Kubernetes v1.11
betaDynamic Kubelet Configuration allows you to change the configuration of each Kubelet in a live Kubernetes cluster by deploying a ConfigMap and configuring each Node to use it.
Warning: All Kubelet configuration parameters can be changed dynamically, but this is unsafe for some parameters. Before deciding to change a parameter dynamically, you need a strong understanding of how that change will affect your cluster’s behavior. Always carefully test configuration changes on a small set of nodes before rolling them out cluster-wide. Advice on configuring specific fields is available in the inlineKubeletConfiguration
type documentation.
--dynamic-config-dir
flag must be set to a writable
directory on the Node.The basic workflow for configuring a Kubelet in a live cluster is as follows:
Each Kubelet watches a configuration reference on its respective Node object. When this reference changes, the Kubelet downloads the new configuration, updates a local reference to refer to the file, and exits. For the feature to work correctly, you must be running an OS-level service manager (such as systemd), which will restart the Kubelet if it exits. When the Kubelet is restarted, it will begin using the new configuration.
The new configuration completely overrides configuration provided by --config
,
and is overridden by command-line flags. Unspecified values in the new configuration
will receive default values appropriate to the configuration version
(e.g. kubelet.config.k8s.io/v1beta1
), unless overridden by flags.
The status of the Node’s Kubelet configuration is reported via
Node.Spec.Status.Config
. Once you have updated a Node to use the new
ConfigMap, you can observe this status to confirm that the Node is using the
intended configuration.
This document describes editing Nodes using kubectl edit
.
There are other ways to modify a Node’s spec, including kubectl patch
, for
example, which facilitate scripted workflows.
This document only describes a single Node consuming each ConfigMap. Keep in mind that it is also valid for multiple Nodes to consume the same ConfigMap.
Warning: While it is possible to change the configuration by updating the ConfigMap in-place, this causes all Kubelets configured with that ConfigMap to update simultaneously. It is much safer to treat ConfigMaps as immutable by convention, aided bykubectl
’s--append-hash
option, and incrementally roll out updates toNode.Spec.ConfigSource
.
Previously, you were required to manually create RBAC rules to allow Nodes to access their assigned ConfigMaps. The Node Authorizer now automatically configures these rules.
The Dynamic Kubelet Configuration feature allows you to provide an override for the entire configuration object, rather than a per-field overlay. This is a simpler model that makes it easier to trace the source of configuration values and debug issues. The compromise, however, is that you must start with knowledge of the existing configuration to ensure that you only change the fields you intend to change.
Ideally, the Kubelet would be bootstrapped from a file on disk
and you could edit this file (which could also be version-controlled),
to create the first Kubelet ConfigMap
(see Set Kubelet parameters via a config file),
Currently, the Kubelet is bootstrapped with a combination of this file and command-line flags
that can override the configuration in the file.
As a workaround, you can generate a config file containing a Node’s current
configuration by accessing the Kubelet server’s configz
endpoint via the
kubectl proxy. This endpoint, in its current implementation, is intended to be
used only as a debugging aid. Do not rely on the behavior of this endpoint for
production scenarios. The examples below use the jq
command to streamline
working with JSON. To follow the tasks as written, you need to have jq
installed, but you can adapt the tasks if you prefer to extract the
kubeletconfig
subobject manually.
NODE_NAME
.Start the kubectl proxy in the background using the following command:
kubectl proxy --port=8001 &
Run the following command to download and unpack the configuration from the
configz
endpoint. The command is long, so be careful when copying and
pasting. If you use zsh, note that common zsh configurations add backslashes
to escape the opening and closing curly braces around the variable name in the URL.
For example: ${NODE_NAME}
will be rewritten as $\{NODE_NAME\}
during the paste.
You must remove the backslashes before running the command, or the command will fail.
NODE_NAME="the-name-of-the-node-you-are-reconfiguring"; curl -sSL "http://localhost:8001/api/v1/nodes/${NODE_NAME}/proxy/configz" | jq '.kubeletconfig|.kind="KubeletConfiguration"|.apiVersion="kubelet.config.k8s.io/v1beta1"' > kubelet_configz_${NODE_NAME}
Note: You need to manually add thekind
andapiVersion
to the downloaded object, because they are not reported by theconfigz
endpoint.
Using a text editor, change one of the parameters in the
file generated by the previous procedure. For example, you
might edit the QPS parameter eventRecordQPS
.
Push the edited configuration file to the control plane with the following command:
kubectl -n kube-system create configmap my-node-config --from-file=kubelet=kubelet_configz_${NODE_NAME} --append-hash -o yaml
This is an example of a valid response:
apiVersion: v1
kind: ConfigMap
metadata:
creationTimestamp: 2017-09-14T20:23:33Z
name: my-node-config-gkt4c2m4b2
namespace: kube-system
resourceVersion: "119980"
uid: 946d785e-998a-11e7-a8dd-42010a800006
data:
kubelet: |
{...}
The ConfigMap is created in the kube-system
namespace because this
ConfigMap configures a Kubelet, which is Kubernetes system component.
The --append-hash
option appends a short checksum of the ConfigMap contents
to the name. This is convenient for an edit-then-push workflow, because it
automatically, yet deterministically, generates new names for new ConfigMaps.
The name that includes this generated hash is referred to as CONFIG_MAP_NAME
in the following examples.
Edit the Node’s reference to point to the new ConfigMap with the following command:
kubectl edit node ${NODE_NAME}
In your text editor, add the following YAML under spec
:
configSource:
configMap:
name: CONFIG_MAP_NAME
namespace: kube-system
kubeletConfigKey: kubelet
You must specify all three of name
, namespace
, and kubeletConfigKey
.
The kubeletConfigKey
parameter shows the Kubelet which key of the ConfigMap
contains its config.
Retrieve the Node using the kubectl get node ${NODE_NAME} -o yaml
command and inspect
Node.Status.Config
. The config sources corresponding to the active
,
assigned
, and lastKnownGood
configurations are reported in the status.
active
configuration is the version the Kubelet is currently running with.assigned
configuration is the latest version the Kubelet has resolved based on
Node.Spec.ConfigSource
.lastKnownGood
configuration is the version the
Kubelet will fall back to if an invalid config is assigned in Node.Spec.ConfigSource
.ThelastKnownGood
configuration might not be present if it is set to its default value,
the local config deployed with the node. The status will update lastKnownGood
to
match a valid assigned
config after the Kubelet becomes comfortable with the config.
The details of how the Kubelet determines a config should become the lastKnownGood
are
not guaranteed by the API, but is currently implemented as a 10-minute grace period.
You can use the following command (using jq
) to filter down
to the config status:
kubectl get no ${NODE_NAME} -o json | jq '.status.config'
The following is an example response:
{
"active": {
"configMap": {
"kubeletConfigKey": "kubelet",
"name": "my-node-config-9mbkccg2cc",
"namespace": "kube-system",
"resourceVersion": "1326",
"uid": "705ab4f5-6393-11e8-b7cc-42010a800002"
}
},
"assigned": {
"configMap": {
"kubeletConfigKey": "kubelet",
"name": "my-node-config-9mbkccg2cc",
"namespace": "kube-system",
"resourceVersion": "1326",
"uid": "705ab4f5-6393-11e8-b7cc-42010a800002"
}
},
"lastKnownGood": {
"configMap": {
"kubeletConfigKey": "kubelet",
"name": "my-node-config-9mbkccg2cc",
"namespace": "kube-system",
"resourceVersion": "1326",
"uid": "705ab4f5-6393-11e8-b7cc-42010a800002"
}
}
}
If an error occurs, the Kubelet reports it in the Node.Status.Config.Error
structure. Possible errors are listed in
Understanding Node.Status.Config.Error messages.
You can search for the identical text in the Kubelet log for additional details
and context about the error.
Follow the workflow above to make more changes and push them again. Each time you push a ConfigMap with new contents, the –append-hash kubectl option creates the ConfigMap with a new name. The safest rollout strategy is to first create a new ConfigMap, and then update the Node to use the new ConfigMap.
To reset the Node to use the configuration it was provisioned with, edit the
Node using kubectl edit node ${NODE_NAME}
and remove the
Node.Spec.ConfigSource
field.
After removing this subfield, Node.Status.Config
eventually becomes
empty, since all config sources have been reset to nil
, which indicates that
the local default config is assigned
, active
, and lastKnownGood
, and no
error is reported.
You can change a Node’s configSource using several different mechanisms.
This example uses kubectl patch
:
kubectl patch node ${NODE_NAME} -p "{\"spec\":{\"configSource\":{\"configMap\":{\"name\":\"${CONFIG_MAP_NAME}\",\"namespace\":\"kube-system\",\"kubeletConfigKey\":\"kubelet\"}}}}"
When a new config is assigned to the Node, the Kubelet downloads and unpacks the
config payload as a set of files on the local disk. The Kubelet also records metadata
that locally tracks the assigned and last-known-good config sources, so that the
Kubelet knows which config to use across restarts, even if the API server becomes
unavailable. After checkpointing a config and the relevant metadata, the Kubelet
exits if it detects that the assigned config has changed. When the Kubelet is
restarted by the OS-level service manager (such as systemd
), it reads the new
metadata and uses the new config.
The recorded metadata is fully resolved, meaning that it contains all necessary
information to choose a specific config version - typically a UID
and ResourceVersion
.
This is in contrast to Node.Spec.ConfigSource
, where the intended config is declared
via the idempotent namespace/name
that identifies the target ConfigMap; the Kubelet
tries to use the latest version of this ConfigMap.
When you are debugging problems on a node, you can inspect the Kubelet’s config metadata and checkpoints. The structure of the Kubelet’s checkpointing directory is:
- --dynamic-config-dir (root for managing dynamic config)
| - meta
| - assigned (encoded kubeletconfig/v1beta1.SerializedNodeConfigSource object, indicating the assigned config)
| - last-known-good (encoded kubeletconfig/v1beta1.SerializedNodeConfigSource object, indicating the last-known-good config)
| - checkpoints
| - uid1 (dir for versions of object identified by uid1)
| - resourceVersion1 (dir for unpacked files from resourceVersion1 of object with uid1)
| - ...
| - ...
The following table describes error messages that can occur when using Dynamic Kubelet Config. You can search for the identical text in the Kubelet log for additional details and context about the error.
Error Message | Possible Causes |
---|---|
failed to load config, see Kubelet log for details | The Kubelet likely could not parse the downloaded config payload, or encountered a filesystem error attempting to load the payload from disk. |
failed to validate config, see Kubelet log for details | The configuration in the payload, combined with any command-line flag overrides, and the sum of feature gates from flags, the config file, and the remote payload, was determined to be invalid by the Kubelet. |
invalid NodeConfigSource, exactly one subfield must be non-nil, but all were nil | Since Node.Spec.ConfigSource is validated by the API server to contain at least one non-nil subfield, this likely means that the Kubelet is older than the API server and does not recognize a newer source type. |
failed to sync: failed to download config, see Kubelet log for details | The Kubelet could not download the config. It is possible that Node.Spec.ConfigSource could not be resolved to a concrete API object, or that network errors disrupted the download attempt. The Kubelet will retry the download when in this error state. |
failed to sync: internal failure, see Kubelet log for details | The Kubelet encountered some internal problem and failed to update its config as a result. Examples include filesystem errors and reading objects from the internal informer cache. |
internal failure, see Kubelet log for details | The Kubelet encountered some internal problem while manipulating config, outside of the configuration sync loop. |
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