/// /// Copyright (c) 2017-2023 Arm Limited. /// /// SPDX-License-Identifier: MIT /// /// Permission is hereby granted, free of charge, to any person obtaining a copy /// of this software and associated documentation files (the "Software"), to /// deal in the Software without restriction, including without limitation the /// rights to use, copy, modify, merge, publish, distribute, sublicense, and/or /// sell copies of the Software, and to permit persons to whom the Software is /// furnished to do so, subject to the following conditions: /// /// The above copyright notice and this permission notice shall be included in all /// copies or substantial portions of the Software. /// /// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR /// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, /// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE /// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER /// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, /// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE /// SOFTWARE. /// namespace arm_compute { /** @page how_to_build How to Build and Run Examples @tableofcontents @section S1_1_build_options Build options scons 2.3 or above is required to build the library. To see the build options available simply run ```scons -h``` @section S1_2_linux Building for Linux @subsection S1_2_1_library How to build the library ? For Linux, the library was successfully built and tested using the following Linaro GCC toolchain: - gcc-linaro-6.3.1-2017.05-x86_64_arm-linux-gnueabihf - gcc-linaro-6.3.1-2017.05-x86_64_aarch64-linux-gnu To cross-compile the library in debug mode, with Arm® Neon™ only support, for Linux 32bit: scons Werror=1 -j8 debug=1 neon=1 opencl=0 os=linux arch=armv7a To cross-compile the library in asserts mode, with OpenCL only support, for Linux 64bit: scons Werror=1 -j8 debug=0 asserts=1 neon=0 opencl=1 embed_kernels=1 os=linux arch=armv8a You can also compile the library natively on an Arm device by using build=native: scons Werror=1 -j8 debug=0 neon=1 opencl=0 os=linux arch=armv8a build=native scons Werror=1 -j8 debug=0 neon=1 opencl=0 os=linux arch=armv7a build=native @note g++ for Arm is mono-arch, therefore if you want to compile for Linux 32bit on a Linux 64bit platform you will have to use a cross compiler. For example on a 64bit Debian based system you would have to install g++-arm-linux-gnueabihf apt-get install g++-arm-linux-gnueabihf Then run scons Werror=1 -j8 debug=0 neon=1 opencl=0 os=linux arch=armv7a build=cross_compile or simply remove the build parameter as build=cross_compile is the default value: scons Werror=1 -j8 debug=0 neon=1 opencl=0 os=linux arch=armv7a @subsection S1_2_2_examples How to manually build the examples ? The examples get automatically built by scons as part of the build process of the library described above. This section just describes how you can build and link your own application against our library. @note The following command lines assume the arm_compute libraries are present in the current directory or in the system library path. If this is not the case you can specify the location of the pre-built libraries with the compiler option -L. When building the OpenCL example the commands below assume that the CL headers are located in the include folder where the command is executed. To cross compile a Arm® Neon™ example for Linux 32bit: arm-linux-gnueabihf-g++ examples/neon_cnn.cpp utils/Utils.cpp -I. -Iinclude -std=c++14 -mfpu=neon -L. -larm_compute -larm_compute_core -o neon_cnn To cross compile a Arm® Neon™ example for Linux 64bit: aarch64-linux-gnu-g++ examples/neon_cnn.cpp utils/Utils.cpp -I. -Iinclude -std=c++14 -L. -larm_compute -larm_compute_core -o neon_cnn (notice the only difference with the 32 bit command is that we don't need the -mfpu option and the compiler's name is different) To cross compile an OpenCL example for Linux 32bit: arm-linux-gnueabihf-g++ examples/cl_sgemm.cpp utils/Utils.cpp -I. -Iinclude -std=c++14 -mfpu=neon -L. -larm_compute -larm_compute_core -o cl_sgemm -DARM_COMPUTE_CL To cross compile an OpenCL example for Linux 64bit: aarch64-linux-gnu-g++ examples/cl_sgemm.cpp utils/Utils.cpp -I. -Iinclude -std=c++14 -L. -larm_compute -larm_compute_core -o cl_sgemm -DARM_COMPUTE_CL (notice the only difference with the 32 bit command is that we don't need the -mfpu option and the compiler's name is different) To cross compile the examples with the Graph API, such as graph_lenet.cpp, you need to link the examples against arm_compute_graph.so too. i.e. to cross compile the "graph_lenet" example for Linux 32bit: arm-linux-gnueabihf-g++ examples/graph_lenet.cpp utils/Utils.cpp utils/GraphUtils.cpp utils/CommonGraphOptions.cpp -I. -Iinclude -std=c++14 -mfpu=neon -L. -larm_compute_graph -larm_compute -larm_compute_core -Wl,--allow-shlib-undefined -o graph_lenet i.e. to cross compile the "graph_lenet" example for Linux 64bit: aarch64-linux-gnu-g++ examples/graph_lenet.cpp utils/Utils.cpp utils/GraphUtils.cpp utils/CommonGraphOptions.cpp -I. -Iinclude -std=c++14 -L. -larm_compute_graph -larm_compute -larm_compute_core -Wl,--allow-shlib-undefined -o graph_lenet (notice the only difference with the 32 bit command is that we don't need the -mfpu option and the compiler's name is different) @note If compiling using static libraries, this order must be followed when linking: arm_compute_graph_static, arm_compute, arm_compute_core To compile natively (i.e directly on an Arm device) for Arm® Neon™ for Linux 32bit: g++ examples/neon_cnn.cpp utils/Utils.cpp -I. -Iinclude -std=c++14 -mfpu=neon -larm_compute -larm_compute_core -o neon_cnn To compile natively (i.e directly on an Arm device) for Arm® Neon™ for Linux 64bit: g++ examples/neon_cnn.cpp utils/Utils.cpp -I. -Iinclude -std=c++14 -larm_compute -larm_compute_core -o neon_cnn (notice the only difference with the 32 bit command is that we don't need the -mfpu option) To compile natively (i.e directly on an Arm device) for OpenCL for Linux 32bit or Linux 64bit: g++ examples/cl_sgemm.cpp utils/Utils.cpp -I. -Iinclude -std=c++14 -larm_compute -larm_compute_core -o cl_sgemm -DARM_COMPUTE_CL To compile natively the examples with the Graph API, such as graph_lenet.cpp, you need to link the examples against arm_compute_graph.so too. i.e. to natively compile the "graph_lenet" example for Linux 32bit: g++ examples/graph_lenet.cpp utils/Utils.cpp utils/GraphUtils.cpp utils/CommonGraphOptions.cpp -I. -Iinclude -std=c++14 -mfpu=neon -L. -larm_compute_graph -larm_compute -larm_compute_core -Wl,--allow-shlib-undefined -o graph_lenet i.e. to natively compile the "graph_lenet" example for Linux 64bit: g++ examples/graph_lenet.cpp utils/Utils.cpp utils/GraphUtils.cpp utils/CommonGraphOptions.cpp -I. -Iinclude -std=c++14 -L. -larm_compute_graph -larm_compute -larm_compute_core -Wl,--allow-shlib-undefined -o graph_lenet (notice the only difference with the 32 bit command is that we don't need the -mfpu option) @note If compiling using static libraries, this order must be followed when linking: arm_compute_graph_static, arm_compute, arm_compute_core @note These two commands assume libarm_compute.so is available in your library path, if not add the path to it using -L (e.g. -Llib/linux-armv8a-neon-cl-asserts/) @note You might need to export the path to OpenCL library as well in your LD_LIBRARY_PATH if Compute Library was built with OpenCL enabled. To run the built executable simply run: LD_LIBRARY_PATH=build ./neon_cnn or LD_LIBRARY_PATH=build ./cl_sgemm @note Examples accept different types of arguments, to find out what they are run the example with \a --help as an argument. If no arguments are specified then random values will be used to execute the graph. For example: LD_LIBRARY_PATH=. ./graph_lenet --help Below is a list of the common parameters among the graph examples : @snippet utils/CommonGraphOptions.h Common graph examples parameters @subsection S1_2_3_sve Build for SVE or SVE2 In order to build for SVE or SVE2 you need a compiler that supports them. You can find more information in the following these links: -# GCC: https://developer.arm.com/tools-and-software/open-source-software/developer-tools/gnu-toolchain/sve-support -# LLVM: https://developer.arm.com/tools-and-software/open-source-software/developer-tools/llvm-toolchain/sve-support @note You the need to indicate the toolchains using the scons "toolchain_prefix" parameter. An example build command with SVE is: scons arch=armv8.2-a-sve os=linux build_dir=arm64 -j55 standalone=0 opencl=0 openmp=0 validation_tests=1 neon=1 cppthreads=1 toolchain_prefix=aarch64-none-linux-gnu- @subsection S1_2_4_sme Build for SME2 In order to build for SME2 you need to use a compiler that supports SVE2 and enable SVE2 in the build as well. @note You the need to indicate the toolchains using the scons "toolchain_prefix" parameter. An example build command with SME2 is: scons arch=armv8.6-a-sve2-sme2 os=linux build_dir=arm64 -j55 standalone=0 opencl=0 openmp=0 validation_tests=1 neon=1 cppthreads=1 toolchain_prefix=aarch64-none-linux-gnu- @section S1_3_android Building for Android For Android, the library was successfully built and tested using Google's standalone toolchains: - clang++ from NDK r20b for armv8a - clang++ from NDK r20b for armv8.2-a with FP16 support (From 23.02, NDK >= r20b is highly recommended) For NDK r18 or older, here is a guide to create your Android standalone toolchains from the NDK: - Download the NDK r18b from here: https://developer.android.com/ndk/downloads/index.html to directory $NDK - Make sure you have Python 2.7 installed on your machine. - Generate the 32 and/or 64 toolchains by running the following commands to your toolchain directory $MY_TOOLCHAINS: $NDK/build/tools/make_standalone_toolchain.py --arch arm64 --install-dir $MY_TOOLCHAINS/aarch64-linux-android-ndk-r18b --stl libc++ --api 21 $NDK/build/tools/make_standalone_toolchain.py --arch arm --install-dir $MY_TOOLCHAINS/arm-linux-android-ndk-r18b --stl libc++ --api 21 For NDK r19 or newer, you can directly Download the NDK package for your development platform, without the need to launch the make_standalone_toolchain.py script. You can find all the prebuilt binaries inside $NDK/toolchains/llvm/prebuilt/$OS_ARCH/bin/. @parblock @attention The building script will look for a binary named "aarch64-linux-android-clang++", while the prebuilt binaries will have their API version as a suffix to their filename (e.g. "aarch64-linux-android21-clang++"). You can instruct scons to use the correct version by using a combination of the toolchain_prefix and the "CC" "CXX" environment variables. @attention For this particular example, you can specify: CC=clang CXX=clang++ scons toolchain_prefix=aarch64-linux-android21- @attention or: CC=aarch64-linux-android21-clang CXX=aarch64-linux-android21-clang++ scons toolchain_prefix="" @endparblock @parblock @attention We used to use gnustl but as of NDK r17 it is deprecated so we switched to libc++ @endparblock @note Make sure to add the toolchains to your PATH: export PATH=$PATH:$MY_TOOLCHAINS/aarch64-linux-android-ndk-r18b/bin:$MY_TOOLCHAINS/arm-linux-android-ndk-r18b/bin @subsection S1_3_1_library How to build the library ? To cross-compile the library in debug mode, with Arm® Neon™ only support, for Android 32bit: CXX=clang++ CC=clang scons Werror=1 -j8 debug=1 neon=1 opencl=0 os=android arch=armv7a To cross-compile the library in asserts mode, with OpenCL only support, for Android 64bit: CXX=clang++ CC=clang scons Werror=1 -j8 debug=0 asserts=1 neon=0 opencl=1 embed_kernels=1 os=android arch=armv8a @subsection S1_3_2_examples How to manually build the examples ? The examples get automatically built by scons as part of the build process of the library described above. This section just describes how you can build and link your own application against our library. @note The following command lines assume the arm_compute libraries are present in the current directory or in the system library path. If this is not the case you can specify the location of the pre-built libraries with the compiler option -L. When building the OpenCL example the commands below assume that the CL headers are located in the include folder where the command is executed. Once you've got your Android standalone toolchain built and added to your path you can do the following: To cross compile a Arm® Neon™ example: #32 bit: arm-linux-androideabi-clang++ examples/neon_cnn.cpp utils/Utils.cpp -I. -Iinclude -std=c++14 -larm_compute-static -larm_compute_core-static -L. -o neon_cnn_arm -static-libstdc++ -pie #64 bit: aarch64-linux-android-clang++ examples/neon_cnn.cpp utils/Utils.cpp -I. -Iinclude -std=c++14 -larm_compute-static -larm_compute_core-static -L. -o neon_cnn_aarch64 -static-libstdc++ -pie To cross compile an OpenCL example: #32 bit: arm-linux-androideabi-clang++ examples/cl_sgemm.cpp utils/Utils.cpp -I. -Iinclude -std=c++14 -larm_compute-static -larm_compute_core-static -L. -o cl_sgemm_arm -static-libstdc++ -pie -DARM_COMPUTE_CL #64 bit: aarch64-linux-android-clang++ examples/cl_sgemm.cpp utils/Utils.cpp -I. -Iinclude -std=c++14 -larm_compute-static -larm_compute_core-static -L. -o cl_sgemm_aarch64 -static-libstdc++ -pie -DARM_COMPUTE_CL To cross compile the examples with the Graph API, such as graph_lenet.cpp, you need to link the library arm_compute_graph also. #32 bit: arm-linux-androideabi-clang++ examples/graph_lenet.cpp utils/Utils.cpp utils/GraphUtils.cpp utils/CommonGraphOptions.cpp -I. -Iinclude -std=c++14 -Wl,--whole-archive -larm_compute_graph-static -Wl,--no-whole-archive -larm_compute-static -larm_compute_core-static -L. -o graph_lenet_arm -static-libstdc++ -pie -DARM_COMPUTE_CL #64 bit: aarch64-linux-android-clang++ examples/graph_lenet.cpp utils/Utils.cpp utils/GraphUtils.cpp utils/CommonGraphOptions.cpp -I. -Iinclude -std=c++14 -Wl,--whole-archive -larm_compute_graph-static -Wl,--no-whole-archive -larm_compute-static -larm_compute_core-static -L. -o graph_lenet_aarch64 -static-libstdc++ -pie -DARM_COMPUTE_CL @note Due to some issues in older versions of the Arm® Mali™ OpenCL DDK (<= r13p0), we recommend to link arm_compute statically on Android. @note When linked statically the arm_compute_graph library currently needs the --whole-archive linker flag in order to work properly Then you need to do is upload the executable and the shared library to the device using ADB: adb push neon_cnn_arm /data/local/tmp/ adb push cl_sgemm_arm /data/local/tmp/ adb push gc_absdiff_arm /data/local/tmp/ adb shell chmod 777 -R /data/local/tmp/ And finally to run the example: adb shell /data/local/tmp/neon_cnn_arm adb shell /data/local/tmp/cl_sgemm_arm adb shell /data/local/tmp/gc_absdiff_arm For 64bit: adb push neon_cnn_aarch64 /data/local/tmp/ adb push cl_sgemm_aarch64 /data/local/tmp/ adb push gc_absdiff_aarch64 /data/local/tmp/ adb shell chmod 777 -R /data/local/tmp/ And finally to run the example: adb shell /data/local/tmp/neon_cnn_aarch64 adb shell /data/local/tmp/cl_sgemm_aarch64 adb shell /data/local/tmp/gc_absdiff_aarch64 @note Examples accept different types of arguments, to find out what they are run the example with \a --help as an argument. If no arguments are specified then random values will be used to execute the graph. For example: adb shell /data/local/tmp/graph_lenet --help In this case the first argument of LeNet (like all the graph examples) is the target (i.e 0 to run on Neon™, 1 to run on OpenCL if available, 2 to run on OpenCL using the CLTuner), the second argument is the path to the folder containing the npy files for the weights and finally the third argument is the number of batches to run. @section S1_4_macos Building for macOS The library was successfully natively built for Apple Silicon under macOS 11.1 using clang v12.0.0. To natively compile the library with accelerated CPU support: scons Werror=1 -j8 neon=1 opencl=0 os=macos arch=armv8a build=native @note Initial support disables feature discovery through HWCAPS and thread scheduling affinity controls @section S1_5_bare_metal Building for bare metal For bare metal, the library was successfully built using linaro's latest (gcc-linaro-6.3.1-2017.05) bare metal toolchains: - arm-eabi for armv7a - aarch64-elf for armv8a Download linaro for armv7a and armv8a. @note Make sure to add the toolchains to your PATH: export PATH=$PATH:$MY_TOOLCHAINS/gcc-linaro-6.3.1-2017.05-x86_64_aarch64-elf/bin:$MY_TOOLCHAINS/gcc-linaro-6.3.1-2017.05-x86_64_arm-eabi/bin @subsection S1_5_1_library How to build the library ? To cross-compile the library with Arm® Neon™ support for baremetal armv8a: scons Werror=1 -j8 debug=0 neon=1 opencl=0 os=bare_metal arch=armv8a build=cross_compile cppthreads=0 openmp=0 standalone=1 @subsection S1_5_2_examples How to manually build the examples ? Examples are disabled when building for bare metal. If you want to build the examples you need to provide a custom bootcode depending on the target architecture and link against the compute library. More information about bare metal bootcode can be found here. @section S1_6_windows_host Building on a Windows host system (cross-compile) Using `scons` directly from the Windows command line is known to cause problems. The reason seems to be that if `scons` is setup for cross-compilation it gets confused about Windows style paths (using backslashes). Thus it is recommended to follow one of the options outlined below. @subsection S1_6_1_ubuntu_on_windows Bash on Ubuntu on Windows (cross-compile) The best and easiest option is to use Ubuntu on Windows. This feature is still marked as *beta* and thus might not be available. However, if it is building the library is as simple as opening a *Bash on Ubuntu on Windows* shell and following the general guidelines given above. @subsection S1_6_2_cygwin Cygwin (cross-compile) If the Windows subsystem for Linux is not available Cygwin can be used to install and run `scons`, the minimum Cygwin version must be 3.0.7 or later. In addition to the default packages installed by Cygwin `scons` has to be selected in the installer. (`git` might also be useful but is not strictly required if you already have got the source code of the library.) Linaro provides pre-built versions of GCC cross-compilers that can be used from the Cygwin terminal. When building for Android the compiler is included in the Android standalone toolchain. After everything has been set up in the Cygwin terminal the general guide on building the library can be followed. @subsection S1_6_3_WoA Windows on ARM (native build) Native builds on Windows are experimental and some features from the library interacting with the OS are missing. It's possible to build Compute Library natively on a windows system running on ARM. Windows on ARM(WoA) systems provide compatibility emulating x86 binaries on aarch64. Unfortunately Visual Studio 2022 does not work on aarch64 systems because it's an x86_64bit application and these binaries cannot be exectuted on WoA yet. Because we cannot use Visual Studio to build Compute Library we have to set up a native standalone toolchain to compile C++ code for arm64 on Windows. Native arm64 toolchain installation for WoA: - LLVM+Clang-12 which can be downloaded from: https://github.com/llvm/llvm-project/releases/download/llvmorg-12.0.0/LLVM-12.0.0-woa64.exe - Arm64 VC Runtime which can be downloaded from https://aka.ms/vs/17/release/vc_redist.arm64.exe - While full VS22 cannot be installed on WoA, we can install some components -# Desktop development with C++ and all Arm64 components for Visual Studio, refer to: https://developer.arm.com/documentation/102528/0100/Install-Visual-Studio -# VS22 build tools: https://visualstudio.microsoft.com/downloads/#build-tools-for-visual-studio-2022 There are some additional tools we need to install to build Compute Library: - git https://git-scm.com/download/win - python 3 https://www.python.org/downloads/windows/ - scons can be installed with pip install scons In order to use clang to build windows binaries natively we have to initialize the environment variables from VS22 correctly so that the compiler could find the arm64 C++ libraries. This can be done by pressing the key windows + r and running the command: cmd /k "C:\Program Files (x86)\Microsoft Visual Studio\2022\BuildTools\VC\Auxiliary\Build\vcvarsx86_arm64.bat" To build Compute Library type: scons opencl=0 neon=1 os=windows examples=0 validation_tests=1 benchmark_examples=0 build=native arch=armv8a Werror=0 exceptions=1 standalone=1 @section S1_7_cl_requirements OpenCL DDK Requirements @subsection S1_7_1_cl_hard_requirements Hard Requirements Compute Library requires OpenCL 1.1 and above with support of non uniform workgroup sizes, which is officially supported in the Arm® Mali™ OpenCL DDK r8p0 and above as an extension (respective extension flag is \a -cl-arm-non-uniform-work-group-size). Enabling 16-bit floating point calculations require \a cl_khr_fp16 extension to be supported. All Arm® Mali™ GPUs with compute capabilities have native support for half precision floating points. @subsection S1_7_2_cl_performance_requirements Performance improvements Integer dot product built-in function extensions (and therefore optimized kernels) are available with Arm® Mali™ OpenCL DDK r22p0 and above for the following GPUs : G71, G76. The relevant extensions are \a cl_arm_integer_dot_product_int8, \a cl_arm_integer_dot_product_accumulate_int8 and \a cl_arm_integer_dot_product_accumulate_int16. OpenCL kernel level debugging can be simplified with the use of printf, this requires the \a cl_arm_printf extension to be supported. SVM allocations are supported for all the underlying allocations in Compute Library. To enable this OpenCL 2.0 and above is a requirement. @section S1_8_experimental_builds Experimental Bazel and CMake builds In addition to the scons build the repository includes experimental Bazel and CMake builds. Both are similar to the scons multi_isa build. It compiles all libraries with Neon (TM) support, as well as SVE and SVE2 libraries. The build is CPU only, not including OpenCL support. Both were successfully built with gcc / g++ version 10.2. @subsection S1_8_1_bazel_build Bazel build @subsubsection S1_8_1_1_file_structure File structure File structure for all files included in the Bazel build: . ├── .bazelrc ├── BUILD ├── WORKSPACE ├── arm_compute │  └── BUILD ├── examples │  └── BUILD ├── include │  └── BUILD ├── scripts │ ├── print_version_file.py │  └── BUILD ├── src │  └── BUILD ├── support │  └── BUILD ├── tests │ ├── BUILD │  └── framework │  └── BUILD └── utils └── BUILD @subsubsection S1_8_1_2_build_options Build options Available build options: - debug: Enable ['-O0','-g','-gdwarf-2'] compilation flags - Werror: Enable -Werror compilation flag - logging: Enable logging - cppthreads: Enable C++11 threads backend - openmp: Enable OpenMP backend @subsubsection S1_8_1_3_example_builds Example builds Build everything (libraries, examples, tests): bazel build //... Build libraries: bazel build //:all Build arm_compute only: bazel build //:arm_compute Build examples: bazel build //examples:all Build resnet50 example: bazel build //examples:graph_resnet50 Build validation and benchmarking: bazel build //tests:all @subsection S1_8_2_cmake_build CMake build @subsubsection S1_8_2_1_file_structure File structure File structure for all files included in the CMake build: . ├── CMakeLists.txt ├── cmake │ ├── Options.cmake │ ├── Version.cmake │  └── toolchains │  └── aarch64_linux_toolchain.cmake ├── examples │  └── CMakeLists.txt ├── src │ └── CMakeLists.txt └── tests ├── CMakeLists.txt ├── benchmark │ └── CMakeLists.txt └── validation └── CMakeLists.txt @subsubsection S1_8_2_2_build_options Build options Available build options: - DEBUG: Enable ['-O0','-g','-gdwarf-2'] compilation flags - WERROR: Enable -Werror compilation flag - EXCEPTIONS: If disabled ARM_COMPUTE_EXCEPTIONS_DISABLED is enabled - LOGGING: Enable logging - BUILD_EXAMPLES: Build examples - BUILD_TESTING: Build tests - CPPTHREADS: Enable C++11 threads backend - OPENMP: Enable OpenMP backend @subsubsection S1_8_2_3_example_builds Example builds To build libraries, examples and tests: mkdir build cd build cmake .. -DOPENMP=1 -DWERROR=0 -DDEBUG=0 -DBUILD_EXAMPLES=1 -DBUILD_TESTING=1 -DCMAKE_INSTALL_LIBDIR=. cmake --build . -j32 */ } // namespace arm_compute