$ oc get priorityclasses
You can enable pod priority and preemption in your cluster. Pod priority indicates the importance of a pod relative to other pods and queues the pods based on that priority. pod preemption allows the cluster to evict, or preempt, lower-priority pods so that higher-priority pods can be scheduled if there is no available space on a suitable node pod priority also affects the scheduling order of pods and out-of-resource eviction ordering on the node.
To use priority and preemption, you create priority classes that define the relative weight of your pods. Then, reference a priority class in the pod specification to apply that weight for scheduling.
When you use the Pod Priority and Preemption feature, the scheduler orders pending pods by their priority, and a pending pod is placed ahead of other pending pods with lower priority in the scheduling queue. As a result, the higher priority pod might be scheduled sooner than pods with lower priority if its scheduling requirements are met. If a pod cannot be scheduled, scheduler continues to schedule other lower priority pods.
You can assign pods a priority class, which is a non-namespaced object that defines a mapping from a name to the integer value of the priority. The higher the value, the higher the priority.
A priority class object can take any 32-bit integer value smaller than or equal to 1000000000 (one billion). Reserve numbers larger than or equal to one billion for critical pods that must not be preempted or evicted. By default, OKD has two reserved priority classes for critical system pods to have guaranteed scheduling.
$ oc get priorityclasses
NAME VALUE GLOBAL-DEFAULT AGE
system-node-critical 2000001000 false 72m
system-cluster-critical 2000000000 false 72m
openshift-user-critical 1000000000 false 3d13h
cluster-logging 1000000 false 29s
system-node-critical - This priority class has a value of 2000001000 and is used for all pods that should never be evicted from a node. Examples of pods that have this priority class are sdn-ovs
, sdn
, and so forth. A number of critical components include the system-node-critical
priority class by default, for example:
master-api
master-controller
master-etcd
sdn
sdn-ovs
sync
system-cluster-critical - This priority class has a value of 2000000000 (two billion) and is used with pods that are important for the cluster. Pods with this priority class can be evicted from a node in certain circumstances. For example, pods configured with the system-node-critical
priority class can take priority. However, this priority class does ensure guaranteed scheduling. Examples of pods that can have this priority class are fluentd, add-on components like descheduler, and so forth.
A number of critical components include the system-cluster-critical
priority class by default, for example:
fluentd
metrics-server
descheduler
openshift-user-critical - You can use the priorityClassName
field with important pods that cannot bind their resource consumption and do not have predictable resource consumption behavior. Prometheus pods under the openshift-monitoring
and openshift-user-workload-monitoring
namespaces use the openshift-user-critical
priorityClassName
. Monitoring workloads use system-critical
as their first priorityClass
, but this causes problems when monitoring uses excessive memory and the nodes cannot evict them. As a result, monitoring drops priority to give the scheduler flexibility, moving heavy workloads around to keep critical nodes operating.
cluster-logging - This priority is used by Fluentd to make sure Fluentd pods are scheduled to nodes over other apps.
After you have one or more priority classes, you can create pods that specify a priority class name in a Pod
spec. The priority admission controller uses the priority class name field to populate the integer value of the priority. If the named priority class is not found, the pod is rejected.
When a developer creates a pod, the pod goes into a queue. If the developer configured the pod for pod priority or preemption, the scheduler picks a pod from the queue and tries to schedule the pod on a node. If the scheduler cannot find space on an appropriate node that satisfies all the specified requirements of the pod, preemption logic is triggered for the pending pod.
When the scheduler preempts one or more pods on a node, the nominatedNodeName
field of higher-priority Pod
spec is set to the name of the node, along with the nodename
field. The scheduler uses the nominatedNodeName
field to keep track of the resources reserved for pods and also provides information to the user about preemptions in the clusters.
After the scheduler preempts a lower-priority pod, the scheduler honors the graceful termination period of the pod. If another node becomes available while scheduler is waiting for the lower-priority pod to terminate, the scheduler can schedule the higher-priority pod on that node. As a result, the nominatedNodeName
field and nodeName
field of the Pod
spec might be different.
Also, if the scheduler preempts pods on a node and is waiting for termination, and a pod with a higher-priority pod than the pending pod needs to be scheduled, the scheduler can schedule the higher-priority pod instead. In such a case, the scheduler clears the nominatedNodeName
of the pending pod, making the pod eligible for another node.
Preemption does not necessarily remove all lower-priority pods from a node. The scheduler can schedule a pending pod by removing a portion of the lower-priority pods.
The scheduler considers a node for pod preemption only if the pending pod can be scheduled on the node.
Pods with the preemption policy set to Never
are placed in the scheduling queue ahead of lower-priority pods, but they cannot preempt other pods. A non-preempting pod waiting to be scheduled stays in the scheduling queue until sufficient resources are free and it can be scheduled. Non-preempting pods, like other pods, are subject to scheduler back-off. This means that if the scheduler tries unsuccessfully to schedule these pods, they are retried with lower frequency, allowing other pods with lower priority to be scheduled before them.
Non-preempting pods can still be preempted by other, high-priority pods.
If you enable pod priority and preemption, consider your other scheduler settings:
A pod disruption budget specifies the minimum number or percentage of replicas that must be up at a time. If you specify pod disruption budgets, OKD respects them when preempting pods at a best effort level. The scheduler attempts to preempt pods without violating the pod disruption budget. If no such pods are found, lower-priority pods might be preempted despite their pod disruption budget requirements.
Pod affinity requires a new pod to be scheduled on the same node as other pods with the same label.
If a pending pod has inter-pod affinity with one or more of the lower-priority pods on a node, the scheduler cannot preempt the lower-priority pods without violating the affinity requirements. In this case, the scheduler looks for another node to schedule the pending pod. However, there is no guarantee that the scheduler can find an appropriate node and pending pod might not be scheduled.
To prevent this situation, carefully configure pod affinity with equal-priority pods.
When preempting a pod, the scheduler waits for the pod graceful termination period to expire, allowing the pod to finish working and exit. If the pod does not exit after the period, the scheduler kills the pod. This graceful termination period creates a time gap between the point that the scheduler preempts the pod and the time when the pending pod can be scheduled on the node.
To minimize this gap, configure a small graceful termination period for lower-priority pods.
You apply pod priority and preemption by creating a priority class object and associating pods to the priority by using the
priorityClassName
in your pod specs.
You cannot add a priority class directly to an existing scheduled pod. |
To configure your cluster to use priority and preemption:
Create one or more priority classes:
Create a YAML file similar to the following:
apiVersion: scheduling.k8s.io/v1
kind: PriorityClass
metadata:
name: high-priority (1)
value: 1000000 (2)
preemptionPolicy: PreemptLowerPriority (3)
globalDefault: false (4)
description: "This priority class should be used for XYZ service pods only." (5)
1 | The name of the priority class object. |
2 | The priority value of the object. |
3 | Optional. Specifies whether this priority class is preempting or non-preempting. The preemption policy defaults to PreemptLowerPriority , which allows pods of that priority class to preempt lower-priority pods. If the preemption policy is set to Never , pods in that priority class are non-preempting. |
4 | Optional. Specifies whether this priority class should be used for pods without a priority class name specified. This field is false by default. Only one priority class with globalDefault set to true can exist in the cluster. If there is no priority class with globalDefault:true , the priority of pods with no priority class name is zero. Adding a priority class with globalDefault:true affects only pods created after the priority class is added and does not change the priorities of existing pods. |
5 | Optional. Describes which pods developers should use with this priority class. Enter an arbitrary text string. |
Create the priority class:
$ oc create -f <file-name>.yaml
Create a pod spec to include the name of a priority class:
Create a YAML file similar to the following:
apiVersion: v1
kind: Pod
metadata:
name: nginx
labels:
env: test
spec:
securityContext:
runAsNonRoot: true
seccompProfile:
type: RuntimeDefault
containers:
- name: nginx
image: nginx
imagePullPolicy: IfNotPresent
securityContext:
allowPrivilegeEscalation: false
capabilities:
drop: [ALL]
priorityClassName: high-priority (1)
1 | Specify the priority class to use with this pod. |
Create the pod:
$ oc create -f <file-name>.yaml
You can add the priority name directly to the pod configuration or to a pod template.