use rustc_hir::def_id::{DefId, LocalDefId}; use rustc_infer::infer::at::ToTrace; use rustc_infer::infer::canonical::CanonicalVarValues; use rustc_infer::infer::type_variable::{TypeVariableOrigin, TypeVariableOriginKind}; use rustc_infer::infer::{ DefineOpaqueTypes, InferCtxt, InferOk, LateBoundRegionConversionTime, RegionVariableOrigin, TyCtxtInferExt, }; use rustc_infer::traits::query::NoSolution; use rustc_infer::traits::ObligationCause; use rustc_middle::infer::unify_key::{ConstVariableOrigin, ConstVariableOriginKind}; use rustc_middle::traits::solve::inspect::{self, CandidateKind}; use rustc_middle::traits::solve::{ CanonicalInput, CanonicalResponse, Certainty, IsNormalizesToHack, MaybeCause, PredefinedOpaques, PredefinedOpaquesData, QueryResult, }; use rustc_middle::traits::DefiningAnchor; use rustc_middle::ty::{ self, OpaqueTypeKey, Ty, TyCtxt, TypeFoldable, TypeSuperVisitable, TypeVisitable, TypeVisitableExt, TypeVisitor, }; use rustc_span::DUMMY_SP; use std::ops::ControlFlow; use crate::traits::specialization_graph; use super::inspect::ProofTreeBuilder; use super::search_graph::{self, OverflowHandler}; use super::SolverMode; use super::{search_graph::SearchGraph, Goal}; pub use select::InferCtxtSelectExt; mod canonical; mod probe; mod select; pub struct EvalCtxt<'a, 'tcx> { /// The inference context that backs (mostly) inference and placeholder terms /// instantiated while solving goals. /// /// NOTE: The `InferCtxt` that backs the `EvalCtxt` is intentionally private, /// because the `InferCtxt` is much more general than `EvalCtxt`. Methods such /// as `take_registered_region_obligations` can mess up query responses, /// using `At::normalize` is totally wrong, calling `evaluate_root_goal` can /// cause coinductive unsoundness, etc. /// /// Methods that are generally of use for trait solving are *intentionally* /// re-declared through the `EvalCtxt` below, often with cleaner signatures /// since we don't care about things like `ObligationCause`s and `Span`s here. /// If some `InferCtxt` method is missing, please first think defensively about /// the method's compatibility with this solver, or if an existing one does /// the job already. infcx: &'a InferCtxt<'tcx>, pub(super) var_values: CanonicalVarValues<'tcx>, predefined_opaques_in_body: PredefinedOpaques<'tcx>, /// The highest universe index nameable by the caller. /// /// When we enter a new binder inside of the query we create new universes /// which the caller cannot name. We have to be careful with variables from /// these new universes when creating the query response. /// /// Both because these new universes can prevent us from reaching a fixpoint /// if we have a coinductive cycle and because that's the only way we can return /// new placeholders to the caller. pub(super) max_input_universe: ty::UniverseIndex, pub(super) search_graph: &'a mut SearchGraph<'tcx>, pub(super) nested_goals: NestedGoals<'tcx>, // Has this `EvalCtxt` errored out with `NoSolution` in `try_evaluate_added_goals`? // // If so, then it can no longer be used to make a canonical query response, // since subsequent calls to `try_evaluate_added_goals` have possibly dropped // ambiguous goals. Instead, a probe needs to be introduced somewhere in the // evaluation code. tainted: Result<(), NoSolution>, inspect: ProofTreeBuilder<'tcx>, } #[derive(Debug, Clone)] pub(super) struct NestedGoals<'tcx> { /// This normalizes-to goal that is treated specially during the evaluation /// loop. In each iteration we take the RHS of the projection, replace it with /// a fresh inference variable, and only after evaluating that goal do we /// equate the fresh inference variable with the actual RHS of the predicate. /// /// This is both to improve caching, and to avoid using the RHS of the /// projection predicate to influence the normalizes-to candidate we select. /// /// This is not a 'real' nested goal. We must not forget to replace the RHS /// with a fresh inference variable when we evaluate this goal. That can result /// in a trait solver cycle. This would currently result in overflow but can be /// can be unsound with more powerful coinduction in the future. pub(super) normalizes_to_hack_goal: Option>>, /// The rest of the goals which have not yet processed or remain ambiguous. pub(super) goals: Vec>>, } impl NestedGoals<'_> { pub(super) fn new() -> Self { Self { normalizes_to_hack_goal: None, goals: Vec::new() } } pub(super) fn is_empty(&self) -> bool { self.normalizes_to_hack_goal.is_none() && self.goals.is_empty() } } #[derive(PartialEq, Eq, Debug, Hash, HashStable, Clone, Copy)] pub enum GenerateProofTree { Yes, No, } pub trait InferCtxtEvalExt<'tcx> { /// Evaluates a goal from **outside** of the trait solver. /// /// Using this while inside of the solver is wrong as it uses a new /// search graph which would break cycle detection. fn evaluate_root_goal( &self, goal: Goal<'tcx, ty::Predicate<'tcx>>, generate_proof_tree: GenerateProofTree, ) -> ( Result<(bool, Certainty, Vec>>), NoSolution>, Option>, ); } impl<'tcx> InferCtxtEvalExt<'tcx> for InferCtxt<'tcx> { #[instrument(level = "debug", skip(self), ret)] fn evaluate_root_goal( &self, goal: Goal<'tcx, ty::Predicate<'tcx>>, generate_proof_tree: GenerateProofTree, ) -> ( Result<(bool, Certainty, Vec>>), NoSolution>, Option>, ) { EvalCtxt::enter_root(self, generate_proof_tree, |ecx| { ecx.evaluate_goal(IsNormalizesToHack::No, goal) }) } } impl<'a, 'tcx> EvalCtxt<'a, 'tcx> { pub(super) fn solver_mode(&self) -> SolverMode { self.search_graph.solver_mode() } /// Creates a root evaluation context and search graph. This should only be /// used from outside of any evaluation, and other methods should be preferred /// over using this manually (such as [`InferCtxtEvalExt::evaluate_root_goal`]). fn enter_root( infcx: &InferCtxt<'tcx>, generate_proof_tree: GenerateProofTree, f: impl FnOnce(&mut EvalCtxt<'_, 'tcx>) -> R, ) -> (R, Option>) { let mode = if infcx.intercrate { SolverMode::Coherence } else { SolverMode::Normal }; let mut search_graph = search_graph::SearchGraph::new(infcx.tcx, mode); let mut ecx = EvalCtxt { search_graph: &mut search_graph, infcx: infcx, // Only relevant when canonicalizing the response, // which we don't do within this evaluation context. predefined_opaques_in_body: infcx .tcx .mk_predefined_opaques_in_body(PredefinedOpaquesData::default()), // Only relevant when canonicalizing the response. max_input_universe: ty::UniverseIndex::ROOT, var_values: CanonicalVarValues::dummy(), nested_goals: NestedGoals::new(), tainted: Ok(()), inspect: (infcx.tcx.sess.opts.unstable_opts.dump_solver_proof_tree || matches!(generate_proof_tree, GenerateProofTree::Yes)) .then(ProofTreeBuilder::new_root) .unwrap_or_else(ProofTreeBuilder::new_noop), }; let result = f(&mut ecx); let tree = ecx.inspect.finalize(); if let Some(tree) = &tree { // module to allow more granular RUSTC_LOG filtering to just proof tree output super::inspect::dump::print_tree(tree); } assert!( ecx.nested_goals.is_empty(), "root `EvalCtxt` should not have any goals added to it" ); assert!(search_graph.is_empty()); (result, tree) } /// Creates a nested evaluation context that shares the same search graph as the /// one passed in. This is suitable for evaluation, granted that the search graph /// has had the nested goal recorded on its stack ([`SearchGraph::with_new_goal`]), /// but it's preferable to use other methods that call this one rather than this /// method directly. /// /// This function takes care of setting up the inference context, setting the anchor, /// and registering opaques from the canonicalized input. fn enter_canonical( tcx: TyCtxt<'tcx>, search_graph: &'a mut search_graph::SearchGraph<'tcx>, canonical_input: CanonicalInput<'tcx>, goal_evaluation: &mut ProofTreeBuilder<'tcx>, f: impl FnOnce(&mut EvalCtxt<'_, 'tcx>, Goal<'tcx, ty::Predicate<'tcx>>) -> R, ) -> R { let intercrate = match search_graph.solver_mode() { SolverMode::Normal => false, SolverMode::Coherence => true, }; let (ref infcx, input, var_values) = tcx .infer_ctxt() .intercrate(intercrate) .with_next_trait_solver(true) .with_opaque_type_inference(canonical_input.value.anchor) .build_with_canonical(DUMMY_SP, &canonical_input); let mut ecx = EvalCtxt { infcx, var_values, predefined_opaques_in_body: input.predefined_opaques_in_body, max_input_universe: canonical_input.max_universe, search_graph, nested_goals: NestedGoals::new(), tainted: Ok(()), inspect: goal_evaluation.new_goal_evaluation_step(input), }; for &(key, ty) in &input.predefined_opaques_in_body.opaque_types { ecx.insert_hidden_type(key, input.goal.param_env, ty) .expect("failed to prepopulate opaque types"); } if !ecx.nested_goals.is_empty() { panic!("prepopulating opaque types shouldn't add goals: {:?}", ecx.nested_goals); } let result = f(&mut ecx, input.goal); goal_evaluation.goal_evaluation_step(ecx.inspect); // When creating a query response we clone the opaque type constraints // instead of taking them. This would cause an ICE here, since we have // assertions against dropping an `InferCtxt` without taking opaques. // FIXME: Once we remove support for the old impl we can remove this. if input.anchor != DefiningAnchor::Error { let _ = infcx.take_opaque_types(); } result } /// The entry point of the solver. /// /// This function deals with (coinductive) cycles, overflow, and caching /// and then calls [`EvalCtxt::compute_goal`] which contains the actual /// logic of the solver. /// /// Instead of calling this function directly, use either [EvalCtxt::evaluate_goal] /// if you're inside of the solver or [InferCtxtEvalExt::evaluate_root_goal] if you're /// outside of it. #[instrument(level = "debug", skip(tcx, search_graph, goal_evaluation), ret)] fn evaluate_canonical_goal( tcx: TyCtxt<'tcx>, search_graph: &'a mut search_graph::SearchGraph<'tcx>, canonical_input: CanonicalInput<'tcx>, mut goal_evaluation: &mut ProofTreeBuilder<'tcx>, ) -> QueryResult<'tcx> { goal_evaluation.canonicalized_goal(canonical_input); // Deal with overflow, caching, and coinduction. // // The actual solver logic happens in `ecx.compute_goal`. search_graph.with_new_goal( tcx, canonical_input, goal_evaluation, |search_graph, goal_evaluation| { EvalCtxt::enter_canonical( tcx, search_graph, canonical_input, goal_evaluation, |ecx, goal| { let result = ecx.compute_goal(goal); ecx.inspect.query_result(result); result }, ) }, ) } /// Recursively evaluates `goal`, returning whether any inference vars have /// been constrained and the certainty of the result. fn evaluate_goal( &mut self, is_normalizes_to_hack: IsNormalizesToHack, goal: Goal<'tcx, ty::Predicate<'tcx>>, ) -> Result<(bool, Certainty, Vec>>), NoSolution> { let (orig_values, canonical_goal) = self.canonicalize_goal(goal); let mut goal_evaluation = self.inspect.new_goal_evaluation(goal, is_normalizes_to_hack); let canonical_response = EvalCtxt::evaluate_canonical_goal( self.tcx(), self.search_graph, canonical_goal, &mut goal_evaluation, ); goal_evaluation.query_result(canonical_response); let canonical_response = match canonical_response { Err(e) => { self.inspect.goal_evaluation(goal_evaluation); return Err(e); } Ok(response) => response, }; let has_changed = !canonical_response.value.var_values.is_identity() || !canonical_response.value.external_constraints.opaque_types.is_empty(); let (certainty, nested_goals) = match self.instantiate_and_apply_query_response( goal.param_env, orig_values, canonical_response, ) { Err(e) => { self.inspect.goal_evaluation(goal_evaluation); return Err(e); } Ok(response) => response, }; goal_evaluation.returned_goals(&nested_goals); self.inspect.goal_evaluation(goal_evaluation); if !has_changed && !nested_goals.is_empty() { bug!("an unchanged goal shouldn't have any side-effects on instantiation"); } // Check that rerunning this query with its inference constraints applied // doesn't result in new inference constraints and has the same result. // // If we have projection goals like `::Assoc == u32` we recursively // call `exists ::Assoc == U` to enable better caching. This goal // could constrain `U` to `u32` which would cause this check to result in a // solver cycle. if cfg!(debug_assertions) && has_changed && is_normalizes_to_hack == IsNormalizesToHack::No && !self.search_graph.in_cycle() { debug!("rerunning goal to check result is stable"); let (_orig_values, canonical_goal) = self.canonicalize_goal(goal); let new_canonical_response = EvalCtxt::evaluate_canonical_goal( self.tcx(), self.search_graph, canonical_goal, // FIXME(-Ztrait-solver=next): we do not track what happens in `evaluate_canonical_goal` &mut ProofTreeBuilder::new_noop(), )?; // We only check for modulo regions as we convert all regions in // the input to new existentials, even if they're expected to be // `'static` or a placeholder region. if !new_canonical_response.value.var_values.is_identity_modulo_regions() { bug!( "unstable result: re-canonicalized goal={canonical_goal:#?} \ first_response={canonical_response:#?} \ second_response={new_canonical_response:#?}" ); } if certainty != new_canonical_response.value.certainty { bug!( "unstable certainty: {certainty:#?} re-canonicalized goal={canonical_goal:#?} \ first_response={canonical_response:#?} \ second_response={new_canonical_response:#?}" ); } } Ok((has_changed, certainty, nested_goals)) } fn compute_goal(&mut self, goal: Goal<'tcx, ty::Predicate<'tcx>>) -> QueryResult<'tcx> { let Goal { param_env, predicate } = goal; let kind = predicate.kind(); if let Some(kind) = kind.no_bound_vars() { match kind { ty::PredicateKind::Clause(ty::ClauseKind::Trait(predicate)) => { self.compute_trait_goal(Goal { param_env, predicate }) } ty::PredicateKind::Clause(ty::ClauseKind::Projection(predicate)) => { self.compute_projection_goal(Goal { param_env, predicate }) } ty::PredicateKind::Clause(ty::ClauseKind::TypeOutlives(predicate)) => { self.compute_type_outlives_goal(Goal { param_env, predicate }) } ty::PredicateKind::Clause(ty::ClauseKind::RegionOutlives(predicate)) => { self.compute_region_outlives_goal(Goal { param_env, predicate }) } ty::PredicateKind::Clause(ty::ClauseKind::ConstArgHasType(ct, ty)) => { self.compute_const_arg_has_type_goal(Goal { param_env, predicate: (ct, ty) }) } ty::PredicateKind::Subtype(predicate) => { self.compute_subtype_goal(Goal { param_env, predicate }) } ty::PredicateKind::Coerce(predicate) => { self.compute_coerce_goal(Goal { param_env, predicate }) } ty::PredicateKind::ClosureKind(def_id, substs, kind) => self .compute_closure_kind_goal(Goal { param_env, predicate: (def_id, substs, kind), }), ty::PredicateKind::ObjectSafe(trait_def_id) => { self.compute_object_safe_goal(trait_def_id) } ty::PredicateKind::Clause(ty::ClauseKind::WellFormed(arg)) => { self.compute_well_formed_goal(Goal { param_env, predicate: arg }) } ty::PredicateKind::Clause(ty::ClauseKind::ConstEvaluatable(ct)) => { self.compute_const_evaluatable_goal(Goal { param_env, predicate: ct }) } ty::PredicateKind::ConstEquate(_, _) => { bug!("ConstEquate should not be emitted when `-Ztrait-solver=next` is active") } ty::PredicateKind::AliasRelate(lhs, rhs, direction) => self .compute_alias_relate_goal(Goal { param_env, predicate: (lhs, rhs, direction), }), ty::PredicateKind::Ambiguous => { self.evaluate_added_goals_and_make_canonical_response(Certainty::AMBIGUOUS) } } } else { let kind = self.infcx.instantiate_binder_with_placeholders(kind); let goal = goal.with(self.tcx(), ty::Binder::dummy(kind)); self.add_goal(goal); self.evaluate_added_goals_and_make_canonical_response(Certainty::Yes) } } // Recursively evaluates all the goals added to this `EvalCtxt` to completion, returning // the certainty of all the goals. #[instrument(level = "debug", skip(self))] pub(super) fn try_evaluate_added_goals(&mut self) -> Result { let inspect = self.inspect.new_evaluate_added_goals(); let inspect = core::mem::replace(&mut self.inspect, inspect); let mut goals = core::mem::replace(&mut self.nested_goals, NestedGoals::new()); let mut new_goals = NestedGoals::new(); let response = self.repeat_while_none( |_| Ok(Certainty::Maybe(MaybeCause::Overflow)), |this| { this.inspect.evaluate_added_goals_loop_start(); let mut has_changed = Err(Certainty::Yes); if let Some(goal) = goals.normalizes_to_hack_goal.take() { // Replace the goal with an unconstrained infer var, so the // RHS does not affect projection candidate assembly. let unconstrained_rhs = this.next_term_infer_of_kind(goal.predicate.term); let unconstrained_goal = goal.with( this.tcx(), ty::Binder::dummy(ty::ProjectionPredicate { projection_ty: goal.predicate.projection_ty, term: unconstrained_rhs, }), ); let (_, certainty, instantiate_goals) = match this.evaluate_goal(IsNormalizesToHack::Yes, unconstrained_goal) { Ok(r) => r, Err(NoSolution) => return Some(Err(NoSolution)), }; new_goals.goals.extend(instantiate_goals); // Finally, equate the goal's RHS with the unconstrained var. // We put the nested goals from this into goals instead of // next_goals to avoid needing to process the loop one extra // time if this goal returns something -- I don't think this // matters in practice, though. match this.eq_and_get_goals( goal.param_env, goal.predicate.term, unconstrained_rhs, ) { Ok(eq_goals) => { goals.goals.extend(eq_goals); } Err(NoSolution) => return Some(Err(NoSolution)), }; // We only look at the `projection_ty` part here rather than // looking at the "has changed" return from evaluate_goal, // because we expect the `unconstrained_rhs` part of the predicate // to have changed -- that means we actually normalized successfully! if goal.predicate.projection_ty != this.resolve_vars_if_possible(goal.predicate.projection_ty) { has_changed = Ok(()) } match certainty { Certainty::Yes => {} Certainty::Maybe(_) => { // We need to resolve vars here so that we correctly // deal with `has_changed` in the next iteration. new_goals.normalizes_to_hack_goal = Some(this.resolve_vars_if_possible(goal)); has_changed = has_changed.map_err(|c| c.unify_with(certainty)); } } } for goal in goals.goals.drain(..) { let (changed, certainty, instantiate_goals) = match this.evaluate_goal(IsNormalizesToHack::No, goal) { Ok(result) => result, Err(NoSolution) => return Some(Err(NoSolution)), }; new_goals.goals.extend(instantiate_goals); if changed { has_changed = Ok(()); } match certainty { Certainty::Yes => {} Certainty::Maybe(_) => { new_goals.goals.push(goal); has_changed = has_changed.map_err(|c| c.unify_with(certainty)); } } } core::mem::swap(&mut new_goals, &mut goals); match has_changed { Ok(()) => None, Err(certainty) => Some(Ok(certainty)), } }, ); self.inspect.eval_added_goals_result(response); if response.is_err() { self.tainted = Err(NoSolution); } let goal_evaluations = std::mem::replace(&mut self.inspect, inspect); self.inspect.added_goals_evaluation(goal_evaluations); self.nested_goals = goals; response } } impl<'tcx> EvalCtxt<'_, 'tcx> { pub(super) fn tcx(&self) -> TyCtxt<'tcx> { self.infcx.tcx } pub(super) fn next_ty_infer(&self) -> Ty<'tcx> { self.infcx.next_ty_var(TypeVariableOrigin { kind: TypeVariableOriginKind::MiscVariable, span: DUMMY_SP, }) } pub(super) fn next_region_infer(&self) -> ty::Region<'tcx> { self.infcx.next_region_var(RegionVariableOrigin::MiscVariable(DUMMY_SP)) } pub(super) fn next_const_infer(&self, ty: Ty<'tcx>) -> ty::Const<'tcx> { self.infcx.next_const_var( ty, ConstVariableOrigin { kind: ConstVariableOriginKind::MiscVariable, span: DUMMY_SP }, ) } /// Returns a ty infer or a const infer depending on whether `kind` is a `Ty` or `Const`. /// If `kind` is an integer inference variable this will still return a ty infer var. pub(super) fn next_term_infer_of_kind(&self, kind: ty::Term<'tcx>) -> ty::Term<'tcx> { match kind.unpack() { ty::TermKind::Ty(_) => self.next_ty_infer().into(), ty::TermKind::Const(ct) => self.next_const_infer(ct.ty()).into(), } } /// Is the projection predicate is of the form `exists ::Assoc = T`. /// /// This is the case if the `term` is an inference variable in the innermost universe /// and does not occur in any other part of the predicate. pub(super) fn term_is_fully_unconstrained( &self, goal: Goal<'tcx, ty::ProjectionPredicate<'tcx>>, ) -> bool { let term_is_infer = match goal.predicate.term.unpack() { ty::TermKind::Ty(ty) => { if let &ty::Infer(ty::TyVar(vid)) = ty.kind() { match self.infcx.probe_ty_var(vid) { Ok(value) => bug!("resolved var in query: {goal:?} {value:?}"), Err(universe) => universe == self.infcx.universe(), } } else { false } } ty::TermKind::Const(ct) => { if let ty::ConstKind::Infer(ty::InferConst::Var(vid)) = ct.kind() { match self.infcx.probe_const_var(vid) { Ok(value) => bug!("resolved var in query: {goal:?} {value:?}"), Err(universe) => universe == self.infcx.universe(), } } else { false } } }; // Guard against `>::Assoc = ?0>`. struct ContainsTerm<'a, 'tcx> { term: ty::Term<'tcx>, infcx: &'a InferCtxt<'tcx>, } impl<'tcx> TypeVisitor> for ContainsTerm<'_, 'tcx> { type BreakTy = (); fn visit_ty(&mut self, t: Ty<'tcx>) -> ControlFlow { if let Some(vid) = t.ty_vid() && let ty::TermKind::Ty(term) = self.term.unpack() && let Some(term_vid) = term.ty_vid() && self.infcx.root_var(vid) == self.infcx.root_var(term_vid) { ControlFlow::Break(()) } else if t.has_non_region_infer() { t.super_visit_with(self) } else { ControlFlow::Continue(()) } } fn visit_const(&mut self, c: ty::Const<'tcx>) -> ControlFlow { if let ty::ConstKind::Infer(ty::InferConst::Var(vid)) = c.kind() && let ty::TermKind::Const(term) = self.term.unpack() && let ty::ConstKind::Infer(ty::InferConst::Var(term_vid)) = term.kind() && self.infcx.root_const_var(vid) == self.infcx.root_const_var(term_vid) { ControlFlow::Break(()) } else if c.has_non_region_infer() { c.super_visit_with(self) } else { ControlFlow::Continue(()) } } } let mut visitor = ContainsTerm { infcx: self.infcx, term: goal.predicate.term }; term_is_infer && goal.predicate.projection_ty.visit_with(&mut visitor).is_continue() && goal.param_env.visit_with(&mut visitor).is_continue() } #[instrument(level = "debug", skip(self, param_env), ret)] pub(super) fn eq>( &mut self, param_env: ty::ParamEnv<'tcx>, lhs: T, rhs: T, ) -> Result<(), NoSolution> { self.infcx .at(&ObligationCause::dummy(), param_env) .eq(DefineOpaqueTypes::No, lhs, rhs) .map(|InferOk { value: (), obligations }| { self.add_goals(obligations.into_iter().map(|o| o.into())); }) .map_err(|e| { debug!(?e, "failed to equate"); NoSolution }) } #[instrument(level = "debug", skip(self, param_env), ret)] pub(super) fn sub>( &mut self, param_env: ty::ParamEnv<'tcx>, sub: T, sup: T, ) -> Result<(), NoSolution> { self.infcx .at(&ObligationCause::dummy(), param_env) .sub(DefineOpaqueTypes::No, sub, sup) .map(|InferOk { value: (), obligations }| { self.add_goals(obligations.into_iter().map(|o| o.into())); }) .map_err(|e| { debug!(?e, "failed to subtype"); NoSolution }) } /// Equates two values returning the nested goals without adding them /// to the nested goals of the `EvalCtxt`. /// /// If possible, try using `eq` instead which automatically handles nested /// goals correctly. #[instrument(level = "trace", skip(self, param_env), ret)] pub(super) fn eq_and_get_goals>( &self, param_env: ty::ParamEnv<'tcx>, lhs: T, rhs: T, ) -> Result>>, NoSolution> { self.infcx .at(&ObligationCause::dummy(), param_env) .eq(DefineOpaqueTypes::No, lhs, rhs) .map(|InferOk { value: (), obligations }| { obligations.into_iter().map(|o| o.into()).collect() }) .map_err(|e| { debug!(?e, "failed to equate"); NoSolution }) } pub(super) fn instantiate_binder_with_infer> + Copy>( &self, value: ty::Binder<'tcx, T>, ) -> T { self.infcx.instantiate_binder_with_fresh_vars( DUMMY_SP, LateBoundRegionConversionTime::HigherRankedType, value, ) } pub(super) fn instantiate_binder_with_placeholders> + Copy>( &self, value: ty::Binder<'tcx, T>, ) -> T { self.infcx.instantiate_binder_with_placeholders(value) } pub(super) fn resolve_vars_if_possible(&self, value: T) -> T where T: TypeFoldable>, { self.infcx.resolve_vars_if_possible(value) } pub(super) fn fresh_substs_for_item(&self, def_id: DefId) -> ty::SubstsRef<'tcx> { self.infcx.fresh_substs_for_item(DUMMY_SP, def_id) } pub(super) fn translate_substs( &self, param_env: ty::ParamEnv<'tcx>, source_impl: DefId, source_substs: ty::SubstsRef<'tcx>, target_node: specialization_graph::Node, ) -> ty::SubstsRef<'tcx> { crate::traits::translate_substs( self.infcx, param_env, source_impl, source_substs, target_node, ) } pub(super) fn register_ty_outlives(&self, ty: Ty<'tcx>, lt: ty::Region<'tcx>) { self.infcx.register_region_obligation_with_cause(ty, lt, &ObligationCause::dummy()); } pub(super) fn register_region_outlives(&self, a: ty::Region<'tcx>, b: ty::Region<'tcx>) { // `b : a` ==> `a <= b` // (inlined from `InferCtxt::region_outlives_predicate`) self.infcx.sub_regions( rustc_infer::infer::SubregionOrigin::RelateRegionParamBound(DUMMY_SP), b, a, ); } /// Computes the list of goals required for `arg` to be well-formed pub(super) fn well_formed_goals( &self, param_env: ty::ParamEnv<'tcx>, arg: ty::GenericArg<'tcx>, ) -> Option>>> { crate::traits::wf::unnormalized_obligations(self.infcx, param_env, arg) .map(|obligations| obligations.into_iter().map(|obligation| obligation.into())) } pub(super) fn is_transmutable( &self, src_and_dst: rustc_transmute::Types<'tcx>, scope: Ty<'tcx>, assume: rustc_transmute::Assume, ) -> Result { use rustc_transmute::Answer; // FIXME(transmutability): This really should be returning nested goals for `Answer::If*` match rustc_transmute::TransmuteTypeEnv::new(self.infcx).is_transmutable( ObligationCause::dummy(), src_and_dst, scope, assume, ) { Answer::Yes => Ok(Certainty::Yes), Answer::No(_) | Answer::If(_) => Err(NoSolution), } } pub(super) fn can_define_opaque_ty(&mut self, def_id: LocalDefId) -> bool { self.infcx.opaque_type_origin(def_id).is_some() } pub(super) fn insert_hidden_type( &mut self, opaque_type_key: OpaqueTypeKey<'tcx>, param_env: ty::ParamEnv<'tcx>, hidden_ty: Ty<'tcx>, ) -> Result<(), NoSolution> { let mut obligations = Vec::new(); self.infcx.insert_hidden_type( opaque_type_key, &ObligationCause::dummy(), param_env, hidden_ty, true, &mut obligations, )?; self.add_goals(obligations.into_iter().map(|o| o.into())); Ok(()) } pub(super) fn add_item_bounds_for_hidden_type( &mut self, opaque_def_id: DefId, opaque_substs: ty::SubstsRef<'tcx>, param_env: ty::ParamEnv<'tcx>, hidden_ty: Ty<'tcx>, ) { let mut obligations = Vec::new(); self.infcx.add_item_bounds_for_hidden_type( opaque_def_id, opaque_substs, ObligationCause::dummy(), param_env, hidden_ty, &mut obligations, ); self.add_goals(obligations.into_iter().map(|o| o.into())); } // Do something for each opaque/hidden pair defined with `def_id` in the // current inference context. pub(super) fn unify_existing_opaque_tys( &mut self, param_env: ty::ParamEnv<'tcx>, key: ty::OpaqueTypeKey<'tcx>, ty: Ty<'tcx>, ) -> Vec> { // FIXME: Super inefficient to be cloning this... let opaques = self.infcx.clone_opaque_types_for_query_response(); let mut values = vec![]; for (candidate_key, candidate_ty) in opaques { if candidate_key.def_id != key.def_id { continue; } values.extend( self.probe(|r| CandidateKind::Candidate { name: "opaque type storage".into(), result: *r, }) .enter(|ecx| { for (a, b) in std::iter::zip(candidate_key.substs, key.substs) { ecx.eq(param_env, a, b)?; } ecx.eq(param_env, candidate_ty, ty)?; ecx.add_item_bounds_for_hidden_type( candidate_key.def_id.to_def_id(), candidate_key.substs, param_env, candidate_ty, ); ecx.evaluate_added_goals_and_make_canonical_response(Certainty::Yes) }), ); } values } // Try to evaluate a const, or return `None` if the const is too generic. // This doesn't mean the const isn't evaluatable, though, and should be treated // as an ambiguity rather than no-solution. pub(super) fn try_const_eval_resolve( &self, param_env: ty::ParamEnv<'tcx>, unevaluated: ty::UnevaluatedConst<'tcx>, ty: Ty<'tcx>, ) -> Option> { use rustc_middle::mir::interpret::ErrorHandled; match self.infcx.try_const_eval_resolve(param_env, unevaluated, ty, None) { Ok(ct) => Some(ct), Err(ErrorHandled::Reported(e)) => Some(self.tcx().const_error(ty, e.into())), Err(ErrorHandled::TooGeneric) => None, } } }