kubeadm init
This command initializes a Kubernetes control-plane node.
Run this command in order to set up the Kubernetes control plane
Synopsis
Run this command in order to set up the Kubernetes control plane
The "init" command executes the following phases:
preflight Run pre-flight checks
certs Certificate generation
/ca Generate the self-signed Kubernetes CA to provision identities for other Kubernetes components
/apiserver Generate the certificate for serving the Kubernetes API
/apiserver-kubelet-client Generate the certificate for the API server to connect to kubelet
/front-proxy-ca Generate the self-signed CA to provision identities for front proxy
/front-proxy-client Generate the certificate for the front proxy client
/etcd-ca Generate the self-signed CA to provision identities for etcd
/etcd-server Generate the certificate for serving etcd
/etcd-peer Generate the certificate for etcd nodes to communicate with each other
/etcd-healthcheck-client Generate the certificate for liveness probes to healthcheck etcd
/apiserver-etcd-client Generate the certificate the apiserver uses to access etcd
/sa Generate a private key for signing service account tokens along with its public key
kubeconfig Generate all kubeconfig files necessary to establish the control plane and the admin kubeconfig file
/admin Generate a kubeconfig file for the admin to use and for kubeadm itself
/super-admin Generate a kubeconfig file for the super-admin
/kubelet Generate a kubeconfig file for the kubelet to use *only* for cluster bootstrapping purposes
/controller-manager Generate a kubeconfig file for the controller manager to use
/scheduler Generate a kubeconfig file for the scheduler to use
etcd Generate static Pod manifest file for local etcd
/local Generate the static Pod manifest file for a local, single-node local etcd instance
control-plane Generate all static Pod manifest files necessary to establish the control plane
/apiserver Generates the kube-apiserver static Pod manifest
/controller-manager Generates the kube-controller-manager static Pod manifest
/scheduler Generates the kube-scheduler static Pod manifest
kubelet-start Write kubelet settings and (re)start the kubelet
upload-config Upload the kubeadm and kubelet configuration to a ConfigMap
/kubeadm Upload the kubeadm ClusterConfiguration to a ConfigMap
/kubelet Upload the kubelet component config to a ConfigMap
upload-certs Upload certificates to kubeadm-certs
mark-control-plane Mark a node as a control-plane
bootstrap-token Generates bootstrap tokens used to join a node to a cluster
kubelet-finalize Updates settings relevant to the kubelet after TLS bootstrap
/enable-client-cert-rotation Enable kubelet client certificate rotation
/experimental-cert-rotation Enable kubelet client certificate rotation (DEPRECATED: use 'enable-client-cert-rotation' instead)
addon Install required addons for passing conformance tests
/coredns Install the CoreDNS addon to a Kubernetes cluster
/kube-proxy Install the kube-proxy addon to a Kubernetes cluster
show-join-command Show the join command for control-plane and worker node
kubeadm init [flags]
Options
--apiserver-advertise-address string | |
The IP address the API Server will advertise it's listening on. If not set the default network interface will be used. |
|
--apiserver-bind-port int32 Default: 6443 | |
Port for the API Server to bind to. |
|
--apiserver-cert-extra-sans strings | |
Optional extra Subject Alternative Names (SANs) to use for the API Server serving certificate. Can be both IP addresses and DNS names. |
|
--cert-dir string Default: "/etc/kubernetes/pki" | |
The path where to save and store the certificates. |
|
--certificate-key string | |
Key used to encrypt the control-plane certificates in the kubeadm-certs Secret. The certificate key is a hex encoded string that is an AES key of size 32 bytes. |
|
--config string | |
Path to a kubeadm configuration file. |
|
--control-plane-endpoint string | |
Specify a stable IP address or DNS name for the control plane. |
|
--cri-socket string | |
Path to the CRI socket to connect. If empty kubeadm will try to auto-detect this value; use this option only if you have more than one CRI installed or if you have non-standard CRI socket. |
|
--dry-run | |
Don't apply any changes; just output what would be done. |
|
--feature-gates string | |
A set of key=value pairs that describe feature gates for various features. Options are: |
|
-h, --help | |
help for init |
|
--ignore-preflight-errors strings | |
A list of checks whose errors will be shown as warnings. Example: 'IsPrivilegedUser,Swap'. Value 'all' ignores errors from all checks. |
|
--image-repository string Default: "registry.k8s.io" | |
Choose a container registry to pull control plane images from |
|
--kubernetes-version string Default: "stable-1" | |
Choose a specific Kubernetes version for the control plane. |
|
--node-name string | |
Specify the node name. |
|
--patches string | |
Path to a directory that contains files named "target[suffix][+patchtype].extension". For example, "kube-apiserver0+merge.yaml" or just "etcd.json". "target" can be one of "kube-apiserver", "kube-controller-manager", "kube-scheduler", "etcd", "kubeletconfiguration", "corednsdeployment". "patchtype" can be one of "strategic", "merge" or "json" and they match the patch formats supported by kubectl. The default "patchtype" is "strategic". "extension" must be either "json" or "yaml". "suffix" is an optional string that can be used to determine which patches are applied first alpha-numerically. |
|
--pod-network-cidr string | |
Specify range of IP addresses for the pod network. If set, the control plane will automatically allocate CIDRs for every node. |
|
--service-cidr string Default: "10.96.0.0/12" | |
Use alternative range of IP address for service VIPs. |
|
--service-dns-domain string Default: "cluster.local" | |
Use alternative domain for services, e.g. "myorg.internal". |
|
--skip-certificate-key-print | |
Don't print the key used to encrypt the control-plane certificates. |
|
--skip-phases strings | |
List of phases to be skipped |
|
--skip-token-print | |
Skip printing of the default bootstrap token generated by 'kubeadm init'. |
|
--token string | |
The token to use for establishing bidirectional trust between nodes and control-plane nodes. The format is [a-z0-9]{6}.[a-z0-9]{16} - e.g. abcdef.0123456789abcdef |
|
--token-ttl duration Default: 24h0m0s | |
The duration before the token is automatically deleted (e.g. 1s, 2m, 3h). If set to '0', the token will never expire |
|
--upload-certs | |
Upload control-plane certificates to the kubeadm-certs Secret. |
Options inherited from parent commands
--rootfs string | |
The path to the 'real' host root filesystem. This will cause kubeadm to chroot into the provided path. |
Init workflow
kubeadm init
bootstraps a Kubernetes control-plane node by executing the
following steps:
-
Runs a series of pre-flight checks to validate the system state before making changes. Some checks only trigger warnings, others are considered errors and will exit kubeadm until the problem is corrected or the user specifies
--ignore-preflight-errors=<list-of-errors>
. -
Generates a self-signed CA to set up identities for each component in the cluster. The user can provide their own CA cert and/or key by dropping it in the cert directory configured via
--cert-dir
(/etc/kubernetes/pki
by default). The APIServer certs will have additional SAN entries for any--apiserver-cert-extra-sans
arguments, lowercased if necessary. -
Writes kubeconfig files in
/etc/kubernetes/
for the kubelet, the controller-manager and the scheduler to use to connect to the API server, each with its own identity. Also additional kubeconfig files are written, for kubeadm as administrative entity (admin.conf
) and for a super admin user that can bypass RBAC (super-admin.conf
). -
Generates static Pod manifests for the API server, controller-manager and scheduler. In case an external etcd is not provided, an additional static Pod manifest is generated for etcd.
Static Pod manifests are written to
/etc/kubernetes/manifests
; the kubelet watches this directory for Pods to create on startup.Once control plane Pods are up and running, the
kubeadm init
sequence can continue. -
Apply labels and taints to the control-plane node so that no additional workloads will run there.
-
Generates the token that additional nodes can use to register themselves with a control-plane in the future. Optionally, the user can provide a token via
--token
, as described in the kubeadm token docs. -
Makes all the necessary configurations for allowing node joining with the Bootstrap Tokens and TLS Bootstrap mechanism:
-
Write a ConfigMap for making available all the information required for joining, and set up related RBAC access rules.
-
Let Bootstrap Tokens access the CSR signing API.
-
Configure auto-approval for new CSR requests.
See kubeadm join for additional info.
-
-
Installs a DNS server (CoreDNS) and the kube-proxy addon components via the API server. In Kubernetes version 1.11 and later CoreDNS is the default DNS server. Please note that although the DNS server is deployed, it will not be scheduled until CNI is installed.
Warning:
kube-dns usage with kubeadm is deprecated as of v1.18 and is removed in v1.21.
Using init phases with kubeadm
Kubeadm allows you to create a control-plane node in phases using the kubeadm init phase
command.
To view the ordered list of phases and sub-phases you can call kubeadm init --help
. The list
will be located at the top of the help screen and each phase will have a description next to it.
Note that by calling kubeadm init
all of the phases and sub-phases will be executed in this exact order.
Some phases have unique flags, so if you want to have a look at the list of available options add
--help
, for example:
sudo kubeadm init phase control-plane controller-manager --help
You can also use --help
to see the list of sub-phases for a certain parent phase:
sudo kubeadm init phase control-plane --help
kubeadm init
also exposes a flag called --skip-phases
that can be used to skip certain phases.
The flag accepts a list of phase names and the names can be taken from the above ordered list.
An example:
sudo kubeadm init phase control-plane all --config=configfile.yaml
sudo kubeadm init phase etcd local --config=configfile.yaml
# you can now modify the control plane and etcd manifest files
sudo kubeadm init --skip-phases=control-plane,etcd --config=configfile.yaml
What this example would do is write the manifest files for the control plane and etcd in
/etc/kubernetes/manifests
based on the configuration in configfile.yaml
. This allows you to
modify the files and then skip these phases using --skip-phases
. By calling the last command you
will create a control plane node with the custom manifest files.
Kubernetes v1.22 [beta]
Alternatively, you can use the skipPhases
field under InitConfiguration
.
Using kubeadm init with a configuration file
Caution:
The config file is still considered beta and may change in future versions.It's possible to configure kubeadm init
with a configuration file instead of command
line flags, and some more advanced features may only be available as
configuration file options. This file is passed using the --config
flag and it must
contain a ClusterConfiguration
structure and optionally more structures separated by ---\n
Mixing --config
with others flags may not be allowed in some cases.
The default configuration can be printed out using the kubeadm config print command.
If your configuration is not using the latest version it is recommended that you migrate using the kubeadm config migrate command.
For more information on the fields and usage of the configuration you can navigate to our API reference page.
Using kubeadm init with feature gates
Kubeadm supports a set of feature gates that are unique to kubeadm and can only be applied
during cluster creation with kubeadm init
. These features can control the behavior
of the cluster. Feature gates are removed after a feature graduates to GA.
To pass a feature gate you can either use the --feature-gates
flag for
kubeadm init
, or you can add items into the featureGates
field when you pass
a configuration file
using --config
.
Passing feature gates for core Kubernetes components directly to kubeadm is not supported. Instead, it is possible to pass them by Customizing components with the kubeadm API.
List of feature gates:
Feature | Default | Alpha | Beta | GA |
---|---|---|---|---|
ControlPlaneKubeletLocalMode |
false |
1.31 | - | - |
EtcdLearnerMode |
true |
1.27 | 1.29 | 1.32 |
PublicKeysECDSA |
false |
1.19 | - | - |
WaitForAllControlPlaneComponents |
false |
1.30 | - | - |
Note:
Once a feature gate goes GA its value becomes locked totrue
by default.Feature gate descriptions:
ControlPlaneKubeletLocalMode
- With this feature gate enabled, when joining a new control plane node, kubeadm will configure the kubelet to connect to the local kube-apiserver. This ensures that there will not be a violation of the version skew policy during rolling upgrades.
EtcdLearnerMode
- With this feature gate enabled, when joining a new control plane node, a new etcd member will be created as a learner and promoted to a voting member only after the etcd data are fully aligned.
PublicKeysECDSA
- Can be used to create a cluster that uses ECDSA certificates instead of the default RSA algorithm.
Renewal of existing ECDSA certificates is also supported using
kubeadm certs renew
, but you cannot switch between the RSA and ECDSA algorithms on the fly or during upgrades. Kubernetes 1.32 has a bug where keys in generated kubeconfig files are set use RSA despite the feature gate being enabled. Kubernetes versions before v1.31 had a bug where keys in generated kubeconfig files were set use RSA, even when you had enabled thePublicKeysECDSA
feature gate. WaitForAllControlPlaneComponents
- With this feature gate enabled kubeadm will wait for all control plane components (kube-apiserver,
kube-controller-manager, kube-scheduler) on a control plane node to report status 200 on their
/healthz
endpoints. These checks are performed onhttps://127.0.0.1:PORT/healthz
, wherePORT
is taken from--secure-port
of a component. If you specify custom--secure-port
values in the kubeadm configuration they will be respected. Without the feature gate enabled, kubeadm will only wait for the kube-apiserver on a control plane node to become ready. The wait process starts right after the kubelet on the host is started by kubeadm. You are advised to enable this feature gate in case you wish to observe a ready state from all control plane components during thekubeadm init
orkubeadm join
command execution.
List of deprecated feature gates:
Feature | Default | Alpha | Beta | GA | Deprecated |
---|---|---|---|---|---|
RootlessControlPlane |
false |
1.22 | - | - | 1.31 |
Feature gate descriptions:
RootlessControlPlane
- Setting this flag configures the kubeadm deployed control plane component static Pod containers
for
kube-apiserver
,kube-controller-manager
,kube-scheduler
andetcd
to run as non-root users. If the flag is not set, those components run as root. You can change the value of this feature gate before you upgrade to a newer version of Kubernetes.
List of removed feature gates:
Feature | Alpha | Beta | GA | Removed |
---|---|---|---|---|
IPv6DualStack |
1.16 | 1.21 | 1.23 | 1.24 |
UnversionedKubeletConfigMap |
1.22 | 1.23 | 1.25 | 1.26 |
UpgradeAddonsBeforeControlPlane |
1.28 | - | - | 1.31 |
Feature gate descriptions:
IPv6DualStack
- This flag helps to configure components dual stack when the feature is in progress. For more details on Kubernetes dual-stack support see Dual-stack support with kubeadm.
UnversionedKubeletConfigMap
- This flag controls the name of the ConfigMap where kubeadm stores
kubelet configuration data. With this flag not specified or set to
true
, the ConfigMap is namedkubelet-config
. If you set this flag tofalse
, the name of the ConfigMap includes the major and minor version for Kubernetes (for example:kubelet-config-1.32
). Kubeadm ensures that RBAC rules for reading and writing that ConfigMap are appropriate for the value you set. When kubeadm writes this ConfigMap (duringkubeadm init
orkubeadm upgrade apply
), kubeadm respects the value ofUnversionedKubeletConfigMap
. When reading that ConfigMap (duringkubeadm join
,kubeadm reset
,kubeadm upgrade ...
), kubeadm attempts to use unversioned ConfigMap name first; if that does not succeed, kubeadm falls back to using the legacy (versioned) name for that ConfigMap. UpgradeAddonsBeforeControlPlane
- This feature gate has been removed. It was introduced in v1.28 as a deprecated feature and then removed in v1.31. For documentation on older versions, please switch to the corresponding website version.
Adding kube-proxy parameters
For information about kube-proxy parameters in the kubeadm configuration see:
For information about enabling IPVS mode with kubeadm see:
Passing custom flags to control plane components
For information about passing flags to control plane components see:
Running kubeadm without an Internet connection
For running kubeadm without an Internet connection you have to pre-pull the required control-plane images.
You can list and pull the images using the kubeadm config images
sub-command:
kubeadm config images list
kubeadm config images pull
You can pass --config
to the above commands with a kubeadm configuration file
to control the kubernetesVersion
and imageRepository
fields.
All default registry.k8s.io
images that kubeadm requires support multiple architectures.
Using custom images
By default, kubeadm pulls images from registry.k8s.io
. If the
requested Kubernetes version is a CI label (such as ci/latest
)
gcr.io/k8s-staging-ci-images
is used.
You can override this behavior by using kubeadm with a configuration file. Allowed customization are:
- To provide
kubernetesVersion
which affects the version of the images. - To provide an alternative
imageRepository
to be used instead ofregistry.k8s.io
. - To provide a specific
imageRepository
andimageTag
for etcd or CoreDNS.
Image paths between the default registry.k8s.io
and a custom repository specified using
imageRepository
may differ for backwards compatibility reasons. For example,
one image might have a subpath at registry.k8s.io/subpath/image
, but be defaulted
to my.customrepository.io/image
when using a custom repository.
To ensure you push the images to your custom repository in paths that kubeadm can consume, you must:
- Pull images from the defaults paths at
registry.k8s.io
usingkubeadm config images {list|pull}
. - Push images to the paths from
kubeadm config images list --config=config.yaml
, whereconfig.yaml
contains the customimageRepository
, and/orimageTag
for etcd and CoreDNS. - Pass the same
config.yaml
tokubeadm init
.
Custom sandbox (pause) images
To set a custom image for these you need to configure this in your container runtime to use the image. Consult the documentation for your container runtime to find out how to change this setting; for selected container runtimes, you can also find advice within the Container Runtimes topic.
Uploading control-plane certificates to the cluster
By adding the flag --upload-certs
to kubeadm init
you can temporary upload
the control-plane certificates to a Secret in the cluster. Please note that this Secret
will expire automatically after 2 hours. The certificates are encrypted using
a 32byte key that can be specified using --certificate-key
. The same key can be used
to download the certificates when additional control-plane nodes are joining, by passing
--control-plane
and --certificate-key
to kubeadm join
.
The following phase command can be used to re-upload the certificates after expiration:
kubeadm init phase upload-certs --upload-certs --config=SOME_YAML_FILE
Note:
A predefinedcertificateKey
can be provided in InitConfiguration
when passing the
configuration file with --config
.If a predefined certificate key is not passed to kubeadm init
and
kubeadm init phase upload-certs
a new key will be generated automatically.
The following command can be used to generate a new key on demand:
kubeadm certs certificate-key
Certificate management with kubeadm
For detailed information on certificate management with kubeadm see Certificate Management with kubeadm. The document includes information about using external CA, custom certificates and certificate renewal.
Managing the kubeadm drop-in file for the kubelet
The kubeadm
package ships with a configuration file for running the kubelet
by systemd
.
Note that the kubeadm CLI never touches this drop-in file. This drop-in file is part of the kubeadm
DEB/RPM package.
For further information, see Managing the kubeadm drop-in file for systemd.
Use kubeadm with CRI runtimes
By default kubeadm attempts to detect your container runtime. For more details on this detection, see the kubeadm CRI installation guide.
Setting the node name
By default, kubeadm
assigns a node name based on a machine's host address.
You can override this setting with the --node-name
flag.
The flag passes the appropriate --hostname-override
value to the kubelet.
Be aware that overriding the hostname can interfere with cloud providers.
Automating kubeadm
Rather than copying the token you obtained from kubeadm init
to each node, as
in the basic kubeadm tutorial,
you can parallelize the token distribution for easier automation. To implement this automation,
you must know the IP address that the control-plane node will have after it is started, or use a
DNS name or an address of a load balancer.
-
Generate a token. This token must have the form
<6 character string>.<16 character string>
. More formally, it must match the regex:[a-z0-9]{6}\.[a-z0-9]{16}
.kubeadm can generate a token for you:
kubeadm token generate
-
Start both the control-plane node and the worker nodes concurrently with this token. As they come up they should find each other and form the cluster. The same
--token
argument can be used on bothkubeadm init
andkubeadm join
. -
Similar can be done for
--certificate-key
when joining additional control-plane nodes. The key can be generated using:kubeadm certs certificate-key
Once the cluster is up, you can use the /etc/kubernetes/admin.conf
file from
a control-plane node to talk to the cluster with administrator credentials or
Generating kubeconfig files for additional users.
Note that this style of bootstrap has some relaxed security guarantees because
it does not allow the root CA hash to be validated with
--discovery-token-ca-cert-hash
(since it's not generated when the nodes are
provisioned). For details, see the kubeadm join.
What's next
- kubeadm init phase to understand more about
kubeadm init
phases - kubeadm join to bootstrap a Kubernetes worker node and join it to the cluster
- kubeadm upgrade to upgrade a Kubernetes cluster to a newer version
- kubeadm reset to revert any changes made
to this host by
kubeadm init
orkubeadm join