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200 lines
7.0 KiB
ReStructuredText
200 lines
7.0 KiB
ReStructuredText
===================================
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How To Setup Clang Tooling For LLVM
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===================================
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Clang Tooling provides infrastructure to write tools that need syntactic
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and semantic information about a program. This term also relates to a set
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of specific tools using this infrastructure (e.g. ``clang-check``). This
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document provides information on how to set up and use Clang Tooling for
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the LLVM source code.
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Introduction
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============
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Clang Tooling needs a compilation database to figure out specific build
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options for each file. Currently it can create a compilation database
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from the ``compile_commands.json`` file, generated by CMake. When
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invoking clang tools, you can either specify a path to a build directory
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using a command line parameter ``-p`` or let Clang Tooling find this
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file in your source tree. In either case you need to configure your
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build using CMake to use clang tools.
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Setup Clang Tooling Using CMake and Make
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========================================
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If you intend to use make to build LLVM, you should have CMake 2.8.6 or
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later installed (can be found `here <https://cmake.org>`_).
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First, you need to generate Makefiles for LLVM with CMake. You need to
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make a build directory and run CMake from it:
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.. code-block:: console
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$ mkdir your/build/directory
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$ cd your/build/directory
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$ cmake -DCMAKE_EXPORT_COMPILE_COMMANDS=ON path/to/llvm/sources
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If you want to use clang instead of GCC, you can add
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``-DCMAKE_C_COMPILER=/path/to/clang -DCMAKE_CXX_COMPILER=/path/to/clang++``.
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You can also use ``ccmake``, which provides a curses interface to configure
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CMake variables for lazy people.
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As a result, the new ``compile_commands.json`` file should appear in the
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current directory. You should link it to the LLVM source tree so that
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Clang Tooling is able to use it:
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.. code-block:: console
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$ ln -s $PWD/compile_commands.json path/to/llvm/source/
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Now you are ready to build and test LLVM using make:
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.. code-block:: console
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$ make check-all
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Using Clang Tools
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=================
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After you completed the previous steps, you are ready to run clang tools. If
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you have a recent clang installed, you should have ``clang-check`` in
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``$PATH``. Try to run it on any ``.cpp`` file inside the LLVM source tree:
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.. code-block:: console
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$ clang-check tools/clang/lib/Tooling/CompilationDatabase.cpp
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If you're using vim, it's convenient to have clang-check integrated. Put
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this into your ``.vimrc``:
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::
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function! ClangCheckImpl(cmd)
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if &autowrite | wall | endif
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echo "Running " . a:cmd . " ..."
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let l:output = system(a:cmd)
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cexpr l:output
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cwindow
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let w:quickfix_title = a:cmd
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if v:shell_error != 0
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cc
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endif
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let g:clang_check_last_cmd = a:cmd
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endfunction
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function! ClangCheck()
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let l:filename = expand('%')
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if l:filename =~ '\.\(cpp\|cxx\|cc\|c\)$'
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call ClangCheckImpl("clang-check " . l:filename)
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elseif exists("g:clang_check_last_cmd")
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call ClangCheckImpl(g:clang_check_last_cmd)
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else
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echo "Can't detect file's compilation arguments and no previous clang-check invocation!"
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endif
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endfunction
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nmap <silent> <F5> :call ClangCheck()<CR><CR>
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When editing a .cpp/.cxx/.cc/.c file, hit F5 to reparse the file. In
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case the current file has a different extension (for example, .h), F5
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will re-run the last clang-check invocation made from this vim instance
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(if any). The output will go into the error window, which is opened
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automatically when clang-check finds errors, and can be re-opened with
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``:cope``.
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Other ``clang-check`` options that can be useful when working with clang
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AST:
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* ``-ast-print`` --- Build ASTs and then pretty-print them.
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* ``-ast-dump`` --- Build ASTs and then debug dump them.
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* ``-ast-dump-filter=<string>`` --- Use with ``-ast-dump`` or ``-ast-print`` to
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dump/print only AST declaration nodes having a certain substring in a
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qualified name. Use ``-ast-list`` to list all filterable declaration node
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names.
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* ``-ast-list`` --- Build ASTs and print the list of declaration node qualified
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names.
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Examples:
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.. code-block:: console
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$ clang-check tools/clang/tools/clang-check/ClangCheck.cpp -ast-dump -ast-dump-filter ActionFactory::newASTConsumer
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Processing: tools/clang/tools/clang-check/ClangCheck.cpp.
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Dumping ::ActionFactory::newASTConsumer:
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clang::ASTConsumer *newASTConsumer() (CompoundStmt 0x44da290 </home/alexfh/local/llvm/tools/clang/tools/clang-check/ClangCheck.cpp:64:40, line:72:3>
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(IfStmt 0x44d97c8 <line:65:5, line:66:45>
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<<<NULL>>>
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(ImplicitCastExpr 0x44d96d0 <line:65:9> '_Bool':'_Bool' <UserDefinedConversion>
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...
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$ clang-check tools/clang/tools/clang-check/ClangCheck.cpp -ast-print -ast-dump-filter ActionFactory::newASTConsumer
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Processing: tools/clang/tools/clang-check/ClangCheck.cpp.
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Printing <anonymous namespace>::ActionFactory::newASTConsumer:
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clang::ASTConsumer *newASTConsumer() {
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if (this->ASTList.operator _Bool())
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return clang::CreateASTDeclNodeLister();
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if (this->ASTDump.operator _Bool())
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return clang::CreateASTDumper(nullptr /*Dump to stdout.*/,
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this->ASTDumpFilter);
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if (this->ASTPrint.operator _Bool())
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return clang::CreateASTPrinter(&llvm::outs(), this->ASTDumpFilter);
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return new clang::ASTConsumer();
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}
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Using Ninja Build System
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=======================================
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Optionally you can use the `Ninja <https://github.com/martine/ninja>`_
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build system instead of make. It is aimed at making your builds faster.
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Currently this step will require building Ninja from sources.
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To take advantage of using Clang Tools along with Ninja build you need
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at least CMake 2.8.9.
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Clone the Ninja git repository and build Ninja from sources:
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.. code-block:: console
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$ git clone git://github.com/martine/ninja.git
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$ cd ninja/
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$ ./bootstrap.py
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This will result in a single binary ``ninja`` in the current directory.
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It doesn't require installation and can just be copied to any location
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inside ``$PATH``, say ``/usr/local/bin/``:
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.. code-block:: console
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$ sudo cp ninja /usr/local/bin/
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$ sudo chmod a+rx /usr/local/bin/ninja
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After doing all of this, you'll need to generate Ninja build files for
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LLVM with CMake. You need to make a build directory and run CMake from
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it:
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.. code-block:: console
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$ mkdir your/build/directory
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$ cd your/build/directory
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$ cmake -G Ninja -DCMAKE_EXPORT_COMPILE_COMMANDS=ON path/to/llvm/sources
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If you want to use clang instead of GCC, you can add
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``-DCMAKE_C_COMPILER=/path/to/clang -DCMAKE_CXX_COMPILER=/path/to/clang++``.
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You can also use ``ccmake``, which provides a curses interface to configure
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CMake variables in an interactive manner.
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As a result, the new ``compile_commands.json`` file should appear in the
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current directory. You should link it to the LLVM source tree so that
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Clang Tooling is able to use it:
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.. code-block:: console
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$ ln -s $PWD/compile_commands.json path/to/llvm/source/
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Now you are ready to build and test LLVM using Ninja:
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.. code-block:: console
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$ ninja check-all
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Other target names can be used in the same way as with make.
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