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    Date : 2019-06-23 21:36:31
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    Message : Import LLVM 8.0.0 release including clang, lld and lldb.

  • gnu/llvm/docs/GettingStarted.rst
  • ====================================
    Getting Started with the LLVM System
    ====================================
    
    .. contents::
       :local:
    
    Overview
    ========
    
    Welcome to the LLVM project! In order to get started, you first need to know
    some basic information.
    
    First, the LLVM project has multiple components. The core of the project is
    itself called "LLVM". This contains all of the tools, libraries, and header
    files needed to process an intermediate representation and convert it into
    object files.  It contains an assembler, disassembler, bitcode analyzer and
    bitcode optimizer.  It also contains basic regression tests.
    
    Another piece is the `Clang <http://clang.llvm.org/>`_ front end.  This
    component compiles C, C++, Objective C, and Objective C++ code into LLVM bitcode
    -- and from there into object files, using LLVM.
    
    There are other components as well:
    the `libc++ C++ standard library <https://libcxx.llvm.org>`_,
    the `LLD linker <https://lld.llvm.org>`_, and more.
    
    Getting Started Quickly (A Summary)
    ===================================
    
    The LLVM Getting Started documentation may be out of date.  So, the `Clang
    Getting Started <http://clang.llvm.org/get_started.html>`_ page might also be a
    good place to start.
    
    Here's the short story for getting up and running quickly with LLVM:
    
    #. Read the documentation.
    #. Read the documentation.
    #. Remember that you were warned twice about reading the documentation.
    
    #. Checkout LLVM (including related subprojects like Clang):
    
       * ``git clone https://github.com/llvm/llvm-project.git``
       * Or, on windows, ``git clone --config core.autocrlf=false
         https://github.com/llvm/llvm-project.git``
    
    #. Configure and build LLVM and Clang:.
    
       * ``cd llvm-project``
       * ``mkdir build``
       * ``cd build``
       * ``cmake -G <generator> [options] ../llvm``
    
         Some common generators are:
    
         * ``Ninja`` --- for generating `Ninja <https://ninja-build.org>`_
           build files. Most llvm developers use Ninja.
         * ``Unix Makefiles`` --- for generating make-compatible parallel makefiles.
         * ``Visual Studio`` --- for generating Visual Studio projects and
           solutions.
         * ``Xcode`` --- for generating Xcode projects.
    
         Some Common options:
    
         * ``-DLLVM_ENABLE_PROJECTS='...'`` --- semicolon-separated list of the LLVM
           subprojects you'd like to additionally build. Can include any of: clang,
           libcxx, libcxxabi, libunwind, lldb, compiler-rt, lld, polly, or
           debuginfo-tests.
    
           For example, to build LLVM, Clang, libcxx, and libcxxabi, use
           ``-DLLVM_ENABLE_PROJECTS="clang;libcxx;libcxxabi"``.
    
         * ``-DCMAKE_INSTALL_PREFIX=directory`` --- Specify for *directory* the full
           pathname of where you want the LLVM tools and libraries to be installed
           (default ``/usr/local``).
    
         * ``-DCMAKE_BUILD_TYPE=type`` --- Valid options for *type* are Debug,
           Release, RelWithDebInfo, and MinSizeRel. Default is Debug.
    
         * ``-DLLVM_ENABLE_ASSERTIONS=On`` --- Compile with assertion checks enabled
           (default is Yes for Debug builds, No for all other build types).
    
       * Run your build tool of choice!
    
         * The default target (i.e. ``ninja`` or ``make``) will build all of LLVM.
    
         * The ``check-all`` target (i.e. ``ninja check-all``) will run the
           regression tests to ensure everything is in working order.
    
         * CMake will generate build targets for each tool and library, and most
           LLVM sub-projects generate their own ``check-<project>`` target.
    
         * Running a serial build will be *slow*.  Make sure you run a parallel
           build. That's already done by default in Ninja; for ``make``, use
           ``make -j NNN`` (with an appropriate value of NNN, e.g. number of CPUs
           you have.)
    
       * For more information see `CMake <CMake.html>`_
    
       * If you get an "internal compiler error (ICE)" or test failures, see
         `below`_.
    
    Consult the `Getting Started with LLVM`_ section for detailed information on
    configuring and compiling LLVM.  Go to `Directory Layout`_ to learn about the
    layout of the source code tree.
    
    Requirements
    ============
    
    Before you begin to use the LLVM system, review the requirements given below.
    This may save you some trouble by knowing ahead of time what hardware and
    software you will need.
    
    Hardware
    --------
    
    LLVM is known to work on the following host platforms:
    
    ================== ===================== =============
    OS                 Arch                  Compilers
    ================== ===================== =============
    Linux              x86\ :sup:`1`         GCC, Clang
    Linux              amd64                 GCC, Clang
    Linux              ARM                   GCC, Clang
    Linux              PowerPC               GCC, Clang
    Solaris            V9 (Ultrasparc)       GCC
    FreeBSD            x86\ :sup:`1`         GCC, Clang
    FreeBSD            amd64                 GCC, Clang
    NetBSD             x86\ :sup:`1`         GCC, Clang
    NetBSD             amd64                 GCC, Clang
    MacOS X\ :sup:`2`  PowerPC               GCC
    MacOS X            x86                   GCC, Clang
    Cygwin/Win32       x86\ :sup:`1, 3`      GCC
    Windows            x86\ :sup:`1`         Visual Studio
    Windows x64        x86-64                Visual Studio
    ================== ===================== =============
    
    .. note::
    
      #. Code generation supported for Pentium processors and up
      #. Code generation supported for 32-bit ABI only
      #. To use LLVM modules on Win32-based system, you may configure LLVM
         with ``-DBUILD_SHARED_LIBS=On``.
    
    Note that Debug builds require a lot of time and disk space.  An LLVM-only build
    will need about 1-3 GB of space.  A full build of LLVM and Clang will need around
    15-20 GB of disk space.  The exact space requirements will vary by system.  (It
    is so large because of all the debugging information and the fact that the
    libraries are statically linked into multiple tools).
    
    If you are space-constrained, you can build only selected tools or only
    selected targets.  The Release build requires considerably less space.
    
    The LLVM suite *may* compile on other platforms, but it is not guaranteed to do
    so.  If compilation is successful, the LLVM utilities should be able to
    assemble, disassemble, analyze, and optimize LLVM bitcode.  Code generation
    should work as well, although the generated native code may not work on your
    platform.
    
    Software
    --------
    
    Compiling LLVM requires that you have several software packages installed. The
    table below lists those required packages. The Package column is the usual name
    for the software package that LLVM depends on. The Version column provides
    "known to work" versions of the package. The Notes column describes how LLVM
    uses the package and provides other details.
    
    =========================================================== ============ ==========================================
    Package                                                     Version      Notes
    =========================================================== ============ ==========================================
    `GNU Make <http://savannah.gnu.org/projects/make>`_         3.79, 3.79.1 Makefile/build processor
    `GCC <http://gcc.gnu.org/>`_                                >=5.1.0      C/C++ compiler\ :sup:`1`
    `python <http://www.python.org/>`_                          >=2.7        Automated test suite\ :sup:`2`
    `zlib <http://zlib.net>`_                                   >=1.2.3.4    Compression library\ :sup:`3`
    =========================================================== ============ ==========================================
    
    .. note::
    
       #. Only the C and C++ languages are needed so there's no need to build the
          other languages for LLVM's purposes. See `below` for specific version
          info.
       #. Only needed if you want to run the automated test suite in the
          ``llvm/test`` directory.
       #. Optional, adds compression / uncompression capabilities to selected LLVM
          tools.
    
    Additionally, your compilation host is expected to have the usual plethora of
    Unix utilities. Specifically:
    
    * **ar** --- archive library builder
    * **bzip2** --- bzip2 command for distribution generation
    * **bunzip2** --- bunzip2 command for distribution checking
    * **chmod** --- change permissions on a file
    * **cat** --- output concatenation utility
    * **cp** --- copy files
    * **date** --- print the current date/time
    * **echo** --- print to standard output
    * **egrep** --- extended regular expression search utility
    * **find** --- find files/dirs in a file system
    * **grep** --- regular expression search utility
    * **gzip** --- gzip command for distribution generation
    * **gunzip** --- gunzip command for distribution checking
    * **install** --- install directories/files
    * **mkdir** --- create a directory
    * **mv** --- move (rename) files
    * **ranlib** --- symbol table builder for archive libraries
    * **rm** --- remove (delete) files and directories
    * **sed** --- stream editor for transforming output
    * **sh** --- Bourne shell for make build scripts
    * **tar** --- tape archive for distribution generation
    * **test** --- test things in file system
    * **unzip** --- unzip command for distribution checking
    * **zip** --- zip command for distribution generation
    
    .. _below:
    .. _check here:
    
    Host C++ Toolchain, both Compiler and Standard Library
    ------------------------------------------------------
    
    LLVM is very demanding of the host C++ compiler, and as such tends to expose
    bugs in the compiler. We also attempt to follow improvements and developments in
    the C++ language and library reasonably closely. As such, we require a modern
    host C++ toolchain, both compiler and standard library, in order to build LLVM.
    
    LLVM is written using the subset of C++ documented in :doc:`coding
    standards<CodingStandards>`. To enforce this language version, we check the most
    popular host toolchains for specific minimum versions in our build systems:
    
    * Clang 3.5
    * Apple Clang 6.0
    * GCC 5.1
    * Visual Studio 2017
    
    The below versions currently soft-error as we transition to the new compiler
    versions listed above. The LLVM codebase is currently known to compile correctly
    with the following compilers, though this will change in the near future:
    
    * Clang 3.1
    * Apple Clang 3.1
    * GCC 4.8
    * Visual Studio 2015 (Update 3)
    
    Anything older than these toolchains *may* work, but will require forcing the
    build system with a special option and is not really a supported host platform.
    Also note that older versions of these compilers have often crashed or
    miscompiled LLVM.
    
    For less widely used host toolchains such as ICC or xlC, be aware that a very
    recent version may be required to support all of the C++ features used in LLVM.
    
    We track certain versions of software that are *known* to fail when used as
    part of the host toolchain. These even include linkers at times.
    
    **GNU ld 2.16.X**. Some 2.16.X versions of the ld linker will produce very long
    warning messages complaining that some "``.gnu.linkonce.t.*``" symbol was
    defined in a discarded section. You can safely ignore these messages as they are
    erroneous and the linkage is correct.  These messages disappear using ld 2.17.
    
    **GNU binutils 2.17**: Binutils 2.17 contains `a bug
    <http://sourceware.org/bugzilla/show_bug.cgi?id=3111>`__ which causes huge link
    times (minutes instead of seconds) when building LLVM.  We recommend upgrading
    to a newer version (2.17.50.0.4 or later).
    
    **GNU Binutils 2.19.1 Gold**: This version of Gold contained `a bug
    <http://sourceware.org/bugzilla/show_bug.cgi?id=9836>`__ which causes
    intermittent failures when building LLVM with position independent code.  The
    symptom is an error about cyclic dependencies.  We recommend upgrading to a
    newer version of Gold.
    
    Getting a Modern Host C++ Toolchain
    ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
    
    This section mostly applies to Linux and older BSDs. On Mac OS X, you should
    have a sufficiently modern Xcode, or you will likely need to upgrade until you
    do. Windows does not have a "system compiler", so you must install either Visual
    Studio 2015 or a recent version of mingw64. FreeBSD 10.0 and newer have a modern
    Clang as the system compiler.
    
    However, some Linux distributions and some other or older BSDs sometimes have
    extremely old versions of GCC. These steps attempt to help you upgrade you
    compiler even on such a system. However, if at all possible, we encourage you
    to use a recent version of a distribution with a modern system compiler that
    meets these requirements. Note that it is tempting to install a prior
    version of Clang and libc++ to be the host compiler, however libc++ was not
    well tested or set up to build on Linux until relatively recently. As
    a consequence, this guide suggests just using libstdc++ and a modern GCC as the
    initial host in a bootstrap, and then using Clang (and potentially libc++).
    
    The first step is to get a recent GCC toolchain installed. The most common
    distribution on which users have struggled with the version requirements is
    Ubuntu Precise, 12.04 LTS. For this distribution, one easy option is to install
    the `toolchain testing PPA`_ and use it to install a modern GCC. There is
    a really nice discussions of this on the `ask ubuntu stack exchange`_ and a
    `github gist`_ with updated commands. However, not all users can use PPAs and
    there are many other distributions, so it may be necessary (or just useful, if
    you're here you *are* doing compiler development after all) to build and install
    GCC from source. It is also quite easy to do these days.
    
    .. _toolchain testing PPA:
      https://launchpad.net/~ubuntu-toolchain-r/+archive/test
    .. _ask ubuntu stack exchange:
      https://askubuntu.com/questions/466651/how-do-i-use-the-latest-gcc-on-ubuntu/581497#58149
    .. _github gist:
      https://gist.github.com/application2000/73fd6f4bf1be6600a2cf9f56315a2d91
    
    Easy steps for installing GCC 5.1.0:
    
    .. code-block:: console
    
      % gcc_version=5.1.0
      % wget https://ftp.gnu.org/gnu/gcc/gcc-${gcc_version}/gcc-${gcc_version}.tar.bz2
      % wget https://ftp.gnu.org/gnu/gcc/gcc-${gcc_version}/gcc-${gcc_version}.tar.bz2.sig
      % wget https://ftp.gnu.org/gnu/gnu-keyring.gpg
      % signature_invalid=`gpg --verify --no-default-keyring --keyring ./gnu-keyring.gpg gcc-${gcc_version}.tar.bz2.sig`
      % if [ $signature_invalid ]; then echo "Invalid signature" ; exit 1 ; fi
      % tar -xvjf gcc-${gcc_version}.tar.bz2
      % cd gcc-${gcc_version}
      % ./contrib/download_prerequisites
      % cd ..
      % mkdir gcc-${gcc_version}-build
      % cd gcc-${gcc_version}-build
      % $PWD/../gcc-${gcc_version}/configure --prefix=$HOME/toolchains --enable-languages=c,c++
      % make -j$(nproc)
      % make install
    
    For more details, check out the excellent `GCC wiki entry`_, where I got most
    of this information from.
    
    .. _GCC wiki entry:
      https://gcc.gnu.org/wiki/InstallingGCC
    
    Once you have a GCC toolchain, configure your build of LLVM to use the new
    toolchain for your host compiler and C++ standard library. Because the new
    version of libstdc++ is not on the system library search path, you need to pass
    extra linker flags so that it can be found at link time (``-L``) and at runtime
    (``-rpath``). If you are using CMake, this invocation should produce working
    binaries:
    
    .. code-block:: console
    
      % mkdir build
      % cd build
      % CC=$HOME/toolchains/bin/gcc CXX=$HOME/toolchains/bin/g++ \
        cmake .. -DCMAKE_CXX_LINK_FLAGS="-Wl,-rpath,$HOME/toolchains/lib64 -L$HOME/toolchains/lib64"
    
    If you fail to set rpath, most LLVM binaries will fail on startup with a message
    from the loader similar to ``libstdc++.so.6: version `GLIBCXX_3.4.20' not
    found``. This means you need to tweak the -rpath linker flag.
    
    When you build Clang, you will need to give *it* access to modern C++
    standard library in order to use it as your new host in part of a bootstrap.
    There are two easy ways to do this, either build (and install) libc++ along
    with Clang and then use it with the ``-stdlib=libc++`` compile and link flag,
    or install Clang into the same prefix (``$HOME/toolchains`` above) as GCC.
    Clang will look within its own prefix for libstdc++ and use it if found. You
    can also add an explicit prefix for Clang to look in for a GCC toolchain with
    the ``--gcc-toolchain=/opt/my/gcc/prefix`` flag, passing it to both compile and
    link commands when using your just-built-Clang to bootstrap.
    
    .. _Getting Started with LLVM:
    
    Getting Started with LLVM
    =========================
    
    The remainder of this guide is meant to get you up and running with LLVM and to
    give you some basic information about the LLVM environment.
    
    The later sections of this guide describe the `general layout`_ of the LLVM
    source tree, a `simple example`_ using the LLVM tool chain, and `links`_ to find
    more information about LLVM or to get help via e-mail.
    
    Terminology and Notation
    ------------------------
    
    Throughout this manual, the following names are used to denote paths specific to
    the local system and working environment.  *These are not environment variables
    you need to set but just strings used in the rest of this document below*.  In
    any of the examples below, simply replace each of these names with the
    appropriate pathname on your local system.  All these paths are absolute:
    
    ``SRC_ROOT``
    
      This is the top level directory of the LLVM source tree.
    
    ``OBJ_ROOT``
    
      This is the top level directory of the LLVM object tree (i.e. the tree where
      object files and compiled programs will be placed.  It can be the same as
      SRC_ROOT).
    
    Unpacking the LLVM Archives
    ---------------------------
    
    If you have the LLVM distribution, you will need to unpack it before you can
    begin to compile it.  LLVM is distributed as a number of different
    subprojects. Each one has its own download which is a TAR archive that is
    compressed with the gzip program.
    
    The files are as follows, with *x.y* marking the version number:
    
    ``llvm-x.y.tar.gz``
    
      Source release for the LLVM libraries and tools.
    
    ``cfe-x.y.tar.gz``
    
      Source release for the Clang frontend.
    
    .. _checkout:
    
    Checkout LLVM from Git
    ----------------------
    
    You can also checkout the source code for LLVM from Git. While the LLVM
    project's official source-code repository is Subversion, we are in the process
    of migrating to git. We currently recommend that all developers use Git for
    day-to-day development.
    
    .. note::
    
      Passing ``--config core.autocrlf=false`` should not be required in
      the future after we adjust the .gitattribute settings correctly, but
      is required for Windows users at the time of this writing.
    
    Simply run:
    
    .. code-block:: console
    
      % git clone https://github.com/llvm/llvm-project.git`
    
    or on Windows,
    
    .. code-block:: console
    
      % git clone --config core.autocrlf=false https://github.com/llvm/llvm-project.git
    
    This will create an '``llvm-project``' directory in the current directory and
    fully populate it with all of the source code, test directories, and local
    copies of documentation files for LLVM and all the related subprojects. Note
    that unlike the tarballs, which contain each subproject in a separate file, the
    git repository contains all of the projects together.
    
    If you want to get a specific release (as opposed to the most recent revision),
    you can check out a tag after cloning the repository. E.g., `git checkout
    llvmorg-6.0.1` inside the ``llvm-project`` directory created by the above
    command.  Use `git tag -l` to list all of them.
    
    Sending patches
    ^^^^^^^^^^^^^^^
    
    Please read `Developer Policy <DeveloperPolicy.html#one-off-patches>`_, too.
    
    We don't currently accept github pull requests, so you'll need to send patches
    either via emailing to llvm-commits, or, preferably, via :ref:`Phabricator
    <phabricator-reviews>`.
    
    You'll generally want to make sure your branch has a single commit,
    corresponding to the review you wish to send, up-to-date with the upstream
    ``origin/master`` branch, and doesn't contain merges. Once you have that, you
    can use ``git show`` or ``git format-patch`` to output the diff, and attach it
    to a Phabricator review (or to an email message).
    
    However, using the "Arcanist" tool is often easier. After `installing
    arcanist`_, you can upload the latest commit using:
    
    .. code-block:: console
    
      % arc diff HEAD~1
    
    Additionally, before sending a patch for review, please also try to ensure it's
    formatted properly. We use ``clang-format`` for this, which has git integration
    through the ``git-clang-format`` script. On some systems, it may already be
    installed (or be installable via your package manager). If so, you can simply
    run it -- the following command will format only the code changed in the most
    recent commit:
    
    .. code-block:: console
    
      % git clang-format HEAD~1
    
    Note that this modifies the files, but doesn't commit them -- you'll likely want
    to run
    
    .. code-block:: console
    
      % git commit --amend -a
    
    in order to update the last commit with all pending changes.
    
    .. note::
      If you don't already have ``clang-format`` or ``git clang-format`` installed
      on your system, the ``clang-format`` binary will be built alongside clang, and
      the git integration can be run from
      ``clang/tools/clang-format/git-clang-format``.
    
    
    .. _commit_from_git:
    
    For developers to commit changes from Git
    ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
    
    A helper script is provided in ``llvm/utils/git-svn/git-llvm``. After you add it
    to your path, you can push committed changes upstream with ``git llvm
    push``. While this creates a Subversion checkout and patches it under the hood,
    it does not require you to have interaction with it.
    
    .. code-block:: console
    
      % export PATH=$PATH:$TOP_LEVEL_DIR/llvm-project/llvm/utils/git-svn/
      % git llvm push
    
    Within a couple minutes after pushing to subversion, the svn commit will have
    been converted back to a Git commit, and made its way into the official Git
    repository. At that point, ``git pull`` should get back the changes as they were
    committed.
    
    You'll likely want to ``git pull --rebase`` to get the official git commit
    downloaded back to your repository. The SVN revision numbers of each commit can
    be found at the end of the commit message, e.g. ``llvm-svn: 350914``.
    
    You may also find the ``-n`` flag useful, like ``git llvm push -n``. This runs
    through all the steps of committing _without_ actually doing the commit, and
    tell you what it would have done. That can be useful if you're unsure whether
    the right thing will happen.
    
    Checkout via SVN (deprecated)
    ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
    
    Until we have fully migrated to Git, you may also get a fresh copy of
    the code from the official Subversion repository.
    
    * ``cd where-you-want-llvm-to-live``
    * Read-Only: ``svn co http://llvm.org/svn/llvm-project/llvm/trunk llvm``
    * Read-Write: ``svn co https://user@llvm.org/svn/llvm-project/llvm/trunk llvm``
    
    This will create an '``llvm``' directory in the current directory and fully
    populate it with the LLVM source code, Makefiles, test directories, and local
    copies of documentation files.
    
    If you want to get a specific release (as opposed to the most recent revision),
    you can check it out from the '``tags``' directory (instead of '``trunk``'). The
    following releases are located in the following subdirectories of the '``tags``'
    directory:
    
    * Release 3.5.0 and later: **RELEASE_350/final** and so on
    * Release 2.9 through 3.4: **RELEASE_29/final** and so on
    * Release 1.1 through 2.8: **RELEASE_11** and so on
    * Release 1.0: **RELEASE_1**
    
    Local LLVM Configuration
    ------------------------
    
    Once checked out repository, the LLVM suite source code must be configured
    before being built. This process uses CMake.  Unlinke the normal ``configure``
    script, CMake generates the build files in whatever format you request as well
    as various ``*.inc`` files, and ``llvm/include/Config/config.h``.
    
    Variables are passed to ``cmake`` on the command line using the format
    ``-D<variable name>=<value>``. The following variables are some common options
    used by people developing LLVM.
    
    +-------------------------+----------------------------------------------------+
    | Variable                | Purpose                                            |
    +=========================+====================================================+
    | CMAKE_C_COMPILER        | Tells ``cmake`` which C compiler to use. By        |
    |                         | default, this will be /usr/bin/cc.                 |
    +-------------------------+----------------------------------------------------+
    | CMAKE_CXX_COMPILER      | Tells ``cmake`` which C++ compiler to use. By      |
    |                         | default, this will be /usr/bin/c++.                |
    +-------------------------+----------------------------------------------------+
    | CMAKE_BUILD_TYPE        | Tells ``cmake`` what type of build you are trying  |
    |                         | to generate files for. Valid options are Debug,    |
    |                         | Release, RelWithDebInfo, and MinSizeRel. Default   |
    |                         | is Debug.                                          |
    +-------------------------+----------------------------------------------------+
    | CMAKE_INSTALL_PREFIX    | Specifies the install directory to target when     |
    |                         | running the install action of the build files.     |
    +-------------------------+----------------------------------------------------+
    | LLVM_TARGETS_TO_BUILD   | A semicolon delimited list controlling which       |
    |                         | targets will be built and linked into llvm.        |
    |                         | The default list is defined as                     |
    |                         | ``LLVM_ALL_TARGETS``, and can be set to include    |
    |                         | out-of-tree targets. The default value includes:   |
    |                         | ``AArch64, AMDGPU, ARM, BPF, Hexagon, Mips,        |
    |                         | MSP430, NVPTX, PowerPC, Sparc, SystemZ, X86,       |
    |                         | XCore``.                                           |
    |                         |                                                    |
    +-------------------------+----------------------------------------------------+
    | LLVM_ENABLE_DOXYGEN     | Build doxygen-based documentation from the source  |
    |                         | code This is disabled by default because it is     |
    |                         | slow and generates a lot of output.                |
    +-------------------------+----------------------------------------------------+
    | LLVM_ENABLE_PROJECTS    | A semicolon-delimited list selecting which of the  |
    |                         | other LLVM subprojects to additionally build. (Only|
    |                         | effective when using a side-by-side project layout |
    |                         | e.g. via git). The default list is empty. Can      |
    |                         | include: clang, libcxx, libcxxabi, libunwind, lldb,|
    |                         | compiler-rt, lld, polly, or debuginfo-tests.       |
    +-------------------------+----------------------------------------------------+
    | LLVM_ENABLE_SPHINX      | Build sphinx-based documentation from the source   |
    |                         | code. This is disabled by default because it is    |
    |                         | slow and generates a lot of output. Sphinx version |
    |                         | 1.5 or later recommended.                          |
    +-------------------------+----------------------------------------------------+
    | LLVM_BUILD_LLVM_DYLIB   | Generate libLLVM.so. This library contains a       |
    |                         | default set of LLVM components that can be         |
    |                         | overridden with ``LLVM_DYLIB_COMPONENTS``. The     |
    |                         | default contains most of LLVM and is defined in    |
    |                         | ``tools/llvm-shlib/CMakelists.txt``.               |
    +-------------------------+----------------------------------------------------+
    | LLVM_OPTIMIZED_TABLEGEN | Builds a release tablegen that gets used during    |
    |                         | the LLVM build. This can dramatically speed up     |
    |                         | debug builds.                                      |
    +-------------------------+----------------------------------------------------+
    
    To configure LLVM, follow these steps:
    
    #. Change directory into the object root directory:
    
       .. code-block:: console
    
         % cd OBJ_ROOT
    
    #. Run the ``cmake``:
    
       .. code-block:: console
    
         % cmake -G "Unix Makefiles" -DCMAKE_INSTALL_PREFIX=/install/path
           [other options] SRC_ROOT
    
    Compiling the LLVM Suite Source Code
    ------------------------------------
    
    Unlike with autotools, with CMake your build type is defined at configuration.
    If you want to change your build type, you can re-run cmake with the following
    invocation:
    
       .. code-block:: console
    
         % cmake -G "Unix Makefiles" -DCMAKE_BUILD_TYPE=type SRC_ROOT
    
    Between runs, CMake preserves the values set for all options. CMake has the
    following build types defined:
    
    Debug
    
      These builds are the default. The build system will compile the tools and
      libraries unoptimized, with debugging information, and asserts enabled.
    
    Release
    
      For these builds, the build system will compile the tools and libraries
      with optimizations enabled and not generate debug info. CMakes default
      optimization level is -O3. This can be configured by setting the
      ``CMAKE_CXX_FLAGS_RELEASE`` variable on the CMake command line.
    
    RelWithDebInfo
    
      These builds are useful when debugging. They generate optimized binaries with
      debug information. CMakes default optimization level is -O2. This can be
      configured by setting the ``CMAKE_CXX_FLAGS_RELWITHDEBINFO`` variable on the
      CMake command line.
    
    Once you have LLVM configured, you can build it by entering the *OBJ_ROOT*
    directory and issuing the following command:
    
    .. code-block:: console
    
      % make
    
    If the build fails, please `check here`_ to see if you are using a version of
    GCC that is known not to compile LLVM.
    
    If you have multiple processors in your machine, you may wish to use some of the
    parallel build options provided by GNU Make.  For example, you could use the
    command:
    
    .. code-block:: console
    
      % make -j2
    
    There are several special targets which are useful when working with the LLVM
    source code:
    
    ``make clean``
    
      Removes all files generated by the build.  This includes object files,
      generated C/C++ files, libraries, and executables.
    
    ``make install``
    
      Installs LLVM header files, libraries, tools, and documentation in a hierarchy
      under ``$PREFIX``, specified with ``CMAKE_INSTALL_PREFIX``, which
      defaults to ``/usr/local``.
    
    ``make docs-llvm-html``
    
      If configured with ``-DLLVM_ENABLE_SPHINX=On``, this will generate a directory
      at ``OBJ_ROOT/docs/html`` which contains the HTML formatted documentation.
    
    Cross-Compiling LLVM
    --------------------
    
    It is possible to cross-compile LLVM itself. That is, you can create LLVM
    executables and libraries to be hosted on a platform different from the platform
    where they are built (a Canadian Cross build). To generate build files for
    cross-compiling CMake provides a variable ``CMAKE_TOOLCHAIN_FILE`` which can
    define compiler flags and variables used during the CMake test operations.
    
    The result of such a build is executables that are not runnable on the build
    host but can be executed on the target. As an example the following CMake
    invocation can generate build files targeting iOS. This will work on Mac OS X
    with the latest Xcode:
    
    .. code-block:: console
    
      % cmake -G "Ninja" -DCMAKE_OSX_ARCHITECTURES="armv7;armv7s;arm64"
        -DCMAKE_TOOLCHAIN_FILE=<PATH_TO_LLVM>/cmake/platforms/iOS.cmake
        -DCMAKE_BUILD_TYPE=Release -DLLVM_BUILD_RUNTIME=Off -DLLVM_INCLUDE_TESTS=Off
        -DLLVM_INCLUDE_EXAMPLES=Off -DLLVM_ENABLE_BACKTRACES=Off [options]
        <PATH_TO_LLVM>
    
    Note: There are some additional flags that need to be passed when building for
    iOS due to limitations in the iOS SDK.
    
    Check :doc:`HowToCrossCompileLLVM` and `Clang docs on how to cross-compile in general
    <http://clang.llvm.org/docs/CrossCompilation.html>`_ for more information
    about cross-compiling.
    
    The Location of LLVM Object Files
    ---------------------------------
    
    The LLVM build system is capable of sharing a single LLVM source tree among
    several LLVM builds.  Hence, it is possible to build LLVM for several different
    platforms or configurations using the same source tree.
    
    * Change directory to where the LLVM object files should live:
    
      .. code-block:: console
    
        % cd OBJ_ROOT
    
    * Run ``cmake``:
    
      .. code-block:: console
    
        % cmake -G "Unix Makefiles" SRC_ROOT
    
    The LLVM build will create a structure underneath *OBJ_ROOT* that matches the
    LLVM source tree. At each level where source files are present in the source
    tree there will be a corresponding ``CMakeFiles`` directory in the *OBJ_ROOT*.
    Underneath that directory there is another directory with a name ending in
    ``.dir`` under which you'll find object files for each source.
    
    For example:
    
      .. code-block:: console
    
        % cd llvm_build_dir
        % find lib/Support/ -name APFloat*
        lib/Support/CMakeFiles/LLVMSupport.dir/APFloat.cpp.o
    
    Optional Configuration Items
    ----------------------------
    
    If you're running on a Linux system that supports the `binfmt_misc
    <http://en.wikipedia.org/wiki/binfmt_misc>`_
    module, and you have root access on the system, you can set your system up to
    execute LLVM bitcode files directly. To do this, use commands like this (the
    first command may not be required if you are already using the module):
    
    .. code-block:: console
    
      % mount -t binfmt_misc none /proc/sys/fs/binfmt_misc
      % echo ':llvm:M::BC::/path/to/lli:' > /proc/sys/fs/binfmt_misc/register
      % chmod u+x hello.bc   (if needed)
      % ./hello.bc
    
    This allows you to execute LLVM bitcode files directly.  On Debian, you can also
    use this command instead of the 'echo' command above:
    
    .. code-block:: console
    
      % sudo update-binfmts --install llvm /path/to/lli --magic 'BC'
    
    .. _Program Layout:
    .. _general layout:
    
    Directory Layout
    ================
    
    One useful source of information about the LLVM source base is the LLVM `doxygen
    <http://www.doxygen.org/>`_ documentation available at
    `<http://llvm.org/doxygen/>`_.  The following is a brief introduction to code
    layout:
    
    ``llvm/examples``
    -----------------
    
    Simple examples using the LLVM IR and JIT.
    
    ``llvm/include``
    ----------------
    
    Public header files exported from the LLVM library. The three main subdirectories:
    
    ``llvm/include/llvm``
    
      All LLVM-specific header files, and  subdirectories for different portions of
      LLVM: ``Analysis``, ``CodeGen``, ``Target``, ``Transforms``, etc...
    
    ``llvm/include/llvm/Support``
    
      Generic support libraries provided with LLVM but not necessarily specific to
      LLVM. For example, some C++ STL utilities and a Command Line option processing
      library store header files here.
    
    ``llvm/include/llvm/Config``
    
      Header files configured by ``cmake``.  They wrap "standard" UNIX and
      C header files.  Source code can include these header files which
      automatically take care of the conditional #includes that ``cmake``
      generates.
    
    ``llvm/lib``
    ------------
    
    Most source files are here. By putting code in libraries, LLVM makes it easy to
    share code among the `tools`_.
    
    ``llvm/lib/IR/``
    
      Core LLVM source files that implement core classes like Instruction and
      BasicBlock.
    
    ``llvm/lib/AsmParser/``
    
      Source code for the LLVM assembly language parser library.
    
    ``llvm/lib/Bitcode/``
    
      Code for reading and writing bitcode.
    
    ``llvm/lib/Analysis/``
    
      A variety of program analyses, such as Call Graphs, Induction Variables,
      Natural Loop Identification, etc.
    
    ``llvm/lib/Transforms/``
    
      IR-to-IR program transformations, such as Aggressive Dead Code Elimination,
      Sparse Conditional Constant Propagation, Inlining, Loop Invariant Code Motion,
      Dead Global Elimination, and many others.
    
    ``llvm/lib/Target/``
    
      Files describing target architectures for code generation.  For example,
      ``llvm/lib/Target/X86`` holds the X86 machine description.
    
    ``llvm/lib/CodeGen/``
    
      The major parts of the code generator: Instruction Selector, Instruction
      Scheduling, and Register Allocation.
    
    ``llvm/lib/MC/``
    
      (FIXME: T.B.D.)  ....?
    
    ``llvm/lib/ExecutionEngine/``
    
      Libraries for directly executing bitcode at runtime in interpreted and
      JIT-compiled scenarios.
    
    ``llvm/lib/Support/``
    
      Source code that corresponding to the header files in ``llvm/include/ADT/``
      and ``llvm/include/Support/``.
    
    ``llvm/projects``
    -----------------
    
    Projects not strictly part of LLVM but shipped with LLVM. This is also the
    directory for creating your own LLVM-based projects which leverage the LLVM
    build system.
    
    ``llvm/test``
    -------------
    
    Feature and regression tests and other sanity checks on LLVM infrastructure. These
    are intended to run quickly and cover a lot of territory without being exhaustive.
    
    ``test-suite``
    --------------
    
    A comprehensive correctness, performance, and benchmarking test suite
    for LLVM.  This comes in a ``separate git repository
    <https://github.com/llvm/llvm-test-suite>``, because it contains a
    large amount of third-party code under a variety of licenses. For
    details see the :doc:`Testing Guide <TestingGuide>` document.
    
    .. _tools:
    
    ``llvm/tools``
    --------------
    
    Executables built out of the libraries
    above, which form the main part of the user interface.  You can always get help
    for a tool by typing ``tool_name -help``.  The following is a brief introduction
    to the most important tools.  More detailed information is in
    the `Command Guide <CommandGuide/index.html>`_.
    
    ``bugpoint``
    
      ``bugpoint`` is used to debug optimization passes or code generation backends
      by narrowing down the given test case to the minimum number of passes and/or
      instructions that still cause a problem, whether it is a crash or
      miscompilation. See `<HowToSubmitABug.html>`_ for more information on using
      ``bugpoint``.
    
    ``llvm-ar``
    
      The archiver produces an archive containing the given LLVM bitcode files,
      optionally with an index for faster lookup.
    
    ``llvm-as``
    
      The assembler transforms the human readable LLVM assembly to LLVM bitcode.
    
    ``llvm-dis``
    
      The disassembler transforms the LLVM bitcode to human readable LLVM assembly.
    
    ``llvm-link``
    
      ``llvm-link``, not surprisingly, links multiple LLVM modules into a single
      program.
    
    ``lli``
    
      ``lli`` is the LLVM interpreter, which can directly execute LLVM bitcode
      (although very slowly...). For architectures that support it (currently x86,
      Sparc, and PowerPC), by default, ``lli`` will function as a Just-In-Time
      compiler (if the functionality was compiled in), and will execute the code
      *much* faster than the interpreter.
    
    ``llc``
    
      ``llc`` is the LLVM backend compiler, which translates LLVM bitcode to a
      native code assembly file.
    
    ``opt``
    
      ``opt`` reads LLVM bitcode, applies a series of LLVM to LLVM transformations
      (which are specified on the command line), and outputs the resultant
      bitcode.   '``opt -help``'  is a good way to get a list of the
      program transformations available in LLVM.
    
      ``opt`` can also  run a specific analysis on an input LLVM bitcode
      file and print  the results.  Primarily useful for debugging
      analyses, or familiarizing yourself with what an analysis does.
    
    ``llvm/utils``
    --------------
    
    Utilities for working with LLVM source code; some are part of the build process
    because they are code generators for parts of the infrastructure.
    
    
    ``codegen-diff``
    
      ``codegen-diff`` finds differences between code that LLC
      generates and code that LLI generates. This is useful if you are
      debugging one of them, assuming that the other generates correct output. For
      the full user manual, run ```perldoc codegen-diff'``.
    
    ``emacs/``
    
       Emacs and XEmacs syntax highlighting  for LLVM   assembly files and TableGen
       description files.  See the ``README`` for information on using them.
    
    ``getsrcs.sh``
    
      Finds and outputs all non-generated source files,
      useful if one wishes to do a lot of development across directories
      and does not want to find each file. One way to use it is to run,
      for example: ``xemacs `utils/getsources.sh``` from the top of the LLVM source
      tree.
    
    ``llvmgrep``
    
      Performs an ``egrep -H -n`` on each source file in LLVM and
      passes to it a regular expression provided on ``llvmgrep``'s command
      line. This is an efficient way of searching the source base for a
      particular regular expression.
    
    ``TableGen/``
    
      Contains the tool used to generate register
      descriptions, instruction set descriptions, and even assemblers from common
      TableGen description files.
    
    ``vim/``
    
      vim syntax-highlighting for LLVM assembly files
      and TableGen description files. See the    ``README`` for how to use them.
    
    .. _simple example:
    
    An Example Using the LLVM Tool Chain
    ====================================
    
    This section gives an example of using LLVM with the Clang front end.
    
    Example with clang
    ------------------
    
    #. First, create a simple C file, name it 'hello.c':
    
       .. code-block:: c
    
         #include <stdio.h>
    
         int main() {
           printf("hello world\n");
           return 0;
         }
    
    #. Next, compile the C file into a native executable:
    
       .. code-block:: console
    
         % clang hello.c -o hello
    
       .. note::
    
         Clang works just like GCC by default.  The standard -S and -c arguments
         work as usual (producing a native .s or .o file, respectively).
    
    #. Next, compile the C file into an LLVM bitcode file:
    
       .. code-block:: console
    
         % clang -O3 -emit-llvm hello.c -c -o hello.bc
    
       The -emit-llvm option can be used with the -S or -c options to emit an LLVM
       ``.ll`` or ``.bc`` file (respectively) for the code.  This allows you to use
       the `standard LLVM tools <CommandGuide/index.html>`_ on the bitcode file.
    
    #. Run the program in both forms. To run the program, use:
    
       .. code-block:: console
    
          % ./hello
    
       and
    
       .. code-block:: console
    
         % lli hello.bc
    
       The second examples shows how to invoke the LLVM JIT, :doc:`lli
       <CommandGuide/lli>`.
    
    #. Use the ``llvm-dis`` utility to take a look at the LLVM assembly code:
    
       .. code-block:: console
    
         % llvm-dis < hello.bc | less
    
    #. Compile the program to native assembly using the LLC code generator:
    
       .. code-block:: console
    
         % llc hello.bc -o hello.s
    
    #. Assemble the native assembly language file into a program:
    
       .. code-block:: console
    
         % /opt/SUNWspro/bin/cc -xarch=v9 hello.s -o hello.native   # On Solaris
    
         % gcc hello.s -o hello.native                              # On others
    
    #. Execute the native code program:
    
       .. code-block:: console
    
         % ./hello.native
    
       Note that using clang to compile directly to native code (i.e. when the
       ``-emit-llvm`` option is not present) does steps 6/7/8 for you.
    
    Common Problems
    ===============
    
    If you are having problems building or using LLVM, or if you have any other
    general questions about LLVM, please consult the `Frequently Asked
    Questions <FAQ.html>`_ page.
    
    .. _links:
    
    Links
    =====
    
    This document is just an **introduction** on how to use LLVM to do some simple
    things... there are many more interesting and complicated things that you can do
    that aren't documented here (but we'll gladly accept a patch if you want to
    write something up!).  For more information about LLVM, check out:
    
    * `LLVM Homepage <http://llvm.org/>`_
    * `LLVM Doxygen Tree <http://llvm.org/doxygen/>`_
    * `Starting a Project that Uses LLVM <http://llvm.org/docs/Projects.html>`_
    
    .. _installing arcanist: https://secure.phabricator.com/book/phabricator/article/arcanist_quick_start/