Old Swift and new Swift runtimes and overlays need to coexist in the same process. This means there must not be any classes which have the same ObjC runtime name in old and new, because the ObjC runtime doesn't like name collisions.
When possible without breaking source compatibility, classes were renamed in Swift, which results in a different ObjC name.
Public classes were renamed only on the ObjC side using the @_objcRuntimeName attribute.
This is similar to the work done in pull request #19295. That only renamed @objc classes. This renames all of the others, since even pure Swift classes still get an ObjC name.
rdar://problem/46646438
This adjusts the standard library test suite to mostly pass on Windows.
The remaining failures are due to various cases:
- memory corruption (`_swift_stdlib_free` in swiftDemangle)
- heap corruption (canGrowUsingRealloc)
- withVAList failure (unresolved)
- unicode handling on the command line
getErrorDomainStringForObjC() now includes the parent types in the error domain string. Its implementation does not support generic types or private discriminators, but those types can’t be PrintAsObjC’d anyway, so we should never see them.
Otherwise we generate a call to String(reflecting:), which correctly handles many things we may not be able to (like private types), and which matches the default implementation of Error._domain.
The old SIMD types had a conformance to CustomDebugStringConvertible,
but the new ones do not, causing a source compatibility
regression. Add back a CustomDebugStringConvertible conformance.
Fixes rdar://problem/46746829.
When the compiler fails to find an overload with suitable parameter or return types, it often attaches a note listing the available overloads so that users can find the one they meant to use. The overloads are currently ordered in a way that depends on the order they were declared, so swift-evolve would sometimes cause tests involving these diagnostics to fail.
This change emits the list in a textually-sorted order instead. The names were already being sorted as they were inserted into a std::set, so this shouldn’t significantly slow down the diagnostic.
While declaration mangling now does the right thing for parameter lists,
the function type mangling unfortunately still models the parameter list
as a single tuple node.
Change the runtime's behavior to match the AST mangler, which wraps
a single tuple-typed parameter in a tuple node, so that we can produce
different mangling trees for function types taking multiple arguments
versus a single tuple argument.
* cmake: Propagate SWIFT_DARWIN_ENABLE_STABLE_ABI_BIT to overlay builds.
* runtime: Clear the correct bit in getROData()
* test/IRGen/objc_class_export.swift: Allow either is-Swift bit.
* test/stdlib/SwiftObjectNSObject.swift: Allow either name for SwiftObject.
The SDK directory is now confusing as the Windows target also has a SDK
overlay. In order to make this more uniform, move the SDK directory to
Darwin which covers the fact that this covers the XNU family of OSes.
The Windows directory contains the SDK overlay for the Windows target.
Within the (single) implementation of abs(_:), dynamically check whether
the numeric type and its `Magnitude` are of the same type and, if so,
return the result of `magnitude`. This ensures that we do the right thing
with respect to (e.g.) floating point values like -0.0, without resorting
to overloading of abs(_:).
