107e07458c
In rust-analyzer, we avoid defualt impls for types which don't have sensible, "empty" defaults. In particular, we avoid using invalid indices for defaults and similar hacks.
473 lines
15 KiB
Rust
473 lines
15 KiB
Rust
//! This module implements import-resolution/macro expansion algorithm.
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//!
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//! The result of this module is `CrateDefMap`: a data structure which contains:
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//!
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//! * a tree of modules for the crate
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//! * for each module, a set of items visible in the module (directly declared
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//! or imported)
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//!
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//! Note that `CrateDefMap` contains fully macro expanded code.
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//!
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//! Computing `CrateDefMap` can be partitioned into several logically
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//! independent "phases". The phases are mutually recursive though, there's no
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//! strict ordering.
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//!
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//! ## Collecting RawItems
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//!
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//! This happens in the `raw` module, which parses a single source file into a
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//! set of top-level items. Nested imports are desugared to flat imports in this
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//! phase. Macro calls are represented as a triple of (Path, Option<Name>,
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//! TokenTree).
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//!
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//! ## Collecting Modules
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//!
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//! This happens in the `collector` module. In this phase, we recursively walk
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//! tree of modules, collect raw items from submodules, populate module scopes
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//! with defined items (so, we assign item ids in this phase) and record the set
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//! of unresolved imports and macros.
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//!
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//! While we walk tree of modules, we also record macro_rules definitions and
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//! expand calls to macro_rules defined macros.
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//!
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//! ## Resolving Imports
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//!
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//! We maintain a list of currently unresolved imports. On every iteration, we
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//! try to resolve some imports from this list. If the import is resolved, we
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//! record it, by adding an item to current module scope and, if necessary, by
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//! recursively populating glob imports.
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//!
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//! ## Resolving Macros
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//!
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//! macro_rules from the same crate use a global mutable namespace. We expand
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//! them immediately, when we collect modules.
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//!
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//! Macros from other crates (including proc-macros) can be used with
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//! `foo::bar!` syntax. We handle them similarly to imports. There's a list of
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//! unexpanded macros. On every iteration, we try to resolve each macro call
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//! path and, upon success, we run macro expansion and "collect module" phase on
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//! the result
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pub mod diagnostics;
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mod collector;
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mod mod_resolution;
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mod path_resolution;
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mod proc_macro;
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#[cfg(test)]
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mod tests;
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use std::sync::Arc;
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use base_db::{CrateId, Edition, FileId};
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use hir_expand::{name::Name, InFile, MacroDefId};
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use la_arena::Arena;
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use profile::Count;
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use rustc_hash::FxHashMap;
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use stdx::format_to;
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use syntax::ast;
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use crate::{
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db::DefDatabase,
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item_scope::{BuiltinShadowMode, ItemScope},
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nameres::{diagnostics::DefDiagnostic, path_resolution::ResolveMode},
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path::ModPath,
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per_ns::PerNs,
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AstId, BlockId, BlockLoc, LocalModuleId, ModuleDefId, ModuleId,
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};
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use self::proc_macro::ProcMacroDef;
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/// Contains the results of (early) name resolution.
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///
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/// A `DefMap` stores the module tree and the definitions that are in scope in every module after
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/// item-level macros have been expanded.
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///
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/// Every crate has a primary `DefMap` whose root is the crate's main file (`main.rs`/`lib.rs`),
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/// computed by the `crate_def_map` query. Additionally, every block expression introduces the
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/// opportunity to write arbitrary item and module hierarchies, and thus gets its own `DefMap` that
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/// is computed by the `block_def_map` query.
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#[derive(Debug, PartialEq, Eq)]
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pub struct DefMap {
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_c: Count<Self>,
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block: Option<BlockInfo>,
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root: LocalModuleId,
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modules: Arena<ModuleData>,
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krate: CrateId,
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/// The prelude module for this crate. This either comes from an import
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/// marked with the `prelude_import` attribute, or (in the normal case) from
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/// a dependency (`std` or `core`).
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prelude: Option<ModuleId>,
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extern_prelude: FxHashMap<Name, ModuleDefId>,
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/// Side table with additional proc. macro info, for use by name resolution in downstream
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/// crates.
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///
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/// (the primary purpose is to resolve derive helpers)
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exported_proc_macros: FxHashMap<MacroDefId, ProcMacroDef>,
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edition: Edition,
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diagnostics: Vec<DefDiagnostic>,
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}
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/// For `DefMap`s computed for a block expression, this stores its location in the parent map.
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#[derive(Debug, PartialEq, Eq, Clone, Copy)]
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struct BlockInfo {
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/// The `BlockId` this `DefMap` was created from.
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block: BlockId,
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/// The containing module.
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parent: ModuleId,
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}
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impl std::ops::Index<LocalModuleId> for DefMap {
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type Output = ModuleData;
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fn index(&self, id: LocalModuleId) -> &ModuleData {
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&self.modules[id]
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}
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}
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#[derive(Debug, PartialEq, Eq, Clone, Copy, Hash)]
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pub enum ModuleOrigin {
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CrateRoot {
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definition: FileId,
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},
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/// Note that non-inline modules, by definition, live inside non-macro file.
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File {
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is_mod_rs: bool,
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declaration: AstId<ast::Module>,
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definition: FileId,
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},
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Inline {
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definition: AstId<ast::Module>,
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},
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/// Pseudo-module introduced by a block scope (contains only inner items).
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BlockExpr {
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block: AstId<ast::BlockExpr>,
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},
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}
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impl ModuleOrigin {
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fn declaration(&self) -> Option<AstId<ast::Module>> {
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match self {
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ModuleOrigin::File { declaration: module, .. }
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| ModuleOrigin::Inline { definition: module, .. } => Some(*module),
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ModuleOrigin::CrateRoot { .. } | ModuleOrigin::BlockExpr { .. } => None,
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}
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}
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pub fn file_id(&self) -> Option<FileId> {
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match self {
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ModuleOrigin::File { definition, .. } | ModuleOrigin::CrateRoot { definition } => {
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Some(*definition)
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}
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_ => None,
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}
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}
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pub fn is_inline(&self) -> bool {
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match self {
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ModuleOrigin::Inline { .. } | ModuleOrigin::BlockExpr { .. } => true,
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ModuleOrigin::CrateRoot { .. } | ModuleOrigin::File { .. } => false,
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}
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}
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/// Returns a node which defines this module.
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/// That is, a file or a `mod foo {}` with items.
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fn definition_source(&self, db: &dyn DefDatabase) -> InFile<ModuleSource> {
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match self {
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ModuleOrigin::File { definition, .. } | ModuleOrigin::CrateRoot { definition } => {
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let file_id = *definition;
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let sf = db.parse(file_id).tree();
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InFile::new(file_id.into(), ModuleSource::SourceFile(sf))
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}
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ModuleOrigin::Inline { definition } => InFile::new(
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definition.file_id,
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ModuleSource::Module(definition.to_node(db.upcast())),
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),
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ModuleOrigin::BlockExpr { block } => {
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InFile::new(block.file_id, ModuleSource::BlockExpr(block.to_node(db.upcast())))
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}
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}
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}
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}
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#[derive(Debug, PartialEq, Eq)]
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pub struct ModuleData {
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pub parent: Option<LocalModuleId>,
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pub children: FxHashMap<Name, LocalModuleId>,
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pub scope: ItemScope,
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/// Where does this module come from?
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pub origin: ModuleOrigin,
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}
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impl Default for ModuleData {
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fn default() -> Self {
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ModuleData {
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parent: None,
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children: FxHashMap::default(),
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scope: ItemScope::default(),
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origin: ModuleOrigin::CrateRoot { definition: FileId(!0) },
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}
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}
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}
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impl DefMap {
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pub(crate) fn crate_def_map_query(db: &dyn DefDatabase, krate: CrateId) -> Arc<DefMap> {
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let _p = profile::span("crate_def_map_query").detail(|| {
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db.crate_graph()[krate].display_name.as_deref().unwrap_or_default().to_string()
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});
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let edition = db.crate_graph()[krate].edition;
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let def_map = DefMap::empty(krate, edition);
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let def_map = collector::collect_defs(db, def_map, None);
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Arc::new(def_map)
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}
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pub(crate) fn block_def_map_query(
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db: &dyn DefDatabase,
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block_id: BlockId,
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) -> Option<Arc<DefMap>> {
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let block: BlockLoc = db.lookup_intern_block(block_id);
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let item_tree = db.file_item_tree(block.ast_id.file_id);
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if item_tree.inner_items_of_block(block.ast_id.value).is_empty() {
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return None;
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}
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let block_info = BlockInfo { block: block_id, parent: block.module };
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let parent_map = block.module.def_map(db);
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let mut def_map = DefMap::empty(block.module.krate, parent_map.edition);
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def_map.block = Some(block_info);
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let def_map = collector::collect_defs(db, def_map, Some(block.ast_id));
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Some(Arc::new(def_map))
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}
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fn empty(krate: CrateId, edition: Edition) -> DefMap {
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let mut modules: Arena<ModuleData> = Arena::default();
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let root = modules.alloc(ModuleData::default());
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DefMap {
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_c: Count::new(),
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block: None,
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krate,
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edition,
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extern_prelude: FxHashMap::default(),
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exported_proc_macros: FxHashMap::default(),
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prelude: None,
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root,
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modules,
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diagnostics: Vec::new(),
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}
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}
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pub fn modules_for_file(&self, file_id: FileId) -> impl Iterator<Item = LocalModuleId> + '_ {
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self.modules
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.iter()
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.filter(move |(_id, data)| data.origin.file_id() == Some(file_id))
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.map(|(id, _data)| id)
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}
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pub fn modules(&self) -> impl Iterator<Item = (LocalModuleId, &ModuleData)> + '_ {
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self.modules.iter()
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}
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pub fn root(&self) -> LocalModuleId {
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self.root
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}
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pub(crate) fn krate(&self) -> CrateId {
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self.krate
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}
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pub(crate) fn block_id(&self) -> Option<BlockId> {
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self.block.as_ref().map(|block| block.block)
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}
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pub(crate) fn prelude(&self) -> Option<ModuleId> {
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self.prelude
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}
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pub(crate) fn extern_prelude(&self) -> impl Iterator<Item = (&Name, &ModuleDefId)> + '_ {
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self.extern_prelude.iter()
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}
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pub fn module_id(&self, local_id: LocalModuleId) -> ModuleId {
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let block = self.block.as_ref().map(|b| b.block);
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ModuleId { krate: self.krate, local_id, block }
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}
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pub(crate) fn crate_root(&self, db: &dyn DefDatabase) -> ModuleId {
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self.with_ancestor_maps(db, self.root, &mut |def_map, _module| {
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if def_map.block.is_none() {
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Some(def_map.module_id(def_map.root))
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} else {
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None
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}
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})
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.expect("DefMap chain without root")
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}
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pub(crate) fn resolve_path(
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&self,
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db: &dyn DefDatabase,
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original_module: LocalModuleId,
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path: &ModPath,
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shadow: BuiltinShadowMode,
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) -> (PerNs, Option<usize>) {
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let res =
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self.resolve_path_fp_with_macro(db, ResolveMode::Other, original_module, path, shadow);
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(res.resolved_def, res.segment_index)
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}
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pub(crate) fn resolve_path_locally(
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&self,
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db: &dyn DefDatabase,
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original_module: LocalModuleId,
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path: &ModPath,
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shadow: BuiltinShadowMode,
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) -> (PerNs, Option<usize>) {
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let res = self.resolve_path_fp_with_macro_single(
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db,
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ResolveMode::Other,
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original_module,
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path,
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shadow,
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);
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(res.resolved_def, res.segment_index)
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}
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/// Ascends the `DefMap` hierarchy and calls `f` with every `DefMap` and containing module.
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///
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/// If `f` returns `Some(val)`, iteration is stopped and `Some(val)` is returned. If `f` returns
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/// `None`, iteration continues.
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pub fn with_ancestor_maps<T>(
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&self,
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db: &dyn DefDatabase,
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local_mod: LocalModuleId,
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f: &mut dyn FnMut(&DefMap, LocalModuleId) -> Option<T>,
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) -> Option<T> {
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if let Some(it) = f(self, local_mod) {
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return Some(it);
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}
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let mut block = self.block;
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while let Some(block_info) = block {
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let parent = block_info.parent.def_map(db);
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if let Some(it) = f(&parent, block_info.parent.local_id) {
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return Some(it);
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}
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block = parent.block;
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}
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None
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}
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/// If this `DefMap` is for a block expression, returns the module containing the block (which
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/// might again be a block, or a module inside a block).
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pub fn parent(&self) -> Option<ModuleId> {
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Some(self.block?.parent)
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}
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/// Returns the module containing `local_mod`, either the parent `mod`, or the module containing
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/// the block, if `self` corresponds to a block expression.
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pub fn containing_module(&self, local_mod: LocalModuleId) -> Option<ModuleId> {
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match &self[local_mod].parent {
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Some(parent) => Some(self.module_id(*parent)),
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None => self.block.as_ref().map(|block| block.parent),
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}
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}
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// FIXME: this can use some more human-readable format (ideally, an IR
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// even), as this should be a great debugging aid.
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pub fn dump(&self, db: &dyn DefDatabase) -> String {
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let mut buf = String::new();
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let mut arc;
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let mut current_map = self;
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while let Some(block) = ¤t_map.block {
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go(&mut buf, current_map, "block scope", current_map.root);
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buf.push('\n');
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arc = block.parent.def_map(db);
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current_map = &*arc;
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}
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go(&mut buf, current_map, "crate", current_map.root);
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return buf;
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fn go(buf: &mut String, map: &DefMap, path: &str, module: LocalModuleId) {
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format_to!(buf, "{}\n", path);
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map.modules[module].scope.dump(buf);
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for (name, child) in map.modules[module].children.iter() {
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let path = format!("{}::{}", path, name);
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buf.push('\n');
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go(buf, map, &path, *child);
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}
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}
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}
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pub fn dump_block_scopes(&self, db: &dyn DefDatabase) -> String {
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let mut buf = String::new();
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let mut arc;
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let mut current_map = self;
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while let Some(block) = ¤t_map.block {
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format_to!(buf, "{:?} in {:?}\n", block.block, block.parent);
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arc = block.parent.def_map(db);
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current_map = &*arc;
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}
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format_to!(buf, "crate scope\n");
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buf
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}
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fn shrink_to_fit(&mut self) {
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// Exhaustive match to require handling new fields.
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let Self {
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_c: _,
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exported_proc_macros,
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extern_prelude,
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diagnostics,
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modules,
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block: _,
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edition: _,
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krate: _,
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prelude: _,
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root: _,
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} = self;
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extern_prelude.shrink_to_fit();
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exported_proc_macros.shrink_to_fit();
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diagnostics.shrink_to_fit();
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modules.shrink_to_fit();
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for (_, module) in modules.iter_mut() {
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module.children.shrink_to_fit();
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module.scope.shrink_to_fit();
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}
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}
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/// Get a reference to the def map's diagnostics.
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pub fn diagnostics(&self) -> &[DefDiagnostic] {
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self.diagnostics.as_slice()
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}
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}
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impl ModuleData {
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/// Returns a node which defines this module. That is, a file or a `mod foo {}` with items.
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pub fn definition_source(&self, db: &dyn DefDatabase) -> InFile<ModuleSource> {
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self.origin.definition_source(db)
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}
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/// Returns a node which declares this module, either a `mod foo;` or a `mod foo {}`.
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/// `None` for the crate root or block.
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pub fn declaration_source(&self, db: &dyn DefDatabase) -> Option<InFile<ast::Module>> {
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let decl = self.origin.declaration()?;
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let value = decl.to_node(db.upcast());
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Some(InFile { file_id: decl.file_id, value })
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}
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}
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#[derive(Debug, Clone, PartialEq, Eq)]
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pub enum ModuleSource {
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SourceFile(ast::SourceFile),
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Module(ast::Module),
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BlockExpr(ast::BlockExpr),
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}
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