Toolchain Roadmap#

The use of the SciPy library requires (or optionally depends upon) several other libraries in order to operate, the main dependencies being Python and NumPy. It requires a larger collection of libraries and tools in order to build the library or to build the documentation.

Of course, the tooling and libraries are themselves not static. This document aims to provide a guide as to how SciPy’s use of these dynamic dependencies will proceed over time.

SciPy aims to be compatible with a number of releases of its dependent libraries and tools. Forcing the user base to other components for upgrade for every release would greatly diminish the value of SciPy. However, maintaining backwards compatibility with very old tooling/libraries imposes limitations on which newer functionalities and capabilities can be incorporated. SciPy takes a somewhat conservative approach, maintaining compatibility with several major releases of Python and NumPy on the major platforms. (That may in and of itself impose further restrictions. See the C Compilers section for an example.)

  • First and foremost, SciPy is a Python project, hence it requires a Python environment.

  • BLAS and LAPACK numerical libraries need to be installed.

  • Compilers for C, C++, Fortran code are needed, as well as for Cython & Pythran (the latter is opt-out currently)

  • The Python environment needs the NumPy package to be installed.

  • Testing requires the pytest and hypothesis Python packages.

  • Building the documentation requires the matplotlib, Sphinx and MyST-NB packages along with PyData theme.

The tooling used to build CPython has some implications for the tooling used in building SciPy. It also has implications for the examples used in the documentation (e.g., docstrings for functions), as these examples can only use functionality present in all supported configurations.

Building SciPy#

Python Versions#

SciPy is compatible with several versions of Python. When dropping support for older Python versions, SciPy takes guidance from NEP 29 [1]. Python 2.7 support was dropped starting from SciPy 1.3.

Date

Pythons supported

2018

Py2.7, Py3.4+ (SciPy 1.2.x is the last release to support Python 2.7)

2019

Py3.5+ (but Py2.7-specific code not removed)

2020

Py3.6+ (removal of Py2.7-specific code permitted)

2021

Py3.7+

2022

Py3.8+

NumPy#

SciPy depends on NumPy but releases of SciPy are not tied to releases of NumPy. SciPy attempts to be compatible with at least the 4 previous releases of NumPy. In particular, SciPy cannot rely on features of just the latest NumPy, but needs to be written using what is common in all of those 4 releases [2].

The table shows the NumPy versions suitable for each major Python version.

SciPy version

Python versions

NumPy versions

1.2

2.7, >=3.4, <=3.7

>=1.8.2, <= 1.16.x

1.4

>=3.5, <=3.8

>=1.13.3, <= 1.17.3

1.5

>=3.6, <=3.9

>=1.14.5, <= 1.19.3

1.6

>=3.7, <=3.9

>=1.16.5, <= 1.20.x

1.7.0/1

>=3.7, <3.10

>=1.16.5, <1.23.0

1.7.2/3

>=3.7, <3.11

>=1.16.5, <1.23.0

1.8

>=3.8, <3.11

>=1.17.3, <1.24.0

1.9.0/1

>=3.8, <3.12

>=1.18.5, <1.25.0

1.9.2

>=3.8, <3.12

>=1.18.5, <1.26.0

1.10

>=3.8, <3.12

>=1.19.5, <1.26.0

1.11

>=3.9, <3.12

>=1.21.6, <1.27.0

1.12

>=3.9, <3.13

>=1.22.4, <2.0.0

In specific cases, such as a particular architecture, these requirements could vary. Please check the release notes [3] and the meta-package oldest-supported-numpy for more info [4].

Compilers#

Building SciPy requires compilers for C, C++, Fortran, as well as the python transpilers Cython and Pythran (the latter is an opt-out dependency starting from version 1.7.0).

To maintain compatibility with a large number of platforms & setups, especially where using the official wheels (or other distribution channels like Anaconda or conda-forge) is not possible, SciPy tries to keep compatibility with older compilers, on platforms that have not yet reached their official end-of-life.

As explained in more detail below, the current minimal compiler versions are:

Compiler

Default Platform (tested)

Secondary Platform (untested)

Minimal Version

GCC

Linux

AIX, Alpine Linux, OSX

GCC 8.x

LLVM

OSX

Linux, FreeBSD, Windows

LLVM 10.x

MSVC

Windows

Visual Studio 2019 (vc142)

Note that the lower bound for LLVM is not enforced. Older versions should work - as long as they support core (non-stdlib) C++17 -, but no version below LLVM 12 is tested regularly during development. Please file an issue if you encounter a problem during compilation.

Official Builds#

Currently, SciPy wheels are being built as follows:

Platform

CI Base Images [5] [6] [7]

Compilers

Comment

Linux x86

ubuntu-22.04

GCC 10.2.1

cibuildwheel

Linux arm

docker-builder-arm64

GCC 11.3.0

cibuildwheel

OSX x86_64

macOS-11

clang-13/gfortran 11.3.0

cibuildwheel

OSX arm64

macos-14

clang-15.0.0/gfortran 13.2.0

cibuildwheel

Windows

windows-2019

GCC 10.3 (rtools)

cibuildwheel

Note that the OSX wheels additionally vendor gfortran 11.3.0 for x86_64, and gfortran 13.2.0 for arm64. See tools/wheels/cibw_before_build_macos.sh.

C Compilers#

SciPy is compatible with most modern C compilers (in particular clang). Nowadays, there is reasonable support for recent C language standards across all relevant compilers, though this is very different from how things used to be. The following paragraphs primarily discuss the evolution of these constraints; readers who do not care about historical context can skip ahead to the table at the end.

In the past, the most restrictive compiler on relevant platform in terms of C support was the Microsoft Visual C++ compiler & toolset (together known as MSVC) [8] [9]. Up until Visual Studio 2013, each MSVC version came with an updated C Runtime (CRT) library that was incompatible with the previous ones.

This lack of compatibility of the Application Binary Interface (ABI) meant that all projects wanting to communicate across this interface (e.g. calling a function from a shared library) needed to be (re)compiled with the same MSVC version. The long support of CPython 2.7 meant that python itself was stuck for a long time with VS 2008 (in order not to break the ABI in patch releases), and thus SciPy was stuck on that version as well.

The use of VS 2008 (which doesn’t have support for C99) to compile builds for CPython 2.7 meant for a long time that C code in SciPy has had to conform to the earlier C90 standard for the language and standard library. After dropping support for CPython 2.7 in SciPy 1.3.x, that restriction was finally lifted (though only gradually at first).

With the introduction of the “Universal C Runtime” (UCRT) [10] since the release of Visual Studio 2015, the ABI of C Runtime has been stable, which means that the restriction of having to use the same compiler version for SciPy as for the underlying CPython version is no longer applicable. This stability is not indefinite though: Microsoft has been planning [11] an ABI-breaking release - across the compiler resp. C/C++ standard libraries - (tentatively called “vNext”) for quite a while, but so far it is unclear when this will arrive. Once that happens, SciPy will again be restricted to at most the last ABI-compatible Visual Studio release (currently VS 2022) until all CPython versions supported according to NEP29 have been built upstream with vNext-compatible compilers.

More specifically, there is a distinction between the Microsoft Visual Studio version and the version of the targeted “toolset”, which is defined [12] as “The Microsoft C++ compiler, linker, standard libraries, and related utilities”. Each version of Visual Studio comes with a default version of the MSVC toolset (for example VS2017 with vc141, VS2019 with vc142), but it is possible to target older toolsets even in newer versions of Visual Studio. Due to the nature of compilers (i.e. split into frontend and backend), it depends whether the limiting factor for supporting a given feature (e.g. in C) is due to the version of Visual Studio or the toolset, but in general the latter is a harder barrier and thus the effective lower bound.

This is due to the fact that while the ABI stays compatible between toolset versions (until vNext), all linking operations must use a toolset at least as new as the one used to build any of the involved artefacts, meaning that toolset version bumps tend to be “infectious”, as in: requiring all consuming libraries to also bump their toolset (and probably compiler) version. This is more of an issue for NumPy than SciPy, as the latter has only a small C API and is compiled against by far fewer projects than NumPy. Additionally, using a newer toolset means that users of libraries that compile C++ code (as SciPy does) might also need a newer Microsoft Visual C++ Redistributable, which might have to be distributed to them [13].

Summing up, the minimal requirement for the MSVC compiler resp. toolset per SciPy version was determined predominantly by the oldest supported CPython version at the time. The first SciPy version to raise the minimal requirement beyond that was SciPy 1.9, due to the inclusion of the HiGHS submodule, which does not compile with vc141 (and the aggressive removal of VS2017 in public CI making it infeasible to keep ensuring that everything everywhere works with non-default toolset versions).

SciPy version

CPython support

MS Visual C++

Toolset version

Until 1.2

2.7 & 3.4+

VS 2008 (9.0)

vc90

1.3, 1.4

3.5+

VS 2010 (10.0)

vc100

1.5

3.6+

VS 2015 (14.0)

vc140

1.6, 1.7

3.7+

VS 2017 (14.1)

vc141

1.8

3.8+

VS 2017 (14.1)

vc141

1.9

3.8+

VS 2019 (14.20)

vc142

In terms of C language standards, it’s relevant to note that C11 has optional features [14] (e.g. atomics, threading), some of which (VLAs & complex types) were mandatory in the C99 standard. C17 (occasionally called C18) can be considered a bug fix for C11, so generally, C11 may be skipped entirely.

SciPy has been restricted in the use of more advanced language features by the available compiler support, and Microsoft in particular has taken very long to achieve conformance to C99/C11/C17, however starting from MS Visual Studio 16.8, C11/C17 is supported [15] (though without the C11 optional features). C99 <complex.h> would be particularly interesting for SciPy; MSVC conformance for this and <stdatomic.h> is being tracked here [16] [17]. However, it’s still possible to use complex types on windows, provided that windows-specific types are used [18].

Therefore, using C features beyond C90 was only possible insofar there was support on Windows; however, as of as of the end of 2021, a sufficiently recent compiler is used. This is because GCC & LLVM support all relevant C11 features with the oldest currently used versions, and C17 is just a bugfix for C11, as mentioned above. In short:

Date

C Standard

<= 2018

C90

2019

C90 for old code, may consider C99 for new

2020

C99 (no <complex.h>, <stdatomic.h>, <threads.h> & VLAs)

2021

C17 (no <complex.h>, <stdatomic.h>, <threads.h> & VLAs)

?

C23, <complex.h>, <stdatomic.h>, …

C++ Language Standards#

C++ language standards for SciPy are generally guidelines rather than official decisions. This is particularly true of attempting to predict adoption timelines for newer standards.

Date

C++ Standard

<= 2019

C++03

2020

C++11

2021

C++14

2022

C++17 (core language + universally available stdlib features)

?

C++17 (with full stdlib), C++20, C++23

Since dropping support for Python 2.7, C++11 can be used universally, and since dropping Python 3.6, the Visual Studio version (that had previously been stuck with 14.0 due to ABI compatibility with CPython) has been recent enough to support even C++17.

Since the official builds (see above) use a pretty recent version of LLVM, the bottleneck for C++ support is therefore the oldest supported GCC version, where SciPy has been constrained mainly by the version in the oldest supported manylinux versions & images [19].

At the end of 2021 (with the final removal of manylinux1 wheels), the minimal requirement of GCC moved to 6.3, which has full C++14 support [20]. This corresponded to the lowest-present GCC version in relevant manylinux versions, though this was still considering the Debian-based “outlier” manylinux_2_24, which - in contrast to previous manylinux images based on RHEL-derivative CentOS that could benefit from the ABI-compatible GCC backports in the “RHEL Dev Toolset” - was stuck with GCC 6.3. That image failed to take off not least due to those outdated compilers [21] and reached its EOL in mid-2022 [22]. For different reasons, manylinux2010 also reached its EOL around the same time [23].

The remaining images manylinux2014 and manylinux_2_28 currently support GCC 10 and 11, respectively. The latter will continue to receive updates as new GCC versions become available as backports, but the former will likely not change since the CentOS project is not responsive anymore about publishing aarch64 backports of GCC 11 [24].

This leaves all the main platforms and their compilers with comparatively recent versions. However, SciPy has historically also endeavored to support less common platforms as well - if not with binary artefacts (i.e. wheels), then at least by remaining compilable from source - which includes for example AIX, Alpine Linux and FreeBSD.

For AIX 7.1 & 7.2 the default compiler is GCC 8 (AIX 6.1 had its EOL in 2017), but GCC 10 is installable (side-by-side) [25]. The oldest currently-supported Alpine Linux release is 3.12 [26], and already comes with GCC 10. For FreeBSD, the oldest currently-supported 12.x release [27] comes with LLVM 10 (and GCC 10 is available as a freebsd-port [28]).

Finally there is the question of which machines are widely used by people needing to compile SciPy from source for other reasons (e.g. SciPy developers, or people wanting to compile for themselves for performance reasons). The oldest relevant distributions (without RHEL-style backports) are Ubuntu 18.04 LTS (which has GCC 7 but also has a backport of GCC 8; Ubuntu 20.04 LTS has GCC 9) and Debian Buster (with GCC 8; Bullseye has GCC 10). This is the weakest restriction for determining the lower bounds of compiler support (power users and developers can be expected to keep their systems at least somewhat up-to-date, or use backports where available), and gradually becomes less important as usage numbers of old distributions dwindle.

All the currently lowest-supported compiler versions (GCC 8, LLVM 12, VS2019 with vc142) have full support for the C++17 core language, which can therefore be used unconditionally. However, as of mid-2022, support for the entirety of the C++17 standard library has not yet been completed across all compilers [20], particularly LLVM. It is therefore necessary to check if a given stdlib-feature is supported by all compilers before it can be used in SciPy. Compiler support for C++20 and C++23 is still under heavy development [20].

Fortran Compilers#

Generally, any well-maintained compiler is likely suitable and can be used to build SciPy.

Tool

Version

gfortran

>= 4.8.0

ifort

A recent version

flang

A recent version

Cython & Pythran#

SciPy always requires a recent Cython compiler. Since 1.7, Pythran is a build dependency (currently with the possibility to opt out).

OpenMP support#

For various reasons [29], SciPy cannot be distributed with built-in OpenMP support. When using the optional Pythran support, OpenMP-enabled parallel code can be generated when building from source.

Other Libraries#

Any library conforming to the BLAS/LAPACK interface may be used. OpenBLAS, ATLAS, MKL, BLIS, and reference Netlib libraries are known to work.

Library

Minimum version

LAPACK

3.7.1

BLAS

A recent version of OpenBLAS, MKL or ATLAS. The Accelerate BLAS library is no longer supported.

There are some additional optional dependencies.

Library

Version

URL

mpmath

Recent

http://mpmath.org/

scikit-umfpack

Recent

https://pypi.org/project/scikit-umfpack/

pooch

Recent

https://pypi.org/project/pooch/

Moreover, SciPy supports interaction with other libraries. The test suite has additional compatibility tests that are run when these are installed:

Tool

Version

URL

pydata/sparse

Recent

pydata/sparse

Testing and Benchmarking#

Testing and benchmarking require recent versions of:

Tool

Version

URL

pytest

Recent

https://docs.pytest.org/en/latest/

Hypothesis

Recent

https://hypothesis.readthedocs.io/

asv (airspeed velocity)

Recent

https://asv.readthedocs.io/

Building the Documentation#

Tool

Version

Sphinx

Whatever recent versions work. >= 5.0.

PyData Sphinx theme

Whatever recent versions work. >= 0.15.2.

Sphinx-Design

Whatever recent versions work. >= 0.4.0.

numpydoc

Whatever recent versions work. >= 1.5.0.

matplotlib

Generally suggest >= 3.5.

MyST-NB

Whatever recent versions work. >= 0.17.1

jupyterlite-sphinx

Whatever recent versions work. >= 0.12.0

Note

Developer Note: The versions of numpy and matplotlib required have implications for the examples in Python docstrings. Examples must be able to be executed both in the environment used to build the documentation, as well as with any supported versions of numpy/matplotlib that a user may use with this release of SciPy.

Packaging#

A Recent version of:

Tool

Version

URL

setuptools

Recent

https://pypi.org/project/setuptools/

wheel

Recent

https://pythonwheels.com

multibuild

Recent

matthew-brett/multibuild

Making a SciPy release and Distributing contain information on making and distributing a SciPy release.

References#