=================================================================== How to cross-compile Clang/LLVM using Clang/LLVM =================================================================== Introduction ------------ This document contains information about building LLVM and Clang on a host machine, targeting another platform. For more information on how to use Clang as a cross-compiler, please check https://clang.llvm.org/docs/CrossCompilation.html. This document describes cross-building a compiler in a single stage, using an existing ``clang`` install as the host compiler. .. note:: These instructions have been tested for targeting 32-bit ARM, AArch64, or 64-bit RISC-V from an x86_64 Linux host. But should be equally applicable to any other target. Setting up a sysroot -------------------- You will need a sysroot that contains essential build dependencies compiled for the target architecture. In this case, we will be using CMake and Ninja on a Linux host and compiling against a Debian sysroot. Detailed instructions on producing sysroots are outside of the scope of this documentation, but the following instructions should work on any Linux distribution with these pre-requisites: * ``binfmt_misc`` configured to execute ``qemu-user`` for binaries of the target architecture. This is done by installing the ``qemu-user-static`` and ``binfmt-support`` packages on Debian-derived distributions. * Root access (setups involving ``proot`` or other tools to avoid this requirement may be possible, but aren't described here). * The ``debootstrap`` tool. This is available in most distributions. The following snippet will initialise sysroots for 32-bit Arm, AArch64, and 64-bit RISC-V (just pick the target(s) you are interested in): .. code-block:: bash sudo debootstrap --arch=armhf --variant=minbase --include=build-essential,symlinks stable sysroot-deb-armhf-stable sudo debootstrap --arch=arm64 --variant=minbase --include=build-essential,symlinks stable sysroot-deb-arm64-stable sudo debootstrap --arch=riscv64 --variant=minbase --include=build-essential,symlinks unstable sysroot-deb-riscv64-unstable The created sysroot may contain absolute symlinks, which will resolve to a location within the host when accessed during compilation, so we must convert any absolute symlinks to relative ones: .. code-block:: bash sudo chroot sysroot-of-your-choice symlinks -cr . Configuring CMake and building ------------------------------ For more information on how to configure CMake for LLVM/Clang, see :doc:`CMake`. Following CMake's recommended practice, we will create a `toolchain file `_. The following assumes you have a system install of ``clang`` and ``lld`` that will be used for cross compiling and that the listed commands are executed from within the root of a checkout of the ``llvm-project`` git repository. First, set variables in your shell session that will be used throughout the build instructions: .. code-block:: bash SYSROOT=$HOME/sysroot-deb-arm64-stable TARGET=aarch64-linux-gnu CFLAGS="" To customise details of the compilation target or choose a different architecture altogether, change the ``SYSROOT``, ``TARGET``, and ``CFLAGS`` variables to something matching your target. For example, for 64-bit RISC-V you might set ``SYSROOT=$HOME/sysroot-deb-riscv64-unstable``, ``TARGET=riscv64-linux-gnu`` and ``CFLAGS="-march=rva20u64"``. Refer to documentation such as your target's compiler documentation or processor manual for guidance on which ``CFLAGS`` settings may be appropriate. The specified ``TARGET`` should match the triple used within the sysroot (i.e. ``$SYSROOT/usr/lib/$TARGET`` should exist). Then execute the following snippet to create a toolchain file: .. code-block:: bash cat - < $TARGET-clang.cmake set(CMAKE_SYSTEM_NAME Linux) set(CMAKE_SYSROOT "$SYSROOT") set(CMAKE_C_COMPILER_TARGET $TARGET) set(CMAKE_CXX_COMPILER_TARGET $TARGET) set(CMAKE_C_FLAGS_INIT "$CFLAGS") set(CMAKE_CXX_FLAGS_INIT "$CFLAGS") set(CMAKE_LINKER_TYPE LLD) set(CMAKE_C_COMPILER clang) set(CMAKE_CXX_COMPILER clang++) set(CMAKE_FIND_ROOT_PATH_MODE_PROGRAM NEVER) set(CMAKE_FIND_ROOT_PATH_MODE_LIBRARY ONLY) set(CMAKE_FIND_ROOT_PATH_MODE_INCLUDE ONLY) set(CMAKE_FIND_ROOT_PATH_MODE_PACKAGE ONLY) EOF Then configure and build by invoking ``cmake``: .. code-block:: bash cmake -G Ninja \ -DCMAKE_BUILD_TYPE=Release \ -DLLVM_ENABLE_PROJECTS="lld;clang" \ -DCMAKE_TOOLCHAIN_FILE=$(pwd)/$TARGET-clang.cmake \ -DLLVM_HOST_TRIPLE=$TARGET \ -DCMAKE_INSTALL_PREFIX=$HOME/clang-$TARGET \ -S llvm \ -B build/$TARGET cmake --build build/$TARGET These options from the toolchain file and ``cmake`` invocation above are important: * ``CMAKE_SYSTEM_NAME``: Perhaps surprisingly, explicitly setting this variable `causes CMake to set CMAKE_CROSSCOMPIILING `_. * ``CMAKE_{C,CXX}_COMPILER_TARGET``: This will be used to set the ``--target`` argument to ``clang``. The triple should match the triple used within the sysroot (i.e. ``$SYSROOT/usr/lib/$TARGET`` should exist). * ``CMAKE_FIND_ROOT_PATH_MODE_*``: These `control the search behaviour for finding libraries, includes or binaries `_. Setting these prevents files for the host being used in the build. * ``LLVM_HOST_TRIPLE``: Specifies the target triple of the system the built LLVM will run on, which also implicitly sets other defaults such as ``LLVM_DEFAULT_TARGET_TRIPLE``. For example, if you are using an x86_64 host to compile for RISC-V, this will be a RISC-V triple. * ``CMAKE_SYSROOT``: The path to the sysroot containing libraries and headers for the target. * ``CMAKE_INSTALL_PREFIX``: Setting this avoids installing binaries compiled for the target system into system directories for the host system. It is not required unless you are going to use the ``install`` target. See `LLVM's build documentation `_ for more guidance on CMake variables (e.g. ``LLVM_TARGETS_TO_BUILD`` may be useful if your cross-compiled binaries only need to support compiling for one target). Working around a ninja dependency issue --------------------------------------- If you followed the instructions above to create a sysroot, you may run into a `longstanding problem related to path canonicalization in ninja `_. GCC canonicalizes system headers in dependency files, so when ninja reads them it does not need to do so. Clang does not do this, and unfortunately ninja does not implement the canonicalization logic at all, meaning for some system headers with symlinks in the paths, it can incorrectly compute a non-existing path and consider it as always modified. If you are suffering from this issue, you will find any attempt at an incremental build (including the suggested command to build the ``install`` target in the next section) results in recompiling everything. ``ninja -C build/$TARGET -t deps`` shows files in ``$SYSROOT/include/*`` that do not exist (as the ``$SYSROOT/include`` folder does not exist) and you can further confirm these files are causing ``ninja`` to determine a rebuild is necessary with ``ninja -C build/$TARGET -d deps``. A workaround is to create a symlink so that the incorrect ``$SYSROOT/include/*`` dependencies resolve to files within ``$SYSROOT/usr/include/*``. This works in practice for the simple cross-compilation use case described here, but is not a general solution. .. code-block:: bash sudo ln -s usr/include $SYSROOT/include Testing the just-built compiler ------------------------------- Confirm the ``clang`` binary was built for the expected target architecture: .. code-block:: bash $ file -L ./build/aarch64-linux-gnu/bin/clang ./build/aarch64-linux-gnu/bin/clang: ELF 64-bit LSB pie executable, ARM aarch64, version 1 (SYSV), dynamically linked, interpreter /lib/ld-linux-aarch64.so.1, for GNU/Linux 3.7.0, BuildID[sha1]=516b8b366a790fcd3563bee4aec0cdfcb90bb1c7, not stripped If you have ``qemu-user`` installed you can test the produced target binary either by invoking ``qemu-{target}-static`` directly: .. code-block:: bash $ qemu-aarch64-static -L $SYSROOT ./build/aarch64-linux-gnu/bin/clang --version clang version 21.0.0git (https://github.com/llvm/llvm-project cedfdc6e889c5c614a953ed1f44bcb45a405f8da) Target: aarch64-unknown-linux-gnu Thread model: posix InstalledDir: /home/asb/llvm-project/build/aarch64-linux-gnu/bin Or, if binfmt_misc is configured (as was necessary for debootstrap): .. code-block:: bash $ export QEMU_LD_PREFIX=$SYSROOT; ./build/aarch64-linux-gnu/bin/clang --version clang version 21.0.0git (https://github.com/llvm/llvm-project cedfdc6e889c5c614a953ed1f44bcb45a405f8da) Target: aarch64-unknown-linux-gnu Thread model: posix InstalledDir: /home/asb/llvm-project/build/aarch64-linux-gnu/bin Installing and using -------------------- .. note:: Use of the ``install`` target requires that you have set ``CMAKE_INSTALL_PREFIX`` otherwise it will attempt to install in directories under `/` on your host. If you want to transfer a copy of the built compiler to another machine, you can first install it to a location on the host via: .. code-block:: bash cmake --build build/$TARGET --target=install This will install the LLVM/Clang headers, binaries, libraries, and other files to paths within ``CMAKE_INSTALL_PREFIX``. Then tar that directory for transfer to a device that runs the target architecture natively: .. code-block:: bash tar -czvf clang-$TARGET.tar.gz -C $HOME clang-$TARGET The generated toolchain is portable, but requires compatible versions of any shared libraries it links against. This means using a sysroot that is as similar to your target operating system as possible is desirable. Other `CMake variables `_ may be helpful, for instance ``LLVM_STATIC_LINK_CXX_STDLIB``.