//! Type context book-keeping. use crate::arena::Arena; use crate::dep_graph::DepGraph; use crate::dep_graph::{self, DepNode, DepConstructor}; use crate::session::Session; use crate::session::config::{BorrowckMode, OutputFilenames}; use crate::session::config::CrateType; use crate::middle; use crate::hir::{self, TraitCandidate, HirId, ItemKind, ItemLocalId, Node}; use crate::hir::def::{Res, DefKind, Export}; use crate::hir::def_id::{CrateNum, DefId, DefIndex, LOCAL_CRATE}; use crate::hir::map as hir_map; use crate::hir::map::DefPathHash; use crate::lint::{self, Lint}; use crate::ich::{StableHashingContext, NodeIdHashingMode}; use crate::infer::canonical::{Canonical, CanonicalVarInfo, CanonicalVarInfos}; use crate::infer::outlives::free_region_map::FreeRegionMap; use crate::middle::cstore::CrateStoreDyn; use crate::middle::cstore::EncodedMetadata; use crate::middle::lang_items; use crate::middle::resolve_lifetime::{self, ObjectLifetimeDefault}; use crate::middle::stability; use crate::mir::{Body, interpret, PlaceElem, ProjectionKind, Promoted}; use crate::mir::interpret::{ConstValue, Allocation, Scalar}; use crate::ty::subst::{GenericArg, InternalSubsts, SubstsRef, Subst}; use crate::ty::ReprOptions; use crate::traits; use crate::traits::{Clause, Clauses, GoalKind, Goal, Goals}; use crate::ty::{self, DefIdTree, Ty, TypeAndMut}; use crate::ty::{TyS, TyKind, List}; use crate::ty::{AdtKind, AdtDef, Region, Const}; use crate::ty::{PolyFnSig, InferTy, ParamTy, ProjectionTy, ExistentialPredicate, Predicate}; use crate::ty::RegionKind; use crate::ty::{TyVar, TyVid, IntVar, IntVid, FloatVar, FloatVid, ConstVid}; use crate::ty::TyKind::*; use crate::ty::{InferConst, ParamConst}; use crate::ty::GenericParamDefKind; use crate::ty::layout::{LayoutDetails, TargetDataLayout, VariantIdx}; use crate::ty::query; use crate::ty::steal::Steal; use crate::ty::subst::{UserSubsts, GenericArgKind}; use crate::ty::{BoundVar, BindingMode}; use crate::ty::CanonicalPolyFnSig; use crate::util::common::ErrorReported; use crate::util::nodemap::{DefIdMap, DefIdSet, ItemLocalMap, ItemLocalSet, NodeMap}; use crate::util::nodemap::{FxHashMap, FxHashSet}; use crate::util::profiling::SelfProfilerRef; use errors::DiagnosticBuilder; use arena::SyncDroplessArena; use smallvec::SmallVec; use rustc_data_structures::stable_hasher::{ HashStable, StableHasher, StableVec, hash_stable_hashmap, }; use rustc_index::vec::{Idx, IndexVec}; use rustc_data_structures::sharded::ShardedHashMap; use rustc_data_structures::sync::{Lrc, Lock, WorkerLocal}; use std::any::Any; use std::borrow::Borrow; use std::cmp::Ordering; use std::collections::hash_map::{self, Entry}; use std::hash::{Hash, Hasher}; use std::fmt; use std::mem; use std::ops::{Deref, Bound}; use std::iter; use std::sync::Arc; use rustc_target::spec::abi; use rustc_macros::HashStable; use syntax::ast; use syntax::attr; use syntax::source_map::MultiSpan; use syntax::feature_gate; use syntax::symbol::{Symbol, InternedString, kw, sym}; use syntax_pos::Span; pub struct AllArenas { pub interner: SyncDroplessArena, } impl AllArenas { pub fn new() -> Self { AllArenas { interner: SyncDroplessArena::default(), } } } type InternedSet<'tcx, T> = ShardedHashMap, ()>; pub struct CtxtInterners<'tcx> { /// The arena that types, regions, etc. are allocated from. arena: &'tcx SyncDroplessArena, /// Specifically use a speedy hash algorithm for these hash sets, since /// they're accessed quite often. type_: InternedSet<'tcx, TyS<'tcx>>, type_list: InternedSet<'tcx, List>>, substs: InternedSet<'tcx, InternalSubsts<'tcx>>, canonical_var_infos: InternedSet<'tcx, List>, region: InternedSet<'tcx, RegionKind>, existential_predicates: InternedSet<'tcx, List>>, predicates: InternedSet<'tcx, List>>, clauses: InternedSet<'tcx, List>>, goal: InternedSet<'tcx, GoalKind<'tcx>>, goal_list: InternedSet<'tcx, List>>, projs: InternedSet<'tcx, List>, place_elems: InternedSet<'tcx, List>>, const_: InternedSet<'tcx, Const<'tcx>>, } impl<'tcx> CtxtInterners<'tcx> { fn new(arena: &'tcx SyncDroplessArena) -> CtxtInterners<'tcx> { CtxtInterners { arena, type_: Default::default(), type_list: Default::default(), substs: Default::default(), region: Default::default(), existential_predicates: Default::default(), canonical_var_infos: Default::default(), predicates: Default::default(), clauses: Default::default(), goal: Default::default(), goal_list: Default::default(), projs: Default::default(), place_elems: Default::default(), const_: Default::default(), } } /// Interns a type. #[allow(rustc::usage_of_ty_tykind)] #[inline(never)] fn intern_ty(&self, kind: TyKind<'tcx> ) -> Ty<'tcx> { self.type_.intern(kind, |kind| { let flags = super::flags::FlagComputation::for_kind(&kind); let ty_struct = TyS { kind, flags: flags.flags, outer_exclusive_binder: flags.outer_exclusive_binder, }; Interned(self.arena.alloc(ty_struct)) }).0 } } pub struct CommonTypes<'tcx> { pub unit: Ty<'tcx>, pub bool: Ty<'tcx>, pub char: Ty<'tcx>, pub isize: Ty<'tcx>, pub i8: Ty<'tcx>, pub i16: Ty<'tcx>, pub i32: Ty<'tcx>, pub i64: Ty<'tcx>, pub i128: Ty<'tcx>, pub usize: Ty<'tcx>, pub u8: Ty<'tcx>, pub u16: Ty<'tcx>, pub u32: Ty<'tcx>, pub u64: Ty<'tcx>, pub u128: Ty<'tcx>, pub f32: Ty<'tcx>, pub f64: Ty<'tcx>, pub never: Ty<'tcx>, pub self_param: Ty<'tcx>, pub err: Ty<'tcx>, /// Dummy type used for the `Self` of a `TraitRef` created for converting /// a trait object, and which gets removed in `ExistentialTraitRef`. /// This type must not appear anywhere in other converted types. pub trait_object_dummy_self: Ty<'tcx>, } pub struct CommonLifetimes<'tcx> { pub re_empty: Region<'tcx>, pub re_static: Region<'tcx>, pub re_erased: Region<'tcx>, } pub struct CommonConsts<'tcx> { pub err: &'tcx Const<'tcx>, } pub struct LocalTableInContext<'a, V> { local_id_root: Option, data: &'a ItemLocalMap } /// Validate that the given HirId (respectively its `local_id` part) can be /// safely used as a key in the tables of a TypeckTable. For that to be /// the case, the HirId must have the same `owner` as all the other IDs in /// this table (signified by `local_id_root`). Otherwise the HirId /// would be in a different frame of reference and using its `local_id` /// would result in lookup errors, or worse, in silently wrong data being /// stored/returned. fn validate_hir_id_for_typeck_tables(local_id_root: Option, hir_id: hir::HirId, mut_access: bool) { if let Some(local_id_root) = local_id_root { if hir_id.owner != local_id_root.index { ty::tls::with(|tcx| { bug!("node {} with HirId::owner {:?} cannot be placed in \ TypeckTables with local_id_root {:?}", tcx.hir().node_to_string(hir_id), DefId::local(hir_id.owner), local_id_root) }); } } else { // We use "Null Object" TypeckTables in some of the analysis passes. // These are just expected to be empty and their `local_id_root` is // `None`. Therefore we cannot verify whether a given `HirId` would // be a valid key for the given table. Instead we make sure that // nobody tries to write to such a Null Object table. if mut_access { bug!("access to invalid TypeckTables") } } } impl<'a, V> LocalTableInContext<'a, V> { pub fn contains_key(&self, id: hir::HirId) -> bool { validate_hir_id_for_typeck_tables(self.local_id_root, id, false); self.data.contains_key(&id.local_id) } pub fn get(&self, id: hir::HirId) -> Option<&V> { validate_hir_id_for_typeck_tables(self.local_id_root, id, false); self.data.get(&id.local_id) } pub fn iter(&self) -> hash_map::Iter<'_, hir::ItemLocalId, V> { self.data.iter() } } impl<'a, V> ::std::ops::Index for LocalTableInContext<'a, V> { type Output = V; fn index(&self, key: hir::HirId) -> &V { self.get(key).expect("LocalTableInContext: key not found") } } pub struct LocalTableInContextMut<'a, V> { local_id_root: Option, data: &'a mut ItemLocalMap } impl<'a, V> LocalTableInContextMut<'a, V> { pub fn get_mut(&mut self, id: hir::HirId) -> Option<&mut V> { validate_hir_id_for_typeck_tables(self.local_id_root, id, true); self.data.get_mut(&id.local_id) } pub fn entry(&mut self, id: hir::HirId) -> Entry<'_, hir::ItemLocalId, V> { validate_hir_id_for_typeck_tables(self.local_id_root, id, true); self.data.entry(id.local_id) } pub fn insert(&mut self, id: hir::HirId, val: V) -> Option { validate_hir_id_for_typeck_tables(self.local_id_root, id, true); self.data.insert(id.local_id, val) } pub fn remove(&mut self, id: hir::HirId) -> Option { validate_hir_id_for_typeck_tables(self.local_id_root, id, true); self.data.remove(&id.local_id) } } /// All information necessary to validate and reveal an `impl Trait`. #[derive(RustcEncodable, RustcDecodable, Debug, HashStable)] pub struct ResolvedOpaqueTy<'tcx> { /// The revealed type as seen by this function. pub concrete_type: Ty<'tcx>, /// Generic parameters on the opaque type as passed by this function. /// For `type Foo = impl Bar; fn foo() -> Foo { .. }` /// this is `[T, U]`, not `[A, B]`. pub substs: SubstsRef<'tcx>, } /// Whenever a value may be live across a generator yield, the type of that value winds up in the /// `GeneratorInteriorTypeCause` struct. This struct adds additional information about such /// captured types that can be useful for diagnostics. In particular, it stores the span that /// caused a given type to be recorded, along with the scope that enclosed the value (which can /// be used to find the await that the value is live across). /// /// For example: /// /// ```ignore (pseudo-Rust) /// async move { /// let x: T = ...; /// foo.await /// ... /// } /// ``` /// /// Here, we would store the type `T`, the span of the value `x`, and the "scope-span" for /// the scope that contains `x`. #[derive(RustcEncodable, RustcDecodable, Clone, Debug, Eq, Hash, HashStable, PartialEq)] pub struct GeneratorInteriorTypeCause<'tcx> { /// Type of the captured binding. pub ty: Ty<'tcx>, /// Span of the binding that was captured. pub span: Span, /// Span of the scope of the captured binding. pub scope_span: Option, } BraceStructTypeFoldableImpl! { impl<'tcx> TypeFoldable<'tcx> for GeneratorInteriorTypeCause<'tcx> { ty, span, scope_span } } #[derive(RustcEncodable, RustcDecodable, Debug)] pub struct TypeckTables<'tcx> { /// The HirId::owner all ItemLocalIds in this table are relative to. pub local_id_root: Option, /// Resolved definitions for `::X` associated paths and /// method calls, including those of overloaded operators. type_dependent_defs: ItemLocalMap>, /// Resolved field indices for field accesses in expressions (`S { field }`, `obj.field`) /// or patterns (`S { field }`). The index is often useful by itself, but to learn more /// about the field you also need definition of the variant to which the field /// belongs, but it may not exist if it's a tuple field (`tuple.0`). field_indices: ItemLocalMap, /// Stores the types for various nodes in the AST. Note that this table /// is not guaranteed to be populated until after typeck. See /// typeck::check::fn_ctxt for details. node_types: ItemLocalMap>, /// Stores the type parameters which were substituted to obtain the type /// of this node. This only applies to nodes that refer to entities /// parameterized by type parameters, such as generic fns, types, or /// other items. node_substs: ItemLocalMap>, /// This will either store the canonicalized types provided by the user /// or the substitutions that the user explicitly gave (if any) attached /// to `id`. These will not include any inferred values. The canonical form /// is used to capture things like `_` or other unspecified values. /// /// For example, if the user wrote `foo.collect::>()`, then the /// canonical substitutions would include only `for { Vec }`. /// /// See also `AscribeUserType` statement in MIR. user_provided_types: ItemLocalMap>, /// Stores the canonicalized types provided by the user. See also /// `AscribeUserType` statement in MIR. pub user_provided_sigs: DefIdMap>, adjustments: ItemLocalMap>>, /// Stores the actual binding mode for all instances of hir::BindingAnnotation. pat_binding_modes: ItemLocalMap, /// Stores the types which were implicitly dereferenced in pattern binding modes /// for later usage in HAIR lowering. For example, /// /// ``` /// match &&Some(5i32) { /// Some(n) => {}, /// _ => {}, /// } /// ``` /// leads to a `vec![&&Option, &Option]`. Empty vectors are not stored. /// /// See: /// https://github.com/rust-lang/rfcs/blob/master/text/2005-match-ergonomics.md#definitions pat_adjustments: ItemLocalMap>>, /// Borrows pub upvar_capture_map: ty::UpvarCaptureMap<'tcx>, /// Records the reasons that we picked the kind of each closure; /// not all closures are present in the map. closure_kind_origins: ItemLocalMap<(Span, ast::Name)>, /// For each fn, records the "liberated" types of its arguments /// and return type. Liberated means that all bound regions /// (including late-bound regions) are replaced with free /// equivalents. This table is not used in codegen (since regions /// are erased there) and hence is not serialized to metadata. liberated_fn_sigs: ItemLocalMap>, /// For each FRU expression, record the normalized types of the fields /// of the struct - this is needed because it is non-trivial to /// normalize while preserving regions. This table is used only in /// MIR construction and hence is not serialized to metadata. fru_field_types: ItemLocalMap>>, /// For every coercion cast we add the HIR node ID of the cast /// expression to this set. coercion_casts: ItemLocalSet, /// Set of trait imports actually used in the method resolution. /// This is used for warning unused imports. During type /// checking, this `Lrc` should not be cloned: it must have a ref-count /// of 1 so that we can insert things into the set mutably. pub used_trait_imports: Lrc, /// If any errors occurred while type-checking this body, /// this field will be set to `true`. pub tainted_by_errors: bool, /// Stores the free-region relationships that were deduced from /// its where-clauses and parameter types. These are then /// read-again by borrowck. pub free_region_map: FreeRegionMap<'tcx>, /// All the opaque types that are restricted to concrete types /// by this function. pub concrete_opaque_types: FxHashMap>, /// Given the closure ID this map provides the list of UpvarIDs used by it. /// The upvarID contains the HIR node ID and it also contains the full path /// leading to the member of the struct or tuple that is used instead of the /// entire variable. pub upvar_list: ty::UpvarListMap, /// Stores the type, span and optional scope span of all types /// that are live across the yield of this generator (if a generator). pub generator_interior_types: Vec>, } impl<'tcx> TypeckTables<'tcx> { pub fn empty(local_id_root: Option) -> TypeckTables<'tcx> { TypeckTables { local_id_root, type_dependent_defs: Default::default(), field_indices: Default::default(), user_provided_types: Default::default(), user_provided_sigs: Default::default(), node_types: Default::default(), node_substs: Default::default(), adjustments: Default::default(), pat_binding_modes: Default::default(), pat_adjustments: Default::default(), upvar_capture_map: Default::default(), closure_kind_origins: Default::default(), liberated_fn_sigs: Default::default(), fru_field_types: Default::default(), coercion_casts: Default::default(), used_trait_imports: Lrc::new(Default::default()), tainted_by_errors: false, free_region_map: Default::default(), concrete_opaque_types: Default::default(), upvar_list: Default::default(), generator_interior_types: Default::default(), } } /// Returns the final resolution of a `QPath` in an `Expr` or `Pat` node. pub fn qpath_res(&self, qpath: &hir::QPath, id: hir::HirId) -> Res { match *qpath { hir::QPath::Resolved(_, ref path) => path.res, hir::QPath::TypeRelative(..) => self.type_dependent_def(id) .map_or(Res::Err, |(kind, def_id)| Res::Def(kind, def_id)), } } pub fn type_dependent_defs( &self, ) -> LocalTableInContext<'_, Result<(DefKind, DefId), ErrorReported>> { LocalTableInContext { local_id_root: self.local_id_root, data: &self.type_dependent_defs } } pub fn type_dependent_def(&self, id: HirId) -> Option<(DefKind, DefId)> { validate_hir_id_for_typeck_tables(self.local_id_root, id, false); self.type_dependent_defs.get(&id.local_id).cloned().and_then(|r| r.ok()) } pub fn type_dependent_def_id(&self, id: HirId) -> Option { self.type_dependent_def(id).map(|(_, def_id)| def_id) } pub fn type_dependent_defs_mut( &mut self, ) -> LocalTableInContextMut<'_, Result<(DefKind, DefId), ErrorReported>> { LocalTableInContextMut { local_id_root: self.local_id_root, data: &mut self.type_dependent_defs } } pub fn field_indices(&self) -> LocalTableInContext<'_, usize> { LocalTableInContext { local_id_root: self.local_id_root, data: &self.field_indices } } pub fn field_indices_mut(&mut self) -> LocalTableInContextMut<'_, usize> { LocalTableInContextMut { local_id_root: self.local_id_root, data: &mut self.field_indices } } pub fn user_provided_types( &self ) -> LocalTableInContext<'_, CanonicalUserType<'tcx>> { LocalTableInContext { local_id_root: self.local_id_root, data: &self.user_provided_types } } pub fn user_provided_types_mut( &mut self ) -> LocalTableInContextMut<'_, CanonicalUserType<'tcx>> { LocalTableInContextMut { local_id_root: self.local_id_root, data: &mut self.user_provided_types } } pub fn node_types(&self) -> LocalTableInContext<'_, Ty<'tcx>> { LocalTableInContext { local_id_root: self.local_id_root, data: &self.node_types } } pub fn node_types_mut(&mut self) -> LocalTableInContextMut<'_, Ty<'tcx>> { LocalTableInContextMut { local_id_root: self.local_id_root, data: &mut self.node_types } } pub fn node_type(&self, id: hir::HirId) -> Ty<'tcx> { self.node_type_opt(id).unwrap_or_else(|| bug!("node_type: no type for node `{}`", tls::with(|tcx| tcx.hir().node_to_string(id))) ) } pub fn node_type_opt(&self, id: hir::HirId) -> Option> { validate_hir_id_for_typeck_tables(self.local_id_root, id, false); self.node_types.get(&id.local_id).cloned() } pub fn node_substs_mut(&mut self) -> LocalTableInContextMut<'_, SubstsRef<'tcx>> { LocalTableInContextMut { local_id_root: self.local_id_root, data: &mut self.node_substs } } pub fn node_substs(&self, id: hir::HirId) -> SubstsRef<'tcx> { validate_hir_id_for_typeck_tables(self.local_id_root, id, false); self.node_substs.get(&id.local_id).cloned().unwrap_or_else(|| InternalSubsts::empty()) } pub fn node_substs_opt(&self, id: hir::HirId) -> Option> { validate_hir_id_for_typeck_tables(self.local_id_root, id, false); self.node_substs.get(&id.local_id).cloned() } // Returns the type of a pattern as a monotype. Like @expr_ty, this function // doesn't provide type parameter substitutions. pub fn pat_ty(&self, pat: &hir::Pat) -> Ty<'tcx> { self.node_type(pat.hir_id) } pub fn pat_ty_opt(&self, pat: &hir::Pat) -> Option> { self.node_type_opt(pat.hir_id) } // Returns the type of an expression as a monotype. // // NB (1): This is the PRE-ADJUSTMENT TYPE for the expression. That is, in // some cases, we insert `Adjustment` annotations such as auto-deref or // auto-ref. The type returned by this function does not consider such // adjustments. See `expr_ty_adjusted()` instead. // // NB (2): This type doesn't provide type parameter substitutions; e.g., if you // ask for the type of "id" in "id(3)", it will return "fn(&isize) -> isize" // instead of "fn(ty) -> T with T = isize". pub fn expr_ty(&self, expr: &hir::Expr) -> Ty<'tcx> { self.node_type(expr.hir_id) } pub fn expr_ty_opt(&self, expr: &hir::Expr) -> Option> { self.node_type_opt(expr.hir_id) } pub fn adjustments(&self) -> LocalTableInContext<'_, Vec>> { LocalTableInContext { local_id_root: self.local_id_root, data: &self.adjustments } } pub fn adjustments_mut(&mut self) -> LocalTableInContextMut<'_, Vec>> { LocalTableInContextMut { local_id_root: self.local_id_root, data: &mut self.adjustments } } pub fn expr_adjustments(&self, expr: &hir::Expr) -> &[ty::adjustment::Adjustment<'tcx>] { validate_hir_id_for_typeck_tables(self.local_id_root, expr.hir_id, false); self.adjustments.get(&expr.hir_id.local_id).map_or(&[], |a| &a[..]) } /// Returns the type of `expr`, considering any `Adjustment` /// entry recorded for that expression. pub fn expr_ty_adjusted(&self, expr: &hir::Expr) -> Ty<'tcx> { self.expr_adjustments(expr) .last() .map_or_else(|| self.expr_ty(expr), |adj| adj.target) } pub fn expr_ty_adjusted_opt(&self, expr: &hir::Expr) -> Option> { self.expr_adjustments(expr) .last() .map(|adj| adj.target) .or_else(|| self.expr_ty_opt(expr)) } pub fn is_method_call(&self, expr: &hir::Expr) -> bool { // Only paths and method calls/overloaded operators have // entries in type_dependent_defs, ignore the former here. if let hir::ExprKind::Path(_) = expr.kind { return false; } match self.type_dependent_defs().get(expr.hir_id) { Some(Ok((DefKind::Method, _))) => true, _ => false } } pub fn pat_binding_modes(&self) -> LocalTableInContext<'_, BindingMode> { LocalTableInContext { local_id_root: self.local_id_root, data: &self.pat_binding_modes } } pub fn pat_binding_modes_mut(&mut self) -> LocalTableInContextMut<'_, BindingMode> { LocalTableInContextMut { local_id_root: self.local_id_root, data: &mut self.pat_binding_modes } } pub fn pat_adjustments(&self) -> LocalTableInContext<'_, Vec>> { LocalTableInContext { local_id_root: self.local_id_root, data: &self.pat_adjustments, } } pub fn pat_adjustments_mut(&mut self) -> LocalTableInContextMut<'_, Vec>> { LocalTableInContextMut { local_id_root: self.local_id_root, data: &mut self.pat_adjustments, } } pub fn upvar_capture(&self, upvar_id: ty::UpvarId) -> ty::UpvarCapture<'tcx> { self.upvar_capture_map[&upvar_id] } pub fn closure_kind_origins(&self) -> LocalTableInContext<'_, (Span, ast::Name)> { LocalTableInContext { local_id_root: self.local_id_root, data: &self.closure_kind_origins } } pub fn closure_kind_origins_mut(&mut self) -> LocalTableInContextMut<'_, (Span, ast::Name)> { LocalTableInContextMut { local_id_root: self.local_id_root, data: &mut self.closure_kind_origins } } pub fn liberated_fn_sigs(&self) -> LocalTableInContext<'_, ty::FnSig<'tcx>> { LocalTableInContext { local_id_root: self.local_id_root, data: &self.liberated_fn_sigs } } pub fn liberated_fn_sigs_mut(&mut self) -> LocalTableInContextMut<'_, ty::FnSig<'tcx>> { LocalTableInContextMut { local_id_root: self.local_id_root, data: &mut self.liberated_fn_sigs } } pub fn fru_field_types(&self) -> LocalTableInContext<'_, Vec>> { LocalTableInContext { local_id_root: self.local_id_root, data: &self.fru_field_types } } pub fn fru_field_types_mut(&mut self) -> LocalTableInContextMut<'_, Vec>> { LocalTableInContextMut { local_id_root: self.local_id_root, data: &mut self.fru_field_types } } pub fn is_coercion_cast(&self, hir_id: hir::HirId) -> bool { validate_hir_id_for_typeck_tables(self.local_id_root, hir_id, true); self.coercion_casts.contains(&hir_id.local_id) } pub fn set_coercion_cast(&mut self, id: ItemLocalId) { self.coercion_casts.insert(id); } pub fn coercion_casts(&self) -> &ItemLocalSet { &self.coercion_casts } } impl<'a, 'tcx> HashStable> for TypeckTables<'tcx> { fn hash_stable(&self, hcx: &mut StableHashingContext<'a>, hasher: &mut StableHasher) { let ty::TypeckTables { local_id_root, ref type_dependent_defs, ref field_indices, ref user_provided_types, ref user_provided_sigs, ref node_types, ref node_substs, ref adjustments, ref pat_binding_modes, ref pat_adjustments, ref upvar_capture_map, ref closure_kind_origins, ref liberated_fn_sigs, ref fru_field_types, ref coercion_casts, ref used_trait_imports, tainted_by_errors, ref free_region_map, ref concrete_opaque_types, ref upvar_list, ref generator_interior_types, } = *self; hcx.with_node_id_hashing_mode(NodeIdHashingMode::HashDefPath, |hcx| { type_dependent_defs.hash_stable(hcx, hasher); field_indices.hash_stable(hcx, hasher); user_provided_types.hash_stable(hcx, hasher); user_provided_sigs.hash_stable(hcx, hasher); node_types.hash_stable(hcx, hasher); node_substs.hash_stable(hcx, hasher); adjustments.hash_stable(hcx, hasher); pat_binding_modes.hash_stable(hcx, hasher); pat_adjustments.hash_stable(hcx, hasher); hash_stable_hashmap(hcx, hasher, upvar_capture_map, |up_var_id, hcx| { let ty::UpvarId { var_path, closure_expr_id } = *up_var_id; let local_id_root = local_id_root.expect("trying to hash invalid TypeckTables"); let var_owner_def_id = DefId { krate: local_id_root.krate, index: var_path.hir_id.owner, }; let closure_def_id = DefId { krate: local_id_root.krate, index: closure_expr_id.to_def_id().index, }; (hcx.def_path_hash(var_owner_def_id), var_path.hir_id.local_id, hcx.def_path_hash(closure_def_id)) }); closure_kind_origins.hash_stable(hcx, hasher); liberated_fn_sigs.hash_stable(hcx, hasher); fru_field_types.hash_stable(hcx, hasher); coercion_casts.hash_stable(hcx, hasher); used_trait_imports.hash_stable(hcx, hasher); tainted_by_errors.hash_stable(hcx, hasher); free_region_map.hash_stable(hcx, hasher); concrete_opaque_types.hash_stable(hcx, hasher); upvar_list.hash_stable(hcx, hasher); generator_interior_types.hash_stable(hcx, hasher); }) } } rustc_index::newtype_index! { pub struct UserTypeAnnotationIndex { derive [HashStable] DEBUG_FORMAT = "UserType({})", const START_INDEX = 0, } } /// Mapping of type annotation indices to canonical user type annotations. pub type CanonicalUserTypeAnnotations<'tcx> = IndexVec>; #[derive(Copy, Clone, Debug, PartialEq, Eq, Hash, RustcEncodable, RustcDecodable, HashStable)] pub struct CanonicalUserTypeAnnotation<'tcx> { pub user_ty: CanonicalUserType<'tcx>, pub span: Span, pub inferred_ty: Ty<'tcx>, } BraceStructTypeFoldableImpl! { impl<'tcx> TypeFoldable<'tcx> for CanonicalUserTypeAnnotation<'tcx> { user_ty, span, inferred_ty } } BraceStructLiftImpl! { impl<'a, 'tcx> Lift<'tcx> for CanonicalUserTypeAnnotation<'a> { type Lifted = CanonicalUserTypeAnnotation<'tcx>; user_ty, span, inferred_ty } } /// Canonicalized user type annotation. pub type CanonicalUserType<'tcx> = Canonical<'tcx, UserType<'tcx>>; impl CanonicalUserType<'tcx> { /// Returns `true` if this represents a substitution of the form `[?0, ?1, ?2]`, /// i.e., each thing is mapped to a canonical variable with the same index. pub fn is_identity(&self) -> bool { match self.value { UserType::Ty(_) => false, UserType::TypeOf(_, user_substs) => { if user_substs.user_self_ty.is_some() { return false; } user_substs.substs.iter().zip(BoundVar::new(0)..).all(|(kind, cvar)| { match kind.unpack() { GenericArgKind::Type(ty) => match ty.kind { ty::Bound(debruijn, b) => { // We only allow a `ty::INNERMOST` index in substitutions. assert_eq!(debruijn, ty::INNERMOST); cvar == b.var } _ => false, }, GenericArgKind::Lifetime(r) => match r { ty::ReLateBound(debruijn, br) => { // We only allow a `ty::INNERMOST` index in substitutions. assert_eq!(*debruijn, ty::INNERMOST); cvar == br.assert_bound_var() } _ => false, }, GenericArgKind::Const(ct) => match ct.val { ConstValue::Infer(InferConst::Canonical(debruijn, b)) => { // We only allow a `ty::INNERMOST` index in substitutions. assert_eq!(debruijn, ty::INNERMOST); cvar == b } _ => false, }, } }) }, } } } /// A user-given type annotation attached to a constant. These arise /// from constants that are named via paths, like `Foo::::new` and /// so forth. #[derive(Copy, Clone, Debug, PartialEq, Eq, Hash, RustcEncodable, RustcDecodable, HashStable)] pub enum UserType<'tcx> { Ty(Ty<'tcx>), /// The canonical type is the result of `type_of(def_id)` with the /// given substitutions applied. TypeOf(DefId, UserSubsts<'tcx>), } EnumTypeFoldableImpl! { impl<'tcx> TypeFoldable<'tcx> for UserType<'tcx> { (UserType::Ty)(ty), (UserType::TypeOf)(def, substs), } } EnumLiftImpl! { impl<'a, 'tcx> Lift<'tcx> for UserType<'a> { type Lifted = UserType<'tcx>; (UserType::Ty)(ty), (UserType::TypeOf)(def, substs), } } impl<'tcx> CommonTypes<'tcx> { fn new(interners: &CtxtInterners<'tcx>) -> CommonTypes<'tcx> { let mk = |ty| interners.intern_ty(ty); CommonTypes { unit: mk(Tuple(List::empty())), bool: mk(Bool), char: mk(Char), never: mk(Never), err: mk(Error), isize: mk(Int(ast::IntTy::Isize)), i8: mk(Int(ast::IntTy::I8)), i16: mk(Int(ast::IntTy::I16)), i32: mk(Int(ast::IntTy::I32)), i64: mk(Int(ast::IntTy::I64)), i128: mk(Int(ast::IntTy::I128)), usize: mk(Uint(ast::UintTy::Usize)), u8: mk(Uint(ast::UintTy::U8)), u16: mk(Uint(ast::UintTy::U16)), u32: mk(Uint(ast::UintTy::U32)), u64: mk(Uint(ast::UintTy::U64)), u128: mk(Uint(ast::UintTy::U128)), f32: mk(Float(ast::FloatTy::F32)), f64: mk(Float(ast::FloatTy::F64)), self_param: mk(ty::Param(ty::ParamTy { index: 0, name: kw::SelfUpper.as_interned_str(), })), trait_object_dummy_self: mk(Infer(ty::FreshTy(0))), } } } impl<'tcx> CommonLifetimes<'tcx> { fn new(interners: &CtxtInterners<'tcx>) -> CommonLifetimes<'tcx> { let mk = |r| { interners.region.intern(r, |r| { Interned(interners.arena.alloc(r)) }).0 }; CommonLifetimes { re_empty: mk(RegionKind::ReEmpty), re_static: mk(RegionKind::ReStatic), re_erased: mk(RegionKind::ReErased), } } } impl<'tcx> CommonConsts<'tcx> { fn new(interners: &CtxtInterners<'tcx>, types: &CommonTypes<'tcx>) -> CommonConsts<'tcx> { let mk_const = |c| { interners.const_.intern(c, |c| { Interned(interners.arena.alloc(c)) }).0 }; CommonConsts { err: mk_const(ty::Const { val: ConstValue::Scalar(Scalar::zst()), ty: types.err, }), } } } // This struct contains information regarding the `ReFree(FreeRegion)` corresponding to a lifetime // conflict. #[derive(Debug)] pub struct FreeRegionInfo { // def id corresponding to FreeRegion pub def_id: DefId, // the bound region corresponding to FreeRegion pub boundregion: ty::BoundRegion, // checks if bound region is in Impl Item pub is_impl_item: bool, } /// The central data structure of the compiler. It stores references /// to the various **arenas** and also houses the results of the /// various **compiler queries** that have been performed. See the /// [rustc guide] for more details. /// /// [rustc guide]: https://rust-lang.github.io/rustc-guide/ty.html #[derive(Copy, Clone)] #[rustc_diagnostic_item = "TyCtxt"] pub struct TyCtxt<'tcx> { gcx: &'tcx GlobalCtxt<'tcx>, } impl<'tcx> Deref for TyCtxt<'tcx> { type Target = &'tcx GlobalCtxt<'tcx>; #[inline(always)] fn deref(&self) -> &Self::Target { &self.gcx } } pub struct GlobalCtxt<'tcx> { pub arena: WorkerLocal>, interners: CtxtInterners<'tcx>, cstore: &'tcx CrateStoreDyn, pub sess: &'tcx Session, pub dep_graph: DepGraph, pub prof: SelfProfilerRef, /// Common types, pre-interned for your convenience. pub types: CommonTypes<'tcx>, /// Common lifetimes, pre-interned for your convenience. pub lifetimes: CommonLifetimes<'tcx>, /// Common consts, pre-interned for your convenience. pub consts: CommonConsts<'tcx>, /// Resolutions of `extern crate` items produced by resolver. extern_crate_map: NodeMap, /// Map indicating what traits are in scope for places where this /// is relevant; generated by resolve. trait_map: FxHashMap>>, /// Export map produced by name resolution. export_map: FxHashMap>>, hir_map: hir_map::Map<'tcx>, /// A map from `DefPathHash` -> `DefId`. Includes `DefId`s from the local crate /// as well as all upstream crates. Only populated in incremental mode. pub def_path_hash_to_def_id: Option>, pub queries: query::Queries<'tcx>, maybe_unused_trait_imports: FxHashSet, maybe_unused_extern_crates: Vec<(DefId, Span)>, /// A map of glob use to a set of names it actually imports. Currently only /// used in save-analysis. glob_map: FxHashMap>, /// Extern prelude entries. The value is `true` if the entry was introduced /// via `extern crate` item and not `--extern` option or compiler built-in. pub extern_prelude: FxHashMap, // Internal cache for metadata decoding. No need to track deps on this. pub rcache: Lock>>, /// Caches the results of trait selection. This cache is used /// for things that do not have to do with the parameters in scope. pub selection_cache: traits::SelectionCache<'tcx>, /// Caches the results of trait evaluation. This cache is used /// for things that do not have to do with the parameters in scope. /// Merge this with `selection_cache`? pub evaluation_cache: traits::EvaluationCache<'tcx>, /// The definite name of the current crate after taking into account /// attributes, commandline parameters, etc. pub crate_name: Symbol, /// Data layout specification for the current target. pub data_layout: TargetDataLayout, stability_interner: ShardedHashMap<&'tcx attr::Stability, ()>, /// Stores the value of constants (and deduplicates the actual memory) allocation_interner: ShardedHashMap<&'tcx Allocation, ()>, pub alloc_map: Lock>, layout_interner: ShardedHashMap<&'tcx LayoutDetails, ()>, output_filenames: Arc, } impl<'tcx> TyCtxt<'tcx> { #[inline(always)] pub fn hir(self) -> &'tcx hir_map::Map<'tcx> { &self.hir_map } pub fn alloc_steal_mir(self, mir: Body<'tcx>) -> &'tcx Steal> { self.arena.alloc(Steal::new(mir)) } pub fn alloc_steal_promoted(self, promoted: IndexVec>) -> &'tcx Steal>> { self.arena.alloc(Steal::new(promoted)) } pub fn intern_promoted(self, promoted: IndexVec>) -> &'tcx IndexVec> { self.arena.alloc(promoted) } pub fn alloc_adt_def( self, did: DefId, kind: AdtKind, variants: IndexVec, repr: ReprOptions, ) -> &'tcx ty::AdtDef { let def = ty::AdtDef::new(self, did, kind, variants, repr); self.arena.alloc(def) } pub fn intern_const_alloc(self, alloc: Allocation) -> &'tcx Allocation { self.allocation_interner.intern(alloc, |alloc| { self.arena.alloc(alloc) }) } /// Allocates a read-only byte or string literal for `mir::interpret`. pub fn allocate_bytes(self, bytes: &[u8]) -> interpret::AllocId { // Create an allocation that just contains these bytes. let alloc = interpret::Allocation::from_byte_aligned_bytes(bytes); let alloc = self.intern_const_alloc(alloc); self.alloc_map.lock().create_memory_alloc(alloc) } pub fn intern_stability(self, stab: attr::Stability) -> &'tcx attr::Stability { self.stability_interner.intern(stab, |stab| { self.arena.alloc(stab) }) } pub fn intern_layout(self, layout: LayoutDetails) -> &'tcx LayoutDetails { self.layout_interner.intern(layout, |layout| { self.arena.alloc(layout) }) } /// Returns a range of the start/end indices specified with the /// `rustc_layout_scalar_valid_range` attribute. pub fn layout_scalar_valid_range(self, def_id: DefId) -> (Bound, Bound) { let attrs = self.get_attrs(def_id); let get = |name| { let attr = match attrs.iter().find(|a| a.check_name(name)) { Some(attr) => attr, None => return Bound::Unbounded, }; for meta in attr.meta_item_list().expect("rustc_layout_scalar_valid_range takes args") { match meta.literal().expect("attribute takes lit").kind { ast::LitKind::Int(a, _) => return Bound::Included(a), _ => span_bug!(attr.span, "rustc_layout_scalar_valid_range expects int arg"), } } span_bug!(attr.span, "no arguments to `rustc_layout_scalar_valid_range` attribute"); }; (get(sym::rustc_layout_scalar_valid_range_start), get(sym::rustc_layout_scalar_valid_range_end)) } pub fn lift>(self, value: &T) -> Option { value.lift_to_tcx(self) } /// Creates a type context and call the closure with a `TyCtxt` reference /// to the context. The closure enforces that the type context and any interned /// value (types, substs, etc.) can only be used while `ty::tls` has a valid /// reference to the context, to allow formatting values that need it. pub fn create_global_ctxt( s: &'tcx Session, cstore: &'tcx CrateStoreDyn, local_providers: ty::query::Providers<'tcx>, extern_providers: ty::query::Providers<'tcx>, arenas: &'tcx AllArenas, resolutions: ty::Resolutions, hir: hir_map::Map<'tcx>, on_disk_query_result_cache: query::OnDiskCache<'tcx>, crate_name: &str, output_filenames: &OutputFilenames, ) -> GlobalCtxt<'tcx> { let data_layout = TargetDataLayout::parse(&s.target.target).unwrap_or_else(|err| { s.fatal(&err); }); let interners = CtxtInterners::new(&arenas.interner); let common_types = CommonTypes::new(&interners); let common_lifetimes = CommonLifetimes::new(&interners); let common_consts = CommonConsts::new(&interners, &common_types); let dep_graph = hir.dep_graph.clone(); let max_cnum = cstore.crates_untracked().iter().map(|c| c.as_usize()).max().unwrap_or(0); let mut providers = IndexVec::from_elem_n(extern_providers, max_cnum + 1); providers[LOCAL_CRATE] = local_providers; let def_path_hash_to_def_id = if s.opts.build_dep_graph() { let upstream_def_path_tables: Vec<(CrateNum, Lrc<_>)> = cstore .crates_untracked() .iter() .map(|&cnum| (cnum, cstore.def_path_table(cnum))) .collect(); let def_path_tables = || { upstream_def_path_tables .iter() .map(|&(cnum, ref rc)| (cnum, &**rc)) .chain(iter::once((LOCAL_CRATE, hir.definitions().def_path_table()))) }; // Precompute the capacity of the hashmap so we don't have to // re-allocate when populating it. let capacity = def_path_tables().map(|(_, t)| t.size()).sum::(); let mut map: FxHashMap<_, _> = FxHashMap::with_capacity_and_hasher( capacity, ::std::default::Default::default() ); for (cnum, def_path_table) in def_path_tables() { def_path_table.add_def_path_hashes_to(cnum, &mut map); } Some(map) } else { None }; let mut trait_map: FxHashMap<_, FxHashMap<_, _>> = FxHashMap::default(); for (k, v) in resolutions.trait_map { let hir_id = hir.node_to_hir_id(k); let map = trait_map.entry(hir_id.owner).or_default(); map.insert(hir_id.local_id, StableVec::new(v)); } GlobalCtxt { sess: s, cstore, arena: WorkerLocal::new(|_| Arena::default()), interners, dep_graph, prof: s.prof.clone(), types: common_types, lifetimes: common_lifetimes, consts: common_consts, extern_crate_map: resolutions.extern_crate_map, trait_map, export_map: resolutions.export_map.into_iter().map(|(k, v)| { let exports: Vec<_> = v.into_iter().map(|e| { e.map_id(|id| hir.node_to_hir_id(id)) }).collect(); (k, exports) }).collect(), maybe_unused_trait_imports: resolutions.maybe_unused_trait_imports .into_iter() .map(|id| hir.local_def_id_from_node_id(id)) .collect(), maybe_unused_extern_crates: resolutions.maybe_unused_extern_crates .into_iter() .map(|(id, sp)| (hir.local_def_id_from_node_id(id), sp)) .collect(), glob_map: resolutions.glob_map.into_iter().map(|(id, names)| { (hir.local_def_id_from_node_id(id), names) }).collect(), extern_prelude: resolutions.extern_prelude, hir_map: hir, def_path_hash_to_def_id, queries: query::Queries::new( providers, extern_providers, on_disk_query_result_cache, ), rcache: Default::default(), selection_cache: Default::default(), evaluation_cache: Default::default(), crate_name: Symbol::intern(crate_name), data_layout, layout_interner: Default::default(), stability_interner: Default::default(), allocation_interner: Default::default(), alloc_map: Lock::new(interpret::AllocMap::new()), output_filenames: Arc::new(output_filenames.clone()), } } pub fn consider_optimizing String>(&self, msg: T) -> bool { let cname = self.crate_name(LOCAL_CRATE).as_str(); self.sess.consider_optimizing(&cname, msg) } pub fn lib_features(self) -> &'tcx middle::lib_features::LibFeatures { self.get_lib_features(LOCAL_CRATE) } /// Obtain all lang items of this crate and all dependencies (recursively) pub fn lang_items(self) -> &'tcx middle::lang_items::LanguageItems { self.get_lang_items(LOCAL_CRATE) } /// Obtain the given diagnostic item's `DefId`. Use `is_diagnostic_item` if you just want to /// compare against another `DefId`, since `is_diagnostic_item` is cheaper. pub fn get_diagnostic_item(self, name: Symbol) -> Option { self.all_diagnostic_items(LOCAL_CRATE).get(&name).copied() } /// Check whether the diagnostic item with the given `name` has the given `DefId`. pub fn is_diagnostic_item(self, name: Symbol, did: DefId) -> bool { self.diagnostic_items(did.krate).get(&name) == Some(&did) } pub fn stability(self) -> &'tcx stability::Index<'tcx> { self.stability_index(LOCAL_CRATE) } pub fn crates(self) -> &'tcx [CrateNum] { self.all_crate_nums(LOCAL_CRATE) } pub fn features(self) -> &'tcx feature_gate::Features { self.features_query(LOCAL_CRATE) } pub fn def_key(self, id: DefId) -> hir_map::DefKey { if id.is_local() { self.hir().def_key(id) } else { self.cstore.def_key(id) } } /// Converts a `DefId` into its fully expanded `DefPath` (every /// `DefId` is really just an interned `DefPath`). /// /// Note that if `id` is not local to this crate, the result will /// be a non-local `DefPath`. pub fn def_path(self, id: DefId) -> hir_map::DefPath { if id.is_local() { self.hir().def_path(id) } else { self.cstore.def_path(id) } } /// Returns whether or not the crate with CrateNum 'cnum' /// is marked as a private dependency pub fn is_private_dep(self, cnum: CrateNum) -> bool { if cnum == LOCAL_CRATE { false } else { self.cstore.crate_is_private_dep_untracked(cnum) } } #[inline] pub fn def_path_hash(self, def_id: DefId) -> hir_map::DefPathHash { if def_id.is_local() { self.hir().definitions().def_path_hash(def_id.index) } else { self.cstore.def_path_hash(def_id) } } pub fn def_path_debug_str(self, def_id: DefId) -> String { // We are explicitly not going through queries here in order to get // crate name and disambiguator since this code is called from debug!() // statements within the query system and we'd run into endless // recursion otherwise. let (crate_name, crate_disambiguator) = if def_id.is_local() { (self.crate_name.clone(), self.sess.local_crate_disambiguator()) } else { (self.cstore.crate_name_untracked(def_id.krate), self.cstore.crate_disambiguator_untracked(def_id.krate)) }; format!("{}[{}]{}", crate_name, // Don't print the whole crate disambiguator. That's just // annoying in debug output. &(crate_disambiguator.to_fingerprint().to_hex())[..4], self.def_path(def_id).to_string_no_crate()) } pub fn metadata_encoding_version(self) -> Vec { self.cstore.metadata_encoding_version().to_vec() } pub fn encode_metadata(self)-> EncodedMetadata { self.cstore.encode_metadata(self) } // Note that this is *untracked* and should only be used within the query // system if the result is otherwise tracked through queries pub fn crate_data_as_rc_any(self, cnum: CrateNum) -> Lrc { self.cstore.crate_data_as_rc_any(cnum) } #[inline(always)] pub fn create_stable_hashing_context(self) -> StableHashingContext<'tcx> { let krate = self.gcx.hir_map.forest.untracked_krate(); StableHashingContext::new(self.sess, krate, self.hir().definitions(), self.cstore) } // This method makes sure that we have a DepNode and a Fingerprint for // every upstream crate. It needs to be called once right after the tcx is // created. // With full-fledged red/green, the method will probably become unnecessary // as this will be done on-demand. pub fn allocate_metadata_dep_nodes(self) { // We cannot use the query versions of crates() and crate_hash(), since // those would need the DepNodes that we are allocating here. for cnum in self.cstore.crates_untracked() { let dep_node = DepNode::new(self, DepConstructor::CrateMetadata(cnum)); let crate_hash = self.cstore.crate_hash_untracked(cnum); self.dep_graph.with_task(dep_node, self, crate_hash, |_, x| x, // No transformation needed dep_graph::hash_result, ); } } pub fn serialize_query_result_cache(self, encoder: &mut E) -> Result<(), E::Error> where E: ty::codec::TyEncoder { self.queries.on_disk_cache.serialize(self, encoder) } /// If `true`, we should use the MIR-based borrowck, but also /// fall back on the AST borrowck if the MIR-based one errors. pub fn migrate_borrowck(self) -> bool { self.borrowck_mode().migrate() } /// If `true`, make MIR codegen for `match` emit a temp that holds a /// borrow of the input to the match expression. pub fn generate_borrow_of_any_match_input(&self) -> bool { self.emit_read_for_match() } /// If `true`, make MIR codegen for `match` emit FakeRead /// statements (which simulate the maximal effect of executing the /// patterns in a match arm). pub fn emit_read_for_match(&self) -> bool { !self.sess.opts.debugging_opts.nll_dont_emit_read_for_match } /// What mode(s) of borrowck should we run? AST? MIR? both? /// (Also considers the `#![feature(nll)]` setting.) pub fn borrowck_mode(&self) -> BorrowckMode { // Here are the main constraints we need to deal with: // // 1. An opts.borrowck_mode of `BorrowckMode::Migrate` is // synonymous with no `-Z borrowck=...` flag at all. // // 2. We want to allow developers on the Nightly channel // to opt back into the "hard error" mode for NLL, // (which they can do via specifying `#![feature(nll)]` // explicitly in their crate). // // So, this precedence list is how pnkfelix chose to work with // the above constraints: // // * `#![feature(nll)]` *always* means use NLL with hard // errors. (To simplify the code here, it now even overrides // a user's attempt to specify `-Z borrowck=compare`, which // we arguably do not need anymore and should remove.) // // * Otherwise, if no `-Z borrowck=...` then use migrate mode // // * Otherwise, use the behavior requested via `-Z borrowck=...` if self.features().nll { return BorrowckMode::Mir; } self.sess.opts.borrowck_mode } #[inline] pub fn local_crate_exports_generics(self) -> bool { debug_assert!(self.sess.opts.share_generics()); self.sess.crate_types.borrow().iter().any(|crate_type| { match crate_type { CrateType::Executable | CrateType::Staticlib | CrateType::ProcMacro | CrateType::Dylib | CrateType::Cdylib => false, CrateType::Rlib => true, } }) } // Returns the `DefId` and the `BoundRegion` corresponding to the given region. pub fn is_suitable_region(&self, region: Region<'tcx>) -> Option { let (suitable_region_binding_scope, bound_region) = match *region { ty::ReFree(ref free_region) => (free_region.scope, free_region.bound_region), ty::ReEarlyBound(ref ebr) => ( self.parent(ebr.def_id).unwrap(), ty::BoundRegion::BrNamed(ebr.def_id, ebr.name), ), _ => return None, // not a free region }; let hir_id = self.hir() .as_local_hir_id(suitable_region_binding_scope) .unwrap(); let is_impl_item = match self.hir().find(hir_id) { Some(Node::Item(..)) | Some(Node::TraitItem(..)) => false, Some(Node::ImplItem(..)) => { self.is_bound_region_in_impl_item(suitable_region_binding_scope) } _ => return None, }; return Some(FreeRegionInfo { def_id: suitable_region_binding_scope, boundregion: bound_region, is_impl_item: is_impl_item, }); } pub fn return_type_impl_trait( &self, scope_def_id: DefId, ) -> Option> { // HACK: `type_of_def_id()` will fail on these (#55796), so return `None`. let hir_id = self.hir().as_local_hir_id(scope_def_id).unwrap(); match self.hir().get(hir_id) { Node::Item(item) => { match item.kind { ItemKind::Fn(..) => { /* `type_of_def_id()` will work */ } _ => { return None; } } } _ => { /* `type_of_def_id()` will work or panic */ } } let ret_ty = self.type_of(scope_def_id); match ret_ty.kind { ty::FnDef(_, _) => { let sig = ret_ty.fn_sig(*self); let output = self.erase_late_bound_regions(&sig.output()); if output.is_impl_trait() { Some(output) } else { None } } _ => None } } // Checks if the bound region is in Impl Item. pub fn is_bound_region_in_impl_item( &self, suitable_region_binding_scope: DefId, ) -> bool { let container_id = self.associated_item(suitable_region_binding_scope) .container .id(); if self.impl_trait_ref(container_id).is_some() { // For now, we do not try to target impls of traits. This is // because this message is going to suggest that the user // change the fn signature, but they may not be free to do so, // since the signature must match the trait. // // FIXME(#42706) -- in some cases, we could do better here. return true; } false } /// Determines whether identifiers in the assembly have strict naming rules. /// Currently, only NVPTX* targets need it. pub fn has_strict_asm_symbol_naming(&self) -> bool { self.sess.target.target.arch.contains("nvptx") } } impl<'tcx> GlobalCtxt<'tcx> { /// Calls the closure with a local `TyCtxt` using the given arena. /// `interners` is a slot passed so we can create a CtxtInterners /// with the same lifetime as `arena`. pub fn enter_local(&'tcx self, f: F) -> R where F: FnOnce(TyCtxt<'tcx>) -> R, { let tcx = TyCtxt { gcx: self, }; ty::tls::with_related_context(tcx, |icx| { let new_icx = ty::tls::ImplicitCtxt { tcx, query: icx.query.clone(), diagnostics: icx.diagnostics, layout_depth: icx.layout_depth, task_deps: icx.task_deps, }; ty::tls::enter_context(&new_icx, |_| { f(tcx) }) }) } } /// A trait implemented for all `X<'a>` types that can be safely and /// efficiently converted to `X<'tcx>` as long as they are part of the /// provided `TyCtxt<'tcx>`. /// This can be done, for example, for `Ty<'tcx>` or `SubstsRef<'tcx>` /// by looking them up in their respective interners. /// /// However, this is still not the best implementation as it does /// need to compare the components, even for interned values. /// It would be more efficient if `TypedArena` provided a way to /// determine whether the address is in the allocated range. /// /// `None` is returned if the value or one of the components is not part /// of the provided context. /// For `Ty`, `None` can be returned if either the type interner doesn't /// contain the `TyKind` key or if the address of the interned /// pointer differs. The latter case is possible if a primitive type, /// e.g., `()` or `u8`, was interned in a different context. pub trait Lift<'tcx>: fmt::Debug { type Lifted: fmt::Debug + 'tcx; fn lift_to_tcx(&self, tcx: TyCtxt<'tcx>) -> Option; } macro_rules! nop_lift { ($ty:ty => $lifted:ty) => { impl<'a, 'tcx> Lift<'tcx> for $ty { type Lifted = $lifted; fn lift_to_tcx(&self, tcx: TyCtxt<'tcx>) -> Option { if tcx.interners.arena.in_arena(*self as *const _) { Some(unsafe { mem::transmute(*self) }) } else { None } } } }; } macro_rules! nop_list_lift { ($ty:ty => $lifted:ty) => { impl<'a, 'tcx> Lift<'tcx> for &'a List<$ty> { type Lifted = &'tcx List<$lifted>; fn lift_to_tcx(&self, tcx: TyCtxt<'tcx>) -> Option { if self.is_empty() { return Some(List::empty()); } if tcx.interners.arena.in_arena(*self as *const _) { Some(unsafe { mem::transmute(*self) }) } else { None } } } }; } nop_lift!{Ty<'a> => Ty<'tcx>} nop_lift!{Region<'a> => Region<'tcx>} nop_lift!{Goal<'a> => Goal<'tcx>} nop_lift!{&'a Const<'a> => &'tcx Const<'tcx>} nop_list_lift!{Goal<'a> => Goal<'tcx>} nop_list_lift!{Clause<'a> => Clause<'tcx>} nop_list_lift!{Ty<'a> => Ty<'tcx>} nop_list_lift!{ExistentialPredicate<'a> => ExistentialPredicate<'tcx>} nop_list_lift!{Predicate<'a> => Predicate<'tcx>} nop_list_lift!{CanonicalVarInfo => CanonicalVarInfo} nop_list_lift!{ProjectionKind => ProjectionKind} // This is the impl for `&'a InternalSubsts<'a>`. nop_list_lift!{GenericArg<'a> => GenericArg<'tcx>} pub mod tls { use super::{GlobalCtxt, TyCtxt, ptr_eq}; use std::fmt; use std::mem; use syntax_pos; use crate::ty::query; use errors::{Diagnostic, TRACK_DIAGNOSTICS}; use rustc_data_structures::OnDrop; use rustc_data_structures::sync::{self, Lrc, Lock}; use rustc_data_structures::thin_vec::ThinVec; use crate::dep_graph::TaskDeps; #[cfg(not(parallel_compiler))] use std::cell::Cell; #[cfg(parallel_compiler)] use rustc_rayon_core as rayon_core; /// This is the implicit state of rustc. It contains the current /// `TyCtxt` and query. It is updated when creating a local interner or /// executing a new query. Whenever there's a `TyCtxt` value available /// you should also have access to an `ImplicitCtxt` through the functions /// in this module. #[derive(Clone)] pub struct ImplicitCtxt<'a, 'tcx> { /// The current `TyCtxt`. Initially created by `enter_global` and updated /// by `enter_local` with a new local interner. pub tcx: TyCtxt<'tcx>, /// The current query job, if any. This is updated by `JobOwner::start` in /// `ty::query::plumbing` when executing a query. pub query: Option>>, /// Where to store diagnostics for the current query job, if any. /// This is updated by `JobOwner::start` in `ty::query::plumbing` when executing a query. pub diagnostics: Option<&'a Lock>>, /// Used to prevent layout from recursing too deeply. pub layout_depth: usize, /// The current dep graph task. This is used to add dependencies to queries /// when executing them. pub task_deps: Option<&'a Lock>, } /// Sets Rayon's thread-local variable, which is preserved for Rayon jobs /// to `value` during the call to `f`. It is restored to its previous value after. /// This is used to set the pointer to the new `ImplicitCtxt`. #[cfg(parallel_compiler)] #[inline] fn set_tlv R, R>(value: usize, f: F) -> R { rayon_core::tlv::with(value, f) } /// Gets Rayon's thread-local variable, which is preserved for Rayon jobs. /// This is used to get the pointer to the current `ImplicitCtxt`. #[cfg(parallel_compiler)] #[inline] fn get_tlv() -> usize { rayon_core::tlv::get() } #[cfg(not(parallel_compiler))] thread_local! { /// A thread local variable that stores a pointer to the current `ImplicitCtxt`. static TLV: Cell = Cell::new(0); } /// Sets TLV to `value` during the call to `f`. /// It is restored to its previous value after. /// This is used to set the pointer to the new `ImplicitCtxt`. #[cfg(not(parallel_compiler))] #[inline] fn set_tlv R, R>(value: usize, f: F) -> R { let old = get_tlv(); let _reset = OnDrop(move || TLV.with(|tlv| tlv.set(old))); TLV.with(|tlv| tlv.set(value)); f() } /// Gets the pointer to the current `ImplicitCtxt`. #[cfg(not(parallel_compiler))] fn get_tlv() -> usize { TLV.with(|tlv| tlv.get()) } /// This is a callback from libsyntax as it cannot access the implicit state /// in librustc otherwise. fn span_debug(span: syntax_pos::Span, f: &mut fmt::Formatter<'_>) -> fmt::Result { with_opt(|tcx| { if let Some(tcx) = tcx { write!(f, "{}", tcx.sess.source_map().span_to_string(span)) } else { syntax_pos::default_span_debug(span, f) } }) } /// This is a callback from libsyntax as it cannot access the implicit state /// in librustc otherwise. It is used to when diagnostic messages are /// emitted and stores them in the current query, if there is one. fn track_diagnostic(diagnostic: &Diagnostic) { with_context_opt(|icx| { if let Some(icx) = icx { if let Some(ref diagnostics) = icx.diagnostics { let mut diagnostics = diagnostics.lock(); diagnostics.extend(Some(diagnostic.clone())); } } }) } /// Sets up the callbacks from libsyntax on the current thread. pub fn with_thread_locals(f: F) -> R where F: FnOnce() -> R { syntax_pos::SPAN_DEBUG.with(|span_dbg| { let original_span_debug = span_dbg.get(); span_dbg.set(span_debug); let _on_drop = OnDrop(move || { span_dbg.set(original_span_debug); }); TRACK_DIAGNOSTICS.with(|current| { let original = current.get(); current.set(track_diagnostic); let _on_drop = OnDrop(move || { current.set(original); }); f() }) }) } /// Sets `context` as the new current `ImplicitCtxt` for the duration of the function `f`. #[inline] pub fn enter_context<'a, 'tcx, F, R>(context: &ImplicitCtxt<'a, 'tcx>, f: F) -> R where F: FnOnce(&ImplicitCtxt<'a, 'tcx>) -> R, { set_tlv(context as *const _ as usize, || { f(&context) }) } /// Enters `GlobalCtxt` by setting up libsyntax callbacks and /// creating a initial `TyCtxt` and `ImplicitCtxt`. /// This happens once per rustc session and `TyCtxt`s only exists /// inside the `f` function. pub fn enter_global<'tcx, F, R>(gcx: &'tcx GlobalCtxt<'tcx>, f: F) -> R where F: FnOnce(TyCtxt<'tcx>) -> R, { // Update `GCX_PTR` to indicate there's a `GlobalCtxt` available. GCX_PTR.with(|lock| { *lock.lock() = gcx as *const _ as usize; }); // Set `GCX_PTR` back to 0 when we exit. let _on_drop = OnDrop(move || { GCX_PTR.with(|lock| *lock.lock() = 0); }); let tcx = TyCtxt { gcx, }; let icx = ImplicitCtxt { tcx, query: None, diagnostics: None, layout_depth: 0, task_deps: None, }; enter_context(&icx, |_| { f(tcx) }) } scoped_thread_local! { /// Stores a pointer to the `GlobalCtxt` if one is available. /// This is used to access the `GlobalCtxt` in the deadlock handler given to Rayon. pub static GCX_PTR: Lock } /// Creates a `TyCtxt` and `ImplicitCtxt` based on the `GCX_PTR` thread local. /// This is used in the deadlock handler. pub unsafe fn with_global(f: F) -> R where F: for<'tcx> FnOnce(TyCtxt<'tcx>) -> R, { let gcx = GCX_PTR.with(|lock| *lock.lock()); assert!(gcx != 0); let gcx = &*(gcx as *const GlobalCtxt<'_>); let tcx = TyCtxt { gcx, }; let icx = ImplicitCtxt { query: None, diagnostics: None, tcx, layout_depth: 0, task_deps: None, }; enter_context(&icx, |_| f(tcx)) } /// Allows access to the current `ImplicitCtxt` in a closure if one is available. #[inline] pub fn with_context_opt(f: F) -> R where F: for<'a, 'tcx> FnOnce(Option<&ImplicitCtxt<'a, 'tcx>>) -> R, { let context = get_tlv(); if context == 0 { f(None) } else { // We could get a `ImplicitCtxt` pointer from another thread. // Ensure that `ImplicitCtxt` is `Sync`. sync::assert_sync::>(); unsafe { f(Some(&*(context as *const ImplicitCtxt<'_, '_>))) } } } /// Allows access to the current `ImplicitCtxt`. /// Panics if there is no `ImplicitCtxt` available. #[inline] pub fn with_context(f: F) -> R where F: for<'a, 'tcx> FnOnce(&ImplicitCtxt<'a, 'tcx>) -> R, { with_context_opt(|opt_context| f(opt_context.expect("no ImplicitCtxt stored in tls"))) } /// Allows access to the current `ImplicitCtxt` whose tcx field has the same global /// interner as the tcx argument passed in. This means the closure is given an `ImplicitCtxt` /// with the same `'tcx` lifetime as the `TyCtxt` passed in. /// This will panic if you pass it a `TyCtxt` which has a different global interner from /// the current `ImplicitCtxt`'s `tcx` field. #[inline] pub fn with_related_context<'tcx, F, R>(tcx: TyCtxt<'tcx>, f: F) -> R where F: FnOnce(&ImplicitCtxt<'_, 'tcx>) -> R, { with_context(|context| { unsafe { assert!(ptr_eq(context.tcx.gcx, tcx.gcx)); let context: &ImplicitCtxt<'_, '_> = mem::transmute(context); f(context) } }) } /// Allows access to the `TyCtxt` in the current `ImplicitCtxt`. /// Panics if there is no `ImplicitCtxt` available. #[inline] pub fn with(f: F) -> R where F: for<'tcx> FnOnce(TyCtxt<'tcx>) -> R, { with_context(|context| f(context.tcx)) } /// Allows access to the `TyCtxt` in the current `ImplicitCtxt`. /// The closure is passed None if there is no `ImplicitCtxt` available. #[inline] pub fn with_opt(f: F) -> R where F: for<'tcx> FnOnce(Option>) -> R, { with_context_opt(|opt_context| f(opt_context.map(|context| context.tcx))) } } macro_rules! sty_debug_print { ($ctxt: expr, $($variant: ident),*) => {{ // Curious inner module to allow variant names to be used as // variable names. #[allow(non_snake_case)] mod inner { use crate::ty::{self, TyCtxt}; use crate::ty::context::Interned; #[derive(Copy, Clone)] struct DebugStat { total: usize, lt_infer: usize, ty_infer: usize, ct_infer: usize, all_infer: usize, } pub fn go(tcx: TyCtxt<'_>) { let mut total = DebugStat { total: 0, lt_infer: 0, ty_infer: 0, ct_infer: 0, all_infer: 0, }; $(let mut $variant = total;)* let shards = tcx.interners.type_.lock_shards(); let types = shards.iter().flat_map(|shard| shard.keys()); for &Interned(t) in types { let variant = match t.kind { ty::Bool | ty::Char | ty::Int(..) | ty::Uint(..) | ty::Float(..) | ty::Str | ty::Never => continue, ty::Error => /* unimportant */ continue, $(ty::$variant(..) => &mut $variant,)* }; let lt = t.flags.intersects(ty::TypeFlags::HAS_RE_INFER); let ty = t.flags.intersects(ty::TypeFlags::HAS_TY_INFER); let ct = t.flags.intersects(ty::TypeFlags::HAS_CT_INFER); variant.total += 1; total.total += 1; if lt { total.lt_infer += 1; variant.lt_infer += 1 } if ty { total.ty_infer += 1; variant.ty_infer += 1 } if ct { total.ct_infer += 1; variant.ct_infer += 1 } if lt && ty && ct { total.all_infer += 1; variant.all_infer += 1 } } println!("Ty interner total ty lt ct all"); $(println!(" {:18}: {uses:6} {usespc:4.1}%, \ {ty:4.1}% {lt:5.1}% {ct:4.1}% {all:4.1}%", stringify!($variant), uses = $variant.total, usespc = $variant.total as f64 * 100.0 / total.total as f64, ty = $variant.ty_infer as f64 * 100.0 / total.total as f64, lt = $variant.lt_infer as f64 * 100.0 / total.total as f64, ct = $variant.ct_infer as f64 * 100.0 / total.total as f64, all = $variant.all_infer as f64 * 100.0 / total.total as f64); )* println!(" total {uses:6} \ {ty:4.1}% {lt:5.1}% {ct:4.1}% {all:4.1}%", uses = total.total, ty = total.ty_infer as f64 * 100.0 / total.total as f64, lt = total.lt_infer as f64 * 100.0 / total.total as f64, ct = total.ct_infer as f64 * 100.0 / total.total as f64, all = total.all_infer as f64 * 100.0 / total.total as f64) } } inner::go($ctxt) }} } impl<'tcx> TyCtxt<'tcx> { pub fn print_debug_stats(self) { sty_debug_print!( self, Adt, Array, Slice, RawPtr, Ref, FnDef, FnPtr, Placeholder, Generator, GeneratorWitness, Dynamic, Closure, Tuple, Bound, Param, Infer, UnnormalizedProjection, Projection, Opaque, Foreign); println!("InternalSubsts interner: #{}", self.interners.substs.len()); println!("Region interner: #{}", self.interners.region.len()); println!("Stability interner: #{}", self.stability_interner.len()); println!("Allocation interner: #{}", self.allocation_interner.len()); println!("Layout interner: #{}", self.layout_interner.len()); } } /// An entry in an interner. struct Interned<'tcx, T: ?Sized>(&'tcx T); impl<'tcx, T: 'tcx+?Sized> Clone for Interned<'tcx, T> { fn clone(&self) -> Self { Interned(self.0) } } impl<'tcx, T: 'tcx+?Sized> Copy for Interned<'tcx, T> {} // N.B., an `Interned` compares and hashes as a `TyKind`. impl<'tcx> PartialEq for Interned<'tcx, TyS<'tcx>> { fn eq(&self, other: &Interned<'tcx, TyS<'tcx>>) -> bool { self.0.kind == other.0.kind } } impl<'tcx> Eq for Interned<'tcx, TyS<'tcx>> {} impl<'tcx> Hash for Interned<'tcx, TyS<'tcx>> { fn hash(&self, s: &mut H) { self.0.kind.hash(s) } } #[allow(rustc::usage_of_ty_tykind)] impl<'tcx> Borrow> for Interned<'tcx, TyS<'tcx>> { fn borrow<'a>(&'a self) -> &'a TyKind<'tcx> { &self.0.kind } } // N.B., an `Interned>` compares and hashes as its elements. impl<'tcx, T: PartialEq> PartialEq for Interned<'tcx, List> { fn eq(&self, other: &Interned<'tcx, List>) -> bool { self.0[..] == other.0[..] } } impl<'tcx, T: Eq> Eq for Interned<'tcx, List> {} impl<'tcx, T: Hash> Hash for Interned<'tcx, List> { fn hash(&self, s: &mut H) { self.0[..].hash(s) } } impl<'tcx> Borrow<[Ty<'tcx>]> for Interned<'tcx, List>> { fn borrow<'a>(&'a self) -> &'a [Ty<'tcx>] { &self.0[..] } } impl<'tcx> Borrow<[CanonicalVarInfo]> for Interned<'tcx, List> { fn borrow(&self) -> &[CanonicalVarInfo] { &self.0[..] } } impl<'tcx> Borrow<[GenericArg<'tcx>]> for Interned<'tcx, InternalSubsts<'tcx>> { fn borrow<'a>(&'a self) -> &'a [GenericArg<'tcx>] { &self.0[..] } } impl<'tcx> Borrow<[ProjectionKind]> for Interned<'tcx, List> { fn borrow(&self) -> &[ProjectionKind] { &self.0[..] } } impl<'tcx> Borrow<[PlaceElem<'tcx>]> for Interned<'tcx, List>> { fn borrow(&self) -> &[PlaceElem<'tcx>] { &self.0[..] } } impl<'tcx> Borrow for Interned<'tcx, RegionKind> { fn borrow(&self) -> &RegionKind { &self.0 } } impl<'tcx> Borrow> for Interned<'tcx, GoalKind<'tcx>> { fn borrow<'a>(&'a self) -> &'a GoalKind<'tcx> { &self.0 } } impl<'tcx> Borrow<[ExistentialPredicate<'tcx>]> for Interned<'tcx, List>> { fn borrow<'a>(&'a self) -> &'a [ExistentialPredicate<'tcx>] { &self.0[..] } } impl<'tcx> Borrow<[Predicate<'tcx>]> for Interned<'tcx, List>> { fn borrow<'a>(&'a self) -> &'a [Predicate<'tcx>] { &self.0[..] } } impl<'tcx> Borrow> for Interned<'tcx, Const<'tcx>> { fn borrow<'a>(&'a self) -> &'a Const<'tcx> { &self.0 } } impl<'tcx> Borrow<[Clause<'tcx>]> for Interned<'tcx, List>> { fn borrow<'a>(&'a self) -> &'a [Clause<'tcx>] { &self.0[..] } } impl<'tcx> Borrow<[Goal<'tcx>]> for Interned<'tcx, List>> { fn borrow<'a>(&'a self) -> &'a [Goal<'tcx>] { &self.0[..] } } macro_rules! direct_interners { ($($name:ident: $method:ident($ty:ty)),+) => { $(impl<'tcx> PartialEq for Interned<'tcx, $ty> { fn eq(&self, other: &Self) -> bool { self.0 == other.0 } } impl<'tcx> Eq for Interned<'tcx, $ty> {} impl<'tcx> Hash for Interned<'tcx, $ty> { fn hash(&self, s: &mut H) { self.0.hash(s) } } impl<'tcx> TyCtxt<'tcx> { pub fn $method(self, v: $ty) -> &'tcx $ty { self.interners.$name.intern_ref(&v, || { Interned(self.interners.arena.alloc(v)) }).0 } })+ } } pub fn keep_local<'tcx, T: ty::TypeFoldable<'tcx>>(x: &T) -> bool { x.has_type_flags(ty::TypeFlags::KEEP_IN_LOCAL_TCX) } direct_interners!( region: mk_region(RegionKind), goal: mk_goal(GoalKind<'tcx>), const_: mk_const(Const<'tcx>) ); macro_rules! slice_interners { ($($field:ident: $method:ident($ty:ty)),+) => ( $(impl<'tcx> TyCtxt<'tcx> { pub fn $method(self, v: &[$ty]) -> &'tcx List<$ty> { self.interners.$field.intern_ref(v, || { Interned(List::from_arena(&self.interners.arena, v)) }).0 } })+ ); } slice_interners!( type_list: _intern_type_list(Ty<'tcx>), substs: _intern_substs(GenericArg<'tcx>), canonical_var_infos: _intern_canonical_var_infos(CanonicalVarInfo), existential_predicates: _intern_existential_predicates(ExistentialPredicate<'tcx>), predicates: _intern_predicates(Predicate<'tcx>), clauses: _intern_clauses(Clause<'tcx>), goal_list: _intern_goals(Goal<'tcx>), projs: _intern_projs(ProjectionKind), place_elems: _intern_place_elems(PlaceElem<'tcx>) ); impl<'tcx> TyCtxt<'tcx> { /// Given a `fn` type, returns an equivalent `unsafe fn` type; /// that is, a `fn` type that is equivalent in every way for being /// unsafe. pub fn safe_to_unsafe_fn_ty(self, sig: PolyFnSig<'tcx>) -> Ty<'tcx> { assert_eq!(sig.unsafety(), hir::Unsafety::Normal); self.mk_fn_ptr(sig.map_bound(|sig| ty::FnSig { unsafety: hir::Unsafety::Unsafe, ..sig })) } /// Given a closure signature `sig`, returns an equivalent `fn` /// type with the same signature. Detuples and so forth -- so /// e.g., if we have a sig with `Fn<(u32, i32)>` then you would get /// a `fn(u32, i32)`. /// `unsafety` determines the unsafety of the `fn` type. If you pass /// `hir::Unsafety::Unsafe` in the previous example, then you would get /// an `unsafe fn (u32, i32)`. /// It cannot convert a closure that requires unsafe. pub fn coerce_closure_fn_ty(self, sig: PolyFnSig<'tcx>, unsafety: hir::Unsafety) -> Ty<'tcx> { let converted_sig = sig.map_bound(|s| { let params_iter = match s.inputs()[0].kind { ty::Tuple(params) => { params.into_iter().map(|k| k.expect_ty()) } _ => bug!(), }; self.mk_fn_sig( params_iter, s.output(), s.c_variadic, unsafety, abi::Abi::Rust, ) }); self.mk_fn_ptr(converted_sig) } #[allow(rustc::usage_of_ty_tykind)] #[inline] pub fn mk_ty(&self, st: TyKind<'tcx>) -> Ty<'tcx> { self.interners.intern_ty(st) } pub fn mk_mach_int(self, tm: ast::IntTy) -> Ty<'tcx> { match tm { ast::IntTy::Isize => self.types.isize, ast::IntTy::I8 => self.types.i8, ast::IntTy::I16 => self.types.i16, ast::IntTy::I32 => self.types.i32, ast::IntTy::I64 => self.types.i64, ast::IntTy::I128 => self.types.i128, } } pub fn mk_mach_uint(self, tm: ast::UintTy) -> Ty<'tcx> { match tm { ast::UintTy::Usize => self.types.usize, ast::UintTy::U8 => self.types.u8, ast::UintTy::U16 => self.types.u16, ast::UintTy::U32 => self.types.u32, ast::UintTy::U64 => self.types.u64, ast::UintTy::U128 => self.types.u128, } } pub fn mk_mach_float(self, tm: ast::FloatTy) -> Ty<'tcx> { match tm { ast::FloatTy::F32 => self.types.f32, ast::FloatTy::F64 => self.types.f64, } } #[inline] pub fn mk_str(self) -> Ty<'tcx> { self.mk_ty(Str) } #[inline] pub fn mk_static_str(self) -> Ty<'tcx> { self.mk_imm_ref(self.lifetimes.re_static, self.mk_str()) } #[inline] pub fn mk_adt(self, def: &'tcx AdtDef, substs: SubstsRef<'tcx>) -> Ty<'tcx> { // Take a copy of substs so that we own the vectors inside. self.mk_ty(Adt(def, substs)) } #[inline] pub fn mk_foreign(self, def_id: DefId) -> Ty<'tcx> { self.mk_ty(Foreign(def_id)) } fn mk_generic_adt(self, wrapper_def_id: DefId, ty_param: Ty<'tcx>) -> Ty<'tcx> { let adt_def = self.adt_def(wrapper_def_id); let substs = InternalSubsts::for_item(self, wrapper_def_id, |param, substs| { match param.kind { GenericParamDefKind::Lifetime | GenericParamDefKind::Const => { bug!() } GenericParamDefKind::Type { has_default, .. } => { if param.index == 0 { ty_param.into() } else { assert!(has_default); self.type_of(param.def_id).subst(self, substs).into() } } } }); self.mk_ty(Adt(adt_def, substs)) } #[inline] pub fn mk_box(self, ty: Ty<'tcx>) -> Ty<'tcx> { let def_id = self.require_lang_item(lang_items::OwnedBoxLangItem, None); self.mk_generic_adt(def_id, ty) } #[inline] pub fn mk_lang_item(self, ty: Ty<'tcx>, item: lang_items::LangItem) -> Option> { let def_id = self.lang_items().require(item).ok()?; Some(self.mk_generic_adt(def_id, ty)) } #[inline] pub fn mk_maybe_uninit(self, ty: Ty<'tcx>) -> Ty<'tcx> { let def_id = self.require_lang_item(lang_items::MaybeUninitLangItem, None); self.mk_generic_adt(def_id, ty) } #[inline] pub fn mk_ptr(self, tm: TypeAndMut<'tcx>) -> Ty<'tcx> { self.mk_ty(RawPtr(tm)) } #[inline] pub fn mk_ref(self, r: Region<'tcx>, tm: TypeAndMut<'tcx>) -> Ty<'tcx> { self.mk_ty(Ref(r, tm.ty, tm.mutbl)) } #[inline] pub fn mk_mut_ref(self, r: Region<'tcx>, ty: Ty<'tcx>) -> Ty<'tcx> { self.mk_ref(r, TypeAndMut {ty: ty, mutbl: hir::MutMutable}) } #[inline] pub fn mk_imm_ref(self, r: Region<'tcx>, ty: Ty<'tcx>) -> Ty<'tcx> { self.mk_ref(r, TypeAndMut {ty: ty, mutbl: hir::MutImmutable}) } #[inline] pub fn mk_mut_ptr(self, ty: Ty<'tcx>) -> Ty<'tcx> { self.mk_ptr(TypeAndMut {ty: ty, mutbl: hir::MutMutable}) } #[inline] pub fn mk_imm_ptr(self, ty: Ty<'tcx>) -> Ty<'tcx> { self.mk_ptr(TypeAndMut {ty: ty, mutbl: hir::MutImmutable}) } #[inline] pub fn mk_nil_ptr(self) -> Ty<'tcx> { self.mk_imm_ptr(self.mk_unit()) } #[inline] pub fn mk_array(self, ty: Ty<'tcx>, n: u64) -> Ty<'tcx> { self.mk_ty(Array(ty, ty::Const::from_usize(self, n))) } #[inline] pub fn mk_slice(self, ty: Ty<'tcx>) -> Ty<'tcx> { self.mk_ty(Slice(ty)) } #[inline] pub fn intern_tup(self, ts: &[Ty<'tcx>]) -> Ty<'tcx> { let kinds: Vec<_> = ts.into_iter().map(|&t| GenericArg::from(t)).collect(); self.mk_ty(Tuple(self.intern_substs(&kinds))) } pub fn mk_tup], Ty<'tcx>>>(self, iter: I) -> I::Output { iter.intern_with(|ts| { let kinds: Vec<_> = ts.into_iter().map(|&t| GenericArg::from(t)).collect(); self.mk_ty(Tuple(self.intern_substs(&kinds))) }) } #[inline] pub fn mk_unit(self) -> Ty<'tcx> { self.types.unit } #[inline] pub fn mk_diverging_default(self) -> Ty<'tcx> { if self.features().never_type { self.types.never } else { self.intern_tup(&[]) } } #[inline] pub fn mk_bool(self) -> Ty<'tcx> { self.mk_ty(Bool) } #[inline] pub fn mk_fn_def(self, def_id: DefId, substs: SubstsRef<'tcx>) -> Ty<'tcx> { self.mk_ty(FnDef(def_id, substs)) } #[inline] pub fn mk_fn_ptr(self, fty: PolyFnSig<'tcx>) -> Ty<'tcx> { self.mk_ty(FnPtr(fty)) } #[inline] pub fn mk_dynamic( self, obj: ty::Binder<&'tcx List>>, reg: ty::Region<'tcx> ) -> Ty<'tcx> { self.mk_ty(Dynamic(obj, reg)) } #[inline] pub fn mk_projection(self, item_def_id: DefId, substs: SubstsRef<'tcx>) -> Ty<'tcx> { self.mk_ty(Projection(ProjectionTy { item_def_id, substs, })) } #[inline] pub fn mk_closure(self, closure_id: DefId, closure_substs: SubstsRef<'tcx>) -> Ty<'tcx> { self.mk_ty(Closure(closure_id, closure_substs)) } #[inline] pub fn mk_generator(self, id: DefId, generator_substs: SubstsRef<'tcx>, movability: hir::GeneratorMovability) -> Ty<'tcx> { self.mk_ty(Generator(id, generator_substs, movability)) } #[inline] pub fn mk_generator_witness(self, types: ty::Binder<&'tcx List>>) -> Ty<'tcx> { self.mk_ty(GeneratorWitness(types)) } #[inline] pub fn mk_ty_var(self, v: TyVid) -> Ty<'tcx> { self.mk_ty_infer(TyVar(v)) } #[inline] pub fn mk_const_var(self, v: ConstVid<'tcx>, ty: Ty<'tcx>) -> &'tcx Const<'tcx> { self.mk_const(ty::Const { val: ConstValue::Infer(InferConst::Var(v)), ty, }) } #[inline] pub fn mk_int_var(self, v: IntVid) -> Ty<'tcx> { self.mk_ty_infer(IntVar(v)) } #[inline] pub fn mk_float_var(self, v: FloatVid) -> Ty<'tcx> { self.mk_ty_infer(FloatVar(v)) } #[inline] pub fn mk_ty_infer(self, it: InferTy) -> Ty<'tcx> { self.mk_ty(Infer(it)) } #[inline] pub fn mk_const_infer( self, ic: InferConst<'tcx>, ty: Ty<'tcx>, ) -> &'tcx ty::Const<'tcx> { self.mk_const(ty::Const { val: ConstValue::Infer(ic), ty, }) } #[inline] pub fn mk_ty_param(self, index: u32, name: InternedString) -> Ty<'tcx> { self.mk_ty(Param(ParamTy { index, name: name })) } #[inline] pub fn mk_const_param( self, index: u32, name: InternedString, ty: Ty<'tcx> ) -> &'tcx Const<'tcx> { self.mk_const(ty::Const { val: ConstValue::Param(ParamConst { index, name }), ty, }) } pub fn mk_param_from_def(self, param: &ty::GenericParamDef) -> GenericArg<'tcx> { match param.kind { GenericParamDefKind::Lifetime => { self.mk_region(ty::ReEarlyBound(param.to_early_bound_region_data())).into() } GenericParamDefKind::Type { .. } => self.mk_ty_param(param.index, param.name).into(), GenericParamDefKind::Const => { self.mk_const_param(param.index, param.name, self.type_of(param.def_id)).into() } } } #[inline] pub fn mk_opaque(self, def_id: DefId, substs: SubstsRef<'tcx>) -> Ty<'tcx> { self.mk_ty(Opaque(def_id, substs)) } pub fn intern_existential_predicates(self, eps: &[ExistentialPredicate<'tcx>]) -> &'tcx List> { assert!(!eps.is_empty()); assert!(eps.windows(2).all(|w| w[0].stable_cmp(self, &w[1]) != Ordering::Greater)); self._intern_existential_predicates(eps) } pub fn intern_predicates(self, preds: &[Predicate<'tcx>]) -> &'tcx List> { // FIXME consider asking the input slice to be sorted to avoid // re-interning permutations, in which case that would be asserted // here. if preds.len() == 0 { // The macro-generated method below asserts we don't intern an empty slice. List::empty() } else { self._intern_predicates(preds) } } pub fn intern_type_list(self, ts: &[Ty<'tcx>]) -> &'tcx List> { if ts.len() == 0 { List::empty() } else { self._intern_type_list(ts) } } pub fn intern_substs(self, ts: &[GenericArg<'tcx>]) -> &'tcx List> { if ts.len() == 0 { List::empty() } else { self._intern_substs(ts) } } pub fn intern_projs(self, ps: &[ProjectionKind]) -> &'tcx List { if ps.len() == 0 { List::empty() } else { self._intern_projs(ps) } } pub fn intern_place_elems(self, ts: &[PlaceElem<'tcx>]) -> &'tcx List> { if ts.len() == 0 { List::empty() } else { self._intern_place_elems(ts) } } pub fn intern_canonical_var_infos(self, ts: &[CanonicalVarInfo]) -> CanonicalVarInfos<'tcx> { if ts.len() == 0 { List::empty() } else { self._intern_canonical_var_infos(ts) } } pub fn intern_clauses(self, ts: &[Clause<'tcx>]) -> Clauses<'tcx> { if ts.len() == 0 { List::empty() } else { self._intern_clauses(ts) } } pub fn intern_goals(self, ts: &[Goal<'tcx>]) -> Goals<'tcx> { if ts.len() == 0 { List::empty() } else { self._intern_goals(ts) } } pub fn mk_fn_sig(self, inputs: I, output: I::Item, c_variadic: bool, unsafety: hir::Unsafety, abi: abi::Abi) -> , ty::FnSig<'tcx>>>::Output where I: Iterator, ty::FnSig<'tcx>>>, { inputs.chain(iter::once(output)).intern_with(|xs| ty::FnSig { inputs_and_output: self.intern_type_list(xs), c_variadic, unsafety, abi }) } pub fn mk_existential_predicates], &'tcx List>>>(self, iter: I) -> I::Output { iter.intern_with(|xs| self.intern_existential_predicates(xs)) } pub fn mk_predicates], &'tcx List>>>(self, iter: I) -> I::Output { iter.intern_with(|xs| self.intern_predicates(xs)) } pub fn mk_type_list], &'tcx List>>>(self, iter: I) -> I::Output { iter.intern_with(|xs| self.intern_type_list(xs)) } pub fn mk_substs], &'tcx List>>>(self, iter: I) -> I::Output { iter.intern_with(|xs| self.intern_substs(xs)) } pub fn mk_place_elems], &'tcx List>>>(self, iter: I) -> I::Output { iter.intern_with(|xs| self.intern_place_elems(xs)) } pub fn mk_substs_trait(self, self_ty: Ty<'tcx>, rest: &[GenericArg<'tcx>]) -> SubstsRef<'tcx> { self.mk_substs(iter::once(self_ty.into()).chain(rest.iter().cloned())) } pub fn mk_clauses], Clauses<'tcx>>>(self, iter: I) -> I::Output { iter.intern_with(|xs| self.intern_clauses(xs)) } pub fn mk_goals], Goals<'tcx>>>(self, iter: I) -> I::Output { iter.intern_with(|xs| self.intern_goals(xs)) } pub fn lint_hir>(self, lint: &'static Lint, hir_id: HirId, span: S, msg: &str) { self.struct_span_lint_hir(lint, hir_id, span.into(), msg).emit() } pub fn lint_hir_note>(self, lint: &'static Lint, hir_id: HirId, span: S, msg: &str, note: &str) { let mut err = self.struct_span_lint_hir(lint, hir_id, span.into(), msg); err.note(note); err.emit() } pub fn lint_node_note>(self, lint: &'static Lint, id: hir::HirId, span: S, msg: &str, note: &str) { let mut err = self.struct_span_lint_hir(lint, id, span.into(), msg); err.note(note); err.emit() } /// Walks upwards from `id` to find a node which might change lint levels with attributes. /// It stops at `bound` and just returns it if reached. pub fn maybe_lint_level_root_bounded( self, mut id: hir::HirId, bound: hir::HirId, ) -> hir::HirId { loop { if id == bound { return bound; } if lint::maybe_lint_level_root(self, id) { return id; } let next = self.hir().get_parent_node(id); if next == id { bug!("lint traversal reached the root of the crate"); } id = next; } } pub fn lint_level_at_node( self, lint: &'static Lint, mut id: hir::HirId ) -> (lint::Level, lint::LintSource) { let sets = self.lint_levels(LOCAL_CRATE); loop { if let Some(pair) = sets.level_and_source(lint, id, self.sess) { return pair } let next = self.hir().get_parent_node(id); if next == id { bug!("lint traversal reached the root of the crate"); } id = next; } } pub fn struct_span_lint_hir>(self, lint: &'static Lint, hir_id: HirId, span: S, msg: &str) -> DiagnosticBuilder<'tcx> { let (level, src) = self.lint_level_at_node(lint, hir_id); lint::struct_lint_level(self.sess, lint, level, src, Some(span.into()), msg) } pub fn struct_lint_node(self, lint: &'static Lint, id: HirId, msg: &str) -> DiagnosticBuilder<'tcx> { let (level, src) = self.lint_level_at_node(lint, id); lint::struct_lint_level(self.sess, lint, level, src, None, msg) } pub fn in_scope_traits(self, id: HirId) -> Option<&'tcx StableVec> { self.in_scope_traits_map(id.owner) .and_then(|map| map.get(&id.local_id)) } pub fn named_region(self, id: HirId) -> Option { self.named_region_map(id.owner) .and_then(|map| map.get(&id.local_id).cloned()) } pub fn is_late_bound(self, id: HirId) -> bool { self.is_late_bound_map(id.owner) .map(|set| set.contains(&id.local_id)) .unwrap_or(false) } pub fn object_lifetime_defaults(self, id: HirId) -> Option<&'tcx [ObjectLifetimeDefault]> { self.object_lifetime_defaults_map(id.owner) .and_then(|map| map.get(&id.local_id).map(|v| &**v)) } } pub trait InternAs { type Output; fn intern_with(self, f: F) -> Self::Output where F: FnOnce(&T) -> R; } impl InternAs<[T], R> for I where E: InternIteratorElement, I: Iterator { type Output = E::Output; fn intern_with(self, f: F) -> Self::Output where F: FnOnce(&[T]) -> R { E::intern_with(self, f) } } pub trait InternIteratorElement: Sized { type Output; fn intern_with, F: FnOnce(&[T]) -> R>(iter: I, f: F) -> Self::Output; } impl InternIteratorElement for T { type Output = R; fn intern_with, F: FnOnce(&[T]) -> R>(iter: I, f: F) -> Self::Output { f(&iter.collect::>()) } } impl<'a, T, R> InternIteratorElement for &'a T where T: Clone + 'a { type Output = R; fn intern_with, F: FnOnce(&[T]) -> R>(iter: I, f: F) -> Self::Output { f(&iter.cloned().collect::>()) } } impl InternIteratorElement for Result { type Output = Result; fn intern_with, F: FnOnce(&[T]) -> R>(mut iter: I, f: F) -> Self::Output { // This code is hot enough that it's worth specializing for the most // common length lists, to avoid the overhead of `SmallVec` creation. // The match arms are in order of frequency. The 1, 2, and 0 cases are // typically hit in ~95% of cases. We assume that if the upper and // lower bounds from `size_hint` agree they are correct. Ok(match iter.size_hint() { (1, Some(1)) => { f(&[iter.next().unwrap()?]) } (2, Some(2)) => { let t0 = iter.next().unwrap()?; let t1 = iter.next().unwrap()?; f(&[t0, t1]) } (0, Some(0)) => { f(&[]) } _ => { f(&iter.collect::, _>>()?) } }) } } // We are comparing types with different invariant lifetimes, so `ptr::eq` // won't work for us. fn ptr_eq(t: *const T, u: *const U) -> bool { t as *const () == u as *const () } pub fn provide(providers: &mut ty::query::Providers<'_>) { providers.in_scope_traits_map = |tcx, id| tcx.gcx.trait_map.get(&id); providers.module_exports = |tcx, id| tcx.gcx.export_map.get(&id).map(|v| &v[..]); providers.crate_name = |tcx, id| { assert_eq!(id, LOCAL_CRATE); tcx.crate_name }; providers.get_lib_features = |tcx, id| { assert_eq!(id, LOCAL_CRATE); tcx.arena.alloc(middle::lib_features::collect(tcx)) }; providers.get_lang_items = |tcx, id| { assert_eq!(id, LOCAL_CRATE); tcx.arena.alloc(middle::lang_items::collect(tcx)) }; providers.diagnostic_items = |tcx, id| { assert_eq!(id, LOCAL_CRATE); middle::diagnostic_items::collect(tcx) }; providers.all_diagnostic_items = |tcx, id| { assert_eq!(id, LOCAL_CRATE); middle::diagnostic_items::collect_all(tcx) }; providers.maybe_unused_trait_import = |tcx, id| { tcx.maybe_unused_trait_imports.contains(&id) }; providers.maybe_unused_extern_crates = |tcx, cnum| { assert_eq!(cnum, LOCAL_CRATE); &tcx.maybe_unused_extern_crates[..] }; providers.names_imported_by_glob_use = |tcx, id| { assert_eq!(id.krate, LOCAL_CRATE); Lrc::new(tcx.glob_map.get(&id).cloned().unwrap_or_default()) }; providers.stability_index = |tcx, cnum| { assert_eq!(cnum, LOCAL_CRATE); tcx.arena.alloc(stability::Index::new(tcx)) }; providers.lookup_stability = |tcx, id| { assert_eq!(id.krate, LOCAL_CRATE); let id = tcx.hir().definitions().def_index_to_hir_id(id.index); tcx.stability().local_stability(id) }; providers.lookup_deprecation_entry = |tcx, id| { assert_eq!(id.krate, LOCAL_CRATE); let id = tcx.hir().definitions().def_index_to_hir_id(id.index); tcx.stability().local_deprecation_entry(id) }; providers.extern_mod_stmt_cnum = |tcx, id| { let id = tcx.hir().as_local_node_id(id).unwrap(); tcx.extern_crate_map.get(&id).cloned() }; providers.all_crate_nums = |tcx, cnum| { assert_eq!(cnum, LOCAL_CRATE); tcx.arena.alloc_slice(&tcx.cstore.crates_untracked()) }; providers.postorder_cnums = |tcx, cnum| { assert_eq!(cnum, LOCAL_CRATE); tcx.arena.alloc_slice(&tcx.cstore.postorder_cnums_untracked()) }; providers.output_filenames = |tcx, cnum| { assert_eq!(cnum, LOCAL_CRATE); tcx.output_filenames.clone() }; providers.features_query = |tcx, cnum| { assert_eq!(cnum, LOCAL_CRATE); tcx.arena.alloc(tcx.sess.features_untracked().clone()) }; providers.is_panic_runtime = |tcx, cnum| { assert_eq!(cnum, LOCAL_CRATE); attr::contains_name(tcx.hir().krate_attrs(), sym::panic_runtime) }; providers.is_compiler_builtins = |tcx, cnum| { assert_eq!(cnum, LOCAL_CRATE); attr::contains_name(tcx.hir().krate_attrs(), sym::compiler_builtins) }; }