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Container Runtimes
You need to install a container runtime into each node in the cluster so that Pods can run there. This page outlines what is involved and describes related tasks for setting up nodes.
Kubernetes 1.26 requires that you use a runtime that conforms with the Container Runtime Interface (CRI).
See CRI version support for more information.
This page provides an outline of how to use several common container runtimes with Kubernetes.
Kubernetes releases before v1.24 included a direct integration with Docker Engine, using a component named dockershim. That special direct integration is no longer part of Kubernetes (this removal was announced as part of the v1.20 release). You can read Check whether Dockershim removal affects you to understand how this removal might affect you. To learn about migrating from using dockershim, see Migrating from dockershim.
If you are running a version of Kubernetes other than v1.26, check the documentation for that version.
Install and configure prerequisites
The following steps apply common settings for Kubernetes nodes on Linux.
You can skip a particular setting if you're certain you don't need it.
For more information, see Network Plugin Requirements or the documentation for your specific container runtime.
Forwarding IPv4 and letting iptables see bridged traffic
Execute the below mentioned instructions:
cat <<EOF | sudo tee /etc/modules-load.d/k8s.conf
overlay
br_netfilter
EOF
sudo modprobe overlay
sudo modprobe br_netfilter
# sysctl params required by setup, params persist across reboots
cat <<EOF | sudo tee /etc/sysctl.d/k8s.conf
net.bridge.bridge-nf-call-iptables = 1
net.bridge.bridge-nf-call-ip6tables = 1
net.ipv4.ip_forward = 1
EOF
# Apply sysctl params without reboot
sudo sysctl --system
Verify that the br_netfilter
, overlay
modules are loaded by running below instructions:
lsmod | grep br_netfilter
lsmod | grep overlay
Verify that the net.bridge.bridge-nf-call-iptables
, net.bridge.bridge-nf-call-ip6tables
, net.ipv4.ip_forward
system variables are set to 1 in your sysctl
config by running below instruction:
sysctl net.bridge.bridge-nf-call-iptables net.bridge.bridge-nf-call-ip6tables net.ipv4.ip_forward
Cgroup drivers
On Linux, control groups are used to constrain resources that are allocated to processes.
Both kubelet and the underlying container runtime need to interface with control groups to enforce resource management for pods and containers and set resources such as cpu/memory requests and limits. To interface with control groups, the kubelet and the container runtime need to use a cgroup driver. It's critical that the kubelet and the container runtime uses the same cgroup driver and are configured the same.
There are two cgroup drivers available:
cgroupfs driver
The cgroupfs
driver is the default cgroup driver in the kubelet. When the cgroupfs
driver is used, the kubelet and the container runtime directly interface with
the cgroup filesystem to configure cgroups.
The cgroupfs
driver is not recommended when
systemd is the
init system because systemd expects a single cgroup manager on
the system. Additionally, if you use cgroup v2
, use the systemd
cgroup driver instead of
cgroupfs
.
systemd cgroup driver
When systemd is chosen as the init
system for a Linux distribution, the init process generates and consumes a root control group
(cgroup
) and acts as a cgroup manager.
systemd has a tight integration with cgroups and allocates a cgroup per systemd
unit. As a result, if you use systemd
as the init system with the cgroupfs
driver, the system gets two different cgroup managers.
Two cgroup managers result in two views of the available and in-use resources in
the system. In some cases, nodes that are configured to use cgroupfs
for the
kubelet and container runtime, but use systemd
for the rest of the processes become
unstable under resource pressure.
The approach to mitigate this instability is to use systemd
as the cgroup driver for
the kubelet and the container runtime when systemd is the selected init system.
To set systemd
as the cgroup driver, edit the
KubeletConfiguration
option of cgroupDriver
and set it to systemd
. For example:
apiVersion: kubelet.config.k8s.io/v1beta1
kind: KubeletConfiguration
...
cgroupDriver: systemd
If you configure systemd
as the cgroup driver for the kubelet, you must also
configure systemd
as the cgroup driver for the container runtime. Refer to
the documentation for your container runtime for instructions. For example:
Changing the cgroup driver of a Node that has joined a cluster is a sensitive operation. If the kubelet has created Pods using the semantics of one cgroup driver, changing the container runtime to another cgroup driver can cause errors when trying to re-create the Pod sandbox for such existing Pods. Restarting the kubelet may not solve such errors.
If you have automation that makes it feasible, replace the node with another using the updated configuration, or reinstall it using automation.
Migrating to the systemd
driver in kubeadm managed clusters
If you wish to migrate to the systemd
cgroup driver in existing kubeadm managed clusters,
follow configuring a cgroup driver.
CRI version support
Your container runtime must support at least v1alpha2 of the container runtime interface.
Kubernetes starting v1.26 only works with v1 of the CRI API. Earlier versions default to v1 version, however if a container runtime does not support the v1 API, the kubelet falls back to using the (deprecated) v1alpha2 API instead.
Container runtimes
containerd
This section outlines the necessary steps to use containerd as CRI runtime.
To install containerd on your system, follow the instructions on getting started with containerd.Return to this step once you've created a valid config.toml
configuration file.
You can find this file under the path /etc/containerd/config.toml
.
You can find this file under the path C:\Program Files\containerd\config.toml
.
On Linux the default CRI socket for containerd is /run/containerd/containerd.sock
.
On Windows the default CRI endpoint is npipe://./pipe/containerd-containerd
.
Configuring the systemd
cgroup driver
To use the systemd
cgroup driver in /etc/containerd/config.toml
with runc
, set
[plugins."io.containerd.grpc.v1.cri".containerd.runtimes.runc]
...
[plugins."io.containerd.grpc.v1.cri".containerd.runtimes.runc.options]
SystemdCgroup = true
The systemd
cgroup driver is recommended if you use cgroup v2.
If you installed containerd from a package (for example, RPM or .deb
), you may find
that the CRI integration plugin is disabled by default.
You need CRI support enabled to use containerd with Kubernetes. Make sure that cri
is not included in thedisabled_plugins
list within /etc/containerd/config.toml
;
if you made changes to that file, also restart containerd
.
If you experience container crash loops after the initial cluster installation or after
installing a CNI, the containerd configuration provided with the package might contain
incompatible configuration parameters. Consider resetting the containerd configuration
with containerd config default > /etc/containerd/config.toml
as specified in
getting-started.md
and then set the configuration parameters specified above accordingly.
If you apply this change, make sure to restart containerd:
sudo systemctl restart containerd
When using kubeadm, manually configure the cgroup driver for kubelet.
Overriding the sandbox (pause) image
In your containerd config you can overwrite the sandbox image by setting the following config:
[plugins."io.containerd.grpc.v1.cri"]
sandbox_image = "registry.k8s.io/pause:3.2"
You might need to restart containerd
as well once you've updated the config file: systemctl restart containerd
.
Please note, that it is a best practice for kubelet to declare the matching pod-infra-container-image
.
If not configured, kubelet may attempt to garbage collect the pause
image.
There is ongoing work in containerd to pin the pause image
and not require this setting on kubelet any longer.
CRI-O
This section contains the necessary steps to install CRI-O as a container runtime.
To install CRI-O, follow CRI-O Install Instructions.
cgroup driver
CRI-O uses the systemd cgroup driver per default, which is likely to work fine
for you. To switch to the cgroupfs
cgroup driver, either edit
/etc/crio/crio.conf
or place a drop-in configuration in
/etc/crio/crio.conf.d/02-cgroup-manager.conf
, for example:
[crio.runtime]
conmon_cgroup = "pod"
cgroup_manager = "cgroupfs"
You should also note the changed conmon_cgroup
, which has to be set to the value
pod
when using CRI-O with cgroupfs
. It is generally necessary to keep the
cgroup driver configuration of the kubelet (usually done via kubeadm) and CRI-O
in sync.
For CRI-O, the CRI socket is /var/run/crio/crio.sock
by default.
Overriding the sandbox (pause) image
In your CRI-O config you can set the following config value:
[crio.image]
pause_image="registry.k8s.io/pause:3.6"
This config option supports live configuration reload to apply this change: systemctl reload crio
or by sending
SIGHUP
to the crio
process.
Docker Engine
cri-dockerd
adapter to integrate
Docker Engine with Kubernetes.On each of your nodes, install Docker for your Linux distribution as per Install Docker Engine.
Install
cri-dockerd
, following the instructions in that source code repository.
For cri-dockerd
, the CRI socket is /run/cri-dockerd.sock
by default.
Mirantis Container Runtime
Mirantis Container Runtime (MCR) is a commercially available container runtime that was formerly known as Docker Enterprise Edition.
You can use Mirantis Container Runtime with Kubernetes using the open source
cri-dockerd
component, included with MCR.
To learn more about how to install Mirantis Container Runtime, visit MCR Deployment Guide.
Check the systemd unit named cri-docker.socket
to find out the path to the CRI
socket.
Overriding the sandbox (pause) image
The cri-dockerd
adapter accepts a command line argument for
specifying which container image to use as the Pod infrastructure container (“pause image”).
The command line argument to use is --pod-infra-container-image
.
What's next
As well as a container runtime, your cluster will need a working network plugin.
Items on this page refer to third party products or projects that provide functionality required by Kubernetes. The Kubernetes project authors aren't responsible for those third-party products or projects. See the CNCF website guidelines for more details.
You should read the content guide before proposing a change that adds an extra third-party link.