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https://github.com/rust-lang/rust-analyzer
synced 2024-12-26 13:03:31 +00:00
SSR: Use Definition::find_usages to speed up matching.
When the search pattern contains a path, this substantially speeds up finding matches, especially if the path references a private item.
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parent
757f755c29
commit
63f500b0ee
5 changed files with 158 additions and 25 deletions
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@ -290,20 +290,25 @@ pub fn classify_name_ref(
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let path = name_ref.syntax().ancestors().find_map(ast::Path::cast)?;
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let resolved = sema.resolve_path(&path)?;
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let res = match resolved {
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PathResolution::Def(def) => Definition::ModuleDef(def),
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PathResolution::AssocItem(item) => {
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let def = match item {
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hir::AssocItem::Function(it) => it.into(),
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hir::AssocItem::Const(it) => it.into(),
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hir::AssocItem::TypeAlias(it) => it.into(),
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};
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Definition::ModuleDef(def)
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}
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PathResolution::Local(local) => Definition::Local(local),
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PathResolution::TypeParam(par) => Definition::TypeParam(par),
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PathResolution::Macro(def) => Definition::Macro(def),
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PathResolution::SelfType(impl_def) => Definition::SelfType(impl_def),
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};
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Some(NameRefClass::Definition(res))
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Some(NameRefClass::Definition(resolved.into()))
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}
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impl From<PathResolution> for Definition {
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fn from(path_resolution: PathResolution) -> Self {
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match path_resolution {
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PathResolution::Def(def) => Definition::ModuleDef(def),
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PathResolution::AssocItem(item) => {
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let def = match item {
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hir::AssocItem::Function(it) => it.into(),
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hir::AssocItem::Const(it) => it.into(),
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hir::AssocItem::TypeAlias(it) => it.into(),
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};
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Definition::ModuleDef(def)
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}
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PathResolution::Local(local) => Definition::Local(local),
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PathResolution::TypeParam(par) => Definition::TypeParam(par),
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PathResolution::Macro(def) => Definition::Macro(def),
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PathResolution::SelfType(impl_def) => Definition::SelfType(impl_def),
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}
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}
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}
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@ -60,6 +60,10 @@ impl SearchScope {
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SearchScope::new(std::iter::once((file, None)).collect())
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}
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pub fn files(files: &[FileId]) -> SearchScope {
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SearchScope::new(files.iter().map(|f| (*f, None)).collect())
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}
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pub fn intersection(&self, other: &SearchScope) -> SearchScope {
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let (mut small, mut large) = (&self.entries, &other.entries);
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if small.len() > large.len() {
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@ -151,8 +151,9 @@ impl<'db> MatchFinder<'db> {
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/// Returns matches for all added rules.
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pub fn matches(&self) -> SsrMatches {
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let mut matches = Vec::new();
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let mut usage_cache = search::UsageCache::default();
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for rule in &self.rules {
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self.find_matches_for_rule(rule, &mut matches);
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self.find_matches_for_rule(rule, &mut usage_cache, &mut matches);
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}
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nester::nest_and_remove_collisions(matches, &self.sema)
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}
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@ -22,6 +22,7 @@ pub(crate) struct ResolvedPattern {
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pub(crate) struct ResolvedPath {
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pub(crate) resolution: hir::PathResolution,
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pub(crate) depth: u32,
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}
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impl ResolvedRule {
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@ -62,7 +63,7 @@ struct Resolver<'a, 'db> {
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impl Resolver<'_, '_> {
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fn resolve_pattern_tree(&self, pattern: SyntaxNode) -> Result<ResolvedPattern, SsrError> {
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let mut resolved_paths = FxHashMap::default();
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self.resolve(pattern.clone(), &mut resolved_paths)?;
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self.resolve(pattern.clone(), 0, &mut resolved_paths)?;
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Ok(ResolvedPattern {
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node: pattern,
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resolved_paths,
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@ -73,6 +74,7 @@ impl Resolver<'_, '_> {
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fn resolve(
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&self,
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node: SyntaxNode,
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depth: u32,
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resolved_paths: &mut FxHashMap<SyntaxNode, ResolvedPath>,
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) -> Result<(), SsrError> {
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use ra_syntax::ast::AstNode;
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@ -86,12 +88,12 @@ impl Resolver<'_, '_> {
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let resolution = self
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.resolve_path(&path)
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.ok_or_else(|| error!("Failed to resolve path `{}`", node.text()))?;
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resolved_paths.insert(node, ResolvedPath { resolution });
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resolved_paths.insert(node, ResolvedPath { resolution, depth });
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return Ok(());
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}
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}
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for node in node.children() {
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self.resolve(node, resolved_paths)?;
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self.resolve(node, depth + 1, resolved_paths)?;
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}
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Ok(())
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}
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@ -1,17 +1,106 @@
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//! Searching for matches.
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use crate::{matching, resolving::ResolvedRule, Match, MatchFinder};
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use crate::{
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matching,
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resolving::{ResolvedPath, ResolvedPattern, ResolvedRule},
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Match, MatchFinder,
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};
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use ra_db::FileRange;
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use ra_ide_db::{
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defs::Definition,
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search::{Reference, SearchScope},
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};
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use ra_syntax::{ast, AstNode, SyntaxNode};
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/// A cache for the results of find_usages. This is for when we have multiple patterns that have the
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/// same path. e.g. if the pattern was `foo::Bar` that can parse as a path, an expression, a type
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/// and as a pattern. In each, the usages of `foo::Bar` are the same and we'd like to avoid finding
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/// them more than once.
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#[derive(Default)]
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pub(crate) struct UsageCache {
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usages: Vec<(Definition, Vec<Reference>)>,
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}
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impl<'db> MatchFinder<'db> {
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/// Adds all matches for `rule` to `matches_out`. Matches may overlap in ways that make
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/// replacement impossible, so further processing is required in order to properly nest matches
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/// and remove overlapping matches. This is done in the `nesting` module.
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pub(crate) fn find_matches_for_rule(&self, rule: &ResolvedRule, matches_out: &mut Vec<Match>) {
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// FIXME: Use resolved paths in the pattern to find places to search instead of always
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// scanning every node.
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self.slow_scan(rule, matches_out);
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pub(crate) fn find_matches_for_rule(
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&self,
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rule: &ResolvedRule,
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usage_cache: &mut UsageCache,
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matches_out: &mut Vec<Match>,
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) {
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if pick_path_for_usages(&rule.pattern).is_none() {
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self.slow_scan(rule, matches_out);
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return;
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}
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self.find_matches_for_pattern_tree(rule, &rule.pattern, usage_cache, matches_out);
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}
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fn find_matches_for_pattern_tree(
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&self,
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rule: &ResolvedRule,
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pattern: &ResolvedPattern,
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usage_cache: &mut UsageCache,
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matches_out: &mut Vec<Match>,
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) {
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if let Some(first_path) = pick_path_for_usages(pattern) {
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let definition: Definition = first_path.resolution.clone().into();
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for reference in self.find_usages(usage_cache, definition) {
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let file = self.sema.parse(reference.file_range.file_id);
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if let Some(path) = self.sema.find_node_at_offset_with_descend::<ast::Path>(
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file.syntax(),
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reference.file_range.range.start(),
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) {
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if let Some(node_to_match) = self
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.sema
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.ancestors_with_macros(path.syntax().clone())
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.skip(first_path.depth as usize)
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.next()
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{
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if let Ok(m) =
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matching::get_match(false, rule, &node_to_match, &None, &self.sema)
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{
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matches_out.push(m);
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}
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}
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}
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}
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}
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}
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fn find_usages<'a>(
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&self,
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usage_cache: &'a mut UsageCache,
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definition: Definition,
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) -> &'a [Reference] {
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// Logically if a lookup succeeds we should just return it. Unfortunately returning it would
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// extend the lifetime of the borrow, then we wouldn't be able to do the insertion on a
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// cache miss. This is a limitation of NLL and is fixed with Polonius. For now we do two
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// lookups in the case of a cache hit.
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if usage_cache.find(&definition).is_none() {
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let usages = definition.find_usages(&self.sema, Some(self.search_scope()));
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usage_cache.usages.push((definition, usages));
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return &usage_cache.usages.last().unwrap().1;
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}
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usage_cache.find(&definition).unwrap()
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}
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/// Returns the scope within which we want to search. We don't want un unrestricted search
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/// scope, since we don't want to find references in external dependencies.
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fn search_scope(&self) -> SearchScope {
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// FIXME: We should ideally have a test that checks that we edit local roots and not library
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// roots. This probably would require some changes to fixtures, since currently everything
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// seems to get put into a single source root.
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use ra_db::SourceDatabaseExt;
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use ra_ide_db::symbol_index::SymbolsDatabase;
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let mut files = Vec::new();
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for &root in self.sema.db.local_roots().iter() {
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let sr = self.sema.db.source_root(root);
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files.extend(sr.iter());
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}
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SearchScope::files(&files)
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}
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fn slow_scan(&self, rule: &ResolvedRule, matches_out: &mut Vec<Match>) {
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@ -59,3 +148,35 @@ impl<'db> MatchFinder<'db> {
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}
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}
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}
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impl UsageCache {
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fn find(&mut self, definition: &Definition) -> Option<&[Reference]> {
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// We expect a very small number of cache entries (generally 1), so a linear scan should be
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// fast enough and avoids the need to implement Hash for Definition.
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for (d, refs) in &self.usages {
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if d == definition {
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return Some(refs);
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}
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}
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None
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}
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}
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/// Returns a path that's suitable for path resolution. We exclude builtin types, since they aren't
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/// something that we can find references to. We then somewhat arbitrarily pick the path that is the
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/// longest as this is hopefully more likely to be less common, making it faster to find.
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fn pick_path_for_usages(pattern: &ResolvedPattern) -> Option<&ResolvedPath> {
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// FIXME: Take the scope of the resolved path into account. e.g. if there are any paths that are
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// private to the current module, then we definitely would want to pick them over say a path
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// from std. Possibly we should go further than this and intersect the search scopes for all
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// resolved paths then search only in that scope.
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pattern
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.resolved_paths
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.iter()
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.filter(|(_, p)| {
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!matches!(p.resolution, hir::PathResolution::Def(hir::ModuleDef::BuiltinType(_)))
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})
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.map(|(node, resolved)| (node.text().len(), resolved))
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.max_by(|(a, _), (b, _)| a.cmp(b))
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.map(|(_, resolved)| resolved)
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}
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