The Kubernetes project maintains release branches for the most recent three minor releases (1.30, 1.29, 1.28). Kubernetes 1.19 and newer receive approximately 1 year of patch support. Kubernetes 1.18 and older received approximately 9 months of patch support.
Kubernetes versions are expressed as x.y.z,
where x is the major version, y is the minor version, and z is the patch version, following Semantic Versioning terminology.
Check out the schedule for the upcoming 1.31 Kubernetes release!
Helpful Resources
1 - Download Kubernetes
Kubernetes ships binaries for each component as well as a standard set of client
applications to bootstrap or interact with a cluster. Components like the
API server are capable of running within container images inside of a
cluster. Those components are also shipped in container images as part of the
official release process. All binaries as well as container images are available
for multiple operating systems as well as hardware architectures.
Container Images
All Kubernetes container images are deployed to the
registry.k8s.io container image registry.
FEATURE STATE:Kubernetes v1.24 [alpha]
For Kubernetes v1.26, the following
container images are signed using cosign
signatures:
Container Image
Supported Architectures
registry.k8s.io/kube-apiserver:v1.26.15
amd64, arm, arm64, ppc64le, s390x
registry.k8s.io/kube-controller-manager:v1.26.15
amd64, arm, arm64, ppc64le, s390x
registry.k8s.io/kube-proxy:v1.26.15
amd64, arm, arm64, ppc64le, s390x
registry.k8s.io/kube-scheduler:v1.26.15
amd64, arm, arm64, ppc64le, s390x
registry.k8s.io/conformance:v1.26.15
amd64, arm, arm64, ppc64le, s390x
All container images are available for multiple architectures, whereas the
container runtime should choose the correct one based on the underlying
platform. It is also possible to pull a dedicated architecture by suffixing the
container image name, for example
registry.k8s.io/kube-apiserver-arm64:v1.26.15. All
those derivations are signed in the same way as the multi-architecture manifest lists.
The Kubernetes project publishes a list of signed Kubernetes container images
in SPDX 2.2 format.
You can fetch that list using:
The Kubernetes command-line tool, kubectl, allows
you to run commands against Kubernetes clusters.
You can use kubectl to deploy applications, inspect and manage cluster resources,
and view logs. For more information including a complete list of kubectl operations, see the
kubectl reference documentation.
kubectl is installable on a variety of Linux platforms, macOS and Windows.
Find your preferred operating system below.
Warning: This content is auto-generated and links may not function. The source of the document is located here.
Targeting enhancements, Issues and PRs to Release Milestones
This document is focused on Kubernetes developers and contributors who need to
create an enhancement, issue, or pull request which targets a specific release
milestone.
Information on workflows and interactions are described below.
As the owner of an enhancement, issue, or pull request (PR), it is your
responsibility to ensure release milestone requirements are met. Automation and
the Release Team will be in contact with you if updates are required, but
inaction can result in your work being removed from the milestone. Additional
requirements exist when the target milestone is a prior release (see
cherry pick process for more information).
TL;DR
If you want your PR to get merged, it needs the following required labels and
milestones, represented here by the Prow /commands it would take to add them:
In the past, there was a requirement for a milestone-targeted pull requests to
have an associated GitHub issue opened, but this is no longer the case.
Features or enhancements are effectively GitHub issues or KEPs which
lead to subsequent PRs.
The general labeling process should be consistent across artifact types.
Definitions
issue owners: Creator, assignees, and user who moved the issue into a
release milestone
Release Team: Each Kubernetes release has a team doing project management
tasks described here.
The contact info for the team associated with any given release can be found
here.
release branch: Git branch release-X.Y created for the vX.Y milestone.
Created at the time of the vX.Y-rc.0 release and maintained after the
release for approximately 12 months with vX.Y.Z patch releases.
Note: releases 1.19 and newer receive 1 year of patch release support, and
releases 1.18 and earlier received 9 months of patch release support.
The Release Cycle
Kubernetes releases currently happen approximately three times per year.
The release process can be thought of as having three main phases:
Enhancement Definition
Implementation
Stabilization
But in reality, this is an open source and agile project, with feature planning
and implementation happening at all times. Given the project scale and globally
distributed developer base, it is critical to project velocity to not rely on a
trailing stabilization phase and rather have continuous integration testing
which ensures the project is always stable so that individual commits can be
flagged as having broken something.
With ongoing feature definition through the year, some set of items will bubble
up as targeting a given release. Enhancements Freeze
starts ~4 weeks into release cycle. By this point all intended feature work for
the given release has been defined in suitable planning artifacts in
conjunction with the Release Team's Enhancements Lead.
After Enhancements Freeze, tracking milestones on PRs and issues is important.
Items within the milestone are used as a punchdown list to complete the
release. On issues, milestones must be applied correctly, via triage by the
SIG, so that Release Team can track bugs and enhancements (any
enhancement-related issue needs a milestone).
There is some automation in place to help automatically assign milestones to
PRs.
This automation currently applies to the following repos:
kubernetes/enhancements
kubernetes/kubernetes
kubernetes/release
kubernetes/sig-release
kubernetes/test-infra
At creation time, PRs against the master branch need humans to hint at which
milestone they might want the PR to target. Once merged, PRs against the
master branch have milestones auto-applied so from that time onward human
management of that PR's milestone is less necessary. On PRs against release
branches, milestones are auto-applied when the PR is created so no human
management of the milestone is ever necessary.
Any other effort that should be tracked by the Release Team that doesn't fall
under that automation umbrella should be have a milestone applied.
Implementation and bug fixing is ongoing across the cycle, but culminates in a
code freeze period.
Code Freeze starts in week ~12 and continues for ~2 weeks.
Only critical bug fixes are accepted into the release codebase during this
time.
There are approximately two weeks following Code Freeze, and preceding release,
during which all remaining critical issues must be resolved before release.
This also gives time for documentation finalization.
When the code base is sufficiently stable, the master branch re-opens for
general development and work begins there for the next release milestone. Any
remaining modifications for the current release are cherry picked from master
back to the release branch. The release is built from the release branch.
Each release is part of a broader Kubernetes lifecycle:
Removal Of Items From The Milestone
Before getting too far into the process for adding an item to the milestone,
please note:
Members of the Release Team may remove issues from the
milestone if they or the responsible SIG determine that the issue is not
actually blocking the release and is unlikely to be resolved in a timely
fashion.
Members of the Release Team may remove PRs from the milestone for any of the
following, or similar, reasons:
PR is potentially de-stabilizing and is not needed to resolve a blocking
issue
PR is a new, late feature PR and has not gone through the enhancements
process or the exception process
There is no responsible SIG willing to take ownership of the PR and resolve
any follow-up issues with it
PR is not correctly labelled
Work has visibly halted on the PR and delivery dates are uncertain or late
While members of the Release Team will help with labelling and contacting
SIG(s), it is the responsibility of the submitter to categorize PRs, and to
secure support from the relevant SIG to guarantee that any breakage caused by
the PR will be rapidly resolved.
Where additional action is required, an attempt at human to human escalation
will be made by the Release Team through the following channels:
Comment in GitHub mentioning the SIG team and SIG members as appropriate for
the issue type
optionally also directly addressing SIG leadership or other SIG members
Messaging the SIG's Slack channel
bootstrapped with the slackchannel and SIG leadership from the
community sig list
optionally directly "@" mentioning SIG leadership or others by handle
Adding An Item To The Milestone
Milestone Maintainers
The members of the milestone-maintainers
GitHub team are entrusted with the responsibility of specifying the release
milestone on GitHub artifacts.
This group is maintained
by SIG Release and has representation from the various SIGs' leadership.
Feature additions
Feature planning and definition takes many forms today, but a typical example
might be a large piece of work described in a KEP, with associated task
issues in GitHub. When the plan has reached an implementable state and work is
underway, the enhancement or parts thereof are targeted for an upcoming milestone
by creating GitHub issues and marking them with the Prow "/milestone" command.
For the first ~4 weeks into the release cycle, the Release Team's Enhancements
Lead will interact with SIGs and feature owners via GitHub, Slack, and SIG
meetings to capture all required planning artifacts.
If you have an enhancement to target for an upcoming release milestone, begin a
conversation with your SIG leadership and with that release's Enhancements
Lead.
Issue additions
Issues are marked as targeting a milestone via the Prow "/milestone" command.
The Release Team's Bug Triage Lead
and overall community watch incoming issues and triage them, as described in
the contributor guide section on
issue triage.
Marking issues with the milestone provides the community better visibility
regarding when an issue was observed and by when the community feels it must be
resolved. During Code Freeze, a milestone must be set to merge
a PR.
An open issue is no longer required for a PR, but open issues and associated
PRs should have synchronized labels. For example a high priority bug issue
might not have its associated PR merged if the PR is only marked as lower
priority.
PR Additions
PRs are marked as targeting a milestone via the Prow "/milestone" command.
This is a blocking requirement during Code Freeze as described above.
The SIG owner label defines the SIG to which we escalate if a milestone issue
is languishing or needs additional attention. If there are no updates after
escalation, the issue may be automatically removed from the milestone.
These are added with the Prow "/sig" command. For example to add the label
indicating SIG Storage is responsible, comment with /sig storage.
Priority Label
Priority labels are used to determine an escalation path before moving issues
out of the release milestone. They are also used to determine whether or not a
release should be blocked on the resolution of the issue.
priority/critical-urgent: Never automatically move out of a release
milestone; continually escalate to contributor and SIG through all available
channels.
considered a release blocking issue
requires daily updates from issue owners during Code Freeze
would require a patch release if left undiscovered until after the minor
release
priority/important-soon: Escalate to the issue owners and SIG owner; move
out of milestone after several unsuccessful escalation attempts.
not considered a release blocking issue
would not require a patch release
will automatically be moved out of the release milestone at Code Freeze
after a 4 day grace period
priority/important-longterm: Escalate to the issue owners; move out of the
milestone after 1 attempt.
even less urgent / critical than priority/important-soon
moved out of milestone more aggressively than priority/important-soon
Issue/PR Kind Label
The issue kind is used to help identify the types of changes going into the
release over time. This may allow the Release Team to develop a better
understanding of what sorts of issues we would miss with a faster release
cadence.
For release targeted issues, including pull requests, one of the following
issue kind labels must be set:
kind/api-change: Adds, removes, or changes an API
kind/bug: Fixes a newly discovered bug.
kind/cleanup: Adding tests, refactoring, fixing old bugs.
kind/design: Related to design
kind/documentation: Adds documentation
kind/failing-test: CI test case is failing consistently.
kind/feature: New functionality.
kind/flake: CI test case is showing intermittent failures.
3 - Patch Releases
Schedule and team contact information for Kubernetes patch releases.
Our typical patch release cadence is monthly. It is
commonly a bit faster (1 to 2 weeks) for the earliest patch releases
after a 1.X minor release. Critical bug fixes may cause a more
immediate release outside of the normal cadence. We also aim to not make
releases during major holiday periods.
Please give us a business day to respond - we may be in a different timezone!
In between releases the team is looking at incoming cherry pick
requests on a weekly basis. The team will get in touch with
submitters via GitHub PR, SIG channels in Slack, and direct messages
in Slack and email
if there are questions on the PR.
Cherry picks must be merge-ready in GitHub with proper labels (e.g.,
approved, lgtm, release-note) and passing CI tests ahead of the
cherry pick deadline. This is typically two days before the target
release, but may be more. Earlier PR readiness is better, as we
need time to get CI signal after merging your cherry picks ahead
of the actual release.
Cherry pick PRs which miss merge criteria will be carried over and tracked
for the next patch release.
Support Period
In accordance with the yearly support KEP, the Kubernetes
Community will support active patch release series for a period of roughly
fourteen (14) months.
The first twelve months of this timeframe will be considered the standard
period.
Towards the end of the twelve month, the following will happen:
The patch release series will enter maintenance mode
During the two-month maintenance mode period, Release Managers may cut
additional maintenance releases to resolve:
CVEs (under the advisement of the Security Response Committee)
dependency issues (including base image updates)
critical core component issues
At the end of the two-month maintenance mode period, the patch release series
will be considered EOL (end of life) and cherry picks to the associated branch
are to be closed soon afterwards.
Note that the 28th of the month was chosen for maintenance mode and EOL target
dates for simplicity (every month has it).
Upcoming Monthly Releases
Timelines may vary with the severity of bug fixes, but for easier planning we
will target the following monthly release points. Unplanned, critical
releases may also occur in between these.
Monthly Patch Release
Cherry Pick Deadline
Target date
April 2023
2023-04-07
2023-04-12
May 2023
2023-05-12
2023-05-17
June 2023
2023-06-09
2023-06-14
Detailed Release History for Active Branches
1.26
Next patch release is 1.26.4.
1.26 enters maintenance mode on and End of Life is on .
"Release Managers" is an umbrella term that encompasses the set of Kubernetes
contributors responsible for maintaining release branches and creating releases
by using the tools SIG Release provides.
The responsibilities of each role are described below.
Some information about releases is subject to embargo and we have defined policy about how those embargoes are set. Please refer to the Security Embargo Policy for more information.
Handbooks
NOTE: The Patch Release Team and Branch Manager handbooks will be de-duplicated at a later date.
Note: The documentation might refer to the Patch Release Team and the
Branch Management role. Those two roles were consolidated into the
Release Managers role.
Minimum requirements for Release Managers and Release Manager Associates are:
Familiarity with basic Unix commands and able to debug shell scripts.
Familiarity with branched source code workflows via git and associated
git command line invocations.
General knowledge of Google Cloud (Cloud Build and Cloud Storage).
To become a Release Manager, one must first serve as a Release Manager
Associate. Associates graduate to Release Manager by actively working on
releases over several cycles and:
demonstrating the willingness to lead
tag-teaming with Release Managers on patches, to eventually cut a release
independently
because releases have a limiting function, we also consider substantial
contributions to image promotion and other core Release Engineering tasks
questioning how Associates work, suggesting improvements, gathering feedback,
and driving change
being reliable and responsive
leaning into advanced work that requires Release Manager-level access and
privileges to complete
Release Manager Associates
Release Manager Associates are apprentices to the Release Managers, formerly
referred to as Release Manager shadows. They are responsible for:
Patch release work, cherry pick review
Contributing to k/release: updating dependencies and getting used to the
source codebase
Contributing to the documentation: maintaining the handbooks, ensuring that
release processes are documented
With help from a release manager: working with the Release Team during the
release cycle and cutting Kubernetes releases
Seeking opportunities to help with prioritization and communication
Sending out pre-announcements and updates about patch releases
Updating the calendar, helping with the release dates and milestones from
the release cycle timeline
Through the Buddy program, onboarding new contributors and pairing up with
them on tasks
Contributors can become Associates by demonstrating the following:
consistent participation, including 6-12 months of active release
engineering-related work
experience fulfilling a technical lead role on the Release Team during a
release cycle
this experience provides a solid baseline for understanding how SIG Release
works overall—including our expectations regarding technical skills,
communications/responsiveness, and reliability
working on k/release items that improve our interactions with Testgrid,
cleaning up libraries, etc.
these efforts require interacting and pairing with Release Managers and
Associates
Build Admins
Build Admins are (currently) Google employees with the requisite access to
Google build systems/tooling to publish deb/rpm packages on behalf of the
Kubernetes project. They are responsible for:
Building, signing, and publishing the deb/rpm packages
Being the interlock with Release Managers (and Associates) on the final steps
of each minor (1.Y) and patch (1.Y.Z) release
SIG Release Chairs and Technical Leads are responsible for:
The governance of SIG Release
Leading knowledge exchange sessions for Release Managers and Associates
Coaching on leadership and prioritization
They are mentioned explicitly here as they are owners of the various
communications channels and permissions groups (GitHub teams, GCP access) for
each role. As such, they are highly privileged community members and privy to
some private communications, which can at times relate to Kubernetes security
disclosures.
Release notes can be found by reading the Changelog that matches your Kubernetes version. View the changelog for 1.26 on GitHub.
Alternately, release notes can be searched and filtered online at: relnotes.k8s.io. View filtered release notes for 1.26 on relnotes.k8s.io.
6 - Version Skew Policy
The maximum version skew supported between various Kubernetes components.
This document describes the maximum version skew supported between various Kubernetes components.
Specific cluster deployment tools may place additional restrictions on version skew.
Supported versions
Kubernetes versions are expressed as x.y.z, where x is the major version, y is the minor version, and z is the patch version, following Semantic Versioning terminology.
For more information, see Kubernetes Release Versioning.
The Kubernetes project maintains release branches for the most recent three minor releases (1.30, 1.29, 1.28). Kubernetes 1.19 and newer receive approximately 1 year of patch support. Kubernetes 1.18 and older received approximately 9 months of patch support.
Applicable fixes, including security fixes, may be backported to those three release branches, depending on severity and feasibility.
Patch releases are cut from those branches at a regular cadence, plus additional urgent releases, when required.
other kube-apiserver instances are supported at 1.26 and 1.25
kubelet
kubelet must not be newer than kube-apiserver, and may be up to two minor versions older.
Example:
kube-apiserver is at 1.26
kubelet is supported at 1.26, 1.25, and 1.24
Note: If version skew exists between kube-apiserver instances in an HA cluster, this narrows the allowed kubelet versions.
Example:
kube-apiserver instances are at 1.26 and 1.25
kubelet is supported at 1.25, and 1.24 (1.26 is not supported because that would be newer than the kube-apiserver instance at version 1.25)
kube-controller-manager, kube-scheduler, and cloud-controller-manager
kube-controller-manager, kube-scheduler, and cloud-controller-manager must not be newer than the kube-apiserver instances they communicate with. They are expected to match the kube-apiserver minor version, but may be up to one minor version older (to allow live upgrades).
Example:
kube-apiserver is at 1.26
kube-controller-manager, kube-scheduler, and cloud-controller-manager are supported at 1.26 and 1.25
Note: If version skew exists between kube-apiserver instances in an HA cluster, and these components can communicate with any kube-apiserver instance in the cluster (for example, via a load balancer), this narrows the allowed versions of these components.
Example:
kube-apiserver instances are at 1.26 and 1.25
kube-controller-manager, kube-scheduler, and cloud-controller-manager communicate with a load balancer that can route to any kube-apiserver instance
kube-controller-manager, kube-scheduler, and cloud-controller-manager are supported at 1.25 (1.26 is not supported because that would be newer than the kube-apiserver instance at version 1.25)
kubectl
kubectl is supported within one minor version (older or newer) of kube-apiserver.
Example:
kube-apiserver is at 1.26
kubectl is supported at 1.27, 1.26, and 1.25
Note: If version skew exists between kube-apiserver instances in an HA cluster, this narrows the supported kubectl versions.
Example:
kube-apiserver instances are at 1.26 and 1.25
kubectl is supported at 1.26 and 1.25 (other versions would be more than one minor version skewed from one of the kube-apiserver components)
Supported component upgrade order
The supported version skew between components has implications on the order in which components must be upgraded.
This section describes the order in which components must be upgraded to transition an existing cluster from version 1.25 to version 1.26.
Optionally, when preparing to upgrade, the Kubernetes project recommends that
you do the following to benefit from as many regression and bug fixes as
possible during your upgrade:
Ensure that components are on the most recent patch version of your current
minor version.
Upgrade components to the most recent patch version of the target minor
version.
For example, if you're running version 1.25,
ensure that you're on the most recent patch version. Then, upgrade to the most
recent patch version of 1.26.
kube-apiserver
Pre-requisites:
In a single-instance cluster, the existing kube-apiserver instance is 1.25
In an HA cluster, all kube-apiserver instances are at 1.25 or 1.26 (this ensures maximum skew of 1 minor version between the oldest and newest kube-apiserver instance)
The kube-controller-manager, kube-scheduler, and cloud-controller-manager instances that communicate with this server are at version 1.25 (this ensures they are not newer than the existing API server version, and are within 1 minor version of the new API server version)
kubelet instances on all nodes are at version 1.25 or 1.24 (this ensures they are not newer than the existing API server version, and are within 2 minor versions of the new API server version)
Registered admission webhooks are able to handle the data the new kube-apiserver instance will send them:
ValidatingWebhookConfiguration and MutatingWebhookConfiguration objects are updated to include any new versions of REST resources added in 1.26 (or use the matchPolicy: Equivalent option available in v1.15+)
The webhooks are able to handle any new versions of REST resources that will be sent to them, and any new fields added to existing versions in 1.26
Upgrade kube-apiserver to 1.26
Note: Project policies for API deprecation and
API change guidelines
require kube-apiserver to not skip minor versions when upgrading, even in single-instance clusters.
kube-controller-manager, kube-scheduler, and cloud-controller-manager
Pre-requisites:
The kube-apiserver instances these components communicate with are at 1.26 (in HA clusters in which these control plane components can communicate with any kube-apiserver instance in the cluster, all kube-apiserver instances must be upgraded before upgrading these components)
Upgrade kube-controller-manager, kube-scheduler, and
cloud-controller-manager to 1.26. There is no
required upgrade order between kube-controller-manager, kube-scheduler, and
cloud-controller-manager. You can upgrade these components in any order, or
even simultaneously.
kubelet
Pre-requisites:
The kube-apiserver instances the kubelet communicates with are at 1.26
Optionally upgrade kubelet instances to 1.26 (or they can be left at 1.25 or 1.24)
Note: Before performing a minor version kubelet upgrade, drain pods from that node.
In-place minor version kubelet upgrades are not supported.
Warning:
Running a cluster with kubelet instances that are persistently two minor versions behind kube-apiserver is not recommended:
they must be upgraded within one minor version of kube-apiserver before the control plane can be upgraded
it increases the likelihood of running kubelet versions older than the three maintained minor releases
kube-proxy
kube-proxy must be the same minor version as kubelet on the node.
kube-proxy must not be newer than kube-apiserver.
kube-proxy must be at most two minor versions older than kube-apiserver.
Example:
If kube-proxy version is 1.24:
kubelet version must be at the same minor version as 1.24.
kube-apiserver version must be between 1.24 and 1.26, inclusive.