strategy:
type: Rolling
rollingParams:
updatePeriodSeconds: 1 (1)
intervalSeconds: 1 (2)
timeoutSeconds: 120 (3)
maxSurge: "20%" (4)
maxUnavailable: "10%" (5)
pre: {} (6)
post: {}
A deployment strategy determines the deployment process, and is defined by the deployment configuration. Each application has different requirements for availability (and other considerations) during deployments. OpenShift Container Platform provides strategies to support a variety of deployment scenarios.
A deployment strategy uses
readiness
checks to determine if a new pod is ready for use. If a readiness check fails,
the deployment configuration will retry to run the pod until it times out. The
default timeout is 10m
, a value set in TimeoutSeconds
in
dc.spec.strategy.*params
.
The Rolling strategy is the default strategy used if no strategy is specified on a deployment configuration.
A rolling deployment slowly replaces instances of the previous version of an application with instances of the new version of the application. A rolling deployment typically waits for new pods to become ready via a readiness check before scaling down the old components. If a significant issue occurs, the rolling deployment can be aborted.
All rolling deployments in OpenShift Container Platform are canary deployments; a new version (the canary) is tested before all of the old instances are replaced. If the readiness check never succeeds, the canary instance is removed and the deployment configuration will be automatically rolled back. The readiness check is part of the application code, and may be as sophisticated as necessary to ensure the new instance is ready to be used. If you need to implement more complex checks of the application (such as sending real user workloads to the new instance), consider implementing a custom deployment or using a blue-green deployment strategy.
When you want to take no downtime during an application update.
When your application supports having old code and new code running at the same time.
A rolling deployment means you to have both old and new versions of your code running at the same time. This typically requires that your application handle N-1 compatibility, that data stored by the new version can be read and handled (or gracefully ignored) by the old version of the code. This can take many forms — data stored on disk, in a database, in a temporary cache, or that is part of a user’s browser session. While most web applications can support rolling deployments, it is important to test and design your application to handle it.
The following is an example of the Rolling strategy:
strategy:
type: Rolling
rollingParams:
updatePeriodSeconds: 1 (1)
intervalSeconds: 1 (2)
timeoutSeconds: 120 (3)
maxSurge: "20%" (4)
maxUnavailable: "10%" (5)
pre: {} (6)
post: {}
1 | The time to wait between individual pod updates. If unspecified, this value defaults to 1 . |
2 | The time to wait between polling the deployment status after update. If unspecified, this value defaults to 1 . |
3 | The time to wait for a scaling event before giving up. Optional; the default is 600 . Here, giving up means
automatically rolling back to the previous complete deployment. |
4 | maxSurge is optional and defaults to 25% if not specified. See the information below the following procedure. |
5 | maxUnavailable is optional and defaults to 25% if not specified. See the information below the following procedure. |
6 | pre and post are both lifecycle hooks. |
The Rolling strategy will:
Execute any pre
lifecycle hook.
Scale up the new replication controller based on the surge count.
Scale down the old replication controller based on the max unavailable count.
Repeat this scaling until the new replication controller has reached the desired replica count and the old replication controller has been scaled to zero.
Execute any post
lifecycle hook.
When scaling down, the Rolling strategy waits for pods to become ready so it can decide whether further scaling would affect availability. If scaled up pods never become ready, the deployment process will eventually time out and result in a deployment failure. |
The maxUnavailable
parameter is the maximum number of pods that can be
unavailable during the update. The maxSurge
parameter is the maximum number
of pods that can be scheduled above the original number of pods. Both parameters
can be set to either a percentage (e.g., 10%
) or an absolute value (e.g.,
2
). The default value for both is 25%
.
These parameters allow the deployment to be tuned for availability and speed. For example:
maxUnavailable=0
and maxSurge=20%
ensures full capacity is maintained
during the update and rapid scale up.
maxUnavailable=10%
and maxSurge=0
performs an update using no extra
capacity (an in-place update).
maxUnavailable=10%
and maxSurge=10%
scales up and down quickly with
some potential for capacity loss.
Generally, if you want fast rollouts, use maxSurge
. If you need to take into
account resource quota and can accept partial unavailability, use
maxUnavailable
.
Rolling deployments are the default in OpenShift Container Platform. To see a rolling update, follow these steps:
Create an application based on the example deployment images found in DockerHub:
$ oc new-app openshift/deployment-example
If you have the router installed, make the application available via a route (or use the service IP directly)
$ oc expose svc/deployment-example
Browse to the application at deployment-example.<project>.<router_domain>
to
verify you see the v1 image.
Scale the deployment configuration up to three replicas:
$ oc scale dc/deployment-example --replicas=3
Trigger a new deployment automatically by tagging a new version of the example
as the latest
tag:
$ oc tag deployment-example:v2 deployment-example:latest
In your browser, refresh the page until you see the v2 image.
If you are using the CLI, the following command will show you how many pods are on version 1 and how many are on version 2. In the web console, you should see the pods slowly being added to v2 and removed from v1.
$ oc describe dc deployment-example
During the deployment process, the new replication controller is incrementally scaled up. Once the new pods are marked as ready (by passing their readiness check), the deployment process will continue. If the pods do not become ready, the process will abort, and the deployment configuration will be rolled back to its previous version.
The Recreate strategy has basic rollout behavior and supports lifecycle hooks for injecting code into the deployment process.
The following is an example of the Recreate strategy:
strategy:
type: Recreate
recreateParams: (1)
pre: {} (2)
mid: {}
post: {}
1 | recreateParams are optional. |
2 | pre , mid , and post are lifecycle hooks. |
The Recreate strategy will:
Execute any pre
lifecycle hook.
Scale down the previous deployment to zero.
Execute any mid
lifecycle hook.
Scale up the new deployment.
Execute any post
lifecycle hook.
During scale up, if the replica count of the deployment is greater than one, the first replica of the deployment will be validated for readiness before fully scaling up the deployment. If the validation of the first replica fails, the deployment will be considered a failure. |
When you must run migrations or other data transformations before your new code starts.
When you do not support having new and old versions of your application code running at the same time.
When you want to use a RWO volume, which is not supported being shared between multiple replicas.
A recreate deployment incurs downtime because, for a brief period, no instances of your application are running. However, your old code and new code do not run at the same time.
The Custom strategy allows you to provide your own deployment behavior.
The following is an example of the Custom strategy:
strategy:
type: Custom
customParams:
image: organization/strategy
command: [ "command", "arg1" ]
environment:
- name: ENV_1
value: VALUE_1
In the above example, the organization/strategy
container image provides the
deployment behavior. The optional command
array overrides any CMD
directive
specified in the image’s Dockerfile. The optional environment variables
provided are added to the execution environment of the strategy process.
Additionally, OpenShift Container Platform provides the following environment variables to the deployment process:
Environment Variable | Description |
---|---|
|
The name of the new deployment (a replication controller). |
|
The name space of the new deployment. |
The replica count of the new deployment will initially be zero. The responsibility of the strategy is to make the new deployment active using the logic that best serves the needs of the user.
Learn more about advanced deployment strategies.
Alternatively, use customParams
to inject the custom deployment logic into the
existing deployment strategies. Provide a custom shell script logic and call the
openshift-deploy
binary. Users do not have to supply their custom deployer
container image, but the default OpenShift Container Platform deployer image will be used
instead:
strategy:
type: Rolling
customParams:
command:
- /bin/sh
- -c
- |
set -e
openshift-deploy --until=50%
echo Halfway there
openshift-deploy
echo Complete
This will result in following deployment:
Started deployment #2
--> Scaling up custom-deployment-2 from 0 to 2, scaling down custom-deployment-1 from 2 to 0 (keep 2 pods available, don't exceed 3 pods)
Scaling custom-deployment-2 up to 1
--> Reached 50% (currently 50%)
Halfway there
--> Scaling up custom-deployment-2 from 1 to 2, scaling down custom-deployment-1 from 2 to 0 (keep 2 pods available, don't exceed 3 pods)
Scaling custom-deployment-1 down to 1
Scaling custom-deployment-2 up to 2
Scaling custom-deployment-1 down to 0
--> Success
Complete
If the custom deployment strategy process requires access to the OpenShift Container Platform API or the Kubernetes API the container that executes the strategy can use the service account token available inside the container for authentication.
The Recreate and Rolling strategies support lifecycle hooks, which allow behavior to be injected into the deployment process at predefined points within the strategy:
The following is an example of a pre
lifecycle hook:
pre:
failurePolicy: Abort
execNewPod: {} (1)
1 | execNewPod is a pod-based lifecycle hook. |
Every hook has a failurePolicy
, which defines the action the strategy should
take when a hook failure is encountered:
|
The deployment process will be considered a failure if the hook fails. |
|
The hook execution should be retried until it succeeds. |
|
Any hook failure should be ignored and the deployment should proceed. |
Hooks have a type-specific field that describes how to execute the hook.
Currently, pod-based hooks are the only
supported hook type, specified by the execNewPod
field.
Pod-based lifecycle hooks execute hook code in a new pod derived from the template in a deployment configuration.
The following simplified example deployment configuration uses the Rolling strategy. Triggers and some other minor details are omitted for brevity:
kind: DeploymentConfig
apiVersion: v1
metadata:
name: frontend
spec:
template:
metadata:
labels:
name: frontend
spec:
containers:
- name: helloworld
image: openshift/origin-ruby-sample
replicas: 5
selector:
name: frontend
strategy:
type: Rolling
rollingParams:
pre:
failurePolicy: Abort
execNewPod:
containerName: helloworld (1)
command: [ "/usr/bin/command", "arg1", "arg2" ] (2)
env: (3)
- name: CUSTOM_VAR1
value: custom_value1
volumes:
- data (4)
1 | The helloworld name refers to spec.template.spec.containers[0].name . |
2 | This command overrides any ENTRYPOINT defined by the openshift/origin-ruby-sample image. |
3 | env is an optional set of environment variables for the hook container. |
4 | volumes is an optional set of volume references for the hook container. |
In this example, the pre
hook will be executed in a new pod using the
openshift/origin-ruby-sample image from the helloworld container. The hook
pod will have the following properties:
The hook command will be /usr/bin/command arg1 arg2
.
The hook container will have the CUSTOM_VAR1=custom_value1
environment variable.
The hook failure policy is Abort
, meaning the deployment process will fail if the hook fails.
The hook pod will inherit the data
volume from the deployment configuration pod.
The oc set deployment-hook
command can be used to set the deployment hook for
a deployment configuration. For the example above, you can set the
pre-deployment hook with the following command:
$ oc set deployment-hook dc/frontend --pre -c helloworld -e CUSTOM_VAR1=custom_value1 \ -v data --failure-policy=abort -- /usr/bin/command arg1 arg2