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I want to use clang-11 on my AArch64 Raspberry Pi 4, running Ubuntu 20.04 Focal. I looked at https://apt.llvm.org/, but AArch64 prebuilt binaries do not seem available?

I tried building clang on the Raspberry Pi directly, but it was very slow and I ran out of space on the SD card eventually.

How do I cross-compile clang myself, on my x64 laptop?

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Building LLVM can be tricky in that it takes lots of computing resources, which makes it hard to iterate with different build options. My first attempt to build trunk version of clang for my AArch64 Raspberry PI ended up with a build for ARM7, and also 30GB in size, which just would not fit on the memory card. Whoops.

Study documentation on project wiki

The first relevant Clang documentation page is Building LLVM with CMake. It explains CMake options CMAKE_BUILD_TYPE, CMAKE_INSTALL_PREFIX, and LLVM_TARGETS_TO_BUILD.

It is a good idea to set -DCMAKE_BUILD_TYPE=MinSizeRel, or some other value other than the default Debug. Debug build of clang will run significantly slower. Customizing CMAKE_INSTALL_PREFIX is necessary, as you do not want to install Clang onto your host system. Give it -DCMAKE_INSTALL_PREFIX=$PWD/install, then copy the install directory to your AArch64 machine.

To decrease the installed size, set -DLLVM_TARGETS_TO_BUILD=AArch64. The default there is to build all targets.

Enable assertions

If you want to use cutting edge features, which is likely, otherwise, why compile clang, you would want to keep assertions in clang code enabled, and you would want debug symbols. It slows the program down and makes it bigger, but it is absolutely worthwhile due to increased safety and debuggability. Check out Getting the Source Code and Building LLVM and set -DCMAKE_BUILD_TYPE=RelWithDebInfo -DLLVM_ENABLE_ASSERTIONS=On in this case.

Next up, read Building a Distribution of LLVM. The relevant advice is to further minimize installed size by setting -DLLVM_BUILD_LLVM_DYLIB=On -DLLVM_LINK_LLVM_DYLIB=On -DLLVM_INSTALL_TOOLCHAIN_ONLY=On.

Finally, read How To Cross-Compile Clang/LLVM using Clang/LLVM. This page is helpful even if you plan on using GCC to cross-compile. If you are using Ubuntu Focal, either directly or you are building in a Docker container, you will probably end up with this skeleton of your CMake command like

CC=aarch64-linux-gnu-gcc-10 CXX=aarch64-linux-gnu-g++-10 cmake ../llvm \
  -DCMAKE_CROSSCOMPILING=True \
  -DLLVM_TARGET_ARCH=AArch64 \
  -DLLVM_DEFAULT_TARGET_TRIPLE=aarch64-linux-gnueabihf \
  -DCMAKE_CXX_FLAGS='-march=armv8-a -mtune=cortex-a72' \
  -GNinja

The options there should be straightforward, except maybe for LLVM_TABLEGEN and CLANG_TABLEGEN. They have to be specified, because these binaries need to run on the host, but the build compiles them for the target, so it cannot use what it just build. Existing binaries must be provided by you. Although llvm-tblgen can be installed with llvm packages, clang-tblgen is not part of the distribution. That means, you need to do two builds. First, build these two binaries for host (you do not have to build complete LLVM, these two binaries are enough), and then point the cross compilation to them.

mkdir build-host
cd build-host
CC=gcc-10 CXX=g++-10 cmake ../llvm -DLLVM_ENABLE_PROJECTS='clang;compiler-rt;lld;clang-tools-extra' -GNinja
ninja llvm-tblgen clang-tblgen

Now, use these binaries in your cross build, so add to your CMake command

-DLLVM_TABLEGEN=/usr/bin/llvm-tblgen-11 -DCLANG_TABLEGEN=/mnt/repos/llvm-project/build-host/bin/clang-tblgen

Start docker

It is advisable to mount the directory with llvm sources into the container from your filesystem. This will make it easier to ship the compilation results out, and also native filesystem is faster than the overlays in docker.

docker run -v `pwd`:/mnt --rm -it ubuntu:focal bash

Install dependencies

On Ubuntu 20.04 Focal

apt install g++-10-aarch64-linux-gnu libstdc++-10-dev-arm64-cross gcc-10 g++-10
apt install cmake ninja-build python3

Configure

mkdir build-aarch64
cd build-aarch64

CC=aarch64-linux-gnu-gcc-10 CXX=aarch64-linux-gnu-g++-10 cmake ../llvm \
    -DCMAKE_BUILD_TYPE=RelWithDebInfo \
    -DLLVM_ENABLE_ASSERTIONS=On \
    -DCMAKE_CROSSCOMPILING=True \
    -DCMAKE_INSTALL_PREFIX=install \
    -DLLVM_DEFAULT_TARGET_TRIPLE=aarch64-linux-gnueabihf \
    -DLLVM_TARGET_ARCH=AArch64 \
    -DLLVM_TARGETS_TO_BUILD=AArch64 \
    -DCMAKE_CXX_FLAGS='-march=armv8-a -mtune=cortex-a72' \
    -GNinja \
    -DLLVM_ENABLE_PROJECTS='clang;compiler-rt;lld;clang-tools-extra' \
    -DLLVM_TABLEGEN=/mnt/repos/llvm-project/build-host/bin/llvm-tblgen \
    -DCLANG_TABLEGEN=/mnt/repos/llvm-project/build-host/bin/clang-tblgen \
    -DLLVM_BUILD_LLVM_DYLIB=On \
    -DLLVM_LINK_LLVM_DYLIB=On \
    -DLLVM_INSTALL_TOOLCHAIN_ONLY=On

Compile

Get a powerful build machine, if you can. Linking some of the binaries takes lots of RAM. You should have ~20 GB of memory available to be able to get anywhere in reasonable time, 64 GB would be even better. If it happens that multiple linking tasks running in parallel exhaust your machine memory, try compiling with ninja -j3 or so, to limit number of parallel tasks to, for example, 3.

ninja install -j3

Using a different linker is supposed to decrease memory requirements. Supposedly, ld.gold has lower memory requirements while linking.

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    Note that debug info is huge. If you aren't going to need it, it is best to leave it out. You can most certainly compile LLVM on smaller system (4GB RAM or so), as long as you don't include debug information. Especially link time will be shorter without debug information. For development, assertions are a good thing however and have little impact on binary size.
    – ayke
    Jan 27 at 1:17

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