Cross-building

Cross-building is compiling a library or executable in one platform to be used in a different one.

Cross-compilation is used to build software for an alien device, such as an embedded device where you don’t have an operating system nor a compiler available. It’s also for building software for slower devices, like an Android machine, a Raspberry Pi etc.

To cross-build code you need the right toolchain.

A toolchain is basically a compiler and linker with a set of libraries matching the host platform.

GNU triplet convention

According to the GNU convention, there are three platforms involved in the software building:

  • Build platform: The platform on which the compilation tools are executed

  • Host platform: The platform on which the code will run

  • Target platform: Only when building a compiler, this is the platform for which the compiler will generate code

When you are building code for your own machine it’s called native building, where the build and the host platforms are the same. The target platform is not defined in this situation.

When you are building code for a different platform, it’s called cross-building, where the build platform is different from the host platform. The target platform is not defined in this situation.

The use of the target platform is rarely needed. It only makes sense when you are building a compiler. For instance, when you are building on your Linux machine a GCC compiler that will run on Windows, to generate code for Android. Here, the build is your Linux computer, the host is the Windows computer and the target is Android.

Conan settings

From version 1.0, Conan introduces new settings to model the GNU convention triplet:

build platform settings:

  • os_build: Operating system of the build system.

  • arch_build: Architecture system of the build system.

These settings are detected the first time you run Conan with the same values than the host settings, so by default, we are doing native building. You will probably never need to change the value of this setting because they describe where are you running Conan.

host platform settings:

  • os: Operating system of the host system.

  • arch: Architecture of the host system.

  • compiler: Compiler of the host system (to declare compatibility of libs in the host platform)

  • … (all the regular settings)

These settings are the regular Conan settings; already present before supporting the GNU triplet convention. If you are cross-building, you have to change them according to the host platform.

target platform:

  • os_target: Operating system of the target system.

  • arch_target: Architecture of the target system.

If you are building a compiler, these settings specify where the compiled code will run.

Cross-building with Conan

If you want to cross-build a Conan package (for example on your Linux machine) to build the zlib Conan package for Windows, you need to tell Conan where to find your cross-compiler/toolchain.

There are two approaches:

  • Install the toolchain in your computer and use a profile to declare the settings and point to the needed tools/libraries in the toolchain using the [env] section to declare, at least, the CC and CXX environment variables.

  • Package the toolchain as a Conan package and include it as a build_require.

Using profiles

Create a profile with:

  • A [settings] section containing the needed settings: os_build, arch_build and the regular settings os, arch, compiler, build_type and so on.

  • An [env] section with a PATH variable pointing to your installed toolchain. Also any other variable that the toolchain expects (read the docs of your compiler). Some build systems need a variable SYSROOT to locate where the host system libraries and tools are.

Linux to Windows

  • Install the needed toolchain, in Ubuntu:

    sudo apt-get install g++-mingw-w64 gcc-mingw-w64

  • Create a file named linux_to_win64 with the contents:

toolchain=/usr/x86_64-w64-mingw32 # Adjust this path
target_host=x86_64-w64-mingw32
cc_compiler=gcc
cxx_compiler=g++

[env]
CONAN_CMAKE_FIND_ROOT_PATH=$toolchain
CHOST=$target_host
AR=$target_host-ar
AS=$target_host-as
RANLIB=$target_host-ranlib
CC=$target_host-$cc_compiler
CXX=$target_host-$cxx_compiler
STRIP=$target_host-strip
RC=$target_host-windres

[settings]
# We are building in Ubuntu Linux
os_build=Linux
arch_build=x86_64

# We are cross-building to Windows
os=Windows
arch=x86_64
compiler=gcc

# Adjust to the gcc version of your MinGW package
compiler.version=7.3
compiler.libcxx=libstdc++11
build_type=Release
  • Clone an example recipe or use your own recipe:

git clone https://github.com/memsharded/conan-hello.git
  • Call conan create using the created linux_to_win64

$ cd conan-hello && conan create . conan/testing --profile ../linux_to_win64
...
[ 50%] Building CXX object CMakeFiles/example.dir/example.cpp.obj
[100%] Linking CXX executable bin/example.exe
[100%] Built target example

A bin/example.exe for Win64 platform has been built.

Windows to Raspberry Pi (Linux/ARM)

  • Install the toolchain: http://gnutoolchains.com/raspberry/ You can choose different versions of the GCC cross compiler. Choose one and adjust the following settings in the profile accordingly.

  • Create a file named win_to_rpi with the contents:

target_host=arm-linux-gnueabihf
standalone_toolchain=C:/sysgcc/raspberry
cc_compiler=gcc
cxx_compiler=g++

[settings]
os_build=Windows
arch_build=x86_64
os=Linux
arch=armv7 # Change to armv6 if you are using Raspberry 1
compiler=gcc
compiler.version=6
compiler.libcxx=libstdc++11
build_type=Release

[env]
CONAN_CMAKE_FIND_ROOT_PATH=$standalone_toolchain/$target_host/sysroot
PATH=[$standalone_toolchain/bin]
CHOST=$target_host
AR=$target_host-ar
AS=$target_host-as
RANLIB=$target_host-ranlib
LD=$target_host-ld
STRIP=$target_host-strip
CC=$target_host-$cc_compiler
CXX=$target_host-$cxx_compiler
CXXFLAGS=-I"$standalone_toolchain/$target_host/lib/include"

The profiles to target Linux are all very similar. You probably just need to adjust the variables declared at the top of the profile:

  • target_host: All the executables in the toolchain starts with this prefix.

  • standalone_toolchain: Path to the toolchain installation.

  • cc_compiler/cxx_compiler: In this case gcc/g++, but could be clang/clang++.

  • Clone an example recipe or use your own recipe:

git clone https://github.com/memsharded/conan-hello.git
  • Call conan create using the created profile.

$ cd conan-hello && conan create . conan/testing --profile=../win_to_rpi
...
[ 50%] Building CXX object CMakeFiles/example.dir/example.cpp.obj
[100%] Linking CXX executable bin/example
[100%] Built target example

A bin/example for Raspberry PI (Linux/armv7hf) platform has been built.

Windows to Windows CE

The Windows CE (WinCE) operating system is supported for CMake and MSBuild. Since WinCE depends on the MSVC compiler, Visual Studio and the according Windows CE platform SDK for the WinCE device have to be installed on the build host.

The os.platform defines the WinCE Platform SDK and is equal to the Platform in Visual Studio.

Some examples for Windows CE platforms:

  • SDK_AM335X_SK_WEC2013_V310

  • STANDARDSDK_500 (ARMV4I)

  • Windows Mobile 5.0 Pocket PC SDK (ARMV4I)

  • Toradex_CE800 (ARMV7)

The os.version defines the WinCE version and must be "5.0", "6.0" or "7.0".

CMake supports Visual Studio 2008 (compiler.version=9) and Visual Studio 2012 (compiler.version=11).

Example of an Windows CE conan profile:

[settings]
os=WindowsCE
os.version=8.0
os.platform=Toradex_CE800 (ARMV7)
arch=armv7
compiler=Visual Studio
compiler.version=11

# Release configuration
build_type=Release
compiler.runtime=MD

Note

Further information about CMake and WinCE can be found in the CMake documentation:

CMake - Cross Compiling for Windows CE

Linux/Windows/macOS to Android

Cross-building a library for Android is very similar to the previous examples, except the complexity of managing different architectures (armeabi, armeabi-v7a, x86, arm64-v8a) and the Android API levels.

Download the Android NDK here and unzip it.

Note

If you are in Windows the process will be almost the same, but unzip the file in the root folder of your hard disk (C:\) to avoid issues with path lengths.

Now you have to build a standalone toolchain. We are going to target the “arm” architecture and the Android API level 21. Change the --install-dir to any other place that works for you:

$ cd build/tools
$ python make_standalone_toolchain.py --arch=arm --api=21 --stl=libc++ --install-dir=/myfolder/arm_21_toolchain

Note

You can generate the standalone toolchain with several different options to target different architectures, API levels etc.

Check the Android docs: standalone toolchain

To use the clang compiler, create a profile android_21_arm_clang. Once again, the profile is very similar to the RPI one:

standalone_toolchain=/myfolder/arm_21_toolchain # Adjust this path
target_host=arm-linux-androideabi
cc_compiler=clang
cxx_compiler=clang++

[settings]
compiler=clang
compiler.version=5.0
compiler.libcxx=libc++
os=Android
os.api_level=21
arch=armv7
build_type=Release

[env]
CONAN_CMAKE_FIND_ROOT_PATH=$standalone_toolchain/sysroot
PATH=[$standalone_toolchain/bin]
CHOST=$target_host
AR=$target_host-ar
AS=$target_host-as
RANLIB=$target_host-ranlib
CC=$target_host-$cc_compiler
CXX=$target_host-$cxx_compiler
LD=$target_host-ld
STRIP=$target_host-strip
CFLAGS= -fPIE -fPIC -I$standalone_toolchain/include/c++/4.9.x
CXXFLAGS= -fPIE -fPIC -I$standalone_toolchain/include/c++/4.9.x
LDFLAGS= -pie

You could also use gcc using this profile arm_21_toolchain_gcc, changing the cc_compiler and cxx_compiler variables, removing -fPIE flag and, of course, changing the [settings] to match the gcc toolchain compiler:

standalone_toolchain=/myfolder/arm_21_toolchain
target_host=arm-linux-androideabi
cc_compiler=gcc
cxx_compiler=g++

[settings]
compiler=gcc
compiler.version=4.9
compiler.libcxx=libstdc++
os=Android
os.api_level=21
arch=armv7
build_type=Release

[env]
CONAN_CMAKE_FIND_ROOT_PATH=$standalone_toolchain/sysroot
PATH=[$standalone_toolchain/bin]
CHOST=$target_host
AR=$target_host-ar
AS=$target_host-as
RANLIB=$target_host-ranlib
CC=$target_host-$cc_compiler
CXX=$target_host-$cxx_compiler
LD=$target_host-ld
STRIP=$target_host-strip
CFLAGS= -fPIC -I$standalone_toolchain/include/c++/4.9.x
CXXFLAGS= -fPIC -I$standalone_toolchain/include/c++/4.9.x
LDFLAGS=
  • Clone, for example, the zlib library to try to build it to Android

git clone https://github.com/conan-community/conan-zlib.git
  • Call conan create using the created profile.

$ cd conan-zlib && conan create . conan/testing --profile=../android_21_arm_clang

...
-- Build files have been written to: /tmp/conan-zlib/test_package/build/ba0b9dbae0576b9a23ce7005180b00e4fdef1198
Scanning dependencies of target enough
[ 50%] Building C object CMakeFiles/enough.dir/enough.c.o
[100%] Linking C executable bin/enough
[100%] Built target enough
zlib/1.2.11@conan/testing (test package): Running test()

A bin/enough for Android ARM platform has been built.

Using build requires

Instead of manually downloading the toolchain and creating a profile, you can create a Conan package with it. The toolchain Conan package needs to fill the env_info object in the package_info() method with the same variables we’ve specified in the examples above in the [env] section of profiles.

A layout of a Conan package for a toolchain could looks like this:

from conans import ConanFile
import os


class MyToolchainXXXConan(ConanFile):
    name = "my_toolchain"
    version = "0.1"
    settings = "os_build", "arch_build"

    def build(self):
        # Typically download the toolchain for the 'build' host
        url = "http://fake_url.com/installers/%s/%s/toolchain.tgz" % (os_build, os_arch)
        tools.download(url, "toolchain.tgz")
        tools.unzip("toolchain.tgz")

    def package(self):
        # Copy all the
        self.copy("*", dst="", src="toolchain")

    def package_info(self):
        bin_folder = os.path.join(self.package_folder, "bin")
        self.env_info.path.append(bin_folder)
        self.env_info.CC = os.path.join(bin_folder, "mycompiler-cc")
        self.env_info.CXX = os.path.join(bin_folder, "mycompiler-cxx")
        self.env_info.SYSROOT = self.package_folder

Finally, when you want to cross-build a library, the profile to be used will include a [build_requires] section with the reference to our new packaged toolchain. This will also contain a [settings] section with the same settings from the examples above.

Example: Darwin Toolchain

Check the Darwin Toolchain package in conan-center. You can use a profile like the following to cross-build your packages for iOS, watchOS and tvOS:

ios_profile
include(default)

[settings]
os=iOS
os.version=9.0
arch=armv7

[build_requires]
darwin-toolchain/1.0@theodelrieu/stable
$ conan install . --profile ios_profile

See also

Using Docker images

You can use some available Docker images with Conan preinstalled images to cross-build Conan packages. Currently there are i386, armv7 and armv7hf images with the needed packages and toolchains installed to cross-build.

Example: Cross-building and uploading a package along with all its missing dependencies for Linux/armv7hf is done in few steps:

$ git clone https://github.com/conan-community/conan-openssl
$ cd conan-openssl
$ docker run -it -v$(pwd):/home/conan/project --rm conanio/gcc49-armv7hf /bin/bash

# Now we are running on the conangcc49-armv7hf container
$ sudo pip install conan --upgrade
$ cd project

$ conan create . user/channel --build missing
$ conan remote add myremoteARMV7 http://some.remote.url
$ conan upload "*" -r myremoteARMV7 --all

Check the section: How to run Conan with Docker to know more.

Preparing recipes to be cross-compiled

If you use the build helpers AutoToolsBuildEnvironment or CMake, Conan will adjust the configuration accordingly to the specified settings.

If don’t, you can always check the self.settings.os, self.settings.build_os, self.settings.arch and self.settings.build_arch settings values and inject the needed flags to your build system script.

You can use this tool to check if you are cross-building:

ARM architecture reference

Remember that the Conan settings are intended to unify the different names for operating systems, compilers, architectures etc.

Conan has different architecture settings for ARM: armv6, armv7, armv7hf, armv8. The “problem” with ARM architecture is that it’s frequently named in different ways, so maybe you are wondering what setting do you need to specify in your case.

Here is a table with some typical ARM platforms:

Platform

Conan setting

Raspberry PI 1

armv6

Raspberry PI 2

armv7 or armv7hf if we want to use the float point hard support

Raspberry PI 3

armv8 also known as armv64-v8a

Visual Studio

armv7 currently Visual Studio builds armv7 binaries when you select ARM.

Android armbeabi-v7a

armv7

Android armv64-v8a

armv8

Android armeabi

armv6 (as a minimal compatible, will be compatible with v7 too)

See also