--- redirect_from: - "/docs/user-guide/liveness/" - "/docs/user-guide.liveness.html" title: Configuring Liveness and Readiness Probes --- {% capture overview %} This page shows how to configure liveness and readiness probes for Containers. The [kubelet](/docs/admin/kubelet/) uses liveness probes to know when to restart a Container. For example, liveness probes could catch a deadlock, where an application is running, but unable to make progress. Restarting a Container in such a state can help to make the application more available despite bugs. The kubelet uses readiness probes to know when a Container is ready to start accepting traffic. A Pod is considered ready when all of its Containers are ready. One use of this signal is to control which Pods are used as backends for Services. When a Pod is not ready, it is removed from Service load balancers. {% endcapture %} {% capture prerequisites %} {% include task-tutorial-prereqs.md %} {% endcapture %} {% capture steps %} ## Defining a liveness command Many applications running for long periods of time eventually transition to broken states, and cannot recover except by being restarted. Kubernetes provides liveness probes to detect and remedy such situations. In this exercise, you create a Pod that runs a Container based on the `gcr.io/google_containers/busybox` image. Here is the configuration file for the Pod: {% include code.html language="yaml" file="exec-liveness.yaml" ghlink="/docs/tasks/configure-pod-container/exec-liveness.yaml" %} In the configuration file, you can see that the Pod has a single Container. The `livenessProbe` field specifies that the kubelet should perform a liveness probe every 5 seconds. The `initialDelaySeconds` field tells the kubelet that it should wait 5 second before performing the first probe. To perform a probe, the kubelet executes the command `cat /tmp/healthy` in the Container. If the command succeeds, it returns 0, and the kubelet considers the Container to be alive and healthy. If the command returns a non-zero value, the kubelet kills the Container and restarts it. When the Container starts, it executes this command: ```shell /bin/sh -c "touch /tmp/healthy; sleep 30; rm -rf /tmp/healthy; sleep 600" ``` For the first 30 seconds of the Container's life, there is a `/tmp/healthy` file. So during the first 30 seconds, the command `cat /tmp/healthy` returns a success code. After 30 seconds, `cat /tmp/healthy` returns a failure code. Create the Pod: ```shell kubectl create -f http://k8s.io/docs/tasks/configure-pod-container/exec-liveness.yaml ``` Within 30 seconds, view the Pod events: ``` kubectl describe pod liveness-exec ``` The output indicates that no liveness probes have failed yet: ```shell FirstSeen LastSeen Count From SubobjectPath Type Reason Message --------- -------- ----- ---- ------------- -------- ------ ------- 24s 24s 1 {default-scheduler } Normal Scheduled Successfully assigned liveness-exec to worker0 23s 23s 1 {kubelet worker0} spec.containers{liveness} Normal Pulling pulling image "gcr.io/google_containers/busybox" 23s 23s 1 {kubelet worker0} spec.containers{liveness} Normal Pulled Successfully pulled image "gcr.io/google_containers/busybox" 23s 23s 1 {kubelet worker0} spec.containers{liveness} Normal Created Created container with docker id 86849c15382e; Security:[seccomp=unconfined] 23s 23s 1 {kubelet worker0} spec.containers{liveness} Normal Started Started container with docker id 86849c15382e ``` After 30 seconds, view the Pod events again: ```shell kubectl describe pod liveness-exec ``` At the bottom of the output, there are messages indicating that the liveness probes have failed, and the containers have been killed and recreated. ```shell FirstSeen LastSeen Count From SubobjectPath Type Reason Message --------- -------- ----- ---- ------------- -------- ------ ------- 37s 37s 1 {default-scheduler } Normal Scheduled Successfully assigned liveness-exec to worker0 36s 36s 1 {kubelet worker0} spec.containers{liveness} Normal Pulling pulling image "gcr.io/google_containers/busybox" 36s 36s 1 {kubelet worker0} spec.containers{liveness} Normal Pulled Successfully pulled image "gcr.io/google_containers/busybox" 36s 36s 1 {kubelet worker0} spec.containers{liveness} Normal Created Created container with docker id 86849c15382e; Security:[seccomp=unconfined] 36s 36s 1 {kubelet worker0} spec.containers{liveness} Normal Started Started container with docker id 86849c15382e 2s 2s 1 {kubelet worker0} spec.containers{liveness} Warning Unhealthy Liveness probe failed: cat: can't open '/tmp/healthy': No such file or directory ``` Wait another 30 seconds, and verify that the Container has been restarted: ```shell kubectl get pod liveness-exec ``` The output shows that `RESTARTS` has been incremented: ```shell NAME READY STATUS RESTARTS AGE liveness-exec 1/1 Running 1 1m ``` ## Defining a liveness HTTP request Another kind of liveness probe uses an HTTP GET request. Here is the configuration file for a Pod that runs a container based on the `gcr.io/google_containers/liveness` image. {% include code.html language="yaml" file="http-liveness.yaml" ghlink="/docs/tasks/configure-pod-container/http-liveness.yaml" %} In the configuration file, you can see that the Pod has a single Container. The `livenessProbe` field specifies that the kubelet should perform a liveness probe every 3 seconds. The `initialDelaySeconds` field tells the kubelet that it should wait 3 seconds before performing the first probe. To perform a probe, the kubelet sends an HTTP GET request to the server that is running in the Container and listening on port 8080. If the handler for the server's `/healthz` path returns a success code, the kubelet considers the Container to be alive and healthy. If the handler returns a failure code, the kubelet kills the Container and restarts it. Any code greater than or equal to 200 and less than 400 indicates success. Any other code indicates failure. You can see the source code for the server in [server.go](http://k8s.io/docs/user-guide/liveness/image/server.go). For the first 10 seconds that the Container is alive, the `/healthz` handler returns a status of 200. After that, the handler returns a status of 500. ```go http.HandleFunc("/healthz", func(w http.ResponseWriter, r *http.Request) { duration := time.Now().Sub(started) if duration.Seconds() > 10 { w.WriteHeader(500) w.Write([]byte(fmt.Sprintf("error: %v", duration.Seconds()))) } else { w.WriteHeader(200) w.Write([]byte("ok")) } ``` The kubelet starts performing health checks 3 seconds after the Container starts. So the first couple of health checks will succeed. But after 10 seconds, the health checks will fail, and the kubelet will kill and restart the Container. To try the HTTP liveness check, create a Pod: ```shell kubectl create -f http://k8s.io/docs/tasks/configure-pod-container/http-liveness.yaml ``` After 10 seconds, view Pod events to verify that liveness probes have failed and the Container has been restarted: ```shell kubectl describe pod liveness-http ``` ## Using a named port You can use a named [ContainerPort](/docs/api-reference/v1/definitions/#_v1_containerport) for HTTP liveness checks: ```yaml ports: - name: liveness-port containerPort: 8080 hostPort: 8080 livenessProbe: httpGet: path: /healthz port: liveness-port ``` ## Defining readiness probes Sometimes, applications are temporarily unable to serve traffic. For example, an application might need to load large data or configuration files during startup. In such cases, you don't want to kill the application, but you don’t want to send it requests either. Kubernetes provides readiness probes to detect and mitigate these situations. A pod with containers reporting that they are not ready does not receive traffic through Kubernetes Services. Readiness probes are configured similarly to liveness probes. The only difference is that you use the `readinessProbe` field instead of the `livenessProbe` field. ```yaml readinessProbe: exec: command: - cat - /tmp/healthy initialDelaySeconds: 5 periodSeconds: 5 ``` {% endcapture %} {% capture discussion %} ## Discussion {% comment %} Eventually, some of this Discussion section could be moved to a concept topic. {% endcomment %} [Probes](/docs/api-reference/v1/definitions/#_v1_probe) have these additional fields that you can use to more precisely control the behavior of liveness and readiness checks: * timeoutSeconds * successThreshold * failureThreshold [HTTP probes](/docs/api-reference/v1/definitions/#_v1_httpgetaction) have these additional fields: * host * scheme * httpHeaders For an HTTP probe, the kubelet sends an HTTP request to the specified path and port to perform the check. The kubelet sends the probe to the container’s IP address, unless the address is overridden by the optional `host` field in `httpGet`. In most scenarios, you do not want to set the `host` field. Here's one scenario where you would set it. Suppose the Container listens on 127.0.0.1 and the Pod's `hostNetwork` field is true. Then `host`, under `httpGet`, should be set to 127.0.0.1. If your pod relies on virtual hosts, which is probably the more common case, you should not use `host`, but rather set the `Host` header in `httpHeaders`. In addition to command probes and HTTP probes, Kubenetes supports [TCP probes](/docs/api-reference/v1/definitions/#_v1_tcpsocketaction). {% endcapture %} {% capture whatsnext %} * Learn more about [Container Probes](/docs/user-guide/pod-states/#container-probes). * Learn more about [Health Checking section](/docs/user-guide/walkthrough/k8s201/#health-checking). ### Reference * [Pod](http://kubernetes.io/docs/api-reference/v1/definitions#_v1_pod) * [Container](/docs/api-reference/v1/definitions/#_v1_container) * [Probe](/docs/api-reference/v1/definitions/#_v1_probe) {% endcapture %} {% include templates/task.md %}