1329 lines
64 KiB
ReStructuredText
1329 lines
64 KiB
ReStructuredText
PEP: 605
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Title: A rolling feature release stream for CPython
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Version: $Revision$
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Last-Modified: $Date$
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Author: Steve Dower <steve.dower@python.org>, Nick Coghlan <ncoghlan@gmail.com>
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Discussions-To: https://discuss.python.org/t/pep-605-a-rolling-feature-release-stream-for-cpython/2418
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Status: Draft
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Type: Informational
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Content-Type: text/x-rst
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Created: 20-Sep-2019
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Python-Version: 3.9
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Post-History: 1-Oct-2019, 6-Oct-2019
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Abstract
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========
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Rather than proposing more frequent full CPython releases (as PEP 602 does),
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or a policy change to allow backwards compatible feature additions later in a
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release series (as PEP 598 does), this PEP instead proposes that we create a
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rolling stream of production-ready beta releases, together with alpha releases
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that are specifically designed to be suitable as platforms for building
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extension modules and wheel archives that are compatible with the subsequent
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beta releases.
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The key desired outcome of this proposal is that the usage guidance given for
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beta releases would become "suitable for production use only in environments
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with sufficiently robust compatibility testing and operational monitoring
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capabilities", rather than current unqualified "not for production use".
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Similarly, the guidance given for alpha releases would be amended to state
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"intended for library compatibility testing and the creation of ABI compatible
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binary artifacts", rather than simply saying "not for production use".
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The PEP authors believe these outcomes can be achieved by amending CPython's
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pre-release management process as described in the Proposal section below.
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This PEP also proposes that the frequency of X.Y.0 releases be adjusted to
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begin each new release series in August every two years (starting in 2021,
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around two years after the release of Python 3.8.0).
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Example Future Release Schedules
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================================
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Under this proposal, Python 3.9.0a1 would be released in December 2019, two
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months after the Python 3.8.0 baseline feature release in October 2019.
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Assuming no further breaking changes were made to the full CPython ABI, the
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3.9.0b2 release would then follow 2 months later in February 2020, continuing
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through to 3.9.0b9 in April 2021.
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Any time a breaking change to the full CPython ABI was introduced, the first
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pre-release that included it would be marked as an alpha release.
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3.9.0rc1 would be published in June 2021, 3.9.0rc2 in July 2021, and then
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the full release published as 3.9.0 in August 2021.
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The cycle would start over again in October 2021, with the publication
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of 3.10.0a1 (4 months after the creation of the 3.9.x maintenance branch).
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The exact schedule of maintenance releases would be up to the release team,
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but assuming maintenance releases of 3.9.x were also to occur every other month
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(offset from the 3.10.0 beta releases), the overall release timeline
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would look like:
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* 2019-12: 3.9.0a1
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* 2020-02: 3.9.0b2
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* ... beta (or alpha) releases every other month
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* 2021-04: 3.9.0b9
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* 2021-06: 3.9.0rc1 (feature freeze, ABI freeze, pyc format freeze)
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* 2021-07: 3.9.0rc2
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* 2021-08: 3.9.0
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* 2021-09: 3.9.1, 3.8.x (final 3.8.x binary maintenance release)
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* 2021-10: 3.10.0a1
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* 2021-11: 3.9.2
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* 2021-12: 3.10.0b2
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* ... beta (or alpha) and maintenance releases continue in alternate months
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* 2023-04: 3.10.0b10
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* 2023-05: 3.9.11
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* 2023-06: 3.10.0rc1 (feature freeze, ABI freeze, pyc format freeze)
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* 2023-07: 3.10.0rc2, 3.9.12
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* 2023-08: 3.10.0
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* 2023-09: 3.10.1, 3.9.13 (final 3.9.x binary maintenance release)
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* 2023-10: 3.11.0a1
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* 2023-12: 3.11.0b2
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* ... etc
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If we assume two additional pre-releases were made that introduced breaking
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changes to the full CPython ABI in the 3.9.0a5 and 3.9.0a7 releases, then the
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overall calendar would look like:
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.. figure:: pep-0605-example-release-calendar.png
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:align: center
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:width: 100%
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Figure 1. Impact of the pre-release process changes on the calendar.
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There are always two or three active maintenance branches in this model,
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which preserves the status quo in that respect. The major difference is that
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we would start encouraging publishers to provide pre-built binaries for the
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pre-freeze rolling releases in addition to providing them for the stable
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maintenance branches.
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.. figure:: pep-0605-overlapping-support-matrix.png
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:align: center
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:width: 50%
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Figure 2. Testing matrix in the 18-month cadence vs. the 24-month
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Package publishers targeting the full CPython ABI that choose to provide
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pre-built binaries for the rolling pre-freeze releases would at least need
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to build new wheel archives following the 3.9.0a1 release. Whether they needed
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to publish updated binaries after subsequent alpha releases (e.g. 3.9.0a5 or
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3.9.0a7 releases in the example timeline) would depend on whether or not they
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were actually affected by the ABI breaks in those later releases.
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As with the status quo, all package publishers wishing to provide pre-built
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binaries for the final release will need to build new wheel archives following
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the ABI freeze date. Unlike the status quo, this date will be clearly marked
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by the publication of the first release candidate, and it will occur early
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enough to give publishers a couple of months to get ready for the final release.
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Example Future Release Announcements
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====================================
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If this PEP is accepted, the primary channels used to communicate the updated
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pre-release management process to end users would be the Python 3.9 What's New
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document, and the release announcements themselves.
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This section provides initial drafts of text that could be used for those
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purposes.
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Suggested "What's New in Python 3.9" Entry
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------------------------------------------
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The following subsection would be added to the Python 3.9 What's New document,
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and then linked from each of the Python 3.9 alpha and beta announcements.
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PEP 605: Changes to the pre-release management process
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^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
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As detailed in PEP 605, the pre-release management process has been updated to
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produce a rolling series of beta releases that are considered suitable for
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production use in environments with sufficiently robust integration testing and
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operational monitoring capabilities.
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Under this new rolling model, the alpha and beta releases are intermingled as
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part of a combined "pre-freeze" period, with alpha releases indicating breaks
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in the full CPython ABI that may require recompilation of extension modules or
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embedding applications, and beta releases indicating full binary compatibility
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with the immediately preceding pre-release.
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Unlike previous releases, publishing pre-built binaries for 3.9.0 alpha and beta
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releases is actively encouraged, as a new pre-release ABI flag ("p") is now
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set when building and loading extension modules prior to the full CPython ABI
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freeze, ensuring that all such pre-freeze extension module builds will be
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ignored by post-freeze interpreter builds.
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The full CPython ABI will be frozen, and the pre-release flag dropped from the
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ABI flags, in 3.9.0rc1, which is expected to occur 2 months prior to the final
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3.9.0 release (refer to the release schedule in PEP 596 for exact target dates).
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For application developers, migrating to the rolling release stream provides
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the opportunity to be actively involved in the design and development of
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enhancements to the standard library and reference interpreter prior to the
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next stable release. It also provides the opportunity to benefit from
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interpreter performance enhancements up to a year or more before they become
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available in a stable release.
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For library developers that publish pre-built wheel archives, opting in to
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supporting the 3.9.x rolling release stream in addition to the 3.8 stable
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release series requires no specific action if the project is already publishing
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either pure Python wheels (tagged as ``py3-none-any``), or builds against the
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stable C ABI (tagged as ``cp38-abi3-<platform>``, or the equivalent from an
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earlier CPython 3.x release). These same wheel archives will also be usable on
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the subsequent 3.9 stable release series.
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For library developers that publish pre-built wheel archives that are built
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against the full CPython ABI, the binaries for the 3.9 stable release series
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will need to be built after the full CPython ABI freeze (i.e. using 3.9.0rc1 or
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later).
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Developers of these libraries may also opt in to supporting the rolling release
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stream by building against the 3.9.0a1 release (or a subsequent beta release)
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and publishing the result as normal.
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In the ideal case, binaries built this way will continue working all the way
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through to the last pre-freeze release. However, if the project is affected by
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a change in the full CPython C ABI during the pre-freeze period, then it will
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be necessary to publish a maintenance update that rebuilds the affected binaries
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against the alpha release that changed the relevant interface. In these cases,
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a corresponding ``Python-Requires`` entry should be added to the project
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metadata. For example, if a project is affected by an ABI change introduced in
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``3.9.0a5``, then the ``Python-Requires`` entry to add would be::
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Python-Requires: >= "3.9.0b6"; python_version == "3.9" and full_python_version != "3.9.0a5"
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(This additional metadata ensures that the updated version won't be installed on
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earlier pre-releases in the 3.9 series that offer an older variant of the ABI)
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As for application developers, library developers that choose to support the
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rolling release stream will have the opportunity to provide feedback on new and
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updated API designs *before* they're locked down for multiple years in a stable
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release (or before they're included as a provisional API in a stable release
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series).
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Example announcement text for the 3.9.0a1 release
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-------------------------------------------------
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This is the first preview release of Python 3.9. As an alpha release, it is
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intended for library and application compatibility testing and the creation of
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ABI compatible binary artifacts. It is not recommended for use in production
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environments.
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Changes to the pre-release management process
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^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
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CPython has switched to a new pre-release management process that is designed
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to produce a rolling series of beta releases that are considered suitable for
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production use in environments with sufficiently robust integration testing and
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operational monitoring capabilities. Refer to the Python 3.9 What's New
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document (hyperlinked to relevant section) for details.
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Major new features of the 3.9 series, compared to 3.8
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^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
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Many new features for Python 3.9 are still being planned and written. Among the
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major new features and changes already implemented:
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* ...
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* (Hey, fellow core developer or user of the rolling release stream, if a
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feature you find important is missing from this list, let <the release
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manager> know.)
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The next pre-release of Python 3.9 is expected to be 3.8.0b2, currently scheduled for 2020-02-02.
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Example announcement text for the 3.9.0b2 release
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-------------------------------------------------
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This is the second preview release of Python 3.9. As a beta release, it is
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fully binary compatible with the preceding 3.9.0a1 release. It is recommended
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for production use only in environments with sufficiently robust integration
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testing and operational monitoring capabilities.
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(Remainder as per 3.9.0a1 announcement, with updates for implemented changes
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and the next expected release being 3.9.0b3)
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Example announcement text for 3.9.0a5 (a mid-stream alpha release)
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------------------------------------------------------------------
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This is the fifth preview release of Python 3.9. As an alpha release, it is
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NOT fully binary compatible with the preceding 3.9.0b4 release. This release is
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intended for library and application compatibility testing and the creation of
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ABI compatible binary artifacts. It is not recommended for use in production
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environments.
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Breaking changes in the full CPython ABI between 3.9.0b4 and 3.9.0a5
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^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
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* new field ``ob_example`` added to the ``PyObject`` struct
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* provisional field ``tp_example`` removed from the ``PyTypeObject`` struct
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Projects that are supporting the rolling release stream and require a rebuild
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to restore binary compatibility should add the following metadata to their
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updated release::
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Python-Requires: >= "3.9.0b6"; python_version == "3.9" and full_python_version != "3.9.0a5"
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(Remainder as per 3.9.0a1 announcement, with updates for implemented changes
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and the next expected release being 3.9.0b6)
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Example announcement text for 3.9.0rc1
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--------------------------------------
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This is the first release candidate for Python 3.9. As a release candidate,
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this release is now feature complete, the full CPython ABI is now frozen, and
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the pre-release marker has been removed from the ABI compatibility flags. It is
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recommended for production use only in environments with sufficiently robust
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integration testing and operational monitoring capabilities.
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Preparation for the final 3.9.0 release
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^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
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With the full CPython ABI now frozen, library developers targeting that ABI are
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encouraged to build and publish binaries for the stable 3.9.x series.
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Application developers that have not been testing against the rolling release
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stream are encouraged to test their applications against the release candidate
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and report any compatibility regressions not already mentioned in the Porting
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Guide (hyperlinked to relevant What's New section).
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A second release candidate is planned for 2021-07-02, and then the final 3.9.0
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release is planned for 2021-08-02.
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Major new features of the 3.9 series, compared to 3.8
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^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
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Some of the major new features and changes in this release:
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* ...
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* (Hey, fellow core developer or user of the rolling release stream, if a
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feature you find important is missing from this list, let <the release
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manager> know.)
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Motivation
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==========
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The current CPython pre-release and release management processes were developed
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in an era where automated continuous integration and operational monitoring
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systems were still relatively immature. Since that time, many organisations
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have adopted deployment models that allow them to incorporate new CPython
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feature releases without adding substantially more risk than they incur for any
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other code change. Newer deployment models, such as lightweight task specific
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application containers, also make it easier to combine an application with a
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language runtime in a CI pipeline, and then keep them together until the entire
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container image is later replaced by an updated one.
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In light of those changes in the wider environment, PEP 602 has proposed
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reducing the feature delivery latency for the Python standard library and
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CPython reference interpreter by increasing the frequency of CPython feature
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releases from every 18-24 months to instead occur every 12 months.
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Unfortunately, for many organisations, the cost of adopting a new Python release
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doesn't automatically scale down with a reduced number of changes in the release,
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as the primary costs aren't associated with resolving any discovered issues;
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the primary costs are associated with the *search* for issues. This search may
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involve manual testing of software systems, human review of written materials,
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and other activities where the time required scales with the size of the
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existing system, rather than with the number of changes between the versions of
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Python.
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For third party library developers, costs are primarily associated with the
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*number* of distinct Python versions in widespread usage. This currently tends
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to be influenced by a combination of which releases are still actively
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maintained by python-dev, and which releases are the latest versions offered
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by particular redistributors (with the Debian, Ubuntu LTS, and RHEL/CentOS
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system Python versions being particularly popular development targets). In
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addition to the basic CI cost of testing against more Python versions, having
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more variants in widespread use can make it more difficult to determine when a
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fault report is an actual error in the project, or an issue in the reporting
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user's environment.
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PEP 602 proposes that affected organisations and projects simply switch to
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adopting every second or third CPython release, rather than attempting to adopt
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every release, but that creates its own set of new problems to be resolved, both
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practical (e.g. deprecations would need to cover more than one release if we're
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expecting users to routinely skip releases) and cultural (e.g. with a larger
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number of versions in active use, there is a much higher chance that open source
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library maintainers will receive bug reports that only occur on Python versions
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that they're not using themselves).
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PEP 598 was an initial attempt by one of the authors of this PEP to propose
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an alternative scheme to reduce feature delivery latency by adopting a
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semantic versioning style policy that allowed for the incremental delivery of
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backwards compatible features within a release series, until that series
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reached feature complete status. That variant still had the undesirable
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consequence of imposing visible changes on end users that are happy enough
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with the current release management model.
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This PEP takes the view that both PEP 598 and PEP 602 share a common flaw: they
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are attempting to satisfy the needs of two quite distinct audiences within the
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constraints of a single release model, which results in conflicting design
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requirements, and the need for awkward trade-offs between those conflicting
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requirements. The proposal in this PEP aims to avoid that flaw by proposing the
|
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creation of two *distinct* production-ready release streams, with the existing
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release stream being largely left alone, while the new release stream is
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tailored towards the audience that would most benefit from a reduction in
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feature delivery latency.
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Aims of this Proposal
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=====================
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The core of the proposal in this PEP is changing the CPython pre-release process
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to produce a rolling stream of incremental feature releases at a regular
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cadence, and to ensure that most of those builds offer a sufficient level of
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stability as to be suitable for use in appropriately managed production systems.
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By adopting this approach, the proposal aims to provide an improved outcome
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||
for almost all Python users and contributors:
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* for users of the new incremental feature release stream, targeting the
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pre-release phase allows for even lower feature delivery latency than the
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annual cadence proposed in PEP 602;
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||
* for core developers working on new features, increased frequency and adoption
|
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of pre-releases should improve pre-release feedback cycles;
|
||
* for users of the established release stream, the increased adoption and
|
||
improved feedback cycles during the pre-release period should result in
|
||
increased feature maturity at the time of its first X.Y.0 release, as well
|
||
as higher levels of ecosystem readiness;
|
||
* for Python library maintainers, the rolling stream of pre-releases will
|
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hopefully provide more opportunities to identify and resolve design issues
|
||
before they make it into a full stable release than is offered by the current
|
||
pre-release management process; and
|
||
* for developers of alternative Python implementations, the rolling stream of
|
||
pre-releases may provide an additional incentive for extension module authors
|
||
to migrate from the full CPython ABI to the Python stable ABI, which would
|
||
also serve to make more of the ecosystem compatible with implementations that
|
||
don't emulate the full CPython C API.
|
||
|
||
That said, it is acknowledged that not all the outcomes of this proposal will be
|
||
beneficial for all members of the wider Python ecosystem:
|
||
|
||
* for Python library maintainers, both this PEP and PEP 602 would likely
|
||
result in user pressure to support the faster release cadence. While this PEP
|
||
attempts to mitigate that by clearly marking which pre-releases include
|
||
potentially breaking changes to the full CPython C ABI, and PEP 602 attempts
|
||
to mitigate it by keeping the minimum time between full releases at
|
||
12 months, it isn't possible to eliminate this downside completely;
|
||
* for third party extension module maintainers, both this PEP and PEP 602 would
|
||
likely result in user pressure to start supporting the stable ABI in order to
|
||
provide wheel archives that work on the new version as soon as it is
|
||
available. Whether that's a net negative or not will depend on how the request
|
||
is presented to them (it could be a positive if the request comes in the form
|
||
of a courteous contribution to their project from a developer interested in
|
||
supporting the rolling pre-freeze releases);
|
||
* for some users of the established release stream that rely on the
|
||
availability of pre-built wheel archives, switching to adopting a new release
|
||
every 12 months may be an acceptable rate increase, while moving consistently
|
||
to the 24 month end of the historical 18-24 month cadence would be an
|
||
undesirable rate reduction relative to the 18 month cycle used for recent
|
||
releases. Whether this proposal would be a net negative for these users will
|
||
depend on whether or not we're able to persuade library maintainers that
|
||
it's worth their while to support the upcoming stable release throughout its
|
||
pre-freeze period, rather than waiting until its API and ABI have been
|
||
frozen.
|
||
|
||
|
||
Proposal
|
||
========
|
||
|
||
The majority of the proposed changes in this PEP only affect the handling of
|
||
pre-release versions. The one change affecting full release versions is a
|
||
suggested change to their cadence.
|
||
|
||
|
||
Two year cadence for stable releases
|
||
------------------------------------
|
||
|
||
With the rolling pre-freeze releases available to users that are looking to
|
||
use leading edge versions of the reference interpreter and standard library,
|
||
this PEP proposes that the frequency of X.Y.0 releases be adjusted to publish
|
||
a new stable release in August every two years (starting in 2021,
|
||
around two years after the release of Python 3.8.0).
|
||
|
||
This change is arguably orthogonal to the proposed changes to the handling of
|
||
the pre-freeze release period, but the connection is that without those
|
||
pre-release management changes, the downsides of a two year full release cadence
|
||
would probably outweigh the upsides, whereas the opposite is true for a 12
|
||
month release cadence (i.e. with the pre-release management changes proposed
|
||
in this PEP in place, the downsides of a 12 month full release cadence would
|
||
outweigh the upsides).
|
||
|
||
|
||
Merging of the alpha and beta phases into a "pre-freeze" phase
|
||
--------------------------------------------------------------
|
||
|
||
Rather than continuing the status quo where the pre-release alpha and beta
|
||
phases are distinct and sequential, this PEP proposes that they instead be
|
||
combined into a single "pre-freeze" phase with a monotonically increasing serial
|
||
number on the releases.
|
||
|
||
Rather than denoting distinct phases, the "alpha" and "beta" names would
|
||
instead indicate whether or not the release contains breaking changes to the
|
||
full CPython C ABI:
|
||
|
||
* "alpha" releases would be "ABI breaking" releases where extension modules
|
||
built against the full CPython ABI in the preceding pre-release are not
|
||
necessarily going to load correctly
|
||
* "beta" releases would be "binary compatible" releases, where extension modules
|
||
built against the full CPython ABI in the preceding pre-release are expected
|
||
to load correctly, as long as those modules abide by the following additional
|
||
criteria:
|
||
|
||
* the module must not be using any provisional or private C APIs (either from
|
||
the previous stable release series, or the in development pre-release series)
|
||
that were removed in this beta release, or were changed in an ABI incompatible
|
||
way
|
||
* the module must not be using any C APIs that were deprecated in the previous
|
||
stable release series, and removed in this beta release
|
||
|
||
Pre-freeze phase duration and cadence
|
||
^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
|
||
|
||
Rather than being released monthly for a period of a few months while preparing
|
||
a new X.Y.0 release, pre-freeze releases would instead be consistently published
|
||
every two months.
|
||
|
||
The only time this would not be the case is during the two month release
|
||
candidate period for an upcoming X.Y.0 release (see the release candidate
|
||
section below for more details). This means two otherwise scheduled releases
|
||
would be skipped (one corresponding with the first release candidate date, one
|
||
with the final release date).
|
||
|
||
The pre-freeze phase would typically be expected to start 2 months after the
|
||
preceding stable X.Y.0 release.
|
||
|
||
The first pre-freeze release for any new release series will always be X.Y.0a1
|
||
(as there is no preceding release with the same ABI version markers to judge
|
||
binary compatibility against).
|
||
|
||
Pre-freeze releases would gain an additional flag in their C ABI compatibility
|
||
markers to avoid binary compatibility issues with the eventual stable release.
|
||
|
||
|
||
Release policy for beta releases
|
||
^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
|
||
|
||
This PEP proposes that the policy for beta releases be set as follows:
|
||
|
||
* as with current beta releases, the stable BuildBot fleet is expected to be
|
||
green prior to preparation and publication of the beta release
|
||
* as with current beta releases, the release manager is expected to review
|
||
open release blocker issues prior to preparation and publication of the beta
|
||
release
|
||
* as with current beta releases, any additions to the `abi3` stable C ABI would
|
||
be expected to become a permanent part of that ABI unless and until that
|
||
stable ABI version is retired completely (Note: there are no current plans
|
||
to increment the stable ABI version)
|
||
* unlike current beta releases, beta releases under this PEP would *not* be
|
||
considered feature complete for the next X.Y.0 release
|
||
* unlike current beta releases, all APIs added since the last CPython feature
|
||
release (other than additions to the stable C ABI) would be considered
|
||
provisional
|
||
* unlike current beta releases, beta releases under this PEP would be prepared
|
||
and published from the master development branch
|
||
* unlike current alpha or beta releases, beta releases under this PEP would be
|
||
required to be fully ABI compatible with the immediately preceding pre-release
|
||
in the series (excluding any changes to provisional APIs, or the removal of
|
||
APIs that were deprecated in the previous release series)
|
||
|
||
|
||
Release policy for alpha releases
|
||
^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
|
||
|
||
This PEP proposes that the policy for alpha releases be set as follows:
|
||
|
||
* as with current alpha releases, the stable BuildBot fleet is expected to be
|
||
green prior to preparation and publication of the alpha release
|
||
* as with current alpha releases, the release manager is expected to review
|
||
open release blocker issues prior to preparation and publication of the beta
|
||
release
|
||
* unlike current alpha release, the release manager would be expected to
|
||
target a similar level of stability to the current beta releases, even
|
||
for the alpha releases
|
||
|
||
Under this PEP, an alpha release would be published whenever it isn't possible
|
||
to publish a release that satisfies the criteria for a beta release, and
|
||
allowing some additional time before making the release won't resolve the issue.
|
||
|
||
It is expected that the full CPython API changing in a way that breaks ABI
|
||
compatibility (for example, a field may have been added to or removed from a
|
||
public struct definition) will be the most likely reason for publishing
|
||
additional alpha releases beyond the initial compatibility tag defining
|
||
X.Y.0a1 release, but the decision for any particular release rests with the
|
||
release manager.
|
||
|
||
|
||
Release candidate policy, phase duration, and cadence
|
||
-----------------------------------------------------
|
||
|
||
Given the proposed changes to the alpha and beta release phases, the release
|
||
candidate phase would see the following related adjustments:
|
||
|
||
* Feature freeze, ABI freeze, pyc file format freeze, and maintenance branch
|
||
creation would all correspond with the creation of X.Y.0rc1 (currently these
|
||
occur across a mixture of X.Y.0b1, the last beta release, and X.Y.0rc1)
|
||
* The X.Y.0 release candidate period would be extended from 3 weeks to 2 months
|
||
* There would normally be two release candidates issued a month apart, but
|
||
additional candidates may be published at the release manager's discretion
|
||
* The final X.Y.0 release would occur between 1 and 4 weeks after the final
|
||
release candidate (depending if additional release candidates were needed
|
||
after the second)
|
||
* If the final X.Y.0 release is delayed beyond the August target date, the
|
||
subsequent release series is not affected, and will still be scheduled for
|
||
August (now slightly less than two years later).
|
||
|
||
In addition to allowing more time for end user feedback on the release
|
||
candidate, this adjusted policy also provides additional time for maintainers
|
||
of Python projects to build and publish pre-built wheel archives for the new
|
||
stable release series, significantly improving the initial user experience of
|
||
the X.Y.0 release.
|
||
|
||
Changes to management of the CPython stable C ABI
|
||
-------------------------------------------------
|
||
|
||
The CPython stable ABI [5_] makes the commitment that binary extension modules
|
||
built against any particular CPython release will continue to work on future
|
||
CPython releases that support the same stable ABI version (this version is
|
||
currently ``abi3``).
|
||
|
||
Under the proposed rolling pre-freeze release model, this commitment would be
|
||
extended to also apply to the beta releases: once an intentional addition to the
|
||
``abi3`` stable ABI for the upcoming Python version has been shipped in a beta
|
||
release, then it will not be removed from future releases for as long as the
|
||
``abi3`` stable ABI remains supported.
|
||
|
||
Two main mechanisms will be available for obtaining community feedback on
|
||
additions to the stable ABI:
|
||
|
||
* the preferred mechanism will be to add new APIs to the full CPython API first,
|
||
and only promote them to the stable ABI after they have been included in at
|
||
least one published beta release and received relevant user feedback
|
||
* for APIs where that approach is unavailable for some reason (e.g. some API
|
||
additions may serve no useful purpose when the full CPython API is available),
|
||
then developers may request that the release manager mark the next release
|
||
as an alpha release (even in the absence of an ABI break in the full CPython
|
||
API), and attempt to obtain further feedback that way
|
||
|
||
As a slight readability and usability improvement, this PEP also proposes the
|
||
introduction of aliases for each major stable ABI version::
|
||
|
||
#define Py_LIMITED_API_3_3 0x03030000
|
||
#define Py_LIMITED_API_3_4 0x03040000
|
||
#define Py_LIMITED_API_3_5 0x03050000
|
||
#define Py_LIMITED_API_3_6 0x03060000
|
||
#define Py_LIMITED_API_3_7 0x03070000
|
||
#define Py_LIMITED_API_3_8 0x03080000
|
||
#define Py_LIMITED_API_3_9 0x03090000
|
||
// etc...
|
||
|
||
These would be used both in extension module code to set the target ABI
|
||
version::
|
||
|
||
#define Py_LIMITED_API Py_LIMITED_API_3_8
|
||
|
||
And also in the CPython interpreter implementation to check which symbols should
|
||
be made available::
|
||
|
||
#if !defined(Py_LIMITED_API) || Py_LIMITED_API+0 >= Py_LIMITED_API_3_9
|
||
// A Python 3.9+ addition to the stable ABI would appear here
|
||
#endif
|
||
|
||
The documentation for the rolling pre-freeze releases and the stable C ABI would
|
||
make it clear that extension modules built against the stable ABI in a later
|
||
pre-freeze release may not load correctly on an earlier pre-freeze release.
|
||
|
||
The documentation for alpha releases and the stable C ABI would make it clear
|
||
that even extension modules built against the stable ABI in an alpha release
|
||
release may not load correctly on the next release if two alpha releases are
|
||
published in a row (this situation would ideally be rare).
|
||
|
||
|
||
Changes to management of the full CPython ABI
|
||
---------------------------------------------
|
||
|
||
This PEP proposes two changes to the management of the full CPython ABI.
|
||
|
||
An explicit commit and NEWS file convention to mark ABI breaking changes
|
||
^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
|
||
|
||
The proposal in this PEP requires that release managers be able to appropriately
|
||
mark a pre-freeze release as either an alpha or a beta release based on whether
|
||
or not it includes an ABI breaking change.
|
||
|
||
To assist in that process, core developers would be requested to include a
|
||
"(CPython ABI break)" marker at the beginning of all NEWS file snippets for
|
||
changes that introduce a breaking change in the full CPython C ABI.
|
||
|
||
The "CPython" marker is included to make it clear that these annotations relate
|
||
to the full CPython ABI, not the stable ABI.
|
||
|
||
For commit messages, the shorter marker "(ABI break)" would be placed at the
|
||
start of the summary line for the commit.
|
||
|
||
The pre-merge bots will be updated to ensure that if the ABI break marker
|
||
appears in one of the two locations, it appears in both of them.
|
||
|
||
If the marker is inadvertently omitted from the initial commit message and NEWS
|
||
entry, then the commit message marker should be included in the subsequent
|
||
commit that adds the marker to the NEWS entry.
|
||
|
||
In addition to being useful for release managers, these markers should also be
|
||
useful for developers investigating unexpected segfaults when testing against
|
||
the affected release.
|
||
|
||
|
||
Explicitly marking builds against the pre-freeze ABI
|
||
^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
|
||
|
||
The full CPython ABI has long operated under a policy where binary
|
||
compatibility only applies within a release series after the ABI has been
|
||
declared frozen, and only source compatibility applies between different
|
||
release series.
|
||
|
||
This policy means that extension modules built against CPython pre-releases
|
||
prior to the ABI freeze for that release series may not actually load correctly
|
||
on the final release.
|
||
|
||
This is due to the fact that the extension module may be relying on provisional
|
||
or previously deprecated interfaces that were changed or removed in a later
|
||
alpha or beta release, or it may be due to public structures used by the
|
||
extension module changing size due to the addition of new fields.
|
||
|
||
Historically, adoption of alpha and beta releases has been low enough that this
|
||
hasn't really been a problem in practice. However, this PEP proposes to actively
|
||
encourage widespread operational use of beta releases, which makes it desirable
|
||
to ensure that users of those releases won't inadvertently publish binary
|
||
extension modules that cause segfaults for users running the release candidates
|
||
and final releases.
|
||
|
||
To that end, this PEP proposes amending the extension module ``SOABI`` marker
|
||
on non-Windows systems to include a new "p" flag for CPython pre-releases, and
|
||
only switch back to omitting that flag once the ABI for that particular X.Y.0
|
||
version has been frozen on entry to the release candidate stage.
|
||
|
||
With this change, alpha and beta releases of 3.9.0 would get an SOABI tag of
|
||
``cpython-39p``, while all release candidates and final builds (for both 3.9.0
|
||
and later 3.9.x releases) would get an unqualified SOABI tag of ``cpython-39``
|
||
|
||
Debug builds would still add the "d" to the end of the tag, giving
|
||
``cpython-39pd`` for debug builds of pre-releases.
|
||
|
||
On Windows systems, the suffix for tagged ``pyd`` files in pre-release builds
|
||
would include "p" as a pre-release marker immediately after the version number,
|
||
giving markers like "cp39p-win_amd64".
|
||
|
||
A proposed reference implementation for this change is available at [4_] (Note:
|
||
at time of writing, that implementation had not yet been tested on Windows).
|
||
|
||
|
||
Updating Python-Requires for projects affected by full C ABI changes
|
||
--------------------------------------------------------------------
|
||
|
||
When a project first opts in to providing pre-built binary wheels for the
|
||
rolling pre-freeze release series, they don't need to do anything special: they
|
||
would add the rolling release series to their build and test matrices and
|
||
publish binary archives that are flagged as being compatible with that release
|
||
series, just as they would if providing pre-built binary wheels after the
|
||
full CPython ABI freeze for that release series.
|
||
|
||
However, if the project is affected by a CPython ABI compatibility break in the
|
||
rolling release stream, then they will need to issue a version update that
|
||
includes both the new binary build, and a new environment constrained
|
||
``Python-Requires`` marker.
|
||
|
||
For example, if a project supporting the rolling release stream was affected by
|
||
a CPython ABI compatibility break in the 3.9.0a5 release, then they would add
|
||
the following metadata entry on the version that published the updated binary
|
||
build::
|
||
|
||
Python-Requires: >= "3.9.0b6"; python_version == "3.9" and full_python_version != "3.9.0a5"
|
||
|
||
What this does is add an additional compatibility constraint as part of the
|
||
published packages, so Python 3.9.0 beta versions prior to 3.9.0b6 won't
|
||
consider the updated package as a candidate for installation, and the only
|
||
alpha release that will consider the package is 3.9.0a5 itself.
|
||
|
||
|
||
Caveats and Limitations
|
||
=======================
|
||
|
||
Actual release dates may be scheduled up to a month earlier or later at
|
||
the discretion of the release manager, based on release team availability, and
|
||
the timing of other events (e.g. PyCon US, or the annual core developer
|
||
sprints). However, as one goal of the proposal is to provide a consistent
|
||
release cadence, adjustments should ideally be rare.
|
||
|
||
Within a release series, the exact frequency of maintenance releases would
|
||
still be up to the release manager and the binary release team; this PEP
|
||
only proposes an expected cadence for pre-releases and X.Y.0 releases.
|
||
|
||
However, for the sake of the example timelines, the PEP assumes maintenance
|
||
releases every other month, allowing them to alternate months with the rolling
|
||
pre-freeze releases.
|
||
|
||
|
||
Design Discussion
|
||
=================
|
||
|
||
Why rolling pre-freeze releases over simply doing more frequent X.Y.0 releases?
|
||
-------------------------------------------------------------------------------
|
||
|
||
For large parts of Python's user base, *availability* of new CPython feature
|
||
releases isn't the limiting factor on their adoption of those new releases
|
||
(this effect is visible in such metrics as PyPI download metadata).
|
||
|
||
As such, any proposal based on speeding up full feature releases needs to strike
|
||
a balance between meeting the needs of users who would be adopting each release
|
||
as it became available, and those that would now be in a position of adopting
|
||
every 2nd, 3rd, or 4th release, rather than being able to migrate to almost
|
||
every release at some point within its lifecycle.
|
||
|
||
This proposal aims to approach the problem from a different angle by defining a
|
||
*new* production-ready release stream that is more specifically tailored to the
|
||
interests of operating environments that are able to consume new releases as
|
||
fast as the CPython core team is prepared to produce them.
|
||
|
||
|
||
Is it necessary to keep the "alpha" and "beta" naming scheme?
|
||
-------------------------------------------------------------
|
||
|
||
Using the "a" and "b" initials for the proposed rolling releases is a design
|
||
constraint imposed by some of the pragmatic aspects of the way CPython version
|
||
numbers are published.
|
||
|
||
Specifically, alpha releases, beta releases, and release candidates are reported
|
||
in some places using the strings "a", "b", and "c" respectively, while in others
|
||
they're reported using the hex digits ``0xA``, ``0xB``, and ``0xC``. We want to
|
||
preserve that, while also ensuring that any ``Python-Requires`` constraints
|
||
are expressed against the beta releases rather than the alpha releases (since
|
||
the latter may not enforce the ``abi3`` stability requirements if two alpha
|
||
releases occur in succession).
|
||
|
||
However, there isn't anything forcing us to say that the "a" stands for "alpha"
|
||
or the "b" stands for "beta".
|
||
|
||
That means that if we wanted to increase adoption amongst folks that were
|
||
only being put off by the "beta" label, then it may make sense to emphasise
|
||
the "\*A\*BI breaking" and "\*B\*inary compatible" names over the "alpha"
|
||
and "beta" names, giving:
|
||
|
||
* 3.9.0a1: ABI breaking pre-freeze release
|
||
* 3.9.0b2: binary compatible pre-freeze release
|
||
* 3.9.0rc1: release candidate
|
||
* 3.9.0: final release
|
||
|
||
This iteration of the PEP doesn't go that far, as limiting initial adoption
|
||
of the rolling pre-freeze releases to folks that are comfortable with the
|
||
"beta" label is likely to be a good thing, as it is the early adopters of these
|
||
releases that are going to encounter any unexpected consequences that occur
|
||
at the level of the wider Python ecosystem, and we're going to need them to
|
||
be willing to take an active part in getting those issues resolved.
|
||
|
||
Moving away from the "beta" naming would then become an option to keep in mind
|
||
for the future, assuming the resulting experience is sufficiently positive that
|
||
we decide the approach is worth continuing.
|
||
|
||
|
||
Why rolling pre-freeze releases rather than alternating between stable and unstable release series?
|
||
---------------------------------------------------------------------------------------------------
|
||
|
||
Rather than using the beta period for rolling releases, another option would be
|
||
to alternate between traditional stable releases (for 3.8.x, 3.10.x, etc), and
|
||
release series that used the new rolling release cadence (for 3.9.x, 3.11.x,
|
||
etc).
|
||
|
||
This idea suffers from the same core problem as PEP 598 and PEP 602: it imposes
|
||
changes on end users that are happy with the status quo without offering them
|
||
any clear compensating benefit.
|
||
|
||
It's also affected by one of the main concerns raised against PEP 598: at least
|
||
some core developers and end users strongly prefer that no particular semantics
|
||
be assigned to the *value* of any of the numbers in a release version. These
|
||
community members instead prefer that all the semantic significance be
|
||
associated with the *position* within the release number that is changing.
|
||
|
||
By contrast, the rolling pre-freeze release proposal aims to address that concern by
|
||
ensuring that the proposed changes in policy all revolve around whether a
|
||
particular release is an alpha release, beta release, release candidate, or
|
||
final release.
|
||
|
||
|
||
Why not use Calendar Versioning for the rolling release stream?
|
||
---------------------------------------------------------------
|
||
|
||
Steve Dower's initial write-up of this proposal [1_] suggested the use of
|
||
calendar versioning for the rolling release stream (so the first rolling
|
||
pre-release after Python 3.8.0 would have been Python 2019.12 rather than
|
||
3.9.0b1).
|
||
|
||
Paul Moore pointed out [2_] two major practical problems with that proposal:
|
||
|
||
* it isn't going to be clear to users of the calendar-based versions where they
|
||
stand in relation to the traditionally numbered versions
|
||
* it breaks ``Python-Requires`` metadata processing in packaging tools with
|
||
no clear way of fixing it reliably (since all calendar versions would appear
|
||
as newer than any standard version)
|
||
|
||
This PEP aims to address both of those problems by using the established beta
|
||
version numbers for the rolling releases.
|
||
|
||
As an example, consider the following question: "Does Python 2021.12 include
|
||
all the new features released in Python 3.9.0?". With calendar versioning on
|
||
the rolling releases, that's impossible to answer without consulting a release
|
||
calendar to see when 3.9.0rc1 was branched off from the rolling release series.
|
||
|
||
By contrast, the equivalent question for rolling pre-freeze releases is
|
||
straightforward to answer: "Does Python 3.10.0b2 include all the new features
|
||
released in Python 3.9.0?". Just from formulating the question, the answer is
|
||
clearly "Yes, unless they were provisional features that got removed".
|
||
|
||
The beta numbering approach also avoids other questions raised by the calendar
|
||
versioning concept, such as how ``sys.version_info``, ``PY_VERSION_HEX``,
|
||
``site-packages`` directory naming, and installed Python binary and extension
|
||
module naming would work.
|
||
|
||
|
||
How would users of the rolling pre-freeze releases detect API changes?
|
||
----------------------------------------------------------------------
|
||
|
||
When adding new features, core developers would be strongly encouraged to
|
||
support feature detection and graceful fallback to alternative approaches via
|
||
mechanisms that don't rely on either ``sys.version_info`` or runtime code object
|
||
introspection.
|
||
|
||
In most cases, a simple ``hasattr`` check on the affected module will serve this
|
||
purpose, but when it doesn't, alternative approaches would be considered as part
|
||
of the feature addition. Prior art in this area includes the
|
||
``pickle.HIGHEST_PROTOCOL`` attribute, the ``hashlib.algorithms_available`` set,
|
||
and the various ``os.supports_*`` sets that the ``os`` module already offers for
|
||
platform dependent capability detection.
|
||
|
||
It would also be possible to add features that need to be explicitly enabled
|
||
via a ``__future__`` import when first included in the rolling pre-freeze releases,
|
||
even if that feature flag was subsequently enabled by default before its first
|
||
appearance in an X.Y.0 release candidate.
|
||
|
||
The rationale behind these approaches is that explicit detection/enabling like
|
||
this would make it straightforward for users of the rolling pre-freeze release
|
||
stream to notice when we remove or change provisional features
|
||
(e.g. ``from __future__`` imports break on compile if the feature flag no
|
||
longer exists), or to safely fall back on previous functionality.
|
||
|
||
The interpreter's rich attribute lookup machinery means we can also choose to
|
||
add warnings for provisional or deprecated imports and attributes that we don't
|
||
have any practical way to add for checks against the value of
|
||
``sys.version_info``.
|
||
|
||
|
||
Why add a new pre-freeze ABI flag to force rebuilds after X.Y.0rc1?
|
||
-------------------------------------------------------------------
|
||
|
||
The core development team currently actively *discourage* the creation of
|
||
public pre-built binaries for an X.Y series prior to the ABI freeze date.
|
||
|
||
The reason we do that is to avoid the risk of painful debugging sessions
|
||
on the stable X.Y.0 release that get traced back to "Oh, our dependency
|
||
'superfast-binary-operation' was affected by a CPython ABI break in
|
||
X.Y.0a3, but the project hasn't published a new build since then".
|
||
|
||
With the proposed pre-freeze ABI flag in place, this aspect of the
|
||
release adoption process continues on essentially unchanged from the
|
||
status quo: a new CPython X.Y release series hits ABI freeze -> package
|
||
maintainers publish new binary extension modules for that release
|
||
series -> end users only get segfaults due to actual bugs, not just
|
||
builds against an incompatible ABI.
|
||
|
||
The primary goal of the new pre-freeze ABI flag is then to improve
|
||
the user experience of the rolling pre-freeze releases themselves, by
|
||
allowing pre-built binary archives to be published for those releases
|
||
without risking the problems that currently cause us to actively
|
||
discourage the publication of binary artifacts prior to ABI freeze.
|
||
|
||
In the ideal case, package maintainers will only need to publish
|
||
one pre-freeze binary build at X.Y.0a1, and then a post-freeze
|
||
build after X.Y.0rc1. The only situations that should *require*
|
||
a rebuild in the meantime are those where the project was
|
||
actually affected by a CPython ABI break in an intervening alpha
|
||
release.
|
||
|
||
As a concrete example, consider the scenario where we end up having three
|
||
releases that include ABI breaks: X.Y.0a1, X.Y.0a5, X.Y.0a7. The X.Y.0a7 ABI is
|
||
then the ABI that carries through all the subsequent beta releases and into
|
||
X.Y.0rc1. (This is the scenario illustrated in figure 1)
|
||
|
||
Forcing everyone to rebuild the world every time there’s an alpha release in
|
||
the rolling release stream would almost certainly lead to publishers deciding
|
||
supporting the rolling releases was more trouble than it was worth, so we want
|
||
to allow modules built against X.Y.0a1 to be loaded against X.Y.0a7, as they’re
|
||
*probably* going to be compatible (there are very few projects that use every
|
||
C API that CPython publishes, and most ABI breaks affect a single specific API).
|
||
|
||
Once we publish X.Y.0rc1 though, we want to ensure that any binaries that were
|
||
built against X.Y.0a1 and X.Y.0a4 are completely removed from the end user
|
||
experience. It would be nice to be able to keep the builds against X.Y.0a7 and
|
||
any subsequent beta releases (since it turned out those actually were built
|
||
against the post-freeze ABI, even if we didn’t know that at the time), but
|
||
losing them isn’t any *worse* than the status quo.
|
||
|
||
This means that the pre-freeze flag is “the simplest thing that could possibly
|
||
work” to solve this problem - it’s just a new ABI flag, and we already have
|
||
the tools available to deal with ABI flags (both in the interpreter and in
|
||
package publication and installation tools).
|
||
|
||
Since the ABI flags have changed relative to the pre-releases, projects don't
|
||
even need to publish a new release: they can upload new wheel archives to their
|
||
existing releases, just as they can today.
|
||
|
||
A cleverer scheme that was able to retroactively accept everything built
|
||
against the last alpha or subsequent beta releases would likely be possible,
|
||
but it isn't considered *necessary* for adoption of this PEP, as even if we
|
||
initially start out with a simple pre-release ABI flag, it would still be
|
||
possible to devise a more sophisticated approach in the future.
|
||
|
||
|
||
Why allow additional alpha releases after X.Y.0a1?
|
||
--------------------------------------------------
|
||
|
||
In an ideal world, all breaking changes to the full CPython ABI would land in
|
||
X.Y.0a1 alongside the filesystem layout changes, and the ABI for the release
|
||
series would remain stable after that.
|
||
|
||
However, recent history doesn't suggest that we'd be able to actually make that
|
||
commitment and stick to it, so the PEP assumes that ABI changes will be made
|
||
progressively throughout the pre-freeze period, and the full lockdown will occur
|
||
only with the creation of the X.Y.z maintenance branch when preparing X.Y.0rc1.
|
||
|
||
|
||
Implications for CPython core development
|
||
-----------------------------------------
|
||
|
||
The major change for CPython core development is the need to keep the master
|
||
branch more consistently release ready.
|
||
|
||
While the main requirement for that would be to keep the stable BuildBot fleet
|
||
green, there would also be encouragement to keep the development version of
|
||
the documentation up to date for the benefit of users of the rolling pre-freeze
|
||
releases. This will include providing draft What's New entries for changes as
|
||
they are implemented, although the initial versions may be relatively sparse,
|
||
and then expanded based on feedback from beta release users.
|
||
|
||
For core developers working on the CPython C API, there would also be a new
|
||
requirement to consistently mark ABI breaking changes in their NEWS file
|
||
snippets.
|
||
|
||
On the specific topic of the stable ABI, most API designs will be able to go
|
||
through a process where they're first introduced as a provisional part of the
|
||
full CPython API (allowing changes between pre-freeze releases), and only
|
||
promoted to the stable ABI once developers are confident that the interface
|
||
is genuinely stable.
|
||
|
||
It's only in rare cases where an API serves no useful purpose outside the
|
||
stable ABI that it may make sense to publish an alpha release containing a
|
||
provisional stable ABI addition rather than iterating on the design in the
|
||
provisional CPython API instead.
|
||
|
||
|
||
Implications for Python library development
|
||
-------------------------------------------
|
||
|
||
If this PEP is successful in its aims, then supporting the rolling pre-freeze
|
||
release stream shouldn't be subtantially more painful for library authors than
|
||
supporting the stable releases.
|
||
|
||
For publishers of pure Python packages, this would be a matter of publishing
|
||
"py3" tagged wheel archives, and potentially adding the rolling pre-freeze
|
||
release stream to their test matrix if that option is available to them.
|
||
|
||
For publishers of binary extension modules, the preferred option would be to
|
||
target the stable C ABI (if feasible), and thus enjoy an experience similar to
|
||
that of pure Python packages, where a single pre-built wheel archive is able to
|
||
cover multiple versions of Python, including the rolling pre-freeze release
|
||
stream.
|
||
|
||
This option isn't going to be viable for all libraries, and the desired outcome
|
||
for those authors is that they be able to support the rolling releases by
|
||
building and publishing one additional wheel archive, built against the initial
|
||
X.Y.0a1 release. The subsequent build against X.Y.0rc1 or later is then the same
|
||
build that would have been needed if only supporting the final stable release.
|
||
|
||
Additional wheel builds beyond those two should then only be needed if that
|
||
particular library is directly affected by an ABI break in any other alpha
|
||
release that occurs between those two points.
|
||
|
||
Having a rolling pre-freeze release stream available may also make it more feasible
|
||
for more CI providers to offer a "CPython beta release" testing option. At the
|
||
moment, this feature is only available from CI providers that are willing and
|
||
able to put the necessary time and effort into creating, testing, and publishing
|
||
their own builds from the CPython master branch (e.g. [6_]).
|
||
|
||
|
||
Implications for the proposed Scientific Python ecosystem support period
|
||
------------------------------------------------------------------------
|
||
|
||
Based on discussions at SciPy 2019, NEP (NumPy Enhancement Proposal) 29 has
|
||
been drafted [3_] to propose a common convention across the Scientific Python
|
||
ecosystem for dropping support for older Python versions.
|
||
|
||
While the exact formulation of that policy is still being discussed, the initial
|
||
proposal is very simple: support any Python feature release published within
|
||
the last 42 months.
|
||
|
||
For an 18 month feature release cadence, that works out to always supporting at
|
||
least the two most recent feature releases, and then dropping support for all
|
||
X.Y.Z releases around 6 months after X.(Y+2).0 is released. This means there is
|
||
a 6 month period roughly every other year where the three most recent feature
|
||
releases are supported.
|
||
|
||
For a 12 month release cadence, it would work out to always supporting at
|
||
least the three most recent feature releases, and then dropping support for all
|
||
X.Y.Z releases around 6 months after X.(Y+3).0 is released. This means that
|
||
for half of each year, the four most recent feature releases would be supported.
|
||
|
||
For a 24 month release cadence, a 42 month support cycle works out to always
|
||
supporting at least the most recent feature release, and then dropping support
|
||
for all X.Y.Z releases around 18 months after X.(Y+1).0 is released.
|
||
This means there is a 6 month period every other year where only one feature
|
||
release is supported. Under the proposal in this PEP, that period would
|
||
correspond to the final few rolling pre-freeze releases and the release candidate
|
||
phase for the upcoming stable feature release.
|
||
|
||
|
||
Release cycle alignment for core development sprints
|
||
----------------------------------------------------
|
||
|
||
With the proposal in this PEP, it is expected that the focus of core
|
||
development sprints would shift slightly based on the current location
|
||
in the two year cycle.
|
||
|
||
In release years, the timing of PyCon US is suitable for new contributors to
|
||
work on bug fixes and smaller features before the first release candidate goes
|
||
out, while the Language Summit and core developer discussions can focus on
|
||
plans for the next release series.
|
||
|
||
The pre-alpha core development sprint in release years will provide an
|
||
opportunity to incorporate feedback received on the previous release, either
|
||
as part of the next maintenance release (for bug fixes and feedback on
|
||
provisional APIs), or as part of the first alpha release of the next release
|
||
series (for feedback received on stable APIs).
|
||
|
||
Those initial alpha releases would also be the preferred target for ABI breaking
|
||
changes to the full CPython ABI (while changes later in the release cycle
|
||
would still be permitted as described in this PEP, landing them in the X.Y.0a1
|
||
release means that they won't trigger any additional work for publishers of
|
||
pre-built binary packages).
|
||
|
||
The Steering Council elections for the next release cycle are also likely to
|
||
occur around the same time as the pre-alpha development sprints.
|
||
|
||
In non-release years, the focus for both events would just be on the upcoming
|
||
maintenance and pre-freeze releases. These less intense years would hopefully
|
||
provide an opportunity to tackle various process changes and infrastructure
|
||
upgrades without impacting the release candidate preparation process.
|
||
|
||
|
||
Release cycle alignment for prominent Linux distributions
|
||
---------------------------------------------------------
|
||
|
||
Some rolling release Linux distributions (e.g. Arch, Gentoo) may be in a
|
||
position to consume the new rolling pre-freeze releases proposed in this PEP,
|
||
but it is expected that most distributions would continue to use the established
|
||
releases.
|
||
|
||
The specific dates for final releases proposed in this PEP are chosen to align
|
||
with the feature freeze schedules for the annual October releases of the Ubuntu
|
||
and Fedora Linux distributions.
|
||
|
||
For both Fedora and Ubuntu, it means that the release candidate phase aligns
|
||
with the development period for a distro release, which is the ideal time for
|
||
them to test a new version and provide feedback on potential regressions and
|
||
compatibility concerns.
|
||
|
||
For Ubuntu, this also means that their April LTS releases will have benefited
|
||
from a full short-term release cycle using the new system Python version, while
|
||
still having that CPython release be open to upstream bug fixes for most of the
|
||
time until the next Ubuntu LTS release.
|
||
|
||
The one Linux release cycle alignment that is likely to be consistently poor
|
||
with the specific proposal in this PEP is with Debian, as that has been released
|
||
in the first half of odd-numbered years since 2005 (roughly 12 months offset
|
||
from Ubuntu LTS releases).
|
||
|
||
With the annual release proposal in PEP 602, both Debian and Ubuntu LTS would
|
||
consistently get a system Python version that is around 6 months old, but
|
||
would also consistently select different Python versions from each other.
|
||
|
||
With a two year cadence, and CPython releases in the latter half of the year,
|
||
they're likely to select the same version as each other, but one of them will
|
||
be choosing a CPython release that is more than 18 months behind the latest beta
|
||
releases by the time the Linux distribution ships.
|
||
|
||
If that situation does occur, and is deemed undesirable (but not sufficiently
|
||
undesirable for *Debian* to choose to adjust their release timing), then that's
|
||
where the additional complexity of the "incremental feature release" proposal
|
||
in PEP 598 may prove worthwhile.
|
||
|
||
(Moving CPython releases to the same half of the year as the Debian and Ubuntu
|
||
LTS releases would potentially help mitigate the problem, but also creates
|
||
new problems where a slip in the CPython release schedule could directly affect
|
||
the release schedule for a Linux distribution, or else result in a distribution
|
||
shipping a Python version that is *more* than 18 months old)
|
||
|
||
|
||
Implications for simple deployment environments
|
||
-----------------------------------------------
|
||
|
||
For the purposes of this PEP, a "simple" deployment environment is any use case
|
||
where it is straightforward to ensure that all target environments are updated
|
||
to a new Python release at the same time (or at least in advance of the rollout
|
||
of new higher level application versions), and any pre-release testing that
|
||
occurs need only target a single Python micro version.
|
||
|
||
The simplest such case would be scripting for personal use, where the testing
|
||
and target environments are the exact same environment.
|
||
|
||
Similarly simple environments would be containerised web services, where the
|
||
same Python container is used in the CI pipeline as is used on deployment, and
|
||
any application that bundles its own Python runtime, rather than relying on a
|
||
pre-existing Python deployment on the target system.
|
||
|
||
For these use cases, there is a straightforward mechanism to minimise the
|
||
impact of this PEP: continue using the stable releases, and ignore the rolling
|
||
pre-freeze releases.
|
||
|
||
To actually adopt the rolling pre-freeze releases in these environments, the
|
||
main challenge will be handling the potential for extension module segfaults
|
||
when the next pre-freeze release is an alpha release rather than a beta
|
||
release, indicating that the CPython ABI may have changed in an incompatible
|
||
way.
|
||
|
||
If all extension modules in use target the stable ABI, then there's no problem,
|
||
and everything will work just as smoothly as it does on the stable releases.
|
||
|
||
Alternatively, "rebuild and recache all extension modules" could become a
|
||
standard activity undertaken as part of updating to an alpha release.
|
||
|
||
Finally, it would also be reasonable to just not worry about it until something
|
||
actually breaks, and then handle it like any other library compatibility issue
|
||
found in a new alpha or beta release.
|
||
|
||
Aside from extension module ABI compatibilty, the other main point of additional
|
||
complexity when using the rolling pre-freeze releases would be "roll-back"
|
||
compatibility for independently versioned features, such as pickle and SQLite,
|
||
where use of new or provisional features in the beta stream may create files
|
||
that are not readable by the stable release. Applications that use these
|
||
kinds of features and also require the ability to reliably roll-back to a
|
||
previous stable CPython release would, as today, be advised to avoid adopting
|
||
pre-release versions.
|
||
|
||
|
||
Implications for complex deployment environments
|
||
------------------------------------------------
|
||
|
||
For the purposes of this PEP, "complex" deployment environments are use cases
|
||
which don't meet the "simple deployment" criteria above. They may involve
|
||
multiple distinct versions of Python, use of a personalised build of Python,
|
||
or "gatekeepers" who are required to approve use of a new version prior to
|
||
deployment.
|
||
|
||
For example, organisations that install Python on their users' machines as part
|
||
of a standard operating environment fall into this category, as do those that
|
||
provide a standard build environment. Distributions such as conda-forge or
|
||
WinPython that provide collections of consistently built and verified packages
|
||
are impacted in similar ways.
|
||
|
||
These organisations tend to either prefer high stability (for example, all of
|
||
those who are happily using the system Python in a stable Linux distribution
|
||
like Debian, RHEL/CentOS, or Ubuntu LTS as their preferred Python environment)
|
||
or fast turnaround (for example, those who regularly contribute toward the
|
||
latest CPython pre-releases).
|
||
|
||
In some cases, both usage models may exist within the same organisation for
|
||
different purposes, such as:
|
||
|
||
* using a stable Python environment for mission critical systems, but allowing
|
||
data scientists to use the latest available version for ad hoc data anaylsis
|
||
* a hardware manufacturer deploying a stable Python version as part of their
|
||
production firmware, but using the latest available version in the development
|
||
and execution of their automated integration tests
|
||
|
||
Under any release model, each new release of Python generates work for these
|
||
organisations. This work may involve legal, security or technical reviews of
|
||
Python itself, assessment and verification of impactful changes, reapplication
|
||
of patches, recompilation and testing of third-party dependencies, and
|
||
only then deployment.
|
||
|
||
Organisations that can take updates quickly should be able to make use of the
|
||
more frequent beta releases. While each update will still require similar
|
||
investigative work to what they require today, the volume of work required per
|
||
release should be reduced as each release will be more similar to the previous
|
||
than it is under the present model. One advantage of the proposed
|
||
release-every-2-months model is that organisations can choose their own adoption
|
||
cadence from adopting every beta release, to adopting one per quarter, or one
|
||
every 6 months, or one every year. Beyond that, it would likely make more sense
|
||
to continue using the stable releases instead.
|
||
|
||
For organisations with stricter evaluations or a preference for stability, the
|
||
longer release cycle for stable releases will reduce the annual effort required
|
||
to update, the longer release candidate period will allow more time to do
|
||
internal testing before the X.Y.0 release, and the greater use by others
|
||
during the beta period will provide more confidence in the initial releases.
|
||
Meanwhile, the organisation can confidently upgrade through maintenance
|
||
releases for a longer time without fear of breaking changes.
|
||
|
||
|
||
Acknowledgements
|
||
================
|
||
|
||
Thanks to Łukasz Langa for creating PEP 602 and prompting this discussion of
|
||
possible improvements to the CPython release cadence, and to Kyle Stanley
|
||
and h-vetinari for constructive feedback on the initial draft of this PEP.
|
||
|
||
|
||
References
|
||
==========
|
||
|
||
.. [1] Steve Dower's initial "Fast and Stable releases" proposal
|
||
(https://discuss.python.org/t/pep-602-annual-release-cycle-for-python/2296/20)
|
||
|
||
.. [2] Paul Moore's initial comments on Steve's proposal
|
||
(https://discuss.python.org/t/pep-602-annual-release-cycle-for-python/2296/37)
|
||
|
||
.. [3] NEP 29 proposes a common policy for dropping support of old Python versions
|
||
(https://numpy.org/neps/nep-0029-deprecation_policy.html)
|
||
|
||
.. [4] Example implementation for a pre-release SOABI flag
|
||
(https://github.com/ncoghlan/cpython/pull/3)
|
||
|
||
.. [5] CPython stable ABI documentation
|
||
(https://docs.python.org/3/c-api/stable.html)
|
||
|
||
.. [6] Travis CI nightly CPython builds
|
||
(https://docs.travis-ci.com/user/languages/python/#nightly-build-support)
|
||
|
||
Copyright
|
||
=========
|
||
|
||
This document is placed in the public domain or under the CC0-1.0-Universal
|
||
license, whichever is more permissive.
|
||
|
||
..
|
||
Local Variables:
|
||
mode: indented-text
|
||
indent-tabs-mode: nil
|
||
sentence-end-double-space: t
|
||
fill-column: 80
|
||
coding: utf-8
|
||
End:
|