2 use super::MethodError;
3 use super::NoMatchData;
4 use super::{CandidateSource, ImplSource, TraitSource};
6 use crate::check::FnCtxt;
7 use crate::hir::def::DefKind;
8 use crate::hir::def_id::DefId;
11 use rustc_ast::util::lev_distance::{find_best_match_for_name, lev_distance};
12 use rustc_data_structures::fx::FxHashSet;
13 use rustc_data_structures::sync::Lrc;
14 use rustc_errors::struct_span_err;
16 use rustc_hir::def::Namespace;
17 use rustc_infer::infer::canonical::OriginalQueryValues;
18 use rustc_infer::infer::canonical::{Canonical, QueryResponse};
19 use rustc_infer::infer::type_variable::{TypeVariableOrigin, TypeVariableOriginKind};
20 use rustc_infer::infer::unify_key::{ConstVariableOrigin, ConstVariableOriginKind};
21 use rustc_infer::infer::{self, InferOk, TyCtxtInferExt};
22 use rustc_middle::middle::stability;
23 use rustc_middle::ty::subst::{InternalSubsts, Subst, SubstsRef};
24 use rustc_middle::ty::GenericParamDefKind;
25 use rustc_middle::ty::{
26 self, ParamEnvAnd, ToPolyTraitRef, ToPredicate, Ty, TyCtxt, TypeFoldable, WithConstness,
28 use rustc_session::config::nightly_options;
29 use rustc_session::lint;
30 use rustc_span::def_id::LocalDefId;
31 use rustc_span::{symbol::Ident, Span, Symbol, DUMMY_SP};
32 use rustc_trait_selection::autoderef::{self, Autoderef};
33 use rustc_trait_selection::traits::query::evaluate_obligation::InferCtxtExt;
34 use rustc_trait_selection::traits::query::method_autoderef::MethodAutoderefBadTy;
35 use rustc_trait_selection::traits::query::method_autoderef::{
36 CandidateStep, MethodAutoderefStepsResult,
38 use rustc_trait_selection::traits::query::CanonicalTyGoal;
39 use rustc_trait_selection::traits::{self, ObligationCause};
45 use smallvec::{smallvec, SmallVec};
47 use self::CandidateKind::*;
48 pub use self::PickKind::*;
50 /// Boolean flag used to indicate if this search is for a suggestion
51 /// or not. If true, we can allow ambiguity and so forth.
52 #[derive(Clone, Copy)]
53 pub struct IsSuggestion(pub bool);
55 struct ProbeContext<'a, 'tcx> {
56 fcx: &'a FnCtxt<'a, 'tcx>,
59 method_name: Option<Ident>,
60 return_type: Option<Ty<'tcx>>,
62 /// This is the OriginalQueryValues for the steps queries
63 /// that are answered in steps.
64 orig_steps_var_values: OriginalQueryValues<'tcx>,
65 steps: Lrc<Vec<CandidateStep<'tcx>>>,
67 inherent_candidates: Vec<Candidate<'tcx>>,
68 extension_candidates: Vec<Candidate<'tcx>>,
69 impl_dups: FxHashSet<DefId>,
71 /// Collects near misses when the candidate functions are missing a `self` keyword and is only
72 /// used for error reporting
73 static_candidates: Vec<CandidateSource>,
75 /// When probing for names, include names that are close to the
76 /// requested name (by Levensthein distance)
77 allow_similar_names: bool,
79 /// Some(candidate) if there is a private candidate
80 private_candidate: Option<(DefKind, DefId)>,
82 /// Collects near misses when trait bounds for type parameters are unsatisfied and is only used
83 /// for error reporting
84 unsatisfied_predicates: Vec<(ty::Predicate<'tcx>, Option<ty::Predicate<'tcx>>)>,
86 is_suggestion: IsSuggestion,
89 impl<'a, 'tcx> Deref for ProbeContext<'a, 'tcx> {
90 type Target = FnCtxt<'a, 'tcx>;
91 fn deref(&self) -> &Self::Target {
97 struct Candidate<'tcx> {
98 // Candidates are (I'm not quite sure, but they are mostly) basically
99 // some metadata on top of a `ty::AssocItem` (without substs).
101 // However, method probing wants to be able to evaluate the predicates
102 // for a function with the substs applied - for example, if a function
103 // has `where Self: Sized`, we don't want to consider it unless `Self`
104 // is actually `Sized`, and similarly, return-type suggestions want
105 // to consider the "actual" return type.
107 // The way this is handled is through `xform_self_ty`. It contains
108 // the receiver type of this candidate, but `xform_self_ty`,
109 // `xform_ret_ty` and `kind` (which contains the predicates) have the
110 // generic parameters of this candidate substituted with the *same set*
111 // of inference variables, which acts as some weird sort of "query".
113 // When we check out a candidate, we require `xform_self_ty` to be
114 // a subtype of the passed-in self-type, and this equates the type
115 // variables in the rest of the fields.
117 // For example, if we have this candidate:
120 // fn foo(&self) where Self: Sized;
124 // Then `xform_self_ty` will be `&'erased ?X` and `kind` will contain
125 // the predicate `?X: Sized`, so if we are evaluating `Foo` for a
126 // the receiver `&T`, we'll do the subtyping which will make `?X`
127 // get the right value, then when we evaluate the predicate we'll check
129 xform_self_ty: Ty<'tcx>,
130 xform_ret_ty: Option<Ty<'tcx>>,
132 kind: CandidateKind<'tcx>,
133 import_ids: SmallVec<[LocalDefId; 1]>,
137 enum CandidateKind<'tcx> {
138 InherentImplCandidate(
140 // Normalize obligations
141 Vec<traits::PredicateObligation<'tcx>>,
144 TraitCandidate(ty::TraitRef<'tcx>),
145 WhereClauseCandidate(
147 ty::PolyTraitRef<'tcx>,
151 #[derive(Debug, PartialEq, Eq, Copy, Clone)]
158 #[derive(Debug, PartialEq, Clone)]
159 pub struct Pick<'tcx> {
160 pub item: ty::AssocItem,
161 pub kind: PickKind<'tcx>,
162 pub import_ids: SmallVec<[LocalDefId; 1]>,
164 // Indicates that the source expression should be autoderef'd N times
166 // A = expr | *expr | **expr | ...
167 pub autoderefs: usize,
169 // Indicates that an autoref is applied after the optional autoderefs
171 // B = A | &A | &mut A
172 pub autoref: Option<hir::Mutability>,
174 // Indicates that the source expression should be "unsized" to a
175 // target type. This should probably eventually go away in favor
176 // of just coercing method receivers.
179 pub unsize: Option<Ty<'tcx>>,
182 #[derive(Clone, Debug, PartialEq, Eq)]
183 pub enum PickKind<'tcx> {
189 ty::PolyTraitRef<'tcx>,
193 pub type PickResult<'tcx> = Result<Pick<'tcx>, MethodError<'tcx>>;
195 #[derive(PartialEq, Eq, Copy, Clone, Debug)]
197 // An expression of the form `receiver.method_name(...)`.
198 // Autoderefs are performed on `receiver`, lookup is done based on the
199 // `self` argument of the method, and static methods aren't considered.
201 // An expression of the form `Type::item` or `<T>::item`.
202 // No autoderefs are performed, lookup is done based on the type each
203 // implementation is for, and static methods are included.
207 #[derive(PartialEq, Eq, Copy, Clone, Debug)]
208 pub enum ProbeScope {
209 // Assemble candidates coming only from traits in scope.
212 // Assemble candidates coming from all traits.
216 impl<'a, 'tcx> FnCtxt<'a, 'tcx> {
217 /// This is used to offer suggestions to users. It returns methods
218 /// that could have been called which have the desired return
219 /// type. Some effort is made to rule out methods that, if called,
220 /// would result in an error (basically, the same criteria we
221 /// would use to decide if a method is a plausible fit for
222 /// ambiguity purposes).
223 pub fn probe_for_return_type(
227 return_type: Ty<'tcx>,
229 scope_expr_id: hir::HirId,
230 ) -> Vec<ty::AssocItem> {
232 "probe(self_ty={:?}, return_type={}, scope_expr_id={})",
233 self_ty, return_type, scope_expr_id
235 let method_names = self
244 ProbeScope::AllTraits,
245 |probe_cx| Ok(probe_cx.candidate_method_names()),
250 .flat_map(|&method_name| {
259 ProbeScope::AllTraits,
260 |probe_cx| probe_cx.pick(),
263 .map(|pick| pick.item)
268 pub fn probe_for_name(
273 is_suggestion: IsSuggestion,
275 scope_expr_id: hir::HirId,
277 ) -> PickResult<'tcx> {
279 "probe(self_ty={:?}, item_name={}, scope_expr_id={})",
280 self_ty, item_name, scope_expr_id
291 |probe_cx| probe_cx.pick(),
299 method_name: Option<Ident>,
300 return_type: Option<Ty<'tcx>>,
301 is_suggestion: IsSuggestion,
303 scope_expr_id: hir::HirId,
306 ) -> Result<R, MethodError<'tcx>>
308 OP: FnOnce(ProbeContext<'a, 'tcx>) -> Result<R, MethodError<'tcx>>,
310 let mut orig_values = OriginalQueryValues::default();
311 let param_env_and_self_ty = self.infcx.canonicalize_query(
312 &ParamEnvAnd { param_env: self.param_env, value: self_ty },
316 let steps = if mode == Mode::MethodCall {
317 self.tcx.method_autoderef_steps(param_env_and_self_ty)
319 self.infcx.probe(|_| {
320 // Mode::Path - the deref steps is "trivial". This turns
321 // our CanonicalQuery into a "trivial" QueryResponse. This
322 // is a bit inefficient, but I don't think that writing
323 // special handling for this "trivial case" is a good idea.
325 let infcx = &self.infcx;
326 let (ParamEnvAnd { param_env: _, value: self_ty }, canonical_inference_vars) =
327 infcx.instantiate_canonical_with_fresh_inference_vars(
329 ¶m_env_and_self_ty,
332 "probe_op: Mode::Path, param_env_and_self_ty={:?} self_ty={:?}",
333 param_env_and_self_ty, self_ty
335 MethodAutoderefStepsResult {
336 steps: Lrc::new(vec![CandidateStep {
337 self_ty: self.make_query_response_ignoring_pending_obligations(
338 canonical_inference_vars,
342 from_unsafe_deref: false,
346 reached_recursion_limit: false,
351 // If our autoderef loop had reached the recursion limit,
352 // report an overflow error, but continue going on with
353 // the truncated autoderef list.
354 if steps.reached_recursion_limit {
359 .unwrap_or_else(|| span_bug!(span, "reached the recursion limit in 0 steps?"))
362 .probe_instantiate_query_response(span, &orig_values, ty)
363 .unwrap_or_else(|_| span_bug!(span, "instantiating {:?} failed?", ty));
364 autoderef::report_autoderef_recursion_limit_error(self.tcx, span, ty.value);
368 // If we encountered an `_` type or an error type during autoderef, this is
370 if let Some(bad_ty) = &steps.opt_bad_ty {
372 // Ambiguity was encountered during a suggestion. Just keep going.
373 debug!("ProbeContext: encountered ambiguity in suggestion");
374 } else if bad_ty.reached_raw_pointer && !self.tcx.features().arbitrary_self_types {
375 // this case used to be allowed by the compiler,
376 // so we do a future-compat lint here for the 2015 edition
377 // (see https://github.com/rust-lang/rust/issues/46906)
378 if self.tcx.sess.rust_2018() {
383 "the type of this value must be known to call a method on a raw pointer on \
388 self.tcx.struct_span_lint_hir(
389 lint::builtin::TYVAR_BEHIND_RAW_POINTER,
392 |lint| lint.build("type annotations needed").emit(),
396 // Encountered a real ambiguity, so abort the lookup. If `ty` is not
397 // an `Err`, report the right "type annotations needed" error pointing
401 .probe_instantiate_query_response(span, &orig_values, ty)
402 .unwrap_or_else(|_| span_bug!(span, "instantiating {:?} failed?", ty));
403 let ty = self.structurally_resolved_type(span, ty.value);
404 assert!(matches!(ty.kind, ty::Error(_)));
405 return Err(MethodError::NoMatch(NoMatchData::new(
415 debug!("ProbeContext: steps for self_ty={:?} are {:?}", self_ty, steps);
417 // this creates one big transaction so that all type variables etc
418 // that we create during the probe process are removed later
420 let mut probe_cx = ProbeContext::new(
431 probe_cx.assemble_inherent_candidates();
433 ProbeScope::TraitsInScope => {
434 probe_cx.assemble_extension_candidates_for_traits_in_scope(scope_expr_id)?
436 ProbeScope::AllTraits => probe_cx.assemble_extension_candidates_for_all_traits()?,
443 pub fn provide(providers: &mut ty::query::Providers) {
444 providers.method_autoderef_steps = method_autoderef_steps;
447 fn method_autoderef_steps<'tcx>(
449 goal: CanonicalTyGoal<'tcx>,
450 ) -> MethodAutoderefStepsResult<'tcx> {
451 debug!("method_autoderef_steps({:?})", goal);
453 tcx.infer_ctxt().enter_with_canonical(DUMMY_SP, &goal, |ref infcx, goal, inference_vars| {
454 let ParamEnvAnd { param_env, value: self_ty } = goal;
456 let mut autoderef = Autoderef::new(infcx, param_env, hir::CRATE_HIR_ID, DUMMY_SP, self_ty)
457 .include_raw_pointers()
459 let mut reached_raw_pointer = false;
460 let mut steps: Vec<_> = autoderef
463 let step = CandidateStep {
464 self_ty: infcx.make_query_response_ignoring_pending_obligations(
465 inference_vars.clone(),
469 from_unsafe_deref: reached_raw_pointer,
472 if let ty::RawPtr(_) = ty.kind {
473 // all the subsequent steps will be from_unsafe_deref
474 reached_raw_pointer = true;
480 let final_ty = autoderef.final_ty(true);
481 let opt_bad_ty = match final_ty.kind {
482 ty::Infer(ty::TyVar(_)) | ty::Error(_) => Some(MethodAutoderefBadTy {
485 .make_query_response_ignoring_pending_obligations(inference_vars, final_ty),
487 ty::Array(elem_ty, _) => {
488 let dereferences = steps.len() - 1;
490 steps.push(CandidateStep {
491 self_ty: infcx.make_query_response_ignoring_pending_obligations(
493 infcx.tcx.mk_slice(elem_ty),
495 autoderefs: dereferences,
496 // this could be from an unsafe deref if we had
497 // a *mut/const [T; N]
498 from_unsafe_deref: reached_raw_pointer,
507 debug!("method_autoderef_steps: steps={:?} opt_bad_ty={:?}", steps, opt_bad_ty);
509 MethodAutoderefStepsResult {
510 steps: Lrc::new(steps),
511 opt_bad_ty: opt_bad_ty.map(Lrc::new),
512 reached_recursion_limit: autoderef.reached_recursion_limit(),
517 impl<'a, 'tcx> ProbeContext<'a, 'tcx> {
519 fcx: &'a FnCtxt<'a, 'tcx>,
522 method_name: Option<Ident>,
523 return_type: Option<Ty<'tcx>>,
524 orig_steps_var_values: OriginalQueryValues<'tcx>,
525 steps: Lrc<Vec<CandidateStep<'tcx>>>,
526 is_suggestion: IsSuggestion,
527 ) -> ProbeContext<'a, 'tcx> {
534 inherent_candidates: Vec::new(),
535 extension_candidates: Vec::new(),
536 impl_dups: FxHashSet::default(),
537 orig_steps_var_values,
539 static_candidates: Vec::new(),
540 allow_similar_names: false,
541 private_candidate: None,
542 unsatisfied_predicates: Vec::new(),
547 fn reset(&mut self) {
548 self.inherent_candidates.clear();
549 self.extension_candidates.clear();
550 self.impl_dups.clear();
551 self.static_candidates.clear();
552 self.private_candidate = None;
555 ///////////////////////////////////////////////////////////////////////////
556 // CANDIDATE ASSEMBLY
558 fn push_candidate(&mut self, candidate: Candidate<'tcx>, is_inherent: bool) {
559 let is_accessible = if let Some(name) = self.method_name {
560 let item = candidate.item;
562 self.tcx.adjust_ident_and_get_scope(name, item.container.id(), self.body_id).1;
563 item.vis.is_accessible_from(def_scope, self.tcx)
569 self.inherent_candidates.push(candidate);
571 self.extension_candidates.push(candidate);
573 } else if self.private_candidate.is_none() {
574 self.private_candidate =
575 Some((candidate.item.kind.as_def_kind(), candidate.item.def_id));
579 fn assemble_inherent_candidates(&mut self) {
580 let steps = Lrc::clone(&self.steps);
581 for step in steps.iter() {
582 self.assemble_probe(&step.self_ty);
586 fn assemble_probe(&mut self, self_ty: &Canonical<'tcx, QueryResponse<'tcx, Ty<'tcx>>>) {
587 debug!("assemble_probe: self_ty={:?}", self_ty);
588 let lang_items = self.tcx.lang_items();
590 match self_ty.value.value.kind {
591 ty::Dynamic(ref data, ..) => {
592 if let Some(p) = data.principal() {
593 // Subtle: we can't use `instantiate_query_response` here: using it will
594 // commit to all of the type equalities assumed by inference going through
595 // autoderef (see the `method-probe-no-guessing` test).
597 // However, in this code, it is OK if we end up with an object type that is
598 // "more general" than the object type that we are evaluating. For *every*
599 // object type `MY_OBJECT`, a function call that goes through a trait-ref
600 // of the form `<MY_OBJECT as SuperTraitOf(MY_OBJECT)>::func` is a valid
601 // `ObjectCandidate`, and it should be discoverable "exactly" through one
602 // of the iterations in the autoderef loop, so there is no problem with it
603 // being discoverable in another one of these iterations.
605 // Using `instantiate_canonical_with_fresh_inference_vars` on our
606 // `Canonical<QueryResponse<Ty<'tcx>>>` and then *throwing away* the
607 // `CanonicalVarValues` will exactly give us such a generalization - it
608 // will still match the original object type, but it won't pollute our
609 // type variables in any form, so just do that!
610 let (QueryResponse { value: generalized_self_ty, .. }, _ignored_var_values) =
612 .instantiate_canonical_with_fresh_inference_vars(self.span, &self_ty);
614 self.assemble_inherent_candidates_from_object(generalized_self_ty);
615 self.assemble_inherent_impl_candidates_for_type(p.def_id());
619 self.assemble_inherent_impl_candidates_for_type(def.did);
621 ty::Foreign(did) => {
622 self.assemble_inherent_impl_candidates_for_type(did);
625 self.assemble_inherent_candidates_from_param(p);
628 let lang_def_id = lang_items.bool_impl();
629 self.assemble_inherent_impl_for_primitive(lang_def_id);
632 let lang_def_id = lang_items.char_impl();
633 self.assemble_inherent_impl_for_primitive(lang_def_id);
636 let lang_def_id = lang_items.str_impl();
637 self.assemble_inherent_impl_for_primitive(lang_def_id);
639 let lang_def_id = lang_items.str_alloc_impl();
640 self.assemble_inherent_impl_for_primitive(lang_def_id);
643 for &lang_def_id in &[
644 lang_items.slice_impl(),
645 lang_items.slice_u8_impl(),
646 lang_items.slice_alloc_impl(),
647 lang_items.slice_u8_alloc_impl(),
649 self.assemble_inherent_impl_for_primitive(lang_def_id);
652 ty::RawPtr(ty::TypeAndMut { ty: _, mutbl }) => {
653 let (lang_def_id1, lang_def_id2) = match mutbl {
654 hir::Mutability::Not => {
655 (lang_items.const_ptr_impl(), lang_items.const_slice_ptr_impl())
657 hir::Mutability::Mut => {
658 (lang_items.mut_ptr_impl(), lang_items.mut_slice_ptr_impl())
661 self.assemble_inherent_impl_for_primitive(lang_def_id1);
662 self.assemble_inherent_impl_for_primitive(lang_def_id2);
665 let lang_def_id = match i {
666 ast::IntTy::I8 => lang_items.i8_impl(),
667 ast::IntTy::I16 => lang_items.i16_impl(),
668 ast::IntTy::I32 => lang_items.i32_impl(),
669 ast::IntTy::I64 => lang_items.i64_impl(),
670 ast::IntTy::I128 => lang_items.i128_impl(),
671 ast::IntTy::Isize => lang_items.isize_impl(),
673 self.assemble_inherent_impl_for_primitive(lang_def_id);
676 let lang_def_id = match i {
677 ast::UintTy::U8 => lang_items.u8_impl(),
678 ast::UintTy::U16 => lang_items.u16_impl(),
679 ast::UintTy::U32 => lang_items.u32_impl(),
680 ast::UintTy::U64 => lang_items.u64_impl(),
681 ast::UintTy::U128 => lang_items.u128_impl(),
682 ast::UintTy::Usize => lang_items.usize_impl(),
684 self.assemble_inherent_impl_for_primitive(lang_def_id);
687 let (lang_def_id1, lang_def_id2) = match f {
688 ast::FloatTy::F32 => (lang_items.f32_impl(), lang_items.f32_runtime_impl()),
689 ast::FloatTy::F64 => (lang_items.f64_impl(), lang_items.f64_runtime_impl()),
691 self.assemble_inherent_impl_for_primitive(lang_def_id1);
692 self.assemble_inherent_impl_for_primitive(lang_def_id2);
698 fn assemble_inherent_impl_for_primitive(&mut self, lang_def_id: Option<DefId>) {
699 if let Some(impl_def_id) = lang_def_id {
700 self.assemble_inherent_impl_probe(impl_def_id);
704 fn assemble_inherent_impl_candidates_for_type(&mut self, def_id: DefId) {
705 let impl_def_ids = self.tcx.at(self.span).inherent_impls(def_id);
706 for &impl_def_id in impl_def_ids.iter() {
707 self.assemble_inherent_impl_probe(impl_def_id);
711 fn assemble_inherent_impl_probe(&mut self, impl_def_id: DefId) {
712 if !self.impl_dups.insert(impl_def_id) {
713 return; // already visited
716 debug!("assemble_inherent_impl_probe {:?}", impl_def_id);
718 for item in self.impl_or_trait_item(impl_def_id) {
719 if !self.has_applicable_self(&item) {
720 // No receiver declared. Not a candidate.
721 self.record_static_candidate(ImplSource(impl_def_id));
725 let (impl_ty, impl_substs) = self.impl_ty_and_substs(impl_def_id);
726 let impl_ty = impl_ty.subst(self.tcx, impl_substs);
728 // Determine the receiver type that the method itself expects.
729 let xform_tys = self.xform_self_ty(&item, impl_ty, impl_substs);
731 // We can't use normalize_associated_types_in as it will pollute the
732 // fcx's fulfillment context after this probe is over.
733 let cause = traits::ObligationCause::misc(self.span, self.body_id);
734 let selcx = &mut traits::SelectionContext::new(self.fcx);
735 let traits::Normalized { value: (xform_self_ty, xform_ret_ty), obligations } =
736 traits::normalize(selcx, self.param_env, cause, &xform_tys);
738 "assemble_inherent_impl_probe: xform_self_ty = {:?}/{:?}",
739 xform_self_ty, xform_ret_ty
747 kind: InherentImplCandidate(impl_substs, obligations),
748 import_ids: smallvec![],
755 fn assemble_inherent_candidates_from_object(&mut self, self_ty: Ty<'tcx>) {
756 debug!("assemble_inherent_candidates_from_object(self_ty={:?})", self_ty);
758 let principal = match self_ty.kind {
759 ty::Dynamic(ref data, ..) => Some(data),
762 .and_then(|data| data.principal())
766 "non-object {:?} in assemble_inherent_candidates_from_object",
771 // It is illegal to invoke a method on a trait instance that
772 // refers to the `Self` type. An error will be reported by
773 // `enforce_object_limitations()` if the method refers to the
774 // `Self` type anywhere other than the receiver. Here, we use
775 // a substitution that replaces `Self` with the object type
776 // itself. Hence, a `&self` method will wind up with an
777 // argument type like `&Trait`.
778 let trait_ref = principal.with_self_ty(self.tcx, self_ty);
779 self.elaborate_bounds(iter::once(trait_ref), |this, new_trait_ref, item| {
780 let new_trait_ref = this.erase_late_bound_regions(&new_trait_ref);
782 let (xform_self_ty, xform_ret_ty) =
783 this.xform_self_ty(&item, new_trait_ref.self_ty(), new_trait_ref.substs);
789 kind: ObjectCandidate,
790 import_ids: smallvec![],
797 fn assemble_inherent_candidates_from_param(&mut self, param_ty: ty::ParamTy) {
798 // FIXME: do we want to commit to this behavior for param bounds?
799 debug!("assemble_inherent_candidates_from_param(param_ty={:?})", param_ty);
802 self.param_env.caller_bounds().iter().map(ty::Predicate::skip_binders).filter_map(
803 |predicate| match predicate {
804 ty::PredicateAtom::Trait(trait_predicate, _) => {
805 match trait_predicate.trait_ref.self_ty().kind {
806 ty::Param(ref p) if *p == param_ty => {
807 Some(ty::Binder::bind(trait_predicate.trait_ref))
812 ty::PredicateAtom::Subtype(..)
813 | ty::PredicateAtom::Projection(..)
814 | ty::PredicateAtom::RegionOutlives(..)
815 | ty::PredicateAtom::WellFormed(..)
816 | ty::PredicateAtom::ObjectSafe(..)
817 | ty::PredicateAtom::ClosureKind(..)
818 | ty::PredicateAtom::TypeOutlives(..)
819 | ty::PredicateAtom::ConstEvaluatable(..)
820 | ty::PredicateAtom::ConstEquate(..) => None,
824 self.elaborate_bounds(bounds, |this, poly_trait_ref, item| {
825 let trait_ref = this.erase_late_bound_regions(&poly_trait_ref);
827 let (xform_self_ty, xform_ret_ty) =
828 this.xform_self_ty(&item, trait_ref.self_ty(), trait_ref.substs);
830 // Because this trait derives from a where-clause, it
831 // should not contain any inference variables or other
832 // artifacts. This means it is safe to put into the
833 // `WhereClauseCandidate` and (eventually) into the
834 // `WhereClausePick`.
835 assert!(!trait_ref.substs.needs_infer());
842 kind: WhereClauseCandidate(poly_trait_ref),
843 import_ids: smallvec![],
850 // Do a search through a list of bounds, using a callback to actually
851 // create the candidates.
852 fn elaborate_bounds<F>(
854 bounds: impl Iterator<Item = ty::PolyTraitRef<'tcx>>,
857 F: for<'b> FnMut(&mut ProbeContext<'b, 'tcx>, ty::PolyTraitRef<'tcx>, ty::AssocItem),
860 for bound_trait_ref in traits::transitive_bounds(tcx, bounds) {
861 debug!("elaborate_bounds(bound_trait_ref={:?})", bound_trait_ref);
862 for item in self.impl_or_trait_item(bound_trait_ref.def_id()) {
863 if !self.has_applicable_self(&item) {
864 self.record_static_candidate(TraitSource(bound_trait_ref.def_id()));
866 mk_cand(self, bound_trait_ref, item);
872 fn assemble_extension_candidates_for_traits_in_scope(
874 expr_hir_id: hir::HirId,
875 ) -> Result<(), MethodError<'tcx>> {
876 let mut duplicates = FxHashSet::default();
877 let opt_applicable_traits = self.tcx.in_scope_traits(expr_hir_id);
878 if let Some(applicable_traits) = opt_applicable_traits {
879 for trait_candidate in applicable_traits.iter() {
880 let trait_did = trait_candidate.def_id;
881 if duplicates.insert(trait_did) {
882 let result = self.assemble_extension_candidates_for_trait(
883 &trait_candidate.import_ids,
893 fn assemble_extension_candidates_for_all_traits(&mut self) -> Result<(), MethodError<'tcx>> {
894 let mut duplicates = FxHashSet::default();
895 for trait_info in suggest::all_traits(self.tcx) {
896 if duplicates.insert(trait_info.def_id) {
897 self.assemble_extension_candidates_for_trait(&smallvec![], trait_info.def_id)?;
903 pub fn matches_return_type(
905 method: &ty::AssocItem,
906 self_ty: Option<Ty<'tcx>>,
910 ty::AssocKind::Fn => {
911 let fty = self.tcx.fn_sig(method.def_id);
913 let substs = self.fresh_substs_for_item(self.span, method.def_id);
914 let fty = fty.subst(self.tcx, substs);
916 self.replace_bound_vars_with_fresh_vars(self.span, infer::FnCall, &fty);
918 if let Some(self_ty) = self_ty {
920 .at(&ObligationCause::dummy(), self.param_env)
921 .sup(fty.inputs()[0], self_ty)
927 self.can_sub(self.param_env, fty.output(), expected).is_ok()
934 fn assemble_extension_candidates_for_trait(
936 import_ids: &SmallVec<[LocalDefId; 1]>,
938 ) -> Result<(), MethodError<'tcx>> {
939 debug!("assemble_extension_candidates_for_trait(trait_def_id={:?})", trait_def_id);
940 let trait_substs = self.fresh_item_substs(trait_def_id);
941 let trait_ref = ty::TraitRef::new(trait_def_id, trait_substs);
943 if self.tcx.is_trait_alias(trait_def_id) {
944 // For trait aliases, assume all super-traits are relevant.
945 let bounds = iter::once(trait_ref.to_poly_trait_ref());
946 self.elaborate_bounds(bounds, |this, new_trait_ref, item| {
947 let new_trait_ref = this.erase_late_bound_regions(&new_trait_ref);
949 let (xform_self_ty, xform_ret_ty) =
950 this.xform_self_ty(&item, new_trait_ref.self_ty(), new_trait_ref.substs);
956 import_ids: import_ids.clone(),
957 kind: TraitCandidate(new_trait_ref),
963 debug_assert!(self.tcx.is_trait(trait_def_id));
964 for item in self.impl_or_trait_item(trait_def_id) {
965 // Check whether `trait_def_id` defines a method with suitable name.
966 if !self.has_applicable_self(&item) {
967 debug!("method has inapplicable self");
968 self.record_static_candidate(TraitSource(trait_def_id));
972 let (xform_self_ty, xform_ret_ty) =
973 self.xform_self_ty(&item, trait_ref.self_ty(), trait_substs);
979 import_ids: import_ids.clone(),
980 kind: TraitCandidate(trait_ref),
989 fn candidate_method_names(&self) -> Vec<Ident> {
990 let mut set = FxHashSet::default();
991 let mut names: Vec<_> = self
994 .chain(&self.extension_candidates)
995 .filter(|candidate| {
996 if let Some(return_ty) = self.return_type {
997 self.matches_return_type(&candidate.item, None, return_ty)
1002 .map(|candidate| candidate.item.ident)
1003 .filter(|&name| set.insert(name))
1006 // Sort them by the name so we have a stable result.
1007 names.sort_by_cached_key(|n| n.as_str());
1011 ///////////////////////////////////////////////////////////////////////////
1012 // THE ACTUAL SEARCH
1014 fn pick(mut self) -> PickResult<'tcx> {
1015 assert!(self.method_name.is_some());
1017 if let Some(r) = self.pick_core() {
1021 debug!("pick: actual search failed, assemble diagnostics");
1023 let static_candidates = mem::take(&mut self.static_candidates);
1024 let private_candidate = self.private_candidate.take();
1025 let unsatisfied_predicates = mem::take(&mut self.unsatisfied_predicates);
1027 // things failed, so lets look at all traits, for diagnostic purposes now:
1030 let span = self.span;
1033 self.assemble_extension_candidates_for_all_traits()?;
1035 let out_of_scope_traits = match self.pick_core() {
1036 Some(Ok(p)) => vec![p.item.container.id()],
1037 //Some(Ok(p)) => p.iter().map(|p| p.item.container().id()).collect(),
1038 Some(Err(MethodError::Ambiguity(v))) => v
1040 .map(|source| match source {
1041 TraitSource(id) => id,
1042 ImplSource(impl_id) => match tcx.trait_id_of_impl(impl_id) {
1044 None => span_bug!(span, "found inherent method when looking at traits"),
1048 Some(Err(MethodError::NoMatch(NoMatchData {
1049 out_of_scope_traits: others, ..
1051 assert!(others.is_empty());
1057 if let Some((kind, def_id)) = private_candidate {
1058 return Err(MethodError::PrivateMatch(kind, def_id, out_of_scope_traits));
1060 let lev_candidate = self.probe_for_lev_candidate()?;
1062 Err(MethodError::NoMatch(NoMatchData::new(
1064 unsatisfied_predicates,
1065 out_of_scope_traits,
1071 fn pick_core(&mut self) -> Option<PickResult<'tcx>> {
1072 let steps = self.steps.clone();
1074 // find the first step that works
1078 debug!("pick_core: step={:?}", step);
1079 // skip types that are from a type error or that would require dereferencing
1081 !step.self_ty.references_error() && !step.from_unsafe_deref
1084 let InferOk { value: self_ty, obligations: _ } = self
1086 .probe_instantiate_query_response(
1088 &self.orig_steps_var_values,
1091 .unwrap_or_else(|_| {
1092 span_bug!(self.span, "{:?} was applicable but now isn't?", step.self_ty)
1094 self.pick_by_value_method(step, self_ty).or_else(|| {
1095 self.pick_autorefd_method(step, self_ty, hir::Mutability::Not)
1096 .or_else(|| self.pick_autorefd_method(step, self_ty, hir::Mutability::Mut))
1102 fn pick_by_value_method(
1104 step: &CandidateStep<'tcx>,
1106 ) -> Option<PickResult<'tcx>> {
1107 //! For each type `T` in the step list, this attempts to find a
1108 //! method where the (transformed) self type is exactly `T`. We
1109 //! do however do one transformation on the adjustment: if we
1110 //! are passing a region pointer in, we will potentially
1111 //! *reborrow* it to a shorter lifetime. This allows us to
1112 //! transparently pass `&mut` pointers, in particular, without
1113 //! consuming them for their entire lifetime.
1119 self.pick_method(self_ty).map(|r| {
1121 pick.autoderefs = step.autoderefs;
1123 // Insert a `&*` or `&mut *` if this is a reference type:
1124 if let ty::Ref(_, _, mutbl) = step.self_ty.value.value.kind {
1125 pick.autoderefs += 1;
1126 pick.autoref = Some(mutbl);
1134 fn pick_autorefd_method(
1136 step: &CandidateStep<'tcx>,
1138 mutbl: hir::Mutability,
1139 ) -> Option<PickResult<'tcx>> {
1142 // In general, during probing we erase regions.
1143 let region = tcx.lifetimes.re_erased;
1145 let autoref_ty = tcx.mk_ref(region, ty::TypeAndMut { ty: self_ty, mutbl });
1146 self.pick_method(autoref_ty).map(|r| {
1148 pick.autoderefs = step.autoderefs;
1149 pick.autoref = Some(mutbl);
1150 pick.unsize = step.unsize.then_some(self_ty);
1156 fn pick_method(&mut self, self_ty: Ty<'tcx>) -> Option<PickResult<'tcx>> {
1157 debug!("pick_method(self_ty={})", self.ty_to_string(self_ty));
1159 let mut possibly_unsatisfied_predicates = Vec::new();
1160 let mut unstable_candidates = Vec::new();
1162 for (kind, candidates) in
1163 &[("inherent", &self.inherent_candidates), ("extension", &self.extension_candidates)]
1165 debug!("searching {} candidates", kind);
1166 let res = self.consider_candidates(
1169 &mut possibly_unsatisfied_predicates,
1170 Some(&mut unstable_candidates),
1172 if let Some(pick) = res {
1173 if !self.is_suggestion.0 && !unstable_candidates.is_empty() {
1174 if let Ok(p) = &pick {
1175 // Emit a lint if there are unstable candidates alongside the stable ones.
1177 // We suppress warning if we're picking the method only because it is a
1179 self.emit_unstable_name_collision_hint(p, &unstable_candidates);
1186 debug!("searching unstable candidates");
1187 let res = self.consider_candidates(
1189 unstable_candidates.into_iter().map(|(c, _)| c),
1190 &mut possibly_unsatisfied_predicates,
1194 self.unsatisfied_predicates.extend(possibly_unsatisfied_predicates);
1199 fn consider_candidates<'b, ProbesIter>(
1203 possibly_unsatisfied_predicates: &mut Vec<(
1204 ty::Predicate<'tcx>,
1205 Option<ty::Predicate<'tcx>>,
1207 unstable_candidates: Option<&mut Vec<(&'b Candidate<'tcx>, Symbol)>>,
1208 ) -> Option<PickResult<'tcx>>
1210 ProbesIter: Iterator<Item = &'b Candidate<'tcx>> + Clone,
1212 let mut applicable_candidates: Vec<_> = probes
1215 (probe, self.consider_probe(self_ty, probe, possibly_unsatisfied_predicates))
1217 .filter(|&(_, status)| status != ProbeResult::NoMatch)
1220 debug!("applicable_candidates: {:?}", applicable_candidates);
1222 if applicable_candidates.len() > 1 {
1223 if let Some(pick) = self.collapse_candidates_to_trait_pick(&applicable_candidates[..]) {
1224 return Some(Ok(pick));
1228 if let Some(uc) = unstable_candidates {
1229 applicable_candidates.retain(|&(p, _)| {
1230 if let stability::EvalResult::Deny { feature, .. } =
1231 self.tcx.eval_stability(p.item.def_id, None, self.span)
1233 uc.push((p, feature));
1240 if applicable_candidates.len() > 1 {
1241 let sources = probes.map(|p| self.candidate_source(p, self_ty)).collect();
1242 return Some(Err(MethodError::Ambiguity(sources)));
1245 applicable_candidates.pop().map(|(probe, status)| {
1246 if status == ProbeResult::Match {
1247 Ok(probe.to_unadjusted_pick())
1249 Err(MethodError::BadReturnType)
1254 fn emit_unstable_name_collision_hint(
1256 stable_pick: &Pick<'_>,
1257 unstable_candidates: &[(&Candidate<'tcx>, Symbol)],
1259 self.tcx.struct_span_lint_hir(
1260 lint::builtin::UNSTABLE_NAME_COLLISIONS,
1264 let mut diag = lint.build(
1265 "a method with this name may be added to the standard library in the future",
1267 // FIXME: This should be a `span_suggestion` instead of `help`
1268 // However `self.span` only
1269 // highlights the method name, so we can't use it. Also consider reusing the code from
1270 // `report_method_error()`.
1272 "call with fully qualified syntax `{}(...)` to keep using the current method",
1273 self.tcx.def_path_str(stable_pick.item.def_id),
1276 if nightly_options::is_nightly_build() {
1277 for (candidate, feature) in unstable_candidates {
1279 "add `#![feature({})]` to the crate attributes to enable `{}`",
1281 self.tcx.def_path_str(candidate.item.def_id),
1291 fn select_trait_candidate(
1293 trait_ref: ty::TraitRef<'tcx>,
1294 ) -> traits::SelectionResult<'tcx, traits::Selection<'tcx>> {
1295 let cause = traits::ObligationCause::misc(self.span, self.body_id);
1296 let predicate = trait_ref.to_poly_trait_ref().to_poly_trait_predicate();
1297 let obligation = traits::Obligation::new(cause, self.param_env, predicate);
1298 traits::SelectionContext::new(self).select(&obligation)
1301 fn candidate_source(&self, candidate: &Candidate<'tcx>, self_ty: Ty<'tcx>) -> CandidateSource {
1302 match candidate.kind {
1303 InherentImplCandidate(..) => ImplSource(candidate.item.container.id()),
1304 ObjectCandidate | WhereClauseCandidate(_) => TraitSource(candidate.item.container.id()),
1305 TraitCandidate(trait_ref) => self.probe(|_| {
1307 .at(&ObligationCause::dummy(), self.param_env)
1308 .sup(candidate.xform_self_ty, self_ty);
1309 match self.select_trait_candidate(trait_ref) {
1310 Ok(Some(traits::ImplSource::ImplSourceUserDefined(ref impl_data))) => {
1311 // If only a single impl matches, make the error message point
1313 ImplSource(impl_data.impl_def_id)
1315 _ => TraitSource(candidate.item.container.id()),
1324 probe: &Candidate<'tcx>,
1325 possibly_unsatisfied_predicates: &mut Vec<(
1326 ty::Predicate<'tcx>,
1327 Option<ty::Predicate<'tcx>>,
1330 debug!("consider_probe: self_ty={:?} probe={:?}", self_ty, probe);
1333 // First check that the self type can be related.
1334 let sub_obligations = match self
1335 .at(&ObligationCause::dummy(), self.param_env)
1336 .sup(probe.xform_self_ty, self_ty)
1338 Ok(InferOk { obligations, value: () }) => obligations,
1340 debug!("--> cannot relate self-types");
1341 return ProbeResult::NoMatch;
1345 let mut result = ProbeResult::Match;
1346 let selcx = &mut traits::SelectionContext::new(self);
1347 let cause = traits::ObligationCause::misc(self.span, self.body_id);
1349 // If so, impls may carry other conditions (e.g., where
1350 // clauses) that must be considered. Make sure that those
1351 // match as well (or at least may match, sometimes we
1352 // don't have enough information to fully evaluate).
1354 InherentImplCandidate(ref substs, ref ref_obligations) => {
1355 // Check whether the impl imposes obligations we have to worry about.
1356 let impl_def_id = probe.item.container.id();
1357 let impl_bounds = self.tcx.predicates_of(impl_def_id);
1358 let impl_bounds = impl_bounds.instantiate(self.tcx, substs);
1359 let traits::Normalized { value: impl_bounds, obligations: norm_obligations } =
1360 traits::normalize(selcx, self.param_env, cause.clone(), &impl_bounds);
1362 // Convert the bounds into obligations.
1363 let impl_obligations =
1364 traits::predicates_for_generics(cause, self.param_env, impl_bounds);
1366 let candidate_obligations = impl_obligations
1367 .chain(norm_obligations.into_iter())
1368 .chain(ref_obligations.iter().cloned());
1369 // Evaluate those obligations to see if they might possibly hold.
1370 for o in candidate_obligations {
1371 let o = self.resolve_vars_if_possible(&o);
1372 if !self.predicate_may_hold(&o) {
1373 result = ProbeResult::NoMatch;
1374 possibly_unsatisfied_predicates.push((o.predicate, None));
1379 ObjectCandidate | WhereClauseCandidate(..) => {
1380 // These have no additional conditions to check.
1383 TraitCandidate(trait_ref) => {
1384 let predicate = trait_ref.without_const().to_predicate(self.tcx);
1385 let obligation = traits::Obligation::new(cause, self.param_env, predicate);
1386 if !self.predicate_may_hold(&obligation) {
1387 result = ProbeResult::NoMatch;
1389 match self.select_trait_candidate(trait_ref) {
1390 Err(_) => return true,
1391 Ok(Some(impl_source))
1392 if !impl_source.borrow_nested_obligations().is_empty() =>
1394 for obligation in impl_source.borrow_nested_obligations() {
1395 // Determine exactly which obligation wasn't met, so
1396 // that we can give more context in the error.
1397 if !self.predicate_may_hold(&obligation) {
1398 let o = self.resolve_vars_if_possible(obligation);
1400 self.resolve_vars_if_possible(&predicate);
1401 let p = if predicate == o.predicate {
1402 // Avoid "`MyStruct: Foo` which is required by
1403 // `MyStruct: Foo`" in E0599.
1408 possibly_unsatisfied_predicates.push((o.predicate, p));
1413 // Some nested subobligation of this predicate
1415 let predicate = self.resolve_vars_if_possible(&predicate);
1416 possibly_unsatisfied_predicates.push((predicate, None));
1421 // This candidate's primary obligation doesn't even
1422 // select - don't bother registering anything in
1423 // `potentially_unsatisfied_predicates`.
1424 return ProbeResult::NoMatch;
1430 // Evaluate those obligations to see if they might possibly hold.
1431 for o in sub_obligations {
1432 let o = self.resolve_vars_if_possible(&o);
1433 if !self.predicate_may_hold(&o) {
1434 result = ProbeResult::NoMatch;
1435 possibly_unsatisfied_predicates.push((o.predicate, None));
1439 if let ProbeResult::Match = result {
1440 if let (Some(return_ty), Some(xform_ret_ty)) =
1441 (self.return_type, probe.xform_ret_ty)
1443 let xform_ret_ty = self.resolve_vars_if_possible(&xform_ret_ty);
1445 "comparing return_ty {:?} with xform ret ty {:?}",
1446 return_ty, probe.xform_ret_ty
1449 .at(&ObligationCause::dummy(), self.param_env)
1450 .sup(return_ty, xform_ret_ty)
1453 return ProbeResult::BadReturnType;
1462 /// Sometimes we get in a situation where we have multiple probes that are all impls of the
1463 /// same trait, but we don't know which impl to use. In this case, since in all cases the
1464 /// external interface of the method can be determined from the trait, it's ok not to decide.
1465 /// We can basically just collapse all of the probes for various impls into one where-clause
1466 /// probe. This will result in a pending obligation so when more type-info is available we can
1467 /// make the final decision.
1469 /// Example (`src/test/ui/method-two-trait-defer-resolution-1.rs`):
1472 /// trait Foo { ... }
1473 /// impl Foo for Vec<i32> { ... }
1474 /// impl Foo for Vec<usize> { ... }
1477 /// Now imagine the receiver is `Vec<_>`. It doesn't really matter at this time which impl we
1478 /// use, so it's ok to just commit to "using the method from the trait Foo".
1479 fn collapse_candidates_to_trait_pick(
1481 probes: &[(&Candidate<'tcx>, ProbeResult)],
1482 ) -> Option<Pick<'tcx>> {
1483 // Do all probes correspond to the same trait?
1484 let container = probes[0].0.item.container;
1485 if let ty::ImplContainer(_) = container {
1488 if probes[1..].iter().any(|&(p, _)| p.item.container != container) {
1492 // FIXME: check the return type here somehow.
1493 // If so, just use this trait and call it a day.
1495 item: probes[0].0.item,
1497 import_ids: probes[0].0.import_ids.clone(),
1504 /// Similarly to `probe_for_return_type`, this method attempts to find the best matching
1505 /// candidate method where the method name may have been misspelt. Similarly to other
1506 /// Levenshtein based suggestions, we provide at most one such suggestion.
1507 fn probe_for_lev_candidate(&mut self) -> Result<Option<ty::AssocItem>, MethodError<'tcx>> {
1508 debug!("probing for method names similar to {:?}", self.method_name);
1510 let steps = self.steps.clone();
1512 let mut pcx = ProbeContext::new(
1518 self.orig_steps_var_values.clone(),
1522 pcx.allow_similar_names = true;
1523 pcx.assemble_inherent_candidates();
1525 let method_names = pcx.candidate_method_names();
1526 pcx.allow_similar_names = false;
1527 let applicable_close_candidates: Vec<ty::AssocItem> = method_names
1529 .filter_map(|&method_name| {
1531 pcx.method_name = Some(method_name);
1532 pcx.assemble_inherent_candidates();
1533 pcx.pick_core().and_then(|pick| pick.ok()).map(|pick| pick.item)
1537 if applicable_close_candidates.is_empty() {
1541 let names = applicable_close_candidates.iter().map(|cand| &cand.ident.name);
1542 find_best_match_for_name(names, self.method_name.unwrap().name, None)
1545 Ok(applicable_close_candidates
1547 .find(|method| method.ident.name == best_name))
1552 ///////////////////////////////////////////////////////////////////////////
1554 fn has_applicable_self(&self, item: &ty::AssocItem) -> bool {
1555 // "Fast track" -- check for usage of sugar when in method call
1558 // In Path mode (i.e., resolving a value like `T::next`), consider any
1559 // associated value (i.e., methods, constants) but not types.
1561 Mode::MethodCall => item.fn_has_self_parameter,
1562 Mode::Path => match item.kind {
1563 ty::AssocKind::Type => false,
1564 ty::AssocKind::Fn | ty::AssocKind::Const => true,
1567 // FIXME -- check for types that deref to `Self`,
1568 // like `Rc<Self>` and so on.
1570 // Note also that the current code will break if this type
1571 // includes any of the type parameters defined on the method
1572 // -- but this could be overcome.
1575 fn record_static_candidate(&mut self, source: CandidateSource) {
1576 self.static_candidates.push(source);
1581 item: &ty::AssocItem,
1583 substs: SubstsRef<'tcx>,
1584 ) -> (Ty<'tcx>, Option<Ty<'tcx>>) {
1585 if item.kind == ty::AssocKind::Fn && self.mode == Mode::MethodCall {
1586 let sig = self.xform_method_sig(item.def_id, substs);
1587 (sig.inputs()[0], Some(sig.output()))
1593 fn xform_method_sig(&self, method: DefId, substs: SubstsRef<'tcx>) -> ty::FnSig<'tcx> {
1594 let fn_sig = self.tcx.fn_sig(method);
1595 debug!("xform_self_ty(fn_sig={:?}, substs={:?})", fn_sig, substs);
1597 assert!(!substs.has_escaping_bound_vars());
1599 // It is possible for type parameters or early-bound lifetimes
1600 // to appear in the signature of `self`. The substitutions we
1601 // are given do not include type/lifetime parameters for the
1602 // method yet. So create fresh variables here for those too,
1603 // if there are any.
1604 let generics = self.tcx.generics_of(method);
1605 assert_eq!(substs.len(), generics.parent_count as usize);
1607 // Erase any late-bound regions from the method and substitute
1608 // in the values from the substitution.
1609 let xform_fn_sig = self.erase_late_bound_regions(&fn_sig);
1611 if generics.params.is_empty() {
1612 xform_fn_sig.subst(self.tcx, substs)
1614 let substs = InternalSubsts::for_item(self.tcx, method, |param, _| {
1615 let i = param.index as usize;
1616 if i < substs.len() {
1620 GenericParamDefKind::Lifetime => {
1621 // In general, during probe we erase regions.
1622 self.tcx.lifetimes.re_erased.into()
1624 GenericParamDefKind::Type { .. } | GenericParamDefKind::Const => {
1625 self.var_for_def(self.span, param)
1630 xform_fn_sig.subst(self.tcx, substs)
1634 /// Gets the type of an impl and generate substitutions with placeholders.
1635 fn impl_ty_and_substs(&self, impl_def_id: DefId) -> (Ty<'tcx>, SubstsRef<'tcx>) {
1636 (self.tcx.type_of(impl_def_id), self.fresh_item_substs(impl_def_id))
1639 fn fresh_item_substs(&self, def_id: DefId) -> SubstsRef<'tcx> {
1640 InternalSubsts::for_item(self.tcx, def_id, |param, _| match param.kind {
1641 GenericParamDefKind::Lifetime => self.tcx.lifetimes.re_erased.into(),
1642 GenericParamDefKind::Type { .. } => self
1643 .next_ty_var(TypeVariableOrigin {
1644 kind: TypeVariableOriginKind::SubstitutionPlaceholder,
1645 span: self.tcx.def_span(def_id),
1648 GenericParamDefKind::Const { .. } => {
1649 let span = self.tcx.def_span(def_id);
1650 let origin = ConstVariableOrigin {
1651 kind: ConstVariableOriginKind::SubstitutionPlaceholder,
1654 self.next_const_var(self.tcx.type_of(param.def_id), origin).into()
1659 /// Replaces late-bound-regions bound by `value` with `'static` using
1660 /// `ty::erase_late_bound_regions`.
1662 /// This is only a reasonable thing to do during the *probe* phase, not the *confirm* phase, of
1663 /// method matching. It is reasonable during the probe phase because we don't consider region
1664 /// relationships at all. Therefore, we can just replace all the region variables with 'static
1665 /// rather than creating fresh region variables. This is nice for two reasons:
1667 /// 1. Because the numbers of the region variables would otherwise be fairly unique to this
1668 /// particular method call, it winds up creating fewer types overall, which helps for memory
1669 /// usage. (Admittedly, this is a rather small effect, though measurable.)
1671 /// 2. It makes it easier to deal with higher-ranked trait bounds, because we can replace any
1672 /// late-bound regions with 'static. Otherwise, if we were going to replace late-bound
1673 /// regions with actual region variables as is proper, we'd have to ensure that the same
1674 /// region got replaced with the same variable, which requires a bit more coordination
1675 /// and/or tracking the substitution and
1677 fn erase_late_bound_regions<T>(&self, value: &ty::Binder<T>) -> T
1679 T: TypeFoldable<'tcx>,
1681 self.tcx.erase_late_bound_regions(value)
1684 /// Finds the method with the appropriate name (or return type, as the case may be). If
1685 /// `allow_similar_names` is set, find methods with close-matching names.
1686 fn impl_or_trait_item(&self, def_id: DefId) -> Vec<ty::AssocItem> {
1687 if let Some(name) = self.method_name {
1688 if self.allow_similar_names {
1689 let max_dist = max(name.as_str().len(), 3) / 3;
1691 .associated_items(def_id)
1692 .in_definition_order()
1694 let dist = lev_distance(&*name.as_str(), &x.ident.as_str());
1695 x.kind.namespace() == Namespace::ValueNS && dist > 0 && dist <= max_dist
1701 .associated_item(def_id, name, Namespace::ValueNS)
1702 .map_or(Vec::new(), |x| vec![x])
1705 self.tcx.associated_items(def_id).in_definition_order().copied().collect()
1710 impl<'tcx> Candidate<'tcx> {
1711 fn to_unadjusted_pick(&self) -> Pick<'tcx> {
1714 kind: match self.kind {
1715 InherentImplCandidate(..) => InherentImplPick,
1716 ObjectCandidate => ObjectPick,
1717 TraitCandidate(_) => TraitPick,
1718 WhereClauseCandidate(ref trait_ref) => {
1719 // Only trait derived from where-clauses should
1720 // appear here, so they should not contain any
1721 // inference variables or other artifacts. This
1722 // means they are safe to put into the
1723 // `WhereClausePick`.
1725 !trait_ref.skip_binder().substs.needs_infer()
1726 && !trait_ref.skip_binder().substs.has_placeholders()
1729 WhereClausePick(*trait_ref)
1732 import_ids: self.import_ids.clone(),