docs/markdown/Cross-compilation.md - meson - Git at Google

 ---
 short-description: Setting up cross-compilation
 ...

 # Cross compilation

 Meson has full support for cross compilation. Since cross compiling is
 more complicated than native building, let's first go over some
 nomenclature. The three most important definitions are traditionally
 called *build*, *host* and *target*. This is confusing because those
 terms are used for quite many different things. To simplify the issue,
 we are going to call these the *build machine*, *host machine* and
 *target machine*. Their definitions are the following:

 * *build machine* is the computer that is doing the actual compiling.
 * *host machine* is the machine on which the compiled binary will run.
 * *target machine* is the machine on which the compiled binary's
   output will run, *only meaningful* if the program produces
   machine-specific output.

 The `tl/dr` summary is the following: if you are doing regular cross
 compilation, you only care about `build_machine` and
 `host_machine`. Just ignore `target_machine` altogether and you will
 be correct 99% of the time. Only compilers and similar tools care
 about the target machine. In fact, for so-called "multi-target" tools
 the target machine need not be fixed at build-time like the others but
 chosen at runtime, so `target_machine` *still* doesn't matter. If your
 needs are more complex or you are interested in the actual details, do
 read on.

 This might be easier to understand through examples. Let's start with
 the regular, not cross-compiling case. In these cases all of these
 three machines are the same. Simple so far.

 Let's next look at the most common cross-compilation setup. Let's
 suppose you are on a 64 bit OSX machine and you are cross compiling a
 binary that will run on a 32 bit ARM Linux board. In this case your
 *build machine* is 64 bit OSX and both your *host* and *target
 machines* are 32 bit ARM Linux. This should be quite understandable as
 well.

 It gets a bit trickier when we think about how the cross compiler was
 generated. It was built and it runs on a specific platform but the
 output it generates is for a different platform. In this case *build*
 and *host machines* are the same, but *target machine* is different.

 The most complicated case is when you cross-compile a cross
 compiler. As an example you can, on a Linux machine, generate a cross
 compiler that runs on Windows but produces binaries on MIPS Linux. In
 this case *build machine* is x86 Linux, *host machine* is x86 Windows
 and *target machine* is MIPS Linux. This setup is known as the
 [Canadian
 Cross](https://en.wikipedia.org/wiki/Cross_compiler#Canadian_Cross). As
 a side note, be careful when reading cross compilation articles on
 Wikipedia or the net in general. It is very common for them to get
 build, host and target mixed up, even in consecutive sentences, which
 can leave you puzzled until you figure it out.

 A lot of confusion stems from the fact that when you cross-compile
 something, the 3 systems (*build*, *host*, and *target*) used when
 building the cross compiler don't align with the ones used when
 building something with that newly-built cross compiler. To take our
 Canadian Cross scenario from above (for full generality), since its
 *host machine* is x86 Windows, the *build machine* of anything we
 build with it is *x86 Windows*. And since its *target machine* is MIPS
 Linux, the *host machine* of anything we build with it is *MIPS
 Linux*. Only the *target machine* of whatever we build with it can be
 freely chosen by us, say if we want to build another cross compiler
 that runs on MIPS Linux and targets Aarch64 iOS. As this example
 hopefully makes clear to you, the platforms are shifted over to the
 left by one position.

 If you did not understand all of the details, don't worry. For most
 people it takes a while to wrap their head around these
 concepts. Don't panic, it might take a while to click, but you will
 get the hang of it eventually.

 ## Defining the environment

 Meson requires you to write a cross build definition file. It defines
 various properties of the cross build environment. The cross file
 consists of different sections. The first one is the list of
 executables that we are going to use. A sample snippet might look like
 this:

 ```ini
 [binaries]
 c = '/usr/bin/i586-mingw32msvc-gcc'
 cpp = '/usr/bin/i586-mingw32msvc-g++'
 ar = '/usr/i586-mingw32msvc/bin/ar'
 strip = '/usr/i586-mingw32msvc/bin/strip'
 pkgconfig = '/usr/bin/i586-mingw32msvc-pkg-config'
 exe_wrapper = 'wine' # A command used to run generated executables.
 ```

 The entries are pretty self explanatory but the last line is
 special. It defines a *wrapper command* that can be used to run
 executables for this host. In this case we can use Wine, which runs
 Windows applications on Linux. Other choices include running the
 application with qemu or a hardware simulator. If you have this kind
 of a wrapper, these lines are all you need to write. Meson will
 automatically use the given wrapper when it needs to run host
 binaries. This happens e.g. when running the project's test suite.

 The next section lists properties of the cross compiler and its target
 system, and thus properties of host system of what we're building. It
 looks like this:

 ```ini
 [properties]
 sizeof_int = 4
 sizeof_wchar_t = 4
 sizeof_void* = 4

 alignment_char = 1
 alignment_void* = 4
 alignment_double = 4

 has_function_printf = true

 c_args = ['-DCROSS=1', '-DSOMETHING=3']
 c_link_args = ['-some_link_arg']
 sys_root = '/some/path'
 ```

 In most cases you don't need the size and alignment settings, Meson
 will detect all these by compiling and running some sample
 programs. If your build requires some piece of data that is not listed
 here, Meson will stop and write an error message describing how to fix
 the issue. If you need extra compiler arguments to be used during
 cross compilation you can set them with `[langname]_args =
 [args]`. Just remember to specify the args as an array and not as a
 single string (i.e. not as `'-DCROSS=1 -DSOMETHING=3'`).

 *Since 0.52.0* The `sys_root` property may point to the root of the host
 system path (the system that will run the compiled binaries). This is used
 internally by Meson to set the PKG_CONFIG_SYSROOT_DIR environment variable
 for pkg-config. If this is unset the host system is assumed to share a root
 with the build system.

 One important thing to note, if you did not define an `exe_wrapper` in
 the previous section, is that Meson will make a best-effort guess at
 whether it can run the generated binaries on the build machine. It
 determines whether this is possible by looking at the `system` and
 `cpu_family` of build vs host. There will however be cases where they
 do match up, but the build machine is actually not compatible with the
 host machine. Typically this will happen if the libc used by the build
 and host machines are incompatible, or the code relies on kernel
 features not available on the build machine. One concrete example is a
 macOS build machine producing binaries for an iOS Simulator x86-64
 host. They're both `darwin` and the same architecture, but their
 binaries are not actually compatible. In such cases you may use the
 `needs_exe_wrapper` property to override the auto-detection:

 ```ini
 [properties]
 needs_exe_wrapper = true
 ```

 The next bit is the definition of host and target machines. Every
 cross build definition must have one or both of them. If it had
 neither, the build would not be a cross build but a native build. You
 do not need to define the build machine, as all necessary information
 about it is extracted automatically. The definitions for host and
 target machines look the same. Here is a sample for host machine.

 ```ini
 [host_machine]
 system = 'windows'
 cpu_family = 'x86'
 cpu = 'i686'
 endian = 'little'
 ```

 These values define the machines sufficiently for cross compilation
 purposes. The corresponding target definition would look the same but
 have `target_machine` in the header. These values are available in
 your Meson scripts. There are three predefined variables called,
 surprisingly, `build_machine`, `host_machine` and
 `target_machine`. Determining the operating system of your host
 machine is simply a matter of calling `host_machine.system()`.

 There are two different values for the CPU. The first one is
 `cpu_family`. It is a general type of the CPU. Common values might
 include `x86`, `arm` or `x86_64`. The second value is `cpu` which is a
 more specific subtype for the CPU. Typical values for a `x86` CPU
 family might include `i386` or `i586` and for `arm` family `armv5` or
 `armv7hl`. Note that CPU type strings are very system dependent. You
 might get a different value if you check its value on the same machine
 but with different operating systems.

 If you do not define your host machine, it is assumed to be the build
 machine. Similarly if you do not specify target machine, it is assumed
 to be the host machine.

 Additionally, you can define the paths that you want to install to in your
 cross file. This may be especially useful when cross compiling an entire
 operating system, or for operating systems to use internally for consistency.

 ```ini
 [paths]
 prefix = '/my/prefix'
 libdir = 'lib/i386-linux-gnu'
 bindir = 'bin'
 ```

 This will be overwritten by any options passed on the command line.


 ## Starting a cross build


 Once you have the cross file, starting a build is simple

 ```console
 $ meson srcdir builddir --cross-file cross_file.txt
 ```

 Once configuration is done, compilation is started by invoking Ninja
 in the usual way.

 ## Introspection and system checks

 The main *meson* object provides two functions to determine cross
 compilation status.

 ```meson
 meson.is_cross_build()  # returns true when cross compiling
 meson.has_exe_wrapper() # returns true if an exe wrapper has been defined
 ```

 Note that the latter gives undefined return value when doing a native
 build.

 You can run system checks on both the system compiler or the cross
 compiler. You just have to specify which one to use.

 ```meson
 build_compiler = meson.get_compiler('c', native : true)
 host_compiler = meson.get_compiler('c', native : false)

 build_int_size = build_compiler.sizeof('int')
 host_int_size  = host_compiler.sizeof('int')
 ```

 ## Mixing host and build targets

 Sometimes you need to build a tool which is used to generate source
 files. These are then compiled for the actual target. For this you
 would want to build some targets with the system's native
 compiler. This requires only one extra keyword argument.

 ```meson
 native_exe = executable('mygen', 'mygen.c', native : true)
 ```

 You can then take `native_exe` and use it as part of a generator rule or anything else you might want.

 ## Using a custom standard library

 Sometimes in cross compilation you need to build your own standard
 library instead of using the one provided by the compiler. Meson has
 built-in support for switching standard libraries transparently. The
 invocation to use in your cross file is the following:

 ```ini
 [properties]
 c_stdlib = ['mylibc', 'mylibc_dep'] # Subproject name, dependency name
 ```

 This specifies that C standard library is provided in the Meson
 subproject `mylibc` in internal dependency variable `mylibc_dep`. It
 is used on every cross built C target in the entire source tree
 (including subprojects) and the standard library is disabled. The
 build definitions of these targets do not need any modification.

 ## Changing cross file settings

 Cross file settings are only read when the build directory is set up
 the first time. Any changes to them after the fact will be
 ignored. This is the same as regular compiles where you can't change
 the compiler once a build tree has been set up. If you need to edit
 your cross file, then you need to wipe your build tree and recreate it
 from scratch.

 ## Custom data

 You can store arbitrary data in `properties` and access them from your
 Meson files. As an example if you cross file has this:

 ```ini
 [properties]
 somekey = 'somevalue'
 ```

 then you can access that using the `meson` object like this:

 ```meson
 myvar = meson.get_cross_property('somekey')
 # myvar now has the value 'somevalue'
 ```

 ## Cross file locations

 As of version 0.44.0 meson supports loading cross files from system locations
 (except on Windows).  This will be $XDG_DATA_DIRS/meson/cross, or if
 XDG_DATA_DIRS is undefined, then /usr/local/share/meson/cross and
 /usr/share/meson/cross will be tried in that order, for system wide cross
 files. User local files can be put in $XDG_DATA_HOME/meson/cross, or
 ~/.local/share/meson/cross if that is undefined.

 The order of locations tried is as follows:
  - A file relative to the local dir
  - The user local location
  - The system wide locations in order

 Distributions are encouraged to ship cross files either with
 their cross compiler toolchain packages or as a standalone package, and put
 them in one of the system paths referenced above.

 These files can be loaded automatically without adding a path to the cross
 file. For example, if a ~/.local/share/meson/cross contains a file called x86-linux,
 then the following command would start a cross build using that cross files:

 ```sh
 meson builddir/ --cross-file x86-linux
 ```
	---
	short-description: Setting up cross-compilation
	...

	# Cross compilation

	Meson has full support for cross compilation. Since cross compiling is
	more complicated than native building, let's first go over some
	nomenclature. The three most important definitions are traditionally
	called build, host and target. This is confusing because those
	terms are used for quite many different things. To simplify the issue,
	we are going to call these the build machine, host machine and
	target machine. Their definitions are the following:

	* build machine is the computer that is doing the actual compiling.
	* host machine is the machine on which the compiled binary will run.
	* target machine is the machine on which the compiled binary's
	output will run, only meaningful if the program produces
	machine-specific output.

	The `tl/dr` summary is the following: if you are doing regular cross
	compilation, you only care about `build_machine` and
	`host_machine`. Just ignore `target_machine` altogether and you will
	be correct 99% of the time. Only compilers and similar tools care
	about the target machine. In fact, for so-called "multi-target" tools
	the target machine need not be fixed at build-time like the others but
	chosen at runtime, so `target_machine` still doesn't matter. If your
	needs are more complex or you are interested in the actual details, do
	read on.

	This might be easier to understand through examples. Let's start with
	the regular, not cross-compiling case. In these cases all of these
	three machines are the same. Simple so far.

	Let's next look at the most common cross-compilation setup. Let's
	suppose you are on a 64 bit OSX machine and you are cross compiling a
	binary that will run on a 32 bit ARM Linux board. In this case your
	build machine is 64 bit OSX and both your host and *target
	machines* are 32 bit ARM Linux. This should be quite understandable as
	well.

	It gets a bit trickier when we think about how the cross compiler was
	generated. It was built and it runs on a specific platform but the
	output it generates is for a different platform. In this case build
	and host machines are the same, but target machine is different.

	The most complicated case is when you cross-compile a cross
	compiler. As an example you can, on a Linux machine, generate a cross
	compiler that runs on Windows but produces binaries on MIPS Linux. In
	this case build machine is x86 Linux, host machine is x86 Windows
	and target machine is MIPS Linux. This setup is known as the
	[Canadian
	Cross](https://en.wikipedia.org/wiki/Cross_compiler#Canadian_Cross). As
	a side note, be careful when reading cross compilation articles on
	Wikipedia or the net in general. It is very common for them to get
	build, host and target mixed up, even in consecutive sentences, which
	can leave you puzzled until you figure it out.

	A lot of confusion stems from the fact that when you cross-compile
	something, the 3 systems (build, host, and target) used when
	building the cross compiler don't align with the ones used when
	building something with that newly-built cross compiler. To take our
	Canadian Cross scenario from above (for full generality), since its
	host machine is x86 Windows, the build machine of anything we
	build with it is x86 Windows. And since its target machine is MIPS
	Linux, the host machine of anything we build with it is *MIPS
	Linux. Only the target machine* of whatever we build with it can be
	freely chosen by us, say if we want to build another cross compiler
	that runs on MIPS Linux and targets Aarch64 iOS. As this example
	hopefully makes clear to you, the platforms are shifted over to the
	left by one position.

	If you did not understand all of the details, don't worry. For most
	people it takes a while to wrap their head around these
	concepts. Don't panic, it might take a while to click, but you will
	get the hang of it eventually.

	## Defining the environment

	Meson requires you to write a cross build definition file. It defines
	various properties of the cross build environment. The cross file
	consists of different sections. The first one is the list of
	executables that we are going to use. A sample snippet might look like
	this:

	```ini
	[binaries]
	c = '/usr/bin/i586-mingw32msvc-gcc'
	cpp = '/usr/bin/i586-mingw32msvc-g++'
	ar = '/usr/i586-mingw32msvc/bin/ar'
	strip = '/usr/i586-mingw32msvc/bin/strip'
	pkgconfig = '/usr/bin/i586-mingw32msvc-pkg-config'
	exe_wrapper = 'wine' # A command used to run generated executables.
	```

	The entries are pretty self explanatory but the last line is
	special. It defines a wrapper command that can be used to run
	executables for this host. In this case we can use Wine, which runs
	Windows applications on Linux. Other choices include running the
	application with qemu or a hardware simulator. If you have this kind
	of a wrapper, these lines are all you need to write. Meson will
	automatically use the given wrapper when it needs to run host
	binaries. This happens e.g. when running the project's test suite.

	The next section lists properties of the cross compiler and its target
	system, and thus properties of host system of what we're building. It
	looks like this:

	```ini
	[properties]
	sizeof_int = 4
	sizeof_wchar_t = 4
	sizeof_void* = 4

	alignment_char = 1
	alignment_void* = 4
	alignment_double = 4

	has_function_printf = true

	c_args = ['-DCROSS=1', '-DSOMETHING=3']
	c_link_args = ['-some_link_arg']
	sys_root = '/some/path'
	```

	In most cases you don't need the size and alignment settings, Meson
	will detect all these by compiling and running some sample
	programs. If your build requires some piece of data that is not listed
	here, Meson will stop and write an error message describing how to fix
	the issue. If you need extra compiler arguments to be used during
	cross compilation you can set them with `[langname]_args =
	[args]`. Just remember to specify the args as an array and not as a
	single string (i.e. not as `'-DCROSS=1 -DSOMETHING=3'`).

	Since 0.52.0 The `sys_root` property may point to the root of the host
	system path (the system that will run the compiled binaries). This is used
	internally by Meson to set the PKG_CONFIG_SYSROOT_DIR environment variable
	for pkg-config. If this is unset the host system is assumed to share a root
	with the build system.

	One important thing to note, if you did not define an `exe_wrapper` in
	the previous section, is that Meson will make a best-effort guess at
	whether it can run the generated binaries on the build machine. It
	determines whether this is possible by looking at the `system` and
	`cpu_family` of build vs host. There will however be cases where they
	do match up, but the build machine is actually not compatible with the
	host machine. Typically this will happen if the libc used by the build
	and host machines are incompatible, or the code relies on kernel
	features not available on the build machine. One concrete example is a
	macOS build machine producing binaries for an iOS Simulator x86-64
	host. They're both `darwin` and the same architecture, but their
	binaries are not actually compatible. In such cases you may use the
	`needs_exe_wrapper` property to override the auto-detection:

	```ini
	[properties]
	needs_exe_wrapper = true
	```

	The next bit is the definition of host and target machines. Every
	cross build definition must have one or both of them. If it had
	neither, the build would not be a cross build but a native build. You
	do not need to define the build machine, as all necessary information
	about it is extracted automatically. The definitions for host and
	target machines look the same. Here is a sample for host machine.

	```ini
	[host_machine]
	system = 'windows'
	cpu_family = 'x86'
	cpu = 'i686'
	endian = 'little'
	```

	These values define the machines sufficiently for cross compilation
	purposes. The corresponding target definition would look the same but
	have `target_machine` in the header. These values are available in
	your Meson scripts. There are three predefined variables called,
	surprisingly, `build_machine`, `host_machine` and
	`target_machine`. Determining the operating system of your host
	machine is simply a matter of calling `host_machine.system()`.

	There are two different values for the CPU. The first one is
	`cpu_family`. It is a general type of the CPU. Common values might
	include `x86`, `arm` or `x86_64`. The second value is `cpu` which is a
	more specific subtype for the CPU. Typical values for a `x86` CPU
	family might include `i386` or `i586` and for `arm` family `armv5` or
	`armv7hl`. Note that CPU type strings are very system dependent. You
	might get a different value if you check its value on the same machine
	but with different operating systems.

	If you do not define your host machine, it is assumed to be the build
	machine. Similarly if you do not specify target machine, it is assumed
	to be the host machine.

	Additionally, you can define the paths that you want to install to in your
	cross file. This may be especially useful when cross compiling an entire
	operating system, or for operating systems to use internally for consistency.

	```ini
	[paths]
	prefix = '/my/prefix'
	libdir = 'lib/i386-linux-gnu'
	bindir = 'bin'
	```

	This will be overwritten by any options passed on the command line.


	## Starting a cross build


	Once you have the cross file, starting a build is simple

	```console
	$ meson srcdir builddir --cross-file cross_file.txt
	```

	Once configuration is done, compilation is started by invoking Ninja
	in the usual way.

	## Introspection and system checks

	The main meson object provides two functions to determine cross
	compilation status.

	```meson
	meson.is_cross_build() # returns true when cross compiling
	meson.has_exe_wrapper() # returns true if an exe wrapper has been defined
	```

	Note that the latter gives undefined return value when doing a native
	build.

	You can run system checks on both the system compiler or the cross
	compiler. You just have to specify which one to use.

	```meson
	build_compiler = meson.get_compiler('c', native : true)
	host_compiler = meson.get_compiler('c', native : false)

	build_int_size = build_compiler.sizeof('int')
	host_int_size = host_compiler.sizeof('int')
	```

	## Mixing host and build targets

	Sometimes you need to build a tool which is used to generate source
	files. These are then compiled for the actual target. For this you
	would want to build some targets with the system's native
	compiler. This requires only one extra keyword argument.

	```meson
	native_exe = executable('mygen', 'mygen.c', native : true)
	```

	You can then take `native_exe` and use it as part of a generator rule or anything else you might want.

	## Using a custom standard library

	Sometimes in cross compilation you need to build your own standard
	library instead of using the one provided by the compiler. Meson has
	built-in support for switching standard libraries transparently. The
	invocation to use in your cross file is the following:

	```ini
	[properties]
	c_stdlib = ['mylibc', 'mylibc_dep'] # Subproject name, dependency name
	```

	This specifies that C standard library is provided in the Meson
	subproject `mylibc` in internal dependency variable `mylibc_dep`. It
	is used on every cross built C target in the entire source tree
	(including subprojects) and the standard library is disabled. The
	build definitions of these targets do not need any modification.

	## Changing cross file settings

	Cross file settings are only read when the build directory is set up
	the first time. Any changes to them after the fact will be
	ignored. This is the same as regular compiles where you can't change
	the compiler once a build tree has been set up. If you need to edit
	your cross file, then you need to wipe your build tree and recreate it
	from scratch.

	## Custom data

	You can store arbitrary data in `properties` and access them from your
	Meson files. As an example if you cross file has this:

	```ini
	[properties]
	somekey = 'somevalue'
	```

	then you can access that using the `meson` object like this:

	```meson
	myvar = meson.get_cross_property('somekey')
	# myvar now has the value 'somevalue'
	```

	## Cross file locations

	As of version 0.44.0 meson supports loading cross files from system locations
	(except on Windows). This will be $XDG_DATA_DIRS/meson/cross, or if
	XDG_DATA_DIRS is undefined, then /usr/local/share/meson/cross and
	/usr/share/meson/cross will be tried in that order, for system wide cross
	files. User local files can be put in $XDG_DATA_HOME/meson/cross, or
	~/.local/share/meson/cross if that is undefined.

	The order of locations tried is as follows:
	- A file relative to the local dir
	- The user local location
	- The system wide locations in order

	Distributions are encouraged to ship cross files either with
	their cross compiler toolchain packages or as a standalone package, and put
	them in one of the system paths referenced above.

	These files can be loaded automatically without adding a path to the cross
	file. For example, if a ~/.local/share/meson/cross contains a file called x86-linux,
	then the following command would start a cross build using that cross files:

	```sh
	meson builddir/ --cross-file x86-linux
	```