This project is participating in the LLVM Incubator process: as such, it is not part of any official LLVM release. While incubation status is not necessarily a reflection of the completeness or stability of the code, it does indicate that the project is not yet endorsed as a component of LLVM.

The NPComp project aims to provide tooling for compiling numerical python programs of various forms to take advantage of MLIR+LLVM code generation and backend runtime systems.

In addition to providing a bridge to a variety of Python based numerical programming frameworks, NPComp also directly develops components for tracing and compilation of generic Python program fragments.

Instructions below go in to detail about how to get a functioning development setup. But to just build and install into a local python instance, the instructions are simple. This support is new and we still need to get dependencies pinned and make these packages distributable. This should work locally, though:

python -m pip install --pre torch torchvision -f https://download.pytorch.org/whl/nightly/cpu/torch_nightly.html

./build_tools/build_python_wheels.sh

• #mlir-npcomp channel on the LLVM Discord
• issues/PR's on this github repo
• mlir-npcomp section of LLVM Discourse

• PyTorch -- Experimental integration for extracting programs from PyTorch.

At the core of NPComp are a set of dialects and python support code for tracing (define by run) numerical programs and compiling idiomatic subsets of the Python language. As another interpretation of the name, NPComp also seeks to provide compiler-backed support for Numpy APIs.

See the features doc for a semi-curated status of what is implemented in this area.

The compiler is separated into:

• Frontend importer: Translates from various AST levels to corresponding MLIR dialects.
• Frontend compiler: MLIR passes and conversions, mostly operating on the basicpy and numpy dialects.
• Backend compiler and runtime: Some effort has been taken to make this pluggable, but right now, only the IREE Backend exists. There is in-tree work to also build a minimal reference backend directly targeting LLVM.

The project is roughly split into the following areas of code:

• User-facing Python code
• C++ include and lib trees, following LLVM/MLIR conventions
• LIT testing trees:
  • test: Lit/FileCheck tests covering core MLIR based infra
  • test/Python/Compiler: Lit test suite that drive the compiler infra from Python
  • backend_test: Lit test suites conditionally enabled for each backend
• tools: Scripts and binaries (npcomp-opt, refback-run, etc)

The cmake configuration populates symlinks in the build/python directory mirroring the source layout. This allows edit-run without rebuilding (unless if files are added/removed).

For using with any interactive tooling (python3, Jupyter/Colab, etc) it should be sufficient to add python_packages/npcomp_torch/ and python_packages/npcomp_core/ directories under build directory to PYTHONPATH

export PYTHONPATH=$(cd build && pwd)/python_packages/npcomp_torch:$(cd build && pwd)/python_packages/npcomp_core

Note that running the build_tools/write_env_file.sh script will output a .env file in the workspace folder with the correct PYTHONPATH set. This allows tools like VSCode to work by default for debugging.

Notes:

• Python sources are symlinked to the output directory at configure time. Adding sources will require a reconfigure. Editing should not.
• It is a very common issue to have both python 2.7 (aka. "python") and python 3.x (aka. "python3") on a system at a time (and we can only hope that one day this ends). Since the native library at development time binds to a specific version, if you try to run with a different python, you will get an error about the "native" module not being found.

For bash users, adding the following to your .bashrc defines some aliases that are useful during compiler development, such as shortcuts for builing and running npcomp-opt.

source $WHERE_YOU_CHECKED_OUT_NPCOMP/tools/bash_helpers.sh

# From checkout directory.
git submodule init
git submodule update

# Use clang and lld to build (optional but recommended).
LLVM_VERSION=10
export CC=clang-$LLVM_VERSION
export CXX=clang++-$LLVM_VERSION
export LDFLAGS=-fuse-ld=$(which ld.lld-$LLVM_VERSION)

# run write_env_file.sh to emit a .env file with needed
# PYTHONPATH setup.
./build_tools/write_env_file.sh

# Configure npcomp.
cmake -GNinja -Bbuild -DCMAKE_BUILD_TYPE=Release .

# Build and run tests
# ./build_tools/test_all.sh runs all of these commands.
cd build
ninja
ninja check-npcomp

# Install PyTorch. We currently track and require the nighly build.
# If a usable PyTorch package is installed, the default cmake settings will
# enable the PyTorch frontend.
pip3 install --pre torch torchvision -f https://download.pytorch.org/whl/nightly/cpu/torch_nightly.html

cmake -DNPCOMP_ENABLE_PYTORCH=ON ...
ninja check-frontends-pytorch  # If building with PyTorch

Create docker image (or follow your own preferences):

• Mount the (host) source directory to /src/mlir-npcomp (in the container).
• Mount the /build directory (in the container) appropriately for your case.

docker build docker/pytorch-nightly --tag local/npcomp:build-pytorch-nightly
docker volume create npcomp-build

Shell into docker image:

docker run \
  --mount type=bind,source=path/to/mlir-npcomp,target=/src/mlir-npcomp \
  --mount source=npcomp-build,target=/build \
  --rm -it local/npcomp:build-pytorch-nightly /bin/bash

Build/test npcomp (from within docker image):

# From within the docker image.
cd /src/mlir-npcomp
cmake -GNinja -B/build/npcomp -DCMAKE_BUILD_TYPE=Release -DNPCOMP_ENABLE_PYTORCH=ON .
cmake --build /build/npcomp --target check-npcomp check-frontends-pytorch

# We currently track and require the latest snapshot.
pip3 install iree-compiler-snapshot iree-runtime-snapshot -f https://github.com/google/iree/releases

# Run TorchScript E2E tests targeting IREE.
# Make sure to run "PyTorch Frontend" setup instructions first.
tools/torchscript_e2e_test.sh --config=iree

This configuration is useful for iterating locally, as you can poke/debug/rebuild things in IREE.

# Locally build IREE.
# See https://google.github.io/iree/building-from-source/getting-started/
# Make sure IREE is configured with `-DIREE_BUILD_PYTHON_BINDINGS=ON`.

# Add IREE's Python bindings to PYTHONPATH.
echo 'PYTHONPATH="${PYTHONPATH}:/path/to/iree-build/bindings/python"' >> .env

# Run TorchScript E2E tests targeting IREE.
# Make sure to run "PyTorch Frontend" setup instructions first.
tools/torchscript_e2e_test.sh --config=iree

Some end-to-end tests require additional dependencies which don't make sense to include as part of the default npcomp setup. Additionally, these dependencies often don't work with the same HEAD PyTorch version that npcomp builds against at the C++ level.

We have a self-contained script that generates all the needed artifacts from a self-contained virtual environment. It can be used like so:

# Build the virtual environment in the specified directory and generate the
# serialized test artifacts in the other specified directory.
# This command is safe to re-run if you have already built the virtual
# environment and just changed the tests.
build_tools/torchscript_e2e_heavydep_tests/generate_serialized_tests.sh \
  path/to/heavydep_venv \
  path/to/heavydep_serialized_tests

# Add the --serialized-test-dir flag to point at the directory containing the
# serialized tests. All other functionality is the same as the normal invocation
# of torchscript_e2e_test.sh, but the serialized tests will be available.
tools/torchscript_e2e_test.sh --serialized-test-dir=path/to/heavydep_serialized_tests

The tests use the same (pure-Python) test framework as the normal torchscript_e2e_test.sh, but the tests are added in build_tools/torchscript_e2e_heavydep_tests instead of frontends/pytorch/e2e_testing/torchscript.

We rely critically on serialized TorchScript compatibility across PyTorch versions to transport the tests + pure-Python compatibility of the torch API, which has worked well so far.

Assumes that mlir-npcomp is checked out locally under ~/src/mlir-npcomp. See docker_shell_funcs.sh for commands to modify if different.

# Build/start the container.
# Follow instructions here to allow running `docker` without `sudo`:
# https://docs.docker.com/engine/install/linux-postinstall/
source ./build_tools/docker_shell_funcs.sh
npcomp_docker_build  # Only needed first time/on updates to docker files.
npcomp_docker_start

# Get an interactive shell to the container and initial build.
npcomp_docker_login

# Stop the container (when done).
npcomp_docker_stop

First, install the VSCode Docker extension and VSCode Remote - Containers extension. Follow instructions here to allow running docker without sudo, otherwise VSCode won't be able to use docker https://docs.docker.com/engine/install/linux-postinstall/ (Note that VSCode has some daemons that you will need to kill/restart for the instructions there to take effect; consider just rebooting your machine)

Attach to your running container by opening the Docker extension tab (left panel), right clicking on the container name, and selecting "Attach Visual Studio code". The container name if you are using docker_shell_funcs.sh is npcomp.

Install extensions in container:

• CMake Tools
• C/C++
• C++ Intellisense

• mlir-npcomp source folder
• external/llvm-project source folder

Ctrl-Shift-P > Preferences: Open Settings (UI)

• For mlir-npcomp folder:
  • Cmake: Build directory: /build/npcomp
  • Uncheck Cmake: Configure On Edit and Cmake: Configure on Open
• For llvm-project folder:
  • Cmake: Build directory: /build/llvm-build
  • Uncheck Cmake: Configure On Edit and Cmake: Configure on Open

Ctrl-Shift-P > C/C++: Edit Configurations (UI)

• Open C/C++ config (for each project folder):
  • Under Advanced, Compile Commands:
    • set /build/npcomp/compile_commands.json for mlir-npcomp
    • set /build/llvm-build/compile_commands.json for llvm-project
• Open a C++ file, give it a few seconds and see if you get code completion (press CTRL-Space).

Make sure to save your workspace (prefer a local folder with the "Use Local" button)!