl) SignatureOverlaps(other *OverloadDecl) bool {
+ if o.IsMemberFunction() != other.IsMemberFunction() || len(o.ArgTypes()) != len(other.ArgTypes()) {
+ return false
+ }
+ argsOverlap := true
+ for i, argType := range o.ArgTypes() {
+ otherArgType := other.ArgTypes()[i]
+ argsOverlap = argsOverlap &&
+ (argType.IsAssignableType(otherArgType) ||
+ otherArgType.IsAssignableType(argType))
+ }
+ return argsOverlap
+}
+
+// hasBinding indicates whether the overload already has a definition.
+func (o *OverloadDecl) hasBinding() bool {
+ return o != nil && (o.unaryOp != nil || o.binaryOp != nil || o.functionOp != nil)
+}
+
+// guardedUnaryOp creates an invocation guard around the provided unary operator, if one is defined.
+func (o *OverloadDecl) guardedUnaryOp(funcName string, disableTypeGuards bool) functions.UnaryOp {
+ if o.unaryOp == nil {
+ return nil
+ }
+ return func(arg ref.Val) ref.Val {
+ if !o.matchesRuntimeUnarySignature(disableTypeGuards, arg) {
+ return MaybeNoSuchOverload(funcName, arg)
+ }
+ return o.unaryOp(arg)
+ }
+}
+
+// guardedBinaryOp creates an invocation guard around the provided binary operator, if one is defined.
+func (o *OverloadDecl) guardedBinaryOp(funcName string, disableTypeGuards bool) functions.BinaryOp {
+ if o.binaryOp == nil {
+ return nil
+ }
+ return func(arg1, arg2 ref.Val) ref.Val {
+ if !o.matchesRuntimeBinarySignature(disableTypeGuards, arg1, arg2) {
+ return MaybeNoSuchOverload(funcName, arg1, arg2)
+ }
+ return o.binaryOp(arg1, arg2)
+ }
+}
+
+// guardedFunctionOp creates an invocation guard around the provided variadic function binding, if one is provided.
+func (o *OverloadDecl) guardedFunctionOp(funcName string, disableTypeGuards bool) functions.FunctionOp {
+ if o.functionOp == nil {
+ return nil
+ }
+ return func(args ...ref.Val) ref.Val {
+ if !o.matchesRuntimeSignature(disableTypeGuards, args...) {
+ return MaybeNoSuchOverload(funcName, args...)
+ }
+ return o.functionOp(args...)
+ }
+}
+
+// matchesRuntimeUnarySignature indicates whether the argument type is runtime assiganble to the overload's expected argument.
+func (o *OverloadDecl) matchesRuntimeUnarySignature(disableTypeGuards bool, arg ref.Val) bool {
+ return matchRuntimeArgType(o.IsNonStrict(), disableTypeGuards, o.ArgTypes()[0], arg) &&
+ matchOperandTrait(o.OperandTrait(), arg)
+}
+
+// matchesRuntimeBinarySignature indicates whether the argument types are runtime assiganble to the overload's expected arguments.
+func (o *OverloadDecl) matchesRuntimeBinarySignature(disableTypeGuards bool, arg1, arg2 ref.Val) bool {
+ return matchRuntimeArgType(o.IsNonStrict(), disableTypeGuards, o.ArgTypes()[0], arg1) &&
+ matchRuntimeArgType(o.IsNonStrict(), disableTypeGuards, o.ArgTypes()[1], arg2) &&
+ matchOperandTrait(o.OperandTrait(), arg1)
+}
+
+// matchesRuntimeSignature indicates whether the argument types are runtime assiganble to the overload's expected arguments.
+func (o *OverloadDecl) matchesRuntimeSignature(disableTypeGuards bool, args ...ref.Val) bool {
+ if len(args) != len(o.ArgTypes()) {
+ return false
+ }
+ if len(args) == 0 {
+ return true
+ }
+ for i, arg := range args {
+ if !matchRuntimeArgType(o.IsNonStrict(), disableTypeGuards, o.ArgTypes()[i], arg) {
+ return false
+ }
+ }
+ return matchOperandTrait(o.OperandTrait(), args[0])
+}
+
+func matchRuntimeArgType(nonStrict, disableTypeGuards bool, argType *types.Type, arg ref.Val) bool {
+ if nonStrict && (disableTypeGuards || types.IsUnknownOrError(arg)) {
+ return true
+ }
+ if types.IsUnknownOrError(arg) {
+ return false
+ }
+ return disableTypeGuards || argType.IsAssignableRuntimeType(arg)
+}
+
+func matchOperandTrait(trait int, arg ref.Val) bool {
+ return trait == 0 || arg.Type().HasTrait(trait) || types.IsUnknownOrError(arg)
+}
+
+// OverloadOpt is a functional option for configuring a function overload.
+type OverloadOpt func(*OverloadDecl) (*OverloadDecl, error)
+
+// UnaryBinding provides the implementation of a unary overload. The provided function is protected by a runtime
+// type-guard which ensures runtime type agreement between the overload signature and runtime argument types.
+func UnaryBinding(binding functions.UnaryOp) OverloadOpt {
+ return func(o *OverloadDecl) (*OverloadDecl, error) {
+ if o.hasBinding() {
+ return nil, fmt.Errorf("overload already has a binding: %s", o.ID())
+ }
+ if len(o.ArgTypes()) != 1 {
+ return nil, fmt.Errorf("unary function bound to non-unary overload: %s", o.ID())
+ }
+ o.unaryOp = binding
+ return o, nil
+ }
+}
+
+// BinaryBinding provides the implementation of a binary overload. The provided function is protected by a runtime
+// type-guard which ensures runtime type agreement between the overload signature and runtime argument types.
+func BinaryBinding(binding functions.BinaryOp) OverloadOpt {
+ return func(o *OverloadDecl) (*OverloadDecl, error) {
+ if o.hasBinding() {
+ return nil, fmt.Errorf("overload already has a binding: %s", o.ID())
+ }
+ if len(o.ArgTypes()) != 2 {
+ return nil, fmt.Errorf("binary function bound to non-binary overload: %s", o.ID())
+ }
+ o.binaryOp = binding
+ return o, nil
+ }
+}
+
+// FunctionBinding provides the implementation of a variadic overload. The provided function is protected by a runtime
+// type-guard which ensures runtime type agreement between the overload signature and runtime argument types.
+func FunctionBinding(binding functions.FunctionOp) OverloadOpt {
+ return func(o *OverloadDecl) (*OverloadDecl, error) {
+ if o.hasBinding() {
+ return nil, fmt.Errorf("overload already has a binding: %s", o.ID())
+ }
+ o.functionOp = binding
+ return o, nil
+ }
+}
+
+// OverloadIsNonStrict enables the function to be called with error and unknown argument values.
+//
+// Note: do not use this option unless absoluately necessary as it should be an uncommon feature.
+func OverloadIsNonStrict() OverloadOpt {
+ return func(o *OverloadDecl) (*OverloadDecl, error) {
+ o.nonStrict = true
+ return o, nil
+ }
+}
+
+// OverloadOperandTrait configures a set of traits which the first argument to the overload must implement in order to be
+// successfully invoked.
+func OverloadOperandTrait(trait int) OverloadOpt {
+ return func(o *OverloadDecl) (*OverloadDecl, error) {
+ o.operandTrait = trait
+ return o, nil
+ }
+}
+
+// NewConstant creates a new constant declaration.
+func NewConstant(name string, t *types.Type, v ref.Val) *VariableDecl {
+ return &VariableDecl{name: name, varType: t, value: v}
+}
+
+// NewVariable creates a new variable declaration.
+func NewVariable(name string, t *types.Type) *VariableDecl {
+ return &VariableDecl{name: name, varType: t}
+}
+
+// VariableDecl defines a variable declaration which may optionally have a constant value.
+type VariableDecl struct {
+ name string
+ varType *types.Type
+ value ref.Val
+}
+
+// Name returns the fully-qualified variable name
+func (v *VariableDecl) Name() string {
+ if v == nil {
+ return ""
+ }
+ return v.name
+}
+
+// Type returns the types.Type value associated with the variable.
+func (v *VariableDecl) Type() *types.Type {
+ if v == nil {
+ // types.Type is nil-safe
+ return nil
+ }
+ return v.varType
+}
+
+// Value returns the constant value associated with the declaration.
+func (v *VariableDecl) Value() ref.Val {
+ if v == nil {
+ return nil
+ }
+ return v.value
+}
+
+// DeclarationIsEquivalent returns true if one variable declaration has the same name and same type as the input.
+func (v *VariableDecl) DeclarationIsEquivalent(other *VariableDecl) bool {
+ if v == other {
+ return true
+ }
+ return v.Name() == other.Name() && v.Type().IsEquivalentType(other.Type())
+}
+
+// VariableDeclToExprDecl converts a go-native variable declaration into a protobuf-type variable declaration.
+func VariableDeclToExprDecl(v *VariableDecl) (*exprpb.Decl, error) {
+ varType, err := types.TypeToExprType(v.Type())
+ if err != nil {
+ return nil, err
+ }
+ return chkdecls.NewVar(v.Name(), varType), nil
+}
+
+// TypeVariable creates a new type identifier for use within a types.Provider
+func TypeVariable(t *types.Type) *VariableDecl {
+ return NewVariable(t.TypeName(), types.NewTypeTypeWithParam(t))
+}
+
+// FunctionDeclToExprDecl converts a go-native function declaration into a protobuf-typed function declaration.
+func FunctionDeclToExprDecl(f *FunctionDecl) (*exprpb.Decl, error) {
+ overloads := make([]*exprpb.Decl_FunctionDecl_Overload, len(f.overloads))
+ for i, oID := range f.overloadOrdinals {
+ o := f.overloads[oID]
+ paramNames := map[string]struct{}{}
+ argTypes := make([]*exprpb.Type, len(o.ArgTypes()))
+ for j, a := range o.ArgTypes() {
+ collectParamNames(paramNames, a)
+ at, err := types.TypeToExprType(a)
+ if err != nil {
+ return nil, err
+ }
+ argTypes[j] = at
+ }
+ collectParamNames(paramNames, o.ResultType())
+ resultType, err := types.TypeToExprType(o.ResultType())
+ if err != nil {
+ return nil, err
+ }
+ if len(paramNames) == 0 {
+ if o.IsMemberFunction() {
+ overloads[i] = chkdecls.NewInstanceOverload(oID, argTypes, resultType)
+ } else {
+ overloads[i] = chkdecls.NewOverload(oID, argTypes, resultType)
+ }
+ } else {
+ params := []string{}
+ for pn := range paramNames {
+ params = append(params, pn)
+ }
+ if o.IsMemberFunction() {
+ overloads[i] = chkdecls.NewParameterizedInstanceOverload(oID, argTypes, resultType, params)
+ } else {
+ overloads[i] = chkdecls.NewParameterizedOverload(oID, argTypes, resultType, params)
+ }
+ }
+ }
+ return chkdecls.NewFunction(f.Name(), overloads...), nil
+}
+
+func collectParamNames(paramNames map[string]struct{}, arg *types.Type) {
+ if arg.Kind() == types.TypeParamKind {
+ paramNames[arg.TypeName()] = struct{}{}
+ }
+ for _, param := range arg.Parameters() {
+ collectParamNames(paramNames, param)
+ }
+}
+
+var (
+ emptyArgs = []*types.Type{}
+)
diff --git a/vendor/github.com/google/cel-go/common/doc.go b/vendor/github.com/google/cel-go/common/doc.go
new file mode 100644
index 000000000000..5362fdfe4b3d
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/doc.go
@@ -0,0 +1,17 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+// Package common defines types and utilities common to expression parsing,
+// checking, and interpretation
+package common
diff --git a/vendor/github.com/google/cel-go/common/error.go b/vendor/github.com/google/cel-go/common/error.go
new file mode 100644
index 000000000000..0cf21345e6fe
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/error.go
@@ -0,0 +1,74 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package common
+
+import (
+ "fmt"
+ "strings"
+ "unicode/utf8"
+)
+
+// NewError creates an error associated with an expression id with the given message at the given location.
+func NewError(id int64, message string, location Location) *Error {
+ return &Error{Message: message, Location: location, ExprID: id}
+}
+
+// Error type which references an expression id, a location within source, and a message.
+type Error struct {
+ Location Location
+ Message string
+ ExprID int64
+}
+
+const (
+ dot = "."
+ ind = "^"
+ wideDot = "\uff0e"
+ wideInd = "\uff3e"
+
+ // maxSnippetLength is the largest number of characters which can be rendered in an error message snippet.
+ maxSnippetLength = 16384
+)
+
+// ToDisplayString decorates the error message with the source location.
+func (e *Error) ToDisplayString(source Source) string {
+ var result = fmt.Sprintf("ERROR: %s:%d:%d: %s",
+ source.Description(),
+ e.Location.Line(),
+ e.Location.Column()+1, // add one to the 0-based column for display
+ e.Message)
+ if snippet, found := source.Snippet(e.Location.Line()); found && len(snippet) <= maxSnippetLength {
+ snippet := strings.Replace(snippet, "\t", " ", -1)
+ srcLine := "\n | " + snippet
+ var bytes = []byte(snippet)
+ var indLine = "\n | "
+ for i := 0; i < e.Location.Column() && len(bytes) > 0; i++ {
+ _, sz := utf8.DecodeRune(bytes)
+ bytes = bytes[sz:]
+ if sz > 1 {
+ indLine += wideDot
+ } else {
+ indLine += dot
+ }
+ }
+ if _, sz := utf8.DecodeRune(bytes); sz > 1 {
+ indLine += wideInd
+ } else {
+ indLine += ind
+ }
+ result += srcLine + indLine
+ }
+ return result
+}
diff --git a/vendor/github.com/google/cel-go/common/errors.go b/vendor/github.com/google/cel-go/common/errors.go
new file mode 100644
index 000000000000..25adc73d8e05
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/errors.go
@@ -0,0 +1,103 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package common
+
+import (
+ "fmt"
+ "sort"
+ "strings"
+)
+
+// Errors type which contains a list of errors observed during parsing.
+type Errors struct {
+ errors []*Error
+ source Source
+ numErrors int
+ maxErrorsToReport int
+}
+
+// NewErrors creates a new instance of the Errors type.
+func NewErrors(source Source) *Errors {
+ return &Errors{
+ errors: []*Error{},
+ source: source,
+ maxErrorsToReport: 100,
+ }
+}
+
+// ReportError records an error at a source location.
+func (e *Errors) ReportError(l Location, format string, args ...any) {
+ e.ReportErrorAtID(0, l, format, args...)
+}
+
+// ReportErrorAtID records an error at a source location and expression id.
+func (e *Errors) ReportErrorAtID(id int64, l Location, format string, args ...any) {
+ e.numErrors++
+ if e.numErrors > e.maxErrorsToReport {
+ return
+ }
+ err := &Error{
+ ExprID: id,
+ Location: l,
+ Message: fmt.Sprintf(format, args...),
+ }
+ e.errors = append(e.errors, err)
+}
+
+// GetErrors returns the list of observed errors.
+func (e *Errors) GetErrors() []*Error {
+ return e.errors[:]
+}
+
+// Append creates a new Errors object with the current and input errors.
+func (e *Errors) Append(errs []*Error) *Errors {
+ return &Errors{
+ errors: append(e.errors[:], errs...),
+ source: e.source,
+ numErrors: e.numErrors + len(errs),
+ maxErrorsToReport: e.maxErrorsToReport,
+ }
+}
+
+// ToDisplayString returns the error set to a newline delimited string.
+func (e *Errors) ToDisplayString() string {
+ errorsInString := e.maxErrorsToReport
+ if e.numErrors > e.maxErrorsToReport {
+ // add one more error to indicate the number of errors truncated.
+ errorsInString++
+ } else {
+ // otherwise the error set will just contain the number of errors.
+ errorsInString = e.numErrors
+ }
+
+ result := make([]string, errorsInString)
+ sort.SliceStable(e.errors, func(i, j int) bool {
+ ei := e.errors[i].Location
+ ej := e.errors[j].Location
+ return ei.Line() < ej.Line() ||
+ (ei.Line() == ej.Line() && ei.Column() < ej.Column())
+ })
+ for i, err := range e.errors {
+ // This can happen during the append of two errors objects
+ if i >= e.maxErrorsToReport {
+ break
+ }
+ result[i] = err.ToDisplayString(e.source)
+ }
+ if e.numErrors > e.maxErrorsToReport {
+ result[e.maxErrorsToReport] = fmt.Sprintf("%d more errors were truncated", e.numErrors-e.maxErrorsToReport)
+ }
+ return strings.Join(result, "\n")
+}
diff --git a/vendor/github.com/google/cel-go/common/functions/BUILD.bazel b/vendor/github.com/google/cel-go/common/functions/BUILD.bazel
new file mode 100644
index 000000000000..9f8f8c069ed7
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/functions/BUILD.bazel
@@ -0,0 +1,16 @@
+load("@io_bazel_rules_go//go:def.bzl", "go_library")
+
+package(
+ default_visibility = ["//visibility:public"],
+ licenses = ["notice"], # Apache 2.0
+)
+
+go_library(
+ name = "go_default_library",
+ srcs = ["functions.go"],
+ importmap = "kubevirt.io/kubevirt/vendor/github.com/google/cel-go/common/functions",
+ importpath = "github.com/google/cel-go/common/functions",
+ deps = [
+ "//vendor/github.com/google/cel-go/common/types/ref:go_default_library",
+ ],
+)
diff --git a/vendor/github.com/google/cel-go/common/functions/functions.go b/vendor/github.com/google/cel-go/common/functions/functions.go
new file mode 100644
index 000000000000..67f4a5944e15
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/functions/functions.go
@@ -0,0 +1,61 @@
+// Copyright 2023 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+// Package functions defines the standard builtin functions supported by the interpreter
+package functions
+
+import "github.com/google/cel-go/common/types/ref"
+
+// Overload defines a named overload of a function, indicating an operand trait
+// which must be present on the first argument to the overload as well as one
+// of either a unary, binary, or function implementation.
+//
+// The majority of operators within the expression language are unary or binary
+// and the specializations simplify the call contract for implementers of
+// types with operator overloads. Any added complexity is assumed to be handled
+// by the generic FunctionOp.
+type Overload struct {
+ // Operator name as written in an expression or defined within
+ // operators.go.
+ Operator string
+
+ // Operand trait used to dispatch the call. The zero-value indicates a
+ // global function overload or that one of the Unary / Binary / Function
+ // definitions should be used to execute the call.
+ OperandTrait int
+
+ // Unary defines the overload with a UnaryOp implementation. May be nil.
+ Unary UnaryOp
+
+ // Binary defines the overload with a BinaryOp implementation. May be nil.
+ Binary BinaryOp
+
+ // Function defines the overload with a FunctionOp implementation. May be
+ // nil.
+ Function FunctionOp
+
+ // NonStrict specifies whether the Overload will tolerate arguments that
+ // are types.Err or types.Unknown.
+ NonStrict bool
+}
+
+// UnaryOp is a function that takes a single value and produces an output.
+type UnaryOp func(value ref.Val) ref.Val
+
+// BinaryOp is a function that takes two values and produces an output.
+type BinaryOp func(lhs ref.Val, rhs ref.Val) ref.Val
+
+// FunctionOp is a function with accepts zero or more arguments and produces
+// a value or error as a result.
+type FunctionOp func(values ...ref.Val) ref.Val
diff --git a/vendor/github.com/google/cel-go/common/location.go b/vendor/github.com/google/cel-go/common/location.go
new file mode 100644
index 000000000000..ec3fa7cb50fc
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/location.go
@@ -0,0 +1,51 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package common
+
+// Location interface to represent a location within Source.
+type Location interface {
+ Line() int // 1-based line number within source.
+ Column() int // 0-based column number within source.
+}
+
+// SourceLocation helper type to manually construct a location.
+type SourceLocation struct {
+ line int
+ column int
+}
+
+var (
+ // Location implements the SourceLocation interface.
+ _ Location = &SourceLocation{}
+ // NoLocation is a particular illegal location.
+ NoLocation = &SourceLocation{-1, -1}
+)
+
+// NewLocation creates a new location.
+func NewLocation(line, column int) Location {
+ return &SourceLocation{
+ line: line,
+ column: column}
+}
+
+// Line returns the 1-based line of the location.
+func (l *SourceLocation) Line() int {
+ return l.line
+}
+
+// Column returns the 0-based column number of the location.
+func (l *SourceLocation) Column() int {
+ return l.column
+}
diff --git a/vendor/github.com/google/cel-go/common/operators/BUILD.bazel b/vendor/github.com/google/cel-go/common/operators/BUILD.bazel
new file mode 100644
index 000000000000..855b9eb0fc6f
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/operators/BUILD.bazel
@@ -0,0 +1,13 @@
+load("@io_bazel_rules_go//go:def.bzl", "go_library")
+
+package(
+ default_visibility = ["//visibility:public"],
+ licenses = ["notice"], # Apache 2.0
+)
+
+go_library(
+ name = "go_default_library",
+ srcs = ["operators.go"],
+ importmap = "kubevirt.io/kubevirt/vendor/github.com/google/cel-go/common/operators",
+ importpath = "github.com/google/cel-go/common/operators",
+)
diff --git a/vendor/github.com/google/cel-go/common/operators/operators.go b/vendor/github.com/google/cel-go/common/operators/operators.go
new file mode 100644
index 000000000000..f9b39bda3fe0
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/operators/operators.go
@@ -0,0 +1,157 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+// Package operators defines the internal function names of operators.
+//
+// All operators in the expression language are modelled as function calls.
+package operators
+
+// String "names" for CEL operators.
+const (
+ // Symbolic operators.
+ Conditional = "_?_:_"
+ LogicalAnd = "_&&_"
+ LogicalOr = "_||_"
+ LogicalNot = "!_"
+ Equals = "_==_"
+ NotEquals = "_!=_"
+ Less = "_<_"
+ LessEquals = "_<=_"
+ Greater = "_>_"
+ GreaterEquals = "_>=_"
+ Add = "_+_"
+ Subtract = "_-_"
+ Multiply = "_*_"
+ Divide = "_/_"
+ Modulo = "_%_"
+ Negate = "-_"
+ Index = "_[_]"
+ OptIndex = "_[?_]"
+ OptSelect = "_?._"
+
+ // Macros, must have a valid identifier.
+ Has = "has"
+ All = "all"
+ Exists = "exists"
+ ExistsOne = "exists_one"
+ Map = "map"
+ Filter = "filter"
+
+ // Named operators, must not have be valid identifiers.
+ NotStrictlyFalse = "@not_strictly_false"
+ In = "@in"
+
+ // Deprecated: named operators with valid identifiers.
+ OldNotStrictlyFalse = "__not_strictly_false__"
+ OldIn = "_in_"
+)
+
+var (
+ operators = map[string]string{
+ "+": Add,
+ "/": Divide,
+ "==": Equals,
+ ">": Greater,
+ ">=": GreaterEquals,
+ "in": In,
+ "<": Less,
+ "<=": LessEquals,
+ "%": Modulo,
+ "*": Multiply,
+ "!=": NotEquals,
+ "-": Subtract,
+ }
+ // operatorMap of the operator symbol which refers to a struct containing the display name,
+ // if applicable, the operator precedence, and the arity.
+ //
+ // If the symbol does not have a display name listed in the map, it is only because it requires
+ // special casing to render properly as text.
+ operatorMap = map[string]struct {
+ displayName string
+ precedence int
+ arity int
+ }{
+ Conditional: {displayName: "", precedence: 8, arity: 3},
+ LogicalOr: {displayName: "||", precedence: 7, arity: 2},
+ LogicalAnd: {displayName: "&&", precedence: 6, arity: 2},
+ Equals: {displayName: "==", precedence: 5, arity: 2},
+ Greater: {displayName: ">", precedence: 5, arity: 2},
+ GreaterEquals: {displayName: ">=", precedence: 5, arity: 2},
+ In: {displayName: "in", precedence: 5, arity: 2},
+ Less: {displayName: "<", precedence: 5, arity: 2},
+ LessEquals: {displayName: "<=", precedence: 5, arity: 2},
+ NotEquals: {displayName: "!=", precedence: 5, arity: 2},
+ OldIn: {displayName: "in", precedence: 5, arity: 2},
+ Add: {displayName: "+", precedence: 4, arity: 2},
+ Subtract: {displayName: "-", precedence: 4, arity: 2},
+ Divide: {displayName: "/", precedence: 3, arity: 2},
+ Modulo: {displayName: "%", precedence: 3, arity: 2},
+ Multiply: {displayName: "*", precedence: 3, arity: 2},
+ LogicalNot: {displayName: "!", precedence: 2, arity: 1},
+ Negate: {displayName: "-", precedence: 2, arity: 1},
+ Index: {displayName: "", precedence: 1, arity: 2},
+ OptIndex: {displayName: "", precedence: 1, arity: 2},
+ OptSelect: {displayName: "", precedence: 1, arity: 2},
+ }
+)
+
+// Find the internal function name for an operator, if the input text is one.
+func Find(text string) (string, bool) {
+ op, found := operators[text]
+ return op, found
+}
+
+// FindReverse returns the unmangled, text representation of the operator.
+func FindReverse(symbol string) (string, bool) {
+ op, found := operatorMap[symbol]
+ if !found {
+ return "", false
+ }
+ return op.displayName, true
+}
+
+// FindReverseBinaryOperator returns the unmangled, text representation of a binary operator.
+//
+// If the symbol does refer to an operator, but the operator does not have a display name the
+// result is false.
+func FindReverseBinaryOperator(symbol string) (string, bool) {
+ op, found := operatorMap[symbol]
+ if !found || op.arity != 2 {
+ return "", false
+ }
+ if op.displayName == "" {
+ return "", false
+ }
+ return op.displayName, true
+}
+
+// Precedence returns the operator precedence, where the higher the number indicates
+// higher precedence operations.
+func Precedence(symbol string) int {
+ op, found := operatorMap[symbol]
+ if !found {
+ return 0
+ }
+ return op.precedence
+}
+
+// Arity returns the number of argument the operator takes
+// -1 is returned if an undefined symbol is provided
+func Arity(symbol string) int {
+ op, found := operatorMap[symbol]
+ if !found {
+ return -1
+ }
+ return op.arity
+}
diff --git a/vendor/github.com/google/cel-go/common/overloads/BUILD.bazel b/vendor/github.com/google/cel-go/common/overloads/BUILD.bazel
new file mode 100644
index 000000000000..ed80bcb26bf6
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/overloads/BUILD.bazel
@@ -0,0 +1,13 @@
+load("@io_bazel_rules_go//go:def.bzl", "go_library")
+
+package(
+ default_visibility = ["//visibility:public"],
+ licenses = ["notice"], # Apache 2.0
+)
+
+go_library(
+ name = "go_default_library",
+ srcs = ["overloads.go"],
+ importmap = "kubevirt.io/kubevirt/vendor/github.com/google/cel-go/common/overloads",
+ importpath = "github.com/google/cel-go/common/overloads",
+)
diff --git a/vendor/github.com/google/cel-go/common/overloads/overloads.go b/vendor/github.com/google/cel-go/common/overloads/overloads.go
new file mode 100644
index 000000000000..9d50f4367bf2
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/overloads/overloads.go
@@ -0,0 +1,327 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+// Package overloads defines the internal overload identifiers for function and
+// operator overloads.
+package overloads
+
+// Boolean logic overloads
+const (
+ Conditional = "conditional"
+ LogicalAnd = "logical_and"
+ LogicalOr = "logical_or"
+ LogicalNot = "logical_not"
+ NotStrictlyFalse = "not_strictly_false"
+ Equals = "equals"
+ NotEquals = "not_equals"
+ LessBool = "less_bool"
+ LessInt64 = "less_int64"
+ LessInt64Double = "less_int64_double"
+ LessInt64Uint64 = "less_int64_uint64"
+ LessUint64 = "less_uint64"
+ LessUint64Double = "less_uint64_double"
+ LessUint64Int64 = "less_uint64_int64"
+ LessDouble = "less_double"
+ LessDoubleInt64 = "less_double_int64"
+ LessDoubleUint64 = "less_double_uint64"
+ LessString = "less_string"
+ LessBytes = "less_bytes"
+ LessTimestamp = "less_timestamp"
+ LessDuration = "less_duration"
+ LessEqualsBool = "less_equals_bool"
+ LessEqualsInt64 = "less_equals_int64"
+ LessEqualsInt64Double = "less_equals_int64_double"
+ LessEqualsInt64Uint64 = "less_equals_int64_uint64"
+ LessEqualsUint64 = "less_equals_uint64"
+ LessEqualsUint64Double = "less_equals_uint64_double"
+ LessEqualsUint64Int64 = "less_equals_uint64_int64"
+ LessEqualsDouble = "less_equals_double"
+ LessEqualsDoubleInt64 = "less_equals_double_int64"
+ LessEqualsDoubleUint64 = "less_equals_double_uint64"
+ LessEqualsString = "less_equals_string"
+ LessEqualsBytes = "less_equals_bytes"
+ LessEqualsTimestamp = "less_equals_timestamp"
+ LessEqualsDuration = "less_equals_duration"
+ GreaterBool = "greater_bool"
+ GreaterInt64 = "greater_int64"
+ GreaterInt64Double = "greater_int64_double"
+ GreaterInt64Uint64 = "greater_int64_uint64"
+ GreaterUint64 = "greater_uint64"
+ GreaterUint64Double = "greater_uint64_double"
+ GreaterUint64Int64 = "greater_uint64_int64"
+ GreaterDouble = "greater_double"
+ GreaterDoubleInt64 = "greater_double_int64"
+ GreaterDoubleUint64 = "greater_double_uint64"
+ GreaterString = "greater_string"
+ GreaterBytes = "greater_bytes"
+ GreaterTimestamp = "greater_timestamp"
+ GreaterDuration = "greater_duration"
+ GreaterEqualsBool = "greater_equals_bool"
+ GreaterEqualsInt64 = "greater_equals_int64"
+ GreaterEqualsInt64Double = "greater_equals_int64_double"
+ GreaterEqualsInt64Uint64 = "greater_equals_int64_uint64"
+ GreaterEqualsUint64 = "greater_equals_uint64"
+ GreaterEqualsUint64Double = "greater_equals_uint64_double"
+ GreaterEqualsUint64Int64 = "greater_equals_uint64_int64"
+ GreaterEqualsDouble = "greater_equals_double"
+ GreaterEqualsDoubleInt64 = "greater_equals_double_int64"
+ GreaterEqualsDoubleUint64 = "greater_equals_double_uint64"
+ GreaterEqualsString = "greater_equals_string"
+ GreaterEqualsBytes = "greater_equals_bytes"
+ GreaterEqualsTimestamp = "greater_equals_timestamp"
+ GreaterEqualsDuration = "greater_equals_duration"
+)
+
+// Math overloads
+const (
+ AddInt64 = "add_int64"
+ AddUint64 = "add_uint64"
+ AddDouble = "add_double"
+ AddString = "add_string"
+ AddBytes = "add_bytes"
+ AddList = "add_list"
+ AddTimestampDuration = "add_timestamp_duration"
+ AddDurationTimestamp = "add_duration_timestamp"
+ AddDurationDuration = "add_duration_duration"
+ SubtractInt64 = "subtract_int64"
+ SubtractUint64 = "subtract_uint64"
+ SubtractDouble = "subtract_double"
+ SubtractTimestampTimestamp = "subtract_timestamp_timestamp"
+ SubtractTimestampDuration = "subtract_timestamp_duration"
+ SubtractDurationDuration = "subtract_duration_duration"
+ MultiplyInt64 = "multiply_int64"
+ MultiplyUint64 = "multiply_uint64"
+ MultiplyDouble = "multiply_double"
+ DivideInt64 = "divide_int64"
+ DivideUint64 = "divide_uint64"
+ DivideDouble = "divide_double"
+ ModuloInt64 = "modulo_int64"
+ ModuloUint64 = "modulo_uint64"
+ NegateInt64 = "negate_int64"
+ NegateDouble = "negate_double"
+)
+
+// Index overloads
+const (
+ IndexList = "index_list"
+ IndexMap = "index_map"
+ IndexMessage = "index_message" // TODO: introduce concept of types.Message
+)
+
+// In operators
+const (
+ DeprecatedIn = "in"
+ InList = "in_list"
+ InMap = "in_map"
+ InMessage = "in_message" // TODO: introduce concept of types.Message
+)
+
+// Size overloads
+const (
+ Size = "size"
+ SizeString = "size_string"
+ SizeBytes = "size_bytes"
+ SizeList = "size_list"
+ SizeMap = "size_map"
+ SizeStringInst = "string_size"
+ SizeBytesInst = "bytes_size"
+ SizeListInst = "list_size"
+ SizeMapInst = "map_size"
+)
+
+// String function names.
+const (
+ Contains = "contains"
+ EndsWith = "endsWith"
+ Matches = "matches"
+ StartsWith = "startsWith"
+)
+
+// Extension function overloads with complex behaviors that need to be referenced in runtime and static analysis cost computations.
+const (
+ ExtQuoteString = "strings_quote"
+)
+
+// String function overload names.
+const (
+ ContainsString = "contains_string"
+ EndsWithString = "ends_with_string"
+ MatchesString = "matches_string"
+ StartsWithString = "starts_with_string"
+)
+
+// Extension function overloads with complex behaviors that need to be referenced in runtime and static analysis cost computations.
+const (
+ ExtFormatString = "string_format"
+)
+
+// Time-based functions.
+const (
+ TimeGetFullYear = "getFullYear"
+ TimeGetMonth = "getMonth"
+ TimeGetDayOfYear = "getDayOfYear"
+ TimeGetDate = "getDate"
+ TimeGetDayOfMonth = "getDayOfMonth"
+ TimeGetDayOfWeek = "getDayOfWeek"
+ TimeGetHours = "getHours"
+ TimeGetMinutes = "getMinutes"
+ TimeGetSeconds = "getSeconds"
+ TimeGetMilliseconds = "getMilliseconds"
+)
+
+// Timestamp overloads for time functions without timezones.
+const (
+ TimestampToYear = "timestamp_to_year"
+ TimestampToMonth = "timestamp_to_month"
+ TimestampToDayOfYear = "timestamp_to_day_of_year"
+ TimestampToDayOfMonthZeroBased = "timestamp_to_day_of_month"
+ TimestampToDayOfMonthOneBased = "timestamp_to_day_of_month_1_based"
+ TimestampToDayOfWeek = "timestamp_to_day_of_week"
+ TimestampToHours = "timestamp_to_hours"
+ TimestampToMinutes = "timestamp_to_minutes"
+ TimestampToSeconds = "timestamp_to_seconds"
+ TimestampToMilliseconds = "timestamp_to_milliseconds"
+)
+
+// Timestamp overloads for time functions with timezones.
+const (
+ TimestampToYearWithTz = "timestamp_to_year_with_tz"
+ TimestampToMonthWithTz = "timestamp_to_month_with_tz"
+ TimestampToDayOfYearWithTz = "timestamp_to_day_of_year_with_tz"
+ TimestampToDayOfMonthZeroBasedWithTz = "timestamp_to_day_of_month_with_tz"
+ TimestampToDayOfMonthOneBasedWithTz = "timestamp_to_day_of_month_1_based_with_tz"
+ TimestampToDayOfWeekWithTz = "timestamp_to_day_of_week_with_tz"
+ TimestampToHoursWithTz = "timestamp_to_hours_with_tz"
+ TimestampToMinutesWithTz = "timestamp_to_minutes_with_tz"
+ TimestampToSecondsWithTz = "timestamp_to_seconds_tz"
+ TimestampToMillisecondsWithTz = "timestamp_to_milliseconds_with_tz"
+)
+
+// Duration overloads for time functions.
+const (
+ DurationToHours = "duration_to_hours"
+ DurationToMinutes = "duration_to_minutes"
+ DurationToSeconds = "duration_to_seconds"
+ DurationToMilliseconds = "duration_to_milliseconds"
+)
+
+// Type conversion methods and overloads
+const (
+ TypeConvertInt = "int"
+ TypeConvertUint = "uint"
+ TypeConvertDouble = "double"
+ TypeConvertBool = "bool"
+ TypeConvertString = "string"
+ TypeConvertBytes = "bytes"
+ TypeConvertTimestamp = "timestamp"
+ TypeConvertDuration = "duration"
+ TypeConvertType = "type"
+ TypeConvertDyn = "dyn"
+)
+
+// Int conversion functions.
+const (
+ IntToInt = "int64_to_int64"
+ UintToInt = "uint64_to_int64"
+ DoubleToInt = "double_to_int64"
+ StringToInt = "string_to_int64"
+ TimestampToInt = "timestamp_to_int64"
+ DurationToInt = "duration_to_int64"
+)
+
+// Uint conversion functions.
+const (
+ UintToUint = "uint64_to_uint64"
+ IntToUint = "int64_to_uint64"
+ DoubleToUint = "double_to_uint64"
+ StringToUint = "string_to_uint64"
+)
+
+// Double conversion functions.
+const (
+ DoubleToDouble = "double_to_double"
+ IntToDouble = "int64_to_double"
+ UintToDouble = "uint64_to_double"
+ StringToDouble = "string_to_double"
+)
+
+// Bool conversion functions.
+const (
+ BoolToBool = "bool_to_bool"
+ StringToBool = "string_to_bool"
+)
+
+// Bytes conversion functions.
+const (
+ BytesToBytes = "bytes_to_bytes"
+ StringToBytes = "string_to_bytes"
+)
+
+// String conversion functions.
+const (
+ StringToString = "string_to_string"
+ BoolToString = "bool_to_string"
+ IntToString = "int64_to_string"
+ UintToString = "uint64_to_string"
+ DoubleToString = "double_to_string"
+ BytesToString = "bytes_to_string"
+ TimestampToString = "timestamp_to_string"
+ DurationToString = "duration_to_string"
+)
+
+// Timestamp conversion functions
+const (
+ TimestampToTimestamp = "timestamp_to_timestamp"
+ StringToTimestamp = "string_to_timestamp"
+ IntToTimestamp = "int64_to_timestamp"
+)
+
+// Convert duration from string
+const (
+ DurationToDuration = "duration_to_duration"
+ StringToDuration = "string_to_duration"
+ IntToDuration = "int64_to_duration"
+)
+
+// Convert to dyn
+const (
+ ToDyn = "to_dyn"
+)
+
+// Comprehensions helper methods, not directly accessible via a developer.
+const (
+ Iterator = "@iterator"
+ HasNext = "@hasNext"
+ Next = "@next"
+)
+
+// IsTypeConversionFunction returns whether the input function is a standard library type
+// conversion function.
+func IsTypeConversionFunction(function string) bool {
+ switch function {
+ case TypeConvertBool,
+ TypeConvertBytes,
+ TypeConvertDouble,
+ TypeConvertDuration,
+ TypeConvertDyn,
+ TypeConvertInt,
+ TypeConvertString,
+ TypeConvertTimestamp,
+ TypeConvertType,
+ TypeConvertUint:
+ return true
+ default:
+ return false
+ }
+}
diff --git a/vendor/github.com/google/cel-go/common/runes/BUILD.bazel b/vendor/github.com/google/cel-go/common/runes/BUILD.bazel
new file mode 100644
index 000000000000..5f3f9aad0dc0
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/runes/BUILD.bazel
@@ -0,0 +1,13 @@
+load("@io_bazel_rules_go//go:def.bzl", "go_library")
+
+package(
+ default_visibility = ["//visibility:public"],
+ licenses = ["notice"], # Apache 2.0
+)
+
+go_library(
+ name = "go_default_library",
+ srcs = ["buffer.go"],
+ importmap = "kubevirt.io/kubevirt/vendor/github.com/google/cel-go/common/runes",
+ importpath = "github.com/google/cel-go/common/runes",
+)
diff --git a/vendor/github.com/google/cel-go/common/runes/buffer.go b/vendor/github.com/google/cel-go/common/runes/buffer.go
new file mode 100644
index 000000000000..021198224dc8
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/runes/buffer.go
@@ -0,0 +1,242 @@
+// Copyright 2021 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+// Package runes provides interfaces and utilities for working with runes.
+package runes
+
+import (
+ "strings"
+ "unicode/utf8"
+)
+
+// Buffer is an interface for accessing a contiguous array of code points.
+type Buffer interface {
+ Get(i int) rune
+ Slice(i, j int) string
+ Len() int
+}
+
+type emptyBuffer struct{}
+
+func (e *emptyBuffer) Get(i int) rune {
+ panic("slice index out of bounds")
+}
+
+func (e *emptyBuffer) Slice(i, j int) string {
+ if i != 0 || i != j {
+ panic("slice index out of bounds")
+ }
+ return ""
+}
+
+func (e *emptyBuffer) Len() int {
+ return 0
+}
+
+var _ Buffer = &emptyBuffer{}
+
+// asciiBuffer is an implementation for an array of code points that contain code points only from
+// the ASCII character set.
+type asciiBuffer struct {
+ arr []byte
+}
+
+func (a *asciiBuffer) Get(i int) rune {
+ return rune(uint32(a.arr[i]))
+}
+
+func (a *asciiBuffer) Slice(i, j int) string {
+ return string(a.arr[i:j])
+}
+
+func (a *asciiBuffer) Len() int {
+ return len(a.arr)
+}
+
+var _ Buffer = &asciiBuffer{}
+
+// basicBuffer is an implementation for an array of code points that contain code points from both
+// the Latin-1 character set and Basic Multilingual Plane.
+type basicBuffer struct {
+ arr []uint16
+}
+
+func (b *basicBuffer) Get(i int) rune {
+ return rune(uint32(b.arr[i]))
+}
+
+func (b *basicBuffer) Slice(i, j int) string {
+ var str strings.Builder
+ str.Grow((j - i) * 3) // Worst case encoding size for 0xffff is 3.
+ for ; i < j; i++ {
+ str.WriteRune(rune(uint32(b.arr[i])))
+ }
+ return str.String()
+}
+
+func (b *basicBuffer) Len() int {
+ return len(b.arr)
+}
+
+var _ Buffer = &basicBuffer{}
+
+// supplementalBuffer is an implementation for an array of code points that contain code points from
+// the Latin-1 character set, Basic Multilingual Plane, or the Supplemental Multilingual Plane.
+type supplementalBuffer struct {
+ arr []rune
+}
+
+func (s *supplementalBuffer) Get(i int) rune {
+ return rune(uint32(s.arr[i]))
+}
+
+func (s *supplementalBuffer) Slice(i, j int) string {
+ return string(s.arr[i:j])
+}
+
+func (s *supplementalBuffer) Len() int {
+ return len(s.arr)
+}
+
+var _ Buffer = &supplementalBuffer{}
+
+var nilBuffer = &emptyBuffer{}
+
+// NewBuffer returns an efficient implementation of Buffer for the given text based on the ranges of
+// the encoded code points contained within.
+//
+// Code points are represented as an array of byte, uint16, or rune. This approach ensures that
+// each index represents a code point by itself without needing to use an array of rune. At first
+// we assume all code points are less than or equal to '\u007f'. If this holds true, the
+// underlying storage is a byte array containing only ASCII characters. If we encountered a code
+// point above this range but less than or equal to '\uffff' we allocate a uint16 array, copy the
+// elements of previous byte array to the uint16 array, and continue. If this holds true, the
+// underlying storage is a uint16 array containing only Unicode characters in the Basic Multilingual
+// Plane. If we encounter a code point above '\uffff' we allocate an rune array, copy the previous
+// elements of the byte or uint16 array, and continue. The underlying storage is an rune array
+// containing any Unicode character.
+func NewBuffer(data string) Buffer {
+ buf, _ := newBuffer(data, false)
+ return buf
+}
+
+// NewBufferAndLineOffsets returns an efficient implementation of Buffer for the given text based on
+// the ranges of the encoded code points contained within, as well as returning the line offsets.
+//
+// Code points are represented as an array of byte, uint16, or rune. This approach ensures that
+// each index represents a code point by itself without needing to use an array of rune. At first
+// we assume all code points are less than or equal to '\u007f'. If this holds true, the
+// underlying storage is a byte array containing only ASCII characters. If we encountered a code
+// point above this range but less than or equal to '\uffff' we allocate a uint16 array, copy the
+// elements of previous byte array to the uint16 array, and continue. If this holds true, the
+// underlying storage is a uint16 array containing only Unicode characters in the Basic Multilingual
+// Plane. If we encounter a code point above '\uffff' we allocate an rune array, copy the previous
+// elements of the byte or uint16 array, and continue. The underlying storage is an rune array
+// containing any Unicode character.
+func NewBufferAndLineOffsets(data string) (Buffer, []int32) {
+ return newBuffer(data, true)
+}
+
+func newBuffer(data string, lines bool) (Buffer, []int32) {
+ if len(data) == 0 {
+ return nilBuffer, []int32{0}
+ }
+ var (
+ idx = 0
+ off int32 = 0
+ buf8 = make([]byte, 0, len(data))
+ buf16 []uint16
+ buf32 []rune
+ offs []int32
+ )
+ for idx < len(data) {
+ r, s := utf8.DecodeRuneInString(data[idx:])
+ idx += s
+ if lines && r == '\n' {
+ offs = append(offs, off+1)
+ }
+ if r < utf8.RuneSelf {
+ buf8 = append(buf8, byte(r))
+ off++
+ continue
+ }
+ if r <= 0xffff {
+ buf16 = make([]uint16, len(buf8), len(data))
+ for i, v := range buf8 {
+ buf16[i] = uint16(v)
+ }
+ buf8 = nil
+ buf16 = append(buf16, uint16(r))
+ off++
+ goto copy16
+ }
+ buf32 = make([]rune, len(buf8), len(data))
+ for i, v := range buf8 {
+ buf32[i] = rune(uint32(v))
+ }
+ buf8 = nil
+ buf32 = append(buf32, r)
+ off++
+ goto copy32
+ }
+ if lines {
+ offs = append(offs, off+1)
+ }
+ return &asciiBuffer{
+ arr: buf8,
+ }, offs
+copy16:
+ for idx < len(data) {
+ r, s := utf8.DecodeRuneInString(data[idx:])
+ idx += s
+ if lines && r == '\n' {
+ offs = append(offs, off+1)
+ }
+ if r <= 0xffff {
+ buf16 = append(buf16, uint16(r))
+ off++
+ continue
+ }
+ buf32 = make([]rune, len(buf16), len(data))
+ for i, v := range buf16 {
+ buf32[i] = rune(uint32(v))
+ }
+ buf16 = nil
+ buf32 = append(buf32, r)
+ off++
+ goto copy32
+ }
+ if lines {
+ offs = append(offs, off+1)
+ }
+ return &basicBuffer{
+ arr: buf16,
+ }, offs
+copy32:
+ for idx < len(data) {
+ r, s := utf8.DecodeRuneInString(data[idx:])
+ idx += s
+ if lines && r == '\n' {
+ offs = append(offs, off+1)
+ }
+ buf32 = append(buf32, r)
+ off++
+ }
+ if lines {
+ offs = append(offs, off+1)
+ }
+ return &supplementalBuffer{
+ arr: buf32,
+ }, offs
+}
diff --git a/vendor/github.com/google/cel-go/common/source.go b/vendor/github.com/google/cel-go/common/source.go
new file mode 100644
index 000000000000..ec79cb5454e5
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/source.go
@@ -0,0 +1,173 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package common
+
+import (
+ "github.com/google/cel-go/common/runes"
+
+ exprpb "google.golang.org/genproto/googleapis/api/expr/v1alpha1"
+)
+
+// Source interface for filter source contents.
+type Source interface {
+ // Content returns the source content represented as a string.
+ // Examples contents are the single file contents, textbox field,
+ // or url parameter.
+ Content() string
+
+ // Description gives a brief description of the source.
+ // Example descriptions are a file name or ui element.
+ Description() string
+
+ // LineOffsets gives the character offsets at which lines occur.
+ // The zero-th entry should refer to the break between the first
+ // and second line, or EOF if there is only one line of source.
+ LineOffsets() []int32
+
+ // LocationOffset translates a Location to an offset.
+ // Given the line and column of the Location returns the
+ // Location's character offset in the Source, and a bool
+ // indicating whether the Location was found.
+ LocationOffset(location Location) (int32, bool)
+
+ // OffsetLocation translates a character offset to a Location, or
+ // false if the conversion was not feasible.
+ OffsetLocation(offset int32) (Location, bool)
+
+ // NewLocation takes an input line and column and produces a Location.
+ // The default behavior is to treat the line and column as absolute,
+ // but concrete derivations may use this method to convert a relative
+ // line and column position into an absolute location.
+ NewLocation(line, col int) Location
+
+ // Snippet returns a line of content and whether the line was found.
+ Snippet(line int) (string, bool)
+}
+
+// The sourceImpl type implementation of the Source interface.
+type sourceImpl struct {
+ runes.Buffer
+ description string
+ lineOffsets []int32
+}
+
+var _ runes.Buffer = &sourceImpl{}
+
+// TODO(jimlarson) "Character offsets" should index the code points
+// within the UTF-8 encoded string. It currently indexes bytes.
+// Can be accomplished by using rune[] instead of string for contents.
+
+// NewTextSource creates a new Source from the input text string.
+func NewTextSource(text string) Source {
+ return NewStringSource(text, "")
+}
+
+// NewStringSource creates a new Source from the given contents and description.
+func NewStringSource(contents string, description string) Source {
+ // Compute line offsets up front as they are referred to frequently.
+ buf, offs := runes.NewBufferAndLineOffsets(contents)
+ return &sourceImpl{
+ Buffer: buf,
+ description: description,
+ lineOffsets: offs,
+ }
+}
+
+// NewInfoSource creates a new Source from a SourceInfo.
+func NewInfoSource(info *exprpb.SourceInfo) Source {
+ return &sourceImpl{
+ Buffer: runes.NewBuffer(""),
+ description: info.GetLocation(),
+ lineOffsets: info.GetLineOffsets(),
+ }
+}
+
+// Content implements the Source interface method.
+func (s *sourceImpl) Content() string {
+ return s.Slice(0, s.Len())
+}
+
+// Description implements the Source interface method.
+func (s *sourceImpl) Description() string {
+ return s.description
+}
+
+// LineOffsets implements the Source interface method.
+func (s *sourceImpl) LineOffsets() []int32 {
+ return s.lineOffsets
+}
+
+// LocationOffset implements the Source interface method.
+func (s *sourceImpl) LocationOffset(location Location) (int32, bool) {
+ if lineOffset, found := s.findLineOffset(location.Line()); found {
+ return lineOffset + int32(location.Column()), true
+ }
+ return -1, false
+}
+
+// NewLocation implements the Source interface method.
+func (s *sourceImpl) NewLocation(line, col int) Location {
+ return NewLocation(line, col)
+}
+
+// OffsetLocation implements the Source interface method.
+func (s *sourceImpl) OffsetLocation(offset int32) (Location, bool) {
+ line, lineOffset := s.findLine(offset)
+ return NewLocation(int(line), int(offset-lineOffset)), true
+}
+
+// Snippet implements the Source interface method.
+func (s *sourceImpl) Snippet(line int) (string, bool) {
+ charStart, found := s.findLineOffset(line)
+ if !found || s.Len() == 0 {
+ return "", false
+ }
+ charEnd, found := s.findLineOffset(line + 1)
+ if found {
+ return s.Slice(int(charStart), int(charEnd-1)), true
+ }
+ return s.Slice(int(charStart), s.Len()), true
+}
+
+// findLineOffset returns the offset where the (1-indexed) line begins,
+// or false if line doesn't exist.
+func (s *sourceImpl) findLineOffset(line int) (int32, bool) {
+ if line == 1 {
+ return 0, true
+ }
+ if line > 1 && line <= int(len(s.lineOffsets)) {
+ offset := s.lineOffsets[line-2]
+ return offset, true
+ }
+ return -1, false
+}
+
+// findLine finds the line that contains the given character offset and
+// returns the line number and offset of the beginning of that line.
+// Note that the last line is treated as if it contains all offsets
+// beyond the end of the actual source.
+func (s *sourceImpl) findLine(characterOffset int32) (int32, int32) {
+ var line int32 = 1
+ for _, lineOffset := range s.lineOffsets {
+ if lineOffset > characterOffset {
+ break
+ }
+ line++
+ }
+ if line == 1 {
+ return line, 0
+ }
+ return line, s.lineOffsets[line-2]
+}
diff --git a/vendor/github.com/google/cel-go/common/stdlib/BUILD.bazel b/vendor/github.com/google/cel-go/common/stdlib/BUILD.bazel
new file mode 100644
index 000000000000..3e0ea7bd2ca7
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/stdlib/BUILD.bazel
@@ -0,0 +1,22 @@
+load("@io_bazel_rules_go//go:def.bzl", "go_library")
+
+package(
+ default_visibility = ["//visibility:public"],
+ licenses = ["notice"], # Apache 2.0
+)
+
+go_library(
+ name = "go_default_library",
+ srcs = ["standard.go"],
+ importmap = "kubevirt.io/kubevirt/vendor/github.com/google/cel-go/common/stdlib",
+ importpath = "github.com/google/cel-go/common/stdlib",
+ deps = [
+ "//vendor/github.com/google/cel-go/common/decls:go_default_library",
+ "//vendor/github.com/google/cel-go/common/functions:go_default_library",
+ "//vendor/github.com/google/cel-go/common/operators:go_default_library",
+ "//vendor/github.com/google/cel-go/common/overloads:go_default_library",
+ "//vendor/github.com/google/cel-go/common/types:go_default_library",
+ "//vendor/github.com/google/cel-go/common/types/ref:go_default_library",
+ "//vendor/github.com/google/cel-go/common/types/traits:go_default_library",
+ ],
+)
diff --git a/vendor/github.com/google/cel-go/common/stdlib/standard.go b/vendor/github.com/google/cel-go/common/stdlib/standard.go
new file mode 100644
index 000000000000..1550c1786387
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/stdlib/standard.go
@@ -0,0 +1,620 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+// Package stdlib contains all of the standard library function declarations and definitions for CEL.
+package stdlib
+
+import (
+ "github.com/google/cel-go/common/decls"
+ "github.com/google/cel-go/common/functions"
+ "github.com/google/cel-go/common/operators"
+ "github.com/google/cel-go/common/overloads"
+ "github.com/google/cel-go/common/types"
+ "github.com/google/cel-go/common/types/ref"
+ "github.com/google/cel-go/common/types/traits"
+)
+
+var (
+ stdFunctions []*decls.FunctionDecl
+ stdTypes []*decls.VariableDecl
+)
+
+func init() {
+ paramA := types.NewTypeParamType("A")
+ paramB := types.NewTypeParamType("B")
+ listOfA := types.NewListType(paramA)
+ mapOfAB := types.NewMapType(paramA, paramB)
+
+ stdTypes = []*decls.VariableDecl{
+ decls.TypeVariable(types.BoolType),
+ decls.TypeVariable(types.BytesType),
+ decls.TypeVariable(types.DoubleType),
+ decls.TypeVariable(types.DurationType),
+ decls.TypeVariable(types.IntType),
+ decls.TypeVariable(listOfA),
+ decls.TypeVariable(mapOfAB),
+ decls.TypeVariable(types.NullType),
+ decls.TypeVariable(types.StringType),
+ decls.TypeVariable(types.TimestampType),
+ decls.TypeVariable(types.TypeType),
+ decls.TypeVariable(types.UintType),
+ }
+
+ stdFunctions = []*decls.FunctionDecl{
+ // Logical operators. Special-cased within the interpreter.
+ // Note, the singleton binding prevents extensions from overriding the operator behavior.
+ function(operators.Conditional,
+ decls.Overload(overloads.Conditional, argTypes(types.BoolType, paramA, paramA), paramA,
+ decls.OverloadIsNonStrict()),
+ decls.SingletonFunctionBinding(noFunctionOverrides)),
+ function(operators.LogicalAnd,
+ decls.Overload(overloads.LogicalAnd, argTypes(types.BoolType, types.BoolType), types.BoolType,
+ decls.OverloadIsNonStrict()),
+ decls.SingletonBinaryBinding(noBinaryOverrides)),
+ function(operators.LogicalOr,
+ decls.Overload(overloads.LogicalOr, argTypes(types.BoolType, types.BoolType), types.BoolType,
+ decls.OverloadIsNonStrict()),
+ decls.SingletonBinaryBinding(noBinaryOverrides)),
+ function(operators.LogicalNot,
+ decls.Overload(overloads.LogicalNot, argTypes(types.BoolType), types.BoolType),
+ decls.SingletonUnaryBinding(func(val ref.Val) ref.Val {
+ b, ok := val.(types.Bool)
+ if !ok {
+ return types.MaybeNoSuchOverloadErr(val)
+ }
+ return b.Negate()
+ })),
+
+ // Comprehension short-circuiting related function
+ function(operators.NotStrictlyFalse,
+ decls.Overload(overloads.NotStrictlyFalse, argTypes(types.BoolType), types.BoolType,
+ decls.OverloadIsNonStrict(),
+ decls.UnaryBinding(notStrictlyFalse))),
+ // Deprecated: __not_strictly_false__
+ function(operators.OldNotStrictlyFalse,
+ decls.DisableDeclaration(true), // safe deprecation
+ decls.Overload(operators.OldNotStrictlyFalse, argTypes(types.BoolType), types.BoolType,
+ decls.OverloadIsNonStrict(),
+ decls.UnaryBinding(notStrictlyFalse))),
+
+ // Equality / inequality. Special-cased in the interpreter
+ function(operators.Equals,
+ decls.Overload(overloads.Equals, argTypes(paramA, paramA), types.BoolType),
+ decls.SingletonBinaryBinding(noBinaryOverrides)),
+ function(operators.NotEquals,
+ decls.Overload(overloads.NotEquals, argTypes(paramA, paramA), types.BoolType),
+ decls.SingletonBinaryBinding(noBinaryOverrides)),
+
+ // Mathematical operators
+ function(operators.Add,
+ decls.Overload(overloads.AddBytes,
+ argTypes(types.BytesType, types.BytesType), types.BytesType),
+ decls.Overload(overloads.AddDouble,
+ argTypes(types.DoubleType, types.DoubleType), types.DoubleType),
+ decls.Overload(overloads.AddDurationDuration,
+ argTypes(types.DurationType, types.DurationType), types.DurationType),
+ decls.Overload(overloads.AddDurationTimestamp,
+ argTypes(types.DurationType, types.TimestampType), types.TimestampType),
+ decls.Overload(overloads.AddTimestampDuration,
+ argTypes(types.TimestampType, types.DurationType), types.TimestampType),
+ decls.Overload(overloads.AddInt64,
+ argTypes(types.IntType, types.IntType), types.IntType),
+ decls.Overload(overloads.AddList,
+ argTypes(listOfA, listOfA), listOfA),
+ decls.Overload(overloads.AddString,
+ argTypes(types.StringType, types.StringType), types.StringType),
+ decls.Overload(overloads.AddUint64,
+ argTypes(types.UintType, types.UintType), types.UintType),
+ decls.SingletonBinaryBinding(func(lhs, rhs ref.Val) ref.Val {
+ return lhs.(traits.Adder).Add(rhs)
+ }, traits.AdderType)),
+ function(operators.Divide,
+ decls.Overload(overloads.DivideDouble,
+ argTypes(types.DoubleType, types.DoubleType), types.DoubleType),
+ decls.Overload(overloads.DivideInt64,
+ argTypes(types.IntType, types.IntType), types.IntType),
+ decls.Overload(overloads.DivideUint64,
+ argTypes(types.UintType, types.UintType), types.UintType),
+ decls.SingletonBinaryBinding(func(lhs, rhs ref.Val) ref.Val {
+ return lhs.(traits.Divider).Divide(rhs)
+ }, traits.DividerType)),
+ function(operators.Modulo,
+ decls.Overload(overloads.ModuloInt64,
+ argTypes(types.IntType, types.IntType), types.IntType),
+ decls.Overload(overloads.ModuloUint64,
+ argTypes(types.UintType, types.UintType), types.UintType),
+ decls.SingletonBinaryBinding(func(lhs, rhs ref.Val) ref.Val {
+ return lhs.(traits.Modder).Modulo(rhs)
+ }, traits.ModderType)),
+ function(operators.Multiply,
+ decls.Overload(overloads.MultiplyDouble,
+ argTypes(types.DoubleType, types.DoubleType), types.DoubleType),
+ decls.Overload(overloads.MultiplyInt64,
+ argTypes(types.IntType, types.IntType), types.IntType),
+ decls.Overload(overloads.MultiplyUint64,
+ argTypes(types.UintType, types.UintType), types.UintType),
+ decls.SingletonBinaryBinding(func(lhs, rhs ref.Val) ref.Val {
+ return lhs.(traits.Multiplier).Multiply(rhs)
+ }, traits.MultiplierType)),
+ function(operators.Negate,
+ decls.Overload(overloads.NegateDouble, argTypes(types.DoubleType), types.DoubleType),
+ decls.Overload(overloads.NegateInt64, argTypes(types.IntType), types.IntType),
+ decls.SingletonUnaryBinding(func(val ref.Val) ref.Val {
+ if types.IsBool(val) {
+ return types.MaybeNoSuchOverloadErr(val)
+ }
+ return val.(traits.Negater).Negate()
+ }, traits.NegatorType)),
+ function(operators.Subtract,
+ decls.Overload(overloads.SubtractDouble,
+ argTypes(types.DoubleType, types.DoubleType), types.DoubleType),
+ decls.Overload(overloads.SubtractDurationDuration,
+ argTypes(types.DurationType, types.DurationType), types.DurationType),
+ decls.Overload(overloads.SubtractInt64,
+ argTypes(types.IntType, types.IntType), types.IntType),
+ decls.Overload(overloads.SubtractTimestampDuration,
+ argTypes(types.TimestampType, types.DurationType), types.TimestampType),
+ decls.Overload(overloads.SubtractTimestampTimestamp,
+ argTypes(types.TimestampType, types.TimestampType), types.DurationType),
+ decls.Overload(overloads.SubtractUint64,
+ argTypes(types.UintType, types.UintType), types.UintType),
+ decls.SingletonBinaryBinding(func(lhs, rhs ref.Val) ref.Val {
+ return lhs.(traits.Subtractor).Subtract(rhs)
+ }, traits.SubtractorType)),
+
+ // Relations operators
+
+ function(operators.Less,
+ decls.Overload(overloads.LessBool,
+ argTypes(types.BoolType, types.BoolType), types.BoolType),
+ decls.Overload(overloads.LessInt64,
+ argTypes(types.IntType, types.IntType), types.BoolType),
+ decls.Overload(overloads.LessInt64Double,
+ argTypes(types.IntType, types.DoubleType), types.BoolType),
+ decls.Overload(overloads.LessInt64Uint64,
+ argTypes(types.IntType, types.UintType), types.BoolType),
+ decls.Overload(overloads.LessUint64,
+ argTypes(types.UintType, types.UintType), types.BoolType),
+ decls.Overload(overloads.LessUint64Double,
+ argTypes(types.UintType, types.DoubleType), types.BoolType),
+ decls.Overload(overloads.LessUint64Int64,
+ argTypes(types.UintType, types.IntType), types.BoolType),
+ decls.Overload(overloads.LessDouble,
+ argTypes(types.DoubleType, types.DoubleType), types.BoolType),
+ decls.Overload(overloads.LessDoubleInt64,
+ argTypes(types.DoubleType, types.IntType), types.BoolType),
+ decls.Overload(overloads.LessDoubleUint64,
+ argTypes(types.DoubleType, types.UintType), types.BoolType),
+ decls.Overload(overloads.LessString,
+ argTypes(types.StringType, types.StringType), types.BoolType),
+ decls.Overload(overloads.LessBytes,
+ argTypes(types.BytesType, types.BytesType), types.BoolType),
+ decls.Overload(overloads.LessTimestamp,
+ argTypes(types.TimestampType, types.TimestampType), types.BoolType),
+ decls.Overload(overloads.LessDuration,
+ argTypes(types.DurationType, types.DurationType), types.BoolType),
+ decls.SingletonBinaryBinding(func(lhs, rhs ref.Val) ref.Val {
+ cmp := lhs.(traits.Comparer).Compare(rhs)
+ if cmp == types.IntNegOne {
+ return types.True
+ }
+ if cmp == types.IntOne || cmp == types.IntZero {
+ return types.False
+ }
+ return cmp
+ }, traits.ComparerType)),
+
+ function(operators.LessEquals,
+ decls.Overload(overloads.LessEqualsBool,
+ argTypes(types.BoolType, types.BoolType), types.BoolType),
+ decls.Overload(overloads.LessEqualsInt64,
+ argTypes(types.IntType, types.IntType), types.BoolType),
+ decls.Overload(overloads.LessEqualsInt64Double,
+ argTypes(types.IntType, types.DoubleType), types.BoolType),
+ decls.Overload(overloads.LessEqualsInt64Uint64,
+ argTypes(types.IntType, types.UintType), types.BoolType),
+ decls.Overload(overloads.LessEqualsUint64,
+ argTypes(types.UintType, types.UintType), types.BoolType),
+ decls.Overload(overloads.LessEqualsUint64Double,
+ argTypes(types.UintType, types.DoubleType), types.BoolType),
+ decls.Overload(overloads.LessEqualsUint64Int64,
+ argTypes(types.UintType, types.IntType), types.BoolType),
+ decls.Overload(overloads.LessEqualsDouble,
+ argTypes(types.DoubleType, types.DoubleType), types.BoolType),
+ decls.Overload(overloads.LessEqualsDoubleInt64,
+ argTypes(types.DoubleType, types.IntType), types.BoolType),
+ decls.Overload(overloads.LessEqualsDoubleUint64,
+ argTypes(types.DoubleType, types.UintType), types.BoolType),
+ decls.Overload(overloads.LessEqualsString,
+ argTypes(types.StringType, types.StringType), types.BoolType),
+ decls.Overload(overloads.LessEqualsBytes,
+ argTypes(types.BytesType, types.BytesType), types.BoolType),
+ decls.Overload(overloads.LessEqualsTimestamp,
+ argTypes(types.TimestampType, types.TimestampType), types.BoolType),
+ decls.Overload(overloads.LessEqualsDuration,
+ argTypes(types.DurationType, types.DurationType), types.BoolType),
+ decls.SingletonBinaryBinding(func(lhs, rhs ref.Val) ref.Val {
+ cmp := lhs.(traits.Comparer).Compare(rhs)
+ if cmp == types.IntNegOne || cmp == types.IntZero {
+ return types.True
+ }
+ if cmp == types.IntOne {
+ return types.False
+ }
+ return cmp
+ }, traits.ComparerType)),
+
+ function(operators.Greater,
+ decls.Overload(overloads.GreaterBool,
+ argTypes(types.BoolType, types.BoolType), types.BoolType),
+ decls.Overload(overloads.GreaterInt64,
+ argTypes(types.IntType, types.IntType), types.BoolType),
+ decls.Overload(overloads.GreaterInt64Double,
+ argTypes(types.IntType, types.DoubleType), types.BoolType),
+ decls.Overload(overloads.GreaterInt64Uint64,
+ argTypes(types.IntType, types.UintType), types.BoolType),
+ decls.Overload(overloads.GreaterUint64,
+ argTypes(types.UintType, types.UintType), types.BoolType),
+ decls.Overload(overloads.GreaterUint64Double,
+ argTypes(types.UintType, types.DoubleType), types.BoolType),
+ decls.Overload(overloads.GreaterUint64Int64,
+ argTypes(types.UintType, types.IntType), types.BoolType),
+ decls.Overload(overloads.GreaterDouble,
+ argTypes(types.DoubleType, types.DoubleType), types.BoolType),
+ decls.Overload(overloads.GreaterDoubleInt64,
+ argTypes(types.DoubleType, types.IntType), types.BoolType),
+ decls.Overload(overloads.GreaterDoubleUint64,
+ argTypes(types.DoubleType, types.UintType), types.BoolType),
+ decls.Overload(overloads.GreaterString,
+ argTypes(types.StringType, types.StringType), types.BoolType),
+ decls.Overload(overloads.GreaterBytes,
+ argTypes(types.BytesType, types.BytesType), types.BoolType),
+ decls.Overload(overloads.GreaterTimestamp,
+ argTypes(types.TimestampType, types.TimestampType), types.BoolType),
+ decls.Overload(overloads.GreaterDuration,
+ argTypes(types.DurationType, types.DurationType), types.BoolType),
+ decls.SingletonBinaryBinding(func(lhs, rhs ref.Val) ref.Val {
+ cmp := lhs.(traits.Comparer).Compare(rhs)
+ if cmp == types.IntOne {
+ return types.True
+ }
+ if cmp == types.IntNegOne || cmp == types.IntZero {
+ return types.False
+ }
+ return cmp
+ }, traits.ComparerType)),
+
+ function(operators.GreaterEquals,
+ decls.Overload(overloads.GreaterEqualsBool,
+ argTypes(types.BoolType, types.BoolType), types.BoolType),
+ decls.Overload(overloads.GreaterEqualsInt64,
+ argTypes(types.IntType, types.IntType), types.BoolType),
+ decls.Overload(overloads.GreaterEqualsInt64Double,
+ argTypes(types.IntType, types.DoubleType), types.BoolType),
+ decls.Overload(overloads.GreaterEqualsInt64Uint64,
+ argTypes(types.IntType, types.UintType), types.BoolType),
+ decls.Overload(overloads.GreaterEqualsUint64,
+ argTypes(types.UintType, types.UintType), types.BoolType),
+ decls.Overload(overloads.GreaterEqualsUint64Double,
+ argTypes(types.UintType, types.DoubleType), types.BoolType),
+ decls.Overload(overloads.GreaterEqualsUint64Int64,
+ argTypes(types.UintType, types.IntType), types.BoolType),
+ decls.Overload(overloads.GreaterEqualsDouble,
+ argTypes(types.DoubleType, types.DoubleType), types.BoolType),
+ decls.Overload(overloads.GreaterEqualsDoubleInt64,
+ argTypes(types.DoubleType, types.IntType), types.BoolType),
+ decls.Overload(overloads.GreaterEqualsDoubleUint64,
+ argTypes(types.DoubleType, types.UintType), types.BoolType),
+ decls.Overload(overloads.GreaterEqualsString,
+ argTypes(types.StringType, types.StringType), types.BoolType),
+ decls.Overload(overloads.GreaterEqualsBytes,
+ argTypes(types.BytesType, types.BytesType), types.BoolType),
+ decls.Overload(overloads.GreaterEqualsTimestamp,
+ argTypes(types.TimestampType, types.TimestampType), types.BoolType),
+ decls.Overload(overloads.GreaterEqualsDuration,
+ argTypes(types.DurationType, types.DurationType), types.BoolType),
+ decls.SingletonBinaryBinding(func(lhs, rhs ref.Val) ref.Val {
+ cmp := lhs.(traits.Comparer).Compare(rhs)
+ if cmp == types.IntOne || cmp == types.IntZero {
+ return types.True
+ }
+ if cmp == types.IntNegOne {
+ return types.False
+ }
+ return cmp
+ }, traits.ComparerType)),
+
+ // Indexing
+ function(operators.Index,
+ decls.Overload(overloads.IndexList, argTypes(listOfA, types.IntType), paramA),
+ decls.Overload(overloads.IndexMap, argTypes(mapOfAB, paramA), paramB),
+ decls.SingletonBinaryBinding(func(lhs, rhs ref.Val) ref.Val {
+ return lhs.(traits.Indexer).Get(rhs)
+ }, traits.IndexerType)),
+
+ // Collections operators
+ function(operators.In,
+ decls.Overload(overloads.InList, argTypes(paramA, listOfA), types.BoolType),
+ decls.Overload(overloads.InMap, argTypes(paramA, mapOfAB), types.BoolType),
+ decls.SingletonBinaryBinding(inAggregate)),
+ function(operators.OldIn,
+ decls.DisableDeclaration(true), // safe deprecation
+ decls.Overload(overloads.InList, argTypes(paramA, listOfA), types.BoolType),
+ decls.Overload(overloads.InMap, argTypes(paramA, mapOfAB), types.BoolType),
+ decls.SingletonBinaryBinding(inAggregate)),
+ function(overloads.DeprecatedIn,
+ decls.DisableDeclaration(true), // safe deprecation
+ decls.Overload(overloads.InList, argTypes(paramA, listOfA), types.BoolType),
+ decls.Overload(overloads.InMap, argTypes(paramA, mapOfAB), types.BoolType),
+ decls.SingletonBinaryBinding(inAggregate)),
+ function(overloads.Size,
+ decls.Overload(overloads.SizeBytes, argTypes(types.BytesType), types.IntType),
+ decls.MemberOverload(overloads.SizeBytesInst, argTypes(types.BytesType), types.IntType),
+ decls.Overload(overloads.SizeList, argTypes(listOfA), types.IntType),
+ decls.MemberOverload(overloads.SizeListInst, argTypes(listOfA), types.IntType),
+ decls.Overload(overloads.SizeMap, argTypes(mapOfAB), types.IntType),
+ decls.MemberOverload(overloads.SizeMapInst, argTypes(mapOfAB), types.IntType),
+ decls.Overload(overloads.SizeString, argTypes(types.StringType), types.IntType),
+ decls.MemberOverload(overloads.SizeStringInst, argTypes(types.StringType), types.IntType),
+ decls.SingletonUnaryBinding(func(val ref.Val) ref.Val {
+ return val.(traits.Sizer).Size()
+ }, traits.SizerType)),
+
+ // Type conversions
+ function(overloads.TypeConvertType,
+ decls.Overload(overloads.TypeConvertType, argTypes(paramA), types.NewTypeTypeWithParam(paramA)),
+ decls.SingletonUnaryBinding(convertToType(types.TypeType))),
+
+ // Bool conversions
+ function(overloads.TypeConvertBool,
+ decls.Overload(overloads.BoolToBool, argTypes(types.BoolType), types.BoolType,
+ decls.UnaryBinding(identity)),
+ decls.Overload(overloads.StringToBool, argTypes(types.StringType), types.BoolType,
+ decls.UnaryBinding(convertToType(types.BoolType)))),
+
+ // Bytes conversions
+ function(overloads.TypeConvertBytes,
+ decls.Overload(overloads.BytesToBytes, argTypes(types.BytesType), types.BytesType,
+ decls.UnaryBinding(identity)),
+ decls.Overload(overloads.StringToBytes, argTypes(types.StringType), types.BytesType,
+ decls.UnaryBinding(convertToType(types.BytesType)))),
+
+ // Double conversions
+ function(overloads.TypeConvertDouble,
+ decls.Overload(overloads.DoubleToDouble, argTypes(types.DoubleType), types.DoubleType,
+ decls.UnaryBinding(identity)),
+ decls.Overload(overloads.IntToDouble, argTypes(types.IntType), types.DoubleType,
+ decls.UnaryBinding(convertToType(types.DoubleType))),
+ decls.Overload(overloads.StringToDouble, argTypes(types.StringType), types.DoubleType,
+ decls.UnaryBinding(convertToType(types.DoubleType))),
+ decls.Overload(overloads.UintToDouble, argTypes(types.UintType), types.DoubleType,
+ decls.UnaryBinding(convertToType(types.DoubleType)))),
+
+ // Duration conversions
+ function(overloads.TypeConvertDuration,
+ decls.Overload(overloads.DurationToDuration, argTypes(types.DurationType), types.DurationType,
+ decls.UnaryBinding(identity)),
+ decls.Overload(overloads.IntToDuration, argTypes(types.IntType), types.DurationType,
+ decls.UnaryBinding(convertToType(types.DurationType))),
+ decls.Overload(overloads.StringToDuration, argTypes(types.StringType), types.DurationType,
+ decls.UnaryBinding(convertToType(types.DurationType)))),
+
+ // Dyn conversions
+ function(overloads.TypeConvertDyn,
+ decls.Overload(overloads.ToDyn, argTypes(paramA), types.DynType),
+ decls.SingletonUnaryBinding(identity)),
+
+ // Int conversions
+ function(overloads.TypeConvertInt,
+ decls.Overload(overloads.IntToInt, argTypes(types.IntType), types.IntType,
+ decls.UnaryBinding(identity)),
+ decls.Overload(overloads.DoubleToInt, argTypes(types.DoubleType), types.IntType,
+ decls.UnaryBinding(convertToType(types.IntType))),
+ decls.Overload(overloads.DurationToInt, argTypes(types.DurationType), types.IntType,
+ decls.UnaryBinding(convertToType(types.IntType))),
+ decls.Overload(overloads.StringToInt, argTypes(types.StringType), types.IntType,
+ decls.UnaryBinding(convertToType(types.IntType))),
+ decls.Overload(overloads.TimestampToInt, argTypes(types.TimestampType), types.IntType,
+ decls.UnaryBinding(convertToType(types.IntType))),
+ decls.Overload(overloads.UintToInt, argTypes(types.UintType), types.IntType,
+ decls.UnaryBinding(convertToType(types.IntType))),
+ ),
+
+ // String conversions
+ function(overloads.TypeConvertString,
+ decls.Overload(overloads.StringToString, argTypes(types.StringType), types.StringType,
+ decls.UnaryBinding(identity)),
+ decls.Overload(overloads.BoolToString, argTypes(types.BoolType), types.StringType,
+ decls.UnaryBinding(convertToType(types.StringType))),
+ decls.Overload(overloads.BytesToString, argTypes(types.BytesType), types.StringType,
+ decls.UnaryBinding(convertToType(types.StringType))),
+ decls.Overload(overloads.DoubleToString, argTypes(types.DoubleType), types.StringType,
+ decls.UnaryBinding(convertToType(types.StringType))),
+ decls.Overload(overloads.DurationToString, argTypes(types.DurationType), types.StringType,
+ decls.UnaryBinding(convertToType(types.StringType))),
+ decls.Overload(overloads.IntToString, argTypes(types.IntType), types.StringType,
+ decls.UnaryBinding(convertToType(types.StringType))),
+ decls.Overload(overloads.TimestampToString, argTypes(types.TimestampType), types.StringType,
+ decls.UnaryBinding(convertToType(types.StringType))),
+ decls.Overload(overloads.UintToString, argTypes(types.UintType), types.StringType,
+ decls.UnaryBinding(convertToType(types.StringType)))),
+
+ // Timestamp conversions
+ function(overloads.TypeConvertTimestamp,
+ decls.Overload(overloads.TimestampToTimestamp, argTypes(types.TimestampType), types.TimestampType,
+ decls.UnaryBinding(identity)),
+ decls.Overload(overloads.IntToTimestamp, argTypes(types.IntType), types.TimestampType,
+ decls.UnaryBinding(convertToType(types.TimestampType))),
+ decls.Overload(overloads.StringToTimestamp, argTypes(types.StringType), types.TimestampType,
+ decls.UnaryBinding(convertToType(types.TimestampType)))),
+
+ // Uint conversions
+ function(overloads.TypeConvertUint,
+ decls.Overload(overloads.UintToUint, argTypes(types.UintType), types.UintType,
+ decls.UnaryBinding(identity)),
+ decls.Overload(overloads.DoubleToUint, argTypes(types.DoubleType), types.UintType,
+ decls.UnaryBinding(convertToType(types.UintType))),
+ decls.Overload(overloads.IntToUint, argTypes(types.IntType), types.UintType,
+ decls.UnaryBinding(convertToType(types.UintType))),
+ decls.Overload(overloads.StringToUint, argTypes(types.StringType), types.UintType,
+ decls.UnaryBinding(convertToType(types.UintType)))),
+
+ // String functions
+ function(overloads.Contains,
+ decls.MemberOverload(overloads.ContainsString,
+ argTypes(types.StringType, types.StringType), types.BoolType,
+ decls.BinaryBinding(types.StringContains)),
+ decls.DisableTypeGuards(true)),
+ function(overloads.EndsWith,
+ decls.MemberOverload(overloads.EndsWithString,
+ argTypes(types.StringType, types.StringType), types.BoolType,
+ decls.BinaryBinding(types.StringEndsWith)),
+ decls.DisableTypeGuards(true)),
+ function(overloads.StartsWith,
+ decls.MemberOverload(overloads.StartsWithString,
+ argTypes(types.StringType, types.StringType), types.BoolType,
+ decls.BinaryBinding(types.StringStartsWith)),
+ decls.DisableTypeGuards(true)),
+ function(overloads.Matches,
+ decls.Overload(overloads.Matches, argTypes(types.StringType, types.StringType), types.BoolType),
+ decls.MemberOverload(overloads.MatchesString,
+ argTypes(types.StringType, types.StringType), types.BoolType),
+ decls.SingletonBinaryBinding(func(str, pat ref.Val) ref.Val {
+ return str.(traits.Matcher).Match(pat)
+ }, traits.MatcherType)),
+
+ // Timestamp / duration functions
+ function(overloads.TimeGetFullYear,
+ decls.MemberOverload(overloads.TimestampToYear,
+ argTypes(types.TimestampType), types.IntType),
+ decls.MemberOverload(overloads.TimestampToYearWithTz,
+ argTypes(types.TimestampType, types.StringType), types.IntType)),
+
+ function(overloads.TimeGetMonth,
+ decls.MemberOverload(overloads.TimestampToMonth,
+ argTypes(types.TimestampType), types.IntType),
+ decls.MemberOverload(overloads.TimestampToMonthWithTz,
+ argTypes(types.TimestampType, types.StringType), types.IntType)),
+
+ function(overloads.TimeGetDayOfYear,
+ decls.MemberOverload(overloads.TimestampToDayOfYear,
+ argTypes(types.TimestampType), types.IntType),
+ decls.MemberOverload(overloads.TimestampToDayOfYearWithTz,
+ argTypes(types.TimestampType, types.StringType), types.IntType)),
+
+ function(overloads.TimeGetDayOfMonth,
+ decls.MemberOverload(overloads.TimestampToDayOfMonthZeroBased,
+ argTypes(types.TimestampType), types.IntType),
+ decls.MemberOverload(overloads.TimestampToDayOfMonthZeroBasedWithTz,
+ argTypes(types.TimestampType, types.StringType), types.IntType)),
+
+ function(overloads.TimeGetDate,
+ decls.MemberOverload(overloads.TimestampToDayOfMonthOneBased,
+ argTypes(types.TimestampType), types.IntType),
+ decls.MemberOverload(overloads.TimestampToDayOfMonthOneBasedWithTz,
+ argTypes(types.TimestampType, types.StringType), types.IntType)),
+
+ function(overloads.TimeGetDayOfWeek,
+ decls.MemberOverload(overloads.TimestampToDayOfWeek,
+ argTypes(types.TimestampType), types.IntType),
+ decls.MemberOverload(overloads.TimestampToDayOfWeekWithTz,
+ argTypes(types.TimestampType, types.StringType), types.IntType)),
+
+ function(overloads.TimeGetHours,
+ decls.MemberOverload(overloads.TimestampToHours,
+ argTypes(types.TimestampType), types.IntType),
+ decls.MemberOverload(overloads.TimestampToHoursWithTz,
+ argTypes(types.TimestampType, types.StringType), types.IntType),
+ decls.MemberOverload(overloads.DurationToHours,
+ argTypes(types.DurationType), types.IntType)),
+
+ function(overloads.TimeGetMinutes,
+ decls.MemberOverload(overloads.TimestampToMinutes,
+ argTypes(types.TimestampType), types.IntType),
+ decls.MemberOverload(overloads.TimestampToMinutesWithTz,
+ argTypes(types.TimestampType, types.StringType), types.IntType),
+ decls.MemberOverload(overloads.DurationToMinutes,
+ argTypes(types.DurationType), types.IntType)),
+
+ function(overloads.TimeGetSeconds,
+ decls.MemberOverload(overloads.TimestampToSeconds,
+ argTypes(types.TimestampType), types.IntType),
+ decls.MemberOverload(overloads.TimestampToSecondsWithTz,
+ argTypes(types.TimestampType, types.StringType), types.IntType),
+ decls.MemberOverload(overloads.DurationToSeconds,
+ argTypes(types.DurationType), types.IntType)),
+
+ function(overloads.TimeGetMilliseconds,
+ decls.MemberOverload(overloads.TimestampToMilliseconds,
+ argTypes(types.TimestampType), types.IntType),
+ decls.MemberOverload(overloads.TimestampToMillisecondsWithTz,
+ argTypes(types.TimestampType, types.StringType), types.IntType),
+ decls.MemberOverload(overloads.DurationToMilliseconds,
+ argTypes(types.DurationType), types.IntType)),
+ }
+}
+
+// Functions returns the set of standard library function declarations and definitions for CEL.
+func Functions() []*decls.FunctionDecl {
+ return stdFunctions
+}
+
+// Types returns the set of standard library types for CEL.
+func Types() []*decls.VariableDecl {
+ return stdTypes
+}
+
+func notStrictlyFalse(value ref.Val) ref.Val {
+ if types.IsBool(value) {
+ return value
+ }
+ return types.True
+}
+
+func inAggregate(lhs ref.Val, rhs ref.Val) ref.Val {
+ if rhs.Type().HasTrait(traits.ContainerType) {
+ return rhs.(traits.Container).Contains(lhs)
+ }
+ return types.ValOrErr(rhs, "no such overload")
+}
+
+func function(name string, opts ...decls.FunctionOpt) *decls.FunctionDecl {
+ fn, err := decls.NewFunction(name, opts...)
+ if err != nil {
+ panic(err)
+ }
+ return fn
+}
+
+func argTypes(args ...*types.Type) []*types.Type {
+ return args
+}
+
+func noBinaryOverrides(rhs, lhs ref.Val) ref.Val {
+ return types.NoSuchOverloadErr()
+}
+
+func noFunctionOverrides(args ...ref.Val) ref.Val {
+ return types.NoSuchOverloadErr()
+}
+
+func identity(val ref.Val) ref.Val {
+ return val
+}
+
+func convertToType(t ref.Type) functions.UnaryOp {
+ return func(val ref.Val) ref.Val {
+ return val.ConvertToType(t)
+ }
+}
diff --git a/vendor/github.com/google/cel-go/common/types/BUILD.bazel b/vendor/github.com/google/cel-go/common/types/BUILD.bazel
new file mode 100644
index 000000000000..62ae72f035f6
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/BUILD.bazel
@@ -0,0 +1,55 @@
+load("@io_bazel_rules_go//go:def.bzl", "go_library")
+
+package(
+ default_visibility = ["//visibility:public"],
+ licenses = ["notice"], # Apache 2.0
+)
+
+go_library(
+ name = "go_default_library",
+ srcs = [
+ "any_value.go",
+ "bool.go",
+ "bytes.go",
+ "compare.go",
+ "doc.go",
+ "double.go",
+ "duration.go",
+ "err.go",
+ "int.go",
+ "iterator.go",
+ "json_value.go",
+ "list.go",
+ "map.go",
+ "null.go",
+ "object.go",
+ "optional.go",
+ "overflow.go",
+ "provider.go",
+ "string.go",
+ "timestamp.go",
+ "types.go",
+ "uint.go",
+ "unknown.go",
+ "util.go",
+ ],
+ importmap = "kubevirt.io/kubevirt/vendor/github.com/google/cel-go/common/types",
+ importpath = "github.com/google/cel-go/common/types",
+ deps = [
+ "//vendor/github.com/google/cel-go/checker/decls:go_default_library",
+ "//vendor/github.com/google/cel-go/common/overloads:go_default_library",
+ "//vendor/github.com/google/cel-go/common/types/pb:go_default_library",
+ "//vendor/github.com/google/cel-go/common/types/ref:go_default_library",
+ "//vendor/github.com/google/cel-go/common/types/traits:go_default_library",
+ "//vendor/github.com/stoewer/go-strcase:go_default_library",
+ "//vendor/google.golang.org/genproto/googleapis/api/expr/v1alpha1:go_default_library",
+ "//vendor/google.golang.org/protobuf/encoding/protojson:go_default_library",
+ "//vendor/google.golang.org/protobuf/proto:go_default_library",
+ "//vendor/google.golang.org/protobuf/reflect/protoreflect:go_default_library",
+ "//vendor/google.golang.org/protobuf/types/known/anypb:go_default_library",
+ "//vendor/google.golang.org/protobuf/types/known/durationpb:go_default_library",
+ "//vendor/google.golang.org/protobuf/types/known/structpb:go_default_library",
+ "//vendor/google.golang.org/protobuf/types/known/timestamppb:go_default_library",
+ "//vendor/google.golang.org/protobuf/types/known/wrapperspb:go_default_library",
+ ],
+)
diff --git a/vendor/github.com/google/cel-go/common/types/any_value.go b/vendor/github.com/google/cel-go/common/types/any_value.go
new file mode 100644
index 000000000000..cda0f13acf04
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/any_value.go
@@ -0,0 +1,24 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package types
+
+import (
+ "reflect"
+
+ anypb "google.golang.org/protobuf/types/known/anypb"
+)
+
+// anyValueType constant representing the reflected type of google.protobuf.Any.
+var anyValueType = reflect.TypeOf(&anypb.Any{})
diff --git a/vendor/github.com/google/cel-go/common/types/bool.go b/vendor/github.com/google/cel-go/common/types/bool.go
new file mode 100644
index 000000000000..565734f3ff5b
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/bool.go
@@ -0,0 +1,141 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package types
+
+import (
+ "fmt"
+ "reflect"
+ "strconv"
+
+ "github.com/google/cel-go/common/types/ref"
+
+ anypb "google.golang.org/protobuf/types/known/anypb"
+ structpb "google.golang.org/protobuf/types/known/structpb"
+ wrapperspb "google.golang.org/protobuf/types/known/wrapperspb"
+)
+
+// Bool type that implements ref.Val and supports comparison and negation.
+type Bool bool
+
+var (
+ // boolWrapperType golang reflected type for protobuf bool wrapper type.
+ boolWrapperType = reflect.TypeOf(&wrapperspb.BoolValue{})
+)
+
+// Boolean constants
+const (
+ False = Bool(false)
+ True = Bool(true)
+)
+
+// Compare implements the traits.Comparer interface method.
+func (b Bool) Compare(other ref.Val) ref.Val {
+ otherBool, ok := other.(Bool)
+ if !ok {
+ return ValOrErr(other, "no such overload")
+ }
+ if b == otherBool {
+ return IntZero
+ }
+ if !b && otherBool {
+ return IntNegOne
+ }
+ return IntOne
+}
+
+// ConvertToNative implements the ref.Val interface method.
+func (b Bool) ConvertToNative(typeDesc reflect.Type) (any, error) {
+ switch typeDesc.Kind() {
+ case reflect.Bool:
+ return reflect.ValueOf(b).Convert(typeDesc).Interface(), nil
+ case reflect.Ptr:
+ switch typeDesc {
+ case anyValueType:
+ // Primitives must be wrapped to a wrapperspb.BoolValue before being packed into an Any.
+ return anypb.New(wrapperspb.Bool(bool(b)))
+ case boolWrapperType:
+ // Convert the bool to a wrapperspb.BoolValue.
+ return wrapperspb.Bool(bool(b)), nil
+ case jsonValueType:
+ // Return the bool as a new structpb.Value.
+ return structpb.NewBoolValue(bool(b)), nil
+ default:
+ if typeDesc.Elem().Kind() == reflect.Bool {
+ p := bool(b)
+ return &p, nil
+ }
+ }
+ case reflect.Interface:
+ bv := b.Value()
+ if reflect.TypeOf(bv).Implements(typeDesc) {
+ return bv, nil
+ }
+ if reflect.TypeOf(b).Implements(typeDesc) {
+ return b, nil
+ }
+ }
+ return nil, fmt.Errorf("type conversion error from bool to '%v'", typeDesc)
+}
+
+// ConvertToType implements the ref.Val interface method.
+func (b Bool) ConvertToType(typeVal ref.Type) ref.Val {
+ switch typeVal {
+ case StringType:
+ return String(strconv.FormatBool(bool(b)))
+ case BoolType:
+ return b
+ case TypeType:
+ return BoolType
+ }
+ return NewErr("type conversion error from '%v' to '%v'", BoolType, typeVal)
+}
+
+// Equal implements the ref.Val interface method.
+func (b Bool) Equal(other ref.Val) ref.Val {
+ otherBool, ok := other.(Bool)
+ return Bool(ok && b == otherBool)
+}
+
+// IsZeroValue returns true if the boolean value is false.
+func (b Bool) IsZeroValue() bool {
+ return b == False
+}
+
+// Negate implements the traits.Negater interface method.
+func (b Bool) Negate() ref.Val {
+ return !b
+}
+
+// Type implements the ref.Val interface method.
+func (b Bool) Type() ref.Type {
+ return BoolType
+}
+
+// Value implements the ref.Val interface method.
+func (b Bool) Value() any {
+ return bool(b)
+}
+
+// IsBool returns whether the input ref.Val or ref.Type is equal to BoolType.
+func IsBool(elem ref.Val) bool {
+ switch v := elem.(type) {
+ case Bool:
+ return true
+ case ref.Val:
+ return v.Type() == BoolType
+ default:
+ return false
+ }
+}
diff --git a/vendor/github.com/google/cel-go/common/types/bytes.go b/vendor/github.com/google/cel-go/common/types/bytes.go
new file mode 100644
index 000000000000..7e813e291bc3
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/bytes.go
@@ -0,0 +1,140 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package types
+
+import (
+ "bytes"
+ "encoding/base64"
+ "fmt"
+ "reflect"
+ "unicode/utf8"
+
+ "github.com/google/cel-go/common/types/ref"
+
+ anypb "google.golang.org/protobuf/types/known/anypb"
+ structpb "google.golang.org/protobuf/types/known/structpb"
+ wrapperspb "google.golang.org/protobuf/types/known/wrapperspb"
+)
+
+// Bytes type that implements ref.Val and supports add, compare, and size
+// operations.
+type Bytes []byte
+
+var (
+ // byteWrapperType golang reflected type for protobuf bytes wrapper type.
+ byteWrapperType = reflect.TypeOf(&wrapperspb.BytesValue{})
+)
+
+// Add implements traits.Adder interface method by concatenating byte sequences.
+func (b Bytes) Add(other ref.Val) ref.Val {
+ otherBytes, ok := other.(Bytes)
+ if !ok {
+ return ValOrErr(other, "no such overload")
+ }
+ return append(b, otherBytes...)
+}
+
+// Compare implements traits.Comparer interface method by lexicographic ordering.
+func (b Bytes) Compare(other ref.Val) ref.Val {
+ otherBytes, ok := other.(Bytes)
+ if !ok {
+ return ValOrErr(other, "no such overload")
+ }
+ return Int(bytes.Compare(b, otherBytes))
+}
+
+// ConvertToNative implements the ref.Val interface method.
+func (b Bytes) ConvertToNative(typeDesc reflect.Type) (any, error) {
+ switch typeDesc.Kind() {
+ case reflect.Array:
+ if len(b) != typeDesc.Len() {
+ return nil, fmt.Errorf("[%d]byte not assignable to [%d]byte array", len(b), typeDesc.Len())
+ }
+ refArrPtr := reflect.New(reflect.ArrayOf(len(b), typeDesc.Elem()))
+ refArr := refArrPtr.Elem()
+ for i, byt := range b {
+ refArr.Index(i).Set(reflect.ValueOf(byt).Convert(typeDesc.Elem()))
+ }
+ return refArr.Interface(), nil
+ case reflect.Slice:
+ return reflect.ValueOf(b).Convert(typeDesc).Interface(), nil
+ case reflect.Ptr:
+ switch typeDesc {
+ case anyValueType:
+ // Primitives must be wrapped before being set on an Any field.
+ return anypb.New(wrapperspb.Bytes([]byte(b)))
+ case byteWrapperType:
+ // Convert the bytes to a wrapperspb.BytesValue.
+ return wrapperspb.Bytes([]byte(b)), nil
+ case jsonValueType:
+ // CEL follows the proto3 to JSON conversion by encoding bytes to a string via base64.
+ // The encoding below matches the golang 'encoding/json' behavior during marshaling,
+ // which uses base64.StdEncoding.
+ str := base64.StdEncoding.EncodeToString([]byte(b))
+ return structpb.NewStringValue(str), nil
+ }
+ case reflect.Interface:
+ bv := b.Value()
+ if reflect.TypeOf(bv).Implements(typeDesc) {
+ return bv, nil
+ }
+ if reflect.TypeOf(b).Implements(typeDesc) {
+ return b, nil
+ }
+ }
+ return nil, fmt.Errorf("type conversion error from Bytes to '%v'", typeDesc)
+}
+
+// ConvertToType implements the ref.Val interface method.
+func (b Bytes) ConvertToType(typeVal ref.Type) ref.Val {
+ switch typeVal {
+ case StringType:
+ if !utf8.Valid(b) {
+ return NewErr("invalid UTF-8 in bytes, cannot convert to string")
+ }
+ return String(b)
+ case BytesType:
+ return b
+ case TypeType:
+ return BytesType
+ }
+ return NewErr("type conversion error from '%s' to '%s'", BytesType, typeVal)
+}
+
+// Equal implements the ref.Val interface method.
+func (b Bytes) Equal(other ref.Val) ref.Val {
+ otherBytes, ok := other.(Bytes)
+ return Bool(ok && bytes.Equal(b, otherBytes))
+}
+
+// IsZeroValue returns true if the byte array is empty.
+func (b Bytes) IsZeroValue() bool {
+ return len(b) == 0
+}
+
+// Size implements the traits.Sizer interface method.
+func (b Bytes) Size() ref.Val {
+ return Int(len(b))
+}
+
+// Type implements the ref.Val interface method.
+func (b Bytes) Type() ref.Type {
+ return BytesType
+}
+
+// Value implements the ref.Val interface method.
+func (b Bytes) Value() any {
+ return []byte(b)
+}
diff --git a/vendor/github.com/google/cel-go/common/types/compare.go b/vendor/github.com/google/cel-go/common/types/compare.go
new file mode 100644
index 000000000000..e19682618025
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/compare.go
@@ -0,0 +1,97 @@
+// Copyright 2021 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package types
+
+import (
+ "math"
+
+ "github.com/google/cel-go/common/types/ref"
+)
+
+func compareDoubleInt(d Double, i Int) Int {
+ if d < math.MinInt64 {
+ return IntNegOne
+ }
+ if d > math.MaxInt64 {
+ return IntOne
+ }
+ return compareDouble(d, Double(i))
+}
+
+func compareIntDouble(i Int, d Double) Int {
+ return -compareDoubleInt(d, i)
+}
+
+func compareDoubleUint(d Double, u Uint) Int {
+ if d < 0 {
+ return IntNegOne
+ }
+ if d > math.MaxUint64 {
+ return IntOne
+ }
+ return compareDouble(d, Double(u))
+}
+
+func compareUintDouble(u Uint, d Double) Int {
+ return -compareDoubleUint(d, u)
+}
+
+func compareIntUint(i Int, u Uint) Int {
+ if i < 0 || u > math.MaxInt64 {
+ return IntNegOne
+ }
+ cmp := i - Int(u)
+ if cmp < 0 {
+ return IntNegOne
+ }
+ if cmp > 0 {
+ return IntOne
+ }
+ return IntZero
+}
+
+func compareUintInt(u Uint, i Int) Int {
+ return -compareIntUint(i, u)
+}
+
+func compareDouble(a, b Double) Int {
+ if a < b {
+ return IntNegOne
+ }
+ if a > b {
+ return IntOne
+ }
+ return IntZero
+}
+
+func compareInt(a, b Int) ref.Val {
+ if a < b {
+ return IntNegOne
+ }
+ if a > b {
+ return IntOne
+ }
+ return IntZero
+}
+
+func compareUint(a, b Uint) ref.Val {
+ if a < b {
+ return IntNegOne
+ }
+ if a > b {
+ return IntOne
+ }
+ return IntZero
+}
diff --git a/vendor/github.com/google/cel-go/common/types/doc.go b/vendor/github.com/google/cel-go/common/types/doc.go
new file mode 100644
index 000000000000..5f641d7043db
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/doc.go
@@ -0,0 +1,17 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+// Package types contains the types, traits, and utilities common to all
+// components of expression handling.
+package types
diff --git a/vendor/github.com/google/cel-go/common/types/double.go b/vendor/github.com/google/cel-go/common/types/double.go
new file mode 100644
index 000000000000..027e789786b9
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/double.go
@@ -0,0 +1,211 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package types
+
+import (
+ "fmt"
+ "math"
+ "reflect"
+
+ "github.com/google/cel-go/common/types/ref"
+
+ anypb "google.golang.org/protobuf/types/known/anypb"
+ structpb "google.golang.org/protobuf/types/known/structpb"
+ wrapperspb "google.golang.org/protobuf/types/known/wrapperspb"
+)
+
+// Double type that implements ref.Val, comparison, and mathematical
+// operations.
+type Double float64
+
+var (
+ // doubleWrapperType reflected type for protobuf double wrapper type.
+ doubleWrapperType = reflect.TypeOf(&wrapperspb.DoubleValue{})
+
+ // floatWrapperType reflected type for protobuf float wrapper type.
+ floatWrapperType = reflect.TypeOf(&wrapperspb.FloatValue{})
+)
+
+// Add implements traits.Adder.Add.
+func (d Double) Add(other ref.Val) ref.Val {
+ otherDouble, ok := other.(Double)
+ if !ok {
+ return MaybeNoSuchOverloadErr(other)
+ }
+ return d + otherDouble
+}
+
+// Compare implements traits.Comparer.Compare.
+func (d Double) Compare(other ref.Val) ref.Val {
+ if math.IsNaN(float64(d)) {
+ return NewErr("NaN values cannot be ordered")
+ }
+ switch ov := other.(type) {
+ case Double:
+ if math.IsNaN(float64(ov)) {
+ return NewErr("NaN values cannot be ordered")
+ }
+ return compareDouble(d, ov)
+ case Int:
+ return compareDoubleInt(d, ov)
+ case Uint:
+ return compareDoubleUint(d, ov)
+ default:
+ return MaybeNoSuchOverloadErr(other)
+ }
+}
+
+// ConvertToNative implements ref.Val.ConvertToNative.
+func (d Double) ConvertToNative(typeDesc reflect.Type) (any, error) {
+ switch typeDesc.Kind() {
+ case reflect.Float32:
+ v := float32(d)
+ return reflect.ValueOf(v).Convert(typeDesc).Interface(), nil
+ case reflect.Float64:
+ v := float64(d)
+ return reflect.ValueOf(v).Convert(typeDesc).Interface(), nil
+ case reflect.Ptr:
+ switch typeDesc {
+ case anyValueType:
+ // Primitives must be wrapped before being set on an Any field.
+ return anypb.New(wrapperspb.Double(float64(d)))
+ case doubleWrapperType:
+ // Convert to a wrapperspb.DoubleValue
+ return wrapperspb.Double(float64(d)), nil
+ case floatWrapperType:
+ // Convert to a wrapperspb.FloatValue (with truncation).
+ return wrapperspb.Float(float32(d)), nil
+ case jsonValueType:
+ // Note, there are special cases for proto3 to json conversion that
+ // expect the floating point value to be converted to a NaN,
+ // Infinity, or -Infinity string values, but the jsonpb string
+ // marshaling of the protobuf.Value will handle this conversion.
+ return structpb.NewNumberValue(float64(d)), nil
+ }
+ switch typeDesc.Elem().Kind() {
+ case reflect.Float32:
+ v := float32(d)
+ p := reflect.New(typeDesc.Elem())
+ p.Elem().Set(reflect.ValueOf(v).Convert(typeDesc.Elem()))
+ return p.Interface(), nil
+ case reflect.Float64:
+ v := float64(d)
+ p := reflect.New(typeDesc.Elem())
+ p.Elem().Set(reflect.ValueOf(v).Convert(typeDesc.Elem()))
+ return p.Interface(), nil
+ }
+ case reflect.Interface:
+ dv := d.Value()
+ if reflect.TypeOf(dv).Implements(typeDesc) {
+ return dv, nil
+ }
+ if reflect.TypeOf(d).Implements(typeDesc) {
+ return d, nil
+ }
+ }
+ return nil, fmt.Errorf("type conversion error from Double to '%v'", typeDesc)
+}
+
+// ConvertToType implements ref.Val.ConvertToType.
+func (d Double) ConvertToType(typeVal ref.Type) ref.Val {
+ switch typeVal {
+ case IntType:
+ i, err := doubleToInt64Checked(float64(d))
+ if err != nil {
+ return WrapErr(err)
+ }
+ return Int(i)
+ case UintType:
+ i, err := doubleToUint64Checked(float64(d))
+ if err != nil {
+ return WrapErr(err)
+ }
+ return Uint(i)
+ case DoubleType:
+ return d
+ case StringType:
+ return String(fmt.Sprintf("%g", float64(d)))
+ case TypeType:
+ return DoubleType
+ }
+ return NewErr("type conversion error from '%s' to '%s'", DoubleType, typeVal)
+}
+
+// Divide implements traits.Divider.Divide.
+func (d Double) Divide(other ref.Val) ref.Val {
+ otherDouble, ok := other.(Double)
+ if !ok {
+ return MaybeNoSuchOverloadErr(other)
+ }
+ return d / otherDouble
+}
+
+// Equal implements ref.Val.Equal.
+func (d Double) Equal(other ref.Val) ref.Val {
+ if math.IsNaN(float64(d)) {
+ return False
+ }
+ switch ov := other.(type) {
+ case Double:
+ if math.IsNaN(float64(ov)) {
+ return False
+ }
+ return Bool(d == ov)
+ case Int:
+ return Bool(compareDoubleInt(d, ov) == 0)
+ case Uint:
+ return Bool(compareDoubleUint(d, ov) == 0)
+ default:
+ return False
+ }
+}
+
+// IsZeroValue returns true if double value is 0.0
+func (d Double) IsZeroValue() bool {
+ return float64(d) == 0.0
+}
+
+// Multiply implements traits.Multiplier.Multiply.
+func (d Double) Multiply(other ref.Val) ref.Val {
+ otherDouble, ok := other.(Double)
+ if !ok {
+ return MaybeNoSuchOverloadErr(other)
+ }
+ return d * otherDouble
+}
+
+// Negate implements traits.Negater.Negate.
+func (d Double) Negate() ref.Val {
+ return -d
+}
+
+// Subtract implements traits.Subtractor.Subtract.
+func (d Double) Subtract(subtrahend ref.Val) ref.Val {
+ subtraDouble, ok := subtrahend.(Double)
+ if !ok {
+ return MaybeNoSuchOverloadErr(subtrahend)
+ }
+ return d - subtraDouble
+}
+
+// Type implements ref.Val.Type.
+func (d Double) Type() ref.Type {
+ return DoubleType
+}
+
+// Value implements ref.Val.Value.
+func (d Double) Value() any {
+ return float64(d)
+}
diff --git a/vendor/github.com/google/cel-go/common/types/duration.go b/vendor/github.com/google/cel-go/common/types/duration.go
new file mode 100644
index 000000000000..596e56d6b03e
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/duration.go
@@ -0,0 +1,222 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package types
+
+import (
+ "fmt"
+ "reflect"
+ "strconv"
+ "time"
+
+ "github.com/google/cel-go/common/overloads"
+ "github.com/google/cel-go/common/types/ref"
+
+ anypb "google.golang.org/protobuf/types/known/anypb"
+ dpb "google.golang.org/protobuf/types/known/durationpb"
+ structpb "google.golang.org/protobuf/types/known/structpb"
+)
+
+// Duration type that implements ref.Val and supports add, compare, negate,
+// and subtract operators. This type is also a receiver which means it can
+// participate in dispatch to receiver functions.
+type Duration struct {
+ time.Duration
+}
+
+func durationOf(d time.Duration) Duration {
+ return Duration{Duration: d}
+}
+
+var (
+ durationValueType = reflect.TypeOf(&dpb.Duration{})
+
+ durationZeroArgOverloads = map[string]func(ref.Val) ref.Val{
+ overloads.TimeGetHours: DurationGetHours,
+ overloads.TimeGetMinutes: DurationGetMinutes,
+ overloads.TimeGetSeconds: DurationGetSeconds,
+ overloads.TimeGetMilliseconds: DurationGetMilliseconds,
+ }
+)
+
+// Add implements traits.Adder.Add.
+func (d Duration) Add(other ref.Val) ref.Val {
+ switch other.Type() {
+ case DurationType:
+ dur2 := other.(Duration)
+ val, err := addDurationChecked(d.Duration, dur2.Duration)
+ if err != nil {
+ return WrapErr(err)
+ }
+ return durationOf(val)
+ case TimestampType:
+ ts := other.(Timestamp).Time
+ val, err := addTimeDurationChecked(ts, d.Duration)
+ if err != nil {
+ return WrapErr(err)
+ }
+ return timestampOf(val)
+ }
+ return MaybeNoSuchOverloadErr(other)
+}
+
+// Compare implements traits.Comparer.Compare.
+func (d Duration) Compare(other ref.Val) ref.Val {
+ otherDur, ok := other.(Duration)
+ if !ok {
+ return MaybeNoSuchOverloadErr(other)
+ }
+ d1 := d.Duration
+ d2 := otherDur.Duration
+ switch {
+ case d1 < d2:
+ return IntNegOne
+ case d1 > d2:
+ return IntOne
+ default:
+ return IntZero
+ }
+}
+
+// ConvertToNative implements ref.Val.ConvertToNative.
+func (d Duration) ConvertToNative(typeDesc reflect.Type) (any, error) {
+ // If the duration is already assignable to the desired type return it.
+ if reflect.TypeOf(d.Duration).AssignableTo(typeDesc) {
+ return d.Duration, nil
+ }
+ if reflect.TypeOf(d).AssignableTo(typeDesc) {
+ return d, nil
+ }
+ switch typeDesc {
+ case anyValueType:
+ // Pack the duration as a dpb.Duration into an Any value.
+ return anypb.New(dpb.New(d.Duration))
+ case durationValueType:
+ // Unwrap the CEL value to its underlying proto value.
+ return dpb.New(d.Duration), nil
+ case jsonValueType:
+ // CEL follows the proto3 to JSON conversion.
+ // Note, using jsonpb would wrap the result in extra double quotes.
+ v := d.ConvertToType(StringType)
+ if IsError(v) {
+ return nil, v.(*Err)
+ }
+ return structpb.NewStringValue(string(v.(String))), nil
+ }
+ return nil, fmt.Errorf("type conversion error from 'Duration' to '%v'", typeDesc)
+}
+
+// ConvertToType implements ref.Val.ConvertToType.
+func (d Duration) ConvertToType(typeVal ref.Type) ref.Val {
+ switch typeVal {
+ case StringType:
+ return String(strconv.FormatFloat(d.Seconds(), 'f', -1, 64) + "s")
+ case IntType:
+ return Int(d.Duration)
+ case DurationType:
+ return d
+ case TypeType:
+ return DurationType
+ }
+ return NewErr("type conversion error from '%s' to '%s'", DurationType, typeVal)
+}
+
+// Equal implements ref.Val.Equal.
+func (d Duration) Equal(other ref.Val) ref.Val {
+ otherDur, ok := other.(Duration)
+ return Bool(ok && d.Duration == otherDur.Duration)
+}
+
+// IsZeroValue returns true if the duration value is zero
+func (d Duration) IsZeroValue() bool {
+ return d.Duration == 0
+}
+
+// Negate implements traits.Negater.Negate.
+func (d Duration) Negate() ref.Val {
+ val, err := negateDurationChecked(d.Duration)
+ if err != nil {
+ return WrapErr(err)
+ }
+ return durationOf(val)
+}
+
+// Receive implements traits.Receiver.Receive.
+func (d Duration) Receive(function string, overload string, args []ref.Val) ref.Val {
+ if len(args) == 0 {
+ if f, found := durationZeroArgOverloads[function]; found {
+ return f(d)
+ }
+ }
+ return NoSuchOverloadErr()
+}
+
+// Subtract implements traits.Subtractor.Subtract.
+func (d Duration) Subtract(subtrahend ref.Val) ref.Val {
+ subtraDur, ok := subtrahend.(Duration)
+ if !ok {
+ return MaybeNoSuchOverloadErr(subtrahend)
+ }
+ val, err := subtractDurationChecked(d.Duration, subtraDur.Duration)
+ if err != nil {
+ return WrapErr(err)
+ }
+ return durationOf(val)
+}
+
+// Type implements ref.Val.Type.
+func (d Duration) Type() ref.Type {
+ return DurationType
+}
+
+// Value implements ref.Val.Value.
+func (d Duration) Value() any {
+ return d.Duration
+}
+
+// DurationGetHours returns the duration in hours.
+func DurationGetHours(val ref.Val) ref.Val {
+ dur, ok := val.(Duration)
+ if !ok {
+ return MaybeNoSuchOverloadErr(val)
+ }
+ return Int(dur.Hours())
+}
+
+// DurationGetMinutes returns duration in minutes.
+func DurationGetMinutes(val ref.Val) ref.Val {
+ dur, ok := val.(Duration)
+ if !ok {
+ return MaybeNoSuchOverloadErr(val)
+ }
+ return Int(dur.Minutes())
+}
+
+// DurationGetSeconds returns duration in seconds.
+func DurationGetSeconds(val ref.Val) ref.Val {
+ dur, ok := val.(Duration)
+ if !ok {
+ return MaybeNoSuchOverloadErr(val)
+ }
+ return Int(dur.Seconds())
+}
+
+// DurationGetMilliseconds returns duration in milliseconds.
+func DurationGetMilliseconds(val ref.Val) ref.Val {
+ dur, ok := val.(Duration)
+ if !ok {
+ return MaybeNoSuchOverloadErr(val)
+ }
+ return Int(dur.Milliseconds())
+}
diff --git a/vendor/github.com/google/cel-go/common/types/err.go b/vendor/github.com/google/cel-go/common/types/err.go
new file mode 100644
index 000000000000..9c9d9e21efba
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/err.go
@@ -0,0 +1,169 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package types
+
+import (
+ "errors"
+ "fmt"
+ "reflect"
+
+ "github.com/google/cel-go/common/types/ref"
+)
+
+// Error interface which allows types types.Err values to be treated as error values.
+type Error interface {
+ error
+ ref.Val
+}
+
+// Err type which extends the built-in go error and implements ref.Val.
+type Err struct {
+ error
+ id int64
+}
+
+var (
+ // ErrType singleton.
+ ErrType = NewOpaqueType("error")
+
+ // errDivideByZero is an error indicating a division by zero of an integer value.
+ errDivideByZero = errors.New("division by zero")
+ // errModulusByZero is an error indicating a modulus by zero of an integer value.
+ errModulusByZero = errors.New("modulus by zero")
+ // errIntOverflow is an error representing integer overflow.
+ errIntOverflow = errors.New("integer overflow")
+ // errUintOverflow is an error representing unsigned integer overflow.
+ errUintOverflow = errors.New("unsigned integer overflow")
+ // errDurationOverflow is an error representing duration overflow.
+ errDurationOverflow = errors.New("duration overflow")
+ // errTimestampOverflow is an error representing timestamp overflow.
+ errTimestampOverflow = errors.New("timestamp overflow")
+ celErrTimestampOverflow = &Err{error: errTimestampOverflow}
+
+ // celErrNoSuchOverload indicates that the call arguments did not match a supported method signature.
+ celErrNoSuchOverload = NewErr("no such overload")
+)
+
+// NewErr creates a new Err described by the format string and args.
+// TODO: Audit the use of this function and standardize the error messages and codes.
+func NewErr(format string, args ...any) ref.Val {
+ return &Err{error: fmt.Errorf(format, args...)}
+}
+
+// NewErrWithNodeID creates a new Err described by the format string and args.
+// TODO: Audit the use of this function and standardize the error messages and codes.
+func NewErrWithNodeID(id int64, format string, args ...any) ref.Val {
+ return &Err{error: fmt.Errorf(format, args...), id: id}
+}
+
+// LabelErrNode returns val unaltered it is not an Err or if the error has a non-zero
+// AST node ID already present. Otherwise the id is added to the error for
+// recovery with the Err.NodeID method.
+func LabelErrNode(id int64, val ref.Val) ref.Val {
+ if err, ok := val.(*Err); ok && err.id == 0 {
+ err.id = id
+ return err
+ }
+ return val
+}
+
+// NoSuchOverloadErr returns a new types.Err instance with a no such overload message.
+func NoSuchOverloadErr() ref.Val {
+ return celErrNoSuchOverload
+}
+
+// UnsupportedRefValConversionErr returns a types.NewErr instance with a no such conversion
+// message that indicates that the native value could not be converted to a CEL ref.Val.
+func UnsupportedRefValConversionErr(val any) ref.Val {
+ return NewErr("unsupported conversion to ref.Val: (%T)%v", val, val)
+}
+
+// MaybeNoSuchOverloadErr returns the error or unknown if the input ref.Val is one of these types,
+// else a new no such overload error.
+func MaybeNoSuchOverloadErr(val ref.Val) ref.Val {
+ return ValOrErr(val, "no such overload")
+}
+
+// ValOrErr either returns the existing error or creates a new one.
+// TODO: Audit the use of this function and standardize the error messages and codes.
+func ValOrErr(val ref.Val, format string, args ...any) ref.Val {
+ if val == nil || !IsUnknownOrError(val) {
+ return NewErr(format, args...)
+ }
+ return val
+}
+
+// WrapErr wraps an existing Go error value into a CEL Err value.
+func WrapErr(err error) ref.Val {
+ return &Err{error: err}
+}
+
+// ConvertToNative implements ref.Val.ConvertToNative.
+func (e *Err) ConvertToNative(typeDesc reflect.Type) (any, error) {
+ return nil, e.error
+}
+
+// ConvertToType implements ref.Val.ConvertToType.
+func (e *Err) ConvertToType(typeVal ref.Type) ref.Val {
+ // Errors are not convertible to other representations.
+ return e
+}
+
+// Equal implements ref.Val.Equal.
+func (e *Err) Equal(other ref.Val) ref.Val {
+ // An error cannot be equal to any other value, so it returns itself.
+ return e
+}
+
+// String implements fmt.Stringer.
+func (e *Err) String() string {
+ return e.error.Error()
+}
+
+// Type implements ref.Val.Type.
+func (e *Err) Type() ref.Type {
+ return ErrType
+}
+
+// Value implements ref.Val.Value.
+func (e *Err) Value() any {
+ return e.error
+}
+
+// NodeID returns the AST node ID of the expression that returned the error.
+func (e *Err) NodeID() int64 {
+ return e.id
+}
+
+// Is implements errors.Is.
+func (e *Err) Is(target error) bool {
+ return e.error.Error() == target.Error()
+}
+
+// Unwrap implements errors.Unwrap.
+func (e *Err) Unwrap() error {
+ return e.error
+}
+
+// IsError returns whether the input element ref.Type or ref.Val is equal to
+// the ErrType singleton.
+func IsError(val ref.Val) bool {
+ switch val.(type) {
+ case *Err:
+ return true
+ default:
+ return false
+ }
+}
diff --git a/vendor/github.com/google/cel-go/common/types/int.go b/vendor/github.com/google/cel-go/common/types/int.go
new file mode 100644
index 000000000000..0ae9507c3960
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/int.go
@@ -0,0 +1,303 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package types
+
+import (
+ "fmt"
+ "math"
+ "reflect"
+ "strconv"
+ "time"
+
+ "github.com/google/cel-go/common/types/ref"
+
+ anypb "google.golang.org/protobuf/types/known/anypb"
+ structpb "google.golang.org/protobuf/types/known/structpb"
+ wrapperspb "google.golang.org/protobuf/types/known/wrapperspb"
+)
+
+// Int type that implements ref.Val as well as comparison and math operators.
+type Int int64
+
+// Int constants used for comparison results.
+const (
+ // IntZero is the zero-value for Int
+ IntZero = Int(0)
+ IntOne = Int(1)
+ IntNegOne = Int(-1)
+)
+
+var (
+ // int32WrapperType reflected type for protobuf int32 wrapper type.
+ int32WrapperType = reflect.TypeOf(&wrapperspb.Int32Value{})
+
+ // int64WrapperType reflected type for protobuf int64 wrapper type.
+ int64WrapperType = reflect.TypeOf(&wrapperspb.Int64Value{})
+)
+
+// Add implements traits.Adder.Add.
+func (i Int) Add(other ref.Val) ref.Val {
+ otherInt, ok := other.(Int)
+ if !ok {
+ return MaybeNoSuchOverloadErr(other)
+ }
+ val, err := addInt64Checked(int64(i), int64(otherInt))
+ if err != nil {
+ return WrapErr(err)
+ }
+ return Int(val)
+}
+
+// Compare implements traits.Comparer.Compare.
+func (i Int) Compare(other ref.Val) ref.Val {
+ switch ov := other.(type) {
+ case Double:
+ if math.IsNaN(float64(ov)) {
+ return NewErr("NaN values cannot be ordered")
+ }
+ return compareIntDouble(i, ov)
+ case Int:
+ return compareInt(i, ov)
+ case Uint:
+ return compareIntUint(i, ov)
+ default:
+ return MaybeNoSuchOverloadErr(other)
+ }
+}
+
+// ConvertToNative implements ref.Val.ConvertToNative.
+func (i Int) ConvertToNative(typeDesc reflect.Type) (any, error) {
+ switch typeDesc.Kind() {
+ case reflect.Int, reflect.Int32:
+ // Enums are also mapped as int32 derivations.
+ // Note, the code doesn't convert to the enum value directly since this is not known, but
+ // the net effect with respect to proto-assignment is handled correctly by the reflection
+ // Convert method.
+ v, err := int64ToInt32Checked(int64(i))
+ if err != nil {
+ return nil, err
+ }
+ return reflect.ValueOf(v).Convert(typeDesc).Interface(), nil
+ case reflect.Int8:
+ v, err := int64ToInt8Checked(int64(i))
+ if err != nil {
+ return nil, err
+ }
+ return reflect.ValueOf(v).Convert(typeDesc).Interface(), nil
+ case reflect.Int16:
+ v, err := int64ToInt16Checked(int64(i))
+ if err != nil {
+ return nil, err
+ }
+ return reflect.ValueOf(v).Convert(typeDesc).Interface(), nil
+ case reflect.Int64:
+ return reflect.ValueOf(i).Convert(typeDesc).Interface(), nil
+ case reflect.Ptr:
+ switch typeDesc {
+ case anyValueType:
+ // Primitives must be wrapped before being set on an Any field.
+ return anypb.New(wrapperspb.Int64(int64(i)))
+ case int32WrapperType:
+ // Convert the value to a wrapperspb.Int32Value, error on overflow.
+ v, err := int64ToInt32Checked(int64(i))
+ if err != nil {
+ return nil, err
+ }
+ return wrapperspb.Int32(v), nil
+ case int64WrapperType:
+ // Convert the value to a wrapperspb.Int64Value.
+ return wrapperspb.Int64(int64(i)), nil
+ case jsonValueType:
+ // The proto-to-JSON conversion rules would convert all 64-bit integer values to JSON
+ // decimal strings. Because CEL ints might come from the automatic widening of 32-bit
+ // values in protos, the JSON type is chosen dynamically based on the value.
+ //
+ // - Integers -2^53-1 < n < 2^53-1 are encoded as JSON numbers.
+ // - Integers outside this range are encoded as JSON strings.
+ //
+ // The integer to float range represents the largest interval where such a conversion
+ // can round-trip accurately. Thus, conversions from a 32-bit source can expect a JSON
+ // number as with protobuf. Those consuming JSON from a 64-bit source must be able to
+ // handle either a JSON number or a JSON decimal string. To handle these cases safely
+ // the string values must be explicitly converted to int() within a CEL expression;
+ // however, it is best to simply stay within the JSON number range when building JSON
+ // objects in CEL.
+ if i.isJSONSafe() {
+ return structpb.NewNumberValue(float64(i)), nil
+ }
+ // Proto3 to JSON conversion requires string-formatted int64 values
+ // since the conversion to floating point would result in truncation.
+ return structpb.NewStringValue(strconv.FormatInt(int64(i), 10)), nil
+ }
+ switch typeDesc.Elem().Kind() {
+ case reflect.Int32:
+ // Convert the value to a wrapperspb.Int32Value, error on overflow.
+ v, err := int64ToInt32Checked(int64(i))
+ if err != nil {
+ return nil, err
+ }
+ p := reflect.New(typeDesc.Elem())
+ p.Elem().Set(reflect.ValueOf(v).Convert(typeDesc.Elem()))
+ return p.Interface(), nil
+ case reflect.Int64:
+ v := int64(i)
+ p := reflect.New(typeDesc.Elem())
+ p.Elem().Set(reflect.ValueOf(v).Convert(typeDesc.Elem()))
+ return p.Interface(), nil
+ }
+ case reflect.Interface:
+ iv := i.Value()
+ if reflect.TypeOf(iv).Implements(typeDesc) {
+ return iv, nil
+ }
+ if reflect.TypeOf(i).Implements(typeDesc) {
+ return i, nil
+ }
+ }
+ return nil, fmt.Errorf("unsupported type conversion from 'int' to %v", typeDesc)
+}
+
+// ConvertToType implements ref.Val.ConvertToType.
+func (i Int) ConvertToType(typeVal ref.Type) ref.Val {
+ switch typeVal {
+ case IntType:
+ return i
+ case UintType:
+ u, err := int64ToUint64Checked(int64(i))
+ if err != nil {
+ return WrapErr(err)
+ }
+ return Uint(u)
+ case DoubleType:
+ return Double(i)
+ case StringType:
+ return String(fmt.Sprintf("%d", int64(i)))
+ case TimestampType:
+ // The maximum positive value that can be passed to time.Unix is math.MaxInt64 minus the number
+ // of seconds between year 1 and year 1970. See comments on unixToInternal.
+ if int64(i) < minUnixTime || int64(i) > maxUnixTime {
+ return celErrTimestampOverflow
+ }
+ return timestampOf(time.Unix(int64(i), 0).UTC())
+ case TypeType:
+ return IntType
+ }
+ return NewErr("type conversion error from '%s' to '%s'", IntType, typeVal)
+}
+
+// Divide implements traits.Divider.Divide.
+func (i Int) Divide(other ref.Val) ref.Val {
+ otherInt, ok := other.(Int)
+ if !ok {
+ return MaybeNoSuchOverloadErr(other)
+ }
+ val, err := divideInt64Checked(int64(i), int64(otherInt))
+ if err != nil {
+ return WrapErr(err)
+ }
+ return Int(val)
+}
+
+// Equal implements ref.Val.Equal.
+func (i Int) Equal(other ref.Val) ref.Val {
+ switch ov := other.(type) {
+ case Double:
+ if math.IsNaN(float64(ov)) {
+ return False
+ }
+ return Bool(compareIntDouble(i, ov) == 0)
+ case Int:
+ return Bool(i == ov)
+ case Uint:
+ return Bool(compareIntUint(i, ov) == 0)
+ default:
+ return False
+ }
+}
+
+// IsZeroValue returns true if integer is equal to 0
+func (i Int) IsZeroValue() bool {
+ return i == IntZero
+}
+
+// Modulo implements traits.Modder.Modulo.
+func (i Int) Modulo(other ref.Val) ref.Val {
+ otherInt, ok := other.(Int)
+ if !ok {
+ return MaybeNoSuchOverloadErr(other)
+ }
+ val, err := moduloInt64Checked(int64(i), int64(otherInt))
+ if err != nil {
+ return WrapErr(err)
+ }
+ return Int(val)
+}
+
+// Multiply implements traits.Multiplier.Multiply.
+func (i Int) Multiply(other ref.Val) ref.Val {
+ otherInt, ok := other.(Int)
+ if !ok {
+ return MaybeNoSuchOverloadErr(other)
+ }
+ val, err := multiplyInt64Checked(int64(i), int64(otherInt))
+ if err != nil {
+ return WrapErr(err)
+ }
+ return Int(val)
+}
+
+// Negate implements traits.Negater.Negate.
+func (i Int) Negate() ref.Val {
+ val, err := negateInt64Checked(int64(i))
+ if err != nil {
+ return WrapErr(err)
+ }
+ return Int(val)
+}
+
+// Subtract implements traits.Subtractor.Subtract.
+func (i Int) Subtract(subtrahend ref.Val) ref.Val {
+ subtraInt, ok := subtrahend.(Int)
+ if !ok {
+ return MaybeNoSuchOverloadErr(subtrahend)
+ }
+ val, err := subtractInt64Checked(int64(i), int64(subtraInt))
+ if err != nil {
+ return WrapErr(err)
+ }
+ return Int(val)
+}
+
+// Type implements ref.Val.Type.
+func (i Int) Type() ref.Type {
+ return IntType
+}
+
+// Value implements ref.Val.Value.
+func (i Int) Value() any {
+ return int64(i)
+}
+
+// isJSONSafe indicates whether the int is safely representable as a floating point value in JSON.
+func (i Int) isJSONSafe() bool {
+ return i >= minIntJSON && i <= maxIntJSON
+}
+
+const (
+ // maxIntJSON is defined as the Number.MAX_SAFE_INTEGER value per EcmaScript 6.
+ maxIntJSON = 1<<53 - 1
+ // minIntJSON is defined as the Number.MIN_SAFE_INTEGER value per EcmaScript 6.
+ minIntJSON = -maxIntJSON
+)
diff --git a/vendor/github.com/google/cel-go/common/types/iterator.go b/vendor/github.com/google/cel-go/common/types/iterator.go
new file mode 100644
index 000000000000..98e9147b6ee8
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/iterator.go
@@ -0,0 +1,55 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package types
+
+import (
+ "fmt"
+ "reflect"
+
+ "github.com/google/cel-go/common/types/ref"
+ "github.com/google/cel-go/common/types/traits"
+)
+
+var (
+ // IteratorType singleton.
+ IteratorType = NewObjectType("iterator", traits.IteratorType)
+)
+
+// baseIterator is the basis for list, map, and object iterators.
+//
+// An iterator in and of itself should not be a valid value for comparison, but must implement the
+// `ref.Val` methods in order to be well-supported within instruction arguments processed by the
+// interpreter.
+type baseIterator struct{}
+
+func (*baseIterator) ConvertToNative(typeDesc reflect.Type) (any, error) {
+ return nil, fmt.Errorf("type conversion on iterators not supported")
+}
+
+func (*baseIterator) ConvertToType(typeVal ref.Type) ref.Val {
+ return NewErr("no such overload")
+}
+
+func (*baseIterator) Equal(other ref.Val) ref.Val {
+ return NewErr("no such overload")
+}
+
+func (*baseIterator) Type() ref.Type {
+ return IteratorType
+}
+
+func (*baseIterator) Value() any {
+ return nil
+}
diff --git a/vendor/github.com/google/cel-go/common/types/json_value.go b/vendor/github.com/google/cel-go/common/types/json_value.go
new file mode 100644
index 000000000000..13a4efe7ada7
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/json_value.go
@@ -0,0 +1,29 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package types
+
+import (
+ "reflect"
+
+ structpb "google.golang.org/protobuf/types/known/structpb"
+)
+
+// JSON type constants representing the reflected types of protobuf JSON values.
+var (
+ jsonValueType = reflect.TypeOf(&structpb.Value{})
+ jsonListValueType = reflect.TypeOf(&structpb.ListValue{})
+ jsonStructType = reflect.TypeOf(&structpb.Struct{})
+ jsonNullType = reflect.TypeOf(structpb.NullValue_NULL_VALUE)
+)
diff --git a/vendor/github.com/google/cel-go/common/types/list.go b/vendor/github.com/google/cel-go/common/types/list.go
new file mode 100644
index 000000000000..06f48dde75f5
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/list.go
@@ -0,0 +1,529 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package types
+
+import (
+ "fmt"
+ "reflect"
+ "strings"
+
+ "google.golang.org/protobuf/proto"
+ "google.golang.org/protobuf/reflect/protoreflect"
+
+ "github.com/google/cel-go/common/types/ref"
+ "github.com/google/cel-go/common/types/traits"
+
+ anypb "google.golang.org/protobuf/types/known/anypb"
+ structpb "google.golang.org/protobuf/types/known/structpb"
+)
+
+// NewDynamicList returns a traits.Lister with heterogenous elements.
+// value should be an array of "native" types, i.e. any type that
+// NativeToValue() can convert to a ref.Val.
+func NewDynamicList(adapter Adapter, value any) traits.Lister {
+ refValue := reflect.ValueOf(value)
+ return &baseList{
+ Adapter: adapter,
+ value: value,
+ size: refValue.Len(),
+ get: func(i int) any {
+ return refValue.Index(i).Interface()
+ },
+ }
+}
+
+// NewStringList returns a traits.Lister containing only strings.
+func NewStringList(adapter Adapter, elems []string) traits.Lister {
+ return &baseList{
+ Adapter: adapter,
+ value: elems,
+ size: len(elems),
+ get: func(i int) any { return elems[i] },
+ }
+}
+
+// NewRefValList returns a traits.Lister with ref.Val elements.
+//
+// This type specialization is used with list literals within CEL expressions.
+func NewRefValList(adapter Adapter, elems []ref.Val) traits.Lister {
+ return &baseList{
+ Adapter: adapter,
+ value: elems,
+ size: len(elems),
+ get: func(i int) any { return elems[i] },
+ }
+}
+
+// NewProtoList returns a traits.Lister based on a pb.List instance.
+func NewProtoList(adapter Adapter, list protoreflect.List) traits.Lister {
+ return &baseList{
+ Adapter: adapter,
+ value: list,
+ size: list.Len(),
+ get: func(i int) any { return list.Get(i).Interface() },
+ }
+}
+
+// NewJSONList returns a traits.Lister based on structpb.ListValue instance.
+func NewJSONList(adapter Adapter, l *structpb.ListValue) traits.Lister {
+ vals := l.GetValues()
+ return &baseList{
+ Adapter: adapter,
+ value: l,
+ size: len(vals),
+ get: func(i int) any { return vals[i] },
+ }
+}
+
+// NewMutableList creates a new mutable list whose internal state can be modified.
+func NewMutableList(adapter Adapter) traits.MutableLister {
+ var mutableValues []ref.Val
+ l := &mutableList{
+ baseList: &baseList{
+ Adapter: adapter,
+ value: mutableValues,
+ size: 0,
+ },
+ mutableValues: mutableValues,
+ }
+ l.get = func(i int) any {
+ return l.mutableValues[i]
+ }
+ return l
+}
+
+// baseList points to a list containing elements of any type.
+// The `value` is an array of native values, and refValue is its reflection object.
+// The `Adapter` enables native type to CEL type conversions.
+type baseList struct {
+ Adapter
+ value any
+
+ // size indicates the number of elements within the list.
+ // Since objects are immutable the size of a list is static.
+ size int
+
+ // get returns a value at the specified integer index.
+ // The index is guaranteed to be checked against the list index range.
+ get func(int) any
+}
+
+// Add implements the traits.Adder interface method.
+func (l *baseList) Add(other ref.Val) ref.Val {
+ otherList, ok := other.(traits.Lister)
+ if !ok {
+ return MaybeNoSuchOverloadErr(other)
+ }
+ if l.Size() == IntZero {
+ return other
+ }
+ if otherList.Size() == IntZero {
+ return l
+ }
+ return &concatList{
+ Adapter: l.Adapter,
+ prevList: l,
+ nextList: otherList}
+}
+
+// Contains implements the traits.Container interface method.
+func (l *baseList) Contains(elem ref.Val) ref.Val {
+ for i := 0; i < l.size; i++ {
+ val := l.NativeToValue(l.get(i))
+ cmp := elem.Equal(val)
+ b, ok := cmp.(Bool)
+ if ok && b == True {
+ return True
+ }
+ }
+ return False
+}
+
+// ConvertToNative implements the ref.Val interface method.
+func (l *baseList) ConvertToNative(typeDesc reflect.Type) (any, error) {
+ // If the underlying list value is assignable to the reflected type return it.
+ if reflect.TypeOf(l.value).AssignableTo(typeDesc) {
+ return l.value, nil
+ }
+ // If the list wrapper is assignable to the desired type return it.
+ if reflect.TypeOf(l).AssignableTo(typeDesc) {
+ return l, nil
+ }
+ // Attempt to convert the list to a set of well known protobuf types.
+ switch typeDesc {
+ case anyValueType:
+ json, err := l.ConvertToNative(jsonListValueType)
+ if err != nil {
+ return nil, err
+ }
+ return anypb.New(json.(proto.Message))
+ case jsonValueType, jsonListValueType:
+ jsonValues, err :=
+ l.ConvertToNative(reflect.TypeOf([]*structpb.Value{}))
+ if err != nil {
+ return nil, err
+ }
+ jsonList := &structpb.ListValue{Values: jsonValues.([]*structpb.Value)}
+ if typeDesc == jsonListValueType {
+ return jsonList, nil
+ }
+ return structpb.NewListValue(jsonList), nil
+ }
+ // Non-list conversion.
+ if typeDesc.Kind() != reflect.Slice && typeDesc.Kind() != reflect.Array {
+ return nil, fmt.Errorf("type conversion error from list to '%v'", typeDesc)
+ }
+
+ // List conversion.
+ // Allow the element ConvertToNative() function to determine whether conversion is possible.
+ otherElemType := typeDesc.Elem()
+ elemCount := l.size
+ var nativeList reflect.Value
+ if typeDesc.Kind() == reflect.Array {
+ nativeList = reflect.New(reflect.ArrayOf(elemCount, typeDesc)).Elem().Index(0)
+ } else {
+ nativeList = reflect.MakeSlice(typeDesc, elemCount, elemCount)
+
+ }
+ for i := 0; i < elemCount; i++ {
+ elem := l.NativeToValue(l.get(i))
+ nativeElemVal, err := elem.ConvertToNative(otherElemType)
+ if err != nil {
+ return nil, err
+ }
+ nativeList.Index(i).Set(reflect.ValueOf(nativeElemVal))
+ }
+ return nativeList.Interface(), nil
+}
+
+// ConvertToType implements the ref.Val interface method.
+func (l *baseList) ConvertToType(typeVal ref.Type) ref.Val {
+ switch typeVal {
+ case ListType:
+ return l
+ case TypeType:
+ return ListType
+ }
+ return NewErr("type conversion error from '%s' to '%s'", ListType, typeVal)
+}
+
+// Equal implements the ref.Val interface method.
+func (l *baseList) Equal(other ref.Val) ref.Val {
+ otherList, ok := other.(traits.Lister)
+ if !ok {
+ return False
+ }
+ if l.Size() != otherList.Size() {
+ return False
+ }
+ for i := IntZero; i < l.Size().(Int); i++ {
+ thisElem := l.Get(i)
+ otherElem := otherList.Get(i)
+ elemEq := Equal(thisElem, otherElem)
+ if elemEq == False {
+ return False
+ }
+ }
+ return True
+}
+
+// Get implements the traits.Indexer interface method.
+func (l *baseList) Get(index ref.Val) ref.Val {
+ ind, err := IndexOrError(index)
+ if err != nil {
+ return ValOrErr(index, err.Error())
+ }
+ if ind < 0 || ind >= l.size {
+ return NewErr("index '%d' out of range in list size '%d'", ind, l.Size())
+ }
+ return l.NativeToValue(l.get(ind))
+}
+
+// IsZeroValue returns true if the list is empty.
+func (l *baseList) IsZeroValue() bool {
+ return l.size == 0
+}
+
+// Iterator implements the traits.Iterable interface method.
+func (l *baseList) Iterator() traits.Iterator {
+ return newListIterator(l)
+}
+
+// Size implements the traits.Sizer interface method.
+func (l *baseList) Size() ref.Val {
+ return Int(l.size)
+}
+
+// Type implements the ref.Val interface method.
+func (l *baseList) Type() ref.Type {
+ return ListType
+}
+
+// Value implements the ref.Val interface method.
+func (l *baseList) Value() any {
+ return l.value
+}
+
+// String converts the list to a human readable string form.
+func (l *baseList) String() string {
+ var sb strings.Builder
+ sb.WriteString("[")
+ for i := 0; i < l.size; i++ {
+ sb.WriteString(fmt.Sprintf("%v", l.get(i)))
+ if i != l.size-1 {
+ sb.WriteString(", ")
+ }
+ }
+ sb.WriteString("]")
+ return sb.String()
+}
+
+// mutableList aggregates values into its internal storage. For use with internal CEL variables only.
+type mutableList struct {
+ *baseList
+ mutableValues []ref.Val
+}
+
+// Add copies elements from the other list into the internal storage of the mutable list.
+// The ref.Val returned by Add is the receiver.
+func (l *mutableList) Add(other ref.Val) ref.Val {
+ switch otherList := other.(type) {
+ case *mutableList:
+ l.mutableValues = append(l.mutableValues, otherList.mutableValues...)
+ l.size += len(otherList.mutableValues)
+ case traits.Lister:
+ for i := IntZero; i < otherList.Size().(Int); i++ {
+ l.size++
+ l.mutableValues = append(l.mutableValues, otherList.Get(i))
+ }
+ default:
+ return MaybeNoSuchOverloadErr(otherList)
+ }
+ return l
+}
+
+// ToImmutableList returns an immutable list based on the internal storage of the mutable list.
+func (l *mutableList) ToImmutableList() traits.Lister {
+ // The reference to internal state is guaranteed to be safe as this call is only performed
+ // when mutations have been completed.
+ return NewRefValList(l.Adapter, l.mutableValues)
+}
+
+// concatList combines two list implementations together into a view.
+// The `Adapter` enables native type to CEL type conversions.
+type concatList struct {
+ Adapter
+ value any
+ prevList traits.Lister
+ nextList traits.Lister
+}
+
+// Add implements the traits.Adder interface method.
+func (l *concatList) Add(other ref.Val) ref.Val {
+ otherList, ok := other.(traits.Lister)
+ if !ok {
+ return MaybeNoSuchOverloadErr(other)
+ }
+ if l.Size() == IntZero {
+ return other
+ }
+ if otherList.Size() == IntZero {
+ return l
+ }
+ return &concatList{
+ Adapter: l.Adapter,
+ prevList: l,
+ nextList: otherList}
+}
+
+// Contains implements the traits.Container interface method.
+func (l *concatList) Contains(elem ref.Val) ref.Val {
+ // The concat list relies on the IsErrorOrUnknown checks against the input element to be
+ // performed by the `prevList` and/or `nextList`.
+ prev := l.prevList.Contains(elem)
+ // Short-circuit the return if the elem was found in the prev list.
+ if prev == True {
+ return prev
+ }
+ // Return if the elem was found in the next list.
+ next := l.nextList.Contains(elem)
+ if next == True {
+ return next
+ }
+ // Handle the case where an error or unknown was encountered before checking next.
+ if IsUnknownOrError(prev) {
+ return prev
+ }
+ // Otherwise, rely on the next value as the representative result.
+ return next
+}
+
+// ConvertToNative implements the ref.Val interface method.
+func (l *concatList) ConvertToNative(typeDesc reflect.Type) (any, error) {
+ combined := NewDynamicList(l.Adapter, l.Value().([]any))
+ return combined.ConvertToNative(typeDesc)
+}
+
+// ConvertToType implements the ref.Val interface method.
+func (l *concatList) ConvertToType(typeVal ref.Type) ref.Val {
+ switch typeVal {
+ case ListType:
+ return l
+ case TypeType:
+ return ListType
+ }
+ return NewErr("type conversion error from '%s' to '%s'", ListType, typeVal)
+}
+
+// Equal implements the ref.Val interface method.
+func (l *concatList) Equal(other ref.Val) ref.Val {
+ otherList, ok := other.(traits.Lister)
+ if !ok {
+ return False
+ }
+ if l.Size() != otherList.Size() {
+ return False
+ }
+ var maybeErr ref.Val
+ for i := IntZero; i < l.Size().(Int); i++ {
+ thisElem := l.Get(i)
+ otherElem := otherList.Get(i)
+ elemEq := Equal(thisElem, otherElem)
+ if elemEq == False {
+ return False
+ }
+ if maybeErr == nil && IsUnknownOrError(elemEq) {
+ maybeErr = elemEq
+ }
+ }
+ if maybeErr != nil {
+ return maybeErr
+ }
+ return True
+}
+
+// Get implements the traits.Indexer interface method.
+func (l *concatList) Get(index ref.Val) ref.Val {
+ ind, err := IndexOrError(index)
+ if err != nil {
+ return ValOrErr(index, err.Error())
+ }
+ i := Int(ind)
+ if i < l.prevList.Size().(Int) {
+ return l.prevList.Get(i)
+ }
+ offset := i - l.prevList.Size().(Int)
+ return l.nextList.Get(offset)
+}
+
+// IsZeroValue returns true if the list is empty.
+func (l *concatList) IsZeroValue() bool {
+ return l.Size().(Int) == 0
+}
+
+// Iterator implements the traits.Iterable interface method.
+func (l *concatList) Iterator() traits.Iterator {
+ return newListIterator(l)
+}
+
+// Size implements the traits.Sizer interface method.
+func (l *concatList) Size() ref.Val {
+ return l.prevList.Size().(Int).Add(l.nextList.Size())
+}
+
+// String converts the concatenated list to a human-readable string.
+func (l *concatList) String() string {
+ var sb strings.Builder
+ sb.WriteString("[")
+ for i := Int(0); i < l.Size().(Int); i++ {
+ sb.WriteString(fmt.Sprintf("%v", l.Get(i)))
+ if i != l.Size().(Int)-1 {
+ sb.WriteString(", ")
+ }
+ }
+ sb.WriteString("]")
+ return sb.String()
+}
+
+// Type implements the ref.Val interface method.
+func (l *concatList) Type() ref.Type {
+ return ListType
+}
+
+// Value implements the ref.Val interface method.
+func (l *concatList) Value() any {
+ if l.value == nil {
+ merged := make([]any, l.Size().(Int))
+ prevLen := l.prevList.Size().(Int)
+ for i := Int(0); i < prevLen; i++ {
+ merged[i] = l.prevList.Get(i).Value()
+ }
+ nextLen := l.nextList.Size().(Int)
+ for j := Int(0); j < nextLen; j++ {
+ merged[prevLen+j] = l.nextList.Get(j).Value()
+ }
+ l.value = merged
+ }
+ return l.value
+}
+
+func newListIterator(listValue traits.Lister) traits.Iterator {
+ return &listIterator{
+ listValue: listValue,
+ len: listValue.Size().(Int),
+ }
+}
+
+type listIterator struct {
+ *baseIterator
+ listValue traits.Lister
+ cursor Int
+ len Int
+}
+
+// HasNext implements the traits.Iterator interface method.
+func (it *listIterator) HasNext() ref.Val {
+ return Bool(it.cursor < it.len)
+}
+
+// Next implements the traits.Iterator interface method.
+func (it *listIterator) Next() ref.Val {
+ if it.HasNext() == True {
+ index := it.cursor
+ it.cursor++
+ return it.listValue.Get(index)
+ }
+ return nil
+}
+
+// IndexOrError converts an input index value into either a lossless integer index or an error.
+func IndexOrError(index ref.Val) (int, error) {
+ switch iv := index.(type) {
+ case Int:
+ return int(iv), nil
+ case Double:
+ if ik, ok := doubleToInt64Lossless(float64(iv)); ok {
+ return int(ik), nil
+ }
+ return -1, fmt.Errorf("unsupported index value %v in list", index)
+ case Uint:
+ if ik, ok := uint64ToInt64Lossless(uint64(iv)); ok {
+ return int(ik), nil
+ }
+ return -1, fmt.Errorf("unsupported index value %v in list", index)
+ default:
+ return -1, fmt.Errorf("unsupported index type '%s' in list", index.Type())
+ }
+}
diff --git a/vendor/github.com/google/cel-go/common/types/map.go b/vendor/github.com/google/cel-go/common/types/map.go
new file mode 100644
index 000000000000..739b7aab00d9
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/map.go
@@ -0,0 +1,854 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package types
+
+import (
+ "fmt"
+ "reflect"
+ "strings"
+
+ "github.com/stoewer/go-strcase"
+ "google.golang.org/protobuf/proto"
+ "google.golang.org/protobuf/reflect/protoreflect"
+
+ "github.com/google/cel-go/common/types/pb"
+ "github.com/google/cel-go/common/types/ref"
+ "github.com/google/cel-go/common/types/traits"
+
+ anypb "google.golang.org/protobuf/types/known/anypb"
+ structpb "google.golang.org/protobuf/types/known/structpb"
+)
+
+// NewDynamicMap returns a traits.Mapper value with dynamic key, value pairs.
+func NewDynamicMap(adapter Adapter, value any) traits.Mapper {
+ refValue := reflect.ValueOf(value)
+ return &baseMap{
+ Adapter: adapter,
+ mapAccessor: newReflectMapAccessor(adapter, refValue),
+ value: value,
+ size: refValue.Len(),
+ }
+}
+
+// NewJSONStruct creates a traits.Mapper implementation backed by a JSON struct that has been
+// encoded in protocol buffer form.
+//
+// The `adapter` argument provides type adaptation capabilities from proto to CEL.
+func NewJSONStruct(adapter Adapter, value *structpb.Struct) traits.Mapper {
+ fields := value.GetFields()
+ return &baseMap{
+ Adapter: adapter,
+ mapAccessor: newJSONStructAccessor(adapter, fields),
+ value: value,
+ size: len(fields),
+ }
+}
+
+// NewRefValMap returns a specialized traits.Mapper with CEL valued keys and values.
+func NewRefValMap(adapter Adapter, value map[ref.Val]ref.Val) traits.Mapper {
+ return &baseMap{
+ Adapter: adapter,
+ mapAccessor: newRefValMapAccessor(value),
+ value: value,
+ size: len(value),
+ }
+}
+
+// NewStringInterfaceMap returns a specialized traits.Mapper with string keys and interface values.
+func NewStringInterfaceMap(adapter Adapter, value map[string]any) traits.Mapper {
+ return &baseMap{
+ Adapter: adapter,
+ mapAccessor: newStringIfaceMapAccessor(adapter, value),
+ value: value,
+ size: len(value),
+ }
+}
+
+// NewStringStringMap returns a specialized traits.Mapper with string keys and values.
+func NewStringStringMap(adapter Adapter, value map[string]string) traits.Mapper {
+ return &baseMap{
+ Adapter: adapter,
+ mapAccessor: newStringMapAccessor(value),
+ value: value,
+ size: len(value),
+ }
+}
+
+// NewProtoMap returns a specialized traits.Mapper for handling protobuf map values.
+func NewProtoMap(adapter Adapter, value *pb.Map) traits.Mapper {
+ return &protoMap{
+ Adapter: adapter,
+ value: value,
+ }
+}
+
+// mapAccessor is a private interface for finding values within a map and iterating over the keys.
+// This interface implements portions of the API surface area required by the traits.Mapper
+// interface.
+type mapAccessor interface {
+ // Find returns a value, if one exists, for the input key.
+ //
+ // If the key is not found the function returns (nil, false).
+ Find(ref.Val) (ref.Val, bool)
+
+ // Iterator returns an Iterator over the map key set.
+ Iterator() traits.Iterator
+}
+
+// baseMap is a reflection based map implementation designed to handle a variety of map-like types.
+//
+// Since CEL is side-effect free, the base map represents an immutable object.
+type baseMap struct {
+ // TypeAdapter used to convert keys and values accessed within the map.
+ Adapter
+
+ // mapAccessor interface implementation used to find and iterate over map keys.
+ mapAccessor
+
+ // value is the native Go value upon which the map type operators.
+ value any
+
+ // size is the number of entries in the map.
+ size int
+}
+
+// Contains implements the traits.Container interface method.
+func (m *baseMap) Contains(index ref.Val) ref.Val {
+ _, found := m.Find(index)
+ return Bool(found)
+}
+
+// ConvertToNative implements the ref.Val interface method.
+func (m *baseMap) ConvertToNative(typeDesc reflect.Type) (any, error) {
+ // If the map is already assignable to the desired type return it, e.g. interfaces and
+ // maps with the same key value types.
+ if reflect.TypeOf(m.value).AssignableTo(typeDesc) {
+ return m.value, nil
+ }
+ if reflect.TypeOf(m).AssignableTo(typeDesc) {
+ return m, nil
+ }
+ switch typeDesc {
+ case anyValueType:
+ json, err := m.ConvertToNative(jsonStructType)
+ if err != nil {
+ return nil, err
+ }
+ return anypb.New(json.(proto.Message))
+ case jsonValueType, jsonStructType:
+ jsonEntries, err :=
+ m.ConvertToNative(reflect.TypeOf(map[string]*structpb.Value{}))
+ if err != nil {
+ return nil, err
+ }
+ jsonMap := &structpb.Struct{Fields: jsonEntries.(map[string]*structpb.Value)}
+ if typeDesc == jsonStructType {
+ return jsonMap, nil
+ }
+ return structpb.NewStructValue(jsonMap), nil
+ }
+
+ // Unwrap pointers, but track their use.
+ isPtr := false
+ if typeDesc.Kind() == reflect.Ptr {
+ tk := typeDesc
+ typeDesc = typeDesc.Elem()
+ if typeDesc.Kind() == reflect.Ptr {
+ return nil, fmt.Errorf("unsupported type conversion to '%v'", tk)
+ }
+ isPtr = true
+ }
+ switch typeDesc.Kind() {
+ // Map conversion.
+ case reflect.Map:
+ otherKey := typeDesc.Key()
+ otherElem := typeDesc.Elem()
+ nativeMap := reflect.MakeMapWithSize(typeDesc, m.size)
+ it := m.Iterator()
+ for it.HasNext() == True {
+ key := it.Next()
+ refKeyValue, err := key.ConvertToNative(otherKey)
+ if err != nil {
+ return nil, err
+ }
+ refElemValue, err := m.Get(key).ConvertToNative(otherElem)
+ if err != nil {
+ return nil, err
+ }
+ nativeMap.SetMapIndex(reflect.ValueOf(refKeyValue), reflect.ValueOf(refElemValue))
+ }
+ return nativeMap.Interface(), nil
+ case reflect.Struct:
+ nativeStructPtr := reflect.New(typeDesc)
+ nativeStruct := nativeStructPtr.Elem()
+ it := m.Iterator()
+ for it.HasNext() == True {
+ key := it.Next()
+ // Ensure the field name being referenced is exported.
+ // Only exported (public) field names can be set by reflection, where the name
+ // must be at least one character in length and start with an upper-case letter.
+ fieldName := key.ConvertToType(StringType)
+ if IsError(fieldName) {
+ return nil, fieldName.(*Err)
+ }
+ name := string(fieldName.(String))
+ name = strcase.UpperCamelCase(name)
+ fieldRef := nativeStruct.FieldByName(name)
+ if !fieldRef.IsValid() {
+ return nil, fmt.Errorf("type conversion error, no such field '%s' in type '%v'", name, typeDesc)
+ }
+ fieldValue, err := m.Get(key).ConvertToNative(fieldRef.Type())
+ if err != nil {
+ return nil, err
+ }
+ fieldRef.Set(reflect.ValueOf(fieldValue))
+ }
+ if isPtr {
+ return nativeStructPtr.Interface(), nil
+ }
+ return nativeStruct.Interface(), nil
+ }
+ return nil, fmt.Errorf("type conversion error from map to '%v'", typeDesc)
+}
+
+// ConvertToType implements the ref.Val interface method.
+func (m *baseMap) ConvertToType(typeVal ref.Type) ref.Val {
+ switch typeVal {
+ case MapType:
+ return m
+ case TypeType:
+ return MapType
+ }
+ return NewErr("type conversion error from '%s' to '%s'", MapType, typeVal)
+}
+
+// Equal implements the ref.Val interface method.
+func (m *baseMap) Equal(other ref.Val) ref.Val {
+ otherMap, ok := other.(traits.Mapper)
+ if !ok {
+ return False
+ }
+ if m.Size() != otherMap.Size() {
+ return False
+ }
+ it := m.Iterator()
+ for it.HasNext() == True {
+ key := it.Next()
+ thisVal, _ := m.Find(key)
+ otherVal, found := otherMap.Find(key)
+ if !found {
+ return False
+ }
+ valEq := Equal(thisVal, otherVal)
+ if valEq == False {
+ return False
+ }
+ }
+ return True
+}
+
+// Get implements the traits.Indexer interface method.
+func (m *baseMap) Get(key ref.Val) ref.Val {
+ v, found := m.Find(key)
+ if !found {
+ return ValOrErr(v, "no such key: %v", key)
+ }
+ return v
+}
+
+// IsZeroValue returns true if the map is empty.
+func (m *baseMap) IsZeroValue() bool {
+ return m.size == 0
+}
+
+// Size implements the traits.Sizer interface method.
+func (m *baseMap) Size() ref.Val {
+ return Int(m.size)
+}
+
+// String converts the map into a human-readable string.
+func (m *baseMap) String() string {
+ var sb strings.Builder
+ sb.WriteString("{")
+ it := m.Iterator()
+ i := 0
+ for it.HasNext() == True {
+ k := it.Next()
+ v, _ := m.Find(k)
+ sb.WriteString(fmt.Sprintf("%v: %v", k, v))
+ if i != m.size-1 {
+ sb.WriteString(", ")
+ }
+ i++
+ }
+ sb.WriteString("}")
+ return sb.String()
+}
+
+// Type implements the ref.Val interface method.
+func (m *baseMap) Type() ref.Type {
+ return MapType
+}
+
+// Value implements the ref.Val interface method.
+func (m *baseMap) Value() any {
+ return m.value
+}
+
+func newJSONStructAccessor(adapter Adapter, st map[string]*structpb.Value) mapAccessor {
+ return &jsonStructAccessor{
+ Adapter: adapter,
+ st: st,
+ }
+}
+
+type jsonStructAccessor struct {
+ Adapter
+ st map[string]*structpb.Value
+}
+
+// Find searches the json struct field map for the input key value and returns (value, true) if
+// found.
+//
+// If the key is not found the function returns (nil, false).
+func (a *jsonStructAccessor) Find(key ref.Val) (ref.Val, bool) {
+ strKey, ok := key.(String)
+ if !ok {
+ return nil, false
+ }
+ keyVal, found := a.st[string(strKey)]
+ if !found {
+ return nil, false
+ }
+ return a.NativeToValue(keyVal), true
+}
+
+// Iterator creates a new traits.Iterator from the set of JSON struct field names.
+func (a *jsonStructAccessor) Iterator() traits.Iterator {
+ // Copy the keys to make their order stable.
+ mapKeys := make([]string, len(a.st))
+ i := 0
+ for k := range a.st {
+ mapKeys[i] = k
+ i++
+ }
+ return &stringKeyIterator{
+ mapKeys: mapKeys,
+ len: len(mapKeys),
+ }
+}
+
+func newReflectMapAccessor(adapter Adapter, value reflect.Value) mapAccessor {
+ keyType := value.Type().Key()
+ return &reflectMapAccessor{
+ Adapter: adapter,
+ refValue: value,
+ keyType: keyType,
+ }
+}
+
+type reflectMapAccessor struct {
+ Adapter
+ refValue reflect.Value
+ keyType reflect.Type
+}
+
+// Find converts the input key to a native Golang type and then uses reflection to find the key,
+// returning (value, true) if present.
+//
+// If the key is not found the function returns (nil, false).
+func (m *reflectMapAccessor) Find(key ref.Val) (ref.Val, bool) {
+ if m.refValue.Len() == 0 {
+ return nil, false
+ }
+ if keyVal, found := m.findInternal(key); found {
+ return keyVal, true
+ }
+ switch k := key.(type) {
+ // Double is not a valid proto map key type, so check for the key as an int or uint.
+ case Double:
+ if ik, ok := doubleToInt64Lossless(float64(k)); ok {
+ if keyVal, found := m.findInternal(Int(ik)); found {
+ return keyVal, true
+ }
+ }
+ if uk, ok := doubleToUint64Lossless(float64(k)); ok {
+ return m.findInternal(Uint(uk))
+ }
+ // map keys of type double are not supported.
+ case Int:
+ if uk, ok := int64ToUint64Lossless(int64(k)); ok {
+ return m.findInternal(Uint(uk))
+ }
+ case Uint:
+ if ik, ok := uint64ToInt64Lossless(uint64(k)); ok {
+ return m.findInternal(Int(ik))
+ }
+ }
+ return nil, false
+}
+
+// findInternal attempts to convert the incoming key to the map's internal native type
+// and then returns the value, if found.
+func (m *reflectMapAccessor) findInternal(key ref.Val) (ref.Val, bool) {
+ k, err := key.ConvertToNative(m.keyType)
+ if err != nil {
+ return nil, false
+ }
+ refKey := reflect.ValueOf(k)
+ val := m.refValue.MapIndex(refKey)
+ if val.IsValid() {
+ return m.NativeToValue(val.Interface()), true
+ }
+ return nil, false
+}
+
+// Iterator creates a Golang reflection based traits.Iterator.
+func (m *reflectMapAccessor) Iterator() traits.Iterator {
+ return &mapIterator{
+ Adapter: m.Adapter,
+ mapKeys: m.refValue.MapRange(),
+ len: m.refValue.Len(),
+ }
+}
+
+func newRefValMapAccessor(mapVal map[ref.Val]ref.Val) mapAccessor {
+ return &refValMapAccessor{mapVal: mapVal}
+}
+
+type refValMapAccessor struct {
+ mapVal map[ref.Val]ref.Val
+}
+
+// Find uses native map accesses to find the key, returning (value, true) if present.
+//
+// If the key is not found the function returns (nil, false).
+func (a *refValMapAccessor) Find(key ref.Val) (ref.Val, bool) {
+ if len(a.mapVal) == 0 {
+ return nil, false
+ }
+ if keyVal, found := a.mapVal[key]; found {
+ return keyVal, true
+ }
+ switch k := key.(type) {
+ case Double:
+ if ik, ok := doubleToInt64Lossless(float64(k)); ok {
+ if keyVal, found := a.mapVal[Int(ik)]; found {
+ return keyVal, found
+ }
+ }
+ if uk, ok := doubleToUint64Lossless(float64(k)); ok {
+ keyVal, found := a.mapVal[Uint(uk)]
+ return keyVal, found
+ }
+ // map keys of type double are not supported.
+ case Int:
+ if uk, ok := int64ToUint64Lossless(int64(k)); ok {
+ keyVal, found := a.mapVal[Uint(uk)]
+ return keyVal, found
+ }
+ case Uint:
+ if ik, ok := uint64ToInt64Lossless(uint64(k)); ok {
+ keyVal, found := a.mapVal[Int(ik)]
+ return keyVal, found
+ }
+ }
+ return nil, false
+}
+
+// Iterator produces a new traits.Iterator which iterates over the map keys via Golang reflection.
+func (a *refValMapAccessor) Iterator() traits.Iterator {
+ return &mapIterator{
+ Adapter: DefaultTypeAdapter,
+ mapKeys: reflect.ValueOf(a.mapVal).MapRange(),
+ len: len(a.mapVal),
+ }
+}
+
+func newStringMapAccessor(strMap map[string]string) mapAccessor {
+ return &stringMapAccessor{mapVal: strMap}
+}
+
+type stringMapAccessor struct {
+ mapVal map[string]string
+}
+
+// Find uses native map accesses to find the key, returning (value, true) if present.
+//
+// If the key is not found the function returns (nil, false).
+func (a *stringMapAccessor) Find(key ref.Val) (ref.Val, bool) {
+ strKey, ok := key.(String)
+ if !ok {
+ return nil, false
+ }
+ keyVal, found := a.mapVal[string(strKey)]
+ if !found {
+ return nil, false
+ }
+ return String(keyVal), true
+}
+
+// Iterator creates a new traits.Iterator from the string key set of the map.
+func (a *stringMapAccessor) Iterator() traits.Iterator {
+ // Copy the keys to make their order stable.
+ mapKeys := make([]string, len(a.mapVal))
+ i := 0
+ for k := range a.mapVal {
+ mapKeys[i] = k
+ i++
+ }
+ return &stringKeyIterator{
+ mapKeys: mapKeys,
+ len: len(mapKeys),
+ }
+}
+
+func newStringIfaceMapAccessor(adapter Adapter, mapVal map[string]any) mapAccessor {
+ return &stringIfaceMapAccessor{
+ Adapter: adapter,
+ mapVal: mapVal,
+ }
+}
+
+type stringIfaceMapAccessor struct {
+ Adapter
+ mapVal map[string]any
+}
+
+// Find uses native map accesses to find the key, returning (value, true) if present.
+//
+// If the key is not found the function returns (nil, false).
+func (a *stringIfaceMapAccessor) Find(key ref.Val) (ref.Val, bool) {
+ strKey, ok := key.(String)
+ if !ok {
+ return nil, false
+ }
+ keyVal, found := a.mapVal[string(strKey)]
+ if !found {
+ return nil, false
+ }
+ return a.NativeToValue(keyVal), true
+}
+
+// Iterator creates a new traits.Iterator from the string key set of the map.
+func (a *stringIfaceMapAccessor) Iterator() traits.Iterator {
+ // Copy the keys to make their order stable.
+ mapKeys := make([]string, len(a.mapVal))
+ i := 0
+ for k := range a.mapVal {
+ mapKeys[i] = k
+ i++
+ }
+ return &stringKeyIterator{
+ mapKeys: mapKeys,
+ len: len(mapKeys),
+ }
+}
+
+// protoMap is a specialized, separate implementation of the traits.Mapper interfaces tailored to
+// accessing protoreflect.Map values.
+type protoMap struct {
+ Adapter
+ value *pb.Map
+}
+
+// Contains returns whether the map contains the given key.
+func (m *protoMap) Contains(key ref.Val) ref.Val {
+ _, found := m.Find(key)
+ return Bool(found)
+}
+
+// ConvertToNative implements the ref.Val interface method.
+//
+// Note, assignment to Golang struct types is not yet supported.
+func (m *protoMap) ConvertToNative(typeDesc reflect.Type) (any, error) {
+ // If the map is already assignable to the desired type return it, e.g. interfaces and
+ // maps with the same key value types.
+ switch typeDesc {
+ case anyValueType:
+ json, err := m.ConvertToNative(jsonStructType)
+ if err != nil {
+ return nil, err
+ }
+ return anypb.New(json.(proto.Message))
+ case jsonValueType, jsonStructType:
+ jsonEntries, err :=
+ m.ConvertToNative(reflect.TypeOf(map[string]*structpb.Value{}))
+ if err != nil {
+ return nil, err
+ }
+ jsonMap := &structpb.Struct{
+ Fields: jsonEntries.(map[string]*structpb.Value)}
+ if typeDesc == jsonStructType {
+ return jsonMap, nil
+ }
+ return structpb.NewStructValue(jsonMap), nil
+ }
+ switch typeDesc.Kind() {
+ case reflect.Struct, reflect.Ptr:
+ if reflect.TypeOf(m.value).AssignableTo(typeDesc) {
+ return m.value, nil
+ }
+ if reflect.TypeOf(m).AssignableTo(typeDesc) {
+ return m, nil
+ }
+ }
+ if typeDesc.Kind() != reflect.Map {
+ return nil, fmt.Errorf("unsupported type conversion: %v to map", typeDesc)
+ }
+
+ keyType := m.value.KeyType.ReflectType()
+ valType := m.value.ValueType.ReflectType()
+ otherKeyType := typeDesc.Key()
+ otherValType := typeDesc.Elem()
+ mapVal := reflect.MakeMapWithSize(typeDesc, m.value.Len())
+ var err error
+ m.value.Range(func(key protoreflect.MapKey, val protoreflect.Value) bool {
+ ntvKey := key.Interface()
+ ntvVal := val.Interface()
+ switch pv := ntvVal.(type) {
+ case protoreflect.Message:
+ ntvVal = pv.Interface()
+ }
+ if keyType == otherKeyType && valType == otherValType {
+ mapVal.SetMapIndex(reflect.ValueOf(ntvKey), reflect.ValueOf(ntvVal))
+ return true
+ }
+ celKey := m.NativeToValue(ntvKey)
+ celVal := m.NativeToValue(ntvVal)
+ ntvKey, err = celKey.ConvertToNative(otherKeyType)
+ if err != nil {
+ // early terminate the range loop.
+ return false
+ }
+ ntvVal, err = celVal.ConvertToNative(otherValType)
+ if err != nil {
+ // early terminate the range loop.
+ return false
+ }
+ mapVal.SetMapIndex(reflect.ValueOf(ntvKey), reflect.ValueOf(ntvVal))
+ return true
+ })
+ if err != nil {
+ return nil, err
+ }
+ return mapVal.Interface(), nil
+}
+
+// ConvertToType implements the ref.Val interface method.
+func (m *protoMap) ConvertToType(typeVal ref.Type) ref.Val {
+ switch typeVal {
+ case MapType:
+ return m
+ case TypeType:
+ return MapType
+ }
+ return NewErr("type conversion error from '%s' to '%s'", MapType, typeVal)
+}
+
+// Equal implements the ref.Val interface method.
+func (m *protoMap) Equal(other ref.Val) ref.Val {
+ otherMap, ok := other.(traits.Mapper)
+ if !ok {
+ return False
+ }
+ if m.value.Map.Len() != int(otherMap.Size().(Int)) {
+ return False
+ }
+ var retVal ref.Val = True
+ m.value.Range(func(key protoreflect.MapKey, val protoreflect.Value) bool {
+ keyVal := m.NativeToValue(key.Interface())
+ valVal := m.NativeToValue(val)
+ otherVal, found := otherMap.Find(keyVal)
+ if !found {
+ retVal = False
+ return false
+ }
+ valEq := Equal(valVal, otherVal)
+ if valEq != True {
+ retVal = valEq
+ return false
+ }
+ return true
+ })
+ return retVal
+}
+
+// Find returns whether the protoreflect.Map contains the input key.
+//
+// If the key is not found the function returns (nil, false).
+func (m *protoMap) Find(key ref.Val) (ref.Val, bool) {
+ if keyVal, found := m.findInternal(key); found {
+ return keyVal, true
+ }
+ switch k := key.(type) {
+ // Double is not a valid proto map key type, so check for the key as an int or uint.
+ case Double:
+ if ik, ok := doubleToInt64Lossless(float64(k)); ok {
+ if keyVal, found := m.findInternal(Int(ik)); found {
+ return keyVal, true
+ }
+ }
+ if uk, ok := doubleToUint64Lossless(float64(k)); ok {
+ return m.findInternal(Uint(uk))
+ }
+ // map keys of type double are not supported.
+ case Int:
+ if uk, ok := int64ToUint64Lossless(int64(k)); ok {
+ return m.findInternal(Uint(uk))
+ }
+ case Uint:
+ if ik, ok := uint64ToInt64Lossless(uint64(k)); ok {
+ return m.findInternal(Int(ik))
+ }
+ }
+ return nil, false
+}
+
+// findInternal attempts to convert the incoming key to the map's internal native type
+// and then returns the value, if found.
+func (m *protoMap) findInternal(key ref.Val) (ref.Val, bool) {
+ // Convert the input key to the expected protobuf key type.
+ ntvKey, err := key.ConvertToNative(m.value.KeyType.ReflectType())
+ if err != nil {
+ return nil, false
+ }
+ // Use protoreflection to get the key value.
+ val := m.value.Get(protoreflect.ValueOf(ntvKey).MapKey())
+ if !val.IsValid() {
+ return nil, false
+ }
+ // Perform nominal type unwrapping from the input value.
+ switch v := val.Interface().(type) {
+ case protoreflect.List, protoreflect.Map:
+ // Maps do not support list or map values
+ return nil, false
+ default:
+ return m.NativeToValue(v), true
+ }
+}
+
+// Get implements the traits.Indexer interface method.
+func (m *protoMap) Get(key ref.Val) ref.Val {
+ v, found := m.Find(key)
+ if !found {
+ return ValOrErr(v, "no such key: %v", key)
+ }
+ return v
+}
+
+// IsZeroValue returns true if the map is empty.
+func (m *protoMap) IsZeroValue() bool {
+ return m.value.Len() == 0
+}
+
+// Iterator implements the traits.Iterable interface method.
+func (m *protoMap) Iterator() traits.Iterator {
+ // Copy the keys to make their order stable.
+ mapKeys := make([]protoreflect.MapKey, 0, m.value.Len())
+ m.value.Range(func(k protoreflect.MapKey, v protoreflect.Value) bool {
+ mapKeys = append(mapKeys, k)
+ return true
+ })
+ return &protoMapIterator{
+ Adapter: m.Adapter,
+ mapKeys: mapKeys,
+ len: m.value.Len(),
+ }
+}
+
+// Size returns the number of entries in the protoreflect.Map.
+func (m *protoMap) Size() ref.Val {
+ return Int(m.value.Len())
+}
+
+// Type implements the ref.Val interface method.
+func (m *protoMap) Type() ref.Type {
+ return MapType
+}
+
+// Value implements the ref.Val interface method.
+func (m *protoMap) Value() any {
+ return m.value
+}
+
+type mapIterator struct {
+ *baseIterator
+ Adapter
+ mapKeys *reflect.MapIter
+ cursor int
+ len int
+}
+
+// HasNext implements the traits.Iterator interface method.
+func (it *mapIterator) HasNext() ref.Val {
+ return Bool(it.cursor < it.len)
+}
+
+// Next implements the traits.Iterator interface method.
+func (it *mapIterator) Next() ref.Val {
+ if it.HasNext() == True && it.mapKeys.Next() {
+ it.cursor++
+ refKey := it.mapKeys.Key()
+ return it.NativeToValue(refKey.Interface())
+ }
+ return nil
+}
+
+type protoMapIterator struct {
+ *baseIterator
+ Adapter
+ mapKeys []protoreflect.MapKey
+ cursor int
+ len int
+}
+
+// HasNext implements the traits.Iterator interface method.
+func (it *protoMapIterator) HasNext() ref.Val {
+ return Bool(it.cursor < it.len)
+}
+
+// Next implements the traits.Iterator interface method.
+func (it *protoMapIterator) Next() ref.Val {
+ if it.HasNext() == True {
+ index := it.cursor
+ it.cursor++
+ refKey := it.mapKeys[index]
+ return it.NativeToValue(refKey.Interface())
+ }
+ return nil
+}
+
+type stringKeyIterator struct {
+ *baseIterator
+ mapKeys []string
+ cursor int
+ len int
+}
+
+// HasNext implements the traits.Iterator interface method.
+func (it *stringKeyIterator) HasNext() ref.Val {
+ return Bool(it.cursor < it.len)
+}
+
+// Next implements the traits.Iterator interface method.
+func (it *stringKeyIterator) Next() ref.Val {
+ if it.HasNext() == True {
+ index := it.cursor
+ it.cursor++
+ return String(it.mapKeys[index])
+ }
+ return nil
+}
diff --git a/vendor/github.com/google/cel-go/common/types/null.go b/vendor/github.com/google/cel-go/common/types/null.go
new file mode 100644
index 000000000000..926ca3dc980b
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/null.go
@@ -0,0 +1,111 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package types
+
+import (
+ "fmt"
+ "reflect"
+
+ "google.golang.org/protobuf/proto"
+
+ "github.com/google/cel-go/common/types/ref"
+
+ anypb "google.golang.org/protobuf/types/known/anypb"
+ structpb "google.golang.org/protobuf/types/known/structpb"
+)
+
+// Null type implementation.
+type Null structpb.NullValue
+
+var (
+ // NullValue singleton.
+ NullValue = Null(structpb.NullValue_NULL_VALUE)
+
+ // golang reflect type for Null values.
+ nullReflectType = reflect.TypeOf(NullValue)
+)
+
+// ConvertToNative implements ref.Val.ConvertToNative.
+func (n Null) ConvertToNative(typeDesc reflect.Type) (any, error) {
+ switch typeDesc.Kind() {
+ case reflect.Int32:
+ switch typeDesc {
+ case jsonNullType:
+ return structpb.NullValue_NULL_VALUE, nil
+ case nullReflectType:
+ return n, nil
+ }
+ case reflect.Ptr:
+ switch typeDesc {
+ case anyValueType:
+ // Convert to a JSON-null before packing to an Any field since the enum value for JSON
+ // null cannot be packed directly.
+ pb, err := n.ConvertToNative(jsonValueType)
+ if err != nil {
+ return nil, err
+ }
+ return anypb.New(pb.(proto.Message))
+ case jsonValueType:
+ return structpb.NewNullValue(), nil
+ case boolWrapperType, byteWrapperType, doubleWrapperType, floatWrapperType,
+ int32WrapperType, int64WrapperType, stringWrapperType, uint32WrapperType,
+ uint64WrapperType:
+ return nil, nil
+ }
+ case reflect.Interface:
+ nv := n.Value()
+ if reflect.TypeOf(nv).Implements(typeDesc) {
+ return nv, nil
+ }
+ if reflect.TypeOf(n).Implements(typeDesc) {
+ return n, nil
+ }
+ }
+ // If the type conversion isn't supported return an error.
+ return nil, fmt.Errorf("type conversion error from '%v' to '%v'", NullType, typeDesc)
+}
+
+// ConvertToType implements ref.Val.ConvertToType.
+func (n Null) ConvertToType(typeVal ref.Type) ref.Val {
+ switch typeVal {
+ case StringType:
+ return String("null")
+ case NullType:
+ return n
+ case TypeType:
+ return NullType
+ }
+ return NewErr("type conversion error from '%s' to '%s'", NullType, typeVal)
+}
+
+// Equal implements ref.Val.Equal.
+func (n Null) Equal(other ref.Val) ref.Val {
+ return Bool(NullType == other.Type())
+}
+
+// IsZeroValue returns true as null always represents an absent value.
+func (n Null) IsZeroValue() bool {
+ return true
+}
+
+// Type implements ref.Val.Type.
+func (n Null) Type() ref.Type {
+ return NullType
+}
+
+// Value implements ref.Val.Value.
+func (n Null) Value() any {
+ return structpb.NullValue_NULL_VALUE
+}
diff --git a/vendor/github.com/google/cel-go/common/types/object.go b/vendor/github.com/google/cel-go/common/types/object.go
new file mode 100644
index 000000000000..8ba0af9fbe1c
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/object.go
@@ -0,0 +1,165 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package types
+
+import (
+ "fmt"
+ "reflect"
+
+ "google.golang.org/protobuf/encoding/protojson"
+ "google.golang.org/protobuf/proto"
+
+ "github.com/google/cel-go/common/types/pb"
+ "github.com/google/cel-go/common/types/ref"
+
+ anypb "google.golang.org/protobuf/types/known/anypb"
+ structpb "google.golang.org/protobuf/types/known/structpb"
+)
+
+type protoObj struct {
+ Adapter
+ value proto.Message
+ typeDesc *pb.TypeDescription
+ typeValue ref.Val
+}
+
+// NewObject returns an object based on a proto.Message value which handles
+// conversion between protobuf type values and expression type values.
+// Objects support indexing and iteration.
+//
+// Note: the type value is pulled from the list of registered types within the
+// type provider. If the proto type is not registered within the type provider,
+// then this will result in an error within the type adapter / provider.
+func NewObject(adapter Adapter,
+ typeDesc *pb.TypeDescription,
+ typeValue ref.Val,
+ value proto.Message) ref.Val {
+ return &protoObj{
+ Adapter: adapter,
+ value: value,
+ typeDesc: typeDesc,
+ typeValue: typeValue}
+}
+
+func (o *protoObj) ConvertToNative(typeDesc reflect.Type) (any, error) {
+ srcPB := o.value
+ if reflect.TypeOf(srcPB).AssignableTo(typeDesc) {
+ return srcPB, nil
+ }
+ if reflect.TypeOf(o).AssignableTo(typeDesc) {
+ return o, nil
+ }
+ switch typeDesc {
+ case anyValueType:
+ _, isAny := srcPB.(*anypb.Any)
+ if isAny {
+ return srcPB, nil
+ }
+ return anypb.New(srcPB)
+ case jsonValueType:
+ // Marshal the proto to JSON first, and then rehydrate as protobuf.Value as there is no
+ // support for direct conversion from proto.Message to protobuf.Value.
+ bytes, err := protojson.Marshal(srcPB)
+ if err != nil {
+ return nil, err
+ }
+ json := &structpb.Value{}
+ err = protojson.Unmarshal(bytes, json)
+ if err != nil {
+ return nil, err
+ }
+ return json, nil
+ default:
+ if typeDesc == o.typeDesc.ReflectType() {
+ return o.value, nil
+ }
+ if typeDesc.Kind() == reflect.Ptr {
+ val := reflect.New(typeDesc.Elem()).Interface()
+ dstPB, ok := val.(proto.Message)
+ if ok {
+ err := pb.Merge(dstPB, srcPB)
+ if err != nil {
+ return nil, fmt.Errorf("type conversion error: %v", err)
+ }
+ return dstPB, nil
+ }
+ }
+ }
+ return nil, fmt.Errorf("type conversion error from '%T' to '%v'", o.value, typeDesc)
+}
+
+func (o *protoObj) ConvertToType(typeVal ref.Type) ref.Val {
+ switch typeVal {
+ default:
+ if o.Type().TypeName() == typeVal.TypeName() {
+ return o
+ }
+ case TypeType:
+ return o.typeValue
+ }
+ return NewErr("type conversion error from '%s' to '%s'", o.typeDesc.Name(), typeVal)
+}
+
+func (o *protoObj) Equal(other ref.Val) ref.Val {
+ otherPB, ok := other.Value().(proto.Message)
+ return Bool(ok && pb.Equal(o.value, otherPB))
+}
+
+// IsSet tests whether a field which is defined is set to a non-default value.
+func (o *protoObj) IsSet(field ref.Val) ref.Val {
+ protoFieldName, ok := field.(String)
+ if !ok {
+ return MaybeNoSuchOverloadErr(field)
+ }
+ protoFieldStr := string(protoFieldName)
+ fd, found := o.typeDesc.FieldByName(protoFieldStr)
+ if !found {
+ return NewErr("no such field '%s'", field)
+ }
+ if fd.IsSet(o.value) {
+ return True
+ }
+ return False
+}
+
+// IsZeroValue returns true if the protobuf object is empty.
+func (o *protoObj) IsZeroValue() bool {
+ return proto.Equal(o.value, o.typeDesc.Zero())
+}
+
+func (o *protoObj) Get(index ref.Val) ref.Val {
+ protoFieldName, ok := index.(String)
+ if !ok {
+ return MaybeNoSuchOverloadErr(index)
+ }
+ protoFieldStr := string(protoFieldName)
+ fd, found := o.typeDesc.FieldByName(protoFieldStr)
+ if !found {
+ return NewErr("no such field '%s'", index)
+ }
+ fv, err := fd.GetFrom(o.value)
+ if err != nil {
+ return NewErr(err.Error())
+ }
+ return o.NativeToValue(fv)
+}
+
+func (o *protoObj) Type() ref.Type {
+ return o.typeValue.(ref.Type)
+}
+
+func (o *protoObj) Value() any {
+ return o.value
+}
diff --git a/vendor/github.com/google/cel-go/common/types/optional.go b/vendor/github.com/google/cel-go/common/types/optional.go
new file mode 100644
index 000000000000..97845a740c89
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/optional.go
@@ -0,0 +1,108 @@
+// Copyright 2022 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package types
+
+import (
+ "errors"
+ "fmt"
+ "reflect"
+
+ "github.com/google/cel-go/common/types/ref"
+)
+
+var (
+ // OptionalType indicates the runtime type of an optional value.
+ OptionalType = NewOpaqueType("optional_type")
+
+ // OptionalNone is a sentinel value which is used to indicate an empty optional value.
+ OptionalNone = &Optional{}
+)
+
+// OptionalOf returns an optional value which wraps a concrete CEL value.
+func OptionalOf(value ref.Val) *Optional {
+ return &Optional{value: value}
+}
+
+// Optional value which points to a value if non-empty.
+type Optional struct {
+ value ref.Val
+}
+
+// HasValue returns true if the optional has a value.
+func (o *Optional) HasValue() bool {
+ return o.value != nil
+}
+
+// GetValue returns the wrapped value contained in the optional.
+func (o *Optional) GetValue() ref.Val {
+ if !o.HasValue() {
+ return NewErr("optional.none() dereference")
+ }
+ return o.value
+}
+
+// ConvertToNative implements the ref.Val interface method.
+func (o *Optional) ConvertToNative(typeDesc reflect.Type) (any, error) {
+ if !o.HasValue() {
+ return nil, errors.New("optional.none() dereference")
+ }
+ return o.value.ConvertToNative(typeDesc)
+}
+
+// ConvertToType implements the ref.Val interface method.
+func (o *Optional) ConvertToType(typeVal ref.Type) ref.Val {
+ switch typeVal {
+ case OptionalType:
+ return o
+ case TypeType:
+ return OptionalType
+ }
+ return NewErr("type conversion error from '%s' to '%s'", OptionalType, typeVal)
+}
+
+// Equal determines whether the values contained by two optional values are equal.
+func (o *Optional) Equal(other ref.Val) ref.Val {
+ otherOpt, isOpt := other.(*Optional)
+ if !isOpt {
+ return False
+ }
+ if !o.HasValue() {
+ return Bool(!otherOpt.HasValue())
+ }
+ if !otherOpt.HasValue() {
+ return False
+ }
+ return o.value.Equal(otherOpt.value)
+}
+
+func (o *Optional) String() string {
+ if o.HasValue() {
+ return fmt.Sprintf("optional(%v)", o.GetValue())
+ }
+ return "optional.none()"
+}
+
+// Type implements the ref.Val interface method.
+func (o *Optional) Type() ref.Type {
+ return OptionalType
+}
+
+// Value returns the underlying 'Value()' of the wrapped value, if present.
+func (o *Optional) Value() any {
+ if o.value == nil {
+ return nil
+ }
+ return o.value.Value()
+}
diff --git a/vendor/github.com/google/cel-go/common/types/overflow.go b/vendor/github.com/google/cel-go/common/types/overflow.go
new file mode 100644
index 000000000000..dcb66ef59613
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/overflow.go
@@ -0,0 +1,429 @@
+// Copyright 2021 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package types
+
+import (
+ "math"
+ "time"
+)
+
+var (
+ doubleTwoTo64 = math.Ldexp(1.0, 64)
+)
+
+// addInt64Checked performs addition with overflow detection of two int64 values.
+//
+// If the operation fails the error return value will be non-nil.
+func addInt64Checked(x, y int64) (int64, error) {
+ if (y > 0 && x > math.MaxInt64-y) || (y < 0 && x < math.MinInt64-y) {
+ return 0, errIntOverflow
+ }
+ return x + y, nil
+}
+
+// subtractInt64Checked performs subtraction with overflow detection of two int64 values.
+//
+// If the operation fails the error return value will be non-nil.
+func subtractInt64Checked(x, y int64) (int64, error) {
+ if (y < 0 && x > math.MaxInt64+y) || (y > 0 && x < math.MinInt64+y) {
+ return 0, errIntOverflow
+ }
+ return x - y, nil
+}
+
+// negateInt64Checked performs negation with overflow detection of an int64.
+//
+// If the operation fails the error return value will be non-nil.
+func negateInt64Checked(x int64) (int64, error) {
+ // In twos complement, negating MinInt64 would result in a valid of MaxInt64+1.
+ if x == math.MinInt64 {
+ return 0, errIntOverflow
+ }
+ return -x, nil
+}
+
+// multiplyInt64Checked performs multiplication with overflow detection of two int64 value.
+//
+// If the operation fails the error return value will be non-nil.
+func multiplyInt64Checked(x, y int64) (int64, error) {
+ // Detecting multiplication overflow is more complicated than the others. The first two detect
+ // attempting to negate MinInt64, which would result in MaxInt64+1. The other four detect normal
+ // overflow conditions.
+ if (x == -1 && y == math.MinInt64) || (y == -1 && x == math.MinInt64) ||
+ // x is positive, y is positive
+ (x > 0 && y > 0 && x > math.MaxInt64/y) ||
+ // x is positive, y is negative
+ (x > 0 && y < 0 && y < math.MinInt64/x) ||
+ // x is negative, y is positive
+ (x < 0 && y > 0 && x < math.MinInt64/y) ||
+ // x is negative, y is negative
+ (x < 0 && y < 0 && y < math.MaxInt64/x) {
+ return 0, errIntOverflow
+ }
+ return x * y, nil
+}
+
+// divideInt64Checked performs division with overflow detection of two int64 values,
+// as well as a division by zero check.
+//
+// If the operation fails the error return value will be non-nil.
+func divideInt64Checked(x, y int64) (int64, error) {
+ // Division by zero.
+ if y == 0 {
+ return 0, errDivideByZero
+ }
+ // In twos complement, negating MinInt64 would result in a valid of MaxInt64+1.
+ if x == math.MinInt64 && y == -1 {
+ return 0, errIntOverflow
+ }
+ return x / y, nil
+}
+
+// moduloInt64Checked performs modulo with overflow detection of two int64 values
+// as well as a modulus by zero check.
+//
+// If the operation fails the error return value will be non-nil.
+func moduloInt64Checked(x, y int64) (int64, error) {
+ // Modulus by zero.
+ if y == 0 {
+ return 0, errModulusByZero
+ }
+ // In twos complement, negating MinInt64 would result in a valid of MaxInt64+1.
+ if x == math.MinInt64 && y == -1 {
+ return 0, errIntOverflow
+ }
+ return x % y, nil
+}
+
+// addUint64Checked performs addition with overflow detection of two uint64 values.
+//
+// If the operation fails due to overflow the error return value will be non-nil.
+func addUint64Checked(x, y uint64) (uint64, error) {
+ if y > 0 && x > math.MaxUint64-y {
+ return 0, errUintOverflow
+ }
+ return x + y, nil
+}
+
+// subtractUint64Checked performs subtraction with overflow detection of two uint64 values.
+//
+// If the operation fails due to overflow the error return value will be non-nil.
+func subtractUint64Checked(x, y uint64) (uint64, error) {
+ if y > x {
+ return 0, errUintOverflow
+ }
+ return x - y, nil
+}
+
+// multiplyUint64Checked performs multiplication with overflow detection of two uint64 values.
+//
+// If the operation fails due to overflow the error return value will be non-nil.
+func multiplyUint64Checked(x, y uint64) (uint64, error) {
+ if y != 0 && x > math.MaxUint64/y {
+ return 0, errUintOverflow
+ }
+ return x * y, nil
+}
+
+// divideUint64Checked performs division with a test for division by zero.
+//
+// If the operation fails the error return value will be non-nil.
+func divideUint64Checked(x, y uint64) (uint64, error) {
+ if y == 0 {
+ return 0, errDivideByZero
+ }
+ return x / y, nil
+}
+
+// moduloUint64Checked performs modulo with a test for modulus by zero.
+//
+// If the operation fails the error return value will be non-nil.
+func moduloUint64Checked(x, y uint64) (uint64, error) {
+ if y == 0 {
+ return 0, errModulusByZero
+ }
+ return x % y, nil
+}
+
+// addDurationChecked performs addition with overflow detection of two time.Durations.
+//
+// If the operation fails due to overflow the error return value will be non-nil.
+func addDurationChecked(x, y time.Duration) (time.Duration, error) {
+ val, err := addInt64Checked(int64(x), int64(y))
+ if err != nil {
+ return time.Duration(0), err
+ }
+ return time.Duration(val), nil
+}
+
+// subtractDurationChecked performs subtraction with overflow detection of two time.Durations.
+//
+// If the operation fails due to overflow the error return value will be non-nil.
+func subtractDurationChecked(x, y time.Duration) (time.Duration, error) {
+ val, err := subtractInt64Checked(int64(x), int64(y))
+ if err != nil {
+ return time.Duration(0), err
+ }
+ return time.Duration(val), nil
+}
+
+// negateDurationChecked performs negation with overflow detection of a time.Duration.
+//
+// If the operation fails due to overflow the error return value will be non-nil.
+func negateDurationChecked(x time.Duration) (time.Duration, error) {
+ val, err := negateInt64Checked(int64(x))
+ if err != nil {
+ return time.Duration(0), err
+ }
+ return time.Duration(val), nil
+}
+
+// addDurationChecked performs addition with overflow detection of a time.Time and time.Duration.
+//
+// If the operation fails due to overflow the error return value will be non-nil.
+func addTimeDurationChecked(x time.Time, y time.Duration) (time.Time, error) {
+ // This is tricky. A time is represented as (int64, int32) where the first is seconds and second
+ // is nanoseconds. A duration is int64 representing nanoseconds. We cannot normalize time to int64
+ // as it could potentially overflow. The only way to proceed is to break time and duration into
+ // second and nanosecond components.
+
+ // First we break time into its components by truncating and subtracting.
+ sec1 := x.Truncate(time.Second).Unix() // Truncate to seconds.
+ nsec1 := x.Sub(x.Truncate(time.Second)).Nanoseconds() // Get nanoseconds by truncating and subtracting.
+
+ // Second we break duration into its components by dividing and modulo.
+ sec2 := int64(y) / int64(time.Second) // Truncate to seconds.
+ nsec2 := int64(y) % int64(time.Second) // Get remainder.
+
+ // Add seconds first, detecting any overflow.
+ sec, err := addInt64Checked(sec1, sec2)
+ if err != nil {
+ return time.Time{}, err
+ }
+ // Nanoseconds cannot overflow as time.Time normalizes them to [0, 999999999].
+ nsec := nsec1 + nsec2
+
+ // We need to normalize nanoseconds to be positive and carry extra nanoseconds to seconds.
+ // Adapted from time.Unix(int64, int64).
+ if nsec < 0 || nsec >= int64(time.Second) {
+ // Add seconds.
+ sec, err = addInt64Checked(sec, nsec/int64(time.Second))
+ if err != nil {
+ return time.Time{}, err
+ }
+
+ nsec -= (nsec / int64(time.Second)) * int64(time.Second)
+ if nsec < 0 {
+ // Subtract an extra second
+ sec, err = addInt64Checked(sec, -1)
+ if err != nil {
+ return time.Time{}, err
+ }
+ nsec += int64(time.Second)
+ }
+ }
+
+ // Check if the the number of seconds from Unix epoch is within our acceptable range.
+ if sec < minUnixTime || sec > maxUnixTime {
+ return time.Time{}, errTimestampOverflow
+ }
+
+ // Return resulting time and propagate time zone.
+ return time.Unix(sec, nsec).In(x.Location()), nil
+}
+
+// subtractTimeChecked performs subtraction with overflow detection of two time.Time.
+//
+// If the operation fails due to overflow the error return value will be non-nil.
+func subtractTimeChecked(x, y time.Time) (time.Duration, error) {
+ // Similar to addTimeDurationOverflow() above.
+
+ // First we break time into its components by truncating and subtracting.
+ sec1 := x.Truncate(time.Second).Unix() // Truncate to seconds.
+ nsec1 := x.Sub(x.Truncate(time.Second)).Nanoseconds() // Get nanoseconds by truncating and subtracting.
+
+ // Second we break duration into its components by truncating and subtracting.
+ sec2 := y.Truncate(time.Second).Unix() // Truncate to seconds.
+ nsec2 := y.Sub(y.Truncate(time.Second)).Nanoseconds() // Get nanoseconds by truncating and subtracting.
+
+ // Subtract seconds first, detecting any overflow.
+ sec, err := subtractInt64Checked(sec1, sec2)
+ if err != nil {
+ return time.Duration(0), err
+ }
+
+ // Nanoseconds cannot overflow as time.Time normalizes them to [0, 999999999].
+ nsec := nsec1 - nsec2
+
+ // Scale seconds to nanoseconds detecting overflow.
+ tsec, err := multiplyInt64Checked(sec, int64(time.Second))
+ if err != nil {
+ return time.Duration(0), err
+ }
+
+ // Lastly we need to add the two nanoseconds together.
+ val, err := addInt64Checked(tsec, nsec)
+ if err != nil {
+ return time.Duration(0), err
+ }
+
+ return time.Duration(val), nil
+}
+
+// subtractTimeDurationChecked performs subtraction with overflow detection of a time.Time and
+// time.Duration.
+//
+// If the operation fails due to overflow the error return value will be non-nil.
+func subtractTimeDurationChecked(x time.Time, y time.Duration) (time.Time, error) {
+ // The easiest way to implement this is to negate y and add them.
+ // x - y = x + -y
+ val, err := negateDurationChecked(y)
+ if err != nil {
+ return time.Time{}, err
+ }
+ return addTimeDurationChecked(x, val)
+}
+
+// doubleToInt64Checked converts a double to an int64 value.
+//
+// If the conversion fails due to overflow the error return value will be non-nil.
+func doubleToInt64Checked(v float64) (int64, error) {
+ if math.IsInf(v, 0) || math.IsNaN(v) || v <= float64(math.MinInt64) || v >= float64(math.MaxInt64) {
+ return 0, errIntOverflow
+ }
+ return int64(v), nil
+}
+
+// doubleToInt64Checked converts a double to a uint64 value.
+//
+// If the conversion fails due to overflow the error return value will be non-nil.
+func doubleToUint64Checked(v float64) (uint64, error) {
+ if math.IsInf(v, 0) || math.IsNaN(v) || v < 0 || v >= doubleTwoTo64 {
+ return 0, errUintOverflow
+ }
+ return uint64(v), nil
+}
+
+// int64ToUint64Checked converts an int64 to a uint64 value.
+//
+// If the conversion fails due to overflow the error return value will be non-nil.
+func int64ToUint64Checked(v int64) (uint64, error) {
+ if v < 0 {
+ return 0, errUintOverflow
+ }
+ return uint64(v), nil
+}
+
+// int64ToInt8Checked converts an int64 to an int8 value.
+//
+// If the conversion fails due to overflow the error return value will be non-nil.
+func int64ToInt8Checked(v int64) (int8, error) {
+ if v < math.MinInt8 || v > math.MaxInt8 {
+ return 0, errIntOverflow
+ }
+ return int8(v), nil
+}
+
+// int64ToInt16Checked converts an int64 to an int16 value.
+//
+// If the conversion fails due to overflow the error return value will be non-nil.
+func int64ToInt16Checked(v int64) (int16, error) {
+ if v < math.MinInt16 || v > math.MaxInt16 {
+ return 0, errIntOverflow
+ }
+ return int16(v), nil
+}
+
+// int64ToInt32Checked converts an int64 to an int32 value.
+//
+// If the conversion fails due to overflow the error return value will be non-nil.
+func int64ToInt32Checked(v int64) (int32, error) {
+ if v < math.MinInt32 || v > math.MaxInt32 {
+ return 0, errIntOverflow
+ }
+ return int32(v), nil
+}
+
+// uint64ToUint8Checked converts a uint64 to a uint8 value.
+//
+// If the conversion fails due to overflow the error return value will be non-nil.
+func uint64ToUint8Checked(v uint64) (uint8, error) {
+ if v > math.MaxUint8 {
+ return 0, errUintOverflow
+ }
+ return uint8(v), nil
+}
+
+// uint64ToUint16Checked converts a uint64 to a uint16 value.
+//
+// If the conversion fails due to overflow the error return value will be non-nil.
+func uint64ToUint16Checked(v uint64) (uint16, error) {
+ if v > math.MaxUint16 {
+ return 0, errUintOverflow
+ }
+ return uint16(v), nil
+}
+
+// uint64ToUint32Checked converts a uint64 to a uint32 value.
+//
+// If the conversion fails due to overflow the error return value will be non-nil.
+func uint64ToUint32Checked(v uint64) (uint32, error) {
+ if v > math.MaxUint32 {
+ return 0, errUintOverflow
+ }
+ return uint32(v), nil
+}
+
+// uint64ToInt64Checked converts a uint64 to an int64 value.
+//
+// If the conversion fails due to overflow the error return value will be non-nil.
+func uint64ToInt64Checked(v uint64) (int64, error) {
+ if v > math.MaxInt64 {
+ return 0, errIntOverflow
+ }
+ return int64(v), nil
+}
+
+func doubleToUint64Lossless(v float64) (uint64, bool) {
+ u, err := doubleToUint64Checked(v)
+ if err != nil {
+ return 0, false
+ }
+ if float64(u) != v {
+ return 0, false
+ }
+ return u, true
+}
+
+func doubleToInt64Lossless(v float64) (int64, bool) {
+ i, err := doubleToInt64Checked(v)
+ if err != nil {
+ return 0, false
+ }
+ if float64(i) != v {
+ return 0, false
+ }
+ return i, true
+}
+
+func int64ToUint64Lossless(v int64) (uint64, bool) {
+ u, err := int64ToUint64Checked(v)
+ return u, err == nil
+}
+
+func uint64ToInt64Lossless(v uint64) (int64, bool) {
+ i, err := uint64ToInt64Checked(v)
+ return i, err == nil
+}
diff --git a/vendor/github.com/google/cel-go/common/types/pb/BUILD.bazel b/vendor/github.com/google/cel-go/common/types/pb/BUILD.bazel
new file mode 100644
index 000000000000..954563349e78
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/pb/BUILD.bazel
@@ -0,0 +1,34 @@
+load("@io_bazel_rules_go//go:def.bzl", "go_library")
+
+package(
+ default_visibility = ["//visibility:public"],
+ licenses = ["notice"], # Apache 2.0
+)
+
+go_library(
+ name = "go_default_library",
+ srcs = [
+ "checked.go",
+ "enum.go",
+ "equal.go",
+ "file.go",
+ "pb.go",
+ "type.go",
+ ],
+ importmap = "kubevirt.io/kubevirt/vendor/github.com/google/cel-go/common/types/pb",
+ importpath = "github.com/google/cel-go/common/types/pb",
+ deps = [
+ "//vendor/google.golang.org/genproto/googleapis/api/expr/v1alpha1:go_default_library",
+ "//vendor/google.golang.org/protobuf/encoding/protowire:go_default_library",
+ "//vendor/google.golang.org/protobuf/proto:go_default_library",
+ "//vendor/google.golang.org/protobuf/reflect/protoreflect:go_default_library",
+ "//vendor/google.golang.org/protobuf/reflect/protoregistry:go_default_library",
+ "//vendor/google.golang.org/protobuf/types/dynamicpb:go_default_library",
+ "//vendor/google.golang.org/protobuf/types/known/anypb:go_default_library",
+ "//vendor/google.golang.org/protobuf/types/known/durationpb:go_default_library",
+ "//vendor/google.golang.org/protobuf/types/known/emptypb:go_default_library",
+ "//vendor/google.golang.org/protobuf/types/known/structpb:go_default_library",
+ "//vendor/google.golang.org/protobuf/types/known/timestamppb:go_default_library",
+ "//vendor/google.golang.org/protobuf/types/known/wrapperspb:go_default_library",
+ ],
+)
diff --git a/vendor/github.com/google/cel-go/common/types/pb/checked.go b/vendor/github.com/google/cel-go/common/types/pb/checked.go
new file mode 100644
index 000000000000..312a6a072fe0
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/pb/checked.go
@@ -0,0 +1,93 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package pb
+
+import (
+ "google.golang.org/protobuf/reflect/protoreflect"
+
+ exprpb "google.golang.org/genproto/googleapis/api/expr/v1alpha1"
+ emptypb "google.golang.org/protobuf/types/known/emptypb"
+ structpb "google.golang.org/protobuf/types/known/structpb"
+)
+
+var (
+ // CheckedPrimitives map from proto field descriptor type to expr.Type.
+ CheckedPrimitives = map[protoreflect.Kind]*exprpb.Type{
+ protoreflect.BoolKind: checkedBool,
+ protoreflect.BytesKind: checkedBytes,
+ protoreflect.DoubleKind: checkedDouble,
+ protoreflect.FloatKind: checkedDouble,
+ protoreflect.Int32Kind: checkedInt,
+ protoreflect.Int64Kind: checkedInt,
+ protoreflect.Sint32Kind: checkedInt,
+ protoreflect.Sint64Kind: checkedInt,
+ protoreflect.Uint32Kind: checkedUint,
+ protoreflect.Uint64Kind: checkedUint,
+ protoreflect.Fixed32Kind: checkedUint,
+ protoreflect.Fixed64Kind: checkedUint,
+ protoreflect.Sfixed32Kind: checkedInt,
+ protoreflect.Sfixed64Kind: checkedInt,
+ protoreflect.StringKind: checkedString}
+
+ // CheckedWellKnowns map from qualified proto type name to expr.Type for
+ // well-known proto types.
+ CheckedWellKnowns = map[string]*exprpb.Type{
+ // Wrapper types.
+ "google.protobuf.BoolValue": checkedWrap(checkedBool),
+ "google.protobuf.BytesValue": checkedWrap(checkedBytes),
+ "google.protobuf.DoubleValue": checkedWrap(checkedDouble),
+ "google.protobuf.FloatValue": checkedWrap(checkedDouble),
+ "google.protobuf.Int64Value": checkedWrap(checkedInt),
+ "google.protobuf.Int32Value": checkedWrap(checkedInt),
+ "google.protobuf.UInt64Value": checkedWrap(checkedUint),
+ "google.protobuf.UInt32Value": checkedWrap(checkedUint),
+ "google.protobuf.StringValue": checkedWrap(checkedString),
+ // Well-known types.
+ "google.protobuf.Any": checkedAny,
+ "google.protobuf.Duration": checkedDuration,
+ "google.protobuf.Timestamp": checkedTimestamp,
+ // Json types.
+ "google.protobuf.ListValue": checkedListDyn,
+ "google.protobuf.NullValue": checkedNull,
+ "google.protobuf.Struct": checkedMapStringDyn,
+ "google.protobuf.Value": checkedDyn,
+ }
+
+ // common types
+ checkedDyn = &exprpb.Type{TypeKind: &exprpb.Type_Dyn{Dyn: &emptypb.Empty{}}}
+ // Wrapper and primitive types.
+ checkedBool = checkedPrimitive(exprpb.Type_BOOL)
+ checkedBytes = checkedPrimitive(exprpb.Type_BYTES)
+ checkedDouble = checkedPrimitive(exprpb.Type_DOUBLE)
+ checkedInt = checkedPrimitive(exprpb.Type_INT64)
+ checkedString = checkedPrimitive(exprpb.Type_STRING)
+ checkedUint = checkedPrimitive(exprpb.Type_UINT64)
+ // Well-known type equivalents.
+ checkedAny = checkedWellKnown(exprpb.Type_ANY)
+ checkedDuration = checkedWellKnown(exprpb.Type_DURATION)
+ checkedTimestamp = checkedWellKnown(exprpb.Type_TIMESTAMP)
+ // Json-based type equivalents.
+ checkedNull = &exprpb.Type{
+ TypeKind: &exprpb.Type_Null{
+ Null: structpb.NullValue_NULL_VALUE}}
+ checkedListDyn = &exprpb.Type{
+ TypeKind: &exprpb.Type_ListType_{
+ ListType: &exprpb.Type_ListType{ElemType: checkedDyn}}}
+ checkedMapStringDyn = &exprpb.Type{
+ TypeKind: &exprpb.Type_MapType_{
+ MapType: &exprpb.Type_MapType{
+ KeyType: checkedString,
+ ValueType: checkedDyn}}}
+)
diff --git a/vendor/github.com/google/cel-go/common/types/pb/enum.go b/vendor/github.com/google/cel-go/common/types/pb/enum.go
new file mode 100644
index 000000000000..09a15463086e
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/pb/enum.go
@@ -0,0 +1,44 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package pb
+
+import (
+ "google.golang.org/protobuf/reflect/protoreflect"
+)
+
+// newEnumValueDescription produces an enum value description with the fully qualified enum value
+// name and the enum value descriptor.
+func newEnumValueDescription(name string, desc protoreflect.EnumValueDescriptor) *EnumValueDescription {
+ return &EnumValueDescription{
+ enumValueName: name,
+ desc: desc,
+ }
+}
+
+// EnumValueDescription maps a fully-qualified enum value name to its numeric value.
+type EnumValueDescription struct {
+ enumValueName string
+ desc protoreflect.EnumValueDescriptor
+}
+
+// Name returns the fully-qualified identifier name for the enum value.
+func (ed *EnumValueDescription) Name() string {
+ return ed.enumValueName
+}
+
+// Value returns the (numeric) value of the enum.
+func (ed *EnumValueDescription) Value() int32 {
+ return int32(ed.desc.Number())
+}
diff --git a/vendor/github.com/google/cel-go/common/types/pb/equal.go b/vendor/github.com/google/cel-go/common/types/pb/equal.go
new file mode 100644
index 000000000000..76893d85eab7
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/pb/equal.go
@@ -0,0 +1,206 @@
+// Copyright 2022 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package pb
+
+import (
+ "bytes"
+ "reflect"
+
+ "google.golang.org/protobuf/encoding/protowire"
+ "google.golang.org/protobuf/proto"
+ "google.golang.org/protobuf/reflect/protoreflect"
+
+ anypb "google.golang.org/protobuf/types/known/anypb"
+)
+
+// Equal returns whether two proto.Message instances are equal using the following criteria:
+//
+// - Messages must share the same instance of the type descriptor
+// - Known set fields are compared using semantics equality
+// - Bytes are compared using bytes.Equal
+// - Scalar values are compared with operator ==
+// - List and map types are equal if they have the same length and all elements are equal
+// - Messages are equal if they share the same descriptor and all set fields are equal
+// - Unknown fields are compared using byte equality
+// - NaN values are not equal to each other
+// - google.protobuf.Any values are unpacked before comparison
+// - If the type descriptor for a protobuf.Any cannot be found, byte equality is used rather than
+// semantic equality.
+//
+// This method of proto equality mirrors the behavior of the C++ protobuf MessageDifferencer
+// whereas the golang proto.Equal implementation mirrors the Java protobuf equals() methods
+// behaviors which needed to treat NaN values as equal due to Java semantics.
+func Equal(x, y proto.Message) bool {
+ if x == nil || y == nil {
+ return x == nil && y == nil
+ }
+ xRef := x.ProtoReflect()
+ yRef := y.ProtoReflect()
+ return equalMessage(xRef, yRef)
+}
+
+func equalMessage(mx, my protoreflect.Message) bool {
+ // Note, the original proto.Equal upon which this implementation is based does not specifically handle the
+ // case when both messages are invalid. It is assumed that the descriptors will be equal and that byte-wise
+ // comparison will be used, though the semantics of validity are neither clear, nor promised within the
+ // proto.Equal implementation.
+ if mx.IsValid() != my.IsValid() || mx.Descriptor() != my.Descriptor() {
+ return false
+ }
+
+ // This is an innovation on the default proto.Equal where protobuf.Any values are unpacked before comparison
+ // as otherwise the Any values are compared by bytes rather than structurally.
+ if isAny(mx) && isAny(my) {
+ ax := mx.Interface().(*anypb.Any)
+ ay := my.Interface().(*anypb.Any)
+ // If the values are not the same type url, return false.
+ if ax.GetTypeUrl() != ay.GetTypeUrl() {
+ return false
+ }
+ // If the values are byte equal, then return true.
+ if bytes.Equal(ax.GetValue(), ay.GetValue()) {
+ return true
+ }
+ // Otherwise fall through to the semantic comparison of the any values.
+ x, err := ax.UnmarshalNew()
+ if err != nil {
+ return false
+ }
+ y, err := ay.UnmarshalNew()
+ if err != nil {
+ return false
+ }
+ // Recursively compare the unwrapped messages to ensure nested Any values are unwrapped accordingly.
+ return equalMessage(x.ProtoReflect(), y.ProtoReflect())
+ }
+
+ // Walk the set fields to determine field-wise equality
+ nx := 0
+ equal := true
+ mx.Range(func(fd protoreflect.FieldDescriptor, vx protoreflect.Value) bool {
+ nx++
+ equal = my.Has(fd) && equalField(fd, vx, my.Get(fd))
+ return equal
+ })
+ if !equal {
+ return false
+ }
+ // Establish the count of set fields on message y
+ ny := 0
+ my.Range(func(protoreflect.FieldDescriptor, protoreflect.Value) bool {
+ ny++
+ return true
+ })
+ // If the number of set fields is not equal return false.
+ if nx != ny {
+ return false
+ }
+
+ return equalUnknown(mx.GetUnknown(), my.GetUnknown())
+}
+
+func equalField(fd protoreflect.FieldDescriptor, x, y protoreflect.Value) bool {
+ switch {
+ case fd.IsMap():
+ return equalMap(fd, x.Map(), y.Map())
+ case fd.IsList():
+ return equalList(fd, x.List(), y.List())
+ default:
+ return equalValue(fd, x, y)
+ }
+}
+
+func equalMap(fd protoreflect.FieldDescriptor, x, y protoreflect.Map) bool {
+ if x.Len() != y.Len() {
+ return false
+ }
+ equal := true
+ x.Range(func(k protoreflect.MapKey, vx protoreflect.Value) bool {
+ vy := y.Get(k)
+ equal = y.Has(k) && equalValue(fd.MapValue(), vx, vy)
+ return equal
+ })
+ return equal
+}
+
+func equalList(fd protoreflect.FieldDescriptor, x, y protoreflect.List) bool {
+ if x.Len() != y.Len() {
+ return false
+ }
+ for i := x.Len() - 1; i >= 0; i-- {
+ if !equalValue(fd, x.Get(i), y.Get(i)) {
+ return false
+ }
+ }
+ return true
+}
+
+func equalValue(fd protoreflect.FieldDescriptor, x, y protoreflect.Value) bool {
+ switch fd.Kind() {
+ case protoreflect.BoolKind:
+ return x.Bool() == y.Bool()
+ case protoreflect.EnumKind:
+ return x.Enum() == y.Enum()
+ case protoreflect.Int32Kind, protoreflect.Sint32Kind,
+ protoreflect.Int64Kind, protoreflect.Sint64Kind,
+ protoreflect.Sfixed32Kind, protoreflect.Sfixed64Kind:
+ return x.Int() == y.Int()
+ case protoreflect.Uint32Kind, protoreflect.Uint64Kind,
+ protoreflect.Fixed32Kind, protoreflect.Fixed64Kind:
+ return x.Uint() == y.Uint()
+ case protoreflect.FloatKind, protoreflect.DoubleKind:
+ return x.Float() == y.Float()
+ case protoreflect.StringKind:
+ return x.String() == y.String()
+ case protoreflect.BytesKind:
+ return bytes.Equal(x.Bytes(), y.Bytes())
+ case protoreflect.MessageKind, protoreflect.GroupKind:
+ return equalMessage(x.Message(), y.Message())
+ default:
+ return x.Interface() == y.Interface()
+ }
+}
+
+func equalUnknown(x, y protoreflect.RawFields) bool {
+ lenX := len(x)
+ lenY := len(y)
+ if lenX != lenY {
+ return false
+ }
+ if lenX == 0 {
+ return true
+ }
+ if bytes.Equal([]byte(x), []byte(y)) {
+ return true
+ }
+
+ mx := make(map[protoreflect.FieldNumber]protoreflect.RawFields)
+ my := make(map[protoreflect.FieldNumber]protoreflect.RawFields)
+ for len(x) > 0 {
+ fnum, _, n := protowire.ConsumeField(x)
+ mx[fnum] = append(mx[fnum], x[:n]...)
+ x = x[n:]
+ }
+ for len(y) > 0 {
+ fnum, _, n := protowire.ConsumeField(y)
+ my[fnum] = append(my[fnum], y[:n]...)
+ y = y[n:]
+ }
+ return reflect.DeepEqual(mx, my)
+}
+
+func isAny(m protoreflect.Message) bool {
+ return string(m.Descriptor().FullName()) == "google.protobuf.Any"
+}
diff --git a/vendor/github.com/google/cel-go/common/types/pb/file.go b/vendor/github.com/google/cel-go/common/types/pb/file.go
new file mode 100644
index 000000000000..e323afb1df30
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/pb/file.go
@@ -0,0 +1,202 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package pb
+
+import (
+ "fmt"
+
+ "google.golang.org/protobuf/reflect/protoreflect"
+
+ dynamicpb "google.golang.org/protobuf/types/dynamicpb"
+)
+
+// newFileDescription returns a FileDescription instance with a complete listing of all the message
+// types and enum values, as well as a map of extensions declared within any scope in the file.
+func newFileDescription(fileDesc protoreflect.FileDescriptor, pbdb *Db) (*FileDescription, extensionMap) {
+ metadata := collectFileMetadata(fileDesc)
+ enums := make(map[string]*EnumValueDescription)
+ for name, enumVal := range metadata.enumValues {
+ enums[name] = newEnumValueDescription(name, enumVal)
+ }
+ types := make(map[string]*TypeDescription)
+ for name, msgType := range metadata.msgTypes {
+ types[name] = newTypeDescription(name, msgType, pbdb.extensions)
+ }
+ fileExtMap := make(extensionMap)
+ for typeName, extensions := range metadata.msgExtensionMap {
+ messageExtMap, found := fileExtMap[typeName]
+ if !found {
+ messageExtMap = make(map[string]*FieldDescription)
+ }
+ for _, ext := range extensions {
+ extDesc := dynamicpb.NewExtensionType(ext).TypeDescriptor()
+ messageExtMap[string(ext.FullName())] = newFieldDescription(extDesc)
+ }
+ fileExtMap[typeName] = messageExtMap
+ }
+ return &FileDescription{
+ name: fileDesc.Path(),
+ types: types,
+ enums: enums,
+ }, fileExtMap
+}
+
+// FileDescription holds a map of all types and enum values declared within a proto file.
+type FileDescription struct {
+ name string
+ types map[string]*TypeDescription
+ enums map[string]*EnumValueDescription
+}
+
+// Copy creates a copy of the FileDescription with updated Db references within its types.
+func (fd *FileDescription) Copy(pbdb *Db) *FileDescription {
+ typesCopy := make(map[string]*TypeDescription, len(fd.types))
+ for k, v := range fd.types {
+ typesCopy[k] = v.Copy(pbdb)
+ }
+ return &FileDescription{
+ name: fd.name,
+ types: typesCopy,
+ enums: fd.enums,
+ }
+}
+
+// GetName returns the fully qualified file path for the file.
+func (fd *FileDescription) GetName() string {
+ return fd.name
+}
+
+// GetEnumDescription returns an EnumDescription for a qualified enum value
+// name declared within the .proto file.
+func (fd *FileDescription) GetEnumDescription(enumName string) (*EnumValueDescription, bool) {
+ ed, found := fd.enums[sanitizeProtoName(enumName)]
+ return ed, found
+}
+
+// GetEnumNames returns the string names of all enum values in the file.
+func (fd *FileDescription) GetEnumNames() []string {
+ enumNames := make([]string, len(fd.enums))
+ i := 0
+ for _, e := range fd.enums {
+ enumNames[i] = e.Name()
+ i++
+ }
+ return enumNames
+}
+
+// GetTypeDescription returns a TypeDescription for a qualified protobuf message type name
+// declared within the .proto file.
+func (fd *FileDescription) GetTypeDescription(typeName string) (*TypeDescription, bool) {
+ td, found := fd.types[sanitizeProtoName(typeName)]
+ return td, found
+}
+
+// GetTypeNames returns the list of all type names contained within the file.
+func (fd *FileDescription) GetTypeNames() []string {
+ typeNames := make([]string, len(fd.types))
+ i := 0
+ for _, t := range fd.types {
+ typeNames[i] = t.Name()
+ i++
+ }
+ return typeNames
+}
+
+// sanitizeProtoName strips the leading '.' from the proto message name.
+func sanitizeProtoName(name string) string {
+ if name != "" && name[0] == '.' {
+ return name[1:]
+ }
+ return name
+}
+
+// fileMetadata is a flattened view of message types and enum values within a file descriptor.
+type fileMetadata struct {
+ // msgTypes maps from fully-qualified message name to descriptor.
+ msgTypes map[string]protoreflect.MessageDescriptor
+ // enumValues maps from fully-qualified enum value to enum value descriptor.
+ enumValues map[string]protoreflect.EnumValueDescriptor
+ // msgExtensionMap maps from the protobuf message name being extended to a set of extensions
+ // for the type.
+ msgExtensionMap map[string][]protoreflect.ExtensionDescriptor
+
+ // TODO: support enum type definitions for use in future type-check enhancements.
+}
+
+// collectFileMetadata traverses the proto file object graph to collect message types and enum
+// values and index them by their fully qualified names.
+func collectFileMetadata(fileDesc protoreflect.FileDescriptor) *fileMetadata {
+ msgTypes := make(map[string]protoreflect.MessageDescriptor)
+ enumValues := make(map[string]protoreflect.EnumValueDescriptor)
+ msgExtensionMap := make(map[string][]protoreflect.ExtensionDescriptor)
+ collectMsgTypes(fileDesc.Messages(), msgTypes, enumValues, msgExtensionMap)
+ collectEnumValues(fileDesc.Enums(), enumValues)
+ collectExtensions(fileDesc.Extensions(), msgExtensionMap)
+ return &fileMetadata{
+ msgTypes: msgTypes,
+ enumValues: enumValues,
+ msgExtensionMap: msgExtensionMap,
+ }
+}
+
+// collectMsgTypes recursively collects messages, nested messages, and nested enums into a map of
+// fully qualified protobuf names to descriptors.
+func collectMsgTypes(msgTypes protoreflect.MessageDescriptors,
+ msgTypeMap map[string]protoreflect.MessageDescriptor,
+ enumValueMap map[string]protoreflect.EnumValueDescriptor,
+ msgExtensionMap map[string][]protoreflect.ExtensionDescriptor) {
+ for i := 0; i < msgTypes.Len(); i++ {
+ msgType := msgTypes.Get(i)
+ msgTypeMap[string(msgType.FullName())] = msgType
+ nestedMsgTypes := msgType.Messages()
+ if nestedMsgTypes.Len() != 0 {
+ collectMsgTypes(nestedMsgTypes, msgTypeMap, enumValueMap, msgExtensionMap)
+ }
+ nestedEnumTypes := msgType.Enums()
+ if nestedEnumTypes.Len() != 0 {
+ collectEnumValues(nestedEnumTypes, enumValueMap)
+ }
+ nestedExtensions := msgType.Extensions()
+ if nestedExtensions.Len() != 0 {
+ collectExtensions(nestedExtensions, msgExtensionMap)
+ }
+ }
+}
+
+// collectEnumValues accumulates the enum values within an enum declaration.
+func collectEnumValues(enumTypes protoreflect.EnumDescriptors, enumValueMap map[string]protoreflect.EnumValueDescriptor) {
+ for i := 0; i < enumTypes.Len(); i++ {
+ enumType := enumTypes.Get(i)
+ enumTypeValues := enumType.Values()
+ for j := 0; j < enumTypeValues.Len(); j++ {
+ enumValue := enumTypeValues.Get(j)
+ enumValueName := fmt.Sprintf("%s.%s", string(enumType.FullName()), string(enumValue.Name()))
+ enumValueMap[enumValueName] = enumValue
+ }
+ }
+}
+
+func collectExtensions(extensions protoreflect.ExtensionDescriptors, msgExtensionMap map[string][]protoreflect.ExtensionDescriptor) {
+ for i := 0; i < extensions.Len(); i++ {
+ ext := extensions.Get(i)
+ extendsMsg := string(ext.ContainingMessage().FullName())
+ msgExts, found := msgExtensionMap[extendsMsg]
+ if !found {
+ msgExts = []protoreflect.ExtensionDescriptor{}
+ }
+ msgExts = append(msgExts, ext)
+ msgExtensionMap[extendsMsg] = msgExts
+ }
+}
diff --git a/vendor/github.com/google/cel-go/common/types/pb/pb.go b/vendor/github.com/google/cel-go/common/types/pb/pb.go
new file mode 100644
index 000000000000..eadebcb04e8b
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/pb/pb.go
@@ -0,0 +1,258 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+// Package pb reflects over protocol buffer descriptors to generate objects
+// that simplify type, enum, and field lookup.
+package pb
+
+import (
+ "fmt"
+
+ "google.golang.org/protobuf/proto"
+ "google.golang.org/protobuf/reflect/protoreflect"
+ "google.golang.org/protobuf/reflect/protoregistry"
+
+ anypb "google.golang.org/protobuf/types/known/anypb"
+ durpb "google.golang.org/protobuf/types/known/durationpb"
+ emptypb "google.golang.org/protobuf/types/known/emptypb"
+ structpb "google.golang.org/protobuf/types/known/structpb"
+ tspb "google.golang.org/protobuf/types/known/timestamppb"
+ wrapperspb "google.golang.org/protobuf/types/known/wrapperspb"
+)
+
+// Db maps from file / message / enum name to file description.
+//
+// Each Db is isolated from each other, and while information about protobuf descriptors may be
+// fetched from the global protobuf registry, no descriptors are added to this registry, else
+// the isolation guarantees of the Db object would be violated.
+type Db struct {
+ revFileDescriptorMap map[string]*FileDescription
+ // files contains the deduped set of FileDescriptions whose types are contained in the pb.Db.
+ files []*FileDescription
+ // extensions contains the mapping between a given type name, extension name and its FieldDescription
+ extensions map[string]map[string]*FieldDescription
+}
+
+// extensionsMap is a type alias to a map[typeName]map[extensionName]*FieldDescription
+type extensionMap = map[string]map[string]*FieldDescription
+
+var (
+ // DefaultDb used at evaluation time or unless overridden at check time.
+ DefaultDb = &Db{
+ revFileDescriptorMap: make(map[string]*FileDescription),
+ files: []*FileDescription{},
+ extensions: make(extensionMap),
+ }
+)
+
+// Merge will copy the source proto message into the destination, or error if the merge cannot be completed.
+//
+// Unlike the proto.Merge, this method will fallback to proto.Marshal/Unmarshal of the two proto messages do not
+// share the same instance of their type descriptor.
+func Merge(dstPB, srcPB proto.Message) error {
+ src, dst := srcPB.ProtoReflect(), dstPB.ProtoReflect()
+ if src.Descriptor() == dst.Descriptor() {
+ proto.Merge(dstPB, srcPB)
+ return nil
+ }
+ if src.Descriptor().FullName() != dst.Descriptor().FullName() {
+ return fmt.Errorf("pb.Merge() arguments must be the same type. got: %v, %v",
+ dst.Descriptor().FullName(), src.Descriptor().FullName())
+ }
+ bytes, err := proto.Marshal(srcPB)
+ if err != nil {
+ return fmt.Errorf("pb.Merge(dstPB, srcPB) failed to marshal source proto: %v", err)
+ }
+ err = proto.Unmarshal(bytes, dstPB)
+ if err != nil {
+ return fmt.Errorf("pb.Merge(dstPB, srcPB) failed to unmarshal to dest proto: %v", err)
+ }
+ return nil
+}
+
+// NewDb creates a new `pb.Db` with an empty type name to file description map.
+func NewDb() *Db {
+ pbdb := &Db{
+ revFileDescriptorMap: make(map[string]*FileDescription),
+ files: []*FileDescription{},
+ extensions: make(extensionMap),
+ }
+ // The FileDescription objects in the default db contain lazily initialized TypeDescription
+ // values which may point to the state contained in the DefaultDb irrespective of this shallow
+ // copy; however, the type graph for a field is idempotently computed, and is guaranteed to
+ // only be initialized once thanks to atomic values within the TypeDescription objects, so it
+ // is safe to share these values across instances.
+ for k, v := range DefaultDb.revFileDescriptorMap {
+ pbdb.revFileDescriptorMap[k] = v
+ }
+ pbdb.files = append(pbdb.files, DefaultDb.files...)
+ return pbdb
+}
+
+// Copy creates a copy of the current database with its own internal descriptor mapping.
+func (pbdb *Db) Copy() *Db {
+ copy := NewDb()
+ for _, fd := range pbdb.files {
+ hasFile := false
+ for _, fd2 := range copy.files {
+ if fd2 == fd {
+ hasFile = true
+ }
+ }
+ if !hasFile {
+ fd = fd.Copy(copy)
+ copy.files = append(copy.files, fd)
+ }
+ for _, enumValName := range fd.GetEnumNames() {
+ copy.revFileDescriptorMap[enumValName] = fd
+ }
+ for _, msgTypeName := range fd.GetTypeNames() {
+ copy.revFileDescriptorMap[msgTypeName] = fd
+ }
+ copy.revFileDescriptorMap[fd.GetName()] = fd
+ }
+ for typeName, extFieldMap := range pbdb.extensions {
+ copyExtFieldMap, found := copy.extensions[typeName]
+ if !found {
+ copyExtFieldMap = make(map[string]*FieldDescription, len(extFieldMap))
+ }
+ for extFieldName, fd := range extFieldMap {
+ copyExtFieldMap[extFieldName] = fd
+ }
+ copy.extensions[typeName] = copyExtFieldMap
+ }
+ return copy
+}
+
+// FileDescriptions returns the set of file descriptions associated with this db.
+func (pbdb *Db) FileDescriptions() []*FileDescription {
+ return pbdb.files
+}
+
+// RegisterDescriptor produces a `FileDescription` from a `FileDescriptor` and registers the
+// message and enum types into the `pb.Db`.
+func (pbdb *Db) RegisterDescriptor(fileDesc protoreflect.FileDescriptor) (*FileDescription, error) {
+ fd, found := pbdb.revFileDescriptorMap[fileDesc.Path()]
+ if found {
+ return fd, nil
+ }
+ // Make sure to search the global registry to see if a protoreflect.FileDescriptor for
+ // the file specified has been linked into the binary. If so, use the copy of the descriptor
+ // from the global cache.
+ //
+ // Note: Proto reflection relies on descriptor values being object equal rather than object
+ // equivalence. This choice means that a FieldDescriptor generated from a FileDescriptorProto
+ // will be incompatible with the FieldDescriptor in the global registry and any message created
+ // from that global registry.
+ globalFD, err := protoregistry.GlobalFiles.FindFileByPath(fileDesc.Path())
+ if err == nil {
+ fileDesc = globalFD
+ }
+ var fileExtMap extensionMap
+ fd, fileExtMap = newFileDescription(fileDesc, pbdb)
+ for _, enumValName := range fd.GetEnumNames() {
+ pbdb.revFileDescriptorMap[enumValName] = fd
+ }
+ for _, msgTypeName := range fd.GetTypeNames() {
+ pbdb.revFileDescriptorMap[msgTypeName] = fd
+ }
+ pbdb.revFileDescriptorMap[fd.GetName()] = fd
+
+ // Return the specific file descriptor registered.
+ pbdb.files = append(pbdb.files, fd)
+
+ // Index the protobuf message extensions from the file into the pbdb
+ for typeName, extMap := range fileExtMap {
+ typeExtMap, found := pbdb.extensions[typeName]
+ if !found {
+ pbdb.extensions[typeName] = extMap
+ continue
+ }
+ for extName, field := range extMap {
+ typeExtMap[extName] = field
+ }
+ }
+ return fd, nil
+}
+
+// RegisterMessage produces a `FileDescription` from a `message` and registers the message and all
+// other definitions within the message file into the `pb.Db`.
+func (pbdb *Db) RegisterMessage(message proto.Message) (*FileDescription, error) {
+ msgDesc := message.ProtoReflect().Descriptor()
+ msgName := msgDesc.FullName()
+ typeName := sanitizeProtoName(string(msgName))
+ if fd, found := pbdb.revFileDescriptorMap[typeName]; found {
+ return fd, nil
+ }
+ return pbdb.RegisterDescriptor(msgDesc.ParentFile())
+}
+
+// DescribeEnum takes a qualified enum name and returns an `EnumDescription` if it exists in the
+// `pb.Db`.
+func (pbdb *Db) DescribeEnum(enumName string) (*EnumValueDescription, bool) {
+ enumName = sanitizeProtoName(enumName)
+ if fd, found := pbdb.revFileDescriptorMap[enumName]; found {
+ return fd.GetEnumDescription(enumName)
+ }
+ return nil, false
+}
+
+// DescribeType returns a `TypeDescription` for the `typeName` if it exists in the `pb.Db`.
+func (pbdb *Db) DescribeType(typeName string) (*TypeDescription, bool) {
+ typeName = sanitizeProtoName(typeName)
+ if fd, found := pbdb.revFileDescriptorMap[typeName]; found {
+ return fd.GetTypeDescription(typeName)
+ }
+ return nil, false
+}
+
+// CollectFileDescriptorSet builds a file descriptor set associated with the file where the input
+// message is declared.
+func CollectFileDescriptorSet(message proto.Message) map[string]protoreflect.FileDescriptor {
+ fdMap := map[string]protoreflect.FileDescriptor{}
+ parentFile := message.ProtoReflect().Descriptor().ParentFile()
+ fdMap[parentFile.Path()] = parentFile
+ // Initialize list of dependencies
+ deps := make([]protoreflect.FileImport, parentFile.Imports().Len())
+ for i := 0; i < parentFile.Imports().Len(); i++ {
+ deps[i] = parentFile.Imports().Get(i)
+ }
+ // Expand list for new dependencies
+ for i := 0; i < len(deps); i++ {
+ dep := deps[i]
+ if _, found := fdMap[dep.Path()]; found {
+ continue
+ }
+ fdMap[dep.Path()] = dep.FileDescriptor
+ for j := 0; j < dep.FileDescriptor.Imports().Len(); j++ {
+ deps = append(deps, dep.FileDescriptor.Imports().Get(j))
+ }
+ }
+ return fdMap
+}
+
+func init() {
+ // Describe well-known types to ensure they can always be resolved by the check and interpret
+ // execution phases.
+ //
+ // The following subset of message types is enough to ensure that all well-known types can
+ // resolved in the runtime, since describing the value results in describing the whole file
+ // where the message is declared.
+ DefaultDb.RegisterMessage(&anypb.Any{})
+ DefaultDb.RegisterMessage(&durpb.Duration{})
+ DefaultDb.RegisterMessage(&emptypb.Empty{})
+ DefaultDb.RegisterMessage(&tspb.Timestamp{})
+ DefaultDb.RegisterMessage(&structpb.Value{})
+ DefaultDb.RegisterMessage(&wrapperspb.BoolValue{})
+}
diff --git a/vendor/github.com/google/cel-go/common/types/pb/type.go b/vendor/github.com/google/cel-go/common/types/pb/type.go
new file mode 100644
index 000000000000..bdd474c95af9
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/pb/type.go
@@ -0,0 +1,614 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package pb
+
+import (
+ "fmt"
+ "reflect"
+
+ "google.golang.org/protobuf/proto"
+ "google.golang.org/protobuf/reflect/protoreflect"
+
+ exprpb "google.golang.org/genproto/googleapis/api/expr/v1alpha1"
+ dynamicpb "google.golang.org/protobuf/types/dynamicpb"
+ anypb "google.golang.org/protobuf/types/known/anypb"
+ dpb "google.golang.org/protobuf/types/known/durationpb"
+ structpb "google.golang.org/protobuf/types/known/structpb"
+ tpb "google.golang.org/protobuf/types/known/timestamppb"
+ wrapperspb "google.golang.org/protobuf/types/known/wrapperspb"
+)
+
+// description is a private interface used to make it convenient to perform type unwrapping at
+// the TypeDescription or FieldDescription level.
+type description interface {
+ // Zero returns an empty immutable protobuf message when the description is a protobuf message
+ // type.
+ Zero() proto.Message
+}
+
+// newTypeDescription produces a TypeDescription value for the fully-qualified proto type name
+// with a given descriptor.
+func newTypeDescription(typeName string, desc protoreflect.MessageDescriptor, extensions extensionMap) *TypeDescription {
+ msgType := dynamicpb.NewMessageType(desc)
+ msgZero := dynamicpb.NewMessage(desc)
+ fieldMap := map[string]*FieldDescription{}
+ fields := desc.Fields()
+ for i := 0; i < fields.Len(); i++ {
+ f := fields.Get(i)
+ fieldMap[string(f.Name())] = newFieldDescription(f)
+ }
+ return &TypeDescription{
+ typeName: typeName,
+ desc: desc,
+ msgType: msgType,
+ fieldMap: fieldMap,
+ extensions: extensions,
+ reflectType: reflectTypeOf(msgZero),
+ zeroMsg: zeroValueOf(msgZero),
+ }
+}
+
+// TypeDescription is a collection of type metadata relevant to expression
+// checking and evaluation.
+type TypeDescription struct {
+ typeName string
+ desc protoreflect.MessageDescriptor
+ msgType protoreflect.MessageType
+ fieldMap map[string]*FieldDescription
+ extensions extensionMap
+ reflectType reflect.Type
+ zeroMsg proto.Message
+}
+
+// Copy copies the type description with updated references to the Db.
+func (td *TypeDescription) Copy(pbdb *Db) *TypeDescription {
+ return &TypeDescription{
+ typeName: td.typeName,
+ desc: td.desc,
+ msgType: td.msgType,
+ fieldMap: td.fieldMap,
+ extensions: pbdb.extensions,
+ reflectType: td.reflectType,
+ zeroMsg: td.zeroMsg,
+ }
+}
+
+// FieldMap returns a string field name to FieldDescription map.
+func (td *TypeDescription) FieldMap() map[string]*FieldDescription {
+ return td.fieldMap
+}
+
+// FieldByName returns (FieldDescription, true) if the field name is declared within the type.
+func (td *TypeDescription) FieldByName(name string) (*FieldDescription, bool) {
+ fd, found := td.fieldMap[name]
+ if found {
+ return fd, true
+ }
+ extFieldMap, found := td.extensions[td.typeName]
+ if !found {
+ return nil, false
+ }
+ fd, found = extFieldMap[name]
+ return fd, found
+}
+
+// MaybeUnwrap accepts a proto message as input and unwraps it to a primitive CEL type if possible.
+//
+// This method returns the unwrapped value and 'true', else the original value and 'false'.
+func (td *TypeDescription) MaybeUnwrap(msg proto.Message) (any, bool, error) {
+ return unwrap(td, msg)
+}
+
+// Name returns the fully-qualified name of the type.
+func (td *TypeDescription) Name() string {
+ return string(td.desc.FullName())
+}
+
+// New returns a mutable proto message
+func (td *TypeDescription) New() protoreflect.Message {
+ return td.msgType.New()
+}
+
+// ReflectType returns the Golang reflect.Type for this type.
+func (td *TypeDescription) ReflectType() reflect.Type {
+ return td.reflectType
+}
+
+// Zero returns the zero proto.Message value for this type.
+func (td *TypeDescription) Zero() proto.Message {
+ return td.zeroMsg
+}
+
+// newFieldDescription creates a new field description from a protoreflect.FieldDescriptor.
+func newFieldDescription(fieldDesc protoreflect.FieldDescriptor) *FieldDescription {
+ var reflectType reflect.Type
+ var zeroMsg proto.Message
+ switch fieldDesc.Kind() {
+ case protoreflect.EnumKind:
+ reflectType = reflectTypeOf(protoreflect.EnumNumber(0))
+ case protoreflect.GroupKind, protoreflect.MessageKind:
+ zeroMsg = dynamicpb.NewMessage(fieldDesc.Message())
+ reflectType = reflectTypeOf(zeroMsg)
+ default:
+ reflectType = reflectTypeOf(fieldDesc.Default().Interface())
+ if fieldDesc.IsList() {
+ var elemValue protoreflect.Value
+ if fieldDesc.IsExtension() {
+ et := dynamicpb.NewExtensionType(fieldDesc)
+ elemValue = et.New().List().NewElement()
+ } else {
+ parentMsgType := fieldDesc.ContainingMessage()
+ parentMsg := dynamicpb.NewMessage(parentMsgType)
+ listField := parentMsg.NewField(fieldDesc).List()
+ elemValue = listField.NewElement()
+ }
+ elem := elemValue.Interface()
+ switch elemType := elem.(type) {
+ case protoreflect.Message:
+ elem = elemType.Interface()
+ }
+ reflectType = reflectTypeOf(elem)
+ }
+ }
+ // Ensure the list type is appropriately reflected as a Go-native list.
+ if fieldDesc.IsList() {
+ reflectType = reflect.SliceOf(reflectType)
+ }
+ var keyType, valType *FieldDescription
+ if fieldDesc.IsMap() {
+ keyType = newFieldDescription(fieldDesc.MapKey())
+ valType = newFieldDescription(fieldDesc.MapValue())
+ }
+ return &FieldDescription{
+ desc: fieldDesc,
+ KeyType: keyType,
+ ValueType: valType,
+ reflectType: reflectType,
+ zeroMsg: zeroValueOf(zeroMsg),
+ }
+}
+
+// FieldDescription holds metadata related to fields declared within a type.
+type FieldDescription struct {
+ // KeyType holds the key FieldDescription for map fields.
+ KeyType *FieldDescription
+ // ValueType holds the value FieldDescription for map fields.
+ ValueType *FieldDescription
+
+ desc protoreflect.FieldDescriptor
+ reflectType reflect.Type
+ zeroMsg proto.Message
+}
+
+// CheckedType returns the type-definition used at type-check time.
+func (fd *FieldDescription) CheckedType() *exprpb.Type {
+ if fd.desc.IsMap() {
+ return &exprpb.Type{
+ TypeKind: &exprpb.Type_MapType_{
+ MapType: &exprpb.Type_MapType{
+ KeyType: fd.KeyType.typeDefToType(),
+ ValueType: fd.ValueType.typeDefToType(),
+ },
+ },
+ }
+ }
+ if fd.desc.IsList() {
+ return &exprpb.Type{
+ TypeKind: &exprpb.Type_ListType_{
+ ListType: &exprpb.Type_ListType{
+ ElemType: fd.typeDefToType()}}}
+ }
+ return fd.typeDefToType()
+}
+
+// Descriptor returns the protoreflect.FieldDescriptor for this type.
+func (fd *FieldDescription) Descriptor() protoreflect.FieldDescriptor {
+ return fd.desc
+}
+
+// IsSet returns whether the field is set on the target value, per the proto presence conventions
+// of proto2 or proto3 accordingly.
+//
+// This function implements the FieldType.IsSet function contract which can be used to operate on
+// more than just protobuf field accesses; however, the target here must be a protobuf.Message.
+func (fd *FieldDescription) IsSet(target any) bool {
+ switch v := target.(type) {
+ case proto.Message:
+ pbRef := v.ProtoReflect()
+ pbDesc := pbRef.Descriptor()
+ if pbDesc == fd.desc.ContainingMessage() {
+ // When the target protobuf shares the same message descriptor instance as the field
+ // descriptor, use the cached field descriptor value.
+ return pbRef.Has(fd.desc)
+ }
+ // Otherwise, fallback to a dynamic lookup of the field descriptor from the target
+ // instance as an attempt to use the cached field descriptor will result in a panic.
+ return pbRef.Has(pbDesc.Fields().ByName(protoreflect.Name(fd.Name())))
+ default:
+ return false
+ }
+}
+
+// GetFrom returns the accessor method associated with the field on the proto generated struct.
+//
+// If the field is not set, the proto default value is returned instead.
+//
+// This function implements the FieldType.GetFrom function contract which can be used to operate
+// on more than just protobuf field accesses; however, the target here must be a protobuf.Message.
+func (fd *FieldDescription) GetFrom(target any) (any, error) {
+ v, ok := target.(proto.Message)
+ if !ok {
+ return nil, fmt.Errorf("unsupported field selection target: (%T)%v", target, target)
+ }
+ pbRef := v.ProtoReflect()
+ pbDesc := pbRef.Descriptor()
+ var fieldVal any
+ if pbDesc == fd.desc.ContainingMessage() {
+ // When the target protobuf shares the same message descriptor instance as the field
+ // descriptor, use the cached field descriptor value.
+ fieldVal = pbRef.Get(fd.desc).Interface()
+ } else {
+ // Otherwise, fallback to a dynamic lookup of the field descriptor from the target
+ // instance as an attempt to use the cached field descriptor will result in a panic.
+ fieldVal = pbRef.Get(pbDesc.Fields().ByName(protoreflect.Name(fd.Name()))).Interface()
+ }
+ switch fv := fieldVal.(type) {
+ // Fast-path return for primitive types.
+ case bool, []byte, float32, float64, int32, int64, string, uint32, uint64, protoreflect.List:
+ return fv, nil
+ case protoreflect.EnumNumber:
+ return int64(fv), nil
+ case protoreflect.Map:
+ // Return a wrapper around the protobuf-reflected Map types which carries additional
+ // information about the key and value definitions of the map.
+ return &Map{Map: fv, KeyType: fd.KeyType, ValueType: fd.ValueType}, nil
+ case protoreflect.Message:
+ // Make sure to unwrap well-known protobuf types before returning.
+ unwrapped, _, err := fd.MaybeUnwrapDynamic(fv)
+ return unwrapped, err
+ default:
+ return fv, nil
+ }
+}
+
+// IsEnum returns true if the field type refers to an enum value.
+func (fd *FieldDescription) IsEnum() bool {
+ return fd.ProtoKind() == protoreflect.EnumKind
+}
+
+// IsMap returns true if the field is of map type.
+func (fd *FieldDescription) IsMap() bool {
+ return fd.desc.IsMap()
+}
+
+// IsMessage returns true if the field is of message type.
+func (fd *FieldDescription) IsMessage() bool {
+ kind := fd.ProtoKind()
+ return kind == protoreflect.MessageKind || kind == protoreflect.GroupKind
+}
+
+// IsOneof returns true if the field is declared within a oneof block.
+func (fd *FieldDescription) IsOneof() bool {
+ return fd.desc.ContainingOneof() != nil
+}
+
+// IsList returns true if the field is a repeated value.
+//
+// This method will also return true for map values, so check whether the
+// field is also a map.
+func (fd *FieldDescription) IsList() bool {
+ return fd.desc.IsList()
+}
+
+// MaybeUnwrapDynamic takes the reflected protoreflect.Message and determines whether the
+// value can be unwrapped to a more primitive CEL type.
+//
+// This function returns the unwrapped value and 'true' on success, or the original value
+// and 'false' otherwise.
+func (fd *FieldDescription) MaybeUnwrapDynamic(msg protoreflect.Message) (any, bool, error) {
+ return unwrapDynamic(fd, msg)
+}
+
+// Name returns the CamelCase name of the field within the proto-based struct.
+func (fd *FieldDescription) Name() string {
+ return string(fd.desc.Name())
+}
+
+// ProtoKind returns the protobuf reflected kind of the field.
+func (fd *FieldDescription) ProtoKind() protoreflect.Kind {
+ return fd.desc.Kind()
+}
+
+// ReflectType returns the Golang reflect.Type for this field.
+func (fd *FieldDescription) ReflectType() reflect.Type {
+ return fd.reflectType
+}
+
+// String returns the fully qualified name of the field within its type as well as whether the
+// field occurs within a oneof.
+func (fd *FieldDescription) String() string {
+ return fmt.Sprintf("%v.%s `oneof=%t`", fd.desc.ContainingMessage().FullName(), fd.Name(), fd.IsOneof())
+}
+
+// Zero returns the zero value for the protobuf message represented by this field.
+//
+// If the field is not a proto.Message type, the zero value is nil.
+func (fd *FieldDescription) Zero() proto.Message {
+ return fd.zeroMsg
+}
+
+func (fd *FieldDescription) typeDefToType() *exprpb.Type {
+ if fd.IsMessage() {
+ msgType := string(fd.desc.Message().FullName())
+ if wk, found := CheckedWellKnowns[msgType]; found {
+ return wk
+ }
+ return checkedMessageType(msgType)
+ }
+ if fd.IsEnum() {
+ return checkedInt
+ }
+ return CheckedPrimitives[fd.ProtoKind()]
+}
+
+// Map wraps the protoreflect.Map object with a key and value FieldDescription for use in
+// retrieving individual elements within CEL value data types.
+type Map struct {
+ protoreflect.Map
+ KeyType *FieldDescription
+ ValueType *FieldDescription
+}
+
+func checkedMessageType(name string) *exprpb.Type {
+ return &exprpb.Type{
+ TypeKind: &exprpb.Type_MessageType{MessageType: name}}
+}
+
+func checkedPrimitive(primitive exprpb.Type_PrimitiveType) *exprpb.Type {
+ return &exprpb.Type{
+ TypeKind: &exprpb.Type_Primitive{Primitive: primitive}}
+}
+
+func checkedWellKnown(wellKnown exprpb.Type_WellKnownType) *exprpb.Type {
+ return &exprpb.Type{
+ TypeKind: &exprpb.Type_WellKnown{WellKnown: wellKnown}}
+}
+
+func checkedWrap(t *exprpb.Type) *exprpb.Type {
+ return &exprpb.Type{
+ TypeKind: &exprpb.Type_Wrapper{Wrapper: t.GetPrimitive()}}
+}
+
+// unwrap unwraps the provided proto.Message value, potentially based on the description if the
+// input message is a *dynamicpb.Message which obscures the typing information from Go.
+//
+// Returns the unwrapped value and 'true' if unwrapped, otherwise the input value and 'false'.
+func unwrap(desc description, msg proto.Message) (any, bool, error) {
+ switch v := msg.(type) {
+ case *anypb.Any:
+ dynMsg, err := v.UnmarshalNew()
+ if err != nil {
+ return v, false, err
+ }
+ return unwrapDynamic(desc, dynMsg.ProtoReflect())
+ case *dynamicpb.Message:
+ return unwrapDynamic(desc, v)
+ case *dpb.Duration:
+ return v.AsDuration(), true, nil
+ case *tpb.Timestamp:
+ return v.AsTime(), true, nil
+ case *structpb.Value:
+ switch v.GetKind().(type) {
+ case *structpb.Value_BoolValue:
+ return v.GetBoolValue(), true, nil
+ case *structpb.Value_ListValue:
+ return v.GetListValue(), true, nil
+ case *structpb.Value_NullValue:
+ return structpb.NullValue_NULL_VALUE, true, nil
+ case *structpb.Value_NumberValue:
+ return v.GetNumberValue(), true, nil
+ case *structpb.Value_StringValue:
+ return v.GetStringValue(), true, nil
+ case *structpb.Value_StructValue:
+ return v.GetStructValue(), true, nil
+ default:
+ return structpb.NullValue_NULL_VALUE, true, nil
+ }
+ case *wrapperspb.BoolValue:
+ if v == nil {
+ return nil, true, nil
+ }
+ return v.GetValue(), true, nil
+ case *wrapperspb.BytesValue:
+ if v == nil {
+ return nil, true, nil
+ }
+ return v.GetValue(), true, nil
+ case *wrapperspb.DoubleValue:
+ if v == nil {
+ return nil, true, nil
+ }
+ return v.GetValue(), true, nil
+ case *wrapperspb.FloatValue:
+ if v == nil {
+ return nil, true, nil
+ }
+ return float64(v.GetValue()), true, nil
+ case *wrapperspb.Int32Value:
+ if v == nil {
+ return nil, true, nil
+ }
+ return int64(v.GetValue()), true, nil
+ case *wrapperspb.Int64Value:
+ if v == nil {
+ return nil, true, nil
+ }
+ return v.GetValue(), true, nil
+ case *wrapperspb.StringValue:
+ if v == nil {
+ return nil, true, nil
+ }
+ return v.GetValue(), true, nil
+ case *wrapperspb.UInt32Value:
+ if v == nil {
+ return nil, true, nil
+ }
+ return uint64(v.GetValue()), true, nil
+ case *wrapperspb.UInt64Value:
+ if v == nil {
+ return nil, true, nil
+ }
+ return v.GetValue(), true, nil
+ }
+ return msg, false, nil
+}
+
+// unwrapDynamic unwraps a reflected protobuf Message value.
+//
+// Returns the unwrapped value and 'true' if unwrapped, otherwise the input value and 'false'.
+func unwrapDynamic(desc description, refMsg protoreflect.Message) (any, bool, error) {
+ msg := refMsg.Interface()
+ if !refMsg.IsValid() {
+ msg = desc.Zero()
+ }
+ // In order to ensure that these wrapped types match the expectations of the CEL type system
+ // the dynamicpb.Message must be merged with an protobuf instance of the well-known type value.
+ typeName := string(refMsg.Descriptor().FullName())
+ switch typeName {
+ case "google.protobuf.Any":
+ // Note, Any values require further unwrapping; however, this unwrapping may or may not
+ // be to a well-known type. If the unwrapped value is a well-known type it will be further
+ // unwrapped before being returned to the caller. Otherwise, the dynamic protobuf object
+ // represented by the Any will be returned.
+ unwrappedAny := &anypb.Any{}
+ err := Merge(unwrappedAny, msg)
+ if err != nil {
+ return nil, false, fmt.Errorf("unwrap dynamic field failed: %v", err)
+ }
+ dynMsg, err := unwrappedAny.UnmarshalNew()
+ if err != nil {
+ // Allow the error to move further up the stack as it should result in an type
+ // conversion error if the caller does not recover it somehow.
+ return nil, false, fmt.Errorf("unmarshal dynamic any failed: %v", err)
+ }
+ // Attempt to unwrap the dynamic type, otherwise return the dynamic message.
+ unwrapped, nested, err := unwrapDynamic(desc, dynMsg.ProtoReflect())
+ if err == nil && nested {
+ return unwrapped, true, nil
+ }
+ return dynMsg, true, err
+ case "google.protobuf.BoolValue",
+ "google.protobuf.BytesValue",
+ "google.protobuf.DoubleValue",
+ "google.protobuf.FloatValue",
+ "google.protobuf.Int32Value",
+ "google.protobuf.Int64Value",
+ "google.protobuf.StringValue",
+ "google.protobuf.UInt32Value",
+ "google.protobuf.UInt64Value":
+ // The msg value is ignored when dealing with wrapper types as they have a null or value
+ // behavior, rather than the standard zero value behavior of other proto message types.
+ if !refMsg.IsValid() {
+ return structpb.NullValue_NULL_VALUE, true, nil
+ }
+ valueField := refMsg.Descriptor().Fields().ByName("value")
+ return refMsg.Get(valueField).Interface(), true, nil
+ case "google.protobuf.Duration":
+ unwrapped := &dpb.Duration{}
+ err := Merge(unwrapped, msg)
+ if err != nil {
+ return nil, false, err
+ }
+ return unwrapped.AsDuration(), true, nil
+ case "google.protobuf.ListValue":
+ unwrapped := &structpb.ListValue{}
+ err := Merge(unwrapped, msg)
+ if err != nil {
+ return nil, false, err
+ }
+ return unwrapped, true, nil
+ case "google.protobuf.NullValue":
+ return structpb.NullValue_NULL_VALUE, true, nil
+ case "google.protobuf.Struct":
+ unwrapped := &structpb.Struct{}
+ err := Merge(unwrapped, msg)
+ if err != nil {
+ return nil, false, err
+ }
+ return unwrapped, true, nil
+ case "google.protobuf.Timestamp":
+ unwrapped := &tpb.Timestamp{}
+ err := Merge(unwrapped, msg)
+ if err != nil {
+ return nil, false, err
+ }
+ return unwrapped.AsTime(), true, nil
+ case "google.protobuf.Value":
+ unwrapped := &structpb.Value{}
+ err := Merge(unwrapped, msg)
+ if err != nil {
+ return nil, false, err
+ }
+ return unwrap(desc, unwrapped)
+ }
+ return msg, false, nil
+}
+
+// reflectTypeOf intercepts the reflect.Type call to ensure that dynamicpb.Message types preserve
+// well-known protobuf reflected types expected by the CEL type system.
+func reflectTypeOf(val any) reflect.Type {
+ switch v := val.(type) {
+ case proto.Message:
+ return reflect.TypeOf(zeroValueOf(v))
+ default:
+ return reflect.TypeOf(v)
+ }
+}
+
+// zeroValueOf will return the strongest possible proto.Message representing the default protobuf
+// message value of the input msg type.
+func zeroValueOf(msg proto.Message) proto.Message {
+ if msg == nil {
+ return nil
+ }
+ typeName := string(msg.ProtoReflect().Descriptor().FullName())
+ zeroVal, found := zeroValueMap[typeName]
+ if found {
+ return zeroVal
+ }
+ return msg
+}
+
+var (
+ jsonValueTypeURL = "types.googleapis.com/google.protobuf.Value"
+
+ zeroValueMap = map[string]proto.Message{
+ "google.protobuf.Any": &anypb.Any{TypeUrl: jsonValueTypeURL},
+ "google.protobuf.Duration": &dpb.Duration{},
+ "google.protobuf.ListValue": &structpb.ListValue{},
+ "google.protobuf.Struct": &structpb.Struct{},
+ "google.protobuf.Timestamp": &tpb.Timestamp{},
+ "google.protobuf.Value": &structpb.Value{},
+ "google.protobuf.BoolValue": wrapperspb.Bool(false),
+ "google.protobuf.BytesValue": wrapperspb.Bytes([]byte{}),
+ "google.protobuf.DoubleValue": wrapperspb.Double(0.0),
+ "google.protobuf.FloatValue": wrapperspb.Float(0.0),
+ "google.protobuf.Int32Value": wrapperspb.Int32(0),
+ "google.protobuf.Int64Value": wrapperspb.Int64(0),
+ "google.protobuf.StringValue": wrapperspb.String(""),
+ "google.protobuf.UInt32Value": wrapperspb.UInt32(0),
+ "google.protobuf.UInt64Value": wrapperspb.UInt64(0),
+ }
+)
diff --git a/vendor/github.com/google/cel-go/common/types/provider.go b/vendor/github.com/google/cel-go/common/types/provider.go
new file mode 100644
index 000000000000..936a4e28b206
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/provider.go
@@ -0,0 +1,766 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package types
+
+import (
+ "fmt"
+ "reflect"
+ "time"
+
+ "google.golang.org/protobuf/proto"
+ "google.golang.org/protobuf/reflect/protoreflect"
+
+ "github.com/google/cel-go/common/types/pb"
+ "github.com/google/cel-go/common/types/ref"
+ "github.com/google/cel-go/common/types/traits"
+
+ exprpb "google.golang.org/genproto/googleapis/api/expr/v1alpha1"
+ anypb "google.golang.org/protobuf/types/known/anypb"
+ dpb "google.golang.org/protobuf/types/known/durationpb"
+ structpb "google.golang.org/protobuf/types/known/structpb"
+ tpb "google.golang.org/protobuf/types/known/timestamppb"
+)
+
+// Adapter converts native Go values of varying type and complexity to equivalent CEL values.
+type Adapter = ref.TypeAdapter
+
+// Provider specifies functions for creating new object instances and for resolving
+// enum values by name.
+type Provider interface {
+ // EnumValue returns the numeric value of the given enum value name.
+ EnumValue(enumName string) ref.Val
+
+ // FindIdent takes a qualified identifier name and returns a ref.Val if one exists.
+ FindIdent(identName string) (ref.Val, bool)
+
+ // FindStructType returns the Type give a qualified type name.
+ //
+ // For historical reasons, only struct types are expected to be returned through this
+ // method, and the type values are expected to be wrapped in a TypeType instance using
+ // TypeTypeWithParam().
+ //
+ // Returns false if not found.
+ FindStructType(structType string) (*Type, bool)
+
+ // FindStructFieldNames returns thet field names associated with the type, if the type
+ // is found.
+ FindStructFieldNames(structType string) ([]string, bool)
+
+ // FieldStructFieldType returns the field type for a checked type value. Returns
+ // false if the field could not be found.
+ FindStructFieldType(structType, fieldName string) (*FieldType, bool)
+
+ // NewValue creates a new type value from a qualified name and map of field
+ // name to value.
+ //
+ // Note, for each value, the Val.ConvertToNative function will be invoked
+ // to convert the Val to the field's native type. If an error occurs during
+ // conversion, the NewValue will be a types.Err.
+ NewValue(structType string, fields map[string]ref.Val) ref.Val
+}
+
+// FieldType represents a field's type value and whether that field supports presence detection.
+type FieldType struct {
+ // Type of the field as a CEL native type value.
+ Type *Type
+
+ // IsSet indicates whether the field is set on an input object.
+ IsSet ref.FieldTester
+
+ // GetFrom retrieves the field value on the input object, if set.
+ GetFrom ref.FieldGetter
+}
+
+// Registry provides type information for a set of registered types.
+type Registry struct {
+ revTypeMap map[string]*Type
+ pbdb *pb.Db
+}
+
+// NewRegistry accepts a list of proto message instances and returns a type
+// provider which can create new instances of the provided message or any
+// message that proto depends upon in its FileDescriptor.
+func NewRegistry(types ...proto.Message) (*Registry, error) {
+ p := &Registry{
+ revTypeMap: make(map[string]*Type),
+ pbdb: pb.NewDb(),
+ }
+ err := p.RegisterType(
+ BoolType,
+ BytesType,
+ DoubleType,
+ DurationType,
+ IntType,
+ ListType,
+ MapType,
+ NullType,
+ StringType,
+ TimestampType,
+ TypeType,
+ UintType)
+ if err != nil {
+ return nil, err
+ }
+ // This block ensures that the well-known protobuf types are registered by default.
+ for _, fd := range p.pbdb.FileDescriptions() {
+ err = p.registerAllTypes(fd)
+ if err != nil {
+ return nil, err
+ }
+ }
+ for _, msgType := range types {
+ err = p.RegisterMessage(msgType)
+ if err != nil {
+ return nil, err
+ }
+ }
+ return p, nil
+}
+
+// NewEmptyRegistry returns a registry which is completely unconfigured.
+func NewEmptyRegistry() *Registry {
+ return &Registry{
+ revTypeMap: make(map[string]*Type),
+ pbdb: pb.NewDb(),
+ }
+}
+
+// Copy copies the current state of the registry into its own memory space.
+func (p *Registry) Copy() *Registry {
+ copy := &Registry{
+ revTypeMap: make(map[string]*Type),
+ pbdb: p.pbdb.Copy(),
+ }
+ for k, v := range p.revTypeMap {
+ copy.revTypeMap[k] = v
+ }
+ return copy
+}
+
+// EnumValue returns the numeric value of the given enum value name.
+func (p *Registry) EnumValue(enumName string) ref.Val {
+ enumVal, found := p.pbdb.DescribeEnum(enumName)
+ if !found {
+ return NewErr("unknown enum name '%s'", enumName)
+ }
+ return Int(enumVal.Value())
+}
+
+// FindFieldType returns the field type for a checked type value. Returns false if
+// the field could not be found.
+//
+// Deprecated: use FindStructFieldType
+func (p *Registry) FindFieldType(structType, fieldName string) (*ref.FieldType, bool) {
+ msgType, found := p.pbdb.DescribeType(structType)
+ if !found {
+ return nil, false
+ }
+ field, found := msgType.FieldByName(fieldName)
+ if !found {
+ return nil, false
+ }
+ return &ref.FieldType{
+ Type: field.CheckedType(),
+ IsSet: field.IsSet,
+ GetFrom: field.GetFrom}, true
+}
+
+// FindStructFieldNames returns the set of field names for the given struct type,
+// if the type exists in the registry.
+func (p *Registry) FindStructFieldNames(structType string) ([]string, bool) {
+ msgType, found := p.pbdb.DescribeType(structType)
+ if !found {
+ return []string{}, false
+ }
+ fieldMap := msgType.FieldMap()
+ fields := make([]string, len(fieldMap))
+ idx := 0
+ for f := range fieldMap {
+ fields[idx] = f
+ idx++
+ }
+ return fields, true
+}
+
+// FindStructFieldType returns the field type for a checked type value. Returns
+// false if the field could not be found.
+func (p *Registry) FindStructFieldType(structType, fieldName string) (*FieldType, bool) {
+ msgType, found := p.pbdb.DescribeType(structType)
+ if !found {
+ return nil, false
+ }
+ field, found := msgType.FieldByName(fieldName)
+ if !found {
+ return nil, false
+ }
+ return &FieldType{
+ Type: fieldDescToCELType(field),
+ IsSet: field.IsSet,
+ GetFrom: field.GetFrom}, true
+}
+
+// FindIdent takes a qualified identifier name and returns a ref.Val if one exists.
+func (p *Registry) FindIdent(identName string) (ref.Val, bool) {
+ if t, found := p.revTypeMap[identName]; found {
+ return t, true
+ }
+ if enumVal, found := p.pbdb.DescribeEnum(identName); found {
+ return Int(enumVal.Value()), true
+ }
+ return nil, false
+}
+
+// FindType looks up the Type given a qualified typeName. Returns false if not found.
+//
+// Deprecated: use FindStructType
+func (p *Registry) FindType(structType string) (*exprpb.Type, bool) {
+ if _, found := p.pbdb.DescribeType(structType); !found {
+ return nil, false
+ }
+ if structType != "" && structType[0] == '.' {
+ structType = structType[1:]
+ }
+ return &exprpb.Type{
+ TypeKind: &exprpb.Type_Type{
+ Type: &exprpb.Type{
+ TypeKind: &exprpb.Type_MessageType{
+ MessageType: structType}}}}, true
+}
+
+// FindStructType returns the Type give a qualified type name.
+//
+// For historical reasons, only struct types are expected to be returned through this
+// method, and the type values are expected to be wrapped in a TypeType instance using
+// TypeTypeWithParam().
+//
+// Returns false if not found.
+func (p *Registry) FindStructType(structType string) (*Type, bool) {
+ if _, found := p.pbdb.DescribeType(structType); !found {
+ return nil, false
+ }
+ if structType != "" && structType[0] == '.' {
+ structType = structType[1:]
+ }
+ return NewTypeTypeWithParam(NewObjectType(structType)), true
+}
+
+// NewValue creates a new type value from a qualified name and map of field
+// name to value.
+//
+// Note, for each value, the Val.ConvertToNative function will be invoked
+// to convert the Val to the field's native type. If an error occurs during
+// conversion, the NewValue will be a types.Err.
+func (p *Registry) NewValue(structType string, fields map[string]ref.Val) ref.Val {
+ td, found := p.pbdb.DescribeType(structType)
+ if !found {
+ return NewErr("unknown type '%s'", structType)
+ }
+ msg := td.New()
+ fieldMap := td.FieldMap()
+ for name, value := range fields {
+ field, found := fieldMap[name]
+ if !found {
+ return NewErr("no such field: %s", name)
+ }
+ err := msgSetField(msg, field, value)
+ if err != nil {
+ return &Err{error: err}
+ }
+ }
+ return p.NativeToValue(msg.Interface())
+}
+
+// RegisterDescriptor registers the contents of a protocol buffer `FileDescriptor`.
+func (p *Registry) RegisterDescriptor(fileDesc protoreflect.FileDescriptor) error {
+ fd, err := p.pbdb.RegisterDescriptor(fileDesc)
+ if err != nil {
+ return err
+ }
+ return p.registerAllTypes(fd)
+}
+
+// RegisterMessage registers a protocol buffer message and its dependencies.
+func (p *Registry) RegisterMessage(message proto.Message) error {
+ fd, err := p.pbdb.RegisterMessage(message)
+ if err != nil {
+ return err
+ }
+ return p.registerAllTypes(fd)
+}
+
+// RegisterType registers a type value with the provider which ensures the provider is aware of how to
+// map the type to an identifier.
+//
+// If the `ref.Type` value is a `*types.Type` it will be registered directly by its runtime type name.
+// If the `ref.Type` value is not a `*types.Type` instance, a `*types.Type` instance which reflects the
+// traits present on the input and the runtime type name. By default this foreign type will be treated
+// as a types.StructKind. To avoid potential issues where the `ref.Type` values does not match the
+// generated `*types.Type` instance, consider always using the `*types.Type` to represent type extensions
+// to CEL, even when they're not based on protobuf types.
+func (p *Registry) RegisterType(types ...ref.Type) error {
+ for _, t := range types {
+ celType := maybeForeignType(t)
+ existing, found := p.revTypeMap[t.TypeName()]
+ if !found {
+ p.revTypeMap[t.TypeName()] = celType
+ continue
+ }
+ if !existing.IsEquivalentType(celType) {
+ return fmt.Errorf("type registration conflict. found: %v, input: %v", existing, celType)
+ }
+ if existing.traitMask != celType.traitMask {
+ return fmt.Errorf(
+ "type registered with conflicting traits: %v with traits %v, input: %v",
+ existing.TypeName(), existing.traitMask, celType.traitMask)
+ }
+ }
+ return nil
+}
+
+// NativeToValue converts various "native" types to ref.Val with this specific implementation
+// providing support for custom proto-based types.
+//
+// This method should be the inverse of ref.Val.ConvertToNative.
+func (p *Registry) NativeToValue(value any) ref.Val {
+ if val, found := nativeToValue(p, value); found {
+ return val
+ }
+ switch v := value.(type) {
+ case proto.Message:
+ typeName := string(v.ProtoReflect().Descriptor().FullName())
+ td, found := p.pbdb.DescribeType(typeName)
+ if !found {
+ return NewErr("unknown type: '%s'", typeName)
+ }
+ unwrapped, isUnwrapped, err := td.MaybeUnwrap(v)
+ if err != nil {
+ return UnsupportedRefValConversionErr(v)
+ }
+ if isUnwrapped {
+ return p.NativeToValue(unwrapped)
+ }
+ typeVal, found := p.FindIdent(typeName)
+ if !found {
+ return NewErr("unknown type: '%s'", typeName)
+ }
+ return NewObject(p, td, typeVal, v)
+ case *pb.Map:
+ return NewProtoMap(p, v)
+ case protoreflect.List:
+ return NewProtoList(p, v)
+ case protoreflect.Message:
+ return p.NativeToValue(v.Interface())
+ case protoreflect.Value:
+ return p.NativeToValue(v.Interface())
+ }
+ return UnsupportedRefValConversionErr(value)
+}
+
+func (p *Registry) registerAllTypes(fd *pb.FileDescription) error {
+ for _, typeName := range fd.GetTypeNames() {
+ // skip well-known type names since they're automatically sanitized
+ // during NewObjectType() calls.
+ if _, found := checkedWellKnowns[typeName]; found {
+ continue
+ }
+ err := p.RegisterType(NewObjectTypeValue(typeName))
+ if err != nil {
+ return err
+ }
+ }
+ return nil
+}
+
+func fieldDescToCELType(field *pb.FieldDescription) *Type {
+ if field.IsMap() {
+ return NewMapType(
+ singularFieldDescToCELType(field.KeyType),
+ singularFieldDescToCELType(field.ValueType))
+ }
+ if field.IsList() {
+ return NewListType(singularFieldDescToCELType(field))
+ }
+ return singularFieldDescToCELType(field)
+}
+
+func singularFieldDescToCELType(field *pb.FieldDescription) *Type {
+ if field.IsMessage() {
+ return NewObjectType(string(field.Descriptor().Message().FullName()))
+ }
+ if field.IsEnum() {
+ return IntType
+ }
+ return ProtoCELPrimitives[field.ProtoKind()]
+}
+
+// defaultTypeAdapter converts go native types to CEL values.
+type defaultTypeAdapter struct{}
+
+var (
+ // DefaultTypeAdapter adapts canonical CEL types from their equivalent Go values.
+ DefaultTypeAdapter = &defaultTypeAdapter{}
+)
+
+// NativeToValue implements the ref.TypeAdapter interface.
+func (a *defaultTypeAdapter) NativeToValue(value any) ref.Val {
+ if val, found := nativeToValue(a, value); found {
+ return val
+ }
+ return UnsupportedRefValConversionErr(value)
+}
+
+// nativeToValue returns the converted (ref.Val, true) of a conversion is found,
+// otherwise (nil, false)
+func nativeToValue(a Adapter, value any) (ref.Val, bool) {
+ switch v := value.(type) {
+ case nil:
+ return NullValue, true
+ case *Bool:
+ if v != nil {
+ return *v, true
+ }
+ case *Bytes:
+ if v != nil {
+ return *v, true
+ }
+ case *Double:
+ if v != nil {
+ return *v, true
+ }
+ case *Int:
+ if v != nil {
+ return *v, true
+ }
+ case *String:
+ if v != nil {
+ return *v, true
+ }
+ case *Uint:
+ if v != nil {
+ return *v, true
+ }
+ case bool:
+ return Bool(v), true
+ case int:
+ return Int(v), true
+ case int32:
+ return Int(v), true
+ case int64:
+ return Int(v), true
+ case uint:
+ return Uint(v), true
+ case uint32:
+ return Uint(v), true
+ case uint64:
+ return Uint(v), true
+ case float32:
+ return Double(v), true
+ case float64:
+ return Double(v), true
+ case string:
+ return String(v), true
+ case *dpb.Duration:
+ return Duration{Duration: v.AsDuration()}, true
+ case time.Duration:
+ return Duration{Duration: v}, true
+ case *tpb.Timestamp:
+ return Timestamp{Time: v.AsTime()}, true
+ case time.Time:
+ return Timestamp{Time: v}, true
+ case *bool:
+ if v != nil {
+ return Bool(*v), true
+ }
+ case *float32:
+ if v != nil {
+ return Double(*v), true
+ }
+ case *float64:
+ if v != nil {
+ return Double(*v), true
+ }
+ case *int:
+ if v != nil {
+ return Int(*v), true
+ }
+ case *int32:
+ if v != nil {
+ return Int(*v), true
+ }
+ case *int64:
+ if v != nil {
+ return Int(*v), true
+ }
+ case *string:
+ if v != nil {
+ return String(*v), true
+ }
+ case *uint:
+ if v != nil {
+ return Uint(*v), true
+ }
+ case *uint32:
+ if v != nil {
+ return Uint(*v), true
+ }
+ case *uint64:
+ if v != nil {
+ return Uint(*v), true
+ }
+ case []byte:
+ return Bytes(v), true
+ // specializations for common lists types.
+ case []string:
+ return NewStringList(a, v), true
+ case []ref.Val:
+ return NewRefValList(a, v), true
+ // specializations for common map types.
+ case map[string]string:
+ return NewStringStringMap(a, v), true
+ case map[string]any:
+ return NewStringInterfaceMap(a, v), true
+ case map[ref.Val]ref.Val:
+ return NewRefValMap(a, v), true
+ // additional specializations may be added upon request / need.
+ case *anypb.Any:
+ if v == nil {
+ return UnsupportedRefValConversionErr(v), true
+ }
+ unpackedAny, err := v.UnmarshalNew()
+ if err != nil {
+ return NewErr("anypb.UnmarshalNew() failed for type %q: %v", v.GetTypeUrl(), err), true
+ }
+ return a.NativeToValue(unpackedAny), true
+ case *structpb.NullValue, structpb.NullValue:
+ return NullValue, true
+ case *structpb.ListValue:
+ return NewJSONList(a, v), true
+ case *structpb.Struct:
+ return NewJSONStruct(a, v), true
+ case ref.Val:
+ return v, true
+ case protoreflect.EnumNumber:
+ return Int(v), true
+ case proto.Message:
+ if v == nil {
+ return UnsupportedRefValConversionErr(v), true
+ }
+ typeName := string(v.ProtoReflect().Descriptor().FullName())
+ td, found := pb.DefaultDb.DescribeType(typeName)
+ if !found {
+ return nil, false
+ }
+ val, unwrapped, err := td.MaybeUnwrap(v)
+ if err != nil {
+ return UnsupportedRefValConversionErr(v), true
+ }
+ if !unwrapped {
+ return nil, false
+ }
+ return a.NativeToValue(val), true
+ // Note: dynamicpb.Message implements the proto.Message _and_ protoreflect.Message interfaces
+ // which means that this case must appear after handling a proto.Message type.
+ case protoreflect.Message:
+ return a.NativeToValue(v.Interface()), true
+ default:
+ refValue := reflect.ValueOf(v)
+ if refValue.Kind() == reflect.Ptr {
+ if refValue.IsNil() {
+ return UnsupportedRefValConversionErr(v), true
+ }
+ refValue = refValue.Elem()
+ }
+ refKind := refValue.Kind()
+ switch refKind {
+ case reflect.Array, reflect.Slice:
+ if refValue.Type().Elem() == reflect.TypeOf(byte(0)) {
+ if refValue.CanAddr() {
+ return Bytes(refValue.Bytes()), true
+ }
+ tmp := reflect.New(refValue.Type())
+ tmp.Elem().Set(refValue)
+ return Bytes(tmp.Elem().Bytes()), true
+ }
+ return NewDynamicList(a, v), true
+ case reflect.Map:
+ return NewDynamicMap(a, v), true
+ // type aliases of primitive types cannot be asserted as that type, but rather need
+ // to be downcast to int32 before being converted to a CEL representation.
+ case reflect.Bool:
+ boolTupe := reflect.TypeOf(false)
+ return Bool(refValue.Convert(boolTupe).Interface().(bool)), true
+ case reflect.Int:
+ intType := reflect.TypeOf(int(0))
+ return Int(refValue.Convert(intType).Interface().(int)), true
+ case reflect.Int8:
+ intType := reflect.TypeOf(int8(0))
+ return Int(refValue.Convert(intType).Interface().(int8)), true
+ case reflect.Int16:
+ intType := reflect.TypeOf(int16(0))
+ return Int(refValue.Convert(intType).Interface().(int16)), true
+ case reflect.Int32:
+ intType := reflect.TypeOf(int32(0))
+ return Int(refValue.Convert(intType).Interface().(int32)), true
+ case reflect.Int64:
+ intType := reflect.TypeOf(int64(0))
+ return Int(refValue.Convert(intType).Interface().(int64)), true
+ case reflect.Uint:
+ uintType := reflect.TypeOf(uint(0))
+ return Uint(refValue.Convert(uintType).Interface().(uint)), true
+ case reflect.Uint8:
+ uintType := reflect.TypeOf(uint8(0))
+ return Uint(refValue.Convert(uintType).Interface().(uint8)), true
+ case reflect.Uint16:
+ uintType := reflect.TypeOf(uint16(0))
+ return Uint(refValue.Convert(uintType).Interface().(uint16)), true
+ case reflect.Uint32:
+ uintType := reflect.TypeOf(uint32(0))
+ return Uint(refValue.Convert(uintType).Interface().(uint32)), true
+ case reflect.Uint64:
+ uintType := reflect.TypeOf(uint64(0))
+ return Uint(refValue.Convert(uintType).Interface().(uint64)), true
+ case reflect.Float32:
+ doubleType := reflect.TypeOf(float32(0))
+ return Double(refValue.Convert(doubleType).Interface().(float32)), true
+ case reflect.Float64:
+ doubleType := reflect.TypeOf(float64(0))
+ return Double(refValue.Convert(doubleType).Interface().(float64)), true
+ case reflect.String:
+ stringType := reflect.TypeOf("")
+ return String(refValue.Convert(stringType).Interface().(string)), true
+ }
+ }
+ return nil, false
+}
+
+func msgSetField(target protoreflect.Message, field *pb.FieldDescription, val ref.Val) error {
+ if field.IsList() {
+ lv := target.NewField(field.Descriptor())
+ list, ok := val.(traits.Lister)
+ if !ok {
+ return unsupportedTypeConversionError(field, val)
+ }
+ err := msgSetListField(lv.List(), field, list)
+ if err != nil {
+ return err
+ }
+ target.Set(field.Descriptor(), lv)
+ return nil
+ }
+ if field.IsMap() {
+ mv := target.NewField(field.Descriptor())
+ mp, ok := val.(traits.Mapper)
+ if !ok {
+ return unsupportedTypeConversionError(field, val)
+ }
+ err := msgSetMapField(mv.Map(), field, mp)
+ if err != nil {
+ return err
+ }
+ target.Set(field.Descriptor(), mv)
+ return nil
+ }
+ v, err := val.ConvertToNative(field.ReflectType())
+ if err != nil {
+ return fieldTypeConversionError(field, err)
+ }
+ if v == nil {
+ return nil
+ }
+ switch pv := v.(type) {
+ case proto.Message:
+ v = pv.ProtoReflect()
+ }
+ target.Set(field.Descriptor(), protoreflect.ValueOf(v))
+ return nil
+}
+
+func msgSetListField(target protoreflect.List, listField *pb.FieldDescription, listVal traits.Lister) error {
+ elemReflectType := listField.ReflectType().Elem()
+ for i := Int(0); i < listVal.Size().(Int); i++ {
+ elem := listVal.Get(i)
+ elemVal, err := elem.ConvertToNative(elemReflectType)
+ if err != nil {
+ return fieldTypeConversionError(listField, err)
+ }
+ if elemVal == nil {
+ continue
+ }
+ switch ev := elemVal.(type) {
+ case proto.Message:
+ elemVal = ev.ProtoReflect()
+ }
+ target.Append(protoreflect.ValueOf(elemVal))
+ }
+ return nil
+}
+
+func msgSetMapField(target protoreflect.Map, mapField *pb.FieldDescription, mapVal traits.Mapper) error {
+ targetKeyType := mapField.KeyType.ReflectType()
+ targetValType := mapField.ValueType.ReflectType()
+ it := mapVal.Iterator()
+ for it.HasNext() == True {
+ key := it.Next()
+ val := mapVal.Get(key)
+ k, err := key.ConvertToNative(targetKeyType)
+ if err != nil {
+ return fieldTypeConversionError(mapField, err)
+ }
+ v, err := val.ConvertToNative(targetValType)
+ if err != nil {
+ return fieldTypeConversionError(mapField, err)
+ }
+ if v == nil {
+ continue
+ }
+ switch pv := v.(type) {
+ case proto.Message:
+ v = pv.ProtoReflect()
+ }
+ target.Set(protoreflect.ValueOf(k).MapKey(), protoreflect.ValueOf(v))
+ }
+ return nil
+}
+
+func unsupportedTypeConversionError(field *pb.FieldDescription, val ref.Val) error {
+ msgName := field.Descriptor().ContainingMessage().FullName()
+ return fmt.Errorf("unsupported field type for %v.%v: %v", msgName, field.Name(), val.Type())
+}
+
+func fieldTypeConversionError(field *pb.FieldDescription, err error) error {
+ msgName := field.Descriptor().ContainingMessage().FullName()
+ return fmt.Errorf("field type conversion error for %v.%v value type: %v", msgName, field.Name(), err)
+}
+
+var (
+ // ProtoCELPrimitives provides a map from the protoreflect Kind to the equivalent CEL type.
+ ProtoCELPrimitives = map[protoreflect.Kind]*Type{
+ protoreflect.BoolKind: BoolType,
+ protoreflect.BytesKind: BytesType,
+ protoreflect.DoubleKind: DoubleType,
+ protoreflect.FloatKind: DoubleType,
+ protoreflect.Int32Kind: IntType,
+ protoreflect.Int64Kind: IntType,
+ protoreflect.Sint32Kind: IntType,
+ protoreflect.Sint64Kind: IntType,
+ protoreflect.Uint32Kind: UintType,
+ protoreflect.Uint64Kind: UintType,
+ protoreflect.Fixed32Kind: UintType,
+ protoreflect.Fixed64Kind: UintType,
+ protoreflect.Sfixed32Kind: IntType,
+ protoreflect.Sfixed64Kind: IntType,
+ protoreflect.StringKind: StringType,
+ }
+)
diff --git a/vendor/github.com/google/cel-go/common/types/ref/BUILD.bazel b/vendor/github.com/google/cel-go/common/types/ref/BUILD.bazel
new file mode 100644
index 000000000000..7f17c6d193b1
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/ref/BUILD.bazel
@@ -0,0 +1,21 @@
+load("@io_bazel_rules_go//go:def.bzl", "go_library")
+
+package(
+ default_visibility = ["//visibility:public"],
+ licenses = ["notice"], # Apache 2.0
+)
+
+go_library(
+ name = "go_default_library",
+ srcs = [
+ "provider.go",
+ "reference.go",
+ ],
+ importmap = "kubevirt.io/kubevirt/vendor/github.com/google/cel-go/common/types/ref",
+ importpath = "github.com/google/cel-go/common/types/ref",
+ deps = [
+ "//vendor/google.golang.org/genproto/googleapis/api/expr/v1alpha1:go_default_library",
+ "//vendor/google.golang.org/protobuf/proto:go_default_library",
+ "//vendor/google.golang.org/protobuf/reflect/protoreflect:go_default_library",
+ ],
+)
diff --git a/vendor/github.com/google/cel-go/common/types/ref/provider.go b/vendor/github.com/google/cel-go/common/types/ref/provider.go
new file mode 100644
index 000000000000..b9820023d6f5
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/ref/provider.go
@@ -0,0 +1,102 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package ref
+
+import (
+ "google.golang.org/protobuf/proto"
+ "google.golang.org/protobuf/reflect/protoreflect"
+
+ exprpb "google.golang.org/genproto/googleapis/api/expr/v1alpha1"
+)
+
+// TypeProvider specifies functions for creating new object instances and for
+// resolving enum values by name.
+//
+// Deprecated: use types.Provider
+type TypeProvider interface {
+ // EnumValue returns the numeric value of the given enum value name.
+ EnumValue(enumName string) Val
+
+ // FindIdent takes a qualified identifier name and returns a Value if one exists.
+ FindIdent(identName string) (Val, bool)
+
+ // FindType looks up the Type given a qualified typeName. Returns false if not found.
+ FindType(typeName string) (*exprpb.Type, bool)
+
+ // FieldFieldType returns the field type for a checked type value. Returns false if
+ // the field could not be found.
+ FindFieldType(messageType, fieldName string) (*FieldType, bool)
+
+ // NewValue creates a new type value from a qualified name and map of field name
+ // to value.
+ //
+ // Note, for each value, the Val.ConvertToNative function will be invoked to convert
+ // the Val to the field's native type. If an error occurs during conversion, the
+ // NewValue will be a types.Err.
+ NewValue(typeName string, fields map[string]Val) Val
+}
+
+// TypeAdapter converts native Go values of varying type and complexity to equivalent CEL values.
+//
+// Deprecated: use types.Adapter
+type TypeAdapter interface {
+ // NativeToValue converts the input `value` to a CEL `ref.Val`.
+ NativeToValue(value any) Val
+}
+
+// TypeRegistry allows third-parties to add custom types to CEL. Not all `TypeProvider`
+// implementations support type-customization, so these features are optional. However, a
+// `TypeRegistry` should be a `TypeProvider` and a `TypeAdapter` to ensure that types
+// which are registered can be converted to CEL representations.
+//
+// Deprecated: use types.Registry
+type TypeRegistry interface {
+ TypeAdapter
+ TypeProvider
+
+ // RegisterDescriptor registers the contents of a protocol buffer `FileDescriptor`.
+ RegisterDescriptor(fileDesc protoreflect.FileDescriptor) error
+
+ // RegisterMessage registers a protocol buffer message and its dependencies.
+ RegisterMessage(message proto.Message) error
+
+ // RegisterType registers a type value with the provider which ensures the
+ // provider is aware of how to map the type to an identifier.
+ //
+ // If a type is provided more than once with an alternative definition, the
+ // call will result in an error.
+ RegisterType(types ...Type) error
+}
+
+// FieldType represents a field's type value and whether that field supports
+// presence detection.
+//
+// Deprecated: use types.FieldType
+type FieldType struct {
+ // Type of the field as a protobuf type value.
+ Type *exprpb.Type
+
+ // IsSet indicates whether the field is set on an input object.
+ IsSet FieldTester
+
+ // GetFrom retrieves the field value on the input object, if set.
+ GetFrom FieldGetter
+}
+
+// FieldTester is used to test field presence on an input object.
+type FieldTester func(target any) bool
+
+// FieldGetter is used to get the field value from an input object, if set.
+type FieldGetter func(target any) (any, error)
diff --git a/vendor/github.com/google/cel-go/common/types/ref/reference.go b/vendor/github.com/google/cel-go/common/types/ref/reference.go
new file mode 100644
index 000000000000..e0d58145cdcd
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/ref/reference.go
@@ -0,0 +1,63 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+// Package ref contains the reference interfaces used throughout the types components.
+package ref
+
+import (
+ "reflect"
+)
+
+// Type interface indicate the name of a given type.
+type Type interface {
+ // HasTrait returns whether the type has a given trait associated with it.
+ //
+ // See common/types/traits/traits.go for a list of supported traits.
+ HasTrait(trait int) bool
+
+ // TypeName returns the qualified type name of the type.
+ //
+ // The type name is also used as the type's identifier name at type-check and interpretation time.
+ TypeName() string
+}
+
+// Val interface defines the functions supported by all expression values.
+// Val implementations may specialize the behavior of the value through the addition of traits.
+type Val interface {
+ // ConvertToNative converts the Value to a native Go struct according to the
+ // reflected type description, or error if the conversion is not feasible.
+ //
+ // The ConvertToNative method is intended to be used to support conversion between CEL types
+ // and native types during object creation expressions or by clients who need to adapt the,
+ // returned CEL value into an equivalent Go value instance.
+ //
+ // When implementing or using ConvertToNative, the following guidelines apply:
+ // - Use ConvertToNative when marshalling CEL evaluation results to native types.
+ // - Do not use ConvertToNative within CEL extension functions.
+ // - Document whether your implementation supports non-CEL field types, such as Go or Protobuf.
+ ConvertToNative(typeDesc reflect.Type) (any, error)
+
+ // ConvertToType supports type conversions between CEL value types supported by the expression language.
+ ConvertToType(typeValue Type) Val
+
+ // Equal returns true if the `other` value has the same type and content as the implementing struct.
+ Equal(other Val) Val
+
+ // Type returns the TypeValue of the value.
+ Type() Type
+
+ // Value returns the raw value of the instance which may not be directly compatible with the expression
+ // language types.
+ Value() any
+}
diff --git a/vendor/github.com/google/cel-go/common/types/string.go b/vendor/github.com/google/cel-go/common/types/string.go
new file mode 100644
index 000000000000..3a93743f24e2
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/string.go
@@ -0,0 +1,226 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package types
+
+import (
+ "fmt"
+ "reflect"
+ "regexp"
+ "strconv"
+ "strings"
+ "time"
+
+ "github.com/google/cel-go/common/overloads"
+ "github.com/google/cel-go/common/types/ref"
+
+ anypb "google.golang.org/protobuf/types/known/anypb"
+ structpb "google.golang.org/protobuf/types/known/structpb"
+ wrapperspb "google.golang.org/protobuf/types/known/wrapperspb"
+)
+
+// String type implementation which supports addition, comparison, matching,
+// and size functions.
+type String string
+
+var (
+ stringOneArgOverloads = map[string]func(ref.Val, ref.Val) ref.Val{
+ overloads.Contains: StringContains,
+ overloads.EndsWith: StringEndsWith,
+ overloads.StartsWith: StringStartsWith,
+ }
+
+ stringWrapperType = reflect.TypeOf(&wrapperspb.StringValue{})
+)
+
+// Add implements traits.Adder.Add.
+func (s String) Add(other ref.Val) ref.Val {
+ otherString, ok := other.(String)
+ if !ok {
+ return MaybeNoSuchOverloadErr(other)
+ }
+ return s + otherString
+}
+
+// Compare implements traits.Comparer.Compare.
+func (s String) Compare(other ref.Val) ref.Val {
+ otherString, ok := other.(String)
+ if !ok {
+ return MaybeNoSuchOverloadErr(other)
+ }
+ return Int(strings.Compare(s.Value().(string), otherString.Value().(string)))
+}
+
+// ConvertToNative implements ref.Val.ConvertToNative.
+func (s String) ConvertToNative(typeDesc reflect.Type) (any, error) {
+ switch typeDesc.Kind() {
+ case reflect.String:
+ return reflect.ValueOf(s).Convert(typeDesc).Interface(), nil
+ case reflect.Ptr:
+ switch typeDesc {
+ case anyValueType:
+ // Primitives must be wrapped before being set on an Any field.
+ return anypb.New(wrapperspb.String(string(s)))
+ case jsonValueType:
+ // Convert to a protobuf representation of a JSON String.
+ return structpb.NewStringValue(string(s)), nil
+ case stringWrapperType:
+ // Convert to a wrapperspb.StringValue.
+ return wrapperspb.String(string(s)), nil
+ }
+ if typeDesc.Elem().Kind() == reflect.String {
+ p := s.Value().(string)
+ return &p, nil
+ }
+ case reflect.Interface:
+ sv := s.Value()
+ if reflect.TypeOf(sv).Implements(typeDesc) {
+ return sv, nil
+ }
+ if reflect.TypeOf(s).Implements(typeDesc) {
+ return s, nil
+ }
+ }
+ return nil, fmt.Errorf(
+ "unsupported native conversion from string to '%v'", typeDesc)
+}
+
+// ConvertToType implements ref.Val.ConvertToType.
+func (s String) ConvertToType(typeVal ref.Type) ref.Val {
+ switch typeVal {
+ case IntType:
+ if n, err := strconv.ParseInt(s.Value().(string), 10, 64); err == nil {
+ return Int(n)
+ }
+ case UintType:
+ if n, err := strconv.ParseUint(s.Value().(string), 10, 64); err == nil {
+ return Uint(n)
+ }
+ case DoubleType:
+ if n, err := strconv.ParseFloat(s.Value().(string), 64); err == nil {
+ return Double(n)
+ }
+ case BoolType:
+ if b, err := strconv.ParseBool(s.Value().(string)); err == nil {
+ return Bool(b)
+ }
+ case BytesType:
+ return Bytes(s)
+ case DurationType:
+ if d, err := time.ParseDuration(s.Value().(string)); err == nil {
+ return durationOf(d)
+ }
+ case TimestampType:
+ if t, err := time.Parse(time.RFC3339, s.Value().(string)); err == nil {
+ if t.Unix() < minUnixTime || t.Unix() > maxUnixTime {
+ return celErrTimestampOverflow
+ }
+ return timestampOf(t)
+ }
+ case StringType:
+ return s
+ case TypeType:
+ return StringType
+ }
+ return NewErr("type conversion error from '%s' to '%s'", StringType, typeVal)
+}
+
+// Equal implements ref.Val.Equal.
+func (s String) Equal(other ref.Val) ref.Val {
+ otherString, ok := other.(String)
+ return Bool(ok && s == otherString)
+}
+
+// IsZeroValue returns true if the string is empty.
+func (s String) IsZeroValue() bool {
+ return len(s) == 0
+}
+
+// Match implements traits.Matcher.Match.
+func (s String) Match(pattern ref.Val) ref.Val {
+ pat, ok := pattern.(String)
+ if !ok {
+ return MaybeNoSuchOverloadErr(pattern)
+ }
+ matched, err := regexp.MatchString(pat.Value().(string), s.Value().(string))
+ if err != nil {
+ return &Err{error: err}
+ }
+ return Bool(matched)
+}
+
+// Receive implements traits.Receiver.Receive.
+func (s String) Receive(function string, overload string, args []ref.Val) ref.Val {
+ switch len(args) {
+ case 1:
+ if f, found := stringOneArgOverloads[function]; found {
+ return f(s, args[0])
+ }
+ }
+ return NoSuchOverloadErr()
+}
+
+// Size implements traits.Sizer.Size.
+func (s String) Size() ref.Val {
+ return Int(len([]rune(s.Value().(string))))
+}
+
+// Type implements ref.Val.Type.
+func (s String) Type() ref.Type {
+ return StringType
+}
+
+// Value implements ref.Val.Value.
+func (s String) Value() any {
+ return string(s)
+}
+
+// StringContains returns whether the string contains a substring.
+func StringContains(s, sub ref.Val) ref.Val {
+ str, ok := s.(String)
+ if !ok {
+ return MaybeNoSuchOverloadErr(s)
+ }
+ subStr, ok := sub.(String)
+ if !ok {
+ return MaybeNoSuchOverloadErr(sub)
+ }
+ return Bool(strings.Contains(string(str), string(subStr)))
+}
+
+// StringEndsWith returns whether the target string contains the input suffix.
+func StringEndsWith(s, suf ref.Val) ref.Val {
+ str, ok := s.(String)
+ if !ok {
+ return MaybeNoSuchOverloadErr(s)
+ }
+ sufStr, ok := suf.(String)
+ if !ok {
+ return MaybeNoSuchOverloadErr(suf)
+ }
+ return Bool(strings.HasSuffix(string(str), string(sufStr)))
+}
+
+// StringStartsWith returns whether the target string contains the input prefix.
+func StringStartsWith(s, pre ref.Val) ref.Val {
+ str, ok := s.(String)
+ if !ok {
+ return MaybeNoSuchOverloadErr(s)
+ }
+ preStr, ok := pre.(String)
+ if !ok {
+ return MaybeNoSuchOverloadErr(pre)
+ }
+ return Bool(strings.HasPrefix(string(str), string(preStr)))
+}
diff --git a/vendor/github.com/google/cel-go/common/types/timestamp.go b/vendor/github.com/google/cel-go/common/types/timestamp.go
new file mode 100644
index 000000000000..33acdea8ef7c
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/timestamp.go
@@ -0,0 +1,311 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package types
+
+import (
+ "fmt"
+ "reflect"
+ "strconv"
+ "strings"
+ "time"
+
+ "github.com/google/cel-go/common/overloads"
+ "github.com/google/cel-go/common/types/ref"
+
+ anypb "google.golang.org/protobuf/types/known/anypb"
+ structpb "google.golang.org/protobuf/types/known/structpb"
+ tpb "google.golang.org/protobuf/types/known/timestamppb"
+)
+
+// Timestamp type implementation which supports add, compare, and subtract
+// operations. Timestamps are also capable of participating in dynamic
+// function dispatch to instance methods.
+type Timestamp struct {
+ time.Time
+}
+
+func timestampOf(t time.Time) Timestamp {
+ // Note that this function does not validate that time.Time is in our supported range.
+ return Timestamp{Time: t}
+}
+
+const (
+ // The number of seconds between year 1 and year 1970. This is borrowed from
+ // https://golang.org/src/time/time.go.
+ unixToInternal int64 = (1969*365 + 1969/4 - 1969/100 + 1969/400) * (60 * 60 * 24)
+
+ // Number of seconds between `0001-01-01T00:00:00Z` and the Unix epoch.
+ minUnixTime int64 = -62135596800
+ // Number of seconds between `9999-12-31T23:59:59.999999999Z` and the Unix epoch.
+ maxUnixTime int64 = 253402300799
+)
+
+// Add implements traits.Adder.Add.
+func (t Timestamp) Add(other ref.Val) ref.Val {
+ switch other.Type() {
+ case DurationType:
+ return other.(Duration).Add(t)
+ }
+ return MaybeNoSuchOverloadErr(other)
+}
+
+// Compare implements traits.Comparer.Compare.
+func (t Timestamp) Compare(other ref.Val) ref.Val {
+ if TimestampType != other.Type() {
+ return MaybeNoSuchOverloadErr(other)
+ }
+ ts1 := t.Time
+ ts2 := other.(Timestamp).Time
+ switch {
+ case ts1.Before(ts2):
+ return IntNegOne
+ case ts1.After(ts2):
+ return IntOne
+ default:
+ return IntZero
+ }
+}
+
+// ConvertToNative implements ref.Val.ConvertToNative.
+func (t Timestamp) ConvertToNative(typeDesc reflect.Type) (any, error) {
+ // If the timestamp is already assignable to the desired type return it.
+ if reflect.TypeOf(t.Time).AssignableTo(typeDesc) {
+ return t.Time, nil
+ }
+ if reflect.TypeOf(t).AssignableTo(typeDesc) {
+ return t, nil
+ }
+ switch typeDesc {
+ case anyValueType:
+ // Pack the underlying time as a tpb.Timestamp into an Any value.
+ return anypb.New(tpb.New(t.Time))
+ case jsonValueType:
+ // CEL follows the proto3 to JSON conversion which formats as an RFC 3339 encoded JSON
+ // string.
+ v := t.ConvertToType(StringType)
+ if IsError(v) {
+ return nil, v.(*Err)
+ }
+ return structpb.NewStringValue(string(v.(String))), nil
+ case timestampValueType:
+ // Unwrap the underlying tpb.Timestamp.
+ return tpb.New(t.Time), nil
+ }
+ return nil, fmt.Errorf("type conversion error from 'Timestamp' to '%v'", typeDesc)
+}
+
+// ConvertToType implements ref.Val.ConvertToType.
+func (t Timestamp) ConvertToType(typeVal ref.Type) ref.Val {
+ switch typeVal {
+ case StringType:
+ return String(t.Format(time.RFC3339Nano))
+ case IntType:
+ // Return the Unix time in seconds since 1970
+ return Int(t.Unix())
+ case TimestampType:
+ return t
+ case TypeType:
+ return TimestampType
+ }
+ return NewErr("type conversion error from '%s' to '%s'", TimestampType, typeVal)
+}
+
+// Equal implements ref.Val.Equal.
+func (t Timestamp) Equal(other ref.Val) ref.Val {
+ otherTime, ok := other.(Timestamp)
+ return Bool(ok && t.Time.Equal(otherTime.Time))
+}
+
+// IsZeroValue returns true if the timestamp is epoch 0.
+func (t Timestamp) IsZeroValue() bool {
+ return t.IsZero()
+}
+
+// Receive implements traits.Receiver.Receive.
+func (t Timestamp) Receive(function string, overload string, args []ref.Val) ref.Val {
+ switch len(args) {
+ case 0:
+ if f, found := timestampZeroArgOverloads[function]; found {
+ return f(t.Time)
+ }
+ case 1:
+ if f, found := timestampOneArgOverloads[function]; found {
+ return f(t.Time, args[0])
+ }
+ }
+ return NoSuchOverloadErr()
+}
+
+// Subtract implements traits.Subtractor.Subtract.
+func (t Timestamp) Subtract(subtrahend ref.Val) ref.Val {
+ switch subtrahend.Type() {
+ case DurationType:
+ dur := subtrahend.(Duration)
+ val, err := subtractTimeDurationChecked(t.Time, dur.Duration)
+ if err != nil {
+ return WrapErr(err)
+ }
+ return timestampOf(val)
+ case TimestampType:
+ t2 := subtrahend.(Timestamp).Time
+ val, err := subtractTimeChecked(t.Time, t2)
+ if err != nil {
+ return WrapErr(err)
+ }
+ return durationOf(val)
+ }
+ return MaybeNoSuchOverloadErr(subtrahend)
+}
+
+// Type implements ref.Val.Type.
+func (t Timestamp) Type() ref.Type {
+ return TimestampType
+}
+
+// Value implements ref.Val.Value.
+func (t Timestamp) Value() any {
+ return t.Time
+}
+
+var (
+ timestampValueType = reflect.TypeOf(&tpb.Timestamp{})
+
+ timestampZeroArgOverloads = map[string]func(time.Time) ref.Val{
+ overloads.TimeGetFullYear: timestampGetFullYear,
+ overloads.TimeGetMonth: timestampGetMonth,
+ overloads.TimeGetDayOfYear: timestampGetDayOfYear,
+ overloads.TimeGetDate: timestampGetDayOfMonthOneBased,
+ overloads.TimeGetDayOfMonth: timestampGetDayOfMonthZeroBased,
+ overloads.TimeGetDayOfWeek: timestampGetDayOfWeek,
+ overloads.TimeGetHours: timestampGetHours,
+ overloads.TimeGetMinutes: timestampGetMinutes,
+ overloads.TimeGetSeconds: timestampGetSeconds,
+ overloads.TimeGetMilliseconds: timestampGetMilliseconds}
+
+ timestampOneArgOverloads = map[string]func(time.Time, ref.Val) ref.Val{
+ overloads.TimeGetFullYear: timestampGetFullYearWithTz,
+ overloads.TimeGetMonth: timestampGetMonthWithTz,
+ overloads.TimeGetDayOfYear: timestampGetDayOfYearWithTz,
+ overloads.TimeGetDate: timestampGetDayOfMonthOneBasedWithTz,
+ overloads.TimeGetDayOfMonth: timestampGetDayOfMonthZeroBasedWithTz,
+ overloads.TimeGetDayOfWeek: timestampGetDayOfWeekWithTz,
+ overloads.TimeGetHours: timestampGetHoursWithTz,
+ overloads.TimeGetMinutes: timestampGetMinutesWithTz,
+ overloads.TimeGetSeconds: timestampGetSecondsWithTz,
+ overloads.TimeGetMilliseconds: timestampGetMillisecondsWithTz}
+)
+
+type timestampVisitor func(time.Time) ref.Val
+
+func timestampGetFullYear(t time.Time) ref.Val {
+ return Int(t.Year())
+}
+func timestampGetMonth(t time.Time) ref.Val {
+ // CEL spec indicates that the month should be 0-based, but the Time value
+ // for Month() is 1-based.
+ return Int(t.Month() - 1)
+}
+func timestampGetDayOfYear(t time.Time) ref.Val {
+ return Int(t.YearDay() - 1)
+}
+func timestampGetDayOfMonthZeroBased(t time.Time) ref.Val {
+ return Int(t.Day() - 1)
+}
+func timestampGetDayOfMonthOneBased(t time.Time) ref.Val {
+ return Int(t.Day())
+}
+func timestampGetDayOfWeek(t time.Time) ref.Val {
+ return Int(t.Weekday())
+}
+func timestampGetHours(t time.Time) ref.Val {
+ return Int(t.Hour())
+}
+func timestampGetMinutes(t time.Time) ref.Val {
+ return Int(t.Minute())
+}
+func timestampGetSeconds(t time.Time) ref.Val {
+ return Int(t.Second())
+}
+func timestampGetMilliseconds(t time.Time) ref.Val {
+ return Int(t.Nanosecond() / 1000000)
+}
+
+func timestampGetFullYearWithTz(t time.Time, tz ref.Val) ref.Val {
+ return timeZone(tz, timestampGetFullYear)(t)
+}
+func timestampGetMonthWithTz(t time.Time, tz ref.Val) ref.Val {
+ return timeZone(tz, timestampGetMonth)(t)
+}
+func timestampGetDayOfYearWithTz(t time.Time, tz ref.Val) ref.Val {
+ return timeZone(tz, timestampGetDayOfYear)(t)
+}
+func timestampGetDayOfMonthZeroBasedWithTz(t time.Time, tz ref.Val) ref.Val {
+ return timeZone(tz, timestampGetDayOfMonthZeroBased)(t)
+}
+func timestampGetDayOfMonthOneBasedWithTz(t time.Time, tz ref.Val) ref.Val {
+ return timeZone(tz, timestampGetDayOfMonthOneBased)(t)
+}
+func timestampGetDayOfWeekWithTz(t time.Time, tz ref.Val) ref.Val {
+ return timeZone(tz, timestampGetDayOfWeek)(t)
+}
+func timestampGetHoursWithTz(t time.Time, tz ref.Val) ref.Val {
+ return timeZone(tz, timestampGetHours)(t)
+}
+func timestampGetMinutesWithTz(t time.Time, tz ref.Val) ref.Val {
+ return timeZone(tz, timestampGetMinutes)(t)
+}
+func timestampGetSecondsWithTz(t time.Time, tz ref.Val) ref.Val {
+ return timeZone(tz, timestampGetSeconds)(t)
+}
+func timestampGetMillisecondsWithTz(t time.Time, tz ref.Val) ref.Val {
+ return timeZone(tz, timestampGetMilliseconds)(t)
+}
+
+func timeZone(tz ref.Val, visitor timestampVisitor) timestampVisitor {
+ return func(t time.Time) ref.Val {
+ if StringType != tz.Type() {
+ return MaybeNoSuchOverloadErr(tz)
+ }
+ val := string(tz.(String))
+ ind := strings.Index(val, ":")
+ if ind == -1 {
+ loc, err := time.LoadLocation(val)
+ if err != nil {
+ return WrapErr(err)
+ }
+ return visitor(t.In(loc))
+ }
+
+ // If the input is not the name of a timezone (for example, 'US/Central'), it should be a numerical offset from UTC
+ // in the format ^(+|-)(0[0-9]|1[0-4]):[0-5][0-9]$. The numerical input is parsed in terms of hours and minutes.
+ hr, err := strconv.Atoi(string(val[0:ind]))
+ if err != nil {
+ return WrapErr(err)
+ }
+ min, err := strconv.Atoi(string(val[ind+1:]))
+ if err != nil {
+ return WrapErr(err)
+ }
+ var offset int
+ if string(val[0]) == "-" {
+ offset = hr*60 - min
+ } else {
+ offset = hr*60 + min
+ }
+ secondsEastOfUTC := int((time.Duration(offset) * time.Minute).Seconds())
+ timezone := time.FixedZone("", secondsEastOfUTC)
+ return visitor(t.In(timezone))
+ }
+}
diff --git a/vendor/github.com/google/cel-go/common/types/traits/BUILD.bazel b/vendor/github.com/google/cel-go/common/types/traits/BUILD.bazel
new file mode 100644
index 000000000000..35ea51633e80
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/traits/BUILD.bazel
@@ -0,0 +1,30 @@
+load("@io_bazel_rules_go//go:def.bzl", "go_library")
+
+package(
+ default_visibility = ["//visibility:public"],
+ licenses = ["notice"], # Apache 2.0
+)
+
+go_library(
+ name = "go_default_library",
+ srcs = [
+ "comparer.go",
+ "container.go",
+ "field_tester.go",
+ "indexer.go",
+ "iterator.go",
+ "lister.go",
+ "mapper.go",
+ "matcher.go",
+ "math.go",
+ "receiver.go",
+ "sizer.go",
+ "traits.go",
+ "zeroer.go",
+ ],
+ importmap = "kubevirt.io/kubevirt/vendor/github.com/google/cel-go/common/types/traits",
+ importpath = "github.com/google/cel-go/common/types/traits",
+ deps = [
+ "//vendor/github.com/google/cel-go/common/types/ref:go_default_library",
+ ],
+)
diff --git a/vendor/github.com/google/cel-go/common/types/traits/comparer.go b/vendor/github.com/google/cel-go/common/types/traits/comparer.go
new file mode 100644
index 000000000000..b531d9ae2bfe
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/traits/comparer.go
@@ -0,0 +1,33 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package traits
+
+import (
+ "github.com/google/cel-go/common/types/ref"
+)
+
+// Comparer interface for ordering comparisons between values in order to
+// support '<', '<=', '>=', '>' overloads.
+type Comparer interface {
+ // Compare this value to the input other value, returning an Int:
+ //
+ // this < other -> Int(-1)
+ // this == other -> Int(0)
+ // this > other -> Int(1)
+ //
+ // If the comparison cannot be made or is not supported, an error should
+ // be returned.
+ Compare(other ref.Val) ref.Val
+}
diff --git a/vendor/github.com/google/cel-go/common/types/traits/container.go b/vendor/github.com/google/cel-go/common/types/traits/container.go
new file mode 100644
index 000000000000..cf5c621ae9f7
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/traits/container.go
@@ -0,0 +1,23 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package traits
+
+import "github.com/google/cel-go/common/types/ref"
+
+// Container interface which permits containment tests such as 'a in b'.
+type Container interface {
+ // Contains returns true if the value exists within the object.
+ Contains(value ref.Val) ref.Val
+}
diff --git a/vendor/github.com/google/cel-go/common/types/traits/field_tester.go b/vendor/github.com/google/cel-go/common/types/traits/field_tester.go
new file mode 100644
index 000000000000..816a9565238a
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/traits/field_tester.go
@@ -0,0 +1,30 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package traits
+
+import (
+ "github.com/google/cel-go/common/types/ref"
+)
+
+// FieldTester indicates if a defined field on an object type is set to a
+// non-default value.
+//
+// For use with the `has()` macro.
+type FieldTester interface {
+ // IsSet returns true if the field is defined and set to a non-default
+ // value. The method will return false if defined and not set, and an error
+ // if the field is not defined.
+ IsSet(field ref.Val) ref.Val
+}
diff --git a/vendor/github.com/google/cel-go/common/types/traits/indexer.go b/vendor/github.com/google/cel-go/common/types/traits/indexer.go
new file mode 100644
index 000000000000..662c6836c332
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/traits/indexer.go
@@ -0,0 +1,25 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package traits
+
+import (
+ "github.com/google/cel-go/common/types/ref"
+)
+
+// Indexer permits random access of elements by index 'a[b()]'.
+type Indexer interface {
+ // Get the value at the specified index or error.
+ Get(index ref.Val) ref.Val
+}
diff --git a/vendor/github.com/google/cel-go/common/types/traits/iterator.go b/vendor/github.com/google/cel-go/common/types/traits/iterator.go
new file mode 100644
index 000000000000..42dd371aa49b
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/traits/iterator.go
@@ -0,0 +1,36 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package traits
+
+import (
+ "github.com/google/cel-go/common/types/ref"
+)
+
+// Iterable aggregate types permit traversal over their elements.
+type Iterable interface {
+ // Iterator returns a new iterator view of the struct.
+ Iterator() Iterator
+}
+
+// Iterator permits safe traversal over the contents of an aggregate type.
+type Iterator interface {
+ ref.Val
+
+ // HasNext returns true if there are unvisited elements in the Iterator.
+ HasNext() ref.Val
+
+ // Next returns the next element.
+ Next() ref.Val
+}
diff --git a/vendor/github.com/google/cel-go/common/types/traits/lister.go b/vendor/github.com/google/cel-go/common/types/traits/lister.go
new file mode 100644
index 000000000000..5cf2593f3b94
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/traits/lister.go
@@ -0,0 +1,33 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package traits
+
+import "github.com/google/cel-go/common/types/ref"
+
+// Lister interface which aggregates the traits of a list.
+type Lister interface {
+ ref.Val
+ Adder
+ Container
+ Indexer
+ Iterable
+ Sizer
+}
+
+// MutableLister interface which emits an immutable result after an intermediate computation.
+type MutableLister interface {
+ Lister
+ ToImmutableList() Lister
+}
diff --git a/vendor/github.com/google/cel-go/common/types/traits/mapper.go b/vendor/github.com/google/cel-go/common/types/traits/mapper.go
new file mode 100644
index 000000000000..2f7c919a8bd8
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/traits/mapper.go
@@ -0,0 +1,33 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package traits
+
+import "github.com/google/cel-go/common/types/ref"
+
+// Mapper interface which aggregates the traits of a maps.
+type Mapper interface {
+ ref.Val
+ Container
+ Indexer
+ Iterable
+ Sizer
+
+ // Find returns a value, if one exists, for the input key.
+ //
+ // If the key is not found the function returns (nil, false).
+ // If the input key is not valid for the map, or is Err or Unknown the function returns
+ // (Unknown|Err, false).
+ Find(key ref.Val) (ref.Val, bool)
+}
diff --git a/vendor/github.com/google/cel-go/common/types/traits/matcher.go b/vendor/github.com/google/cel-go/common/types/traits/matcher.go
new file mode 100644
index 000000000000..085dc94ff4fb
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/traits/matcher.go
@@ -0,0 +1,23 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package traits
+
+import "github.com/google/cel-go/common/types/ref"
+
+// Matcher interface for supporting 'matches()' overloads.
+type Matcher interface {
+ // Match returns true if the pattern matches the current value.
+ Match(pattern ref.Val) ref.Val
+}
diff --git a/vendor/github.com/google/cel-go/common/types/traits/math.go b/vendor/github.com/google/cel-go/common/types/traits/math.go
new file mode 100644
index 000000000000..86d5b9137e6e
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/traits/math.go
@@ -0,0 +1,62 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package traits
+
+import "github.com/google/cel-go/common/types/ref"
+
+// Adder interface to support '+' operator overloads.
+type Adder interface {
+ // Add returns a combination of the current value and other value.
+ //
+ // If the other value is an unsupported type, an error is returned.
+ Add(other ref.Val) ref.Val
+}
+
+// Divider interface to support '/' operator overloads.
+type Divider interface {
+ // Divide returns the result of dividing the current value by the input
+ // denominator.
+ //
+ // A denominator value of zero results in an error.
+ Divide(denominator ref.Val) ref.Val
+}
+
+// Modder interface to support '%' operator overloads.
+type Modder interface {
+ // Modulo returns the result of taking the modulus of the current value
+ // by the denominator.
+ //
+ // A denominator value of zero results in an error.
+ Modulo(denominator ref.Val) ref.Val
+}
+
+// Multiplier interface to support '*' operator overloads.
+type Multiplier interface {
+ // Multiply returns the result of multiplying the current and input value.
+ Multiply(other ref.Val) ref.Val
+}
+
+// Negater interface to support unary '-' and '!' operator overloads.
+type Negater interface {
+ // Negate returns the complement of the current value.
+ Negate() ref.Val
+}
+
+// Subtractor interface to support binary '-' operator overloads.
+type Subtractor interface {
+ // Subtract returns the result of subtracting the input from the current
+ // value.
+ Subtract(subtrahend ref.Val) ref.Val
+}
diff --git a/vendor/github.com/google/cel-go/common/types/traits/receiver.go b/vendor/github.com/google/cel-go/common/types/traits/receiver.go
new file mode 100644
index 000000000000..8f41db45e8f3
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/traits/receiver.go
@@ -0,0 +1,24 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package traits
+
+import "github.com/google/cel-go/common/types/ref"
+
+// Receiver interface for routing instance method calls within a value.
+type Receiver interface {
+ // Receive accepts a function name, overload id, and arguments and returns
+ // a value.
+ Receive(function string, overload string, args []ref.Val) ref.Val
+}
diff --git a/vendor/github.com/google/cel-go/common/types/traits/sizer.go b/vendor/github.com/google/cel-go/common/types/traits/sizer.go
new file mode 100644
index 000000000000..b80d25137a72
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/traits/sizer.go
@@ -0,0 +1,25 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package traits
+
+import (
+ "github.com/google/cel-go/common/types/ref"
+)
+
+// Sizer interface for supporting 'size()' overloads.
+type Sizer interface {
+ // Size returns the number of elements or length of the value.
+ Size() ref.Val
+}
diff --git a/vendor/github.com/google/cel-go/common/types/traits/traits.go b/vendor/github.com/google/cel-go/common/types/traits/traits.go
new file mode 100644
index 000000000000..6da3e6a3e1f8
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/traits/traits.go
@@ -0,0 +1,64 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+// Package traits defines interfaces that a type may implement to participate
+// in operator overloads and function dispatch.
+package traits
+
+const (
+ // AdderType types provide a '+' operator overload.
+ AdderType = 1 << iota
+
+ // ComparerType types support ordering comparisons '<', '<=', '>', '>='.
+ ComparerType
+
+ // ContainerType types support 'in' operations.
+ ContainerType
+
+ // DividerType types support '/' operations.
+ DividerType
+
+ // FieldTesterType types support the detection of field value presence.
+ FieldTesterType
+
+ // IndexerType types support index access with dynamic values.
+ IndexerType
+
+ // IterableType types can be iterated over in comprehensions.
+ IterableType
+
+ // IteratorType types support iterator semantics.
+ IteratorType
+
+ // MatcherType types support pattern matching via 'matches' method.
+ MatcherType
+
+ // ModderType types support modulus operations '%'
+ ModderType
+
+ // MultiplierType types support '*' operations.
+ MultiplierType
+
+ // NegatorType types support either negation via '!' or '-'
+ NegatorType
+
+ // ReceiverType types support dynamic dispatch to instance methods.
+ ReceiverType
+
+ // SizerType types support the size() method.
+ SizerType
+
+ // SubtractorType type support '-' operations.
+ SubtractorType
+)
diff --git a/vendor/github.com/google/cel-go/common/types/traits/zeroer.go b/vendor/github.com/google/cel-go/common/types/traits/zeroer.go
new file mode 100644
index 000000000000..0b7c830a2465
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/traits/zeroer.go
@@ -0,0 +1,21 @@
+// Copyright 2022 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package traits
+
+// Zeroer interface for testing whether a CEL value is a zero value for its type.
+type Zeroer interface {
+ // IsZeroValue indicates whether the object is the zero value for the type.
+ IsZeroValue() bool
+}
diff --git a/vendor/github.com/google/cel-go/common/types/types.go b/vendor/github.com/google/cel-go/common/types/types.go
new file mode 100644
index 000000000000..6c3d5f719baf
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/types.go
@@ -0,0 +1,823 @@
+// Copyright 2023 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package types
+
+import (
+ "fmt"
+ "reflect"
+ "strings"
+
+ chkdecls "github.com/google/cel-go/checker/decls"
+ "github.com/google/cel-go/common/types/ref"
+ "github.com/google/cel-go/common/types/traits"
+
+ exprpb "google.golang.org/genproto/googleapis/api/expr/v1alpha1"
+)
+
+// Kind indicates a CEL type's kind which is used to differentiate quickly between simple
+// and complex types.
+type Kind uint
+
+const (
+ // UnspecifiedKind is returned when the type is nil or its kind is not specified.
+ UnspecifiedKind Kind = iota
+
+ // DynKind represents a dynamic type. This kind only exists at type-check time.
+ DynKind
+
+ // AnyKind represents a google.protobuf.Any type. This kind only exists at type-check time.
+ // Prefer DynKind to AnyKind as AnyKind has a specific meaning which is based on protobuf
+ // well-known types.
+ AnyKind
+
+ // BoolKind represents a boolean type.
+ BoolKind
+
+ // BytesKind represents a bytes type.
+ BytesKind
+
+ // DoubleKind represents a double type.
+ DoubleKind
+
+ // DurationKind represents a CEL duration type.
+ DurationKind
+
+ // ErrorKind represents a CEL error type.
+ ErrorKind
+
+ // IntKind represents an integer type.
+ IntKind
+
+ // ListKind represents a list type.
+ ListKind
+
+ // MapKind represents a map type.
+ MapKind
+
+ // NullTypeKind represents a null type.
+ NullTypeKind
+
+ // OpaqueKind represents an abstract type which has no accessible fields.
+ OpaqueKind
+
+ // StringKind represents a string type.
+ StringKind
+
+ // StructKind represents a structured object with typed fields.
+ StructKind
+
+ // TimestampKind represents a a CEL time type.
+ TimestampKind
+
+ // TypeKind represents the CEL type.
+ TypeKind
+
+ // TypeParamKind represents a parameterized type whose type name will be resolved at type-check time, if possible.
+ TypeParamKind
+
+ // UintKind represents a uint type.
+ UintKind
+
+ // UnknownKind represents an unknown value type.
+ UnknownKind
+)
+
+var (
+ // AnyType represents the google.protobuf.Any type.
+ AnyType = &Type{
+ kind: AnyKind,
+ runtimeTypeName: "google.protobuf.Any",
+ traitMask: traits.FieldTesterType |
+ traits.IndexerType,
+ }
+ // BoolType represents the bool type.
+ BoolType = &Type{
+ kind: BoolKind,
+ runtimeTypeName: "bool",
+ traitMask: traits.ComparerType |
+ traits.NegatorType,
+ }
+ // BytesType represents the bytes type.
+ BytesType = &Type{
+ kind: BytesKind,
+ runtimeTypeName: "bytes",
+ traitMask: traits.AdderType |
+ traits.ComparerType |
+ traits.SizerType,
+ }
+ // DoubleType represents the double type.
+ DoubleType = &Type{
+ kind: DoubleKind,
+ runtimeTypeName: "double",
+ traitMask: traits.AdderType |
+ traits.ComparerType |
+ traits.DividerType |
+ traits.MultiplierType |
+ traits.NegatorType |
+ traits.SubtractorType,
+ }
+ // DurationType represents the CEL duration type.
+ DurationType = &Type{
+ kind: DurationKind,
+ runtimeTypeName: "google.protobuf.Duration",
+ traitMask: traits.AdderType |
+ traits.ComparerType |
+ traits.NegatorType |
+ traits.ReceiverType |
+ traits.SubtractorType,
+ }
+ // DynType represents a dynamic CEL type whose type will be determined at runtime from context.
+ DynType = &Type{
+ kind: DynKind,
+ runtimeTypeName: "dyn",
+ }
+ // ErrorType represents a CEL error value.
+ ErrorType = &Type{
+ kind: ErrorKind,
+ runtimeTypeName: "error",
+ }
+ // IntType represents the int type.
+ IntType = &Type{
+ kind: IntKind,
+ runtimeTypeName: "int",
+ traitMask: traits.AdderType |
+ traits.ComparerType |
+ traits.DividerType |
+ traits.ModderType |
+ traits.MultiplierType |
+ traits.NegatorType |
+ traits.SubtractorType,
+ }
+ // ListType represents the runtime list type.
+ ListType = NewListType(nil)
+ // MapType represents the runtime map type.
+ MapType = NewMapType(nil, nil)
+ // NullType represents the type of a null value.
+ NullType = &Type{
+ kind: NullTypeKind,
+ runtimeTypeName: "null_type",
+ }
+ // StringType represents the string type.
+ StringType = &Type{
+ kind: StringKind,
+ runtimeTypeName: "string",
+ traitMask: traits.AdderType |
+ traits.ComparerType |
+ traits.MatcherType |
+ traits.ReceiverType |
+ traits.SizerType,
+ }
+ // TimestampType represents the time type.
+ TimestampType = &Type{
+ kind: TimestampKind,
+ runtimeTypeName: "google.protobuf.Timestamp",
+ traitMask: traits.AdderType |
+ traits.ComparerType |
+ traits.ReceiverType |
+ traits.SubtractorType,
+ }
+ // TypeType represents a CEL type
+ TypeType = &Type{
+ kind: TypeKind,
+ runtimeTypeName: "type",
+ }
+ // UintType represents a uint type.
+ UintType = &Type{
+ kind: UintKind,
+ runtimeTypeName: "uint",
+ traitMask: traits.AdderType |
+ traits.ComparerType |
+ traits.DividerType |
+ traits.ModderType |
+ traits.MultiplierType |
+ traits.SubtractorType,
+ }
+ // UnknownType represents an unknown value type.
+ UnknownType = &Type{
+ kind: UnknownKind,
+ runtimeTypeName: "unknown",
+ }
+)
+
+var _ ref.Type = &Type{}
+var _ ref.Val = &Type{}
+
+// Type holds a reference to a runtime type with an optional type-checked set of type parameters.
+type Type struct {
+ // kind indicates general category of the type.
+ kind Kind
+
+ // parameters holds the optional type-checked set of type Parameters that are used during static analysis.
+ parameters []*Type
+
+ // runtimeTypeName indicates the runtime type name of the type.
+ runtimeTypeName string
+
+ // isAssignableType function determines whether one type is assignable to this type.
+ // A nil value for the isAssignableType function falls back to equality of kind, runtimeType, and parameters.
+ isAssignableType func(other *Type) bool
+
+ // isAssignableRuntimeType function determines whether the runtime type (with erasure) is assignable to this type.
+ // A nil value for the isAssignableRuntimeType function falls back to the equality of the type or type name.
+ isAssignableRuntimeType func(other ref.Val) bool
+
+ // traitMask is a mask of flags which indicate the capabilities of the type.
+ traitMask int
+}
+
+// ConvertToNative implements ref.Val.ConvertToNative.
+func (t *Type) ConvertToNative(typeDesc reflect.Type) (any, error) {
+ return nil, fmt.Errorf("type conversion not supported for 'type'")
+}
+
+// ConvertToType implements ref.Val.ConvertToType.
+func (t *Type) ConvertToType(typeVal ref.Type) ref.Val {
+ switch typeVal {
+ case TypeType:
+ return TypeType
+ case StringType:
+ return String(t.TypeName())
+ }
+ return NewErr("type conversion error from '%s' to '%s'", TypeType, typeVal)
+}
+
+// Equal indicates whether two types have the same runtime type name.
+//
+// The name Equal is a bit of a misnomer, but for historical reasons, this is the
+// runtime behavior. For a more accurate definition see IsType().
+func (t *Type) Equal(other ref.Val) ref.Val {
+ otherType, ok := other.(ref.Type)
+ return Bool(ok && t.TypeName() == otherType.TypeName())
+}
+
+// HasTrait implements the ref.Type interface method.
+func (t *Type) HasTrait(trait int) bool {
+ return trait&t.traitMask == trait
+}
+
+// IsExactType indicates whether the two types are exactly the same. This check also verifies type parameter type names.
+func (t *Type) IsExactType(other *Type) bool {
+ return t.isTypeInternal(other, true)
+}
+
+// IsEquivalentType indicates whether two types are equivalent. This check ignores type parameter type names.
+func (t *Type) IsEquivalentType(other *Type) bool {
+ return t.isTypeInternal(other, false)
+}
+
+// Kind indicates general category of the type.
+func (t *Type) Kind() Kind {
+ if t == nil {
+ return UnspecifiedKind
+ }
+ return t.kind
+}
+
+// isTypeInternal checks whether the two types are equivalent or exactly the same based on the checkTypeParamName flag.
+func (t *Type) isTypeInternal(other *Type, checkTypeParamName bool) bool {
+ if t == nil {
+ return false
+ }
+ if t == other {
+ return true
+ }
+ if t.Kind() != other.Kind() || len(t.Parameters()) != len(other.Parameters()) {
+ return false
+ }
+ if (checkTypeParamName || t.Kind() != TypeParamKind) && t.TypeName() != other.TypeName() {
+ return false
+ }
+ for i, p := range t.Parameters() {
+ if !p.isTypeInternal(other.Parameters()[i], checkTypeParamName) {
+ return false
+ }
+ }
+ return true
+}
+
+// IsAssignableType determines whether the current type is type-check assignable from the input fromType.
+func (t *Type) IsAssignableType(fromType *Type) bool {
+ if t == nil {
+ return false
+ }
+ if t.isAssignableType != nil {
+ return t.isAssignableType(fromType)
+ }
+ return t.defaultIsAssignableType(fromType)
+}
+
+// IsAssignableRuntimeType determines whether the current type is runtime assignable from the input runtimeType.
+//
+// At runtime, parameterized types are erased and so a function which type-checks to support a map(string, string)
+// will have a runtime assignable type of a map.
+func (t *Type) IsAssignableRuntimeType(val ref.Val) bool {
+ if t == nil {
+ return false
+ }
+ if t.isAssignableRuntimeType != nil {
+ return t.isAssignableRuntimeType(val)
+ }
+ return t.defaultIsAssignableRuntimeType(val)
+}
+
+// Parameters returns the list of type parameters if set.
+//
+// For ListKind, Parameters()[0] represents the list element type
+// For MapKind, Parameters()[0] represents the map key type, and Parameters()[1] represents the map
+// value type.
+func (t *Type) Parameters() []*Type {
+ if t == nil {
+ return emptyParams
+ }
+ return t.parameters
+}
+
+// DeclaredTypeName indicates the fully qualified and parameterized type-check type name.
+func (t *Type) DeclaredTypeName() string {
+ // if the type itself is neither null, nor dyn, but is assignable to null, then it's a wrapper type.
+ if t.Kind() != NullTypeKind && !t.isDyn() && t.IsAssignableType(NullType) {
+ return fmt.Sprintf("wrapper(%s)", t.TypeName())
+ }
+ return t.TypeName()
+}
+
+// Type implements the ref.Val interface method.
+func (t *Type) Type() ref.Type {
+ return TypeType
+}
+
+// Value implements the ref.Val interface method.
+func (t *Type) Value() any {
+ return t.TypeName()
+}
+
+// TypeName returns the type-erased fully qualified runtime type name.
+//
+// TypeName implements the ref.Type interface method.
+func (t *Type) TypeName() string {
+ if t == nil {
+ return ""
+ }
+ return t.runtimeTypeName
+}
+
+// WithTraits creates a copy of the current Type and sets the trait mask to the traits parameter.
+//
+// This method should be used with Opaque types where the type acts like a container, e.g. vector.
+func (t *Type) WithTraits(traits int) *Type {
+ if t == nil {
+ return nil
+ }
+ return &Type{
+ kind: t.kind,
+ parameters: t.parameters,
+ runtimeTypeName: t.runtimeTypeName,
+ isAssignableType: t.isAssignableType,
+ isAssignableRuntimeType: t.isAssignableRuntimeType,
+ traitMask: traits,
+ }
+}
+
+// String returns a human-readable definition of the type name.
+func (t *Type) String() string {
+ if len(t.Parameters()) == 0 {
+ return t.DeclaredTypeName()
+ }
+ params := make([]string, len(t.Parameters()))
+ for i, p := range t.Parameters() {
+ params[i] = p.String()
+ }
+ return fmt.Sprintf("%s(%s)", t.DeclaredTypeName(), strings.Join(params, ", "))
+}
+
+// isDyn indicates whether the type is dynamic in any way.
+func (t *Type) isDyn() bool {
+ k := t.Kind()
+ return k == DynKind || k == AnyKind || k == TypeParamKind
+}
+
+// defaultIsAssignableType provides the standard definition of what it means for one type to be assignable to another
+// where any of the following may return a true result:
+// - The from types are the same instance
+// - The target type is dynamic
+// - The fromType has the same kind and type name as the target type, and all parameters of the target type
+//
+// are IsAssignableType() from the parameters of the fromType.
+func (t *Type) defaultIsAssignableType(fromType *Type) bool {
+ if t == fromType || t.isDyn() {
+ return true
+ }
+ if t.Kind() != fromType.Kind() ||
+ t.TypeName() != fromType.TypeName() ||
+ len(t.Parameters()) != len(fromType.Parameters()) {
+ return false
+ }
+ for i, tp := range t.Parameters() {
+ fp := fromType.Parameters()[i]
+ if !tp.IsAssignableType(fp) {
+ return false
+ }
+ }
+ return true
+}
+
+// defaultIsAssignableRuntimeType inspects the type and in the case of list and map elements, the key and element types
+// to determine whether a ref.Val is assignable to the declared type for a function signature.
+func (t *Type) defaultIsAssignableRuntimeType(val ref.Val) bool {
+ valType := val.Type()
+ // If the current type and value type don't agree, then return
+ if !(t.isDyn() || t.TypeName() == valType.TypeName()) {
+ return false
+ }
+ switch t.Kind() {
+ case ListKind:
+ elemType := t.Parameters()[0]
+ l := val.(traits.Lister)
+ if l.Size() == IntZero {
+ return true
+ }
+ it := l.Iterator()
+ elemVal := it.Next()
+ return elemType.IsAssignableRuntimeType(elemVal)
+ case MapKind:
+ keyType := t.Parameters()[0]
+ elemType := t.Parameters()[1]
+ m := val.(traits.Mapper)
+ if m.Size() == IntZero {
+ return true
+ }
+ it := m.Iterator()
+ keyVal := it.Next()
+ elemVal := m.Get(keyVal)
+ return keyType.IsAssignableRuntimeType(keyVal) && elemType.IsAssignableRuntimeType(elemVal)
+ }
+ return true
+}
+
+// NewListType creates an instances of a list type value with the provided element type.
+func NewListType(elemType *Type) *Type {
+ return &Type{
+ kind: ListKind,
+ parameters: []*Type{elemType},
+ runtimeTypeName: "list",
+ traitMask: traits.AdderType |
+ traits.ContainerType |
+ traits.IndexerType |
+ traits.IterableType |
+ traits.SizerType,
+ }
+}
+
+// NewMapType creates an instance of a map type value with the provided key and value types.
+func NewMapType(keyType, valueType *Type) *Type {
+ return &Type{
+ kind: MapKind,
+ parameters: []*Type{keyType, valueType},
+ runtimeTypeName: "map",
+ traitMask: traits.ContainerType |
+ traits.IndexerType |
+ traits.IterableType |
+ traits.SizerType,
+ }
+}
+
+// NewNullableType creates an instance of a nullable type with the provided wrapped type.
+//
+// Note: only primitive types are supported as wrapped types.
+func NewNullableType(wrapped *Type) *Type {
+ return &Type{
+ kind: wrapped.Kind(),
+ parameters: wrapped.Parameters(),
+ runtimeTypeName: wrapped.TypeName(),
+ traitMask: wrapped.traitMask,
+ isAssignableType: func(other *Type) bool {
+ return NullType.IsAssignableType(other) || wrapped.IsAssignableType(other)
+ },
+ isAssignableRuntimeType: func(other ref.Val) bool {
+ return NullType.IsAssignableRuntimeType(other) || wrapped.IsAssignableRuntimeType(other)
+ },
+ }
+}
+
+// NewOptionalType creates an abstract parameterized type instance corresponding to CEL's notion of optional.
+func NewOptionalType(param *Type) *Type {
+ return NewOpaqueType("optional_type", param)
+}
+
+// NewOpaqueType creates an abstract parameterized type with a given name.
+func NewOpaqueType(name string, params ...*Type) *Type {
+ return &Type{
+ kind: OpaqueKind,
+ parameters: params,
+ runtimeTypeName: name,
+ }
+}
+
+// NewObjectType creates a type reference to an externally defined type, e.g. a protobuf message type.
+//
+// An object type is assumed to support field presence testing and field indexing. Additionally, the
+// type may also indicate additional traits through the use of the optional traits vararg argument.
+func NewObjectType(typeName string, traits ...int) *Type {
+ // Function sanitizes object types on the fly
+ if wkt, found := checkedWellKnowns[typeName]; found {
+ return wkt
+ }
+ traitMask := 0
+ for _, trait := range traits {
+ traitMask |= trait
+ }
+ return &Type{
+ kind: StructKind,
+ parameters: emptyParams,
+ runtimeTypeName: typeName,
+ traitMask: structTypeTraitMask | traitMask,
+ }
+}
+
+// NewObjectTypeValue creates a type reference to an externally defined type.
+//
+// Deprecated: use cel.ObjectType(typeName)
+func NewObjectTypeValue(typeName string) *Type {
+ return NewObjectType(typeName)
+}
+
+// NewTypeValue creates an opaque type which has a set of optional type traits as defined in
+// the common/types/traits package.
+//
+// Deprecated: use cel.ObjectType(typeName, traits)
+func NewTypeValue(typeName string, traits ...int) *Type {
+ traitMask := 0
+ for _, trait := range traits {
+ traitMask |= trait
+ }
+ return &Type{
+ kind: StructKind,
+ parameters: emptyParams,
+ runtimeTypeName: typeName,
+ traitMask: traitMask,
+ }
+}
+
+// NewTypeParamType creates a parameterized type instance.
+func NewTypeParamType(paramName string) *Type {
+ return &Type{
+ kind: TypeParamKind,
+ runtimeTypeName: paramName,
+ }
+}
+
+// NewTypeTypeWithParam creates a type with a type parameter.
+// Used for type-checking purposes, but equivalent to TypeType otherwise.
+func NewTypeTypeWithParam(param *Type) *Type {
+ return &Type{
+ kind: TypeKind,
+ runtimeTypeName: "type",
+ parameters: []*Type{param},
+ }
+}
+
+// TypeToExprType converts a CEL-native type representation to a protobuf CEL Type representation.
+func TypeToExprType(t *Type) (*exprpb.Type, error) {
+ switch t.Kind() {
+ case AnyKind:
+ return chkdecls.Any, nil
+ case BoolKind:
+ return maybeWrapper(t, chkdecls.Bool), nil
+ case BytesKind:
+ return maybeWrapper(t, chkdecls.Bytes), nil
+ case DoubleKind:
+ return maybeWrapper(t, chkdecls.Double), nil
+ case DurationKind:
+ return chkdecls.Duration, nil
+ case DynKind:
+ return chkdecls.Dyn, nil
+ case ErrorKind:
+ return chkdecls.Error, nil
+ case IntKind:
+ return maybeWrapper(t, chkdecls.Int), nil
+ case ListKind:
+ if len(t.Parameters()) != 1 {
+ return nil, fmt.Errorf("invalid list, got %d parameters, wanted one", len(t.Parameters()))
+ }
+ et, err := TypeToExprType(t.Parameters()[0])
+ if err != nil {
+ return nil, err
+ }
+ return chkdecls.NewListType(et), nil
+ case MapKind:
+ if len(t.Parameters()) != 2 {
+ return nil, fmt.Errorf("invalid map, got %d parameters, wanted two", len(t.Parameters()))
+ }
+ kt, err := TypeToExprType(t.Parameters()[0])
+ if err != nil {
+ return nil, err
+ }
+ vt, err := TypeToExprType(t.Parameters()[1])
+ if err != nil {
+ return nil, err
+ }
+ return chkdecls.NewMapType(kt, vt), nil
+ case NullTypeKind:
+ return chkdecls.Null, nil
+ case OpaqueKind:
+ params := make([]*exprpb.Type, len(t.Parameters()))
+ for i, p := range t.Parameters() {
+ pt, err := TypeToExprType(p)
+ if err != nil {
+ return nil, err
+ }
+ params[i] = pt
+ }
+ return chkdecls.NewAbstractType(t.TypeName(), params...), nil
+ case StringKind:
+ return maybeWrapper(t, chkdecls.String), nil
+ case StructKind:
+ return chkdecls.NewObjectType(t.TypeName()), nil
+ case TimestampKind:
+ return chkdecls.Timestamp, nil
+ case TypeParamKind:
+ return chkdecls.NewTypeParamType(t.TypeName()), nil
+ case TypeKind:
+ if len(t.Parameters()) == 1 {
+ p, err := TypeToExprType(t.Parameters()[0])
+ if err != nil {
+ return nil, err
+ }
+ return chkdecls.NewTypeType(p), nil
+ }
+ return chkdecls.NewTypeType(nil), nil
+ case UintKind:
+ return maybeWrapper(t, chkdecls.Uint), nil
+ }
+ return nil, fmt.Errorf("missing type conversion to proto: %v", t)
+}
+
+// ExprTypeToType converts a protobuf CEL type representation to a CEL-native type representation.
+func ExprTypeToType(t *exprpb.Type) (*Type, error) {
+ switch t.GetTypeKind().(type) {
+ case *exprpb.Type_Dyn:
+ return DynType, nil
+ case *exprpb.Type_AbstractType_:
+ paramTypes := make([]*Type, len(t.GetAbstractType().GetParameterTypes()))
+ for i, p := range t.GetAbstractType().GetParameterTypes() {
+ pt, err := ExprTypeToType(p)
+ if err != nil {
+ return nil, err
+ }
+ paramTypes[i] = pt
+ }
+ return NewOpaqueType(t.GetAbstractType().GetName(), paramTypes...), nil
+ case *exprpb.Type_ListType_:
+ et, err := ExprTypeToType(t.GetListType().GetElemType())
+ if err != nil {
+ return nil, err
+ }
+ return NewListType(et), nil
+ case *exprpb.Type_MapType_:
+ kt, err := ExprTypeToType(t.GetMapType().GetKeyType())
+ if err != nil {
+ return nil, err
+ }
+ vt, err := ExprTypeToType(t.GetMapType().GetValueType())
+ if err != nil {
+ return nil, err
+ }
+ return NewMapType(kt, vt), nil
+ case *exprpb.Type_MessageType:
+ return NewObjectType(t.GetMessageType()), nil
+ case *exprpb.Type_Null:
+ return NullType, nil
+ case *exprpb.Type_Primitive:
+ switch t.GetPrimitive() {
+ case exprpb.Type_BOOL:
+ return BoolType, nil
+ case exprpb.Type_BYTES:
+ return BytesType, nil
+ case exprpb.Type_DOUBLE:
+ return DoubleType, nil
+ case exprpb.Type_INT64:
+ return IntType, nil
+ case exprpb.Type_STRING:
+ return StringType, nil
+ case exprpb.Type_UINT64:
+ return UintType, nil
+ default:
+ return nil, fmt.Errorf("unsupported primitive type: %v", t)
+ }
+ case *exprpb.Type_TypeParam:
+ return NewTypeParamType(t.GetTypeParam()), nil
+ case *exprpb.Type_Type:
+ if t.GetType().GetTypeKind() != nil {
+ p, err := ExprTypeToType(t.GetType())
+ if err != nil {
+ return nil, err
+ }
+ return NewTypeTypeWithParam(p), nil
+ }
+ return TypeType, nil
+ case *exprpb.Type_WellKnown:
+ switch t.GetWellKnown() {
+ case exprpb.Type_ANY:
+ return AnyType, nil
+ case exprpb.Type_DURATION:
+ return DurationType, nil
+ case exprpb.Type_TIMESTAMP:
+ return TimestampType, nil
+ default:
+ return nil, fmt.Errorf("unsupported well-known type: %v", t)
+ }
+ case *exprpb.Type_Wrapper:
+ t, err := ExprTypeToType(&exprpb.Type{TypeKind: &exprpb.Type_Primitive{Primitive: t.GetWrapper()}})
+ if err != nil {
+ return nil, err
+ }
+ return NewNullableType(t), nil
+ case *exprpb.Type_Error:
+ return ErrorType, nil
+ default:
+ return nil, fmt.Errorf("unsupported type: %v", t)
+ }
+}
+
+func maybeWrapper(t *Type, pbType *exprpb.Type) *exprpb.Type {
+ if t.IsAssignableType(NullType) {
+ return chkdecls.NewWrapperType(pbType)
+ }
+ return pbType
+}
+
+func maybeForeignType(t ref.Type) *Type {
+ if celType, ok := t.(*Type); ok {
+ return celType
+ }
+ // Inspect the incoming type to determine its traits. The assumption will be that the incoming
+ // type does not have any field values; however, if the trait mask indicates that field testing
+ // and indexing are supported, the foreign type is marked as a struct.
+ traitMask := 0
+ for _, trait := range allTraits {
+ if t.HasTrait(trait) {
+ traitMask |= trait
+ }
+ }
+ // Treat the value like a struct. If it has no fields, this is harmless to denote the type
+ // as such since it basically becomes an opaque type by convention.
+ return NewObjectType(t.TypeName(), traitMask)
+}
+
+var (
+ checkedWellKnowns = map[string]*Type{
+ // Wrapper types.
+ "google.protobuf.BoolValue": NewNullableType(BoolType),
+ "google.protobuf.BytesValue": NewNullableType(BytesType),
+ "google.protobuf.DoubleValue": NewNullableType(DoubleType),
+ "google.protobuf.FloatValue": NewNullableType(DoubleType),
+ "google.protobuf.Int64Value": NewNullableType(IntType),
+ "google.protobuf.Int32Value": NewNullableType(IntType),
+ "google.protobuf.UInt64Value": NewNullableType(UintType),
+ "google.protobuf.UInt32Value": NewNullableType(UintType),
+ "google.protobuf.StringValue": NewNullableType(StringType),
+ // Well-known types.
+ "google.protobuf.Any": AnyType,
+ "google.protobuf.Duration": DurationType,
+ "google.protobuf.Timestamp": TimestampType,
+ // Json types.
+ "google.protobuf.ListValue": NewListType(DynType),
+ "google.protobuf.NullValue": NullType,
+ "google.protobuf.Struct": NewMapType(StringType, DynType),
+ "google.protobuf.Value": DynType,
+ }
+
+ emptyParams = []*Type{}
+
+ allTraits = []int{
+ traits.AdderType,
+ traits.ComparerType,
+ traits.ContainerType,
+ traits.DividerType,
+ traits.FieldTesterType,
+ traits.IndexerType,
+ traits.IterableType,
+ traits.IteratorType,
+ traits.MatcherType,
+ traits.ModderType,
+ traits.MultiplierType,
+ traits.NegatorType,
+ traits.ReceiverType,
+ traits.SizerType,
+ traits.SubtractorType,
+ }
+
+ structTypeTraitMask = traits.FieldTesterType | traits.IndexerType
+)
diff --git a/vendor/github.com/google/cel-go/common/types/uint.go b/vendor/github.com/google/cel-go/common/types/uint.go
new file mode 100644
index 000000000000..6d74f30d884d
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/uint.go
@@ -0,0 +1,256 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package types
+
+import (
+ "fmt"
+ "math"
+ "reflect"
+ "strconv"
+
+ "github.com/google/cel-go/common/types/ref"
+
+ anypb "google.golang.org/protobuf/types/known/anypb"
+ structpb "google.golang.org/protobuf/types/known/structpb"
+ wrapperspb "google.golang.org/protobuf/types/known/wrapperspb"
+)
+
+// Uint type implementation which supports comparison and math operators.
+type Uint uint64
+
+var (
+ uint32WrapperType = reflect.TypeOf(&wrapperspb.UInt32Value{})
+
+ uint64WrapperType = reflect.TypeOf(&wrapperspb.UInt64Value{})
+)
+
+// Uint constants
+const (
+ uintZero = Uint(0)
+)
+
+// Add implements traits.Adder.Add.
+func (i Uint) Add(other ref.Val) ref.Val {
+ otherUint, ok := other.(Uint)
+ if !ok {
+ return MaybeNoSuchOverloadErr(other)
+ }
+ val, err := addUint64Checked(uint64(i), uint64(otherUint))
+ if err != nil {
+ return WrapErr(err)
+ }
+ return Uint(val)
+}
+
+// Compare implements traits.Comparer.Compare.
+func (i Uint) Compare(other ref.Val) ref.Val {
+ switch ov := other.(type) {
+ case Double:
+ if math.IsNaN(float64(ov)) {
+ return NewErr("NaN values cannot be ordered")
+ }
+ return compareUintDouble(i, ov)
+ case Int:
+ return compareUintInt(i, ov)
+ case Uint:
+ return compareUint(i, ov)
+ default:
+ return MaybeNoSuchOverloadErr(other)
+ }
+}
+
+// ConvertToNative implements ref.Val.ConvertToNative.
+func (i Uint) ConvertToNative(typeDesc reflect.Type) (any, error) {
+ switch typeDesc.Kind() {
+ case reflect.Uint, reflect.Uint32:
+ v, err := uint64ToUint32Checked(uint64(i))
+ if err != nil {
+ return 0, err
+ }
+ return reflect.ValueOf(v).Convert(typeDesc).Interface(), nil
+ case reflect.Uint8:
+ v, err := uint64ToUint8Checked(uint64(i))
+ if err != nil {
+ return 0, err
+ }
+ return reflect.ValueOf(v).Convert(typeDesc).Interface(), nil
+ case reflect.Uint16:
+ v, err := uint64ToUint16Checked(uint64(i))
+ if err != nil {
+ return 0, err
+ }
+ return reflect.ValueOf(v).Convert(typeDesc).Interface(), nil
+ case reflect.Uint64:
+ return reflect.ValueOf(i).Convert(typeDesc).Interface(), nil
+ case reflect.Ptr:
+ switch typeDesc {
+ case anyValueType:
+ // Primitives must be wrapped before being set on an Any field.
+ return anypb.New(wrapperspb.UInt64(uint64(i)))
+ case jsonValueType:
+ // JSON can accurately represent 32-bit uints as floating point values.
+ if i.isJSONSafe() {
+ return structpb.NewNumberValue(float64(i)), nil
+ }
+ // Proto3 to JSON conversion requires string-formatted uint64 values
+ // since the conversion to floating point would result in truncation.
+ return structpb.NewStringValue(strconv.FormatUint(uint64(i), 10)), nil
+ case uint32WrapperType:
+ // Convert the value to a wrapperspb.UInt32Value, error on overflow.
+ v, err := uint64ToUint32Checked(uint64(i))
+ if err != nil {
+ return 0, err
+ }
+ return wrapperspb.UInt32(v), nil
+ case uint64WrapperType:
+ // Convert the value to a wrapperspb.UInt64Value.
+ return wrapperspb.UInt64(uint64(i)), nil
+ }
+ switch typeDesc.Elem().Kind() {
+ case reflect.Uint32:
+ v, err := uint64ToUint32Checked(uint64(i))
+ if err != nil {
+ return 0, err
+ }
+ p := reflect.New(typeDesc.Elem())
+ p.Elem().Set(reflect.ValueOf(v).Convert(typeDesc.Elem()))
+ return p.Interface(), nil
+ case reflect.Uint64:
+ v := uint64(i)
+ p := reflect.New(typeDesc.Elem())
+ p.Elem().Set(reflect.ValueOf(v).Convert(typeDesc.Elem()))
+ return p.Interface(), nil
+ }
+ case reflect.Interface:
+ iv := i.Value()
+ if reflect.TypeOf(iv).Implements(typeDesc) {
+ return iv, nil
+ }
+ if reflect.TypeOf(i).Implements(typeDesc) {
+ return i, nil
+ }
+ }
+ return nil, fmt.Errorf("unsupported type conversion from 'uint' to %v", typeDesc)
+}
+
+// ConvertToType implements ref.Val.ConvertToType.
+func (i Uint) ConvertToType(typeVal ref.Type) ref.Val {
+ switch typeVal {
+ case IntType:
+ v, err := uint64ToInt64Checked(uint64(i))
+ if err != nil {
+ return WrapErr(err)
+ }
+ return Int(v)
+ case UintType:
+ return i
+ case DoubleType:
+ return Double(i)
+ case StringType:
+ return String(fmt.Sprintf("%d", uint64(i)))
+ case TypeType:
+ return UintType
+ }
+ return NewErr("type conversion error from '%s' to '%s'", UintType, typeVal)
+}
+
+// Divide implements traits.Divider.Divide.
+func (i Uint) Divide(other ref.Val) ref.Val {
+ otherUint, ok := other.(Uint)
+ if !ok {
+ return MaybeNoSuchOverloadErr(other)
+ }
+ div, err := divideUint64Checked(uint64(i), uint64(otherUint))
+ if err != nil {
+ return WrapErr(err)
+ }
+ return Uint(div)
+}
+
+// Equal implements ref.Val.Equal.
+func (i Uint) Equal(other ref.Val) ref.Val {
+ switch ov := other.(type) {
+ case Double:
+ if math.IsNaN(float64(ov)) {
+ return False
+ }
+ return Bool(compareUintDouble(i, ov) == 0)
+ case Int:
+ return Bool(compareUintInt(i, ov) == 0)
+ case Uint:
+ return Bool(i == ov)
+ default:
+ return False
+ }
+}
+
+// IsZeroValue returns true if the uint is zero.
+func (i Uint) IsZeroValue() bool {
+ return i == 0
+}
+
+// Modulo implements traits.Modder.Modulo.
+func (i Uint) Modulo(other ref.Val) ref.Val {
+ otherUint, ok := other.(Uint)
+ if !ok {
+ return MaybeNoSuchOverloadErr(other)
+ }
+ mod, err := moduloUint64Checked(uint64(i), uint64(otherUint))
+ if err != nil {
+ return WrapErr(err)
+ }
+ return Uint(mod)
+}
+
+// Multiply implements traits.Multiplier.Multiply.
+func (i Uint) Multiply(other ref.Val) ref.Val {
+ otherUint, ok := other.(Uint)
+ if !ok {
+ return MaybeNoSuchOverloadErr(other)
+ }
+ val, err := multiplyUint64Checked(uint64(i), uint64(otherUint))
+ if err != nil {
+ return WrapErr(err)
+ }
+ return Uint(val)
+}
+
+// Subtract implements traits.Subtractor.Subtract.
+func (i Uint) Subtract(subtrahend ref.Val) ref.Val {
+ subtraUint, ok := subtrahend.(Uint)
+ if !ok {
+ return MaybeNoSuchOverloadErr(subtrahend)
+ }
+ val, err := subtractUint64Checked(uint64(i), uint64(subtraUint))
+ if err != nil {
+ return WrapErr(err)
+ }
+ return Uint(val)
+}
+
+// Type implements ref.Val.Type.
+func (i Uint) Type() ref.Type {
+ return UintType
+}
+
+// Value implements ref.Val.Value.
+func (i Uint) Value() any {
+ return uint64(i)
+}
+
+// isJSONSafe indicates whether the uint is safely representable as a floating point value in JSON.
+func (i Uint) isJSONSafe() bool {
+ return i <= maxIntJSON
+}
diff --git a/vendor/github.com/google/cel-go/common/types/unknown.go b/vendor/github.com/google/cel-go/common/types/unknown.go
new file mode 100644
index 000000000000..9dd2b2579479
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/unknown.go
@@ -0,0 +1,326 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package types
+
+import (
+ "fmt"
+ "math"
+ "reflect"
+ "sort"
+ "strings"
+ "unicode"
+
+ "github.com/google/cel-go/common/types/ref"
+)
+
+var (
+ unspecifiedAttribute = &AttributeTrail{qualifierPath: []any{}}
+)
+
+// NewAttributeTrail creates a new simple attribute from a variable name.
+func NewAttributeTrail(variable string) *AttributeTrail {
+ if variable == "" {
+ return unspecifiedAttribute
+ }
+ return &AttributeTrail{variable: variable}
+}
+
+// AttributeTrail specifies a variable with an optional qualifier path. An attribute value is expected to
+// correspond to an AbsoluteAttribute, meaning a field selection which starts with a top-level variable.
+//
+// The qualifer path elements adhere to the AttributeQualifier type constraint.
+type AttributeTrail struct {
+ variable string
+ qualifierPath []any
+}
+
+// Equal returns whether two attribute values have the same variable name and qualifier paths.
+func (a *AttributeTrail) Equal(other *AttributeTrail) bool {
+ if a.Variable() != other.Variable() || len(a.QualifierPath()) != len(other.QualifierPath()) {
+ return false
+ }
+ for i, q := range a.QualifierPath() {
+ qual := other.QualifierPath()[i]
+ if !qualifiersEqual(q, qual) {
+ return false
+ }
+ }
+ return true
+}
+
+func qualifiersEqual(a, b any) bool {
+ if a == b {
+ return true
+ }
+ switch numA := a.(type) {
+ case int64:
+ numB, ok := b.(uint64)
+ if !ok {
+ return false
+ }
+ return intUintEqual(numA, numB)
+ case uint64:
+ numB, ok := b.(int64)
+ if !ok {
+ return false
+ }
+ return intUintEqual(numB, numA)
+ default:
+ return false
+ }
+}
+
+func intUintEqual(i int64, u uint64) bool {
+ if i < 0 || u > math.MaxInt64 {
+ return false
+ }
+ return i == int64(u)
+}
+
+// Variable returns the variable name associated with the attribute.
+func (a *AttributeTrail) Variable() string {
+ return a.variable
+}
+
+// QualifierPath returns the optional set of qualifying fields or indices applied to the variable.
+func (a *AttributeTrail) QualifierPath() []any {
+ return a.qualifierPath
+}
+
+// String returns the string representation of the Attribute.
+func (a *AttributeTrail) String() string {
+ if a.variable == "" {
+ return ""
+ }
+ var str strings.Builder
+ str.WriteString(a.variable)
+ for _, q := range a.qualifierPath {
+ switch q := q.(type) {
+ case bool, int64:
+ str.WriteString(fmt.Sprintf("[%v]", q))
+ case uint64:
+ str.WriteString(fmt.Sprintf("[%vu]", q))
+ case string:
+ if isIdentifierCharacter(q) {
+ str.WriteString(fmt.Sprintf(".%v", q))
+ } else {
+ str.WriteString(fmt.Sprintf("[%q]", q))
+ }
+ }
+ }
+ return str.String()
+}
+
+func isIdentifierCharacter(str string) bool {
+ for _, c := range str {
+ if unicode.IsLetter(c) || unicode.IsDigit(c) || string(c) == "_" {
+ continue
+ }
+ return false
+ }
+ return true
+}
+
+// AttributeQualifier constrains the possible types which may be used to qualify an attribute.
+type AttributeQualifier interface {
+ bool | int64 | uint64 | string
+}
+
+// QualifyAttribute qualifies an attribute using a valid AttributeQualifier type.
+func QualifyAttribute[T AttributeQualifier](attr *AttributeTrail, qualifier T) *AttributeTrail {
+ attr.qualifierPath = append(attr.qualifierPath, qualifier)
+ return attr
+}
+
+// Unknown type which collects expression ids which caused the current value to become unknown.
+type Unknown struct {
+ attributeTrails map[int64][]*AttributeTrail
+}
+
+// NewUnknown creates a new unknown at a given expression id for an attribute.
+//
+// If the attribute is nil, the attribute value will be the `unspecifiedAttribute`.
+func NewUnknown(id int64, attr *AttributeTrail) *Unknown {
+ if attr == nil {
+ attr = unspecifiedAttribute
+ }
+ return &Unknown{
+ attributeTrails: map[int64][]*AttributeTrail{id: {attr}},
+ }
+}
+
+// IDs returns the set of unknown expression ids contained by this value.
+//
+// Numeric identifiers are guaranteed to be in sorted order.
+func (u *Unknown) IDs() []int64 {
+ ids := make(int64Slice, len(u.attributeTrails))
+ i := 0
+ for id := range u.attributeTrails {
+ ids[i] = id
+ i++
+ }
+ ids.Sort()
+ return ids
+}
+
+// GetAttributeTrails returns the attribute trails, if present, missing for a given expression id.
+func (u *Unknown) GetAttributeTrails(id int64) ([]*AttributeTrail, bool) {
+ trails, found := u.attributeTrails[id]
+ return trails, found
+}
+
+// Contains returns true if the input unknown is a subset of the current unknown.
+func (u *Unknown) Contains(other *Unknown) bool {
+ for id, otherTrails := range other.attributeTrails {
+ trails, found := u.attributeTrails[id]
+ if !found || len(otherTrails) != len(trails) {
+ return false
+ }
+ for _, ot := range otherTrails {
+ found := false
+ for _, t := range trails {
+ if t.Equal(ot) {
+ found = true
+ break
+ }
+ }
+ if !found {
+ return false
+ }
+ }
+ }
+ return true
+}
+
+// ConvertToNative implements ref.Val.ConvertToNative.
+func (u *Unknown) ConvertToNative(typeDesc reflect.Type) (any, error) {
+ return u.Value(), nil
+}
+
+// ConvertToType is an identity function since unknown values cannot be modified.
+func (u *Unknown) ConvertToType(typeVal ref.Type) ref.Val {
+ return u
+}
+
+// Equal is an identity function since unknown values cannot be modified.
+func (u *Unknown) Equal(other ref.Val) ref.Val {
+ return u
+}
+
+// String implements the Stringer interface
+func (u *Unknown) String() string {
+ var str strings.Builder
+ for id, attrs := range u.attributeTrails {
+ if str.Len() != 0 {
+ str.WriteString(", ")
+ }
+ if len(attrs) == 1 {
+ str.WriteString(fmt.Sprintf("%v (%d)", attrs[0], id))
+ } else {
+ str.WriteString(fmt.Sprintf("%v (%d)", attrs, id))
+ }
+ }
+ return str.String()
+}
+
+// Type implements ref.Val.Type.
+func (u *Unknown) Type() ref.Type {
+ return UnknownType
+}
+
+// Value implements ref.Val.Value.
+func (u *Unknown) Value() any {
+ return u
+}
+
+// IsUnknown returns whether the element ref.Val is in instance of *types.Unknown
+func IsUnknown(val ref.Val) bool {
+ switch val.(type) {
+ case *Unknown:
+ return true
+ default:
+ return false
+ }
+}
+
+// MaybeMergeUnknowns determines whether an input value and another, possibly nil, unknown will produce
+// an unknown result.
+//
+// If the input `val` is another Unknown, then the result will be the merge of the `val` and the input
+// `unk`. If the `val` is not unknown, then the result will depend on whether the input `unk` is nil.
+// If both values are non-nil and unknown, then the return value will be a merge of both unknowns.
+func MaybeMergeUnknowns(val ref.Val, unk *Unknown) (*Unknown, bool) {
+ src, isUnk := val.(*Unknown)
+ if !isUnk {
+ if unk != nil {
+ return unk, true
+ }
+ return unk, false
+ }
+ return MergeUnknowns(src, unk), true
+}
+
+// MergeUnknowns combines two unknown values into a new unknown value.
+func MergeUnknowns(unk1, unk2 *Unknown) *Unknown {
+ if unk1 == nil {
+ return unk2
+ }
+ if unk2 == nil {
+ return unk1
+ }
+ out := &Unknown{
+ attributeTrails: make(map[int64][]*AttributeTrail, len(unk1.attributeTrails)+len(unk2.attributeTrails)),
+ }
+ for id, ats := range unk1.attributeTrails {
+ out.attributeTrails[id] = ats
+ }
+ for id, ats := range unk2.attributeTrails {
+ existing, found := out.attributeTrails[id]
+ if !found {
+ out.attributeTrails[id] = ats
+ continue
+ }
+
+ for _, at := range ats {
+ found := false
+ for _, et := range existing {
+ if at.Equal(et) {
+ found = true
+ break
+ }
+ }
+ if !found {
+ existing = append(existing, at)
+ }
+ }
+ out.attributeTrails[id] = existing
+ }
+ return out
+}
+
+// int64Slice is an implementation of the sort.Interface
+type int64Slice []int64
+
+// Len returns the number of elements in the slice.
+func (x int64Slice) Len() int { return len(x) }
+
+// Less indicates whether the value at index i is less than the value at index j.
+func (x int64Slice) Less(i, j int) bool { return x[i] < x[j] }
+
+// Swap swaps the values at indices i and j in place.
+func (x int64Slice) Swap(i, j int) { x[i], x[j] = x[j], x[i] }
+
+// Sort is a convenience method: x.Sort() calls Sort(x).
+func (x int64Slice) Sort() { sort.Sort(x) }
diff --git a/vendor/github.com/google/cel-go/common/types/util.go b/vendor/github.com/google/cel-go/common/types/util.go
new file mode 100644
index 000000000000..71662eee31b7
--- /dev/null
+++ b/vendor/github.com/google/cel-go/common/types/util.go
@@ -0,0 +1,48 @@
+// Copyright 2018 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package types
+
+import (
+ "github.com/google/cel-go/common/types/ref"
+)
+
+// IsUnknownOrError returns whether the input element ref.Val is an ErrType or UnknownType.
+func IsUnknownOrError(val ref.Val) bool {
+ switch val.(type) {
+ case *Unknown, *Err:
+ return true
+ }
+ return false
+}
+
+// IsPrimitiveType returns whether the input element ref.Val is a primitive type.
+// Note, primitive types do not include well-known types such as Duration and Timestamp.
+func IsPrimitiveType(val ref.Val) bool {
+ switch val.Type() {
+ case BoolType, BytesType, DoubleType, IntType, StringType, UintType:
+ return true
+ }
+ return false
+}
+
+// Equal returns whether the two ref.Value are heterogeneously equivalent.
+func Equal(lhs ref.Val, rhs ref.Val) ref.Val {
+ lNull := lhs == NullValue
+ rNull := rhs == NullValue
+ if lNull || rNull {
+ return Bool(lNull == rNull)
+ }
+ return lhs.Equal(rhs)
+}
diff --git a/vendor/github.com/google/cel-go/ext/BUILD.bazel b/vendor/github.com/google/cel-go/ext/BUILD.bazel
new file mode 100644
index 000000000000..9d694e775b47
--- /dev/null
+++ b/vendor/github.com/google/cel-go/ext/BUILD.bazel
@@ -0,0 +1,41 @@
+load("@io_bazel_rules_go//go:def.bzl", "go_library")
+
+package(
+ licenses = ["notice"], # Apache 2.0
+)
+
+go_library(
+ name = "go_default_library",
+ srcs = [
+ "bindings.go",
+ "encoders.go",
+ "formatting.go",
+ "guards.go",
+ "lists.go",
+ "math.go",
+ "native.go",
+ "protos.go",
+ "sets.go",
+ "strings.go",
+ ],
+ importmap = "kubevirt.io/kubevirt/vendor/github.com/google/cel-go/ext",
+ importpath = "github.com/google/cel-go/ext",
+ visibility = ["//visibility:public"],
+ deps = [
+ "//vendor/github.com/google/cel-go/cel:go_default_library",
+ "//vendor/github.com/google/cel-go/checker:go_default_library",
+ "//vendor/github.com/google/cel-go/common/ast:go_default_library",
+ "//vendor/github.com/google/cel-go/common/operators:go_default_library",
+ "//vendor/github.com/google/cel-go/common/overloads:go_default_library",
+ "//vendor/github.com/google/cel-go/common/types:go_default_library",
+ "//vendor/github.com/google/cel-go/common/types/pb:go_default_library",
+ "//vendor/github.com/google/cel-go/common/types/ref:go_default_library",
+ "//vendor/github.com/google/cel-go/common/types/traits:go_default_library",
+ "//vendor/github.com/google/cel-go/interpreter:go_default_library",
+ "//vendor/golang.org/x/text/language:go_default_library",
+ "//vendor/golang.org/x/text/message:go_default_library",
+ "//vendor/google.golang.org/protobuf/proto:go_default_library",
+ "//vendor/google.golang.org/protobuf/reflect/protoreflect:go_default_library",
+ "//vendor/google.golang.org/protobuf/types/known/structpb:go_default_library",
+ ],
+)
diff --git a/vendor/github.com/google/cel-go/ext/README.md b/vendor/github.com/google/cel-go/ext/README.md
new file mode 100644
index 000000000000..a55f56de1236
--- /dev/null
+++ b/vendor/github.com/google/cel-go/ext/README.md
@@ -0,0 +1,669 @@
+# Extensions
+
+CEL extensions are a related set of constants, functions, macros, or other
+features which may not be covered by the core CEL spec.
+
+## Bindings
+
+Returns a cel.EnvOption to configure support for local variable bindings
+in expressions.
+
+# Cel.Bind
+
+Binds a simple identifier to an initialization expression which may be used
+in a subsequenct result expression. Bindings may also be nested within each
+other.
+
+ cel.bind(, , )
+
+Examples:
+
+ cel.bind(a, 'hello',
+ cel.bind(b, 'world', a + b + b + a)) // "helloworldworldhello"
+
+ // Avoid a list allocation within the exists comprehension.
+ cel.bind(valid_values, [a, b, c],
+ [d, e, f].exists(elem, elem in valid_values))
+
+Local bindings are not guaranteed to be evaluated before use.
+
+## Encoders
+
+Encoding utilies for marshalling data into standardized representations.
+
+### Base64.Decode
+
+Decodes base64-encoded string to bytes.
+
+This function will return an error if the string input is not
+base64-encoded.
+
+ base64.decode() ->
+
+Examples:
+
+ base64.decode('aGVsbG8=') // return b'hello'
+ base64.decode('aGVsbG8') // error
+
+### Base64.Encode
+
+Encodes bytes to a base64-encoded string.
+
+ base64.encode() ->
+
+Example:
+
+ base64.encode(b'hello') // return 'aGVsbG8='
+
+## Math
+
+Math helper macros and functions.
+
+Note, all macros use the 'math' namespace; however, at the time of macro
+expansion the namespace looks just like any other identifier. If you are
+currently using a variable named 'math', the macro will likely work just as
+intended; however, there is some chance for collision.
+
+### Math.Greatest
+
+Returns the greatest valued number present in the arguments to the macro.
+
+Greatest is a variable argument count macro which must take at least one
+argument. Simple numeric and list literals are supported as valid argument
+types; however, other literals will be flagged as errors during macro
+expansion. If the argument expression does not resolve to a numeric or
+list(numeric) type during type-checking, or during runtime then an error
+will be produced. If a list argument is empty, this too will produce an
+error.
+
+ math.greatest(, ...) ->
+
+Examples:
+
+ math.greatest(1) // 1
+ math.greatest(1u, 2u) // 2u
+ math.greatest(-42.0, -21.5, -100.0) // -21.5
+ math.greatest([-42.0, -21.5, -100.0]) // -21.5
+ math.greatest(numbers) // numbers must be list(numeric)
+
+ math.greatest() // parse error
+ math.greatest('string') // parse error
+ math.greatest(a, b) // check-time error if a or b is non-numeric
+ math.greatest(dyn('string')) // runtime error
+
+### Math.Least
+
+Returns the least valued number present in the arguments to the macro.
+
+Least is a variable argument count macro which must take at least one
+argument. Simple numeric and list literals are supported as valid argument
+types; however, other literals will be flagged as errors during macro
+expansion. If the argument expression does not resolve to a numeric or
+list(numeric) type during type-checking, or during runtime then an error
+will be produced. If a list argument is empty, this too will produce an
+error.
+
+ math.least(, ...) ->
+
+Examples:
+
+ math.least(1) // 1
+ math.least(1u, 2u) // 1u
+ math.least(-42.0, -21.5, -100.0) // -100.0
+ math.least([-42.0, -21.5, -100.0]) // -100.0
+ math.least(numbers) // numbers must be list(numeric)
+
+ math.least() // parse error
+ math.least('string') // parse error
+ math.least(a, b) // check-time error if a or b is non-numeric
+ math.least(dyn('string')) // runtime error
+
+### Math.BitOr
+
+Introduced at version: 1
+
+Performs a bitwise-OR operation over two int or uint values.
+
+ math.bitOr(, ) ->
+ math.bitOr(, ) ->
+
+Examples:
+
+ math.bitOr(1u, 2u) // returns 3u
+ math.bitOr(-2, -4) // returns -2
+
+### Math.BitAnd
+
+Introduced at version: 1
+
+Performs a bitwise-AND operation over two int or uint values.
+
+ math.bitAnd(, ) ->
+ math.bitAnd(, ) ->
+
+Examples:
+
+ math.bitAnd(3u, 2u) // return 2u
+ math.bitAnd(3, 5) // returns 3
+ math.bitAnd(-3, -5) // returns -7
+
+### Math.BitXor
+
+Introduced at version: 1
+
+ math.bitXor(, ) ->
+ math.bitXor(, ) ->
+
+Performs a bitwise-XOR operation over two int or uint values.
+
+Examples:
+
+ math.bitXor(3u, 5u) // returns 6u
+ math.bitXor(1, 3) // returns 2
+
+### Math.BitNot
+
+Introduced at version: 1
+
+Function which accepts a single int or uint and performs a bitwise-NOT
+ones-complement of the given binary value.
+
+ math.bitNot() ->
+ math.bitNot() ->
+
+Examples
+
+ math.bitNot(1) // returns -1
+ math.bitNot(-1) // return 0
+ math.bitNot(0u) // returns 18446744073709551615u
+
+### Math.BitShiftLeft
+
+Introduced at version: 1
+
+Perform a left shift of bits on the first parameter, by the amount of bits
+specified in the second parameter. The first parameter is either a uint or
+an int. The second parameter must be an int.
+
+When the second parameter is 64 or greater, 0 will be always be returned
+since the number of bits shifted is greater than or equal to the total bit
+length of the number being shifted. Negative valued bit shifts will result
+in a runtime error.
+
+ math.bitShiftLeft(, ) ->
+ math.bitShiftLeft(, ) ->
+
+Examples
+
+ math.bitShiftLeft(1, 2) // returns 4
+ math.bitShiftLeft(-1, 2) // returns -4
+ math.bitShiftLeft(1u, 2) // return 4u
+ math.bitShiftLeft(1u, 200) // returns 0u
+
+### Math.BitShiftRight
+
+Introduced at version: 1
+
+Perform a right shift of bits on the first parameter, by the amount of bits
+specified in the second parameter. The first parameter is either a uint or
+an int. The second parameter must be an int.
+
+When the second parameter is 64 or greater, 0 will always be returned since
+the number of bits shifted is greater than or equal to the total bit length
+of the number being shifted. Negative valued bit shifts will result in a
+runtime error.
+
+The sign bit extension will not be preserved for this operation: vacant bits
+on the left are filled with 0.
+
+ math.bitShiftRight(, ) ->
+ math.bitShiftRight(, ) ->
+
+Examples
+
+ math.bitShiftRight(1024, 2) // returns 256
+ math.bitShiftRight(1024u, 2) // returns 256u
+ math.bitShiftRight(1024u, 64) // returns 0u
+
+### Math.Ceil
+
+Introduced at version: 1
+
+Compute the ceiling of a double value.
+
+ math.ceil() ->
+
+Examples:
+
+ math.ceil(1.2) // returns 2.0
+ math.ceil(-1.2) // returns -1.0
+
+### Math.Floor
+
+Introduced at version: 1
+
+Compute the floor of a double value.
+
+ math.floor() ->
+
+Examples:
+
+ math.floor(1.2) // returns 1.0
+ math.floor(-1.2) // returns -2.0
+
+### Math.Round
+
+Introduced at version: 1
+
+Rounds the double value to the nearest whole number with ties rounding away
+from zero, e.g. 1.5 -> 2.0, -1.5 -> -2.0.
+
+ math.round() ->
+
+Examples:
+
+ math.round(1.2) // returns 1.0
+ math.round(1.5) // returns 2.0
+ math.round(-1.5) // returns -2.0
+
+### Math.Trunc
+
+Introduced at version: 1
+
+Truncates the fractional portion of the double value.
+
+ math.trunc() ->
+
+Examples:
+
+ math.trunc(-1.3) // returns -1.0
+ math.trunc(1.3) // returns 1.0
+
+### Math.Abs
+
+Introduced at version: 1
+
+Returns the absolute value of the numeric type provided as input. If the
+value is NaN, the output is NaN. If the input is int64 min, the function
+will result in an overflow error.
+
+ math.abs() ->
+ math.abs() ->
+ math.abs() ->
+
+Examples:
+
+ math.abs(-1) // returns 1
+ math.abs(1) // returns 1
+ math.abs(-9223372036854775808) // overlflow error
+
+### Math.Sign
+
+Introduced at version: 1
+
+Returns the sign of the numeric type, either -1, 0, 1 as an int, double, or
+uint depending on the overload. For floating point values, if NaN is
+provided as input, the output is also NaN. The implementation does not
+differentiate between positive and negative zero.
+
+ math.sign() ->
+ math.sign() ->
+ math.sign() ->
+
+Examples:
+
+ math.sign(-42) // returns -1
+ math.sign(0) // returns 0
+ math.sign(42) // returns 1
+
+### Math.IsInf
+
+Introduced at version: 1
+
+Returns true if the input double value is -Inf or +Inf.
+
+ math.isInf() ->
+
+Examples:
+
+ math.isInf(1.0/0.0) // returns true
+ math.isInf(1.2) // returns false
+
+### Math.IsNaN
+
+Introduced at version: 1
+
+Returns true if the input double value is NaN, false otherwise.
+
+ math.isNaN() ->
+
+Examples:
+
+ math.isNaN(0.0/0.0) // returns true
+ math.isNaN(1.2) // returns false
+
+### Math.IsFinite
+
+Introduced at version: 1
+
+Returns true if the value is a finite number. Equivalent in behavior to:
+!math.isNaN(double) && !math.isInf(double)
+
+ math.isFinite() ->
+
+Examples:
+
+ math.isFinite(0.0/0.0) // returns false
+ math.isFinite(1.2) // returns true
+
+## Protos
+
+Protos configure extended macros and functions for proto manipulation.
+
+Note, all macros use the 'proto' namespace; however, at the time of macro
+expansion the namespace looks just like any other identifier. If you are
+currently using a variable named 'proto', the macro will likely work just as
+you intend; however, there is some chance for collision.
+
+### Protos.GetExt
+
+Macro which generates a select expression that retrieves an extension field
+from the input proto2 syntax message. If the field is not set, the default
+value forthe extension field is returned according to safe-traversal semantics.
+
+ proto.getExt(, ) ->
+
+Example:
+
+ proto.getExt(msg, google.expr.proto2.test.int32_ext) // returns int value
+
+### Protos.HasExt
+
+Macro which generates a test-only select expression that determines whether
+an extension field is set on a proto2 syntax message.
+
+ proto.hasExt(, ) ->
+
+Example:
+
+ proto.hasExt(msg, google.expr.proto2.test.int32_ext) // returns true || false
+
+## Lists
+
+Extended functions for list manipulation. As a general note, all indices are
+zero-based.
+
+### Slice
+
+
+Returns a new sub-list using the indexes provided.
+
+ .slice(, ) ->
+
+Examples:
+
+ [1,2,3,4].slice(1, 3) // return [2, 3]
+ [1,2,3,4].slice(2, 4) // return [3 ,4]
+
+## Sets
+
+Sets provides set relationship tests.
+
+There is no set type within CEL, and while one may be introduced in the
+future, there are cases where a `list` type is known to behave like a set.
+For such cases, this library provides some basic functionality for
+determining set containment, equivalence, and intersection.
+
+### Sets.Contains
+
+Returns whether the first list argument contains all elements in the second
+list argument. The list may contain elements of any type and standard CEL
+equality is used to determine whether a value exists in both lists. If the
+second list is empty, the result will always return true.
+
+ sets.contains(list(T), list(T)) -> bool
+
+Examples:
+
+ sets.contains([], []) // true
+ sets.contains([], [1]) // false
+ sets.contains([1, 2, 3, 4], [2, 3]) // true
+ sets.contains([1, 2.0, 3u], [1.0, 2u, 3]) // true
+
+### Sets.Equivalent
+
+Returns whether the first and second list are set equivalent. Lists are set
+equivalent if for every item in the first list, there is an element in the
+second which is equal. The lists may not be of the same size as they do not
+guarantee the elements within them are unique, so size does not factor into
+the computation.
+
+ sets.equivalent(list(T), list(T)) -> bool
+
+Examples:
+
+ sets.equivalent([], []) // true
+ sets.equivalent([1], [1, 1]) // true
+ sets.equivalent([1], [1u, 1.0]) // true
+ sets.equivalent([1, 2, 3], [3u, 2.0, 1]) // true
+
+### Sets.Intersects
+
+Returns whether the first list has at least one element whose value is equal
+to an element in the second list. If either list is empty, the result will
+be false.
+
+ sets.intersects(list(T), list(T)) -> bool
+
+Examples:
+
+ sets.intersects([1], []) // false
+ sets.intersects([1], [1, 2]) // true
+ sets.intersects([[1], [2, 3]], [[1, 2], [2, 3.0]]) // true
+
+## Strings
+
+Extended functions for string manipulation. As a general note, all indices are
+zero-based.
+
+### CharAt
+
+Returns the character at the given position. If the position is negative, or
+greater than the length of the string, the function will produce an error:
+
+ .charAt() ->
+
+Examples:
+
+ 'hello'.charAt(4) // return 'o'
+ 'hello'.charAt(5) // return ''
+ 'hello'.charAt(-1) // error
+
+### IndexOf
+
+Returns the integer index of the first occurrence of the search string. If the
+search string is not found the function returns -1.
+
+The function also accepts an optional position from which to begin the
+substring search. If the substring is the empty string, the index where the
+search starts is returned (zero or custom).
+
+ .indexOf() ->
+ .indexOf(, ) ->
+
+Examples:
+
+ 'hello mellow'.indexOf('') // returns 0
+ 'hello mellow'.indexOf('ello') // returns 1
+ 'hello mellow'.indexOf('jello') // returns -1
+ 'hello mellow'.indexOf('', 2) // returns 2
+ 'hello mellow'.indexOf('ello', 2) // returns 7
+ 'hello mellow'.indexOf('ello', 20) // error
+
+### Join
+
+Returns a new string where the elements of string list are concatenated.
+
+The function also accepts an optional separator which is placed between
+elements in the resulting string.
+
+ >.join() ->
+ >.join() ->
+
+Examples:
+
+ ['hello', 'mellow'].join() // returns 'hellomellow'
+ ['hello', 'mellow'].join(' ') // returns 'hello mellow'
+ [].join() // returns ''
+ [].join('/') // returns ''
+
+### LastIndexOf
+
+Returns the integer index of the last occurrence of the search string. If the
+search string is not found the function returns -1.
+
+The function also accepts an optional position which represents the last index
+to be considered as the beginning of the substring match. If the substring is
+the empty string, the index where the search starts is returned (string length
+or custom).
+
+ .lastIndexOf() ->
+ .lastIndexOf(, ) ->
+
+Examples:
+
+ 'hello mellow'.lastIndexOf('') // returns 12
+ 'hello mellow'.lastIndexOf('ello') // returns 7
+ 'hello mellow'.lastIndexOf('jello') // returns -1
+ 'hello mellow'.lastIndexOf('ello', 6) // returns 1
+ 'hello mellow'.lastIndexOf('ello', -1) // error
+
+### LowerAscii
+
+Returns a new string where all ASCII characters are lower-cased.
+
+This function does not perform Unicode case-mapping for characters outside the
+ASCII range.
+
+ .lowerAscii() ->
+
+Examples:
+
+ 'TacoCat'.lowerAscii() // returns 'tacocat'
+ 'TacoCÆt Xii'.lowerAscii() // returns 'tacocÆt xii'
+
+### Quote
+
+**Introduced in version 1**
+
+Takes the given string and makes it safe to print (without any formatting due to escape sequences).
+If any invalid UTF-8 characters are encountered, they are replaced with \uFFFD.
+
+ strings.quote()
+
+Examples:
+
+ strings.quote('single-quote with "double quote"') // returns '"single-quote with \"double quote\""'
+ strings.quote("two escape sequences \a\n") // returns '"two escape sequences \\a\\n"'
+
+### Replace
+
+Returns a new string based on the target, which replaces the occurrences of a
+search string with a replacement string if present. The function accepts an
+optional limit on the number of substring replacements to be made.
+
+When the replacement limit is 0, the result is the original string. When the
+limit is a negative number, the function behaves the same as replace all.
+
+ .replace(, ) ->
+ .replace(, , ) ->
+
+Examples:
+
+ 'hello hello'.replace('he', 'we') // returns 'wello wello'
+ 'hello hello'.replace('he', 'we', -1) // returns 'wello wello'
+ 'hello hello'.replace('he', 'we', 1) // returns 'wello hello'
+ 'hello hello'.replace('he', 'we', 0) // returns 'hello hello'
+
+### Split
+
+Returns a list of strings split from the input by the given separator. The
+function accepts an optional argument specifying a limit on the number of
+substrings produced by the split.
+
+When the split limit is 0, the result is an empty list. When the limit is 1,
+the result is the target string to split. When the limit is a negative
+number, the function behaves the same as split all.
+
+ .split() -> >
+ .split(, ) -> >
+
+Examples:
+
+ 'hello hello hello'.split(' ') // returns ['hello', 'hello', 'hello']
+ 'hello hello hello'.split(' ', 0) // returns []
+ 'hello hello hello'.split(' ', 1) // returns ['hello hello hello']
+ 'hello hello hello'.split(' ', 2) // returns ['hello', 'hello hello']
+ 'hello hello hello'.split(' ', -1) // returns ['hello', 'hello', 'hello']
+
+### Substring
+
+Returns the substring given a numeric range corresponding to character
+positions. Optionally may omit the trailing range for a substring from a given
+character position until the end of a string.
+
+Character offsets are 0-based with an inclusive start range and exclusive end
+range. It is an error to specify an end range that is lower than the start
+range, or for either the start or end index to be negative or exceed the string
+length.
+
+ .substring() ->
+ .substring(, ) ->
+
+Examples:
+
+ 'tacocat'.substring(4) // returns 'cat'
+ 'tacocat'.substring(0, 4) // returns 'taco'
+ 'tacocat'.substring(-1) // error
+ 'tacocat'.substring(2, 1) // error
+
+### Trim
+
+Returns a new string which removes the leading and trailing whitespace in the
+target string. The trim function uses the Unicode definition of whitespace
+which does not include the zero-width spaces. See:
+https://en.wikipedia.org/wiki/Whitespace_character#Unicode
+
+ .trim() ->
+
+Examples:
+
+ ' \ttrim\n '.trim() // returns 'trim'
+
+### UpperAscii
+
+Returns a new string where all ASCII characters are upper-cased.
+
+This function does not perform Unicode case-mapping for characters outside the
+ASCII range.
+
+ .upperAscii() ->
+
+Examples:
+
+ 'TacoCat'.upperAscii() // returns 'TACOCAT'
+ 'TacoCÆt Xii'.upperAscii() // returns 'TACOCÆT XII'
+
+### Reverse
+
+Returns a new string whose characters are the same as the target string, only formatted in
+reverse order.
+This function relies on converting strings to rune arrays in order to reverse.
+It can be located in Version 3 of strings.
+
+ .reverse() ->
+
+Examples:
+
+ 'gums'.reverse() // returns 'smug'
+ 'John Smith'.reverse() // returns 'htimS nhoJ'
\ No newline at end of file
diff --git a/vendor/github.com/google/cel-go/ext/bindings.go b/vendor/github.com/google/cel-go/ext/bindings.go
new file mode 100644
index 000000000000..2c6cc627fab4
--- /dev/null
+++ b/vendor/github.com/google/cel-go/ext/bindings.go
@@ -0,0 +1,96 @@
+// Copyright 2023 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package ext
+
+import (
+ "github.com/google/cel-go/cel"
+ "github.com/google/cel-go/common/ast"
+ "github.com/google/cel-go/common/types"
+)
+
+// Bindings returns a cel.EnvOption to configure support for local variable
+// bindings in expressions.
+//
+// # Cel.Bind
+//
+// Binds a simple identifier to an initialization expression which may be used
+// in a subsequenct result expression. Bindings may also be nested within each
+// other.
+//
+// cel.bind(, , )
+//
+// Examples:
+//
+// cel.bind(a, 'hello',
+// cel.bind(b, 'world', a + b + b + a)) // "helloworldworldhello"
+//
+// // Avoid a list allocation within the exists comprehension.
+// cel.bind(valid_values, [a, b, c],
+// [d, e, f].exists(elem, elem in valid_values))
+//
+// Local bindings are not guaranteed to be evaluated before use.
+func Bindings() cel.EnvOption {
+ return cel.Lib(celBindings{})
+}
+
+const (
+ celNamespace = "cel"
+ bindMacro = "bind"
+ unusedIterVar = "#unused"
+)
+
+type celBindings struct{}
+
+func (celBindings) LibraryName() string {
+ return "cel.lib.ext.cel.bindings"
+}
+
+func (celBindings) CompileOptions() []cel.EnvOption {
+ return []cel.EnvOption{
+ cel.Macros(
+ // cel.bind(var, , )
+ cel.ReceiverMacro(bindMacro, 3, celBind),
+ ),
+ }
+}
+
+func (celBindings) ProgramOptions() []cel.ProgramOption {
+ return []cel.ProgramOption{}
+}
+
+func celBind(mef cel.MacroExprFactory, target ast.Expr, args []ast.Expr) (ast.Expr, *cel.Error) {
+ if !macroTargetMatchesNamespace(celNamespace, target) {
+ return nil, nil
+ }
+ varIdent := args[0]
+ varName := ""
+ switch varIdent.Kind() {
+ case ast.IdentKind:
+ varName = varIdent.AsIdent()
+ default:
+ return nil, mef.NewError(varIdent.ID(), "cel.bind() variable names must be simple identifiers")
+ }
+ varInit := args[1]
+ resultExpr := args[2]
+ return mef.NewComprehension(
+ mef.NewList(),
+ unusedIterVar,
+ varName,
+ varInit,
+ mef.NewLiteral(types.False),
+ mef.NewIdent(varName),
+ resultExpr,
+ ), nil
+}
diff --git a/vendor/github.com/google/cel-go/ext/encoders.go b/vendor/github.com/google/cel-go/ext/encoders.go
new file mode 100644
index 000000000000..61ac0b777507
--- /dev/null
+++ b/vendor/github.com/google/cel-go/ext/encoders.go
@@ -0,0 +1,87 @@
+// Copyright 2020 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package ext
+
+import (
+ "encoding/base64"
+
+ "github.com/google/cel-go/cel"
+ "github.com/google/cel-go/common/types"
+ "github.com/google/cel-go/common/types/ref"
+)
+
+// Encoders returns a cel.EnvOption to configure extended functions for string, byte, and object
+// encodings.
+//
+// # Base64.Decode
+//
+// Decodes base64-encoded string to bytes.
+//
+// This function will return an error if the string input is not base64-encoded.
+//
+// base64.decode() ->
+//
+// Examples:
+//
+// base64.decode('aGVsbG8=') // return b'hello'
+// base64.decode('aGVsbG8') // error
+//
+// # Base64.Encode
+//
+// Encodes bytes to a base64-encoded string.
+//
+// base64.encode() ->
+//
+// Examples:
+//
+// base64.encode(b'hello') // return b'aGVsbG8='
+func Encoders() cel.EnvOption {
+ return cel.Lib(encoderLib{})
+}
+
+type encoderLib struct{}
+
+func (encoderLib) LibraryName() string {
+ return "cel.lib.ext.encoders"
+}
+
+func (encoderLib) CompileOptions() []cel.EnvOption {
+ return []cel.EnvOption{
+ cel.Function("base64.decode",
+ cel.Overload("base64_decode_string", []*cel.Type{cel.StringType}, cel.BytesType,
+ cel.UnaryBinding(func(str ref.Val) ref.Val {
+ s := str.(types.String)
+ return bytesOrError(base64DecodeString(string(s)))
+ }))),
+ cel.Function("base64.encode",
+ cel.Overload("base64_encode_bytes", []*cel.Type{cel.BytesType}, cel.StringType,
+ cel.UnaryBinding(func(bytes ref.Val) ref.Val {
+ b := bytes.(types.Bytes)
+ return stringOrError(base64EncodeBytes([]byte(b)))
+ }))),
+ }
+}
+
+func (encoderLib) ProgramOptions() []cel.ProgramOption {
+ return []cel.ProgramOption{}
+}
+
+func base64DecodeString(str string) ([]byte, error) {
+ return base64.StdEncoding.DecodeString(str)
+}
+
+func base64EncodeBytes(bytes []byte) (string, error) {
+ return base64.StdEncoding.EncodeToString(bytes), nil
+}
diff --git a/vendor/github.com/google/cel-go/ext/formatting.go b/vendor/github.com/google/cel-go/ext/formatting.go
new file mode 100644
index 000000000000..dbff613b2aab
--- /dev/null
+++ b/vendor/github.com/google/cel-go/ext/formatting.go
@@ -0,0 +1,904 @@
+// Copyright 2023 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package ext
+
+import (
+ "errors"
+ "fmt"
+ "math"
+ "sort"
+ "strconv"
+ "strings"
+ "unicode"
+
+ "golang.org/x/text/language"
+ "golang.org/x/text/message"
+
+ "github.com/google/cel-go/cel"
+ "github.com/google/cel-go/common/ast"
+ "github.com/google/cel-go/common/overloads"
+ "github.com/google/cel-go/common/types"
+ "github.com/google/cel-go/common/types/ref"
+ "github.com/google/cel-go/common/types/traits"
+)
+
+type clauseImpl func(ref.Val, string) (string, error)
+
+func clauseForType(argType ref.Type) (clauseImpl, error) {
+ switch argType {
+ case types.IntType, types.UintType:
+ return formatDecimal, nil
+ case types.StringType, types.BytesType, types.BoolType, types.NullType, types.TypeType:
+ return FormatString, nil
+ case types.TimestampType, types.DurationType:
+ // special case to ensure timestamps/durations get printed as CEL literals
+ return func(arg ref.Val, locale string) (string, error) {
+ argStrVal := arg.ConvertToType(types.StringType)
+ argStr := argStrVal.Value().(string)
+ if arg.Type() == types.TimestampType {
+ return fmt.Sprintf("timestamp(%q)", argStr), nil
+ }
+ if arg.Type() == types.DurationType {
+ return fmt.Sprintf("duration(%q)", argStr), nil
+ }
+ return "", fmt.Errorf("cannot convert argument of type %s to timestamp/duration", arg.Type().TypeName())
+ }, nil
+ case types.ListType:
+ return formatList, nil
+ case types.MapType:
+ return formatMap, nil
+ case types.DoubleType:
+ // avoid formatFixed so we can output a period as the decimal separator in order
+ // to always be a valid CEL literal
+ return func(arg ref.Val, locale string) (string, error) {
+ argDouble, ok := arg.Value().(float64)
+ if !ok {
+ return "", fmt.Errorf("couldn't convert %s to float64", arg.Type().TypeName())
+ }
+ fmtStr := fmt.Sprintf("%%.%df", defaultPrecision)
+ return fmt.Sprintf(fmtStr, argDouble), nil
+ }, nil
+ case types.TypeType:
+ return func(arg ref.Val, locale string) (string, error) {
+ return fmt.Sprintf("type(%s)", arg.Value().(string)), nil
+ }, nil
+ default:
+ return nil, fmt.Errorf("no formatting function for %s", argType.TypeName())
+ }
+}
+
+func formatList(arg ref.Val, locale string) (string, error) {
+ argList := arg.(traits.Lister)
+ argIterator := argList.Iterator()
+ var listStrBuilder strings.Builder
+ _, err := listStrBuilder.WriteRune('[')
+ if err != nil {
+ return "", fmt.Errorf("error writing to list string: %w", err)
+ }
+ for argIterator.HasNext() == types.True {
+ member := argIterator.Next()
+ memberFormat, err := clauseForType(member.Type())
+ if err != nil {
+ return "", err
+ }
+ unquotedStr, err := memberFormat(member, locale)
+ if err != nil {
+ return "", err
+ }
+ str := quoteForCEL(member, unquotedStr)
+ _, err = listStrBuilder.WriteString(str)
+ if err != nil {
+ return "", fmt.Errorf("error writing to list string: %w", err)
+ }
+ if argIterator.HasNext() == types.True {
+ _, err = listStrBuilder.WriteString(", ")
+ if err != nil {
+ return "", fmt.Errorf("error writing to list string: %w", err)
+ }
+ }
+ }
+ _, err = listStrBuilder.WriteRune(']')
+ if err != nil {
+ return "", fmt.Errorf("error writing to list string: %w", err)
+ }
+ return listStrBuilder.String(), nil
+}
+
+func formatMap(arg ref.Val, locale string) (string, error) {
+ argMap := arg.(traits.Mapper)
+ argIterator := argMap.Iterator()
+ type mapPair struct {
+ key string
+ value string
+ }
+ argPairs := make([]mapPair, argMap.Size().Value().(int64))
+ i := 0
+ for argIterator.HasNext() == types.True {
+ key := argIterator.Next()
+ var keyFormat clauseImpl
+ switch key.Type() {
+ case types.StringType, types.BoolType:
+ keyFormat = FormatString
+ case types.IntType, types.UintType:
+ keyFormat = formatDecimal
+ default:
+ return "", fmt.Errorf("no formatting function for map key of type %s", key.Type().TypeName())
+ }
+ unquotedKeyStr, err := keyFormat(key, locale)
+ if err != nil {
+ return "", err
+ }
+ keyStr := quoteForCEL(key, unquotedKeyStr)
+ value, found := argMap.Find(key)
+ if !found {
+ return "", fmt.Errorf("could not find key: %q", key)
+ }
+ valueFormat, err := clauseForType(value.Type())
+ if err != nil {
+ return "", err
+ }
+ unquotedValueStr, err := valueFormat(value, locale)
+ if err != nil {
+ return "", err
+ }
+ valueStr := quoteForCEL(value, unquotedValueStr)
+ argPairs[i] = mapPair{keyStr, valueStr}
+ i++
+ }
+ sort.SliceStable(argPairs, func(x, y int) bool {
+ return argPairs[x].key < argPairs[y].key
+ })
+ var mapStrBuilder strings.Builder
+ _, err := mapStrBuilder.WriteRune('{')
+ if err != nil {
+ return "", fmt.Errorf("error writing to map string: %w", err)
+ }
+ for i, entry := range argPairs {
+ _, err = mapStrBuilder.WriteString(fmt.Sprintf("%s:%s", entry.key, entry.value))
+ if err != nil {
+ return "", fmt.Errorf("error writing to map string: %w", err)
+ }
+ if i < len(argPairs)-1 {
+ _, err = mapStrBuilder.WriteString(", ")
+ if err != nil {
+ return "", fmt.Errorf("error writing to map string: %w", err)
+ }
+ }
+ }
+ _, err = mapStrBuilder.WriteRune('}')
+ if err != nil {
+ return "", fmt.Errorf("error writing to map string: %w", err)
+ }
+ return mapStrBuilder.String(), nil
+}
+
+// quoteForCEL takes a formatted, unquoted value and quotes it in a manner suitable
+// for embedding directly in CEL.
+func quoteForCEL(refVal ref.Val, unquotedValue string) string {
+ switch refVal.Type() {
+ case types.StringType:
+ return fmt.Sprintf("%q", unquotedValue)
+ case types.BytesType:
+ return fmt.Sprintf("b%q", unquotedValue)
+ case types.DoubleType:
+ // special case to handle infinity/NaN
+ num := refVal.Value().(float64)
+ if math.IsInf(num, 1) || math.IsInf(num, -1) || math.IsNaN(num) {
+ return fmt.Sprintf("%q", unquotedValue)
+ }
+ return unquotedValue
+ default:
+ return unquotedValue
+ }
+}
+
+// FormatString returns the string representation of a CEL value.
+//
+// It is used to implement the %s specifier in the (string).format() extension function.
+func FormatString(arg ref.Val, locale string) (string, error) {
+ switch arg.Type() {
+ case types.ListType:
+ return formatList(arg, locale)
+ case types.MapType:
+ return formatMap(arg, locale)
+ case types.IntType, types.UintType, types.DoubleType,
+ types.BoolType, types.StringType, types.TimestampType, types.BytesType, types.DurationType, types.TypeType:
+ argStrVal := arg.ConvertToType(types.StringType)
+ argStr, ok := argStrVal.Value().(string)
+ if !ok {
+ return "", fmt.Errorf("could not convert argument %q to string", argStrVal)
+ }
+ return argStr, nil
+ case types.NullType:
+ return "null", nil
+ default:
+ return "", stringFormatError(runtimeID, arg.Type().TypeName())
+ }
+}
+
+func formatDecimal(arg ref.Val, locale string) (string, error) {
+ switch arg.Type() {
+ case types.IntType:
+ argInt, ok := arg.ConvertToType(types.IntType).Value().(int64)
+ if !ok {
+ return "", fmt.Errorf("could not convert \"%s\" to int64", arg.Value())
+ }
+ return fmt.Sprintf("%d", argInt), nil
+ case types.UintType:
+ argInt, ok := arg.ConvertToType(types.UintType).Value().(uint64)
+ if !ok {
+ return "", fmt.Errorf("could not convert \"%s\" to uint64", arg.Value())
+ }
+ return fmt.Sprintf("%d", argInt), nil
+ default:
+ return "", decimalFormatError(runtimeID, arg.Type().TypeName())
+ }
+}
+
+func matchLanguage(locale string) (language.Tag, error) {
+ matcher, err := makeMatcher(locale)
+ if err != nil {
+ return language.Und, err
+ }
+ tag, _ := language.MatchStrings(matcher, locale)
+ return tag, nil
+}
+
+func makeMatcher(locale string) (language.Matcher, error) {
+ tags := make([]language.Tag, 0)
+ tag, err := language.Parse(locale)
+ if err != nil {
+ return nil, err
+ }
+ tags = append(tags, tag)
+ return language.NewMatcher(tags), nil
+}
+
+type stringFormatter struct{}
+
+func (c *stringFormatter) String(arg ref.Val, locale string) (string, error) {
+ return FormatString(arg, locale)
+}
+
+func (c *stringFormatter) Decimal(arg ref.Val, locale string) (string, error) {
+ return formatDecimal(arg, locale)
+}
+
+func (c *stringFormatter) Fixed(precision *int) func(ref.Val, string) (string, error) {
+ if precision == nil {
+ precision = new(int)
+ *precision = defaultPrecision
+ }
+ return func(arg ref.Val, locale string) (string, error) {
+ strException := false
+ if arg.Type() == types.StringType {
+ argStr := arg.Value().(string)
+ if argStr == "NaN" || argStr == "Infinity" || argStr == "-Infinity" {
+ strException = true
+ }
+ }
+ if arg.Type() != types.DoubleType && !strException {
+ return "", fixedPointFormatError(runtimeID, arg.Type().TypeName())
+ }
+ argFloatVal := arg.ConvertToType(types.DoubleType)
+ argFloat, ok := argFloatVal.Value().(float64)
+ if !ok {
+ return "", fmt.Errorf("could not convert \"%s\" to float64", argFloatVal.Value())
+ }
+ fmtStr := fmt.Sprintf("%%.%df", *precision)
+
+ matchedLocale, err := matchLanguage(locale)
+ if err != nil {
+ return "", fmt.Errorf("error matching locale: %w", err)
+ }
+ return message.NewPrinter(matchedLocale).Sprintf(fmtStr, argFloat), nil
+ }
+}
+
+func (c *stringFormatter) Scientific(precision *int) func(ref.Val, string) (string, error) {
+ if precision == nil {
+ precision = new(int)
+ *precision = defaultPrecision
+ }
+ return func(arg ref.Val, locale string) (string, error) {
+ strException := false
+ if arg.Type() == types.StringType {
+ argStr := arg.Value().(string)
+ if argStr == "NaN" || argStr == "Infinity" || argStr == "-Infinity" {
+ strException = true
+ }
+ }
+ if arg.Type() != types.DoubleType && !strException {
+ return "", scientificFormatError(runtimeID, arg.Type().TypeName())
+ }
+ argFloatVal := arg.ConvertToType(types.DoubleType)
+ argFloat, ok := argFloatVal.Value().(float64)
+ if !ok {
+ return "", fmt.Errorf("could not convert \"%v\" to float64", argFloatVal.Value())
+ }
+ matchedLocale, err := matchLanguage(locale)
+ if err != nil {
+ return "", fmt.Errorf("error matching locale: %w", err)
+ }
+ fmtStr := fmt.Sprintf("%%%de", *precision)
+ return message.NewPrinter(matchedLocale).Sprintf(fmtStr, argFloat), nil
+ }
+}
+
+func (c *stringFormatter) Binary(arg ref.Val, locale string) (string, error) {
+ switch arg.Type() {
+ case types.IntType:
+ argInt := arg.Value().(int64)
+ // locale is intentionally unused as integers formatted as binary
+ // strings are locale-independent
+ return fmt.Sprintf("%b", argInt), nil
+ case types.UintType:
+ argInt := arg.Value().(uint64)
+ return fmt.Sprintf("%b", argInt), nil
+ case types.BoolType:
+ argBool := arg.Value().(bool)
+ if argBool {
+ return "1", nil
+ }
+ return "0", nil
+ default:
+ return "", binaryFormatError(runtimeID, arg.Type().TypeName())
+ }
+}
+
+func (c *stringFormatter) Hex(useUpper bool) func(ref.Val, string) (string, error) {
+ return func(arg ref.Val, locale string) (string, error) {
+ fmtStr := "%x"
+ if useUpper {
+ fmtStr = "%X"
+ }
+ switch arg.Type() {
+ case types.StringType, types.BytesType:
+ if arg.Type() == types.BytesType {
+ return fmt.Sprintf(fmtStr, arg.Value().([]byte)), nil
+ }
+ return fmt.Sprintf(fmtStr, arg.Value().(string)), nil
+ case types.IntType:
+ argInt, ok := arg.Value().(int64)
+ if !ok {
+ return "", fmt.Errorf("could not convert \"%s\" to int64", arg.Value())
+ }
+ return fmt.Sprintf(fmtStr, argInt), nil
+ case types.UintType:
+ argInt, ok := arg.Value().(uint64)
+ if !ok {
+ return "", fmt.Errorf("could not convert \"%s\" to uint64", arg.Value())
+ }
+ return fmt.Sprintf(fmtStr, argInt), nil
+ default:
+ return "", hexFormatError(runtimeID, arg.Type().TypeName())
+ }
+ }
+}
+
+func (c *stringFormatter) Octal(arg ref.Val, locale string) (string, error) {
+ switch arg.Type() {
+ case types.IntType:
+ argInt := arg.Value().(int64)
+ return fmt.Sprintf("%o", argInt), nil
+ case types.UintType:
+ argInt := arg.Value().(uint64)
+ return fmt.Sprintf("%o", argInt), nil
+ default:
+ return "", octalFormatError(runtimeID, arg.Type().TypeName())
+ }
+}
+
+// stringFormatValidator implements the cel.ASTValidator interface allowing for static validation
+// of string.format calls.
+type stringFormatValidator struct{}
+
+// Name returns the name of the validator.
+func (stringFormatValidator) Name() string {
+ return "cel.lib.ext.validate.functions.string.format"
+}
+
+// Configure implements the ASTValidatorConfigurer interface and augments the list of functions to skip
+// during homogeneous aggregate literal type-checks.
+func (stringFormatValidator) Configure(config cel.MutableValidatorConfig) error {
+ functions := config.GetOrDefault(cel.HomogeneousAggregateLiteralExemptFunctions, []string{}).([]string)
+ functions = append(functions, "format")
+ return config.Set(cel.HomogeneousAggregateLiteralExemptFunctions, functions)
+}
+
+// Validate parses all literal format strings and type checks the format clause against the argument
+// at the corresponding ordinal within the list literal argument to the function, if one is specified.
+func (stringFormatValidator) Validate(env *cel.Env, _ cel.ValidatorConfig, a *ast.AST, iss *cel.Issues) {
+ root := ast.NavigateAST(a)
+ formatCallExprs := ast.MatchDescendants(root, matchConstantFormatStringWithListLiteralArgs(a))
+ for _, e := range formatCallExprs {
+ call := e.AsCall()
+ formatStr := call.Target().AsLiteral().Value().(string)
+ args := call.Args()[0].AsList().Elements()
+ formatCheck := &stringFormatChecker{
+ args: args,
+ ast: a,
+ }
+ // use a placeholder locale, since locale doesn't affect syntax
+ _, err := parseFormatString(formatStr, formatCheck, formatCheck, "en_US")
+ if err != nil {
+ iss.ReportErrorAtID(getErrorExprID(e.ID(), err), err.Error())
+ continue
+ }
+ seenArgs := formatCheck.argsRequested
+ if len(args) > seenArgs {
+ iss.ReportErrorAtID(e.ID(),
+ "too many arguments supplied to string.format (expected %d, got %d)", seenArgs, len(args))
+ }
+ }
+}
+
+// getErrorExprID determines which list literal argument triggered a type-disagreement for the
+// purposes of more accurate error message reports.
+func getErrorExprID(id int64, err error) int64 {
+ fmtErr, ok := err.(formatError)
+ if ok {
+ return fmtErr.id
+ }
+ wrapped := errors.Unwrap(err)
+ if wrapped != nil {
+ return getErrorExprID(id, wrapped)
+ }
+ return id
+}
+
+// matchConstantFormatStringWithListLiteralArgs matches all valid expression nodes for string
+// format checking.
+func matchConstantFormatStringWithListLiteralArgs(a *ast.AST) ast.ExprMatcher {
+ return func(e ast.NavigableExpr) bool {
+ if e.Kind() != ast.CallKind {
+ return false
+ }
+ call := e.AsCall()
+ if !call.IsMemberFunction() || call.FunctionName() != "format" {
+ return false
+ }
+ overloadIDs := a.GetOverloadIDs(e.ID())
+ if len(overloadIDs) != 0 {
+ found := false
+ for _, overload := range overloadIDs {
+ if overload == overloads.ExtFormatString {
+ found = true
+ break
+ }
+ }
+ if !found {
+ return false
+ }
+ }
+ formatString := call.Target()
+ if formatString.Kind() != ast.LiteralKind || formatString.AsLiteral().Type() != cel.StringType {
+ return false
+ }
+ args := call.Args()
+ if len(args) != 1 {
+ return false
+ }
+ formatArgs := args[0]
+ return formatArgs.Kind() == ast.ListKind
+ }
+}
+
+// stringFormatChecker implements the formatStringInterpolater interface
+type stringFormatChecker struct {
+ args []ast.Expr
+ argsRequested int
+ currArgIndex int64
+ ast *ast.AST
+}
+
+func (c *stringFormatChecker) String(arg ref.Val, locale string) (string, error) {
+ formatArg := c.args[c.currArgIndex]
+ valid, badID := c.verifyString(formatArg)
+ if !valid {
+ return "", stringFormatError(badID, c.typeOf(badID).TypeName())
+ }
+ return "", nil
+}
+
+func (c *stringFormatChecker) Decimal(arg ref.Val, locale string) (string, error) {
+ id := c.args[c.currArgIndex].ID()
+ valid := c.verifyTypeOneOf(id, types.IntType, types.UintType)
+ if !valid {
+ return "", decimalFormatError(id, c.typeOf(id).TypeName())
+ }
+ return "", nil
+}
+
+func (c *stringFormatChecker) Fixed(precision *int) func(ref.Val, string) (string, error) {
+ return func(arg ref.Val, locale string) (string, error) {
+ id := c.args[c.currArgIndex].ID()
+ // we allow StringType since "NaN", "Infinity", and "-Infinity" are also valid values
+ valid := c.verifyTypeOneOf(id, types.DoubleType, types.StringType)
+ if !valid {
+ return "", fixedPointFormatError(id, c.typeOf(id).TypeName())
+ }
+ return "", nil
+ }
+}
+
+func (c *stringFormatChecker) Scientific(precision *int) func(ref.Val, string) (string, error) {
+ return func(arg ref.Val, locale string) (string, error) {
+ id := c.args[c.currArgIndex].ID()
+ valid := c.verifyTypeOneOf(id, types.DoubleType, types.StringType)
+ if !valid {
+ return "", scientificFormatError(id, c.typeOf(id).TypeName())
+ }
+ return "", nil
+ }
+}
+
+func (c *stringFormatChecker) Binary(arg ref.Val, locale string) (string, error) {
+ id := c.args[c.currArgIndex].ID()
+ valid := c.verifyTypeOneOf(id, types.IntType, types.UintType, types.BoolType)
+ if !valid {
+ return "", binaryFormatError(id, c.typeOf(id).TypeName())
+ }
+ return "", nil
+}
+
+func (c *stringFormatChecker) Hex(useUpper bool) func(ref.Val, string) (string, error) {
+ return func(arg ref.Val, locale string) (string, error) {
+ id := c.args[c.currArgIndex].ID()
+ valid := c.verifyTypeOneOf(id, types.IntType, types.UintType, types.StringType, types.BytesType)
+ if !valid {
+ return "", hexFormatError(id, c.typeOf(id).TypeName())
+ }
+ return "", nil
+ }
+}
+
+func (c *stringFormatChecker) Octal(arg ref.Val, locale string) (string, error) {
+ id := c.args[c.currArgIndex].ID()
+ valid := c.verifyTypeOneOf(id, types.IntType, types.UintType)
+ if !valid {
+ return "", octalFormatError(id, c.typeOf(id).TypeName())
+ }
+ return "", nil
+}
+
+func (c *stringFormatChecker) Arg(index int64) (ref.Val, error) {
+ c.argsRequested++
+ c.currArgIndex = index
+ // return a dummy value - this is immediately passed to back to us
+ // through one of the FormatCallback functions, so anything will do
+ return types.Int(0), nil
+}
+
+func (c *stringFormatChecker) Size() int64 {
+ return int64(len(c.args))
+}
+
+func (c *stringFormatChecker) typeOf(id int64) *cel.Type {
+ return c.ast.GetType(id)
+}
+
+func (c *stringFormatChecker) verifyTypeOneOf(id int64, validTypes ...*cel.Type) bool {
+ t := c.typeOf(id)
+ if t == cel.DynType {
+ return true
+ }
+ for _, vt := range validTypes {
+ // Only check runtime type compatibility without delving deeper into parameterized types
+ if t.Kind() == vt.Kind() {
+ return true
+ }
+ }
+ return false
+}
+
+func (c *stringFormatChecker) verifyString(sub ast.Expr) (bool, int64) {
+ paramA := cel.TypeParamType("A")
+ paramB := cel.TypeParamType("B")
+ subVerified := c.verifyTypeOneOf(sub.ID(),
+ cel.ListType(paramA), cel.MapType(paramA, paramB),
+ cel.IntType, cel.UintType, cel.DoubleType, cel.BoolType, cel.StringType,
+ cel.TimestampType, cel.BytesType, cel.DurationType, cel.TypeType, cel.NullType)
+ if !subVerified {
+ return false, sub.ID()
+ }
+ switch sub.Kind() {
+ case ast.ListKind:
+ for _, e := range sub.AsList().Elements() {
+ // recursively verify if we're dealing with a list/map
+ verified, id := c.verifyString(e)
+ if !verified {
+ return false, id
+ }
+ }
+ return true, sub.ID()
+ case ast.MapKind:
+ for _, e := range sub.AsMap().Entries() {
+ // recursively verify if we're dealing with a list/map
+ entry := e.AsMapEntry()
+ verified, id := c.verifyString(entry.Key())
+ if !verified {
+ return false, id
+ }
+ verified, id = c.verifyString(entry.Value())
+ if !verified {
+ return false, id
+ }
+ }
+ return true, sub.ID()
+ default:
+ return true, sub.ID()
+ }
+}
+
+// helper routines for reporting common errors during string formatting static validation and
+// runtime execution.
+
+func binaryFormatError(id int64, badType string) error {
+ return newFormatError(id, "only integers and bools can be formatted as binary, was given %s", badType)
+}
+
+func decimalFormatError(id int64, badType string) error {
+ return newFormatError(id, "decimal clause can only be used on integers, was given %s", badType)
+}
+
+func fixedPointFormatError(id int64, badType string) error {
+ return newFormatError(id, "fixed-point clause can only be used on doubles, was given %s", badType)
+}
+
+func hexFormatError(id int64, badType string) error {
+ return newFormatError(id, "only integers, byte buffers, and strings can be formatted as hex, was given %s", badType)
+}
+
+func octalFormatError(id int64, badType string) error {
+ return newFormatError(id, "octal clause can only be used on integers, was given %s", badType)
+}
+
+func scientificFormatError(id int64, badType string) error {
+ return newFormatError(id, "scientific clause can only be used on doubles, was given %s", badType)
+}
+
+func stringFormatError(id int64, badType string) error {
+ return newFormatError(id, "string clause can only be used on strings, bools, bytes, ints, doubles, maps, lists, types, durations, and timestamps, was given %s", badType)
+}
+
+type formatError struct {
+ id int64
+ msg string
+}
+
+func newFormatError(id int64, msg string, args ...any) error {
+ return formatError{
+ id: id,
+ msg: fmt.Sprintf(msg, args...),
+ }
+}
+
+func (e formatError) Error() string {
+ return e.msg
+}
+
+func (e formatError) Is(target error) bool {
+ return e.msg == target.Error()
+}
+
+// stringArgList implements the formatListArgs interface.
+type stringArgList struct {
+ args traits.Lister
+}
+
+func (c *stringArgList) Arg(index int64) (ref.Val, error) {
+ if index >= c.args.Size().Value().(int64) {
+ return nil, fmt.Errorf("index %d out of range", index)
+ }
+ return c.args.Get(types.Int(index)), nil
+}
+
+func (c *stringArgList) Size() int64 {
+ return c.args.Size().Value().(int64)
+}
+
+// formatStringInterpolator is an interface that allows user-defined behavior
+// for formatting clause implementations, as well as argument retrieval.
+// Each function is expected to support the appropriate types as laid out in
+// the string.format documentation, and to return an error if given an inappropriate type.
+type formatStringInterpolator interface {
+ // String takes a ref.Val and a string representing the current locale identifier
+ // and returns the Val formatted as a string, or an error if one occurred.
+ String(ref.Val, string) (string, error)
+
+ // Decimal takes a ref.Val and a string representing the current locale identifier
+ // and returns the Val formatted as a decimal integer, or an error if one occurred.
+ Decimal(ref.Val, string) (string, error)
+
+ // Fixed takes an int pointer representing precision (or nil if none was given) and
+ // returns a function operating in a similar manner to String and Decimal, taking a
+ // ref.Val and locale and returning the appropriate string. A closure is returned
+ // so precision can be set without needing an additional function call/configuration.
+ Fixed(*int) func(ref.Val, string) (string, error)
+
+ // Scientific functions identically to Fixed, except the string returned from the closure
+ // is expected to be in scientific notation.
+ Scientific(*int) func(ref.Val, string) (string, error)
+
+ // Binary takes a ref.Val and a string representing the current locale identifier
+ // and returns the Val formatted as a binary integer, or an error if one occurred.
+ Binary(ref.Val, string) (string, error)
+
+ // Hex takes a boolean that, if true, indicates the hex string output by the returned
+ // closure should use uppercase letters for A-F.
+ Hex(bool) func(ref.Val, string) (string, error)
+
+ // Octal takes a ref.Val and a string representing the current locale identifier and
+ // returns the Val formatted in octal, or an error if one occurred.
+ Octal(ref.Val, string) (string, error)
+}
+
+// formatListArgs is an interface that allows user-defined list-like datatypes to be used
+// for formatting clause implementations.
+type formatListArgs interface {
+ // Arg returns the ref.Val at the given index, or an error if one occurred.
+ Arg(int64) (ref.Val, error)
+
+ // Size returns the length of the argument list.
+ Size() int64
+}
+
+// parseFormatString formats a string according to the string.format syntax, taking the clause implementations
+// from the provided FormatCallback and the args from the given FormatList.
+func parseFormatString(formatStr string, callback formatStringInterpolator, list formatListArgs, locale string) (string, error) {
+ i := 0
+ argIndex := 0
+ var builtStr strings.Builder
+ for i < len(formatStr) {
+ if formatStr[i] == '%' {
+ if i+1 < len(formatStr) && formatStr[i+1] == '%' {
+ err := builtStr.WriteByte('%')
+ if err != nil {
+ return "", fmt.Errorf("error writing format string: %w", err)
+ }
+ i += 2
+ continue
+ } else {
+ argAny, err := list.Arg(int64(argIndex))
+ if err != nil {
+ return "", err
+ }
+ if i+1 >= len(formatStr) {
+ return "", errors.New("unexpected end of string")
+ }
+ if int64(argIndex) >= list.Size() {
+ return "", fmt.Errorf("index %d out of range", argIndex)
+ }
+ numRead, val, refErr := parseAndFormatClause(formatStr[i:], argAny, callback, list, locale)
+ if refErr != nil {
+ return "", refErr
+ }
+ _, err = builtStr.WriteString(val)
+ if err != nil {
+ return "", fmt.Errorf("error writing format string: %w", err)
+ }
+ i += numRead
+ argIndex++
+ }
+ } else {
+ err := builtStr.WriteByte(formatStr[i])
+ if err != nil {
+ return "", fmt.Errorf("error writing format string: %w", err)
+ }
+ i++
+ }
+ }
+ return builtStr.String(), nil
+}
+
+// parseAndFormatClause parses the format clause at the start of the given string with val, and returns
+// how many characters were consumed and the substituted string form of val, or an error if one occurred.
+func parseAndFormatClause(formatStr string, val ref.Val, callback formatStringInterpolator, list formatListArgs, locale string) (int, string, error) {
+ i := 1
+ read, formatter, err := parseFormattingClause(formatStr[i:], callback)
+ i += read
+ if err != nil {
+ return -1, "", newParseFormatError("could not parse formatting clause", err)
+ }
+
+ valStr, err := formatter(val, locale)
+ if err != nil {
+ return -1, "", newParseFormatError("error during formatting", err)
+ }
+ return i, valStr, nil
+}
+
+func parseFormattingClause(formatStr string, callback formatStringInterpolator) (int, clauseImpl, error) {
+ i := 0
+ read, precision, err := parsePrecision(formatStr[i:])
+ i += read
+ if err != nil {
+ return -1, nil, fmt.Errorf("error while parsing precision: %w", err)
+ }
+ r := rune(formatStr[i])
+ i++
+ switch r {
+ case 's':
+ return i, callback.String, nil
+ case 'd':
+ return i, callback.Decimal, nil
+ case 'f':
+ return i, callback.Fixed(precision), nil
+ case 'e':
+ return i, callback.Scientific(precision), nil
+ case 'b':
+ return i, callback.Binary, nil
+ case 'x', 'X':
+ return i, callback.Hex(unicode.IsUpper(r)), nil
+ case 'o':
+ return i, callback.Octal, nil
+ default:
+ return -1, nil, fmt.Errorf("unrecognized formatting clause \"%c\"", r)
+ }
+}
+
+func parsePrecision(formatStr string) (int, *int, error) {
+ i := 0
+ if formatStr[i] != '.' {
+ return i, nil, nil
+ }
+ i++
+ var buffer strings.Builder
+ for {
+ if i >= len(formatStr) {
+ return -1, nil, errors.New("could not find end of precision specifier")
+ }
+ if !isASCIIDigit(rune(formatStr[i])) {
+ break
+ }
+ buffer.WriteByte(formatStr[i])
+ i++
+ }
+ precision, err := strconv.Atoi(buffer.String())
+ if err != nil {
+ return -1, nil, fmt.Errorf("error while converting precision to integer: %w", err)
+ }
+ return i, &precision, nil
+}
+
+func isASCIIDigit(r rune) bool {
+ return r <= unicode.MaxASCII && unicode.IsDigit(r)
+}
+
+type parseFormatError struct {
+ msg string
+ wrapped error
+}
+
+func newParseFormatError(msg string, wrapped error) error {
+ return parseFormatError{msg: msg, wrapped: wrapped}
+}
+
+func (e parseFormatError) Error() string {
+ return fmt.Sprintf("%s: %s", e.msg, e.wrapped.Error())
+}
+
+func (e parseFormatError) Is(target error) bool {
+ return e.Error() == target.Error()
+}
+
+func (e parseFormatError) Unwrap() error {
+ return e.wrapped
+}
+
+const (
+ runtimeID = int64(-1)
+)
diff --git a/vendor/github.com/google/cel-go/ext/guards.go b/vendor/github.com/google/cel-go/ext/guards.go
new file mode 100644
index 000000000000..2c00bfe3a87b
--- /dev/null
+++ b/vendor/github.com/google/cel-go/ext/guards.go
@@ -0,0 +1,63 @@
+// Copyright 2020 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package ext
+
+import (
+ "github.com/google/cel-go/common/ast"
+ "github.com/google/cel-go/common/types"
+ "github.com/google/cel-go/common/types/ref"
+)
+
+// function invocation guards for common call signatures within extension functions.
+
+func intOrError(i int64, err error) ref.Val {
+ if err != nil {
+ return types.NewErr(err.Error())
+ }
+ return types.Int(i)
+}
+
+func bytesOrError(bytes []byte, err error) ref.Val {
+ if err != nil {
+ return types.NewErr(err.Error())
+ }
+ return types.Bytes(bytes)
+}
+
+func stringOrError(str string, err error) ref.Val {
+ if err != nil {
+ return types.NewErr(err.Error())
+ }
+ return types.String(str)
+}
+
+func listStringOrError(strs []string, err error) ref.Val {
+ if err != nil {
+ return types.NewErr(err.Error())
+ }
+ return types.DefaultTypeAdapter.NativeToValue(strs)
+}
+
+func macroTargetMatchesNamespace(ns string, target ast.Expr) bool {
+ switch target.Kind() {
+ case ast.IdentKind:
+ if target.AsIdent() != ns {
+ return false
+ }
+ return true
+ default:
+ return false
+ }
+}
diff --git a/vendor/github.com/google/cel-go/ext/lists.go b/vendor/github.com/google/cel-go/ext/lists.go
new file mode 100644
index 000000000000..08751d08a1e8
--- /dev/null
+++ b/vendor/github.com/google/cel-go/ext/lists.go
@@ -0,0 +1,94 @@
+// Copyright 2023 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package ext
+
+import (
+ "fmt"
+
+ "github.com/google/cel-go/cel"
+ "github.com/google/cel-go/common/types"
+ "github.com/google/cel-go/common/types/ref"
+ "github.com/google/cel-go/common/types/traits"
+)
+
+// Lists returns a cel.EnvOption to configure extended functions for list manipulation.
+// As a general note, all indices are zero-based.
+// # Slice
+//
+// Returns a new sub-list using the indexes provided.
+//
+// .slice(, ) ->
+//
+// Examples:
+//
+// [1,2,3,4].slice(1, 3) // return [2, 3]
+// [1,2,3,4].slice(2, 4) // return [3 ,4]
+func Lists() cel.EnvOption {
+ return cel.Lib(listsLib{})
+}
+
+type listsLib struct{}
+
+// LibraryName implements the SingletonLibrary interface method.
+func (listsLib) LibraryName() string {
+ return "cel.lib.ext.lists"
+}
+
+// CompileOptions implements the Library interface method.
+func (listsLib) CompileOptions() []cel.EnvOption {
+ listType := cel.ListType(cel.TypeParamType("T"))
+ return []cel.EnvOption{
+ cel.Function("slice",
+ cel.MemberOverload("list_slice",
+ []*cel.Type{listType, cel.IntType, cel.IntType}, listType,
+ cel.FunctionBinding(func(args ...ref.Val) ref.Val {
+ list := args[0].(traits.Lister)
+ start := args[1].(types.Int)
+ end := args[2].(types.Int)
+ result, err := slice(list, start, end)
+ if err != nil {
+ return types.WrapErr(err)
+ }
+ return result
+ }),
+ ),
+ ),
+ }
+}
+
+// ProgramOptions implements the Library interface method.
+func (listsLib) ProgramOptions() []cel.ProgramOption {
+ return []cel.ProgramOption{}
+}
+
+func slice(list traits.Lister, start, end types.Int) (ref.Val, error) {
+ listLength := list.Size().(types.Int)
+ if start < 0 || end < 0 {
+ return nil, fmt.Errorf("cannot slice(%d, %d), negative indexes not supported", start, end)
+ }
+ if start > end {
+ return nil, fmt.Errorf("cannot slice(%d, %d), start index must be less than or equal to end index", start, end)
+ }
+ if listLength < end {
+ return nil, fmt.Errorf("cannot slice(%d, %d), list is length %d", start, end, listLength)
+ }
+
+ var newList []ref.Val
+ for i := types.Int(start); i < end; i++ {
+ val := list.Get(i)
+ newList = append(newList, val)
+ }
+ return types.DefaultTypeAdapter.NativeToValue(newList), nil
+}
diff --git a/vendor/github.com/google/cel-go/ext/math.go b/vendor/github.com/google/cel-go/ext/math.go
new file mode 100644
index 000000000000..893654e7fb73
--- /dev/null
+++ b/vendor/github.com/google/cel-go/ext/math.go
@@ -0,0 +1,895 @@
+// Copyright 2022 Google LLC
+//
+// Licensed under the Apache License, Version 2.0 (the "License");
+// you may not use this file except in compliance with the License.
+// You may obtain a copy of the License at
+//
+// http://www.apache.org/licenses/LICENSE-2.0
+//
+// Unless required by applicable law or agreed to in writing, software
+// distributed under the License is distributed on an "AS IS" BASIS,
+// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+// See the License for the specific language governing permissions and
+// limitations under the License.
+
+package ext
+
+import (
+ "fmt"
+ "math"
+ "strings"
+
+ "github.com/google/cel-go/cel"
+ "github.com/google/cel-go/common/ast"
+ "github.com/google/cel-go/common/types"
+ "github.com/google/cel-go/common/types/ref"
+ "github.com/google/cel-go/common/types/traits"
+)
+
+// Math returns a cel.EnvOption to configure namespaced math helper macros and
+// functions.
+//
+// Note, all macros use the 'math' namespace; however, at the time of macro
+// expansion the namespace looks just like any other identifier. If you are
+// currently using a variable named 'math', the macro will likely work just as
+// intended; however, there is some chance for collision.
+//
+// # Math.Greatest
+//
+// Returns the greatest valued number present in the arguments to the macro.
+//
+// Greatest is a variable argument count macro which must take at least one
+// argument. Simple numeric and list literals are supported as valid argument
+// types; however, other literals will be flagged as errors during macro
+// expansion. If the argument expression does not resolve to a numeric or
+// list(numeric) type during type-checking, or during runtime then an error
+// will be produced. If a list argument is empty, this too will produce an
+// error.
+//
+// math.greatest(, ...) ->
+//
+// Examples:
+//
+// math.greatest(1) // 1
+// math.greatest(1u, 2u) // 2u
+// math.greatest(-42.0, -21.5, -100.0) // -21.5
+// math.greatest([-42.0, -21.5, -100.0]) // -21.5
+// math.greatest(numbers) // numbers must be list(numeric)
+//
+// math.greatest() // parse error
+// math.greatest('string') // parse error
+// math.greatest(a, b) // check-time error if a or b is non-numeric
+// math.greatest(dyn('string')) // runtime error
+//
+// # Math.Least
+//
+// Returns the least valued number present in the arguments to the macro.
+//
+// Least is a variable argument count macro which must take at least one
+// argument. Simple numeric and list literals are supported as valid argument
+// types; however, other literals will be flagged as errors during macro
+// expansion. If the argument expression does not resolve to a numeric or
+// list(numeric) type during type-checking, or during runtime then an error
+// will be produced. If a list argument is empty, this too will produce an
+// error.
+//
+// math.least(, ...) ->
+//
+// Examples:
+//
+// math.least(1) // 1
+// math.least(1u, 2u) // 1u
+// math.least(-42.0, -21.5, -100.0) // -100.0
+// math.least([-42.0, -21.5, -100.0]) // -100.0
+// math.least(numbers) // numbers must be list(numeric)
+//
+// math.least() // parse error
+// math.least('string') // parse error
+// math.least(a, b) // check-time error if a or b is non-numeric
+// math.least(dyn('string')) // runtime error
+//
+// # Math.BitOr
+//
+// Introduced at version: 1
+//
+// Performs a bitwise-OR operation over two int or uint values.
+//
+// math.bitOr(, ) ->
+// math.bitOr(, ) ->
+//
+// Examples:
+//
+// math.bitOr(1u, 2u) // returns 3u
+// math.bitOr(-2, -4) // returns -2
+//
+// # Math.BitAnd
+//
+// Introduced at version: 1
+//
+// Performs a bitwise-AND operation over two int or uint values.
+//
+// math.bitAnd(, ) ->
+// math.bitAnd(, ) ->
+//
+// Examples:
+//
+// math.bitAnd(3u, 2u) // return 2u
+// math.bitAnd(3, 5) // returns 3
+// math.bitAnd(-3, -5) // returns -7
+//
+// # Math.BitXor
+//
+// Introduced at version: 1
+//
+// math.bitXor(, ) ->
+// math.bitXor(, ) ->
+//
+// Performs a bitwise-XOR operation over two int or uint values.
+//
+// Examples:
+//
+// math.bitXor(3u, 5u) // returns 6u
+// math.bitXor(1, 3) // returns 2
+//
+// # Math.BitNot
+//
+// Introduced at version: 1
+//
+// Function which accepts a single int or uint and performs a bitwise-NOT
+// ones-complement of the given binary value.
+//
+// math.bitNot() ->
+// math.bitNot() ->
+//
+// Examples
+//
+// math.bitNot(1) // returns -1
+// math.bitNot(-1) // return 0
+// math.bitNot(0u) // returns 18446744073709551615u
+//
+// # Math.BitShiftLeft
+//
+// Introduced at version: 1
+//
+// Perform a left shift of bits on the first parameter, by the amount of bits
+// specified in the second parameter. The first parameter is either a uint or
+// an int. The second parameter must be an int.
+//
+// When the second parameter is 64 or greater, 0 will be always be returned
+// since the number of bits shifted is greater than or equal to the total bit
+// length of the number being shifted. Negative valued bit shifts will result
+// in a runtime error.
+//
+// math.bitShiftLeft(, ) ->
+// math.bitShiftLeft(, ) ->
+//
+// Examples
+//
+// math.bitShiftLeft(1, 2) // returns 4
+// math.bitShiftLeft(-1, 2) // returns -4
+// math.bitShiftLeft(1u, 2) // return 4u
+// math.bitShiftLeft(1u, 200) // returns 0u
+//
+// # Math.BitShiftRight
+//
+// Introduced at version: 1
+//
+// Perform a right shift of bits on the first parameter, by the amount of bits
+// specified in the second parameter. The first parameter is either a uint or
+// an int. The second parameter must be an int.
+//
+// When the second parameter is 64 or greater, 0 will always be returned since
+// the number of bits shifted is greater than or equal to the total bit length
+// of the number being shifted. Negative valued bit shifts will result in a
+// runtime error.
+//
+// The sign bit extension will not be preserved for this operation: vacant bits
+// on the left are filled with 0.
+//
+// math.bitShiftRight(, ) ->
+// math.bitShiftRight(, ) ->
+//
+// Examples
+//
+// math.bitShiftRight(1024, 2) // returns 256
+// math.bitShiftRight(1024u, 2) // returns 256u
+// math.bitShiftRight(1024u, 64) // returns 0u
+//
+// # Math.Ceil
+//
+// Introduced at version: 1
+//
+// Compute the ceiling of a double value.
+//
+// math.ceil() ->
+//
+// Examples:
+//
+// math.ceil(1.2) // returns 2.0
+// math.ceil(-1.2) // returns -1.0
+//
+// # Math.Floor
+//
+// Introduced at version: 1
+//
+// Compute the floor of a double value.
+//
+// math.floor() ->
+//
+// Examples:
+//
+// math.floor(1.2) // returns 1.0
+// math.floor(-1.2) // returns -2.0
+//
+// # Math.Round
+//
+// Introduced at version: 1
+//
+// Rounds the double value to the nearest whole number with ties rounding away
+// from zero, e.g. 1.5 -> 2.0, -1.5 -> -2.0.
+//
+// math.round() ->
+//
+// Examples:
+//
+// math.round(1.2) // returns 1.0
+// math.round(1.5) // returns 2.0
+// math.round(-1.5) // returns -2.0
+//
+// # Math.Trunc
+//
+// Introduced at version: 1
+//
+// Truncates the fractional portion of the double value.
+//
+// math.trunc() ->