Concepts

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Pod Lifecycle

This page describes the lifecycle of a Pod.

Pod phase

A Pod’s status field is a PodStatus object, which has a phase field.

The phase of a Pod is a simple, high-level summary of where the Pod is in its lifecycle. The phase is not intended to be a comprehensive rollup of observations of Container or Pod state, nor is it intended to be a comprehensive state machine.

The number and meanings of Pod phase values are tightly guarded. Other than what is documented here, nothing should be assumed about Pods that have a given phase value.

Here are the possible values for phase:

Value Description
Pending The Pod has been accepted by the Kubernetes system, but one or more of the Container images has not been created. This includes time before being scheduled as well as time spent downloading images over the network, which could take a while.
Running The Pod has been bound to a node, and all of the Containers have been created. At least one Container is still running, or is in the process of starting or restarting.
Succeeded All Containers in the Pod have terminated in success, and will not be restarted.
Failed All Containers in the Pod have terminated, and at least one Container has terminated in failure. That is, the Container either exited with non-zero status or was terminated by the system.
Unknown For some reason the state of the Pod could not be obtained, typically due to an error in communicating with the host of the Pod.
Completed The pod has run to completion as there’s nothing to keep it running eg. Completed Jobs.
CrashLoopBackOff This means that one of the containers in the pod has exited unexpectedly, and perhaps with a non-zero error code even after restarting due to restart policy.

Pod conditions

A Pod has a PodStatus, which has an array of PodConditions through which the Pod has or has not passed. Each element of the PodCondition array has six possible fields:

Container probes

A Probe is a diagnostic performed periodically by the kubelet on a Container. To perform a diagnostic, the kubelet calls a Handler implemented by the Container. There are three types of handlers:

Each probe has one of three results:

The kubelet can optionally perform and react to two kinds of probes on running Containers:

When should you use liveness or readiness probes?

If the process in your Container is able to crash on its own whenever it encounters an issue or becomes unhealthy, you do not necessarily need a liveness probe; the kubelet will automatically perform the correct action in accordance with the Pod’s restartPolicy.

If you’d like your Container to be killed and restarted if a probe fails, then specify a liveness probe, and specify a restartPolicy of Always or OnFailure.

If you’d like to start sending traffic to a Pod only when a probe succeeds, specify a readiness probe. In this case, the readiness probe might be the same as the liveness probe, but the existence of the readiness probe in the spec means that the Pod will start without receiving any traffic and only start receiving traffic after the probe starts succeeding. If your Container needs to work on loading large data, configuration files, or migrations during startup, specify a readiness probe.

If you want your Container to be able to take itself down for maintenance, you can specify a readiness probe that checks an endpoint specific to readiness that is different from the liveness probe.

Note that if you just want to be able to drain requests when the Pod is deleted, you do not necessarily need a readiness probe; on deletion, the Pod automatically puts itself into an unready state regardless of whether the readiness probe exists. The Pod remains in the unready state while it waits for the Containers in the Pod to stop.

For more information about how to set up a liveness or readiness probe, see Configure Liveness and Readiness Probes.

Pod and Container status

For detailed information about Pod Container status, see PodStatus and ContainerStatus. Note that the information reported as Pod status depends on the current ContainerState.

Container States

Once Pod is assigned to a node by scheduler, kubelet starts creating containers using container runtime.There are three possible states of containers: Waiting, Running and Terminated. To check state of container, you can use kubectl describe pod [POD_NAME]. State is displayed for each container within that Pod.

Pod readiness gate

FEATURE STATE: Kubernetes v1.12 beta
This feature is currently in a beta state, meaning:

  • The version names contain beta (e.g. v2beta3).
  • Code is well tested. Enabling the feature is considered safe. Enabled by default.
  • Support for the overall feature will not be dropped, though details may change.
  • The schema and/or semantics of objects may change in incompatible ways in a subsequent beta or stable release. When this happens, we will provide instructions for migrating to the next version. This may require deleting, editing, and re-creating API objects. The editing process may require some thought. This may require downtime for applications that rely on the feature.
  • Recommended for only non-business-critical uses because of potential for incompatible changes in subsequent releases. If you have multiple clusters that can be upgraded independently, you may be able to relax this restriction.
  • Please do try our beta features and give feedback on them! After they exit beta, it may not be practical for us to make more changes.

In order to add extensibility to Pod readiness by enabling the injection of extra feedbacks or signals into PodStatus, Kubernetes 1.11 introduced a feature named Pod ready++. You can use the new field ReadinessGate in the PodSpec to specify additional conditions to be evaluated for Pod readiness. If Kubernetes cannot find such a condition in the status.conditions field of a Pod, the status of the condition is default to “False”. Below is an example:

Kind: Pod
...
spec:
  readinessGates:
    - conditionType: "www.example.com/feature-1"
status:
  conditions:
    - type: Ready  # this is a builtin PodCondition
      status: "True"
      lastProbeTime: null
      lastTransitionTime: 2018-01-01T00:00:00Z
    - type: "www.example.com/feature-1"   # an extra PodCondition
      status: "False"
      lastProbeTime: null
      lastTransitionTime: 2018-01-01T00:00:00Z
  containerStatuses:
    - containerID: docker://abcd...
      ready: true
...

The new Pod conditions must comply with Kubernetes label key format. Since the kubectl patch command still doesn’t support patching object status, the new Pod conditions have to be injected through the PATCH action using one of the KubeClient libraries.

With the introduction of new Pod conditions, a Pod is evaluated to be ready only when both the following statements are true:

To facilitate this change to Pod readiness evaluation, a new Pod condition ContainersReady is introduced to capture the old Pod Ready condition.

In K8s 1.11, as an alpha feature, the “Pod Ready++” feature has to be explicitly enabled by setting the PodReadinessGates feature gate to true.

In K8s 1.12, the feature is enabled by default.

Restart policy

A PodSpec has a restartPolicy field with possible values Always, OnFailure, and Never. The default value is Always. restartPolicy applies to all Containers in the Pod. restartPolicy only refers to restarts of the Containers by the kubelet on the same node. Exited Containers that are restarted by the kubelet are restarted with an exponential back-off delay (10s, 20s, 40s …) capped at five minutes, and is reset after ten minutes of successful execution. As discussed in the Pods document, once bound to a node, a Pod will never be rebound to another node.

Pod lifetime

In general, Pods do not disappear until someone destroys them. This might be a human or a controller. The only exception to this rule is that Pods with a phase of Succeeded or Failed for more than some duration (determined by terminated-pod-gc-threshold in the master) will expire and be automatically destroyed.

Three types of controllers are available:

All three types of controllers contain a PodTemplate. It is recommended to create the appropriate controller and let it create Pods, rather than directly create Pods yourself. That is because Pods alone are not resilient to machine failures, but controllers are.

If a node dies or is disconnected from the rest of the cluster, Kubernetes applies a policy for setting the phase of all Pods on the lost node to Failed.

Examples

Advanced liveness probe example

Liveness probes are executed by the kubelet, so all requests are made in the kubelet network namespace.

apiVersion: v1
kind: Pod
metadata:
  labels:
    test: liveness
  name: liveness-http
spec:
  containers:
  - args:
    - /server
    image: k8s.gcr.io/liveness
    livenessProbe:
      httpGet:
        # when "host" is not defined, "PodIP" will be used
        # host: my-host
        # when "scheme" is not defined, "HTTP" scheme will be used. Only "HTTP" and "HTTPS" are allowed
        # scheme: HTTPS
        path: /healthz
        port: 8080
        httpHeaders:
        - name: X-Custom-Header
          value: Awesome
      initialDelaySeconds: 15
      timeoutSeconds: 1
    name: liveness

Example states

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