To start using musl, you have three choices.
This allows you to test and use musl on a glibc/uclibc system with no great effort. You cannot, however, use C++ with it.
When building musl, there are 3 important flags to pass to configure:
--prefix=<path>Where to install musl. A good choice is something like
--exec-prefix=<path>This is where the musl-gcc wrapper gets installed to. It should point to somewhere in your
PATH. A good choice is something like
--syslibdir=<path>This is where the dynamic linker gets installed into. The default is
/lib; this path will be baked into binaries built by musl-gcc, so you should not alter it if you want your dynamic binaries to be portable. Installing to
/libon most systems requires root privileges, so a typical choice for non-root users would be
You can omit shared library support (static linking only) and cut musl's build
time in half using
This configure run will generate a config.mak file, which contains your settings.
make && make install.
Now you can use
musl-gcc instead of
gcc to compile things against musl. Use
-static to build static binaries. For example, to compile a software package
that uses autoconf statically against musl:
CC="musl-gcc -static" ./configure --prefix=$HOME/musl && make
Use the pre-built cross compilers at musl-cross or built it yourself using the supplied scripts (git mirror). This gives you a full musl toolchain, including C+ support. Note that although the scripts are capable of building compilers targeting other architectures, a cross compiler targeting your host architecture with musl libc is also useful, as the whole toolchain is aware of its target libc.
There are three float modes available on modern ARM SoC's:
soft- floating point is completely emulated, very slow
softfp- uses hardware floating point, but is ABI compatible with soft
hard- complete hardware floating point, incompatible ABI with soft and softfp
On modern armv6 and armv7 chips, hardware floating point is usually implemented on chip. If someone is planing to compile musl-cross with hardware floating point, add the following to your config.sh:
ARCH=arm TRIPLE=arm-linux-musleabihf GCC_BOOTSTRAP_CONFFLAGS="--with-arch=armv7-a --with-float=hard --with-fpu=vfpv3-d16" GCC_CONFFLAGS="--with-arch=armv7-a --with-float=hard --with-fpu=vfpv3-d16"
This should produce a cross-toolchain that is compatible at least with: Marvell
Dove, Freescale i.MX5x, TI OMAP3+4, Qualcomm Snapdragon, nVidia Tegra2+3 and
probably all other modern Cortex-A8, Cortex-A9 and Cortex-A15 SoC's on the
market. If you plan to compile for older armv6 SoC's, like the one found on the
--with-arch=armv6-a --with-float=hard --with-fpu=vfpv2. VFPv3
contains the VFPv2 subset, so you can also use the armv6 binaries on a more
modern armv7 system, but losing some performance. On contrary, for Cortex-A15
SoC's like the new Samsung Exynos 5, you can activate the even more powerful
If your distro uses musl natively, then naturally, anything compiled on that distro will use musl. Several distros using musl, such as sabotage, are listed on the Projects using musl page of this wiki.
You can contribute to this wiki! Submit pull-requests to somasis/musl-wiki.
This work is licensed under a Creative Commons Attribution-ShareAlike 3.0 Unported license, unless otherwise noted.
Last edited by Kylie McClain, 2016-07-01 16:55:02