Configure Liveness, Readiness and Startup Probes
This page shows how to configure liveness, readiness and startup probes for containers.
The 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.
A common pattern for liveness probes is to use the same low-cost HTTP endpoint as for readiness probes, but with a higher failureThreshold. This ensures that the pod is observed as not-ready for some period of time before it is hard killed.
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.
The kubelet uses startup probes to know when a container application has started. If such a probe is configured, liveness and readiness probes do not start until it succeeds, making sure those probes don't interfere with the application startup. This can be used to adopt liveness checks on slow starting containers, avoiding them getting killed by the kubelet before they are up and running.
Before you begin
You need to have a Kubernetes cluster, and the kubectl command-line tool must be configured to communicate with your cluster. It is recommended to run this tutorial on a cluster with at least two nodes that are not acting as control plane hosts. If you do not already have a cluster, you can create one by using minikube or you can use one of these Kubernetes playgrounds:
Define 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
registry.k8s.io/busybox
image. Here is the configuration file for the Pod:
apiVersion: v1
kind: Pod
metadata:
labels:
test: liveness
name: liveness-exec
spec:
containers:
- name: liveness
image: registry.k8s.io/busybox
args:
- /bin/sh
- -c
- touch /tmp/healthy; sleep 30; rm -f /tmp/healthy; sleep 600
livenessProbe:
exec:
command:
- cat
- /tmp/healthy
initialDelaySeconds: 5
periodSeconds: 5
In the configuration file, you can see that the Pod has a single Container
.
The periodSeconds
field specifies that the kubelet should perform a liveness
probe every 5 seconds. The initialDelaySeconds
field tells the kubelet that it
should wait 5 seconds before performing the first probe. To perform a probe, the
kubelet executes the command cat /tmp/healthy
in the target 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:
/bin/sh -c "touch /tmp/healthy; sleep 30; rm -f /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:
kubectl apply -f https://k8s.io/examples/pods/probe/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:
Type Reason Age From Message
---- ------ ---- ---- -------
Normal Scheduled 11s default-scheduler Successfully assigned default/liveness-exec to node01
Normal Pulling 9s kubelet, node01 Pulling image "registry.k8s.io/busybox"
Normal Pulled 7s kubelet, node01 Successfully pulled image "registry.k8s.io/busybox"
Normal Created 7s kubelet, node01 Created container liveness
Normal Started 7s kubelet, node01 Started container liveness
After 35 seconds, view the Pod events again:
kubectl describe pod liveness-exec
At the bottom of the output, there are messages indicating that the liveness probes have failed, and the failed containers have been killed and recreated.
Type Reason Age From Message
---- ------ ---- ---- -------
Normal Scheduled 57s default-scheduler Successfully assigned default/liveness-exec to node01
Normal Pulling 55s kubelet, node01 Pulling image "registry.k8s.io/busybox"
Normal Pulled 53s kubelet, node01 Successfully pulled image "registry.k8s.io/busybox"
Normal Created 53s kubelet, node01 Created container liveness
Normal Started 53s kubelet, node01 Started container liveness
Warning Unhealthy 10s (x3 over 20s) kubelet, node01 Liveness probe failed: cat: can't open '/tmp/healthy': No such file or directory
Normal Killing 10s kubelet, node01 Container liveness failed liveness probe, will be restarted
Wait another 30 seconds, and verify that the container has been restarted:
kubectl get pod liveness-exec
The output shows that RESTARTS
has been incremented. Note that the RESTARTS
counter
increments as soon as a failed container comes back to the running state:
NAME READY STATUS RESTARTS AGE
liveness-exec 1/1 Running 1 1m
Define 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 registry.k8s.io/liveness
image.
apiVersion: v1
kind: Pod
metadata:
labels:
test: liveness
name: liveness-http
spec:
containers:
- name: liveness
image: registry.k8s.io/liveness
args:
- /server
livenessProbe:
httpGet:
path: /healthz
port: 8080
httpHeaders:
- name: Custom-Header
value: Awesome
initialDelaySeconds: 3
periodSeconds: 3
In the configuration file, you can see that the Pod has a single container.
The periodSeconds
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.
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.
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:
kubectl apply -f https://k8s.io/examples/pods/probe/http-liveness.yaml
After 10 seconds, view Pod events to verify that liveness probes have failed and the container has been restarted:
kubectl describe pod liveness-http
In releases after v1.13, local HTTP proxy environment variable settings do not affect the HTTP liveness probe.
Define a TCP liveness probe
A third type of liveness probe uses a TCP socket. With this configuration, the kubelet will attempt to open a socket to your container on the specified port. If it can establish a connection, the container is considered healthy, if it can't it is considered a failure.
apiVersion: v1
kind: Pod
metadata:
name: goproxy
labels:
app: goproxy
spec:
containers:
- name: goproxy
image: registry.k8s.io/goproxy:0.1
ports:
- containerPort: 8080
readinessProbe:
tcpSocket:
port: 8080
initialDelaySeconds: 15
periodSeconds: 10
livenessProbe:
tcpSocket:
port: 8080
initialDelaySeconds: 15
periodSeconds: 10
As you can see, configuration for a TCP check is quite similar to an HTTP check.
This example uses both readiness and liveness probes. The kubelet will send the
first readiness probe 15 seconds after the container starts. This will attempt to
connect to the goproxy
container on port 8080. If the probe succeeds, the Pod
will be marked as ready. The kubelet will continue to run this check every 10
seconds.
In addition to the readiness probe, this configuration includes a liveness probe.
The kubelet will run the first liveness probe 15 seconds after the container
starts. Similar to the readiness probe, this will attempt to connect to the
goproxy
container on port 8080. If the liveness probe fails, the container
will be restarted.
To try the TCP liveness check, create a Pod:
kubectl apply -f https://k8s.io/examples/pods/probe/tcp-liveness-readiness.yaml
After 15 seconds, view Pod events to verify that liveness probes:
kubectl describe pod goproxy
Define a gRPC liveness probe
Kubernetes v1.27 [stable]
If your application implements the gRPC Health Checking Protocol, this example shows how to configure Kubernetes to use it for application liveness checks. Similarly you can configure readiness and startup probes.
Here is an example manifest:
apiVersion: v1
kind: Pod
metadata:
name: etcd-with-grpc
spec:
containers:
- name: etcd
image: registry.k8s.io/etcd:3.5.1-0
command: [ "/usr/local/bin/etcd", "--data-dir", "/var/lib/etcd", "--listen-client-urls", "http://0.0.0.0:2379", "--advertise-client-urls", "http://127.0.0.1:2379", "--log-level", "debug"]
ports:
- containerPort: 2379
livenessProbe:
grpc:
port: 2379
initialDelaySeconds: 10
To use a gRPC probe, port
must be configured. If you want to distinguish probes of different types
and probes for different features you can use the service
field.
You can set service
to the value liveness
and make your gRPC Health Checking endpoint
respond to this request differently than when you set service
set to readiness
.
This lets you use the same endpoint for different kinds of container health check
rather than listening on two different ports.
If you want to specify your own custom service name and also specify a probe type,
the Kubernetes project recommends that you use a name that concatenates
those. For example: myservice-liveness
(using -
as a separator).
Configuration problems (for example: incorrect port or service, unimplemented health checking protocol) are considered a probe failure, similar to HTTP and TCP probes.
To try the gRPC liveness check, create a Pod using the command below. In the example below, the etcd pod is configured to use gRPC liveness probe.
kubectl apply -f https://k8s.io/examples/pods/probe/grpc-liveness.yaml
After 15 seconds, view Pod events to verify that the liveness check has not failed:
kubectl describe pod etcd-with-grpc
When using a gRPC probe, there are some technical details to be aware of:
- The probes run against the pod IP address or its hostname. Be sure to configure your gRPC endpoint to listen on the Pod's IP address.
- The probes do not support any authentication parameters (like
-tls
). - There are no error codes for built-in probes. All errors are considered as probe failures.
- If
ExecProbeTimeout
feature gate is set tofalse
, grpc-health-probe does not respect thetimeoutSeconds
setting (which defaults to 1s), while built-in probe would fail on timeout.
Use a named port
You can use a named port
for HTTP and TCP probes. gRPC probes do not support named ports.
For example:
ports:
- name: liveness-port
containerPort: 8080
hostPort: 8080
livenessProbe:
httpGet:
path: /healthz
port: liveness-port
Protect slow starting containers with startup probes
Sometimes, you have to deal with legacy applications that might require
an additional startup time on their first initialization.
In such cases, it can be tricky to set up liveness probe parameters without
compromising the fast response to deadlocks that motivated such a probe.
The trick is to set up a startup probe with the same command, HTTP or TCP
check, with a failureThreshold * periodSeconds
long enough to cover the
worst case startup time.
So, the previous example would become:
ports:
- name: liveness-port
containerPort: 8080
hostPort: 8080
livenessProbe:
httpGet:
path: /healthz
port: liveness-port
failureThreshold: 1
periodSeconds: 10
startupProbe:
httpGet:
path: /healthz
port: liveness-port
failureThreshold: 30
periodSeconds: 10
Thanks to the startup probe, the application will have a maximum of 5 minutes
(30 * 10 = 300s) to finish its startup.
Once the startup probe has succeeded once, the liveness probe takes over to
provide a fast response to container deadlocks.
If the startup probe never succeeds, the container is killed after 300s and
subject to the pod's restartPolicy
.
Define 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, or depend on external services after 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.
initialDelaySeconds
or a startupProbe
.
Readiness probes are configured similarly to liveness probes. The only difference
is that you use the readinessProbe
field instead of the livenessProbe
field.
readinessProbe:
exec:
command:
- cat
- /tmp/healthy
initialDelaySeconds: 5
periodSeconds: 5
Configuration for HTTP and TCP readiness probes also remains identical to liveness probes.
Readiness and liveness probes can be used in parallel for the same container. Using both can ensure that traffic does not reach a container that is not ready for it, and that containers are restarted when they fail.
Configure Probes
Probes have a number of fields that you can use to more precisely control the behavior of startup, liveness and readiness checks:
initialDelaySeconds
: Number of seconds after the container has started before startup, liveness or readiness probes are initiated. If a startup probe is defined, liveness and readiness probe delays do not begin until the startup probe has succeeded. If the value ofperiodSeconds
is greater thaninitialDelaySeconds
then theinitialDelaySeconds
would be ignored. Defaults to 0 seconds. Minimum value is 0.periodSeconds
: How often (in seconds) to perform the probe. Default to 10 seconds. The minimum value is 1.timeoutSeconds
: Number of seconds after which the probe times out. Defaults to 1 second. Minimum value is 1.successThreshold
: Minimum consecutive successes for the probe to be considered successful after having failed. Defaults to 1. Must be 1 for liveness and startup Probes. Minimum value is 1.failureThreshold
: After a probe failsfailureThreshold
times in a row, Kubernetes considers that the overall check has failed: the container is not ready/healthy/live. For the case of a startup or liveness probe, if at leastfailureThreshold
probes have failed, Kubernetes treats the container as unhealthy and triggers a restart for that specific container. The kubelet honors the setting ofterminationGracePeriodSeconds
for that container. For a failed readiness probe, the kubelet continues running the container that failed checks, and also continues to run more probes; because the check failed, the kubelet sets theReady
condition on the Pod tofalse
.terminationGracePeriodSeconds
: configure a grace period for the kubelet to wait between triggering a shut down of the failed container, and then forcing the container runtime to stop that container. The default is to inherit the Pod-level value forterminationGracePeriodSeconds
(30 seconds if not specified), and the minimum value is 1. See probe-levelterminationGracePeriodSeconds
for more detail.
HTTP probes
HTTP probes
have additional fields that can be set on httpGet
:
host
: Host name to connect to, defaults to the pod IP. You probably want to set "Host" inhttpHeaders
instead.scheme
: Scheme to use for connecting to the host (HTTP or HTTPS). Defaults to "HTTP".path
: Path to access on the HTTP server. Defaults to "/".httpHeaders
: Custom headers to set in the request. HTTP allows repeated headers.port
: Name or number of the port to access on the container. Number must be in the range 1 to 65535.
For an HTTP probe, the kubelet sends an HTTP request to the specified port and
path to perform the check. The kubelet sends the probe to the Pod's IP address,
unless the address is overridden by the optional host
field in httpGet
. If
scheme
field is set to HTTPS
, the kubelet sends an HTTPS request skipping the
certificate verification. 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
.
For an HTTP probe, the kubelet sends two request headers in addition to the mandatory Host
header:
User-Agent
: The default value iskube-probe/1.29
, where1.29
is the version of the kubelet.Accept
: The default value is*/*
.
You can override the default headers by defining httpHeaders
for the probe.
For example:
livenessProbe:
httpGet:
httpHeaders:
- name: Accept
value: application/json
startupProbe:
httpGet:
httpHeaders:
- name: User-Agent
value: MyUserAgent
You can also remove these two headers by defining them with an empty value.
livenessProbe:
httpGet:
httpHeaders:
- name: Accept
value: ""
startupProbe:
httpGet:
httpHeaders:
- name: User-Agent
value: ""
When the kubelet probes a Pod using HTTP, it only follows redirects if the redirect
is to the same host. If the kubelet receives 11 or more redirects during probing, the probe is considered successful
and a related Event is created:
Events:
Type Reason Age From Message
---- ------ ---- ---- -------
Normal Scheduled 29m default-scheduler Successfully assigned default/httpbin-7b8bc9cb85-bjzwn to daocloud
Normal Pulling 29m kubelet Pulling image "docker.io/kennethreitz/httpbin"
Normal Pulled 24m kubelet Successfully pulled image "docker.io/kennethreitz/httpbin" in 5m12.402735213s
Normal Created 24m kubelet Created container httpbin
Normal Started 24m kubelet Started container httpbin
Warning ProbeWarning 4m11s (x1197 over 24m) kubelet Readiness probe warning: Probe terminated redirects
If the kubelet receives a redirect where the hostname is different from the request, the outcome of the probe is treated as successful and kubelet creates an event to report the redirect failure.
TCP probes
For a TCP probe, the kubelet makes the probe connection at the node, not in the Pod, which
means that you can not use a service name in the host
parameter since the kubelet is unable
to resolve it.
Probe-level terminationGracePeriodSeconds
Kubernetes v1.28 [stable]
In 1.25 and above, users can specify a probe-level terminationGracePeriodSeconds
as part of the probe specification. When both a pod- and probe-level
terminationGracePeriodSeconds
are set, the kubelet will use the probe-level value.
When setting the terminationGracePeriodSeconds
, please note the following:
-
The kubelet always honors the probe-level
terminationGracePeriodSeconds
field if it is present on a Pod. -
If you have existing Pods where the
terminationGracePeriodSeconds
field is set and you no longer wish to use per-probe termination grace periods, you must delete those existing Pods.
For example:
spec:
terminationGracePeriodSeconds: 3600 # pod-level
containers:
- name: test
image: ...
ports:
- name: liveness-port
containerPort: 8080
hostPort: 8080
livenessProbe:
httpGet:
path: /healthz
port: liveness-port
failureThreshold: 1
periodSeconds: 60
# Override pod-level terminationGracePeriodSeconds #
terminationGracePeriodSeconds: 60
Probe-level terminationGracePeriodSeconds
cannot be set for readiness probes.
It will be rejected by the API server.
What's next
- Learn more about Container Probes.
You can also read the API references for:
- Pod, and specifically: