Compilation and Installation Using Meson¶
1. Introduction¶
For general information about Meson see the Meson website.
Mesa requires Meson >= 0.60.0 to build.
If your distribution doesn’t have something recent enough in its repositories, you can try the methods suggested here to install the current version of Meson.
The Meson build of Mesa is tested on Linux, macOS, Windows, Cygwin, Haiku, FreeBSD, DragonflyBSD, NetBSD, and should work on OpenBSD.
Unix-like OSes¶
If Meson is not already installed on your system, you can typically install it with your package installer. For example:
sudo apt-get install meson # Ubuntu
or
sudo dnf install meson # Fedora
Some older versions of Meson do not check that they are too old and will error out in odd ways.
You’ll also need Ninja. If it’s not already installed, use apt-get or dnf to install the ninja-build package.
Dependencies¶
Following are the dependencies you would need to install on linux to build and install mesa main. You can install these packages using your linux distibutions’ package manager.
All these dependencies are for latest linux distros and is tested on ubuntu-24 only for now.
Also note, some packages below might not be available in your OS with the exact name, in such case you can search for it and install the distribution specific one.
For some packages (eg: libclc etc), you will need the full content of the packages, so make sure to also install -dev
/-devel
/-headers
/etc. packages (if available) on distributions that split the files into multiple packages.
glslang-tools
python3-pyyaml
python3-mako
libdrm (This will get libdrm for intel, amd, qualcomm, nvidia, etc. If you are building a specific driver out of these, you can install only that specific libdrm)
libclc-<version>
llvm-<version>
libllvmspirvlib-<version>
libclang-<version>
byacc (or) bison
flex
You should make sure that all the llvm related packages (libclc, libclc-dev, llvm, libllvmspirvlib, libclang) are of the same version. You can go with the latest version available on your OS if you are not aware of which version to select.
wayland specific:
libwayland
libwayland-egl-backend
x11 specific:
libx11
libxext
libxfixes
libxcb-glx
libxcb-shm
libx11-xcb
libxcb-dri2
libxcb-dri3
libxcb-present
libxshmfence
libxxf86vm
libxrandr
for intel vulkan ray-tracing:
python3-ply
radeon specific:
libelf
nouveau/rusticl specific:
rustc
rustfmt
bindgen
cbindgen
Windows¶
You will need to install Python 3 and Meson as a module using pip. This is because we use Python for generating code, and rely on external modules (Mako). You also need pkg-config (a hard dependency of Meson), Flex, and Bison. The easiest way to install everything you need is with Chocolatey.
choco install python3 winflexbison pkgconfiglite
You can even use Chocolatey to install MinGW and Ninja (Ninja can be used with MSVC as well)
choco install ninja mingw
Then install Meson using pip
py -3 -m pip install meson packaging mako
You may need to add the Python 3 scripts directory to your path for Meson.
2. Basic Usage¶
The Meson program is used to configure the source directory and
generates either a Ninja build file or Visual Studio® build files. The
latter must be enabled via the --backend
switch, as Ninja is the
default backend on all operating systems.
Meson only supports out-of-tree builds, and must be passed a directory to put built and generated sources into. We’ll call that directory “build” here. It’s recommended to create a separate build directory for each configuration you might want to use.
Basic configuration is done with:
meson setup build/
This will create the build directory. If any dependencies are missing, you can install them, or try to remove the dependency with a Meson configuration option (see below). Meson will print a summary of the build options at the end.
To review the options which Meson chose, run:
meson configure build/
Recent version of Meson can print the available options and their
default values by running meson configure
in the source directory.
If your Meson version is too old, you can always look in the
meson_options.txt
file at the root of the project.
With additional arguments meson configure
can be used to change
options for a previously configured build directory. All options passed
to this command are in the form -D "option"="value"
. For example:
meson configure build/ -Dprefix=/tmp/install -Dglx=true
Note that options taking lists (such as platforms
) are a bit more
complicated,
but the simplest form compatible with Mesa options is to use a comma to
separate values (-D platforms=drm,wayland
) and brackets to represent
an empty list (-D platforms=[]
).
Once you’ve run the initial meson
command successfully you can use
your configured backend to build the project in your build directory:
ninja -C build/
The next step is to install the Mesa libraries, drivers, etc. This also finishes up some final steps of the build process (such as creating symbolic links for drivers). To install:
ninja -C build/ install
After installation, you can check if the installation happened properly or not by running the command:
glxinfo | grep OpenGL
If the installation succeeded, you should see the Mesa devel version and also the commit hash of the latest commit.
In case you don’t see the devel version, you can run
sudo ldconfig
Windows specific instructions¶
On Windows you have a couple of choices for compilers. If you installed MinGW with Chocolatey and want to use Ninja you should be able to open any shell and follow the instructions above. If you want to you MSVC, clang-cl, or ICL (the Intel Compiler), read on.
Both ICL and MSVC come with shell environments, the easiest way to use Meson with these it to open a shell. For clang-cl you will need to open an MSVC shell, and then override the compilers, either using a native file, or with the CC and CXX environment variables.
All of these compilers are tested and work with Ninja, but if you want
Visual Studio integration or you just like msbuild, passing
--backend=vs
to Meson will generate a Visual Studio solution.
3. Advanced Usage¶
Installation Location¶
Meson default to installing libGL.so
in your system’s main
lib/
directory and DRI drivers to a dri/
subdirectory.
Developers will often want to install Mesa to a testing directory rather than the system library directory. This can be done with the –prefix option. For example:
meson --prefix="${PWD}/build/install" build/
will put the final libraries and drivers into the build/install/ directory. Then you can set LD_LIBRARY_PATH to that location to run/test the driver.
Meson also honors DESTDIR
for installs.
Compiler Options¶
Meson supports the common CFLAGS, CXXFLAGS, etc. environment variables but their use is discouraged because of the many caveats in using them.
Instead, it is recommended to use -D${lang}_args
and
-D${lang}_link_args
. Among the benefits of these options is that
they are guaranteed to persist across rebuilds and reconfigurations.
This example sets -fmax-errors for compiling C sources and -DMAGIC=123 for C++ sources:
meson setup builddir/ -Dc_args=-fmax-errors=10 -Dcpp_args=-DMAGIC=123
Compiler Specification¶
Meson supports the standard CC and CXX environment variables for changing the default compiler. Note that Meson does not allow changing the compilers in a configured build directory so you will need to create a new build dir for a different compiler.
This is an example of specifying the Clang compilers and cleaning the build directory before reconfiguring with an extra C option:
CC=clang CXX=clang++ meson setup build-clang
ninja -C build-clang
ninja -C build-clang clean
meson configure build -Dc_args="-Wno-typedef-redefinition"
ninja -C build-clang
The default compilers depends on your operating system. Meson supports most of the popular compilers, a complete list is available here.
LLVM¶
Meson includes upstream logic to wrap llvm-config using its standard dependency interface.
Meson can use CMake to find LLVM. But due to the way LLVM implements its
CMake finder it will only find static libraries, it will never find
libllvm.so
. There is also a -Dcmake_module_path
option,
which points to the root of an alternative installation (the prefix).
For example:
meson setup builddir -Dcmake_module_path=/home/user/mycmake/prefix
As of Meson 0.49.0 Meson also has the concept of a “native file”, these files provide information about the native build environment (as opposed to a cross build environment). They are INI formatted and can override where to find llvm-config:
[binaries]
llvm-config = '/usr/local/bin/llvm/llvm-config'
Then configure Meson:
meson setup builddir/ --native-file custom-llvm.ini
For selecting llvm-config for cross compiling a “cross file” should be used. It uses the same format as the native file above:
[binaries]
...
llvm-config = '/usr/lib/llvm-config-32'
cmake = '/usr/bin/cmake-for-my-arch'
Obviously, only CMake or llvm-config is required.
Then configure Meson:
meson setup builddir/ --cross-file cross-llvm.ini
See the Cross Compilation section for more information.
On Windows (and in other cases), using llvm-config or CMake may be either undesirable or impossible. Meson’s solution for this is a wrap, in this case a “binary wrap”. Follow the steps below:
Install the binaries and headers into the
$mesa_src/subprojects/llvm
Add a
meson.build
file to that directory (more on that later)
The wrap file must define the following:
dep_llvm
: adeclare_dependency()
object with include_directories, dependencies, and version set)
It may also define:
irbuilder_h
: afiles()
object pointing to llvm/IR/IRBuilder.hhas_rtti
: abool
that declares whether LLVM was built with RTTI. Defaults to true
such a meson.build
file might look like:
project('llvm', ['cpp'])
cpp = meson.get_compiler('cpp')
_deps = []
_search = join_paths(meson.current_source_dir(), 'lib')
foreach d : ['libLLVMCodeGen', 'libLLVMScalarOpts', 'libLLVMAnalysis',
'libLLVMTransformUtils', 'libLLVMCore', 'libLLVMX86CodeGen',
'libLLVMSelectionDAG', 'libLLVMipo', 'libLLVMAsmPrinter',
'libLLVMInstCombine', 'libLLVMInstrumentation', 'libLLVMMC',
'libLLVMGlobalISel', 'libLLVMObjectYAML', 'libLLVMDebugInfoPDB',
'libLLVMVectorize', 'libLLVMPasses', 'libLLVMSupport',
'libLLVMLTO', 'libLLVMObject', 'libLLVMDebugInfoCodeView',
'libLLVMDebugInfoDWARF', 'libLLVMOrcJIT', 'libLLVMProfileData',
'libLLVMObjCARCOpts', 'libLLVMBitReader', 'libLLVMCoroutines',
'libLLVMBitWriter', 'libLLVMRuntimeDyld', 'libLLVMMIRParser',
'libLLVMX86Desc', 'libLLVMAsmParser', 'libLLVMTableGen',
'libLLVMFuzzMutate', 'libLLVMLinker', 'libLLVMMCParser',
'libLLVMExecutionEngine', 'libLLVMCoverage', 'libLLVMInterpreter',
'libLLVMTarget', 'libLLVMX86AsmParser', 'libLLVMSymbolize',
'libLLVMDebugInfoMSF', 'libLLVMMCJIT', 'libLLVMXRay',
'libLLVMX86AsmPrinter', 'libLLVMX86Disassembler',
'libLLVMMCDisassembler', 'libLLVMOption', 'libLLVMIRReader',
'libLLVMLibDriver', 'libLLVMDlltoolDriver', 'libLLVMDemangle',
'libLLVMBinaryFormat', 'libLLVMLineEditor',
'libLLVMWindowsManifest', 'libLLVMX86Info', 'libLLVMX86Utils']
_deps += cpp.find_library(d, dirs : _search)
endforeach
dep_llvm = declare_dependency(
include_directories : include_directories('include'),
dependencies : _deps,
version : '6.0.0',
)
has_rtti = false
irbuilder_h = files('include/llvm/IR/IRBuilder.h')
It is very important that version is defined and is accurate, if it is not, workarounds for the wrong version of LLVM might be used resulting in build failures.
PKG_CONFIG_PATH
¶
The pkg-config
utility is a hard requirement for configuring and
building Mesa on Unix-like systems. It is used to search for external
libraries on the system. This environment variable is used to control
the search path for pkg-config
. For instance, setting
PKG_CONFIG_PATH=/usr/X11R6/lib/pkgconfig
will search for package
metadata in /usr/X11R6
before the standard directories.
Options¶
One of the oddities of Meson is that some options are different when
passed to meson than to meson configure
. These options are
passed as –option=foo to meson, but -Doption=foo to
meson configure
. Mesa defined options are always passed as
-Doption=foo.
For those coming from Autotools be aware of the following:
--buildtype/-Dbuildtype
This option will set the compiler debug/optimization levels to aid debugging the Mesa libraries.
Note that in Meson this defaults to
debugoptimized
, and not setting it torelease
will yield non-optimal performance and binary size. Not usingdebug
may interfere with debugging as some code and validation will be optimized away.For those wishing to pass their own optimization flags, use the
plain
buildtype, which causes Meson to inject no additional compiler arguments, only those in the C/CXXFLAGS and those that mesa itself defines.-Db_ndebug
This option controls assertions in Meson projects. When set to
false
(the default) assertions are enabled, when set to true they are disabled. This is unrelated to thebuildtype
; setting the latter torelease
will not turn off assertions.
4. Cross-compilation and 32-bit builds¶
Meson supports
cross-compilation by
specifying a number of binary paths and settings in a file and passing
this file to meson
or meson configure
with the --cross-file
parameter.
This file can live at any location, but you can use the bare filename
(without the folder path) if you put it in
$XDG_DATA_HOME/meson/cross
or ~/.local/share/meson/cross
Below are a few example of cross files, but keep in mind that you will likely have to alter them for your system.
Those running on Arch Linux can use the AUR-maintained packages for some of those, as they’ll have the right values for your system:
32-bit build on x86 linux:
[binaries]
c = '/usr/bin/gcc'
cpp = '/usr/bin/g++'
ar = '/usr/bin/gcc-ar'
strip = '/usr/bin/strip'
pkg-config = '/usr/bin/pkg-config-32'
llvm-config = '/usr/bin/llvm-config32'
[properties]
c_args = ['-m32']
c_link_args = ['-m32']
cpp_args = ['-m32']
cpp_link_args = ['-m32']
[host_machine]
system = 'linux'
cpu_family = 'x86'
cpu = 'i686'
endian = 'little'
64-bit build on ARM linux:
[binaries]
c = '/usr/bin/aarch64-linux-gnu-gcc'
cpp = '/usr/bin/aarch64-linux-gnu-g++'
ar = '/usr/bin/aarch64-linux-gnu-gcc-ar'
strip = '/usr/bin/aarch64-linux-gnu-strip'
pkg-config = '/usr/bin/aarch64-linux-gnu-pkg-config'
exe_wrapper = '/usr/bin/qemu-aarch64-static'
[host_machine]
system = 'linux'
cpu_family = 'aarch64'
cpu = 'aarch64'
endian = 'little'
64-bit build on x86 Windows:
[binaries]
c = '/usr/bin/x86_64-w64-mingw32-gcc'
cpp = '/usr/bin/x86_64-w64-mingw32-g++'
ar = '/usr/bin/x86_64-w64-mingw32-ar'
strip = '/usr/bin/x86_64-w64-mingw32-strip'
pkg-config = '/usr/bin/x86_64-w64-mingw32-pkg-config'
exe_wrapper = 'wine'
[host_machine]
system = 'windows'
cpu_family = 'x86_64'
cpu = 'i686'
endian = 'little'