//! A map of all publicly exported items in a crate. use std::{cmp::Ordering, fmt, hash::BuildHasherDefault, sync::Arc}; use base_db::CrateId; use fst::{self, Streamer}; use hir_expand::name::Name; use indexmap::{map::Entry, IndexMap}; use itertools::Itertools; use rustc_hash::{FxHashSet, FxHasher}; use crate::{ db::DefDatabase, item_scope::ItemInNs, visibility::Visibility, AssocItemId, ModuleDefId, ModuleId, TraitId, }; type FxIndexMap = IndexMap>; /// Item import details stored in the `ImportMap`. #[derive(Debug, Clone, Eq, PartialEq)] pub struct ImportInfo { /// A path that can be used to import the item, relative to the crate's root. pub path: ImportPath, /// The module containing this item. pub container: ModuleId, /// Whether the import is a trait associated item or not. pub is_assoc_item: bool, } #[derive(Debug, Clone, Eq, PartialEq)] pub struct ImportPath { pub segments: Vec, } impl fmt::Display for ImportPath { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { fmt::Display::fmt(&self.segments.iter().format("::"), f) } } impl ImportPath { fn len(&self) -> usize { self.segments.len() } } /// A map from publicly exported items to the path needed to import/name them from a downstream /// crate. /// /// Reexports of items are taken into account, ie. if something is exported under multiple /// names, the one with the shortest import path will be used. /// /// Note that all paths are relative to the containing crate's root, so the crate name still needs /// to be prepended to the `ModPath` before the path is valid. #[derive(Default)] pub struct ImportMap { map: FxIndexMap, /// List of keys stored in `map`, sorted lexicographically by their `ModPath`. Indexed by the /// values returned by running `fst`. /// /// Since a path can refer to multiple items due to namespacing, we store all items with the /// same path right after each other. This allows us to find all items after the FST gives us /// the index of the first one. importables: Vec, fst: fst::Map>, } impl ImportMap { pub fn import_map_query(db: &dyn DefDatabase, krate: CrateId) -> Arc { let _p = profile::span("import_map_query"); let def_map = db.crate_def_map(krate); let mut import_map = Self::default(); // We look only into modules that are public(ly reexported), starting with the crate root. let empty = ImportPath { segments: vec![] }; let root = ModuleId { krate, local_id: def_map.root }; let mut worklist = vec![(root, empty)]; while let Some((module, mod_path)) = worklist.pop() { let ext_def_map; let mod_data = if module.krate == krate { &def_map[module.local_id] } else { // The crate might reexport a module defined in another crate. ext_def_map = db.crate_def_map(module.krate); &ext_def_map[module.local_id] }; let visible_items = mod_data.scope.entries().filter_map(|(name, per_ns)| { let per_ns = per_ns.filter_visibility(|vis| vis == Visibility::Public); if per_ns.is_none() { None } else { Some((name, per_ns)) } }); for (name, per_ns) in visible_items { let mk_path = || { let mut path = mod_path.clone(); path.segments.push(name.clone()); path }; for item in per_ns.iter_items() { let path = mk_path(); let path_len = path.len(); let import_info = ImportInfo { path, container: module, is_assoc_item: false }; // If we've added a path to a trait, add the trait's associated items to the assoc map. if let Some(ModuleDefId::TraitId(tr)) = item.as_module_def_id() { import_map.collect_trait_assoc_items(db, tr, &import_info); } match import_map.map.entry(item) { Entry::Vacant(entry) => { entry.insert(import_info); } Entry::Occupied(mut entry) => { // If the new path is shorter, prefer that one. if path_len < entry.get().path.len() { *entry.get_mut() = import_info; } else { continue; } } } // If we've just added a path to a module, descend into it. We might traverse // modules multiple times, but only if the new path to it is shorter than the // first (else we `continue` above). if let Some(ModuleDefId::ModuleId(mod_id)) = item.as_module_def_id() { worklist.push((mod_id, mk_path())); } } } } let mut importables = import_map.map.iter().collect::>(); importables.sort_by(cmp); // Build the FST, taking care not to insert duplicate values. let mut builder = fst::MapBuilder::memory(); let mut last_batch_start = 0; for idx in 0..importables.len() { if let Some(next_item) = importables.get(idx + 1) { if cmp(&importables[last_batch_start], next_item) == Ordering::Equal { continue; } } let key = fst_path(&importables[last_batch_start].1.path); builder.insert(key, last_batch_start as u64).unwrap(); last_batch_start = idx + 1; } import_map.fst = fst::Map::new(builder.into_inner().unwrap()).unwrap(); import_map.importables = importables.iter().map(|(item, _)| **item).collect(); Arc::new(import_map) } /// Returns the `ModPath` needed to import/mention `item`, relative to this crate's root. pub fn path_of(&self, item: ItemInNs) -> Option<&ImportPath> { self.import_info_for(item).map(|it| &it.path) } pub fn import_info_for(&self, item: ItemInNs) -> Option<&ImportInfo> { self.map.get(&item) } fn collect_trait_assoc_items( &mut self, db: &dyn DefDatabase, tr: TraitId, import_info: &ImportInfo, ) { for (assoc_item_name, item) in db.trait_data(tr).items.iter() { let assoc_item = ItemInNs::Types(match item.clone() { AssocItemId::FunctionId(f) => f.into(), AssocItemId::ConstId(c) => c.into(), AssocItemId::TypeAliasId(t) => t.into(), }); let mut assoc_item_info = import_info.to_owned(); assoc_item_info.path.segments.push(assoc_item_name.to_owned()); assoc_item_info.is_assoc_item = true; self.map.insert(assoc_item, assoc_item_info); } } } impl PartialEq for ImportMap { fn eq(&self, other: &Self) -> bool { // `fst` and `importables` are built from `map`, so we don't need to compare them. self.map == other.map } } impl Eq for ImportMap {} impl fmt::Debug for ImportMap { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { let mut importable_paths: Vec<_> = self .map .iter() .map(|(item, info)| { let ns = match item { ItemInNs::Types(_) => "t", ItemInNs::Values(_) => "v", ItemInNs::Macros(_) => "m", }; format!("- {} ({})", info.path, ns) }) .collect(); importable_paths.sort(); f.write_str(&importable_paths.join("\n")) } } fn fst_path(path: &ImportPath) -> String { let mut s = path.to_string(); s.make_ascii_lowercase(); s } fn cmp((_, lhs): &(&ItemInNs, &ImportInfo), (_, rhs): &(&ItemInNs, &ImportInfo)) -> Ordering { let lhs_str = fst_path(&lhs.path); let rhs_str = fst_path(&rhs.path); lhs_str.cmp(&rhs_str) } #[derive(Debug, Eq, PartialEq, Hash)] pub enum ImportKind { Module, Function, Adt, EnumVariant, Const, Static, Trait, TypeAlias, BuiltinType, } /// A way to match import map contents against the search query. #[derive(Debug)] pub enum SearchMode { /// Import map entry should strictly match the query string. Equals, /// Import map entry should contain the query string. Contains, /// Import map entry should contain all letters from the query string, /// in the same order, but not necessary adjacent. Fuzzy, } #[derive(Debug)] pub struct Query { query: String, lowercased: String, name_only: bool, search_mode: SearchMode, case_sensitive: bool, limit: usize, exclude_import_kinds: FxHashSet, } impl Query { pub fn new(query: String) -> Self { let lowercased = query.to_lowercase(); Self { query, lowercased, name_only: false, search_mode: SearchMode::Contains, case_sensitive: false, limit: usize::max_value(), exclude_import_kinds: FxHashSet::default(), } } /// Matches entries' names only, ignoring the rest of /// the qualifier. /// Example: for `std::marker::PhantomData`, the name is `PhantomData`. pub fn name_only(self) -> Self { Self { name_only: true, ..self } } /// Specifies the way to search for the entries using the query. pub fn search_mode(self, search_mode: SearchMode) -> Self { Self { search_mode, ..self } } /// Limits the returned number of items to `limit`. pub fn limit(self, limit: usize) -> Self { Self { limit, ..self } } /// Respect casing of the query string when matching. pub fn case_sensitive(self) -> Self { Self { case_sensitive: true, ..self } } /// Do not include imports of the specified kind in the search results. pub fn exclude_import_kind(mut self, import_kind: ImportKind) -> Self { self.exclude_import_kinds.insert(import_kind); self } } fn import_matches_query(import: &ImportInfo, query: &Query, enforce_lowercase: bool) -> bool { let mut input = if import.is_assoc_item || query.name_only { import.path.segments.last().unwrap().to_string() } else { import.path.to_string() }; if enforce_lowercase || !query.case_sensitive { input.make_ascii_lowercase(); } let query_string = if !enforce_lowercase && query.case_sensitive { &query.query } else { &query.lowercased }; match query.search_mode { SearchMode::Equals => &input == query_string, SearchMode::Contains => input.contains(query_string), SearchMode::Fuzzy => { let mut unchecked_query_chars = query_string.chars(); let mut mismatching_query_char = unchecked_query_chars.next(); for input_char in input.chars() { match mismatching_query_char { None => return true, Some(matching_query_char) if matching_query_char == input_char => { mismatching_query_char = unchecked_query_chars.next(); } _ => (), } } mismatching_query_char.is_none() } } } /// Searches dependencies of `krate` for an importable path matching `query`. /// /// This returns a list of items that could be imported from dependencies of `krate`. pub fn search_dependencies<'a>( db: &'a dyn DefDatabase, krate: CrateId, query: Query, ) -> Vec { let _p = profile::span("search_dependencies").detail(|| format!("{:?}", query)); let graph = db.crate_graph(); let import_maps: Vec<_> = graph[krate].dependencies.iter().map(|dep| db.import_map(dep.crate_id)).collect(); let automaton = fst::automaton::Subsequence::new(&query.lowercased); let mut op = fst::map::OpBuilder::new(); for map in &import_maps { op = op.add(map.fst.search(&automaton)); } let mut stream = op.union(); let mut res = Vec::new(); while let Some((_, indexed_values)) = stream.next() { for indexed_value in indexed_values { let import_map = &import_maps[indexed_value.index]; let importables = &import_map.importables[indexed_value.value as usize..]; let common_importable_data = &import_map.map[&importables[0]]; if !import_matches_query(common_importable_data, &query, true) { continue; } // Path shared by the importable items in this group. let common_importables_path_fst = fst_path(&common_importable_data.path); // Add the items from this `ModPath` group. Those are all subsequent items in // `importables` whose paths match `path`. let iter = importables .iter() .copied() .take_while(|item| { common_importables_path_fst == fst_path(&import_map.map[item].path) }) .filter(|&item| match item_import_kind(item) { Some(import_kind) => !query.exclude_import_kinds.contains(&import_kind), None => true, }) .filter(|item| { !query.case_sensitive // we've already checked the common importables path case-insensitively || import_matches_query(&import_map.map[item], &query, false) }); res.extend(iter); if res.len() >= query.limit { res.truncate(query.limit); return res; } } } res } fn item_import_kind(item: ItemInNs) -> Option { Some(match item.as_module_def_id()? { ModuleDefId::ModuleId(_) => ImportKind::Module, ModuleDefId::FunctionId(_) => ImportKind::Function, ModuleDefId::AdtId(_) => ImportKind::Adt, ModuleDefId::EnumVariantId(_) => ImportKind::EnumVariant, ModuleDefId::ConstId(_) => ImportKind::Const, ModuleDefId::StaticId(_) => ImportKind::Static, ModuleDefId::TraitId(_) => ImportKind::Trait, ModuleDefId::TypeAliasId(_) => ImportKind::TypeAlias, ModuleDefId::BuiltinType(_) => ImportKind::BuiltinType, }) } #[cfg(test)] mod tests { use base_db::{fixture::WithFixture, SourceDatabase, Upcast}; use expect_test::{expect, Expect}; use crate::{test_db::TestDB, AssocContainerId, Lookup}; use super::*; fn check_search(ra_fixture: &str, crate_name: &str, query: Query, expect: Expect) { let db = TestDB::with_files(ra_fixture); let crate_graph = db.crate_graph(); let krate = crate_graph .iter() .find(|krate| { crate_graph[*krate].display_name.as_ref().map(|n| n.to_string()) == Some(crate_name.to_string()) }) .unwrap(); let actual = search_dependencies(db.upcast(), krate, query) .into_iter() .filter_map(|dependency| { let dependency_krate = dependency.krate(db.upcast())?; let dependency_imports = db.import_map(dependency_krate); let (path, mark) = match assoc_item_path(&db, &dependency_imports, dependency) { Some(assoc_item_path) => (assoc_item_path, "a"), None => ( dependency_imports.path_of(dependency)?.to_string(), match dependency { ItemInNs::Types(_) => "t", ItemInNs::Values(_) => "v", ItemInNs::Macros(_) => "m", }, ), }; Some(format!( "{}::{} ({})\n", crate_graph[dependency_krate].display_name.as_ref()?, path, mark )) }) .collect::(); expect.assert_eq(&actual) } fn assoc_item_path( db: &dyn DefDatabase, dependency_imports: &ImportMap, dependency: ItemInNs, ) -> Option { let dependency_assoc_item_id = dependency.as_assoc_item_id()?; let trait_ = assoc_to_trait(db, dependency)?; if let ModuleDefId::TraitId(tr) = trait_.as_module_def_id()? { let trait_data = db.trait_data(tr); let assoc_item_name = trait_data.items.iter().find_map(|(assoc_item_name, assoc_item_id)| { if &dependency_assoc_item_id == assoc_item_id { Some(assoc_item_name) } else { None } })?; return Some(format!("{}::{}", dependency_imports.path_of(trait_)?, assoc_item_name)); } None } fn assoc_to_trait(db: &dyn DefDatabase, item: ItemInNs) -> Option { let assoc: AssocItemId = match item { ItemInNs::Types(it) | ItemInNs::Values(it) => match it { ModuleDefId::TypeAliasId(it) => it.into(), ModuleDefId::FunctionId(it) => it.into(), ModuleDefId::ConstId(it) => it.into(), _ => return None, }, _ => return None, }; let container = match assoc { AssocItemId::FunctionId(it) => it.lookup(db).container, AssocItemId::ConstId(it) => it.lookup(db).container, AssocItemId::TypeAliasId(it) => it.lookup(db).container, }; match container { AssocContainerId::TraitId(it) => Some(ItemInNs::Types(it.into())), _ => None, } } fn check(ra_fixture: &str, expect: Expect) { let db = TestDB::with_files(ra_fixture); let crate_graph = db.crate_graph(); let actual = crate_graph .iter() .filter_map(|krate| { let cdata = &crate_graph[krate]; let name = cdata.display_name.as_ref()?; let map = db.import_map(krate); Some(format!("{}:\n{:?}\n", name, map)) }) .collect::(); expect.assert_eq(&actual) } #[test] fn smoke() { check( r" //- /main.rs crate:main deps:lib mod private { pub use lib::Pub; pub struct InPrivateModule; } pub mod publ1 { use lib::Pub; } pub mod real_pub { pub use lib::Pub; } pub mod real_pu2 { // same path length as above pub use lib::Pub; } //- /lib.rs crate:lib pub struct Pub {} pub struct Pub2; // t + v struct Priv; ", expect![[r#" main: - publ1 (t) - real_pu2 (t) - real_pub (t) - real_pub::Pub (t) lib: - Pub (t) - Pub2 (t) - Pub2 (v) "#]], ); } #[test] fn prefers_shortest_path() { check( r" //- /main.rs crate:main pub mod sub { pub mod subsub { pub struct Def {} } pub use super::sub::subsub::Def; } ", expect![[r#" main: - sub (t) - sub::Def (t) - sub::subsub (t) "#]], ); } #[test] fn type_reexport_cross_crate() { // Reexports need to be visible from a crate, even if the original crate exports the item // at a shorter path. check( r" //- /main.rs crate:main deps:lib pub mod m { pub use lib::S; } //- /lib.rs crate:lib pub struct S; ", expect![[r#" main: - m (t) - m::S (t) - m::S (v) lib: - S (t) - S (v) "#]], ); } #[test] fn macro_reexport() { check( r" //- /main.rs crate:main deps:lib pub mod m { pub use lib::pub_macro; } //- /lib.rs crate:lib #[macro_export] macro_rules! pub_macro { () => {}; } ", expect![[r#" main: - m (t) - m::pub_macro (m) lib: - pub_macro (m) "#]], ); } #[test] fn module_reexport() { // Reexporting modules from a dependency adds all contents to the import map. check( r" //- /main.rs crate:main deps:lib pub use lib::module as reexported_module; //- /lib.rs crate:lib pub mod module { pub struct S; } ", expect![[r#" main: - reexported_module (t) - reexported_module::S (t) - reexported_module::S (v) lib: - module (t) - module::S (t) - module::S (v) "#]], ); } #[test] fn cyclic_module_reexport() { // A cyclic reexport does not hang. check( r" //- /lib.rs crate:lib pub mod module { pub struct S; pub use super::sub::*; } pub mod sub { pub use super::module; } ", expect![[r#" lib: - module (t) - module::S (t) - module::S (v) - sub (t) "#]], ); } #[test] fn private_macro() { check( r" //- /lib.rs crate:lib macro_rules! private_macro { () => {}; } ", expect![[r#" lib: "#]], ); } #[test] fn namespacing() { check( r" //- /lib.rs crate:lib pub struct Thing; // t + v #[macro_export] macro_rules! Thing { // m () => {}; } ", expect![[r#" lib: - Thing (m) - Thing (t) - Thing (v) "#]], ); check( r" //- /lib.rs crate:lib pub mod Thing {} // t #[macro_export] macro_rules! Thing { // m () => {}; } ", expect![[r#" lib: - Thing (m) - Thing (t) "#]], ); } #[test] fn fuzzy_import_trait_and_assoc_items() { let ra_fixture = r#" //- /main.rs crate:main deps:dep //- /dep.rs crate:dep pub mod fmt { pub trait Display { type FmtTypeAlias; const FMT_CONST: bool; fn format_function(); fn format_method(&self); } } "#; check_search( ra_fixture, "main", Query::new("fmt".to_string()).search_mode(SearchMode::Fuzzy), expect![[r#" dep::fmt (t) dep::fmt::Display (t) dep::fmt::Display::FMT_CONST (a) dep::fmt::Display::FmtTypeAlias (a) dep::fmt::Display::format_function (a) dep::fmt::Display::format_method (a) "#]], ); } #[test] fn search_mode() { let ra_fixture = r#" //- /main.rs crate:main deps:dep //- /dep.rs crate:dep deps:tdep use tdep::fmt as fmt_dep; pub mod fmt { pub trait Display { fn fmt(); } } #[macro_export] macro_rules! Fmt { () => {}; } pub struct Fmt; pub fn format() {} pub fn no() {} //- /tdep.rs crate:tdep pub mod fmt { pub struct NotImportableFromMain; } "#; check_search( ra_fixture, "main", Query::new("fmt".to_string()).search_mode(SearchMode::Fuzzy), expect![[r#" dep::fmt (t) dep::Fmt (t) dep::Fmt (v) dep::Fmt (m) dep::fmt::Display (t) dep::fmt::Display::fmt (a) dep::format (v) "#]], ); check_search( ra_fixture, "main", Query::new("fmt".to_string()).search_mode(SearchMode::Equals), expect![[r#" dep::fmt (t) dep::Fmt (t) dep::Fmt (v) dep::Fmt (m) dep::fmt::Display::fmt (a) "#]], ); check_search( ra_fixture, "main", Query::new("fmt".to_string()).search_mode(SearchMode::Contains), expect![[r#" dep::fmt (t) dep::Fmt (t) dep::Fmt (v) dep::Fmt (m) dep::fmt::Display (t) dep::fmt::Display::fmt (a) "#]], ); } #[test] fn name_only() { let ra_fixture = r#" //- /main.rs crate:main deps:dep //- /dep.rs crate:dep deps:tdep use tdep::fmt as fmt_dep; pub mod fmt { pub trait Display { fn fmt(); } } #[macro_export] macro_rules! Fmt { () => {}; } pub struct Fmt; pub fn format() {} pub fn no() {} //- /tdep.rs crate:tdep pub mod fmt { pub struct NotImportableFromMain; } "#; check_search( ra_fixture, "main", Query::new("fmt".to_string()), expect![[r#" dep::fmt (t) dep::Fmt (t) dep::Fmt (v) dep::Fmt (m) dep::fmt::Display (t) dep::fmt::Display::fmt (a) "#]], ); check_search( ra_fixture, "main", Query::new("fmt".to_string()).name_only(), expect![[r#" dep::fmt (t) dep::Fmt (t) dep::Fmt (v) dep::Fmt (m) dep::fmt::Display::fmt (a) "#]], ); } #[test] fn search_casing() { let ra_fixture = r#" //- /main.rs crate:main deps:dep //- /dep.rs crate:dep pub struct fmt; pub struct FMT; "#; check_search( ra_fixture, "main", Query::new("FMT".to_string()), expect![[r#" dep::fmt (t) dep::fmt (v) dep::FMT (t) dep::FMT (v) "#]], ); check_search( ra_fixture, "main", Query::new("FMT".to_string()).case_sensitive(), expect![[r#" dep::FMT (t) dep::FMT (v) "#]], ); } #[test] fn search_limit() { check_search( r#" //- /main.rs crate:main deps:dep //- /dep.rs crate:dep pub mod fmt { pub trait Display { fn fmt(); } } #[macro_export] macro_rules! Fmt { () => {}; } pub struct Fmt; pub fn format() {} pub fn no() {} "#, "main", Query::new("".to_string()).limit(2), expect![[r#" dep::fmt (t) dep::Fmt (t) "#]], ); } #[test] fn search_exclusions() { let ra_fixture = r#" //- /main.rs crate:main deps:dep //- /dep.rs crate:dep pub struct fmt; pub struct FMT; "#; check_search( ra_fixture, "main", Query::new("FMT".to_string()), expect![[r#" dep::fmt (t) dep::fmt (v) dep::FMT (t) dep::FMT (v) "#]], ); check_search( ra_fixture, "main", Query::new("FMT".to_string()).exclude_import_kind(ImportKind::Adt), expect![[r#""#]], ); } }