path: root/doc/lispref/parsing.texi

@c -*- mode: texinfo; coding: utf-8 -*-
@c This is part of the GNU Emacs Lisp Reference Manual.
@c Copyright (C) 2021--2024 Free Software Foundation, Inc.
@c See the file elisp.texi for copying conditions.
@node Parsing Program Source
@chapter Parsing Program Source

@cindex syntax tree, from parsing program source
Emacs provides various ways to parse program source text and produce a
@dfn{syntax tree}.  In a syntax tree, text is no longer considered a
one-dimensional stream of characters, but a structured tree of nodes,
where each node represents a piece of text.  Thus, a syntax tree can
enable interesting features like precise fontification, indentation,
navigation, structured editing, etc.

Emacs has a simple facility for parsing balanced expressions
(@pxref{Parsing Expressions}).  There is also the SMIE library for
generic navigation and indentation (@pxref{SMIE}).

In addition to those, Emacs also provides integration with
@uref{https://tree-sitter.github.io/tree-sitter, the tree-sitter
library} if support for it was compiled in.  The tree-sitter library
implements an incremental parser and has support for a wide range of
programming languages.

@defun treesit-available-p
This function returns non-@code{nil} if tree-sitter features are
available for the current Emacs session.
@end defun

To be able to parse the program source using the tree-sitter library
and access the syntax tree of the program, a Lisp program needs to
load a language grammar library, and create a parser for that
language and the current buffer.  After that, the Lisp program can
query the parser about specific nodes of the syntax tree.  Then, it
can access various kinds of information about each node, and search
for nodes using a powerful pattern-matching syntax.  This chapter
explains how to do all this, and also how a Lisp program can work with
source files that mix multiple programming languages.

@menu
* Language Grammar::         Loading tree-sitter language grammar.
* Using Parser::             Introduction to parsers.
* Retrieving Nodes::         Retrieving nodes from a syntax tree.
* Accessing Node Information:: Accessing node information.
* Pattern Matching::         Pattern matching with query patterns.
* Multiple Languages::       Parse text written in multiple languages.
* Tree-sitter Major Modes::  Develop major modes using tree-sitter.
* Tree-sitter C API::        Compare the C API and the ELisp API.
@end menu

@node Language Grammar
@section Tree-sitter Language Grammar
@cindex language grammar, for tree-sitter

@heading Loading a language grammar
@cindex loading language grammar for tree-sitter

@cindex language argument, for tree-sitter
Tree-sitter relies on language grammar to parse text in that
language.  In Emacs, a language grammar is represented by a symbol.
For example, the C language grammar is represented as the symbol
@code{c}, and @code{c} can be passed to tree-sitter functions as the
@var{language} argument.

@vindex treesit-extra-load-path
@vindex treesit-load-language-error
Tree-sitter language grammars are distributed as dynamic libraries.
In order to use a language grammar in Emacs, you need to make sure
that the dynamic library is installed on the system.  Emacs looks for
language grammars in several places, in the following order:

@itemize @bullet
@item
first, in the list of directories specified by the variable
@code{treesit-extra-load-path};
@item
then, in the @file{tree-sitter} subdirectory of the directory
specified by @code{user-emacs-directory} (@pxref{Init File});
@item
and finally, in the system's default locations for dynamic libraries.
@end itemize

In each of these directories, Emacs looks for a file with file-name
extensions specified by the variable @code{dynamic-library-suffixes}.

If Emacs cannot find the library or has problems loading it, Emacs
signals the @code{treesit-load-language-error} error.  The data of
that signal could be one of the following:

@table @code
@item (not-found @var{error-msg} @dots{})
This means that Emacs could not find the language grammar library.
@item (symbol-error @var{error-msg})
This means that Emacs could not find in the library the expected function
that every language grammar library should export.
@item (version-mismatch @var{error-msg})
This means that the version of the language grammar library is
incompatible with that of the tree-sitter library.
@end table

@noindent
In all of these cases, @var{error-msg} might provide additional
details about the failure.

@defun treesit-language-available-p language &optional detail
This function returns non-@code{nil} if the language grammar for
@var{language} exists and can be loaded.

If @var{detail} is non-@code{nil}, return @code{(t . nil)} when
@var{language} is available, and @code{(nil . @var{data})} when it's
unavailable.  @var{data} is the signal data of
@code{treesit-load-language-error}.
@end defun

@vindex treesit-load-name-override-list
By convention, the file name of the dynamic library for @var{language} is
@file{libtree-sitter-@var{language}.@var{ext}}, where @var{ext} is the
system-specific extension for dynamic libraries.  Also by convention,
the function provided by that library is named
@code{tree_sitter_@var{language}}.  If a language grammar library
doesn't follow this convention, you should add an entry

@example
(@var{language} @var{library-base-name} @var{function-name})
@end example

to the list in the variable @code{treesit-load-name-override-list}, where
@var{library-base-name} is the basename of the dynamic library's file name
(usually, @file{libtree-sitter-@var{language}}), and
@var{function-name} is the function provided by the library
(usually, @code{tree_sitter_@var{language}}).  For example,

@example
(cool-lang "libtree-sitter-coool" "tree_sitter_cooool")
@end example

@noindent
for a language that considers itself too ``cool'' to abide by
conventions.

@cindex language grammar version, compatibility
@defun treesit-library-abi-version &optional min-compatible
This function returns the version of the language grammar
Application Binary Interface (@acronym{ABI}) supported by the
tree-sitter library.  By default, it returns the latest ABI version
supported by the library, but if @var{min-compatible} is
non-@code{nil}, it returns the oldest ABI version which the library
still can support.  Language grammar libraries must be built for
ABI versions between the oldest and the latest versions supported by
the tree-sitter library, otherwise the library will be unable to load
them.
@end defun

@defun treesit-language-abi-version language
This function returns the @acronym{ABI} version of the language
grammar library loaded by Emacs for @var{language}.  If @var{language}
is unavailable, this function returns @code{nil}.
@end defun

@heading Concrete syntax tree
@cindex syntax tree, concrete

A syntax tree is what a parser generates.  In a syntax tree, each node
represents a piece of text, and is connected to each other by a
parent-child relationship.  For example, if the source text is

@example
1 + 2
@end example

@noindent
its syntax tree could be

@example
@group
                  +--------------+
                  | root "1 + 2" |
                  +--------------+
                         |
        +--------------------------------+
        |       expression "1 + 2"       |
        +--------------------------------+
           |             |            |
+------------+   +--------------+   +------------+
| number "1" |   | operator "+" |   | number "2" |
+------------+   +--------------+   +------------+
@end group
@end example

We can also represent it as an s-expression:

@example
(root (expression (number) (operator) (number)))
@end example

@subheading Node types
@cindex node types, in a syntax tree

@cindex type of node, tree-sitter
@anchor{tree-sitter node type}
@cindex named node, tree-sitter
@anchor{tree-sitter named node}
@cindex anonymous node, tree-sitter
Names like @code{root}, @code{expression}, @code{number}, and
@code{operator} specify the @dfn{type} of the nodes.  However, not all
nodes in a syntax tree have a type.  Nodes that don't have a type are
known as @dfn{anonymous nodes}, and nodes with a type are @dfn{named
nodes}.  Anonymous nodes are tokens with fixed spellings, including
punctuation characters like bracket @samp{]}, and keywords like
@code{return}.

@subheading Field names

@cindex field name, tree-sitter
@cindex tree-sitter node field name
@anchor{tree-sitter node field name}
To make the syntax tree easier to analyze, many language grammar
assign @dfn{field names} to child nodes.  For example, a
@code{function_definition} node could have a @code{declarator} and a
@code{body}:

@example
@group
(function_definition
 declarator: (declaration)
 body: (compound_statement))
@end group
@end example

@heading Exploring the syntax tree
@cindex explore tree-sitter syntax tree
@cindex inspection of tree-sitter parse tree nodes

To aid in understanding the syntax of a language and in debugging Lisp
programs that use the syntax tree, Emacs provides an ``explore'' mode,
which displays the syntax tree of the source in the current buffer in
real time.  Emacs also comes with an ``inspect mode'', which displays
information of the nodes at point in the mode-line.

@deffn Command treesit-explore-mode
This mode pops up a window displaying the syntax tree of the source in
the current buffer.  Selecting text in the source buffer highlights
the corresponding nodes in the syntax tree display.  Clicking
on nodes in the syntax tree highlights the corresponding text in the
source buffer.
@end deffn

@deffn Command treesit-inspect-mode
This minor mode displays on the mode-line the node that @emph{starts}
at point.  For example, the mode-line can display

@example
@var{parent} @var{field}: (@var{node} (@var{child} (@dots{})))
@end example

@noindent
where @var{node}, @var{child}, etc., are nodes which begin at point.
@var{parent} is the parent of @var{node}.  @var{node} is displayed in
a bold typeface.  @var{field-name}s are field names of @var{node} and
of @var{child}, etc.

If no node starts at point, i.e., point is in the middle of a node,
then the mode line displays the earliest node that spans point, and
its immediate parent.

This minor mode doesn't create parsers on its own.  It uses the first
parser in @code{(treesit-parser-list)} (@pxref{Using Parser}).
@end deffn

@heading Reading the grammar definition
@cindex reading grammar definition, tree-sitter

Authors of language grammars define the @dfn{grammar} of a
programming language, which determines how a parser constructs a
concrete syntax tree out of the program text.  In order to use the
syntax tree effectively, you need to consult the @dfn{grammar file}.

The grammar file is usually @file{grammar.js} in a language
grammar's project repository.  The link to a language grammar's
home page can be found on
@uref{https://tree-sitter.github.io/tree-sitter, tree-sitter's
homepage}.

The grammar definition is written in JavaScript.  For example, the
rule matching a @code{function_definition} node may look like

@example
@group
function_definition: $ => seq(
  $.declaration_specifiers,
  field('declarator', $.declaration),
  field('body', $.compound_statement)
)
@end group
@end example

@noindent
The rules are represented by functions that take a single argument
@var{$}, representing the whole grammar.  The function itself is
constructed by other functions: the @code{seq} function puts together
a sequence of children; the @code{field} function annotates a child
with a field name.  If we write the above definition in the so-called
@dfn{Backus-Naur Form} (@acronym{BNF}) syntax, it would look like

@example
@group
function_definition :=
  <declaration_specifiers> <declaration> <compound_statement>
@end group
@end example

@noindent
and the node returned by the parser would look like

@example
@group
(function_definition
  (declaration_specifier)
  declarator: (declaration)
  body: (compound_statement))
@end group
@end example

Below is a list of functions that one can see in a grammar definition.
Each function takes other rules as arguments and returns a new rule.

@table @code
@item seq(@var{rule1}, @var{rule2}, @dots{})
matches each rule one after another.
@item choice(@var{rule1}, @var{rule2}, @dots{})
matches one of the rules in its arguments.
@item repeat(@var{rule})
matches @var{rule} @emph{zero or more} times.
This is like the @samp{*} operator in regular expressions.
@item repeat1(@var{rule})
matches @var{rule} @emph{one or more} times.
This is like the @samp{+} operator in regular expressions.
@item optional(@var{rule})
matches @var{rule} @emph{zero or one} times.
This is like the @samp{?} operator in regular expressions.
@item field(@var{name}, @var{rule})
assigns field name @var{name} to the child node matched by @var{rule}.
@item alias(@var{rule}, @var{alias})
makes nodes matched by @var{rule} appear as @var{alias} in the syntax
tree generated by the parser.  For example,

@example
alias(preprocessor_call_exp, call_expression)
@end example

@noindent
makes any node matched by @code{preprocessor_call_exp} appear as
@code{call_expression}.
@end table

Below are grammar functions of lesser importance for reading a
language grammar.

@table @code
@item token(@var{rule})
marks @var{rule} to produce a single leaf node.  That is, instead of
generating a parent node with individual child nodes under it,
everything is combined into a single leaf node.  @xref{Retrieving
Nodes}.
@item token.immediate(@var{rule})
Normally, grammar rules ignore preceding whitespace; this
changes @var{rule} to match only when there is no preceding
whitespace.
@item prec(@var{n}, @var{rule})
gives @var{rule} the level-@var{n} precedence.
@item prec.left([@var{n},] @var{rule})
marks @var{rule} as left-associative, optionally with level @var{n}.
@item prec.right([@var{n},] @var{rule})
marks @var{rule} as right-associative, optionally with level @var{n}.
@item prec.dynamic(@var{n}, @var{rule})
this is like @code{prec}, but the precedence is applied at runtime
instead.
@end table

The documentation of the tree-sitter project has
@uref{https://tree-sitter.github.io/tree-sitter/creating-parsers, more
about writing a grammar}.  Read especially ``The Grammar DSL''
section.

@node Using Parser
@section Using Tree-sitter Parser
@cindex tree-sitter parser, using

This section describes how to create and configure a tree-sitter
parser.  In Emacs, each tree-sitter parser is associated with a
buffer.  As the user edits the buffer, the associated parser and
syntax tree are automatically kept up-to-date.

@defvar treesit-max-buffer-size
This variable contains the maximum size of buffers in which
tree-sitter can be activated.  Major modes should check this value
when deciding whether to enable tree-sitter features.
@end defvar

@cindex creating tree-sitter parsers
@cindex tree-sitter parser, creating
@defun treesit-parser-create language &optional buffer no-reuse tag
Create a parser for the specified @var{buffer} and @var{language}
(@pxref{Language Grammar}), with @var{tag}.  If @var{buffer} is
omitted or @code{nil}, it stands for the current buffer.

By default, this function reuses a parser if one already exists for
@var{language} with @var{tag} in @var{buffer}, but if @var{no-reuse}
is non-@code{nil}, this function always creates a new parser.

@var{tag} can be any symbol except @code{t}, and defaults to
@code{nil}.  Different parsers can have the same tag.

If that buffer is an indirect buffer, its base buffer is used instead.
That is, indirect buffers use their base buffer's parsers.  If the
base buffer is narrowed, an indirect buffer might not be able to
retrieve information of the portion of the buffer text that is
invisible in the base buffer.  Lisp programs should widen as necessary
should they want to use a parser in an indirect buffer.
@end defun

Given a parser, we can query information about it.

@defun treesit-parser-buffer parser
This function returns the buffer associated with @var{parser}.
@end defun

@defun treesit-parser-language parser
This function returns the language used by @var{parser}.
@end defun

@defun treesit-parser-p object
This function checks if @var{object} is a tree-sitter parser, and
returns non-@code{nil} if it is, and @code{nil} otherwise.
@end defun

There is no need to explicitly parse a buffer, because parsing is done
automatically and lazily.  A parser only parses when a Lisp program
queries for a node in its syntax tree.  Therefore, when a parser is
first created, it doesn't parse the buffer; it waits until the Lisp
program queries for a node for the first time.  Similarly, when some
change is made in the buffer, a parser doesn't re-parse immediately.

@vindex treesit-buffer-too-large
When a parser does parse, it checks for the size of the buffer.
Tree-sitter can only handle buffers no larger than about 4GB@.  If the
size exceeds that, Emacs signals the @code{treesit-buffer-too-large}
error with signal data being the buffer size.

Once a parser is created, Emacs automatically adds it to the
internal parser list.  Every time a change is made to the buffer,
Emacs updates parsers in this list so they can update their syntax
tree incrementally.

@defun treesit-parser-list &optional buffer language tag
This function returns the parser list of @var{buffer}, filtered by
@var{language} and @var{tag}.  If @var{buffer} is @code{nil} or
omitted, it defaults to the current buffer.  If that buffer is an
indirect buffer, its base buffer is used instead.  That is, indirect
buffers use their base buffer's parsers.

If @var{language} is non-@var{nil}, only include parsers for that
language, and only include parsers with @var{tag}.  @var{tag} defaults
to @code{nil}.  If @var{tag} is @code{t}, include parsers in the
returned list regardless of their tag.
@end defun

@defun treesit-parser-delete parser
This function deletes @var{parser}.
@end defun

@cindex tree-sitter narrowing
@anchor{tree-sitter narrowing}
Normally, a parser ``sees'' the whole buffer, but when the buffer is
narrowed (@pxref{Narrowing}), the parser will only see the accessible
portion of the buffer.  As far as the parser can tell, the hidden
region was deleted.  When the buffer is later widened, the parser
thinks text is inserted at the beginning and at the end.  Although
parsers respect narrowing, modes should not use narrowing as a means
to handle a multi-language buffer; instead, set the ranges in which the
parser should operate.  @xref{Multiple Languages}.

Because a parser parses lazily, when the user or a Lisp program
narrows the buffer, the parser is not affected immediately; as long as
the mode doesn't query for a node while the buffer is narrowed, the
parser is oblivious of the narrowing.

@cindex tree-sitter parse string
@cindex parse string, tree-sitter
Besides creating a parser for a buffer, a Lisp program can also parse a
string.  Unlike a buffer, parsing a string is a one-off operation, and
there is no way to update the result.

@defun treesit-parse-string string language
This function parses @var{string} using @var{language}, and returns
the root node of the generated syntax tree.
@end defun

@heading Be notified by changes to the parse tree
@cindex update callback, for tree-sitter parse-tree
@cindex after-change notifier, for tree-sitter parse-tree
@cindex tree-sitter parse-tree, update and after-change callback
@cindex notifiers, tree-sitter

A Lisp program might want to be notified of text affected by
incremental parsing.  For example, inserting a comment-closing token
converts text before that token into a comment.  Even
though the text is not directly edited, it is deemed to be ``changed''
nevertheless.

Emacs lets a Lisp program register callback functions (a.k.a.@:
@dfn{notifiers}) for these kinds of changes.  A notifier function
takes two arguments: @var{ranges} and @var{parser}.  @var{ranges} is a
list of cons cells of the form @w{@code{(@var{start} . @var{end})}},
where @var{start} and @var{end} mark the start and the end positions
of a range.  @var{parser} is the parser issuing the notification.

Every time a parser reparses a buffer, it compares the old and new
parse-tree, computes the ranges in which nodes have changed, and
passes the ranges to notifier functions.  Note that the initial parse
is also considered a ``change'', so notifier functions are called on
the initial parse, with range being the whole buffer.

@defun treesit-parser-add-notifier parser function
This function adds @var{function} to @var{parser}'s list of
after-change notifier functions.  @var{function} must be a function
symbol, not a lambda function (@pxref{Anonymous Functions}).
@end defun

@defun treesit-parser-remove-notifier parser function
This function removes @var{function} from the list of @var{parser}'s
after-change notifier functions.  @var{function} must be a function
symbol, rather than a lambda function.
@end defun

@defun treesit-parser-notifiers parser
This function returns the list of @var{parser}'s notifier functions.
@end defun

@node Retrieving Nodes
@section Retrieving Nodes
@cindex retrieve node, tree-sitter
@cindex tree-sitter, find node
@cindex get node, tree-sitter

@cindex terminology, for tree-sitter functions
Here are some terms and conventions we use when documenting
tree-sitter functions.

A node in a syntax tree spans some portion of the program text in the
buffer.  We say that a node is ``smaller'' or ``larger'' than another
if it spans, respectively, a smaller or larger portion of buffer text
than the other node.  Since nodes that are deeper (``lower'') in the
tree are children of the nodes that are ``higher'' in the tree, it
follows that a lower node will always be smaller than a node that is
higher in the node hierarchy.  A node that is higher up in the syntax
tree contains one or more smaller nodes as its children, and therefore
spans a larger portion of buffer text.

When a function cannot find a node, it returns @code{nil}.  For
convenience, all functions that take a node as argument and return
a node, also accept the node argument of @code{nil} and in that case
just return @code{nil}.

@vindex treesit-node-outdated
Nodes are not automatically updated when the associated buffer is
modified, and there is no way to update a node once it is retrieved.
Using an outdated node signals the @code{treesit-node-outdated} error.

@heading Retrieving nodes from syntax tree
@cindex retrieving tree-sitter nodes
@cindex syntax tree, retrieving nodes

@cindex leaf node, of tree-sitter parse tree
@cindex tree-sitter parse tree, leaf node
@defun treesit-node-at pos &optional parser-or-lang named
This function returns a @dfn{leaf} node at buffer position @var{pos}.
A leaf node is a node that doesn't have any child nodes.

This function tries to return a node whose span covers @var{pos}: the
node's beginning position is less than or equal to @var{pos}, and the
node's end position is greater than or equal to @var{pos}.

If no leaf node's span covers @var{pos} (e.g., @var{pos} is in the
whitespace between two leaf nodes), this function returns the first
leaf node after @var{pos}.

Finally, if there is no leaf node after @var{pos}, return the first
leaf node before @var{pos}.

If @var{parser-or-lang} is a parser object, this function uses that
parser; if @var{parser-or-lang} is a language, this function uses the
first parser for that language in the current buffer, or creates one
if none exists; if @var{parser-or-lang} is @code{nil}, this function
tries to guess the language at @var{pos} by calling
@code{treesit-language-at} (@pxref{Multiple Languages}).

If this function cannot find a suitable node to return, it returns
@code{nil}.

If @var{named} is non-@code{nil}, this function looks only for named
nodes (@pxref{tree-sitter named node, named node}).

Example:

@example
@group
;; Find the node at point in a C parser's syntax tree.
(treesit-node-at (point) 'c)
  @result{} #<treesit-node (primitive_type) in 23-27>
@end group
@end example
@end defun

@defun treesit-node-on beg end &optional parser-or-lang named
This function returns the @emph{smallest} node that covers the region
of buffer text between @var{beg} and @var{end}.  In other words, the
start of the node is before or at @var{beg}, and the end of the node
is at or after @var{end}.

@emph{Beware:} calling this function on an empty line that is not
inside any top-level construct (function definition, etc.@:) most
probably will give you the root node, because the root node is the
smallest node that covers that empty line.  Most of the time, you want
to use @code{treesit-node-at} instead.

If @var{parser-or-lang} is a parser object, this function uses that
parser; if @var{parser-or-lang} is a language, this function uses the
first parser for that language in the current buffer, or creates one
if none exists; if @var{parser-or-lang} is @code{nil}, this function
tries to guess the language at @var{beg} by calling
@code{treesit-language-at}.

If @var{named} is non-@code{nil}, this function looks for a named node
only (@pxref{tree-sitter named node, named node}).
@end defun

@defun treesit-parser-root-node parser
This function returns the root node of the syntax tree generated by
@var{parser}.
@end defun

@defun treesit-buffer-root-node &optional language
This function finds the first parser for @var{language} in the current
buffer, or creates one if none exists, and returns the root node
generated by that parser.  If @var{language} is omitted, it uses the
first parser in the parser list.  If it cannot find an appropriate
parser, it returns @code{nil}.
@end defun

Given a node, a Lisp program can retrieve other nodes starting from
it, or query for information about this node.

@heading Retrieving nodes from other nodes
@cindex syntax tree nodes, retrieving from other nodes

@subheading By kinship
@cindex kinship, syntax tree nodes
@cindex nodes, by kinship
@cindex syntax tree nodes, by kinship

@defun treesit-node-parent node
This function returns the immediate parent of @var{node}.

If @var{node} is more than 1000 levels deep in a parse tree, the
return value is undefined.  Currently it returns @code{nil}, but that
could change in the future.
@end defun

@defun treesit-node-child node n &optional named
This function returns the @var{n}'th child of @var{node}.  If
@var{named} is non-@code{nil}, it counts only named nodes
(@pxref{tree-sitter named node, named node}).

For example, in a node that represents a string @code{"text"}, there
are three children nodes: the opening quote @code{"}, the string text
@code{text}, and the closing quote @code{"}.  Among these nodes, the
first child is the opening quote @code{"}, and the first named child
is the string text.

This function returns @code{nil} if there is no @var{n}'th child.
@var{n} could be negative, e.g., @minus{}1 represents the last child.
@end defun

@defun treesit-node-children node &optional named
This function returns all of @var{node}'s children as a list.  If
@var{named} is non-@code{nil}, it retrieves only named nodes.
@end defun

@defun treesit-node-next-sibling node &optional named
This function finds the next sibling of @var{node}.  If @var{named} is
non-@code{nil}, it finds the next named sibling.
@end defun

@defun treesit-node-prev-sibling node &optional named
This function finds the previous sibling of @var{node}.  If
@var{named} is non-@code{nil}, it finds the previous named sibling.
@end defun

@subheading By field name
@cindex nodes, by field name
@cindex syntax tree nodes, by field name

To make the syntax tree easier to analyze, many language grammars
assign @dfn{field names} to child nodes (@pxref{tree-sitter node field
name, field name}).  For example, a @code{function_definition} node
could have a @code{declarator} child and a @code{body} child.

@defun treesit-node-child-by-field-name node field-name
This function finds the child of @var{node} whose field name is
@var{field-name}, a string.

@example
@group
;; Get the child that has "body" as its field name.
(treesit-node-child-by-field-name node "body")
  @result{} #<treesit-node (compound_statement) in 45-89>
@end group
@end example
@end defun

@subheading By position
@cindex nodes, by position
@cindex syntax tree nodes, by position

@defun treesit-node-first-child-for-pos node pos &optional named
This function finds the first child of @var{node} that extends beyond
buffer position @var{pos}.  ``Extends beyond'' means the end of the
child node is greater or equal to @var{pos}.  This function only looks
for immediate children of @var{node}, and doesn't look in its
grandchildren.  If @var{named} is non-@code{nil}, it looks for the
first named child (@pxref{tree-sitter named node, named node}).
@end defun

@defun treesit-node-descendant-for-range node beg end &optional named
This function finds the @emph{smallest} descendant node of @var{node}
that spans the region of text between positions @var{beg} and
@var{end}.  It is similar to @code{treesit-node-at}.  If @var{named}
is non-@code{nil}, it looks for the smallest named child.
@end defun

@heading Searching for node

@defun treesit-search-subtree node predicate &optional backward all depth
This function traverses the subtree of @var{node} (including
@var{node} itself), looking for a node for which @var{predicate}
returns non-@code{nil}.  @var{predicate} is a regexp that is matched
against each node's type, or a predicate function that takes a node
and returns non-@code{nil} if the node matches.  The function returns
the first node that matches, or @code{nil} if none does.

By default, this function only traverses named nodes, but if @var{all}
is non-@code{nil}, it traverses all the nodes.  If @var{backward} is
non-@code{nil}, it traverses backwards (i.e., it visits the last child
first when traversing down the tree).  If @var{depth} is
non-@code{nil}, it must be a number that limits the tree traversal to
that many levels down the tree.  If @var{depth} is @code{nil}, it
defaults to 1000.
@end defun

@defun treesit-search-forward start predicate &optional backward all
Like @code{treesit-search-subtree}, this function also traverses the
parse tree and matches each node with @var{predicate} (except for
@var{start}), where @var{predicate} can be a regexp or a function.
For a tree like the one below where @var{start} is marked @samp{S},
this function traverses as numbered from 1 to 12:

@example
@group
              12
              |
     S--------3----------11
     |        |          |
o--o-+--o  1--+--2    6--+-----10
|  |                  |        |
o  o                +-+-+   +--+--+
                    |   |   |  |  |
                    4   5   7  8  9
@end group
@end example

Note that this function doesn't traverse the subtree of @var{start},
and it always traverses leaf nodes first, before moving upwards.

Like @code{treesit-search-subtree}, this function only searches for
named nodes by default, but if @var{all} is non-@code{nil}, it
searches for all nodes.  If @var{backward} is non-@code{nil}, it
searches backwards.

While @code{treesit-search-subtree} traverses the subtree of a node,
this function starts with node @var{start} and traverses every node
that comes after it in the buffer position order, i.e., nodes with
start positions greater than the end position of @var{start}.

In the tree shown above, @code{treesit-search-subtree} traverses node
@samp{S} (@var{start}) and nodes marked with @code{o}, where this
function traverses the nodes marked with numbers.  This function is
useful for answering questions like ``what is the first node after
@var{start} in the buffer that satisfies some condition?''
@end defun

@defun treesit-search-forward-goto node predicate &optional start backward all
This function moves point to the start or end of the next node after
@var{node} in the buffer that matches @var{predicate}.  If @var{start}
is non-@code{nil}, stop at the beginning rather than the end of a node.

This function guarantees that the matched node it returns makes
progress in terms of buffer position: the start/end position of the
returned node is always greater than that of @var{node}.

Arguments @var{predicate}, @var{backward}, and @var{all} are the same
as in @code{treesit-search-forward}.
@end defun

@defun treesit-induce-sparse-tree root predicate &optional process-fn depth
This function creates a sparse tree from @var{root}'s subtree.

It takes the subtree under @var{root}, and combs it so only the nodes
that match @var{predicate} are left.  Like previous functions, the
@var{predicate} can be a regexp string that matches against each
node's type, or a function that takes a node and returns
non-@code{nil} if it matches.

For example, given the subtree on the left that consists of both
numbers and letters, if @var{predicate} is ``letter only'', the
returned tree is the one on the right.

@example
@group
    a                 a              a
    |                 |              |
+---+---+         +---+---+      +---+---+
|   |   |         |   |   |      |   |   |
b   1   2         b   |   |      b   c   d
    |   |     =>      |   |  =>      |
    c   +--+          c   +          e
    |   |  |          |   |
 +--+   d  4       +--+   d
 |  |              |
 e  5              e
@end group
@end example

If @var{process-fn} is non-@code{nil}, instead of returning the
matched nodes, this function passes each node to @var{process-fn} and
uses the returned value instead.  If non-@code{nil}, @var{depth}
limits the number of levels to go down from @var{root}.  If
@var{depth} is @code{nil}, it defaults to 1000.

Each node in the returned tree looks like
@w{@code{(@var{tree-sitter-node} . (@var{child} @dots{}))}}.  The
@var{tree-sitter-node} of the root of this tree will be @code{nil} if
@var{root} doesn't match @var{predicate}.  If no node matches
@var{predicate}, the function returns @code{nil}.
@end defun

@heading More convenience functions

@defun treesit-node-get node instructions
This is a convenience function that chains together multiple node
accessor functions together.  For example, to get @var{node}'s
parent's next sibling's second child's text:

@example
@group
(treesit-node-get node
   '((parent 1)
    (sibling 1 nil)
    (child 1 nil)
    (text nil)))
@end group
@end example

@var{instruction} is a list of INSTRUCTIONs of the form
@w{@code{(@var{fn} @var{arg}...)}}.  The following @var{fn}'s are
supported:

@table @code
@item (child @var{idx} @var{named})
Get the @var{idx}'th child.

@item (parent @var{n})
Go to parent @var{n} times.

@item (field-name)
Get the field name of the current node.

@item (type)
Get the type of the current node.

@item (text @var{no-property})
Get the text of the current node.

@item (children @var{named})
Get a list of children.

@item (sibling @var{step} @var{named})
Get the nth prev/next sibling, negative @var{step} means prev sibling,
positive means next sibling.
@end table

Note that arguments like @var{named} and @var{no-property} can't be
omitted, unlike in their original functions.
@end defun

@defun treesit-filter-child node predicate &optional named
This function finds immediate children of @var{node} that satisfy
@var{predicate}.

The @var{predicate} function takes a node as argument and should
return non-@code{nil} to indicate that the node should be kept.  If
@var{named} is non-@code{nil}, this function only examines named
nodes.
@end defun

@defun treesit-parent-until node predicate &optional include-node
This function repeatedly finds the parents of @var{node}, and returns
the parent that satisfies @var{pred}, a function that takes a node as
argument and returns a boolean that indicates a match.  If no parent
satisfies @var{pred}, this function returns @code{nil}.

Normally this function only looks at the parents of @var{node} but not
@var{node} itself.  But if @var{include-node} is non-@code{nil}, this
function returns @var{node} if @var{node} satisfies @var{pred}.
@end defun

@defun treesit-parent-while node pred
This function goes up the tree starting from @var{node}, and keeps
doing so as long as the nodes satisfy @var{pred}, a function that
takes a node as argument.  That is, this function returns the highest
parent of @var{node} that still satisfies @var{pred}.  Note that if
@var{node} satisfies @var{pred} but its immediate parent doesn't,
@var{node} itself is returned.
@end defun

@defun treesit-node-top-level node &optional type
This function returns the highest parent of @var{node} that has the
same type as @var{node}.  If no such parent exists, it returns
@code{nil}.  Therefore this function is also useful for testing
whether @var{node} is top-level.

If @var{type} is non-@code{nil}, this function matches each parent's
type with @var{type} as a regexp, rather than using @var{node}'s type.
@end defun

@node Accessing Node Information
@section Accessing Node Information
@cindex information of node, syntax trees
@cindex syntax trees, node information

@heading Basic information of Node

Every node is associated with a parser, and that parser is associated
with a buffer.  The following functions retrieve them.

@defun treesit-node-parser node
This function returns @var{node}'s associated parser.
@end defun

@defun treesit-node-buffer node
This function returns @var{node}'s parser's associated buffer.
@end defun

@defun treesit-node-language node
This function returns @var{node}'s parser's associated language.
@end defun

Each node represents a portion of text in the buffer.  Functions below
find relevant information about that text.

@defun treesit-node-start node
Return the start position of @var{node}.
@end defun

@defun treesit-node-end node
Return the end position of @var{node}.
@end defun

@defun treesit-node-text node &optional object
Return the buffer text that @var{node} represents, as a string.  (If
@var{node} is retrieved from parsing a string, it will be the text
from that string.)
@end defun

@cindex predicates for syntax tree nodes
Here are some predicates on tree-sitter nodes:

@defun treesit-node-p object
Checks if @var{object} is a tree-sitter syntax node.
@end defun

@cindex compare tree-sitter syntax nodes
@cindex tree-sitter nodes, comparing
@defun treesit-node-eq node1 node2
Checks if @var{node1} and @var{node2} refer to the same node in a
tree-sitter syntax tree.  This function uses the same equivalence
metric as @code{equal}.  You can also compare nodes using @code{equal}
(@pxref{Equality Predicates}).
@end defun

@heading Property information

In general, nodes in a concrete syntax tree fall into two categories:
@dfn{named nodes} and @dfn{anonymous nodes}.  Whether a node is named
or anonymous is determined by the language grammar
(@pxref{tree-sitter named node, named node}).

@cindex tree-sitter missing node
@cindex missing node, tree-sitter
Apart from being named or anonymous, a node can have other properties.
A node can be ``missing'': such nodes are inserted by the parser in
order to recover from certain kinds of syntax errors, i.e., something
should probably be there according to the grammar, but is not there.
This can happen during editing of the program source, when the source
is not yet in its final form.

@cindex tree-sitter extra node
@cindex extra node, tree-sitter
A node can be ``extra'': such nodes represent things like comments,
which can appear anywhere in the text.

@cindex tree-sitter outdated node
@cindex outdated node, tree-sitter
A node can be ``outdated'', if its parser has reparsed at least once
after the node was created.

@cindex tree-sitter node that has error
@cindex has error, tree-sitter node
A node ``has error'' if the text it spans contains a syntax error.  It
can be that the node itself has an error, or one of its descendants
has an error.

@cindex tree-sitter, live parsing node
@cindex live node, tree-sitter
A node is considered @dfn{live} if its parser is not deleted, and the
buffer to which it belongs is a live buffer (@pxref{Killing Buffers}).

@defun treesit-node-check node property
This function returns non-@code{nil} if @var{node} has the specified
@var{property}.  @var{property} can be @code{named}, @code{missing},
@code{extra}, @code{outdated}, @code{has-error}, or @code{live}.
@end defun

@defun treesit-node-type node
Named nodes have ``types'' (@pxref{tree-sitter node type, node type}).
For example, a named node can be a @code{string_literal} node, where
@code{string_literal} is its type.  The type of an anonymous node is
just the text that the node represents; e.g., the type of a @samp{,}
node is just @samp{,}.

This function returns @var{node}'s type as a string.
@end defun

@heading Information as a child or parent

@defun treesit-node-index node &optional named
This function returns the index of @var{node} as a child node of its
parent.  If @var{named} is non-@code{nil}, it only counts named nodes
(@pxref{tree-sitter named node, named node}).
@end defun

@defun treesit-node-field-name node
A child of a parent node could have a field name (@pxref{tree-sitter
node field name, field name}).  This function returns the field name
of @var{node} as a child of its parent.
@end defun

@defun treesit-node-field-name-for-child node n
This function returns the field name of the @var{n}'th child of
@var{node}.  It returns @code{nil} if there is no @var{n}'th child, or
the @var{n}'th child doesn't have a field name.

Note that @var{n} counts both named and anonymous children, and
@var{n} can be negative, e.g., @minus{}1 represents the last child.
@end defun

@defun treesit-node-child-count node &optional named
This function returns the number of children of @var{node}.  If
@var{named} is non-@code{nil}, it only counts named children
(@pxref{tree-sitter named node, named node}).
@end defun

@heading Convenience functions

@defun treesit-node-enclosed-p smaller larger &optional strict
This function returns non-@code{nil} if @var{smaller} is enclosed in
@var{larger}.  @var{smaller} and @var{larger} can be either a cons
@code{(@var{beg} . @var{end})} or a node.

Return non-@code{nil} if @var{larger}'s start <= @var{smaller}'s start
and @var{larger}'s end <= @var{smaller}'s end.

If @var{strict} is @code{t}, compare with < rather than <=.

If @var{strict} is @code{partial}, consider @var{larger} encloses
@var{smaller} when at least one side is strictly enclosing.
@end defun

@node Pattern Matching
@section Pattern Matching Tree-sitter Nodes
@cindex pattern matching with tree-sitter nodes

@cindex capturing, tree-sitter node
Tree-sitter lets Lisp programs match patterns using a small
declarative language.  This pattern matching consists of two steps:
first tree-sitter matches a @dfn{pattern} against nodes in the syntax
tree, then it @dfn{captures} specific nodes that matched the pattern
and returns the captured nodes.

We describe first how to write the most basic query pattern and how to
capture nodes in a pattern, then the pattern-matching function, and
finally the more advanced pattern syntax.

@heading Basic query syntax

@cindex tree-sitter query pattern syntax
@cindex pattern syntax, tree-sitter query
@cindex query, tree-sitter
A @dfn{query} consists of multiple @dfn{patterns}.  Each pattern is an
s-expression that matches a certain node in the syntax node.  A
pattern has the form @w{@code{(@var{type} (@var{child}@dots{}))}}.

For example, a pattern that matches a @code{binary_expression} node that
contains @code{number_literal} child nodes would look like

@example
(binary_expression (number_literal))
@end example

To @dfn{capture} a node using the query pattern above, append
@code{@@@var{capture-name}} after the node pattern you want to
capture.  For example,

@example
(binary_expression (number_literal) @@number-in-exp)
@end example

@noindent
captures @code{number_literal} nodes that are inside a
@code{binary_expression} node with the capture name
@code{number-in-exp}.

We can capture the @code{binary_expression} node as well, with, for
example, the capture name @code{biexp}:

@example
(binary_expression
 (number_literal) @@number-in-exp) @@biexp
@end example

@heading Query function

@cindex query functions, tree-sitter
Now we can introduce the @dfn{query functions}.

@defun treesit-query-capture node query &optional beg end node-only
This function matches patterns in @var{query} within @var{node}.  The
argument @var{query} can be either an s-expression, a string, or a
compiled query object.  For now, we focus on the s-expression syntax;
string syntax and compiled queries are described at the end of
the section.

The argument @var{node} can also be a parser or a language symbol.  A
parser means use its root node, a language symbol means find or create
a parser for that language in the current buffer, and use the root
node.

The function returns all the captured nodes in an alist with elements
of the form @w{@code{(@var{capture_name} . @var{node})}}.  If
@var{node-only} is non-@code{nil}, it returns the list of @var{node}s
instead.  By default the entire text of @var{node} is searched, but if
@var{beg} and @var{end} are both non-@code{nil}, they specify the
region of buffer text where this function should match nodes.  Any
matching node whose span overlaps with the region between @var{beg}
and @var{end} is captured; it doesn't have to be completely contained
in the region.

@vindex treesit-query-error
@findex treesit-query-validate
This function raises the @code{treesit-query-error} error if
@var{query} is malformed.  The signal data contains a description of
the specific error.  You can use @code{treesit-query-validate} to
validate and debug the query.
@end defun

For example, suppose @var{node}'s text is @code{1 + 2}, and
@var{query} is

@example
@group
(setq query
      '((binary_expression
         (number_literal) @@number-in-exp) @@biexp)
@end group
@end example

Matching that query would return

@example
@group
(treesit-query-capture node query)
    @result{} ((biexp . @var{<node for "1 + 2">})
       (number-in-exp . @var{<node for "1">})
       (number-in-exp . @var{<node for "2">}))
@end group
@end example

As mentioned earlier, @var{query} could contain multiple patterns.
For example, it could have two top-level patterns:

@example
@group
(setq query
      '((binary_expression) @@biexp
        (number_literal) @@number @@biexp)
@end group
@end example

@defun treesit-query-string string query language
This function parses @var{string} as @var{language}, matches its root
node with @var{query}, and returns the result.
@end defun

@heading More query syntax

Besides node type and capture name, tree-sitter's pattern syntax can
express anonymous node, field name, wildcard, quantification,
grouping, alternation, anchor, and predicate.

@subheading Anonymous node

An anonymous node is written verbatim, surrounded by quotes.  A
pattern matching (and capturing) keyword @code{return} would be

@example
"return" @@keyword
@end example

@subheading Wild card

In a pattern, @samp{(_)} matches any named node, and @samp{_} matches
any named or anonymous node.  For example, to capture any named child
of a @code{binary_expression} node, the pattern would be

@example
(binary_expression (_) @@in-biexp)
@end example

@subheading Field name

It is possible to capture child nodes that have specific field names.
In the pattern below, @code{declarator} and @code{body} are field
names, indicated by the colon following them.

@example
@group
(function_definition
  declarator: (_) @@func-declarator
  body: (_) @@func-body)
@end group
@end example

It is also possible to capture a node that doesn't have a certain
field, say, a @code{function_definition} without a @code{body} field:

@example
(function_definition !body) @@func-no-body
@end example

@subheading Quantify node

@cindex quantify node, tree-sitter
Tree-sitter recognizes quantification operators @samp{:*}, @samp{:+},
and @samp{:?}.  Their meanings are the same as in regular expressions:
@samp{:*} matches the preceding pattern zero or more times, @samp{:+}
matches one or more times, and @samp{:?} matches zero or one times.

For example, the following pattern matches @code{type_declaration}
nodes that have @emph{zero or more} @code{long} keywords.

@example
(type_declaration "long" :*) @@long-type
@end example

The following pattern matches a type declaration that may or may not
have a @code{long} keyword:

@example
(type_declaration "long" :?) @@long-type
@end example

@subheading Grouping

Similar to groups in regular expressions, we can bundle patterns into
groups and apply quantification operators to them.  For example, to
express a comma-separated list of identifiers, one could write

@example
(identifier) ("," (identifier)) :*
@end example

@subheading Alternation

Again, similar to regular expressions, we can express ``match any one
of these patterns'' in a pattern.  The syntax is a vector of patterns.
For example, to capture some keywords in C, the pattern would be

@example
@group
[
  "return"
  "break"
  "if"
  "else"
] @@keyword
@end group
@end example

@subheading Anchor

The anchor operator @code{:anchor} can be used to enforce juxtaposition,
i.e., to enforce two things to be directly next to each other.  The
two ``things'' can be two nodes, or a child and the end of its parent.
For example, to capture the first child, the last child, or two
adjacent children:

@example
@group
;; Anchor the child with the end of its parent.
(compound_expression (_) @@last-child :anchor)
@end group

@group
;; Anchor the child with the beginning of its parent.
(compound_expression :anchor (_) @@first-child)
@end group

@group
;; Anchor two adjacent children.
(compound_expression
 (_) @@prev-child
 :anchor
 (_) @@next-child)
@end group
@end example

Note that the enforcement of juxtaposition ignores any anonymous
nodes.

@subheading Predicate

It is possible to add predicate constraints to a pattern.  For
example, with the following pattern:

@example
@group
(
 (array :anchor (_) @@first (_) @@last :anchor)
 (:equal @@first @@last)
)
@end group
@end example

@noindent
tree-sitter only matches arrays where the first element is equal to
the last element.  To attach a predicate to a pattern, we need to
group them together.  Currently there are three predicates:
@code{:equal}, @code{:match}, and @code{:pred}.

@deffn Predicate :equal arg1 arg2
Matches if @var{arg1} is equal to @var{arg2}.  Arguments can be either
strings or capture names.  Capture names represent the text that the
captured node spans in the buffer.
@end deffn

@deffn Predicate :match regexp capture-name
Matches if the text that @var{capture-name}'s node spans in the buffer
matches regular expression @var{regexp}, given as a string literal.
Matching is case-sensitive.
@end deffn

@deffn Predicate :pred fn &rest nodes
Matches if function @var{fn} returns non-@code{nil} when passed each
node in @var{nodes} as arguments.  The function runs with the current
buffer set to the buffer of node being queried.
@end deffn

Note that a predicate can only refer to capture names that appear in
the same pattern.  Indeed, it makes little sense to refer to capture
names in other patterns.

@heading String patterns

@cindex tree-sitter patterns as strings
@cindex patterns, tree-sitter, in string form
Besides s-expressions, Emacs allows the tree-sitter's native query
syntax to be used by writing them as strings.  It largely resembles
the s-expression syntax.  For example, the following query

@example
@group
(treesit-query-capture
 node '((addition_expression
         left: (_) @@left
         "+" @@plus-sign
         right: (_) @@right) @@addition

         ["return" "break"] @@keyword))
@end group
@end example

@noindent
is equivalent to

@example
@group
(treesit-query-capture
 node "(addition_expression
        left: (_) @@left
        \"+\" @@plus-sign
        right: (_) @@right) @@addition

        [\"return\" \"break\"] @@keyword")
@end group
@end example

Most patterns can be written directly as s-expressions inside a string.
Only a few of them need modification:

@itemize
@item
Anchor @code{:anchor} is written as @samp{.}.
@item
@samp{:?} is written as @samp{?}.
@item
@samp{:*} is written as @samp{*}.
@item
@samp{:+} is written as @samp{+}.
@item
@code{:equal}, @code{:match} and @code{:pred} are written as
@code{#equal}, @code{#match} and @code{#pred}, respectively.
In general, predicates change their @samp{:} to @samp{#}.
@end itemize

For example,

@example
@group
'((
   (compound_expression :anchor (_) @@first (_) :* @@rest)
   (:match "love" @@first)
   ))
@end group
@end example

@noindent
is written in string form as

@example
@group
"(
  (compound_expression . (_) @@first (_)* @@rest)
  (#match \"love\" @@first)
  )"
@end group
@end example

@heading Compiling queries

@cindex compiling tree-sitter queries
@cindex queries, compiling
If a query is intended to be used repeatedly, especially in tight
loops, it is important to compile that query, because a compiled query
is much faster than an uncompiled one.  A compiled query can be used
anywhere a query is accepted.

@defun treesit-query-compile language query
This function compiles @var{query} for @var{language} into a compiled
query object and returns it.

This function raises the @code{treesit-query-error} error if
@var{query} is malformed.  The signal data contains a description of
the specific error.  You can use @code{treesit-query-validate} to
validate and debug the query.
@end defun

@defun treesit-query-language query
This function returns the language of @var{query}.
@end defun

@defun treesit-query-expand query
This function converts the s-expression @var{query} into the string
format.
@end defun

@defun treesit-pattern-expand pattern
This function converts the s-expression @var{pattern} into the string
format.
@end defun

For more details, read the tree-sitter project's documentation about
pattern-matching, which can be found at
@uref{https://tree-sitter.github.io/tree-sitter/using-parsers#pattern-matching-with-queries}.

@node Multiple Languages
@section Parsing Text in Multiple Languages
@cindex multiple languages, parsing with tree-sitter
@cindex parsing multiple languages with tree-sitter
Sometimes, the source of a programming language could contain snippets
of other languages; @acronym{HTML} + @acronym{CSS} + JavaScript is one
example.  In that case, text segments written in different languages
need to be assigned different parsers.  Traditionally, this is
achieved by using narrowing.  While tree-sitter works with narrowing
(@pxref{tree-sitter narrowing, narrowing}), the recommended way is
instead to specify regions of buffer text (i.e., ranges) in which a
parser will operate.  This section describes functions for setting and
getting ranges for a parser.

Lisp programs should call @code{treesit-update-ranges} to make sure
the ranges for each parser are correct before using parsers in a
buffer, and call @code{treesit-language-at} to figure out the language
responsible for the text at some position.  These two functions don't
work by themselves, they need major modes to set
@code{treesit-range-settings} and
@code{treesit-language-at-point-function}, which do the actual work.
These functions and variables are explained in more detail towards the
end of the section.

@heading Getting and setting ranges

@defun treesit-parser-set-included-ranges parser ranges
This function sets up @var{parser} to operate on @var{ranges}.  The
@var{parser} will only read the text of the specified ranges.  Each
range in @var{ranges} is a pair of the form @w{@code{(@var{beg}
. @var{end})}}.

The ranges in @var{ranges} must come in order and must not overlap.
That is, in pseudo code:

@example
@group
(cl-loop for idx from 1 to (1- (length ranges))
         for prev = (nth (1- idx) ranges)
         for next = (nth idx ranges)
         should (<= (car prev) (cdr prev)
                    (car next) (cdr next)))
@end group
@end example

@vindex treesit-range-invalid
If @var{ranges} violates this constraint, or something else went
wrong, this function signals the @code{treesit-range-invalid} error.
The signal data contains a specific error message and the ranges we
are trying to set.

This function can also be used for disabling ranges.  If @var{ranges}
is @code{nil}, the parser is set to parse the whole buffer.

Example:

@example
@group
(treesit-parser-set-included-ranges
 parser '((1 . 9) (16 . 24) (24 . 25)))
@end group
@end example
@end defun

@defun treesit-parser-included-ranges parser
This function returns the ranges set for @var{parser}.  The return
value is the same as the @var{ranges} argument of
@code{treesit-parser-included-ranges}: a list of cons cells of the form
@w{@code{(@var{beg} . @var{end})}}.  If @var{parser} doesn't have any
ranges, the return value is @code{nil}.

@example
@group
(treesit-parser-included-ranges parser)
    @result{} ((1 . 9) (16 . 24) (24 . 25))
@end group
@end example
@end defun

@defun treesit-query-range source query &optional beg end
This function matches @var{source} with @var{query} and returns the
ranges of captured nodes.  The return value is a list of cons cells of
the form @w{@code{(@var{beg} . @var{end})}}, where @var{beg} and
@var{end} specify the beginning and the end of a region of text.

For convenience, @var{source} can be a language symbol, a parser, or a
node.  If it's a language symbol, this function matches in the root
node of the first parser using that language; if a parser, this
function matches in the root node of that parser; if a node, this
function matches in that node.

The argument @var{query} is the query used to capture nodes
(@pxref{Pattern Matching}).  The capture names don't matter.  The
arguments @var{beg} and @var{end}, if both non-@code{nil}, limit the
range in which this function queries.

Like other query functions, this function raises the
@code{treesit-query-error} error if @var{query} is malformed.
@end defun

@heading Supporting multiple languages in Lisp programs

It should suffice for general Lisp programs to call the following two
functions in order to support program sources that mix multiple
languages.

@defun treesit-update-ranges &optional beg end
This function updates ranges for parsers in the buffer.  It makes sure
the parsers' ranges are set correctly between @var{beg} and @var{end},
according to @code{treesit-range-settings}.  If omitted, @var{beg}
defaults to the beginning of the buffer, and @var{end} defaults to the
end of the buffer.

For example, fontification functions use this function before querying
for nodes in a region.
@end defun

@defun treesit-language-at pos
This function returns the language of the text at buffer position
@var{pos}.  Under the hood it calls
@code{treesit-language-at-point-function} and returns its return
value.  If @code{treesit-language-at-point-function} is @code{nil},
this function returns the language of the first parser in the returned
value of @code{treesit-parser-list}.  If there is no parser in the
buffer, it returns @code{nil}.
@end defun

@heading Supporting multiple languages in major modes

@cindex host language, tree-sitter
@cindex tree-sitter host and embedded languages
@cindex embedded language, tree-sitter
Normally, in a set of languages that can be mixed together, there is a
@dfn{host language} and one or more @dfn{embedded languages}.  A Lisp
program usually first parses the whole document with the host
language's parser, retrieves some information, sets ranges for the
embedded languages with that information, and then parses the embedded
languages.

Take a buffer containing @acronym{HTML}, @acronym{CSS}, and JavaScript
as an example.  A Lisp program will first parse the whole buffer with
an @acronym{HTML} parser, then query the parser for
@code{style_element} and @code{script_element} nodes, which correspond
to @acronym{CSS} and JavaScript text, respectively.  Then it sets the
range of the @acronym{CSS} and JavaScript parsers to the range which
their corresponding nodes span.

Given a simple @acronym{HTML} document:

@example
@group
<html>
  <script>1 + 2</script>
  <style>body @{ color: "blue"; @}</style>
</html>
@end group
@end example

@noindent
a Lisp program will first parse with a @acronym{HTML} parser, then set
ranges for @acronym{CSS} and JavaScript parsers:

@example
@group
;; Create parsers.
(setq html (treesit-parser-create 'html))
(setq css (treesit-parser-create 'css))
(setq js (treesit-parser-create 'javascript))
@end group

@group
;; Set CSS ranges.
(setq css-range
      (treesit-query-range
       'html
       '((style_element (raw_text) @@capture))))
(treesit-parser-set-included-ranges css css-range)
@end group

@group
;; Set JavaScript ranges.
(setq js-range
      (treesit-query-range
       'html
       '((script_element (raw_text) @@capture))))
(treesit-parser-set-included-ranges js js-range)
@end group
@end example

Emacs automates this process in @code{treesit-update-ranges}.  A
multi-language major mode should set @code{treesit-range-settings} so
that @code{treesit-update-ranges} knows how to perform this process
automatically.  Major modes should use the helper function
@code{treesit-range-rules} to generate a value that can be assigned to
@code{treesit-range-settings}.  The settings in the following example
directly translate into operations shown above.

@example
@group
(setq treesit-range-settings
      (treesit-range-rules
       :embed 'javascript
       :host 'html
       '((script_element (raw_text) @@capture))
@end group

@group
       :embed 'css
       :host 'html
       '((style_element (raw_text) @@capture))))
@end group
@end example

@defun treesit-range-rules &rest query-specs
This function is used to set @code{treesit-range-settings}.  It takes
care of compiling queries and other post-processing, and outputs a
value that @code{treesit-range-settings} can have.

It takes a series of @var{query-spec}s, where each @var{query-spec} is
a @var{query} preceded by zero or more @var{keyword}/@var{value}
pairs.  Each @var{query} is a tree-sitter query in either the string,
s-expression, or compiled form, or a function.

If @var{query} is a tree-sitter query, it should be preceded by two
@var{keyword}/@var{value} pairs, where the @code{:embed} keyword
specifies the embedded language, and the @code{:host} keyword
specifies the host language.

@cindex local parser
If the query is given the @code{:local} keyword whose value is
@code{t}, the range set by this query has a dedicated local parser;
otherwise the range shares a parser with other ranges for the same
language.

By default, a parser sees its ranges as a continuum, rather than
treating them as separate independent segments.  Therefore, if the
embedded ranges are semantically independent segments, they should be
processed by local parsers, described below.

Local parser set to a range can be retrieved by
@code{treesit-local-parsers-at} and @code{treesit-local-parsers-on}.

@code{treesit-update-ranges} uses @var{query} to figure out how to set
the ranges for parsers for the embedded language.  It queries
@var{query} in a host language parser, computes the ranges which the
captured nodes span, and applies these ranges to embedded language
parsers.

If @var{query} is a function, it doesn't need any @var{keyword} and
@var{value} pair.  It should be a function that takes 2 arguments,
@var{start} and @var{end}, and sets the ranges for parsers in the
current buffer in the region between @var{start} and @var{end}.  It is
fine for this function to set ranges in a larger region that
encompasses the region between @var{start} and @var{end}.
@end defun

@defvar treesit-range-settings
This variable helps @code{treesit-update-ranges} in updating the
ranges for parsers in the buffer.  It is a list of @var{setting}s
where the exact format of a @var{setting} is considered internal.  You
should use @code{treesit-range-rules} to generate a value that this
variable can have.

@c Because the format is internal, we don't document them here.  Though
@c we do have it explained in the docstring.  We also expose the fact
@c that it is a list of settings, so one could combine two of them with
@c append.
@end defvar


@defvar treesit-language-at-point-function
This variable's value should be a function that takes a single
argument, @var{pos}, which is a buffer position, and returns the
language of the buffer text at @var{pos}.  This variable is used by
@code{treesit-language-at}.
@end defvar

@defun treesit-local-parsers-at &optional pos language
This function returns all the local parsers at @var{pos} in the
current buffer.  @var{pos} defaults to point.

Local parsers are those which only parse a limited region marked by an
overlay with a non-@code{nil} @code{treesit-parser} property.  If
@var{language} is non-@code{nil}, only return parsers for that
language.
@end defun

@defun treesit-local-parsers-on &optional beg end language
This function is the same as @code{treesit-local-parsers-at}, but it
returns the local parsers in the range between @var{beg} and @var{end}
instead of at point.

@var{beg} and @var{end} default to the entire accessible portion of
the buffer.
@end defun

@node Tree-sitter Major Modes
@section Developing major modes with tree-sitter
@cindex major mode, developing with tree-sitter

This section covers some general guidelines on developing tree-sitter
integration for a major mode.

A major mode supporting tree-sitter features should roughly follow
this pattern:

@example
@group
(define-derived-mode woomy-mode prog-mode "Woomy"
  "A mode for Woomy programming language."
  (when (treesit-ready-p 'woomy)
    (setq-local treesit-variables ...)
    ...
    (treesit-major-mode-setup)))
@end group
@end example

@code{treesit-ready-p} automatically emits a warning if conditions for
enabling tree-sitter aren't met.

If a tree-sitter major mode shares setup with its ``native''
counterpart, one can create a ``base mode'' that contains the common
setup, like this:

@example
@group
(define-derived-mode woomy--base-mode prog-mode "Woomy"
  "An internal mode for Woomy programming language."
  (common-setup)
  ...)
@end group

@group
(define-derived-mode woomy-mode woomy--base-mode "Woomy"
  "A mode for Woomy programming language."
  (native-setup)
  ...)
@end group

@group
(define-derived-mode woomy-ts-mode woomy--base-mode "Woomy"
  "A mode for Woomy programming language."
  (when (treesit-ready-p 'woomy)
    (setq-local treesit-variables ...)
    ...
    (treesit-major-mode-setup)))
@end group
@end example

@defun treesit-ready-p language &optional quiet
This function checks for conditions for activating tree-sitter.  It
checks whether Emacs was built with tree-sitter, whether the buffer's
size is not too large for tree-sitter to handle, and whether the
grammar for @var{language} is available on the system (@pxref{Language
Grammar}).

This function emits a warning if tree-sitter cannot be activated.  If
@var{quiet} is @code{message}, the warning is turned into a message;
if @var{quiet} is @code{t}, no warning or message is displayed.

If all the necessary conditions are met, this function returns
non-@code{nil}; otherwise it returns @code{nil}.
@end defun

@defun treesit-major-mode-setup
This function activates some tree-sitter features for a major mode.

Currently, it sets up the following features:
@itemize
@item
If @code{treesit-font-lock-settings} (@pxref{Parser-based Font Lock})
is non-@code{nil}, it sets up fontification.

@item
If @code{treesit-simple-indent-rules} (@pxref{Parser-based Indentation})
is non-@code{nil}, it sets up indentation.

@item
If @code{treesit-defun-type-regexp} is non-@code{nil}, it sets up
navigation functions for @code{beginning-of-defun} and
@code{end-of-defun}.

@item
If @code{treesit-defun-name-function} is non-@code{nil}, it sets up
add-log functions used by @code{add-log-current-defun}.

@item
If @code{treesit-simple-imenu-settings} (@pxref{Imenu}) is
non-@code{nil}, it sets up Imenu.
@end itemize

@c TODO: Add treesit-thing-settings stuff once we finalize it.
@end defun

For more information on these built-in tree-sitter features,
@pxref{Parser-based Font Lock}, @pxref{Parser-based Indentation}, and
@pxref{List Motion}.

For supporting mixing of multiple languages in a major mode,
@pxref{Multiple Languages}.

Besides @code{beginning-of-defun} and @code{end-of-defun}, Emacs
provides some additional functions for working with defuns:
@code{treesit-defun-at-point} returns the defun node at point, and
@code{treesit-defun-name} returns the name of a defun node.

@c FIXME: Cross-reference to treesit-defun-tactic once we have it in
@c the user manual.
@defun treesit-defun-at-point
This function returns the defun node at point, or @code{nil} if none
is found.  It respects @code{treesit-defun-tactic}: if its value is
@code{top-level}, this function returns the top-level defun, and if
its value is @code{nested}, it returns the immediate enclosing defun.

This function requires @code{treesit-defun-type-regexp} to work.  If
it is @code{nil}, this function simply returns @code{nil}.
@end defun

@defun treesit-defun-name node
This function returns the defun name of @var{node}.  It returns
@code{nil} if there is no defun name for @var{node}, or if @var{node}
is not a defun node, or if @var{node} is @code{nil}.

Depending on the language and major mode, the defun names are names
like function name, class name, struct name, etc.

If @code{treesit-defun-name-function} is @code{nil}, this function
always returns @code{nil}.
@end defun

@defvar treesit-defun-name-function
If non-@code{nil}, this variable's value should be a function that is
called with a node as its argument, and returns the defun name of the
node.  The function should have the same semantics as
@code{treesit-defun-name}: if the node is not a defun node, or the
node is a defun node but doesn't have a name, or the node is
@code{nil}, it should return @code{nil}.
@end defvar

@node Tree-sitter C API
@section Tree-sitter C API Correspondence

Emacs' tree-sitter integration doesn't expose every feature
provided by tree-sitter's C API@.  Missing features include:

@itemize
@item
Creating a tree cursor and navigating the syntax tree with it.
@item
Setting timeout and cancellation flag for a parser.
@item
Setting the logger for a parser.
@item
Printing a @acronym{DOT} graph of the syntax tree to a file.
@item
Copying and modifying a syntax tree.  (Emacs doesn't expose a tree
object.)
@item
Using (row, column) coordinates as position.
@item
Updating a node with changes.  (In Emacs, retrieve a new node instead
of updating the existing one.)
@item
Querying statics of a language grammar.
@end itemize

In addition, Emacs makes some changes to the C API to make the API more
convenient and idiomatic:

@itemize
@item
Instead of using byte positions, the Emacs Lisp API uses character
positions.
@item
Null nodes are converted to @code{nil}.
@end itemize

Below is the correspondence between all C API functions and their
ELisp counterparts.  Sometimes one ELisp function corresponds to
multiple C functions, and many C functions don't have an ELisp
counterpart.

@example
ts_parser_new                           treesit-parser-create
ts_parser_delete
ts_parser_set_language
ts_parser_language                      treesit-parser-language
ts_parser_set_included_ranges           treesit-parser-set-included-ranges
ts_parser_included_ranges               treesit-parser-included-ranges
ts_parser_parse
ts_parser_parse_string                  treesit-parse-string
ts_parser_parse_string_encoding
ts_parser_reset
ts_parser_set_timeout_micros
ts_parser_timeout_micros
ts_parser_set_cancellation_flag
ts_parser_cancellation_flag
ts_parser_set_logger
ts_parser_logger
ts_parser_print_dot_graphs
ts_tree_copy
ts_tree_delete
ts_tree_root_node
ts_tree_language
ts_tree_edit
ts_tree_get_changed_ranges
ts_tree_print_dot_graph
ts_node_type                            treesit-node-type
ts_node_symbol
ts_node_start_byte                      treesit-node-start
ts_node_start_point
ts_node_end_byte                        treesit-node-end
ts_node_end_point
ts_node_string                          treesit-node-string
ts_node_is_null
ts_node_is_named                        treesit-node-check
ts_node_is_missing                      treesit-node-check
ts_node_is_extra                        treesit-node-check
ts_node_has_changes
ts_node_has_error                       treesit-node-check
ts_node_parent                          treesit-node-parent
ts_node_child                           treesit-node-child
ts_node_field_name_for_child            treesit-node-field-name-for-child
ts_node_child_count                     treesit-node-child-count
ts_node_named_child                     treesit-node-child
ts_node_named_child_count               treesit-node-child-count
ts_node_child_by_field_name             treesit-node-child-by-field-name
ts_node_child_by_field_id
ts_node_next_sibling                    treesit-node-next-sibling
ts_node_prev_sibling                    treesit-node-prev-sibling
ts_node_next_named_sibling              treesit-node-next-sibling
ts_node_prev_named_sibling              treesit-node-prev-sibling
ts_node_first_child_for_byte            treesit-node-first-child-for-pos
ts_node_first_named_child_for_byte      treesit-node-first-child-for-pos
ts_node_descendant_for_byte_range       treesit-node-descendant-for-range
ts_node_descendant_for_point_range
ts_node_named_descendant_for_byte_range treesit-node-descendant-for-range
ts_node_named_descendant_for_point_range
ts_node_edit
ts_node_eq                              treesit-node-eq
ts_tree_cursor_new
ts_tree_cursor_delete
ts_tree_cursor_reset
ts_tree_cursor_current_node
ts_tree_cursor_current_field_name
ts_tree_cursor_current_field_id
ts_tree_cursor_goto_parent
ts_tree_cursor_goto_next_sibling
ts_tree_cursor_goto_first_child
ts_tree_cursor_goto_first_child_for_byte
ts_tree_cursor_goto_first_child_for_point
ts_tree_cursor_copy
ts_query_new
ts_query_delete
ts_query_pattern_count
ts_query_capture_count
ts_query_string_count
ts_query_start_byte_for_pattern
ts_query_predicates_for_pattern
ts_query_step_is_definite
ts_query_capture_name_for_id
ts_query_string_value_for_id
ts_query_disable_capture
ts_query_disable_pattern
ts_query_cursor_new
ts_query_cursor_delete
ts_query_cursor_exec                    treesit-query-capture
ts_query_cursor_did_exceed_match_limit
ts_query_cursor_match_limit
ts_query_cursor_set_match_limit
ts_query_cursor_set_byte_range
ts_query_cursor_set_point_range
ts_query_cursor_next_match
ts_query_cursor_remove_match
ts_query_cursor_next_capture
ts_language_symbol_count
ts_language_symbol_name
ts_language_symbol_for_name
ts_language_field_count
ts_language_field_name_for_id
ts_language_field_id_for_name
ts_language_symbol_type
ts_language_version
@end example