1pub use crate::{
2 diagnostic_set::DiagnosticSet,
3 highlight_map::{HighlightId, HighlightMap},
4 markdown::ParsedMarkdown,
5 proto, Grammar, Language, LanguageRegistry,
6};
7use crate::{
8 diagnostic_set::{DiagnosticEntry, DiagnosticGroup},
9 language_settings::{language_settings, IndentGuideSettings, LanguageSettings},
10 markdown::parse_markdown,
11 outline::OutlineItem,
12 syntax_map::{
13 SyntaxLayer, SyntaxMap, SyntaxMapCapture, SyntaxMapCaptures, SyntaxMapMatch,
14 SyntaxMapMatches, SyntaxSnapshot, ToTreeSitterPoint,
15 },
16 task_context::RunnableRange,
17 LanguageScope, Outline, OutlineConfig, RunnableCapture, RunnableTag,
18};
19use anyhow::{anyhow, Context, Result};
20use async_watch as watch;
21pub use clock::ReplicaId;
22use futures::channel::oneshot;
23use gpui::{
24 AnyElement, AppContext, EventEmitter, HighlightStyle, ModelContext, Pixels, Task, TaskLabel,
25 WindowContext,
26};
27use lsp::LanguageServerId;
28use parking_lot::Mutex;
29use serde_json::Value;
30use similar::{ChangeTag, TextDiff};
31use smallvec::SmallVec;
32use smol::future::yield_now;
33use std::{
34 any::Any,
35 cell::Cell,
36 cmp::{self, Ordering, Reverse},
37 collections::BTreeMap,
38 ffi::OsStr,
39 fmt,
40 future::Future,
41 iter::{self, Iterator, Peekable},
42 mem,
43 ops::{Deref, DerefMut, Range},
44 path::{Path, PathBuf},
45 str,
46 sync::{Arc, LazyLock},
47 time::{Duration, Instant, SystemTime},
48 vec,
49};
50use sum_tree::TreeMap;
51use text::operation_queue::OperationQueue;
52use text::*;
53pub use text::{
54 Anchor, Bias, Buffer as TextBuffer, BufferId, BufferSnapshot as TextBufferSnapshot, Edit,
55 OffsetRangeExt, OffsetUtf16, Patch, Point, PointUtf16, Rope, Selection, SelectionGoal,
56 Subscription, TextDimension, TextSummary, ToOffset, ToOffsetUtf16, ToPoint, ToPointUtf16,
57 Transaction, TransactionId, Unclipped,
58};
59use theme::SyntaxTheme;
60#[cfg(any(test, feature = "test-support"))]
61use util::RandomCharIter;
62use util::RangeExt;
63
64#[cfg(any(test, feature = "test-support"))]
65pub use {tree_sitter_rust, tree_sitter_typescript};
66
67pub use lsp::DiagnosticSeverity;
68
69/// A label for the background task spawned by the buffer to compute
70/// a diff against the contents of its file.
71pub static BUFFER_DIFF_TASK: LazyLock<TaskLabel> = LazyLock::new(|| TaskLabel::new());
72
73/// Indicate whether a [Buffer] has permissions to edit.
74#[derive(PartialEq, Clone, Copy, Debug)]
75pub enum Capability {
76 /// The buffer is a mutable replica.
77 ReadWrite,
78 /// The buffer is a read-only replica.
79 ReadOnly,
80}
81
82pub type BufferRow = u32;
83
84/// An in-memory representation of a source code file, including its text,
85/// syntax trees, git status, and diagnostics.
86pub struct Buffer {
87 text: TextBuffer,
88 diff_base: Option<Rope>,
89 git_diff: git::diff::BufferDiff,
90 file: Option<Arc<dyn File>>,
91 /// The mtime of the file when this buffer was last loaded from
92 /// or saved to disk.
93 saved_mtime: Option<SystemTime>,
94 /// The version vector when this buffer was last loaded from
95 /// or saved to disk.
96 saved_version: clock::Global,
97 preview_version: clock::Global,
98 transaction_depth: usize,
99 was_dirty_before_starting_transaction: Option<bool>,
100 reload_task: Option<Task<Result<()>>>,
101 language: Option<Arc<Language>>,
102 autoindent_requests: Vec<Arc<AutoindentRequest>>,
103 pending_autoindent: Option<Task<()>>,
104 sync_parse_timeout: Duration,
105 syntax_map: Mutex<SyntaxMap>,
106 parsing_in_background: bool,
107 parse_status: (watch::Sender<ParseStatus>, watch::Receiver<ParseStatus>),
108 non_text_state_update_count: usize,
109 diagnostics: SmallVec<[(LanguageServerId, DiagnosticSet); 2]>,
110 remote_selections: TreeMap<ReplicaId, SelectionSet>,
111 diagnostics_timestamp: clock::Lamport,
112 completion_triggers: Vec<String>,
113 completion_triggers_timestamp: clock::Lamport,
114 deferred_ops: OperationQueue<Operation>,
115 capability: Capability,
116 has_conflict: bool,
117 diff_base_version: usize,
118 /// Memoize calls to has_changes_since(saved_version).
119 /// The contents of a cell are (self.version, has_changes) at the time of a last call.
120 has_unsaved_edits: Cell<(clock::Global, bool)>,
121}
122
123#[derive(Copy, Clone, Debug, PartialEq, Eq)]
124pub enum ParseStatus {
125 Idle,
126 Parsing,
127}
128
129/// An immutable, cheaply cloneable representation of a fixed
130/// state of a buffer.
131pub struct BufferSnapshot {
132 text: text::BufferSnapshot,
133 git_diff: git::diff::BufferDiff,
134 pub(crate) syntax: SyntaxSnapshot,
135 file: Option<Arc<dyn File>>,
136 diagnostics: SmallVec<[(LanguageServerId, DiagnosticSet); 2]>,
137 remote_selections: TreeMap<ReplicaId, SelectionSet>,
138 language: Option<Arc<Language>>,
139 non_text_state_update_count: usize,
140}
141
142/// The kind and amount of indentation in a particular line. For now,
143/// assumes that indentation is all the same character.
144#[derive(Clone, Copy, Debug, PartialEq, Eq, Default)]
145pub struct IndentSize {
146 /// The number of bytes that comprise the indentation.
147 pub len: u32,
148 /// The kind of whitespace used for indentation.
149 pub kind: IndentKind,
150}
151
152/// A whitespace character that's used for indentation.
153#[derive(Clone, Copy, Debug, PartialEq, Eq, Default)]
154pub enum IndentKind {
155 /// An ASCII space character.
156 #[default]
157 Space,
158 /// An ASCII tab character.
159 Tab,
160}
161
162/// The shape of a selection cursor.
163#[derive(Copy, Clone, PartialEq, Eq, Debug, Default)]
164pub enum CursorShape {
165 /// A vertical bar
166 #[default]
167 Bar,
168 /// A block that surrounds the following character
169 Block,
170 /// An underline that runs along the following character
171 Underscore,
172 /// A box drawn around the following character
173 Hollow,
174}
175
176#[derive(Clone, Debug)]
177struct SelectionSet {
178 line_mode: bool,
179 cursor_shape: CursorShape,
180 selections: Arc<[Selection<Anchor>]>,
181 lamport_timestamp: clock::Lamport,
182}
183
184/// A diagnostic associated with a certain range of a buffer.
185#[derive(Clone, Debug, PartialEq, Eq)]
186pub struct Diagnostic {
187 /// The name of the service that produced this diagnostic.
188 pub source: Option<String>,
189 /// A machine-readable code that identifies this diagnostic.
190 pub code: Option<String>,
191 /// Whether this diagnostic is a hint, warning, or error.
192 pub severity: DiagnosticSeverity,
193 /// The human-readable message associated with this diagnostic.
194 pub message: String,
195 /// An id that identifies the group to which this diagnostic belongs.
196 ///
197 /// When a language server produces a diagnostic with
198 /// one or more associated diagnostics, those diagnostics are all
199 /// assigned a single group id.
200 pub group_id: usize,
201 /// Whether this diagnostic is the primary diagnostic for its group.
202 ///
203 /// In a given group, the primary diagnostic is the top-level diagnostic
204 /// returned by the language server. The non-primary diagnostics are the
205 /// associated diagnostics.
206 pub is_primary: bool,
207 /// Whether this diagnostic is considered to originate from an analysis of
208 /// files on disk, as opposed to any unsaved buffer contents. This is a
209 /// property of a given diagnostic source, and is configured for a given
210 /// language server via the [`LspAdapter::disk_based_diagnostic_sources`](crate::LspAdapter::disk_based_diagnostic_sources) method
211 /// for the language server.
212 pub is_disk_based: bool,
213 /// Whether this diagnostic marks unnecessary code.
214 pub is_unnecessary: bool,
215 /// Data from language server that produced this diagnostic. Passed back to the LS when we request code actions for this diagnostic.
216 pub data: Option<Value>,
217}
218
219/// TODO - move this into the `project` crate and make it private.
220pub async fn prepare_completion_documentation(
221 documentation: &lsp::Documentation,
222 language_registry: &Arc<LanguageRegistry>,
223 language: Option<Arc<Language>>,
224) -> Documentation {
225 match documentation {
226 lsp::Documentation::String(text) => {
227 if text.lines().count() <= 1 {
228 Documentation::SingleLine(text.clone())
229 } else {
230 Documentation::MultiLinePlainText(text.clone())
231 }
232 }
233
234 lsp::Documentation::MarkupContent(lsp::MarkupContent { kind, value }) => match kind {
235 lsp::MarkupKind::PlainText => {
236 if value.lines().count() <= 1 {
237 Documentation::SingleLine(value.clone())
238 } else {
239 Documentation::MultiLinePlainText(value.clone())
240 }
241 }
242
243 lsp::MarkupKind::Markdown => {
244 let parsed = parse_markdown(value, language_registry, language).await;
245 Documentation::MultiLineMarkdown(parsed)
246 }
247 },
248 }
249}
250
251/// Documentation associated with a [`Completion`].
252#[derive(Clone, Debug)]
253pub enum Documentation {
254 /// There is no documentation for this completion.
255 Undocumented,
256 /// A single line of documentation.
257 SingleLine(String),
258 /// Multiple lines of plain text documentation.
259 MultiLinePlainText(String),
260 /// Markdown documentation.
261 MultiLineMarkdown(ParsedMarkdown),
262}
263
264/// An operation used to synchronize this buffer with its other replicas.
265#[derive(Clone, Debug, PartialEq)]
266pub enum Operation {
267 /// A text operation.
268 Buffer(text::Operation),
269
270 /// An update to the buffer's diagnostics.
271 UpdateDiagnostics {
272 /// The id of the language server that produced the new diagnostics.
273 server_id: LanguageServerId,
274 /// The diagnostics.
275 diagnostics: Arc<[DiagnosticEntry<Anchor>]>,
276 /// The buffer's lamport timestamp.
277 lamport_timestamp: clock::Lamport,
278 },
279
280 /// An update to the most recent selections in this buffer.
281 UpdateSelections {
282 /// The selections.
283 selections: Arc<[Selection<Anchor>]>,
284 /// The buffer's lamport timestamp.
285 lamport_timestamp: clock::Lamport,
286 /// Whether the selections are in 'line mode'.
287 line_mode: bool,
288 /// The [`CursorShape`] associated with these selections.
289 cursor_shape: CursorShape,
290 },
291
292 /// An update to the characters that should trigger autocompletion
293 /// for this buffer.
294 UpdateCompletionTriggers {
295 /// The characters that trigger autocompletion.
296 triggers: Vec<String>,
297 /// The buffer's lamport timestamp.
298 lamport_timestamp: clock::Lamport,
299 },
300}
301
302/// An event that occurs in a buffer.
303#[derive(Clone, Debug, PartialEq)]
304pub enum Event {
305 /// The buffer was changed in a way that must be
306 /// propagated to its other replicas.
307 Operation(Operation),
308 /// The buffer was edited.
309 Edited,
310 /// The buffer's `dirty` bit changed.
311 DirtyChanged,
312 /// The buffer was saved.
313 Saved,
314 /// The buffer's file was changed on disk.
315 FileHandleChanged,
316 /// The buffer was reloaded.
317 Reloaded,
318 /// The buffer's diff_base changed.
319 DiffBaseChanged,
320 /// Buffer's excerpts for a certain diff base were recalculated.
321 DiffUpdated,
322 /// The buffer's language was changed.
323 LanguageChanged,
324 /// The buffer's syntax trees were updated.
325 Reparsed,
326 /// The buffer's diagnostics were updated.
327 DiagnosticsUpdated,
328 /// The buffer gained or lost editing capabilities.
329 CapabilityChanged,
330 /// The buffer was explicitly requested to close.
331 Closed,
332 /// The buffer was discarded when closing.
333 Discarded,
334}
335
336/// The file associated with a buffer.
337pub trait File: Send + Sync {
338 /// Returns the [`LocalFile`] associated with this file, if the
339 /// file is local.
340 fn as_local(&self) -> Option<&dyn LocalFile>;
341
342 /// Returns whether this file is local.
343 fn is_local(&self) -> bool {
344 self.as_local().is_some()
345 }
346
347 /// Returns the file's mtime.
348 fn mtime(&self) -> Option<SystemTime>;
349
350 /// Returns the path of this file relative to the worktree's root directory.
351 fn path(&self) -> &Arc<Path>;
352
353 /// Returns the path of this file relative to the worktree's parent directory (this means it
354 /// includes the name of the worktree's root folder).
355 fn full_path(&self, cx: &AppContext) -> PathBuf;
356
357 /// Returns the last component of this handle's absolute path. If this handle refers to the root
358 /// of its worktree, then this method will return the name of the worktree itself.
359 fn file_name<'a>(&'a self, cx: &'a AppContext) -> &'a OsStr;
360
361 /// Returns the id of the worktree to which this file belongs.
362 ///
363 /// This is needed for looking up project-specific settings.
364 fn worktree_id(&self) -> usize;
365
366 /// Returns whether the file has been deleted.
367 fn is_deleted(&self) -> bool;
368
369 /// Returns whether the file existed on disk at one point
370 fn is_created(&self) -> bool {
371 self.mtime().is_some()
372 }
373
374 /// Converts this file into an [`Any`] trait object.
375 fn as_any(&self) -> &dyn Any;
376
377 /// Converts this file into a protobuf message.
378 fn to_proto(&self, cx: &AppContext) -> rpc::proto::File;
379
380 /// Return whether Zed considers this to be a private file.
381 fn is_private(&self) -> bool;
382}
383
384/// The file associated with a buffer, in the case where the file is on the local disk.
385pub trait LocalFile: File {
386 /// Returns the absolute path of this file
387 fn abs_path(&self, cx: &AppContext) -> PathBuf;
388
389 /// Loads the file's contents from disk.
390 fn load(&self, cx: &AppContext) -> Task<Result<String>>;
391
392 /// Returns true if the file should not be shared with collaborators.
393 fn is_private(&self, _: &AppContext) -> bool {
394 false
395 }
396}
397
398/// The auto-indent behavior associated with an editing operation.
399/// For some editing operations, each affected line of text has its
400/// indentation recomputed. For other operations, the entire block
401/// of edited text is adjusted uniformly.
402#[derive(Clone, Debug)]
403pub enum AutoindentMode {
404 /// Indent each line of inserted text.
405 EachLine,
406 /// Apply the same indentation adjustment to all of the lines
407 /// in a given insertion.
408 Block {
409 /// The original indentation level of the first line of each
410 /// insertion, if it has been copied.
411 original_indent_columns: Vec<u32>,
412 },
413}
414
415#[derive(Clone)]
416struct AutoindentRequest {
417 before_edit: BufferSnapshot,
418 entries: Vec<AutoindentRequestEntry>,
419 is_block_mode: bool,
420}
421
422#[derive(Clone)]
423struct AutoindentRequestEntry {
424 /// A range of the buffer whose indentation should be adjusted.
425 range: Range<Anchor>,
426 /// Whether or not these lines should be considered brand new, for the
427 /// purpose of auto-indent. When text is not new, its indentation will
428 /// only be adjusted if the suggested indentation level has *changed*
429 /// since the edit was made.
430 first_line_is_new: bool,
431 indent_size: IndentSize,
432 original_indent_column: Option<u32>,
433}
434
435#[derive(Debug)]
436struct IndentSuggestion {
437 basis_row: u32,
438 delta: Ordering,
439 within_error: bool,
440}
441
442struct BufferChunkHighlights<'a> {
443 captures: SyntaxMapCaptures<'a>,
444 next_capture: Option<SyntaxMapCapture<'a>>,
445 stack: Vec<(usize, HighlightId)>,
446 highlight_maps: Vec<HighlightMap>,
447}
448
449/// An iterator that yields chunks of a buffer's text, along with their
450/// syntax highlights and diagnostic status.
451pub struct BufferChunks<'a> {
452 buffer_snapshot: Option<&'a BufferSnapshot>,
453 range: Range<usize>,
454 chunks: text::Chunks<'a>,
455 diagnostic_endpoints: Option<Peekable<vec::IntoIter<DiagnosticEndpoint>>>,
456 error_depth: usize,
457 warning_depth: usize,
458 information_depth: usize,
459 hint_depth: usize,
460 unnecessary_depth: usize,
461 highlights: Option<BufferChunkHighlights<'a>>,
462}
463
464/// A chunk of a buffer's text, along with its syntax highlight and
465/// diagnostic status.
466#[derive(Clone, Debug, Default)]
467pub struct Chunk<'a> {
468 /// The text of the chunk.
469 pub text: &'a str,
470 /// The syntax highlighting style of the chunk.
471 pub syntax_highlight_id: Option<HighlightId>,
472 /// The highlight style that has been applied to this chunk in
473 /// the editor.
474 pub highlight_style: Option<HighlightStyle>,
475 /// The severity of diagnostic associated with this chunk, if any.
476 pub diagnostic_severity: Option<DiagnosticSeverity>,
477 /// Whether this chunk of text is marked as unnecessary.
478 pub is_unnecessary: bool,
479 /// Whether this chunk of text was originally a tab character.
480 pub is_tab: bool,
481 /// An optional recipe for how the chunk should be presented.
482 pub renderer: Option<ChunkRenderer>,
483}
484
485/// A recipe for how the chunk should be presented.
486#[derive(Clone)]
487pub struct ChunkRenderer {
488 /// creates a custom element to represent this chunk.
489 pub render: Arc<dyn Send + Sync + Fn(&mut ChunkRendererContext) -> AnyElement>,
490 /// If true, the element is constrained to the shaped width of the text.
491 pub constrain_width: bool,
492}
493
494pub struct ChunkRendererContext<'a, 'b> {
495 pub context: &'a mut WindowContext<'b>,
496 pub max_width: Pixels,
497}
498
499impl fmt::Debug for ChunkRenderer {
500 fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
501 f.debug_struct("ChunkRenderer")
502 .field("constrain_width", &self.constrain_width)
503 .finish()
504 }
505}
506
507impl<'a, 'b> Deref for ChunkRendererContext<'a, 'b> {
508 type Target = WindowContext<'b>;
509
510 fn deref(&self) -> &Self::Target {
511 self.context
512 }
513}
514
515impl<'a, 'b> DerefMut for ChunkRendererContext<'a, 'b> {
516 fn deref_mut(&mut self) -> &mut Self::Target {
517 self.context
518 }
519}
520
521/// A set of edits to a given version of a buffer, computed asynchronously.
522#[derive(Debug)]
523pub struct Diff {
524 pub(crate) base_version: clock::Global,
525 line_ending: LineEnding,
526 edits: Vec<(Range<usize>, Arc<str>)>,
527}
528
529#[derive(Clone, Copy)]
530pub(crate) struct DiagnosticEndpoint {
531 offset: usize,
532 is_start: bool,
533 severity: DiagnosticSeverity,
534 is_unnecessary: bool,
535}
536
537/// A class of characters, used for characterizing a run of text.
538#[derive(Copy, Clone, Eq, PartialEq, PartialOrd, Ord, Debug)]
539pub enum CharKind {
540 /// Whitespace.
541 Whitespace,
542 /// Punctuation.
543 Punctuation,
544 /// Word.
545 Word,
546}
547
548/// A runnable is a set of data about a region that could be resolved into a task
549pub struct Runnable {
550 pub tags: SmallVec<[RunnableTag; 1]>,
551 pub language: Arc<Language>,
552 pub buffer: BufferId,
553}
554
555#[derive(Clone, Debug, PartialEq)]
556pub struct IndentGuide {
557 pub buffer_id: BufferId,
558 pub start_row: BufferRow,
559 pub end_row: BufferRow,
560 pub depth: u32,
561 pub tab_size: u32,
562 pub settings: IndentGuideSettings,
563}
564
565impl IndentGuide {
566 pub fn indent_level(&self) -> u32 {
567 self.depth * self.tab_size
568 }
569}
570
571impl Buffer {
572 /// Create a new buffer with the given base text.
573 pub fn local<T: Into<String>>(base_text: T, cx: &mut ModelContext<Self>) -> Self {
574 Self::build(
575 TextBuffer::new(0, cx.entity_id().as_non_zero_u64().into(), base_text.into()),
576 None,
577 None,
578 Capability::ReadWrite,
579 )
580 }
581
582 /// Create a new buffer with the given base text that has proper line endings and other normalization applied.
583 pub fn local_normalized(
584 base_text_normalized: Rope,
585 line_ending: LineEnding,
586 cx: &mut ModelContext<Self>,
587 ) -> Self {
588 Self::build(
589 TextBuffer::new_normalized(
590 0,
591 cx.entity_id().as_non_zero_u64().into(),
592 line_ending,
593 base_text_normalized,
594 ),
595 None,
596 None,
597 Capability::ReadWrite,
598 )
599 }
600
601 /// Create a new buffer that is a replica of a remote buffer.
602 pub fn remote(
603 remote_id: BufferId,
604 replica_id: ReplicaId,
605 capability: Capability,
606 base_text: impl Into<String>,
607 ) -> Self {
608 Self::build(
609 TextBuffer::new(replica_id, remote_id, base_text.into()),
610 None,
611 None,
612 capability,
613 )
614 }
615
616 /// Create a new buffer that is a replica of a remote buffer, populating its
617 /// state from the given protobuf message.
618 pub fn from_proto(
619 replica_id: ReplicaId,
620 capability: Capability,
621 message: proto::BufferState,
622 file: Option<Arc<dyn File>>,
623 ) -> Result<Self> {
624 let buffer_id = BufferId::new(message.id)
625 .with_context(|| anyhow!("Could not deserialize buffer_id"))?;
626 let buffer = TextBuffer::new(replica_id, buffer_id, message.base_text);
627 let mut this = Self::build(buffer, message.diff_base, file, capability);
628 this.text.set_line_ending(proto::deserialize_line_ending(
629 rpc::proto::LineEnding::from_i32(message.line_ending)
630 .ok_or_else(|| anyhow!("missing line_ending"))?,
631 ));
632 this.saved_version = proto::deserialize_version(&message.saved_version);
633 this.saved_mtime = message.saved_mtime.map(|time| time.into());
634 Ok(this)
635 }
636
637 /// Serialize the buffer's state to a protobuf message.
638 pub fn to_proto(&self, cx: &AppContext) -> proto::BufferState {
639 proto::BufferState {
640 id: self.remote_id().into(),
641 file: self.file.as_ref().map(|f| f.to_proto(cx)),
642 base_text: self.base_text().to_string(),
643 diff_base: self.diff_base.as_ref().map(|h| h.to_string()),
644 line_ending: proto::serialize_line_ending(self.line_ending()) as i32,
645 saved_version: proto::serialize_version(&self.saved_version),
646 saved_mtime: self.saved_mtime.map(|time| time.into()),
647 }
648 }
649
650 /// Serialize as protobufs all of the changes to the buffer since the given version.
651 pub fn serialize_ops(
652 &self,
653 since: Option<clock::Global>,
654 cx: &AppContext,
655 ) -> Task<Vec<proto::Operation>> {
656 let mut operations = Vec::new();
657 operations.extend(self.deferred_ops.iter().map(proto::serialize_operation));
658
659 operations.extend(self.remote_selections.iter().map(|(_, set)| {
660 proto::serialize_operation(&Operation::UpdateSelections {
661 selections: set.selections.clone(),
662 lamport_timestamp: set.lamport_timestamp,
663 line_mode: set.line_mode,
664 cursor_shape: set.cursor_shape,
665 })
666 }));
667
668 for (server_id, diagnostics) in &self.diagnostics {
669 operations.push(proto::serialize_operation(&Operation::UpdateDiagnostics {
670 lamport_timestamp: self.diagnostics_timestamp,
671 server_id: *server_id,
672 diagnostics: diagnostics.iter().cloned().collect(),
673 }));
674 }
675
676 operations.push(proto::serialize_operation(
677 &Operation::UpdateCompletionTriggers {
678 triggers: self.completion_triggers.clone(),
679 lamport_timestamp: self.completion_triggers_timestamp,
680 },
681 ));
682
683 let text_operations = self.text.operations().clone();
684 cx.background_executor().spawn(async move {
685 let since = since.unwrap_or_default();
686 operations.extend(
687 text_operations
688 .iter()
689 .filter(|(_, op)| !since.observed(op.timestamp()))
690 .map(|(_, op)| proto::serialize_operation(&Operation::Buffer(op.clone()))),
691 );
692 operations.sort_unstable_by_key(proto::lamport_timestamp_for_operation);
693 operations
694 })
695 }
696
697 /// Assign a language to the buffer, returning the buffer.
698 pub fn with_language(mut self, language: Arc<Language>, cx: &mut ModelContext<Self>) -> Self {
699 self.set_language(Some(language), cx);
700 self
701 }
702
703 /// Returns the [Capability] of this buffer.
704 pub fn capability(&self) -> Capability {
705 self.capability
706 }
707
708 /// Whether this buffer can only be read.
709 pub fn read_only(&self) -> bool {
710 self.capability == Capability::ReadOnly
711 }
712
713 /// Builds a [Buffer] with the given underlying [TextBuffer], diff base, [File] and [Capability].
714 pub fn build(
715 buffer: TextBuffer,
716 diff_base: Option<String>,
717 file: Option<Arc<dyn File>>,
718 capability: Capability,
719 ) -> Self {
720 let saved_mtime = file.as_ref().and_then(|file| file.mtime());
721
722 Self {
723 saved_mtime,
724 saved_version: buffer.version(),
725 preview_version: buffer.version(),
726 reload_task: None,
727 transaction_depth: 0,
728 was_dirty_before_starting_transaction: None,
729 has_unsaved_edits: Cell::new((buffer.version(), false)),
730 text: buffer,
731 diff_base: diff_base
732 .map(|mut raw_diff_base| {
733 LineEnding::normalize(&mut raw_diff_base);
734 raw_diff_base
735 })
736 .map(Rope::from),
737 diff_base_version: 0,
738 git_diff: git::diff::BufferDiff::new(),
739 file,
740 capability,
741 syntax_map: Mutex::new(SyntaxMap::new()),
742 parsing_in_background: false,
743 non_text_state_update_count: 0,
744 sync_parse_timeout: Duration::from_millis(1),
745 parse_status: async_watch::channel(ParseStatus::Idle),
746 autoindent_requests: Default::default(),
747 pending_autoindent: Default::default(),
748 language: None,
749 remote_selections: Default::default(),
750 diagnostics: Default::default(),
751 diagnostics_timestamp: Default::default(),
752 completion_triggers: Default::default(),
753 completion_triggers_timestamp: Default::default(),
754 deferred_ops: OperationQueue::new(),
755 has_conflict: false,
756 }
757 }
758
759 /// Retrieve a snapshot of the buffer's current state. This is computationally
760 /// cheap, and allows reading from the buffer on a background thread.
761 pub fn snapshot(&self) -> BufferSnapshot {
762 let text = self.text.snapshot();
763 let mut syntax_map = self.syntax_map.lock();
764 syntax_map.interpolate(&text);
765 let syntax = syntax_map.snapshot();
766
767 BufferSnapshot {
768 text,
769 syntax,
770 git_diff: self.git_diff.clone(),
771 file: self.file.clone(),
772 remote_selections: self.remote_selections.clone(),
773 diagnostics: self.diagnostics.clone(),
774 language: self.language.clone(),
775 non_text_state_update_count: self.non_text_state_update_count,
776 }
777 }
778
779 #[cfg(test)]
780 pub(crate) fn as_text_snapshot(&self) -> &text::BufferSnapshot {
781 &self.text
782 }
783
784 /// Retrieve a snapshot of the buffer's raw text, without any
785 /// language-related state like the syntax tree or diagnostics.
786 pub fn text_snapshot(&self) -> text::BufferSnapshot {
787 self.text.snapshot()
788 }
789
790 /// The file associated with the buffer, if any.
791 pub fn file(&self) -> Option<&Arc<dyn File>> {
792 self.file.as_ref()
793 }
794
795 /// The version of the buffer that was last saved or reloaded from disk.
796 pub fn saved_version(&self) -> &clock::Global {
797 &self.saved_version
798 }
799
800 /// The mtime of the buffer's file when the buffer was last saved or reloaded from disk.
801 pub fn saved_mtime(&self) -> Option<SystemTime> {
802 self.saved_mtime
803 }
804
805 /// Assign a language to the buffer.
806 pub fn set_language(&mut self, language: Option<Arc<Language>>, cx: &mut ModelContext<Self>) {
807 self.non_text_state_update_count += 1;
808 self.syntax_map.lock().clear();
809 self.language = language;
810 self.reparse(cx);
811 cx.emit(Event::LanguageChanged);
812 }
813
814 /// Assign a language registry to the buffer. This allows the buffer to retrieve
815 /// other languages if parts of the buffer are written in different languages.
816 pub fn set_language_registry(&mut self, language_registry: Arc<LanguageRegistry>) {
817 self.syntax_map
818 .lock()
819 .set_language_registry(language_registry);
820 }
821
822 pub fn language_registry(&self) -> Option<Arc<LanguageRegistry>> {
823 self.syntax_map.lock().language_registry()
824 }
825
826 /// Assign the buffer a new [Capability].
827 pub fn set_capability(&mut self, capability: Capability, cx: &mut ModelContext<Self>) {
828 self.capability = capability;
829 cx.emit(Event::CapabilityChanged)
830 }
831
832 /// This method is called to signal that the buffer has been saved.
833 pub fn did_save(
834 &mut self,
835 version: clock::Global,
836 mtime: Option<SystemTime>,
837 cx: &mut ModelContext<Self>,
838 ) {
839 self.saved_version = version;
840 self.has_unsaved_edits
841 .set((self.saved_version().clone(), false));
842 self.has_conflict = false;
843 self.saved_mtime = mtime;
844 cx.emit(Event::Saved);
845 cx.notify();
846 }
847
848 /// This method is called to signal that the buffer has been discarded.
849 pub fn discarded(&mut self, cx: &mut ModelContext<Self>) {
850 cx.emit(Event::Discarded);
851 cx.notify();
852 }
853
854 /// Reloads the contents of the buffer from disk.
855 pub fn reload(
856 &mut self,
857 cx: &mut ModelContext<Self>,
858 ) -> oneshot::Receiver<Option<Transaction>> {
859 let (tx, rx) = futures::channel::oneshot::channel();
860 let prev_version = self.text.version();
861 self.reload_task = Some(cx.spawn(|this, mut cx| async move {
862 let Some((new_mtime, new_text)) = this.update(&mut cx, |this, cx| {
863 let file = this.file.as_ref()?.as_local()?;
864 Some((file.mtime(), file.load(cx)))
865 })?
866 else {
867 return Ok(());
868 };
869
870 let new_text = new_text.await?;
871 let diff = this
872 .update(&mut cx, |this, cx| this.diff(new_text.clone(), cx))?
873 .await;
874 this.update(&mut cx, |this, cx| {
875 if this.version() == diff.base_version {
876 this.finalize_last_transaction();
877 this.apply_diff(diff, cx);
878 tx.send(this.finalize_last_transaction().cloned()).ok();
879 this.has_conflict = false;
880 this.did_reload(this.version(), this.line_ending(), new_mtime, cx);
881 } else {
882 if !diff.edits.is_empty()
883 || this
884 .edits_since::<usize>(&diff.base_version)
885 .next()
886 .is_some()
887 {
888 this.has_conflict = true;
889 }
890
891 this.did_reload(prev_version, this.line_ending(), this.saved_mtime, cx);
892 }
893
894 this.reload_task.take();
895 })
896 }));
897 rx
898 }
899
900 /// This method is called to signal that the buffer has been reloaded.
901 pub fn did_reload(
902 &mut self,
903 version: clock::Global,
904 line_ending: LineEnding,
905 mtime: Option<SystemTime>,
906 cx: &mut ModelContext<Self>,
907 ) {
908 self.saved_version = version;
909 self.has_unsaved_edits
910 .set((self.saved_version.clone(), false));
911 self.text.set_line_ending(line_ending);
912 self.saved_mtime = mtime;
913 cx.emit(Event::Reloaded);
914 cx.notify();
915 }
916
917 /// Updates the [File] backing this buffer. This should be called when
918 /// the file has changed or has been deleted.
919 pub fn file_updated(&mut self, new_file: Arc<dyn File>, cx: &mut ModelContext<Self>) {
920 let mut file_changed = false;
921
922 if let Some(old_file) = self.file.as_ref() {
923 if new_file.path() != old_file.path() {
924 file_changed = true;
925 }
926
927 if new_file.is_deleted() {
928 if !old_file.is_deleted() {
929 file_changed = true;
930 if !self.is_dirty() {
931 cx.emit(Event::DirtyChanged);
932 }
933 }
934 } else {
935 let new_mtime = new_file.mtime();
936 if new_mtime != old_file.mtime() {
937 file_changed = true;
938
939 if !self.is_dirty() {
940 self.reload(cx).close();
941 }
942 }
943 }
944 } else {
945 file_changed = true;
946 };
947
948 self.file = Some(new_file);
949 if file_changed {
950 self.non_text_state_update_count += 1;
951 cx.emit(Event::FileHandleChanged);
952 cx.notify();
953 }
954 }
955
956 /// Returns the current diff base, see [Buffer::set_diff_base].
957 pub fn diff_base(&self) -> Option<&Rope> {
958 self.diff_base.as_ref()
959 }
960
961 /// Sets the text that will be used to compute a Git diff
962 /// against the buffer text.
963 pub fn set_diff_base(&mut self, diff_base: Option<String>, cx: &mut ModelContext<Self>) {
964 self.diff_base = diff_base
965 .map(|mut raw_diff_base| {
966 LineEnding::normalize(&mut raw_diff_base);
967 raw_diff_base
968 })
969 .map(Rope::from);
970 self.diff_base_version += 1;
971 if let Some(recalc_task) = self.git_diff_recalc(cx) {
972 cx.spawn(|buffer, mut cx| async move {
973 recalc_task.await;
974 buffer
975 .update(&mut cx, |_, cx| {
976 cx.emit(Event::DiffBaseChanged);
977 })
978 .ok();
979 })
980 .detach();
981 }
982 }
983
984 /// Returns a number, unique per diff base set to the buffer.
985 pub fn diff_base_version(&self) -> usize {
986 self.diff_base_version
987 }
988
989 /// Recomputes the Git diff status.
990 pub fn git_diff_recalc(&mut self, cx: &mut ModelContext<Self>) -> Option<Task<()>> {
991 let diff_base = self.diff_base.clone()?;
992 let snapshot = self.snapshot();
993
994 let mut diff = self.git_diff.clone();
995 let diff = cx.background_executor().spawn(async move {
996 diff.update(&diff_base, &snapshot).await;
997 diff
998 });
999
1000 Some(cx.spawn(|this, mut cx| async move {
1001 let buffer_diff = diff.await;
1002 this.update(&mut cx, |this, cx| {
1003 this.git_diff = buffer_diff;
1004 this.non_text_state_update_count += 1;
1005 cx.emit(Event::DiffUpdated);
1006 })
1007 .ok();
1008 }))
1009 }
1010
1011 /// Returns the primary [Language] assigned to this [Buffer].
1012 pub fn language(&self) -> Option<&Arc<Language>> {
1013 self.language.as_ref()
1014 }
1015
1016 /// Returns the [Language] at the given location.
1017 pub fn language_at<D: ToOffset>(&self, position: D) -> Option<Arc<Language>> {
1018 let offset = position.to_offset(self);
1019 self.syntax_map
1020 .lock()
1021 .layers_for_range(offset..offset, &self.text, false)
1022 .last()
1023 .map(|info| info.language.clone())
1024 .or_else(|| self.language.clone())
1025 }
1026
1027 /// An integer version number that accounts for all updates besides
1028 /// the buffer's text itself (which is versioned via a version vector).
1029 pub fn non_text_state_update_count(&self) -> usize {
1030 self.non_text_state_update_count
1031 }
1032
1033 /// Whether the buffer is being parsed in the background.
1034 #[cfg(any(test, feature = "test-support"))]
1035 pub fn is_parsing(&self) -> bool {
1036 self.parsing_in_background
1037 }
1038
1039 /// Indicates whether the buffer contains any regions that may be
1040 /// written in a language that hasn't been loaded yet.
1041 pub fn contains_unknown_injections(&self) -> bool {
1042 self.syntax_map.lock().contains_unknown_injections()
1043 }
1044
1045 #[cfg(test)]
1046 pub fn set_sync_parse_timeout(&mut self, timeout: Duration) {
1047 self.sync_parse_timeout = timeout;
1048 }
1049
1050 /// Called after an edit to synchronize the buffer's main parse tree with
1051 /// the buffer's new underlying state.
1052 ///
1053 /// Locks the syntax map and interpolates the edits since the last reparse
1054 /// into the foreground syntax tree.
1055 ///
1056 /// Then takes a stable snapshot of the syntax map before unlocking it.
1057 /// The snapshot with the interpolated edits is sent to a background thread,
1058 /// where we ask Tree-sitter to perform an incremental parse.
1059 ///
1060 /// Meanwhile, in the foreground, we block the main thread for up to 1ms
1061 /// waiting on the parse to complete. As soon as it completes, we proceed
1062 /// synchronously, unless a 1ms timeout elapses.
1063 ///
1064 /// If we time out waiting on the parse, we spawn a second task waiting
1065 /// until the parse does complete and return with the interpolated tree still
1066 /// in the foreground. When the background parse completes, call back into
1067 /// the main thread and assign the foreground parse state.
1068 ///
1069 /// If the buffer or grammar changed since the start of the background parse,
1070 /// initiate an additional reparse recursively. To avoid concurrent parses
1071 /// for the same buffer, we only initiate a new parse if we are not already
1072 /// parsing in the background.
1073 pub fn reparse(&mut self, cx: &mut ModelContext<Self>) {
1074 if self.parsing_in_background {
1075 return;
1076 }
1077 let language = if let Some(language) = self.language.clone() {
1078 language
1079 } else {
1080 return;
1081 };
1082
1083 let text = self.text_snapshot();
1084 let parsed_version = self.version();
1085
1086 let mut syntax_map = self.syntax_map.lock();
1087 syntax_map.interpolate(&text);
1088 let language_registry = syntax_map.language_registry();
1089 let mut syntax_snapshot = syntax_map.snapshot();
1090 drop(syntax_map);
1091
1092 let parse_task = cx.background_executor().spawn({
1093 let language = language.clone();
1094 let language_registry = language_registry.clone();
1095 async move {
1096 syntax_snapshot.reparse(&text, language_registry, language);
1097 syntax_snapshot
1098 }
1099 });
1100
1101 self.parse_status.0.send(ParseStatus::Parsing).unwrap();
1102 match cx
1103 .background_executor()
1104 .block_with_timeout(self.sync_parse_timeout, parse_task)
1105 {
1106 Ok(new_syntax_snapshot) => {
1107 self.did_finish_parsing(new_syntax_snapshot, cx);
1108 return;
1109 }
1110 Err(parse_task) => {
1111 self.parsing_in_background = true;
1112 cx.spawn(move |this, mut cx| async move {
1113 let new_syntax_map = parse_task.await;
1114 this.update(&mut cx, move |this, cx| {
1115 let grammar_changed =
1116 this.language.as_ref().map_or(true, |current_language| {
1117 !Arc::ptr_eq(&language, current_language)
1118 });
1119 let language_registry_changed = new_syntax_map
1120 .contains_unknown_injections()
1121 && language_registry.map_or(false, |registry| {
1122 registry.version() != new_syntax_map.language_registry_version()
1123 });
1124 let parse_again = language_registry_changed
1125 || grammar_changed
1126 || this.version.changed_since(&parsed_version);
1127 this.did_finish_parsing(new_syntax_map, cx);
1128 this.parsing_in_background = false;
1129 if parse_again {
1130 this.reparse(cx);
1131 }
1132 })
1133 .ok();
1134 })
1135 .detach();
1136 }
1137 }
1138 }
1139
1140 fn did_finish_parsing(&mut self, syntax_snapshot: SyntaxSnapshot, cx: &mut ModelContext<Self>) {
1141 self.non_text_state_update_count += 1;
1142 self.syntax_map.lock().did_parse(syntax_snapshot);
1143 self.request_autoindent(cx);
1144 self.parse_status.0.send(ParseStatus::Idle).unwrap();
1145 cx.emit(Event::Reparsed);
1146 cx.notify();
1147 }
1148
1149 pub fn parse_status(&self) -> watch::Receiver<ParseStatus> {
1150 self.parse_status.1.clone()
1151 }
1152
1153 /// Assign to the buffer a set of diagnostics created by a given language server.
1154 pub fn update_diagnostics(
1155 &mut self,
1156 server_id: LanguageServerId,
1157 diagnostics: DiagnosticSet,
1158 cx: &mut ModelContext<Self>,
1159 ) {
1160 let lamport_timestamp = self.text.lamport_clock.tick();
1161 let op = Operation::UpdateDiagnostics {
1162 server_id,
1163 diagnostics: diagnostics.iter().cloned().collect(),
1164 lamport_timestamp,
1165 };
1166 self.apply_diagnostic_update(server_id, diagnostics, lamport_timestamp, cx);
1167 self.send_operation(op, cx);
1168 }
1169
1170 fn request_autoindent(&mut self, cx: &mut ModelContext<Self>) {
1171 if let Some(indent_sizes) = self.compute_autoindents() {
1172 let indent_sizes = cx.background_executor().spawn(indent_sizes);
1173 match cx
1174 .background_executor()
1175 .block_with_timeout(Duration::from_micros(500), indent_sizes)
1176 {
1177 Ok(indent_sizes) => self.apply_autoindents(indent_sizes, cx),
1178 Err(indent_sizes) => {
1179 self.pending_autoindent = Some(cx.spawn(|this, mut cx| async move {
1180 let indent_sizes = indent_sizes.await;
1181 this.update(&mut cx, |this, cx| {
1182 this.apply_autoindents(indent_sizes, cx);
1183 })
1184 .ok();
1185 }));
1186 }
1187 }
1188 } else {
1189 self.autoindent_requests.clear();
1190 }
1191 }
1192
1193 fn compute_autoindents(&self) -> Option<impl Future<Output = BTreeMap<u32, IndentSize>>> {
1194 let max_rows_between_yields = 100;
1195 let snapshot = self.snapshot();
1196 if snapshot.syntax.is_empty() || self.autoindent_requests.is_empty() {
1197 return None;
1198 }
1199
1200 let autoindent_requests = self.autoindent_requests.clone();
1201 Some(async move {
1202 let mut indent_sizes = BTreeMap::new();
1203 for request in autoindent_requests {
1204 // Resolve each edited range to its row in the current buffer and in the
1205 // buffer before this batch of edits.
1206 let mut row_ranges = Vec::new();
1207 let mut old_to_new_rows = BTreeMap::new();
1208 let mut language_indent_sizes_by_new_row = Vec::new();
1209 for entry in &request.entries {
1210 let position = entry.range.start;
1211 let new_row = position.to_point(&snapshot).row;
1212 let new_end_row = entry.range.end.to_point(&snapshot).row + 1;
1213 language_indent_sizes_by_new_row.push((new_row, entry.indent_size));
1214
1215 if !entry.first_line_is_new {
1216 let old_row = position.to_point(&request.before_edit).row;
1217 old_to_new_rows.insert(old_row, new_row);
1218 }
1219 row_ranges.push((new_row..new_end_row, entry.original_indent_column));
1220 }
1221
1222 // Build a map containing the suggested indentation for each of the edited lines
1223 // with respect to the state of the buffer before these edits. This map is keyed
1224 // by the rows for these lines in the current state of the buffer.
1225 let mut old_suggestions = BTreeMap::<u32, (IndentSize, bool)>::default();
1226 let old_edited_ranges =
1227 contiguous_ranges(old_to_new_rows.keys().copied(), max_rows_between_yields);
1228 let mut language_indent_sizes = language_indent_sizes_by_new_row.iter().peekable();
1229 let mut language_indent_size = IndentSize::default();
1230 for old_edited_range in old_edited_ranges {
1231 let suggestions = request
1232 .before_edit
1233 .suggest_autoindents(old_edited_range.clone())
1234 .into_iter()
1235 .flatten();
1236 for (old_row, suggestion) in old_edited_range.zip(suggestions) {
1237 if let Some(suggestion) = suggestion {
1238 let new_row = *old_to_new_rows.get(&old_row).unwrap();
1239
1240 // Find the indent size based on the language for this row.
1241 while let Some((row, size)) = language_indent_sizes.peek() {
1242 if *row > new_row {
1243 break;
1244 }
1245 language_indent_size = *size;
1246 language_indent_sizes.next();
1247 }
1248
1249 let suggested_indent = old_to_new_rows
1250 .get(&suggestion.basis_row)
1251 .and_then(|from_row| {
1252 Some(old_suggestions.get(from_row).copied()?.0)
1253 })
1254 .unwrap_or_else(|| {
1255 request
1256 .before_edit
1257 .indent_size_for_line(suggestion.basis_row)
1258 })
1259 .with_delta(suggestion.delta, language_indent_size);
1260 old_suggestions
1261 .insert(new_row, (suggested_indent, suggestion.within_error));
1262 }
1263 }
1264 yield_now().await;
1265 }
1266
1267 // In block mode, only compute indentation suggestions for the first line
1268 // of each insertion. Otherwise, compute suggestions for every inserted line.
1269 let new_edited_row_ranges = contiguous_ranges(
1270 row_ranges.iter().flat_map(|(range, _)| {
1271 if request.is_block_mode {
1272 range.start..range.start + 1
1273 } else {
1274 range.clone()
1275 }
1276 }),
1277 max_rows_between_yields,
1278 );
1279
1280 // Compute new suggestions for each line, but only include them in the result
1281 // if they differ from the old suggestion for that line.
1282 let mut language_indent_sizes = language_indent_sizes_by_new_row.iter().peekable();
1283 let mut language_indent_size = IndentSize::default();
1284 for new_edited_row_range in new_edited_row_ranges {
1285 let suggestions = snapshot
1286 .suggest_autoindents(new_edited_row_range.clone())
1287 .into_iter()
1288 .flatten();
1289 for (new_row, suggestion) in new_edited_row_range.zip(suggestions) {
1290 if let Some(suggestion) = suggestion {
1291 // Find the indent size based on the language for this row.
1292 while let Some((row, size)) = language_indent_sizes.peek() {
1293 if *row > new_row {
1294 break;
1295 }
1296 language_indent_size = *size;
1297 language_indent_sizes.next();
1298 }
1299
1300 let suggested_indent = indent_sizes
1301 .get(&suggestion.basis_row)
1302 .copied()
1303 .unwrap_or_else(|| {
1304 snapshot.indent_size_for_line(suggestion.basis_row)
1305 })
1306 .with_delta(suggestion.delta, language_indent_size);
1307 if old_suggestions.get(&new_row).map_or(
1308 true,
1309 |(old_indentation, was_within_error)| {
1310 suggested_indent != *old_indentation
1311 && (!suggestion.within_error || *was_within_error)
1312 },
1313 ) {
1314 indent_sizes.insert(new_row, suggested_indent);
1315 }
1316 }
1317 }
1318 yield_now().await;
1319 }
1320
1321 // For each block of inserted text, adjust the indentation of the remaining
1322 // lines of the block by the same amount as the first line was adjusted.
1323 if request.is_block_mode {
1324 for (row_range, original_indent_column) in
1325 row_ranges
1326 .into_iter()
1327 .filter_map(|(range, original_indent_column)| {
1328 if range.len() > 1 {
1329 Some((range, original_indent_column?))
1330 } else {
1331 None
1332 }
1333 })
1334 {
1335 let new_indent = indent_sizes
1336 .get(&row_range.start)
1337 .copied()
1338 .unwrap_or_else(|| snapshot.indent_size_for_line(row_range.start));
1339 let delta = new_indent.len as i64 - original_indent_column as i64;
1340 if delta != 0 {
1341 for row in row_range.skip(1) {
1342 indent_sizes.entry(row).or_insert_with(|| {
1343 let mut size = snapshot.indent_size_for_line(row);
1344 if size.kind == new_indent.kind {
1345 match delta.cmp(&0) {
1346 Ordering::Greater => size.len += delta as u32,
1347 Ordering::Less => {
1348 size.len = size.len.saturating_sub(-delta as u32)
1349 }
1350 Ordering::Equal => {}
1351 }
1352 }
1353 size
1354 });
1355 }
1356 }
1357 }
1358 }
1359 }
1360
1361 indent_sizes
1362 })
1363 }
1364
1365 fn apply_autoindents(
1366 &mut self,
1367 indent_sizes: BTreeMap<u32, IndentSize>,
1368 cx: &mut ModelContext<Self>,
1369 ) {
1370 self.autoindent_requests.clear();
1371
1372 let edits: Vec<_> = indent_sizes
1373 .into_iter()
1374 .filter_map(|(row, indent_size)| {
1375 let current_size = indent_size_for_line(self, row);
1376 Self::edit_for_indent_size_adjustment(row, current_size, indent_size)
1377 })
1378 .collect();
1379
1380 let preserve_preview = self.preserve_preview();
1381 self.edit(edits, None, cx);
1382 if preserve_preview {
1383 self.refresh_preview();
1384 }
1385 }
1386
1387 /// Create a minimal edit that will cause the given row to be indented
1388 /// with the given size. After applying this edit, the length of the line
1389 /// will always be at least `new_size.len`.
1390 pub fn edit_for_indent_size_adjustment(
1391 row: u32,
1392 current_size: IndentSize,
1393 new_size: IndentSize,
1394 ) -> Option<(Range<Point>, String)> {
1395 if new_size.kind == current_size.kind {
1396 match new_size.len.cmp(¤t_size.len) {
1397 Ordering::Greater => {
1398 let point = Point::new(row, 0);
1399 Some((
1400 point..point,
1401 iter::repeat(new_size.char())
1402 .take((new_size.len - current_size.len) as usize)
1403 .collect::<String>(),
1404 ))
1405 }
1406
1407 Ordering::Less => Some((
1408 Point::new(row, 0)..Point::new(row, current_size.len - new_size.len),
1409 String::new(),
1410 )),
1411
1412 Ordering::Equal => None,
1413 }
1414 } else {
1415 Some((
1416 Point::new(row, 0)..Point::new(row, current_size.len),
1417 iter::repeat(new_size.char())
1418 .take(new_size.len as usize)
1419 .collect::<String>(),
1420 ))
1421 }
1422 }
1423
1424 /// Spawns a background task that asynchronously computes a `Diff` between the buffer's text
1425 /// and the given new text.
1426 pub fn diff(&self, mut new_text: String, cx: &AppContext) -> Task<Diff> {
1427 let old_text = self.as_rope().clone();
1428 let base_version = self.version();
1429 cx.background_executor()
1430 .spawn_labeled(*BUFFER_DIFF_TASK, async move {
1431 let old_text = old_text.to_string();
1432 let line_ending = LineEnding::detect(&new_text);
1433 LineEnding::normalize(&mut new_text);
1434
1435 let diff = TextDiff::from_chars(old_text.as_str(), new_text.as_str());
1436 let empty: Arc<str> = Arc::default();
1437
1438 let mut edits = Vec::new();
1439 let mut old_offset = 0;
1440 let mut new_offset = 0;
1441 let mut last_edit: Option<(Range<usize>, Range<usize>)> = None;
1442 for change in diff.iter_all_changes().map(Some).chain([None]) {
1443 if let Some(change) = &change {
1444 let len = change.value().len();
1445 match change.tag() {
1446 ChangeTag::Equal => {
1447 old_offset += len;
1448 new_offset += len;
1449 }
1450 ChangeTag::Delete => {
1451 let old_end_offset = old_offset + len;
1452 if let Some((last_old_range, _)) = &mut last_edit {
1453 last_old_range.end = old_end_offset;
1454 } else {
1455 last_edit =
1456 Some((old_offset..old_end_offset, new_offset..new_offset));
1457 }
1458 old_offset = old_end_offset;
1459 }
1460 ChangeTag::Insert => {
1461 let new_end_offset = new_offset + len;
1462 if let Some((_, last_new_range)) = &mut last_edit {
1463 last_new_range.end = new_end_offset;
1464 } else {
1465 last_edit =
1466 Some((old_offset..old_offset, new_offset..new_end_offset));
1467 }
1468 new_offset = new_end_offset;
1469 }
1470 }
1471 }
1472
1473 if let Some((old_range, new_range)) = &last_edit {
1474 if old_offset > old_range.end
1475 || new_offset > new_range.end
1476 || change.is_none()
1477 {
1478 let text = if new_range.is_empty() {
1479 empty.clone()
1480 } else {
1481 new_text[new_range.clone()].into()
1482 };
1483 edits.push((old_range.clone(), text));
1484 last_edit.take();
1485 }
1486 }
1487 }
1488
1489 Diff {
1490 base_version,
1491 line_ending,
1492 edits,
1493 }
1494 })
1495 }
1496
1497 /// Spawns a background task that searches the buffer for any whitespace
1498 /// at the ends of a lines, and returns a `Diff` that removes that whitespace.
1499 pub fn remove_trailing_whitespace(&self, cx: &AppContext) -> Task<Diff> {
1500 let old_text = self.as_rope().clone();
1501 let line_ending = self.line_ending();
1502 let base_version = self.version();
1503 cx.background_executor().spawn(async move {
1504 let ranges = trailing_whitespace_ranges(&old_text);
1505 let empty = Arc::<str>::from("");
1506 Diff {
1507 base_version,
1508 line_ending,
1509 edits: ranges
1510 .into_iter()
1511 .map(|range| (range, empty.clone()))
1512 .collect(),
1513 }
1514 })
1515 }
1516
1517 /// Ensures that the buffer ends with a single newline character, and
1518 /// no other whitespace.
1519 pub fn ensure_final_newline(&mut self, cx: &mut ModelContext<Self>) {
1520 let len = self.len();
1521 let mut offset = len;
1522 for chunk in self.as_rope().reversed_chunks_in_range(0..len) {
1523 let non_whitespace_len = chunk
1524 .trim_end_matches(|c: char| c.is_ascii_whitespace())
1525 .len();
1526 offset -= chunk.len();
1527 offset += non_whitespace_len;
1528 if non_whitespace_len != 0 {
1529 if offset == len - 1 && chunk.get(non_whitespace_len..) == Some("\n") {
1530 return;
1531 }
1532 break;
1533 }
1534 }
1535 self.edit([(offset..len, "\n")], None, cx);
1536 }
1537
1538 /// Applies a diff to the buffer. If the buffer has changed since the given diff was
1539 /// calculated, then adjust the diff to account for those changes, and discard any
1540 /// parts of the diff that conflict with those changes.
1541 pub fn apply_diff(&mut self, diff: Diff, cx: &mut ModelContext<Self>) -> Option<TransactionId> {
1542 // Check for any edits to the buffer that have occurred since this diff
1543 // was computed.
1544 let snapshot = self.snapshot();
1545 let mut edits_since = snapshot.edits_since::<usize>(&diff.base_version).peekable();
1546 let mut delta = 0;
1547 let adjusted_edits = diff.edits.into_iter().filter_map(|(range, new_text)| {
1548 while let Some(edit_since) = edits_since.peek() {
1549 // If the edit occurs after a diff hunk, then it does not
1550 // affect that hunk.
1551 if edit_since.old.start > range.end {
1552 break;
1553 }
1554 // If the edit precedes the diff hunk, then adjust the hunk
1555 // to reflect the edit.
1556 else if edit_since.old.end < range.start {
1557 delta += edit_since.new_len() as i64 - edit_since.old_len() as i64;
1558 edits_since.next();
1559 }
1560 // If the edit intersects a diff hunk, then discard that hunk.
1561 else {
1562 return None;
1563 }
1564 }
1565
1566 let start = (range.start as i64 + delta) as usize;
1567 let end = (range.end as i64 + delta) as usize;
1568 Some((start..end, new_text))
1569 });
1570
1571 self.start_transaction();
1572 self.text.set_line_ending(diff.line_ending);
1573 self.edit(adjusted_edits, None, cx);
1574 self.end_transaction(cx)
1575 }
1576
1577 fn has_unsaved_edits(&self) -> bool {
1578 let (last_version, has_unsaved_edits) = self.has_unsaved_edits.take();
1579
1580 if last_version == self.version {
1581 self.has_unsaved_edits
1582 .set((last_version, has_unsaved_edits));
1583 return has_unsaved_edits;
1584 }
1585
1586 let has_edits = self.has_edits_since(&self.saved_version);
1587 self.has_unsaved_edits
1588 .set((self.version.clone(), has_edits));
1589 has_edits
1590 }
1591
1592 /// Checks if the buffer has unsaved changes.
1593 pub fn is_dirty(&self) -> bool {
1594 self.capability != Capability::ReadOnly
1595 && (self.has_conflict
1596 || self.has_unsaved_edits()
1597 || self
1598 .file
1599 .as_ref()
1600 .map_or(false, |file| file.is_deleted() || !file.is_created()))
1601 }
1602
1603 /// Checks if the buffer and its file have both changed since the buffer
1604 /// was last saved or reloaded.
1605 pub fn has_conflict(&self) -> bool {
1606 self.has_conflict
1607 || self.file.as_ref().map_or(false, |file| {
1608 file.mtime() > self.saved_mtime && self.has_unsaved_edits()
1609 })
1610 }
1611
1612 /// Gets a [`Subscription`] that tracks all of the changes to the buffer's text.
1613 pub fn subscribe(&mut self) -> Subscription {
1614 self.text.subscribe()
1615 }
1616
1617 /// Starts a transaction, if one is not already in-progress. When undoing or
1618 /// redoing edits, all of the edits performed within a transaction are undone
1619 /// or redone together.
1620 pub fn start_transaction(&mut self) -> Option<TransactionId> {
1621 self.start_transaction_at(Instant::now())
1622 }
1623
1624 /// Starts a transaction, providing the current time. Subsequent transactions
1625 /// that occur within a short period of time will be grouped together. This
1626 /// is controlled by the buffer's undo grouping duration.
1627 pub fn start_transaction_at(&mut self, now: Instant) -> Option<TransactionId> {
1628 self.transaction_depth += 1;
1629 if self.was_dirty_before_starting_transaction.is_none() {
1630 self.was_dirty_before_starting_transaction = Some(self.is_dirty());
1631 }
1632 self.text.start_transaction_at(now)
1633 }
1634
1635 /// Terminates the current transaction, if this is the outermost transaction.
1636 pub fn end_transaction(&mut self, cx: &mut ModelContext<Self>) -> Option<TransactionId> {
1637 self.end_transaction_at(Instant::now(), cx)
1638 }
1639
1640 /// Terminates the current transaction, providing the current time. Subsequent transactions
1641 /// that occur within a short period of time will be grouped together. This
1642 /// is controlled by the buffer's undo grouping duration.
1643 pub fn end_transaction_at(
1644 &mut self,
1645 now: Instant,
1646 cx: &mut ModelContext<Self>,
1647 ) -> Option<TransactionId> {
1648 assert!(self.transaction_depth > 0);
1649 self.transaction_depth -= 1;
1650 let was_dirty = if self.transaction_depth == 0 {
1651 self.was_dirty_before_starting_transaction.take().unwrap()
1652 } else {
1653 false
1654 };
1655 if let Some((transaction_id, start_version)) = self.text.end_transaction_at(now) {
1656 self.did_edit(&start_version, was_dirty, cx);
1657 Some(transaction_id)
1658 } else {
1659 None
1660 }
1661 }
1662
1663 /// Manually add a transaction to the buffer's undo history.
1664 pub fn push_transaction(&mut self, transaction: Transaction, now: Instant) {
1665 self.text.push_transaction(transaction, now);
1666 }
1667
1668 /// Prevent the last transaction from being grouped with any subsequent transactions,
1669 /// even if they occur with the buffer's undo grouping duration.
1670 pub fn finalize_last_transaction(&mut self) -> Option<&Transaction> {
1671 self.text.finalize_last_transaction()
1672 }
1673
1674 /// Manually group all changes since a given transaction.
1675 pub fn group_until_transaction(&mut self, transaction_id: TransactionId) {
1676 self.text.group_until_transaction(transaction_id);
1677 }
1678
1679 /// Manually remove a transaction from the buffer's undo history
1680 pub fn forget_transaction(&mut self, transaction_id: TransactionId) {
1681 self.text.forget_transaction(transaction_id);
1682 }
1683
1684 /// Manually merge two adjacent transactions in the buffer's undo history.
1685 pub fn merge_transactions(&mut self, transaction: TransactionId, destination: TransactionId) {
1686 self.text.merge_transactions(transaction, destination);
1687 }
1688
1689 /// Waits for the buffer to receive operations with the given timestamps.
1690 pub fn wait_for_edits(
1691 &mut self,
1692 edit_ids: impl IntoIterator<Item = clock::Lamport>,
1693 ) -> impl Future<Output = Result<()>> {
1694 self.text.wait_for_edits(edit_ids)
1695 }
1696
1697 /// Waits for the buffer to receive the operations necessary for resolving the given anchors.
1698 pub fn wait_for_anchors(
1699 &mut self,
1700 anchors: impl IntoIterator<Item = Anchor>,
1701 ) -> impl 'static + Future<Output = Result<()>> {
1702 self.text.wait_for_anchors(anchors)
1703 }
1704
1705 /// Waits for the buffer to receive operations up to the given version.
1706 pub fn wait_for_version(&mut self, version: clock::Global) -> impl Future<Output = Result<()>> {
1707 self.text.wait_for_version(version)
1708 }
1709
1710 /// Forces all futures returned by [`Buffer::wait_for_version`], [`Buffer::wait_for_edits`], or
1711 /// [`Buffer::wait_for_version`] to resolve with an error.
1712 pub fn give_up_waiting(&mut self) {
1713 self.text.give_up_waiting();
1714 }
1715
1716 /// Stores a set of selections that should be broadcasted to all of the buffer's replicas.
1717 pub fn set_active_selections(
1718 &mut self,
1719 selections: Arc<[Selection<Anchor>]>,
1720 line_mode: bool,
1721 cursor_shape: CursorShape,
1722 cx: &mut ModelContext<Self>,
1723 ) {
1724 let lamport_timestamp = self.text.lamport_clock.tick();
1725 self.remote_selections.insert(
1726 self.text.replica_id(),
1727 SelectionSet {
1728 selections: selections.clone(),
1729 lamport_timestamp,
1730 line_mode,
1731 cursor_shape,
1732 },
1733 );
1734 self.send_operation(
1735 Operation::UpdateSelections {
1736 selections,
1737 line_mode,
1738 lamport_timestamp,
1739 cursor_shape,
1740 },
1741 cx,
1742 );
1743 self.non_text_state_update_count += 1;
1744 cx.notify();
1745 }
1746
1747 /// Clears the selections, so that other replicas of the buffer do not see any selections for
1748 /// this replica.
1749 pub fn remove_active_selections(&mut self, cx: &mut ModelContext<Self>) {
1750 if self
1751 .remote_selections
1752 .get(&self.text.replica_id())
1753 .map_or(true, |set| !set.selections.is_empty())
1754 {
1755 self.set_active_selections(Arc::default(), false, Default::default(), cx);
1756 }
1757 }
1758
1759 /// Replaces the buffer's entire text.
1760 pub fn set_text<T>(&mut self, text: T, cx: &mut ModelContext<Self>) -> Option<clock::Lamport>
1761 where
1762 T: Into<Arc<str>>,
1763 {
1764 self.autoindent_requests.clear();
1765 self.edit([(0..self.len(), text)], None, cx)
1766 }
1767
1768 /// Applies the given edits to the buffer. Each edit is specified as a range of text to
1769 /// delete, and a string of text to insert at that location.
1770 ///
1771 /// If an [`AutoindentMode`] is provided, then the buffer will enqueue an auto-indent
1772 /// request for the edited ranges, which will be processed when the buffer finishes
1773 /// parsing.
1774 ///
1775 /// Parsing takes place at the end of a transaction, and may compute synchronously
1776 /// or asynchronously, depending on the changes.
1777 pub fn edit<I, S, T>(
1778 &mut self,
1779 edits_iter: I,
1780 autoindent_mode: Option<AutoindentMode>,
1781 cx: &mut ModelContext<Self>,
1782 ) -> Option<clock::Lamport>
1783 where
1784 I: IntoIterator<Item = (Range<S>, T)>,
1785 S: ToOffset,
1786 T: Into<Arc<str>>,
1787 {
1788 // Skip invalid edits and coalesce contiguous ones.
1789 let mut edits: Vec<(Range<usize>, Arc<str>)> = Vec::new();
1790 for (range, new_text) in edits_iter {
1791 let mut range = range.start.to_offset(self)..range.end.to_offset(self);
1792 if range.start > range.end {
1793 mem::swap(&mut range.start, &mut range.end);
1794 }
1795 let new_text = new_text.into();
1796 if !new_text.is_empty() || !range.is_empty() {
1797 if let Some((prev_range, prev_text)) = edits.last_mut() {
1798 if prev_range.end >= range.start {
1799 prev_range.end = cmp::max(prev_range.end, range.end);
1800 *prev_text = format!("{prev_text}{new_text}").into();
1801 } else {
1802 edits.push((range, new_text));
1803 }
1804 } else {
1805 edits.push((range, new_text));
1806 }
1807 }
1808 }
1809 if edits.is_empty() {
1810 return None;
1811 }
1812
1813 self.start_transaction();
1814 self.pending_autoindent.take();
1815 let autoindent_request = autoindent_mode
1816 .and_then(|mode| self.language.as_ref().map(|_| (self.snapshot(), mode)));
1817
1818 let edit_operation = self.text.edit(edits.iter().cloned());
1819 let edit_id = edit_operation.timestamp();
1820
1821 if let Some((before_edit, mode)) = autoindent_request {
1822 let mut delta = 0isize;
1823 let entries = edits
1824 .into_iter()
1825 .enumerate()
1826 .zip(&edit_operation.as_edit().unwrap().new_text)
1827 .map(|((ix, (range, _)), new_text)| {
1828 let new_text_length = new_text.len();
1829 let old_start = range.start.to_point(&before_edit);
1830 let new_start = (delta + range.start as isize) as usize;
1831 delta += new_text_length as isize - (range.end as isize - range.start as isize);
1832
1833 let mut range_of_insertion_to_indent = 0..new_text_length;
1834 let mut first_line_is_new = false;
1835 let mut original_indent_column = None;
1836
1837 // When inserting an entire line at the beginning of an existing line,
1838 // treat the insertion as new.
1839 if new_text.contains('\n')
1840 && old_start.column <= before_edit.indent_size_for_line(old_start.row).len
1841 {
1842 first_line_is_new = true;
1843 }
1844
1845 // When inserting text starting with a newline, avoid auto-indenting the
1846 // previous line.
1847 if new_text.starts_with('\n') {
1848 range_of_insertion_to_indent.start += 1;
1849 first_line_is_new = true;
1850 }
1851
1852 // Avoid auto-indenting after the insertion.
1853 if let AutoindentMode::Block {
1854 original_indent_columns,
1855 } = &mode
1856 {
1857 original_indent_column =
1858 Some(original_indent_columns.get(ix).copied().unwrap_or_else(|| {
1859 indent_size_for_text(
1860 new_text[range_of_insertion_to_indent.clone()].chars(),
1861 )
1862 .len
1863 }));
1864 if new_text[range_of_insertion_to_indent.clone()].ends_with('\n') {
1865 range_of_insertion_to_indent.end -= 1;
1866 }
1867 }
1868
1869 AutoindentRequestEntry {
1870 first_line_is_new,
1871 original_indent_column,
1872 indent_size: before_edit.language_indent_size_at(range.start, cx),
1873 range: self.anchor_before(new_start + range_of_insertion_to_indent.start)
1874 ..self.anchor_after(new_start + range_of_insertion_to_indent.end),
1875 }
1876 })
1877 .collect();
1878
1879 self.autoindent_requests.push(Arc::new(AutoindentRequest {
1880 before_edit,
1881 entries,
1882 is_block_mode: matches!(mode, AutoindentMode::Block { .. }),
1883 }));
1884 }
1885
1886 self.end_transaction(cx);
1887 self.send_operation(Operation::Buffer(edit_operation), cx);
1888 Some(edit_id)
1889 }
1890
1891 fn did_edit(
1892 &mut self,
1893 old_version: &clock::Global,
1894 was_dirty: bool,
1895 cx: &mut ModelContext<Self>,
1896 ) {
1897 if self.edits_since::<usize>(old_version).next().is_none() {
1898 return;
1899 }
1900
1901 self.reparse(cx);
1902
1903 cx.emit(Event::Edited);
1904 if was_dirty != self.is_dirty() {
1905 cx.emit(Event::DirtyChanged);
1906 }
1907 cx.notify();
1908 }
1909
1910 // Inserts newlines at the given position to create an empty line, returning the start of the new line.
1911 // You can also request the insertion of empty lines above and below the line starting at the returned point.
1912 pub fn insert_empty_line(
1913 &mut self,
1914 position: impl ToPoint,
1915 space_above: bool,
1916 space_below: bool,
1917 cx: &mut ModelContext<Self>,
1918 ) -> Point {
1919 let mut position = position.to_point(self);
1920
1921 self.start_transaction();
1922
1923 self.edit(
1924 [(position..position, "\n")],
1925 Some(AutoindentMode::EachLine),
1926 cx,
1927 );
1928
1929 if position.column > 0 {
1930 position += Point::new(1, 0);
1931 }
1932
1933 if !self.is_line_blank(position.row) {
1934 self.edit(
1935 [(position..position, "\n")],
1936 Some(AutoindentMode::EachLine),
1937 cx,
1938 );
1939 }
1940
1941 if space_above {
1942 if position.row > 0 && !self.is_line_blank(position.row - 1) {
1943 self.edit(
1944 [(position..position, "\n")],
1945 Some(AutoindentMode::EachLine),
1946 cx,
1947 );
1948 position.row += 1;
1949 }
1950 }
1951
1952 if space_below {
1953 if position.row == self.max_point().row || !self.is_line_blank(position.row + 1) {
1954 self.edit(
1955 [(position..position, "\n")],
1956 Some(AutoindentMode::EachLine),
1957 cx,
1958 );
1959 }
1960 }
1961
1962 self.end_transaction(cx);
1963
1964 position
1965 }
1966
1967 /// Applies the given remote operations to the buffer.
1968 pub fn apply_ops<I: IntoIterator<Item = Operation>>(
1969 &mut self,
1970 ops: I,
1971 cx: &mut ModelContext<Self>,
1972 ) -> Result<()> {
1973 self.pending_autoindent.take();
1974 let was_dirty = self.is_dirty();
1975 let old_version = self.version.clone();
1976 let mut deferred_ops = Vec::new();
1977 let buffer_ops = ops
1978 .into_iter()
1979 .filter_map(|op| match op {
1980 Operation::Buffer(op) => Some(op),
1981 _ => {
1982 if self.can_apply_op(&op) {
1983 self.apply_op(op, cx);
1984 } else {
1985 deferred_ops.push(op);
1986 }
1987 None
1988 }
1989 })
1990 .collect::<Vec<_>>();
1991 self.text.apply_ops(buffer_ops)?;
1992 self.deferred_ops.insert(deferred_ops);
1993 self.flush_deferred_ops(cx);
1994 self.did_edit(&old_version, was_dirty, cx);
1995 // Notify independently of whether the buffer was edited as the operations could include a
1996 // selection update.
1997 cx.notify();
1998 Ok(())
1999 }
2000
2001 fn flush_deferred_ops(&mut self, cx: &mut ModelContext<Self>) {
2002 let mut deferred_ops = Vec::new();
2003 for op in self.deferred_ops.drain().iter().cloned() {
2004 if self.can_apply_op(&op) {
2005 self.apply_op(op, cx);
2006 } else {
2007 deferred_ops.push(op);
2008 }
2009 }
2010 self.deferred_ops.insert(deferred_ops);
2011 }
2012
2013 pub fn has_deferred_ops(&self) -> bool {
2014 !self.deferred_ops.is_empty() || self.text.has_deferred_ops()
2015 }
2016
2017 fn can_apply_op(&self, operation: &Operation) -> bool {
2018 match operation {
2019 Operation::Buffer(_) => {
2020 unreachable!("buffer operations should never be applied at this layer")
2021 }
2022 Operation::UpdateDiagnostics {
2023 diagnostics: diagnostic_set,
2024 ..
2025 } => diagnostic_set.iter().all(|diagnostic| {
2026 self.text.can_resolve(&diagnostic.range.start)
2027 && self.text.can_resolve(&diagnostic.range.end)
2028 }),
2029 Operation::UpdateSelections { selections, .. } => selections
2030 .iter()
2031 .all(|s| self.can_resolve(&s.start) && self.can_resolve(&s.end)),
2032 Operation::UpdateCompletionTriggers { .. } => true,
2033 }
2034 }
2035
2036 fn apply_op(&mut self, operation: Operation, cx: &mut ModelContext<Self>) {
2037 match operation {
2038 Operation::Buffer(_) => {
2039 unreachable!("buffer operations should never be applied at this layer")
2040 }
2041 Operation::UpdateDiagnostics {
2042 server_id,
2043 diagnostics: diagnostic_set,
2044 lamport_timestamp,
2045 } => {
2046 let snapshot = self.snapshot();
2047 self.apply_diagnostic_update(
2048 server_id,
2049 DiagnosticSet::from_sorted_entries(diagnostic_set.iter().cloned(), &snapshot),
2050 lamport_timestamp,
2051 cx,
2052 );
2053 }
2054 Operation::UpdateSelections {
2055 selections,
2056 lamport_timestamp,
2057 line_mode,
2058 cursor_shape,
2059 } => {
2060 if let Some(set) = self.remote_selections.get(&lamport_timestamp.replica_id) {
2061 if set.lamport_timestamp > lamport_timestamp {
2062 return;
2063 }
2064 }
2065
2066 self.remote_selections.insert(
2067 lamport_timestamp.replica_id,
2068 SelectionSet {
2069 selections,
2070 lamport_timestamp,
2071 line_mode,
2072 cursor_shape,
2073 },
2074 );
2075 self.text.lamport_clock.observe(lamport_timestamp);
2076 self.non_text_state_update_count += 1;
2077 }
2078 Operation::UpdateCompletionTriggers {
2079 triggers,
2080 lamport_timestamp,
2081 } => {
2082 self.completion_triggers = triggers;
2083 self.text.lamport_clock.observe(lamport_timestamp);
2084 }
2085 }
2086 }
2087
2088 fn apply_diagnostic_update(
2089 &mut self,
2090 server_id: LanguageServerId,
2091 diagnostics: DiagnosticSet,
2092 lamport_timestamp: clock::Lamport,
2093 cx: &mut ModelContext<Self>,
2094 ) {
2095 if lamport_timestamp > self.diagnostics_timestamp {
2096 let ix = self.diagnostics.binary_search_by_key(&server_id, |e| e.0);
2097 if diagnostics.len() == 0 {
2098 if let Ok(ix) = ix {
2099 self.diagnostics.remove(ix);
2100 }
2101 } else {
2102 match ix {
2103 Err(ix) => self.diagnostics.insert(ix, (server_id, diagnostics)),
2104 Ok(ix) => self.diagnostics[ix].1 = diagnostics,
2105 };
2106 }
2107 self.diagnostics_timestamp = lamport_timestamp;
2108 self.non_text_state_update_count += 1;
2109 self.text.lamport_clock.observe(lamport_timestamp);
2110 cx.notify();
2111 cx.emit(Event::DiagnosticsUpdated);
2112 }
2113 }
2114
2115 fn send_operation(&mut self, operation: Operation, cx: &mut ModelContext<Self>) {
2116 cx.emit(Event::Operation(operation));
2117 }
2118
2119 /// Removes the selections for a given peer.
2120 pub fn remove_peer(&mut self, replica_id: ReplicaId, cx: &mut ModelContext<Self>) {
2121 self.remote_selections.remove(&replica_id);
2122 cx.notify();
2123 }
2124
2125 /// Undoes the most recent transaction.
2126 pub fn undo(&mut self, cx: &mut ModelContext<Self>) -> Option<TransactionId> {
2127 let was_dirty = self.is_dirty();
2128 let old_version = self.version.clone();
2129
2130 if let Some((transaction_id, operation)) = self.text.undo() {
2131 self.send_operation(Operation::Buffer(operation), cx);
2132 self.did_edit(&old_version, was_dirty, cx);
2133 Some(transaction_id)
2134 } else {
2135 None
2136 }
2137 }
2138
2139 /// Manually undoes a specific transaction in the buffer's undo history.
2140 pub fn undo_transaction(
2141 &mut self,
2142 transaction_id: TransactionId,
2143 cx: &mut ModelContext<Self>,
2144 ) -> bool {
2145 let was_dirty = self.is_dirty();
2146 let old_version = self.version.clone();
2147 if let Some(operation) = self.text.undo_transaction(transaction_id) {
2148 self.send_operation(Operation::Buffer(operation), cx);
2149 self.did_edit(&old_version, was_dirty, cx);
2150 true
2151 } else {
2152 false
2153 }
2154 }
2155
2156 /// Manually undoes all changes after a given transaction in the buffer's undo history.
2157 pub fn undo_to_transaction(
2158 &mut self,
2159 transaction_id: TransactionId,
2160 cx: &mut ModelContext<Self>,
2161 ) -> bool {
2162 let was_dirty = self.is_dirty();
2163 let old_version = self.version.clone();
2164
2165 let operations = self.text.undo_to_transaction(transaction_id);
2166 let undone = !operations.is_empty();
2167 for operation in operations {
2168 self.send_operation(Operation::Buffer(operation), cx);
2169 }
2170 if undone {
2171 self.did_edit(&old_version, was_dirty, cx)
2172 }
2173 undone
2174 }
2175
2176 /// Manually redoes a specific transaction in the buffer's redo history.
2177 pub fn redo(&mut self, cx: &mut ModelContext<Self>) -> Option<TransactionId> {
2178 let was_dirty = self.is_dirty();
2179 let old_version = self.version.clone();
2180
2181 if let Some((transaction_id, operation)) = self.text.redo() {
2182 self.send_operation(Operation::Buffer(operation), cx);
2183 self.did_edit(&old_version, was_dirty, cx);
2184 Some(transaction_id)
2185 } else {
2186 None
2187 }
2188 }
2189
2190 /// Manually undoes all changes until a given transaction in the buffer's redo history.
2191 pub fn redo_to_transaction(
2192 &mut self,
2193 transaction_id: TransactionId,
2194 cx: &mut ModelContext<Self>,
2195 ) -> bool {
2196 let was_dirty = self.is_dirty();
2197 let old_version = self.version.clone();
2198
2199 let operations = self.text.redo_to_transaction(transaction_id);
2200 let redone = !operations.is_empty();
2201 for operation in operations {
2202 self.send_operation(Operation::Buffer(operation), cx);
2203 }
2204 if redone {
2205 self.did_edit(&old_version, was_dirty, cx)
2206 }
2207 redone
2208 }
2209
2210 /// Override current completion triggers with the user-provided completion triggers.
2211 pub fn set_completion_triggers(&mut self, triggers: Vec<String>, cx: &mut ModelContext<Self>) {
2212 self.completion_triggers.clone_from(&triggers);
2213 self.completion_triggers_timestamp = self.text.lamport_clock.tick();
2214 self.send_operation(
2215 Operation::UpdateCompletionTriggers {
2216 triggers,
2217 lamport_timestamp: self.completion_triggers_timestamp,
2218 },
2219 cx,
2220 );
2221 cx.notify();
2222 }
2223
2224 /// Returns a list of strings which trigger a completion menu for this language.
2225 /// Usually this is driven by LSP server which returns a list of trigger characters for completions.
2226 pub fn completion_triggers(&self) -> &[String] {
2227 &self.completion_triggers
2228 }
2229
2230 /// Call this directly after performing edits to prevent the preview tab
2231 /// from being dismissed by those edits. It causes `should_dismiss_preview`
2232 /// to return false until there are additional edits.
2233 pub fn refresh_preview(&mut self) {
2234 self.preview_version = self.version.clone();
2235 }
2236
2237 /// Whether we should preserve the preview status of a tab containing this buffer.
2238 pub fn preserve_preview(&self) -> bool {
2239 !self.has_edits_since(&self.preview_version)
2240 }
2241}
2242
2243#[doc(hidden)]
2244#[cfg(any(test, feature = "test-support"))]
2245impl Buffer {
2246 pub fn edit_via_marked_text(
2247 &mut self,
2248 marked_string: &str,
2249 autoindent_mode: Option<AutoindentMode>,
2250 cx: &mut ModelContext<Self>,
2251 ) {
2252 let edits = self.edits_for_marked_text(marked_string);
2253 self.edit(edits, autoindent_mode, cx);
2254 }
2255
2256 pub fn set_group_interval(&mut self, group_interval: Duration) {
2257 self.text.set_group_interval(group_interval);
2258 }
2259
2260 pub fn randomly_edit<T>(
2261 &mut self,
2262 rng: &mut T,
2263 old_range_count: usize,
2264 cx: &mut ModelContext<Self>,
2265 ) where
2266 T: rand::Rng,
2267 {
2268 let mut edits: Vec<(Range<usize>, String)> = Vec::new();
2269 let mut last_end = None;
2270 for _ in 0..old_range_count {
2271 if last_end.map_or(false, |last_end| last_end >= self.len()) {
2272 break;
2273 }
2274
2275 let new_start = last_end.map_or(0, |last_end| last_end + 1);
2276 let mut range = self.random_byte_range(new_start, rng);
2277 if rng.gen_bool(0.2) {
2278 mem::swap(&mut range.start, &mut range.end);
2279 }
2280 last_end = Some(range.end);
2281
2282 let new_text_len = rng.gen_range(0..10);
2283 let new_text: String = RandomCharIter::new(&mut *rng).take(new_text_len).collect();
2284
2285 edits.push((range, new_text));
2286 }
2287 log::info!("mutating buffer {} with {:?}", self.replica_id(), edits);
2288 self.edit(edits, None, cx);
2289 }
2290
2291 pub fn randomly_undo_redo(&mut self, rng: &mut impl rand::Rng, cx: &mut ModelContext<Self>) {
2292 let was_dirty = self.is_dirty();
2293 let old_version = self.version.clone();
2294
2295 let ops = self.text.randomly_undo_redo(rng);
2296 if !ops.is_empty() {
2297 for op in ops {
2298 self.send_operation(Operation::Buffer(op), cx);
2299 self.did_edit(&old_version, was_dirty, cx);
2300 }
2301 }
2302 }
2303}
2304
2305impl EventEmitter<Event> for Buffer {}
2306
2307impl Deref for Buffer {
2308 type Target = TextBuffer;
2309
2310 fn deref(&self) -> &Self::Target {
2311 &self.text
2312 }
2313}
2314
2315impl BufferSnapshot {
2316 /// Returns [`IndentSize`] for a given line that respects user settings and /// language preferences.
2317 pub fn indent_size_for_line(&self, row: u32) -> IndentSize {
2318 indent_size_for_line(self, row)
2319 }
2320 /// Returns [`IndentSize`] for a given position that respects user settings
2321 /// and language preferences.
2322 pub fn language_indent_size_at<T: ToOffset>(&self, position: T, cx: &AppContext) -> IndentSize {
2323 let settings = language_settings(self.language_at(position), self.file(), cx);
2324 if settings.hard_tabs {
2325 IndentSize::tab()
2326 } else {
2327 IndentSize::spaces(settings.tab_size.get())
2328 }
2329 }
2330
2331 /// Retrieve the suggested indent size for all of the given rows. The unit of indentation
2332 /// is passed in as `single_indent_size`.
2333 pub fn suggested_indents(
2334 &self,
2335 rows: impl Iterator<Item = u32>,
2336 single_indent_size: IndentSize,
2337 ) -> BTreeMap<u32, IndentSize> {
2338 let mut result = BTreeMap::new();
2339
2340 for row_range in contiguous_ranges(rows, 10) {
2341 let suggestions = match self.suggest_autoindents(row_range.clone()) {
2342 Some(suggestions) => suggestions,
2343 _ => break,
2344 };
2345
2346 for (row, suggestion) in row_range.zip(suggestions) {
2347 let indent_size = if let Some(suggestion) = suggestion {
2348 result
2349 .get(&suggestion.basis_row)
2350 .copied()
2351 .unwrap_or_else(|| self.indent_size_for_line(suggestion.basis_row))
2352 .with_delta(suggestion.delta, single_indent_size)
2353 } else {
2354 self.indent_size_for_line(row)
2355 };
2356
2357 result.insert(row, indent_size);
2358 }
2359 }
2360
2361 result
2362 }
2363
2364 fn suggest_autoindents(
2365 &self,
2366 row_range: Range<u32>,
2367 ) -> Option<impl Iterator<Item = Option<IndentSuggestion>> + '_> {
2368 let config = &self.language.as_ref()?.config;
2369 let prev_non_blank_row = self.prev_non_blank_row(row_range.start);
2370
2371 // Find the suggested indentation ranges based on the syntax tree.
2372 let start = Point::new(prev_non_blank_row.unwrap_or(row_range.start), 0);
2373 let end = Point::new(row_range.end, 0);
2374 let range = (start..end).to_offset(&self.text);
2375 let mut matches = self.syntax.matches(range.clone(), &self.text, |grammar| {
2376 Some(&grammar.indents_config.as_ref()?.query)
2377 });
2378 let indent_configs = matches
2379 .grammars()
2380 .iter()
2381 .map(|grammar| grammar.indents_config.as_ref().unwrap())
2382 .collect::<Vec<_>>();
2383
2384 let mut indent_ranges = Vec::<Range<Point>>::new();
2385 let mut outdent_positions = Vec::<Point>::new();
2386 while let Some(mat) = matches.peek() {
2387 let mut start: Option<Point> = None;
2388 let mut end: Option<Point> = None;
2389
2390 let config = &indent_configs[mat.grammar_index];
2391 for capture in mat.captures {
2392 if capture.index == config.indent_capture_ix {
2393 start.get_or_insert(Point::from_ts_point(capture.node.start_position()));
2394 end.get_or_insert(Point::from_ts_point(capture.node.end_position()));
2395 } else if Some(capture.index) == config.start_capture_ix {
2396 start = Some(Point::from_ts_point(capture.node.end_position()));
2397 } else if Some(capture.index) == config.end_capture_ix {
2398 end = Some(Point::from_ts_point(capture.node.start_position()));
2399 } else if Some(capture.index) == config.outdent_capture_ix {
2400 outdent_positions.push(Point::from_ts_point(capture.node.start_position()));
2401 }
2402 }
2403
2404 matches.advance();
2405 if let Some((start, end)) = start.zip(end) {
2406 if start.row == end.row {
2407 continue;
2408 }
2409
2410 let range = start..end;
2411 match indent_ranges.binary_search_by_key(&range.start, |r| r.start) {
2412 Err(ix) => indent_ranges.insert(ix, range),
2413 Ok(ix) => {
2414 let prev_range = &mut indent_ranges[ix];
2415 prev_range.end = prev_range.end.max(range.end);
2416 }
2417 }
2418 }
2419 }
2420
2421 let mut error_ranges = Vec::<Range<Point>>::new();
2422 let mut matches = self.syntax.matches(range.clone(), &self.text, |grammar| {
2423 Some(&grammar.error_query)
2424 });
2425 while let Some(mat) = matches.peek() {
2426 let node = mat.captures[0].node;
2427 let start = Point::from_ts_point(node.start_position());
2428 let end = Point::from_ts_point(node.end_position());
2429 let range = start..end;
2430 let ix = match error_ranges.binary_search_by_key(&range.start, |r| r.start) {
2431 Ok(ix) | Err(ix) => ix,
2432 };
2433 let mut end_ix = ix;
2434 while let Some(existing_range) = error_ranges.get(end_ix) {
2435 if existing_range.end < end {
2436 end_ix += 1;
2437 } else {
2438 break;
2439 }
2440 }
2441 error_ranges.splice(ix..end_ix, [range]);
2442 matches.advance();
2443 }
2444
2445 outdent_positions.sort();
2446 for outdent_position in outdent_positions {
2447 // find the innermost indent range containing this outdent_position
2448 // set its end to the outdent position
2449 if let Some(range_to_truncate) = indent_ranges
2450 .iter_mut()
2451 .filter(|indent_range| indent_range.contains(&outdent_position))
2452 .last()
2453 {
2454 range_to_truncate.end = outdent_position;
2455 }
2456 }
2457
2458 // Find the suggested indentation increases and decreased based on regexes.
2459 let mut indent_change_rows = Vec::<(u32, Ordering)>::new();
2460 self.for_each_line(
2461 Point::new(prev_non_blank_row.unwrap_or(row_range.start), 0)
2462 ..Point::new(row_range.end, 0),
2463 |row, line| {
2464 if config
2465 .decrease_indent_pattern
2466 .as_ref()
2467 .map_or(false, |regex| regex.is_match(line))
2468 {
2469 indent_change_rows.push((row, Ordering::Less));
2470 }
2471 if config
2472 .increase_indent_pattern
2473 .as_ref()
2474 .map_or(false, |regex| regex.is_match(line))
2475 {
2476 indent_change_rows.push((row + 1, Ordering::Greater));
2477 }
2478 },
2479 );
2480
2481 let mut indent_changes = indent_change_rows.into_iter().peekable();
2482 let mut prev_row = if config.auto_indent_using_last_non_empty_line {
2483 prev_non_blank_row.unwrap_or(0)
2484 } else {
2485 row_range.start.saturating_sub(1)
2486 };
2487 let mut prev_row_start = Point::new(prev_row, self.indent_size_for_line(prev_row).len);
2488 Some(row_range.map(move |row| {
2489 let row_start = Point::new(row, self.indent_size_for_line(row).len);
2490
2491 let mut indent_from_prev_row = false;
2492 let mut outdent_from_prev_row = false;
2493 let mut outdent_to_row = u32::MAX;
2494
2495 while let Some((indent_row, delta)) = indent_changes.peek() {
2496 match indent_row.cmp(&row) {
2497 Ordering::Equal => match delta {
2498 Ordering::Less => outdent_from_prev_row = true,
2499 Ordering::Greater => indent_from_prev_row = true,
2500 _ => {}
2501 },
2502
2503 Ordering::Greater => break,
2504 Ordering::Less => {}
2505 }
2506
2507 indent_changes.next();
2508 }
2509
2510 for range in &indent_ranges {
2511 if range.start.row >= row {
2512 break;
2513 }
2514 if range.start.row == prev_row && range.end > row_start {
2515 indent_from_prev_row = true;
2516 }
2517 if range.end > prev_row_start && range.end <= row_start {
2518 outdent_to_row = outdent_to_row.min(range.start.row);
2519 }
2520 }
2521
2522 let within_error = error_ranges
2523 .iter()
2524 .any(|e| e.start.row < row && e.end > row_start);
2525
2526 let suggestion = if outdent_to_row == prev_row
2527 || (outdent_from_prev_row && indent_from_prev_row)
2528 {
2529 Some(IndentSuggestion {
2530 basis_row: prev_row,
2531 delta: Ordering::Equal,
2532 within_error,
2533 })
2534 } else if indent_from_prev_row {
2535 Some(IndentSuggestion {
2536 basis_row: prev_row,
2537 delta: Ordering::Greater,
2538 within_error,
2539 })
2540 } else if outdent_to_row < prev_row {
2541 Some(IndentSuggestion {
2542 basis_row: outdent_to_row,
2543 delta: Ordering::Equal,
2544 within_error,
2545 })
2546 } else if outdent_from_prev_row {
2547 Some(IndentSuggestion {
2548 basis_row: prev_row,
2549 delta: Ordering::Less,
2550 within_error,
2551 })
2552 } else if config.auto_indent_using_last_non_empty_line || !self.is_line_blank(prev_row)
2553 {
2554 Some(IndentSuggestion {
2555 basis_row: prev_row,
2556 delta: Ordering::Equal,
2557 within_error,
2558 })
2559 } else {
2560 None
2561 };
2562
2563 prev_row = row;
2564 prev_row_start = row_start;
2565 suggestion
2566 }))
2567 }
2568
2569 fn prev_non_blank_row(&self, mut row: u32) -> Option<u32> {
2570 while row > 0 {
2571 row -= 1;
2572 if !self.is_line_blank(row) {
2573 return Some(row);
2574 }
2575 }
2576 None
2577 }
2578
2579 fn get_highlights(&self, range: Range<usize>) -> (SyntaxMapCaptures, Vec<HighlightMap>) {
2580 let captures = self.syntax.captures(range, &self.text, |grammar| {
2581 grammar.highlights_query.as_ref()
2582 });
2583 let highlight_maps = captures
2584 .grammars()
2585 .into_iter()
2586 .map(|grammar| grammar.highlight_map())
2587 .collect();
2588 (captures, highlight_maps)
2589 }
2590 /// Iterates over chunks of text in the given range of the buffer. Text is chunked
2591 /// in an arbitrary way due to being stored in a [`Rope`](text::Rope). The text is also
2592 /// returned in chunks where each chunk has a single syntax highlighting style and
2593 /// diagnostic status.
2594 pub fn chunks<T: ToOffset>(&self, range: Range<T>, language_aware: bool) -> BufferChunks {
2595 let range = range.start.to_offset(self)..range.end.to_offset(self);
2596
2597 let mut syntax = None;
2598 if language_aware {
2599 syntax = Some(self.get_highlights(range.clone()));
2600 }
2601 // We want to look at diagnostic spans only when iterating over language-annotated chunks.
2602 let diagnostics = language_aware;
2603 BufferChunks::new(self.text.as_rope(), range, syntax, diagnostics, Some(self))
2604 }
2605
2606 /// Invokes the given callback for each line of text in the given range of the buffer.
2607 /// Uses callback to avoid allocating a string for each line.
2608 fn for_each_line(&self, range: Range<Point>, mut callback: impl FnMut(u32, &str)) {
2609 let mut line = String::new();
2610 let mut row = range.start.row;
2611 for chunk in self
2612 .as_rope()
2613 .chunks_in_range(range.to_offset(self))
2614 .chain(["\n"])
2615 {
2616 for (newline_ix, text) in chunk.split('\n').enumerate() {
2617 if newline_ix > 0 {
2618 callback(row, &line);
2619 row += 1;
2620 line.clear();
2621 }
2622 line.push_str(text);
2623 }
2624 }
2625 }
2626
2627 /// Iterates over every [`SyntaxLayer`] in the buffer.
2628 pub fn syntax_layers(&self) -> impl Iterator<Item = SyntaxLayer> + '_ {
2629 self.syntax
2630 .layers_for_range(0..self.len(), &self.text, true)
2631 }
2632
2633 pub fn syntax_layer_at<D: ToOffset>(&self, position: D) -> Option<SyntaxLayer> {
2634 let offset = position.to_offset(self);
2635 self.syntax
2636 .layers_for_range(offset..offset, &self.text, false)
2637 .filter(|l| l.node().end_byte() > offset)
2638 .last()
2639 }
2640
2641 /// Returns the main [Language]
2642 pub fn language(&self) -> Option<&Arc<Language>> {
2643 self.language.as_ref()
2644 }
2645
2646 /// Returns the [Language] at the given location.
2647 pub fn language_at<D: ToOffset>(&self, position: D) -> Option<&Arc<Language>> {
2648 self.syntax_layer_at(position)
2649 .map(|info| info.language)
2650 .or(self.language.as_ref())
2651 }
2652
2653 /// Returns the settings for the language at the given location.
2654 pub fn settings_at<'a, D: ToOffset>(
2655 &self,
2656 position: D,
2657 cx: &'a AppContext,
2658 ) -> &'a LanguageSettings {
2659 language_settings(self.language_at(position), self.file.as_ref(), cx)
2660 }
2661
2662 pub fn char_classifier_at<T: ToOffset>(&self, point: T) -> CharClassifier {
2663 CharClassifier::new(self.language_scope_at(point))
2664 }
2665
2666 /// Returns the [LanguageScope] at the given location.
2667 pub fn language_scope_at<D: ToOffset>(&self, position: D) -> Option<LanguageScope> {
2668 let offset = position.to_offset(self);
2669 let mut scope = None;
2670 let mut smallest_range: Option<Range<usize>> = None;
2671
2672 // Use the layer that has the smallest node intersecting the given point.
2673 for layer in self
2674 .syntax
2675 .layers_for_range(offset..offset, &self.text, false)
2676 {
2677 let mut cursor = layer.node().walk();
2678
2679 let mut range = None;
2680 loop {
2681 let child_range = cursor.node().byte_range();
2682 if !child_range.to_inclusive().contains(&offset) {
2683 break;
2684 }
2685
2686 range = Some(child_range);
2687 if cursor.goto_first_child_for_byte(offset).is_none() {
2688 break;
2689 }
2690 }
2691
2692 if let Some(range) = range {
2693 if smallest_range
2694 .as_ref()
2695 .map_or(true, |smallest_range| range.len() < smallest_range.len())
2696 {
2697 smallest_range = Some(range);
2698 scope = Some(LanguageScope {
2699 language: layer.language.clone(),
2700 override_id: layer.override_id(offset, &self.text),
2701 });
2702 }
2703 }
2704 }
2705
2706 scope.or_else(|| {
2707 self.language.clone().map(|language| LanguageScope {
2708 language,
2709 override_id: None,
2710 })
2711 })
2712 }
2713
2714 /// Returns a tuple of the range and character kind of the word
2715 /// surrounding the given position.
2716 pub fn surrounding_word<T: ToOffset>(&self, start: T) -> (Range<usize>, Option<CharKind>) {
2717 let mut start = start.to_offset(self);
2718 let mut end = start;
2719 let mut next_chars = self.chars_at(start).peekable();
2720 let mut prev_chars = self.reversed_chars_at(start).peekable();
2721
2722 let classifier = self.char_classifier_at(start);
2723 let word_kind = cmp::max(
2724 prev_chars.peek().copied().map(|c| classifier.kind(c)),
2725 next_chars.peek().copied().map(|c| classifier.kind(c)),
2726 );
2727
2728 for ch in prev_chars {
2729 if Some(classifier.kind(ch)) == word_kind && ch != '\n' {
2730 start -= ch.len_utf8();
2731 } else {
2732 break;
2733 }
2734 }
2735
2736 for ch in next_chars {
2737 if Some(classifier.kind(ch)) == word_kind && ch != '\n' {
2738 end += ch.len_utf8();
2739 } else {
2740 break;
2741 }
2742 }
2743
2744 (start..end, word_kind)
2745 }
2746
2747 /// Returns the range for the closes syntax node enclosing the given range.
2748 pub fn range_for_syntax_ancestor<T: ToOffset>(&self, range: Range<T>) -> Option<Range<usize>> {
2749 let range = range.start.to_offset(self)..range.end.to_offset(self);
2750 let mut result: Option<Range<usize>> = None;
2751 'outer: for layer in self
2752 .syntax
2753 .layers_for_range(range.clone(), &self.text, true)
2754 {
2755 let mut cursor = layer.node().walk();
2756
2757 // Descend to the first leaf that touches the start of the range,
2758 // and if the range is non-empty, extends beyond the start.
2759 while cursor.goto_first_child_for_byte(range.start).is_some() {
2760 if !range.is_empty() && cursor.node().end_byte() == range.start {
2761 cursor.goto_next_sibling();
2762 }
2763 }
2764
2765 // Ascend to the smallest ancestor that strictly contains the range.
2766 loop {
2767 let node_range = cursor.node().byte_range();
2768 if node_range.start <= range.start
2769 && node_range.end >= range.end
2770 && node_range.len() > range.len()
2771 {
2772 break;
2773 }
2774 if !cursor.goto_parent() {
2775 continue 'outer;
2776 }
2777 }
2778
2779 let left_node = cursor.node();
2780 let mut layer_result = left_node.byte_range();
2781
2782 // For an empty range, try to find another node immediately to the right of the range.
2783 if left_node.end_byte() == range.start {
2784 let mut right_node = None;
2785 while !cursor.goto_next_sibling() {
2786 if !cursor.goto_parent() {
2787 break;
2788 }
2789 }
2790
2791 while cursor.node().start_byte() == range.start {
2792 right_node = Some(cursor.node());
2793 if !cursor.goto_first_child() {
2794 break;
2795 }
2796 }
2797
2798 // If there is a candidate node on both sides of the (empty) range, then
2799 // decide between the two by favoring a named node over an anonymous token.
2800 // If both nodes are the same in that regard, favor the right one.
2801 if let Some(right_node) = right_node {
2802 if right_node.is_named() || !left_node.is_named() {
2803 layer_result = right_node.byte_range();
2804 }
2805 }
2806 }
2807
2808 if let Some(previous_result) = &result {
2809 if previous_result.len() < layer_result.len() {
2810 continue;
2811 }
2812 }
2813 result = Some(layer_result);
2814 }
2815
2816 result
2817 }
2818
2819 /// Returns the outline for the buffer.
2820 ///
2821 /// This method allows passing an optional [SyntaxTheme] to
2822 /// syntax-highlight the returned symbols.
2823 pub fn outline(&self, theme: Option<&SyntaxTheme>) -> Option<Outline<Anchor>> {
2824 self.outline_items_containing(0..self.len(), true, theme)
2825 .map(Outline::new)
2826 }
2827
2828 /// Returns all the symbols that contain the given position.
2829 ///
2830 /// This method allows passing an optional [SyntaxTheme] to
2831 /// syntax-highlight the returned symbols.
2832 pub fn symbols_containing<T: ToOffset>(
2833 &self,
2834 position: T,
2835 theme: Option<&SyntaxTheme>,
2836 ) -> Option<Vec<OutlineItem<Anchor>>> {
2837 let position = position.to_offset(self);
2838 let mut items = self.outline_items_containing(
2839 position.saturating_sub(1)..self.len().min(position + 1),
2840 false,
2841 theme,
2842 )?;
2843 let mut prev_depth = None;
2844 items.retain(|item| {
2845 let result = prev_depth.map_or(true, |prev_depth| item.depth > prev_depth);
2846 prev_depth = Some(item.depth);
2847 result
2848 });
2849 Some(items)
2850 }
2851
2852 pub fn outline_items_containing<T: ToOffset>(
2853 &self,
2854 range: Range<T>,
2855 include_extra_context: bool,
2856 theme: Option<&SyntaxTheme>,
2857 ) -> Option<Vec<OutlineItem<Anchor>>> {
2858 let range = range.to_offset(self);
2859 let mut matches = self.syntax.matches(range.clone(), &self.text, |grammar| {
2860 grammar.outline_config.as_ref().map(|c| &c.query)
2861 });
2862 let configs = matches
2863 .grammars()
2864 .iter()
2865 .map(|g| g.outline_config.as_ref().unwrap())
2866 .collect::<Vec<_>>();
2867
2868 let mut items = Vec::new();
2869 let mut annotation_row_ranges: Vec<Range<u32>> = Vec::new();
2870 while let Some(mat) = matches.peek() {
2871 let config = &configs[mat.grammar_index];
2872 if let Some(item) =
2873 self.next_outline_item(config, &mat, &range, include_extra_context, theme)
2874 {
2875 items.push(item);
2876 } else if let Some(capture) = mat
2877 .captures
2878 .iter()
2879 .find(|capture| Some(capture.index) == config.annotation_capture_ix)
2880 {
2881 let capture_range = capture.node.start_position()..capture.node.end_position();
2882 let mut capture_row_range =
2883 capture_range.start.row as u32..capture_range.end.row as u32;
2884 if capture_range.end.row > capture_range.start.row && capture_range.end.column == 0
2885 {
2886 capture_row_range.end -= 1;
2887 }
2888 if let Some(last_row_range) = annotation_row_ranges.last_mut() {
2889 if last_row_range.end >= capture_row_range.start.saturating_sub(1) {
2890 last_row_range.end = capture_row_range.end;
2891 } else {
2892 annotation_row_ranges.push(capture_row_range);
2893 }
2894 } else {
2895 annotation_row_ranges.push(capture_row_range);
2896 }
2897 }
2898 matches.advance();
2899 }
2900
2901 items.sort_by_key(|item| (item.range.start, Reverse(item.range.end)));
2902
2903 // Assign depths based on containment relationships and convert to anchors.
2904 let mut item_ends_stack = Vec::<Point>::new();
2905 let mut anchor_items = Vec::new();
2906 let mut annotation_row_ranges = annotation_row_ranges.into_iter().peekable();
2907 for item in items {
2908 while let Some(last_end) = item_ends_stack.last().copied() {
2909 if last_end < item.range.end {
2910 item_ends_stack.pop();
2911 } else {
2912 break;
2913 }
2914 }
2915
2916 let mut annotation_row_range = None;
2917 while let Some(next_annotation_row_range) = annotation_row_ranges.peek() {
2918 let row_preceding_item = item.range.start.row.saturating_sub(1);
2919 if next_annotation_row_range.end < row_preceding_item {
2920 annotation_row_ranges.next();
2921 } else {
2922 if next_annotation_row_range.end == row_preceding_item {
2923 annotation_row_range = Some(next_annotation_row_range.clone());
2924 annotation_row_ranges.next();
2925 }
2926 break;
2927 }
2928 }
2929
2930 anchor_items.push(OutlineItem {
2931 depth: item_ends_stack.len(),
2932 range: self.anchor_after(item.range.start)..self.anchor_before(item.range.end),
2933 text: item.text,
2934 highlight_ranges: item.highlight_ranges,
2935 name_ranges: item.name_ranges,
2936 body_range: item.body_range.map(|body_range| {
2937 self.anchor_after(body_range.start)..self.anchor_before(body_range.end)
2938 }),
2939 annotation_range: annotation_row_range.map(|annotation_range| {
2940 self.anchor_after(Point::new(annotation_range.start, 0))
2941 ..self.anchor_before(Point::new(
2942 annotation_range.end,
2943 self.line_len(annotation_range.end),
2944 ))
2945 }),
2946 });
2947 item_ends_stack.push(item.range.end);
2948 }
2949
2950 Some(anchor_items)
2951 }
2952
2953 fn next_outline_item(
2954 &self,
2955 config: &OutlineConfig,
2956 mat: &SyntaxMapMatch,
2957 range: &Range<usize>,
2958 include_extra_context: bool,
2959 theme: Option<&SyntaxTheme>,
2960 ) -> Option<OutlineItem<Point>> {
2961 let item_node = mat.captures.iter().find_map(|cap| {
2962 if cap.index == config.item_capture_ix {
2963 Some(cap.node)
2964 } else {
2965 None
2966 }
2967 })?;
2968
2969 let item_byte_range = item_node.byte_range();
2970 if item_byte_range.end < range.start || item_byte_range.start > range.end {
2971 return None;
2972 }
2973 let item_point_range = Point::from_ts_point(item_node.start_position())
2974 ..Point::from_ts_point(item_node.end_position());
2975
2976 let mut open_point = None;
2977 let mut close_point = None;
2978 let mut buffer_ranges = Vec::new();
2979 for capture in mat.captures {
2980 let node_is_name;
2981 if capture.index == config.name_capture_ix {
2982 node_is_name = true;
2983 } else if Some(capture.index) == config.context_capture_ix
2984 || (Some(capture.index) == config.extra_context_capture_ix && include_extra_context)
2985 {
2986 node_is_name = false;
2987 } else {
2988 if Some(capture.index) == config.open_capture_ix {
2989 open_point = Some(Point::from_ts_point(capture.node.end_position()));
2990 } else if Some(capture.index) == config.close_capture_ix {
2991 close_point = Some(Point::from_ts_point(capture.node.start_position()));
2992 }
2993
2994 continue;
2995 }
2996
2997 let mut range = capture.node.start_byte()..capture.node.end_byte();
2998 let start = capture.node.start_position();
2999 if capture.node.end_position().row > start.row {
3000 range.end = range.start + self.line_len(start.row as u32) as usize - start.column;
3001 }
3002
3003 if !range.is_empty() {
3004 buffer_ranges.push((range, node_is_name));
3005 }
3006 }
3007 if buffer_ranges.is_empty() {
3008 return None;
3009 }
3010 let mut text = String::new();
3011 let mut highlight_ranges = Vec::new();
3012 let mut name_ranges = Vec::new();
3013 let mut chunks = self.chunks(
3014 buffer_ranges.first().unwrap().0.start..buffer_ranges.last().unwrap().0.end,
3015 true,
3016 );
3017 let mut last_buffer_range_end = 0;
3018 for (buffer_range, is_name) in buffer_ranges {
3019 if !text.is_empty() && buffer_range.start > last_buffer_range_end {
3020 text.push(' ');
3021 }
3022 last_buffer_range_end = buffer_range.end;
3023 if is_name {
3024 let mut start = text.len();
3025 let end = start + buffer_range.len();
3026
3027 // When multiple names are captured, then the matcheable text
3028 // includes the whitespace in between the names.
3029 if !name_ranges.is_empty() {
3030 start -= 1;
3031 }
3032
3033 name_ranges.push(start..end);
3034 }
3035
3036 let mut offset = buffer_range.start;
3037 chunks.seek(buffer_range.clone());
3038 for mut chunk in chunks.by_ref() {
3039 if chunk.text.len() > buffer_range.end - offset {
3040 chunk.text = &chunk.text[0..(buffer_range.end - offset)];
3041 offset = buffer_range.end;
3042 } else {
3043 offset += chunk.text.len();
3044 }
3045 let style = chunk
3046 .syntax_highlight_id
3047 .zip(theme)
3048 .and_then(|(highlight, theme)| highlight.style(theme));
3049 if let Some(style) = style {
3050 let start = text.len();
3051 let end = start + chunk.text.len();
3052 highlight_ranges.push((start..end, style));
3053 }
3054 text.push_str(chunk.text);
3055 if offset >= buffer_range.end {
3056 break;
3057 }
3058 }
3059 }
3060
3061 Some(OutlineItem {
3062 depth: 0, // We'll calculate the depth later
3063 range: item_point_range,
3064 text,
3065 highlight_ranges,
3066 name_ranges,
3067 body_range: open_point.zip(close_point).map(|(start, end)| start..end),
3068 annotation_range: None,
3069 })
3070 }
3071
3072 /// For each grammar in the language, runs the provided
3073 /// [tree_sitter::Query] against the given range.
3074 pub fn matches(
3075 &self,
3076 range: Range<usize>,
3077 query: fn(&Grammar) -> Option<&tree_sitter::Query>,
3078 ) -> SyntaxMapMatches {
3079 self.syntax.matches(range, self, query)
3080 }
3081
3082 /// Returns bracket range pairs overlapping or adjacent to `range`
3083 pub fn bracket_ranges<T: ToOffset>(
3084 &self,
3085 range: Range<T>,
3086 ) -> impl Iterator<Item = (Range<usize>, Range<usize>)> + '_ {
3087 // Find bracket pairs that *inclusively* contain the given range.
3088 let range = range.start.to_offset(self).saturating_sub(1)
3089 ..self.len().min(range.end.to_offset(self) + 1);
3090
3091 let mut matches = self.syntax.matches(range.clone(), &self.text, |grammar| {
3092 grammar.brackets_config.as_ref().map(|c| &c.query)
3093 });
3094 let configs = matches
3095 .grammars()
3096 .iter()
3097 .map(|grammar| grammar.brackets_config.as_ref().unwrap())
3098 .collect::<Vec<_>>();
3099
3100 iter::from_fn(move || {
3101 while let Some(mat) = matches.peek() {
3102 let mut open = None;
3103 let mut close = None;
3104 let config = &configs[mat.grammar_index];
3105 for capture in mat.captures {
3106 if capture.index == config.open_capture_ix {
3107 open = Some(capture.node.byte_range());
3108 } else if capture.index == config.close_capture_ix {
3109 close = Some(capture.node.byte_range());
3110 }
3111 }
3112
3113 matches.advance();
3114
3115 let Some((open, close)) = open.zip(close) else {
3116 continue;
3117 };
3118
3119 let bracket_range = open.start..=close.end;
3120 if !bracket_range.overlaps(&range) {
3121 continue;
3122 }
3123
3124 return Some((open, close));
3125 }
3126 None
3127 })
3128 }
3129
3130 /// Returns enclosing bracket ranges containing the given range
3131 pub fn enclosing_bracket_ranges<T: ToOffset>(
3132 &self,
3133 range: Range<T>,
3134 ) -> impl Iterator<Item = (Range<usize>, Range<usize>)> + '_ {
3135 let range = range.start.to_offset(self)..range.end.to_offset(self);
3136
3137 self.bracket_ranges(range.clone())
3138 .filter(move |(open, close)| open.start <= range.start && close.end >= range.end)
3139 }
3140
3141 /// Returns the smallest enclosing bracket ranges containing the given range or None if no brackets contain range
3142 ///
3143 /// Can optionally pass a range_filter to filter the ranges of brackets to consider
3144 pub fn innermost_enclosing_bracket_ranges<T: ToOffset>(
3145 &self,
3146 range: Range<T>,
3147 range_filter: Option<&dyn Fn(Range<usize>, Range<usize>) -> bool>,
3148 ) -> Option<(Range<usize>, Range<usize>)> {
3149 let range = range.start.to_offset(self)..range.end.to_offset(self);
3150
3151 // Get the ranges of the innermost pair of brackets.
3152 let mut result: Option<(Range<usize>, Range<usize>)> = None;
3153
3154 for (open, close) in self.enclosing_bracket_ranges(range.clone()) {
3155 if let Some(range_filter) = range_filter {
3156 if !range_filter(open.clone(), close.clone()) {
3157 continue;
3158 }
3159 }
3160
3161 let len = close.end - open.start;
3162
3163 if let Some((existing_open, existing_close)) = &result {
3164 let existing_len = existing_close.end - existing_open.start;
3165 if len > existing_len {
3166 continue;
3167 }
3168 }
3169
3170 result = Some((open, close));
3171 }
3172
3173 result
3174 }
3175
3176 /// Returns anchor ranges for any matches of the redaction query.
3177 /// The buffer can be associated with multiple languages, and the redaction query associated with each
3178 /// will be run on the relevant section of the buffer.
3179 pub fn redacted_ranges<T: ToOffset>(
3180 &self,
3181 range: Range<T>,
3182 ) -> impl Iterator<Item = Range<usize>> + '_ {
3183 let offset_range = range.start.to_offset(self)..range.end.to_offset(self);
3184 let mut syntax_matches = self.syntax.matches(offset_range, self, |grammar| {
3185 grammar
3186 .redactions_config
3187 .as_ref()
3188 .map(|config| &config.query)
3189 });
3190
3191 let configs = syntax_matches
3192 .grammars()
3193 .iter()
3194 .map(|grammar| grammar.redactions_config.as_ref())
3195 .collect::<Vec<_>>();
3196
3197 iter::from_fn(move || {
3198 let redacted_range = syntax_matches
3199 .peek()
3200 .and_then(|mat| {
3201 configs[mat.grammar_index].and_then(|config| {
3202 mat.captures
3203 .iter()
3204 .find(|capture| capture.index == config.redaction_capture_ix)
3205 })
3206 })
3207 .map(|mat| mat.node.byte_range());
3208 syntax_matches.advance();
3209 redacted_range
3210 })
3211 }
3212
3213 pub fn injections_intersecting_range<T: ToOffset>(
3214 &self,
3215 range: Range<T>,
3216 ) -> impl Iterator<Item = (Range<usize>, &Arc<Language>)> + '_ {
3217 let offset_range = range.start.to_offset(self)..range.end.to_offset(self);
3218
3219 let mut syntax_matches = self.syntax.matches(offset_range, self, |grammar| {
3220 grammar
3221 .injection_config
3222 .as_ref()
3223 .map(|config| &config.query)
3224 });
3225
3226 let configs = syntax_matches
3227 .grammars()
3228 .iter()
3229 .map(|grammar| grammar.injection_config.as_ref())
3230 .collect::<Vec<_>>();
3231
3232 iter::from_fn(move || {
3233 let ranges = syntax_matches.peek().and_then(|mat| {
3234 let config = &configs[mat.grammar_index]?;
3235 let content_capture_range = mat.captures.iter().find_map(|capture| {
3236 if capture.index == config.content_capture_ix {
3237 Some(capture.node.byte_range())
3238 } else {
3239 None
3240 }
3241 })?;
3242 let language = self.language_at(content_capture_range.start)?;
3243 Some((content_capture_range, language))
3244 });
3245 syntax_matches.advance();
3246 ranges
3247 })
3248 }
3249
3250 pub fn runnable_ranges(
3251 &self,
3252 range: Range<Anchor>,
3253 ) -> impl Iterator<Item = RunnableRange> + '_ {
3254 let offset_range = range.start.to_offset(self)..range.end.to_offset(self);
3255
3256 let mut syntax_matches = self.syntax.matches(offset_range, self, |grammar| {
3257 grammar.runnable_config.as_ref().map(|config| &config.query)
3258 });
3259
3260 let test_configs = syntax_matches
3261 .grammars()
3262 .iter()
3263 .map(|grammar| grammar.runnable_config.as_ref())
3264 .collect::<Vec<_>>();
3265
3266 iter::from_fn(move || loop {
3267 let mat = syntax_matches.peek()?;
3268
3269 let test_range = test_configs[mat.grammar_index].and_then(|test_configs| {
3270 let mut run_range = None;
3271 let full_range = mat.captures.iter().fold(
3272 Range {
3273 start: usize::MAX,
3274 end: 0,
3275 },
3276 |mut acc, next| {
3277 let byte_range = next.node.byte_range();
3278 if acc.start > byte_range.start {
3279 acc.start = byte_range.start;
3280 }
3281 if acc.end < byte_range.end {
3282 acc.end = byte_range.end;
3283 }
3284 acc
3285 },
3286 );
3287 if full_range.start > full_range.end {
3288 // We did not find a full spanning range of this match.
3289 return None;
3290 }
3291 let extra_captures: SmallVec<[_; 1]> =
3292 SmallVec::from_iter(mat.captures.iter().filter_map(|capture| {
3293 test_configs
3294 .extra_captures
3295 .get(capture.index as usize)
3296 .cloned()
3297 .and_then(|tag_name| match tag_name {
3298 RunnableCapture::Named(name) => {
3299 Some((capture.node.byte_range(), name))
3300 }
3301 RunnableCapture::Run => {
3302 let _ = run_range.insert(capture.node.byte_range());
3303 None
3304 }
3305 })
3306 }));
3307 let run_range = run_range?;
3308 let tags = test_configs
3309 .query
3310 .property_settings(mat.pattern_index)
3311 .iter()
3312 .filter_map(|property| {
3313 if *property.key == *"tag" {
3314 property
3315 .value
3316 .as_ref()
3317 .map(|value| RunnableTag(value.to_string().into()))
3318 } else {
3319 None
3320 }
3321 })
3322 .collect();
3323 let extra_captures = extra_captures
3324 .into_iter()
3325 .map(|(range, name)| {
3326 (
3327 name.to_string(),
3328 self.text_for_range(range.clone()).collect::<String>(),
3329 )
3330 })
3331 .collect();
3332 // All tags should have the same range.
3333 Some(RunnableRange {
3334 run_range,
3335 full_range,
3336 runnable: Runnable {
3337 tags,
3338 language: mat.language,
3339 buffer: self.remote_id(),
3340 },
3341 extra_captures,
3342 buffer_id: self.remote_id(),
3343 })
3344 });
3345
3346 syntax_matches.advance();
3347 if test_range.is_some() {
3348 // It's fine for us to short-circuit on .peek()? returning None. We don't want to return None from this iter if we
3349 // had a capture that did not contain a run marker, hence we'll just loop around for the next capture.
3350 return test_range;
3351 }
3352 })
3353 }
3354
3355 pub fn indent_guides_in_range(
3356 &self,
3357 range: Range<Anchor>,
3358 ignore_disabled_for_language: bool,
3359 cx: &AppContext,
3360 ) -> Vec<IndentGuide> {
3361 let language_settings = language_settings(self.language(), self.file.as_ref(), cx);
3362 let settings = language_settings.indent_guides;
3363 if !ignore_disabled_for_language && !settings.enabled {
3364 return Vec::new();
3365 }
3366 let tab_size = language_settings.tab_size.get() as u32;
3367
3368 let start_row = range.start.to_point(self).row;
3369 let end_row = range.end.to_point(self).row;
3370 let row_range = start_row..end_row + 1;
3371
3372 let mut row_indents = self.line_indents_in_row_range(row_range.clone());
3373
3374 let mut result_vec = Vec::new();
3375 let mut indent_stack = SmallVec::<[IndentGuide; 8]>::new();
3376
3377 while let Some((first_row, mut line_indent)) = row_indents.next() {
3378 let current_depth = indent_stack.len() as u32;
3379
3380 // When encountering empty, continue until found useful line indent
3381 // then add to the indent stack with the depth found
3382 let mut found_indent = false;
3383 let mut last_row = first_row;
3384 if line_indent.is_line_empty() {
3385 let mut trailing_row = end_row;
3386 while !found_indent {
3387 let (target_row, new_line_indent) =
3388 if let Some(display_row) = row_indents.next() {
3389 display_row
3390 } else {
3391 // This means we reached the end of the given range and found empty lines at the end.
3392 // We need to traverse further until we find a non-empty line to know if we need to add
3393 // an indent guide for the last visible indent.
3394 trailing_row += 1;
3395
3396 const TRAILING_ROW_SEARCH_LIMIT: u32 = 25;
3397 if trailing_row > self.max_point().row
3398 || trailing_row > end_row + TRAILING_ROW_SEARCH_LIMIT
3399 {
3400 break;
3401 }
3402 let new_line_indent = self.line_indent_for_row(trailing_row);
3403 (trailing_row, new_line_indent)
3404 };
3405
3406 if new_line_indent.is_line_empty() {
3407 continue;
3408 }
3409 last_row = target_row.min(end_row);
3410 line_indent = new_line_indent;
3411 found_indent = true;
3412 break;
3413 }
3414 } else {
3415 found_indent = true
3416 }
3417
3418 let depth = if found_indent {
3419 line_indent.len(tab_size) / tab_size
3420 + ((line_indent.len(tab_size) % tab_size) > 0) as u32
3421 } else {
3422 current_depth
3423 };
3424
3425 if depth < current_depth {
3426 for _ in 0..(current_depth - depth) {
3427 let mut indent = indent_stack.pop().unwrap();
3428 if last_row != first_row {
3429 // In this case, we landed on an empty row, had to seek forward,
3430 // and discovered that the indent we where on is ending.
3431 // This means that the last display row must
3432 // be on line that ends this indent range, so we
3433 // should display the range up to the first non-empty line
3434 indent.end_row = first_row.saturating_sub(1);
3435 }
3436
3437 result_vec.push(indent)
3438 }
3439 } else if depth > current_depth {
3440 for next_depth in current_depth..depth {
3441 indent_stack.push(IndentGuide {
3442 buffer_id: self.remote_id(),
3443 start_row: first_row,
3444 end_row: last_row,
3445 depth: next_depth,
3446 tab_size,
3447 settings,
3448 });
3449 }
3450 }
3451
3452 for indent in indent_stack.iter_mut() {
3453 indent.end_row = last_row;
3454 }
3455 }
3456
3457 result_vec.extend(indent_stack);
3458
3459 result_vec
3460 }
3461
3462 pub async fn enclosing_indent(
3463 &self,
3464 mut buffer_row: BufferRow,
3465 ) -> Option<(Range<BufferRow>, LineIndent)> {
3466 let max_row = self.max_point().row;
3467 if buffer_row >= max_row {
3468 return None;
3469 }
3470
3471 let mut target_indent = self.line_indent_for_row(buffer_row);
3472
3473 // If the current row is at the start of an indented block, we want to return this
3474 // block as the enclosing indent.
3475 if !target_indent.is_line_empty() && buffer_row < max_row {
3476 let next_line_indent = self.line_indent_for_row(buffer_row + 1);
3477 if !next_line_indent.is_line_empty()
3478 && target_indent.raw_len() < next_line_indent.raw_len()
3479 {
3480 target_indent = next_line_indent;
3481 buffer_row += 1;
3482 }
3483 }
3484
3485 const SEARCH_ROW_LIMIT: u32 = 25000;
3486 const SEARCH_WHITESPACE_ROW_LIMIT: u32 = 2500;
3487 const YIELD_INTERVAL: u32 = 100;
3488
3489 let mut accessed_row_counter = 0;
3490
3491 // If there is a blank line at the current row, search for the next non indented lines
3492 if target_indent.is_line_empty() {
3493 let start = buffer_row.saturating_sub(SEARCH_WHITESPACE_ROW_LIMIT);
3494 let end = (max_row + 1).min(buffer_row + SEARCH_WHITESPACE_ROW_LIMIT);
3495
3496 let mut non_empty_line_above = None;
3497 for (row, indent) in self
3498 .text
3499 .reversed_line_indents_in_row_range(start..buffer_row)
3500 {
3501 accessed_row_counter += 1;
3502 if accessed_row_counter == YIELD_INTERVAL {
3503 accessed_row_counter = 0;
3504 yield_now().await;
3505 }
3506 if !indent.is_line_empty() {
3507 non_empty_line_above = Some((row, indent));
3508 break;
3509 }
3510 }
3511
3512 let mut non_empty_line_below = None;
3513 for (row, indent) in self.text.line_indents_in_row_range((buffer_row + 1)..end) {
3514 accessed_row_counter += 1;
3515 if accessed_row_counter == YIELD_INTERVAL {
3516 accessed_row_counter = 0;
3517 yield_now().await;
3518 }
3519 if !indent.is_line_empty() {
3520 non_empty_line_below = Some((row, indent));
3521 break;
3522 }
3523 }
3524
3525 let (row, indent) = match (non_empty_line_above, non_empty_line_below) {
3526 (Some((above_row, above_indent)), Some((below_row, below_indent))) => {
3527 if above_indent.raw_len() >= below_indent.raw_len() {
3528 (above_row, above_indent)
3529 } else {
3530 (below_row, below_indent)
3531 }
3532 }
3533 (Some(above), None) => above,
3534 (None, Some(below)) => below,
3535 _ => return None,
3536 };
3537
3538 target_indent = indent;
3539 buffer_row = row;
3540 }
3541
3542 let start = buffer_row.saturating_sub(SEARCH_ROW_LIMIT);
3543 let end = (max_row + 1).min(buffer_row + SEARCH_ROW_LIMIT);
3544
3545 let mut start_indent = None;
3546 for (row, indent) in self
3547 .text
3548 .reversed_line_indents_in_row_range(start..buffer_row)
3549 {
3550 accessed_row_counter += 1;
3551 if accessed_row_counter == YIELD_INTERVAL {
3552 accessed_row_counter = 0;
3553 yield_now().await;
3554 }
3555 if !indent.is_line_empty() && indent.raw_len() < target_indent.raw_len() {
3556 start_indent = Some((row, indent));
3557 break;
3558 }
3559 }
3560 let (start_row, start_indent_size) = start_indent?;
3561
3562 let mut end_indent = (end, None);
3563 for (row, indent) in self.text.line_indents_in_row_range((buffer_row + 1)..end) {
3564 accessed_row_counter += 1;
3565 if accessed_row_counter == YIELD_INTERVAL {
3566 accessed_row_counter = 0;
3567 yield_now().await;
3568 }
3569 if !indent.is_line_empty() && indent.raw_len() < target_indent.raw_len() {
3570 end_indent = (row.saturating_sub(1), Some(indent));
3571 break;
3572 }
3573 }
3574 let (end_row, end_indent_size) = end_indent;
3575
3576 let indent = if let Some(end_indent_size) = end_indent_size {
3577 if start_indent_size.raw_len() > end_indent_size.raw_len() {
3578 start_indent_size
3579 } else {
3580 end_indent_size
3581 }
3582 } else {
3583 start_indent_size
3584 };
3585
3586 Some((start_row..end_row, indent))
3587 }
3588
3589 /// Returns selections for remote peers intersecting the given range.
3590 #[allow(clippy::type_complexity)]
3591 pub fn selections_in_range(
3592 &self,
3593 range: Range<Anchor>,
3594 include_local: bool,
3595 ) -> impl Iterator<
3596 Item = (
3597 ReplicaId,
3598 bool,
3599 CursorShape,
3600 impl Iterator<Item = &Selection<Anchor>> + '_,
3601 ),
3602 > + '_ {
3603 self.remote_selections
3604 .iter()
3605 .filter(move |(replica_id, set)| {
3606 (include_local || **replica_id != self.text.replica_id())
3607 && !set.selections.is_empty()
3608 })
3609 .map(move |(replica_id, set)| {
3610 let start_ix = match set.selections.binary_search_by(|probe| {
3611 probe.end.cmp(&range.start, self).then(Ordering::Greater)
3612 }) {
3613 Ok(ix) | Err(ix) => ix,
3614 };
3615 let end_ix = match set.selections.binary_search_by(|probe| {
3616 probe.start.cmp(&range.end, self).then(Ordering::Less)
3617 }) {
3618 Ok(ix) | Err(ix) => ix,
3619 };
3620
3621 (
3622 *replica_id,
3623 set.line_mode,
3624 set.cursor_shape,
3625 set.selections[start_ix..end_ix].iter(),
3626 )
3627 })
3628 }
3629
3630 /// Whether the buffer contains any git changes.
3631 pub fn has_git_diff(&self) -> bool {
3632 !self.git_diff.is_empty()
3633 }
3634
3635 /// Returns all the Git diff hunks intersecting the given
3636 /// row range.
3637 pub fn git_diff_hunks_in_row_range(
3638 &self,
3639 range: Range<BufferRow>,
3640 ) -> impl '_ + Iterator<Item = git::diff::DiffHunk<u32>> {
3641 self.git_diff.hunks_in_row_range(range, self)
3642 }
3643
3644 /// Returns all the Git diff hunks intersecting the given
3645 /// range.
3646 pub fn git_diff_hunks_intersecting_range(
3647 &self,
3648 range: Range<Anchor>,
3649 ) -> impl '_ + Iterator<Item = git::diff::DiffHunk<u32>> {
3650 self.git_diff.hunks_intersecting_range(range, self)
3651 }
3652
3653 /// Returns all the Git diff hunks intersecting the given
3654 /// range, in reverse order.
3655 pub fn git_diff_hunks_intersecting_range_rev(
3656 &self,
3657 range: Range<Anchor>,
3658 ) -> impl '_ + Iterator<Item = git::diff::DiffHunk<u32>> {
3659 self.git_diff.hunks_intersecting_range_rev(range, self)
3660 }
3661
3662 /// Returns if the buffer contains any diagnostics.
3663 pub fn has_diagnostics(&self) -> bool {
3664 !self.diagnostics.is_empty()
3665 }
3666
3667 /// Returns all the diagnostics intersecting the given range.
3668 pub fn diagnostics_in_range<'a, T, O>(
3669 &'a self,
3670 search_range: Range<T>,
3671 reversed: bool,
3672 ) -> impl 'a + Iterator<Item = DiagnosticEntry<O>>
3673 where
3674 T: 'a + Clone + ToOffset,
3675 O: 'a + FromAnchor + Ord,
3676 {
3677 let mut iterators: Vec<_> = self
3678 .diagnostics
3679 .iter()
3680 .map(|(_, collection)| {
3681 collection
3682 .range::<T, O>(search_range.clone(), self, true, reversed)
3683 .peekable()
3684 })
3685 .collect();
3686
3687 std::iter::from_fn(move || {
3688 let (next_ix, _) = iterators
3689 .iter_mut()
3690 .enumerate()
3691 .flat_map(|(ix, iter)| Some((ix, iter.peek()?)))
3692 .min_by(|(_, a), (_, b)| {
3693 let cmp = a
3694 .range
3695 .start
3696 .cmp(&b.range.start)
3697 // when range is equal, sort by diagnostic severity
3698 .then(a.diagnostic.severity.cmp(&b.diagnostic.severity))
3699 // and stabilize order with group_id
3700 .then(a.diagnostic.group_id.cmp(&b.diagnostic.group_id));
3701 if reversed {
3702 cmp.reverse()
3703 } else {
3704 cmp
3705 }
3706 })?;
3707 iterators[next_ix].next()
3708 })
3709 }
3710
3711 /// Returns all the diagnostic groups associated with the given
3712 /// language server id. If no language server id is provided,
3713 /// all diagnostics groups are returned.
3714 pub fn diagnostic_groups(
3715 &self,
3716 language_server_id: Option<LanguageServerId>,
3717 ) -> Vec<(LanguageServerId, DiagnosticGroup<Anchor>)> {
3718 let mut groups = Vec::new();
3719
3720 if let Some(language_server_id) = language_server_id {
3721 if let Ok(ix) = self
3722 .diagnostics
3723 .binary_search_by_key(&language_server_id, |e| e.0)
3724 {
3725 self.diagnostics[ix]
3726 .1
3727 .groups(language_server_id, &mut groups, self);
3728 }
3729 } else {
3730 for (language_server_id, diagnostics) in self.diagnostics.iter() {
3731 diagnostics.groups(*language_server_id, &mut groups, self);
3732 }
3733 }
3734
3735 groups.sort_by(|(id_a, group_a), (id_b, group_b)| {
3736 let a_start = &group_a.entries[group_a.primary_ix].range.start;
3737 let b_start = &group_b.entries[group_b.primary_ix].range.start;
3738 a_start.cmp(b_start, self).then_with(|| id_a.cmp(id_b))
3739 });
3740
3741 groups
3742 }
3743
3744 /// Returns an iterator over the diagnostics for the given group.
3745 pub fn diagnostic_group<'a, O>(
3746 &'a self,
3747 group_id: usize,
3748 ) -> impl 'a + Iterator<Item = DiagnosticEntry<O>>
3749 where
3750 O: 'a + FromAnchor,
3751 {
3752 self.diagnostics
3753 .iter()
3754 .flat_map(move |(_, set)| set.group(group_id, self))
3755 }
3756
3757 /// An integer version number that accounts for all updates besides
3758 /// the buffer's text itself (which is versioned via a version vector).
3759 pub fn non_text_state_update_count(&self) -> usize {
3760 self.non_text_state_update_count
3761 }
3762
3763 /// Returns a snapshot of underlying file.
3764 pub fn file(&self) -> Option<&Arc<dyn File>> {
3765 self.file.as_ref()
3766 }
3767
3768 /// Resolves the file path (relative to the worktree root) associated with the underlying file.
3769 pub fn resolve_file_path(&self, cx: &AppContext, include_root: bool) -> Option<PathBuf> {
3770 if let Some(file) = self.file() {
3771 if file.path().file_name().is_none() || include_root {
3772 Some(file.full_path(cx))
3773 } else {
3774 Some(file.path().to_path_buf())
3775 }
3776 } else {
3777 None
3778 }
3779 }
3780}
3781
3782fn indent_size_for_line(text: &text::BufferSnapshot, row: u32) -> IndentSize {
3783 indent_size_for_text(text.chars_at(Point::new(row, 0)))
3784}
3785
3786fn indent_size_for_text(text: impl Iterator<Item = char>) -> IndentSize {
3787 let mut result = IndentSize::spaces(0);
3788 for c in text {
3789 let kind = match c {
3790 ' ' => IndentKind::Space,
3791 '\t' => IndentKind::Tab,
3792 _ => break,
3793 };
3794 if result.len == 0 {
3795 result.kind = kind;
3796 }
3797 result.len += 1;
3798 }
3799 result
3800}
3801
3802impl Clone for BufferSnapshot {
3803 fn clone(&self) -> Self {
3804 Self {
3805 text: self.text.clone(),
3806 git_diff: self.git_diff.clone(),
3807 syntax: self.syntax.clone(),
3808 file: self.file.clone(),
3809 remote_selections: self.remote_selections.clone(),
3810 diagnostics: self.diagnostics.clone(),
3811 language: self.language.clone(),
3812 non_text_state_update_count: self.non_text_state_update_count,
3813 }
3814 }
3815}
3816
3817impl Deref for BufferSnapshot {
3818 type Target = text::BufferSnapshot;
3819
3820 fn deref(&self) -> &Self::Target {
3821 &self.text
3822 }
3823}
3824
3825unsafe impl<'a> Send for BufferChunks<'a> {}
3826
3827impl<'a> BufferChunks<'a> {
3828 pub(crate) fn new(
3829 text: &'a Rope,
3830 range: Range<usize>,
3831 syntax: Option<(SyntaxMapCaptures<'a>, Vec<HighlightMap>)>,
3832 diagnostics: bool,
3833 buffer_snapshot: Option<&'a BufferSnapshot>,
3834 ) -> Self {
3835 let mut highlights = None;
3836 if let Some((captures, highlight_maps)) = syntax {
3837 highlights = Some(BufferChunkHighlights {
3838 captures,
3839 next_capture: None,
3840 stack: Default::default(),
3841 highlight_maps,
3842 })
3843 }
3844
3845 let diagnostic_endpoints = diagnostics.then(|| Vec::new().into_iter().peekable());
3846 let chunks = text.chunks_in_range(range.clone());
3847
3848 let mut this = BufferChunks {
3849 range,
3850 buffer_snapshot,
3851 chunks,
3852 diagnostic_endpoints,
3853 error_depth: 0,
3854 warning_depth: 0,
3855 information_depth: 0,
3856 hint_depth: 0,
3857 unnecessary_depth: 0,
3858 highlights,
3859 };
3860 this.initialize_diagnostic_endpoints();
3861 this
3862 }
3863
3864 /// Seeks to the given byte offset in the buffer.
3865 pub fn seek(&mut self, range: Range<usize>) {
3866 let old_range = std::mem::replace(&mut self.range, range.clone());
3867 self.chunks.set_range(self.range.clone());
3868 if let Some(highlights) = self.highlights.as_mut() {
3869 if old_range.start >= self.range.start && old_range.end <= self.range.end {
3870 // Reuse existing highlights stack, as the new range is a subrange of the old one.
3871 highlights
3872 .stack
3873 .retain(|(end_offset, _)| *end_offset > range.start);
3874 if let Some(capture) = &highlights.next_capture {
3875 if range.start >= capture.node.start_byte() {
3876 let next_capture_end = capture.node.end_byte();
3877 if range.start < next_capture_end {
3878 highlights.stack.push((
3879 next_capture_end,
3880 highlights.highlight_maps[capture.grammar_index].get(capture.index),
3881 ));
3882 }
3883 highlights.next_capture.take();
3884 }
3885 }
3886 } else if let Some(snapshot) = self.buffer_snapshot {
3887 let (captures, highlight_maps) = snapshot.get_highlights(self.range.clone());
3888 *highlights = BufferChunkHighlights {
3889 captures,
3890 next_capture: None,
3891 stack: Default::default(),
3892 highlight_maps,
3893 };
3894 } else {
3895 // We cannot obtain new highlights for a language-aware buffer iterator, as we don't have a buffer snapshot.
3896 // Seeking such BufferChunks is not supported.
3897 debug_assert!(false, "Attempted to seek on a language-aware buffer iterator without associated buffer snapshot");
3898 }
3899
3900 highlights.captures.set_byte_range(self.range.clone());
3901 self.initialize_diagnostic_endpoints();
3902 }
3903 }
3904
3905 fn initialize_diagnostic_endpoints(&mut self) {
3906 if let Some(diagnostics) = self.diagnostic_endpoints.as_mut() {
3907 if let Some(buffer) = self.buffer_snapshot {
3908 let mut diagnostic_endpoints = Vec::new();
3909 for entry in buffer.diagnostics_in_range::<_, usize>(self.range.clone(), false) {
3910 diagnostic_endpoints.push(DiagnosticEndpoint {
3911 offset: entry.range.start,
3912 is_start: true,
3913 severity: entry.diagnostic.severity,
3914 is_unnecessary: entry.diagnostic.is_unnecessary,
3915 });
3916 diagnostic_endpoints.push(DiagnosticEndpoint {
3917 offset: entry.range.end,
3918 is_start: false,
3919 severity: entry.diagnostic.severity,
3920 is_unnecessary: entry.diagnostic.is_unnecessary,
3921 });
3922 }
3923 diagnostic_endpoints
3924 .sort_unstable_by_key(|endpoint| (endpoint.offset, !endpoint.is_start));
3925 *diagnostics = diagnostic_endpoints.into_iter().peekable();
3926 }
3927 }
3928 }
3929
3930 /// The current byte offset in the buffer.
3931 pub fn offset(&self) -> usize {
3932 self.range.start
3933 }
3934
3935 fn update_diagnostic_depths(&mut self, endpoint: DiagnosticEndpoint) {
3936 let depth = match endpoint.severity {
3937 DiagnosticSeverity::ERROR => &mut self.error_depth,
3938 DiagnosticSeverity::WARNING => &mut self.warning_depth,
3939 DiagnosticSeverity::INFORMATION => &mut self.information_depth,
3940 DiagnosticSeverity::HINT => &mut self.hint_depth,
3941 _ => return,
3942 };
3943 if endpoint.is_start {
3944 *depth += 1;
3945 } else {
3946 *depth -= 1;
3947 }
3948
3949 if endpoint.is_unnecessary {
3950 if endpoint.is_start {
3951 self.unnecessary_depth += 1;
3952 } else {
3953 self.unnecessary_depth -= 1;
3954 }
3955 }
3956 }
3957
3958 fn current_diagnostic_severity(&self) -> Option<DiagnosticSeverity> {
3959 if self.error_depth > 0 {
3960 Some(DiagnosticSeverity::ERROR)
3961 } else if self.warning_depth > 0 {
3962 Some(DiagnosticSeverity::WARNING)
3963 } else if self.information_depth > 0 {
3964 Some(DiagnosticSeverity::INFORMATION)
3965 } else if self.hint_depth > 0 {
3966 Some(DiagnosticSeverity::HINT)
3967 } else {
3968 None
3969 }
3970 }
3971
3972 fn current_code_is_unnecessary(&self) -> bool {
3973 self.unnecessary_depth > 0
3974 }
3975}
3976
3977impl<'a> Iterator for BufferChunks<'a> {
3978 type Item = Chunk<'a>;
3979
3980 fn next(&mut self) -> Option<Self::Item> {
3981 let mut next_capture_start = usize::MAX;
3982 let mut next_diagnostic_endpoint = usize::MAX;
3983
3984 if let Some(highlights) = self.highlights.as_mut() {
3985 while let Some((parent_capture_end, _)) = highlights.stack.last() {
3986 if *parent_capture_end <= self.range.start {
3987 highlights.stack.pop();
3988 } else {
3989 break;
3990 }
3991 }
3992
3993 if highlights.next_capture.is_none() {
3994 highlights.next_capture = highlights.captures.next();
3995 }
3996
3997 while let Some(capture) = highlights.next_capture.as_ref() {
3998 if self.range.start < capture.node.start_byte() {
3999 next_capture_start = capture.node.start_byte();
4000 break;
4001 } else {
4002 let highlight_id =
4003 highlights.highlight_maps[capture.grammar_index].get(capture.index);
4004 highlights
4005 .stack
4006 .push((capture.node.end_byte(), highlight_id));
4007 highlights.next_capture = highlights.captures.next();
4008 }
4009 }
4010 }
4011
4012 let mut diagnostic_endpoints = std::mem::take(&mut self.diagnostic_endpoints);
4013 if let Some(diagnostic_endpoints) = diagnostic_endpoints.as_mut() {
4014 while let Some(endpoint) = diagnostic_endpoints.peek().copied() {
4015 if endpoint.offset <= self.range.start {
4016 self.update_diagnostic_depths(endpoint);
4017 diagnostic_endpoints.next();
4018 } else {
4019 next_diagnostic_endpoint = endpoint.offset;
4020 break;
4021 }
4022 }
4023 }
4024 self.diagnostic_endpoints = diagnostic_endpoints;
4025
4026 if let Some(chunk) = self.chunks.peek() {
4027 let chunk_start = self.range.start;
4028 let mut chunk_end = (self.chunks.offset() + chunk.len())
4029 .min(next_capture_start)
4030 .min(next_diagnostic_endpoint);
4031 let mut highlight_id = None;
4032 if let Some(highlights) = self.highlights.as_ref() {
4033 if let Some((parent_capture_end, parent_highlight_id)) = highlights.stack.last() {
4034 chunk_end = chunk_end.min(*parent_capture_end);
4035 highlight_id = Some(*parent_highlight_id);
4036 }
4037 }
4038
4039 let slice =
4040 &chunk[chunk_start - self.chunks.offset()..chunk_end - self.chunks.offset()];
4041 self.range.start = chunk_end;
4042 if self.range.start == self.chunks.offset() + chunk.len() {
4043 self.chunks.next().unwrap();
4044 }
4045
4046 Some(Chunk {
4047 text: slice,
4048 syntax_highlight_id: highlight_id,
4049 diagnostic_severity: self.current_diagnostic_severity(),
4050 is_unnecessary: self.current_code_is_unnecessary(),
4051 ..Default::default()
4052 })
4053 } else {
4054 None
4055 }
4056 }
4057}
4058
4059impl operation_queue::Operation for Operation {
4060 fn lamport_timestamp(&self) -> clock::Lamport {
4061 match self {
4062 Operation::Buffer(_) => {
4063 unreachable!("buffer operations should never be deferred at this layer")
4064 }
4065 Operation::UpdateDiagnostics {
4066 lamport_timestamp, ..
4067 }
4068 | Operation::UpdateSelections {
4069 lamport_timestamp, ..
4070 }
4071 | Operation::UpdateCompletionTriggers {
4072 lamport_timestamp, ..
4073 } => *lamport_timestamp,
4074 }
4075 }
4076}
4077
4078impl Default for Diagnostic {
4079 fn default() -> Self {
4080 Self {
4081 source: Default::default(),
4082 code: None,
4083 severity: DiagnosticSeverity::ERROR,
4084 message: Default::default(),
4085 group_id: 0,
4086 is_primary: false,
4087 is_disk_based: false,
4088 is_unnecessary: false,
4089 data: None,
4090 }
4091 }
4092}
4093
4094impl IndentSize {
4095 /// Returns an [IndentSize] representing the given spaces.
4096 pub fn spaces(len: u32) -> Self {
4097 Self {
4098 len,
4099 kind: IndentKind::Space,
4100 }
4101 }
4102
4103 /// Returns an [IndentSize] representing a tab.
4104 pub fn tab() -> Self {
4105 Self {
4106 len: 1,
4107 kind: IndentKind::Tab,
4108 }
4109 }
4110
4111 /// An iterator over the characters represented by this [IndentSize].
4112 pub fn chars(&self) -> impl Iterator<Item = char> {
4113 iter::repeat(self.char()).take(self.len as usize)
4114 }
4115
4116 /// The character representation of this [IndentSize].
4117 pub fn char(&self) -> char {
4118 match self.kind {
4119 IndentKind::Space => ' ',
4120 IndentKind::Tab => '\t',
4121 }
4122 }
4123
4124 /// Consumes the current [IndentSize] and returns a new one that has
4125 /// been shrunk or enlarged by the given size along the given direction.
4126 pub fn with_delta(mut self, direction: Ordering, size: IndentSize) -> Self {
4127 match direction {
4128 Ordering::Less => {
4129 if self.kind == size.kind && self.len >= size.len {
4130 self.len -= size.len;
4131 }
4132 }
4133 Ordering::Equal => {}
4134 Ordering::Greater => {
4135 if self.len == 0 {
4136 self = size;
4137 } else if self.kind == size.kind {
4138 self.len += size.len;
4139 }
4140 }
4141 }
4142 self
4143 }
4144}
4145
4146#[cfg(any(test, feature = "test-support"))]
4147pub struct TestFile {
4148 pub path: Arc<Path>,
4149 pub root_name: String,
4150}
4151
4152#[cfg(any(test, feature = "test-support"))]
4153impl File for TestFile {
4154 fn path(&self) -> &Arc<Path> {
4155 &self.path
4156 }
4157
4158 fn full_path(&self, _: &gpui::AppContext) -> PathBuf {
4159 PathBuf::from(&self.root_name).join(self.path.as_ref())
4160 }
4161
4162 fn as_local(&self) -> Option<&dyn LocalFile> {
4163 None
4164 }
4165
4166 fn mtime(&self) -> Option<SystemTime> {
4167 unimplemented!()
4168 }
4169
4170 fn file_name<'a>(&'a self, _: &'a gpui::AppContext) -> &'a std::ffi::OsStr {
4171 self.path().file_name().unwrap_or(self.root_name.as_ref())
4172 }
4173
4174 fn worktree_id(&self) -> usize {
4175 0
4176 }
4177
4178 fn is_deleted(&self) -> bool {
4179 unimplemented!()
4180 }
4181
4182 fn as_any(&self) -> &dyn std::any::Any {
4183 unimplemented!()
4184 }
4185
4186 fn to_proto(&self, _: &AppContext) -> rpc::proto::File {
4187 unimplemented!()
4188 }
4189
4190 fn is_private(&self) -> bool {
4191 false
4192 }
4193}
4194
4195pub(crate) fn contiguous_ranges(
4196 values: impl Iterator<Item = u32>,
4197 max_len: usize,
4198) -> impl Iterator<Item = Range<u32>> {
4199 let mut values = values;
4200 let mut current_range: Option<Range<u32>> = None;
4201 std::iter::from_fn(move || loop {
4202 if let Some(value) = values.next() {
4203 if let Some(range) = &mut current_range {
4204 if value == range.end && range.len() < max_len {
4205 range.end += 1;
4206 continue;
4207 }
4208 }
4209
4210 let prev_range = current_range.clone();
4211 current_range = Some(value..(value + 1));
4212 if prev_range.is_some() {
4213 return prev_range;
4214 }
4215 } else {
4216 return current_range.take();
4217 }
4218 })
4219}
4220
4221#[derive(Default, Debug)]
4222pub struct CharClassifier {
4223 scope: Option<LanguageScope>,
4224 for_completion: bool,
4225 ignore_punctuation: bool,
4226}
4227
4228impl CharClassifier {
4229 pub fn new(scope: Option<LanguageScope>) -> Self {
4230 Self {
4231 scope,
4232 for_completion: false,
4233 ignore_punctuation: false,
4234 }
4235 }
4236
4237 pub fn for_completion(self, for_completion: bool) -> Self {
4238 Self {
4239 for_completion,
4240 ..self
4241 }
4242 }
4243
4244 pub fn ignore_punctuation(self, ignore_punctuation: bool) -> Self {
4245 Self {
4246 ignore_punctuation,
4247 ..self
4248 }
4249 }
4250
4251 pub fn is_whitespace(&self, c: char) -> bool {
4252 self.kind(c) == CharKind::Whitespace
4253 }
4254
4255 pub fn is_word(&self, c: char) -> bool {
4256 self.kind(c) == CharKind::Word
4257 }
4258
4259 pub fn is_punctuation(&self, c: char) -> bool {
4260 self.kind(c) == CharKind::Punctuation
4261 }
4262
4263 pub fn kind(&self, c: char) -> CharKind {
4264 if c.is_whitespace() {
4265 return CharKind::Whitespace;
4266 } else if c.is_alphanumeric() || c == '_' {
4267 return CharKind::Word;
4268 }
4269
4270 if let Some(scope) = &self.scope {
4271 if let Some(characters) = scope.word_characters() {
4272 if characters.contains(&c) {
4273 if c == '-' && !self.for_completion && !self.ignore_punctuation {
4274 return CharKind::Punctuation;
4275 }
4276 return CharKind::Word;
4277 }
4278 }
4279 }
4280
4281 if self.ignore_punctuation {
4282 CharKind::Word
4283 } else {
4284 CharKind::Punctuation
4285 }
4286 }
4287}
4288
4289/// Find all of the ranges of whitespace that occur at the ends of lines
4290/// in the given rope.
4291///
4292/// This could also be done with a regex search, but this implementation
4293/// avoids copying text.
4294pub fn trailing_whitespace_ranges(rope: &Rope) -> Vec<Range<usize>> {
4295 let mut ranges = Vec::new();
4296
4297 let mut offset = 0;
4298 let mut prev_chunk_trailing_whitespace_range = 0..0;
4299 for chunk in rope.chunks() {
4300 let mut prev_line_trailing_whitespace_range = 0..0;
4301 for (i, line) in chunk.split('\n').enumerate() {
4302 let line_end_offset = offset + line.len();
4303 let trimmed_line_len = line.trim_end_matches(|c| matches!(c, ' ' | '\t')).len();
4304 let mut trailing_whitespace_range = (offset + trimmed_line_len)..line_end_offset;
4305
4306 if i == 0 && trimmed_line_len == 0 {
4307 trailing_whitespace_range.start = prev_chunk_trailing_whitespace_range.start;
4308 }
4309 if !prev_line_trailing_whitespace_range.is_empty() {
4310 ranges.push(prev_line_trailing_whitespace_range);
4311 }
4312
4313 offset = line_end_offset + 1;
4314 prev_line_trailing_whitespace_range = trailing_whitespace_range;
4315 }
4316
4317 offset -= 1;
4318 prev_chunk_trailing_whitespace_range = prev_line_trailing_whitespace_range;
4319 }
4320
4321 if !prev_chunk_trailing_whitespace_range.is_empty() {
4322 ranges.push(prev_chunk_trailing_whitespace_range);
4323 }
4324
4325 ranges
4326}