llvm/docs/HowToBuildOnARM.rst - toolchain/llvm-project - Gitiles

 ===================================================================
 How To Build On ARM
 ===================================================================

 Introduction
 ============

 This document contains information about building/testing LLVM and
 Clang on an ARM machine.

 This document is *NOT* tailored to help you cross-compile LLVM/Clang
 to ARM on another architecture, for example an x86_64 machine. To find
 out more about cross-compiling, please check :doc:`HowToCrossCompileLLVM`.

 Notes On Building LLVM/Clang on ARM
 =====================================
 Here are some notes on building/testing LLVM/Clang on ARM. Note that
 ARM encompasses a wide variety of CPUs; this advice is primarily based
 on the ARMv6 and ARMv7 architectures and may be inapplicable to older chips.

 #. If you are building LLVM/Clang on an ARM board with 1G of memory or less,
    please use ``gold`` rather then GNU ``ld``.
    Building LLVM/Clang with ``--enable-optimized``
    is preferred since it consumes less memory. Otherwise, the building
    process will very likely fail due to insufficient memory. In any
    case it is probably a good idea to set up a swap partition.

 #. If you want to run ``make check-all`` after building LLVM/Clang, to avoid
    false alarms (e.g., ARCMT failure) please use at least the following
    configuration:

    .. code-block:: bash

      $ ../$LLVM_SRC_DIR/configure --with-abi=aapcs-vfp

 #. The most popular Linaro/Ubuntu OS's for ARM boards, e.g., the
    Pandaboard, have become hard-float platforms. The following set
    of configuration options appears to be a good choice for this
    platform:

    .. code-block:: bash

      ../$LLVM_SRC_DIR/configure --build=armv7l-unknown-linux-gnueabihf \
      --host=armv7l-unknown-linux-gnueabihf \
      --target=armv7l-unknown-linux-gnueabihf --with-cpu=cortex-a9 \
      --with-float=hard --with-abi=aapcs-vfp --with-fpu=neon \
      --enable-targets=arm --enable-optimized --enable-assertions

 #. ARM development boards can be unstable and you may experience that cores
    are disappearing, caches being flushed on every big.LITTLE switch, and
    other similar issues.  To help ease the effect of this, set the Linux
    scheduler to "performance" on **all** cores using this little script:

    .. code-block:: bash

       # The code below requires the package 'cpufrequtils' to be installed.
       for ((cpu=0; cpu<`grep -c proc /proc/cpuinfo`; cpu++)); do
           sudo cpufreq-set -c $cpu -g performance
       done

 #. Running the build on SD cards is ok, but they are more prone to failures
    than good quality USB sticks, and those are more prone to failures than
    external hard-drives (those are also a lot faster). So, at least, you
    should consider to buy a fast USB stick.  On systems with a fast eMMC,
    that's a good option too.

 #. Make sure you have a decent power supply (dozens of dollars worth) that can
    provide *at least* 4 amperes, this is especially important if you use USB
    devices with your board.
	===================================================================
	How To Build On ARM
	===================================================================

	Introduction
	============

	This document contains information about building/testing LLVM and
	Clang on an ARM machine.

	This document is NOT tailored to help you cross-compile LLVM/Clang
	to ARM on another architecture, for example an x86_64 machine. To find
	out more about cross-compiling, please check :doc:`HowToCrossCompileLLVM`.

	Notes On Building LLVM/Clang on ARM
	=====================================
	Here are some notes on building/testing LLVM/Clang on ARM. Note that
	ARM encompasses a wide variety of CPUs; this advice is primarily based
	on the ARMv6 and ARMv7 architectures and may be inapplicable to older chips.

	#. If you are building LLVM/Clang on an ARM board with 1G of memory or less,
	please use ``gold`` rather then GNU ``ld``.
	Building LLVM/Clang with ``--enable-optimized``
	is preferred since it consumes less memory. Otherwise, the building
	process will very likely fail due to insufficient memory. In any
	case it is probably a good idea to set up a swap partition.

	#. If you want to run ``make check-all`` after building LLVM/Clang, to avoid
	false alarms (e.g., ARCMT failure) please use at least the following
	configuration:

	.. code-block:: bash

	$ ../$LLVM_SRC_DIR/configure --with-abi=aapcs-vfp

	#. The most popular Linaro/Ubuntu OS's for ARM boards, e.g., the
	Pandaboard, have become hard-float platforms. The following set
	of configuration options appears to be a good choice for this
	platform:

	.. code-block:: bash

	../$LLVM_SRC_DIR/configure --build=armv7l-unknown-linux-gnueabihf \
	--host=armv7l-unknown-linux-gnueabihf \
	--target=armv7l-unknown-linux-gnueabihf --with-cpu=cortex-a9 \
	--with-float=hard --with-abi=aapcs-vfp --with-fpu=neon \
	--enable-targets=arm --enable-optimized --enable-assertions

	#. ARM development boards can be unstable and you may experience that cores
	are disappearing, caches being flushed on every big.LITTLE switch, and
	other similar issues. To help ease the effect of this, set the Linux
	scheduler to "performance" on all cores using this little script:

	.. code-block:: bash

	# The code below requires the package 'cpufrequtils' to be installed.
	for ((cpu=0; cpu<`grep -c proc /proc/cpuinfo`; cpu++)); do
	sudo cpufreq-set -c $cpu -g performance
	done

	#. Running the build on SD cards is ok, but they are more prone to failures
	than good quality USB sticks, and those are more prone to failures than
	external hard-drives (those are also a lot faster). So, at least, you
	should consider to buy a fast USB stick. On systems with a fast eMMC,
	that's a good option too.

	#. Make sure you have a decent power supply (dozens of dollars worth) that can
	provide at least 4 amperes, this is especially important if you use USB
	devices with your board.