LLVM changing SmallSetVector resulted in it no longer being a SetVector.
swift::SmallSetVector is an llvm::SetVector though, so I just changed
out the types. If we need to change more, we can do that.
The memory effects are no longer represented as raw attributes, but as
its own type. This patch migrates IRGen over to using the new unified
memory effect type.
This removes some of the typed pointer cutouts in IRGen.
LLVM has removed the typed pointers, so `LLVMContext.setOpaquePointers`
doesn't make sense. Clang doesn't have opaque pointers either.
Also removing defunct assertions in IRGen were checking pointer-type
information. With llvm moving to opaque pointer types, these functions
are no longer returning useful information and are deprecated.
Specifically
- `isOpaqueOrPointeeTypeMatches` always returns true
- `supportsTypedPointers()` always returns false
- `getNonOpaquePointerElementType()->isFunctionTy()` will never get hit
`StringRef::endswith_insensitive` and
`StringRef::startswith_insensitive` is deprecated and being replaced
with `StringRef::ends_with_insensitive` and
`StringRef::starts_with_insensitive` respectively.
Ensure that context descriptor pointers are signed in the runtime by putting the ptrauth_struct attribute on the types.
We use the new __builtin_ptrauth_struct_key/disc to conditionally apply ptrauth_struct to TrailingObjects based on the signing of the base type, so that pointers to TrailingObjects get signed when used with a context descriptor pointer.
We add new runtime entrypoints that take signed pointers where appropriate, and have the compiler emit calls to the new entrypoints when targeting a sufficiently new OS.
rdar://111480914
- Renames ExperimentalPlatformCCallingConvention to
PlatformCCallingConvention.
- Removes non-arm calling convention support as this feature is working
around a clang bug for some arm triples which we hope to see resolved.
- Removes misleading MetaVarName from platform-c-calling-convention
argument.
- Replaces other uses of LLVM::CallingConv::C with
IGM.getOptions().PlatformCCallingConvention().
The Clang importer's Clang instance may be configured with a different (higher)
OS version than the compilation target itself in order to be able to load
pre-compiled Clang modules that are aligned with the broader SDK, and match the
SDK deployment target against which Swift modules are also built. In this case,
we must use the Swift compiler's OS version triple in order to generate the
binary as-requested.
This change makes 'ClangImporter' 'Implementation' keep track of a distinct
'TargetInfo' and 'CodeGenOpts' containers that are meant to be used by clients
in IRGen. When '-clang-target' is not set, they are defined to be copies of the
'ClangImporter's built-in module-loading Clang instance. When '-clang-target' is
set, they are configured with the Swift compilation's target triple and OS
version (but otherwise identical) instead. To distinguish IRGen clients from
module loading clients, 'getModuleAvailabilityTarget' is added for module
loading clients of 'ClangImporter'.
The notion of using a different triple for loading Clang modules arises for the
following reason:
- Swift is able to load Swift modules built against a different target triple
than the source module that is being compiled. Swift relies on availability
annotations on the API within the loaded modules to ensure that compilation
for the current target only uses appropriately-available API from its
dependencies.
- Clang, in contrast, requires that compilation only ever load modules (.pcm)
that are precisely aligned to the current source compilation. Because the
target triple (OS version in particular) between Swift source compilation and
Swift dependency module compilation may differ, this would otherwise result in
builtin multiple copies of the same Clang module, against different OS
versions, once for each different triple in the build graph.
Instead, with Explicitly-Built Modules, Swift sets a '-clang-target' argument
that ensures that all Clang modules participating in the build are built against
the SDK deployment target, matching the Swift modules in the SDK, which allows
them to expose a maximally-available API surface as required by
potentially-depending Swift modules' target OS version.
--------------------------------------------
For example:
Suppose we are building a source module 'Foo', targeting 'macosx10.0', using an
SDK with a deployment target of 'macosx12.0'. Swift modules in said SDK will be
built for 'macosx12.0' (as hard-coded in their textual interfaces), meaning they
may reference symbols expected to be present in dependency Clang modules at that
target OS version.
Suppose the source module 'Foo' depends on Swift module 'Bar', which then
depends on Clang module `Baz`. 'Bar' must be built targeting 'macosx12.0'
(SDK-matching deployment target is hard-coded into its textual interface). Which
means that 'Bar' expects 'Baz' to expose symbols that may only be available when
targeting at least 'macosx12.0'. e.g. 'Baz' may have symbols guarded with
'__MAC_OS_X_VERSION_MIN_REQUIRED >= __MAC_12_0'. For this reason, we use
'-clang-target' to ensure 'Baz' is built targeting 'macosx12.0', and can be
loaded by both 'Foo' and 'Bar'.
As a result, we cannot direclty use the Clang instance's target triple here and
must check if we need to instead use the triple of the Swift compiler instance.
Resolves rdar://109228963
Default system linkers on non-Darwin platforms do not support the `-framework`
argument for framework linking. This change updates autolinking to not emit
`-framework` into the .o _swift1_autolink_entries metadata when there is no
native linker support.
This is related to rdar://106578342.
When compiling with interop enabled, emit the C++ interop compiler flag
into the DW_AT_APPLE_flags, to make it so LLDB can accurately match the
C++ interop mode when initializing its compiler instance.
rdar://97610458
(cherry picked from commit b1dbb0a321)
Using a virutal output backend to capture all the outputs from
swift-frontend invocation. This allows redirecting and/or mirroring
compiler outputs to multiple location using different OutputBackend.
As an example usage for the virtual outputs, teach swift compiler to
check its output determinism by running the compiler invocation
twice and compare the hash of all its outputs.
Virtual output will be used to enable caching in the future.
rdar://105837040
* WIP: Store layout string in type metadata
* WIP: More cases working
* WIP: Layout strings almost working
* Add layout string pointer to struct metadata
* Fetch bytecode layout strings from metadata in runtime
* More efficient bytecode layout
* Add support for interpreted generics in layout strings
* Layout string instantiation, take and more
* Remove duplicate information from layout strings
* Include size of previous object in next objects offset to reduce number of increments at runtime
* Add support for existentials
* Build type layout strings with StructBuilder to support target sizes and metadata pointers
* Add support for resilient types
* Properly cache layout strings in compiler
* Generic resilient types working
* Non-generic resilient types working
* Instantiate resilient type in layout when possible
* Fix a few issues around alignment and signing
* Disable generics, fix static alignment
* Fix MultiPayloadEnum size when no extra tag is necessary
* Fixes after rebase
* Cleanup
* Fix most tests
* Fix objcImplementattion and non-Darwin builds
* Fix BytecodeLayouts on non-Darwin
* Fix Linux build
* Fix sizes in linux tests
* Sign layout string pointers
* Use nullptr instead of debug value
Iterating over the IRGenModules and emitting every
SILCoverageMap in the SILModule meant that we
were emitting N copies of the coverage maps for
parallel IRGen, where N is the number of output
object files.
This has always been wrong, but was previously
saved by the fact that we would drop the coverage
map on the floor if we didn't have the name data
available. This would only be the case for the
IRGenModule that had the emitted entity to
profile, in addition to any IRGenModules that
had inlined the body of a profiled enitity. As
such, this prevented the duplication from being
too egregious. However with the recent change to
emit unused name data in the case where we don't
already have name data available, we're now fully
duplicating every coverage mapping, and emitting a
ton of redundant name data.
Fix things such that we only emit coverage mapping
records for the IRGenModule that corresponds to
the entity being profiled.
rdar://102905496
This is done using a condition variable upon which the awaiting thread
will block if the continuation has not be resumed by the point of await.
The resuming thread will signal this condition variable, thereby
unblocking the awaiting thread.
Rdar://99977665
This code currently uses the "empty array" metadata for static arrays (because
the "empty array" can never be freed and the metadata on the array storage is
not actually used in Swift).
But that doesn't work if the array is passed to Objective-C,
which does rely on the metadata. So Objective-C code would
see bridged arrays of this type as empty.
Workaround for: rdar://101126543
In preparation for moving to llvm's opaque pointer representation
replace getPointerElementType and CreateCall/CreateLoad/Store uses that
dependent on the address operand's pointer element type.
This means an `Address` carries the element type and we use
`FunctionPointer` in more places or read the function type off the
`llvm::Function`.
We don't need to perform coverage mapping for any
Clang decls we've synthesized, as they have no
user-written code. This is also needed to avoid a
Clang crash when attempting to emit coverage for
decls without source locations (rdar://100172217).
rdar://82820628
Trivial conflict caused by the line above the
`IGM.constructInitialFnAttributes` change in `lib/IRGen/GenDecl.cpp`
having an extra argument passed in rebranch (due to the new LLVM API).
Adds frontend option -enable-stack-protector to enable emission of a
stack protector.
Disabled by default.
When enabled enables LLVM's strong stack protection mode.
rdar://93677524
The new intrinsic, exposed via static functions on Task<T, Never> and
Task<T, Error> (rethrowing), begins an asynchronous context within a
synchronous caller's context. This is only available for use under the
task-to-thread concurrency model, and even then only under SPI.
So far, static arrays had to be put into a writable section, because the isa pointer and the (immortal) ref count field were initialized dynamically at the first use of such an array.
But with a new runtime library, which exports the symbols for the (immortal) ref count field and the isa pointer, it's possible to put the whole array into a read-only section. I.e. make it a constant global.
rdar://94185998
This reverts the revert commit df353ff3c0.
Also, I added a frontend option to disable this optimization: `-disable-readonly-static-objects`
