use crate::{ auto_pairs::AutoPairs, chars::char_is_line_ending, diagnostic::Severity, regex::Regex, transaction::{ChangeSet, Operation}, Rope, RopeSlice, Tendril, }; use ahash::RandomState; use arc_swap::{ArcSwap, Guard}; use bitflags::bitflags; use hashbrown::raw::RawTable; use slotmap::{DefaultKey as LayerId, HopSlotMap}; use std::{ borrow::Cow, cell::RefCell, collections::{HashMap, VecDeque}, fmt, hash::{Hash, Hasher}, mem::{replace, transmute}, path::Path, str::FromStr, sync::Arc, }; use once_cell::sync::{Lazy, OnceCell}; use serde::{Deserialize, Serialize}; use helix_loader::grammar::{get_language, load_runtime_file}; fn deserialize_regex<'de, D>(deserializer: D) -> Result, D::Error> where D: serde::Deserializer<'de>, { Option::::deserialize(deserializer)? .map(|buf| Regex::new(&buf).map_err(serde::de::Error::custom)) .transpose() } fn deserialize_lsp_config<'de, D>(deserializer: D) -> Result, D::Error> where D: serde::Deserializer<'de>, { Option::::deserialize(deserializer)? .map(|toml| toml.try_into().map_err(serde::de::Error::custom)) .transpose() } pub fn deserialize_auto_pairs<'de, D>(deserializer: D) -> Result, D::Error> where D: serde::Deserializer<'de>, { Ok(Option::::deserialize(deserializer)?.and_then(AutoPairConfig::into)) } fn default_timeout() -> u64 { 20 } #[derive(Debug, Serialize, Deserialize)] pub struct Configuration { pub language: Vec, } impl Default for Configuration { fn default() -> Self { crate::config::default_syntax_loader() } } // largely based on tree-sitter/cli/src/loader.rs #[derive(Debug, Serialize, Deserialize)] #[serde(rename_all = "kebab-case", deny_unknown_fields)] pub struct LanguageConfiguration { #[serde(rename = "name")] pub language_id: String, // c-sharp, rust pub scope: String, // source.rust pub file_types: Vec, // filename extension or ends_with? #[serde(default)] pub shebangs: Vec, // interpreter(s) associated with language pub roots: Vec, // these indicate project roots <.git, Cargo.toml> pub comment_token: Option, pub max_line_length: Option, #[serde(default, skip_serializing, deserialize_with = "deserialize_lsp_config")] pub config: Option, #[serde(default)] pub auto_format: bool, #[serde(skip_serializing_if = "Option::is_none")] pub formatter: Option, #[serde(default)] pub diagnostic_severity: Severity, pub grammar: Option, // tree-sitter grammar name, defaults to language_id // content_regex #[serde(default, skip_serializing, deserialize_with = "deserialize_regex")] pub injection_regex: Option, // first_line_regex // #[serde(skip)] pub(crate) highlight_config: OnceCell>>, // tags_config OnceCell<> https://github.com/tree-sitter/tree-sitter/pull/583 #[serde(skip_serializing_if = "Option::is_none")] pub language_server: Option, #[serde(skip_serializing_if = "Option::is_none")] pub indent: Option, #[serde(skip)] pub(crate) indent_query: OnceCell>, #[serde(skip)] pub(crate) textobject_query: OnceCell>, #[serde(skip_serializing_if = "Option::is_none")] pub debugger: Option, /// Automatic insertion of pairs to parentheses, brackets, /// etc. Defaults to true. Optionally, this can be a list of 2-tuples /// to specify a list of characters to pair. This overrides the /// global setting. #[serde(default, skip_serializing, deserialize_with = "deserialize_auto_pairs")] pub auto_pairs: Option, pub rulers: Option>, // if set, override editor's rulers } #[derive(Debug, PartialEq, Eq, Hash)] pub enum FileType { /// The extension of the file, either the `Path::extension` or the full /// filename if the file does not have an extension. Extension(String), /// The suffix of a file. This is compared to a given file's absolute /// path, so it can be used to detect files based on their directories. Suffix(String), } impl Serialize for FileType { fn serialize(&self, serializer: S) -> Result where S: serde::Serializer, { use serde::ser::SerializeMap; match self { FileType::Extension(extension) => serializer.serialize_str(extension), FileType::Suffix(suffix) => { let mut map = serializer.serialize_map(Some(1))?; map.serialize_entry("suffix", &suffix.replace(std::path::MAIN_SEPARATOR, "/"))?; map.end() } } } } impl<'de> Deserialize<'de> for FileType { fn deserialize(deserializer: D) -> Result where D: serde::de::Deserializer<'de>, { struct FileTypeVisitor; impl<'de> serde::de::Visitor<'de> for FileTypeVisitor { type Value = FileType; fn expecting(&self, formatter: &mut std::fmt::Formatter) -> std::fmt::Result { formatter.write_str("string or table") } fn visit_str(self, value: &str) -> Result where E: serde::de::Error, { Ok(FileType::Extension(value.to_string())) } fn visit_map(self, mut map: M) -> Result where M: serde::de::MapAccess<'de>, { match map.next_entry::()? { Some((key, suffix)) if key == "suffix" => Ok(FileType::Suffix( suffix.replace('/', &std::path::MAIN_SEPARATOR.to_string()), )), Some((key, _value)) => Err(serde::de::Error::custom(format!( "unknown key in `file-types` list: {}", key ))), None => Err(serde::de::Error::custom( "expected a `suffix` key in the `file-types` entry", )), } } } deserializer.deserialize_any(FileTypeVisitor) } } #[derive(Debug, Serialize, Deserialize)] #[serde(rename_all = "kebab-case")] pub struct LanguageServerConfiguration { pub command: String, #[serde(default)] #[serde(skip_serializing_if = "Vec::is_empty")] pub args: Vec, #[serde(default = "default_timeout")] pub timeout: u64, pub language_id: Option, } #[derive(Debug, Clone, Serialize, Deserialize)] #[serde(rename_all = "kebab-case")] pub struct FormatterConfiguration { pub command: String, #[serde(default)] #[serde(skip_serializing_if = "Vec::is_empty")] pub args: Vec, } #[derive(Debug, PartialEq, Eq, Clone, Deserialize, Serialize)] #[serde(rename_all = "kebab-case")] pub struct AdvancedCompletion { pub name: Option, pub completion: Option, pub default: Option, } #[derive(Debug, PartialEq, Eq, Clone, Deserialize, Serialize)] #[serde(rename_all = "kebab-case", untagged)] pub enum DebugConfigCompletion { Named(String), Advanced(AdvancedCompletion), } #[derive(Debug, PartialEq, Eq, Clone, Deserialize, Serialize)] #[serde(untagged)] pub enum DebugArgumentValue { String(String), Array(Vec), Boolean(bool), } #[derive(Debug, PartialEq, Eq, Clone, Deserialize, Serialize)] #[serde(rename_all = "kebab-case")] pub struct DebugTemplate { pub name: String, pub request: String, pub completion: Vec, pub args: HashMap, } #[derive(Debug, PartialEq, Eq, Clone, Deserialize, Serialize)] #[serde(rename_all = "kebab-case")] pub struct DebugAdapterConfig { pub name: String, pub transport: String, #[serde(default)] pub command: String, #[serde(default)] pub args: Vec, pub port_arg: Option, pub templates: Vec, #[serde(default)] pub quirks: DebuggerQuirks, } // Different workarounds for adapters' differences #[derive(Debug, Default, PartialEq, Eq, Clone, Serialize, Deserialize)] pub struct DebuggerQuirks { #[serde(default)] pub absolute_paths: bool, } #[derive(Debug, Serialize, Deserialize)] #[serde(rename_all = "kebab-case")] pub struct IndentationConfiguration { pub tab_width: usize, pub unit: String, } /// Configuration for auto pairs #[derive(Debug, Clone, PartialEq, Eq, Serialize, Deserialize)] #[serde(rename_all = "kebab-case", deny_unknown_fields, untagged)] pub enum AutoPairConfig { /// Enables or disables auto pairing. False means disabled. True means to use the default pairs. Enable(bool), /// The mappings of pairs. Pairs(HashMap), } impl Default for AutoPairConfig { fn default() -> Self { AutoPairConfig::Enable(true) } } impl From<&AutoPairConfig> for Option { fn from(auto_pair_config: &AutoPairConfig) -> Self { match auto_pair_config { AutoPairConfig::Enable(false) => None, AutoPairConfig::Enable(true) => Some(AutoPairs::default()), AutoPairConfig::Pairs(pairs) => Some(AutoPairs::new(pairs.iter())), } } } impl From for Option { fn from(auto_pairs_config: AutoPairConfig) -> Self { (&auto_pairs_config).into() } } impl FromStr for AutoPairConfig { type Err = std::str::ParseBoolError; // only do bool parsing for runtime setting fn from_str(s: &str) -> Result { let enable: bool = s.parse()?; Ok(AutoPairConfig::Enable(enable)) } } #[derive(Debug)] pub struct TextObjectQuery { pub query: Query, } #[derive(Debug)] pub enum CapturedNode<'a> { Single(Node<'a>), /// Guaranteed to be not empty Grouped(Vec>), } impl<'a> CapturedNode<'a> { pub fn start_byte(&self) -> usize { match self { Self::Single(n) => n.start_byte(), Self::Grouped(ns) => ns[0].start_byte(), } } pub fn end_byte(&self) -> usize { match self { Self::Single(n) => n.end_byte(), Self::Grouped(ns) => ns.last().unwrap().end_byte(), } } pub fn byte_range(&self) -> std::ops::Range { self.start_byte()..self.end_byte() } } /// The maximum number of in-progress matches a TS cursor can consider at once. /// This is set to a constant in order to avoid performance problems for medium to large files. Set with `set_match_limit`. /// Using such a limit means that we lose valid captures, so there is fundamentally a tradeoff here. /// /// /// Old tree sitter versions used a limit of 32 by default until this limit was removed in version `0.19.5` (must now be set manually). /// However, this causes performance issues for medium to large files. /// In helix, this problem caused treesitter motions to take multiple seconds to complete in medium-sized rust files (3k loc). /// /// /// Neovim also encountered this problem and reintroduced this limit after it was removed upstream /// (see and ). /// The number used here is fundamentally a tradeoff between breaking some obscure edge cases and performance. /// /// /// Neovim chose 64 for this value somewhat arbitrarily (). /// 64 is too low for some languages though. In particular, it breaks some highlighting for record fields in Erlang record definitions. /// This number can be increased if new syntax highlight breakages are found, as long as the performance penalty is not too high. const TREE_SITTER_MATCH_LIMIT: u32 = 256; impl TextObjectQuery { /// Run the query on the given node and return sub nodes which match given /// capture ("function.inside", "class.around", etc). /// /// Captures may contain multiple nodes by using quantifiers (+, *, etc), /// and support for this is partial and could use improvement. /// /// ```query /// (comment)+ @capture /// /// ; OR /// ( /// (comment)* /// . /// (function) /// ) @capture /// ``` pub fn capture_nodes<'a>( &'a self, capture_name: &str, node: Node<'a>, slice: RopeSlice<'a>, cursor: &'a mut QueryCursor, ) -> Option>> { self.capture_nodes_any(&[capture_name], node, slice, cursor) } /// Find the first capture that exists out of all given `capture_names` /// and return sub nodes that match this capture. pub fn capture_nodes_any<'a>( &'a self, capture_names: &[&str], node: Node<'a>, slice: RopeSlice<'a>, cursor: &'a mut QueryCursor, ) -> Option>> { let capture_idx = capture_names .iter() .find_map(|cap| self.query.capture_index_for_name(cap))?; cursor.set_match_limit(TREE_SITTER_MATCH_LIMIT); let nodes = cursor .captures(&self.query, node, RopeProvider(slice)) .filter_map(move |(mat, _)| { let nodes: Vec<_> = mat .captures .iter() .filter_map(|cap| (cap.index == capture_idx).then(|| cap.node)) .collect(); if nodes.len() > 1 { Some(CapturedNode::Grouped(nodes)) } else { nodes.into_iter().map(CapturedNode::Single).next() } }); Some(nodes) } } pub fn read_query(language: &str, filename: &str) -> String { static INHERITS_REGEX: Lazy = Lazy::new(|| Regex::new(r";+\s*inherits\s*:?\s*([a-z_,()-]+)\s*").unwrap()); let query = load_runtime_file(language, filename).unwrap_or_default(); // replaces all "; inherits (,)*" with the queries of the given language(s) INHERITS_REGEX .replace_all(&query, |captures: ®ex::Captures| { captures[1] .split(',') .map(|language| format!("\n{}\n", read_query(language, filename))) .collect::() }) .to_string() } impl LanguageConfiguration { fn initialize_highlight(&self, scopes: &[String]) -> Option> { let highlights_query = read_query(&self.language_id, "highlights.scm"); // always highlight syntax errors // highlights_query += "\n(ERROR) @error"; let injections_query = read_query(&self.language_id, "injections.scm"); let locals_query = read_query(&self.language_id, "locals.scm"); if highlights_query.is_empty() { None } else { let language = get_language(self.grammar.as_deref().unwrap_or(&self.language_id)) .map_err(|err| { log::error!( "Failed to load tree-sitter parser for language {:?}: {}", self.language_id, err ) }) .ok()?; let config = HighlightConfiguration::new( language, &highlights_query, &injections_query, &locals_query, ) .map_err(|err| log::error!("Could not parse queries for language {:?}. Are your grammars out of sync? Try running 'hx --grammar fetch' and 'hx --grammar build'. This query could not be parsed: {:?}", self.language_id, err)) .ok()?; config.configure(scopes); Some(Arc::new(config)) } } pub fn reconfigure(&self, scopes: &[String]) { if let Some(Some(config)) = self.highlight_config.get() { config.configure(scopes); } } pub fn highlight_config(&self, scopes: &[String]) -> Option> { self.highlight_config .get_or_init(|| self.initialize_highlight(scopes)) .clone() } pub fn is_highlight_initialized(&self) -> bool { self.highlight_config.get().is_some() } pub fn indent_query(&self) -> Option<&Query> { self.indent_query .get_or_init(|| self.load_query("indents.scm")) .as_ref() } pub fn textobject_query(&self) -> Option<&TextObjectQuery> { self.textobject_query .get_or_init(|| { self.load_query("textobjects.scm") .map(|query| TextObjectQuery { query }) }) .as_ref() } pub fn scope(&self) -> &str { &self.scope } fn load_query(&self, kind: &str) -> Option { let query_text = read_query(&self.language_id, kind); if query_text.is_empty() { return None; } let lang = self.highlight_config.get()?.as_ref()?.language; Query::new(lang, &query_text) .map_err(|e| { log::error!( "Failed to parse {} queries for {}: {}", kind, self.language_id, e ) }) .ok() } } // Expose loader as Lazy<> global since it's always static? #[derive(Debug)] pub struct Loader { // highlight_names ? language_configs: Vec>, language_config_ids_by_extension: HashMap, // Vec language_config_ids_by_suffix: HashMap, language_config_ids_by_shebang: HashMap, scopes: ArcSwap>, } impl Loader { pub fn new(config: Configuration) -> Self { let mut loader = Self { language_configs: Vec::new(), language_config_ids_by_extension: HashMap::new(), language_config_ids_by_suffix: HashMap::new(), language_config_ids_by_shebang: HashMap::new(), scopes: ArcSwap::from_pointee(Vec::new()), }; for config in config.language { // get the next id let language_id = loader.language_configs.len(); for file_type in &config.file_types { // entry().or_insert(Vec::new).push(language_id); match file_type { FileType::Extension(extension) => loader .language_config_ids_by_extension .insert(extension.clone(), language_id), FileType::Suffix(suffix) => loader .language_config_ids_by_suffix .insert(suffix.clone(), language_id), }; } for shebang in &config.shebangs { loader .language_config_ids_by_shebang .insert(shebang.clone(), language_id); } loader.language_configs.push(Arc::new(config)); } loader } pub fn language_config_for_file_name(&self, path: &Path) -> Option> { // Find all the language configurations that match this file name // or a suffix of the file name. let configuration_id = path .file_name() .and_then(|n| n.to_str()) .and_then(|file_name| self.language_config_ids_by_extension.get(file_name)) .or_else(|| { path.extension() .and_then(|extension| extension.to_str()) .and_then(|extension| self.language_config_ids_by_extension.get(extension)) }) .or_else(|| { self.language_config_ids_by_suffix .iter() .find_map(|(file_type, id)| { if path.to_str()?.ends_with(file_type) { Some(id) } else { None } }) }); configuration_id.and_then(|&id| self.language_configs.get(id).cloned()) // TODO: content_regex handling conflict resolution } pub fn language_config_for_shebang(&self, source: &Rope) -> Option> { let line = Cow::from(source.line(0)); static SHEBANG_REGEX: Lazy = Lazy::new(|| { Regex::new(r"^#!\s*(?:\S*[/\\](?:env\s+(?:\-\S+\s+)*)?)?([^\s\.\d]+)").unwrap() }); let configuration_id = SHEBANG_REGEX .captures(&line) .and_then(|cap| self.language_config_ids_by_shebang.get(&cap[1])); configuration_id.and_then(|&id| self.language_configs.get(id).cloned()) } pub fn language_config_for_scope(&self, scope: &str) -> Option> { self.language_configs .iter() .find(|config| config.scope == scope) .cloned() } pub fn language_config_for_language_id(&self, id: &str) -> Option> { self.language_configs .iter() .find(|config| config.language_id == id) .cloned() } pub fn language_configuration_for_injection_string( &self, string: &str, ) -> Option> { let mut best_match_length = 0; let mut best_match_position = None; for (i, configuration) in self.language_configs.iter().enumerate() { if let Some(injection_regex) = &configuration.injection_regex { if let Some(mat) = injection_regex.find(string) { let length = mat.end() - mat.start(); if length > best_match_length { best_match_position = Some(i); best_match_length = length; } } } } if let Some(i) = best_match_position { let configuration = &self.language_configs[i]; return Some(configuration.clone()); } None } pub fn language_configs(&self) -> impl Iterator> { self.language_configs.iter() } pub fn set_scopes(&self, scopes: Vec) { self.scopes.store(Arc::new(scopes)); // Reconfigure existing grammars for config in self .language_configs .iter() .filter(|cfg| cfg.is_highlight_initialized()) { config.reconfigure(&self.scopes()); } } pub fn scopes(&self) -> Guard>> { self.scopes.load() } } pub struct TsParser { parser: tree_sitter::Parser, pub cursors: Vec, } // could also just use a pool, or a single instance? thread_local! { pub static PARSER: RefCell = RefCell::new(TsParser { parser: Parser::new(), cursors: Vec::new(), }) } #[derive(Debug)] pub struct Syntax { layers: HopSlotMap, root: LayerId, loader: Arc, } fn byte_range_to_str(range: std::ops::Range, source: RopeSlice) -> Cow { Cow::from(source.byte_slice(range)) } impl Syntax { pub fn new(source: &Rope, config: Arc, loader: Arc) -> Self { let root_layer = LanguageLayer { tree: None, config, depth: 0, flags: LayerUpdateFlags::empty(), ranges: vec![Range { start_byte: 0, end_byte: usize::MAX, start_point: Point::new(0, 0), end_point: Point::new(usize::MAX, usize::MAX), }], }; // track scope_descriptor: a Vec of scopes for item in tree let mut layers = HopSlotMap::default(); let root = layers.insert(root_layer); let mut syntax = Self { root, layers, loader, }; syntax .update(source, source, &ChangeSet::new(source)) .unwrap(); syntax } pub fn update( &mut self, old_source: &Rope, source: &Rope, changeset: &ChangeSet, ) -> Result<(), Error> { let mut queue = VecDeque::new(); queue.push_back(self.root); let scopes = self.loader.scopes.load(); let injection_callback = |language: &str| { self.loader .language_configuration_for_injection_string(language) .and_then(|language_config| language_config.highlight_config(&scopes)) }; // Convert the changeset into tree sitter edits. let edits = generate_edits(old_source, changeset); // This table allows inverse indexing of `layers`. // That is by hashing a `Layer` you can find // the `LayerId` of an existing equivalent `Layer` in `layers`. // // It is used to determine if a new layer exists for an injection // or if an existing layer needs to be updated. let mut layers_table = RawTable::with_capacity(self.layers.len()); let layers_hasher = RandomState::new(); // Use the edits to update all layers markers fn point_add(a: Point, b: Point) -> Point { if b.row > 0 { Point::new(a.row.saturating_add(b.row), b.column) } else { Point::new(0, a.column.saturating_add(b.column)) } } fn point_sub(a: Point, b: Point) -> Point { if a.row > b.row { Point::new(a.row.saturating_sub(b.row), a.column) } else { Point::new(0, a.column.saturating_sub(b.column)) } } for (layer_id, layer) in self.layers.iter_mut() { // The root layer always covers the whole range (0..usize::MAX) if layer.depth == 0 { layer.flags = LayerUpdateFlags::MODIFIED; continue; } if !edits.is_empty() { for range in &mut layer.ranges { // Roughly based on https://github.com/tree-sitter/tree-sitter/blob/ddeaa0c7f534268b35b4f6cb39b52df082754413/lib/src/subtree.c#L691-L720 for edit in edits.iter().rev() { let is_pure_insertion = edit.old_end_byte == edit.start_byte; // if edit is after range, skip if edit.start_byte > range.end_byte { // TODO: || (is_noop && edit.start_byte == range.end_byte) continue; } // if edit is before range, shift entire range by len if edit.old_end_byte < range.start_byte { range.start_byte = edit.new_end_byte + (range.start_byte - edit.old_end_byte); range.start_point = point_add( edit.new_end_position, point_sub(range.start_point, edit.old_end_position), ); range.end_byte = edit .new_end_byte .saturating_add(range.end_byte - edit.old_end_byte); range.end_point = point_add( edit.new_end_position, point_sub(range.end_point, edit.old_end_position), ); layer.flags |= LayerUpdateFlags::MOVED; } // if the edit starts in the space before and extends into the range else if edit.start_byte < range.start_byte { range.start_byte = edit.new_end_byte; range.start_point = edit.new_end_position; range.end_byte = range .end_byte .saturating_sub(edit.old_end_byte) .saturating_add(edit.new_end_byte); range.end_point = point_add( edit.new_end_position, point_sub(range.end_point, edit.old_end_position), ); layer.flags = LayerUpdateFlags::MODIFIED; } // If the edit is an insertion at the start of the tree, shift else if edit.start_byte == range.start_byte && is_pure_insertion { range.start_byte = edit.new_end_byte; range.start_point = edit.new_end_position; layer.flags |= LayerUpdateFlags::MOVED; } else { range.end_byte = range .end_byte .saturating_sub(edit.old_end_byte) .saturating_add(edit.new_end_byte); range.end_point = point_add( edit.new_end_position, point_sub(range.end_point, edit.old_end_position), ); layer.flags = LayerUpdateFlags::MODIFIED; } } } } let hash = layers_hasher.hash_one(layer); // Safety: insert_no_grow is unsafe because it assumes that the table // has enough capacity to hold additional elements. // This is always the case as we reserved enough capacity above. unsafe { layers_table.insert_no_grow(hash, layer_id) }; } PARSER.with(|ts_parser| { let ts_parser = &mut ts_parser.borrow_mut(); let mut cursor = ts_parser.cursors.pop().unwrap_or_else(QueryCursor::new); // TODO: might need to set cursor range cursor.set_byte_range(0..usize::MAX); cursor.set_match_limit(TREE_SITTER_MATCH_LIMIT); let source_slice = source.slice(..); while let Some(layer_id) = queue.pop_front() { let layer = &mut self.layers[layer_id]; // Mark the layer as touched layer.flags |= LayerUpdateFlags::TOUCHED; // If a tree already exists, notify it of changes. if let Some(tree) = &mut layer.tree { if layer .flags .intersects(LayerUpdateFlags::MODIFIED | LayerUpdateFlags::MOVED) { for edit in edits.iter().rev() { // Apply the edits in reverse. // If we applied them in order then edit 1 would disrupt the positioning of edit 2. tree.edit(edit); } } if layer.flags.contains(LayerUpdateFlags::MODIFIED) { // Re-parse the tree. layer.parse(&mut ts_parser.parser, source)?; } } else { // always parse if this layer has never been parsed before layer.parse(&mut ts_parser.parser, source)?; } // Switch to an immutable borrow. let layer = &self.layers[layer_id]; // Process injections. let matches = cursor.matches( &layer.config.injections_query, layer.tree().root_node(), RopeProvider(source_slice), ); let mut injections = Vec::new(); for mat in matches { let (language_name, content_node, included_children) = injection_for_match( &layer.config, &layer.config.injections_query, &mat, source_slice, ); // Explicitly remove this match so that none of its other captures will remain // in the stream of captures. mat.remove(); // If a language is found with the given name, then add a new language layer // to the highlighted document. if let (Some(language_name), Some(content_node)) = (language_name, content_node) { if let Some(config) = (injection_callback)(&language_name) { let ranges = intersect_ranges(&layer.ranges, &[content_node], included_children); if !ranges.is_empty() { injections.push((config, ranges)); } } } } // Process combined injections. if let Some(combined_injections_query) = &layer.config.combined_injections_query { let mut injections_by_pattern_index = vec![ (None, Vec::new(), IncludedChildren::default()); combined_injections_query.pattern_count() ]; let matches = cursor.matches( combined_injections_query, layer.tree().root_node(), RopeProvider(source_slice), ); for mat in matches { let entry = &mut injections_by_pattern_index[mat.pattern_index]; let (language_name, content_node, included_children) = injection_for_match( &layer.config, combined_injections_query, &mat, source_slice, ); if language_name.is_some() { entry.0 = language_name; } if let Some(content_node) = content_node { entry.1.push(content_node); } entry.2 = included_children; } for (lang_name, content_nodes, included_children) in injections_by_pattern_index { if let (Some(lang_name), false) = (lang_name, content_nodes.is_empty()) { if let Some(config) = (injection_callback)(&lang_name) { let ranges = intersect_ranges( &layer.ranges, &content_nodes, included_children, ); if !ranges.is_empty() { injections.push((config, ranges)); } } } } } let depth = layer.depth + 1; // TODO: can't inline this since matches borrows self.layers for (config, ranges) in injections { let new_layer = LanguageLayer { tree: None, config, depth, ranges, flags: LayerUpdateFlags::empty(), }; // Find an identical existing layer let layer = layers_table .get(layers_hasher.hash_one(&new_layer), |&it| { self.layers[it] == new_layer }) .copied(); // ...or insert a new one. let layer_id = layer.unwrap_or_else(|| self.layers.insert(new_layer)); queue.push_back(layer_id); } // TODO: pre-process local scopes at this time, rather than highlight? // would solve problems with locals not working across boundaries } // Return the cursor back in the pool. ts_parser.cursors.push(cursor); // Reset all `LayerUpdateFlags` and remove all untouched layers self.layers.retain(|_, layer| { replace(&mut layer.flags, LayerUpdateFlags::empty()) .contains(LayerUpdateFlags::TOUCHED) }); Ok(()) }) } pub fn tree(&self) -> &Tree { self.layers[self.root].tree() } /// Iterate over the highlighted regions for a given slice of source code. pub fn highlight_iter<'a>( &'a self, source: RopeSlice<'a>, range: Option>, cancellation_flag: Option<&'a AtomicUsize>, ) -> impl Iterator> + 'a { let mut layers = self .layers .iter() .filter_map(|(_, layer)| { // TODO: if range doesn't overlap layer range, skip it // Reuse a cursor from the pool if available. let mut cursor = PARSER.with(|ts_parser| { let highlighter = &mut ts_parser.borrow_mut(); highlighter.cursors.pop().unwrap_or_else(QueryCursor::new) }); // The `captures` iterator borrows the `Tree` and the `QueryCursor`, which // prevents them from being moved. But both of these values are really just // pointers, so it's actually ok to move them. let cursor_ref = unsafe { mem::transmute::<_, &'static mut QueryCursor>(&mut cursor) }; // if reusing cursors & no range this resets to whole range cursor_ref.set_byte_range(range.clone().unwrap_or(0..usize::MAX)); cursor_ref.set_match_limit(TREE_SITTER_MATCH_LIMIT); let mut captures = cursor_ref .captures( &layer.config.query, layer.tree().root_node(), RopeProvider(source), ) .peekable(); // If there's no captures, skip the layer captures.peek()?; Some(HighlightIterLayer { highlight_end_stack: Vec::new(), scope_stack: vec![LocalScope { inherits: false, range: 0..usize::MAX, local_defs: Vec::new(), }], cursor, _tree: None, captures, config: layer.config.as_ref(), // TODO: just reuse `layer` depth: layer.depth, // TODO: just reuse `layer` ranges: &layer.ranges, // TODO: temp }) }) .collect::>(); // HAXX: arrange layers by byte range, with deeper layers positioned first layers.sort_by_key(|layer| { ( layer.ranges.first().cloned(), std::cmp::Reverse(layer.depth), ) }); let mut result = HighlightIter { source, byte_offset: range.map_or(0, |r| r.start), cancellation_flag, iter_count: 0, layers, next_event: None, last_highlight_range: None, }; result.sort_layers(); result } // Commenting // comment_strings_for_pos // is_commented // Indentation // suggested_indent_for_line_at_buffer_row // suggested_indent_for_buffer_row // indent_level_for_line // TODO: Folding } bitflags! { /// Flags that track the status of a layer /// in the `Sytaxn::update` function struct LayerUpdateFlags : u32{ const MODIFIED = 0b001; const MOVED = 0b010; const TOUCHED = 0b100; } } #[derive(Debug)] pub struct LanguageLayer { // mode // grammar pub config: Arc, pub(crate) tree: Option, pub ranges: Vec, pub depth: u32, flags: LayerUpdateFlags, } /// This PartialEq implementation only checks if that /// two layers are theoretically identical (meaning they highlight the same text range with the same language). /// It does not check whether the layers have the same internal treesitter /// state. impl PartialEq for LanguageLayer { fn eq(&self, other: &Self) -> bool { self.depth == other.depth && self.config.language == other.config.language && self.ranges == other.ranges } } /// Hash implementation belongs to PartialEq implementation above. /// See its documentation for details. impl Hash for LanguageLayer { fn hash(&self, state: &mut H) { self.depth.hash(state); // The transmute is necessary here because tree_sitter::Language does not derive Hash at the moment. // However it does use #[repr] transparent so the transmute here is safe // as `Language` (which `Grammar` is an alias for) is just a newtype wrapper around a (thin) pointer. // This is also compatible with the PartialEq implementation of language // as that is just a pointer comparison. let language: *const () = unsafe { transmute(self.config.language) }; language.hash(state); self.ranges.hash(state); } } impl LanguageLayer { pub fn tree(&self) -> &Tree { // TODO: no unwrap self.tree.as_ref().unwrap() } fn parse(&mut self, parser: &mut Parser, source: &Rope) -> Result<(), Error> { parser .set_included_ranges(&self.ranges) .map_err(|_| Error::InvalidRanges)?; parser .set_language(self.config.language) .map_err(|_| Error::InvalidLanguage)?; // unsafe { syntax.parser.set_cancellation_flag(cancellation_flag) }; let tree = parser .parse_with( &mut |byte, _| { if byte <= source.len_bytes() { let (chunk, start_byte, _, _) = source.chunk_at_byte(byte); chunk[byte - start_byte..].as_bytes() } else { // out of range &[] } }, self.tree.as_ref(), ) .ok_or(Error::Cancelled)?; // unsafe { ts_parser.parser.set_cancellation_flag(None) }; self.tree = Some(tree); Ok(()) } } pub(crate) fn generate_edits( old_text: &Rope, changeset: &ChangeSet, ) -> Vec { use Operation::*; let mut old_pos = 0; let mut edits = Vec::new(); if changeset.changes.is_empty() { return edits; } let mut iter = changeset.changes.iter().peekable(); // TODO; this is a lot easier with Change instead of Operation. fn point_at_pos(text: &Rope, pos: usize) -> (usize, Point) { let byte = text.char_to_byte(pos); // <- attempted to index past end let line = text.char_to_line(pos); let line_start_byte = text.line_to_byte(line); let col = byte - line_start_byte; (byte, Point::new(line, col)) } fn traverse(point: Point, text: &Tendril) -> Point { let Point { mut row, mut column, } = point; // TODO: there should be a better way here. let mut chars = text.chars().peekable(); while let Some(ch) = chars.next() { if char_is_line_ending(ch) && !(ch == '\r' && chars.peek() == Some(&'\n')) { row += 1; column = 0; } else { column += 1; } } Point { row, column } } while let Some(change) = iter.next() { let len = match change { Delete(i) | Retain(i) => *i, Insert(_) => 0, }; let mut old_end = old_pos + len; match change { Retain(_) => {} Delete(_) => { let (start_byte, start_position) = point_at_pos(old_text, old_pos); let (old_end_byte, old_end_position) = point_at_pos(old_text, old_end); // deletion edits.push(tree_sitter::InputEdit { start_byte, // old_pos to byte old_end_byte, // old_end to byte new_end_byte: start_byte, // old_pos to byte start_position, // old pos to coords old_end_position, // old_end to coords new_end_position: start_position, // old pos to coords }); } Insert(s) => { let (start_byte, start_position) = point_at_pos(old_text, old_pos); // a subsequent delete means a replace, consume it if let Some(Delete(len)) = iter.peek() { old_end = old_pos + len; let (old_end_byte, old_end_position) = point_at_pos(old_text, old_end); iter.next(); // replacement edits.push(tree_sitter::InputEdit { start_byte, // old_pos to byte old_end_byte, // old_end to byte new_end_byte: start_byte + s.len(), // old_pos to byte + s.len() start_position, // old pos to coords old_end_position, // old_end to coords new_end_position: traverse(start_position, s), // old pos + chars, newlines matter too (iter over) }); } else { // insert edits.push(tree_sitter::InputEdit { start_byte, // old_pos to byte old_end_byte: start_byte, // same new_end_byte: start_byte + s.len(), // old_pos + s.len() start_position, // old pos to coords old_end_position: start_position, // same new_end_position: traverse(start_position, s), // old pos + chars, newlines matter too (iter over) }); } } } old_pos = old_end; } edits } use std::sync::atomic::{AtomicUsize, Ordering}; use std::{iter, mem, ops, str, usize}; use tree_sitter::{ Language as Grammar, Node, Parser, Point, Query, QueryCaptures, QueryCursor, QueryError, QueryMatch, Range, TextProvider, Tree, TreeCursor, }; const CANCELLATION_CHECK_INTERVAL: usize = 100; /// Indicates which highlight should be applied to a region of source code. #[derive(Copy, Clone, Debug, PartialEq, Eq)] pub struct Highlight(pub usize); /// Represents the reason why syntax highlighting failed. #[derive(Debug, PartialEq, Eq)] pub enum Error { Cancelled, InvalidLanguage, InvalidRanges, Unknown, } /// Represents a single step in rendering a syntax-highlighted document. #[derive(Copy, Clone, Debug)] pub enum HighlightEvent { Source { start: usize, end: usize }, HighlightStart(Highlight), HighlightEnd, } /// Contains the data needed to highlight code written in a particular language. /// /// This struct is immutable and can be shared between threads. #[derive(Debug)] pub struct HighlightConfiguration { pub language: Grammar, pub query: Query, injections_query: Query, combined_injections_query: Option, highlights_pattern_index: usize, highlight_indices: ArcSwap>>, non_local_variable_patterns: Vec, injection_content_capture_index: Option, injection_language_capture_index: Option, local_scope_capture_index: Option, local_def_capture_index: Option, local_def_value_capture_index: Option, local_ref_capture_index: Option, } #[derive(Debug)] struct LocalDef<'a> { name: Cow<'a, str>, value_range: ops::Range, highlight: Option, } #[derive(Debug)] struct LocalScope<'a> { inherits: bool, range: ops::Range, local_defs: Vec>, } #[derive(Debug)] struct HighlightIter<'a> { source: RopeSlice<'a>, byte_offset: usize, cancellation_flag: Option<&'a AtomicUsize>, layers: Vec>, iter_count: usize, next_event: Option, last_highlight_range: Option<(usize, usize, u32)>, } // Adapter to convert rope chunks to bytes pub struct ChunksBytes<'a> { chunks: ropey::iter::Chunks<'a>, } impl<'a> Iterator for ChunksBytes<'a> { type Item = &'a [u8]; fn next(&mut self) -> Option { self.chunks.next().map(str::as_bytes) } } pub struct RopeProvider<'a>(pub RopeSlice<'a>); impl<'a> TextProvider<'a> for RopeProvider<'a> { type I = ChunksBytes<'a>; fn text(&mut self, node: Node) -> Self::I { let fragment = self.0.byte_slice(node.start_byte()..node.end_byte()); ChunksBytes { chunks: fragment.chunks(), } } } struct HighlightIterLayer<'a> { _tree: Option, cursor: QueryCursor, captures: iter::Peekable>>, config: &'a HighlightConfiguration, highlight_end_stack: Vec, scope_stack: Vec>, depth: u32, ranges: &'a [Range], } impl<'a> fmt::Debug for HighlightIterLayer<'a> { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { f.debug_struct("HighlightIterLayer").finish() } } impl HighlightConfiguration { /// Creates a `HighlightConfiguration` for a given `Grammar` and set of highlighting /// queries. /// /// # Parameters /// /// * `language` - The Tree-sitter `Grammar` that should be used for parsing. /// * `highlights_query` - A string containing tree patterns for syntax highlighting. This /// should be non-empty, otherwise no syntax highlights will be added. /// * `injections_query` - A string containing tree patterns for injecting other languages /// into the document. This can be empty if no injections are desired. /// * `locals_query` - A string containing tree patterns for tracking local variable /// definitions and references. This can be empty if local variable tracking is not needed. /// /// Returns a `HighlightConfiguration` that can then be used with the `highlight` method. pub fn new( language: Grammar, highlights_query: &str, injection_query: &str, locals_query: &str, ) -> Result { // Concatenate the query strings, keeping track of the start offset of each section. let mut query_source = String::new(); query_source.push_str(locals_query); let highlights_query_offset = query_source.len(); query_source.push_str(highlights_query); // Construct a single query by concatenating the three query strings, but record the // range of pattern indices that belong to each individual string. let query = Query::new(language, &query_source)?; let mut highlights_pattern_index = 0; for i in 0..(query.pattern_count()) { let pattern_offset = query.start_byte_for_pattern(i); if pattern_offset < highlights_query_offset { highlights_pattern_index += 1; } } let mut injections_query = Query::new(language, injection_query)?; // Construct a separate query just for dealing with the 'combined injections'. // Disable the combined injection patterns in the main query. let mut combined_injections_query = Query::new(language, injection_query)?; let mut has_combined_queries = false; for pattern_index in 0..injections_query.pattern_count() { let settings = injections_query.property_settings(pattern_index); if settings.iter().any(|s| &*s.key == "injection.combined") { has_combined_queries = true; injections_query.disable_pattern(pattern_index); } else { combined_injections_query.disable_pattern(pattern_index); } } let combined_injections_query = if has_combined_queries { Some(combined_injections_query) } else { None }; // Find all of the highlighting patterns that are disabled for nodes that // have been identified as local variables. let non_local_variable_patterns = (0..query.pattern_count()) .map(|i| { query .property_predicates(i) .iter() .any(|(prop, positive)| !*positive && prop.key.as_ref() == "local") }) .collect(); // Store the numeric ids for all of the special captures. let mut injection_content_capture_index = None; let mut injection_language_capture_index = None; let mut local_def_capture_index = None; let mut local_def_value_capture_index = None; let mut local_ref_capture_index = None; let mut local_scope_capture_index = None; for (i, name) in query.capture_names().iter().enumerate() { let i = Some(i as u32); match name.as_str() { "local.definition" => local_def_capture_index = i, "local.definition-value" => local_def_value_capture_index = i, "local.reference" => local_ref_capture_index = i, "local.scope" => local_scope_capture_index = i, _ => {} } } for (i, name) in injections_query.capture_names().iter().enumerate() { let i = Some(i as u32); match name.as_str() { "injection.content" => injection_content_capture_index = i, "injection.language" => injection_language_capture_index = i, _ => {} } } let highlight_indices = ArcSwap::from_pointee(vec![None; query.capture_names().len()]); Ok(Self { language, query, injections_query, combined_injections_query, highlights_pattern_index, highlight_indices, non_local_variable_patterns, injection_content_capture_index, injection_language_capture_index, local_scope_capture_index, local_def_capture_index, local_def_value_capture_index, local_ref_capture_index, }) } /// Get a slice containing all of the highlight names used in the configuration. pub fn names(&self) -> &[String] { self.query.capture_names() } /// Set the list of recognized highlight names. /// /// Tree-sitter syntax-highlighting queries specify highlights in the form of dot-separated /// highlight names like `punctuation.bracket` and `function.method.builtin`. Consumers of /// these queries can choose to recognize highlights with different levels of specificity. /// For example, the string `function.builtin` will match against `function.builtin.constructor` /// but will not match `function.method.builtin` and `function.method`. /// /// When highlighting, results are returned as `Highlight` values, which contain the index /// of the matched highlight this list of highlight names. pub fn configure(&self, recognized_names: &[String]) { let mut capture_parts = Vec::new(); let indices: Vec<_> = self .query .capture_names() .iter() .map(move |capture_name| { capture_parts.clear(); capture_parts.extend(capture_name.split('.')); let mut best_index = None; let mut best_match_len = 0; for (i, recognized_name) in recognized_names.iter().enumerate() { let recognized_name = recognized_name; let mut len = 0; let mut matches = true; for (i, part) in recognized_name.split('.').enumerate() { match capture_parts.get(i) { Some(capture_part) if *capture_part == part => len += 1, _ => { matches = false; break; } } } if matches && len > best_match_len { best_index = Some(i); best_match_len = len; } } best_index.map(Highlight) }) .collect(); self.highlight_indices.store(Arc::new(indices)); } } impl<'a> HighlightIterLayer<'a> { // First, sort scope boundaries by their byte offset in the document. At a // given position, emit scope endings before scope beginnings. Finally, emit // scope boundaries from deeper layers first. fn sort_key(&mut self) -> Option<(usize, bool, isize)> { let depth = -(self.depth as isize); let next_start = self .captures .peek() .map(|(m, i)| m.captures[*i].node.start_byte()); let next_end = self.highlight_end_stack.last().cloned(); match (next_start, next_end) { (Some(start), Some(end)) => { if start < end { Some((start, true, depth)) } else { Some((end, false, depth)) } } (Some(i), None) => Some((i, true, depth)), (None, Some(j)) => Some((j, false, depth)), _ => None, } } } #[derive(Clone)] enum IncludedChildren { None, All, Unnamed, } impl Default for IncludedChildren { fn default() -> Self { Self::None } } // Compute the ranges that should be included when parsing an injection. // This takes into account three things: // * `parent_ranges` - The ranges must all fall within the *current* layer's ranges. // * `nodes` - Every injection takes place within a set of nodes. The injection ranges // are the ranges of those nodes. // * `includes_children` - For some injections, the content nodes' children should be // excluded from the nested document, so that only the content nodes' *own* content // is reparsed. For other injections, the content nodes' entire ranges should be // reparsed, including the ranges of their children. fn intersect_ranges( parent_ranges: &[Range], nodes: &[Node], included_children: IncludedChildren, ) -> Vec { let mut cursor = nodes[0].walk(); let mut result = Vec::new(); let mut parent_range_iter = parent_ranges.iter(); let mut parent_range = parent_range_iter .next() .expect("Layers should only be constructed with non-empty ranges vectors"); for node in nodes.iter() { let mut preceding_range = Range { start_byte: 0, start_point: Point::new(0, 0), end_byte: node.start_byte(), end_point: node.start_position(), }; let following_range = Range { start_byte: node.end_byte(), start_point: node.end_position(), end_byte: usize::MAX, end_point: Point::new(usize::MAX, usize::MAX), }; for excluded_range in node .children(&mut cursor) .filter_map(|child| match included_children { IncludedChildren::None => Some(child.range()), IncludedChildren::All => None, IncludedChildren::Unnamed => { if child.is_named() { Some(child.range()) } else { None } } }) .chain([following_range].iter().cloned()) { let mut range = Range { start_byte: preceding_range.end_byte, start_point: preceding_range.end_point, end_byte: excluded_range.start_byte, end_point: excluded_range.start_point, }; preceding_range = excluded_range; if range.end_byte < parent_range.start_byte { continue; } while parent_range.start_byte <= range.end_byte { if parent_range.end_byte > range.start_byte { if range.start_byte < parent_range.start_byte { range.start_byte = parent_range.start_byte; range.start_point = parent_range.start_point; } if parent_range.end_byte < range.end_byte { if range.start_byte < parent_range.end_byte { result.push(Range { start_byte: range.start_byte, start_point: range.start_point, end_byte: parent_range.end_byte, end_point: parent_range.end_point, }); } range.start_byte = parent_range.end_byte; range.start_point = parent_range.end_point; } else { if range.start_byte < range.end_byte { result.push(range); } break; } } if let Some(next_range) = parent_range_iter.next() { parent_range = next_range; } else { return result; } } } } result } impl<'a> HighlightIter<'a> { fn emit_event( &mut self, offset: usize, event: Option, ) -> Option> { let result; if self.byte_offset < offset { result = Some(Ok(HighlightEvent::Source { start: self.byte_offset, end: offset, })); self.byte_offset = offset; self.next_event = event; } else { result = event.map(Ok); } self.sort_layers(); result } fn sort_layers(&mut self) { while !self.layers.is_empty() { if let Some(sort_key) = self.layers[0].sort_key() { let mut i = 0; while i + 1 < self.layers.len() { if let Some(next_offset) = self.layers[i + 1].sort_key() { if next_offset < sort_key { i += 1; continue; } } else { let layer = self.layers.remove(i + 1); PARSER.with(|ts_parser| { let highlighter = &mut ts_parser.borrow_mut(); highlighter.cursors.push(layer.cursor); }); } break; } if i > 0 { self.layers[0..(i + 1)].rotate_left(1); } break; } else { let layer = self.layers.remove(0); PARSER.with(|ts_parser| { let highlighter = &mut ts_parser.borrow_mut(); highlighter.cursors.push(layer.cursor); }); } } } } impl<'a> Iterator for HighlightIter<'a> { type Item = Result; fn next(&mut self) -> Option { 'main: loop { // If we've already determined the next highlight boundary, just return it. if let Some(e) = self.next_event.take() { return Some(Ok(e)); } // Periodically check for cancellation, returning `Cancelled` error if the // cancellation flag was flipped. if let Some(cancellation_flag) = self.cancellation_flag { self.iter_count += 1; if self.iter_count >= CANCELLATION_CHECK_INTERVAL { self.iter_count = 0; if cancellation_flag.load(Ordering::Relaxed) != 0 { return Some(Err(Error::Cancelled)); } } } // If none of the layers have any more highlight boundaries, terminate. if self.layers.is_empty() { let len = self.source.len_bytes(); return if self.byte_offset < len { let result = Some(Ok(HighlightEvent::Source { start: self.byte_offset, end: len, })); self.byte_offset = len; result } else { None }; } // Get the next capture from whichever layer has the earliest highlight boundary. let range; let layer = &mut self.layers[0]; if let Some((next_match, capture_index)) = layer.captures.peek() { let next_capture = next_match.captures[*capture_index]; range = next_capture.node.byte_range(); // If any previous highlight ends before this node starts, then before // processing this capture, emit the source code up until the end of the // previous highlight, and an end event for that highlight. if let Some(end_byte) = layer.highlight_end_stack.last().cloned() { if end_byte <= range.start { layer.highlight_end_stack.pop(); return self.emit_event(end_byte, Some(HighlightEvent::HighlightEnd)); } } } // If there are no more captures, then emit any remaining highlight end events. // And if there are none of those, then just advance to the end of the document. else if let Some(end_byte) = layer.highlight_end_stack.last().cloned() { layer.highlight_end_stack.pop(); return self.emit_event(end_byte, Some(HighlightEvent::HighlightEnd)); } else { return self.emit_event(self.source.len_bytes(), None); }; let (mut match_, capture_index) = layer.captures.next().unwrap(); let mut capture = match_.captures[capture_index]; // Remove from the local scope stack any local scopes that have already ended. while range.start > layer.scope_stack.last().unwrap().range.end { layer.scope_stack.pop(); } // If this capture is for tracking local variables, then process the // local variable info. let mut reference_highlight = None; let mut definition_highlight = None; while match_.pattern_index < layer.config.highlights_pattern_index { // If the node represents a local scope, push a new local scope onto // the scope stack. if Some(capture.index) == layer.config.local_scope_capture_index { definition_highlight = None; let mut scope = LocalScope { inherits: true, range: range.clone(), local_defs: Vec::new(), }; for prop in layer.config.query.property_settings(match_.pattern_index) { if let "local.scope-inherits" = prop.key.as_ref() { scope.inherits = prop.value.as_ref().map_or(true, |r| r.as_ref() == "true"); } } layer.scope_stack.push(scope); } // If the node represents a definition, add a new definition to the // local scope at the top of the scope stack. else if Some(capture.index) == layer.config.local_def_capture_index { reference_highlight = None; let scope = layer.scope_stack.last_mut().unwrap(); let mut value_range = 0..0; for capture in match_.captures { if Some(capture.index) == layer.config.local_def_value_capture_index { value_range = capture.node.byte_range(); } } let name = byte_range_to_str(range.clone(), self.source); scope.local_defs.push(LocalDef { name, value_range, highlight: None, }); definition_highlight = scope.local_defs.last_mut().map(|s| &mut s.highlight); } // If the node represents a reference, then try to find the corresponding // definition in the scope stack. else if Some(capture.index) == layer.config.local_ref_capture_index && definition_highlight.is_none() { definition_highlight = None; let name = byte_range_to_str(range.clone(), self.source); for scope in layer.scope_stack.iter().rev() { if let Some(highlight) = scope.local_defs.iter().rev().find_map(|def| { if def.name == name && range.start >= def.value_range.end { Some(def.highlight) } else { None } }) { reference_highlight = highlight; break; } if !scope.inherits { break; } } } // Continue processing any additional matches for the same node. if let Some((next_match, next_capture_index)) = layer.captures.peek() { let next_capture = next_match.captures[*next_capture_index]; if next_capture.node == capture.node { capture = next_capture; match_ = layer.captures.next().unwrap().0; continue; } } self.sort_layers(); continue 'main; } // Otherwise, this capture must represent a highlight. // If this exact range has already been highlighted by an earlier pattern, or by // a different layer, then skip over this one. if let Some((last_start, last_end, last_depth)) = self.last_highlight_range { if range.start == last_start && range.end == last_end && layer.depth < last_depth { self.sort_layers(); continue 'main; } } // If the current node was found to be a local variable, then skip over any // highlighting patterns that are disabled for local variables. if definition_highlight.is_some() || reference_highlight.is_some() { while layer.config.non_local_variable_patterns[match_.pattern_index] { if let Some((next_match, next_capture_index)) = layer.captures.peek() { let next_capture = next_match.captures[*next_capture_index]; if next_capture.node == capture.node { capture = next_capture; match_ = layer.captures.next().unwrap().0; continue; } } self.sort_layers(); continue 'main; } } // Once a highlighting pattern is found for the current node, skip over // any later highlighting patterns that also match this node. Captures // for a given node are ordered by pattern index, so these subsequent // captures are guaranteed to be for highlighting, not injections or // local variables. while let Some((next_match, next_capture_index)) = layer.captures.peek() { let next_capture = next_match.captures[*next_capture_index]; if next_capture.node == capture.node { layer.captures.next(); } else { break; } } let current_highlight = layer.config.highlight_indices.load()[capture.index as usize]; // If this node represents a local definition, then store the current // highlight value on the local scope entry representing this node. if let Some(definition_highlight) = definition_highlight { *definition_highlight = current_highlight; } // Emit a scope start event and push the node's end position to the stack. if let Some(highlight) = reference_highlight.or(current_highlight) { self.last_highlight_range = Some((range.start, range.end, layer.depth)); layer.highlight_end_stack.push(range.end); return self .emit_event(range.start, Some(HighlightEvent::HighlightStart(highlight))); } self.sort_layers(); } } } fn injection_for_match<'a>( config: &HighlightConfiguration, query: &'a Query, query_match: &QueryMatch<'a, 'a>, source: RopeSlice<'a>, ) -> (Option>, Option>, IncludedChildren) { let content_capture_index = config.injection_content_capture_index; let language_capture_index = config.injection_language_capture_index; let mut language_name = None; let mut content_node = None; for capture in query_match.captures { let index = Some(capture.index); if index == language_capture_index { let name = byte_range_to_str(capture.node.byte_range(), source); language_name = Some(name); } else if index == content_capture_index { content_node = Some(capture.node); } } let mut included_children = IncludedChildren::default(); for prop in query.property_settings(query_match.pattern_index) { match prop.key.as_ref() { // In addition to specifying the language name via the text of a // captured node, it can also be hard-coded via a `#set!` predicate // that sets the injection.language key. "injection.language" => { if language_name.is_none() { language_name = prop.value.as_ref().map(|s| s.as_ref().into()) } } // By default, injections do not include the *children* of an // `injection.content` node - only the ranges that belong to the // node itself. This can be changed using a `#set!` predicate that // sets the `injection.include-children` key. "injection.include-children" => included_children = IncludedChildren::All, // Some queries might only exclude named children but include unnamed // children in their `injection.content` node. This can be enabled using // a `#set!` predicate that sets the `injection.include-unnamed-children` key. "injection.include-unnamed-children" => included_children = IncludedChildren::Unnamed, _ => {} } } (language_name, content_node, included_children) } pub struct Merge { iter: I, spans: Box)>>, next_event: Option, next_span: Option<(usize, std::ops::Range)>, queue: Vec, } /// Merge a list of spans into the highlight event stream. pub fn merge>( iter: I, spans: Vec<(usize, std::ops::Range)>, ) -> Merge { let spans = Box::new(spans.into_iter()); let mut merge = Merge { iter, spans, next_event: None, next_span: None, queue: Vec::new(), }; merge.next_event = merge.iter.next(); merge.next_span = merge.spans.next(); merge } impl> Iterator for Merge { type Item = HighlightEvent; fn next(&mut self) -> Option { use HighlightEvent::*; if let Some(event) = self.queue.pop() { return Some(event); } loop { match (self.next_event, &self.next_span) { // this happens when range is partially or fully offscreen (Some(Source { start, .. }), Some((span, range))) if start > range.start => { if start > range.end { self.next_span = self.spans.next(); } else { self.next_span = Some((*span, start..range.end)); }; } _ => break, } } match (self.next_event, &self.next_span) { (Some(HighlightStart(i)), _) => { self.next_event = self.iter.next(); Some(HighlightStart(i)) } (Some(HighlightEnd), _) => { self.next_event = self.iter.next(); Some(HighlightEnd) } (Some(Source { start, end }), Some((_, range))) if start < range.start => { let intersect = range.start.min(end); let event = Source { start, end: intersect, }; if end == intersect { // the event is complete self.next_event = self.iter.next(); } else { // subslice the event self.next_event = Some(Source { start: intersect, end, }); }; Some(event) } (Some(Source { start, end }), Some((span, range))) if start == range.start => { let intersect = range.end.min(end); let event = HighlightStart(Highlight(*span)); // enqueue in reverse order self.queue.push(HighlightEnd); self.queue.push(Source { start, end: intersect, }); if end == intersect { // the event is complete self.next_event = self.iter.next(); } else { // subslice the event self.next_event = Some(Source { start: intersect, end, }); }; if intersect == range.end { self.next_span = self.spans.next(); } else { self.next_span = Some((*span, intersect..range.end)); } Some(event) } (Some(event), None) => { self.next_event = self.iter.next(); Some(event) } // Can happen if cursor at EOF and/or diagnostic reaches past the end. // We need to actually emit events for the cursor-at-EOF situation, // even though the range is past the end of the text. This needs to be // handled appropriately by the drawing code by not assuming that // all `Source` events point to valid indices in the rope. (None, Some((span, range))) => { let event = HighlightStart(Highlight(*span)); self.queue.push(HighlightEnd); self.queue.push(Source { start: range.start, end: range.end, }); self.next_span = self.spans.next(); Some(event) } (None, None) => None, e => unreachable!("{:?}", e), } } } fn node_is_visible(node: &Node) -> bool { node.is_missing() || (node.is_named() && node.language().node_kind_is_visible(node.kind_id())) } pub fn pretty_print_tree(fmt: &mut W, node: Node) -> fmt::Result { if node.child_count() == 0 { if node_is_visible(&node) { write!(fmt, "({})", node.kind()) } else { write!(fmt, "\"{}\"", node.kind()) } } else { pretty_print_tree_impl(fmt, &mut node.walk(), 0) } } fn pretty_print_tree_impl( fmt: &mut W, cursor: &mut TreeCursor, depth: usize, ) -> fmt::Result { let node = cursor.node(); let visible = node_is_visible(&node); if visible { let indentation_columns = depth * 2; write!(fmt, "{:indentation_columns$}", "")?; if let Some(field_name) = cursor.field_name() { write!(fmt, "{}: ", field_name)?; } write!(fmt, "({}", node.kind())?; } // Handle children. if cursor.goto_first_child() { loop { if node_is_visible(&cursor.node()) { fmt.write_char('\n')?; } pretty_print_tree_impl(fmt, cursor, depth + 1)?; if !cursor.goto_next_sibling() { break; } } let moved = cursor.goto_parent(); // The parent of the first child must exist, and must be `node`. debug_assert!(moved); debug_assert!(cursor.node() == node); } if visible { fmt.write_char(')')?; } Ok(()) } #[cfg(test)] mod test { use super::*; use crate::{Rope, Transaction}; #[test] fn test_textobject_queries() { let query_str = r#" (line_comment)+ @quantified_nodes ((line_comment)+) @quantified_nodes_grouped ((line_comment) (line_comment)) @multiple_nodes_grouped "#; let source = Rope::from_str( r#" /// a comment on /// multiple lines "#, ); let loader = Loader::new(Configuration { language: vec![] }); let language = get_language("rust").unwrap(); let query = Query::new(language, query_str).unwrap(); let textobject = TextObjectQuery { query }; let mut cursor = QueryCursor::new(); let config = HighlightConfiguration::new(language, "", "", "").unwrap(); let syntax = Syntax::new(&source, Arc::new(config), Arc::new(loader)); let root = syntax.tree().root_node(); let mut test = |capture, range| { let matches: Vec<_> = textobject .capture_nodes(capture, root, source.slice(..), &mut cursor) .unwrap() .collect(); assert_eq!( matches[0].byte_range(), range, "@{} expected {:?}", capture, range ) }; test("quantified_nodes", 1..36); // NOTE: Enable after implementing proper node group capturing // test("quantified_nodes_grouped", 1..36); // test("multiple_nodes_grouped", 1..36); } #[test] fn test_parser() { let highlight_names: Vec = [ "attribute", "constant", "function.builtin", "function", "keyword", "operator", "property", "punctuation", "punctuation.bracket", "punctuation.delimiter", "string", "string.special", "tag", "type", "type.builtin", "variable", "variable.builtin", "variable.parameter", ] .iter() .cloned() .map(String::from) .collect(); let loader = Loader::new(Configuration { language: vec![] }); let language = get_language("rust").unwrap(); let config = HighlightConfiguration::new( language, &std::fs::read_to_string("../runtime/grammars/sources/rust/queries/highlights.scm") .unwrap(), &std::fs::read_to_string("../runtime/grammars/sources/rust/queries/injections.scm") .unwrap(), "", // locals.scm ) .unwrap(); config.configure(&highlight_names); let source = Rope::from_str( " struct Stuff {} fn main() {} ", ); let syntax = Syntax::new(&source, Arc::new(config), Arc::new(loader)); let tree = syntax.tree(); let root = tree.root_node(); assert_eq!(root.kind(), "source_file"); assert_eq!( root.to_sexp(), concat!( "(source_file ", "(struct_item name: (type_identifier) body: (field_declaration_list)) ", "(function_item name: (identifier) parameters: (parameters) body: (block)))" ) ); let struct_node = root.child(0).unwrap(); assert_eq!(struct_node.kind(), "struct_item"); } #[test] fn test_input_edits() { use tree_sitter::InputEdit; let doc = Rope::from("hello world!\ntest 123"); let transaction = Transaction::change( &doc, vec![(6, 11, Some("test".into())), (12, 17, None)].into_iter(), ); let edits = generate_edits(&doc, transaction.changes()); // transaction.apply(&mut state); assert_eq!( edits, &[ InputEdit { start_byte: 6, old_end_byte: 11, new_end_byte: 10, start_position: Point { row: 0, column: 6 }, old_end_position: Point { row: 0, column: 11 }, new_end_position: Point { row: 0, column: 10 } }, InputEdit { start_byte: 12, old_end_byte: 17, new_end_byte: 12, start_position: Point { row: 0, column: 12 }, old_end_position: Point { row: 1, column: 4 }, new_end_position: Point { row: 0, column: 12 } } ] ); // Testing with the official example from tree-sitter let mut doc = Rope::from("fn test() {}"); let transaction = Transaction::change(&doc, vec![(8, 8, Some("a: u32".into()))].into_iter()); let edits = generate_edits(&doc, transaction.changes()); transaction.apply(&mut doc); assert_eq!(doc, "fn test(a: u32) {}"); assert_eq!( edits, &[InputEdit { start_byte: 8, old_end_byte: 8, new_end_byte: 14, start_position: Point { row: 0, column: 8 }, old_end_position: Point { row: 0, column: 8 }, new_end_position: Point { row: 0, column: 14 } }] ); } #[track_caller] fn assert_pretty_print( language_name: &str, source: &str, expected: &str, start: usize, end: usize, ) { let source = Rope::from_str(source); let loader = Loader::new(Configuration { language: vec![] }); let language = get_language(language_name).unwrap(); let config = HighlightConfiguration::new(language, "", "", "").unwrap(); let syntax = Syntax::new(&source, Arc::new(config), Arc::new(loader)); let root = syntax .tree() .root_node() .descendant_for_byte_range(start, end) .unwrap(); let mut output = String::new(); pretty_print_tree(&mut output, root).unwrap(); assert_eq!(expected, output); } #[test] fn test_pretty_print() { let source = r#"/// Hello"#; assert_pretty_print("rust", source, "(line_comment)", 0, source.len()); // A large tree should be indented with fields: let source = r#"fn main() { println!("Hello, World!"); }"#; assert_pretty_print( "rust", source, concat!( "(function_item\n", " name: (identifier)\n", " parameters: (parameters)\n", " body: (block\n", " (expression_statement\n", " (macro_invocation\n", " macro: (identifier)\n", " (token_tree\n", " (string_literal))))))", ), 0, source.len(), ); // Selecting a token should print just that token: let source = r#"fn main() {}"#; assert_pretty_print("rust", source, r#""fn""#, 0, 1); // Error nodes are printed as errors: let source = r#"}{"#; assert_pretty_print("rust", source, "(ERROR)", 0, source.len()); // Fields broken under unnamed nodes are determined correctly. // In the following source, `object` belongs to the `singleton_method` // rule but `name` and `body` belong to an unnamed helper `_method_rest`. // This can cause a bug with a pretty-printing implementation that // uses `Node::field_name_for_child` to determine field names but is // fixed when using `TreeCursor::field_name`. let source = "def self.method_name true end"; assert_pretty_print( "ruby", source, concat!( "(singleton_method\n", " object: (self)\n", " name: (identifier)\n", " body: (body_statement\n", " (true)))" ), 0, source.len(), ); } #[test] fn test_load_runtime_file() { // Test to make sure we can load some data from the runtime directory. let contents = load_runtime_file("rust", "indents.scm").unwrap(); assert!(!contents.is_empty()); let results = load_runtime_file("rust", "does-not-exist"); assert!(results.is_err()); } }