//! Generalized type folding mechanism. The setup is a bit convoluted //! but allows for convenient usage. Let T be an instance of some //! "foldable type" (one which implements `TypeFoldable`) and F be an //! instance of a "folder" (a type which implements `TypeFolder`). Then //! the setup is intended to be: //! //! T.fold_with(F) --calls--> F.fold_T(T) --calls--> T.super_fold_with(F) //! //! This way, when you define a new folder F, you can override //! `fold_T()` to customize the behavior, and invoke `T.super_fold_with()` //! to get the original behavior. Meanwhile, to actually fold //! something, you can just write `T.fold_with(F)`, which is //! convenient. (Note that `fold_with` will also transparently handle //! things like a `Vec` where T is foldable and so on.) //! //! In this ideal setup, the only function that actually *does* //! anything is `T.super_fold_with()`, which traverses the type `T`. //! Moreover, `T.super_fold_with()` should only ever call `T.fold_with()`. //! //! In some cases, we follow a degenerate pattern where we do not have //! a `fold_T` method. Instead, `T.fold_with` traverses the structure directly. //! This is suboptimal because the behavior cannot be overridden, but it's //! much less work to implement. If you ever *do* need an override that //! doesn't exist, it's not hard to convert the degenerate pattern into the //! proper thing. //! //! A `TypeFoldable` T can also be visited by a `TypeVisitor` V using similar setup: //! //! T.visit_with(V) --calls--> V.visit_T(T) --calls--> T.super_visit_with(V). //! //! These methods return true to indicate that the visitor has found what it is //! looking for, and does not need to visit anything else. use crate::ty::{self, flags::FlagComputation, Binder, Ty, TyCtxt, TypeFlags}; use rustc_hir as hir; use rustc_hir::def_id::DefId; use rustc_data_structures::fx::FxHashSet; use std::collections::BTreeMap; use std::fmt; use std::ops::ControlFlow; /// This trait is implemented for every type that can be folded. /// Basically, every type that has a corresponding method in `TypeFolder`. /// /// To implement this conveniently, use the derive macro located in librustc_macros. pub trait TypeFoldable<'tcx>: fmt::Debug + Clone { fn super_fold_with>(self, folder: &mut F) -> Self; fn fold_with>(self, folder: &mut F) -> Self { self.super_fold_with(folder) } fn super_visit_with>(&self, visitor: &mut V) -> ControlFlow; fn visit_with>(&self, visitor: &mut V) -> ControlFlow { self.super_visit_with(visitor) } /// Returns `true` if `self` has any late-bound regions that are either /// bound by `binder` or bound by some binder outside of `binder`. /// If `binder` is `ty::INNERMOST`, this indicates whether /// there are any late-bound regions that appear free. fn has_vars_bound_at_or_above(&self, binder: ty::DebruijnIndex) -> bool { self.visit_with(&mut HasEscapingVarsVisitor { outer_index: binder }).is_break() } /// Returns `true` if this `self` has any regions that escape `binder` (and /// hence are not bound by it). fn has_vars_bound_above(&self, binder: ty::DebruijnIndex) -> bool { self.has_vars_bound_at_or_above(binder.shifted_in(1)) } fn has_escaping_bound_vars(&self) -> bool { self.has_vars_bound_at_or_above(ty::INNERMOST) } fn has_type_flags(&self, flags: TypeFlags) -> bool { self.visit_with(&mut HasTypeFlagsVisitor { flags }).break_value() == Some(FoundFlags) } fn has_projections(&self) -> bool { self.has_type_flags(TypeFlags::HAS_PROJECTION) } fn has_opaque_types(&self) -> bool { self.has_type_flags(TypeFlags::HAS_TY_OPAQUE) } fn references_error(&self) -> bool { self.has_type_flags(TypeFlags::HAS_ERROR) } fn has_param_types_or_consts(&self) -> bool { self.has_type_flags(TypeFlags::HAS_TY_PARAM | TypeFlags::HAS_CT_PARAM) } fn has_infer_regions(&self) -> bool { self.has_type_flags(TypeFlags::HAS_RE_INFER) } fn has_infer_types(&self) -> bool { self.has_type_flags(TypeFlags::HAS_TY_INFER) } fn has_infer_types_or_consts(&self) -> bool { self.has_type_flags(TypeFlags::HAS_TY_INFER | TypeFlags::HAS_CT_INFER) } fn needs_infer(&self) -> bool { self.has_type_flags(TypeFlags::NEEDS_INFER) } fn has_placeholders(&self) -> bool { self.has_type_flags( TypeFlags::HAS_RE_PLACEHOLDER | TypeFlags::HAS_TY_PLACEHOLDER | TypeFlags::HAS_CT_PLACEHOLDER, ) } fn needs_subst(&self) -> bool { self.has_type_flags(TypeFlags::NEEDS_SUBST) } /// "Free" regions in this context means that it has any region /// that is not (a) erased or (b) late-bound. fn has_free_regions(&self) -> bool { self.has_type_flags(TypeFlags::HAS_FREE_REGIONS) } fn has_erased_regions(&self) -> bool { self.has_type_flags(TypeFlags::HAS_RE_ERASED) } /// True if there are any un-erased free regions. fn has_erasable_regions(&self) -> bool { self.has_type_flags(TypeFlags::HAS_FREE_REGIONS) } /// Indicates whether this value references only 'global' /// generic parameters that are the same regardless of what fn we are /// in. This is used for caching. fn is_global(&self) -> bool { !self.has_type_flags(TypeFlags::HAS_FREE_LOCAL_NAMES) } /// True if there are any late-bound regions fn has_late_bound_regions(&self) -> bool { self.has_type_flags(TypeFlags::HAS_RE_LATE_BOUND) } /// Indicates whether this value still has parameters/placeholders/inference variables /// which could be replaced later, in a way that would change the results of `impl` /// specialization. fn still_further_specializable(&self) -> bool { self.has_type_flags(TypeFlags::STILL_FURTHER_SPECIALIZABLE) } } impl TypeFoldable<'tcx> for hir::Constness { fn super_fold_with>(self, _: &mut F) -> Self { self } fn super_visit_with>(&self, _: &mut V) -> ControlFlow { ControlFlow::CONTINUE } } /// The `TypeFolder` trait defines the actual *folding*. There is a /// method defined for every foldable type. Each of these has a /// default implementation that does an "identity" fold. Within each /// identity fold, it should invoke `foo.fold_with(self)` to fold each /// sub-item. pub trait TypeFolder<'tcx>: Sized { fn tcx<'a>(&'a self) -> TyCtxt<'tcx>; fn fold_binder(&mut self, t: Binder) -> Binder where T: TypeFoldable<'tcx>, { t.super_fold_with(self) } fn fold_ty(&mut self, t: Ty<'tcx>) -> Ty<'tcx> { t.super_fold_with(self) } fn fold_region(&mut self, r: ty::Region<'tcx>) -> ty::Region<'tcx> { r.super_fold_with(self) } fn fold_const(&mut self, c: &'tcx ty::Const<'tcx>) -> &'tcx ty::Const<'tcx> { c.super_fold_with(self) } } pub trait TypeVisitor<'tcx>: Sized { type BreakTy = !; fn visit_binder>(&mut self, t: &Binder) -> ControlFlow { t.super_visit_with(self) } fn visit_ty(&mut self, t: Ty<'tcx>) -> ControlFlow { t.super_visit_with(self) } fn visit_region(&mut self, r: ty::Region<'tcx>) -> ControlFlow { r.super_visit_with(self) } fn visit_const(&mut self, c: &'tcx ty::Const<'tcx>) -> ControlFlow { c.super_visit_with(self) } fn visit_predicate(&mut self, p: ty::Predicate<'tcx>) -> ControlFlow { p.super_visit_with(self) } } /////////////////////////////////////////////////////////////////////////// // Some sample folders pub struct BottomUpFolder<'tcx, F, G, H> where F: FnMut(Ty<'tcx>) -> Ty<'tcx>, G: FnMut(ty::Region<'tcx>) -> ty::Region<'tcx>, H: FnMut(&'tcx ty::Const<'tcx>) -> &'tcx ty::Const<'tcx>, { pub tcx: TyCtxt<'tcx>, pub ty_op: F, pub lt_op: G, pub ct_op: H, } impl<'tcx, F, G, H> TypeFolder<'tcx> for BottomUpFolder<'tcx, F, G, H> where F: FnMut(Ty<'tcx>) -> Ty<'tcx>, G: FnMut(ty::Region<'tcx>) -> ty::Region<'tcx>, H: FnMut(&'tcx ty::Const<'tcx>) -> &'tcx ty::Const<'tcx>, { fn tcx<'b>(&'b self) -> TyCtxt<'tcx> { self.tcx } fn fold_ty(&mut self, ty: Ty<'tcx>) -> Ty<'tcx> { let t = ty.super_fold_with(self); (self.ty_op)(t) } fn fold_region(&mut self, r: ty::Region<'tcx>) -> ty::Region<'tcx> { let r = r.super_fold_with(self); (self.lt_op)(r) } fn fold_const(&mut self, ct: &'tcx ty::Const<'tcx>) -> &'tcx ty::Const<'tcx> { let ct = ct.super_fold_with(self); (self.ct_op)(ct) } } /////////////////////////////////////////////////////////////////////////// // Region folder impl<'tcx> TyCtxt<'tcx> { /// Folds the escaping and free regions in `value` using `f`, and /// sets `skipped_regions` to true if any late-bound region was found /// and skipped. pub fn fold_regions( self, value: T, skipped_regions: &mut bool, mut f: impl FnMut(ty::Region<'tcx>, ty::DebruijnIndex) -> ty::Region<'tcx>, ) -> T where T: TypeFoldable<'tcx>, { value.fold_with(&mut RegionFolder::new(self, skipped_regions, &mut f)) } /// Invoke `callback` on every region appearing free in `value`. pub fn for_each_free_region( self, value: &impl TypeFoldable<'tcx>, mut callback: impl FnMut(ty::Region<'tcx>), ) { self.any_free_region_meets(value, |r| { callback(r); false }); } /// Returns `true` if `callback` returns true for every region appearing free in `value`. pub fn all_free_regions_meet( self, value: &impl TypeFoldable<'tcx>, mut callback: impl FnMut(ty::Region<'tcx>) -> bool, ) -> bool { !self.any_free_region_meets(value, |r| !callback(r)) } /// Returns `true` if `callback` returns true for some region appearing free in `value`. pub fn any_free_region_meets( self, value: &impl TypeFoldable<'tcx>, callback: impl FnMut(ty::Region<'tcx>) -> bool, ) -> bool { struct RegionVisitor { /// The index of a binder *just outside* the things we have /// traversed. If we encounter a bound region bound by this /// binder or one outer to it, it appears free. Example: /// /// ``` /// for<'a> fn(for<'b> fn(), T) /// ^ ^ ^ ^ /// | | | | here, would be shifted in 1 /// | | | here, would be shifted in 2 /// | | here, would be `INNERMOST` shifted in by 1 /// | here, initially, binder would be `INNERMOST` /// ``` /// /// You see that, initially, *any* bound value is free, /// because we've not traversed any binders. As we pass /// through a binder, we shift the `outer_index` by 1 to /// account for the new binder that encloses us. outer_index: ty::DebruijnIndex, callback: F, } impl<'tcx, F> TypeVisitor<'tcx> for RegionVisitor where F: FnMut(ty::Region<'tcx>) -> bool, { type BreakTy = (); fn visit_binder>( &mut self, t: &Binder, ) -> ControlFlow { self.outer_index.shift_in(1); let result = t.as_ref().skip_binder().visit_with(self); self.outer_index.shift_out(1); result } fn visit_region(&mut self, r: ty::Region<'tcx>) -> ControlFlow { match *r { ty::ReLateBound(debruijn, _) if debruijn < self.outer_index => { ControlFlow::CONTINUE } _ => { if (self.callback)(r) { ControlFlow::BREAK } else { ControlFlow::CONTINUE } } } } fn visit_ty(&mut self, ty: Ty<'tcx>) -> ControlFlow { // We're only interested in types involving regions if ty.flags().intersects(TypeFlags::HAS_FREE_REGIONS) { ty.super_visit_with(self) } else { ControlFlow::CONTINUE } } } value.visit_with(&mut RegionVisitor { outer_index: ty::INNERMOST, callback }).is_break() } } /// Folds over the substructure of a type, visiting its component /// types and all regions that occur *free* within it. /// /// That is, `Ty` can contain function or method types that bind /// regions at the call site (`ReLateBound`), and occurrences of /// regions (aka "lifetimes") that are bound within a type are not /// visited by this folder; only regions that occur free will be /// visited by `fld_r`. pub struct RegionFolder<'a, 'tcx> { tcx: TyCtxt<'tcx>, skipped_regions: &'a mut bool, /// Stores the index of a binder *just outside* the stuff we have /// visited. So this begins as INNERMOST; when we pass through a /// binder, it is incremented (via `shift_in`). current_index: ty::DebruijnIndex, /// Callback invokes for each free region. The `DebruijnIndex` /// points to the binder *just outside* the ones we have passed /// through. fold_region_fn: &'a mut (dyn FnMut(ty::Region<'tcx>, ty::DebruijnIndex) -> ty::Region<'tcx> + 'a), } impl<'a, 'tcx> RegionFolder<'a, 'tcx> { #[inline] pub fn new( tcx: TyCtxt<'tcx>, skipped_regions: &'a mut bool, fold_region_fn: &'a mut dyn FnMut(ty::Region<'tcx>, ty::DebruijnIndex) -> ty::Region<'tcx>, ) -> RegionFolder<'a, 'tcx> { RegionFolder { tcx, skipped_regions, current_index: ty::INNERMOST, fold_region_fn } } } impl<'a, 'tcx> TypeFolder<'tcx> for RegionFolder<'a, 'tcx> { fn tcx<'b>(&'b self) -> TyCtxt<'tcx> { self.tcx } fn fold_binder>(&mut self, t: ty::Binder) -> ty::Binder { 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 < self.current_index => { debug!( "RegionFolder.fold_region({:?}) skipped bound region (current index={:?})", r, self.current_index ); *self.skipped_regions = true; r } _ => { debug!( "RegionFolder.fold_region({:?}) folding free region (current_index={:?})", r, self.current_index ); (self.fold_region_fn)(r, self.current_index) } } } } /////////////////////////////////////////////////////////////////////////// // Bound vars replacer /// Replaces the escaping bound vars (late bound regions or bound types) in a type. struct BoundVarReplacer<'a, 'tcx> { tcx: TyCtxt<'tcx>, /// As with `RegionFolder`, represents the index of a binder *just outside* /// the ones we have visited. current_index: ty::DebruijnIndex, fld_r: &'a mut (dyn FnMut(ty::BoundRegion) -> ty::Region<'tcx> + 'a), fld_t: &'a mut (dyn FnMut(ty::BoundTy) -> Ty<'tcx> + 'a), fld_c: &'a mut (dyn FnMut(ty::BoundVar, Ty<'tcx>) -> &'tcx ty::Const<'tcx> + 'a), } impl<'a, 'tcx> BoundVarReplacer<'a, 'tcx> { fn new(tcx: TyCtxt<'tcx>, fld_r: &'a mut F, fld_t: &'a mut G, fld_c: &'a mut H) -> Self where F: FnMut(ty::BoundRegion) -> ty::Region<'tcx>, G: FnMut(ty::BoundTy) -> Ty<'tcx>, H: FnMut(ty::BoundVar, Ty<'tcx>) -> &'tcx ty::Const<'tcx>, { BoundVarReplacer { tcx, current_index: ty::INNERMOST, fld_r, fld_t, fld_c } } } impl<'a, 'tcx> TypeFolder<'tcx> for BoundVarReplacer<'a, 'tcx> { fn tcx<'b>(&'b self) -> TyCtxt<'tcx> { self.tcx } fn fold_binder>(&mut self, t: ty::Binder) -> ty::Binder { self.current_index.shift_in(1); let t = t.super_fold_with(self); self.current_index.shift_out(1); t } fn fold_ty(&mut self, t: Ty<'tcx>) -> Ty<'tcx> { match *t.kind() { ty::Bound(debruijn, bound_ty) => { if debruijn == self.current_index { let fld_t = &mut self.fld_t; let ty = fld_t(bound_ty); ty::fold::shift_vars(self.tcx, &ty, self.current_index.as_u32()) } else { t } } _ => { if !t.has_vars_bound_at_or_above(self.current_index) { // Nothing more to substitute. t } else { t.super_fold_with(self) } } } } fn fold_region(&mut self, r: ty::Region<'tcx>) -> ty::Region<'tcx> { match *r { ty::ReLateBound(debruijn, br) if debruijn == self.current_index => { let fld_r = &mut self.fld_r; let region = fld_r(br); if let ty::ReLateBound(debruijn1, br) = *region { // If the callback returns a late-bound region, // that region should always use the INNERMOST // debruijn index. Then we adjust it to the // correct depth. assert_eq!(debruijn1, ty::INNERMOST); self.tcx.mk_region(ty::ReLateBound(debruijn, br)) } else { region } } _ => r, } } fn fold_const(&mut self, ct: &'tcx ty::Const<'tcx>) -> &'tcx ty::Const<'tcx> { if let ty::Const { val: ty::ConstKind::Bound(debruijn, bound_const), ty } = *ct { if debruijn == self.current_index { let fld_c = &mut self.fld_c; let ct = fld_c(bound_const, ty); ty::fold::shift_vars(self.tcx, &ct, self.current_index.as_u32()) } else { ct } } else { if !ct.has_vars_bound_at_or_above(self.current_index) { // Nothing more to substitute. ct } else { ct.super_fold_with(self) } } } } impl<'tcx> TyCtxt<'tcx> { /// Replaces all regions bound by the given `Binder` with the /// results returned by the closure; the closure is expected to /// return a free region (relative to this binder), and hence the /// binder is removed in the return type. The closure is invoked /// once for each unique `BoundRegion`; multiple references to the /// same `BoundRegion` will reuse the previous result. A map is /// returned at the end with each bound region and the free region /// that replaced it. /// /// This method only replaces late bound regions and the result may still /// contain escaping bound types. pub fn replace_late_bound_regions( self, value: Binder, fld_r: F, ) -> (T, BTreeMap>) where F: FnMut(ty::BoundRegion) -> ty::Region<'tcx>, T: TypeFoldable<'tcx>, { // identity for bound types and consts let fld_t = |bound_ty| self.mk_ty(ty::Bound(ty::INNERMOST, bound_ty)); let fld_c = |bound_ct, ty| { self.mk_const(ty::Const { val: ty::ConstKind::Bound(ty::INNERMOST, bound_ct), ty }) }; self.replace_escaping_bound_vars(value.skip_binder(), fld_r, fld_t, fld_c) } /// Replaces all escaping bound vars. The `fld_r` closure replaces escaping /// bound regions; the `fld_t` closure replaces escaping bound types and the `fld_c` /// closure replaces escaping bound consts. pub fn replace_escaping_bound_vars( self, value: T, mut fld_r: F, mut fld_t: G, mut fld_c: H, ) -> (T, BTreeMap>) where F: FnMut(ty::BoundRegion) -> ty::Region<'tcx>, G: FnMut(ty::BoundTy) -> Ty<'tcx>, H: FnMut(ty::BoundVar, Ty<'tcx>) -> &'tcx ty::Const<'tcx>, T: TypeFoldable<'tcx>, { use rustc_data_structures::fx::FxHashMap; let mut region_map = BTreeMap::new(); let mut type_map = FxHashMap::default(); let mut const_map = FxHashMap::default(); if !value.has_escaping_bound_vars() { (value, region_map) } else { let mut real_fld_r = |br| *region_map.entry(br).or_insert_with(|| fld_r(br)); let mut real_fld_t = |bound_ty| *type_map.entry(bound_ty).or_insert_with(|| fld_t(bound_ty)); let mut real_fld_c = |bound_ct, ty| *const_map.entry(bound_ct).or_insert_with(|| fld_c(bound_ct, ty)); let mut replacer = BoundVarReplacer::new(self, &mut real_fld_r, &mut real_fld_t, &mut real_fld_c); let result = value.fold_with(&mut replacer); (result, region_map) } } /// Replaces all types or regions bound by the given `Binder`. The `fld_r` /// closure replaces bound regions while the `fld_t` closure replaces bound /// types. pub fn replace_bound_vars( self, value: Binder, fld_r: F, fld_t: G, fld_c: H, ) -> (T, BTreeMap>) where F: FnMut(ty::BoundRegion) -> ty::Region<'tcx>, G: FnMut(ty::BoundTy) -> Ty<'tcx>, H: FnMut(ty::BoundVar, Ty<'tcx>) -> &'tcx ty::Const<'tcx>, T: TypeFoldable<'tcx>, { self.replace_escaping_bound_vars(value.skip_binder(), fld_r, fld_t, fld_c) } /// Replaces any late-bound regions bound in `value` with /// free variants attached to `all_outlive_scope`. pub fn liberate_late_bound_regions(self, all_outlive_scope: DefId, value: ty::Binder) -> T where T: TypeFoldable<'tcx>, { self.replace_late_bound_regions(value, |br| { self.mk_region(ty::ReFree(ty::FreeRegion { scope: all_outlive_scope, bound_region: br, })) }) .0 } /// Returns a set of all late-bound regions that are constrained /// by `value`, meaning that if we instantiate those LBR with /// variables and equate `value` with something else, those /// variables will also be equated. pub fn collect_constrained_late_bound_regions( self, value: &Binder, ) -> FxHashSet where T: TypeFoldable<'tcx>, { self.collect_late_bound_regions(value, true) } /// Returns a set of all late-bound regions that appear in `value` anywhere. pub fn collect_referenced_late_bound_regions( self, value: &Binder, ) -> FxHashSet where T: TypeFoldable<'tcx>, { self.collect_late_bound_regions(value, false) } fn collect_late_bound_regions( self, value: &Binder, just_constraint: bool, ) -> FxHashSet where T: TypeFoldable<'tcx>, { let mut collector = LateBoundRegionsCollector::new(just_constraint); let result = value.as_ref().skip_binder().visit_with(&mut collector); assert!(result.is_continue()); // should never have stopped early collector.regions } /// Replaces any late-bound regions bound in `value` with `'erased`. Useful in codegen but also /// method lookup and a few other places where precise region relationships are not required. pub fn erase_late_bound_regions(self, value: Binder) -> T where T: TypeFoldable<'tcx>, { self.replace_late_bound_regions(value, |_| self.lifetimes.re_erased).0 } /// Rewrite any late-bound regions so that they are anonymous. Region numbers are /// assigned starting at 0 and increasing monotonically in the order traversed /// by the fold operation. /// /// The chief purpose of this function is to canonicalize regions so that two /// `FnSig`s or `TraitRef`s which are equivalent up to region naming will become /// structurally identical. For example, `for<'a, 'b> fn(&'a isize, &'b isize)` and /// `for<'a, 'b> fn(&'b isize, &'a isize)` will become identical after anonymization. pub fn anonymize_late_bound_regions(self, sig: Binder) -> Binder where T: TypeFoldable<'tcx>, { let mut counter = 0; Binder::bind( self.replace_late_bound_regions(sig, |_| { let r = self.mk_region(ty::ReLateBound(ty::INNERMOST, ty::BrAnon(counter))); counter += 1; r }) .0, ) } } /////////////////////////////////////////////////////////////////////////// // Shifter // // Shifts the De Bruijn indices on all escaping bound vars by a // fixed amount. Useful in substitution or when otherwise introducing // a binding level that is not intended to capture the existing bound // vars. See comment on `shift_vars_through_binders` method in // `subst.rs` for more details. struct Shifter<'tcx> { tcx: TyCtxt<'tcx>, current_index: ty::DebruijnIndex, amount: u32, } impl Shifter<'tcx> { pub fn new(tcx: TyCtxt<'tcx>, amount: u32) -> Self { Shifter { tcx, current_index: ty::INNERMOST, amount } } } impl TypeFolder<'tcx> for Shifter<'tcx> { fn tcx<'b>(&'b self) -> TyCtxt<'tcx> { self.tcx } fn fold_binder>(&mut self, t: ty::Binder) -> ty::Binder { 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, br) => { if self.amount == 0 || debruijn < self.current_index { r } else { let debruijn = debruijn.shifted_in(self.amount); let shifted = ty::ReLateBound(debruijn, br); self.tcx.mk_region(shifted) } } _ => r, } } fn fold_ty(&mut self, ty: Ty<'tcx>) -> Ty<'tcx> { match *ty.kind() { ty::Bound(debruijn, bound_ty) => { if self.amount == 0 || debruijn < self.current_index { ty } else { let debruijn = debruijn.shifted_in(self.amount); self.tcx.mk_ty(ty::Bound(debruijn, bound_ty)) } } _ => ty.super_fold_with(self), } } fn fold_const(&mut self, ct: &'tcx ty::Const<'tcx>) -> &'tcx ty::Const<'tcx> { if let ty::Const { val: ty::ConstKind::Bound(debruijn, bound_ct), ty } = *ct { if self.amount == 0 || debruijn < self.current_index { ct } else { let debruijn = debruijn.shifted_in(self.amount); self.tcx.mk_const(ty::Const { val: ty::ConstKind::Bound(debruijn, bound_ct), ty }) } } else { ct.super_fold_with(self) } } } pub fn shift_region<'tcx>( tcx: TyCtxt<'tcx>, region: ty::Region<'tcx>, amount: u32, ) -> ty::Region<'tcx> { match region { ty::ReLateBound(debruijn, br) if amount > 0 => { tcx.mk_region(ty::ReLateBound(debruijn.shifted_in(amount), *br)) } _ => region, } } pub fn shift_vars<'tcx, T>(tcx: TyCtxt<'tcx>, value: T, amount: u32) -> T where T: TypeFoldable<'tcx>, { debug!("shift_vars(value={:?}, amount={})", value, amount); value.fold_with(&mut Shifter::new(tcx, amount)) } #[derive(Debug, PartialEq, Eq, Copy, Clone)] struct FoundEscapingVars; /// An "escaping var" is a bound var whose binder is not part of `t`. A bound var can be a /// bound region or a bound type. /// /// So, for example, consider a type like the following, which has two binders: /// /// for<'a> fn(x: for<'b> fn(&'a isize, &'b isize)) /// ^~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ outer scope /// ^~~~~~~~~~~~~~~~~~~~~~~~~~~~ inner scope /// /// This type has *bound regions* (`'a`, `'b`), but it does not have escaping regions, because the /// binders of both `'a` and `'b` are part of the type itself. However, if we consider the *inner /// fn type*, that type has an escaping region: `'a`. /// /// Note that what I'm calling an "escaping var" is often just called a "free var". However, /// we already use the term "free var". It refers to the regions or types that we use to represent /// bound regions or type params on a fn definition while we are type checking its body. /// /// To clarify, conceptually there is no particular difference between /// an "escaping" var and a "free" var. However, there is a big /// difference in practice. Basically, when "entering" a binding /// level, one is generally required to do some sort of processing to /// a bound var, such as replacing it with a fresh/placeholder /// var, or making an entry in the environment to represent the /// scope to which it is attached, etc. An escaping var represents /// a bound var for which this processing has not yet been done. struct HasEscapingVarsVisitor { /// Anything bound by `outer_index` or "above" is escaping. outer_index: ty::DebruijnIndex, } impl<'tcx> TypeVisitor<'tcx> for HasEscapingVarsVisitor { type BreakTy = FoundEscapingVars; fn visit_binder>(&mut self, t: &Binder) -> ControlFlow { self.outer_index.shift_in(1); let result = t.super_visit_with(self); self.outer_index.shift_out(1); result } fn visit_ty(&mut self, t: Ty<'tcx>) -> ControlFlow { // If the outer-exclusive-binder is *strictly greater* than // `outer_index`, that means that `t` contains some content // bound at `outer_index` or above (because // `outer_exclusive_binder` is always 1 higher than the // content in `t`). Therefore, `t` has some escaping vars. if t.outer_exclusive_binder > self.outer_index { ControlFlow::Break(FoundEscapingVars) } else { ControlFlow::CONTINUE } } fn visit_region(&mut self, r: ty::Region<'tcx>) -> ControlFlow { // If the region is bound by `outer_index` or anything outside // of outer index, then it escapes the binders we have // visited. if r.bound_at_or_above_binder(self.outer_index) { ControlFlow::Break(FoundEscapingVars) } else { ControlFlow::CONTINUE } } fn visit_const(&mut self, ct: &'tcx ty::Const<'tcx>) -> ControlFlow { // we don't have a `visit_infer_const` callback, so we have to // hook in here to catch this case (annoying...), but // otherwise we do want to remember to visit the rest of the // const, as it has types/regions embedded in a lot of other // places. match ct.val { ty::ConstKind::Bound(debruijn, _) if debruijn >= self.outer_index => { ControlFlow::Break(FoundEscapingVars) } _ => ct.super_visit_with(self), } } fn visit_predicate(&mut self, predicate: ty::Predicate<'tcx>) -> ControlFlow { if predicate.inner.outer_exclusive_binder > self.outer_index { ControlFlow::Break(FoundEscapingVars) } else { ControlFlow::CONTINUE } } } #[derive(Debug, PartialEq, Eq, Copy, Clone)] struct FoundFlags; // FIXME: Optimize for checking for infer flags struct HasTypeFlagsVisitor { flags: ty::TypeFlags, } impl<'tcx> TypeVisitor<'tcx> for HasTypeFlagsVisitor { type BreakTy = FoundFlags; fn visit_ty(&mut self, t: Ty<'_>) -> ControlFlow { debug!( "HasTypeFlagsVisitor: t={:?} t.flags={:?} self.flags={:?}", t, t.flags(), self.flags ); if t.flags().intersects(self.flags) { ControlFlow::Break(FoundFlags) } else { ControlFlow::CONTINUE } } fn visit_region(&mut self, r: ty::Region<'tcx>) -> ControlFlow { let flags = r.type_flags(); debug!("HasTypeFlagsVisitor: r={:?} r.flags={:?} self.flags={:?}", r, flags, self.flags); if flags.intersects(self.flags) { ControlFlow::Break(FoundFlags) } else { ControlFlow::CONTINUE } } fn visit_const(&mut self, c: &'tcx ty::Const<'tcx>) -> ControlFlow { let flags = FlagComputation::for_const(c); debug!("HasTypeFlagsVisitor: c={:?} c.flags={:?} self.flags={:?}", c, flags, self.flags); if flags.intersects(self.flags) { ControlFlow::Break(FoundFlags) } else { ControlFlow::CONTINUE } } fn visit_predicate(&mut self, predicate: ty::Predicate<'tcx>) -> ControlFlow { debug!( "HasTypeFlagsVisitor: predicate={:?} predicate.flags={:?} self.flags={:?}", predicate, predicate.inner.flags, self.flags ); if predicate.inner.flags.intersects(self.flags) { ControlFlow::Break(FoundFlags) } else { ControlFlow::CONTINUE } } } /// Collects all the late-bound regions at the innermost binding level /// into a hash set. struct LateBoundRegionsCollector { current_index: ty::DebruijnIndex, regions: FxHashSet, /// `true` if we only want regions that are known to be /// "constrained" when you equate this type with another type. In /// particular, if you have e.g., `&'a u32` and `&'b u32`, equating /// them constraints `'a == 'b`. But if you have `<&'a u32 as /// Trait>::Foo` and `<&'b u32 as Trait>::Foo`, normalizing those /// types may mean that `'a` and `'b` don't appear in the results, /// so they are not considered *constrained*. just_constrained: bool, } impl LateBoundRegionsCollector { fn new(just_constrained: bool) -> Self { LateBoundRegionsCollector { current_index: ty::INNERMOST, regions: Default::default(), just_constrained, } } } impl<'tcx> TypeVisitor<'tcx> for LateBoundRegionsCollector { fn visit_binder>(&mut self, t: &Binder) -> ControlFlow { self.current_index.shift_in(1); let result = t.super_visit_with(self); self.current_index.shift_out(1); result } fn visit_ty(&mut self, t: Ty<'tcx>) -> ControlFlow { // if we are only looking for "constrained" region, we have to // ignore the inputs to a projection, as they may not appear // in the normalized form if self.just_constrained { if let ty::Projection(..) | ty::Opaque(..) = t.kind() { return ControlFlow::CONTINUE; } } t.super_visit_with(self) } fn visit_const(&mut self, c: &'tcx ty::Const<'tcx>) -> ControlFlow { // if we are only looking for "constrained" region, we have to // ignore the inputs of an unevaluated const, as they may not appear // in the normalized form if self.just_constrained { if let ty::ConstKind::Unevaluated(..) = c.val { return ControlFlow::CONTINUE; } } c.super_visit_with(self) } fn visit_region(&mut self, r: ty::Region<'tcx>) -> ControlFlow { if let ty::ReLateBound(debruijn, br) = *r { if debruijn == self.current_index { self.regions.insert(br); } } ControlFlow::CONTINUE } }