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*lua.txt* Nvim
NVIM REFERENCE MANUAL
Lua engine *lua* *Lua*
Type |gO| to see the table of contents.
==============================================================================
Introduction *lua-intro*
The Lua 5.1 language is builtin and always available. Try this command to get
an idea of what lurks beneath: >
:lua print(vim.inspect(package.loaded))
Nvim includes a "standard library" |lua-stdlib| for Lua. It complements the
"editor stdlib" (|functions| and Ex commands) and the |API|, all of which can
be used from Lua code.
Module conflicts are resolved by "last wins". For example if both of these
are on 'runtimepath':
runtime/lua/foo.lua
~/.config/nvim/lua/foo.lua
then `require('foo')` loads "~/.config/nvim/lua/foo.lua", and
"runtime/lua/foo.lua" is not used. See |lua-require| to understand how Nvim
finds and loads Lua modules. The conventions are similar to VimL plugins,
with some extra features. See |lua-require-example| for a walkthrough.
==============================================================================
Importing Lua modules *lua-require*
*lua-package-path*
Nvim automatically adjusts `package.path` and `package.cpath` according to
effective 'runtimepath' value. Adjustment happens whenever 'runtimepath' is
changed. `package.path` is adjusted by simply appending `/lua/?.lua` and
`/lua/?/init.lua` to each directory from 'runtimepath' (`/` is actually the
first character of `package.config`).
Similarly to `package.path`, modified directories from 'runtimepath' are also
added to `package.cpath`. In this case, instead of appending `/lua/?.lua` and
`/lua/?/init.lua` to each runtimepath, all unique `?`-containing suffixes of
the existing `package.cpath` are used. Example:
1. Given that
- 'runtimepath' contains `/foo/bar,/xxx;yyy/baz,/abc`;
- initial (defined at compile-time or derived from
`$LUA_CPATH`/`$LUA_INIT`) `package.cpath` contains
`./?.so;/def/ghi/a?d/j/g.elf;/def/?.so`.
2. It finds `?`-containing suffixes `/?.so`, `/a?d/j/g.elf` and `/?.so`, in
order: parts of the path starting from the first path component containing
question mark and preceding path separator.
3. The suffix of `/def/?.so`, namely `/?.so` is not unique, as its the same
as the suffix of the first path from `package.path` (i.e. `./?.so`). Which
leaves `/?.so` and `/a?d/j/g.elf`, in this order.
4. 'runtimepath' has three paths: `/foo/bar`, `/xxx;yyy/baz` and `/abc`. The
second one contains semicolon which is a paths separator so it is out,
leaving only `/foo/bar` and `/abc`, in order.
5. The cartesian product of paths from 4. and suffixes from 3. is taken,
giving four variants. In each variant `/lua` path segment is inserted
between path and suffix, leaving
- `/foo/bar/lua/?.so`
- `/foo/bar/lua/a?d/j/g.elf`
- `/abc/lua/?.so`
- `/abc/lua/a?d/j/g.elf`
6. New paths are prepended to the original `package.cpath`.
The result will look like this:
`/foo/bar,/xxx;yyy/baz,/abc` ('runtimepath')
× `./?.so;/def/ghi/a?d/j/g.elf;/def/?.so` (`package.cpath`)
= `/foo/bar/lua/?.so;/foo/bar/lua/a?d/j/g.elf;/abc/lua/?.so;/abc/lua/a?d/j/g.elf;./?.so;/def/ghi/a?d/j/g.elf;/def/?.so`
Note:
- To track 'runtimepath' updates, paths added at previous update are
remembered and removed at the next update, while all paths derived from the
new 'runtimepath' are prepended as described above. This allows removing
paths when path is removed from 'runtimepath', adding paths when they are
added and reordering `package.path`/`package.cpath` content if 'runtimepath'
was reordered.
- Although adjustments happen automatically, Nvim does not track current
values of `package.path` or `package.cpath`. If you happen to delete some
paths from there you can set 'runtimepath' to trigger an update: >
let &runtimepath = &runtimepath
- Skipping paths from 'runtimepath' which contain semicolons applies both to
`package.path` and `package.cpath`. Given that there are some badly written
plugins using shell which will not work with paths containing semicolons it
is better to not have them in 'runtimepath' at all.
------------------------------------------------------------------------------
LUA PLUGIN EXAMPLE *lua-require-example*
The following example plugin adds a command `:MakeCharBlob` which transforms
current buffer into a long `unsigned char` array. Lua contains transformation
function in a module `lua/charblob.lua` which is imported in
`autoload/charblob.vim` (`require("charblob")`). Example plugin is supposed
to be put into any directory from 'runtimepath', e.g. `~/.config/nvim` (in
this case `lua/charblob.lua` means `~/.config/nvim/lua/charblob.lua`).
autoload/charblob.vim: >
function charblob#encode_buffer()
call setline(1, luaeval(
\ 'require("charblob").encode(unpack(_A))',
\ [getline(1, '$'), &textwidth, ' ']))
endfunction
plugin/charblob.vim: >
if exists('g:charblob_loaded')
finish
endif
let g:charblob_loaded = 1
command MakeCharBlob :call charblob#encode_buffer()
lua/charblob.lua: >
local function charblob_bytes_iter(lines)
local init_s = {
next_line_idx = 1,
next_byte_idx = 1,
lines = lines,
}
local function next(s, _)
if lines[s.next_line_idx] == nil then
return nil
end
if s.next_byte_idx > #(lines[s.next_line_idx]) then
s.next_line_idx = s.next_line_idx + 1
s.next_byte_idx = 1
return ('\n'):byte()
end
local ret = lines[s.next_line_idx]:byte(s.next_byte_idx)
if ret == ('\n'):byte() then
ret = 0 -- See :h NL-used-for-NUL.
end
s.next_byte_idx = s.next_byte_idx + 1
return ret
end
return next, init_s, nil
end
local function charblob_encode(lines, textwidth, indent)
local ret = {
'const unsigned char blob[] = {',
indent,
}
for byte in charblob_bytes_iter(lines) do
-- .- space + number (width 3) + comma
if #(ret[#ret]) + 5 > textwidth then
ret[#ret + 1] = indent
else
ret[#ret] = ret[#ret] .. ' '
end
ret[#ret] = ret[#ret] .. (('%3u,'):format(byte))
end
ret[#ret + 1] = '};'
return ret
end
return {
bytes_iter = charblob_bytes_iter,
encode = charblob_encode,
}
==============================================================================
Commands *lua-commands*
These commands execute a Lua chunk from either the command line (:lua, :luado)
or a file (:luafile) on the given line [range]. As always in Lua, each chunk
has its own scope (closure), so only global variables are shared between
command calls. The |lua-stdlib| modules, user modules, and anything else on
|lua-package-path| are available.
The Lua print() function redirects its output to the Nvim message area, with
arguments separated by " " (space) instead of "\t" (tab).
*:lua*
:[range]lua {chunk}
Executes Lua chunk {chunk}.
Examples: >
:lua vim.api.nvim_command('echo "Hello, Nvim!"')
< To see the Lua version: >
:lua print(_VERSION)
< To see the LuaJIT version: >
:lua print(jit.version)
<
*:lua-heredoc*
:[range]lua << [endmarker]
{script}
{endmarker}
Executes Lua script {script} from within Vimscript.
{endmarker} must NOT be preceded by whitespace. You
can omit [endmarker] after the "<<" and use a dot "."
after {script} (similar to |:append|, |:insert|).
Example:
>
function! CurrentLineInfo()
lua << EOF
local linenr = vim.api.nvim_win_get_cursor(0)[1]
local curline = vim.api.nvim_buf_get_lines(
0, linenr, linenr + 1, false)[1]
print(string.format("Current line [%d] has %d bytes",
linenr, #curline))
EOF
endfunction
< Note that the `local` variables will disappear when
the block finishes. But not globals.
*:luado*
:[range]luado {body} Executes Lua chunk "function(line, linenr) {body} end"
for each buffer line in [range], where `line` is the
current line text (without <EOL>), and `linenr` is the
current line number. If the function returns a string
that becomes the text of the corresponding buffer
line. Default [range] is the whole file: "1,$".
Examples:
>
:luado return string.format("%s\t%d", line:reverse(), #line)
:lua require"lpeg"
:lua -- balanced parenthesis grammar:
:lua bp = lpeg.P{ "(" * ((1 - lpeg.S"()") + lpeg.V(1))^0 * ")" }
:luado if bp:match(line) then return "-->\t" .. line end
<
*:luafile*
:[range]luafile {file}
Execute Lua script in {file}.
The whole argument is used as a single file name.
Examples:
>
:luafile script.lua
:luafile %
<
==============================================================================
luaeval() *lua-eval* *luaeval()*
The (dual) equivalent of "vim.eval" for passing Lua values to Nvim is
"luaeval". "luaeval" takes an expression string and an optional argument used
for _A inside expression and returns the result of the expression. It is
semantically equivalent in Lua to:
>
local chunkheader = "local _A = select(1, ...) return "
function luaeval (expstr, arg)
local chunk = assert(loadstring(chunkheader .. expstr, "luaeval"))
return chunk(arg) -- return typval
end
Lua nils, numbers, strings, tables and booleans are converted to their
respective VimL types. An error is thrown if conversion of any other Lua types
is attempted.
The magic global "_A" contains the second argument to luaeval().
Example: >
:echo luaeval('_A[1] + _A[2]', [40, 2])
42
:echo luaeval('string.match(_A, "[a-z]+")', 'XYXfoo123')
foo
Lua tables are used as both dictionaries and lists, so it is impossible to
determine whether empty table is meant to be empty list or empty dictionary.
Additionally Lua does not have integer numbers. To distinguish between these
cases there is the following agreement:
0. Empty table is empty list.
1. Table with N incrementally growing integral numbers, starting from 1 and
ending with N is considered to be a list.
2. Table with string keys, none of which contains NUL byte, is considered to
be a dictionary.
3. Table with string keys, at least one of which contains NUL byte, is also
considered to be a dictionary, but this time it is converted to
a |msgpack-special-map|.
*lua-special-tbl*
4. Table with `vim.type_idx` key may be a dictionary, a list or floating-point
value:
- `{[vim.type_idx]=vim.types.float, [vim.val_idx]=1}` is converted to
a floating-point 1.0. Note that by default integral Lua numbers are
converted to |Number|s, non-integral are converted to |Float|s. This
variant allows integral |Float|s.
- `{[vim.type_idx]=vim.types.dictionary}` is converted to an empty
dictionary, `{[vim.type_idx]=vim.types.dictionary, [42]=1, a=2}` is
converted to a dictionary `{'a': 42}`: non-string keys are ignored.
Without `vim.type_idx` key tables with keys not fitting in 1., 2. or 3.
are errors.
- `{[vim.type_idx]=vim.types.list}` is converted to an empty list. As well
as `{[vim.type_idx]=vim.types.list, [42]=1}`: integral keys that do not
form a 1-step sequence from 1 to N are ignored, as well as all
non-integral keys.
Examples: >
:echo luaeval('math.pi')
:function Rand(x,y) " random uniform between x and y
: return luaeval('(_A.y-_A.x)*math.random()+_A.x', {'x':a:x,'y':a:y})
: endfunction
:echo Rand(1,10)
Note: second argument to `luaeval` undergoes VimL to Lua conversion
("marshalled"), so changes to Lua containers do not affect values in VimL.
Return value is also always converted. When converting,
|msgpack-special-dict|s are treated specially.
==============================================================================
Vimscript v:lua interface *v:lua-call*
From Vimscript the special `v:lua` prefix can be used to call Lua functions
which are global or accessible from global tables. The expression >
v:lua.func(arg1, arg2)
is equivalent to the Lua chunk >
return func(...)
where the args are converted to Lua values. The expression >
v:lua.somemod.func(args)
is equivalent to the Lua chunk >
return somemod.func(...)
You can use `v:lua` in "func" options like 'tagfunc', 'omnifunc', etc.
For example consider the following Lua omnifunc handler: >
function mymod.omnifunc(findstart, base)
if findstart == 1 then
return 0
else
return {'stuff', 'steam', 'strange things'}
end
end
vim.api.nvim_buf_set_option(0, 'omnifunc', 'v:lua.mymod.omnifunc')
Note: the module ("mymod" in the above example) must be a Lua global.
Note: `v:lua` without a call is not allowed in a Vimscript expression:
|Funcref|s cannot represent Lua functions. The following are errors: >
let g:Myvar = v:lua.myfunc " Error
call SomeFunc(v:lua.mycallback) " Error
let g:foo = v:lua " Error
let g:foo = v:['lua'] " Error
==============================================================================
Lua standard modules *lua-stdlib*
The Nvim Lua "standard library" (stdlib) is the `vim` module, which exposes
various functions and sub-modules. It is always loaded, thus require("vim")
is unnecessary.
You can peek at the module properties: >
:lua print(vim.inspect(vim))
Result is something like this: >
{
_os_proc_children = <function 1>,
_os_proc_info = <function 2>,
...
api = {
nvim__id = <function 5>,
nvim__id_array = <function 6>,
...
},
deepcopy = <function 106>,
gsplit = <function 107>,
...
}
To find documentation on e.g. the "deepcopy" function: >
:help vim.deepcopy()
Note that underscore-prefixed functions (e.g. "_os_proc_children") are
internal/private and must not be used by plugins.
------------------------------------------------------------------------------
VIM.LOOP *lua-loop* *vim.loop*
`vim.loop` exposes all features of the Nvim event-loop. This is a low-level
API that provides functionality for networking, filesystem, and process
management. Try this command to see available functions: >
:lua print(vim.inspect(vim.loop))
Reference: http://docs.libuv.org
Examples: https://github.com/luvit/luv/tree/master/examples
*E5560* *lua-loop-callbacks*
It is an error to directly invoke `vim.api` functions (except |api-fast|) in
`vim.loop` callbacks. For example, this is an error: >
local timer = vim.loop.new_timer()
timer:start(1000, 0, function()
vim.api.nvim_command('echomsg "test"')
end)
To avoid the error use |vim.schedule_wrap()| to defer the callback: >
local timer = vim.loop.new_timer()
timer:start(1000, 0, vim.schedule_wrap(function()
vim.api.nvim_command('echomsg "test"')
end))
Example: repeating timer
1. Save this code to a file.
2. Execute it with ":luafile %". >
-- Create a timer handle (implementation detail: uv_timer_t).
local timer = vim.loop.new_timer()
local i = 0
-- Waits 1000ms, then repeats every 750ms until timer:close().
timer:start(1000, 750, function()
print('timer invoked! i='..tostring(i))
if i > 4 then
timer:close() -- Always close handles to avoid leaks.
end
i = i + 1
end)
print('sleeping');
Example: File-change detection *watch-file*
1. Save this code to a file.
2. Execute it with ":luafile %".
3. Use ":Watch %" to watch any file.
4. Try editing the file from another text editor.
5. Observe that the file reloads in Nvim (because on_change() calls
|:checktime|). >
local w = vim.loop.new_fs_event()
local function on_change(err, fname, status)
-- Do work...
vim.api.nvim_command('checktime')
-- Debounce: stop/start.
w:stop()
watch_file(fname)
end
function watch_file(fname)
local fullpath = vim.api.nvim_call_function(
'fnamemodify', {fname, ':p'})
w:start(fullpath, {}, vim.schedule_wrap(function(...)
on_change(...) end))
end
vim.api.nvim_command(
"command! -nargs=1 Watch call luaeval('watch_file(_A)', expand('<args>'))")
Example: TCP echo-server *tcp-server*
1. Save this code to a file.
2. Execute it with ":luafile %".
3. Note the port number.
4. Connect from any TCP client (e.g. "nc 0.0.0.0 36795"): >
local function create_server(host, port, on_connect)
local server = vim.loop.new_tcp()
server:bind(host, port)
server:listen(128, function(err)
assert(not err, err) -- Check for errors.
local sock = vim.loop.new_tcp()
server:accept(sock) -- Accept client connection.
on_connect(sock) -- Start reading messages.
end)
return server
end
local server = create_server('0.0.0.0', 0, function(sock)
sock:read_start(function(err, chunk)
assert(not err, err) -- Check for errors.
if chunk then
sock:write(chunk) -- Echo received messages to the channel.
else -- EOF (stream closed).
sock:close() -- Always close handles to avoid leaks.
end
end)
end)
print('TCP echo-server listening on port: '..server:getsockname().port)
------------------------------------------------------------------------------
VIM.TREESITTER *lua-treesitter*
Nvim integrates the tree-sitter library for incremental parsing of buffers.
Currently Nvim does not provide the tree-sitter parsers, instead these must
be built separately, for instance using the tree-sitter utility.
The parser is loaded into nvim using >
vim.treesitter.add_language("/path/to/c_parser.so", "c")
<Create a parser for a buffer and a given language (if another plugin uses the
same buffer/language combination, it will be safely reused). Use >
parser = vim.treesitter.get_parser(bufnr, lang)
<`bufnr=0` can be used for current buffer. `lang` will default to 'filetype' (this
doesn't work yet for some filetypes like "cpp") Currently, the parser will be
retained for the lifetime of a buffer but this is subject to change. A plugin
should keep a reference to the parser object as long as it wants incremental
updates.
Whenever you need to access the current syntax tree, parse the buffer: >
tstree = parser:parse()
<This will return an immutable tree that represents the current state of the
buffer. When the plugin wants to access the state after a (possible) edit
it should call `parse()` again. If the buffer wasn't edited, the same tree will
be returned again without extra work. If the buffer was parsed before,
incremental parsing will be done of the changed parts.
NB: to use the parser directly inside a |nvim_buf_attach| Lua callback, you must
call `get_parser()` before you register your callback. But preferably parsing
shouldn't be done directly in the change callback anyway as they will be very
frequent. Rather a plugin that does any kind of analysis on a tree should use
a timer to throttle too frequent updates.
Tree methods *lua-treesitter-tree*
tstree:root() *tstree:root()*
Return the root node of this tree.
Node methods *lua-treesitter-node*
tsnode:parent() *tsnode:parent()*
Get the node's immediate parent.
tsnode:child_count() *tsnode:child_count()*
Get the node's number of children.
tsnode:child(N) *tsnode:child()*
Get the node's child at the given index, where zero represents the
first child.
tsnode:named_child_count() *tsnode:named_child_count()*
Get the node's number of named children.
tsnode:named_child(N) *tsnode:named_child()*
Get the node's named child at the given index, where zero represents
the first named child.
tsnode:start() *tsnode:start()*
Get the node's start position. Return three values: the row, column
and total byte count (all zero-based).
tsnode:end_() *tsnode:end_()*
Get the node's end position. Return three values: the row, column
and total byte count (all zero-based).
tsnode:range() *tsnode:range()*
Get the range of the node. Return four values: the row, column
of the start position, then the row, column of the end position.
tsnode:type() *tsnode:type()*
Get the node's type as a string.
tsnode:symbol() *tsnode:symbol()*
Get the node's type as a numerical id.
tsnode:named() *tsnode:named()*
Check if the node is named. Named nodes correspond to named rules in
the grammar, whereas anonymous nodes correspond to string literals
in the grammar.
tsnode:missing() *tsnode:missing()*
Check if the node is missing. Missing nodes are inserted by the
parser in order to recover from certain kinds of syntax errors.
tsnode:has_error() *tsnode:has_error()*
Check if the node is a syntax error or contains any syntax errors.
tsnode:sexpr() *tsnode:sexpr()*
Get an S-expression representing the node as a string.
tsnode:descendant_for_range(start_row, start_col, end_row, end_col)
*tsnode:descendant_for_range()*
Get the smallest node within this node that spans the given range of
(row, column) positions
tsnode:named_descendant_for_range(start_row, start_col, end_row, end_col)
*tsnode:named_descendant_for_range()*
Get the smallest named node within this node that spans the given
range of (row, column) positions
Query methods *lua-treesitter-query*
Tree-sitter queries are supported, with some limitations. Currently, the only
supported match predicate is `eq?` (both comparing a capture against a string
and two captures against each other).
vim.treesitter.parse_query(lang, query)
*vim.treesitter.parse_query(()*
Parse the query as a string. (If the query is in a file, the caller
should read the contents into a string before calling).
query:iter_captures(node, bufnr, start_row, end_row)
*query:iter_captures()*
Iterate over all captures from all matches inside a `node`.
`bufnr` is needed if the query contains predicates, then the caller
must ensure to use a freshly parsed tree consistent with the current
text of the buffer. `start_row` and `end_row` can be used to limit
matches inside a row range (this is typically used with root node
as the node, i e to get syntax highlight matches in the current
viewport)
The iterator returns two values, a numeric id identifying the capture
and the captured node. The following example shows how to get captures
by name:
>
for id, node in query:iter_captures(tree:root(), bufnr, first, last) do
local name = query.captures[id] -- name of the capture in the query
-- typically useful info about the node:
local type = node:type() -- type of the captured node
local row1, col1, row2, col2 = node:range() -- range of the capture
... use the info here ...
end
<
query:iter_matches(node, bufnr, start_row, end_row)
*query:iter_matches()*
Iterate over all matches within a node. The arguments are the same as
for |query:iter_captures()| but the iterated values are different:
an (1-based) index of the pattern in the query, and a table mapping
capture indices to nodes. If the query has more than one pattern
the capture table might be sparse, and e.g. `pairs` should be used and not
`ipairs`. Here an example iterating over all captures in
every match:
>
for pattern, match in cquery:iter_matches(tree:root(), bufnr, first, last) do
for id,node in pairs(match) do
local name = query.captures[id]
-- `node` was captured by the `name` capture in the match
... use the info here ...
end
end
>
Treesitter syntax highlighting (WIP) *lua-treesitter-highlight*
NOTE: This is a partially implemented feature, and not usable as a default
solution yet. What is documented here is a temporary interface indented
for those who want to experiment with this feature and contribute to
its development.
Highlights are defined in the same query format as in the tree-sitter highlight
crate, which some limitations and additions. Set a highlight query for a
buffer with this code: >
local query = [[
"for" @keyword
"if" @keyword
"return" @keyword
(string_literal) @string
(number_literal) @number
(comment) @comment
(preproc_function_def name: (identifier) @function)
; ... more definitions
]]
highlighter = vim.treesitter.TSHighlighter.new(query, bufnr, lang)
-- alternatively, to use the current buffer and its filetype:
-- highlighter = vim.treesitter.TSHighlighter.new(query)
-- Don't recreate the highlighter for the same buffer, instead
-- modify the query like this:
local query2 = [[ ... ]]
highlighter:set_query(query2)
As mentioned above the supported predicate is currently only `eq?`. `match?`
predicates behave like matching always fails. As an addition a capture which
begin with an upper-case letter like `@WarningMsg` will map directly to this
highlight group, if defined. Also if the predicate begins with upper-case and
contains a dot only the part before the first will be interpreted as the
highlight group. As an example, this warns of a binary expression with two
identical identifiers, highlighting both as |hl-WarningMsg|: >
((binary_expression left: (identifier) @WarningMsg.left right: (identifier) @WarningMsg.right)
(eq? @WarningMsg.left @WarningMsg.right))
------------------------------------------------------------------------------
VIM *lua-builtin*
vim.api.{func}({...}) *vim.api*
Invokes Nvim |API| function {func} with arguments {...}.
Example: call the "nvim_get_current_line()" API function: >
print(tostring(vim.api.nvim_get_current_line()))
vim.call({func}, {...}) *vim.call()*
Invokes |vim-function| or |user-function| {func} with arguments {...}.
See also |vim.fn|. Equivalent to: >
vim.fn[func]({...})
vim.in_fast_event() *vim.in_fast_event()*
Returns true if the code is executing as part of a "fast" event
handler, where most of the API is disabled. These are low-level events
(e.g. |lua-loop-callbacks|) which can be invoked whenever Nvim polls
for input. When this is `false` most API functions are callable (but
may be subject to other restrictions such as |textlock|).
vim.NIL *vim.NIL*
Special value used to represent NIL in msgpack-rpc and |v:null| in
vimL interaction, and similar cases. Lua `nil` cannot be used as
part of a lua table representing a Dictionary or Array, as it
is equivalent to a missing value: `{"foo", nil}` is the same as
`{"foo"}`
vim.empty_dict() *vim.empty_dict()*
Creates a special table which will be converted to an empty
dictionary when converting lua values to vimL or API types. The
table is empty, and this property is marked using a metatable. An
empty table `{}` without this metatable will default to convert to
an array/list.
Note: if numeric keys are added to the table, the metatable will be
ignored and the dict converted to a list/array anyway.
vim.rpcnotify({channel}, {method}[, {args}...]) *vim.rpcnotify()*
Sends {event} to {channel} via |RPC| and returns immediately.
If {channel} is 0, the event is broadcast to all channels.
This function also works in a fast callback |lua-loop-callbacks|.
vim.rpcrequest({channel}, {method}[, {args}...]) *vim.rpcrequest()*
Sends a request to {channel} to invoke {method} via
|RPC| and blocks until a response is received.
Note: NIL values as part of the return value is represented as
|vim.NIL| special value
vim.stricmp({a}, {b}) *vim.stricmp()*
Compares strings case-insensitively. Returns 0, 1 or -1 if strings
are equal, {a} is greater than {b} or {a} is lesser than {b},
respectively.
vim.str_utfindex({str}[, {index}]) *vim.str_utfindex()*
Convert byte index to UTF-32 and UTF-16 indicies. If {index} is not
supplied, the length of the string is used. All indicies are zero-based.
Returns two values: the UTF-32 and UTF-16 indicies respectively.
Embedded NUL bytes are treated as terminating the string. Invalid
UTF-8 bytes, and embedded surrogates are counted as one code
point each. An {index} in the middle of a UTF-8 sequence is rounded
upwards to the end of that sequence.
vim.str_byteindex({str}, {index}[, {use_utf16}]) *vim.str_byteindex()*
Convert UTF-32 or UTF-16 {index} to byte index. If {use_utf16} is not
supplied, it defaults to false (use UTF-32). Returns the byte index.
Invalid UTF-8 and NUL is treated like by |vim.str_byteindex()|. An {index}
in the middle of a UTF-16 sequence is rounded upwards to the end of that
sequence.
vim.schedule({callback}) *vim.schedule()*
Schedules {callback} to be invoked soon by the main event-loop. Useful
to avoid |textlock| or other temporary restrictions.
vim.fn.{func}({...}) *vim.fn*
Invokes |vim-function| or |user-function| {func} with arguments {...}.
To call autoload functions, use the syntax: >
vim.fn['some#function']({...})
<
Unlike vim.api.|nvim_call_function| this converts directly between Vim
objects and Lua objects. If the Vim function returns a float, it will
be represented directly as a Lua number. Empty lists and dictionaries
both are represented by an empty table.
Note: |v:null| values as part of the return value is represented as
|vim.NIL| special value
Note: vim.fn keys are generated lazily, thus `pairs(vim.fn)` only
enumerates functions that were called at least once.
vim.type_idx *vim.type_idx*
Type index for use in |lua-special-tbl|. Specifying one of the
values from |vim.types| allows typing the empty table (it is
unclear whether empty Lua table represents empty list or empty array)
and forcing integral numbers to be |Float|. See |lua-special-tbl| for
more details.
vim.val_idx *vim.val_idx*
Value index for tables representing |Float|s. A table representing
floating-point value 1.0 looks like this: >
{
[vim.type_idx] = vim.types.float,
[vim.val_idx] = 1.0,
}
< See also |vim.type_idx| and |lua-special-tbl|.
vim.types *vim.types*
Table with possible values for |vim.type_idx|. Contains two sets
of key-value pairs: first maps possible values for |vim.type_idx|
to human-readable strings, second maps human-readable type names to
values for |vim.type_idx|. Currently contains pairs for `float`,
`array` and `dictionary` types.
Note: one must expect that values corresponding to `vim.types.float`,
`vim.types.array` and `vim.types.dictionary` fall under only two
following assumptions:
1. Value may serve both as a key and as a value in a table. Given the
properties of Lua tables this basically means “value is not `nil`”.
2. For each value in `vim.types` table `vim.types[vim.types[value]]`
is the same as `value`.
No other restrictions are put on types, and it is not guaranteed that
values corresponding to `vim.types.float`, `vim.types.array` and
`vim.types.dictionary` will not change or that `vim.types` table will
only contain values for these three types.
==============================================================================
Lua module: vim *lua-vim*
inspect({object}, {options}) *vim.inspect()*
Return a human-readable representation of the given object.
See also: ~
https://github.com/kikito/inspect.lua
https://github.com/mpeterv/vinspect
paste({lines}, {phase}) *vim.paste()*
Paste handler, invoked by |nvim_paste()| when a conforming UI
(such as the |TUI|) pastes text into the editor.
Example: To remove ANSI color codes when pasting: >
vim.paste = (function(overridden)
return function(lines, phase)
for i,line in ipairs(lines) do
-- Scrub ANSI color codes from paste input.
lines[i] = line:gsub('\27%[[0-9;mK]+', '')
end
overridden(lines, phase)
end
end)(vim.paste)
<
Parameters: ~
{lines} |readfile()|-style list of lines to paste.
|channel-lines|
{phase} -1: "non-streaming" paste: the call contains all
lines. If paste is "streamed", `phase` indicates the stream state:
• 1: starts the paste (exactly once)
• 2: continues the paste (zero or more times)
• 3: ends the paste (exactly once)
Return: ~
false if client should cancel the paste.
See also: ~
|paste|
schedule_wrap({cb}) *vim.schedule_wrap()*
Defers callback `cb` until the Nvim API is safe to call.
See also: ~
|lua-loop-callbacks|
|vim.schedule()|
|vim.in_fast_event()|
deep_equal({a}, {b}) *vim.deep_equal()*
TODO: Documentation
deepcopy({orig}) *vim.deepcopy()*
Returns a deep copy of the given object. Non-table objects are
copied as in a typical Lua assignment, whereas table objects
are copied recursively.
Parameters: ~
{orig} Table to copy
Return: ~
New table of copied keys and (nested) values.
endswith({s}, {suffix}) *vim.endswith()*
Tests if `s` ends with `suffix` .
Parameters: ~
{s} (string) a string
{suffix} (string) a suffix
Return: ~
(boolean) true if `suffix` is a suffix of s
gsplit({s}, {sep}, {plain}) *vim.gsplit()*
Splits a string at each instance of a separator.
Parameters: ~
{s} String to split
{sep} Separator string or pattern
{plain} If `true` use `sep` literally (passed to
String.find)
Return: ~
Iterator over the split components
See also: ~
|vim.split()|
https://www.lua.org/pil/20.2.html
http://lua-users.org/wiki/StringLibraryTutorial
is_callable({f}) *vim.is_callable()*
Returns true if object `f` can be called as a function.
Parameters: ~
{f} Any object
Return: ~
true if `f` is callable, else false
list_extend({dst}, {src}, {start}, {finish}) *vim.list_extend()*
Extends a list-like table with the values of another list-like
table.
NOTE: This mutates dst!
Parameters: ~
{dst} list which will be modified and appended to.
{src} list from which values will be inserted.
{start} Start index on src. defaults to 1
{finish} Final index on src. defaults to #src
Return: ~
dst
See also: ~
|vim.tbl_extend()|
pesc({s}) *vim.pesc()*
Escapes magic chars in a Lua pattern string.
Parameters: ~
{s} String to escape
Return: ~
%-escaped pattern string
See also: ~
https://github.com/rxi/lume
split({s}, {sep}, {plain}) *vim.split()*
Splits a string at each instance of a separator.
Examples: >
split(":aa::b:", ":") --> {'','aa','','bb',''}
split("axaby", "ab?") --> {'','x','y'}
split(x*yz*o, "*", true) --> {'x','yz','o'}
<
Parameters: ~
{s} String to split
{sep} Separator string or pattern
{plain} If `true` use `sep` literally (passed to
String.find)
Return: ~
List-like table of the split components.
See also: ~
|vim.gsplit()|
startswith({s}, {prefix}) *vim.startswith()*
Tests if `s` starts with `prefix` .
Parameters: ~
{s} (string) a string
{prefix} (string) a prefix
Return: ~
(boolean) true if `prefix` is a prefix of s
tbl_add_reverse_lookup({o}) *vim.tbl_add_reverse_lookup()*
Add the reverse lookup values to an existing table. For
example: `tbl_add_reverse_lookup { A = 1 } == { [1] = 'A', A =
1 }`
Parameters: ~
{o} table The table to add the reverse to.
tbl_contains({t}, {value}) *vim.tbl_contains()*
Checks if a list-like (vector) table contains `value` .
Parameters: ~
{t} Table to check
{value} Value to compare
Return: ~
true if `t` contains `value`
tbl_extend({behavior}, {...}) *vim.tbl_extend()*
Merges two or more map-like tables.
Parameters: ~
{behavior} Decides what to do if a key is found in more
than one map:
• "error": raise an error
• "keep": use value from the leftmost map
• "force": use value from the rightmost map
{...} Two or more map-like tables.
See also: ~
|extend()|
tbl_flatten({t}) *vim.tbl_flatten()*
Creates a copy of a list-like table such that any nested
tables are "unrolled" and appended to the result.
Parameters: ~
{t} List-like table
Return: ~
Flattened copy of the given list-like table.
See also: ~
Fromhttps://github.com/premake/premake-core/blob/master/src/base/table.lua
tbl_isempty({t}) *vim.tbl_isempty()*
See also: ~
Fromhttps://github.com/premake/premake-core/blob/master/src/base/table.lua@paramt Table to check
tbl_islist({t}) *vim.tbl_islist()*
Table
Return: ~
true: A non-empty array, false: A non-empty table, nil: An
empty table
tbl_keys({t}) *vim.tbl_keys()*
Return a list of all keys used in a table. However, the order
of the return table of keys is not guaranteed.
Parameters: ~
{t} Table
Return: ~
list of keys
See also: ~
Fromhttps://github.com/premake/premake-core/blob/master/src/base/table.lua
tbl_values({t}) *vim.tbl_values()*
Return a list of all values used in a table. However, the
order of the return table of values is not guaranteed.
Parameters: ~
{t} Table
Return: ~
list of values
trim({s}) *vim.trim()*
Trim whitespace (Lua pattern "%s") from both sides of a
string.
Parameters: ~
{s} String to trim
Return: ~
String with whitespace removed from its beginning and end
See also: ~
https://www.lua.org/pil/20.2.html
validate({opt}) *vim.validate()*
Validates a parameter specification (types and values).
Usage example: >
function user.new(name, age, hobbies)
vim.validate{
name={name, 'string'},
age={age, 'number'},
hobbies={hobbies, 'table'},
}
...
end
<
Examples with explicit argument values (can be run directly): >
vim.validate{arg1={{'foo'}, 'table'}, arg2={'foo', 'string'}}
=> NOP (success)
<
>
vim.validate{arg1={1, 'table'}}
=> error('arg1: expected table, got number')
<
>
vim.validate{arg1={3, function(a) return (a % 2) == 0 end, 'even number'}}
=> error('arg1: expected even number, got 3')
<
Parameters: ~
{opt} Map of parameter names to validations. Each key is
a parameter name; each value is a tuple in one of
these forms:
1. (arg_value, type_name, optional)
• arg_value: argument value
• type_name: string type name, one of: ("table",
"t", "string", "s", "number", "n", "boolean",
"b", "function", "f", "nil", "thread",
"userdata")
• optional: (optional) boolean, if true, `nil`
is valid
2. (arg_value, fn, msg)
• arg_value: argument value
• fn: any function accepting one argument,
returns true if and only if the argument is
valid
• msg: (optional) error string if validation
fails
vim:tw=78:ts=8:ft=help:norl:
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