The legacy parser has a special case for code like `fn(:)` which corrects it to `fn(_:)`, but the new `::` token was interfering with cases where there were two adjacent colons (e.g. `fn(::)`). Correct this issue.
In Swift 6 and later, whitespace is no longer permitted between an
attribute name and the opening parenthesis. Update the parser so that
in Swift 6+, a `(` without preceding whitespace is always treated as
the start of the argument list, while a '(' with preceding whitespace is
considered the start of the argument list _only when_ it is unambiguous.
This change makes the following closure be parsed correctly:
{ @MainActor (arg: Int) in ... }
rdar://147785544
Implements SE-0460 -- the non-underscored version of @specialized.
It allows to specify "internal" (not abi affecting) specializations.
rdar://150033316
By default (currently) the closure passed to a parameter with `@_inheritActorContext`
would only inherit isolation from `nonisolated`, global actor isolated or actor
context when "self" is captured by the closure. `always` changes this behavior to
always inherit actor isolation from context regardless of whether it's captured
or not.
* [CS] Decline to handle InlineArray in shrink
Previously we would try the contextual type `(<int>, <element>)`,
which is wrong. Given we want to eliminate shrink, let's just bail.
* [Sema] Sink `ValueMatchVisitor` into `applyUnboundGenericArguments`
Make sure it's called for sugar code paths too. Also let's just always
run it since it should be a pretty cheap check.
* [Sema] Diagnose passing integer to non-integer type parameter
This was previously missed, though would have been diagnosed later
as a requirement failure.
* [Parse] Split up `canParseType`
While here, address the FIXME in `canParseTypeSimpleOrComposition`
and only check to see if we can parse a type-simple, including
`each`, `some`, and `any` for better recovery.
* Introduce type sugar for InlineArray
Parse e.g `[3 x Int]` as type sugar for InlineArray. Gated behind
an experimental feature flag for now.
The original module names themselves must still be valid unescaped identifiers; most of the serialization logic in the compiler depends on the name of a module matching its name on the file system, and it would be very complex to turn escaped identifiers into file-safe names.
Raw identifiers are backtick-delimited identifiers that can contain any
non-identifier character other than the backtick itself, CR, LF, or other
non-printable ASCII code units, and which are also not composed entirely
of operator characters.
This will unblock parsing and type-checking availability queries that specify
custom availability domains, e.g.:
```
if #available(CustomDomain) {
// Use declarations protected by @available(CustomDomain)
}
```
Memory unsafety in the iteration part of the for-in loop (i.e., the part
that works on the iterator) can be covered by the "unsafe" effect on
the for..in loop, before the pattern.
* Move `AvailabilitySpec` handling logic to AST, so they can be shared
between libParse and ASTGen
* Requestify '-define-availability' arguments parsing and parse them
with 'SwiftParser' according to the 'ParserASTGen' feature flag
* Implement 'AvailableAttr' generation in ASTGen
There’s a very easy to reach `llvm_unreachable()` in this code which ought to be a diagnostic, as well as a couple of other issues. Rework it into something that’s a bit better at handling the edge cases.
This attribute will allow you to specify an alternate version of the declaration used for mangling. It will allow minor adjustments to be made to declarations so long as they’re still compatible at the calling convention level, such as refining isolation or sendability, renaming without breaking ABI, etc.
The attribute is behind the experimental feature flag `ABIAttribute`.
Since the introduction of custom attributes (as part of property
wrappers), we've modeled the context of expressions within these
attributes as PatternBindingInitializers. These
PatternBindingInitializers would get wired in to the variable
declarations they apply to, establishing the appropriate declaration
context hierarchy. This worked because property wrappers only every
applied to---you guessed it!---properties, so the
PatternBindingInitializer would always get filled in.
When custom attributes were extended to apply to anything for the
purposes of macros, the use of PatternBindingInitializer became less
appropriate. Specifically, the binding declaration would never get
filled in (it's always NULL), so any place in the compiler that
accesses the binding might have to deal with it being NULL, which is a
new requirement. Few did, crashes ensued.
Rather than continue to play whack-a-mole with the abused
PatternBindingInitializer, introduce a new CustomAttributeInitializer
to model the context of custom attribute arguments. When the
attributes are assigned to a declaration that has a
PatternBindingInitializer, we reparent this new initializer to the
PatternBindingInitializer. This helps separate out the logic for
custom attributes vs. actual initializers.
Fixes https://github.com/swiftlang/swift/issues/76409 / rdar://136997841
The previous logic for this was unused, replace
it with new logic that consults
InvertibleProtocols.def for the list of protocols
to suggest.
rdar://139212286
