=================== Clang-Include-Fixer

.. contents::

One of the major nuisances of C++ compared to other languages is the manual management of #include directives in any file. :program:clang-include-fixer addresses one aspect of this problem by providing an automated way of adding #include directives for missing symbols in one translation unit.

While inserting missing #include, :program:clang-include-fixer adds missing namespace qualifiers to all instances of an unidentified symbol if the symbol is missing some prefix namespace qualifiers.

Setup

To use :program:clang-include-fixer two databases are required. Both can be generated with existing tools.

Compilation database. Contains the compiler commands for any given file in a project and can be generated by CMake, see How To Setup Tooling For LLVM_.
Symbol index. Contains all symbol information in a project to match a given identifier to a header file.

Ideally both databases (compile_commands.json and find_all_symbols_db.yaml) are linked into the root of the source tree they correspond to. Then the :program:clang-include-fixer can automatically pick them up if called with a source file from that tree. Note that by default compile_commands.json as generated by CMake does not include header files, so only implementation files can be handled by tools.

.. _How To Setup Tooling For LLVM: https://clang.llvm.org/docs/HowToSetupToolingForLLVM.html

Creating a Symbol Index From a Compilation Database

The include fixer contains :program:find-all-symbols, a tool to create a symbol database in YAML format from a compilation database by parsing all source files listed in it. The following list of commands shows how to set up a database for LLVM, any project built by CMake should follow similar steps.

.. code-block:: console

$ cd path/to/llvm-build $ ninja find-all-symbols // build find-all-symbols tool. $ ninja clang-include-fixer // build clang-include-fixer tool. $ ls compile_commands.json # Make sure compile_commands.json exists. compile_commands.json $ path/to/llvm/source/clang-tools-extra/clang-include-fixer/find-all-symbols/tool/run-find-all-symbols.py ... wait as clang indexes the code base ... $ ln -s $PWD/find_all_symbols_db.yaml path/to/llvm/source/ # Link database into the source tree. $ ln -s $PWD/compile_commands.json path/to/llvm/source/ # Also link compilation database if it's not there already. $ cd path/to/llvm/source $ /path/to/clang-include-fixer -db=yaml path/to/file/with/missing/include.cpp Added #include "foo.h"

Integrate with Vim

To run clang-include-fixer on a potentially unsaved buffer in Vim. Add the following key binding to your .vimrc:

.. code-block:: console

noremap cf :pyf path/to/llvm/source/clang-tools-extra/clang-include-fixer/tool/clang-include-fixer.py

This enables clang-include-fixer for NORMAL and VISUAL mode. Change <leader>cf to another binding if you need clang-include-fixer on a different key. The <leader> key <http://vim.wikia.com/wiki/Mapping_keys_in_Vim_-_Tutorial_(Part_3)#Map_leader>_ is a reference to a specific key defined by the mapleader variable and is bound to backslash by default.

Make sure vim can find :program:clang-include-fixer:

Add the path to :program:clang-include-fixer to the PATH environment variable.
Or set g:clang_include_fixer_path in vimrc: let g:clang_include_fixer_path=path/to/clang-include-fixer

You can customize the number of headers being shown by setting let g:clang_include_fixer_maximum_suggested_headers=5

Customized settings in .vimrc:

let g:clang_include_fixer_path = "clang-include-fixer"

Set clang-include-fixer binary file path.
let g:clang_include_fixer_maximum_suggested_headers = 3

Set the maximum number of #includes to show. Default is 3.
let g:clang_include_fixer_increment_num = 5

Set the increment number of #includes to show every time when pressing m. Default is 5.
let g:clang_include_fixer_jump_to_include = 0

Set to 1 if you want to jump to the new inserted #include line. Default is 0.
let g:clang_include_fixer_query_mode = 0

Set to 1 if you want to insert #include for the symbol under the cursor. Default is 0. Compared to normal mode, this mode won't parse the source file and only search the symbol from database, which is faster than normal mode.

See clang-include-fixer.py for more details.

Integrate with Emacs

To run clang-include-fixer on a potentially unsaved buffer in Emacs. Ensure that Emacs finds clang-include-fixer.el by adding the directory containing the file to the load-path and requiring the clang-include-fixer in your .emacs:

.. code-block:: console

(add-to-list 'load-path "path/to/llvm/source/clang-tools-extra/clang-include-fixer/tool/" (require 'clang-include-fixer)

Within Emacs the tool can be invoked with the command M-x clang-include-fixer. This will insert the header that defines the first undefined symbol; if there is more than one header that would define the symbol, the user is prompted to select one.

To include the header that defines the symbol at point, run M-x clang-include-fixer-at-point.

Make sure Emacs can find :program:clang-include-fixer:

Either add the parent directory of :program:clang-include-fixer to the PATH environment variable, or customize the Emacs user option clang-include-fixer-executable to point to the file name of the program.

How it Works

To get the most information out of Clang at parse time, :program:clang-include-fixer runs in tandem with the parse and receives callbacks from Clang's semantic analysis. In particular it reuses the existing support for typo corrections. Whenever Clang tries to correct a potential typo it emits a callback to the include fixer which then looks for a corresponding file. At this point rich lookup information is still available, which is not available in the AST at a later stage.

The identifier that should be typo corrected is then sent to the database, if a header file is returned it is added as an include directive at the top of the file.

Currently :program:clang-include-fixer only inserts a single include at a time to avoid getting caught in follow-up errors. If multiple #include additions are desired the program can be rerun until a fix-point is reached.