compiler/rustc_hir_analysis/src/coherence/orphan.rs - toolchain/rustc - Git at Google

 //! Orphan checker: every impl either implements a trait defined in this
 //! crate or pertains to a type defined in this crate.

 use crate::errors;
 use rustc_errors::ErrorGuaranteed;
 use rustc_hir as hir;
 use rustc_middle::ty::{self, AliasKind, Ty, TyCtxt, TypeVisitableExt};
 use rustc_span::def_id::LocalDefId;
 use rustc_span::Span;
 use rustc_trait_selection::traits::{self, IsFirstInputType};

 #[instrument(skip(tcx), level = "debug")]
 pub(crate) fn orphan_check_impl(
     tcx: TyCtxt<'_>,
     impl_def_id: LocalDefId,
 ) -> Result<(), ErrorGuaranteed> {
     let trait_ref = tcx.impl_trait_ref(impl_def_id).unwrap().instantiate_identity();
     trait_ref.error_reported()?;

     let trait_def_id = trait_ref.def_id;

     match traits::orphan_check(tcx, impl_def_id.to_def_id()) {
         Ok(()) => {}
         Err(err) => {
             let item = tcx.hir().expect_item(impl_def_id);
             let hir::ItemKind::Impl(impl_) = item.kind else {
                 bug!("{:?} is not an impl: {:?}", impl_def_id, item);
             };
             let tr = impl_.of_trait.as_ref().unwrap();
             let sp = tcx.def_span(impl_def_id);

             emit_orphan_check_error(
                 tcx,
                 sp,
                 item.span,
                 tr.path.span,
                 trait_ref,
                 impl_.self_ty.span,
                 impl_.generics,
                 err,
             )?
         }
     }

     // In addition to the above rules, we restrict impls of auto traits
     // so that they can only be implemented on nominal types, such as structs,
     // enums or foreign types. To see why this restriction exists, consider the
     // following example (#22978). Imagine that crate A defines an auto trait
     // `Foo` and a fn that operates on pairs of types:
     //
     // ```
     // // Crate A
     // auto trait Foo { }
     // fn two_foos<A:Foo,B:Foo>(..) {
     //     one_foo::<(A,B)>(..)
     // }
     // fn one_foo<T:Foo>(..) { .. }
     // ```
     //
     // This type-checks fine; in particular the fn
     // `two_foos` is able to conclude that `(A,B):Foo`
     // because `A:Foo` and `B:Foo`.
     //
     // Now imagine that crate B comes along and does the following:
     //
     // ```
     // struct A { }
     // struct B { }
     // impl Foo for A { }
     // impl Foo for B { }
     // impl !Foo for (A, B) { }
     // ```
     //
     // This final impl is legal according to the orphan
     // rules, but it invalidates the reasoning from
     // `two_foos` above.
     debug!(
         "trait_ref={:?} trait_def_id={:?} trait_is_auto={}",
         trait_ref,
         trait_def_id,
         tcx.trait_is_auto(trait_def_id)
     );

     if tcx.trait_is_auto(trait_def_id) {
         let self_ty = trait_ref.self_ty();

         // If the impl is in the same crate as the auto-trait, almost anything
         // goes.
         //
         //     impl MyAuto for Rc<Something> {}  // okay
         //     impl<T> !MyAuto for *const T {}   // okay
         //     impl<T> MyAuto for T {}           // okay
         //
         // But there is one important exception: implementing for a trait object
         // is not allowed.
         //
         //     impl MyAuto for dyn Trait {}      // NOT OKAY
         //     impl<T: ?Sized> MyAuto for T {}   // NOT OKAY
         //
         // With this restriction, it's guaranteed that an auto-trait is
         // implemented for a trait object if and only if the auto-trait is one
         // of the trait object's trait bounds (or a supertrait of a bound). In
         // other words `dyn Trait + AutoTrait` always implements AutoTrait,
         // while `dyn Trait` never implements AutoTrait.
         //
         // This is necessary in order for autotrait bounds on methods of trait
         // objects to be sound.
         //
         //     auto trait AutoTrait {}
         //
         //     trait ObjectSafeTrait {
         //         fn f(&self) where Self: AutoTrait;
         //     }
         //
         // We can allow f to be called on `dyn ObjectSafeTrait + AutoTrait`.
         //
         // If we didn't deny `impl AutoTrait for dyn Trait`, it would be unsound
         // for the ObjectSafeTrait shown above to be object safe because someone
         // could take some type implementing ObjectSafeTrait but not AutoTrait,
         // unsize it to `dyn ObjectSafeTrait`, and call .f() which has no
         // concrete implementation (issue #50781).
         enum LocalImpl {
             Allow,
             Disallow { problematic_kind: &'static str },
         }

         // If the auto-trait is from a dependency, it must only be getting
         // implemented for a nominal type, and specifically one local to the
         // current crate.
         //
         //     impl<T> Sync for MyStruct<T> {}   // okay
         //
         //     impl Sync for Rc<MyStruct> {}     // NOT OKAY
         enum NonlocalImpl {
             Allow,
             DisallowBecauseNonlocal,
             DisallowOther,
         }

         // Exhaustive match considering that this logic is essential for
         // soundness.
         let (local_impl, nonlocal_impl) = match self_ty.kind() {
             // struct Struct<T>;
             // impl AutoTrait for Struct<Foo> {}
             ty::Adt(self_def, _) => (
                 LocalImpl::Allow,
                 if self_def.did().is_local() {
                     NonlocalImpl::Allow
                 } else {
                     NonlocalImpl::DisallowBecauseNonlocal
                 },
             ),

             // extern { type OpaqueType; }
             // impl AutoTrait for OpaqueType {}
             ty::Foreign(did) => (
                 LocalImpl::Allow,
                 if did.is_local() {
                     NonlocalImpl::Allow
                 } else {
                     NonlocalImpl::DisallowBecauseNonlocal
                 },
             ),

             // impl AutoTrait for dyn Trait {}
             ty::Dynamic(..) => (
                 LocalImpl::Disallow { problematic_kind: "trait object" },
                 NonlocalImpl::DisallowOther,
             ),

             // impl<T> AutoTrait for T {}
             // impl<T: ?Sized> AutoTrait for T {}
             ty::Param(..) => (
                 if self_ty.is_sized(tcx, tcx.param_env(impl_def_id)) {
                     LocalImpl::Allow
                 } else {
                     LocalImpl::Disallow { problematic_kind: "generic type" }
                 },
                 NonlocalImpl::DisallowOther,
             ),

             ty::Alias(kind, _) => {
                 let problematic_kind = match kind {
                     // trait Id { type This: ?Sized; }
                     // impl<T: ?Sized> Id for T {
                     //     type This = T;
                     // }
                     // impl<T: ?Sized> AutoTrait for <T as Id>::This {}
                     AliasKind::Projection => "associated type",
                     // type Foo = (impl Sized, bool)
                     // impl AutoTrait for Foo {}
                     AliasKind::Weak => "type alias",
                     // type Opaque = impl Trait;
                     // impl AutoTrait for Opaque {}
                     AliasKind::Opaque => "opaque type",
                     // ```
                     // struct S<T>(T);
                     // impl<T: ?Sized> S<T> {
                     //     type This = T;
                     // }
                     // impl<T: ?Sized> AutoTrait for S<T>::This {}
                     // ```
                     // FIXME(inherent_associated_types): The example code above currently leads to a cycle
                     AliasKind::Inherent => "associated type",
                 };
                 (LocalImpl::Disallow { problematic_kind }, NonlocalImpl::DisallowOther)
             }

             ty::Bool
             | ty::Char
             | ty::Int(..)
             | ty::Uint(..)
             | ty::Float(..)
             | ty::Str
             | ty::Array(..)
             | ty::Slice(..)
             | ty::RawPtr(..)
             | ty::Ref(..)
             | ty::FnDef(..)
             | ty::FnPtr(..)
             | ty::Never
             | ty::Tuple(..) => (LocalImpl::Allow, NonlocalImpl::DisallowOther),

             ty::Closure(..)
             | ty::CoroutineClosure(..)
             | ty::Coroutine(..)
             | ty::CoroutineWitness(..)
             | ty::Bound(..)
             | ty::Placeholder(..)
             | ty::Infer(..) => {
                 let sp = tcx.def_span(impl_def_id);
                 span_bug!(sp, "weird self type for autotrait impl")
             }

             ty::Error(..) => (LocalImpl::Allow, NonlocalImpl::Allow),
         };

         if trait_def_id.is_local() {
             match local_impl {
                 LocalImpl::Allow => {}
                 LocalImpl::Disallow { problematic_kind } => {
                     return Err(tcx.dcx().emit_err(errors::TraitsWithDefaultImpl {
                         span: tcx.def_span(impl_def_id),
                         traits: tcx.def_path_str(trait_def_id),
                         problematic_kind,
                         self_ty,
                     }));
                 }
             }
         } else {
             match nonlocal_impl {
                 NonlocalImpl::Allow => {}
                 NonlocalImpl::DisallowBecauseNonlocal => {
                     return Err(tcx.dcx().emit_err(errors::CrossCrateTraitsDefined {
                         span: tcx.def_span(impl_def_id),
                         traits: tcx.def_path_str(trait_def_id),
                     }));
                 }
                 NonlocalImpl::DisallowOther => {
                     return Err(tcx.dcx().emit_err(errors::CrossCrateTraits {
                         span: tcx.def_span(impl_def_id),
                         traits: tcx.def_path_str(trait_def_id),
                         self_ty,
                     }));
                 }
             }
         }
     }

     Ok(())
 }

 fn emit_orphan_check_error<'tcx>(
     tcx: TyCtxt<'tcx>,
     sp: Span,
     full_impl_span: Span,
     trait_span: Span,
     trait_ref: ty::TraitRef<'tcx>,
     self_ty_span: Span,
     generics: &hir::Generics<'tcx>,
     err: traits::OrphanCheckErr<'tcx>,
 ) -> Result<!, ErrorGuaranteed> {
     let self_ty = trait_ref.self_ty();
     Err(match err {
         traits::OrphanCheckErr::NonLocalInputType(tys) => {
             let (mut opaque, mut foreign, mut name, mut pointer, mut ty_diag) =
                 (Vec::new(), Vec::new(), Vec::new(), Vec::new(), Vec::new());
             let mut sugg = None;
             for &(mut ty, is_target_ty) in &tys {
                 let span = if matches!(is_target_ty, IsFirstInputType::Yes) {
                     // Point at `D<A>` in `impl<A, B> for C<B> in D<A>`
                     self_ty_span
                 } else {
                     // Point at `C<B>` in `impl<A, B> for C<B> in D<A>`
                     trait_span
                 };

                 ty = tcx.erase_regions(ty);
                 ty = match ty.kind() {
                     // Remove the type arguments from the output, as they are not relevant.
                     // You can think of this as the reverse of `resolve_vars_if_possible`.
                     // That way if we had `Vec<MyType>`, we will properly attribute the
                     // problem to `Vec<T>` and avoid confusing the user if they were to see
                     // `MyType` in the error.
                     ty::Adt(def, _) => Ty::new_adt(tcx, *def, ty::List::empty()),
                     _ => ty,
                 };

                 fn push_to_foreign_or_name<'tcx>(
                     is_foreign: bool,
                     foreign: &mut Vec<errors::OnlyCurrentTraitsForeign>,
                     name: &mut Vec<errors::OnlyCurrentTraitsName<'tcx>>,
                     span: Span,
                     sname: &'tcx str,
                 ) {
                     if is_foreign {
                         foreign.push(errors::OnlyCurrentTraitsForeign { span })
                     } else {
                         name.push(errors::OnlyCurrentTraitsName { span, name: sname });
                     }
                 }

                 let is_foreign =
                     !trait_ref.def_id.is_local() && matches!(is_target_ty, IsFirstInputType::No);

                 match &ty.kind() {
                     ty::Slice(_) => {
                         push_to_foreign_or_name(
                             is_foreign,
                             &mut foreign,
                             &mut name,
                             span,
                             "slices",
                         );
                     }
                     ty::Array(..) => {
                         push_to_foreign_or_name(
                             is_foreign,
                             &mut foreign,
                             &mut name,
                             span,
                             "arrays",
                         );
                     }
                     ty::Tuple(..) => {
                         push_to_foreign_or_name(
                             is_foreign,
                             &mut foreign,
                             &mut name,
                             span,
                             "tuples",
                         );
                     }
                     ty::Alias(ty::Opaque, ..) => {
                         opaque.push(errors::OnlyCurrentTraitsOpaque { span })
                     }
                     ty::RawPtr(ptr_ty) => {
                         if !self_ty.has_param() {
                             let mut_key = ptr_ty.mutbl.prefix_str();
                             sugg = Some(errors::OnlyCurrentTraitsPointerSugg {
                                 wrapper_span: self_ty_span,
                                 struct_span: full_impl_span.shrink_to_lo(),
                                 mut_key,
                                 ptr_ty: ptr_ty.ty,
                             });
                         }
                         pointer.push(errors::OnlyCurrentTraitsPointer { span, pointer: ty });
                     }
                     _ => ty_diag.push(errors::OnlyCurrentTraitsTy { span, ty }),
                 }
             }

             let err_struct = match self_ty.kind() {
                 ty::Adt(..) => errors::OnlyCurrentTraits::Outside {
                     span: sp,
                     note: (),
                     opaque,
                     foreign,
                     name,
                     pointer,
                     ty: ty_diag,
                     sugg,
                 },
                 _ if self_ty.is_primitive() => errors::OnlyCurrentTraits::Primitive {
                     span: sp,
                     note: (),
                     opaque,
                     foreign,
                     name,
                     pointer,
                     ty: ty_diag,
                     sugg,
                 },
                 _ => errors::OnlyCurrentTraits::Arbitrary {
                     span: sp,
                     note: (),
                     opaque,
                     foreign,
                     name,
                     pointer,
                     ty: ty_diag,
                     sugg,
                 },
             };
             tcx.dcx().emit_err(err_struct)
         }
         traits::OrphanCheckErr::UncoveredTy(param_ty, local_type) => {
             let mut sp = sp;
             for param in generics.params {
                 if param.name.ident().to_string() == param_ty.to_string() {
                     sp = param.span;
                 }
             }

             match local_type {
                 Some(local_type) => tcx.dcx().emit_err(errors::TyParamFirstLocal {
                     span: sp,
                     note: (),
                     param_ty,
                     local_type,
                 }),
                 None => tcx.dcx().emit_err(errors::TyParamSome { span: sp, note: (), param_ty }),
             }
         }
     })
 }
	//! Orphan checker: every impl either implements a trait defined in this
	//! crate or pertains to a type defined in this crate.

	use crate::errors;
	use rustc_errors::ErrorGuaranteed;
	use rustc_hir as hir;
	use rustc_middle::ty::{self, AliasKind, Ty, TyCtxt, TypeVisitableExt};
	use rustc_span::def_id::LocalDefId;
	use rustc_span::Span;
	use rustc_trait_selection::traits::{self, IsFirstInputType};

	#[instrument(skip(tcx), level = "debug")]
	pub(crate) fn orphan_check_impl(
	tcx: TyCtxt<'_>,
	impl_def_id: LocalDefId,
	) -> Result<(), ErrorGuaranteed> {
	let trait_ref = tcx.impl_trait_ref(impl_def_id).unwrap().instantiate_identity();
	trait_ref.error_reported()?;

	let trait_def_id = trait_ref.def_id;

	match traits::orphan_check(tcx, impl_def_id.to_def_id()) {
	Ok(()) => {}
	Err(err) => {
	let item = tcx.hir().expect_item(impl_def_id);
	let hir::ItemKind::Impl(impl_) = item.kind else {
	bug!("{:?} is not an impl: {:?}", impl_def_id, item);
	};
	let tr = impl_.of_trait.as_ref().unwrap();
	let sp = tcx.def_span(impl_def_id);

	emit_orphan_check_error(
	tcx,
	sp,
	item.span,
	tr.path.span,
	trait_ref,
	impl_.self_ty.span,
	impl_.generics,
	err,
	)?
	}
	}

	// In addition to the above rules, we restrict impls of auto traits
	// so that they can only be implemented on nominal types, such as structs,
	// enums or foreign types. To see why this restriction exists, consider the
	// following example (#22978). Imagine that crate A defines an auto trait
	// `Foo` and a fn that operates on pairs of types:
	//
	// ```
	// // Crate A
	// auto trait Foo { }
	// fn two_foos<A:Foo,B:Foo>(..) {
	// one_foo::<(A,B)>(..)
	// }
	// fn one_foo<T:Foo>(..) { .. }
	// ```
	//
	// This type-checks fine; in particular the fn
	// `two_foos` is able to conclude that `(A,B):Foo`
	// because `A:Foo` and `B:Foo`.
	//
	// Now imagine that crate B comes along and does the following:
	//
	// ```
	// struct A { }
	// struct B { }
	// impl Foo for A { }
	// impl Foo for B { }
	// impl !Foo for (A, B) { }
	// ```
	//
	// This final impl is legal according to the orphan
	// rules, but it invalidates the reasoning from
	// `two_foos` above.
	debug!(
	"trait_ref={:?} trait_def_id={:?} trait_is_auto={}",
	trait_ref,
	trait_def_id,
	tcx.trait_is_auto(trait_def_id)
	);

	if tcx.trait_is_auto(trait_def_id) {
	let self_ty = trait_ref.self_ty();

	// If the impl is in the same crate as the auto-trait, almost anything
	// goes.
	//
	// impl MyAuto for Rc<Something> {} // okay
	// impl<T> !MyAuto for *const T {} // okay
	// impl<T> MyAuto for T {} // okay
	//
	// But there is one important exception: implementing for a trait object
	// is not allowed.
	//
	// impl MyAuto for dyn Trait {} // NOT OKAY
	// impl<T: ?Sized> MyAuto for T {} // NOT OKAY
	//
	// With this restriction, it's guaranteed that an auto-trait is
	// implemented for a trait object if and only if the auto-trait is one
	// of the trait object's trait bounds (or a supertrait of a bound). In
	// other words `dyn Trait + AutoTrait` always implements AutoTrait,
	// while `dyn Trait` never implements AutoTrait.
	//
	// This is necessary in order for autotrait bounds on methods of trait
	// objects to be sound.
	//
	// auto trait AutoTrait {}
	//
	// trait ObjectSafeTrait {
	// fn f(&self) where Self: AutoTrait;
	// }
	//
	// We can allow f to be called on `dyn ObjectSafeTrait + AutoTrait`.
	//
	// If we didn't deny `impl AutoTrait for dyn Trait`, it would be unsound
	// for the ObjectSafeTrait shown above to be object safe because someone
	// could take some type implementing ObjectSafeTrait but not AutoTrait,
	// unsize it to `dyn ObjectSafeTrait`, and call .f() which has no
	// concrete implementation (issue #50781).
	enum LocalImpl {
	Allow,
	Disallow { problematic_kind: &'static str },
	}

	// If the auto-trait is from a dependency, it must only be getting
	// implemented for a nominal type, and specifically one local to the
	// current crate.
	//
	// impl<T> Sync for MyStruct<T> {} // okay
	//
	// impl Sync for Rc<MyStruct> {} // NOT OKAY
	enum NonlocalImpl {
	Allow,
	DisallowBecauseNonlocal,
	DisallowOther,
	}

	// Exhaustive match considering that this logic is essential for
	// soundness.
	let (local_impl, nonlocal_impl) = match self_ty.kind() {
	// struct Struct<T>;
	// impl AutoTrait for Struct<Foo> {}
	ty::Adt(self_def, _) => (
	LocalImpl::Allow,
	if self_def.did().is_local() {
	NonlocalImpl::Allow
	} else {
	NonlocalImpl::DisallowBecauseNonlocal
	},
	),

	// extern { type OpaqueType; }
	// impl AutoTrait for OpaqueType {}
	ty::Foreign(did) => (
	LocalImpl::Allow,
	if did.is_local() {
	NonlocalImpl::Allow
	} else {
	NonlocalImpl::DisallowBecauseNonlocal
	},
	),

	// impl AutoTrait for dyn Trait {}
	ty::Dynamic(..) => (
	LocalImpl::Disallow { problematic_kind: "trait object" },
	NonlocalImpl::DisallowOther,
	),

	// impl<T> AutoTrait for T {}
	// impl<T: ?Sized> AutoTrait for T {}
	ty::Param(..) => (
	if self_ty.is_sized(tcx, tcx.param_env(impl_def_id)) {
	LocalImpl::Allow
	} else {
	LocalImpl::Disallow { problematic_kind: "generic type" }
	},
	NonlocalImpl::DisallowOther,
	),

	ty::Alias(kind, _) => {
	let problematic_kind = match kind {
	// trait Id { type This: ?Sized; }
	// impl<T: ?Sized> Id for T {
	// type This = T;
	// }
	// impl<T: ?Sized> AutoTrait for <T as Id>::This {}
	AliasKind::Projection => "associated type",
	// type Foo = (impl Sized, bool)
	// impl AutoTrait for Foo {}
	AliasKind::Weak => "type alias",
	// type Opaque = impl Trait;
	// impl AutoTrait for Opaque {}
	AliasKind::Opaque => "opaque type",
	// ```
	// struct S<T>(T);
	// impl<T: ?Sized> S<T> {
	// type This = T;
	// }
	// impl<T: ?Sized> AutoTrait for S<T>::This {}
	// ```
	// FIXME(inherent_associated_types): The example code above currently leads to a cycle
	AliasKind::Inherent => "associated type",
	};
	(LocalImpl::Disallow { problematic_kind }, NonlocalImpl::DisallowOther)
	}

	ty::Bool
	\| ty::Char
	\| ty::Int(..)
	\| ty::Uint(..)
	\| ty::Float(..)
	\| ty::Str
	\| ty::Array(..)
	\| ty::Slice(..)
	\| ty::RawPtr(..)
	\| ty::Ref(..)
	\| ty::FnDef(..)
	\| ty::FnPtr(..)
	\| ty::Never
	\| ty::Tuple(..) => (LocalImpl::Allow, NonlocalImpl::DisallowOther),

	ty::Closure(..)
	\| ty::CoroutineClosure(..)
	\| ty::Coroutine(..)
	\| ty::CoroutineWitness(..)
	\| ty::Bound(..)
	\| ty::Placeholder(..)
	\| ty::Infer(..) => {
	let sp = tcx.def_span(impl_def_id);
	span_bug!(sp, "weird self type for autotrait impl")
	}

	ty::Error(..) => (LocalImpl::Allow, NonlocalImpl::Allow),
	};

	if trait_def_id.is_local() {
	match local_impl {
	LocalImpl::Allow => {}
	LocalImpl::Disallow { problematic_kind } => {
	return Err(tcx.dcx().emit_err(errors::TraitsWithDefaultImpl {
	span: tcx.def_span(impl_def_id),
	traits: tcx.def_path_str(trait_def_id),
	problematic_kind,
	self_ty,
	}));
	}
	}
	} else {
	match nonlocal_impl {
	NonlocalImpl::Allow => {}
	NonlocalImpl::DisallowBecauseNonlocal => {
	return Err(tcx.dcx().emit_err(errors::CrossCrateTraitsDefined {
	span: tcx.def_span(impl_def_id),
	traits: tcx.def_path_str(trait_def_id),
	}));
	}
	NonlocalImpl::DisallowOther => {
	return Err(tcx.dcx().emit_err(errors::CrossCrateTraits {
	span: tcx.def_span(impl_def_id),
	traits: tcx.def_path_str(trait_def_id),
	self_ty,
	}));
	}
	}
	}
	}

	Ok(())
	}

	fn emit_orphan_check_error<'tcx>(
	tcx: TyCtxt<'tcx>,
	sp: Span,
	full_impl_span: Span,
	trait_span: Span,
	trait_ref: ty::TraitRef<'tcx>,
	self_ty_span: Span,
	generics: &hir::Generics<'tcx>,
	err: traits::OrphanCheckErr<'tcx>,
	) -> Result<!, ErrorGuaranteed> {
	let self_ty = trait_ref.self_ty();
	Err(match err {
	traits::OrphanCheckErr::NonLocalInputType(tys) => {
	let (mut opaque, mut foreign, mut name, mut pointer, mut ty_diag) =
	(Vec::new(), Vec::new(), Vec::new(), Vec::new(), Vec::new());
	let mut sugg = None;
	for &(mut ty, is_target_ty) in &tys {
	let span = if matches!(is_target_ty, IsFirstInputType::Yes) {
	// Point at `D<A>` in `impl<A, B> for C<B> in D<A>`
	self_ty_span
	} else {
	// Point at `C<B>` in `impl<A, B> for C<B> in D<A>`
	trait_span
	};

	ty = tcx.erase_regions(ty);
	ty = match ty.kind() {
	// Remove the type arguments from the output, as they are not relevant.
	// You can think of this as the reverse of `resolve_vars_if_possible`.
	// That way if we had `Vec<MyType>`, we will properly attribute the
	// problem to `Vec<T>` and avoid confusing the user if they were to see
	// `MyType` in the error.
	ty::Adt(def, _) => Ty::new_adt(tcx, *def, ty::List::empty()),
	_ => ty,
	};

	fn push_to_foreign_or_name<'tcx>(
	is_foreign: bool,
	foreign: &mut Vec<errors::OnlyCurrentTraitsForeign>,
	name: &mut Vec<errors::OnlyCurrentTraitsName<'tcx>>,
	span: Span,
	sname: &'tcx str,
	) {
	if is_foreign {
	foreign.push(errors::OnlyCurrentTraitsForeign { span })
	} else {
	name.push(errors::OnlyCurrentTraitsName { span, name: sname });
	}
	}

	let is_foreign =
	!trait_ref.def_id.is_local() && matches!(is_target_ty, IsFirstInputType::No);

	match &ty.kind() {
	ty::Slice(_) => {
	push_to_foreign_or_name(
	is_foreign,
	&mut foreign,
	&mut name,
	span,
	"slices",
	);
	}
	ty::Array(..) => {
	push_to_foreign_or_name(
	is_foreign,
	&mut foreign,
	&mut name,
	span,
	"arrays",
	);
	}
	ty::Tuple(..) => {
	push_to_foreign_or_name(
	is_foreign,
	&mut foreign,
	&mut name,
	span,
	"tuples",
	);
	}
	ty::Alias(ty::Opaque, ..) => {
	opaque.push(errors::OnlyCurrentTraitsOpaque { span })
	}
	ty::RawPtr(ptr_ty) => {
	if !self_ty.has_param() {
	let mut_key = ptr_ty.mutbl.prefix_str();
	sugg = Some(errors::OnlyCurrentTraitsPointerSugg {
	wrapper_span: self_ty_span,
	struct_span: full_impl_span.shrink_to_lo(),
	mut_key,
	ptr_ty: ptr_ty.ty,
	});
	}
	pointer.push(errors::OnlyCurrentTraitsPointer { span, pointer: ty });
	}
	_ => ty_diag.push(errors::OnlyCurrentTraitsTy { span, ty }),
	}
	}

	let err_struct = match self_ty.kind() {
	ty::Adt(..) => errors::OnlyCurrentTraits::Outside {
	span: sp,
	note: (),
	opaque,
	foreign,
	name,
	pointer,
	ty: ty_diag,
	sugg,
	},
	_ if self_ty.is_primitive() => errors::OnlyCurrentTraits::Primitive {
	span: sp,
	note: (),
	opaque,
	foreign,
	name,
	pointer,
	ty: ty_diag,
	sugg,
	},
	_ => errors::OnlyCurrentTraits::Arbitrary {
	span: sp,
	note: (),
	opaque,
	foreign,
	name,
	pointer,
	ty: ty_diag,
	sugg,
	},
	};
	tcx.dcx().emit_err(err_struct)
	}
	traits::OrphanCheckErr::UncoveredTy(param_ty, local_type) => {
	let mut sp = sp;
	for param in generics.params {
	if param.name.ident().to_string() == param_ty.to_string() {
	sp = param.span;
	}
	}

	match local_type {
	Some(local_type) => tcx.dcx().emit_err(errors::TyParamFirstLocal {
	span: sp,
	note: (),
	param_ty,
	local_type,
	}),
	None => tcx.dcx().emit_err(errors::TyParamSome { span: sp, note: (), param_ty }),
	}
	}
	})
	}