Kuryr Kubernetes Openshift Routes integration design

updated: 2020-11-26 08:24

Kuryr Kubernetes Openshift Routes integration design

Purpose

The purpose of this document is to present how Openshift Routes are supported by kuryr-kubernetes.

Overview

OpenShift Origin [1] is an open source cloud application development and hosting platform that automates the provisioning, management and scaling of applications.

OpenShift Origin is a distribution of Kubernetes optimized for continuous application development and multi-tenancy deployment. OpenShift adds developer and operations-centric tools on top of Kubernetes to enable rapid application development, easy deployment and scaling, and long-term lifecycle maintenance.

An OpenShift Route [2] exposes a Service at a host name, like www.example.com, so that external clients can reach it by name. The Route is an Openshift resource that defines the rules you want to apply to incoming connections. The Openshift Routes concept introduced before Ingress [3] was supported by kubernetes, the Openshift Route matches the functionality of kubernetes Ingress.

Proposed Solution

The solution will rely on L7 router, Service/Endpoints handler and L7 router driver components described at kuryr-kubernetes Ingress integration design, where a new component - OCP-Route handler, will satisfy requests for Openshift Route resources.

Controller Handlers impact:

The controller handlers should be extended to support OCP-Route resource.

The OCP-Route handler

The OCP-Route handler watches the apiserver’s for updates to Openshift Route resources. The following scheme describes OCP-Route controller SW architecture:

Ingress/OCP-Route controllers SW architecture

Similar to Kubernetes Ingress, each OCP-Route object being translated to a L7 policy in L7 router, and the rules on OCP-Route become L7 (URL) mapping rules in that L7 policy. The L7 policy is configured to forward the filtered traffic to LbaaS Pool. The LbaaS pool represents an Endpoints resource, and it’s the Service/Endpoints handler responsibility to attach all its members to this pool. Since the Endpoints resource is not aware of changes in OCP-Route objects pointing to it, the OCP-Route handler should trigger this notification, the notification will be implemented using annotation of the relevant Endpoint resource.

Use cases examples

This section describes in details the following scenarios:

  1. Create OCP-Route, create Service/Endpoints.
  2. Create Service/Endpoints, create OCP-Route, delete OCP-Route.

  • Create OCP-Route, create Service/Endpoints:

    • OCP-Route is created under namespace ‘mynamespace’

      • OCP-Route details :
      apiVersion: v1
kind: Route
metadata:
  name: test
  spec:
    host: www.example.com
    to:
      kind: Service
      name: s1
      • Since it’s the first route pointing to this Service, the OCP-Route handler will create LbaaS pool (attached to L7 router)- named ‘mynamespace_s1’.
      • The OCP-Route handler will create L7 rule and L7 policy, the L7 policy direct it’s filtered traffic towards ‘mynamespace_s1’ pool.

    • Service/Endpoints is created under namespace ‘mynamespace’

      • name: s1
      • The Service/Endpoints handler will create user loadbalancer
      • The Service/Endpoints handler will check for pool named ‘mynamespace_s1’ and add its members to this pool.

  • Create Service/Endpoints, create OCP-Route, delete OCP-Route:

    • Service/Endpoints is created under namespace ‘mynamespace’
      • name: s1
      • The Service/Endpoints handler will create user loadbalancer
      • Since no pool named ‘mynamespace_s1’ exist in L7 router, Service will exit.
    • OCP-Route is created with same details as described in above yaml file.
      • Since it’s the first route pointing to this Service, the OCP-Route handler will create LbaaS pool (attached to L7 router) named ‘mynamespace_s1’.
      • The OCP-Route handler will create L7 rule and L7 policy, the L7 policy configured to direct its filtered traffic towards ‘mynamespace_s1’ pool.
      • The last step from OCP-Route handler will be to notify (using annotation) s1 Endpoint.
      • As a result to the OCP-Route notification, the Endpoint handler will be called. The Service/Endpoints handler will update the members information attached to ‘mynamespace_s1’ pool.
    • OCP-Route is deleted
      • OCP-Route handler will first delete L7 rule and L7 policy.
      • In case no other L7 policy is pointing ‘mynamespace_s1’ pool, the OCP-Route handler will delete ‘mynamespace_s1’ pool’s members and the pool itself. The last step from Ingress handler will be to notify s1 Service/Endpoints.
      • As a result to the OCP-Route handler notification, the Service/Endpoints handler will set its internal state to ‘no Ingress is pointing’ state.
updated: 2020-11-26 08:24
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