;;; treesit.el --- tree-sitter utilities -*- lexical-binding: t -*- ;; Copyright (C) 2021-2022 Free Software Foundation, Inc. ;; Maintainer: 付禹安 (Yuan Fu) ;; Keywords: treesit, tree-sitter, languages ;; Package: emacs ;; This file is part of GNU Emacs. ;; GNU Emacs is free software: you can redistribute it and/or modify ;; it under the terms of the GNU General Public License as published by ;; the Free Software Foundation, either version 3 of the License, or ;; (at your option) any later version. ;; GNU Emacs is distributed in the hope that it will be useful, ;; but WITHOUT ANY WARRANTY; without even the implied warranty of ;; MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the ;; GNU General Public License for more details. ;; You should have received a copy of the GNU General Public License ;; along with GNU Emacs. If not, see . ;;; Commentary: ;; This file is the Lisp counterpart of treesit.c. Together they ;; provide tree-sitter integration for Emacs. This file contains ;; convenient functions that are more idiomatic and flexible than the ;; exposed C API of tree-sitter. It also contains frameworks for ;; integrating tree-sitter with font-lock, indentation, activating and ;; deactivating tree-sitter, debugging tree-sitter, etc. ;;; Code: (eval-when-compile (require 'cl-lib)) (eval-when-compile (require 'subr-x)) ; For `string-join'. (require 'cl-seq) (require 'font-lock) ;;; Function declarations (declare-function treesit-language-available-p "treesit.c") (declare-function treesit-language-version "treesit.c") (declare-function treesit-parser-p "treesit.c") (declare-function treesit-node-p "treesit.c") (declare-function treesit-compiled-query-p "treesit.c") (declare-function treesit-query-p "treesit.c") (declare-function treesit-query-language "treesit.c") (declare-function treesit-node-parser "treesit.c") (declare-function treesit-parser-create "treesit.c") (declare-function treesit-parser-delete "treesit.c") (declare-function treesit-parser-list "treesit.c") (declare-function treesit-parser-buffer "treesit.c") (declare-function treesit-parser-language "treesit.c") (declare-function treesit-parser-root-node "treesit.c") (declare-function treesit-parser-set-included-ranges "treesit.c") (declare-function treesit-parser-included-ranges "treesit.c") (declare-function treesit-parser-add-notifier "treesit.c") (declare-function treesit-node-type "treesit.c") (declare-function treesit-node-start "treesit.c") (declare-function treesit-node-end "treesit.c") (declare-function treesit-node-string "treesit.c") (declare-function treesit-node-parent "treesit.c") (declare-function treesit-node-child "treesit.c") (declare-function treesit-node-check "treesit.c") (declare-function treesit-node-field-name-for-child "treesit.c") (declare-function treesit-node-child-count "treesit.c") (declare-function treesit-node-child-by-field-name "treesit.c") (declare-function treesit-node-next-sibling "treesit.c") (declare-function treesit-node-prev-sibling "treesit.c") (declare-function treesit-node-first-child-for-pos "treesit.c") (declare-function treesit-node-descendant-for-range "treesit.c") (declare-function treesit-node-eq "treesit.c") (declare-function treesit-pattern-expand "treesit.c") (declare-function treesit-query-expand "treesit.c") (declare-function treesit-query-compile "treesit.c") (declare-function treesit-query-capture "treesit.c") (declare-function treesit-search-subtree "treesit.c") (declare-function treesit-search-forward "treesit.c") (declare-function treesit-induce-sparse-tree "treesit.c") (declare-function treesit-available-p "treesit.c") ;;; Custom options ;; Tree-sitter always appear as treesit in symbols. (defgroup treesit nil "Incremental parser. It is used to enhance major mode features like font-lock, indent, imenu, etc." :group 'tools :version "29.1") (defcustom treesit-max-buffer-size (let ((mb (* 1024 1024))) ;; 40MB for 64-bit systems, 15 for 32-bit. (if (or (< most-positive-fixnum (* 2.0 1024 mb)) ;; 32-bit system with wide ints. (string-match-p "--with-wide-int" system-configuration-options)) (* 15 mb) (* 40 mb))) "Maximum buffer size (in bytes) for enabling tree-sitter parsing. A typical tree-sitter parser needs 10 times as much memory as the buffer it parses. Also, the tree-sitter library has a hard limit of max unsigned 32-bit value for byte offsets into buffer text." :type 'integer :version "29.1") ;;; Parser API supplement (defun treesit-parse-string (string language) "Parse STRING using a parser for LANGUAGE. Return the root node of the syntax tree." (with-temp-buffer (insert string) (treesit-parser-root-node (treesit-parser-create language)))) (defvar-local treesit-language-at-point-function nil "A function that returns the language at point. This is used by `treesit-language-at', which is used by various functions to determine which parser to use at point. The function is called with one argument, the position of point.") (defun treesit-language-at (position) "Return the language at POSITION. This function assumes that parser ranges are up-to-date. It returns the return value of `treesit-language-at-point-function' if it's non-nil, otherwise it returns the language of the first parser in `treesit-parser-list', or nil if there is no parser." (if treesit-language-at-point-function (funcall treesit-language-at-point-function position) (when-let ((parser (car (treesit-parser-list)))) (treesit-parser-language parser)))) ;;; Node API supplement (define-error 'treesit-no-parser "No available parser for this buffer" 'treesit-error) (defun treesit-node-buffer (node) "Return the buffer in which NODE belongs." (treesit-parser-buffer (treesit-node-parser node))) (defun treesit-node-language (node) "Return the language symbol that NODE's parser uses." (treesit-parser-language (treesit-node-parser node))) (defun treesit-node-at (pos &optional parser-or-lang named) "Return the leaf node at position POS. A leaf node is a node that doesn't have any child nodes. The returned node's span covers POS: the node's beginning is before or at POS, and the node's end is at or after POS. If no leaf node's span covers POS (e.g., POS is on whitespace between two leaf nodes), return the first leaf node after POS. If there is no leaf node after POS, return the first leaf node before POS. Return nil if no leaf node can be returned. If NAMED is non-nil, only look for named nodes. If PARSER-OR-LANG is a parser, use that parser; if PARSER-OR-LANG is a language, find the first parser for that language in the current buffer, or create one if none exists; If PARSER-OR-LANG is nil, try to guess the language at POS using `treesit-language-at'." (let* ((root (if (treesit-parser-p parser-or-lang) (treesit-parser-root-node parser-or-lang) (treesit-buffer-root-node (or parser-or-lang (treesit-language-at pos))))) (node root) (node-before root) (pos-1 (max (1- pos) (point-min))) next) (when node ;; This is very fast so no need for C implementation. (while (setq next (treesit-node-first-child-for-pos node pos named)) (setq node next)) ;; If POS is at the end of buffer, after all the text, we will ;; end up with NODE = root node. Instead of returning nil, ;; return the last leaf node in the tree for convenience. (if (treesit-node-eq node root) (progn (while (setq next (treesit-node-child node -1 named)) (setq node next)) node) ;; Normal case, where we found a node. (if (<= (treesit-node-start node) pos) node ;; So the node we found is completely after POS, try to find ;; a node whose end equals to POS. (while (setq next (treesit-node-first-child-for-pos node-before pos-1 named)) (setq node-before next)) (if (eq (treesit-node-end node-before) pos) node-before node)))))) (defun treesit-node-on (beg end &optional parser-or-lang named) "Return the smallest node covering BEG to END. 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. You probably want to use `treesit-node-at' instead. Return nil if none was found. If NAMED is non-nil, only look for named node. If PARSER-OR-LANG is a parser, use that parser; if PARSER-OR-LANG is a language, find the first parser for that language in the current buffer, or create one if none exists; If PARSER-OR-LANG is nil, try to guess the language at BEG using `treesit-language-at'." (let ((root (if (treesit-parser-p parser-or-lang) (treesit-parser-root-node parser-or-lang) (treesit-buffer-root-node (or parser-or-lang (treesit-language-at beg)))))) (treesit-node-descendant-for-range root beg (or end beg) named))) (defun treesit-node-top-level (node &optional pred include-node) "Return the top-level equivalent of NODE. Specifically, return the highest parent of NODE that has the same type as it. If no such parent exists, return nil. If PRED is non-nil, match each parent's type with PRED as a regexp, rather than using NODE's type. PRED can also be a function that takes the node as an argument, and return non-nil/nil for match/no match. If INCLUDE-NODE is non-nil, return NODE if it satisfies PRED." (let ((pred (or pred (treesit-node-type node))) (result nil)) (cl-loop for cursor = (if include-node node (treesit-node-parent node)) then (treesit-node-parent cursor) while cursor if (if (stringp pred) (string-match-p pred (treesit-node-type cursor)) (funcall pred cursor)) do (setq result cursor)) result)) (defun treesit-buffer-root-node (&optional language) "Return the root node of the current buffer. Use the first parser in the parser list if LANGUAGE is omitted. If LANGUAGE is non-nil, use the first parser for LANGUAGE in the parser list, or create one if none exists." (if-let ((parser (if language (treesit-parser-create language) (or (car (treesit-parser-list)) (signal 'treesit-no-parser (list (current-buffer))))))) (treesit-parser-root-node parser))) (defun treesit-filter-child (node pred &optional named) "Return children of NODE that satisfies predicate PRED. PRED is a function that takes one argument, the child node. If optional argument NAMED is non-nil, only search for named node." (let ((child (treesit-node-child node 0 named)) result) (while child (when (funcall pred child) (push child result)) (setq child (treesit-node-next-sibling child named))) (reverse result))) (defun treesit-node-text (node &optional no-property) "Return the buffer (or string) content corresponding to NODE. If optional argument NO-PROPERTY is non-nil, remove text properties." (when node (with-current-buffer (treesit-node-buffer node) (if no-property (buffer-substring-no-properties (treesit-node-start node) (treesit-node-end node)) (buffer-substring (treesit-node-start node) (treesit-node-end node)))))) (defun treesit-parent-until (node pred &optional include-node) "Return the closest parent of NODE that satisfies PRED. Return nil if none was found. PRED should be a function that takes one argument, the parent node, and return non-nil/nil for match/no match. If INCLUDE-NODE is non-nil, return NODE if it satisfies PRED." (let ((node (if include-node node (treesit-node-parent node)))) (while (and node (not (funcall pred node))) (setq node (treesit-node-parent node))) node)) (defun treesit-parent-while (node pred) "Return the furthest parent of NODE that satisfies PRED. Return nil if none was found. PRED should be a function that takes one argument, the parent node." (let ((last nil)) (while (and node (funcall pred node)) (setq last node node (treesit-node-parent node))) last)) (defun treesit-node-children (node &optional named) "Return a list of NODE's children. If NAMED is non-nil, collect named child only." (mapcar (lambda (idx) (treesit-node-child node idx named)) (number-sequence 0 (1- (treesit-node-child-count node named))))) (defun treesit-node-index (node &optional named) "Return the index of NODE in its parent. If NAMED is non-nil, count named child only." (let ((count 0)) (while (setq node (treesit-node-prev-sibling node named)) (cl-incf count)) count)) (defun treesit-node-field-name (node) "Return the field name of NODE as a child of its parent." (when-let ((parent (treesit-node-parent node)) (idx (treesit-node-index node))) (treesit-node-field-name-for-child parent idx))) ;;; Query API supplement (defun treesit-query-string (string query language) "Query STRING with QUERY in LANGUAGE. See `treesit-query-capture' for QUERY." (with-temp-buffer (insert string) (let ((parser (treesit-parser-create language))) (treesit-query-capture (treesit-parser-root-node parser) query)))) (defun treesit-query-range (node query &optional beg end) "Query the current buffer and return ranges of captured nodes. QUERY, NODE, BEG, END are the same as in `treesit-query-capture'. This function returns a list of (START . END), where START and END specifics the range of each captured node. Capture names don't matter." (cl-loop for capture in (treesit-query-capture node query beg end) for node = (cdr capture) collect (cons (treesit-node-start node) (treesit-node-end node)))) ;;; Range API supplement (defvar-local treesit-range-settings nil "A list of range settings. Each element of the list is of the form (QUERY LANGUAGE). When updating the range of each parser in the buffer, `treesit-update-ranges' queries each QUERY, and sets LANGUAGE's range to the range spanned by captured nodes. QUERY must be a compiled query. QUERY can also be a function, in which case it is called with 2 arguments, START and END. It should ensure parsers' ranges are correct in the region between START and END. The exact form of each setting is considered internal and subject to change. Use `treesit-range-rules' to set this variable.") (defun treesit-range-rules (&rest query-specs) "Produce settings for `treesit-range-settings'. QUERY-SPECS are a series of QUERY-SPECs, where each QUERY-SPEC is a QUERY preceded by zero or more pairs of :KEYWORD and VALUE, like this: :KEYWORD VALUE... QUERY Each QUERY is a tree-sitter query in either the string, s-expression or compiled form. For each QUERY, :KEYWORD and VALUE pairs add meta information to it. For example, (treesit-range-rules :embed \\='javascript :host \\='html \\='((script_element (raw_text) @cap))) The `:embed' keyword specifies the embedded language, and the `:host' keyword specifies the host language. They are used in this way: Emacs queries QUERY in the host language's parser, computes the ranges spanned by the captured nodes, and applies these ranges to parsers for the embedded language. QUERY can also be a function that takes two arguments, START and END. If QUERY is a function, it doesn't need the :KEYWORD VALUE pair preceding it. This function should set the ranges for parsers in the current buffer in the region between START and END. It is OK for this function to set ranges in a larger region that encompasses the region between START and END." (let (host embed result) (while query-specs (pcase (pop query-specs) (:host (let ((host-lang (pop query-specs))) (unless (symbolp host-lang) (signal 'treesit-error (list "Value of :host option should be a symbol" host-lang))) (setq host host-lang))) (:embed (let ((embed-lang (pop query-specs))) (unless (symbolp embed-lang) (signal 'treesit-error (list "Value of :embed option should be a symbol" embed-lang))) (setq embed embed-lang))) (query (if (functionp query) (push (list query nil nil) result) (when (null embed) (signal 'treesit-error (list "Value of :embed option cannot be omitted"))) (when (null host) (signal 'treesit-error (list "Value of :host option cannot be omitted"))) (push (list (treesit-query-compile host query) embed host) result)) (setq host nil embed nil)))) (nreverse result))) (defun treesit--merge-ranges (old-ranges new-ranges start end) "Merge OLD-RANGES and NEW-RANGES, discarding ranges between START and END. OLD-RANGES and NEW-RANGES are lists of cons of the form (BEG . END). When merging the two ranges, if a range in OLD-RANGES intersects with another range in NEW-RANGES, discard the one in OLD-RANGES and keep the one in NEW-RANGES. Also discard any range in OLD-RANGES that intersects the region marked by START and END. Return the merged list of ranges." (let ((result nil)) (while (and old-ranges new-ranges) (let ((new-beg (caar new-ranges)) (new-end (cdar new-ranges)) (old-beg (caar old-ranges)) (old-end (cdar old-ranges))) (cond ;; Old range intersects with START-END, discard. ((and (< start old-end) (< old-beg end)) (setq old-ranges (cdr old-ranges))) ;; New range and old range don't intersect, new comes ;; before, push new. ((<= new-end old-beg) (push (car new-ranges) result) (setq new-ranges (cdr new-ranges))) ;; New range and old range don't intersect, old comes ;; before, push old. ((<= old-end new-beg) (push (car old-ranges) result) (setq old-ranges (cdr old-ranges))) (t ;; New and old range intersect, discard old. (setq old-ranges (cdr old-ranges)))))) (let ((left-over (or new-ranges old-ranges))) (dolist (range left-over) (push range result))) (nreverse result))) (defun treesit--clip-ranges (ranges start end) "Clip RANGES in between START and END. RANGES is a list of ranges of the form (BEG . END). Ranges outside of the region between START and END are thrown away, and those inside are kept." (cl-loop for range in ranges if (<= start (car range) (cdr range) end) collect range)) (defun treesit-update-ranges (&optional beg end) "Update the ranges for each language in the current buffer. If BEG and END are non-nil, only update parser ranges in that region." ;; When updating ranges, we want to avoid querying the whole buffer ;; which could be slow in very large buffers. Instead, we only ;; query for nodes that intersect with the region between BEG and ;; END. Also, we only update the ranges intersecting BEG and END; ;; outside of that region we inherit old ranges. (dolist (setting treesit-range-settings) (let ((query (nth 0 setting)) (language (nth 1 setting)) (beg (or beg (point-min))) (end (or end (point-max)))) (if (functionp query) (funcall query beg end) (let* ((host-lang (treesit-query-language query)) (parser (treesit-parser-create language)) (old-ranges (treesit-parser-included-ranges parser)) (new-ranges (treesit-query-range host-lang query beg end)) (set-ranges (treesit--clip-ranges (treesit--merge-ranges old-ranges new-ranges beg end) (point-min) (point-max)))) (dolist (parser (treesit-parser-list)) (when (eq (treesit-parser-language parser) language) (treesit-parser-set-included-ranges parser set-ranges)))))))) (defun treesit-parser-range-on (parser beg &optional end) "Check if PARSER's range covers the portion between BEG and END. If it does, return the range covering that portion in the form of (RANGE-BEG . RANGE-END), if not, return nil. If nil or omitted, default END to BEG." (let ((ranges (treesit-parser-included-ranges parser)) (end (or end beg))) (if (null ranges) (cons (point-min) (point-max)) (cl-loop for rng in ranges if (<= (car rng) beg end (cdr rng)) return rng finally return nil)))) ;;; Fontification (define-error 'treesit-font-lock-error "Generic tree-sitter font-lock error" 'treesit-error) (defvar-local treesit-font-lock-level 3 "Decoration level to be used by tree-sitter fontifications. Major modes categorize their fontification features into levels, from 1 which is the absolute minimum, to 4 that yields the maximum fontifications. Level 1 usually contains only comments and definitions. Level 2 usually adds keywords, strings, constants, types, etc. Level 3 usually represents a full-blown fontification, including assignment, constants, numbers, properties, etc. Level 4 adds everything else that can be fontified: delimiters, operators, brackets, all functions and variables, etc. In addition to the decoration level, individual features can be turned on/off by calling `treesit-font-lock-recompute-features'. Changing the decoration level requires calling `treesit-font-lock-recompute-features' to have an effect.") (defvar-local treesit--font-lock-query-expand-range (cons 0 0) "The amount to expand the start and end of the region when fontifying. This should be a cons cell (START . END). When fontifying a buffer, Emacs will move the start of the query range backward by START amount, and the end of the query range by END amount. Both START and END should be positive integers or 0. This doesn't affect the fontified range.") (defvar-local treesit-font-lock-feature-list nil "A list of lists of feature symbols. Use `treesit-font-lock-recompute-features' and `treesit-font-lock-level' to configure enabled features. Each sublist represents a decoration level. `treesit-font-lock-level' controls which levels are activated. Inside each sublist are feature symbols, which correspond to the :feature value of a query defined in `treesit-font-lock-rules'. Removing a feature symbol from this list disables the corresponding query during font-lock. Common feature names (for general programming languages) include definition, type, assignment, builtin, constant, keyword, string-interpolation, comment, doc, string, operator, property, preprocessor, escape-sequence, key (in key-value pairs). Major modes are free to subdivide or extend on these common features. See the manual for more explanations on some of the features. For changes to this variable to take effect, run `treesit-font-lock-recompute-features'.") (defvar-local treesit-font-lock-settings nil "A list of SETTINGs for treesit-based fontification. The exact format of each SETTING is considered internal. Use `treesit-font-lock-rules' to set this variable. Each SETTING has the form: (QUERY ENABLE FEATURE OVERRIDE) QUERY must be a compiled query. See Info node `(elisp)Pattern Matching' for how to write a query and compile it. For SETTING to be activated for font-lock, ENABLE must be t. To disable this SETTING, set ENABLE to nil. FEATURE is the \"feature name\" of the query. Users can control which features are enabled with `treesit-font-lock-level' and `treesit-font-lock-feature-list'. OVERRIDE is the override flag for this query. Its value can be t, nil, append, prepend, keep. See more in `treesit-font-lock-rules'.") (defun treesit-font-lock-rules (&rest query-specs) "Return a value suitable for `treesit-font-lock-settings'. QUERY-SPECS is a series of QUERY-SPECs. Each QUERY-SPEC is a QUERY preceded by multiple pairs of :KEYWORD and VALUE: :KEYWORD VALUE... QUERY QUERY is a tree-sitter query in either the string, s-expression or compiled form. For each query, captured nodes are highlighted with the capture name as its face. :KEYWORD and VALUE pairs preceding a QUERY add meta information to QUERY. For example, (treesit-font-lock-rules :language \\='javascript :override t :feature\\='constant \\='((true) @font-lock-constant-face (false) @font-lock-constant-face) :language \\='html :feature \\='script \"(script_element) @font-lock-builtin-face\") For each QUERY, a :language keyword and a :feature keyword are required. Each query's :feature is a symbol summarizing what the query fontifies. It is used to allow users to enable/disable certain features. See `treesit-font-lock-feature-list' for more. Other keywords include: KEYWORD VALUE DESCRIPTION :override nil If the region already has a face, discard the new face. t Always apply the new face. `append' Append the new face to existing ones. `prepend' Prepend the new face to existing ones. `keep' Fill-in regions without an existing face. Capture names in QUERY should be face names like `font-lock-keyword-face'. The captured node will be fontified with that face. Capture names can also be function names, in which case the function will be called with the following argument list: (NODE OVERRIDE START END &rest _) where NODE is the tree-sitter node object, OVERRIDE is the override option of that rule, and START and END specify the region to be fontified. This function should accept more arguments as optional arguments for future extensibility, and it shouldn't fontify text outside the region given by START and END. If a capture name is both a face and a function, the face takes priority. If a capture name is not a face name nor a function name, it is ignored." ;; Other tree-sitter function don't tend to be called unless ;; tree-sitter is enabled, which means tree-sitter must be compiled. ;; But this function is usually call in `defvar' which runs ;; regardless whether tree-sitter is enabled. So we need this ;; guard. (when (treesit-available-p) (let (;; Tracks the current :language/:override/:toggle/:level value ;; that following queries will apply to. current-language current-override current-feature ;; The list this function returns. (result nil)) (while query-specs (let ((token (pop query-specs))) (pcase token ;; (1) Process keywords. (:language (let ((lang (pop query-specs))) (when (or (not (symbolp lang)) (null lang)) (signal 'treesit-font-lock-error `("Value of :language should be a symbol" ,lang))) (setq current-language lang))) (:override (let ((flag (pop query-specs))) (when (not (memq flag '(t nil append prepend keep))) (signal 'treesit-font-lock-error `("Value of :override should be one of t, nil, append, prepend, keep" ,flag)) (signal 'wrong-type-argument `((or t nil append prepend keep) ,flag))) (setq current-override flag))) (:feature (let ((var (pop query-specs))) (when (or (not (symbolp var)) (memq var '(t nil))) (signal 'treesit-font-lock-error `("Value of :feature should be a symbol" ,var))) (setq current-feature var))) ;; (2) Process query. ((pred treesit-query-p) (when (null current-language) (signal 'treesit-font-lock-error `("Language unspecified, use :language keyword to specify a language for this query" ,token))) (when (null current-feature) (signal 'treesit-font-lock-error `("Feature unspecified, use :feature keyword to specify the feature name for this query" ,token))) (if (treesit-compiled-query-p token) (push `(,current-language token) result) (push `(,(treesit-query-compile current-language token) t ,current-feature ,current-override) result)) ;; Clears any configurations set for this query. (setq current-language nil current-override nil current-feature nil)) (_ (signal 'treesit-font-lock-error `("Unexpected value" ,token)))))) (nreverse result)))) ;; `font-lock-fontify-region-function' has the LOUDLY argument, but ;; `jit-lock-functions' doesn't pass that argument. So even if we set ;; `font-lock-verbose' to t, if jit-lock is enabled (and it's almost ;; always is), we don't get debug messages. So we add our own. (defvar treesit--font-lock-verbose nil "If non-nil, print debug messages when fontifying.") (defun treesit-font-lock-recompute-features (&optional add-list remove-list) "Enable/disable font-lock features. Enable each feature in ADD-LIST, disable each feature in REMOVE-LIST. If both ADD-LIST and REMOVE-LIST are omitted, recompute each feature according to `treesit-font-lock-feature-list' and `treesit-font-lock-level'. If the value of `treesit-font-lock-level', is N, then the features in the first N sublists of `treesit-font-lock-feature-list' are enabled, and the rest of the features are disabled. ADD-LIST and REMOVE-LIST are lists of feature symbols. The same feature symbol cannot appear in both lists; the function signals the `treesit-font-lock-error' error if that happens." (when-let ((intersection (cl-intersection add-list remove-list))) (signal 'treesit-font-lock-error (list "ADD-LIST and REMOVE-LIST contain the same feature" intersection))) (let* ((level treesit-font-lock-level) (base-features (cl-loop for idx = 0 then (1+ idx) for features in treesit-font-lock-feature-list if (or (eq level t) (>= level (1+ idx))) append features)) (features (cl-set-difference (cl-union base-features add-list) remove-list)) ;; If additive non-nil, we are configuring on top of the ;; existing configuration, if nil, we are resetting ;; everything according to `treesit-font-lock-feature-list'. (additive (or add-list remove-list))) (cl-loop for idx = 0 then (1+ idx) for setting in treesit-font-lock-settings for feature = (nth 2 setting) for current-value = (nth 1 setting) ;; Set the ENABLE flag for the setting. do (setf (nth 1 (nth idx treesit-font-lock-settings)) (cond ((not additive) (if (memq feature features) t nil)) ((memq feature add-list) t) ((memq feature remove-list) nil) (t current-value)))))) (defun treesit-fontify-with-override (start end face override &optional bound-start bound-end) "Apply FACE to the region between START and END. OVERRIDE can be nil, t, `append', `prepend', or `keep'. See `treesit-font-lock-rules' for their semantic. If BOUND-START and BOUND-END are non-nil, only fontify the region in between them." (when (or (null bound-start) (null bound-end) (and bound-start bound-end (<= bound-start end) (>= bound-end start))) (when (and bound-start bound-end) (setq start (max bound-start start) end (min bound-end end))) (pcase override ('nil (unless (text-property-not-all start end 'face nil) (put-text-property start end 'face face))) ('t (put-text-property start end 'face face)) ('append (font-lock-append-text-property start end 'face face)) ('prepend (font-lock-prepend-text-property start end 'face face)) ('keep (font-lock-fillin-text-property start end 'face face)) (_ (signal 'treesit-font-lock-error (list "Unrecognized value of :override option" override)))))) (defun treesit--set-nonsticky (start end sym &optional remove) "Set `rear-nonsticky' property between START and END. Set the property to a list containing SYM. If there is already a list, add SYM to that list. If REMOVE is non-nil, remove SYM instead." (let* ((prop (get-text-property start 'rear-nonsticky)) (new-prop (pcase prop ((pred listp) ; PROP is a list or nil. (if remove (remove sym prop) ;; We should make sure PORP doesn't contain SYM, but ;; whatever. (cons sym prop))) ;; PROP is t. (_ (if remove nil (list sym)))))) (if (null new-prop) (remove-text-properties start end '(rear-nonsticky nil)) (put-text-property start end 'rear-nonsticky new-prop)))) (defun treesit--children-covering-range (node start end) "Return a list of children of NODE covering a range. The range is between START and END." (if-let* ((child (treesit-node-first-child-for-pos node start)) (result (list child))) (progn (while (and child (< (treesit-node-end child) end) (setq child (treesit-node-next-sibling child))) (push child result)) (nreverse result)) (list node))) (defun treesit--children-covering-range-recurse (node start end threshold &optional limit) "Return a list of children of NODE covering a range. Recursively go down the parse tree and collect children, until all nodes in the returned list are smaller than THRESHOLD. The range is between START and END. LIMIT is the recursion limit, which defaults to 100." (let* ((child (treesit-node-first-child-for-pos node start)) (limit (or limit 100)) result) ;; If LIMIT is exceeded, we are probably seeing the erroneously ;; tall tree, in that case, just give up. (while (and (> limit 0) child (<= (treesit-node-start child) end)) ;; If child still too large, recurse down. Otherwise collect ;; child. (if (> (- (treesit-node-end child) (treesit-node-start child)) threshold) (dolist (r (treesit--children-covering-range-recurse child start end threshold (1- limit))) (push r result)) (push child result)) (setq child (treesit-node-next-sibling child))) ;; If NODE has no child, keep NODE. (or result (list node)))) (defsubst treesit--node-length (node) "Return the length of the text of NODE." (- (treesit-node-end node) (treesit-node-start node))) (defvar-local treesit--font-lock-fast-mode nil "If this variable is t, change the way we query so it's faster. This is not a general optimization and should be RARELY needed! See comments in `treesit-font-lock-fontify-region' for more detail.") ;; Some details worth explaining: ;; ;; 1. When we apply face to a node, we clip the face into the ;; currently fontifying region, this way we don't overwrite faces ;; applied by regexp-based font-lock. The clipped part will be ;; fontified fine when Emacs fontifies the region containing it. ;; ;; 2. If you insert an ending quote into a buffer, jit-lock only wants ;; to fontify that single quote, and (treesit-node-on start end) will ;; give you that quote node. We want to capture the string and apply ;; string face to it, but querying on the quote node will not give us ;; the string node. So we don't use treesit-node-on: using the root ;; node with a restricted range is very fast anyway (even in large ;; files of size ~10MB). Plus, querying the result of ;; `treesit-node-on' could still miss patterns even if we use some ;; heuristic to enlarge the node (how much to enlarge? to which ;; extent?), it's much safer to just use the root node. ;; ;; Sometimes the source file has some errors that cause tree-sitter to ;; parse it into a enormously tall tree (10k levels tall). In that ;; case querying the root node is very slow. So we try to get ;; top-level nodes and query them. This ensures that querying is fast ;; everywhere else, except for the problematic region. ;; ;; Some other time the source file has a top-level node that contains ;; a huge number of children (say, 10k children), querying that node ;; is also very slow, so instead of getting the top-level node, we ;; recursively go down the tree to find nodes that cover the region ;; but are reasonably small. ;; ;; 3. It is possible to capture a node that's completely outside the ;; region between START and END: as long as the whole pattern ;; intersects the region, all the captured nodes in that pattern are ;; returned. If the node is outside of that region, (max node-start ;; start) and friends return bad values, so we filter them out. ;; However, we don't filter these nodes out if a function will process ;; the node, because could (and often do) fontify the relatives of the ;; captured node, not just the node itself. If we took out those ;; nodes author of those functions would be very confused. (defun treesit-font-lock-fontify-region (start end &optional loudly) "Fontify the region between START and END. If LOUDLY is non-nil, display some debugging information." (when (or loudly treesit--font-lock-verbose) (message "Fontifying region: %s-%s" start end)) (treesit-update-ranges start end) (font-lock-unfontify-region start end) (dolist (setting treesit-font-lock-settings) (let* ((query (nth 0 setting)) (enable (nth 1 setting)) (override (nth 3 setting)) (language (treesit-query-language query))) (when-let ((nodes (list (treesit-buffer-root-node language))) ;; Only activate if ENABLE flag is t. (activate (eq t enable))) (ignore activate) ;; If we run into problematic files, use the "fast mode" to ;; try to recover. See comment #2 above for more explanation. (when treesit--font-lock-fast-mode (setq nodes (treesit--children-covering-range-recurse (car nodes) start end (* 4 jit-lock-chunk-size)))) ;; Query each node. (dolist (sub-node nodes) (let* ((delta-start (car treesit--font-lock-query-expand-range)) (delta-end (cdr treesit--font-lock-query-expand-range)) (start-time (current-time)) (captures (treesit-query-capture sub-node query (max (- start delta-start) (point-min)) (min (+ end delta-end) (point-max)))) (end-time (current-time))) ;; If for any query the query time is strangely long, ;; switch to fast mode (see comments above). (when (> (time-to-seconds (time-subtract end-time start-time)) 0.01) (setq-local treesit--font-lock-fast-mode t)) ;; For each captured node, fontify that node. (with-silent-modifications (dolist (capture captures) (let* ((face (car capture)) (node (cdr capture)) (node-start (treesit-node-start node)) (node-end (treesit-node-end node))) ;; If node is not in the region, take them out. See ;; comment #3 above for more detail. (if (and (facep face) (or (>= start node-end) (>= node-start end))) (when (or loudly treesit--font-lock-verbose) (message "Captured node %s(%s-%s) but it is outside of fontifing region" node node-start node-end)) (cond ((facep face) (treesit-fontify-with-override (max node-start start) (min node-end end) face override)) ((functionp face) (funcall face node override start end))) ;; Don't raise an error if FACE is neither a face nor ;; a function. This is to allow intermediate capture ;; names used for #match and #eq. (when (or loudly treesit--font-lock-verbose) (message "Fontifying text from %d to %d, Face: %s, Node: %s" (max node-start start) (min node-end end) face (treesit-node-type node)))))))))))) `(jit-lock-bounds ,start . ,end)) (defun treesit--font-lock-notifier (ranges parser) "Ensures updated parts of the parse-tree are refontified. RANGES is a list of (BEG . END) ranges, PARSER is the tree-sitter parser notifying of the change." (with-current-buffer (treesit-parser-buffer parser) (dolist (range ranges) (when treesit--font-lock-verbose (message "Notifier received range: %s-%s" (car range) (cdr range))) (put-text-property (car range) (cdr range) 'fontified nil)))) ;;; Indent (define-error 'treesit-indent-error "Generic tree-sitter indentation error" 'treesit-error) (defvar treesit--indent-verbose nil "If non-nil, log progress when indenting.") (defvar-local treesit-simple-indent-rules nil "A list of indent rule settings. Each indent rule setting should be (LANGUAGE . RULES), where LANGUAGE is a language symbol, and RULES is a list of (MATCHER ANCHOR OFFSET). MATCHER determines whether this rule applies, ANCHOR and OFFSET together determines which column to indent to. A MATCHER is a function that takes three arguments (NODE PARENT BOL). BOL is the point where we are indenting: the beginning of line content, the position of the first non-whitespace character. NODE is the largest (highest-in-tree) node starting at that point. PARENT is the parent of NODE. If MATCHER returns non-nil, meaning the rule matches, Emacs then uses ANCHOR to find an anchor, it should be a function that takes the same argument (NODE PARENT BOL) and returns a point. Finally Emacs computes the column of that point returned by ANCHOR and adds OFFSET to it, and indents to that column. OFFSET can be an integer or a variable whose value is an integer. For MATCHER and ANCHOR, Emacs provides some convenient presets. See `treesit-simple-indent-presets'.") (defvar treesit-simple-indent-presets (list (cons 'match (lambda (&optional node-type parent-type node-field node-index-min node-index-max) (lambda (node parent &rest _) (and (or (null node-type) (string-match-p node-type (or (treesit-node-type node) ""))) (or (null parent-type) (string-match-p parent-type (treesit-node-type parent))) (or (null node-field) (string-match-p node-field (or (treesit-node-field-name node) ""))) (or (null node-index-min) (>= (treesit-node-index node) node-index-min)) (or (null node-index-max) (<= (treesit-node-index node) node-index-max)))))) (cons 'n-p-gp (lambda (node-t parent-t grand-parent-t) (lambda (node parent &rest _) (and (or (null node-t) (string-match-p node-t (or (treesit-node-type node) ""))) (or (null parent-t) (string-match-p parent-t (treesit-node-type parent))) (or (null grand-parent-t) (string-match-p grand-parent-t (treesit-node-type (treesit-node-parent parent)))))))) (cons 'no-node (lambda (node &rest _) (null node))) (cons 'parent-is (lambda (type) (lambda (_n parent &rest _) (string-match-p type (treesit-node-type parent))))) (cons 'node-is (lambda (type) (lambda (node &rest _) (string-match-p type (or (treesit-node-type node) ""))))) (cons 'field-is (lambda (name) (lambda (node &rest _) (string-match-p name (or (treesit-node-field-name node) ""))))) (cons 'comment-end (lambda (_node _parent bol &rest _) (save-excursion (goto-char bol) (looking-at-p comment-end-skip)))) ;; TODO: Document. (cons 'catch-all (lambda (&rest _) t)) (cons 'query (lambda (pattern) (lambda (node parent &rest _) (cl-loop for capture in (treesit-query-capture parent pattern) if (treesit-node-eq node (cdr capture)) return t finally return nil)))) (cons 'first-sibling (lambda (_n parent &rest _) (treesit-node-start (treesit-node-child parent 0)))) ;; TODO: Document. (cons 'nth-sibling (lambda (n &optional named) (lambda (_n parent &rest _) (treesit-node-start (treesit-node-child parent n named))))) (cons 'parent (lambda (_n parent &rest _) (treesit-node-start parent))) (cons 'comment-start (lambda (_n parent &rest _) (save-excursion (goto-char (treesit-node-start parent)) (re-search-forward comment-start-skip) (skip-syntax-backward "-") (point)))) (cons 'prev-adaptive-prefix (lambda (_n parent &rest _) (save-excursion (re-search-backward (rx (not (or " " "\t" "\n"))) nil t) (beginning-of-line) (and (>= (point) (treesit-node-start parent)) ;; `adaptive-fill-regexp' will not match "/*", ;; so we need to also try `comment-start-skip'. (or (and adaptive-fill-regexp (looking-at adaptive-fill-regexp) (> (- (match-end 0) (match-beginning 0)) 0) (match-end 0)) (and comment-start-skip (looking-at comment-start-skip) (match-end 0))))))) ;; TODO: Document. (cons 'grand-parent (lambda (_n parent &rest _) (treesit-node-start (treesit-node-parent parent)))) (cons 'parent-bol (lambda (_n parent &rest _) (save-excursion (goto-char (treesit-node-start parent)) (back-to-indentation) (point)))) (cons 'prev-sibling (lambda (node &rest _) (treesit-node-start (treesit-node-prev-sibling node)))) (cons 'no-indent (lambda (_n _p bol &rest _) bol)) (cons 'prev-line (lambda (_n _p bol &rest _) (save-excursion (goto-char bol) (forward-line -1) (skip-chars-forward " \t")))) (cons 'point-min (lambda (&rest _) (point-min))) ;; TODO: Document. (cons 'and (lambda (&rest fns) (lambda (node parent bol &rest _) (cl-reduce (lambda (a b) (and a b)) (mapcar (lambda (fn) (funcall fn node parent bol)) fns))))) (cons 'or (lambda (&rest fns) (lambda (node parent bol &rest _) (cl-reduce (lambda (a b) (or a b)) (mapcar (lambda (fn) (funcall fn node parent bol)) fns))))) (cons 'not (lambda (fn) (lambda (node parent bol &rest _) (debug) (not (funcall fn node parent bol))))) (cons 'list (lambda (&rest fns) (lambda (node parent bol &rest _) (mapcar (lambda (fn) (funcall fn node parent bol)) fns))))) "A list of presets. These presets that can be used as MATHER and ANCHOR in `treesit-simple-indent-rules'. MACHTERs and ANCHORs are functions that take 3 arguments: NODE, PARENT and BOL. MATCHER: \(match NODE-TYPE PARENT-TYPE NODE-FIELD NODE-INDEX-MIN NODE-INDEX-MAX) NODE-TYPE checks for NODE's type, PARENT-TYPE checks for PARENT's type, NODE-FIELD checks for the field name of NODE in PARENT, NODE-INDEX-MIN and NODE-INDEX-MAX check for NODE's index in PARENT. Therefore, to match the first child where PARENT is \"argument_list\", use (match nil \"argument_list\" nil nil 0 0). NODE-TYPE, PARENT-TYPE, and NODE-FIELD are regexps. no-node Matches the case where NODE is nil, i.e., there is no node that starts at point. This is the case when indenting an empty line. \(parent-is TYPE) Check that PARENT's type matches regexp TYPE. \(node-is TYPE) Checks that NODE's type matches regexp TYPE. \(n-p-gp NODE-TYPE PARENT-TYPE GRANDPARENT-TYPE) Checks for NODE's, its parent's, and its grandparent's type. \(query QUERY) Queries PARENT with QUERY, and checks if NODE is captured (by any capture name). comment-end Matches if text after point matches `treesit-comment-end'. ANCHOR: first-sibling Returns the start of the first child of PARENT. parent Returns the start of PARENT. parent-bol Returns the beginning of non-space characters on the line where PARENT is on. prev-sibling Returns the start of NODE's previous sibling. no-indent Returns the start of NODE. prev-line Returns the first non-whitespace character on the previous line. point-min Returns the beginning of buffer, which is always at column 0. comment-start Goes to the position that `comment-start-skip' would return, skips whitespace backwards, and returns the resulting position. Assumes PARENT is a comment node. prev-adaptive-prefix Goes to the beginning of previous non-empty line, and tries to match `adaptive-fill-regexp'. If it matches, return the end of the match, otherwise return nil. This is useful for a `indent-relative'-like indent behavior for block comments.") (defun treesit--simple-indent-eval (exp) "Evaluate EXP. If EXP is an application and the function is a key in `treesit-simple-indent-presets', use the corresponding value as the function." ;; We don't want to match uncompiled lambdas, so make sure this cons ;; is not a function. We could move the condition functionp ;; forward, but better be explicit. (cond ((and (consp exp) (not (functionp exp))) (apply (treesit--simple-indent-eval (car exp)) (mapcar #'treesit--simple-indent-eval (cdr exp)))) ;; Presets override functions, so this condition comes before ;; `functionp'. ((alist-get exp treesit-simple-indent-presets) (alist-get exp treesit-simple-indent-presets)) ((functionp exp) exp) ((symbolp exp) (if (null exp) exp ;; Matchers only return lambdas, anchors only return ;; integer, so we should never see a variable. (signal 'treesit-indent-error (list "Couldn't find the preset corresponding to expression" exp)))) (t exp))) ;; This variable might seem unnecessary: why split ;; `treesit-indent' and `treesit-simple-indent' into two ;; functions? We add this variable in between because later we might ;; add more powerful indentation engines, and that new engine can ;; probably share `treesit-indent'. It is also useful, suggested ;; by Stefan M, to have a function that figures out how much to indent ;; but doesn't actually performs the indentation, because we might ;; want to know where will a node indent to if we put it at some other ;; location, and use that information to calculate the actual ;; indentation. And `treesit-simple-indent' is that function. I ;; forgot the example Stefan gave, but it makes a lot of sense. (defvar treesit-indent-function #'treesit-simple-indent "Function used by `treesit-indent' to do some of the work. This function is called with (NODE PARENT BOL &rest _) and returns (ANCHOR . OFFSET). BOL is the position of the beginning of the line; NODE is the \"largest\" node that starts at BOL; PARENT is its parent; ANCHOR is a point (not a node), and OFFSET is a number. Emacs finds the column of ANCHOR and adds OFFSET to it as the final indentation of the current line.") (defun treesit--indent-1 () "Indent the current line. Return (ANCHOR . OFFSET). This function is used by `treesit-indent' and `treesit-indent-region'." ;; Basically holds the common part between the two indent function. (let* ((bol (save-excursion (forward-line 0) (skip-chars-forward " \t") (point))) (smallest-node (cond ((null (treesit-parser-list)) nil) ((eq 1 (length (treesit-parser-list))) (treesit-node-at bol)) ((treesit-language-at (point)) (treesit-node-at bol (treesit-language-at (point)))) (t (treesit-node-at bol)))) (node (treesit-parent-while smallest-node (lambda (node) (eq bol (treesit-node-start node)))))) (let* ((parser (if smallest-node (treesit-node-parser smallest-node) nil)) ;; NODE would be nil if BOL is on a whitespace. In that case ;; we set PARENT to the "node at point", which would ;; encompass the whitespace. (parent (cond ((and node parser) (treesit-node-parent node)) (t (treesit-node-on bol bol))))) (funcall treesit-indent-function node parent bol)))) (defun treesit-indent () "Indent according to the result of `treesit-indent-function'." (treesit-update-ranges (line-beginning-position) (line-end-position)) ;; We don't return 'noindent even if no rules match, because ;; `indent-for-tab-command' tries to indent itself when we return ;; 'noindent, which leads to wrong indentation at times. (pcase-let* ((`(,anchor . ,offset) (treesit--indent-1))) (when (and anchor offset) (let ((col (+ (save-excursion (goto-char anchor) (current-column)) offset)) (delta (- (point-max) (point)))) (indent-line-to col) ;; Now point is at the end of indentation. If we started ;; from within the line, go back to where we started. (when (> (- (point-max) delta) (point)) (goto-char (- (point-max) delta))))))) ;; Batch size can't be too large, because we put markers on each ;; ANCHOR, so a batch size of 400 lines means 400 markers. (defvar treesit--indent-region-batch-size 400 "How many lines of indent value do we precompute. In `treesit-indent-region' we indent in batches: precompute indent for each line, apply them in one go, let parser reparse, and do it again. This way the parser doesn't need to unnecessarily reparse after indenting every single line.") (defun treesit-indent-region (beg end) "Indent the region between BEG and END. Similar to `treesit-indent', but indent a region instead." (treesit-update-ranges beg end) ;; We indent `treesit--indent-region-batch-size' lines at a time, to ;; reduce the number of times the parser needs to re-parse. In each ;; batch, we go through each line and calculate the anchor and ;; offset as usual, but instead of modifying the buffer, we save ;; these information in a vector. Once we've collected ANCHOR and ;; OFFSET for each line in the batch, we go through each line again ;; and apply the changes. Now that buffer is modified, we need to ;; reparse the buffer before continuing to indent the next batch. (let* ((meta-len 2) (vector-len (* meta-len treesit--indent-region-batch-size)) ;; This vector saves the indent meta for each line in the ;; batch. It is a vector [ANCHOR OFFSET ANCHOR OFFSET...]. ;; ANCHOR is a marker on the anchor position, and OFFSET is ;; an integer. ANCHOR and OFFSET are either both nil, or ;; both valid. (meta-vec (make-vector vector-len 0)) (lines-left-to-move 0) (end (copy-marker end t)) (idx 0) (starting-pos 0) (announce-progress (> (- end beg) 80000))) (save-excursion (goto-char beg) ;; First pass. Go through each line and compute the ;; indentation. (while (and (eq lines-left-to-move 0) (< (point) end)) (setq idx 0 starting-pos (point)) (while (and (eq lines-left-to-move 0) (< idx treesit--indent-region-batch-size) (< (point) end)) (if (looking-at (rx (* whitespace) eol) t) ;; Unlike in `indent-line' where we sometimes pre-indent ;; an empty line, We don't indent empty lines in ;; `indent-region'. Set ANCHOR and OFFSET to nil. (setf (aref meta-vec (* idx meta-len)) nil (aref meta-vec (+ 1 (* idx meta-len))) nil) (pcase-let* ((`(,anchor . ,offset) (treesit--indent-1)) (marker (aref meta-vec (* idx meta-len)))) ;; Set ANCHOR. (when anchor (if (markerp marker) (move-marker marker anchor) (setf (aref meta-vec (* idx meta-len)) (copy-marker anchor t)))) ;; SET OFFSET. (setf (aref meta-vec (+ 1 (* idx meta-len))) offset))) (cl-incf idx) (setq lines-left-to-move (forward-line 1))) ;; Now IDX = last valid IDX + 1. (goto-char starting-pos) ;; Second pass, go to each line and apply the indentation. (dotimes (jdx idx) (let ((anchor (aref meta-vec (* jdx meta-len))) (offset (aref meta-vec (+ 1 (* jdx meta-len))))) (when offset (let ((col (save-excursion (goto-char anchor) (+ offset (current-column))))) (indent-line-to col)))) (forward-line 1)) (when announce-progress (message "Indenting region...%s%%" (/ (* (- (point) beg) 100) (- end beg))))) ;; Delete markers. (dotimes (idx treesit--indent-region-batch-size) (let ((marker (aref meta-vec (* idx meta-len)))) (when (markerp marker) (move-marker marker nil)))) (move-marker end nil)))) (defun treesit-simple-indent (node parent bol) "Calculate indentation according to `treesit-simple-indent-rules'. BOL is the position of the first non-whitespace character on the current line. NODE is the largest node that starts at BOL, PARENT is NODE's parent. Return (ANCHOR . OFFSET) where ANCHOR is a node, OFFSET is the indentation offset, meaning indent to align with ANCHOR and add OFFSET." (if (null parent) (progn (when treesit--indent-verbose (message "PARENT is nil, not indenting")) (cons nil nil)) (let* ((language (treesit-node-language parent)) (rules (alist-get language treesit-simple-indent-rules))) (cl-loop for rule in rules for pred = (nth 0 rule) for anchor = (nth 1 rule) for offset = (nth 2 rule) if (treesit--simple-indent-eval (list pred node parent bol)) do (when treesit--indent-verbose (message "Matched rule: %S" rule)) and return (let ((anchor-pos (treesit--simple-indent-eval (list anchor node parent bol)))) (cons anchor-pos (if (symbolp offset) (symbol-value offset) offset))) finally return (progn (when treesit--indent-verbose (message "No matched rule")) (cons nil nil)))))) (defun treesit-check-indent (mode) "Check current buffer's indentation against a major mode MODE. Pop up a diff buffer showing the difference. Correct indentation (target) is in green, current indentation is in red." (interactive "CTarget major mode: ") (let ((source-buf (current-buffer))) (with-temp-buffer (insert-buffer-substring source-buf) (funcall mode) (indent-region (point-min) (point-max)) (diff-buffers source-buf (current-buffer))))) (defun treesit--indent-rules-optimize (rules) "Optimize simple indent RULES. RULES should be a value suitable for `treesit-simple-indent-rules'. Return the optimized version of RULES." ;; Right now this function just compiles queries. It doesn't ;; byte-compile matchers and anchors because it doesn't make much ;; difference. (cl-loop for setting in rules for lang = (car setting) for indent-rules = (cdr setting) collect (cl-labels ;; Optimize a matcher or anchor. ((optimize-func (func) (pcase func (`(query ,qry) (list 'query (treesit-query-compile lang qry))) (_ func))) ;; Optimize a rule (MATCHER ANCHOR OFFSET). (optimize-rule (rule) (let ((matcher (nth 0 rule)) (anchor (nth 1 rule)) (offset (nth 2 rule))) (list (optimize-func matcher) (optimize-func anchor) offset)))) (cons lang (mapcar #'optimize-rule indent-rules))))) ;;; Search (defun treesit-search-forward-goto (node predicate &optional start backward all) "Search forward for a node and move to its end position. Stop at the first node after NODE that matches PREDICATE. PREDICATE can be either a regexp that matches against each node's type case-insensitively, or a function that takes a node and returns nil/non-nil for match/no match. If a node matches, move to that node and return the node, otherwise return nil. If START is non-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 STRICTLY greater/less than that of NODE. BACKWARD and ALL are the same as in `treesit-search-forward'." (when-let* ((start-pos (if start (treesit-node-start node) (treesit-node-end node))) (current-pos start-pos)) ;; When searching forward and stopping at beginnings, or search ;; backward stopping at ends, it is possible to "roll back" in ;; position. Take three nodes N1, N2, N3 as an example, if we ;; start at N3, search for forward for beginning, and N1 matches, ;; we would stop at beg of N1, which is backwards! So we skip N1 ;; and keep going. ;; ;; |<--------N1------->| ;; |<--N2-->| |<--N3-->| (while (and node (if backward (>= current-pos start-pos) (<= current-pos start-pos))) (setq node (treesit-search-forward node predicate backward all)) (setq current-pos (if start (treesit-node-start node) (treesit-node-end node)))) (cond ;; When there is a match and match made progress, go to the ;; result position. ((and node (if backward (< current-pos (point)) (> current-pos (point)))) (goto-char current-pos))) node)) ;;; Navigation, defun, things ;; ;; Emacs lets you define "things" by a regexp that matches the type of ;; a node, and here are some functions that lets you find the "things" ;; at/around point, navigate backward/forward a "thing", etc. ;; ;; The most obvious "thing" is a defun, and there are thin wrappers ;; around thing functions for defun for convenience. ;; ;; We have more command-like functions like: ;; - treesit-beginning-of-thing/defun ;; - treesit-end-of-thing/defun ;; - treesit-thing/defun-at-point ;; ;; And more generic functions like: ;; - treesit--things-around ;; - treesit--top-level-thing ;; - treesit--navigate-thing ;; ;; There are also some defun-specific functions, like ;; treesit-defun-name, treesit-add-log-current-defun. ;; ;; TODO: I'm not entirely sure how would this go, so I only documented ;; the "defun" functions and didn't document any "thing" functions. ;; We should also document `treesit-block-type-regexp' and support it ;; in major modes if we can meaningfully intergrate hideshow: I tried ;; and failed, we need SomeOne that understands hideshow to look at ;; it. (BTW, hideshow should use its own ;; `treesit-hideshow-block-type-regexp'.) (defvar-local treesit-defun-type-regexp nil "A regexp that matches the node type of defun nodes. For example, \"(function|class)_definition\". Sometimes not all nodes matched by the regexp are valid defuns. In that case, set this variable to a cons cell of the form (REGEXP . PRED), where PRED is a function that takes a node (the matched node) and returns t if node is valid, or nil for invalid node. This is used by `treesit-beginning-of-defun' and friends.") (defvar-local treesit-block-type-regexp nil "Like `treesit-defun-type-regexp', but for blocks.") (defvar-local treesit-defun-tactic 'nested "Determines how does Emacs treat nested defuns. If the value is `top-level', Emacs only moves across top-level defuns, if the value is `nested', Emacs recognizes nested defuns.") (defvar-local treesit-defun-skipper #'treesit-default-defun-skipper "A function called after tree-sitter navigation moved a step. It is called with no arguments. By default, this function tries to move to the beginning of a line, either by moving to the empty newline after a defun, or the beginning of a defun. If the value is nil, no skipping is performed.") (defvar-local treesit-defun-name-function nil "A function that is called with a node and returns its defun name or nil. If the node is a defun node, return the defun name, e.g., the function name of a function. If the node is not a defun node, or the defun node doesn't have a name, or the node is nil, return nil.") (defvar-local treesit-add-log-defun-delimiter "." "The delimiter used to connect several defun names. This is used in `treesit-add-log-current-defun'.") (defsubst treesit--thing-unpack-pattern (pattern) "Unpack PATTERN in the shape of `treesit-defun-type-regexp'. Basically, (unpack REGEXP) = (REGEXP . nil) (unpack (REGEXP . PRED)) = (REGEXP . PRED)" (if (consp pattern) pattern (cons pattern nil))) (defun treesit-beginning-of-thing (pattern &optional arg) "Like `beginning-of-defun', but generalized into things. PATTERN is like `treesit-defun-type-regexp', ARG is the same as in `beginning-of-defun'. Return non-nil if successfully moved, nil otherwise." (pcase-let* ((arg (or arg 1)) (`(,regexp . ,pred) (treesit--thing-unpack-pattern pattern)) (dest (treesit--navigate-thing (point) (- arg) 'beg regexp pred))) (when dest (goto-char dest)))) (defun treesit-end-of-thing (pattern &optional arg) "Like `end-of-defun', but generalized into things. PATTERN is like `treesit-defun-type-regexp', ARG is the same as in `end-of-defun'. Return non-nil if successfully moved, nil otherwise." (pcase-let* ((arg (or arg 1)) (`(,regexp . ,pred) (treesit--thing-unpack-pattern pattern)) (dest (treesit--navigate-thing (point) arg 'end regexp pred))) (when dest (goto-char dest)))) (defun treesit-beginning-of-defun (&optional arg) "Move backward to the beginning of a defun. With argument ARG, do it that many times. Negative ARG means move forward to the ARGth following beginning of defun. If search is successful, return t, otherwise return nil. This is a tree-sitter equivalent of `beginning-of-defun'. Behavior of this function depends on `treesit-defun-type-regexp' and `treesit-defun-skipper'." (interactive "^p") (when (treesit-beginning-of-thing treesit-defun-type-regexp arg) (when treesit-defun-skipper (funcall treesit-defun-skipper)) t)) (defun treesit-end-of-defun (&optional arg _) "Move forward to next end of defun. With argument ARG, do it that many times. Negative argument -N means move back to Nth preceding end of defun. This is a tree-sitter equivalent of `end-of-defun'. Behavior of this function depends on `treesit-defun-type-regexp' and `treesit-defun-skipper'." (interactive "^p\nd") (when (treesit-end-of-thing treesit-defun-type-regexp arg) (when treesit-defun-skipper (funcall treesit-defun-skipper)))) (defun treesit-default-defun-skipper () "Skips spaces after navigating a defun. This function tries to move to the beginning of a line, either by moving to the empty newline after a defun, or to the beginning of the current line if the beginning of the defun is indented." ;; Moving forward, point at the end of a line and not already on an ;; empty line: go to BOL of the next line (which hopefully is an ;; empty line). (cond ((and (looking-at (rx (* (or " " "\t")) "\n")) (not (bolp))) (forward-line 1)) ;; Moving backward, but there are some whitespace (and only ;; whitespace) between point and BOL: go back to BOL. ((looking-back (rx (+ (or " " "\t"))) (line-beginning-position)) (beginning-of-line)))) ;; prev-sibling: ;; 1. end-of-node before pos ;; 2. highest such node ;; ;; next-sibling: ;; 1. beg-of-node after pos ;; 2. highest such node ;; ;; parent: ;; 1. node covers pos ;; 2. smallest such node (defun treesit--things-around (pos regexp &optional pred) "Return the previous, next, and parent thing around POS. Return a list of (PREV NEXT PARENT), where PREV and NEXT are previous and next sibling things around POS, and PARENT is the parent thing surrounding POS. All of three could be nil if no sound things exists. REGEXP and PRED are the same as in `treesit-thing-at-point'." (let* ((node (treesit-node-at pos)) (result (list nil nil nil))) ;; 1. Find previous and next sibling defuns. (cl-loop for idx from 0 to 1 for backward in '(t nil) ;; Make sure we go in the right direction, and the defun we find ;; doesn't cover POS. for pos-pred in (list (lambda (n) (<= (treesit-node-end n) pos)) (lambda (n) (>= (treesit-node-start n) pos))) ;; We repeatedly find next defun candidate with ;; `treesit-search-forward', and check if it is a valid defun, ;; until the node we find covers POS, meaning we've gone through ;; every possible sibling defuns. But there is a catch: ;; `treesit-search-forward' searches bottom-up, so for each ;; candidate we need to go up the tree and find the top-most ;; valid sibling, this defun will be at the same level as POS. ;; Don't use `treesit-search-forward-goto', it skips nodes in ;; order to enforce progress. when node do (let ((cursor node) (iter-pred (lambda (node) (and (string-match-p regexp (treesit-node-type node)) (or (null pred) (funcall pred node)) (funcall pos-pred node))))) ;; Find the node just before/after POS to start searching. (save-excursion (while (and cursor (not (funcall pos-pred cursor))) (setq cursor (treesit-search-forward-goto cursor "" backward backward t)))) ;; Keep searching until we run out of candidates. (while (and cursor (funcall pos-pred cursor) (null (nth idx result))) (setf (nth idx result) (treesit-node-top-level cursor iter-pred t)) (setq cursor (treesit-search-forward cursor regexp backward backward))))) ;; 2. Find the parent defun. (let ((cursor (or (nth 0 result) (nth 1 result) node)) (iter-pred (lambda (node) (and (string-match-p regexp (treesit-node-type node)) (or (null pred) (funcall pred node)) (not (treesit-node-eq node (nth 0 result))) (not (treesit-node-eq node (nth 1 result))) (< (treesit-node-start node) pos (treesit-node-end node)))))) (setf (nth 2 result) (treesit-parent-until cursor iter-pred))) result)) (defun treesit--top-level-thing (node regexp &optional pred) "Return the top-level parent thing of NODE. REGEXP and PRED are the same as in `treesit-thing-at-point'." (treesit-node-top-level node (lambda (node) (and (string-match-p regexp (treesit-node-type node)) (or (null pred) (funcall pred node)))) t)) ;; The basic idea for nested defun navigation is that we first try to ;; move across sibling defuns in the same level, if no more siblings ;; exist, we move to parents's beg/end, rinse and repeat. We never ;; move into a defun, only outwards. ;; ;; Let me describe roughly what does this function do: there are four ;; possible operations: prev-beg, next-end, prev-end, next-beg, and ;; each of (prev-sibling next-sibling and parent) could exist or not ;; exist. So there are 4 times 8 = 32 situations. ;; ;; I'll only describe the situation when we go backward (prev-beg & ;; prev-end), and consider only prev-sibling & parent. Deriving the ;; reverse situations is left as an exercise for the reader. ;; ;; prev-beg (easy case): ;; 1. prev-sibling or parent exists ;; -> go the prev-sibling/parent's beg ;; ;; prev-end (tricky): ;; 1. prev-sibling exists ;; -> If you think about it, we are already at prev-sibling's end! ;; So we need to go one step further, either to ;; prev-prev-sibling's end, or parent's prev-sibling's end, etc. ;; 2. prev-sibling is nil but parent exists ;; -> Obviously we don't want to go to parent's end, instead, we ;; want to go to parent's prev-sibling's end. Again, we recurse ;; in the function to do that. (defun treesit--navigate-thing (pos arg side regexp &optional pred recursing) "Navigate thing ARG steps from POS. If ARG is positive, move forward that many steps, if negative, move backward. If SIDE is `beg', stop at the beginning of a thing, if SIDE is `end', stop at the end. This function doesn't actually move point, it just returns the position it would move to. If there aren't enough things to move across, return nil. REGEXP and PRED are the same as in `treesit-thing-at-point'. RECURSING is an internal parameter, if non-nil, it means this function is called recursively." (pcase-let* ((counter (abs arg)) ;; Move POS to the beg/end of NODE. If NODE is nil, terminate. ;; Return the position we moved to. (advance (lambda (node) (let ((dest (pcase side ('beg (treesit-node-start node)) ('end (treesit-node-end node))))) (if (null dest) (throw 'term nil) dest))))) (catch 'term (while (> counter 0) (pcase-let ((`(,prev ,next ,parent) (treesit--things-around pos regexp pred))) ;; When PARENT is nil, nested and top-level are the same, if ;; there is a PARENT, make PARENT to be the top-level parent ;; and pretend there is no nested PREV and NEXT. (when (and (eq treesit-defun-tactic 'top-level) parent) (setq parent (treesit--top-level-thing parent regexp pred) prev nil next nil)) ;; Move... (if (> arg 0) ;; ...forward. (if (and (eq side 'beg) ;; Should we skip the defun (recurse)? (cond (next (not recursing)) ; [1] (see below) (parent t) ; [2] (t nil))) ;; Special case: go to next beg-of-defun. Set POS ;; to the end of next-sib/parent defun, and run one ;; more step. If there is a next-sib defun, we only ;; need to recurse once, so we don't need to recurse ;; if we are already recursing [1]. If there is no ;; next-sib but a parent, keep stepping out ;; (recursing) until we got out of the parents until ;; (1) there is a next sibling defun, or (2) no more ;; parents [2]. (setq pos (or (treesit--navigate-thing (treesit-node-end (or next parent)) 1 'beg regexp pred t) (throw 'term nil))) ;; Normal case. (setq pos (funcall advance (or next parent)))) ;; ...backward. (if (and (eq side 'end) (cond (prev (not recursing)) (parent t) (t nil))) ;; Special case: go to prev end-of-defun. (setq pos (or (treesit--navigate-thing (treesit-node-start (or prev parent)) -1 'end regexp pred t) (throw 'term nil))) ;; Normal case. (setq pos (funcall advance (or prev parent))))) ;; A successful step! Decrement counter. (cl-decf counter)))) ;; Counter equal to 0 means we successfully stepped ARG steps. (if (eq counter 0) pos nil))) ;; TODO: In corporate into thing-at-point. (defun treesit-thing-at-point (pattern tactic) "Return the thing node at point or nil if none is found. \"Thing\" is defined by PATTERN, which can be either a string REGEXP or a cons cell (REGEXP . PRED): if a node's type matches REGEXP, it is a thing. The \"thing\" could be further restricted by PRED: if non-nil, PRED should be a function that takes a node and returns t if the node is a \"thing\", and nil if not. Return the top-level defun if TACTIC is `top-level', return the immediate parent thing if TACTIC is `nested'." (pcase-let* ((`(,regexp . ,pred) (treesit--thing-unpack-pattern pattern)) (`(,_ ,next ,parent) (treesit--things-around (point) regexp pred)) ;; If point is at the beginning of a thing, we ;; prioritize that thing over the parent in nested ;; mode. (node (or (and (eq (treesit-node-start next) (point)) next) parent))) (if (eq tactic 'top-level) (treesit--top-level-thing node regexp pred) node))) (defun treesit-defun-at-point () "Return the defun node at point or nil if none is found. Respects `treesit-defun-tactic': return the top-level defun if it is `top-level', return the immediate parent defun if it is `nested'. Return nil if `treesit-defun-type-regexp' is not set." (when treesit-defun-type-regexp (treesit-thing-at-point treesit-defun-type-regexp treesit-defun-tactic))) (defun treesit-defun-name (node) "Return the defun name of NODE. Return nil if there is no name, or if NODE is not a defun node, or if NODE is nil. If `treesit-defun-name-function' is nil, always return nil." (when treesit-defun-name-function (funcall treesit-defun-name-function node))) (defun treesit-add-log-current-defun () "Return the name of the defun at point. Used for `add-log-current-defun-function'. The delimiter between nested defun names is controlled by `treesit-add-log-defun-delimiter'." (let ((node (treesit-defun-at-point)) (name nil)) (while node (when-let ((new-name (treesit-defun-name node))) (if name (setq name (concat new-name treesit-add-log-defun-delimiter name)) (setq name new-name))) (setq node (treesit-node-parent node))) name)) ;;; Imenu (defvar treesit-simple-imenu-settings nil "Settings that configure `treesit-simple-imenu'. It should be a list of (CATEGORY REGEXP PRED NAME-FN). CATEGORY is the name of a category, like \"Function\", \"Class\", etc. REGEXP should be a regexp matching the type of nodes that belong to CATEGORY. PRED should be either nil or a function that takes a node an the argument. It should return non-nil if the node is a valid node for CATEGORY, or nil if not. CATEGORY could also be nil. In that case the entries matched by REGEXP and PRED are not grouped under CATEGORY. NAME-FN should be either nil or a function that takes a defun node and returns the name of that defun node. If NAME-FN is nil, `treesit-defun-name' is used. `treesit-major-mode-setup' automatically sets up Imenu if this variable is non-nil.") (defun treesit--simple-imenu-1 (node pred name-fn) "Given a sparse tree, create an Imenu index. NODE is a node in the tree returned by `treesit-induce-sparse-tree' (not a tree-sitter node, its car is a tree-sitter node). Walk that tree and return an Imenu index. Return a list of entries where each ENTRY has the form: ENTRY := (NAME . MARKER) | (NAME . ((\" \" . MARKER) ENTRY ...) PRED and NAME-FN are the same as described in `treesit-simple-imenu-settings'. NAME-FN computes NAME in an ENTRY. MARKER marks the start of each tree-sitter node." (let* ((ts-node (car node)) (children (cdr node)) (subtrees (mapcan (lambda (node) (treesit--simple-imenu-1 node pred name-fn)) children)) ;; The root of the tree could have a nil ts-node. (name (when ts-node (or (if name-fn (funcall name-fn ts-node) (treesit-defun-name ts-node)) "Anonymous"))) (marker (when ts-node (set-marker (make-marker) (treesit-node-start ts-node))))) (cond ;; The tree-sitter node in the root node of the tree returned by ;; `treesit-induce-sparse-tree' is often nil. ((null ts-node) subtrees) ;; This tree-sitter node is not a valid entry, skip it. ((and pred (not (funcall pred ts-node))) subtrees) ;; Non-leaf node, return a (list of) subgroup. (subtrees `((,name ,(cons " " marker) ,@subtrees))) ;; Leaf node, return a (list of) plain index entry. (t (list (cons name marker)))))) (defun treesit-simple-imenu () "Return an Imenu index for the current buffer." (let ((root (treesit-buffer-root-node))) (mapcan (lambda (setting) (pcase-let ((`(,category ,regexp ,pred ,name-fn) setting)) (when-let* ((tree (treesit-induce-sparse-tree root regexp)) (index (treesit--simple-imenu-1 tree pred name-fn))) (if category (list (cons category index)) index)))) treesit-simple-imenu-settings))) ;;; Activating tree-sitter (defun treesit-ready-p (language &optional quiet) "Check whether tree-sitter is ready to be used for MODE and LANGUAGE. LANGUAGE is the language symbol to check for availability. It can also be a list of language symbols. If tree-sitter is not ready, emit a warning and return nil. If the user has chosen to activate tree-sitter for LANGUAGE and tree-sitter is ready, return non-nil. If QUIET is t, don't emit a warning in either case; if quiet is `message', display a message instead of emitting a warning." (let ((language-list (if (consp language) language (list language))) msg) ;; Check for each condition and set MSG. (catch 'term (when (not (treesit-available-p)) (setq msg "tree-sitter library is not compiled with Emacs") (throw 'term nil)) (when (> (position-bytes (max (point-min) (1- (point-max)))) treesit-max-buffer-size) (setq msg "buffer larger than `treesit-max-buffer-size'") (throw 'term nil)) (dolist (lang language-list) (pcase-let ((`(,available . ,err) (treesit-language-available-p lang t))) (when (not available) (setq msg (format "language grammar for %s is unavailable (%s): %s" lang (nth 0 err) (string-join (mapcar (lambda (x) (format "%s" x)) (cdr err)) " "))) (throw 'term nil))))) ;; Decide if all conditions met and whether emit a warning. (if (not msg) t (setq msg (concat "Cannot activate tree-sitter, because " msg)) (pcase quiet ('nil (display-warning 'treesit msg)) ('message (message "%s" msg))) nil))) (defun treesit-major-mode-setup () "Activate tree-sitter to power major-mode features. If `treesit-font-lock-settings' is non-nil, setup fontification and enable `font-lock-mode'. If `treesit-simple-indent-rules' is non-nil, setup indentation. If `treesit-defun-type-regexp' is non-nil, setup `beginning/end-of-defun' functions. If `treesit-defun-name-function' is non-nil, setup `add-log-current-defun'. If `treesit-simple-imenu-settings' is non-nil, setup Imenu. Make sure necessary parsers are created for the current buffer before calling this function." ;; Font-lock. (when treesit-font-lock-settings ;; `font-lock-mode' wouldn't setup properly if ;; `font-lock-defaults' is nil, see `font-lock-specified-p'. (setq-local font-lock-defaults '( nil nil nil nil (font-lock-fontify-syntactically-function . treesit-font-lock-fontify-region))) (font-lock-mode 1) (treesit-font-lock-recompute-features) (dolist (parser (treesit-parser-list)) (treesit-parser-add-notifier parser #'treesit--font-lock-notifier))) ;; Indent. (when treesit-simple-indent-rules (setq-local treesit-simple-indent-rules (treesit--indent-rules-optimize treesit-simple-indent-rules)) (setq-local indent-line-function #'treesit-indent) (setq-local indent-region-function #'treesit-indent-region)) ;; Navigation. (when treesit-defun-type-regexp (keymap-set (current-local-map) " " #'treesit-beginning-of-defun) (keymap-set (current-local-map) " " #'treesit-end-of-defun) ;; `end-of-defun' will not work completely correctly in nested ;; defuns due to its implementation. However, many lisp programs ;; use `beginning/end-of-defun', so we should still set ;; `beginning/end-of-defun-function' so they still mostly work. ;; This is also what `cc-mode' does: rebind user commands and set ;; the variables. In future we should update `end-of-defun' to ;; work with nested defuns. (setq-local beginning-of-defun-function #'treesit-beginning-of-defun) (setq-local end-of-defun-function #'treesit-end-of-defun)) ;; Defun name. (when treesit-defun-name-function (setq-local add-log-current-defun-function #'treesit-add-log-current-defun)) ;; Imenu. (when treesit-simple-imenu-settings (setq-local imenu-create-index-function #'treesit-simple-imenu))) ;;; Debugging (defvar-local treesit--inspect-name nil "Used by `treesit-inspect-mode' to show node name in mode-line.") (defun treesit-inspect-node-at-point (&optional arg) "Show information of the node at point. If called interactively, show in echo area, otherwise set `treesit--inspect-name' (which will appear in the mode-line if `treesit-inspect-mode' is enabled). Uses the first parser in `treesit-parser-list'." (interactive "p") ;; NODE-LIST contains all the node that starts at point. (let* ((node-list (cl-loop for node = (treesit-node-at (point)) then (treesit-node-parent node) while node if (eq (treesit-node-start node) (point)) collect node)) (largest-node (car (last node-list))) (parent (treesit-node-parent largest-node)) ;; node-list-ascending contains all the node bottom-up, then ;; the parent. (node-list-ascending (if (null largest-node) ;; If there are no nodes that start at point, just show ;; the node at point and its parent. (list (treesit-node-at (point)) (treesit-node-parent (treesit-node-at (point)))) (append node-list (list parent)))) (name "")) ;; We draw nodes like (parent field-name: (node)) recursively, ;; so it could be (node1 field-name: (node2 field-name: (node3))). (dolist (node node-list-ascending) (setq name (concat (if (treesit-node-field-name node) (format " %s: " (treesit-node-field-name node)) " ") (if (treesit-node-check node 'named) "(" "\"") (propertize (or (treesit-node-type node) "N/A") 'face (if (treesit-node-eq node largest-node) 'bold nil)) name (if (treesit-node-check node 'named) ")" "\"")))) (setq treesit--inspect-name name) (force-mode-line-update) (when arg (if node-list (message "%s" treesit--inspect-name) (message "No node at point"))))) (define-minor-mode treesit-inspect-mode "Minor mode that displays in the mode-line the node which starts at point. When this mode is enabled, the mode-line displays PARENT FIELD-NAME: (NODE FIELD-NAME: (CHILD (...))) where NODE, CHILD, etc, are nodes which begin at point. PARENT is the parent of NODE. NODE is displayed in bold typeface. FIELD-NAMEs are field names of NODE and CHILD, etc (see Info node `(elisp)Language Grammar', heading \"Field names\"). 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 `treesit-parser-list'." :lighter nil (if treesit-inspect-mode (progn (add-hook 'post-command-hook #'treesit-inspect-node-at-point 0 t) (add-to-list 'mode-line-misc-info '(:eval treesit--inspect-name))) (remove-hook 'post-command-hook #'treesit-inspect-node-at-point t) (setq mode-line-misc-info (remove '(:eval treesit--inspect-name) mode-line-misc-info)))) (defun treesit-query-validate (language query) "Check if QUERY is valid for LANGUAGE. If QUERY is invalid, display the query in a popup buffer, jump to the offending pattern and highlight the pattern." (cl-assert (or (consp query) (stringp query))) (let ((buf (get-buffer-create "*tree-sitter check query*"))) (with-temp-buffer (treesit-parser-create language) (condition-case err (progn (treesit-query-capture language query) (message "QUERY is valid")) (treesit-query-error (with-current-buffer buf (let* ((data (cdr err)) (message (nth 0 data)) (start (nth 1 data))) (erase-buffer) (insert (treesit-query-expand query)) (goto-char start) (search-forward " " nil t) (put-text-property start (point) 'face 'error) (message "%s" (buffer-substring start (point))) (goto-char (point-min)) (insert (format "%s: %d\n" message start)) (forward-char start))) (pop-to-buffer buf) (view-mode)))))) ;;; Explorer (defface treesit-explorer-anonymous-node (let ((display t) (atts '(:inherit shadow))) `((,display . ,atts))) "Face for anonymous nodes in tree-sitter explorer.") (defface treesit-explorer-field-name (let ((display t) (atts nil)) `((,display . ,atts))) "Face for field names in tree-sitter explorer.") (defvar-local treesit--explorer-buffer nil "Buffer used to display the syntax tree.") (defvar-local treesit--explorer-source-buffer nil "Source buffer corresponding to the playground buffer.") (defvar-local treesit--explorer-language nil "The language used in the playground.") (defvar-local treesit--explorer-refresh-timer nil "Timer for refreshing the syntax tree buffer.") (defvar-local treesit--explorer-highlight-overlay nil "Overlay used to highlight in syntax tree and source buffer.") (defvar-local treesit--explorer-last-node nil "Last top-level node used to generate syntax tree.") (defvar treesit-explore-mode) (defun treesit--explorer--nodes-to-highlight (language) "Return nodes for LANGUAGE covered in region. This function tries to return the largest node possible. If the region covers exactly one node, that node is returned (in a list). If the region covers more than one node, two nodes are returned: the very first one in the region and the very last one in the region." (let* ((beg (region-beginning)) (end (region-end)) (node (treesit-node-on beg end language)) (node (or (treesit-parent-while node (lambda (n) (<= beg (treesit-node-start n) (treesit-node-end n) end))) node))) ;; If NODE is completely contained in the region, return NODE, ;; otherwise return its children that are in the region. (if (<= beg (treesit-node-start node) (treesit-node-end node) end) (list node) (list (treesit-node-at beg) (treesit-search-forward (treesit-node-at end) (lambda (n) (<= (treesit-node-end n) end)) t t))))) (defun treesit--explorer-refresh () "Update the syntax tree buffer." (when (and treesit-explore-mode (buffer-live-p treesit--explorer-buffer)) (let* ((root (treesit-node-on (window-start) (window-end) treesit--explorer-language)) ;; Only highlight the current top-level construct. ;; Highlighting the whole buffer is slow and unnecessary. (top-level (treesit-node-first-child-for-pos root (if (eolp) (max (point-min) (1- (point))) (point)) t)) ;; Only highlight node when region is active, if we ;; highlight node at point the syntax tree is too jumpy. (nodes-hl (when (region-active-p) (treesit--explorer--nodes-to-highlight treesit--explorer-language))) ;; If we didn't edit the buffer nor change the top-level ;; node, don't redraw the whole syntax tree. (highlight-only (treesit-node-eq top-level treesit--explorer-last-node)) (source-buffer (current-buffer))) (setq-local treesit--explorer-last-node top-level) (with-current-buffer treesit--explorer-buffer (let ((inhibit-read-only t)) (setq-local treesit--explorer-source-buffer source-buffer) ;; Redraw the syntax tree or just rehighlight the focused ;; node. (when (and top-level (not highlight-only)) (erase-buffer) (treesit--explorer-draw-node top-level)) (when-let ((pos (treesit--explorer-highlight-node nodes-hl)) (window (get-buffer-window treesit--explorer-buffer))) (if highlight-only (goto-char pos) ;; If HIGHLIGHT-ONLY is nil, we erased the buffer and ;; re-inserted text, scroll down from the very top until ;; we can see the highlighted node. (goto-char (point-min)) (while (and (null (pos-visible-in-window-p pos window)) (= (forward-line 4) 0)) (set-window-start window (point)))) (set-window-point window pos))))))) (defun treesit--explorer-post-command (&rest _) "Post-command function that runs in the source buffer." (when treesit-explore-mode (when treesit--explorer-highlight-overlay (delete-overlay treesit--explorer-highlight-overlay)) (when treesit--explorer-refresh-timer (cancel-timer treesit--explorer-refresh-timer)) (setq-local treesit--explorer-refresh-timer (run-with-timer 0.1 nil #'treesit--explorer-refresh)))) (defun treesit--explorer-jump (button) "Mark the original text corresponding to BUTTON." (interactive) (when (and (derived-mode-p 'treesit--explorer-tree-mode) (buffer-live-p treesit--explorer-source-buffer)) (with-current-buffer treesit--explorer-source-buffer (let ((start (button-get button 'node-start)) (end (button-get button 'node-end))) (when treesit--explorer-highlight-overlay (delete-overlay treesit--explorer-highlight-overlay)) (setq-local treesit--explorer-highlight-overlay (make-overlay start end nil t nil)) (overlay-put treesit--explorer-highlight-overlay 'face 'highlight))))) (defun treesit--explorer-highlight-node (nodes) "Highlight nodes in NODES in the syntax tree buffer. Return the start of the syntax tree text corresponding to NODE." (when treesit--explorer-highlight-overlay (delete-overlay treesit--explorer-highlight-overlay)) (let ((start-node (car nodes)) (end-node (car (last nodes))) start end) (when (and start-node end-node) (cl-loop for ov in (overlays-in (point-min) (point-max)) while (or (null start) (null end)) if (treesit-node-eq start-node (overlay-get ov 'treesit-node)) do (setq start (overlay-start ov)) if (treesit-node-eq end-node (overlay-get ov 'treesit-node)) do (setq end (overlay-end ov))) (when (and start end) (setq-local treesit--explorer-highlight-overlay (make-overlay start end)) (overlay-put treesit--explorer-highlight-overlay 'face 'highlight) start)))) (defun treesit--explorer-draw-node (node) "Draw the syntax tree of NODE. When this function is called, point should be at the position where the node should start. When this function returns, it leaves point at the end of the last line of NODE." (let* ((type (treesit-node-type node)) (field-name (treesit-node-field-name node)) (children (treesit-node-children node)) (named (treesit-node-check node 'named)) ;; Column number of the start of the field-name, aka start of ;; the whole node. (before-field-column (current-column)) ;; Column number after the field-name. after-field-column ;; Column number after the type. after-type-column ;; Are all children suitable for inline? (all-children-inline (eq 0 (apply #'+ (mapcar #'treesit-node-child-count children)))) ;; If the child is the first child, we can inline, if the ;; previous child is suitable for inline, this child can ;; inline, if the previous child is not suitable for inline, ;; this child cannot inline. (can-inline t) ;; The beg and end of this node. beg end) (when treesit--explorer-highlight-overlay (delete-overlay treesit--explorer-highlight-overlay)) (setq beg (point)) ;; Draw field name. If all children are suitable for inline, we ;; draw everything in one line, other wise draw field name and the ;; rest of the node in two lines. (when field-name (insert (propertize (concat field-name ": ") 'face 'treesit-explorer-field-name)) (when (and children (not all-children-inline)) (insert "\n") (indent-to-column (1+ before-field-column)))) (setq after-field-column (current-column)) ;; Draw type. (if named (progn (insert "(") (insert-text-button type 'action #'treesit--explorer-jump 'follow-link t 'node-start (treesit-node-start node) 'node-end (treesit-node-end node))) (pcase type ("\n" (insert "\\n")) ("\t" (insert "\\t")) (" " (insert "SPC")) (_ (insert type)))) (setq after-type-column (current-column)) ;; Draw children. (dolist (child children) ;; If a child doesn't have children, it is suitable for inline. (let ((draw-inline (eq 0 (treesit-node-child-count child))) (children-indent (1+ after-field-column))) (while ;; This form returns t if it wants to run another ;; iteration, returns nil if it wants to stop. (if (and draw-inline can-inline) ;; Draw children on the same line. (let ((inline-beg (point))) (insert " ") (treesit--explorer-draw-node child) ;; If we exceeds window width, draw on the next line. (if (< (current-column) (window-width)) nil (delete-region inline-beg (point)) (setq draw-inline nil children-indent (1+ after-type-column)) t)) ;; Draw children on the new line. (insert "\n") (indent-to-column children-indent) (treesit--explorer-draw-node child) nil)) (setq can-inline draw-inline))) ;; Done drawing children, draw the ending paren. (when named (insert ")")) (setq end (point)) ;; Associate the text with NODE, so we can later find a piece of ;; text by a node. (let ((ov (make-overlay beg end))) (overlay-put ov 'treesit-node node) (overlay-put ov 'evaporate t) (when (not named) (overlay-put ov 'face 'treesit-explorer-anonymous-node))))) (define-derived-mode treesit--explorer-tree-mode special-mode "TS Explorer" "Mode for displaying syntax trees for `treesit-explore-mode'." nil) (define-minor-mode treesit-explore-mode "Enable exploring the current buffer's syntax tree. Pops up a window showing the syntax tree of the source in the current buffer in real time. The corresponding node enclosing the text in the active region is highlighted in the explorer window." :lighter " TSplay" (if treesit-explore-mode (progn (unless (buffer-live-p treesit--explorer-buffer) (setq-local treesit--explorer-buffer (get-buffer-create (format "*tree-sitter explorer for %s*" (buffer-name)))) (setq-local treesit--explorer-language (intern (completing-read "Language: " (mapcar #'treesit-parser-language (treesit-parser-list))))) (with-current-buffer treesit--explorer-buffer (treesit--explorer-tree-mode))) (display-buffer treesit--explorer-buffer (cons nil '((inhibit-same-window . t)))) (treesit--explorer-refresh) (add-hook 'post-command-hook #'treesit--explorer-post-command 0 t) (setq-local treesit--explorer-last-node nil)) (remove-hook 'post-command-hook #'treesit--explorer-post-command t) (kill-buffer treesit--explorer-buffer))) ;;; Install & build language grammar (defvar treesit-language-source-alist nil "Configures how to download tree-sitter language grammars. This should be an alist of (LANG . (URL SOURCE-DIR GRAMMAR-DIR CC C++)) Only LANG and URL are mandatory. LANG is the language symbol. URL is the repository's url. SOURCE-DIR is the relative directory in the repository in which the grammar.c file resides, default to \"src\". GRAMMAR-DIR is the relative grammar directory in the repository in which the grammar.js file resides, default to \"\". CC and C++ are C and C++ compilers, default to \"cc\" and \"c++\", respectively.") (defun treesit-install-language-grammar (lang) "Install language grammar for LANG. This command requires git, a C compiler and (sometimes) a C++ compiler to exist and locatable in the executable paths. It also requires that the recipe for LANG exists in `treesit-language-source-alist'. Current executable paths can be checked by calling `exec-path'." (interactive (list (intern (completing-read "Language: " (mapcar #'car treesit-language-source-alist) nil t)))) (condition-case err (apply #'treesit--install-language-grammar-1 ;; The nil is OUT-DIR. (cons nil (assoc lang treesit-language-source-alist))) (error (display-warning 'treesit (format "Error encountered when installing language grammar: %s" err)))) ;; Check that the installed language grammar is loadable. (pcase-let ((`(,available . ,err) (treesit-language-available-p lang t))) (when (not available) (display-warning 'treesit (format "The installed language grammar for %s cannot be located or has problems (%s): %s" lang (nth 0 err) (string-join (mapcar (lambda (x) (format "%s" x)) (cdr err)) " ")))))) (defun treesit--call-process-signal (&rest args) "Run `call-process' with ARGS. If it returns anything but 0, signal an error. Use the buffer content as signal data, and erase buffer afterwards." (unless (eq 0 (apply #'call-process args)) (signal 'treesit-error (list "Command:" (string-join (cons (car args) (nthcdr 4 args)) " ") "Error output:" (buffer-string))) (erase-buffer))) (defun treesit--install-language-grammar-1 (out-dir lang url &optional source-dir grammar-dir cc c++) "Install and compile a tree-sitter language grammar. OUT-DIR is the direcotory to put the compiled library file, default to ~/.emacs.d/tree-sitter. For LANG, URL, SOURCE-DIR, GRAMMAR-DIR, CC, C++, see `treesit-language-source-alist'. If anything goes wrong, this function signals an error." (let* ((lang (symbol-name lang)) (default-directory "/tmp") (workdir (expand-file-name "treesit-workdir-00893133134")) (source-dir (expand-file-name (or source-dir "src") workdir)) (grammar-dir (expand-file-name (or grammar-dir "") workdir)) (cc (or cc "cc")) (c++ (or c++ "c++")) (soext (pcase system-type ('darwin "dylib") ((or 'ms-dos 'cywin 'windows-nt) "dll") (_ "so"))) (out-dir (or (and out-dir (expand-file-name out-dir)) (expand-file-name "tree-sitter" user-emacs-directory))) (lib-name (format "libtree-sitter-%s.%s" lang soext))) (unwind-protect (with-temp-buffer (message "Cloning repository") ;; git clone xxx --depth 1 --quiet workdir (treesit--call-process-signal "git" nil t nil "clone" url "--depth" "1" "--quiet" workdir) ;; cp "${grammardir}"/grammar.js "${sourcedir}" (copy-file (concat grammar-dir "/grammar.js") (concat source-dir "/grammar.js")) ;; cd "${sourcedir}" (setq default-directory source-dir) (message "Compiling library") ;; cc -fPIC -c -I. parser.c (treesit--call-process-signal cc nil t nil "-fPIC" "-c" "-I." "parser.c") ;; cc -fPIC -c -I. scanner.c (when (file-exists-p "scanner.c") (treesit--call-process-signal cc nil t nil "-fPIC" "-c" "-I." "scanner.c")) ;; c++ -fPIC -I. -c scanner.cc (when (file-exists-p "scanner.cc") (treesit--call-process-signal c++ nil t nil "-fPIC" "-c" "-I." "scanner.cc")) ;; cc/c++ -fPIC -shared *.o -o "libtree-sitter-${lang}.${soext}" (apply #'treesit--call-process-signal (if (file-exists-p "scanner.cc") c++ cc) nil t nil `("-fPIC" "-shared" ,@(directory-files default-directory nil (rx bos (+ anychar) ".o" eos)) "-o" ,lib-name)) ;; Copy out. (copy-file lib-name (concat out-dir "/") t) (message "Library installed to %s/%s" out-dir lib-name)) (when (file-exists-p workdir) (delete-directory workdir t))))) ;;; Etc (declare-function find-library-name "find-func.el") (defun treesit--check-manual-coverage () "Print tree-sitter functions missing from the manual in message buffer." (interactive) (require 'find-func) (let ((functions-in-source (with-temp-buffer (insert-file-contents (find-library-name "treesit")) (cl-remove-if (lambda (name) (string-match "treesit--" name)) (cl-sort (save-excursion (goto-char (point-min)) (cl-loop while (re-search-forward "^(defun \\([^ ]+\\)" nil t) collect (match-string-no-properties 1))) #'string<)))) (functions-in-manual (with-temp-buffer (insert-file-contents (expand-file-name "doc/lispref/parsing.texi" source-directory)) (insert-file-contents (expand-file-name "doc/lispref/modes.texi" source-directory)) (cl-sort (save-excursion (goto-char (point-min)) (cl-loop while (re-search-forward "^@defun \\([^ ]+\\)" nil t) collect (match-string-no-properties 1))) #'string<)))) (message "Missing: %s" (string-join (cl-remove-if (lambda (name) (member name functions-in-manual)) functions-in-source) "\n")))) ;;; Shortdocs (defun treesit--generate-shortdoc-examples () "Generate examples for shortdoc." (with-temp-buffer (let (node parent) (insert "int c = 0;") (print (treesit-parser-create 'c)) (print (treesit-parser-list)) (goto-char (point-min)) (print (setq node (treesit-node-at (point)))) (print (setq parent (treesit-node-parent node))) (print (treesit-node-children parent)) (print (treesit-node-next-sibling node)) (print (treesit-node-child-by-field-name parent "declarator")) nil))) (define-short-documentation-group treesit "Parsers" (treesit-parser-create :no-eval (treesit-parser-create) :eg-result-string "#") (treesit-parser-delete :no-value (treesit-parser-delete parser)) (treesit-parser-list :no-eval (treesit-parser-list) :eg-result-string "(#)") (treesit-parser-buffer :no-eval (treesit-parser-buffer parser) :eg-result-string "#") (treesit-parser-language :no-eval (treesit-parser-language parser) :eg-result c) (treesit-parser-add-notifier) (treesit-parser-remove-notifier) (treesit-parser-notifiers :no-eval (treesit-parser-notifiers parser) :eg-result (function1 function2 function3)) "Parser ranges" (treesit-parser-set-included-ranges :no-value (treesit-parser-set-included-ranges parser '((1 . 4) (5 . 8)))) (treesit-parser-included-ranges :no-eval (treesit-parser-included-ranges parser) :eg-result '((1 . 4) (5 . 8))) (treesit-query-range :no-eval (treesit-query-range node '((script_element) @cap)) :eg-result-string '((1 . 4) (5 . 8))) "Retrieving a node" (treesit-node-at :no-eval (treesit-node-at (point)) :eg-result-string "#") (treesit-node-on :no-eval (treesit-node-on 18 28) :eg-result-string "#") (treesit-buffer-root-node :no-eval (treesit-buffer-root-node) :eg-result-string "#") (treesit-parser-root-node :no-eval (treesit-parser-root-node parser) :eg-result-string "#") "Retrieving a node from another node" (treesit-node-parent :no-eval (treesit-node-parent node) :eg-result-string "#") (treesit-node-child :no-eval (treesit-node-child node 0) :eg-result-string "#") (treesit-node-children :no-eval (treesit-node-children node) :eg-result-string "(# # #)") (treesit-node-next-sibling :no-eval (treesit-node-next-sibling node) :eg-result-string "#") (treesit-node-prev-sibling :no-eval (treesit-node-prev-sibling node) :eg-result-string "#") (treesit-node-child-by-field-name :no-eval (treesit-node-child-by-field-name node "declarator") :eg-result-string "#") (treesit-first-child-for-pos :no-eval (treesit-first-child-for-pos node 1) :eg-result-string "#") (treesit-node-descendant-for-range :no-eval (treesit-node-descendant-for-range node 2 3) :eg-result-string "#") "Searching for node" (treesit-search-subtree :no-eval (treesit-search-subtree node "function_definition") :eg-result-string "#") (treesit-search-forward :no-eval (treesit-search-forward node "function_definition") :eg-result-string "#") (treesit-search-forward-goto :no-eval (treesit-search-forward-goto node "function_definition") :eg-result-string "#") (treesit-induce-sparse-tree :no-eval (treesit-induce-sparse-tree node "function_definition") :eg-result-string "(nil (#) (#) (#))") (treesit-filter-child :no-eval (treesit-filter-child node (lambda (n) (equal (treesit-node-type) "identifier"))) :eg-result-string "(#)") (treesit-parent-until :no-eval (treesit-parent-until node (lambda (p) (eq (treesit-node-start p) (point)))) :eg-result-string "#") (treesit-parent-while :no-eval (treesit-parent-while node (lambda (p) (eq (treesit-node-start p) (point)))) :eg-result-string "#") (treesit-node-top-level :no-eval (treesit-node-top-level node) :eg-result-string "#") "Retrieving node information" (treesit-node-text :no-eval (treesit-node-text node) :eg-result "int") (treesit-node-start :no-eval (treesit-node-start node) :eg-result 1) (treesit-node-end :no-eval (treesit-node-end node) :eg-result 10) (treesit-node-type :no-eval (treesit-node-type node) :eg-result "function_definition") (treesit-node-field-name :no-eval (treesit-node-field-name node) :eg-result "body") (treesit-node-parser :no-eval (treesit-node-parser node) :eg-result-string "#") (treesit-node-language :no-eval (treesit-node-language node) :eg-result c) (treesit-node-buffer :no-eval (treesit-node-buffer node) :eg-result-string "#") (treesit-node-index :no-eval (treesit-node-index node) :eg-result 0) (treesit-node-string :no-eval (treesit-node-string node) :eg-result-string "(init_declarator declarator: (identifier) value: (number_literal))") (treesit-node-check :no-eval (treesit-node-check node 'named) :eg-result t) (treesit-field-name-for-child :no-eval (treesit-field-name-for-child node) :eg-result "body") (treesit-child-count :no-eval (treesit-child-count node) :eg-result 3) "Pattern matching" (treesit-query-capture :no-eval (treesit-query-capture node '((identifier) @id "return" @ret)) :eg-result-string "((id . #) (ret . #))") (treesit-query-compile :no-eval (treesit-query-compile 'c '((identifier) @id "return" @ret)) :eg-result-string "#") (treesit-query-language :no-eval (treesit-query-language compiled-query) :eg-result c) (treesit-query-expand :eval (treesit-query-expand '((identifier) @id "return" @ret))) (treesit-pattern-expand :eval (treesit-pattern-expand :anchor) :eval (treesit-pattern-expand '(identifier)) :eval (treesit-pattern-expand :equal)) "Parsing a string" (treesit-parse-string :no-eval (treesit-parse-string "int c = 0;" 'c) :eg-result-string "#") (treesit-query-string :no-eval (treesit-query-string "int c = 0;" '((identifier) @id) 'c) :eg-result-string "((id . #))")) (provide 'treesit) ;;; treesit.el ends here