//! Miscellaneous type-system utilities that are too small to deserve their own modules. use crate::middle::codegen_fn_attrs::CodegenFnAttrFlags; use crate::query::Providers; use crate::ty::layout::IntegerExt; use crate::ty::{ self, FallibleTypeFolder, ToPredicate, Ty, TyCtxt, TypeFoldable, TypeFolder, TypeSuperFoldable, TypeVisitableExt, }; use crate::ty::{GenericArgKind, GenericArgsRef}; use rustc_apfloat::Float as _; use rustc_data_structures::fx::{FxHashMap, FxHashSet}; use rustc_data_structures::stable_hasher::{Hash128, HashStable, StableHasher}; use rustc_errors::ErrorGuaranteed; use rustc_hir as hir; use rustc_hir::def::{CtorOf, DefKind, Res}; use rustc_hir::def_id::{CrateNum, DefId, LocalDefId}; use rustc_index::bit_set::GrowableBitSet; use rustc_macros::HashStable; use rustc_session::Limit; use rustc_span::sym; use rustc_target::abi::{Integer, IntegerType, Primitive, Size}; use rustc_target::spec::abi::Abi; use smallvec::SmallVec; use std::{fmt, iter}; #[derive(Copy, Clone, Debug)] pub struct Discr<'tcx> { /// Bit representation of the discriminant (e.g., `-128i8` is `0xFF_u128`). pub val: u128, pub ty: Ty<'tcx>, } /// Used as an input to [`TyCtxt::uses_unique_generic_params`]. #[derive(Copy, Clone, Debug, PartialEq, Eq)] pub enum CheckRegions { No, /// Only permit early bound regions. This is useful for Adts which /// can never have late bound regions. OnlyEarlyBound, /// Permit both late bound and early bound regions. Use this for functions, /// which frequently have late bound regions. Bound, } #[derive(Copy, Clone, Debug)] pub enum NotUniqueParam<'tcx> { DuplicateParam(ty::GenericArg<'tcx>), NotParam(ty::GenericArg<'tcx>), } impl<'tcx> fmt::Display for Discr<'tcx> { fn fmt(&self, fmt: &mut fmt::Formatter<'_>) -> fmt::Result { match *self.ty.kind() { ty::Int(ity) => { let size = ty::tls::with(|tcx| Integer::from_int_ty(&tcx, ity).size()); let x = self.val; // sign extend the raw representation to be an i128 let x = size.sign_extend(x) as i128; write!(fmt, "{x}") } _ => write!(fmt, "{}", self.val), } } } impl<'tcx> Discr<'tcx> { /// Adds `1` to the value and wraps around if the maximum for the type is reached. pub fn wrap_incr(self, tcx: TyCtxt<'tcx>) -> Self { self.checked_add(tcx, 1).0 } pub fn checked_add(self, tcx: TyCtxt<'tcx>, n: u128) -> (Self, bool) { let (size, signed) = self.ty.int_size_and_signed(tcx); let (val, oflo) = if signed { let min = size.signed_int_min(); let max = size.signed_int_max(); let val = size.sign_extend(self.val) as i128; assert!(n < (i128::MAX as u128)); let n = n as i128; let oflo = val > max - n; let val = if oflo { min + (n - (max - val) - 1) } else { val + n }; // zero the upper bits let val = val as u128; let val = size.truncate(val); (val, oflo) } else { let max = size.unsigned_int_max(); let val = self.val; let oflo = val > max - n; let val = if oflo { n - (max - val) - 1 } else { val + n }; (val, oflo) }; (Self { val, ty: self.ty }, oflo) } } pub trait IntTypeExt { fn to_ty<'tcx>(&self, tcx: TyCtxt<'tcx>) -> Ty<'tcx>; fn disr_incr<'tcx>(&self, tcx: TyCtxt<'tcx>, val: Option>) -> Option>; fn initial_discriminant<'tcx>(&self, tcx: TyCtxt<'tcx>) -> Discr<'tcx>; } impl IntTypeExt for IntegerType { fn to_ty<'tcx>(&self, tcx: TyCtxt<'tcx>) -> Ty<'tcx> { match self { IntegerType::Pointer(true) => tcx.types.isize, IntegerType::Pointer(false) => tcx.types.usize, IntegerType::Fixed(i, s) => i.to_ty(tcx, *s), } } fn initial_discriminant<'tcx>(&self, tcx: TyCtxt<'tcx>) -> Discr<'tcx> { Discr { val: 0, ty: self.to_ty(tcx) } } fn disr_incr<'tcx>(&self, tcx: TyCtxt<'tcx>, val: Option>) -> Option> { if let Some(val) = val { assert_eq!(self.to_ty(tcx), val.ty); let (new, oflo) = val.checked_add(tcx, 1); if oflo { None } else { Some(new) } } else { Some(self.initial_discriminant(tcx)) } } } impl<'tcx> TyCtxt<'tcx> { /// Creates a hash of the type `Ty` which will be the same no matter what crate /// context it's calculated within. This is used by the `type_id` intrinsic. pub fn type_id_hash(self, ty: Ty<'tcx>) -> Hash128 { // We want the type_id be independent of the types free regions, so we // erase them. The erase_regions() call will also anonymize bound // regions, which is desirable too. let ty = self.erase_regions(ty); self.with_stable_hashing_context(|mut hcx| { let mut hasher = StableHasher::new(); hcx.while_hashing_spans(false, |hcx| ty.hash_stable(hcx, &mut hasher)); hasher.finish() }) } pub fn res_generics_def_id(self, res: Res) -> Option { match res { Res::Def(DefKind::Ctor(CtorOf::Variant, _), def_id) => { Some(self.parent(self.parent(def_id))) } Res::Def(DefKind::Variant | DefKind::Ctor(CtorOf::Struct, _), def_id) => { Some(self.parent(def_id)) } // Other `DefKind`s don't have generics and would ICE when calling // `generics_of`. Res::Def( DefKind::Struct | DefKind::Union | DefKind::Enum | DefKind::Trait | DefKind::OpaqueTy | DefKind::TyAlias | DefKind::ForeignTy | DefKind::TraitAlias | DefKind::AssocTy | DefKind::Fn | DefKind::AssocFn | DefKind::AssocConst | DefKind::Impl { .. }, def_id, ) => Some(def_id), Res::Err => None, _ => None, } } /// Attempts to returns the deeply last field of nested structures, but /// does not apply any normalization in its search. Returns the same type /// if input `ty` is not a structure at all. pub fn struct_tail_without_normalization(self, ty: Ty<'tcx>) -> Ty<'tcx> { let tcx = self; tcx.struct_tail_with_normalize(ty, |ty| ty, || {}) } /// Returns the deeply last field of nested structures, or the same type if /// not a structure at all. Corresponds to the only possible unsized field, /// and its type can be used to determine unsizing strategy. /// /// Should only be called if `ty` has no inference variables and does not /// need its lifetimes preserved (e.g. as part of codegen); otherwise /// normalization attempt may cause compiler bugs. pub fn struct_tail_erasing_lifetimes( self, ty: Ty<'tcx>, param_env: ty::ParamEnv<'tcx>, ) -> Ty<'tcx> { let tcx = self; tcx.struct_tail_with_normalize(ty, |ty| tcx.normalize_erasing_regions(param_env, ty), || {}) } /// Returns the deeply last field of nested structures, or the same type if /// not a structure at all. Corresponds to the only possible unsized field, /// and its type can be used to determine unsizing strategy. /// /// This is parameterized over the normalization strategy (i.e. how to /// handle `::Assoc` and `impl Trait`); pass the identity /// function to indicate no normalization should take place. /// /// See also `struct_tail_erasing_lifetimes`, which is suitable for use /// during codegen. pub fn struct_tail_with_normalize( self, mut ty: Ty<'tcx>, mut normalize: impl FnMut(Ty<'tcx>) -> Ty<'tcx>, // This is currently used to allow us to walk a ValTree // in lockstep with the type in order to get the ValTree branch that // corresponds to an unsized field. mut f: impl FnMut() -> (), ) -> Ty<'tcx> { let recursion_limit = self.recursion_limit(); for iteration in 0.. { if !recursion_limit.value_within_limit(iteration) { let suggested_limit = match recursion_limit { Limit(0) => Limit(2), limit => limit * 2, }; let reported = self.sess.emit_err(crate::error::RecursionLimitReached { ty, suggested_limit }); return Ty::new_error(self, reported); } match *ty.kind() { ty::Adt(def, args) => { if !def.is_struct() { break; } match def.non_enum_variant().tail_opt() { Some(field) => { f(); ty = field.ty(self, args); } None => break, } } ty::Tuple(tys) if let Some((&last_ty, _)) = tys.split_last() => { f(); ty = last_ty; } ty::Tuple(_) => break, ty::Alias(..) => { let normalized = normalize(ty); if ty == normalized { return ty; } else { ty = normalized; } } _ => { break; } } } ty } /// Same as applying `struct_tail` on `source` and `target`, but only /// keeps going as long as the two types are instances of the same /// structure definitions. /// For `(Foo>, Foo)`, the result will be `(Foo, Trait)`, /// whereas struct_tail produces `T`, and `Trait`, respectively. /// /// Should only be called if the types have no inference variables and do /// not need their lifetimes preserved (e.g., as part of codegen); otherwise, /// normalization attempt may cause compiler bugs. pub fn struct_lockstep_tails_erasing_lifetimes( self, source: Ty<'tcx>, target: Ty<'tcx>, param_env: ty::ParamEnv<'tcx>, ) -> (Ty<'tcx>, Ty<'tcx>) { let tcx = self; tcx.struct_lockstep_tails_with_normalize(source, target, |ty| { tcx.normalize_erasing_regions(param_env, ty) }) } /// Same as applying `struct_tail` on `source` and `target`, but only /// keeps going as long as the two types are instances of the same /// structure definitions. /// For `(Foo>, Foo)`, the result will be `(Foo, Trait)`, /// whereas struct_tail produces `T`, and `Trait`, respectively. /// /// See also `struct_lockstep_tails_erasing_lifetimes`, which is suitable for use /// during codegen. pub fn struct_lockstep_tails_with_normalize( self, source: Ty<'tcx>, target: Ty<'tcx>, normalize: impl Fn(Ty<'tcx>) -> Ty<'tcx>, ) -> (Ty<'tcx>, Ty<'tcx>) { let (mut a, mut b) = (source, target); loop { match (&a.kind(), &b.kind()) { (&ty::Adt(a_def, a_args), &ty::Adt(b_def, b_args)) if a_def == b_def && a_def.is_struct() => { if let Some(f) = a_def.non_enum_variant().tail_opt() { a = f.ty(self, a_args); b = f.ty(self, b_args); } else { break; } } (&ty::Tuple(a_tys), &ty::Tuple(b_tys)) if a_tys.len() == b_tys.len() => { if let Some(&a_last) = a_tys.last() { a = a_last; b = *b_tys.last().unwrap(); } else { break; } } (ty::Alias(..), _) | (_, ty::Alias(..)) => { // If either side is a projection, attempt to // progress via normalization. (Should be safe to // apply to both sides as normalization is // idempotent.) let a_norm = normalize(a); let b_norm = normalize(b); if a == a_norm && b == b_norm { break; } else { a = a_norm; b = b_norm; } } _ => break, } } (a, b) } /// Calculate the destructor of a given type. pub fn calculate_dtor( self, adt_did: DefId, validate: impl Fn(Self, DefId) -> Result<(), ErrorGuaranteed>, ) -> Option { let drop_trait = self.lang_items().drop_trait()?; self.ensure().coherent_trait(drop_trait); let ty = self.type_of(adt_did).instantiate_identity(); let mut dtor_candidate = None; self.for_each_relevant_impl(drop_trait, ty, |impl_did| { if validate(self, impl_did).is_err() { // Already `ErrorGuaranteed`, no need to delay a span bug here. return; } let Some(item_id) = self.associated_item_def_ids(impl_did).first() else { self.sess .delay_span_bug(self.def_span(impl_did), "Drop impl without drop function"); return; }; if let Some((old_item_id, _)) = dtor_candidate { self.sess .struct_span_err(self.def_span(item_id), "multiple drop impls found") .span_note(self.def_span(old_item_id), "other impl here") .delay_as_bug(); } dtor_candidate = Some((*item_id, self.constness(impl_did))); }); let (did, constness) = dtor_candidate?; Some(ty::Destructor { did, constness }) } /// Returns the set of types that are required to be alive in /// order to run the destructor of `def` (see RFCs 769 and /// 1238). /// /// Note that this returns only the constraints for the /// destructor of `def` itself. For the destructors of the /// contents, you need `adt_dtorck_constraint`. pub fn destructor_constraints(self, def: ty::AdtDef<'tcx>) -> Vec> { let dtor = match def.destructor(self) { None => { debug!("destructor_constraints({:?}) - no dtor", def.did()); return vec![]; } Some(dtor) => dtor.did, }; let impl_def_id = self.parent(dtor); let impl_generics = self.generics_of(impl_def_id); // We have a destructor - all the parameters that are not // pure_wrt_drop (i.e, don't have a #[may_dangle] attribute) // must be live. // We need to return the list of parameters from the ADTs // generics/args that correspond to impure parameters on the // impl's generics. This is a bit ugly, but conceptually simple: // // Suppose our ADT looks like the following // // struct S(X, Y, Z); // // and the impl is // // impl<#[may_dangle] P0, P1, P2> Drop for S // // We want to return the parameters (X, Y). For that, we match // up the item-args with the args on the impl ADT, // , and then look up which of the impl args refer to // parameters marked as pure. let impl_args = match *self.type_of(impl_def_id).instantiate_identity().kind() { ty::Adt(def_, args) if def_ == def => args, _ => bug!(), }; let item_args = match *self.type_of(def.did()).instantiate_identity().kind() { ty::Adt(def_, args) if def_ == def => args, _ => bug!(), }; let result = iter::zip(item_args, impl_args) .filter(|&(_, k)| { match k.unpack() { GenericArgKind::Lifetime(region) => match region.kind() { ty::ReEarlyBound(ref ebr) => { !impl_generics.region_param(ebr, self).pure_wrt_drop } // Error: not a region param _ => false, }, GenericArgKind::Type(ty) => match ty.kind() { ty::Param(ref pt) => !impl_generics.type_param(pt, self).pure_wrt_drop, // Error: not a type param _ => false, }, GenericArgKind::Const(ct) => match ct.kind() { ty::ConstKind::Param(ref pc) => { !impl_generics.const_param(pc, self).pure_wrt_drop } // Error: not a const param _ => false, }, } }) .map(|(item_param, _)| item_param) .collect(); debug!("destructor_constraint({:?}) = {:?}", def.did(), result); result } /// Checks whether each generic argument is simply a unique generic parameter. pub fn uses_unique_generic_params( self, args: &[ty::GenericArg<'tcx>], ignore_regions: CheckRegions, ) -> Result<(), NotUniqueParam<'tcx>> { let mut seen = GrowableBitSet::default(); let mut seen_late = FxHashSet::default(); for arg in args { match arg.unpack() { GenericArgKind::Lifetime(lt) => match (ignore_regions, lt.kind()) { (CheckRegions::Bound, ty::ReLateBound(di, reg)) => { if !seen_late.insert((di, reg)) { return Err(NotUniqueParam::DuplicateParam(lt.into())); } } (CheckRegions::OnlyEarlyBound | CheckRegions::Bound, ty::ReEarlyBound(p)) => { if !seen.insert(p.index) { return Err(NotUniqueParam::DuplicateParam(lt.into())); } } (CheckRegions::OnlyEarlyBound | CheckRegions::Bound, _) => { return Err(NotUniqueParam::NotParam(lt.into())); } (CheckRegions::No, _) => {} }, GenericArgKind::Type(t) => match t.kind() { ty::Param(p) => { if !seen.insert(p.index) { return Err(NotUniqueParam::DuplicateParam(t.into())); } } _ => return Err(NotUniqueParam::NotParam(t.into())), }, GenericArgKind::Const(c) => match c.kind() { ty::ConstKind::Param(p) => { if !seen.insert(p.index) { return Err(NotUniqueParam::DuplicateParam(c.into())); } } _ => return Err(NotUniqueParam::NotParam(c.into())), }, } } Ok(()) } /// Checks whether each generic argument is simply a unique generic placeholder. /// /// This is used in the new solver, which canonicalizes params to placeholders /// for better caching. pub fn uses_unique_placeholders_ignoring_regions( self, args: GenericArgsRef<'tcx>, ) -> Result<(), NotUniqueParam<'tcx>> { let mut seen = GrowableBitSet::default(); for arg in args { match arg.unpack() { // Ignore regions, since we can't resolve those in a canonicalized // query in the trait solver. GenericArgKind::Lifetime(_) => {} GenericArgKind::Type(t) => match t.kind() { ty::Placeholder(p) => { if !seen.insert(p.bound.var) { return Err(NotUniqueParam::DuplicateParam(t.into())); } } _ => return Err(NotUniqueParam::NotParam(t.into())), }, GenericArgKind::Const(c) => match c.kind() { ty::ConstKind::Placeholder(p) => { if !seen.insert(p.bound) { return Err(NotUniqueParam::DuplicateParam(c.into())); } } _ => return Err(NotUniqueParam::NotParam(c.into())), }, } } Ok(()) } /// Returns `true` if `def_id` refers to a closure (e.g., `|x| x * 2`). Note /// that closures have a `DefId`, but the closure *expression* also /// has a `HirId` that is located within the context where the /// closure appears (and, sadly, a corresponding `NodeId`, since /// those are not yet phased out). The parent of the closure's /// `DefId` will also be the context where it appears. pub fn is_closure(self, def_id: DefId) -> bool { matches!(self.def_kind(def_id), DefKind::Closure | DefKind::Coroutine) } /// Returns `true` if `def_id` refers to a definition that does not have its own /// type-checking context, i.e. closure, coroutine or inline const. pub fn is_typeck_child(self, def_id: DefId) -> bool { matches!( self.def_kind(def_id), DefKind::Closure | DefKind::Coroutine | DefKind::InlineConst ) } /// Returns `true` if `def_id` refers to a trait (i.e., `trait Foo { ... }`). pub fn is_trait(self, def_id: DefId) -> bool { self.def_kind(def_id) == DefKind::Trait } /// Returns `true` if `def_id` refers to a trait alias (i.e., `trait Foo = ...;`), /// and `false` otherwise. pub fn is_trait_alias(self, def_id: DefId) -> bool { self.def_kind(def_id) == DefKind::TraitAlias } /// Returns `true` if this `DefId` refers to the implicit constructor for /// a tuple struct like `struct Foo(u32)`, and `false` otherwise. pub fn is_constructor(self, def_id: DefId) -> bool { matches!(self.def_kind(def_id), DefKind::Ctor(..)) } /// Given the `DefId`, returns the `DefId` of the innermost item that /// has its own type-checking context or "inference environment". /// /// For example, a closure has its own `DefId`, but it is type-checked /// with the containing item. Similarly, an inline const block has its /// own `DefId` but it is type-checked together with the containing item. /// /// Therefore, when we fetch the /// `typeck` the closure, for example, we really wind up /// fetching the `typeck` the enclosing fn item. pub fn typeck_root_def_id(self, def_id: DefId) -> DefId { let mut def_id = def_id; while self.is_typeck_child(def_id) { def_id = self.parent(def_id); } def_id } /// Given the `DefId` and args a closure, creates the type of /// `self` argument that the closure expects. For example, for a /// `Fn` closure, this would return a reference type `&T` where /// `T = closure_ty`. /// /// Returns `None` if this closure's kind has not yet been inferred. /// This should only be possible during type checking. /// /// Note that the return value is a late-bound region and hence /// wrapped in a binder. pub fn closure_env_ty( self, closure_def_id: DefId, closure_args: GenericArgsRef<'tcx>, env_region: ty::Region<'tcx>, ) -> Option> { let closure_ty = Ty::new_closure(self, closure_def_id, closure_args); let closure_kind_ty = closure_args.as_closure().kind_ty(); let closure_kind = closure_kind_ty.to_opt_closure_kind()?; let env_ty = match closure_kind { ty::ClosureKind::Fn => Ty::new_imm_ref(self, env_region, closure_ty), ty::ClosureKind::FnMut => Ty::new_mut_ref(self, env_region, closure_ty), ty::ClosureKind::FnOnce => closure_ty, }; Some(env_ty) } /// Returns `true` if the node pointed to by `def_id` is a `static` item. #[inline] pub fn is_static(self, def_id: DefId) -> bool { matches!(self.def_kind(def_id), DefKind::Static(_)) } #[inline] pub fn static_mutability(self, def_id: DefId) -> Option { if let DefKind::Static(mt) = self.def_kind(def_id) { Some(mt) } else { None } } /// Returns `true` if this is a `static` item with the `#[thread_local]` attribute. pub fn is_thread_local_static(self, def_id: DefId) -> bool { self.codegen_fn_attrs(def_id).flags.contains(CodegenFnAttrFlags::THREAD_LOCAL) } /// Returns `true` if the node pointed to by `def_id` is a mutable `static` item. #[inline] pub fn is_mutable_static(self, def_id: DefId) -> bool { self.static_mutability(def_id) == Some(hir::Mutability::Mut) } /// Returns `true` if the item pointed to by `def_id` is a thread local which needs a /// thread local shim generated. #[inline] pub fn needs_thread_local_shim(self, def_id: DefId) -> bool { !self.sess.target.dll_tls_export && self.is_thread_local_static(def_id) && !self.is_foreign_item(def_id) } /// Returns the type a reference to the thread local takes in MIR. pub fn thread_local_ptr_ty(self, def_id: DefId) -> Ty<'tcx> { let static_ty = self.type_of(def_id).instantiate_identity(); if self.is_mutable_static(def_id) { Ty::new_mut_ptr(self, static_ty) } else if self.is_foreign_item(def_id) { Ty::new_imm_ptr(self, static_ty) } else { // FIXME: These things don't *really* have 'static lifetime. Ty::new_imm_ref(self, self.lifetimes.re_static, static_ty) } } /// Get the type of the pointer to the static that we use in MIR. pub fn static_ptr_ty(self, def_id: DefId) -> Ty<'tcx> { // Make sure that any constants in the static's type are evaluated. let static_ty = self.normalize_erasing_regions( ty::ParamEnv::empty(), self.type_of(def_id).instantiate_identity(), ); // Make sure that accesses to unsafe statics end up using raw pointers. // For thread-locals, this needs to be kept in sync with `Rvalue::ty`. if self.is_mutable_static(def_id) { Ty::new_mut_ptr(self, static_ty) } else if self.is_foreign_item(def_id) { Ty::new_imm_ptr(self, static_ty) } else { Ty::new_imm_ref(self, self.lifetimes.re_erased, static_ty) } } /// Return the set of types that should be taken into account when checking /// trait bounds on a coroutine's internal state. pub fn coroutine_hidden_types( self, def_id: DefId, ) -> impl Iterator>> { let coroutine_layout = self.mir_coroutine_witnesses(def_id); coroutine_layout .as_ref() .map_or_else(|| [].iter(), |l| l.field_tys.iter()) .filter(|decl| !decl.ignore_for_traits) .map(|decl| ty::EarlyBinder::bind(decl.ty)) } /// Normalizes all opaque types in the given value, replacing them /// with their underlying types. pub fn expand_opaque_types(self, val: Ty<'tcx>) -> Ty<'tcx> { let mut visitor = OpaqueTypeExpander { seen_opaque_tys: FxHashSet::default(), expanded_cache: FxHashMap::default(), primary_def_id: None, found_recursion: false, found_any_recursion: false, check_recursion: false, expand_coroutines: false, tcx: self, }; val.fold_with(&mut visitor) } /// Expands the given impl trait type, stopping if the type is recursive. #[instrument(skip(self), level = "debug", ret)] pub fn try_expand_impl_trait_type( self, def_id: DefId, args: GenericArgsRef<'tcx>, ) -> Result, Ty<'tcx>> { let mut visitor = OpaqueTypeExpander { seen_opaque_tys: FxHashSet::default(), expanded_cache: FxHashMap::default(), primary_def_id: Some(def_id), found_recursion: false, found_any_recursion: false, check_recursion: true, expand_coroutines: true, tcx: self, }; let expanded_type = visitor.expand_opaque_ty(def_id, args).unwrap(); if visitor.found_recursion { Err(expanded_type) } else { Ok(expanded_type) } } /// Query and get an English description for the item's kind. pub fn def_descr(self, def_id: DefId) -> &'static str { self.def_kind_descr(self.def_kind(def_id), def_id) } /// Get an English description for the item's kind. pub fn def_kind_descr(self, def_kind: DefKind, def_id: DefId) -> &'static str { match def_kind { DefKind::AssocFn if self.associated_item(def_id).fn_has_self_parameter => "method", DefKind::Coroutine => match self.coroutine_kind(def_id).unwrap() { rustc_hir::CoroutineKind::Async(..) => "async closure", rustc_hir::CoroutineKind::Coroutine => "coroutine", rustc_hir::CoroutineKind::Gen(..) => "gen closure", }, _ => def_kind.descr(def_id), } } /// Gets an English article for the [`TyCtxt::def_descr`]. pub fn def_descr_article(self, def_id: DefId) -> &'static str { self.def_kind_descr_article(self.def_kind(def_id), def_id) } /// Gets an English article for the [`TyCtxt::def_kind_descr`]. pub fn def_kind_descr_article(self, def_kind: DefKind, def_id: DefId) -> &'static str { match def_kind { DefKind::AssocFn if self.associated_item(def_id).fn_has_self_parameter => "a", DefKind::Coroutine => match self.coroutine_kind(def_id).unwrap() { rustc_hir::CoroutineKind::Async(..) => "an", rustc_hir::CoroutineKind::Coroutine => "a", rustc_hir::CoroutineKind::Gen(..) => "a", }, _ => def_kind.article(), } } /// Return `true` if the supplied `CrateNum` is "user-visible," meaning either a [public] /// dependency, or a [direct] private dependency. This is used to decide whether the crate can /// be shown in `impl` suggestions. /// /// [public]: TyCtxt::is_private_dep /// [direct]: rustc_session::cstore::ExternCrate::is_direct pub fn is_user_visible_dep(self, key: CrateNum) -> bool { // | Private | Direct | Visible | | // |---------|--------|---------|--------------------| // | Yes | Yes | Yes | !true || true | // | No | Yes | Yes | !false || true | // | Yes | No | No | !true || false | // | No | No | Yes | !false || false | !self.is_private_dep(key) // If `extern_crate` is `None`, then the crate was injected (e.g., by the allocator). // Treat that kind of crate as "indirect", since it's an implementation detail of // the language. || self.extern_crate(key.as_def_id()).map_or(false, |e| e.is_direct()) } } struct OpaqueTypeExpander<'tcx> { // Contains the DefIds of the opaque types that are currently being // expanded. When we expand an opaque type we insert the DefId of // that type, and when we finish expanding that type we remove the // its DefId. seen_opaque_tys: FxHashSet, // Cache of all expansions we've seen so far. This is a critical // optimization for some large types produced by async fn trees. expanded_cache: FxHashMap<(DefId, GenericArgsRef<'tcx>), Ty<'tcx>>, primary_def_id: Option, found_recursion: bool, found_any_recursion: bool, expand_coroutines: bool, /// Whether or not to check for recursive opaque types. /// This is `true` when we're explicitly checking for opaque type /// recursion, and 'false' otherwise to avoid unnecessary work. check_recursion: bool, tcx: TyCtxt<'tcx>, } impl<'tcx> OpaqueTypeExpander<'tcx> { fn expand_opaque_ty(&mut self, def_id: DefId, args: GenericArgsRef<'tcx>) -> Option> { if self.found_any_recursion { return None; } let args = args.fold_with(self); if !self.check_recursion || self.seen_opaque_tys.insert(def_id) { let expanded_ty = match self.expanded_cache.get(&(def_id, args)) { Some(expanded_ty) => *expanded_ty, None => { let generic_ty = self.tcx.type_of(def_id); let concrete_ty = generic_ty.instantiate(self.tcx, args); let expanded_ty = self.fold_ty(concrete_ty); self.expanded_cache.insert((def_id, args), expanded_ty); expanded_ty } }; if self.check_recursion { self.seen_opaque_tys.remove(&def_id); } Some(expanded_ty) } else { // If another opaque type that we contain is recursive, then it // will report the error, so we don't have to. self.found_any_recursion = true; self.found_recursion = def_id == *self.primary_def_id.as_ref().unwrap(); None } } fn expand_coroutine(&mut self, def_id: DefId, args: GenericArgsRef<'tcx>) -> Option> { if self.found_any_recursion { return None; } let args = args.fold_with(self); if !self.check_recursion || self.seen_opaque_tys.insert(def_id) { let expanded_ty = match self.expanded_cache.get(&(def_id, args)) { Some(expanded_ty) => *expanded_ty, None => { for bty in self.tcx.coroutine_hidden_types(def_id) { let hidden_ty = bty.instantiate(self.tcx, args); self.fold_ty(hidden_ty); } let expanded_ty = Ty::new_coroutine_witness(self.tcx, def_id, args); self.expanded_cache.insert((def_id, args), expanded_ty); expanded_ty } }; if self.check_recursion { self.seen_opaque_tys.remove(&def_id); } Some(expanded_ty) } else { // If another opaque type that we contain is recursive, then it // will report the error, so we don't have to. self.found_any_recursion = true; self.found_recursion = def_id == *self.primary_def_id.as_ref().unwrap(); None } } } impl<'tcx> TypeFolder> for OpaqueTypeExpander<'tcx> { fn interner(&self) -> TyCtxt<'tcx> { self.tcx } fn fold_ty(&mut self, t: Ty<'tcx>) -> Ty<'tcx> { let mut t = if let ty::Alias(ty::Opaque, ty::AliasTy { def_id, args, .. }) = *t.kind() { self.expand_opaque_ty(def_id, args).unwrap_or(t) } else if t.has_opaque_types() || t.has_coroutines() { t.super_fold_with(self) } else { t }; if self.expand_coroutines { if let ty::CoroutineWitness(def_id, args) = *t.kind() { t = self.expand_coroutine(def_id, args).unwrap_or(t); } } t } fn fold_predicate(&mut self, p: ty::Predicate<'tcx>) -> ty::Predicate<'tcx> { if let ty::PredicateKind::Clause(clause) = p.kind().skip_binder() && let ty::ClauseKind::Projection(projection_pred) = clause { p.kind() .rebind(ty::ProjectionPredicate { projection_ty: projection_pred.projection_ty.fold_with(self), // Don't fold the term on the RHS of the projection predicate. // This is because for default trait methods with RPITITs, we // install a `NormalizesTo(Projection(RPITIT) -> Opaque(RPITIT))` // predicate, which would trivially cause a cycle when we do // anything that requires `ParamEnv::with_reveal_all_normalized`. term: projection_pred.term, }) .to_predicate(self.tcx) } else { p.super_fold_with(self) } } } impl<'tcx> Ty<'tcx> { /// Returns the `Size` for primitive types (bool, uint, int, char, float). pub fn primitive_size(self, tcx: TyCtxt<'tcx>) -> Size { match *self.kind() { ty::Bool => Size::from_bytes(1), ty::Char => Size::from_bytes(4), ty::Int(ity) => Integer::from_int_ty(&tcx, ity).size(), ty::Uint(uty) => Integer::from_uint_ty(&tcx, uty).size(), ty::Float(ty::FloatTy::F32) => Primitive::F32.size(&tcx), ty::Float(ty::FloatTy::F64) => Primitive::F64.size(&tcx), _ => bug!("non primitive type"), } } pub fn int_size_and_signed(self, tcx: TyCtxt<'tcx>) -> (Size, bool) { match *self.kind() { ty::Int(ity) => (Integer::from_int_ty(&tcx, ity).size(), true), ty::Uint(uty) => (Integer::from_uint_ty(&tcx, uty).size(), false), _ => bug!("non integer discriminant"), } } /// Returns the minimum and maximum values for the given numeric type (including `char`s) or /// returns `None` if the type is not numeric. pub fn numeric_min_and_max_as_bits(self, tcx: TyCtxt<'tcx>) -> Option<(u128, u128)> { use rustc_apfloat::ieee::{Double, Single}; Some(match self.kind() { ty::Int(_) | ty::Uint(_) => { let (size, signed) = self.int_size_and_signed(tcx); let min = if signed { size.truncate(size.signed_int_min() as u128) } else { 0 }; let max = if signed { size.signed_int_max() as u128 } else { size.unsigned_int_max() }; (min, max) } ty::Char => (0, std::char::MAX as u128), ty::Float(ty::FloatTy::F32) => { ((-Single::INFINITY).to_bits(), Single::INFINITY.to_bits()) } ty::Float(ty::FloatTy::F64) => { ((-Double::INFINITY).to_bits(), Double::INFINITY.to_bits()) } _ => return None, }) } /// Returns the maximum value for the given numeric type (including `char`s) /// or returns `None` if the type is not numeric. pub fn numeric_max_val(self, tcx: TyCtxt<'tcx>) -> Option> { self.numeric_min_and_max_as_bits(tcx) .map(|(_, max)| ty::Const::from_bits(tcx, max, ty::ParamEnv::empty().and(self))) } /// Returns the minimum value for the given numeric type (including `char`s) /// or returns `None` if the type is not numeric. pub fn numeric_min_val(self, tcx: TyCtxt<'tcx>) -> Option> { self.numeric_min_and_max_as_bits(tcx) .map(|(min, _)| ty::Const::from_bits(tcx, min, ty::ParamEnv::empty().and(self))) } /// Checks whether values of this type `T` are *moved* or *copied* /// when referenced -- this amounts to a check for whether `T: /// Copy`, but note that we **don't** consider lifetimes when /// doing this check. This means that we may generate MIR which /// does copies even when the type actually doesn't satisfy the /// full requirements for the `Copy` trait (cc #29149) -- this /// winds up being reported as an error during NLL borrow check. pub fn is_copy_modulo_regions(self, tcx: TyCtxt<'tcx>, param_env: ty::ParamEnv<'tcx>) -> bool { self.is_trivially_pure_clone_copy() || tcx.is_copy_raw(param_env.and(self)) } /// Checks whether values of this type `T` have a size known at /// compile time (i.e., whether `T: Sized`). Lifetimes are ignored /// for the purposes of this check, so it can be an /// over-approximation in generic contexts, where one can have /// strange rules like `>::Bar: Sized` that /// actually carry lifetime requirements. pub fn is_sized(self, tcx: TyCtxt<'tcx>, param_env: ty::ParamEnv<'tcx>) -> bool { self.is_trivially_sized(tcx) || tcx.is_sized_raw(param_env.and(self)) } /// Checks whether values of this type `T` implement the `Freeze` /// trait -- frozen types are those that do not contain an /// `UnsafeCell` anywhere. This is a language concept used to /// distinguish "true immutability", which is relevant to /// optimization as well as the rules around static values. Note /// that the `Freeze` trait is not exposed to end users and is /// effectively an implementation detail. pub fn is_freeze(self, tcx: TyCtxt<'tcx>, param_env: ty::ParamEnv<'tcx>) -> bool { self.is_trivially_freeze() || tcx.is_freeze_raw(param_env.and(self)) } /// Fast path helper for testing if a type is `Freeze`. /// /// Returning true means the type is known to be `Freeze`. Returning /// `false` means nothing -- could be `Freeze`, might not be. fn is_trivially_freeze(self) -> bool { match self.kind() { ty::Int(_) | ty::Uint(_) | ty::Float(_) | ty::Bool | ty::Char | ty::Str | ty::Never | ty::Ref(..) | ty::RawPtr(_) | ty::FnDef(..) | ty::Error(_) | ty::FnPtr(_) => true, ty::Tuple(fields) => fields.iter().all(Self::is_trivially_freeze), ty::Slice(elem_ty) | ty::Array(elem_ty, _) => elem_ty.is_trivially_freeze(), ty::Adt(..) | ty::Bound(..) | ty::Closure(..) | ty::Dynamic(..) | ty::Foreign(_) | ty::Coroutine(..) | ty::CoroutineWitness(..) | ty::Infer(_) | ty::Alias(..) | ty::Param(_) | ty::Placeholder(_) => false, } } /// Checks whether values of this type `T` implement the `Unpin` trait. pub fn is_unpin(self, tcx: TyCtxt<'tcx>, param_env: ty::ParamEnv<'tcx>) -> bool { self.is_trivially_unpin() || tcx.is_unpin_raw(param_env.and(self)) } /// Fast path helper for testing if a type is `Unpin`. /// /// Returning true means the type is known to be `Unpin`. Returning /// `false` means nothing -- could be `Unpin`, might not be. fn is_trivially_unpin(self) -> bool { match self.kind() { ty::Int(_) | ty::Uint(_) | ty::Float(_) | ty::Bool | ty::Char | ty::Str | ty::Never | ty::Ref(..) | ty::RawPtr(_) | ty::FnDef(..) | ty::Error(_) | ty::FnPtr(_) => true, ty::Tuple(fields) => fields.iter().all(Self::is_trivially_unpin), ty::Slice(elem_ty) | ty::Array(elem_ty, _) => elem_ty.is_trivially_unpin(), ty::Adt(..) | ty::Bound(..) | ty::Closure(..) | ty::Dynamic(..) | ty::Foreign(_) | ty::Coroutine(..) | ty::CoroutineWitness(..) | ty::Infer(_) | ty::Alias(..) | ty::Param(_) | ty::Placeholder(_) => false, } } /// If `ty.needs_drop(...)` returns `true`, then `ty` is definitely /// non-copy and *might* have a destructor attached; if it returns /// `false`, then `ty` definitely has no destructor (i.e., no drop glue). /// /// (Note that this implies that if `ty` has a destructor attached, /// then `needs_drop` will definitely return `true` for `ty`.) /// /// Note that this method is used to check eligible types in unions. #[inline] pub fn needs_drop(self, tcx: TyCtxt<'tcx>, param_env: ty::ParamEnv<'tcx>) -> bool { // Avoid querying in simple cases. match needs_drop_components(tcx, self) { Err(AlwaysRequiresDrop) => true, Ok(components) => { let query_ty = match *components { [] => return false, // If we've got a single component, call the query with that // to increase the chance that we hit the query cache. [component_ty] => component_ty, _ => self, }; // This doesn't depend on regions, so try to minimize distinct // query keys used. // If normalization fails, we just use `query_ty`. debug_assert!(!param_env.has_infer()); let query_ty = tcx .try_normalize_erasing_regions(param_env, query_ty) .unwrap_or_else(|_| tcx.erase_regions(query_ty)); tcx.needs_drop_raw(param_env.and(query_ty)) } } } /// Checks if `ty` has a significant drop. /// /// Note that this method can return false even if `ty` has a destructor /// attached; even if that is the case then the adt has been marked with /// the attribute `rustc_insignificant_dtor`. /// /// Note that this method is used to check for change in drop order for /// 2229 drop reorder migration analysis. #[inline] pub fn has_significant_drop(self, tcx: TyCtxt<'tcx>, param_env: ty::ParamEnv<'tcx>) -> bool { // Avoid querying in simple cases. match needs_drop_components(tcx, self) { Err(AlwaysRequiresDrop) => true, Ok(components) => { let query_ty = match *components { [] => return false, // If we've got a single component, call the query with that // to increase the chance that we hit the query cache. [component_ty] => component_ty, _ => self, }; // FIXME(#86868): We should be canonicalizing, or else moving this to a method of inference // context, or *something* like that, but for now just avoid passing inference // variables to queries that can't cope with them. Instead, conservatively // return "true" (may change drop order). if query_ty.has_infer() { return true; } // This doesn't depend on regions, so try to minimize distinct // query keys used. let erased = tcx.normalize_erasing_regions(param_env, query_ty); tcx.has_significant_drop_raw(param_env.and(erased)) } } } /// Returns `true` if equality for this type is both reflexive and structural. /// /// Reflexive equality for a type is indicated by an `Eq` impl for that type. /// /// Primitive types (`u32`, `str`) have structural equality by definition. For composite data /// types, equality for the type as a whole is structural when it is the same as equality /// between all components (fields, array elements, etc.) of that type. For ADTs, structural /// equality is indicated by an implementation of `PartialStructuralEq` and `StructuralEq` for /// that type. /// /// This function is "shallow" because it may return `true` for a composite type whose fields /// are not `StructuralEq`. For example, `[T; 4]` has structural equality regardless of `T` /// because equality for arrays is determined by the equality of each array element. If you /// want to know whether a given call to `PartialEq::eq` will proceed structurally all the way /// down, you will need to use a type visitor. #[inline] pub fn is_structural_eq_shallow(self, tcx: TyCtxt<'tcx>) -> bool { match self.kind() { // Look for an impl of both `PartialStructuralEq` and `StructuralEq`. ty::Adt(..) => tcx.has_structural_eq_impls(self), // Primitive types that satisfy `Eq`. ty::Bool | ty::Char | ty::Int(_) | ty::Uint(_) | ty::Str | ty::Never => true, // Composite types that satisfy `Eq` when all of their fields do. // // Because this function is "shallow", we return `true` for these composites regardless // of the type(s) contained within. ty::Ref(..) | ty::Array(..) | ty::Slice(_) | ty::Tuple(..) => true, // Raw pointers use bitwise comparison. ty::RawPtr(_) | ty::FnPtr(_) => true, // Floating point numbers are not `Eq`. ty::Float(_) => false, // Conservatively return `false` for all others... // Anonymous function types ty::FnDef(..) | ty::Closure(..) | ty::Dynamic(..) | ty::Coroutine(..) => false, // Generic or inferred types // // FIXME(ecstaticmorse): Maybe we should `bug` here? This should probably only be // called for known, fully-monomorphized types. ty::Alias(..) | ty::Param(_) | ty::Bound(..) | ty::Placeholder(_) | ty::Infer(_) => { false } ty::Foreign(_) | ty::CoroutineWitness(..) | ty::Error(_) => false, } } /// Peel off all reference types in this type until there are none left. /// /// This method is idempotent, i.e. `ty.peel_refs().peel_refs() == ty.peel_refs()`. /// /// # Examples /// /// - `u8` -> `u8` /// - `&'a mut u8` -> `u8` /// - `&'a &'b u8` -> `u8` /// - `&'a *const &'b u8 -> *const &'b u8` pub fn peel_refs(self) -> Ty<'tcx> { let mut ty = self; while let ty::Ref(_, inner_ty, _) = ty.kind() { ty = *inner_ty; } ty } #[inline] pub fn outer_exclusive_binder(self) -> ty::DebruijnIndex { self.0.outer_exclusive_binder } } pub enum ExplicitSelf<'tcx> { ByValue, ByReference(ty::Region<'tcx>, hir::Mutability), ByRawPointer(hir::Mutability), ByBox, Other, } impl<'tcx> ExplicitSelf<'tcx> { /// Categorizes an explicit self declaration like `self: SomeType` /// into either `self`, `&self`, `&mut self`, `Box`, or /// `Other`. /// This is mainly used to require the arbitrary_self_types feature /// in the case of `Other`, to improve error messages in the common cases, /// and to make `Other` non-object-safe. /// /// Examples: /// /// ```ignore (illustrative) /// impl<'a> Foo for &'a T { /// // Legal declarations: /// fn method1(self: &&'a T); // ExplicitSelf::ByReference /// fn method2(self: &'a T); // ExplicitSelf::ByValue /// fn method3(self: Box<&'a T>); // ExplicitSelf::ByBox /// fn method4(self: Rc<&'a T>); // ExplicitSelf::Other /// /// // Invalid cases will be caught by `check_method_receiver`: /// fn method_err1(self: &'a mut T); // ExplicitSelf::Other /// fn method_err2(self: &'static T) // ExplicitSelf::ByValue /// fn method_err3(self: &&T) // ExplicitSelf::ByReference /// } /// ``` /// pub fn determine

(self_arg_ty: Ty<'tcx>, is_self_ty: P) -> ExplicitSelf<'tcx> where P: Fn(Ty<'tcx>) -> bool, { use self::ExplicitSelf::*; match *self_arg_ty.kind() { _ if is_self_ty(self_arg_ty) => ByValue, ty::Ref(region, ty, mutbl) if is_self_ty(ty) => ByReference(region, mutbl), ty::RawPtr(ty::TypeAndMut { ty, mutbl }) if is_self_ty(ty) => ByRawPointer(mutbl), ty::Adt(def, _) if def.is_box() && is_self_ty(self_arg_ty.boxed_ty()) => ByBox, _ => Other, } } } /// Returns a list of types such that the given type needs drop if and only if /// *any* of the returned types need drop. Returns `Err(AlwaysRequiresDrop)` if /// this type always needs drop. pub fn needs_drop_components<'tcx>( tcx: TyCtxt<'tcx>, ty: Ty<'tcx>, ) -> Result; 2]>, AlwaysRequiresDrop> { match *ty.kind() { ty::Infer(ty::FreshIntTy(_)) | ty::Infer(ty::FreshFloatTy(_)) | ty::Bool | ty::Int(_) | ty::Uint(_) | ty::Float(_) | ty::Never | ty::FnDef(..) | ty::FnPtr(_) | ty::Char | ty::RawPtr(_) | ty::Ref(..) | ty::Str => Ok(SmallVec::new()), // Foreign types can never have destructors. ty::Foreign(..) => Ok(SmallVec::new()), ty::Dynamic(..) | ty::Error(_) => Err(AlwaysRequiresDrop), ty::Slice(ty) => needs_drop_components(tcx, ty), ty::Array(elem_ty, size) => { match needs_drop_components(tcx, elem_ty) { Ok(v) if v.is_empty() => Ok(v), res => match size.try_to_target_usize(tcx) { // Arrays of size zero don't need drop, even if their element // type does. Some(0) => Ok(SmallVec::new()), Some(_) => res, // We don't know which of the cases above we are in, so // return the whole type and let the caller decide what to // do. None => Ok(smallvec![ty]), }, } } // If any field needs drop, then the whole tuple does. ty::Tuple(fields) => fields.iter().try_fold(SmallVec::new(), move |mut acc, elem| { acc.extend(needs_drop_components(tcx, elem)?); Ok(acc) }), // These require checking for `Copy` bounds or `Adt` destructors. ty::Adt(..) | ty::Alias(..) | ty::Param(_) | ty::Bound(..) | ty::Placeholder(..) | ty::Infer(_) | ty::Closure(..) | ty::Coroutine(..) | ty::CoroutineWitness(..) => Ok(smallvec![ty]), } } pub fn is_trivially_const_drop(ty: Ty<'_>) -> bool { match *ty.kind() { ty::Bool | ty::Char | ty::Int(_) | ty::Uint(_) | ty::Float(_) | ty::Infer(ty::IntVar(_)) | ty::Infer(ty::FloatVar(_)) | ty::Str | ty::RawPtr(_) | ty::Ref(..) | ty::FnDef(..) | ty::FnPtr(_) | ty::Never | ty::Foreign(_) => true, ty::Alias(..) | ty::Dynamic(..) | ty::Error(_) | ty::Bound(..) | ty::Param(_) | ty::Placeholder(_) | ty::Infer(_) => false, // Not trivial because they have components, and instead of looking inside, // we'll just perform trait selection. ty::Closure(..) | ty::Coroutine(..) | ty::CoroutineWitness(..) | ty::Adt(..) => false, ty::Array(ty, _) | ty::Slice(ty) => is_trivially_const_drop(ty), ty::Tuple(tys) => tys.iter().all(|ty| is_trivially_const_drop(ty)), } } /// Does the equivalent of /// ```ignore (illustrative) /// let v = self.iter().map(|p| p.fold_with(folder)).collect::>(); /// folder.tcx().intern_*(&v) /// ``` pub fn fold_list<'tcx, F, T>( list: &'tcx ty::List, folder: &mut F, intern: impl FnOnce(TyCtxt<'tcx>, &[T]) -> &'tcx ty::List, ) -> Result<&'tcx ty::List, F::Error> where F: FallibleTypeFolder>, T: TypeFoldable> + PartialEq + Copy, { let mut iter = list.iter(); // Look for the first element that changed match iter.by_ref().enumerate().find_map(|(i, t)| match t.try_fold_with(folder) { Ok(new_t) if new_t == t => None, new_t => Some((i, new_t)), }) { Some((i, Ok(new_t))) => { // An element changed, prepare to intern the resulting list let mut new_list = SmallVec::<[_; 8]>::with_capacity(list.len()); new_list.extend_from_slice(&list[..i]); new_list.push(new_t); for t in iter { new_list.push(t.try_fold_with(folder)?) } Ok(intern(folder.interner(), &new_list)) } Some((_, Err(err))) => { return Err(err); } None => Ok(list), } } #[derive(Copy, Clone, Debug, HashStable, TyEncodable, TyDecodable)] pub struct AlwaysRequiresDrop; /// Reveals all opaque types in the given value, replacing them /// with their underlying types. pub fn reveal_opaque_types_in_bounds<'tcx>( tcx: TyCtxt<'tcx>, val: &'tcx ty::List>, ) -> &'tcx ty::List> { let mut visitor = OpaqueTypeExpander { seen_opaque_tys: FxHashSet::default(), expanded_cache: FxHashMap::default(), primary_def_id: None, found_recursion: false, found_any_recursion: false, check_recursion: false, expand_coroutines: false, tcx, }; val.fold_with(&mut visitor) } /// Determines whether an item is annotated with `doc(hidden)`. fn is_doc_hidden(tcx: TyCtxt<'_>, def_id: LocalDefId) -> bool { tcx.get_attrs(def_id, sym::doc) .filter_map(|attr| attr.meta_item_list()) .any(|items| items.iter().any(|item| item.has_name(sym::hidden))) } /// Determines whether an item is annotated with `doc(notable_trait)`. pub fn is_doc_notable_trait(tcx: TyCtxt<'_>, def_id: DefId) -> bool { tcx.get_attrs(def_id, sym::doc) .filter_map(|attr| attr.meta_item_list()) .any(|items| items.iter().any(|item| item.has_name(sym::notable_trait))) } /// Determines whether an item is an intrinsic by Abi. pub fn is_intrinsic(tcx: TyCtxt<'_>, def_id: LocalDefId) -> bool { matches!(tcx.fn_sig(def_id).skip_binder().abi(), Abi::RustIntrinsic | Abi::PlatformIntrinsic) } pub fn provide(providers: &mut Providers) { *providers = Providers { reveal_opaque_types_in_bounds, is_doc_hidden, is_doc_notable_trait, is_intrinsic, ..*providers } }