//! Code for projecting associated types out of trait references. use super::specialization_graph; use super::translate_substs; use super::util; use super::MismatchedProjectionTypes; use super::Obligation; use super::ObligationCause; use super::PredicateObligation; use super::Selection; use super::SelectionContext; use super::SelectionError; use super::{ ImplSourceClosureData, ImplSourceDiscriminantKindData, ImplSourceFnPointerData, ImplSourceGeneratorData, ImplSourcePointeeData, ImplSourceUserDefinedData, }; use super::{Normalized, NormalizedTy, ProjectionCacheEntry, ProjectionCacheKey}; use crate::infer::type_variable::{TypeVariableOrigin, TypeVariableOriginKind}; use crate::infer::{InferCtxt, InferOk, LateBoundRegionConversionTime}; use crate::traits::error_reporting::TypeErrCtxtExt as _; use crate::traits::query::evaluate_obligation::InferCtxtExt as _; use crate::traits::select::ProjectionMatchesProjection; use rustc_data_structures::sso::SsoHashSet; use rustc_data_structures::stack::ensure_sufficient_stack; use rustc_errors::ErrorGuaranteed; use rustc_hir::def::DefKind; use rustc_hir::def_id::DefId; use rustc_hir::lang_items::LangItem; use rustc_infer::infer::resolve::OpportunisticRegionResolver; use rustc_middle::traits::select::OverflowError; use rustc_middle::ty::fold::{TypeFoldable, TypeFolder, TypeSuperFoldable}; use rustc_middle::ty::visit::{MaxUniverse, TypeVisitable}; use rustc_middle::ty::DefIdTree; use rustc_middle::ty::{self, Term, ToPredicate, Ty, TyCtxt}; use rustc_span::symbol::sym; use std::collections::BTreeMap; pub use rustc_middle::traits::Reveal; pub type PolyProjectionObligation<'tcx> = Obligation<'tcx, ty::PolyProjectionPredicate<'tcx>>; pub type ProjectionObligation<'tcx> = Obligation<'tcx, ty::ProjectionPredicate<'tcx>>; pub type ProjectionTyObligation<'tcx> = Obligation<'tcx, ty::ProjectionTy<'tcx>>; pub(super) struct InProgress; /// When attempting to resolve `::Name` ... #[derive(Debug)] pub enum ProjectionError<'tcx> { /// ...we found multiple sources of information and couldn't resolve the ambiguity. TooManyCandidates, /// ...an error occurred matching `T : TraitRef` TraitSelectionError(SelectionError<'tcx>), } #[derive(PartialEq, Eq, Debug)] enum ProjectionCandidate<'tcx> { /// From a where-clause in the env or object type ParamEnv(ty::PolyProjectionPredicate<'tcx>), /// From the definition of `Trait` when you have something like /// `<::B as Trait2>::C`. TraitDef(ty::PolyProjectionPredicate<'tcx>), /// Bounds specified on an object type Object(ty::PolyProjectionPredicate<'tcx>), /// From an "impl" (or a "pseudo-impl" returned by select) Select(Selection<'tcx>), ImplTraitInTrait(ImplTraitInTraitCandidate<'tcx>), } #[derive(PartialEq, Eq, Debug)] enum ImplTraitInTraitCandidate<'tcx> { // The `impl Trait` from a trait function's default body Trait, // A concrete type provided from a trait's `impl Trait` from an impl Impl(ImplSourceUserDefinedData<'tcx, PredicateObligation<'tcx>>), } enum ProjectionCandidateSet<'tcx> { None, Single(ProjectionCandidate<'tcx>), Ambiguous, Error(SelectionError<'tcx>), } impl<'tcx> ProjectionCandidateSet<'tcx> { fn mark_ambiguous(&mut self) { *self = ProjectionCandidateSet::Ambiguous; } fn mark_error(&mut self, err: SelectionError<'tcx>) { *self = ProjectionCandidateSet::Error(err); } // Returns true if the push was successful, or false if the candidate // was discarded -- this could be because of ambiguity, or because // a higher-priority candidate is already there. fn push_candidate(&mut self, candidate: ProjectionCandidate<'tcx>) -> bool { use self::ProjectionCandidate::*; use self::ProjectionCandidateSet::*; // This wacky variable is just used to try and // make code readable and avoid confusing paths. // It is assigned a "value" of `()` only on those // paths in which we wish to convert `*self` to // ambiguous (and return false, because the candidate // was not used). On other paths, it is not assigned, // and hence if those paths *could* reach the code that // comes after the match, this fn would not compile. let convert_to_ambiguous; match self { None => { *self = Single(candidate); return true; } Single(current) => { // Duplicates can happen inside ParamEnv. In the case, we // perform a lazy deduplication. if current == &candidate { return false; } // Prefer where-clauses. As in select, if there are multiple // candidates, we prefer where-clause candidates over impls. This // may seem a bit surprising, since impls are the source of // "truth" in some sense, but in fact some of the impls that SEEM // applicable are not, because of nested obligations. Where // clauses are the safer choice. See the comment on // `select::SelectionCandidate` and #21974 for more details. match (current, candidate) { (ParamEnv(..), ParamEnv(..)) => convert_to_ambiguous = (), (ParamEnv(..), _) => return false, (_, ParamEnv(..)) => unreachable!(), (_, _) => convert_to_ambiguous = (), } } Ambiguous | Error(..) => { return false; } } // We only ever get here when we moved from a single candidate // to ambiguous. let () = convert_to_ambiguous; *self = Ambiguous; false } } /// States returned from `poly_project_and_unify_type`. Takes the place /// of the old return type, which was: /// ```ignore (not-rust) /// Result< /// Result>>, InProgress>, /// MismatchedProjectionTypes<'tcx>, /// > /// ``` pub(super) enum ProjectAndUnifyResult<'tcx> { /// The projection bound holds subject to the given obligations. If the /// projection cannot be normalized because the required trait bound does /// not hold, this is returned, with `obligations` being a predicate that /// cannot be proven. Holds(Vec>), /// The projection cannot be normalized due to ambiguity. Resolving some /// inference variables in the projection may fix this. FailedNormalization, /// The project cannot be normalized because `poly_project_and_unify_type` /// is called recursively while normalizing the same projection. Recursive, // the projection can be normalized, but is not equal to the expected type. // Returns the type error that arose from the mismatch. MismatchedProjectionTypes(MismatchedProjectionTypes<'tcx>), } /// Evaluates constraints of the form: /// ```ignore (not-rust) /// for<...> ::U == V /// ``` /// If successful, this may result in additional obligations. Also returns /// the projection cache key used to track these additional obligations. #[instrument(level = "debug", skip(selcx))] pub(super) fn poly_project_and_unify_type<'cx, 'tcx>( selcx: &mut SelectionContext<'cx, 'tcx>, obligation: &PolyProjectionObligation<'tcx>, ) -> ProjectAndUnifyResult<'tcx> { let infcx = selcx.infcx(); let r = infcx.commit_if_ok(|_snapshot| { let old_universe = infcx.universe(); let placeholder_predicate = infcx.replace_bound_vars_with_placeholders(obligation.predicate); let new_universe = infcx.universe(); let placeholder_obligation = obligation.with(placeholder_predicate); match project_and_unify_type(selcx, &placeholder_obligation) { ProjectAndUnifyResult::MismatchedProjectionTypes(e) => Err(e), ProjectAndUnifyResult::Holds(obligations) if old_universe != new_universe && selcx.tcx().features().generic_associated_types_extended => { // If the `generic_associated_types_extended` feature is active, then we ignore any // obligations references lifetimes from any universe greater than or equal to the // universe just created. Otherwise, we can end up with something like `for<'a> I: 'a`, // which isn't quite what we want. Ideally, we want either an implied // `for<'a where I: 'a> I: 'a` or we want to "lazily" check these hold when we // substitute concrete regions. There is design work to be done here; until then, // however, this allows experimenting potential GAT features without running into // well-formedness issues. let new_obligations = obligations .into_iter() .filter(|obligation| { let mut visitor = MaxUniverse::new(); obligation.predicate.visit_with(&mut visitor); visitor.max_universe() < new_universe }) .collect(); Ok(ProjectAndUnifyResult::Holds(new_obligations)) } other => Ok(other), } }); match r { Ok(inner) => inner, Err(err) => ProjectAndUnifyResult::MismatchedProjectionTypes(err), } } /// Evaluates constraints of the form: /// ```ignore (not-rust) /// ::U == V /// ``` /// If successful, this may result in additional obligations. /// /// See [poly_project_and_unify_type] for an explanation of the return value. #[instrument(level = "debug", skip(selcx))] fn project_and_unify_type<'cx, 'tcx>( selcx: &mut SelectionContext<'cx, 'tcx>, obligation: &ProjectionObligation<'tcx>, ) -> ProjectAndUnifyResult<'tcx> { let mut obligations = vec![]; let infcx = selcx.infcx(); let normalized = match opt_normalize_projection_type( selcx, obligation.param_env, obligation.predicate.projection_ty, obligation.cause.clone(), obligation.recursion_depth, &mut obligations, ) { Ok(Some(n)) => n, Ok(None) => return ProjectAndUnifyResult::FailedNormalization, Err(InProgress) => return ProjectAndUnifyResult::Recursive, }; debug!(?normalized, ?obligations, "project_and_unify_type result"); let actual = obligation.predicate.term; // For an example where this is necessary see src/test/ui/impl-trait/nested-return-type2.rs // This allows users to omit re-mentioning all bounds on an associated type and just use an // `impl Trait` for the assoc type to add more bounds. let InferOk { value: actual, obligations: new } = selcx.infcx().replace_opaque_types_with_inference_vars( actual, obligation.cause.body_id, obligation.cause.span, obligation.param_env, ); obligations.extend(new); match infcx.at(&obligation.cause, obligation.param_env).eq(normalized, actual) { Ok(InferOk { obligations: inferred_obligations, value: () }) => { obligations.extend(inferred_obligations); ProjectAndUnifyResult::Holds(obligations) } Err(err) => { debug!("equating types encountered error {:?}", err); ProjectAndUnifyResult::MismatchedProjectionTypes(MismatchedProjectionTypes { err }) } } } /// Normalizes any associated type projections in `value`, replacing /// them with a fully resolved type where possible. The return value /// combines the normalized result and any additional obligations that /// were incurred as result. pub fn normalize<'a, 'b, 'tcx, T>( selcx: &'a mut SelectionContext<'b, 'tcx>, param_env: ty::ParamEnv<'tcx>, cause: ObligationCause<'tcx>, value: T, ) -> Normalized<'tcx, T> where T: TypeFoldable<'tcx>, { let mut obligations = Vec::new(); let value = normalize_to(selcx, param_env, cause, value, &mut obligations); Normalized { value, obligations } } pub fn normalize_to<'a, 'b, 'tcx, T>( selcx: &'a mut SelectionContext<'b, 'tcx>, param_env: ty::ParamEnv<'tcx>, cause: ObligationCause<'tcx>, value: T, obligations: &mut Vec>, ) -> T where T: TypeFoldable<'tcx>, { normalize_with_depth_to(selcx, param_env, cause, 0, value, obligations) } /// As `normalize`, but with a custom depth. pub fn normalize_with_depth<'a, 'b, 'tcx, T>( selcx: &'a mut SelectionContext<'b, 'tcx>, param_env: ty::ParamEnv<'tcx>, cause: ObligationCause<'tcx>, depth: usize, value: T, ) -> Normalized<'tcx, T> where T: TypeFoldable<'tcx>, { let mut obligations = Vec::new(); let value = normalize_with_depth_to(selcx, param_env, cause, depth, value, &mut obligations); Normalized { value, obligations } } #[instrument(level = "info", skip(selcx, param_env, cause, obligations))] pub fn normalize_with_depth_to<'a, 'b, 'tcx, T>( selcx: &'a mut SelectionContext<'b, 'tcx>, param_env: ty::ParamEnv<'tcx>, cause: ObligationCause<'tcx>, depth: usize, value: T, obligations: &mut Vec>, ) -> T where T: TypeFoldable<'tcx>, { debug!(obligations.len = obligations.len()); let mut normalizer = AssocTypeNormalizer::new(selcx, param_env, cause, depth, obligations); let result = ensure_sufficient_stack(|| normalizer.fold(value)); debug!(?result, obligations.len = normalizer.obligations.len()); debug!(?normalizer.obligations,); result } #[instrument(level = "info", skip(selcx, param_env, cause, obligations))] pub fn try_normalize_with_depth_to<'a, 'b, 'tcx, T>( selcx: &'a mut SelectionContext<'b, 'tcx>, param_env: ty::ParamEnv<'tcx>, cause: ObligationCause<'tcx>, depth: usize, value: T, obligations: &mut Vec>, ) -> T where T: TypeFoldable<'tcx>, { debug!(obligations.len = obligations.len()); let mut normalizer = AssocTypeNormalizer::new_without_eager_inference_replacement( selcx, param_env, cause, depth, obligations, ); let result = ensure_sufficient_stack(|| normalizer.fold(value)); debug!(?result, obligations.len = normalizer.obligations.len()); debug!(?normalizer.obligations,); result } pub(crate) fn needs_normalization<'tcx, T: TypeVisitable<'tcx>>(value: &T, reveal: Reveal) -> bool { match reveal { Reveal::UserFacing => value .has_type_flags(ty::TypeFlags::HAS_TY_PROJECTION | ty::TypeFlags::HAS_CT_PROJECTION), Reveal::All => value.has_type_flags( ty::TypeFlags::HAS_TY_PROJECTION | ty::TypeFlags::HAS_TY_OPAQUE | ty::TypeFlags::HAS_CT_PROJECTION, ), } } struct AssocTypeNormalizer<'a, 'b, 'tcx> { selcx: &'a mut SelectionContext<'b, 'tcx>, param_env: ty::ParamEnv<'tcx>, cause: ObligationCause<'tcx>, obligations: &'a mut Vec>, depth: usize, universes: Vec>, /// If true, when a projection is unable to be completed, an inference /// variable will be created and an obligation registered to project to that /// inference variable. Also, constants will be eagerly evaluated. eager_inference_replacement: bool, } impl<'a, 'b, 'tcx> AssocTypeNormalizer<'a, 'b, 'tcx> { fn new( selcx: &'a mut SelectionContext<'b, 'tcx>, param_env: ty::ParamEnv<'tcx>, cause: ObligationCause<'tcx>, depth: usize, obligations: &'a mut Vec>, ) -> AssocTypeNormalizer<'a, 'b, 'tcx> { AssocTypeNormalizer { selcx, param_env, cause, obligations, depth, universes: vec![], eager_inference_replacement: true, } } fn new_without_eager_inference_replacement( selcx: &'a mut SelectionContext<'b, 'tcx>, param_env: ty::ParamEnv<'tcx>, cause: ObligationCause<'tcx>, depth: usize, obligations: &'a mut Vec>, ) -> AssocTypeNormalizer<'a, 'b, 'tcx> { AssocTypeNormalizer { selcx, param_env, cause, obligations, depth, universes: vec![], eager_inference_replacement: false, } } fn fold>(&mut self, value: T) -> T { let value = self.selcx.infcx().resolve_vars_if_possible(value); debug!(?value); assert!( !value.has_escaping_bound_vars(), "Normalizing {:?} without wrapping in a `Binder`", value ); if !needs_normalization(&value, self.param_env.reveal()) { value } else { value.fold_with(self) } } } impl<'a, 'b, 'tcx> TypeFolder<'tcx> for AssocTypeNormalizer<'a, 'b, 'tcx> { fn tcx<'c>(&'c self) -> TyCtxt<'tcx> { self.selcx.tcx() } fn fold_binder>( &mut self, t: ty::Binder<'tcx, T>, ) -> ty::Binder<'tcx, T> { self.universes.push(None); let t = t.super_fold_with(self); self.universes.pop(); t } fn fold_ty(&mut self, ty: Ty<'tcx>) -> Ty<'tcx> { if !needs_normalization(&ty, self.param_env.reveal()) { return ty; } // We try to be a little clever here as a performance optimization in // cases where there are nested projections under binders. // For example: // ``` // for<'a> fn(::One<'a, Box::Two<'a>>>>) // ``` // We normalize the substs on the projection before the projecting, but // if we're naive, we'll // replace bound vars on inner, project inner, replace placeholders on inner, // replace bound vars on outer, project outer, replace placeholders on outer // // However, if we're a bit more clever, we can replace the bound vars // on the entire type before normalizing nested projections, meaning we // replace bound vars on outer, project inner, // project outer, replace placeholders on outer // // This is possible because the inner `'a` will already be a placeholder // when we need to normalize the inner projection // // On the other hand, this does add a bit of complexity, since we only // replace bound vars if the current type is a `Projection` and we need // to make sure we don't forget to fold the substs regardless. match *ty.kind() { // This is really important. While we *can* handle this, this has // severe performance implications for large opaque types with // late-bound regions. See `issue-88862` benchmark. ty::Opaque(def_id, substs) if !substs.has_escaping_bound_vars() => { // Only normalize `impl Trait` outside of type inference, usually in codegen. match self.param_env.reveal() { Reveal::UserFacing => ty.super_fold_with(self), Reveal::All => { let recursion_limit = self.tcx().recursion_limit(); if !recursion_limit.value_within_limit(self.depth) { let obligation = Obligation::with_depth( self.cause.clone(), recursion_limit.0, self.param_env, ty, ); self.selcx.infcx().err_ctxt().report_overflow_error(&obligation, true); } let substs = substs.fold_with(self); let generic_ty = self.tcx().bound_type_of(def_id); let concrete_ty = generic_ty.subst(self.tcx(), substs); self.depth += 1; let folded_ty = self.fold_ty(concrete_ty); self.depth -= 1; folded_ty } } } ty::Projection(data) if !data.has_escaping_bound_vars() => { // This branch is *mostly* just an optimization: when we don't // have escaping bound vars, we don't need to replace them with // placeholders (see branch below). *Also*, we know that we can // register an obligation to *later* project, since we know // there won't be bound vars there. let data = data.fold_with(self); let normalized_ty = if self.eager_inference_replacement { normalize_projection_type( self.selcx, self.param_env, data, self.cause.clone(), self.depth, &mut self.obligations, ) } else { opt_normalize_projection_type( self.selcx, self.param_env, data, self.cause.clone(), self.depth, &mut self.obligations, ) .ok() .flatten() .unwrap_or_else(|| ty.super_fold_with(self).into()) }; debug!( ?self.depth, ?ty, ?normalized_ty, obligations.len = ?self.obligations.len(), "AssocTypeNormalizer: normalized type" ); normalized_ty.ty().unwrap() } ty::Projection(data) => { // If there are escaping bound vars, we temporarily replace the // bound vars with placeholders. Note though, that in the case // that we still can't project for whatever reason (e.g. self // type isn't known enough), we *can't* register an obligation // and return an inference variable (since then that obligation // would have bound vars and that's a can of worms). Instead, // we just give up and fall back to pretending like we never tried! // // Note: this isn't necessarily the final approach here; we may // want to figure out how to register obligations with escaping vars // or handle this some other way. let infcx = self.selcx.infcx(); let (data, mapped_regions, mapped_types, mapped_consts) = BoundVarReplacer::replace_bound_vars(infcx, &mut self.universes, data); let data = data.fold_with(self); let normalized_ty = opt_normalize_projection_type( self.selcx, self.param_env, data, self.cause.clone(), self.depth, &mut self.obligations, ) .ok() .flatten() .map(|term| term.ty().unwrap()) .map(|normalized_ty| { PlaceholderReplacer::replace_placeholders( infcx, mapped_regions, mapped_types, mapped_consts, &self.universes, normalized_ty, ) }) .unwrap_or_else(|| ty.super_fold_with(self)); debug!( ?self.depth, ?ty, ?normalized_ty, obligations.len = ?self.obligations.len(), "AssocTypeNormalizer: normalized type" ); normalized_ty } _ => ty.super_fold_with(self), } } #[instrument(skip(self), level = "debug")] fn fold_const(&mut self, constant: ty::Const<'tcx>) -> ty::Const<'tcx> { let tcx = self.selcx.tcx(); if tcx.lazy_normalization() { constant } else { let constant = constant.super_fold_with(self); debug!(?constant, ?self.param_env); with_replaced_escaping_bound_vars( self.selcx.infcx(), &mut self.universes, constant, |constant| constant.eval(tcx, self.param_env), ) } } #[inline] fn fold_predicate(&mut self, p: ty::Predicate<'tcx>) -> ty::Predicate<'tcx> { if p.allow_normalization() && needs_normalization(&p, self.param_env.reveal()) { p.super_fold_with(self) } else { p } } } pub struct BoundVarReplacer<'me, 'tcx> { infcx: &'me InferCtxt<'tcx>, // These three maps track the bound variable that were replaced by placeholders. It might be // nice to remove these since we already have the `kind` in the placeholder; we really just need // the `var` (but we *could* bring that into scope if we were to track them as we pass them). mapped_regions: BTreeMap, mapped_types: BTreeMap, mapped_consts: BTreeMap, ty::BoundVar>, // The current depth relative to *this* folding, *not* the entire normalization. In other words, // the depth of binders we've passed here. current_index: ty::DebruijnIndex, // The `UniverseIndex` of the binding levels above us. These are optional, since we are lazy: // we don't actually create a universe until we see a bound var we have to replace. universe_indices: &'me mut Vec>, } /// Executes `f` on `value` after replacing all escaping bound variables with placeholders /// and then replaces these placeholders with the original bound variables in the result. /// /// In most places, bound variables should be replaced right when entering a binder, making /// this function unnecessary. However, normalization currently does not do that, so we have /// to do this lazily. /// /// You should not add any additional uses of this function, at least not without first /// discussing it with t-types. /// /// FIXME(@lcnr): We may even consider experimenting with eagerly replacing bound vars during /// normalization as well, at which point this function will be unnecessary and can be removed. pub fn with_replaced_escaping_bound_vars<'a, 'tcx, T: TypeFoldable<'tcx>, R: TypeFoldable<'tcx>>( infcx: &'a InferCtxt<'tcx>, universe_indices: &'a mut Vec>, value: T, f: impl FnOnce(T) -> R, ) -> R { if value.has_escaping_bound_vars() { let (value, mapped_regions, mapped_types, mapped_consts) = BoundVarReplacer::replace_bound_vars(infcx, universe_indices, value); let result = f(value); PlaceholderReplacer::replace_placeholders( infcx, mapped_regions, mapped_types, mapped_consts, universe_indices, result, ) } else { f(value) } } impl<'me, 'tcx> BoundVarReplacer<'me, 'tcx> { /// Returns `Some` if we *were* able to replace bound vars. If there are any bound vars that /// use a binding level above `universe_indices.len()`, we fail. pub fn replace_bound_vars>( infcx: &'me InferCtxt<'tcx>, universe_indices: &'me mut Vec>, value: T, ) -> ( T, BTreeMap, BTreeMap, BTreeMap, ty::BoundVar>, ) { let mapped_regions: BTreeMap = BTreeMap::new(); let mapped_types: BTreeMap = BTreeMap::new(); let mapped_consts: BTreeMap, ty::BoundVar> = BTreeMap::new(); let mut replacer = BoundVarReplacer { infcx, mapped_regions, mapped_types, mapped_consts, current_index: ty::INNERMOST, universe_indices, }; let value = value.fold_with(&mut replacer); (value, replacer.mapped_regions, replacer.mapped_types, replacer.mapped_consts) } fn universe_for(&mut self, debruijn: ty::DebruijnIndex) -> ty::UniverseIndex { let infcx = self.infcx; let index = self.universe_indices.len() + self.current_index.as_usize() - debruijn.as_usize() - 1; let universe = self.universe_indices[index].unwrap_or_else(|| { for i in self.universe_indices.iter_mut().take(index + 1) { *i = i.or_else(|| Some(infcx.create_next_universe())) } self.universe_indices[index].unwrap() }); universe } } impl<'tcx> TypeFolder<'tcx> for BoundVarReplacer<'_, 'tcx> { fn tcx<'b>(&'b self) -> TyCtxt<'tcx> { self.infcx.tcx } fn fold_binder>( &mut self, t: ty::Binder<'tcx, T>, ) -> ty::Binder<'tcx, T> { self.current_index.shift_in(1); let t = t.super_fold_with(self); self.current_index.shift_out(1); t } fn fold_region(&mut self, r: ty::Region<'tcx>) -> ty::Region<'tcx> { match *r { ty::ReLateBound(debruijn, _) if debruijn.as_usize() + 1 > self.current_index.as_usize() + self.universe_indices.len() => { bug!("Bound vars outside of `self.universe_indices`"); } ty::ReLateBound(debruijn, br) if debruijn >= self.current_index => { let universe = self.universe_for(debruijn); let p = ty::PlaceholderRegion { universe, name: br.kind }; self.mapped_regions.insert(p, br); self.infcx.tcx.mk_region(ty::RePlaceholder(p)) } _ => r, } } fn fold_ty(&mut self, t: Ty<'tcx>) -> Ty<'tcx> { match *t.kind() { ty::Bound(debruijn, _) if debruijn.as_usize() + 1 > self.current_index.as_usize() + self.universe_indices.len() => { bug!("Bound vars outside of `self.universe_indices`"); } ty::Bound(debruijn, bound_ty) if debruijn >= self.current_index => { let universe = self.universe_for(debruijn); let p = ty::PlaceholderType { universe, name: bound_ty.var }; self.mapped_types.insert(p, bound_ty); self.infcx.tcx.mk_ty(ty::Placeholder(p)) } _ if t.has_vars_bound_at_or_above(self.current_index) => t.super_fold_with(self), _ => t, } } fn fold_const(&mut self, ct: ty::Const<'tcx>) -> ty::Const<'tcx> { match ct.kind() { ty::ConstKind::Bound(debruijn, _) if debruijn.as_usize() + 1 > self.current_index.as_usize() + self.universe_indices.len() => { bug!("Bound vars outside of `self.universe_indices`"); } ty::ConstKind::Bound(debruijn, bound_const) if debruijn >= self.current_index => { let universe = self.universe_for(debruijn); let p = ty::PlaceholderConst { universe, name: bound_const }; self.mapped_consts.insert(p, bound_const); self.infcx .tcx .mk_const(ty::ConstS { kind: ty::ConstKind::Placeholder(p), ty: ct.ty() }) } _ => ct.super_fold_with(self), } } fn fold_predicate(&mut self, p: ty::Predicate<'tcx>) -> ty::Predicate<'tcx> { if p.has_vars_bound_at_or_above(self.current_index) { p.super_fold_with(self) } else { p } } } // The inverse of `BoundVarReplacer`: replaces placeholders with the bound vars from which they came. pub struct PlaceholderReplacer<'me, 'tcx> { infcx: &'me InferCtxt<'tcx>, mapped_regions: BTreeMap, mapped_types: BTreeMap, mapped_consts: BTreeMap, ty::BoundVar>, universe_indices: &'me [Option], current_index: ty::DebruijnIndex, } impl<'me, 'tcx> PlaceholderReplacer<'me, 'tcx> { pub fn replace_placeholders>( infcx: &'me InferCtxt<'tcx>, mapped_regions: BTreeMap, mapped_types: BTreeMap, mapped_consts: BTreeMap, ty::BoundVar>, universe_indices: &'me [Option], value: T, ) -> T { let mut replacer = PlaceholderReplacer { infcx, mapped_regions, mapped_types, mapped_consts, universe_indices, current_index: ty::INNERMOST, }; value.fold_with(&mut replacer) } } impl<'tcx> TypeFolder<'tcx> for PlaceholderReplacer<'_, 'tcx> { fn tcx<'b>(&'b self) -> TyCtxt<'tcx> { self.infcx.tcx } fn fold_binder>( &mut self, t: ty::Binder<'tcx, T>, ) -> ty::Binder<'tcx, T> { if !t.has_placeholders() && !t.has_infer_regions() { return t; } self.current_index.shift_in(1); let t = t.super_fold_with(self); self.current_index.shift_out(1); t } fn fold_region(&mut self, r0: ty::Region<'tcx>) -> ty::Region<'tcx> { let r1 = match *r0 { ty::ReVar(_) => self .infcx .inner .borrow_mut() .unwrap_region_constraints() .opportunistic_resolve_region(self.infcx.tcx, r0), _ => r0, }; let r2 = match *r1 { ty::RePlaceholder(p) => { let replace_var = self.mapped_regions.get(&p); match replace_var { Some(replace_var) => { let index = self .universe_indices .iter() .position(|u| matches!(u, Some(pu) if *pu == p.universe)) .unwrap_or_else(|| bug!("Unexpected placeholder universe.")); let db = ty::DebruijnIndex::from_usize( self.universe_indices.len() - index + self.current_index.as_usize() - 1, ); self.tcx().mk_region(ty::ReLateBound(db, *replace_var)) } None => r1, } } _ => r1, }; debug!(?r0, ?r1, ?r2, "fold_region"); r2 } fn fold_ty(&mut self, ty: Ty<'tcx>) -> Ty<'tcx> { match *ty.kind() { ty::Placeholder(p) => { let replace_var = self.mapped_types.get(&p); match replace_var { Some(replace_var) => { let index = self .universe_indices .iter() .position(|u| matches!(u, Some(pu) if *pu == p.universe)) .unwrap_or_else(|| bug!("Unexpected placeholder universe.")); let db = ty::DebruijnIndex::from_usize( self.universe_indices.len() - index + self.current_index.as_usize() - 1, ); self.tcx().mk_ty(ty::Bound(db, *replace_var)) } None => ty, } } _ if ty.has_placeholders() || ty.has_infer_regions() => ty.super_fold_with(self), _ => ty, } } fn fold_const(&mut self, ct: ty::Const<'tcx>) -> ty::Const<'tcx> { if let ty::ConstKind::Placeholder(p) = ct.kind() { let replace_var = self.mapped_consts.get(&p); match replace_var { Some(replace_var) => { let index = self .universe_indices .iter() .position(|u| matches!(u, Some(pu) if *pu == p.universe)) .unwrap_or_else(|| bug!("Unexpected placeholder universe.")); let db = ty::DebruijnIndex::from_usize( self.universe_indices.len() - index + self.current_index.as_usize() - 1, ); self.tcx().mk_const(ty::ConstS { kind: ty::ConstKind::Bound(db, *replace_var), ty: ct.ty(), }) } None => ct, } } else { ct.super_fold_with(self) } } } /// The guts of `normalize`: normalize a specific projection like `::Item`. The result is always a type (and possibly /// additional obligations). If ambiguity arises, which implies that /// there are unresolved type variables in the projection, we will /// substitute a fresh type variable `$X` and generate a new /// obligation `::Item == $X` for later. pub fn normalize_projection_type<'a, 'b, 'tcx>( selcx: &'a mut SelectionContext<'b, 'tcx>, param_env: ty::ParamEnv<'tcx>, projection_ty: ty::ProjectionTy<'tcx>, cause: ObligationCause<'tcx>, depth: usize, obligations: &mut Vec>, ) -> Term<'tcx> { opt_normalize_projection_type( selcx, param_env, projection_ty, cause.clone(), depth, obligations, ) .ok() .flatten() .unwrap_or_else(move || { // if we bottom out in ambiguity, create a type variable // and a deferred predicate to resolve this when more type // information is available. selcx .infcx() .infer_projection(param_env, projection_ty, cause, depth + 1, obligations) .into() }) } /// The guts of `normalize`: normalize a specific projection like `::Item`. The result is always a type (and possibly /// additional obligations). Returns `None` in the case of ambiguity, /// which indicates that there are unbound type variables. /// /// This function used to return `Option>`, which contains a /// `Ty<'tcx>` and an obligations vector. But that obligation vector was very /// often immediately appended to another obligations vector. So now this /// function takes an obligations vector and appends to it directly, which is /// slightly uglier but avoids the need for an extra short-lived allocation. #[instrument(level = "debug", skip(selcx, param_env, cause, obligations))] fn opt_normalize_projection_type<'a, 'b, 'tcx>( selcx: &'a mut SelectionContext<'b, 'tcx>, param_env: ty::ParamEnv<'tcx>, projection_ty: ty::ProjectionTy<'tcx>, cause: ObligationCause<'tcx>, depth: usize, obligations: &mut Vec>, ) -> Result>, InProgress> { let infcx = selcx.infcx(); // Don't use the projection cache in intercrate mode - // the `infcx` may be re-used between intercrate in non-intercrate // mode, which could lead to using incorrect cache results. let use_cache = !selcx.is_intercrate(); let projection_ty = infcx.resolve_vars_if_possible(projection_ty); let cache_key = ProjectionCacheKey::new(projection_ty); // FIXME(#20304) For now, I am caching here, which is good, but it // means we don't capture the type variables that are created in // the case of ambiguity. Which means we may create a large stream // of such variables. OTOH, if we move the caching up a level, we // would not benefit from caching when proving `T: Trait` // bounds. It might be the case that we want two distinct caches, // or else another kind of cache entry. let cache_result = if use_cache { infcx.inner.borrow_mut().projection_cache().try_start(cache_key) } else { Ok(()) }; match cache_result { Ok(()) => debug!("no cache"), Err(ProjectionCacheEntry::Ambiguous) => { // If we found ambiguity the last time, that means we will continue // to do so until some type in the key changes (and we know it // hasn't, because we just fully resolved it). debug!("found cache entry: ambiguous"); return Ok(None); } Err(ProjectionCacheEntry::InProgress) => { // Under lazy normalization, this can arise when // bootstrapping. That is, imagine an environment with a // where-clause like `A::B == u32`. Now, if we are asked // to normalize `A::B`, we will want to check the // where-clauses in scope. So we will try to unify `A::B` // with `A::B`, which can trigger a recursive // normalization. debug!("found cache entry: in-progress"); // Cache that normalizing this projection resulted in a cycle. This // should ensure that, unless this happens within a snapshot that's // rolled back, fulfillment or evaluation will notice the cycle. if use_cache { infcx.inner.borrow_mut().projection_cache().recur(cache_key); } return Err(InProgress); } Err(ProjectionCacheEntry::Recur) => { debug!("recur cache"); return Err(InProgress); } Err(ProjectionCacheEntry::NormalizedTy { ty, complete: _ }) => { // This is the hottest path in this function. // // If we find the value in the cache, then return it along // with the obligations that went along with it. Note // that, when using a fulfillment context, these // obligations could in principle be ignored: they have // already been registered when the cache entry was // created (and hence the new ones will quickly be // discarded as duplicated). But when doing trait // evaluation this is not the case, and dropping the trait // evaluations can causes ICEs (e.g., #43132). debug!(?ty, "found normalized ty"); obligations.extend(ty.obligations); return Ok(Some(ty.value)); } Err(ProjectionCacheEntry::Error) => { debug!("opt_normalize_projection_type: found error"); let result = normalize_to_error(selcx, param_env, projection_ty, cause, depth); obligations.extend(result.obligations); return Ok(Some(result.value.into())); } } let obligation = Obligation::with_depth(cause.clone(), depth, param_env, projection_ty); match project(selcx, &obligation) { Ok(Projected::Progress(Progress { term: projected_term, obligations: mut projected_obligations, })) => { // if projection succeeded, then what we get out of this // is also non-normalized (consider: it was derived from // an impl, where-clause etc) and hence we must // re-normalize it let projected_term = selcx.infcx().resolve_vars_if_possible(projected_term); let mut result = if projected_term.has_projections() { let mut normalizer = AssocTypeNormalizer::new( selcx, param_env, cause, depth + 1, &mut projected_obligations, ); let normalized_ty = normalizer.fold(projected_term); Normalized { value: normalized_ty, obligations: projected_obligations } } else { Normalized { value: projected_term, obligations: projected_obligations } }; let mut deduped: SsoHashSet<_> = Default::default(); result.obligations.drain_filter(|projected_obligation| { if !deduped.insert(projected_obligation.clone()) { return true; } false }); if use_cache { infcx.inner.borrow_mut().projection_cache().insert_term(cache_key, result.clone()); } obligations.extend(result.obligations); Ok(Some(result.value)) } Ok(Projected::NoProgress(projected_ty)) => { let result = Normalized { value: projected_ty, obligations: vec![] }; if use_cache { infcx.inner.borrow_mut().projection_cache().insert_term(cache_key, result.clone()); } // No need to extend `obligations`. Ok(Some(result.value)) } Err(ProjectionError::TooManyCandidates) => { debug!("opt_normalize_projection_type: too many candidates"); if use_cache { infcx.inner.borrow_mut().projection_cache().ambiguous(cache_key); } Ok(None) } Err(ProjectionError::TraitSelectionError(_)) => { debug!("opt_normalize_projection_type: ERROR"); // if we got an error processing the `T as Trait` part, // just return `ty::err` but add the obligation `T : // Trait`, which when processed will cause the error to be // reported later if use_cache { infcx.inner.borrow_mut().projection_cache().error(cache_key); } let result = normalize_to_error(selcx, param_env, projection_ty, cause, depth); obligations.extend(result.obligations); Ok(Some(result.value.into())) } } } /// If we are projecting `::Item`, but `T: Trait` does not /// hold. In various error cases, we cannot generate a valid /// normalized projection. Therefore, we create an inference variable /// return an associated obligation that, when fulfilled, will lead to /// an error. /// /// Note that we used to return `Error` here, but that was quite /// dubious -- the premise was that an error would *eventually* be /// reported, when the obligation was processed. But in general once /// you see an `Error` you are supposed to be able to assume that an /// error *has been* reported, so that you can take whatever heuristic /// paths you want to take. To make things worse, it was possible for /// cycles to arise, where you basically had a setup like ` /// as Trait>::Foo == $0`. Here, normalizing ` as /// Trait>::Foo> to `[type error]` would lead to an obligation of /// ` as Trait>::Foo`. We are supposed to report /// an error for this obligation, but we legitimately should not, /// because it contains `[type error]`. Yuck! (See issue #29857 for /// one case where this arose.) fn normalize_to_error<'a, 'tcx>( selcx: &mut SelectionContext<'a, 'tcx>, param_env: ty::ParamEnv<'tcx>, projection_ty: ty::ProjectionTy<'tcx>, cause: ObligationCause<'tcx>, depth: usize, ) -> NormalizedTy<'tcx> { let trait_ref = ty::Binder::dummy(projection_ty.trait_ref(selcx.tcx())); let trait_obligation = Obligation { cause, recursion_depth: depth, param_env, predicate: trait_ref.without_const().to_predicate(selcx.tcx()), }; let tcx = selcx.infcx().tcx; let def_id = projection_ty.item_def_id; let new_value = selcx.infcx().next_ty_var(TypeVariableOrigin { kind: TypeVariableOriginKind::NormalizeProjectionType, span: tcx.def_span(def_id), }); Normalized { value: new_value, obligations: vec![trait_obligation] } } enum Projected<'tcx> { Progress(Progress<'tcx>), NoProgress(ty::Term<'tcx>), } struct Progress<'tcx> { term: ty::Term<'tcx>, obligations: Vec>, } impl<'tcx> Progress<'tcx> { fn error(tcx: TyCtxt<'tcx>) -> Self { Progress { term: tcx.ty_error().into(), obligations: vec![] } } fn with_addl_obligations(mut self, mut obligations: Vec>) -> Self { self.obligations.append(&mut obligations); self } } /// Computes the result of a projection type (if we can). /// /// IMPORTANT: /// - `obligation` must be fully normalized #[instrument(level = "info", skip(selcx))] fn project<'cx, 'tcx>( selcx: &mut SelectionContext<'cx, 'tcx>, obligation: &ProjectionTyObligation<'tcx>, ) -> Result, ProjectionError<'tcx>> { if !selcx.tcx().recursion_limit().value_within_limit(obligation.recursion_depth) { // This should really be an immediate error, but some existing code // relies on being able to recover from this. return Err(ProjectionError::TraitSelectionError(SelectionError::Overflow( OverflowError::Canonical, ))); } if obligation.predicate.references_error() { return Ok(Projected::Progress(Progress::error(selcx.tcx()))); } let mut candidates = ProjectionCandidateSet::None; assemble_candidate_for_impl_trait_in_trait(selcx, obligation, &mut candidates); // Make sure that the following procedures are kept in order. ParamEnv // needs to be first because it has highest priority, and Select checks // the return value of push_candidate which assumes it's ran at last. assemble_candidates_from_param_env(selcx, obligation, &mut candidates); assemble_candidates_from_trait_def(selcx, obligation, &mut candidates); assemble_candidates_from_object_ty(selcx, obligation, &mut candidates); if let ProjectionCandidateSet::Single(ProjectionCandidate::Object(_)) = candidates { // Avoid normalization cycle from selection (see // `assemble_candidates_from_object_ty`). // FIXME(lazy_normalization): Lazy normalization should save us from // having to special case this. } else { assemble_candidates_from_impls(selcx, obligation, &mut candidates); }; match candidates { ProjectionCandidateSet::Single(candidate) => { Ok(Projected::Progress(confirm_candidate(selcx, obligation, candidate))) } ProjectionCandidateSet::None => Ok(Projected::NoProgress( // FIXME(associated_const_generics): this may need to change in the future? // need to investigate whether or not this is fine. selcx .tcx() .mk_projection(obligation.predicate.item_def_id, obligation.predicate.substs) .into(), )), // Error occurred while trying to processing impls. ProjectionCandidateSet::Error(e) => Err(ProjectionError::TraitSelectionError(e)), // Inherent ambiguity that prevents us from even enumerating the // candidates. ProjectionCandidateSet::Ambiguous => Err(ProjectionError::TooManyCandidates), } } /// If the predicate's item is an `ImplTraitPlaceholder`, we do a select on the /// corresponding trait ref. If this yields an `impl`, then we're able to project /// to a concrete type, since we have an `impl`'s method to provide the RPITIT. fn assemble_candidate_for_impl_trait_in_trait<'cx, 'tcx>( selcx: &mut SelectionContext<'cx, 'tcx>, obligation: &ProjectionTyObligation<'tcx>, candidate_set: &mut ProjectionCandidateSet<'tcx>, ) { let tcx = selcx.tcx(); if tcx.def_kind(obligation.predicate.item_def_id) == DefKind::ImplTraitPlaceholder { let trait_fn_def_id = tcx.impl_trait_in_trait_parent(obligation.predicate.item_def_id); // If we are trying to project an RPITIT with trait's default `Self` parameter, // then we must be within a default trait body. if obligation.predicate.self_ty() == ty::InternalSubsts::identity_for_item(tcx, obligation.predicate.item_def_id) .type_at(0) && tcx.associated_item(trait_fn_def_id).defaultness(tcx).has_value() { candidate_set.push_candidate(ProjectionCandidate::ImplTraitInTrait( ImplTraitInTraitCandidate::Trait, )); return; } let trait_def_id = tcx.parent(trait_fn_def_id); let trait_substs = obligation.predicate.substs.truncate_to(tcx, tcx.generics_of(trait_def_id)); // FIXME(named-returns): Binders let trait_predicate = ty::Binder::dummy(ty::TraitRef { def_id: trait_def_id, substs: trait_substs }) .to_poly_trait_predicate(); let _ = selcx.infcx().commit_if_ok(|_| match selcx.select(&obligation.with(trait_predicate)) { Ok(Some(super::ImplSource::UserDefined(data))) => { candidate_set.push_candidate(ProjectionCandidate::ImplTraitInTrait( ImplTraitInTraitCandidate::Impl(data), )); Ok(()) } Ok(None) => { candidate_set.mark_ambiguous(); return Err(()); } Ok(Some(_)) => { // Don't know enough about the impl to provide a useful signature return Err(()); } Err(e) => { debug!(error = ?e, "selection error"); candidate_set.mark_error(e); return Err(()); } }); } } /// The first thing we have to do is scan through the parameter /// environment to see whether there are any projection predicates /// there that can answer this question. fn assemble_candidates_from_param_env<'cx, 'tcx>( selcx: &mut SelectionContext<'cx, 'tcx>, obligation: &ProjectionTyObligation<'tcx>, candidate_set: &mut ProjectionCandidateSet<'tcx>, ) { assemble_candidates_from_predicates( selcx, obligation, candidate_set, ProjectionCandidate::ParamEnv, obligation.param_env.caller_bounds().iter(), false, ); } /// In the case of a nested projection like `<::FooT as Bar>::BarT`, we may find /// that the definition of `Foo` has some clues: /// /// ```ignore (illustrative) /// trait Foo { /// type FooT : Bar /// } /// ``` /// /// Here, for example, we could conclude that the result is `i32`. fn assemble_candidates_from_trait_def<'cx, 'tcx>( selcx: &mut SelectionContext<'cx, 'tcx>, obligation: &ProjectionTyObligation<'tcx>, candidate_set: &mut ProjectionCandidateSet<'tcx>, ) { debug!("assemble_candidates_from_trait_def(..)"); let tcx = selcx.tcx(); // Check whether the self-type is itself a projection. // If so, extract what we know from the trait and try to come up with a good answer. let bounds = match *obligation.predicate.self_ty().kind() { ty::Projection(ref data) => tcx.bound_item_bounds(data.item_def_id).subst(tcx, data.substs), ty::Opaque(def_id, substs) => tcx.bound_item_bounds(def_id).subst(tcx, substs), ty::Infer(ty::TyVar(_)) => { // If the self-type is an inference variable, then it MAY wind up // being a projected type, so induce an ambiguity. candidate_set.mark_ambiguous(); return; } _ => return, }; assemble_candidates_from_predicates( selcx, obligation, candidate_set, ProjectionCandidate::TraitDef, bounds.iter(), true, ); } /// In the case of a trait object like /// ` as Iterator>::Item` we can use the existential /// predicate in the trait object. /// /// We don't go through the select candidate for these bounds to avoid cycles: /// In the above case, `dyn Iterator: Iterator` would create a /// nested obligation of ` as Iterator>::Item: Sized`, /// this then has to be normalized without having to prove /// `dyn Iterator: Iterator` again. fn assemble_candidates_from_object_ty<'cx, 'tcx>( selcx: &mut SelectionContext<'cx, 'tcx>, obligation: &ProjectionTyObligation<'tcx>, candidate_set: &mut ProjectionCandidateSet<'tcx>, ) { debug!("assemble_candidates_from_object_ty(..)"); let tcx = selcx.tcx(); let self_ty = obligation.predicate.self_ty(); let object_ty = selcx.infcx().shallow_resolve(self_ty); let data = match object_ty.kind() { ty::Dynamic(data, ..) => data, ty::Infer(ty::TyVar(_)) => { // If the self-type is an inference variable, then it MAY wind up // being an object type, so induce an ambiguity. candidate_set.mark_ambiguous(); return; } _ => return, }; let env_predicates = data .projection_bounds() .filter(|bound| bound.item_def_id() == obligation.predicate.item_def_id) .map(|p| p.with_self_ty(tcx, object_ty).to_predicate(tcx)); assemble_candidates_from_predicates( selcx, obligation, candidate_set, ProjectionCandidate::Object, env_predicates, false, ); } #[instrument( level = "debug", skip(selcx, candidate_set, ctor, env_predicates, potentially_unnormalized_candidates) )] fn assemble_candidates_from_predicates<'cx, 'tcx>( selcx: &mut SelectionContext<'cx, 'tcx>, obligation: &ProjectionTyObligation<'tcx>, candidate_set: &mut ProjectionCandidateSet<'tcx>, ctor: fn(ty::PolyProjectionPredicate<'tcx>) -> ProjectionCandidate<'tcx>, env_predicates: impl Iterator>, potentially_unnormalized_candidates: bool, ) { let infcx = selcx.infcx(); for predicate in env_predicates { let bound_predicate = predicate.kind(); if let ty::PredicateKind::Projection(data) = predicate.kind().skip_binder() { let data = bound_predicate.rebind(data); if data.projection_def_id() != obligation.predicate.item_def_id { continue; } let is_match = infcx.probe(|_| { selcx.match_projection_projections( obligation, data, potentially_unnormalized_candidates, ) }); match is_match { ProjectionMatchesProjection::Yes => { candidate_set.push_candidate(ctor(data)); if potentially_unnormalized_candidates && !obligation.predicate.has_non_region_infer() { // HACK: Pick the first trait def candidate for a fully // inferred predicate. This is to allow duplicates that // differ only in normalization. return; } } ProjectionMatchesProjection::Ambiguous => { candidate_set.mark_ambiguous(); } ProjectionMatchesProjection::No => {} } } } } #[instrument(level = "debug", skip(selcx, obligation, candidate_set))] fn assemble_candidates_from_impls<'cx, 'tcx>( selcx: &mut SelectionContext<'cx, 'tcx>, obligation: &ProjectionTyObligation<'tcx>, candidate_set: &mut ProjectionCandidateSet<'tcx>, ) { // Can't assemble candidate from impl for RPITIT if selcx.tcx().def_kind(obligation.predicate.item_def_id) == DefKind::ImplTraitPlaceholder { return; } // If we are resolving `>::Item == Type`, // start out by selecting the predicate `T as TraitRef<...>`: let poly_trait_ref = ty::Binder::dummy(obligation.predicate.trait_ref(selcx.tcx())); let trait_obligation = obligation.with(poly_trait_ref.to_poly_trait_predicate()); let _ = selcx.infcx().commit_if_ok(|_| { let impl_source = match selcx.select(&trait_obligation) { Ok(Some(impl_source)) => impl_source, Ok(None) => { candidate_set.mark_ambiguous(); return Err(()); } Err(e) => { debug!(error = ?e, "selection error"); candidate_set.mark_error(e); return Err(()); } }; let eligible = match &impl_source { super::ImplSource::Closure(_) | super::ImplSource::Generator(_) | super::ImplSource::FnPointer(_) | super::ImplSource::TraitAlias(_) => true, super::ImplSource::UserDefined(impl_data) => { // We have to be careful when projecting out of an // impl because of specialization. If we are not in // codegen (i.e., projection mode is not "any"), and the // impl's type is declared as default, then we disable // projection (even if the trait ref is fully // monomorphic). In the case where trait ref is not // fully monomorphic (i.e., includes type parameters), // this is because those type parameters may // ultimately be bound to types from other crates that // may have specialized impls we can't see. In the // case where the trait ref IS fully monomorphic, this // is a policy decision that we made in the RFC in // order to preserve flexibility for the crate that // defined the specializable impl to specialize later // for existing types. // // In either case, we handle this by not adding a // candidate for an impl if it contains a `default` // type. // // NOTE: This should be kept in sync with the similar code in // `rustc_ty_utils::instance::resolve_associated_item()`. let node_item = assoc_def(selcx, impl_data.impl_def_id, obligation.predicate.item_def_id) .map_err(|ErrorGuaranteed { .. }| ())?; if node_item.is_final() { // Non-specializable items are always projectable. true } else { // Only reveal a specializable default if we're past type-checking // and the obligation is monomorphic, otherwise passes such as // transmute checking and polymorphic MIR optimizations could // get a result which isn't correct for all monomorphizations. if obligation.param_env.reveal() == Reveal::All { // NOTE(eddyb) inference variables can resolve to parameters, so // assume `poly_trait_ref` isn't monomorphic, if it contains any. let poly_trait_ref = selcx.infcx().resolve_vars_if_possible(poly_trait_ref); !poly_trait_ref.still_further_specializable() } else { debug!( assoc_ty = ?selcx.tcx().def_path_str(node_item.item.def_id), ?obligation.predicate, "assemble_candidates_from_impls: not eligible due to default", ); false } } } super::ImplSource::DiscriminantKind(..) => { // While `DiscriminantKind` is automatically implemented for every type, // the concrete discriminant may not be known yet. // // Any type with multiple potential discriminant types is therefore not eligible. let self_ty = selcx.infcx().shallow_resolve(obligation.predicate.self_ty()); match self_ty.kind() { 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::Never | ty::Tuple(..) // Integers and floats always have `u8` as their discriminant. | ty::Infer(ty::InferTy::IntVar(_) | ty::InferTy::FloatVar(..)) => true, ty::Projection(..) | ty::Opaque(..) | ty::Param(..) | ty::Bound(..) | ty::Placeholder(..) | ty::Infer(..) | ty::Error(_) => false, } } super::ImplSource::Pointee(..) => { // While `Pointee` is automatically implemented for every type, // the concrete metadata type may not be known yet. // // Any type with multiple potential metadata types is therefore not eligible. let self_ty = selcx.infcx().shallow_resolve(obligation.predicate.self_ty()); let tail = selcx.tcx().struct_tail_with_normalize( self_ty, |ty| { // We throw away any obligations we get from this, since we normalize // and confirm these obligations once again during confirmation normalize_with_depth( selcx, obligation.param_env, obligation.cause.clone(), obligation.recursion_depth + 1, ty, ) .value }, || {}, ); match tail.kind() { ty::Bool | ty::Char | ty::Int(_) | ty::Uint(_) | ty::Float(_) | ty::Str | ty::Array(..) | ty::Slice(_) | ty::RawPtr(..) | ty::Ref(..) | ty::FnDef(..) | ty::FnPtr(..) | ty::Dynamic(..) | ty::Closure(..) | ty::Generator(..) | ty::GeneratorWitness(..) | ty::Never // Extern types have unit metadata, according to RFC 2850 | ty::Foreign(_) // If returned by `struct_tail_without_normalization` this is a unit struct // without any fields, or not a struct, and therefore is Sized. | ty::Adt(..) // If returned by `struct_tail_without_normalization` this is the empty tuple. | ty::Tuple(..) // Integers and floats are always Sized, and so have unit type metadata. | ty::Infer(ty::InferTy::IntVar(_) | ty::InferTy::FloatVar(..)) => true, // type parameters, opaques, and unnormalized projections have pointer // metadata if they're known (e.g. by the param_env) to be sized ty::Param(_) | ty::Projection(..) | ty::Opaque(..) if selcx.infcx().predicate_must_hold_modulo_regions( &obligation.with( ty::Binder::dummy(ty::TraitRef::new( selcx.tcx().require_lang_item(LangItem::Sized, None), selcx.tcx().mk_substs_trait(self_ty, &[]), )) .without_const() .to_predicate(selcx.tcx()), ), ) => { true } // FIXME(compiler-errors): are Bound and Placeholder types ever known sized? ty::Param(_) | ty::Projection(..) | ty::Opaque(..) | ty::Bound(..) | ty::Placeholder(..) | ty::Infer(..) | ty::Error(_) => { if tail.has_infer_types() { candidate_set.mark_ambiguous(); } false } } } super::ImplSource::Param(..) => { // This case tell us nothing about the value of an // associated type. Consider: // // ``` // trait SomeTrait { type Foo; } // fn foo(...) { } // ``` // // If the user writes `::Foo`, then the `T // : SomeTrait` binding does not help us decide what the // type `Foo` is (at least, not more specifically than // what we already knew). // // But wait, you say! What about an example like this: // // ``` // fn bar>(...) { ... } // ``` // // Doesn't the `T : SomeTrait` predicate help // resolve `T::Foo`? And of course it does, but in fact // that single predicate is desugared into two predicates // in the compiler: a trait predicate (`T : SomeTrait`) and a // projection. And the projection where clause is handled // in `assemble_candidates_from_param_env`. false } super::ImplSource::Object(_) => { // Handled by the `Object` projection candidate. See // `assemble_candidates_from_object_ty` for an explanation of // why we special case object types. false } super::ImplSource::AutoImpl(..) | super::ImplSource::Builtin(..) | super::ImplSource::TraitUpcasting(_) | super::ImplSource::ConstDestruct(_) => { // These traits have no associated types. selcx.tcx().sess.delay_span_bug( obligation.cause.span, &format!("Cannot project an associated type from `{:?}`", impl_source), ); return Err(()); } }; if eligible { if candidate_set.push_candidate(ProjectionCandidate::Select(impl_source)) { Ok(()) } else { Err(()) } } else { Err(()) } }); } fn confirm_candidate<'cx, 'tcx>( selcx: &mut SelectionContext<'cx, 'tcx>, obligation: &ProjectionTyObligation<'tcx>, candidate: ProjectionCandidate<'tcx>, ) -> Progress<'tcx> { debug!(?obligation, ?candidate, "confirm_candidate"); let mut progress = match candidate { ProjectionCandidate::ParamEnv(poly_projection) | ProjectionCandidate::Object(poly_projection) => { confirm_param_env_candidate(selcx, obligation, poly_projection, false) } ProjectionCandidate::TraitDef(poly_projection) => { confirm_param_env_candidate(selcx, obligation, poly_projection, true) } ProjectionCandidate::Select(impl_source) => { confirm_select_candidate(selcx, obligation, impl_source) } ProjectionCandidate::ImplTraitInTrait(ImplTraitInTraitCandidate::Impl(data)) => { confirm_impl_trait_in_trait_candidate(selcx, obligation, data) } // If we're projecting an RPITIT for a default trait body, that's just // the same def-id, but as an opaque type (with regular RPIT semantics). ProjectionCandidate::ImplTraitInTrait(ImplTraitInTraitCandidate::Trait) => Progress { term: selcx .tcx() .mk_opaque(obligation.predicate.item_def_id, obligation.predicate.substs) .into(), obligations: vec![], }, }; // When checking for cycle during evaluation, we compare predicates with // "syntactic" equality. Since normalization generally introduces a type // with new region variables, we need to resolve them to existing variables // when possible for this to work. See `auto-trait-projection-recursion.rs` // for a case where this matters. if progress.term.has_infer_regions() { progress.term = progress.term.fold_with(&mut OpportunisticRegionResolver::new(selcx.infcx())); } progress } fn confirm_select_candidate<'cx, 'tcx>( selcx: &mut SelectionContext<'cx, 'tcx>, obligation: &ProjectionTyObligation<'tcx>, impl_source: Selection<'tcx>, ) -> Progress<'tcx> { match impl_source { super::ImplSource::UserDefined(data) => confirm_impl_candidate(selcx, obligation, data), super::ImplSource::Generator(data) => confirm_generator_candidate(selcx, obligation, data), super::ImplSource::Closure(data) => confirm_closure_candidate(selcx, obligation, data), super::ImplSource::FnPointer(data) => confirm_fn_pointer_candidate(selcx, obligation, data), super::ImplSource::DiscriminantKind(data) => { confirm_discriminant_kind_candidate(selcx, obligation, data) } super::ImplSource::Pointee(data) => confirm_pointee_candidate(selcx, obligation, data), super::ImplSource::Object(_) | super::ImplSource::AutoImpl(..) | super::ImplSource::Param(..) | super::ImplSource::Builtin(..) | super::ImplSource::TraitUpcasting(_) | super::ImplSource::TraitAlias(..) | super::ImplSource::ConstDestruct(_) => { // we don't create Select candidates with this kind of resolution span_bug!( obligation.cause.span, "Cannot project an associated type from `{:?}`", impl_source ) } } } fn confirm_generator_candidate<'cx, 'tcx>( selcx: &mut SelectionContext<'cx, 'tcx>, obligation: &ProjectionTyObligation<'tcx>, impl_source: ImplSourceGeneratorData<'tcx, PredicateObligation<'tcx>>, ) -> Progress<'tcx> { let gen_sig = impl_source.substs.as_generator().poly_sig(); let Normalized { value: gen_sig, obligations } = normalize_with_depth( selcx, obligation.param_env, obligation.cause.clone(), obligation.recursion_depth + 1, gen_sig, ); debug!(?obligation, ?gen_sig, ?obligations, "confirm_generator_candidate"); let tcx = selcx.tcx(); let gen_def_id = tcx.require_lang_item(LangItem::Generator, None); let predicate = super::util::generator_trait_ref_and_outputs( tcx, gen_def_id, obligation.predicate.self_ty(), gen_sig, ) .map_bound(|(trait_ref, yield_ty, return_ty)| { let name = tcx.associated_item(obligation.predicate.item_def_id).name; let ty = if name == sym::Return { return_ty } else if name == sym::Yield { yield_ty } else { bug!() }; ty::ProjectionPredicate { projection_ty: ty::ProjectionTy { substs: trait_ref.substs, item_def_id: obligation.predicate.item_def_id, }, term: ty.into(), } }); confirm_param_env_candidate(selcx, obligation, predicate, false) .with_addl_obligations(impl_source.nested) .with_addl_obligations(obligations) } fn confirm_discriminant_kind_candidate<'cx, 'tcx>( selcx: &mut SelectionContext<'cx, 'tcx>, obligation: &ProjectionTyObligation<'tcx>, _: ImplSourceDiscriminantKindData, ) -> Progress<'tcx> { let tcx = selcx.tcx(); let self_ty = selcx.infcx().shallow_resolve(obligation.predicate.self_ty()); // We get here from `poly_project_and_unify_type` which replaces bound vars // with placeholders debug_assert!(!self_ty.has_escaping_bound_vars()); let substs = tcx.mk_substs([self_ty.into()].iter()); let discriminant_def_id = tcx.require_lang_item(LangItem::Discriminant, None); let predicate = ty::ProjectionPredicate { projection_ty: ty::ProjectionTy { substs, item_def_id: discriminant_def_id }, term: self_ty.discriminant_ty(tcx).into(), }; // We get here from `poly_project_and_unify_type` which replaces bound vars // with placeholders, so dummy is okay here. confirm_param_env_candidate(selcx, obligation, ty::Binder::dummy(predicate), false) } fn confirm_pointee_candidate<'cx, 'tcx>( selcx: &mut SelectionContext<'cx, 'tcx>, obligation: &ProjectionTyObligation<'tcx>, _: ImplSourcePointeeData, ) -> Progress<'tcx> { let tcx = selcx.tcx(); let self_ty = selcx.infcx().shallow_resolve(obligation.predicate.self_ty()); let mut obligations = vec![]; let (metadata_ty, check_is_sized) = self_ty.ptr_metadata_ty(tcx, |ty| { normalize_with_depth_to( selcx, obligation.param_env, obligation.cause.clone(), obligation.recursion_depth + 1, ty, &mut obligations, ) }); if check_is_sized { let sized_predicate = ty::Binder::dummy(ty::TraitRef::new( tcx.require_lang_item(LangItem::Sized, None), tcx.mk_substs_trait(self_ty, &[]), )) .without_const() .to_predicate(tcx); obligations.push(Obligation::new( obligation.cause.clone(), obligation.param_env, sized_predicate, )); } let substs = tcx.mk_substs([self_ty.into()].iter()); let metadata_def_id = tcx.require_lang_item(LangItem::Metadata, None); let predicate = ty::ProjectionPredicate { projection_ty: ty::ProjectionTy { substs, item_def_id: metadata_def_id }, term: metadata_ty.into(), }; confirm_param_env_candidate(selcx, obligation, ty::Binder::dummy(predicate), false) .with_addl_obligations(obligations) } fn confirm_fn_pointer_candidate<'cx, 'tcx>( selcx: &mut SelectionContext<'cx, 'tcx>, obligation: &ProjectionTyObligation<'tcx>, fn_pointer_impl_source: ImplSourceFnPointerData<'tcx, PredicateObligation<'tcx>>, ) -> Progress<'tcx> { let fn_type = selcx.infcx().shallow_resolve(fn_pointer_impl_source.fn_ty); let sig = fn_type.fn_sig(selcx.tcx()); let Normalized { value: sig, obligations } = normalize_with_depth( selcx, obligation.param_env, obligation.cause.clone(), obligation.recursion_depth + 1, sig, ); confirm_callable_candidate(selcx, obligation, sig, util::TupleArgumentsFlag::Yes) .with_addl_obligations(fn_pointer_impl_source.nested) .with_addl_obligations(obligations) } fn confirm_closure_candidate<'cx, 'tcx>( selcx: &mut SelectionContext<'cx, 'tcx>, obligation: &ProjectionTyObligation<'tcx>, impl_source: ImplSourceClosureData<'tcx, PredicateObligation<'tcx>>, ) -> Progress<'tcx> { let closure_sig = impl_source.substs.as_closure().sig(); let Normalized { value: closure_sig, obligations } = normalize_with_depth( selcx, obligation.param_env, obligation.cause.clone(), obligation.recursion_depth + 1, closure_sig, ); debug!(?obligation, ?closure_sig, ?obligations, "confirm_closure_candidate"); confirm_callable_candidate(selcx, obligation, closure_sig, util::TupleArgumentsFlag::No) .with_addl_obligations(impl_source.nested) .with_addl_obligations(obligations) } fn confirm_callable_candidate<'cx, 'tcx>( selcx: &mut SelectionContext<'cx, 'tcx>, obligation: &ProjectionTyObligation<'tcx>, fn_sig: ty::PolyFnSig<'tcx>, flag: util::TupleArgumentsFlag, ) -> Progress<'tcx> { let tcx = selcx.tcx(); debug!(?obligation, ?fn_sig, "confirm_callable_candidate"); let fn_once_def_id = tcx.require_lang_item(LangItem::FnOnce, None); let fn_once_output_def_id = tcx.require_lang_item(LangItem::FnOnceOutput, None); let predicate = super::util::closure_trait_ref_and_return_type( tcx, fn_once_def_id, obligation.predicate.self_ty(), fn_sig, flag, ) .map_bound(|(trait_ref, ret_type)| ty::ProjectionPredicate { projection_ty: ty::ProjectionTy { substs: trait_ref.substs, item_def_id: fn_once_output_def_id, }, term: ret_type.into(), }); confirm_param_env_candidate(selcx, obligation, predicate, true) } fn confirm_param_env_candidate<'cx, 'tcx>( selcx: &mut SelectionContext<'cx, 'tcx>, obligation: &ProjectionTyObligation<'tcx>, poly_cache_entry: ty::PolyProjectionPredicate<'tcx>, potentially_unnormalized_candidate: bool, ) -> Progress<'tcx> { let infcx = selcx.infcx(); let cause = &obligation.cause; let param_env = obligation.param_env; let cache_entry = infcx.replace_bound_vars_with_fresh_vars( cause.span, LateBoundRegionConversionTime::HigherRankedType, poly_cache_entry, ); let cache_projection = cache_entry.projection_ty; let mut nested_obligations = Vec::new(); let obligation_projection = obligation.predicate; let obligation_projection = ensure_sufficient_stack(|| { normalize_with_depth_to( selcx, obligation.param_env, obligation.cause.clone(), obligation.recursion_depth + 1, obligation_projection, &mut nested_obligations, ) }); let cache_projection = if potentially_unnormalized_candidate { ensure_sufficient_stack(|| { normalize_with_depth_to( selcx, obligation.param_env, obligation.cause.clone(), obligation.recursion_depth + 1, cache_projection, &mut nested_obligations, ) }) } else { cache_projection }; debug!(?cache_projection, ?obligation_projection); match infcx.at(cause, param_env).eq(cache_projection, obligation_projection) { Ok(InferOk { value: _, obligations }) => { nested_obligations.extend(obligations); assoc_ty_own_obligations(selcx, obligation, &mut nested_obligations); // FIXME(associated_const_equality): Handle consts here as well? Maybe this progress type should just take // a term instead. Progress { term: cache_entry.term, obligations: nested_obligations } } Err(e) => { let msg = format!( "Failed to unify obligation `{:?}` with poly_projection `{:?}`: {:?}", obligation, poly_cache_entry, e, ); debug!("confirm_param_env_candidate: {}", msg); let err = infcx.tcx.ty_error_with_message(obligation.cause.span, &msg); Progress { term: err.into(), obligations: vec![] } } } } fn confirm_impl_candidate<'cx, 'tcx>( selcx: &mut SelectionContext<'cx, 'tcx>, obligation: &ProjectionTyObligation<'tcx>, impl_impl_source: ImplSourceUserDefinedData<'tcx, PredicateObligation<'tcx>>, ) -> Progress<'tcx> { let tcx = selcx.tcx(); let ImplSourceUserDefinedData { impl_def_id, substs, mut nested } = impl_impl_source; let assoc_item_id = obligation.predicate.item_def_id; let trait_def_id = tcx.trait_id_of_impl(impl_def_id).unwrap(); let param_env = obligation.param_env; let Ok(assoc_ty) = assoc_def(selcx, impl_def_id, assoc_item_id) else { return Progress { term: tcx.ty_error().into(), obligations: nested }; }; if !assoc_ty.item.defaultness(tcx).has_value() { // This means that the impl is missing a definition for the // associated type. This error will be reported by the type // checker method `check_impl_items_against_trait`, so here we // just return Error. debug!( "confirm_impl_candidate: no associated type {:?} for {:?}", assoc_ty.item.name, obligation.predicate ); return Progress { term: tcx.ty_error().into(), obligations: nested }; } // If we're trying to normalize ` as X>::A` using //`impl X for Vec { type A = Box; }`, then: // // * `obligation.predicate.substs` is `[Vec, S]` // * `substs` is `[u32]` // * `substs` ends up as `[u32, S]` let substs = obligation.predicate.substs.rebase_onto(tcx, trait_def_id, substs); let substs = translate_substs(selcx.infcx(), param_env, impl_def_id, substs, assoc_ty.defining_node); let ty = tcx.bound_type_of(assoc_ty.item.def_id); let is_const = matches!(tcx.def_kind(assoc_ty.item.def_id), DefKind::AssocConst); let term: ty::EarlyBinder> = if is_const { let identity_substs = crate::traits::InternalSubsts::identity_for_item(tcx, assoc_ty.item.def_id); let did = ty::WithOptConstParam::unknown(assoc_ty.item.def_id); let kind = ty::ConstKind::Unevaluated(ty::UnevaluatedConst::new(did, identity_substs)); ty.map_bound(|ty| tcx.mk_const(ty::ConstS { ty, kind }).into()) } else { ty.map_bound(|ty| ty.into()) }; if !check_substs_compatible(tcx, &assoc_ty.item, substs) { let err = tcx.ty_error_with_message( obligation.cause.span, "impl item and trait item have different parameters", ); Progress { term: err.into(), obligations: nested } } else { assoc_ty_own_obligations(selcx, obligation, &mut nested); Progress { term: term.subst(tcx, substs), obligations: nested } } } // Verify that the trait item and its implementation have compatible substs lists fn check_substs_compatible<'tcx>( tcx: TyCtxt<'tcx>, assoc_ty: &ty::AssocItem, substs: ty::SubstsRef<'tcx>, ) -> bool { fn check_substs_compatible_inner<'tcx>( tcx: TyCtxt<'tcx>, generics: &'tcx ty::Generics, args: &'tcx [ty::GenericArg<'tcx>], ) -> bool { if generics.count() != args.len() { return false; } let (parent_args, own_args) = args.split_at(generics.parent_count); if let Some(parent) = generics.parent && let parent_generics = tcx.generics_of(parent) && !check_substs_compatible_inner(tcx, parent_generics, parent_args) { return false; } for (param, arg) in std::iter::zip(&generics.params, own_args) { match (¶m.kind, arg.unpack()) { (ty::GenericParamDefKind::Type { .. }, ty::GenericArgKind::Type(_)) | (ty::GenericParamDefKind::Lifetime, ty::GenericArgKind::Lifetime(_)) | (ty::GenericParamDefKind::Const { .. }, ty::GenericArgKind::Const(_)) => {} _ => return false, } } true } check_substs_compatible_inner(tcx, tcx.generics_of(assoc_ty.def_id), substs.as_slice()) } fn confirm_impl_trait_in_trait_candidate<'tcx>( selcx: &mut SelectionContext<'_, 'tcx>, obligation: &ProjectionTyObligation<'tcx>, data: ImplSourceUserDefinedData<'tcx, PredicateObligation<'tcx>>, ) -> Progress<'tcx> { let tcx = selcx.tcx(); let mut obligations = data.nested; let trait_fn_def_id = tcx.impl_trait_in_trait_parent(obligation.predicate.item_def_id); let Ok(leaf_def) = assoc_def(selcx, data.impl_def_id, trait_fn_def_id) else { return Progress { term: tcx.ty_error().into(), obligations }; }; if !leaf_def.item.defaultness(tcx).has_value() { return Progress { term: tcx.ty_error().into(), obligations }; } // Use the default `impl Trait` for the trait, e.g., for a default trait body if leaf_def.item.container == ty::AssocItemContainer::TraitContainer { return Progress { term: tcx .mk_opaque(obligation.predicate.item_def_id, obligation.predicate.substs) .into(), obligations, }; } let impl_fn_def_id = leaf_def.item.def_id; // Rebase from {trait}::{fn}::{opaque} to {impl}::{fn}::{opaque}, // since `data.substs` are the impl substs. let impl_fn_substs = obligation.predicate.substs.rebase_onto(tcx, tcx.parent(trait_fn_def_id), data.substs); let cause = ObligationCause::new( obligation.cause.span, obligation.cause.body_id, super::ItemObligation(impl_fn_def_id), ); let predicates = normalize_with_depth_to( selcx, obligation.param_env, cause.clone(), obligation.recursion_depth + 1, tcx.predicates_of(impl_fn_def_id).instantiate(tcx, impl_fn_substs), &mut obligations, ); obligations.extend(std::iter::zip(predicates.predicates, predicates.spans).map( |(pred, span)| { Obligation::with_depth( ObligationCause::new( obligation.cause.span, obligation.cause.body_id, if span.is_dummy() { super::ItemObligation(impl_fn_def_id) } else { super::BindingObligation(impl_fn_def_id, span) }, ), obligation.recursion_depth + 1, obligation.param_env, pred, ) }, )); let ty = super::normalize_to( selcx, obligation.param_env, cause.clone(), tcx.bound_trait_impl_trait_tys(impl_fn_def_id) .map_bound(|tys| { tys.map_or_else(|_| tcx.ty_error(), |tys| tys[&obligation.predicate.item_def_id]) }) .subst(tcx, impl_fn_substs), &mut obligations, ); Progress { term: ty.into(), obligations } } // Get obligations corresponding to the predicates from the where-clause of the // associated type itself. fn assoc_ty_own_obligations<'cx, 'tcx>( selcx: &mut SelectionContext<'cx, 'tcx>, obligation: &ProjectionTyObligation<'tcx>, nested: &mut Vec>, ) { let tcx = selcx.tcx(); for predicate in tcx .predicates_of(obligation.predicate.item_def_id) .instantiate_own(tcx, obligation.predicate.substs) .predicates { let normalized = normalize_with_depth_to( selcx, obligation.param_env, obligation.cause.clone(), obligation.recursion_depth + 1, predicate, nested, ); nested.push(Obligation::with_depth( obligation.cause.clone(), obligation.recursion_depth + 1, obligation.param_env, normalized, )); } } /// Locate the definition of an associated type in the specialization hierarchy, /// starting from the given impl. /// /// Based on the "projection mode", this lookup may in fact only examine the /// topmost impl. See the comments for `Reveal` for more details. fn assoc_def( selcx: &SelectionContext<'_, '_>, impl_def_id: DefId, assoc_def_id: DefId, ) -> Result { let tcx = selcx.tcx(); let trait_def_id = tcx.impl_trait_ref(impl_def_id).unwrap().def_id; let trait_def = tcx.trait_def(trait_def_id); // This function may be called while we are still building the // specialization graph that is queried below (via TraitDef::ancestors()), // so, in order to avoid unnecessary infinite recursion, we manually look // for the associated item at the given impl. // If there is no such item in that impl, this function will fail with a // cycle error if the specialization graph is currently being built. if let Some(&impl_item_id) = tcx.impl_item_implementor_ids(impl_def_id).get(&assoc_def_id) { let item = tcx.associated_item(impl_item_id); let impl_node = specialization_graph::Node::Impl(impl_def_id); return Ok(specialization_graph::LeafDef { item: *item, defining_node: impl_node, finalizing_node: if item.defaultness(tcx).is_default() { None } else { Some(impl_node) }, }); } let ancestors = trait_def.ancestors(tcx, impl_def_id)?; if let Some(assoc_item) = ancestors.leaf_def(tcx, assoc_def_id) { Ok(assoc_item) } else { // This is saying that neither the trait nor // the impl contain a definition for this // associated type. Normally this situation // could only arise through a compiler bug -- // if the user wrote a bad item name, it // should have failed in astconv. bug!( "No associated type `{}` for {}", tcx.item_name(assoc_def_id), tcx.def_path_str(impl_def_id) ) } } pub(crate) trait ProjectionCacheKeyExt<'cx, 'tcx>: Sized { fn from_poly_projection_predicate( selcx: &mut SelectionContext<'cx, 'tcx>, predicate: ty::PolyProjectionPredicate<'tcx>, ) -> Option; } impl<'cx, 'tcx> ProjectionCacheKeyExt<'cx, 'tcx> for ProjectionCacheKey<'tcx> { fn from_poly_projection_predicate( selcx: &mut SelectionContext<'cx, 'tcx>, predicate: ty::PolyProjectionPredicate<'tcx>, ) -> Option { let infcx = selcx.infcx(); // We don't do cross-snapshot caching of obligations with escaping regions, // so there's no cache key to use predicate.no_bound_vars().map(|predicate| { ProjectionCacheKey::new( // We don't attempt to match up with a specific type-variable state // from a specific call to `opt_normalize_projection_type` - if // there's no precise match, the original cache entry is "stranded" // anyway. infcx.resolve_vars_if_possible(predicate.projection_ty), ) }) } }