//! Confirmation. //! //! Confirmation unifies the output type parameters of the trait //! with the values found in the obligation, possibly yielding a //! type error. See the [rustc dev guide] for more details. //! //! [rustc dev guide]: //! https://rustc-dev-guide.rust-lang.org/traits/resolution.html#confirmation use rustc_data_structures::stack::ensure_sufficient_stack; use rustc_hir::lang_items::LangItem; use rustc_index::bit_set::GrowableBitSet; use rustc_infer::infer::InferOk; use rustc_infer::infer::LateBoundRegionConversionTime::HigherRankedType; use rustc_middle::ty::subst::{GenericArg, GenericArgKind, InternalSubsts, Subst, SubstsRef}; use rustc_middle::ty::{self, GenericParamDefKind, Ty, TyCtxt}; use rustc_middle::ty::{ToPolyTraitRef, ToPredicate}; use rustc_span::def_id::DefId; use crate::traits::project::{normalize_with_depth, normalize_with_depth_to}; use crate::traits::util::{self, closure_trait_ref_and_return_type, predicate_for_trait_def}; use crate::traits::{ BuiltinDerivedObligation, ImplDerivedObligation, ImplDerivedObligationCause, ImplSource, ImplSourceAutoImplData, ImplSourceBuiltinData, ImplSourceClosureData, ImplSourceConstDestructData, ImplSourceDiscriminantKindData, ImplSourceFnPointerData, ImplSourceGeneratorData, ImplSourceObjectData, ImplSourcePointeeData, ImplSourceTraitAliasData, ImplSourceTraitUpcastingData, ImplSourceUserDefinedData, Normalized, ObjectCastObligation, Obligation, ObligationCause, OutputTypeParameterMismatch, PredicateObligation, Selection, SelectionError, TraitNotObjectSafe, TraitObligation, Unimplemented, VtblSegment, }; use super::BuiltinImplConditions; use super::SelectionCandidate::{self, *}; use super::SelectionContext; use std::iter; use std::ops::ControlFlow; impl<'cx, 'tcx> SelectionContext<'cx, 'tcx> { #[instrument(level = "debug", skip(self))] pub(super) fn confirm_candidate( &mut self, obligation: &TraitObligation<'tcx>, candidate: SelectionCandidate<'tcx>, ) -> Result, SelectionError<'tcx>> { let mut impl_src = match candidate { BuiltinCandidate { has_nested } => { let data = self.confirm_builtin_candidate(obligation, has_nested); ImplSource::Builtin(data) } TransmutabilityCandidate => { let data = self.confirm_transmutability_candidate(obligation)?; ImplSource::Builtin(data) } ParamCandidate(param) => { let obligations = self.confirm_param_candidate(obligation, param.map_bound(|t| t.trait_ref)); ImplSource::Param(obligations, param.skip_binder().constness) } ImplCandidate(impl_def_id) => { ImplSource::UserDefined(self.confirm_impl_candidate(obligation, impl_def_id)) } AutoImplCandidate(trait_def_id) => { let data = self.confirm_auto_impl_candidate(obligation, trait_def_id); ImplSource::AutoImpl(data) } ProjectionCandidate(idx) => { let obligations = self.confirm_projection_candidate(obligation, idx)?; // FIXME(jschievink): constness ImplSource::Param(obligations, ty::BoundConstness::NotConst) } ObjectCandidate(idx) => { let data = self.confirm_object_candidate(obligation, idx)?; ImplSource::Object(data) } ClosureCandidate => { let vtable_closure = self.confirm_closure_candidate(obligation)?; ImplSource::Closure(vtable_closure) } GeneratorCandidate => { let vtable_generator = self.confirm_generator_candidate(obligation)?; ImplSource::Generator(vtable_generator) } FnPointerCandidate { .. } => { let data = self.confirm_fn_pointer_candidate(obligation)?; ImplSource::FnPointer(data) } DiscriminantKindCandidate => { ImplSource::DiscriminantKind(ImplSourceDiscriminantKindData) } PointeeCandidate => ImplSource::Pointee(ImplSourcePointeeData), TraitAliasCandidate(alias_def_id) => { let data = self.confirm_trait_alias_candidate(obligation, alias_def_id); ImplSource::TraitAlias(data) } BuiltinObjectCandidate => { // This indicates something like `Trait + Send: Send`. In this case, we know that // this holds because that's what the object type is telling us, and there's really // no additional obligations to prove and no types in particular to unify, etc. ImplSource::Param(Vec::new(), ty::BoundConstness::NotConst) } BuiltinUnsizeCandidate => { let data = self.confirm_builtin_unsize_candidate(obligation)?; ImplSource::Builtin(data) } TraitUpcastingUnsizeCandidate(idx) => { let data = self.confirm_trait_upcasting_unsize_candidate(obligation, idx)?; ImplSource::TraitUpcasting(data) } ConstDestructCandidate(def_id) => { let data = self.confirm_const_destruct_candidate(obligation, def_id)?; ImplSource::ConstDestruct(data) } }; if !obligation.predicate.is_const_if_const() { // normalize nested predicates according to parent predicate's constness. impl_src = impl_src.map(|mut o| { o.predicate = o.predicate.without_const(self.tcx()); o }); } Ok(impl_src) } fn confirm_projection_candidate( &mut self, obligation: &TraitObligation<'tcx>, idx: usize, ) -> Result>, SelectionError<'tcx>> { let tcx = self.tcx(); let trait_predicate = self.infcx.shallow_resolve(obligation.predicate); let placeholder_trait_predicate = self.infcx().replace_bound_vars_with_placeholders(trait_predicate).trait_ref; let placeholder_self_ty = placeholder_trait_predicate.self_ty(); let placeholder_trait_predicate = ty::Binder::dummy(placeholder_trait_predicate); let (def_id, substs) = match *placeholder_self_ty.kind() { ty::Projection(proj) => (proj.item_def_id, proj.substs), ty::Opaque(def_id, substs) => (def_id, substs), _ => bug!("projection candidate for unexpected type: {:?}", placeholder_self_ty), }; let candidate_predicate = tcx.bound_item_bounds(def_id).map_bound(|i| i[idx]).subst(tcx, substs); let candidate = candidate_predicate .to_opt_poly_trait_pred() .expect("projection candidate is not a trait predicate") .map_bound(|t| t.trait_ref); let mut obligations = Vec::new(); let candidate = normalize_with_depth_to( self, obligation.param_env, obligation.cause.clone(), obligation.recursion_depth + 1, candidate, &mut obligations, ); obligations.extend(self.infcx.commit_if_ok(|_| { self.infcx .at(&obligation.cause, obligation.param_env) .sup(placeholder_trait_predicate, candidate) .map(|InferOk { obligations, .. }| obligations) .map_err(|_| Unimplemented) })?); if let ty::Projection(..) = placeholder_self_ty.kind() { let predicates = tcx.predicates_of(def_id).instantiate_own(tcx, substs).predicates; debug!(?predicates, "projection predicates"); for predicate in predicates { let normalized = normalize_with_depth_to( self, obligation.param_env, obligation.cause.clone(), obligation.recursion_depth + 1, predicate, &mut obligations, ); obligations.push(Obligation::with_depth( obligation.cause.clone(), obligation.recursion_depth + 1, obligation.param_env, normalized, )); } } Ok(obligations) } fn confirm_param_candidate( &mut self, obligation: &TraitObligation<'tcx>, param: ty::PolyTraitRef<'tcx>, ) -> Vec> { debug!(?obligation, ?param, "confirm_param_candidate"); // During evaluation, we already checked that this // where-clause trait-ref could be unified with the obligation // trait-ref. Repeat that unification now without any // transactional boundary; it should not fail. match self.match_where_clause_trait_ref(obligation, param) { Ok(obligations) => obligations, Err(()) => { bug!( "Where clause `{:?}` was applicable to `{:?}` but now is not", param, obligation ); } } } fn confirm_builtin_candidate( &mut self, obligation: &TraitObligation<'tcx>, has_nested: bool, ) -> ImplSourceBuiltinData> { debug!(?obligation, ?has_nested, "confirm_builtin_candidate"); let lang_items = self.tcx().lang_items(); let obligations = if has_nested { let trait_def = obligation.predicate.def_id(); let conditions = if Some(trait_def) == lang_items.sized_trait() { self.sized_conditions(obligation) } else if Some(trait_def) == lang_items.copy_trait() { self.copy_clone_conditions(obligation) } else if Some(trait_def) == lang_items.clone_trait() { self.copy_clone_conditions(obligation) } else { bug!("unexpected builtin trait {:?}", trait_def) }; let BuiltinImplConditions::Where(nested) = conditions else { bug!("obligation {:?} had matched a builtin impl but now doesn't", obligation); }; let cause = obligation.derived_cause(BuiltinDerivedObligation); ensure_sufficient_stack(|| { self.collect_predicates_for_types( obligation.param_env, cause, obligation.recursion_depth + 1, trait_def, nested, ) }) } else { vec![] }; debug!(?obligations); ImplSourceBuiltinData { nested: obligations } } fn confirm_transmutability_candidate( &mut self, obligation: &TraitObligation<'tcx>, ) -> Result>, SelectionError<'tcx>> { debug!(?obligation, "confirm_transmutability_candidate"); let predicate = obligation.predicate; let type_at = |i| predicate.map_bound(|p| p.trait_ref.substs.type_at(i)); let bool_at = |i| { predicate .skip_binder() .trait_ref .substs .const_at(i) .try_eval_bool(self.tcx(), obligation.param_env) .unwrap_or(true) }; let src_and_dst = predicate.map_bound(|p| rustc_transmute::Types { src: p.trait_ref.substs.type_at(1), dst: p.trait_ref.substs.type_at(0), }); let scope = type_at(2).skip_binder(); let assume = rustc_transmute::Assume { alignment: bool_at(3), lifetimes: bool_at(4), validity: bool_at(5), visibility: bool_at(6), }; let cause = obligation.cause.clone(); let mut transmute_env = rustc_transmute::TransmuteTypeEnv::new(self.infcx); let maybe_transmutable = transmute_env.is_transmutable(cause, src_and_dst, scope, assume); use rustc_transmute::Answer; match maybe_transmutable { Answer::Yes => Ok(ImplSourceBuiltinData { nested: vec![] }), _ => Err(Unimplemented), } } /// This handles the case where an `auto trait Foo` impl is being used. /// The idea is that the impl applies to `X : Foo` if the following conditions are met: /// /// 1. For each constituent type `Y` in `X`, `Y : Foo` holds /// 2. For each where-clause `C` declared on `Foo`, `[Self => X] C` holds. fn confirm_auto_impl_candidate( &mut self, obligation: &TraitObligation<'tcx>, trait_def_id: DefId, ) -> ImplSourceAutoImplData> { debug!(?obligation, ?trait_def_id, "confirm_auto_impl_candidate"); let self_ty = self.infcx.shallow_resolve(obligation.predicate.self_ty()); let types = self.constituent_types_for_ty(self_ty); self.vtable_auto_impl(obligation, trait_def_id, types) } /// See `confirm_auto_impl_candidate`. fn vtable_auto_impl( &mut self, obligation: &TraitObligation<'tcx>, trait_def_id: DefId, nested: ty::Binder<'tcx, Vec>>, ) -> ImplSourceAutoImplData> { debug!(?nested, "vtable_auto_impl"); ensure_sufficient_stack(|| { let cause = obligation.derived_cause(BuiltinDerivedObligation); let poly_trait_ref = obligation.predicate.to_poly_trait_ref(); let trait_ref = self.infcx.replace_bound_vars_with_placeholders(poly_trait_ref); let trait_obligations: Vec> = self.impl_or_trait_obligations( &cause, obligation.recursion_depth + 1, obligation.param_env, trait_def_id, &trait_ref.substs, obligation.predicate, ); let mut obligations = self.collect_predicates_for_types( obligation.param_env, cause, obligation.recursion_depth + 1, trait_def_id, nested, ); // Adds the predicates from the trait. Note that this contains a `Self: Trait` // predicate as usual. It won't have any effect since auto traits are coinductive. obligations.extend(trait_obligations); debug!(?obligations, "vtable_auto_impl"); ImplSourceAutoImplData { trait_def_id, nested: obligations } }) } fn confirm_impl_candidate( &mut self, obligation: &TraitObligation<'tcx>, impl_def_id: DefId, ) -> ImplSourceUserDefinedData<'tcx, PredicateObligation<'tcx>> { debug!(?obligation, ?impl_def_id, "confirm_impl_candidate"); // First, create the substitutions by matching the impl again, // this time not in a probe. let substs = self.rematch_impl(impl_def_id, obligation); debug!(?substs, "impl substs"); ensure_sufficient_stack(|| { self.vtable_impl( impl_def_id, substs, &obligation.cause, obligation.recursion_depth + 1, obligation.param_env, obligation.predicate, ) }) } fn vtable_impl( &mut self, impl_def_id: DefId, substs: Normalized<'tcx, SubstsRef<'tcx>>, cause: &ObligationCause<'tcx>, recursion_depth: usize, param_env: ty::ParamEnv<'tcx>, parent_trait_pred: ty::Binder<'tcx, ty::TraitPredicate<'tcx>>, ) -> ImplSourceUserDefinedData<'tcx, PredicateObligation<'tcx>> { debug!(?impl_def_id, ?substs, ?recursion_depth, "vtable_impl"); let mut impl_obligations = self.impl_or_trait_obligations( cause, recursion_depth, param_env, impl_def_id, &substs.value, parent_trait_pred, ); debug!(?impl_obligations, "vtable_impl"); // Because of RFC447, the impl-trait-ref and obligations // are sufficient to determine the impl substs, without // relying on projections in the impl-trait-ref. // // e.g., `impl> Foo<::T> for V` impl_obligations.extend(substs.obligations); ImplSourceUserDefinedData { impl_def_id, substs: substs.value, nested: impl_obligations } } fn confirm_object_candidate( &mut self, obligation: &TraitObligation<'tcx>, index: usize, ) -> Result>, SelectionError<'tcx>> { let tcx = self.tcx(); debug!(?obligation, ?index, "confirm_object_candidate"); let trait_predicate = self.infcx.replace_bound_vars_with_placeholders(obligation.predicate); let self_ty = self.infcx.shallow_resolve(trait_predicate.self_ty()); let obligation_trait_ref = ty::Binder::dummy(trait_predicate.trait_ref); let ty::Dynamic(data, ..) = *self_ty.kind() else { span_bug!(obligation.cause.span, "object candidate with non-object"); }; let object_trait_ref = data.principal().unwrap_or_else(|| { span_bug!(obligation.cause.span, "object candidate with no principal") }); let object_trait_ref = self.infcx.replace_bound_vars_with_fresh_vars( obligation.cause.span, HigherRankedType, object_trait_ref, ); let object_trait_ref = object_trait_ref.with_self_ty(self.tcx(), self_ty); let mut nested = vec![]; let mut supertraits = util::supertraits(tcx, ty::Binder::dummy(object_trait_ref)); let unnormalized_upcast_trait_ref = supertraits.nth(index).expect("supertraits iterator no longer has as many elements"); let upcast_trait_ref = normalize_with_depth_to( self, obligation.param_env, obligation.cause.clone(), obligation.recursion_depth + 1, unnormalized_upcast_trait_ref, &mut nested, ); nested.extend(self.infcx.commit_if_ok(|_| { self.infcx .at(&obligation.cause, obligation.param_env) .sup(obligation_trait_ref, upcast_trait_ref) .map(|InferOk { obligations, .. }| obligations) .map_err(|_| Unimplemented) })?); // Check supertraits hold. This is so that their associated type bounds // will be checked in the code below. for super_trait in tcx .super_predicates_of(trait_predicate.def_id()) .instantiate(tcx, trait_predicate.trait_ref.substs) .predicates .into_iter() { let normalized_super_trait = normalize_with_depth_to( self, obligation.param_env, obligation.cause.clone(), obligation.recursion_depth + 1, super_trait, &mut nested, ); nested.push(Obligation::new( obligation.cause.clone(), obligation.param_env, normalized_super_trait, )); } let assoc_types: Vec<_> = tcx .associated_items(trait_predicate.def_id()) .in_definition_order() .filter_map( |item| if item.kind == ty::AssocKind::Type { Some(item.def_id) } else { None }, ) .collect(); for assoc_type in assoc_types { let defs: &ty::Generics = tcx.generics_of(assoc_type); if !defs.params.is_empty() && !tcx.features().generic_associated_types_extended { tcx.sess.delay_span_bug( obligation.cause.span, "GATs in trait object shouldn't have been considered", ); return Err(SelectionError::Unimplemented); } // This maybe belongs in wf, but that can't (doesn't) handle // higher-ranked things. // Prevent, e.g., `dyn Iterator`. for bound in self.tcx().bound_item_bounds(assoc_type).transpose_iter() { let subst_bound = if defs.count() == 0 { bound.subst(tcx, trait_predicate.trait_ref.substs) } else { let mut substs = smallvec::SmallVec::with_capacity(defs.count()); substs.extend(trait_predicate.trait_ref.substs.iter()); let mut bound_vars: smallvec::SmallVec<[ty::BoundVariableKind; 8]> = smallvec::SmallVec::with_capacity( bound.0.kind().bound_vars().len() + defs.count(), ); bound_vars.extend(bound.0.kind().bound_vars().into_iter()); InternalSubsts::fill_single(&mut substs, defs, &mut |param, _| match param .kind { GenericParamDefKind::Type { .. } => { let kind = ty::BoundTyKind::Param(param.name); let bound_var = ty::BoundVariableKind::Ty(kind); bound_vars.push(bound_var); tcx.mk_ty(ty::Bound( ty::INNERMOST, ty::BoundTy { var: ty::BoundVar::from_usize(bound_vars.len() - 1), kind, }, )) .into() } GenericParamDefKind::Lifetime => { let kind = ty::BoundRegionKind::BrNamed(param.def_id, param.name); let bound_var = ty::BoundVariableKind::Region(kind); bound_vars.push(bound_var); tcx.mk_region(ty::ReLateBound( ty::INNERMOST, ty::BoundRegion { var: ty::BoundVar::from_usize(bound_vars.len() - 1), kind, }, )) .into() } GenericParamDefKind::Const { .. } => { let bound_var = ty::BoundVariableKind::Const; bound_vars.push(bound_var); tcx.mk_const(ty::ConstS { ty: tcx.type_of(param.def_id), kind: ty::ConstKind::Bound( ty::INNERMOST, ty::BoundVar::from_usize(bound_vars.len() - 1), ), }) .into() } }); let bound_vars = tcx.mk_bound_variable_kinds(bound_vars.into_iter()); let assoc_ty_substs = tcx.intern_substs(&substs); let bound_vars = tcx.mk_bound_variable_kinds(bound_vars.into_iter()); let bound = bound.map_bound(|b| b.kind().skip_binder()).subst(tcx, assoc_ty_substs); tcx.mk_predicate(ty::Binder::bind_with_vars(bound, bound_vars)) }; let normalized_bound = normalize_with_depth_to( self, obligation.param_env, obligation.cause.clone(), obligation.recursion_depth + 1, subst_bound, &mut nested, ); nested.push(Obligation::new( obligation.cause.clone(), obligation.param_env, normalized_bound, )); } } debug!(?nested, "object nested obligations"); let vtable_base = super::super::vtable_trait_first_method_offset( tcx, (unnormalized_upcast_trait_ref, ty::Binder::dummy(object_trait_ref)), ); Ok(ImplSourceObjectData { upcast_trait_ref, vtable_base, nested }) } fn confirm_fn_pointer_candidate( &mut self, obligation: &TraitObligation<'tcx>, ) -> Result>, SelectionError<'tcx>> { debug!(?obligation, "confirm_fn_pointer_candidate"); // Okay to skip binder; it is reintroduced below. let self_ty = self.infcx.shallow_resolve(obligation.self_ty().skip_binder()); let sig = self_ty.fn_sig(self.tcx()); let trait_ref = closure_trait_ref_and_return_type( self.tcx(), obligation.predicate.def_id(), self_ty, sig, util::TupleArgumentsFlag::Yes, ) .map_bound(|(trait_ref, _)| trait_ref); let nested = self.confirm_poly_trait_refs(obligation, trait_ref)?; Ok(ImplSourceFnPointerData { fn_ty: self_ty, nested }) } fn confirm_trait_alias_candidate( &mut self, obligation: &TraitObligation<'tcx>, alias_def_id: DefId, ) -> ImplSourceTraitAliasData<'tcx, PredicateObligation<'tcx>> { debug!(?obligation, ?alias_def_id, "confirm_trait_alias_candidate"); let predicate = self.infcx().replace_bound_vars_with_placeholders(obligation.predicate); let trait_ref = predicate.trait_ref; let trait_def_id = trait_ref.def_id; let substs = trait_ref.substs; let trait_obligations = self.impl_or_trait_obligations( &obligation.cause, obligation.recursion_depth, obligation.param_env, trait_def_id, &substs, obligation.predicate, ); debug!(?trait_def_id, ?trait_obligations, "trait alias obligations"); ImplSourceTraitAliasData { alias_def_id, substs, nested: trait_obligations } } fn confirm_generator_candidate( &mut self, obligation: &TraitObligation<'tcx>, ) -> Result>, SelectionError<'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 = self.infcx.shallow_resolve(obligation.self_ty().skip_binder()); let ty::Generator(generator_def_id, substs, _) = *self_ty.kind() else { bug!("closure candidate for non-closure {:?}", obligation); }; debug!(?obligation, ?generator_def_id, ?substs, "confirm_generator_candidate"); let trait_ref = self.generator_trait_ref_unnormalized(obligation, substs); let nested = self.confirm_poly_trait_refs(obligation, trait_ref)?; debug!(?trait_ref, ?nested, "generator candidate obligations"); Ok(ImplSourceGeneratorData { generator_def_id, substs, nested }) } #[instrument(skip(self), level = "debug")] fn confirm_closure_candidate( &mut self, obligation: &TraitObligation<'tcx>, ) -> Result>, SelectionError<'tcx>> { let kind = self .tcx() .fn_trait_kind_from_lang_item(obligation.predicate.def_id()) .unwrap_or_else(|| bug!("closure candidate for non-fn trait {:?}", obligation)); // Okay to skip binder because the substs on closure types never // touch bound regions, they just capture the in-scope // type/region parameters. let self_ty = self.infcx.shallow_resolve(obligation.self_ty().skip_binder()); let ty::Closure(closure_def_id, substs) = *self_ty.kind() else { bug!("closure candidate for non-closure {:?}", obligation); }; let trait_ref = self.closure_trait_ref_unnormalized(obligation, substs); let mut nested = self.confirm_poly_trait_refs(obligation, trait_ref)?; debug!(?closure_def_id, ?trait_ref, ?nested, "confirm closure candidate obligations"); // FIXME: Chalk if !self.tcx().sess.opts.unstable_opts.chalk { nested.push(Obligation::new( obligation.cause.clone(), obligation.param_env, ty::Binder::dummy(ty::PredicateKind::ClosureKind(closure_def_id, substs, kind)) .to_predicate(self.tcx()), )); } Ok(ImplSourceClosureData { closure_def_id, substs, nested }) } /// In the case of closure types and fn pointers, /// we currently treat the input type parameters on the trait as /// outputs. This means that when we have a match we have only /// considered the self type, so we have to go back and make sure /// to relate the argument types too. This is kind of wrong, but /// since we control the full set of impls, also not that wrong, /// and it DOES yield better error messages (since we don't report /// errors as if there is no applicable impl, but rather report /// errors are about mismatched argument types. /// /// Here is an example. Imagine we have a closure expression /// and we desugared it so that the type of the expression is /// `Closure`, and `Closure` expects `i32` as argument. Then it /// is "as if" the compiler generated this impl: /// ```ignore (illustrative) /// impl Fn(i32) for Closure { ... } /// ``` /// Now imagine our obligation is `Closure: Fn(usize)`. So far /// we have matched the self type `Closure`. At this point we'll /// compare the `i32` to `usize` and generate an error. /// /// Note that this checking occurs *after* the impl has selected, /// because these output type parameters should not affect the /// selection of the impl. Therefore, if there is a mismatch, we /// report an error to the user. #[instrument(skip(self), level = "trace")] fn confirm_poly_trait_refs( &mut self, obligation: &TraitObligation<'tcx>, expected_trait_ref: ty::PolyTraitRef<'tcx>, ) -> Result>, SelectionError<'tcx>> { let obligation_trait_ref = obligation.predicate.to_poly_trait_ref(); // Normalize the obligation and expected trait refs together, because why not let Normalized { obligations: nested, value: (obligation_trait_ref, expected_trait_ref) } = ensure_sufficient_stack(|| { normalize_with_depth( self, obligation.param_env, obligation.cause.clone(), obligation.recursion_depth + 1, (obligation_trait_ref, expected_trait_ref), ) }); self.infcx .at(&obligation.cause, obligation.param_env) .sup(obligation_trait_ref, expected_trait_ref) .map(|InferOk { mut obligations, .. }| { obligations.extend(nested); obligations }) .map_err(|e| OutputTypeParameterMismatch(expected_trait_ref, obligation_trait_ref, e)) } fn confirm_trait_upcasting_unsize_candidate( &mut self, obligation: &TraitObligation<'tcx>, idx: usize, ) -> Result>, SelectionError<'tcx>> { let tcx = self.tcx(); // `assemble_candidates_for_unsizing` should ensure there are no late-bound // regions here. See the comment there for more details. let source = self.infcx.shallow_resolve(obligation.self_ty().no_bound_vars().unwrap()); let target = obligation.predicate.skip_binder().trait_ref.substs.type_at(1); let target = self.infcx.shallow_resolve(target); debug!(?source, ?target, "confirm_trait_upcasting_unsize_candidate"); let mut nested = vec![]; let source_trait_ref; let upcast_trait_ref; match (source.kind(), target.kind()) { // TraitA+Kx+'a -> TraitB+Ky+'b (trait upcasting coercion). (&ty::Dynamic(ref data_a, r_a), &ty::Dynamic(ref data_b, r_b)) => { // See `assemble_candidates_for_unsizing` for more info. // We already checked the compatibility of auto traits within `assemble_candidates_for_unsizing`. let principal_a = data_a.principal().unwrap(); source_trait_ref = principal_a.with_self_ty(tcx, source); upcast_trait_ref = util::supertraits(tcx, source_trait_ref).nth(idx).unwrap(); assert_eq!(data_b.principal_def_id(), Some(upcast_trait_ref.def_id())); let existential_predicate = upcast_trait_ref.map_bound(|trait_ref| { ty::ExistentialPredicate::Trait(ty::ExistentialTraitRef::erase_self_ty( tcx, trait_ref, )) }); let iter = Some(existential_predicate) .into_iter() .chain( data_a .projection_bounds() .map(|b| b.map_bound(ty::ExistentialPredicate::Projection)), ) .chain( data_b .auto_traits() .map(ty::ExistentialPredicate::AutoTrait) .map(ty::Binder::dummy), ); let existential_predicates = tcx.mk_poly_existential_predicates(iter); let source_trait = tcx.mk_dynamic(existential_predicates, r_b); // Require that the traits involved in this upcast are **equal**; // only the **lifetime bound** is changed. let InferOk { obligations, .. } = self .infcx .at(&obligation.cause, obligation.param_env) .sup(target, source_trait) .map_err(|_| Unimplemented)?; nested.extend(obligations); // Register one obligation for 'a: 'b. let cause = ObligationCause::new( obligation.cause.span, obligation.cause.body_id, ObjectCastObligation(source, target), ); let outlives = ty::OutlivesPredicate(r_a, r_b); nested.push(Obligation::with_depth( cause, obligation.recursion_depth + 1, obligation.param_env, obligation.predicate.rebind(outlives).to_predicate(tcx), )); } _ => bug!(), }; let vtable_segment_callback = { let mut vptr_offset = 0; move |segment| { match segment { VtblSegment::MetadataDSA => { vptr_offset += TyCtxt::COMMON_VTABLE_ENTRIES.len(); } VtblSegment::TraitOwnEntries { trait_ref, emit_vptr } => { vptr_offset += util::count_own_vtable_entries(tcx, trait_ref); if trait_ref == upcast_trait_ref { if emit_vptr { return ControlFlow::Break(Some(vptr_offset)); } else { return ControlFlow::Break(None); } } if emit_vptr { vptr_offset += 1; } } } ControlFlow::Continue(()) } }; let vtable_vptr_slot = super::super::prepare_vtable_segments(tcx, source_trait_ref, vtable_segment_callback) .unwrap(); Ok(ImplSourceTraitUpcastingData { upcast_trait_ref, vtable_vptr_slot, nested }) } fn confirm_builtin_unsize_candidate( &mut self, obligation: &TraitObligation<'tcx>, ) -> Result>, SelectionError<'tcx>> { let tcx = self.tcx(); // `assemble_candidates_for_unsizing` should ensure there are no late-bound // regions here. See the comment there for more details. let source = self.infcx.shallow_resolve(obligation.self_ty().no_bound_vars().unwrap()); let target = obligation.predicate.skip_binder().trait_ref.substs.type_at(1); let target = self.infcx.shallow_resolve(target); debug!(?source, ?target, "confirm_builtin_unsize_candidate"); let mut nested = vec![]; match (source.kind(), target.kind()) { // Trait+Kx+'a -> Trait+Ky+'b (auto traits and lifetime subtyping). (&ty::Dynamic(ref data_a, r_a), &ty::Dynamic(ref data_b, r_b)) => { // See `assemble_candidates_for_unsizing` for more info. // We already checked the compatibility of auto traits within `assemble_candidates_for_unsizing`. let iter = data_a .principal() .map(|b| b.map_bound(ty::ExistentialPredicate::Trait)) .into_iter() .chain( data_a .projection_bounds() .map(|b| b.map_bound(ty::ExistentialPredicate::Projection)), ) .chain( data_b .auto_traits() .map(ty::ExistentialPredicate::AutoTrait) .map(ty::Binder::dummy), ); let existential_predicates = tcx.mk_poly_existential_predicates(iter); let source_trait = tcx.mk_dynamic(existential_predicates, r_b); // Require that the traits involved in this upcast are **equal**; // only the **lifetime bound** is changed. let InferOk { obligations, .. } = self .infcx .at(&obligation.cause, obligation.param_env) .sup(target, source_trait) .map_err(|_| Unimplemented)?; nested.extend(obligations); // Register one obligation for 'a: 'b. let cause = ObligationCause::new( obligation.cause.span, obligation.cause.body_id, ObjectCastObligation(source, target), ); let outlives = ty::OutlivesPredicate(r_a, r_b); nested.push(Obligation::with_depth( cause, obligation.recursion_depth + 1, obligation.param_env, obligation.predicate.rebind(outlives).to_predicate(tcx), )); } // `T` -> `Trait` (_, &ty::Dynamic(ref data, r)) => { let mut object_dids = data.auto_traits().chain(data.principal_def_id()); if let Some(did) = object_dids.find(|did| !tcx.is_object_safe(*did)) { return Err(TraitNotObjectSafe(did)); } let cause = ObligationCause::new( obligation.cause.span, obligation.cause.body_id, ObjectCastObligation(source, target), ); let predicate_to_obligation = |predicate| { Obligation::with_depth( cause.clone(), obligation.recursion_depth + 1, obligation.param_env, predicate, ) }; // Create obligations: // - Casting `T` to `Trait` // - For all the various builtin bounds attached to the object cast. (In other // words, if the object type is `Foo + Send`, this would create an obligation for // the `Send` check.) // - Projection predicates nested.extend( data.iter().map(|predicate| { predicate_to_obligation(predicate.with_self_ty(tcx, source)) }), ); // We can only make objects from sized types. let tr = ty::Binder::dummy(ty::TraitRef::new( tcx.require_lang_item(LangItem::Sized, None), tcx.mk_substs_trait(source, &[]), )); nested.push(predicate_to_obligation(tr.without_const().to_predicate(tcx))); // If the type is `Foo + 'a`, ensure that the type // being cast to `Foo + 'a` outlives `'a`: let outlives = ty::OutlivesPredicate(source, r); nested.push(predicate_to_obligation(ty::Binder::dummy(outlives).to_predicate(tcx))); } // `[T; n]` -> `[T]` (&ty::Array(a, _), &ty::Slice(b)) => { let InferOk { obligations, .. } = self .infcx .at(&obligation.cause, obligation.param_env) .eq(b, a) .map_err(|_| Unimplemented)?; nested.extend(obligations); } // `Struct` -> `Struct` (&ty::Adt(def, substs_a), &ty::Adt(_, substs_b)) => { let maybe_unsizing_param_idx = |arg: GenericArg<'tcx>| match arg.unpack() { GenericArgKind::Type(ty) => match ty.kind() { ty::Param(p) => Some(p.index), _ => None, }, // Lifetimes aren't allowed to change during unsizing. GenericArgKind::Lifetime(_) => None, GenericArgKind::Const(ct) => match ct.kind() { ty::ConstKind::Param(p) => Some(p.index), _ => None, }, }; // FIXME(eddyb) cache this (including computing `unsizing_params`) // by putting it in a query; it would only need the `DefId` as it // looks at declared field types, not anything substituted. // The last field of the structure has to exist and contain type/const parameters. let (tail_field, prefix_fields) = def.non_enum_variant().fields.split_last().ok_or(Unimplemented)?; let tail_field_ty = tcx.bound_type_of(tail_field.did); let mut unsizing_params = GrowableBitSet::new_empty(); for arg in tail_field_ty.0.walk() { if let Some(i) = maybe_unsizing_param_idx(arg) { unsizing_params.insert(i); } } // Ensure none of the other fields mention the parameters used // in unsizing. for field in prefix_fields { for arg in tcx.type_of(field.did).walk() { if let Some(i) = maybe_unsizing_param_idx(arg) { unsizing_params.remove(i); } } } if unsizing_params.is_empty() { return Err(Unimplemented); } // Extract `TailField` and `TailField` from `Struct` and `Struct`. let source_tail = tail_field_ty.subst(tcx, substs_a); let target_tail = tail_field_ty.subst(tcx, substs_b); // Check that the source struct with the target's // unsizing parameters is equal to the target. let substs = tcx.mk_substs(substs_a.iter().enumerate().map(|(i, k)| { if unsizing_params.contains(i as u32) { substs_b[i] } else { k } })); let new_struct = tcx.mk_adt(def, substs); let InferOk { obligations, .. } = self .infcx .at(&obligation.cause, obligation.param_env) .eq(target, new_struct) .map_err(|_| Unimplemented)?; nested.extend(obligations); // Construct the nested `TailField: Unsize>` predicate. nested.push(predicate_for_trait_def( tcx, obligation.param_env, obligation.cause.clone(), obligation.predicate.def_id(), obligation.recursion_depth + 1, source_tail, &[target_tail.into()], )); } // `(.., T)` -> `(.., U)` (&ty::Tuple(tys_a), &ty::Tuple(tys_b)) => { assert_eq!(tys_a.len(), tys_b.len()); // The last field of the tuple has to exist. let (&a_last, a_mid) = tys_a.split_last().ok_or(Unimplemented)?; let &b_last = tys_b.last().unwrap(); // Check that the source tuple with the target's // last element is equal to the target. let new_tuple = tcx.mk_tup(a_mid.iter().copied().chain(iter::once(b_last))); let InferOk { obligations, .. } = self .infcx .at(&obligation.cause, obligation.param_env) .eq(target, new_tuple) .map_err(|_| Unimplemented)?; nested.extend(obligations); // Construct the nested `T: Unsize` predicate. nested.push(ensure_sufficient_stack(|| { predicate_for_trait_def( tcx, obligation.param_env, obligation.cause.clone(), obligation.predicate.def_id(), obligation.recursion_depth + 1, a_last, &[b_last.into()], ) })); } _ => bug!(), }; Ok(ImplSourceBuiltinData { nested }) } fn confirm_const_destruct_candidate( &mut self, obligation: &TraitObligation<'tcx>, impl_def_id: Option, ) -> Result>, SelectionError<'tcx>> { // `~const Destruct` in a non-const environment is always trivially true, since our type is `Drop` if !obligation.is_const() { return Ok(ImplSourceConstDestructData { nested: vec![] }); } let drop_trait = self.tcx().require_lang_item(LangItem::Drop, None); let tcx = self.tcx(); let self_ty = self.infcx.shallow_resolve(obligation.self_ty()); let mut nested = vec![]; let cause = obligation.derived_cause(BuiltinDerivedObligation); // If we have a custom `impl const Drop`, then // first check it like a regular impl candidate. // This is copied from confirm_impl_candidate but remaps the predicate to `~const Drop` beforehand. if let Some(impl_def_id) = impl_def_id { let mut new_obligation = obligation.clone(); new_obligation.predicate = new_obligation.predicate.map_bound(|mut trait_pred| { trait_pred.trait_ref.def_id = drop_trait; trait_pred }); let substs = self.rematch_impl(impl_def_id, &new_obligation); debug!(?substs, "impl substs"); let cause = obligation.derived_cause(|derived| { ImplDerivedObligation(Box::new(ImplDerivedObligationCause { derived, impl_def_id, span: obligation.cause.span, })) }); let obligations = ensure_sufficient_stack(|| { self.vtable_impl( impl_def_id, substs, &cause, new_obligation.recursion_depth + 1, new_obligation.param_env, obligation.predicate, ) }); nested.extend(obligations.nested); } // We want to confirm the ADT's fields if we have an ADT let mut stack = match *self_ty.skip_binder().kind() { ty::Adt(def, substs) => def.all_fields().map(|f| f.ty(tcx, substs)).collect(), _ => vec![self_ty.skip_binder()], }; while let Some(nested_ty) = stack.pop() { match *nested_ty.kind() { // We know these types are trivially drop 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(_) => {} // These types are built-in, so we can fast-track by registering // nested predicates for their constituent type(s) ty::Array(ty, _) | ty::Slice(ty) => { stack.push(ty); } ty::Tuple(tys) => { stack.extend(tys.iter()); } ty::Closure(_, substs) => { stack.push(substs.as_closure().tupled_upvars_ty()); } ty::Generator(_, substs, _) => { let generator = substs.as_generator(); stack.extend([generator.tupled_upvars_ty(), generator.witness()]); } ty::GeneratorWitness(tys) => { stack.extend(tcx.erase_late_bound_regions(tys).to_vec()); } // If we have a projection type, make sure to normalize it so we replace it // with a fresh infer variable ty::Projection(..) => { let predicate = normalize_with_depth_to( self, obligation.param_env, cause.clone(), obligation.recursion_depth + 1, self_ty .rebind(ty::TraitPredicate { trait_ref: ty::TraitRef { def_id: self.tcx().require_lang_item(LangItem::Destruct, None), substs: self.tcx().mk_substs_trait(nested_ty, &[]), }, constness: ty::BoundConstness::ConstIfConst, polarity: ty::ImplPolarity::Positive, }) .to_predicate(tcx), &mut nested, ); nested.push(Obligation::with_depth( cause.clone(), obligation.recursion_depth + 1, obligation.param_env, predicate, )); } // If we have any other type (e.g. an ADT), just register a nested obligation // since it's either not `const Drop` (and we raise an error during selection), // or it's an ADT (and we need to check for a custom impl during selection) _ => { let predicate = self_ty .rebind(ty::TraitPredicate { trait_ref: ty::TraitRef { def_id: self.tcx().require_lang_item(LangItem::Destruct, None), substs: self.tcx().mk_substs_trait(nested_ty, &[]), }, constness: ty::BoundConstness::ConstIfConst, polarity: ty::ImplPolarity::Positive, }) .to_predicate(tcx); nested.push(Obligation::with_depth( cause.clone(), obligation.recursion_depth + 1, obligation.param_env, predicate, )); } } } Ok(ImplSourceConstDestructData { nested }) } }