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how-to-cross-build-runtime-for-arm.md

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How to Cross-build Runtime for ARM

Prepare ARM Ubuntu RootFS

Install required packages

$ sudo apt-get install qemu-user-static binfmt-support debootstrap

Use install_rootfs.sh script to prepare Root File System. You should have sudo

$ sudo ./tools/cross/install_rootfs.sh arm
  • supports arm(default) and aarch64 architecutre for now
  • supports focal,jammy, and noble release

To see the options,

$ ./tools/cross/install_rootfs.sh -h

RootFS will be prepared at tools/cross/rootfs/arm or tools/cross/rootfs/aarch64 folder.

* CAUTION: The OS version of rootfs must match the OS version of execution target device. On the other hand, you need to match the Ubuntu version of the development PC with the Ubuntu version of rootfs to be used for cross-build. Otherwise, unexpected build errors may occur.

If you are using Ubuntu 20.04 LTS, select focal, if you are using Ubuntu 22.04 LTS, select jammy. You can check your Ubuntu code name in the following way.

$ cat /etc/lsb-release
DISTRIB_ID=Ubuntu
DISTRIB_RELEASE=22.04
DISTRIB_CODENAME=jammy
DISTRIB_DESCRIPTION="Ubuntu 22.04.3 LTS"

install_rootfs.sh will select development system code name as default.

If a build error occurs because the version of the development system and the target system do not match, and if you can't replace your development system for any reason, you can consider cross-build using the docker image.

Prepare RootFS at alternative folder

Use ROOTFS_DIR to a full path to prepare at alternative path.

$ ROOTFS_DIR=/home/user/rootfs/arm-bionic sudo -E ./tools/cross/install_rootfs.sh arm

Using proxy

If you need to use proxy server while building the rootfs, use --setproxy option.

# for example,
$ sudo ./tools/cross/install_rootfs.sh arm --setproxy="1.2.3.4:8080"
# or
$ sudo ./tools/cross/install_rootfs.sh arm --setproxy="proxy.server.com:8888"

This will put apt proxy settings in rootfs/etc/apt/apt.conf.d/90proxy file for http, https and ftp protocol.

Install ARM Cross Toolchain

We recommend you have g++ >= 6.1 installed on your system because NN generated tests require it (c++14).

Ubuntu 20.04 LTS

On Ubuntu 20.04 LTS, you can install using apt-get.

Choose g++ version whatever you prefer: 9 (default) or 10. We are officially testing on default g++ version, so we don't confirm build on different version.

$ sudo apt-get install g++-{9,10}-arm-linux-gnueabihf

If you select specific version, update symbolic link for build toolchain.

Otherwise, you should set your custom cmake crossbuild toolchain. You can find cmake toolchain files in infra/nnfw/cmake/buildtool/cross/.

$ update-alternatives --install /usr/bin/arm-linux-gnueabihf-gcc arm-linux-gnueabihf-gcc /usr/bin/arm-linux-gnueabihf-gcc-10 80 \
    --slave /usr/bin/arm-linux-gnueabihf-g++ arm-linux-gnueabihf-g++ /usr/bin/arm-linux-gnueabihf-g++-10 \
    --slave /usr/bin/arm-linux-gnueabihf-gcov arm-linux-gnueabihf-gcov /usr/bin/arm-linux-gnueabihf-gcov-10

Ubuntu 22.04 LTS

Same with Ubuntu 20.04 LTS. (except g++ version)

Build and install ARM Compute Library

Mostly you only need once of ACL (ARM Compute Library) build.

To build ACL, you need to install scons

$ sudo apt-get install scons

ACL source will be automatically installed in externals/ARMCOMPUTE when you build runtime without any changes.

You can check ACL source information in infra/cmake/packages/ARMComputeSourceConfig.cmake

Cross build for ARM by using Makefile.template

Give TARGET_ARCH variable to set the target architecture.

If you used ROOTFS_DIR to prepare in alternative folder, you should also give this to makefile.

$ CROSS_BUILD=1 TARGET_ARCH=armv7l make -f Makefile.template

# If ROOTFS_DIR is in alternative folder
$ ROOTFS_DIR=/path/to/your/rootfs/arm \
CROSS_BUILD=1 TARGET_ARCH=armv7l make

You can also omit the CROSS_BUILD=1 option if you explicitly pass ROOTFS_DIR. In that case, if the TARGET_ARCH are differs from the hostarchitecture, the make script automatically applies CROSS_BUILD=1. So, if you set ROOTFS_DIR as an environment variable, you can simply perform normal build and cross build as follows.

$ export ROOTFS_DIR=xxx
...
$ make -f Makefile.template                     # do normal build
$ TARGET_ARCH=armv7l make -f Makefile.template  # do cross build

Makefile.template will pass crossbuild toolchain setting to cmake automatically by parsing variables.

Run test

To run and test the cross-compiled runtime, you need to install library packages and copy the compiled output to the target device of the architecture in which it is executable.

  1. Install hdf5 library package
$ sudo apt install libhdf5-dev
  1. Copy all artifacts under the ./Product/armv7l-linux.<BUILD_TYPE> folder to the target device, Odroid-XU4 for example, as a whole.
$ ssh odroid mkdir -p one/Product
sjlee@odroid's password:
$ scp -rp ./Product/armv7l-linux.debug odroid:one/Product
sjlee@odroid's password:
FillFrom_runner                                                                                 100%  224KB 223.6KB/s   00:00
benchmark_nnapi.sh                                                                              100% 7464     7.3KB/s   00:00
common.sh                                                                                       100% 2084     2.0KB/s   00:00
test_framework.sh                                                                               100% 3154     3.1KB/s   00:00
test-driver.sh
...
  1. Log in to the target device, go to the copied path, and reestore the symbolic link settings of the Product directory.
$ ssh odroid
sjlee@odroid's password:
...
$ cd ~/one/Product
$ ln ${PWD}/armv7l-linux.debug/out out
$ cd ..
$ ls -la Product
drwxrwxr-x  5 sjlee sjlee 4096 Jun  4 20:55 armv7l-linux.debug
lrwxrwxrwx  1 sjlee sjlee   51 Jun  4 20:55 out -> /home/sjlee/one/Product/armv7l-linux.debug/out

Now you can test the compilation result in the same way as the native build. Please refer to the following document for details on the test procedure.