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Branches Tags
zhangyiss:main zhangyiss:ibv-backend zhangyiss:ibv-backend-test zhangyiss:jit-nax zhangyiss:sign-warns zhangyiss:gh-pages zhangyiss:simple-gemm zhangyiss:jagrit06/cuda-gemm-experiment zhangyiss:sdpav-backup zhangyiss:qmm zhangyiss:ring-init zhangyiss:cuda-sdpa-vector zhangyiss:fft zhangyiss:split_logsumexp zhangyiss:sdpa-test zhangyiss:steel-refactor zhangyiss:gguf_q4_k zhangyiss:interrupt_eval zhangyiss:cpp20 zhangyiss:q-sdpa
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zhangyiss:main zhangyiss:ibv-backend zhangyiss:ibv-backend-test zhangyiss:jit-nax zhangyiss:sign-warns zhangyiss:gh-pages zhangyiss:simple-gemm zhangyiss:jagrit06/cuda-gemm-experiment zhangyiss:sdpav-backup zhangyiss:qmm zhangyiss:ring-init zhangyiss:cuda-sdpa-vector zhangyiss:fft zhangyiss:split_logsumexp zhangyiss:sdpa-test zhangyiss:steel-refactor zhangyiss:gguf_q4_k zhangyiss:interrupt_eval zhangyiss:cpp20 zhangyiss:q-sdpa
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1 Commits
ca7970a4f1 ... ring-init

Author SHA1 Message Date
Angelos Katharopoulos
a9c720e8cd Improve the ring backend initialization 2025-07-11 15:31:28 -07:00
354 changed files with 5647 additions and 18211 deletions
Expand all files Collapse all files

515
.circleci/config.yml
View File

@@ -7,9 +7,18 @@ parameters:
nightly_build:
type: boolean
default: false
weekly_build:
type: boolean
default: false
test_release:
type: boolean
default: false
linux_release:
type: boolean
default: false
cuda_release:
type: boolean
default: false
jobs:
build_documentation:
@@ -18,14 +27,13 @@ jobs:
type: boolean
default: false
macos:
xcode: "26.0.0"
resource_class: m4pro.medium
xcode: "16.2.0"
resource_class: m2pro.medium
steps:
- checkout
- run:
name: Install
command: |
xcodebuild -downloadComponent MetalToolchain
brew install python@3.9
brew install doxygen
python3.9 -m venv env
@@ -65,9 +73,9 @@ jobs:
git push -f origin gh-pages
linux_build_and_test:
machine:
image: ubuntu-2204:current
resource_class: large
docker:
- image: cimg/python:3.9
steps:
- checkout
- run:
@@ -79,36 +87,34 @@ jobs:
- run:
name: Install dependencies
command: |
export DEBIAN_FRONTEND=noninteractive
export NEEDRESTART_MODE=a
pip install --upgrade cmake
pip install nanobind==2.4.0
pip install numpy
sudo apt-get update
sudo apt-get install -y libblas-dev liblapack-dev liblapacke-dev
sudo apt-get install libblas-dev liblapack-dev liblapacke-dev
sudo apt-get install openmpi-bin openmpi-common libopenmpi-dev
curl -LsSf https://astral.sh/uv/install.sh | sh
- run:
name: Install Python package
command: |
uv venv
uv pip install cmake
DEBUG=1 CMAKE_ARGS="-DCMAKE_COMPILE_WARNING_AS_ERROR=ON" \
uv pip install -e ".[dev]" -v
CMAKE_ARGS="-DMLX_BUILD_METAL=OFF" \
python3 setup.py build_ext --inplace
CMAKE_ARGS="-DMLX_BUILD_METAL=OFF" \
python3 setup.py develop
- run:
name: Generate package stubs
command: |
uv pip install typing_extensions
uv run --no-project setup.py generate_stubs
echo "stubs"
pip install typing_extensions
python setup.py generate_stubs
- run:
name: Run Python tests
command: |
source .venv/bin/activate
python -m unittest discover python/tests -v
python3 -m unittest discover python/tests -v
mpirun --bind-to none -host localhost:8 -np 8 python python/tests/mpi_test_distributed.py
mlx.launch --verbose -n 8 python/tests/ring_test_distributed.py -v 2> >(tee -a stderr.log >&2)
if $(grep "\[WARN\]" stderr.log); then echo "Distributed ring test failed"; exit 1; fi
mlx.launch --verbose -n 8 python/tests/ring_test_distributed.py
- run:
name: Build CPP only
command: |
source .venv/bin/activate
mkdir -p build && cd build
cmake .. -DMLX_BUILD_METAL=OFF -DCMAKE_BUILD_TYPE=DEBUG
make -j `nproc`
@@ -120,7 +126,7 @@ jobs:
parameters:
xcode_version:
type: string
default: "26.0.0"
default: "16.2.0"
macosx_deployment_target:
type: string
default: ""
@@ -128,56 +134,56 @@ jobs:
xcode: << parameters.xcode_version >>
environment:
MACOSX_DEPLOYMENT_TARGET: << parameters.macosx_deployment_target >>
resource_class: m4pro.medium
resource_class: m2pro.medium
steps:
- checkout
- run:
name: Install dependencies
command: |
xcodebuild -downloadComponent MetalToolchain
HOMEBREW_NO_AUTO_UPDATE=1 HOMEBREW_NO_INSTALL_CLEANUP=1 \
brew install openmpi uv
brew install python@3.9
brew install openmpi
python3.9 -m venv env
source env/bin/activate
pip install --upgrade pip
pip install --upgrade cmake
pip install nanobind==2.4.0
pip install numpy
pip install torch
pip install tensorflow
pip install unittest-xml-reporting
- run:
name: Install Python package
command: |
uv venv --python 3.9
uv pip install \
nanobind==2.4.0 \
cmake \
numpy \
torch \
tensorflow \
unittest-xml-reporting
source env/bin/activate
DEBUG=1 CMAKE_ARGS="-DCMAKE_COMPILE_WARNING_AS_ERROR=ON" \
uv pip install -e . -v
pip install -e . -v
- run:
name: Generate package stubs
command: |
uv pip install typing_extensions
uv run --no-project setup.py generate_stubs
source env/bin/activate
pip install typing_extensions
python setup.py generate_stubs
- run:
name: Run Python tests
command: |
source .venv/bin/activate
source env/bin/activate
LOW_MEMORY=1 DEVICE=cpu python -m xmlrunner discover -v python/tests -o test-results/cpu
LOW_MEMORY=1 DEVICE=gpu METAL_DEVICE_WRAPPER_TYPE=1 METAL_DEBUG_ERROR_MODE=0 python -m xmlrunner discover -v python/tests -o test-results/gpu
mpirun --bind-to none -host localhost:8 -np 8 -x DYLD_LIBRARY_PATH=/opt/homebrew/lib/ python python/tests/mpi_test_distributed.py
mlx.launch --verbose -n 8 python/tests/ring_test_distributed.py -v 2> >(tee -a stderr.log >&2)
if $(grep "\[WARN\]" stderr.log); then echo "Distributed ring test failed"; exit 1; fi
mlx.launch --verbose -n 8 python/tests/ring_test_distributed.py
- run:
name: Build example extension
command: |
source .venv/bin/activate
source env/bin/activate
cd examples/extensions
uv pip install -r requirements.txt
uv run --no-project setup.py build_ext --inplace
uv run --no-project python test.py
pip install -r requirements.txt
python setup.py build_ext -j8
- store_test_results:
path: test-results
- run:
name: Build CPP only
command: |
source .venv/bin/activate
source env/bin/activate
mkdir -p build && cd build && cmake .. && make -j `sysctl -n hw.ncpu`
- run:
name: Run CPP tests
@@ -186,7 +192,7 @@ jobs:
- run:
name: Build small binary
command: |
source .venv/bin/activate
source env/bin/activate
cd build/
cmake .. -DCMAKE_BUILD_TYPE=MinSizeRel \
-DBUILD_SHARED_LIBS=ON \
@@ -198,76 +204,34 @@ jobs:
- run:
name: Run Python tests with JIT
command: |
source env/bin/activate
CMAKE_ARGS="-DMLX_METAL_JIT=ON" \
uv pip install -e . -v
pip install -e . -v
LOW_MEMORY=1 DEVICE=gpu METAL_DEVICE_WRAPPER_TYPE=1 \
METAL_DEBUG_ERROR_MODE=0 \
uv run --no-project python -m xmlrunner discover \
-v python/tests \
-o test-results/gpu_jit
python -m xmlrunner discover -v python/tests -o test-results/gpu_jit
cuda_build_and_test:
parameters:
image_date:
type: string
default: "2023.11.1"
machine:
image: "linux-cuda-12:<< parameters.image_date >>"
image: linux-cuda-12:default
resource_class: gpu.nvidia.small.gen2
steps:
- checkout
- restore_cache:
keys:
- cuda-<< parameters.image_date >>-{{ arch }}-
- run:
name: Install dependencies
command: |
sudo apt-get update
sudo apt-get install libcudnn9-dev-cuda-12
sudo apt-get install libblas-dev liblapack-dev liblapacke-dev
sudo apt-get install libnccl2 libnccl-dev
curl -sL https://github.com/ccache/ccache/releases/download/v4.11.3/ccache-4.11.3-linux-x86_64.tar.xz | tar xJf -
sudo mv ccache-4.11.3-linux-x86_64/ccache /usr/bin/ccache
rm -rf ccache-4.11.3-linux-x86_64
curl -LsSf https://astral.sh/uv/install.sh | sh
- run:
name: Set CCache size
command: ccache --max-size 1G
- run:
name: Install Python package
command: |
uv venv
uv pip install cmake
DEBUG=1 CMAKE_ARGS="-DMLX_BUILD_CUDA=ON -DCMAKE_COMPILE_WARNING_AS_ERROR=ON -DCMAKE_CUDA_COMPILER=`which nvcc`" \
uv pip install -e ".[dev]" -v
sudo apt-get update
sudo apt-get install libblas-dev liblapack-dev liblapacke-dev
python -m venv env
source env/bin/activate
CMAKE_ARGS="-DMLX_BUILD_CUDA=ON -DCMAKE_CUDA_COMPILER=`which nvcc`" \
pip install -e ".[dev]"
- run:
name: Run Python tests
command: |
source .venv/bin/activate
source env/bin/activate
LOW_MEMORY=1 DEVICE=cpu python -m unittest discover python/tests -v
LOW_MEMORY=1 DEVICE=gpu python -m tests discover python/tests -v
- run:
name: Build CPP only
command: |
source .venv/bin/activate
cmake . -B build \
-DMLX_BUILD_CUDA=ON \
-DCMAKE_CUDA_COMPILER=`which nvcc` \
-DCMAKE_BUILD_TYPE=DEBUG
cmake --build build -j `nproc`
- run:
name: Run CPP tests
command: ./build/tests/tests -sfe="*fft_tests.cpp,*linalg_tests.cpp"
- run:
name: CCache report
command: |
ccache --show-stats
ccache --zero-stats
ccache --cleanup
- save_cache:
key: cuda-<< parameters.image_date >>-{{ arch }}-{{ epoch }}
paths:
- /home/circleci/.cache/ccache
build_release:
parameters:
@@ -276,7 +240,7 @@ jobs:
default: "3.9"
xcode_version:
type: string
default: "26.0.0"
default: "16.2.0"
build_env:
type: string
default: ""
@@ -285,7 +249,7 @@ jobs:
default: ""
macos:
xcode: << parameters.xcode_version >>
resource_class: m4pro.medium
resource_class: m2pro.medium
environment:
MACOSX_DEPLOYMENT_TARGET: << parameters.macosx_deployment_target >>
steps:
@@ -293,15 +257,11 @@ jobs:
- run:
name: Install dependencies
command: |
xcodebuild -downloadComponent MetalToolchain
mkdir -p ~/miniconda3
curl https://repo.anaconda.com/miniconda/Miniconda3-latest-MacOSX-arm64.sh -o ~/miniconda3/miniconda.sh
bash ~/miniconda3/miniconda.sh -b -u -p ~/miniconda3
rm ~/miniconda3/miniconda.sh
source ~/miniconda3/bin/activate
conda init --all
conda create -n env python=<< parameters.python_version >> -y
conda activate env
brew install python@<< parameters.python_version >>
brew install openmpi
python<< parameters.python_version >> -m venv env
source env/bin/activate
pip install --upgrade pip
pip install --upgrade cmake
pip install nanobind==2.4.0
pip install --upgrade setuptools
@@ -311,38 +271,27 @@ jobs:
- run:
name: Install Python package
command: |
conda activate env
source env/bin/activate
env -u MACOSX_DEPLOYMENT_TARGET DEV_RELEASE=1 \
pip install . -v
- run:
name: Generate package stubs
command: |
conda activate env
source env/bin/activate
pip install typing_extensions
python setup.py generate_stubs
- run:
name: Build Python package
command: |
conda activate env
python setup.py clean --all
<< parameters.build_env >> MLX_BUILD_STAGE=1 python -m build -w
- when:
condition:
equal: ["3.9", << parameters.python_version >>]
steps:
- run:
name: Build common package
command: |
conda activate env
python setup.py clean --all
<< parameters.build_env >> MLX_BUILD_STAGE=2 python -m build -w
source env/bin/activate
<< parameters.build_env >> python -m build -w
- when:
condition: << parameters.build_env >>
steps:
- run:
name: Upload package
command: |
conda activate env
source env/bin/activate
twine upload dist/*
- store_artifacts:
path: dist/
@@ -352,99 +301,87 @@ jobs:
python_version:
type: string
default: "3.9"
build_env:
extra_env:
type: string
default: ""
machine:
image: ubuntu-2204:current
resource_class: large
default: "DEV_RELEASE=1"
docker:
- image: ubuntu:20.04
steps:
- checkout
- run:
name: Build wheel
command: |
PYTHON=python<< parameters.python_version >>
export DEBIAN_FRONTEND=noninteractive
export NEEDRESTART_MODE=a
sudo apt-get update
TZ=Etc/UTC sudo apt-get -y install tzdata
sudo add-apt-repository -y ppa:deadsnakes/ppa
sudo apt-get install -y $PYTHON $PYTHON-dev $PYTHON-full
sudo apt-get install -y libblas-dev liblapack-dev liblapacke-dev
apt-get update
apt-get upgrade -y
DEBIAN_FRONTEND=noninteractive TZ=Etc/UTC apt-get -y install tzdata
apt-get install -y apt-utils
apt-get install -y software-properties-common
add-apt-repository -y ppa:deadsnakes/ppa
apt-get install -y $PYTHON $PYTHON-dev $PYTHON-full
apt-get install -y libblas-dev liblapack-dev liblapacke-dev
apt-get install -y build-essential git
$PYTHON -m venv env
source env/bin/activate
pip install --upgrade pip
pip install --upgrade cmake
pip install nanobind==2.4.0
pip install --upgrade setuptools
pip install numpy
pip install auditwheel
pip install patchelf
pip install build
pip install twine
<< parameters.build_env >> pip install ".[dev]" -v
<< parameters.extra_env >> pip install . -v
pip install typing_extensions
python setup.py generate_stubs
python setup.py clean --all
MLX_BUILD_STAGE=1 << parameters.build_env >> python -m build -w
bash python/scripts/repair_linux.sh
- when:
condition:
equal: ["3.9", << parameters.python_version >>]
steps:
<< parameters.extra_env >> python -m build --wheel
auditwheel show dist/*
auditwheel repair dist/* --plat manylinux_2_31_x86_64
- run:
name: Build common package
name: Upload package
command: |
source env/bin/activate
python setup.py clean --all
<< parameters.build_env >> MLX_BUILD_STAGE=2 \
python -m build -w
auditwheel repair dist/mlx_cpu*.whl --plat manylinux_2_35_x86_64
- when:
condition: << parameters.build_env >>
steps:
- run:
name: Upload packages
command: |
source env/bin/activate
twine upload wheelhouse/*.whl
twine upload wheelhouse/*
- store_artifacts:
path: wheelhouse/
build_cuda_release:
parameters:
build_env:
python_version:
type: string
default: ""
default: "3.9"
extra_env:
type: string
default: "DEV_RELEASE=1"
machine:
image: ubuntu-2204:current
resource_class: xlarge
image: linux-cuda-12:default
resource_class: gpu.nvidia.small.gen2
steps:
- checkout
- run:
name: Build wheel
command: |
export DEBIAN_FRONTEND=noninteractive
export NEEDRESTART_MODE=a
wget https://developer.download.nvidia.com/compute/cuda/repos/ubuntu2404/x86_64/cuda-keyring_1.1-1_all.deb
sudo dpkg -i cuda-keyring_1.1-1_all.deb
sudo apt-get update
sudo apt-get install cuda-toolkit-12-9 libcudnn9-dev-cuda-12
sudo apt-get install libblas-dev liblapack-dev liblapacke-dev
sudo apt-get install zip
python -m venv env
source env/bin/activate
pip install auditwheel
pip install patchelf
pip install build
pip install twine
export PATH=/usr/local/cuda/bin${PATH:+:${PATH}}
export LD_LIBRARY_PATH=/usr/local/cuda/lib64${LD_LIBRARY_PATH:+:${LD_LIBRARY_PATH}}
<< parameters.build_env >> MLX_BUILD_STAGE=2 \
<< parameters.extra_env >> \
CMAKE_ARGS="-DMLX_BUILD_CUDA=ON -DCMAKE_CUDA_COMPILER=`which nvcc`" \
python -m build -w
pip install ".[dev]" -v
python setup.py generate_stubs
<< parameters.extra_env >> \
CMAKE_ARGS="-DMLX_BUILD_CUDA=ON -DCMAKE_CUDA_COMPILER=`which nvcc`" \
python -m build --wheel
bash python/scripts/repair_cuda.sh
- when:
condition: << parameters.build_env >>
steps:
- run:
name: Upload package
command: |
source env/bin/activate
twine upload wheelhouse/*.whl
- store_artifacts:
path: wheelhouse/
@@ -457,23 +394,22 @@ workflows:
pattern: "^(?!pull/)[-\\w]+$"
value: << pipeline.git.branch >>
- not: << pipeline.parameters.nightly_build >>
- not: << pipeline.parameters.weekly_build >>
- not: << pipeline.parameters.test_release >>
jobs:
- mac_build_and_test:
matrix:
parameters:
macosx_deployment_target: ["13.5", "15.0"]
macosx_deployment_target: ["13.5", "14.0"]
- linux_build_and_test
- cuda_build_and_test:
matrix:
parameters:
image_date: ["2023.11.1", "2025.05.1"]
- cuda_build_and_test
- build_documentation
build_pypi_release:
when:
and:
- not: << pipeline.parameters.nightly_build >>
- not: << pipeline.parameters.weekly_build >>
- not: << pipeline.parameters.test_release >>
jobs:
- build_release:
@@ -487,7 +423,68 @@ workflows:
python_version: ["3.9", "3.10", "3.11", "3.12", "3.13"]
macosx_deployment_target: ["13.5", "14.0", "15.0"]
build_env: ["PYPI_RELEASE=1"]
xcode_version: ["26.0.0"]
xcode_version: ["16.2.0", "15.0.0"]
exclude:
- macosx_deployment_target: "13.5"
xcode_version: "16.2.0"
python_version: "3.9"
build_env: "PYPI_RELEASE=1"
- macosx_deployment_target: "13.5"
xcode_version: "16.2.0"
python_version: "3.10"
build_env: "PYPI_RELEASE=1"
- macosx_deployment_target: "13.5"
xcode_version: "16.2.0"
python_version: "3.11"
build_env: "PYPI_RELEASE=1"
- macosx_deployment_target: "13.5"
xcode_version: "16.2.0"
python_version: "3.12"
build_env: "PYPI_RELEASE=1"
- macosx_deployment_target: "13.5"
xcode_version: "16.2.0"
python_version: "3.13"
build_env: "PYPI_RELEASE=1"
- macosx_deployment_target: "14.0"
xcode_version: "15.0.0"
python_version: "3.9"
build_env: "PYPI_RELEASE=1"
- macosx_deployment_target: "14.0"
xcode_version: "15.0.0"
python_version: "3.10"
build_env: "PYPI_RELEASE=1"
- macosx_deployment_target: "14.0"
xcode_version: "15.0.0"
python_version: "3.11"
build_env: "PYPI_RELEASE=1"
- macosx_deployment_target: "14.0"
xcode_version: "15.0.0"
python_version: "3.12"
build_env: "PYPI_RELEASE=1"
- macosx_deployment_target: "14.0"
xcode_version: "15.0.0"
python_version: "3.13"
build_env: "PYPI_RELEASE=1"
- macosx_deployment_target: "15.0"
xcode_version: "15.0.0"
python_version: "3.9"
build_env: "PYPI_RELEASE=1"
- macosx_deployment_target: "15.0"
xcode_version: "15.0.0"
python_version: "3.10"
build_env: "PYPI_RELEASE=1"
- macosx_deployment_target: "15.0"
xcode_version: "15.0.0"
python_version: "3.11"
build_env: "PYPI_RELEASE=1"
- macosx_deployment_target: "15.0"
xcode_version: "15.0.0"
python_version: "3.12"
build_env: "PYPI_RELEASE=1"
- macosx_deployment_target: "15.0"
xcode_version: "15.0.0"
python_version: "3.13"
build_env: "PYPI_RELEASE=1"
- build_documentation:
filters:
tags:
@@ -504,16 +501,7 @@ workflows:
matrix:
parameters:
python_version: ["3.9", "3.10", "3.11", "3.12", "3.13"]
build_env: ["PYPI_RELEASE=1"]
- build_cuda_release:
filters:
tags:
only: /^v.*/
branches:
ignore: /.*/
matrix:
parameters:
build_env: ["PYPI_RELEASE=1"]
extra_env: ["PYPI_RELEASE=1"]
prb:
when:
@@ -529,14 +517,11 @@ workflows:
requires: [ hold ]
matrix:
parameters:
macosx_deployment_target: ["13.5", "15.0"]
macosx_deployment_target: ["13.5", "14.0"]
- linux_build_and_test:
requires: [ hold ]
- cuda_build_and_test:
requires: [ hold ]
matrix:
parameters:
image_date: ["2023.11.1", "2025.05.1"]
nightly_build:
when:
and:
@@ -548,18 +533,58 @@ workflows:
parameters:
python_version: ["3.9", "3.10", "3.11", "3.12", "3.13"]
macosx_deployment_target: ["13.5", "14.0", "15.0"]
xcode_version: ["26.0.0"]
- build_linux_release:
matrix:
parameters:
python_version: ["3.9", "3.10", "3.11", "3.12", "3.13"]
- build_cuda_release
build_dev_release:
xcode_version: ["16.2.0", "15.0.0"]
exclude:
- macosx_deployment_target: "13.5"
xcode_version: "16.2.0"
python_version: "3.9"
- macosx_deployment_target: "13.5"
xcode_version: "16.2.0"
python_version: "3.10"
- macosx_deployment_target: "13.5"
xcode_version: "16.2.0"
python_version: "3.11"
- macosx_deployment_target: "13.5"
xcode_version: "16.2.0"
python_version: "3.12"
- macosx_deployment_target: "13.5"
xcode_version: "16.2.0"
python_version: "3.13"
- macosx_deployment_target: "14.0"
xcode_version: "15.0.0"
python_version: "3.9"
- macosx_deployment_target: "14.0"
xcode_version: "15.0.0"
python_version: "3.10"
- macosx_deployment_target: "14.0"
xcode_version: "15.0.0"
python_version: "3.11"
- macosx_deployment_target: "14.0"
xcode_version: "15.0.0"
python_version: "3.12"
- macosx_deployment_target: "14.0"
xcode_version: "15.0.0"
python_version: "3.13"
- macosx_deployment_target: "15.0"
xcode_version: "15.0.0"
python_version: "3.9"
- macosx_deployment_target: "15.0"
xcode_version: "15.0.0"
python_version: "3.10"
- macosx_deployment_target: "15.0"
xcode_version: "15.0.0"
python_version: "3.11"
- macosx_deployment_target: "15.0"
xcode_version: "15.0.0"
python_version: "3.12"
- macosx_deployment_target: "15.0"
xcode_version: "15.0.0"
python_version: "3.13"
weekly_build:
when:
and:
- equal: [ main, << pipeline.git.branch >> ]
- << pipeline.parameters.test_release >>
- << pipeline.parameters.weekly_build >>
jobs:
- build_release:
matrix:
@@ -567,13 +592,87 @@ workflows:
python_version: ["3.9", "3.10", "3.11", "3.12", "3.13"]
macosx_deployment_target: ["13.5", "14.0", "15.0"]
build_env: ["DEV_RELEASE=1"]
xcode_version: ["26.0.0"]
xcode_version: ["16.2.0", "15.0.0"]
exclude:
- macosx_deployment_target: "13.5"
xcode_version: "16.2.0"
python_version: "3.9"
build_env: "DEV_RELEASE=1"
- macosx_deployment_target: "13.5"
xcode_version: "16.2.0"
python_version: "3.10"
build_env: "DEV_RELEASE=1"
- macosx_deployment_target: "13.5"
xcode_version: "16.2.0"
python_version: "3.11"
build_env: "DEV_RELEASE=1"
- macosx_deployment_target: "13.5"
xcode_version: "16.2.0"
python_version: "3.12"
build_env: "DEV_RELEASE=1"
- macosx_deployment_target: "13.5"
xcode_version: "16.2.0"
python_version: "3.13"
build_env: "DEV_RELEASE=1"
- macosx_deployment_target: "14.0"
xcode_version: "15.0.0"
python_version: "3.9"
build_env: "DEV_RELEASE=1"
- macosx_deployment_target: "14.0"
xcode_version: "15.0.0"
python_version: "3.10"
build_env: "DEV_RELEASE=1"
- macosx_deployment_target: "14.0"
xcode_version: "15.0.0"
python_version: "3.11"
build_env: "DEV_RELEASE=1"
- macosx_deployment_target: "14.0"
xcode_version: "15.0.0"
python_version: "3.12"
build_env: "DEV_RELEASE=1"
- macosx_deployment_target: "14.0"
xcode_version: "15.0.0"
python_version: "3.13"
build_env: "DEV_RELEASE=1"
- macosx_deployment_target: "15.0"
xcode_version: "15.0.0"
python_version: "3.9"
build_env: "DEV_RELEASE=1"
- macosx_deployment_target: "15.0"
xcode_version: "15.0.0"
python_version: "3.10"
build_env: "DEV_RELEASE=1"
- macosx_deployment_target: "15.0"
xcode_version: "15.0.0"
python_version: "3.11"
build_env: "DEV_RELEASE=1"
- macosx_deployment_target: "15.0"
xcode_version: "15.0.0"
python_version: "3.12"
build_env: "DEV_RELEASE=1"
- macosx_deployment_target: "15.0"
xcode_version: "15.0.0"
python_version: "3.13"
build_env: "DEV_RELEASE=1"
linux_test_release:
when:
and:
- equal: [ main, << pipeline.git.branch >> ]
- << pipeline.parameters.linux_release >>
jobs:
- build_linux_release:
matrix:
parameters:
python_version: ["3.9", "3.10", "3.11", "3.12", "3.13"]
build_env: ["DEV_RELEASE=1"]
extra_env: ["PYPI_RELEASE=1"]
cuda_test_release:
when:
and:
- equal: [ main, << pipeline.git.branch >> ]
- << pipeline.parameters.cuda_release >>
jobs:
- build_cuda_release:
matrix:
parameters:
build_env: ["DEV_RELEASE=1"]
python_version: ["3.9", "3.10", "3.11", "3.12", "3.13"]
extra_env: ["PYPI_RELEASE=1"]

6
ACKNOWLEDGMENTS.md
View File

@@ -19,17 +19,11 @@ MLX was developed with contributions from the following individuals:
- Gleb Pobudzey: Added the `where` primitive, and groups in 1D and 2D convolutions.
- Paul Paczuski: Improved stability of BCE loss calculation
- Max-Heinrich Laves: Added `conv_transpose1d`, `conv_transpose2d`, and `conv_transpose3d` ops.
- Gökdeniz Gülmez: Added the `Muon (MomentUm Orthogonalized by Newton-schulz)` optimizer, and the `ReLU²` activation function.
<a href="https://github.com/ml-explore/mlx/graphs/contributors">
<img class="dark-light" src="https://contrib.rocks/image?repo=ml-explore/mlx&anon=0&columns=20&max=100&r=true" />
</a>
# Organizations
MLX has received contributions from the following companies:
- NVIDIA Corporation & Affiliates
# Third-Party Software
MLX leverages several third-party software, listed here together with

55
CMakeLists.txt
View File

@@ -41,9 +41,7 @@ option(MLX_BUILD_GGUF "Include support for GGUF format" ON)
option(MLX_BUILD_SAFETENSORS "Include support for safetensors format" ON)
option(MLX_BUILD_BLAS_FROM_SOURCE "Build OpenBLAS from source code" OFF)
option(MLX_METAL_JIT "Use JIT compilation for Metal kernels" OFF)
option(MLX_USE_CCACHE "Use CCache for compilation cache when available" ON)
option(BUILD_SHARED_LIBS "Build mlx as a shared library" OFF)
option(USE_SYSTEM_FMT "Use system's provided fmt library" OFF)
# --------------------- Processor tests -------------------------
message(
@@ -66,17 +64,10 @@ if(${CMAKE_SYSTEM_NAME} MATCHES "Darwin")
message(WARNING "Building for x86_64 arch is not officially supported.")
endif()
endif()
else()
set(MLX_BUILD_METAL OFF)
endif()
if(MLX_USE_CCACHE)
find_program(CCACHE_PROGRAM ccache)
if(CCACHE_PROGRAM)
set(CMAKE_C_COMPILER_LAUNCHER "${CCACHE_PROGRAM}")
set(CMAKE_CXX_COMPILER_LAUNCHER "${CCACHE_PROGRAM}")
set(CMAKE_CUDA_COMPILER_LAUNCHER "${CCACHE_PROGRAM}")
endif()
message(WARNING "MLX is prioritised for Apple silicon systems using macOS.")
endif()
# ----------------------------- Lib -----------------------------
@@ -87,21 +78,22 @@ cmake_policy(SET CMP0135 NEW)
add_library(mlx)
if(MLX_BUILD_METAL)
set(METAL_LIB "-framework Metal")
set(FOUNDATION_LIB "-framework Foundation")
set(QUARTZ_LIB "-framework QuartzCore")
endif()
if(MLX_BUILD_CUDA)
enable_language(CUDA)
endif()
if(MLX_BUILD_METAL)
find_library(METAL_LIB Metal)
find_library(FOUNDATION_LIB Foundation)
find_library(QUARTZ_LIB QuartzCore)
if(METAL_LIB)
message(STATUS "Metal found ${METAL_LIB}")
else()
message(
FATAL_ERROR
"Metal not found. Set MLX_BUILD_METAL=OFF to build without GPU")
endif()
if(MLX_BUILD_METAL AND NOT METAL_LIB)
message(STATUS "Metal not found. Unable to build GPU")
set(MLX_BUILD_METAL OFF)
set(MLX_METAL_DEBUG OFF)
elseif(MLX_BUILD_METAL)
message(STATUS "Building METAL sources")
if(MLX_METAL_DEBUG)
add_compile_definitions(MLX_METAL_DEBUG)
@@ -110,8 +102,7 @@ if(MLX_BUILD_METAL)
# Throw an error if xcrun not found
execute_process(
COMMAND zsh "-c" "/usr/bin/xcrun -sdk macosx --show-sdk-version"
OUTPUT_VARIABLE MACOS_SDK_VERSION
OUTPUT_STRIP_TRAILING_WHITESPACE COMMAND_ERROR_IS_FATAL ANY)
OUTPUT_VARIABLE MACOS_SDK_VERSION COMMAND_ERROR_IS_FATAL ANY)
if(${MACOS_SDK_VERSION} LESS 14.0)
message(
@@ -140,12 +131,6 @@ if(MLX_BUILD_METAL)
target_link_libraries(mlx PUBLIC ${METAL_LIB} ${FOUNDATION_LIB} ${QUARTZ_LIB})
endif()
if(CMAKE_SYSTEM_NAME STREQUAL "Linux")
# With newer clang/gcc versions following libs are implicitly linked, but when
# building on old distributions they need to be explicitly listed.
target_link_libraries(mlx PRIVATE dl pthread)
endif()
if(WIN32)
if(MSVC)
# GGUF does not build with MSVC.
@@ -173,7 +158,7 @@ if(MLX_BUILD_CPU)
message(STATUS "Accelerate found ${ACCELERATE_LIBRARY}")
set(MLX_BUILD_ACCELERATE ON)
else()
message(STATUS "Accelerate not found, using default backend.")
message(STATUS "Accelerate or arm neon not found, using default backend.")
set(MLX_BUILD_ACCELERATE OFF)
endif()
@@ -249,16 +234,12 @@ target_include_directories(
# Do not add mlx_EXPORTS define for shared library.
set_target_properties(mlx PROPERTIES DEFINE_SYMBOL "")
if(USE_SYSTEM_FMT)
find_package(fmt REQUIRED)
else()
FetchContent_Declare(
FetchContent_Declare(
fmt
GIT_REPOSITORY https://github.com/fmtlib/fmt.git
GIT_TAG 10.2.1
EXCLUDE_FROM_ALL)
FetchContent_MakeAvailable(fmt)
endif()
FetchContent_MakeAvailable(fmt)
target_link_libraries(mlx PRIVATE $<BUILD_INTERFACE:fmt::fmt-header-only>)
if(MLX_BUILD_PYTHON_BINDINGS)

17
README.md
View File

@@ -68,23 +68,18 @@ in the documentation.
## Installation
MLX is available on [PyPI](https://pypi.org/project/mlx/). To install MLX on
macOS, run:
MLX is available on [PyPI](https://pypi.org/project/mlx/). To install the Python API, run:
```bash
**With `pip`**:
```
pip install mlx
```
To install the CUDA backend on Linux, run:
**With `conda`**:
```bash
pip install mlx[cuda]
```
To install a CPU-only Linux package, run:
```bash
pip install mlx[cpu]
conda install -c conda-forge mlx
```
Checkout the

54
cmake/FindNCCL.cmake
View File

@@ -1,54 +0,0 @@
# FindNCCL.cmake This module finds the NVIDIA NCCL library and its include
# directories.
set(NCCL_ROOT_DIR
$ENV{NCCL_ROOT_DIR}
CACHE PATH "Folder contains NVIDIA NCCL")
find_path(
NCCL_INCLUDE_DIRS
NAMES nccl.h
HINTS ${NCCL_INCLUDE_DIR} ${NCCL_ROOT_DIR} ${NCCL_ROOT_DIR}/include
${CUDA_TOOLKIT_ROOT_DIR}/include)
if($ENV{USE_STATIC_NCCL})
message(
STATUS "USE_STATIC_NCCL detected. Linking against static NCCL library")
set(NCCL_LIBNAME "libnccl_static.a")
else()
set(NCCL_LIBNAME "nccl")
endif()
find_library(
NCCL_LIBRARIES
NAMES ${NCCL_LIBNAME}
HINTS ${NCCL_LIB_DIR}
${NCCL_ROOT_DIR}
${NCCL_ROOT_DIR}/lib
${NCCL_ROOT_DIR}/lib/x86_64-linux-gnu
${NCCL_ROOT_DIR}/lib64
${CUDA_TOOLKIT_ROOT_DIR}/lib
${CUDA_TOOLKIT_ROOT_DIR}/lib64)
include(FindPackageHandleStandardArgs)
find_package_handle_standard_args(NCCL DEFAULT_MSG NCCL_INCLUDE_DIRS
NCCL_LIBRARIES)
if(NCCL_FOUND)
set(NCCL_HEADER_FILE "${NCCL_INCLUDE_DIRS}/nccl.h")
message(
STATUS "Determining NCCL version from the header file: ${NCCL_HEADER_FILE}")
file(
STRINGS ${NCCL_HEADER_FILE} NCCL_MAJOR_VERSION_DEFINED
REGEX "^[ \t]*#define[ \t]+NCCL_MAJOR[ \t]+[0-9]+.*$"
LIMIT_COUNT 1)
if(NCCL_MAJOR_VERSION_DEFINED)
string(REGEX REPLACE "^[ \t]*#define[ \t]+NCCL_MAJOR[ \t]+" ""
NCCL_MAJOR_VERSION ${NCCL_MAJOR_VERSION_DEFINED})
message(STATUS "NCCL_MAJOR_VERSION: ${NCCL_MAJOR_VERSION}")
endif()
message(
STATUS
"Found NCCL (include: ${NCCL_INCLUDE_DIRS}, library: ${NCCL_LIBRARIES})")
mark_as_advanced(NCCL_ROOT_DIR NCCL_INCLUDE_DIRS NCCL_LIBRARIES)
endif()

1
docs/requirements.txt
View File

@@ -1,5 +1,4 @@
sphinx
breathe
sphinx-book-theme
sphinx-copybutton
mlx

1
docs/src/conf.py
View File

@@ -18,7 +18,6 @@ release = version
# -- General configuration ---------------------------------------------------
extensions = [
"sphinx_copybutton",
"sphinx.ext.autodoc",
"sphinx.ext.autosummary",
"sphinx.ext.intersphinx",

4
docs/src/dev/custom_metal_kernels.rst
View File

@@ -127,8 +127,7 @@ relying on a copy from ``ensure_row_contiguous``:
name="myexp_strided",
input_names=["inp"],
output_names=["out"],
source=source,
ensure_row_contiguous=False,
source=source
)
def exp_elementwise(a: mx.array):
@@ -139,6 +138,7 @@ relying on a copy from ``ensure_row_contiguous``:
threadgroup=(256, 1, 1),
output_shapes=[a.shape],
output_dtypes=[a.dtype],
ensure_row_contiguous=False,
)
return outputs[0]

16
docs/src/dev/extensions.rst
View File

@@ -138,13 +138,13 @@ more concrete:
* representing the vectorized computation and the axis which
* corresponds to the output vectorized dimension.
*/
std::pair<std::vector<array>, std::vector<int>> vmap(
virtual std::pair<std::vector<array>, std::vector<int>> vmap(
const std::vector<array>& inputs,
const std::vector<int>& axes) override;
/** The name of primitive. */
const char* name() const override {
return "Axpby";
/** Print the primitive. */
void print(std::ostream& os) override {
os << "Axpby";
}
/** Equivalence check **/
@@ -394,14 +394,14 @@ below.
out.set_data(allocator::malloc(out.nbytes()));
// Resolve name of kernel
std::stream kname;
kname = "axpby_general_" + type_to_name(out);
std::ostringstream kname;
kname << "axpby_" << "general_" << type_to_name(out);
// Load the metal library
auto lib = d.get_library("mlx_ext", current_binary_dir());
auto lib = d.get_library("mlx_ext");
// Make a kernel from this metal library
auto kernel = d.get_kernel(kname, lib);
auto kernel = d.get_kernel(kname.str(), lib);
// Prepare to encode kernel
auto& compute_encoder = d.get_command_encoder(s.index);

1
docs/src/index.rst
View File

@@ -70,7 +70,6 @@ are the CPU and GPU.
python/fft
python/linalg
python/metal
python/cuda
python/memory_management
python/nn
python/optimizers

41
docs/src/install.rst
View File

@@ -13,7 +13,7 @@ silicon computer is
pip install mlx
To install from PyPI your system must meet the following requirements:
To install from PyPI you must meet the following requirements:
- Using an M series chip (Apple silicon)
- Using a native Python >= 3.9
@@ -23,39 +23,22 @@ To install from PyPI your system must meet the following requirements:
MLX is only available on devices running macOS >= 13.5
It is highly recommended to use macOS 14 (Sonoma)
MLX is also available on conda-forge. To install MLX with conda do:
.. code-block:: shell
conda install conda-forge::mlx
CUDA
^^^^
MLX has a CUDA backend which you can install with:
MLX has a CUDA backend which you can use on any Linux platform with CUDA 12
and SM 7.0 (Volta) and up. To install MLX with CUDA support, run:
.. code-block:: shell
pip install mlx[cuda]
To install the CUDA package from PyPi your system must meet the following
requirements:
- Nvidia architecture >= SM 7.0 (Volta)
- Nvidia driver >= 550.54.14
- CUDA toolkit >= 12.0
- Linux distribution with glibc >= 2.35
- Python >= 3.9
CPU-only (Linux)
^^^^^^^^^^^^^^^^
For a CPU-only version of MLX that runs on Linux use:
.. code-block:: shell
pip install mlx[cpu]
To install the CPU-only package from PyPi your system must meet the following
requirements:
- Linux distribution with glibc >= 2.35
- Python >= 3.9
pip install mlx-cuda
Troubleshooting
@@ -271,7 +254,7 @@ and the CUDA toolkit. For example on Ubuntu, run the following:
dpkg -i cuda-keyring_1.1-1_all.deb
apt-get update -y
apt-get -y install cuda-toolkit-12-9
apt-get install libblas-dev liblapack-dev liblapacke-dev libcudnn9-dev-cuda-12 -y
apt-get install libblas-dev liblapack-dev liblapacke-dev -y
When building either the Python or C++ APIs make sure to pass the cmake flag

9
docs/src/python/cuda.rst
View File

@@ -1,9 +0,0 @@
CUDA
=====
.. currentmodule:: mlx.core.cuda
.. autosummary::
:toctree: _autosummary
is_available

1
docs/src/python/fast.rst
View File

@@ -13,4 +13,3 @@ Fast
rope
scaled_dot_product_attention
metal_kernel
cuda_kernel

1
docs/src/python/nn/functions.rst
View File

@@ -27,7 +27,6 @@ simple functions.
mish
prelu
relu
relu2
relu6
selu
sigmoid

1
docs/src/python/nn/layers.rst
View File

@@ -50,7 +50,6 @@ Layers
QuantizedLinear
RMSNorm
ReLU
ReLU2
ReLU6
RNN
RoPE

6
docs/src/python/optimizers.rst
View File

@@ -51,14 +51,14 @@ the saved state. Here's a simple example:
optimizer.update(model, grads)
# Save the state
state = tree_flatten(optimizer.state, destination={})
mx.save_safetensors("optimizer.safetensors", state)
state = tree_flatten(optimizer.state)
mx.save_safetensors("optimizer.safetensors", dict(state))
# Later on, for example when loading from a checkpoint,
# recreate the optimizer and load the state
optimizer = optim.Adam(learning_rate=1e-2)
state = tree_unflatten(mx.load("optimizer.safetensors"))
state = tree_unflatten(list(mx.load("optimizer.safetensors").items()))
optimizer.state = state
Note, not every optimizer configuation parameter is saved in the state. For

1
docs/src/python/optimizers/common_optimizers.rst
View File

@@ -19,4 +19,3 @@ Common Optimizers
Adamax
Lion
MultiOptimizer
Muon

6
docs/src/usage/compile.rst
View File

@@ -130,8 +130,8 @@ Now make an array, and benchmark both functions:
.. code-block:: python
x = mx.random.uniform(shape=(32, 1000, 4096))
timeit(gelu, x)
timeit(mx.compile(gelu), x)
timeit(nn.gelu, x)
timeit(mx.compile(nn.gelu), x)
On an M1 Max the times are 15.5 and 3.1 milliseconds. The compiled ``gelu`` is
five times faster.
@@ -225,7 +225,7 @@ In some cases returning updated state can be pretty inconvenient. Hence,
def fun(x, y):
z = x + y
state.append(z)
return mx.exp(z)
return mx.exp(z), state
fun(mx.array(1.0), mx.array(2.0))
# Prints [array(3, dtype=float32)]

2
docs/src/usage/distributed.rst
View File

@@ -184,7 +184,7 @@ almost identical to the example above:
def step(model, x, y):
loss, grads = loss_grad_fn(model, x, y)
grads = mx.nn.average_gradients(grads) # <---- This line was added
grads = mlx.nn.average_gradients(grads) # <---- This line was added
optimizer.update(model, grads)
return loss

6
docs/src/usage/export.rst
View File

@@ -151,7 +151,7 @@ parameters, pass them as inputs to the ``call`` wrapper:
model.update(tree_unflatten(list(params.items())))
return model(x)
params = tree_flatten(model.parameters(), destination={})
params = dict(tree_flatten(model.parameters()))
mx.export_function("model.mlxfn", call, (mx.zeros(4),), params)
@@ -164,11 +164,11 @@ to export a function which can be used for inputs with variable shapes:
.. code-block:: python
mx.export_function("fun.mlxfn", mx.abs, mx.array([0.0]), shapeless=True)
mx.export_function("fun.mlxfn", mx.abs, mx.array(0.0), shapeless=True)
imported_abs = mx.import_function("fun.mlxfn")
# Ok
out, = imported_abs(mx.array([-1.0]))
out, = imported_abs(mx.array(-1.0))
# Also ok
out, = imported_abs(mx.array([-1.0, -2.0]))

14
docs/src/usage/indexing.rst
View File

@@ -107,20 +107,8 @@ same array:
>>> a
array([1, 2, 0], dtype=int32)
Note that unlike NumPy, slicing an array creates a copy, not a view. So
mutating it does not mutate the original array:
.. code-block:: shell
>>> a = mx.array([1, 2, 3])
>>> b = a[:]
>>> b[2] = 0
>>> b
array([1, 2, 0], dtype=int32)
>>> a
array([1, 2, 3], dtype=int32)
Also unlike NumPy, updates to the same location are nondeterministic:
Note, unlike NumPy, updates to the same location are nondeterministic:
.. code-block:: shell

25
examples/extensions/axpby/axpby.cpp
View File

@@ -1,6 +1,5 @@
// Copyright © 2023-2025 Apple Inc.
#include <dlfcn.h>
#include <iostream>
#include <sstream>
@@ -17,19 +16,6 @@
namespace my_ext {
// A helper function to find the location of the current binary on disk.
// The Metal library ("mlx_ext.mtllib"), should be in the same directory.
std::string current_binary_dir() {
static std::string binary_dir = []() {
Dl_info info;
if (!dladdr(reinterpret_cast<void*>(&current_binary_dir), &info)) {
throw std::runtime_error("Unable to get current binary dir.");
}
return std::filesystem::path(info.dli_fname).parent_path().string();
}();
return binary_dir;
}
///////////////////////////////////////////////////////////////////////////////
// Operation Implementation
///////////////////////////////////////////////////////////////////////////////
@@ -181,15 +167,16 @@ void Axpby::eval_gpu(
}
// Resolve name of kernel (corresponds to axpby.metal)
std::string kname = "axpby_";
kname += (contiguous_kernel ? "contiguous_" : "general_");
kname += type_to_name(out);
std::ostringstream kname;
kname << "axpby_";
kname << (contiguous_kernel ? "contiguous_" : "general_");
kname << type_to_name(out);
// Load the metal library
auto lib = d.get_library("mlx_ext", current_binary_dir());
auto lib = d.get_library("mlx_ext");
// Make a kernel from this metal library
auto kernel = d.get_kernel(kname, lib);
auto kernel = d.get_kernel(kname.str(), lib);
// Prepare to encode kernel
auto& compute_encoder = d.get_command_encoder(s.index);

6
examples/extensions/axpby/axpby.h
View File

@@ -74,9 +74,9 @@ class Axpby : public mx::Primitive {
const std::vector<mx::array>& inputs,
const std::vector<int>& axes) override;
/** The name of primitive. */
const char* name() const override {
return "Axpby";
/** Print the primitive. */
void print(std::ostream& os) override {
os << "Axpby";
}
/** Equivalence check **/

2
examples/extensions/requirements.txt
View File

@@ -1,4 +1,4 @@
setuptools>=42
cmake>=3.25
mlx>=0.21.0
nanobind==2.4.0
nanobind==2.2.0

10
examples/extensions/test.py
View File

@@ -3,10 +3,8 @@ from mlx_sample_extensions import axpby
a = mx.ones((3, 4))
b = mx.ones((3, 4))
c_cpu = axpby(a, b, 4.0, 2.0, stream=mx.cpu)
c_gpu = axpby(a, b, 4.0, 2.0, stream=mx.gpu)
c = axpby(a, b, 4.0, 2.0, stream=mx.cpu)
print(f"c shape: {c_cpu.shape}")
print(f"c dtype: {c_cpu.dtype}")
print(f"c_cpu correct: {mx.all(c_cpu == 6.0).item()}")
print(f"c_gpu correct: {mx.all(c_gpu == 6.0).item()}")
print(f"c shape: {c.shape}")
print(f"c dtype: {c.dtype}")
print(f"c correct: {mx.all(c == 6.0).item()}")

5
mlx/array.h
View File

@@ -10,7 +10,6 @@
#include "mlx/allocator.h"
#include "mlx/dtype.h"
#include "mlx/event.h"
#include "mlx/small_vector.h"
namespace mlx::core {
@@ -19,8 +18,8 @@ class Primitive;
using Deleter = std::function<void(allocator::Buffer)>;
using ShapeElem = int32_t;
using Shape = SmallVector<ShapeElem>;
using Strides = SmallVector<int64_t>;
using Shape = std::vector<ShapeElem>;
using Strides = std::vector<int64_t>;
class array {
/* An array is really a node in a graph. It contains a shared ArrayDesc

16
mlx/backend/common/utils.cpp
View File

@@ -1,20 +1,14 @@
// Copyright © 2023-2024 Apple Inc.
#include <dlfcn.h>
#include "mlx/backend/common/utils.h"
#include "mlx/primitives.h"
namespace mlx::core {
std::filesystem::path current_binary_dir() {
static std::filesystem::path binary_dir = []() {
Dl_info info;
if (!dladdr(reinterpret_cast<void*>(&current_binary_dir), &info)) {
throw std::runtime_error("Unable to get current binary dir.");
}
return std::filesystem::path(info.dli_fname).parent_path();
}();
return binary_dir;
std::string get_primitive_string(Primitive* primitive) {
std::ostringstream op_t;
primitive->print(op_t);
return op_t.str();
}
std::tuple<Shape, std::vector<Strides>> collapse_contiguous_dims(

6
mlx/backend/common/utils.h
View File

@@ -2,7 +2,6 @@
#pragma once
#include <filesystem>
#include <tuple>
#include <vector>
@@ -10,8 +9,7 @@
namespace mlx::core {
// Return the directory that contains current shared library.
std::filesystem::path current_binary_dir();
std::string get_primitive_string(Primitive* primitive);
inline int64_t
elem_to_loc(int elem, const Shape& shape, const Strides& strides) {
@@ -197,7 +195,7 @@ void shared_buffer_reshape(
array& out);
template <typename T>
inline SmallVector<T> remove_index(SmallVector<T> vec, size_t index) {
inline std::vector<T> remove_index(std::vector<T> vec, size_t index) {
vec.erase(std::next(vec.begin(), index));
return vec;
}

2
mlx/backend/cpu/cholesky.cpp
View File

@@ -20,7 +20,7 @@ void cholesky_impl(const array& a, array& factor, bool upper, Stream stream) {
// The decomposition is computed in place, so just copy the input to the
// output.
copy_cpu(
copy(
a,
factor,
a.flags().row_contiguous ? CopyType::Vector : CopyType::General,

41
mlx/backend/cpu/compiled.cpp
View File

@@ -15,7 +15,6 @@
#include "mlx/backend/cpu/jit_compiler.h"
#include "mlx/device.h"
#include "mlx/graph_utils.h"
#include "mlx/version.h"
namespace mlx::core {
@@ -95,11 +94,7 @@ void* compile(
kernel_file_name = kernel_name;
}
auto output_dir =
std::filesystem::temp_directory_path() / "mlx" / version() / "cpu";
if (!std::filesystem::exists(output_dir)) {
std::filesystem::create_directories(output_dir);
}
auto output_dir = std::filesystem::temp_directory_path();
std::string shared_lib_name = "lib" + kernel_file_name + ".so";
auto shared_lib_path = (output_dir / shared_lib_name).string();
@@ -162,12 +157,10 @@ inline void build_kernel(
#endif
// Start the kernel
os << "void " << kernel_name
<< "(int* shape, int64_t** strides, void** args) {" << std::endl;
os << "void " << kernel_name << "(void** args) {" << std::endl;
// Add the input arguments
int cnt = 0;
int strides_index = 1;
for (size_t i = 0; i < inputs.size(); ++i) {
// Skip constants from the input list
if (is_constant(i)) {
@@ -182,8 +175,8 @@ inline void build_kernel(
<< "];" << std::endl;
// Scalars and contiguous need no strides
if (!is_scalar(x) && !contiguous) {
os << " const int64_t* " << xname << "_strides = strides["
<< strides_index++ << "];" << std::endl;
os << " const size_t* " << xname << "_strides = (size_t*)args[" << cnt++
<< "];" << std::endl;
}
}
@@ -193,8 +186,10 @@ inline void build_kernel(
os << " " << tstr << "* " << namer.get_name(x) << " = (" << tstr
<< "*)args[" << cnt++ << "];" << std::endl;
}
// Add output size
if (contiguous) {
// Add output strides and shape to extract the indices.
if (!contiguous) {
os << " const int* shape = (int*)args[" << cnt++ << "];" << std::endl;
} else {
os << " const size_t size = (size_t)args[" << cnt++ << "];" << std::endl;
}
@@ -236,7 +231,7 @@ inline void build_kernel(
os << "static_cast<" << get_type_string(x.dtype()) << ">(tmp_"
<< namer.get_name(x.inputs()[0]) << ");" << std::endl;
} else {
os << x.primitive().name();
x.primitive().print(os);
os << "()(";
for (int i = 0; i < x.inputs().size() - 1; i++) {
os << "tmp_" << namer.get_name(x.inputs()[i]) << ", ";
@@ -295,6 +290,7 @@ void Compiled::eval_cpu(
// Collect function input arguments.
std::vector<void*> args;
int strides_index = 1;
for (size_t i = 0; i < inputs.size(); ++i) {
if (is_constant_(i)) {
continue;
@@ -302,6 +298,9 @@ void Compiled::eval_cpu(
const auto& x = inputs[i];
encoder.set_input_array(x);
args.push_back((void*)x.data<void>());
if (!contiguous && !is_scalar(x)) {
args.push_back(strides[strides_index++].data());
}
}
// Get the kernel name from the lib
@@ -336,20 +335,16 @@ void Compiled::eval_cpu(
args.push_back(x.data<void>());
encoder.set_output_array(x);
}
if (contiguous) {
if (!contiguous) {
args.push_back((void*)shape.data());
} else {
args.push_back((void*)outputs[0].data_size());
}
auto fun = reinterpret_cast<void (*)(int*, int64_t**, void**)>(fn_ptr);
auto fun = (void (*)(void**))fn_ptr;
encoder.dispatch([fun,
args = std::move(args),
strides = std::move(strides),
shape = std::move(shape)]() mutable {
SmallVector<int64_t*> strides_ptrs;
for (auto& s : strides) {
strides_ptrs.push_back(s.data());
}
fun(shape.data(), strides_ptrs.data(), args.data());
});
shape = std::move(shape)]() mutable { fun(args.data()); });
}
} // namespace mlx::core

34
mlx/backend/cpu/conv.cpp
View File

@@ -883,7 +883,7 @@ void explicit_gemm_conv_1D_cpu(
// Fill with zeros
std::vector<array> temps;
temps.push_back(array(0, conv_dtype));
copy_cpu(temps.back(), in_padded, CopyType::Scalar, stream);
copy(temps.back(), in_padded, CopyType::Scalar, stream);
// Pick input slice from padded
size_t data_offset = padding_lo[0] * in_padded.strides()[1];
@@ -895,7 +895,7 @@ void explicit_gemm_conv_1D_cpu(
in_padded_slice.size(),
data_offset);
// Copy input values into the slice
copy_cpu_inplace(in, in_padded_slice, CopyType::GeneralGeneral, stream);
copy_inplace(in, in_padded_slice, CopyType::GeneralGeneral, stream);
temps.push_back(in_padded_slice);
// Make strided view
@@ -920,7 +920,7 @@ void explicit_gemm_conv_1D_cpu(
// Materialize strided view
Shape strided_reshape = {N * oH, wH * C};
array in_strided(strided_reshape, in_strided_view.dtype(), nullptr, {});
copy_cpu(in_strided_view, in_strided, CopyType::General, stream);
copy(in_strided_view, in_strided, CopyType::General, stream);
temps.push_back(in_strided);
// Check wt dtype and prepare
@@ -938,13 +938,13 @@ void explicit_gemm_conv_1D_cpu(
wt.size(),
0);
gemm_wt = array(wt_transpose.shape(), float32, nullptr, {});
copy_cpu(wt_transpose, gemm_wt, CopyType::General, stream);
copy(wt_transpose, gemm_wt, CopyType::General, stream);
temps.push_back(gemm_wt);
} else if (wt.dtype() != float32 || !wt.flags().row_contiguous) {
auto ctype =
wt.flags().row_contiguous ? CopyType::Vector : CopyType::General;
gemm_wt = array(wt.shape(), float32, nullptr, {});
copy_cpu(wt, gemm_wt, ctype, stream);
copy(wt, gemm_wt, ctype, stream);
temps.push_back(gemm_wt);
}
@@ -991,7 +991,7 @@ void explicit_gemm_conv_1D_cpu(
// Copy results if needed
if (out.dtype() != float32) {
copy_cpu_inplace(gemm_out, out, CopyType::Vector, stream);
copy_inplace(gemm_out, out, CopyType::Vector, stream);
}
encoder.add_temporaries(std::move(temps));
}
@@ -1029,7 +1029,7 @@ void explicit_gemm_conv_2D_cpu(
// Fill with zeros
std::vector<array> temps;
temps.push_back(array(0, conv_dtype));
copy_cpu(temps.back(), in_padded, CopyType::Scalar, stream);
copy(temps.back(), in_padded, CopyType::Scalar, stream);
// Pick input slice from padded
size_t data_offset = padding_lo[0] * in_padded.strides()[1] +
@@ -1044,7 +1044,7 @@ void explicit_gemm_conv_2D_cpu(
temps.push_back(in_padded_slice);
// Copy input values into the slice
copy_cpu_inplace(in, in_padded_slice, CopyType::GeneralGeneral, stream);
copy_inplace(in, in_padded_slice, CopyType::GeneralGeneral, stream);
// Make strided view
Shape strided_shape = {N, oH, oW, wH, wW, C};
@@ -1065,7 +1065,7 @@ void explicit_gemm_conv_2D_cpu(
// Materialize strided view
Shape strided_reshape = {N * oH * oW, wH * wW * C};
array in_strided(strided_reshape, in_strided_view.dtype(), nullptr, {});
copy_cpu(in_strided_view, in_strided, CopyType::General, stream);
copy(in_strided_view, in_strided, CopyType::General, stream);
temps.push_back(in_strided);
// Check wt dtype and prepare
@@ -1076,7 +1076,7 @@ void explicit_gemm_conv_2D_cpu(
auto ctype =
wt.flags().row_contiguous ? CopyType::Vector : CopyType::General;
gemm_wt = array(wt.shape(), float32, nullptr, {});
copy_cpu(wt, gemm_wt, ctype, stream);
copy(wt, gemm_wt, ctype, stream);
temps.push_back(gemm_wt);
}
@@ -1116,7 +1116,7 @@ void explicit_gemm_conv_2D_cpu(
// Copy results if needed
if (out.dtype() != float32) {
copy_cpu_inplace(gemm_out, out, CopyType::Vector, stream);
copy_inplace(gemm_out, out, CopyType::Vector, stream);
}
encoder.add_temporaries(std::move(temps));
}
@@ -1156,7 +1156,7 @@ void explicit_gemm_conv_ND_cpu(
// Fill with zeros
std::vector<array> temps = {array(0, conv_dtype)};
copy_cpu(temps.back(), in_padded, CopyType::Scalar, stream);
copy(temps.back(), in_padded, CopyType::Scalar, stream);
// Pick input slice from padded
size_t data_offset = 0;
@@ -1173,7 +1173,7 @@ void explicit_gemm_conv_ND_cpu(
data_offset);
// Copy input values into the slice
copy_cpu_inplace(in, in_padded_slice, CopyType::GeneralGeneral, stream);
copy_inplace(in, in_padded_slice, CopyType::GeneralGeneral, stream);
temps.push_back(in_padded_slice);
// Make strided view
@@ -1212,7 +1212,7 @@ void explicit_gemm_conv_ND_cpu(
}
array in_strided(strided_reshape, in_strided_view.dtype(), nullptr, {});
copy_cpu(in_strided_view, in_strided, CopyType::General, stream);
copy(in_strided_view, in_strided, CopyType::General, stream);
temps.push_back(in_strided);
// Check wt dtype and prepare
@@ -1223,13 +1223,13 @@ void explicit_gemm_conv_ND_cpu(
auto ctype =
wt.flags().row_contiguous ? CopyType::Vector : CopyType::General;
gemm_wt = array(wt.shape(), float32, nullptr, {});
copy_cpu(wt, gemm_wt, ctype, stream);
copy(wt, gemm_wt, ctype, stream);
temps.push_back(gemm_wt);
}
if (flip) {
auto gemm_wt_ = array(gemm_wt.shape(), float32, nullptr, {});
copy_cpu(gemm_wt, gemm_wt_, CopyType::Vector, stream);
copy(gemm_wt, gemm_wt_, CopyType::Vector, stream);
temps.push_back(gemm_wt_);
// Calculate the total size of the spatial dimensions
@@ -1284,7 +1284,7 @@ void explicit_gemm_conv_ND_cpu(
// Copy results if needed
if (out.dtype() != float32) {
copy_cpu_inplace(gemm_out, out, CopyType::Vector, stream);
copy_inplace(gemm_out, out, CopyType::Vector, stream);
}
encoder.add_temporaries(std::move(temps));
}

18
mlx/backend/cpu/copy.cpp
View File

@@ -295,11 +295,7 @@ inline void copy_inplace_dispatch(
} // namespace
void copy_cpu_inplace(
const array& src,
array& dst,
CopyType ctype,
Stream stream) {
void copy_inplace(const array& src, array& dst, CopyType ctype, Stream stream) {
auto& encoder = cpu::get_command_encoder(stream);
encoder.set_input_array(src);
encoder.set_output_array(dst);
@@ -309,7 +305,7 @@ void copy_cpu_inplace(
ctype]() mutable { copy_inplace_dispatch(src, dst, ctype); });
}
void copy_cpu(const array& src, array& dst, CopyType ctype, Stream stream) {
void copy(const array& src, array& dst, CopyType ctype, Stream stream) {
bool donated = set_copy_output_data(src, dst, ctype);
if (donated && src.dtype() == dst.dtype()) {
// If the output has the same type as the input then there is nothing to
@@ -319,10 +315,10 @@ void copy_cpu(const array& src, array& dst, CopyType ctype, Stream stream) {
if (ctype == CopyType::GeneralGeneral) {
ctype = CopyType::General;
}
copy_cpu_inplace(src, dst, ctype, stream);
copy_inplace(src, dst, ctype, stream);
}
void copy_cpu_inplace(
void copy_inplace(
const array& src,
array& dst,
const Shape& data_shape,
@@ -377,10 +373,4 @@ void copy_cpu_inplace(
});
}
array contiguous_copy_cpu(const array& arr, Stream stream) {
array arr_copy(arr.shape(), arr.dtype(), nullptr, {});
copy_cpu(arr, arr_copy, CopyType::General, stream);
return arr_copy;
}
} // namespace mlx::core

13
mlx/backend/cpu/copy.h
View File

@@ -10,14 +10,10 @@
namespace mlx::core {
void copy_cpu(const array& src, array& dst, CopyType ctype, Stream stream);
void copy_cpu_inplace(
const array& src,
array& dst,
CopyType ctype,
Stream stream);
void copy(const array& src, array& dst, CopyType ctype, Stream stream);
void copy_inplace(const array& src, array& dst, CopyType ctype, Stream stream);
void copy_cpu_inplace(
void copy_inplace(
const array& src,
array& dst,
const Shape& data_shape,
@@ -30,7 +26,4 @@ void copy_cpu_inplace(
const std::optional<array>& dynamic_i_offset = std::nullopt,
const std::optional<array>& dynamic_o_offset = std::nullopt);
// Return a contiguous array with same shape that copies the data of |arr|.
array contiguous_copy_cpu(const array& arr, Stream stream);
} // namespace mlx::core

7
mlx/backend/cpu/distributed.cpp
View File

@@ -13,7 +13,9 @@ std::pair<array, bool> ensure_row_contiguous(const array& arr, Stream stream) {
if (arr.flags().row_contiguous) {
return {arr, false};
} else {
return {contiguous_copy_cpu(arr, stream), true};
array arr_copy(arr.shape(), arr.dtype(), nullptr, {});
copy(arr, arr_copy, CopyType::General, stream);
return {arr_copy, true};
}
};
@@ -32,7 +34,8 @@ void AllReduce::eval_cpu(
}
return in;
} else {
array arr_copy = contiguous_copy_cpu(in, s);
array arr_copy(in.shape(), in.dtype(), nullptr, {});
copy(in, arr_copy, CopyType::General, s);
out.copy_shared_buffer(arr_copy);
return arr_copy;
}

2
mlx/backend/cpu/eig.cpp
View File

@@ -135,7 +135,7 @@ void Eig::eval_cpu(
: array(a.shape(), complex64, nullptr, {});
auto a_copy = array(a.shape(), a.dtype(), nullptr, {});
copy_cpu(
copy(
a,
a_copy,
a.flags().row_contiguous ? CopyType::Vector : CopyType::General,

2
mlx/backend/cpu/eigh.cpp
View File

@@ -196,7 +196,7 @@ void Eigh::eval_cpu(
values.set_data(allocator::malloc(values.nbytes()));
copy_cpu(
copy(
a,
vectors,
a.flags().row_contiguous ? CopyType::Vector : CopyType::General,

2
mlx/backend/cpu/hadamard.cpp
View File

@@ -96,7 +96,7 @@ void Hadamard::eval_cpu(const std::vector<array>& inputs, array& out) {
if (in.flags().row_contiguous && in.is_donatable()) {
out.copy_shared_buffer(in);
} else {
copy_cpu(
copy(
in,
out,
in.flags().row_contiguous ? CopyType::Vector : CopyType::General,

4
mlx/backend/cpu/indexing.cpp
View File

@@ -517,7 +517,7 @@ void Scatter::eval_cpu(const std::vector<array>& inputs, array& out) {
// Copy src into out (copy allocates memory for out)
auto ctype =
src.flags().row_contiguous ? CopyType::Vector : CopyType::General;
copy_cpu(src, out, ctype, stream());
copy(src, out, ctype, stream());
auto& encoder = cpu::get_command_encoder(stream());
std::vector<array> inds;
@@ -686,7 +686,7 @@ void ScatterAxis::eval_cpu(const std::vector<array>& inputs, array& out) {
// Copy src into out (copy allocates memory for out)
auto ctype =
src.flags().row_contiguous ? CopyType::Vector : CopyType::General;
copy_cpu(src, out, ctype, stream());
copy(src, out, ctype, stream());
auto& encoder = cpu::get_command_encoder(stream());
encoder.set_input_array(idx);

2
mlx/backend/cpu/inverse.cpp
View File

@@ -115,7 +115,7 @@ void inverse_impl(
// (A⁻¹)ᵀ = (Aᵀ)⁻¹
// The inverse is computed in place, so just copy the input to the output.
copy_cpu(
copy(
a,
inv,
a.flags().row_contiguous ? CopyType::Vector : CopyType::General,

1
mlx/backend/cpu/jit_compiler.cpp
View File

@@ -2,7 +2,6 @@
#include "mlx/backend/cpu/jit_compiler.h"
#include <algorithm>
#include <sstream>
#include <vector>

2
mlx/backend/cpu/lapack.h
View File

@@ -47,7 +47,7 @@ INSTANTIATE_LAPACK_REAL(orgqr)
INSTANTIATE_LAPACK_REAL(syevd)
INSTANTIATE_LAPACK_REAL(geev)
INSTANTIATE_LAPACK_REAL(potrf)
INSTANTIATE_LAPACK_REAL(gesdd)
INSTANTIATE_LAPACK_REAL(gesvdx)
INSTANTIATE_LAPACK_REAL(getrf)
INSTANTIATE_LAPACK_REAL(getri)
INSTANTIATE_LAPACK_REAL(trtri)

3
mlx/backend/cpu/logsumexp.cpp
View File

@@ -87,7 +87,8 @@ void LogSumExp::eval_cpu(const std::vector<array>& inputs, array& out) {
if (x.flags().contiguous && x.strides()[x.ndim() - 1] == 1) {
return x;
} else {
array x_copy = contiguous_copy_cpu(x, s);
auto x_copy = array(x.shape(), x.dtype(), nullptr, {});
copy(x, x_copy, CopyType::General, s);
encoder.add_temporary(x_copy);
return x_copy;
}

2
mlx/backend/cpu/luf.cpp
View File

@@ -31,7 +31,7 @@ void luf_impl(
strides[ndim - 1] = M;
strides[ndim - 2] = 1;
lu.set_data(allocator::malloc(lu.nbytes()), lu.nbytes(), strides, flags);
copy_cpu_inplace(
copy_inplace(
a,
lu,
a.shape(),

11
mlx/backend/cpu/masked_mm.cpp
View File

@@ -124,20 +124,21 @@ void BlockMaskedMM::eval_cpu(const std::vector<array>& inputs, array& out) {
if (!expand_all && stx == arr.shape(-1) && sty == 1) {
if (do_copy) {
array arr_copy(arr.shape(), arr.dtype(), nullptr, {});
copy_cpu(arr, arr_copy, CopyType::Vector, s);
copy(arr, arr_copy, CopyType::Vector, s);
return std::make_tuple(false, stx, arr_copy, true);
}
return std::make_tuple(false, stx, arr, false);
} else if (!expand_all && stx == 1 && sty == arr.shape(-2)) {
if (do_copy) {
array arr_copy(arr.shape(), arr.dtype(), nullptr, {});
copy_cpu(arr, arr_copy, CopyType::Vector, s);
copy(arr, arr_copy, CopyType::Vector, s);
return std::make_tuple(true, sty, arr_copy, true);
}
return std::make_tuple(true, sty, arr, false);
} else {
array arr_copy(arr.shape(), arr.dtype(), nullptr, {});
copy(arr, arr_copy, CopyType::General, s);
int64_t stx = arr.shape(-1);
array arr_copy = contiguous_copy_cpu(arr, s);
return std::make_tuple(false, stx, arr_copy, true);
}
};
@@ -385,7 +386,7 @@ void GatherMM::eval_cpu(const std::vector<array>& inputs, array& out) {
return std::make_tuple(true, sty, arr);
} else {
temps.push_back(array(arr.shape(), arr.dtype(), nullptr, {}));
copy_cpu(arr, temps.back(), CopyType::General, s);
copy(arr, temps.back(), CopyType::General, s);
int64_t stx = arr.shape(-1);
return std::make_tuple(false, stx, temps.back());
}
@@ -503,7 +504,7 @@ void SegmentedMM::eval_cpu(const std::vector<array>& inputs, array& out) {
return std::make_tuple(true, sty, x);
} else {
array xc(x.shape(), x.dtype(), nullptr, {});
copy_cpu(x, xc, CopyType::General, s);
copy(x, xc, CopyType::General, s);
encoder.add_temporary(xc);
int64_t stx = x.shape(-1);
return std::make_tuple(false, stx, xc);

4
mlx/backend/cpu/matmul.cpp
View File

@@ -81,7 +81,7 @@ void matmul_general(
return std::make_tuple(true, sty, arr);
} else {
temps.push_back(array(arr.shape(), arr.dtype(), nullptr, {}));
copy_cpu(arr, temps.back(), CopyType::General, stream);
copy(arr, temps.back(), CopyType::General, stream);
stx = arr.shape(-1);
return std::make_tuple(false, stx, temps.back());
}
@@ -142,7 +142,7 @@ void AddMM::eval_cpu(const std::vector<array>& inputs, array& out) {
CopyType ctype = c.data_size() == 1
? CopyType::Scalar
: (c.flags().row_contiguous ? CopyType::Vector : CopyType::General);
copy_cpu(c, out, ctype, stream());
copy(c, out, ctype, stream());
if (inputs[0].shape(-1) == 0) {
return;
}

28
mlx/backend/cpu/primitives.cpp
View File

@@ -22,7 +22,7 @@ void reshape(const array& in, array& out) {
auto [copy_necessary, out_strides] = prepare_reshape(in, out);
if (copy_necessary) {
out.set_data(allocator::malloc(out.nbytes()));
copy_cpu_inplace(in, out, CopyType::General, out.primitive().stream());
copy_inplace(in, out, CopyType::General, out.primitive().stream());
} else {
shared_buffer_reshape(in, out_strides, out);
}
@@ -175,7 +175,7 @@ void AsType::eval_cpu(const std::vector<array>& inputs, array& out) {
assert(inputs.size() == 1);
auto& in = inputs[0];
CopyType ctype = in.flags().contiguous ? CopyType::Vector : CopyType::General;
copy_cpu(in, out, ctype, stream());
copy(in, out, ctype, stream());
}
void Concatenate::eval_cpu(const std::vector<array>& inputs, array& out) {
@@ -198,7 +198,7 @@ void Concatenate::eval_cpu(const std::vector<array>& inputs, array& out) {
size_t data_offset = strides[axis_] * sizes[i];
out_slice.copy_shared_buffer(
out, strides, flags, out_slice.size(), data_offset);
copy_cpu_inplace(inputs[i], out_slice, CopyType::GeneralGeneral, stream());
copy_inplace(inputs[i], out_slice, CopyType::GeneralGeneral, stream());
}
}
@@ -211,7 +211,7 @@ void Contiguous::eval_cpu(const std::vector<array>& inputs, array& out) {
(allow_col_major_ && in.flags().col_contiguous))) {
out.copy_shared_buffer(in);
} else {
copy_cpu(in, out, CopyType::General, stream());
copy(in, out, CopyType::General, stream());
}
}
@@ -235,7 +235,7 @@ void Full::eval_cpu(const std::vector<array>& inputs, array& out) {
} else {
ctype = CopyType::General;
}
copy_cpu(in, out, ctype, stream());
copy(in, out, ctype, stream());
}
void Pad::eval_cpu(const std::vector<array>& inputs, array& out) {
@@ -251,7 +251,7 @@ void Pad::eval_cpu(const std::vector<array>& inputs, array& out) {
assert(val.dtype() == in.dtype() && in.dtype() == out.dtype());
// Fill output with val
copy_cpu(val, out, CopyType::Scalar, stream());
copy(val, out, CopyType::Scalar, stream());
// Find offset for start of input values
size_t data_offset = 0;
@@ -266,7 +266,7 @@ void Pad::eval_cpu(const std::vector<array>& inputs, array& out) {
out, out.strides(), out.flags(), out_slice.size(), data_offset);
// Copy input values into the slice
copy_cpu_inplace(in, out_slice, CopyType::GeneralGeneral, stream());
copy_inplace(in, out_slice, CopyType::GeneralGeneral, stream());
}
void RandomBits::eval_cpu(const std::vector<array>& inputs, array& out) {
@@ -340,7 +340,7 @@ void DynamicSlice::eval_cpu(const std::vector<array>& inputs, array& out) {
out.set_data(allocator::malloc(out.nbytes()));
auto [in_offset, donated] =
compute_dynamic_offset(inputs[1], in.strides(), axes_, stream());
copy_cpu_inplace(
copy_inplace(
/* const array& src = */ in,
/* array& dst = */ out,
/* const Shape& data_shape = */ out.shape(),
@@ -372,11 +372,11 @@ void DynamicSliceUpdate::eval_cpu(
auto ctype = in.flags().contiguous && in.size() == in.data_size()
? CopyType::Vector
: CopyType::General;
copy_cpu(in, out, in.data_size() == 1 ? CopyType::Scalar : ctype, stream());
copy(in, out, in.data_size() == 1 ? CopyType::Scalar : ctype, stream());
auto [out_offset, donated] =
compute_dynamic_offset(inputs[2], out.strides(), axes_, stream());
copy_cpu_inplace(
copy_inplace(
/* const array& src = */ upd,
/* array& dst = */ out,
/* const std::vector<int>& data_shape = */ upd.shape(),
@@ -412,14 +412,14 @@ void SliceUpdate::eval_cpu(const std::vector<array>& inputs, array& out) {
auto ctype = in.flags().contiguous && in.size() == in.data_size()
? CopyType::Vector
: CopyType::General;
copy_cpu(in, out, in.data_size() == 1 ? CopyType::Scalar : ctype, stream());
copy(in, out, in.data_size() == 1 ? CopyType::Scalar : ctype, stream());
// Calculate out strides, initial offset and if copy needs to be made
auto [data_offset, out_strides] =
prepare_slice(out, start_indices_, strides_);
// Do copy
copy_cpu_inplace(
copy_inplace(
/* const array& src = */ upd,
/* array& dst = */ out,
/* const std::vector<int>& data_shape = */ upd.shape(),
@@ -456,9 +456,9 @@ void View::eval_cpu(const std::vector<array>& inputs, array& out) {
if (in.dtype() == bool_) {
auto in_tmp = array(in.shape(), uint8, nullptr, {});
in_tmp.copy_shared_buffer(in);
copy_cpu_inplace(in_tmp, tmp, CopyType::General, stream());
copy_inplace(in_tmp, tmp, CopyType::General, stream());
} else {
copy_cpu_inplace(in, tmp, CopyType::General, stream());
copy_inplace(in, tmp, CopyType::General, stream());
}
auto flags = out.flags();

2
mlx/backend/cpu/qrf.cpp
View File

@@ -26,7 +26,7 @@ void qrf_impl(const array& a, array& q, array& r, Stream stream) {
strides[in.ndim() - 2] = 1;
strides[in.ndim() - 1] = M;
in.set_data(allocator::malloc(in.nbytes()), in.nbytes(), strides, flags);
copy_cpu_inplace(a, in, CopyType::GeneralGeneral, stream);
copy_inplace(a, in, CopyType::GeneralGeneral, stream);
auto& encoder = cpu::get_command_encoder(stream);
q.set_data(allocator::malloc(q.nbytes()));
r.set_data(allocator::malloc(r.nbytes()));

399
mlx/backend/cpu/quantized.cpp
View File

@@ -1,5 +1,7 @@
// Copyright © 2023 Apple Inc.
#include <cassert>
#include "mlx/backend/cpu/copy.h"
#include "mlx/backend/cpu/encoder.h"
#include "mlx/backend/cpu/simd/simd.h"
@@ -11,35 +13,6 @@ namespace mlx::core {
namespace {
const static float MXFP4_LUT[16] = {
+0.0f,
+0.5f,
+1.0f,
+1.5f,
+2.0f,
+3.0f,
+4.0f,
+6.0f,
-0.0f,
-0.5f,
-1.0f,
-1.5f,
-2.0f,
-3.0f,
-4.0f,
-6.0f};
template <typename T>
static inline T dequantize_scale(uint8_t s) {
using FOrI = union {
bfloat16_t f;
uint16_t i;
};
FOrI out;
out.i = (s == 0 ? 0x40 : (static_cast<uint16_t>(s) << 7));
return static_cast<T>(out.f);
}
inline constexpr short get_pack_factor(int bits, int wsize = 8) {
return (bits == 3 || bits == 5) ? 8 : (bits == 6 ? 4 : wsize / bits);
}
@@ -434,231 +407,6 @@ void _qmm_dispatch(
}
}
template <typename T>
void mxfp4_qmm(
T* result,
const T* x,
const uint32_t* w,
const uint8_t* scales,
int M,
int N,
int K) {
constexpr int group_size = 32;
constexpr int pack_factor = get_pack_factor(4, 8);
constexpr int bytes_per_pack = get_bytes_per_pack(4);
constexpr int packs_in_group = group_size / pack_factor;
for (int m = 0; m < M; m++) {
const uint8_t* w_local = (const uint8_t*)w;
const uint8_t* scales_local = scales;
std::fill(result, result + N, 0);
for (int k = 0; k < K; k++) {
T* result_local = result;
T xi = *x++;
for (int n = 0; n < N; n += group_size) {
T scale = dequantize_scale<T>(*scales_local++);
for (int ng = 0; ng < packs_in_group; ng++) {
uint8_t wi = *w_local++;
#pragma clang loop unroll(full)
for (int p = 0; p < pack_factor; p++) {
(*result_local++) +=
xi * scale * static_cast<T>(MXFP4_LUT[wi & 0xf]);
wi >>= 4;
}
}
}
}
result += N;
}
}
template <typename T>
void mxfp4_qmm_t(
T* result,
const T* x,
const uint32_t* w,
const uint8_t* scales,
int M,
int N,
int K) {
constexpr int group_size = 32;
constexpr int pack_factor = get_pack_factor(4, 8);
constexpr int bytes_per_pack = get_bytes_per_pack(4);
constexpr int packs_in_group = group_size / pack_factor;
for (int m = 0; m < M; m++) {
const uint8_t* w_local = (const uint8_t*)w;
const uint8_t* scales_local = scales;
for (int n = 0; n < N; n++) {
const T* x_local = x;
T sum = 0;
for (int k = 0; k < K; k += group_size) {
T scale = dequantize_scale<T>(*scales_local++);
T gsum = 0;
for (int kw = 0; kw < packs_in_group; kw++) {
uint8_t wi = *w_local++;
#pragma clang loop unroll(full)
for (int p = 0; p < pack_factor; p++) {
gsum += (*x_local++) * static_cast<T>(MXFP4_LUT[wi & 0xf]);
wi >>= 4;
}
}
sum += scale * gsum;
}
*result = sum;
result++;
}
x += K;
}
}
template <int S>
simd::Simd<float, S> mxfp4_extract_bits_simd(const uint32_t* w) {
if constexpr (S == 8) {
constexpr std::array<uint32_t, 8> shifts_ = {{0, 4, 8, 12, 16, 20, 24, 28}};
auto shifts(*(simd::Simd<uint32_t, S>*)&shifts_);
auto wi = simd::Simd<uint32_t, S>(*w);
wi = wi >> shifts;
wi = wi & 0xf;
simd::Simd<float, S> w_out;
for (int i = 0; i < S; ++i) {
w_out[i] = MXFP4_LUT[wi[i]];
}
return w_out;
} else {
// Appease compiler.. but should never get here
throw std::runtime_error("Unsupported combination for simd qmm.");
}
}
template <typename T>
void mxfp4_qmm_t_simd(
T* result,
const T* x,
const uint32_t* w,
const uint8_t* scales,
int M,
int N,
int K) {
constexpr int group_size = 32;
constexpr int pack_factor = 32 / 4;
constexpr int packs_in_group = group_size / pack_factor;
constexpr int S = simd::max_size<T>;
static_assert(
S % pack_factor == 0, "SIMD size must be divisible by pack factor");
constexpr int packs_per_simd = S / pack_factor;
for (int m = 0; m < M; m++) {
const uint32_t* w_local = w;
const uint8_t* scales_local = scales;
for (int n = 0; n < N; n++) {
simd::Simd<float, S> acc(0);
auto x_local = x;
for (int k = 0; k < K; k += group_size) {
T scale = dequantize_scale<T>(*scales_local++);
simd::Simd<float, S> g_acc(0);
for (int kw = 0; kw < packs_in_group; kw += packs_per_simd) {
// Extract bits
auto wf = mxfp4_extract_bits_simd<S>(w_local);
w_local += packs_per_simd;
simd::Simd<float, S> x_simd = simd::load<T, S>(x_local);
g_acc = g_acc + x_simd * wf;
x_local += S;
}
acc = acc + scale * g_acc;
}
*result = T(simd::sum(acc));
result++;
}
x += K;
}
}
template <typename T>
void mxfp4_qmm_dispatch_transpose(
T* result,
const T* x,
const uint32_t* w,
const uint8_t* scales,
int M,
int N,
int K,
bool transposed_w) {
if (transposed_w) {
// the simd size must be a multiple of the number of elements per word
if constexpr (simd::max_size<T> % 8 == 0) {
mxfp4_qmm_t_simd<T>(result, x, w, scales, M, N, K);
} else {
mxfp4_qmm_t<T>(result, x, w, scales, M, N, K);
}
} else {
mxfp4_qmm<T>(result, x, w, scales, M, N, K);
}
}
template <typename T>
void mxfp4_qmm_dispatch_typed(
array& out,
const array& x,
const array& w,
const array& scales,
bool transposed_w) {
int K = x.shape(-1);
int M = x.ndim() > 1 ? x.shape(-2) : 1;
int N = out.shape(-1);
int w_els = w.ndim() > 2 ? w.shape(-1) * w.shape(-2) : 0;
int g_els = w.ndim() > 2 ? scales.shape(-1) * scales.shape(-2) : 0;
int batch_size = x.size() / (K * M);
auto out_ptr = out.data<T>();
auto x_ptr = x.data<T>();
auto w_ptr = w.data<uint32_t>();
auto scales_ptr = scales.data<uint8_t>();
for (int i = 0; i < batch_size; i++) {
mxfp4_qmm_dispatch_transpose<T>(
out_ptr + i * M * N,
x_ptr + elem_to_loc(i * M * K, x.shape(), x.strides()),
w_ptr + elem_to_loc(i * w_els, w.shape(), w.strides()),
scales_ptr + elem_to_loc(i * g_els, scales.shape(), scales.strides()),
M,
N,
K,
transposed_w);
}
}
void mxfp4_qmm_dispatch(
array& out,
const array& x,
const array& w,
const array& scales,
bool transposed_w) {
switch (x.dtype()) {
case bfloat16:
mxfp4_qmm_dispatch_typed<bfloat16_t>(out, x, w, scales, transposed_w);
break;
case float16:
mxfp4_qmm_dispatch_typed<float16_t>(out, x, w, scales, transposed_w);
break;
case float32:
mxfp4_qmm_dispatch_typed<float>(out, x, w, scales, transposed_w);
break;
default:
throw std::invalid_argument(
"[quantized_matmul] only floating types are supported");
}
}
template <typename T>
void _bs_qmm_dispatch_typed(
array& out,
@@ -765,106 +513,41 @@ void _bs_qmm_dispatch(
}
}
template <typename T>
void mxfp4_bs_qmm_dispatch_typed(
array& out,
const array& x,
const array& w,
const array& scales,
const array& lhs_indices,
const array& rhs_indices,
bool transposed_w) {
int K = x.shape(-1);
int M = x.shape(-2);
int N = out.shape(-1);
int w_els = w.shape(-1) * w.shape(-2);
int g_els = scales.shape(-1) * scales.shape(-2);
auto out_ptr = out.data<T>();
auto x_ptr = x.data<T>();
auto w_ptr = w.data<uint32_t>();
auto scales_ptr = scales.data<uint8_t>();
auto lhs_indices_ptr = lhs_indices.data<uint32_t>();
auto rhs_indices_ptr = rhs_indices.data<uint32_t>();
for (int i = 0; i < lhs_indices.size(); i++) {
int x_idx = lhs_indices_ptr[elem_to_loc(
i, lhs_indices.shape(), lhs_indices.strides())];
int w_idx = rhs_indices_ptr[elem_to_loc(
i, rhs_indices.shape(), rhs_indices.strides())];
mxfp4_qmm_dispatch_transpose<T>(
out_ptr + i * M * N,
x_ptr + elem_to_loc(x_idx * M * K, x.shape(), x.strides()),
w_ptr + elem_to_loc(w_idx * w_els, w.shape(), w.strides()),
scales_ptr +
elem_to_loc(w_idx * g_els, scales.shape(), scales.strides()),
M,
N,
K,
transposed_w);
}
}
void mxfp4_bs_qmm_dispatch(
array& out,
const array& x,
const array& w,
const array& scales,
const array& lhs_indices,
const array& rhs_indices,
bool transposed_w) {
switch (x.dtype()) {
case float32:
mxfp4_bs_qmm_dispatch_typed<float>(
out, x, w, scales, lhs_indices, rhs_indices, transposed_w);
break;
case float16:
mxfp4_bs_qmm_dispatch_typed<float16_t>(
out, x, w, scales, lhs_indices, rhs_indices, transposed_w);
break;
case bfloat16:
mxfp4_bs_qmm_dispatch_typed<bfloat16_t>(
out, x, w, scales, lhs_indices, rhs_indices, transposed_w);
break;
default:
throw std::invalid_argument(
"[quantized_matmul] only floating types are supported");
}
}
} // namespace
void QuantizedMatmul::eval_cpu(const std::vector<array>& inputs, array& out) {
assert(inputs.size() == 4);
auto& x_pre = inputs[0];
auto& w_pre = inputs[1];
auto& scales_pre = inputs[2];
auto& biases_pre = inputs[3];
auto& encoder = cpu::get_command_encoder(stream());
auto ensure_row_contiguous = [s = stream(), &encoder](const array& arr) {
std::vector<array> temps;
auto ensure_row_contiguous = [s = stream(), &temps](const array& arr) {
if (arr.flags().row_contiguous) {
return arr;
} else {
auto arr_cpy = array(arr.shape(), arr.dtype(), nullptr, {});
copy_cpu(arr, arr_cpy, CopyType::General, s);
encoder.add_temporary(arr_cpy);
return arr_cpy;
temps.push_back(array(arr.shape(), arr.dtype(), nullptr, {}));
copy(arr, temps.back(), CopyType::General, s);
return temps.back();
}
};
auto x = ensure_row_contiguous(x_pre);
auto w = ensure_row_contiguous(w_pre);
auto scales = ensure_row_contiguous(scales_pre);
auto biases = ensure_row_contiguous(biases_pre);
out.set_data(allocator::malloc(out.nbytes()));
auto& encoder = cpu::get_command_encoder(stream());
encoder.add_temporaries(std::move(temps));
encoder.set_input_array(x);
encoder.set_input_array(w);
encoder.set_input_array(scales);
encoder.set_output_array(out);
if (mode_ == QuantizationMode::Affine) {
auto biases = ensure_row_contiguous(inputs[3]);
encoder.set_input_array(biases);
encoder.set_output_array(out);
encoder.dispatch([out = array::unsafe_weak_copy(out),
x = array::unsafe_weak_copy(x),
w = array::unsafe_weak_copy(w),
@@ -875,54 +558,48 @@ void QuantizedMatmul::eval_cpu(const std::vector<array>& inputs, array& out) {
transpose_ = transpose_]() mutable {
_qmm_dispatch(out, x, w, scales, biases, group_size_, bits_, transpose_);
});
} else {
encoder.dispatch([out = array::unsafe_weak_copy(out),
x = array::unsafe_weak_copy(x),
w = array::unsafe_weak_copy(w),
scales = array::unsafe_weak_copy(scales),
transpose_ = transpose_]() mutable {
mxfp4_qmm_dispatch(out, x, w, scales, transpose_);
});
}
}
void GatherQMM::eval_cpu(const std::vector<array>& inputs, array& out) {
assert(inputs.size() == 6);
auto& x_pre = inputs[0];
auto& w_pre = inputs[1];
auto& scales_pre = inputs[2];
auto& lhs_indices = inputs[inputs.size() - 2];
auto& rhs_indices = inputs[inputs.size() - 1];
auto& biases_pre = inputs[3];
auto& lhs_indices = inputs[4];
auto& rhs_indices = inputs[5];
auto& encoder = cpu::get_command_encoder(stream());
std::vector<array> temps;
auto ensure_row_contiguous_last_dims = [s = stream(),
&encoder](const array& arr) {
&temps](const array& arr) {
auto stride_0 = arr.strides()[arr.ndim() - 2];
auto stride_1 = arr.strides()[arr.ndim() - 1];
if (stride_0 == arr.shape(-1) && stride_1 == 1) {
return arr;
} else {
auto arr_cpy = array(arr.shape(), arr.dtype(), nullptr, {});
copy_cpu(arr, arr_cpy, CopyType::General, s);
encoder.add_temporary(arr_cpy);
return arr_cpy;
temps.push_back(array(arr.shape(), arr.dtype(), nullptr, {}));
copy(arr, temps.back(), CopyType::General, s);
return temps.back();
}
};
auto x = ensure_row_contiguous_last_dims(x_pre);
auto w = ensure_row_contiguous_last_dims(w_pre);
auto scales = ensure_row_contiguous_last_dims(scales_pre);
auto biases = ensure_row_contiguous_last_dims(biases_pre);
out.set_data(allocator::malloc(out.nbytes()));
auto& encoder = cpu::get_command_encoder(stream());
encoder.add_temporaries(std::move(temps));
encoder.set_input_array(x);
encoder.set_input_array(w);
encoder.set_input_array(scales);
encoder.set_input_array(biases);
encoder.set_input_array(lhs_indices);
encoder.set_input_array(rhs_indices);
encoder.set_output_array(out);
if (mode_ == QuantizationMode::Affine) {
auto biases = ensure_row_contiguous_last_dims(inputs[3]);
encoder.set_input_array(biases);
encoder.dispatch([out = array::unsafe_weak_copy(out),
x = array::unsafe_weak_copy(x),
w = array::unsafe_weak_copy(w),
@@ -945,18 +622,6 @@ void GatherQMM::eval_cpu(const std::vector<array>& inputs, array& out) {
bits_,
transpose_);
});
} else {
encoder.dispatch([out = array::unsafe_weak_copy(out),
x = array::unsafe_weak_copy(x),
w = array::unsafe_weak_copy(w),
scales = array::unsafe_weak_copy(scales),
lhs_indices = array::unsafe_weak_copy(lhs_indices),
rhs_indices = array::unsafe_weak_copy(rhs_indices),
transpose_ = transpose_]() mutable {
mxfp4_bs_qmm_dispatch(
out, x, w, scales, lhs_indices, rhs_indices, transpose_);
});
}
}
template <typename T, typename U>
@@ -1040,14 +705,16 @@ void dispatch_quantize(
w_ptr, out_ptr, scales_ptr, biases_ptr, bits, group_size, w.size());
}
void fast::Quantize::eval_cpu(
void fast::AffineQuantize::eval_cpu(
const std::vector<array>& inputs,
std::vector<array>& outputs) {
auto ensure_row_contiguous = [s = stream()](const array& arr) {
if (arr.flags().row_contiguous) {
return std::make_pair(arr, false);
} else {
return std::make_pair(contiguous_copy_cpu(arr, s), true);
array arr_copy(arr.shape(), arr.dtype(), nullptr, {});
copy(arr, arr_copy, CopyType::General, s);
return std::make_pair(arr_copy, true);
}
};
@@ -1099,7 +766,7 @@ void fast::Quantize::eval_cpu(
}
} else {
throw std::runtime_error(
"[fast::Quantize::eval_cpu] Only supports floating point inputs");
"[fast::AffineQuantize::eval_cpu] Only supports floating point inputs");
}
});
}

14
mlx/backend/cpu/reduce.cpp
View File

@@ -491,27 +491,19 @@ void Reduce::eval_cpu(const std::vector<array>& inputs, array& out) {
switch (in.dtype()) {
case bool_:
case uint8:
reduce_dispatch_sum_prod<uint8_t>(in, out, reduce_type_, axes_);
break;
case uint16:
reduce_dispatch_sum_prod<uint16_t>(in, out, reduce_type_, axes_);
break;
case uint32:
reduce_dispatch_sum_prod<uint32_t>(in, out, reduce_type_, axes_);
break;
case uint64:
reduce_dispatch_sum_prod<uint64_t>(in, out, reduce_type_, axes_);
break;
case int8:
reduce_dispatch_sum_prod<int8_t>(in, out, reduce_type_, axes_);
break;
case int16:
case uint16:
reduce_dispatch_sum_prod<int16_t>(in, out, reduce_type_, axes_);
break;
case int32:
case uint32:
reduce_dispatch_sum_prod<int32_t>(in, out, reduce_type_, axes_);
break;
case int64:
case uint64:
reduce_dispatch_sum_prod<int64_t>(in, out, reduce_type_, axes_);
break;
case float16:

6
mlx/backend/cpu/scan.cpp
View File

@@ -250,8 +250,10 @@ void Scan::eval_cpu(const std::vector<array>& inputs, array& out) {
// Ensure contiguity
auto in = inputs[0];
if (!in.flags().row_contiguous) {
in = contiguous_copy_cpu(in, stream());
encoder.add_temporary(in);
array arr_copy(in.shape(), in.dtype(), nullptr, {});
copy(in, arr_copy, CopyType::General, stream());
in = arr_copy;
encoder.add_temporary(arr_copy);
}
out.set_data(allocator::malloc(out.nbytes()));

13
mlx/backend/cpu/simd/accelerate_simd.h
View File

@@ -9,7 +9,7 @@
#include "mlx/backend/cpu/simd/base_simd.h"
// There seems to be a bug in simd/base_simd.h
// There seems to be a bug in sims/base.h
// __XROS_2_0 is not defined, the expression evaluates
// to true instead of false setting the SIMD library
// higher than it should be even on macOS < 15
@@ -234,7 +234,6 @@ Simd<T, N> remainder(Simd<T, N> a, Simd<T, N> b) {
template <typename MaskT, typename T1, typename T2, int N>
Simd<T1, N> select(Simd<MaskT, N> mask, Simd<T1, N> x, Simd<T2, N> y) {
static_assert(std::is_same_v<MaskT, bool>);
if constexpr (sizeof(T1) == 1) {
return asd::bitselect(y.value, x.value, asd::convert<char>(mask.value));
} else if constexpr (sizeof(T1) == 2) {
@@ -252,13 +251,9 @@ Simd<T, N> pow(Simd<T, N> base, Simd<T, N> exp) {
return asd::pow(base.value, exp.value);
} else {
Simd<T, N> res = 1;
// Raising an integer to a negative power is undefined
if (any(exp < 0)) {
return 0;
}
while (any(exp > 0)) {
res = select((exp & 1) != 0, res * base, res);
base = select(exp > 0, base * base, base);
while (any(exp)) {
res = select(exp & 1, res * base, res);
base = select(exp, base * base, base);
exp = exp >> 1;
}
return res;

3
mlx/backend/cpu/softmax.cpp
View File

@@ -131,7 +131,8 @@ void Softmax::eval_cpu(const std::vector<array>& inputs, array& out) {
}
return x;
} else {
array x_copy = contiguous_copy_cpu(x, s);
array x_copy(x.shape(), x.dtype(), nullptr, {});
copy(x, x_copy, CopyType::General, s);
out.copy_shared_buffer(x_copy);
return x_copy;
}

55
mlx/backend/cpu/sort.cpp
View File

@@ -8,7 +8,7 @@
#include "mlx/backend/common/utils.h"
#include "mlx/backend/cpu/copy.h"
#include "mlx/backend/cpu/encoder.h"
#include "mlx/dtype_utils.h"
#include "mlx/primitives.h"
namespace mlx::core {
@@ -333,23 +333,44 @@ void Sort::eval_cpu(const std::vector<array>& inputs, array& out) {
assert(inputs.size() == 1);
auto& in = inputs[0];
int axis = axis_;
if (axis < 0) {
axis += in.ndim();
}
// Copy input to output
CopyType ctype = (in.flags().contiguous && in.strides()[axis] != 0)
? CopyType::Vector
: CopyType::General;
copy_cpu(in, out, ctype, stream());
CopyType ctype = in.flags().contiguous ? CopyType::Vector : CopyType::General;
copy(in, out, ctype, stream());
auto& encoder = cpu::get_command_encoder(stream());
encoder.set_output_array(out);
encoder.dispatch([out = array::unsafe_weak_copy(out), axis]() mutable {
dispatch_all_types(out.dtype(), [&](auto type_tag) {
sort<MLX_GET_TYPE(type_tag)>(out, axis);
});
encoder.dispatch(
[out = array::unsafe_weak_copy(out), axis_ = axis_]() mutable {
switch (out.dtype()) {
case bool_:
return sort<bool>(out, axis_);
case uint8:
return sort<uint8_t>(out, axis_);
case uint16:
return sort<uint16_t>(out, axis_);
case uint32:
return sort<uint32_t>(out, axis_);
case uint64:
return sort<uint64_t>(out, axis_);
case int8:
return sort<int8_t>(out, axis_);
case int16:
return sort<int16_t>(out, axis_);
case int32:
return sort<int32_t>(out, axis_);
case int64:
return sort<int64_t>(out, axis_);
case float32:
return sort<float>(out, axis_);
case float64:
return sort<double>(out, axis_);
case float16:
return sort<float16_t>(out, axis_);
case bfloat16:
return sort<bfloat16_t>(out, axis_);
case complex64:
return sort<complex64_t>(out, axis_);
}
});
}
@@ -405,10 +426,8 @@ void Partition::eval_cpu(const std::vector<array>& inputs, array& out) {
auto& in = inputs[0];
// Copy input to output
CopyType ctype = (in.flags().contiguous && in.strides()[axis_] != 0)
? CopyType::Vector
: CopyType::General;
copy_cpu(in, out, ctype, stream());
CopyType ctype = in.flags().contiguous ? CopyType::Vector : CopyType::General;
copy(in, out, ctype, stream());
auto& encoder = cpu::get_command_encoder(stream());
encoder.set_output_array(out);

40
mlx/backend/cpu/svd.cpp
View File

@@ -31,7 +31,7 @@ void svd_impl(
// lapack clobbers the input, so we have to make a copy.
array in(a.shape(), a.dtype(), nullptr, {});
copy_cpu(
copy(
a,
in,
a.flags().row_contiguous ? CopyType::Vector : CopyType::General,
@@ -81,7 +81,9 @@ void svd_impl(
// Vᵀ of shape N x N. (M x M in lapack).
const int ldvt = M;
auto jobz = (u_ptr) ? "A" : "N";
auto job_u = (u_ptr) ? "V" : "N";
auto job_vt = (u_ptr) ? "V" : "N";
static constexpr auto range = "A";
// Will contain the number of singular values after the call has returned.
int ns = 0;
@@ -89,20 +91,30 @@ void svd_impl(
// Will contain the indices of eigenvectors that failed to converge (not
// used here but required by lapack).
auto iwork = array::Data{allocator::malloc(sizeof(int) * 8 * K)};
auto iwork = array::Data{allocator::malloc(sizeof(int) * 12 * K)};
static const int lwork_query = -1;
static const int ignored_int = 0;
static const T ignored_float = 0;
int info;
// Compute workspace size.
gesdd<T>(
/* jobz = */ jobz,
gesvdx<T>(
/* jobu = */ job_u,
/* jobvt = */ job_vt,
/* range = */ range,
// M and N are swapped since lapack expects column-major.
/* m = */ &N,
/* n = */ &M,
/* a = */ nullptr,
/* lda = */ &lda,
/* vl = */ &ignored_float,
/* vu = */ &ignored_float,
/* il = */ &ignored_int,
/* iu = */ &ignored_int,
/* ns = */ &ns,
/* s = */ nullptr,
/* u = */ nullptr,
/* ldu = */ &ldu,
@@ -124,13 +136,20 @@ void svd_impl(
// Loop over matrices.
for (int i = 0; i < num_matrices; i++) {
gesdd<T>(
/* jobz = */ jobz,
gesvdx<T>(
/* jobu = */ job_u,
/* jobvt = */ job_vt,
/* range = */ range,
// M and N are swapped since lapack expects column-major.
/* m = */ &N,
/* n = */ &M,
/* a = */ in_ptr + M * N * i,
/* lda = */ &lda,
/* vl = */ &ignored_float,
/* vu = */ &ignored_float,
/* il = */ &ignored_int,
/* iu = */ &ignored_int,
/* ns = */ &ns,
/* s = */ s_ptr + K * i,
// According to the identity above, lapack will write Vᵀᵀ as U.
/* u = */ vt_ptr ? vt_ptr + N * N * i : nullptr,
@@ -148,6 +167,13 @@ void svd_impl(
ss << "svd_impl: sgesvdx_ failed with code " << info;
throw std::runtime_error(ss.str());
}
if (ns != K) {
std::stringstream ss;
ss << "svd_impl: expected " << K << " singular values, but " << ns
<< " were computed.";
throw std::runtime_error(ss.str());
}
}
});
encoder.add_temporary(in);

65
mlx/backend/cuda/CMakeLists.txt
View File

@@ -6,8 +6,8 @@
target_sources(
mlx
PRIVATE ${CMAKE_CURRENT_SOURCE_DIR}/allocator.cpp
${CMAKE_CURRENT_SOURCE_DIR}/arange.cu
${CMAKE_CURRENT_SOURCE_DIR}/arg_reduce.cu
${CMAKE_CURRENT_SOURCE_DIR}/binary.cu
${CMAKE_CURRENT_SOURCE_DIR}/binary_two.cu
${CMAKE_CURRENT_SOURCE_DIR}/compiled.cpp
${CMAKE_CURRENT_SOURCE_DIR}/copy.cu
@@ -15,26 +15,18 @@ target_sources(
${CMAKE_CURRENT_SOURCE_DIR}/copy/copy_general.cu
${CMAKE_CURRENT_SOURCE_DIR}/copy/copy_general_dynamic.cu
${CMAKE_CURRENT_SOURCE_DIR}/copy/copy_general_input.cu
${CMAKE_CURRENT_SOURCE_DIR}/conv.cpp
${CMAKE_CURRENT_SOURCE_DIR}/conv/gemm_conv.cu
${CMAKE_CURRENT_SOURCE_DIR}/conv/gemm_grouped_conv.cu
${CMAKE_CURRENT_SOURCE_DIR}/cuda.cpp
${CMAKE_CURRENT_SOURCE_DIR}/cudnn_utils.cpp
${CMAKE_CURRENT_SOURCE_DIR}/custom_kernel.cpp
${CMAKE_CURRENT_SOURCE_DIR}/device.cpp
${CMAKE_CURRENT_SOURCE_DIR}/distributed.cu
${CMAKE_CURRENT_SOURCE_DIR}/eval.cpp
${CMAKE_CURRENT_SOURCE_DIR}/event.cu
${CMAKE_CURRENT_SOURCE_DIR}/fence.cpp
${CMAKE_CURRENT_SOURCE_DIR}/gemms/gemv.cu
${CMAKE_CURRENT_SOURCE_DIR}/gemms/cublas_gemm.cpp
${CMAKE_CURRENT_SOURCE_DIR}/jit_module.cpp
${CMAKE_CURRENT_SOURCE_DIR}/indexing.cpp
${CMAKE_CURRENT_SOURCE_DIR}/kernel_utils.cu
${CMAKE_CURRENT_SOURCE_DIR}/matmul.cpp
${CMAKE_CURRENT_SOURCE_DIR}/layer_norm.cu
${CMAKE_CURRENT_SOURCE_DIR}/logsumexp.cu
${CMAKE_CURRENT_SOURCE_DIR}/primitives.cpp
${CMAKE_CURRENT_SOURCE_DIR}/primitives.cu
${CMAKE_CURRENT_SOURCE_DIR}/random.cu
${CMAKE_CURRENT_SOURCE_DIR}/reduce.cu
${CMAKE_CURRENT_SOURCE_DIR}/reduce/all_reduce.cu
@@ -43,28 +35,15 @@ target_sources(
${CMAKE_CURRENT_SOURCE_DIR}/reduce/row_reduce.cu
${CMAKE_CURRENT_SOURCE_DIR}/rms_norm.cu
${CMAKE_CURRENT_SOURCE_DIR}/rope.cu
${CMAKE_CURRENT_SOURCE_DIR}/scaled_dot_product_attention.cu
${CMAKE_CURRENT_SOURCE_DIR}/scan.cu
${CMAKE_CURRENT_SOURCE_DIR}/slicing.cpp
${CMAKE_CURRENT_SOURCE_DIR}/softmax.cu
${CMAKE_CURRENT_SOURCE_DIR}/sort.cu
${CMAKE_CURRENT_SOURCE_DIR}/ternary.cu
${CMAKE_CURRENT_SOURCE_DIR}/unary.cu
${CMAKE_CURRENT_SOURCE_DIR}/utils.cpp
${CMAKE_CURRENT_SOURCE_DIR}/quantized/affine_quantize.cu
${CMAKE_CURRENT_SOURCE_DIR}/quantized/quantized.cpp
${CMAKE_CURRENT_SOURCE_DIR}/worker.cpp)
add_subdirectory(${CMAKE_CURRENT_SOURCE_DIR}/binary)
add_subdirectory(${CMAKE_CURRENT_SOURCE_DIR}/unary)
if(CMAKE_CUDA_COMPILER_VERSION VERSION_GREATER_EQUAL 12.9.0)
target_sources(
mlx PRIVATE ${CMAKE_CURRENT_SOURCE_DIR}/gemms/cublas_gemm_batched_12_9.cu)
else()
target_sources(
mlx PRIVATE ${CMAKE_CURRENT_SOURCE_DIR}/gemms/cublas_gemm_batched_12_0.cpp)
endif()
target_compile_definitions(mlx PRIVATE MLX_USE_CUDA)
# Embed kernel sources in binary for JIT compilation.
@@ -107,18 +86,11 @@ endif()
target_compile_options(
mlx PRIVATE "$<$<COMPILE_LANGUAGE:CUDA>:--Wno-deprecated-gpu-targets>")
# Use stronger binaries compression. This feature was introduced in CUDA 12.8
# and requires drivers released after CUDA 12.4.
if(CMAKE_CUDA_COMPILER_VERSION VERSION_GREATER_EQUAL 12.8.0)
target_compile_options(
mlx PRIVATE "$<$<COMPILE_LANGUAGE:CUDA>:--compress-mode=size>")
endif()
# Compute capability >= 7.0 is required for synchronization between CPU/GPU with
# managed memory.
if(NOT DEFINED MLX_CUDA_ARCHITECTURES)
set(MLX_CUDA_ARCHITECTURES "native")
endif()
# Compute capability 7 is required for synchronization between CPU/GPU with
# managed memory. TODO: Add more architectures for potential performance gain.
set(MLX_CUDA_ARCHITECTURES
"70;80"
CACHE STRING "CUDA architectures")
message(STATUS "CUDA architectures: ${MLX_CUDA_ARCHITECTURES}")
set_target_properties(mlx PROPERTIES CUDA_ARCHITECTURES
"${MLX_CUDA_ARCHITECTURES}")
@@ -150,27 +122,6 @@ target_link_libraries(mlx PRIVATE CUDA::cublasLt)
# Use NVRTC and driver APIs.
target_link_libraries(mlx PRIVATE CUDA::nvrtc CUDA::cuda_driver)
# Use the frontend APIs of cuDNN.
FetchContent_Declare(
cudnn
GIT_REPOSITORY https://github.com/NVIDIA/cudnn-frontend.git
GIT_TAG v1.14.0
GIT_SHALLOW TRUE
EXCLUDE_FROM_ALL)
set(CUDNN_FRONTEND_SKIP_JSON_LIB ON)
set(CUDNN_FRONTEND_BUILD_SAMPLES OFF)
set(CUDNN_FRONTEND_BUILD_TESTS OFF)
set(CUDNN_FRONTEND_BUILD_PYTHON_BINDINGS OFF)
FetchContent_MakeAvailable(cudnn)
target_link_libraries(mlx PRIVATE cudnn_frontend)
# Link with the actual cuDNN libraries.
include(${cudnn_frontend_SOURCE_DIR}/cmake/cuDNN.cmake)
target_link_libraries(mlx PRIVATE CUDNN::cudnn_all)
# Suppress nvcc warnings on MLX headers.
target_compile_options(mlx PRIVATE $<$<COMPILE_LANGUAGE:CUDA>:-Xcudafe
--diag_suppress=997>)
# Install CCCL headers for JIT.
install(DIRECTORY ${cccl_SOURCE_DIR}/include/cuda
DESTINATION ${CMAKE_INSTALL_INCLUDEDIR}/cccl)

122
mlx/backend/cuda/allocator.cpp
View File

@@ -2,6 +2,7 @@
#include "mlx/backend/cuda/allocator.h"
#include "mlx/backend/cuda/utils.h"
#include "mlx/backend/cuda/worker.h"
#include "mlx/utils.h"
#include <cuda_runtime.h>
@@ -16,77 +17,18 @@ namespace cu {
constexpr int page_size = 16384;
// Any allocations smaller than this will try to use the small pool
constexpr int small_block_size = 8;
// The small pool size in bytes. This should be a multiple of the host page
// size and small_block_size.
constexpr int small_pool_size = 4 * page_size;
SmallSizePool::SmallSizePool() {
auto num_blocks = small_pool_size / small_block_size;
buffer_ = new Block[num_blocks];
next_free_ = buffer_;
CHECK_CUDA_ERROR(cudaMallocManaged(&data_, small_pool_size));
#if CUDART_VERSION >= 13000
cudaMemLocation loc;
loc.type = cudaMemLocationTypeDevice;
loc.id = 0;
#else
int loc = 0;
#endif // CUDART_VERSION >= 13000
CHECK_CUDA_ERROR(
cudaMemAdvise(data_, small_pool_size, cudaMemAdviseSetReadMostly, loc));
auto curr = next_free_;
for (size_t i = 1; i < num_blocks; ++i) {
curr->next = buffer_ + i;
curr = curr->next;
}
curr->next = nullptr;
}
SmallSizePool::~SmallSizePool() {
CHECK_CUDA_ERROR(cudaFree(data_));
delete[] buffer_;
}
CudaBuffer* SmallSizePool::malloc() {
if (next_free_ == nullptr) {
return nullptr;
}
Block* b = next_free_;
uint64_t i = next_free_ - buffer_;
next_free_ = next_free_->next;
b->buf.data = static_cast<char*>(data_) + i * small_block_size;
b->buf.size = small_block_size;
return &b->buf;
}
void SmallSizePool::free(CudaBuffer* buf) {
auto b = reinterpret_cast<Block*>(buf);
b->next = next_free_;
next_free_ = b;
}
bool SmallSizePool::in_pool(CudaBuffer* buf) {
constexpr int num_blocks = (small_pool_size / small_block_size);
auto b = reinterpret_cast<Block*>(buf);
int64_t block_num = b - buffer_;
return block_num >= 0 && block_num < num_blocks;
}
CudaAllocator::CudaAllocator()
: buffer_cache_(
page_size,
[](CudaBuffer* buf) { return buf->size; },
[this](CudaBuffer* buf) { cuda_free(buf); }) {
[this](CudaBuffer* buf) {
cuda_free(buf->data);
delete buf;
}) {
// TODO: Set memory limit for multi-device.
size_t free, total;
CHECK_CUDA_ERROR(cudaMemGetInfo(&free, &total));
memory_limit_ = total * 0.95;
memory_limit_ = total * 0.8;
max_pool_size_ = memory_limit_;
}
@@ -94,9 +36,7 @@ Buffer CudaAllocator::malloc(size_t size) {
// Find available buffer from cache.
auto orig_size = size;
std::unique_lock lock(mutex_);
if (size <= small_block_size) {
size = 8;
} else if (size < page_size) {
if (size < page_size) {
size = next_power_of_2(size);
} else {
size = page_size * ((size + page_size - 1) / page_size);
@@ -104,26 +44,20 @@ Buffer CudaAllocator::malloc(size_t size) {
CudaBuffer* buf = buffer_cache_.reuse_from_cache(size);
if (!buf) {
// If we have a lot of memory pressure try to reclaim memory from the cache.
int64_t mem_to_free =
get_active_memory() + get_cache_memory() + size - memory_limit_;
if (mem_to_free > 0) {
buffer_cache_.release_cached_buffers(mem_to_free);
// If we have a lot of memory pressure or are over the maximum cache size,
// try to reclaim memory from the cache.
size_t mem_required = get_active_memory() + get_cache_memory() + size;
if (mem_required >= memory_limit_) {
buffer_cache_.release_cached_buffers(mem_required - memory_limit_);
}
// Try the scalar pool first
if (size <= small_block_size) {
buf = scalar_pool_.malloc();
}
lock.unlock();
if (!buf) {
buf = new CudaBuffer{nullptr, size};
cudaError_t err = cudaMallocManaged(&buf->data, size);
if (err != cudaSuccess && err != cudaErrorMemoryAllocation) {
throw std::runtime_error(fmt::format(
"cudaMallocManaged failed: {}.", cudaGetErrorString(err)));
}
}
lock.lock();
}
active_memory_ += size;
@@ -133,6 +67,7 @@ Buffer CudaAllocator::malloc(size_t size) {
if (get_cache_memory() > max_pool_size_) {
buffer_cache_.release_cached_buffers(get_cache_memory() - max_pool_size_);
}
return Buffer{buf};
}
@@ -147,7 +82,9 @@ void CudaAllocator::free(Buffer buffer) {
if (get_cache_memory() < max_pool_size_) {
buffer_cache_.recycle_to_cache(buf);
} else {
cuda_free(buf);
lock.unlock();
cuda_free(buf->data);
delete buf;
}
}
@@ -159,14 +96,27 @@ size_t CudaAllocator::size(Buffer buffer) const {
return buf->size;
}
// This must be called with mutex_ aquired
void CudaAllocator::cuda_free(CudaBuffer* buf) {
if (scalar_pool_.in_pool(buf)) {
scalar_pool_.free(buf);
} else {
cudaFree(buf->data);
delete buf;
void CudaAllocator::register_this_thread() {
std::lock_guard lock(worker_mutex_);
allowed_threads_.insert(std::this_thread::get_id());
}
void CudaAllocator::cuda_free(void* buf) {
// If cuda_free() is called from a unregistered thread, reschedule the call to
// worker.
{
std::lock_guard lock(worker_mutex_);
if (allowed_threads_.count(std::this_thread::get_id()) == 0) {
if (!worker_) {
worker_.reset(new Worker);
}
worker_->add_task([this, buf]() { this->cuda_free(buf); });
worker_->end_batch();
worker_->commit();
return;
}
}
cudaFree(buf);
}
size_t CudaAllocator::get_active_memory() const {

42
mlx/backend/cuda/allocator.h
View File

@@ -7,10 +7,13 @@
#include <mutex>
#include <set>
#include <thread>
#include <utility>
namespace mlx::core::cu {
class Worker;
using allocator::Buffer;
// Stores cuda-managed unified memory.
@@ -19,35 +22,21 @@ struct CudaBuffer {
size_t size;
};
class SmallSizePool {
private:
union Block {
Block* next;
CudaBuffer buf;
};
Block* buffer_{nullptr};
void* data_{nullptr};
Block* next_free_{nullptr};
public:
SmallSizePool();
~SmallSizePool();
SmallSizePool(const SmallSizePool&) = delete;
SmallSizePool& operator=(const SmallSizePool&) = delete;
CudaBuffer* malloc();
void free(CudaBuffer* buf);
bool in_pool(CudaBuffer* buf);
};
class CudaAllocator : public allocator::Allocator {
public:
Buffer malloc(size_t size) override;
void free(Buffer buffer) override;
size_t size(Buffer buffer) const override;
// Register current thread as safe to free buffers.
// In cuda freeing a buffer implicitly synchronizes stream, and for threads
// that may be waited by gpu stream (for example cpu stream threads), freeing
// buffers there would result in dead lock.
void register_this_thread();
// Call cudaFree in the safe thread.
void cuda_free(void* buf);
size_t get_active_memory() const;
size_t get_peak_memory() const;
void reset_peak_memory();
@@ -58,18 +47,19 @@ class CudaAllocator : public allocator::Allocator {
void clear_cache();
private:
void cuda_free(CudaBuffer* buf);
CudaAllocator();
friend CudaAllocator& allocator();
std::mutex worker_mutex_;
std::unique_ptr<Worker> worker_;
std::set<std::thread::id> allowed_threads_;
std::mutex mutex_;
size_t memory_limit_;
size_t max_pool_size_;
BufferCache<CudaBuffer> buffer_cache_;
size_t active_memory_{0};
size_t peak_memory_{0};
SmallSizePool scalar_pool_;
};
CudaAllocator& allocator();

69
mlx/backend/cuda/arange.cu
View File

@@ -1,69 +0,0 @@
// Copyright © 2025 Apple Inc.
#include "mlx/backend/cuda/device.h"
#include "mlx/backend/cuda/device/fp16_math.cuh"
#include "mlx/backend/cuda/kernel_utils.cuh"
#include "mlx/dtype_utils.h"
#include "mlx/primitives.h"
#include <cooperative_groups.h>
#include <nvtx3/nvtx3.hpp>
namespace mlx::core {
namespace cu {
namespace cg = cooperative_groups;
template <typename T, typename IdxT, int N_WRITES>
__global__ void arange(T* out, IdxT size, T start, T step) {
IdxT index = cg::this_grid().thread_rank();
if ((index + 1) * N_WRITES > size) {
for (IdxT i = index * N_WRITES; i < size; ++i) {
out[i] = start + i * step;
}
} else {
AlignedVector<T, N_WRITES> out_vec;
#pragma unroll
for (int i = 0; i < N_WRITES; ++i) {
out_vec[i] = start + (index * N_WRITES + i) * step;
}
store_vector<N_WRITES>(out, index, out_vec);
}
}
} // namespace cu
void Arange::eval_gpu(const std::vector<array>& inputs, array& out) {
nvtx3::scoped_range r("Arange::eval_gpu");
if (out.size() == 0) {
return;
}
out.set_data(allocator::malloc(out.nbytes()));
auto& encoder = cu::get_command_encoder(stream());
encoder.set_output_array(out);
dispatch_int_float_types(out.dtype(), "Arange", [&](auto type_tag) {
using CTYPE = MLX_GET_TYPE(type_tag);
using OutType = cuda_type_t<CTYPE>;
constexpr int N_WRITES = 16 / sizeof(OutType);
dispatch_bool(out.data_size() > INT32_MAX, [&](auto large) {
using IdxT = std::conditional_t<large(), int64_t, int32_t>;
auto [num_blocks, block_dims] = get_launch_args(out, large(), N_WRITES);
encoder.add_kernel_node(
cu::arange<OutType, IdxT, N_WRITES>,
num_blocks,
block_dims,
0,
out.data<OutType>(),
out.data_size(),
static_cast<CTYPE>(start_),
static_cast<CTYPE>(start_ + step_) - static_cast<CTYPE>(start_));
});
});
}
} // namespace mlx::core

22
mlx/backend/cuda/arg_reduce.cu
View File

@@ -1,8 +1,8 @@
// Copyright © 2025 Apple Inc.
#include "mlx/backend/common/utils.h"
#include "mlx/backend/cuda/device.h"
#include "mlx/backend/cuda/device/fp16_math.cuh"
#include "mlx/backend/cuda/iterators/strided_iterator.cuh"
#include "mlx/backend/cuda/kernel_utils.cuh"
#include "mlx/dtype_utils.h"
#include "mlx/primitives.h"
@@ -44,11 +44,8 @@ struct ArgMin {
}
template <int N>
__device__ IndexValPair<T> reduce_many(
IndexValPair<T> best,
const AlignedVector<T, N>& vals,
uint32_t offset) {
#pragma unroll
__device__ IndexValPair<T>
reduce_many(IndexValPair<T> best, T (&vals)[N], uint32_t offset) {
for (int i = 0; i < N; i++) {
if (vals[i] < best.val) {
best.val = vals[i];
@@ -77,11 +74,8 @@ struct ArgMax {
}
template <int N>
__device__ IndexValPair<T> reduce_many(
IndexValPair<T> best,
const AlignedVector<T, N>& vals,
uint32_t offset) {
#pragma unroll
__device__ IndexValPair<T>
reduce_many(IndexValPair<T> best, T (&vals)[N], uint32_t offset) {
for (int i = 0; i < N; i++) {
if (vals[i] > best.val) {
best.val = vals[i];
@@ -112,15 +106,16 @@ __global__ void arg_reduce_general(
int64_t in_idx = elem_to_loc(index, shape.data(), in_strides.data(), ndim);
int64_t out_idx = elem_to_loc(index, shape.data(), out_strides.data(), ndim);
in += in_idx;
Op op;
T init = op.init();
IndexValPair<T> best{0, init};
for (int r = 0; r < cuda::ceil_div(axis_size, BLOCK_DIM * N_READS); ++r) {
T vals[N_READS];
auto tid = r * BLOCK_DIM + block.thread_index().x;
auto vals = load_vector<N_READS>(in, tid, axis_size, axis_stride, init);
cub::LoadDirectBlocked(
tid, strided_iterator(in + in_idx, axis_stride), vals, axis_size, init);
best = op.reduce_many(best, vals, tid * N_READS);
}
@@ -171,7 +166,6 @@ void ArgReduce::eval_gpu(const std::vector<array>& inputs, array& out) {
kernel,
num_blocks,
block_dim(),
0,
in.data<T>(),
out.data<uint32_t>(),
out.size(),

201
mlx/backend/cuda/binary/binary.cuh → mlx/backend/cuda/binary.cu
View File

@@ -3,6 +3,7 @@
#include "mlx/backend/common/binary.h"
#include "mlx/backend/cuda/device.h"
#include "mlx/backend/cuda/device/binary_ops.cuh"
#include "mlx/backend/cuda/device/cucomplex_math.cuh"
#include "mlx/backend/cuda/kernel_utils.cuh"
#include "mlx/dtype_utils.h"
#include "mlx/primitives.h"
@@ -28,7 +29,7 @@ __global__ void binary_ss(const In* a, const In* b, Out* out, IdxT size) {
AlignedVector<Out, N_READS> out_vec;
#pragma unroll
for (int i = 0; i < N_READS; ++i) {
out_vec[i] = Op{}(a[0], b[0]);
out_vec.val[i] = Op{}(a[0], b[0]);
}
store_vector<N_READS>(out, index, out_vec);
@@ -49,7 +50,7 @@ __global__ void binary_sv(const In* a, const In* b, Out* out, IdxT size) {
AlignedVector<Out, N_READS> out_vec;
#pragma unroll
for (int i = 0; i < N_READS; ++i) {
out_vec[i] = Op{}(a[0], b_vec[i]);
out_vec.val[i] = Op{}(a[0], b_vec.val[i]);
}
store_vector<N_READS>(out, index, out_vec);
@@ -70,7 +71,7 @@ __global__ void binary_vs(const In* a, const In* b, Out* out, IdxT size) {
AlignedVector<Out, N_READS> out_vec;
#pragma unroll
for (int i = 0; i < N_READS; ++i) {
out_vec[i] = Op{}(a_vec[i], b[0]);
out_vec.val[i] = Op{}(a_vec.val[i], b[0]);
}
store_vector<N_READS>(out, index, out_vec);
@@ -92,96 +93,46 @@ __global__ void binary_vv(const In* a, const In* b, Out* out, IdxT size) {
AlignedVector<Out, N_READS> out_vec;
#pragma unroll
for (int i = 0; i < N_READS; ++i) {
out_vec[i] = Op{}(a_vec[i], b_vec[i]);
out_vec.val[i] = Op{}(a_vec.val[i], b_vec.val[i]);
}
store_vector<N_READS>(out, index, out_vec);
}
}
template <
typename Op,
typename In,
typename Out,
typename IdxT,
int NDIM,
int N_READS>
template <typename Op, typename In, typename Out, typename IdxT, int NDIM>
__global__ void binary_g_nd(
const In* a,
const In* b,
Out* out,
IdxT size_rest,
IdxT size,
const __grid_constant__ cuda::std::array<int32_t, NDIM> shape,
const __grid_constant__ cuda::std::array<int64_t, NDIM> a_strides,
const __grid_constant__ cuda::std::array<int64_t, NDIM> b_strides) {
auto block = cg::this_thread_block();
auto grid = cg::this_grid();
IdxT index_rest =
grid.block_index().y * block.dim_threads().y + block.thread_index().y;
if (index_rest >= size_rest) {
return;
}
auto shape_x = shape[NDIM - 1];
auto a_stride_x = a_strides[NDIM - 1];
auto b_stride_x = b_strides[NDIM - 1];
IdxT index_x =
grid.block_index().x * block.dim_threads().x + block.thread_index().x;
IdxT index = cg::this_grid().thread_rank();
if (index < size) {
auto [a_idx, b_idx] = elem_to_loc_nd<NDIM>(
index_rest * shape_x, shape.data(), a_strides.data(), b_strides.data());
auto a_vec =
load_vector<N_READS>(a + a_idx, index_x, shape_x, a_stride_x, In(0));
auto b_vec =
load_vector<N_READS>(b + b_idx, index_x, shape_x, b_stride_x, In(0));
AlignedVector<Out, N_READS> out_vec;
#pragma unroll
for (int i = 0; i < N_READS; ++i) {
out_vec[i] = Op{}(a_vec[i], b_vec[i]);
index, shape.data(), a_strides.data(), b_strides.data());
out[index] = Op{}(a[a_idx], b[b_idx]);
}
store_vector(out + shape_x * index_rest, index_x, out_vec, shape_x);
}
template <typename Op, typename In, typename Out, typename IdxT, int N_READS>
template <typename Op, typename In, typename Out, typename IdxT>
__global__ void binary_g(
const In* a,
const In* b,
Out* out,
IdxT size_rest,
IdxT size,
const __grid_constant__ Shape shape,
const __grid_constant__ Strides a_strides,
const __grid_constant__ Strides b_strides,
int ndim) {
auto block = cg::this_thread_block();
auto grid = cg::this_grid();
IdxT index_rest =
grid.block_index().y * block.dim_threads().y + block.thread_index().y;
if (index_rest >= size_rest) {
return;
IdxT index = cg::this_grid().thread_rank();
if (index < size) {
auto [a_idx, b_idx] = elem_to_loc_4d(
index, shape.data(), a_strides.data(), b_strides.data(), ndim);
out[index] = Op{}(a[a_idx], b[b_idx]);
}
auto shape_x = shape[ndim - 1];
auto a_stride_x = a_strides[ndim - 1];
auto b_stride_x = b_strides[ndim - 1];
IdxT index_x =
grid.block_index().x * block.dim_threads().x + block.thread_index().x;
auto [a_idx, b_idx] = elem_to_loc(
index_rest * shape_x,
shape.data(),
a_strides.data(),
b_strides.data(),
ndim);
auto a_vec =
load_vector<N_READS>(a + a_idx, index_x, shape_x, a_stride_x, In(0));
auto b_vec =
load_vector<N_READS>(b + b_idx, index_x, shape_x, b_stride_x, In(0));
AlignedVector<Out, N_READS> out_vec;
#pragma unroll
for (int i = 0; i < N_READS; ++i) {
out_vec[i] = Op{}(a_vec[i], b_vec[i]);
}
store_vector(out + shape_x * index_rest, index_x, out_vec, shape_x);
}
template <typename Op, typename In, typename Out>
@@ -226,7 +177,7 @@ template <typename Op>
void binary_op_gpu_inplace(
const std::vector<array>& inputs,
array& out,
const char* op,
std::string_view op,
const Stream& s) {
assert(inputs.size() > 1);
const auto& a = inputs[0];
@@ -259,61 +210,36 @@ void binary_op_gpu_inplace(
auto& a_strides = strides[0];
auto& b_strides = strides[1];
int ndim = shape.size();
int work_per_thread = 1;
auto dim0 = ndim > 0 ? shape.back() : 1;
auto rest = out.size() / dim0;
if (dim0 >= 4) {
work_per_thread = 4;
}
dim0 = (dim0 + work_per_thread - 1) / work_per_thread;
auto block_dims = get_block_dims(dim0, rest, 1);
uint32_t num_blocks_x = cuda::ceil_div(dim0, block_dims.x);
uint32_t num_blocks_y = cuda::ceil_div(rest, block_dims.y);
if (ndim <= 3) {
dispatch_1_2_3(ndim, [&](auto dims_constant) {
auto kernel = cu::binary_g_nd<
Op,
InType,
OutType,
IdxT,
dims_constant(),
1>;
if (work_per_thread == 4) {
kernel = cu::binary_g_nd<
Op,
InType,
OutType,
IdxT,
dims_constant(),
4>;
}
auto kernel = cu::
binary_g_nd<Op, InType, OutType, IdxT, dims_constant()>;
auto [num_blocks, block_dims] =
get_launch_args(kernel, out, large());
encoder.add_kernel_node(
kernel,
{num_blocks_x, num_blocks_y},
num_blocks,
block_dims,
0,
a.data<InType>(),
b.data<InType>(),
out.data<OutType>(),
rest,
out.size(),
const_param<dims_constant()>(shape),
const_param<dims_constant()>(a_strides),
const_param<dims_constant()>(b_strides));
});
} else {
auto kernel = cu::binary_g<Op, InType, OutType, IdxT, 1>;
if (work_per_thread == 4) {
kernel = cu::binary_g<Op, InType, OutType, IdxT, 4>;
}
auto kernel = cu::binary_g<Op, InType, OutType, IdxT>;
auto [num_blocks, block_dims] =
get_launch_args(kernel, out, large());
encoder.add_kernel_node(
kernel,
{num_blocks_x, num_blocks_y},
num_blocks,
block_dims,
0,
a.data<InType>(),
b.data<InType>(),
out.data<OutType>(),
rest,
out.size(),
const_param(shape),
const_param(a_strides),
const_param(b_strides),
@@ -323,7 +249,8 @@ void binary_op_gpu_inplace(
} else {
dispatch_bool(out.data_size() > UINT32_MAX, [&](auto large) {
using IdxT = std::conditional_t<large(), int64_t, uint32_t>;
constexpr int N_READS = 16 / sizeof(InType);
// TODO: Choose optimized value based on type size.
constexpr int N_READS = 4;
auto kernel = cu::binary_ss<Op, InType, OutType, IdxT, N_READS>;
if (bopt == BinaryOpType::ScalarVector) {
kernel = cu::binary_sv<Op, InType, OutType, IdxT, N_READS>;
@@ -333,12 +260,16 @@ void binary_op_gpu_inplace(
kernel = cu::binary_vv<Op, InType, OutType, IdxT, N_READS>;
}
auto [num_blocks, block_dims] = get_launch_args(
out.data_size(), out.shape(), out.strides(), large(), N_READS);
kernel,
out.data_size(),
out.shape(),
out.strides(),
large(),
N_READS);
encoder.add_kernel_node(
kernel,
num_blocks,
block_dims,
0,
a.data<InType>(),
b.data<InType>(),
out.data<OutType>(),
@@ -360,7 +291,7 @@ template <typename Op>
void binary_op_gpu(
const std::vector<array>& inputs,
array& out,
const char* op,
std::string_view op,
const Stream& s) {
auto& a = inputs[0];
auto& b = inputs[1];
@@ -373,7 +304,59 @@ void binary_op_gpu(
void func::eval_gpu(const std::vector<array>& inputs, array& out) { \
nvtx3::scoped_range r(#func "::eval_gpu"); \
auto& s = out.primitive().stream(); \
binary_op_gpu<cu::func>(inputs, out, name(), s); \
binary_op_gpu<cu::func>(inputs, out, get_primitive_string(this), s); \
}
BINARY_GPU(Add)
BINARY_GPU(ArcTan2)
BINARY_GPU(Divide)
BINARY_GPU(Remainder)
BINARY_GPU(Greater)
BINARY_GPU(GreaterEqual)
BINARY_GPU(Less)
BINARY_GPU(LessEqual)
BINARY_GPU(LogicalAnd)
BINARY_GPU(LogicalOr)
BINARY_GPU(LogAddExp)
BINARY_GPU(Maximum)
BINARY_GPU(Minimum)
BINARY_GPU(Multiply)
BINARY_GPU(NotEqual)
BINARY_GPU(Power)
BINARY_GPU(Subtract)
void Equal::eval_gpu(const std::vector<array>& inputs, array& out) {
nvtx3::scoped_range r("Equal::eval_gpu");
auto& s = out.primitive().stream();
auto op = get_primitive_string(this);
if (equal_nan_) {
binary_op_gpu<cu::NaNEqual>(inputs, out, op, s);
} else {
binary_op_gpu<cu::Equal>(inputs, out, op, s);
}
}
void BitwiseBinary::eval_gpu(const std::vector<array>& inputs, array& out) {
nvtx3::scoped_range r("BitwiseBinary::eval_gpu");
auto& s = out.primitive().stream();
auto op = get_primitive_string(this);
switch (op_) {
case BitwiseBinary::And:
binary_op_gpu<cu::BitwiseAnd>(inputs, out, op, s);
break;
case BitwiseBinary::Or:
binary_op_gpu<cu::BitwiseOr>(inputs, out, op, s);
break;
case BitwiseBinary::Xor:
binary_op_gpu<cu::BitwiseXor>(inputs, out, op, s);
break;
case BitwiseBinary::LeftShift:
binary_op_gpu<cu::LeftShift>(inputs, out, op, s);
break;
case BitwiseBinary::RightShift:
binary_op_gpu<cu::RightShift>(inputs, out, op, s);
break;
}
}
} // namespace mlx::core

21
mlx/backend/cuda/binary/CMakeLists.txt
View File

@@ -1,21 +0,0 @@
target_sources(
mlx
PRIVATE ${CMAKE_CURRENT_SOURCE_DIR}/add.cu
PRIVATE ${CMAKE_CURRENT_SOURCE_DIR}/arctan2.cu
PRIVATE ${CMAKE_CURRENT_SOURCE_DIR}/bitwise_binary.cu
PRIVATE ${CMAKE_CURRENT_SOURCE_DIR}/divide.cu
PRIVATE ${CMAKE_CURRENT_SOURCE_DIR}/equal.cu
PRIVATE ${CMAKE_CURRENT_SOURCE_DIR}/greater.cu
PRIVATE ${CMAKE_CURRENT_SOURCE_DIR}/greater_equal.cu
PRIVATE ${CMAKE_CURRENT_SOURCE_DIR}/less.cu
PRIVATE ${CMAKE_CURRENT_SOURCE_DIR}/less_equal.cu
PRIVATE ${CMAKE_CURRENT_SOURCE_DIR}/logical_and.cu
PRIVATE ${CMAKE_CURRENT_SOURCE_DIR}/logical_or.cu
PRIVATE ${CMAKE_CURRENT_SOURCE_DIR}/log_add_exp.cu
PRIVATE ${CMAKE_CURRENT_SOURCE_DIR}/minimum.cu
PRIVATE ${CMAKE_CURRENT_SOURCE_DIR}/maximum.cu
PRIVATE ${CMAKE_CURRENT_SOURCE_DIR}/multiply.cu
PRIVATE ${CMAKE_CURRENT_SOURCE_DIR}/power.cu
PRIVATE ${CMAKE_CURRENT_SOURCE_DIR}/remainder.cu
PRIVATE ${CMAKE_CURRENT_SOURCE_DIR}/not_equal.cu
PRIVATE ${CMAKE_CURRENT_SOURCE_DIR}/subtract.cu)

7
mlx/backend/cuda/binary/add.cu
View File

@@ -1,7 +0,0 @@
// Copyright © 2025 Apple Inc.
#include "mlx/backend/cuda/binary/binary.cuh"
namespace mlx::core {
BINARY_GPU(Add)
} // namespace mlx::core

7
mlx/backend/cuda/binary/arctan2.cu
View File

@@ -1,7 +0,0 @@
// Copyright © 2025 Apple Inc.
#include "mlx/backend/cuda/binary/binary.cuh"
namespace mlx::core {
BINARY_GPU(ArcTan2)
} // namespace mlx::core

27
mlx/backend/cuda/binary/bitwise_binary.cu
View File

@@ -1,27 +0,0 @@
// Copyright © 2025 Apple Inc.
#include "mlx/backend/cuda/binary/binary.cuh"
namespace mlx::core {
void BitwiseBinary::eval_gpu(const std::vector<array>& inputs, array& out) {
nvtx3::scoped_range r("BitwiseBinary::eval_gpu");
auto& s = out.primitive().stream();
switch (op_) {
case BitwiseBinary::And:
binary_op_gpu<cu::BitwiseAnd>(inputs, out, name(), s);
break;
case BitwiseBinary::Or:
binary_op_gpu<cu::BitwiseOr>(inputs, out, name(), s);
break;
case BitwiseBinary::Xor:
binary_op_gpu<cu::BitwiseXor>(inputs, out, name(), s);
break;
case BitwiseBinary::LeftShift:
binary_op_gpu<cu::LeftShift>(inputs, out, name(), s);
break;
case BitwiseBinary::RightShift:
binary_op_gpu<cu::RightShift>(inputs, out, name(), s);
break;
}
}
} // namespace mlx::core

7
mlx/backend/cuda/binary/divide.cu
View File

@@ -1,7 +0,0 @@
// Copyright © 2025 Apple Inc.
#include "mlx/backend/cuda/binary/binary.cuh"
namespace mlx::core {
BINARY_GPU(Divide)
} // namespace mlx::core

15
mlx/backend/cuda/binary/equal.cu
View File

@@ -1,15 +0,0 @@
// Copyright © 2025 Apple Inc.
#include "mlx/backend/cuda/binary/binary.cuh"
namespace mlx::core {
void Equal::eval_gpu(const std::vector<array>& inputs, array& out) {
nvtx3::scoped_range r("Equal::eval_gpu");
auto& s = out.primitive().stream();
if (equal_nan_) {
binary_op_gpu<cu::NaNEqual>(inputs, out, name(), s);
} else {
binary_op_gpu<cu::Equal>(inputs, out, name(), s);
}
}
} // namespace mlx::core

7
mlx/backend/cuda/binary/greater.cu
View File

@@ -1,7 +0,0 @@
// Copyright © 2025 Apple Inc.
#include "mlx/backend/cuda/binary/binary.cuh"
namespace mlx::core {
BINARY_GPU(Greater)
} // namespace mlx::core

7
mlx/backend/cuda/binary/greater_equal.cu
View File

@@ -1,7 +0,0 @@
// Copyright © 2025 Apple Inc.
#include "mlx/backend/cuda/binary/binary.cuh"
namespace mlx::core {
BINARY_GPU(GreaterEqual)
} // namespace mlx::core

7
mlx/backend/cuda/binary/less.cu
View File

@@ -1,7 +0,0 @@
// Copyright © 2025 Apple Inc.
#include "mlx/backend/cuda/binary/binary.cuh"
namespace mlx::core {
BINARY_GPU(Less)
} // namespace mlx::core

7
mlx/backend/cuda/binary/less_equal.cu
View File

@@ -1,7 +0,0 @@
// Copyright © 2025 Apple Inc.
#include "mlx/backend/cuda/binary/binary.cuh"
namespace mlx::core {
BINARY_GPU(LessEqual)
} // namespace mlx::core

7
mlx/backend/cuda/binary/log_add_exp.cu
View File

@@ -1,7 +0,0 @@
// Copyright © 2025 Apple Inc.
#include "mlx/backend/cuda/binary/binary.cuh"
namespace mlx::core {
BINARY_GPU(LogAddExp)
} // namespace mlx::core

7
mlx/backend/cuda/binary/logical_and.cu
View File

@@ -1,7 +0,0 @@
// Copyright © 2025 Apple Inc.
#include "mlx/backend/cuda/binary/binary.cuh"
namespace mlx::core {
BINARY_GPU(LogicalAnd)
} // namespace mlx::core

7
mlx/backend/cuda/binary/logical_or.cu
View File

@@ -1,7 +0,0 @@
// Copyright © 2025 Apple Inc.
#include "mlx/backend/cuda/binary/binary.cuh"
namespace mlx::core {
BINARY_GPU(LogicalOr)
} // namespace mlx::core

7
mlx/backend/cuda/binary/maximum.cu
View File

@@ -1,7 +0,0 @@
// Copyright © 2025 Apple Inc.
#include "mlx/backend/cuda/binary/binary.cuh"
namespace mlx::core {
BINARY_GPU(Maximum)
} // namespace mlx::core

7
mlx/backend/cuda/binary/minimum.cu
View File

@@ -1,7 +0,0 @@
// Copyright © 2025 Apple Inc.
#include "mlx/backend/cuda/binary/binary.cuh"
namespace mlx::core {
BINARY_GPU(Minimum)
} // namespace mlx::core

7
mlx/backend/cuda/binary/multiply.cu
View File

@@ -1,7 +0,0 @@
// Copyright © 2025 Apple Inc.
#include "mlx/backend/cuda/binary/binary.cuh"
namespace mlx::core {
BINARY_GPU(Multiply)
} // namespace mlx::core

7
mlx/backend/cuda/binary/not_equal.cu
View File

@@ -1,7 +0,0 @@
// Copyright © 2025 Apple Inc.
#include "mlx/backend/cuda/binary/binary.cuh"
namespace mlx::core {
BINARY_GPU(NotEqual)
} // namespace mlx::core

7
mlx/backend/cuda/binary/power.cu
View File

@@ -1,7 +0,0 @@
// Copyright © 2025 Apple Inc.
#include "mlx/backend/cuda/binary/binary.cuh"
namespace mlx::core {
BINARY_GPU(Power)
} // namespace mlx::core

7
mlx/backend/cuda/binary/remainder.cu
View File

@@ -1,7 +0,0 @@
// Copyright © 2025 Apple Inc.
#include "mlx/backend/cuda/binary/binary.cuh"
namespace mlx::core {
BINARY_GPU(Remainder)
} // namespace mlx::core

7
mlx/backend/cuda/binary/subtract.cu
View File

@@ -1,7 +0,0 @@
// Copyright © 2025 Apple Inc.
#include "mlx/backend/cuda/binary/binary.cuh"
namespace mlx::core {
BINARY_GPU(Subtract)
} // namespace mlx::core

164
mlx/backend/cuda/binary_two.cu
View File

@@ -3,6 +3,7 @@
#include "mlx/backend/common/binary.h"
#include "mlx/backend/cuda/device.h"
#include "mlx/backend/cuda/device/binary_ops.cuh"
#include "mlx/backend/cuda/device/cucomplex_math.cuh"
#include "mlx/backend/cuda/kernel_utils.cuh"
#include "mlx/dtype_utils.h"
#include "mlx/primitives.h"
@@ -33,8 +34,8 @@ binary_two_ss(const In* a, const In* b, Out* out_a, Out* out_b, IdxT size) {
#pragma unroll
for (int i = 0; i < N_READS; ++i) {
auto out = Op{}(a[0], b[0]);
out_a_vec[i] = out[0];
out_b_vec[i] = out[1];
out_a_vec.val[i] = out[0];
out_b_vec.val[i] = out[1];
}
store_vector<N_READS>(out_a, index, out_a_vec);
@@ -60,9 +61,9 @@ binary_two_sv(const In* a, const In* b, Out* out_a, Out* out_b, IdxT size) {
AlignedVector<Out, N_READS> out_b_vec;
#pragma unroll
for (int i = 0; i < N_READS; ++i) {
auto out = Op{}(a[0], b_vec[i]);
out_a_vec[i] = out[0];
out_b_vec[i] = out[1];
auto out = Op{}(a[0], b_vec.val[i]);
out_a_vec.val[i] = out[0];
out_b_vec.val[i] = out[1];
}
store_vector<N_READS>(out_a, index, out_a_vec);
@@ -88,9 +89,9 @@ binary_two_vs(const In* a, const In* b, Out* out_a, Out* out_b, IdxT size) {
AlignedVector<Out, N_READS> out_b_vec;
#pragma unroll
for (int i = 0; i < N_READS; ++i) {
auto out = Op{}(a_vec[i], b[0]);
out_a_vec[i] = out[0];
out_b_vec[i] = out[1];
auto out = Op{}(a_vec.val[i], b[0]);
out_a_vec.val[i] = out[0];
out_b_vec.val[i] = out[1];
}
store_vector<N_READS>(out_a, index, out_a_vec);
@@ -117,9 +118,9 @@ binary_two_vv(const In* a, const In* b, Out* out_a, Out* out_b, IdxT size) {
AlignedVector<Out, N_READS> out_b_vec;
#pragma unroll
for (int i = 0; i < N_READS; ++i) {
auto out = Op{}(a_vec[i], b_vec[i]);
out_a_vec[i] = out[0];
out_b_vec[i] = out[1];
auto out = Op{}(a_vec.val[i], b_vec.val[i]);
out_a_vec.val[i] = out[0];
out_b_vec.val[i] = out[1];
}
store_vector<N_READS>(out_a, index, out_a_vec);
@@ -127,99 +128,45 @@ binary_two_vv(const In* a, const In* b, Out* out_a, Out* out_b, IdxT size) {
}
}
template <
typename Op,
typename In,
typename Out,
typename IdxT,
int NDIM,
int N_READS>
template <typename Op, typename In, typename Out, typename IdxT, int NDIM>
__global__ void binary_two_g_nd(
const In* a,
const In* b,
Out* out_a,
Out* out_b,
IdxT size_rest,
IdxT size,
const __grid_constant__ cuda::std::array<int32_t, NDIM> shape,
const __grid_constant__ cuda::std::array<int64_t, NDIM> a_strides,
const __grid_constant__ cuda::std::array<int64_t, NDIM> b_strides) {
auto block = cg::this_thread_block();
auto grid = cg::this_grid();
IdxT index_rest =
grid.block_index().y * block.dim_threads().y + block.thread_index().y;
if (index_rest >= size_rest) {
return;
}
auto shape_x = shape[NDIM - 1];
auto a_stride_x = a_strides[NDIM - 1];
auto b_stride_x = b_strides[NDIM - 1];
IdxT index_x =
grid.block_index().x * block.dim_threads().x + block.thread_index().x;
IdxT index = cg::this_grid().thread_rank();
if (index < size) {
auto [a_idx, b_idx] = elem_to_loc_nd<NDIM>(
index_rest * shape_x, shape.data(), a_strides.data(), b_strides.data());
auto a_vec =
load_vector<N_READS>(a + a_idx, index_x, shape_x, a_stride_x, In(0));
auto b_vec =
load_vector<N_READS>(b + b_idx, index_x, shape_x, b_stride_x, In(0));
AlignedVector<Out, N_READS> out_vec_a;
AlignedVector<Out, N_READS> out_vec_b;
#pragma unroll
for (int i = 0; i < N_READS; ++i) {
auto out = Op{}(a_vec[i], b_vec[i]);
out_vec_a[i] = out[0];
out_vec_b[i] = out[1];
index, shape.data(), a_strides.data(), b_strides.data());
auto out = Op{}(a[a_idx], b[b_idx]);
out_a[index] = out[0];
out_b[index] = out[1];
}
store_vector(out_a + shape_x * index_rest, index_x, out_vec_a, shape_x);
store_vector(out_b + shape_x * index_rest, index_x, out_vec_b, shape_x);
}
template <typename Op, typename In, typename Out, typename IdxT, int N_READS>
template <typename Op, typename In, typename Out, typename IdxT>
__global__ void binary_two_g(
const In* a,
const In* b,
Out* out_a,
Out* out_b,
IdxT size_rest,
IdxT size,
const __grid_constant__ Shape shape,
const __grid_constant__ Strides a_strides,
const __grid_constant__ Strides b_strides,
int ndim) {
auto block = cg::this_thread_block();
auto grid = cg::this_grid();
IdxT index_rest =
grid.block_index().y * block.dim_threads().y + block.thread_index().y;
if (index_rest >= size_rest) {
return;
IdxT index = cg::this_grid().thread_rank();
if (index < size) {
auto [a_idx, b_idx] = elem_to_loc_4d(
index, shape.data(), a_strides.data(), b_strides.data(), ndim);
auto out = Op{}(a[a_idx], b[b_idx]);
out_a[index] = out[0];
out_b[index] = out[1];
}
auto shape_x = shape[ndim - 1];
auto a_stride_x = a_strides[ndim - 1];
auto b_stride_x = b_strides[ndim - 1];
IdxT index_x =
grid.block_index().x * block.dim_threads().x + block.thread_index().x;
auto [a_idx, b_idx] = elem_to_loc(
index_rest * shape_x,
shape.data(),
a_strides.data(),
b_strides.data(),
ndim);
auto a_vec =
load_vector<N_READS>(a + a_idx, index_x, shape_x, a_stride_x, In(0));
auto b_vec =
load_vector<N_READS>(b + b_idx, index_x, shape_x, b_stride_x, In(0));
AlignedVector<Out, N_READS> out_vec_a;
AlignedVector<Out, N_READS> out_vec_b;
#pragma unroll
for (int i = 0; i < N_READS; ++i) {
auto out = Op{}(a_vec[i], b_vec[i]);
out_vec_a[i] = out[0];
out_vec_b[i] = out[1];
}
store_vector(out_a + shape_x * index_rest, index_x, out_vec_a, shape_x);
store_vector(out_b + shape_x * index_rest, index_x, out_vec_b, shape_x);
}
template <typename Op, typename In, typename Out>
@@ -237,7 +184,7 @@ template <typename Op>
void binary_two_op_gpu_inplace(
const std::vector<array>& inputs,
std::vector<array>& outputs,
const char* op,
std::string_view op,
const Stream& s) {
assert(inputs.size() > 1);
const auto& a = inputs[0];
@@ -279,17 +226,6 @@ void binary_two_op_gpu_inplace(
auto& a_strides = strides[0];
auto& b_strides = strides[1];
int ndim = shape.size();
int work_per_thread = 1;
auto dim0 = ndim > 0 ? shape.back() : 1;
auto rest = out_a.size() / dim0;
if (dim0 >= 4) {
work_per_thread = 4;
}
dim0 = (dim0 + work_per_thread - 1) / work_per_thread;
auto block_dims = get_block_dims(dim0, rest, 1);
uint32_t num_blocks_x = cuda::ceil_div(dim0, block_dims.x);
uint32_t num_blocks_y = cuda::ceil_div(rest, block_dims.y);
if (ndim <= 3) {
dispatch_1_2_3(ndim, [&](auto dims_constant) {
auto kernel = cu::binary_two_g_nd<
@@ -297,46 +233,35 @@ void binary_two_op_gpu_inplace(
InType,
OutType,
IdxT,
dims_constant(),
1>;
if (work_per_thread == 4) {
kernel = cu::binary_two_g_nd<
Op,
InType,
OutType,
IdxT,
dims_constant(),
4>;
}
dims_constant()>;
auto [num_blocks, block_dims] =
get_launch_args(kernel, out_a, large());
encoder.add_kernel_node(
kernel,
{num_blocks_x, num_blocks_y},
num_blocks,
block_dims,
0,
a.data<InType>(),
b.data<InType>(),
out_a.data<OutType>(),
out_b.data<OutType>(),
rest,
out_a.size(),
const_param<dims_constant()>(shape),
const_param<dims_constant()>(a_strides),
const_param<dims_constant()>(b_strides));
});
} else {
auto kernel = cu::binary_two_g<Op, InType, OutType, IdxT, 1>;
if (work_per_thread == 4) {
kernel = cu::binary_two_g<Op, InType, OutType, IdxT, 4>;
}
auto kernel = cu::binary_two_g<Op, InType, OutType, IdxT>;
auto [num_blocks, block_dims] =
get_launch_args(kernel, out_a, large());
encoder.add_kernel_node(
kernel,
{num_blocks_x, num_blocks_y},
num_blocks,
block_dims,
0,
a.data<InType>(),
b.data<InType>(),
out_a.data<OutType>(),
out_b.data<OutType>(),
rest,
out_a.size(),
const_param(shape),
const_param(a_strides),
const_param(b_strides),
@@ -346,7 +271,8 @@ void binary_two_op_gpu_inplace(
} else {
dispatch_bool(out_a.data_size() > UINT32_MAX, [&](auto large) {
using IdxT = std::conditional_t<large(), int64_t, uint32_t>;
constexpr int N_READS = 16 / sizeof(InType);
// TODO: Choose optimized value based on type size.
constexpr int N_READS = 4;
auto kernel = cu::binary_two_ss<Op, InType, OutType, IdxT, N_READS>;
if (bopt == BinaryOpType::ScalarVector) {
kernel = cu::binary_two_sv<Op, InType, OutType, IdxT, N_READS>;
@@ -356,6 +282,7 @@ void binary_two_op_gpu_inplace(
kernel = cu::binary_two_vv<Op, InType, OutType, IdxT, N_READS>;
}
auto [num_blocks, block_dims] = get_launch_args(
kernel,
out_a.data_size(),
out_a.shape(),
out_a.strides(),
@@ -365,7 +292,6 @@ void binary_two_op_gpu_inplace(
kernel,
num_blocks,
block_dims,
0,
a.data<InType>(),
b.data<InType>(),
out_a.data<OutType>(),
@@ -388,7 +314,7 @@ template <typename Op>
void binary_two_op_gpu(
const std::vector<array>& inputs,
std::vector<array>& outputs,
const char* op,
std::string_view op,
const Stream& s) {
auto& a = inputs[0];
auto& b = inputs[1];
@@ -403,7 +329,7 @@ void DivMod::eval_gpu(
std::vector<array>& outputs) {
nvtx3::scoped_range r("DivMod::eval_gpu");
auto& s = outputs[0].primitive().stream();
binary_two_op_gpu<cu::DivMod>(inputs, outputs, name(), s);
binary_two_op_gpu<cu::DivMod>(inputs, outputs, get_primitive_string(this), s);
}
} // namespace mlx::core

160
mlx/backend/cuda/compiled.cpp
View File

@@ -53,10 +53,9 @@ struct FusedKernelBuilder {
// Build function signature.
if (contiguous) {
os += "template <typename IdxT = uint32_t, int work_per_thread = 1>\n";
os += "template <typename IdxT = uint32_t>\n";
} else {
os +=
"template <int NDIM, typename IdxT = uint32_t, int work_per_thread = 1>\n";
os += "template <int NDIM, typename IdxT = uint32_t>\n";
}
os += fmt::format("__global__ void {}(\n", kernel_name + name);
for (size_t i = 0; i < params.size(); ++i) {
@@ -68,77 +67,12 @@ struct FusedKernelBuilder {
}
os += ") {\n";
// Index. For non contiguous kernels we create a separate index
// variable per variable otherwise everyone uses `index`.
// Index.
os +=
" IdxT index = cg::this_grid().thread_rank() * work_per_thread;\n"
" IdxT index = cg::this_grid().thread_rank();\n"
" if (index >= size) {\n"
" return;\n"
" }\n";
if (!contiguous) {
for (size_t i = 0; i < inputs.size(); ++i) {
const auto& x = inputs[i];
const std::string& xname = namer.get_name(x);
if (is_scalar(x) || is_constant(i)) {
continue;
}
os += " IdxT " + xname + "_idx = 0;\n";
}
os += " {\n";
os += " IdxT loc = index;\n";
os +=
" #pragma unroll\n"
" for (int i = NDIM - 1; i >= 0; i--) {\n";
for (size_t i = 0; i < inputs.size(); ++i) {
const auto& x = inputs[i];
const std::string& xname = namer.get_name(x);
if (is_scalar(x) || is_constant(i)) {
continue;
}
os += " " + xname + "_idx += (loc \% shape[i]) * IdxT(" + xname +
"_strides[i]);\n";
}
os +=
" loc /= shape[i];\n"
" }\n"
" }\n";
}
// Vectorized read loop
if (contiguous) {
for (size_t i = 0; i < inputs.size(); ++i) {
const auto& x = inputs[i];
if (is_scalar(x) || is_constant(i)) {
continue;
}
const std::string& xname = namer.get_name(x);
std::string type = dtype_to_cuda_type(x.dtype());
os += fmt::format(
" auto vec_{0} = load_vector<work_per_thread, {1}>({0} + index, 0, size - index, 0);\n",
xname,
type);
}
}
// Create some space for the outputs
for (const auto& x : outputs) {
const std::string& xname = namer.get_name(x);
std::string type = dtype_to_cuda_type(x.dtype());
os += fmt::format(
" AlignedVector<{}, work_per_thread> vec_{};\n", type, xname);
}
// Work loop
if (!contiguous) {
os +=
"\n"
" for (int i = 0; i < work_per_thread && index < size; i++) {\n";
} else {
os +=
"\n"
" #pragma unroll\n"
" for (int i = 0; i < work_per_thread; i++) {\n";
}
// Read inputs.
for (size_t i = 0; i < inputs.size(); ++i) {
@@ -153,9 +87,12 @@ struct FusedKernelBuilder {
} else if (is_scalar(x)) {
value = fmt::format("{}[0]", xname);
} else if (contiguous) {
value = fmt::format("vec_{}[i]", xname);
value = fmt::format("{}[index]", xname);
} else {
value = fmt::format("{}[{}_idx]", xname, xname);
std::string index = fmt::format(
"elem_to_loc_nd<NDIM>(index, shape.data(), {}_strides.data())",
xname);
value = fmt::format("{}[{}]", xname, index);
}
os += fmt::format(" {} tmp_{} = {};\n", type, xname, value);
}
@@ -169,7 +106,9 @@ struct FusedKernelBuilder {
value = fmt::format(
"static_cast<{}>(tmp_{})", type, namer.get_name(x.inputs()[0]));
} else {
value = x.primitive().name();
std::ostringstream ss;
x.primitive().print(ss);
value = ss.str();
value += "{}(";
for (size_t i = 0; i < x.inputs().size() - 1; ++i) {
value += fmt::format("tmp_{}, ", namer.get_name(x.inputs()[i]));
@@ -181,28 +120,7 @@ struct FusedKernelBuilder {
// Write output.
for (const auto& x : outputs) {
os += fmt::format(" vec_{0}[i] = tmp_{0};\n", namer.get_name(x));
}
// End of work loop
if (!contiguous) {
os += "\n";
for (size_t i = 0; i < inputs.size(); ++i) {
const auto& x = inputs[i];
const std::string& xname = namer.get_name(x);
if (is_scalar(x) || is_constant(i)) {
continue;
}
os += fmt::format(" {0}_idx += {0}_strides[NDIM - 1];\n", xname);
}
}
os += " }\n";
// Store the output to global memory
for (const auto& x : outputs) {
os += fmt::format(
" store_vector({0} + index, 0, vec_{0}, size - index);\n",
namer.get_name(x));
os += fmt::format(" {0}[index] = tmp_{0};\n", namer.get_name(x));
}
os += "}\n";
@@ -228,15 +146,6 @@ void Compiled::eval_gpu(
nvtx3::scoped_range r("Compiled::eval_gpu");
auto& s = stream();
// Determine the work per thread for the vectorized reads/writes. We take it
// as 16 over the max itemsize for the outputs. Another heuristic could be
// over the max itemsize of all arrays.
int max_size = 1;
for (const auto& x : outputs) {
max_size = (max_size > x.itemsize()) ? max_size : x.itemsize();
}
int work_per_thread = 16 / max_size;
cu::JitModule& mod = cu::get_jit_module(s.device, lib_name(), [&]() {
// Build source code.
cu::FusedKernelBuilder builder{
@@ -249,26 +158,17 @@ void Compiled::eval_gpu(
builder.build("_strided", false);
builder.os += "\n} // namespace mlx::core::cu\n";
// Build kernel names.
std::vector<std::string> kernel_names;
kernel_names.push_back(fmt::format(
"mlx::core::cu::{}_contiguous<uint32_t, {}>",
lib_name(),
work_per_thread));
kernel_names.push_back(fmt::format(
"mlx::core::cu::{}_contiguous<int64_t, {}>",
lib_name(),
work_per_thread));
for (auto wpt : std::array<int, 2>{1, work_per_thread}) {
std::vector<std::string> kernel_names = {
fmt::format("mlx::core::cu::{}_contiguous<uint32_t>", lib_name()),
fmt::format("mlx::core::cu::{}_contiguous<int64_t>", lib_name()),
};
for (int i = 1; i <= MAX_NDIM; ++i) {
kernel_names.push_back(fmt::format(
"mlx::core::cu::{}_strided<{}, uint32_t, {}>", lib_name(), i, wpt));
kernel_names.push_back(fmt::format(
"mlx::core::cu::{}_strided<{}, int64_t, {}>", lib_name(), i, wpt));
"mlx::core::cu::{}_strided<{}, uint32_t>", lib_name(), i));
kernel_names.push_back(
fmt::format("mlx::core::cu::{}_strided<{}, int64_t>", lib_name(), i));
}
}
return std::make_tuple(
false, std::move(builder.os), std::move(kernel_names));
return std::make_pair(std::move(builder.os), std::move(kernel_names));
});
// Collapse contiguous dims to route to a faster kernel if possible. Also
@@ -309,20 +209,13 @@ void Compiled::eval_gpu(
args.append<uint32_t>(outputs[0].data_size());
}
// Choose work per thread
if (!contiguous && shape.back() % work_per_thread != 0) {
work_per_thread = 1;
}
// Launch kernel.
const char* index_type = large ? "int64_t" : "uint32_t";
std::string kernel_name = fmt::format("mlx::core::cu::{}", lib_name());
if (contiguous) {
kernel_name +=
fmt::format("_contiguous<{}, {}>", index_type, work_per_thread);
kernel_name += fmt::format("_contiguous<{}>", index_type);
} else {
kernel_name += fmt::format(
"_strided<{}, {}, {}>", shape.size(), index_type, work_per_thread);
kernel_name += fmt::format("_strided<{}, {}>", shape.size(), index_type);
}
auto& encoder = cu::get_command_encoder(s);
for (const auto& in : inputs) {
@@ -332,10 +225,9 @@ void Compiled::eval_gpu(
encoder.set_output_array(out);
}
auto [kernel, max_block_dims] = mod.get_kernel_and_dims(kernel_name);
auto [num_blocks, block_dims] =
get_launch_args(outputs[0], large, work_per_thread, max_block_dims);
encoder.add_kernel_node(kernel, num_blocks, block_dims, 0, args.args());
auto kernel = mod.get_kernel(kernel_name);
auto [num_blocks, block_dims] = get_launch_args(kernel, outputs[0], large);
encoder.add_kernel_node(kernel, num_blocks, block_dims, args.args());
}
} // namespace mlx::core

418
mlx/backend/cuda/conv.cpp
View File

@@ -1,418 +0,0 @@
// Copyright © 2025 Apple Inc.
#include "mlx/backend/cuda/conv/conv.h"
#include "mlx/backend/cuda/cudnn_utils.h"
#include "mlx/backend/cuda/device.h"
#include "mlx/backend/cuda/lru_cache.h"
#include "mlx/backend/gpu/copy.h"
#include "mlx/primitives.h"
#include <nvtx3/nvtx3.hpp>
#include <cassert>
namespace mlx::core {
namespace {
// Alias for better readability.
#define CONV_FORWARD CUDNN_BACKEND_OPERATION_CONVOLUTION_FORWARD_DESCRIPTOR
#define CONV_BACKWARD_INPUT \
CUDNN_BACKEND_OPERATION_CONVOLUTION_BACKWARD_DATA_DESCRIPTOR
#define CONV_BACKWARD_WEIGHT \
CUDNN_BACKEND_OPERATION_CONVOLUTION_BACKWARD_FILTER_DESCRIPTOR
// Custom placeholder representing fallback kernel.
#define CONV_FALLBACK static_cast<cudnnBackendDescriptorType_t>(-1)
struct ConvCacheKey {
int device_id;
cudnnDataType_t cudnn_dtype;
std::array<int, MAX_NDIM> input_shape;
std::array<int, MAX_NDIM> weight_shape;
std::array<int, MAX_NDIM> stride;
std::array<int, MAX_NDIM> padding_lo;
std::array<int, MAX_NDIM> padding_hi;
std::array<int, MAX_NDIM> dilation;
int groups;
bool flip;
uint8_t input_alignment;
uint8_t weight_alignment;
uint8_t output_alignment;
};
auto& conv_cache() {
static LRUBytesKeyCache<
ConvCacheKey,
std::pair<
cudnnBackendDescriptorType_t,
std::optional<cudnn_frontend::ExecutionPlan>>>
cache("MLX_CUDA_CONV_CACHE_SIZE", /* default_capacity */ 128);
return cache;
}
auto get_conv_op_settings(
cudnnBackendDescriptorType_t backend_type,
array& x,
array& w,
array& y,
const std::vector<int>& kernel_strides,
const std::vector<int>& padding_lo_,
const std::vector<int>& padding_hi_,
const std::vector<int>& kernel_dilation,
const std::vector<int>& input_dilation) {
auto padding_lo = convert_vector<int64_t>(padding_lo_);
auto padding_hi = convert_vector<int64_t>(padding_hi_);
if (backend_type == CONV_BACKWARD_INPUT) {
for (int i = 0; i < padding_lo.size(); ++i) {
int wt_size = 1 + kernel_dilation[i] * (w.shape(1 + i) - 1);
padding_lo[i] = wt_size - padding_lo[i] - 1;
int in_size = 1 + kernel_strides[i] * (x.shape(1 + i) - 1);
int out_size = 1 + input_dilation[i] * (y.shape(1 + i) - 1);
padding_hi[i] = out_size - in_size + padding_hi[i];
}
return std::make_tuple(
convert_vector<int64_t>(input_dilation),
std::move(padding_lo),
std::move(padding_hi),
convert_vector<int64_t>(kernel_dilation));
} else if (backend_type == CONV_BACKWARD_WEIGHT) {
padding_hi = padding_lo;
return std::make_tuple(
convert_vector<int64_t>(kernel_dilation),
std::move(padding_lo),
std::move(padding_hi),
convert_vector<int64_t>(kernel_strides));
} else {
return std::make_tuple(
convert_vector<int64_t>(kernel_strides),
std::move(padding_lo),
std::move(padding_hi),
convert_vector<int64_t>(kernel_dilation));
}
}
std::optional<cudnn_frontend::OperationGraph> build_conv_op_graph(
cu::CommandEncoder& encoder,
cudnnBackendDescriptorType_t backend_type,
Dtype dtype,
array& x,
array& w,
array& y,
const SmallVector<int64_t>& stride,
const SmallVector<int64_t>& padding_lo,
const SmallVector<int64_t>& padding_hi,
const SmallVector<int64_t>& dilation) {
try {
auto compute_dtype = (dtype == float16 || dtype == bfloat16)
? CUDNN_DATA_FLOAT
: dtype_to_cudnn_type(dtype);
auto conv_desc = cudnn_frontend::ConvDescBuilder()
.setDataType(compute_dtype)
.setMathMode(CUDNN_CROSS_CORRELATION)
.setNDims(stride.size())
.setStrides(stride.size(), stride.data())
.setPrePadding(padding_lo.size(), padding_lo.data())
.setPostPadding(padding_hi.size(), padding_hi.data())
.setDilation(dilation.size(), dilation.data())
.build();
auto op = cudnn_frontend::OperationBuilder(backend_type)
.setxDesc(build_cudnn_tensor_nchw('x', x))
.setwDesc(build_cudnn_tensor_nchw('w', w))
.setyDesc(build_cudnn_tensor_nchw('y', y))
.setcDesc(conv_desc)
.build();
std::array<cudnn_frontend::Operation const*, 1> ops = {&op};
return cudnn_frontend::OperationGraphBuilder()
.setHandle(encoder.device().cudnn_handle())
.setOperationGraph(ops.size(), ops.data())
.build();
} catch (cudnn_frontend::cudnnException& error) {
if (error.getCudnnStatus() != CUDNN_STATUS_BAD_PARAM) {
throw;
}
return std::nullopt;
}
}
// Transpose from (C_out, H, W, C_in / groups) to (C_in, H, W, C_out / groups).
array group_transpose(
const array& x,
int groups,
int group_dim,
int axis1,
int axis2,
Stream s) {
if (groups == 1) {
return swapaxes_in_eval(x, axis1, axis2);
}
int ndim = x.ndim();
if (group_dim < 0) {
group_dim += ndim;
}
if (axis1 < 0) {
axis1 += ndim;
}
if (axis2 < 0) {
axis2 += ndim;
}
if (group_dim <= axis1) {
axis1 += 1;
}
if (group_dim <= axis2) {
axis2 += 1;
}
auto shape = x.shape();
shape.insert(shape.begin() + group_dim, groups);
shape[group_dim + 1] = shape[group_dim + 1] / groups;
array x_trans = reshape_in_eval(x, std::move(shape), s);
x_trans = swapaxes_in_eval(x_trans, axis1, axis2);
x_trans = flatten_in_eval(x_trans, group_dim, group_dim + 1, s);
return x_trans;
}
// Do necessary transposes and copies to prepare the inputs and outputs for
// building the cuDNN conv op. It is safe to be called multiple times in one
// eval_gpu, with cost of possible redundant copies.
std::tuple<array, array, array> prepare_args(
cu::CommandEncoder& encoder,
cudnnBackendDescriptorType_t backend_type,
array in,
array wt,
array out,
int groups,
Stream s) {
// Transpose the args depending on the backend type.
// TODO: Handle groups.
if (backend_type == CONV_BACKWARD_INPUT) {
wt = group_transpose(wt, groups, 0, 0, -1, s);
} else if (backend_type == CONV_BACKWARD_WEIGHT) {
in = group_transpose(in, groups, -1, 0, -1, s);
wt = swapaxes_in_eval(wt, 0, -1);
// Create a contiguous array that shares the data with |out|, but with dim
// C_in and C_out swapped.
Shape shape(out.shape());
std::swap(shape.front(), shape.back());
Strides strides(shape.size(), 1);
for (int i = shape.size() - 2; i >= 0; --i) {
strides[i] = shape[i + 1] * strides[i + 1];
}
array intermediate(std::move(shape), out.dtype(), nullptr, {});
intermediate.copy_shared_buffer(
out, std::move(strides), {true, true, false}, out.data_size());
out = intermediate;
}
// cuDNN requires contiguous input.
if (!in.flags().row_contiguous) {
in = contiguous_copy_gpu(in, s);
encoder.add_temporary(in);
}
if (!wt.flags().row_contiguous) {
wt = contiguous_copy_gpu(wt, s);
encoder.add_temporary(wt);
}
return {std::move(in), std::move(wt), std::move(out)};
}
// Get the x/w/y args from the in/wt/out args depending on backend type.
inline std::tuple<array&, array&, array&> dispatch_args(
cudnnBackendDescriptorType_t backend_type,
array& in,
array& wt,
array& out) {
switch (backend_type) {
case CONV_BACKWARD_INPUT:
return {out, wt, in};
case CONV_BACKWARD_WEIGHT:
return {in, out, wt};
default:
return {in, wt, out};
}
}
// Register inputs and outputs before actually running conv op. Can only be
// called once per eval_gpu.
void register_args(
cu::CommandEncoder& encoder,
cudnnBackendDescriptorType_t backend_type,
array& in,
array& wt,
array& intermediate_out,
array& final_out) {
encoder.set_input_array(in);
encoder.set_input_array(wt);
encoder.set_output_array(final_out);
if (backend_type == CONV_BACKWARD_WEIGHT) {
// Turn |out| into a strided array, which will have C_in and C_out swapped
// in vjp and the final |grad_weight| will then be contiguous.
Strides strides = intermediate_out.strides();
std::swap(strides.front(), strides.back());
final_out.copy_shared_buffer(
intermediate_out,
std::move(strides),
{false, false, false},
intermediate_out.data_size());
}
}
} // namespace
void Convolution::eval_gpu(const std::vector<array>& inputs, array& out_) {
nvtx3::scoped_range r("Convolution::eval_gpu");
if (out_.size() == 0) {
return;
}
assert(inputs.size() == 2);
array in = inputs[0];
array wt = inputs[1];
array out = out_;
out.set_data(allocator::malloc(out.nbytes()));
Dtype dtype = out.dtype();
auto& s = stream();
auto& encoder = cu::get_command_encoder(s);
// Search cache.
ConvCacheKey cache_key{
encoder.device().cuda_device(),
dtype_to_cudnn_type(dtype),
vector_key(in.shape()),
vector_key(wt.shape()),
vector_key(kernel_strides_),
vector_key(padding_lo_),
vector_key(padding_hi_),
vector_key(kernel_dilation_),
groups_,
flip_,
get_alignment(in),
get_alignment(wt),
get_alignment(out)};
if (auto it = conv_cache().find(cache_key); it != conv_cache().end()) {
auto& [backend_type, plan] = it->second;
if (plan) {
// Run cached plan.
std::tie(in, wt, out) =
prepare_args(encoder, backend_type, in, wt, out, groups_, s);
register_args(encoder, backend_type, in, wt, out, out_);
auto [x, w, y] = dispatch_args(backend_type, in, wt, out);
if (!encode_cudnn_plan(encoder, *plan, {'x', 'w', 'y'}, x, w, y)) {
throw std::runtime_error("[conv] Cached plan failed to execute.");
}
} else {
// Run fallback kernel.
gemm_conv(
encoder,
in,
wt,
out,
kernel_strides_,
padding_lo_,
kernel_dilation_,
input_dilation_,
groups_,
flip_,
s);
}
return;
}
// There is no reliable way to deduce the proper cuDNN backend for the
// convolution, so we make a best guess and then try.
SmallVector<cudnnBackendDescriptorType_t, 2> try_backends;
if (flip_) {
// When weight is flipped, we assume it is backward input convolution.
try_backends.push_back(CONV_BACKWARD_INPUT);
} else {
// Otherwise it could be backward weight convolution or forward convolution,
// mathematically there is no difference so we have to use heuristics.
// Empirically backward convolutions have large kernel dimensions, and
// usually have |in| and |wt| transposed.
if (!in.flags().row_contiguous && !wt.flags().row_contiguous &&
wt.shape(2) > out.shape(2)) {
try_backends = {CONV_BACKWARD_WEIGHT, CONV_FORWARD};
} else {
try_backends = {CONV_FORWARD, CONV_BACKWARD_WEIGHT};
}
}
// Try to build op graph.
cudnnBackendDescriptorType_t backend_type;
std::optional<cudnn_frontend::OperationGraph> op_graph;
for (auto try_backend : try_backends) {
auto [in_copy, wt_copy, out_copy] =
prepare_args(encoder, try_backend, in, wt, out, groups_, s);
auto [x, w, y] = dispatch_args(try_backend, in_copy, wt_copy, out_copy);
auto [stride, padding_lo, padding_hi, dilation] = get_conv_op_settings(
try_backend,
x,
w,
y,
kernel_strides_,
padding_lo_,
padding_hi_,
kernel_dilation_,
input_dilation_);
op_graph = build_conv_op_graph(
encoder,
try_backend,
dtype,
x,
w,
y,
stride,
padding_lo,
padding_hi,
dilation);
if (op_graph) {
backend_type = try_backend;
in = std::move(in_copy);
wt = std::move(wt_copy);
out = std::move(out_copy);
break;
}
}
if (op_graph) {
// Setup inputs and outputs.
register_args(encoder, backend_type, in, wt, out, out_);
// Find a plan for the graph and execute it.
auto plan = find_cudnn_plan_from_op_graph(
encoder.device().cudnn_handle(), backend_type, dtype, *op_graph);
if (!plan) {
throw std::runtime_error("[conv] Unable to find an execution plan.");
}
auto [x, w, y] = dispatch_args(backend_type, in, wt, out);
if (encode_cudnn_plan(encoder, *plan, {'x', 'w', 'y'}, x, w, y)) {
conv_cache().emplace(
cache_key, std::make_pair(backend_type, std::move(*plan)));
return;
}
}
// Use fallback kernel for settings not supported by cuDNN.
gemm_conv(
encoder,
in,
wt,
out,
kernel_strides_,
padding_lo_,
kernel_dilation_,
input_dilation_,
groups_,
flip_,
s);
conv_cache().emplace(cache_key, std::make_pair(CONV_FALLBACK, std::nullopt));
}
} // namespace mlx::core

126
mlx/backend/cuda/conv/conv.h
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@@ -1,126 +0,0 @@
// Copyright © 2025 Apple Inc.
#pragma once
#include "mlx/backend/cuda/device.h"
#include "mlx/backend/gpu/copy.h"
namespace mlx::core {
template <int NDIM>
struct ConvParams {
int N; // Batch size
int C; // In channels
int O; // Out channels
int strides[NDIM];
int padding[NDIM];
int kernel_dilation[NDIM];
int input_dilation[NDIM];
int groups;
bool flip;
int in_spatial_dims[NDIM];
int wt_spatial_dims[NDIM];
int out_spatial_dims[NDIM];
int64_t in_strides[NDIM + 2];
ConvParams(
const array& in,
const array& wt,
const array& out,
const std::vector<int>& strides,
const std::vector<int>& padding,
const std::vector<int>& kernel_dilation,
const std::vector<int>& input_dilation,
int groups,
bool flip)
: N(in.shape(0)),
C(in.shape(-1)),
O(wt.shape(0)),
groups(groups),
flip(flip) {
std::copy_n(strides.begin(), NDIM, this->strides);
std::copy_n(padding.begin(), NDIM, this->padding);
std::copy_n(kernel_dilation.begin(), NDIM, this->kernel_dilation);
std::copy_n(input_dilation.begin(), NDIM, this->input_dilation);
std::copy_n(in.shape().begin() + 1, NDIM, this->in_spatial_dims);
std::copy_n(wt.shape().begin() + 1, NDIM, this->wt_spatial_dims);
std::copy_n(out.shape().begin() + 1, NDIM, this->out_spatial_dims);
std::copy_n(in.strides().begin(), NDIM + 2, this->in_strides);
}
};
void gemm_grouped_conv(
cu::CommandEncoder& encoder,
const array& in,
const array& wt,
array& out,
const std::vector<int>& strides,
const std::vector<int>& padding,
const std::vector<int>& kernel_dilation,
const std::vector<int>& input_dilation,
int groups,
bool flip,
Stream s);
void gemm_conv(
cu::CommandEncoder& encoder,
const array& in,
const array& wt,
array& out,
const std::vector<int>& strides,
const std::vector<int>& padding,
const std::vector<int>& kernel_dilation,
const std::vector<int>& input_dilation,
bool flip,
Stream s);
inline void gemm_conv(
cu::CommandEncoder& encoder,
array in,
array wt,
array& out,
const std::vector<int>& strides,
const std::vector<int>& padding,
const std::vector<int>& kernel_dilation,
const std::vector<int>& input_dilation,
int groups,
bool flip,
Stream s) {
if (!in.flags().row_contiguous) {
in = contiguous_copy_gpu(in, s);
encoder.add_temporary(in);
}
if (!wt.flags().row_contiguous) {
wt = contiguous_copy_gpu(wt, s);
encoder.add_temporary(wt);
}
if (groups == 1) {
gemm_conv(
encoder,
in,
wt,
out,
strides,
padding,
kernel_dilation,
input_dilation,
flip,
s);
} else {
gemm_grouped_conv(
encoder,
in,
wt,
out,
strides,
padding,
kernel_dilation,
input_dilation,
groups,
flip,
s);
}
}
} // namespace mlx::core

217
mlx/backend/cuda/conv/gemm_conv.cu
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@@ -1,217 +0,0 @@
// Copyright © 2025 Apple Inc.
#include "mlx/backend/cuda/conv/conv.h"
#include "mlx/backend/cuda/gemms/cublas_gemm.h"
#include "mlx/backend/cuda/kernel_utils.cuh"
#include "mlx/dtype_utils.h"
#include <cooperative_groups.h>
namespace mlx::core {
namespace cu {
namespace cg = cooperative_groups;
template <typename T, int NDIM>
__global__ void naive_unfold_nd(
const T* in,
T* out,
int filter_size,
int out_pixels,
const __grid_constant__ ConvParams<NDIM> params) {
auto block = cg::this_thread_block();
auto tid = block.group_index();
auto lid = block.thread_index();
int index_batch = tid.z / out_pixels; // [0, N)
int index_out_spatial = tid.z % out_pixels; // [0, H_out * W_out)
int index_wt_spatial =
tid.x * block.dim_threads().x + lid.x; // [0, H_wt * W_wt)
if (index_wt_spatial >= filter_size / params.C) {
return;
}
in += tid.y; // [0, C)
out += tid.z * filter_size + index_wt_spatial * params.C + tid.y;
bool valid = index_batch < params.N;
// Get the coordinates in input.
int index_in[NDIM] = {};
#pragma unroll
for (int i = NDIM - 1; i >= 0; --i) {
int index_out = index_out_spatial % params.out_spatial_dims[i];
int index_wt = index_wt_spatial % params.wt_spatial_dims[i];
if (params.flip) {
index_wt = params.wt_spatial_dims[i] - index_wt - 1;
}
int index = index_out * params.strides[i] - params.padding[i] +
index_wt * params.kernel_dilation[i];
int index_max =
1 + params.input_dilation[i] * (params.in_spatial_dims[i] - 1);
valid &= (index >= 0) && (index < index_max) &&
(index % params.input_dilation[i] == 0);
index_in[i] = index / params.input_dilation[i];
index_out_spatial /= params.out_spatial_dims[i];
index_wt_spatial /= params.wt_spatial_dims[i];
}
if (valid) {
int in_offset = index_batch * params.in_strides[0];
#pragma unroll
for (int i = 0; i < NDIM; ++i) {
in_offset += index_in[i] * params.in_strides[i + 1];
}
*out = in[in_offset];
} else {
*out = T{0};
}
}
} // namespace cu
template <int NDIM>
array unfold_inputs_nd(
cu::CommandEncoder& encoder,
const array& in,
int mat_M,
int mat_K,
int mat_N,
ConvParams<NDIM>& params) {
array unfolded({mat_M, mat_K}, in.dtype(), nullptr, {});
unfolded.set_data(allocator::malloc(unfolded.nbytes()));
encoder.add_temporary(unfolded);
int filter_size = params.C;
#pragma unroll
for (int i = 0; i < NDIM; ++i) {
filter_size *= params.wt_spatial_dims[i];
}
int out_pixels = 1;
#pragma unroll
for (int i = 0; i < NDIM; ++i) {
out_pixels *= params.out_spatial_dims[i];
}
int wt_spatial_size = mat_K / params.C;
dim3 block_dims;
block_dims.x = std::min(std::max(wt_spatial_size, 32), 1024);
dim3 num_blocks;
num_blocks.x = cuda::ceil_div(wt_spatial_size, block_dims.x);
num_blocks.y = params.C;
num_blocks.z = mat_M;
encoder.set_input_array(in);
encoder.set_output_array(unfolded);
dispatch_float_types(in.dtype(), "unfold", [&](auto type_tag) {
using DataType = cuda_type_t<MLX_GET_TYPE(type_tag)>;
encoder.add_kernel_node(
cu::naive_unfold_nd<DataType, NDIM>,
num_blocks,
block_dims,
0,
in.data<DataType>(),
unfolded.data<DataType>(),
filter_size,
out_pixels,
params);
});
return unfolded;
}
template <int NDIM>
void gemm_conv_nd(
cu::CommandEncoder& encoder,
const array& in,
const array& wt,
array& out,
ConvParams<NDIM>& params,
Stream s) {
// Get gemm shapes.
int mat_M = out.size() / params.O; // N * H_out * W_out
int mat_K = wt.size() / params.O; // C * H_wt * W_wt
int mat_N = params.O; // O
// Unfold input to (N * H_out * W_out, C * H_wt * W_wt) for gemm.
array in_unfolded =
unfold_inputs_nd<NDIM>(encoder, in, mat_M, mat_K, mat_N, params);
// Reshape weight to (C * H_wt * W_wt, O) for gemm.
array wt_reshaped({mat_K, mat_N}, wt.dtype(), nullptr, {});
wt_reshaped.copy_shared_buffer(
wt,
{1, mat_K},
{false, false, /* col_contiguous */ true},
wt.data_size());
// Single batch.
Shape batch_shape{1};
Strides a_batch_strides{0};
Strides b_batch_strides{0};
// Run matmul.
CublasGemm gemm(
encoder.device(),
in.dtype(),
false, // a_transposed
mat_M, // a_rows
mat_K, // a_cols
mat_K, // lda
true, // b_transposed
mat_K, // b_rows
mat_N, // b_cols
mat_K, // ldb
batch_shape.back(),
a_batch_strides.back(),
b_batch_strides.back());
gemm.run(
encoder,
out,
in_unfolded,
wt_reshaped,
batch_shape,
a_batch_strides,
b_batch_strides);
}
void gemm_conv(
cu::CommandEncoder& encoder,
const array& in,
const array& wt,
array& out,
const std::vector<int>& strides,
const std::vector<int>& padding,
const std::vector<int>& kernel_dilation,
const std::vector<int>& input_dilation,
bool flip,
Stream s) {
int conv_ndim = in.ndim() - 2;
if (conv_ndim < 1 || conv_ndim > 3) {
throw std::runtime_error(
fmt::format("[conv] Unsupported gemm_conv for {}D conv.", conv_ndim));
}
dispatch_1_2_3(conv_ndim, [&](auto ndim_constant) {
ConvParams<ndim_constant()> params(
in,
wt,
out,
strides,
padding,
kernel_dilation,
input_dilation,
1, // groups
flip);
gemm_conv_nd<ndim_constant()>(encoder, in, wt, out, params, s);
});
}
} // namespace mlx::core

231
mlx/backend/cuda/conv/gemm_grouped_conv.cu
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@@ -1,231 +0,0 @@
// Copyright © 2025 Apple Inc.
#include "mlx/backend/cuda/conv/conv.h"
#include "mlx/backend/cuda/gemms/cublas_gemm.h"
#include "mlx/backend/cuda/kernel_utils.cuh"
#include "mlx/dtype_utils.h"
#include <cooperative_groups.h>
namespace mlx::core {
namespace cu {
namespace cg = cooperative_groups;
template <typename T, int NDIM>
__global__ void naive_grouped_unfold_transpose_nd(
const T* in,
T* out,
int filter_size,
int out_pixels,
const __grid_constant__ ConvParams<NDIM> params) {
auto block = cg::this_thread_block();
auto tid = block.group_index();
auto lid = block.thread_index();
int index_batch = tid.z / out_pixels; // [0, N)
int index_out_spatial = tid.z % out_pixels; // [0, H_out * W_out)
int index_wt_spatial =
tid.x * block.dim_threads().x + lid.x; // [0, H_wt * W_wt)
if (index_wt_spatial >= filter_size / params.C) {
return;
}
in += tid.y; // [0, C)
out += tid.z * filter_size + tid.y * (filter_size / params.C);
bool valid = index_batch < params.N;
// Get the coordinates in input.
int index_in[NDIM] = {};
int wt_stride = 1;
#pragma unroll
for (int i = NDIM - 1; i >= 0; --i) {
int index_out = index_out_spatial % params.out_spatial_dims[i];
int index_wt = index_wt_spatial % params.wt_spatial_dims[i];
out += index_wt * wt_stride;
if (params.flip) {
index_wt = params.wt_spatial_dims[i] - index_wt - 1;
}
int index = index_out * params.strides[i] - params.padding[i] +
index_wt * params.kernel_dilation[i];
int index_max =
1 + params.input_dilation[i] * (params.in_spatial_dims[i] - 1);
valid &= (index >= 0) && (index < index_max) &&
(index % params.input_dilation[i] == 0);
index_in[i] = index / params.input_dilation[i];
index_out_spatial /= params.out_spatial_dims[i];
index_wt_spatial /= params.wt_spatial_dims[i];
wt_stride *= params.wt_spatial_dims[i];
}
if (valid) {
int in_offset = index_batch * params.in_strides[0];
#pragma unroll
for (int i = 0; i < NDIM; ++i) {
in_offset += index_in[i] * params.in_strides[i + 1];
}
*out = in[in_offset];
} else {
*out = T{0};
}
}
} // namespace cu
template <int NDIM>
array grouped_unfold_transpose_inputs_nd(
cu::CommandEncoder& encoder,
const array& in,
int mat_M,
int mat_K,
int mat_N,
ConvParams<NDIM>& params) {
array unfolded({mat_M, mat_K * params.groups}, in.dtype(), nullptr, {});
unfolded.set_data(allocator::malloc(unfolded.nbytes()));
encoder.add_temporary(unfolded);
int filter_size = params.C;
#pragma unroll
for (int i = 0; i < NDIM; ++i) {
filter_size *= params.wt_spatial_dims[i];
}
int out_pixels = 1;
#pragma unroll
for (int i = 0; i < NDIM; ++i) {
out_pixels *= params.out_spatial_dims[i];
}
int wt_spatial_size = (mat_K * params.groups) / params.C;
dim3 block_dims;
block_dims.x = std::min(std::max(wt_spatial_size, 32), 1024);
dim3 num_blocks;
num_blocks.x = cuda::ceil_div(wt_spatial_size, block_dims.x);
num_blocks.y = params.C;
num_blocks.z = mat_M;
encoder.set_input_array(in);
encoder.set_output_array(unfolded);
dispatch_float_types(in.dtype(), "unfold", [&](auto type_tag) {
using DataType = cuda_type_t<MLX_GET_TYPE(type_tag)>;
encoder.add_kernel_node(
cu::naive_grouped_unfold_transpose_nd<DataType, NDIM>,
num_blocks,
block_dims,
0,
in.data<DataType>(),
unfolded.data<DataType>(),
filter_size,
out_pixels,
params);
});
return unfolded;
}
template <int NDIM>
void gemm_grouped_conv_nd(
cu::CommandEncoder& encoder,
const array& in,
const array& wt,
array& out,
ConvParams<NDIM>& params,
Stream s) {
// Get gemm shapes.
int C_per_group = params.C / params.groups;
int O_per_group = params.O / params.groups;
int mat_M = out.size() / params.O; // N * H_out * W_out
int mat_K = wt.size() / params.O; // C_per_group * H_wt * W_wt
int mat_N = O_per_group; // O_per_group
// Unfold input to (N * H_out * W_out, C * H_wt * W_wt) for gemm.
array in_unfolded = grouped_unfold_transpose_inputs_nd<NDIM>(
encoder, in, mat_M, mat_K, mat_N, params);
// Reshape weight to (O, C_per_group, H_wt * W_wt) for gemm.
int wt_spatial_size = (wt.size() / wt.shape(0)) / wt.shape(-1);
array wt_view(
{params.O, C_per_group, wt_spatial_size}, wt.dtype(), nullptr, {});
wt_view.copy_shared_buffer(
wt, {wt.strides(0), 1, C_per_group}, wt.flags(), wt.size());
array wt_reshaped = contiguous_copy_gpu(wt_view, s);
// Batch with size of groups.
Shape batch_shape{params.groups};
Strides a_batch_strides{mat_K};
Strides b_batch_strides{mat_N * mat_K};
// Run matmul.
CublasGemm gemm(
encoder.device(),
in.dtype(),
false, // a_transposed
mat_M, // a_rows
mat_K, // a_cols
mat_K * params.groups, // lda
true, // b_transposed
mat_K, // b_rows
mat_N, // b_cols
mat_K, // ldb
batch_shape.back(),
a_batch_strides.back(),
b_batch_strides.back());
gemm.set_out(
out.dtype(),
false, // out_transposed
mat_M, // out_rows
mat_N, // out_cols
mat_N * params.groups, // out_ld
params.groups, // batch_count
mat_N); // batch_stride
gemm.run(
encoder,
out,
in_unfolded,
wt_reshaped,
batch_shape,
a_batch_strides,
b_batch_strides);
}
void gemm_grouped_conv(
cu::CommandEncoder& encoder,
const array& in,
const array& wt,
array& out,
const std::vector<int>& strides,
const std::vector<int>& padding,
const std::vector<int>& kernel_dilation,
const std::vector<int>& input_dilation,
int groups,
bool flip,
Stream s) {
int conv_ndim = in.ndim() - 2;
if (conv_ndim < 1 || conv_ndim > 3) {
throw std::runtime_error(
fmt::format("[conv] Unsupported gemm_conv for {}D conv.", conv_ndim));
}
dispatch_1_2_3(conv_ndim, [&](auto ndim_constant) {
ConvParams<ndim_constant()> params(
in,
wt,
out,
strides,
padding,
kernel_dilation,
input_dilation,
groups,
flip);
gemm_grouped_conv_nd<ndim_constant()>(encoder, in, wt, out, params, s);
});
}
} // namespace mlx::core

18
mlx/backend/cuda/copy.cu
View File

@@ -15,8 +15,8 @@ void copy_gpu_inplace(
int64_t offset_out,
CopyType ctype,
const Stream& s,
std::optional<array> dynamic_offset_in,
std::optional<array> dynamic_offset_out) {
const std::optional<array>& dynamic_offset_in,
const std::optional<array>& dynamic_offset_out) {
if (out.size() == 0) {
return;
}
@@ -44,16 +44,6 @@ void copy_gpu_inplace(
strides_vec[0]);
} else {
if (dynamic_offset_in || dynamic_offset_out) {
if (!dynamic_offset_in) {
dynamic_offset_in = array(0, int64);
encoder.add_temporary(*dynamic_offset_in);
}
if (!dynamic_offset_out) {
dynamic_offset_out = array(0, int64);
encoder.add_temporary(*dynamic_offset_out);
}
encoder.set_input_array(*dynamic_offset_in);
encoder.set_input_array(*dynamic_offset_out);
copy_general_dynamic(
encoder,
ctype,
@@ -64,8 +54,8 @@ void copy_gpu_inplace(
shape_collapsed,
strides_vec[0],
strides_vec[1],
*dynamic_offset_in,
*dynamic_offset_out);
dynamic_offset_in ? *dynamic_offset_in : array(0, int64),
dynamic_offset_out ? *dynamic_offset_out : array(0, int64));
} else {
copy_general(
encoder,

15
mlx/backend/cuda/copy/copy_contiguous.cu
View File

@@ -22,7 +22,7 @@ __global__ void copy_s(const In* in, Out* out, IdxT size) {
AlignedVector<Out, N_READS> out_vec;
#pragma unroll
for (int i = 0; i < N_READS; ++i) {
out_vec[i] = cast_to<Out>(in[0]);
out_vec.val[i] = cast_to<Out>(in[0]);
}
store_vector<N_READS>(out, index, out_vec);
@@ -43,7 +43,7 @@ __global__ void copy_v(const In* in, Out* out, IdxT size) {
AlignedVector<Out, N_READS> out_vec;
#pragma unroll
for (int i = 0; i < N_READS; ++i) {
out_vec[i] = cast_to<Out>(in_vec[i]);
out_vec.val[i] = cast_to<Out>(in_vec.val[i]);
}
store_vector<N_READS>(out, index, out_vec);
@@ -65,18 +65,23 @@ void copy_contiguous(
using InType = cuda_type_t<MLX_GET_TYPE(in_type_tag)>;
using OutType = cuda_type_t<MLX_GET_TYPE(out_type_tag)>;
using IdxT = std::conditional_t<large(), int64_t, uint32_t>;
constexpr int N_READS = 16 / sizeof(InType);
// TODO: Choose optimized value based on type size.
constexpr int N_READS = 4;
auto kernel = cu::copy_s<InType, OutType, IdxT, N_READS>;
if (ctype == CopyType::Vector) {
kernel = cu::copy_v<InType, OutType, IdxT, N_READS>;
}
auto [num_blocks, block_dims] = get_launch_args(
out.data_size(), out.shape(), out.strides(), large(), N_READS);
kernel,
out.data_size(),
out.shape(),
out.strides(),
large(),
N_READS);
encoder.add_kernel_node(
kernel,
num_blocks,
block_dims,
0,
in.data<InType>() + in_offset,
out.data<OutType>() + out_offset,
out.data_size());

107
mlx/backend/cuda/copy/copy_general.cu
View File

@@ -10,80 +10,37 @@ namespace cu {
namespace cg = cooperative_groups;
template <typename In, typename Out, typename IdxT, int NDIM, int N_READS>
template <typename In, typename Out, typename IdxT, int NDIM>
__global__ void copy_gg_nd(
const In* in,
Out* out,
IdxT size_rest,
IdxT size,
const __grid_constant__ cuda::std::array<int32_t, NDIM> shape,
const __grid_constant__ cuda::std::array<int64_t, NDIM> strides_in,
const __grid_constant__ cuda::std::array<int64_t, NDIM> strides_out) {
auto block = cg::this_thread_block();
auto grid = cg::this_grid();
IdxT index_rest =
grid.block_index().y * block.dim_threads().y + block.thread_index().y;
if (index_rest >= size_rest) {
return;
}
auto shape_x = shape[NDIM - 1];
auto in_stride_x = strides_in[NDIM - 1];
auto out_stride_x = strides_out[NDIM - 1];
IdxT index_x =
grid.block_index().x * block.dim_threads().x + block.thread_index().x;
IdxT index = cg::this_grid().thread_rank();
if (index < size) {
auto [idx_in, idx_out] = elem_to_loc_nd<NDIM>(
index_rest * shape_x,
shape.data(),
strides_in.data(),
strides_out.data());
auto in_vec =
load_vector<N_READS>(in + idx_in, index_x, shape_x, in_stride_x, In(0));
AlignedVector<Out, N_READS> out_vec;
#pragma unroll
for (int i = 0; i < N_READS; ++i) {
out_vec[i] = CastOp<In, Out>{}(in_vec[i]);
index, shape.data(), strides_in.data(), strides_out.data());
out[idx_out] = CastOp<In, Out>{}(in[idx_in]);
}
store_vector(out + idx_out, index_x, out_vec, shape_x, out_stride_x);
}
template <typename In, typename Out, typename IdxT, int N_READS>
template <typename In, typename Out, typename IdxT>
__global__ void copy_gg(
const In* in,
Out* out,
IdxT size_rest,
IdxT size,
const __grid_constant__ Shape shape,
const __grid_constant__ Strides strides_in,
const __grid_constant__ Strides strides_out,
int ndim) {
auto block = cg::this_thread_block();
auto grid = cg::this_grid();
IdxT index_rest =
grid.block_index().y * block.dim_threads().y + block.thread_index().y;
if (index_rest >= size_rest) {
return;
IdxT index = cg::this_grid().thread_rank();
if (index < size) {
auto [idx_in, idx_out] = elem_to_loc_4d(
index, shape.data(), strides_in.data(), strides_out.data(), ndim);
out[idx_out] = CastOp<In, Out>{}(in[idx_in]);
}
auto shape_x = shape[ndim - 1];
auto in_stride_x = strides_in[ndim - 1];
auto out_stride_x = strides_out[ndim - 1];
IdxT index_x =
grid.block_index().x * block.dim_threads().x + block.thread_index().x;
auto [idx_in, idx_out] = elem_to_loc(
index_rest * shape_x,
shape.data(),
strides_in.data(),
strides_out.data(),
ndim);
auto in_vec =
load_vector<N_READS>(in + idx_in, index_x, shape_x, in_stride_x, In(0));
AlignedVector<Out, N_READS> out_vec;
#pragma unroll
for (int i = 0; i < N_READS; ++i) {
out_vec[i] = CastOp<In, Out>{}(in_vec[i]);
}
store_vector(out + idx_out, index_x, out_vec, shape_x, out_stride_x);
}
} // namespace cu
@@ -112,52 +69,34 @@ void copy_general(
size_t data_size = 1;
for (auto& s : shape)
data_size *= s;
int work_per_thread = 1;
auto dim0 = ndim > 0 ? shape.back() : 1;
auto rest = data_size / dim0;
if (dim0 >= 4) {
work_per_thread = 4;
}
dim0 = (dim0 + work_per_thread - 1) / work_per_thread;
auto block_dims = get_block_dims(dim0, rest, 1);
uint32_t num_blocks_x = cuda::ceil_div(dim0, block_dims.x);
uint32_t num_blocks_y = cuda::ceil_div(rest, block_dims.y);
if (ndim <= 3) {
dispatch_1_2_3(ndim, [&](auto ndim_constant) {
auto kernel =
cu::copy_gg_nd<InType, OutType, IdxT, ndim_constant(), 1>;
if (work_per_thread == 4) {
kernel =
cu::copy_gg_nd<InType, OutType, IdxT, ndim_constant(), 4>;
}
cu::copy_gg_nd<InType, OutType, IdxT, ndim_constant()>;
auto [num_blocks, block_dims] = get_launch_args(
kernel, data_size, shape, out.strides(), large());
encoder.add_kernel_node(
kernel,
{num_blocks_x, num_blocks_y},
num_blocks,
block_dims,
0,
in_ptr,
out_ptr,
rest,
data_size,
const_param<ndim_constant()>(shape),
const_param<ndim_constant()>(strides_in),
const_param<ndim_constant()>(strides_out));
});
} else { // ndim >= 4
auto kernel = cu::copy_gg<InType, OutType, IdxT, 1>;
if (work_per_thread == 4) {
kernel = cu::copy_gg<InType, OutType, IdxT, 4>;
}
auto kernel = cu::copy_gg<InType, OutType, IdxT>;
auto [num_blocks, block_dims] = get_launch_args(
kernel, data_size, shape, out.strides(), large());
encoder.add_kernel_node(
kernel,
{num_blocks_x, num_blocks_y},
num_blocks,
block_dims,
0,
in_ptr,
out_ptr,
rest,
data_size,
const_param(shape),
const_param(strides_in),
const_param(strides_out),

21
mlx/backend/cuda/copy/copy_general_dynamic.cu
View File

@@ -41,7 +41,7 @@ __global__ void copy_gg_dynamic(
const int64_t* offset_out) {
IdxT index = cg::this_grid().thread_rank();
if (index < size) {
auto [idx_in, idx_out] = elem_to_loc(
auto [idx_in, idx_out] = elem_to_loc_4d(
index, shape.data(), strides_in.data(), strides_out.data(), ndim);
out[idx_out + *offset_out] = CastOp<In, Out>{}(in[idx_in + *offset_in]);
}
@@ -74,16 +74,14 @@ void copy_general_dynamic(
int ndim = shape.size();
if (ndim <= 3) {
dispatch_1_2_3(ndim, [&](auto dims_constant) {
auto [num_blocks, block_dims] = get_launch_args(out, large());
auto kernel = cu::
copy_gg_dynamic_nd<InType, OutType, IdxT, dims_constant()>;
auto [num_blocks, block_dims] =
get_launch_args(kernel, out, large());
encoder.add_kernel_node(
cu::copy_gg_dynamic_nd<
InType,
OutType,
IdxT,
dims_constant()>,
kernel,
num_blocks,
block_dims,
0,
in_ptr,
out_ptr,
out.size(),
@@ -94,12 +92,13 @@ void copy_general_dynamic(
dynamic_offset_out.data<int64_t>());
});
} else { // ndim >= 4
auto [num_blocks, block_dims] = get_launch_args(out, large());
auto kernel = cu::copy_gg_dynamic<InType, OutType, IdxT>;
auto [num_blocks, block_dims] =
get_launch_args(kernel, out, large());
encoder.add_kernel_node(
cu::copy_gg_dynamic<InType, OutType, IdxT>,
kernel,
num_blocks,
block_dims,
0,
in_ptr,
out_ptr,
out.size(),

98
mlx/backend/cuda/copy/copy_general_input.cu
View File

@@ -10,67 +10,33 @@ namespace cu {
namespace cg = cooperative_groups;
template <typename In, typename Out, typename IdxT, int NDIM, int N_READS>
template <typename In, typename Out, typename IdxT, int NDIM>
__global__ void copy_g_nd(
const In* in,
Out* out,
IdxT size_rest,
IdxT size,
const __grid_constant__ cuda::std::array<int32_t, NDIM> shape,
const __grid_constant__ cuda::std::array<int64_t, NDIM> strides) {
auto block = cg::this_thread_block();
auto grid = cg::this_grid();
IdxT index_rest =
grid.block_index().y * block.dim_threads().y + block.thread_index().y;
if (index_rest >= size_rest) {
return;
const __grid_constant__ cuda::std::array<int64_t, NDIM> strides_in) {
IdxT index = cg::this_grid().thread_rank();
if (index < size) {
IdxT idx_in = elem_to_loc_nd<NDIM>(index, shape.data(), strides_in.data());
out[index] = CastOp<In, Out>{}(in[idx_in]);
}
auto shape_x = shape[NDIM - 1];
auto stride_x = strides[NDIM - 1];
IdxT index_x =
grid.block_index().x * block.dim_threads().x + block.thread_index().x;
auto idx =
elem_to_loc_nd<NDIM>(index_rest * shape_x, shape.data(), strides.data());
auto in_vec =
load_vector<N_READS>(in + idx, index_x, shape_x, stride_x, In(0));
AlignedVector<Out, N_READS> out_vec;
#pragma unroll
for (int i = 0; i < N_READS; ++i) {
out_vec[i] = CastOp<In, Out>{}(in_vec[i]);
}
store_vector(out + shape_x * index_rest, index_x, out_vec, shape_x);
}
template <typename In, typename Out, typename IdxT, int N_READS>
template <typename In, typename Out, typename IdxT>
__global__ void copy_g(
const In* in,
Out* out,
IdxT size_rest,
IdxT size,
const __grid_constant__ Shape shape,
const __grid_constant__ Strides strides,
const __grid_constant__ Strides strides_in,
int ndim) {
auto block = cg::this_thread_block();
auto grid = cg::this_grid();
IdxT index_rest =
grid.block_index().y * block.dim_threads().y + block.thread_index().y;
if (index_rest >= size_rest) {
return;
IdxT index = cg::this_grid().thread_rank();
if (index < size) {
IdxT idx_in = elem_to_loc_4d(index, shape.data(), strides_in.data(), ndim);
out[index] = CastOp<In, Out>{}(in[idx_in]);
}
auto shape_x = shape[ndim - 1];
auto stride_x = strides[ndim - 1];
IdxT index_x =
grid.block_index().x * block.dim_threads().x + block.thread_index().x;
auto idx =
elem_to_loc(index_rest * shape_x, shape.data(), strides.data(), ndim);
auto in_vec =
load_vector<N_READS>(in + idx, index_x, shape_x, stride_x, In(0));
AlignedVector<Out, N_READS> out_vec;
#pragma unroll
for (int i = 0; i < N_READS; ++i) {
out_vec[i] = CastOp<In, Out>{}(in_vec[i]);
}
store_vector(out + shape_x * index_rest, index_x, out_vec, shape_x);
}
} // namespace cu
@@ -95,49 +61,33 @@ void copy_general_input(
const InType* in_ptr = in.data<InType>() + offset_in;
OutType* out_ptr = out.data<OutType>() + offset_out;
int ndim = shape.size();
int work_per_thread = 1;
auto dim0 = ndim > 0 ? shape.back() : 1;
auto rest = out.size() / dim0;
if (dim0 >= 4) {
work_per_thread = 4;
}
dim0 = (dim0 + work_per_thread - 1) / work_per_thread;
auto block_dims = get_block_dims(dim0, rest, 1);
uint32_t num_blocks_x = cuda::ceil_div(dim0, block_dims.x);
uint32_t num_blocks_y = cuda::ceil_div(rest, block_dims.y);
if (ndim <= 3) {
dispatch_1_2_3(ndim, [&](auto dims_constant) {
auto kernel =
cu::copy_g_nd<InType, OutType, IdxT, dims_constant(), 1>;
if (work_per_thread == 4) {
kernel =
cu::copy_g_nd<InType, OutType, IdxT, dims_constant(), 4>;
}
cu::copy_g_nd<InType, OutType, IdxT, dims_constant()>;
auto [num_blocks, block_dims] =
get_launch_args(kernel, out, large());
encoder.add_kernel_node(
kernel,
{num_blocks_x, num_blocks_y},
num_blocks,
block_dims,
0,
in_ptr,
out_ptr,
rest,
out.size(),
const_param<dims_constant()>(shape),
const_param<dims_constant()>(strides_in));
});
} else { // ndim >= 4
auto kernel = cu::copy_g<InType, OutType, IdxT, 1>;
if (work_per_thread == 4) {
kernel = cu::copy_g<InType, OutType, IdxT, 4>;
}
auto kernel = cu::copy_g<InType, OutType, IdxT>;
auto [num_blocks, block_dims] =
get_launch_args(kernel, out, large());
encoder.add_kernel_node(
kernel,
{num_blocks_x, num_blocks_y},
num_blocks,
block_dims,
0,
in_ptr,
out_ptr,
rest,
out.size(),
const_param(shape),
const_param(strides_in),
ndim);

272
mlx/backend/cuda/cudnn_utils.cpp
View File

@@ -1,272 +0,0 @@
// Copyright © 2025 Apple Inc.
#include "mlx/backend/cuda/cudnn_utils.h"
#include "mlx/backend/cuda/device.h"
namespace mlx::core {
namespace {
// Create a cudnn tensor descriptor.
template <typename Vec>
inline cudnn_frontend::Tensor build_cudnn_tensor(
int64_t id,
const array& x,
const Vec& shape,
const Vec& strides) {
return cudnn_frontend::TensorBuilder()
.setDim(shape.size(), shape.data())
.setStrides(strides.size(), strides.data())
.setId(id)
.setAlignment(get_alignment(x))
.setDataType(dtype_to_cudnn_type(x.dtype()))
.build();
}
// In MLX a singleton dim (shape[dim] == 1) can have any stride, but in cuDNN
// whether a tensor is contiguous is determined with:
// shape[dim] == shape[dim + 1] * strides[dim + 1]
// So a contiguous array with singleton dims in MLX may be mistakenly treated
// as strided in cuDNN, and we work around it by normalizing the strides.
Strides normalized_strides(const array& x) {
if (!x.flags().row_contiguous || x.ndim() < 2) {
return x.strides();
}
Strides strides = x.strides();
for (int i = x.ndim() - 2; i >= 0; --i) {
if (x.shape(i) == 1) {
strides[i] = x.shape(i + 1) * strides[i + 1];
}
}
return strides;
}
// Return the shape and strides after transposing from NHWC to NCHW.
auto nhwc_to_nchw(SmallVector<int64_t> shape, SmallVector<int64_t> strides) {
assert(shape.size() >= 3);
shape.insert(shape.begin() + 1, shape.back());
shape.erase(shape.end() - 1);
strides.insert(strides.begin() + 1, strides.back());
strides.erase(strides.end() - 1);
return std::make_tuple(std::move(shape), std::move(strides));
}
inline auto nhwc_to_nchw(const array& x) {
return nhwc_to_nchw(
convert_vector<int64_t>(x.shape()), normalized_strides(x));
}
// Return available engines for a |op_graph|.
cudnn_frontend::EngineConfigList get_cudnn_engine_configs(
cudnnBackendDescriptorType_t backend_type,
Dtype dtype,
cudnn_frontend::OperationGraph& op_graph,
bool use_fallback = true) {
SmallVector<cudnn_frontend::GeneratorSource, 2> sources;
sources.push_back([](auto& op_graph) {
auto heuristics = cudnn_frontend::EngineHeuristicsBuilder()
.setOperationGraph(op_graph)
.setHeurMode(CUDNN_HEUR_MODE_A)
.build();
return heuristics.getEngineConfig(heuristics.getEngineConfigCount());
});
if (use_fallback) {
sources.push_back([&backend_type](auto& op_graph) {
auto fallback = cudnn_frontend::EngineFallbackListBuilder()
.setOperationGraph(op_graph)
.setOperation(backend_type)
.build();
return fallback.getFallbackList();
});
}
auto configs =
cudnn_frontend::EngineConfigGenerator(sources.size(), sources.data())
.generate_engine_config(op_graph);
cudnn_frontend::EngineConfigList filtered_configs;
cudnn_frontend::filter(configs, filtered_configs, [dtype](auto c) {
if (cudnn_frontend::hasNumericalNote<
CUDNN_NUMERICAL_NOTE_DOWN_CONVERT_INPUTS>(c)) {
return true;
}
if (cudnn_frontend::hasNumericalNote<CUDNN_NUMERICAL_NOTE_TENSOR_CORE>(c) &&
dtype == float32 && !env::enable_tf32()) {
return true;
}
return false;
});
return filtered_configs;
}
// Take |engine_configs| and |op_graph| and find a working execution plans
// from them.
std::optional<cudnn_frontend::ExecutionPlan>
find_cudnn_plan_from_engine_configs(
cudnnHandle_t handle,
const cudnn_frontend::EngineConfigList& engine_configs,
const cudnn_frontend::OperationGraph& op_graph) {
auto op_graph_tag = op_graph.getTag();
for (const auto& config : engine_configs) {
try {
return cudnn_frontend::ExecutionPlanBuilder()
.setHandle(handle)
.setEngineConfig(config, op_graph_tag)
.build();
} catch (cudnn_frontend::cudnnException& error) {
if (error.getCudnnStatus() != CUDNN_STATUS_NOT_SUPPORTED) {
throw;
}
}
}
return std::nullopt;
}
// Prepare workspace and args to execute plan.
template <typename F>
bool prepare_cudnn_plan(
cu::CommandEncoder& encoder,
cudnn_frontend::ExecutionPlan& plan,
int num_args,
const int64_t* uids,
void** data_ptrs,
F&& execute) {
int workspace_size = plan.getWorkspaceSize();
array workspace(
workspace_size > 0 ? allocator::malloc(workspace_size)
: allocator::Buffer(nullptr),
{workspace_size},
uint8);
auto args = cudnn_frontend::VariantPackBuilder()
.setWorkspacePointer(workspace.data<void>())
.setDataPointers(num_args, data_ptrs)
.setUids(num_args, uids)
.build();
auto handle = encoder.device().cudnn_handle();
cudnnSetStream(handle, encoder.stream());
if (!execute(handle, plan.get_raw_desc(), args.get_raw_desc())) {
return false;
}
encoder.add_temporary(workspace);
return true;
}
} // namespace
cudnn_frontend::Tensor build_cudnn_tensor(int64_t id, const array& x) {
auto shape = convert_vector<int64_t>(x.shape());
return build_cudnn_tensor(id, x, shape, normalized_strides(x));
}
cudnn_frontend::Tensor build_cudnn_tensor_nchw(int64_t id, const array& x) {
auto [shape, strides] = nhwc_to_nchw(x);
return build_cudnn_tensor(id, x, shape, strides);
}
cudnn_frontend::Tensor build_cudnn_tensor_4d_nchw(int64_t id, const array& x) {
if (x.ndim() == 0) {
SmallVector<int64_t, 4> scalar_dims = {1, 1, 1, 1};
return build_cudnn_tensor(id, x, scalar_dims, scalar_dims);
}
if (x.ndim() == 1) {
int64_t s = x.shape(0);
SmallVector<int64_t, 4> shape = {1, x.shape(0), 1, 1};
SmallVector<int64_t, 4> strides = {s, 1, s, s};
return build_cudnn_tensor(id, x, shape, strides);
}
if (x.ndim() == 2) {
int64_t s =
x.flags().row_contiguous ? x.shape(1) * x.strides(1) : x.strides(0);
SmallVector<int64_t, 4> shape = {x.shape(0), x.shape(1), 1, 1};
SmallVector<int64_t, 4> strides = {s, x.strides(1), s, s};
return build_cudnn_tensor(id, x, shape, strides);
}
if (x.ndim() == 3 || x.ndim() == 4) {
return build_cudnn_tensor_nchw(id, x);
}
throw std::runtime_error(
fmt::format("Unsupported array with {} dims.", x.ndim()));
}
cudnn_frontend::Tensor build_cudnn_scalar_4d(int64_t id, Dtype dtype) {
SmallVector<int64_t, 4> scalar_dims = {1, 1, 1, 1};
return cudnn_frontend::TensorBuilder()
.setDim(scalar_dims.size(), scalar_dims.data())
.setStrides(scalar_dims.size(), scalar_dims.data())
.setId(id)
.setAlignment(16)
.setDataType(dtype_to_cudnn_type(dtype))
.setByValue(true)
.build();
}
std::optional<cudnn_frontend::ExecutionPlan> find_cudnn_plan_from_op_graph(
cudnnHandle_t handle,
cudnnBackendDescriptorType_t backend_type,
Dtype dtype,
cudnn_frontend::OperationGraph& op_graph) {
auto engine_configs = get_cudnn_engine_configs(backend_type, dtype, op_graph);
return find_cudnn_plan_from_engine_configs(handle, engine_configs, op_graph);
}
bool encode_cudnn_plan_with_capturing(
cu::CommandEncoder& encoder,
cudnn_frontend::ExecutionPlan& plan,
int num_args,
const int64_t* uids,
void** data_ptrs) {
return prepare_cudnn_plan(
encoder,
plan,
num_args,
uids,
data_ptrs,
[&](auto handle, auto plan, auto args) {
auto capture = encoder.capture_context();
if (cudnnBackendExecute(handle, plan, args) != CUDNN_STATUS_SUCCESS) {
// Discard the captured graph when failed.
capture.discard = true;
return false;
}
return true;
});
}
#if CUDNN_VERSION >= 90500
bool encode_cudnn_plan_with_graph_api(
cu::CommandEncoder& encoder,
cudnn_frontend::ExecutionPlan& plan,
CudaGraph& graph,
int num_args,
const int64_t* uids,
void** data_ptrs) {
return prepare_cudnn_plan(
encoder,
plan,
num_args,
uids,
data_ptrs,
[&](auto handle, auto plan, auto args) {
if (!graph) {
graph = CudaGraph(encoder.device());
if (cudnnBackendPopulateCudaGraph(handle, plan, args, graph) !=
CUDNN_STATUS_SUCCESS) {
return false;
}
} else {
if (cudnnBackendUpdateCudaGraph(handle, plan, args, graph) !=
CUDNN_STATUS_SUCCESS) {
return false;
}
}
encoder.add_graph_node(graph);
return true;
});
}
#endif
} // namespace mlx::core

164
mlx/backend/cuda/cudnn_utils.h
View File

@@ -1,164 +0,0 @@
// Copyright © 2025 Apple Inc.
#pragma once
#include "mlx/array.h"
#include "mlx/backend/cuda/device/config.h"
#include "mlx/backend/cuda/utils.h"
#include "mlx/dtype_utils.h"
#include <cudnn_frontend.h>
#include <cudnn_frontend_find_plan.h>
#include <fmt/format.h>
#include <algorithm>
#include <array>
namespace mlx::core {
namespace cu {
class CommandEncoder;
}
// Return pointer alignment of |x|'s data.
inline uint8_t get_alignment(const array& x) {
uint8_t alignment = 1;
uintptr_t address = reinterpret_cast<uintptr_t>(x.data<void>());
for (; alignment < 32; alignment *= 2) {
if (address % (alignment * 2)) {
return alignment;
}
}
return alignment;
}
// Convert the type of elements in |vec| to |T|.
template <typename T, typename Vec>
inline SmallVector<T> convert_vector(const Vec& vec) {
return SmallVector<T>(vec.begin(), vec.end());
}
// Return an array that can be used as map key for |vec| with size <= MAX_NDIM.
//
// There are 2 differences from the const_param util from kernel_utils.cuh:
// 1. The rest of array is filled with 0.
// 2. This util can be used in .cpp files.
template <typename T, template <typename U> class Vec>
inline std::array<T, MAX_NDIM> vector_key(const Vec<T>& vec) {
if (vec.size() > MAX_NDIM) {
throw std::runtime_error(
fmt::format("ndim can not be larger than {}.", MAX_NDIM));
}
std::array<T, MAX_NDIM> result = {};
std::copy_n(vec.begin(), vec.size(), result.begin());
return result;
}
// Helpers used by get_data_ptrs to get pointers.
inline void* get_data_ptr(const array& arr) {
return const_cast<void*>(arr.data<void>());
}
template <typename T, typename = std::enable_if_t<std::is_scalar_v<T>>>
inline void* get_data_ptr(T& scalar) {
return &scalar;
}
// Return an array filled with data pointers of args.
template <typename... Args>
inline std::array<void*, sizeof...(Args)> get_data_ptrs(Args&... args) {
return {get_data_ptr(args)...};
}
// Map dtype to cudnn data type.
inline cudnnDataType_t dtype_to_cudnn_type(Dtype dtype) {
switch (dtype) {
case int8:
return CUDNN_DATA_INT8;
case int32:
return CUDNN_DATA_INT32;
case uint8:
return CUDNN_DATA_UINT8;
case float16:
return CUDNN_DATA_HALF;
case bfloat16:
return CUDNN_DATA_BFLOAT16;
case float32:
return CUDNN_DATA_FLOAT;
case float64:
return CUDNN_DATA_DOUBLE;
default:
throw std::runtime_error(fmt::format(
"Unsupported dtype in Convolution: {}.", dtype_to_string(dtype)));
}
}
// Create a tensor descriptor from |x|.
cudnn_frontend::Tensor build_cudnn_tensor(int64_t id, const array& x);
// Create a tensor descriptor from |x|, and transpose from NHWC to NCHW.
cudnn_frontend::Tensor build_cudnn_tensor_nchw(int64_t id, const array& x);
// Create a tensor descriptor from |x|, make sure it is 4D, and transpose it
// from NHWC to NCHW.
cudnn_frontend::Tensor build_cudnn_tensor_4d_nchw(int64_t id, const array& x);
// Create a 4D scalar tensor descriptor, which is passed by value.
cudnn_frontend::Tensor build_cudnn_scalar_4d(int64_t id, Dtype dtype);
// Find a working plan for |op_graph|.
std::optional<cudnn_frontend::ExecutionPlan> find_cudnn_plan_from_op_graph(
cudnnHandle_t handle,
cudnnBackendDescriptorType_t backend_type,
Dtype dtype,
cudnn_frontend::OperationGraph& op_graph);
// Encode the plan to command buffer by capturing.
bool encode_cudnn_plan_with_capturing(
cu::CommandEncoder& encoder,
cudnn_frontend::ExecutionPlan& plan,
int num_args,
const int64_t* uids,
void** data_ptrs);
#if CUDNN_VERSION >= 90500
// Encode the plan to command buffer by using native graph api of cudnn. If the
// |graph| is empty it will be populated, otherwise it will be updated.
bool encode_cudnn_plan_with_graph_api(
cu::CommandEncoder& encoder,
cudnn_frontend::ExecutionPlan& plan,
CudaGraph& graph,
int num_args,
const int64_t* uids,
void** data_ptrs);
#endif
// Helpers to make calls like encode_cudnn_plan(..., {'x', 'y', 'z'}, x, y, z).
template <typename... Args>
bool encode_cudnn_plan(
cu::CommandEncoder& encoder,
cudnn_frontend::ExecutionPlan& plan,
std::initializer_list<int64_t> uids,
Args&... args) {
assert(uids.size() == sizeof...(args));
auto data_ptrs = get_data_ptrs(args...);
return encode_cudnn_plan_with_capturing(
encoder, plan, uids.size(), uids.begin(), data_ptrs.data());
}
#if CUDNN_VERSION >= 90500
template <typename... Args>
bool encode_cudnn_plan(
cu::CommandEncoder& encoder,
cudnn_frontend::ExecutionPlan& plan,
CudaGraph& graph,
std::initializer_list<int64_t> uids,
Args&... args) {
assert(uids.size() == sizeof...(args));
auto data_ptrs = get_data_ptrs(args...);
return encode_cudnn_plan_with_graph_api(
encoder, plan, graph, uids.size(), uids.begin(), data_ptrs.data());
}
#endif
} // namespace mlx::core

379
mlx/backend/cuda/custom_kernel.cpp
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@@ -1,379 +0,0 @@
// Copyright © 2025 Apple Inc.
#include <iostream>
#include "mlx/backend/common/compiled.h"
#include "mlx/backend/cuda/jit_module.h"
#include "mlx/backend/cuda/utils.h"
#include "mlx/backend/gpu/copy.h"
#include "mlx/fast.h"
#include "mlx/fast_primitives.h"
#include <fmt/format.h>
#include <nvtx3/nvtx3.hpp>
namespace mlx::core::fast {
namespace {
constexpr const char* default_header = R"(
#include "mlx/backend/cuda/device/utils.cuh"
#include <cooperative_groups.h>
#define inf cuda::std::numeric_limits<float>::infinity()
)";
std::string template_arguments_hash(
const std::vector<std::pair<std::string, TemplateArg>>& template_args) {
if (template_args.empty()) {
return "";
}
std::string hash;
hash.reserve(512);
for (const auto& [name, arg] : template_args) {
if (std::holds_alternative<int>(arg)) {
hash += fmt::format("_{}", std::get<int>(arg));
} else if (std::holds_alternative<bool>(arg)) {
hash += (std::get<bool>(arg)) ? "_t" : "_f";
} else if (std::holds_alternative<Dtype>(arg)) {
hash += "_";
hash += get_type_string(std::get<Dtype>(arg));
}
}
return hash;
}
std::string build_kernel(
const std::string& func_name,
const std::string& header,
const std::string& source,
const std::vector<std::string>& input_names,
const std::vector<array>& inputs,
const std::vector<std::string>& output_names,
const std::vector<Dtype>& output_dtypes,
const std::vector<std::pair<std::string, TemplateArg>>& template_args,
const std::vector<CustomKernelShapeInfo>& shape_infos) {
std::string kernel_source;
kernel_source.reserve(header.size() + source.size() + 8192);
kernel_source += default_header;
kernel_source += header;
kernel_source +=
"namespace mlx::core::cu {\n\n"
"namespace cg = cooperative_groups;\n\n";
kernel_source += "__global__ void ";
kernel_source += func_name;
kernel_source += "(\n";
// Add inputs
for (int i = 0; i < inputs.size(); ++i) {
const auto& name = input_names[i];
const auto& arr = inputs[i];
kernel_source += " const ";
kernel_source += dtype_to_cuda_type(arr.dtype());
kernel_source += "* ";
kernel_source += name;
kernel_source += ",\n";
// Add input shape, strides and ndim if present in the source
if (arr.ndim() > 0) {
if (shape_infos[i].shape) {
kernel_source += " const __grid_constant__ Shape ";
kernel_source += name;
kernel_source += "_shape,\n";
}
if (shape_infos[i].strides) {
kernel_source += " const __grid_constant__ Strides ";
kernel_source += name;
kernel_source += "_strides,\n";
}
if (shape_infos[i].ndim) {
kernel_source += " const __grid_constant__ int ";
kernel_source += name;
kernel_source += "_ndim,\n";
}
}
}
// Add outputs
for (int i = 0; i < output_names.size(); ++i) {
const auto& name = output_names[i];
const auto& dtype = output_dtypes[i];
kernel_source += " ";
kernel_source += dtype_to_cuda_type(dtype);
kernel_source += "* ";
kernel_source += name;
if (i < output_names.size() - 1) {
kernel_source += ",\n";
} else {
kernel_source += ") {\n";
}
}
// Set compile time constants
if (!template_args.empty()) {
for (const auto& [name, arg] : template_args) {
if (std::holds_alternative<int>(arg)) {
kernel_source +=
fmt::format(" constexpr int {} = {};\n", name, std::get<int>(arg));
} else if (std::holds_alternative<bool>(arg)) {
kernel_source += fmt::format(
" constexpr bool {} = {};\n", name, std::get<bool>(arg));
} else {
kernel_source += fmt::format(
" using {} = {};\n",
name,
dtype_to_cuda_type(std::get<Dtype>(arg)));
}
}
kernel_source += "\n";
}
kernel_source += source;
kernel_source += "\n}\n\n} // namespace mlx::core::cu\n";
return kernel_source;
}
} // namespace
CustomKernelFunction cuda_kernel(
const std::string& name,
const std::vector<std::string>& input_names,
const std::vector<std::string>& output_names,
const std::string& source,
const std::string& header,
bool ensure_row_contiguous,
int shared_memory) {
if (output_names.empty()) {
throw std::invalid_argument(
"[custom_kernel] Must specify at least one output.");
}
std::vector<CustomKernelShapeInfo> shape_infos;
for (auto& n : input_names) {
CustomKernelShapeInfo shape_info;
shape_info.shape = source.find(n + "_shape") != std::string::npos;
shape_info.strides = source.find(n + "_strides") != std::string::npos;
shape_info.ndim = source.find(n + "_ndim") != std::string::npos;
shape_infos.push_back(shape_info);
}
return [=, shape_infos = std::move(shape_infos)](
const std::vector<array>& inputs,
const std::vector<Shape>& output_shapes,
const std::vector<Dtype>& output_dtypes,
std::tuple<int, int, int> grid,
std::tuple<int, int, int> threadgroup,
const std::vector<std::pair<std::string, TemplateArg>>&
template_args = {},
std::optional<float> init_value = std::nullopt,
bool verbose = false,
StreamOrDevice s_ = {}) {
if (inputs.size() != input_names.size()) {
std::ostringstream msg;
msg << "[custom_kernel] Expected `inputs` to have size "
<< input_names.size() << " but got size " << inputs.size() << "."
<< std::endl;
throw std::invalid_argument(msg.str());
}
if (output_shapes.size() != output_names.size()) {
std::ostringstream msg;
msg << "[custom_kernel] Expected `output_shapes` to have size "
<< output_names.size() << " but got size " << output_shapes.size()
<< "." << std::endl;
throw std::invalid_argument(msg.str());
}
if (output_dtypes.size() != output_names.size()) {
std::ostringstream msg;
msg << "[custom_kernel] Expected `output_dtypes` to have size "
<< output_names.size() << " but got size " << output_dtypes.size()
<< "." << std::endl;
throw std::invalid_argument(msg.str());
}
auto s = to_stream(s_);
if (s.device != Device::gpu) {
throw std::invalid_argument("[custom_kernel] Only supports the GPU.");
}
std::string kernel_name =
"custom_kernel_" + name + template_arguments_hash(template_args);
std::string kernel_source = build_kernel(
kernel_name,
header,
source,
input_names,
inputs,
output_names,
output_dtypes,
template_args,
shape_infos);
if (verbose) {
std::cout << "Generated source code for `" << kernel_name
<< "`:" << std::endl
<< "```" << std::endl
<< kernel_source << std::endl
<< "```" << std::endl;
}
return array::make_arrays(
std::move(output_shapes),
std::move(output_dtypes),
std::make_shared<CustomKernel>(
s,
std::move(kernel_name),
std::move(kernel_source),
grid,
threadgroup,
shape_infos,
ensure_row_contiguous,
init_value,
std::vector<ScalarArg>{},
false,
shared_memory),
std::move(inputs));
};
}
std::vector<array> precompiled_cuda_kernel(
const std::string& name,
const std::string& compiled_source,
const std::vector<array>& inputs,
const std::vector<Shape>& output_shapes,
const std::vector<Dtype>& output_dtypes,
const std::vector<ScalarArg>& scalars,
std::tuple<int, int, int> grid,
std::tuple<int, int, int> threadgroup,
int shared_memory,
std::optional<float> init_value,
bool ensure_row_contiguous,
StreamOrDevice s) {
std::vector<CustomKernelShapeInfo> shape_infos(
inputs.size(), CustomKernelShapeInfo{false, false, false});
return array::make_arrays(
output_shapes,
output_dtypes,
std::make_shared<CustomKernel>(
to_stream(s),
name,
compiled_source,
grid,
threadgroup,
shape_infos,
ensure_row_contiguous,
init_value,
scalars,
true,
shared_memory),
inputs);
}
void CustomKernel::eval_gpu(
const std::vector<array>& inputs,
std::vector<array>& outputs) {
nvtx3::scoped_range r("CustomKernel::eval_gpu");
auto& s = stream();
std::vector<array> copies;
// Allocate and initialize the output arrays
for (auto& out : outputs) {
if (init_value_) {
copies.emplace_back(init_value_.value(), out.dtype());
fill_gpu(copies.back(), out, s);
} else {
out.set_data(allocator::malloc(out.nbytes()));
}
}
// Create the input arrays and copy if needed
auto check_input = [&copies, &s, this](const array& x) -> const array {
bool no_copy = x.flags().row_contiguous;
if (!ensure_row_contiguous_ || no_copy) {
return x;
} else {
copies.push_back(array(x.shape(), x.dtype(), nullptr, {}));
copy_gpu(x, copies.back(), CopyType::General, s);
return copies.back();
}
};
std::vector<array> checked_inputs;
for (const array& in : inputs) {
checked_inputs.push_back(check_input(in));
}
// Compile the custom kernel
std::string kernel_name =
(is_precompiled_) ? name_ : "mlx::core::cu::" + name_;
cu::JitModule& mod = cu::get_jit_module(
s.device,
name_,
[&]() {
return std::make_tuple(
is_precompiled_, source_, std::vector{kernel_name});
},
false);
// Make the arguments
cu::KernelArgs args;
for (int i = 0; i < checked_inputs.size(); i++) {
const array& in = checked_inputs[i];
auto& shape_info = shape_infos_[i];
args.append(in);
if (shape_info.shape) {
args.append_ndim(in.shape());
}
if (shape_info.strides) {
args.append_ndim(in.strides());
}
if (shape_info.ndim) {
args.append<int32_t>(in.ndim());
}
}
for (auto& out : outputs) {
args.append(out);
}
for (auto& s : scalar_arguments_) {
if (std::holds_alternative<bool>(s)) {
args.append(std::get<bool>(s));
} else if (std::holds_alternative<int>(s)) {
args.append(std::get<int>(s));
} else if (std::holds_alternative<float>(s)) {
args.append(std::get<float>(s));
}
}
// Make the grid
const auto [tx, ty, tz] = threadgroup_;
const auto [gx, gy, gz] = grid_;
dim3 block(std::min(tx, gx), std::min(ty, gy), std::min(tz, gz));
dim3 grid((gx + tx - 1) / tx, (gy + ty - 1) / ty, (gz + tz - 1) / tz);
// Call the kernel
auto& encoder = cu::get_command_encoder(s);
for (const auto& in : checked_inputs) {
encoder.set_input_array(in);
}
for (const auto& out : outputs) {
encoder.set_output_array(out);
}
for (const auto& t : copies) {
encoder.add_temporary(t);
}
auto kernel =
mod.get_kernel(kernel_name, [smem = shared_memory_](CUfunction kernel) {
if (smem > 0 && smem > 48000) {
cuFuncSetAttribute(
kernel, CU_FUNC_ATTRIBUTE_MAX_DYNAMIC_SHARED_SIZE_BYTES, smem);
}
});
encoder.add_kernel_node(kernel, grid, block, shared_memory_, args.args());
}
} // namespace mlx::core::fast

207
mlx/backend/cuda/device.cpp
View File

@@ -1,7 +1,6 @@
// Copyright © 2025 Apple Inc.
#include "mlx/backend/cuda/device.h"
#include "mlx/backend/cuda/jit_module.h"
#include "mlx/backend/cuda/worker.h"
#include "mlx/utils.h"
@@ -10,27 +9,20 @@
#include <future>
#include <unordered_set>
namespace mlx::core::cu {
namespace mlx::core {
namespace {
// Can be tuned with MLX_MAX_OPS_PER_BUFFER
// This should be less than 255
constexpr int default_max_nodes_per_graph = 20;
#define CHECK_CUDNN_ERROR(cmd) check_cudnn_error(#cmd, (cmd))
void check_cudnn_error(const char* name, cudnnStatus_t err) {
if (err != CUDNN_STATUS_SUCCESS) {
throw std::runtime_error(
fmt::format("{} failed: {}.", name, cudnnGetErrorString(err)));
}
}
bool use_cuda_graphs() {
static bool use_graphs = []() {
return env::get_var("MLX_USE_CUDA_GRAPHS", true);
int cuda_graph_cache_size() {
static int cache_size = []() {
return env::get_var("MLX_CUDA_GRAPH_CACHE_SIZE", 100);
}();
return use_graphs;
return cache_size;
}
} // namespace
namespace cu {
Device::Device(int device) : device_(device) {
CHECK_CUDA_ERROR(cudaDeviceGetAttribute(
@@ -48,24 +40,17 @@ Device::Device(int device) : device_(device) {
}
// The cublasLt handle is used by matmul.
make_current();
CHECK_CUBLAS_ERROR(cublasLtCreate(&lt_));
// The cudnn handle is used by Convolution.
CHECK_CUDNN_ERROR(cudnnCreate(&cudnn_));
// Initialize the jit module cache here ensures it is not
// unloaded before any evaluation is done
get_jit_module_cache();
cublasLtCreate(&lt_);
}
Device::~Device() {
CHECK_CUDNN_ERROR(cudnnDestroy(cudnn_));
CHECK_CUBLAS_ERROR(cublasLtDestroy(lt_));
cublasLtDestroy(lt_);
}
void Device::make_current() {
// We need to set/get current CUDA device very frequently, cache it to reduce
// actual calls of CUDA APIs.
static thread_local int current = 0;
// actual calls of CUDA APIs. This function assumes single-thread in host.
static int current = 0;
if (current != device_) {
CHECK_CUDA_ERROR(cudaSetDevice(device_));
current = device_;
@@ -81,25 +66,30 @@ CommandEncoder& Device::get_command_encoder(Stream s) {
}
CommandEncoder::CaptureContext::CaptureContext(CommandEncoder& enc) : enc(enc) {
enc.device().make_current();
if (!use_cuda_graphs()) {
return;
}
CHECK_CUDA_ERROR(cudaGraphCreate(&graph, 0));
CHECK_CUDA_ERROR(
cudaStreamBeginCapture(enc.stream(), cudaStreamCaptureModeGlobal));
}
CommandEncoder::CaptureContext::~CaptureContext() {
if (!use_cuda_graphs()) {
enc.node_count_++;
return;
CHECK_CUDA_ERROR(cudaStreamEndCapture(enc.stream(), &graph));
size_t num_nodes;
CHECK_CUDA_ERROR(cudaGraphGetNodes(graph, NULL, &num_nodes));
if (num_nodes == 1) {
cudaGraphNode_t captured_node;
CHECK_CUDA_ERROR(cudaGraphGetNodes(graph, &captured_node, &num_nodes));
CUDA_KERNEL_NODE_PARAMS params;
CHECK_CUDA_ERROR(cuGraphKernelNodeGetParams(captured_node, &params));
cudaGraphNode_t node;
CHECK_CUDA_ERROR(cuGraphAddKernelNode(&node, enc.graph_, NULL, 0, &params));
enc.insert_graph_dependencies(GraphNode{node, 'K'});
} else {
cudaGraphNode_t node;
CHECK_CUDA_ERROR(
cudaGraphAddChildGraphNode(&node, enc.graph_, NULL, 0, graph));
enc.insert_graph_dependencies(GraphNode{node, 'G'});
}
graph.end_capture(enc.stream());
if (discard) {
return;
}
enc.add_graph_node(graph);
CHECK_CUDA_ERROR(cudaGraphDestroy(graph));
}
CommandEncoder::ConcurrentContext::ConcurrentContext(CommandEncoder& enc)
@@ -109,9 +99,6 @@ CommandEncoder::ConcurrentContext::ConcurrentContext(CommandEncoder& enc)
CommandEncoder::ConcurrentContext::~ConcurrentContext() {
enc.in_concurrent_ = false;
if (!use_cuda_graphs()) {
return;
}
// Use an empty graph node for synchronization
CommandEncoder::GraphNode empty{NULL, 'E', std::to_string(enc.node_count_++)};
@@ -189,79 +176,63 @@ void CommandEncoder::insert_graph_dependencies(std::vector<GraphNode> nodes) {
}
}
CommandEncoder::CommandEncoder(Device& d)
: device_(d),
stream_(d),
graph_(d),
worker_(d),
graph_cache_("MLX_CUDA_GRAPH_CACHE_SIZE", /* default_capacity */ 400) {}
CommandEncoder::CommandEncoder(Device& d) : device_(d), stream_(d) {
CHECK_CUDA_ERROR(cudaGraphCreate(&graph_, 0));
}
void clear_graphs(std::unordered_map<std::string, cudaGraphExec_t>& graphs) {
for (auto& [_, graph_exec] : graphs) {
CHECK_CUDA_ERROR(cudaGraphExecDestroy(graph_exec));
}
graphs.clear();
}
CommandEncoder::~CommandEncoder() {
clear_graphs(graph_cache_);
}
void CommandEncoder::add_completed_handler(std::function<void()> task) {
worker_.add_task(std::move(task));
}
void CommandEncoder::set_input_array(const array& arr) {
if (!use_cuda_graphs()) {
return;
}
auto id = reinterpret_cast<std::uintptr_t>(arr.buffer().ptr());
active_deps_.push_back(id);
}
void CommandEncoder::set_output_array(const array& arr) {
if (!use_cuda_graphs()) {
return;
}
auto id = reinterpret_cast<std::uintptr_t>(arr.buffer().ptr());
active_deps_.push_back(id);
active_outputs_.push_back(id);
}
void CommandEncoder::maybe_commit() {
if (node_count_ >= env::max_ops_per_buffer(default_max_nodes_per_graph)) {
commit();
}
}
void CommandEncoder::add_kernel_node(
void* func,
dim3 grid_dim,
dim3 block_dim,
uint32_t smem_bytes,
void** params) {
if (!use_cuda_graphs()) {
node_count_++;
CHECK_CUDA_ERROR(cudaLaunchKernel(
func, grid_dim, block_dim, params, smem_bytes, stream()));
return;
}
cudaKernelNodeParams kernel_params = {0};
kernel_params.func = func;
kernel_params.gridDim = grid_dim;
kernel_params.blockDim = block_dim;
kernel_params.kernelParams = params;
kernel_params.sharedMemBytes = smem_bytes;
add_kernel_node(kernel_params);
cudaGraphNode_t node;
CHECK_CUDA_ERROR(
cudaGraphAddKernelNode(&node, graph_, NULL, 0, &kernel_params));
insert_graph_dependencies(GraphNode{node, 'K'});
}
void CommandEncoder::add_kernel_node(
CUfunction func,
dim3 grid_dim,
dim3 block_dim,
uint32_t smem_bytes,
void** params) {
if (!use_cuda_graphs()) {
node_count_++;
CHECK_CUDA_ERROR(cuLaunchKernel(
func,
grid_dim.x,
grid_dim.y,
grid_dim.z,
block_dim.x,
block_dim.y,
block_dim.z,
smem_bytes,
stream(),
params,
nullptr));
return;
}
CUDA_KERNEL_NODE_PARAMS kernel_params = {0};
kernel_params.func = func;
kernel_params.gridDimX = grid_dim.x;
@@ -271,55 +242,20 @@ void CommandEncoder::add_kernel_node(
kernel_params.blockDimY = block_dim.y;
kernel_params.blockDimZ = block_dim.z;
kernel_params.kernelParams = params;
kernel_params.sharedMemBytes = smem_bytes;
add_kernel_node(kernel_params);
}
void CommandEncoder::add_kernel_node(const cudaKernelNodeParams& params) {
cudaGraphNode_t node;
CHECK_CUDA_ERROR(cudaGraphAddKernelNode(&node, graph_, NULL, 0, &params));
insert_graph_dependencies(GraphNode{node, 'K'});
}
void CommandEncoder::add_kernel_node(const CUDA_KERNEL_NODE_PARAMS& params) {
CUgraphNode node;
CHECK_CUDA_ERROR(cuGraphAddKernelNode(&node, graph_, NULL, 0, &params));
CHECK_CUDA_ERROR(
cuGraphAddKernelNode(&node, graph_, NULL, 0, &kernel_params));
insert_graph_dependencies(GraphNode{node, 'K'});
}
void CommandEncoder::add_graph_node(cudaGraph_t child) {
if (!use_cuda_graphs()) {
node_count_++;
CudaGraphExec graph_exec;
graph_exec.instantiate(child);
device_.make_current();
CHECK_CUDA_ERROR(cudaGraphLaunch(graph_exec, stream()));
return;
}
cudaGraphNode_t node;
CHECK_CUDA_ERROR(cudaGraphAddChildGraphNode(&node, graph_, NULL, 0, child));
insert_graph_dependencies(GraphNode{node, 'G'});
}
int CommandEncoder::get_num_ops() {
return node_count_;
}
void CommandEncoder::commit() {
nvtx3::scoped_range r("CommandEncoder::commit");
if (!temporaries_.empty()) {
add_completed_handler([temporaries = std::move(temporaries_)]() {});
}
if (use_cuda_graphs() && node_count_ > 0) {
if (node_count_ > 0) {
if (!from_nodes_.empty()) {
CHECK_CUDA_ERROR(cudaGraphAddDependencies(
graph_,
from_nodes_.data(),
to_nodes_.data(),
#if CUDART_VERSION >= 13000
nullptr, // edgeData
#endif // CUDART_VERSION >= 13000
from_nodes_.size()));
graph_, from_nodes_.data(), to_nodes_.data(), from_nodes_.size()));
}
graph_key_ += ".";
@@ -329,7 +265,7 @@ void CommandEncoder::commit() {
graph_key_ += ".";
graph_key_ += std::to_string(empty_node_count_);
CudaGraphExec& graph_exec = graph_cache_[graph_key_];
cudaGraphExec_t& graph_exec = graph_cache_[graph_key_];
if (graph_exec != nullptr) {
cudaGraphExecUpdateResult update_result;
@@ -343,28 +279,36 @@ void CommandEncoder::commit() {
#endif // CUDART_VERSION >= 12000
if (update_result != cudaGraphExecUpdateSuccess) {
cudaGetLastError(); // reset error
graph_exec.reset();
CHECK_CUDA_ERROR(cudaGraphExecDestroy(graph_exec));
graph_exec = nullptr;
}
}
if (graph_exec == nullptr) {
graph_exec.instantiate(graph_);
CHECK_CUDA_ERROR(
cudaGraphInstantiate(&graph_exec, graph_, NULL, NULL, 0));
}
device_.make_current();
CHECK_CUDA_ERROR(cudaGraphLaunch(graph_exec, stream_));
// TODO smarter cache policy
if (graph_cache_.size() > cuda_graph_cache_size()) {
clear_graphs(graph_cache_);
}
// Reset state
node_count_ = 0;
graph_node_count_ = 0;
empty_node_count_ = 0;
from_nodes_.clear();
to_nodes_.clear();
graph_key_.clear();
node_map_.clear();
graph_ = CudaGraph(device_);
CHECK_CUDA_ERROR(cudaGraphDestroy(graph_));
CHECK_CUDA_ERROR(cudaGraphCreate(&graph_, 0));
}
// Put completion handlers in a batch.
worker_.end_batch();
worker_.commit(stream_);
node_count_ = 0;
}
void CommandEncoder::synchronize() {
@@ -372,6 +316,7 @@ void CommandEncoder::synchronize() {
auto p = std::make_shared<std::promise<void>>();
std::future<void> f = p->get_future();
add_completed_handler([p = std::move(p)]() { p->set_value(); });
worker_.end_batch();
commit();
f.wait();
}
@@ -389,4 +334,6 @@ CommandEncoder& get_command_encoder(Stream s) {
return device(s.device).get_command_encoder(s);
}
} // namespace mlx::core::cu
} // namespace cu
} // namespace mlx::core

46
mlx/backend/cuda/device.h
View File

@@ -3,13 +3,11 @@
#pragma once
#include "mlx/array.h"
#include "mlx/backend/cuda/lru_cache.h"
#include "mlx/backend/cuda/worker.h"
#include "mlx/stream.h"
#include <cublasLt.h>
#include <cuda.h>
#include <cudnn.h>
#include <thrust/execution_policy.h>
#include <unordered_map>
@@ -21,9 +19,8 @@ class CommandEncoder {
struct CaptureContext {
CaptureContext(CommandEncoder& enc);
~CaptureContext();
CudaGraph graph;
cudaGraph_t graph;
CommandEncoder& enc;
bool discard{false};
};
struct ConcurrentContext {
ConcurrentContext(CommandEncoder& enc);
@@ -32,6 +29,7 @@ class CommandEncoder {
};
explicit CommandEncoder(Device& d);
~CommandEncoder();
CommandEncoder(const CommandEncoder&) = delete;
CommandEncoder& operator=(const CommandEncoder&) = delete;
@@ -47,49 +45,34 @@ class CommandEncoder {
void set_output_array(const array& arr);
template <typename F, typename... Params>
void add_kernel_node(
F* func,
dim3 grid_dim,
dim3 block_dim,
uint32_t smem_bytes,
Params&&... params) {
void
add_kernel_node(F* func, dim3 grid_dim, dim3 block_dim, Params&&... params) {
constexpr size_t num = sizeof...(Params);
void* ptrs[num];
size_t i = 0;
([&](auto&& p) { ptrs[i++] = static_cast<void*>(&p); }(
std::forward<Params>(params)),
...);
add_kernel_node((void*)func, grid_dim, block_dim, smem_bytes, ptrs);
add_kernel_node((void*)func, grid_dim, block_dim, ptrs);
}
void add_kernel_node(
CUfunction func,
dim3 grid_dim,
dim3 block_dim,
uint32_t smem_bytes,
void** params);
void add_kernel_node(
void* func,
dim3 grid_dim,
dim3 block_dim,
uint32_t smem_bytes,
void** params);
void add_graph_node(cudaGraph_t child);
void
add_kernel_node(void* func, dim3 grid_dim, dim3 block_dim, void** params);
void add_temporary(const array& arr) {
temporaries_.push_back(arr.data_shared_ptr());
}
void add_completed_handler(std::function<void()> task);
int get_num_ops();
void maybe_commit();
void commit();
Device& device() {
return device_;
}
CudaStream& stream() {
return stream_;
}
@@ -98,9 +81,6 @@ class CommandEncoder {
void synchronize();
private:
void add_kernel_node(const cudaKernelNodeParams& params);
void add_kernel_node(const CUDA_KERNEL_NODE_PARAMS& params);
struct GraphNode {
cudaGraphNode_t node;
// K = kernel
@@ -115,7 +95,7 @@ class CommandEncoder {
Device& device_;
CudaStream stream_;
CudaGraph graph_;
cudaGraph_t graph_;
Worker worker_;
char node_count_{0};
char graph_node_count_{0};
@@ -126,7 +106,7 @@ class CommandEncoder {
std::string graph_key_;
std::vector<GraphNode> concurrent_nodes_;
std::vector<std::shared_ptr<array::Data>> temporaries_;
LRUCache<std::string, CudaGraphExec> graph_cache_;
std::unordered_map<std::string, cudaGraphExec_t> graph_cache_;
std::vector<std::uintptr_t> active_deps_;
std::vector<std::uintptr_t> active_outputs_;
std::unordered_map<std::uintptr_t, GraphNode> node_map_;
@@ -140,7 +120,7 @@ class Device {
Device(const Device&) = delete;
Device& operator=(const Device&) = delete;
// Make this device the current cuda device, this method is thread-safe.
// Make this device the current cuda device, required by some cuda calls.
void make_current();
CommandEncoder& get_command_encoder(Stream s);
@@ -157,16 +137,12 @@ class Device {
cublasLtHandle_t lt_handle() const {
return lt_;
}
cudnnHandle_t cudnn_handle() const {
return cudnn_;
}
private:
int device_;
int compute_capability_major_;
int compute_capability_minor_;
cublasLtHandle_t lt_;
cudnnHandle_t cudnn_;
std::unordered_map<int, CommandEncoder> encoders_;
};

15
mlx/backend/cuda/device/arange.cuh Normal file
View File

@@ -0,0 +1,15 @@
// Copyright © 2025 Apple Inc.
namespace mlx::core::cu {
template <typename T>
struct Arange {
const T start;
const T step;
__device__ T operator()(uint32_t i) const {
return start + i * step;
}
};
} // namespace mlx::core::cu

23
mlx/backend/cuda/device/atomic_ops.cuh
View File

@@ -2,7 +2,7 @@
#pragma once
#include "mlx/backend/cuda/device/complex.cuh"
#include "mlx/backend/cuda/device/cucomplex_math.cuh"
#include "mlx/backend/cuda/device/fp16_math.cuh"
#include <cuda/atomic>
@@ -48,16 +48,25 @@ inline __device__ void atomic_add(__half* out, __half val) {
atomicAdd(out, val);
}
inline __device__ void atomic_add(complex64_t* out, complex64_t val) {
atomic_add_general(out, val);
}
inline __device__ void atomic_add(__nv_bfloat16* out, __nv_bfloat16 val) {
#if __CUDA_ARCH__ < 800
inline __device__ void atomic_add(cuComplex* out, cuComplex val) {
#if __CUDA_ARCH__ < 900
atomic_add_general(out, val);
#else
atomicAdd(out, val);
#endif
}
inline __device__ void atomic_add(__nv_bfloat16* out, __nv_bfloat16 val) {
#if __CUDA_ARCH__ < 800
#if CCCL_VERSION >= 2008000
atomic_add_general(out, val);
#else
bool cccl_version_too_old_for_bfloat16_atomic_add = false;
assert(cccl_version_too_old_for_bfloat16_atomic_add);
#endif
#else
atomicAdd(out, val);
#endif
}
} // namespace mlx::core::cu

61
mlx/backend/cuda/device/binary_ops.cuh
View File

@@ -44,7 +44,7 @@ struct Remainder {
} else {
return x % y;
}
} else if constexpr (is_complex_v<T>) {
} else if constexpr (cuda::std::is_same_v<T, cuComplex>) {
return x % y;
} else {
T r = fmod(x, y);
@@ -66,12 +66,14 @@ struct Equal {
struct NaNEqual {
template <typename T>
__device__ bool operator()(T x, T y) {
if constexpr (is_complex_v<T>) {
if constexpr (std::is_same_v<T, cuComplex>) {
return x == y ||
(isnan(x.real()) && isnan(y.real()) && isnan(x.imag()) &&
isnan(y.imag())) ||
(x.real() == y.real() && isnan(x.imag()) && isnan(y.imag())) ||
(isnan(x.real()) && isnan(y.real()) && x.imag() == y.imag());
(isnan(cuCrealf(x)) && isnan(cuCrealf(y)) && isnan(cuCimagf(x)) &&
isnan(cuCimagf(y))) ||
(cuCrealf(x) == cuCrealf(y) && isnan(cuCimagf(x)) &&
isnan(cuCimagf(y))) ||
(isnan(cuCrealf(x)) && isnan(cuCrealf(y)) &&
cuCimagf(x) == cuCimagf(y));
} else {
return x == y || (isnan(x) && isnan(y));
}
@@ -109,17 +111,17 @@ struct LessEqual {
struct LogAddExp {
template <typename T>
__device__ T operator()(T x, T y) {
if constexpr (is_complex_v<T>) {
if (isnan(x.real()) || isnan(x.imag()) || isnan(y.real()) ||
isnan(y.imag())) {
if constexpr (cuda::std::is_same_v<T, cuComplex>) {
if (isnan(cuCrealf(x)) || isnan(cuCimagf(x)) || isnan(cuCrealf(y)) ||
isnan(cuCimagf(y))) {
return {
cuda::std::numeric_limits<float>::quiet_NaN(),
cuda::std::numeric_limits<float>::quiet_NaN()};
}
auto max = x.real() > y.real() ? x : y;
auto min = x.real() < y.real() ? x : y;
auto min_real = min.real();
auto max_real = max.real();
auto max = cuCrealf(x) > cuCrealf(y) ? x : y;
auto min = cuCrealf(x) < cuCrealf(y) ? x : y;
auto min_real = cuCrealf(min);
auto max_real = cuCrealf(max);
if (!isfinite(min_real) && (min_real == max_real)) {
if (min_real < 0) {
return min;
@@ -148,8 +150,8 @@ struct Maximum {
__device__ T operator()(T x, T y) {
if constexpr (cuda::std::is_integral_v<T>) {
return max(x, y);
} else if constexpr (is_complex_v<T>) {
if (isnan(x.real()) || isnan(x.imag())) {
} else if constexpr (cuda::std::is_same_v<T, cuComplex>) {
if (isnan(cuCrealf(x)) || isnan(cuCimagf(x))) {
return x;
}
return x > y ? x : y;
@@ -167,8 +169,8 @@ struct Minimum {
__device__ T operator()(T x, T y) {
if constexpr (cuda::std::is_integral_v<T>) {
return min(x, y);
} else if constexpr (is_complex_v<T>) {
if (isnan(x.real()) || isnan(x.imag())) {
} else if constexpr (cuda::std::is_same_v<T, cuComplex>) {
if (isnan(cuCrealf(x)) || isnan(cuCimagf(x))) {
return x;
}
return x < y ? x : y;
@@ -191,8 +193,8 @@ struct Multiply {
struct NotEqual {
template <typename T>
__device__ bool operator()(T x, T y) {
if constexpr (is_complex_v<T>) {
return x.real() != y.real() || x.imag() != y.imag();
if constexpr (std::is_same_v<T, cuComplex>) {
return cuCrealf(x) != cuCrealf(y) || cuCimagf(x) != cuCimagf(y);
} else {
return x != y;
}
@@ -204,12 +206,6 @@ struct Power {
__device__ T operator()(T base, T exp) {
if constexpr (cuda::std::is_integral_v<T>) {
T res = 1;
// Raising an integer to a negative power is undefined
if constexpr (cuda::std::is_signed_v<T>) {
if (exp < 0) {
return 0;
}
}
while (exp) {
if (exp & 1) {
res *= base;
@@ -218,8 +214,19 @@ struct Power {
base *= base;
}
return res;
} else if constexpr (is_complex_v<T>) {
return pow(base, exp);
} else if constexpr (cuda::std::is_same_v<T, cuComplex>) {
if (base.y == 0 && base.x == 0) {
if (isnan(exp.x) || isnan(exp.y)) {
auto nan = cuda::std::numeric_limits<float>::quiet_NaN();
return make_cuFloatComplex(nan, nan);
}
return make_cuFloatComplex(0.0, 0.0);
}
auto x_theta = atan2f(base.y, base.x);
auto x_ln_r = 0.5 * logf(base.x * base.x + base.y * base.y);
auto mag = expf(exp.x * x_ln_r - exp.y * x_theta);
auto phase = exp.y * x_ln_r + exp.x * x_theta;
return make_cuFloatComplex(mag * cosf(phase), mag * sinf(phase));
} else {
return powf(base, exp);
}

68
mlx/backend/cuda/device/cast_op.cuh
View File

@@ -2,10 +2,10 @@
#pragma once
#include "mlx/backend/cuda/device/complex.cuh"
#include <cuComplex.h>
#include <cuda_bf16.h>
#include <cuda_fp16.h>
#include <thrust/iterator/transform_iterator.h>
namespace mlx::core::cu {
@@ -20,43 +20,50 @@ struct CastOp {
};
// Castings between complex and boolean.
template <typename T>
struct CastOp<complex_t<T>, bool> {
// TODO: Should make a custom complex type.
template <>
struct CastOp<cuComplex, bool> {
static constexpr bool is_castable = true;
__device__ bool operator()(complex_t<T> x) {
return x.real() != 0 && x.imag() != 0;
__device__ bool operator()(cuComplex x) {
return x.x != 0 && x.y != 0;
}
};
template <typename T>
struct CastOp<bool, complex_t<T>> {
template <>
struct CastOp<bool, cuComplex> {
static constexpr bool is_castable = true;
__device__ complex_t<T> operator()(bool x) {
return x ? complex_t<T>{1, 1} : complex_t<T>{0, 0};
__device__ cuComplex operator()(bool x) {
return x ? make_cuFloatComplex(1, 1) : make_cuFloatComplex(0, 0);
}
};
// Converting a complex number to real number discards the imaginary part.
template <typename T, typename DstT>
struct CastOp<complex_t<T>, DstT, cuda::std::enable_if_t<!is_complex_v<DstT>>> {
static constexpr bool is_castable = cuda::std::is_convertible_v<T, DstT>;
template <typename DstT>
struct CastOp<
cuComplex,
DstT,
cuda::std::enable_if_t<!cuda::std::is_same_v<cuComplex, DstT>>> {
static constexpr bool is_castable = cuda::std::is_convertible_v<float, DstT>;
__device__ DstT operator()(complex_t<T> x) {
static_assert(!is_complex_v<DstT>);
return static_cast<DstT>(x.real());
__device__ DstT operator()(cuComplex x) {
static_assert(!cuda::std::is_same_v<cuComplex, DstT>);
return static_cast<DstT>(cuCrealf(x));
}
};
// Allow converting a real number to complex number.
template <typename SrcT, typename T>
struct CastOp<SrcT, complex_t<T>, cuda::std::enable_if_t<!is_complex_v<SrcT>>> {
static constexpr bool is_castable = cuda::std::is_convertible_v<SrcT, T>;
template <typename SrcT>
struct CastOp<
SrcT,
cuComplex,
cuda::std::enable_if_t<!cuda::std::is_same_v<SrcT, cuComplex>>> {
static constexpr bool is_castable = cuda::std::is_convertible_v<SrcT, float>;
__device__ complex_t<T> operator()(SrcT x) {
static_assert(!is_complex_v<SrcT>);
return complex_t<T>{static_cast<T>(x), 0};
__device__ cuComplex operator()(SrcT x) {
static_assert(!cuda::std::is_same_v<SrcT, cuComplex>);
return cuComplex{static_cast<float>(x), 0};
}
};
@@ -81,7 +88,8 @@ struct CastOp<
SrcT,
DstT,
cuda::std::enable_if_t<
!cuda::std::is_convertible_v<SrcT, DstT> && !is_complex_v<SrcT> &&
!cuda::std::is_convertible_v<SrcT, DstT> &&
!cuda::std::is_same_v<SrcT, cuComplex> &&
(cuda::std::is_same_v<DstT, __half> ||
cuda::std::is_same_v<DstT, __nv_bfloat16>)>> {
static constexpr bool is_castable = true;
@@ -96,7 +104,8 @@ struct CastOp<
SrcT,
DstT,
cuda::std::enable_if_t<
!cuda::std::is_convertible_v<SrcT, DstT> && !is_complex_v<SrcT> &&
!cuda::std::is_convertible_v<SrcT, DstT> &&
!cuda::std::is_same_v<DstT, cuComplex> &&
!cuda::std::is_same_v<DstT, __half> &&
!cuda::std::is_same_v<DstT, __nv_bfloat16> &&
(cuda::std::is_same_v<SrcT, __half> ||
@@ -115,4 +124,15 @@ inline __host__ __device__ auto cast_to(SrcT x) {
return CastOp<SrcT, DstT>{}(x);
}
// Return an iterator that cast the value to DstT using CastOp.
template <typename DstT, typename Iterator>
inline __host__ __device__ auto make_cast_iterator(Iterator it) {
using SrcT = typename cuda::std::iterator_traits<Iterator>::value_type;
if constexpr (std::is_same_v<SrcT, DstT>) {
return it;
} else {
return thrust::make_transform_iterator(it, CastOp<SrcT, DstT>{});
}
}
} // namespace mlx::core::cu

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