//! Support code for rustdoc and external tools . You really don't //! want to be using this unless you need to. use super::*; use std::collections::hash_map::Entry; use std::collections::VecDeque; use crate::infer::region_constraints::{Constraint, RegionConstraintData}; use crate::infer::InferCtxt; use rustc_data_structures::fx::{FxHashMap, FxHashSet}; use crate::ty::fold::TypeFolder; use crate::ty::{Region, RegionVid}; // FIXME(twk): this is obviously not nice to duplicate like that #[derive(Eq, PartialEq, Hash, Copy, Clone, Debug)] pub enum RegionTarget<'tcx> { Region(Region<'tcx>), RegionVid(RegionVid), } #[derive(Default, Debug, Clone)] pub struct RegionDeps<'tcx> { larger: FxHashSet>, smaller: FxHashSet>, } pub enum AutoTraitResult { ExplicitImpl, PositiveImpl(A), NegativeImpl, } impl AutoTraitResult { fn is_auto(&self) -> bool { match *self { AutoTraitResult::PositiveImpl(_) | AutoTraitResult::NegativeImpl => true, _ => false, } } } pub struct AutoTraitInfo<'cx> { pub full_user_env: ty::ParamEnv<'cx>, pub region_data: RegionConstraintData<'cx>, pub names_map: FxHashSet, pub vid_to_region: FxHashMap>, } pub struct AutoTraitFinder<'a, 'tcx: 'a> { tcx: TyCtxt<'a, 'tcx, 'tcx>, } impl<'a, 'tcx> AutoTraitFinder<'a, 'tcx> { pub fn new(tcx: TyCtxt<'a, 'tcx, 'tcx>) -> Self { AutoTraitFinder { tcx } } /// Makes a best effort to determine whether and under which conditions an auto trait is /// implemented for a type. For example, if you have /// /// ``` /// struct Foo { data: Box } /// ``` /// /// then this might return that Foo: Send if T: Send (encoded in the AutoTraitResult type). /// The analysis attempts to account for custom impls as well as other complex cases. This /// result is intended for use by rustdoc and other such consumers. /// /// (Note that due to the coinductive nature of Send, the full and correct result is actually /// quite simple to generate. That is, when a type has no custom impl, it is Send iff its field /// types are all Send. So, in our example, we might have that Foo: Send if Box: Send. /// But this is often not the best way to present to the user.) /// /// Warning: The API should be considered highly unstable, and it may be refactored or removed /// in the future. pub fn find_auto_trait_generics( &self, did: DefId, trait_did: DefId, generics: &ty::Generics, auto_trait_callback: impl for<'i> Fn(&InferCtxt<'_, 'tcx, 'i>, AutoTraitInfo<'i>) -> A, ) -> AutoTraitResult { let tcx = self.tcx; let ty = self.tcx.type_of(did); let orig_params = tcx.param_env(did); let trait_ref = ty::TraitRef { def_id: trait_did, substs: tcx.mk_substs_trait(ty, &[]), }; let trait_pred = ty::Binder::bind(trait_ref); let bail_out = tcx.infer_ctxt().enter(|infcx| { let mut selcx = SelectionContext::with_negative(&infcx, true); let result = selcx.select(&Obligation::new( ObligationCause::dummy(), orig_params, trait_pred.to_poly_trait_predicate(), )); match result { Ok(Some(Vtable::VtableImpl(_))) => { debug!( "find_auto_trait_generics(did={:?}, trait_did={:?}, generics={:?}): \ manual impl found, bailing out", did, trait_did, generics ); true } _ => false } }); // If an explicit impl exists, it always takes priority over an auto impl if bail_out { return AutoTraitResult::ExplicitImpl; } return tcx.infer_ctxt().enter(|mut infcx| { let mut fresh_preds = FxHashSet::default(); // Due to the way projections are handled by SelectionContext, we need to run // evaluate_predicates twice: once on the original param env, and once on the result of // the first evaluate_predicates call. // // The problem is this: most of rustc, including SelectionContext and traits::project, // are designed to work with a concrete usage of a type (e.g., Vec // fn() { Vec }. This information will generally never change - given // the 'T' in fn() { ... }, we'll never know anything else about 'T'. // If we're unable to prove that 'T' implements a particular trait, we're done - // there's nothing left to do but error out. // // However, synthesizing an auto trait impl works differently. Here, we start out with // a set of initial conditions - the ParamEnv of the struct/enum/union we're dealing // with - and progressively discover the conditions we need to fulfill for it to // implement a certain auto trait. This ends up breaking two assumptions made by trait // selection and projection: // // * We can always cache the result of a particular trait selection for the lifetime of // an InfCtxt // * Given a projection bound such as '::SomeItem = K', if 'T: // SomeTrait' doesn't hold, then we don't need to care about the 'SomeItem = K' // // We fix the first assumption by manually clearing out all of the InferCtxt's caches // in between calls to SelectionContext.select. This allows us to keep all of the // intermediate types we create bound to the 'tcx lifetime, rather than needing to lift // them between calls. // // We fix the second assumption by reprocessing the result of our first call to // evaluate_predicates. Using the example of '::SomeItem = K', our first // pass will pick up 'T: SomeTrait', but not 'SomeItem = K'. On our second pass, // traits::project will see that 'T: SomeTrait' is in our ParamEnv, allowing // SelectionContext to return it back to us. let (new_env, user_env) = match self.evaluate_predicates( &mut infcx, did, trait_did, ty, orig_params.clone(), orig_params, &mut fresh_preds, false, ) { Some(e) => e, None => return AutoTraitResult::NegativeImpl, }; let (full_env, full_user_env) = self.evaluate_predicates( &mut infcx, did, trait_did, ty, new_env.clone(), user_env, &mut fresh_preds, true, ).unwrap_or_else(|| { panic!( "Failed to fully process: {:?} {:?} {:?}", ty, trait_did, orig_params ) }); debug!( "find_auto_trait_generics(did={:?}, trait_did={:?}, generics={:?}): fulfilling \ with {:?}", did, trait_did, generics, full_env ); infcx.clear_caches(); // At this point, we already have all of the bounds we need. FulfillmentContext is used // to store all of the necessary region/lifetime bounds in the InferContext, as well as // an additional sanity check. let mut fulfill = FulfillmentContext::new(); fulfill.register_bound( &infcx, full_env, ty, trait_did, ObligationCause::misc(DUMMY_SP, hir::DUMMY_HIR_ID), ); fulfill.select_all_or_error(&infcx).unwrap_or_else(|e| { panic!( "Unable to fulfill trait {:?} for '{:?}': {:?}", trait_did, ty, e ) }); let names_map: FxHashSet = generics .params .iter() .filter_map(|param| match param.kind { ty::GenericParamDefKind::Lifetime => Some(param.name.to_string()), _ => None, }) .collect(); let body_id_map: FxHashMap<_, _> = infcx .region_obligations .borrow() .iter() .map(|&(id, _)| (id, vec![])) .collect(); infcx.process_registered_region_obligations(&body_id_map, None, full_env.clone()); let region_data = infcx .borrow_region_constraints() .region_constraint_data() .clone(); let vid_to_region = self.map_vid_to_region(®ion_data); let info = AutoTraitInfo { full_user_env, region_data, names_map, vid_to_region, }; return AutoTraitResult::PositiveImpl(auto_trait_callback(&infcx, info)); }); } } impl<'a, 'tcx> AutoTraitFinder<'a, 'tcx> { // The core logic responsible for computing the bounds for our synthesized impl. // // To calculate the bounds, we call SelectionContext.select in a loop. Like FulfillmentContext, // we recursively select the nested obligations of predicates we encounter. However, whenever we // encounter an UnimplementedError involving a type parameter, we add it to our ParamEnv. Since // our goal is to determine when a particular type implements an auto trait, Unimplemented // errors tell us what conditions need to be met. // // This method ends up working somewhat similarly to FulfillmentContext, but with a few key // differences. FulfillmentContext works under the assumption that it's dealing with concrete // user code. According, it considers all possible ways that a Predicate could be met - which // isn't always what we want for a synthesized impl. For example, given the predicate 'T: // Iterator', FulfillmentContext can end up reporting an Unimplemented error for T: // IntoIterator - since there's an implementation of Iteratpr where T: IntoIterator, // FulfillmentContext will drive SelectionContext to consider that impl before giving up. If we // were to rely on FulfillmentContext's decision, we might end up synthesizing an impl like // this: // 'impl Send for Foo where T: IntoIterator' // // While it might be technically true that Foo implements Send where T: IntoIterator, // the bound is overly restrictive - it's really only necessary that T: Iterator. // // For this reason, evaluate_predicates handles predicates with type variables specially. When // we encounter an Unimplemented error for a bound such as 'T: Iterator', we immediately add it // to our ParamEnv, and add it to our stack for recursive evaluation. When we later select it, // we'll pick up any nested bounds, without ever inferring that 'T: IntoIterator' needs to // hold. // // One additional consideration is supertrait bounds. Normally, a ParamEnv is only ever // constructed once for a given type. As part of the construction process, the ParamEnv will // have any supertrait bounds normalized - e.g., if we have a type 'struct Foo', the // ParamEnv will contain 'T: Copy' and 'T: Clone', since 'Copy: Clone'. When we construct our // own ParamEnv, we need to do this ourselves, through traits::elaborate_predicates, or else // SelectionContext will choke on the missing predicates. However, this should never show up in // the final synthesized generics: we don't want our generated docs page to contain something // like 'T: Copy + Clone', as that's redundant. Therefore, we keep track of a separate // 'user_env', which only holds the predicates that will actually be displayed to the user. pub fn evaluate_predicates<'b, 'gcx, 'c>( &self, infcx: &InferCtxt<'b, 'tcx, 'c>, ty_did: DefId, trait_did: DefId, ty: Ty<'c>, param_env: ty::ParamEnv<'c>, user_env: ty::ParamEnv<'c>, fresh_preds: &mut FxHashSet>, only_projections: bool, ) -> Option<(ty::ParamEnv<'c>, ty::ParamEnv<'c>)> { let tcx = infcx.tcx; let mut select = SelectionContext::with_negative(&infcx, true); let mut already_visited = FxHashSet::default(); let mut predicates = VecDeque::new(); predicates.push_back(ty::Binder::bind(ty::TraitPredicate { trait_ref: ty::TraitRef { def_id: trait_did, substs: infcx.tcx.mk_substs_trait(ty, &[]), }, })); let mut computed_preds: FxHashSet<_> = param_env.caller_bounds.iter().cloned().collect(); let mut user_computed_preds: FxHashSet<_> = user_env.caller_bounds.iter().cloned().collect(); let mut new_env = param_env.clone(); let dummy_cause = ObligationCause::misc(DUMMY_SP, hir::DUMMY_HIR_ID); while let Some(pred) = predicates.pop_front() { infcx.clear_caches(); if !already_visited.insert(pred.clone()) { continue; } // Call infcx.resolve_type_vars_if_possible to see if we can // get rid of any inference variables. let obligation = infcx.resolve_type_vars_if_possible( &Obligation::new(dummy_cause.clone(), new_env, pred) ); let result = select.select(&obligation); match &result { &Ok(Some(ref vtable)) => { // If we see an explicit negative impl (e.g., 'impl !Send for MyStruct'), // we immediately bail out, since it's impossible for us to continue. match vtable { Vtable::VtableImpl(VtableImplData { impl_def_id, .. }) => { // Blame tidy for the weird bracket placement if infcx.tcx.impl_polarity(*impl_def_id) == hir::ImplPolarity::Negative { debug!("evaluate_nested_obligations: Found explicit negative impl\ {:?}, bailing out", impl_def_id); return None; } }, _ => {} } let obligations = vtable.clone().nested_obligations().into_iter(); if !self.evaluate_nested_obligations( ty, obligations, &mut user_computed_preds, fresh_preds, &mut predicates, &mut select, only_projections, ) { return None; } } &Ok(None) => {} &Err(SelectionError::Unimplemented) => { if self.is_param_no_infer(pred.skip_binder().trait_ref.substs) { already_visited.remove(&pred); self.add_user_pred( &mut user_computed_preds, ty::Predicate::Trait(pred.clone()), ); predicates.push_back(pred); } else { debug!( "evaluate_nested_obligations: Unimplemented found, bailing: \ {:?} {:?} {:?}", ty, pred, pred.skip_binder().trait_ref.substs ); return None; } } _ => panic!("Unexpected error for '{:?}': {:?}", ty, result), }; computed_preds.extend(user_computed_preds.iter().cloned()); let normalized_preds = elaborate_predicates(tcx, computed_preds.clone().into_iter().collect()); new_env = ty::ParamEnv::new( tcx.mk_predicates(normalized_preds), param_env.reveal, None ); } let final_user_env = ty::ParamEnv::new( tcx.mk_predicates(user_computed_preds.into_iter()), user_env.reveal, None ); debug!( "evaluate_nested_obligations(ty_did={:?}, trait_did={:?}): succeeded with '{:?}' \ '{:?}'", ty_did, trait_did, new_env, final_user_env ); return Some((new_env, final_user_env)); } // This method is designed to work around the following issue: // When we compute auto trait bounds, we repeatedly call SelectionContext.select, // progressively building a ParamEnv based on the results we get. // However, our usage of SelectionContext differs from its normal use within the compiler, // in that we capture and re-reprocess predicates from Unimplemented errors. // // This can lead to a corner case when dealing with region parameters. // During our selection loop in evaluate_predicates, we might end up with // two trait predicates that differ only in their region parameters: // one containing a HRTB lifetime parameter, and one containing a 'normal' // lifetime parameter. For example: // // T as MyTrait<'a> // T as MyTrait<'static> // // If we put both of these predicates in our computed ParamEnv, we'll // confuse SelectionContext, since it will (correctly) view both as being applicable. // // To solve this, we pick the 'more strict' lifetime bound - i.e., the HRTB // Our end goal is to generate a user-visible description of the conditions // under which a type implements an auto trait. A trait predicate involving // a HRTB means that the type needs to work with any choice of lifetime, // not just one specific lifetime (e.g., 'static). fn add_user_pred<'c>( &self, user_computed_preds: &mut FxHashSet>, new_pred: ty::Predicate<'c>, ) { let mut should_add_new = true; user_computed_preds.retain(|&old_pred| { match (&new_pred, old_pred) { (&ty::Predicate::Trait(new_trait), ty::Predicate::Trait(old_trait)) => { if new_trait.def_id() == old_trait.def_id() { let new_substs = new_trait.skip_binder().trait_ref.substs; let old_substs = old_trait.skip_binder().trait_ref.substs; if !new_substs.types().eq(old_substs.types()) { // We can't compare lifetimes if the types are different, // so skip checking old_pred return true; } for (new_region, old_region) in new_substs.regions().zip(old_substs.regions()) { match (new_region, old_region) { // If both predicates have an 'ReLateBound' (a HRTB) in the // same spot, we do nothing ( ty::RegionKind::ReLateBound(_, _), ty::RegionKind::ReLateBound(_, _), ) => {} (ty::RegionKind::ReLateBound(_, _), _) | (_, ty::RegionKind::ReVar(_)) => { // One of these is true: // The new predicate has a HRTB in a spot where the old // predicate does not (if they both had a HRTB, the previous // match arm would have executed). A HRBT is a 'stricter' // bound than anything else, so we want to keep the newer // predicate (with the HRBT) in place of the old predicate. // // OR // // The old predicate has a region variable where the new // predicate has some other kind of region. An region // variable isn't something we can actually display to a user, // so we choose ther new predicate (which doesn't have a region // varaible). // // In both cases, we want to remove the old predicate, // from user_computed_preds, and replace it with the new // one. Having both the old and the new // predicate in a ParamEnv would confuse SelectionContext // // We're currently in the predicate passed to 'retain', // so we return 'false' to remove the old predicate from // user_computed_preds return false; } (_, ty::RegionKind::ReLateBound(_, _)) | (ty::RegionKind::ReVar(_), _) => { // This is the opposite situation as the previous arm. // One of these is true: // // The old predicate has a HRTB lifetime in a place where the // new predicate does not. // // OR // // The new predicate has a region variable where the old // predicate has some other type of region. // // We want to leave the old // predicate in user_computed_preds, and skip adding // new_pred to user_computed_params. should_add_new = false }, _ => {} } } } } _ => {} } return true; }); if should_add_new { user_computed_preds.insert(new_pred); } } pub fn region_name(&self, region: Region<'_>) -> Option { match region { &ty::ReEarlyBound(r) => Some(r.name.to_string()), _ => None, } } pub fn get_lifetime(&self, region: Region<'_>, names_map: &FxHashMap) -> String { self.region_name(region) .map(|name| names_map.get(&name).unwrap_or_else(|| panic!("Missing lifetime with name {:?} for {:?}", name, region) ) ) .cloned() .unwrap_or_else(|| "'static".to_owned()) } // This is very similar to handle_lifetimes. However, instead of matching ty::Region's // to each other, we match ty::RegionVid's to ty::Region's pub fn map_vid_to_region<'cx>( &self, regions: &RegionConstraintData<'cx>, ) -> FxHashMap> { let mut vid_map: FxHashMap, RegionDeps<'cx>> = FxHashMap::default(); let mut finished_map = FxHashMap::default(); for constraint in regions.constraints.keys() { match constraint { &Constraint::VarSubVar(r1, r2) => { { let deps1 = vid_map.entry(RegionTarget::RegionVid(r1)).or_default(); deps1.larger.insert(RegionTarget::RegionVid(r2)); } let deps2 = vid_map.entry(RegionTarget::RegionVid(r2)).or_default(); deps2.smaller.insert(RegionTarget::RegionVid(r1)); } &Constraint::RegSubVar(region, vid) => { { let deps1 = vid_map.entry(RegionTarget::Region(region)).or_default(); deps1.larger.insert(RegionTarget::RegionVid(vid)); } let deps2 = vid_map.entry(RegionTarget::RegionVid(vid)).or_default(); deps2.smaller.insert(RegionTarget::Region(region)); } &Constraint::VarSubReg(vid, region) => { finished_map.insert(vid, region); } &Constraint::RegSubReg(r1, r2) => { { let deps1 = vid_map.entry(RegionTarget::Region(r1)).or_default(); deps1.larger.insert(RegionTarget::Region(r2)); } let deps2 = vid_map.entry(RegionTarget::Region(r2)).or_default(); deps2.smaller.insert(RegionTarget::Region(r1)); } } } while !vid_map.is_empty() { let target = vid_map.keys().next().expect("Keys somehow empty").clone(); let deps = vid_map.remove(&target).expect("Entry somehow missing"); for smaller in deps.smaller.iter() { for larger in deps.larger.iter() { match (smaller, larger) { (&RegionTarget::Region(_), &RegionTarget::Region(_)) => { if let Entry::Occupied(v) = vid_map.entry(*smaller) { let smaller_deps = v.into_mut(); smaller_deps.larger.insert(*larger); smaller_deps.larger.remove(&target); } if let Entry::Occupied(v) = vid_map.entry(*larger) { let larger_deps = v.into_mut(); larger_deps.smaller.insert(*smaller); larger_deps.smaller.remove(&target); } } (&RegionTarget::RegionVid(v1), &RegionTarget::Region(r1)) => { finished_map.insert(v1, r1); } (&RegionTarget::Region(_), &RegionTarget::RegionVid(_)) => { // Do nothing - we don't care about regions that are smaller than vids } (&RegionTarget::RegionVid(_), &RegionTarget::RegionVid(_)) => { if let Entry::Occupied(v) = vid_map.entry(*smaller) { let smaller_deps = v.into_mut(); smaller_deps.larger.insert(*larger); smaller_deps.larger.remove(&target); } if let Entry::Occupied(v) = vid_map.entry(*larger) { let larger_deps = v.into_mut(); larger_deps.smaller.insert(*smaller); larger_deps.smaller.remove(&target); } } } } } } finished_map } fn is_param_no_infer(&self, substs: SubstsRef<'_>) -> bool { return self.is_of_param(substs.type_at(0)) && !substs.types().any(|t| t.has_infer_types()); } pub fn is_of_param(&self, ty: Ty<'_>) -> bool { return match ty.sty { ty::Param(_) => true, ty::Projection(p) => self.is_of_param(p.self_ty()), _ => false, }; } fn is_self_referential_projection(&self, p: ty::PolyProjectionPredicate<'_>) -> bool { match p.ty().skip_binder().sty { ty::Projection(proj) if proj == p.skip_binder().projection_ty => { true }, _ => false } } pub fn evaluate_nested_obligations< 'b, 'c, 'd, 'cx, T: Iterator>>, >( &self, ty: Ty<'_>, nested: T, computed_preds: &'b mut FxHashSet>, fresh_preds: &'b mut FxHashSet>, predicates: &'b mut VecDeque>, select: &mut SelectionContext<'c, 'd, 'cx>, only_projections: bool, ) -> bool { let dummy_cause = ObligationCause::misc(DUMMY_SP, hir::DUMMY_HIR_ID); for (obligation, mut predicate) in nested .map(|o| (o.clone(), o.predicate.clone())) { let is_new_pred = fresh_preds.insert(self.clean_pred(select.infcx(), predicate.clone())); // Resolve any inference variables that we can, to help selection succeed predicate = select.infcx().resolve_type_vars_if_possible(&predicate); // We only add a predicate as a user-displayable bound if // it involves a generic parameter, and doesn't contain // any inference variables. // // Displaying a bound involving a concrete type (instead of a generic // parameter) would be pointless, since it's always true // (e.g. u8: Copy) // Displaying an inference variable is impossible, since they're // an internal compiler detail without a defined visual representation // // We check this by calling is_of_param on the relevant types // from the various possible predicates match &predicate { &ty::Predicate::Trait(ref p) => { if self.is_param_no_infer(p.skip_binder().trait_ref.substs) && !only_projections && is_new_pred { self.add_user_pred(computed_preds, predicate); } predicates.push_back(p.clone()); } &ty::Predicate::Projection(p) => { debug!("evaluate_nested_obligations: examining projection predicate {:?}", predicate); // As described above, we only want to display // bounds which include a generic parameter but don't include // an inference variable. // Additionally, we check if we've seen this predicate before, // to avoid rendering duplicate bounds to the user. if self.is_param_no_infer(p.skip_binder().projection_ty.substs) && !p.ty().skip_binder().is_ty_infer() && is_new_pred { debug!("evaluate_nested_obligations: adding projection predicate\ to computed_preds: {:?}", predicate); // Under unusual circumstances, we can end up with a self-refeential // projection predicate. For example: // ::Value == ::Value // Not only is displaying this to the user pointless, // having it in the ParamEnv will cause an issue if we try to call // poly_project_and_unify_type on the predicate, since this kind of // predicate will normally never end up in a ParamEnv. // // For these reasons, we ignore these weird predicates, // ensuring that we're able to properly synthesize an auto trait impl if self.is_self_referential_projection(p) { debug!("evaluate_nested_obligations: encountered a projection predicate equating a type with itself! Skipping"); } else { self.add_user_pred(computed_preds, predicate); } } // We can only call poly_project_and_unify_type when our predicate's // Ty contains an inference variable - otherwise, there won't be anything to // unify if p.ty().skip_binder().has_infer_types() { debug!("Projecting and unifying projection predicate {:?}", predicate); match poly_project_and_unify_type(select, &obligation.with(p.clone())) { Err(e) => { debug!( "evaluate_nested_obligations: Unable to unify predicate \ '{:?}' '{:?}', bailing out", ty, e ); return false; } Ok(Some(v)) => { if !self.evaluate_nested_obligations( ty, v.clone().iter().cloned(), computed_preds, fresh_preds, predicates, select, only_projections, ) { return false; } } Ok(None) => { panic!("Unexpected result when selecting {:?} {:?}", ty, obligation) } } } } &ty::Predicate::RegionOutlives(ref binder) => { if select .infcx() .region_outlives_predicate(&dummy_cause, binder) .is_err() { return false; } } &ty::Predicate::TypeOutlives(ref binder) => { match ( binder.no_bound_vars(), binder.map_bound_ref(|pred| pred.0).no_bound_vars(), ) { (None, Some(t_a)) => { select.infcx().register_region_obligation_with_cause( t_a, select.infcx().tcx.types.re_static, &dummy_cause, ); } (Some(ty::OutlivesPredicate(t_a, r_b)), _) => { select.infcx().register_region_obligation_with_cause( t_a, r_b, &dummy_cause, ); } _ => {} }; } _ => panic!("Unexpected predicate {:?} {:?}", ty, predicate), }; } return true; } pub fn clean_pred<'c, 'd, 'cx>( &self, infcx: &InferCtxt<'c, 'd, 'cx>, p: ty::Predicate<'cx>, ) -> ty::Predicate<'cx> { infcx.freshen(p) } } // Replaces all ReVars in a type with ty::Region's, using the provided map pub struct RegionReplacer<'a, 'gcx: 'a + 'tcx, 'tcx: 'a> { vid_to_region: &'a FxHashMap>, tcx: TyCtxt<'a, 'gcx, 'tcx>, } impl<'a, 'gcx, 'tcx> TypeFolder<'gcx, 'tcx> for RegionReplacer<'a, 'gcx, 'tcx> { fn tcx<'b>(&'b self) -> TyCtxt<'b, 'gcx, 'tcx> { self.tcx } fn fold_region(&mut self, r: ty::Region<'tcx>) -> ty::Region<'tcx> { (match r { &ty::ReVar(vid) => self.vid_to_region.get(&vid).cloned(), _ => None, }).unwrap_or_else(|| r.super_fold_with(self)) } }