- Create a Kubernetes Cluster
- Install release v0.30.6 and use Coscheduling
- Test Coscheduling
- Install old-version releases
- Uninstall scheduler-plugins
Firstly you need to have a Kubernetes cluster, and a kubectl
command-line tool must be configured to communicate with the cluster.
The Kubernetes version must equal to or greater than v1.23.0. To check the version, use kubectl version --short
.
If you do not have a cluster yet, create one by using one of the following provision tools:
Note: we provide two ways to install the scheduler-plugin artifacts: as a second scheduler and as a single scheduler. Their pros and cons are as below:
- second scheduler:
-
pro: it's easy to install by deploying the Helm chart
-
con: running multi-scheduler will inevitably encounter resource conflicts when the cluster is short of resources.
Consider the scenario where multiple schedulers attempt to assign their pods simultaneously to a node which can only fit one of the pods. The pod that arrives later will be evicted by the kubelet, and hang there (without its
.spec.nodeName
cleared) until resources get released on the node.Running multiple schedulers, therefore, is not recommended in the production env. However, it's a good starting point to play with scheduler framework and exercise plugin development, no matter you're on managed or on-premise Kubernetes clusters.
-
- single scheduler:
- pro: you will be using a unified scheduler and hence keep the resources conflict-free. It's recommended for the production env.
- con: you have to have the privileges to manipulate the control plane, and at this moment, the installation is not fully automated (no Helm chart yet).
The quickest way to try scheduler-plugins is to install it using helm chart as a second scheduler. You can find the demo chart in manifests/install/charts. But if in the production environment, it is recommended to replace the default-scheduler manually(as described in next section).
A bit different from the automatic installation steps above, using scheduler-plugins as a single scheduler needs some manual steps.
The main obstacle here is that we need to reconfigure the vanilla scheduler, but it's challenging to get it automated as how it's deployed varies a lot (i.e., deployment, static pod, or an executable binary managed by systemd). Moreover, managed Kubernetes offerings may be cluster-specific that need extra configuration and hence hard to be pipelined nicely.
In this section, we will walk you through how to replace the default scheduler with the scheduler-plugins image. As the new image is built on top of the default scheduler, you won't lose any vanilla Kubernetes scheduling capability. Instead, a lot of extra out-of-box functionalities (implemented by the plugins in this repo) can be obtained, such as coscheduling.
The following steps are based on a Kubernetes cluster created by Kind.
-
Log into the control plane node
sudo docker exec -it $(sudo docker ps | grep control-plane | awk '{print $1}') bash
-
Backup
kube-scheduler.yaml
cp /etc/kubernetes/manifests/kube-scheduler.yaml /etc/kubernetes/kube-scheduler.yaml
-
Create
/etc/kubernetes/sched-cc.yaml
apiVersion: kubescheduler.config.k8s.io/v1 kind: KubeSchedulerConfiguration leaderElection: # (Optional) Change true to false if you are not running a HA control-plane. leaderElect: true clientConnection: kubeconfig: /etc/kubernetes/scheduler.conf profiles: - schedulerName: default-scheduler plugins: multiPoint: enabled: - name: Coscheduling disabled: - name: PrioritySort
-
❗IMPORTANT❗ Starting with release v0.19, several plugins (e.g., coscheduling) introduced CRD to optimize their design and implementation. And hence we need an extra step to:
- apply extra RBAC privileges to user
system:kube-scheduler
so that the scheduler binary is able to manipulate the custom resource objects - install a controller binary managing the custom resource objects
Next, we apply the compiled yaml located at manifests/install/all-in-one.yaml.
$ kubectl apply -f all-in-one.yaml
After this step, a deployment called
scheduler-plugins-controller
is expected to run in namespacescheduler-plugins
:$ kubectl get deploy -n scheduler-plugins NAME READY UP-TO-DATE AVAILABLE AGE scheduler-plugins-controller 1/1 1 1 19h
- apply extra RBAC privileges to user
-
❗IMPORTANT❗ Install the CRDs your workloads depend on.
You can refer to each folder under manifests/crds to obtain the CRD yaml for each plugin. Here we install coscheduling CRD:
$ kubectl apply -f manifests/crds/scheduling.x-k8s.io_podgroups.yaml
-
Modify
/etc/kubernetes/manifests/kube-scheduler.yaml
to run scheduler-plugins with coschedulingGenerally, we need to make a couple of changes:
- pass in the composed scheduler-config file via argument
--config
- (optional) remove duplicated CLI parameters (e.g.,
--leader-elect
), as they may have been defined in the config file - replace vanilla Kubernetes scheduler image with scheduler-plugin image
- mount the scheduler-config file to be readable when scheduler starting
Here is a diff:
16d15 + - --config=/etc/kubernetes/sched-cc.yaml 17a17,18 - - --kubeconfig=/etc/kubernetes/scheduler.conf - - --leader-elect=true 19,20c20 + image: registry.k8s.io/scheduler-plugins/kube-scheduler:v0.30.6 --- - image: registry.k8s.io/kube-scheduler:v1.28.9 50,52d49 + - mountPath: /etc/kubernetes/sched-cc.yaml + name: sched-cc + readOnly: true 60,63d56 + - hostPath: + path: /etc/kubernetes/sched-cc.yaml + type: FileOrCreate + name: sched-cc
- pass in the composed scheduler-config file via argument
-
Verify that kube-scheduler pod is running properly with a correct image:
registry.k8s.io/scheduler-plugins/kube-scheduler:v0.30.6
$ kubectl get pod -n kube-system | grep kube-scheduler kube-scheduler-kind-control-plane 1/1 Running 0 3m27s $ kubectl get pods -l component=kube-scheduler -n kube-system -o=jsonpath="{.items[0].spec.containers[0].image}{'\n'}" registry.k8s.io/scheduler-plugins/kube-scheduler:v0.30.6
⚠️ Troubleshooting: If the kube-scheudler is not up, you may need to restart kubelet service inside the kind control plane (systemctl restart kubelet.service
)
Now, we're able to verify how the coscheduling plugin works.
-
Create a PodGroup custom object called
pg1
:# podgroup.yaml apiVersion: scheduling.x-k8s.io/v1alpha1 kind: PodGroup metadata: name: pg1 spec: scheduleTimeoutSeconds: 10 minMember: 3
$ kubectl apply -f podgroup.yaml
-
Create a deployment labelled
scheduling.x-k8s.io/pod-group: pg1
to associated with PodGrouppg1
created in the previous step.# deploy.yaml apiVersion: apps/v1 kind: Deployment metadata: name: pause spec: replicas: 2 selector: matchLabels: app: pause template: metadata: labels: app: pause scheduling.x-k8s.io/pod-group: pg1 spec: containers: - name: pause image: registry.k8s.io/pause:3.6
⚠️ Note:️ If you are running scheduler-plugins as a second scheduler, you should explicitly specify.spec.schedulerName
to match the secondary scheduler name:# deploy.yaml ... spec: ... template: spec: schedulerName: scheduler-plugins-scheduler
-
As PodGroup
pg1
requires at least 3 pods to be scheduled all-together, and there are only 2 Pods so far, so it's expected to observer they are pending:All pods are expected to be
Pending
as they cannot be co-scheduled altogether.$ kubectl get pod NAME READY STATUS RESTARTS AGE pause-646dbcfb64-4zvt6 0/1 Pending 0 9s pause-646dbcfb64-8kpg4 0/1 Pending 0 9s
-
Now let's scale the deployment up to have 3 replicas, so as to qualify for
minMember
(i.e., 3) of the associated PodGroup:$ kubectl scale deploy pause --replicas=3 deployment.apps/pause scaled
And wait for a couple of seconds, it's expected to see all Pods get into running state:
$ kubectl get pod NAME READY STATUS RESTARTS AGE pause-646dbcfb64-4zvt6 1/1 Running 0 42s pause-646dbcfb64-8kpg4 1/1 Running 0 42s pause-646dbcfb64-npzcf 1/1 Running 0 8s
-
You can also get the PodGroup's spec via:
$ kubectl get podgroup pg1 -o yaml apiVersion: scheduling.x-k8s.io/v1alpha1 kind: PodGroup metadata: annotations: kubectl.kubernetes.io/last-applied-configuration: | {"apiVersion":"scheduling.x-k8s.io/v1alpha1","kind":"PodGroup","metadata":{"annotations":{},"name":"pg1","namespace":"default"},"spec":{"minMember":3,"scheduleTimeoutSeconds":10}} creationTimestamp: "2022-02-08T19:55:24Z" generation: 8 name: pg1 namespace: default resourceVersion: "6142" uid: b4ac3562-54ab-4c1e-89bb-541a81c6acce spec: minMember: 3 scheduleTimeoutSeconds: 10 status: phase: Running running: 3 scheduleStartTime: "2022-02-08T19:55:24Z" scheduled: 3
⚠ NOTE: There are some UX issues need to be addressed in controller side - #166.
If you're running at v0.18.9, which doesn't depend on PodGroup CRD, you should refer to the
install doc in
branch release-1.18
for detailed installation instructions.
-
Delete the deployment
$ kubectl delete deploy pause -n default
-
Recover
kube-scheduler.yaml
and deletesched-cc.yaml
-
If the cluster is created by
kubeadm
orminikube
, log into Master node:$ mv /etc/kubernetes/kube-scheduler.yaml /etc/kubernetes/manifests/ $ rm /etc/kubernetes/sched-cc.yaml
-
If the cluster is created by
kind
, enter the Master's container:$ sudo docker exec -it $(sudo docker ps | grep control-plane | awk '{print $1}') bash $ mv /etc/kubernetes/kube-scheduler.yaml /etc/kubernetes/manifests/ $ rm /etc/kubernetes/sched-cc.yaml exit
-
-
Check state of default scheduler
$ kubectl get pod -n kube-system | grep kube-scheduler kube-scheduler-kind-control-plane 1/1 Running 0 91s