If you are using a released version of Kubernetes, you should refer to the docs that go with that version.
The latest 1.0.x release of this document can be found [here](http://releases.k8s.io/release-1.0/docs/user-guide/pod-states.md).Documentation for other releases can be found at releases.k8s.io.
Updated: 4/14/2015
This document covers the lifecycle of a pod. It is not an exhaustive document, but an introduction to the topic.
As consistent with the overall API convention, phase is a simple, high-level summary of the phase of the lifecycle of a pod. It is not intended to be a comprehensive rollup of observations of container-level or even pod-level conditions or other state, nor is it intended to be a comprehensive state machine.
The number and meanings of PodPhase
values are tightly guarded. Other than what is documented here, nothing should be assumed about pods with a given PodPhase
.
- Pending: The pod has been accepted by the 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, at least one container has terminated in failure (exited with non-zero exit 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.
A pod containing containers that specify readiness probes will also report the Ready condition. Condition status values may be True
, False
, or Unknown
.
A Probe is a diagnostic performed periodically by the kubelet on a container. Specifically the diagnostic is one of three Handlers:
ExecAction
: executes a specified command inside the container expecting on success that the command exits with status code 0.TCPSocketAction
: performs a tcp check against the container's IP address on a specified port expecting on success that the port is open.HTTPGetAction
: performs an HTTP Get against the container's IP address on a specified port and path expecting on success that the response has a status code greater than or equal to 200 and less than 400.
Each probe will have one of three results:
Success
: indicates that the container passed the diagnostic.Failure
: indicates that the container failed the diagnostic.Unknown
: indicates that the diagnostic failed so no action should be taken.
Currently, the kubelet optionally performs two independent diagnostics on running containers which trigger action:
LivenessProbe
: indicates whether the container is live, i.e. still running. The LivenessProbe hints to the kubelet when a container is unhealthy. If the LivenessProbe fails, the kubelet will kill the container and the container will be subjected to it's RestartPolicy. The default state of Liveness before the initial delay isSuccess
. The state of Liveness for a container when no probe is provided is assumed to beSuccess
.ReadinessProbe
: indicates whether the container is ready to service requests. If the ReadinessProbe fails, the endpoints controller will remove the pod's IP address from the endpoints of all services that match the pod. Thus, the ReadinessProbe is sometimes useful to signal to the endpoints controller that even though a pod may be running, it should not receive traffic from the proxy (e.g. the container has a long startup time before it starts listening or the container is down for maintenance). The default state of Readiness before the initial delay isFailure
. The state of Readiness for a container when no probe is provided is assumed to beSuccess
.
More detailed information about the current (and previous) container statuses can be found in ContainerStatuses. The information reported depends on the current ContainerState, which may be Waiting, Running, or Terminated.
The possible values for RestartPolicy are Always
, OnFailure
, or Never
. If RestartPolicy is not set, 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. Failed containers that are restarted by Kubelet, are restarted with an exponential back-off delay, the delay is in multiples of sync-frequency 0, 1x, 2x, 4x, 8x ... capped at 5 minutes and is reset after 10 minutes of successful execution. As discussed in the pods document, once bound to a node, a pod will never be rebound to another node. This means that some kind of controller is necessary in order for a pod to survive node failure, even if just a single pod at a time is desired.
Three types of controllers are currently available:
- Use a
Job
for pods which are expected to terminate (e.g. batch computations). - Use a
ReplicationController
for pods which are not expected to terminate, and where (e.g. web servers). - Use a
DaemonSet
: Use for pods which need to run 1 per machine because they provide a machine-specific system service. If you are unsure whether to use ReplicationController or Daemon, then see Daemon Set versus Replication Controller.
ReplicationController
is only appropriate for pods with RestartPolicy = Always
.
Job
is only appropriate for pods with RestartPolicy
equal to OnFailure
or Never
.
All 3 types of controllers contain a PodTemplate, which has all the same fields as a Pod. It is recommended to create the appropriate controller and let it create pods, rather than to directly create pods yourself. That is because pods alone are not resilient to machine failures, but Controllers are.
In general, pods which are created do not disappear until someone destroys them. This might be a human or a ReplicationController
, or another controller. The only exception to this rule is that pods with a PodPhase
of Succeeded
or Failed
for more than some duration (determined by the master) will expire and be automatically reaped.
If a node dies or is disconnected from the rest of the cluster, some entity within the system (call it the NodeController for now) is responsible for applying policy (e.g. a timeout) and marking any pods on the lost node as Failed
.
-
Pod is
Running
, 1 container, container exits success- Log completion event
- If RestartPolicy is:
- Always: restart container, pod stays
Running
- OnFailure: pod becomes
Succeeded
- Never: pod becomes
Succeeded
- Always: restart container, pod stays
-
Pod is
Running
, 1 container, container exits failure- Log failure event
- If RestartPolicy is:
- Always: restart container, pod stays
Running
- OnFailure: restart container, pod stays
Running
- Never: pod becomes
Failed
- Always: restart container, pod stays
-
Pod is
Running
, 2 containers, container 1 exits failure- Log failure event
- If RestartPolicy is:
- Always: restart container, pod stays
Running
- OnFailure: restart container, pod stays
Running
- Never: pod stays
Running
- Always: restart container, pod stays
- When container 2 exits...
- Log failure event
- If RestartPolicy is:
- Always: restart container, pod stays
Running
- OnFailure: restart container, pod stays
Running
- Never: pod becomes
Failed
- Always: restart container, pod stays
-
Pod is
Running
, container becomes OOM- Container terminates in failure
- Log OOM event
- If RestartPolicy is:
- Always: restart container, pod stays
Running
- OnFailure: restart container, pod stays
Running
- Never: log failure event, pod becomes
Failed
- Always: restart container, pod stays
-
Pod is
Running
, a disk dies- All containers are killed
- Log appropriate event
- Pod becomes
Failed
- If running under a controller, pod will be recreated elsewhere
-
Pod is
Running
, its node is segmented out- NodeController waits for timeout
- NodeController marks pod
Failed
- If running under a controller, pod will be recreated elsewhere