Kubernetes v1.9 alpha
This feature is currently in a alpha state, meaning:
Pods in Kubernetes 1.8 and later can have priority. Priority indicates the importance of a Pod relative to other Pods. When a Pod cannot be scheduled, the scheduler tries to preempt (evict) lower priority Pods to make scheduling of the pending Pod possible. In Kubernetes 1.9 and later, Priority also affects scheduling order of pods and out-of-resource eviction ordering on the Node.
To use priority and preemption in Kubernetes 1.8 and later, follow these steps:
Enable the feature.
Add one or more PriorityClasses.
Create Pods with
PriorityClassName set to one of the added PriorityClasses.
Of course you do not need to create the Pods directly; normally you would add
PriorityClassName to the Pod template of a collection object like a Deployment.
The following sections provide more information about these steps.
Pod priority and preemption is disabled by default in Kubernetes 1.8. To enable the feature, set this command-line flag for the API server, scheduler and kubelet:
Also enable scheduling.k8s.io/v1alpha1 API and Priority admission controller in API server:
If you try the feature and then decide to disable it, you must remove the PodPriority command-line flag or set it to false, and then restart the API server and scheduler. After the feature is disabled, the existing Pods keep their priority fields, but preemption is disabled, and priority fields are ignored, and you cannot set PriorityClassName in new Pods.
A PriorityClass is a non-namespaced object that defines a mapping from a priority
class name to the integer value of the priority. The name is specified in the
field of the PriorityClass object’s metadata. The value is specified in the required
value field. The higher the value, the higher the priority.
A PriorityClass object can have any 32-bit integer value smaller than or equal to 1 billion. Larger numbers are reserved for critical system Pods that should not normally be preempted or evicted. A cluster admin should create one PriorityClass object for each such mapping that they want.
PriorityClass also has two optional fields:
globalDefault field indicates that the value of this PriorityClass should
be used for Pods without a
PriorityClassName. Only one PriorityClass with
globalDefault set to true can exist in the system. If there is no PriorityClass
globalDefault set, the priority of Pods with no
PriorityClassName is zero.
description field is an arbitrary string. It is meant to tell users of
the cluster when they should use this PriorityClass.
Note 1: If you upgrade your existing cluster and enable this feature, the priority of your existing Pods will be considered to be zero.
Note 2: Addition of a PriorityClass with
globalDefault set to true does not
change the priorities of existing Pods. The value of such a PriorityClass is used only
for Pods created after the PriorityClass is added.
Note 3: If you delete a PriorityClass, existing Pods that use the name of the deleted priority class remain unchanged, but you are not able to create more Pods that use the name of the deleted PriorityClass.
apiVersion: scheduling.k8s.io/v1alpha1 kind: PriorityClass metadata: name: high-priority value: 1000000 globalDefault: false description: "This priority class should be used for XYZ service pods only."
After you have one or more PriorityClasses, you can create Pods that specify one
of those PriorityClass names in their specifications. The priority admission
controller uses the
priorityClassName field and populates the integer value
of the priority. If the priority class is not found, the Pod is rejected.
The following YAML is an example of a Pod configuration that uses the PriorityClass created in the preceding example. The priority admission controller checks the specification and resolves the priority of the Pod to 1000000.
apiVersion: v1 kind: Pod metadata: name: nginx labels: env: test spec: containers: - name: nginx image: nginx imagePullPolicy: IfNotPresent priorityClassName: high-priority
In Kubernetes 1.9 and later, when Pod priority is enabled, 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 may by scheduled sooner that pods with lower priority if its scheduling requirements are met. If such pod cannot be scheduled, scheduler will continue and tries to schedule other lower priority Pods.
When Pods are created, they go to a queue and wait to be scheduled. The scheduler picks a Pod from the queue and tries to schedule it on a Node. If no Node is found that satisfies all the specified requirements of the Pod, preemption logic is triggered for the pending Pod. Let’s call the pending pod P. Preemption logic tries to find a Node where removal of one or more Pods with lower priority than P would enable P to be scheduled on that Node. If such a Node is found, one or more lower priority Pods get deleted from the Node. After the Pods are gone, P can be scheduled on the Node.
When Pods are preempted, the victims get their graceful termination period. They have that much time to finish their work and exit. If they don’t, they are killed. This graceful termination period creates a time gap between the point that the scheduler preempts Pods and the time when the pending Pod (P) can be scheduled on the Node (N). In the meantime, the scheduler keeps scheduling other pending Pods. As victims exit or get terminated, the scheduler tries to schedule Pods in the pending queue. Therefore, there is usually a time gap between the point that scheduler preempts victims and the time that Pod P is scheduled. In order to minimize this gap, one can set graceful termination period of lower priority pods to zero or a small number.
A Pod Disruption Budget (PDB) allows application owners to limit the number Pods of a replicated application that are down simultaneously from voluntary disruptions. Kubernetes 1.9 supports PDB when preempting pods, but respecting PDB is best effort. The Scheduler tries to find victims whose PDB are not violated by preemption, but if no such victims are found, preemption will still happen, and lower priority Pods will be removed despite their PDBs being violated.
A Node is considered for preemption only when the answer to this question is yes: “If all the Pods with lower priority than the pending Pod are removed from the Node, can the pending pod be scheduled on the Node?”
Note: Preemption does not necessarily remove all lower-priority Pods. If the pending pod can be scheduled by removing fewer than all lower-priority Pods, then only a portion of the lower-priority Pods are removed. Even so, the answer to the preceding question must be yes. If the answer is no, the Node is not considered for preemption.
If a pending Pod has inter-pod affinity to one or more of the lower-priority Pods on the Node, the inter-Pod affinity rule cannot be satisfied in the absence of those lower-priority Pods. In this case, the scheduler does not preempt any Pods on the Node. Instead, it looks for another Node. The scheduler might find a suitable Node or it might not. There is no guarantee that the pending Pod can be scheduled.
Our recommended solution for this problem is to create inter-Pod affinity only towards equal or higher priority pods.
Suppose a Node N is being considered for preemption so that a pending Pod P can be scheduled on N. P might become feasible on N only if a Pod on another Node is preempted. Here’s an example:
If Pod Q were removed from its Node, the anti-affinity violation would be gone, and Pod P could possibly be scheduled on Node N.
We may consider adding cross Node preemption in future versions if we find an algorithm with reasonable performance. We cannot promise anything at this point, and cross Node preemption will not be considered a blocker for Beta or GA.Create an Issue Edit this Page