The only reason to use `abort_if_errors` is when the program is so broken that either:
1. later passes get confused and ICE
2. any diagnostics from later passes would be noise
This is never the case for lints, because the compiler has to be able to deal with `allow`-ed lints.
So it can continue to lint and compile even if there are lint errors.
Add features gates for experimental asm features
This PR splits off parts of `asm!` into separate features because they are not ready for stabilization.
Specifically this adds:
- `asm_const` for `const` operands.
- `asm_sym` for `sym` operands.
- `asm_experimental_arch` for architectures other than x86, x86_64, arm, aarch64 and riscv.
r? `@nagisa`
Rollup of 6 pull requests
Successful merges:
- #90487 (Add a chapter on reading Rustdoc output)
- #90508 (Apply adjustments for field expression even if inaccessible)
- #90627 (Suggest dereference of `Box` when inner type is expected)
- #90642 (use matches!() macro in more places)
- #90646 (type error go brrrrrrrr)
- #90649 (Run reveal_all on MIR when inlining is activated.)
Failed merges:
r? `@ghost`
`@rustbot` modify labels: rollup
type error go brrrrrrrr
Fixes#90444
when we relate something like:
`fn(fn((), (), u32))` with `fn(fn((), (), ()))`
we relate the inner fn ptrs:
`fn((), (), u32)` with `fn((), (), ())`
yielding a `TypeError::ArgumentSorts(_, 2)` which we then use as the `TypeError` for the `fn(fn(..))` which later causes the ICE as the `2` does not correspond to any input or output types in `fn(_)`
r? `@estebank`
Suggest dereference of `Box` when inner type is expected
For example:
enum Ty {
Unit,
List(Box<Ty>),
}
fn foo(x: Ty) -> Ty {
match x {
Ty::Unit => Ty::Unit,
Ty::List(elem) => foo(elem),
}
}
Before, the only suggestion was to rewrap `inner` with `Ty::Wrapper`,
which is unhelpful and confusing:
error[E0308]: mismatched types
--> src/test/ui/suggestions/boxed-variant-field.rs:9:31
|
9 | Ty::List(elem) => foo(elem),
| ^^^^
| |
| expected enum `Ty`, found struct `Box`
| help: try using a variant of the expected enum: `Ty::List(elem)`
|
= note: expected enum `Ty`
found struct `Box<Ty>`
Now, rustc will first suggest dereferencing the `Box`, which is most
likely what the user intended:
error[E0308]: mismatched types
--> src/test/ui/suggestions/boxed-variant-field.rs:9:31
|
9 | Ty::List(elem) => foo(elem),
| ^^^^ expected enum `Ty`, found struct `Box`
|
= note: expected enum `Ty`
found struct `Box<Ty>`
help: try dereferencing the `Box`
|
9 | Ty::List(elem) => foo(*elem),
| +
help: try using a variant of the expected enum
|
9 | Ty::List(elem) => foo(Ty::List(elem)),
| ~~~~~~~~~~~~~~
r? ``@davidtwco``
Apply adjustments for field expression even if inaccessible
The adjustments are used later by ExprUseVisitor to build Place projections and without adjustments it can produce invalid result.
Fix#90483
``@rustbot`` label: T-compiler
Add a chapter on reading Rustdoc output
Includes documentation for:
- general page structure
- navigation
- searching
- themes
- deep-linking
Doesn't include docs on the settings page.
Per https://github.com/rust-lang/rust/issues/90309
For example:
enum Ty {
Unit,
List(Box<Ty>),
}
fn foo(x: Ty) -> Ty {
match x {
Ty::Unit => Ty::Unit,
Ty::List(elem) => foo(elem),
}
}
Before, the only suggestion was to rewrap `elem` with `Ty::List`,
which is unhelpful and confusing:
error[E0308]: mismatched types
--> src/test/ui/suggestions/boxed-variant-field.rs:9:31
|
9 | Ty::List(elem) => foo(elem),
| ^^^^
| |
| expected enum `Ty`, found struct `Box`
| help: try using a variant of the expected enum: `Ty::List(elem)`
|
= note: expected enum `Ty`
found struct `Box<Ty>`
Now, rustc will first suggest dereferencing the `Box`, which is most
likely what the user intended:
error[E0308]: mismatched types
--> src/test/ui/suggestions/boxed-variant-field.rs:9:31
|
9 | Ty::List(elem) => foo(elem),
| ^^^^ expected enum `Ty`, found struct `Box`
|
= note: expected enum `Ty`
found struct `Box<Ty>`
help: try dereferencing the `Box`
|
9 | Ty::List(elem) => foo(*elem),
| +
help: try using a variant of the expected enum
|
9 | Ty::List(elem) => foo(Ty::List(elem)),
| ~~~~~~~~~~~~~~
Optimize bidi character detection.
Should fix most of the performance regression of the bidi character detection (#90514), to be confirmed with a perf run.
Initialize LLVM time trace profiler on each code generation thread
In https://reviews.llvm.org/D71059 LLVM 11, the time trace profiler was
extended to support multiple threads.
`timeTraceProfilerInitialize` creates a thread local profiler instance.
When a thread finishes `timeTraceProfilerFinishThread` moves a thread
local instance into a global collection of instances. Finally when all
codegen work is complete `timeTraceProfilerWrite` writes data from the
current thread local instance and the instances in global collection
of instances.
Previously, the profiler was intialized on a single thread only. Since
this thread performs no code generation on its own, the resulting
profile was empty.
Update LLVM codegen to initialize & finish time trace profiler on each
code generation thread.
cc `@tmandry`
r? `@wesleywiser`
Append .0 to unsuffixed float if it would otherwise become int token
Previously the unsuffixed f32/f64 constructors of `proc_macro::Literal` would create literal tokens that are definitely not a float:
```rust
Literal::f32_unsuffixed(10.0) // 10
Literal::f32_suffixed(10.0) // 10f32
Literal::f64_unsuffixed(10.0) // 10
Literal::f64_suffixed(10.0) // 10f64
```
Notice that the `10` are actually integer tokens if you were to reparse them, not float tokens.
This diff updates `Literal::f32_unsuffixed` and `Literal::f64_unsuffixed` to produce tokens that unambiguously parse as a float. This matches longstanding behavior of the proc-macro2 crate's implementation of these APIs dating back at least 3.5 years, so it's likely an unobjectionable behavior.
```rust
Literal::f32_unsuffixed(10.0) // 10.0
Literal::f32_suffixed(10.0) // 10f32
Literal::f64_unsuffixed(10.0) // 10.0
Literal::f64_suffixed(10.0) // 10f64
```
Fixes https://github.com/dtolnay/syn/issues/1085.
Implementation of GATs outlives lint
See #87479 for background. Closes#87479
The basic premise of this lint/error is to require the user to write where clauses on a GAT when those bounds can be implied or proven from any function on the trait returning that GAT.
## Intuitive Explanation (Attempt) ##
Let's take this trait definition as an example:
```rust
trait Iterable {
type Item<'x>;
fn iter<'a>(&'a self) -> Self::Item<'a>;
}
```
Let's focus on the `iter` function. The first thing to realize is that we know that `Self: 'a` because of `&'a self`. If an impl wants `Self::Item` to contain any data with references, then those references must be derived from `&'a self`. Thus, they must live only as long as `'a`. Furthermore, because of the `Self: 'a` implied bound, they must live only as long as `Self`. Since it's `'a` is used in place of `'x`, it is reasonable to assume that any value of `Self::Item<'x>`, and thus `'x`, will only be able to live as long as `Self`. Therefore, we require this bound on `Item` in the trait.
As another example:
```rust
trait Deserializer<T> {
type Out<'x>;
fn deserialize<'a>(&self, input: &'a T) -> Self::Out<'a>;
}
```
The intuition is similar here, except rather than a `Self: 'a` implied bound, we have a `T: 'a` implied bound. Thus, the data on `Self::Out<'a>` is derived from `&'a T`, and thus it is reasonable to expect that the lifetime `'x` will always be less than `T`.
## Implementation Algorithm ##
* Given a GAT `<P0 as Trait<P1..Pi>>::G<Pi...Pn>` declared as `trait T<A1..Ai> for A0 { type G<Ai...An>; }` used in return type of one associated function `F`
* Given env `E` (including implied bounds) for `F`
* For each lifetime parameter `'a` in `P0...Pn`:
* For each other type parameter `Pi != 'a` in `P0...Pn`: // FIXME: this include of lifetime parameters too
* If `E => (P: 'a)`:
* Require where clause `Ai: 'a`
## Follow-up questions ##
* What should we do when we don't pass params exactly?
For this example:
```rust
trait Des {
type Out<'x, D>;
fn des<'z, T>(&self, data: &'z Wrap<T>) -> Self::Out<'z, Wrap<T>>;
}
```
Should we be requiring a `D: 'x` clause? We pass `Wrap<T>` as `D` and `'z` as `'x`, and should be able to prove that `Wrap<T>: 'z`.
r? `@nikomatsakis`
Rollup of 5 pull requests
Successful merges:
- #89942 (Reorder `widening_impl`s to make the doc clearer)
- #90569 (Fix tests using `only-i686` to use the correct `only-x86` directive)
- #90597 (Warn for variables that are no longer captured)
- #90623 (Remove more checks for LLVM < 12)
- #90626 (Properly register text_direction_codepoint_in_comment lint.)
Failed merges:
r? `@ghost`
`@rustbot` modify labels: rollup
Properly register text_direction_codepoint_in_comment lint.
This makes it known to the compiler so it can be configured like with `#![allow(text_direction_codepoint_in_comment)]`.
Fixes#90614.
Fix ICE when rustdoc is scraping examples inside of a proc macro
This PR provides a clearer semantics for how --scrape-examples interacts with macros. If an expression's span AND it's enclosing item's span both are not `from_expansion`, then the example will be scraped. The added test case `rustdoc-scrape-examples-macros` shows a variety of situations.
* A macro-rules macro that takes a function call as input: good
* A macro-rules macro that generates a function call as output: bad
* A proc-macro that generates a function call as output: bad
* An attribute macro that generates a function call as output: bad
* An attribute macro that takes a function call as input: good, if the proc macro is designed to propagate the input spans
I ran this updated rustdoc on pyo3 and confirmed that it successfully scrapes examples from inside a proc macro, eg
<img width="1013" alt="Screen Shot 2021-11-04 at 1 11 28 PM" src="https://user-images.githubusercontent.com/663326/140412691-81a3bb6b-a448-4a1b-a293-f7a795553634.png">
(cc `@mejrs)`
Additionally, this PR fixes an ordering bug in the highlighting logic.
Fixes https://github.com/rust-lang/rust/issues/90567.
r? `@jyn514`
In https://reviews.llvm.org/D71059 LLVM 11, the time trace profiler was
extended to support multiple threads.
`timeTraceProfilerInitialize` creates a thread local profiler instance.
When a thread finishes `timeTraceProfilerFinishThread` moves a thread
local instance into a global collection of instances. Finally when all
codegen work is complete `timeTraceProfilerWrite` writes data from the
current thread local instance and the instances in global collection
of instances.
Previously, the profiler was intialized on a single thread only. Since
this thread performs no code generation on its own, the resulting
profile was empty.
Update LLVM codegen to initialize & finish time trace profiler on each
code generation thread.
Re-export some iterators from `core` in `std`
These iterators seem to have been forgotten to be re-exported from `std` (through `alloc`)
These are stable:
`core::slice::{SplitInclusive, SplitInclusiveMut}`
This one is still unstable:
`core::slice::EscapeAscii` (cc #77174)
