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Bootstrapping clusters with kubeadm
- 1: Installing kubeadm
- 2: Troubleshooting kubeadm
- 3: Creating a cluster with kubeadm
- 4: Customizing components with the kubeadm API
- 5: Options for Highly Available Topology
- 6: Creating Highly Available Clusters with kubeadm
- 7: Set up a High Availability etcd Cluster with kubeadm
- 8: Configuring each kubelet in your cluster using kubeadm
- 9: Dual-stack support with kubeadm
1 - Installing kubeadm
This page shows how to install the kubeadm
toolbox.
For information on how to create a cluster with kubeadm once you have performed this installation process,
see the Creating a cluster with kubeadm page.
This installation guide is for Kubernetes v1.30. If you want to use a different Kubernetes version, please refer to the following pages instead:
Before you begin
- A compatible Linux host. The Kubernetes project provides generic instructions for Linux distributions based on Debian and Red Hat, and those distributions without a package manager.
- 2 GB or more of RAM per machine (any less will leave little room for your apps).
- 2 CPUs or more.
- Full network connectivity between all machines in the cluster (public or private network is fine).
- Unique hostname, MAC address, and product_uuid for every node. See here for more details.
- Certain ports are open on your machines. See here for more details.
- Swap configuration. The default behavior of a kubelet was to fail to start if swap memory was detected on a node.
Swap has been supported since v1.22. And since v1.28, Swap is supported for cgroup v2 only; the NodeSwap feature
gate of the kubelet is beta but disabled by default.
- You MUST disable swap if the kubelet is not properly configured to use swap. For example,
sudo swapoff -a
will disable swapping temporarily. To make this change persistent across reboots, make sure swap is disabled in config files like/etc/fstab
,systemd.swap
, depending how it was configured on your system.
- You MUST disable swap if the kubelet is not properly configured to use swap. For example,
kubeadm
installation is done via binaries that use dynamic linking and assumes that your target system provides glibc
.
This is a reasonable assumption on many Linux distributions (including Debian, Ubuntu, Fedora, CentOS, etc.)
but it is not always the case with custom and lightweight distributions which don't include glibc
by default, such as Alpine Linux.
The expectation is that the distribution either includes glibc
or a compatibility layer
that provides the expected symbols.
Verify the MAC address and product_uuid are unique for every node
- You can get the MAC address of the network interfaces using the command
ip link
orifconfig -a
- The product_uuid can be checked by using the command
sudo cat /sys/class/dmi/id/product_uuid
It is very likely that hardware devices will have unique addresses, although some virtual machines may have identical values. Kubernetes uses these values to uniquely identify the nodes in the cluster. If these values are not unique to each node, the installation process may fail.
Check network adapters
If you have more than one network adapter, and your Kubernetes components are not reachable on the default route, we recommend you add IP route(s) so Kubernetes cluster addresses go via the appropriate adapter.
Check required ports
These required ports need to be open in order for Kubernetes components to communicate with each other. You can use tools like netcat to check if a port is open. For example:
nc 127.0.0.1 6443
The pod network plugin you use may also require certain ports to be open. Since this differs with each pod network plugin, please see the documentation for the plugins about what port(s) those need.
Installing a container runtime
To run containers in Pods, Kubernetes uses a container runtime.
By default, Kubernetes uses the Container Runtime Interface (CRI) to interface with your chosen container runtime.
If you don't specify a runtime, kubeadm automatically tries to detect an installed container runtime by scanning through a list of known endpoints.
If multiple or no container runtimes are detected kubeadm will throw an error and will request that you specify which one you want to use.
See container runtimes for more information.
The tables below include the known endpoints for supported operating systems:
Runtime | Path to Unix domain socket |
---|---|
containerd | unix:///var/run/containerd/containerd.sock |
CRI-O | unix:///var/run/crio/crio.sock |
Docker Engine (using cri-dockerd) | unix:///var/run/cri-dockerd.sock |
Runtime | Path to Windows named pipe |
---|---|
containerd | npipe:////./pipe/containerd-containerd |
Docker Engine (using cri-dockerd) | npipe:////./pipe/cri-dockerd |
Installing kubeadm, kubelet and kubectl
You will install these packages on all of your machines:
-
kubeadm
: the command to bootstrap the cluster. -
kubelet
: the component that runs on all of the machines in your cluster and does things like starting pods and containers. -
kubectl
: the command line util to talk to your cluster.
kubeadm will not install or manage kubelet
or kubectl
for you, so you will
need to ensure they match the version of the Kubernetes control plane you want
kubeadm to install for you. If you do not, there is a risk of a version skew occurring that
can lead to unexpected, buggy behaviour. However, one minor version skew between the
kubelet and the control plane is supported, but the kubelet version may never exceed the API
server version. For example, the kubelet running 1.7.0 should be fully compatible with a 1.8.0 API server,
but not vice versa.
For information about installing kubectl
, see Install and set up kubectl.
For more information on version skews, see:
- Kubernetes version and version-skew policy
- Kubeadm-specific version skew policy
apt.kubernetes.io
and yum.kubernetes.io
) have been
deprecated and frozen starting from September 13, 2023.
Using the new package repositories hosted at pkgs.k8s.io
is strongly recommended and required in order to install Kubernetes versions released after September 13, 2023.
The deprecated legacy repositories, and their contents, might be removed at any time in the future and without
a further notice period. The new package repositories provide downloads for Kubernetes versions starting with v1.24.0.
These instructions are for Kubernetes 1.30.
-
Update the
apt
package index and install packages needed to use the Kubernetesapt
repository:sudo apt-get update # apt-transport-https may be a dummy package; if so, you can skip that package sudo apt-get install -y apt-transport-https ca-certificates curl gpg
-
Download the public signing key for the Kubernetes package repositories. The same signing key is used for all repositories so you can disregard the version in the URL:
# If the folder `/etc/apt/keyrings` does not exist, it should be created before the curl command, read the note below. # sudo mkdir -p -m 755 /etc/apt/keyrings curl -fsSL https://pkgs.k8s.io/core:/stable:/v1.30/deb/Release.key | sudo gpg --dearmor -o /etc/apt/keyrings/kubernetes-apt-keyring.gpg
/etc/apt/keyrings
does not exist by default, and it should be created before the curl command.
-
Add the appropriate Kubernetes
apt
repository. Please note that this repository have packages only for Kubernetes 1.30; for other Kubernetes minor versions, you need to change the Kubernetes minor version in the URL to match your desired minor version (you should also check that you are reading the documentation for the version of Kubernetes that you plan to install).# This overwrites any existing configuration in /etc/apt/sources.list.d/kubernetes.list echo 'deb [signed-by=/etc/apt/keyrings/kubernetes-apt-keyring.gpg] https://pkgs.k8s.io/core:/stable:/v1.30/deb/ /' | sudo tee /etc/apt/sources.list.d/kubernetes.list
-
Update the
apt
package index, install kubelet, kubeadm and kubectl, and pin their version:sudo apt-get update sudo apt-get install -y kubelet kubeadm kubectl sudo apt-mark hold kubelet kubeadm kubectl
-
Set SELinux to
permissive
mode:These instructions are for Kubernetes 1.30.
# Set SELinux in permissive mode (effectively disabling it) sudo setenforce 0 sudo sed -i 's/^SELINUX=enforcing$/SELINUX=permissive/' /etc/selinux/config
- Setting SELinux in permissive mode by running
setenforce 0
andsed ...
effectively disables it. This is required to allow containers to access the host filesystem; for example, some cluster network plugins require that. You have to do this until SELinux support is improved in the kubelet. - You can leave SELinux enabled if you know how to configure it but it may require settings that are not supported by kubeadm.
-
Add the Kubernetes
yum
repository. Theexclude
parameter in the repository definition ensures that the packages related to Kubernetes are not upgraded upon runningyum update
as there's a special procedure that must be followed for upgrading Kubernetes. Please note that this repository have packages only for Kubernetes 1.30; for other Kubernetes minor versions, you need to change the Kubernetes minor version in the URL to match your desired minor version (you should also check that you are reading the documentation for the version of Kubernetes that you plan to install).# This overwrites any existing configuration in /etc/yum.repos.d/kubernetes.repo cat <<EOF | sudo tee /etc/yum.repos.d/kubernetes.repo [kubernetes] name=Kubernetes baseurl=https://pkgs.k8s.io/core:/stable:/v1.30/rpm/ enabled=1 gpgcheck=1 gpgkey=https://pkgs.k8s.io/core:/stable:/v1.30/rpm/repodata/repomd.xml.key exclude=kubelet kubeadm kubectl cri-tools kubernetes-cni EOF
-
Install kubelet, kubeadm and kubectl, and enable kubelet to ensure it's automatically started on startup:
sudo yum install -y kubelet kubeadm kubectl --disableexcludes=kubernetes sudo systemctl enable --now kubelet
Install CNI plugins (required for most pod network):
CNI_PLUGINS_VERSION="v1.3.0"
ARCH="amd64"
DEST="/opt/cni/bin"
sudo mkdir -p "$DEST"
curl -L "https://github.com/containernetworking/plugins/releases/download/${CNI_PLUGINS_VERSION}/cni-plugins-linux-${ARCH}-${CNI_PLUGINS_VERSION}.tgz" | sudo tar -C "$DEST" -xz
Define the directory to download command files:
DOWNLOAD_DIR
variable must be set to a writable directory.
If you are running Flatcar Container Linux, set DOWNLOAD_DIR="/opt/bin"
.
DOWNLOAD_DIR="/usr/local/bin"
sudo mkdir -p "$DOWNLOAD_DIR"
Install crictl (required for kubeadm / Kubelet Container Runtime Interface (CRI)):
CRICTL_VERSION="v1.28.0"
ARCH="amd64"
curl -L "https://github.com/kubernetes-sigs/cri-tools/releases/download/${CRICTL_VERSION}/crictl-${CRICTL_VERSION}-linux-${ARCH}.tar.gz" | sudo tar -C $DOWNLOAD_DIR -xz
Install kubeadm
, kubelet
, kubectl
and add a kubelet
systemd service:
RELEASE="$(curl -sSL https://dl.k8s.io/release/stable.txt)"
ARCH="amd64"
cd $DOWNLOAD_DIR
sudo curl -L --remote-name-all https://dl.k8s.io/release/${RELEASE}/bin/linux/${ARCH}/{kubeadm,kubelet}
sudo chmod +x {kubeadm,kubelet}
RELEASE_VERSION="v0.16.2"
curl -sSL "https://raw.githubusercontent.com/kubernetes/release/${RELEASE_VERSION}/cmd/krel/templates/latest/kubelet/kubelet.service" | sed "s:/usr/bin:${DOWNLOAD_DIR}:g" | sudo tee /etc/systemd/system/kubelet.service
sudo mkdir -p /etc/systemd/system/kubelet.service.d
curl -sSL "https://raw.githubusercontent.com/kubernetes/release/${RELEASE_VERSION}/cmd/krel/templates/latest/kubeadm/10-kubeadm.conf" | sed "s:/usr/bin:${DOWNLOAD_DIR}:g" | sudo tee /etc/systemd/system/kubelet.service.d/10-kubeadm.conf
glibc
by default.
Install kubectl
by following the instructions on Install Tools page.
Enable and start kubelet
:
systemctl enable --now kubelet
/usr
directory as a read-only filesystem.
Before bootstrapping your cluster, you need to take additional steps to configure a writable directory.
See the Kubeadm Troubleshooting guide
to learn how to set up a writable directory.
The kubelet is now restarting every few seconds, as it waits in a crashloop for kubeadm to tell it what to do.
Configuring a cgroup driver
Both the container runtime and the kubelet have a property called "cgroup driver", which is important for the management of cgroups on Linux machines.
Matching the container runtime and kubelet cgroup drivers is required or otherwise the kubelet process will fail.
See Configuring a cgroup driver for more details.
Troubleshooting
If you are running into difficulties with kubeadm, please consult our troubleshooting docs.
What's next
2 - Troubleshooting kubeadm
As with any program, you might run into an error installing or running kubeadm. This page lists some common failure scenarios and have provided steps that can help you understand and fix the problem.
If your problem is not listed below, please follow the following steps:
-
If you think your problem is a bug with kubeadm:
- Go to github.com/kubernetes/kubeadm and search for existing issues.
- If no issue exists, please open one and follow the issue template.
-
If you are unsure about how kubeadm works, you can ask on Slack in
#kubeadm
, or open a question on StackOverflow. Please include relevant tags like#kubernetes
and#kubeadm
so folks can help you.
Not possible to join a v1.18 Node to a v1.17 cluster due to missing RBAC
In v1.18 kubeadm added prevention for joining a Node in the cluster if a Node with the same name already exists. This required adding RBAC for the bootstrap-token user to be able to GET a Node object.
However this causes an issue where kubeadm join
from v1.18 cannot join a cluster created by kubeadm v1.17.
To workaround the issue you have two options:
Execute kubeadm init phase bootstrap-token
on a control-plane node using kubeadm v1.18.
Note that this enables the rest of the bootstrap-token permissions as well.
or
Apply the following RBAC manually using kubectl apply -f ...
:
apiVersion: rbac.authorization.k8s.io/v1
kind: ClusterRole
metadata:
name: kubeadm:get-nodes
rules:
- apiGroups:
- ""
resources:
- nodes
verbs:
- get
---
apiVersion: rbac.authorization.k8s.io/v1
kind: ClusterRoleBinding
metadata:
name: kubeadm:get-nodes
roleRef:
apiGroup: rbac.authorization.k8s.io
kind: ClusterRole
name: kubeadm:get-nodes
subjects:
- apiGroup: rbac.authorization.k8s.io
kind: Group
name: system:bootstrappers:kubeadm:default-node-token
ebtables
or some similar executable not found during installation
If you see the following warnings while running kubeadm init
[preflight] WARNING: ebtables not found in system path
[preflight] WARNING: ethtool not found in system path
Then you may be missing ebtables
, ethtool
or a similar executable on your node.
You can install them with the following commands:
- For Ubuntu/Debian users, run
apt install ebtables ethtool
. - For CentOS/Fedora users, run
yum install ebtables ethtool
.
kubeadm blocks waiting for control plane during installation
If you notice that kubeadm init
hangs after printing out the following line:
[apiclient] Created API client, waiting for the control plane to become ready
This may be caused by a number of problems. The most common are:
- network connection problems. Check that your machine has full network connectivity before continuing.
- the cgroup driver of the container runtime differs from that of the kubelet. To understand how to configure it properly, see Configuring a cgroup driver.
- control plane containers are crashlooping or hanging. You can check this by running
docker ps
and investigating each container by runningdocker logs
. For other container runtime, see Debugging Kubernetes nodes with crictl.
kubeadm blocks when removing managed containers
The following could happen if the container runtime halts and does not remove any Kubernetes-managed containers:
sudo kubeadm reset
[preflight] Running pre-flight checks
[reset] Stopping the kubelet service
[reset] Unmounting mounted directories in "/var/lib/kubelet"
[reset] Removing kubernetes-managed containers
(block)
A possible solution is to restart the container runtime and then re-run kubeadm reset
.
You can also use crictl
to debug the state of the container runtime. See
Debugging Kubernetes nodes with crictl.
Pods in RunContainerError
, CrashLoopBackOff
or Error
state
Right after kubeadm init
there should not be any pods in these states.
- If there are pods in one of these states right after
kubeadm init
, please open an issue in the kubeadm repo.coredns
(orkube-dns
) should be in thePending
state until you have deployed the network add-on. - If you see Pods in the
RunContainerError
,CrashLoopBackOff
orError
state after deploying the network add-on and nothing happens tocoredns
(orkube-dns
), it's very likely that the Pod Network add-on that you installed is somehow broken. You might have to grant it more RBAC privileges or use a newer version. Please file an issue in the Pod Network providers' issue tracker and get the issue triaged there.
coredns
is stuck in the Pending
state
This is expected and part of the design. kubeadm is network provider-agnostic, so the admin
should install the pod network add-on
of choice. You have to install a Pod Network
before CoreDNS may be deployed fully. Hence the Pending
state before the network is set up.
HostPort
services do not work
The HostPort
and HostIP
functionality is available depending on your Pod Network
provider. Please contact the author of the Pod Network add-on to find out whether
HostPort
and HostIP
functionality are available.
Calico, Canal, and Flannel CNI providers are verified to support HostPort.
For more information, see the CNI portmap documentation.
If your network provider does not support the portmap CNI plugin, you may need to use the
NodePort feature of services
or use HostNetwork=true
.
Pods are not accessible via their Service IP
-
Many network add-ons do not yet enable hairpin mode which allows pods to access themselves via their Service IP. This is an issue related to CNI. Please contact the network add-on provider to get the latest status of their support for hairpin mode.
-
If you are using VirtualBox (directly or via Vagrant), you will need to ensure that
hostname -i
returns a routable IP address. By default, the first interface is connected to a non-routable host-only network. A work around is to modify/etc/hosts
, see this Vagrantfile for an example.
TLS certificate errors
The following error indicates a possible certificate mismatch.
# kubectl get pods
Unable to connect to the server: x509: certificate signed by unknown authority (possibly because of "crypto/rsa: verification error" while trying to verify candidate authority certificate "kubernetes")
-
Verify that the
$HOME/.kube/config
file contains a valid certificate, and regenerate a certificate if necessary. The certificates in a kubeconfig file are base64 encoded. Thebase64 --decode
command can be used to decode the certificate andopenssl x509 -text -noout
can be used for viewing the certificate information. -
Unset the
KUBECONFIG
environment variable using:unset KUBECONFIG
Or set it to the default
KUBECONFIG
location:export KUBECONFIG=/etc/kubernetes/admin.conf
-
Another workaround is to overwrite the existing
kubeconfig
for the "admin" user:mv $HOME/.kube $HOME/.kube.bak mkdir $HOME/.kube sudo cp -i /etc/kubernetes/admin.conf $HOME/.kube/config sudo chown $(id -u):$(id -g) $HOME/.kube/config
Kubelet client certificate rotation fails
By default, kubeadm configures a kubelet with automatic rotation of client certificates by using the
/var/lib/kubelet/pki/kubelet-client-current.pem
symlink specified in /etc/kubernetes/kubelet.conf
.
If this rotation process fails you might see errors such as x509: certificate has expired or is not yet valid
in kube-apiserver logs. To fix the issue you must follow these steps:
-
Backup and delete
/etc/kubernetes/kubelet.conf
and/var/lib/kubelet/pki/kubelet-client*
from the failed node. -
From a working control plane node in the cluster that has
/etc/kubernetes/pki/ca.key
executekubeadm kubeconfig user --org system:nodes --client-name system:node:$NODE > kubelet.conf
.$NODE
must be set to the name of the existing failed node in the cluster. Modify the resultedkubelet.conf
manually to adjust the cluster name and server endpoint, or passkubeconfig user --config
(see Generating kubeconfig files for additional users). If your cluster does not have theca.key
you must sign the embedded certificates in thekubelet.conf
externally. -
Copy this resulted
kubelet.conf
to/etc/kubernetes/kubelet.conf
on the failed node. -
Restart the kubelet (
systemctl restart kubelet
) on the failed node and wait for/var/lib/kubelet/pki/kubelet-client-current.pem
to be recreated. -
Manually edit the
kubelet.conf
to point to the rotated kubelet client certificates, by replacingclient-certificate-data
andclient-key-data
with:client-certificate: /var/lib/kubelet/pki/kubelet-client-current.pem client-key: /var/lib/kubelet/pki/kubelet-client-current.pem
-
Restart the kubelet.
-
Make sure the node becomes
Ready
.
Default NIC When using flannel as the pod network in Vagrant
The following error might indicate that something was wrong in the pod network:
Error from server (NotFound): the server could not find the requested resource
-
If you're using flannel as the pod network inside Vagrant, then you will have to specify the default interface name for flannel.
Vagrant typically assigns two interfaces to all VMs. The first, for which all hosts are assigned the IP address
10.0.2.15
, is for external traffic that gets NATed.This may lead to problems with flannel, which defaults to the first interface on a host. This leads to all hosts thinking they have the same public IP address. To prevent this, pass the
--iface eth1
flag to flannel so that the second interface is chosen.
Non-public IP used for containers
In some situations kubectl logs
and kubectl run
commands may return with the
following errors in an otherwise functional cluster:
Error from server: Get https://10.19.0.41:10250/containerLogs/default/mysql-ddc65b868-glc5m/mysql: dial tcp 10.19.0.41:10250: getsockopt: no route to host
-
This may be due to Kubernetes using an IP that can not communicate with other IPs on the seemingly same subnet, possibly by policy of the machine provider.
-
DigitalOcean assigns a public IP to
eth0
as well as a private one to be used internally as anchor for their floating IP feature, yetkubelet
will pick the latter as the node'sInternalIP
instead of the public one.Use
ip addr show
to check for this scenario instead ofifconfig
becauseifconfig
will not display the offending alias IP address. Alternatively an API endpoint specific to DigitalOcean allows to query for the anchor IP from the droplet:curl http://169.254.169.254/metadata/v1/interfaces/public/0/anchor_ipv4/address
The workaround is to tell
kubelet
which IP to use using--node-ip
. When using DigitalOcean, it can be the public one (assigned toeth0
) or the private one (assigned toeth1
) should you want to use the optional private network. ThekubeletExtraArgs
section of the kubeadmNodeRegistrationOptions
structure can be used for this.Then restart
kubelet
:systemctl daemon-reload systemctl restart kubelet
coredns
pods have CrashLoopBackOff
or Error
state
If you have nodes that are running SELinux with an older version of Docker, you might experience a scenario
where the coredns
pods are not starting. To solve that, you can try one of the following options:
-
Upgrade to a newer version of Docker.
-
Modify the
coredns
deployment to setallowPrivilegeEscalation
totrue
:
kubectl -n kube-system get deployment coredns -o yaml | \
sed 's/allowPrivilegeEscalation: false/allowPrivilegeEscalation: true/g' | \
kubectl apply -f -
Another cause for CoreDNS to have CrashLoopBackOff
is when a CoreDNS Pod deployed in Kubernetes detects a loop.
A number of workarounds
are available to avoid Kubernetes trying to restart the CoreDNS Pod every time CoreDNS detects the loop and exits.
allowPrivilegeEscalation
to true
can compromise
the security of your cluster.
etcd pods restart continually
If you encounter the following error:
rpc error: code = 2 desc = oci runtime error: exec failed: container_linux.go:247: starting container process caused "process_linux.go:110: decoding init error from pipe caused \"read parent: connection reset by peer\""
This issue appears if you run CentOS 7 with Docker 1.13.1.84. This version of Docker can prevent the kubelet from executing into the etcd container.
To work around the issue, choose one of these options:
-
Roll back to an earlier version of Docker, such as 1.13.1-75
yum downgrade docker-1.13.1-75.git8633870.el7.centos.x86_64 docker-client-1.13.1-75.git8633870.el7.centos.x86_64 docker-common-1.13.1-75.git8633870.el7.centos.x86_64
-
Install one of the more recent recommended versions, such as 18.06:
sudo yum-config-manager --add-repo https://download.docker.com/linux/centos/docker-ce.repo yum install docker-ce-18.06.1.ce-3.el7.x86_64
Not possible to pass a comma separated list of values to arguments inside a --component-extra-args
flag
kubeadm init
flags such as --component-extra-args
allow you to pass custom arguments to a control-plane
component like the kube-apiserver. However, this mechanism is limited due to the underlying type used for parsing
the values (mapStringString
).
If you decide to pass an argument that supports multiple, comma-separated values such as
--apiserver-extra-args "enable-admission-plugins=LimitRanger,NamespaceExists"
this flag will fail with
flag: malformed pair, expect string=string
. This happens because the list of arguments for
--apiserver-extra-args
expects key=value
pairs and in this case NamespacesExists
is considered
as a key that is missing a value.
Alternatively, you can try separating the key=value
pairs like so:
--apiserver-extra-args "enable-admission-plugins=LimitRanger,enable-admission-plugins=NamespaceExists"
but this will result in the key enable-admission-plugins
only having the value of NamespaceExists
.
A known workaround is to use the kubeadm configuration file.
kube-proxy scheduled before node is initialized by cloud-controller-manager
In cloud provider scenarios, kube-proxy can end up being scheduled on new worker nodes before the cloud-controller-manager has initialized the node addresses. This causes kube-proxy to fail to pick up the node's IP address properly and has knock-on effects to the proxy function managing load balancers.
The following error can be seen in kube-proxy Pods:
server.go:610] Failed to retrieve node IP: host IP unknown; known addresses: []
proxier.go:340] invalid nodeIP, initializing kube-proxy with 127.0.0.1 as nodeIP
A known solution is to patch the kube-proxy DaemonSet to allow scheduling it on control-plane nodes regardless of their conditions, keeping it off of other nodes until their initial guarding conditions abate:
kubectl -n kube-system patch ds kube-proxy -p='{
"spec": {
"template": {
"spec": {
"tolerations": [
{
"key": "CriticalAddonsOnly",
"operator": "Exists"
},
{
"effect": "NoSchedule",
"key": "node-role.kubernetes.io/control-plane"
}
]
}
}
}
}'
The tracking issue for this problem is here.
/usr
is mounted read-only on nodes
On Linux distributions such as Fedora CoreOS or Flatcar Container Linux, the directory /usr
is mounted as a read-only filesystem.
For flex-volume support,
Kubernetes components like the kubelet and kube-controller-manager use the default path of
/usr/libexec/kubernetes/kubelet-plugins/volume/exec/
, yet the flex-volume directory must be writeable
for the feature to work.
To workaround this issue, you can configure the flex-volume directory using the kubeadm configuration file.
On the primary control-plane Node (created using kubeadm init
), pass the following
file using --config
:
apiVersion: kubeadm.k8s.io/v1beta3
kind: InitConfiguration
nodeRegistration:
kubeletExtraArgs:
volume-plugin-dir: "/opt/libexec/kubernetes/kubelet-plugins/volume/exec/"
---
apiVersion: kubeadm.k8s.io/v1beta3
kind: ClusterConfiguration
controllerManager:
extraArgs:
flex-volume-plugin-dir: "/opt/libexec/kubernetes/kubelet-plugins/volume/exec/"
On joining Nodes:
apiVersion: kubeadm.k8s.io/v1beta3
kind: JoinConfiguration
nodeRegistration:
kubeletExtraArgs:
volume-plugin-dir: "/opt/libexec/kubernetes/kubelet-plugins/volume/exec/"
Alternatively, you can modify /etc/fstab
to make the /usr
mount writeable, but please
be advised that this is modifying a design principle of the Linux distribution.
kubeadm upgrade plan
prints out context deadline exceeded
error message
This error message is shown when upgrading a Kubernetes cluster with kubeadm
in
the case of running an external etcd. This is not a critical bug and happens because
older versions of kubeadm perform a version check on the external etcd cluster.
You can proceed with kubeadm upgrade apply ...
.
This issue is fixed as of version 1.19.
kubeadm reset
unmounts /var/lib/kubelet
If /var/lib/kubelet
is being mounted, performing a kubeadm reset
will effectively unmount it.
To workaround the issue, re-mount the /var/lib/kubelet
directory after performing the kubeadm reset
operation.
This is a regression introduced in kubeadm 1.15. The issue is fixed in 1.20.
Cannot use the metrics-server securely in a kubeadm cluster
In a kubeadm cluster, the metrics-server
can be used insecurely by passing the --kubelet-insecure-tls
to it. This is not recommended for production clusters.
If you want to use TLS between the metrics-server and the kubelet there is a problem, since kubeadm deploys a self-signed serving certificate for the kubelet. This can cause the following errors on the side of the metrics-server:
x509: certificate signed by unknown authority
x509: certificate is valid for IP-foo not IP-bar
See Enabling signed kubelet serving certificates to understand how to configure the kubelets in a kubeadm cluster to have properly signed serving certificates.
Also see How to run the metrics-server securely.
Upgrade fails due to etcd hash not changing
Only applicable to upgrading a control plane node with a kubeadm binary v1.28.3 or later, where the node is currently managed by kubeadm versions v1.28.0, v1.28.1 or v1.28.2.
Here is the error message you may encounter:
[upgrade/etcd] Failed to upgrade etcd: couldn't upgrade control plane. kubeadm has tried to recover everything into the earlier state. Errors faced: static Pod hash for component etcd on Node kinder-upgrade-control-plane-1 did not change after 5m0s: timed out waiting for the condition
[upgrade/etcd] Waiting for previous etcd to become available
I0907 10:10:09.109104 3704 etcd.go:588] [etcd] attempting to see if all cluster endpoints ([https://172.17.0.6:2379/ https://172.17.0.4:2379/ https://172.17.0.3:2379/]) are available 1/10
[upgrade/etcd] Etcd was rolled back and is now available
static Pod hash for component etcd on Node kinder-upgrade-control-plane-1 did not change after 5m0s: timed out waiting for the condition
couldn't upgrade control plane. kubeadm has tried to recover everything into the earlier state. Errors faced
k8s.io/kubernetes/cmd/kubeadm/app/phases/upgrade.rollbackOldManifests
cmd/kubeadm/app/phases/upgrade/staticpods.go:525
k8s.io/kubernetes/cmd/kubeadm/app/phases/upgrade.upgradeComponent
cmd/kubeadm/app/phases/upgrade/staticpods.go:254
k8s.io/kubernetes/cmd/kubeadm/app/phases/upgrade.performEtcdStaticPodUpgrade
cmd/kubeadm/app/phases/upgrade/staticpods.go:338
...
The reason for this failure is that the affected versions generate an etcd manifest file with unwanted defaults in the PodSpec. This will result in a diff from the manifest comparison, and kubeadm will expect a change in the Pod hash, but the kubelet will never update the hash.
There are two way to workaround this issue if you see it in your cluster:
-
The etcd upgrade can be skipped between the affected versions and v1.28.3 (or later) by using:
kubeadm upgrade {apply|node} [version] --etcd-upgrade=false
This is not recommended in case a new etcd version was introduced by a later v1.28 patch version.
-
Before upgrade, patch the manifest for the etcd static pod, to remove the problematic defaulted attributes:
diff --git a/etc/kubernetes/manifests/etcd_defaults.yaml b/etc/kubernetes/manifests/etcd_origin.yaml index d807ccbe0aa..46b35f00e15 100644 --- a/etc/kubernetes/manifests/etcd_defaults.yaml +++ b/etc/kubernetes/manifests/etcd_origin.yaml @@ -43,7 +43,6 @@ spec: scheme: HTTP initialDelaySeconds: 10 periodSeconds: 10 - successThreshold: 1 timeoutSeconds: 15 name: etcd resources: @@ -59,26 +58,18 @@ spec: scheme: HTTP initialDelaySeconds: 10 periodSeconds: 10 - successThreshold: 1 timeoutSeconds: 15 - terminationMessagePath: /dev/termination-log - terminationMessagePolicy: File volumeMounts: - mountPath: /var/lib/etcd name: etcd-data - mountPath: /etc/kubernetes/pki/etcd name: etcd-certs - dnsPolicy: ClusterFirst - enableServiceLinks: true hostNetwork: true priority: 2000001000 priorityClassName: system-node-critical - restartPolicy: Always - schedulerName: default-scheduler securityContext: seccompProfile: type: RuntimeDefault - terminationGracePeriodSeconds: 30 volumes: - hostPath: path: /etc/kubernetes/pki/etcd
More information can be found in the tracking issue for this bug.
3 - Creating a cluster with kubeadm
Using kubeadm
, you can create a minimum viable Kubernetes cluster that conforms to best practices.
In fact, you can use kubeadm
to set up a cluster that will pass the
Kubernetes Conformance tests.
kubeadm
also supports other cluster lifecycle functions, such as
bootstrap tokens and cluster upgrades.
The kubeadm
tool is good if you need:
- A simple way for you to try out Kubernetes, possibly for the first time.
- A way for existing users to automate setting up a cluster and test their application.
- A building block in other ecosystem and/or installer tools with a larger scope.
You can install and use kubeadm
on various machines: your laptop, a set
of cloud servers, a Raspberry Pi, and more. Whether you're deploying into the
cloud or on-premises, you can integrate kubeadm
into provisioning systems such
as Ansible or Terraform.
Before you begin
To follow this guide, you need:
- One or more machines running a deb/rpm-compatible Linux OS; for example: Ubuntu or CentOS.
- 2 GiB or more of RAM per machine--any less leaves little room for your apps.
- At least 2 CPUs on the machine that you use as a control-plane node.
- Full network connectivity among all machines in the cluster. You can use either a public or a private network.
You also need to use a version of kubeadm
that can deploy the version
of Kubernetes that you want to use in your new cluster.
Kubernetes' version and version skew support policy
applies to kubeadm
as well as to Kubernetes overall.
Check that policy to learn about what versions of Kubernetes and kubeadm
are supported. This page is written for Kubernetes v1.30.
The kubeadm
tool's overall feature state is General Availability (GA). Some sub-features are
still under active development. The implementation of creating the cluster may change
slightly as the tool evolves, but the overall implementation should be pretty stable.
kubeadm alpha
are, by definition, supported on an alpha level.
Objectives
- Install a single control-plane Kubernetes cluster
- Install a Pod network on the cluster so that your Pods can talk to each other
Instructions
Preparing the hosts
Component installation
Install a container runtime and kubeadm on all the hosts. For detailed instructions and other prerequisites, see Installing kubeadm.
If you have already installed kubeadm, see the first two steps of the Upgrading Linux nodes document for instructions on how to upgrade kubeadm.
When you upgrade, the kubelet restarts every few seconds as it waits in a crashloop for kubeadm to tell it what to do. This crashloop is expected and normal. After you initialize your control-plane, the kubelet runs normally.
Network setup
kubeadm similarly to other Kubernetes components tries to find a usable IP on the network interfaces associated with a default gateway on a host. Such an IP is then used for the advertising and/or listening performed by a component.
To find out what this IP is on a Linux host you can use:
ip route show # Look for a line starting with "default via"
Kubernetes components do not accept custom network interface as an option, therefore a custom IP address must be passed as a flag to all components instances that need such a custom configuration.
To configure the API server advertise address for control plane nodes created with both
init
and join
, the flag --apiserver-advertise-address
can be used.
Preferably, this option can be set in the kubeadm API
as InitConfiguration.localAPIEndpoint
and JoinConfiguration.controlPlane.localAPIEndpoint
.
For kubelets on all nodes, the --node-ip
option can be passed in
.nodeRegistration.kubeletExtraArgs
inside a kubeadm configuration file
(InitConfiguration
or JoinConfiguration
).
For dual-stack see Dual-stack support with kubeadm.
The IP addresses that you assign to control plane components become part of their X.509 certificates' subject alternative name fields. Changing these IP addresses would require signing new certificates and restarting the affected components, so that the change in certificate files is reflected. See Manual certificate renewal for more details on this topic.
ip route
to configure networking; your operating
system might also provide higher level network management tools. If your node's default gateway
is a public IP address, you should configure packet filtering or other security measures that
protect the nodes and your cluster.
Preparing the required container images
This step is optional and only applies in case you wish kubeadm init
and kubeadm join
to not download the default container images which are hosted at registry.k8s.io
.
Kubeadm has commands that can help you pre-pull the required images when creating a cluster without an internet connection on its nodes. See Running kubeadm without an internet connection for more details.
Kubeadm allows you to use a custom image repository for the required images. See Using custom images for more details.
Initializing your control-plane node
The control-plane node is the machine where the control plane components run, including etcd (the cluster database) and the API Server (which the kubectl command line tool communicates with).
- (Recommended) If you have plans to upgrade this single control-plane
kubeadm
cluster to high availability you should specify the--control-plane-endpoint
to set the shared endpoint for all control-plane nodes. Such an endpoint can be either a DNS name or an IP address of a load-balancer. - Choose a Pod network add-on, and verify whether it requires any arguments to
be passed to
kubeadm init
. Depending on which third-party provider you choose, you might need to set the--pod-network-cidr
to a provider-specific value. See Installing a Pod network add-on. - (Optional)
kubeadm
tries to detect the container runtime by using a list of well known endpoints. To use different container runtime or if there are more than one installed on the provisioned node, specify the--cri-socket
argument tokubeadm
. See Installing a runtime.
To initialize the control-plane node run:
kubeadm init <args>
Considerations about apiserver-advertise-address and ControlPlaneEndpoint
While --apiserver-advertise-address
can be used to set the advertise address for this particular
control-plane node's API server, --control-plane-endpoint
can be used to set the shared endpoint
for all control-plane nodes.
--control-plane-endpoint
allows both IP addresses and DNS names that can map to IP addresses.
Please contact your network administrator to evaluate possible solutions with respect to such mapping.
Here is an example mapping:
192.168.0.102 cluster-endpoint
Where 192.168.0.102
is the IP address of this node and cluster-endpoint
is a custom DNS name that maps to this IP.
This will allow you to pass --control-plane-endpoint=cluster-endpoint
to kubeadm init
and pass the same DNS name to
kubeadm join
. Later you can modify cluster-endpoint
to point to the address of your load-balancer in an
high availability scenario.
Turning a single control plane cluster created without --control-plane-endpoint
into a highly available cluster
is not supported by kubeadm.
More information
For more information about kubeadm init
arguments, see the kubeadm reference guide.
To configure kubeadm init
with a configuration file see
Using kubeadm init with a configuration file.
To customize control plane components, including optional IPv6 assignment to liveness probe for control plane components and etcd server, provide extra arguments to each component as documented in custom arguments.
To reconfigure a cluster that has already been created see Reconfiguring a kubeadm cluster.
To run kubeadm init
again, you must first tear down the cluster.
If you join a node with a different architecture to your cluster, make sure that your deployed DaemonSets have container image support for this architecture.
kubeadm init
first runs a series of prechecks to ensure that the machine
is ready to run Kubernetes. These prechecks expose warnings and exit on errors. kubeadm init
then downloads and installs the cluster control plane components. This may take several minutes.
After it finishes you should see:
Your Kubernetes control-plane has initialized successfully!
To start using your cluster, you need to run the following as a regular user:
mkdir -p $HOME/.kube
sudo cp -i /etc/kubernetes/admin.conf $HOME/.kube/config
sudo chown $(id -u):$(id -g) $HOME/.kube/config
You should now deploy a Pod network to the cluster.
Run "kubectl apply -f [podnetwork].yaml" with one of the options listed at:
/docs/concepts/cluster-administration/addons/
You can now join any number of machines by running the following on each node
as root:
kubeadm join <control-plane-host>:<control-plane-port> --token <token> --discovery-token-ca-cert-hash sha256:<hash>
To make kubectl work for your non-root user, run these commands, which are
also part of the kubeadm init
output:
mkdir -p $HOME/.kube
sudo cp -i /etc/kubernetes/admin.conf $HOME/.kube/config
sudo chown $(id -u):$(id -g) $HOME/.kube/config
Alternatively, if you are the root
user, you can run:
export KUBECONFIG=/etc/kubernetes/admin.conf
The kubeconfig file admin.conf
that kubeadm init
generates contains a certificate with
Subject: O = kubeadm:cluster-admins, CN = kubernetes-admin
. The group kubeadm:cluster-admins
is bound to the built-in cluster-admin
ClusterRole.
Do not share the admin.conf
file with anyone.
kubeadm init
generates another kubeconfig file super-admin.conf
that contains a certificate with
Subject: O = system:masters, CN = kubernetes-super-admin
.
system:masters
is a break-glass, super user group that bypasses the authorization layer (for example RBAC).
Do not share the super-admin.conf
file with anyone. It is recommended to move the file to a safe location.
See
Generating kubeconfig files for additional users
on how to use kubeadm kubeconfig user
to generate kubeconfig files for additional users.
Make a record of the kubeadm join
command that kubeadm init
outputs. You
need this command to join nodes to your cluster.
The token is used for mutual authentication between the control-plane node and the joining
nodes. The token included here is secret. Keep it safe, because anyone with this
token can add authenticated nodes to your cluster. These tokens can be listed,
created, and deleted with the kubeadm token
command. See the
kubeadm reference guide.
Installing a Pod network add-on
This section contains important information about networking setup and deployment order. Read all of this advice carefully before proceeding.
You must deploy a Container Network Interface (CNI) based Pod network add-on so that your Pods can communicate with each other. Cluster DNS (CoreDNS) will not start up before a network is installed.
-
Take care that your Pod network must not overlap with any of the host networks: you are likely to see problems if there is any overlap. (If you find a collision between your network plugin's preferred Pod network and some of your host networks, you should think of a suitable CIDR block to use instead, then use that during
kubeadm init
with--pod-network-cidr
and as a replacement in your network plugin's YAML). -
By default,
kubeadm
sets up your cluster to use and enforce use of RBAC (role based access control). Make sure that your Pod network plugin supports RBAC, and so do any manifests that you use to deploy it. -
If you want to use IPv6--either dual-stack, or single-stack IPv6 only networking--for your cluster, make sure that your Pod network plugin supports IPv6. IPv6 support was added to CNI in v0.6.0.
Several external projects provide Kubernetes Pod networks using CNI, some of which also support Network Policy.
See a list of add-ons that implement the Kubernetes networking model.
Please refer to the Installing Addons page for a non-exhaustive list of networking addons supported by Kubernetes. You can install a Pod network add-on with the following command on the control-plane node or a node that has the kubeconfig credentials:
kubectl apply -f <add-on.yaml>
You can install only one Pod network per cluster.
Once a Pod network has been installed, you can confirm that it is working by
checking that the CoreDNS Pod is Running
in the output of kubectl get pods --all-namespaces
.
And once the CoreDNS Pod is up and running, you can continue by joining your nodes.
If your network is not working or CoreDNS is not in the Running
state, check out the
troubleshooting guide
for kubeadm
.
Managed node labels
By default, kubeadm enables the NodeRestriction
admission controller that restricts what labels can be self-applied by kubelets on node registration.
The admission controller documentation covers what labels are permitted to be used with the kubelet --node-labels
option.
The node-role.kubernetes.io/control-plane
label is such a restricted label and kubeadm manually applies it using
a privileged client after a node has been created. To do that manually you can do the same by using kubectl label
and ensure it is using a privileged kubeconfig such as the kubeadm managed /etc/kubernetes/admin.conf
.
Control plane node isolation
By default, your cluster will not schedule Pods on the control plane nodes for security reasons. If you want to be able to schedule Pods on the control plane nodes, for example for a single machine Kubernetes cluster, run:
kubectl taint nodes --all node-role.kubernetes.io/control-plane-
The output will look something like:
node "test-01" untainted
...
This will remove the node-role.kubernetes.io/control-plane:NoSchedule
taint
from any nodes that have it, including the control plane nodes, meaning that the
scheduler will then be able to schedule Pods everywhere.
Additionally, you can execute the following command to remove the
node.kubernetes.io/exclude-from-external-load-balancers
label
from the control plane node, which excludes it from the list of backend servers:
kubectl label nodes --all node.kubernetes.io/exclude-from-external-load-balancers-
Joining your nodes
The nodes are where your workloads (containers and Pods, etc) run. To add new nodes to your cluster do the following for each machine:
-
SSH to the machine
-
Become root (e.g.
sudo su -
) -
Install a runtime if needed
-
Run the command that was output by
kubeadm init
. For example:kubeadm join --token <token> <control-plane-host>:<control-plane-port> --discovery-token-ca-cert-hash sha256:<hash>
If you do not have the token, you can get it by running the following command on the control-plane node:
kubeadm token list
The output is similar to this:
TOKEN TTL EXPIRES USAGES DESCRIPTION EXTRA GROUPS
8ewj1p.9r9hcjoqgajrj4gi 23h 2018-06-12T02:51:28Z authentication, The default bootstrap system:
signing token generated by bootstrappers:
'kubeadm init'. kubeadm:
default-node-token
By default, tokens expire after 24 hours. If you are joining a node to the cluster after the current token has expired, you can create a new token by running the following command on the control-plane node:
kubeadm token create
The output is similar to this:
5didvk.d09sbcov8ph2amjw
If you don't have the value of --discovery-token-ca-cert-hash
, you can get it by running the
following command chain on the control-plane node:
openssl x509 -pubkey -in /etc/kubernetes/pki/ca.crt | openssl rsa -pubin -outform der 2>/dev/null | \
openssl dgst -sha256 -hex | sed 's/^.* //'
The output is similar to:
8cb2de97839780a412b93877f8507ad6c94f73add17d5d7058e91741c9d5ec78
<control-plane-host>:<control-plane-port>
, IPv6 address must be enclosed in square brackets, for example: [2001:db8::101]:2073
.
The output should look something like:
[preflight] Running pre-flight checks
... (log output of join workflow) ...
Node join complete:
* Certificate signing request sent to control-plane and response
received.
* Kubelet informed of new secure connection details.
Run 'kubectl get nodes' on control-plane to see this machine join.
A few seconds later, you should notice this node in the output from kubectl get nodes
when run on the control-plane node.
kubectl -n kube-system rollout restart deployment coredns
after at least one new node is joined.
(Optional) Controlling your cluster from machines other than the control-plane node
In order to get a kubectl on some other computer (e.g. laptop) to talk to your cluster, you need to copy the administrator kubeconfig file from your control-plane node to your workstation like this:
scp root@<control-plane-host>:/etc/kubernetes/admin.conf .
kubectl --kubeconfig ./admin.conf get nodes
The example above assumes SSH access is enabled for root. If that is not the
case, you can copy the admin.conf
file to be accessible by some other user
and scp
using that other user instead.
The admin.conf
file gives the user superuser privileges over the cluster.
This file should be used sparingly. For normal users, it's recommended to
generate an unique credential to which you grant privileges. You can do
this with the kubeadm kubeconfig user --client-name <CN>
command. That command will print out a KubeConfig file to STDOUT which you
should save to a file and distribute to your user. After that, grant
privileges by using kubectl create (cluster)rolebinding
.
(Optional) Proxying API Server to localhost
If you want to connect to the API Server from outside the cluster you can use
kubectl proxy
:
scp root@<control-plane-host>:/etc/kubernetes/admin.conf .
kubectl --kubeconfig ./admin.conf proxy
You can now access the API Server locally at http://localhost:8001/api/v1
Clean up
If you used disposable servers for your cluster, for testing, you can
switch those off and do no further clean up. You can use
kubectl config delete-cluster
to delete your local references to the
cluster.
However, if you want to deprovision your cluster more cleanly, you should first drain the node and make sure that the node is empty, then deconfigure the node.
Remove the node
Talking to the control-plane node with the appropriate credentials, run:
kubectl drain <node name> --delete-emptydir-data --force --ignore-daemonsets
Before removing the node, reset the state installed by kubeadm
:
kubeadm reset
The reset process does not reset or clean up iptables rules or IPVS tables. If you wish to reset iptables, you must do so manually:
iptables -F && iptables -t nat -F && iptables -t mangle -F && iptables -X
If you want to reset the IPVS tables, you must run the following command:
ipvsadm -C
Now remove the node:
kubectl delete node <node name>
If you wish to start over, run kubeadm init
or kubeadm join
with the
appropriate arguments.
Clean up the control plane
You can use kubeadm reset
on the control plane host to trigger a best-effort
clean up.
See the kubeadm reset
reference documentation for more information about this subcommand and its
options.
Version skew policy
While kubeadm allows version skew against some components that it manages, it is recommended that you match the kubeadm version with the versions of the control plane components, kube-proxy and kubelet.
kubeadm's skew against the Kubernetes version
kubeadm can be used with Kubernetes components that are the same version as kubeadm
or one version older. The Kubernetes version can be specified to kubeadm by using the
--kubernetes-version
flag of kubeadm init
or the
ClusterConfiguration.kubernetesVersion
field when using --config
. This option will control the versions
of kube-apiserver, kube-controller-manager, kube-scheduler and kube-proxy.
Example:
- kubeadm is at 1.30
kubernetesVersion
must be at 1.30 or 1.29
kubeadm's skew against the kubelet
Similarly to the Kubernetes version, kubeadm can be used with a kubelet version that is the same version as kubeadm or three versions older.
Example:
- kubeadm is at 1.30
- kubelet on the host must be at 1.30, 1.29, 1.28 or 1.27
kubeadm's skew against kubeadm
There are certain limitations on how kubeadm commands can operate on existing nodes or whole clusters managed by kubeadm.
If new nodes are joined to the cluster, the kubeadm binary used for kubeadm join
must match
the last version of kubeadm used to either create the cluster with kubeadm init
or to upgrade
the same node with kubeadm upgrade
. Similar rules apply to the rest of the kubeadm commands
with the exception of kubeadm upgrade
.
Example for kubeadm join
:
- kubeadm version 1.30 was used to create a cluster with
kubeadm init
- Joining nodes must use a kubeadm binary that is at version 1.30
Nodes that are being upgraded must use a version of kubeadm that is the same MINOR version or one MINOR version newer than the version of kubeadm used for managing the node.
Example for kubeadm upgrade
:
- kubeadm version 1.29 was used to create or upgrade the node
- The version of kubeadm used for upgrading the node must be at 1.29 or 1.30
To learn more about the version skew between the different Kubernetes component see the Version Skew Policy.
Limitations
Cluster resilience
The cluster created here has a single control-plane node, with a single etcd database running on it. This means that if the control-plane node fails, your cluster may lose data and may need to be recreated from scratch.
Workarounds:
-
Regularly back up etcd. The etcd data directory configured by kubeadm is at
/var/lib/etcd
on the control-plane node. -
Use multiple control-plane nodes. You can read Options for Highly Available topology to pick a cluster topology that provides high-availability.
Platform compatibility
kubeadm deb/rpm packages and binaries are built for amd64, arm (32-bit), arm64, ppc64le, and s390x following the multi-platform proposal.
Multiplatform container images for the control plane and addons are also supported since v1.12.
Only some of the network providers offer solutions for all platforms. Please consult the list of network providers above or the documentation from each provider to figure out whether the provider supports your chosen platform.
Troubleshooting
If you are running into difficulties with kubeadm, please consult our troubleshooting docs.
What's next
- Verify that your cluster is running properly with Sonobuoy
- See Upgrading kubeadm clusters
for details about upgrading your cluster using
kubeadm
. - Learn about advanced
kubeadm
usage in the kubeadm reference documentation - Learn more about Kubernetes concepts and
kubectl
. - See the Cluster Networking page for a bigger list of Pod network add-ons.
- See the list of add-ons to explore other add-ons, including tools for logging, monitoring, network policy, visualization & control of your Kubernetes cluster.
- Configure how your cluster handles logs for cluster events and from applications running in Pods. See Logging Architecture for an overview of what is involved.
Feedback
- For bugs, visit the kubeadm GitHub issue tracker
- For support, visit the #kubeadm Slack channel
- General SIG Cluster Lifecycle development Slack channel: #sig-cluster-lifecycle
- SIG Cluster Lifecycle SIG information
- SIG Cluster Lifecycle mailing list: kubernetes-sig-cluster-lifecycle
4 - Customizing components with the kubeadm API
This page covers how to customize the components that kubeadm deploys. For control plane components
you can use flags in the ClusterConfiguration
structure or patches per-node. For the kubelet
and kube-proxy you can use KubeletConfiguration
and KubeProxyConfiguration
, accordingly.
All of these options are possible via the kubeadm configuration API. For more details on each field in the configuration you can navigate to our API reference pages.
kube-system/coredns
ConfigMap
and recreate the CoreDNS Pods after that. Alternatively,
you can skip the default CoreDNS deployment and deploy your own variant.
For more details on that see Using init phases with kubeadm.
Customizing the control plane with flags in ClusterConfiguration
The kubeadm ClusterConfiguration
object exposes a way for users to override the default
flags passed to control plane components such as the APIServer, ControllerManager, Scheduler and Etcd.
The components are defined using the following structures:
apiServer
controllerManager
scheduler
etcd
These structures contain a common extraArgs
field, that consists of key: value
pairs.
To override a flag for a control plane component:
- Add the appropriate
extraArgs
to your configuration. - Add flags to the
extraArgs
field. - Run
kubeadm init
with--config <YOUR CONFIG YAML>
.
ClusterConfiguration
object with default values by running kubeadm config print init-defaults
and saving the output to a file of your choice.
ClusterConfiguration
object is currently global in kubeadm clusters. This means that any flags that you add,
will apply to all instances of the same component on different nodes. To apply individual configuration per component
on different nodes you can use patches.
--foo
multiple times, is currently not supported.
To workaround that you must use patches.
APIServer flags
For details, see the reference documentation for kube-apiserver.
Example usage:
apiVersion: kubeadm.k8s.io/v1beta3
kind: ClusterConfiguration
kubernetesVersion: v1.16.0
apiServer:
extraArgs:
anonymous-auth: "false"
enable-admission-plugins: AlwaysPullImages,DefaultStorageClass
audit-log-path: /home/johndoe/audit.log
ControllerManager flags
For details, see the reference documentation for kube-controller-manager.
Example usage:
apiVersion: kubeadm.k8s.io/v1beta3
kind: ClusterConfiguration
kubernetesVersion: v1.16.0
controllerManager:
extraArgs:
cluster-signing-key-file: /home/johndoe/keys/ca.key
deployment-controller-sync-period: "50"
Scheduler flags
For details, see the reference documentation for kube-scheduler.
Example usage:
apiVersion: kubeadm.k8s.io/v1beta3
kind: ClusterConfiguration
kubernetesVersion: v1.16.0
scheduler:
extraArgs:
config: /etc/kubernetes/scheduler-config.yaml
extraVolumes:
- name: schedulerconfig
hostPath: /home/johndoe/schedconfig.yaml
mountPath: /etc/kubernetes/scheduler-config.yaml
readOnly: true
pathType: "File"
Etcd flags
For details, see the etcd server documentation.
Example usage:
apiVersion: kubeadm.k8s.io/v1beta3
kind: ClusterConfiguration
etcd:
local:
extraArgs:
election-timeout: 1000
Customizing with patches
Kubernetes v1.22 [beta]
Kubeadm allows you to pass a directory with patch files to InitConfiguration
and JoinConfiguration
on individual nodes. These patches can be used as the last customization step before component configuration
is written to disk.
You can pass this file to kubeadm init
with --config <YOUR CONFIG YAML>
:
apiVersion: kubeadm.k8s.io/v1beta3
kind: InitConfiguration
patches:
directory: /home/user/somedir
kubeadm init
you can pass a file containing both a ClusterConfiguration
and InitConfiguration
separated by ---
.
You can pass this file to kubeadm join
with --config <YOUR CONFIG YAML>
:
apiVersion: kubeadm.k8s.io/v1beta3
kind: JoinConfiguration
patches:
directory: /home/user/somedir
The directory must contain files named target[suffix][+patchtype].extension
.
For example, kube-apiserver0+merge.yaml
or just etcd.json
.
target
can be one ofkube-apiserver
,kube-controller-manager
,kube-scheduler
,etcd
andkubeletconfiguration
.patchtype
can be one ofstrategic
,merge
orjson
and these must match the patching formats supported by kubectl. The defaultpatchtype
isstrategic
.extension
must be eitherjson
oryaml
.suffix
is an optional string that can be used to determine which patches are applied first alpha-numerically.
kubeadm upgrade
to upgrade your kubeadm nodes you must again provide the same
patches, so that the customization is preserved after upgrade. To do that you can use the --patches
flag, which must point to the same directory. kubeadm upgrade
currently does not support a configuration
API structure that can be used for the same purpose.
Customizing the kubelet
To customize the kubelet you can add a KubeletConfiguration
next to the ClusterConfiguration
or InitConfiguration
separated by ---
within the same configuration file.
This file can then be passed to kubeadm init
and kubeadm will apply the same base KubeletConfiguration
to all nodes in the cluster.
For applying instance-specific configuration over the base KubeletConfiguration
you can use the
kubeletconfiguration
patch target.
Alternatively, you can use kubelet flags as overrides by passing them in the
nodeRegistration.kubeletExtraArgs
field supported by both InitConfiguration
and JoinConfiguration
.
Some kubelet flags are deprecated, so check their status in the
kubelet reference documentation before using them.
For additional details see Configuring each kubelet in your cluster using kubeadm
Customizing kube-proxy
To customize kube-proxy you can pass a KubeProxyConfiguration
next your ClusterConfiguration
or
InitConfiguration
to kubeadm init
separated by ---
.
For more details you can navigate to our API reference pages.
KubeProxyConfiguration
would apply to all instances of kube-proxy in the cluster.
5 - Options for Highly Available Topology
This page explains the two options for configuring the topology of your highly available (HA) Kubernetes clusters.
You can set up an HA cluster:
- With stacked control plane nodes, where etcd nodes are colocated with control plane nodes
- With external etcd nodes, where etcd runs on separate nodes from the control plane
You should carefully consider the advantages and disadvantages of each topology before setting up an HA cluster.
Stacked etcd topology
A stacked HA cluster is a topology where the distributed data storage cluster provided by etcd is stacked on top of the cluster formed by the nodes managed by kubeadm that run control plane components.
Each control plane node runs an instance of the kube-apiserver
, kube-scheduler
, and kube-controller-manager
.
The kube-apiserver
is exposed to worker nodes using a load balancer.
Each control plane node creates a local etcd member and this etcd member communicates only with
the kube-apiserver
of this node. The same applies to the local kube-controller-manager
and kube-scheduler
instances.
This topology couples the control planes and etcd members on the same nodes. It is simpler to set up than a cluster with external etcd nodes, and simpler to manage for replication.
However, a stacked cluster runs the risk of failed coupling. If one node goes down, both an etcd member and a control plane instance are lost, and redundancy is compromised. You can mitigate this risk by adding more control plane nodes.
You should therefore run a minimum of three stacked control plane nodes for an HA cluster.
This is the default topology in kubeadm. A local etcd member is created automatically
on control plane nodes when using kubeadm init
and kubeadm join --control-plane
.
External etcd topology
An HA cluster with external etcd is a topology where the distributed data storage cluster provided by etcd is external to the cluster formed by the nodes that run control plane components.
Like the stacked etcd topology, each control plane node in an external etcd topology runs an instance of the kube-apiserver
, kube-scheduler
, and kube-controller-manager
. And the kube-apiserver
is exposed to worker nodes using a load balancer. However, etcd members run on separate hosts, and each etcd host communicates with the kube-apiserver
of each control plane node.
This topology decouples the control plane and etcd member. It therefore provides an HA setup where losing a control plane instance or an etcd member has less impact and does not affect the cluster redundancy as much as the stacked HA topology.
However, this topology requires twice the number of hosts as the stacked HA topology. A minimum of three hosts for control plane nodes and three hosts for etcd nodes are required for an HA cluster with this topology.
What's next
6 - Creating Highly Available Clusters with kubeadm
This page explains two different approaches to setting up a highly available Kubernetes cluster using kubeadm:
- With stacked control plane nodes. This approach requires less infrastructure. The etcd members and control plane nodes are co-located.
- With an external etcd cluster. This approach requires more infrastructure. The control plane nodes and etcd members are separated.
Before proceeding, you should carefully consider which approach best meets the needs of your applications and environment. Options for Highly Available topology outlines the advantages and disadvantages of each.
If you encounter issues with setting up the HA cluster, please report these in the kubeadm issue tracker.
See also the upgrade documentation.
Before you begin
The prerequisites depend on which topology you have selected for your cluster's control plane:
You need:
- Three or more machines that meet kubeadm's minimum requirements for
the control-plane nodes. Having an odd number of control plane nodes can help
with leader selection in the case of machine or zone failure.
- including a container runtime, already set up and working
- Three or more machines that meet kubeadm's minimum
requirements for the workers
- including a container runtime, already set up and working
- Full network connectivity between all machines in the cluster (public or private network)
- Superuser privileges on all machines using
sudo
- You can use a different tool; this guide uses
sudo
in the examples.
- You can use a different tool; this guide uses
- SSH access from one device to all nodes in the system
kubeadm
andkubelet
already installed on all machines.
See Stacked etcd topology for context.
You need:
- Three or more machines that meet kubeadm's minimum requirements for
the control-plane nodes. Having an odd number of control plane nodes can help
with leader selection in the case of machine or zone failure.
- including a container runtime, already set up and working
- Three or more machines that meet kubeadm's minimum
requirements for the workers
- including a container runtime, already set up and working
- Full network connectivity between all machines in the cluster (public or private network)
- Superuser privileges on all machines using
sudo
- You can use a different tool; this guide uses
sudo
in the examples.
- You can use a different tool; this guide uses
- SSH access from one device to all nodes in the system
kubeadm
andkubelet
already installed on all machines.
And you also need:
- Three or more additional machines, that will become etcd cluster members.
Having an odd number of members in the etcd cluster is a requirement for achieving
optimal voting quorum.
- These machines again need to have
kubeadm
andkubelet
installed. - These machines also require a container runtime, that is already set up and working.
- These machines again need to have
See External etcd topology for context.
Container images
Each host should have access read and fetch images from the Kubernetes container image registry, registry.k8s.io
.
If you want to deploy a highly-available cluster where the hosts do not have access to pull images, this is possible. You must ensure by some other means that the correct container images are already available on the relevant hosts.
Command line interface
To manage Kubernetes once your cluster is set up, you should
install kubectl on your PC. It is also useful
to install the kubectl
tool on each control plane node, as this can be
helpful for troubleshooting.
First steps for both methods
Create load balancer for kube-apiserver
-
Create a kube-apiserver load balancer with a name that resolves to DNS.
-
In a cloud environment you should place your control plane nodes behind a TCP forwarding load balancer. This load balancer distributes traffic to all healthy control plane nodes in its target list. The health check for an apiserver is a TCP check on the port the kube-apiserver listens on (default value
:6443
). -
It is not recommended to use an IP address directly in a cloud environment.
-
The load balancer must be able to communicate with all control plane nodes on the apiserver port. It must also allow incoming traffic on its listening port.
-
Make sure the address of the load balancer always matches the address of kubeadm's
ControlPlaneEndpoint
. -
Read the Options for Software Load Balancing guide for more details.
-
-
Add the first control plane node to the load balancer, and test the connection:
nc -v <LOAD_BALANCER_IP> <PORT>
A connection refused error is expected because the API server is not yet running. A timeout, however, means the load balancer cannot communicate with the control plane node. If a timeout occurs, reconfigure the load balancer to communicate with the control plane node.
-
Add the remaining control plane nodes to the load balancer target group.
Stacked control plane and etcd nodes
Steps for the first control plane node
-
Initialize the control plane:
sudo kubeadm init --control-plane-endpoint "LOAD_BALANCER_DNS:LOAD_BALANCER_PORT" --upload-certs
-
You can use the
--kubernetes-version
flag to set the Kubernetes version to use. It is recommended that the versions of kubeadm, kubelet, kubectl and Kubernetes match. -
The
--control-plane-endpoint
flag should be set to the address or DNS and port of the load balancer. -
The
--upload-certs
flag is used to upload the certificates that should be shared across all the control-plane instances to the cluster. If instead, you prefer to copy certs across control-plane nodes manually or using automation tools, please remove this flag and refer to Manual certificate distribution section below.
Note: Thekubeadm init
flags--config
and--certificate-key
cannot be mixed, therefore if you want to use the kubeadm configuration you must add thecertificateKey
field in the appropriate config locations (underInitConfiguration
andJoinConfiguration: controlPlane
).Note: Some CNI network plugins require additional configuration, for example specifying the pod IP CIDR, while others do not. See the CNI network documentation. To add a pod CIDR pass the flag--pod-network-cidr
, or if you are using a kubeadm configuration file set thepodSubnet
field under thenetworking
object ofClusterConfiguration
.The output looks similar to:
... You can now join any number of control-plane node by running the following command on each as a root: kubeadm join 192.168.0.200:6443 --token 9vr73a.a8uxyaju799qwdjv --discovery-token-ca-cert-hash sha256:7c2e69131a36ae2a042a339b33381c6d0d43887e2de83720eff5359e26aec866 --control-plane --certificate-key f8902e114ef118304e561c3ecd4d0b543adc226b7a07f675f56564185ffe0c07 Please note that the certificate-key gives access to cluster sensitive data, keep it secret! As a safeguard, uploaded-certs will be deleted in two hours; If necessary, you can use kubeadm init phase upload-certs to reload certs afterward. Then you can join any number of worker nodes by running the following on each as root: kubeadm join 192.168.0.200:6443 --token 9vr73a.a8uxyaju799qwdjv --discovery-token-ca-cert-hash sha256:7c2e69131a36ae2a042a339b33381c6d0d43887e2de83720eff5359e26aec866
-
Copy this output to a text file. You will need it later to join control plane and worker nodes to the cluster.
-
When
--upload-certs
is used withkubeadm init
, the certificates of the primary control plane are encrypted and uploaded in thekubeadm-certs
Secret. -
To re-upload the certificates and generate a new decryption key, use the following command on a control plane node that is already joined to the cluster:
sudo kubeadm init phase upload-certs --upload-certs
-
You can also specify a custom
--certificate-key
duringinit
that can later be used byjoin
. To generate such a key you can use the following command:kubeadm certs certificate-key
The certificate key is a hex encoded string that is an AES key of size 32 bytes.
Note: Thekubeadm-certs
Secret and the decryption key expire after two hours.Caution: As stated in the command output, the certificate key gives access to cluster sensitive data, keep it secret! -
-
Apply the CNI plugin of your choice: Follow these instructions to install the CNI provider. Make sure the configuration corresponds to the Pod CIDR specified in the kubeadm configuration file (if applicable).
Note: You must pick a network plugin that suits your use case and deploy it before you move on to next step. If you don't do this, you will not be able to launch your cluster properly. -
Type the following and watch the pods of the control plane components get started:
kubectl get pod -n kube-system -w
Steps for the rest of the control plane nodes
For each additional control plane node you should:
-
Execute the join command that was previously given to you by the
kubeadm init
output on the first node. It should look something like this:sudo kubeadm join 192.168.0.200:6443 --token 9vr73a.a8uxyaju799qwdjv --discovery-token-ca-cert-hash sha256:7c2e69131a36ae2a042a339b33381c6d0d43887e2de83720eff5359e26aec866 --control-plane --certificate-key f8902e114ef118304e561c3ecd4d0b543adc226b7a07f675f56564185ffe0c07
- The
--control-plane
flag tellskubeadm join
to create a new control plane. - The
--certificate-key ...
will cause the control plane certificates to be downloaded from thekubeadm-certs
Secret in the cluster and be decrypted using the given key.
- The
You can join multiple control-plane nodes in parallel.
External etcd nodes
Setting up a cluster with external etcd nodes is similar to the procedure used for stacked etcd with the exception that you should setup etcd first, and you should pass the etcd information in the kubeadm config file.
Set up the etcd cluster
-
Follow these instructions to set up the etcd cluster.
-
Set up SSH as described here.
-
Copy the following files from any etcd node in the cluster to the first control plane node:
export CONTROL_PLANE="ubuntu@10.0.0.7" scp /etc/kubernetes/pki/etcd/ca.crt "${CONTROL_PLANE}": scp /etc/kubernetes/pki/apiserver-etcd-client.crt "${CONTROL_PLANE}": scp /etc/kubernetes/pki/apiserver-etcd-client.key "${CONTROL_PLANE}":
- Replace the value of
CONTROL_PLANE
with theuser@host
of the first control-plane node.
- Replace the value of
Set up the first control plane node
-
Create a file called
kubeadm-config.yaml
with the following contents:--- apiVersion: kubeadm.k8s.io/v1beta3 kind: ClusterConfiguration kubernetesVersion: stable controlPlaneEndpoint: "LOAD_BALANCER_DNS:LOAD_BALANCER_PORT" # change this (see below) etcd: external: endpoints: - https://ETCD_0_IP:2379 # change ETCD_0_IP appropriately - https://ETCD_1_IP:2379 # change ETCD_1_IP appropriately - https://ETCD_2_IP:2379 # change ETCD_2_IP appropriately caFile: /etc/kubernetes/pki/etcd/ca.crt certFile: /etc/kubernetes/pki/apiserver-etcd-client.crt keyFile: /etc/kubernetes/pki/apiserver-etcd-client.key
Note: The difference between stacked etcd and external etcd here is that the external etcd setup requires a configuration file with the etcd endpoints under theexternal
object foretcd
. In the case of the stacked etcd topology, this is managed automatically.-
Replace the following variables in the config template with the appropriate values for your cluster:
LOAD_BALANCER_DNS
LOAD_BALANCER_PORT
ETCD_0_IP
ETCD_1_IP
ETCD_2_IP
-
The following steps are similar to the stacked etcd setup:
-
Run
sudo kubeadm init --config kubeadm-config.yaml --upload-certs
on this node. -
Write the output join commands that are returned to a text file for later use.
-
Apply the CNI plugin of your choice.
Note: You must pick a network plugin that suits your use case and deploy it before you move on to next step. If you don't do this, you will not be able to launch your cluster properly.
Steps for the rest of the control plane nodes
The steps are the same as for the stacked etcd setup:
- Make sure the first control plane node is fully initialized.
- Join each control plane node with the join command you saved to a text file. It's recommended to join the control plane nodes one at a time.
- Don't forget that the decryption key from
--certificate-key
expires after two hours, by default.
Common tasks after bootstrapping control plane
Install workers
Worker nodes can be joined to the cluster with the command you stored previously
as the output from the kubeadm init
command:
sudo kubeadm join 192.168.0.200:6443 --token 9vr73a.a8uxyaju799qwdjv --discovery-token-ca-cert-hash sha256:7c2e69131a36ae2a042a339b33381c6d0d43887e2de83720eff5359e26aec866
Manual certificate distribution
If you choose to not use kubeadm init
with the --upload-certs
flag this means that
you are going to have to manually copy the certificates from the primary control plane node to the
joining control plane nodes.
There are many ways to do this. The following example uses ssh
and scp
:
SSH is required if you want to control all nodes from a single machine.
-
Enable ssh-agent on your main device that has access to all other nodes in the system:
eval $(ssh-agent)
-
Add your SSH identity to the session:
ssh-add ~/.ssh/path_to_private_key
-
SSH between nodes to check that the connection is working correctly.
-
When you SSH to any node, add the
-A
flag. This flag allows the node that you have logged into via SSH to access the SSH agent on your PC. Consider alternative methods if you do not fully trust the security of your user session on the node.ssh -A 10.0.0.7
-
When using sudo on any node, make sure to preserve the environment so SSH forwarding works:
sudo -E -s
-
-
After configuring SSH on all the nodes you should run the following script on the first control plane node after running
kubeadm init
. This script will copy the certificates from the first control plane node to the other control plane nodes:In the following example, replace
CONTROL_PLANE_IPS
with the IP addresses of the other control plane nodes.USER=ubuntu # customizable CONTROL_PLANE_IPS="10.0.0.7 10.0.0.8" for host in ${CONTROL_PLANE_IPS}; do scp /etc/kubernetes/pki/ca.crt "${USER}"@$host: scp /etc/kubernetes/pki/ca.key "${USER}"@$host: scp /etc/kubernetes/pki/sa.key "${USER}"@$host: scp /etc/kubernetes/pki/sa.pub "${USER}"@$host: scp /etc/kubernetes/pki/front-proxy-ca.crt "${USER}"@$host: scp /etc/kubernetes/pki/front-proxy-ca.key "${USER}"@$host: scp /etc/kubernetes/pki/etcd/ca.crt "${USER}"@$host:etcd-ca.crt # Skip the next line if you are using external etcd scp /etc/kubernetes/pki/etcd/ca.key "${USER}"@$host:etcd-ca.key done
Caution: Copy only the certificates in the above list. kubeadm will take care of generating the rest of the certificates with the required SANs for the joining control-plane instances. If you copy all the certificates by mistake, the creation of additional nodes could fail due to a lack of required SANs. -
Then on each joining control plane node you have to run the following script before running
kubeadm join
. This script will move the previously copied certificates from the home directory to/etc/kubernetes/pki
:USER=ubuntu # customizable mkdir -p /etc/kubernetes/pki/etcd mv /home/${USER}/ca.crt /etc/kubernetes/pki/ mv /home/${USER}/ca.key /etc/kubernetes/pki/ mv /home/${USER}/sa.pub /etc/kubernetes/pki/ mv /home/${USER}/sa.key /etc/kubernetes/pki/ mv /home/${USER}/front-proxy-ca.crt /etc/kubernetes/pki/ mv /home/${USER}/front-proxy-ca.key /etc/kubernetes/pki/ mv /home/${USER}/etcd-ca.crt /etc/kubernetes/pki/etcd/ca.crt # Skip the next line if you are using external etcd mv /home/${USER}/etcd-ca.key /etc/kubernetes/pki/etcd/ca.key
7 - Set up a High Availability etcd Cluster with kubeadm
By default, kubeadm runs a local etcd instance on each control plane node. It is also possible to treat the etcd cluster as external and provision etcd instances on separate hosts. The differences between the two approaches are covered in the Options for Highly Available topology page.
This task walks through the process of creating a high availability external etcd cluster of three members that can be used by kubeadm during cluster creation.
Before you begin
- Three hosts that can talk to each other over TCP ports 2379 and 2380. This document assumes these default ports. However, they are configurable through the kubeadm config file.
- Each host must have systemd and a bash compatible shell installed.
- Each host must have a container runtime, kubelet, and kubeadm installed.
- Each host should have access to the Kubernetes container image registry (
registry.k8s.io
) or list/pull the required etcd image usingkubeadm config images list/pull
. This guide will set up etcd instances as static pods managed by a kubelet. - Some infrastructure to copy files between hosts. For example
ssh
andscp
can satisfy this requirement.
Setting up the cluster
The general approach is to generate all certs on one node and only distribute the necessary files to the other nodes.
-
Configure the kubelet to be a service manager for etcd.
Note: You must do this on every host where etcd should be running.Since etcd was created first, you must override the service priority by creating a new unit file that has higher precedence than the kubeadm-provided kubelet unit file.cat << EOF > /etc/systemd/system/kubelet.service.d/kubelet.conf # Replace "systemd" with the cgroup driver of your container runtime. The default value in the kubelet is "cgroupfs". # Replace the value of "containerRuntimeEndpoint" for a different container runtime if needed. # apiVersion: kubelet.config.k8s.io/v1beta1 kind: KubeletConfiguration authentication: anonymous: enabled: false webhook: enabled: false authorization: mode: AlwaysAllow cgroupDriver: systemd address: 127.0.0.1 containerRuntimeEndpoint: unix:///var/run/containerd/containerd.sock staticPodPath: /etc/kubernetes/manifests EOF cat << EOF > /etc/systemd/system/kubelet.service.d/20-etcd-service-manager.conf [Service] ExecStart= ExecStart=/usr/bin/kubelet --config=/etc/systemd/system/kubelet.service.d/kubelet.conf Restart=always EOF systemctl daemon-reload systemctl restart kubelet
Check the kubelet status to ensure it is running.
systemctl status kubelet
-
Create configuration files for kubeadm.
Generate one kubeadm configuration file for each host that will have an etcd member running on it using the following script.
# Update HOST0, HOST1 and HOST2 with the IPs of your hosts export HOST0=10.0.0.6 export HOST1=10.0.0.7 export HOST2=10.0.0.8 # Update NAME0, NAME1 and NAME2 with the hostnames of your hosts export NAME0="infra0" export NAME1="infra1" export NAME2="infra2" # Create temp directories to store files that will end up on other hosts mkdir -p /tmp/${HOST0}/ /tmp/${HOST1}/ /tmp/${HOST2}/ HOSTS=(${HOST0} ${HOST1} ${HOST2}) NAMES=(${NAME0} ${NAME1} ${NAME2}) for i in "${!HOSTS[@]}"; do HOST=${HOSTS[$i]} NAME=${NAMES[$i]} cat << EOF > /tmp/${HOST}/kubeadmcfg.yaml --- apiVersion: "kubeadm.k8s.io/v1beta3" kind: InitConfiguration nodeRegistration: name: ${NAME} localAPIEndpoint: advertiseAddress: ${HOST} --- apiVersion: "kubeadm.k8s.io/v1beta3" kind: ClusterConfiguration etcd: local: serverCertSANs: - "${HOST}" peerCertSANs: - "${HOST}" extraArgs: initial-cluster: ${NAMES[0]}=https://${HOSTS[0]}:2380,${NAMES[1]}=https://${HOSTS[1]}:2380,${NAMES[2]}=https://${HOSTS[2]}:2380 initial-cluster-state: new name: ${NAME} listen-peer-urls: https://${HOST}:2380 listen-client-urls: https://${HOST}:2379 advertise-client-urls: https://${HOST}:2379 initial-advertise-peer-urls: https://${HOST}:2380 EOF done
-
Generate the certificate authority.
If you already have a CA then the only action that is copying the CA's
crt
andkey
file to/etc/kubernetes/pki/etcd/ca.crt
and/etc/kubernetes/pki/etcd/ca.key
. After those files have been copied, proceed to the next step, "Create certificates for each member".If you do not already have a CA then run this command on
$HOST0
(where you generated the configuration files for kubeadm).kubeadm init phase certs etcd-ca
This creates two files:
/etc/kubernetes/pki/etcd/ca.crt
/etc/kubernetes/pki/etcd/ca.key
-
Create certificates for each member.
kubeadm init phase certs etcd-server --config=/tmp/${HOST2}/kubeadmcfg.yaml kubeadm init phase certs etcd-peer --config=/tmp/${HOST2}/kubeadmcfg.yaml kubeadm init phase certs etcd-healthcheck-client --config=/tmp/${HOST2}/kubeadmcfg.yaml kubeadm init phase certs apiserver-etcd-client --config=/tmp/${HOST2}/kubeadmcfg.yaml cp -R /etc/kubernetes/pki /tmp/${HOST2}/ # cleanup non-reusable certificates find /etc/kubernetes/pki -not -name ca.crt -not -name ca.key -type f -delete kubeadm init phase certs etcd-server --config=/tmp/${HOST1}/kubeadmcfg.yaml kubeadm init phase certs etcd-peer --config=/tmp/${HOST1}/kubeadmcfg.yaml kubeadm init phase certs etcd-healthcheck-client --config=/tmp/${HOST1}/kubeadmcfg.yaml kubeadm init phase certs apiserver-etcd-client --config=/tmp/${HOST1}/kubeadmcfg.yaml cp -R /etc/kubernetes/pki /tmp/${HOST1}/ find /etc/kubernetes/pki -not -name ca.crt -not -name ca.key -type f -delete kubeadm init phase certs etcd-server --config=/tmp/${HOST0}/kubeadmcfg.yaml kubeadm init phase certs etcd-peer --config=/tmp/${HOST0}/kubeadmcfg.yaml kubeadm init phase certs etcd-healthcheck-client --config=/tmp/${HOST0}/kubeadmcfg.yaml kubeadm init phase certs apiserver-etcd-client --config=/tmp/${HOST0}/kubeadmcfg.yaml # No need to move the certs because they are for HOST0 # clean up certs that should not be copied off this host find /tmp/${HOST2} -name ca.key -type f -delete find /tmp/${HOST1} -name ca.key -type f -delete
-
Copy certificates and kubeadm configs.
The certificates have been generated and now they must be moved to their respective hosts.
USER=ubuntu HOST=${HOST1} scp -r /tmp/${HOST}/* ${USER}@${HOST}: ssh ${USER}@${HOST} USER@HOST $ sudo -Es root@HOST $ chown -R root:root pki root@HOST $ mv pki /etc/kubernetes/
-
Ensure all expected files exist.
The complete list of required files on
$HOST0
is:/tmp/${HOST0} └── kubeadmcfg.yaml --- /etc/kubernetes/pki ├── apiserver-etcd-client.crt ├── apiserver-etcd-client.key └── etcd ├── ca.crt ├── ca.key ├── healthcheck-client.crt ├── healthcheck-client.key ├── peer.crt ├── peer.key ├── server.crt └── server.key
On
$HOST1
:$HOME └── kubeadmcfg.yaml --- /etc/kubernetes/pki ├── apiserver-etcd-client.crt ├── apiserver-etcd-client.key └── etcd ├── ca.crt ├── healthcheck-client.crt ├── healthcheck-client.key ├── peer.crt ├── peer.key ├── server.crt └── server.key
On
$HOST2
:$HOME └── kubeadmcfg.yaml --- /etc/kubernetes/pki ├── apiserver-etcd-client.crt ├── apiserver-etcd-client.key └── etcd ├── ca.crt ├── healthcheck-client.crt ├── healthcheck-client.key ├── peer.crt ├── peer.key ├── server.crt └── server.key
-
Create the static pod manifests.
Now that the certificates and configs are in place it's time to create the manifests. On each host run the
kubeadm
command to generate a static manifest for etcd.root@HOST0 $ kubeadm init phase etcd local --config=/tmp/${HOST0}/kubeadmcfg.yaml root@HOST1 $ kubeadm init phase etcd local --config=$HOME/kubeadmcfg.yaml root@HOST2 $ kubeadm init phase etcd local --config=$HOME/kubeadmcfg.yaml
-
Optional: Check the cluster health.
If
etcdctl
isn't available, you can run this tool inside a container image. You would do that directly with your container runtime using a tool such ascrictl run
and not through KubernetesETCDCTL_API=3 etcdctl \ --cert /etc/kubernetes/pki/etcd/peer.crt \ --key /etc/kubernetes/pki/etcd/peer.key \ --cacert /etc/kubernetes/pki/etcd/ca.crt \ --endpoints https://${HOST0}:2379 endpoint health ... https://[HOST0 IP]:2379 is healthy: successfully committed proposal: took = 16.283339ms https://[HOST1 IP]:2379 is healthy: successfully committed proposal: took = 19.44402ms https://[HOST2 IP]:2379 is healthy: successfully committed proposal: took = 35.926451ms
- Set
${HOST0}
to the IP address of the host you are testing.
- Set
What's next
Once you have an etcd cluster with 3 working members, you can continue setting up a highly available control plane using the external etcd method with kubeadm.
8 - Configuring each kubelet in your cluster using kubeadm
Kubernetes v1.11 [stable]
The lifecycle of the kubeadm CLI tool is decoupled from the kubelet, which is a daemon that runs on each node within the Kubernetes cluster. The kubeadm CLI tool is executed by the user when Kubernetes is initialized or upgraded, whereas the kubelet is always running in the background.
Since the kubelet is a daemon, it needs to be maintained by some kind of an init system or service manager. When the kubelet is installed using DEBs or RPMs, systemd is configured to manage the kubelet. You can use a different service manager instead, but you need to configure it manually.
Some kubelet configuration details need to be the same across all kubelets involved in the cluster, while
other configuration aspects need to be set on a per-kubelet basis to accommodate the different
characteristics of a given machine (such as OS, storage, and networking). You can manage the configuration
of your kubelets manually, but kubeadm now provides a KubeletConfiguration
API type for
managing your kubelet configurations centrally.
Kubelet configuration patterns
The following sections describe patterns to kubelet configuration that are simplified by using kubeadm, rather than managing the kubelet configuration for each Node manually.
Propagating cluster-level configuration to each kubelet
You can provide the kubelet with default values to be used by kubeadm init
and kubeadm join
commands. Interesting examples include using a different container runtime or setting the default subnet
used by services.
If you want your services to use the subnet 10.96.0.0/12
as the default for services, you can pass
the --service-cidr
parameter to kubeadm:
kubeadm init --service-cidr 10.96.0.0/12
Virtual IPs for services are now allocated from this subnet. You also need to set the DNS address used
by the kubelet, using the --cluster-dns
flag. This setting needs to be the same for every kubelet
on every manager and Node in the cluster. The kubelet provides a versioned, structured API object
that can configure most parameters in the kubelet and push out this configuration to each running
kubelet in the cluster. This object is called
KubeletConfiguration
.
The KubeletConfiguration
allows the user to specify flags such as the cluster DNS IP addresses expressed as
a list of values to a camelCased key, illustrated by the following example:
apiVersion: kubelet.config.k8s.io/v1beta1
kind: KubeletConfiguration
clusterDNS:
- 10.96.0.10
For more details on the KubeletConfiguration
have a look at this section.
Providing instance-specific configuration details
Some hosts require specific kubelet configurations due to differences in hardware, operating system, networking, or other host-specific parameters. The following list provides a few examples.
-
The path to the DNS resolution file, as specified by the
--resolv-conf
kubelet configuration flag, may differ among operating systems, or depending on whether you are usingsystemd-resolved
. If this path is wrong, DNS resolution will fail on the Node whose kubelet is configured incorrectly. -
The Node API object
.metadata.name
is set to the machine's hostname by default, unless you are using a cloud provider. You can use the--hostname-override
flag to override the default behavior if you need to specify a Node name different from the machine's hostname. -
Currently, the kubelet cannot automatically detect the cgroup driver used by the container runtime, but the value of
--cgroup-driver
must match the cgroup driver used by the container runtime to ensure the health of the kubelet. -
To specify the container runtime you must set its endpoint with the
--container-runtime-endpoint=<path>
flag.
The recommended way of applying such instance-specific configuration is by using
KubeletConfiguration
patches.
Configure kubelets using kubeadm
It is possible to configure the kubelet that kubeadm will start if a custom
KubeletConfiguration
API object is passed with a configuration file like so kubeadm ... --config some-config-file.yaml
.
By calling kubeadm config print init-defaults --component-configs KubeletConfiguration
you can
see all the default values for this structure.
It is also possible to apply instance-specific patches over the base KubeletConfiguration
.
Have a look at Customizing the kubelet
for more details.
Workflow when using kubeadm init
When you call kubeadm init
, the kubelet configuration is marshalled to disk
at /var/lib/kubelet/config.yaml
, and also uploaded to a kubelet-config
ConfigMap in the kube-system
namespace of the cluster. A kubelet configuration file is also written to /etc/kubernetes/kubelet.conf
with the baseline cluster-wide configuration for all kubelets in the cluster. This configuration file
points to the client certificates that allow the kubelet to communicate with the API server. This
addresses the need to
propagate cluster-level configuration to each kubelet.
To address the second pattern of
providing instance-specific configuration details,
kubeadm writes an environment file to /var/lib/kubelet/kubeadm-flags.env
, which contains a list of
flags to pass to the kubelet when it starts. The flags are presented in the file like this:
KUBELET_KUBEADM_ARGS="--flag1=value1 --flag2=value2 ..."
In addition to the flags used when starting the kubelet, the file also contains dynamic
parameters such as the cgroup driver and whether to use a different container runtime socket
(--cri-socket
).
After marshalling these two files to disk, kubeadm attempts to run the following two commands, if you are using systemd:
systemctl daemon-reload && systemctl restart kubelet
If the reload and restart are successful, the normal kubeadm init
workflow continues.
Workflow when using kubeadm join
When you run kubeadm join
, kubeadm uses the Bootstrap Token credential to perform
a TLS bootstrap, which fetches the credential needed to download the
kubelet-config
ConfigMap and writes it to /var/lib/kubelet/config.yaml
. The dynamic
environment file is generated in exactly the same way as kubeadm init
.
Next, kubeadm
runs the following two commands to load the new configuration into the kubelet:
systemctl daemon-reload && systemctl restart kubelet
After the kubelet loads the new configuration, kubeadm writes the
/etc/kubernetes/bootstrap-kubelet.conf
KubeConfig file, which contains a CA certificate and Bootstrap
Token. These are used by the kubelet to perform the TLS Bootstrap and obtain a unique
credential, which is stored in /etc/kubernetes/kubelet.conf
.
When the /etc/kubernetes/kubelet.conf
file is written, the kubelet has finished performing the TLS Bootstrap.
Kubeadm deletes the /etc/kubernetes/bootstrap-kubelet.conf
file after completing the TLS Bootstrap.
The kubelet drop-in file for systemd
kubeadm
ships with configuration for how systemd should run the kubelet.
Note that the kubeadm CLI command never touches this drop-in file.
This configuration file installed by the kubeadm
package is written to
/etc/systemd/system/kubelet.service.d/10-kubeadm.conf
and is used by systemd.
It augments the basic
kubelet.service
:
[Service]
Environment="KUBELET_KUBECONFIG_ARGS=--bootstrap-kubeconfig=/etc/kubernetes/bootstrap-kubelet.conf --kubeconfig=/etc/kubernetes/kubelet.conf"
Environment="KUBELET_CONFIG_ARGS=--config=/var/lib/kubelet/config.yaml"
# This is a file that "kubeadm init" and "kubeadm join" generate at runtime, populating
# the KUBELET_KUBEADM_ARGS variable dynamically
EnvironmentFile=-/var/lib/kubelet/kubeadm-flags.env
# This is a file that the user can use for overrides of the kubelet args as a last resort. Preferably,
# the user should use the .NodeRegistration.KubeletExtraArgs object in the configuration files instead.
# KUBELET_EXTRA_ARGS should be sourced from this file.
EnvironmentFile=-/etc/default/kubelet
ExecStart=
ExecStart=/usr/bin/kubelet $KUBELET_KUBECONFIG_ARGS $KUBELET_CONFIG_ARGS $KUBELET_KUBEADM_ARGS $KUBELET_EXTRA_ARGS
This file specifies the default locations for all of the files managed by kubeadm for the kubelet.
- The KubeConfig file to use for the TLS Bootstrap is
/etc/kubernetes/bootstrap-kubelet.conf
, but it is only used if/etc/kubernetes/kubelet.conf
does not exist. - The KubeConfig file with the unique kubelet identity is
/etc/kubernetes/kubelet.conf
. - The file containing the kubelet's ComponentConfig is
/var/lib/kubelet/config.yaml
. - The dynamic environment file that contains
KUBELET_KUBEADM_ARGS
is sourced from/var/lib/kubelet/kubeadm-flags.env
. - The file that can contain user-specified flag overrides with
KUBELET_EXTRA_ARGS
is sourced from/etc/default/kubelet
(for DEBs), or/etc/sysconfig/kubelet
(for RPMs).KUBELET_EXTRA_ARGS
is last in the flag chain and has the highest priority in the event of conflicting settings.
Kubernetes binaries and package contents
The DEB and RPM packages shipped with the Kubernetes releases are:
Package name | Description |
---|---|
kubeadm |
Installs the /usr/bin/kubeadm CLI tool and the kubelet drop-in file for the kubelet. |
kubelet |
Installs the /usr/bin/kubelet binary. |
kubectl |
Installs the /usr/bin/kubectl binary. |
cri-tools |
Installs the /usr/bin/crictl binary from the cri-tools git repository. |
kubernetes-cni |
Installs the /opt/cni/bin binaries from the plugins git repository. |
9 - Dual-stack support with kubeadm
Kubernetes v1.23 [stable]
Your Kubernetes cluster includes dual-stack networking, which means that cluster networking lets you use either address family. In a cluster, the control plane can assign both an IPv4 address and an IPv6 address to a single Pod or a Service.
Before you begin
You need to have installed the kubeadm tool, following the steps from Installing kubeadm.
For each server that you want to use as a node,
make sure it allows IPv6 forwarding. On Linux, you can set this by running run
sysctl -w net.ipv6.conf.all.forwarding=1
as the root user on each server.
You need to have an IPv4 and and IPv6 address range to use. Cluster operators typically
use private address ranges for IPv4. For IPv6, a cluster operator typically chooses a global
unicast address block from within 2000::/3
, using a range that is assigned to the operator.
You don't have to route the cluster's IP address ranges to the public internet.
The size of the IP address allocations should be suitable for the number of Pods and Services that you are planning to run.
kubeadm upgrade
command,
kubeadm
does not support making modifications to the pod IP address range
(“cluster CIDR”) nor to the cluster's Service address range (“Service CIDR”).
Create a dual-stack cluster
To create a dual-stack cluster with kubeadm init
you can pass command line arguments
similar to the following example:
# These address ranges are examples
kubeadm init --pod-network-cidr=10.244.0.0/16,2001:db8:42:0::/56 --service-cidr=10.96.0.0/16,2001:db8:42:1::/112
To make things clearer, here is an example kubeadm
configuration file
kubeadm-config.yaml
for the primary dual-stack control plane node.
---
apiVersion: kubeadm.k8s.io/v1beta3
kind: ClusterConfiguration
networking:
podSubnet: 10.244.0.0/16,2001:db8:42:0::/56
serviceSubnet: 10.96.0.0/16,2001:db8:42:1::/112
---
apiVersion: kubeadm.k8s.io/v1beta3
kind: InitConfiguration
localAPIEndpoint:
advertiseAddress: "10.100.0.1"
bindPort: 6443
nodeRegistration:
kubeletExtraArgs:
node-ip: 10.100.0.2,fd00:1:2:3::2
advertiseAddress
in InitConfiguration specifies the IP address that the API Server
will advertise it is listening on. The value of advertiseAddress
equals the
--apiserver-advertise-address
flag of kubeadm init
.
Run kubeadm to initiate the dual-stack control plane node:
kubeadm init --config=kubeadm-config.yaml
The kube-controller-manager flags --node-cidr-mask-size-ipv4|--node-cidr-mask-size-ipv6
are set with default values. See configure IPv4/IPv6 dual stack.
--apiserver-advertise-address
flag does not support dual-stack.
Join a node to dual-stack cluster
Before joining a node, make sure that the node has IPv6 routable network interface and allows IPv6 forwarding.
Here is an example kubeadm configuration file
kubeadm-config.yaml
for joining a worker node to the cluster.
apiVersion: kubeadm.k8s.io/v1beta3
kind: JoinConfiguration
discovery:
bootstrapToken:
apiServerEndpoint: 10.100.0.1:6443
token: "clvldh.vjjwg16ucnhp94qr"
caCertHashes:
- "sha256:a4863cde706cfc580a439f842cc65d5ef112b7b2be31628513a9881cf0d9fe0e"
# change auth info above to match the actual token and CA certificate hash for your cluster
nodeRegistration:
kubeletExtraArgs:
node-ip: 10.100.0.3,fd00:1:2:3::3
Also, here is an example kubeadm configuration file
kubeadm-config.yaml
for joining another control plane node to the cluster.
apiVersion: kubeadm.k8s.io/v1beta3
kind: JoinConfiguration
controlPlane:
localAPIEndpoint:
advertiseAddress: "10.100.0.2"
bindPort: 6443
discovery:
bootstrapToken:
apiServerEndpoint: 10.100.0.1:6443
token: "clvldh.vjjwg16ucnhp94qr"
caCertHashes:
- "sha256:a4863cde706cfc580a439f842cc65d5ef112b7b2be31628513a9881cf0d9fe0e"
# change auth info above to match the actual token and CA certificate hash for your cluster
nodeRegistration:
kubeletExtraArgs:
node-ip: 10.100.0.4,fd00:1:2:3::4
advertiseAddress
in JoinConfiguration.controlPlane specifies the IP address that the
API Server will advertise it is listening on. The value of advertiseAddress
equals
the --apiserver-advertise-address
flag of kubeadm join
.
kubeadm join --config=kubeadm-config.yaml
Create a single-stack cluster
To make things more clear, here is an example kubeadm
configuration file
kubeadm-config.yaml
for the single-stack control plane node.
apiVersion: kubeadm.k8s.io/v1beta3
kind: ClusterConfiguration
networking:
podSubnet: 10.244.0.0/16
serviceSubnet: 10.96.0.0/16
What's next
- Validate IPv4/IPv6 dual-stack networking
- Read about Dual-stack cluster networking
- Learn more about the kubeadm configuration format