After the last commit, they contain `Option<&OperandBundleDef<'a>>` but
the values are always `Some(_)`. This commit removes the needless
`Option` wrapper. This also simplifies the type signatures of
`LLVMRustBuild{Invoke,Call}`, which were relying on the fact that the
represention of `Option<&T>` is the same as `&T` for non-`None` values.
They never have a length of more than two. So this commit changes them
to `SmallVec<[_; 2]>`.
Also, we possibly push `None` values and then filter those `None` values
out again with `retain`. So this commit removes the `retain` and instead
only pushes the values if they are `Some(_)`.
It no longer has any uses. If it's needed in the future, it can be
easily reinstated. Or a crate such as `smallstr` can be used, much like
we use `smallvec`.
I don't know why `SmallStr` was used here; some ad hoc profiling showed
this code is not that hot, the string is usually empty, and when it's
not empty it's usually very short. However, the use of a
`SmallStr<1024>` does result in 1024 byte `memcpy` call on each
execution, which shows up when I do `memcpy` profiling. So using a
normal string makes the code both simpler and very slightly faster.
`lookup_debug_loc` finds a file, line, and column, which requires two
binary searches. But this call site only needs the file.
This commit replaces the call with `lookup_source_file`, which does a
single binary search.
`lookup_debug_loc` calls `SourceMap::lookup_line`, which does a binary
search over the files, and then a binary search over the lines within
the found file. It then calls `SourceFile::line_begin_pos`, which redoes
the binary search over the lines within the found file.
This commit removes the second binary search over the lines, instead
getting the line starting pos directly using the result of the first
binary search over the lines.
(And likewise for `get_span_loc`, in the cranelift backend.)
Make associated type bounds in supertrait position implied
`trait A: B<Assoc: C> {}` should be able to imply both `Self: B` and `<Self as B>::Assoc: C`. Adjust the way that we collect implied predicates to do so.
Fixes#112573Fixes#112568
add check for ConstKind::Value(_) to in_operand()
Added check for valtree value to close#113012 which fixes the issue, although I am not sure if adding the check there is sound or not cc `@oli-obk`
Refactor metadata emission to avoid visiting HIR
This PR refactors metadata emission to be based on tables and iteration over definitions.
In a first part, this PR moves information from the `EntryKind` enum to tables, until removing the `EntryKind` enum.
In a second part, the iteration scheme is refactored to avoid fetching HIR unless strictly necessary.
r? `@ghost`
add note for non-exhaustive matches with guards
Associated issue: #92197
When a match statement includes guards on every match arm (and is therefore necessarily non-exhaustive), add a note to the error E0004 diagnostic noting this.
Validate fluent variable references in tests
Closes#101109
Under `cfg(test)`, the `fluent_messages` macro will emit a list of variables referenced by each message and its attributes. The derive attribute will now emit a `#[test]` that checks that each referenced variable exists in the structure it's applied to.
mir opt + codegen: handle subtyping
fixes#107205
the same issue was caused in multiple places:
- mir opts: both copy and destination propagation
- codegen: assigning operands to locals (which also propagates values)
I changed codegen to always update the type in the operands used for locals which should guard against any new occurrences of this bug going forward. I don't know how to make mir optimizations more resilient here. Hopefully the added tests will be enough to detect any trivially wrong optimizations going forward.
Make `UnwindAction::Continue` explicit in MIR dump
Makes it easier to spot unwinding related issues in MIR by making `UnwindAction::Continue` explicit, just like all other `UnwindAction`s.
Add trustzone and virtualization target features for aarch32.
These are LLVM target features which allow the `smc` and `hvc` instructions respectively to be used in inline assembly.
