SciPy Roadmap#
This roadmap page contains only the most important ideas and needs for SciPy going forward. For a more detailed roadmap, including per-subpackage status, many more ideas, API stability and more, see Detailed SciPy Roadmap.
Support for distributed arrays and GPU arrays#
NumPy has split its API from its execution engine with
__array_function__
and __array_ufunc__
. This will enable parts of SciPy
to accept distributed arrays (e.g. dask.array.Array
) and GPU arrays (e.g.
cupy.ndarray
) that implement the ndarray
interface. At the moment it is
not yet clear which algorithms will work out of the box, and if there are
significant performance gains when they do. We want to create a map of which
parts of the SciPy API work, and improve support over time.
In addition to making use of NumPy protocols like __array_function__
, we can
make use of these protocols in SciPy as well. That will make it possible to
(re)implement SciPy functions like, e.g., those in scipy.signal
for Dask
or GPU arrays (see
NEP 18 - use outside of NumPy). NumPy’s features in this areas are still evolving,
see e.g. NEP 37 - A dispatch protocol for NumPy-like modules,
and SciPy is an important “client” for those features.
Performance improvements#
Speed improvements, lower memory usage and the ability to parallelize
algorithms are beneficial to most science domains and use cases. We have
established an API design pattern for multiprocessing - using the workers
keyword - that can be adopted in many more functions.
Enabling the use of an accelerator like Pythran, possibly via Transonic, and
making it easier for users to use Numba’s @njit
in their code that relies
on SciPy functionality would unlock a lot of performance gain. That needs a
strategy though, all solutions are still maturing (see for example
this overview).
Finally, many individual functions can be optimized for performance.
scipy.optimize
and scipy.interpolate
functions are particularly often
requested in this respect.
Statistics enhancements#
The following scipy.stats
enhancements and those listed in the
Detailed SciPy Roadmap are of particularly high importance to the
project.
Overhaul the univariate distribution infrastructure to address longstanding issues (e.g. see gh-15928.)
Consistently handle
nan_policy
,axis
arguments, and masked arrays instats
functions (where appropriate).
Support for more hardware platforms#
SciPy now has continuous integration for ARM64 (or aarch64
) and POWER8/9
(or ppc64le
), and binaries are available via
Miniforge. Wheels on PyPI for
these platforms are now also possible (with the manylinux2014
standard),
and requests for those are becoming more frequent.
Additionally, having IBM Z (or s390x
) in CI is now possible with TravisCI
but not yet done - and manylinux2014
wheels for that platform are also
possible then. Finally, resolving open AIX build issues would help users.
Implement sparse arrays in addition to sparse matrices#
The sparse matrix formats are mostly feature-complete, however the main issue
is that they act like numpy.matrix
(which will be deprecated in NumPy at
some point). What we want is sparse arrays that act like numpy.ndarray
.
This is being worked on in https://github.com/pydata/sparse, which is quite far
along. The tentative plan is:
Start depending on
pydata/sparse
once it’s feature-complete enough (it still needs a CSC/CSR equivalent) and okay performance-wise.Indicate in the documentation that for new code users should prefer
pydata/sparse
over sparse matrices.When NumPy deprecates
numpy.matrix
, vendor that or maintain it as a stand-alone package.