//! Trait Resolution. See the [rustc guide] for more information on how this works. //! //! [rustc guide]: https://rust-lang.github.io/rustc-guide/traits/resolution.html #[allow(dead_code)] pub mod auto_trait; mod chalk_fulfill; mod coherence; pub mod error_reporting; mod engine; mod fulfill; mod project; mod object_safety; mod on_unimplemented; mod select; mod specialize; mod structural_impls; pub mod codegen; mod util; pub mod query; use chalk_engine; use crate::hir; use crate::hir::def_id::DefId; use crate::infer::{InferCtxt, SuppressRegionErrors}; use crate::infer::outlives::env::OutlivesEnvironment; use crate::middle::region; use crate::mir::interpret::ErrorHandled; use rustc_macros::HashStable; use syntax::ast; use syntax_pos::{Span, DUMMY_SP}; use crate::ty::subst::{InternalSubsts, SubstsRef}; use crate::ty::{self, AdtKind, List, Ty, TyCtxt, GenericParamDefKind, ToPredicate}; use crate::ty::error::{ExpectedFound, TypeError}; use crate::ty::fold::{TypeFolder, TypeFoldable, TypeVisitor}; use crate::util::common::ErrorReported; use std::fmt::Debug; use std::rc::Rc; pub use self::SelectionError::*; pub use self::FulfillmentErrorCode::*; pub use self::Vtable::*; pub use self::ObligationCauseCode::*; pub use self::coherence::{add_placeholder_note, orphan_check, overlapping_impls}; pub use self::coherence::{OrphanCheckErr, OverlapResult}; pub use self::fulfill::{FulfillmentContext, PendingPredicateObligation}; pub use self::project::MismatchedProjectionTypes; pub use self::project::{normalize, normalize_projection_type, poly_project_and_unify_type}; pub use self::project::{ProjectionCache, ProjectionCacheSnapshot, Reveal, Normalized}; pub use self::object_safety::ObjectSafetyViolation; pub use self::object_safety::MethodViolationCode; pub use self::on_unimplemented::{OnUnimplementedDirective, OnUnimplementedNote}; pub use self::select::{EvaluationCache, SelectionContext, SelectionCache}; pub use self::select::{EvaluationResult, IntercrateAmbiguityCause, OverflowError}; pub use self::specialize::{OverlapError, specialization_graph, translate_substs}; pub use self::specialize::find_associated_item; pub use self::specialize::specialization_graph::FutureCompatOverlapError; pub use self::specialize::specialization_graph::FutureCompatOverlapErrorKind; pub use self::engine::{TraitEngine, TraitEngineExt}; pub use self::util::{elaborate_predicates, elaborate_trait_ref, elaborate_trait_refs}; pub use self::util::{supertraits, supertrait_def_ids, transitive_bounds, Supertraits, SupertraitDefIds}; pub use self::chalk_fulfill::{ CanonicalGoal as ChalkCanonicalGoal, FulfillmentContext as ChalkFulfillmentContext }; pub use self::ObligationCauseCode::*; pub use self::FulfillmentErrorCode::*; pub use self::SelectionError::*; pub use self::Vtable::*; /// Whether to enable bug compatibility with issue #43355. #[derive(Copy, Clone, PartialEq, Eq, Debug)] pub enum IntercrateMode { Issue43355, Fixed } /// The mode that trait queries run in. #[derive(Copy, Clone, PartialEq, Eq, Debug)] pub enum TraitQueryMode { // Standard/un-canonicalized queries get accurate // spans etc. passed in and hence can do reasonable // error reporting on their own. Standard, // Canonicalized queries get dummy spans and hence // must generally propagate errors to // pre-canonicalization callsites. Canonical, } /// An `Obligation` represents some trait reference (e.g., `int: Eq`) for /// which the vtable must be found. The process of finding a vtable is /// called "resolving" the `Obligation`. This process consists of /// either identifying an `impl` (e.g., `impl Eq for int`) that /// provides the required vtable, or else finding a bound that is in /// scope. The eventual result is usually a `Selection` (defined below). #[derive(Clone, PartialEq, Eq, Hash)] pub struct Obligation<'tcx, T> { /// The reason we have to prove this thing. pub cause: ObligationCause<'tcx>, /// The environment in which we should prove this thing. pub param_env: ty::ParamEnv<'tcx>, /// The thing we are trying to prove. pub predicate: T, /// If we started proving this as a result of trying to prove /// something else, track the total depth to ensure termination. /// If this goes over a certain threshold, we abort compilation -- /// in such cases, we can not say whether or not the predicate /// holds for certain. Stupid halting problem; such a drag. pub recursion_depth: usize, } pub type PredicateObligation<'tcx> = Obligation<'tcx, ty::Predicate<'tcx>>; pub type TraitObligation<'tcx> = Obligation<'tcx, ty::PolyTraitPredicate<'tcx>>; /// The reason why we incurred this obligation; used for error reporting. #[derive(Clone, Debug, PartialEq, Eq, Hash)] pub struct ObligationCause<'tcx> { pub span: Span, /// The ID of the fn body that triggered this obligation. This is /// used for region obligations to determine the precise /// environment in which the region obligation should be evaluated /// (in particular, closures can add new assumptions). See the /// field `region_obligations` of the `FulfillmentContext` for more /// information. pub body_id: hir::HirId, pub code: ObligationCauseCode<'tcx> } impl<'tcx> ObligationCause<'tcx> { pub fn span<'a, 'gcx>(&self, tcx: TyCtxt<'a, 'gcx, 'tcx>) -> Span { match self.code { ObligationCauseCode::CompareImplMethodObligation { .. } | ObligationCauseCode::MainFunctionType | ObligationCauseCode::StartFunctionType => { tcx.sess.source_map().def_span(self.span) } ObligationCauseCode::MatchExpressionArm { arm_span, .. } => arm_span, _ => self.span, } } } #[derive(Clone, Debug, PartialEq, Eq, Hash)] pub enum ObligationCauseCode<'tcx> { /// Not well classified or should be obvious from the span. MiscObligation, /// A slice or array is WF only if `T: Sized`. SliceOrArrayElem, /// A tuple is WF only if its middle elements are `Sized`. TupleElem, /// This is the trait reference from the given projection. ProjectionWf(ty::ProjectionTy<'tcx>), /// In an impl of trait `X` for type `Y`, type `Y` must /// also implement all supertraits of `X`. ItemObligation(DefId), /// A type like `&'a T` is WF only if `T: 'a`. ReferenceOutlivesReferent(Ty<'tcx>), /// A type like `Box + 'b>` is WF only if `'b: 'a`. ObjectTypeBound(Ty<'tcx>, ty::Region<'tcx>), /// Obligation incurred due to an object cast. ObjectCastObligation(/* Object type */ Ty<'tcx>), // Various cases where expressions must be sized/copy/etc: /// L = X implies that L is Sized AssignmentLhsSized, /// (x1, .., xn) must be Sized TupleInitializerSized, /// S { ... } must be Sized StructInitializerSized, /// Type of each variable must be Sized VariableType(ast::NodeId), /// Argument type must be Sized SizedArgumentType, /// Return type must be Sized SizedReturnType, /// Yield type must be Sized SizedYieldType, /// [T,..n] --> T must be Copy RepeatVec, /// Types of fields (other than the last, except for packed structs) in a struct must be sized. FieldSized { adt_kind: AdtKind, last: bool }, /// Constant expressions must be sized. ConstSized, /// static items must have `Sync` type SharedStatic, BuiltinDerivedObligation(DerivedObligationCause<'tcx>), ImplDerivedObligation(DerivedObligationCause<'tcx>), /// error derived when matching traits/impls; see ObligationCause for more details CompareImplMethodObligation { item_name: ast::Name, impl_item_def_id: DefId, trait_item_def_id: DefId, }, /// Checking that this expression can be assigned where it needs to be // FIXME(eddyb) #11161 is the original Expr required? ExprAssignable, /// Computing common supertype in the arms of a match expression MatchExpressionArm { arm_span: Span, source: hir::MatchSource, prior_arms: Vec, last_ty: Ty<'tcx>, discrim_hir_id: hir::HirId, }, /// Computing common supertype in the pattern guard for the arms of a match expression MatchExpressionArmPattern { span: Span, ty: Ty<'tcx> }, /// Computing common supertype in an if expression IfExpression { then: Span, outer: Option, semicolon: Option, }, /// Computing common supertype of an if expression with no else counter-part IfExpressionWithNoElse, /// `main` has wrong type MainFunctionType, /// `start` has wrong type StartFunctionType, /// intrinsic has wrong type IntrinsicType, /// method receiver MethodReceiver, /// `return` with no expression ReturnNoExpression, /// `return` with an expression ReturnType(hir::HirId), /// Block implicit return BlockTailExpression(hir::HirId), /// #[feature(trivial_bounds)] is not enabled TrivialBound, } #[derive(Clone, Debug, PartialEq, Eq, Hash)] pub struct DerivedObligationCause<'tcx> { /// The trait reference of the parent obligation that led to the /// current obligation. Note that only trait obligations lead to /// derived obligations, so we just store the trait reference here /// directly. parent_trait_ref: ty::PolyTraitRef<'tcx>, /// The parent trait had this cause. parent_code: Rc> } pub type Obligations<'tcx, O> = Vec>; pub type PredicateObligations<'tcx> = Vec>; pub type TraitObligations<'tcx> = Vec>; /// The following types: /// * `WhereClause`, /// * `WellFormed`, /// * `FromEnv`, /// * `DomainGoal`, /// * `Goal`, /// * `Clause`, /// * `Environment`, /// * `InEnvironment`, /// are used for representing the trait system in the form of /// logic programming clauses. They are part of the interface /// for the chalk SLG solver. #[derive(Clone, Copy, PartialEq, Eq, Hash, Debug, HashStable)] pub enum WhereClause<'tcx> { Implemented(ty::TraitPredicate<'tcx>), ProjectionEq(ty::ProjectionPredicate<'tcx>), RegionOutlives(ty::RegionOutlivesPredicate<'tcx>), TypeOutlives(ty::TypeOutlivesPredicate<'tcx>), } #[derive(Clone, Copy, PartialEq, Eq, Hash, Debug, HashStable)] pub enum WellFormed<'tcx> { Trait(ty::TraitPredicate<'tcx>), Ty(Ty<'tcx>), } #[derive(Clone, Copy, PartialEq, Eq, Hash, Debug, HashStable)] pub enum FromEnv<'tcx> { Trait(ty::TraitPredicate<'tcx>), Ty(Ty<'tcx>), } #[derive(Clone, Copy, PartialEq, Eq, Hash, Debug, HashStable)] pub enum DomainGoal<'tcx> { Holds(WhereClause<'tcx>), WellFormed(WellFormed<'tcx>), FromEnv(FromEnv<'tcx>), Normalize(ty::ProjectionPredicate<'tcx>), } pub type PolyDomainGoal<'tcx> = ty::Binder>; #[derive(Copy, Clone, PartialEq, Eq, Hash, Debug, HashStable)] pub enum QuantifierKind { Universal, Existential, } #[derive(Copy, Clone, PartialEq, Eq, Hash, Debug, HashStable)] pub enum GoalKind<'tcx> { Implies(Clauses<'tcx>, Goal<'tcx>), And(Goal<'tcx>, Goal<'tcx>), Not(Goal<'tcx>), DomainGoal(DomainGoal<'tcx>), Quantified(QuantifierKind, ty::Binder>), Subtype(Ty<'tcx>, Ty<'tcx>), CannotProve, } pub type Goal<'tcx> = &'tcx GoalKind<'tcx>; pub type Goals<'tcx> = &'tcx List>; impl<'tcx> DomainGoal<'tcx> { pub fn into_goal(self) -> GoalKind<'tcx> { GoalKind::DomainGoal(self) } pub fn into_program_clause(self) -> ProgramClause<'tcx> { ProgramClause { goal: self, hypotheses: ty::List::empty(), category: ProgramClauseCategory::Other, } } } impl<'tcx> GoalKind<'tcx> { pub fn from_poly_domain_goal<'a, 'gcx>( domain_goal: PolyDomainGoal<'tcx>, tcx: TyCtxt<'a, 'gcx, 'tcx>, ) -> GoalKind<'tcx> { match domain_goal.no_bound_vars() { Some(p) => p.into_goal(), None => GoalKind::Quantified( QuantifierKind::Universal, domain_goal.map_bound(|p| tcx.mk_goal(p.into_goal())) ), } } } /// This matches the definition from Page 7 of "A Proof Procedure for the Logic of Hereditary /// Harrop Formulas". #[derive(Copy, Clone, PartialEq, Eq, Hash, Debug, HashStable)] pub enum Clause<'tcx> { Implies(ProgramClause<'tcx>), ForAll(ty::Binder>), } impl Clause<'tcx> { pub fn category(self) -> ProgramClauseCategory { match self { Clause::Implies(clause) => clause.category, Clause::ForAll(clause) => clause.skip_binder().category, } } } /// Multiple clauses. pub type Clauses<'tcx> = &'tcx List>; /// A "program clause" has the form `D :- G1, ..., Gn`. It is saying /// that the domain goal `D` is true if `G1...Gn` are provable. This /// is equivalent to the implication `G1..Gn => D`; we usually write /// it with the reverse implication operator `:-` to emphasize the way /// that programs are actually solved (via backchaining, which starts /// with the goal to solve and proceeds from there). #[derive(Copy, Clone, PartialEq, Eq, Hash, Debug, HashStable)] pub struct ProgramClause<'tcx> { /// This goal will be considered true ... pub goal: DomainGoal<'tcx>, /// ... if we can prove these hypotheses (there may be no hypotheses at all): pub hypotheses: Goals<'tcx>, /// Useful for filtering clauses. pub category: ProgramClauseCategory, } #[derive(Copy, Clone, PartialEq, Eq, Hash, Debug, HashStable)] pub enum ProgramClauseCategory { ImpliedBound, WellFormed, Other, } /// A set of clauses that we assume to be true. #[derive(Copy, Clone, PartialEq, Eq, Hash, Debug, HashStable)] pub struct Environment<'tcx> { pub clauses: Clauses<'tcx>, } impl Environment<'tcx> { pub fn with(self, goal: G) -> InEnvironment<'tcx, G> { InEnvironment { environment: self, goal, } } } /// Something (usually a goal), along with an environment. #[derive(Copy, Clone, PartialEq, Eq, Hash, Debug, HashStable)] pub struct InEnvironment<'tcx, G> { pub environment: Environment<'tcx>, pub goal: G, } pub type Selection<'tcx> = Vtable<'tcx, PredicateObligation<'tcx>>; #[derive(Clone,Debug)] pub enum SelectionError<'tcx> { Unimplemented, OutputTypeParameterMismatch(ty::PolyTraitRef<'tcx>, ty::PolyTraitRef<'tcx>, ty::error::TypeError<'tcx>), TraitNotObjectSafe(DefId), ConstEvalFailure(ErrorHandled), Overflow, } pub struct FulfillmentError<'tcx> { pub obligation: PredicateObligation<'tcx>, pub code: FulfillmentErrorCode<'tcx> } #[derive(Clone)] pub enum FulfillmentErrorCode<'tcx> { CodeSelectionError(SelectionError<'tcx>), CodeProjectionError(MismatchedProjectionTypes<'tcx>), CodeSubtypeError(ExpectedFound>, TypeError<'tcx>), // always comes from a SubtypePredicate CodeAmbiguity, } /// When performing resolution, it is typically the case that there /// can be one of three outcomes: /// /// - `Ok(Some(r))`: success occurred with result `r` /// - `Ok(None)`: could not definitely determine anything, usually due /// to inconclusive type inference. /// - `Err(e)`: error `e` occurred pub type SelectionResult<'tcx, T> = Result, SelectionError<'tcx>>; /// Given the successful resolution of an obligation, the `Vtable` /// indicates where the vtable comes from. Note that while we call this /// a "vtable", it does not necessarily indicate dynamic dispatch at /// runtime. `Vtable` instances just tell the compiler where to find /// methods, but in generic code those methods are typically statically /// dispatched -- only when an object is constructed is a `Vtable` /// instance reified into an actual vtable. /// /// For example, the vtable may be tied to a specific impl (case A), /// or it may be relative to some bound that is in scope (case B). /// /// ``` /// impl Clone for Option { ... } // Impl_1 /// impl Clone for Box { ... } // Impl_2 /// impl Clone for int { ... } // Impl_3 /// /// fn foo(concrete: Option>, /// param: T, /// mixed: Option) { /// /// // Case A: Vtable points at a specific impl. Only possible when /// // type is concretely known. If the impl itself has bounded /// // type parameters, Vtable will carry resolutions for those as well: /// concrete.clone(); // Vtable(Impl_1, [Vtable(Impl_2, [Vtable(Impl_3)])]) /// /// // Case B: Vtable must be provided by caller. This applies when /// // type is a type parameter. /// param.clone(); // VtableParam /// /// // Case C: A mix of cases A and B. /// mixed.clone(); // Vtable(Impl_1, [VtableParam]) /// } /// ``` /// /// ### The type parameter `N` /// /// See explanation on `VtableImplData`. #[derive(Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, HashStable)] pub enum Vtable<'tcx, N> { /// Vtable identifying a particular impl. VtableImpl(VtableImplData<'tcx, N>), /// Vtable for auto trait implementations. /// This carries the information and nested obligations with regards /// to an auto implementation for a trait `Trait`. The nested obligations /// ensure the trait implementation holds for all the constituent types. VtableAutoImpl(VtableAutoImplData), /// Successful resolution to an obligation provided by the caller /// for some type parameter. The `Vec` represents the /// obligations incurred from normalizing the where-clause (if /// any). VtableParam(Vec), /// Virtual calls through an object. VtableObject(VtableObjectData<'tcx, N>), /// Successful resolution for a builtin trait. VtableBuiltin(VtableBuiltinData), /// Vtable automatically generated for a closure. The `DefId` is the ID /// of the closure expression. This is a `VtableImpl` in spirit, but the /// impl is generated by the compiler and does not appear in the source. VtableClosure(VtableClosureData<'tcx, N>), /// Same as above, but for a function pointer type with the given signature. VtableFnPointer(VtableFnPointerData<'tcx, N>), /// Vtable automatically generated for a generator. VtableGenerator(VtableGeneratorData<'tcx, N>), /// Vtable for a trait alias. VtableTraitAlias(VtableTraitAliasData<'tcx, N>), } /// Identifies a particular impl in the source, along with a set of /// substitutions from the impl's type/lifetime parameters. The /// `nested` vector corresponds to the nested obligations attached to /// the impl's type parameters. /// /// The type parameter `N` indicates the type used for "nested /// obligations" that are required by the impl. During type check, this /// is `Obligation`, as one might expect. During codegen, however, this /// is `()`, because codegen only requires a shallow resolution of an /// impl, and nested obligations are satisfied later. #[derive(Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, HashStable)] pub struct VtableImplData<'tcx, N> { pub impl_def_id: DefId, pub substs: SubstsRef<'tcx>, pub nested: Vec } #[derive(Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, HashStable)] pub struct VtableGeneratorData<'tcx, N> { pub generator_def_id: DefId, pub substs: ty::GeneratorSubsts<'tcx>, /// Nested obligations. This can be non-empty if the generator /// signature contains associated types. pub nested: Vec } #[derive(Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, HashStable)] pub struct VtableClosureData<'tcx, N> { pub closure_def_id: DefId, pub substs: ty::ClosureSubsts<'tcx>, /// Nested obligations. This can be non-empty if the closure /// signature contains associated types. pub nested: Vec } #[derive(Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, HashStable)] pub struct VtableAutoImplData { pub trait_def_id: DefId, pub nested: Vec } #[derive(Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, HashStable)] pub struct VtableBuiltinData { pub nested: Vec } /// A vtable for some object-safe trait `Foo` automatically derived /// for the object type `Foo`. #[derive(PartialEq, Eq, Clone, RustcEncodable, RustcDecodable, HashStable)] pub struct VtableObjectData<'tcx, N> { /// `Foo` upcast to the obligation trait. This will be some supertrait of `Foo`. pub upcast_trait_ref: ty::PolyTraitRef<'tcx>, /// The vtable is formed by concatenating together the method lists of /// the base object trait and all supertraits; this is the start of /// `upcast_trait_ref`'s methods in that vtable. pub vtable_base: usize, pub nested: Vec, } #[derive(Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, HashStable)] pub struct VtableFnPointerData<'tcx, N> { pub fn_ty: Ty<'tcx>, pub nested: Vec } #[derive(Clone, PartialEq, Eq, RustcEncodable, RustcDecodable, HashStable)] pub struct VtableTraitAliasData<'tcx, N> { pub alias_def_id: DefId, pub substs: SubstsRef<'tcx>, pub nested: Vec, } /// Creates predicate obligations from the generic bounds. pub fn predicates_for_generics<'tcx>(cause: ObligationCause<'tcx>, param_env: ty::ParamEnv<'tcx>, generic_bounds: &ty::InstantiatedPredicates<'tcx>) -> PredicateObligations<'tcx> { util::predicates_for_generics(cause, 0, param_env, generic_bounds) } /// Determines whether the type `ty` is known to meet `bound` and /// returns true if so. Returns false if `ty` either does not meet /// `bound` or is not known to meet bound (note that this is /// conservative towards *no impl*, which is the opposite of the /// `evaluate` methods). pub fn type_known_to_meet_bound_modulo_regions<'a, 'gcx, 'tcx>( infcx: &InferCtxt<'a, 'gcx, 'tcx>, param_env: ty::ParamEnv<'tcx>, ty: Ty<'tcx>, def_id: DefId, span: Span, ) -> bool { debug!("type_known_to_meet_bound_modulo_regions(ty={:?}, bound={:?})", ty, infcx.tcx.def_path_str(def_id)); let trait_ref = ty::TraitRef { def_id, substs: infcx.tcx.mk_substs_trait(ty, &[]), }; let obligation = Obligation { param_env, cause: ObligationCause::misc(span, hir::DUMMY_HIR_ID), recursion_depth: 0, predicate: trait_ref.to_predicate(), }; let result = infcx.predicate_must_hold_modulo_regions(&obligation); debug!("type_known_to_meet_ty={:?} bound={} => {:?}", ty, infcx.tcx.def_path_str(def_id), result); if result && (ty.has_infer_types() || ty.has_closure_types()) { // Because of inference "guessing", selection can sometimes claim // to succeed while the success requires a guess. To ensure // this function's result remains infallible, we must confirm // that guess. While imperfect, I believe this is sound. // The handling of regions in this area of the code is terrible, // see issue #29149. We should be able to improve on this with // NLL. let mut fulfill_cx = FulfillmentContext::new_ignoring_regions(); // We can use a dummy node-id here because we won't pay any mind // to region obligations that arise (there shouldn't really be any // anyhow). let cause = ObligationCause::misc(span, hir::DUMMY_HIR_ID); fulfill_cx.register_bound(infcx, param_env, ty, def_id, cause); // Note: we only assume something is `Copy` if we can // *definitively* show that it implements `Copy`. Otherwise, // assume it is move; linear is always ok. match fulfill_cx.select_all_or_error(infcx) { Ok(()) => { debug!("type_known_to_meet_bound_modulo_regions: ty={:?} bound={} success", ty, infcx.tcx.def_path_str(def_id)); true } Err(e) => { debug!("type_known_to_meet_bound_modulo_regions: ty={:?} bound={} errors={:?}", ty, infcx.tcx.def_path_str(def_id), e); false } } } else { result } } fn do_normalize_predicates<'a, 'tcx>(tcx: TyCtxt<'a, 'tcx, 'tcx>, region_context: DefId, cause: ObligationCause<'tcx>, elaborated_env: ty::ParamEnv<'tcx>, predicates: Vec>) -> Result>, ErrorReported> { debug!( "do_normalize_predicates(predicates={:?}, region_context={:?}, cause={:?})", predicates, region_context, cause, ); let span = cause.span; tcx.infer_ctxt().enter(|infcx| { // FIXME. We should really... do something with these region // obligations. But this call just continues the older // behavior (i.e., doesn't cause any new bugs), and it would // take some further refactoring to actually solve them. In // particular, we would have to handle implied bounds // properly, and that code is currently largely confined to // regionck (though I made some efforts to extract it // out). -nmatsakis // // @arielby: In any case, these obligations are checked // by wfcheck anyway, so I'm not sure we have to check // them here too, and we will remove this function when // we move over to lazy normalization *anyway*. let fulfill_cx = FulfillmentContext::new_ignoring_regions(); let predicates = match fully_normalize( &infcx, fulfill_cx, cause, elaborated_env, &predicates, ) { Ok(predicates) => predicates, Err(errors) => { infcx.report_fulfillment_errors(&errors, None, false); return Err(ErrorReported) } }; debug!("do_normalize_predictes: normalized predicates = {:?}", predicates); let region_scope_tree = region::ScopeTree::default(); // We can use the `elaborated_env` here; the region code only // cares about declarations like `'a: 'b`. let outlives_env = OutlivesEnvironment::new(elaborated_env); infcx.resolve_regions_and_report_errors( region_context, ®ion_scope_tree, &outlives_env, SuppressRegionErrors::default(), ); let predicates = match infcx.fully_resolve(&predicates) { Ok(predicates) => predicates, Err(fixup_err) => { // If we encounter a fixup error, it means that some type // variable wound up unconstrained. I actually don't know // if this can happen, and I certainly don't expect it to // happen often, but if it did happen it probably // represents a legitimate failure due to some kind of // unconstrained variable, and it seems better not to ICE, // all things considered. tcx.sess.span_err(span, &fixup_err.to_string()); return Err(ErrorReported) } }; match tcx.lift_to_global(&predicates) { Some(predicates) => Ok(predicates), None => { // FIXME: shouldn't we, you know, actually report an error here? or an ICE? Err(ErrorReported) } } }) } // FIXME: this is gonna need to be removed ... /// Normalizes the parameter environment, reporting errors if they occur. pub fn normalize_param_env_or_error<'a, 'tcx>(tcx: TyCtxt<'a, 'tcx, 'tcx>, region_context: DefId, unnormalized_env: ty::ParamEnv<'tcx>, cause: ObligationCause<'tcx>) -> ty::ParamEnv<'tcx> { // I'm not wild about reporting errors here; I'd prefer to // have the errors get reported at a defined place (e.g., // during typeck). Instead I have all parameter // environments, in effect, going through this function // and hence potentially reporting errors. This ensures of // course that we never forget to normalize (the // alternative seemed like it would involve a lot of // manual invocations of this fn -- and then we'd have to // deal with the errors at each of those sites). // // In any case, in practice, typeck constructs all the // parameter environments once for every fn as it goes, // and errors will get reported then; so after typeck we // can be sure that no errors should occur. debug!("normalize_param_env_or_error(region_context={:?}, unnormalized_env={:?}, cause={:?})", region_context, unnormalized_env, cause); let mut predicates: Vec<_> = util::elaborate_predicates(tcx, unnormalized_env.caller_bounds.to_vec()) .collect(); debug!("normalize_param_env_or_error: elaborated-predicates={:?}", predicates); let elaborated_env = ty::ParamEnv::new( tcx.intern_predicates(&predicates), unnormalized_env.reveal, unnormalized_env.def_id ); // HACK: we are trying to normalize the param-env inside *itself*. The problem is that // normalization expects its param-env to be already normalized, which means we have // a circularity. // // The way we handle this is by normalizing the param-env inside an unnormalized version // of the param-env, which means that if the param-env contains unnormalized projections, // we'll have some normalization failures. This is unfortunate. // // Lazy normalization would basically handle this by treating just the // normalizing-a-trait-ref-requires-itself cycles as evaluation failures. // // Inferred outlives bounds can create a lot of `TypeOutlives` predicates for associated // types, so to make the situation less bad, we normalize all the predicates *but* // the `TypeOutlives` predicates first inside the unnormalized parameter environment, and // then we normalize the `TypeOutlives` bounds inside the normalized parameter environment. // // This works fairly well because trait matching does not actually care about param-env // TypeOutlives predicates - these are normally used by regionck. let outlives_predicates: Vec<_> = predicates.drain_filter(|predicate| { match predicate { ty::Predicate::TypeOutlives(..) => true, _ => false } }).collect(); debug!("normalize_param_env_or_error: predicates=(non-outlives={:?}, outlives={:?})", predicates, outlives_predicates); let non_outlives_predicates = match do_normalize_predicates(tcx, region_context, cause.clone(), elaborated_env, predicates) { Ok(predicates) => predicates, // An unnormalized env is better than nothing. Err(ErrorReported) => { debug!("normalize_param_env_or_error: errored resolving non-outlives predicates"); return elaborated_env } }; debug!("normalize_param_env_or_error: non-outlives predicates={:?}", non_outlives_predicates); // Not sure whether it is better to include the unnormalized TypeOutlives predicates // here. I believe they should not matter, because we are ignoring TypeOutlives param-env // predicates here anyway. Keeping them here anyway because it seems safer. let outlives_env: Vec<_> = non_outlives_predicates.iter().chain(&outlives_predicates).cloned().collect(); let outlives_env = ty::ParamEnv::new( tcx.intern_predicates(&outlives_env), unnormalized_env.reveal, None ); let outlives_predicates = match do_normalize_predicates(tcx, region_context, cause, outlives_env, outlives_predicates) { Ok(predicates) => predicates, // An unnormalized env is better than nothing. Err(ErrorReported) => { debug!("normalize_param_env_or_error: errored resolving outlives predicates"); return elaborated_env } }; debug!("normalize_param_env_or_error: outlives predicates={:?}", outlives_predicates); let mut predicates = non_outlives_predicates; predicates.extend(outlives_predicates); debug!("normalize_param_env_or_error: final predicates={:?}", predicates); ty::ParamEnv::new( tcx.intern_predicates(&predicates), unnormalized_env.reveal, unnormalized_env.def_id ) } pub fn fully_normalize<'a, 'gcx, 'tcx, T>( infcx: &InferCtxt<'a, 'gcx, 'tcx>, mut fulfill_cx: FulfillmentContext<'tcx>, cause: ObligationCause<'tcx>, param_env: ty::ParamEnv<'tcx>, value: &T) -> Result>> where T : TypeFoldable<'tcx> { debug!("fully_normalize_with_fulfillcx(value={:?})", value); let selcx = &mut SelectionContext::new(infcx); let Normalized { value: normalized_value, obligations } = project::normalize(selcx, param_env, cause, value); debug!("fully_normalize: normalized_value={:?} obligations={:?}", normalized_value, obligations); for obligation in obligations { fulfill_cx.register_predicate_obligation(selcx.infcx(), obligation); } debug!("fully_normalize: select_all_or_error start"); fulfill_cx.select_all_or_error(infcx)?; debug!("fully_normalize: select_all_or_error complete"); let resolved_value = infcx.resolve_type_vars_if_possible(&normalized_value); debug!("fully_normalize: resolved_value={:?}", resolved_value); Ok(resolved_value) } /// Normalizes the predicates and checks whether they hold in an empty /// environment. If this returns false, then either normalize /// encountered an error or one of the predicates did not hold. Used /// when creating vtables to check for unsatisfiable methods. fn normalize_and_test_predicates<'a, 'tcx>(tcx: TyCtxt<'a, 'tcx, 'tcx>, predicates: Vec>) -> bool { debug!("normalize_and_test_predicates(predicates={:?})", predicates); let result = tcx.infer_ctxt().enter(|infcx| { let param_env = ty::ParamEnv::reveal_all(); let mut selcx = SelectionContext::new(&infcx); let mut fulfill_cx = FulfillmentContext::new(); let cause = ObligationCause::dummy(); let Normalized { value: predicates, obligations } = normalize(&mut selcx, param_env, cause.clone(), &predicates); for obligation in obligations { fulfill_cx.register_predicate_obligation(&infcx, obligation); } for predicate in predicates { let obligation = Obligation::new(cause.clone(), param_env, predicate); fulfill_cx.register_predicate_obligation(&infcx, obligation); } fulfill_cx.select_all_or_error(&infcx).is_ok() }); debug!("normalize_and_test_predicates(predicates={:?}) = {:?}", predicates, result); result } fn substitute_normalize_and_test_predicates<'a, 'tcx>(tcx: TyCtxt<'a, 'tcx, 'tcx>, key: (DefId, SubstsRef<'tcx>)) -> bool { debug!("substitute_normalize_and_test_predicates(key={:?})", key); let predicates = tcx.predicates_of(key.0).instantiate(tcx, key.1).predicates; let result = normalize_and_test_predicates(tcx, predicates); debug!("substitute_normalize_and_test_predicates(key={:?}) = {:?}", key, result); result } /// Given a trait `trait_ref`, iterates the vtable entries /// that come from `trait_ref`, including its supertraits. #[inline] // FIXME(#35870): avoid closures being unexported due to `impl Trait`. fn vtable_methods<'a, 'tcx>( tcx: TyCtxt<'a, 'tcx, 'tcx>, trait_ref: ty::PolyTraitRef<'tcx>) -> &'tcx [Option<(DefId, SubstsRef<'tcx>)>] { debug!("vtable_methods({:?})", trait_ref); tcx.arena.alloc_from_iter( supertraits(tcx, trait_ref).flat_map(move |trait_ref| { let trait_methods = tcx.associated_items(trait_ref.def_id()) .filter(|item| item.kind == ty::AssociatedKind::Method); // Now list each method's DefId and InternalSubsts (for within its trait). // If the method can never be called from this object, produce None. trait_methods.map(move |trait_method| { debug!("vtable_methods: trait_method={:?}", trait_method); let def_id = trait_method.def_id; // Some methods cannot be called on an object; skip those. if !tcx.is_vtable_safe_method(trait_ref.def_id(), &trait_method) { debug!("vtable_methods: not vtable safe"); return None; } // the method may have some early-bound lifetimes, add // regions for those let substs = trait_ref.map_bound(|trait_ref| InternalSubsts::for_item(tcx, def_id, |param, _| match param.kind { GenericParamDefKind::Lifetime => tcx.types.re_erased.into(), GenericParamDefKind::Type { .. } | GenericParamDefKind::Const => { trait_ref.substs[param.index as usize] } } ) ); // the trait type may have higher-ranked lifetimes in it; // so erase them if they appear, so that we get the type // at some particular call site let substs = tcx.normalize_erasing_late_bound_regions( ty::ParamEnv::reveal_all(), &substs ); // It's possible that the method relies on where clauses that // do not hold for this particular set of type parameters. // Note that this method could then never be called, so we // do not want to try and codegen it, in that case (see #23435). let predicates = tcx.predicates_of(def_id).instantiate_own(tcx, substs); if !normalize_and_test_predicates(tcx, predicates.predicates) { debug!("vtable_methods: predicates do not hold"); return None; } Some((def_id, substs)) }) }) ) } impl<'tcx,O> Obligation<'tcx,O> { pub fn new(cause: ObligationCause<'tcx>, param_env: ty::ParamEnv<'tcx>, predicate: O) -> Obligation<'tcx, O> { Obligation { cause, param_env, recursion_depth: 0, predicate } } fn with_depth(cause: ObligationCause<'tcx>, recursion_depth: usize, param_env: ty::ParamEnv<'tcx>, predicate: O) -> Obligation<'tcx, O> { Obligation { cause, param_env, recursion_depth, predicate } } pub fn misc(span: Span, body_id: hir::HirId, param_env: ty::ParamEnv<'tcx>, trait_ref: O) -> Obligation<'tcx, O> { Obligation::new(ObligationCause::misc(span, body_id), param_env, trait_ref) } pub fn with

(&self, value: P) -> Obligation<'tcx,P> { Obligation { cause: self.cause.clone(), param_env: self.param_env, recursion_depth: self.recursion_depth, predicate: value } } } impl<'tcx> ObligationCause<'tcx> { #[inline] pub fn new(span: Span, body_id: hir::HirId, code: ObligationCauseCode<'tcx>) -> ObligationCause<'tcx> { ObligationCause { span, body_id, code } } pub fn misc(span: Span, body_id: hir::HirId) -> ObligationCause<'tcx> { ObligationCause { span, body_id, code: MiscObligation } } pub fn dummy() -> ObligationCause<'tcx> { ObligationCause { span: DUMMY_SP, body_id: hir::CRATE_HIR_ID, code: MiscObligation } } } impl<'tcx, N> Vtable<'tcx, N> { pub fn nested_obligations(self) -> Vec { match self { VtableImpl(i) => i.nested, VtableParam(n) => n, VtableBuiltin(i) => i.nested, VtableAutoImpl(d) => d.nested, VtableClosure(c) => c.nested, VtableGenerator(c) => c.nested, VtableObject(d) => d.nested, VtableFnPointer(d) => d.nested, VtableTraitAlias(d) => d.nested, } } pub fn map(self, f: F) -> Vtable<'tcx, M> where F: FnMut(N) -> M { match self { VtableImpl(i) => VtableImpl(VtableImplData { impl_def_id: i.impl_def_id, substs: i.substs, nested: i.nested.into_iter().map(f).collect(), }), VtableParam(n) => VtableParam(n.into_iter().map(f).collect()), VtableBuiltin(i) => VtableBuiltin(VtableBuiltinData { nested: i.nested.into_iter().map(f).collect(), }), VtableObject(o) => VtableObject(VtableObjectData { upcast_trait_ref: o.upcast_trait_ref, vtable_base: o.vtable_base, nested: o.nested.into_iter().map(f).collect(), }), VtableAutoImpl(d) => VtableAutoImpl(VtableAutoImplData { trait_def_id: d.trait_def_id, nested: d.nested.into_iter().map(f).collect(), }), VtableClosure(c) => VtableClosure(VtableClosureData { closure_def_id: c.closure_def_id, substs: c.substs, nested: c.nested.into_iter().map(f).collect(), }), VtableGenerator(c) => VtableGenerator(VtableGeneratorData { generator_def_id: c.generator_def_id, substs: c.substs, nested: c.nested.into_iter().map(f).collect(), }), VtableFnPointer(p) => VtableFnPointer(VtableFnPointerData { fn_ty: p.fn_ty, nested: p.nested.into_iter().map(f).collect(), }), VtableTraitAlias(d) => VtableTraitAlias(VtableTraitAliasData { alias_def_id: d.alias_def_id, substs: d.substs, nested: d.nested.into_iter().map(f).collect(), }), } } } impl<'tcx> FulfillmentError<'tcx> { fn new(obligation: PredicateObligation<'tcx>, code: FulfillmentErrorCode<'tcx>) -> FulfillmentError<'tcx> { FulfillmentError { obligation: obligation, code: code } } } impl<'tcx> TraitObligation<'tcx> { fn self_ty(&self) -> ty::Binder> { self.predicate.map_bound(|p| p.self_ty()) } } pub fn provide(providers: &mut ty::query::Providers<'_>) { *providers = ty::query::Providers { is_object_safe: object_safety::is_object_safe_provider, specialization_graph_of: specialize::specialization_graph_provider, specializes: specialize::specializes, codegen_fulfill_obligation: codegen::codegen_fulfill_obligation, vtable_methods, substitute_normalize_and_test_predicates, ..*providers }; } pub trait ExClauseFold<'tcx> where Self: chalk_engine::context::Context + Clone, { fn fold_ex_clause_with<'gcx: 'tcx, F: TypeFolder<'gcx, 'tcx>>( ex_clause: &chalk_engine::ExClause, folder: &mut F, ) -> chalk_engine::ExClause; fn visit_ex_clause_with<'gcx: 'tcx, V: TypeVisitor<'tcx>>( ex_clause: &chalk_engine::ExClause, visitor: &mut V, ) -> bool; } pub trait ChalkContextLift<'tcx> where Self: chalk_engine::context::Context + Clone, { type LiftedExClause: Debug + 'tcx; type LiftedDelayedLiteral: Debug + 'tcx; type LiftedLiteral: Debug + 'tcx; fn lift_ex_clause_to_tcx<'a, 'gcx>( ex_clause: &chalk_engine::ExClause, tcx: TyCtxt<'a, 'gcx, 'tcx>, ) -> Option; fn lift_delayed_literal_to_tcx<'a, 'gcx>( ex_clause: &chalk_engine::DelayedLiteral, tcx: TyCtxt<'a, 'gcx, 'tcx>, ) -> Option; fn lift_literal_to_tcx<'a, 'gcx>( ex_clause: &chalk_engine::Literal, tcx: TyCtxt<'a, 'gcx, 'tcx>, ) -> Option; }