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helix/helix-core/src/syntax.rs

2524 lines
90 KiB
Rust

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<Option<Regex>, D::Error>
where
D: serde::Deserializer<'de>,
{
Option::<String>::deserialize(deserializer)?
.map(|buf| Regex::new(&buf).map_err(serde::de::Error::custom))
.transpose()
}
fn deserialize_lsp_config<'de, D>(deserializer: D) -> Result<Option<serde_json::Value>, D::Error>
where
D: serde::Deserializer<'de>,
{
Option::<toml::Value>::deserialize(deserializer)?
.map(|toml| toml.try_into().map_err(serde::de::Error::custom))
.transpose()
}
pub fn deserialize_auto_pairs<'de, D>(deserializer: D) -> Result<Option<AutoPairs>, D::Error>
where
D: serde::Deserializer<'de>,
{
Ok(Option::<AutoPairConfig>::deserialize(deserializer)?.and_then(AutoPairConfig::into))
}
fn default_timeout() -> u64 {
20
}
#[derive(Debug, Serialize, Deserialize)]
pub struct Configuration {
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pub language: Vec<LanguageConfiguration>,
}
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<FileType>, // filename extension or ends_with? <Gemfile, rb, etc>
#[serde(default)]
pub shebangs: Vec<String>, // interpreter(s) associated with language
pub roots: Vec<String>, // these indicate project roots <.git, Cargo.toml>
pub comment_token: Option<String>,
pub max_line_length: Option<usize>,
#[serde(default, skip_serializing, deserialize_with = "deserialize_lsp_config")]
pub config: Option<serde_json::Value>,
#[serde(default)]
pub auto_format: bool,
#[serde(skip_serializing_if = "Option::is_none")]
pub formatter: Option<FormatterConfiguration>,
#[serde(default)]
pub diagnostic_severity: Severity,
pub grammar: Option<String>, // tree-sitter grammar name, defaults to language_id
// content_regex
#[serde(default, skip_serializing, deserialize_with = "deserialize_regex")]
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pub injection_regex: Option<Regex>,
// first_line_regex
//
#[serde(skip)]
pub(crate) highlight_config: OnceCell<Option<Arc<HighlightConfiguration>>>,
// tags_config OnceCell<> https://github.com/tree-sitter/tree-sitter/pull/583
#[serde(skip_serializing_if = "Option::is_none")]
pub language_server: Option<LanguageServerConfiguration>,
#[serde(skip_serializing_if = "Option::is_none")]
pub indent: Option<IndentationConfiguration>,
#[serde(skip)]
pub(crate) indent_query: OnceCell<Option<Query>>,
#[serde(skip)]
pub(crate) textobject_query: OnceCell<Option<TextObjectQuery>>,
#[serde(skip_serializing_if = "Option::is_none")]
pub debugger: Option<DebugAdapterConfig>,
/// 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<AutoPairs>,
pub rulers: Option<Vec<u16>>, // 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<S>(&self, serializer: S) -> Result<S::Ok, S::Error>
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<D>(deserializer: D) -> Result<Self, D::Error>
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<E>(self, value: &str) -> Result<Self::Value, E>
where
E: serde::de::Error,
{
Ok(FileType::Extension(value.to_string()))
}
fn visit_map<M>(self, mut map: M) -> Result<Self::Value, M::Error>
where
M: serde::de::MapAccess<'de>,
{
match map.next_entry::<String, String>()? {
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<String>,
#[serde(default, skip_serializing_if = "HashMap::is_empty")]
pub environment: HashMap<String, String>,
#[serde(default = "default_timeout")]
pub timeout: u64,
pub language_id: Option<String>,
}
#[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<String>,
}
#[derive(Debug, PartialEq, Eq, Clone, Deserialize, Serialize)]
#[serde(rename_all = "kebab-case")]
pub struct AdvancedCompletion {
pub name: Option<String>,
pub completion: Option<String>,
pub default: Option<String>,
}
#[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<String>),
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<DebugConfigCompletion>,
pub args: HashMap<String, DebugArgumentValue>,
}
#[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<String>,
pub port_arg: Option<String>,
pub templates: Vec<DebugTemplate>,
#[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<char, char>),
}
impl Default for AutoPairConfig {
fn default() -> Self {
AutoPairConfig::Enable(true)
}
}
impl From<&AutoPairConfig> for Option<AutoPairs> {
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<AutoPairConfig> for Option<AutoPairs> {
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<Self, Self::Err> {
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<Node<'a>>),
}
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<usize> {
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 <https://github.com/neovim/neovim/issues/14897> and <https://github.com/neovim/neovim/pull/14915>).
/// The number used here is fundamentally a tradeoff between breaking some obscure edge cases and performance.
///
///
/// Neovim chose 64 for this value somewhat arbitrarily (<https://github.com/neovim/neovim/pull/18397>).
/// 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<impl Iterator<Item = CapturedNode<'a>>> {
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<impl Iterator<Item = CapturedNode<'a>>> {
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<Regex> =
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 <language>(,<language>)*" with the queries of the given language(s)
INHERITS_REGEX
.replace_all(&query, |captures: &regex::Captures| {
captures[1]
.split(',')
.map(|language| format!("\n{}\n", read_query(language, filename)))
.collect::<String>()
})
.to_string()
}
impl LanguageConfiguration {
fn initialize_highlight(&self, scopes: &[String]) -> Option<Arc<HighlightConfiguration>> {
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,
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)
.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<Arc<HighlightConfiguration>> {
self.highlight_config
.get_or_init(|| self.initialize_highlight(scopes))
.clone()
}
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pub fn is_highlight_initialized(&self) -> bool {
self.highlight_config.get().is_some()
}
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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()
}
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pub fn scope(&self) -> &str {
&self.scope
}
fn load_query(&self, kind: &str) -> Option<Query> {
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<Arc<LanguageConfiguration>>,
language_config_ids_by_extension: HashMap<String, usize>, // Vec<usize>
language_config_ids_by_suffix: HashMap<String, usize>,
language_config_ids_by_shebang: HashMap<String, usize>,
scopes: ArcSwap<Vec<String>>,
}
impl Loader {
pub fn new(config: Configuration) -> Self {
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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<Arc<LanguageConfiguration>> {
// 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<Arc<LanguageConfiguration>> {
let line = Cow::from(source.line(0));
static SHEBANG_REGEX: Lazy<Regex> = 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<Arc<LanguageConfiguration>> {
self.language_configs
.iter()
.find(|config| config.scope == scope)
.cloned()
}
pub fn language_config_for_language_id(&self, id: &str) -> Option<Arc<LanguageConfiguration>> {
self.language_configs
.iter()
.find(|config| config.language_id == id)
.cloned()
}
pub fn language_configuration_for_injection_string(
&self,
string: &str,
) -> Option<Arc<LanguageConfiguration>> {
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<Item = &Arc<LanguageConfiguration>> {
self.language_configs.iter()
}
pub fn set_scopes(&self, scopes: Vec<String>) {
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<Arc<Vec<String>>> {
self.scopes.load()
}
}
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pub struct TsParser {
parser: tree_sitter::Parser,
pub cursors: Vec<QueryCursor>,
}
// could also just use a pool, or a single instance?
thread_local! {
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pub static PARSER: RefCell<TsParser> = RefCell::new(TsParser {
parser: Parser::new(),
cursors: Vec::new(),
})
}
#[derive(Debug)]
pub struct Syntax {
layers: HopSlotMap<LayerId, LanguageLayer>,
root: LayerId,
loader: Arc<Loader>,
}
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fn byte_range_to_str(range: std::ops::Range<usize>, source: RopeSlice) -> Cow<str> {
Cow::from(source.byte_slice(range))
}
impl Syntax {
pub fn new(source: &Rope, config: Arc<HighlightConfiguration>, loader: Arc<Loader>) -> 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<std::ops::Range<usize>>,
cancellation_flag: Option<&'a AtomicUsize>,
) -> impl Iterator<Item = Result<HighlightEvent, Error>> + 'a {
let mut layers = self
.layers
.iter()
.filter_map(|(_, layer)| {
3 years ago
// 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,
Fix initial highlight layer sort order (#5196) The purpose of this change is to remove the mutable self borrow on `HighlightIterLayer::sort_key` so that we can sort layers with the correct ordering using the `Vec::sort` function family. `HighlightIterLayer::sort_key` needs `&mut self` since it calls `Peekable::peek` which needs `&mut self`. `Vec::sort` functions only give immutable borrows of the elements to ensure the correctness of the sort. We could instead approach this by creating an eager Peekable and using that instead of `std::iter::Peekable` to wrap `QueryCaptures`: ```rust struct EagerPeekable<I: Iterator> { iter: I, peeked: Option<I::Item>, } impl<I: Iterator> EagerPeekable<I> { fn new(mut iter: I) -> Self { let peeked = iter.next(); Self { iter, peeked } } fn peek(&self) -> Option<&I::Item> { self.peeked.as_ref() } } impl<I: Iterator> Iterator for EagerPeekable<I> { type Item = I::Item; fn next(&mut self) -> Option<Self::Item> { std::mem::replace(&mut self.peeked, self.iter.next()) } } ``` This would be a cleaner approach (notice how `EagerPeekable::peek` takes `&self` rather than `&mut self`), however this doesn't work in practice because the Items emitted by the `tree_sitter::QueryCaptures` Iterator must be consumed before the next Item is returned. `Iterator::next` on `tree_sitter::QueryCaptures` modifies the `QueryMatch` returned by the last call of `next`. This behavior is not currently reflected in the lifetimes/structure of `QueryCaptures`. This fixes an issue with layers being out of order when using combined injections since the old code only checked the first range in the layer. Layers being out of order could cause missing highlights for combined-injections content.
2 years ago
captures: RefCell::new(captures),
config: layer.config.as_ref(), // TODO: just reuse `layer`
depth: layer.depth, // TODO: just reuse `layer`
})
})
.collect::<Vec<_>>();
Fix initial highlight layer sort order (#5196) The purpose of this change is to remove the mutable self borrow on `HighlightIterLayer::sort_key` so that we can sort layers with the correct ordering using the `Vec::sort` function family. `HighlightIterLayer::sort_key` needs `&mut self` since it calls `Peekable::peek` which needs `&mut self`. `Vec::sort` functions only give immutable borrows of the elements to ensure the correctness of the sort. We could instead approach this by creating an eager Peekable and using that instead of `std::iter::Peekable` to wrap `QueryCaptures`: ```rust struct EagerPeekable<I: Iterator> { iter: I, peeked: Option<I::Item>, } impl<I: Iterator> EagerPeekable<I> { fn new(mut iter: I) -> Self { let peeked = iter.next(); Self { iter, peeked } } fn peek(&self) -> Option<&I::Item> { self.peeked.as_ref() } } impl<I: Iterator> Iterator for EagerPeekable<I> { type Item = I::Item; fn next(&mut self) -> Option<Self::Item> { std::mem::replace(&mut self.peeked, self.iter.next()) } } ``` This would be a cleaner approach (notice how `EagerPeekable::peek` takes `&self` rather than `&mut self`), however this doesn't work in practice because the Items emitted by the `tree_sitter::QueryCaptures` Iterator must be consumed before the next Item is returned. `Iterator::next` on `tree_sitter::QueryCaptures` modifies the `QueryMatch` returned by the last call of `next`. This behavior is not currently reflected in the lifetimes/structure of `QueryCaptures`. This fixes an issue with layers being out of order when using combined injections since the old code only checked the first range in the layer. Layers being out of order could cause missing highlights for combined-injections content.
2 years ago
layers.sort_unstable_by_key(|layer| layer.sort_key());
let mut result = HighlightIter {
source,
3 years ago
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<HighlightConfiguration>,
pub(crate) tree: Option<Tree>,
pub ranges: Vec<Range>,
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<H: Hasher>(&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<tree_sitter::InputEdit> {
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<Query>,
highlights_pattern_index: usize,
highlight_indices: ArcSwap<Vec<Option<Highlight>>>,
non_local_variable_patterns: Vec<bool>,
injection_content_capture_index: Option<u32>,
injection_language_capture_index: Option<u32>,
local_scope_capture_index: Option<u32>,
local_def_capture_index: Option<u32>,
local_def_value_capture_index: Option<u32>,
local_ref_capture_index: Option<u32>,
}
#[derive(Debug)]
struct LocalDef<'a> {
name: Cow<'a, str>,
value_range: ops::Range<usize>,
highlight: Option<Highlight>,
}
#[derive(Debug)]
struct LocalScope<'a> {
inherits: bool,
range: ops::Range<usize>,
local_defs: Vec<LocalDef<'a>>,
}
#[derive(Debug)]
struct HighlightIter<'a> {
source: RopeSlice<'a>,
byte_offset: usize,
cancellation_flag: Option<&'a AtomicUsize>,
layers: Vec<HighlightIterLayer<'a>>,
iter_count: usize,
next_event: Option<HighlightEvent>,
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::Item> {
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<Tree>,
cursor: QueryCursor,
Fix initial highlight layer sort order (#5196) The purpose of this change is to remove the mutable self borrow on `HighlightIterLayer::sort_key` so that we can sort layers with the correct ordering using the `Vec::sort` function family. `HighlightIterLayer::sort_key` needs `&mut self` since it calls `Peekable::peek` which needs `&mut self`. `Vec::sort` functions only give immutable borrows of the elements to ensure the correctness of the sort. We could instead approach this by creating an eager Peekable and using that instead of `std::iter::Peekable` to wrap `QueryCaptures`: ```rust struct EagerPeekable<I: Iterator> { iter: I, peeked: Option<I::Item>, } impl<I: Iterator> EagerPeekable<I> { fn new(mut iter: I) -> Self { let peeked = iter.next(); Self { iter, peeked } } fn peek(&self) -> Option<&I::Item> { self.peeked.as_ref() } } impl<I: Iterator> Iterator for EagerPeekable<I> { type Item = I::Item; fn next(&mut self) -> Option<Self::Item> { std::mem::replace(&mut self.peeked, self.iter.next()) } } ``` This would be a cleaner approach (notice how `EagerPeekable::peek` takes `&self` rather than `&mut self`), however this doesn't work in practice because the Items emitted by the `tree_sitter::QueryCaptures` Iterator must be consumed before the next Item is returned. `Iterator::next` on `tree_sitter::QueryCaptures` modifies the `QueryMatch` returned by the last call of `next`. This behavior is not currently reflected in the lifetimes/structure of `QueryCaptures`. This fixes an issue with layers being out of order when using combined injections since the old code only checked the first range in the layer. Layers being out of order could cause missing highlights for combined-injections content.
2 years ago
captures: RefCell<iter::Peekable<QueryCaptures<'a, 'a, RopeProvider<'a>>>>,
config: &'a HighlightConfiguration,
highlight_end_stack: Vec<usize>,
scope_stack: Vec<LocalScope<'a>>,
depth: u32,
}
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<Self, QueryError> {
// 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()]);
4 years ago
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,
4 years ago
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.
Fix initial highlight layer sort order (#5196) The purpose of this change is to remove the mutable self borrow on `HighlightIterLayer::sort_key` so that we can sort layers with the correct ordering using the `Vec::sort` function family. `HighlightIterLayer::sort_key` needs `&mut self` since it calls `Peekable::peek` which needs `&mut self`. `Vec::sort` functions only give immutable borrows of the elements to ensure the correctness of the sort. We could instead approach this by creating an eager Peekable and using that instead of `std::iter::Peekable` to wrap `QueryCaptures`: ```rust struct EagerPeekable<I: Iterator> { iter: I, peeked: Option<I::Item>, } impl<I: Iterator> EagerPeekable<I> { fn new(mut iter: I) -> Self { let peeked = iter.next(); Self { iter, peeked } } fn peek(&self) -> Option<&I::Item> { self.peeked.as_ref() } } impl<I: Iterator> Iterator for EagerPeekable<I> { type Item = I::Item; fn next(&mut self) -> Option<Self::Item> { std::mem::replace(&mut self.peeked, self.iter.next()) } } ``` This would be a cleaner approach (notice how `EagerPeekable::peek` takes `&self` rather than `&mut self`), however this doesn't work in practice because the Items emitted by the `tree_sitter::QueryCaptures` Iterator must be consumed before the next Item is returned. `Iterator::next` on `tree_sitter::QueryCaptures` modifies the `QueryMatch` returned by the last call of `next`. This behavior is not currently reflected in the lifetimes/structure of `QueryCaptures`. This fixes an issue with layers being out of order when using combined injections since the old code only checked the first range in the layer. Layers being out of order could cause missing highlights for combined-injections content.
2 years ago
fn sort_key(&self) -> Option<(usize, bool, isize)> {
let depth = -(self.depth as isize);
let next_start = self
.captures
Fix initial highlight layer sort order (#5196) The purpose of this change is to remove the mutable self borrow on `HighlightIterLayer::sort_key` so that we can sort layers with the correct ordering using the `Vec::sort` function family. `HighlightIterLayer::sort_key` needs `&mut self` since it calls `Peekable::peek` which needs `&mut self`. `Vec::sort` functions only give immutable borrows of the elements to ensure the correctness of the sort. We could instead approach this by creating an eager Peekable and using that instead of `std::iter::Peekable` to wrap `QueryCaptures`: ```rust struct EagerPeekable<I: Iterator> { iter: I, peeked: Option<I::Item>, } impl<I: Iterator> EagerPeekable<I> { fn new(mut iter: I) -> Self { let peeked = iter.next(); Self { iter, peeked } } fn peek(&self) -> Option<&I::Item> { self.peeked.as_ref() } } impl<I: Iterator> Iterator for EagerPeekable<I> { type Item = I::Item; fn next(&mut self) -> Option<Self::Item> { std::mem::replace(&mut self.peeked, self.iter.next()) } } ``` This would be a cleaner approach (notice how `EagerPeekable::peek` takes `&self` rather than `&mut self`), however this doesn't work in practice because the Items emitted by the `tree_sitter::QueryCaptures` Iterator must be consumed before the next Item is returned. `Iterator::next` on `tree_sitter::QueryCaptures` modifies the `QueryMatch` returned by the last call of `next`. This behavior is not currently reflected in the lifetimes/structure of `QueryCaptures`. This fixes an issue with layers being out of order when using combined injections since the old code only checked the first range in the layer. Layers being out of order could cause missing highlights for combined-injections content.
2 years ago
.borrow_mut()
.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<Range> {
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<HighlightEvent>,
) -> Option<Result<HighlightEvent, Error>> {
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<HighlightEvent, Error>;
fn next(&mut self) -> Option<Self::Item> {
'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];
Fix initial highlight layer sort order (#5196) The purpose of this change is to remove the mutable self borrow on `HighlightIterLayer::sort_key` so that we can sort layers with the correct ordering using the `Vec::sort` function family. `HighlightIterLayer::sort_key` needs `&mut self` since it calls `Peekable::peek` which needs `&mut self`. `Vec::sort` functions only give immutable borrows of the elements to ensure the correctness of the sort. We could instead approach this by creating an eager Peekable and using that instead of `std::iter::Peekable` to wrap `QueryCaptures`: ```rust struct EagerPeekable<I: Iterator> { iter: I, peeked: Option<I::Item>, } impl<I: Iterator> EagerPeekable<I> { fn new(mut iter: I) -> Self { let peeked = iter.next(); Self { iter, peeked } } fn peek(&self) -> Option<&I::Item> { self.peeked.as_ref() } } impl<I: Iterator> Iterator for EagerPeekable<I> { type Item = I::Item; fn next(&mut self) -> Option<Self::Item> { std::mem::replace(&mut self.peeked, self.iter.next()) } } ``` This would be a cleaner approach (notice how `EagerPeekable::peek` takes `&self` rather than `&mut self`), however this doesn't work in practice because the Items emitted by the `tree_sitter::QueryCaptures` Iterator must be consumed before the next Item is returned. `Iterator::next` on `tree_sitter::QueryCaptures` modifies the `QueryMatch` returned by the last call of `next`. This behavior is not currently reflected in the lifetimes/structure of `QueryCaptures`. This fixes an issue with layers being out of order when using combined injections since the old code only checked the first range in the layer. Layers being out of order could cause missing highlights for combined-injections content.
2 years ago
let captures = layer.captures.get_mut();
if let Some((next_match, capture_index)) = 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);
};
Fix initial highlight layer sort order (#5196) The purpose of this change is to remove the mutable self borrow on `HighlightIterLayer::sort_key` so that we can sort layers with the correct ordering using the `Vec::sort` function family. `HighlightIterLayer::sort_key` needs `&mut self` since it calls `Peekable::peek` which needs `&mut self`. `Vec::sort` functions only give immutable borrows of the elements to ensure the correctness of the sort. We could instead approach this by creating an eager Peekable and using that instead of `std::iter::Peekable` to wrap `QueryCaptures`: ```rust struct EagerPeekable<I: Iterator> { iter: I, peeked: Option<I::Item>, } impl<I: Iterator> EagerPeekable<I> { fn new(mut iter: I) -> Self { let peeked = iter.next(); Self { iter, peeked } } fn peek(&self) -> Option<&I::Item> { self.peeked.as_ref() } } impl<I: Iterator> Iterator for EagerPeekable<I> { type Item = I::Item; fn next(&mut self) -> Option<Self::Item> { std::mem::replace(&mut self.peeked, self.iter.next()) } } ``` This would be a cleaner approach (notice how `EagerPeekable::peek` takes `&self` rather than `&mut self`), however this doesn't work in practice because the Items emitted by the `tree_sitter::QueryCaptures` Iterator must be consumed before the next Item is returned. `Iterator::next` on `tree_sitter::QueryCaptures` modifies the `QueryMatch` returned by the last call of `next`. This behavior is not currently reflected in the lifetimes/structure of `QueryCaptures`. This fixes an issue with layers being out of order when using combined injections since the old code only checked the first range in the layer. Layers being out of order could cause missing highlights for combined-injections content.
2 years ago
let (mut match_, capture_index) = 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.
Fix initial highlight layer sort order (#5196) The purpose of this change is to remove the mutable self borrow on `HighlightIterLayer::sort_key` so that we can sort layers with the correct ordering using the `Vec::sort` function family. `HighlightIterLayer::sort_key` needs `&mut self` since it calls `Peekable::peek` which needs `&mut self`. `Vec::sort` functions only give immutable borrows of the elements to ensure the correctness of the sort. We could instead approach this by creating an eager Peekable and using that instead of `std::iter::Peekable` to wrap `QueryCaptures`: ```rust struct EagerPeekable<I: Iterator> { iter: I, peeked: Option<I::Item>, } impl<I: Iterator> EagerPeekable<I> { fn new(mut iter: I) -> Self { let peeked = iter.next(); Self { iter, peeked } } fn peek(&self) -> Option<&I::Item> { self.peeked.as_ref() } } impl<I: Iterator> Iterator for EagerPeekable<I> { type Item = I::Item; fn next(&mut self) -> Option<Self::Item> { std::mem::replace(&mut self.peeked, self.iter.next()) } } ``` This would be a cleaner approach (notice how `EagerPeekable::peek` takes `&self` rather than `&mut self`), however this doesn't work in practice because the Items emitted by the `tree_sitter::QueryCaptures` Iterator must be consumed before the next Item is returned. `Iterator::next` on `tree_sitter::QueryCaptures` modifies the `QueryMatch` returned by the last call of `next`. This behavior is not currently reflected in the lifetimes/structure of `QueryCaptures`. This fixes an issue with layers being out of order when using combined injections since the old code only checked the first range in the layer. Layers being out of order could cause missing highlights for combined-injections content.
2 years ago
if let Some((next_match, next_capture_index)) = captures.peek() {
let next_capture = next_match.captures[*next_capture_index];
if next_capture.node == capture.node {
capture = next_capture;
Fix initial highlight layer sort order (#5196) The purpose of this change is to remove the mutable self borrow on `HighlightIterLayer::sort_key` so that we can sort layers with the correct ordering using the `Vec::sort` function family. `HighlightIterLayer::sort_key` needs `&mut self` since it calls `Peekable::peek` which needs `&mut self`. `Vec::sort` functions only give immutable borrows of the elements to ensure the correctness of the sort. We could instead approach this by creating an eager Peekable and using that instead of `std::iter::Peekable` to wrap `QueryCaptures`: ```rust struct EagerPeekable<I: Iterator> { iter: I, peeked: Option<I::Item>, } impl<I: Iterator> EagerPeekable<I> { fn new(mut iter: I) -> Self { let peeked = iter.next(); Self { iter, peeked } } fn peek(&self) -> Option<&I::Item> { self.peeked.as_ref() } } impl<I: Iterator> Iterator for EagerPeekable<I> { type Item = I::Item; fn next(&mut self) -> Option<Self::Item> { std::mem::replace(&mut self.peeked, self.iter.next()) } } ``` This would be a cleaner approach (notice how `EagerPeekable::peek` takes `&self` rather than `&mut self`), however this doesn't work in practice because the Items emitted by the `tree_sitter::QueryCaptures` Iterator must be consumed before the next Item is returned. `Iterator::next` on `tree_sitter::QueryCaptures` modifies the `QueryMatch` returned by the last call of `next`. This behavior is not currently reflected in the lifetimes/structure of `QueryCaptures`. This fixes an issue with layers being out of order when using combined injections since the old code only checked the first range in the layer. Layers being out of order could cause missing highlights for combined-injections content.
2 years ago
match_ = 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] {
Fix initial highlight layer sort order (#5196) The purpose of this change is to remove the mutable self borrow on `HighlightIterLayer::sort_key` so that we can sort layers with the correct ordering using the `Vec::sort` function family. `HighlightIterLayer::sort_key` needs `&mut self` since it calls `Peekable::peek` which needs `&mut self`. `Vec::sort` functions only give immutable borrows of the elements to ensure the correctness of the sort. We could instead approach this by creating an eager Peekable and using that instead of `std::iter::Peekable` to wrap `QueryCaptures`: ```rust struct EagerPeekable<I: Iterator> { iter: I, peeked: Option<I::Item>, } impl<I: Iterator> EagerPeekable<I> { fn new(mut iter: I) -> Self { let peeked = iter.next(); Self { iter, peeked } } fn peek(&self) -> Option<&I::Item> { self.peeked.as_ref() } } impl<I: Iterator> Iterator for EagerPeekable<I> { type Item = I::Item; fn next(&mut self) -> Option<Self::Item> { std::mem::replace(&mut self.peeked, self.iter.next()) } } ``` This would be a cleaner approach (notice how `EagerPeekable::peek` takes `&self` rather than `&mut self`), however this doesn't work in practice because the Items emitted by the `tree_sitter::QueryCaptures` Iterator must be consumed before the next Item is returned. `Iterator::next` on `tree_sitter::QueryCaptures` modifies the `QueryMatch` returned by the last call of `next`. This behavior is not currently reflected in the lifetimes/structure of `QueryCaptures`. This fixes an issue with layers being out of order when using combined injections since the old code only checked the first range in the layer. Layers being out of order could cause missing highlights for combined-injections content.
2 years ago
if let Some((next_match, next_capture_index)) = captures.peek() {
let next_capture = next_match.captures[*next_capture_index];
if next_capture.node == capture.node {
capture = next_capture;
Fix initial highlight layer sort order (#5196) The purpose of this change is to remove the mutable self borrow on `HighlightIterLayer::sort_key` so that we can sort layers with the correct ordering using the `Vec::sort` function family. `HighlightIterLayer::sort_key` needs `&mut self` since it calls `Peekable::peek` which needs `&mut self`. `Vec::sort` functions only give immutable borrows of the elements to ensure the correctness of the sort. We could instead approach this by creating an eager Peekable and using that instead of `std::iter::Peekable` to wrap `QueryCaptures`: ```rust struct EagerPeekable<I: Iterator> { iter: I, peeked: Option<I::Item>, } impl<I: Iterator> EagerPeekable<I> { fn new(mut iter: I) -> Self { let peeked = iter.next(); Self { iter, peeked } } fn peek(&self) -> Option<&I::Item> { self.peeked.as_ref() } } impl<I: Iterator> Iterator for EagerPeekable<I> { type Item = I::Item; fn next(&mut self) -> Option<Self::Item> { std::mem::replace(&mut self.peeked, self.iter.next()) } } ``` This would be a cleaner approach (notice how `EagerPeekable::peek` takes `&self` rather than `&mut self`), however this doesn't work in practice because the Items emitted by the `tree_sitter::QueryCaptures` Iterator must be consumed before the next Item is returned. `Iterator::next` on `tree_sitter::QueryCaptures` modifies the `QueryMatch` returned by the last call of `next`. This behavior is not currently reflected in the lifetimes/structure of `QueryCaptures`. This fixes an issue with layers being out of order when using combined injections since the old code only checked the first range in the layer. Layers being out of order could cause missing highlights for combined-injections content.
2 years ago
match_ = 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.
Fix initial highlight layer sort order (#5196) The purpose of this change is to remove the mutable self borrow on `HighlightIterLayer::sort_key` so that we can sort layers with the correct ordering using the `Vec::sort` function family. `HighlightIterLayer::sort_key` needs `&mut self` since it calls `Peekable::peek` which needs `&mut self`. `Vec::sort` functions only give immutable borrows of the elements to ensure the correctness of the sort. We could instead approach this by creating an eager Peekable and using that instead of `std::iter::Peekable` to wrap `QueryCaptures`: ```rust struct EagerPeekable<I: Iterator> { iter: I, peeked: Option<I::Item>, } impl<I: Iterator> EagerPeekable<I> { fn new(mut iter: I) -> Self { let peeked = iter.next(); Self { iter, peeked } } fn peek(&self) -> Option<&I::Item> { self.peeked.as_ref() } } impl<I: Iterator> Iterator for EagerPeekable<I> { type Item = I::Item; fn next(&mut self) -> Option<Self::Item> { std::mem::replace(&mut self.peeked, self.iter.next()) } } ``` This would be a cleaner approach (notice how `EagerPeekable::peek` takes `&self` rather than `&mut self`), however this doesn't work in practice because the Items emitted by the `tree_sitter::QueryCaptures` Iterator must be consumed before the next Item is returned. `Iterator::next` on `tree_sitter::QueryCaptures` modifies the `QueryMatch` returned by the last call of `next`. This behavior is not currently reflected in the lifetimes/structure of `QueryCaptures`. This fixes an issue with layers being out of order when using combined injections since the old code only checked the first range in the layer. Layers being out of order could cause missing highlights for combined-injections content.
2 years ago
while let Some((next_match, next_capture_index)) = captures.peek() {
let next_capture = next_match.captures[*next_capture_index];
if next_capture.node == capture.node {
Fix initial highlight layer sort order (#5196) The purpose of this change is to remove the mutable self borrow on `HighlightIterLayer::sort_key` so that we can sort layers with the correct ordering using the `Vec::sort` function family. `HighlightIterLayer::sort_key` needs `&mut self` since it calls `Peekable::peek` which needs `&mut self`. `Vec::sort` functions only give immutable borrows of the elements to ensure the correctness of the sort. We could instead approach this by creating an eager Peekable and using that instead of `std::iter::Peekable` to wrap `QueryCaptures`: ```rust struct EagerPeekable<I: Iterator> { iter: I, peeked: Option<I::Item>, } impl<I: Iterator> EagerPeekable<I> { fn new(mut iter: I) -> Self { let peeked = iter.next(); Self { iter, peeked } } fn peek(&self) -> Option<&I::Item> { self.peeked.as_ref() } } impl<I: Iterator> Iterator for EagerPeekable<I> { type Item = I::Item; fn next(&mut self) -> Option<Self::Item> { std::mem::replace(&mut self.peeked, self.iter.next()) } } ``` This would be a cleaner approach (notice how `EagerPeekable::peek` takes `&self` rather than `&mut self`), however this doesn't work in practice because the Items emitted by the `tree_sitter::QueryCaptures` Iterator must be consumed before the next Item is returned. `Iterator::next` on `tree_sitter::QueryCaptures` modifies the `QueryMatch` returned by the last call of `next`. This behavior is not currently reflected in the lifetimes/structure of `QueryCaptures`. This fixes an issue with layers being out of order when using combined injections since the old code only checked the first range in the layer. Layers being out of order could cause missing highlights for combined-injections content.
2 years ago
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<Cow<'a, str>>, Option<Node<'a>>, 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<I> {
iter: I,
spans: Box<dyn Iterator<Item = (usize, std::ops::Range<usize>)>>,
next_event: Option<HighlightEvent>,
next_span: Option<(usize, std::ops::Range<usize>)>,
queue: Vec<HighlightEvent>,
}
/// Merge a list of spans into the highlight event stream.
pub fn merge<I: Iterator<Item = HighlightEvent>>(
iter: I,
spans: Vec<(usize, std::ops::Range<usize>)>,
) -> Merge<I> {
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<I: Iterator<Item = HighlightEvent>> Iterator for Merge<I> {
type Item = HighlightEvent;
fn next(&mut self) -> Option<Self::Item> {
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<W: fmt::Write>(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<W: fmt::Write>(
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<String> = [
"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());
}
}