| //! "Object safety" refers to the ability for a trait to be converted |
| //! to an object. In general, traits may only be converted to an |
| //! object if all of their methods meet certain criteria. In particular, |
| //! they must: |
| //! |
| //! - have a suitable receiver from which we can extract a vtable and coerce to a "thin" version |
| //! that doesn't contain the vtable; |
| //! - not reference the erased type `Self` except for in this receiver; |
| //! - not have generic type parameters. |
| |
| use super::elaborate_predicates; |
| |
| use crate::hir; |
| use crate::hir::def_id::DefId; |
| use crate::lint; |
| use crate::traits::{self, Obligation, ObligationCause}; |
| use crate::ty::{self, Ty, TyCtxt, TypeFoldable, Predicate, ToPredicate}; |
| use crate::ty::subst::{Subst, InternalSubsts}; |
| use std::borrow::Cow; |
| use std::iter::{self}; |
| use syntax::ast::{self}; |
| use syntax::symbol::Symbol; |
| use syntax_pos::{Span, DUMMY_SP}; |
| |
| #[derive(Copy, Clone, Debug, PartialEq, Eq, Hash)] |
| pub enum ObjectSafetyViolation { |
| /// `Self: Sized` declared on the trait. |
| SizedSelf, |
| |
| /// Supertrait reference references `Self` an in illegal location |
| /// (e.g., `trait Foo : Bar<Self>`). |
| SupertraitSelf, |
| |
| /// Method has something illegal. |
| Method(ast::Name, MethodViolationCode, Span), |
| |
| /// Associated const. |
| AssocConst(ast::Name, Span), |
| } |
| |
| impl ObjectSafetyViolation { |
| pub fn error_msg(&self) -> Cow<'static, str> { |
| match *self { |
| ObjectSafetyViolation::SizedSelf => |
| "the trait cannot require that `Self : Sized`".into(), |
| ObjectSafetyViolation::SupertraitSelf => |
| "the trait cannot use `Self` as a type parameter \ |
| in the supertraits or where-clauses".into(), |
| ObjectSafetyViolation::Method(name, MethodViolationCode::StaticMethod, _) => |
| format!("associated function `{}` has no `self` parameter", name).into(), |
| ObjectSafetyViolation::Method(name, MethodViolationCode::ReferencesSelf, _) => format!( |
| "method `{}` references the `Self` type in its parameters or return type", |
| name, |
| ).into(), |
| ObjectSafetyViolation::Method( |
| name, |
| MethodViolationCode::WhereClauseReferencesSelf, |
| _, |
| ) => format!("method `{}` references the `Self` type in where clauses", name).into(), |
| ObjectSafetyViolation::Method(name, MethodViolationCode::Generic, _) => |
| format!("method `{}` has generic type parameters", name).into(), |
| ObjectSafetyViolation::Method(name, MethodViolationCode::UndispatchableReceiver, _) => |
| format!("method `{}`'s `self` parameter cannot be dispatched on", name).into(), |
| ObjectSafetyViolation::AssocConst(name, _) => |
| format!("the trait cannot contain associated consts like `{}`", name).into(), |
| } |
| } |
| |
| pub fn span(&self) -> Option<Span> { |
| // When `span` comes from a separate crate, it'll be `DUMMY_SP`. Treat it as `None` so |
| // diagnostics use a `note` instead of a `span_label`. |
| match *self { |
| ObjectSafetyViolation::AssocConst(_, span) | |
| ObjectSafetyViolation::Method(_, _, span) if span != DUMMY_SP => Some(span), |
| _ => None, |
| } |
| } |
| } |
| |
| /// Reasons a method might not be object-safe. |
| #[derive(Copy, Clone, Debug, PartialEq, Eq, Hash)] |
| pub enum MethodViolationCode { |
| /// e.g., `fn foo()` |
| StaticMethod, |
| |
| /// e.g., `fn foo(&self, x: Self)` or `fn foo(&self) -> Self` |
| ReferencesSelf, |
| |
| /// e.g., `fn foo(&self) where Self: Clone` |
| WhereClauseReferencesSelf, |
| |
| /// e.g., `fn foo<A>()` |
| Generic, |
| |
| /// the method's receiver (`self` argument) can't be dispatched on |
| UndispatchableReceiver, |
| } |
| |
| impl<'tcx> TyCtxt<'tcx> { |
| /// Returns the object safety violations that affect |
| /// astconv -- currently, `Self` in supertraits. This is needed |
| /// because `object_safety_violations` can't be used during |
| /// type collection. |
| pub fn astconv_object_safety_violations( |
| self, |
| trait_def_id: DefId, |
| ) -> Vec<ObjectSafetyViolation> { |
| debug_assert!(self.generics_of(trait_def_id).has_self); |
| let violations = traits::supertrait_def_ids(self, trait_def_id) |
| .filter(|&def_id| self.predicates_reference_self(def_id, true)) |
| .map(|_| ObjectSafetyViolation::SupertraitSelf) |
| .collect(); |
| |
| debug!("astconv_object_safety_violations(trait_def_id={:?}) = {:?}", |
| trait_def_id, |
| violations); |
| |
| violations |
| } |
| |
| pub fn object_safety_violations(self, trait_def_id: DefId) |
| -> Vec<ObjectSafetyViolation> |
| { |
| debug_assert!(self.generics_of(trait_def_id).has_self); |
| debug!("object_safety_violations: {:?}", trait_def_id); |
| |
| traits::supertrait_def_ids(self, trait_def_id) |
| .flat_map(|def_id| self.object_safety_violations_for_trait(def_id)) |
| .collect() |
| } |
| |
| /// We say a method is *vtable safe* if it can be invoked on a trait |
| /// object. Note that object-safe traits can have some |
| /// non-vtable-safe methods, so long as they require `Self: Sized` or |
| /// otherwise ensure that they cannot be used when `Self = Trait`. |
| pub fn is_vtable_safe_method(self, trait_def_id: DefId, method: &ty::AssocItem) -> bool { |
| debug_assert!(self.generics_of(trait_def_id).has_self); |
| debug!("is_vtable_safe_method({:?}, {:?})", trait_def_id, method); |
| // Any method that has a `Self: Sized` bound cannot be called. |
| if self.generics_require_sized_self(method.def_id) { |
| return false; |
| } |
| |
| match self.virtual_call_violation_for_method(trait_def_id, method) { |
| None | Some(MethodViolationCode::WhereClauseReferencesSelf) => true, |
| Some(_) => false, |
| } |
| } |
| |
| fn object_safety_violations_for_trait(self, trait_def_id: DefId) -> Vec<ObjectSafetyViolation> { |
| // Check methods for violations. |
| let mut violations: Vec<_> = self.associated_items(trait_def_id) |
| .filter(|item| item.kind == ty::AssocKind::Method) |
| .filter_map(|item| |
| self.object_safety_violation_for_method(trait_def_id, &item).map(|code| { |
| ObjectSafetyViolation::Method(item.ident.name, code, item.ident.span) |
| }) |
| ).filter(|violation| { |
| if let ObjectSafetyViolation::Method( |
| _, |
| MethodViolationCode::WhereClauseReferencesSelf, |
| span, |
| ) = violation { |
| // Using `CRATE_NODE_ID` is wrong, but it's hard to get a more precise id. |
| // It's also hard to get a use site span, so we use the method definition span. |
| self.lint_node_note( |
| lint::builtin::WHERE_CLAUSES_OBJECT_SAFETY, |
| hir::CRATE_HIR_ID, |
| *span, |
| &format!("the trait `{}` cannot be made into an object", |
| self.def_path_str(trait_def_id)), |
| &violation.error_msg()); |
| false |
| } else { |
| true |
| } |
| }).collect(); |
| |
| // Check the trait itself. |
| if self.trait_has_sized_self(trait_def_id) { |
| violations.push(ObjectSafetyViolation::SizedSelf); |
| } |
| if self.predicates_reference_self(trait_def_id, false) { |
| violations.push(ObjectSafetyViolation::SupertraitSelf); |
| } |
| |
| violations.extend(self.associated_items(trait_def_id) |
| .filter(|item| item.kind == ty::AssocKind::Const) |
| .map(|item| ObjectSafetyViolation::AssocConst(item.ident.name, item.ident.span))); |
| |
| debug!("object_safety_violations_for_trait(trait_def_id={:?}) = {:?}", |
| trait_def_id, |
| violations); |
| |
| violations |
| } |
| |
| fn predicates_reference_self( |
| self, |
| trait_def_id: DefId, |
| supertraits_only: bool, |
| ) -> bool { |
| let trait_ref = ty::Binder::dummy(ty::TraitRef::identity(self, trait_def_id)); |
| let predicates = if supertraits_only { |
| self.super_predicates_of(trait_def_id) |
| } else { |
| self.predicates_of(trait_def_id) |
| }; |
| let self_ty = self.types.self_param; |
| let has_self_ty = |t: Ty<'tcx>| t.walk().any(|t| t == self_ty); |
| predicates |
| .predicates |
| .iter() |
| .map(|(predicate, _)| predicate.subst_supertrait(self, &trait_ref)) |
| .any(|predicate| { |
| match predicate { |
| ty::Predicate::Trait(ref data) => { |
| // In the case of a trait predicate, we can skip the "self" type. |
| data.skip_binder().input_types().skip(1).any(has_self_ty) |
| } |
| ty::Predicate::Projection(ref data) => { |
| // And similarly for projections. This should be redundant with |
| // the previous check because any projection should have a |
| // matching `Trait` predicate with the same inputs, but we do |
| // the check to be safe. |
| // |
| // Note that we *do* allow projection *outputs* to contain |
| // `self` (i.e., `trait Foo: Bar<Output=Self::Result> { type Result; }`), |
| // we just require the user to specify *both* outputs |
| // in the object type (i.e., `dyn Foo<Output=(), Result=()>`). |
| // |
| // This is ALT2 in issue #56288, see that for discussion of the |
| // possible alternatives. |
| data.skip_binder() |
| .projection_ty |
| .trait_ref(self) |
| .input_types() |
| .skip(1) |
| .any(has_self_ty) |
| } |
| ty::Predicate::WellFormed(..) | |
| ty::Predicate::ObjectSafe(..) | |
| ty::Predicate::TypeOutlives(..) | |
| ty::Predicate::RegionOutlives(..) | |
| ty::Predicate::ClosureKind(..) | |
| ty::Predicate::Subtype(..) | |
| ty::Predicate::ConstEvaluatable(..) => { |
| false |
| } |
| } |
| }) |
| } |
| |
| fn trait_has_sized_self(self, trait_def_id: DefId) -> bool { |
| self.generics_require_sized_self(trait_def_id) |
| } |
| |
| fn generics_require_sized_self(self, def_id: DefId) -> bool { |
| let sized_def_id = match self.lang_items().sized_trait() { |
| Some(def_id) => def_id, |
| None => { return false; /* No Sized trait, can't require it! */ } |
| }; |
| |
| // Search for a predicate like `Self : Sized` amongst the trait bounds. |
| let predicates = self.predicates_of(def_id); |
| let predicates = predicates.instantiate_identity(self).predicates; |
| elaborate_predicates(self, predicates) |
| .any(|predicate| match predicate { |
| ty::Predicate::Trait(ref trait_pred) => { |
| trait_pred.def_id() == sized_def_id |
| && trait_pred.skip_binder().self_ty().is_param(0) |
| } |
| ty::Predicate::Projection(..) | |
| ty::Predicate::Subtype(..) | |
| ty::Predicate::RegionOutlives(..) | |
| ty::Predicate::WellFormed(..) | |
| ty::Predicate::ObjectSafe(..) | |
| ty::Predicate::ClosureKind(..) | |
| ty::Predicate::TypeOutlives(..) | |
| ty::Predicate::ConstEvaluatable(..) => { |
| false |
| } |
| } |
| ) |
| } |
| |
| /// Returns `Some(_)` if this method makes the containing trait not object safe. |
| fn object_safety_violation_for_method( |
| self, |
| trait_def_id: DefId, |
| method: &ty::AssocItem, |
| ) -> Option<MethodViolationCode> { |
| debug!("object_safety_violation_for_method({:?}, {:?})", trait_def_id, method); |
| // Any method that has a `Self : Sized` requisite is otherwise |
| // exempt from the regulations. |
| if self.generics_require_sized_self(method.def_id) { |
| return None; |
| } |
| |
| self.virtual_call_violation_for_method(trait_def_id, method) |
| } |
| |
| /// Returns `Some(_)` if this method cannot be called on a trait |
| /// object; this does not necessarily imply that the enclosing trait |
| /// is not object safe, because the method might have a where clause |
| /// `Self:Sized`. |
| fn virtual_call_violation_for_method( |
| self, |
| trait_def_id: DefId, |
| method: &ty::AssocItem, |
| ) -> Option<MethodViolationCode> { |
| // The method's first parameter must be named `self` |
| if !method.method_has_self_argument { |
| return Some(MethodViolationCode::StaticMethod); |
| } |
| |
| let sig = self.fn_sig(method.def_id); |
| |
| for input_ty in &sig.skip_binder().inputs()[1..] { |
| if self.contains_illegal_self_type_reference(trait_def_id, input_ty) { |
| return Some(MethodViolationCode::ReferencesSelf); |
| } |
| } |
| if self.contains_illegal_self_type_reference(trait_def_id, sig.output().skip_binder()) { |
| return Some(MethodViolationCode::ReferencesSelf); |
| } |
| |
| // We can't monomorphize things like `fn foo<A>(...)`. |
| let own_counts = self.generics_of(method.def_id).own_counts(); |
| if own_counts.types + own_counts.consts != 0 { |
| return Some(MethodViolationCode::Generic); |
| } |
| |
| if self.predicates_of(method.def_id).predicates.iter() |
| // A trait object can't claim to live more than the concrete type, |
| // so outlives predicates will always hold. |
| .cloned() |
| .filter(|(p, _)| p.to_opt_type_outlives().is_none()) |
| .collect::<Vec<_>>() |
| // Do a shallow visit so that `contains_illegal_self_type_reference` |
| // may apply it's custom visiting. |
| .visit_tys_shallow(|t| { |
| self.contains_illegal_self_type_reference(trait_def_id, t) |
| }) { |
| return Some(MethodViolationCode::WhereClauseReferencesSelf); |
| } |
| |
| let receiver_ty = self.liberate_late_bound_regions( |
| method.def_id, |
| &sig.map_bound(|sig| sig.inputs()[0]), |
| ); |
| |
| // Until `unsized_locals` is fully implemented, `self: Self` can't be dispatched on. |
| // However, this is already considered object-safe. We allow it as a special case here. |
| // FIXME(mikeyhew) get rid of this `if` statement once `receiver_is_dispatchable` allows |
| // `Receiver: Unsize<Receiver[Self => dyn Trait]>`. |
| if receiver_ty != self.types.self_param { |
| if !self.receiver_is_dispatchable(method, receiver_ty) { |
| return Some(MethodViolationCode::UndispatchableReceiver); |
| } else { |
| // Do sanity check to make sure the receiver actually has the layout of a pointer. |
| |
| use crate::ty::layout::Abi; |
| |
| let param_env = self.param_env(method.def_id); |
| |
| let abi_of_ty = |ty: Ty<'tcx>| -> &Abi { |
| match self.layout_of(param_env.and(ty)) { |
| Ok(layout) => &layout.abi, |
| Err(err) => bug!( |
| "error: {}\n while computing layout for type {:?}", err, ty |
| ) |
| } |
| }; |
| |
| // e.g., `Rc<()>` |
| let unit_receiver_ty = self.receiver_for_self_ty( |
| receiver_ty, self.mk_unit(), method.def_id |
| ); |
| |
| match abi_of_ty(unit_receiver_ty) { |
| &Abi::Scalar(..) => (), |
| abi => { |
| self.sess.delay_span_bug( |
| self.def_span(method.def_id), |
| &format!( |
| "receiver when `Self = ()` should have a Scalar ABI; found {:?}", |
| abi |
| ), |
| ); |
| } |
| } |
| |
| let trait_object_ty = self.object_ty_for_trait( |
| trait_def_id, self.mk_region(ty::ReStatic) |
| ); |
| |
| // e.g., `Rc<dyn Trait>` |
| let trait_object_receiver = self.receiver_for_self_ty( |
| receiver_ty, trait_object_ty, method.def_id |
| ); |
| |
| match abi_of_ty(trait_object_receiver) { |
| &Abi::ScalarPair(..) => (), |
| abi => { |
| self.sess.delay_span_bug( |
| self.def_span(method.def_id), |
| &format!( |
| "receiver when `Self = {}` should have a ScalarPair ABI; \ |
| found {:?}", |
| trait_object_ty, abi |
| ), |
| ); |
| } |
| } |
| } |
| } |
| |
| None |
| } |
| |
| /// Performs a type substitution to produce the version of `receiver_ty` when `Self = self_ty`. |
| /// For example, for `receiver_ty = Rc<Self>` and `self_ty = Foo`, returns `Rc<Foo>`. |
| fn receiver_for_self_ty( |
| self, |
| receiver_ty: Ty<'tcx>, |
| self_ty: Ty<'tcx>, |
| method_def_id: DefId, |
| ) -> Ty<'tcx> { |
| debug!("receiver_for_self_ty({:?}, {:?}, {:?})", receiver_ty, self_ty, method_def_id); |
| let substs = InternalSubsts::for_item(self, method_def_id, |param, _| { |
| if param.index == 0 { |
| self_ty.into() |
| } else { |
| self.mk_param_from_def(param) |
| } |
| }); |
| |
| let result = receiver_ty.subst(self, substs); |
| debug!("receiver_for_self_ty({:?}, {:?}, {:?}) = {:?}", |
| receiver_ty, self_ty, method_def_id, result); |
| result |
| } |
| |
| /// Creates the object type for the current trait. For example, |
| /// if the current trait is `Deref`, then this will be |
| /// `dyn Deref<Target = Self::Target> + 'static`. |
| fn object_ty_for_trait(self, trait_def_id: DefId, lifetime: ty::Region<'tcx>) -> Ty<'tcx> { |
| debug!("object_ty_for_trait: trait_def_id={:?}", trait_def_id); |
| |
| let trait_ref = ty::TraitRef::identity(self, trait_def_id); |
| |
| let trait_predicate = ty::ExistentialPredicate::Trait( |
| ty::ExistentialTraitRef::erase_self_ty(self, trait_ref) |
| ); |
| |
| let mut associated_types = traits::supertraits(self, ty::Binder::dummy(trait_ref)) |
| .flat_map(|super_trait_ref| { |
| self.associated_items(super_trait_ref.def_id()) |
| .map(move |item| (super_trait_ref, item)) |
| }) |
| .filter(|(_, item)| item.kind == ty::AssocKind::Type) |
| .collect::<Vec<_>>(); |
| |
| // existential predicates need to be in a specific order |
| associated_types.sort_by_cached_key(|(_, item)| self.def_path_hash(item.def_id)); |
| |
| let projection_predicates = associated_types.into_iter().map(|(super_trait_ref, item)| { |
| // We *can* get bound lifetimes here in cases like |
| // `trait MyTrait: for<'s> OtherTrait<&'s T, Output=bool>`. |
| // |
| // binder moved to (*)... |
| let super_trait_ref = super_trait_ref.skip_binder(); |
| ty::ExistentialPredicate::Projection(ty::ExistentialProjection { |
| ty: self.mk_projection(item.def_id, super_trait_ref.substs), |
| item_def_id: item.def_id, |
| substs: super_trait_ref.substs, |
| }) |
| }); |
| |
| let existential_predicates = self.mk_existential_predicates( |
| iter::once(trait_predicate).chain(projection_predicates) |
| ); |
| |
| let object_ty = self.mk_dynamic( |
| // (*) ... binder re-introduced here |
| ty::Binder::bind(existential_predicates), |
| lifetime, |
| ); |
| |
| debug!("object_ty_for_trait: object_ty=`{}`", object_ty); |
| |
| object_ty |
| } |
| |
| /// Checks the method's receiver (the `self` argument) can be dispatched on when `Self` is a |
| /// trait object. We require that `DispatchableFromDyn` be implemented for the receiver type |
| /// in the following way: |
| /// - let `Receiver` be the type of the `self` argument, i.e `Self`, `&Self`, `Rc<Self>`, |
| /// - require the following bound: |
| /// |
| /// ``` |
| /// Receiver[Self => T]: DispatchFromDyn<Receiver[Self => dyn Trait]> |
| /// ``` |
| /// |
| /// where `Foo[X => Y]` means "the same type as `Foo`, but with `X` replaced with `Y`" |
| /// (substitution notation). |
| /// |
| /// Some examples of receiver types and their required obligation: |
| /// - `&'a mut self` requires `&'a mut Self: DispatchFromDyn<&'a mut dyn Trait>`, |
| /// - `self: Rc<Self>` requires `Rc<Self>: DispatchFromDyn<Rc<dyn Trait>>`, |
| /// - `self: Pin<Box<Self>>` requires `Pin<Box<Self>>: DispatchFromDyn<Pin<Box<dyn Trait>>>`. |
| /// |
| /// The only case where the receiver is not dispatchable, but is still a valid receiver |
| /// type (just not object-safe), is when there is more than one level of pointer indirection. |
| /// E.g., `self: &&Self`, `self: &Rc<Self>`, `self: Box<Box<Self>>`. In these cases, there |
| /// is no way, or at least no inexpensive way, to coerce the receiver from the version where |
| /// `Self = dyn Trait` to the version where `Self = T`, where `T` is the unknown erased type |
| /// contained by the trait object, because the object that needs to be coerced is behind |
| /// a pointer. |
| /// |
| /// In practice, we cannot use `dyn Trait` explicitly in the obligation because it would result |
| /// in a new check that `Trait` is object safe, creating a cycle (until object_safe_for_dispatch |
| /// is stabilized, see tracking issue https://github.com/rust-lang/rust/issues/43561). |
| /// Instead, we fudge a little by introducing a new type parameter `U` such that |
| /// `Self: Unsize<U>` and `U: Trait + ?Sized`, and use `U` in place of `dyn Trait`. |
| /// Written as a chalk-style query: |
| /// |
| /// forall (U: Trait + ?Sized) { |
| /// if (Self: Unsize<U>) { |
| /// Receiver: DispatchFromDyn<Receiver[Self => U]> |
| /// } |
| /// } |
| /// |
| /// for `self: &'a mut Self`, this means `&'a mut Self: DispatchFromDyn<&'a mut U>` |
| /// for `self: Rc<Self>`, this means `Rc<Self>: DispatchFromDyn<Rc<U>>` |
| /// for `self: Pin<Box<Self>>`, this means `Pin<Box<Self>>: DispatchFromDyn<Pin<Box<U>>>` |
| // |
| // FIXME(mikeyhew) when unsized receivers are implemented as part of unsized rvalues, add this |
| // fallback query: `Receiver: Unsize<Receiver[Self => U]>` to support receivers like |
| // `self: Wrapper<Self>`. |
| #[allow(dead_code)] |
| fn receiver_is_dispatchable( |
| self, |
| method: &ty::AssocItem, |
| receiver_ty: Ty<'tcx>, |
| ) -> bool { |
| debug!("receiver_is_dispatchable: method = {:?}, receiver_ty = {:?}", method, receiver_ty); |
| |
| let traits = (self.lang_items().unsize_trait(), |
| self.lang_items().dispatch_from_dyn_trait()); |
| let (unsize_did, dispatch_from_dyn_did) = if let (Some(u), Some(cu)) = traits { |
| (u, cu) |
| } else { |
| debug!("receiver_is_dispatchable: Missing Unsize or DispatchFromDyn traits"); |
| return false; |
| }; |
| |
| // the type `U` in the query |
| // use a bogus type parameter to mimick a forall(U) query using u32::MAX for now. |
| // FIXME(mikeyhew) this is a total hack. Once object_safe_for_dispatch is stabilized, we can |
| // replace this with `dyn Trait` |
| let unsized_self_ty: Ty<'tcx> = self.mk_ty_param( |
| ::std::u32::MAX, |
| Symbol::intern("RustaceansAreAwesome"), |
| ); |
| |
| // `Receiver[Self => U]` |
| let unsized_receiver_ty = self.receiver_for_self_ty( |
| receiver_ty, unsized_self_ty, method.def_id |
| ); |
| |
| // create a modified param env, with `Self: Unsize<U>` and `U: Trait` added to caller bounds |
| // `U: ?Sized` is already implied here |
| let param_env = { |
| let mut param_env = self.param_env(method.def_id); |
| |
| // Self: Unsize<U> |
| let unsize_predicate = ty::TraitRef { |
| def_id: unsize_did, |
| substs: self.mk_substs_trait(self.types.self_param, &[unsized_self_ty.into()]), |
| }.to_predicate(); |
| |
| // U: Trait<Arg1, ..., ArgN> |
| let trait_predicate = { |
| let substs = InternalSubsts::for_item( |
| self, |
| method.container.assert_trait(), |
| |param, _| { |
| if param.index == 0 { |
| unsized_self_ty.into() |
| } else { |
| self.mk_param_from_def(param) |
| } |
| }, |
| ); |
| |
| ty::TraitRef { |
| def_id: unsize_did, |
| substs, |
| }.to_predicate() |
| }; |
| |
| let caller_bounds: Vec<Predicate<'tcx>> = param_env.caller_bounds.iter().cloned() |
| .chain(iter::once(unsize_predicate)) |
| .chain(iter::once(trait_predicate)) |
| .collect(); |
| |
| param_env.caller_bounds = self.intern_predicates(&caller_bounds); |
| |
| param_env |
| }; |
| |
| // Receiver: DispatchFromDyn<Receiver[Self => U]> |
| let obligation = { |
| let predicate = ty::TraitRef { |
| def_id: dispatch_from_dyn_did, |
| substs: self.mk_substs_trait(receiver_ty, &[unsized_receiver_ty.into()]), |
| }.to_predicate(); |
| |
| Obligation::new( |
| ObligationCause::dummy(), |
| param_env, |
| predicate, |
| ) |
| }; |
| |
| self.infer_ctxt().enter(|ref infcx| { |
| // the receiver is dispatchable iff the obligation holds |
| infcx.predicate_must_hold_modulo_regions(&obligation) |
| }) |
| } |
| |
| fn contains_illegal_self_type_reference( |
| self, |
| trait_def_id: DefId, |
| ty: Ty<'tcx>, |
| ) -> bool { |
| // This is somewhat subtle. In general, we want to forbid |
| // references to `Self` in the argument and return types, |
| // since the value of `Self` is erased. However, there is one |
| // exception: it is ok to reference `Self` in order to access |
| // an associated type of the current trait, since we retain |
| // the value of those associated types in the object type |
| // itself. |
| // |
| // ```rust |
| // trait SuperTrait { |
| // type X; |
| // } |
| // |
| // trait Trait : SuperTrait { |
| // type Y; |
| // fn foo(&self, x: Self) // bad |
| // fn foo(&self) -> Self // bad |
| // fn foo(&self) -> Option<Self> // bad |
| // fn foo(&self) -> Self::Y // OK, desugars to next example |
| // fn foo(&self) -> <Self as Trait>::Y // OK |
| // fn foo(&self) -> Self::X // OK, desugars to next example |
| // fn foo(&self) -> <Self as SuperTrait>::X // OK |
| // } |
| // ``` |
| // |
| // However, it is not as simple as allowing `Self` in a projected |
| // type, because there are illegal ways to use `Self` as well: |
| // |
| // ```rust |
| // trait Trait : SuperTrait { |
| // ... |
| // fn foo(&self) -> <Self as SomeOtherTrait>::X; |
| // } |
| // ``` |
| // |
| // Here we will not have the type of `X` recorded in the |
| // object type, and we cannot resolve `Self as SomeOtherTrait` |
| // without knowing what `Self` is. |
| |
| let mut supertraits: Option<Vec<ty::PolyTraitRef<'tcx>>> = None; |
| let mut error = false; |
| let self_ty = self.types.self_param; |
| ty.maybe_walk(|ty| { |
| match ty.kind { |
| ty::Param(_) => { |
| if ty == self_ty { |
| error = true; |
| } |
| |
| false // no contained types to walk |
| } |
| |
| ty::Projection(ref data) => { |
| // This is a projected type `<Foo as SomeTrait>::X`. |
| |
| // Compute supertraits of current trait lazily. |
| if supertraits.is_none() { |
| let trait_ref = ty::Binder::bind( |
| ty::TraitRef::identity(self, trait_def_id), |
| ); |
| supertraits = Some(traits::supertraits(self, trait_ref).collect()); |
| } |
| |
| // Determine whether the trait reference `Foo as |
| // SomeTrait` is in fact a supertrait of the |
| // current trait. In that case, this type is |
| // legal, because the type `X` will be specified |
| // in the object type. Note that we can just use |
| // direct equality here because all of these types |
| // are part of the formal parameter listing, and |
| // hence there should be no inference variables. |
| let projection_trait_ref = ty::Binder::bind(data.trait_ref(self)); |
| let is_supertrait_of_current_trait = |
| supertraits.as_ref().unwrap().contains(&projection_trait_ref); |
| |
| if is_supertrait_of_current_trait { |
| false // do not walk contained types, do not report error, do collect $200 |
| } else { |
| true // DO walk contained types, POSSIBLY reporting an error |
| } |
| } |
| |
| _ => true, // walk contained types, if any |
| } |
| }); |
| |
| error |
| } |
| } |
| |
| pub(super) fn is_object_safe_provider(tcx: TyCtxt<'_>, trait_def_id: DefId) -> bool { |
| tcx.object_safety_violations(trait_def_id).is_empty() |
| } |