//! Candidate assembly. //! //! The selection process begins by examining all in-scope impls, //! caller obligations, and so forth and assembling a list of //! candidates. See the [rustc dev guide] for more details. //! //! [rustc dev guide]:https://rustc-dev-guide.rust-lang.org/traits/resolution.html#candidate-assembly use hir::LangItem; use rustc_hir as hir; use rustc_infer::traits::ObligationCause; use rustc_infer::traits::{Obligation, SelectionError, TraitObligation}; use rustc_middle::ty::{self, Ty, TypeVisitableExt}; use rustc_target::spec::abi::Abi; use crate::traits; use crate::traits::query::evaluate_obligation::InferCtxtExt; use crate::traits::util; use super::BuiltinImplConditions; use super::SelectionCandidate::*; use super::{SelectionCandidateSet, SelectionContext, TraitObligationStack}; impl<'cx, 'tcx> SelectionContext<'cx, 'tcx> { #[instrument(skip(self, stack), level = "debug")] pub(super) fn assemble_candidates<'o>( &mut self, stack: &TraitObligationStack<'o, 'tcx>, ) -> Result, SelectionError<'tcx>> { let TraitObligationStack { obligation, .. } = *stack; let obligation = &Obligation { param_env: obligation.param_env, cause: obligation.cause.clone(), recursion_depth: obligation.recursion_depth, predicate: self.infcx.resolve_vars_if_possible(obligation.predicate), }; if obligation.predicate.skip_binder().self_ty().is_ty_var() { debug!(ty = ?obligation.predicate.skip_binder().self_ty(), "ambiguous inference var or opaque type"); // Self is a type variable (e.g., `_: AsRef`). // // This is somewhat problematic, as the current scheme can't really // handle it turning to be a projection. This does end up as truly // ambiguous in most cases anyway. // // Take the fast path out - this also improves // performance by preventing assemble_candidates_from_impls from // matching every impl for this trait. return Ok(SelectionCandidateSet { vec: vec![], ambiguous: true }); } let mut candidates = SelectionCandidateSet { vec: Vec::new(), ambiguous: false }; // The only way to prove a NotImplemented(T: Foo) predicate is via a negative impl. // There are no compiler built-in rules for this. if obligation.polarity() == ty::ImplPolarity::Negative { self.assemble_candidates_for_trait_alias(obligation, &mut candidates); self.assemble_candidates_from_impls(obligation, &mut candidates); } else { self.assemble_candidates_for_trait_alias(obligation, &mut candidates); // Other bounds. Consider both in-scope bounds from fn decl // and applicable impls. There is a certain set of precedence rules here. let def_id = obligation.predicate.def_id(); let lang_items = self.tcx().lang_items(); if lang_items.copy_trait() == Some(def_id) { debug!(obligation_self_ty = ?obligation.predicate.skip_binder().self_ty()); // User-defined copy impls are permitted, but only for // structs and enums. self.assemble_candidates_from_impls(obligation, &mut candidates); // For other types, we'll use the builtin rules. let copy_conditions = self.copy_clone_conditions(obligation); self.assemble_builtin_bound_candidates(copy_conditions, &mut candidates); } else if lang_items.discriminant_kind_trait() == Some(def_id) { // `DiscriminantKind` is automatically implemented for every type. candidates.vec.push(BuiltinCandidate { has_nested: false }); } else if lang_items.pointee_trait() == Some(def_id) { // `Pointee` is automatically implemented for every type. candidates.vec.push(BuiltinCandidate { has_nested: false }); } else if lang_items.sized_trait() == Some(def_id) { // Sized is never implementable by end-users, it is // always automatically computed. let sized_conditions = self.sized_conditions(obligation); self.assemble_builtin_bound_candidates(sized_conditions, &mut candidates); } else if lang_items.unsize_trait() == Some(def_id) { self.assemble_candidates_for_unsizing(obligation, &mut candidates); } else if lang_items.destruct_trait() == Some(def_id) { self.assemble_const_destruct_candidates(obligation, &mut candidates); } else if lang_items.transmute_trait() == Some(def_id) { // User-defined transmutability impls are permitted. self.assemble_candidates_from_impls(obligation, &mut candidates); self.assemble_candidates_for_transmutability(obligation, &mut candidates); } else if lang_items.tuple_trait() == Some(def_id) { self.assemble_candidate_for_tuple(obligation, &mut candidates); } else if lang_items.pointer_like() == Some(def_id) { self.assemble_candidate_for_ptr_sized(obligation, &mut candidates); } else { if lang_items.clone_trait() == Some(def_id) { // Same builtin conditions as `Copy`, i.e., every type which has builtin support // for `Copy` also has builtin support for `Clone`, and tuples/arrays of `Clone` // types have builtin support for `Clone`. let clone_conditions = self.copy_clone_conditions(obligation); self.assemble_builtin_bound_candidates(clone_conditions, &mut candidates); } if lang_items.gen_trait() == Some(def_id) { self.assemble_generator_candidates(obligation, &mut candidates); } else if lang_items.future_trait() == Some(def_id) { self.assemble_future_candidates(obligation, &mut candidates); } self.assemble_closure_candidates(obligation, &mut candidates); self.assemble_fn_pointer_candidates(obligation, &mut candidates); self.assemble_candidates_from_impls(obligation, &mut candidates); self.assemble_candidates_from_object_ty(obligation, &mut candidates); } self.assemble_candidates_from_projected_tys(obligation, &mut candidates); self.assemble_candidates_from_caller_bounds(stack, &mut candidates)?; // Auto implementations have lower priority, so we only // consider triggering a default if there is no other impl that can apply. if candidates.vec.is_empty() { self.assemble_candidates_from_auto_impls(obligation, &mut candidates); } } debug!("candidate list size: {}", candidates.vec.len()); Ok(candidates) } #[instrument(level = "debug", skip(self, candidates))] fn assemble_candidates_from_projected_tys( &mut self, obligation: &TraitObligation<'tcx>, candidates: &mut SelectionCandidateSet<'tcx>, ) { // Before we go into the whole placeholder thing, just // quickly check if the self-type is a projection at all. match obligation.predicate.skip_binder().trait_ref.self_ty().kind() { ty::Alias(..) => {} ty::Infer(ty::TyVar(_)) => { span_bug!( obligation.cause.span, "Self=_ should have been handled by assemble_candidates" ); } _ => return, } let result = self .infcx .probe(|_| self.match_projection_obligation_against_definition_bounds(obligation)); candidates .vec .extend(result.into_iter().map(|(idx, constness)| ProjectionCandidate(idx, constness))); } /// Given an obligation like ``, searches the obligations that the caller /// supplied to find out whether it is listed among them. /// /// Never affects the inference environment. #[instrument(level = "debug", skip(self, stack, candidates))] fn assemble_candidates_from_caller_bounds<'o>( &mut self, stack: &TraitObligationStack<'o, 'tcx>, candidates: &mut SelectionCandidateSet<'tcx>, ) -> Result<(), SelectionError<'tcx>> { debug!(?stack.obligation); let all_bounds = stack .obligation .param_env .caller_bounds() .iter() .filter(|p| !p.references_error()) .filter_map(|p| p.to_opt_poly_trait_pred()); // Micro-optimization: filter out predicates relating to different traits. let matching_bounds = all_bounds.filter(|p| p.def_id() == stack.obligation.predicate.def_id()); // Keep only those bounds which may apply, and propagate overflow if it occurs. for bound in matching_bounds { // FIXME(oli-obk): it is suspicious that we are dropping the constness and // polarity here. let wc = self.where_clause_may_apply(stack, bound.map_bound(|t| t.trait_ref))?; if wc.may_apply() { candidates.vec.push(ParamCandidate(bound)); } } Ok(()) } fn assemble_generator_candidates( &mut self, obligation: &TraitObligation<'tcx>, candidates: &mut SelectionCandidateSet<'tcx>, ) { // Okay to skip binder because the substs on generator types never // touch bound regions, they just capture the in-scope // type/region parameters. let self_ty = obligation.self_ty().skip_binder(); match self_ty.kind() { // async constructs get lowered to a special kind of generator that // should *not* `impl Generator`. ty::Generator(did, ..) if !self.tcx().generator_is_async(*did) => { debug!(?self_ty, ?obligation, "assemble_generator_candidates",); candidates.vec.push(GeneratorCandidate); } ty::Infer(ty::TyVar(_)) => { debug!("assemble_generator_candidates: ambiguous self-type"); candidates.ambiguous = true; } _ => {} } } fn assemble_future_candidates( &mut self, obligation: &TraitObligation<'tcx>, candidates: &mut SelectionCandidateSet<'tcx>, ) { let self_ty = obligation.self_ty().skip_binder(); if let ty::Generator(did, ..) = self_ty.kind() { // async constructs get lowered to a special kind of generator that // should directly `impl Future`. if self.tcx().generator_is_async(*did) { debug!(?self_ty, ?obligation, "assemble_future_candidates",); candidates.vec.push(FutureCandidate); } } } /// Checks for the artificial impl that the compiler will create for an obligation like `X : /// FnMut<..>` where `X` is a closure type. /// /// Note: the type parameters on a closure candidate are modeled as *output* type /// parameters and hence do not affect whether this trait is a match or not. They will be /// unified during the confirmation step. fn assemble_closure_candidates( &mut self, obligation: &TraitObligation<'tcx>, candidates: &mut SelectionCandidateSet<'tcx>, ) { let Some(kind) = self.tcx().fn_trait_kind_from_def_id(obligation.predicate.def_id()) else { return; }; // Okay to skip binder because the substs on closure types never // touch bound regions, they just capture the in-scope // type/region parameters match *obligation.self_ty().skip_binder().kind() { ty::Closure(def_id, closure_substs) => { let is_const = self.tcx().is_const_fn_raw(def_id); debug!(?kind, ?obligation, "assemble_unboxed_candidates"); match self.infcx.closure_kind(closure_substs) { Some(closure_kind) => { debug!(?closure_kind, "assemble_unboxed_candidates"); if closure_kind.extends(kind) { candidates.vec.push(ClosureCandidate { is_const }); } } None => { debug!("assemble_unboxed_candidates: closure_kind not yet known"); candidates.vec.push(ClosureCandidate { is_const }); } } } ty::Infer(ty::TyVar(_)) => { debug!("assemble_unboxed_closure_candidates: ambiguous self-type"); candidates.ambiguous = true; } _ => {} } } /// Implements one of the `Fn()` family for a fn pointer. fn assemble_fn_pointer_candidates( &mut self, obligation: &TraitObligation<'tcx>, candidates: &mut SelectionCandidateSet<'tcx>, ) { // We provide impl of all fn traits for fn pointers. if !self.tcx().is_fn_trait(obligation.predicate.def_id()) { return; } // Okay to skip binder because what we are inspecting doesn't involve bound regions. let self_ty = obligation.self_ty().skip_binder(); match *self_ty.kind() { ty::Infer(ty::TyVar(_)) => { debug!("assemble_fn_pointer_candidates: ambiguous self-type"); candidates.ambiguous = true; // Could wind up being a fn() type. } // Provide an impl, but only for suitable `fn` pointers. ty::FnPtr(_) => { if let ty::FnSig { unsafety: hir::Unsafety::Normal, abi: Abi::Rust, c_variadic: false, .. } = self_ty.fn_sig(self.tcx()).skip_binder() { candidates.vec.push(FnPointerCandidate { is_const: false }); } } // Provide an impl for suitable functions, rejecting `#[target_feature]` functions (RFC 2396). ty::FnDef(def_id, _) => { if let ty::FnSig { unsafety: hir::Unsafety::Normal, abi: Abi::Rust, c_variadic: false, .. } = self_ty.fn_sig(self.tcx()).skip_binder() { if self.tcx().codegen_fn_attrs(def_id).target_features.is_empty() { candidates .vec .push(FnPointerCandidate { is_const: self.tcx().is_const_fn(def_id) }); } } } _ => {} } } /// Searches for impls that might apply to `obligation`. fn assemble_candidates_from_impls( &mut self, obligation: &TraitObligation<'tcx>, candidates: &mut SelectionCandidateSet<'tcx>, ) { debug!(?obligation, "assemble_candidates_from_impls"); // Essentially any user-written impl will match with an error type, // so creating `ImplCandidates` isn't useful. However, we might // end up finding a candidate elsewhere (e.g. a `BuiltinCandidate` for `Sized`) // This helps us avoid overflow: see issue #72839 // Since compilation is already guaranteed to fail, this is just // to try to show the 'nicest' possible errors to the user. // We don't check for errors in the `ParamEnv` - in practice, // it seems to cause us to be overly aggressive in deciding // to give up searching for candidates, leading to spurious errors. if obligation.predicate.references_error() { return; } self.tcx().for_each_relevant_impl( obligation.predicate.def_id(), obligation.predicate.skip_binder().trait_ref.self_ty(), |impl_def_id| { // Before we create the substitutions and everything, first // consider a "quick reject". This avoids creating more types // and so forth that we need to. let impl_trait_ref = self.tcx().impl_trait_ref(impl_def_id).unwrap(); if self.fast_reject_trait_refs(obligation, &impl_trait_ref.0) { return; } self.infcx.probe(|_| { if let Ok(_substs) = self.match_impl(impl_def_id, impl_trait_ref, obligation) { candidates.vec.push(ImplCandidate(impl_def_id)); } }); }, ); } fn assemble_candidates_from_auto_impls( &mut self, obligation: &TraitObligation<'tcx>, candidates: &mut SelectionCandidateSet<'tcx>, ) { // Okay to skip binder here because the tests we do below do not involve bound regions. let self_ty = obligation.self_ty().skip_binder(); debug!(?self_ty, "assemble_candidates_from_auto_impls"); let def_id = obligation.predicate.def_id(); if self.tcx().trait_is_auto(def_id) { match self_ty.kind() { ty::Dynamic(..) => { // For object types, we don't know what the closed // over types are. This means we conservatively // say nothing; a candidate may be added by // `assemble_candidates_from_object_ty`. } ty::Foreign(..) => { // Since the contents of foreign types is unknown, // we don't add any `..` impl. Default traits could // still be provided by a manual implementation for // this trait and type. } ty::Param(..) | ty::Alias(ty::Projection, ..) | ty::Placeholder(..) | ty::Bound(..) => { // In these cases, we don't know what the actual // type is. Therefore, we cannot break it down // into its constituent types. So we don't // consider the `..` impl but instead just add no // candidates: this means that typeck will only // succeed if there is another reason to believe // that this obligation holds. That could be a // where-clause or, in the case of an object type, // it could be that the object type lists the // trait (e.g., `Foo+Send : Send`). See // `ui/typeck/typeck-default-trait-impl-send-param.rs` // for an example of a test case that exercises // this path. } ty::Infer(ty::TyVar(_)) => { // The auto impl might apply; we don't know. candidates.ambiguous = true; } ty::Generator(_, _, movability) if self.tcx().lang_items().unpin_trait() == Some(def_id) => { match movability { hir::Movability::Static => { // Immovable generators are never `Unpin`, so // suppress the normal auto-impl candidate for it. } hir::Movability::Movable => { // Movable generators are always `Unpin`, so add an // unconditional builtin candidate. candidates.vec.push(BuiltinCandidate { has_nested: false }); } } } _ => candidates.vec.push(AutoImplCandidate), } } } /// Searches for impls that might apply to `obligation`. fn assemble_candidates_from_object_ty( &mut self, obligation: &TraitObligation<'tcx>, candidates: &mut SelectionCandidateSet<'tcx>, ) { debug!( self_ty = ?obligation.self_ty().skip_binder(), "assemble_candidates_from_object_ty", ); self.infcx.probe(|_snapshot| { if obligation.has_non_region_late_bound() { return; } // The code below doesn't care about regions, and the // self-ty here doesn't escape this probe, so just erase // any LBR. let self_ty = self.tcx().erase_late_bound_regions(obligation.self_ty()); let poly_trait_ref = match self_ty.kind() { ty::Dynamic(ref data, ..) => { if data.auto_traits().any(|did| did == obligation.predicate.def_id()) { debug!( "assemble_candidates_from_object_ty: matched builtin bound, \ pushing candidate" ); candidates.vec.push(BuiltinObjectCandidate); return; } if let Some(principal) = data.principal() { if !self.infcx.tcx.features().object_safe_for_dispatch { principal.with_self_ty(self.tcx(), self_ty) } else if self.tcx().check_is_object_safe(principal.def_id()) { principal.with_self_ty(self.tcx(), self_ty) } else { return; } } else { // Only auto trait bounds exist. return; } } ty::Infer(ty::TyVar(_)) => { debug!("assemble_candidates_from_object_ty: ambiguous"); candidates.ambiguous = true; // could wind up being an object type return; } _ => return, }; debug!(?poly_trait_ref, "assemble_candidates_from_object_ty"); let poly_trait_predicate = self.infcx.resolve_vars_if_possible(obligation.predicate); let placeholder_trait_predicate = self.infcx.instantiate_binder_with_placeholders(poly_trait_predicate); // Count only those upcast versions that match the trait-ref // we are looking for. Specifically, do not only check for the // correct trait, but also the correct type parameters. // For example, we may be trying to upcast `Foo` to `Bar`, // but `Foo` is declared as `trait Foo: Bar`. let candidate_supertraits = util::supertraits(self.tcx(), poly_trait_ref) .enumerate() .filter(|&(_, upcast_trait_ref)| { self.infcx.probe(|_| { self.match_normalize_trait_ref( obligation, upcast_trait_ref, placeholder_trait_predicate.trait_ref, ) .is_ok() }) }) .map(|(idx, _)| ObjectCandidate(idx)); candidates.vec.extend(candidate_supertraits); }) } /// Temporary migration for #89190 fn need_migrate_deref_output_trait_object( &mut self, ty: Ty<'tcx>, param_env: ty::ParamEnv<'tcx>, cause: &ObligationCause<'tcx>, ) -> Option> { let tcx = self.tcx(); if tcx.features().trait_upcasting { return None; } // let trait_ref = tcx.mk_trait_ref(tcx.lang_items().deref_trait()?, [ty]); let obligation = traits::Obligation::new(tcx, cause.clone(), param_env, ty::Binder::dummy(trait_ref)); if !self.infcx.predicate_may_hold(&obligation) { return None; } self.infcx.probe(|_| { let ty = traits::normalize_projection_type( self, param_env, tcx.mk_alias_ty(tcx.lang_items().deref_target()?, trait_ref.substs), cause.clone(), 0, // We're *intentionally* throwing these away, // since we don't actually use them. &mut vec![], ) .ty() .unwrap(); if let ty::Dynamic(data, ..) = ty.kind() { data.principal() } else { None } }) } /// Searches for unsizing that might apply to `obligation`. fn assemble_candidates_for_unsizing( &mut self, obligation: &TraitObligation<'tcx>, candidates: &mut SelectionCandidateSet<'tcx>, ) { // We currently never consider higher-ranked obligations e.g. // `for<'a> &'a T: Unsize` to be implemented. This is not // because they are a priori invalid, and we could potentially add support // for them later, it's just that there isn't really a strong need for it. // A `T: Unsize` obligation is always used as part of a `T: CoerceUnsize` // impl, and those are generally applied to concrete types. // // That said, one might try to write a fn with a where clause like // for<'a> Foo<'a, T>: Unsize> // where the `'a` is kind of orthogonal to the relevant part of the `Unsize`. // Still, you'd be more likely to write that where clause as // T: Trait // so it seems ok if we (conservatively) fail to accept that `Unsize` // obligation above. Should be possible to extend this in the future. let Some(source) = obligation.self_ty().no_bound_vars() else { // Don't add any candidates if there are bound regions. return; }; let target = obligation.predicate.skip_binder().trait_ref.substs.type_at(1); debug!(?source, ?target, "assemble_candidates_for_unsizing"); match (source.kind(), target.kind()) { // Trait+Kx+'a -> Trait+Ky+'b (upcasts). (&ty::Dynamic(ref data_a, _, ty::Dyn), &ty::Dynamic(ref data_b, _, ty::Dyn)) => { // Upcast coercions permit several things: // // 1. Dropping auto traits, e.g., `Foo + Send` to `Foo` // 2. Tightening the region bound, e.g., `Foo + 'a` to `Foo + 'b` if `'a: 'b` // 3. Tightening trait to its super traits, eg. `Foo` to `Bar` if `Foo: Bar` // // Note that neither of the first two of these changes requires any // change at runtime. The third needs to change pointer metadata at runtime. // // We always perform upcasting coercions when we can because of reason // #2 (region bounds). let auto_traits_compatible = data_b .auto_traits() // All of a's auto traits need to be in b's auto traits. .all(|b| data_a.auto_traits().any(|a| a == b)); if auto_traits_compatible { let principal_def_id_a = data_a.principal_def_id(); let principal_def_id_b = data_b.principal_def_id(); if principal_def_id_a == principal_def_id_b { // no cyclic candidates.vec.push(BuiltinUnsizeCandidate); } else if principal_def_id_a.is_some() && principal_def_id_b.is_some() { // not casual unsizing, now check whether this is trait upcasting coercion. let principal_a = data_a.principal().unwrap(); let target_trait_did = principal_def_id_b.unwrap(); let source_trait_ref = principal_a.with_self_ty(self.tcx(), source); if let Some(deref_trait_ref) = self.need_migrate_deref_output_trait_object( source, obligation.param_env, &obligation.cause, ) { if deref_trait_ref.def_id() == target_trait_did { return; } } for (idx, upcast_trait_ref) in util::supertraits(self.tcx(), source_trait_ref).enumerate() { if upcast_trait_ref.def_id() == target_trait_did { candidates.vec.push(TraitUpcastingUnsizeCandidate(idx)); } } } } } // `T` -> `Trait` (_, &ty::Dynamic(_, _, ty::Dyn)) => { candidates.vec.push(BuiltinUnsizeCandidate); } // Ambiguous handling is below `T` -> `Trait`, because inference // variables can still implement `Unsize` and nested // obligations will have the final say (likely deferred). (&ty::Infer(ty::TyVar(_)), _) | (_, &ty::Infer(ty::TyVar(_))) => { debug!("assemble_candidates_for_unsizing: ambiguous"); candidates.ambiguous = true; } // `[T; n]` -> `[T]` (&ty::Array(..), &ty::Slice(_)) => { candidates.vec.push(BuiltinUnsizeCandidate); } // `Struct` -> `Struct` (&ty::Adt(def_id_a, _), &ty::Adt(def_id_b, _)) if def_id_a.is_struct() => { if def_id_a == def_id_b { candidates.vec.push(BuiltinUnsizeCandidate); } } // `(.., T)` -> `(.., U)` (&ty::Tuple(tys_a), &ty::Tuple(tys_b)) => { if tys_a.len() == tys_b.len() { candidates.vec.push(BuiltinUnsizeCandidate); } } _ => {} }; } #[instrument(level = "debug", skip(self, obligation, candidates))] fn assemble_candidates_for_transmutability( &mut self, obligation: &TraitObligation<'tcx>, candidates: &mut SelectionCandidateSet<'tcx>, ) { if obligation.has_non_region_param() { return; } if obligation.has_non_region_infer() { candidates.ambiguous = true; return; } candidates.vec.push(TransmutabilityCandidate); } #[instrument(level = "debug", skip(self, obligation, candidates))] fn assemble_candidates_for_trait_alias( &mut self, obligation: &TraitObligation<'tcx>, candidates: &mut SelectionCandidateSet<'tcx>, ) { // Okay to skip binder here because the tests we do below do not involve bound regions. let self_ty = obligation.self_ty().skip_binder(); debug!(?self_ty); let def_id = obligation.predicate.def_id(); if self.tcx().is_trait_alias(def_id) { candidates.vec.push(TraitAliasCandidate); } } /// Assembles the trait which are built-in to the language itself: /// `Copy`, `Clone` and `Sized`. #[instrument(level = "debug", skip(self, candidates))] fn assemble_builtin_bound_candidates( &mut self, conditions: BuiltinImplConditions<'tcx>, candidates: &mut SelectionCandidateSet<'tcx>, ) { match conditions { BuiltinImplConditions::Where(nested) => { candidates .vec .push(BuiltinCandidate { has_nested: !nested.skip_binder().is_empty() }); } BuiltinImplConditions::None => {} BuiltinImplConditions::Ambiguous => { candidates.ambiguous = true; } } } fn assemble_const_destruct_candidates( &mut self, obligation: &TraitObligation<'tcx>, candidates: &mut SelectionCandidateSet<'tcx>, ) { // If the predicate is `~const Destruct` in a non-const environment, we don't actually need // to check anything. We'll short-circuit checking any obligations in confirmation, too. if !obligation.is_const() { candidates.vec.push(ConstDestructCandidate(None)); return; } let self_ty = self.infcx.shallow_resolve(obligation.self_ty()); match self_ty.skip_binder().kind() { ty::Alias(..) | ty::Dynamic(..) | ty::Error(_) | ty::Bound(..) | ty::Param(_) | ty::Placeholder(_) => { // We don't know if these are `~const Destruct`, at least // not structurally... so don't push a candidate. } 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(_) | ty::Array(..) | ty::Slice(_) | ty::Closure(..) | ty::Generator(..) | ty::Tuple(_) | ty::GeneratorWitness(_) | ty::GeneratorWitnessMIR(..) => { // These are built-in, and cannot have a custom `impl const Destruct`. candidates.vec.push(ConstDestructCandidate(None)); } ty::Adt(..) => { // Find a custom `impl Drop` impl, if it exists let relevant_impl = self.tcx().find_map_relevant_impl( self.tcx().require_lang_item(LangItem::Drop, None), obligation.predicate.skip_binder().trait_ref.self_ty(), Some, ); if let Some(impl_def_id) = relevant_impl { // Check that `impl Drop` is actually const, if there is a custom impl if self.tcx().constness(impl_def_id) == hir::Constness::Const { candidates.vec.push(ConstDestructCandidate(Some(impl_def_id))); } } else { // Otherwise check the ADT like a built-in type (structurally) candidates.vec.push(ConstDestructCandidate(None)); } } ty::Infer(_) => { candidates.ambiguous = true; } } } fn assemble_candidate_for_tuple( &mut self, obligation: &TraitObligation<'tcx>, candidates: &mut SelectionCandidateSet<'tcx>, ) { let self_ty = self.infcx.shallow_resolve(obligation.self_ty().skip_binder()); match self_ty.kind() { ty::Tuple(_) => { candidates.vec.push(BuiltinCandidate { has_nested: false }); } ty::Infer(ty::TyVar(_)) => { candidates.ambiguous = true; } ty::Bool | ty::Char | ty::Int(_) | ty::Uint(_) | ty::Float(_) | ty::Adt(_, _) | ty::Foreign(_) | ty::Str | ty::Array(_, _) | ty::Slice(_) | ty::RawPtr(_) | ty::Ref(_, _, _) | ty::FnDef(_, _) | ty::FnPtr(_) | ty::Dynamic(_, _, _) | ty::Closure(_, _) | ty::Generator(_, _, _) | ty::GeneratorWitness(_) | ty::GeneratorWitnessMIR(..) | ty::Never | ty::Alias(..) | ty::Param(_) | ty::Bound(_, _) | ty::Error(_) | ty::Infer(_) | ty::Placeholder(_) => {} } } fn assemble_candidate_for_ptr_sized( &mut self, obligation: &TraitObligation<'tcx>, candidates: &mut SelectionCandidateSet<'tcx>, ) { // The regions of a type don't affect the size of the type let self_ty = self .tcx() .erase_regions(self.tcx().erase_late_bound_regions(obligation.predicate.self_ty())); // But if there are inference variables, we have to wait until it's resolved. if self_ty.has_non_region_infer() { candidates.ambiguous = true; return; } let usize_layout = self.tcx().layout_of(ty::ParamEnv::empty().and(self.tcx().types.usize)).unwrap().layout; if let Ok(layout) = self.tcx().layout_of(obligation.param_env.and(self_ty)) && layout.layout.size() == usize_layout.size() && layout.layout.align().abi == usize_layout.align().abi { candidates.vec.push(BuiltinCandidate { has_nested: false }); } } }