341 lines
12 KiB
Rust
341 lines
12 KiB
Rust
//! See [`AssistContext`].
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use std::mem;
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use hir::Semantics;
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use ide_db::{
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base_db::{AnchoredPathBuf, FileId, FileRange},
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helpers::SnippetCap,
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};
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use ide_db::{
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label::Label,
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source_change::{FileSystemEdit, SourceChange},
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RootDatabase,
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};
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use syntax::{
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algo::{self, find_node_at_offset, find_node_at_range},
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AstNode, AstToken, Direction, SourceFile, SyntaxElement, SyntaxKind, SyntaxNode, SyntaxNodePtr,
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SyntaxToken, TextRange, TextSize, TokenAtOffset,
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};
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use text_edit::{TextEdit, TextEditBuilder};
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use crate::{
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assist_config::AssistConfig, Assist, AssistId, AssistKind, AssistResolveStrategy, GroupLabel,
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};
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/// `AssistContext` allows to apply an assist or check if it could be applied.
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///
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/// Assists use a somewhat over-engineered approach, given the current needs.
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/// The assists workflow consists of two phases. In the first phase, a user asks
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/// for the list of available assists. In the second phase, the user picks a
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/// particular assist and it gets applied.
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///
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/// There are two peculiarities here:
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///
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/// * first, we ideally avoid computing more things then necessary to answer "is
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/// assist applicable" in the first phase.
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/// * second, when we are applying assist, we don't have a guarantee that there
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/// weren't any changes between the point when user asked for assists and when
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/// they applied a particular assist. So, when applying assist, we need to do
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/// all the checks from scratch.
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///
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/// To avoid repeating the same code twice for both "check" and "apply"
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/// functions, we use an approach reminiscent of that of Django's function based
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/// views dealing with forms. Each assist receives a runtime parameter,
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/// `resolve`. It first check if an edit is applicable (potentially computing
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/// info required to compute the actual edit). If it is applicable, and
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/// `resolve` is `true`, it then computes the actual edit.
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///
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/// So, to implement the original assists workflow, we can first apply each edit
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/// with `resolve = false`, and then applying the selected edit again, with
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/// `resolve = true` this time.
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///
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/// Note, however, that we don't actually use such two-phase logic at the
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/// moment, because the LSP API is pretty awkward in this place, and it's much
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/// easier to just compute the edit eagerly :-)
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pub(crate) struct AssistContext<'a> {
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pub(crate) config: &'a AssistConfig,
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pub(crate) sema: Semantics<'a, RootDatabase>,
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frange: FileRange,
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trimmed_range: TextRange,
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source_file: SourceFile,
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}
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impl<'a> AssistContext<'a> {
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pub(crate) fn new(
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sema: Semantics<'a, RootDatabase>,
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config: &'a AssistConfig,
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frange: FileRange,
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) -> AssistContext<'a> {
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let source_file = sema.parse(frange.file_id);
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let start = frange.range.start();
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let end = frange.range.end();
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let left = source_file.syntax().token_at_offset(start);
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let right = source_file.syntax().token_at_offset(end);
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let left =
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left.right_biased().and_then(|t| algo::skip_whitespace_token(t, Direction::Next));
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let right =
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right.left_biased().and_then(|t| algo::skip_whitespace_token(t, Direction::Prev));
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let left = left.map(|t| t.text_range().start().clamp(start, end));
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let right = right.map(|t| t.text_range().end().clamp(start, end));
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let trimmed_range = match (left, right) {
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(Some(left), Some(right)) if left <= right => TextRange::new(left, right),
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// Selection solely consists of whitespace so just fall back to the original
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_ => frange.range,
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};
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AssistContext { config, sema, frange, source_file, trimmed_range }
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}
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pub(crate) fn db(&self) -> &RootDatabase {
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self.sema.db
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}
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// NB, this ignores active selection.
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pub(crate) fn offset(&self) -> TextSize {
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self.frange.range.start()
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}
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pub(crate) fn file_id(&self) -> FileId {
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self.frange.file_id
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}
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pub(crate) fn has_empty_selection(&self) -> bool {
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self.trimmed_range.is_empty()
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}
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/// Returns the selected range trimmed for whitespace tokens, that is the range will be snapped
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/// to the nearest enclosed token.
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pub(crate) fn selection_trimmed(&self) -> TextRange {
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self.trimmed_range
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}
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pub(crate) fn token_at_offset(&self) -> TokenAtOffset<SyntaxToken> {
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self.source_file.syntax().token_at_offset(self.offset())
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}
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pub(crate) fn find_token_syntax_at_offset(&self, kind: SyntaxKind) -> Option<SyntaxToken> {
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self.token_at_offset().find(|it| it.kind() == kind)
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}
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pub(crate) fn find_token_at_offset<T: AstToken>(&self) -> Option<T> {
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self.token_at_offset().find_map(T::cast)
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}
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pub(crate) fn find_node_at_offset<N: AstNode>(&self) -> Option<N> {
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find_node_at_offset(self.source_file.syntax(), self.offset())
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}
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pub(crate) fn find_node_at_range<N: AstNode>(&self) -> Option<N> {
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find_node_at_range(self.source_file.syntax(), self.trimmed_range)
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}
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pub(crate) fn find_node_at_offset_with_descend<N: AstNode>(&self) -> Option<N> {
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self.sema.find_node_at_offset_with_descend(self.source_file.syntax(), self.offset())
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}
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/// Returns the element covered by the selection range, this excludes trailing whitespace in the selection.
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pub(crate) fn covering_element(&self) -> SyntaxElement {
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self.source_file.syntax().covering_element(self.selection_trimmed())
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}
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}
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pub(crate) struct Assists {
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file: FileId,
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resolve: AssistResolveStrategy,
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buf: Vec<Assist>,
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allowed: Option<Vec<AssistKind>>,
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}
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impl Assists {
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pub(crate) fn new(ctx: &AssistContext, resolve: AssistResolveStrategy) -> Assists {
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Assists {
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resolve,
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file: ctx.frange.file_id,
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buf: Vec::new(),
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allowed: ctx.config.allowed.clone(),
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}
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}
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pub(crate) fn finish(mut self) -> Vec<Assist> {
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self.buf.sort_by_key(|assist| assist.target.len());
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self.buf
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}
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pub(crate) fn add(
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&mut self,
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id: AssistId,
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label: impl Into<String>,
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target: TextRange,
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f: impl FnOnce(&mut AssistBuilder),
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) -> Option<()> {
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let mut f = Some(f);
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self.add_impl(None, id, label.into(), target, &mut |it| f.take().unwrap()(it))
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}
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pub(crate) fn add_group(
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&mut self,
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group: &GroupLabel,
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id: AssistId,
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label: impl Into<String>,
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target: TextRange,
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f: impl FnOnce(&mut AssistBuilder),
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) -> Option<()> {
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let mut f = Some(f);
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self.add_impl(Some(group), id, label.into(), target, &mut |it| f.take().unwrap()(it))
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}
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fn add_impl(
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&mut self,
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group: Option<&GroupLabel>,
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id: AssistId,
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label: String,
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target: TextRange,
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f: &mut dyn FnMut(&mut AssistBuilder),
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) -> Option<()> {
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if !self.is_allowed(&id) {
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return None;
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}
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let source_change = if self.resolve.should_resolve(&id) {
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let mut builder = AssistBuilder::new(self.file);
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f(&mut builder);
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Some(builder.finish())
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} else {
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None
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};
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let label = Label::new(label);
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let group = group.cloned();
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self.buf.push(Assist { id, label, group, target, source_change });
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Some(())
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}
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fn is_allowed(&self, id: &AssistId) -> bool {
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match &self.allowed {
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Some(allowed) => allowed.iter().any(|kind| kind.contains(id.1)),
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None => true,
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}
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}
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}
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pub(crate) struct AssistBuilder {
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edit: TextEditBuilder,
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file_id: FileId,
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source_change: SourceChange,
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/// Maps the original, immutable `SyntaxNode` to a `clone_for_update` twin.
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mutated_tree: Option<TreeMutator>,
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}
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pub(crate) struct TreeMutator {
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immutable: SyntaxNode,
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mutable_clone: SyntaxNode,
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}
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impl TreeMutator {
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pub(crate) fn new(immutable: &SyntaxNode) -> TreeMutator {
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let immutable = immutable.ancestors().last().unwrap();
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let mutable_clone = immutable.clone_for_update();
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TreeMutator { immutable, mutable_clone }
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}
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pub(crate) fn make_mut<N: AstNode>(&self, node: &N) -> N {
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N::cast(self.make_syntax_mut(node.syntax())).unwrap()
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}
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pub(crate) fn make_syntax_mut(&self, node: &SyntaxNode) -> SyntaxNode {
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let ptr = SyntaxNodePtr::new(node);
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ptr.to_node(&self.mutable_clone)
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}
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}
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impl AssistBuilder {
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pub(crate) fn new(file_id: FileId) -> AssistBuilder {
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AssistBuilder {
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edit: TextEdit::builder(),
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file_id,
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source_change: SourceChange::default(),
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mutated_tree: None,
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}
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}
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pub(crate) fn edit_file(&mut self, file_id: FileId) {
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self.commit();
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self.file_id = file_id;
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}
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fn commit(&mut self) {
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if let Some(tm) = self.mutated_tree.take() {
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algo::diff(&tm.immutable, &tm.mutable_clone).into_text_edit(&mut self.edit)
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}
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let edit = mem::take(&mut self.edit).finish();
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if !edit.is_empty() {
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self.source_change.insert_source_edit(self.file_id, edit);
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}
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}
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pub(crate) fn make_mut<N: AstNode>(&mut self, node: N) -> N {
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self.mutated_tree.get_or_insert_with(|| TreeMutator::new(node.syntax())).make_mut(&node)
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}
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/// Returns a copy of the `node`, suitable for mutation.
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///
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/// Syntax trees in rust-analyzer are typically immutable, and mutating
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/// operations panic at runtime. However, it is possible to make a copy of
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/// the tree and mutate the copy freely. Mutation is based on interior
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/// mutability, and different nodes in the same tree see the same mutations.
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///
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/// The typical pattern for an assist is to find specific nodes in the read
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/// phase, and then get their mutable couterparts using `make_mut` in the
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/// mutable state.
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pub(crate) fn make_syntax_mut(&mut self, node: SyntaxNode) -> SyntaxNode {
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self.mutated_tree.get_or_insert_with(|| TreeMutator::new(&node)).make_syntax_mut(&node)
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}
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/// Remove specified `range` of text.
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pub(crate) fn delete(&mut self, range: TextRange) {
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self.edit.delete(range)
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}
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/// Append specified `text` at the given `offset`
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pub(crate) fn insert(&mut self, offset: TextSize, text: impl Into<String>) {
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self.edit.insert(offset, text.into())
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}
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/// Append specified `snippet` at the given `offset`
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pub(crate) fn insert_snippet(
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&mut self,
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_cap: SnippetCap,
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offset: TextSize,
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snippet: impl Into<String>,
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) {
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self.source_change.is_snippet = true;
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self.insert(offset, snippet);
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}
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/// Replaces specified `range` of text with a given string.
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pub(crate) fn replace(&mut self, range: TextRange, replace_with: impl Into<String>) {
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self.edit.replace(range, replace_with.into())
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}
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/// Replaces specified `range` of text with a given `snippet`.
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pub(crate) fn replace_snippet(
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&mut self,
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_cap: SnippetCap,
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range: TextRange,
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snippet: impl Into<String>,
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) {
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self.source_change.is_snippet = true;
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self.replace(range, snippet);
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}
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pub(crate) fn replace_ast<N: AstNode>(&mut self, old: N, new: N) {
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algo::diff(old.syntax(), new.syntax()).into_text_edit(&mut self.edit)
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}
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pub(crate) fn create_file(&mut self, dst: AnchoredPathBuf, content: impl Into<String>) {
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let file_system_edit = FileSystemEdit::CreateFile { dst, initial_contents: content.into() };
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self.source_change.push_file_system_edit(file_system_edit);
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}
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pub(crate) fn move_file(&mut self, src: FileId, dst: AnchoredPathBuf) {
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let file_system_edit = FileSystemEdit::MoveFile { src, dst };
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self.source_change.push_file_system_edit(file_system_edit);
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}
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fn finish(mut self) -> SourceChange {
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self.commit();
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mem::take(&mut self.source_change)
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}
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}
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