Begin accepting the attribute in the form of `@cdecl(cName)`, using an
identifier instead of a string.
For ease of landing this change we still accept the string form. We
should stop accepting it before making this feature available in
production.
This implements basic checks on the validity of the @cdecl attribute and
ensures the parameters and result types are representable in C. Many
more diagnostics will need to be updated to verify full representability
in C.
Adds an access control field for each imported module identified. When multiple imports of the same module are found, this keeps track of the most "open" access specifier.
Split out the state mutation into a new `updateFor`
function that we call for diagnostic emission, allowing
`DiagnosticTransaction::hasErrors` to query the behavior without
mutating any state.
It's shouldn't be possible to use these attributes directly on
the function type that is `@isolated(any)` as per SE-0461 proposal
but it shouldn't preclude declarations that have parameters with
`@isolated(any)` from using them.
Resolves: rdar://154754939
(cherry picked from commit a522448e90)
- **Explanation**: USR mangling can include an extension context infix
(`AAE`) when an extended type uses `@_originallyDefinedIn` on platforms
other than the active one. This adds a check for the
`RespectOriginallyDefinedIn` flag when checking extension decls against
their extended type.
- **Scope**: Changes USR mangling in these situations so that USRs are
the same for the same code regardless of platform.
- **Issues**: rdar://152598492
- **Original PRs**: https://github.com/swiftlang/swift/pull/82348
- **Risk**: Low. The change is limited to situations where the name
mangler is already disrespecting the alternate module name, and only
additionally turns on that flag for any USR mangling.
- **Testing**: Automated tests
- **Reviewers**: @edymtt @augusto2112
use local funcs to implement `defer`, this also fixes several
bugs with that feature, such as it breaking in nonisolated
functions when a default isolation is in effect in the source file.
Change how we compute isolation of local funcs. The rule here is
supposed to be that non-`@Sendable` local funcs are isolated the
same as their enclosing context. Unlike closure expressions, this
is unconditional: in instance-isolated functions, the isolation
does not depend on whether `self` is captured. But the computation
was wrong: it didn't translate global actor isolation between
contexts, it didn't turn parameter isolation into capture isolation,
and it fell through for several other kinds of parent isolation,
causing the compiler to try to apply default isolation instead.
I've extracted the logic from the closure expression path into a
common function and used it for both paths.
The capture computation logic was forcing a capture of the
enclosing isolation in local funcs, but only for async functions.
Presumably this was conditional because async functions need the
isolation for actor hops, but sync functions don't really need it.
However, this was causing crashes with `-enable-actor-data-race-checks`.
(I didn't investigate whether it also failed with the similar
assertion we do with preconcurrency.) For now, I've switched this
to capture the isolated instance unconditionally. If we need to
be more conservative by either only capturing when data-race checks
are enabled or disabling the checks when the isolation isn't captured,
we can look into that.
Fix a bug in capture isolation checking. We were ignoring captures
of nonisolated declarations in order to implement the rule that
permits `nonisolated(unsafe)` variables to be captured in
non-sendable closures. This check needs to only apply to variables!
The isolation of a local func has nothing to do with its sendability
as a capture.
That fix exposed a problem where we were being unnecessarily
restrictive with generic local func declarations because we didn't
consider them to have sendable type. This was true even if the
genericity was purely from being declared in a generic context,
but it doesn't matter, they ought to be sendable regardless.
Finally, fix a handful of bugs where global actor types were not
remapped properly in SILGen.
This is a common mistake made more common be suggestions of existing diagnostic
that tell users not to use a 'copy' dependency.
Report a diagnostic error rather than crashing the compiler. Fix the diagnostic
output to make sense relative to the source location.
Fixes rdar://154136015 ([nonescapable] compiler assertion with @_lifetime(x: inout x))
(cherry picked from commit 080b68292d)
Correctly diagnose this as:
"invalid use of inout dependence on the same inout parameter
@_lifetime(a: &a)
func f_inout_useless(a: inout MutableRawSpan) {}
Correctly diagnose this as:
"lifetime-dependent parameter must be 'inout'":
@_lifetime(a: borrow a)
func f_inout_useless(a: borrowing MutableRawSpan) {}
(cherry picked from commit 05fa82b7a7)
This comes up often when passing a MutableSpan as an 'inout' argument. The
vague diagnostic was causing developers to attempt incorrect @_lifetime
annotations. Be clear about why the annotation is needed and which annotation
should be used.
(cherry picked from commit df0b81c88d)
This lifts the check for the feature flag up into the `importParameterType`
from `importType` and means that completion handler type for `async` variant
is no longer gains `@Sendable` attribute.
(cherry picked from commit 74471e858b)
Non-escapable struct definitions often have inicidental integer fields that are
unrelated to lifetime. Without an explicit initializer, the compiler would infer
these fields to be borrowed by the implicit intializer.
struct CountedSpan: ~Escapable {
let span: Span<Int>
let i: Int
/* infer: @lifetime(copy span, borrow i) init(...) */
}
This was done because
- we always want to infer lifetimes of synthesized code if possible
- inferring a borrow dependence is always conservative
But this was the wrong decision because it inevitabely results in lifetime
diagnostic errors elsewhere in the code that can't be tracked down at the use
site:
let span = CountedSpan(span: span, i: 3) // ERROR: span depends on the lifetime of this value
Instead, force the author of the data type to specify whether the type actually
depends on trivial fields or not. Such as:
struct CountedSpan: ~Escapable {
let span: Span<Int>
let i: Int
@lifetime(copy span) init(...) { ... }
}
This fix enables stricter diagnostics, so we need it in 6.2.
Fixes rdar://152130977 ([nonescapable] confusing diagnostic message when a
synthesized initializer generates dependence on an Int parameter)
(cherry picked from commit 8789a686fed869e3cd7bc4e748a443e71df464e1)
'@preconcurrency' imports open up memory safety holes with respect to
Sendable, which are diagnosed under strict memory safety + strict
concurrency checking. Allow one to write '@unsafe' on those imports to
silence the diagnostic about it.
To guard the new UnsafeMutablePointer.mutableSpan APIs.
This allows older compilers to ignore the new APIs. Otherwise, the type checker
will crash on the synthesized _read accessor for a non-Escapable type:
error: cannot infer lifetime dependence on the '_read' accessor because 'self'
is BitwiseCopyable, specify '@lifetime(borrow self)'
I don't know why the _read is synthesized in these cases, but apparently it's
always been that way.
Fixes: rdar://153773093 ([nonescapable] add a compiler feature to guard
~Escapable accessors when self is trivial)
(cherry picked from commit cc357f4f32)
These are special declarations that are synthesized by the compiler
or a macro and warnings about them are non-actionable.
(cherry picked from commit 17976c7775)
Currently, when we jump-to-definition for decls that are macro-expanded
from Clang imported decls (e.g., safe overloads generated by
@_SwiftifyImport), setLocationInfo() emits a bongus location pointing to
a generated buffer, leading the IDE to try to jump to a file that does
not exist.
The root cause here is that setLocationInfo() calls getOriginalRange()
(earlier, getOriginalLocation()), which was not written to account for
such cases where a macro is generated from another generated buffer
whose kind is 'AttributeFromClang'.
This patch fixes setLocationInfo() with some refactoring:
- getOriginalRange() is inlined into setLocationInfo(), so that the
generated buffer-handling logic is localized to that function. This
includes how it handles buffers generated for ReplacedFunctionBody.
- getOriginalLocation() is used in a couple of other places that only
care about macros expanded from the same buffer (so other generated
buffers not not relevant). This "macro-chasing" logic is simplified
and moved from ModuleDecl::getOriginalRange() to a free-standing
function, getMacroUnexpandedRange() (there is no reason for it to be
a method of ModuleDecl).
- GeneratedSourceInfo now carries an extra ClangNode field, which is
populated by getClangSwiftAttrSourceFile() when constructing
a generated buffer for an 'AttributeFromClang'. This could probably
be union'ed with one or more of the other fields in the future.
rdar://151020332
(cherry picked from commit 44aba1382d)
