cuNumeric is a Legate library that aims to provide a distributed and accelerated drop-in replacement for the NumPy API on top of the Legion runtime. Using cuNumeric you do things like run the final example of the Python CFD course completely unmodified on 2048 A100 GPUs in a DGX SuperPOD and achieve good weak scaling.
cuNumeric works best for programs that have very large arrays of data that cannot fit in the memory of a single GPU or a single node and need to span multiple nodes and GPUs. While our implementation of the current NumPy API is still incomplete, programs that use unimplemented features will still work (assuming enough memory) by falling back to the canonical NumPy implementation.
If you have questions, please contact us at legate(at)nvidia.com.
- Installation
- Dependencies
- Building from Source
- Usage and Execution
- Supported and Planned Features
- Supported Types and Dimensions
- Documentation
- Future Directions
- Contributing
- Known Bugs
cuNumeric is available on conda:
conda install -c nvidia -c conda-forge -c legate cunumeric
The conda package is compatible with CUDA >= 11.4 (CUDA driver version >= r470), and Volta or later GPU architectures.
Docker image build scripts, as well as specialized install scripts for supported clusters are available on the quickstart repo.
Read on for general instructions on building cuNumeric from source.
Users must have a working installation of the Legate Core library prior to installing cuNumeric.
cuNumeric requires the following:
- Python >= 3.8
- CUDA >= 10.2
- GNU Make
- C++17 compatible compiler (g++, clang, or nvc++)
- Fortran compiler (for building OpenBLAS; not necessary if you provide a pre-built version of OpenBLAS)
- the Python packages listed in any one of the conda environment files:
conda/environment-test-3.8.yml
conda/environment-test-3.9.yml
conda/environment-test-3.10.yml
See the corresponding section on the Legate Core instructions for help on installing the required Python packages using conda.
cuNumeric is tested and guaranteed to be compatible with Volta and later GPU architectures. You can use cuNumeric with Pascal GPUs as well, but there could be issues due to lack of independent thread scheduling. Please report any such issues on GitHub.
Installation of cuNumeric is done with either setup.py
for simple
uses cases or install.py
for more advanced use cases. The most common
installation command is:
python setup.py --with-core <path-to-legate-core-installation>
This will build cuNumeric against the Legate Core installation and then install cuNumeric into the same location.
If Legate Core has been installed with CUDA support, a working cuTENSOR
installation must also be provided to the installation command with the
--with-cutensor
option:
python setup.py --with-core <path-to-legate-core-installation> --with-cutensor <path-to-cutensor-installation>
You can also specify an installation of OpenBLAS
to use for the build. If you already have an installation of OpenBLAS on your
machine, you can inform the installation script using the --with-openblas
option:
python setup.py --with-openblas <path-to-OpenBLAS>
Advanced users can also invoke install.py --help
to see options for
configuring cuNumeric by invoking the install.py
script directly.
Note that after the first invocation of setup.py
or install.py
this
repository will remember the paths you provided with the installation options
and they can be omitted in subsequent invocations unless you want to change
them.
Using cuNumeric as a replacement for NumPy is easy. Users only need to replace:
import numpy as np
with:
import cunumeric as np
These programs can then be run by the Legate driver script described in the Legate Core documentation.
legate cunumeric_program.py
For execution with multiple nodes (assuming Legate Core is installed with GASNet support)
users can supply the --nodes
option. For execution with GPUs, users can use the
--gpus
flags to specify the number of GPUs to use per node. We encourage all users
to familiarize themselves with these resource flags as described in the Legate Core
documentation or simply by passing --help
to the legate
driver script.
You can use test.py
to run the test suite. This script will invoke the legate
driver script automatically. Check out test.py --help
for further options.
cuNumeric is currently a work in progress and we are gradually adding support for additional NumPy operators. Unsupported NumPy operations will provide a warning that we are falling back to canonical NumPy. Please report unimplemented features that are necessary for attaining good performance so that we can triage them and prioritize implementation appropriately. The more users that report an unimplemented feature, the more we will prioritize it. Please include a pointer to your code if possible too so we can see how you are using the feature in context.
cuNumeric currently supports the following NumPy types: float16
, float32
,
float64
, int16
, int32
, int64
, uint16
, uint32
, uint64
, bool
,
complex64
, and complex128
.
cuNumeric supports up to 4D arrays by default, you can adjust this setting by
installing legate.core with a larger --max-dim
.
A complete list of available features can is provided in the API reference.
There are three primary directions that we plan to investigate with cuNumeric going forward:
- More features: we plan to identify a few key lighthouse applications and use the demands of these applications to drive the addition of new features to cuNumeric.
- We plan to add support for sharded file I/O for loading and storing large data sets that could never be loaded on a single node. Initially this will begin with native support for h5py but will grow to accommodate other formats needed by our lighthouse applications.
- Strong scaling: while cuNumeric is currently implemented in a way that enables weak scaling of codes on larger data sets, we would also like to make it possible to strong-scale Legate applications for a single problem size. This will require leveraging some of the more advanced features of Legion from inside the Python interpreter.
We are open to comments, suggestions, and ideas.
See the discussion of contributing in CONTRIBUTING.md.
- When using certain operations with high scratch space requirements (e.g.
einsum
orconvolve
) you might run into the following error:Currently, Legion splits its memory reservations between two pools: the "deferred" pool, used for allocating cuNumericLEGION ERROR: Failed to allocate DeferredBuffer/Value/Reduction in task [some task] because [some memory] is full. This is an eager allocation ...
ndarray
s, and the "eager" pool, used for allocating scratch memory for operations. The above error message signifies that not enough memory was available for an operation's scratch space requirements. You can work around this by allocating more memory overall to cuNumeric (e.g. adjusting--sysmem
,--numamem
or--fbmem
), and/or by adjusting the split between the two pools (e.g. by passing-lg:eager_alloc_percentage 60
on the command line to allocate 60% of memory to the eager pool, up from the default of 50%). - cuNumeric can exercise a bug in OpenBLAS when it is run with multiple OpenMP processors
- On Mac OSX, cuNumeric can trigger a bug in Apple's implementation of libc++. The bug has since been fixed but likely will not show up on most Apple machines for quite some time. You may have to manually patch your implementation of libc++. If you have trouble doing this please contact us and we will be able to help you.