a1fcc5f19f
Previously, this function only worked correctly for 64bit data types. Signed-off-by: Péter Zarándy <pza@wehowsky.com> |
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.. | ||
auto_vectorization | ||
blas | ||
cmake | ||
include | ||
minifier | ||
msi | ||
packages | ||
profile | ||
server | ||
tests_cpu | ||
.gitignore | ||
AddingNewOps.md | ||
CMakeLists.txt | ||
CMakeLists.txt.cpu_features.in | ||
CMakeLists.txt.in | ||
CMakeLists.txt.mkldnn.in | ||
CMakeSettings.json | ||
README.md | ||
RaspberryPi.md | ||
UnderstandingGraph.md | ||
assembly-cuda.xml | ||
assembly.xml | ||
buildnativeoperations.sh | ||
cibuild.sh | ||
flatproto.txt | ||
iOS.md | ||
linuxOnPower.md | ||
macOSx10 (CPU only).md | ||
pi_build.sh | ||
pom.xml | ||
proto.sh | ||
setuposx.sh | ||
windows.md |
README.md
LibND4J
Native operations for nd4j. Build using cmake
Prerequisites
- GCC 4.9+
- CUDA Toolkit Versions 10 or 11
- CMake 3.8 (as of Nov 2017, in near future will require 3.9)
Additional build arguments
There's few additional arguments for buildnativeoperations.sh
script you could use:
-a XXXXXXXX// shortcut for -march/-mtune, i.e. -a native
-b release OR -b debug // enables/desables debug builds. release is considered by default
-j XX // this argument defines how many threads will be used to binaries on your box. i.e. -j 8
-cc XX// CUDA-only argument, builds only binaries for target GPU architecture. use this for fast builds
--check-vectorization auto-vectorization report for developers. (Currently, only GCC is supported)
More about AutoVectorization report
You can provide the compute capability for your card on the NVIDIA website here or use auto.
Please also check your Cuda Toolkit Release notes for supported and dropped features.
Here is the latest CUDA Toolkit Release note.
You can find the same information for the older Toolkit versions in the CUDA archives.
-cc and --compute option examples | description |
---|---|
-cc all | builds for common GPUs |
-cc auto | tries to detect automatically |
-cc Maxwell | GPU microarchitecture codename |
-cc 75 | compute capability 7.5 without a dot |
-cc 7.5 | compute capability 7.5 with a dot |
-cc "Maxwell 6.0 7.5" | space-separated multiple arguments within quotes (note: numbers only with a dot) |
OS Specific Requirements
Android
Download the NDK, extract it somewhere, and execute the following commands, replacing android-xxx
with either android-arm
or android-x86
:
git clone https://github.com/deeplearning4j/libnd4j
git clone https://github.com/deeplearning4j/nd4j
export ANDROID_NDK=/path/to/android-ndk/
cd libnd4j
bash buildnativeoperations.sh -platform android-xxx
cd ../nd4j
mvn clean install -Djavacpp.platform=android-xxx -DskipTests -pl '!:nd4j-cuda-9.0,!:nd4j-cuda-9.0-platform,!:nd4j-tests'
OSX
Run ./setuposx.sh (Please ensure you have brew installed)
Linux
Depends on the distro - ask in the earlyadopters channel for specifics on distro
Ubuntu Linux 15.10
wget http://developer.download.nvidia.com/compute/cuda/7.5/Prod/local_installers/cuda-repo-ubuntu1504-7-5-local_7.5-18_amd64.deb
sudo dpkg -i cuda-repo-ubuntu1504-7-5-local_7.5-18_amd64.deb
sudo apt-get update
sudo apt-get install cuda
sudo apt-get install cmake
sudo apt-get install gcc-4.9
sudo apt-get install g++-4.9
sudo apt-get install git
git clone https://github.com/deeplearning4j/libnd4j
cd libnd4j/
export LIBND4J_HOME=~/libnd4j/
sudo rm /usr/bin/gcc
sudo rm /usr/bin/g++
sudo ln -s /usr/bin/gcc-4.9 /usr/bin/gcc
sudo ln -s /usr/bin/g++-4.9 /usr/bin/g++
./buildnativeoperations.sh
./buildnativeoperations.sh -c cuda -сс YOUR_DEVICE_ARCH
Ubuntu Linux 16.04
sudo apt install cmake
sudo apt install nvidia-cuda-dev nvidia-cuda-toolkit nvidia-361
export TRICK_NVCC=YES
./buildnativeoperations.sh
./buildnativeoperations.sh -c cuda -сс YOUR_DEVICE_ARCH
The standard development headers are needed.
CentOS 6
yum install centos-release-scl-rh epel-release
yum install devtoolset-3-toolchain maven30 cmake3 git
scl enable devtoolset-3 maven30 bash
./buildnativeoperations.sh
./buildnativeoperations.sh -c cuda -сс YOUR_DEVICE_ARCH
Windows
See Windows.md
Setup for All OS
-
Set a LIBND4J_HOME as an environment variable to the libnd4j folder you've obtained from GIT
- Note: this is required for building nd4j as well.
-
Setup cpu followed by gpu, run the following on the command line:
-
For standard builds:
./buildnativeoperations.sh ./buildnativeoperations.sh -c cuda -сс YOUR_DEVICE_ARCH
-
For Debug builds:
./buildnativeoperations.sh blas -b debug ./buildnativeoperations.sh blas -c cuda -сс YOUR_DEVICE_ARCH -b debug
-
For release builds (default):
./buildnativeoperations.sh ./buildnativeoperations.sh -c cuda -сс YOUR_DEVICE_ARCH
-
OpenMP support
OpenMP 4.0+ should be used to compile libnd4j. However, this shouldn't be any trouble, since OpenMP 4 was released in 2015 and should be available on all major platforms.
Linking with MKL
We can link with MKL either at build time, or at runtime with binaries initially linked with another BLAS implementation such as OpenBLAS. In either case, simply add the path containing libmkl_rt.so
(or mkl_rt.dll
on Windows), say /path/to/intel64/lib/
, to the LD_LIBRARY_PATH
environment variable on Linux (or PATH
on Windows), and build or run your Java application as usual. If you get an error message like undefined symbol: omp_get_num_procs
, it probably means that libiomp5.so
, libiomp5.dylib
, or libiomp5md.dll
is not present on your system. In that case though, it is still possible to use the GNU version of OpenMP by setting these environment variables on Linux, for example:
export MKL_THREADING_LAYER=GNU
export LD_PRELOAD=/usr/lib64/libgomp.so.1
##Troubleshooting MKL
Sometimes the above steps might not be all you need to do. Another additional step might be the need to add:
export LD_LIBRARY_PATH=/opt/intel/lib/intel64/:/opt/intel/mkl/lib/intel64
This ensures that mkl will be found first and liked to.
Packaging
If on Ubuntu (14.04 or above) or CentOS (6 or above), this repository is also set to create packages for your distribution. Let's assume you have built:
- for the cpu, your command-line was
./buildnativeoperations.sh ...
:
cd blasbuild/cpu
make package
- for the gpu, your command-line was
./buildnativeoperations.sh -c cuda ...
:
cd blasbuild/cuda
make package
Uploading package to Bintray
The package upload script is in packaging. The upload command for an rpm built for cpu is:
./packages/push_to_bintray.sh myAPIUser myAPIKey deeplearning4j blasbuild/cpu/libnd4j-0.8.0.fc7.3.1611.x86_64.rpm https://github.com/deeplearning4j
The upload command for a deb package built for cuda is:
./packages/push_to_bintray.sh myAPIUser myAPIKey deeplearning4j blasbuild/cuda/libnd4j-0.8.0.fc7.3.1611.x86_64.deb https://github.com/deeplearning4j
Running tests
Tests are written with gtest, run using cmake. Tests are currently under tests_cpu/
There are 2 directories for running tests:
1. libnd4j_tests: These are older legacy ops tests.
2. layers_tests: This covers the newer graph operations and ops associated with samediff.
For running the tests, we currently use cmake or CLion to run the tests.
To run tests using CUDA backend it's pretty much similar process:
1. ./buildnativeoperations.h -c cuda -cc <YOUR_ARCH> -b debug -t -j <NUMBER_OF_CORES>
2. ./blasbuild/cuda/tests_cpu/layers_tests/runtests (.exe on Windows)
Development
In order to extend and update libnd4j, understanding libnd4j's various cmake flags is the key. Many of them are in buildnativeoperations.sh. The pom.xml is used to integrate and auto configure the project for building with deeplearning4j.
At a minimum, you will want to enable tests. An example default set of flags for running tests and getting cpu builds working is as follows:
-DSD_CPU=true -DBLAS=TRUE -DSD_ARCH=x86-64 -DSD_EXTENSION= -DSD_LIBRARY_NAME=nd4jcpu -DSD_CHECK_VECTORIZATION=OFF -DSD_SHARED_LIB=ON -DSD_STATIC_LIB=OFF -DSD_BUILD_MINIFIER=false -DSD_ALL_OPS=true -DCMAKE_BUILD_TYPE=Release -DPACKAGING=none -DSD_BUILD_TESTS=OFF -DCOMPUTE=all -DOPENBLAS_PATH=C:/Users/agibs/.javacpp/cache/openblas-0.3.10-1.5.4-windows-x86_64.jar/org/bytedeco/openblas/windows-x86_64 -DDEV=FALSE -DCMAKE_NEED_RESPONSE=YES -DMKL_MULTI_THREADED=TRUE -DSD_BUILD_TESTS=YES
The way the main build script works, it dynamically generates a set of flags suitable for use for building the projects. Understanding the build script will go a long way in to configuring cmake for your particular IDE.