Looking for help, advice or support? Having problems getting YCM to work?
First carefully read the installation instructions for your OS.
We recommend you use the supplied install.py
- the "full" installation guide
is for rare, advanced use cases and most users should use install.py
.
If the server isn't starting and you're getting a "YouCompleteMe unavailable" error, check the Troubleshooting guide.
Next check the User Guide section on the semantic completer that you are using. For C/C++/Objective-C/Objective-C++/CUDA, you must read this section.
Finally, check the FAQ.
If, after reading the installation and user guides, and checking the FAQ, you're still having trouble, check the contacts section below for how to get in touch.
Please do NOT go to #vim on Freenode for support. Please contact the YouCompleteMe maintainers directly using the contact details below.
- Intro
- Installation
- Quick Feature Summary
- User Guide
- General Usage
- Client-Server Architecture
- Completion String Ranking
- General Semantic Completion
- Signature Help
- Semantic Highlighting
- Inlay Hints
- C-family Semantic Completion
- Java Semantic Completion
- C# Semantic Completion
- Python Semantic Completion
- Rust Semantic Completion
- Go Semantic Completion
- JavaScript and TypeScript Semantic Completion
- Semantic Completion for Other Languages
- LSP Configuration
- Writing New Semantic Completers
- Diagnostic Display
- Symbol Search
- Commands
- Functions
- Autocommands
- Options
- FAQ
- Contributor Code of Conduct
- Contact
- License
- Sponsorship
YouCompleteMe is a fast, as-you-type, fuzzy-search code completion, comprehension and refactoring engine for Vim.
It has several completion engines built in and supports any protocol-compliant Language Server, so can work with practically any language. YouCompleteMe contains:
- an identifier-based engine that works with every programming language,
- a powerful clangd-based engine that provides native semantic code completion for C/C++/Objective-C/Objective-C++/CUDA (from now on referred to as "the C-family languages"),
- a Jedi-based completion engine for Python 2 and 3,
- an OmniSharp-Roslyn-based completion engine for C#,
- a Gopls-based completion engine for Go,
- a TSServer-based completion engine for JavaScript and TypeScript,
- a rust-analyzer-based completion engine for Rust,
- a jdt.ls-based completion engine for Java.
- a generic Language Server Protocol implementation for any language
- and an omnifunc-based completer that uses data from Vim's omnicomplete system to provide semantic completions for many other languages (Ruby, PHP etc.).
Here's an explanation of what happens in the last GIF demo above.
First, realize that no keyboard shortcuts had to be pressed to get the list of completion candidates at any point in the demo. The user just types and the suggestions pop up by themselves. If the user doesn't find the completion suggestions relevant and/or just wants to type, they can do so; the completion engine will not interfere.
When the user sees a useful completion string being offered, they press the TAB key to accept it. This inserts the completion string. Repeated presses of the TAB key cycle through the offered completions.
If the offered completions are not relevant enough, the user can continue typing to further filter out unwanted completions.
A critical thing to notice is that the completion filtering is NOT based on
the input being a string prefix of the completion (but that works too). The
input needs to be a subsequence match of a completion. This is a fancy way
of saying that any input characters need to be present in a completion string in
the order in which they appear in the input. So abc
is a subsequence of
xaybgc
, but not of xbyxaxxc
. After the filter, a complicated sorting system
ranks the completion strings so that the most relevant ones rise to the top of
the menu (so you usually need to press TAB just once).
All of the above works with any programming language because of the identifier-based completion engine. It collects all of the identifiers in the current file and other files you visit (and your tags files) and searches them when you type (identifiers are put into per-filetype groups).
The demo also shows the semantic engine in use. When the user presses .
, ->
or ::
while typing in insert mode (for C++; different triggers are used for
other languages), the semantic engine is triggered (it can also be triggered
with a keyboard shortcut; see the rest of the docs).
The last thing that you can see in the demo is YCM's diagnostic display features (the little red X that shows up in the left gutter; inspired by Syntastic) if you are editing a C-family file. As the completer engine compiles your file and detects warnings or errors, they will be presented in various ways. You don't need to save your file or press any keyboard shortcut to trigger this, it "just happens" in the background.
And that's not all...
YCM might be the only vim completion engine with the correct Unicode support. Though we do assume UTF-8 everywhere.
YCM also provides semantic IDE-like features in a number of languages, including:
- displaying signature help (argument hints) when entering the arguments to a function call (Vim only)
- finding declarations, definitions, usages, etc. of identifiers, and an interactive symbol finder
- displaying type information for classes, variables, functions etc.,
- displaying documentation for methods, members, etc. in the preview window, or in a popup next to the cursor (Vim only)
- fixing common coding errors, like missing semi-colons, typos, etc.,
- semantic renaming of variables across files,
- formatting code,
- removing unused imports, sorting imports, etc.
For example, here's a demo of signature help:
Below we can see YCM being able to do a few things:
- Retrieve references across files
- Go to declaration/definition
- Expand
auto
in C++ - Fix some common errors with
FixIt
- Not shown in the GIF is
GoToImplementation
andGoToType
for servers that support it.
And here's some documentation being shown in a hover popup, automatically and manually:
Features vary by file type, so make sure to check out the file type feature summary and the full list of completer subcommands to find out what's available for your favourite languages.
You'll also find that YCM has filepath completers (try typing ./
in a file)
and a completer that integrates with UltiSnips.
Our policy is to support the Vim version that's in the latest LTS of Ubuntu.
That's currently Ubuntu 20.04 which contains vim-nox
at v8.1.2269
.
Vim must have a working Python 3.6 runtime, compiled with --enable-shared
(or
--enable-framework
). You can check with :py3 import sys; print( sys.version )
.
For Neovim users, our policy is to require the latest released version. Currently, Neovim 0.5.0 is required. Please note that some features are not available in Neovim, and Neovim is not officially supported.
In order to provide the best possible performance and stability, ycmd has updated its code to C++17. This requires a version bump of the minimum supported compilers. The new requirements are:
Compiler | Current Min |
---|---|
GCC | 8 |
Clang | 7 |
MSVC | 15.7 (VS 2017) |
YCM requires CMake 3.13 or greater. If your CMake is too old, you may be able to
simply pip install --user cmake
to get a really new version.
When enabling language support for a particular language, there may be runtime requirements, such as needing a very recent Java Development Kit for Java support. In general, YCM is not in control of the required versions for the downstream compilers, though we do our best to signal where we know them.
- Install YCM plugin via Vundle
- Install CMake, MacVim and Python 3; Note that the pre-installed macOS system vim is not supported (due to it having broken Python integration).
$ brew install cmake python go nodejs
-
Install mono from Mono Project (NOTE: on Intel Macs you can also
brew install mono
. On arm Macs, you may require Rosetta) -
For java support you must install a JDK, one way to do this is with Homebrew:
$ brew install java
$ sudo ln -sfn $(brew --prefix java)/libexec/openjdk.jdk /Library/Java/JavaVirtualMachines/openjdk.jdk
-
Pre-installed macOS system Vim does not support Python 3. So you need to install either a Vim that supports Python 3 OR MacVim with Homebrew:
- Option 1: Installing a Vim that supports Python 3
brew install vim
- Option 2: Installing MacVim
brew install macvim
-
Compile YCM.
-
For Intel and arm64 Macs, the bundled libclang/clangd work:
cd ~/.vim/bundle/YouCompleteMe python3 install.py --all
-
If you have troubles with finding system frameworks or C++ standard library, try using the homebrew llvm:
brew install llvm cd ~/.vim/bundle/YouCompleteMe python3 install.py --system-libclang --all
And edit your vimrc to add the following line to use the Homebrew llvm's clangd:
" Use homebrew's clangd let g:ycm_clangd_binary_path = trim(system('brew --prefix llvm')).'/bin/clangd'
-
-
For using an arbitrary LSP server, check the relevant section
These instructions (using install.py
) are the quickest way to install
YouCompleteMe, however they may not work for everyone. If the following
instructions don't work for you, check out the full installation
guide.
A supported Vim version with Python 3 is required. MacVim is a good option, even if you only use the terminal. YCM won't work with the pre-installed Vim from Apple as its Python support is broken. If you don't already use a Vim that supports Python 3 or MacVim, install it with Homebrew. Install CMake as well:
brew install vim cmake
OR
brew install macvim cmake
Install YouCompleteMe with Vundle.
Remember: YCM is a plugin with a compiled component. If you update YCM
using Vundle and the ycm_core
library APIs have changed (happens
rarely), YCM will notify you to recompile it. You should then rerun the install
process.
NOTE: If you want C-family completion, you MUST have the latest Xcode
installed along with the latest Command Line Tools (they are installed
automatically when you run clang
for the first time, or manually by running
xcode-select --install
)
Compiling YCM with semantic support for C-family languages through clangd:
cd ~/.vim/bundle/YouCompleteMe
./install.py --clangd-completer
Compiling YCM without semantic support for C-family languages:
cd ~/.vim/bundle/YouCompleteMe
./install.py
The following additional language support options are available:
- C# support: install by downloading the Mono macOS package
and add
--cs-completer
when callinginstall.py
. - Go support: install Go and add
--go-completer
when callinginstall.py
. - JavaScript and TypeScript support: install Node.js and npm and
add
--ts-completer
when callinginstall.py
. - Rust support: add
--rust-completer
when callinginstall.py
. - Java support: install JDK 17 and add
--java-completer
when callinginstall.py
.
To simply compile with everything enabled, there's a --all
flag. So, to
install with all language features, ensure xbuild
, go
, node
and npm
tools are installed and in your PATH
, then simply run:
cd ~/.vim/bundle/YouCompleteMe
./install.py --all
That's it. You're done. Refer to the User Guide section on how to use YCM. Don't forget that if you want the C-family semantic completion engine to work, you will need to provide the compilation flags for your project to YCM. It's all in the User Guide.
YCM comes with sane defaults for its options, but you still may want to take a look at what's available for configuration. There are a few interesting options that are conservatively turned off by default that you may want to turn on.
The following assume you're using Ubuntu 20.04.
- Install YCM plugin via Vundle
- Install CMake, Vim and Python
apt install build-essential cmake vim-nox python3-dev
- Install mono-complete, go, node, java and npm
apt install mono-complete golang nodejs openjdk-17-jdk openjdk-17-jre npm
- Compile YCM
cd ~/.vim/bundle/YouCompleteMe
python3 install.py --all
- For plugging an arbitrary LSP server, check the relevant section
These instructions (using install.py
) are the quickest way to install
YouCompleteMe, however they may not work for everyone. If the following
instructions don't work for you, check out the full installation
guide.
Make sure you have a supported version of Vim with Python 3 support, and a supported compiler. The latest LTS of Ubuntu is the minimum platform for simple installation. For earlier releases or other distributions, you may have to do some work to acquire the dependencies.
If your vim version is too old, you may need to compile Vim from source (don't worry, it's easy).
Install YouCompleteMe with Vundle.
Remember: YCM is a plugin with a compiled component. If you update YCM
using Vundle and the ycm_core
library APIs have changed (happens rarely), YCM
will notify you to recompile it. You should then rerun the install process.
Install development tools, CMake, and Python headers:
- Fedora-like distributions:
sudo dnf install cmake gcc-c++ make python3-devel
- Ubuntu LTS:
sudo apt install build-essential cmake3 python3-dev
Compiling YCM with semantic support for C-family languages through clangd:
cd ~/.vim/bundle/YouCompleteMe
python3 install.py --clangd-completer
Compiling YCM without semantic support for C-family languages:
cd ~/.vim/bundle/YouCompleteMe
python3 install.py
The following additional language support options are available:
- C# support: install Mono and add
--cs-completer
when callinginstall.py
. - Go support: install Go and add
--go-completer
when callinginstall.py
. - JavaScript and TypeScript support: install Node.js and npm and
add
--ts-completer
when callinginstall.py
. - Rust support: add
--rust-completer
when callinginstall.py
. - Java support: install JDK 17 and add
--java-completer
when callinginstall.py
.
To simply compile with everything enabled, there's a --all
flag. So, to
install with all language features, ensure xbuild
, go
, node
and npm
tools are installed and in your PATH
, then simply run:
cd ~/.vim/bundle/YouCompleteMe
python3 install.py --all
That's it. You're done. Refer to the User Guide section on how to use YCM. Don't forget that if you want the C-family semantic completion engine to work, you will need to provide the compilation flags for your project to YCM. It's all in the User Guide.
YCM comes with sane defaults for its options, but you still may want to take a look at what's available for configuration. There are a few interesting options that are conservatively turned off by default that you may want to turn on.
- Install YCM plugin via Vundle
- Install Visual Studio Build Tools 2019
- Install CMake, Vim and Python
- Install go, node and npm
- Compile YCM
cd YouCompleteMe
python3 install.py --all
- Add
set encoding=utf-8
to your vimrc - For plugging an arbitrary LSP server, check the relevant section
These instructions (using install.py
) are the quickest way to install
YouCompleteMe, however they may not work for everyone. If the following
instructions don't work for you, check out the full installation
guide.
Important: we assume that you are using the cmd.exe
command prompt and
that you know how to add an executable to the PATH environment variable.
Make sure you have a supported Vim version with Python 3 support. You
can check the version and which Python is supported by typing :version
inside
Vim. Look at the features included: +python3/dyn
for Python 3.
Take note of the Vim architecture, i.e. 32 or
64-bit. It will be important when choosing the Python installer. We recommend
using a 64-bit client. Daily updated installers of 32-bit and 64-bit Vim with
Python 3 support are available.
Add the following line to your vimrc if not already present.:
set encoding=utf-8
This option is required by YCM. Note that it does not prevent you from editing a
file in another encoding than UTF-8. You can do that by specifying the ++enc
argument to the :e
command.
Install YouCompleteMe with Vundle.
Remember: YCM is a plugin with a compiled component. If you update YCM
using Vundle and the ycm_core
library APIs have changed (happens
rarely), YCM will notify you to recompile it. You should then rerun the install
process.
Download and install the following software:
- Python 3. Be sure to pick the version
corresponding to your Vim architecture. It is Windows x86 for a 32-bit Vim
and Windows x86-64 for a 64-bit Vim. We recommend installing Python 3.
Additionally, the version of Python you install must match up exactly with
the version of Python that Vim is looking for. Type
:version
and look at the bottom of the page at the list of compiler flags. Look for flags that look similar to-DDYNAMIC_PYTHON3_DLL=\"python36.dll\"
. This indicates that Vim is looking for Python 3.6. You'll need one or the other installed, matching the version number exactly. - CMake. Add CMake executable to the PATH environment variable.
- Build Tools for Visual Studio 2019. During setup, select C++ build tools in Workloads.
Compiling YCM with semantic support for C-family languages through clangd:
cd %USERPROFILE%/vimfiles/bundle/YouCompleteMe
python install.py --clangd-completer
Compiling YCM without semantic support for C-family languages:
cd %USERPROFILE%/vimfiles/bundle/YouCompleteMe
python install.py
The following additional language support options are available:
- C# support: add
--cs-completer
when callinginstall.py
. Be sure that the build utilitymsbuild
is in your PATH. - Go support: install Go and add
--go-completer
when callinginstall.py
. - JavaScript and TypeScript support: install Node.js and npm and
add
--ts-completer
when callinginstall.py
. - Rust support: add
--rust-completer
when callinginstall.py
. - Java support: install JDK 17 and add
--java-completer
when callinginstall.py
.
To simply compile with everything enabled, there's a --all
flag. So, to
install with all language features, ensure msbuild
, go
, node
and npm
tools are installed and in your PATH
, then simply run:
cd %USERPROFILE%/vimfiles/bundle/YouCompleteMe
python install.py --all
You can specify the Microsoft Visual C++ (MSVC) version using the --msvc
option. YCM officially supports MSVC 15 (2017), MSVC 16 (Visual Studio 2019)
and MSVC 17 (Visual Studio 17 2022).
That's it. You're done. Refer to the User Guide section on how to use YCM. Don't forget that if you want the C-family semantic completion engine to work, you will need to provide the compilation flags for your project to YCM. It's all in the User Guide.
YCM comes with sane defaults for its options, but you still may want to take a look at what's available for configuration. There are a few interesting options that are conservatively turned off by default that you may want to turn on.
- Install YCM plugin via Vundle
- Install CMake
pkg install cmake
- Install xbuild, go, node and npm
- Compile YCM
cd ~/.vim/bundle/YouCompleteMe
python3 install.py --all
- For plugging an arbitrary LSP server, check the relevant section
These instructions (using install.py
) are the quickest way to install
YouCompleteMe, however they may not work for everyone. If the following
instructions don't work for you, check out the full installation
guide.
NOTE: OpenBSD / FreeBSD are not officially supported platforms by YCM.
Make sure you have a supported Vim version with Python 3 support, and a supported compiler and CMake, perhaps:
pkg install cmake
Install YouCompleteMe with Vundle.
Remember: YCM is a plugin with a compiled component. If you update YCM
using Vundle and the ycm_core
library APIs have changed (happens
rarely), YCM will notify you to recompile it. You should then rerun the install
process.
Compiling YCM with semantic support for C-family languages through clangd:
cd ~/.vim/bundle/YouCompleteMe
./install.py --clangd-completer
Compiling YCM without semantic support for C-family languages:
cd ~/.vim/bundle/YouCompleteMe
./install.py
If the python
executable is not present, or the default python
is not the
one that should be compiled against, specify the python interpreter explicitly:
python3 install.py --clangd-completer
The following additional language support options are available:
- C# support: install Mono and add
--cs-completer
when calling./install.py
. - Go support: install Go and add
--go-completer
when calling./install.py
. - JavaScript and TypeScript support: install Node.js and npm and
add
--ts-completer
when callinginstall.py
. - Rust support: add
--rust-completer
when calling./install.py
. - Java support: install JDK 17 and add
--java-completer
when calling./install.py
.
To simply compile with everything enabled, there's a --all
flag. So, to
install with all language features, ensure xbuild
, go
, node
and npm
tools are installed and in your PATH
, then simply run:
cd ~/.vim/bundle/YouCompleteMe
./install.py --all
That's it. You're done. Refer to the User Guide section on how to use YCM. Don't forget that if you want the C-family semantic completion engine to work, you will need to provide the compilation flags for your project to YCM. It's all in the User Guide.
YCM comes with sane defaults for its options, but you still may want to take a look at what's available for configuration. There are a few interesting options that are conservatively turned off by default that you may want to turn on.
The full installation guide has been moved to the wiki.
- Super-fast identifier completer including tags files and syntax elements
- Intelligent suggestion ranking and filtering
- File and path suggestions
- Suggestions from Vim's omnifunc
- UltiSnips snippet suggestions
- Semantic auto-completion with automatic fixes
- Signature help
- Real-time diagnostic display
- Go to include/declaration/definition (
GoTo
, etc.) - Find Symbol (
GoToSymbol
), with interactive search - Document outline (
GoToDocumentOutline
), with interactive search - View documentation comments for identifiers (
GetDoc
) - Type information for identifiers (
GetType
) - Automatically fix certain errors (
FixIt
) - Reference finding (
GoToReferences
) - Renaming symbols (
RefactorRename <new name>
) - Code formatting (
Format
) - Semantic highlighting
- Inlay hints
- Semantic auto-completion
- Signature help
- Real-time diagnostic display
- Go to declaration/definition (
GoTo
, etc.) - Go to implementation (
GoToImplementation
) - Find Symbol (
GoToSymbol
), with interactive search - View documentation comments for identifiers (
GetDoc
) - Type information for identifiers (
GetType
) - Automatically fix certain errors (
FixIt
) - Management of OmniSharp-Roslyn server instance
- Renaming symbols (
RefactorRename <new name>
) - Code formatting (
Format
)
- Semantic auto-completion
- Signature help
- Go to definition (
GoTo
) - Find Symbol (
GoToSymbol
), with interactive search - Reference finding (
GoToReferences
) - View documentation comments for identifiers (
GetDoc
) - Type information for identifiers (
GetType
) - Renaming symbols (
RefactorRename <new name>
)
- Semantic auto-completion
- Signature help
- Real-time diagnostic display
- Go to declaration/definition (
GoTo
, etc.) - Go to type definition (
GoToType
) - Go to implementation (
GoToImplementation
) - Document outline (
GoToDocumentOutline
), with interactive search - Automatically fix certain errors (
FixIt
) - View documentation comments for identifiers (
GetDoc
) - Type information for identifiers (
GetType
) - Code formatting (
Format
) - Management of
gopls
server instance
- Semantic auto-completion with automatic import insertion
- Signature help
- Real-time diagnostic display
- Go to definition (
GoTo
,GoToDefinition
, andGoToDeclaration
are identical) - Go to type definition (
GoToType
) - Go to implementation (
GoToImplementation
) - Find Symbol (
GoToSymbol
), with interactive search - Reference finding (
GoToReferences
) - View documentation comments for identifiers (
GetDoc
) - Type information for identifiers (
GetType
) - Automatically fix certain errors (
FixIt
) - Renaming symbols (
RefactorRename <new name>
) - Code formatting (
Format
) - Organize imports (
OrganizeImports
) - Management of
TSServer
server instance - Inlay hints
- Semantic auto-completion
- Real-time diagnostic display
- Go to declaration/definition (
GoTo
, etc.) - Go to implementation (
GoToImplementation
) - Reference finding (
GoToReferences
) - Document outline (
GoToDocumentOutline
), with interactive search - View documentation comments for identifiers (
GetDoc
) - Automatically fix certain errors (
FixIt
) - Type information for identifiers (
GetType
) - Renaming symbols (
RefactorRename <new name>
) - Code formatting (
Format
) - Management of
rust-analyzer
server instance - Semantic highlighting
- Inlay hints
- Semantic auto-completion with automatic import insertion
- Signature help
- Real-time diagnostic display
- Go to definition (
GoTo
,GoToDefinition
, andGoToDeclaration
are identical) - Go to type definition (
GoToType
) - Go to implementation (
GoToImplementation
) - Find Symbol (
GoToSymbol
), with interactive search - Reference finding (
GoToReferences
) - Document outline (
GoToDocumentOutline
), with interactive search - View documentation comments for identifiers (
GetDoc
) - Type information for identifiers (
GetType
) - Automatically fix certain errors including code generation (
FixIt
) - Renaming symbols (
RefactorRename <new name>
) - Code formatting (
Format
) - Organize imports (
OrganizeImports
) - Detection of java projects
- Execute custom server command (
ExecuteCommand <args>
) - Management of
jdt.ls
server instance - Semantic highlighting
If the offered completions are too broad, keep typing characters; YCM will continue refining the offered completions based on your input.
Filtering is "smart-case" and "smart-diacritic" sensitive; if you are typing only lowercase letters, then it's case-insensitive. If your input contains uppercase letters, then the uppercase letters in your query must match uppercase letters in the completion strings (the lowercase letters still match both). On top of that, a letter with no diacritic marks will match that letter with or without marks:
matches | foo | fôo | fOo | fÔo |
---|---|---|---|---|
foo | ✔️ | ✔️ | ✔️ | ✔️ |
fôo | ❌ | ✔️ | ❌ | ✔️ |
fOo | ❌ | ❌ | ✔️ | ✔️ |
fÔo | ❌ | ❌ | ❌ | ✔️ |
Use the TAB key to accept a completion and continue pressing TAB to cycle through the completions. Use Shift-TAB to cycle backwards. Note that if you're using console Vim (that is, not gvim or MacVim) then it's likely that the Shift-TAB binding will not work because the console will not pass it to Vim. You can remap the keys; see the Options section below.
Knowing a little bit about how YCM works internally will prevent confusion. YCM has several completion engines: an identifier-based completer that collects all of the identifiers in the current file and other files you visit (and your tags files) and searches them when you type (identifiers are put into per-filetype groups).
There are also several semantic engines in YCM. There are libclang-based and clangd-based completers that provide semantic completion for C-family languages. There's a Jedi-based completer for semantic completion for Python. There's also an omnifunc-based completer that uses data from Vim's omnicomplete system to provide semantic completions when no native completer exists for that language in YCM.
There are also other completion engines, like the UltiSnips completer and the filepath completer.
YCM automatically detects which completion engine would be the best in any situation. On occasion, it queries several of them at once, merges the outputs and presents the results to you.
YCM has a client-server architecture; the Vim part of YCM is only a thin client that talks to the ycmd HTTP+JSON server that has the vast majority of YCM logic and functionality. The server is started and stopped automatically as you start and stop Vim.
The subsequence filter removes any completions that do not match the input, but then the sorting system kicks in. It's actually very complicated and uses lots of factors, but suffice it to say that "word boundary" (WB) subsequence character matches are "worth" more than non-WB matches. In effect, this means given an input of "gua", the completion "getUserAccount" would be ranked higher in the list than the "Fooguxa" completion (both of which are subsequence matches). A word-boundary character are all capital characters, characters preceded by an underscore and the first letter character in the completion string.
Valid signatures are displayed in a second popup menu and the current signature is highlighted along with the current argument.
Signature help is triggered in insert mode automatically when
g:ycm_auto_trigger
is enabled and is not supported when it is not enabled.
The signatures popup is hidden when there are no matching signatures or when you leave insert mode. There is no key binding to clear the popup.
For more details on this feature and a few demos, check out the PR that proposed it.
The signature help popup sometimes gets in the way. You can toggle its
visibility with a mapping. YCM provides the "Plug" mapping
<Plug>(YCMToggleSignatureHelp)
for this.
For example, to hide/show the signature help popup by pressing Ctrl+l in insert
mode: imap <silent> <C-l> <Plug>(YCMToggleSignatureHelp)
.
NOTE: No default mapping is provided because insert mappings are very difficult to create without breaking or overriding some existing functionality. Ctrl-l is not a suggestion, just an example.
NOTE: This feature is highly experimental and offered in the hope that it is useful. It shall not be considered stable; if you find issues with it, feel free to report them however.
Semantic highlighting is the process where the buffer text is coloured according to the underlying semantic type of the word, rather than classic syntax highlighting based on regular expressions. This can be powerful additional data that we can process very quickly.
This feature is only supported in Vim.
For example, here is a function with classic highlighting:
And here is the same function with semantic highlighting:
As you can see, the function calls, macros, etc. are correctly identified.
This can be enabled globally with let g:ycm_enable_semantic_highlighting=1
or
per buffer, by setting b:ycm_enable_semantic_highlighting
.
YCM uses text properties (see :help text-prop-intro
) for semantic
highlighting. In order to customise the coloring, you can define the text
properties that are used.
If you define a text property named YCM_HL_<token type>
, then it will be used
in place of the defaults. The <token type>
is defined as the Language Server
Protocol semantic token type, defined in the LSP Spec.
Some servers also use custom values. In this case, YCM prints a warning including the token type name that you can customise.
For example, to render parameter
tokens using the Normal
highlight group,
you can do this:
call prop_type_add( 'YCM_HL_parameter', { 'highlight': 'Normal' } )
More generally, this pattern can be useful for customising the groups:
let MY_YCM_HIGHLIGHT_GROUP = {
\ 'typeParameter': 'PreProc',
\ 'parameter': 'Normal',
\ 'variable': 'Normal',
\ 'property': 'Normal',
\ 'enumMember': 'Normal',
\ 'event': 'Special',
\ 'member': 'Normal',
\ 'method': 'Normal',
\ 'class': 'Special',
\ 'namespace': 'Special',
\ }
for tokenType in keys( MY_YCM_HIGHLIGHT_GROUP )
call prop_type_add( 'YCM_HL_' . tokenType,
\ { 'highlight': MY_YCM_HIGHLIGHT_GROUP[ tokenType ] } )
endfor
NOTE: Hightly experimental feature, requiring vim 9.0.214 or later (no neovim).
When g:ycm_enable_inlay_hints
(globally) or b:ycm_enable_inlay_hints
(for a
specific buffer) is set to 1
, then YCM will insert inlay hints as supported by
the language semantic engine.
An inlay hint is text renderd on the screen which is not part of the buffer and is often used to mark up the type or name of arguments, perameters, etc. which help the developer understand the semantics of the code.
Here are some examples:
- C
- TypeScript
- Go
By default, YCM renders the inlay hints with the NonText
highlight group. To
override this, define the YcmInlayHint
highlight yourself, e.g. in your
.vimrc
:
hi link YcmInlayHint Comment
Similar to semantic highlighting above, you can override specific highlighting for different inlay hint types by defining text properties named after the kind of inlay hint, for example:
call prop_type_add( 'YCM_INLAY_Type', #{ highlight: 'Comment' } )
The list of inlay hint kinds can be found in python/ycm/inlay_hints.py
g:ycm_enable_inlay_hints
orb:ycm_enable_inlay_hints
- enable/disable globally or for local bufferg:ycm_clear_inlay_hints_in_insert_mode
- set to1
to remove all inlay hints when entering insert mode and reinstate them when leaving insert mode
Inlay hints can add a lot of text to the screen and may be distracting. You can
toggle them on/off instantly, by mapping something to
<Plug>(YCMToggleInlayHints)
, for example:
nnoremap <silent> <localleader>h <Plug>(YCMToggleInlayHints)
No default mapping is provided for this due to the personal nature of mappings.
You can use Ctrl+Space to trigger the completion suggestions anywhere, even without a string prefix. This is useful to see which top-level functions are available for use.
NOTE: YCM originally used the libclang
based engine for C-family, but
users should migrate to clangd, as it provides more features and better
performance. Users who rely on override_filename
in their .ycm_extra_conf.py
will need to stay on the old libclang
engine. Instructions on how to stay on
the old engine are available on the wiki.
Some of the features of clangd:
- Project wide indexing: Clangd has both dynamic and static index support. The dynamic index stores up-to-date symbols coming from any files you are currently editing, whereas static index contains project-wide symbol information. This symbol information is used for code completion and code navigation. Whereas libclang is limited to the current translation unit(TU).
- Code navigation: Clangd provides all the GoTo requests libclang provides and it improves those using the above mentioned index information to contain project-wide information rather than just the current TU.
- Rename: Clangd can perform semantic rename operations on the current file, whereas libclang doesn't support such functionality.
- Code Completion: Clangd can perform code completions at a lower latency
than libclang; also, it has information about all the symbols in your
project so it can suggest items outside your current TU and also provides
proper
#include
insertions for those items. - Signature help: Clangd provides signature help so that you can see the names and types of arguments when calling functions.
- Format Code: Clangd provides code formatting either for the selected lines or the whole file, whereas libclang doesn't have such functionality.
- Performance: Clangd has faster re-parse and code completion times compared to libclang.
On supported architectures, the install.py
script will download a suitable
clangd (--clangd-completer
) or libclang (--clang-completer
) for you.
Supported architectures are:
- Linux glibc >= 2.27 (Intel, armv7-a, aarch64) - built on ubuntu 18.04
- MacOS >=10.15 (Intel, arm64)
- For Intel, compatibility per clang.llvm.org downloads
- For arm64, macOS 10.15+
- Windows (Intel) - compatibility per clang.llvm.org downloads
clangd:
Typically, clangd is installed by the YCM installer (either with --all
or with
--clangd-completer
). This downloads a pre-built clangd
binary for your
architecture. If your OS or architecture is not supported or too old, you can
install a compatible clangd
and use g:ycm_clangd_binary_path
to point to
it.
libclang:
libclang
can be enabled also with --all
or --clang-completer
. As with
clangd
, YCM will try and download a version of libclang
that is suitable for
your environment, but again if your environment can't be supported, you can
build or acquire libclang
for yourself and specify it when building, as:
$ EXTRA_CMAKE_ARGS='-DPATH_TO_LLVM_ROOT=/path/to/your/llvm' ./install.py --clang-completer --system-libclang
Please note that if using custom clangd
or libclang
it must match the
version that YCM requires. Currently YCM requires clang 15.0.1.
In order to perform semantic analysis such as code completion, GoTo
and
diagnostics, YouCompleteMe uses clangd
, which makes use of
clang compiler, sometimes also referred to as LLVM. Like any compiler,
clang also requires a set of compile flags in order to parse your code. Simply
put: If clang can't parse your code, YouCompleteMe can't provide semantic
analysis.
There are 2 methods which can be used to provide compile flags to clang:
Option 1: Use a compilation database
The easiest way to get YCM to compile your code is to use a compilation
database. A compilation database is usually generated by your build system
(e.g. CMake
) and contains the compiler invocation for each compilation unit in
your project.
For information on how to generate a compilation database, see the clang documentation. In short:
- If using CMake, add
-DCMAKE_EXPORT_COMPILE_COMMANDS=ON
when configuring (or addset( CMAKE_EXPORT_COMPILE_COMMANDS ON )
toCMakeLists.txt
) and copy or symlink the generated database to the root of your project. - If using Ninja, check out the
compdb
tool (-t compdb
) in its docs. - If using GNU make, check out compiledb or Bear.
- For other build systems, check out
.ycm_extra_conf.py
below.
If no .ycm_extra_conf.py
is found,
YouCompleteMe automatically tries to load a compilation database if there is
one.
YCM looks for a file named compile_commands.json
in the directory of the
opened file or in any directory above it in the hierarchy (recursively); when
the file is found before a local .ycm_extra_conf.py
, YouCompleteMe stops
searching the directories and lets clangd take over and handle the flags.
If you don't have a compilation database, or aren't able to generate one, you have to tell YouCompleteMe how to compile your code some other way.
Every C-family project is different. It is not possible for YCM to guess what compiler flags to supply for your project. Fortunately, YCM provides a mechanism for you to generate the flags for a particular file with arbitrary complexity. This is achieved by requiring you to provide a Python module which implements a trivial function which, given the file name as argument, returns a list of compiler flags to use to compile that file.
YCM looks for a .ycm_extra_conf.py
file in the directory of the opened file or
in any directory above it in the hierarchy (recursively); when the file is
found, it is loaded (only once!) as a Python module. YCM calls a Settings
method in that module which should provide it with the information necessary to
compile the current file. You can also provide a path to a global configuration
file with the
g:ycm_global_ycm_extra_conf
option,
which will be used as a fallback. To prevent the execution of malicious code
from a file you didn't write YCM will ask you once per .ycm_extra_conf.py
if
it is safe to load. This can be disabled and you can white-/blacklist files. See
the g:ycm_confirm_extra_conf
and
g:ycm_extra_conf_globlist
options
respectively.
This system was designed this way so that the user can perform any arbitrary sequence of operations to produce a list of compilation flags YCM should hand to Clang.
NOTE: It is highly recommended to include -x <language>
flag to libclang.
This is so that the correct language is detected, particularly for header files.
Common values are -x c
for C, -x c++
for C++, -x objc
for Objective-C, and
-x cuda
for CUDA.
To give you an impression, if your C++ project is trivial, and your usual
compilation command is: g++ -Wall -Wextra -Werror -o FILE.o FILE.cc
, then the
following .ycm_extra_conf.py
is enough to get semantic analysis from
YouCompleteMe:
def Settings( **kwargs ):
return {
'flags': [ '-x', 'c++', '-Wall', '-Wextra', '-Werror' ],
}
As you can see from the trivial example, YCM calls the Settings
method which
returns a dictionary with a single element 'flags'
. This element is a list
of compiler flags to pass to libclang for the current file. The absolute path of
that file is accessible under the filename
key of the kwargs
dictionary.
That's it! This is actually enough for most projects, but for complex projects
it is not uncommon to integrate directly with an existing build system using the
full power of the Python language.
For a more elaborate example,
see ycmd's own .ycm_extra_conf.py
. You should be able to
use it as a starting point. Don't just copy/paste that file somewhere and
expect things to magically work; your project needs different flags. Hint:
just replace the strings in the flags
variable with compilation flags
necessary for your project. That should be enough for 99% of projects.
You could also consider using YCM-Generator to generate the
ycm_extra_conf.py
file.
If Clang encounters errors when compiling the header files that your file includes, then it's probably going to take a long time to get completions. When the completion menu finally appears, it's going to have a large number of unrelated completion strings (type/function names that are not actually members). This is because Clang fails to build a precompiled preamble for your file if there are any errors in the included headers and that preamble is key to getting fast completions.
Call the :YcmDiags
command to see if any errors or warnings were detected in
your file.
-
Ensure that you have enabled the Java completer. See the installation guide for details.
-
Create a project file (gradle or maven) file in the root directory of your Java project, by following the instructions below.
-
(Optional) Configure the LSP server. The jdt.ls configuration options can be found in their codebase.
-
If you previously used Eclim or Syntastic for Java, disable them for Java.
-
Edit a Java file from your project.
In order to provide semantic analysis, the Java completion engine requires knowledge of your project structure. In particular it needs to know the class path to use, when compiling your code. Fortunately jdt.ls supports eclipse project files, maven projects and gradle projects.
NOTE: Our recommendation is to use either maven or gradle projects.
The native support for Java includes YCM's native realtime diagnostics display. This can conflict with other diagnostics plugins like Syntastic, so when enabling Java support, please manually disable Syntastic Java diagnostics.
Add the following to your vimrc
:
let g:syntastic_java_checkers = []
The native support for Java includes YCM's native realtime diagnostics display. This can conflict with other diagnostics plugins like Eclim, so when enabling Java support, please manually disable Eclim Java diagnostics.
Add the following to your vimrc
:
let g:EclimFileTypeValidate = 0
NOTE: We recommend disabling Eclim entirely when editing Java with YCM's
native Java support. This can be done temporarily with :EclimDisable
.
Eclipse style projects require two files: .project and .classpath.
If your project already has these files due to previously being set up within eclipse, then no setup is required. jdt.ls should load the project just fine (it's basically eclipse after all).
However, if not, it is possible (easy in fact) to craft them manually, though it is not recommended. You're better off using gradle or maven (see below).
A simple eclipse style project example can be found in
the ycmd test directory. Normally all that is required is to copy these files to
the root of your project and to edit the .classpath
to add additional
libraries, such as:
<classpathentry kind="lib" path="/path/to/external/jar" />
<classpathentry kind="lib" path="/path/to/external/java/source" />
It may also be necessary to change the directory in which your source files are located (paths are relative to the .project file itself):
<classpathentry kind="src" output="target/classes" path="path/to/src/" />
NOTE: The eclipse project and classpath files are not a public interface and it is highly recommended to use Maven or Gradle project definitions if you don't already use eclipse to manage your projects.
Maven needs a file named pom.xml in the root of the project. Once again a simple pom.xml can be found in ycmd source.
The format of pom.xml files is way beyond the scope of this document, but we do recommend using the various tools that can generate them for you, if you're not familiar with them already.
Gradle projects require a build.gradle. Again, there is a trivial example in ycmd's tests.
The format of build.gradle files is way beyond the scope of this document, but we do recommend using the various tools that can generate them for you, if you're not familiar with them already.
Some users have experienced issues with their jdt.ls when using the Groovy language for their build.gradle. As such, try using Kotlin instead.
If you're not getting completions or diagnostics, check the server health:
- The Java completion engine takes a while to start up and parse your project.
You should be able to see its progress in the command line, and
:YcmDebugInfo
. Ensure that the following lines are present:
-- jdt.ls Java Language Server running
-- jdt.ls Java Language Server Startup Status: Ready
- If the above lines don't appear after a few minutes, check the jdt.ls and ycmd
log files using
:YcmToggleLogs
. The jdt.ls log file is called.log
(for some reason).
If you get a message about "classpath is incomplete", then make sure you have correctly configured the project files.
If you get messages about unresolved imports, then make sure you have correctly configured the project files, in particular check that the classpath is set correctly.
YCM relies on OmniSharp-Roslyn to provide completion and code navigation. OmniSharp-Roslyn needs a solution file for a C# project and there are two ways of letting YCM know about your solution files.
YCM will scan all parent directories of the file currently being edited and look
for file with .sln
extension.
If YCM loads .ycm_extra_conf.py
which contains CSharpSolutionFile
function,
YCM will try to use that to determine the solution file. This is useful when one
wants to override the default behaviour and specify a solution file that is not
in any of the parent directories of the currently edited file. Example:
def CSharpSolutionFile( filepath ):
# `filepath` is the path of the file user is editing
return '/path/to/solution/file' # Can be relative to the `.ycm_extra_conf.py`
If the path returned by CSharpSolutionFile
is not an actual file, YCM will
fall back to the other way of finding the file.
YCM relies on the Jedi engine to provide completion and code navigation. By
default, it will pick the version of Python running the ycmd server and
use its sys.path
. While this is fine for simple projects, this needs to be
configurable when working with virtual environments or in a project with
third-party packages. The next sections explain how to do that.
A common practice when working on a Python project is to install its
dependencies in a virtual environment and develop the project inside that
environment. To support this, YCM needs to know the interpreter path of the
virtual environment. You can specify it by creating a .ycm_extra_conf.py
file
at the root of your project with the following contents:
def Settings( **kwargs ):
return {
'interpreter_path': '/path/to/virtual/environment/python'
}
Here, /path/to/virtual/environment/python
is the path to the Python used
by the virtual environment you are working in. Typically, the executable can be
found in the Scripts
folder of the virtual environment directory on Windows
and in the bin
folder on other platforms.
If you don't like having to create a .ycm_extra_conf.py
file at the root of
your project and would prefer to specify the interpreter path with a Vim option,
read the Configuring through Vim options
section.
Another common practice is to put the dependencies directly into the project and
add their paths to sys.path
at runtime in order to import them. YCM needs to
be told about this path manipulation to support those dependencies. This can be
done by creating a .ycm_extra_conf.py
file at the root of the project. This
file must define a Settings( **kwargs )
function returning a dictionary with
the list of paths to prepend to sys.path
under the sys_path
key. For
instance, the following .ycm_extra_conf.py
adds the paths
/path/to/some/third_party/package
and /path/to/another/third_party/package
at the start of sys.path
:
def Settings( **kwargs ):
return {
'sys_path': [
'/path/to/some/third_party/package',
'/path/to/another/third_party/package'
]
}
If you would rather prepend paths to sys.path
with a Vim option, read the
Configuring through Vim options section.
If you need further control on how to add paths to sys.path
, you should define
the PythonSysPath( **kwargs )
function in the .ycm_extra_conf.py
file. Its
keyword arguments are sys_path
which contains the default sys.path
, and
interpreter_path
which is the path to the Python interpreter. Here's a trivial
example that insert the /path/to/third_party/package
path at the second
position of sys.path
:
def PythonSysPath( **kwargs ):
sys_path = kwargs[ 'sys_path' ]
sys_path.insert( 1, '/path/to/third_party/package' )
return sys_path
A more advanced example can be found in YCM's own
.ycm_extra_conf.py
.
You may find inconvenient to have to create a .ycm_extra_conf.py
file at the
root of each one of your projects in order to set the path to the Python
interpreter and/or add paths to sys.path
and would prefer to be able to
configure those through Vim options. Don't worry, this is possible by using the
g:ycm_extra_conf_vim_data
option and
creating a global extra configuration file. Let's take an example. Suppose that
you want to set the interpreter path with the g:ycm_python_interpreter_path
option and prepend paths to sys.path
with the g:ycm_python_sys_path
option.
Suppose also that you want to name the global extra configuration file
global_extra_conf.py
and that you want to put it in your HOME folder. You
should then add the following lines to your vimrc:
let g:ycm_python_interpreter_path = ''
let g:ycm_python_sys_path = []
let g:ycm_extra_conf_vim_data = [
\ 'g:ycm_python_interpreter_path',
\ 'g:ycm_python_sys_path'
\]
let g:ycm_global_ycm_extra_conf = '~/global_extra_conf.py'
Then, create the ~/global_extra_conf.py
file with the following contents:
def Settings( **kwargs ):
client_data = kwargs[ 'client_data' ]
return {
'interpreter_path': client_data[ 'g:ycm_python_interpreter_path' ],
'sys_path': client_data[ 'g:ycm_python_sys_path' ]
}
That's it. You are done. Note that you don't need to restart the server when setting one of the options. YCM will automatically pick the new values.
YCM uses rust-analyzer for Rust semantic completion.
NOTE: Previously, YCM used rls for rust completion. This is no longer supported, as the Rust community has decided on rust-analyzer as the future of Rust tooling.
Completions and GoTo commands within the current crate and its dependencies
should work out of the box with no additional configuration (provided that you
built YCM with the --rust-completer
flag; see the Installation
section for details). The install script takes care of
installing the Rust source code, so no configuration is necessary.
rust-analyzer
supports a myriad of options. These are configured using LSP
configuration, and are documented here.
Completions and GoTo commands should work out of the box (provided that you
built YCM with the --go-completer
flag; see the Installation
section for details). The server only works for projects with
the "canonical" layout.
gopls
also has a handful of undocumented options for which the
source code is the only reference.
NOTE: YCM originally used the Tern engine for JavaScript but due to
Tern not being maintained anymore by its main author and the TSServer
engine offering more features, YCM is moving to TSServer. This won't affect
you if you were already using Tern but you are encouraged to do the switch
by deleting the third_party/ycmd/third_party/tern_runtime/node_modules
directory in YCM folder. If you are a new user but still want to use Tern,
you should pass the --js-completer
option to the install.py
script during
installation. Further instructions on how to setup YCM with Tern are
available on the wiki.
All JavaScript and TypeScript features are provided by the TSServer engine,
which is included in the TypeScript SDK. To enable these features, install
Node.js and npm and call the install.py
script with the
--ts-completer
flag.
TSServer relies on the jsconfig.json
file for JavaScript
and the tsconfig.json
file for TypeScript to analyze your
project. Ensure the file exists at the root of your project.
To get diagnostics in JavaScript, set the checkJs
option to true
in your
jsconfig.json
file:
{
"compilerOptions": {
"checkJs": true
}
}
C-family, C#, Go, Java, Python, Rust, and JavaScript/TypeScript languages are supported natively by YouCompleteMe using the Clang, OmniSharp-Roslyn, Gopls, jdt.ls, Jedi, rust-analyzer, and TSServer engines, respectively. Check the installation section for instructions to enable these features if desired.
Similar to other LSP clients, YCM can use an arbitrary LSP server with the help
of g:ycm_language_server
option. An
example of a value of this option would be:
let g:ycm_language_server =
\ [
\ {
\ 'name': 'yaml',
\ 'cmdline': [ '/path/to/yaml/server/yaml-language-server', '--stdio' ],
\ 'filetypes': [ 'yaml' ]
\ },
\ {
\ 'name': 'rust',
\ 'cmdline': [ 'ra_lsp_server' ],
\ 'filetypes': [ 'rust' ],
\ 'project_root_files': [ 'Cargo.toml' ]
\ },
\ {
\ 'name': 'godot',
\ 'filetypes': [ 'gdscript' ],
\ 'port': 6008,
\ 'project_root_files': [ 'project.godot' ]
\ }
\ ]
Each dictionary contains the following keys:
name
(string, mandatory): When configuring a LSP server the value of thename
key will be used as thekwargs[ 'language' ]
. Can be anything you like.filetypes
(list of string, mandatory): List of Vim filetypes this server should be used for.project_root_files
(list of string, optional): List of filenames to search for when trying to determine the project root.cmdline
(list of string, optional): If supplied, the server is started with this command line (each list element is a command line word). Typically, the server should be started with STDIO communication. If not supplied,port
must be supplied.port
(number, optional): If supplied, ycmd will connect to the server atlocalhost:<port>
using TCP (remote servers are not supported).capabilities
(dict, optional): If supplied, this is a dictionary that is merged with the LSP client capabilities reported to the language server. This can be used to enable or disable certain features, such as the support for configuration sections (workspace/configuration
).
See the LSP Examples project for more examples of configuring the likes of PHP, Ruby, Kotlin, and D.
Many LSP servers allow some level of user configuration. YCM enables this with
the help of .ycm_extra_conf.py
files. Here's an example of jdt.ls user
examples of configuring the likes of PHP, Ruby, Kotlin, D, and many, many more.
def Settings( **kwargs ):
if kwargs[ 'language' ] == 'java':
return {
'ls': {
'java.format.onType.enabled': True
}
}
The ls
key tells YCM that the dictionary should be passed to the LSP server.
For each of the LSP server's configuration you should look up the respective
server's documentation.
Some servers request settings from arbitrary 'sections' of configuration. There
is no concept of configuration sections in vim, so you can specify an additional
config_sections
dictionary which maps section to a dictionary of config
required by the server. For example:
def Settings( **kwargs ):
if kwargs[ 'language' ] == 'java':
return {
'ls': {
'java.format.onType.enabled': True
},
'config_sections': {
'some section': {
'some option': 'some value'
}
}
The sections and options/values are complete server-specific and rarely well documented.
YCM will use your omnifunc
(see :h omnifunc
in Vim) as a source for semantic
completions if it does not have a native semantic completion engine for your
file's filetype. Vim comes with rudimentary omnifuncs for various languages like
Ruby, PHP, etc. It depends on the language.
You can get a stellar omnifunc for Ruby with Eclim. Just make sure you have
the latest Eclim installed and configured (this means Eclim >= 2.2.*
and
Eclipse >= 4.2.*
).
After installing Eclim remember to create a new Eclipse project within your
application by typing :ProjectCreate <path-to-your-project> -n ruby
inside vim
and don't forget to have let g:EclimCompletionMethod = 'omnifunc'
in your
vimrc. This will make YCM and Eclim play nice; YCM will use Eclim's omnifuncs as
the data source for semantic completions and provide the auto-triggering and
subsequence-based matching (and other YCM features) on top of it.
You have two options here: writing an omnifunc
for Vim's omnicomplete system
that YCM will then use through its omni-completer, or a custom completer for YCM
using the Completer API.
Here are the differences between the two approaches:
- You have to use VimScript to write the omnifunc, but get to use Python to write for the Completer API; this by itself should make you want to use the API.
- The Completer API is a much more powerful way to integrate with YCM and it provides a wider set of features. For instance, you can make your Completer query your semantic back-end in an asynchronous fashion, thus not blocking Vim's GUI thread while your completion system is processing stuff. This is impossible with VimScript. All of YCM's completers use the Completer API.
- Performance with the Completer API is better since Python executes faster than VimScript.
If you want to use the omnifunc
system, see the relevant Vim docs with :h complete-functions
. For the Completer API, see the API docs.
If you want to upstream your completer into YCM's source, you should use the Completer API.
YCM will display diagnostic notifications for the C-family, C#, Go, Java, JavaScript, Rust and TypeScript languages. Since YCM continuously recompiles your file as you type, you'll get notified of errors and warnings in your file as fast as possible.
Here are the various pieces of the diagnostic UI:
- Icons show up in the Vim gutter on lines that have a diagnostic.
- Regions of text related to diagnostics are highlighted (by default, a red
wavy underline in
gvim
and a red background invim
). - Moving the cursor to a line with a diagnostic echoes the diagnostic text.
- Vim's location list is automatically populated with diagnostic data (off by default, see options).
The new diagnostics (if any) will be displayed the next time you press any key on the keyboard. So if you stop typing and just wait for the new diagnostics to come in, that will not work. You need to press some key for the GUI to update.
Having to press a key to get the updates is unfortunate, but cannot be changed due to the way Vim internals operate; there is no way that a background task can update Vim's GUI after it has finished running. You have to press a key. This will make YCM check for any pending diagnostics updates.
You can force a full, blocking compilation cycle with the
:YcmForceCompileAndDiagnostics
command (you may want to map that command to a
key; try putting nnoremap <F5> :YcmForceCompileAndDiagnostics<CR>
in your
vimrc). Calling this command will force YCM to immediately recompile your file
and display any new diagnostics it encounters. Do note that recompilation with
this command may take a while and during this time the Vim GUI will be
blocked.
YCM will display a short diagnostic message when you move your cursor to the
line with the error. You can get a detailed diagnostic message with the
<leader>d
key mapping (can be changed in the options) YCM provides when your
cursor is on the line with the diagnostic.
You can also see the full diagnostic message for all the diagnostics in the
current file in Vim's locationlist
, which can be opened with the :lopen
and
:lclose
commands (make sure you have set let g:ycm_always_populate_location_list = 1
in your vimrc). A good way to toggle
the display of the locationlist
with a single key mapping is provided by
another (very small) Vim plugin called ListToggle (which also makes it
possible to change the height of the locationlist
window), also written by
yours truly.
You can change the styling for the highlighting groups YCM uses. For the signs in the Vim gutter, the relevant groups are:
YcmErrorSign
, which falls back to groupSyntasticErrorSign
and thenerror
if they existYcmWarningSign
, which falls back to groupSyntasticWarningSign
and thentodo
if they exist
You can also style the line that has the warning/error with these groups:
YcmErrorLine
, which falls back to groupSyntasticErrorLine
if it existsYcmWarningLine
, which falls back to groupSyntasticWarningLine
if it exists
Note that the line highlighting groups only work when the
g:ycm_enable_diagnostic_signs
option is set. If you want highlighted lines but no signs in the Vim gutter,
set the signcolumn
option to no
in your vimrc:
set signcolumn=no
The syntax groups used to highlight regions of text with errors/warnings:
YcmErrorSection
, which falls back to groupSyntasticError
if it exists and thenSpellBad
YcmWarningSection
, which falls back to groupSyntasticWarning
if it exists and thenSpellCap
Here's how you'd change the style for a group:
highlight YcmErrorLine guibg=#3f0000
This feature requires Vim and is not supported in Neovim
YCM provides a way to search for and jump to a symbol in the current project or document when using supported languages.
You can search for symbols in the current workspace when the GoToSymbol
request is supported and the current document when GoToDocumentOutline
is
supported.
Here's a quick demo:
As you can see, you can type and YCM filters down the list as you type. The current set of matches are displayed in a popup window in the centre of the screen and you can select an entry with the keyboard, to jump to that position. Any matches are then added to the quickfix list.
To enable:
nmap <something> <Plug>(YCMFindSymbolInWorkspace)
nmap <something> <Plug>(YCMFindSymbolInDocument)
e.g.
nmap <leader>yfw <Plug>(YCMFindSymbolInWorkspace)
nmap <leader>yfd <Plug>(YCMFindSymbolInDocument)
When searching, YCM opens a prompt buffer at the top of the screen for the
input, and puts you in insert mode. This means that you can hit <Esc>
to go
into normal mode and use any other input commands that are supported in prompt
buffers. As you type characters, the search is updated.
Intially, results are queried from all open filetypes. You can hit <C-f>
to
switch to just the current filetype while the popup is open.
While the popup is open, the following keys are intercepted:
<C-j>
,<Down>
,<C-n>
,<Tab>
- select the next item<C-k>
,<Up>
,<C-p>
,<S-Tab>
- select the previous item<PageUp>
,<kPageUp>
- jump up one screenful of items<PageDown>
,<kPageDown>
- jump down one screenful of items<Home>
,<kHome>
- jump to first item<End>
,<kEnd>
- jump to last item<CR>
- jump to the selected item<C-c>
cancel/dismiss the popup<C-f>
- toggle results from all file types or just the current filetype
The search is also cancelled if you leave the prompt buffer window at any time,
so you can use window commands <C-w>...
for example.
NOTE: Pressing <Esc>
does not close the popup - you must use Ctrl-c
for that, or use a window command (e.g. <Ctrl-w>j
) or the mouse to leave the
prompt buffer window.
If the ycmd completion server suddenly stops for some reason, you can restart it with this command.
Calling this command will force YCM to immediately recompile your file and display any new diagnostics it encounters. Do note that recompilation with this command may take a while and during this time the Vim GUI will be blocked.
You may want to map this command to a key; try putting nnoremap <F5> :YcmForceCompileAndDiagnostics<CR>
in your vimrc.
Calling this command will fill Vim's locationlist
with errors or warnings if
any were detected in your file and then open it. If a given error or warning can
be fixed by a call to :YcmCompleter FixIt
, then (FixIt available)
is
appended to the error or warning text. See the FixIt
completer subcommand for
more information.
NOTE: The absence of (FixIt available)
does not strictly imply a fix-it
is not available as not all completers are able to provide this indication. For
example, the c-sharp completer provides many fix-its but does not add this
additional indication.
The g:ycm_open_loclist_on_ycm_diags
option can be used to prevent the location
list from opening, but still have it filled with new diagnostic data. See the
Options section for details.
This command shows the full diagnostic text when the user's cursor is on the line with the diagnostic.
An options argument can be passed. If the argument is popup
the diagnostic
text will be displayed in a popup at cursor position.
If you prefer the detailed diagnostic to always be shown in a popup, then
let g:ycm_show_detailed_diag_in_popup=1
.
This will print out various debug information for the current file. Useful to see what compile commands will be used for the file if you're using the semantic completion engine.
This command presents the list of logfiles created by YCM, the ycmd
server, and the semantic engine server for the current filetype, if any.
One of these logfiles can be opened in the editor (or closed if already open) by
entering the corresponding number or by clicking on it with the mouse.
Additionally, this command can take the logfile names as arguments. Use the
<TAB>
key (or any other key defined by the wildchar
option) to complete the
arguments or to cycle through them (depending on the value of the wildmode
option). Each logfile given as an argument is directly opened (or closed if
already open) in the editor. Only for debugging purposes.
This command gives access to a number of additional IDE-like features in YCM, for things like semantic GoTo, type information, FixIt and refactoring.
This command accepts a range that can either be specified through a selection in
one of Vim's visual modes (see :h visual-use
) or on the command line. For
instance, :2,5YcmCompleter
will apply the command from line 2 to line 5. This
is useful for the Format
subcommand.
Call YcmCompleter
without further arguments for a list of the commands you can
call for the current completer.
See the file type feature summary for an overview of the features available for each file type. See the YcmCompleter subcommands section for more information on the available subcommands and their usage.
NOTE: See the docs for the YcmCompleter
command before tackling this
section.
The invoked subcommand is automatically routed to the currently active semantic
completer, so :YcmCompleter GoToDefinition
will invoke the GoToDefinition
subcommand on the Python semantic completer if the currently active file is a
Python one and on the Clang completer if the currently active file is a C-family
language one.
You may also want to map the subcommands to something less verbose; for
instance, nnoremap <leader>jd :YcmCompleter GoTo<CR>
maps the <leader>jd
sequence to the longer subcommand invocation.
These commands are useful for jumping around and exploring code. When moving
the cursor, the subcommands add entries to Vim's jumplist
so you can use
CTRL-O
to jump back to where you were before invoking the command (and
CTRL-I
to jump forward; see :h jumplist
for details). If there is more
than one destination, the quickfix list (see :h quickfix
) is populated with
the available locations and opened to full width at the bottom of the screen.
You can change this behavior by using the YcmQuickFixOpened
autocommand.
Looks up the current line for a header and jumps to it.
Supported in filetypes: c, cpp, objc, objcpp, cuda
Looks up the symbol under the cursor and jumps to its declaration.
Supported in filetypes: c, cpp, objc, objcpp, cuda, cs, go, java, javascript, python, rust, typescript
Looks up the symbol under the cursor and jumps to its definition.
NOTE: For C-family languages this only works in certain situations,
namely when the definition of the symbol is in the current translation unit. A
translation unit consists of the file you are editing and all the files you are
including with #include
directives (directly or indirectly) in that file.
Supported in filetypes: c, cpp, objc, objcpp, cuda, cs, go, java, javascript, python, rust, typescript
This command tries to perform the "most sensible" GoTo operation it can. Currently, this means that it tries to look up the symbol under the cursor and jumps to its definition if possible; if the definition is not accessible from the current translation unit, jumps to the symbol's declaration. For C-family languages, it first tries to look up the current line for a header and jump to it. For C#, implementations are also considered and preferred.
Supported in filetypes: c, cpp, objc, objcpp, cuda, cs, go, java, javascript, python, rust, typescript
WARNING: This command trades correctness for speed!
Same as the GoTo
command except that it doesn't recompile the file with
libclang before looking up nodes in the AST. This can be very useful when you're
editing files that take long to compile but you know that you haven't made any
changes since the last parse that would lead to incorrect jumps. When you're
just browsing around your codebase, this command can spare you quite a bit of
latency.
Supported in filetypes: c, cpp, objc, objcpp, cuda
Finds the definition of all symbols matching a specified string. Note that this does not use any sort of smart/fuzzy matching. However, an interactive symbol search is also available.
Supported in filetypes: c, cpp, objc, objcpp, cuda, cs, java, javascript, python, typescript
This command attempts to find all of the references within the project to the identifier under the cursor and populates the quickfix list with those locations.
Supported in filetypes: c, cpp, objc, objcpp, cuda, java, javascript, python, typescript, rust
Looks up the symbol under the cursor and jumps to its implementation (i.e. non-interface). If there are multiple implementations, instead provides a list of implementations to choose from.
Supported in filetypes: cs, go, java, rust, typescript, javascript
Looks up the symbol under the cursor and jumps to its implementation if one, else jump to its declaration. If there are multiple implementations, instead provides a list of implementations to choose from.
Supported in filetypes: cs
Looks up the symbol under the cursor and jumps to the definition of its type e.g. if the symbol is an object, go to the definition of its class.
Supported in filetypes: go, java, javascript, typescript
Provides a list of symbols in current document, in the quickfix list. See also interactive symbol search.
Supported in filetypes: c, cpp, objc, objcpp, cuda, go, java, rust
Populate the quickfix list with the callers, or callees respectively, of the function associated with the current cursor position. The semantics of this differ depending on the filetype and language server.
Only supported for LSP servers which provide the callHierarchyProvider
capability.
These commands are useful for finding static information about the code, such as the types of variables, viewing declarations and documentation strings.
Echos the type of the variable or method under the cursor, and where it differs, the derived type.
For example:
std::string s;
Invoking this command on s
returns std::string => std::basic_string<char>
NOTE: Causes re-parsing of the current translation unit.
Supported in filetypes: c, cpp, objc, objcpp, cuda, java, javascript, go, python, typescript, rust
WARNING: This command trades correctness for speed!
Same as the GetType
command except that it doesn't recompile the file with
libclang before looking up nodes in the AST. This can be very useful when you're
editing files that take long to compile but you know that you haven't made any
changes since the last parse that would lead to incorrect type. When you're
just browsing around your codebase, this command can spare you quite a bit of
latency.
Supported in filetypes: c, cpp, objc, objcpp, cuda
Echos the semantic parent of the point under the cursor.
The semantic parent is the item that semantically contains the given position.
For example:
class C {
void f();
};
void C::f() {
}
In the out-of-line definition of C::f
, the semantic parent is the class C
,
of which this function is a member.
In the example above, both declarations of C::f
have C
as their semantic
context, while the lexical context of the first C::f
is C
and the lexical
context of the second C::f
is the translation unit.
For global declarations, the semantic parent is the translation unit.
NOTE: Causes re-parsing of the current translation unit.
Supported in filetypes: c, cpp, objc, objcpp, cuda
Displays the preview window populated with quick info about the identifier under the cursor. Depending on the file type, this includes things like:
- The type or declaration of identifier,
- Doxygen/javadoc comments,
- Python docstrings,
- etc.
Supported in filetypes: c, cpp, objc, objcpp, cuda, cs, go, java, javascript, python, typescript, rust
WARNING: This command trades correctness for speed!
Same as the GetDoc
command except that it doesn't recompile the file with
libclang before looking up nodes in the AST. This can be very useful when you're
editing files that take long to compile but you know that you haven't made any
changes since the last parse that would lead to incorrect docs. When you're
just browsing around your codebase, this command can spare you quite a bit of
latency.
Supported in filetypes: c, cpp, objc, objcpp, cuda
These commands make changes to your source code in order to perform refactoring or code correction. YouCompleteMe does not perform any action which cannot be undone, and never saves or writes files to the disk.
Where available, attempts to make changes to the buffer to correct diagnostics on the current line. Where multiple suggestions are available (such as when there are multiple ways to resolve a given warning, or where multiple diagnostics are reported for the current line), the options are presented and one can be selected.
Completers which provide diagnostics may also provide trivial modifications to the source in order to correct the diagnostic. Examples include syntax errors such as missing trailing semi-colons, spurious characters, or other errors which the semantic engine can deterministically suggest corrections.
If no fix-it is available for the current line, or there is no diagnostic on the current line, this command has no effect on the current buffer. If any modifications are made, the number of changes made to the buffer is echo'd and the user may use the editor's undo command to revert.
When a diagnostic is available, and g:ycm_echo_current_diagnostic
is enabled,
then the text (FixIt)
is appended to the echo'd diagnostic when the
completer is able to add this indication. The text (FixIt available)
is
also appended to the diagnostic text in the output of the :YcmDiags
command
for any diagnostics with available fix-its (where the completer can provide this
indication).
NOTE: Causes re-parsing of the current translation unit.
Supported in filetypes: c, cpp, objc, objcpp, cuda, cs, go, java, javascript, rust, typescript
In supported file types, this command attempts to perform a semantic rename of the identifier under the cursor. This includes renaming declarations, definitions and usages of the identifier, or any other language-appropriate action. The specific behavior is defined by the semantic engine in use.
Similar to FixIt
, this command applies automatic modifications to your source
files. Rename operations may involve changes to multiple files, which may or may
not be open in Vim buffers at the time. YouCompleteMe handles all of this for
you. The behavior is described in the following section.
Supported in filetypes: c, cpp, objc, objcpp, cuda, java, javascript, python, typescript, rust, cs
The following additional commands are supported for python:
RefactorInline
RefactorExtractVariable
RefactorExtractFunction
See the jedi docs for what they do.
Supported in filetypes: python
When a Refactor or FixIt command touches multiple files, YouCompleteMe attempts to apply those modifications to any existing open, visible buffer in the current tab. If no such buffer can be found, YouCompleteMe opens the file in a new small horizontal split at the top of the current window, applies the change, and then hides the window. NOTE: The buffer remains open, and must be manually saved. A confirmation dialog is opened prior to doing this to remind you that this is about to happen.
Once the modifications have been made, the quickfix list (see :help quickfix
)
is populated with the locations of all modifications. This can be used to review
all automatic changes made by using :copen
. Typically, use the CTRL-W <enter>
combination to open the selected file in a new split. It is possible to
customize how the quickfix window is opened by using the YcmQuickFixOpened
autocommand.
The buffers are not saved automatically. That is, you must save the modified
buffers manually after reviewing the changes from the quickfix list. Changes
can be undone using Vim's powerful undo features (see :help undo
). Note
that Vim's undo is per-buffer, so to undo all changes, the undo commands must
be applied in each modified buffer separately.
NOTE: While applying modifications, Vim may find files which are already
open and have a swap file. The command is aborted if you select Abort or Quit in
any such prompts. This leaves the Refactor operation partially complete and must
be manually corrected using Vim's undo features. The quickfix list is not
populated in this case. Inspect :buffers
or equivalent (see :help buffers
)
to see the buffers that were opened by the command.
This command formats the whole buffer or some part of it according to the value
of the Vim options shiftwidth
and expandtab
(see :h 'sw'
and :h et
respectively). To format a specific part of your document, you can either select
it in one of Vim's visual modes (see :h visual-use
) and run the command or
directly enter the range on the command line, e.g. :2,5YcmCompleter Format
to
format it from line 2 to line 5.
Supported in filetypes: c, cpp, objc, objcpp, cuda, java, javascript, go, typescript, rust, cs
This command removes unused imports and sorts imports in the current file. It can also group imports from the same module in TypeScript and resolves imports in Java.
Supported in filetypes: java, javascript, typescript
These commands are for general administration, rather than IDE-like features. They cover things like the semantic engine server instance and compilation flags.
Some LSP completers (currently only Java completers) support executing server specific commands. Consult the jdt.ls documentation to find out what commands are supported and which arguments are expected.
The support for ExecuteCommand
was implemented to support plugins like
Vimspector to debug java, but isn't limited to that specific use case.
Restarts the downstream semantic engine server for those semantic engines that work as separate servers that YCM talks to.
Supported in filetypes: c, cpp, objc, objcpp, cuda, cs, go, java, javascript, rust, typescript
Instruct the Omnisharp-Roslyn server to clear its cache and reload all files from disk. This is useful when files are added, removed, or renamed in the solution, files are changed outside of Vim, or whenever Omnisharp-Roslyn cache is out-of-sync.
Supported in filetypes: cs
Get the number of YCM Diagnostic errors. If no errors are present, this function returns 0.
For example:
call youcompleteme#GetErrorCount()
Both this function and youcompleteme#GetWarningCount
can be useful when
integrating YCM with other Vim plugins. For example, a lightline user could
add a diagnostics section to their statusline which would display the number of
errors and warnings.
Get the number of YCM Diagnostic warnings. If no warnings are present, this function returns 0.
For example:
call youcompleteme#GetWarningCount()
Run a completer subcommand and return the result as
a string. This can be useful for example to display the GetGoc
output in a
popup window, e.g.:
let s:ycm_hover_popup = -1
function s:Hover()
let response = youcompleteme#GetCommandResponse( 'GetDoc' )
if response == ''
return
endif
call popup_hide( s:ycm_hover_popup )
let s:ycm_hover_popup = popup_atcursor( balloon_split( response ), {} )
endfunction
" CursorHold triggers in normal mode after a delay
autocmd CursorHold * call s:Hover()
" Or, if you prefer, a mapping:
nnoremap <silent> <leader>D :call <SID>Hover()<CR>
NOTE: This is only an example, for real hover support, see
g:ycm_auto_hover
.
If the completer subcommand result is not a string (for example, it's a FixIt or a Location), or if the completer subcommand raises an error, an empty string is returned, so that calling code does not have to check for complex error conditions.
The arguments to the function are the same as the arguments to the
:YcmCompleter
ex command, e.g. the name of the subcommand, followed by any
additional subcommand arguments. As with the YcmCompleter
command, if the
first argument is ft=<filetype>
the request is targeted at the specified
filetype completer. This is an advanced usage and not necessary in most cases.
NOTE: The request is run synchronously and blocks Vim until the response is received, so we do not recommend running this as part of an autocommand that triggers frequently.
This works exactly like youcompleteme#GetCommandResponse
, except that instead
of returning the result, you supply a callback
argument. This argument must be
a FuncRef
to a function taking a single argument response
. This callback
will be called with the command response at some point later, or immediately.
As with youcompleteme#GetCommandResponse()
, this function will call the
callback with ''
(an empty string) if the request is not sent, or if there was
some sort of error.
Here's an example that's similar to the one above:
let s:ycm_hover_popup = -1
function! s:ShowDataPopup( response ) abort
if response == ''
return
endif
call popup_hide( s:ycm_hover_popup )
let s:ycm_hover_popup = popup_atcursor( balloon_split( response ), {} )
endfunction
function! s:GetData() abort
call youcompleteme#GetCommandResponseAsync(
\ function( 's:ShowDataPopup' ),
\ 'GetDoc' )
endfunction
autocommand CursorHold * call s:GetData()
Again, see g:ycm_auto_hover
for proper hover
support.
NOTE: The callback may be called immediately, in the stack frame that called this function.
NOTE: Only one command request can be outstanding at once. Attempting to
request a second responses while the first is outstanding will result in the
second callback being immediately called with ''
.
This User
autocommand is fired when YCM opens the location list window in
response to the YcmDiags
command. By default, the location list window is
opened to the bottom of the current window and its height is set to fit all
entries. This behavior can be overridden by using the YcmLocationOpened
autocommand which is triggered while the cursor is in the location list window.
For instance:
function! s:CustomizeYcmLocationWindow()
" Move the window to the top of the screen.
wincmd K
" Set the window height to 5.
5wincmd _
" Switch back to working window.
wincmd p
endfunction
autocmd User YcmLocationOpened call s:CustomizeYcmLocationWindow()
This User
autocommand is fired when YCM opens the quickfix window in response
to the GoTo*
and RefactorRename
subcommands. By default, the quickfix window
is opened to full width at the bottom of the screen and its height is set to fit
all entries. This behavior can be overridden by using the YcmQuickFixOpened
autocommand which is triggered while the cursor is in the quickfix window. For
instance:
function! s:CustomizeYcmQuickFixWindow()
" Move the window to the top of the screen.
wincmd K
" Set the window height to 5.
5wincmd _
endfunction
autocmd User YcmQuickFixOpened call s:CustomizeYcmQuickFixWindow()
All options have reasonable defaults so if the plug-in works after installation you don't need to change any options. These options can be configured in your vimrc script by including a line like this:
let g:ycm_min_num_of_chars_for_completion = 1
Note that after changing an option in your vimrc script you have to
restart ycmd with the :YcmRestartServer
command for the changes to take
effect.
This option controls the number of characters the user needs to type before
identifier-based completion suggestions are triggered. For example, if the
option is set to 2
, then when the user types a second alphanumeric character
after a whitespace character, completion suggestions will be triggered. This
option is NOT used for semantic completion.
Setting this option to a high number like 99
effectively turns off the
identifier completion engine and just leaves the semantic engine.
Default: 2
let g:ycm_min_num_of_chars_for_completion = 2
This option controls the minimum number of characters that a completion candidate coming from the identifier completer must have to be shown in the popup menu.
A special value of 0
means there is no limit.
NOTE: This option only applies to the identifier completer; it has no effect on the various semantic completers.
Default: 0
let g:ycm_min_num_identifier_candidate_chars = 0
This option controls the maximum number of semantic completion suggestions shown
in the completion menu. This only applies to suggestions from semantic
completion engines; see the g:ycm_max_identifier_candidates
option to limit the number of
suggestions from the identifier-based engine.
A special value of 0
means there is no limit.
NOTE: Setting this option to 0
or to a value greater than 100
is not
recommended as it will slow down completion when there are a very large number
of suggestions.
Default: 50
let g:ycm_max_num_candidates = 50
Some completion engines require completion candidates to be 'resolved' in order
to get detailed info such as inline documentation, method signatures etc. This
information is displayed by YCM in the preview window, or if completeopt
contains popup
, in the info popup next to the completion menu.
By default, if the info popup is in use, and there are more than 10 candidates, YCM will defer resolving candidates until they are selected in the completion menu. Otherwise, YCM must resolve the details upfront, which can be costly.
If neither popup
nor preview
are in completeopt
, YCM disables resolving
altogether as the information would not be displayed.
This setting can be used to override these defaults and controls the number of
completion candidates that should be resolved upfront. Typically users do not
need to change this, as YCM will work out an appropriate value based on your
completeopt
and g:ycm_add_preview_to_completeopt
settings. However, you may
override this calculation by setting this value to a number:
-1
- Resolve all candidates up front0
- Never resolve any candidates up front.> 0
- Resolve up to this many candidates up front. If the number of candidates is greater than this value, no candidates are resolved.
In the later two cases, if completeopt
contains popup
, then candidates are
resolved on demand asynchronously.
Default:
0
if neitherpopup
norpreview
are incompleteopt
.10
ifpopup
is in completeopt.-1
ifpreview
is in completeopt.
Example:
let g:ycm_max_num_candidates_to_detail = 0
This option controls the maximum number of completion suggestions from the identifier-based engine shown in the completion menu.
A special value of 0
means there is no limit.
NOTE: Setting this option to 0
or to a value greater than 100
is not
recommended as it will slow down completion when there are a very large number
of suggestions.
Default: 10
let g:ycm_max_num_identifier_candidates = 10
When set to 0
, this option turns off YCM's identifier completer (the
as-you-type popup) and the semantic triggers (the popup you'd get after typing
.
or ->
in say C++). You can still force semantic completion with the
<C-Space>
shortcut.
If you want to just turn off the identifier completer but keep the semantic
triggers, you should set g:ycm_min_num_of_chars_for_completion
to a high
number like 99
.
Default: 1
let g:ycm_auto_trigger = 1
This option controls for which Vim filetypes (see :h filetype
) should YCM be
turned on. The option value should be a Vim dictionary with keys being filetype
strings (like python
, cpp
, etc.) and values being unimportant (the
dictionary is used like a hash set, meaning that only the keys matter).
The *
key is special and matches all filetypes. By default, the whitelist
contains only this *
key.
YCM also has a g:ycm_filetype_blacklist
option that lists filetypes for which
YCM shouldn't be turned on. YCM will work only in filetypes that both the
whitelist and the blacklist allow (the blacklist "allows" a filetype by not
having it as a key).
For example, let's assume you want YCM to work in files with the cpp
filetype.
The filetype should then be present in the whitelist either directly (cpp
key
in the whitelist) or indirectly through the special *
key. It should not be
present in the blacklist.
Filetypes that are blocked by the either of the lists will be completely ignored by YCM, meaning that neither the identifier-based completion engine nor the semantic engine will operate in them.
You can get the filetype of the current file in Vim with :set ft?
.
Default: {'*': 1}
let g:ycm_filetype_whitelist = {'*': 1}
** Completion in buffers with no filetype **
There is one exception to the above rule. YCM supports completion in buffers
with no filetype set, but this must be explicitly whitelisted. To identify
buffers with no filetype, we use the ycm_nofiletype
pseudo-filetype. To enable
completion in buffers with no filetype, set:
let g:ycm_filetype_whitelist = {
\ '*': 1,
\ 'ycm_nofiletype': 1
\ }
This option controls for which Vim filetypes (see :h filetype
) should YCM be
turned off. The option value should be a Vim dictionary with keys being filetype
strings (like python
, cpp
, etc.) and values being unimportant (the
dictionary is used like a hash set, meaning that only the keys matter).
See the g:ycm_filetype_whitelist
option for more details on how this works.
Default: [see next line]
let g:ycm_filetype_blacklist = {
\ 'tagbar': 1,
\ 'notes': 1,
\ 'markdown': 1,
\ 'netrw': 1,
\ 'unite': 1,
\ 'text': 1,
\ 'vimwiki': 1,
\ 'pandoc': 1,
\ 'infolog': 1,
\ 'leaderf': 1,
\ 'mail': 1
\}
In addition, ycm_nofiletype
(representing buffers with no filetype set)
is blacklisted if ycm_nofiletype
is not explicitly whitelisted (using
g:ycm_filetype_whitelist
).
This option controls for which Vim filetypes (see :h filetype
) should the YCM
semantic completion engine be turned off. The option value should be a Vim
dictionary with keys being filetype strings (like python
, cpp
, etc.) and
values being unimportant (the dictionary is used like a hash set, meaning that
only the keys matter). The listed filetypes will be ignored by the YCM semantic
completion engine, but the identifier-based completion engine will still trigger
in files of those filetypes.
Note that even if semantic completion is not turned off for a specific filetype, you will not get semantic completion if the semantic engine does not support that filetype.
You can get the filetype of the current file in Vim with :set ft?
.
Default: [see next line]
let g:ycm_filetype_specific_completion_to_disable = {
\ 'gitcommit': 1
\}
This option controls for which Vim filetypes (see :h filetype
) should filepath
completion be disabled. The option value should be a Vim dictionary with keys
being filetype strings (like python
, cpp
, etc.) and values being unimportant
(the dictionary is used like a hash set, meaning that only the keys matter).
The *
key is special and matches all filetypes. Use this key if you want to
completely disable filepath completion:
let g:ycm_filepath_blacklist = {'*': 1}
You can get the filetype of the current file in Vim with :set ft?
.
Default: [see next line]
let g:ycm_filepath_blacklist = {
\ 'html': 1,
\ 'jsx': 1,
\ 'xml': 1,
\}
When set, this option turns on YCM's diagnostic display features. See the Diagnostic display section in the User Manual for more details.
Specific parts of the diagnostics UI (like the gutter signs, text highlighting, diagnostic echo and auto location list population) can be individually turned on or off. See the other options below for details.
Note that YCM's diagnostics UI is only supported for C-family languages.
When set, this option also makes YCM remove all Syntastic checkers set for the
c
, cpp
, objc
, objcpp
, and cuda
filetypes since this would conflict
with YCM's own diagnostics UI.
If you're using YCM's identifier completer in C-family languages but cannot use the clang-based semantic completer for those languages and want to use the GCC Syntastic checkers, unset this option.
Default: 1
let g:ycm_show_diagnostics_ui = 1
YCM will use the value of this option as the symbol for errors in the Vim gutter.
This option is part of the Syntastic compatibility layer; if the option is not
set, YCM will fall back to the value of the g:syntastic_error_symbol
option
before using this option's default.
Default: >>
let g:ycm_error_symbol = '>>'
YCM will use the value of this option as the symbol for warnings in the Vim gutter.
This option is part of the Syntastic compatibility layer; if the option is not
set, YCM will fall back to the value of the g:syntastic_warning_symbol
option
before using this option's default.
Default: >>
let g:ycm_warning_symbol = '>>'
When this option is set, YCM will put icons in Vim's gutter on lines that have a
diagnostic set. Turning this off will also turn off the YcmErrorLine
and
YcmWarningLine
highlighting.
This option is part of the Syntastic compatibility layer; if the option is not
set, YCM will fall back to the value of the g:syntastic_enable_signs
option
before using this option's default.
Default: 1
let g:ycm_enable_diagnostic_signs = 1
When this option is set, YCM will highlight regions of text that are related to the diagnostic that is present on a line, if any.
This option is part of the Syntastic compatibility layer; if the option is not
set, YCM will fall back to the value of the g:syntastic_enable_highlighting
option before using this option's default.
Default: 1
let g:ycm_enable_diagnostic_highlighting = 1
When this option is set to 1, YCM will echo the text of the diagnostic present
on the current line when you move your cursor to that line. If a FixIt
is
available for the current diagnostic, then (FixIt)
is appended.
If you have a vim that supports virtual text, you can set this option
to the string virtual-text
, and the diagnostic will be displayed inline with
the text, right aligned in the window and wrapping to the next line if there is
not enough space, for example:
NOTE: It's strongly recommended to also set
g:ycm_update_diagnostics_in_insert_mode
to 0
when using virtual-text
for
diagnostics. This is due to the increased amount distraction provided by
drawing diagnostics next to your input position.
This option is part of the Syntastic compatibility layer; if the option is not
set, YCM will fall back to the value of the g:syntastic_echo_current_error
option before using this option's default.
Default: 1
Valid values:
0
- disabled1
- echo diagnostic to the command area'virtual-text'
- display the dignostic to the right of the line in the window using virtual text
let g:ycm_echo_current_diagnostic = 1
" Or, when you have vim supporting virtual text
let g:ycm_echo_current_diagnostic = 'virtual-text'
This option controls whether or not YCM shows documentation in a popup at the cursor location after a short delay. Only supported in Vim.
When this option is set to 'CursorHold'
, the popup is displayed on the
CursorHold
autocommand. See :help CursorHold
for the details, but this means
that it is displayed after updatetime
milliseconds. When set to an empty
string, the popup is not automatically displayed.
In addition to this setting, there is the <plug>(YCMHover)
mapping, which can
be used to manually trigger or hide the popup (it works like a toggle).
For example:
nmap <leader>D <plug>(YCMHover)
After dismissing the popup with this mapping, it will not be automatically
triggered again until the cursor is moved (i.e. CursorMoved
autocommand).
The displayed documentation depends on what the completer for the current language supports. It's selected heuristically in this order of preference:
GetHover
withmarkdown
syntaxGetDoc
with no syntaxGetType
with the syntax of the current file.
You can customise this by manually setting up b:ycm_hover
to your liking. This
buffer-local variable can be set to a dictionary with the following keys:
command
: The YCM completer subcommand which should be run on hoversyntax
: The syntax to use (as inset syntax=
) in the popup window for highlighting.
For example, to use C/C++ syntax highlighting in the popup for C-family languages, add something like this to your vimrc:
augroup MyYCMCustom
autocmd!
autocmd FileType c,cpp let b:ycm_hover = {
\ 'command': 'GetDoc',
\ 'syntax': &filetype
\ }
augroup END
Default: 'CursorHold'
This option controls which diagnostics will be rendered by YCM. This option holds a dictionary of key-values, where the keys are Vim's filetype strings delimited by commas and values are dictionaries describing the filter.
A filter is a dictionary of key-values, where the keys are the type of filter, and the value is a list of arguments to that filter. In the case of just a single item in the list, you may omit the brackets and just provide the argument directly. If any filter matches a diagnostic, it will be dropped and YCM will not render it.
The following filter types are supported:
- "regex": Accepts a string regular expression. This type matches
when the regex (treated as case-insensitive) is found anywhere in the diagnostic
text (
re.search
, notre.match
) - "level": Accepts a string level, either "warning" or "error." This type
matches when the diagnostic has the same level, that is,
specifying
level: "error"
will remove all errors from the diagnostics.
NOTE: The regex syntax is NOT Vim's, it's Python's.
Default: {}
The following example will do, for java filetype only:
- Remove all error level diagnostics, and,
- Also remove anything that contains
ta<something>co
let g:ycm_filter_diagnostics = {
\ "java": {
\ "regex": [ "ta.+co", ... ],
\ "level": "error",
\ ...
\ }
\ }
When this option is set, YCM will populate the location list automatically every time it gets new diagnostic data. This option is off by default so as not to interfere with other data you might have placed in the location list.
See :help location-list
in Vim to learn more about the location list.
This option is part of the Syntastic compatibility layer; if the option is not
set, YCM will fall back to the value of the
g:syntastic_always_populate_loc_list
option before using this option's
default.
Note: if YCM's errors aren't visible, it might be that YCM is updating an older location list. See :help :lhistory
and :lolder
.
Default: 0
let g:ycm_always_populate_location_list = 0
When this option is set, :YcmDiags
will automatically open the location list
after forcing a compilation and filling the list with diagnostic data.
See :help location-list
in Vim to learn more about the location list.
Default: 1
let g:ycm_open_loclist_on_ycm_diags = 1
When this option is set to 1
, YCM will show the completion menu even when
typing inside comments.
Default: 0
let g:ycm_complete_in_comments = 0
When this option is set to 1
, YCM will show the completion menu even when
typing inside strings.
Note that this is turned on by default so that you can use the filename
completion inside strings. This is very useful for instance in C-family files
where typing #include "
will trigger the start of filename completion. If you
turn off this option, you will turn off filename completion in such situations
as well.
Default: 1
let g:ycm_complete_in_strings = 1
When this option is set to 1
, YCM's identifier completer will also collect
identifiers from strings and comments. Otherwise, the text in comments and
strings will be ignored.
Default: 0
let g:ycm_collect_identifiers_from_comments_and_strings = 0
When this option is set to 1
, YCM's identifier completer will also collect
identifiers from tags files. The list of tags files to examine is retrieved from
the tagfiles()
Vim function which examines the tags
Vim option. See :h 'tags'
for details.
YCM will re-index your tags files if it detects that they have been modified.
The only supported tag format is the Exuberant Ctags format. The
format from "plain" ctags is NOT supported. Ctags needs to be called with the
--fields=+l
option (that's a lowercase L
, not a one) because YCM needs the
language:<lang>
field in the tags output.
See the FAQ for pointers if YCM does not appear to read your tag files.
This option is off by default because it makes Vim slower if your tags are on a network directory.
Default: 0
let g:ycm_collect_identifiers_from_tags_files = 0
When this option is set to 1
, YCM's identifier completer will seed its
identifier database with the keywords of the programming language you're
writing.
Since the keywords are extracted from the Vim syntax file for the filetype, all keywords may not be collected, depending on how the syntax file was written. Usually at least 95% of the keywords are successfully extracted.
Default: 0
let g:ycm_seed_identifiers_with_syntax = 0
If you're using semantic completion for C-family files, this option might come
handy; it's a way of sending data from Vim to your Settings
function in
your .ycm_extra_conf.py
file.
This option is supposed to be a list of VimScript expression strings that are
evaluated for every request to the ycmd server and then passed to your
Settings
function as a client_data
keyword argument.
For instance, if you set this option to ['v:version']
, your Settings
function will be called like this:
# The '801' value is of course contingent on Vim 8.1; in 8.0 it would be '800'
Settings( ..., client_data = { 'v:version': 801 } )
So the client_data
parameter is a dictionary mapping Vim expression strings to
their values at the time of the request.
The correct way to define parameters for your Settings
function:
def Settings( **kwargs ):
You can then get to client_data
with kwargs['client_data']
.
Default: []
let g:ycm_extra_conf_vim_data = []
YCM will by default search for an appropriate Python interpreter on your system. You can use this option to override that behavior and force the use of a specific interpreter of your choosing.
NOTE: This interpreter is only used for the ycmd server. The YCM client running inside Vim always uses the Python interpreter that's embedded inside Vim.
Default: ''
let g:ycm_server_python_interpreter = ''
When this option is set to 1
, YCM and the ycmd completion server will
keep the logfiles around after shutting down (they are deleted on shutdown by
default).
To see where the logfiles are, call :YcmDebugInfo
.
Default: 0
let g:ycm_keep_logfiles = 0
The logging level that YCM and the ycmd completion server use. Valid values are the following, from most verbose to least verbose:
debug
info
warning
error
critical
Note that debug
is very verbose.
Default: info
let g:ycm_log_level = 'info'
When set to 1
, the OmniSharp-Roslyn server will be automatically started
(once per Vim session) when you open a C# file.
Default: 1
let g:ycm_auto_start_csharp_server = 1
When set to 1
, the OmniSharp-Roslyn server will be automatically stopped upon
closing Vim.
Default: 1
let g:ycm_auto_stop_csharp_server = 1
When g:ycm_auto_start_csharp_server is set to 1
, specifies the port for
the OmniSharp-Roslyn server to listen on. When set to 0
uses an unused port provided
by the OS.
Default: 0
let g:ycm_csharp_server_port = 0
By default, when YCM inserts a namespace, it will insert the using
statement
under the nearest using
statement. You may prefer that the using
statement is
inserted somewhere, for example, to preserve sorting. If so, you can set this
option to override this behavior.
When this option is set, instead of inserting the using
statement itself, YCM
will set the global variable g:ycm_namespace_to_insert
to the namespace to
insert, and then evaluate this option's value as an expression. The option's
expression is responsible for inserting the namespace - the default insertion
will not occur.
Default: ''
let g:ycm_csharp_insert_namespace_expr = ''
When this option is set to 1
, YCM will add the preview
string to Vim's
completeopt
option (see :h completeopt
). If your completeopt
option
already has preview
set, there will be no effect. Alternatively, when set to
popup
and your version of Vim supports popup windows (see :help popup
), the
popup
string will be used instead. You can see the current state of your
completeopt
setting with :set completeopt?
(yes, the question mark is
important).
When preview
is present in completeopt
, YCM will use the preview
window at
the top of the file to store detailed information about the current completion
candidate (but only if the candidate came from the semantic engine). For
instance, it would show the full function prototype and all the function
overloads in the window if the current completion is a function name.
When popup
is present in completeopt
, YCM will instead use a popup
window to the side of the completion popup for storing detailed information
about the current completion candidate. In addition, YCM may truncate the
detailed completion information in order to give the popup sufficient room
to display that detailed information.
Default: 0
let g:ycm_add_preview_to_completeopt = 0
When this option is set to 1
, YCM will auto-close the preview
window after
the user accepts the offered completion string. If there is no preview
window
triggered because there is no preview
string in completeopt
, this option is
irrelevant. See the g:ycm_add_preview_to_completeopt
option for more details.
Default: 0
let g:ycm_autoclose_preview_window_after_completion = 0
When this option is set to 1
, YCM will auto-close the preview
window after
the user leaves insert mode. This option is irrelevant if
g:ycm_autoclose_preview_window_after_completion
is set or if no preview
window is triggered. See the g:ycm_add_preview_to_completeopt
option for more
details.
Default: 0
let g:ycm_autoclose_preview_window_after_insertion = 0
This option controls the maximum number of diagnostics shown to the user when errors or warnings are detected in the file. This option is only relevant for the C-family, C#, Java, JavaScript, and TypeScript languages.
A special value of 0
means there is no limit.
Default: 30
let g:ycm_max_diagnostics_to_display = 30
This option controls the key mappings used to select the first completion string. Invoking any of them repeatedly cycles forward through the completion list.
Some users like adding <Enter>
to this list.
Default: ['<TAB>', '<Down>']
let g:ycm_key_list_select_completion = ['<TAB>', '<Down>']
This option controls the key mappings used to select the previous completion string. Invoking any of them repeatedly cycles backwards through the completion list.
Note that one of the defaults is <S-TAB>
which means Shift-TAB. That mapping
will probably only work in GUI Vim (Gvim or MacVim) and not in plain console Vim
because the terminal usually does not forward modifier key combinations to Vim.
Default: ['<S-TAB>', '<Up>']
let g:ycm_key_list_previous_completion = ['<S-TAB>', '<Up>']
This option controls the key mappings used to close the completion menu. This is
useful when the menu is blocking the view, when you need to insert the <TAB>
character, or when you want to expand a snippet from UltiSnips and navigate
through it.
Default: ['<C-y>']
let g:ycm_key_list_stop_completion = ['<C-y>']
This option controls the key mapping used to invoke the completion menu for
semantic completion. By default, semantic completion is triggered automatically
after typing .
, ->
and ::
in insert mode (if semantic completion support
has been compiled in). This key mapping can be used to trigger semantic
completion anywhere. Useful for searching for top-level functions and classes.
Console Vim (not Gvim or MacVim) passes <Nul>
to Vim when the user types
<C-Space>
so YCM will make sure that <Nul>
is used in the map command when
you're editing in console Vim, and <C-Space>
in GUI Vim. This means that you
can just press <C-Space>
in both console and GUI Vim and YCM will do the right
thing.
Setting this option to an empty string will make sure no mapping is created.
Default: <C-Space>
let g:ycm_key_invoke_completion = '<C-Space>'
This option controls the key mapping used to show the full diagnostic text when
the user's cursor is on the line with the diagnostic. It basically calls
:YcmShowDetailedDiagnostic
.
Setting this option to an empty string will make sure no mapping is created.
If you prefer the detailed diagnostic to be shown in a popup, then
let g:ycm_show_detailed_diag_in_popup=1
.
Default: <leader>d
let g:ycm_key_detailed_diagnostics = '<leader>d'
Makes :YcmShowDetailedDiagnostic
always show in a popup rather than echoing to
the command line.
Default: 0
let g:ycm_show_detailed_diag_in_popup = 0
Normally, YCM searches for a .ycm_extra_conf.py
file for compilation flags
(see the User Guide for more details on how this works). This option specifies
a fallback path to a config file which is used if no .ycm_extra_conf.py
is
found.
You can place such a global file anywhere in your filesystem.
Default: ''
let g:ycm_global_ycm_extra_conf = ''
When this option is set to 1
YCM will ask once per .ycm_extra_conf.py
file
if it is safe to be loaded. This is to prevent execution of malicious code
from a .ycm_extra_conf.py
file you didn't write.
To selectively get YCM to ask/not ask about loading certain .ycm_extra_conf.py
files, see the g:ycm_extra_conf_globlist
option.
Default: 1
let g:ycm_confirm_extra_conf = 1
This option is a list that may contain several globbing patterns. If a pattern
starts with a !
all .ycm_extra_conf.py
files matching that pattern will be
blacklisted, that is they won't be loaded and no confirmation dialog will be
shown. If a pattern does not start with a !
all files matching that pattern
will be whitelisted. Note that this option is not used when confirmation is
disabled using g:ycm_confirm_extra_conf
and that items earlier in the list
will take precedence over the later ones.
Rules:
*
matches everything?
matches any single character[seq]
matches any character in seq[!seq]
matches any char not in seq
Example:
let g:ycm_extra_conf_globlist = ['~/dev/*','!~/*']
- The first rule will match everything contained in the
~/dev
directory so.ycm_extra_conf.py
files from there will be loaded. - The second rule will match everything in the home directory so a
.ycm_extra_conf.py
file from there won't be loaded. - As the first rule takes precedence everything in the home directory excluding
the
~/dev
directory will be blacklisted.
NOTE: The glob pattern is first expanded with Python's
os.path.expanduser()
and then resolved with os.path.abspath()
before being
matched against the filename.
Default: []
let g:ycm_extra_conf_globlist = []
By default, YCM's filepath completion will interpret relative paths like ../
as being relative to the folder of the file of the currently active buffer.
Setting this option will force YCM to always interpret relative paths as being
relative to Vim's current working directory.
Default: 0
let g:ycm_filepath_completion_use_working_dir = 0
This option controls the character-based triggers for the various semantic completion engines. The option holds a dictionary of key-values, where the keys are Vim's filetype strings delimited by commas and values are lists of strings, where the strings are the triggers.
Setting key-value pairs on the dictionary adds semantic triggers to the internal default set (listed below). You cannot remove the default triggers, only add new ones.
A "trigger" is a sequence of one or more characters that trigger semantic
completion when typed. For instance, C++ (cpp
filetype) has .
listed as a
trigger. So when the user types foo.
, the semantic engine will trigger and
serve foo
's list of member functions and variables. Since C++ also has ->
listed as a trigger, the same thing would happen when the user typed foo->
.
It's also possible to use a regular expression as a trigger. You have to prefix
your trigger with re!
to signify it's a regex trigger. For instance,
re!\w+\.
would only trigger after the \w+\.
regex matches.
NOTE: The regex syntax is NOT Vim's, it's Python's.
Default: [see next line]
let g:ycm_semantic_triggers = {
\ 'c': ['->', '.'],
\ 'objc': ['->', '.', 're!\[[_a-zA-Z]+\w*\s', 're!^\s*[^\W\d]\w*\s',
\ 're!\[.*\]\s'],
\ 'ocaml': ['.', '#'],
\ 'cpp,cuda,objcpp': ['->', '.', '::'],
\ 'perl': ['->'],
\ 'php': ['->', '::'],
\ 'cs,d,elixir,go,groovy,java,javascript,julia,perl6,python,scala,typescript,vb': ['.'],
\ 'ruby,rust': ['.', '::'],
\ 'lua': ['.', ':'],
\ 'erlang': [':'],
\ }
Some omnicompletion engines do not work well with the YCM cache—in particular, they might not produce all possible results for a given prefix. By unsetting this option you can ensure that the omnicompletion engine is re-queried on every keypress. That will ensure all completions will be presented, but might cause stuttering and lagginess if the omnifunc is slow.
Default: 1
let g:ycm_cache_omnifunc = 1
By default, YCM will query the UltiSnips plugin for possible completions of snippet triggers. This option can turn that behavior off.
Default: 1
let g:ycm_use_ultisnips_completer = 1
Defines where GoTo*
commands result should be opened. Can take one of the
following values: 'same-buffer'
, 'split'
, or 'split-or-existing-window'
.
If this option is set to the 'same-buffer'
but current buffer can not be
switched (when buffer is modified and nohidden
option is set), then result
will be opened in a split. When the option is set to
'split-or-existing-window'
, if the result is already open in a window of the
current tab page (or any tab pages with the :tab
modifier; see below), it will
jump to that window. Otherwise, the result will be opened in a split as if the
option was set to 'split'
.
To customize the way a new window is split, prefix the GoTo*
command with one
of the following modifiers: :aboveleft
, :belowright
, :botright
,
:leftabove
, :rightbelow
, :topleft
, and :vertical
. For instance, to
split vertically to the right of the current window, run the command:
:rightbelow vertical YcmCompleter GoTo
To open in a new tab page, use the :tab
modifier with the 'split'
or
'split-or-existing-window'
options e.g.:
:tab YcmCompleter GoTo
Default: 'same-buffer'
let g:ycm_goto_buffer_command = 'same-buffer'
Defines the max size (in Kb) for a file to be considered for completion. If this option is set to 0 then no check is made on the size of the file you're opening.
Default: 1000
let g:ycm_disable_for_files_larger_than_kb = 1000
This option controls whether clangd should be used as completion engine for
C-family languages. Can take one of the following values: 1
, 0
, with
meanings:
1
: YCM will use clangd if clangd binary exists in third party or it was provided withycm_clangd_binary_path
option.0
: YCM will never use clangd completer.
Default: 1
let g:ycm_use_clangd = 1
When ycm_use_clangd
option is set to 1
, this option sets the path to
clangd binary.
Default: ''
let g:ycm_clangd_binary_path = ''
This option controls the command line arguments passed to the clangd binary. It appends new options and overrides the existing ones.
Default: []
let g:ycm_clangd_args = []
This option controls which ranking and filtering algorithm to use for completion items. It can take values:
1
: Uses ycmd's caching and filtering logic.0
: Uses clangd's caching and filtering logic.
Default: 1
let g:ycm_clangd_uses_ycmd_caching = 1
This option lets YCM use an arbitrary Language Server Protocol (LSP) server, not unlike many other completion systems. The officially supported completers are favoured over custom LSP ones, so overriding an existing completer means first making sure YCM won't choose that existing completer in the first place.
A simple working example of this option can be found in the section called "Semantic Completion for Other Languages".
Many working examples can be found in the YCM lsp-examples repo.
Default: []
let g:ycm_language_server = []
This option allows you to disable all signature help for all completion engines. There is no way to disable it per-completer. This option is reserved, meaning that while signature help support remains experimental, its values and meaning may change and it may be removed in a future version.
Default: 0
" Disable signature help
let g:ycm_disable_signature_help = 1
In case the system-wide gopls
binary is newer than the bundled one, setting
this option to the path of the system-wide gopls
would make YCM use that one
instead.
If the path is just gopls
, YCM will search in $PATH
.
Similar to the g:ycm_clangd_args
, this option allows
passing additional flags to the gopls
command line.
Default: []
let g:ycm_gopls_args = []
YCM no longer uses RLS for rust, and these options are therefore no longer supported.
To use a custom rust-analyzer, see g:ycm_rust_toolchain_root
.
Optionally specify the path to a custom rust toolchain including at least a
supported version of rust-analyzer
.
Similar to the gopls
path, this option
tells YCM where is the TSServer executable located.
Similar to the gopls
path, this option
tells YCM where is the Omnisharp-Roslyn executable located.
With async diagnostics, LSP servers might send new diagnostics mid-typing. If seeing these new diagnostics while typing is not desired, this option can be set to 0.
In addition, this option is recommended when g:ycm_echo_current_diagnostic
is
set to virtual-text
as it prevents updating the virtual text while you are
typing.
Default: 1
let g:ycm_update_diagnostics_in_insert_mode = 1
The FAQ section has been moved to the wiki.
Please note that this project is released with a Contributor Code of Conduct. By participating in this project you agree to abide by its terms.
If you have questions about the plugin or need help, please join the Gitter room or use the ycm-users mailing list.
If you have bug reports or feature suggestions, please use the issue tracker. Before you do, please carefully read CONTRIBUTING.md as this asks for important diagnostics which the team will use to help get you going.
The latest version of the plugin is available at https://ycm-core.github.io/YouCompleteMe/.
The author's homepage is https://val.markovic.io.
Please do NOT go to #vim on freenode for support. Please contact the YouCompleteMe maintainers directly using the contact details.
This software is licensed under the GPL v3 license. © 2015-2018 YouCompleteMe contributors
If you like YCM so much that you're wiling to part with your hard-earned cash, please consider donating to one of the following charities, which are meaningful to the current maintainers (in no particular order):
- Greyhound Rescue Wales
- Be Humane
- Cancer Research UK
- ICCF Holland
- Any charity of your choosing.
Please note: The YCM maintainers do not specifically endorse nor necessarily have any relationship with the above charities. Disclosure: It is noted that one key maintainer is family with Trustees of Greyhound Rescue Wales.