28 Jan 2026

feedKubernetes Blog

Experimenting with Gateway API using kind

This document will guide you through setting up a local experimental environment with Gateway API on kind. This setup is designed for learning and testing. It helps you understand Gateway API concepts without production complexity.

Overview

In this guide, you will:

This setup is ideal for learning, development, and experimentation with Gateway API concepts.

Prerequisites

Before you begin, ensure you have the following installed on your local machine:

Create a kind cluster

Create a new kind cluster by running:

kind create cluster

This will create a single-node Kubernetes cluster running in a Docker container.

Install cloud-provider-kind

Next, you need cloud-provider-kind, which provides two key components for this setup:

It also automatically installs the Gateway API Custom Resource Definitions (CRDs) in your cluster.

Run cloud-provider-kind as a Docker container on the same host where you created the kind cluster:

VERSION="$(basename $(curl -s -L -o /dev/null -w '%{url_effective}' https://github.com/kubernetes-sigs/cloud-provider-kind/releases/latest))"
docker run -d --name cloud-provider-kind --rm --network host -v /var/run/docker.sock:/var/run/docker.sock registry.k8s.io/cloud-provider-kind/cloud-controller-manager:${VERSION}

Note: On some systems, you may need elevated privileges to access the Docker socket.

Verify that cloud-provider-kind is running:

docker ps --filter name=cloud-provider-kind

You should see the container listed and in a running state. You can also check the logs:

docker logs cloud-provider-kind

Experimenting with Gateway API

Now that your cluster is set up, you can start experimenting with Gateway API resources.

cloud-provider-kind automatically provisions a GatewayClass called cloud-provider-kind. You'll use this class to create your Gateway.

It is worth noticing that while kind is not a cloud provider, the project is named as cloud-provider-kind as it provides features that simulate a cloud-enabled environment.

Deploy a Gateway

The following manifest will:

Apply the following manifest:

---
apiVersion: v1
kind: Namespace
metadata:
 name: gateway-infra
---
apiVersion: gateway.networking.k8s.io/v1
kind: Gateway
metadata:
 name: gateway
 namespace: gateway-infra
spec:
 gatewayClassName: cloud-provider-kind
 listeners:
 - name: default
 hostname: "*.exampledomain.example"
 port: 80
 protocol: HTTP
 allowedRoutes:
 namespaces:
 from: All

Then verify that your Gateway is properly programmed and has an address assigned:

kubectl get gateway -n gateway-infra gateway

Expected output:

NAME CLASS ADDRESS PROGRAMMED AGE
gateway cloud-provider-kind 172.18.0.3 True 5m6s

The PROGRAMMED column should show True, and the ADDRESS field should contain an IP address.

Deploy a demo application

Next, deploy a simple echo application that will help you test your Gateway configuration. This application:

Apply the following manifest:

apiVersion: v1
kind: Namespace
metadata:
 name: demo
---
apiVersion: v1
kind: Service
metadata:
 labels:
 app.kubernetes.io/name: echo
 name: echo
 namespace: demo
spec:
 ports:
 - name: http
 port: 3000
 protocol: TCP
 targetPort: 3000
 selector:
 app.kubernetes.io/name: echo
 type: ClusterIP
---
apiVersion: apps/v1
kind: Deployment
metadata:
 labels:
 app.kubernetes.io/name: echo
 name: echo
 namespace: demo
spec:
 selector:
 matchLabels:
 app.kubernetes.io/name: echo
 template:
 metadata:
 labels:
 app.kubernetes.io/name: echo
 spec:
 containers:
 - env:
 - name: POD_NAME
 valueFrom:
 fieldRef:
 apiVersion: v1
 fieldPath: metadata.name
 - name: NAMESPACE
 valueFrom:
 fieldRef:
 apiVersion: v1
 fieldPath: metadata.namespace
 image: registry.k8s.io/gateway-api/echo-basic:v20251204-v1.4.1
 name: echo-basic

Create an HTTPRoute

Now create an HTTPRoute to route traffic from your Gateway to the echo application. This HTTPRoute will:

Apply the following manifest:

apiVersion: gateway.networking.k8s.io/v1
kind: HTTPRoute
metadata:
 name: echo
 namespace: demo
spec:
 parentRefs:
 - name: gateway
 namespace: gateway-infra
 hostnames: ["some.exampledomain.example"]
 rules:
 - matches:
 - path:
 type: PathPrefix
 value: /
 backendRefs:
 - name: echo
 port: 3000

Test your route

The final step is to test your route using curl. You'll make a request to the Gateway's IP address with the hostname some.exampledomain.example. The command below is for POSIX shell only, and may need to be adjusted for your environment:

GW_ADDR=$(kubectl get gateway -n gateway-infra gateway -o jsonpath='{.status.addresses[0].value}')
curl --resolve some.exampledomain.example:80:${GW_ADDR} http://some.exampledomain.example

You should receive a JSON response similar to this:

{
 "path": "/",
 "host": "some.exampledomain.example",
 "method": "GET",
 "proto": "HTTP/1.1",
 "headers": {
 "Accept": [
 "*/*"
 ],
 "User-Agent": [
 "curl/8.15.0"
 ]
 },
 "namespace": "demo",
 "ingress": "",
 "service": "",
 "pod": "echo-dc48d7cf8-vs2df"
}

If you see this response, congratulations! Your Gateway API setup is working correctly.

Troubleshooting

If something isn't working as expected, you can troubleshoot by checking the status of your resources.

Check the Gateway status

First, inspect your Gateway resource:

kubectl get gateway -n gateway-infra gateway -o yaml

Look at the status section for conditions. Your Gateway should have:

Check the HTTPRoute status

Next, inspect your HTTPRoute:

kubectl get httproute -n demo echo -o yaml

Check the status.parents section for conditions. Common issues include:

Example error when a backend is not found:

status:
 parents:
 - conditions:
 - lastTransitionTime: "2026-01-19T17:13:35Z"
 message: backend not found
 observedGeneration: 2
 reason: BackendNotFound
 status: "False"
 type: ResolvedRefs
 controllerName: kind.sigs.k8s.io/gateway-controller

Check controller logs

If the resource statuses don't reveal the issue, check the cloud-provider-kind logs:

docker logs -f cloud-provider-kind

This will show detailed logs from both the LoadBalancer and Gateway API controllers.

Cleanup

When you're finished with your experiments, you can clean up the resources:

Remove Kubernetes resources

Delete the namespaces (this will remove all resources within them):

kubectl delete namespace gateway-infra
kubectl delete namespace demo

Stop cloud-provider-kind

Stop and remove the cloud-provider-kind container:

docker stop cloud-provider-kind

Because the container was started with the --rm flag, it will be automatically removed when stopped.

Delete the kind cluster

Finally, delete the kind cluster:

kind delete cluster

Next steps

Now that you've experimented with Gateway API locally, you're ready to explore production-ready implementations:

A final word of caution

This kind setup is for development and learning only. Always use a production-grade Gateway API implementation for real workloads.

28 Jan 2026 12:00am GMT

27 Jan 2026

feedKubernetes Blog

Cluster API v1.12: Introducing In-place Updates and Chained Upgrades

Cluster API brings declarative management to Kubernetes cluster lifecycle, allowing users and platform teams to define the desired state of clusters and rely on controllers to continuously reconcile toward it.

Similar to how you can use StatefulSets or Deployments in Kubernetes to manage a group of Pods, in Cluster API you can use KubeadmControlPlane to manage a set of control plane Machines, or you can use MachineDeployments to manage a group of worker Nodes.

The Cluster API v1.12.0 release expands what is possible in Cluster API, reducing friction in common lifecycle operations by introducing in-place updates and chained upgrades.

Emphasis on simplicity and usability

With v1.12.0, the Cluster API project demonstrates once again that this community is capable of delivering a great amount of innovation, while at the same time minimizing impact for Cluster API users.

What does this mean in practice?

Users simply have to change the Cluster or the Machine spec (just as with previous Cluster API releases), and Cluster API will automatically trigger in-place updates or chained upgrades when possible and advisable.

In-place Updates

Like Kubernetes does for Pods in Deployments, when the Machine spec changes also Cluster API performs rollouts by creating a new Machine and deleting the old one.

This approach, inspired by the principle of immutable infrastructure, has a set of considerable advantages:

As a result, Machine rollouts drastically reduce the number of variables to be considered when managing the lifecycle of a host server that is hosting Nodes.

However, while advantages of immutability are not under discussion, both Kubernetes and Cluster API are undergoing a similar journey, introducing changes that allow users to minimize workload disruption whenever possible.

Over time, also Cluster API has introduced several improvements to immutable rollouts, including:

The new in-place update feature in Cluster API is the next step in this journey.

With the v1.12.0 release, Cluster API introduces support for update extensions allowing users to make changes on existing machines in-place, without deleting and re-creating the Machines.

Both KubeadmControlPlane and MachineDeployments support in-place updates based on the new update extension, and this means that the boundary of what is possible in Cluster API is now changed in a significant way.

How do in-place updates work?

The simplest way to explain it is that once the user triggers an update by changing the desired state of Machines, then Cluster API chooses the best tool to achieve the desired state.

The news is that now Cluster API can choose between immutable rollouts and in-place update extensions to perform required changes.

In-place updates in Cluster API

Importantly, this is not immutable rollouts vs in-place updates; Cluster API considers both valid options and selects the most appropriate mechanism for a given change.

From the perspective of the Cluster API maintainers, in-place updates are most useful for making changes that don't otherwise require a node drain or pod restart; for example: changing user credentials for the Machine. On the other hand, when the workload will be disrupted anyway, just do a rollout.

Nevertheless, Cluster API remains true to its extensible nature, and everyone can create their own update extension and decide when and how to use in-place updates by trading in some of the benefits of immutable rollouts.

For a deep dive into this feature, make sure to attend the session In-place Updates with Cluster API: The Sweet Spot Between Immutable and Mutable Infrastructure at KubeCon EU in Amsterdam!

Chained Upgrades

ClusterClass and managed topologies in Cluster API jointly provided a powerful and effective framework that acts as a building block for many platforms offering Kubernetes-as-a-Service.

Now with v1.12.0 this feature is making another important step forward, by allowing users to upgrade by more than one Kubernetes minor version in a single operation, commonly referred to as a chained upgrade.

This allows users to declare a target Kubernetes version and let Cluster API safely orchestrate the required intermediate steps, rather than manually managing each minor upgrade.

The simplest way to explain how chained upgrades work, is that once the user triggers an update by changing the desired version for a Cluster, Cluster API computes an upgrade plan, and then starts executing it. Rather than (for example) update the Cluster to v1.33.0 and then v1.34.0 and then v1.35.0, checking on progress at each step, a chained upgrade lets you go directly to v1.35.0.

Executing an upgrade plan means upgrading control plane and worker machines in a strictly controlled order, repeating this process as many times as needed to reach the desired state. The Cluster API is now capable of managing this for you.

Cluster API takes care of optimizing and minimizing the upgrade steps for worker machines, and in fact worker machines will skip upgrades to intermediate Kubernetes minor releases whenever allowed by the Kubernetes version skew policies.

Chained upgrades in Cluster API

Also in this case extensibility is at the core of this feature, and upgrade plan runtime extensions can be used to influence how the upgrade plan is computed; similarly, lifecycle hooks can be used to automate other tasks that must be performed during an upgrade, e.g. upgrading an addon after the control plane update completed.

From our perspective, chained upgrades are most useful for users that struggle to keep up with Kubernetes minor releases, and e.g. they want to upgrade only once per year and then upgrade by three versions (n-3 → n). But be warned: the fact that you can now easily upgrade by more than one minor version is not an excuse to not patch your cluster frequently!

Release team

I would like to thank all the contributors, the maintainers, and all the engineers that volunteered for the release team.

The reliability and predictability of Cluster API releases, which is one of the most appreciated features from our users, is only possible with the support, commitment, and hard work of its community.

Kudos to the entire Cluster API community for the v1.12.0 release and all the great releases delivered in 2025! ​​ If you are interested in getting involved, learn about Cluster API contributing guidelines.

What's next?

If you read the Cluster API manifesto, you can see how the Cluster API subproject claims the right to remain unfinished, recognizing the need to continuously evolve, improve, and adapt to the changing needs of Cluster API's users and the broader Cloud Native ecosystem.

As Kubernetes itself continues to evolve, the Cluster API subproject will keep advancing alongside it, focusing on safer upgrades, reduced disruption, and stronger building blocks for platforms managing Kubernetes at scale.

Innovation remains at the heart of Cluster API, stay tuned for an exciting 2026!

Useful links:

27 Jan 2026 4:00pm GMT

22 Jan 2026

feedKubernetes Blog

Headlamp in 2025: Project Highlights

This announcement is a recap from a post originally published on the Headlamp blog.

Headlamp has come a long way in 2025. The project has continued to grow - reaching more teams across platforms, powering new workflows and integrations through plugins, and seeing increased collaboration from the broader community.

We wanted to take a moment to share a few updates and highlight how Headlamp has evolved over the past year.

Updates

Joining Kubernetes SIG UI

This year marked a big milestone for the project: Headlamp is now officially part of Kubernetes SIG UI. This move brings roadmap and design discussions even closer to the core Kubernetes community and reinforces Headlamp's role as a modern, extensible UI for the project.

As part of that, we've also been sharing more about making Kubernetes approachable for a wider audience, including an appearance on Enlightening with Whitney Lee and a talk at KCD New York 2025.

Linux Foundation mentorship

This year, we were excited to work with several students through the Linux Foundation's Mentorship program, and our mentees have already left a visible mark on Headlamp:

New changes

Multi-cluster view

Managing multiple clusters is challenging: teams often switch between tools and lose context when trying to see what runs where. Headlamp solves this by giving you a single view to compare clusters side-by-side. This makes it easier to understand workloads across environments and reduces the time spent hunting for resources.

Multi-cluster view View of multi-cluster workloads

Projects

Kubernetes apps often span multiple namespaces and resource types, which makes troubleshooting feel like piecing together a puzzle. We've added Projects to give you an application-centric view that groups related resources across multiple namespaces - and even clusters. This allows you to reduce sprawl, troubleshoot faster, and collaborate without digging through YAML or cluster-wide lists.

Projects feature View of the new Projects feature

Changes:

Navigation and Activities

Day-to-day ops in Kubernetes often means juggling logs, terminals, YAML, and dashboards across clusters. We redesigned Headlamp's navigation to treat these as first-class "activities" you can keep open and come back to, instead of one-off views you lose as soon as you click away.

New task bar View of the new task bar

Changes:

Thanks to Jan Jansen and Aditya Chaudhary.

Search and map

When something breaks in production, the first two questions are usually "where is it?" and "what is it connected to?" We've upgraded both search and the map view so you can get from a high-level symptom to the right set of objects much faster.

Advanced search View of the new Advanced Search feature

Changes:

Thanks to Fabian, Alexander North, and Victor Marcolino from Swisscom, and also to Aditya Chaudhary.

OIDC and authentication

We've put real work into making OIDC setup clearer and more resilient, especially for in-cluster deployments.

User info View of user information for OIDC clusters

Changes:

Thanks to David Dobmeier and Harsh Srivastava.

App Catalog and Helm

We've broadened how you deploy and source apps via Headlamp, specifically supporting vanilla Helm repos.

Changes:

Thanks to Vrushali Shah and Murali Annamneni from Oracle, and also to Pat Riehecky, Joshua Akers, Rostislav Stříbrný, Rick L,and Victor.

Performance, accessibility, and UX

Finally, we've spent a lot of time on the things you notice every day but don't always make headlines: startup time, list views, log viewers, accessibility, and small network UX details. A continuous accessibility self-audit has also helped us identify key issues and make Headlamp easier for everyone to use.

Learn section View of the Learn section in docs

Changes:

Thanks to Jaehan Byun and Jan Jansen.

Plugins and extensibility

Discovering plugins is simpler now - no more hopping between Artifact Hub and assorted GitHub repos. Browse our dedicated Plugins page for a curated catalog of Headlamp-endorsed plugins, along with a showcase of featured plugins.

Plugins page View of the Plugins showcase

Headlamp AI Assistant

Managing Kubernetes often means memorizing commands and juggling tools. Headlamp's new AI Assistant changes this by adding a natural-language interface built into the UI. Now, instead of typing kubectl or digging through YAML you can ask, "Is my app healthy?" or "Show logs for this deployment," and get answers in context, speeding up troubleshooting and smoothing onboarding for new users. Learn more about it here.

New plugins additions

Alongside the new AI Assistant, we've been growing Headlamp's plugin ecosystem so you can bring more of your workflows into a single UI, with integrations like Minikube, Karpenter, and more.

Highlights from the latest plugin releases:

Thanks to Vrushali Shah and Murali Annamneni from Oracle, and also to Anirban Singha, Adwait Godbole, Sertaç Özercan, Ernest Wong, and Chloe Lim.

Other plugins updates

Alongside new additions, we've also spent time refining plugins that many of you already use, focusing on smoother workflows and better integration with the core UI.

Backstage plugin View of the Backstage plugin

Changes:

Plugin development

We've focused on making it faster and clearer to build, test, and ship Headlamp plugins, backed by improved documentation and lighter tooling.

Plugin development View of the Plugin Development guide

Changes:

Security upgrades

We've also been investing in keeping Headlamp secure - both by tightening how authentication works and by staying on top of upstream vulnerabilities and tooling.

Updates:

Conclusion

Thank you to everyone who has contributed to Headlamp this year - whether through pull requests, plugins, or simply sharing how you're using the project. Seeing the different ways teams are adopting and extending the project is a big part of what keeps us moving forward. If your organization uses Headlamp, consider adding it to our adopters list.

If you haven't tried Headlamp recently, all these updates are available today. Check out the latest Headlamp release, explore the new views, plugins, and docs, and share your feedback with us on Slack or GitHub - your feedback helps shape where Headlamp goes next.

22 Jan 2026 2:00am GMT

21 Jan 2026

feedKubernetes Blog

Announcing the Checkpoint/Restore Working Group

The community around Kubernetes includes a number of Special Interest Groups (SIGs) and Working Groups (WGs) facilitating discussions on important topics between interested contributors. Today we would like to announce the new Kubernetes Checkpoint Restore WG focusing on the integration of Checkpoint/Restore functionality into Kubernetes.

Motivation and use cases

There are several high-level scenarios discussed in the working group:

Across these scenarios, the goal is to help facilitate discussions of ideas between the Kubernetes community and the growing Checkpoint/Restore in Userspace (CRIU) ecosystem. The CRIU community includes several projects that support these use cases, including:

More information about the checkpoint/restore integration with Kubernetes is also available here.

Related events

Following our presentation about transparent checkpointing at KubeCon EU 2025, we are excited to welcome you to our panel discussion and AI + ML session at KubeCon + CloudNativeCon Europe 2026.

Connect with us

If you are interested in contributing to Kubernetes or CRIU, there are several ways to participate:

21 Jan 2026 6:00pm GMT

19 Jan 2026

feedKubernetes Blog

Uniform API server access using clientcmd

If you've ever wanted to develop a command line client for a Kubernetes API, especially if you've considered making your client usable as a kubectl plugin, you might have wondered how to make your client feel familiar to users of kubectl. A quick glance at the output of kubectl options might put a damper on that: "Am I really supposed to implement all those options?"

Fear not, others have done a lot of the work involved for you. In fact, the Kubernetes project provides two libraries to help you handle kubectl-style command line arguments in Go programs: clientcmd and cli-runtime (which uses clientcmd). This article will show how to use the former.

General philosophy

As might be expected since it's part of client-go, clientcmd's ultimate purpose is to provide an instance of restclient.Config that can issue requests to an API server.

It follows kubectl semantics:

It doesn't set up a --kubeconfig command line argument, which you might want to do to align with kubectl; you'll see how to do this in the "Bind the flags" section.

Available features

clientcmd allows programs to handle

Configuration merging

In various scenarios, clientcmd supports merging configuration settings: KUBECONFIG can specify multiple files whose contents are combined. This can be confusing, because settings are merged in different directions depending on how they are implemented. If a setting is defined in a map, the first definition wins, subsequent definitions are ignored. If a setting is not defined in a map, the last definition wins.

When settings are retrieved using KUBECONFIG, missing files result in warnings only. If the user explicitly specifies a path (in --kubeconfig style), there must be a corresponding file.

If KUBECONFIG isn't defined, the default configuration file, ~/.kube/config, is used instead, if present.

Overall process

The general usage pattern is succinctly expressed in the clientcmd package documentation:

loadingRules := clientcmd.NewDefaultClientConfigLoadingRules()
// if you want to change the loading rules (which files in which order), you can do so here

configOverrides := &clientcmd.ConfigOverrides{}
// if you want to change override values or bind them to flags, there are methods to help you

kubeConfig := clientcmd.NewNonInteractiveDeferredLoadingClientConfig(loadingRules, configOverrides)
config, err := kubeConfig.ClientConfig()
if err != nil {
 // Do something
}
client, err := metav1.New(config)
// ...

In the context of this article, there are six steps:

  1. Configure the loading rules.
  2. Configure the overrides.
  3. Build a set of flags.
  4. Bind the flags.
  5. Build the merged configuration.
  6. Obtain an API client.

Configure the loading rules

clientcmd.NewDefaultClientConfigLoadingRules() builds loading rules which will use either the contents of the KUBECONFIG environment variable, or the default configuration file name (~/.kube/config). In addition, if the default configuration file is used, it is able to migrate settings from the (very) old default configuration file (~/.kube/.kubeconfig).

You can build your own ClientConfigLoadingRules, but in most cases the defaults are fine.

Configure the overrides

clientcmd.ConfigOverrides is a struct storing overrides which will be applied over the settings loaded from the configuration derived using the loading rules. In the context of this article, its primary purpose is to store values obtained from command line arguments. These are handled using the pflag library, which is a drop-in replacement for Go's flag package, adding support for double-hyphen arguments with long names.

In most cases there's nothing to set in the overrides; I will only bind them to flags.

Build a set of flags

In this context, a flag is a representation of a command line argument, specifying its long name (such as --namespace), its short name if any (such as -n), its default value, and a description shown in the usage information. Flags are stored in instances of the FlagInfo struct.

Three sets of flags are available, representing the following command line arguments:

The recommended selection includes all three with a named context selection argument and a timeout argument.

These are all available using the Recommended…Flags functions. The functions take a prefix, which is prepended to all the argument long names.

So calling clientcmd.RecommendedConfigOverrideFlags("") results in command line arguments such as --context, --namespace, and so on. The --timeout argument is given a default value of 0, and the --namespace argument has a corresponding short variant, -n. Adding a prefix, such as "from-", results in command line arguments such as --from-context, --from-namespace, etc. This might not seem particularly useful on commands involving a single API server, but they come in handy when multiple API servers are involved, such as in multi-cluster scenarios.

There's a potential gotcha here: prefixes don't modify the short name, so --namespace needs some care if multiple prefixes are used: only one of the prefixes can be associated with the -n short name. You'll have to clear the short names associated with the other prefixes' --namespace , or perhaps all prefixes if there's no sensible -n association. Short names can be cleared as follows:

kflags := clientcmd.RecommendedConfigOverrideFlags(prefix)
kflags.ContextOverrideFlags.Namespace.ShortName = ""

In a similar fashion, flags can be disabled entirely by clearing their long name:

kflags.ContextOverrideFlags.Namespace.LongName = ""

Bind the flags

Once a set of flags has been defined, it can be used to bind command line arguments to overrides using clientcmd.BindOverrideFlags. This requires a pflag FlagSet rather than one from Go's flag package.

If you also want to bind --kubeconfig, you should do so now, by binding ExplicitPath in the loading rules:

flags.StringVarP(&loadingRules.ExplicitPath, "kubeconfig", "", "", "absolute path(s) to the kubeconfig file(s)")

Build the merged configuration

Two functions are available to build a merged configuration:

As the names suggest, the difference between the two is that the first can ask for authentication information interactively, using a provided reader, whereas the second only operates on the information given to it by the caller.

The "deferred" mention in these function names refers to the fact that the final configuration will be determined as late as possible. This means that these functions can be called before the command line arguments are parsed, and the resulting configuration will use whatever values have been parsed by the time it's actually constructed.

Obtain an API client

The merged configuration is returned as a ClientConfig instance. An API client can be obtained from that by calling the ClientConfig() method.

If no configuration is given (KUBECONFIG is empty or points to non-existent files, ~/.kube/config doesn't exist, and no configuration is given using command line arguments), the default setup will return an obscure error referring to KUBERNETES_MASTER. This is legacy behaviour; several attempts have been made to get rid of it, but it is preserved for the --local and --dry-run command line arguments in --kubectl. You should check for "empty configuration" errors by calling clientcmd.IsEmptyConfig() and provide a more explicit error message.

The Namespace() method is also useful: it returns the namespace that should be used. It also indicates whether the namespace was overridden by the user (using --namespace).

Full example

Here's a complete example.

package main

import (
 "context"
 "fmt"
 "os"

 "github.com/spf13/pflag"
 v1 "k8s.io/apimachinery/pkg/apis/meta/v1"
 "k8s.io/client-go/kubernetes"
 "k8s.io/client-go/tools/clientcmd"
)

func main() {
 // Loading rules, no configuration
 loadingRules := clientcmd.NewDefaultClientConfigLoadingRules()

 // Overrides and flag (command line argument) setup
 configOverrides := &clientcmd.ConfigOverrides{}
 flags := pflag.NewFlagSet("clientcmddemo", pflag.ExitOnError)
 clientcmd.BindOverrideFlags(configOverrides, flags,
 clientcmd.RecommendedConfigOverrideFlags(""))
 flags.StringVarP(&loadingRules.ExplicitPath, "kubeconfig", "", "", "absolute path(s) to the kubeconfig file(s)")
 flags.Parse(os.Args)

 // Client construction
 kubeConfig := clientcmd.NewNonInteractiveDeferredLoadingClientConfig(loadingRules, configOverrides)
 config, err := kubeConfig.ClientConfig()
 if err != nil {
 if clientcmd.IsEmptyConfig(err) {
 panic("Please provide a configuration pointing to the Kubernetes API server")
 }
 panic(err)
 }
 client, err := kubernetes.NewForConfig(config)
 if err != nil {
 panic(err)
 }

 // How to find out what namespace to use
 namespace, overridden, err := kubeConfig.Namespace()
 if err != nil {
 panic(err)
 }
 fmt.Printf("Chosen namespace: %s; overridden: %t\n", namespace, overridden)

 // Let's use the client
 nodeList, err := client.CoreV1().Nodes().List(context.TODO(), v1.ListOptions{})
 if err != nil {
 panic(err)
 }
 for _, node := range nodeList.Items {
 fmt.Println(node.Name)
 }
}

Happy coding, and thank you for your interest in implementing tools with familiar usage patterns!

19 Jan 2026 6:00pm GMT

09 Jan 2026

feedKubernetes Blog

Kubernetes v1.35: Restricting executables invoked by kubeconfigs via exec plugin allowList added to kuberc

Did you know that kubectl can run arbitrary executables, including shell scripts, with the full privileges of the invoking user, and without your knowledge? Whenever you download or auto-generate a kubeconfig, the users[n].exec.command field can specify an executable to fetch credentials on your behalf. Don't get me wrong, this is an incredible feature that allows you to authenticate to the cluster with external identity providers. Nevertheless, you probably see the problem: Do you know exactly what executables your kubeconfig is running on your system? Do you trust the pipeline that generated your kubeconfig? If there has been a supply-chain attack on the code that generates the kubeconfig, or if the generating pipeline has been compromised, an attacker might well be doing unsavory things to your machine by tricking your kubeconfig into running arbitrary code.

To give the user more control over what gets run on their system, SIG-Auth and SIG-CLI added the credential plugin policy and allowlist as a beta feature to Kubernetes 1.35. This is available to all clients using the client-go library, by filling out the ExecProvider.PluginPolicy struct on a REST config. To broaden the impact of this change, Kubernetes v1.35 also lets you manage this without writing a line of application code. You can configure kubectl to enforce the policy and allowlist by adding two fields to the kuberc configuration file: credentialPluginPolicy and credentialPluginAllowlist. Adding one or both of these fields restricts which credential plugins kubectl is allowed to execute.

How it works

A full description of this functionality is available in our official documentation for kuberc, but this blog post will give a brief overview of the new security knobs. The new features are in beta and available without using any feature gates.

The following example is the simplest one: simply don't specify the new fields.

apiVersion: kubectl.config.k8s.io/v1beta1
kind: Preference

This will keep kubectl acting as it always has, and all plugins will be allowed.

The next example is functionally identical, but it is more explicit and therefore preferred if it's actually what you want:

apiVersion: kubectl.config.k8s.io/v1beta1
kind: Preference
credentialPluginPolicy: AllowAll

If you don't know whether or not you're using exec credential plugins, try setting your policy to DenyAll:

apiVersion: kubectl.config.k8s.io/v1beta1
kind: Preference
credentialPluginPolicy: DenyAll

If you are using credential plugins, you'll quickly find out what kubectl is trying to execute. You'll get an error like the following.

Unable to connect to the server: getting credentials: plugin "cloudco-login" not allowed: policy set to "DenyAll"

If there is insufficient information for you to debug the issue, increase the logging verbosity when you run your next command. For example:

# increase or decrease verbosity if the issue is still unclear
kubectl get pods --verbosity 5

Selectively allowing plugins

What if you need the cloudco-login plugin to do your daily work? That is why there's a third option for your policy, Allowlist. To allow a specific plugin, set the policy and add the credentialPluginAllowlist:

apiVersion: kubectl.config.k8s.io/v1beta1
kind: Preference
credentialPluginPolicy: Allowlist
credentialPluginAllowlist:
 - name: /usr/local/bin/cloudco-login
 - name: get-identity

You'll notice that there are two entries in the allowlist. One of them is specified by full path, and the other, get-identity is just a basename. When you specify just the basename, the full path will be looked up using exec.LookPath, which does not expand globbing or handle wildcards. Globbing is not supported at this time. Both forms (basename and full path) are acceptable, but the full path is preferable because it narrows the scope of allowed binaries even further.

Future enhancements

Currently, an allowlist entry has only one field, name. In the future, we (Kubernetes SIG CLI) want to see other requirements added. One idea that seems useful is checksum verification whereby, for example, a binary would only be allowed to run if it has the sha256 sum b9a3fad00d848ff31960c44ebb5f8b92032dc085020f857c98e32a5d5900ff9c and exists at the path /usr/bin/cloudco-login.

Another possibility is only allowing binaries that have been signed by one of a set of a trusted signing keys.

Get involved

The credential plugin policy is still under development and we are very interested in your feedback. We'd love to hear what you like about it and what problems you'd like to see it solve. Or, if you have the cycles to contribute one of the above enhancements, they'd be a great way to get started contributing to Kubernetes. Feel free to join in the discussion on slack:

09 Jan 2026 6:30pm GMT

08 Jan 2026

feedKubernetes Blog

Kubernetes v1.35: Mutable PersistentVolume Node Affinity (alpha)

The PersistentVolume node affinity API dates back to Kubernetes v1.10. It is widely used to express that volumes may not be equally accessible by all nodes in the cluster. This field was previously immutable, and it is now mutable in Kubernetes v1.35 (alpha). This change opens a door to more flexible online volume management.

Why make node affinity mutable?

This raises an obvious question: why make node affinity mutable now? While stateless workloads like Deployments can be changed freely and the changes will be rolled out automatically by re-creating every Pod, PersistentVolumes (PVs) are stateful and cannot be re-created easily without losing data.

However, Storage providers evolve and storage requirements change. Most notably, multiple providers are offering regional disks now. Some of them even support live migration from zonal to regional disks, without disrupting the workloads. This change can be expressed through the VolumeAttributesClass API, which recently graduated to GA in 1.34. However, even if the volume is migrated to regional storage, Kubernetes still prevents scheduling Pods to other zones because of the node affinity recorded in the PV object. In this case, you may want to change the PV node affinity from:

spec:
 nodeAffinity:
 required:
 nodeSelectorTerms:
 - matchExpressions:
 - key: topology.kubernetes.io/zone
 operator: In
 values:
 - us-east1-b

to:

spec:
 nodeAffinity:
 required:
 nodeSelectorTerms:
 - matchExpressions:
 - key: topology.kubernetes.io/region
 operator: In
 values:
 - us-east1

As another example, providers sometimes offer new generations of disks. New disks cannot always be attached to older nodes in the cluster. This accessibility can also be expressed through PV node affinity and ensures the Pods can be scheduled to the right nodes. But when the disk is upgraded, new Pods using this disk can still be scheduled to older nodes. To prevent this, you may want to change the PV node affinity from:

spec:
 nodeAffinity:
 required:
 nodeSelectorTerms:
 - matchExpressions:
 - key: provider.com/disktype.gen1
 operator: In
 values:
 - available

to:

spec:
 nodeAffinity:
 required:
 nodeSelectorTerms:
 - matchExpressions:
 - key: provider.com/disktype.gen2
 operator: In
 values:
 - available

So, it is mutable now, a first step towards a more flexible online volume management. While it is a simple change that removes one validation from the API server, we still have a long way to go to integrate well with the Kubernetes ecosystem.

Try it out

This feature is for you if you are a Kubernetes cluster administrator, and your storage provider allows online update that you want to utilize, but those updates can affect the accessibility of the volume.

Note that changing PV node affinity alone will not actually change the accessibility of the underlying volume. Before using this feature, you must first update the underlying volume in the storage provider, and understand which nodes can access the volume after the update. You can then enable this feature and keep the PV node affinity in sync.

Currently, this feature is in alpha state. It is disabled by default, and may subject to change. To try it out, enable the MutablePVNodeAffinity feature gate on APIServer, then you can edit the PV spec.nodeAffinity field. Typically only administrators can edit PVs, please make sure you have the right RBAC permissions.

Race condition between updating and scheduling

There are only a few factors outside of a Pod that can affect the scheduling decision, and PV node affinity is one of them. It is fine to allow more nodes to access the volume by relaxing node affinity, but there is a race condition when you try to tighten node affinity: it is unclear how the Scheduler will see the modified PV in its cache, so there is a small window where the scheduler may place a Pod on an old node that can no longer access the volume. In this case, the Pod will stuck at ContainerCreating state.

One mitigation currently under discussion is for the kubelet to fail Pod startup if the PersistentVolume's node affinity is violated. This has not landed yet. So if you are trying this out now, please watch subsequent Pods that use the updated PV, and make sure they are scheduled onto nodes that can access the volume. If you update PV and immediately start new Pods in a script, it may not work as intended.

Future integration with CSI (Container Storage Interface)

Currently, it is up to the cluster administrator to modify both PV's node affinity and the underlying volume in the storage provider. But manual operations are error-prone and time-consuming. It is preferred to eventually integrate this with VolumeAttributesClass, so that an unprivileged user can modify their PersistentVolumeClaim (PVC) to trigger storage-side updates, and PV node affinity is updated automatically when appropriate, without the need for cluster admin's intervention.

We welcome your feedback from users and storage driver developers

As noted earlier, this is only a first step.

If you are a Kubernetes user, we would like to learn how you use (or will use) PV node affinity. Is it beneficial to update it online in your case?

If you are a CSI driver developer, would you be willing to implement this feature? How would you like the API to look?

Please provide your feedback via:

For any inquiries or specific questions related to this feature, please reach out to the SIG Storage community.

08 Jan 2026 6:30pm GMT

07 Jan 2026

feedKubernetes Blog

Kubernetes v1.35: A Better Way to Pass Service Account Tokens to CSI Drivers

If you maintain a CSI driver that uses service account tokens, Kubernetes v1.35 brings a refinement you'll want to know about. Since the introduction of the TokenRequests feature, service account tokens requested by CSI drivers have been passed to them through the volume_context field. While this has worked, it's not the ideal place for sensitive information, and we've seen instances where tokens were accidentally logged in CSI drivers.

Kubernetes v1.35 introduces a beta solution to address this: CSI Driver Opt-in for Service Account Tokens via Secrets Field. This allows CSI drivers to receive service account tokens through the secrets field in NodePublishVolumeRequest, which is the appropriate place for sensitive data in the CSI specification.

Understanding the existing approach

When CSI drivers use the TokenRequests feature, they can request service account tokens for workload identity by configuring the TokenRequests field in the CSIDriver spec. These tokens are passed to drivers as part of the volume attributes map, using the key csi.storage.k8s.io/serviceAccount.tokens.

The volume_context field works, but it's not designed for sensitive data. Because of this, there are a few challenges:

First, the protosanitizer tool that CSI drivers use doesn't treat volume context as sensitive, so service account tokens can end up in logs when gRPC requests are logged. This happened with CVE-2023-2878 in the Secrets Store CSI Driver and CVE-2024-3744 in the Azure File CSI Driver.

Second, each CSI driver that wants to avoid this issue needs to implement its own sanitization logic, which leads to inconsistency across drivers.

The CSI specification already has a secrets field in NodePublishVolumeRequest that's designed exactly for this kind of sensitive information. The challenge is that we can't just change where we put the tokens without breaking existing CSI drivers that expect them in volume context.

How the opt-in mechanism works

Kubernetes v1.35 introduces an opt-in mechanism that lets CSI drivers choose how they receive service account tokens. This way, existing drivers continue working as they do today, and drivers can move to the more appropriate secrets field when they're ready.

CSI drivers can set a new field in their CSIDriver spec:

#
# CAUTION: this is an example configuration.
# Do not use this for your own cluster!
#
apiVersion: storage.k8s.io/v1
kind: CSIDriver
metadata:
 name: example-csi-driver
spec:
 # ... existing fields ...
 tokenRequests:
 - audience: "example.com"
 expirationSeconds: 3600
 # New field for opting into secrets delivery
 serviceAccountTokenInSecrets: true # defaults to false

The behavior depends on the serviceAccountTokenInSecrets field:

When set to false (the default), tokens are placed in VolumeContext with the key csi.storage.k8s.io/serviceAccount.tokens, just like today. When set to true, tokens are placed only in the Secrets field with the same key.

About the beta release

The CSIServiceAccountTokenSecrets feature gate is enabled by default on both kubelet and kube-apiserver. Since the serviceAccountTokenInSecrets field defaults to false, enabling the feature gate doesn't change any existing behavior. All drivers continue receiving tokens via volume context unless they explicitly opt in. This is why we felt comfortable starting at beta rather than alpha.

Guide for CSI driver authors

If you maintain a CSI driver that uses service account tokens, here's how to adopt this feature.

Adding fallback logic

First, update your driver code to check both locations for tokens. This makes your driver compatible with both the old and new approaches:

const serviceAccountTokenKey = "csi.storage.k8s.io/serviceAccount.tokens"

func getServiceAccountTokens(req *csi.NodePublishVolumeRequest) (string, error) {
 // Check secrets field first (new behavior when driver opts in)
 if tokens, ok := req.Secrets[serviceAccountTokenKey]; ok {
 return tokens, nil
 }

 // Fall back to volume context (existing behavior)
 if tokens, ok := req.VolumeContext[serviceAccountTokenKey]; ok {
 return tokens, nil
 }

 return "", fmt.Errorf("service account tokens not found")
}

This fallback logic is backward compatible and safe to ship in any driver version, even before clusters upgrade to v1.35.

Rollout sequence

CSI driver authors need to follow a specific sequence when adopting this feature to avoid breaking existing volumes.

Driver preparation (can happen anytime)

You can start preparing your driver right away by adding fallback logic that checks both the secrets field and volume context for tokens. This code change is backward compatible and safe to ship in any driver version, even before clusters upgrade to v1.35. We encourage you to add this fallback logic early, cut releases, and even backport to maintenance branches where feasible.

Cluster upgrade and feature enablement

Once your driver has the fallback logic deployed, here's the safe rollout order for enabling the feature in a cluster:

  1. Complete the kube-apiserver upgrade to 1.35 or later
  2. Complete kubelet upgrade to 1.35 or later on all nodes
  3. Ensure CSI driver version with fallback logic is deployed (if not already done in preparation phase)
  4. Fully complete CSI driver DaemonSet rollout across all nodes
  5. Update your CSIDriver manifest to set serviceAccountTokenInSecrets: true

Important constraints

The most important thing to remember is timing. If your CSI driver DaemonSet and CSIDriver object are in the same manifest or Helm chart, you need two separate updates. Deploy the new driver version with fallback logic first, wait for the DaemonSet rollout to complete, then update the CSIDriver spec to set serviceAccountTokenInSecrets: true.

Also, don't update the CSIDriver before all driver pods have rolled out. If you do, volume mounts will fail on nodes still running the old driver version, since those pods only check volume context.

Why this matters

Adopting this feature helps in a few ways:

Call to action

We (Kubernetes SIG Storage) encourage CSI driver authors to adopt this feature and provide feedback on the migration experience. If you have thoughts on the API design or run into any issues during adoption, please reach out to us on the #csi channel on Kubernetes Slack (for an invitation, visit https://slack.k8s.io/).

You can follow along on KEP-5538 to track progress across the coming Kubernetes releases.

07 Jan 2026 6:30pm GMT

05 Jan 2026

feedKubernetes Blog

Kubernetes v1.35: Extended Toleration Operators to Support Numeric Comparisons (Alpha)

Many production Kubernetes clusters blend on-demand (higher-SLA) and spot/preemptible (lower-SLA) nodes to optimize costs while maintaining reliability for critical workloads. Platform teams need a safe default that keeps most workloads away from risky capacity, while allowing specific workloads to opt-in with explicit thresholds like "I can tolerate nodes with failure probability up to 5%".

Today, Kubernetes taints and tolerations can match exact values or check for existence, but they can't compare numeric thresholds. You'd need to create discrete taint categories, use external admission controllers, or accept less-than-optimal placement decisions.

In Kubernetes v1.35, we're introducing Extended Toleration Operators as an alpha feature. This enhancement adds Gt (Greater Than) and Lt (Less Than) operators to spec.tolerations, enabling threshold-based scheduling decisions that unlock new possibilities for SLA-based placement, cost optimization, and performance-aware workload distribution.

The evolution of tolerations

Historically, Kubernetes supported two primary toleration operators:

While these worked well for categorical scenarios, they fell short for numeric comparisons. Starting with v1.35, we are closing this gap.

Consider these real-world scenarios:

Without numeric comparison operators, cluster operators have had to resort to workarounds like creating multiple discrete taint values or using external admission controllers, neither of which scale well or provide the flexibility needed for dynamic threshold-based scheduling.

Why extend tolerations instead of using NodeAffinity?

You might wonder: NodeAffinity already supports numeric comparison operators, so why extend tolerations? While NodeAffinity is powerful for expressing pod preferences, taints and tolerations provide critical operational benefits:

This enhancement preserves the well-understood safety model of taints and tolerations while enabling threshold-based placement for SLA-aware scheduling.

Introducing Gt and Lt operators

Kubernetes v1.35 introduces two new operators for tolerations:

When a pod tolerates a taint with Lt, it's saying "I can tolerate nodes where this metric is less than my threshold". Since tolerations allow scheduling, the pod can run on nodes where the taint value is greater than the toleration value. Think of it as: "I tolerate nodes that are above my minimum requirements".

These operators work with numeric taint values and enable the scheduler to make sophisticated placement decisions based on continuous metrics rather than discrete categories.

Use cases and examples

Let's explore how Extended Toleration Operators solve real-world scheduling challenges.

Example 1: Spot instance protection with SLA thresholds

Many clusters mix on-demand and spot/preemptible nodes to optimize costs. Spot nodes offer significant savings but have higher failure rates. You want most workloads to avoid spot nodes by default, while allowing specific workloads to opt-in with clear SLA boundaries.

First, taint spot nodes with their failure probability (for example, 15% annual failure rate):

apiVersion: v1
kind: Node
metadata:
 name: spot-node-1
spec:
 taints:
 - key: "failure-probability"
 value: "15"
 effect: "NoExecute"

On-demand nodes have much lower failure rates:

apiVersion: v1
kind: Node
metadata:
 name: ondemand-node-1
spec:
 taints:
 - key: "failure-probability"
 value: "2"
 effect: "NoExecute"

Critical workloads can specify strict SLA requirements:

apiVersion: v1
kind: Pod
metadata:
 name: payment-processor
spec:
 tolerations:
 - key: "failure-probability"
 operator: "Lt"
 value: "5"
 effect: "NoExecute"
 tolerationSeconds: 30
 containers:
 - name: app
 image: payment-app:v1

This pod will only schedule on nodes with failure-probability less than 5 (meaning ondemand-node-1 with 2% but not spot-node-1 with 15%). The NoExecute effect with tolerationSeconds: 30 means if a node's SLA degrades (for example, cloud provider changes the taint value), the pod gets 30 seconds to gracefully terminate before forced eviction.

Meanwhile, a fault-tolerant batch job can explicitly opt-in to spot instances:

apiVersion: v1
kind: Pod
metadata:
 name: batch-job
spec:
 tolerations:
 - key: "failure-probability"
 operator: "Lt"
 value: "20"
 effect: "NoExecute"
 containers:
 - name: worker
 image: batch-worker:v1

This batch job tolerates nodes with failure probability up to 20%, so it can run on both on-demand and spot nodes, maximizing cost savings while accepting higher risk.

Example 2: AI workload placement with GPU tiers

AI and machine learning workloads often have specific hardware requirements. With Extended Toleration Operators, you can create GPU node tiers and ensure workloads land on appropriately powered hardware.

Taint GPU nodes with their compute capability score:

apiVersion: v1
kind: Node
metadata:
 name: gpu-node-a100
spec:
 taints:
 - key: "gpu-compute-score"
 value: "1000"
 effect: "NoSchedule"
---
apiVersion: v1
kind: Node
metadata:
 name: gpu-node-t4
spec:
 taints:
 - key: "gpu-compute-score"
 value: "500"
 effect: "NoSchedule"

A heavy training workload can require high-performance GPUs:

apiVersion: v1
kind: Pod
metadata:
 name: model-training
spec:
 tolerations:
 - key: "gpu-compute-score"
 operator: "Gt"
 value: "800"
 effect: "NoSchedule"
 containers:
 - name: trainer
 image: ml-trainer:v1
 resources:
 limits:
 nvidia.com/gpu: 1

This ensures the training pod only schedules on nodes with compute scores greater than 800 (like the A100 node), preventing placement on lower-tier GPUs that would slow down training.

Meanwhile, inference workloads with less demanding requirements can use any available GPU:

apiVersion: v1
kind: Pod
metadata:
 name: model-inference
spec:
 tolerations:
 - key: "gpu-compute-score"
 operator: "Gt"
 value: "400"
 effect: "NoSchedule"
 containers:
 - name: inference
 image: ml-inference:v1
 resources:
 limits:
 nvidia.com/gpu: 1

Example 3: Cost-optimized workload placement

For batch processing or non-critical workloads, you might want to minimize costs by running on cheaper nodes, even if they have lower performance characteristics.

Nodes can be tainted with their cost rating:

spec:
 taints:
 - key: "cost-per-hour"
 value: "50"
 effect: "NoSchedule"

A cost-sensitive batch job can express its tolerance for expensive nodes:

tolerations:
- key: "cost-per-hour"
 operator: "Lt"
 value: "100"
 effect: "NoSchedule"

This batch job will schedule on nodes costing less than $100/hour but avoid more expensive nodes. Combined with Kubernetes scheduling priorities, this enables sophisticated cost-tiering strategies where critical workloads get premium nodes while batch workloads efficiently use budget-friendly resources.

Example 4: Performance-based placement

Storage-intensive applications often require minimum disk performance guarantees. With Extended Toleration Operators, you can enforce these requirements at the scheduling level.

tolerations:
- key: "disk-iops"
 operator: "Gt"
 value: "3000"
 effect: "NoSchedule"

This toleration ensures the pod only schedules on nodes where disk-iops exceeds 3000. The Gt operator means "I need nodes that are greater than this minimum".

How to use this feature

Extended Toleration Operators is an alpha feature in Kubernetes v1.35. To try it out:

  1. Enable the feature gate on both your API server and scheduler:

    --feature-gates=TaintTolerationComparisonOperators=true

  2. Taint your nodes with numeric values representing the metrics relevant to your scheduling needs:

     kubectl taint nodes node-1 failure-probability=5:NoSchedule
 kubectl taint nodes node-2 disk-iops=5000:NoSchedule

  3. Use the new operators in your pod specifications:

     spec:
 tolerations:
 - key: "failure-probability"
 operator: "Lt"
 value: "1"
 effect: "NoSchedule"

What's next?

This alpha release is just the beginning. As we gather feedback from the community, we plan to:

We're particularly interested in hearing about your use cases! Do you have scenarios where threshold-based scheduling would solve problems? Are there additional operators or capabilities you'd like to see?

Getting involved

This feature is driven by the SIG Scheduling community. Please join us to connect with the community and share your ideas and feedback around this feature and beyond.

You can reach the maintainers of this feature at:

For questions or specific inquiries related to Extended Toleration Operators, please reach out to the SIG Scheduling community. We look forward to hearing from you!

How can I learn more?

05 Jan 2026 6:30pm GMT

02 Jan 2026

feedKubernetes Blog

Kubernetes v1.35: New level of efficiency with in-place Pod restart

The release of Kubernetes 1.35 introduces a powerful new feature that provides a much-requested capability: the ability to trigger a full, in-place restart of the Pod. This feature, Restart All Containers (alpha in 1.35), allows for an efficient way to reset a Pod's state compared to resource-intensive approach of deleting and recreating the entire Pod. This feature is especially useful for AI/ML workloads allowing application developers to concentrate on their core training logic while offloading complex failure-handling and recovery mechanisms to sidecars and declarative Kubernetes configuration. With RestartAllContainers and other planned enhancements, Kubernetes continues to add building blocks for creating the most flexible, robust, and efficient platforms for AI/ML workloads.

This new functionality is available by enabling the RestartAllContainersOnContainerExits feature gate. This alpha feature extends the Container Restart Rules feature, which graduated to beta in Kubernetes 1.35.

The problem: when a single container restart isn't enough and recreating pods is too costly

Kubernetes has long supported restart policies at the Pod level (restartPolicy) and, more recently, at the individual container level. These policies are great for handling crashes in a single, isolated process. However, many modern applications have more complex inter-container dependencies. For instance:

In all these cases, the desired action is not to restart a single container, but all of them. Previously, the only way to achieve this was to delete the Pod and have a controller (like a Job or ReplicaSet) create a new one. This process is slow and expensive, involving the scheduler, node resource allocation and re-initialization of networking and storage.

This inefficiency becomes even worse when handling large-scale AI/ML workloads (>= 1,000 Nodes with one Pod per Node). A common requirement for these synchronous workloads is that when a failure occurs (such as a Node crash), all Pods in the fleet must be recreated to reset the state before training can resume, even if all the other Pods were not directly affected by the failure. Deleting, creating and scheduling thousands of Pods simultaneously creates a massive bottleneck. The estimated overhead of this failure could cost $100,000 per month in wasted resources.

Handling these failures for AI/ML training jobs requires a complex integration touching both the training framework and Kubernetes, which are often fragile and toilsome. This feature introduces a Kubernetes-native solution, improving system robustness and allowing application developers to concentrate on their core training logic.

Another major benefit of restarting Pods in place is that keeping Pods on their assigned Nodes allows for further optimizations. For example, one can implement node-level caching tied to a specific Pod identity, something that is impossible when Pods are unnecessarily being recreated on different Nodes.

Introducing the RestartAllContainers action

To address this, Kubernetes v1.35 adds a new action to the container restart rules: RestartAllContainers. When a container exits in a way that matches a rule with this action, the kubelet initiates a fast, in-place restart of the Pod.

This in-place restart is highly efficient because it preserves the Pod's most important resources:

After terminating all running containers, the Pod's startup sequence is re-executed from the very beginning. This means all init containers are run again in order, followed by the sidecar and regular containers, ensuring a completely fresh start in a known-good environment. With the exception of ephemeral containers (which are terminated), all other containers-including those that previously succeeded or failed-will be restarted, regardless of their individual restart policies.

Use cases

1. Efficient restarts for ML/Batch jobs

For ML training jobs, rescheduling a worker Pod on failure is a costly operation that wastes valuable compute resources. On a 1,000-node training cluster, rescheduling overhead can waste over $100,000 in compute resources monthly.

With RestartAllContainers actions you can address this by enabling a much faster, hybrid recovery strategy: recreate only the "bad" Pods (e.g., those on unhealthy Nodes) while triggering RestartAllContainers for the remaining healthy Pods. Benchmarks show this reduces the recovery overhead from minutes to a few seconds.

With in-place restarts, a watcher sidecar can monitor the main training process. If it encounters a specific, retriable error, the watcher can exit with a designated code to trigger a fast reset of the worker Pod, allowing it to restart from the last checkpoint without involving the Job controller. This capability is now natively supported by Kubernetes.

Read more details about future development and JobSet features at KEP-467 JobSet in-place restart.

apiVersion: v1
kind: Pod
metadata:
 name: ml-worker-pod
spec:
 restartPolicy: Never
 initContainers:
 # This init container will re-run on every in-place restart
 - name: setup-environment
 image: my-repo/setup-worker:1.0
 - name: watcher-sidecar
 image: my-repo/watcher:1.0
 restartPolicy: Always
 restartPolicyRules:
 - action: RestartAllContainers
 onExit:
 exitCodes:
 operator: In
 # A specific exit code from the watcher triggers a full pod restart
 values: [88]
 containers:
 - name: main-application
 image: my-repo/training-app:1.0

2. Re-running init containers for a clean state

Imagine a scenario where an init container is responsible for fetching credentials or setting up a shared volume. If the main application fails in a way that corrupts this shared state, you need the init container to rerun.

By configuring the main application to exit with a specific code upon detecting such a corruption, you can trigger the RestartAllContainers action, guaranteeing that the init container provides a clean setup before the application restarts.

3. Handling high rate of similar tasks execution

There are cases when tasks are best represented as a Pod execution. And each task requires a clean execution. The task may be a game session backend or some queue item processing. If the rate of tasks is high, running the whole cycle of Pod creation, scheduling and initialization is simply too expensive, especially when tasks can be short. The ability to restart all containers from scratch enables a Kubernetes-native way to handle this scenario without custom solutions or frameworks.

How to use it

To try this feature, you must enable the RestartAllContainersOnContainerExits feature gate on your Kubernetes cluster components (API server and kubelet) running Kubernetes v1.35+. This alpha feature extends the ContainerRestartRules feature, which graduated to beta in v1.35 and is enabled by default.

Once enabled, you can add restartPolicyRules to any container (init, sidecar, or regular) and use the RestartAllContainers action.

The feature is designed to be easily usable on existing apps. However, if an application does not follow some best practices, it may cause issues for the application or for observability tooling. When enabling the feature, make sure that all containers are reentrant and that external tooling is prepared for init containers to re-run. Also, when restarting all containers, the kubelet does not run preStop hooks. This means containers must be designed to handle abrupt termination without relying on preStop hooks for graceful shutdown.

Observing the restart

To make this process observable, a new Pod condition, AllContainersRestarting, is added to the Pod's status. When a restart is triggered, this condition becomes True and it reverts to False once all containers have terminated and the Pod is ready to start its lifecycle anew. This provides a clear signal to users and other cluster components about the Pod's state.

All containers restarted by this action will have their restart count incremented in the container status.

Learn more

We want your feedback!

As an alpha feature, RestartAllContainers is ready for you to experiment with and any use cases and feedback are welcome. This feature is driven by the SIG Node community. If you are interested in getting involved, sharing your thoughts, or contributing, please join us!

You can reach SIG Node through:

02 Jan 2026 6:30pm GMT

31 Dec 2025

feedKubernetes Blog

Kubernetes 1.35: Enhanced Debugging with Versioned z-pages APIs

Debugging Kubernetes control plane components can be challenging, especially when you need to quickly understand the runtime state of a component or verify its configuration. With Kubernetes 1.35, we're enhancing the z-pages debugging endpoints with structured, machine-parseable responses that make it easier to build tooling and automate troubleshooting workflows.

What are z-pages?

z-pages are special debugging endpoints exposed by Kubernetes control plane components. Introduced as an alpha feature in Kubernetes 1.32, these endpoints provide runtime diagnostics for components like kube-apiserver, kube-controller-manager, kube-scheduler, kubelet and kube-proxy. The name "z-pages" comes from the convention of using /*z paths for debugging endpoints.

Currently, Kubernetes supports two primary z-page endpoints:

/statusz
Displays high-level component information including version information, start time, uptime, and available debug paths
/flagz
Shows all command-line arguments and their values used to start the component (with confidential values redacted for security)

These endpoints are valuable for human operators who need to quickly inspect component state, but until now, they only returned plain text output that was difficult to parse programmatically.

What's new in Kubernetes 1.35?

Kubernetes 1.35 introduces structured, versioned responses for both /statusz and /flagz endpoints. This enhancement maintains backward compatibility with the existing plain text format while adding support for machine-readable JSON responses.

Backward compatible design

The new structured responses are opt-in. Without specifying an Accept header, the endpoints continue to return the familiar plain text format:

$ curl --cert /etc/kubernetes/pki/apiserver-kubelet-client.crt \
--key /etc/kubernetes/pki/apiserver-kubelet-client.key \
--cacert /etc/kubernetes/pki/ca.crt \
https://localhost:6443/statusz
kube-apiserver statusz
Warning: This endpoint is not meant to be machine parseable, has no formatting compatibility guarantees and is for debugging purposes only.
Started: Wed Oct 16 21:03:43 UTC 2024
Up: 0 hr 00 min 16 sec
Go version: go1.23.2
Binary version: 1.35.0-alpha.0.1595
Emulation version: 1.35
Paths: /healthz /livez /metrics /readyz /statusz /version

Structured JSON responses

To receive a structured response, include the appropriate Accept header:

Accept: application/json;v=v1alpha1;g=config.k8s.io;as=Statusz

This returns a versioned JSON response:

{
 "kind": "Statusz",
 "apiVersion": "config.k8s.io/v1alpha1",
 "metadata": {
 "name": "kube-apiserver"
 },
 "startTime": "2025-10-29T00:30:01Z",
 "uptimeSeconds": 856,
 "goVersion": "go1.23.2",
 "binaryVersion": "1.35.0",
 "emulationVersion": "1.35",
 "paths": [
 "/healthz",
 "/livez",
 "/metrics",
 "/readyz",
 "/statusz",
 "/version"
 ]
}

Similarly, /flagz supports structured responses with the header:

Accept: application/json;v=v1alpha1;g=config.k8s.io;as=Flagz

Example response:

{
 "kind": "Flagz",
 "apiVersion": "config.k8s.io/v1alpha1",
 "metadata": {
 "name": "kube-apiserver"
 },
 "flags": {
 "advertise-address": "192.168.8.4",
 "allow-privileged": "true",
 "authorization-mode": "[Node,RBAC]",
 "enable-priority-and-fairness": "true",
 "profiling": "true"
 }
}

Why structured responses matter

The addition of structured responses opens up several new possibilities:

1. Automated health checks and monitoring

Instead of parsing plain text, monitoring tools can now easily extract specific fields. For example, you can programmatically check if a component has been running with an unexpected emulated version or verify that critical flags are set correctly.

2. Better debugging tools

Developers can build sophisticated debugging tools that compare configurations across multiple components or track configuration drift over time. The structured format makes it trivial to diff configurations or validate that components are running with expected settings.

3. API versioning and stability

By introducing versioned APIs (starting with v1alpha1), we provide a clear path to stability. As the feature matures, we'll introduce v1beta1 and eventually v1, giving you confidence that your tooling won't break with future Kubernetes releases.

How to use structured z-pages

Prerequisites

Both endpoints require feature gates to be enabled:

Example: Getting structured responses

Here's an example using curl to retrieve structured JSON responses from the kube-apiserver:

# Get structured statusz response
curl \
 --cert /etc/kubernetes/pki/apiserver-kubelet-client.crt \
 --key /etc/kubernetes/pki/apiserver-kubelet-client.key \
 --cacert /etc/kubernetes/pki/ca.crt \
 -H "Accept: application/json;v=v1alpha1;g=config.k8s.io;as=Statusz" \
 https://localhost:6443/statusz | jq .

# Get structured flagz response
curl \
 --cert /etc/kubernetes/pki/apiserver-kubelet-client.crt \
 --key /etc/kubernetes/pki/apiserver-kubelet-client.key \
 --cacert /etc/kubernetes/pki/ca.crt \
 -H "Accept: application/json;v=v1alpha1;g=config.k8s.io;as=Flagz" \
 https://localhost:6443/flagz | jq .

Important considerations

Alpha feature status

The structured z-page responses are an alpha feature in Kubernetes 1.35. This means:

Security and access control

z-pages expose internal component information and require proper access controls. Here are the key security considerations:

Authorization: Access to z-page endpoints is restricted to members of the system:monitoring group, which follows the same authorization model as other debugging endpoints like /healthz, /livez, and /readyz. This ensures that only authorized users and service accounts can access debugging information. If your cluster uses RBAC, you can manage access by granting appropriate permissions to this group.

Authentication: The authentication requirements for these endpoints depend on your cluster's configuration. Unless anonymous authentication is enabled for your cluster, you typically need to use authentication mechanisms (such as client certificates) to access these endpoints.

Information disclosure: These endpoints reveal configuration details about your cluster components, including:

Only grant access to trusted operators and debugging tools. Avoid exposing these endpoints to unauthorized users or automated systems that don't require this level of access.

Future evolution

As the feature matures, we (Kubernetes SIG Instrumentation) expect to:

Try it out

We encourage you to experiment with structured z-pages in a test environment:

  1. Enable the ComponentStatusz and ComponentFlagz feature gates on your control plane components
  2. Try querying the endpoints with both plain text and structured formats
  3. Build a simple tool or script that uses the structured data
  4. Share your feedback with the community

Learn more

Get involved

We'd love to hear your feedback! The structured z-pages feature is designed to make Kubernetes easier to debug and monitor. Whether you're building internal tooling, contributing to open source projects, or just exploring the feature, your input helps shape the future of Kubernetes observability.

If you have questions, suggestions, or run into issues, please reach out to SIG Instrumentation. You can find us on Slack or at our regular community meetings.

Happy debugging!

31 Dec 2025 6:30pm GMT

30 Dec 2025

feedKubernetes Blog

Kubernetes v1.35: Watch Based Route Reconciliation in the Cloud Controller Manager

Up to and including Kubernetes v1.34, the route controller in Cloud Controller Manager (CCM) implementations built using the k8s.io/cloud-provider library reconciles routes at a fixed interval. This causes unnecessary API requests to the cloud provider when there are no changes to routes. Other controllers implemented through the same library already use watch-based mechanisms, leveraging informers to avoid unnecessary API calls. A new feature gate is being introduced in v1.35 to allow changing the behavior of the route controller to use watch-based informers.

What's new?

The feature gate CloudControllerManagerWatchBasedRoutesReconciliation has been introduced to k8s.io/cloud-provider in alpha stage by SIG Cloud Provider. To enable this feature you can use --feature-gate=CloudControllerManagerWatchBasedRoutesReconciliation=true in the CCM implementation you are using.

About the feature gate

This feature gate will trigger the route reconciliation loop whenever a node is added, deleted, or the fields .spec.podCIDRs or .status.addresses are updated.

An additional reconcile is performed in a random interval between 12h and 24h, which is chosen at the controller's start time.

This feature gate does not modify the logic within the reconciliation loop. Therefore, users of a CCM implementation should not experience significant changes to their existing route configurations.

How can I learn more?

For more details, refer to the KEP-5237.

30 Dec 2025 6:30pm GMT

29 Dec 2025

feedKubernetes Blog

Kubernetes v1.35: Introducing Workload Aware Scheduling

Scheduling large workloads is a much more complex and fragile operation than scheduling a single Pod, as it often requires considering all Pods together instead of scheduling each one independently. For example, when scheduling a machine learning batch job, you often need to place each worker strategically, such as on the same rack, to make the entire process as efficient as possible. At the same time, the Pods that are part of such a workload are very often identical from the scheduling perspective, which fundamentally changes how this process should look.

There are many custom schedulers adapted to perform workload scheduling efficiently, but considering how common and important workload scheduling is to Kubernetes users, especially in the AI era with the growing number of use cases, it is high time to make workloads a first-class citizen for kube-scheduler and support them natively.

Workload aware scheduling

The recent 1.35 release of Kubernetes delivered the first tranche of workload aware scheduling improvements. These are part of a wider effort that is aiming to improve scheduling and management of workloads. The effort will span over many SIGs and releases, and is supposed to gradually expand capabilities of the system toward reaching the north star goal, which is seamless workload scheduling and management in Kubernetes including, but not limited to, preemption and autoscaling.

Kubernetes v1.35 introduces the Workload API that you can use to describe the desired shape as well as scheduling-oriented requirements of the workload. It comes with an initial implementation of gang scheduling that instructs the kube-scheduler to schedule gang Pods in the all-or-nothing fashion. Finally, we improved scheduling of identical Pods (that typically make a gang) to speed up the process thanks to the opportunistic batching feature.

Workload API

The new Workload API resource is part of the scheduling.k8s.io/v1alpha1 API group. This resource acts as a structured, machine-readable definition of the scheduling requirements of a multi-Pod application. While user-facing workloads like Jobs define what to run, the Workload resource determines how a group of Pods should be scheduled and how its placement should be managed throughout its lifecycle.

A Workload allows you to define a group of Pods and apply a scheduling policy to them. Here is what a gang scheduling configuration looks like. You can define a podGroup named workers and apply the gang policy with a minCount of 4.

apiVersion: scheduling.k8s.io/v1alpha1
kind: Workload
metadata:
 name: training-job-workload
 namespace: some-ns
spec:
 podGroups:
 - name: workers
 policy:
 gang:
 # The gang is schedulable only if 4 pods can run at once
 minCount: 4

When you create your Pods, you link them to this Workload using the new workloadRef field:

apiVersion: v1
kind: Pod
metadata:
 name: worker-0
 namespace: some-ns
spec:
 workloadRef:
 name: training-job-workload
 podGroup: workers
 ...

How gang scheduling works

The gang policy enforces all-or-nothing placement. Without gang scheduling, a Job might be partially scheduled, consuming resources without being able to run, leading to resource wastage and potential deadlocks.

When you create Pods that are part of a gang-scheduled pod group, the scheduler's GangScheduling plugin manages the lifecycle independently for each pod group (or replica key):

  1. When you create your Pods (or a controller makes them for you), the scheduler blocks them from scheduling, until:

    • The referenced Workload object is created.
    • The referenced pod group exists in a Workload.
    • The number of pending Pods in that group meets your minCount.

  2. Once enough Pods arrive, the scheduler tries to place them. However, instead of binding them to nodes immediately, the Pods wait at a Permit gate.

  3. The scheduler checks if it has found valid assignments for the entire group (at least the minCount).

    • If there is room for the group, the gate opens, and all Pods are bound to nodes.
    • If only a subset of the group pods was successfully scheduled within a timeout (set to 5 minutes), the scheduler rejects all of the Pods in the group. They go back to the queue, freeing up the reserved resources for other workloads.

We'd like to point out that that while this is a first implementation, the Kubernetes project firmly intends to improve and expand the gang scheduling algorithm in future releases. Benefits we hope to deliver include a single-cycle scheduling phase for a whole gang, workload-level preemption, and more, moving towards the north star goal.

Opportunistic batching

In addition to explicit gang scheduling, v1.35 introduces opportunistic batching. This is a Beta feature that improves scheduling latency for identical Pods.

Unlike gang scheduling, this feature does not require the Workload API or any explicit opt-in on the user's part. It works opportunistically within the scheduler by identifying Pods that have identical scheduling requirements (container images, resource requests, affinities, etc.). When the scheduler processes a Pod, it can reuse the feasibility calculations for subsequent identical Pods in the queue, significantly speeding up the process.

Most users will benefit from this optimization automatically, without taking any special steps, provided their Pods meet the following criteria.

Restrictions

Opportunistic batching works under specific conditions. All fields used by the kube-scheduler to find a placement must be identical between Pods. Additionally, using some features disables the batching mechanism for those Pods to ensure correctness.

Note that you may need to review your kube-scheduler configuration to ensure it is not implicitly disabling batching for your workloads.

See the docs for more details about restrictions.

The north star vision

The project has a broad ambition to deliver workload aware scheduling. These new APIs and scheduling enhancements are just the first steps. In the near future, the effort aims to tackle:

And more. The priority and implementation order of these focus areas are subject to change. Stay tuned for further updates.

Getting started

To try the workload aware scheduling improvements:

We encourage you to try out workload aware scheduling in your test clusters and share your experiences to help shape the future of Kubernetes scheduling. You can send your feedback by:

Learn more

29 Dec 2025 6:30pm GMT

23 Dec 2025

feedKubernetes Blog

Kubernetes v1.35: Fine-grained Supplemental Groups Control Graduates to GA

On behalf of Kubernetes SIG Node, we are pleased to announce the graduation of fine-grained supplemental groups control to General Availability (GA) in Kubernetes v1.35!

The new Pod field, supplementalGroupsPolicy, was introduced as an opt-in alpha feature for Kubernetes v1.31, and then had graduated to beta in v1.33. Now, the feature is generally available. This feature allows you to implement more precise control over supplemental groups in Linux containers that can strengthen the security posture particularly in accessing volumes. Moreover, it also enhances the transparency of UID/GID details in containers, offering improved security oversight.

If you are planning to upgrade your cluster from v1.32 or an earlier version, please be aware that some behavioral breaking change introduced since beta (v1.33). For more details, see the behavioral changes introduced in beta and the upgrade considerations sections of the previous blog for graduation to beta.

Motivation: Implicit group memberships defined in /etc/group in the container image

Even though the majority of Kubernetes cluster admins/users may not be aware of this, by default Kubernetes merges group information from the Pod with information defined in /etc/group in the container image.

Here's an example; a Pod manifest that specifies spec.securityContext.runAsUser: 1000, spec.securityContext.runAsGroup: 3000 and spec.securityContext.supplementalGroups: 4000 as part of the Pod's security context.

apiVersion: v1
kind: Pod
metadata:
 name: implicit-groups-example
spec:
 securityContext:
 runAsUser: 1000
 runAsGroup: 3000
 supplementalGroups: [4000]
 containers:
 - name: example-container
 image: registry.k8s.io/e2e-test-images/agnhost:2.45
 command: [ "sh", "-c", "sleep 1h" ]
 securityContext:
 allowPrivilegeEscalation: false

What is the result of id command in the example-container container? The output should be similar to this:

uid=1000 gid=3000 groups=3000,4000,50000

Where does group ID 50000 in supplementary groups (groups field) come from, even though 50000 is not defined in the Pod's manifest at all? The answer is /etc/group file in the container image.

Checking the contents of /etc/group in the container image contains something like the following:

user-defined-in-image:x:1000:
group-defined-in-image:x:50000:user-defined-in-image

This shows that the container's primary user 1000 belongs to the group 50000 in the last entry.

Thus, the group membership defined in /etc/group in the container image for the container's primary user is implicitly merged to the information from the Pod. Please note that this was a design decision the current CRI implementations inherited from Docker, and the community never really reconsidered it until now.

What's wrong with it?

The implicitly merged group information from /etc/group in the container image poses a security risk. These implicit GIDs can't be detected or validated by policy engines because there's no record of them in the Pod manifest. This can lead to unexpected access control issues, particularly when accessing volumes (see kubernetes/kubernetes#112879 for details) because file permission is controlled by UID/GIDs in Linux.

Fine-grained supplemental groups control in a Pod: supplementaryGroupsPolicy

To tackle this problem, a Pod's .spec.securityContext now includes supplementalGroupsPolicy field.

This field lets you control how Kubernetes calculates the supplementary groups for container processes within a Pod. The available policies are:

I'll explain how the Strict policy works. The following Pod manifest specifies supplementalGroupsPolicy: Strict:

apiVersion: v1
kind: Pod
metadata:
 name: strict-supplementalgroups-policy-example
spec:
 securityContext:
 runAsUser: 1000
 runAsGroup: 3000
 supplementalGroups: [4000]
 supplementalGroupsPolicy: Strict
 containers:
 - name: example-container
 image: registry.k8s.io/e2e-test-images/agnhost:2.45
 command: [ "sh", "-c", "sleep 1h" ]
 securityContext:
 allowPrivilegeEscalation: false

The result of id command in the example-container container should be similar to this:

uid=1000 gid=3000 groups=3000,4000

You can see Strict policy can exclude group 50000 from groups!

Thus, ensuring supplementalGroupsPolicy: Strict (enforced by some policy mechanism) helps prevent the implicit supplementary groups in a Pod.

Attached process identity in Pod status

This feature also exposes the process identity attached to the first container process of the container via .status.containerStatuses[].user.linux field. It would be helpful to see if implicit group IDs are attached.

...
status:
 containerStatuses:
 - name: ctr
 user:
 linux:
 gid: 3000
 supplementalGroups:
 - 3000
 - 4000
 uid: 1000
...

Strict policy requires up-to-date container runtimes

The high level container runtime (e.g. containerd, CRI-O) plays a key role for calculating supplementary group ids that will be attached to the containers. Thus, supplementalGroupsPolicy: Strict requires a CRI runtime that support this feature. The old behavior (supplementalGroupsPolicy: Merge) can work with a CRI runtime that does not support this feature, because this policy is fully backward compatible.

Here are some CRI runtimes that support this feature, and the versions you need to be running:

And, you can see if the feature is supported in the Node's .status.features.supplementalGroupsPolicy field. Please note that this field is different from status.declaredFeatures introduced in KEP-5328: Node Declared Features(formerly Node Capabilities).

apiVersion: v1
kind: Node
...
status:
 features:
 supplementalGroupsPolicy: true

As container runtimes support this feature universally, various security policies may start enforcing the Strict behavior as more secure. It is the best practice to ensure that your Pods are ready for this enforcement and all supplemental groups are transparently declared in Pod spec, rather than in images.

Getting involved

This enhancement was driven by the SIG Node community. Please join us to connect with the community and share your ideas and feedback around the above feature and beyond. We look forward to hearing from you!

How can I learn more?

23 Dec 2025 6:30pm GMT

22 Dec 2025

feedKubernetes Blog

Kubernetes v1.35: Kubelet Configuration Drop-in Directory Graduates to GA

With the recent v1.35 release of Kubernetes, support for a kubelet configuration drop-in directory is generally available. The newly stable feature simplifies the management of kubelet configuration across large, heterogeneous clusters.

With v1.35, the kubelet command line argument --config-dir is production-ready and fully supported, allowing you to specify a directory containing kubelet configuration drop-in files. All files in that directory will be automatically merged with your main kubelet configuration. This allows cluster administrators to maintain a cohesive base configuration for kubelets while enabling targeted customizations for different node groups or use cases, and without complex tooling or manual configuration management.

The problem: managing kubelet configuration at scale

As Kubernetes clusters grow larger and more complex, they often include heterogeneous node pools with different hardware capabilities, workload requirements, and operational constraints. This diversity necessitates different kubelet configurations across node groups-yet managing these varied configurations at scale becomes increasingly challenging. Several pain points emerge:

Before this support was added to Kubernetes, cluster administrators had to choose between using a single monolithic configuration file for all nodes, manually maintaining multiple complete configuration files, or relying on separate tooling. Each approach had its own drawbacks. This graduation to stable gives cluster administrators a fully supported fourth way to solve that challenge.

Example use cases

Managing heterogeneous node pools

Consider a cluster with multiple node types: standard compute nodes, high-capacity nodes (such as those with GPUs or large amounts of memory), and edge nodes with specialized requirements.

Base configuration

File: 00-base.conf

apiVersion: kubelet.config.k8s.io/v1beta1
kind: KubeletConfiguration
clusterDNS:
 - "10.96.0.10"
clusterDomain: cluster.local

High-capacity node override

File: 50-high-capacity-nodes.conf

apiVersion: kubelet.config.k8s.io/v1beta1
kind: KubeletConfiguration
maxPods: 50
systemReserved:
 memory: "4Gi"
 cpu: "1000m"

Edge node override

File: 50-edge-nodes.conf (edge compute typically has lower capacity)

apiVersion: kubelet.config.k8s.io/v1beta1
kind: KubeletConfiguration
evictionHard:
 memory.available: "500Mi"
 nodefs.available: "5%"

With this structure, high-capacity nodes apply both the base configuration and the capacity-specific overrides, while edge nodes apply the base configuration with edge-specific settings.

Gradual configuration rollouts

When rolling out configuration changes, you can:

  1. Add a new drop-in file with a high numeric prefix (e.g., 99-new-feature.conf)
  2. Test the changes on a subset of nodes
  3. Gradually roll out to more nodes
  4. Once stable, merge changes into the base configuration

Viewing the merged configuration

Since configuration is now spread across multiple files, you can inspect the final merged configuration using the kubelet's /configz endpoint:

# Start kubectl proxy
kubectl proxy

# In another terminal, fetch the merged configuration
# Change the '<node-name>' placeholder before running the curl command
curl -X GET http://127.0.0.1:8001/api/v1/nodes/<node-name>/proxy/configz | jq .

This shows the actual configuration the kubelet is using after all merging has been applied. The merged configuration also includes any configuration settings that were specified via kubelet command-line arguments.

For detailed setup instructions, configuration examples, and merging behavior, see the official documentation:

Good practices

When using the kubelet configuration drop-in directory:

  1. Test configurations incrementally: Always test new drop-in configurations on a subset of nodes before rolling out cluster-wide to minimize risk

  2. Version control your drop-ins: Store your drop-in configuration files in version control (or the configuration source from which these are generated) alongside your infrastructure as code to track changes and enable easy rollbacks

  3. Use numeric prefixes for predictable ordering: Name files with numeric prefixes (e.g., 00-, 50-, 90-) to explicitly control merge order and make the configuration layering obvious to other administrators

  4. Be mindful of temporary files: Some text editors automatically create backup files (such as .bak, .swp, or files with ~ suffix) in the same directory when editing. Ensure these temporary or backup files are not left in the configuration directory, as they may be processed by the kubelet

Acknowledgments

This feature was developed through the collaborative efforts of SIG Node. Special thanks to all contributors who helped design, implement, test, and document this feature across its journey from alpha in v1.28, through beta in v1.30, to GA in v1.35.

To provide feedback on this feature, join the Kubernetes Node Special Interest Group, participate in discussions on the public Slack channel (#sig-node), or file an issue on GitHub.

Get involved

If you have feedback or questions about kubelet configuration management, or want to share your experience using this feature, join the discussion:

SIG Node would love to hear about your experiences using this feature in production!

22 Dec 2025 6:30pm GMT

21 Dec 2025

feedKubernetes Blog

Avoiding Zombie Cluster Members When Upgrading to etcd v3.6

This article is a mirror of an original that was recently published to the official etcd blog. The key takeaway? Always upgrade to etcd v3.5.26 or later before moving to v3.6. This ensures your cluster is automatically repaired, and avoids zombie members.

Issue summary

Recently, the etcd community addressed an issue that may appear when users upgrade from v3.5 to v3.6. This bug can cause the cluster to report "zombie members", which are etcd nodes that were removed from the database cluster some time ago, and are re-appearing and joining database consensus. The etcd cluster is then inoperable until these zombie members are removed.

In etcd v3.5 and earlier, the v2store was the source of truth for membership data, even though the v3store was also present. As a part of our v2store deprecation plan, in v3.6 the v3store is the source of truth for cluster membership. Through a bug report we found out that, in some older clusters, v2store and v3store could become inconsistent. This inconsistency manifests after upgrading as seeing old, removed "zombie" cluster members re-appearing in the cluster.

The fix and upgrade path

We've added a mechanism in etcd v3.5.26 to automatically sync v3store from v2store, ensuring that affected clusters are repaired before upgrading to 3.6.x.

To support the many users currently upgrading to 3.6, we have provided the following safe upgrade path:

  1. Upgrade your cluster to v3.5.26 or later.
  2. Wait and confirm that all members are healthy post-update.
  3. Upgrade to v3.6.

We are unable to provide a safe workaround path for users who have some obstacle preventing updating to v3.5.26. As such, if v3.5.26 is not available from your packaging source or vendor, you should delay upgrading to v3.6 until it is.

Additional technical detail

Information below is offered for reference only. Users can follow the safe upgrade path without knowledge of the following details.

This issue is encountered with clusters that have been running in production on etcd v3.5.25 or earlier. It is a side effect of adding and removing members from the cluster, or recovering the cluster from failure. This means that the issue is more likely the older the etcd cluster is, but it cannot be ruled out for any user regardless of the age of the cluster.

etcd maintainers, working with issue reporters, have found three possible triggers for the issue based on symptoms and an analysis of etcd code and logs:

  1. Bug in etcdctl snapshot restore (v3.4 and old versions): When restoring a snapshot using etcdctl snapshot restore, etcdctl was supposed to remove existing members before adding the new ones. In v3.4, due to a bug, old members were not removed, resulting in zombie members. Refer to the comment on etcdctl.
  2. --force-new-cluster in v3.5 and earlier versions: In rare cases, forcibly creating a new single-member cluster did not fully remove old members, leaving zombies. The issue was resolved in v3.5.22. Please refer to this PR in the Raft project for detailed technical information.
  3. --unsafe-no-sync enabled: If --unsafe-no-sync is enabled, in rare cases etcd might persist a membership change to v3store but crash before writing it to the WAL, causing inconsistency between v2store and v3store. This is a problem for single-member clusters. For multi-member clusters, forcibly creating a new single-member cluster from the crashed node's data may lead to zombie members.

Importantly, there may be other triggers for v2store and v3store membership data becoming inconsistent that we have not yet found. This means that you cannot assume that you are safe just because you have not performed any of the three actions above. Once users are upgraded to etcd v3.6, v3store becomes the source of membership data, and further inconsistency is not possible.

Advanced users who want to verify the consistency between v2store and v3store can follow the steps described in this comment. This check is not required to fix the issue, nor does SIG etcd recommend bypassing the v3.5.26 update regardless of the results of the check.

Key takeaway

Always upgrade to v3.5.26 or later before moving to v3.6. This ensures your cluster is automatically repaired and avoids zombie members.

Acknowledgements

We would like to thank Christian Baumann for reporting this long-standing upgrade issue. His report and follow-up work helped bring the issue to our attention so that we could investigate and resolve it upstream.

21 Dec 2025 12:00am GMT