1 // Copyright 2012-2014 The Rust Project Developers. See the COPYRIGHT
2 // file at the top-level directory of this distribution and at
3 // http://rust-lang.org/COPYRIGHT.
5 // Licensed under the Apache License, Version 2.0 <LICENSE-APACHE or
6 // http://www.apache.org/licenses/LICENSE-2.0> or the MIT license
7 // <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your
8 // option. This file may not be copied, modified, or distributed
9 // except according to those terms.
11 //! See the Book for more information.
13 pub use self::LateBoundRegionConversionTime::*;
14 pub use self::RegionVariableOrigin::*;
15 pub use self::SubregionOrigin::*;
16 pub use self::ValuePairs::*;
17 pub use ty::IntVarValue;
18 pub use self::freshen::TypeFreshener;
20 use hir::def_id::DefId;
21 use middle::free_region::RegionRelations;
23 use middle::lang_items;
24 use ty::subst::{Kind, Substs};
25 use ty::{TyVid, IntVid, FloatVid};
26 use ty::{self, Ty, TyCtxt, GenericParamDefKind};
27 use ty::error::{ExpectedFound, TypeError, UnconstrainedNumeric};
28 use ty::fold::TypeFoldable;
29 use ty::relate::RelateResult;
30 use traits::{self, ObligationCause, PredicateObligations, TraitEngine};
31 use rustc_data_structures::unify as ut;
32 use std::cell::{Cell, RefCell, Ref, RefMut};
33 use std::collections::BTreeMap;
36 use errors::DiagnosticBuilder;
37 use syntax_pos::{self, Span};
38 use syntax_pos::symbol::InternedString;
39 use util::nodemap::FxHashMap;
40 use arena::SyncDroplessArena;
42 use self::combine::CombineFields;
43 use self::higher_ranked::HrMatchResult;
44 use self::region_constraints::{RegionConstraintCollector, RegionSnapshot};
45 use self::region_constraints::{GenericKind, VerifyBound, RegionConstraintData, VarInfos};
46 use self::lexical_region_resolve::LexicalRegionResolutions;
47 use self::outlives::env::OutlivesEnvironment;
48 use self::type_variable::TypeVariableOrigin;
49 use self::unify_key::ToType;
56 pub mod error_reporting;
62 pub mod region_constraints;
63 mod lexical_region_resolve;
68 pub mod type_variable;
73 pub struct InferOk<'tcx, T> {
75 pub obligations: PredicateObligations<'tcx>,
77 pub type InferResult<'tcx, T> = Result<InferOk<'tcx, T>, TypeError<'tcx>>;
79 pub type Bound<T> = Option<T>;
80 pub type UnitResult<'tcx> = RelateResult<'tcx, ()>; // "unify result"
81 pub type FixupResult<T> = Result<T, FixupError>; // "fixup result"
83 pub struct InferCtxt<'a, 'gcx: 'a+'tcx, 'tcx: 'a> {
84 pub tcx: TyCtxt<'a, 'gcx, 'tcx>,
86 /// During type-checking/inference of a body, `in_progress_tables`
87 /// contains a reference to the tables being built up, which are
88 /// used for reading closure kinds/signatures as they are inferred,
89 /// and for error reporting logic to read arbitrary node types.
90 pub in_progress_tables: Option<&'a RefCell<ty::TypeckTables<'tcx>>>,
92 // Cache for projections. This cache is snapshotted along with the
95 // Public so that `traits::project` can use it.
96 pub projection_cache: RefCell<traits::ProjectionCache<'tcx>>,
98 // We instantiate UnificationTable with bounds<Ty> because the
99 // types that might instantiate a general type variable have an
100 // order, represented by its upper and lower bounds.
101 pub type_variables: RefCell<type_variable::TypeVariableTable<'tcx>>,
103 // Map from integral variable to the kind of integer it represents
104 int_unification_table: RefCell<ut::UnificationTable<ut::InPlace<ty::IntVid>>>,
106 // Map from floating variable to the kind of float it represents
107 float_unification_table: RefCell<ut::UnificationTable<ut::InPlace<ty::FloatVid>>>,
109 // Tracks the set of region variables and the constraints between
110 // them. This is initially `Some(_)` but when
111 // `resolve_regions_and_report_errors` is invoked, this gets set
112 // to `None` -- further attempts to perform unification etc may
113 // fail if new region constraints would've been added.
114 region_constraints: RefCell<Option<RegionConstraintCollector<'tcx>>>,
116 // Once region inference is done, the values for each variable.
117 lexical_region_resolutions: RefCell<Option<LexicalRegionResolutions<'tcx>>>,
119 /// Caches the results of trait selection. This cache is used
120 /// for things that have to do with the parameters in scope.
121 pub selection_cache: traits::SelectionCache<'tcx>,
123 /// Caches the results of trait evaluation.
124 pub evaluation_cache: traits::EvaluationCache<'tcx>,
126 // the set of predicates on which errors have been reported, to
127 // avoid reporting the same error twice.
128 pub reported_trait_errors: RefCell<FxHashMap<Span, Vec<ty::Predicate<'tcx>>>>,
130 // When an error occurs, we want to avoid reporting "derived"
131 // errors that are due to this original failure. Normally, we
132 // handle this with the `err_count_on_creation` count, which
133 // basically just tracks how many errors were reported when we
134 // started type-checking a fn and checks to see if any new errors
135 // have been reported since then. Not great, but it works.
137 // However, when errors originated in other passes -- notably
138 // resolve -- this heuristic breaks down. Therefore, we have this
139 // auxiliary flag that one can set whenever one creates a
140 // type-error that is due to an error in a prior pass.
142 // Don't read this flag directly, call `is_tainted_by_errors()`
143 // and `set_tainted_by_errors()`.
144 tainted_by_errors_flag: Cell<bool>,
146 // Track how many errors were reported when this infcx is created.
147 // If the number of errors increases, that's also a sign (line
148 // `tained_by_errors`) to avoid reporting certain kinds of errors.
149 err_count_on_creation: usize,
151 // This flag is true while there is an active snapshot.
152 in_snapshot: Cell<bool>,
154 // A set of constraints that regionck must validate. Each
155 // constraint has the form `T:'a`, meaning "some type `T` must
156 // outlive the lifetime 'a". These constraints derive from
157 // instantiated type parameters. So if you had a struct defined
160 // struct Foo<T:'static> { ... }
162 // then in some expression `let x = Foo { ... }` it will
163 // instantiate the type parameter `T` with a fresh type `$0`. At
164 // the same time, it will record a region obligation of
165 // `$0:'static`. This will get checked later by regionck. (We
166 // can't generally check these things right away because we have
167 // to wait until types are resolved.)
169 // These are stored in a map keyed to the id of the innermost
170 // enclosing fn body / static initializer expression. This is
171 // because the location where the obligation was incurred can be
172 // relevant with respect to which sublifetime assumptions are in
173 // place. The reason that we store under the fn-id, and not
174 // something more fine-grained, is so that it is easier for
175 // regionck to be sure that it has found *all* the region
176 // obligations (otherwise, it's easy to fail to walk to a
177 // particular node-id).
179 // Before running `resolve_regions_and_report_errors`, the creator
180 // of the inference context is expected to invoke
181 // `process_region_obligations` (defined in `self::region_obligations`)
182 // for each body-id in this map, which will process the
183 // obligations within. This is expected to be done 'late enough'
184 // that all type inference variables have been bound and so forth.
185 pub region_obligations: RefCell<Vec<(ast::NodeId, RegionObligation<'tcx>)>>,
187 /// What is the innermost universe we have created? Starts out as
188 /// `UniverseIndex::root()` but grows from there as we enter
189 /// universal quantifiers.
191 /// NB: At present, we exclude the universal quantifiers on the
192 /// item we are type-checking, and just consider those names as
193 /// part of the root universe. So this would only get incremented
194 /// when we enter into a higher-ranked (`for<..>`) type or trait
196 universe: Cell<ty::UniverseIndex>,
199 /// A map returned by `skolemize_late_bound_regions()` indicating the skolemized
200 /// region that each late-bound region was replaced with.
201 pub type SkolemizationMap<'tcx> = BTreeMap<ty::BoundRegion, ty::Region<'tcx>>;
203 /// See `error_reporting` module for more details
204 #[derive(Clone, Debug)]
205 pub enum ValuePairs<'tcx> {
206 Types(ExpectedFound<Ty<'tcx>>),
207 Regions(ExpectedFound<ty::Region<'tcx>>),
208 TraitRefs(ExpectedFound<ty::TraitRef<'tcx>>),
209 PolyTraitRefs(ExpectedFound<ty::PolyTraitRef<'tcx>>),
212 /// The trace designates the path through inference that we took to
213 /// encounter an error or subtyping constraint.
215 /// See `error_reporting` module for more details.
217 pub struct TypeTrace<'tcx> {
218 cause: ObligationCause<'tcx>,
219 values: ValuePairs<'tcx>,
222 /// The origin of a `r1 <= r2` constraint.
224 /// See `error_reporting` module for more details
225 #[derive(Clone, Debug)]
226 pub enum SubregionOrigin<'tcx> {
227 // Arose from a subtyping relation
228 Subtype(TypeTrace<'tcx>),
230 // Stack-allocated closures cannot outlive innermost loop
231 // or function so as to ensure we only require finite stack
232 InfStackClosure(Span),
234 // Invocation of closure must be within its lifetime
237 // Dereference of reference must be within its lifetime
240 // Closure bound must not outlive captured free variables
241 FreeVariable(Span, ast::NodeId),
243 // Index into slice must be within its lifetime
246 // When casting `&'a T` to an `&'b Trait` object,
247 // relating `'a` to `'b`
248 RelateObjectBound(Span),
250 // Some type parameter was instantiated with the given type,
251 // and that type must outlive some region.
252 RelateParamBound(Span, Ty<'tcx>),
254 // The given region parameter was instantiated with a region
255 // that must outlive some other region.
256 RelateRegionParamBound(Span),
258 // A bound placed on type parameters that states that must outlive
259 // the moment of their instantiation.
260 RelateDefaultParamBound(Span, Ty<'tcx>),
262 // Creating a pointer `b` to contents of another reference
265 // Creating a pointer `b` to contents of an upvar
266 ReborrowUpvar(Span, ty::UpvarId),
268 // Data with type `Ty<'tcx>` was borrowed
269 DataBorrowed(Ty<'tcx>, Span),
271 // (&'a &'b T) where a >= b
272 ReferenceOutlivesReferent(Ty<'tcx>, Span),
274 // Type or region parameters must be in scope.
275 ParameterInScope(ParameterOrigin, Span),
277 // The type T of an expression E must outlive the lifetime for E.
278 ExprTypeIsNotInScope(Ty<'tcx>, Span),
280 // A `ref b` whose region does not enclose the decl site
281 BindingTypeIsNotValidAtDecl(Span),
283 // Regions appearing in a method receiver must outlive method call
286 // Regions appearing in a function argument must outlive func call
289 // Region in return type of invoked fn must enclose call
292 // Operands must be in scope
295 // Region resulting from a `&` expr must enclose the `&` expr
298 // An auto-borrow that does not enclose the expr where it occurs
301 // Region constraint arriving from destructor safety
302 SafeDestructor(Span),
304 // Comparing the signature and requirements of an impl method against
305 // the containing trait.
306 CompareImplMethodObligation {
308 item_name: ast::Name,
309 impl_item_def_id: DefId,
310 trait_item_def_id: DefId,
314 /// Places that type/region parameters can appear.
315 #[derive(Clone, Copy, Debug)]
316 pub enum ParameterOrigin {
318 MethodCall, // foo.bar() <-- parameters on impl providing bar()
319 OverloadedOperator, // a + b when overloaded
320 OverloadedDeref, // *a when overloaded
323 /// Times when we replace late-bound regions with variables:
324 #[derive(Clone, Copy, Debug)]
325 pub enum LateBoundRegionConversionTime {
326 /// when a fn is called
329 /// when two higher-ranked types are compared
332 /// when projecting an associated type
333 AssocTypeProjection(DefId),
336 /// Reasons to create a region inference variable
338 /// See `error_reporting` module for more details
339 #[derive(Copy, Clone, Debug)]
340 pub enum RegionVariableOrigin {
341 // Region variables created for ill-categorized reasons,
342 // mostly indicates places in need of refactoring
345 // Regions created by a `&P` or `[...]` pattern
348 // Regions created by `&` operator
351 // Regions created as part of an autoref of a method receiver
354 // Regions created as part of an automatic coercion
357 // Region variables created as the values for early-bound regions
358 EarlyBoundRegion(Span, InternedString),
360 // Region variables created for bound regions
361 // in a function or method that is called
362 LateBoundRegion(Span, ty::BoundRegion, LateBoundRegionConversionTime),
364 UpvarRegion(ty::UpvarId, Span),
366 BoundRegionInCoherence(ast::Name),
368 // This origin is used for the inference variables that we create
369 // during NLL region processing.
370 NLL(NLLRegionVariableOrigin),
373 #[derive(Copy, Clone, Debug, PartialEq, Eq, Hash)]
374 pub enum NLLRegionVariableOrigin {
375 // During NLL region processing, we create variables for free
376 // regions that we encounter in the function signature and
377 // elsewhere. This origin indices we've got one of those.
380 BoundRegion(ty::UniverseIndex),
385 impl NLLRegionVariableOrigin {
386 pub fn is_universal(self) -> bool {
388 NLLRegionVariableOrigin::FreeRegion => true,
389 NLLRegionVariableOrigin::BoundRegion(..) => true,
390 NLLRegionVariableOrigin::Existential => false,
394 pub fn is_existential(self) -> bool {
399 #[derive(Copy, Clone, Debug)]
400 pub enum FixupError {
401 UnresolvedIntTy(IntVid),
402 UnresolvedFloatTy(FloatVid),
406 /// See the `region_obligations` field for more information.
408 pub struct RegionObligation<'tcx> {
409 pub sub_region: ty::Region<'tcx>,
410 pub sup_type: Ty<'tcx>,
411 pub cause: ObligationCause<'tcx>,
414 impl fmt::Display for FixupError {
415 fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
416 use self::FixupError::*;
419 UnresolvedIntTy(_) => {
420 write!(f, "cannot determine the type of this integer; \
421 add a suffix to specify the type explicitly")
423 UnresolvedFloatTy(_) => {
424 write!(f, "cannot determine the type of this number; \
425 add a suffix to specify the type explicitly")
427 UnresolvedTy(_) => write!(f, "unconstrained type")
432 /// Helper type of a temporary returned by tcx.infer_ctxt().
433 /// Necessary because we can't write the following bound:
434 /// F: for<'b, 'tcx> where 'gcx: 'tcx FnOnce(InferCtxt<'b, 'gcx, 'tcx>).
435 pub struct InferCtxtBuilder<'a, 'gcx: 'a+'tcx, 'tcx: 'a> {
436 global_tcx: TyCtxt<'a, 'gcx, 'gcx>,
437 arena: SyncDroplessArena,
438 fresh_tables: Option<RefCell<ty::TypeckTables<'tcx>>>,
441 impl<'a, 'gcx, 'tcx> TyCtxt<'a, 'gcx, 'gcx> {
442 pub fn infer_ctxt(self) -> InferCtxtBuilder<'a, 'gcx, 'tcx> {
445 arena: SyncDroplessArena::new(),
452 impl<'a, 'gcx, 'tcx> InferCtxtBuilder<'a, 'gcx, 'tcx> {
453 /// Used only by `rustc_typeck` during body type-checking/inference,
454 /// will initialize `in_progress_tables` with fresh `TypeckTables`.
455 pub fn with_fresh_in_progress_tables(mut self, table_owner: DefId) -> Self {
456 self.fresh_tables = Some(RefCell::new(ty::TypeckTables::empty(Some(table_owner))));
460 pub fn enter<F, R>(&'tcx mut self, f: F) -> R
461 where F: for<'b> FnOnce(InferCtxt<'b, 'gcx, 'tcx>) -> R
463 let InferCtxtBuilder {
468 let in_progress_tables = fresh_tables.as_ref();
469 global_tcx.enter_local(arena, |tcx| f(InferCtxt {
472 projection_cache: RefCell::new(traits::ProjectionCache::new()),
473 type_variables: RefCell::new(type_variable::TypeVariableTable::new()),
474 int_unification_table: RefCell::new(ut::UnificationTable::new()),
475 float_unification_table: RefCell::new(ut::UnificationTable::new()),
476 region_constraints: RefCell::new(Some(RegionConstraintCollector::new())),
477 lexical_region_resolutions: RefCell::new(None),
478 selection_cache: traits::SelectionCache::new(),
479 evaluation_cache: traits::EvaluationCache::new(),
480 reported_trait_errors: RefCell::new(FxHashMap()),
481 tainted_by_errors_flag: Cell::new(false),
482 err_count_on_creation: tcx.sess.err_count(),
483 in_snapshot: Cell::new(false),
484 region_obligations: RefCell::new(vec![]),
485 universe: Cell::new(ty::UniverseIndex::ROOT),
490 impl<T> ExpectedFound<T> {
491 pub fn new(a_is_expected: bool, a: T, b: T) -> Self {
493 ExpectedFound {expected: a, found: b}
495 ExpectedFound {expected: b, found: a}
500 impl<'tcx, T> InferOk<'tcx, T> {
501 pub fn unit(self) -> InferOk<'tcx, ()> {
502 InferOk { value: (), obligations: self.obligations }
505 /// Extract `value`, registering any obligations into `fulfill_cx`
506 pub fn into_value_registering_obligations(
508 infcx: &InferCtxt<'_, '_, 'tcx>,
509 fulfill_cx: &mut impl TraitEngine<'tcx>,
511 let InferOk { value, obligations } = self;
512 for obligation in obligations {
513 fulfill_cx.register_predicate_obligation(infcx, obligation);
519 impl<'tcx> InferOk<'tcx, ()> {
520 pub fn into_obligations(self) -> PredicateObligations<'tcx> {
525 #[must_use = "once you start a snapshot, you should always consume it"]
526 pub struct CombinedSnapshot<'a, 'tcx:'a> {
527 projection_cache_snapshot: traits::ProjectionCacheSnapshot,
528 type_snapshot: type_variable::Snapshot<'tcx>,
529 int_snapshot: ut::Snapshot<ut::InPlace<ty::IntVid>>,
530 float_snapshot: ut::Snapshot<ut::InPlace<ty::FloatVid>>,
531 region_constraints_snapshot: RegionSnapshot,
532 region_obligations_snapshot: usize,
533 universe: ty::UniverseIndex,
534 was_in_snapshot: bool,
535 _in_progress_tables: Option<Ref<'a, ty::TypeckTables<'tcx>>>,
538 impl<'a, 'gcx, 'tcx> InferCtxt<'a, 'gcx, 'tcx> {
539 pub fn is_in_snapshot(&self) -> bool {
540 self.in_snapshot.get()
543 pub fn freshen<T:TypeFoldable<'tcx>>(&self, t: T) -> T {
544 t.fold_with(&mut self.freshener())
547 pub fn type_var_diverges(&'a self, ty: Ty) -> bool {
549 ty::Infer(ty::TyVar(vid)) => self.type_variables.borrow().var_diverges(vid),
554 pub fn freshener<'b>(&'b self) -> TypeFreshener<'b, 'gcx, 'tcx> {
555 freshen::TypeFreshener::new(self)
558 pub fn type_is_unconstrained_numeric(&'a self, ty: Ty) -> UnconstrainedNumeric {
559 use ty::error::UnconstrainedNumeric::Neither;
560 use ty::error::UnconstrainedNumeric::{UnconstrainedInt, UnconstrainedFloat};
562 ty::Infer(ty::IntVar(vid)) => {
563 if self.int_unification_table.borrow_mut().probe_value(vid).is_some() {
569 ty::Infer(ty::FloatVar(vid)) => {
570 if self.float_unification_table.borrow_mut().probe_value(vid).is_some() {
580 pub fn unsolved_variables(&self) -> Vec<Ty<'tcx>> {
581 let mut type_variables = self.type_variables.borrow_mut();
582 let mut int_unification_table = self.int_unification_table.borrow_mut();
583 let mut float_unification_table = self.float_unification_table.borrow_mut();
586 .unsolved_variables()
588 .map(|t| self.tcx.mk_var(t))
590 (0..int_unification_table.len())
591 .map(|i| ty::IntVid { index: i as u32 })
592 .filter(|&vid| int_unification_table.probe_value(vid).is_none())
593 .map(|v| self.tcx.mk_int_var(v))
595 (0..float_unification_table.len())
596 .map(|i| ty::FloatVid { index: i as u32 })
597 .filter(|&vid| float_unification_table.probe_value(vid).is_none())
598 .map(|v| self.tcx.mk_float_var(v))
602 fn combine_fields(&'a self, trace: TypeTrace<'tcx>, param_env: ty::ParamEnv<'tcx>)
603 -> CombineFields<'a, 'gcx, 'tcx> {
609 obligations: PredicateObligations::new(),
613 // Clear the "currently in a snapshot" flag, invoke the closure,
614 // then restore the flag to its original value. This flag is a
615 // debugging measure designed to detect cases where we start a
616 // snapshot, create type variables, and register obligations
617 // which may involve those type variables in the fulfillment cx,
618 // potentially leaving "dangling type variables" behind.
619 // In such cases, an assertion will fail when attempting to
620 // register obligations, within a snapshot. Very useful, much
621 // better than grovelling through megabytes of RUST_LOG output.
623 // HOWEVER, in some cases the flag is unhelpful. In particular, we
624 // sometimes create a "mini-fulfilment-cx" in which we enroll
625 // obligations. As long as this fulfillment cx is fully drained
626 // before we return, this is not a problem, as there won't be any
627 // escaping obligations in the main cx. In those cases, you can
628 // use this function.
629 pub fn save_and_restore_in_snapshot_flag<F, R>(&self, func: F) -> R
630 where F: FnOnce(&Self) -> R
632 let flag = self.in_snapshot.get();
633 self.in_snapshot.set(false);
634 let result = func(self);
635 self.in_snapshot.set(flag);
639 fn start_snapshot(&self) -> CombinedSnapshot<'a, 'tcx> {
640 debug!("start_snapshot()");
642 let in_snapshot = self.in_snapshot.get();
643 self.in_snapshot.set(true);
646 projection_cache_snapshot: self.projection_cache.borrow_mut().snapshot(),
647 type_snapshot: self.type_variables.borrow_mut().snapshot(),
648 int_snapshot: self.int_unification_table.borrow_mut().snapshot(),
649 float_snapshot: self.float_unification_table.borrow_mut().snapshot(),
650 region_constraints_snapshot: self.borrow_region_constraints().start_snapshot(),
651 region_obligations_snapshot: self.region_obligations.borrow().len(),
652 universe: self.universe(),
653 was_in_snapshot: in_snapshot,
654 // Borrow tables "in progress" (i.e. during typeck)
655 // to ban writes from within a snapshot to them.
656 _in_progress_tables: self.in_progress_tables.map(|tables| {
662 fn rollback_to(&self, cause: &str, snapshot: CombinedSnapshot<'a, 'tcx>) {
663 debug!("rollback_to(cause={})", cause);
664 let CombinedSnapshot { projection_cache_snapshot,
668 region_constraints_snapshot,
669 region_obligations_snapshot,
672 _in_progress_tables } = snapshot;
674 self.in_snapshot.set(was_in_snapshot);
675 self.universe.set(universe);
677 self.projection_cache
679 .rollback_to(projection_cache_snapshot);
682 .rollback_to(type_snapshot);
683 self.int_unification_table
685 .rollback_to(int_snapshot);
686 self.float_unification_table
688 .rollback_to(float_snapshot);
689 self.region_obligations
691 .truncate(region_obligations_snapshot);
692 self.borrow_region_constraints()
693 .rollback_to(region_constraints_snapshot);
696 fn commit_from(&self, snapshot: CombinedSnapshot<'a, 'tcx>) {
697 debug!("commit_from()");
698 let CombinedSnapshot { projection_cache_snapshot,
702 region_constraints_snapshot,
703 region_obligations_snapshot: _,
706 _in_progress_tables } = snapshot;
708 self.in_snapshot.set(was_in_snapshot);
710 self.projection_cache
712 .commit(&projection_cache_snapshot);
715 .commit(type_snapshot);
716 self.int_unification_table
718 .commit(int_snapshot);
719 self.float_unification_table
721 .commit(float_snapshot);
722 self.borrow_region_constraints()
723 .commit(region_constraints_snapshot);
726 /// Execute `f` and commit the bindings
727 pub fn commit_unconditionally<R, F>(&self, f: F) -> R where
731 let snapshot = self.start_snapshot();
733 self.commit_from(snapshot);
737 /// Execute `f` and commit the bindings if closure `f` returns `Ok(_)`
738 pub fn commit_if_ok<T, E, F>(&self, f: F) -> Result<T, E> where
739 F: FnOnce(&CombinedSnapshot<'a, 'tcx>) -> Result<T, E>
741 debug!("commit_if_ok()");
742 let snapshot = self.start_snapshot();
743 let r = f(&snapshot);
744 debug!("commit_if_ok() -- r.is_ok() = {}", r.is_ok());
746 Ok(_) => { self.commit_from(snapshot); }
747 Err(_) => { self.rollback_to("commit_if_ok -- error", snapshot); }
752 // Execute `f` in a snapshot, and commit the bindings it creates
753 pub fn in_snapshot<T, F>(&self, f: F) -> T where
754 F: FnOnce(&CombinedSnapshot<'a, 'tcx>) -> T
756 debug!("in_snapshot()");
757 let snapshot = self.start_snapshot();
758 let r = f(&snapshot);
759 self.commit_from(snapshot);
763 /// Execute `f` then unroll any bindings it creates
764 pub fn probe<R, F>(&self, f: F) -> R where
765 F: FnOnce(&CombinedSnapshot<'a, 'tcx>) -> R,
768 let snapshot = self.start_snapshot();
769 let r = f(&snapshot);
770 self.rollback_to("probe", snapshot);
774 pub fn add_given(&self,
775 sub: ty::Region<'tcx>,
778 self.borrow_region_constraints().add_given(sub, sup);
781 pub fn can_sub<T>(&self,
782 param_env: ty::ParamEnv<'tcx>,
786 where T: at::ToTrace<'tcx>
788 let origin = &ObligationCause::dummy();
790 self.at(origin, param_env).sub(a, b).map(|InferOk { obligations: _, .. }| {
791 // Ignore obligations, since we are unrolling
792 // everything anyway.
797 pub fn can_eq<T>(&self,
798 param_env: ty::ParamEnv<'tcx>,
802 where T: at::ToTrace<'tcx>
804 let origin = &ObligationCause::dummy();
806 self.at(origin, param_env).eq(a, b).map(|InferOk { obligations: _, .. }| {
807 // Ignore obligations, since we are unrolling
808 // everything anyway.
813 pub fn sub_regions(&self,
814 origin: SubregionOrigin<'tcx>,
816 b: ty::Region<'tcx>) {
817 debug!("sub_regions({:?} <: {:?})", a, b);
818 self.borrow_region_constraints().make_subregion(origin, a, b);
821 pub fn subtype_predicate(&self,
822 cause: &ObligationCause<'tcx>,
823 param_env: ty::ParamEnv<'tcx>,
824 predicate: &ty::PolySubtypePredicate<'tcx>)
825 -> Option<InferResult<'tcx, ()>>
827 // Subtle: it's ok to skip the binder here and resolve because
828 // `shallow_resolve` just ignores anything that is not a type
829 // variable, and because type variable's can't (at present, at
830 // least) capture any of the things bound by this binder.
832 // Really, there is no *particular* reason to do this
833 // `shallow_resolve` here except as a
834 // micro-optimization. Naturally I could not
835 // resist. -nmatsakis
836 let two_unbound_type_vars = {
837 let a = self.shallow_resolve(predicate.skip_binder().a);
838 let b = self.shallow_resolve(predicate.skip_binder().b);
839 a.is_ty_var() && b.is_ty_var()
842 if two_unbound_type_vars {
843 // Two unbound type variables? Can't make progress.
847 Some(self.commit_if_ok(|snapshot| {
848 let (ty::SubtypePredicate { a_is_expected, a, b}, skol_map) =
849 self.skolemize_late_bound_regions(predicate);
851 let cause_span = cause.span;
852 let ok = self.at(cause, param_env).sub_exp(a_is_expected, a, b)?;
853 self.leak_check(false, cause_span, &skol_map, snapshot)?;
854 self.pop_skolemized(skol_map, snapshot);
859 pub fn region_outlives_predicate(&self,
860 cause: &traits::ObligationCause<'tcx>,
861 predicate: &ty::PolyRegionOutlivesPredicate<'tcx>)
864 self.commit_if_ok(|snapshot| {
865 let (ty::OutlivesPredicate(r_a, r_b), skol_map) =
866 self.skolemize_late_bound_regions(predicate);
868 SubregionOrigin::from_obligation_cause(cause,
869 || RelateRegionParamBound(cause.span));
870 self.sub_regions(origin, r_b, r_a); // `b : a` ==> `a <= b`
871 self.leak_check(false, cause.span, &skol_map, snapshot)?;
872 Ok(self.pop_skolemized(skol_map, snapshot))
876 pub fn next_ty_var_id(&self, diverging: bool, origin: TypeVariableOrigin) -> TyVid {
879 .new_var(self.universe(), diverging, origin)
882 pub fn next_ty_var(&self, origin: TypeVariableOrigin) -> Ty<'tcx> {
883 self.tcx.mk_var(self.next_ty_var_id(false, origin))
886 pub fn next_diverging_ty_var(&self, origin: TypeVariableOrigin) -> Ty<'tcx> {
887 self.tcx.mk_var(self.next_ty_var_id(true, origin))
890 pub fn next_int_var_id(&self) -> IntVid {
891 self.int_unification_table
896 pub fn next_float_var_id(&self) -> FloatVid {
897 self.float_unification_table
902 /// Create a fresh region variable with the next available index.
906 /// - `origin`: information about why we created this variable, for use
907 /// during diagnostics / error-reporting.
908 pub fn next_region_var(&self, origin: RegionVariableOrigin)
909 -> ty::Region<'tcx> {
910 let region_var = self.borrow_region_constraints()
911 .new_region_var(self.universe(), origin);
912 self.tcx.mk_region(ty::ReVar(region_var))
915 /// Number of region variables created so far.
916 pub fn num_region_vars(&self) -> usize {
917 self.borrow_region_constraints().num_region_vars()
920 /// Just a convenient wrapper of `next_region_var` for using during NLL.
921 pub fn next_nll_region_var(&self, origin: NLLRegionVariableOrigin)
922 -> ty::Region<'tcx> {
923 self.next_region_var(RegionVariableOrigin::NLL(origin))
926 pub fn var_for_def(&self,
928 param: &ty::GenericParamDef)
931 GenericParamDefKind::Lifetime => {
932 // Create a region inference variable for the given
933 // region parameter definition.
934 self.next_region_var(EarlyBoundRegion(span, param.name)).into()
936 GenericParamDefKind::Type {..} => {
937 // Create a type inference variable for the given
938 // type parameter definition. The substitutions are
939 // for actual parameters that may be referred to by
940 // the default of this type parameter, if it exists.
941 // E.g. `struct Foo<A, B, C = (A, B)>(...);` when
942 // used in a path such as `Foo::<T, U>::new()` will
943 // use an inference variable for `C` with `[T, U]`
944 // as the substitutions for the default, `(T, U)`.
948 .new_var(self.universe(),
950 TypeVariableOrigin::TypeParameterDefinition(span, param.name));
952 self.tcx.mk_var(ty_var_id).into()
957 /// Given a set of generics defined on a type or impl, returns a substitution mapping each
958 /// type/region parameter to a fresh inference variable.
959 pub fn fresh_substs_for_item(&self,
962 -> &'tcx Substs<'tcx> {
963 Substs::for_item(self.tcx, def_id, |param, _| {
964 self.var_for_def(span, param)
968 /// True if errors have been reported since this infcx was
969 /// created. This is sometimes used as a heuristic to skip
970 /// reporting errors that often occur as a result of earlier
971 /// errors, but where it's hard to be 100% sure (e.g., unresolved
972 /// inference variables, regionck errors).
973 pub fn is_tainted_by_errors(&self) -> bool {
974 debug!("is_tainted_by_errors(err_count={}, err_count_on_creation={}, \
975 tainted_by_errors_flag={})",
976 self.tcx.sess.err_count(),
977 self.err_count_on_creation,
978 self.tainted_by_errors_flag.get());
980 if self.tcx.sess.err_count() > self.err_count_on_creation {
981 return true; // errors reported since this infcx was made
983 self.tainted_by_errors_flag.get()
986 /// Set the "tainted by errors" flag to true. We call this when we
987 /// observe an error from a prior pass.
988 pub fn set_tainted_by_errors(&self) {
989 debug!("set_tainted_by_errors()");
990 self.tainted_by_errors_flag.set(true)
993 /// Process the region constraints and report any errors that
994 /// result. After this, no more unification operations should be
995 /// done -- or the compiler will panic -- but it is legal to use
996 /// `resolve_type_vars_if_possible` as well as `fully_resolve`.
997 pub fn resolve_regions_and_report_errors(
999 region_context: DefId,
1000 region_map: ®ion::ScopeTree,
1001 outlives_env: &OutlivesEnvironment<'tcx>,
1003 self.resolve_regions_and_report_errors_inner(
1011 /// Like `resolve_regions_and_report_errors`, but skips error
1012 /// reporting if NLL is enabled. This is used for fn bodies where
1013 /// the same error may later be reported by the NLL-based
1015 pub fn resolve_regions_and_report_errors_unless_nll(
1017 region_context: DefId,
1018 region_map: ®ion::ScopeTree,
1019 outlives_env: &OutlivesEnvironment<'tcx>,
1021 self.resolve_regions_and_report_errors_inner(
1029 fn resolve_regions_and_report_errors_inner(
1031 region_context: DefId,
1032 region_map: ®ion::ScopeTree,
1033 outlives_env: &OutlivesEnvironment<'tcx>,
1034 will_later_be_reported_by_nll: bool,
1036 assert!(self.is_tainted_by_errors() || self.region_obligations.borrow().is_empty(),
1037 "region_obligations not empty: {:#?}",
1038 self.region_obligations.borrow());
1040 let region_rels = &RegionRelations::new(self.tcx,
1043 outlives_env.free_region_map());
1044 let (var_infos, data) = self.region_constraints.borrow_mut()
1046 .expect("regions already resolved")
1047 .into_infos_and_data();
1048 let (lexical_region_resolutions, errors) =
1049 lexical_region_resolve::resolve(region_rels, var_infos, data);
1051 let old_value = self.lexical_region_resolutions.replace(Some(lexical_region_resolutions));
1052 assert!(old_value.is_none());
1054 if !self.is_tainted_by_errors() {
1055 // As a heuristic, just skip reporting region errors
1056 // altogether if other errors have been reported while
1057 // this infcx was in use. This is totally hokey but
1058 // otherwise we have a hard time separating legit region
1059 // errors from silly ones.
1060 self.report_region_errors(region_map, &errors, will_later_be_reported_by_nll);
1064 /// Obtains (and clears) the current set of region
1065 /// constraints. The inference context is still usable: further
1066 /// unifications will simply add new constraints.
1068 /// This method is not meant to be used with normal lexical region
1069 /// resolution. Rather, it is used in the NLL mode as a kind of
1070 /// interim hack: basically we run normal type-check and generate
1071 /// region constraints as normal, but then we take them and
1072 /// translate them into the form that the NLL solver
1073 /// understands. See the NLL module for mode details.
1074 pub fn take_and_reset_region_constraints(&self) -> RegionConstraintData<'tcx> {
1075 assert!(self.region_obligations.borrow().is_empty(),
1076 "region_obligations not empty: {:#?}",
1077 self.region_obligations.borrow());
1079 self.borrow_region_constraints().take_and_reset_data()
1082 /// Gives temporary access to the region constraint data.
1083 #[allow(non_camel_case_types)] // bug with impl trait
1084 pub fn with_region_constraints<R>(
1086 op: impl FnOnce(&RegionConstraintData<'tcx>) -> R,
1088 let region_constraints = self.borrow_region_constraints();
1089 op(region_constraints.data())
1092 /// Takes ownership of the list of variable regions. This implies
1093 /// that all the region constriants have already been taken, and
1094 /// hence that `resolve_regions_and_report_errors` can never be
1095 /// called. This is used only during NLL processing to "hand off" ownership
1096 /// of the set of region vairables into the NLL region context.
1097 pub fn take_region_var_origins(&self) -> VarInfos {
1098 let (var_infos, data) = self.region_constraints.borrow_mut()
1100 .expect("regions already resolved")
1101 .into_infos_and_data();
1102 assert!(data.is_empty());
1106 pub fn ty_to_string(&self, t: Ty<'tcx>) -> String {
1107 self.resolve_type_vars_if_possible(&t).to_string()
1110 pub fn tys_to_string(&self, ts: &[Ty<'tcx>]) -> String {
1111 let tstrs: Vec<String> = ts.iter().map(|t| self.ty_to_string(*t)).collect();
1112 format!("({})", tstrs.join(", "))
1115 pub fn trait_ref_to_string(&self, t: &ty::TraitRef<'tcx>) -> String {
1116 self.resolve_type_vars_if_possible(t).to_string()
1119 pub fn shallow_resolve(&self, typ: Ty<'tcx>) -> Ty<'tcx> {
1121 ty::Infer(ty::TyVar(v)) => {
1122 // Not entirely obvious: if `typ` is a type variable,
1123 // it can be resolved to an int/float variable, which
1124 // can then be recursively resolved, hence the
1125 // recursion. Note though that we prevent type
1126 // variables from unifyxing to other type variables
1127 // directly (though they may be embedded
1128 // structurally), and we prevent cycles in any case,
1129 // so this recursion should always be of very limited
1131 self.type_variables.borrow_mut()
1134 .map(|t| self.shallow_resolve(t))
1138 ty::Infer(ty::IntVar(v)) => {
1139 self.int_unification_table
1142 .map(|v| v.to_type(self.tcx))
1146 ty::Infer(ty::FloatVar(v)) => {
1147 self.float_unification_table
1150 .map(|v| v.to_type(self.tcx))
1160 pub fn resolve_type_vars_if_possible<T>(&self, value: &T) -> T
1161 where T: TypeFoldable<'tcx>
1164 * Where possible, replaces type/int/float variables in
1165 * `value` with their final value. Note that region variables
1166 * are unaffected. If a type variable has not been unified, it
1167 * is left as is. This is an idempotent operation that does
1168 * not affect inference state in any way and so you can do it
1172 if !value.needs_infer() {
1173 return value.clone(); // avoid duplicated subst-folding
1175 let mut r = resolve::OpportunisticTypeResolver::new(self);
1176 value.fold_with(&mut r)
1179 /// Returns true if `T` contains unresolved type variables. In the
1180 /// process of visiting `T`, this will resolve (where possible)
1181 /// type variables in `T`, but it never constructs the final,
1182 /// resolved type, so it's more efficient than
1183 /// `resolve_type_vars_if_possible()`.
1184 pub fn any_unresolved_type_vars<T>(&self, value: &T) -> bool
1185 where T: TypeFoldable<'tcx>
1187 let mut r = resolve::UnresolvedTypeFinder::new(self);
1188 value.visit_with(&mut r)
1191 pub fn resolve_type_and_region_vars_if_possible<T>(&self, value: &T) -> T
1192 where T: TypeFoldable<'tcx>
1194 let mut r = resolve::OpportunisticTypeAndRegionResolver::new(self);
1195 value.fold_with(&mut r)
1198 pub fn fully_resolve<T:TypeFoldable<'tcx>>(&self, value: &T) -> FixupResult<T> {
1200 * Attempts to resolve all type/region variables in
1201 * `value`. Region inference must have been run already (e.g.,
1202 * by calling `resolve_regions_and_report_errors`). If some
1203 * variable was never unified, an `Err` results.
1205 * This method is idempotent, but it not typically not invoked
1206 * except during the writeback phase.
1209 resolve::fully_resolve(self, value)
1212 // [Note-Type-error-reporting]
1213 // An invariant is that anytime the expected or actual type is Error (the special
1214 // error type, meaning that an error occurred when typechecking this expression),
1215 // this is a derived error. The error cascaded from another error (that was already
1216 // reported), so it's not useful to display it to the user.
1217 // The following methods implement this logic.
1218 // They check if either the actual or expected type is Error, and don't print the error
1219 // in this case. The typechecker should only ever report type errors involving mismatched
1220 // types using one of these methods, and should not call span_err directly for such
1223 pub fn type_error_struct_with_diag<M>(&self,
1226 actual_ty: Ty<'tcx>)
1227 -> DiagnosticBuilder<'tcx>
1228 where M: FnOnce(String) -> DiagnosticBuilder<'tcx>,
1230 let actual_ty = self.resolve_type_vars_if_possible(&actual_ty);
1231 debug!("type_error_struct_with_diag({:?}, {:?})", sp, actual_ty);
1233 // Don't report an error if actual type is Error.
1234 if actual_ty.references_error() {
1235 return self.tcx.sess.diagnostic().struct_dummy();
1238 mk_diag(self.ty_to_string(actual_ty))
1241 pub fn report_mismatched_types(&self,
1242 cause: &ObligationCause<'tcx>,
1245 err: TypeError<'tcx>)
1246 -> DiagnosticBuilder<'tcx> {
1247 let trace = TypeTrace::types(cause, true, expected, actual);
1248 self.report_and_explain_type_error(trace, &err)
1251 pub fn replace_late_bound_regions_with_fresh_var<T>(
1254 lbrct: LateBoundRegionConversionTime,
1255 value: &ty::Binder<T>)
1256 -> (T, BTreeMap<ty::BoundRegion, ty::Region<'tcx>>)
1257 where T : TypeFoldable<'tcx>
1259 self.tcx.replace_late_bound_regions(
1261 |br| self.next_region_var(LateBoundRegion(span, br, lbrct)))
1264 /// Given a higher-ranked projection predicate like:
1266 /// for<'a> <T as Fn<&'a u32>>::Output = &'a u32
1268 /// and a target trait-ref like:
1270 /// <T as Fn<&'x u32>>
1272 /// find a substitution `S` for the higher-ranked regions (here,
1273 /// `['a => 'x]`) such that the predicate matches the trait-ref,
1274 /// and then return the value (here, `&'a u32`) but with the
1275 /// substitution applied (hence, `&'x u32`).
1277 /// See `higher_ranked_match` in `higher_ranked/mod.rs` for more
1279 pub fn match_poly_projection_predicate(&self,
1280 cause: ObligationCause<'tcx>,
1281 param_env: ty::ParamEnv<'tcx>,
1282 match_a: ty::PolyProjectionPredicate<'tcx>,
1283 match_b: ty::TraitRef<'tcx>)
1284 -> InferResult<'tcx, HrMatchResult<Ty<'tcx>>>
1286 let match_pair = match_a.map_bound(|p| (p.projection_ty.trait_ref(self.tcx), p.ty));
1287 let trace = TypeTrace {
1289 values: TraitRefs(ExpectedFound::new(true, match_pair.skip_binder().0, match_b))
1292 let mut combine = self.combine_fields(trace, param_env);
1293 let result = combine.higher_ranked_match(&match_pair, &match_b, true)?;
1294 Ok(InferOk { value: result, obligations: combine.obligations })
1297 /// See `verify_generic_bound` method in `region_constraints`
1298 pub fn verify_generic_bound(&self,
1299 origin: SubregionOrigin<'tcx>,
1300 kind: GenericKind<'tcx>,
1301 a: ty::Region<'tcx>,
1302 bound: VerifyBound<'tcx>) {
1303 debug!("verify_generic_bound({:?}, {:?} <: {:?})",
1308 self.borrow_region_constraints().verify_generic_bound(origin, kind, a, bound);
1311 pub fn type_moves_by_default(&self,
1312 param_env: ty::ParamEnv<'tcx>,
1316 let ty = self.resolve_type_vars_if_possible(&ty);
1317 // Even if the type may have no inference variables, during
1318 // type-checking closure types are in local tables only.
1319 if !self.in_progress_tables.is_some() || !ty.has_closure_types() {
1320 if let Some((param_env, ty)) = self.tcx.lift_to_global(&(param_env, ty)) {
1321 return ty.moves_by_default(self.tcx.global_tcx(), param_env, span);
1325 let copy_def_id = self.tcx.require_lang_item(lang_items::CopyTraitLangItem);
1327 // this can get called from typeck (by euv), and moves_by_default
1328 // rightly refuses to work with inference variables, but
1329 // moves_by_default has a cache, which we want to use in other
1331 !traits::type_known_to_meet_bound(self, param_env, ty, copy_def_id, span)
1334 /// Obtains the latest type of the given closure; this may be a
1335 /// closure in the current function, in which case its
1336 /// `ClosureKind` may not yet be known.
1337 pub fn closure_kind(&self,
1338 closure_def_id: DefId,
1339 closure_substs: ty::ClosureSubsts<'tcx>)
1340 -> Option<ty::ClosureKind>
1342 let closure_kind_ty = closure_substs.closure_kind_ty(closure_def_id, self.tcx);
1343 let closure_kind_ty = self.shallow_resolve(&closure_kind_ty);
1344 closure_kind_ty.to_opt_closure_kind()
1347 /// Obtain the signature of a closure. For closures, unlike
1348 /// `tcx.fn_sig(def_id)`, this method will work during the
1349 /// type-checking of the enclosing function and return the closure
1350 /// signature in its partially inferred state.
1354 substs: ty::ClosureSubsts<'tcx>
1355 ) -> ty::PolyFnSig<'tcx> {
1356 let closure_sig_ty = substs.closure_sig_ty(def_id, self.tcx);
1357 let closure_sig_ty = self.shallow_resolve(&closure_sig_ty);
1358 closure_sig_ty.fn_sig(self.tcx)
1361 /// Normalizes associated types in `value`, potentially returning
1362 /// new obligations that must further be processed.
1363 pub fn partially_normalize_associated_types_in<T>(&self,
1365 body_id: ast::NodeId,
1366 param_env: ty::ParamEnv<'tcx>,
1369 where T : TypeFoldable<'tcx>
1371 debug!("partially_normalize_associated_types_in(value={:?})", value);
1372 let mut selcx = traits::SelectionContext::new(self);
1373 let cause = ObligationCause::misc(span, body_id);
1374 let traits::Normalized { value, obligations } =
1375 traits::normalize(&mut selcx, param_env, cause, value);
1376 debug!("partially_normalize_associated_types_in: result={:?} predicates={:?}",
1379 InferOk { value, obligations }
1382 pub fn borrow_region_constraints(&self) -> RefMut<'_, RegionConstraintCollector<'tcx>> {
1384 self.region_constraints.borrow_mut(),
1385 |c| c.as_mut().expect("region constraints already solved"))
1388 /// Clears the selection, evaluation, and projection cachesThis is useful when
1389 /// repeatedly attemping to select an Obligation while changing only
1390 /// its ParamEnv, since FulfillmentContext doesn't use 'probe'
1391 pub fn clear_caches(&self) {
1392 self.selection_cache.clear();
1393 self.evaluation_cache.clear();
1394 self.projection_cache.borrow_mut().clear();
1397 fn universe(&self) -> ty::UniverseIndex {
1401 /// Create and return a new subunivese of the current universe;
1402 /// update `self.universe` to that new subuniverse. At present,
1403 /// used only in the NLL subtyping code, which uses the new
1404 /// universe-based scheme instead of the more limited leak-check
1406 pub fn create_subuniverse(&self) -> ty::UniverseIndex {
1407 let u = self.universe.get().subuniverse();
1408 self.universe.set(u);
1413 impl<'a, 'gcx, 'tcx> TypeTrace<'tcx> {
1414 pub fn span(&self) -> Span {
1418 pub fn types(cause: &ObligationCause<'tcx>,
1419 a_is_expected: bool,
1422 -> TypeTrace<'tcx> {
1424 cause: cause.clone(),
1425 values: Types(ExpectedFound::new(a_is_expected, a, b))
1429 pub fn dummy(tcx: TyCtxt<'a, 'gcx, 'tcx>) -> TypeTrace<'tcx> {
1431 cause: ObligationCause::dummy(),
1432 values: Types(ExpectedFound {
1433 expected: tcx.types.err,
1434 found: tcx.types.err,
1440 impl<'tcx> fmt::Debug for TypeTrace<'tcx> {
1441 fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
1442 write!(f, "TypeTrace({:?})", self.cause)
1446 impl<'tcx> SubregionOrigin<'tcx> {
1447 pub fn span(&self) -> Span {
1449 Subtype(ref a) => a.span(),
1450 InfStackClosure(a) => a,
1451 InvokeClosure(a) => a,
1452 DerefPointer(a) => a,
1453 FreeVariable(a, _) => a,
1455 RelateObjectBound(a) => a,
1456 RelateParamBound(a, _) => a,
1457 RelateRegionParamBound(a) => a,
1458 RelateDefaultParamBound(a, _) => a,
1460 ReborrowUpvar(a, _) => a,
1461 DataBorrowed(_, a) => a,
1462 ReferenceOutlivesReferent(_, a) => a,
1463 ParameterInScope(_, a) => a,
1464 ExprTypeIsNotInScope(_, a) => a,
1465 BindingTypeIsNotValidAtDecl(a) => a,
1472 SafeDestructor(a) => a,
1473 CompareImplMethodObligation { span, .. } => span,
1477 pub fn from_obligation_cause<F>(cause: &traits::ObligationCause<'tcx>,
1480 where F: FnOnce() -> Self
1483 traits::ObligationCauseCode::ReferenceOutlivesReferent(ref_type) =>
1484 SubregionOrigin::ReferenceOutlivesReferent(ref_type, cause.span),
1486 traits::ObligationCauseCode::CompareImplMethodObligation { item_name,
1488 trait_item_def_id, } =>
1489 SubregionOrigin::CompareImplMethodObligation {
1501 impl RegionVariableOrigin {
1502 pub fn span(&self) -> Span {
1504 MiscVariable(a) => a,
1505 PatternRegion(a) => a,
1506 AddrOfRegion(a) => a,
1509 EarlyBoundRegion(a, ..) => a,
1510 LateBoundRegion(a, ..) => a,
1511 BoundRegionInCoherence(_) => syntax_pos::DUMMY_SP,
1512 UpvarRegion(_, a) => a,
1513 NLL(..) => bug!("NLL variable used with `span`"),
1518 EnumTypeFoldableImpl! {
1519 impl<'tcx> TypeFoldable<'tcx> for ValuePairs<'tcx> {
1520 (ValuePairs::Types)(a),
1521 (ValuePairs::Regions)(a),
1522 (ValuePairs::TraitRefs)(a),
1523 (ValuePairs::PolyTraitRefs)(a),
1527 impl<'tcx> fmt::Debug for RegionObligation<'tcx> {
1528 fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
1529 write!(f, "RegionObligation(sub_region={:?}, sup_type={:?})",