For downstream package authors#
This document aims to explain some best practices for authoring a package that depends on NumPy.
Understanding NumPy’s versioning and API/ABI stability#
NumPy uses a standard, PEP 440 compliant, versioning scheme:
major.minor.bugfix
. A major release is highly unusual and if it happens
it will most likely indicate an ABI break. NumPy 1.xx releases happened from
2006 to 2023; NumPy 2.0 in early 2024 is the first release which changed the
ABI (minor ABI breaks for corner cases may have happened a few times in minor
releases).
Minor versions are released regularly, typically every 6 months. Minor
versions contain new features, deprecations, and removals of previously
deprecated code. Bugfix releases are made even more frequently; they do not
contain any new features or deprecations.
It is important to know that NumPy, like Python itself and most other well known scientific Python projects, does not use semantic versioning. Instead, backwards incompatible API changes require deprecation warnings for at least two releases. For more details, see NEP 23 — Backwards compatibility and deprecation policy.
NumPy has both a Python API and a C API. The C API can be used directly or via Cython, f2py, or other such tools. If your package uses the C API, then ABI (application binary interface) stability of NumPy is important. NumPy’s ABI is forward but not backward compatible. This means: binaries compiled against a given target version of NumPy’s C API will still run correctly with newer NumPy versions, but not with older versions.
Testing against the NumPy main branch or pre-releases#
For large, actively maintained packages that depend on NumPy, we recommend testing against the development version of NumPy in CI. To make this easy, nightly builds are provided as wheels at https://anaconda.org/scientific-python-nightly-wheels/. Example install command:
pip install -U --pre --only-binary :all: -i https://pypi.anaconda.org/scientific-python-nightly-wheels/simple numpy
This helps detect regressions in NumPy that need fixing before the next NumPy
release. Furthermore, we recommend to raise errors on warnings in CI for this
job, either all warnings or otherwise at least DeprecationWarning
and
FutureWarning
. This gives you an early warning about changes in NumPy to
adapt your code.
If you want to test your own wheel builds against the latest NumPy nightly
build and you’re using cibuildwheel
, you may need something like this in
your CI config file:
CIBW_ENVIRONMENT: "PIP_PRE=1 PIP_EXTRA_INDEX_URL=https://pypi.anaconda.org/scientific-python-nightly-wheels/simple"
Adding a dependency on NumPy#
Build-time dependency#
Note
Before NumPy 1.25, the NumPy C-API was not exposed in a backwards compatible way by default. This means that when compiling with a NumPy version earlier than 1.25 you have to compile with the oldest version you wish to support. This can be done by using oldest-supported-numpy. Please see the NumPy 1.24 documentation.
If a package either uses the NumPy C API directly or it uses some other tool that depends on it like Cython or Pythran, NumPy is a build-time dependency of the package.
By default, NumPy will expose an API that is backwards compatible with the oldest NumPy version that supports the currently oldest compatible Python version. NumPy 1.25.0 supports Python 3.9 and higher and NumPy 1.19 is the first version to support Python 3.9. Thus, we guarantee that, when using defaults, NumPy 1.25 will expose a C-API compatible with NumPy 1.19. (the exact version is set within NumPy-internal header files).
NumPy is also forward compatible for all minor releases, but a major release will require recompilation (see NumPy 2.0-specific advice further down).
The default behavior can be customized for example by adding:
#define NPY_TARGET_VERSION NPY_1_22_API_VERSION
before including any NumPy headers (or the equivalent -D
compiler flag) in
every extension module that requires the NumPy C-API.
This is mainly useful if you need to use newly added API at the cost of not
being compatible with older versions.
If for some reason you wish to compile for the currently installed NumPy version by default you can add:
#ifndef NPY_TARGET_VERSION
#define NPY_TARGET_VERSION NPY_API_VERSION
#endif
Which allows a user to override the default via -DNPY_TARGET_VERSION
.
This define must be consistent for each extension module (use of
import_array()
) and also applies to the umath module.
When you compile against NumPy, you should add the proper version restrictions
to your pyproject.toml
(see PEP 517). Since your extension will not be
compatible with a new major release of NumPy and may not be compatible with
very old versions.
For conda-forge packages, please see here.
as of now, it is usually as easy as including:
host:
- numpy
run:
- {{ pin_compatible('numpy') }}
Runtime dependency & version ranges#
NumPy itself and many core scientific Python packages have agreed on a schedule for dropping support for old Python and NumPy versions: NEP 29 — Recommend Python and NumPy version support as a community policy standard. We recommend all packages depending on NumPy to follow the recommendations in NEP 29.
For run-time dependencies, specify version bounds using
install_requires
in setup.py
(assuming you use numpy.distutils
or
setuptools
to build).
Most libraries that rely on NumPy will not need to set an upper version bound: NumPy is careful to preserve backward-compatibility.
That said, if you are (a) a project that is guaranteed to release
frequently, (b) use a large part of NumPy’s API surface, and (c) is
worried that changes in NumPy may break your code, you can set an
upper bound of <MAJOR.MINOR + N
with N no less than 3, and
MAJOR.MINOR
being the current release of NumPy [*]. If you use the NumPy
C API (directly or via Cython), you can also pin the current major
version to prevent ABI breakage. Note that setting an upper bound on
NumPy may affect the ability of your library to be installed
alongside other, newer packages.
Note
SciPy has more documentation on how it builds wheels and deals with its build-time and runtime dependencies here.
NumPy and SciPy wheel build CI may also be useful as a reference, it can be found here for NumPy and here for SciPy.
NumPy 2.0-specific advice#
NumPy 2.0 is an ABI-breaking release, however it does contain support for building wheels that work on both 2.0 and 1.xx releases. It’s important to understand that:
When you build wheels for your package using a NumPy 1.xx version at build time, those will not work with NumPy 2.0.
When you build wheels for your package using a NumPy 2.x version at build time, those will work with NumPy 1.xx.
The first time the NumPy ABI for 2.0 is guaranteed to be stable will be the release of the first release candidate for 2.0 (i.e., 2.0.0rc1). Our advice for handling your dependency on NumPy is as follows:
In the main (development) branch of your package, do not add any constraints.
If you rely on the NumPy C API (e.g. via direct use in C/C++, or via Cython code that uses NumPy), add a
numpy<2.0
requirement in your package’s dependency metadata for releases / in release branches. Do this until numpy2.0.0rc1
is released and you can target that. Rationale: the NumPy C ABI will change in 2.0, so any compiled extension modules that rely on NumPy will break; they need to be recompiled.If you rely on a large API surface from NumPy’s Python API, also consider adding the same
numpy<2.0
requirement to your metadata until you are sure your code is updated for changes in 2.0 (i.e., when you’ve tested things work against2.0.0rc1
). Rationale: we will do a significant API cleanup, with many aliases and deprecated/non-recommended objects being removed (see, e.g., NumPy 2.0 migration guide and NEP 52 — Python API cleanup for NumPy 2.0), so unless you only use modern/recommended functions and objects, your code is likely to require at least some adjustments.Plan to do a release of your own packages which depend on
numpy
shortly after the first NumPy 2.0 release candidate is released (probably around 1 Feb 2024). Rationale: at that point, you can release packages that will work with both 2.0 and 1.X, and hence your own end users will not be seeing much/any disruption (you wantpip install mypackage
to continue working on the day NumPy 2.0 is released).Once
2.0.0rc1
is available, you can adjust your metadata inpyproject.toml
in the way outlined below.
There are two cases: you need to keep compatibility with numpy 1.xx while also
supporting 2.0, or you are able to drop numpy 1.xx support for new releases of
your package and support >=2.0 only. The latter is simpler, but may be more
restrictive for your users. In that case, simply add numpy>=2.0
(or
numpy>=2.0.0rc1
) to your build and runtime requirements and you’re good to
go. We’ll focus on the “keep compatibility with 1.xx and 2.x” now, which is a
little more involved.
Example for a package using the NumPy C API (via C/Cython/etc.) which wants to support NumPy 1.23.5 and up:
[build-system]
build-backend = ...
requires = [
# Note for packagers: this constraint is specific to wheels
# for PyPI; it is also supported to build against 1.xx still.
# If you do so, please ensure to include a `numpy<2.0`
# runtime requirement for those binary packages.
"numpy>=2.0.0rc1",
...
]
[project]
dependencies = [
"numpy>=1.23.5",
]
We recommend that you have at least one CI job which builds/installs via a wheel, and then runs tests against the oldest numpy version that the package supports. For example:
- name: Build wheel via wheel, then install it
run: |
python -m build # This will pull in numpy 2.0 in an isolated env
python -m pip install dist/*.whl
- name: Test against oldest supported numpy version
run: |
python -m pip install numpy==1.23.5
# now run test suite
The above only works once NumPy 2.0 is available on PyPI. If you want to test against a NumPy 2.0-dev wheel, you have to use a numpy nightly build (see this section higher up) or build numpy from source.