my rust fork
https://www.rust-lang.org
9ec287dec2
For a rigid projection, recursively look at the self type's item bounds to fix the `associated_type_bounds` feature
Given a deeply nested rigid projection like `<<<T as Trait1>::Assoc1 as Trait2>::Assoc2 as Trait3>::Assoc3`, this PR adjusts both trait solvers to look at the item bounds for all of `Assoc3`, `Assoc2`, and `Assoc1` in order to satisfy a goal. We do this because the item bounds for projections may contain relevant bounds for *other* nested projections when the `associated_type_bounds` (ATB) feature is enabled. For example:
```rust
#![feature(associated_type_bounds)]
trait Trait1 {
type Assoc1: Trait2<Assoc2: Foo>;
// Item bounds for `Assoc1` are:
// `<Self as Trait1>::Assoc1: Trait2`
// `<<Self as Trait1>::Assoc1 as Trait2>::Assoc2: Foo`
}
trait Trait2 {
type Assoc2;
}
trait Foo {}
fn hello<T: Trait1>(x: <<T as Trait1>::Assoc1 as Trait2>::Assoc2) {
fn is_foo(_: impl Foo) {}
is_foo(x);
// Currently fails with:
// ERROR the trait bound `<<Self as Trait1>::Assoc1 as Trait2>::Assoc2: Foo` is not satisfied
}
```
This has been a long-standing place of brokenness for ATBs, and is also part of the reason why ATBs currently desugar so differently in various positions (i.e. sometimes desugaring to param-env bounds, sometimes desugaring to RPITs, etc). For example, in RPIT and TAIT position, `impl Foo<Bar: Baz>` currently desugars to `impl Foo<Bar = impl Baz>` because we do not currently take advantage of these nested item bounds if we desugared them into a single set of item bounds on the opaque. This is obviously both strange and unnecessary if we just take advantage of these bounds as we should.
## Approach
This PR repeatedly peels off each projection of a given goal's self type and tries to match its item bounds against a goal, repeating with the self type of the projection. This is pretty straightforward to implement in the new solver, only requiring us to loop on the self type of a rigid projection to discover inner rigid projections, and we also need to introduce an extra probe so we can normalize them.
In the old solver, we can do essentially the same thing, however we rely on the fact that projections *should* be normalized already. This is obviously not always the case -- however, in the case that they are not fully normalized, such as a projection which has both infer vars and, we bail out with ambiguity if we hit an infer var for the self type.
## Caveats
⚠️ In the old solver, this has the side-effect of actually stalling some higher-ranked trait goals of the form `for<'a> <?0 as Tr<'a>>: Tr2`. Because we stall them, they no longer are eagerly treated as error -- this cause some existing `known-bug` tests to go from fail -> pass.
I'm pretty unconvinced that this is a problem since we make code that we expect to pass in the *new* solver also pass in the *old* solver, though this obviously doesn't solve the *full* problem.
## And then also...
We also adjust the desugaring of ATB to always desugar to a regular associated bound, rather than sometimes to an impl Trait **except** for when the ATB is present in a `dyn Trait`. We need to lower `dyn Trait<Assoc: Bar>` to `dyn Trait<Assoc = impl Bar>` because object types need all of their associated types specified.
I would also be in favor of splitting out the ATB feature and/or removing support for object types in order to stabilize just the set of positions for which the ATB feature is consistent (i.e. always elaborates to a bound).
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