Welcome to the OpenShift Pipelines tutorial!
OpenShift Pipelines is a cloud-native, continuous integration and delivery (CI/CD) solution for building pipelines using Tekton. Tekton is a flexible, Kubernetes-native, open-source CI/CD framework that enables automating deployments across multiple platforms (Kubernetes, serverless, VMs, etc) by abstracting away the underlying details.
OpenShift Pipelines features:
- Standard CI/CD pipeline definition based on Tekton
- Build images with Kubernetes tools such as S2I, Buildah, Buildpacks, Kaniko, etc
- Deploy applications to multiple platforms such as Kubernetes, serverless and VMs
- Easy to extend and integrate with existing tools
- Scale pipelines on-demand
- Portable across any Kubernetes platform
- Designed for microservices and decentralized teams
- Integrated with the OpenShift Developer Console
This tutorial walks you through pipeline concepts and how to create and run a simple pipeline for building and deploying a containerized app on OpenShift, and in this tutorial, we will use Triggers
to handle a real GitHub webhook request to kickoff a PipelineRun.
In this tutorial you will:
- Learn about Tekton concepts
- Install OpenShift Pipelines
- Deploy a Sample Application
- Install Tasks
- Create a Pipeline
- Trigger a Pipeline
You need an OpenShift 4 cluster in order to complete this tutorial. If you don't have an existing cluster, go to http://try.openshift.com and register for free in order to get an OpenShift 4 cluster up and running on AWS within minutes.
You will also use the Tekton CLI (tkn
) through out this tutorial. Download the Tekton CLI by following instructions available on the CLI GitHub repository.
Tekton defines a number of Kubernetes custom resources as building blocks in order to standardize pipeline concepts and provide a terminology that is consistent across CI/CD solutions. These custom resources are an extension of the Kubernetes API that let users create and interact with these objects using kubectl
and other Kubernetes tools.
The custom resources needed to define a pipeline are listed below:
Task
: a reusable, loosely coupled number of steps that perform a specific task (e.g. building a container image)Pipeline
: the definition of the pipeline and theTasks
that it should performTaskRun
: the execution and result of running an instance of taskPipelineRun
: the execution and result of running an instance of pipeline, which includes a number ofTaskRuns
In short, in order to create a pipeline, one does the following:
- Create custom or install existing reusable
Tasks
- Create a
Pipeline
andPipelineResources
to define your application's delivery pipeline - Create a
PersistentVolumeClaim
to provide the volume/filesystem for pipeline execution or provide aVolumeClaimTemplate
which creates aPersistentVolumeClaim
- Create a
PipelineRun
to instantiate and invoke the pipeline
For further details on pipeline concepts, refer to the Tekton documentation that provides an excellent guide for understanding various parameters and attributes available for defining pipelines.
The Tekton API enables functionality to be separated from configuration (e.g. Pipelines vs PipelineRuns) such that steps can be reusable.
Triggers extend the Tekton architecture with the following CRDs:
TriggerTemplate
- Templates resources to be created (e.g. Create PipelineResources and PipelineRun that uses them)TriggerBinding
- Validates events and extracts payload fieldsTrigger
- combines TriggerTemplate, TriggerBindings and interceptors.EventListener
- provides an addressable endpoint (the event sink).Trigger
is referenced inside the EventListener Spec. It uses the extracted event parameters from eachTriggerBinding
(and any supplied static parameters) to create the resources specified in the correspondingTriggerTemplate
. It also optionally allows an external service to pre-process the event payload via theinterceptor
field.ClusterTriggerBinding
- A cluster-scoped TriggerBinding
Using tektoncd/triggers
in conjunction with tektoncd/pipeline
enables you to
easily create full-fledged CI/CD systems where the execution is defined
entirely through Kubernetes resources.
You can learn more about triggers
by checking out the docs
In the following sections, you will go through each of the above steps to define and invoke a pipeline.
OpenShift Pipelines is provided as an add-on on top of OpenShift that can be installed via an operator available in the OpenShift OperatorHub. Follow these instructions in order to install OpenShift Pipelines on OpenShift via the OperatorHub.
Create a project for the sample application that you will be using in this tutorial:
$ oc new-project pipelines-tutorial
OpenShift Pipelines automatically adds and configures a ServiceAccount
named pipeline
that has sufficient permissions to build and push an image. This
service account will be used later in the tutorial.
Run the following command to see the pipeline
service account:
$ oc get serviceaccount pipeline
You will use the simple application during this tutorial, which has a frontend and backend
You can also deploy the same applications by applying the artifacts available in k8s directory of the respective repo
If you deploy the application directly, you should be able to see the deployment in the OpenShift Web Console by switching over to the Developer perspective of the OpenShift Web Console. Change from Administrator to Developer from the drop down as shown below:
Make sure you are on the pipelines-tutorial
project by selecting it from the Project dropdown menu. Either search for pipelines-tutorial
in the search bar or scroll down until you find pipelines-tutorial
and click on the name of your project.
Tasks consist of a number of steps that are executed sequentially. Tasks are executed/run by creating TaskRuns. A TaskRun will schedule a Pod. Each step is executed in a separate container within the same pod. They can also have inputs and outputs in order to interact with other tasks in the pipeline.
Here is an example of a Maven task for building a Maven-based Java application:
apiVersion: tekton.dev/v1
kind: Task
metadata:
name: maven-build
spec:
workspaces:
- name: filedrop
steps:
- name: build
image: maven:3.6.0-jdk-8-slim
command:
- /usr/bin/mvn
args:
- install
When a task starts running, it starts a pod and runs each step sequentially in a separate container on the same pod. This task happens to have a single step, but tasks can have multiple steps, and, since they run within the same pod, they have access to the same volumes in order to cache files, access configmaps, secrets, etc. You can specify volume using workspace. It is recommended that Tasks uses at most one writeable Workspace. Workspace can be secret, pvc, config or emptyDir.
Note that only the requirement for a git repository is declared on the task and not a specific git repository to be used. That allows tasks to be reusable for multiple pipelines and purposes. You can find more examples of reusable tasks in the Tekton Catalog and OpenShift Catalog repositories.
Install the apply-manifests
and update-deployment
tasks from the repository using oc
or kubectl
, which you will need for creating a pipeline in the next section:
$ oc create -f https://raw.githubusercontent.com/openshift/pipelines-tutorial/master/01_pipeline/01_apply_manifest_task.yaml
$ oc create -f https://raw.githubusercontent.com/openshift/pipelines-tutorial/master/01_pipeline/02_update_deployment_task.yaml
You can take a look at the tasks you created using the Tekton CLI:
$ tkn task ls
NAME AGE
apply-manifests 10 seconds ago
update-deployment 4 seconds ago
We will be using buildah
clusterTasks, which gets installed along with Operator. Operator installs few ClusterTask which you can see.
$ tkn clustertasks ls
NAME DESCRIPTION AGE
buildah 1 day ago
buildah-v0-14-3 1 day ago
git-clone 1 day ago
s2i-php 1 day ago
tkn 1 day ago
A pipeline defines a number of tasks that should be executed and how they interact with each other via their inputs and outputs.
In this tutorial, you will create a pipeline that takes the source code of the application from GitHub and then builds and deploys it on OpenShift.
Here is the YAML file that represents the above pipeline:
apiVersion: tekton.dev/v1
kind: Pipeline
metadata:
name: build-and-deploy
spec:
workspaces:
- name: shared-workspace
params:
- name: deployment-name
type: string
description: name of the deployment to be patched
- name: git-url
type: string
description: url of the git repo for the code of deployment
- name: git-revision
type: string
description: revision to be used from repo of the code for deployment
default: master
- name: IMAGE
type: string
description: image to be build from the code
tasks:
- name: fetch-repository
taskRef:
name: git-clone
kind: ClusterTask
workspaces:
- name: output
workspace: shared-workspace
params:
- name: url
value: $(params.git-url)
- name: subdirectory
value: ""
- name: deleteExisting
value: "true"
- name: revision
value: $(params.git-revision)
- name: build-image
taskRef:
name: buildah
kind: ClusterTask
params:
- name: IMAGE
value: $(params.IMAGE)
workspaces:
- name: source
workspace: shared-workspace
runAfter:
- fetch-repository
- name: apply-manifests
taskRef:
name: apply-manifests
workspaces:
- name: source
workspace: shared-workspace
runAfter:
- build-image
- name: update-deployment
taskRef:
name: update-deployment
params:
- name: deployment
value: $(params.deployment-name)
- name: IMAGE
value: $(params.IMAGE)
runAfter:
- apply-manifests
Once you deploy the pipelines, you should be able to visualize pipeline flow in the OpenShift Web Console by switching over to the Developer perspective of the OpenShift Web Console. Select pipeline tab, select project as pipelines-tutorial
and click on pipeline build-and-deploy
This pipeline helps you to build and deploy backend/frontend, by configuring right resources to pipeline.
Pipeline Steps:
- Clones the source code of the application from a git repository by referring (
git-url
andgit-revision
param) - Builds the container image of application using the
buildah
clustertask that uses Buildah to build the image - The application image is pushed to an image registry by refering (
image
param) - The new application image is deployed on OpenShift using the
apply-manifests
andupdate-deployment
tasks.
You might have noticed that there are no references to the git
repository or the image registry it will be pushed to in pipeline. That's because pipeline in Tekton
are designed to be generic and re-usable across environments and stages through
the application's lifecycle. Pipelines abstract away the specifics of the git
source repository and image to be produced as PipelineResources
or Params
. When triggering a
pipeline, you can provide different git repositories and image registries to be
used during pipeline execution. Be patient! You will do that in a little bit in
the next section.
The execution order of tasks is determined by dependencies that are defined between the tasks via inputs and outputs as well as explicit orders that are defined via runAfter
.
workspaces
field allows you to specify one or more volumes that each Task in the Pipeline requires during execution. You specify one or more Workspaces in the workspaces
field.
Create the pipeline by running the following:
$ oc create -f https://raw.githubusercontent.com/openshift/pipelines-tutorial/master/01_pipeline/04_pipeline.yaml
Alternatively, in the OpenShift Web Console, you can click on the + at the top right of the screen while you are in the pipelines-tutorial project:
Upon creating the pipeline via the web console, you will be taken to a Pipeline Details page that gives an overview of the pipeline you created.
Check the list of pipelines you have created using the CLI:
$ tkn pipeline ls
NAME AGE LAST RUN STARTED DURATION STATUS
build-and-deploy 1 minute ago --- --- --- ---
Now that the pipeline is created, you can trigger it to execute the tasks specified in the pipeline.
Note :-
If you are not into the
pipelines-tutorial
namespace, and using another namespace for the tutorial steps, please make sure you update the frontend and backend image resource to the correct url with your namespace name like so :
image-registry.openshift-image-registry.svc:5000/<namespace-name>/pipelines-vote-api:latest
A PipelineRun
is how you can start a pipeline and tie it to the persistentVolumeClaim and params that should be used for this specific invocation.
Let's start a pipeline to build and deploy the backend application using tkn
:
$ tkn pipeline start build-and-deploy \
--prefix-name build-deploy-api-pipelinerun \
-w name=shared-workspace,volumeClaimTemplateFile=https://raw.githubusercontent.com/openshift/pipelines-tutorial/master/01_pipeline/03_persistent_volume_claim.yaml \
-p deployment-name=pipelines-vote-api \
-p git-url=https://github.com/openshift/pipelines-vote-api.git \
-p IMAGE=image-registry.openshift-image-registry.svc:5000/pipelines-tutorial/pipelines-vote-api \
--use-param-defaults
Pipelinerun started: vote-api-t9tpq
In order to track the pipelinerun progress run:
tkn pipelinerun logs vote-api-t9tpq -f -n pipelines-tutorial
Similarly, start a pipeline to build and deploy the frontend application:
$ tkn pipeline start build-and-deploy \
--prefix-name build-deploy-ui-pipelinerun \
-w name=shared-workspace,volumeClaimTemplateFile=https://raw.githubusercontent.com/openshift/pipelines-tutorial/master/01_pipeline/03_persistent_volume_claim.yaml \
-p deployment-name=pipelines-vote-ui \
-p git-url=https://github.com/openshift/pipelines-vote-ui.git \
-p IMAGE=image-registry.openshift-image-registry.svc:5000/pipelines-tutorial/pipelines-vote-ui \
--use-param-defaults
PipelineRun started: vote-ui-9tb2q
In order to track the PipelineRun progress run:
tkn pipelinerun logs vote-ui-9tb2q -f -n pipelines-tutorial
As soon as you start the build-and-deploy
pipeline, a pipelinerun will be instantiated and pods will be created to execute the tasks that are defined in the pipeline.
$ tkn pipeline list
NAME AGE LAST RUN STARTED DURATION STATUS
build-and-deploy 10 minutes ago vote-ui-9tb2q 47 seconds ago --- Running
Above we have started build-and-deploy
pipeline, with relevant pipeline resources to deploy the backend/frontend applications using single pipeline
$ tkn pipelinerun ls
NAME STARTED DURATION STATUS
vote-ui-9tb2q 1 minute ago --- Running
vote-api-t9tpq 1 minute ago --- Running
Check out the logs of the pipelinerun as it runs using the tkn pipeline logs
command which interactively allows you to pick the pipelinerun of your interest and inspect the logs:
$ tkn pipeline logs -f
? Select pipelinerun: [Use arrows to move, type to filter]
> vote-ui-9tb2q started 3 minutes ago
vote-api-t9tpq started 7 minutes ago
After a few minutes, the pipeline should finish successfully.
$ tkn pipelinerun list
NAME STARTED DURATION STATUS
vote-ui-9tb2q 1 minute ago 1m23s Succeeded
vote-api-t9tpq 5 minutes ago 1m31s Succeeded
Looking back at the project, you should see that the images are successfully built and deployed.
You can get the route of the application by executing the following command and access the application
$ oc get route pipelines-vote-ui --template='http://{{.spec.host}}'
If you want to re-run the pipeline again, you can use the following short-hand command to rerun the last pipelinerun again that uses the same workspaces, params and service account used in the previous pipeline run:
$ tkn pipeline start build-and-deploy --last
Whenever there is any change to your repository we need to start the pipeline explicitly to see new changes take effect.
Triggers in conjunction with pipelines enable us to hook our Pipelines to respond to external GitHub events (push events, pull requests etc).
You need an OpenShift 4 cluster running on AWS, Azure or onprem in order to complete this tutorial. If you don't have an existing cluster, go to http://try.openshift.com and register for free in order to get an OpenShift 4 cluster up and running on AWS within minutes.
NOTE: Running cluster localy crc won't work, as we need
webhook-url
to be accessable togithub-repos
Now let’s add a TriggerTemplate, TriggerBinding, and an EventListener to our project.
A TriggerTemplate
is a resource that has parameters that can be substituted anywhere within the resources of a template.
The definition of our TriggerTemplate is given in 03_triggers/02-template.yaml
.
apiVersion: triggers.tekton.dev/v1beta1
kind: TriggerTemplate
metadata:
name: vote-app
spec:
params:
- name: git-repo-url
description: The git repository url
- name: git-revision
description: The git revision
default: master
- name: git-repo-name
description: The name of the deployment to be created / patched
resourcetemplates:
- apiVersion: tekton.dev/v1
kind: PipelineRun
metadata:
generateName: build-deploy-$(tt.params.git-repo-name)-
spec:
taskRunTemplate:
serviceAccountName: pipeline
pipelineRef:
name: build-and-deploy
params:
- name: deployment-name
value: $(tt.params.git-repo-name)
- name: git-url
value: $(tt.params.git-repo-url)
- name: git-revision
value: $(tt.params.git-revision)
- name: IMAGE
value: image-registry.openshift-image-registry.svc:5000/$(context.pipelineRun.namespace)/$(tt.params.git-repo-name)
workspaces:
- name: shared-workspace
volumeClaimTemplate:
spec:
accessModes:
- ReadWriteOnce
resources:
requests:
storage: 500Mi
Run the following command to apply Triggertemplate.
$ oc create -f https://raw.githubusercontent.com/openshift/pipelines-tutorial/master/03_triggers/02_template.yaml
TriggerBindings is a map enable you to capture fields from an event and store them as parameters, and replace them in triggerTemplate whenever an event occurs.
The definition of our TriggerBinding is given in 03_triggers/01_binding.yaml
.
apiVersion: triggers.tekton.dev/v1beta1
kind: TriggerBinding
metadata:
name: vote-app
spec:
params:
- name: git-repo-url
value: $(body.repository.url)
- name: git-repo-name
value: $(body.repository.name)
- name: git-revision
value: $(body.head_commit.id)
The exact paths (keys) of the parameters we need can be found by examining the event payload (eg: GitHub events).
Run the following command to apply TriggerBinding.
$ oc create -f https://raw.githubusercontent.com/openshift/pipelines-tutorial/master/03_triggers/01_binding.yaml
Trigger
combines TriggerTemplate, TriggerBindings and interceptors. They are used as ref inside the EventListener.
The definition of our Trigger is given in 03_triggers/03_trigger.yaml
.
apiVersion: triggers.tekton.dev/v1beta1
kind: Trigger
metadata:
name: vote-trigger
spec:
serviceAccountName: pipeline
interceptors:
- ref:
name: "github"
params:
- name: "secretRef"
value:
secretName: github-secret
secretKey: secretToken
- name: "eventTypes"
value: ["push"]
bindings:
- ref: vote-app
template:
ref: vote-app
The secret is to verify events are coming from the correct source code management.
---
apiVersion: v1
kind: Secret
metadata:
name: github-secret
type: Opaque
stringData:
secretToken: "1234567"
Run the following command to apply Trigger.
$ oc create -f https://raw.githubusercontent.com/openshift/pipelines-tutorial/master/03_triggers/03_trigger.yaml
This component sets up a Service and listens for events. It also connects a TriggerTemplate to a TriggerBinding, into an addressable endpoint (the event sink)
The definition for our EventListener can be found in
03_triggers/04_event_listener.yaml
.
apiVersion: triggers.tekton.dev/v1beta1
kind: EventListener
metadata:
name: vote-app
spec:
serviceAccountName: pipeline
triggers:
- triggerRef: vote-trigger
- Run the following command to create EventListener.
$ oc create -f https://raw.githubusercontent.com/openshift/pipelines-tutorial/master/03_triggers/04_event_listener.yaml
Note: EventListener will setup a Service. We need to expose that Service as an OpenShift Route to make it publicly accessible.
- Run the below command to expose the EventListener service as a route
$ oc expose svc el-vote-app
Now we need to configure webhook-url on backend and frontend source code repositories with the Route we exposed previously.
- Run the below command to get webhook-url
$ echo "URL: $(oc get route el-vote-app --template='http://{{.spec.host}}')"
Note:
Fork the backend and frontend source code repositories so that you have sufficient privileges to configure GitHub webhooks.
Open the forked GitHub repo (Go to Settings > Webhook).
Click on Add Webhook
> Add
$ echo "$(oc get route el-vote-app --template='http://{{.spec.host}}')"
to payload URL > Select Content type as application/json
> Add secret eg: 1234567
> Click on Add Webhook
- Follow the above procedure to configure the webhook on frontend repo
Now we should see a webhook configured on your forked source code repositories (on our GitHub Repo, go to Settings>Webhooks).
Great!, We have configured webhooks
When we perform any push event on the backend the following should happen.
-
The configured webhook in vote-api GitHub repository should push the event payload to our route (exposed EventListener Service).
-
The Event-Listener will pass the event to the TriggerBinding and TriggerTemplate pair.
-
TriggerBinding will extract parameters needed for rendering the TriggerTemplate. Successful rendering of TriggerTemplate should create 2 PipelineResources (source-repo-vote-api and image-source-vote-api) and a PipelineRun (build-deploy-vote-api)
We can test this by pushing a commit to vote-api repository from GitHub web ui or from the terminal.
Let’s push an empty commit to vote-api repository.
$ git commit -m "empty-commit" --allow-empty && git push origin master
...
Writing objects: 100% (1/1), 190 bytes | 190.00 KiB/s, done.
Total 1 (delta 0), reused 0 (delta 0)
To github.com:<github-username>/pipelines-vote-api.git
72c14bb..97d3115 master -> master
Watch the OpenShift WebConsole Developer perspective and a PipelineRun will be automatically created.