This task shows how to use kubectl patch
to update an API object in place. The exercises in this task demonstrate a strategic merge patch and a JSON merge patch.
You need to have a Kubernetes cluster, and the kubectl command-line tool must be configured to communicate with your cluster. It is recommended to run this tutorial on a cluster with at least two nodes that are not acting as control plane hosts. If you do not already have a cluster, you can create one by using minikube or you can use one of these Kubernetes playgrounds:
To check the version, enterkubectl version
. Here's the configuration file for a Deployment that has two replicas. Each replica is a Pod that has one container:
application/deployment-patch.yaml
Create the Deployment:
kubectl apply -f https://k8s.io/examples/application/deployment-patch.yaml
View the Pods associated with your Deployment:
kubectl get pods
The output shows that the Deployment has two Pods. The 1/1
indicates that each Pod has one container:
NAME READY STATUS RESTARTS AGE
patch-demo-28633765-670qr 1/1 Running 0 23s
patch-demo-28633765-j5qs3 1/1 Running 0 23s
Make a note of the names of the running Pods. Later, you will see that these Pods get terminated and replaced by new ones.
At this point, each Pod has one Container that runs the nginx image. Now suppose you want each Pod to have two containers: one that runs nginx and one that runs redis.
Create a file named patch-file.yaml
that has this content:
spec: template: spec: containers: - name: patch-demo-ctr-2 image: redis
Patch your Deployment:
kubectl patch deployment patch-demo --patch "$(cat patch-file.yaml)"
kubectl patch deployment patch-demo --patch $(Get-Content patch-file.yaml -Raw)
View the patched Deployment:
kubectl get deployment patch-demo --output yaml
The output shows that the PodSpec in the Deployment has two Containers:
containers: - image: redis imagePullPolicy: Always name: patch-demo-ctr-2 ... - image: nginx imagePullPolicy: Always name: patch-demo-ctr ...
View the Pods associated with your patched Deployment:
kubectl get pods
The output shows that the running Pods have different names from the Pods that were running previously. The Deployment terminated the old Pods and created two new Pods that comply with the updated Deployment spec. The 2/2
indicates that each Pod has two Containers:
NAME READY STATUS RESTARTS AGE
patch-demo-1081991389-2wrn5 2/2 Running 0 1m
patch-demo-1081991389-jmg7b 2/2 Running 0 1m
Take a closer look at one of the patch-demo Pods:
kubectl get pod <your-pod-name> --output yaml
The output shows that the Pod has two Containers: one running nginx and one running redis:
containers:
- image: redis
...
- image: nginx
...
The patch you did in the preceding exercise is called a strategic merge patch. Notice that the patch did not replace the containers
list. Instead it added a new Container to the list. In other words, the list in the patch was merged with the existing list. This is not always what happens when you use a strategic merge patch on a list. In some cases, the list is replaced, not merged.
With a strategic merge patch, a list is either replaced or merged depending on its patch strategy. The patch strategy is specified by the value of the patchStrategy
key in a field tag in the Kubernetes source code. For example, the Containers
field of PodSpec
struct has a patchStrategy
of merge
:
type PodSpec struct { ... Containers []Container `json:"containers" patchStrategy:"merge" patchMergeKey:"name" ...`
You can also see the patch strategy in the OpenApi spec:
"io.k8s.api.core.v1.PodSpec": { ... "containers": { "description": "List of containers belonging to the pod. ... }, "x-kubernetes-patch-merge-key": "name", "x-kubernetes-patch-strategy": "merge" },
And you can see the patch strategy in the Kubernetes API documentation.
Create a file named patch-file-tolerations.yaml
that has this content:
spec: template: spec: tolerations: - effect: NoSchedule key: disktype value: ssd
Patch your Deployment:
kubectl patch deployment patch-demo --patch "$(cat patch-file-tolerations.yaml)"
View the patched Deployment:
kubectl get deployment patch-demo --output yaml
The output shows that the PodSpec in the Deployment has only one Toleration:
tolerations: - effect: NoSchedule key: disktype value: ssd
Notice that the tolerations
list in the PodSpec was replaced, not merged. This is because the Tolerations field of PodSpec does not have a patchStrategy
key in its field tag. So the strategic merge patch uses the default patch strategy, which is replace
.
type PodSpec struct { ... Tolerations []Toleration `json:"tolerations,omitempty" protobuf:"bytes,22,opt,name=tolerations"`
A strategic merge patch is different from a JSON merge patch. With a JSON merge patch, if you want to update a list, you have to specify the entire new list. And the new list completely replaces the existing list.
The kubectl patch
command has a type
parameter that you can set to one of these values:
Parameter value | Merge type |
---|---|
json | JSON Patch, RFC 6902 |
merge | JSON Merge Patch, RFC 7386 |
strategic | Strategic merge patch |
For a comparison of JSON patch and JSON merge patch, see JSON Patch and JSON Merge Patch.
The default value for the type
parameter is strategic
. So in the preceding exercise, you did a strategic merge patch.
Next, do a JSON merge patch on your same Deployment. Create a file named patch-file-2.yaml
that has this content:
spec: template: spec: containers: - name: patch-demo-ctr-3 image: gcr.io/google-samples/node-hello:1.0
In your patch command, set type
to merge
:
kubectl patch deployment patch-demo --type merge --patch "$(cat patch-file-2.yaml)"
View the patched Deployment:
kubectl get deployment patch-demo --output yaml
The containers
list that you specified in the patch has only one Container. The output shows that your list of one Container replaced the existing containers
list.
spec: containers: - image: gcr.io/google-samples/node-hello:1.0 ... name: patch-demo-ctr-3
List the running Pods:
kubectl get pods
In the output, you can see that the existing Pods were terminated, and new Pods were created. The 1/1
indicates that each new Pod is running only one Container.
NAME READY STATUS RESTARTS AGE patch-demo-1307768864-69308 1/1 Running 0 1m patch-demo-1307768864-c86dc 1/1 Running 0 1m
Here's the configuration file for a Deployment that uses the RollingUpdate
strategy:
application/deployment-retainkeys.yaml
Create the deployment:
kubectl apply -f https://k8s.io/examples/application/deployment-retainkeys.yaml
At this point, the deployment is created and is using the RollingUpdate
strategy.
Create a file named patch-file-no-retainkeys.yaml
that has this content:
spec: strategy: type: Recreate
Patch your Deployment:
kubectl patch deployment retainkeys-demo --type merge --patch "$(cat patch-file-no-retainkeys.yaml)"
kubectl patch deployment retainkeys-demo --type merge --patch $(Get-Content patch-file-no-retainkeys.yaml -Raw)
In the output, you can see that it is not possible to set type
as Recreate
when a value is defined for spec.strategy.rollingUpdate
:
The Deployment "retainkeys-demo" is invalid: spec.strategy.rollingUpdate: Forbidden: may not be specified when strategy `type` is 'Recreate'
The way to remove the value for spec.strategy.rollingUpdate
when updating the value for type
is to use the retainKeys
strategy for the strategic merge.
Create another file named patch-file-retainkeys.yaml
that has this content:
spec: strategy: $retainKeys: - type type: Recreate
With this patch, we indicate that we want to retain only the type
key of the strategy
object. Thus, the rollingUpdate
will be removed during the patch operation.
Patch your Deployment again with this new patch:
kubectl patch deployment retainkeys-demo --type merge --patch "$(cat patch-file-retainkeys.yaml)"
kubectl patch deployment retainkeys-demo --type merge --patch $(Get-Content patch-file-retainkeys.yaml -Raw)
Examine the content of the Deployment:
kubectl get deployment retainkeys-demo --output yaml
The output shows that the strategy object in the Deployment does not contain the rollingUpdate
key anymore:
spec: strategy: type: Recreate template:
The patch you did in the preceding exercise is called a strategic merge patch with retainKeys strategy. This method introduces a new directive $retainKeys
that has the following strategies:
$retainKeys
list.$retainKeys
list must be a superset or the same as the fields present in the patch.The retainKeys
strategy does not work for all objects. It only works when the value of the patchStrategy
key in a field tag in the Kubernetes source code contains retainKeys
. For example, the Strategy
field of the DeploymentSpec
struct has a patchStrategy
of retainKeys
:
type DeploymentSpec struct { ... // +patchStrategy=retainKeys Strategy DeploymentStrategy `json:"strategy,omitempty" patchStrategy:"retainKeys" ...`
You can also see the retainKeys
strategy in the OpenApi spec:
"io.k8s.api.apps.v1.DeploymentSpec": { ... "strategy": { "$ref": "#/definitions/io.k8s.api.apps.v1.DeploymentStrategy", "description": "The deployment strategy to use to replace existing pods with new ones.", "x-kubernetes-patch-strategy": "retainKeys" },
And you can see the retainKeys
strategy in the Kubernetes API documentation.
The kubectl patch
command takes YAML or JSON. It can take the patch as a file or directly on the command line.
Create a file named patch-file.json
that has this content:
{ "spec": { "template": { "spec": { "containers": [ { "name": "patch-demo-ctr-2", "image": "redis" } ] } } } }
The following commands are equivalent:
kubectl patch deployment patch-demo --patch "$(cat patch-file.yaml)" kubectl patch deployment patch-demo --patch 'spec:\n template:\n spec:\n containers:\n - name: patch-demo-ctr-2\n image: redis' kubectl patch deployment patch-demo --patch "$(cat patch-file.json)" kubectl patch deployment patch-demo --patch '{"spec": {"template": {"spec": {"containers": [{"name": "patch-demo-ctr-2","image": "redis"}]}}}}'
In this exercise, you used kubectl patch
to change the live configuration of a Deployment object. You did not change the configuration file that you originally used to create the Deployment object. Other commands for updating API objects include kubectl annotate, kubectl edit, kubectl replace, kubectl scale, and kubectl apply.
© 2022 The Kubernetes Authors
Documentation Distributed under CC BY 4.0.
https://kubernetes.io/docs/tasks/manage-kubernetes-objects/update-api-object-kubectl-patch