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Projection bound validation #72788
Projection bound validation #72788
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@bors try |
⌛ Trying commit 504a46955a8a8fdb925fce8e0037f79e44ede07d with merge 4662032ab74cd44d423120d08d251dfead4914a0... |
☀️ Try build successful - checks-azure |
@craterbot check |
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Regression and fix are spurious. |
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Left a nit, but this seems good!
// For "final", non-generic associate type implementations, we | ||
// don't need this as described above. | ||
return Ok(()); | ||
} | ||
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let param_env = tcx.param_env(impl_ty.def_id); | ||
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let impl_substs = InternalSubsts::identity_for_item(tcx, impl_ty.container.id()); | ||
let impl_ty_substs = InternalSubsts::identity_for_item(tcx, impl_ty.def_id); |
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I think it'd be nice to have a comment here explaining what impl_ty_substs
and rebased_substs
represent in terms of an example.
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i.e.,
given
impl<A, B> Foo for (A, B) {
type Bar<C> =...
}
impl_substs
would be[A, B, C]
placeholdersrebased_substs
would be[(A, B), C]
, combining the substs from the trait with the generic associated type parameters
LL | trait Iterate<'a> { | ||
| ----------------- required by `Iterate` | ||
LL | type Ty: Valid; | ||
| --------------- required by `Iterate::Ty` |
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interesting that this changed
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This is because the def_id used in ObligationCauseCode::ItemObligation
was changed
r=me modulo the nit |
@bors r=nikomatsakis |
📌 Commit e785472 has been approved by |
…dation, r=nikomatsakis Projection bound validation During selection we use bounds declared on associated types (e.g. `type X: Copy`) to satisfy trait/projection bounds. This would be fine so long as those bounds are checked on any impls/trait objects. For simple cases they are because the bound `Self::X: Copy` gets normalized when we check the impl. However, for default values with specialization and higher-ranked bounds from GATs or otherwise, we can't normalize when checking the impl, and so we use the bound from the trait to prove that the bound applies to the impl, which is clearly unsound. This PR makes 2 fixes for this: 1. Requiring that the bounds on the trait apply to a projection type with the corresponding substs, so a bound `for<'a> <Self as X<'a>>::U: Copy` on the trait cannot be used to prove `<T as X<'_>>::U: Copy`. 2. Actually checking that the bounds that we still allow apply to generic/default associated types. Opening for a crater run. Closes rust-lang#68641 Closes rust-lang#68642 Closes rust-lang#68643 Closes rust-lang#68644 Closes rust-lang#68645 Closes rust-lang#68656 r? @ghost
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@bors r- |
…dation, r=nikomatsakis Projection bound validation During selection we use bounds declared on associated types (e.g. `type X: Copy`) to satisfy trait/projection bounds. This would be fine so long as those bounds are checked on any impls/trait objects. For simple cases they are because the bound `Self::X: Copy` gets normalized when we check the impl. However, for default values with specialization and higher-ranked bounds from GATs or otherwise, we can't normalize when checking the impl, and so we use the bound from the trait to prove that the bound applies to the impl, which is clearly unsound. This PR makes 2 fixes for this: 1. Requiring that the bounds on the trait apply to a projection type with the corresponding substs, so a bound `for<'a> <Self as X<'a>>::U: Copy` on the trait cannot be used to prove `<T as X<'_>>::U: Copy`. 2. Actually checking that the bounds that we still allow apply to generic/default associated types. Opening for a crater run. Closes rust-lang#68641 Closes rust-lang#68642 Closes rust-lang#68643 Closes rust-lang#68644 Closes rust-lang#68645 Closes rust-lang#68656 r? @ghost
…arth Rollup of 9 pull requests Successful merges: - rust-lang#72456 (Try to suggest dereferences on trait selection failed) - rust-lang#72788 (Projection bound validation) - rust-lang#72790 (core/time: Add Duration methods for zero) - rust-lang#73227 (Allow multiple `asm!` options groups and report an error on duplicate options) - rust-lang#73287 (lint: normalize projections using opaque types) - rust-lang#73291 (Pre-compute `LocalDefId` <-> `HirId` mappings and remove `NodeId` <-> `HirId` conversion APIs) - rust-lang#73378 (Remove use of specialization from librustc_arena) - rust-lang#73411 (Update bootstrap to rustc 1.45.0-beta.2 (1dc0f6d 2020-06-15)) - rust-lang#73443 (ci: allow gating GHA on everything but macOS) Failed merges: r? @ghost
…nikomatsakis Separate projection bounds and predicates Follow up to rust-lang#72788. - Rename `projection_predicates` to `item_bounds` - Separate bounds on associated types (the things after the `:` in `type X: ...`) and opaque types (the things after `impl`) from predicates. - Projection candidates now have the correct nested obligations - Trait object candidates now check that the associated types on the trait object satisfy their bounds as nested obligations - Type alias impl trait types are now checked (rust-lang#73035) - `feature(generic_associated_types)` no longer changes how we handle bounds (rust-lang#73816) Opening for a perf and crater runs. r? `@nikomatsakis`
…er-errors Stabilize generic associated types Closes rust-lang#44265 r? `@nikomatsakis` # ⚡ Status of the discussion ⚡ * [x] There have been several serious concerns raised, [summarized here](rust-lang#96709 (comment)). * [x] There has also been a [deep-dive comment](rust-lang#96709 (comment)) explaining some of the "patterns of code" that are enabled by GATs, based on use-cases posted to this thread or on the tracking issue. * [x] We have modeled some aspects of GATs in [a-mir-formality](https://github.com/nikomatsakis/a-mir-formality) to give better confidence in how they will be resolved in the future. [You can read a write-up here](https://github.com/rust-lang/types-team/blob/master/minutes/2022-07-08-implied-bounds-and-wf-checking.md). * [x] The major points of the discussion have been [summarized on the GAT initiative repository](https://rust-lang.github.io/generic-associated-types-initiative/mvp.html). * [x] [FCP has been proposed](rust-lang#96709 (comment)) and we are awaiting final decisions and discussion amidst the relevant team members. # Stabilization proposal This PR proposes the stabilization of `#![feature(generic_associated_types)]`. While there a number of future additions to be made and bugs to be fixed (both discussed below), properly doing these will require significant language design and will ultimately likely be backwards-compatible. Given the overwhelming desire to have some form of generic associated types (GATs) available on stable and the stability of the "simple" uses, stabilizing the current subset of GAT features is almost certainly the correct next step. Tracking issue: rust-lang#44265 Initiative: https://rust-lang.github.io/generic-associated-types-initiative/ RFC: https://github.com/rust-lang/rfcs/blob/master/text/1598-generic_associated_types.md Version: 1.65 (2022-08-22 => beta, 2022-11-03 => stable). ## Motivation There are a myriad of potential use cases for GATs. Stabilization unblocks probable future language features (e.g. async functions in traits), potential future standard library features (e.g. a `LendingIterator` or some form of `Iterator` with a lifetime generic), and a plethora of user use cases (some of which can be seen just by scrolling through the tracking issue and looking at all the issues linking to it). There are a myriad of potential use cases for GATs. First, there are many users that have chosen to not use GATs primarily because they are not stable (some of which can be seen just by scrolling through the tracking issue and looking at all the issues linking to it). Second, while language feature desugaring isn't *blocked* on stabilization, it gives more confidence on using the feature. Likewise, library features like `LendingIterator` are not necessarily blocked on stabilization to be implemented unstably; however few, if any, public-facing APIs actually use unstable features. This feature has a long history of design, discussion, and developement - the RFC was first introduced roughly 6 years ago. While there are still a number of features left to implement and bugs left to fix, it's clear that it's unlikely those will have backwards-incompatibility concerns. Additionally, the bugs that do exist do not strongly impede the most-common use cases. ## What is stabilized The primary language feature stabilized here is the ability to have generics on associated types, as so. Additionally, where clauses on associated types will now be accepted, regardless if the associated type is generic or not. ```rust trait ATraitWithGATs { type Assoc<'a, T> where T: 'a; } trait ATraitWithoutGATs<'a, T> { type Assoc where T: 'a; } ``` When adding an impl for a trait with generic associated types, the generics for the associated type are copied as well. Note that where clauses are allowed both after the specified type and before the equals sign; however, the latter is a warn-by-default deprecation. ```rust struct X; struct Y; impl ATraitWithGATs for X { type Assoc<'a, T> = &'a T where T: 'a; } impl ATraitWithGATs for Y { type Assoc<'a, T> where T: 'a = &'a T; } ``` To use a GAT in a function, generics are specified on the associated type, as if it was a struct or enum. GATs can also be specified in trait bounds: ```rust fn accepts_gat<'a, T>(t: &'a T) -> T::Assoc<'a, T> where for<'x> T: ATraitWithGATs<Assoc<'a, T> = &'a T> { ... } ``` GATs can also appear in trait methods. However, depending on how they are used, they may confer where clauses on the associated type definition. More information can be found [here](rust-lang#87479). Briefly, where clauses are required when those bounds can be proven in the methods that *construct* the GAT or other associated types that use the GAT in the trait. This allows impls to have maximum flexibility in the types defined for the associated type. To take a relatively simple example: ```rust trait Iterable { type Item<'a>; type Iterator<'a>: Iterator<Item = Self::Item<'a>>; fn iter<'x>(&'x self) -> Self::Iterator<'x>; //^ We know that `Self: 'a` for `Iterator<'a>`, so we require that bound on `Iterator` // `Iterator` uses `Self::Item`, so we also require a `Self: 'a` on `Item` too } ``` A couple well-explained examples are available in a previous [blog post](https://blog.rust-lang.org/2021/08/03/GATs-stabilization-push.html). ## What isn't stabilized/implemented ### Universal type/const quantification Currently, you can write a bound like `X: for<'a> Trait<Assoc<'a> = &'a ()>`. However, you cannot currently write `for<T> X: Trait<Assoc<T> = T>` or `for<const N> X: Trait<Assoc<N> = [usize; N]>`. Here is an example where this is needed: ```rust trait Foo {} trait Trait { type Assoc<F: Foo>; } trait Trait2: Sized { fn foo<F: Foo, T: Trait<Assoc<F> = F>>(_t: T); } ``` In the above example, the *caller* must specify `F`, which is likely not what is desired. ### Object-safe GATs Unlike non-generic associated types, traits with GATs are not currently object-safe. In other words the following are not allowed: ```rust trait Trait { type Assoc<'a>; } fn foo(t: &dyn for<'a> Trait<Assoc<'a> = &'a ()>) {} //^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ not allowed let ty: Box<dyn for<'a> Trait<Assoc<'a> = &'a ()>>; //^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ not allowed ``` ### Higher-kinded types You cannot write currently (and there are no current plans to implement this): ```rust struct Struct<'a> {} fn foo(s: for<'a> Struct<'a>) {} ``` ## Tests There are many tests covering GATs that can be found in `src/test/ui/generic-associated-types`. Here, I'll list (in alphanumeric order) tests highlight some important behavior or contain important patterns. - `./parse/*`: Parsing of GATs in traits and impls, and the trait path with GATs - `./collections-project-default.rs`: Interaction with associated type defaults - `./collections.rs`: The `Collection` pattern - `./const-generics-gat-in-trait-return-type-*.rs`: Const parameters - `./constraint-assoc-type-suggestion.rs`: Emit correct syntax in suggestion - `./cross-crate-bounds.rs`: Ensure we handles bounds across crates the same - `./elided-in-expr-position.rs`: Disallow lifetime elision in return position - `./gat-in-trait-path-undeclared-lifetime.rs`: Ensure we error on undeclared lifetime in trait path - `./gat-in-trait-path.rs`: Base trait path case - `./gat-trait-path-generic-type-arg.rs`: Don't allow shadowing of parameters - `./gat-trait-path-parenthesised-args.rs`: Don't allow paranthesized args in trait path - `./generic-associated-types-where.rs`: Ensure that we require where clauses from trait to be met on impl - `./impl_bounds.rs`: Check that the bounds on GATs in an impl are checked - `./issue-76826.rs`: `Windows` pattern - `./issue-78113-lifetime-mismatch-dyn-trait-box.rs`: Implicit 'static diagnostics - `./issue-84931.rs`: Ensure that we have a where clause on GAT to ensure trait parameter lives long enough - `./issue-87258_a.rs`: Unconstrained opaque type with TAITs - `./issue-87429-2.rs`: Ensure we can use bound vars in the bounds - `./issue-87429-associated-type-default.rs`: Ensure bounds hold with associated type defaults, for both trait and impl - `./issue-87429-specialization.rs`: Check that bounds hold under specialization - `./issue-88595.rs`: Under the outlives lint, we require a bound for both trait and GAT lifetime when trait lifetime is used in function - `./issue-90014.rs`: Lifetime bounds are checked with TAITs - `./issue-91139.rs`: Under migrate mode, but not NLL, we don't capture implied bounds from HRTB lifetimes used in a function and GATs - `./issue-91762.rs`: We used to too eagerly pick param env candidates when normalizing with GATs. We now require explicit parameters specified. - `./issue-95305.rs`: Disallow lifetime elision in trait paths - `./iterable.rs`: `Iterable` pattern - `./method-unsatified-assoc-type-predicate.rs`: Print predicates with GATs correctly in method resolve error - `./missing_lifetime_const.rs`: Ensure we must specify lifetime args (not elidable) - `./missing-where-clause-on-trait.rs`: Ensure we don't allow stricter bounds on impl than trait - `./parameter_number_and_kind_impl.rs`: Ensure paramters on GAT in impl match GAT in trait - `./pointer_family.rs`: `PointerFamily` pattern - `./projection-bound-cycle.rs`: Don't allow invalid cycles to prove bounds - `./self-outlives-lint.rs`: Ensures that an e.g. `Self: 'a` is written on the traits GAT if that bound can be implied from the GAT usage in the trait - `./shadowing.rs`: Don't allow lifetime shadowing in params - `./streaming_iterator.rs`: `StreamingIterator`(`LendingIterator`) pattern - `./trait-objects.rs`: Disallow trait objects for traits with GATs - `./variance_constraints.rs`: Require that GAT substs be invariant ## Remaining bugs and open issues A full list of remaining open issues can be found at: https://github.com/rust-lang/rust/labels/F-generic_associated_types There are some `known-bug` tests in-tree at `src/test/ui/generic-associated-types/bugs`. Here I'll categorize most of those that GAT bugs (or involve a pattern found more with GATs), but not those that include GATs but not a GAT issue in and of itself. (I also won't include issues directly for things listed elsewhere here.) Using the concrete type of a GAT instead of the projection type can give errors, since lifetimes are chosen to be early-bound vs late-bound. - rust-lang#85533 - rust-lang#87803 In certain cases, we can run into cycle or overflow errors. This is more generally a problem with associated types. - rust-lang#87755 - rust-lang#87758 Bounds on an associatd type need to be proven by an impl, but where clauses need to be proven by the usage. This can lead to confusion when users write one when they mean the other. - rust-lang#87831 - rust-lang#90573 We sometimes can't normalize closure signatures fully. Really an asociated types issue, but might happen a bit more frequently with GATs, since more obvious place for HRTB lifetimes. - rust-lang#88382 When calling a function, we assign types to parameters "too late", after we already try (and fail) to normalize projections. Another associated types issue that might pop up more with GATs. - rust-lang#88460 - rust-lang#96230 We don't fully have implied bounds for lifetimes appearing in GAT trait paths, which can lead to unconstrained type errors. - rust-lang#88526 Suggestion for adding lifetime bounds can suggest unhelpful fixes (`T: 'a` instead of `Self: 'a`), but the next compiler error after making the suggested change is helpful. - rust-lang#90816 - rust-lang#92096 - rust-lang#95268 We can end up requiring that `for<'a> I: 'a` when we really want `for<'a where I: 'a> I: 'a`. This can leave unhelpful errors than effectively can't be satisfied unless `I: 'static`. Requires bigger changes and not only GATs. - rust-lang#91693 Unlike with non-generic associated types, we don't eagerly normalize with param env candidates. This is intended behavior (for now), to avoid accidentaly stabilizing picking arbitrary impls. - rust-lang#91762 Some Iterator adapter patterns (namely `filter`) require Polonius or unsafe to work. - rust-lang#92985 ## Potential Future work ### Universal type/const quantification No work has been done to implement this. There are also some questions around implied bounds. ### Object-safe GATs The intention is to make traits with GATs object-safe. There are some design work to be done around well-formedness rules and general implementation. ### GATified std lib types It would be helpful to either introduce new std lib traits (like `LendingIterator`) or to modify existing ones (adding a `'a` generic to `Iterator::Item`). There also a number of other candidates, like `Index`/`IndexMut` and `Fn`/`FnMut`/`FnOnce`. ### Reduce the need for `for<'a>` Seen [here](rust-lang/rfcs#1598 (comment)). One possible syntax: ```rust trait Iterable { type Iter<'a>: Iterator<Item = Self::Item<'a>>; } fn foo<T>() where T: Iterable, T::Item<let 'a>: Display { } //note the `let`! ``` ### Better implied bounds on higher-ranked things Currently if we have a `type Item<'a> where self: 'a`, and a `for<'a> T: Iterator<Item<'a> = &'a ()`, this requires `for<'a> Self: 'a`. Really, we want `for<'a where T: 'a> ...` There was some mentions of this all the back in the RFC thread [here](rust-lang/rfcs#1598 (comment)). ## Alternatives ### Make generics on associated type in bounds a binder Imagine the bound `for<'a> T: Trait<Item<'a>= &'a ()>`. It might be that `for<'a>` is "too large" and it should instead be `T: Trait<for<'a> Item<'a>= &'a ()>`. Brought up in RFC thread [here](rust-lang/rfcs#1598 (comment)) and in a few places since. Another related question: Is `for<'a>` the right syntax? Maybe `where<'a>`? Also originally found in RFC thread [here](rust-lang/rfcs#1598 (comment)). ### Stabilize lifetime GATs first This has been brought up a few times. The idea is to only allow GATs with lifetime parameters to in initial stabilization. This was probably most useful prior to actual implementation. At this point, lifetimes, types, and consts are all implemented and work. It feels like an arbitrary split without strong reason. ## History * On 2016-04-30, [RFC opened](rust-lang/rfcs#1598) * On 2017-09-02, RFC merged and [tracking issue opened](rust-lang#44265) * On 2017-10-23, [Move Generics from MethodSig to TraitItem and ImplItem](rust-lang#44766) * On 2017-12-01, [Generic Associated Types Parsing & Name Resolution](rust-lang#45904) * On 2017-12-15, [https://github.com/rust-lang/rust/pull/46706](https://github.com/rust-lang/rust/pull/46706) * On 2018-04-23, [Feature gate where clauses on associated types](rust-lang#49368) * On 2018-05-10, [Extend tests for RFC1598 (GAT)](rust-lang#49423) * On 2018-05-24, [Finish implementing GATs (Chalk)](rust-lang/chalk#134) * On 2019-12-21, [Make GATs less ICE-prone](rust-lang#67160) * On 2020-02-13, [fix lifetime shadowing check in GATs](rust-lang#68938) * On 2020-06-20, [Projection bound validation](rust-lang#72788) * On 2020-10-06, [Separate projection bounds and predicates](rust-lang#73905) * On 2021-02-05, [Generic associated types in trait paths](rust-lang#79554) * On 2021-02-06, [Trait objects do not work with generic associated types](rust-lang#81823) * On 2021-04-28, [Make traits with GATs not object safe](rust-lang#84622) * On 2021-05-11, [Improve diagnostics for GATs](rust-lang#82272) * On 2021-07-16, [Make GATs no longer an incomplete feature](rust-lang#84623) * On 2021-07-16, [Replace associated item bound vars with placeholders when projecting](rust-lang#86993) * On 2021-07-26, [GATs: Decide whether to have defaults for `where Self: 'a`](rust-lang#87479) * On 2021-08-25, [Normalize projections under binders](rust-lang#85499) * On 2021-08-03, [The push for GATs stabilization](https://blog.rust-lang.org/2021/08/03/GATs-stabilization-push.html) * On 2021-08-12, [Detect stricter constraints on gats where clauses in impls vs trait](rust-lang#88336) * On 2021-09-20, [Proposal: Change syntax of where clauses on type aliases](rust-lang#89122) * On 2021-11-06, [Implementation of GATs outlives lint](rust-lang#89970) * On 2021-12-29. [Parse and suggest moving where clauses after equals for type aliases](rust-lang#92118) * On 2022-01-15, [Ignore static lifetimes for GATs outlives lint](rust-lang#92865) * On 2022-02-08, [Don't constrain projection predicates with inference vars in GAT substs](rust-lang#92917) * On 2022-02-15, [Rework GAT where clause check](rust-lang#93820) * On 2022-02-19, [Only mark projection as ambiguous if GAT substs are constrained](rust-lang#93892) * On 2022-03-03, [Support GATs in Rustdoc](rust-lang#94009) * On 2022-03-06, [Change location of where clause on GATs](rust-lang#90076) * On 2022-05-04, [A shiny future with GATs blog post](https://jackh726.github.io/rust/2022/05/04/a-shiny-future-with-gats.html) * On 2022-05-04, [Stabilization PR](rust-lang#96709)
Stabilize generic associated types Closes #44265 r? `@nikomatsakis` # ⚡ Status of the discussion ⚡ * [x] There have been several serious concerns raised, [summarized here](rust-lang/rust#96709 (comment)). * [x] There has also been a [deep-dive comment](rust-lang/rust#96709 (comment)) explaining some of the "patterns of code" that are enabled by GATs, based on use-cases posted to this thread or on the tracking issue. * [x] We have modeled some aspects of GATs in [a-mir-formality](https://github.com/nikomatsakis/a-mir-formality) to give better confidence in how they will be resolved in the future. [You can read a write-up here](https://github.com/rust-lang/types-team/blob/master/minutes/2022-07-08-implied-bounds-and-wf-checking.md). * [x] The major points of the discussion have been [summarized on the GAT initiative repository](https://rust-lang.github.io/generic-associated-types-initiative/mvp.html). * [x] [FCP has been proposed](rust-lang/rust#96709 (comment)) and we are awaiting final decisions and discussion amidst the relevant team members. # Stabilization proposal This PR proposes the stabilization of `#![feature(generic_associated_types)]`. While there a number of future additions to be made and bugs to be fixed (both discussed below), properly doing these will require significant language design and will ultimately likely be backwards-compatible. Given the overwhelming desire to have some form of generic associated types (GATs) available on stable and the stability of the "simple" uses, stabilizing the current subset of GAT features is almost certainly the correct next step. Tracking issue: #44265 Initiative: https://rust-lang.github.io/generic-associated-types-initiative/ RFC: https://github.com/rust-lang/rfcs/blob/master/text/1598-generic_associated_types.md Version: 1.65 (2022-08-22 => beta, 2022-11-03 => stable). ## Motivation There are a myriad of potential use cases for GATs. Stabilization unblocks probable future language features (e.g. async functions in traits), potential future standard library features (e.g. a `LendingIterator` or some form of `Iterator` with a lifetime generic), and a plethora of user use cases (some of which can be seen just by scrolling through the tracking issue and looking at all the issues linking to it). There are a myriad of potential use cases for GATs. First, there are many users that have chosen to not use GATs primarily because they are not stable (some of which can be seen just by scrolling through the tracking issue and looking at all the issues linking to it). Second, while language feature desugaring isn't *blocked* on stabilization, it gives more confidence on using the feature. Likewise, library features like `LendingIterator` are not necessarily blocked on stabilization to be implemented unstably; however few, if any, public-facing APIs actually use unstable features. This feature has a long history of design, discussion, and developement - the RFC was first introduced roughly 6 years ago. While there are still a number of features left to implement and bugs left to fix, it's clear that it's unlikely those will have backwards-incompatibility concerns. Additionally, the bugs that do exist do not strongly impede the most-common use cases. ## What is stabilized The primary language feature stabilized here is the ability to have generics on associated types, as so. Additionally, where clauses on associated types will now be accepted, regardless if the associated type is generic or not. ```rust trait ATraitWithGATs { type Assoc<'a, T> where T: 'a; } trait ATraitWithoutGATs<'a, T> { type Assoc where T: 'a; } ``` When adding an impl for a trait with generic associated types, the generics for the associated type are copied as well. Note that where clauses are allowed both after the specified type and before the equals sign; however, the latter is a warn-by-default deprecation. ```rust struct X; struct Y; impl ATraitWithGATs for X { type Assoc<'a, T> = &'a T where T: 'a; } impl ATraitWithGATs for Y { type Assoc<'a, T> where T: 'a = &'a T; } ``` To use a GAT in a function, generics are specified on the associated type, as if it was a struct or enum. GATs can also be specified in trait bounds: ```rust fn accepts_gat<'a, T>(t: &'a T) -> T::Assoc<'a, T> where for<'x> T: ATraitWithGATs<Assoc<'a, T> = &'a T> { ... } ``` GATs can also appear in trait methods. However, depending on how they are used, they may confer where clauses on the associated type definition. More information can be found [here](rust-lang/rust#87479). Briefly, where clauses are required when those bounds can be proven in the methods that *construct* the GAT or other associated types that use the GAT in the trait. This allows impls to have maximum flexibility in the types defined for the associated type. To take a relatively simple example: ```rust trait Iterable { type Item<'a>; type Iterator<'a>: Iterator<Item = Self::Item<'a>>; fn iter<'x>(&'x self) -> Self::Iterator<'x>; //^ We know that `Self: 'a` for `Iterator<'a>`, so we require that bound on `Iterator` // `Iterator` uses `Self::Item`, so we also require a `Self: 'a` on `Item` too } ``` A couple well-explained examples are available in a previous [blog post](https://blog.rust-lang.org/2021/08/03/GATs-stabilization-push.html). ## What isn't stabilized/implemented ### Universal type/const quantification Currently, you can write a bound like `X: for<'a> Trait<Assoc<'a> = &'a ()>`. However, you cannot currently write `for<T> X: Trait<Assoc<T> = T>` or `for<const N> X: Trait<Assoc<N> = [usize; N]>`. Here is an example where this is needed: ```rust trait Foo {} trait Trait { type Assoc<F: Foo>; } trait Trait2: Sized { fn foo<F: Foo, T: Trait<Assoc<F> = F>>(_t: T); } ``` In the above example, the *caller* must specify `F`, which is likely not what is desired. ### Object-safe GATs Unlike non-generic associated types, traits with GATs are not currently object-safe. In other words the following are not allowed: ```rust trait Trait { type Assoc<'a>; } fn foo(t: &dyn for<'a> Trait<Assoc<'a> = &'a ()>) {} //^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ not allowed let ty: Box<dyn for<'a> Trait<Assoc<'a> = &'a ()>>; //^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ not allowed ``` ### Higher-kinded types You cannot write currently (and there are no current plans to implement this): ```rust struct Struct<'a> {} fn foo(s: for<'a> Struct<'a>) {} ``` ## Tests There are many tests covering GATs that can be found in `src/test/ui/generic-associated-types`. Here, I'll list (in alphanumeric order) tests highlight some important behavior or contain important patterns. - `./parse/*`: Parsing of GATs in traits and impls, and the trait path with GATs - `./collections-project-default.rs`: Interaction with associated type defaults - `./collections.rs`: The `Collection` pattern - `./const-generics-gat-in-trait-return-type-*.rs`: Const parameters - `./constraint-assoc-type-suggestion.rs`: Emit correct syntax in suggestion - `./cross-crate-bounds.rs`: Ensure we handles bounds across crates the same - `./elided-in-expr-position.rs`: Disallow lifetime elision in return position - `./gat-in-trait-path-undeclared-lifetime.rs`: Ensure we error on undeclared lifetime in trait path - `./gat-in-trait-path.rs`: Base trait path case - `./gat-trait-path-generic-type-arg.rs`: Don't allow shadowing of parameters - `./gat-trait-path-parenthesised-args.rs`: Don't allow paranthesized args in trait path - `./generic-associated-types-where.rs`: Ensure that we require where clauses from trait to be met on impl - `./impl_bounds.rs`: Check that the bounds on GATs in an impl are checked - `./issue-76826.rs`: `Windows` pattern - `./issue-78113-lifetime-mismatch-dyn-trait-box.rs`: Implicit 'static diagnostics - `./issue-84931.rs`: Ensure that we have a where clause on GAT to ensure trait parameter lives long enough - `./issue-87258_a.rs`: Unconstrained opaque type with TAITs - `./issue-87429-2.rs`: Ensure we can use bound vars in the bounds - `./issue-87429-associated-type-default.rs`: Ensure bounds hold with associated type defaults, for both trait and impl - `./issue-87429-specialization.rs`: Check that bounds hold under specialization - `./issue-88595.rs`: Under the outlives lint, we require a bound for both trait and GAT lifetime when trait lifetime is used in function - `./issue-90014.rs`: Lifetime bounds are checked with TAITs - `./issue-91139.rs`: Under migrate mode, but not NLL, we don't capture implied bounds from HRTB lifetimes used in a function and GATs - `./issue-91762.rs`: We used to too eagerly pick param env candidates when normalizing with GATs. We now require explicit parameters specified. - `./issue-95305.rs`: Disallow lifetime elision in trait paths - `./iterable.rs`: `Iterable` pattern - `./method-unsatified-assoc-type-predicate.rs`: Print predicates with GATs correctly in method resolve error - `./missing_lifetime_const.rs`: Ensure we must specify lifetime args (not elidable) - `./missing-where-clause-on-trait.rs`: Ensure we don't allow stricter bounds on impl than trait - `./parameter_number_and_kind_impl.rs`: Ensure paramters on GAT in impl match GAT in trait - `./pointer_family.rs`: `PointerFamily` pattern - `./projection-bound-cycle.rs`: Don't allow invalid cycles to prove bounds - `./self-outlives-lint.rs`: Ensures that an e.g. `Self: 'a` is written on the traits GAT if that bound can be implied from the GAT usage in the trait - `./shadowing.rs`: Don't allow lifetime shadowing in params - `./streaming_iterator.rs`: `StreamingIterator`(`LendingIterator`) pattern - `./trait-objects.rs`: Disallow trait objects for traits with GATs - `./variance_constraints.rs`: Require that GAT substs be invariant ## Remaining bugs and open issues A full list of remaining open issues can be found at: https://github.com/rust-lang/rust/labels/F-generic_associated_types There are some `known-bug` tests in-tree at `src/test/ui/generic-associated-types/bugs`. Here I'll categorize most of those that GAT bugs (or involve a pattern found more with GATs), but not those that include GATs but not a GAT issue in and of itself. (I also won't include issues directly for things listed elsewhere here.) Using the concrete type of a GAT instead of the projection type can give errors, since lifetimes are chosen to be early-bound vs late-bound. - #85533 - #87803 In certain cases, we can run into cycle or overflow errors. This is more generally a problem with associated types. - #87755 - #87758 Bounds on an associatd type need to be proven by an impl, but where clauses need to be proven by the usage. This can lead to confusion when users write one when they mean the other. - #87831 - #90573 We sometimes can't normalize closure signatures fully. Really an asociated types issue, but might happen a bit more frequently with GATs, since more obvious place for HRTB lifetimes. - #88382 When calling a function, we assign types to parameters "too late", after we already try (and fail) to normalize projections. Another associated types issue that might pop up more with GATs. - #88460 - #96230 We don't fully have implied bounds for lifetimes appearing in GAT trait paths, which can lead to unconstrained type errors. - #88526 Suggestion for adding lifetime bounds can suggest unhelpful fixes (`T: 'a` instead of `Self: 'a`), but the next compiler error after making the suggested change is helpful. - #90816 - #92096 - #95268 We can end up requiring that `for<'a> I: 'a` when we really want `for<'a where I: 'a> I: 'a`. This can leave unhelpful errors than effectively can't be satisfied unless `I: 'static`. Requires bigger changes and not only GATs. - #91693 Unlike with non-generic associated types, we don't eagerly normalize with param env candidates. This is intended behavior (for now), to avoid accidentaly stabilizing picking arbitrary impls. - #91762 Some Iterator adapter patterns (namely `filter`) require Polonius or unsafe to work. - #92985 ## Potential Future work ### Universal type/const quantification No work has been done to implement this. There are also some questions around implied bounds. ### Object-safe GATs The intention is to make traits with GATs object-safe. There are some design work to be done around well-formedness rules and general implementation. ### GATified std lib types It would be helpful to either introduce new std lib traits (like `LendingIterator`) or to modify existing ones (adding a `'a` generic to `Iterator::Item`). There also a number of other candidates, like `Index`/`IndexMut` and `Fn`/`FnMut`/`FnOnce`. ### Reduce the need for `for<'a>` Seen [here](rust-lang/rfcs#1598 (comment)). One possible syntax: ```rust trait Iterable { type Iter<'a>: Iterator<Item = Self::Item<'a>>; } fn foo<T>() where T: Iterable, T::Item<let 'a>: Display { } //note the `let`! ``` ### Better implied bounds on higher-ranked things Currently if we have a `type Item<'a> where self: 'a`, and a `for<'a> T: Iterator<Item<'a> = &'a ()`, this requires `for<'a> Self: 'a`. Really, we want `for<'a where T: 'a> ...` There was some mentions of this all the back in the RFC thread [here](rust-lang/rfcs#1598 (comment)). ## Alternatives ### Make generics on associated type in bounds a binder Imagine the bound `for<'a> T: Trait<Item<'a>= &'a ()>`. It might be that `for<'a>` is "too large" and it should instead be `T: Trait<for<'a> Item<'a>= &'a ()>`. Brought up in RFC thread [here](rust-lang/rfcs#1598 (comment)) and in a few places since. Another related question: Is `for<'a>` the right syntax? Maybe `where<'a>`? Also originally found in RFC thread [here](rust-lang/rfcs#1598 (comment)). ### Stabilize lifetime GATs first This has been brought up a few times. The idea is to only allow GATs with lifetime parameters to in initial stabilization. This was probably most useful prior to actual implementation. At this point, lifetimes, types, and consts are all implemented and work. It feels like an arbitrary split without strong reason. ## History * On 2016-04-30, [RFC opened](rust-lang/rfcs#1598) * On 2017-09-02, RFC merged and [tracking issue opened](rust-lang/rust#44265) * On 2017-10-23, [Move Generics from MethodSig to TraitItem and ImplItem](rust-lang/rust#44766) * On 2017-12-01, [Generic Associated Types Parsing & Name Resolution](rust-lang/rust#45904) * On 2017-12-15, [https://github.com/rust-lang/rust/pull/46706](https://github.com/rust-lang/rust/pull/46706) * On 2018-04-23, [Feature gate where clauses on associated types](rust-lang/rust#49368) * On 2018-05-10, [Extend tests for RFC1598 (GAT)](rust-lang/rust#49423) * On 2018-05-24, [Finish implementing GATs (Chalk)](rust-lang/chalk#134) * On 2019-12-21, [Make GATs less ICE-prone](rust-lang/rust#67160) * On 2020-02-13, [fix lifetime shadowing check in GATs](rust-lang/rust#68938) * On 2020-06-20, [Projection bound validation](rust-lang/rust#72788) * On 2020-10-06, [Separate projection bounds and predicates](rust-lang/rust#73905) * On 2021-02-05, [Generic associated types in trait paths](rust-lang/rust#79554) * On 2021-02-06, [Trait objects do not work with generic associated types](rust-lang/rust#81823) * On 2021-04-28, [Make traits with GATs not object safe](rust-lang/rust#84622) * On 2021-05-11, [Improve diagnostics for GATs](rust-lang/rust#82272) * On 2021-07-16, [Make GATs no longer an incomplete feature](rust-lang/rust#84623) * On 2021-07-16, [Replace associated item bound vars with placeholders when projecting](rust-lang/rust#86993) * On 2021-07-26, [GATs: Decide whether to have defaults for `where Self: 'a`](rust-lang/rust#87479) * On 2021-08-25, [Normalize projections under binders](rust-lang/rust#85499) * On 2021-08-03, [The push for GATs stabilization](https://blog.rust-lang.org/2021/08/03/GATs-stabilization-push.html) * On 2021-08-12, [Detect stricter constraints on gats where clauses in impls vs trait](rust-lang/rust#88336) * On 2021-09-20, [Proposal: Change syntax of where clauses on type aliases](rust-lang/rust#89122) * On 2021-11-06, [Implementation of GATs outlives lint](rust-lang/rust#89970) * On 2021-12-29. [Parse and suggest moving where clauses after equals for type aliases](rust-lang/rust#92118) * On 2022-01-15, [Ignore static lifetimes for GATs outlives lint](rust-lang/rust#92865) * On 2022-02-08, [Don't constrain projection predicates with inference vars in GAT substs](rust-lang/rust#92917) * On 2022-02-15, [Rework GAT where clause check](rust-lang/rust#93820) * On 2022-02-19, [Only mark projection as ambiguous if GAT substs are constrained](rust-lang/rust#93892) * On 2022-03-03, [Support GATs in Rustdoc](rust-lang/rust#94009) * On 2022-03-06, [Change location of where clause on GATs](rust-lang/rust#90076) * On 2022-05-04, [A shiny future with GATs blog post](https://jackh726.github.io/rust/2022/05/04/a-shiny-future-with-gats.html) * On 2022-05-04, [Stabilization PR](rust-lang/rust#96709)
Stabilize generic associated types Closes #44265 r? `@nikomatsakis` # ⚡ Status of the discussion ⚡ * [x] There have been several serious concerns raised, [summarized here](rust-lang/rust#96709 (comment)). * [x] There has also been a [deep-dive comment](rust-lang/rust#96709 (comment)) explaining some of the "patterns of code" that are enabled by GATs, based on use-cases posted to this thread or on the tracking issue. * [x] We have modeled some aspects of GATs in [a-mir-formality](https://github.com/nikomatsakis/a-mir-formality) to give better confidence in how they will be resolved in the future. [You can read a write-up here](https://github.com/rust-lang/types-team/blob/master/minutes/2022-07-08-implied-bounds-and-wf-checking.md). * [x] The major points of the discussion have been [summarized on the GAT initiative repository](https://rust-lang.github.io/generic-associated-types-initiative/mvp.html). * [x] [FCP has been proposed](rust-lang/rust#96709 (comment)) and we are awaiting final decisions and discussion amidst the relevant team members. # Stabilization proposal This PR proposes the stabilization of `#![feature(generic_associated_types)]`. While there a number of future additions to be made and bugs to be fixed (both discussed below), properly doing these will require significant language design and will ultimately likely be backwards-compatible. Given the overwhelming desire to have some form of generic associated types (GATs) available on stable and the stability of the "simple" uses, stabilizing the current subset of GAT features is almost certainly the correct next step. Tracking issue: #44265 Initiative: https://rust-lang.github.io/generic-associated-types-initiative/ RFC: https://github.com/rust-lang/rfcs/blob/master/text/1598-generic_associated_types.md Version: 1.65 (2022-08-22 => beta, 2022-11-03 => stable). ## Motivation There are a myriad of potential use cases for GATs. Stabilization unblocks probable future language features (e.g. async functions in traits), potential future standard library features (e.g. a `LendingIterator` or some form of `Iterator` with a lifetime generic), and a plethora of user use cases (some of which can be seen just by scrolling through the tracking issue and looking at all the issues linking to it). There are a myriad of potential use cases for GATs. First, there are many users that have chosen to not use GATs primarily because they are not stable (some of which can be seen just by scrolling through the tracking issue and looking at all the issues linking to it). Second, while language feature desugaring isn't *blocked* on stabilization, it gives more confidence on using the feature. Likewise, library features like `LendingIterator` are not necessarily blocked on stabilization to be implemented unstably; however few, if any, public-facing APIs actually use unstable features. This feature has a long history of design, discussion, and developement - the RFC was first introduced roughly 6 years ago. While there are still a number of features left to implement and bugs left to fix, it's clear that it's unlikely those will have backwards-incompatibility concerns. Additionally, the bugs that do exist do not strongly impede the most-common use cases. ## What is stabilized The primary language feature stabilized here is the ability to have generics on associated types, as so. Additionally, where clauses on associated types will now be accepted, regardless if the associated type is generic or not. ```rust trait ATraitWithGATs { type Assoc<'a, T> where T: 'a; } trait ATraitWithoutGATs<'a, T> { type Assoc where T: 'a; } ``` When adding an impl for a trait with generic associated types, the generics for the associated type are copied as well. Note that where clauses are allowed both after the specified type and before the equals sign; however, the latter is a warn-by-default deprecation. ```rust struct X; struct Y; impl ATraitWithGATs for X { type Assoc<'a, T> = &'a T where T: 'a; } impl ATraitWithGATs for Y { type Assoc<'a, T> where T: 'a = &'a T; } ``` To use a GAT in a function, generics are specified on the associated type, as if it was a struct or enum. GATs can also be specified in trait bounds: ```rust fn accepts_gat<'a, T>(t: &'a T) -> T::Assoc<'a, T> where for<'x> T: ATraitWithGATs<Assoc<'a, T> = &'a T> { ... } ``` GATs can also appear in trait methods. However, depending on how they are used, they may confer where clauses on the associated type definition. More information can be found [here](rust-lang/rust#87479). Briefly, where clauses are required when those bounds can be proven in the methods that *construct* the GAT or other associated types that use the GAT in the trait. This allows impls to have maximum flexibility in the types defined for the associated type. To take a relatively simple example: ```rust trait Iterable { type Item<'a>; type Iterator<'a>: Iterator<Item = Self::Item<'a>>; fn iter<'x>(&'x self) -> Self::Iterator<'x>; //^ We know that `Self: 'a` for `Iterator<'a>`, so we require that bound on `Iterator` // `Iterator` uses `Self::Item`, so we also require a `Self: 'a` on `Item` too } ``` A couple well-explained examples are available in a previous [blog post](https://blog.rust-lang.org/2021/08/03/GATs-stabilization-push.html). ## What isn't stabilized/implemented ### Universal type/const quantification Currently, you can write a bound like `X: for<'a> Trait<Assoc<'a> = &'a ()>`. However, you cannot currently write `for<T> X: Trait<Assoc<T> = T>` or `for<const N> X: Trait<Assoc<N> = [usize; N]>`. Here is an example where this is needed: ```rust trait Foo {} trait Trait { type Assoc<F: Foo>; } trait Trait2: Sized { fn foo<F: Foo, T: Trait<Assoc<F> = F>>(_t: T); } ``` In the above example, the *caller* must specify `F`, which is likely not what is desired. ### Object-safe GATs Unlike non-generic associated types, traits with GATs are not currently object-safe. In other words the following are not allowed: ```rust trait Trait { type Assoc<'a>; } fn foo(t: &dyn for<'a> Trait<Assoc<'a> = &'a ()>) {} //^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ not allowed let ty: Box<dyn for<'a> Trait<Assoc<'a> = &'a ()>>; //^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ not allowed ``` ### Higher-kinded types You cannot write currently (and there are no current plans to implement this): ```rust struct Struct<'a> {} fn foo(s: for<'a> Struct<'a>) {} ``` ## Tests There are many tests covering GATs that can be found in `src/test/ui/generic-associated-types`. Here, I'll list (in alphanumeric order) tests highlight some important behavior or contain important patterns. - `./parse/*`: Parsing of GATs in traits and impls, and the trait path with GATs - `./collections-project-default.rs`: Interaction with associated type defaults - `./collections.rs`: The `Collection` pattern - `./const-generics-gat-in-trait-return-type-*.rs`: Const parameters - `./constraint-assoc-type-suggestion.rs`: Emit correct syntax in suggestion - `./cross-crate-bounds.rs`: Ensure we handles bounds across crates the same - `./elided-in-expr-position.rs`: Disallow lifetime elision in return position - `./gat-in-trait-path-undeclared-lifetime.rs`: Ensure we error on undeclared lifetime in trait path - `./gat-in-trait-path.rs`: Base trait path case - `./gat-trait-path-generic-type-arg.rs`: Don't allow shadowing of parameters - `./gat-trait-path-parenthesised-args.rs`: Don't allow paranthesized args in trait path - `./generic-associated-types-where.rs`: Ensure that we require where clauses from trait to be met on impl - `./impl_bounds.rs`: Check that the bounds on GATs in an impl are checked - `./issue-76826.rs`: `Windows` pattern - `./issue-78113-lifetime-mismatch-dyn-trait-box.rs`: Implicit 'static diagnostics - `./issue-84931.rs`: Ensure that we have a where clause on GAT to ensure trait parameter lives long enough - `./issue-87258_a.rs`: Unconstrained opaque type with TAITs - `./issue-87429-2.rs`: Ensure we can use bound vars in the bounds - `./issue-87429-associated-type-default.rs`: Ensure bounds hold with associated type defaults, for both trait and impl - `./issue-87429-specialization.rs`: Check that bounds hold under specialization - `./issue-88595.rs`: Under the outlives lint, we require a bound for both trait and GAT lifetime when trait lifetime is used in function - `./issue-90014.rs`: Lifetime bounds are checked with TAITs - `./issue-91139.rs`: Under migrate mode, but not NLL, we don't capture implied bounds from HRTB lifetimes used in a function and GATs - `./issue-91762.rs`: We used to too eagerly pick param env candidates when normalizing with GATs. We now require explicit parameters specified. - `./issue-95305.rs`: Disallow lifetime elision in trait paths - `./iterable.rs`: `Iterable` pattern - `./method-unsatified-assoc-type-predicate.rs`: Print predicates with GATs correctly in method resolve error - `./missing_lifetime_const.rs`: Ensure we must specify lifetime args (not elidable) - `./missing-where-clause-on-trait.rs`: Ensure we don't allow stricter bounds on impl than trait - `./parameter_number_and_kind_impl.rs`: Ensure paramters on GAT in impl match GAT in trait - `./pointer_family.rs`: `PointerFamily` pattern - `./projection-bound-cycle.rs`: Don't allow invalid cycles to prove bounds - `./self-outlives-lint.rs`: Ensures that an e.g. `Self: 'a` is written on the traits GAT if that bound can be implied from the GAT usage in the trait - `./shadowing.rs`: Don't allow lifetime shadowing in params - `./streaming_iterator.rs`: `StreamingIterator`(`LendingIterator`) pattern - `./trait-objects.rs`: Disallow trait objects for traits with GATs - `./variance_constraints.rs`: Require that GAT substs be invariant ## Remaining bugs and open issues A full list of remaining open issues can be found at: https://github.com/rust-lang/rust/labels/F-generic_associated_types There are some `known-bug` tests in-tree at `src/test/ui/generic-associated-types/bugs`. Here I'll categorize most of those that GAT bugs (or involve a pattern found more with GATs), but not those that include GATs but not a GAT issue in and of itself. (I also won't include issues directly for things listed elsewhere here.) Using the concrete type of a GAT instead of the projection type can give errors, since lifetimes are chosen to be early-bound vs late-bound. - #85533 - #87803 In certain cases, we can run into cycle or overflow errors. This is more generally a problem with associated types. - #87755 - #87758 Bounds on an associatd type need to be proven by an impl, but where clauses need to be proven by the usage. This can lead to confusion when users write one when they mean the other. - #87831 - #90573 We sometimes can't normalize closure signatures fully. Really an asociated types issue, but might happen a bit more frequently with GATs, since more obvious place for HRTB lifetimes. - #88382 When calling a function, we assign types to parameters "too late", after we already try (and fail) to normalize projections. Another associated types issue that might pop up more with GATs. - #88460 - #96230 We don't fully have implied bounds for lifetimes appearing in GAT trait paths, which can lead to unconstrained type errors. - #88526 Suggestion for adding lifetime bounds can suggest unhelpful fixes (`T: 'a` instead of `Self: 'a`), but the next compiler error after making the suggested change is helpful. - #90816 - #92096 - #95268 We can end up requiring that `for<'a> I: 'a` when we really want `for<'a where I: 'a> I: 'a`. This can leave unhelpful errors than effectively can't be satisfied unless `I: 'static`. Requires bigger changes and not only GATs. - #91693 Unlike with non-generic associated types, we don't eagerly normalize with param env candidates. This is intended behavior (for now), to avoid accidentaly stabilizing picking arbitrary impls. - #91762 Some Iterator adapter patterns (namely `filter`) require Polonius or unsafe to work. - #92985 ## Potential Future work ### Universal type/const quantification No work has been done to implement this. There are also some questions around implied bounds. ### Object-safe GATs The intention is to make traits with GATs object-safe. There are some design work to be done around well-formedness rules and general implementation. ### GATified std lib types It would be helpful to either introduce new std lib traits (like `LendingIterator`) or to modify existing ones (adding a `'a` generic to `Iterator::Item`). There also a number of other candidates, like `Index`/`IndexMut` and `Fn`/`FnMut`/`FnOnce`. ### Reduce the need for `for<'a>` Seen [here](rust-lang/rfcs#1598 (comment)). One possible syntax: ```rust trait Iterable { type Iter<'a>: Iterator<Item = Self::Item<'a>>; } fn foo<T>() where T: Iterable, T::Item<let 'a>: Display { } //note the `let`! ``` ### Better implied bounds on higher-ranked things Currently if we have a `type Item<'a> where self: 'a`, and a `for<'a> T: Iterator<Item<'a> = &'a ()`, this requires `for<'a> Self: 'a`. Really, we want `for<'a where T: 'a> ...` There was some mentions of this all the back in the RFC thread [here](rust-lang/rfcs#1598 (comment)). ## Alternatives ### Make generics on associated type in bounds a binder Imagine the bound `for<'a> T: Trait<Item<'a>= &'a ()>`. It might be that `for<'a>` is "too large" and it should instead be `T: Trait<for<'a> Item<'a>= &'a ()>`. Brought up in RFC thread [here](rust-lang/rfcs#1598 (comment)) and in a few places since. Another related question: Is `for<'a>` the right syntax? Maybe `where<'a>`? Also originally found in RFC thread [here](rust-lang/rfcs#1598 (comment)). ### Stabilize lifetime GATs first This has been brought up a few times. The idea is to only allow GATs with lifetime parameters to in initial stabilization. This was probably most useful prior to actual implementation. At this point, lifetimes, types, and consts are all implemented and work. It feels like an arbitrary split without strong reason. ## History * On 2016-04-30, [RFC opened](rust-lang/rfcs#1598) * On 2017-09-02, RFC merged and [tracking issue opened](rust-lang/rust#44265) * On 2017-10-23, [Move Generics from MethodSig to TraitItem and ImplItem](rust-lang/rust#44766) * On 2017-12-01, [Generic Associated Types Parsing & Name Resolution](rust-lang/rust#45904) * On 2017-12-15, [https://github.com/rust-lang/rust/pull/46706](https://github.com/rust-lang/rust/pull/46706) * On 2018-04-23, [Feature gate where clauses on associated types](rust-lang/rust#49368) * On 2018-05-10, [Extend tests for RFC1598 (GAT)](rust-lang/rust#49423) * On 2018-05-24, [Finish implementing GATs (Chalk)](rust-lang/chalk#134) * On 2019-12-21, [Make GATs less ICE-prone](rust-lang/rust#67160) * On 2020-02-13, [fix lifetime shadowing check in GATs](rust-lang/rust#68938) * On 2020-06-20, [Projection bound validation](rust-lang/rust#72788) * On 2020-10-06, [Separate projection bounds and predicates](rust-lang/rust#73905) * On 2021-02-05, [Generic associated types in trait paths](rust-lang/rust#79554) * On 2021-02-06, [Trait objects do not work with generic associated types](rust-lang/rust#81823) * On 2021-04-28, [Make traits with GATs not object safe](rust-lang/rust#84622) * On 2021-05-11, [Improve diagnostics for GATs](rust-lang/rust#82272) * On 2021-07-16, [Make GATs no longer an incomplete feature](rust-lang/rust#84623) * On 2021-07-16, [Replace associated item bound vars with placeholders when projecting](rust-lang/rust#86993) * On 2021-07-26, [GATs: Decide whether to have defaults for `where Self: 'a`](rust-lang/rust#87479) * On 2021-08-25, [Normalize projections under binders](rust-lang/rust#85499) * On 2021-08-03, [The push for GATs stabilization](https://blog.rust-lang.org/2021/08/03/GATs-stabilization-push.html) * On 2021-08-12, [Detect stricter constraints on gats where clauses in impls vs trait](rust-lang/rust#88336) * On 2021-09-20, [Proposal: Change syntax of where clauses on type aliases](rust-lang/rust#89122) * On 2021-11-06, [Implementation of GATs outlives lint](rust-lang/rust#89970) * On 2021-12-29. [Parse and suggest moving where clauses after equals for type aliases](rust-lang/rust#92118) * On 2022-01-15, [Ignore static lifetimes for GATs outlives lint](rust-lang/rust#92865) * On 2022-02-08, [Don't constrain projection predicates with inference vars in GAT substs](rust-lang/rust#92917) * On 2022-02-15, [Rework GAT where clause check](rust-lang/rust#93820) * On 2022-02-19, [Only mark projection as ambiguous if GAT substs are constrained](rust-lang/rust#93892) * On 2022-03-03, [Support GATs in Rustdoc](rust-lang/rust#94009) * On 2022-03-06, [Change location of where clause on GATs](rust-lang/rust#90076) * On 2022-05-04, [A shiny future with GATs blog post](https://jackh726.github.io/rust/2022/05/04/a-shiny-future-with-gats.html) * On 2022-05-04, [Stabilization PR](rust-lang/rust#96709)
Stabilize generic associated types Closes #44265 r? `@nikomatsakis` # ⚡ Status of the discussion ⚡ * [x] There have been several serious concerns raised, [summarized here](rust-lang/rust#96709 (comment)). * [x] There has also been a [deep-dive comment](rust-lang/rust#96709 (comment)) explaining some of the "patterns of code" that are enabled by GATs, based on use-cases posted to this thread or on the tracking issue. * [x] We have modeled some aspects of GATs in [a-mir-formality](https://github.com/nikomatsakis/a-mir-formality) to give better confidence in how they will be resolved in the future. [You can read a write-up here](https://github.com/rust-lang/types-team/blob/master/minutes/2022-07-08-implied-bounds-and-wf-checking.md). * [x] The major points of the discussion have been [summarized on the GAT initiative repository](https://rust-lang.github.io/generic-associated-types-initiative/mvp.html). * [x] [FCP has been proposed](rust-lang/rust#96709 (comment)) and we are awaiting final decisions and discussion amidst the relevant team members. # Stabilization proposal This PR proposes the stabilization of `#![feature(generic_associated_types)]`. While there a number of future additions to be made and bugs to be fixed (both discussed below), properly doing these will require significant language design and will ultimately likely be backwards-compatible. Given the overwhelming desire to have some form of generic associated types (GATs) available on stable and the stability of the "simple" uses, stabilizing the current subset of GAT features is almost certainly the correct next step. Tracking issue: #44265 Initiative: https://rust-lang.github.io/generic-associated-types-initiative/ RFC: https://github.com/rust-lang/rfcs/blob/master/text/1598-generic_associated_types.md Version: 1.65 (2022-08-22 => beta, 2022-11-03 => stable). ## Motivation There are a myriad of potential use cases for GATs. Stabilization unblocks probable future language features (e.g. async functions in traits), potential future standard library features (e.g. a `LendingIterator` or some form of `Iterator` with a lifetime generic), and a plethora of user use cases (some of which can be seen just by scrolling through the tracking issue and looking at all the issues linking to it). There are a myriad of potential use cases for GATs. First, there are many users that have chosen to not use GATs primarily because they are not stable (some of which can be seen just by scrolling through the tracking issue and looking at all the issues linking to it). Second, while language feature desugaring isn't *blocked* on stabilization, it gives more confidence on using the feature. Likewise, library features like `LendingIterator` are not necessarily blocked on stabilization to be implemented unstably; however few, if any, public-facing APIs actually use unstable features. This feature has a long history of design, discussion, and developement - the RFC was first introduced roughly 6 years ago. While there are still a number of features left to implement and bugs left to fix, it's clear that it's unlikely those will have backwards-incompatibility concerns. Additionally, the bugs that do exist do not strongly impede the most-common use cases. ## What is stabilized The primary language feature stabilized here is the ability to have generics on associated types, as so. Additionally, where clauses on associated types will now be accepted, regardless if the associated type is generic or not. ```rust trait ATraitWithGATs { type Assoc<'a, T> where T: 'a; } trait ATraitWithoutGATs<'a, T> { type Assoc where T: 'a; } ``` When adding an impl for a trait with generic associated types, the generics for the associated type are copied as well. Note that where clauses are allowed both after the specified type and before the equals sign; however, the latter is a warn-by-default deprecation. ```rust struct X; struct Y; impl ATraitWithGATs for X { type Assoc<'a, T> = &'a T where T: 'a; } impl ATraitWithGATs for Y { type Assoc<'a, T> where T: 'a = &'a T; } ``` To use a GAT in a function, generics are specified on the associated type, as if it was a struct or enum. GATs can also be specified in trait bounds: ```rust fn accepts_gat<'a, T>(t: &'a T) -> T::Assoc<'a, T> where for<'x> T: ATraitWithGATs<Assoc<'a, T> = &'a T> { ... } ``` GATs can also appear in trait methods. However, depending on how they are used, they may confer where clauses on the associated type definition. More information can be found [here](rust-lang/rust#87479). Briefly, where clauses are required when those bounds can be proven in the methods that *construct* the GAT or other associated types that use the GAT in the trait. This allows impls to have maximum flexibility in the types defined for the associated type. To take a relatively simple example: ```rust trait Iterable { type Item<'a>; type Iterator<'a>: Iterator<Item = Self::Item<'a>>; fn iter<'x>(&'x self) -> Self::Iterator<'x>; //^ We know that `Self: 'a` for `Iterator<'a>`, so we require that bound on `Iterator` // `Iterator` uses `Self::Item`, so we also require a `Self: 'a` on `Item` too } ``` A couple well-explained examples are available in a previous [blog post](https://blog.rust-lang.org/2021/08/03/GATs-stabilization-push.html). ## What isn't stabilized/implemented ### Universal type/const quantification Currently, you can write a bound like `X: for<'a> Trait<Assoc<'a> = &'a ()>`. However, you cannot currently write `for<T> X: Trait<Assoc<T> = T>` or `for<const N> X: Trait<Assoc<N> = [usize; N]>`. Here is an example where this is needed: ```rust trait Foo {} trait Trait { type Assoc<F: Foo>; } trait Trait2: Sized { fn foo<F: Foo, T: Trait<Assoc<F> = F>>(_t: T); } ``` In the above example, the *caller* must specify `F`, which is likely not what is desired. ### Object-safe GATs Unlike non-generic associated types, traits with GATs are not currently object-safe. In other words the following are not allowed: ```rust trait Trait { type Assoc<'a>; } fn foo(t: &dyn for<'a> Trait<Assoc<'a> = &'a ()>) {} //^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ not allowed let ty: Box<dyn for<'a> Trait<Assoc<'a> = &'a ()>>; //^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ not allowed ``` ### Higher-kinded types You cannot write currently (and there are no current plans to implement this): ```rust struct Struct<'a> {} fn foo(s: for<'a> Struct<'a>) {} ``` ## Tests There are many tests covering GATs that can be found in `src/test/ui/generic-associated-types`. Here, I'll list (in alphanumeric order) tests highlight some important behavior or contain important patterns. - `./parse/*`: Parsing of GATs in traits and impls, and the trait path with GATs - `./collections-project-default.rs`: Interaction with associated type defaults - `./collections.rs`: The `Collection` pattern - `./const-generics-gat-in-trait-return-type-*.rs`: Const parameters - `./constraint-assoc-type-suggestion.rs`: Emit correct syntax in suggestion - `./cross-crate-bounds.rs`: Ensure we handles bounds across crates the same - `./elided-in-expr-position.rs`: Disallow lifetime elision in return position - `./gat-in-trait-path-undeclared-lifetime.rs`: Ensure we error on undeclared lifetime in trait path - `./gat-in-trait-path.rs`: Base trait path case - `./gat-trait-path-generic-type-arg.rs`: Don't allow shadowing of parameters - `./gat-trait-path-parenthesised-args.rs`: Don't allow paranthesized args in trait path - `./generic-associated-types-where.rs`: Ensure that we require where clauses from trait to be met on impl - `./impl_bounds.rs`: Check that the bounds on GATs in an impl are checked - `./issue-76826.rs`: `Windows` pattern - `./issue-78113-lifetime-mismatch-dyn-trait-box.rs`: Implicit 'static diagnostics - `./issue-84931.rs`: Ensure that we have a where clause on GAT to ensure trait parameter lives long enough - `./issue-87258_a.rs`: Unconstrained opaque type with TAITs - `./issue-87429-2.rs`: Ensure we can use bound vars in the bounds - `./issue-87429-associated-type-default.rs`: Ensure bounds hold with associated type defaults, for both trait and impl - `./issue-87429-specialization.rs`: Check that bounds hold under specialization - `./issue-88595.rs`: Under the outlives lint, we require a bound for both trait and GAT lifetime when trait lifetime is used in function - `./issue-90014.rs`: Lifetime bounds are checked with TAITs - `./issue-91139.rs`: Under migrate mode, but not NLL, we don't capture implied bounds from HRTB lifetimes used in a function and GATs - `./issue-91762.rs`: We used to too eagerly pick param env candidates when normalizing with GATs. We now require explicit parameters specified. - `./issue-95305.rs`: Disallow lifetime elision in trait paths - `./iterable.rs`: `Iterable` pattern - `./method-unsatified-assoc-type-predicate.rs`: Print predicates with GATs correctly in method resolve error - `./missing_lifetime_const.rs`: Ensure we must specify lifetime args (not elidable) - `./missing-where-clause-on-trait.rs`: Ensure we don't allow stricter bounds on impl than trait - `./parameter_number_and_kind_impl.rs`: Ensure paramters on GAT in impl match GAT in trait - `./pointer_family.rs`: `PointerFamily` pattern - `./projection-bound-cycle.rs`: Don't allow invalid cycles to prove bounds - `./self-outlives-lint.rs`: Ensures that an e.g. `Self: 'a` is written on the traits GAT if that bound can be implied from the GAT usage in the trait - `./shadowing.rs`: Don't allow lifetime shadowing in params - `./streaming_iterator.rs`: `StreamingIterator`(`LendingIterator`) pattern - `./trait-objects.rs`: Disallow trait objects for traits with GATs - `./variance_constraints.rs`: Require that GAT substs be invariant ## Remaining bugs and open issues A full list of remaining open issues can be found at: https://github.com/rust-lang/rust/labels/F-generic_associated_types There are some `known-bug` tests in-tree at `src/test/ui/generic-associated-types/bugs`. Here I'll categorize most of those that GAT bugs (or involve a pattern found more with GATs), but not those that include GATs but not a GAT issue in and of itself. (I also won't include issues directly for things listed elsewhere here.) Using the concrete type of a GAT instead of the projection type can give errors, since lifetimes are chosen to be early-bound vs late-bound. - #85533 - #87803 In certain cases, we can run into cycle or overflow errors. This is more generally a problem with associated types. - #87755 - #87758 Bounds on an associatd type need to be proven by an impl, but where clauses need to be proven by the usage. This can lead to confusion when users write one when they mean the other. - #87831 - #90573 We sometimes can't normalize closure signatures fully. Really an asociated types issue, but might happen a bit more frequently with GATs, since more obvious place for HRTB lifetimes. - #88382 When calling a function, we assign types to parameters "too late", after we already try (and fail) to normalize projections. Another associated types issue that might pop up more with GATs. - #88460 - #96230 We don't fully have implied bounds for lifetimes appearing in GAT trait paths, which can lead to unconstrained type errors. - #88526 Suggestion for adding lifetime bounds can suggest unhelpful fixes (`T: 'a` instead of `Self: 'a`), but the next compiler error after making the suggested change is helpful. - #90816 - #92096 - #95268 We can end up requiring that `for<'a> I: 'a` when we really want `for<'a where I: 'a> I: 'a`. This can leave unhelpful errors than effectively can't be satisfied unless `I: 'static`. Requires bigger changes and not only GATs. - #91693 Unlike with non-generic associated types, we don't eagerly normalize with param env candidates. This is intended behavior (for now), to avoid accidentaly stabilizing picking arbitrary impls. - #91762 Some Iterator adapter patterns (namely `filter`) require Polonius or unsafe to work. - #92985 ## Potential Future work ### Universal type/const quantification No work has been done to implement this. There are also some questions around implied bounds. ### Object-safe GATs The intention is to make traits with GATs object-safe. There are some design work to be done around well-formedness rules and general implementation. ### GATified std lib types It would be helpful to either introduce new std lib traits (like `LendingIterator`) or to modify existing ones (adding a `'a` generic to `Iterator::Item`). There also a number of other candidates, like `Index`/`IndexMut` and `Fn`/`FnMut`/`FnOnce`. ### Reduce the need for `for<'a>` Seen [here](rust-lang/rfcs#1598 (comment)). One possible syntax: ```rust trait Iterable { type Iter<'a>: Iterator<Item = Self::Item<'a>>; } fn foo<T>() where T: Iterable, T::Item<let 'a>: Display { } //note the `let`! ``` ### Better implied bounds on higher-ranked things Currently if we have a `type Item<'a> where self: 'a`, and a `for<'a> T: Iterator<Item<'a> = &'a ()`, this requires `for<'a> Self: 'a`. Really, we want `for<'a where T: 'a> ...` There was some mentions of this all the back in the RFC thread [here](rust-lang/rfcs#1598 (comment)). ## Alternatives ### Make generics on associated type in bounds a binder Imagine the bound `for<'a> T: Trait<Item<'a>= &'a ()>`. It might be that `for<'a>` is "too large" and it should instead be `T: Trait<for<'a> Item<'a>= &'a ()>`. Brought up in RFC thread [here](rust-lang/rfcs#1598 (comment)) and in a few places since. Another related question: Is `for<'a>` the right syntax? Maybe `where<'a>`? Also originally found in RFC thread [here](rust-lang/rfcs#1598 (comment)). ### Stabilize lifetime GATs first This has been brought up a few times. The idea is to only allow GATs with lifetime parameters to in initial stabilization. This was probably most useful prior to actual implementation. At this point, lifetimes, types, and consts are all implemented and work. It feels like an arbitrary split without strong reason. ## History * On 2016-04-30, [RFC opened](rust-lang/rfcs#1598) * On 2017-09-02, RFC merged and [tracking issue opened](rust-lang/rust#44265) * On 2017-10-23, [Move Generics from MethodSig to TraitItem and ImplItem](rust-lang/rust#44766) * On 2017-12-01, [Generic Associated Types Parsing & Name Resolution](rust-lang/rust#45904) * On 2017-12-15, [https://github.com/rust-lang/rust/pull/46706](https://github.com/rust-lang/rust/pull/46706) * On 2018-04-23, [Feature gate where clauses on associated types](rust-lang/rust#49368) * On 2018-05-10, [Extend tests for RFC1598 (GAT)](rust-lang/rust#49423) * On 2018-05-24, [Finish implementing GATs (Chalk)](rust-lang/chalk#134) * On 2019-12-21, [Make GATs less ICE-prone](rust-lang/rust#67160) * On 2020-02-13, [fix lifetime shadowing check in GATs](rust-lang/rust#68938) * On 2020-06-20, [Projection bound validation](rust-lang/rust#72788) * On 2020-10-06, [Separate projection bounds and predicates](rust-lang/rust#73905) * On 2021-02-05, [Generic associated types in trait paths](rust-lang/rust#79554) * On 2021-02-06, [Trait objects do not work with generic associated types](rust-lang/rust#81823) * On 2021-04-28, [Make traits with GATs not object safe](rust-lang/rust#84622) * On 2021-05-11, [Improve diagnostics for GATs](rust-lang/rust#82272) * On 2021-07-16, [Make GATs no longer an incomplete feature](rust-lang/rust#84623) * On 2021-07-16, [Replace associated item bound vars with placeholders when projecting](rust-lang/rust#86993) * On 2021-07-26, [GATs: Decide whether to have defaults for `where Self: 'a`](rust-lang/rust#87479) * On 2021-08-25, [Normalize projections under binders](rust-lang/rust#85499) * On 2021-08-03, [The push for GATs stabilization](https://blog.rust-lang.org/2021/08/03/GATs-stabilization-push.html) * On 2021-08-12, [Detect stricter constraints on gats where clauses in impls vs trait](rust-lang/rust#88336) * On 2021-09-20, [Proposal: Change syntax of where clauses on type aliases](rust-lang/rust#89122) * On 2021-11-06, [Implementation of GATs outlives lint](rust-lang/rust#89970) * On 2021-12-29. [Parse and suggest moving where clauses after equals for type aliases](rust-lang/rust#92118) * On 2022-01-15, [Ignore static lifetimes for GATs outlives lint](rust-lang/rust#92865) * On 2022-02-08, [Don't constrain projection predicates with inference vars in GAT substs](rust-lang/rust#92917) * On 2022-02-15, [Rework GAT where clause check](rust-lang/rust#93820) * On 2022-02-19, [Only mark projection as ambiguous if GAT substs are constrained](rust-lang/rust#93892) * On 2022-03-03, [Support GATs in Rustdoc](rust-lang/rust#94009) * On 2022-03-06, [Change location of where clause on GATs](rust-lang/rust#90076) * On 2022-05-04, [A shiny future with GATs blog post](https://jackh726.github.io/rust/2022/05/04/a-shiny-future-with-gats.html) * On 2022-05-04, [Stabilization PR](rust-lang/rust#96709)
…, r=lcnr Collect relevant item bounds from trait clauses for nested rigid projections Rust currently considers trait where-clauses that bound the trait's *own* associated types to act like an item bound: ```rust trait Foo where Self::Assoc: Bar { type Assoc; } // acts as if: trait Foo { type Assoc: Bar; } ``` ### Background This behavior has existed since essentially forever (i.e. before Rust 1.0), since we originally started out by literally looking at the where clauses written on the trait when assembling `SelectionCandidate::ProjectionCandidate` for projections. However, looking at the predicates of the associated type themselves was not sound, since it was unclear which predicates were *assumed* and which predicates were *implied*, and therefore this was reworked in rust-lang#72788 (which added a query for the predicates we consider for `ProjectionCandidate`s), and then finally item bounds and predicates were split in rust-lang#73905. ### Problem 1: GATs don't uplift bounds correctly All the while, we've still had logic to uplift associated type bounds from a trait's where clauses. However, with the introduction of GATs, this logic was never really generalized correctly for them, since we were using simple equality to test if the self type of a trait where clause is a projection. This leads to shortcomings, such as: ```rust trait Foo where for<'a> Self::Gat<'a>: Debug, { type Gat<'a>; } fn test<T: Foo>(x: T::Gat<'static>) { //~^ ERROR `<T as Foo>::Gat<'a>` doesn't implement `Debug` println!("{:?}", x); } ``` ### Problem 2: Nested associated type bounds are not uplifted We also don't attempt to uplift bounds on nested associated types, something that we couldn't really support until rust-lang#120584. This can be demonstrated best with an example: ```rust trait A where Self::Assoc: B, where <Self::Assoc as B>::Assoc2: C, { type Assoc; // <~ The compiler *should* treat this like it has an item bound `B<Assoc2: C>`. } trait B { type Assoc2; } trait C {} fn is_c<T: C>() {} fn test<T: A>() { is_c::<<Self::Assoc as B>::Assoc2>(); //~^ ERROR the trait bound `<<T as A>::Assoc as B>::Assoc2: C` is not satisfied } ``` Why does this matter? Well, generalizing this behavior bridges a gap between the associated type bounds (ATB) feature and trait where clauses. Currently, all bounds that can be stably written on associated types can also be expressed as where clauses on traits; however, with the stabilization of ATB, there are now bounds that can't be desugared in the same way. This fixes that. ## How does this PR fix things? First, when scraping item bounds from the trait's where clauses, given a trait predicate, we'll loop of the self type of the predicate as long as it's a projection. If we find a projection whose trait ref matches, we'll uplift the bound. This allows us to uplift, for example `<Self as Trait>::Assoc: Bound` (pre-existing), but also `<<Self as Trait>::Assoc as Iterator>::Item: Bound` (new). If that projection is a GAT, we will check if all of the GAT's *own* args are all unique late-bound vars. We then map the late-bound vars to early-bound vars from the GAT -- this allows us to uplift `for<'a, 'b> Self::Assoc<'a, 'b>: Trait` into an item bound, but we will leave `for<'a> Self::Assoc<'a, 'a>: Trait` and `Self::Assoc<'static, 'static>: Trait` alone. ### Okay, but does this *really* matter? I consider this to be an improvement of the status quo because it makes GATs a bit less magical, and makes rigid projections a bit more expressive.
…, r=lcnr Collect relevant item bounds from trait clauses for nested rigid projections Rust currently considers trait where-clauses that bound the trait's *own* associated types to act like an item bound: ```rust trait Foo where Self::Assoc: Bar { type Assoc; } // acts as if: trait Foo { type Assoc: Bar; } ``` ### Background This behavior has existed since essentially forever (i.e. before Rust 1.0), since we originally started out by literally looking at the where clauses written on the trait when assembling `SelectionCandidate::ProjectionCandidate` for projections. However, looking at the predicates of the associated type themselves was not sound, since it was unclear which predicates were *assumed* and which predicates were *implied*, and therefore this was reworked in rust-lang#72788 (which added a query for the predicates we consider for `ProjectionCandidate`s), and then finally item bounds and predicates were split in rust-lang#73905. ### Problem 1: GATs don't uplift bounds correctly All the while, we've still had logic to uplift associated type bounds from a trait's where clauses. However, with the introduction of GATs, this logic was never really generalized correctly for them, since we were using simple equality to test if the self type of a trait where clause is a projection. This leads to shortcomings, such as: ```rust trait Foo where for<'a> Self::Gat<'a>: Debug, { type Gat<'a>; } fn test<T: Foo>(x: T::Gat<'static>) { //~^ ERROR `<T as Foo>::Gat<'a>` doesn't implement `Debug` println!("{:?}", x); } ``` ### Problem 2: Nested associated type bounds are not uplifted We also don't attempt to uplift bounds on nested associated types, something that we couldn't really support until rust-lang#120584. This can be demonstrated best with an example: ```rust trait A where Self::Assoc: B, where <Self::Assoc as B>::Assoc2: C, { type Assoc; // <~ The compiler *should* treat this like it has an item bound `B<Assoc2: C>`. } trait B { type Assoc2; } trait C {} fn is_c<T: C>() {} fn test<T: A>() { is_c::<<Self::Assoc as B>::Assoc2>(); //~^ ERROR the trait bound `<<T as A>::Assoc as B>::Assoc2: C` is not satisfied } ``` Why does this matter? Well, generalizing this behavior bridges a gap between the associated type bounds (ATB) feature and trait where clauses. Currently, all bounds that can be stably written on associated types can also be expressed as where clauses on traits; however, with the stabilization of ATB, there are now bounds that can't be desugared in the same way. This fixes that. ## How does this PR fix things? First, when scraping item bounds from the trait's where clauses, given a trait predicate, we'll loop of the self type of the predicate as long as it's a projection. If we find a projection whose trait ref matches, we'll uplift the bound. This allows us to uplift, for example `<Self as Trait>::Assoc: Bound` (pre-existing), but also `<<Self as Trait>::Assoc as Iterator>::Item: Bound` (new). If that projection is a GAT, we will check if all of the GAT's *own* args are all unique late-bound vars. We then map the late-bound vars to early-bound vars from the GAT -- this allows us to uplift `for<'a, 'b> Self::Assoc<'a, 'b>: Trait` into an item bound, but we will leave `for<'a> Self::Assoc<'a, 'a>: Trait` and `Self::Assoc<'static, 'static>: Trait` alone. ### Okay, but does this *really* matter? I consider this to be an improvement of the status quo because it makes GATs a bit less magical, and makes rigid projections a bit more expressive.
During selection we use bounds declared on associated types (e.g.
type X: Copy
) to satisfy trait/projection bounds. This would be fine so long as those bounds are checked on any impls/trait objects. For simple cases they are because the boundSelf::X: Copy
gets normalized when we check the impl.However, for default values with specialization and higher-ranked bounds from GATs or otherwise, we can't normalize when checking the impl, and so we use the bound from the trait to prove that the bound applies to the impl, which is clearly unsound.
This PR makes 2 fixes for this:
for<'a> <Self as X<'a>>::U: Copy
on the trait cannot be used to prove<T as X<'_>>::U: Copy
.Opening for a crater run.
Closes #68641
Closes #68642
Closes #68643
Closes #68644
Closes #68645
Closes #68656
r? @ghost