This teaches Swift to rebuild the CxxStdlib overlay module from its interface when using a C++ standard library that is not the platform default, specifically libc++ on Linux.
rdar://138838506
Mangling a non-canonical type can run into
unexpected type sugar such as the newly introduced
LocatableType. USRs should be based on canonical
types anyway, so make sure we canonicalize before
mangling.
rdar://141168628
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
Update the logic selecting the most restrictive import for a given
reference to account for @_exported imports from the local module. We
should always prioritize @_exported imports from the local module over
more restrictive same file imports. Only if an import from the same file
is also public we prefer it as it's more useful for diagnostics and
generally recommended to locally declare dependencies.
Also update the test that was meant to check this configuration to apply
two different variations, one for a module local @_exported and one
relying on the underlying clang module.
rdar://140924031
The mangling of macro expansions relies on having a type-checked AST
for its enclosing context. When that enclosing context is within a
local context (say, a local type), mangling would trigger type
checking of that local type, which could then involve assigning local
discriminators. However, if this happens before type checking of the
enclosing function body, we would end up failing to assign closure
discriminators to (e.g.) autoclosures within the body.
The fundamental problem here is the interaction between discriminator
assignment (which can only happen after type checking) and mangling of
macro expansion buffers (which can happen during that type checking).
Break this cycle by providing a different approach to mangling macro
expansions within local contexts as the innermost non-local context +
a name-based discriminator within that local context. These manglings
are not ABI and are not stable, so we can adjust them later if we come
up with a scheme we like better. However, by breaking this cycle, we
eliminate assertions and miscompiles that come from missing
discriminators in this case.
Fixes rdar://139734958.
This query's functionality was not useful enough to be exposed on `Decl` and
cached in the request evaluator. Instead, just share a local implementation of
it in `TypeCheckAttr.cpp`.
There are a bunch of AST nodes that can have
associated DeclNameLocs, make sure we cover them
all. I don't think this makes a difference for
`unwrapPropertyWrapperParameterTypes` since the
extra cases should be invalid, but for cursor info
it ensures we handle UnresolvedMemberExprs.
Just because the type of the initializer expression is an opaque return type,
does not mean it is the opaque return type *for the variable being initialized*.
It looks like there is a bit of duplicated logic and layering violations going
on so I only fixed one caller of openOpaqueType(). This addresses the test case
in the issue. For the remaining calls I added FIXMEs to investigate what is
going on.
Fixes https://github.com/swiftlang/swift/issues/73245.
Fixes rdar://127180656.
Instead, each scan's 'ModuleDependenciesCache' will hold all of the data corresponding to discovered module dependencies.
The initial design presumed the possibility of sharing a global scanning cache amongs different scanner invocations, possibly even different concurrent scanner invocations.
This change also deprecates two libSwiftScan entry-points: 'swiftscan_scanner_cache_load' and 'swiftscan_scanner_cache_serialize'. They never ended up getting used, and since this code has been largely stale, we are confident they have not otherwise had users, and they do not fit with this design.
A follow-up change will re-introduce moduele dependency cache serialization on a per-query basis and bring the binary format up-to-date.
Previously only some random decl attributes were included in the dump
with the source spelling (e.g. @objc), or some affected how the decl is
dumped. But the full attribute list has not been dumped. Dumping
attributes are useful for debugging attribute handling.
Many APIs using nonescapable types would like to vend interior pointers to their
parameter bindings, but this isn't normally always possible because of representation
changes the caller may do around the call, such as moving the value in or out of memory,
bridging or reabstracting it, etc. `@_addressable` forces the corresponding parameter
to be passed indirectly in memory, in its maximally-abstracted representation.
[TODO] If return values have a lifetime dependency on this parameter, the caller must
keep this in-memory representation alive for the duration of the dependent value's
lifetime.
This change addresses the following issue: when an error is being wrapped in a warning, the diagnostic message will use the wrapper's `DiagGroupID` as the warning's name. However, we want to retain the original error's group for use. For example, in Swift 5, async_unavailable_decl is wrapped in error_in_future_swift_version. When we print a diagnostic of this kind, we want to keep the `DiagGroupID` of `async_unavailable_decl`, not that of `error_in_future_swift_version`.
To achieve this, we add `DiagGroupID` to the `Diagnostic` class. When an active diagnostic is wrapped in DiagnosticEngine, we retain the original `DiagGroupID`.
For illustration purposes, this change also introduces a new group: `DeclarationUnavailableFromAsynchronousContext`.
With this change, we produce errors and warnings of this kind with messages like the following:
```
global function 'fNoAsync' is unavailable from asynchronous contexts [DeclarationUnavailableFromAsynchronousContext]
global function 'fNoAsync' is unavailable from asynchronous contexts; this is an error in the Swift 6 language mode [DeclarationUnavailableFromAsynchronousContext]
```
Also remove the underlying `SemanticUnavailableAttrRequest`, which used memory
very inefficiently in order to cache a detailed answer to what was usually a
much simpler question.
The only remaining use of `Decl::getSemanticUnavailableAttr()` that actually
needed to locate the semantic attribute making a declaration unavailable was in
`TypeCheckAttr.cpp`. The implementation of the request could just be used
directly in that one location. The other remaining callers only needed to know
if the decl was unavailable or not, which there are simpler queries for.
# Please enter the commit message for your changes. Lines starting
This is a crucial fix without which we can crash on some distributed
protocol declarations with @Resolvable. We cannot "just" use a String to
represent the "fake base" of the thunks, and must instead find the
$Target macro generated type and use it as the base of the thunk's
mangling.
Calls are made in such way that record for the protocol requirement:
`$s4main28GreeterDefinedSystemProtocolP5greetSSyYaKFTEHF` points at
`$$s4main29$GreeterDefinedSystemProtocolC5greetSSyYaKFTE` which makes a
dispatch through the _apropriate_ witness table.
And the record for the $witness named e.g.
`$s4main29$GreeterDefinedSystemProtocolC5greetSSyYaKFTEHF` points to
`$s4main28GreeterDefinedSystemProtocolPAA11Distributed01_F9ActorStubRzrlE5greetSSyYaKFTE`
which is an extension method: `distributed thunk (extension in main):main.GreeterDefinedSystemProtocol< where A: Distributed._DistributedActorStub>.greet() async throws -> Swift.String`,
this very specific design allows us to call the "right method" on the
recieving end of a remote call where we do not know the recipient type.
