Merge `BorrowKind::Unique` into `BorrowKind::Mut`
Fixes#112072
Might have conflict with #112070
r? `@lcnr`
I'm not sure what's the suitable change in a couple places.
Revert #112758 and add test case
Fixes#112831.
Cannot unwrap `update_resolution` for `resolution.single_imports.remove(&Interned::new_unchecked(import));` because there is a relationship between the `Import` and `&NameBinding` in `NameResolution`. This issue caused by my unfamiliarity with the data structure and I apologize for it.
This PR had been reverted, and test case have been added.
r? `@Nilstrieb`
cc `@petrochenkov`
Sort the errors from arguments checking so that suggestions are handled properly
Fixes#112507
The algorithm of `find_issue` does not make sure the index comes out in order, which will make suggesting `remove` or `add` arguments broken in some cases.
Modifying the algorithm to obey order involves much more trivial change, so it's better to order the `errors` after iterations.
Add `implement_via_object` to `rustc_deny_explicit_impl` to control object candidate assembly
Some built-in traits are special, since they are used to prove facts about the program that are important for later phases of compilation such as codegen and CTFE. For example, the `Unsize` trait is used to assert to the compiler that we are able to unsize a type into another type. It doesn't have any methods because it doesn't actually *instruct* the compiler how to do this unsizing, but this is later used (alongside an exhaustive match of combinations of unsizeable types) during codegen to generate unsize coercion code.
Due to this, these built-in traits are incompatible with the type erasure provided by object types. For example, the existence of `dyn Unsize<T>` does not mean that the compiler is able to unsize `Box<dyn Unsize<T>>` into `Box<T>`, since `Unsize` is a *witness* to the fact that a type can be unsized, and it doesn't actually encode that unsizing operation in its vtable as mentioned above.
The old trait solver gets around this fact by having complex control flow that never considers object bounds for certain built-in traits:
2f896da247/compiler/rustc_trait_selection/src/traits/select/candidate_assembly.rs (L61-L132)
However, candidate assembly in the new solver is much more lovely, and I'd hate to add this list of opt-out cases into the new solver. Instead of maintaining this complex and hard-coded control flow, instead we can make this a property of the trait via a built-in attribute. We already have such a build attribute that's applied to every single trait that we care about: `rustc_deny_explicit_impl`. This PR adds `implement_via_object` as a meta-item to that attribute that allows us to opt a trait out of object-bound candidate assembly as well.
r? `@lcnr`
Don't consider TAIT normalizable to hidden ty if it would result in impossible item bounds
See test for example where we shouldn't consider it possible to alias-relate a TAIT and hidden type.
r? `@lcnr`
Don't ICE on bound var in `reject_fn_ptr_impls`
We may try to use an impl like `impl<T: FnPtr> PartialEq {}` to satisfy a predicate like `for<T> T: PartialEq` -- don't ICE in that case.
Fixes#112735
Treat TAIT equation as always ambiguous in coherence
Not sure why we weren't treating all TAIT equality as ambiguous -- this behavior combined with `DefineOpaqueTypes::No` leads to coherence overlap failures, since we incorrectly consider impls as not overlapping because the obligation `T: From<Foo>` doesn't hold.
Fixes#112765
Continue folding in query normalizer on weak aliases
Fixes#112752Fixes#112731 (same root cause, so didn't make a test for it)
fixes#112776
r? ```@oli-obk```
Rewrite various resolve/diagnostics errors as translatable diagnostics
additional question:
For trivial strings is it ever accepted to use `fluent_generated::foo` in a `label` for example? Or is an empty struct `Diagnostic` preferred?
`#[test]` function signature verification improvements
This PR contains two improvements to the expansion of the `#[test]` macro.
The first one fixes https://github.com/rust-lang/rust/issues/112360 by correctly recovering item statements if the signature verification fails.
The second one forbids non-lifetime generics on `#[test]` functions. These were previously allowed if the function returned `()`, but always caused an inference error:
before:
```text
error[E0282]: type annotations needed
--> src/lib.rs:2:1
|
1 | #[test]
| ------- in this procedural macro expansion
2 | fn foo<T>() {}
| ^^^^^^^^^^^^^^ cannot infer type
```
after:
```text
error: functions used as tests can not have any non-lifetime generic parameters
--> src/lib.rs:2:1
|
2 | fn foo<T>() {}
| ^^^^^^^^^^^^^^
```
Also includes some basic tests for test function signature verification, because I couldn't find any (???) in the test suite.
