src/test/ui/methods/method-deref-to-same-trait-object-with-separate-params.rs - third_party/rust - Git at Google

 #![feature(arbitrary_self_types, coerce_unsized, dispatch_from_dyn, unsize, unsized_locals)]

 // This tests a few edge-cases around `arbitrary_self_types`. Most specifically,
 // it checks that the `ObjectCandidate` you get from method matching can't
 // match a trait with the same DefId as a supertrait but a bad type parameter.

 use std::marker::PhantomData;

 mod internal {
     use std::ops::{CoerceUnsized, Deref, DispatchFromDyn};
     use std::marker::{PhantomData, Unsize};

     pub struct Smaht<T: ?Sized, MISC>(pub Box<T>, pub PhantomData<MISC>);

     impl<T: ?Sized, MISC> Deref for Smaht<T, MISC> {
         type Target = T;

         fn deref(&self) -> &Self::Target {
             &self.0
         }
     }
     impl<T: ?Sized + Unsize<U>, U: ?Sized, MISC> CoerceUnsized<Smaht<U, MISC>>
         for Smaht<T, MISC>
     {}
     impl<T: ?Sized + Unsize<U>, U: ?Sized, MISC> DispatchFromDyn<Smaht<U, MISC>>
         for Smaht<T, MISC>
     {}

     pub trait Foo: X<u32> {}
     pub trait X<T> {
         fn foo(self: Smaht<Self, T>) -> T;
     }

     impl X<u32> for () {
         fn foo(self: Smaht<Self, u32>) -> u32 {
             0
         }
     }

     pub trait Marker {}
     impl Marker for dyn Foo {}
     impl<T: Marker + ?Sized> X<u64> for T {
         fn foo(self: Smaht<Self, u64>) -> u64 {
             1
         }
     }

     impl Deref for dyn Foo {
         type Target = ();
         fn deref(&self) -> &() { &() }
     }

     impl Foo for () {}
 }

 pub trait FinalFoo {
     fn foo(&self) -> u8;
 }

 impl FinalFoo for () {
     fn foo(&self) -> u8 { 0 }
 }

 mod nuisance_foo {
     pub trait NuisanceFoo {
         fn foo(self);
     }

     impl<T: ?Sized> NuisanceFoo for T {
         fn foo(self) {}
     }
 }


 fn objectcandidate_impl() {
     let x: internal::Smaht<(), u32> = internal::Smaht(Box::new(()), PhantomData);
     let x: internal::Smaht<dyn internal::Foo, u32> = x;

     // This picks `<dyn internal::Foo as X<u32>>::foo` via `ObjectCandidate`.
     //
     // The `TraitCandidate` is not relevant because `X` is not in scope.
     let z = x.foo();

     // Observe the type of `z` is `u32`
     let _seetype: () = z; //~ ERROR mismatched types
     //~| expected `()`, found `u32`
 }

 fn traitcandidate_impl() {
     use internal::X;

     let x: internal::Smaht<(), u64> = internal::Smaht(Box::new(()), PhantomData);
     let x: internal::Smaht<dyn internal::Foo, u64> = x;

     // This picks `<dyn internal::Foo as X<u64>>::foo` via `TraitCandidate`.
     //
     // The `ObjectCandidate` does not apply, as it only applies to
     // `X<u32>` (and not `X<u64>`).
     let z = x.foo();

     // Observe the type of `z` is `u64`
     let _seetype: () = z; //~ ERROR mismatched types
     //~| expected `()`, found `u64`
 }

 fn traitcandidate_impl_with_nuisance() {
     use internal::X;
     use nuisance_foo::NuisanceFoo;

     let x: internal::Smaht<(), u64> = internal::Smaht(Box::new(()), PhantomData);
     let x: internal::Smaht<dyn internal::Foo, u64> = x;

     // This picks `<dyn internal::Foo as X<u64>>::foo` via `TraitCandidate`.
     //
     // The `ObjectCandidate` does not apply, as it only applies to
     // `X<u32>` (and not `X<u64>`).
     //
     // The NuisanceFoo impl has the same priority as the `X` impl,
     // so we get a conflict.
     let z = x.foo(); //~ ERROR multiple applicable items in scope
 }


 fn neither_impl() {
     let x: internal::Smaht<(), u64> = internal::Smaht(Box::new(()), PhantomData);
     let x: internal::Smaht<dyn internal::Foo, u64> = x;

     // This can't pick the `TraitCandidate` impl, because `Foo` is not
     // imported. However, this also can't pick the `ObjectCandidate`
     // impl, because it only applies to `X<u32>` (and not `X<u64>`).
     //
     // Therefore, neither of the candidates is applicable, and we pick
     // the `FinalFoo` impl after another deref, which will return `u8`.
     let z = x.foo();

     // Observe the type of `z` is `u8`
     let _seetype: () = z; //~ ERROR mismatched types
     //~| expected `()`, found `u8`
 }

 fn both_impls() {
     use internal::X;

     let x: internal::Smaht<(), u32> = internal::Smaht(Box::new(()), PhantomData);
     let x: internal::Smaht<dyn internal::Foo, u32> = x;

     // This can pick both the `TraitCandidate` and the `ObjectCandidate` impl.
     //
     // However, the `ObjectCandidate` is considered an "inherent candidate",
     // and therefore has priority over both the `TraitCandidate` as well as
     // any other "nuisance" candidate" (if present).
     let z = x.foo();

     // Observe the type of `z` is `u32`
     let _seetype: () = z; //~ ERROR mismatched types
     //~| expected `()`, found `u32`
 }


 fn both_impls_with_nuisance() {
     // Similar to the `both_impls` example, except with a nuisance impl to
     // make sure the `ObjectCandidate` indeed has a higher priority.

     use internal::X;
     use nuisance_foo::NuisanceFoo;

     let x: internal::Smaht<(), u32> = internal::Smaht(Box::new(()), PhantomData);
     let x: internal::Smaht<dyn internal::Foo, u32> = x;
     let z = x.foo();

     // Observe the type of `z` is `u32`
     let _seetype: () = z; //~ ERROR mismatched types
     //~| expected `()`, found `u32`
 }

 fn main() {
 }
	#![feature(arbitrary_self_types, coerce_unsized, dispatch_from_dyn, unsize, unsized_locals)]

	// This tests a few edge-cases around `arbitrary_self_types`. Most specifically,
	// it checks that the `ObjectCandidate` you get from method matching can't
	// match a trait with the same DefId as a supertrait but a bad type parameter.

	use std::marker::PhantomData;

	mod internal {
	use std::ops::{CoerceUnsized, Deref, DispatchFromDyn};
	use std::marker::{PhantomData, Unsize};

	pub struct Smaht<T: ?Sized, MISC>(pub Box<T>, pub PhantomData<MISC>);

	impl<T: ?Sized, MISC> Deref for Smaht<T, MISC> {
	type Target = T;

	fn deref(&self) -> &Self::Target {
	&self.0
	}
	}
	impl<T: ?Sized + Unsize<U>, U: ?Sized, MISC> CoerceUnsized<Smaht<U, MISC>>
	for Smaht<T, MISC>
	{}
	impl<T: ?Sized + Unsize<U>, U: ?Sized, MISC> DispatchFromDyn<Smaht<U, MISC>>
	for Smaht<T, MISC>
	{}

	pub trait Foo: X<u32> {}
	pub trait X<T> {
	fn foo(self: Smaht<Self, T>) -> T;
	}

	impl X<u32> for () {
	fn foo(self: Smaht<Self, u32>) -> u32 {
	0
	}
	}

	pub trait Marker {}
	impl Marker for dyn Foo {}
	impl<T: Marker + ?Sized> X<u64> for T {
	fn foo(self: Smaht<Self, u64>) -> u64 {
	1
	}
	}

	impl Deref for dyn Foo {
	type Target = ();
	fn deref(&self) -> &() { &() }
	}

	impl Foo for () {}
	}

	pub trait FinalFoo {
	fn foo(&self) -> u8;
	}

	impl FinalFoo for () {
	fn foo(&self) -> u8 { 0 }
	}

	mod nuisance_foo {
	pub trait NuisanceFoo {
	fn foo(self);
	}

	impl<T: ?Sized> NuisanceFoo for T {
	fn foo(self) {}
	}
	}


	fn objectcandidate_impl() {
	let x: internal::Smaht<(), u32> = internal::Smaht(Box::new(()), PhantomData);
	let x: internal::Smaht<dyn internal::Foo, u32> = x;

	// This picks `<dyn internal::Foo as X<u32>>::foo` via `ObjectCandidate`.
	//
	// The `TraitCandidate` is not relevant because `X` is not in scope.
	let z = x.foo();

	// Observe the type of `z` is `u32`
	let _seetype: () = z; //~ ERROR mismatched types
	//~\| expected `()`, found `u32`
	}

	fn traitcandidate_impl() {
	use internal::X;

	let x: internal::Smaht<(), u64> = internal::Smaht(Box::new(()), PhantomData);
	let x: internal::Smaht<dyn internal::Foo, u64> = x;

	// This picks `<dyn internal::Foo as X<u64>>::foo` via `TraitCandidate`.
	//
	// The `ObjectCandidate` does not apply, as it only applies to
	// `X<u32>` (and not `X<u64>`).
	let z = x.foo();

	// Observe the type of `z` is `u64`
	let _seetype: () = z; //~ ERROR mismatched types
	//~\| expected `()`, found `u64`
	}

	fn traitcandidate_impl_with_nuisance() {
	use internal::X;
	use nuisance_foo::NuisanceFoo;

	let x: internal::Smaht<(), u64> = internal::Smaht(Box::new(()), PhantomData);
	let x: internal::Smaht<dyn internal::Foo, u64> = x;

	// This picks `<dyn internal::Foo as X<u64>>::foo` via `TraitCandidate`.
	//
	// The `ObjectCandidate` does not apply, as it only applies to
	// `X<u32>` (and not `X<u64>`).
	//
	// The NuisanceFoo impl has the same priority as the `X` impl,
	// so we get a conflict.
	let z = x.foo(); //~ ERROR multiple applicable items in scope
	}


	fn neither_impl() {
	let x: internal::Smaht<(), u64> = internal::Smaht(Box::new(()), PhantomData);
	let x: internal::Smaht<dyn internal::Foo, u64> = x;

	// This can't pick the `TraitCandidate` impl, because `Foo` is not
	// imported. However, this also can't pick the `ObjectCandidate`
	// impl, because it only applies to `X<u32>` (and not `X<u64>`).
	//
	// Therefore, neither of the candidates is applicable, and we pick
	// the `FinalFoo` impl after another deref, which will return `u8`.
	let z = x.foo();

	// Observe the type of `z` is `u8`
	let _seetype: () = z; //~ ERROR mismatched types
	//~\| expected `()`, found `u8`
	}

	fn both_impls() {
	use internal::X;

	let x: internal::Smaht<(), u32> = internal::Smaht(Box::new(()), PhantomData);
	let x: internal::Smaht<dyn internal::Foo, u32> = x;

	// This can pick both the `TraitCandidate` and the `ObjectCandidate` impl.
	//
	// However, the `ObjectCandidate` is considered an "inherent candidate",
	// and therefore has priority over both the `TraitCandidate` as well as
	// any other "nuisance" candidate" (if present).
	let z = x.foo();

	// Observe the type of `z` is `u32`
	let _seetype: () = z; //~ ERROR mismatched types
	//~\| expected `()`, found `u32`
	}


	fn both_impls_with_nuisance() {
	// Similar to the `both_impls` example, except with a nuisance impl to
	// make sure the `ObjectCandidate` indeed has a higher priority.

	use internal::X;
	use nuisance_foo::NuisanceFoo;

	let x: internal::Smaht<(), u32> = internal::Smaht(Box::new(()), PhantomData);
	let x: internal::Smaht<dyn internal::Foo, u32> = x;
	let z = x.foo();

	// Observe the type of `z` is `u32`
	let _seetype: () = z; //~ ERROR mismatched types
	//~\| expected `()`, found `u32`
	}

	fn main() {
	}