Reformatting everything now that we have `llvm` namespaces. I've
separated this from the main commit to help manage merge-conflicts and
for making it a bit easier to read the mega-patch.
This is phase-1 of switching from llvm::Optional to std::optional in the
next rebranch. llvm::Optional was removed from upstream LLVM, so we need
to migrate off rather soon. On Darwin, std::optional, and llvm::Optional
have the same layout, so we don't need to be as concerned about ABI
beyond the name mangling. `llvm::Optional` is only returned from one
function in
```
getStandardTypeSubst(StringRef TypeName,
bool allowConcurrencyManglings);
```
It's the return value, so it should not impact the mangling of the
function, and the layout is the same as `std::optional`, so it should be
mostly okay. This function doesn't appear to have users, and the ABI was
already broken 2 years ago for concurrency and no one seemed to notice
so this should be "okay".
I'm doing the migration incrementally so that folks working on main can
cherry-pick back to the release/5.9 branch. Once 5.9 is done and locked
away, then we can go through and finish the replacement. Since `None`
and `Optional` show up in contexts where they are not `llvm::None` and
`llvm::Optional`, I'm preparing the work now by going through and
removing the namespace unwrapping and making the `llvm` namespace
explicit. This should make it fairly mechanical to go through and
replace llvm::Optional with std::optional, and llvm::None with
std::nullopt. It's also a change that can be brought onto the
release/5.9 with minimal impact. This should be an NFC change.
Upgrade the old mangling from a list of argument types to a
list of requiremnets. For now, only same-type requirements
may actually be mangled since those are all that are available
to the surface language.
Reconstruction of existential types now consists of demangling (a list of)
base protocol(s), decoding the constraints, and converting the same-type
constraints back into a list of arguments.
rdar://96088707
Generic params of typerefs are supposed to be "attached" on the level
they belong, not as a flat list, unlike other parts of the system. Fix
the application of bound generic params by checking how many were
already applied in the hierarchy and ignoring those already attached.
Add requirements to the Builder concept to construct generic signatures and substitution maps. Then introduce a `subst` requirement that uses the substitution map to call through to the builder's notion of type (ref) substitution.
This infrastructure is sufficient to model the notion of a RuntimeGenericSignature.
Implement name mangling, type metadata, runtime demangling, etc. for
global-actor qualified function types. Ensure that the manglings
round-trip through the various subsystems.
Implements rdar://78269642.
* Move differentiability kinds from target function type metadata to trailing objects so that we don't exhaust all remaining bits of function type metadata.
* Differentiability kind is now stored in a tail-allocated word when function type flags say it's differentiable, located immediately after the normal function type metadata's contents (with proper alignment in between).
* Add new runtime function `swift_getFunctionTypeMetadataDifferentiable` which handles differentiable function types.
* Fix mangling of different differentiability kinds in function types. Mangle it like `ConcurrentFunctionType` so that we can drop special cases for escaping functions.
```
function-signature ::= params-type params-type async? sendable? throws? differentiable? // results and parameters
...
differentiable ::= 'jf' // @differentiable(_forward) on function type
differentiable ::= 'jr' // @differentiable(reverse) on function type
differentiable ::= 'jd' // @differentiable on function type
differentiable ::= 'jl' // @differentiable(_linear) on function type
```
Resolves rdar://75240064.
Since libDemangling is included in the Swift standard library,
ODR violations can occur on platforms that allow statically
linking stdlib if Swift code is linked with other compiler
libraries that also transitively pull in libDemangling, and if
the stdlib version and compiler version do not match exactly
(even down to commit drift between releases). This lets the
runtime conditionally segregate its copies of the libDemangling
symbols from those in the compiler using an inline namespace
without affecting usage throughout source.
When printing a swiftinterface, represent opaque result types using an attribute that refers to
the mangled name of the defining decl for the opaque type. To turn this back into a reference
to the right decl's implicit OpaqueTypeDecl, use type reconstruction. Since type reconstruction
doesn't normally concern itself with non-type decls, set up a lookup table in SourceFiles and
ModuleFiles to let us handle the mapping from mangled name to opaque type decl in type
reconstruction.
(Since we're invoking type reconstruction during type checking, when the module hasn't yet been
fully validated, we need to plumb a LazyResolver into the ASTBuilder in an unsightly way. Maybe
there's a better way to do this... Longer term, at least, this surface design gives space for
doing things more the right way--a more request-ified decl validator ought to be able to naturally
lazily service this request without the LazyResolver reference, and if type reconstruction in
the future learns how to reconstruct non-type decls, then the lookup tables can go away.)
MetadataLookup gives special treatment to imported Objective-C classes,
since there's no nominal type descriptor and metadata is obtained
directly by calling into the Objective-C runtime.
Remote reflection also gives special treatment to imported Objective-C
classes; they don't have field descriptors.
However, the ASTDemangler needs to treat them like ordinary classes,
in particular it wants to preserve the generic arguments here so that
we can round-trip debug info.
Debug info uses a special mangling where type aliases can be
represented without being desugared; attempt to reconstruct
the TypeAliasType in this case.
It's clever how it leverages the type checker to check generic arguments,
but calling checkGenericArguments() would have been simpler, and it doesn't
work for interface types anyway, so we would fail to demangle those.
Let's just cut this all out for now and build a BoundGenericType directly.
