django/docs/internals/release-process.txt

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========================
Django's release process
========================
.. _official-releases:
Official releases
=================
Since version 1.0, Django's release numbering works as follows:
* Versions are numbered in the form ``A.B`` or ``A.B.C``.
* ``A.B`` is the *major version* number. Each version will be mostly backwards
compatible with the previous release. Exceptions to this rule will be listed
in the release notes. When ``B == 9``, the next major release will be
``A+1.0``. For example, Django 2.0 will follow Django 1.9. There won't be
anything special about "dot zero" releases.
* ``C`` is the *minor version* number, which is incremented for bug and
security fixes. A new minor release will be 100% backwards-compatible with
the previous minor release. The only exception is when a security issue
can't be fixed without breaking backwards-compatibility. If this happens,
the release notes will provide detailed upgrade instructions.
* Before a new major release, we'll make alpha, beta, and release candidate
releases. These are of the form ``A.B alpha/beta/rc N``, which means the
``Nth`` alpha/beta/release candidate of version ``A.B``.
In git, each Django release will have a tag indicating its version number,
signed with the Django release key. Additionally, each release series has its
own branch, called ``stable/A.B.x``, and bugfix/security releases will be
issued from those branches.
For more information about how the Django project issues new releases for
security purposes, please see :doc:`our security policies <security>`.
.. glossary::
Major release
Major releases (1.5, 1.6, etc.) will happen roughly every nine months -- see
`release process`_, below for details. These releases will contain new
features, improvements to existing features, and such.
.. _internal-release-deprecation-policy:
A major release may deprecate certain features from previous releases. If a
feature is deprecated in version ``A.B``, it will continue to work in versions
``A.B`` and ``A.B+1`` but raise warnings. It will be removed in version
``A.B+2``.
So, for example, if we decided to start the deprecation of a function in
Django 1.7:
* Django 1.7 will contain a backwards-compatible replica of the function which
will raise a ``RemovedInDjango19Warning``. This warning is silent by
default; you can turn on display of these warnings with the ``-Wd`` option
of Python.
* Django 1.8 will still contain the backwards-compatible replica. This
warning becomes *loud* by default, and will likely be quite annoying.
* Django 1.9 will remove the feature outright.
Minor release
Minor releases (1.5.1, 1.6.2, 1.6.1, etc.) will be issued as needed, often to
fix security issues.
These releases will be 100% compatible with the associated major release,
unless this is impossible for security reasons. So the answer to "should I
upgrade to the latest minor release?" will always be "yes."
.. _backwards-compatibility-policy:
Supported versions
==================
At any moment in time, Django's developer team will support a set of releases to
varying levels:
* The current development master will get new features and bug fixes
requiring major refactoring.
* Patches applied to the master branch must also be applied to the last major
release, to be released as the next minor release, when they fix critical
problems:
* Security issues.
* Data-loss bugs.
* Crashing bugs.
* Major functionality bugs in newly-introduced features.
The rule of thumb is that fixes will be backported to the last major release
for bugs that would have prevented a release in the first place (release
blockers).
* Security fixes will be applied to the current master, the previous two major
releases, and the current :ref:`LTS release <lts-releases>`.
* Committers may choose to backport bugfixes at their own discretion,
provided they do not introduce backwards incompatibilities.
* Documentation fixes generally will be more freely backported to the last
release branch. That's because it's highly advantageous to have the docs for
the last release be up-to-date and correct, and the risk of introducing
regressions is much less of a concern.
As a concrete example, consider a moment in time halfway between the release of
Django 1.6 and 1.7. At this point in time:
* Features will be added to development master, to be released as Django 1.7.
* Critical bug fixes will be applied to the ``stable/1.6.x`` branch, and
released as 1.6.1, 1.6.2, etc.
* Security fixes will be applied to ``master``, to the ``stable/1.6.x``
branch, and to the ``stable/1.5.x`` branch. They will trigger the release of
``1.6.1``, ``1.5.1``, etc.
* Documentation fixes will be applied to master, and, if easily backported, to
the ``1.6.x`` branch. Bugfixes may also be backported.
.. _lts-releases:
Long-term support (LTS) releases
================================
Additionally, the Django team will occasionally designate certain releases
to be "Long-term support" (LTS) releases. LTS releases will get security fixes
applied for a guaranteed period of time, typically 3+ years, regardless of
the pace of releases afterwards.
The follow releases have been designated for long-term support:
* Django 1.4, supported until at least March 2015.
.. _release-process:
Release process
===============
Django uses a time-based release schedule, with major (i.e. 1.6, 1.7, etc.)
releases every nine months, or more, depending on features.
After each release, and after a suitable cooling-off period of a few weeks, the
core development team will examine the landscape and announce a timeline for the
next release. Most releases will be scheduled in the 6-9 month range, but if we
have bigger features to development we might schedule a longer period to allow
for more ambitious work.
Release cycle
-------------
Each release cycle will be split into three periods, each lasting roughly
one-third of the cycle:
Phase one: feature proposal
~~~~~~~~~~~~~~~~~~~~~~~~~~~
The first phase of the release process will be devoted to figuring out what
features to include in the next version. This should include a good deal of
preliminary work on those features -- working code trumps grand design.
At the end of part one, the core developers will propose a feature list for the
upcoming release. This will be broken into:
* "Must-have": critical features that will delay the release if not finished
* "Maybe" features: that will be pushed to the next release if not finished
* "Not going to happen": features explicitly deferred to a later release.
Anything that hasn't got at least some work done by the end of the first third
isn't eligible for the next release; a design alone isn't sufficient.
Phase two: development
~~~~~~~~~~~~~~~~~~~~~~
The second third of the release schedule is the "heads-down" working period.
Using the roadmap produced at the end of phase one, we'll all work very hard to
get everything on it done.
Longer release schedules will likely spend more than a third of the time in this
phase.
At the end of phase two, any unfinished "maybe" features will be postponed until
the next release. Though it shouldn't happen, any "must-have" features will
extend phase two, and thus postpone the final release.
Phase two will culminate with an alpha release. At this point, the
``stable/A.B.x`` branch will be forked from ``master``.
Phase three: bugfixes
~~~~~~~~~~~~~~~~~~~~~
The last third of a release cycle is spent fixing bugs -- no new features will
be accepted during this time. We'll try to release a beta release after one
month and a release candidate after two months.
The release candidate marks the string freeze, and it happens at least two
weeks before the final release. After this point, new translatable strings
must not be added.
During this phase, committers will be more and more conservative with
backports, to avoid introducing regressions. After the release candidate, only
release blockers and documentation fixes should be backported.
In parallel to this phase, ``master`` can receive new features, to be released
in the ``A.B+1`` cycle.
Bug-fix releases
----------------
After a major release (e.g. 1.6), the previous release will go into bugfix
mode.
The branch for the previous major release (e.g. ``stable/1.5.x``) will include
bugfixes. Critical bugs fixed on master must *also* be fixed on the bugfix
branch; this means that commits need to cleanly separate bug fixes from feature
additions. The developer who commits a fix to master will be responsible for
also applying the fix to the current bugfix branch.
How this all fits together
--------------------------
Let's look at a hypothetical example for how this all first together. Imagine,
if you will, a point about halfway between 1.5 and 1.6. At this point,
development will be happening in a bunch of places:
* On master, development towards 1.6 proceeds with small additions, bugs
fixes, etc. being checked in daily.
* On the branch ``stable/1.5.x``, fixes for critical bugs found in
the 1.5 release are checked in as needed. At some point, this branch will
be released as "1.5.1", "1.5.2", etc.
* On the branch ``stable/1.4.x``, security fixes are made if
needed and released as "1.4.2", "1.4.3", etc.
* Development of major features is done in branches in forks of the main
repository. These branches will be merged into ``master`` before "1.6
alpha 1".