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234 lines
8.7 KiB
ReStructuredText
234 lines
8.7 KiB
ReStructuredText
=======
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ThinLTO
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=======
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.. contents::
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:local:
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Introduction
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============
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*ThinLTO* compilation is a new type of LTO that is both scalable and
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incremental. *LTO* (Link Time Optimization) achieves better
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runtime performance through whole-program analysis and cross-module
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optimization. However, monolithic LTO implements this by merging all
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input into a single module, which is not scalable
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in time or memory, and also prevents fast incremental compiles.
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In ThinLTO mode, as with regular LTO, clang emits LLVM bitcode after the
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compile phase. The ThinLTO bitcode is augmented with a compact summary
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of the module. During the link step, only the summaries are read and
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merged into a combined summary index, which includes an index of function
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locations for later cross-module function importing. Fast and efficient
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whole-program analysis is then performed on the combined summary index.
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However, all transformations, including function importing, occur
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later when the modules are optimized in fully parallel backends.
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By default, linkers_ that support ThinLTO are set up to launch
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the ThinLTO backends in threads. So the usage model is not affected
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as the distinction between the fast serial thin link step and the backends
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is transparent to the user.
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For more information on the ThinLTO design and current performance,
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see the LLVM blog post `ThinLTO: Scalable and Incremental LTO
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<http://blog.llvm.org/2016/06/thinlto-scalable-and-incremental-lto.html>`_.
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While tuning is still in progress, results in the blog post show that
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ThinLTO already performs well compared to LTO, in many cases matching
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the performance improvement.
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Current Status
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==============
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Clang/LLVM
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----------
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.. _compiler:
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The 3.9 release of clang includes ThinLTO support. However, ThinLTO
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is under active development, and new features, improvements and bugfixes
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are being added for the next release. For the latest ThinLTO support,
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`build a recent version of clang and LLVM
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<https://llvm.org/docs/CMake.html>`_.
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Linkers
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-------
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.. _linkers:
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.. _linker:
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ThinLTO is currently supported for the following linkers:
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- **gold (via the gold-plugin)**:
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Similar to monolithic LTO, this requires using
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a `gold linker configured with plugins enabled
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<https://llvm.org/docs/GoldPlugin.html>`_.
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- **ld64**:
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Starting with `Xcode 8 <https://developer.apple.com/xcode/>`_.
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- **lld**:
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Starting with r284050 for ELF, r298942 for COFF.
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Usage
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=====
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Basic
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-----
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To utilize ThinLTO, simply add the -flto=thin option to compile and link. E.g.
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.. code-block:: console
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% clang -flto=thin -O2 file1.c file2.c -c
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% clang -flto=thin -O2 file1.o file2.o -o a.out
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When using lld-link, the -flto option need only be added to the compile step:
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.. code-block:: console
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% clang-cl -flto=thin -O2 -c file1.c file2.c
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% lld-link /out:a.exe file1.obj file2.obj
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As mentioned earlier, by default the linkers will launch the ThinLTO backend
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threads in parallel, passing the resulting native object files back to the
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linker for the final native link. As such, the usage model the same as
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non-LTO.
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With gold, if you see an error during the link of the form:
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.. code-block:: console
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/usr/bin/ld: error: /path/to/clang/bin/../lib/LLVMgold.so: could not load plugin library: /path/to/clang/bin/../lib/LLVMgold.so: cannot open shared object file: No such file or directory
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Then either gold was not configured with plugins enabled, or clang
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was not built with ``-DLLVM_BINUTILS_INCDIR`` set properly. See
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the instructions for the
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`LLVM gold plugin <https://llvm.org/docs/GoldPlugin.html#how-to-build-it>`_.
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Controlling Backend Parallelism
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-------------------------------
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.. _parallelism:
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By default, the ThinLTO link step will launch as many
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threads in parallel as there are cores. If the number of
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cores can't be computed for the architecture, then it will launch
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``std::thread::hardware_concurrency`` number of threads in parallel.
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For machines with hyper-threading, this is the total number of
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virtual cores. For some applications and machine configurations this
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may be too aggressive, in which case the amount of parallelism can
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be reduced to ``N`` via:
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- gold:
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``-Wl,-plugin-opt,jobs=N``
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- ld64:
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``-Wl,-mllvm,-threads=N``
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- lld:
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``-Wl,--thinlto-jobs=N``
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- lld-link:
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``/opt:lldltojobs=N``
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Incremental
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-----------
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.. _incremental:
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ThinLTO supports fast incremental builds through the use of a cache,
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which currently must be enabled through a linker option.
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- gold (as of LLVM 4.0):
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``-Wl,-plugin-opt,cache-dir=/path/to/cache``
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- ld64 (support in clang 3.9 and Xcode 8):
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``-Wl,-cache_path_lto,/path/to/cache``
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- ELF lld (as of LLVM 5.0):
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``-Wl,--thinlto-cache-dir=/path/to/cache``
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- COFF lld-link (as of LLVM 6.0):
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``/lldltocache:/path/to/cache``
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Cache Pruning
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-------------
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To help keep the size of the cache under control, ThinLTO supports cache
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pruning. Cache pruning is supported with gold, ld64 and ELF and COFF lld, but
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currently only gold, ELF and COFF lld allow you to control the policy with a
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policy string. The cache policy must be specified with a linker option.
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- gold (as of LLVM 6.0):
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``-Wl,-plugin-opt,cache-policy=POLICY``
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- ELF lld (as of LLVM 5.0):
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``-Wl,--thinlto-cache-policy,POLICY``
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- COFF lld-link (as of LLVM 6.0):
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``/lldltocachepolicy:POLICY``
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A policy string is a series of key-value pairs separated by ``:`` characters.
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Possible key-value pairs are:
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- ``cache_size=X%``: The maximum size for the cache directory is ``X`` percent
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of the available space on the disk. Set to 100 to indicate no limit,
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50 to indicate that the cache size will not be left over half the available
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disk space. A value over 100 is invalid. A value of 0 disables the percentage
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size-based pruning. The default is 75%.
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- ``cache_size_bytes=X``, ``cache_size_bytes=Xk``, ``cache_size_bytes=Xm``,
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``cache_size_bytes=Xg``:
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Sets the maximum size for the cache directory to ``X`` bytes (or KB, MB,
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GB respectively). A value over the amount of available space on the disk
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will be reduced to the amount of available space. A value of 0 disables
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the byte size-based pruning. The default is no byte size-based pruning.
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Note that ThinLTO will apply both size-based pruning policies simultaneously,
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and changing one does not affect the other. For example, a policy of
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``cache_size_bytes=1g`` on its own will cause both the 1GB and default 75%
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policies to be applied unless the default ``cache_size`` is overridden.
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- ``cache_size_files=X``:
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Set the maximum number of files in the cache directory. Set to 0 to indicate
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no limit. The default is 1000000 files.
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- ``prune_after=Xs``, ``prune_after=Xm``, ``prune_after=Xh``: Sets the
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expiration time for cache files to ``X`` seconds (or minutes, hours
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respectively). When a file hasn't been accessed for ``prune_after`` seconds,
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it is removed from the cache. A value of 0 disables the expiration-based
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pruning. The default is 1 week.
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- ``prune_interval=Xs``, ``prune_interval=Xm``, ``prune_interval=Xh``:
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Sets the pruning interval to ``X`` seconds (or minutes, hours
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respectively). This is intended to be used to avoid scanning the directory
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too often. It does not impact the decision of which files to prune. A
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value of 0 forces the scan to occur. The default is every 20 minutes.
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Clang Bootstrap
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---------------
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To bootstrap clang/LLVM with ThinLTO, follow these steps:
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1. The host compiler_ must be a version of clang that supports ThinLTO.
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#. The host linker_ must support ThinLTO (and in the case of gold, must be
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`configured with plugins enabled <https://llvm.org/docs/GoldPlugin.html>`_.
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#. Use the following additional `CMake variables
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<https://llvm.org/docs/CMake.html#options-and-variables>`_
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when configuring the bootstrap compiler build:
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* ``-DLLVM_ENABLE_LTO=Thin``
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* ``-DCMAKE_C_COMPILER=/path/to/host/clang``
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* ``-DCMAKE_CXX_COMPILER=/path/to/host/clang++``
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* ``-DCMAKE_RANLIB=/path/to/host/llvm-ranlib``
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* ``-DCMAKE_AR=/path/to/host/llvm-ar``
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Or, on Windows:
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* ``-DLLVM_ENABLE_LTO=Thin``
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* ``-DCMAKE_C_COMPILER=/path/to/host/clang-cl.exe``
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* ``-DCMAKE_CXX_COMPILER=/path/to/host/clang-cl.exe``
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* ``-DCMAKE_LINKER=/path/to/host/lld-link.exe``
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* ``-DCMAKE_RANLIB=/path/to/host/llvm-ranlib.exe``
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* ``-DCMAKE_AR=/path/to/host/llvm-ar.exe``
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#. To use additional linker arguments for controlling the backend
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parallelism_ or enabling incremental_ builds of the bootstrap compiler,
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after configuring the build, modify the resulting CMakeCache.txt file in the
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build directory. Specify any additional linker options after
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``CMAKE_EXE_LINKER_FLAGS:STRING=``. Note the configure may fail if
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linker plugin options are instead specified directly in the previous step.
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More Information
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================
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* From LLVM project blog:
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`ThinLTO: Scalable and Incremental LTO
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<http://blog.llvm.org/2016/06/thinlto-scalable-and-incremental-lto.html>`_
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