| LLD - The LLVM Linker |
| ===================== |
| |
| LLD is a linker from the LLVM project. That is a drop-in replacement |
| for system linkers and runs much faster than them. It also provides |
| features that are useful for toolchain developers. |
| |
| The linker supports ELF (Unix), PE/COFF (Windows), Mach-O (macOS) and |
| WebAssembly in descending order of completeness. Internally, LLD consists of |
| several different linkers. The ELF port is the one that will be described in |
| this document. The PE/COFF port is complete, including |
| Windows debug info (PDB) support. The WebAssembly port is still a work in |
| progress (See :doc:`WebAssembly`). The Mach-O port is built based on a |
| different architecture than the others. For the details about Mach-O, please |
| read :doc:`AtomLLD`. |
| |
| Features |
| -------- |
| |
| - LLD is a drop-in replacement for the GNU linkers. That accepts the |
| same command line arguments and linker scripts as GNU. |
| |
| We are currently working closely with the FreeBSD project to make |
| LLD default system linker in future versions of the operating |
| system, so we are serious about addressing compatibility issues. As |
| of February 2017, LLD is able to link the entire FreeBSD/amd64 base |
| system including the kernel. With a few work-in-progress patches it |
| can link approximately 95% of the ports collection on AMD64. For the |
| details, see `FreeBSD quarterly status report |
| <https://www.freebsd.org/news/status/report-2016-10-2016-12.html#Using-LLVM%27s-LLD-Linker-as-FreeBSD%27s-System-Linker>`_. |
| |
| - LLD is very fast. When you link a large program on a multicore |
| machine, you can expect that LLD runs more than twice as fast as GNU |
| gold linker. Your milage may vary, though. |
| |
| - It supports various CPUs/ABIs including x86-64, x86, x32, AArch64, |
| ARM, MIPS 32/64 big/little-endian, PowerPC, PowerPC 64 and AMDGPU. |
| Among these, x86-64 is the most well-supported target and have |
| reached production quality. AArch64 and MIPS seem decent too. x86 |
| should be OK but not well tested yet. ARM support is being developed |
| actively. |
| |
| - It is always a cross-linker, meaning that it always supports all the |
| above targets however it was built. In fact, we don't provide a |
| build-time option to enable/disable each target. This should make it |
| easy to use our linker as part of a cross-compile toolchain. |
| |
| - You can embed LLD to your program to eliminate dependency to |
| external linkers. All you have to do is to construct object files |
| and command line arguments just like you would do to invoke an |
| external linker and then call the linker's main function, |
| ``lld::elf::link``, from your code. |
| |
| - It is small. We are using LLVM libObject library to read from object |
| files, so it is not completely a fair comparison, but as of February |
| 2017, LLD/ELF consists only of 21k lines of C++ code while GNU gold |
| consists of 198k lines of C++ code. |
| |
| - Link-time optimization (LTO) is supported by default. Essentially, |
| all you have to do to do LTO is to pass the ``-flto`` option to clang. |
| Then clang creates object files not in the native object file format |
| but in LLVM bitcode format. LLD reads bitcode object files, compile |
| them using LLVM and emit an output file. Because in this way LLD can |
| see the entire program, it can do the whole program optimization. |
| |
| - Some very old features for ancient Unix systems (pre-90s or even |
| before that) have been removed. Some default settings have been |
| tuned for the 21st century. For example, the stack is marked as |
| non-executable by default to tighten security. |
| |
| Performance |
| ----------- |
| |
| This is a link time comparison on a 2-socket 20-core 40-thread Xeon |
| E5-2680 2.80 GHz machine with an SSD drive. We ran gold and lld with |
| or without multi-threading support. To disable multi-threading, we |
| added ``-no-threads`` to the command lines. |
| |
| ============ =========== ============ ==================== ================== =============== ============= |
| Program Output size GNU ld GNU gold w/o threads GNU gold w/threads lld w/o threads lld w/threads |
| ffmpeg dbg 92 MiB 1.72s 1.16s 1.01s 0.60s 0.35s |
| mysqld dbg 154 MiB 8.50s 2.96s 2.68s 1.06s 0.68s |
| clang dbg 1.67 GiB 104.03s 34.18s 23.49s 14.82s 5.28s |
| chromium dbg 1.14 GiB 209.05s [1]_ 64.70s 60.82s 27.60s 16.70s |
| ============ =========== ============ ==================== ================== =============== ============= |
| |
| As you can see, lld is significantly faster than GNU linkers. |
| Note that this is just a benchmark result of our environment. |
| Depending on number of available cores, available amount of memory or |
| disk latency/throughput, your results may vary. |
| |
| .. [1] Since GNU ld doesn't support the ``-icf=all`` and |
| ``-gdb-index`` options, we removed them from the command line |
| for GNU ld. GNU ld would have been slower than this if it had |
| these options. |
| |
| Build |
| ----- |
| |
| If you have already checked out LLVM using SVN, you can check out LLD |
| under ``tools`` directory just like you probably did for clang. For the |
| details, see `Getting Started with the LLVM System |
| <http://llvm.org/docs/GettingStarted.html>`_. |
| |
| If you haven't checkout out LLVM, the easiest way to build LLD is to |
| checkout the entire LLVM projects/sub-projects from a git mirror and |
| build that tree. You need `cmake` and of course a C++ compiler. |
| |
| .. code-block:: console |
| |
| $ git clone https://github.com/llvm-project/llvm-project-20170507 llvm-project |
| $ mkdir build |
| $ cd build |
| $ cmake -DCMAKE_BUILD_TYPE=Release -DLLVM_ENABLE_PROJECTS=lld -DCMAKE_INSTALL_PREFIX=/usr/local ../llvm-project/llvm |
| $ make install |
| |
| Using LLD |
| --------- |
| |
| LLD is installed as ``ld.lld``. On Unix, linkers are invoked by |
| compiler drivers, so you are not expected to use that command |
| directly. There are a few ways to tell compiler drivers to use ld.lld |
| instead of the default linker. |
| |
| The easiest way to do that is to overwrite the default linker. After |
| installing LLD to somewhere on your disk, you can create a symbolic |
| link by doing ``ln -s /path/to/ld.lld /usr/bin/ld`` so that |
| ``/usr/bin/ld`` is resolved to LLD. |
| |
| If you don't want to change the system setting, you can use clang's |
| ``-fuse-ld`` option. In this way, you want to set ``-fuse-ld=lld`` to |
| LDFLAGS when building your programs. |
| |
| LLD leaves its name and version number to a ``.comment`` section in an |
| output. If you are in doubt whether you are successfully using LLD or |
| not, run ``readelf --string-dump .comment <output-file>`` and examine the |
| output. If the string "Linker: LLD" is included in the output, you are |
| using LLD. |
| |
| History |
| ------- |
| |
| Here is a brief project history of the ELF and COFF ports. |
| |
| - May 2015: We decided to rewrite the COFF linker and did that. |
| Noticed that the new linker is much faster than the MSVC linker. |
| |
| - July 2015: The new ELF port was developed based on the COFF linker |
| architecture. |
| |
| - September 2015: The first patches to support MIPS and AArch64 landed. |
| |
| - October 2015: Succeeded to self-host the ELF port. We have noticed |
| that the linker was faster than the GNU linkers, but we weren't sure |
| at the time if we would be able to keep the gap as we would add more |
| features to the linker. |
| |
| - July 2016: Started working on improving the linker script support. |
| |
| - December 2016: Succeeded to build the entire FreeBSD base system |
| including the kernel. We had widen the performance gap against the |
| GNU linkers. |
| |
| Internals |
| --------- |
| |
| For the internals of the linker, please read :doc:`NewLLD`. It is a bit |
| outdated but the fundamental concepts remain valid. We'll update the |
| document soon. |
| |
| .. toctree:: |
| :maxdepth: 1 |
| |
| NewLLD |
| AtomLLD |
| WebAssembly |
| windows_support |
| ReleaseNotes |
