//! For each definition, we track the following data. A definition //! here is defined somewhat circularly as "something with a `DefId`", //! but it generally corresponds to things like structs, enums, etc. //! There are also some rather random cases (like const initializer //! expressions) that are mostly just leftovers. pub use crate::def_id::DefPathHash; use crate::def_id::{CrateNum, DefId, DefIndex, LocalDefId, CRATE_DEF_INDEX, LOCAL_CRATE}; use crate::hir; use rustc_ast::crate_disambiguator::CrateDisambiguator; use rustc_data_structures::fx::FxHashMap; use rustc_data_structures::stable_hasher::StableHasher; use rustc_index::vec::IndexVec; use rustc_span::hygiene::ExpnId; use rustc_span::symbol::{kw, sym, Ident, Symbol}; use std::fmt::{self, Write}; use std::hash::Hash; use tracing::debug; /// The `DefPathTable` maps `DefIndex`es to `DefKey`s and vice versa. /// Internally the `DefPathTable` holds a tree of `DefKey`s, where each `DefKey` /// stores the `DefIndex` of its parent. /// There is one `DefPathTable` for each crate. #[derive(Clone, Default)] pub struct DefPathTable { index_to_key: IndexVec, def_path_hashes: IndexVec, } impl DefPathTable { fn allocate(&mut self, key: DefKey, def_path_hash: DefPathHash) -> DefIndex { let index = { let index = DefIndex::from(self.index_to_key.len()); debug!("DefPathTable::insert() - {:?} <-> {:?}", key, index); self.index_to_key.push(key); index }; self.def_path_hashes.push(def_path_hash); debug_assert!(self.def_path_hashes.len() == self.index_to_key.len()); index } #[inline(always)] pub fn def_key(&self, index: DefIndex) -> DefKey { self.index_to_key[index] } #[inline(always)] pub fn def_path_hash(&self, index: DefIndex) -> DefPathHash { let hash = self.def_path_hashes[index]; debug!("def_path_hash({:?}) = {:?}", index, hash); hash } pub fn num_def_ids(&self) -> usize { self.index_to_key.len() } pub fn enumerated_keys_and_path_hashes( &self, ) -> impl Iterator + '_ { self.index_to_key .iter_enumerated() .map(move |(index, key)| (index, key, &self.def_path_hashes[index])) } pub fn all_def_path_hashes_and_def_ids( &self, krate: CrateNum, ) -> impl Iterator + '_ { self.def_path_hashes .iter_enumerated() .map(move |(index, hash)| (*hash, DefId { krate, index })) } } /// The definition table containing node definitions. /// It holds the `DefPathTable` for `LocalDefId`s/`DefPath`s. /// It also stores mappings to convert `LocalDefId`s to/from `HirId`s. #[derive(Clone)] pub struct Definitions { table: DefPathTable, // FIXME(eddyb) ideally all `LocalDefId`s would be HIR owners. pub(super) def_id_to_hir_id: IndexVec>, /// The reverse mapping of `def_id_to_hir_id`. pub(super) hir_id_to_def_id: FxHashMap, /// If `ExpnId` is an ID of some macro expansion, /// then `DefId` is the normal module (`mod`) in which the expanded macro was defined. parent_modules_of_macro_defs: FxHashMap, /// Item with a given `LocalDefId` was defined during macro expansion with ID `ExpnId`. expansions_that_defined: FxHashMap, } /// A unique identifier that we can use to lookup a definition /// precisely. It combines the index of the definition's parent (if /// any) with a `DisambiguatedDefPathData`. #[derive(Copy, Clone, PartialEq, Debug, Encodable, Decodable)] pub struct DefKey { /// The parent path. pub parent: Option, /// The identifier of this node. pub disambiguated_data: DisambiguatedDefPathData, } impl DefKey { fn compute_stable_hash(&self, parent_hash: DefPathHash) -> DefPathHash { let mut hasher = StableHasher::new(); // We hash a `0u8` here to disambiguate between regular `DefPath` hashes, // and the special "root_parent" below. 0u8.hash(&mut hasher); parent_hash.hash(&mut hasher); let DisambiguatedDefPathData { ref data, disambiguator } = self.disambiguated_data; ::std::mem::discriminant(data).hash(&mut hasher); if let Some(name) = data.get_opt_name() { // Get a stable hash by considering the symbol chars rather than // the symbol index. name.as_str().hash(&mut hasher); } disambiguator.hash(&mut hasher); DefPathHash(hasher.finish()) } fn root_parent_stable_hash( crate_name: &str, crate_disambiguator: CrateDisambiguator, ) -> DefPathHash { let mut hasher = StableHasher::new(); // Disambiguate this from a regular `DefPath` hash; see `compute_stable_hash()` above. 1u8.hash(&mut hasher); crate_name.hash(&mut hasher); crate_disambiguator.hash(&mut hasher); DefPathHash(hasher.finish()) } } /// A pair of `DefPathData` and an integer disambiguator. The integer is /// normally `0`, but in the event that there are multiple defs with the /// same `parent` and `data`, we use this field to disambiguate /// between them. This introduces some artificial ordering dependency /// but means that if you have, e.g., two impls for the same type in /// the same module, they do get distinct `DefId`s. #[derive(Copy, Clone, PartialEq, Debug, Encodable, Decodable)] pub struct DisambiguatedDefPathData { pub data: DefPathData, pub disambiguator: u32, } impl DisambiguatedDefPathData { pub fn fmt_maybe_verbose(&self, writer: &mut impl Write, verbose: bool) -> fmt::Result { match self.data.name() { DefPathDataName::Named(name) => { if Ident::with_dummy_span(name).is_raw_guess() { writer.write_str("r#")?; } if verbose && self.disambiguator != 0 { write!(writer, "{}#{}", name, self.disambiguator) } else { writer.write_str(&name.as_str()) } } DefPathDataName::Anon { namespace } => { write!(writer, "{{{}#{}}}", namespace, self.disambiguator) } } } } impl fmt::Display for DisambiguatedDefPathData { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { self.fmt_maybe_verbose(f, true) } } #[derive(Clone, Debug, Encodable, Decodable)] pub struct DefPath { /// The path leading from the crate root to the item. pub data: Vec, /// The crate root this path is relative to. pub krate: CrateNum, } impl DefPath { pub fn is_local(&self) -> bool { self.krate == LOCAL_CRATE } pub fn make(krate: CrateNum, start_index: DefIndex, mut get_key: FN) -> DefPath where FN: FnMut(DefIndex) -> DefKey, { let mut data = vec![]; let mut index = Some(start_index); loop { debug!("DefPath::make: krate={:?} index={:?}", krate, index); let p = index.unwrap(); let key = get_key(p); debug!("DefPath::make: key={:?}", key); match key.disambiguated_data.data { DefPathData::CrateRoot => { assert!(key.parent.is_none()); break; } _ => { data.push(key.disambiguated_data); index = key.parent; } } } data.reverse(); DefPath { data, krate } } /// Returns a string representation of the `DefPath` without /// the crate-prefix. This method is useful if you don't have /// a `TyCtxt` available. pub fn to_string_no_crate_verbose(&self) -> String { let mut s = String::with_capacity(self.data.len() * 16); for component in &self.data { write!(s, "::{}", component).unwrap(); } s } /// Returns a filename-friendly string of the `DefPath`, without /// the crate-prefix. This method is useful if you don't have /// a `TyCtxt` available. pub fn to_filename_friendly_no_crate(&self) -> String { let mut s = String::with_capacity(self.data.len() * 16); let mut opt_delimiter = None; for component in &self.data { s.extend(opt_delimiter); opt_delimiter = Some('-'); write!(s, "{}", component).unwrap(); } s } } #[derive(Copy, Clone, Debug, PartialEq, Eq, Hash, Encodable, Decodable)] pub enum DefPathData { // Root: these should only be used for the root nodes, because // they are treated specially by the `def_path` function. /// The crate root (marker). CrateRoot, // Catch-all for random `DefId` things like `DUMMY_NODE_ID`. Misc, // Different kinds of items and item-like things: /// An impl. Impl, /// Something in the type namespace. TypeNs(Symbol), /// Something in the value namespace. ValueNs(Symbol), /// Something in the macro namespace. MacroNs(Symbol), /// Something in the lifetime namespace. LifetimeNs(Symbol), /// A closure expression. ClosureExpr, // Subportions of items: /// Implicit constructor for a unit or tuple-like struct or enum variant. Ctor, /// A constant expression (see `{ast,hir}::AnonConst`). AnonConst, /// An `impl Trait` type node. ImplTrait, } impl Definitions { pub fn def_path_table(&self) -> &DefPathTable { &self.table } /// Gets the number of definitions. pub fn def_index_count(&self) -> usize { self.table.index_to_key.len() } pub fn def_key(&self, id: LocalDefId) -> DefKey { self.table.def_key(id.local_def_index) } #[inline(always)] pub fn def_path_hash(&self, id: LocalDefId) -> DefPathHash { self.table.def_path_hash(id.local_def_index) } /// Returns the path from the crate root to `index`. The root /// nodes are not included in the path (i.e., this will be an /// empty vector for the crate root). For an inlined item, this /// will be the path of the item in the external crate (but the /// path will begin with the path to the external crate). pub fn def_path(&self, id: LocalDefId) -> DefPath { DefPath::make(LOCAL_CRATE, id.local_def_index, |index| { self.def_key(LocalDefId { local_def_index: index }) }) } #[inline] #[track_caller] pub fn local_def_id_to_hir_id(&self, id: LocalDefId) -> hir::HirId { self.def_id_to_hir_id[id].unwrap() } #[inline] pub fn opt_local_def_id_to_hir_id(&self, id: LocalDefId) -> Option { self.def_id_to_hir_id[id] } #[inline] pub fn opt_hir_id_to_local_def_id(&self, hir_id: hir::HirId) -> Option { self.hir_id_to_def_id.get(&hir_id).copied() } /// Adds a root definition (no parent) and a few other reserved definitions. pub fn new(crate_name: &str, crate_disambiguator: CrateDisambiguator) -> Definitions { let key = DefKey { parent: None, disambiguated_data: DisambiguatedDefPathData { data: DefPathData::CrateRoot, disambiguator: 0, }, }; let parent_hash = DefKey::root_parent_stable_hash(crate_name, crate_disambiguator); let def_path_hash = key.compute_stable_hash(parent_hash); // Create the root definition. let mut table = DefPathTable::default(); let root = LocalDefId { local_def_index: table.allocate(key, def_path_hash) }; assert_eq!(root.local_def_index, CRATE_DEF_INDEX); Definitions { table, def_id_to_hir_id: Default::default(), hir_id_to_def_id: Default::default(), expansions_that_defined: Default::default(), parent_modules_of_macro_defs: Default::default(), } } /// Retrieves the root definition. pub fn get_root_def(&self) -> LocalDefId { LocalDefId { local_def_index: CRATE_DEF_INDEX } } /// Adds a definition with a parent definition. pub fn create_def( &mut self, parent: LocalDefId, data: DefPathData, expn_id: ExpnId, mut next_disambiguator: impl FnMut(LocalDefId, DefPathData) -> u32, ) -> LocalDefId { debug!("create_def(parent={:?}, data={:?}, expn_id={:?})", parent, data, expn_id); // The root node must be created with `create_root_def()`. assert!(data != DefPathData::CrateRoot); let disambiguator = next_disambiguator(parent, data); let key = DefKey { parent: Some(parent.local_def_index), disambiguated_data: DisambiguatedDefPathData { data, disambiguator }, }; let parent_hash = self.table.def_path_hash(parent.local_def_index); let def_path_hash = key.compute_stable_hash(parent_hash); debug!("create_def: after disambiguation, key = {:?}", key); // Create the definition. let def_id = LocalDefId { local_def_index: self.table.allocate(key, def_path_hash) }; if expn_id != ExpnId::root() { self.expansions_that_defined.insert(def_id, expn_id); } def_id } /// Initializes the `LocalDefId` to `HirId` mapping once it has been generated during /// AST to HIR lowering. pub fn init_def_id_to_hir_id_mapping( &mut self, mapping: IndexVec>, ) { assert!( self.def_id_to_hir_id.is_empty(), "trying to initialize `LocalDefId` <-> `HirId` mappings twice" ); // Build the reverse mapping of `def_id_to_hir_id`. self.hir_id_to_def_id = mapping .iter_enumerated() .filter_map(|(def_id, hir_id)| hir_id.map(|hir_id| (hir_id, def_id))) .collect(); self.def_id_to_hir_id = mapping; } pub fn expansion_that_defined(&self, id: LocalDefId) -> ExpnId { self.expansions_that_defined.get(&id).copied().unwrap_or(ExpnId::root()) } pub fn parent_module_of_macro_def(&self, expn_id: ExpnId) -> DefId { self.parent_modules_of_macro_defs[&expn_id] } pub fn add_parent_module_of_macro_def(&mut self, expn_id: ExpnId, module: DefId) { self.parent_modules_of_macro_defs.insert(expn_id, module); } } #[derive(Copy, Clone, PartialEq, Debug)] pub enum DefPathDataName { Named(Symbol), Anon { namespace: Symbol }, } impl DefPathData { pub fn get_opt_name(&self) -> Option { use self::DefPathData::*; match *self { TypeNs(name) | ValueNs(name) | MacroNs(name) | LifetimeNs(name) => Some(name), Impl | CrateRoot | Misc | ClosureExpr | Ctor | AnonConst | ImplTrait => None, } } pub fn name(&self) -> DefPathDataName { use self::DefPathData::*; match *self { TypeNs(name) | ValueNs(name) | MacroNs(name) | LifetimeNs(name) => { DefPathDataName::Named(name) } // Note that this does not show up in user print-outs. CrateRoot => DefPathDataName::Anon { namespace: kw::Crate }, Impl => DefPathDataName::Anon { namespace: kw::Impl }, Misc => DefPathDataName::Anon { namespace: sym::misc }, ClosureExpr => DefPathDataName::Anon { namespace: sym::closure }, Ctor => DefPathDataName::Anon { namespace: sym::constructor }, AnonConst => DefPathDataName::Anon { namespace: sym::constant }, ImplTrait => DefPathDataName::Anon { namespace: sym::opaque }, } } } impl fmt::Display for DefPathData { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { match self.name() { DefPathDataName::Named(name) => f.write_str(&name.as_str()), // FIXME(#70334): this will generate legacy {{closure}}, {{impl}}, etc DefPathDataName::Anon { namespace } => write!(f, "{{{{{}}}}}", namespace), } } }