1 //! See the Book for more information.
3 pub use self::freshen::TypeFreshener;
4 pub use self::LateBoundRegionConversionTime::*;
5 pub use self::RegionVariableOrigin::*;
6 pub use self::SubregionOrigin::*;
7 pub use self::ValuePairs::*;
8 pub use crate::ty::IntVarValue;
11 use crate::hir::def_id::DefId;
12 use crate::infer::canonical::{Canonical, CanonicalVarValues};
13 use crate::infer::unify_key::{ConstVarValue, ConstVariableValue};
14 use crate::middle::free_region::RegionRelations;
15 use crate::middle::lang_items;
16 use crate::middle::region;
17 use crate::mir::interpret::ConstValue;
18 use crate::session::config::BorrowckMode;
19 use crate::traits::{self, ObligationCause, PredicateObligations, TraitEngine};
20 use crate::ty::error::{ExpectedFound, TypeError, UnconstrainedNumeric};
21 use crate::ty::fold::{TypeFolder, TypeFoldable};
22 use crate::ty::relate::RelateResult;
23 use crate::ty::subst::{Kind, InternalSubsts, SubstsRef};
24 use crate::ty::{self, GenericParamDefKind, Ty, TyCtxt, InferConst};
25 use crate::ty::{FloatVid, IntVid, TyVid, ConstVid};
26 use crate::util::nodemap::FxHashMap;
28 use errors::DiagnosticBuilder;
29 use rustc_data_structures::unify as ut;
30 use std::cell::{Cell, Ref, RefCell, RefMut};
31 use std::collections::BTreeMap;
34 use syntax_pos::symbol::InternedString;
37 use self::combine::CombineFields;
38 use self::lexical_region_resolve::LexicalRegionResolutions;
39 use self::outlives::env::OutlivesEnvironment;
40 use self::region_constraints::{GenericKind, RegionConstraintData, VarInfos, VerifyBound};
41 use self::region_constraints::{RegionConstraintCollector, RegionSnapshot};
42 use self::type_variable::TypeVariableOrigin;
43 use self::unify_key::{ToType, ConstVariableOrigin};
49 pub mod error_reporting;
55 mod lexical_region_resolve;
60 pub mod region_constraints;
63 pub mod type_variable;
68 pub struct InferOk<'tcx, T> {
70 pub obligations: PredicateObligations<'tcx>,
72 pub type InferResult<'tcx, T> = Result<InferOk<'tcx, T>, TypeError<'tcx>>;
74 pub type Bound<T> = Option<T>;
75 pub type UnitResult<'tcx> = RelateResult<'tcx, ()>; // "unify result"
76 pub type FixupResult<'tcx, T> = Result<T, FixupError<'tcx>>; // "fixup result"
78 /// A flag that is used to suppress region errors. This is normally
79 /// false, but sometimes -- when we are doing region checks that the
80 /// NLL borrow checker will also do -- it might be set to true.
81 #[derive(Copy, Clone, Default, Debug)]
82 pub struct SuppressRegionErrors {
86 impl SuppressRegionErrors {
87 pub fn suppressed(self) -> bool {
91 /// Indicates that the MIR borrowck will repeat these region
92 /// checks, so we should ignore errors if NLL is (unconditionally)
94 pub fn when_nll_is_enabled(tcx: TyCtxt<'_, '_, '_>) -> Self {
95 match tcx.borrowck_mode() {
96 // If we're on Migrate mode, report AST region errors
97 BorrowckMode::Migrate => SuppressRegionErrors { suppressed: false },
99 // If we're on MIR, don't report AST region errors as they should be reported by NLL
100 BorrowckMode::Mir => SuppressRegionErrors { suppressed: true },
105 pub struct InferCtxt<'a, 'gcx: 'a + 'tcx, 'tcx: 'a> {
106 pub tcx: TyCtxt<'a, 'gcx, 'tcx>,
108 /// During type-checking/inference of a body, `in_progress_tables`
109 /// contains a reference to the tables being built up, which are
110 /// used for reading closure kinds/signatures as they are inferred,
111 /// and for error reporting logic to read arbitrary node types.
112 pub in_progress_tables: Option<&'a RefCell<ty::TypeckTables<'tcx>>>,
114 /// Cache for projections. This cache is snapshotted along with the
117 /// Public so that `traits::project` can use it.
118 pub projection_cache: RefCell<traits::ProjectionCache<'tcx>>,
120 /// We instantiate `UnificationTable` with `bounds<Ty>` because the
121 /// types that might instantiate a general type variable have an
122 /// order, represented by its upper and lower bounds.
123 pub type_variables: RefCell<type_variable::TypeVariableTable<'tcx>>,
125 /// Map from const parameter variable to the kind of const it represents.
126 const_unification_table: RefCell<ut::UnificationTable<ut::InPlace<ty::ConstVid<'tcx>>>>,
128 /// Map from integral variable to the kind of integer it represents.
129 int_unification_table: RefCell<ut::UnificationTable<ut::InPlace<ty::IntVid>>>,
131 /// Map from floating variable to the kind of float it represents
132 float_unification_table: RefCell<ut::UnificationTable<ut::InPlace<ty::FloatVid>>>,
134 /// Tracks the set of region variables and the constraints between
135 /// them. This is initially `Some(_)` but when
136 /// `resolve_regions_and_report_errors` is invoked, this gets set
137 /// to `None` -- further attempts to perform unification etc may
138 /// fail if new region constraints would've been added.
139 region_constraints: RefCell<Option<RegionConstraintCollector<'tcx>>>,
141 /// Once region inference is done, the values for each variable.
142 lexical_region_resolutions: RefCell<Option<LexicalRegionResolutions<'tcx>>>,
144 /// Caches the results of trait selection. This cache is used
145 /// for things that have to do with the parameters in scope.
146 pub selection_cache: traits::SelectionCache<'tcx>,
148 /// Caches the results of trait evaluation.
149 pub evaluation_cache: traits::EvaluationCache<'tcx>,
151 /// the set of predicates on which errors have been reported, to
152 /// avoid reporting the same error twice.
153 pub reported_trait_errors: RefCell<FxHashMap<Span, Vec<ty::Predicate<'tcx>>>>,
155 /// When an error occurs, we want to avoid reporting "derived"
156 /// errors that are due to this original failure. Normally, we
157 /// handle this with the `err_count_on_creation` count, which
158 /// basically just tracks how many errors were reported when we
159 /// started type-checking a fn and checks to see if any new errors
160 /// have been reported since then. Not great, but it works.
162 /// However, when errors originated in other passes -- notably
163 /// resolve -- this heuristic breaks down. Therefore, we have this
164 /// auxiliary flag that one can set whenever one creates a
165 /// type-error that is due to an error in a prior pass.
167 /// Don't read this flag directly, call `is_tainted_by_errors()`
168 /// and `set_tainted_by_errors()`.
169 tainted_by_errors_flag: Cell<bool>,
171 /// Track how many errors were reported when this infcx is created.
172 /// If the number of errors increases, that's also a sign (line
173 /// `tained_by_errors`) to avoid reporting certain kinds of errors.
174 err_count_on_creation: usize,
176 /// This flag is true while there is an active snapshot.
177 in_snapshot: Cell<bool>,
179 /// A set of constraints that regionck must validate. Each
180 /// constraint has the form `T:'a`, meaning "some type `T` must
181 /// outlive the lifetime 'a". These constraints derive from
182 /// instantiated type parameters. So if you had a struct defined
185 /// struct Foo<T:'static> { ... }
187 /// then in some expression `let x = Foo { ... }` it will
188 /// instantiate the type parameter `T` with a fresh type `$0`. At
189 /// the same time, it will record a region obligation of
190 /// `$0:'static`. This will get checked later by regionck. (We
191 /// can't generally check these things right away because we have
192 /// to wait until types are resolved.)
194 /// These are stored in a map keyed to the id of the innermost
195 /// enclosing fn body / static initializer expression. This is
196 /// because the location where the obligation was incurred can be
197 /// relevant with respect to which sublifetime assumptions are in
198 /// place. The reason that we store under the fn-id, and not
199 /// something more fine-grained, is so that it is easier for
200 /// regionck to be sure that it has found *all* the region
201 /// obligations (otherwise, it's easy to fail to walk to a
202 /// particular node-id).
204 /// Before running `resolve_regions_and_report_errors`, the creator
205 /// of the inference context is expected to invoke
206 /// `process_region_obligations` (defined in `self::region_obligations`)
207 /// for each body-id in this map, which will process the
208 /// obligations within. This is expected to be done 'late enough'
209 /// that all type inference variables have been bound and so forth.
210 pub region_obligations: RefCell<Vec<(hir::HirId, RegionObligation<'tcx>)>>,
212 /// What is the innermost universe we have created? Starts out as
213 /// `UniverseIndex::root()` but grows from there as we enter
214 /// universal quantifiers.
216 /// N.B., at present, we exclude the universal quantifiers on the
217 /// item we are type-checking, and just consider those names as
218 /// part of the root universe. So this would only get incremented
219 /// when we enter into a higher-ranked (`for<..>`) type or trait
221 universe: Cell<ty::UniverseIndex>,
224 /// A map returned by `replace_bound_vars_with_placeholders()`
225 /// indicating the placeholder region that each late-bound region was
227 pub type PlaceholderMap<'tcx> = BTreeMap<ty::BoundRegion, ty::Region<'tcx>>;
229 /// See the `error_reporting` module for more details.
230 #[derive(Clone, Debug, PartialEq, Eq)]
231 pub enum ValuePairs<'tcx> {
232 Types(ExpectedFound<Ty<'tcx>>),
233 Regions(ExpectedFound<ty::Region<'tcx>>),
234 Consts(ExpectedFound<&'tcx ty::Const<'tcx>>),
235 TraitRefs(ExpectedFound<ty::TraitRef<'tcx>>),
236 PolyTraitRefs(ExpectedFound<ty::PolyTraitRef<'tcx>>),
239 /// The trace designates the path through inference that we took to
240 /// encounter an error or subtyping constraint.
242 /// See the `error_reporting` module for more details.
244 pub struct TypeTrace<'tcx> {
245 cause: ObligationCause<'tcx>,
246 values: ValuePairs<'tcx>,
249 /// The origin of a `r1 <= r2` constraint.
251 /// See `error_reporting` module for more details
252 #[derive(Clone, Debug)]
253 pub enum SubregionOrigin<'tcx> {
254 /// Arose from a subtyping relation
255 Subtype(TypeTrace<'tcx>),
257 /// Stack-allocated closures cannot outlive innermost loop
258 /// or function so as to ensure we only require finite stack
259 InfStackClosure(Span),
261 /// Invocation of closure must be within its lifetime
264 /// Dereference of reference must be within its lifetime
267 /// Closure bound must not outlive captured variables
268 ClosureCapture(Span, ast::NodeId),
270 /// Index into slice must be within its lifetime
273 /// When casting `&'a T` to an `&'b Trait` object,
274 /// relating `'a` to `'b`
275 RelateObjectBound(Span),
277 /// Some type parameter was instantiated with the given type,
278 /// and that type must outlive some region.
279 RelateParamBound(Span, Ty<'tcx>),
281 /// The given region parameter was instantiated with a region
282 /// that must outlive some other region.
283 RelateRegionParamBound(Span),
285 /// A bound placed on type parameters that states that must outlive
286 /// the moment of their instantiation.
287 RelateDefaultParamBound(Span, Ty<'tcx>),
289 /// Creating a pointer `b` to contents of another reference
292 /// Creating a pointer `b` to contents of an upvar
293 ReborrowUpvar(Span, ty::UpvarId),
295 /// Data with type `Ty<'tcx>` was borrowed
296 DataBorrowed(Ty<'tcx>, Span),
298 /// (&'a &'b T) where a >= b
299 ReferenceOutlivesReferent(Ty<'tcx>, Span),
301 /// Type or region parameters must be in scope.
302 ParameterInScope(ParameterOrigin, Span),
304 /// The type T of an expression E must outlive the lifetime for E.
305 ExprTypeIsNotInScope(Ty<'tcx>, Span),
307 /// A `ref b` whose region does not enclose the decl site
308 BindingTypeIsNotValidAtDecl(Span),
310 /// Regions appearing in a method receiver must outlive method call
313 /// Regions appearing in a function argument must outlive func call
316 /// Region in return type of invoked fn must enclose call
319 /// Operands must be in scope
322 /// Region resulting from a `&` expr must enclose the `&` expr
325 /// An auto-borrow that does not enclose the expr where it occurs
328 /// Region constraint arriving from destructor safety
329 SafeDestructor(Span),
331 /// Comparing the signature and requirements of an impl method against
332 /// the containing trait.
333 CompareImplMethodObligation {
335 item_name: ast::Name,
336 impl_item_def_id: DefId,
337 trait_item_def_id: DefId,
341 /// Places that type/region parameters can appear.
342 #[derive(Clone, Copy, Debug)]
343 pub enum ParameterOrigin {
345 MethodCall, // foo.bar() <-- parameters on impl providing bar()
346 OverloadedOperator, // a + b when overloaded
347 OverloadedDeref, // *a when overloaded
350 /// Times when we replace late-bound regions with variables:
351 #[derive(Clone, Copy, Debug)]
352 pub enum LateBoundRegionConversionTime {
353 /// when a fn is called
356 /// when two higher-ranked types are compared
359 /// when projecting an associated type
360 AssocTypeProjection(DefId),
363 /// Reasons to create a region inference variable
365 /// See `error_reporting` module for more details
366 #[derive(Copy, Clone, Debug)]
367 pub enum RegionVariableOrigin {
368 /// Region variables created for ill-categorized reasons,
369 /// mostly indicates places in need of refactoring
372 /// Regions created by a `&P` or `[...]` pattern
375 /// Regions created by `&` operator
378 /// Regions created as part of an autoref of a method receiver
381 /// Regions created as part of an automatic coercion
384 /// Region variables created as the values for early-bound regions
385 EarlyBoundRegion(Span, InternedString),
387 /// Region variables created for bound regions
388 /// in a function or method that is called
389 LateBoundRegion(Span, ty::BoundRegion, LateBoundRegionConversionTime),
391 UpvarRegion(ty::UpvarId, Span),
393 BoundRegionInCoherence(ast::Name),
395 /// This origin is used for the inference variables that we create
396 /// during NLL region processing.
397 NLL(NLLRegionVariableOrigin),
400 #[derive(Copy, Clone, Debug, PartialEq, Eq, Hash)]
401 pub enum NLLRegionVariableOrigin {
402 /// During NLL region processing, we create variables for free
403 /// regions that we encounter in the function signature and
404 /// elsewhere. This origin indices we've got one of those.
407 /// "Universal" instantiation of a higher-ranked region (e.g.,
408 /// from a `for<'a> T` binder). Meant to represent "any region".
409 Placeholder(ty::PlaceholderRegion),
414 impl NLLRegionVariableOrigin {
415 pub fn is_universal(self) -> bool {
417 NLLRegionVariableOrigin::FreeRegion => true,
418 NLLRegionVariableOrigin::Placeholder(..) => true,
419 NLLRegionVariableOrigin::Existential => false,
423 pub fn is_existential(self) -> bool {
428 #[derive(Copy, Clone, Debug)]
429 pub enum FixupError<'tcx> {
430 UnresolvedIntTy(IntVid),
431 UnresolvedFloatTy(FloatVid),
433 UnresolvedConst(ConstVid<'tcx>),
436 /// See the `region_obligations` field for more information.
438 pub struct RegionObligation<'tcx> {
439 pub sub_region: ty::Region<'tcx>,
440 pub sup_type: Ty<'tcx>,
441 pub origin: SubregionOrigin<'tcx>,
444 impl<'tcx> fmt::Display for FixupError<'tcx> {
445 fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
446 use self::FixupError::*;
449 UnresolvedIntTy(_) => write!(
451 "cannot determine the type of this integer; \
452 add a suffix to specify the type explicitly"
454 UnresolvedFloatTy(_) => write!(
456 "cannot determine the type of this number; \
457 add a suffix to specify the type explicitly"
459 UnresolvedTy(_) => write!(f, "unconstrained type"),
460 UnresolvedConst(_) => write!(f, "unconstrained const value"),
465 /// Helper type of a temporary returned by `tcx.infer_ctxt()`.
466 /// Necessary because we can't write the following bound:
467 /// `F: for<'b, 'tcx> where 'gcx: 'tcx FnOnce(InferCtxt<'b, 'gcx, 'tcx>)`.
468 pub struct InferCtxtBuilder<'a, 'gcx: 'a + 'tcx, 'tcx: 'a> {
469 global_tcx: TyCtxt<'a, 'gcx, 'gcx>,
470 fresh_tables: Option<RefCell<ty::TypeckTables<'tcx>>>,
473 impl<'a, 'gcx, 'tcx> TyCtxt<'a, 'gcx, 'gcx> {
474 pub fn infer_ctxt(self) -> InferCtxtBuilder<'a, 'gcx, 'tcx> {
482 impl<'a, 'gcx, 'tcx> InferCtxtBuilder<'a, 'gcx, 'tcx> {
483 /// Used only by `rustc_typeck` during body type-checking/inference,
484 /// will initialize `in_progress_tables` with fresh `TypeckTables`.
485 pub fn with_fresh_in_progress_tables(mut self, table_owner: DefId) -> Self {
486 self.fresh_tables = Some(RefCell::new(ty::TypeckTables::empty(Some(table_owner))));
490 /// Given a canonical value `C` as a starting point, create an
491 /// inference context that contains each of the bound values
492 /// within instantiated as a fresh variable. The `f` closure is
493 /// invoked with the new infcx, along with the instantiated value
494 /// `V` and a substitution `S`. This substitution `S` maps from
495 /// the bound values in `C` to their instantiated values in `V`
496 /// (in other words, `S(C) = V`).
497 pub fn enter_with_canonical<T, R>(
500 canonical: &Canonical<'tcx, T>,
501 f: impl for<'b> FnOnce(InferCtxt<'b, 'gcx, 'tcx>, T, CanonicalVarValues<'tcx>) -> R,
504 T: TypeFoldable<'tcx>,
508 infcx.instantiate_canonical_with_fresh_inference_vars(span, canonical);
509 f(infcx, value, subst)
513 pub fn enter<R>(&'tcx mut self, f: impl for<'b> FnOnce(InferCtxt<'b, 'gcx, 'tcx>) -> R) -> R {
514 let InferCtxtBuilder {
518 let in_progress_tables = fresh_tables.as_ref();
519 global_tcx.enter_local(|tcx| {
523 projection_cache: Default::default(),
524 type_variables: RefCell::new(type_variable::TypeVariableTable::new()),
525 const_unification_table: RefCell::new(ut::UnificationTable::new()),
526 int_unification_table: RefCell::new(ut::UnificationTable::new()),
527 float_unification_table: RefCell::new(ut::UnificationTable::new()),
528 region_constraints: RefCell::new(Some(RegionConstraintCollector::new())),
529 lexical_region_resolutions: RefCell::new(None),
530 selection_cache: Default::default(),
531 evaluation_cache: Default::default(),
532 reported_trait_errors: Default::default(),
533 tainted_by_errors_flag: Cell::new(false),
534 err_count_on_creation: tcx.sess.err_count(),
535 in_snapshot: Cell::new(false),
536 region_obligations: RefCell::new(vec![]),
537 universe: Cell::new(ty::UniverseIndex::ROOT),
543 impl<T> ExpectedFound<T> {
544 pub fn new(a_is_expected: bool, a: T, b: T) -> Self {
559 impl<'tcx, T> InferOk<'tcx, T> {
560 pub fn unit(self) -> InferOk<'tcx, ()> {
563 obligations: self.obligations,
567 /// Extracts `value`, registering any obligations into `fulfill_cx`.
568 pub fn into_value_registering_obligations(
570 infcx: &InferCtxt<'_, '_, 'tcx>,
571 fulfill_cx: &mut dyn TraitEngine<'tcx>,
573 let InferOk { value, obligations } = self;
574 for obligation in obligations {
575 fulfill_cx.register_predicate_obligation(infcx, obligation);
581 impl<'tcx> InferOk<'tcx, ()> {
582 pub fn into_obligations(self) -> PredicateObligations<'tcx> {
587 #[must_use = "once you start a snapshot, you should always consume it"]
588 pub struct CombinedSnapshot<'a, 'tcx: 'a> {
589 projection_cache_snapshot: traits::ProjectionCacheSnapshot,
590 type_snapshot: type_variable::Snapshot<'tcx>,
591 const_snapshot: ut::Snapshot<ut::InPlace<ty::ConstVid<'tcx>>>,
592 int_snapshot: ut::Snapshot<ut::InPlace<ty::IntVid>>,
593 float_snapshot: ut::Snapshot<ut::InPlace<ty::FloatVid>>,
594 region_constraints_snapshot: RegionSnapshot,
595 region_obligations_snapshot: usize,
596 universe: ty::UniverseIndex,
597 was_in_snapshot: bool,
598 _in_progress_tables: Option<Ref<'a, ty::TypeckTables<'tcx>>>,
601 impl<'a, 'gcx, 'tcx> InferCtxt<'a, 'gcx, 'tcx> {
602 pub fn is_in_snapshot(&self) -> bool {
603 self.in_snapshot.get()
606 pub fn freshen<T: TypeFoldable<'tcx>>(&self, t: T) -> T {
607 t.fold_with(&mut self.freshener())
610 pub fn type_var_diverges(&'a self, ty: Ty<'_>) -> bool {
612 ty::Infer(ty::TyVar(vid)) => self.type_variables.borrow().var_diverges(vid),
617 pub fn freshener<'b>(&'b self) -> TypeFreshener<'b, 'gcx, 'tcx> {
618 freshen::TypeFreshener::new(self)
621 pub fn type_is_unconstrained_numeric(&'a self, ty: Ty<'_>) -> UnconstrainedNumeric {
622 use crate::ty::error::UnconstrainedNumeric::Neither;
623 use crate::ty::error::UnconstrainedNumeric::{UnconstrainedFloat, UnconstrainedInt};
625 ty::Infer(ty::IntVar(vid)) => {
626 if self.int_unification_table
636 ty::Infer(ty::FloatVar(vid)) => {
637 if self.float_unification_table
651 pub fn unsolved_variables(&self) -> Vec<Ty<'tcx>> {
652 let mut type_variables = self.type_variables.borrow_mut();
653 let mut int_unification_table = self.int_unification_table.borrow_mut();
654 let mut float_unification_table = self.float_unification_table.borrow_mut();
655 // FIXME(const_generics): should there be an equivalent function for const variables?
658 .unsolved_variables()
660 .map(|t| self.tcx.mk_ty_var(t))
662 (0..int_unification_table.len())
663 .map(|i| ty::IntVid { index: i as u32 })
664 .filter(|&vid| int_unification_table.probe_value(vid).is_none())
665 .map(|v| self.tcx.mk_int_var(v)),
668 (0..float_unification_table.len())
669 .map(|i| ty::FloatVid { index: i as u32 })
670 .filter(|&vid| float_unification_table.probe_value(vid).is_none())
671 .map(|v| self.tcx.mk_float_var(v)),
678 trace: TypeTrace<'tcx>,
679 param_env: ty::ParamEnv<'tcx>,
680 ) -> CombineFields<'a, 'gcx, 'tcx> {
686 obligations: PredicateObligations::new(),
690 /// Clear the "currently in a snapshot" flag, invoke the closure,
691 /// then restore the flag to its original value. This flag is a
692 /// debugging measure designed to detect cases where we start a
693 /// snapshot, create type variables, and register obligations
694 /// which may involve those type variables in the fulfillment cx,
695 /// potentially leaving "dangling type variables" behind.
696 /// In such cases, an assertion will fail when attempting to
697 /// register obligations, within a snapshot. Very useful, much
698 /// better than grovelling through megabytes of `RUSTC_LOG` output.
700 /// HOWEVER, in some cases the flag is unhelpful. In particular, we
701 /// sometimes create a "mini-fulfilment-cx" in which we enroll
702 /// obligations. As long as this fulfillment cx is fully drained
703 /// before we return, this is not a problem, as there won't be any
704 /// escaping obligations in the main cx. In those cases, you can
705 /// use this function.
706 pub fn save_and_restore_in_snapshot_flag<F, R>(&self, func: F) -> R
708 F: FnOnce(&Self) -> R,
710 let flag = self.in_snapshot.get();
711 self.in_snapshot.set(false);
712 let result = func(self);
713 self.in_snapshot.set(flag);
717 fn start_snapshot(&self) -> CombinedSnapshot<'a, 'tcx> {
718 debug!("start_snapshot()");
720 let in_snapshot = self.in_snapshot.get();
721 self.in_snapshot.set(true);
724 projection_cache_snapshot: self.projection_cache.borrow_mut().snapshot(),
725 type_snapshot: self.type_variables.borrow_mut().snapshot(),
726 const_snapshot: self.const_unification_table.borrow_mut().snapshot(),
727 int_snapshot: self.int_unification_table.borrow_mut().snapshot(),
728 float_snapshot: self.float_unification_table.borrow_mut().snapshot(),
729 region_constraints_snapshot: self.borrow_region_constraints().start_snapshot(),
730 region_obligations_snapshot: self.region_obligations.borrow().len(),
731 universe: self.universe(),
732 was_in_snapshot: in_snapshot,
733 // Borrow tables "in progress" (i.e., during typeck)
734 // to ban writes from within a snapshot to them.
735 _in_progress_tables: self.in_progress_tables.map(|tables| tables.borrow()),
739 fn rollback_to(&self, cause: &str, snapshot: CombinedSnapshot<'a, 'tcx>) {
740 debug!("rollback_to(cause={})", cause);
741 let CombinedSnapshot {
742 projection_cache_snapshot,
747 region_constraints_snapshot,
748 region_obligations_snapshot,
754 self.in_snapshot.set(was_in_snapshot);
755 self.universe.set(universe);
757 self.projection_cache.borrow_mut().rollback_to(projection_cache_snapshot);
758 self.type_variables.borrow_mut().rollback_to(type_snapshot);
759 self.const_unification_table.borrow_mut().rollback_to(const_snapshot);
760 self.int_unification_table.borrow_mut().rollback_to(int_snapshot);
761 self.float_unification_table.borrow_mut().rollback_to(float_snapshot);
762 self.region_obligations.borrow_mut().truncate(region_obligations_snapshot);
763 self.borrow_region_constraints().rollback_to(region_constraints_snapshot);
766 fn commit_from(&self, snapshot: CombinedSnapshot<'a, 'tcx>) {
767 debug!("commit_from()");
768 let CombinedSnapshot {
769 projection_cache_snapshot,
774 region_constraints_snapshot,
775 region_obligations_snapshot: _,
781 self.in_snapshot.set(was_in_snapshot);
783 self.projection_cache.borrow_mut().commit(projection_cache_snapshot);
784 self.type_variables.borrow_mut().commit(type_snapshot);
785 self.const_unification_table.borrow_mut().commit(const_snapshot);
786 self.int_unification_table.borrow_mut().commit(int_snapshot);
787 self.float_unification_table.borrow_mut().commit(float_snapshot);
788 self.borrow_region_constraints().commit(region_constraints_snapshot);
791 /// Executes `f` and commit the bindings.
792 pub fn commit_unconditionally<R, F>(&self, f: F) -> R
797 let snapshot = self.start_snapshot();
799 self.commit_from(snapshot);
803 /// Executes `f` and commit the bindings if closure `f` returns `Ok(_)`.
804 pub fn commit_if_ok<T, E, F>(&self, f: F) -> Result<T, E>
806 F: FnOnce(&CombinedSnapshot<'a, 'tcx>) -> Result<T, E>,
808 debug!("commit_if_ok()");
809 let snapshot = self.start_snapshot();
810 let r = f(&snapshot);
811 debug!("commit_if_ok() -- r.is_ok() = {}", r.is_ok());
814 self.commit_from(snapshot);
817 self.rollback_to("commit_if_ok -- error", snapshot);
823 /// Execute `f` in a snapshot, and commit the bindings it creates.
824 pub fn in_snapshot<T, F>(&self, f: F) -> T
826 F: FnOnce(&CombinedSnapshot<'a, 'tcx>) -> T,
828 debug!("in_snapshot()");
829 let snapshot = self.start_snapshot();
830 let r = f(&snapshot);
831 self.commit_from(snapshot);
835 /// Executes `f` then unroll any bindings it creates.
836 pub fn probe<R, F>(&self, f: F) -> R
838 F: FnOnce(&CombinedSnapshot<'a, 'tcx>) -> R,
841 let snapshot = self.start_snapshot();
842 let r = f(&snapshot);
843 self.rollback_to("probe", snapshot);
847 /// Scan the constraints produced since `snapshot` began and returns:
849 /// - `None` -- if none of them involve "region outlives" constraints
850 /// - `Some(true)` -- if there are `'a: 'b` constraints where `'a` or `'b` is a placeholder
851 /// - `Some(false)` -- if there are `'a: 'b` constraints but none involve placeholders
852 pub fn region_constraints_added_in_snapshot(
854 snapshot: &CombinedSnapshot<'a, 'tcx>,
856 self.borrow_region_constraints().region_constraints_added_in_snapshot(
857 &snapshot.region_constraints_snapshot,
861 pub fn add_given(&self, sub: ty::Region<'tcx>, sup: ty::RegionVid) {
862 self.borrow_region_constraints().add_given(sub, sup);
865 pub fn can_sub<T>(&self, param_env: ty::ParamEnv<'tcx>, a: T, b: T) -> UnitResult<'tcx>
867 T: at::ToTrace<'tcx>,
869 let origin = &ObligationCause::dummy();
871 self.at(origin, param_env)
873 .map(|InferOk { obligations: _, .. }| {
874 // Ignore obligations, since we are unrolling
875 // everything anyway.
880 pub fn can_eq<T>(&self, param_env: ty::ParamEnv<'tcx>, a: T, b: T) -> UnitResult<'tcx>
882 T: at::ToTrace<'tcx>,
884 let origin = &ObligationCause::dummy();
886 self.at(origin, param_env)
888 .map(|InferOk { obligations: _, .. }| {
889 // Ignore obligations, since we are unrolling
890 // everything anyway.
897 origin: SubregionOrigin<'tcx>,
901 debug!("sub_regions({:?} <: {:?})", a, b);
902 self.borrow_region_constraints()
903 .make_subregion(origin, a, b);
906 pub fn subtype_predicate(
908 cause: &ObligationCause<'tcx>,
909 param_env: ty::ParamEnv<'tcx>,
910 predicate: &ty::PolySubtypePredicate<'tcx>,
911 ) -> Option<InferResult<'tcx, ()>> {
912 // Subtle: it's ok to skip the binder here and resolve because
913 // `shallow_resolve` just ignores anything that is not a type
914 // variable, and because type variable's can't (at present, at
915 // least) capture any of the things bound by this binder.
917 // Really, there is no *particular* reason to do this
918 // `shallow_resolve` here except as a
919 // micro-optimization. Naturally I could not
920 // resist. -nmatsakis
921 let two_unbound_type_vars = {
922 let a = self.shallow_resolve(predicate.skip_binder().a);
923 let b = self.shallow_resolve(predicate.skip_binder().b);
924 a.is_ty_var() && b.is_ty_var()
927 if two_unbound_type_vars {
928 // Two unbound type variables? Can't make progress.
932 Some(self.commit_if_ok(|snapshot| {
934 ty::SubtypePredicate {
940 ) = self.replace_bound_vars_with_placeholders(predicate);
942 let ok = self.at(cause, param_env)
943 .sub_exp(a_is_expected, a, b)?;
945 self.leak_check(false, &placeholder_map, snapshot)?;
951 pub fn region_outlives_predicate(
953 cause: &traits::ObligationCause<'tcx>,
954 predicate: &ty::PolyRegionOutlivesPredicate<'tcx>,
955 ) -> UnitResult<'tcx> {
956 self.commit_if_ok(|snapshot| {
957 let (ty::OutlivesPredicate(r_a, r_b), placeholder_map) =
958 self.replace_bound_vars_with_placeholders(predicate);
959 let origin = SubregionOrigin::from_obligation_cause(
961 || RelateRegionParamBound(cause.span),
963 self.sub_regions(origin, r_b, r_a); // `b : a` ==> `a <= b`
964 self.leak_check(false, &placeholder_map, snapshot)?;
969 pub fn next_ty_var_id(&self, diverging: bool, origin: TypeVariableOrigin) -> TyVid {
972 .new_var(self.universe(), diverging, origin)
975 pub fn next_ty_var(&self, origin: TypeVariableOrigin) -> Ty<'tcx> {
976 self.tcx.mk_ty_var(self.next_ty_var_id(false, origin))
979 pub fn next_ty_var_in_universe(
981 origin: TypeVariableOrigin,
982 universe: ty::UniverseIndex
984 let vid = self.type_variables
986 .new_var(universe, false, origin);
987 self.tcx.mk_ty_var(vid)
990 pub fn next_diverging_ty_var(&self, origin: TypeVariableOrigin) -> Ty<'tcx> {
991 self.tcx.mk_ty_var(self.next_ty_var_id(true, origin))
994 pub fn next_const_var(
997 origin: ConstVariableOrigin
998 ) -> &'tcx ty::Const<'tcx> {
999 self.tcx.mk_const_var(self.next_const_var_id(origin), ty)
1002 pub fn next_const_var_in_universe(
1005 origin: ConstVariableOrigin,
1006 universe: ty::UniverseIndex,
1007 ) -> &'tcx ty::Const<'tcx> {
1008 let vid = self.const_unification_table
1010 .new_key(ConstVarValue {
1012 val: ConstVariableValue::Unknown { universe },
1014 self.tcx.mk_const_var(vid, ty)
1017 pub fn next_const_var_id(&self, origin: ConstVariableOrigin) -> ConstVid<'tcx> {
1018 self.const_unification_table
1020 .new_key(ConstVarValue {
1022 val: ConstVariableValue::Unknown { universe: self.universe() },
1026 fn next_int_var_id(&self) -> IntVid {
1027 self.int_unification_table.borrow_mut().new_key(None)
1030 pub fn next_int_var(&self) -> Ty<'tcx> {
1031 self.tcx.mk_int_var(self.next_int_var_id())
1034 fn next_float_var_id(&self) -> FloatVid {
1035 self.float_unification_table.borrow_mut().new_key(None)
1038 pub fn next_float_var(&self) -> Ty<'tcx> {
1039 self.tcx.mk_float_var(self.next_float_var_id())
1042 /// Creates a fresh region variable with the next available index.
1043 /// The variable will be created in the maximum universe created
1044 /// thus far, allowing it to name any region created thus far.
1045 pub fn next_region_var(&self, origin: RegionVariableOrigin) -> ty::Region<'tcx> {
1046 self.next_region_var_in_universe(origin, self.universe())
1049 /// Creates a fresh region variable with the next available index
1050 /// in the given universe; typically, you can use
1051 /// `next_region_var` and just use the maximal universe.
1052 pub fn next_region_var_in_universe(
1054 origin: RegionVariableOrigin,
1055 universe: ty::UniverseIndex,
1056 ) -> ty::Region<'tcx> {
1057 let region_var = self.borrow_region_constraints()
1058 .new_region_var(universe, origin);
1059 self.tcx.mk_region(ty::ReVar(region_var))
1062 /// Return the universe that the region `r` was created in. For
1063 /// most regions (e.g., `'static`, named regions from the user,
1064 /// etc) this is the root universe U0. For inference variables or
1065 /// placeholders, however, it will return the universe which which
1066 /// they are associated.
1067 fn universe_of_region(
1069 r: ty::Region<'tcx>,
1070 ) -> ty::UniverseIndex {
1071 self.borrow_region_constraints().universe(r)
1074 /// Number of region variables created so far.
1075 pub fn num_region_vars(&self) -> usize {
1076 self.borrow_region_constraints().num_region_vars()
1079 /// Just a convenient wrapper of `next_region_var` for using during NLL.
1080 pub fn next_nll_region_var(&self, origin: NLLRegionVariableOrigin) -> ty::Region<'tcx> {
1081 self.next_region_var(RegionVariableOrigin::NLL(origin))
1084 /// Just a convenient wrapper of `next_region_var` for using during NLL.
1085 pub fn next_nll_region_var_in_universe(
1087 origin: NLLRegionVariableOrigin,
1088 universe: ty::UniverseIndex,
1089 ) -> ty::Region<'tcx> {
1090 self.next_region_var_in_universe(RegionVariableOrigin::NLL(origin), universe)
1093 pub fn var_for_def(&self, span: Span, param: &ty::GenericParamDef) -> Kind<'tcx> {
1095 GenericParamDefKind::Lifetime => {
1096 // Create a region inference variable for the given
1097 // region parameter definition.
1098 self.next_region_var(EarlyBoundRegion(span, param.name))
1101 GenericParamDefKind::Type { .. } => {
1102 // Create a type inference variable for the given
1103 // type parameter definition. The substitutions are
1104 // for actual parameters that may be referred to by
1105 // the default of this type parameter, if it exists.
1106 // e.g., `struct Foo<A, B, C = (A, B)>(...);` when
1107 // used in a path such as `Foo::<T, U>::new()` will
1108 // use an inference variable for `C` with `[T, U]`
1109 // as the substitutions for the default, `(T, U)`.
1110 let ty_var_id = self.type_variables.borrow_mut().new_var(
1113 TypeVariableOrigin::TypeParameterDefinition(span, param.name),
1116 self.tcx.mk_ty_var(ty_var_id).into()
1118 GenericParamDefKind::Const { .. } => {
1119 let origin = ConstVariableOrigin::ConstParameterDefinition(span, param.name);
1121 self.const_unification_table
1123 .new_key(ConstVarValue {
1125 val: ConstVariableValue::Unknown { universe: self.universe() },
1127 self.tcx.mk_const_var(const_var_id, self.tcx.type_of(param.def_id)).into()
1132 /// Given a set of generics defined on a type or impl, returns a substitution mapping each
1133 /// type/region parameter to a fresh inference variable.
1134 pub fn fresh_substs_for_item(&self, span: Span, def_id: DefId) -> SubstsRef<'tcx> {
1135 InternalSubsts::for_item(self.tcx, def_id, |param, _| self.var_for_def(span, param))
1138 /// Returns `true` if errors have been reported since this infcx was
1139 /// created. This is sometimes used as a heuristic to skip
1140 /// reporting errors that often occur as a result of earlier
1141 /// errors, but where it's hard to be 100% sure (e.g., unresolved
1142 /// inference variables, regionck errors).
1143 pub fn is_tainted_by_errors(&self) -> bool {
1145 "is_tainted_by_errors(err_count={}, err_count_on_creation={}, \
1146 tainted_by_errors_flag={})",
1147 self.tcx.sess.err_count(),
1148 self.err_count_on_creation,
1149 self.tainted_by_errors_flag.get()
1152 if self.tcx.sess.err_count() > self.err_count_on_creation {
1153 return true; // errors reported since this infcx was made
1155 self.tainted_by_errors_flag.get()
1158 /// Set the "tainted by errors" flag to true. We call this when we
1159 /// observe an error from a prior pass.
1160 pub fn set_tainted_by_errors(&self) {
1161 debug!("set_tainted_by_errors()");
1162 self.tainted_by_errors_flag.set(true)
1165 /// Process the region constraints and report any errors that
1166 /// result. After this, no more unification operations should be
1167 /// done -- or the compiler will panic -- but it is legal to use
1168 /// `resolve_vars_if_possible` as well as `fully_resolve`.
1169 pub fn resolve_regions_and_report_errors(
1171 region_context: DefId,
1172 region_map: ®ion::ScopeTree,
1173 outlives_env: &OutlivesEnvironment<'tcx>,
1174 suppress: SuppressRegionErrors,
1177 self.is_tainted_by_errors() || self.region_obligations.borrow().is_empty(),
1178 "region_obligations not empty: {:#?}",
1179 self.region_obligations.borrow()
1182 let region_rels = &RegionRelations::new(
1186 outlives_env.free_region_map(),
1188 let (var_infos, data) = self.region_constraints
1191 .expect("regions already resolved")
1192 .into_infos_and_data();
1193 let (lexical_region_resolutions, errors) =
1194 lexical_region_resolve::resolve(region_rels, var_infos, data);
1196 let old_value = self.lexical_region_resolutions
1197 .replace(Some(lexical_region_resolutions));
1198 assert!(old_value.is_none());
1200 if !self.is_tainted_by_errors() {
1201 // As a heuristic, just skip reporting region errors
1202 // altogether if other errors have been reported while
1203 // this infcx was in use. This is totally hokey but
1204 // otherwise we have a hard time separating legit region
1205 // errors from silly ones.
1206 self.report_region_errors(region_map, &errors, suppress);
1210 /// Obtains (and clears) the current set of region
1211 /// constraints. The inference context is still usable: further
1212 /// unifications will simply add new constraints.
1214 /// This method is not meant to be used with normal lexical region
1215 /// resolution. Rather, it is used in the NLL mode as a kind of
1216 /// interim hack: basically we run normal type-check and generate
1217 /// region constraints as normal, but then we take them and
1218 /// translate them into the form that the NLL solver
1219 /// understands. See the NLL module for mode details.
1220 pub fn take_and_reset_region_constraints(&self) -> RegionConstraintData<'tcx> {
1222 self.region_obligations.borrow().is_empty(),
1223 "region_obligations not empty: {:#?}",
1224 self.region_obligations.borrow()
1227 self.borrow_region_constraints().take_and_reset_data()
1230 /// Gives temporary access to the region constraint data.
1231 #[allow(non_camel_case_types)] // bug with impl trait
1232 pub fn with_region_constraints<R>(
1234 op: impl FnOnce(&RegionConstraintData<'tcx>) -> R,
1236 let region_constraints = self.borrow_region_constraints();
1237 op(region_constraints.data())
1240 /// Takes ownership of the list of variable regions. This implies
1241 /// that all the region constraints have already been taken, and
1242 /// hence that `resolve_regions_and_report_errors` can never be
1243 /// called. This is used only during NLL processing to "hand off" ownership
1244 /// of the set of region variables into the NLL region context.
1245 pub fn take_region_var_origins(&self) -> VarInfos {
1246 let (var_infos, data) = self.region_constraints
1249 .expect("regions already resolved")
1250 .into_infos_and_data();
1251 assert!(data.is_empty());
1255 pub fn ty_to_string(&self, t: Ty<'tcx>) -> String {
1256 self.resolve_vars_if_possible(&t).to_string()
1259 pub fn tys_to_string(&self, ts: &[Ty<'tcx>]) -> String {
1260 let tstrs: Vec<String> = ts.iter().map(|t| self.ty_to_string(*t)).collect();
1261 format!("({})", tstrs.join(", "))
1264 pub fn trait_ref_to_string(&self, t: &ty::TraitRef<'tcx>) -> String {
1265 self.resolve_vars_if_possible(t).to_string()
1268 /// If `TyVar(vid)` resolves to a type, return that type. Else, return the
1269 /// universe index of `TyVar(vid)`.
1270 pub fn probe_ty_var(&self, vid: TyVid) -> Result<Ty<'tcx>, ty::UniverseIndex> {
1271 use self::type_variable::TypeVariableValue;
1273 match self.type_variables.borrow_mut().probe(vid) {
1274 TypeVariableValue::Known { value } => Ok(value),
1275 TypeVariableValue::Unknown { universe } => Err(universe),
1279 pub fn shallow_resolve<T>(&self, value: T) -> T
1281 T: TypeFoldable<'tcx>,
1283 let mut r = ShallowResolver::new(self);
1284 value.fold_with(&mut r)
1287 pub fn root_var(&self, var: ty::TyVid) -> ty::TyVid {
1288 self.type_variables.borrow_mut().root_var(var)
1291 /// Where possible, replaces type/const variables in
1292 /// `value` with their final value. Note that region variables
1293 /// are unaffected. If a type/const variable has not been unified, it
1294 /// is left as is. This is an idempotent operation that does
1295 /// not affect inference state in any way and so you can do it
1297 pub fn resolve_vars_if_possible<T>(&self, value: &T) -> T
1299 T: TypeFoldable<'tcx>,
1301 if !value.needs_infer() {
1302 return value.clone(); // avoid duplicated subst-folding
1304 let mut r = resolve::OpportunisticVarResolver::new(self);
1305 value.fold_with(&mut r)
1308 /// Returns first unresolved variable contained in `T`. In the
1309 /// process of visiting `T`, this will resolve (where possible)
1310 /// type variables in `T`, but it never constructs the final,
1311 /// resolved type, so it's more efficient than
1312 /// `resolve_vars_if_possible()`.
1313 pub fn unresolved_type_vars<T>(&self, value: &T) -> Option<(Ty<'tcx>, Option<Span>)>
1315 T: TypeFoldable<'tcx>,
1317 let mut r = resolve::UnresolvedTypeFinder::new(self);
1318 value.visit_with(&mut r);
1322 pub fn probe_const_var(
1324 vid: ty::ConstVid<'tcx>
1325 ) -> Result<&'tcx ty::Const<'tcx>, ty::UniverseIndex> {
1326 match self.const_unification_table.borrow_mut().probe_value(vid).val {
1327 ConstVariableValue::Known { value } => Ok(value),
1328 ConstVariableValue::Unknown { universe } => Err(universe),
1332 pub fn resolve_const_var(
1334 ct: &'tcx ty::Const<'tcx>
1335 ) -> &'tcx ty::Const<'tcx> {
1336 if let ty::Const { val: ConstValue::Infer(InferConst::Var(v)), .. } = ct {
1337 self.const_unification_table
1342 .map(|c| self.resolve_const_var(c))
1349 pub fn fully_resolve<T: TypeFoldable<'tcx>>(&self, value: &T) -> FixupResult<'tcx, T> {
1351 * Attempts to resolve all type/region/const variables in
1352 * `value`. Region inference must have been run already (e.g.,
1353 * by calling `resolve_regions_and_report_errors`). If some
1354 * variable was never unified, an `Err` results.
1356 * This method is idempotent, but it not typically not invoked
1357 * except during the writeback phase.
1360 resolve::fully_resolve(self, value)
1363 // [Note-Type-error-reporting]
1364 // An invariant is that anytime the expected or actual type is Error (the special
1365 // error type, meaning that an error occurred when typechecking this expression),
1366 // this is a derived error. The error cascaded from another error (that was already
1367 // reported), so it's not useful to display it to the user.
1368 // The following methods implement this logic.
1369 // They check if either the actual or expected type is Error, and don't print the error
1370 // in this case. The typechecker should only ever report type errors involving mismatched
1371 // types using one of these methods, and should not call span_err directly for such
1374 pub fn type_error_struct_with_diag<M>(
1378 actual_ty: Ty<'tcx>,
1379 ) -> DiagnosticBuilder<'tcx>
1381 M: FnOnce(String) -> DiagnosticBuilder<'tcx>,
1383 let actual_ty = self.resolve_vars_if_possible(&actual_ty);
1384 debug!("type_error_struct_with_diag({:?}, {:?})", sp, actual_ty);
1386 // Don't report an error if actual type is `Error`.
1387 if actual_ty.references_error() {
1388 return self.tcx.sess.diagnostic().struct_dummy();
1391 mk_diag(self.ty_to_string(actual_ty))
1394 pub fn report_mismatched_types(
1396 cause: &ObligationCause<'tcx>,
1399 err: TypeError<'tcx>,
1400 ) -> DiagnosticBuilder<'tcx> {
1401 let trace = TypeTrace::types(cause, true, expected, actual);
1402 self.report_and_explain_type_error(trace, &err)
1405 pub fn replace_bound_vars_with_fresh_vars<T>(
1408 lbrct: LateBoundRegionConversionTime,
1409 value: &ty::Binder<T>
1410 ) -> (T, BTreeMap<ty::BoundRegion, ty::Region<'tcx>>)
1412 T: TypeFoldable<'tcx>
1414 let fld_r = |br| self.next_region_var(LateBoundRegion(span, br, lbrct));
1415 let fld_t = |_| self.next_ty_var(TypeVariableOrigin::MiscVariable(span));
1416 let fld_c = |_, ty| self.next_const_var(ty, ConstVariableOrigin::MiscVariable(span));
1417 self.tcx.replace_bound_vars(value, fld_r, fld_t, fld_c)
1420 /// See the [`region_constraints::verify_generic_bound`] method.
1421 pub fn verify_generic_bound(
1423 origin: SubregionOrigin<'tcx>,
1424 kind: GenericKind<'tcx>,
1425 a: ty::Region<'tcx>,
1426 bound: VerifyBound<'tcx>,
1428 debug!("verify_generic_bound({:?}, {:?} <: {:?})", kind, a, bound);
1430 self.borrow_region_constraints()
1431 .verify_generic_bound(origin, kind, a, bound);
1434 pub fn type_is_copy_modulo_regions(
1436 param_env: ty::ParamEnv<'tcx>,
1440 let ty = self.resolve_vars_if_possible(&ty);
1442 // Even if the type may have no inference variables, during
1443 // type-checking closure types are in local tables only.
1444 if !self.in_progress_tables.is_some() || !ty.has_closure_types() {
1445 if let Some((param_env, ty)) = self.tcx.lift_to_global(&(param_env, ty)) {
1446 return ty.is_copy_modulo_regions(self.tcx.global_tcx(), param_env, span);
1450 let copy_def_id = self.tcx.require_lang_item(lang_items::CopyTraitLangItem);
1452 // this can get called from typeck (by euv), and moves_by_default
1453 // rightly refuses to work with inference variables, but
1454 // moves_by_default has a cache, which we want to use in other
1456 traits::type_known_to_meet_bound_modulo_regions(self, param_env, ty, copy_def_id, span)
1459 /// Obtains the latest type of the given closure; this may be a
1460 /// closure in the current function, in which case its
1461 /// `ClosureKind` may not yet be known.
1462 pub fn closure_kind(
1464 closure_def_id: DefId,
1465 closure_substs: ty::ClosureSubsts<'tcx>,
1466 ) -> Option<ty::ClosureKind> {
1467 let closure_kind_ty = closure_substs.closure_kind_ty(closure_def_id, self.tcx);
1468 let closure_kind_ty = self.shallow_resolve(closure_kind_ty);
1469 closure_kind_ty.to_opt_closure_kind()
1472 /// Obtain the signature of a closure. For closures, unlike
1473 /// `tcx.fn_sig(def_id)`, this method will work during the
1474 /// type-checking of the enclosing function and return the closure
1475 /// signature in its partially inferred state.
1479 substs: ty::ClosureSubsts<'tcx>,
1480 ) -> ty::PolyFnSig<'tcx> {
1481 let closure_sig_ty = substs.closure_sig_ty(def_id, self.tcx);
1482 let closure_sig_ty = self.shallow_resolve(closure_sig_ty);
1483 closure_sig_ty.fn_sig(self.tcx)
1486 /// Normalizes associated types in `value`, potentially returning
1487 /// new obligations that must further be processed.
1488 pub fn partially_normalize_associated_types_in<T>(
1491 body_id: hir::HirId,
1492 param_env: ty::ParamEnv<'tcx>,
1494 ) -> InferOk<'tcx, T>
1496 T: TypeFoldable<'tcx>,
1498 debug!("partially_normalize_associated_types_in(value={:?})", value);
1499 let mut selcx = traits::SelectionContext::new(self);
1500 let cause = ObligationCause::misc(span, body_id);
1501 let traits::Normalized { value, obligations } =
1502 traits::normalize(&mut selcx, param_env, cause, value);
1504 "partially_normalize_associated_types_in: result={:?} predicates={:?}",
1507 InferOk { value, obligations }
1510 pub fn borrow_region_constraints(&self) -> RefMut<'_, RegionConstraintCollector<'tcx>> {
1511 RefMut::map(self.region_constraints.borrow_mut(), |c| {
1512 c.as_mut().expect("region constraints already solved")
1516 /// Clears the selection, evaluation, and projection caches. This is useful when
1517 /// repeatedly attempting to select an `Obligation` while changing only
1518 /// its `ParamEnv`, since `FulfillmentContext` doesn't use probing.
1519 pub fn clear_caches(&self) {
1520 self.selection_cache.clear();
1521 self.evaluation_cache.clear();
1522 self.projection_cache.borrow_mut().clear();
1525 fn universe(&self) -> ty::UniverseIndex {
1529 /// Creates and return a fresh universe that extends all previous
1530 /// universes. Updates `self.universe` to that new universe.
1531 pub fn create_next_universe(&self) -> ty::UniverseIndex {
1532 let u = self.universe.get().next_universe();
1533 self.universe.set(u);
1538 pub struct ShallowResolver<'a, 'gcx: 'a + 'tcx, 'tcx: 'a> {
1539 infcx: &'a InferCtxt<'a, 'gcx, 'tcx>,
1542 impl<'a, 'gcx, 'tcx> ShallowResolver<'a, 'gcx, 'tcx> {
1544 pub fn new(infcx: &'a InferCtxt<'a, 'gcx, 'tcx>) -> Self {
1545 ShallowResolver { infcx }
1548 // We have this force-inlined variant of `shallow_resolve` for the one
1549 // callsite that is extremely hot. All other callsites use the normal
1552 pub fn inlined_shallow_resolve(&mut self, typ: Ty<'tcx>) -> Ty<'tcx> {
1554 ty::Infer(ty::TyVar(v)) => {
1555 // Not entirely obvious: if `typ` is a type variable,
1556 // it can be resolved to an int/float variable, which
1557 // can then be recursively resolved, hence the
1558 // recursion. Note though that we prevent type
1559 // variables from unifyxing to other type variables
1560 // directly (though they may be embedded
1561 // structurally), and we prevent cycles in any case,
1562 // so this recursion should always be of very limited
1564 self.infcx.type_variables
1568 .map(|t| self.fold_ty(t))
1572 ty::Infer(ty::IntVar(v)) => self.infcx.int_unification_table
1575 .map(|v| v.to_type(self.infcx.tcx))
1578 ty::Infer(ty::FloatVar(v)) => self.infcx.float_unification_table
1581 .map(|v| v.to_type(self.infcx.tcx))
1589 impl<'a, 'gcx, 'tcx> TypeFolder<'gcx, 'tcx> for ShallowResolver<'a, 'gcx, 'tcx> {
1590 fn tcx<'b>(&'b self) -> TyCtxt<'b, 'gcx, 'tcx> {
1594 fn fold_ty(&mut self, ty: Ty<'tcx>) -> Ty<'tcx> {
1595 self.inlined_shallow_resolve(ty)
1598 fn fold_const(&mut self, ct: &'tcx ty::Const<'tcx>) -> &'tcx ty::Const<'tcx> {
1600 ty::Const { val: ConstValue::Infer(InferConst::Var(vid)), .. } => {
1601 self.infcx.const_unification_table
1606 .map(|c| self.fold_const(c))
1614 impl<'a, 'gcx, 'tcx> TypeTrace<'tcx> {
1615 pub fn span(&self) -> Span {
1620 cause: &ObligationCause<'tcx>,
1621 a_is_expected: bool,
1624 ) -> TypeTrace<'tcx> {
1626 cause: cause.clone(),
1627 values: Types(ExpectedFound::new(a_is_expected, a, b)),
1631 pub fn dummy(tcx: TyCtxt<'a, 'gcx, 'tcx>) -> TypeTrace<'tcx> {
1633 cause: ObligationCause::dummy(),
1634 values: Types(ExpectedFound {
1635 expected: tcx.types.err,
1636 found: tcx.types.err,
1642 impl<'tcx> fmt::Debug for TypeTrace<'tcx> {
1643 fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
1644 write!(f, "TypeTrace({:?})", self.cause)
1648 impl<'tcx> SubregionOrigin<'tcx> {
1649 pub fn span(&self) -> Span {
1651 Subtype(ref a) => a.span(),
1652 InfStackClosure(a) => a,
1653 InvokeClosure(a) => a,
1654 DerefPointer(a) => a,
1655 ClosureCapture(a, _) => a,
1657 RelateObjectBound(a) => a,
1658 RelateParamBound(a, _) => a,
1659 RelateRegionParamBound(a) => a,
1660 RelateDefaultParamBound(a, _) => a,
1662 ReborrowUpvar(a, _) => a,
1663 DataBorrowed(_, a) => a,
1664 ReferenceOutlivesReferent(_, a) => a,
1665 ParameterInScope(_, a) => a,
1666 ExprTypeIsNotInScope(_, a) => a,
1667 BindingTypeIsNotValidAtDecl(a) => a,
1674 SafeDestructor(a) => a,
1675 CompareImplMethodObligation { span, .. } => span,
1679 pub fn from_obligation_cause<F>(cause: &traits::ObligationCause<'tcx>, default: F) -> Self
1681 F: FnOnce() -> Self,
1684 traits::ObligationCauseCode::ReferenceOutlivesReferent(ref_type) => {
1685 SubregionOrigin::ReferenceOutlivesReferent(ref_type, cause.span)
1688 traits::ObligationCauseCode::CompareImplMethodObligation {
1692 } => SubregionOrigin::CompareImplMethodObligation {
1704 impl RegionVariableOrigin {
1705 pub fn span(&self) -> Span {
1707 MiscVariable(a) => a,
1708 PatternRegion(a) => a,
1709 AddrOfRegion(a) => a,
1712 EarlyBoundRegion(a, ..) => a,
1713 LateBoundRegion(a, ..) => a,
1714 BoundRegionInCoherence(_) => syntax_pos::DUMMY_SP,
1715 UpvarRegion(_, a) => a,
1716 NLL(..) => bug!("NLL variable used with `span`"),
1721 EnumTypeFoldableImpl! {
1722 impl<'tcx> TypeFoldable<'tcx> for ValuePairs<'tcx> {
1723 (ValuePairs::Types)(a),
1724 (ValuePairs::Regions)(a),
1725 (ValuePairs::Consts)(a),
1726 (ValuePairs::TraitRefs)(a),
1727 (ValuePairs::PolyTraitRefs)(a),
1731 impl<'tcx> fmt::Debug for RegionObligation<'tcx> {
1732 fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
1735 "RegionObligation(sub_region={:?}, sup_type={:?})",
1736 self.sub_region, self.sup_type