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A Kubernetes Operator to Manage Cisco ACI Policies

Tests GitHub go.mod Go version Go Report Card Kubernetes version published

Simplify the Day-2 operation of a Kubernetes Cluster running the Cisco ACI Container Network Interface (CNI), by automating the configuration of the APIC using a Kubernetes Operator. This repository contains a Kubernetes Operator used to manage a Custom Resource named SegmentationPolicy. The Operator enforces Namespace segmentation, based on a straightforward and user-friendly Kubernetes manifest, through the configuration of the required objects (Contracts, Filters, EPGs) on the APIC controller.

ACI CNI Unified Networking

The ACI-CNI is an overlay network plugin that enables a smooth integration between Kubernetes nodes and the ACI Fabric. The plugin makes possible distributed routing and switching with VXLAN overlays on the Fabric and on the Kubernetes nodes. By using the ACI CNI, Pods running inside the Kubernetes cluster become endpoints of the ACI Fabric. As a result, the same level of segmentation and policing applied to Bare-metal servers and virtual machines can also be applied to the Pods.


Kubernetes administrators can map Deployments and Namespaces to EPGs, which are in turn managed by Network administrators to apply rules with the ACI Policy Model. This Operator eases the collaboration between Network and Kubernetes administrators through the automation of the configuration of ACI Policies based on the specification of a new Custom Resource, the SegmentationPolicy.

Table of Contents

Requirements

Installation

This repository has been scaffolded using Kubebuilder. Projects created by Kubebuilder contain a Makefile that eases the installation and testing of the Kubernetes Operator. The Makefile also leverages Kustomize to dynamically generate Kubernetes manifests.

Your Kubernetes cluster must have already been configured to use the Cisco ACI CNI

1. Clone this repository

      $ git clone https://github.com/jgomezve/aci-k8s-operator
      $ cd aci-k8s-operator

2. Configure the CRD SegmentationPolicy

  • Configure the Custom Resource Definition (CRD) SegmentationPolicy on the Kubernetes clusters
      $ make install
      customresourcedefinition.apiextensions.k8s.io/segmentationpolicies.apic.aci.cisco configured
      $ kubectl get crd
      NAME                                    CREATED AT
      segmentationpolicies.apic.aci.cisco     2022-04-19T15:58:11Z
  • Alternatively you could apply the manifest directly
      $ kubectl apply -f config/crd/bases/apic.aci.cisco_segmentationpolicies.yaml
      customresourcedefinition.apiextensions.k8s.io/segmentationpolicies.apic.aci.cisco configured
config/crd/bases/apic.aci.cisco_segmentationpolicies.yaml
  ---
  apiVersion: apiextensions.k8s.io/v1
  kind: CustomResourceDefinition
  metadata:
    annotations:
      controller-gen.kubebuilder.io/version: v0.8.0
    creationTimestamp: null
    name: segmentationpolicies.apic.aci.cisco
  spec:
    group: apic.aci.cisco
    names:
      kind: SegmentationPolicy
      listKind: SegmentationPolicyList
      plural: segmentationpolicies
      shortNames:
      - segpol
      singular: segmentationpolicy
    scope: Namespaced
    versions:
    - name: v1alpha1
      schema:
        openAPIV3Schema:
          description: SegmentationPolicy is the Schema for the segmentationpolicies
            API
          properties:
            apiVersion:
              description: 'APIVersion defines the versioned schema of this representation
                of an object. Servers should convert recognized schemas to the latest
                internal value, and may reject unrecognized values. More info: https://git.k8s.io/community/contributors/devel/sig-architecture/api-conventions.md#resources'
              type: string
            kind:
              description: 'Kind is a string value representing the REST resource this
                object represents. Servers may infer this from the endpoint the client
                submits requests to. Cannot be updated. In CamelCase. More info: https://git.k8s.io/community/contributors/devel/sig-architecture/api-conventions.md#types-kinds'
              type: string
            metadata:
              type: object
            spec:
              description: SegmentationPolicySpec defines the desired state of SegmentationPolicy
              properties:
                namespaces:
                  items:
                    type: string
                  type: array
                rules:
                  items:
                    properties:
                      eth:
                        type: string
                      ip:
                        type: string
                      port:
                        type: integer
                    type: object
                  type: array
              required:
              - namespaces
              - rules
              type: object
            status:
              description: SegmentationPolicyStatus defines the observed state of SegmentationPolicy
              type: object
          type: object
      served: true
      storage: true
      subresources:
        status: {}
  status:
    acceptedNames:
      kind: ""
      plural: ""
    conditions: []
    storedVersions: []

3. Start the operator

The operator requires read/write access privileges to the Kubernetes cluster and the APIC controller. During the start-up phase, the Operator discovers the APIC configuration parameters from the ConfigMap aci-containers-config. This ConfigMap is automatically deployed during the installation of the ACI CNI.

APIC's username and private key, which are used by the Operator, are discovered during the start-up phase.

Note: The ConfigMap aci-containers-config is deployed in the Namespace aci-containers-system

Option 1: Operator running outside of the K8s Cluster

This is the preferred method for development environments. Make sure Go >=1.17 is installed on the machine running the Kubernetes Operator

  • Set the kubeconfig file on the hosting machine to grant the Operator access to the Kubernetes cluster
      $ export KUBECONFIG=<kubeconfigfile.yaml>
  • Compile the code and execute the binary file
      $ make run

  • Alternatively you could excute Go commands directly
      $ go run ./main.go

1.6523912324578347e+09	INFO	setup	ACI CNI configuration discovered for tenant k8s-rke-aci-cni-pod-4 in APIC controller 172.20.91.9
1.6523912325494506e+09	INFO	setup	starting manager
1.6523912325497773e+09	INFO	controller.segmentationpolicy	Starting EventSource	{"reconciler group": "apic.aci.cisco", "reconciler kind": "SegmentationPolicy", "source": "kind source: *v1alpha1.SegmentationPolicy"}
1.6523912325498345e+09	INFO	controller.segmentationpolicy	Starting EventSource	{"reconciler group": "apic.aci.cisco", "reconciler kind": "SegmentationPolicy", "source": "kind source: *v1.Namespace"}
1.6523912325498483e+09	INFO	controller.segmentationpolicy	Starting Controller	{"reconciler group": "apic.aci.cisco", "reconciler kind": "SegmentationPolicy"}
1.6523912326504896e+09	INFO	controller.segmentationpolicy	Starting workers	{"reconciler group": "apic.aci.cisco", "reconciler kind": "SegmentationPolicy", "worker count": 1}

Option 2: Operator running inside of the K8s Cluster as a Pod

This is the preferred method for production environments. The operator runs as a containerized application inside a Pod. ClusterRole and corresponding ClusterRoleBinding with ServiceAccount objects must be configured to ensure that the Pod has the required permissions to read/write the Kubernetes API. Based on best-practices, a Deployment, configured in a dedicated Namespace, manages the Pod which hosts the Operator application

Connectivity from the Operator's Pod to the APIC controller can satisfied by any of the following options:

  1. SnatPolicy: This new CRD, available in the ACI-CNI, allows Pods to communicate outside of the cluster using SNAT
  2. LoadBalancer: This Service Type exposes Pods in the cluster over a known IP address. It also enables the exposed Pods to reach external networks
  • Deploy the Operator on the Kubernetes Cluster
      $ make deploy 

      namespace/aci-k8s-operator-system created
      customresourcedefinition.apiextensions.k8s.io/segmentationpolicies.apic.aci.cisco created
      serviceaccount/aci-k8s-operator-controller-manager created
      role.rbac.authorization.k8s.io/aci-k8s-operator-leader-election-role created
      clusterrole.rbac.authorization.k8s.io/aci-k8s-operator-manager-role created
      clusterrole.rbac.authorization.k8s.io/aci-k8s-operator-metrics-reader created
      clusterrole.rbac.authorization.k8s.io/aci-k8s-operator-proxy-role created
      rolebinding.rbac.authorization.k8s.io/aci-k8s-operator-leader-election-rolebinding created
      clusterrolebinding.rbac.authorization.k8s.io/aci-k8s-operator-manager-rolebinding created
      clusterrolebinding.rbac.authorization.k8s.io/aci-k8s-operator-proxy-rolebinding created
      configmap/aci-k8s-operator-manager-config created
      service/aci-k8s-operator-controller-manager-metrics-service created
      deployment.apps/aci-k8s-operator-controller-manager created
  • Alternatively you could apply the manifest config/samples/controller_lightweight.yaml directly. This manifest creates the minimum resources required to run the operator inside the Kubernetes Cluster:
    • A Namespace which contains the namespace-scoped resources
    • A ServiceAccount which grants the Operator access tot he Kubernetes API Server
    • A ClusterRole listing the resources and actions the Operator has access to
    • A ClusterRoleBinding which binds the Role with the ServiceAccount
    • A Deployment of one replica hosting the Operator code.
      $ kubectl apply  -f config/samples/controller_lightweight.yaml
      namespace/aci-k8s-operator-system created
      deployment.apps/controller-manager created
      serviceaccount/controller-manager created
      clusterrole.rbac.authorization.k8s.io/manager-role created
      clusterrolebinding.rbac.authorization.k8s.io/manager-rolebinding created
  • Check the Controler status
      $ kubectl get pod -n aci-k8s-operator-system
      NAME                                              READY   STATUS    RESTARTS   AGE
      aci-k8s-operator-controller-manager-55d9777c9-89vh4   2/2     Running   0          14m

Usage

The following example restricts communication between Namepaces ns1 and ns2 to only HTTPS. A Custom Resource of type SegmentationPolicy is created. It specifies the name of the Namespaces and the rules under spec.namespaces[] and spec.rules[] respectively

  • Create the Namespaces
      $ kubectl create namespace ns1
      $ kubectl create namespace ns2
      namespace/ns1 created
      namespace/ns2 created
      $ kubectl get namespace
      NAME                    STATUS   AGE
      ns1                     Active   11s
      ns2                     Active   8s

  • Create a SegmentationPolicy Custom Resources (CR)

segmentationpolicy.yaml

apiVersion: apic.aci.cisco/v1alpha1
kind: SegmentationPolicy
metadata:
  name: segpol1
spec:
  namespaces:
    - ns1
    - ns2
  rules:
    - eth: ip
      ip: tcp
      port: 443
  $ kubectl apply -f segmentationpolicy.yaml
  segmentationpolicy.apic.aci.cisco/segpol1 created
      $ kubectl get segmentationpolicies
      NAME      NAMESPACES   RULES        STATE      AGE
      segpol1   ns1, ns2     ip-tcp-443   Enforced   20s
  • The Kubernetes Operator configures the following Objects/Relationship on the APIC Controller
    1. Filter per rule defined in the SegmentationPolicy CR. The name of the Filters is built based on the information from the manifest as follows <metadata.name><rule.eth><rule.ip><rule.port>
    2. Contract and Subject with the name of the SegmentationPolicy. The subject includes all the filters mentioned in point (i)
    3. An Application Profile named Seg_Pol_<tenant_name>
    4. An EPG per Namespace defined in the SegmentationPolicy CR. The names of the EPGs are the same names of the Namespaces [*]. The following properties are configured under the EPG:
    • The Bridge Domain is set to the one assigned to the Pod Network
    • The VMM Domain of type Kubernetes used by the CNI is assigned
    • The Contracts mentioned in point (ii) are consumed and assigned
    • The ACI-CNI "default" EPG is set as the Master EPG

add-app

Note: [*] If a Namespace is defined in the SegmentationPolicy but does not exist in the Kubernetes Cluster, the EPG is not created. Likewise, if a Namespace listed in a SegmentationPolicy is deleted, the Operator reacts and deletes the corresponding EPG.