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astScript.sml
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astScript.sml
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(*
Definition of CakeML abstract syntax (AST).
*)
open HolKernel Parse boolLib bossLib;
open namespaceTheory fpSemTheory fpValTreeTheory realOpsTheory;
local open integerTheory wordsTheory stringTheory namespaceTheory locationTheory in end;
val _ = new_theory "ast"
val _ = set_grammar_ancestry ["integer", "words", "string", "namespace", "location"];
(* Literal constants *)
Datatype:
lit =
IntLit int
| Char char
| StrLit string
| Word8 word8
| Word64 word64
End
(* Built-in binary operations *)
Datatype:
opn = Plus | Minus | Times | Divide | Modulo
End
Datatype:
opb = Lt | Gt | Leq | Geq
End
Datatype:
opw = Andw | Orw | Xor | Add | Sub
End
Datatype:
shift = Lsl | Lsr | Asr | Ror
End
(* Module names *)
Type modN = “:string”
(* Variable names *)
Type varN = “:string”
(* Constructor names (from datatype definitions) *)
Type conN = ``: string``
(* Type names *)
Type typeN = ``: string``
(* Type variable names *)
Type tvarN = ``: string``
Datatype:
word_size = W8 | W64
End
Datatype:
op =
(* Operations on integers *)
Opn opn
| Opb opb
(* Operations on words *)
| Opw word_size opw
| Shift word_size shift num
| Equality
(* FP operations *)
| FP_cmp fp_cmp
| FP_uop fp_uop
| FP_bop fp_bop
| FP_top fp_top
(* Floating-point <-> word translations *)
| FpFromWord
| FpToWord
(* Real ops for verification *)
| Real_cmp real_cmp
| Real_uop real_uop
| Real_bop real_bop
(* Translation from floating-points to reals for verification *)
| RealFromFP
(* Function application *)
| Opapp
(* Reference operations *)
| Opassign
| Opref
| Opderef
(* Word8Array operations *)
| Aw8alloc
| Aw8sub
| Aw8length
| Aw8update
(* Word/integer conversions *)
| WordFromInt word_size
| WordToInt word_size
(* string/bytearray conversions *)
| CopyStrStr
| CopyStrAw8
| CopyAw8Str
| CopyAw8Aw8
(* Char operations *)
| Ord
| Chr
| Chopb opb
(* String operations *)
| Implode
| Explode
| Strsub
| Strlen
| Strcat
(* Vector operations *)
| VfromList
| Vsub
| Vlength
(* Array operations *)
| Aalloc
| AallocEmpty
| AallocFixed
| Asub
| Alength
| Aupdate
(* Unsafe array accesses *)
| Asub_unsafe
| Aupdate_unsafe
| Aw8sub_unsafe
| Aw8update_unsafe
(* List operations *)
| ListAppend
(* Configure the GC *)
| ConfigGC
(* Call a given foreign function *)
| FFI string
(* Evaluate new code in a given env *)
| Eval
(* Get the identifier of an env object *)
| Env_id
End
(* Define operator classes, that allow to group their behavior later *)
Datatype:
op_class =
EvalOp (* Eval primitive *)
| FunApp (* function application *)
| Simple (* arithmetic operation, no finite-precision/reals *)
| Icing (* 64-bit floating-points *)
| Reals (* real numbers *)
End
Definition getOpClass_def[simp]:
getOpClass op =
case op of
FP_cmp _ => Icing
| FP_top _ => Icing
| FP_bop _ => Icing
| FP_uop _ => Icing
| Real_cmp _ => Reals
| Real_bop _ => Reals
| Real_uop _ => Reals
| RealFromFP => Reals
| Opapp => FunApp
| Eval => EvalOp
| _ => Simple
End
Definition isFpBool_def:
isFpBool op = case op of FP_cmp _ => T | _ => F
End
(* Logical operations *)
Datatype:
lop = And | Or
End
(* Types *)
Datatype:
ast_t =
(* Type variables that the user writes down ('a, 'b, etc.) *)
Atvar tvarN
(* Function type *)
| Atfun ast_t ast_t
(* Tuple type *)
| Attup (ast_t list)
(* Type constructor applications.
0-ary type applications represent unparameterised types (e.g., num or string) *)
| Atapp (ast_t list) ((modN, typeN) id)
End
(* Patterns *)
Datatype:
pat =
Pany
| Pvar varN
| Plit lit
(* Constructor applications.
A Nothing constructor indicates a tuple pattern. *)
| Pcon (((modN, conN) id) option) (pat list)
| Pref pat
(* Pattern alias. *)
| Pas pat varN
| Ptannot pat ast_t
End
(* Expressions *)
Datatype:
exp =
Raise exp
| Handle exp ((pat # exp) list)
| Lit lit
(* Constructor application.
A Nothing constructor indicates a tuple pattern. *)
| Con (((modN, conN)id)option) (exp list)
| Var ((modN, varN) id)
| Fun varN exp
(* Application a primitive operator to arguments.
Includes function application. *)
| App op (exp list)
(* Logical operations (and, or) *)
| Log lop exp exp
| If exp exp exp
(* Pattern matching *)
| Mat exp ((pat # exp) list)
(* A let expression
A Nothing value for the binding indicates that this is a
sequencing expression, that is: (e1; e2). *)
| Let (varN option) exp exp
(* Local definition (potentially) mutually recursive
functions.
The first varN is the function's name, and the second varN
is its parameter. *)
| Letrec ((varN # varN # exp) list) exp
| Tannot exp ast_t
(* Location annotated expressions, not expected in source programs *)
| Lannot exp locs
(* Floating-point optimisations *)
| FpOptimise fp_opt exp
End
Type type_def = ``: ( tvarN list # typeN # (conN # ast_t list) list) list``
(* Declarations *)
Datatype:
dec =
(* Top-level bindings
* The pattern allows several names to be bound at once *)
Dlet locs pat exp
(* Mutually recursive function definition *)
| Dletrec locs ((varN # varN # exp) list)
(* Type definition
Defines several data types, each which has several
named variants, which can in turn have several arguments.
*)
| Dtype locs type_def
(* Type abbreviations *)
| Dtabbrev locs (tvarN list) typeN ast_t
(* New exceptions *)
| Dexn locs conN (ast_t list)
(* Module *)
| Dmod modN (dec list)
(* Local: local part, visible part *)
| Dlocal (dec list) (dec list)
(* Store current lexical env in an env value *)
| Denv tvarN
End
(* Accumulates the bindings of a pattern *)
Definition pat_bindings_def:
pat_bindings Pany already_bound = already_bound ∧
pat_bindings (Pvar n) already_bound = n::already_bound ∧
pat_bindings (Plit l) already_bound = already_bound ∧
pat_bindings (Pcon v0 ps) already_bound = pats_bindings ps already_bound ∧
pat_bindings (Pref p) already_bound = pat_bindings p already_bound ∧
pat_bindings (Pas p i) already_bound = pat_bindings p (i::already_bound) ∧
pat_bindings (Ptannot p v1) already_bound = pat_bindings p already_bound ∧
pats_bindings [] already_bound = already_bound ∧
pats_bindings (p::ps) already_bound =
pats_bindings ps (pat_bindings p already_bound)
End
Definition every_exp_def[simp]:
(every_exp p (Raise e) ⇔
p (Raise e) ∧ every_exp p e) ∧
(every_exp p (Handle e pes) ⇔
p (Handle e pes) ∧ every_exp p e ∧ EVERY (λ(pat,e). every_exp p e) pes) ∧
(every_exp p (ast$Lit l) ⇔
p (ast$Lit l)) ∧
(every_exp p (Con cn es) ⇔
p (Con cn es) ∧ EVERY (every_exp p) es) ∧
(every_exp p (Var v) ⇔
p (Var v)) ∧
(every_exp p (Fun x e) ⇔
p (Fun x e) ∧ every_exp p e) ∧
(every_exp p (App op es) ⇔
p (App op es) ∧ EVERY (every_exp p) es) ∧
(every_exp p (Log lop e1 e2) ⇔
p (Log lop e1 e2) ∧ every_exp p e1 ∧ every_exp p e2) ∧
(every_exp p (If e1 e2 e3) ⇔
p (If e1 e2 e3) ∧ every_exp p e1 ∧ every_exp p e2 ∧ every_exp p e3) ∧
(every_exp p (Mat e pes) ⇔
p (Mat e pes) ∧ every_exp p e ∧ EVERY (λ(pat,e). every_exp p e) pes) ∧
(every_exp p (Let x e1 e2) ⇔
p (Let x e1 e2) ∧ every_exp p e1 ∧ every_exp p e2) ∧
(every_exp p (Tannot e a) ⇔
p (Tannot e a) ∧ every_exp p e) ∧
(every_exp p (Lannot e a) ⇔
p (Lannot e a) ∧ every_exp p e) ∧
(every_exp p (FpOptimise sc e) ⇔
p (FpOptimise sc e) ∧ every_exp p e) ∧
(every_exp p (Letrec funs e) ⇔
p (Letrec funs e) ∧ every_exp p e ∧ EVERY (λ(n,v,e). every_exp p e) funs)
Termination
WF_REL_TAC ‘measure $ exp_size o SND’
End
val _ = export_theory()