AMD's library for high performance machine learning primitives. Sources and binaries can be found at MIOpen's GitHub site. The latest released documentation can be read online here.
MIOpen supports two programming models -
- HIP (Primary Support).
- OpenCL.
For a detailed description of the MIOpen library see the Documentation.
Run the steps below to build documentation locally.
cd docs
pip3 install -r .sphinx/requirements.txt
python3 -m sphinx -T -E -b html -d _build/doctrees -D language=en . _build/html
- More information about ROCm stack via ROCm Information Portal.
- A ROCm enabled platform, more info here.
- Base software stack, which includes:
- HIP -
- HIP and HCC libraries and header files.
- OpenCL - OpenCL libraries and header files.
- HIP -
- MIOpenGEMM - enable various functionalities including transposed and dilated convolutions.
- This is optional on the HIP backend, and required on the OpenCL backend.
- Users can enable this library using the cmake configuration flag
-DMIOPEN_USE_MIOPENGEMM=On
, which is enabled by default when OpenCL backend is chosen.
- ROCm cmake - provide cmake modules for common build tasks needed for the ROCM software stack.
- Half - IEEE 754-based half-precision floating point library
- Boost
- MIOpen uses
boost-system
andboost-filesystem
packages to enable persistent kernel cache - Version 1.79 is recommended, older version may need patches to work on newer systems, e.g. boost1{69,70,72} w/glibc-2.34
- MIOpen uses
- SQLite3 - reading and writing performance database
- lbzip2 - multi-threaded compress or decompress utility
- MIOpenTENSILE - users can enable this library using the cmake configuration flag
-DMIOPEN_USE_MIOPENTENSILE=On
. (deprecated after ROCm 5.1.1) - rocBLAS - AMD library for Basic Linear Algebra Subprograms (BLAS) on the ROCm platform.
- Minimum version branch for pre-ROCm 3.5 master-rocm-2.10
- Minimum version branch for post-ROCm 3.5 master-rocm-3.5
- MLIR - (Multi-Level Intermediate Representation) with its MIOpen dialect to support and complement kernel development.
- Composable Kernel - C++ templated device library for GEMM-like and reduction-like operators.
MIOpen can be installed on Ubuntu using apt-get
.
For OpenCL backend: apt-get install miopen-opencl
For HIP backend: apt-get install miopen-hip
Currently both the backends cannot be installed on the same system simultaneously. If a different backend other than what currently exists on the system is desired, please uninstall the existing backend completely and then install the new backend.
MIOpen provides an optional pre-compiled kernels package to reduce the startup latency. These precompiled kernels comprise a select set of popular input configurations and will expand in future release to contain additional coverage.
Note that all compiled kernels are locally cached in the folder $HOME/.cache/miopen/
, so precompiled kernels reduce the startup latency only for the first execution of a neural network. Precompiled kernels do not reduce startup time on subsequent runs.
To install the kernels package for your GPU architecture, use the following command:
apt-get install miopenkernels-<arch>-<num cu>
Where <arch>
is the GPU architecture ( for example, gfx900
, gfx906
, gfx1030
) and <num cu>
is the number of CUs available in the GPU (for example 56 or 64 etc).
Not installing these packages would not impact the functioning of MIOpen, since MIOpen will compile these kernels on the target machine once the kernel is run. However, the compilation step may significantly increase the startup time for different operations.
The script utils/install_precompiled_kernels.sh
provided as part of MIOpen automates the above process, it queries the user machine for the GPU architecture and then installs the appropriate package. It may be invoked as:
./utils/install_precompiled_kernels.sh
The above script depends on the rocminfo package to query the GPU architecture.
More info can be found here.
The dependencies can be installed with the install_deps.cmake
, script: cmake -P install_deps.cmake
This will install by default to /usr/local
but it can be installed in another location with --prefix
argument:
cmake -P install_deps.cmake --prefix <miopen-dependency-path>
An example cmake step can be:
cmake -P install_deps.cmake --minimum --prefix /root/MIOpen/install_dir
This prefix can used to specify the dependency path during the configuration phase using the CMAKE_PREFIX_PATH
.
-
MIOpen's HIP backend uses rocBLAS by default. Users can install rocBLAS minimum release by using
apt-get install rocblas
. To disable using rocBLAS set the configuration flag-DMIOPEN_USE_ROCBLAS=Off
. rocBLAS is not available for the OpenCL backend. -
MIOpen's OpenCL backend uses MIOpenGEMM by default. Users can install MIOpenGEMM minimum release by using
apt-get install miopengemm
.
First create a build directory:
mkdir build; cd build;
Next configure cmake. The preferred backend for MIOpen can be set using the -DMIOPEN_BACKEND
cmake variable.
Set the C++ compiler to clang++
.
export CXX=<location-of-clang++-compiler>
cmake -DMIOPEN_BACKEND=HIP -DCMAKE_PREFIX_PATH="<hip-installed-path>;<rocm-installed-path>;<miopen-dependency-path>" ..
An example cmake step can be:
export CXX=/opt/rocm/llvm/bin/clang++ && \
cmake -DMIOPEN_BACKEND=HIP -DCMAKE_PREFIX_PATH="/opt/rocm/;/opt/rocm/hip;/root/MIOpen/install_dir" ..
Note: When specifying the path for the CMAKE_PREFIX_PATH
variable, do not use the ~
shorthand for the user home directory.
cmake -DMIOPEN_BACKEND=OpenCL ..
The above assumes that OpenCL is installed in one of the standard locations. If not, then manually set these cmake variables:
cmake -DMIOPEN_BACKEND=OpenCL -DMIOPEN_HIP_COMPILER=<hip-compiler-path> -DOPENCL_LIBRARIES=<opencl-library-path> -DOPENCL_INCLUDE_DIRS=<opencl-headers-path> ..
And an example setting the dependency path for an envirnment in ROCm 3.5 and later:
cmake -DMIOPEN_BACKEND=OpenCL -DMIOPEN_HIP_COMPILER=/opt/rocm/llvm/bin/clang++ -DCMAKE_PREFIX_PATH="/opt/rocm/;/opt/rocm/hip;/root/MIOpen/install_dir" ..
By default the install location is set to '/opt/rocm', this can be set by using CMAKE_INSTALL_PREFIX
:
cmake -DMIOPEN_BACKEND=OpenCL -DCMAKE_INSTALL_PREFIX=<miopen-installed-path> ..
The default path to the System PerfDb is miopen/share/miopen/db/
within install location. The default path to the User PerfDb is ~/.config/miopen/
. For development purposes, setting BUILD_DEV
will change default path to both database files to the source directory:
cmake -DMIOPEN_BACKEND=OpenCL -DBUILD_DEV=On ..
Database paths can be explicitly customized by means of MIOPEN_SYSTEM_DB_PATH
(System PerfDb) and MIOPEN_USER_DB_PATH
(User PerfDb) cmake variables.
More information about the performance database can be found here.
MIOpen by default caches the device programs in the location ~/.cache/miopen/
. In the cache directory there exists a directory for each version of MIOpen. Users can change the location of the cache directory during configuration using the flag -DMIOPEN_CACHE_DIR=<cache-directory-path>
.
Users can also disable the cache during runtime using the environmental variable set as MIOPEN_DISABLE_CACHE=1
.
If the compiler changes, or the user modifies the kernels then the cache must be deleted for the MIOpen version in use; e.g., rm -rf ~/.cache/miopen/<miopen-version-number>
. More information about the cache can be found here.
MIOpen's kernel cache directory is versioned so that users' cached kernels will not collide when upgrading from earlier version.
The configuration can be changed after running cmake by using ccmake
:
ccmake ..
OR cmake-gui
: cmake-gui ..
The ccmake
program can be downloaded as the Linux package cmake-curses-gui
, but is not available on windows.
The library can be built, from the build
directory using the 'Release' configuration:
cmake --build . --config Release
OR make
And can be installed by using the 'install' target:
cmake --build . --config Release --target install
OR make install
This will install the library to the CMAKE_INSTALL_PREFIX
path that was set.
MIOpen provides an application-driver which can be used to execute any one particular layer in isolation and measure performance and verification of the library.
The driver can be built using the MIOpenDriver
target:
cmake --build . --config Release --target MIOpenDriver
OR make MIOpenDriver
Documentation on how to run the driver is here.
The tests can be run by using the 'check' target:
cmake --build . --config Release --target check
OR make check
A single test can be built and ran, by doing:
cmake --build . --config Release --target test_tensor
./bin/test_tensor
All the code is formatted using clang-format. To format a file, use:
clang-format-10 -style=file -i <path-to-source-file>
Also, githooks can be installed to format the code per-commit:
./.githooks/install
Git Large File Storage (LFS) replaces large files such as audio samples, videos, datasets, and graphics with text pointers inside Git, while storing the file contents on a remote server. In MIOpen, we use git LFS to store the large files, such as the kernel database files (*.kdb) which are normally > 0.5GB. Steps:
Git LFS can be installed and set up by:
sudo apt install git-lfs
git lfs install
In the Git repository that you want to use Git LFS, track the file type that you's like by (if the file type has been tracked, this step can be skipped):
git lfs track "*.file_type"
git add .gitattributes
Pull all or a single large file that you would like to update by:
git lfs pull --exclude=
or
git lfs pull --exclude= --include "filename"
Update the large files and push to the github by:
git add my_large_files
git commit -m "the message"
git push
If Ubuntu v16 is used then the Boost
packages can also be installed by:
sudo apt-get install libboost-dev
sudo apt-get install libboost-system-dev
sudo apt-get install libboost-filesystem-dev
Note: MIOpen by default will attempt to build with Boost statically linked libraries. If it is needed, the user can build with dynamically linked Boost libraries by using this flag during the configruation stage:
-DBoost_USE_STATIC_LIBS=Off
however, this is not recommended.
The half
header needs to be installed from here.
The easiest way is to use docker. You can build the top-level docker file:
docker build -t miopen-image .
Then to enter the development environment use docker run
, for example:
docker run -it -v $HOME:/data --privileged --rm --device=/dev/kfd --device /dev/dri:/dev/dri:rw --volume /dev/dri:/dev/dri:rw -v /var/lib/docker/:/var/lib/docker --group-add video --cap-add=SYS_PTRACE --security-opt seccomp=unconfined miopen-image
Prebuilt docker images can be found on ROCm's public docker hub here.
MIOpen's paper is freely available and can be accessed on arXiv:
MIOpen: An Open Source Library For Deep Learning Primitives
@misc{jeh2019miopen,
title={MIOpen: An Open Source Library For Deep Learning Primitives},
author={Jehandad Khan and Paul Fultz and Artem Tamazov and Daniel Lowell and Chao Liu and Michael Melesse and Murali Nandhimandalam and Kamil Nasyrov and Ilya Perminov and Tejash Shah and Vasilii Filippov and Jing Zhang and Jing Zhou and Bragadeesh Natarajan and Mayank Daga},
year={2019},
eprint={1910.00078},
archivePrefix={arXiv},
primaryClass={cs.LG}
}
The porting guide highlights the key differences between the current cuDNN and MIOpen APIs.