A ReplicaSet’s purpose is to maintain a stable set of replica Pods running at any given time. As such, it is often used to guarantee the availability of a specified number of identical Pods.
A ReplicaSet is defined with fields, including a selector that specifies how to identify Pods it can acquire, a number of replicas indicating how many Pods it should be maintaining, and a pod template specifying the data of new Pods it should create to meet the number of replicas criteria. A ReplicaSet then fulfills its purpose by creating and deleting Pods as needed to reach the desired number. When a ReplicaSet needs to create new Pods, it uses its Pod template.
The link a ReplicaSet has to its Pods is via the Pods’ metadata.ownerReferences field, which specifies what resource the current object is owned by. All Pods acquired by a ReplicaSet have their owning ReplicaSet’s identifying information within their ownerReferences field. It’s through this link that the ReplicaSet knows of the state of the Pods it is maintaining and plans accordingly.
A ReplicaSet identifies new Pods to acquire by using its selector. If there is a Pod that has no OwnerReference or the OwnerReference is not a controller and it matches a ReplicaSet’s selector, it will be immediately acquired by said ReplicaSet.
A ReplicaSet ensures that a specified number of pod replicas are running at any given time. However, a Deployment is a higher-level concept that manages ReplicaSets and provides declarative updates to Pods along with a lot of other useful features. Therefore, we recommend using Deployments instead of directly using ReplicaSets, unless you require custom update orchestration or don’t require updates at all.
This actually means that you may never need to manipulate ReplicaSet objects: use a Deployment instead, and define your application in the spec section.
controllers/frontend.yaml
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Saving this manifest into frontend.yaml
and submitting it to a Kubernetes cluster will
create the defined ReplicaSet and the Pods that it manages.
kubectl apply -f https://kubernetes.io/examples/controllers/frontend.yaml
You can then get the current ReplicaSets deployed:
kubectl get rs
And see the frontend one you created:
NAME DESIRED CURRENT READY AGE
frontend 3 3 3 6s
You can also check on the state of the replicaset:
kubectl describe rs/frontend
And you will see output similar to:
Name: frontend
Namespace: default
Selector: tier=frontend,tier in (frontend)
Labels: app=guestbook
tier=frontend
Annotations: <none>
Replicas: 3 current / 3 desired
Pods Status: 3 Running / 0 Waiting / 0 Succeeded / 0 Failed
Pod Template:
Labels: app=guestbook
tier=frontend
Containers:
php-redis:
Image: gcr.io/google_samples/gb-frontend:v3
Port: 80/TCP
Requests:
cpu: 100m
memory: 100Mi
Environment:
GET_HOSTS_FROM: dns
Mounts: <none>
Volumes: <none>
Events:
FirstSeen LastSeen Count From SubobjectPath Type Reason Message
--------- -------- ----- ---- ------------- -------- ------ -------
1m 1m 1 {replicaset-controller } Normal SuccessfulCreate Created pod: frontend-qhloh
1m 1m 1 {replicaset-controller } Normal SuccessfulCreate Created pod: frontend-dnjpy
1m 1m 1 {replicaset-controller } Normal SuccessfulCreate Created pod: frontend-9si5l
And lastly you can check for the Pods brought up:
kubectl get Pods
You should see Pod information similar to:
NAME READY STATUS RESTARTS AGE
frontend-9si5l 1/1 Running 0 1m
frontend-dnjpy 1/1 Running 0 1m
frontend-qhloh 1/1 Running 0 1m
You can also verify that the owner reference of these pods is set to the frontend ReplicaSet. To do this, get the yaml of one of the Pods running:
kubectl get pods frontend-9si5l -o yaml
The output will look similar to this, with the frontend ReplicaSet’s info set in the metadata’s ownerReferences field:
apiVersion: v1
kind: Pod
metadata:
creationTimestamp: 2019-01-31T17:20:41Z
generateName: frontend-
labels:
tier: frontend
name: frontend-9si5l
namespace: default
ownerReferences:
- apiVersion: extensions/v1beta1
blockOwnerDeletion: true
controller: true
kind: ReplicaSet
name: frontend
uid: 892a2330-257c-11e9-aecd-025000000001
...
While you can create bare Pods with no problems, it is strongly recommended to make sure that the bare Pods do not have labels which match the selector of one of your ReplicaSets. The reason for this is because a ReplicaSet is not limited to owning Pods specified by its template– it can acquire other Pods in the manner specified in the previous sections.
Take the previous frontend ReplicaSet example, and the Pods specified in the following manifest:
pods/pod-rs.yaml
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As those Pods do not have a Controller (or any object) as their owner reference and match the selector of the frontend ReplicaSet, they will immediately be acquired by it.
Suppose you create the Pods after the frontend ReplicaSet has been deployed and has set up its initial Pod replicas to fulfill its replica count requirement:
kubectl apply -f https://kubernetes.io/examples/pods/pod-rs.yaml
The new Pods will be acquired by the ReplicaSet, and then immediately terminated as the ReplicaSet would be over its desired count.
Fetching the Pods:
kubectl get Pods
The output shows that the new Pods are either already terminated, or in the process of being terminated:
NAME READY STATUS RESTARTS AGE
frontend-9si5l 1/1 Running 0 1m
frontend-dnjpy 1/1 Running 0 1m
frontend-qhloh 1/1 Running 0 1m
pod2 0/1 Terminating 0 4s
If you create the Pods first:
kubectl apply -f https://kubernetes.io/examples/pods/pod-rs.yaml
And then create the ReplicaSet however:
kubectl apply -f https://kubernetes.io/examples/controllers/frontend.yaml
You shall see that the ReplicaSet has acquired the Pods and has only created new ones according to its spec until the number of its new Pods and the original matches its desired count. As fetching the Pods:
kubectl get Pods
Will reveal in its output:
NAME READY STATUS RESTARTS AGE
frontend-pxj4r 1/1 Running 0 5s
pod1 1/1 Running 0 13s
pod2 1/1 Running 0 13s
In this manner, a ReplicaSet can own a non-homogenous set of Pods
As with all other Kubernetes API objects, a ReplicaSet needs the apiVersion
, kind
, and metadata
fields.
For ReplicaSets, the kind is always just ReplicaSet.
In Kubernetes 1.9 the API version apps/v1
on the ReplicaSet kind is the current version and is enabled by default. The API version apps/v1beta2
is deprecated.
Refer to the first lines of the frontend.yaml
example for guidance.
A ReplicaSet also needs a .spec
section.
The .spec.template
is a pod template which is also
required to have labels in place. In our frontend.yaml
example we had one label: tier: frontend
.
Be careful not to overlap with the selectors of other controllers, lest they try to adopt this Pod.
For the template’s restart policy field,
.spec.template.spec.restartPolicy
, the only allowed value is Always
, which is the default.
The .spec.selector
field is a label selector. As discussed
earlier these are the labels used to identify potential Pods to acquire. In our
frontend.yaml
example, the selector was:
matchLabels:
tier: frontend
In the ReplicaSet, .spec.template.metadata.labels
must match spec.selector
, or it will
be rejected by the API.
Note: For 2 ReplicaSets specifying the same.spec.selector
but different.spec.template.metadata.labels
and.spec.template.spec
fields, each ReplicaSet ignores the Pods created by the other ReplicaSet.
You can specify how many Pods should run concurrently by setting .spec.replicas
. The ReplicaSet will create/delete
its Pods to match this number.
If you do not specify .spec.replicas
, then it defaults to 1.
To delete a ReplicaSet and all of its Pods, use kubectl delete
. The Garbage collector automatically deletes all of the dependent Pods by default.
When using the REST API or the client-go
library, you must set propagationPolicy
to Background
or Foreground
in
the -d option.
For example:
kubectl proxy --port=8080
curl -X DELETE 'localhost:8080/apis/extensions/v1beta1/namespaces/default/replicasets/frontend' \
> -d '{"kind":"DeleteOptions","apiVersion":"v1","propagationPolicy":"Foreground"}' \
> -H "Content-Type: application/json"
You can delete a ReplicaSet without affecting any of its Pods using kubectl delete
with the --cascade=false
option.
When using the REST API or the client-go
library, you must set propagationPolicy
to Orphan
.
For example:
kubectl proxy --port=8080
curl -X DELETE 'localhost:8080/apis/extensions/v1beta1/namespaces/default/replicasets/frontend' \
> -d '{"kind":"DeleteOptions","apiVersion":"v1","propagationPolicy":"Orphan"}' \
> -H "Content-Type: application/json"
Once the original is deleted, you can create a new ReplicaSet to replace it. As long
as the old and new .spec.selector
are the same, then the new one will adopt the old Pods.
However, it will not make any effort to make existing Pods match a new, different pod template.
To update Pods to a new spec in a controlled way, use a
Deployment, as ReplicaSets do not support a rolling update directly.
You can remove Pods from a ReplicaSet by changing their labels. This technique may be used to remove Pods from service for debugging, data recovery, etc. Pods that are removed in this way will be replaced automatically ( assuming that the number of replicas is not also changed).
A ReplicaSet can be easily scaled up or down by simply updating the .spec.replicas
field. The ReplicaSet controller
ensures that a desired number of Pods with a matching label selector are available and operational.
A ReplicaSet can also be a target for Horizontal Pod Autoscalers (HPA). That is, a ReplicaSet can be auto-scaled by an HPA. Here is an example HPA targeting the ReplicaSet we created in the previous example.
controllers/hpa-rs.yaml
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Saving this manifest into hpa-rs.yaml
and submitting it to a Kubernetes cluster should
create the defined HPA that autoscales the target ReplicaSet depending on the CPU usage
of the replicated Pods.
kubectl apply -f https://k8s.io/examples/controllers/hpa-rs.yaml
Alternatively, you can use the kubectl autoscale
command to accomplish the same
(and it’s easier!)
kubectl autoscale rs frontend --max=10
Deployment
is an object which can own ReplicaSets and update
them and their Pods via declarative, server-side rolling updates.
While ReplicaSets can be used independently, today they’re mainly used by Deployments as a mechanism to orchestrate Pod
creation, deletion and updates. When you use Deployments you don’t have to worry about managing the ReplicaSets that
they create. Deployments own and manage their ReplicaSets.
As such, it is recommended to use Deployments when you want ReplicaSets.
Unlike the case where a user directly created Pods, a ReplicaSet replaces Pods that are deleted or terminated for any reason, such as in the case of node failure or disruptive node maintenance, such as a kernel upgrade. For this reason, we recommend that you use a ReplicaSet even if your application requires only a single Pod. Think of it similarly to a process supervisor, only it supervises multiple Pods across multiple nodes instead of individual processes on a single node. A ReplicaSet delegates local container restarts to some agent on the node (for example, Kubelet or Docker).
Use a Job
instead of a ReplicaSet for Pods that are expected to terminate on their own
(that is, batch jobs).
Use a DaemonSet
instead of a ReplicaSet for Pods that provide a
machine-level function, such as machine monitoring or machine logging. These Pods have a lifetime that is tied
to a machine lifetime: the Pod needs to be running on the machine before other Pods start, and are
safe to terminate when the machine is otherwise ready to be rebooted/shutdown.
ReplicaSets are the successors to ReplicationControllers. The two serve the same purpose, and behave similarly, except that a ReplicationController does not support set-based selector requirements as described in the labels user guide. As such, ReplicaSets are preferred over ReplicationControllers
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