Previously we had two separate mechanisms to turn a metatype
into a string. The swift_typeName() function was used to print
the metatype in a human-readable fashion, whereas the
_swift_buildDemanglingForMetadata() was used when naming
generated generic Objective-C classes.
Unify them, since what swift_typeName() does is redundant;
instead of going directly from the metatype to a human-readable
string, we can get the mangling, and print that using the
demangler.
This fixes some issues with unnecessary parenthesis when
printing function types, and also allows Objective-C classes
to be instantiated with nested generic types as parameters.
When in Swift 3 Compatibility Mode we now acceptable a standalone
'$' as an identifier. In all other cases this is now disallowed
and must be surrounded by backticks.
We don't want the machine calling conventions for closure invocation functions to necessarily be tied to the convention for normal thin functions or methods. NFC yet; for now, 'closure' follows the same behavior as the 'method' convention, but as part of partial_apply simplification it will be a requirement that partial_apply takes a @convention(closure) function and a box and produces a @convention(thick) function from them.
llvm r283043 and possibly other recent changes switch to use StringRef
instead of char* pointers. Update Swift to match. In some cases, this is
a clear improvement. It would be good to assess the impact on memory use,
particularly for the Filename component of source locations.
Note that the change to SILLocation::isNull fixes an apparent bug where
the location was treated as null when the filename was *not* null.
The recent @escaping on variadic argument closures back-compat fix is
the first Swift 3.0 compatibility behavior that we don't want to carry
forwards indefinitely into the future. To address this, we
version-gate the diagnostic suppression.
Makes it an official compatibility check. Creates new test directory
for compatibility testing. Allow -swift-version 4 so that we can test
it both ways.
With a bit of work, we can re-purpose the existing
QualifiedArchetype mangling to cover this case.
This allows us to get rid of a usage of
ArchetypeType::getSelfProtocol(), which we want to remove.
This flag switches the "effective language version" of the compiler,
at least to any version supported (as of this change: "3" or "3.0").
At the moment nothing uses it except the language version build
configuration statements (#if swift(...)) and various other places
that report, encode, or otherwise check version numbers.
In the future, it's intended as scaffolding for backwards compatibility.
Fixes SR-2582
Now that I am going to be adding an IN_SWIFT_COMPONENT argument, I need to do
this to distinguish the concepts of an LLVM_COMPONENT and a SWIFT_COMPONENT.
Local generic types can appear inside functions inside extensions
of other types. When demangling bound generic arguments, the demangler
assumed that a module was the only other kind of context outside
of nominal types.
rdar://problem/27573079
* Add UnsafeRawPointer type and API.
As proposed in SE-0107: UnsafeRawPointer.
https://github.com/apple/swift-evolution/blob/master/proposals/0107-unsaferawpointer.md
The fundamental difference between Unsafe[Mutable]RawPointer and
Unsafe[Mutable]Pointer<Pointee> is simply that the former is used for "untyped"
memory access, and the later is used for "typed" memory access. Let's refer to
these as "raw pointers" and "typed pointers". Because operations on raw pointers
access untyped memory, the compiler cannot make assumptions about the underlying
type of memory and must be conservative. With operations on typed pointers, the
compiler may make strict assumptions about the type of the underlying memory,
which allows more aggressive optimization.
Memory can only be accessed by a typed pointer when it is currently
bound to the Pointee type. Memory can be bound to type `T` via:
- `UnsafePointer<T>.allocate(capacity: n)`
- `UnsafePointer<Pointee>.withMemoryRebound(to: T.self, capacity: n) {...}`
- `UnsafeMutableRawPointer.initializeMemory(as: T.self, at: i, count: n, to: x)`
- `UnsafeMutableRawPointer.initializeMemory(as: T.self, from: p, count: n)`
- `UnsafeMutableRawPointer.moveInitializeMemory(as: T.self, from: p, count: n)`
- `UnsafeMutableRawPointer.bindMemory(to: T.self, capacity: n)`
Mangle UnsafeRawPointer as predefined substitution 'Sv' for Swift void
pointer ([urp] are taken).
* UnsafeRawPointer minor improvements.
Incorporate Dmitri's feedback.
Properly use a _memmove helper.
Add load/storeBytes alignment precondition checks.
Reword comments.
Demangler tests.
* Fix name mangling test cases.
* Fix bind_memory specialization.
- All parts of the compiler now use ‘P1 & P2’ syntax
- The demangler and AST printer wrap the composition in parens if it is
in a metatype lookup
- IRGen mangles compositions differently
- “protocol<>” is now “swift.Any”
- “protocol<_TP1P,_TP1Q>” is now “_TP1P&_TP1Q”
- Tests cases are updated and added to test the new syntax and mangling
Some modifications for the ms-extension option of the clang.exe in the Visual Studio 2015 development environment
This patch is only for swiftc.exe. I used the library set of Visual Studio 2015 Update 1 and recent version of swift-clang as the compiler. If you are using the real MSVC compiler, more patch might be required.
...by canonicalizing it to the known platform name. This isn't a
wonderful answer, but it preserves the invariant that a platform
condition has at most one value.
A later commit will switch which one is the default.
All of the checks here perform the same operation and use a locally defined
static array. Create a small helper that performs the contains operation. NFC.
