I am attempting to get cross-compiling for Raspberry Pi working on my Ubuntu machine.

During my initial attempts I was using the arm-linux-gnueabi compiler, which is available in the Ubuntu repo. I got this working. I was able to build all my dependencies and use the cross-compiler in my cmake project.

However, I believe I should be using the hf version, so I switched to arm-linux-gnueabihf. Then I realized that this does not work with Raspberry Pi since it is armv6.

After some Googling, I then found the pre-built toolchain from GitHub.

I downloaded the toolchain, but I don't really understand how to "install" it. I extracted the files to my home directory. The directory structure looks like this:

            (contains g++, gcc, etc)
            (contains libstdc++ library)
        (contains arm-linux-gnueabihf-g++, arm-linux-gnueabihf-...)
        (gcc lib stuff)

If I change directory to the INNER bin folder I am able to compile a test program from the terminal without any problems.

arm-linux-gnueabihf/bin$ g++ test.cpp -o test

I then tried to compile a test program in the OUTER bin folder, which contains the prefixed versions of the tools.

 arm-linux-gnueabihf-g++ test.cpp -o test

However, when I try to use the compiler now (from outside the inner bin directory), it is unable to find the libstdc++ shared library that comes with the toolchain:

arm-linux-gnueabihf-gcc: error while loading shared libraries: 
libstdc++.so.6: cannot open shared object file: No such file or directory.

Furthermore, I want to be able to use the compiler without having to navigate to the bin directory. So I tried adding the OUTER bin directory (since I want the prefixed versions) and both lib directories to my PATH:

export PATH=$PATH:~/tools/.../bin
export PATH=$PATH:~/tools/.../lib
export PATH=$PATH:~/tools/.../.../lib

However, this results in the same error. How should I "install" the toolchain so that I can use the toolchain from everywhere, just like I can when I use the cross-compilers from the Ubuntu repo?

  • Try setting --sysroot via CMAKE_C{XX}_FLAGS to install dir. – auselen Oct 3 '13 at 15:27
  • I tried some different paths for --sysroot, but that did not help. I'm not really sure what path I should specify for the sysroot. See above regarding the directory structure of the toolchain. Also, some Googling seems to indicate that --sysroot does not help for libstdc++. – pqvst Oct 4 '13 at 8:17
  • I would try either /gcc-linearo-arm-linux-gnueabihf-raspbian or /gcc-linearo-arm-linux-gnueabihf-raspbian/arm-linux-gnueabihf – auselen Oct 4 '13 at 8:23
  • go here launchpad.net/gcc-arm-embedded and download the tarball and extract. Set your path to the bin dir...done. Or go to codesourcery.com (now mentor graphics) get the lite version, untar/bz, set your path to the bin dir...done. – old_timer Oct 8 '13 at 2:12

I'm gonna try to write this as a tutorial for you so it becomes easy to follow.


Before you start you need to make sure the following is installed:

apt-get install git rsync cmake ia32-libs

Let's cross compile a Pie!

Start with making a folder in your home directory called raspberrypi.

Go in to this folder and pull down the ENTIRE tools folder you mentioned above:

git clone git://github.com/raspberrypi/tools.git

You wanted to use the following of the 3 ones, gcc-linaro-arm-linux-gnueabihf-raspbian, if I did not read wrong.

Go into your home directory and add:

export PATH=$PATH:$HOME/raspberrypi/tools/arm-bcm2708/gcc-linaro-arm-linux-gnueabihf-raspbian/bin

to the end of the file named ~/.bashrc

Now you can either log out and log back in (i.e. restart your terminal session), or run . ~/.bashrc in your terminal to pick up the PATH addition in your current terminal session.

Now, verify that you can access the compiler arm-linux-gnueabihf-gcc -v. You should get something like this:

Using built-in specs.
Target: arm-linux-gnueabihf
Configured with: /cbuild/slaves/oort61/crosstool-ng/builds/arm-linux-gnueabihf-raspbian-linux/.b
 uild/src/gcc-linaro-4.7-2012.08/configure --build=i686-build_pc-linux-gnu --host=i686-build_pc-
 linux-gnu --target=arm-linux-gnueabihf --prefix=/cbuild/slaves/oort61/crosstool-ng/builds/arm-l
 inux-gnueabihf-raspbian-linux/install --with-sysroot=/cbuild/slaves/oort61/crosstool-ng/builds/
 arm-linux-gnueabihf-raspbian-linux/install/arm-linux-gnueabihf/libc --enable-languages=c,c++,fo
 rtran --disable-multilib --with-arch=armv6 --with-tune=arm1176jz-s --with-fpu=vfp --with-float=
 hard --with-pkgversion='crosstool-NG linaro-1.13.1+bzr2458 - Linaro GCC 2012.08' --with-bugurl=
 https://bugs.launchpad.net/gcc-linaro --enable-__cxa_atexit --enable-libmudflap --enable-libgom
 p --enable-libssp --with-gmp=/cbuild/slaves/oort61/crosstool-ng/builds/arm-linux-gnueabihf-rasp
 bian-linux/.build/arm-linux-gnueabihf/build/static --with-mpfr=/cbuild/slaves/oort61/crosstool-
 ng/builds/arm-linux-gnueabihf-raspbian-linux/.build/arm-linux-gnueabihf/build/static --with-mpc
 gnueabihf/build/static --with-ppl=/cbuild/slaves/oort61/crosstool-ng/builds/arm-linux-gnueabihf
 -raspbian-linux/.build/arm-linux-gnueabihf/build/static --with-cloog=/cbuild/slaves/oort61/cros
 stool-ng/builds/arm-linux-gnueabihf-raspbian-linux/.build/arm-linux-gnueabihf/build/static --wi
 rm-linux-gnueabihf/build/static --with-host-libstdcxx='-L/cbuild/slaves/oort61/crosstool-ng/bui
 lds/arm-linux-gnueabihf-raspbian-linux/.build/arm-linux-gnueabihf/build/static/lib -lpwl' --ena
 ble-threads=posix --disable-libstdcxx-pch --enable-linker-build-id --enable-plugin --enable-gol
 d --with-local-prefix=/cbuild/slaves/oort61/crosstool-ng/builds/arm-linux-gnueabihf-raspbian-li
 nux/install/arm-linux-gnueabihf/libc --enable-c99 --enable-long-long
Thread model: posix
gcc version 4.7.2 20120731 (prerelease) (crosstool-NG linaro-1.13.1+bzr2458 - Linaro GCC 2012.08

But hey! I did that and the libs still don't work!

We're not done yet! So far, we've only done the basics.

In your raspberrypi folder, make a folder called rootfs.

Now you need to copy the entire /liband /usr directory to this newly created folder. I usually bring the rpi image up and copy it via rsync:

rsync -rl --delete-after --safe-links pi@192.168.1.PI:/{lib,usr} $HOME/raspberrypi/rootfs

where 192.168.1.PI is replaced by the IP of your Raspberry Pi.

Now, we need to write a cmake config file. Open ~/home/raspberrypi/pi.cmake in your favorite editor and insert the following:

SET(CMAKE_C_COMPILER $ENV{HOME}/raspberrypi/tools/arm-bcm2708/gcc-linaro-arm-linux-gnueabihf-raspbian/bin/arm-linux-gnueabihf-gcc)
SET(CMAKE_CXX_COMPILER $ENV{HOME}/raspberrypi/tools/arm-bcm2708/gcc-linaro-arm-linux-gnueabihf-raspbian/bin/arm-linux-gnueabihf-g++)
SET(CMAKE_FIND_ROOT_PATH $ENV{HOME}/raspberrypi/rootfs)

Now you should be able to compile your cmake programs simply by adding this extra flag: -D CMAKE_TOOLCHAIN_FILE=$HOME/raspberrypi/pi.cmake.

Using a cmake hello world example:

git clone https://github.com/jameskbride/cmake-hello-world.git 
cd cmake-hello-world
mkdir build
cd build
cmake -D CMAKE_TOOLCHAIN_FILE=$HOME/raspberrypi/pi.cmake ../
scp CMakeHelloWorld pi@192.168.1.PI:/home/pi/
ssh pi@192.168.1.PI ./CMakeHelloWorld
  • 2
    I followed your tutorial step by step and now I am able to compile without any errors. Thanks! Extra thanks for including the cmake example. – pqvst Oct 10 '13 at 15:03
  • 1
    This works well for simple projects, but I can't cross-compile my CMAKE project that depends on opencv. I get following error "/opt/tools/arm-bcm2708/gcc-linaro-arm-linux-gnueabihf-raspbian/bin/../lib/gcc/arm-linux-gnueabihf/4.7.2/../../../../arm-linux-gnueabihf/bin/ld: warning: libjpeg.so.8, needed by /opt/rpi-rootfs/usr/lib/libopencv_highgui.so, not found (try using -rpath or -rpath-link)". Cmake also seems to pass "-Wl,-rpath,/opt/rpi-rootfs/usr/lib" flag to the linker – Hans Solo Nov 9 '13 at 23:00
  • 17
    The ia32-libs package isn't available on Ubuntu 13.10. I used libc6-i386 lib32z1 lib32stdc++6 instead. – blt Dec 19 '13 at 12:24
  • 2
    Great tutorial answer! Have a bounty :) – andrewdotnich Jul 18 '14 at 2:43
  • 2
    Thank you for a thorough tutorial! Would you please explain why is it needed to copy /lib /usr folders from pi machine? – Marcello Jan 18 '15 at 5:23

I couldn't get the compiler (x64 version) to use the sysroot until I added SET(CMAKE_SYSROOT $ENV{HOME}/raspberrypi/rootfs) to pi.cmake.

  • I could run the Hello World example without CMAKE_SYSROOT set, but when trying the pi.cmake file with a project which uses a shared library I got the linker error libstdc++.so.6 not found. After I set CMAKE_SYSROOT everything worked flawless. – Michael Hilbert Nov 9 '16 at 20:49

For Windows host, I want to highly recommend this tutorial::

  • Download and install the toolchain
  • Sync sysroot with your RPi include/lib directories
  • Compile your code
  • Drag and drop the executable to your RPi using SmarTTY
  • Run it!

Nothing more, nothing less!

Prebuilt GNU Toolchains available for Raspberry, Beaglebone, Cubieboard, AVR (Atmel) and more


You may use clang as well. It used to be faster than GCC, and now it is quite a stable thing. It is much easier to build clang from sources (you can really drink cup of coffee during build process).

In short:

  1. Get clang binaries (sudo apt-get install clang).. or download and build (read instructions here)
  2. Mount your raspberry rootfs (it may be the real rootfs mounted via sshfs, or an image).
  3. Compile your code:

    path/to/clang --target=arm-linux-gnueabihf --sysroot=/some/path/arm-linux-gnueabihf/sysroot my-happy-program.c -fuse-ld=lld

Optionally you may use legacy arm-linux-gnueabihf binutils. Then you may remove "-fuse-ld=lld" flag at the end.

Below is my cmake toolchain file.



# Custom toolchain-specific definitions for your project

# There we go!
# Below, we specify toolchain itself!

set(TARGET_TRIPLE arm-linux-gnueabihf)

# Specify your target rootfs mount point on your compiler host machine
set(TARGET_ROOTFS /Volumes/rootfs-${TARGET_TRIPLE})

# Specify clang paths
set(LLVM_DIR /Users/stepan/projects/shared/toolchains/llvm-7.0.darwin-release-x86_64/install)
set(CLANG ${LLVM_DIR}/bin/clang)
set(CLANGXX ${LLVM_DIR}/bin/clang++)

# Specify compiler (which is clang)

# Specify binutils

set (CMAKE_AR      "${LLVM_DIR}/bin/llvm-ar" CACHE FILEPATH "Archiver")
set (CMAKE_LINKER  "${LLVM_DIR}/bin/llvm-ld" CACHE FILEPATH "Linker")
set (CMAKE_NM      "${LLVM_DIR}/bin/llvm-nm" CACHE FILEPATH "NM")
set (CMAKE_OBJDUMP "${LLVM_DIR}/bin/llvm-objdump" CACHE FILEPATH "Objdump")
set (CMAKE_RANLIB  "${LLVM_DIR}/bin/llvm-ranlib" CACHE FILEPATH "ranlib")

# You may use legacy binutils though.
#set(BINUTILS /usr/local/Cellar/arm-linux-gnueabihf-binutils/2.31.1)
#set (CMAKE_AR      "${BINUTILS}/bin/${TARGET_TRIPLE}-ar" CACHE FILEPATH "Archiver")

# Specify sysroot (almost same as rootfs)

# Specify lookup methods for cmake

# Sometimes you also need this:

# Specify raspberry triple
set(CROSS_FLAGS "--target=${TARGET_TRIPLE}")

# Specify other raspberry related flags

# Gather and distribute flags specified at prev steps.

# Use clang linker. Why?
# Well, you may install custom arm-linux-gnueabihf binutils,
# but then, you also need to recompile clang, with customized triple;
# otherwise clang will try to use host 'ld' for linking,
# so... use clang linker.

I could not compile QT5 with any of the (fairly outdated) toolchains from git://github.com/raspberrypi/tools.git. The configure script kept failing with an "could not determine architecture" error and with massive path problems for include directories. What worked for me was using the Linaro toolchain


in combination with


Failing to fix the symlinks of the sysroot leads to undefined symbol errors as described here: An error building Qt libraries for the raspberry pi This happened to me when I tried the fixQualifiedLibraryPaths script from tools.git. Everthing else is described in detail in http://wiki.qt.io/RaspberryPi2EGLFS . My configure settings were:

./configure -opengl es2 -device linux-rpi3-g++ -device-option CROSS_COMPILE=/usr/local/rasp/gcc-linaro-4.9-2016.02-x86_64_arm-linux-gnueabihf/bin/arm-linux-gnueabihf- -sysroot /usr/local/rasp/sysroot -opensource -confirm-license -optimized-qmake -reduce-exports -release -make libs -prefix /usr/local/qt5pi -hostprefix /usr/local/qt5pi

with /usr/local/rasp/sysroot being the path of my local Raspberry Pi 3 Raspbian (Jessie) system copy and /usr/local/qt5pi being the path of the cross compiled QT that also has to be copied to the device. Be aware that Jessie comes with GCC 4.9.2 when you choose your toolchain.


The initial question has been posted quite some time ago and in the meantime Debian has made huge headway in the area of multiarch support.

Multiarch is a great achievement for cross compilation!

In a nutshell the following steps are required to leverage multiarch for Raspbian Jessie cross compilation:

  • On your Ubuntu host install Debian Jessie amd64 within a chroot or a LXC container.
  • Enable the foreign architecture armhf.
  • Install the cross compiler from the emdebian tools repository.
  • Tweak the cross compiler (it would generate code for ARMv7-A by default) by writing a custom gcc specs file.
  • Install armhf libraries (libstdc++ etc.) from the Raspbian repository.
  • Build your source code.

Since this is a lot of work I have automated the above setup. You can read about it here:

Cross Compiling for Raspbian


there is a CDP Studio IDE available that makes cross compile and deploy quite simple from both windows and linux and you can just check the raspberry toolchain checkbox during the installation. (PS. it has GPIO and I2C support so no code is needed to access those)

The IDE demo of raspberry use is up here: https://youtu.be/4SVZ68sQz5U

and you can download the IDE here: https://cdpstudio.com/home-edition

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.