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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
zhangyiss:v0.30.0 zhangyiss:v0.29.4 zhangyiss:v0.29.3 zhangyiss:v0.29.2 zhangyiss:v0.29.1 zhangyiss:v0.29.0 zhangyiss:v0.28.0 zhangyiss:v0.27.1 zhangyiss:v0.26.5 zhangyiss:v0.26.3 zhangyiss:v0.26.2 zhangyiss:v0.26.1 zhangyiss:v0.26.0 zhangyiss:v0.25.2 zhangyiss:v0.25.1 zhangyiss:v0.25.0 zhangyiss:v0.24.2 zhangyiss:v0.24.1 zhangyiss:v0.24.0 zhangyiss:v0.23.2 zhangyiss:v0.23.1 zhangyiss:v0.23.0 zhangyiss:v0.22.1 zhangyiss:v0.22.0 zhangyiss:v0.21.1 zhangyiss:v0.21.0 zhangyiss:v0.20.0 zhangyiss:v0.19.3 zhangyiss:v0.19.2 zhangyiss:v0.19.1 zhangyiss:v0.19.0 zhangyiss:v0.18.1 zhangyiss:v0.18.0 zhangyiss:v0.17.3 zhangyiss:v0.17.2 zhangyiss:v0.17.1 zhangyiss:v0.17.0 zhangyiss:v0.16.3 zhangyiss:v0.16.2 zhangyiss:v0.16.1 zhangyiss:v0.16.0 zhangyiss:v0.15.2 zhangyiss:v0.15.1 zhangyiss:v0.15.0 zhangyiss:v0.14.1 zhangyiss:v0.14.0 zhangyiss:v0.13.1 zhangyiss:v0.13.0 zhangyiss:v0.12.2 zhangyiss:v0.12.1 zhangyiss:v0.12.0 zhangyiss:v0.11.1 zhangyiss:v0.11.0 zhangyiss:v0.10.0 zhangyiss:v0.9.1 zhangyiss:v0.9.0 zhangyiss:v0.8.1 zhangyiss:v0.8.0 zhangyiss:v0.7.0 zhangyiss:v0.6.0 zhangyiss:v0.5.1 zhangyiss:v0.5.0 zhangyiss:v0.4.0 zhangyiss:v0.3.0 zhangyiss:v0.2.0 zhangyiss:v0.1.0 zhangyiss:v0.0.11 zhangyiss:v0.0.10 zhangyiss:v0.0.9 zhangyiss:v0.0.7 zhangyiss:v0.0.6 zhangyiss:v0.0.5 zhangyiss:v0.0.4 zhangyiss:v0.0.3 zhangyiss:v0.0.2
...
compare: zhangyiss:jagrit06/cuda-gemm-experiment
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
zhangyiss:v0.30.0 zhangyiss:v0.29.4 zhangyiss:v0.29.3 zhangyiss:v0.29.2 zhangyiss:v0.29.1 zhangyiss:v0.29.0 zhangyiss:v0.28.0 zhangyiss:v0.27.1 zhangyiss:v0.26.5 zhangyiss:v0.26.3 zhangyiss:v0.26.2 zhangyiss:v0.26.1 zhangyiss:v0.26.0 zhangyiss:v0.25.2 zhangyiss:v0.25.1 zhangyiss:v0.25.0 zhangyiss:v0.24.2 zhangyiss:v0.24.1 zhangyiss:v0.24.0 zhangyiss:v0.23.2 zhangyiss:v0.23.1 zhangyiss:v0.23.0 zhangyiss:v0.22.1 zhangyiss:v0.22.0 zhangyiss:v0.21.1 zhangyiss:v0.21.0 zhangyiss:v0.20.0 zhangyiss:v0.19.3 zhangyiss:v0.19.2 zhangyiss:v0.19.1 zhangyiss:v0.19.0 zhangyiss:v0.18.1 zhangyiss:v0.18.0 zhangyiss:v0.17.3 zhangyiss:v0.17.2 zhangyiss:v0.17.1 zhangyiss:v0.17.0 zhangyiss:v0.16.3 zhangyiss:v0.16.2 zhangyiss:v0.16.1 zhangyiss:v0.16.0 zhangyiss:v0.15.2 zhangyiss:v0.15.1 zhangyiss:v0.15.0 zhangyiss:v0.14.1 zhangyiss:v0.14.0 zhangyiss:v0.13.1 zhangyiss:v0.13.0 zhangyiss:v0.12.2 zhangyiss:v0.12.1 zhangyiss:v0.12.0 zhangyiss:v0.11.1 zhangyiss:v0.11.0 zhangyiss:v0.10.0 zhangyiss:v0.9.1 zhangyiss:v0.9.0 zhangyiss:v0.8.1 zhangyiss:v0.8.0 zhangyiss:v0.7.0 zhangyiss:v0.6.0 zhangyiss:v0.5.1 zhangyiss:v0.5.0 zhangyiss:v0.4.0 zhangyiss:v0.3.0 zhangyiss:v0.2.0 zhangyiss:v0.1.0 zhangyiss:v0.0.11 zhangyiss:v0.0.10 zhangyiss:v0.0.9 zhangyiss:v0.0.7 zhangyiss:v0.0.6 zhangyiss:v0.0.5 zhangyiss:v0.0.4 zhangyiss:v0.0.3 zhangyiss:v0.0.2

63 Commits
93d70419e7 ... jagrit06/c

Author SHA1 Message Date
Jagrit Digani
400f8457ea Experimenting with a gemm based on the cuda steel utils 2025-08-14 11:27:50 -07:00
Cheng
dfb5022eab Rename cu::Matmul to CublasGemm (#2488) 2025-08-13 09:37:40 +09:00
Daniel Yeh
ac207ce7aa make code blocks copyable (#2480) 
Co-authored-by: Chen-Chen Yeh <ge96noj@mytum.de>
 2025-08-12 12:29:02 -07:00
Abe Leininger
fce53b61d6 Fix reduce sum/prod overflow (#2477) 2025-08-12 00:05:33 -07:00
Angelos Katharopoulos
8ae4a76308 Use CMake <4.1 to avoid the nvpl error (#2489) 2025-08-12 00:03:42 -07:00
Cheng
7fde1b6a1e Fix logsumexp/softmax not fused for some cases (#2474) 2025-08-08 14:07:17 -07:00
Cheng
aa7b47481a [CUDA] Optimize set_mm_device_pointers for small ndim (#2473) 2025-08-08 15:23:30 +09:00
Awni Hannun
56be773610 version (#2470) 2025-08-07 00:36:04 -07:00
Jagrit Digani
a9bdd67baa Add CUDA sdpa vector (#2468) 2025-08-06 21:40:26 -07:00
Angelos Katharopoulos
f2adb5638d Fix typo in metal command encoder (#2471) 2025-08-06 16:58:23 -07:00
Luca Vivona
728d4db582 Support destination arg in tree flatten/unflatten (#2450) 2025-08-06 15:34:59 -07:00
Awni Hannun
db5c7efcf6 revert default cuda install (#2465) 
* revert default cuda install

* revert default cuda install
 2025-08-06 06:19:12 -07:00
Awni Hannun
7bb96e4249 fix cublas on h100 (#2466) 2025-08-06 06:18:58 -07:00
Awni Hannun
fa89f0b150 faster gather qmm sorted test (#2463) 2025-08-05 06:27:40 -07:00
Awni Hannun
ca973d1e83 fix install tags (#2464) 2025-08-04 20:01:23 -07:00
Cheng
828c5f1137 Use SmallVector for shapes and strides (#2454) 
* Use SmallVector for shapes and strides

* Convert SmallVector to tuple
 2025-08-05 09:41:03 +09:00
Gaétan Lepage
7d86a5c108 Feat: add USE_SYSTEM_FMT CMake option (#2219) 2025-08-04 16:36:11 -07:00
Awni Hannun
0b807893a7 fix wraps compile (#2461) 2025-08-04 16:14:18 -07:00
Awni Hannun
6ad0889c8a default install cuda on linux (#2462) 2025-08-04 15:33:05 -07:00
Zamderax
737dd6d1ac Add missing <algorithm> header to jit_compiler.cpp (#2460) 
Fixes compilation error on Linux where std::find_if is used on line 121
but the <algorithm> header was not included. While this might work on
some platforms due to transitive includes, it's not guaranteed by the
C++ standard.

Resolves issue #2459
 2025-08-04 14:00:46 -07:00
Cheng
aaf78f4c6b Use LRU cache for cuda graph (#2448) 
* Use LRU cache for cuda graph

* Remove unused destructor
 2025-08-02 21:28:57 +09:00
Angelos Katharopoulos
8831064493 Fix arctan2 grads (#2453) 2025-08-01 21:06:04 -07:00
Angelos Katharopoulos
be9bc96da4 [CUDA] Matmul utils initial commit (#2441) 2025-08-01 14:22:25 -07:00
Angelos Katharopoulos
86258f292f [CUDA] Vectorize generated kernels (#2444) 2025-07-31 18:18:57 -07:00
Cheng
b26d88591c [CUDA] Save primitive inputs faster (#2449) 
* Add more nvtx loggings

* [CUDA] Saving primitive inputs faster

* Remove unneeded check
 2025-08-01 10:16:06 +09:00
Cheng
86c6a15571 [CUDA] Backward convolution (#2431) 2025-08-01 09:54:05 +09:00
junpeiz
8b25ce62d5 Add tests for export including control flow models and quantized models (#2430) 
* Add tests for export, including control flow export and quantized model export.

* Skip quantization related test for CUDA backend.
 2025-07-31 11:06:26 -07:00
Awni Hannun
da5912e4f2 fix custom metal extension (#2446) 2025-07-31 06:25:36 -07:00
Cheng
daafee676f Fix wrong graph key when using concurrent context (#2447) 2025-07-31 06:01:05 -07:00
Awni Hannun
d32519c8ee fix gemv regression (#2445) 2025-07-30 14:23:01 -07:00
Awni Hannun
b405591249 fix circular reference (#2443) 2025-07-30 09:37:44 -07:00
Angelos Katharopoulos
3bf81ed1bd [CUDA] Quantized refactoring (#2442) 2025-07-30 08:27:20 -07:00
Cheng
2204182bba Make CI faster (#2440) 2025-07-30 02:26:36 -07:00
Cheng
3628e5d497 Use load_vector in arg_reduce (#2439) 2025-07-30 17:40:26 +09:00
Cheng
a0ae49d397 Move arange to its own file (#2438) 2025-07-30 13:05:51 +09:00
Cheng
254476718b Remove the kernel arg from get_launch_args (#2437) 2025-07-30 11:43:02 +09:00
Awni Hannun
3adba92ebe Cuda faster softmax (#2435) 
* faster softmax and logsumexp

* faster softmax and logsumexp

* format
 2025-07-29 17:18:12 -07:00
Awni Hannun
ef631d63af faster rms norm (#2433) 2025-07-29 13:12:00 -07:00
Cheng
970dbe8e25 Use ccache in CI (#2414) 
* Detect ccache

* Use ccache in CI

* Separate cache for different images

* Test both 12.2 and 12.9 for PRs
 2025-07-29 08:43:22 +09:00
Awni Hannun
641be9463b Add more CUDA architectures for PyPi package (#2427) 
* add cuda sm 90

* add more archs
 2025-07-28 12:35:15 -07:00
Awni Hannun
ab0e608862 [CUDA] More sizes for gemv (#2429) 
* route more to gemv

* route more sizes to custom gemv
 2025-07-28 12:35:01 -07:00
Awni Hannun
1588659062 no occupancy query for launch params (#2426) 2025-07-28 09:09:41 -07:00
Awni Hannun
b9e88fb976 [CUDA] Fix segfault on exit (#2424) 
* fix cuda segfault on exit

* comment
 2025-07-27 08:08:13 -07:00
Awni Hannun
4ad53414dd fix cuda pypi package (#2423) 
* fix cuda pypi package

* patch bump
 2025-07-25 15:20:29 -07:00
Awni Hannun
d1165b215e version (#2420) 2025-07-25 13:29:28 -07:00
Awni Hannun
dcb8319f3d update install docs and requirements (#2419) 2025-07-25 12:13:19 -07:00
Awni Hannun
5597fa089c Fix qvm splitk (#2415) 2025-07-25 11:50:24 -07:00
Awni Hannun
9acec364c2 [CUDA] Always use batched matmul (#2404) 
* cuda batched mm

* addmm as well

* comment
 2025-07-24 20:46:02 -07:00
Skonor
7d9d6ef456 docs: fix adam and adamw eps placement (#2416) 
Co-authored-by: Mikhail Gorbunov <m_gorbunov@apple.com>
 2025-07-24 16:40:45 -07:00
Cheng
6f5874a2f2 [CUDA] Initial implementation of Convolution with cuDNN (#2385) 
* Link with cuDNN

* Initial implementation

* Remove backend apis

* Fix recording cudnn conv

* More unused backend apis

* Fix C++ conv tests

* include cudnn as python dep

* Install libcudnn9-dev-cuda-12 in CI

* cudnn only accepts contiguous inputs

* Switch to backend apis

* Plan needs to be kept alive

* Turn off tf32

* Add cache

* Test the native cuda graph api

* Set cudnn stream before execution

* Make LRUCache more like a normal container

* Do error check for cublas handle

* Zero-initilizing array

* Use tf32 for conv

* Skip TestConv.test_torch_conv_2D test

---------

Co-authored-by: Awni Hannun <awni@apple.com>
 2025-07-25 08:12:10 +09:00
Awni Hannun
70dc336785 Test on cuda 12.2 and 12.9 (#2413) 2025-07-24 06:06:15 -07:00
Awni Hannun
4e504039f5 [Metal] Release metal events (#2412) 
* release metal events

* fix

* fix
 2025-07-23 19:53:42 -07:00
Awni Hannun
d1f4d291e8 Fix uv install and add dev release (#2411) 
* fix uv install and add dev release

* fix docstring

* pin cuda deps

* cuda release on cpu-only machine
 2025-07-23 16:54:19 -07:00
Awni Hannun
e1840853ce full row mask in sdpa consistently gives nan (#2406) 2025-07-23 16:37:03 -07:00
Cheng
0f5ce173da [CUDA] --compress-mode requires CUDA 12.8 (#2407) 2025-07-23 06:11:11 -07:00
Cheng
588854195f Remove unused code in Convolution::vjp (#2408) 2025-07-23 06:11:00 -07:00
Fangjun Kuang
28d068bce6 Fix an error in the comment for mx.dequantize (#2409) 2025-07-23 06:10:50 -07:00
Awni Hannun
d107d8d495 add cuda gemv (#2400) 2025-07-22 08:24:13 -07:00
Awni Hannun
1e496ddb82 [CUDA] Simplify allocator (#2392) 
* simplify allocator and fixe race with small pool

* Don't use shared event in worker

* use cuda buffer in small pool

* comment

* comment
 2025-07-22 08:24:01 -07:00
Awni Hannun
74eccbf3fa use size option in binary (#2399) 2025-07-22 07:00:53 -07:00
Awni Hannun
08638223ca Fix including stubs in wheel (#2398) 
* fix including stubs in wheel

* fix bool_
 2025-07-22 06:30:17 -07:00
Cheng
56cc858af9 Add contiguous_copy_cpu util for copying array (#2397) 2025-07-21 07:30:35 -07:00
Cheng
f55c4ed1d6 Remove thrust iterators (#2396) 2025-07-21 07:30:27 -07:00
145 changed files with 6360 additions and 1802 deletions
Expand all files Collapse all files

217
.circleci/config.yml
View File

@@ -7,6 +7,9 @@ parameters:
nightly_build:
type: boolean
default: false
test_release:
type: boolean
default: false
jobs:
build_documentation:
@@ -78,23 +81,24 @@ jobs:
export DEBIAN_FRONTEND=noninteractive
export NEEDRESTART_MODE=a
sudo apt-get update
sudo apt-get upgrade -y
pip install --upgrade cmake
sudo apt-get install -y 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: |
pip install -e ".[dev]"
uv venv
uv pip install cmake
uv pip install -e ".[dev]" -v
- run:
name: Generate package stubs
command: |
echo "stubs"
pip install typing_extensions
python setup.py generate_stubs
uv pip install typing_extensions
uv run --no-project setup.py generate_stubs
- run:
name: Run Python tests
command: |
source .venv/bin/activate
python -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)
@@ -102,6 +106,7 @@ jobs:
- 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`
@@ -127,33 +132,30 @@ jobs:
- run:
name: Install dependencies
command: |
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
HOMEBREW_NO_AUTO_UPDATE=1 HOMEBREW_NO_INSTALL_CLEANUP=1 \
brew install openmpi uv
- run:
name: Install Python package
command: |
source env/bin/activate
uv venv --python 3.9
uv pip install \
nanobind==2.4.0 \
cmake \
numpy \
torch \
tensorflow \
unittest-xml-reporting
DEBUG=1 CMAKE_ARGS="-DCMAKE_COMPILE_WARNING_AS_ERROR=ON" \
pip install -e . -v
uv pip install -e . -v
- run:
name: Generate package stubs
command: |
source env/bin/activate
pip install typing_extensions
python setup.py generate_stubs
uv pip install typing_extensions
uv run --no-project setup.py generate_stubs
- run:
name: Run Python tests
command: |
source env/bin/activate
source .venv/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
@@ -162,16 +164,17 @@ jobs:
- run:
name: Build example extension
command: |
source env/bin/activate
source .venv/bin/activate
cd examples/extensions
pip install -r requirements.txt
python setup.py build_ext -j8
uv pip install -r requirements.txt
uv run --no-project setup.py build_ext --inplace
uv run --no-project python test.py
- store_test_results:
path: test-results
- run:
name: Build CPP only
command: |
source env/bin/activate
source .venv/bin/activate
mkdir -p build && cd build && cmake .. && make -j `sysctl -n hw.ncpu`
- run:
name: Run CPP tests
@@ -180,7 +183,7 @@ jobs:
- run:
name: Build small binary
command: |
source env/bin/activate
source .venv/bin/activate
cd build/
cmake .. -DCMAKE_BUILD_TYPE=MinSizeRel \
-DBUILD_SHARED_LIBS=ON \
@@ -192,34 +195,60 @@ jobs:
- run:
name: Run Python tests with JIT
command: |
source env/bin/activate
CMAKE_ARGS="-DMLX_METAL_JIT=ON" \
pip install -e . -v
uv pip install -e .
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_jit
uv run --no-project 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-12:2023.11.1
image: "linux-cuda-12:<< parameters.image_date >>"
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
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: Install Python package
command: |
sudo apt-get update
sudo apt-get install libblas-dev liblapack-dev liblapacke-dev
python3 -m venv env
source env/bin/activate
uv venv
CMAKE_ARGS="-DMLX_BUILD_CUDA=ON -DCMAKE_CUDA_COMPILER=`which nvcc`" \
pip install -e ".[dev]"
uv pip install -e ".[dev]" -v
- run:
name: Run Python tests
command: |
source env/bin/activate
source .venv/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: CCache report
command: |
ccache --show-stats
ccache --zero-stats
ccache --max-size 400MB
ccache --cleanup
- save_cache:
key: cuda-<< parameters.image_date >>-{{ arch }}-{{ epoch }}
paths:
- /home/circleci/.cache/ccache
build_release:
parameters:
@@ -315,14 +344,10 @@ jobs:
export DEBIAN_FRONTEND=noninteractive
export NEEDRESTART_MODE=a
sudo apt-get update
sudo apt-get upgrade -y
TZ=Etc/UTC sudo apt-get -y install tzdata
sudo apt-get install -y apt-utils
sudo apt-get install -y software-properties-common
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
sudo apt-get install -y build-essential git
$PYTHON -m venv env
source env/bin/activate
pip install --upgrade pip
@@ -366,22 +391,27 @@ jobs:
type: string
default: ""
machine:
image: linux-cuda-12:2024.11.1
resource_class: gpu.nvidia.small.gen2
image: ubuntu-2204:current
resource_class: large
steps:
- checkout
- run:
name: Build wheel
command: |
export DEBIAN_FRONTEND=noninteractive
export NEEDRESTART_MODE=a
wget https://developer.download.nvidia.com/compute/cuda/repos/ubuntu2404/x86_64/cuda-keyring_1.1-1_all.deb
sudo dpkg -i cuda-keyring_1.1-1_all.deb
sudo apt-get update
sudo apt-get install cuda-toolkit-12-9 libcudnn9-dev-cuda-12
sudo apt-get install libblas-dev liblapack-dev liblapacke-dev
sudo apt-get install zip
python -m venv env
source env/bin/activate
pip install auditwheel
pip install patchelf
pip install build
pip install twine
export PATH=/usr/local/cuda/bin${PATH:+:${PATH}}
export LD_LIBRARY_PATH=/usr/local/cuda/lib64${LD_LIBRARY_PATH:+:${LD_LIBRARY_PATH}}
<< parameters.build_env >> MLX_BUILD_STAGE=2 \
CMAKE_ARGS="-DMLX_BUILD_CUDA=ON -DCMAKE_CUDA_COMPILER=`which nvcc`" \
python -m build -w
@@ -392,7 +422,6 @@ jobs:
- run:
name: Upload package
command: |
source env/bin/activate
twine upload wheelhouse/*.whl
- store_artifacts:
path: wheelhouse/
@@ -405,19 +434,24 @@ workflows:
pattern: "^(?!pull/)[-\\w]+$"
value: << pipeline.git.branch >>
- not: << pipeline.parameters.nightly_build >>
- not: << pipeline.parameters.test_release >>
jobs:
- mac_build_and_test:
matrix:
parameters:
macosx_deployment_target: ["13.5", "14.0"]
- linux_build_and_test
- cuda_build_and_test
- cuda_build_and_test:
matrix:
parameters:
image_date: ["2023.11.1", "2025.05.1"]
- build_documentation
build_pypi_release:
when:
and:
- not: << pipeline.parameters.nightly_build >>
- not: << pipeline.parameters.test_release >>
jobs:
- build_release:
filters:
@@ -538,6 +572,9 @@ workflows:
requires: [ hold ]
- cuda_build_and_test:
requires: [ hold ]
matrix:
parameters:
image_date: ["2023.11.1", "2025.05.1"]
nightly_build:
when:
and:
@@ -601,3 +638,87 @@ workflows:
parameters:
python_version: ["3.9", "3.10", "3.11", "3.12", "3.13"]
- build_cuda_release
build_dev_release:
when:
and:
- equal: [ main, << pipeline.git.branch >> ]
- << pipeline.parameters.test_release >>
jobs:
- build_release:
matrix:
parameters:
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: ["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"
- build_linux_release:
matrix:
parameters:
python_version: ["3.9", "3.10", "3.11", "3.12", "3.13"]
build_env: ["DEV_RELEASE=1"]
- build_cuda_release:
matrix:
parameters:
build_env: ["DEV_RELEASE=1"]

15
CMakeLists.txt
View File

@@ -41,7 +41,9 @@ 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(
@@ -68,6 +70,15 @@ 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()
endif()
# ----------------------------- Lib -----------------------------
include(FetchContent)
@@ -232,12 +243,16 @@ 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(
fmt
GIT_REPOSITORY https://github.com/fmtlib/fmt.git
GIT_TAG 10.2.1
EXCLUDE_FROM_ALL)
FetchContent_MakeAvailable(fmt)
endif()
target_link_libraries(mlx PRIVATE $<BUILD_INTERFACE:fmt::fmt-header-only>)
if(MLX_BUILD_PYTHON_BINDINGS)

17
README.md
View File

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

1
docs/requirements.txt
View File

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

1
docs/src/conf.py
View File

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

8
docs/src/dev/extensions.rst
View File

@@ -394,14 +394,14 @@ below.
out.set_data(allocator::malloc(out.nbytes()));
// Resolve name of kernel
std::ostringstream kname;
kname << "axpby_" << "general_" << type_to_name(out);
std::stream kname;
kname = "axpby_general_" + type_to_name(out);
// Load the metal library
auto lib = d.get_library("mlx_ext");
auto lib = d.get_library("mlx_ext", current_binary_dir());
// Make a kernel from this metal library
auto kernel = d.get_kernel(kname.str(), lib);
auto kernel = d.get_kernel(kname, lib);
// Prepare to encode kernel
auto& compute_encoder = d.get_command_encoder(s.index);

26
docs/src/install.rst
View File

@@ -13,7 +13,7 @@ silicon computer is
pip install mlx
To install from PyPI you must meet the following requirements:
To install from PyPI your system must meet the following requirements:
- Using an M series chip (Apple silicon)
- Using a native Python >= 3.9
@@ -26,12 +26,21 @@ To install from PyPI you must meet the following requirements:
CUDA
^^^^
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:
MLX has a CUDA backend which you can install with:
.. code-block:: shell
pip install "mlx[cuda]"
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)
^^^^^^^^^^^^^^^^
@@ -40,7 +49,14 @@ For a CPU-only version of MLX that runs on Linux use:
.. code-block:: shell
pip install "mlx[cpu]"
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
Troubleshooting
^^^^^^^^^^^^^^^

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)
mx.save_safetensors("optimizer.safetensors", dict(state))
state = tree_flatten(optimizer.state, destination={})
mx.save_safetensors("optimizer.safetensors", 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(list(mx.load("optimizer.safetensors").items()))
state = tree_unflatten(mx.load("optimizer.safetensors"))
optimizer.state = state
Note, not every optimizer configuation parameter is saved in the state. For

2
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 = dict(tree_flatten(model.parameters()))
params = tree_flatten(model.parameters(), destination={})
mx.export_function("model.mlxfn", call, (mx.zeros(4),), params)

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

@@ -1,5 +1,6 @@
// Copyright © 2023-2025 Apple Inc.
#include <dlfcn.h>
#include <iostream>
#include <sstream>
@@ -16,6 +17,19 @@
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
///////////////////////////////////////////////////////////////////////////////
@@ -167,16 +181,15 @@ void Axpby::eval_gpu(
}
// Resolve name of kernel (corresponds to axpby.metal)
std::ostringstream kname;
kname << "axpby_";
kname << (contiguous_kernel ? "contiguous_" : "general_");
kname << type_to_name(out);
std::string kname = "axpby_";
kname += (contiguous_kernel ? "contiguous_" : "general_");
kname += type_to_name(out);
// Load the metal library
auto lib = d.get_library("mlx_ext");
auto lib = d.get_library("mlx_ext", current_binary_dir());
// Make a kernel from this metal library
auto kernel = d.get_kernel(kname.str(), lib);
auto kernel = d.get_kernel(kname, lib);
// Prepare to encode kernel
auto& compute_encoder = d.get_command_encoder(s.index);

2
examples/extensions/requirements.txt
View File

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

10
examples/extensions/test.py
View File

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

5
mlx/array.h
View File

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

27
mlx/backend/common/utils.cpp
View File

@@ -228,4 +228,31 @@ std::pair<Dims, Dims> get_grid_and_block_common(int dim0, int dim1, int dim2) {
std::make_tuple(gx, gy, gz), std::make_tuple(bx, by, bz));
}
array swapaxes_in_eval(const array& x, int axis1, int axis2) {
int ndim = x.ndim();
if (axis1 < 0) {
axis1 += ndim;
}
if (axis2 < 0) {
axis2 += ndim;
}
auto shape = x.shape();
std::swap(shape[axis1], shape[axis2]);
auto strides = x.strides();
std::swap(strides[axis1], strides[axis2]);
auto [data_size, row_contiguous, col_contiguous] =
check_contiguity(shape, strides);
bool contiguous = data_size == x.data_size();
array out(std::move(shape), x.dtype(), nullptr, {});
out.copy_shared_buffer(
x,
std::move(strides),
{contiguous, row_contiguous, col_contiguous},
x.data_size());
return out;
}
} // namespace mlx::core

5
mlx/backend/common/utils.h
View File

@@ -196,8 +196,11 @@ void shared_buffer_reshape(
const Strides& out_strides,
array& out);
// Like the swapaxes op but safe to call in eval_gpu.
array swapaxes_in_eval(const array& x, int axis1, int axis2);
template <typename T>
inline std::vector<T> remove_index(std::vector<T> vec, size_t index) {
inline SmallVector<T> remove_index(SmallVector<T> vec, size_t index) {
vec.erase(std::next(vec.begin(), index));
return vec;
}

8
mlx/backend/cpu/compiled.cpp
View File

@@ -288,6 +288,14 @@ void Compiled::eval_cpu(
auto [contiguous, shape, strides] =
compiled_collapse_contiguous_dims(inputs, outputs[0], is_constant_);
// Force allocating shape/strides on heap so we can take their data() first
// and then std::move them.
// TODO: Refactor code to avoid heap allocation.
shape.grow();
for (auto& s : strides) {
s.grow();
}
// Collect function input arguments.
std::vector<void*> args;
int strides_index = 1;

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

@@ -377,4 +377,10 @@ 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

3
mlx/backend/cpu/copy.h
View File

@@ -30,4 +30,7 @@ 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

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

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

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

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

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

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

@@ -136,9 +136,8 @@ void BlockMaskedMM::eval_cpu(const std::vector<array>& inputs, array& out) {
}
return std::make_tuple(true, sty, arr, false);
} else {
array arr_copy(arr.shape(), arr.dtype(), nullptr, {});
copy_cpu(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);
}
};

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

@@ -712,9 +712,7 @@ void fast::AffineQuantize::eval_cpu(
if (arr.flags().row_contiguous) {
return std::make_pair(arr, false);
} else {
array arr_copy(arr.shape(), arr.dtype(), nullptr, {});
copy_cpu(arr, arr_copy, CopyType::General, s);
return std::make_pair(arr_copy, true);
return std::make_pair(contiguous_copy_cpu(arr, s), true);
}
};

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

@@ -491,19 +491,27 @@ 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

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

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

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

45
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 {
@@ -333,46 +333,23 @@ 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 ctype = (in.flags().contiguous && in.strides()[axis] != 0)
? CopyType::Vector
: CopyType::General;
copy_cpu(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_ = 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_);
}
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);
});
});
}

53
mlx/backend/cuda/CMakeLists.txt
View File

@@ -6,6 +6,7 @@
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
@@ -15,18 +16,22 @@ 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}/cuda.cpp
${CMAKE_CURRENT_SOURCE_DIR}/device.cpp
${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}/gemms/steel_gemm.cu
${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.cu
${CMAKE_CURRENT_SOURCE_DIR}/primitives.cpp
${CMAKE_CURRENT_SOURCE_DIR}/random.cu
${CMAKE_CURRENT_SOURCE_DIR}/reduce.cu
${CMAKE_CURRENT_SOURCE_DIR}/reduce/all_reduce.cu
@@ -35,6 +40,7 @@ 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
@@ -42,9 +48,18 @@ target_sources(
${CMAKE_CURRENT_SOURCE_DIR}/ternary.cu
${CMAKE_CURRENT_SOURCE_DIR}/unary.cu
${CMAKE_CURRENT_SOURCE_DIR}/utils.cpp
${CMAKE_CURRENT_SOURCE_DIR}/quantized.cu
${CMAKE_CURRENT_SOURCE_DIR}/quantized/affine_quantize.cu
${CMAKE_CURRENT_SOURCE_DIR}/quantized/quantized.cpp
${CMAKE_CURRENT_SOURCE_DIR}/worker.cpp)
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 ${CMAKE_CURRENT_SOURCE_DIR}/gemms/cublas_gemm_batched_12_0.cpp)
endif()
target_compile_definitions(mlx PRIVATE MLX_USE_CUDA)
# Embed kernel sources in binary for JIT compilation.
@@ -87,11 +102,18 @@ endif()
target_compile_options(
mlx PRIVATE "$<$<COMPILE_LANGUAGE:CUDA>:--Wno-deprecated-gpu-targets>")
# Compute capability 7 is required for synchronization between CPU/GPU with
# managed memory. TODO: Add more architectures for potential performance gain.
set(MLX_CUDA_ARCHITECTURES
"70;80"
CACHE STRING "CUDA architectures")
# Use stronger binaries compression. This feature was introduced in CUDA 12.8
# and requires drivers released after CUDA 12.4.
if(CMAKE_CUDA_COMPILER_VERSION VERSION_GREATER_EQUAL 12.8.0)
target_compile_options(
mlx PRIVATE "$<$<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()
message(STATUS "CUDA architectures: ${MLX_CUDA_ARCHITECTURES}")
set_target_properties(mlx PROPERTIES CUDA_ARCHITECTURES
"${MLX_CUDA_ARCHITECTURES}")
@@ -123,6 +145,23 @@ 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 v1.12.1
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>)

95
mlx/backend/cuda/allocator.cpp
View File

@@ -2,7 +2,6 @@
#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>
@@ -25,52 +24,58 @@ constexpr int small_block_size = 8;
constexpr int small_pool_size = 4 * page_size;
SmallSizePool::SmallSizePool() {
CHECK_CUDA_ERROR(cudaMallocManaged(&buffer_, small_pool_size));
end_ = reinterpret_cast<void*>(
reinterpret_cast<char*>(buffer_) + small_pool_size);
next_free_ = reinterpret_cast<Block*>(buffer_);
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));
CHECK_CUDA_ERROR(
cudaMemAdvise(data_, small_pool_size, cudaMemAdviseSetReadMostly, 0));
auto curr = next_free_;
for (size_t i = 0; i < num_blocks - 1; ++i) {
curr->next = reinterpret_cast<Block*>(
reinterpret_cast<char*>(buffer_) + (i + 1) * small_block_size);
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(buffer_));
CHECK_CUDA_ERROR(cudaFree(data_));
delete[] buffer_;
}
void* SmallSizePool::malloc() {
CudaBuffer* SmallSizePool::malloc() {
if (next_free_ == nullptr) {
return nullptr;
}
Block* b = next_free_;
uint64_t i = next_free_ - buffer_;
next_free_ = next_free_->next;
return static_cast<void*>(b);
b->buf.data = static_cast<char*>(data_) + i * small_block_size;
b->buf.size = small_block_size;
return &b->buf;
}
void SmallSizePool::free(void* p) {
auto b = static_cast<Block*>(p);
void SmallSizePool::free(CudaBuffer* buf) {
auto b = reinterpret_cast<Block*>(buf);
b->next = next_free_;
next_free_ = b;
}
bool SmallSizePool::in_pool(void* p) {
return (p >= buffer_) && (p < end_);
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->data);
delete buf;
}) {
[this](CudaBuffer* buf) { cuda_free(buf); }) {
// TODO: Set memory limit for multi-device.
size_t free, total;
CHECK_CUDA_ERROR(cudaMemGetInfo(&free, &total));
@@ -92,28 +97,26 @@ Buffer CudaAllocator::malloc(size_t size) {
CudaBuffer* buf = buffer_cache_.reuse_from_cache(size);
if (!buf) {
// 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_);
// 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);
}
lock.unlock();
buf = new CudaBuffer{nullptr, size};
// Try the scalar pool first
if (size <= small_block_size) {
buf->data = scalar_pool_.malloc();
buf = scalar_pool_.malloc();
}
if (!buf->data) {
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;
@@ -123,7 +126,6 @@ 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};
}
@@ -138,9 +140,7 @@ void CudaAllocator::free(Buffer buffer) {
if (get_cache_memory() < max_pool_size_) {
buffer_cache_.recycle_to_cache(buf);
} else {
lock.unlock();
cuda_free(buf->data);
delete buf;
cuda_free(buf);
}
}
@@ -152,30 +152,13 @@ size_t CudaAllocator::size(Buffer buffer) const {
return buf->size;
}
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;
}
}
// 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);
cudaFree(buf->data);
delete buf;
}
}

31
mlx/backend/cuda/allocator.h
View File

@@ -7,13 +7,10 @@
#include <mutex>
#include <set>
#include <thread>
#include <utility>
namespace mlx::core::cu {
class Worker;
using allocator::Buffer;
// Stores cuda-managed unified memory.
@@ -24,13 +21,14 @@ struct CudaBuffer {
class SmallSizePool {
private:
struct Block {
union Block {
Block* next;
CudaBuffer buf;
};
void* buffer_{nullptr};
Block* buffer_{nullptr};
void* data_{nullptr};
Block* next_free_{nullptr};
void* end_{nullptr};
public:
SmallSizePool();
@@ -39,9 +37,9 @@ class SmallSizePool {
SmallSizePool(const SmallSizePool&) = delete;
SmallSizePool& operator=(const SmallSizePool&) = delete;
void* malloc();
void free(void* p);
bool in_pool(void* p);
CudaBuffer* malloc();
void free(CudaBuffer* buf);
bool in_pool(CudaBuffer* buf);
};
class CudaAllocator : public allocator::Allocator {
@@ -50,15 +48,6 @@ class CudaAllocator : public allocator::Allocator {
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();
@@ -69,13 +58,11 @@ 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_;

55
mlx/backend/cuda/arange.cu Normal file
View File

@@ -0,0 +1,55 @@
// 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 <nvtx3/nvtx3.hpp>
#include <thrust/device_ptr.h>
#include <thrust/transform.h>
namespace mlx::core {
namespace cu {
template <typename T>
struct Arange {
const T start;
const T step;
__device__ T operator()(uint32_t i) const {
return start + i * step;
}
};
} // 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);
auto capture = encoder.capture_context();
dispatch_int_float_types(out.dtype(), "Arange", [&](auto type_tag) {
using CTYPE = MLX_GET_TYPE(type_tag);
using OutType = cuda_type_t<CTYPE>;
CTYPE step =
static_cast<CTYPE>(start_ + step_) - static_cast<CTYPE>(start_);
thrust::transform(
cu::thrust_policy(encoder.stream()),
thrust::counting_iterator<uint32_t>(0),
thrust::counting_iterator<uint32_t>(out.data_size()),
thrust::device_pointer_cast(out.data<OutType>()),
cu::Arange<OutType>{
static_cast<OutType>(start_), static_cast<OutType>(step)});
});
}
} // 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"
@@ -44,8 +44,11 @@ struct ArgMin {
}
template <int N>
__device__ IndexValPair<T>
reduce_many(IndexValPair<T> best, T (&vals)[N], uint32_t offset) {
__device__ IndexValPair<T> reduce_many(
IndexValPair<T> best,
const AlignedVector<T, N>& vals,
uint32_t offset) {
#pragma unroll
for (int i = 0; i < N; i++) {
if (vals[i] < best.val) {
best.val = vals[i];
@@ -74,8 +77,11 @@ struct ArgMax {
}
template <int N>
__device__ IndexValPair<T>
reduce_many(IndexValPair<T> best, T (&vals)[N], uint32_t offset) {
__device__ IndexValPair<T> reduce_many(
IndexValPair<T> best,
const AlignedVector<T, N>& vals,
uint32_t offset) {
#pragma unroll
for (int i = 0; i < N; i++) {
if (vals[i] > best.val) {
best.val = vals[i];
@@ -106,16 +112,15 @@ __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;
cub::LoadDirectBlocked(
tid, strided_iterator(in + in_idx, axis_stride), vals, axis_size, init);
auto vals = load_vector<N_READS>(in, tid, axis_size, axis_stride, init);
best = op.reduce_many(best, vals, tid * N_READS);
}
@@ -166,6 +171,7 @@ 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(),

40
mlx/backend/cuda/binary.cu
View File

@@ -28,7 +28,7 @@ __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.val[i] = Op{}(a[0], b[0]);
out_vec[i] = Op{}(a[0], b[0]);
}
store_vector<N_READS>(out, index, out_vec);
@@ -49,7 +49,7 @@ __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.val[i] = Op{}(a[0], b_vec.val[i]);
out_vec[i] = Op{}(a[0], b_vec[i]);
}
store_vector<N_READS>(out, index, out_vec);
@@ -70,7 +70,7 @@ __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.val[i] = Op{}(a_vec.val[i], b[0]);
out_vec[i] = Op{}(a_vec[i], b[0]);
}
store_vector<N_READS>(out, index, out_vec);
@@ -92,7 +92,7 @@ __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.val[i] = Op{}(a_vec.val[i], b_vec.val[i]);
out_vec[i] = Op{}(a_vec[i], b_vec[i]);
}
store_vector<N_READS>(out, index, out_vec);
@@ -128,7 +128,7 @@ __global__ void binary_g(
int ndim) {
IdxT index = cg::this_grid().thread_rank();
if (index < size) {
auto [a_idx, b_idx] = elem_to_loc_4d(
auto [a_idx, b_idx] = elem_to_loc(
index, shape.data(), a_strides.data(), b_strides.data(), ndim);
out[index] = Op{}(a[a_idx], b[b_idx]);
}
@@ -211,14 +211,18 @@ void binary_op_gpu_inplace(
int ndim = shape.size();
if (ndim <= 3) {
dispatch_1_2_3(ndim, [&](auto dims_constant) {
auto kernel = cu::
binary_g_nd<Op, InType, OutType, IdxT, dims_constant()>;
auto [num_blocks, block_dims] =
get_launch_args(kernel, out, large());
get_launch_args(out, large());
encoder.add_kernel_node(
kernel,
cu::binary_g_nd<
Op,
InType,
OutType,
IdxT,
dims_constant()>,
num_blocks,
block_dims,
0,
a.data<InType>(),
b.data<InType>(),
out.data<OutType>(),
@@ -228,13 +232,12 @@ void binary_op_gpu_inplace(
const_param<dims_constant()>(b_strides));
});
} else {
auto kernel = cu::binary_g<Op, InType, OutType, IdxT>;
auto [num_blocks, block_dims] =
get_launch_args(kernel, out, large());
auto [num_blocks, block_dims] = get_launch_args(out, large());
encoder.add_kernel_node(
kernel,
cu::binary_g<Op, InType, OutType, IdxT>,
num_blocks,
block_dims,
0,
a.data<InType>(),
b.data<InType>(),
out.data<OutType>(),
@@ -248,8 +251,7 @@ 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>;
// TODO: Choose optimized value based on type size.
constexpr int N_READS = 4;
constexpr int N_READS = 16 / sizeof(InType);
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>;
@@ -259,16 +261,12 @@ void binary_op_gpu_inplace(
kernel = cu::binary_vv<Op, InType, OutType, IdxT, N_READS>;
}
auto [num_blocks, block_dims] = get_launch_args(
kernel,
out.data_size(),
out.shape(),
out.strides(),
large(),
N_READS);
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>(),

47
mlx/backend/cuda/binary_two.cu
View File

@@ -33,8 +33,8 @@ 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.val[i] = out[0];
out_b_vec.val[i] = out[1];
out_a_vec[i] = out[0];
out_b_vec[i] = out[1];
}
store_vector<N_READS>(out_a, index, out_a_vec);
@@ -60,9 +60,9 @@ 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.val[i]);
out_a_vec.val[i] = out[0];
out_b_vec.val[i] = out[1];
auto out = Op{}(a[0], b_vec[i]);
out_a_vec[i] = out[0];
out_b_vec[i] = out[1];
}
store_vector<N_READS>(out_a, index, out_a_vec);
@@ -88,9 +88,9 @@ 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.val[i], b[0]);
out_a_vec.val[i] = out[0];
out_b_vec.val[i] = out[1];
auto out = Op{}(a_vec[i], b[0]);
out_a_vec[i] = out[0];
out_b_vec[i] = out[1];
}
store_vector<N_READS>(out_a, index, out_a_vec);
@@ -117,9 +117,9 @@ 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.val[i], b_vec.val[i]);
out_a_vec.val[i] = out[0];
out_b_vec.val[i] = out[1];
auto out = Op{}(a_vec[i], b_vec[i]);
out_a_vec[i] = out[0];
out_b_vec[i] = out[1];
}
store_vector<N_READS>(out_a, index, out_a_vec);
@@ -160,7 +160,7 @@ __global__ void binary_two_g(
int ndim) {
IdxT index = cg::this_grid().thread_rank();
if (index < size) {
auto [a_idx, b_idx] = elem_to_loc_4d(
auto [a_idx, b_idx] = elem_to_loc(
index, shape.data(), a_strides.data(), b_strides.data(), ndim);
auto out = Op{}(a[a_idx], b[b_idx]);
out_a[index] = out[0];
@@ -227,18 +227,18 @@ void binary_two_op_gpu_inplace(
int ndim = shape.size();
if (ndim <= 3) {
dispatch_1_2_3(ndim, [&](auto dims_constant) {
auto kernel = cu::binary_two_g_nd<
auto [num_blocks, block_dims] =
get_launch_args(out_a, large());
encoder.add_kernel_node(
cu::binary_two_g_nd<
Op,
InType,
OutType,
IdxT,
dims_constant()>;
auto [num_blocks, block_dims] =
get_launch_args(kernel, out_a, large());
encoder.add_kernel_node(
kernel,
dims_constant()>,
num_blocks,
block_dims,
0,
a.data<InType>(),
b.data<InType>(),
out_a.data<OutType>(),
@@ -249,13 +249,13 @@ void binary_two_op_gpu_inplace(
const_param<dims_constant()>(b_strides));
});
} else {
auto kernel = cu::binary_two_g<Op, InType, OutType, IdxT>;
auto [num_blocks, block_dims] =
get_launch_args(kernel, out_a, large());
get_launch_args(out_a, large());
encoder.add_kernel_node(
kernel,
cu::binary_two_g<Op, InType, OutType, IdxT>,
num_blocks,
block_dims,
0,
a.data<InType>(),
b.data<InType>(),
out_a.data<OutType>(),
@@ -270,8 +270,7 @@ 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>;
// TODO: Choose optimized value based on type size.
constexpr int N_READS = 4;
constexpr int N_READS = 16 / sizeof(InType);
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>;
@@ -281,7 +280,6 @@ 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(),
@@ -291,6 +289,7 @@ void binary_two_op_gpu_inplace(
kernel,
num_blocks,
block_dims,
0,
a.data<InType>(),
b.data<InType>(),
out_a.data<OutType>(),

75
mlx/backend/cuda/compiled.cpp
View File

@@ -104,10 +104,41 @@ struct FusedKernelBuilder {
" }\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) {
@@ -122,7 +153,7 @@ struct FusedKernelBuilder {
} else if (is_scalar(x)) {
value = fmt::format("{}[0]", xname);
} else if (contiguous) {
value = fmt::format("{}[index]", xname);
value = fmt::format("vec_{}[i]", xname);
} else {
value = fmt::format("{}[{}_idx]", xname, xname);
}
@@ -150,25 +181,30 @@ struct FusedKernelBuilder {
// Write output.
for (const auto& x : outputs) {
os += fmt::format(" {0}[index] = tmp_{0};\n", namer.get_name(x));
os += fmt::format(" vec_{0}[i] = tmp_{0};\n", namer.get_name(x));
}
// End of work loop
os +=
"\n"
" index++;\n";
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 += " " + xname + "_idx += " + xname + "_strides[NDIM - 1];\n";
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 += "}\n";
}
};
@@ -192,6 +228,15 @@ 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{
@@ -205,7 +250,6 @@ void Compiled::eval_gpu(
builder.os += "\n} // namespace mlx::core::cu\n";
// Build kernel names.
std::vector<std::string> kernel_names;
for (auto work_per_thread : std::array<int, 2>{1, 4}) {
kernel_names.push_back(fmt::format(
"mlx::core::cu::{}_contiguous<uint32_t, {}>",
lib_name(),
@@ -214,19 +258,15 @@ void Compiled::eval_gpu(
"mlx::core::cu::{}_contiguous<int64_t, {}>",
lib_name(),
work_per_thread));
for (auto wpt : std::array<int, 2>{1, work_per_thread}) {
for (int i = 1; i <= MAX_NDIM; ++i) {
kernel_names.push_back(fmt::format(
"mlx::core::cu::{}_strided<{}, uint32_t, {}>",
lib_name(),
i,
work_per_thread));
"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,
work_per_thread));
"mlx::core::cu::{}_strided<{}, int64_t, {}>", lib_name(), i, wpt));
}
}
return std::make_pair(std::move(builder.os), std::move(kernel_names));
});
@@ -269,7 +309,6 @@ void Compiled::eval_gpu(
}
// Choose work per thread
int work_per_thread = 4;
if (!contiguous && shape.back() % work_per_thread != 0) {
work_per_thread = 1;
}
@@ -294,8 +333,8 @@ void Compiled::eval_gpu(
auto kernel = mod.get_kernel(kernel_name);
auto [num_blocks, block_dims] =
get_launch_args(kernel, outputs[0], large, work_per_thread);
encoder.add_kernel_node(kernel, num_blocks, block_dims, args.args());
get_launch_args(outputs[0], large, work_per_thread);
encoder.add_kernel_node(kernel, num_blocks, block_dims, 0, args.args());
}
} // namespace mlx::core

546
mlx/backend/cuda/conv.cpp Normal file
View File

@@ -0,0 +1,546 @@
// Copyright © 2025 Apple Inc.
#include "mlx/backend/cuda/device.h"
#include "mlx/backend/cuda/device/config.h"
#include "mlx/backend/cuda/lru_cache.h"
#include "mlx/backend/gpu/copy.h"
#include "mlx/dtype_utils.h"
#include "mlx/primitives.h"
// cudnn_frontend.h redefines this macro.
#undef CHECK_CUDA_ERROR
#include <cudnn_frontend.h>
#include <cudnn_frontend_find_plan.h>
#include <fmt/format.h>
#include <nvtx3/nvtx3.hpp>
#include <cassert>
namespace mlx::core {
namespace {
// Not all engines support it so can not use this API now.
#define MLX_USE_CUDNN_NATIVE_CUDA_GRAPH_API 0
// 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
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, cudnn_frontend::ExecutionPlan>>
cache(/* capacity */ 128);
return cache;
}
template <typename T, typename Vec>
inline SmallVector<T> convert_vector(const Vec& vec) {
return SmallVector<T>(vec.begin(), vec.end());
}
template <typename T, template <typename U> class Vec>
inline std::array<T, MAX_NDIM> fixed_vector(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;
}
auto nhwc_to_nchw(const array& x) {
auto shape = convert_vector<int64_t>(x.shape());
shape.insert(shape.begin() + 1, shape.back());
shape.erase(shape.end() - 1);
auto strides = convert_vector<int64_t>(x.strides());
strides.insert(strides.begin() + 1, strides.back());
strides.erase(strides.end() - 1);
return std::make_tuple(std::move(shape), std::move(strides));
}
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)));
}
}
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;
}
inline cudnn_frontend::Tensor build_tensor(int64_t id, const array& x) {
auto [shape, strides] = nhwc_to_nchw(x);
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();
}
cudnn_frontend::EngineConfigList get_engine_configs(
cudnnBackendDescriptorType_t backend_type,
Dtype dtype,
cudnn_frontend::OperationGraph& op_graph,
bool use_fallback = false) {
cudnn_frontend::GeneratorSource source;
if (use_fallback) {
source = [&backend_type](cudnn_frontend::OperationGraph& op_graph) {
auto fallback = cudnn_frontend::EngineFallbackListBuilder()
.setOperationGraph(op_graph)
.setOperation(backend_type)
.build();
return fallback.getFallbackList();
};
} else {
source = [](cudnn_frontend::OperationGraph& op_graph) {
auto heuristics = cudnn_frontend::EngineHeuristicsBuilder()
.setOperationGraph(op_graph)
.setHeurMode(CUDNN_HEUR_MODE_A)
.build();
return heuristics.getEngineConfig(heuristics.getEngineConfigCount());
};
}
cudnn_frontend::EngineConfigGenerator generator(1, &source);
auto configs = generator.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;
}
bool execute_plan(
cu::CommandEncoder& encoder,
cudnn_frontend::ExecutionPlan& plan,
array& x,
array& w,
array& y) {
int workspace_size = plan.getWorkspaceSize();
array workspace(allocator::malloc(workspace_size), {workspace_size}, uint8);
int64_t uids[3] = {'x', 'w', 'y'};
void* data_ptrs[3] = {
x.data<void>(),
w.data<void>(),
y.data<void>(),
};
auto variantPack = cudnn_frontend::VariantPackBuilder()
.setWorkspacePointer(workspace.data<void>())
.setDataPointers(3, data_ptrs)
.setUids(3, uids)
.build();
auto handle = encoder.device().cudnn_handle();
cudnnSetStream(handle, encoder.stream());
#if CUDNN_VERSION >= 90500 && MLX_USE_CUDNN_NATIVE_CUDA_GRAPH_API
cudaGraph_t graph;
cudaGraphCreate(&graph, 0);
std::unique_ptr<cudaGraph_t, void (*)(cudaGraph_t*)> graph_freer(
&graph, [](cudaGraph_t* p) { cudaGraphDestroy(*p); });
if (cudnnBackendPopulateCudaGraph(
handle, plan.get_raw_desc(), variantPack.get_raw_desc(), graph) !=
CUDNN_STATUS_SUCCESS) {
return false;
}
encoder.add_graph_node(graph);
#else
auto capture = encoder.capture_context();
if (cudnnBackendExecute(
handle, plan.get_raw_desc(), variantPack.get_raw_desc()) !=
CUDNN_STATUS_SUCCESS) {
// Discard the captured graph when failed.
capture.discard = true;
return false;
}
#endif
encoder.add_temporary(workspace);
return true;
}
bool try_engines(
cu::CommandEncoder& encoder,
const ConvCacheKey& cache_key,
cudnnBackendDescriptorType_t backend_type,
cudnn_frontend::EngineConfigList& configs,
const std::string& op_graph_tag,
array& x,
array& w,
array& y) {
for (auto& config : configs) {
try {
auto plan = cudnn_frontend::ExecutionPlanBuilder()
.setHandle(encoder.device().cudnn_handle())
.setEngineConfig(config, op_graph_tag)
.build();
if (execute_plan(encoder, plan, x, w, y)) {
conv_cache().emplace(
cache_key, std::make_pair(backend_type, std::move(plan)));
return true;
}
} catch (cudnn_frontend::cudnnException& error) {
if (error.getCudnnStatus() != CUDNN_STATUS_NOT_SUPPORTED) {
throw;
}
}
}
return false;
}
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_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_tensor('x', x))
.setwDesc(build_tensor('w', w))
.setyDesc(build_tensor('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;
}
}
// 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,
Stream s) {
// Transpose the args depending on the backend type.
// TODO: Handle groups.
if (backend_type == CONV_BACKWARD_INPUT) {
wt = swapaxes_in_eval(wt, 0, -1);
} else if (backend_type == CONV_BACKWARD_WEIGHT) {
in = swapaxes_in_eval(in, 0, -1);
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),
fixed_vector(in.shape()),
fixed_vector(wt.shape()),
fixed_vector(kernel_strides_),
fixed_vector(padding_lo_),
fixed_vector(padding_hi_),
fixed_vector(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;
std::tie(in, wt, out) = prepare_args(encoder, backend_type, in, wt, out, s);
register_args(encoder, backend_type, in, wt, out, out_);
auto [x, w, y] = dispatch_args(backend_type, in, wt, out);
if (!execute_plan(encoder, plan, x, w, y)) {
throw std::runtime_error("[conv] Cached plan failed to execute.");
}
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, 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_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) {
throw std::runtime_error("[conv] Can not build op graph.");
}
// Get ready to execute the graph.
register_args(encoder, backend_type, in, wt, out, out_);
// Try to run plans based on heuristics.
auto configs = get_engine_configs(backend_type, dtype, *op_graph);
auto tag = op_graph->getTag();
auto [x, w, y] = dispatch_args(backend_type, in, wt, out);
if (try_engines(encoder, cache_key, backend_type, configs, tag, x, w, y)) {
return;
}
// Then try fallback plans.
configs = get_engine_configs(backend_type, dtype, *op_graph);
if (try_engines(encoder, cache_key, backend_type, configs, tag, x, w, y)) {
return;
}
throw std::runtime_error("[conv] Unable to find a working engine.");
}
} // namespace mlx::core

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.val[i] = cast_to<Out>(in[0]);
out_vec[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.val[i] = cast_to<Out>(in_vec.val[i]);
out_vec[i] = cast_to<Out>(in_vec[i]);
}
store_vector<N_READS>(out, index, out_vec);
@@ -65,23 +65,18 @@ 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>;
// TODO: Choose optimized value based on type size.
constexpr int N_READS = 4;
constexpr int N_READS = 16 / sizeof(InType);
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(
kernel,
out.data_size(),
out.shape(),
out.strides(),
large(),
N_READS);
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());

19
mlx/backend/cuda/copy/copy_general.cu
View File

@@ -37,7 +37,7 @@ __global__ void copy_gg(
int ndim) {
IdxT index = cg::this_grid().thread_rank();
if (index < size) {
auto [idx_in, idx_out] = elem_to_loc_4d(
auto [idx_in, idx_out] = elem_to_loc(
index, shape.data(), strides_in.data(), strides_out.data(), ndim);
out[idx_out] = CastOp<In, Out>{}(in[idx_in]);
}
@@ -71,14 +71,13 @@ void copy_general(
data_size *= s;
if (ndim <= 3) {
dispatch_1_2_3(ndim, [&](auto ndim_constant) {
auto kernel =
cu::copy_gg_nd<InType, OutType, IdxT, ndim_constant()>;
auto [num_blocks, block_dims] = get_launch_args(
kernel, data_size, shape, out.strides(), large());
auto [num_blocks, block_dims] =
get_launch_args(data_size, shape, out.strides(), large());
encoder.add_kernel_node(
kernel,
cu::copy_gg_nd<InType, OutType, IdxT, ndim_constant()>,
num_blocks,
block_dims,
0,
in_ptr,
out_ptr,
data_size,
@@ -87,13 +86,13 @@ void copy_general(
const_param<ndim_constant()>(strides_out));
});
} else { // ndim >= 4
auto kernel = cu::copy_gg<InType, OutType, IdxT>;
auto [num_blocks, block_dims] = get_launch_args(
kernel, data_size, shape, out.strides(), large());
auto [num_blocks, block_dims] =
get_launch_args(data_size, shape, out.strides(), large());
encoder.add_kernel_node(
kernel,
cu::copy_gg<InType, OutType, IdxT>,
num_blocks,
block_dims,
0,
in_ptr,
out_ptr,
data_size,

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_4d(
auto [idx_in, idx_out] = elem_to_loc(
index, shape.data(), strides_in.data(), strides_out.data(), ndim);
out[idx_out + *offset_out] = CastOp<In, Out>{}(in[idx_in + *offset_in]);
}
@@ -74,14 +74,16 @@ void copy_general_dynamic(
int ndim = shape.size();
if (ndim <= 3) {
dispatch_1_2_3(ndim, [&](auto dims_constant) {
auto kernel = cu::
copy_gg_dynamic_nd<InType, OutType, IdxT, dims_constant()>;
auto [num_blocks, block_dims] =
get_launch_args(kernel, out, large());
auto [num_blocks, block_dims] = get_launch_args(out, large());
encoder.add_kernel_node(
kernel,
cu::copy_gg_dynamic_nd<
InType,
OutType,
IdxT,
dims_constant()>,
num_blocks,
block_dims,
0,
in_ptr,
out_ptr,
out.size(),
@@ -92,13 +94,12 @@ void copy_general_dynamic(
dynamic_offset_out.data<int64_t>());
});
} else { // ndim >= 4
auto kernel = cu::copy_gg_dynamic<InType, OutType, IdxT>;
auto [num_blocks, block_dims] =
get_launch_args(kernel, out, large());
auto [num_blocks, block_dims] = get_launch_args(out, large());
encoder.add_kernel_node(
kernel,
cu::copy_gg_dynamic<InType, OutType, IdxT>,
num_blocks,
block_dims,
0,
in_ptr,
out_ptr,
out.size(),

17
mlx/backend/cuda/copy/copy_general_input.cu
View File

@@ -34,7 +34,7 @@ __global__ void copy_g(
int ndim) {
IdxT index = cg::this_grid().thread_rank();
if (index < size) {
IdxT idx_in = elem_to_loc_4d(index, shape.data(), strides_in.data(), ndim);
IdxT idx_in = elem_to_loc(index, shape.data(), strides_in.data(), ndim);
out[index] = CastOp<In, Out>{}(in[idx_in]);
}
}
@@ -63,14 +63,12 @@ void copy_general_input(
int ndim = shape.size();
if (ndim <= 3) {
dispatch_1_2_3(ndim, [&](auto dims_constant) {
auto kernel =
cu::copy_g_nd<InType, OutType, IdxT, dims_constant()>;
auto [num_blocks, block_dims] =
get_launch_args(kernel, out, large());
auto [num_blocks, block_dims] = get_launch_args(out, large());
encoder.add_kernel_node(
kernel,
cu::copy_g_nd<InType, OutType, IdxT, dims_constant()>,
num_blocks,
block_dims,
0,
in_ptr,
out_ptr,
out.size(),
@@ -78,13 +76,12 @@ void copy_general_input(
const_param<dims_constant()>(strides_in));
});
} else { // ndim >= 4
auto kernel = cu::copy_g<InType, OutType, IdxT>;
auto [num_blocks, block_dims] =
get_launch_args(kernel, out, large());
auto [num_blocks, block_dims] = get_launch_args(out, large());
encoder.add_kernel_node(
kernel,
cu::copy_g<InType, OutType, IdxT>,
num_blocks,
block_dims,
0,
in_ptr,
out_ptr,
out.size(),

114
mlx/backend/cuda/device.cpp
View File

@@ -1,6 +1,7 @@
// 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"
@@ -9,12 +10,23 @@
#include <future>
#include <unordered_set>
namespace mlx::core {
namespace mlx::core::cu {
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)));
}
}
int cuda_graph_cache_size() {
static int cache_size = []() {
return env::get_var("MLX_CUDA_GRAPH_CACHE_SIZE", 100);
@@ -22,7 +34,7 @@ int cuda_graph_cache_size() {
return cache_size;
}
namespace cu {
} // namespace
Device::Device(int device) : device_(device) {
CHECK_CUDA_ERROR(cudaDeviceGetAttribute(
@@ -40,11 +52,18 @@ Device::Device(int device) : device_(device) {
}
// The cublasLt handle is used by matmul.
make_current();
cublasLtCreate(&lt_);
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();
}
Device::~Device() {
cublasLtDestroy(lt_);
CHECK_CUDNN_ERROR(cudnnDestroy(cudnn_));
CHECK_CUBLAS_ERROR(cublasLtDestroy(lt_));
}
void Device::make_current() {
@@ -66,29 +85,19 @@ CommandEncoder& Device::get_command_encoder(Stream s) {
}
CommandEncoder::CaptureContext::CaptureContext(CommandEncoder& enc) : enc(enc) {
enc.device().make_current();
CHECK_CUDA_ERROR(
cudaStreamBeginCapture(enc.stream(), cudaStreamCaptureModeGlobal));
}
CommandEncoder::CaptureContext::~CaptureContext() {
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'});
std::unique_ptr<cudaGraph_t, void (*)(cudaGraph_t*)> graph_freer(
&graph, [](cudaGraph_t* p) { CHECK_CUDA_ERROR(cudaGraphDestroy(*p)); });
if (discard) {
return;
}
CHECK_CUDA_ERROR(cudaGraphDestroy(graph));
enc.add_graph_node(graph);
}
CommandEncoder::ConcurrentContext::ConcurrentContext(CommandEncoder& enc)
@@ -175,21 +184,11 @@ void CommandEncoder::insert_graph_dependencies(std::vector<GraphNode> nodes) {
}
}
CommandEncoder::CommandEncoder(Device& d) : device_(d), stream_(d) {
CommandEncoder::CommandEncoder(Device& d)
: device_(d), stream_(d), graph_cache_(cuda_graph_cache_size()) {
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));
}
@@ -215,22 +214,22 @@ void CommandEncoder::add_kernel_node(
void* func,
dim3 grid_dim,
dim3 block_dim,
uint32_t smem_bytes,
void** params) {
cudaKernelNodeParams kernel_params = {0};
kernel_params.func = func;
kernel_params.gridDim = grid_dim;
kernel_params.blockDim = block_dim;
kernel_params.kernelParams = params;
cudaGraphNode_t node;
CHECK_CUDA_ERROR(
cudaGraphAddKernelNode(&node, graph_, NULL, 0, &kernel_params));
insert_graph_dependencies(GraphNode{node, 'K'});
kernel_params.sharedMemBytes = smem_bytes;
add_kernel_node(kernel_params);
}
void CommandEncoder::add_kernel_node(
CUfunction func,
dim3 grid_dim,
dim3 block_dim,
uint32_t smem_bytes,
void** params) {
CUDA_KERNEL_NODE_PARAMS kernel_params = {0};
kernel_params.func = func;
@@ -241,13 +240,30 @@ void CommandEncoder::add_kernel_node(
kernel_params.blockDimY = block_dim.y;
kernel_params.blockDimZ = block_dim.z;
kernel_params.kernelParams = params;
CUgraphNode node;
CHECK_CUDA_ERROR(
cuGraphAddKernelNode(&node, graph_, NULL, 0, &kernel_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));
insert_graph_dependencies(GraphNode{node, 'K'});
}
void CommandEncoder::add_graph_node(cudaGraph_t child) {
cudaGraphNode_t node;
CHECK_CUDA_ERROR(cudaGraphAddChildGraphNode(&node, graph_, NULL, 0, child));
insert_graph_dependencies(GraphNode{node, 'G'});
}
void CommandEncoder::commit() {
nvtx3::scoped_range r("CommandEncoder::commit");
if (!temporaries_.empty()) {
add_completed_handler([temporaries = std::move(temporaries_)]() {});
}
@@ -264,7 +280,7 @@ void CommandEncoder::commit() {
graph_key_ += ".";
graph_key_ += std::to_string(empty_node_count_);
cudaGraphExec_t& graph_exec = graph_cache_[graph_key_];
CudaGraphExec& graph_exec = graph_cache_[graph_key_];
if (graph_exec != nullptr) {
cudaGraphExecUpdateResult update_result;
@@ -278,25 +294,19 @@ void CommandEncoder::commit() {
#endif // CUDART_VERSION >= 12000
if (update_result != cudaGraphExecUpdateSuccess) {
cudaGetLastError(); // reset error
CHECK_CUDA_ERROR(cudaGraphExecDestroy(graph_exec));
graph_exec = nullptr;
graph_exec.reset();
}
}
if (graph_exec == nullptr) {
CHECK_CUDA_ERROR(
cudaGraphInstantiate(&graph_exec, graph_, NULL, NULL, 0));
graph_exec.instantiate(graph_);
}
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();
@@ -306,7 +316,6 @@ void CommandEncoder::commit() {
}
// Put completion handlers in a batch.
worker_.end_batch();
worker_.commit(stream_);
}
@@ -315,7 +324,6 @@ 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();
}
@@ -333,6 +341,4 @@ CommandEncoder& get_command_encoder(Stream s) {
return device(s.device).get_command_encoder(s);
}
} // namespace cu
} // namespace mlx::core
} // namespace mlx::core::cu

38
mlx/backend/cuda/device.h
View File

@@ -3,11 +3,13 @@
#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>
@@ -21,6 +23,7 @@ class CommandEncoder {
~CaptureContext();
cudaGraph_t graph;
CommandEncoder& enc;
bool discard{false};
};
struct ConcurrentContext {
ConcurrentContext(CommandEncoder& enc);
@@ -29,7 +32,6 @@ class CommandEncoder {
};
explicit CommandEncoder(Device& d);
~CommandEncoder();
CommandEncoder(const CommandEncoder&) = delete;
CommandEncoder& operator=(const CommandEncoder&) = delete;
@@ -45,25 +47,39 @@ 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, Params&&... params) {
void add_kernel_node(
F* func,
dim3 grid_dim,
dim3 block_dim,
uint32_t smem_bytes,
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, ptrs);
add_kernel_node((void*)func, grid_dim, block_dim, smem_bytes, 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, void** params);
void add_kernel_node(
void* func,
dim3 grid_dim,
dim3 block_dim,
uint32_t smem_bytes,
void** params);
// Low-level graph helpers.
void add_kernel_node(const cudaKernelNodeParams& params);
void add_kernel_node(const CUDA_KERNEL_NODE_PARAMS& params);
void add_graph_node(cudaGraph_t child);
void add_temporary(const array& arr) {
temporaries_.push_back(arr.data_shared_ptr());
@@ -73,6 +89,10 @@ class CommandEncoder {
void maybe_commit();
void commit();
Device& device() {
return device_;
}
CudaStream& stream() {
return stream_;
}
@@ -106,7 +126,7 @@ class CommandEncoder {
std::string graph_key_;
std::vector<GraphNode> concurrent_nodes_;
std::vector<std::shared_ptr<array::Data>> temporaries_;
std::unordered_map<std::string, cudaGraphExec_t> graph_cache_;
LRUCache<std::string, CudaGraphExec> 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_;
@@ -137,12 +157,16 @@ 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
View File

@@ -1,15 +0,0 @@
// 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

4
mlx/backend/cuda/device/atomic_ops.cuh
View File

@@ -49,11 +49,7 @@ inline __device__ void atomic_add(__half* out, __half val) {
}
inline __device__ void atomic_add(complex64_t* out, complex64_t 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) {

117
mlx/backend/cuda/device/utils.cuh
View File

@@ -32,23 +32,120 @@ using Strides = cuda::std::array<int64_t, MAX_NDIM>;
template <typename T, int N>
struct alignas(sizeof(T) * N) AlignedVector {
T val[N];
__device__ T& operator[](int i) {
return val[i];
}
__device__ T operator[](int i) const {
return val[i];
}
};
template <int N, typename T>
inline __device__ AlignedVector<T, N> load_vector(
inline __host__ __device__ bool is_aligned(T* x) {
return (reinterpret_cast<uintptr_t>(x) % (N * sizeof(T))) == 0;
}
template <int N, typename T>
inline __device__ AlignedVector<T, N> unsafe_load_vector(
const T* ptr,
uint32_t offset) {
auto* from = reinterpret_cast<const AlignedVector<T, N>*>(ptr);
return from[offset];
}
template <int N, typename T>
inline __device__ AlignedVector<T, N> load_vector(
const T* ptr,
uint32_t offset) {
if (is_aligned<N>(ptr)) {
auto* from = reinterpret_cast<const AlignedVector<T, N>*>(ptr);
return from[offset];
} else {
AlignedVector<T, N> v;
#pragma unroll
for (int i = 0; i < N; ++i) {
v[i] = ptr[offset * N + i];
}
return v;
}
}
template <int N, typename T, typename SizeT>
inline __device__ AlignedVector<T, N>
load_vector(const T* ptr, uint32_t offset, SizeT size, T fallback) {
if (is_aligned<N>(ptr) && (offset + 1) * N <= size) {
auto* from = reinterpret_cast<const AlignedVector<T, N>*>(ptr);
return from[offset];
} else {
AlignedVector<T, N> v;
#pragma unroll
for (int i = 0; i < N; ++i) {
v[i] = (N * offset + i) < size ? ptr[offset * N + i] : fallback;
}
return v;
}
}
template <int N, typename T, typename SizeT>
inline __device__ AlignedVector<T, N> load_vector(
const T* ptr,
uint32_t offset,
SizeT size,
int64_t stride,
T fallback) {
if (is_aligned<N>(ptr) && stride == 1 && (offset + 1) * N <= size) {
auto* from = reinterpret_cast<const AlignedVector<T, N>*>(ptr);
return from[offset];
} else {
AlignedVector<T, N> v;
#pragma unroll
for (int i = 0; i < N; ++i) {
v[i] =
(N * offset + i) < size ? ptr[stride * (offset * N + i)] : fallback;
}
return v;
}
}
template <int N, typename T>
inline __device__ void
store_vector(T* ptr, uint32_t offset, const AlignedVector<T, N>& vec) {
unsafe_store_vector(T* ptr, uint32_t offset, const AlignedVector<T, N>& vec) {
auto* to = reinterpret_cast<AlignedVector<T, N>*>(ptr);
to[offset] = vec;
}
template <int N, typename T>
inline __device__ void
store_vector(T* ptr, uint32_t offset, const AlignedVector<T, N>& vec) {
if (is_aligned<N>(ptr)) {
auto* to = reinterpret_cast<AlignedVector<T, N>*>(ptr);
to[offset] = vec;
} else {
#pragma unroll
for (int i = 0; i < N; ++i) {
ptr[offset * N + i] = vec[i];
}
}
}
template <int N, typename T, typename SizeT>
inline __device__ void store_vector(
T* ptr,
uint32_t offset,
const AlignedVector<T, N>& vec,
SizeT size) {
if (is_aligned<N>(ptr) && (offset + 1) * N <= size) {
auto* to = reinterpret_cast<AlignedVector<T, N>*>(ptr);
to[offset] = vec;
} else {
for (int i = 0; (offset * N + i) < size && i < N; ++i) {
ptr[offset * N + i] = vec[i];
}
}
}
///////////////////////////////////////////////////////////////////////////////
// Type limits utils
///////////////////////////////////////////////////////////////////////////////
@@ -204,20 +301,8 @@ inline __host__ __device__ cuda::std::tuple<IdxT, IdxT, IdxT> elem_to_loc_nd(
return cuda::std::make_tuple(a_loc, b_loc, c_loc);
}
// Optimized version when ndim is larger than 4.
template <typename IdxT = int64_t>
inline __host__ __device__ IdxT
elem_to_loc_4d(IdxT elem, const int* shape, const int64_t* strides, int ndim) {
IdxT loc = 0;
for (int i = ndim - 1; i >= 0; --i) {
loc += (elem % shape[i]) * IdxT(strides[i]);
elem /= shape[i];
}
return loc;
}
template <typename IdxT = int64_t>
inline __host__ __device__ cuda::std::tuple<IdxT, IdxT> elem_to_loc_4d(
inline __host__ __device__ cuda::std::tuple<IdxT, IdxT> elem_to_loc(
IdxT elem,
const int* shape,
const int64_t* a_strides,
@@ -235,7 +320,7 @@ inline __host__ __device__ cuda::std::tuple<IdxT, IdxT> elem_to_loc_4d(
}
template <typename IdxT = int64_t>
inline __host__ __device__ cuda::std::tuple<IdxT, IdxT, IdxT> elem_to_loc_4d(
inline __host__ __device__ cuda::std::tuple<IdxT, IdxT, IdxT> elem_to_loc(
IdxT elem,
const int* shape,
const int64_t* a_strides,

15
mlx/backend/cuda/eval.cpp
View File

@@ -19,8 +19,6 @@ void new_stream(Stream s) {
cudaFree(nullptr);
// Ensure the static stream objects get created.
cu::get_command_encoder(s);
// The main thread is safe to free buffers.
cu::allocator().register_this_thread();
}
void eval(array& arr) {
@@ -38,18 +36,15 @@ void eval(array& arr) {
auto& encoder = cu::get_command_encoder(arr.primitive().stream());
// Keep used buffers alive until kernel finishes running.
std::unordered_set<std::shared_ptr<array::Data>> buffers;
for (auto& in : arr.inputs()) {
buffers.insert(in.data_shared_ptr());
// Except for the donated one.
if (in.data_shared_ptr() != arr.data_shared_ptr()) {
encoder.add_temporary(in);
}
}
for (auto& s : arr.siblings()) {
buffers.insert(s.data_shared_ptr());
encoder.add_temporary(s);
}
// Remove the output if it was donated to by an input.
if (auto it = buffers.find(arr.data_shared_ptr()); it != buffers.end()) {
buffers.erase(it);
}
encoder.add_completed_handler([buffers = std::move(buffers)]() {});
encoder.maybe_commit();
}

32
mlx/backend/cuda/event.cu
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@@ -110,24 +110,26 @@ __global__ void event_signal_kernel(SharedEvent::Atomic* ac, uint64_t value) {
event_signal(ac, value);
}
SharedEvent::Atomic* to_atomic(std::shared_ptr<Buffer> buf) {
return static_cast<SharedEvent::Atomic*>(buf->raw_ptr());
}
SharedEvent::SharedEvent() {
// Allocate cuda::atomic on managed memory.
Atomic* ac;
CHECK_CUDA_ERROR(cudaMallocManaged(&ac, sizeof(Atomic)));
new (ac) Atomic(0);
ac_ = std::shared_ptr<Atomic>(ac, [](Atomic* ptr) {
ptr->~Atomic();
allocator().cuda_free(ptr);
buf_ = std::shared_ptr<Buffer>(
new Buffer{allocator().malloc(sizeof(Atomic))}, [](Buffer* ptr) {
allocator().free(*ptr);
delete ptr;
});
*static_cast<uint64_t*>(buf_->raw_ptr()) = 0;
}
void SharedEvent::wait(uint64_t value) {
nvtx3::scoped_range r("cu::SharedEvent::wait");
event_wait(ac_.get(), value);
event_wait(to_atomic(buf_), value);
}
void SharedEvent::wait(cudaStream_t stream, uint64_t value) {
event_wait_kernel<<<1, 1, 0, stream>>>(ac_.get(), value);
event_wait_kernel<<<1, 1, 0, stream>>>(to_atomic(buf_), value);
}
void SharedEvent::wait(Stream s, uint64_t value) {
@@ -138,17 +140,17 @@ void SharedEvent::wait(Stream s, uint64_t value) {
auto& encoder = get_command_encoder(s);
encoder.commit();
wait(encoder.stream(), value);
encoder.add_completed_handler([ac = ac_]() {});
encoder.add_completed_handler([buf = buf_]() {});
}
}
void SharedEvent::signal(uint64_t value) {
nvtx3::scoped_range r("cu::SharedEvent::signal");
event_signal(ac_.get(), value);
event_signal(to_atomic(buf_), value);
}
void SharedEvent::signal(cudaStream_t stream, uint64_t value) {
event_signal_kernel<<<1, 1, 0, stream>>>(ac_.get(), value);
event_signal_kernel<<<1, 1, 0, stream>>>(to_atomic(buf_), value);
}
void SharedEvent::signal(Stream s, uint64_t value) {
@@ -162,18 +164,18 @@ void SharedEvent::signal(Stream s, uint64_t value) {
auto& encoder = get_command_encoder(s);
encoder.commit();
signal(encoder.stream(), value);
encoder.add_completed_handler([ac = ac_]() {});
encoder.add_completed_handler([buf = buf_]() {});
}
}
bool SharedEvent::is_signaled(uint64_t value) const {
nvtx3::scoped_range r("cu::SharedEvent::is_signaled");
return ac_->load() >= value;
return to_atomic(buf_)->load() >= value;
}
uint64_t SharedEvent::value() const {
nvtx3::scoped_range r("cu::SharedEvent::value");
return ac_->load();
return to_atomic(buf_)->load();
}
} // namespace cu

7
mlx/backend/cuda/event.h
View File

@@ -2,6 +2,7 @@
#pragma once
#include "mlx/allocator.h"
#include "mlx/stream.h"
#include <cuda_runtime.h>
@@ -55,12 +56,8 @@ class SharedEvent {
bool is_signaled(uint64_t value) const;
uint64_t value() const;
const std::shared_ptr<Atomic>& atomic() const {
return ac_;
}
private:
std::shared_ptr<Atomic> ac_;
std::shared_ptr<mlx::core::allocator::Buffer> buf_;
};
} // namespace mlx::core::cu

329
mlx/backend/cuda/gemms/cublas_gemm.cpp Normal file
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@@ -0,0 +1,329 @@
// Copyright © 2025 Apple Inc.
#include "mlx/backend/cuda/gemms/cublas_gemm.h"
#include "mlx/backend/cuda/device.h"
#include "mlx/dtype_utils.h"
#include "mlx/utils.h"
#include <fmt/format.h>
namespace mlx::core {
namespace {
struct CublasPreference {
CublasPreference(cu::Device& device) {
// The recommended cublas workspace size is 4 MiB for pre-Hopper and 32 MiB
// for Hopper+:
// https://docs.nvidia.com/cuda/cublas/#cublassetworkspace
uint64_t MiB = 1024 * 1024;
uint64_t workspace_size =
device.compute_capability_major() >= 9 ? 32 * MiB : 4 * MiB;
CHECK_CUBLAS_ERROR(cublasLtMatmulPreferenceCreate(&pref_));
CHECK_CUBLAS_ERROR(cublasLtMatmulPreferenceSetAttribute(
pref_,
CUBLASLT_MATMUL_PREF_MAX_WORKSPACE_BYTES,
&workspace_size,
sizeof(uint64_t)));
}
~CublasPreference() {
CHECK_CUBLAS_ERROR(cublasLtMatmulPreferenceDestroy(pref_));
}
cublasLtMatmulPreference_t pref_{nullptr};
};
cublasLtMatmulPreference_t cublas_preference(cu::Device& device) {
static CublasPreference pref(device);
return pref.pref_;
}
cublasComputeType_t dtype_to_compute_type(Dtype dtype) {
switch (dtype) {
case float16:
return CUBLAS_COMPUTE_32F;
case bfloat16:
return CUBLAS_COMPUTE_32F;
case float32:
return mlx::core::env::enable_tf32() ? CUBLAS_COMPUTE_32F_FAST_TF32
: CUBLAS_COMPUTE_32F;
case float64:
case complex64:
return CUBLAS_COMPUTE_64F;
default:
throw std::runtime_error(fmt::format(
"Unsupported dtype in CublasGemm: {}.", dtype_to_string(dtype)));
}
}
cudaDataType_t dtype_to_cublas_type(Dtype dtype) {
switch (dtype) {
case float16:
return CUDA_R_16F;
case bfloat16:
return CUDA_R_16BF;
case float32:
return CUDA_R_32F;
case float64:
return CUDA_R_64F;
case complex64:
return CUDA_C_32F;
default:
throw std::runtime_error(fmt::format(
"Unsupported dtype in CublasGemm: {}.", dtype_to_string(dtype)));
}
}
cublasLtMatrixLayout_t create_matrix_layout(
cudaDataType_t type,
uint64_t rows,
uint64_t cols,
bool transposed,
int64_t ld,
int32_t batch_count,
int64_t batch_stride) {
cublasLtMatrixLayout_t desc;
CHECK_CUBLAS_ERROR(cublasLtMatrixLayoutCreate(&desc, type, rows, cols, ld));
cublasLtOrder_t order = transposed ? CUBLASLT_ORDER_COL : CUBLASLT_ORDER_ROW;
CHECK_CUBLAS_ERROR(cublasLtMatrixLayoutSetAttribute(
desc, CUBLASLT_MATRIX_LAYOUT_ORDER, &order, sizeof(cublasLtOrder_t)));
if (batch_count > 1) {
CHECK_CUBLAS_ERROR(cublasLtMatrixLayoutSetAttribute(
desc,
CUBLASLT_MATRIX_LAYOUT_BATCH_COUNT,
&batch_count,
sizeof(int32_t)));
CHECK_CUBLAS_ERROR(cublasLtMatrixLayoutSetAttribute(
desc,
CUBLASLT_MATRIX_LAYOUT_STRIDED_BATCH_OFFSET,
&batch_stride,
sizeof(int64_t)));
}
return desc;
}
} // namespace
CublasGemm::CublasGemm(
cu::Device& device,
Dtype dtype,
bool a_transposed,
uint64_t a_rows,
uint64_t a_cols,
int64_t lda,
bool b_transposed,
uint64_t b_rows,
uint64_t b_cols,
int64_t ldb,
int32_t batch_count,
int64_t a_batch_stride,
int64_t b_batch_stride)
: handle_(device.lt_handle()),
pref_(cublas_preference(device)),
M_(a_rows),
N_(b_cols) {
heuristic_.state = CUBLAS_STATUS_NOT_INITIALIZED;
auto scale_type = dtype_to_cublas_type(dtype);
if (dtype == bfloat16 || dtype == float16) {
scale_type = CUDA_R_32F;
}
CHECK_CUBLAS_ERROR(cublasLtMatmulDescCreate(
&matmul_desc_, dtype_to_compute_type(dtype), scale_type));
int32_t pointer_mode = CUBLASLT_POINTER_MODE_HOST;
CHECK_CUBLAS_ERROR(cublasLtMatmulDescSetAttribute(
matmul_desc_,
CUBLASLT_MATMUL_DESC_POINTER_MODE,
&pointer_mode,
sizeof(int32_t)));
cublasOperation_t op = CUBLAS_OP_N;
CHECK_CUBLAS_ERROR(cublasLtMatmulDescSetAttribute(
matmul_desc_,
CUBLASLT_MATMUL_DESC_TRANSA,
&op,
sizeof(cublasOperation_t)));
CHECK_CUBLAS_ERROR(cublasLtMatmulDescSetAttribute(
matmul_desc_,
CUBLASLT_MATMUL_DESC_TRANSB,
&op,
sizeof(cublasOperation_t)));
auto type = dtype_to_cublas_type(dtype);
a_desc_ = create_matrix_layout(
type, a_rows, a_cols, a_transposed, lda, batch_count, a_batch_stride);
b_desc_ = create_matrix_layout(
type, b_rows, b_cols, b_transposed, ldb, batch_count, b_batch_stride);
out_desc_ = create_matrix_layout(
type, a_rows, b_cols, false, b_cols, batch_count, a_rows * b_cols);
}
CublasGemm::CublasGemm(
cu::Device& device,
Dtype dtype,
bool a_transposed,
uint64_t a_rows,
uint64_t a_cols,
int64_t lda,
bool b_transposed,
uint64_t b_rows,
uint64_t b_cols,
int64_t ldb,
int64_t ldc,
int32_t batch_count,
int64_t a_batch_stride,
int64_t b_batch_stride,
int64_t c_batch_stride)
: CublasGemm(
device,
dtype,
a_transposed,
a_rows,
a_cols,
lda,
b_transposed,
b_rows,
b_cols,
ldb,
batch_count,
a_batch_stride,
b_batch_stride) {
auto type = dtype_to_cublas_type(dtype);
c_desc_ = create_matrix_layout(
type, a_rows, b_cols, false, ldc, batch_count, c_batch_stride);
}
CublasGemm::~CublasGemm() {
CHECK_CUBLAS_ERROR(cublasLtMatrixLayoutDestroy(a_desc_));
CHECK_CUBLAS_ERROR(cublasLtMatrixLayoutDestroy(b_desc_));
CHECK_CUBLAS_ERROR(cublasLtMatrixLayoutDestroy(c_desc_));
CHECK_CUBLAS_ERROR(cublasLtMatrixLayoutDestroy(out_desc_));
CHECK_CUBLAS_ERROR(cublasLtMatmulDescDestroy(matmul_desc_));
}
void CublasGemm::run(
cu::CommandEncoder& encoder,
array& out,
const array& a,
const array& b,
const Shape& batch_shape,
const Strides& a_batch_strides,
const Strides& b_batch_strides) {
int batch_count = out.size() / (M_ * N_);
if (batch_count / batch_shape.back() > 1) {
run_batched(
encoder, out, a, b, batch_shape, a_batch_strides, b_batch_strides);
return;
}
encoder.set_input_array(a);
encoder.set_input_array(b);
encoder.set_output_array(out);
execute(encoder, out.data<void>(), a.data<void>(), b.data<void>(), nullptr);
}
void CublasGemm::run(
cu::CommandEncoder& encoder,
array& out,
const array& a,
const array& b,
const array& c,
const Shape& batch_shape,
const Strides& a_batch_strides,
const Strides& b_batch_strides,
const Strides& c_batch_strides,
float alpha,
float beta) {
int batch_count = out.size() / (M_ * N_);
if (batch_count / batch_shape.back() > 1) {
run_batched(
encoder,
out,
a,
b,
c,
batch_shape,
a_batch_strides,
b_batch_strides,
c_batch_strides,
alpha,
beta);
return;
}
encoder.set_input_array(a);
encoder.set_input_array(b);
encoder.set_input_array(c);
encoder.set_output_array(out);
execute(
encoder,
out.data<void>(),
a.data<void>(),
b.data<void>(),
c.data<void>(),
alpha,
beta);
}
void CublasGemm::execute(
cu::CommandEncoder& encoder,
void* out,
const void* a,
const void* b,
const void* c,
float alpha /* = 1 */,
float beta /* = 0 */) {
if (heuristic_.state != CUBLAS_STATUS_SUCCESS) {
int ret = 0;
CHECK_CUBLAS_ERROR(cublasLtMatmulAlgoGetHeuristic(
handle_,
matmul_desc_,
a_desc_,
b_desc_,
c ? c_desc_ : out_desc_,
out_desc_,
pref_,
1,
&heuristic_,
&ret));
if (ret == 0) {
throw std::runtime_error("Can not find algorithm for matmul.");
}
}
void* workspace_ptr = nullptr;
if (heuristic_.workspaceSize > 0) {
// Ensure workspace is 256-byte aligned
int nbytes = cuda::ceil_div(heuristic_.workspaceSize, 256) * 256;
array workspace(
allocator::malloc(nbytes),
{static_cast<int>(heuristic_.workspaceSize)},
int8);
encoder.add_temporary(workspace);
workspace_ptr = workspace.data<void>();
}
auto capture = encoder.capture_context();
CHECK_CUBLAS_ERROR(cublasLtMatmul(
handle_,
matmul_desc_,
&alpha,
a,
a_desc_,
b,
b_desc_,
&beta,
c ? c : out,
c ? c_desc_ : out_desc_,
out,
out_desc_,
&heuristic_.algo,
workspace_ptr,
heuristic_.workspaceSize,
encoder.stream()));
}
} // namespace mlx::core

113
mlx/backend/cuda/gemms/cublas_gemm.h Normal file
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@@ -0,0 +1,113 @@
// Copyright © 2025 Apple Inc.
#pragma once
#include "mlx/array.h"
#include "mlx/backend/cuda/device.h"
#include <cublasLt.h>
namespace mlx::core {
class CublasGemm {
public:
CublasGemm(
cu::Device& device,
Dtype dtype,
bool a_transposed,
uint64_t a_rows,
uint64_t a_cols,
int64_t lda,
bool b_transposed,
uint64_t b_rows,
uint64_t b_cols,
int64_t ldb,
int32_t batch_count,
int64_t a_batch_stride,
int64_t b_batch_stride);
CublasGemm(
cu::Device& device,
Dtype dtype,
bool a_transposed,
uint64_t a_rows,
uint64_t a_cols,
int64_t lda,
bool b_transposed,
uint64_t b_rows,
uint64_t b_cols,
int64_t ldb,
int64_t ldc,
int32_t batch_count,
int64_t a_batch_stride,
int64_t b_batch_stride,
int64_t c_batch_stride);
~CublasGemm();
void run(
cu::CommandEncoder& encoder,
array& out,
const array& a,
const array& b,
const Shape& batch_shape,
const Strides& a_batch_strides,
const Strides& b_batch_strides);
void run(
cu::CommandEncoder& encoder,
array& out,
const array& a,
const array& b,
const array& c,
const Shape& batch_shape,
const Strides& a_batch_strides,
const Strides& b_batch_strides,
const Strides& c_batch_strides,
float alpha,
float beta);
private:
void run_batched(
cu::CommandEncoder& encoder,
array& out,
const array& a,
const array& b,
const Shape& batch_shape,
const Strides& a_batch_strides,
const Strides& b_batch_strides);
void run_batched(
cu::CommandEncoder& encoder,
array& out,
const array& a,
const array& b,
const array& c,
const Shape& batch_shape,
const Strides& a_batch_strides,
const Strides& b_batch_strides,
const Strides& c_batch_strides,
float alpha,
float beta);
void execute(
cu::CommandEncoder& encoder,
void* out,
const void* a,
const void* b,
const void* c,
float alpha = 1,
float beta = 0);
uint64_t M_;
uint64_t N_;
cublasLtMatmulPreference_t pref_{nullptr};
cublasLtHandle_t handle_{nullptr};
cublasLtMatmulDesc_t matmul_desc_{nullptr};
cublasLtMatrixLayout_t a_desc_{nullptr};
cublasLtMatrixLayout_t b_desc_{nullptr};
cublasLtMatrixLayout_t c_desc_{nullptr};
cublasLtMatrixLayout_t out_desc_{nullptr};
cublasLtMatmulHeuristicResult_t heuristic_;
};
} // namespace mlx::core

73
mlx/backend/cuda/gemms/cublas_gemm_batched_12_0.cpp Normal file
View File

@@ -0,0 +1,73 @@
// Copyright © 2025 Apple Inc.
#include "mlx/backend/common/utils.h"
#include "mlx/backend/cuda/device.h"
#include "mlx/backend/cuda/gemms/cublas_gemm.h"
namespace mlx::core {
void CublasGemm::run_batched(
cu::CommandEncoder& encoder,
array& out,
const array& a,
const array& b,
const Shape& batch_shape,
const Strides& a_batch_strides,
const Strides& b_batch_strides) {
encoder.set_input_array(a);
encoder.set_input_array(b);
encoder.set_output_array(out);
auto nbatch = out.size() / (M_ * N_ * batch_shape.back());
ContiguousIterator a_it(batch_shape, a_batch_strides, batch_shape.size() - 1);
ContiguousIterator b_it(batch_shape, b_batch_strides, batch_shape.size() - 1);
auto concurrent = encoder.concurrent_context();
for (size_t i = 0; i < nbatch; ++i) {
execute(
encoder,
out.data<int8_t>() + out.itemsize() * i * batch_shape.back() * M_ * N_,
a.data<int8_t>() + a.itemsize() * a_it.loc,
b.data<int8_t>() + b.itemsize() * b_it.loc,
nullptr);
a_it.step();
b_it.step();
}
}
void CublasGemm::run_batched(
cu::CommandEncoder& encoder,
array& out,
const array& a,
const array& b,
const array& c,
const Shape& batch_shape,
const Strides& a_batch_strides,
const Strides& b_batch_strides,
const Strides& c_batch_strides,
float alpha,
float beta) {
encoder.set_input_array(a);
encoder.set_input_array(b);
encoder.set_input_array(c);
encoder.set_output_array(out);
auto nbatch = out.size() / (M_ * N_ * batch_shape.back());
ContiguousIterator a_it(batch_shape, a_batch_strides, batch_shape.size() - 1);
ContiguousIterator b_it(batch_shape, b_batch_strides, batch_shape.size() - 1);
ContiguousIterator c_it(batch_shape, c_batch_strides, batch_shape.size() - 1);
auto concurrent = encoder.concurrent_context();
for (size_t i = 0; i < nbatch; ++i) {
execute(
encoder,
out.data<int8_t>() + out.itemsize() * i * batch_shape.back() * M_ * N_,
a.data<int8_t>() + a.itemsize() * a_it.loc,
b.data<int8_t>() + b.itemsize() * b_it.loc,
c.data<int8_t>() + c.itemsize() * c_it.loc,
alpha,
beta);
a_it.step();
b_it.step();
c_it.step();
}
}
} // namespace mlx::core

327
mlx/backend/cuda/gemms/cublas_gemm_batched_12_9.cu Normal file
View File

@@ -0,0 +1,327 @@
// Copyright © 2025 Apple Inc.
#include "mlx/backend/cuda/device.h"
#include "mlx/backend/cuda/gemms/cublas_gemm.h"
#include "mlx/backend/cuda/kernel_utils.cuh"
#include <cooperative_groups.h>
namespace mlx::core {
namespace cu {
namespace cg = cooperative_groups;
template <int NDIM>
__global__ void set_mm_device_pointers_nd(
int8_t** pointers,
int8_t* a_start,
int8_t* b_start,
int8_t* out_start,
int item_size,
const __grid_constant__ cuda::std::array<int32_t, NDIM> batch_shape,
const __grid_constant__ cuda::std::array<int64_t, NDIM> a_batch_strides,
const __grid_constant__ cuda::std::array<int64_t, NDIM> b_batch_strides,
int64_t batch_stride,
int batch_count) {
auto index = cg::this_grid().thread_rank();
if (index >= batch_count) {
return;
}
auto [a_offset, b_offset] = elem_to_loc_nd<NDIM>(
index,
batch_shape.data(),
a_batch_strides.data(),
b_batch_strides.data());
pointers[index] = a_start + item_size * a_offset;
pointers[index + batch_count] = b_start + item_size * b_offset;
pointers[index + 2 * batch_count] =
out_start + item_size * index * batch_stride;
}
__global__ void set_mm_device_pointers_g(
int8_t** pointers,
int8_t* a_start,
int8_t* b_start,
int8_t* out_start,
int item_size,
const __grid_constant__ Shape batch_shape,
const __grid_constant__ Strides a_batch_strides,
const __grid_constant__ Strides b_batch_strides,
int64_t batch_stride,
int batch_ndim,
int batch_count) {
auto index = cg::this_grid().thread_rank();
if (index >= batch_count) {
return;
}
auto [a_offset, b_offset] = elem_to_loc(
index,
batch_shape.data(),
a_batch_strides.data(),
b_batch_strides.data(),
batch_ndim);
pointers[index] = a_start + item_size * a_offset;
pointers[index + batch_count] = b_start + item_size * b_offset;
pointers[index + 2 * batch_count] =
out_start + item_size * index * batch_stride;
}
template <int NDIM>
__global__ void set_addmm_device_pointers_nd(
int8_t** pointers,
int8_t* a_start,
int8_t* b_start,
int8_t* c_start,
int8_t* out_start,
int item_size,
const __grid_constant__ cuda::std::array<int32_t, NDIM> batch_shape,
const __grid_constant__ cuda::std::array<int64_t, NDIM> a_batch_strides,
const __grid_constant__ cuda::std::array<int64_t, NDIM> b_batch_strides,
const __grid_constant__ cuda::std::array<int64_t, NDIM> c_batch_strides,
int64_t batch_stride,
int batch_count) {
auto index = cg::this_grid().thread_rank();
if (index >= batch_count) {
return;
}
auto [a_offset, b_offset, c_offset] = elem_to_loc_nd<NDIM>(
index,
batch_shape.data(),
a_batch_strides.data(),
b_batch_strides.data(),
c_batch_strides.data());
pointers[index] = a_start + item_size * a_offset;
pointers[index + batch_count] = b_start + item_size * b_offset;
pointers[index + 2 * batch_count] = c_start + item_size * c_offset;
pointers[index + 3 * batch_count] =
out_start + item_size * index * batch_stride;
}
__global__ void set_addmm_device_pointers_g(
int8_t** pointers,
int8_t* a_start,
int8_t* b_start,
int8_t* c_start,
int8_t* out_start,
int item_size,
const __grid_constant__ Shape batch_shape,
const __grid_constant__ Strides a_batch_strides,
const __grid_constant__ Strides b_batch_strides,
const __grid_constant__ Strides c_batch_strides,
int64_t batch_stride,
int batch_ndim,
int batch_count) {
auto index = cg::this_grid().thread_rank();
if (index >= batch_count) {
return;
}
auto [a_offset, b_offset, c_offset] = elem_to_loc(
index,
batch_shape.data(),
a_batch_strides.data(),
b_batch_strides.data(),
c_batch_strides.data(),
batch_ndim);
pointers[index] = a_start + item_size * a_offset;
pointers[index + batch_count] = b_start + item_size * b_offset;
pointers[index + 2 * batch_count] = c_start + item_size * c_offset;
pointers[index + 3 * batch_count] =
out_start + item_size * index * batch_stride;
}
} // namespace cu
namespace {
void set_pointer_mode(cublasLtMatrixLayout_t desc, int batch_count) {
auto batch_mode = CUBLASLT_BATCH_MODE_POINTER_ARRAY;
CHECK_CUBLAS_ERROR(cublasLtMatrixLayoutSetAttribute(
desc,
CUBLASLT_MATRIX_LAYOUT_BATCH_MODE,
&batch_mode,
sizeof(batch_mode)));
CHECK_CUBLAS_ERROR(cublasLtMatrixLayoutSetAttribute(
desc, CUBLASLT_MATRIX_LAYOUT_BATCH_COUNT, &batch_count, sizeof(int32_t)));
}
} // namespace
void CublasGemm::run_batched(
cu::CommandEncoder& encoder,
array& out,
const array& a,
const array& b,
const Shape& batch_shape,
const Strides& a_batch_strides,
const Strides& b_batch_strides) {
int batch_count = out.size() / (M_ * N_);
set_pointer_mode(a_desc_, batch_count);
set_pointer_mode(b_desc_, batch_count);
set_pointer_mode(out_desc_, batch_count);
// Launch kernel to set device offsets
auto pointers = array(
allocator::malloc(batch_count * sizeof(void*) * 3),
{batch_count * 3},
uint64);
encoder.add_temporary(pointers);
encoder.set_output_array(pointers);
int block_dims = std::min(batch_count, 256);
int num_blocks = cuda::ceil_div(batch_count, block_dims);
int64_t batch_stride = M_ * N_;
int item_size = out.itemsize();
int ndim = batch_shape.size();
if (ndim <= 3) {
dispatch_1_2_3(ndim, [&](auto ndim_constant) {
encoder.add_kernel_node(
cu::set_mm_device_pointers_nd<ndim_constant()>,
num_blocks,
block_dims,
0,
pointers.data<int8_t*>(),
a.data<int8_t>(),
b.data<int8_t>(),
out.data<int8_t>(),
item_size,
const_param<ndim_constant()>(batch_shape),
const_param<ndim_constant()>(a_batch_strides),
const_param<ndim_constant()>(b_batch_strides),
batch_stride,
batch_count);
});
} else {
encoder.add_kernel_node(
cu::set_mm_device_pointers_g,
num_blocks,
block_dims,
0,
pointers.data<int8_t*>(),
a.data<int8_t>(),
b.data<int8_t>(),
out.data<int8_t>(),
item_size,
const_param(batch_shape),
const_param(a_batch_strides),
const_param(b_batch_strides),
batch_stride,
ndim,
batch_count);
}
// Run matmul
encoder.set_input_array(pointers);
encoder.set_input_array(a);
encoder.set_input_array(b);
encoder.set_output_array(out);
auto a_pointers = pointers.data<int8_t*>();
auto b_pointers = a_pointers + batch_count;
auto out_pointers = b_pointers + batch_count;
execute(
encoder,
reinterpret_cast<void*>(out_pointers),
reinterpret_cast<void*>(a_pointers),
reinterpret_cast<void*>(b_pointers),
nullptr);
}
void CublasGemm::run_batched(
cu::CommandEncoder& encoder,
array& out,
const array& a,
const array& b,
const array& c,
const Shape& batch_shape,
const Strides& a_batch_strides,
const Strides& b_batch_strides,
const Strides& c_batch_strides,
float alpha,
float beta) {
int batch_count = out.size() / (M_ * N_);
set_pointer_mode(a_desc_, batch_count);
set_pointer_mode(b_desc_, batch_count);
set_pointer_mode(c_desc_, batch_count);
set_pointer_mode(out_desc_, batch_count);
// Launch kernel to set device offsets
auto pointers = array(
allocator::malloc(batch_count * sizeof(uint64_t) * 4),
{batch_count * 4},
uint64);
encoder.add_temporary(pointers);
encoder.set_output_array(pointers);
int block_dims = std::min(batch_count, 256);
int num_blocks = cuda::ceil_div(batch_count, block_dims);
int64_t batch_stride = M_ * N_;
int item_size = out.itemsize();
int ndim = batch_shape.size();
if (ndim <= 3) {
dispatch_1_2_3(ndim, [&](auto ndim_constant) {
encoder.add_kernel_node(
cu::set_addmm_device_pointers_nd<ndim_constant()>,
num_blocks,
block_dims,
0,
pointers.data<int8_t*>(),
a.data<int8_t>(),
b.data<int8_t>(),
c.data<int8_t>(),
out.data<int8_t>(),
item_size,
const_param<ndim_constant()>(batch_shape),
const_param<ndim_constant()>(a_batch_strides),
const_param<ndim_constant()>(b_batch_strides),
const_param<ndim_constant()>(c_batch_strides),
batch_stride,
batch_count);
});
} else {
encoder.add_kernel_node(
cu::set_addmm_device_pointers_g,
num_blocks,
block_dims,
0,
pointers.data<int8_t*>(),
a.data<int8_t>(),
b.data<int8_t>(),
c.data<int8_t>(),
out.data<int8_t>(),
item_size,
const_param(batch_shape),
const_param(a_batch_strides),
const_param(b_batch_strides),
const_param(c_batch_strides),
batch_stride,
ndim,
batch_count);
}
// Run matmul
encoder.set_input_array(pointers);
encoder.set_input_array(a);
encoder.set_input_array(b);
encoder.set_input_array(c);
encoder.set_output_array(out);
auto a_pointers = pointers.data<int8_t*>();
auto b_pointers = a_pointers + batch_count;
auto c_pointers = b_pointers + batch_count;
auto out_pointers = c_pointers + batch_count;
execute(
encoder,
reinterpret_cast<void*>(out_pointers),
reinterpret_cast<void*>(a_pointers),
reinterpret_cast<void*>(b_pointers),
reinterpret_cast<void*>(c_pointers),
alpha,
beta);
}
} // namespace mlx::core

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// Copyright © 2025 Apple Inc.
#include "mlx/backend/cuda/gemms/gemv.h"
#include "mlx/backend/cuda/kernel_utils.cuh"
#include "mlx/dtype_utils.h"
#include <cooperative_groups.h>
#include <cooperative_groups/reduce.h>
namespace mlx::core::cu {
namespace cg = cooperative_groups;
static constexpr int rows_per_block = 8;
template <typename T, int rows_per_block, int n_per_thread>
__device__ void
gemv_impl(const T* mat, const T* vec, T* out, int rows, int cols) {
auto block = cg::this_thread_block();
auto warp = cg::tiled_partition<WARP_SIZE>(block);
auto g_idx = block.group_index();
auto t_idx = block.thread_index();
int row = g_idx.x * rows_per_block + t_idx.y;
if (row < rows) {
float sum = 0.0f;
for (int col = n_per_thread * warp.thread_rank(); col < cols;
col += (WARP_SIZE * n_per_thread)) {
auto local_mat =
unsafe_load_vector<n_per_thread>(mat + row * cols + col, 0);
auto local_vec = unsafe_load_vector<n_per_thread>(vec + col, 0);
#pragma unroll
for (int j = 0; j < n_per_thread; ++j) {
sum +=
static_cast<float>(local_mat[j]) * static_cast<float>(local_vec[j]);
}
}
sum = cg::reduce(warp, sum, cg::plus<float>{});
if (warp.thread_rank() == 0) {
out[row] = static_cast<T>(sum);
}
}
}
template <typename T, int rows_per_block, int n_per_thread>
__global__ void
gemv_single(const T* mat, const T* vec, T* out, int rows, int cols) {
gemv_impl<T, rows_per_block, n_per_thread>(mat, vec, out, rows, cols);
}
template <typename T, int rows_per_block, int n_per_thread>
__global__ void gemv_batched(
const T* mat,
const T* vec,
T* out,
int rows,
int cols,
const __grid_constant__ Shape batch_shape,
const __grid_constant__ Strides mat_batch_strides,
const __grid_constant__ Strides vec_batch_strides,
int batch_ndim) {
auto block = cg::this_thread_block();
auto batch_idx = block.group_index().y;
auto [vec_offset, mat_offset] = elem_to_loc(
batch_idx,
batch_shape.data(),
vec_batch_strides.data(),
mat_batch_strides.data(),
batch_ndim);
gemv_impl<T, rows_per_block, n_per_thread>(
mat + mat_offset, vec + vec_offset, out + batch_idx * rows, rows, cols);
}
bool can_use_gemv(int M, int N, int K, bool a_transposed, bool b_transposed) {
return K % 32 == 0 && ((M == 1 && b_transposed) || (N == 1 && !a_transposed));
}
template <typename F>
void dispatch_n_per_thread(int n_per_thread, F&& f) {
switch (n_per_thread) {
case 1:
f(std::integral_constant<int, 1>{});
break;
case 2:
f(std::integral_constant<int, 2>{});
break;
case 4:
f(std::integral_constant<int, 4>{});
break;
}
}
void gemv(
const array& a,
const array& b,
array& out,
int M,
int N,
int K,
uint32_t batch_count,
const mlx::core::Shape& batch_shape,
const mlx::core::Strides& a_batch_strides,
const mlx::core::Strides& b_batch_strides,
CommandEncoder& encoder) {
encoder.set_input_array(a);
encoder.set_input_array(b);
encoder.set_output_array(out);
dispatch_float_types(out.dtype(), "gemv", [&](auto type_tag) {
using DataType = cuda_type_t<MLX_GET_TYPE(type_tag)>;
dim3 block_dims{WARP_SIZE, rows_per_block};
const DataType* mat;
const DataType* vec;
int rows;
int cols = K;
auto mat_strides = const_param(a_batch_strides);
auto vec_strides = const_param(b_batch_strides);
if (M == 1) {
mat = b.data<DataType>();
vec = a.data<DataType>();
rows = N;
std::swap(mat_strides, vec_strides);
} else {
mat = a.data<DataType>();
vec = b.data<DataType>();
rows = M;
}
uint32_t num_blocks_x = (rows + rows_per_block - 1) / rows_per_block;
int n_per_t;
if (K % 128 == 0 && is_aligned<4>(mat) && is_aligned<4>(vec)) {
n_per_t = 4;
} else if (K % 64 == 0 && is_aligned<2>(mat) && is_aligned<2>(vec)) {
n_per_t = 2;
} else {
n_per_t = 1;
}
dispatch_n_per_thread(n_per_t, [&](auto n_per_thread) {
if (batch_count == 1) {
auto kernel = gemv_single<DataType, rows_per_block, n_per_thread()>;
encoder.add_kernel_node(
kernel,
num_blocks_x,
block_dims,
0,
mat,
vec,
out.data<DataType>(),
rows,
cols);
} else {
auto kernel = gemv_batched<DataType, rows_per_block, n_per_thread()>;
encoder.add_kernel_node(
kernel,
dim3{num_blocks_x, batch_count},
block_dims,
0,
mat,
vec,
out.data<DataType>(),
rows,
cols,
const_param(batch_shape),
mat_strides,
vec_strides,
batch_shape.size());
}
});
});
}
} // namespace mlx::core::cu

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// Copyright © 2025 Apple Inc.
#pragma once
#include "mlx/backend/cuda/device.h"
namespace mlx::core::cu {
bool can_use_gemv(int M, int N, int K, bool a_transposed, bool b_transposed);
void gemv(
const array& a,
const array& b,
array& out,
int M,
int N,
int K,
uint32_t batch_count,
const mlx::core::Shape& batch_shape,
const mlx::core::Strides& a_batch_strides,
const mlx::core::Strides& b_batch_strides,
CommandEncoder& encoder);
} // namespace mlx::core::cu

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#include "mlx/backend/common/matmul.h"
#include "mlx/backend/cuda/device.h"
#include "mlx/backend/cuda/device/utils.cuh"
#include "mlx/backend/cuda/gemms/steel_gemm.h"
#include "mlx/backend/cuda/kernel_utils.cuh"
#include "mlx/primitives.h"
#include <nvtx3/nvtx3.hpp>
#include <numeric>
#include <cooperative_groups.h>
#include "mlx/backend/cuda/steel/gemm.cuh"
#include "mlx/backend/cuda/steel/mma.cuh"
#include "mlx/backend/cuda/steel/tiles.cuh"
namespace mlx::core {
namespace cu {
namespace cg = cooperative_groups;
struct GemmParams {
int M;
int N;
int K;
int lda;
int ldb;
int ldd;
int NblockM;
int NblockN;
int NblockK;
};
template <
typename T,
int BM,
int BN,
int BK,
int WM,
int WN,
bool transpose_a,
bool transpose_b,
int SL,
int Nstages>
__global__ void kernel_steel_gemm(
const T* a,
const T* b,
T* d,
__grid_constant__ const GemmParams params) {
const int bM_idx = (blockIdx.y << SL) + (blockIdx.x & ((1 << SL) - 1));
const int bN_idx = blockIdx.x >> SL;
if (params.NblockN <= bN_idx || params.NblockM <= bM_idx) {
return;
}
const int d_row = bM_idx * BM;
const int d_col = bN_idx * BN;
const size_t d_row_long = size_t(d_row);
const size_t d_col_long = size_t(d_col);
a += transpose_a ? d_row_long : d_row_long * params.K;
b += transpose_b ? d_col_long * params.K : d_col_long;
d += d_row_long * params.ldd + d_col_long;
auto block = cg::this_thread_block();
auto warp = cg::tiled_partition<32>(block);
const int lane_idx = warp.thread_rank();
const int warp_idx = warp.meta_group_rank();
const int wm = warp_idx / WN;
const int wn = warp_idx % WN;
constexpr int SM = BM / WM;
constexpr int SN = BN / WN;
constexpr int SK = BK;
constexpr int TK = SK / 16;
constexpr int NUM_WARPS = WM * WN;
// Allocate shared memory
extern __shared__ char shmem[];
SharedTile<T, BM, BK>(&as)[Nstages] =
*(SharedTile<T, BM, BK>(*)[Nstages])(&shmem[0]);
SharedTile<T, BN, BK>(&bs)[Nstages] = *(SharedTile<T, BN, BK>(*)[Nstages])(
&shmem[sizeof(T) * Nstages * BM * BK]);
// Allocate registers for the MMA
RegisterTile<float, SM, SN> C;
RegisterTile<T, SM, 16> A[TK];
RegisterTile<T, SN, 16> B[TK];
// Zero the accumulators
C.fill(0);
// Start gmem -> smem copies
int k_block_read = 0;
MLX_UNROLL
for (int bk = 0; bk < (Nstages - 1); bk++) {
load_async<NUM_WARPS>(
as[bk], as[bk].base_addr(), a + k_block_read, params.K);
load_async<NUM_WARPS>(
bs[bk], bs[bk].base_addr(), b + k_block_read, params.K);
k_block_read += BK;
cp_async_commit();
}
int smem_pipe_read = 0;
int smem_pipe_write = Nstages - 1;
// Wait till only 1 remains laoding
cp_async_wait<1>();
block.sync();
const int offset_m = wm * SM;
const int offset_n = wn * SN;
// Start smem -> register copy
A[0].load(
as[smem_pipe_read],
as[smem_pipe_read].base_addr(),
offset_m + lane_idx % 16,
lane_idx / 16 * 8);
B[0].load(
bs[smem_pipe_read],
bs[smem_pipe_read].base_addr(),
offset_n + lane_idx % 16,
lane_idx / 16 * 8);
// Main loop
for (int kb = 0; kb < params.NblockK; kb++) {
// Prepare next registers
{
A[1].load(
as[smem_pipe_read],
as[smem_pipe_read].base_addr(),
offset_m + lane_idx % 16,
16 + lane_idx / 16 * 8);
B[1].load(
bs[smem_pipe_read],
bs[smem_pipe_read].base_addr(),
offset_n + lane_idx % 16,
16 + lane_idx / 16 * 8);
}
// Prepare next smem
if ((kb + Nstages - 1) < params.NblockK) {
load_async<NUM_WARPS>(
as[smem_pipe_write],
as[smem_pipe_write].base_addr(),
a + k_block_read,
params.K);
load_async<NUM_WARPS>(
bs[smem_pipe_write],
bs[smem_pipe_write].base_addr(),
b + k_block_read,
params.K);
}
k_block_read += BK;
cp_async_commit();
smem_pipe_write = smem_pipe_read;
smem_pipe_read = smem_pipe_read + 1;
smem_pipe_read = (smem_pipe_read == Nstages) ? 0 : smem_pipe_read;
// Do current gemm
mma_t(C, A[0], B[0]);
// Do wait for next register
cp_async_wait<1>();
block.sync();
// Prepare next register (smem_pipe_read has moved to the next)
{
A[0].load(
as[smem_pipe_read],
as[smem_pipe_read].base_addr(),
offset_m + lane_idx % 16,
lane_idx / 16 * 8);
B[0].load(
bs[smem_pipe_read],
bs[smem_pipe_read].base_addr(),
offset_n + lane_idx % 16,
lane_idx / 16 * 8);
}
// Do current gemm
mma_t(C, A[1], B[1]);
}
// Wait and clear
cp_async_wait_all();
block.sync();
C.store_global(d, params.ldd, offset_m, offset_n);
}
} // namespace cu
void dispatch_steel_gemm(
const Stream& s,
cu::CommandEncoder& encoder,
const array& a,
const array& b,
array& d,
int M,
int N,
int K,
int lda,
int ldb,
int ldd,
bool a_transposed,
bool b_transposed) {
using DataType = cuda_type_t<float16_t>;
encoder.set_input_array(a);
encoder.set_input_array(b);
encoder.set_output_array(d);
constexpr int BM = 128;
constexpr int BN = 128;
constexpr int BK = 32;
constexpr int WM = 2;
constexpr int WN = 2;
constexpr int SL = 0;
constexpr int Nstages = 3;
constexpr uint32_t smem_bytes = BK * (BM + BN) * Nstages * sizeof(DataType);
const int NblockM = (M + BM - 1) / BM;
const int NblockN = (N + BN - 1) / BN;
const int NblockK = (K + BK - 1) / BK;
cu::GemmParams params{
/* int M = */ M,
/* int N = */ N,
/* int K = */ K,
/* int lda = */ lda,
/* int ldb = */ ldb,
/* int ldd = */ ldd,
/* int NblockM = */ NblockM,
/* int NblockN = */ NblockN,
/* int NblockK = */ NblockK,
};
// Prepare launch grid params
int tile = 1 << SL;
int tm = (NblockM + tile - 1) / tile;
int tn = NblockN * tile;
dim3 grid_dim(tn, tm, 1);
dim3 block_dim(32 * WM * WN, 1, 1);
dispatch_bool(a_transposed, [&](auto ta_) {
dispatch_bool(b_transposed, [&](auto tb_) {
constexpr bool ta = ta_.value;
constexpr bool tb = tb_.value;
auto kernel = cu::ab_t_aligned<DataType, BM, BN, BK>;
cudaFuncSetAttribute(
kernel, cudaFuncAttributeMaxDynamicSharedMemorySize, smem_bytes);
encoder.add_kernel_node(
kernel,
grid_dim,
block_dim,
smem_bytes,
a.data<DataType>(),
b.data<DataType>(),
d.data<DataType>(),
N,
K);
// auto kernel = cu::kernel_steel_gemm<DataType, BM, BN, BK, WM, WN, ta,
// tb, SL, Nstages>;
// cudaFuncSetAttribute(kernel,
// cudaFuncAttributeMaxDynamicSharedMemorySize, smem_bytes);
// encoder.add_kernel_node(
// kernel,
// grid_dim,
// block_dim,
// smem_bytes,
// a.data<DataType>(),
// b.data<DataType>(),
// d.data<DataType>(),
// params);
});
});
}
} // namespace mlx::core

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#pragma once
#include "mlx/backend/common/matmul.h"
#include "mlx/backend/cuda/device.h"
#include "mlx/primitives.h"
#include <nvtx3/nvtx3.hpp>
#include <numeric>
namespace mlx::core {
void dispatch_steel_gemm(
const Stream& s,
cu::CommandEncoder& encoder,
const array& a,
const array& b,
array& d,
int M,
int N,
int K,
int lda,
int ldb,
int ldd,
bool a_transposed,
bool b_transposed);
} // namespace mlx::core

26
mlx/backend/cuda/indexing.cpp
View File

@@ -29,12 +29,12 @@ void append_indices_arg(
const std::vector<array>& inputs,
int nidx,
int idx_ndim) {
std::vector<const void*> indices(nidx);
SmallVector<const void*> indices(nidx);
for (int i = 0; i < nidx; ++i) {
indices[i] = inputs[i + 1].data<void>();
}
args.append(std::move(indices));
std::vector<int32_t> indices_shape(nidx * idx_ndim);
SmallVector<int32_t> indices_shape(nidx * idx_ndim);
for (int i = 0; i < nidx; ++i) {
std::copy_n(
inputs[i + 1].shape().begin(),
@@ -42,7 +42,7 @@ void append_indices_arg(
indices_shape.data() + i * idx_ndim);
}
args.append(std::move(indices_shape));
std::vector<int64_t> indices_strides(nidx * idx_ndim);
SmallVector<int64_t> indices_strides(nidx * idx_ndim);
for (int i = 0; i < nidx; ++i) {
std::copy_n(
inputs[i + 1].strides().begin(),
@@ -110,7 +110,7 @@ void Gather::eval_gpu(const std::vector<array>& inputs, array& out) {
args.append<int32_t>(src.ndim());
args.append_ndim(slice_sizes_);
args.append(slice_size);
args.append(axes_);
args.append(SmallVector<int32_t>(axes_.begin(), axes_.end()));
append_indices_arg(args, inputs, nidx, idx_ndim);
std::string kernel_name = fmt::format(
@@ -128,8 +128,8 @@ void Gather::eval_gpu(const std::vector<array>& inputs, array& out) {
encoder.set_output_array(out);
auto kernel = mod.get_kernel(kernel_name);
auto [num_blocks, block_dims] = get_launch_args(kernel, out, large);
encoder.add_kernel_node(kernel, num_blocks, block_dims, args.args());
auto [num_blocks, block_dims] = get_launch_args(out, large);
encoder.add_kernel_node(kernel, num_blocks, block_dims, 0, args.args());
}
void Scatter::eval_gpu(const std::vector<array>& inputs, array& out) {
@@ -211,7 +211,7 @@ void Scatter::eval_gpu(const std::vector<array>& inputs, array& out) {
args.append_ndim(out.shape());
args.append_ndim(out.strides());
args.append<int32_t>(out.ndim());
args.append(axes_);
args.append(SmallVector<int32_t>(axes_.begin(), axes_.end()));
append_indices_arg(args, inputs, nidx, idx_ndim);
std::string kernel_name = fmt::format(
@@ -229,8 +229,8 @@ void Scatter::eval_gpu(const std::vector<array>& inputs, array& out) {
}
encoder.set_output_array(out);
auto kernel = mod.get_kernel(kernel_name);
auto [num_blocks, block_dims] = get_launch_args(kernel, upd, large);
encoder.add_kernel_node(kernel, num_blocks, block_dims, args.args());
auto [num_blocks, block_dims] = get_launch_args(upd, large);
encoder.add_kernel_node(kernel, num_blocks, block_dims, 0, args.args());
}
void GatherAxis::eval_gpu(const std::vector<array>& inputs, array& out) {
@@ -317,8 +317,8 @@ void GatherAxis::eval_gpu(const std::vector<array>& inputs, array& out) {
}
encoder.set_output_array(out);
auto kernel = mod.get_kernel(kernel_name);
auto [num_blocks, block_dims] = get_launch_args(kernel, idx, large);
encoder.add_kernel_node(kernel, num_blocks, block_dims, args.args());
auto [num_blocks, block_dims] = get_launch_args(idx, large);
encoder.add_kernel_node(kernel, num_blocks, block_dims, 0, args.args());
}
void ScatterAxis::eval_gpu(const std::vector<array>& inputs, array& out) {
@@ -421,8 +421,8 @@ void ScatterAxis::eval_gpu(const std::vector<array>& inputs, array& out) {
}
encoder.set_output_array(out);
auto kernel = mod.get_kernel(kernel_name);
auto [num_blocks, block_dims] = get_launch_args(kernel, idx, large);
encoder.add_kernel_node(kernel, num_blocks, block_dims, args.args());
auto [num_blocks, block_dims] = get_launch_args(idx, large);
encoder.add_kernel_node(kernel, num_blocks, block_dims, 0, args.args());
}
} // namespace mlx::core

121
mlx/backend/cuda/iterators/general_iterator.cuh
View File

@@ -1,121 +0,0 @@
// Copyright © 2025 Apple Inc.
#pragma once
#include <thrust/iterator/iterator_adaptor.h>
#include <cuda/std/utility>
#include "mlx/backend/cuda/kernel_utils.cuh"
namespace mlx::core::cu {
// Iterating non-contiguous array.
template <typename Iterator, typename IdxT = int64_t>
class general_iterator
: public thrust::
iterator_adaptor<general_iterator<Iterator, IdxT>, Iterator> {
public:
using super_t =
thrust::iterator_adaptor<general_iterator<Iterator, IdxT>, Iterator>;
using reference = typename super_t::reference;
using difference_type = typename super_t::difference_type;
__host__ __device__ general_iterator(
Iterator it,
IdxT index,
int ndim,
Shape shape,
Strides strides)
: super_t(it),
index_(index),
ndim_(ndim),
shape_(cuda::std::move(shape)),
strides_(cuda::std::move(strides)) {}
__host__ __device__ IdxT index() const {
return index_;
}
__host__ __device__ const Shape& shape() const {
return shape_;
}
__host__ __device__ const Strides& strides() const {
return strides_;
}
private:
friend class thrust::iterator_core_access;
__host__ __device__ bool equal(const general_iterator& other) const {
return this->base() == other.base() && this->index() == other.index();
}
__host__ __device__ void advance(difference_type n) {
this->index_ += n;
}
__host__ __device__ void increment() {
this->index_ += 1;
}
__host__ __device__ void decrement() {
this->index_ -= 1;
}
__host__ __device__ difference_type
distance_to(const general_iterator& other) const {
_CCCL_ASSERT(
this->base() == other.base(),
"Underlying iterator must point to same base iterator");
return other.index() - this->index();
}
// The dereference is device-only to avoid accidental running in host.
__device__ typename super_t::reference dereference() const {
IdxT offset = elem_to_loc(index_, shape_.data(), strides_.data(), ndim_);
return *(this->base() + offset);
}
IdxT index_;
int ndim_;
Shape shape_;
Strides strides_;
};
template <typename IdxT, typename Iterator>
__host__ __device__ auto make_general_iterator(
Iterator it,
IdxT index,
int ndim,
Shape shape,
Strides strides) {
return general_iterator<Iterator, IdxT>(
it, index, ndim, cuda::std::move(shape), cuda::std::move(strides));
}
template <typename IdxT, typename Iterator>
auto make_general_iterator(
Iterator it,
const std::vector<int32_t>& shape,
const std::vector<int64_t>& strides) {
return make_general_iterator<IdxT>(
it, 0, shape.size(), const_param(shape), const_param(strides));
}
template <typename IdxT, typename Iterator>
auto make_general_iterators(
Iterator it,
IdxT size,
const std::vector<int32_t>& shape,
const std::vector<int64_t>& strides) {
auto ndim = shape.size();
auto shape_arg = const_param(shape);
auto strides_arg = const_param(strides);
return std::make_pair(
make_general_iterator<IdxT>(it, 0, ndim, shape_arg, strides_arg),
make_general_iterator<IdxT>(it, size, ndim, shape_arg, strides_arg));
}
} // namespace mlx::core::cu

60
mlx/backend/cuda/iterators/strided_iterator.cuh
View File

@@ -1,60 +0,0 @@
// Copyright © 2025 Apple Inc.
#pragma once
#include <thrust/iterator/iterator_adaptor.h>
#include <thrust/iterator/iterator_facade.h>
namespace mlx::core::cu {
// RandomAccessIterator for strided access to array entries.
template <typename Iterator, typename Stride = int64_t>
class strided_iterator
: public thrust::
iterator_adaptor<strided_iterator<Iterator, Stride>, Iterator> {
public:
using super_t =
thrust::iterator_adaptor<strided_iterator<Iterator, Stride>, Iterator>;
using reference = typename super_t::reference;
using difference_type = typename super_t::difference_type;
__host__ __device__ strided_iterator(Iterator it, Stride stride)
: super_t(it), stride_(stride) {}
__host__ __device__ Stride stride() const {
return stride_;
}
private:
friend class thrust::iterator_core_access;
__host__ __device__ bool equal(const strided_iterator& other) const {
return this->base() == other.base();
}
__host__ __device__ void advance(difference_type n) {
this->base_reference() += n * stride_;
}
__host__ __device__ void increment() {
this->base_reference() += stride_;
}
__host__ __device__ void decrement() {
this->base_reference() -= stride_;
}
__host__ __device__ difference_type
distance_to(const strided_iterator& other) const {
const difference_type dist = other.base() - this->base();
_CCCL_ASSERT(
dist % stride() == 0,
"Underlying iterator difference must be divisible by the stride");
return dist / stride();
}
Stride stride_;
};
} // namespace mlx::core::cu

8
mlx/backend/cuda/jit_module.cpp
View File

@@ -9,7 +9,6 @@
#include <cstdlib>
#include <filesystem>
#include <fstream>
#include <unordered_map>
#include <fmt/format.h>
#include <nvrtc.h>
@@ -330,11 +329,16 @@ CUfunction JitModule::get_kernel(const std::string& kernel_name) {
return it->second;
}
std::unordered_map<std::string, JitModule>& get_jit_module_cache() {
static std::unordered_map<std::string, JitModule> map;
return map;
}
JitModule& get_jit_module(
const mlx::core::Device& device,
const std::string& name,
const KernelBuilder& builder) {
static std::unordered_map<std::string, JitModule> map;
auto& map = get_jit_module_cache();
auto it = map.find(name);
if (it == map.end()) {
it = map.try_emplace(name, cu::device(device), name, builder).first;

19
mlx/backend/cuda/jit_module.h
View File

@@ -40,19 +40,14 @@ struct KernelArgs {
}
template <typename T>
void append(std::vector<T> vec) {
if (vec.empty()) {
// The nullptr can not be used as arg, pass something not null.
append(std::monostate{});
} else {
append_ptr(vec.data());
void append(SmallVector<T> vec) {
storage_.emplace_back(std::move(vec));
}
append_ptr(std::get<SmallVector<T>>(storage_.back()).data());
}
// Make sure the arg is copied to an array with size of NDIM.
template <size_t NDIM = MAX_NDIM, typename T>
void append_ndim(std::vector<T> vec) {
void append_ndim(SmallVector<T> vec) {
if (vec.size() > NDIM) {
throw std::runtime_error(
fmt::format("ndim can not be larger than {}.", NDIM));
@@ -76,9 +71,9 @@ struct KernelArgs {
int32_t,
uint32_t,
int64_t,
std::vector<const void*>,
std::vector<int32_t>,
std::vector<int64_t>>;
SmallVector<const void*>,
SmallVector<int32_t>,
SmallVector<int64_t>>;
std::deque<Arg> storage_;
};
@@ -99,6 +94,8 @@ class JitModule {
std::unordered_map<std::string, CUfunction> kernels_;
};
std::unordered_map<std::string, JitModule>& get_jit_module_cache();
JitModule& get_jit_module(
const mlx::core::Device& device,
const std::string& name,

21
mlx/backend/cuda/kernel_utils.cu
View File

@@ -30,4 +30,25 @@ std::pair<dim3, dim3> get_grid_and_block(int dim0, int dim1, int dim2) {
return std::make_pair(dim3(gx, gy, gz), dim3(bx, by, bz));
}
std::tuple<dim3, uint> get_launch_args(
size_t size,
const Shape& shape,
const Strides& strides,
bool large,
int work_per_thread) {
size_t nthreads = cuda::ceil_div(size, work_per_thread);
uint block_dim = 1024;
if (block_dim > nthreads) {
block_dim = nthreads;
}
dim3 num_blocks;
if (large) {
num_blocks = get_2d_grid_dims(shape, strides, work_per_thread);
num_blocks.x = cuda::ceil_div(num_blocks.x, block_dim);
} else {
num_blocks.x = cuda::ceil_div(nthreads, block_dim);
}
return std::make_tuple(num_blocks, block_dim);
}
} // namespace mlx::core

46
mlx/backend/cuda/kernel_utils.cuh
View File

@@ -101,7 +101,7 @@ inline constexpr bool is_inexact_v = is_floating_v<T> || is_complex_v<T>;
// Utility to copy data from vector to array in host.
template <int NDIM = MAX_NDIM, typename T = int32_t>
inline cuda::std::array<T, NDIM> const_param(const std::vector<T>& vec) {
inline cuda::std::array<T, NDIM> const_param(const SmallVector<T>& vec) {
if (vec.size() > NDIM) {
throw std::runtime_error(
fmt::format("ndim can not be larger than {}.", NDIM));
@@ -120,53 +120,19 @@ dim3 get_2d_grid_dims(
size_t divisor);
std::pair<dim3, dim3> get_grid_and_block(int dim0, int dim1, int dim2);
// Return a block size that achieves maximum potential occupancy for kernel.
template <typename T>
inline uint max_occupancy_block_dim(T kernel) {
int _, block_dim;
if constexpr (std::is_same_v<T, CUfunction>) {
CHECK_CUDA_ERROR(
cuOccupancyMaxPotentialBlockSize(&_, &block_dim, kernel, 0, 0, 0));
} else {
CHECK_CUDA_ERROR(
cudaOccupancyMaxPotentialBlockSize(&_, &block_dim, kernel));
}
return block_dim;
}
// Get the num_blocks and block_dims that maximize occupancy for |kernel|,
// assuming each thread handles |work_per_thread| elements of |arr|.
template <typename T>
inline std::tuple<dim3, uint> get_launch_args(
T kernel,
std::tuple<dim3, uint> get_launch_args(
size_t size,
const Shape& shape,
const Strides& strides,
bool large,
int work_per_thread = 1) {
size_t nthreads = cuda::ceil_div(size, work_per_thread);
uint block_dim = max_occupancy_block_dim(kernel);
if (block_dim > nthreads) {
block_dim = nthreads;
}
dim3 num_blocks;
if (large) {
num_blocks = get_2d_grid_dims(shape, strides, work_per_thread);
num_blocks.x = cuda::ceil_div(num_blocks.x, block_dim);
} else {
num_blocks.x = cuda::ceil_div(nthreads, block_dim);
}
return std::make_tuple(num_blocks, block_dim);
}
int work_per_thread = 1);
template <typename T>
inline std::tuple<dim3, uint> get_launch_args(
T kernel,
const array& arr,
bool large,
int work_per_thread = 1) {
inline std::tuple<dim3, uint>
get_launch_args(const array& arr, bool large, int work_per_thread = 1) {
return get_launch_args(
kernel, arr.size(), arr.shape(), arr.strides(), large, work_per_thread);
arr.size(), arr.shape(), arr.strides(), large, work_per_thread);
}
} // namespace mlx::core

89
mlx/backend/cuda/layer_norm.cu
View File

@@ -1,7 +1,6 @@
// Copyright © 2025 Apple Inc.
#include "mlx/backend/cuda/device.h"
#include "mlx/backend/cuda/iterators/strided_iterator.cuh"
#include "mlx/backend/cuda/kernel_utils.cuh"
#include "mlx/backend/cuda/reduce/reduce.cuh"
#include "mlx/backend/gpu/copy.h"
@@ -11,8 +10,6 @@
#include <cooperative_groups.h>
#include <cooperative_groups/reduce.h>
#include <nvtx3/nvtx3.hpp>
#include <cub/block/block_load.cuh>
#include <cub/block/block_reduce.cuh>
namespace mlx::core {
@@ -75,9 +72,11 @@ __global__ void layer_norm(
float sum = 0;
for (int r = 0; r < cuda::ceil_div(axis_size, BLOCK_DIM * N_READS); ++r) {
auto index = r * BLOCK_DIM + block.thread_rank();
T xn[N_READS] = {};
cub::LoadDirectBlocked(index, x, xn, axis_size);
sum += static_cast<float>(cub::ThreadReduce(xn, cuda::std::plus<>{}));
auto xn = load_vector<N_READS>(x, index, axis_size, T(0));
#pragma unroll
for (int i = 0; i < N_READS; ++i) {
sum += static_cast<float>(xn[i]);
}
}
sum = BlockReduceT{block, temp}.Sum(sum);
@@ -88,12 +87,19 @@ __global__ void layer_norm(
float normalizer = 0;
for (int r = 0; r < cuda::ceil_div(axis_size, BLOCK_DIM * N_READS); ++r) {
auto index = r * BLOCK_DIM + block.thread_rank();
T xn[N_READS];
cub::LoadDirectBlocked(index, x, xn, axis_size, mean);
if ((index + 1) * N_READS <= axis_size) {
auto xn = load_vector<N_READS>(x, index);
#pragma unroll
for (int i = 0; i < N_READS; ++i) {
float t = static_cast<float>(xn[i]) - mean;
normalizer += t * t;
}
} else {
for (int i = index * N_READS; i < axis_size; ++i) {
float t = static_cast<float>(x[i]) - mean;
normalizer += t * t;
}
}
}
normalizer = BlockReduceT{block, temp}.Sum(normalizer);
normalizer = rsqrt(normalizer / axis_size + eps);
@@ -101,17 +107,15 @@ __global__ void layer_norm(
// Outputs.
for (int r = 0; r < cuda::ceil_div(axis_size, BLOCK_DIM * N_READS); ++r) {
auto index = r * BLOCK_DIM + block.thread_rank();
T xn[N_READS];
T wn[N_READS];
T bn[N_READS];
cub::LoadDirectBlocked(index, x, xn, axis_size);
cub::LoadDirectBlocked(index, strided_iterator(w, w_stride), wn, axis_size);
cub::LoadDirectBlocked(index, strided_iterator(b, b_stride), bn, axis_size);
auto xn = load_vector<N_READS>(x, index, axis_size, T(0));
auto wn = load_vector<N_READS>(w, index, axis_size, w_stride, T(0));
auto bn = load_vector<N_READS>(b, index, axis_size, b_stride, T(0));
#pragma unroll
for (int i = 0; i < N_READS; ++i) {
float norm = (static_cast<float>(xn[i]) - mean) * normalizer;
xn[i] = wn[i] * static_cast<T>(norm) + bn[i];
}
cub::StoreDirectBlocked(index, out, xn, axis_size);
store_vector<N_READS>(out, index, xn, axis_size);
}
}
@@ -144,9 +148,11 @@ __global__ void layer_norm_vjp(
float sum = 0;
for (int r = 0; r < cuda::ceil_div(axis_size, BLOCK_DIM * N_READS); ++r) {
auto index = r * BLOCK_DIM + block.thread_rank();
T xn[N_READS] = {};
cub::LoadDirectBlocked(index, x, xn, axis_size);
sum += static_cast<float>(cub::ThreadReduce(xn, cuda::std::plus<>{}));
auto xn = load_vector<N_READS>(x, index, axis_size, T(0));
#pragma unroll
for (int i = 0; i < N_READS; ++i) {
sum += static_cast<float>(xn[i]);
}
}
sum = BlockReduceF{block, temp.f}.Sum(sum);
@@ -156,20 +162,29 @@ __global__ void layer_norm_vjp(
// Normalizer.
float3 factors = {};
for (int r = 0; r < cuda::ceil_div(axis_size, BLOCK_DIM * N_READS); ++r) {
T xn[N_READS];
T wn[N_READS] = {};
T gn[N_READS] = {};
auto index = r * BLOCK_DIM + block.thread_rank();
cub::LoadDirectBlocked(index, x, xn, axis_size, mean);
cub::LoadDirectBlocked(index, g, gn, axis_size);
cub::LoadDirectBlocked(index, strided_iterator(w, w_stride), wn, axis_size);
for (int i = 0; i < N_READS; i++) {
auto gn = load_vector<N_READS>(g, index, axis_size, T(0));
auto wn = load_vector<N_READS>(w, index, axis_size, w_stride, T(0));
if ((index + 1) * N_READS <= axis_size) {
auto xn = load_vector<N_READS>(x, index);
#pragma unroll
for (int i = 0; i < N_READS; ++i) {
float t = static_cast<float>(xn[i]) - mean;
float wi = wn[i];
float gi = gn[i];
float wg = wi * gi;
factors = plus_f3(factors, {wg, wg * t, t * t});
}
} else {
for (int i = index * N_READS; i < axis_size; ++i) {
float t = static_cast<float>(x[i]) - mean;
float wi = wn[i];
float gi = gn[i];
float wg = wi * gi;
factors = plus_f3(factors, {wg, wg * t, t * t});
}
}
}
factors = BlockReduceF3{block, temp.f3}.Reduce(factors, plus_f3, {});
float meanwg = factors.x / axis_size;
@@ -180,12 +195,10 @@ __global__ void layer_norm_vjp(
// Outputs.
for (int r = 0; r < cuda::ceil_div(axis_size, BLOCK_DIM * N_READS); ++r) {
auto index = r * BLOCK_DIM + block.thread_rank();
T xn[N_READS];
T wn[N_READS];
T gn[N_READS];
cub::LoadDirectBlocked(index, x, xn, axis_size);
cub::LoadDirectBlocked(index, g, gn, axis_size);
cub::LoadDirectBlocked(index, strided_iterator(w, w_stride), wn, axis_size);
auto xn = load_vector<N_READS>(x, index, axis_size, T(0));
auto gn = load_vector<N_READS>(g, index, axis_size, T(0));
auto wn = load_vector<N_READS>(w, index, axis_size, w_stride, T(0));
for (int i = 0; i < N_READS; i++) {
float xi = (static_cast<float>(xn[i]) - mean) * normalizer;
float wi = wn[i];
@@ -195,9 +208,9 @@ __global__ void layer_norm_vjp(
wn[i] = gi * xi;
}
}
cub::StoreDirectBlocked(index, gx, xn, axis_size);
store_vector<N_READS>(gx, index, xn, axis_size);
if constexpr (HAS_W) {
cub::StoreDirectBlocked(index, gw, wn, axis_size);
store_vector<N_READS>(gw, index, wn, axis_size);
}
}
}
@@ -258,14 +271,15 @@ void LayerNorm::eval_gpu(
encoder.set_input_array(b);
encoder.set_output_array(out);
dispatch_float_types(out.dtype(), "layernorm", [&](auto type_tag) {
constexpr uint32_t N_READS = 4;
dispatch_block_dim(cuda::ceil_div(axis_size, N_READS), [&](auto block_dim) {
using DataType = cuda_type_t<MLX_GET_TYPE(type_tag)>;
constexpr int N_READS = 16 / sizeof(DataType);
dispatch_block_dim(cuda::ceil_div(axis_size, N_READS), [&](auto block_dim) {
auto kernel = cu::layer_norm<DataType, block_dim(), N_READS>;
encoder.add_kernel_node(
kernel,
n_rows,
block_dim(),
0,
x.data<DataType>(),
w.data<DataType>(),
b.data<DataType>(),
@@ -365,10 +379,10 @@ void LayerNormVJP::eval_gpu(
encoder.set_output_array(gw_temp);
dispatch_float_types(gx.dtype(), "layernorm_vjp", [&](auto type_tag) {
dispatch_bool(has_w, [&](auto has_w_constant) {
constexpr int N_READS = 4;
using DataType = cuda_type_t<MLX_GET_TYPE(type_tag)>;
constexpr int N_READS = 16 / sizeof(DataType);
dispatch_block_dim(
cuda::ceil_div(axis_size, N_READS), [&](auto block_dim) {
using DataType = cuda_type_t<MLX_GET_TYPE(type_tag)>;
auto kernel = cu::layer_norm_vjp<
DataType,
has_w_constant.value,
@@ -378,6 +392,7 @@ void LayerNormVJP::eval_gpu(
kernel,
n_rows,
block_dim(),
0,
x.data<DataType>(),
w.data<DataType>(),
g.data<DataType>(),

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

@@ -43,20 +43,19 @@ __global__ void logsumexp(const T* in, T* out, int axis_size) {
AccT maxval = Limits<AccT>::finite_min();
AccT normalizer = 0;
for (int r = 0; r < cuda::ceil_div(axis_size, BLOCK_DIM * N_READS); r++) {
AccT vals[N_READS];
cub::LoadDirectBlocked(
r * BLOCK_DIM + block.thread_rank(),
make_cast_iterator<AccT>(in),
vals,
axis_size,
Limits<AccT>::min());
auto index = r * BLOCK_DIM + block.thread_rank();
auto vals = load_vector<N_READS>(in, index, axis_size, Limits<T>::min());
prevmax = maxval;
maxval = max_op(maxval, cub::ThreadReduce(vals, max_op));
#pragma unroll
for (int i = 0; i < N_READS; ++i) {
maxval = max_op(maxval, static_cast<AccT>(vals[i]));
}
// Online normalizer calculation for softmax:
// https://github.com/NVIDIA/online-softmax
normalizer = normalizer * softmax_exp(prevmax - maxval);
for (int i = 0; i < N_READS; i++) {
normalizer = normalizer + softmax_exp(vals[i] - maxval);
normalizer =
normalizer + softmax_exp(static_cast<AccT>(vals[i]) - maxval);
}
}
@@ -143,14 +142,15 @@ void LogSumExp::eval_gpu(const std::vector<array>& inputs, array& out) {
encoder.set_input_array(in);
encoder.set_output_array(out);
dispatch_float_types(out.dtype(), "logsumexp", [&](auto type_tag) {
constexpr int N_READS = 4;
dispatch_block_dim(cuda::ceil_div(axis_size, N_READS), [&](auto block_dim) {
using DataType = cuda_type_t<MLX_GET_TYPE(type_tag)>;
constexpr int N_READS = 16 / sizeof(DataType);
dispatch_block_dim(cuda::ceil_div(axis_size, N_READS), [&](auto block_dim) {
auto kernel = cu::logsumexp<DataType, float, block_dim(), N_READS>;
encoder.add_kernel_node(
kernel,
n_rows,
block_dim(),
0,
in.data<DataType>(),
out.data<DataType>(),
axis_size);

159
mlx/backend/cuda/lru_cache.h Normal file
View File

@@ -0,0 +1,159 @@
// Copyright © 2025 Apple Inc.
#pragma once
#include <cstring>
#include <list>
#include <unordered_map>
#include <utility>
namespace mlx::core {
template <
typename K,
typename V,
template <typename...> typename M = std::unordered_map>
class LRUCache {
public:
using value_type = std::pair<K, V>;
using list_type = std::list<value_type>;
using iterator = typename list_type::iterator;
using const_iterator = typename list_type::const_iterator;
using map_type = M<K, iterator>;
explicit LRUCache(size_t capacity) : capacity_(capacity) {
if (capacity == 0) {
throw std::runtime_error("LRUCache requires capacity > 0.");
}
}
size_t size() const {
return map_.size();
}
size_t capacity() const {
return capacity_;
}
bool empty() const {
return vlist_.empty();
}
void resize(size_t new_capacity) {
capacity_ = new_capacity;
trim();
}
iterator begin() {
return vlist_.begin();
}
const_iterator begin() const {
return vlist_.begin();
}
iterator end() {
return vlist_.end();
}
const_iterator end() const {
return vlist_.end();
}
void clear() {
map_.clear();
vlist_.clear();
}
iterator find(const K& key) {
auto it = map_.find(key);
if (it == map_.end())
return end();
vlist_.splice(vlist_.begin(), vlist_, it->second);
return it->second;
}
template <typename U>
std::pair<iterator, bool> emplace(const K& key, U&& value) {
auto it = map_.find(key);
if (it != map_.end()) {
vlist_.splice(vlist_.begin(), vlist_, it->second);
return {it->second, false};
}
vlist_.emplace_front(key, std::forward<U>(value));
map_[key] = vlist_.begin();
trim();
return {vlist_.begin(), true};
}
iterator erase(iterator pos) {
map_.erase(pos->first);
return vlist_.erase(pos);
}
V& operator[](const K& key) {
auto it = find(key);
if (it == end()) {
it = emplace(key, V{}).first;
}
return it->second;
}
private:
void trim() {
while (map_.size() > capacity_) {
auto last = std::prev(vlist_.end());
map_.erase(last->first);
vlist_.pop_back();
}
}
list_type vlist_;
map_type map_;
size_t capacity_;
};
// Turn a POD struct into a container key by doing bytes compare.
template <typename T>
struct BytesKey {
T pod;
static_assert(std::is_standard_layout_v<T>, "T is not POD");
BytesKey(T pod) : pod(std::move(pod)) {}
BytesKey(const BytesKey& other) {
memcpy(&pod, &other.pod, sizeof(T));
}
BytesKey(BytesKey&& other) {
memcpy(&pod, &other.pod, sizeof(T));
}
bool operator==(const BytesKey& other) const {
auto* ptr1 = reinterpret_cast<const uint8_t*>(&pod);
auto* ptr2 = reinterpret_cast<const uint8_t*>(&other.pod);
return memcmp(ptr1, ptr2, sizeof(T)) == 0;
}
};
// Compute hash according to the bytes value of T.
template <typename T>
struct BytesHash {
static_assert(std::is_standard_layout_v<T>, "T is not POD");
size_t operator()(const T& pod) const {
auto* ptr = reinterpret_cast<const uint8_t*>(&pod);
uint32_t value = 0x811C9DC5;
for (int i = 0; i < sizeof(T); ++i) {
value ^= ptr[i];
value *= 0x01000193;
}
return value;
}
};
template <typename K, typename V>
using BytesKeyHashMap = std::unordered_map<K, V, BytesHash<K>>;
template <typename K, typename V>
using LRUBytesKeyCache = LRUCache<BytesKey<K>, V, BytesKeyHashMap>;
} // namespace mlx::core

384
mlx/backend/cuda/matmul.cpp
View File

@@ -2,289 +2,17 @@
#include "mlx/backend/common/matmul.h"
#include "mlx/backend/cuda/device.h"
#include "mlx/backend/cuda/gemms/cublas_gemm.h"
#include "mlx/backend/cuda/gemms/gemv.h"
#include "mlx/backend/gpu/copy.h"
#include "mlx/dtype_utils.h"
#include "mlx/primitives.h"
#include "mlx/utils.h"
#include <cublasLt.h>
#include <fmt/format.h>
#include "mlx/backend/cuda/gemms/steel_gemm.h"
#include <nvtx3/nvtx3.hpp>
#include <numeric>
namespace mlx::core {
namespace cu {
#define CHECK_CUBLAS_ERROR(cmd) check_cublas_error(#cmd, (cmd))
void check_cublas_error(const char* name, cublasStatus_t err) {
if (err != CUBLAS_STATUS_SUCCESS) {
// TODO: Use cublasGetStatusString when it is widely available.
throw std::runtime_error(
fmt::format("{} failed with code: {}.", name, static_cast<int>(err)));
}
}
struct CublasPreference {
CublasPreference(Device& device) {
// The recommended cublas workspace size is 4 MiB for pre-Hopper and 32 MiB
// for Hopper+:
// https://docs.nvidia.com/cuda/cublas/#cublassetworkspace
uint64_t MiB = 1024 * 1024;
uint64_t workspace_size =
device.compute_capability_major() >= 9 ? 32 * MiB : 4 * MiB;
CHECK_CUBLAS_ERROR(cublasLtMatmulPreferenceCreate(&pref_));
CHECK_CUBLAS_ERROR(cublasLtMatmulPreferenceSetAttribute(
pref_,
CUBLASLT_MATMUL_PREF_MAX_WORKSPACE_BYTES,
&workspace_size,
sizeof(uint64_t)));
}
~CublasPreference() {
CHECK_CUBLAS_ERROR(cublasLtMatmulPreferenceDestroy(pref_));
}
cublasLtMatmulPreference_t pref_{nullptr};
};
cublasLtMatmulPreference_t cublas_preference(Device& device) {
static CublasPreference pref(device);
return pref.pref_;
}
class MatMul {
public:
MatMul(
Device& device,
Dtype dtype,
bool a_transposed,
uint64_t a_rows,
uint64_t a_cols,
int64_t lda,
bool b_transposed,
uint64_t b_rows,
uint64_t b_cols,
int64_t ldb,
int32_t batch_count,
int64_t a_batch_stride,
int64_t b_batch_stride)
: handle_(device.lt_handle()), pref_(cublas_preference(device)) {
heuristic_.state = CUBLAS_STATUS_NOT_INITIALIZED;
auto scale_type = dtype_to_cuda_type(dtype);
if (dtype == bfloat16 || dtype == float16) {
scale_type = CUDA_R_32F;
}
CHECK_CUBLAS_ERROR(cublasLtMatmulDescCreate(
&matmul_desc_, dtype_to_compute_type(dtype), scale_type));
int32_t pointer_mode = CUBLASLT_POINTER_MODE_HOST;
CHECK_CUBLAS_ERROR(cublasLtMatmulDescSetAttribute(
matmul_desc_,
CUBLASLT_MATMUL_DESC_POINTER_MODE,
&pointer_mode,
sizeof(int32_t)));
cublasOperation_t op = CUBLAS_OP_N;
CHECK_CUBLAS_ERROR(cublasLtMatmulDescSetAttribute(
matmul_desc_,
CUBLASLT_MATMUL_DESC_TRANSA,
&op,
sizeof(cublasOperation_t)));
CHECK_CUBLAS_ERROR(cublasLtMatmulDescSetAttribute(
matmul_desc_,
CUBLASLT_MATMUL_DESC_TRANSB,
&op,
sizeof(cublasOperation_t)));
auto type = dtype_to_cuda_type(dtype);
a_desc_ = create_matrix_layout(
type, a_rows, a_cols, a_transposed, lda, batch_count, a_batch_stride);
b_desc_ = create_matrix_layout(
type, b_rows, b_cols, b_transposed, ldb, batch_count, b_batch_stride);
out_desc_ = create_matrix_layout(
type, a_rows, b_cols, false, b_cols, batch_count, a_rows * b_cols);
}
MatMul(
Device& device,
Dtype dtype,
bool a_transposed,
uint64_t a_rows,
uint64_t a_cols,
int64_t lda,
bool b_transposed,
uint64_t b_rows,
uint64_t b_cols,
int64_t ldb,
int64_t ldc,
int32_t batch_count,
int64_t a_batch_stride,
int64_t b_batch_stride,
int64_t c_batch_stride)
: MatMul(
device,
dtype,
a_transposed,
a_rows,
a_cols,
lda,
b_transposed,
b_rows,
b_cols,
ldb,
batch_count,
a_batch_stride,
b_batch_stride) {
auto type = dtype_to_cuda_type(dtype);
c_desc_ = create_matrix_layout(
type, a_rows, b_cols, false, ldc, batch_count, c_batch_stride);
}
~MatMul() {
CHECK_CUBLAS_ERROR(cublasLtMatrixLayoutDestroy(a_desc_));
CHECK_CUBLAS_ERROR(cublasLtMatrixLayoutDestroy(b_desc_));
CHECK_CUBLAS_ERROR(cublasLtMatrixLayoutDestroy(c_desc_));
CHECK_CUBLAS_ERROR(cublasLtMatrixLayoutDestroy(out_desc_));
CHECK_CUBLAS_ERROR(cublasLtMatmulDescDestroy(matmul_desc_));
}
void run(
cu::CommandEncoder& encoder,
void* out,
void* a,
void* b,
void* c = nullptr,
float alpha = 1,
float beta = 0) {
if (heuristic_.state != CUBLAS_STATUS_SUCCESS) {
int ret = 0;
CHECK_CUBLAS_ERROR(cublasLtMatmulAlgoGetHeuristic(
handle_,
matmul_desc_,
a_desc_,
b_desc_,
out_desc_,
out_desc_,
pref_,
1,
&heuristic_,
&ret));
if (ret == 0) {
throw std::runtime_error("Can not find algorithm for matmul.");
}
}
void* workspace_ptr = nullptr;
if (heuristic_.workspaceSize > 0) {
array workspace(
allocator::malloc(heuristic_.workspaceSize),
{static_cast<int>(heuristic_.workspaceSize)},
int8);
encoder.add_temporary(workspace);
workspace_ptr = workspace.data<void>();
}
auto capture = encoder.capture_context();
CHECK_CUBLAS_ERROR(cublasLtMatmul(
handle_,
matmul_desc_,
&alpha,
a,
a_desc_,
b,
b_desc_,
&beta,
c ? c : out,
c ? c_desc_ : out_desc_,
out,
out_desc_,
&heuristic_.algo,
workspace_ptr,
heuristic_.workspaceSize,
encoder.stream()));
}
private:
cublasComputeType_t dtype_to_compute_type(Dtype dtype) {
switch (dtype) {
case float16:
return CUBLAS_COMPUTE_32F;
case bfloat16:
return CUBLAS_COMPUTE_32F;
case float32:
return mlx::core::env::enable_tf32() ? CUBLAS_COMPUTE_32F_FAST_TF32
: CUBLAS_COMPUTE_32F;
case float64:
case complex64:
return CUBLAS_COMPUTE_64F;
default:
throw std::runtime_error(fmt::format(
"Unsupported dtype in MatMul: {}.", dtype_to_string(dtype)));
}
}
cudaDataType_t dtype_to_cuda_type(Dtype dtype) {
switch (dtype) {
case float16:
return CUDA_R_16F;
case bfloat16:
return CUDA_R_16BF;
case float32:
return CUDA_R_32F;
case float64:
return CUDA_R_64F;
case complex64:
return CUDA_C_32F;
default:
throw std::runtime_error(fmt::format(
"Unsupported dtype in MatMul: {}.", dtype_to_string(dtype)));
}
}
cublasLtMatrixLayout_t create_matrix_layout(
cudaDataType_t type,
uint64_t rows,
uint64_t cols,
bool transposed,
int64_t ld,
int32_t batch_count,
int64_t batch_stride) {
cublasLtMatrixLayout_t desc;
CHECK_CUBLAS_ERROR(cublasLtMatrixLayoutCreate(&desc, type, rows, cols, ld));
cublasLtOrder_t order =
transposed ? CUBLASLT_ORDER_COL : CUBLASLT_ORDER_ROW;
CHECK_CUBLAS_ERROR(cublasLtMatrixLayoutSetAttribute(
desc, CUBLASLT_MATRIX_LAYOUT_ORDER, &order, sizeof(cublasLtOrder_t)));
if (batch_count > 1) {
CHECK_CUBLAS_ERROR(cublasLtMatrixLayoutSetAttribute(
desc,
CUBLASLT_MATRIX_LAYOUT_BATCH_COUNT,
&batch_count,
sizeof(int32_t)));
CHECK_CUBLAS_ERROR(cublasLtMatrixLayoutSetAttribute(
desc,
CUBLASLT_MATRIX_LAYOUT_STRIDED_BATCH_OFFSET,
&batch_stride,
sizeof(int64_t)));
}
return desc;
}
cublasLtMatmulPreference_t pref_{nullptr};
cublasLtHandle_t handle_{nullptr};
cublasLtMatmulDesc_t matmul_desc_{nullptr};
cublasLtMatrixLayout_t a_desc_{nullptr};
cublasLtMatrixLayout_t b_desc_{nullptr};
cublasLtMatrixLayout_t c_desc_{nullptr};
cublasLtMatrixLayout_t out_desc_{nullptr};
cublasLtMatmulHeuristicResult_t heuristic_;
};
} // namespace cu
namespace {
std::tuple<bool, int64_t, array>
@@ -353,10 +81,43 @@ void Matmul::eval_gpu(const std::vector<array>& inputs, array& out) {
batch_shape = {1};
}
if (cu::can_use_gemv(M, N, K, a_transposed, b_transposed)) {
cu::gemv(
a,
b,
out,
M,
N,
K,
batch_count,
batch_shape,
a_batch_strides,
b_batch_strides,
encoder);
return;
}
if (out.dtype() == float16 && batch_count == 1 && !a_transposed &&
b_transposed) {
return dispatch_steel_gemm(
/* const Stream& s = */ s,
/* cu::CommandEncoder& encoder = */ encoder,
/* const array& a = */ a,
/* const array& b = */ b,
/* array& d = */ out,
/* int M = */ M,
/* int N = */ N,
/* int K = */ K,
/* int lda = */ lda,
/* int ldb = */ ldb,
/* int ldd = */ N,
/* bool a_transposed = */ a_transposed,
/* bool b_transposed = */ b_transposed);
}
/////////////////////////////////////////////////////////////////////////////
// Invoke cublasLt
cu::MatMul matmul(
CublasGemm gemm(
cu::device(s.device),
a.dtype(),
a_transposed,
@@ -370,28 +131,7 @@ void Matmul::eval_gpu(const std::vector<array>& inputs, array& out) {
batch_shape.back(),
a_batch_strides.back(),
b_batch_strides.back());
encoder.set_input_array(a);
encoder.set_input_array(b);
encoder.set_output_array(out);
auto nbatch = batch_count / batch_shape.back();
if (nbatch == 1) {
matmul.run(encoder, out.data<int8_t>(), a.data<int8_t>(), b.data<int8_t>());
return;
}
ContiguousIterator a_it(batch_shape, a_batch_strides, batch_shape.size() - 1);
ContiguousIterator b_it(batch_shape, b_batch_strides, batch_shape.size() - 1);
auto concurrent = encoder.concurrent_context();
for (size_t i = 0; i < nbatch; ++i) {
matmul.run(
encoder,
out.data<int8_t>() + out.itemsize() * i * batch_shape.back() * M * N,
a.data<int8_t>() + a.itemsize() * a_it.loc,
b.data<int8_t>() + b.itemsize() * b_it.loc);
a_it.step();
b_it.step();
}
gemm.run(encoder, out, a, b, batch_shape, a_batch_strides, b_batch_strides);
}
void AddMM::eval_gpu(const std::vector<array>& inputs, array& out) {
@@ -459,7 +199,7 @@ void AddMM::eval_gpu(const std::vector<array>& inputs, array& out) {
/////////////////////////////////////////////////////////////////////////////
// Invoke cublasLt
cu::MatMul matmul(
CublasGemm gemm(
cu::device(s.device),
a.dtype(),
a_transposed,
@@ -475,42 +215,18 @@ void AddMM::eval_gpu(const std::vector<array>& inputs, array& out) {
a_batch_strides.back(),
b_batch_strides.back(),
c_batch_strides.back());
encoder.set_input_array(a);
encoder.set_input_array(b);
encoder.set_input_array(c);
encoder.set_output_array(out);
auto nbatch = batch_count / batch_shape.back();
if (nbatch == 1) {
matmul.run(
gemm.run(
encoder,
out.data<int8_t>(),
a.data<int8_t>(),
b.data<int8_t>(),
c.data<int8_t>(),
out,
a,
b,
c,
batch_shape,
a_batch_strides,
b_batch_strides,
c_batch_strides,
alpha_,
beta_);
return;
}
ContiguousIterator a_it(batch_shape, a_batch_strides, batch_shape.size() - 1);
ContiguousIterator b_it(batch_shape, b_batch_strides, batch_shape.size() - 1);
ContiguousIterator c_it(batch_shape, c_batch_strides, batch_shape.size() - 1);
auto concurrent = encoder.concurrent_context();
for (size_t i = 0; i < nbatch; ++i) {
matmul.run(
encoder,
out.data<int8_t>() + out.itemsize() * i * batch_shape.back() * M * N,
a.data<int8_t>() + a.itemsize() * a_it.loc,
b.data<int8_t>() + b.itemsize() * b_it.loc,
c.data<int8_t>() + c.itemsize() * c_it.loc,
alpha_,
beta_);
a_it.step();
b_it.step();
c_it.step();
}
}
} // namespace mlx::core

55
mlx/backend/cuda/primitives.cpp Normal file
View File

@@ -0,0 +1,55 @@
// Copyright © 2025 Apple Inc.
#include "mlx/distributed/primitives.h"
#include "mlx/fast_primitives.h"
#include "mlx/primitives.h"
namespace mlx::core {
#define NO_GPU_MULTI(func) \
void func::eval_gpu( \
const std::vector<array>& inputs, std::vector<array>& outputs) { \
throw std::runtime_error(#func " has no CUDA implementation."); \
}
#define NO_GPU_USE_FALLBACK(func) \
bool func::use_fallback(Stream s) { \
return true; \
} \
NO_GPU_MULTI(func)
#define NO_GPU(func) \
void func::eval_gpu(const std::vector<array>& inputs, array& out) { \
throw std::runtime_error(#func " has no CUDA implementation."); \
}
NO_GPU(BlockMaskedMM)
NO_GPU(DynamicSlice)
NO_GPU(DynamicSliceUpdate)
NO_GPU(FFT)
NO_GPU(GatherMM)
NO_GPU(GatherQMM)
NO_GPU(Hadamard)
NO_GPU(Load)
NO_GPU_MULTI(LUF)
NO_GPU_MULTI(QRF)
NO_GPU(QuantizedMatmul)
NO_GPU(SegmentedMM)
NO_GPU_MULTI(SVD)
NO_GPU(Inverse)
NO_GPU(Cholesky)
NO_GPU_MULTI(Eig)
NO_GPU_MULTI(Eigh)
namespace fast {
NO_GPU_MULTI(CustomKernel)
} // namespace fast
namespace distributed {
NO_GPU_MULTI(AllReduce)
NO_GPU_MULTI(AllGather)
NO_GPU_MULTI(Send)
NO_GPU_MULTI(Recv)
} // namespace distributed
} // namespace mlx::core

104
mlx/backend/cuda/primitives.cu
View File

@@ -1,104 +0,0 @@
// Copyright © 2025 Apple Inc.
#include "mlx/backend/cuda/device.h"
#include "mlx/backend/cuda/device/arange.cuh"
#include "mlx/backend/cuda/device/fp16_math.cuh"
#include "mlx/backend/cuda/kernel_utils.cuh"
#include "mlx/distributed/primitives.h"
#include "mlx/dtype_utils.h"
#include "mlx/fast_primitives.h"
#include "mlx/primitives.h"
#include <nvtx3/nvtx3.hpp>
#include <thrust/device_ptr.h>
#include <thrust/transform.h>
#include <cassert>
namespace mlx::core {
void Arange::eval_gpu(const std::vector<array>& inputs, array& out) {
nvtx3::scoped_range r("Arange::eval_gpu");
assert(inputs.size() == 0);
out.set_data(allocator::malloc(out.nbytes()));
if (out.size() == 0) {
return;
}
auto& encoder = cu::get_command_encoder(stream());
encoder.set_output_array(out);
auto capture = encoder.capture_context();
dispatch_int_float_types(out.dtype(), "Arange", [&](auto type_tag) {
using CTYPE = MLX_GET_TYPE(type_tag);
using OutType = cuda_type_t<CTYPE>;
CTYPE step =
static_cast<CTYPE>(start_ + step_) - static_cast<CTYPE>(start_);
thrust::transform(
cu::thrust_policy(encoder.stream()),
thrust::counting_iterator<uint32_t>(0),
thrust::counting_iterator<uint32_t>(out.data_size()),
thrust::device_pointer_cast(out.data<OutType>()),
cu::Arange<OutType>{
static_cast<OutType>(start_), static_cast<OutType>(step)});
});
}
bool fast::ScaledDotProductAttention::use_fallback(
const array& q,
const array& k,
const array& v,
bool has_mask,
bool has_arr_mask,
bool do_causal,
Stream s) {
return true;
}
#define NO_GPU_MULTI(func) \
void func::eval_gpu( \
const std::vector<array>& inputs, std::vector<array>& outputs) { \
throw std::runtime_error(#func " has no CUDA implementation."); \
}
#define NO_GPU_USE_FALLBACK(func) \
bool func::use_fallback(Stream s) { \
return true; \
} \
NO_GPU_MULTI(func)
#define NO_GPU(func) \
void func::eval_gpu(const std::vector<array>& inputs, array& out) { \
throw std::runtime_error(#func " has no CUDA implementation."); \
}
NO_GPU(BlockMaskedMM)
NO_GPU(Convolution)
NO_GPU(DynamicSlice)
NO_GPU(DynamicSliceUpdate)
NO_GPU(FFT)
NO_GPU(GatherMM)
NO_GPU(GatherQMM)
NO_GPU(Hadamard)
NO_GPU(Load)
NO_GPU_MULTI(LUF)
NO_GPU_MULTI(QRF)
NO_GPU(QuantizedMatmul)
NO_GPU(SegmentedMM)
NO_GPU_MULTI(SVD)
NO_GPU(Inverse)
NO_GPU(Cholesky)
NO_GPU_MULTI(Eig)
NO_GPU_MULTI(Eigh)
namespace fast {
NO_GPU(ScaledDotProductAttention)
NO_GPU_MULTI(CustomKernel)
} // namespace fast
namespace distributed {
NO_GPU_MULTI(AllReduce)
NO_GPU_MULTI(AllGather)
NO_GPU_MULTI(Send)
NO_GPU_MULTI(Recv)
} // namespace distributed
} // namespace mlx::core

215
mlx/backend/cuda/quantized.cu → mlx/backend/cuda/quantized/affine_quantize.cu
View File

@@ -2,30 +2,17 @@
#include "mlx/backend/cuda/device.h"
#include "mlx/backend/cuda/kernel_utils.cuh"
#include "mlx/backend/gpu/copy.h"
#include "mlx/backend/cuda/quantized/quantized_utils.cuh"
#include "mlx/dtype_utils.h"
#include "mlx/fast_primitives.h"
#include <cooperative_groups.h>
#include <cooperative_groups/reduce.h>
#include <nvtx3/nvtx3.hpp>
namespace mlx::core {
namespace cu {
namespace cg = cooperative_groups;
template <int bits, int wsize = 8>
inline constexpr __device__ short get_pack_factor() {
return (bits == 3 || bits == 5) ? 8 : (bits == 6 ? 4 : wsize / bits);
}
template <int bits, int wsize = 8>
inline constexpr __device__ short get_bytes_per_pack() {
constexpr int power_of_2_bits = (bits & (bits - 1)) == 0;
return power_of_2_bits ? (wsize / 8) : (bits == 5 ? 5 : 3);
}
template <typename T, int group_size, int bits>
__global__ void
affine_quantize(const T* w, uint8_t* out, T* scales, T* biases, size_t size) {
@@ -240,144 +227,102 @@ __global__ void affine_dequantize(
}
} // namespace cu
namespace {
inline array ensure_row_contiguous(
const array& x,
void affine_quantize(
const array& w,
array& wq,
array& scales,
array& biases,
int group_size_,
int bits_,
cu::CommandEncoder& enc,
const Stream& s) {
if (!x.flags().row_contiguous) {
array x_copy = contiguous_copy_gpu(x, s);
enc.add_temporary(x_copy);
return x_copy;
} else {
return x;
}
}
} // namespace
template <typename F>
void dispatch_groups(int group_size, F&& f) {
switch (group_size) {
case 32:
f(std::integral_constant<int, 32>{});
break;
case 64:
f(std::integral_constant<int, 64>{});
break;
case 128:
f(std::integral_constant<int, 128>{});
break;
}
}
template <typename F>
void dispatch_bits(int bits, F&& f) {
switch (bits) {
case 2:
f(std::integral_constant<int, 2>{});
break;
case 3:
f(std::integral_constant<int, 3>{});
break;
case 4:
f(std::integral_constant<int, 4>{});
break;
case 5:
f(std::integral_constant<int, 5>{});
break;
case 6:
f(std::integral_constant<int, 6>{});
break;
case 8:
f(std::integral_constant<int, 8>{});
break;
}
}
void fast::AffineQuantize::eval_gpu(
const std::vector<array>& inputs,
std::vector<array>& outputs) {
auto& w_pre = inputs[0];
auto& out = outputs[0];
out.set_data(allocator::malloc(out.nbytes()));
auto& s = stream();
auto& d = cu::device(s.device);
auto& enc = d.get_command_encoder(s);
auto w = ensure_row_contiguous(w_pre, enc, s);
enc.set_input_array(w);
if (dequantize_) {
auto scales = ensure_row_contiguous(inputs[1], enc, s);
auto biases = ensure_row_contiguous(inputs[2], enc, s);
enc.set_input_array(scales);
enc.set_input_array(biases);
enc.set_output_array(out);
} else {
auto& scales = outputs[1];
auto& biases = outputs[2];
scales.set_data(allocator::malloc(scales.nbytes()));
biases.set_data(allocator::malloc(biases.nbytes()));
enc.set_output_array(out);
enc.set_output_array(scales);
enc.set_output_array(biases);
}
auto dtype = dequantize_ ? outputs[0].dtype() : inputs[0].dtype();
// Treat uint32 as uint8 in kernel
int uint8_per_uint32 = 4;
int packs_per_int = (bits_ == 3 || bits_ == 5) ? 8
: bits_ == 6 ? 4
: 8 / bits_;
int per_thread = dequantize_ ? packs_per_int : group_size_ / WARP_SIZE;
size_t size =
dequantize_ ? out.size() / packs_per_int : w.size() / per_thread;
// Calculate the number of elements per thread
int per_thread = group_size_ / WARP_SIZE;
size_t size = w.size() / per_thread;
// Calculate the thread grid that we need to launch
bool large = size > UINT_MAX;
auto grid_shape = w.shape();
if (dequantize_) {
grid_shape.back() *= uint8_per_uint32;
} else {
grid_shape.back() /= per_thread;
}
dispatch_float_types(dtype, "affine_quantize", [&](auto type_tag) {
enc.set_input_array(w);
enc.set_output_array(wq);
enc.set_output_array(scales);
enc.set_output_array(biases);
dispatch_float_types(w.dtype(), "affine_quantize", [&](auto type_tag) {
dispatch_groups(group_size_, [&](auto group_size) {
dispatch_bits(bits_, [&](auto bits) {
using DataType = cuda_type_t<MLX_GET_TYPE(type_tag)>;
if (dequantize_) {
auto kernel =
cu::affine_dequantize<DataType, group_size.value, bits.value>;
using T = cuda_type_t<MLX_GET_TYPE(type_tag)>;
auto kernel = cu::affine_quantize<T, group_size.value, bits.value>;
auto [num_blocks, block_dims] =
get_launch_args(kernel, size, grid_shape, w.strides(), large);
get_launch_args(size, grid_shape, w.strides(), large);
enc.add_kernel_node(
kernel,
num_blocks,
block_dims,
w.data<uint8_t>(),
inputs[1].data<DataType>(),
inputs[2].data<DataType>(),
out.data<DataType>(),
out.size());
} else {
auto kernel =
cu::affine_quantize<DataType, group_size.value, bits.value>;
auto [num_blocks, block_dims] =
get_launch_args(kernel, size, grid_shape, w.strides(), large);
enc.add_kernel_node(
kernel,
num_blocks,
block_dims,
w.data<DataType>(),
out.data<uint8_t>(),
outputs[1].data<DataType>(),
outputs[2].data<DataType>(),
0,
w.data<T>(),
wq.data<uint8_t>(),
scales.data<T>(),
biases.data<T>(),
w.size());
});
});
});
}
void affine_dequantize(
const array& wq,
const array& scales,
const array& biases,
array& w,
int group_size_,
int bits_,
cu::CommandEncoder& enc,
const Stream& s) {
// Calculate how many numbers we pack together. For 2, 4, 8 bits we pack in
// one uint8, for 3, 6 in 3 uint8 and for 5 in 5 uint8.
constexpr int uint8_per_uint32 = 4;
int packs_per_int;
switch (bits_) {
case 3:
case 5:
packs_per_int = 8;
break;
case 6:
packs_per_int = 4;
break;
default:
packs_per_int = 8 / bits_;
}
size_t size = w.size() / packs_per_int;
bool large = size > UINT_MAX;
auto grid_shape = w.shape();
grid_shape.back() *= uint8_per_uint32;
enc.set_input_array(wq);
enc.set_input_array(scales);
enc.set_input_array(biases);
enc.set_output_array(w);
dispatch_float_types(w.dtype(), "affine_quantize", [&](auto type_tag) {
dispatch_groups(group_size_, [&](auto group_size) {
dispatch_bits(bits_, [&](auto bits) {
using T = cuda_type_t<MLX_GET_TYPE(type_tag)>;
auto kernel = cu::affine_dequantize<T, group_size.value, bits.value>;
auto [num_blocks, block_dims] =
get_launch_args(size, grid_shape, w.strides(), large);
enc.add_kernel_node(
kernel,
num_blocks,
block_dims,
0,
wq.data<uint8_t>(),
scales.data<T>(),
biases.data<T>(),
w.data<T>(),
w.size());
});
});
});

80
mlx/backend/cuda/quantized/quantized.cpp Normal file
View File

@@ -0,0 +1,80 @@
// Copyright © 2025 Apple Inc.
#include "mlx/backend/cuda/quantized/quantized.h"
#include "mlx/backend/cuda/device.h"
#include "mlx/backend/gpu/copy.h"
#include "mlx/fast_primitives.h"
#include <nvtx3/nvtx3.hpp>
namespace mlx::core {
namespace {
inline array ensure_row_contiguous(
const array& x,
cu::CommandEncoder& enc,
const Stream& s) {
if (!x.flags().row_contiguous) {
array x_copy = contiguous_copy_gpu(x, s);
enc.add_temporary(x_copy);
return x_copy;
} else {
return x;
}
}
inline array ensure_row_contiguous_matrix(
const array& x,
cu::CommandEncoder& enc,
const Stream& s) {
if (x.ndim() < 2) {
if (x.strides()[0] == 1) {
return x;
}
} else {
auto stride_0 = x.strides()[x.ndim() - 2];
auto stride_1 = x.strides()[x.ndim() - 1];
if (stride_0 == x.shape(-1) && stride_1 == 1) {
return x;
}
}
array x_copy = contiguous_copy_gpu(x, s);
enc.add_temporary(x_copy);
return x_copy;
}
} // namespace
void fast::AffineQuantize::eval_gpu(
const std::vector<array>& inputs,
std::vector<array>& outputs) {
nvtx3::scoped_range r("AffineQuantize::eval_gpu");
auto& s = stream();
auto& d = cu::device(s.device);
auto& enc = d.get_command_encoder(s);
if (dequantize_) {
auto wq = ensure_row_contiguous(inputs[0], enc, s);
auto scales = ensure_row_contiguous(inputs[1], enc, s);
auto biases = ensure_row_contiguous(inputs[2], enc, s);
auto& w = outputs[0];
w.set_data(allocator::malloc(w.nbytes()));
affine_dequantize(wq, scales, biases, w, group_size_, bits_, enc, s);
} else {
auto w = ensure_row_contiguous(inputs[0], enc, s);
auto& wq = outputs[0];
auto& scales = outputs[1];
auto& biases = outputs[2];
wq.set_data(allocator::malloc(wq.nbytes()));
scales.set_data(allocator::malloc(scales.nbytes()));
biases.set_data(allocator::malloc(biases.nbytes()));
affine_quantize(w, wq, scales, biases, group_size_, bits_, enc, s);
}
}
} // namespace mlx::core

27
mlx/backend/cuda/quantized/quantized.h Normal file
View File

@@ -0,0 +1,27 @@
// Copyright © 2025 Apple Inc.
#include "mlx/backend/cuda/device.h"
namespace mlx::core {
void affine_quantize(
const array& w,
array& wq,
array& scales,
array& biases,
int group_size_,
int bits_,
cu::CommandEncoder& enc,
const Stream& s);
void affine_dequantize(
const array& wq,
const array& scales,
const array& biases,
array& w,
int group_size_,
int bits_,
cu::CommandEncoder& enc,
const Stream& s);
} // namespace mlx::core

59
mlx/backend/cuda/quantized/quantized_utils.cuh Normal file
View File

@@ -0,0 +1,59 @@
// Copyright © 2025 Apple Inc.
namespace mlx::core {
namespace cu {
template <int bits, int wsize = 8>
inline constexpr __device__ short get_pack_factor() {
return (bits == 3 || bits == 5) ? 8 : (bits == 6 ? 4 : wsize / bits);
}
template <int bits, int wsize = 8>
inline constexpr __device__ short get_bytes_per_pack() {
constexpr int power_of_2_bits = (bits & (bits - 1)) == 0;
return power_of_2_bits ? (wsize / 8) : (bits == 5 ? 5 : 3);
}
} // namespace cu
template <typename F>
void dispatch_groups(int group_size, F&& f) {
switch (group_size) {
case 32:
f(std::integral_constant<int, 32>{});
break;
case 64:
f(std::integral_constant<int, 64>{});
break;
case 128:
f(std::integral_constant<int, 128>{});
break;
}
}
template <typename F>
void dispatch_bits(int bits, F&& f) {
switch (bits) {
case 2:
f(std::integral_constant<int, 2>{});
break;
case 3:
f(std::integral_constant<int, 3>{});
break;
case 4:
f(std::integral_constant<int, 4>{});
break;
case 5:
f(std::integral_constant<int, 5>{});
break;
case 6:
f(std::integral_constant<int, 6>{});
break;
case 8:
f(std::integral_constant<int, 8>{});
break;
}
}
} // namespace mlx::core

2
mlx/backend/cuda/random.cu
View File

@@ -170,6 +170,7 @@ void RandomBits::eval_gpu(const std::vector<array>& inputs, array& out) {
cu::rbitsc,
grid,
block,
0,
keys.data<uint32_t>(),
out.data<uint8_t>(),
grid_dims,
@@ -180,6 +181,7 @@ void RandomBits::eval_gpu(const std::vector<array>& inputs, array& out) {
cu::rbits,
grid,
block,
0,
keys.data<uint32_t>(),
out.data<uint8_t>(),
grid_dims,

2
mlx/backend/cuda/reduce.cu
View File

@@ -5,8 +5,6 @@
#include "mlx/backend/gpu/copy.h"
#include <nvtx3/nvtx3.hpp>
#include <thrust/device_ptr.h>
#include <thrust/fill.h>
#include <cassert>

2
mlx/backend/cuda/reduce/all_reduce.cu
View File

@@ -120,6 +120,7 @@ void all_reduce(
kernel,
blocks,
threads,
0,
static_cast<T*>(indata),
intermediate.data<U>(),
block_step,
@@ -146,6 +147,7 @@ void all_reduce(
kernel,
blocks,
threads,
0,
static_cast<T*>(indata),
out.data<U>(),
block_step,

2
mlx/backend/cuda/reduce/col_reduce.cu
View File

@@ -230,7 +230,7 @@ void col_reduce_looped(
auto kernel =
cu::col_reduce_looped<T, U, OP, reduce_ndim(), BM, BN, N_READS>;
encoder.add_kernel_node(
kernel, grid, blocks, indata, out.data<U>(), args);
kernel, grid, blocks, 0, indata, out.data<U>(), args);
});
});
});

3
mlx/backend/cuda/reduce/init_reduce.cu
View File

@@ -41,7 +41,8 @@ void init_reduce(
dim3 grid = get_2d_grid_dims(out.shape(), out.strides());
dim3 block(grid.x < 1024 ? grid.x : 1024, 1, 1);
grid.x = (grid.x + 1023) / 1024;
encoder.add_kernel_node(kernel, grid, block, out.data<U>(), out.size());
encoder.add_kernel_node(
kernel, grid, block, 0, out.data<U>(), out.size());
});
});
}

4
mlx/backend/cuda/reduce/row_reduce.cu
View File

@@ -269,7 +269,7 @@ void row_reduce_simple(
int size = plan.shape.back();
encoder.add_kernel_node(
kernel, grid, block, indata, out.data<U>(), out.size(), size);
kernel, grid, block, 0, indata, out.data<U>(), out.size(), size);
});
});
}
@@ -322,7 +322,7 @@ void row_reduce_looped(
});
encoder.add_kernel_node(
kernel, grid, block, indata, out.data<U>(), out.size(), args);
kernel, grid, block, 0, indata, out.data<U>(), out.size(), args);
});
});
}

55
mlx/backend/cuda/rms_norm.cu
View File

@@ -1,7 +1,6 @@
// Copyright © 2025 Apple Inc.
#include "mlx/backend/cuda/device.h"
#include "mlx/backend/cuda/iterators/strided_iterator.cuh"
#include "mlx/backend/cuda/kernel_utils.cuh"
#include "mlx/backend/cuda/reduce/reduce.cuh"
#include "mlx/backend/gpu/copy.h"
@@ -11,8 +10,6 @@
#include <cooperative_groups.h>
#include <cooperative_groups/reduce.h>
#include <nvtx3/nvtx3.hpp>
#include <cub/block/block_load.cuh>
#include <cub/block/block_reduce.cuh>
namespace mlx::core {
@@ -58,7 +55,7 @@ __global__ void rms_norm(
const T* w,
T* out,
float eps,
int32_t axis_size,
uint32_t axis_size,
int64_t w_stride) {
auto grid = cg::this_grid();
auto block = cg::this_thread_block();
@@ -73,8 +70,8 @@ __global__ void rms_norm(
float normalizer = 0;
for (int r = 0; r < cuda::ceil_div(axis_size, BLOCK_DIM * N_READS); ++r) {
auto index = r * BLOCK_DIM + block.thread_rank();
T xn[N_READS];
cub::LoadDirectBlocked(index, x, xn, axis_size, cast_to<T>(0));
auto xn = load_vector<N_READS>(x, index, axis_size, T(0));
#pragma unroll
for (int i = 0; i < N_READS; ++i) {
float t = static_cast<float>(xn[i]);
normalizer += t * t;
@@ -86,15 +83,14 @@ __global__ void rms_norm(
// Outputs.
for (int r = 0; r < cuda::ceil_div(axis_size, BLOCK_DIM * N_READS); ++r) {
auto index = r * BLOCK_DIM + block.thread_rank();
T xn[N_READS];
T wn[N_READS];
cub::LoadDirectBlocked(index, x, xn, axis_size);
cub::LoadDirectBlocked(index, strided_iterator(w, w_stride), wn, axis_size);
auto xn = load_vector<N_READS>(x, index, axis_size, T(0));
auto wn = load_vector<N_READS>(w, index, axis_size, w_stride, T(0));
#pragma unroll
for (int i = 0; i < N_READS; ++i) {
float norm = static_cast<float>(xn[i]) * normalizer;
xn[i] = wn[i] * static_cast<T>(norm);
float y = static_cast<float>(xn[i]) * normalizer;
xn[i] = wn[i] * static_cast<T>(y);
}
cub::StoreDirectBlocked(index, out, xn, axis_size);
store_vector<N_READS>(out, index, xn, axis_size);
}
}
@@ -126,13 +122,10 @@ __global__ void rms_norm_vjp(
// Normalizer.
float2 factors = {};
for (int r = 0; r < cuda::ceil_div(axis_size, BLOCK_DIM * N_READS); ++r) {
T xn[N_READS];
T wn[N_READS] = {};
T gn[N_READS] = {};
auto index = r * BLOCK_DIM + block.thread_rank();
cub::LoadDirectBlocked(index, x, xn, axis_size, cast_to<T>(0));
cub::LoadDirectBlocked(index, g, gn, axis_size);
cub::LoadDirectBlocked(index, strided_iterator(w, w_stride), wn, axis_size);
auto xn = load_vector<N_READS>(x, index, axis_size, T(0));
auto gn = load_vector<N_READS>(g, index, axis_size, T(0));
auto wn = load_vector<N_READS>(w, index, axis_size, w_stride, T(0));
for (int i = 0; i < N_READS; i++) {
float t = static_cast<float>(xn[i]);
float wi = wn[i];
@@ -149,12 +142,9 @@ __global__ void rms_norm_vjp(
// Outputs.
for (int r = 0; r < cuda::ceil_div(axis_size, BLOCK_DIM * N_READS); ++r) {
auto index = r * BLOCK_DIM + block.thread_rank();
T xn[N_READS];
T wn[N_READS];
T gn[N_READS];
cub::LoadDirectBlocked(index, x, xn, axis_size);
cub::LoadDirectBlocked(index, g, gn, axis_size);
cub::LoadDirectBlocked(index, strided_iterator(w, w_stride), wn, axis_size);
auto xn = load_vector<N_READS>(x, index, axis_size, T(0));
auto gn = load_vector<N_READS>(g, index, axis_size, T(0));
auto wn = load_vector<N_READS>(w, index, axis_size, w_stride, T(0));
for (int i = 0; i < N_READS; i++) {
float xi = xn[i];
float wi = wn[i];
@@ -164,9 +154,9 @@ __global__ void rms_norm_vjp(
wn[i] = static_cast<T>(gi * xi * normalizer);
}
}
cub::StoreDirectBlocked(index, gx, xn, axis_size);
store_vector<N_READS>(gx, index, xn, axis_size);
if constexpr (HAS_W) {
cub::StoreDirectBlocked(index, gw, wn, axis_size);
store_vector<N_READS>(gw, index, wn, axis_size);
}
}
}
@@ -224,14 +214,15 @@ void RMSNorm::eval_gpu(
encoder.set_input_array(w);
encoder.set_output_array(out);
dispatch_float_types(out.dtype(), "rms_norm", [&](auto type_tag) {
constexpr uint32_t N_READS = 4;
dispatch_block_dim(cuda::ceil_div(axis_size, N_READS), [&](auto block_dim) {
using DataType = cuda_type_t<MLX_GET_TYPE(type_tag)>;
constexpr int N_READS = 16 / sizeof(DataType);
dispatch_block_dim(cuda::ceil_div(axis_size, N_READS), [&](auto block_dim) {
auto kernel = cu::rms_norm<DataType, block_dim(), N_READS>;
encoder.add_kernel_node(
kernel,
n_rows,
block_dim(),
0,
x.data<DataType>(),
w.data<DataType>(),
out.data<DataType>(),
@@ -313,11 +304,10 @@ void RMSNormVJP::eval_gpu(
encoder.set_output_array(gw_temp);
dispatch_float_types(gx.dtype(), "rms_norm_vjp", [&](auto type_tag) {
dispatch_bool(has_w, [&](auto has_w_constant) {
constexpr int N_READS = 4;
using DataType = cuda_type_t<MLX_GET_TYPE(type_tag)>;
constexpr int N_READS = 16 / sizeof(DataType);
dispatch_block_dim(
cuda::ceil_div(axis_size, N_READS), [&](auto block_dim) {
using DataType = cuda_type_t<MLX_GET_TYPE(type_tag)>;
constexpr int N_READS = 4;
auto kernel = cu::rms_norm_vjp<
DataType,
has_w_constant.value,
@@ -327,6 +317,7 @@ void RMSNormVJP::eval_gpu(
kernel,
n_rows,
block_dim(),
0,
x.data<DataType>(),
w.data<DataType>(),
g.data<DataType>(),

4
mlx/backend/cuda/rope.cu
View File

@@ -325,6 +325,7 @@ void RoPE::eval_gpu(
kernel,
grid,
block,
0,
(donated ? out : in).data<DataType>(),
out.data<DataType>(),
offset.data<int32_t>(),
@@ -341,6 +342,7 @@ void RoPE::eval_gpu(
kernel,
grid,
block,
0,
(donated ? out : in).data<DataType>(),
out.data<DataType>(),
offset.data<int32_t>(),
@@ -360,6 +362,7 @@ void RoPE::eval_gpu(
kernel,
grid,
block,
0,
(donated ? out : in).data<DataType>(),
out.data<DataType>(),
offset.data<int32_t>(),
@@ -381,6 +384,7 @@ void RoPE::eval_gpu(
kernel,
grid,
block,
0,
(donated ? out : in).data<DataType>(),
out.data<DataType>(),
offset.data<int32_t>(),

781
mlx/backend/cuda/scaled_dot_product_attention.cu Normal file
View File

@@ -0,0 +1,781 @@
// Copyright © 2025 Apple Inc.
#include "mlx/backend/cuda/device.h"
#include "mlx/backend/cuda/device/config.h"
#include "mlx/backend/cuda/device/utils.cuh"
#include "mlx/backend/cuda/kernel_utils.cuh"
#include "mlx/backend/cuda/lru_cache.h"
#include "mlx/backend/gpu/copy.h"
#include "mlx/dtype_utils.h"
#include "mlx/fast_primitives.h"
#include "mlx/transforms_impl.h"
#include <nvtx3/nvtx3.hpp>
#include <cooperative_groups.h>
#include <cooperative_groups/reduce.h>
namespace mlx::core {
namespace cu {
namespace cg = cooperative_groups;
#define PRAGMA_LOOP_UNROLL #pragma unroll
struct AttnParams {
int B;
int H;
int D;
int qL;
int kL;
int gqa_factor;
float scale;
int64_t Q_strides[3];
int64_t K_strides[3];
int64_t V_strides[3];
int64_t O_strides[3];
};
template <typename T, bool do_causal, int D>
__global__ void kernel_sdpav_1pass(
const T* Q,
const T* K,
const T* V,
T* O,
__grid_constant__ const AttnParams params) {
constexpr int BN = 32;
constexpr int BD = 32;
constexpr int v_per_thread = D / BD;
const int inner_k_stride = BN * int(params.K_strides[2]);
const int inner_v_stride = BN * int(params.V_strides[2]);
typedef float U;
U q[v_per_thread];
U k[v_per_thread];
U o[v_per_thread];
__shared__ U outputs[BN][BD + 1];
__shared__ U max_scores[BN];
__shared__ U sum_exp_scores[BN];
const U scale_log2 = params.scale * 1.44269504089f;
auto block = cg::this_thread_block();
auto warp = cg::tiled_partition<32>(block);
const int lane_idx = warp.thread_rank();
const int warp_idx = warp.meta_group_rank();
// Adjust to thread block and thread
const int batch_idx = blockIdx.z;
const int head_idx = blockIdx.x;
const int kv_head_idx = head_idx / params.gqa_factor;
const int q_seq_idx = blockIdx.y;
const int kv_seq_idx = warp_idx;
Q += batch_idx * params.Q_strides[0] + // Batch
head_idx * params.Q_strides[1] + // Head
q_seq_idx * params.Q_strides[2]; // Sequence
K += batch_idx * params.K_strides[0] + // Batch
kv_head_idx * params.K_strides[1] + // Head
kv_seq_idx * params.K_strides[2]; // Sequence
V += batch_idx * params.V_strides[0] + // Batch
kv_head_idx * params.V_strides[1] + // Head
kv_seq_idx * params.V_strides[2]; // Sequence
O += batch_idx * params.O_strides[0] + // Batch
head_idx * params.O_strides[1] + // Head
q_seq_idx * params.O_strides[2]; // Sequence
// Read the query and 0 the output accumulator
PRAGMA_LOOP_UNROLL
for (int i = 0; i < v_per_thread; i++) {
q[i] = scale_log2 * static_cast<U>(Q[v_per_thread * lane_idx + i]);
}
PRAGMA_LOOP_UNROLL
for (int i = 0; i < v_per_thread; i++) {
o[i] = 0.f;
}
U max_score = -INFINITY;
U sum_exp_score = 0.f;
// For each key
for (int i = kv_seq_idx; i < params.kL; i += BN) {
bool use_key = true;
if constexpr (do_causal) {
use_key = i <= (params.kL - params.qL + q_seq_idx);
}
if (use_key) {
// Read the key
PRAGMA_LOOP_UNROLL
for (int j = 0; j < v_per_thread; j++) {
k[j] = K[v_per_thread * lane_idx + j];
}
// Compute the i-th score
U score = 0.f;
PRAGMA_LOOP_UNROLL
for (int j = 0; j < v_per_thread; j++) {
score += q[j] * k[j];
}
// Warp sum
score = cg::reduce(warp, score, cg::plus<U>());
// Update the accumulators
U new_max = max(max_score, score);
U factor = exp2f(max_score - new_max);
U exp_score = exp2f(score - new_max);
max_score = new_max;
sum_exp_score = sum_exp_score * factor + exp_score;
// Update the output accumulator
PRAGMA_LOOP_UNROLL
for (int j = 0; j < v_per_thread; j++) {
o[j] = o[j] * factor +
exp_score * static_cast<U>(V[v_per_thread * lane_idx + j]);
}
}
// Move the pointers to the next kv
K += inner_k_stride;
V += inner_v_stride;
}
if (lane_idx == 0) {
max_scores[warp_idx] = max_score;
sum_exp_scores[warp_idx] = sum_exp_score;
}
block.sync();
max_score = max_scores[lane_idx];
U new_max = cg::reduce(warp, max_score, cg::greater<U>());
U factor = exp2f(max_score - new_max);
sum_exp_score =
cg::reduce(warp, sum_exp_scores[lane_idx] * factor, cg::plus<U>());
sum_exp_score = __frcp_rn(sum_exp_score);
// Now we need to aggregate all the outputs
PRAGMA_LOOP_UNROLL
for (int i = 0; i < v_per_thread; i++) {
outputs[lane_idx][warp_idx] = o[i];
block.sync();
U ot = outputs[warp_idx][lane_idx] * factor;
o[i] = cg::reduce(warp, ot, cg::plus<U>()) * sum_exp_score;
block.sync();
}
// And write the output
if (lane_idx == 0) {
PRAGMA_LOOP_UNROLL
for (int i = 0; i < v_per_thread; i++) {
O[v_per_thread * warp_idx + i] = static_cast<T>(o[i]);
}
}
}
template <typename T, bool do_causal, int D>
__global__ void kernel_sdpav_2pass_1(
const T* Q,
const T* K,
const T* V,
float* partials,
float* sums,
float* maxs,
__grid_constant__ const AttnParams params) {
constexpr int BN = 8;
constexpr int BD = 32;
constexpr int blocks = 32;
constexpr int v_per_thread = D / BD;
const int inner_k_stride = blocks * BN * int(params.K_strides[2]);
const int inner_v_stride = blocks * BN * int(params.V_strides[2]);
typedef float U;
U q[v_per_thread];
U k[v_per_thread];
U o[v_per_thread];
__shared__ U outputs[BN][BD + 1];
__shared__ U max_scores[BN];
__shared__ U sum_exp_scores[BN];
const U scale_log2 = params.scale * 1.44269504089f;
auto block = cg::this_thread_block();
auto warp = cg::tiled_partition<32>(block);
const int lane_idx = warp.thread_rank();
const int warp_idx = warp.meta_group_rank();
// Adjust to thread block and thread
const int batch_idx = blockIdx.z / blocks;
const int block_idx = blockIdx.z % blocks;
const int head_idx = blockIdx.x;
const int kv_head_idx = head_idx / params.gqa_factor;
const int q_seq_idx = blockIdx.y;
const int kv_seq_idx = block_idx * BN + warp_idx;
Q += batch_idx * params.Q_strides[0] + // Batch
head_idx * params.Q_strides[1] + // Head
q_seq_idx * params.Q_strides[2]; // Sequence
K += batch_idx * params.K_strides[0] + // Batch
kv_head_idx * params.K_strides[1] + // Head
kv_seq_idx * params.K_strides[2]; // Sequence
V += batch_idx * params.V_strides[0] + // Batch
kv_head_idx * params.V_strides[1] + // Head
kv_seq_idx * params.V_strides[2]; // Sequence
const int p_stride_s = blocks;
const int p_stride_h = params.qL * p_stride_s;
const int p_stride_b = params.H * p_stride_h;
const int p_offset = batch_idx * p_stride_b + // Batch
head_idx * p_stride_h + // Head
q_seq_idx * p_stride_s + // Sequence
block_idx; // Block
partials += p_offset * D;
sums += p_offset;
maxs += p_offset;
// Read the query and 0 the output accumulator
PRAGMA_LOOP_UNROLL
for (int i = 0; i < v_per_thread; i++) {
q[i] = scale_log2 * static_cast<U>(Q[v_per_thread * lane_idx + i]);
}
PRAGMA_LOOP_UNROLL
for (int i = 0; i < v_per_thread; i++) {
o[i] = 0.f;
}
U max_score = -1e9;
U sum_exp_score = 0.f;
// For each key
for (int i = kv_seq_idx; i < params.kL; i += blocks * BN) {
bool use_key = true;
if constexpr (do_causal) {
use_key = i <= (params.kL - params.qL + q_seq_idx);
}
if (use_key) {
// Read the key
PRAGMA_LOOP_UNROLL
for (int j = 0; j < v_per_thread; j++) {
k[j] = K[v_per_thread * lane_idx + j];
}
// Compute the i-th score
U score = 0.f;
PRAGMA_LOOP_UNROLL
for (int j = 0; j < v_per_thread; j++) {
score += q[j] * k[j];
}
// Warp sum
score = cg::reduce(warp, score, cg::plus<U>());
// Update the accumulators
U new_max = max(max_score, score);
U factor = exp2f(max_score - new_max);
U exp_score = exp2f(score - new_max);
max_score = new_max;
sum_exp_score = sum_exp_score * factor + exp_score;
// Update the output accumulator
PRAGMA_LOOP_UNROLL
for (int j = 0; j < v_per_thread; j++) {
o[j] = o[j] * factor +
exp_score * static_cast<U>(V[v_per_thread * lane_idx + j]);
}
}
// Move the pointers to the next kv
K += inner_k_stride;
V += inner_v_stride;
}
if (lane_idx == 0) {
max_scores[warp_idx] = max_score;
sum_exp_scores[warp_idx] = sum_exp_score;
}
block.sync();
max_score = (lane_idx < BN) ? max_scores[lane_idx] : -1e9;
U new_max = cg::reduce(warp, max_score, cg::greater<U>());
U factor = exp2f(max_score - new_max);
sum_exp_score = (lane_idx < BN) ? sum_exp_scores[lane_idx] : 0.f;
sum_exp_score = cg::reduce(warp, sum_exp_score * factor, cg::plus<U>());
// Write the sum and new max
if (warp_idx == 0) {
sums[0] = sum_exp_score;
maxs[0] = new_max;
}
// Now we need to aggregate all the outputs
auto ff = exp2f(max_scores[warp_idx] - new_max);
PRAGMA_LOOP_UNROLL
for (int i = 0; i < v_per_thread; i++) {
outputs[warp_idx][lane_idx] = o[i] * ff;
block.sync();
if (warp_idx == 0) {
U ot = outputs[0][lane_idx];
PRAGMA_LOOP_UNROLL
for (int j = 1; j < BN; j++) {
ot += outputs[j][lane_idx];
warp.sync();
}
o[i] = ot;
}
block.sync();
}
if (warp_idx == 0) {
PRAGMA_LOOP_UNROLL
for (int i = 0; i < v_per_thread; i++) {
partials[v_per_thread * lane_idx + i] = o[i];
}
}
}
template <typename T, bool do_causal, int D>
__global__ void kernel_sdpav_2pass_2(
const float* partials,
const float* sums,
const float* maxs,
T* O,
__grid_constant__ const AttnParams params) {
constexpr int BN = 32;
constexpr int BD = 32;
constexpr int blocks = 32;
constexpr int v_per_thread = D / BD;
typedef float U;
U o[v_per_thread];
__shared__ U outputs[BN][BD + 1];
auto block = cg::this_thread_block();
auto warp = cg::tiled_partition<32>(block);
const int lane_idx = warp.thread_rank();
const int warp_idx = warp.meta_group_rank();
// Adjust to thread block and thread
const int batch_idx = blockIdx.z;
const int head_idx = blockIdx.x;
const int q_seq_idx = blockIdx.y;
const int p_stride_s = blocks;
const int p_stride_h = params.qL * p_stride_s;
const int p_stride_b = params.H * p_stride_h;
const int p_offset = batch_idx * p_stride_b + // Batch
head_idx * p_stride_h + // Head
q_seq_idx * p_stride_s; // Sequence
partials += p_offset * D + warp_idx * D;
sums += p_offset;
maxs += p_offset;
O += batch_idx * params.O_strides[0] + // Batch
head_idx * params.O_strides[1] + // Head
q_seq_idx * params.O_strides[2]; // Sequence
U max_score = maxs[lane_idx];
U new_max = cg::reduce(warp, max_score, cg::greater<U>());
U factor = exp2f(max_score - new_max);
U sum_exp_score = cg::reduce(warp, sums[lane_idx] * factor, cg::plus<U>());
sum_exp_score = __frcp_rn(sum_exp_score);
PRAGMA_LOOP_UNROLL
for (int i = 0; i < v_per_thread; i++) {
o[i] = partials[v_per_thread * lane_idx + i];
}
// Now we need to aggregate all the outputs
PRAGMA_LOOP_UNROLL
for (int i = 0; i < v_per_thread; i++) {
outputs[lane_idx][warp_idx] = o[i];
block.sync();
U ot = outputs[warp_idx][lane_idx] * factor;
o[i] = cg::reduce(warp, ot, cg::plus<U>()) * sum_exp_score;
block.sync();
}
// And write the output
if (lane_idx == 0) {
PRAGMA_LOOP_UNROLL
for (int i = 0; i < v_per_thread; i++) {
O[v_per_thread * warp_idx + i] = static_cast<T>(o[i]);
}
}
}
} // namespace cu
namespace {
template <typename F>
void dispatch_headdim(int n, F&& f) {
switch (n) {
case 64:
f(std::integral_constant<int, 64>{});
break;
case 96:
f(std::integral_constant<int, 96>{});
break;
case 128:
f(std::integral_constant<int, 128>{});
break;
}
}
void sdpa_vector_1pass_fallback(
const Stream& s,
cu::CommandEncoder& encoder,
const array& q,
const array& k,
const array& v,
const float scale,
array& o,
bool do_causal_ = false) {
encoder.set_input_array(q);
encoder.set_input_array(k);
encoder.set_input_array(v);
encoder.set_output_array(o);
cu::AttnParams params{
/* int B = */ q.shape(0),
/* int H = */ q.shape(1),
/* int D = */ q.shape(3),
/* int qL = */ q.shape(2),
/* int kL = */ k.shape(2),
/* int gqa_factor = */ q.shape(1) / k.shape(1),
/* float scale = */ scale,
/* int64_t Q_strides[3] = */ {q.strides(0), q.strides(1), q.strides(2)},
/* int64_t K_strides[3] = */ {k.strides(0), k.strides(1), k.strides(2)},
/* int64_t V_strides[3] = */ {v.strides(0), v.strides(1), v.strides(2)},
/* int64_t O_strides[3] = */ {o.strides(0), o.strides(1), o.strides(2)}};
dim3 grid_dim(params.H, params.qL, params.B);
dim3 block_dim(1024, 1, 1);
dispatch_float_types(o.dtype(), "kernel_sdpav_1pass", [&](auto type_tag) {
dispatch_bool(do_causal_, [&](auto do_causal) {
dispatch_headdim(params.D, [&](auto headdim) {
using DataType = cuda_type_t<MLX_GET_TYPE(type_tag)>;
auto kernel =
cu::kernel_sdpav_1pass<DataType, do_causal.value, headdim.value>;
encoder.add_kernel_node(
kernel,
grid_dim,
block_dim,
0,
q.data<DataType>(),
k.data<DataType>(),
v.data<DataType>(),
o.data<DataType>(),
params);
});
});
});
}
void sdpa_vector_2pass_fallback(
const Stream& s,
cu::CommandEncoder& encoder,
const array& q,
const array& k,
const array& v,
const float scale,
array& o,
bool do_causal_ = false) {
cu::AttnParams params{
/* int B = */ q.shape(0),
/* int H = */ q.shape(1),
/* int D = */ q.shape(3),
/* int qL = */ q.shape(2),
/* int kL = */ k.shape(2),
/* int gqa_factor = */ q.shape(1) / k.shape(1),
/* float scale = */ scale,
/* int64_t Q_strides[3] = */ {q.strides(0), q.strides(1), q.strides(2)},
/* int64_t K_strides[3] = */ {k.strides(0), k.strides(1), k.strides(2)},
/* int64_t V_strides[3] = */ {v.strides(0), v.strides(1), v.strides(2)},
/* int64_t O_strides[3] = */ {o.strides(0), o.strides(1), o.strides(2)}};
// Allocate the intermediates
int blocks = 32;
Shape intermediate_shape;
intermediate_shape.reserve(o.ndim() + 1);
intermediate_shape.insert(
intermediate_shape.end(), o.shape().begin(), o.shape().end() - 1);
intermediate_shape.push_back(blocks);
intermediate_shape.push_back(o.shape().back());
array intermediate(intermediate_shape, float32, nullptr, {});
intermediate_shape.pop_back();
array sums(intermediate_shape, float32, nullptr, {});
array maxs(std::move(intermediate_shape), float32, nullptr, {});
intermediate.set_data(allocator::malloc(intermediate.nbytes()));
sums.set_data(allocator::malloc(sums.nbytes()));
maxs.set_data(allocator::malloc(maxs.nbytes()));
encoder.add_temporary(intermediate);
encoder.add_temporary(sums);
encoder.add_temporary(maxs);
dispatch_float_types(o.dtype(), "kernel_sdpav_2pass", [&](auto type_tag) {
dispatch_bool(do_causal_, [&](auto do_causal) {
dispatch_headdim(params.D, [&](auto headdim) {
using DataType = cuda_type_t<MLX_GET_TYPE(type_tag)>;
{
auto kernel = cu::
kernel_sdpav_2pass_1<DataType, do_causal.value, headdim.value>;
encoder.set_input_array(q);
encoder.set_input_array(k);
encoder.set_input_array(v);
encoder.set_output_array(intermediate);
encoder.set_output_array(sums);
encoder.set_output_array(maxs);
dim3 grid_dim(params.H, params.qL, params.B * 32);
dim3 block_dim(8 * 32, 1, 1);
encoder.add_kernel_node(
kernel,
grid_dim,
block_dim,
0,
q.data<DataType>(),
k.data<DataType>(),
v.data<DataType>(),
intermediate.data<float>(),
sums.data<float>(),
maxs.data<float>(),
params);
}
{
auto kernel = cu::
kernel_sdpav_2pass_2<DataType, do_causal.value, headdim.value>;
encoder.set_input_array(intermediate);
encoder.set_input_array(sums);
encoder.set_input_array(maxs);
encoder.set_output_array(o);
dim3 grid_dim(params.H, params.qL, params.B);
dim3 block_dim(1024, 1, 1);
encoder.add_kernel_node(
kernel,
grid_dim,
block_dim,
0,
intermediate.data<float>(),
sums.data<float>(),
maxs.data<float>(),
o.data<DataType>(),
params);
}
});
});
});
}
void sdpa_vector_fallback(
const Stream& s,
cu::CommandEncoder& encoder,
const array& q,
const array& k,
const array& v,
const float scale,
array& o,
bool do_causal_ = false) {
int kL = k.shape(2);
if (kL > 1024) {
return sdpa_vector_2pass_fallback(
s, encoder, q, k, v, scale, o, do_causal_);
} else {
return sdpa_vector_1pass_fallback(
s, encoder, q, k, v, scale, o, do_causal_);
}
}
} // namespace
namespace fast {
bool ScaledDotProductAttention::use_fallback(
const array& q,
const array& k,
const array& v,
bool has_mask,
bool has_arr_mask,
bool do_causal,
Stream s) {
if (detail::in_grad_tracing()) {
return true;
}
if (s.device == Device::cpu) {
return true;
}
const int value_head_dim = v.shape(-1);
const int query_head_dim = q.shape(-1);
const int query_sequence_length = q.shape(2);
const int key_sequence_length = k.shape(2);
const bool sdpa_supported_head_dim = query_head_dim == value_head_dim &&
(query_head_dim == 64 || query_head_dim == 96 || query_head_dim == 128);
const bool supported_vector_config =
sdpa_supported_head_dim && query_sequence_length < 4;
const bool supported_config = supported_vector_config;
return has_arr_mask || !supported_config;
}
void ScaledDotProductAttention::eval_gpu(
const std::vector<array>& inputs,
array& out) {
nvtx3::scoped_range r("ScaledDotProductAttention::eval_gpu");
auto& s = stream();
auto& encoder = cu::get_command_encoder(s);
auto& q_pre = inputs[0];
auto& k_pre = inputs[1];
auto& v_pre = inputs[2];
auto& o = out;
std::vector<array> copies;
// Define some copy functions to ensure the layout of the inputs is as
// expected.
copies.reserve(3);
auto copy_unless = [&copies, &s](
auto predicate, const array& arr) -> const array& {
if (!predicate(arr)) {
array arr_copy = contiguous_copy_gpu(arr, s);
copies.push_back(std::move(arr_copy));
return copies.back();
} else {
return arr;
}
};
// We are in vector mode ie single query
if (q_pre.shape(2) < 4) {
auto q_copy_unless = [](const array& arr) {
if (arr.flags().row_contiguous) {
return true;
}
auto& strides = arr.strides();
auto& shape = arr.shape();
if (shape[0] == 1 || shape[1] == 1) {
// If either the batch or head dimension is a singleton, the other can
// be transposed with the sequence dimension
auto bidx = shape[0] == 1 ? 1 : 0;
return (strides[3] == 1) && (strides[2] == shape[3] * shape[bidx]) &&
(strides[bidx] == shape[3]);
}
return false;
};
auto kv_copy_unless = [](const array& arr) {
// keys and values should be copied if:
// - the last dimension is not contiguous
// - the batch and head dim are not contiguous
auto& strides = arr.strides();
auto& shape = arr.shape();
if (strides.back() != 1) {
return false;
}
if (shape[0] == 1 || shape[1] == 1) {
return true;
}
return (strides[0] == strides[1] * shape[1]);
};
const auto& q = copy_unless(q_copy_unless, q_pre);
const auto& k = copy_unless(kv_copy_unless, k_pre);
const auto& v = copy_unless(kv_copy_unless, v_pre);
for (const auto& cp : copies) {
encoder.add_temporary(cp);
}
// Donate the query if possible
if (q.is_donatable() && q.flags().row_contiguous && q.size() == o.size()) {
o.copy_shared_buffer(q);
} else {
int64_t str_oD = 1;
int64_t str_oH = o.shape(3);
int64_t str_oL = o.shape(1) * str_oH;
int64_t str_oB = o.shape(2) * str_oL;
size_t data_size = o.shape(0) * str_oB;
array::Flags flags{
/* bool contiguous = */ 1,
/* bool row_contiguous = */ o.shape(2) == 1,
/* bool col_contiguous = */ 0,
};
o.set_data(
allocator::malloc(o.nbytes()),
data_size,
{str_oB, str_oH, str_oL, str_oD},
flags);
}
return sdpa_vector_fallback(s, encoder, q, k, v, scale_, o, do_causal_);
}
// Full attention mode should never reach here
else {
throw std::runtime_error("Doesn't support matrix yet.");
}
}
} // namespace fast
} // namespace mlx::core

2
mlx/backend/cuda/scan.cu
View File

@@ -414,6 +414,7 @@ void Scan::eval_gpu(const std::vector<array>& inputs, array& out) {
kernel,
in.data_size() / axis_size,
block_dim,
0,
in.data<T>(),
out.data<U>(),
axis_size);
@@ -443,6 +444,7 @@ void Scan::eval_gpu(const std::vector<array>& inputs, array& out) {
kernel,
num_blocks,
block_dim,
0,
in.data<T>(),
out.data<U>(),
axis_size,

30
mlx/backend/cuda/softmax.cu
View File

@@ -11,7 +11,6 @@
#include <cooperative_groups.h>
#include <cooperative_groups/reduce.h>
#include <nvtx3/nvtx3.hpp>
#include <cub/block/block_load.cuh>
#include <cassert>
@@ -45,20 +44,21 @@ __global__ void softmax(const T* in, T* out, int axis_size) {
AccT maxval = Limits<AccT>::finite_min();
AccT normalizer = cast_to<AccT>(0);
for (int r = 0; r < cuda::ceil_div(axis_size, BLOCK_DIM * N_READS); r++) {
AccT vals[N_READS];
cub::LoadDirectBlocked(
r * BLOCK_DIM + block.thread_rank(),
make_cast_iterator<AccT>(in),
vals,
axis_size,
Limits<AccT>::min());
auto index = r * BLOCK_DIM + block.thread_rank();
auto vals = load_vector<N_READS>(in, index, axis_size, Limits<T>::min());
prevmax = maxval;
maxval = max_op(maxval, cub::ThreadReduce(vals, max_op));
#pragma unroll
for (int i = 0; i < N_READS; ++i) {
maxval = max_op(maxval, static_cast<AccT>(vals[i]));
}
// Online normalizer calculation for softmax:
// https://github.com/NVIDIA/online-softmax
normalizer = normalizer * softmax_exp(prevmax - maxval);
#pragma unroll
for (int i = 0; i < N_READS; i++) {
normalizer = normalizer + softmax_exp(vals[i] - maxval);
normalizer =
normalizer + softmax_exp(static_cast<AccT>(vals[i]) - maxval);
}
}
@@ -95,12 +95,11 @@ __global__ void softmax(const T* in, T* out, int axis_size) {
// Write output.
for (int r = 0; r < cuda::ceil_div(axis_size, BLOCK_DIM * N_READS); r++) {
auto index = r * BLOCK_DIM + block.thread_rank();
T vals[N_READS];
cub::LoadDirectBlocked(index, in, vals, axis_size);
auto vals = load_vector<N_READS>(in, index, axis_size, T(0));
for (int i = 0; i < N_READS; i++) {
vals[i] = softmax_exp(static_cast<AccT>(vals[i]) - maxval) * normalizer;
}
cub::StoreDirectBlocked(index, out, vals, axis_size);
store_vector<N_READS>(out, index, vals, axis_size);
}
}
@@ -141,9 +140,9 @@ void Softmax::eval_gpu(const std::vector<array>& inputs, array& out) {
encoder.set_input_array(in);
encoder.set_output_array(out);
dispatch_float_types(out.dtype(), "softmax", [&](auto type_tag) {
constexpr int N_READS = 4;
dispatch_block_dim(cuda::ceil_div(axis_size, N_READS), [&](auto block_dim) {
using DataType = cuda_type_t<MLX_GET_TYPE(type_tag)>;
constexpr int N_READS = 16 / sizeof(DataType);
dispatch_block_dim(cuda::ceil_div(axis_size, N_READS), [&](auto block_dim) {
auto kernel = cu::softmax<DataType, DataType, block_dim(), N_READS>;
if (precise) {
kernel = cu::softmax<DataType, float, block_dim(), N_READS>;
@@ -152,6 +151,7 @@ void Softmax::eval_gpu(const std::vector<array>& inputs, array& out) {
kernel,
n_rows,
block_dim(),
0,
in.data<DataType>(),
out.data<DataType>(),
axis_size);

24
mlx/backend/cuda/sort.cu
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@@ -13,7 +13,6 @@
#include <cub/device/device_segmented_sort.cuh>
#include <cassert>
#include <numeric>
namespace mlx::core {
@@ -27,29 +26,6 @@ struct ModOp {
}
};
// We can not use any op in eval, make an utility.
array swapaxes_in_eval(const array& in, int axis1, int axis2) {
std::vector<int> axes(in.ndim());
std::iota(axes.begin(), axes.end(), 0);
std::swap(axes[axis1], axes[axis2]);
// TODO: Share the code with Transpose::eval.
Shape shape(axes.size());
Strides strides(in.ndim());
for (size_t ax = 0; ax < axes.size(); ++ax) {
shape[ax] = in.shape()[axes[ax]];
strides[ax] = in.strides()[axes[ax]];
}
auto flags = in.flags();
if (flags.contiguous) {
auto [_, row_contiguous, col_contiguous] = check_contiguity(shape, strides);
flags.row_contiguous = row_contiguous;
flags.col_contiguous = col_contiguous;
}
array out(shape, in.dtype(), nullptr, {});
out.copy_shared_buffer(in, strides, flags, in.data_size());
return out;
}
struct OffsetTransform {
int nsort;

9
mlx/backend/cuda/steel/defines.cuh Normal file
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@@ -0,0 +1,9 @@
// Copyright © 2025 Apple Inc.
#pragma once
#define MLX_UNROLL _Pragma("unroll")
#if defined(__CUDA_ARCH__) && (__CUDA_ARCH__ >= 800)
#define MLX_CUDA_SM_80_ENABLED
#endif

101
mlx/backend/cuda/steel/gemm.cuh Normal file
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@@ -0,0 +1,101 @@
#include "mlx/backend/cuda/steel/mma.cuh"
#include "mlx/backend/cuda/steel/tiles.cuh"
namespace mlx::core::cu {
/**
* An example gemm written with the utils.
*
* Computes A @ B.T when A and B are all aligned with the block sizes.
*/
template <typename T, int BM, int BN, int BK>
__global__ void ab_t_aligned(const T* a, const T* b, T* y, int N, int K) {
constexpr int WARPS_M = 2;
constexpr int WARPS_N = 2;
constexpr int NUM_WARPS = WARPS_M * WARPS_N;
constexpr int WARP_STEP_M = BM / WARPS_M;
constexpr int WARP_STEP_N = BN / WARPS_N;
// Precompute some offsets for each thread
const int warpid = threadIdx.x / 32;
const int laneid = threadIdx.x % 32;
const int wm = warpid / WARPS_N;
const int wn = warpid % WARPS_N;
const int offset_m = wm * WARP_STEP_M;
const int offset_n = wn * WARP_STEP_N;
// Allocate shared memory
extern __shared__ char shmem[];
SharedTile<T, BM, BK>(&as)[2] = *(SharedTile<T, BM, BK>(*)[2])(&shmem[0]);
SharedTile<T, BN, BK>(&bs)[2] =
*(SharedTile<T, BN, BK>(*)[2])(&shmem[sizeof(T) * 2 * BM * BK]);
// Allocate registers for the MMA
RegisterTile<float, BM / WARPS_M, BN / WARPS_N> C;
RegisterTile<T, BM / WARPS_M, 16> A;
RegisterTile<T, BN / WARPS_N, 16> B;
// Move the global pointers to the tile
a += blockIdx.y * BM * K;
b += blockIdx.x * BN * K;
y += blockIdx.y * BM * N + blockIdx.x * BN;
// Zero the accumulators
C.fill(0);
// Start the SM pipeline
load_async<NUM_WARPS>(as[0], as[0].base_addr(), a, K);
load_async<NUM_WARPS>(bs[0], bs[0].base_addr(), b, K);
cp_async_commit();
int tic = 0;
for (int k_block = BK; k_block < K; k_block += BK) {
load_async<NUM_WARPS>(as[tic ^ 1], as[tic ^ 1].base_addr(), a + k_block, K);
load_async<NUM_WARPS>(bs[tic ^ 1], bs[tic ^ 1].base_addr(), b + k_block, K);
cp_async_commit();
cp_async_wait<1>();
__syncthreads();
MLX_UNROLL
for (int k = 0; k < BK / 16; k++) {
A.load(
as[tic],
as[tic].base_addr(),
offset_m + laneid % 16,
k * 16 + laneid / 16 * 8);
B.load(
bs[tic],
bs[tic].base_addr(),
offset_n + laneid % 16,
k * 16 + laneid / 16 * 8);
mma_t(C, A, B);
}
tic ^= 1;
}
// Empty the pipeline
cp_async_wait_all();
__syncthreads();
MLX_UNROLL
for (int k = 0; k < BK / 16; k++) {
A.load(
as[tic],
as[tic].base_addr(),
offset_m + laneid % 16,
k * 16 + laneid / 16 * 8);
B.load(
bs[tic],
bs[tic].base_addr(),
offset_n + laneid % 16,
k * 16 + laneid / 16 * 8);
mma_t(C, A, B);
}
C.store_global(y, N, offset_m, offset_n);
}
} // namespace mlx::core::cu

117
mlx/backend/cuda/steel/mma.cuh Normal file
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@@ -0,0 +1,117 @@
// Copyright © 2025 Apple Inc.
#pragma once
#include "mlx/backend/cuda/steel/defines.cuh"
#include "mlx/backend/cuda/steel/tiles.cuh"
namespace mlx::core::cu {
/**
* Fallback mma.
*
* We should probably a) implement a fallback or complain about it to the
* compiler.
*/
template <typename U, typename T>
__device__ inline void
mma_t(Tile16x16<U>& C, Tile16x16<T>& A, Tile16x16<T>& B) {}
/**
* Multiply the 16x16 bfloat16 tiles and accumulate the result in one 16x16
* float tile.
*
* We actually perform C += A @ B.T
*/
__device__ __forceinline__ void mma_t(
Tile16x16<float>& C,
Tile16x16<__nv_bfloat16>& A,
Tile16x16<__nv_bfloat16>& B) {
#if defined(MLX_CUDA_SM_80_ENABLED)
asm volatile(
"mma.sync.aligned.m16n8k16.row.col.f32.bf16.bf16.f32 "
"{%0, %1, %2, %3}, "
"{%4, %5, %6, %7}, "
"{%8, %9}, "
"{%10, %11, %12, %13};"
// D matrix
: "+f"(C.values[0].x),
"+f"(C.values[0].y),
"+f"(C.values[1].x),
"+f"(C.values[1].y)
// A matrix
: "r"(*(uint32_t*)(&A.values[0])),
"r"(*(uint32_t*)(&A.values[1])),
"r"(*(uint32_t*)(&A.values[2])),
"r"(*(uint32_t*)(&A.values[3])),
// B matrix
"r"(*(uint32_t*)(&B.values[0])),
"r"(*(uint32_t*)(&B.values[2])),
// C matrix
"f"(C.values[0].x),
"f"(C.values[0].y),
"f"(C.values[1].x),
"f"(C.values[1].y));
asm volatile(
"mma.sync.aligned.m16n8k16.row.col.f32.bf16.bf16.f32 "
"{%0, %1, %2, %3}, "
"{%4, %5, %6, %7}, "
"{%8, %9}, "
"{%10, %11, %12, %13};"
// D matrix
: "+f"(C.values[2].x),
"+f"(C.values[2].y),
"+f"(C.values[3].x),
"+f"(C.values[3].y)
// A matrix
: "r"(*(uint32_t*)(&A.values[0])),
"r"(*(uint32_t*)(&A.values[1])),
"r"(*(uint32_t*)(&A.values[2])),
"r"(*(uint32_t*)(&A.values[3])),
// B matrix
"r"(*(uint32_t*)(&B.values[1])),
"r"(*(uint32_t*)(&B.values[3])),
// C matrix
"f"(C.values[2].x),
"f"(C.values[2].y),
"f"(C.values[3].x),
"f"(C.values[3].y));
#endif
}
/**
* Multiply larger register tiles by delegating to mma_t.
*/
template <typename U, typename T, int M, int N, int K>
__device__ __forceinline__ void mma_t(
RegisterTile<U, M, N>& C,
RegisterTile<T, M, K>& A,
RegisterTile<T, N, K>& B) {
constexpr int TILES_M = RegisterTile<T, M, K>::TILES_Y;
constexpr int TILES_K = RegisterTile<T, M, K>::TILES_X;
constexpr int TILES_N = RegisterTile<T, N, K>::TILES_Y;
MLX_UNROLL
for (int k = 0; k < TILES_K; k++) {
MLX_UNROLL
for (int m = 0; m < TILES_M; m++) {
MLX_UNROLL
for (int n = 0; n < TILES_N; n++) {
mma_t(
C.data[m * TILES_N + n],
A.data[m * TILES_K + k],
B.data[n * TILES_K + k]);
}
}
}
}
} // namespace mlx::core::cu

473
mlx/backend/cuda/steel/tiles.cuh Normal file
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@@ -0,0 +1,473 @@
// Copyright © 2025 Apple Inc.
#pragma once
#include "mlx/backend/cuda/steel/utils.cuh"
namespace mlx::core::cu {
// Map types to their vector of 2 type float -> float2, double -> double2 etc
template <typename T>
struct Vector2;
template <>
struct Vector2<double> {
using type = double2;
};
template <>
struct Vector2<float> {
using type = float2;
};
template <>
struct Vector2<__half> {
using type = __half2;
};
template <>
struct Vector2<__nv_bfloat16> {
using type = __nv_bfloat162;
};
template <typename T>
using Vector2_t = typename Vector2<T>::type;
/**
* The basic building block for Ampere mmas. A 16x16 tile distributed across
* the warp.
*
* Each thread holds 8 values. They are distributed according to
* https://docs.nvidia.com/cuda/parallel-thread-execution/#warp-level-matrix-fragment-mma-16816-float
*
* For use instructions see the individual methods eg load().
*/
template <typename T>
struct Tile16x16 {
using T2 = Vector2_t<T>;
T2 values[4];
__device__ inline void fill(T v) {
T2 v2 = {v, v};
for (int i = 0; i < 4; i++) {
values[i] = v2;
}
}
/**
* Load a 16x16 tile from shared memory.
*
* The instruction is a bit weird in the sense that the address provided by
* each thread and the elements loaded are not the same.
*
* We load 4 8x8 tiles. The tile rows are stored contiguously in memory. As a
* result the warp provides 4*8 = 32 addresses one per row.
*
* Threads 0-7 provide the addresses for the first tile, 8-15 for the second
* and so on. For instance to load a non swizzled tile we would do
*
* base_addr + (laneid % 16) * BK + (laneid / 2) * 8
*
* See
* https://docs.nvidia.com/cuda/parallel-thread-execution/#warp-level-matrix-instructions-ldmatrix
*/
__device__ __forceinline__ void load(uint32_t row_address) {
if constexpr (
std::is_same_v<T2, __nv_bfloat162> || std::is_same_v<T2, __half2>) {
asm volatile(
"ldmatrix.sync.aligned.m8n8.x4.shared::cta.b16 {%0, %1, %2, %3}, [%4];\n"
: "=r"(*(uint32_t*)&(values[0])),
"=r"(*(uint32_t*)&(values[1])),
"=r"(*(uint32_t*)&(values[2])),
"=r"(*(uint32_t*)&(values[3]))
: "r"(row_address));
}
}
/**
* Store the tile to the address pointed to by `x`.
*
* The provided pointer is a generic pointer but this is meant to be used to
* store to global memory. For storing to shared memory we should use
* `stmatrix`.
*
* This also showcases the format of the tile quite nicely. Each register is
* holding to adjacent values. The indices are
*
* row + 0, col + 0
* row + 8, col + 0
* row + 0, col + 8
* row + 8, col + 8
*
* Given that we are dealing with Vector2_t<U> the column offsets are 4
* instead of 8.
*/
template <typename U>
__device__ inline void store_global(U* x, int N) {
using U2 = Vector2_t<U>;
U2* x2 = reinterpret_cast<U2*>(x);
const int laneid = threadIdx.x % 32;
const int row = laneid / 4;
const int col = laneid % 4;
if constexpr (std::is_same_v<U2, T2>) {
x2[(row + 0) * (N / 2) + col + 0] = values[0];
x2[(row + 0) * (N / 2) + col + 4] = values[2];
x2[(row + 8) * (N / 2) + col + 0] = values[1];
x2[(row + 8) * (N / 2) + col + 4] = values[3];
} else if constexpr (
std::is_same_v<T2, float2> && std::is_same_v<U, __nv_bfloat16>) {
x2[(row + 0) * (N / 2) + col + 0] =
__floats2bfloat162_rn(values[0].x, values[0].y);
x2[(row + 0) * (N / 2) + col + 4] =
__floats2bfloat162_rn(values[2].x, values[2].y);
x2[(row + 8) * (N / 2) + col + 0] =
__floats2bfloat162_rn(values[1].x, values[1].y);
x2[(row + 8) * (N / 2) + col + 4] =
__floats2bfloat162_rn(values[3].x, values[3].y);
}
}
template <typename U>
__device__ inline void store_global_safe(U* x, int N, int max_rows) {
const int laneid = threadIdx.x % 32;
const int row = laneid / 4;
const int col = laneid % 4;
if (row < max_rows) {
x[(row + 0) * N + 2 * col + 0] = static_cast<U>(values[0].x);
x[(row + 0) * N + 2 * col + 1] = static_cast<U>(values[0].y);
x[(row + 0) * N + 2 * col + 8] = static_cast<U>(values[2].x);
x[(row + 0) * N + 2 * col + 9] = static_cast<U>(values[2].y);
}
if (row + 8 < max_rows) {
x[(row + 8) * N + 2 * col + 0] = static_cast<U>(values[1].x);
x[(row + 8) * N + 2 * col + 1] = static_cast<U>(values[1].y);
x[(row + 8) * N + 2 * col + 8] = static_cast<U>(values[3].x);
x[(row + 8) * N + 2 * col + 9] = static_cast<U>(values[3].y);
}
}
};
// /**
// * A simple container of multiple Tile16x16.
// *
// * Provides utility functions for loading and manipulating collections of
// basic
// * tiles.
// */
// template <typename T, int ROWS_, int COLS_>
// struct RegisterTile {
// static constexpr int ROWS = ROWS_;
// static constexpr int COLS = COLS_;
// static constexpr int TILES_X = COLS / 16;
// static constexpr int TILES_Y = ROWS / 16;
// Tile16x16<T> data[TILES_X * TILES_Y];
// __device__ inline void fill(T v) {
// MLX_UNROLL
// for (int i = 0; i < TILES_Y; i++) {
// MLX_UNROLL
// for (int j = 0; j < TILES_X; j++) {
// data[i * TILES_X + j].fill(v);
// }
// }
// }
// template <typename Tile>
// __device__ __forceinline__ void
// load(Tile& tile, uint32_t base_address, int row, int col) {
// MLX_UNROLL
// for (int i = 0; i < TILES_Y; i++) {
// MLX_UNROLL
// for (int j = 0; j < TILES_X; j++) {
// data[i * TILES_X + j].load(
// tile.loc(base_address, row + i * 16, col + j * 16));
// }
// }
// }
// template <typename Tile, typename F>
// __device__ __forceinline__ void
// load(Tile& tile, F f, uint32_t base_address, int row, int col) {
// MLX_UNROLL
// for (int i = 0; i < TILES_Y; i++) {
// MLX_UNROLL
// for (int j = 0; j < TILES_X; j++) {
// f(data[i * TILES_X + j],
// tile,
// base_address,
// row + i * 16,
// col + j * 16);
// }
// }
// }
// template <typename U>
// __device__ inline void store_global(U* x, int N, int row, int col) {
// MLX_UNROLL
// for (int i = 0; i < TILES_Y; i++) {
// MLX_UNROLL
// for (int j = 0; j < TILES_X; j++) {
// data[i * TILES_X + j].store_global(
// x + (row + i * 16) * N + col + j * 16, N);
// }
// }
// }
// template <typename U>
// __device__ inline void
// store_global_safe(U* x, int N, int row, int col, int max_rows) {
// MLX_UNROLL
// for (int i = 0; i < TILES_Y; i++) {
// MLX_UNROLL
// for (int j = 0; j < TILES_X; j++) {
// data[i * TILES_X + j].store_global_safe(
// x + (row + i * 16) * N + col + j * 16, N, max_rows - row - i *
// 16);
// }
// }
// }
// };
/**
* A simple container of multiple Tile16x16.
*
* Provides utility functions for loading and manipulating collections of basic
* tiles.
*/
template <typename T, int ROWS_, int COLS_>
struct RegisterTile {
static constexpr int ROWS = ROWS_;
static constexpr int COLS = COLS_;
static constexpr int TILES_X = COLS / 16;
static constexpr int TILES_Y = ROWS / 16;
Tile16x16<T> data[TILES_X * TILES_Y];
__device__ inline void fill(T v) {
MLX_UNROLL
for (int i = 0; i < TILES_Y; i++) {
MLX_UNROLL
for (int j = 0; j < TILES_X; j++) {
data[i * TILES_X + j].fill(v);
}
}
}
template <typename Tile>
__device__ inline void
load(Tile& tile, uint32_t base_address, int row, int col) {
MLX_UNROLL
for (int i = 0; i < TILES_Y; i++) {
MLX_UNROLL
for (int j = 0; j < TILES_X; j++) {
data[i * TILES_X + j].load(
tile.loc(base_address, row + i * 16, col + j * 16));
}
}
}
template <typename U>
__device__ inline void store_global(U* x, int N, int row, int col) {
MLX_UNROLL
for (int i = 0; i < TILES_Y; i++) {
MLX_UNROLL
for (int j = 0; j < TILES_X; j++) {
data[i * TILES_X + j].store_global(
x + (row + i * 16) * N + col + j * 16, N);
}
}
}
};
template <typename T, int ROWS_, int COLS_>
struct SharedTile {
static constexpr int ROWS = ROWS_;
static constexpr int COLS = COLS_;
static constexpr int TILES_X = COLS / 16;
static constexpr int TILES_Y = ROWS / 16;
static constexpr int NUMEL = ROWS * COLS;
// Swizzle taken from ThunderKittens. Should be changed when we switch to
// cute Layouts.
//
// See inludes/types/shared/st.cuh
//
// I do feel that it is too math heavy and can be improved. Also the math is
// done every time although the addresses don't change from load to load. I
// guess we are expecting the compiler to figure that out.
static constexpr int swizzle_bytes =
(sizeof(T) == 2 ? (TILES_X % 4 == 0 ? 128 : (TILES_X % 2 == 0 ? 64 : 32))
: (sizeof(T) == 4 ? (TILES_X % 2 == 0 ? 128 : 64) : 0));
T data[ROWS * COLS];
__device__ inline uint32_t base_addr() const {
return __cvta_generic_to_shared(&data[0]);
}
// Return a pointer to the element at (row, col) using the swizzle.
__device__ static inline T* ptr(T* ptr, int row, int col) {
if constexpr (swizzle_bytes > 0) {
static constexpr int swizzle_repeat = swizzle_bytes * 8;
static constexpr int subtile_cols = swizzle_bytes / sizeof(T);
const int outer_idx = col / subtile_cols;
const uint64_t addr =
(uint64_t)(&ptr
[outer_idx * ROWS * subtile_cols + row * subtile_cols +
col % subtile_cols]);
const int swizzle = ((addr % swizzle_repeat) >> 7) << 4;
return (T*)(addr ^ swizzle);
} else {
return ptr + row * COLS + col;
}
}
// Return the location of the element at (row, col) using the swizzle.
__device__ static inline uint32_t loc(uint32_t ptr, int row, int col) {
if constexpr (swizzle_bytes > 0) {
static constexpr int swizzle_repeat = swizzle_bytes * 8;
static constexpr int subtile_cols = swizzle_bytes / sizeof(T);
const int outer_idx = col / subtile_cols;
const uint32_t addr = ptr +
sizeof(T) *
(outer_idx * ROWS * subtile_cols + row * subtile_cols +
col % subtile_cols);
const int swizzle = ((addr % swizzle_repeat) >> 7) << 4;
return (addr ^ swizzle);
} else {
return ptr + sizeof(T) * (row * COLS + col);
}
}
// Convenience functions to edit elements going through the swizzle.
__device__ inline T& operator()(int row, int col) {
return *ptr(data, row, col);
}
__device__ inline void store(float4& v, int row, int col) {
*(reinterpret_cast<float4*>(ptr(data, row, col))) = v;
}
__device__ inline void store(float2& v, int row, int col) {
*(reinterpret_cast<float2*>(ptr(data, row, col))) = v;
}
__device__ inline void store(float& v, int row, int col) {
*(reinterpret_cast<float*>(ptr(data, row, col))) = v;
}
template <int N>
__device__ inline void store(T (&v)[N], int row, int col) {
if constexpr (sizeof(T) * N == 4) {
store(*(reinterpret_cast<float*>(&v[0])), row, col);
} else if constexpr (sizeof(T) * N == 8) {
store(*(reinterpret_cast<float2*>(&v[0])), row, col);
} else if constexpr (sizeof(T) * N == 16) {
store(*(reinterpret_cast<float4*>(&v[0])), row, col);
} else {
MLX_UNROLL
for (int i = 0; i < N; i++) {
*ptr(data, row, col + i) = v[i];
}
}
}
};
/**
* Load the tile from global memory by loading 16 bytes at a time and storing
* them immediately.
*
* Can also be used as a fallback for architectures before sm_80.
*/
template <int NUM_WARPS, typename T, typename Tile>
__device__ inline void load(Tile& tile, const T* x, int N) {
constexpr int NUM_THREADS = NUM_WARPS * 32;
constexpr int ELEMENTS_PER_LOAD = sizeof(float4) / sizeof(T);
constexpr int NUM_LOADS = Tile::NUMEL / ELEMENTS_PER_LOAD;
constexpr int NUM_LOADS_PER_THREAD = NUM_LOADS / NUM_THREADS;
constexpr int NUM_LOADS_PER_ROW = Tile::COLS / ELEMENTS_PER_LOAD;
constexpr int STEP_ROWS = NUM_THREADS / NUM_LOADS_PER_ROW;
const int row = threadIdx.x / NUM_LOADS_PER_ROW;
const int col = threadIdx.x % NUM_LOADS_PER_ROW;
x += row * N + col * ELEMENTS_PER_LOAD;
MLX_UNROLL
for (int i = 0; i < NUM_LOADS_PER_THREAD; i++) {
float4 tmp;
tmp = *(reinterpret_cast<const float4*>(&x[i * STEP_ROWS * N]));
tile.store(tmp, row + i * STEP_ROWS, col * ELEMENTS_PER_LOAD);
}
}
/**
* The asynchronous equivalent of load.
*
* Loads the tile from global memory by submitting a bunch of async copy
* instructions. The copy won't start until commit is called and we don't have
* a guarantee it will finish until wait is called.
*
* It should be used as follows
*
* load(...)
* load(...)
* cp_async_commit()
* do_other_stuff()
* cp_async_wait_all()
* do_stuff_with_shmem()
*/
template <int NUM_WARPS, typename T, typename Tile>
__device__ inline void
load_async(Tile& tile, uint32_t base_address, const T* x, int N) {
constexpr int NUM_THREADS = NUM_WARPS * 32;
constexpr int ELEMENTS_PER_LOAD = sizeof(float4) / sizeof(T);
constexpr int NUM_LOADS = Tile::NUMEL / ELEMENTS_PER_LOAD;
constexpr int NUM_LOADS_PER_THREAD = NUM_LOADS / NUM_THREADS;
constexpr int NUM_LOADS_PER_ROW = Tile::COLS / ELEMENTS_PER_LOAD;
constexpr int STEP_ROWS = NUM_THREADS / NUM_LOADS_PER_ROW;
const int row = threadIdx.x / NUM_LOADS_PER_ROW;
const int col = threadIdx.x % NUM_LOADS_PER_ROW;
x += row * N + col * ELEMENTS_PER_LOAD;
MLX_UNROLL
for (int i = 0; i < NUM_LOADS_PER_THREAD; i++) {
cp_async<16>(
tile.loc(base_address, row + i * STEP_ROWS, col * ELEMENTS_PER_LOAD),
x + i * STEP_ROWS * N);
}
}
/**
* Same as load_async but checks if we can load the row.
*
* NOTE: It should be changed to use a predicated cp async instead.
*/
template <int NUM_WARPS, typename T, typename Tile>
__device__ inline void load_async_safe(
Tile& tile,
uint32_t base_address,
const T* x,
int N,
int max_rows) {
constexpr int NUM_THREADS = NUM_WARPS * 32;
constexpr int ELEMENTS_PER_LOAD = sizeof(float4) / sizeof(T);
constexpr int NUM_LOADS = Tile::NUMEL / ELEMENTS_PER_LOAD;
constexpr int NUM_LOADS_PER_THREAD = NUM_LOADS / NUM_THREADS;
constexpr int NUM_LOADS_PER_ROW = Tile::COLS / ELEMENTS_PER_LOAD;
constexpr int STEP_ROWS = NUM_THREADS / NUM_LOADS_PER_ROW;
const int row = threadIdx.x / NUM_LOADS_PER_ROW;
const int col = threadIdx.x % NUM_LOADS_PER_ROW;
x += row * N + col * ELEMENTS_PER_LOAD;
MLX_UNROLL
for (int i = 0; i < NUM_LOADS_PER_THREAD; i++) {
if (row + i * STEP_ROWS < max_rows) {
cp_async<16>(
tile.loc(base_address, row + i * STEP_ROWS, col * ELEMENTS_PER_LOAD),
x + i * STEP_ROWS * N);
} else {
float4 tmp = {0, 0, 0, 0};
tile.store(tmp, row + i * STEP_ROWS, col * ELEMENTS_PER_LOAD);
}
}
}
} // namespace mlx::core::cu

89
mlx/backend/cuda/steel/utils.cuh Normal file
View File

@@ -0,0 +1,89 @@
// Copyright © 2025 Apple Inc.
#pragma once
#include "mlx/backend/cuda/device/utils.cuh"
#include "mlx/backend/cuda/steel/defines.cuh"
namespace mlx::core::cu {
/**
* Copy bytes from the global memory address pointed to by x to the smem
* address pointed to by row_address.
*
* A simple wrapper over the PTX.
*/
template <int N, typename T>
__device__ inline void cp_async(uint32_t row_address, const T* x) {
static_assert(
N == 16 || N == 8 || N == 4,
"cp.async is only supported for N in {4, 8, 16}.");
#if defined(MLX_CUDA_SM_80_ENABLED)
if constexpr (N == 16) {
asm volatile(
"cp.async.ca.shared::cta.global [%0], [%1], 16;\n" ::"r"(row_address),
"l"(reinterpret_cast<const int4*>(x)));
} else if constexpr (N == 8) {
asm volatile(
"cp.async.ca.shared::cta.global [%0], [%1], 8;\n" ::"r"(row_address),
"l"(reinterpret_cast<const int2*>(x)));
} else if constexpr (N == 4) {
asm volatile(
"cp.async.ca.shared::cta.global [%0], [%1], 4;\n" ::"r"(row_address),
"l"(reinterpret_cast<const int*>(x)));
}
#endif
}
/**
* Submit all the previous async copies to be executed.
*/
__device__ inline void cp_async_commit() {
#if defined(MLX_CUDA_SM_80_ENABLED)
asm volatile("cp.async.commit_group;\n" ::);
#endif
}
/**
* Wait for all but N of the async copies to finish.
*/
template <int N>
__device__ inline void cp_async_wait() {
#if defined(MLX_CUDA_SM_80_ENABLED)
if constexpr (N == 0) {
asm volatile("cp.async.wait_all;\n" ::);
} else {
asm volatile("cp.async.wait_group %0;\n" ::"n"(N));
}
#endif
}
/**
* Wait for all the async copies to finish.
*/
__device__ inline void cp_async_wait_all() {
cp_async_wait<0>();
}
/**
* Extract ``bits`` bits from the 32 bit value.
*
* Single instruction shift and mask.
*/
template <int bits>
__device__ inline uint32_t extract_bits(uint32_t value, int start_bit) {
static_assert(
bits == 2 || bits == 4 || bits == 8,
"extract_bits only supports 2, 4, 8 for now.");
uint32_t result;
if constexpr (bits == 2) {
asm("bfe.u32 %0, %1, %2, 2;" : "=r"(result) : "r"(value), "r"(start_bit));
} else if constexpr (bits == 4) {
asm("bfe.u32 %0, %1, %2, 4;" : "=r"(result) : "r"(value), "r"(start_bit));
} else if constexpr (bits == 8) {
asm("bfe.u32 %0, %1, %2, 8;" : "=r"(result) : "r"(value), "r"(start_bit));
}
return result;
}
} // namespace mlx::core::cu

35
mlx/backend/cuda/ternary.cu
View File

@@ -32,7 +32,7 @@ ternary_v(const bool* a, const T* b, const T* c, T* out, IdxT size) {
AlignedVector<T, N_READS> out_vec;
#pragma unroll
for (int i = 0; i < N_READS; ++i) {
out_vec.val[i] = Op{}(a_vec.val[i], b_vec.val[i], c_vec.val[i]);
out_vec[i] = Op{}(a_vec[i], b_vec[i], c_vec[i]);
}
store_vector<N_READS>(out, index, out_vec);
@@ -76,7 +76,7 @@ __global__ void ternary_g(
int ndim) {
IdxT index = cg::this_grid().thread_rank();
if (index < size) {
auto [a_idx, b_idx, c_idx] = elem_to_loc_4d(
auto [a_idx, b_idx, c_idx] = elem_to_loc(
index,
shape.data(),
a_strides.data(),
@@ -125,14 +125,12 @@ void ternary_op_gpu_inplace(
int ndim = shape.size();
if (ndim <= 3) {
dispatch_1_2_3(ndim, [&](auto dims_constant) {
auto kernel =
cu::ternary_g_nd<Op, DType, IdxT, dims_constant()>;
auto [num_blocks, block_dims] =
get_launch_args(kernel, out, large());
auto [num_blocks, block_dims] = get_launch_args(out, large());
encoder.add_kernel_node(
kernel,
cu::ternary_g_nd<Op, DType, IdxT, dims_constant()>,
num_blocks,
block_dims,
0,
a.data<bool>(),
b.data<DType>(),
c.data<DType>(),
@@ -144,13 +142,12 @@ void ternary_op_gpu_inplace(
const_param<dims_constant()>(c_strides));
});
} else {
auto kernel = cu::ternary_g<Op, DType, IdxT>;
auto [num_blocks, block_dims] =
get_launch_args(kernel, out, large());
auto [num_blocks, block_dims] = get_launch_args(out, large());
encoder.add_kernel_node(
kernel,
cu::ternary_g<Op, DType, IdxT>,
num_blocks,
block_dims,
0,
a.data<bool>(),
b.data<DType>(),
c.data<DType>(),
@@ -166,20 +163,14 @@ void ternary_op_gpu_inplace(
} else {
dispatch_bool(out.data_size() > UINT32_MAX, [&](auto large) {
using IdxT = std::conditional_t<large(), int64_t, uint32_t>;
// TODO: Choose optimized value based on type size.
constexpr int N_READS = 4;
auto kernel = cu::ternary_v<Op, DType, IdxT, N_READS>;
constexpr int N_READS = 16 / sizeof(DType);
auto [num_blocks, block_dims] = get_launch_args(
kernel,
out.data_size(),
out.shape(),
out.strides(),
large(),
N_READS);
out.data_size(), out.shape(), out.strides(), large(), N_READS);
encoder.add_kernel_node(
kernel,
cu::ternary_v<Op, DType, IdxT, N_READS>,
num_blocks,
block_dims,
0,
a.data<bool>(),
b.data<DType>(),
c.data<DType>(),
@@ -204,7 +195,7 @@ void ternary_op_gpu(
}
void Select::eval_gpu(const std::vector<array>& inputs, array& out) {
nvtx3::scoped_range r("select::eval_gpu");
nvtx3::scoped_range r("Select::eval_gpu");
auto& s = out.primitive().stream();
ternary_op_gpu<cu::Select>(inputs, out, s);
}

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

@@ -3,7 +3,6 @@
#include "mlx/backend/common/unary.h"
#include "mlx/backend/cuda/device.h"
#include "mlx/backend/cuda/device/unary_ops.cuh"
#include "mlx/backend/cuda/iterators/general_iterator.cuh"
#include "mlx/backend/cuda/kernel_utils.cuh"
#include "mlx/dtype_utils.h"
#include "mlx/primitives.h"
@@ -31,7 +30,7 @@ __global__ void unary_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.val[i] = Op{}(in_vec.val[i]);
out_vec[i] = Op{}(in_vec[i]);
}
store_vector<N_READS>(out, index, out_vec);
@@ -48,7 +47,7 @@ __global__ void unary_g(
int ndim) {
IdxT index = cg::this_grid().thread_rank();
if (index < size) {
auto idx = elem_to_loc_4d(index, shape.data(), strides.data(), ndim);
auto idx = elem_to_loc(index, shape.data(), strides.data(), ndim);
out[index] = Op{}(in[idx]);
}
}
@@ -130,30 +129,25 @@ void unary_op_gpu_inplace(
using IdxT = std::conditional_t<large(), int64_t, uint32_t>;
// TODO: Choose optimized value based on type size.
constexpr int N_READS = 4;
auto kernel = cu::unary_v<Op, InType, OutType, IdxT, N_READS>;
auto [num_blocks, block_dims] = get_launch_args(
kernel,
out.data_size(),
out.shape(),
out.strides(),
large,
N_READS);
out.data_size(), out.shape(), out.strides(), large, N_READS);
encoder.add_kernel_node(
kernel,
cu::unary_v<Op, InType, OutType, IdxT, N_READS>,
num_blocks,
block_dims,
0,
in.data<InType>(),
out.data<OutType>(),
out.data_size());
} else {
using IdxT = std::conditional_t<large(), int64_t, int32_t>;
auto [shape, strides] = collapse_contiguous_dims(in);
auto kernel = cu::unary_g<Op, InType, OutType, IdxT>;
auto [num_blocks, block_dims] = get_launch_args(kernel, out, large);
auto [num_blocks, block_dims] = get_launch_args(out, large);
encoder.add_kernel_node(
kernel,
cu::unary_g<Op, InType, OutType, IdxT>,
num_blocks,
block_dims,
0,
in.data<InType>(),
out.data<OutType>(),
out.data_size(),

29
mlx/backend/cuda/utils.cpp
View File

@@ -17,6 +17,35 @@ CudaStream::~CudaStream() {
CHECK_CUDA_ERROR(cudaStreamDestroy(stream_));
}
CudaGraphExec::CudaGraphExec(cudaGraphExec_t handle) : handle_(handle) {}
CudaGraphExec::CudaGraphExec(CudaGraphExec&& other) : handle_(other.handle_) {
other.handle_ = nullptr;
};
CudaGraphExec::~CudaGraphExec() {
reset();
}
void CudaGraphExec::instantiate(cudaGraph_t graph) {
CHECK_CUDA_ERROR(cudaGraphInstantiate(&handle_, graph, nullptr, nullptr, 0));
}
void CudaGraphExec::reset() {
if (handle_ != nullptr) {
CHECK_CUDA_ERROR(cudaGraphExecDestroy(handle_));
handle_ = nullptr;
}
}
void check_cublas_error(const char* name, cublasStatus_t err) {
if (err != CUBLAS_STATUS_SUCCESS) {
// TODO: Use cublasGetStatusString when it is widely available.
throw std::runtime_error(
fmt::format("{} failed with code: {}.", name, static_cast<int>(err)));
}
}
void check_cuda_error(const char* name, cudaError_t err) {
if (err != cudaSuccess) {
throw std::runtime_error(

24
mlx/backend/cuda/utils.h
View File

@@ -4,6 +4,7 @@
#pragma once
#include <cublasLt.h>
#include <cuda.h>
#include <cuda_runtime.h>
@@ -32,11 +33,34 @@ class CudaStream {
cudaStream_t stream_;
};
// Move-able RAII handle of cudaGraphExec_t.
class CudaGraphExec {
public:
CudaGraphExec(cudaGraphExec_t handle = nullptr);
CudaGraphExec(CudaGraphExec&& other);
~CudaGraphExec();
CudaGraphExec(const CudaGraphExec&) = delete;
CudaGraphExec& operator=(const CudaGraphExec&) = delete;
void instantiate(cudaGraph_t graph);
void reset();
operator cudaGraphExec_t() const {
return handle_;
}
private:
cudaGraphExec_t handle_;
};
// Throw exception if the cuda API does not succeed.
void check_cublas_error(const char* name, cublasStatus_t err);
void check_cuda_error(const char* name, cudaError_t err);
void check_cuda_error(const char* name, CUresult err);
// The macro version that prints the command that failed.
#define CHECK_CUBLAS_ERROR(cmd) check_cublas_error(#cmd, (cmd))
#define CHECK_CUDA_ERROR(cmd) check_cuda_error(#cmd, (cmd))
// Convert Dtype to CUDA C++ types.

58
mlx/backend/cuda/worker.cpp
View File

@@ -1,7 +1,6 @@
// Copyright © 2025 Apple Inc.
#include "mlx/backend/cuda/worker.h"
#include "mlx/backend/cuda/allocator.h"
#include "mlx/backend/cuda/device.h"
namespace mlx::core::cu {
@@ -12,10 +11,10 @@ Worker::Worker()
Worker::~Worker() {
{
std::lock_guard lock(worker_mutex_);
std::lock_guard lock(mtx_);
stop_ = true;
}
worker_event_.signal(batch_ + 1);
cond_.notify_one();
worker_.join();
}
@@ -23,53 +22,41 @@ void Worker::add_task(std::function<void()> task) {
pending_tasks_.push_back(std::move(task));
}
void Worker::consume_in_this_thread() {
for (auto& task : pending_tasks_) {
task();
}
pending_tasks_.clear();
}
void Worker::end_batch() {
batch_++;
void Worker::signal(void* data) {
auto w = static_cast<Worker*>(data);
{
std::lock_guard lock(worker_mutex_);
worker_tasks_[batch_] = std::move(pending_tasks_);
std::lock_guard lock(w->mtx_);
w->signaled_batch_++;
}
uncommited_batches_++;
}
void Worker::commit() {
if (uncommited_batches_ == 0) {
return;
}
uncommited_batches_ = 0;
worker_event_.signal(batch_);
w->cond_.notify_one();
}
void Worker::commit(cudaStream_t stream) {
if (uncommited_batches_ == 0) {
// Move pending tasks into tasks
if (pending_tasks_.empty()) {
return;
}
uncommited_batches_ = 0;
// Signal the |worker_event_| in |signal_stream_| after the kernels in
// |stream_| finish running.
{
std::lock_guard lock(mtx_);
// Move pending tasks into ready tasks
worker_tasks_[++committed_batch_] = std::move(pending_tasks_);
}
signal_event_.record(stream);
signal_event_.wait(signal_stream_);
worker_event_.signal(signal_stream_, batch_);
cudaLaunchHostFunc(signal_stream_, signal, this);
}
void Worker::thread_fn() {
// The worker thread is safe to free buffers.
allocator().register_this_thread();
while (!stop_) {
uint64_t batch = worker_event_.value();
uint64_t current_batch = 0;
Tasks tasks;
{
std::lock_guard lock(worker_mutex_);
// Move tasks in signaled batches.
auto end = worker_tasks_.upper_bound(batch);
std::unique_lock<std::mutex> lk(mtx_);
cond_.wait(lk, [this, &current_batch] {
return this->signaled_batch_ > current_batch || this->stop_;
});
current_batch = signaled_batch_;
auto end = worker_tasks_.upper_bound(current_batch);
for (auto it = worker_tasks_.begin(); it != end; ++it) {
if (tasks.empty()) {
tasks = std::move(it->second);
@@ -85,7 +72,6 @@ void Worker::thread_fn() {
auto task = std::move(tasks[i]);
task();
}
worker_event_.wait(batch + 1);
}
}

30
mlx/backend/cuda/worker.h
View File

@@ -5,6 +5,7 @@
#include "mlx/backend/cuda/event.h"
#include "mlx/backend/cuda/utils.h"
#include <condition_variable>
#include <functional>
#include <map>
#include <mutex>
@@ -24,38 +25,24 @@ class Worker {
// Add a pending |task| that will run when consumed or commited.
void add_task(std::function<void()> task);
// Run pending tasks immediately in current thread.
void consume_in_this_thread();
// Put pending tasks in a batch.
void end_batch();
// Inform worker thread to run current batches now.
void commit();
// Inform worker thread to run current batches after kernels in |stream|
// finish running.
void commit(cudaStream_t stream);
// Return how many batches have been added but not committed yet.
size_t uncommited_batches() const {
return uncommited_batches_;
}
private:
void thread_fn();
static void signal(void*);
uint64_t batch_{0};
size_t uncommited_batches_{0};
void thread_fn();
std::mutex mtx_;
std::condition_variable cond_;
uint64_t committed_batch_{0};
uint64_t signaled_batch_{0};
// Cuda stream and event for signaling kernel completion.
CudaStream signal_stream_;
CudaEvent signal_event_;
// Worker thread.
SharedEvent worker_event_;
std::thread worker_;
std::mutex worker_mutex_;
bool stop_{false};
// Tasks are put in |pending_tasks_| first, and then moved to
@@ -63,6 +50,7 @@ class Worker {
using Tasks = std::vector<std::function<void()>>;
Tasks pending_tasks_;
std::map<uint64_t, Tasks> worker_tasks_;
std::thread worker_;
};
} // namespace mlx::core::cu

1
mlx/backend/gpu/primitives.cpp
View File

@@ -133,6 +133,7 @@ void NumberOfElements::eval_gpu(const std::vector<array>& inputs, array& out) {
}
void Pad::eval_gpu(const std::vector<array>& inputs, array& out) {
MLX_PROFILER_RANGE("Pad::eval_gpu");
// Inputs must be base input array and scalar val array
assert(inputs.size() == 2);
auto& in = inputs[0];

3
mlx/backend/metal/allocator.cpp
View File

@@ -128,8 +128,7 @@ Buffer MetalAllocator::malloc(size_t size) {
auto pool = metal::new_scoped_memory_pool();
// If we have a lot of memory pressure or are over the maximum cache size,
// try to reclaim memory from the cache
// If we have a lot of memory pressure try to reclaim memory from the cache
if (mem_required >= gc_limit_ || num_resources_ >= resource_limit_) {
num_resources_ -=
buffer_cache_.release_cached_buffers(mem_required - gc_limit_);

12
mlx/backend/metal/device.h
View File

@@ -60,6 +60,16 @@ struct CommandEncoder {
enc_->updateFence(fence);
}
template <typename T>
void set_vector_bytes(const SmallVector<T>& vec, size_t nelems, int idx) {
enc_->setBytes(vec.data(), nelems * sizeof(T), idx);
}
template <typename T>
void set_vector_bytes(const SmallVector<T>& vec, int idx) {
return set_vector_bytes(vec, vec.size(), idx);
}
// TODO: Code is duplicated but they should be deleted soon.
template <typename T>
void set_vector_bytes(const std::vector<T>& vec, size_t nelems, int idx) {
enc_->setBytes(vec.data(), nelems * sizeof(T), idx);
@@ -94,7 +104,7 @@ struct CommandEncoder {
};
// Outputs of all kernels in the encoder including temporaries
std::unordered_set<const void*> outputs() {
std::unordered_set<const void*>& outputs() {
return all_outputs_;
};

4
mlx/backend/metal/event.cpp
View File

@@ -14,6 +14,10 @@ Event::Event(Stream stream) : stream_(stream) {
auto p = metal::new_scoped_memory_pool();
event_ = std::shared_ptr<void>(
metal::device(Device::gpu).mtl_device()->newSharedEvent(), dtor);
if (event_ == nullptr) {
throw std::runtime_error(
"[Event::Event] Failed to create Metal shared event.");
}
}
void Event::wait() {

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