A new `RuntimeAttributeGenerator` is used to reference runtime
attribute generator functions synthesized by SILGen.
`#function` magic literal points to the declaration that declaration
attribute is attached to.
* Introduce TypeLayout Strings
Layout strings encode the structure of a type into a byte string that can be
interpreted by a runtime function to achieve a destroy or copy. Rather than
generating ir for a destroy/assignWithCopy/etc, we instead generate a layout
string which encodes enough information for a called runtime function to
perform the operation for us. Value witness functions tend to be quite large,
so this allows us to replace them with a single call instead. This gives us the
option of making a codesize/runtime cost trade off.
* Added Attribute @_GenerateLayoutBytecode
This marks a type definition that should use generic bytecode based
value witnesses rather than generating the standard suite of
value witness functions. This should reduce the codesize of the binary
for a runtime interpretation of the bytecode cost.
* Statically link in implementation
Summary:
This creates a library to store the runtime functions in to deploy to
runtimes that do not implement bytecode layouts. Right now, that is
everything. Once these are added to the runtime itself, it can be used
to deploy to old runtimes.
* Implement Destroy at Runtime Using LayoutStrings
If GenerateLayoutBytecode is enabled, Create a layout string and use it
to call swift_generic_destroy
* Add Resilient type and Archetype Support for BytecodeLayouts
Add Resilient type and Archetype Support to Bytecode Layouts
* Implement Bytecode assign/init with copy/take
Implements swift_generic_initialize and swift_generic_assign to allow copying
types using bytecode based witnesses.
* Add EnumTag Support
* Add IRGen Bytecode Layouts Test
Added a test to ensure layouts are correct and getting generated
* Implement BytecodeLayouts ObjC retain/release
* Fix for Non static alignments in aligned groups
* Disable MultiEnums
MultiEnums currently have some correctness issues with non fixed multienum
types. Disabling them for now then going to attempt a correct implementation in
a follow up patch
* Fixes after merge
* More fixes
* Possible fix for native unowned
* Use TypeInfoeBasedTypeLayoutEntry for all scalars when ForceStructTypeLayouts is disabled
* Remove @_GenerateBytecodeLayout attribute
* Fix typelayout_based_value_witness.swift
Co-authored-by: Gwen Mittertreiner <gwenm@fb.com>
Co-authored-by: Gwen Mittertreiner <gwen.mittertreiner@gmail.com>
And only replace the variable inside of the clang generated protocol-refs list.
This should make this resilient to mismatches in the protocol list order.
Getting the `protocolRefs` constant must not be hoisted out of the loop because this constant might be deleted by `oldVar->replaceAllUsesWith(newOpd)`.
rdar://102554134
`getValue` -> `value`
`getValueOr` -> `value_or`
`hasValue` -> `has_value`
`map` -> `transform`
The old API will be deprecated in the rebranch.
To avoid merge conflicts, use the new API already in the main branch.
rdar://102362022
```
@protocol DeclarationOnly;
@protocol DeclarationOnlyUser<DeclarationOnly>
- (void) printIt;
@end
```
This should not be neccessary, but the compiler currently accepts cases
like the one in the test case added.
rdar://101828847
There are certain protocol method decls types that swift does not import
today.
```
@protocol Incomplete
- (id)getObjectFromVarArgs:(id)first, ...;
@end
```
Furthermore, the old method also emitted duplicate entries for protocols
methods when Swift synthesized methods for diagnosics.
We won't import this method into Swift. So if we emit protocol metadata
from swift delcs we would generate incomplete records.
rdar://60888524
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`.
Previously we gave them the same SIL linkage as the method, then changed
the LLVM IR linkage to 'internal' (which is roughly equivalent to
SIL 'private') in IRGen.
This would crash in the SIL verifier if an @objc method was
'@_alwaysEmitIntoClient'. While such a combination of attributes is
silly since '@objc' methods are intrinsically part of the ABI, we
should not crash in this case.
The simplest fix is to just set the linkage to private at the SIL
level, avoiding the IRGen hack entirely.
The `AttrBuilder` API was changed in llvm/llvm-project
d2cc6c2d0c2f8a6e272110416a3fd579ed5a3ac1 to now take a `LLVMContext &`
as part of its constructor. Update uses to pass one in.
This reverts commit d27e6e1e46, reversing
changes made to f2e85a2b1f.
It causes an execution time failure in
`Interpreter/struct_extra_inhabitants.swift` with
```
ninja -C swift-macosx-x86_64 check-swift-optimize
```
rdar://86054209
The functions in llvm-project `AttributeList` have been
renamed/refactored to help remove uses of `AttributeList::*Index`.
Update to use these new functions where possible. There's one use of
`AttrIndex` remaining as `replaceAttributeTypeAtIndex` still takes the
index and there is no `param` equivalent. We could add one locally, but
presumably that will be added eventually.
This reverts commit 5ebb1b2fc6, reversing
changes made to 76260c2235.
This commit causes compiler crashes when using protocol composition
types involving objc.
Repo:
```
import Foundation
public class SomeObject : NSObject {}
public protocol ProtoA{}
public protocol SomeProtoType { }
public typealias Composition = SomeObject & SomeProtoType
public struct Thing<T: ProtoA> {
let a: Composition
let b: T
init(a: Composition,
b: T
) {
self.a = a
self.b = b
}
}
$ swiftc -c Repo.swift -O
```
While looking at this issue I noticed that it is not correct to use a
ScalarEntry of ObjCReference (or other ScalarKind::XXXReference) for
`AddressOnly##Name##ClassExistentialTypeInfo` types. These should be
calling the IGF.emit##Name##Destroy(addr, Refcounting); functions not
objc_release.
It is probably best to use the macro facilities in a similar fashion like
lib/IRGen/GenExistential.cpp does.
rdar://85269025
The AsyncEntryPoint represents the thunk that is wrapped in a task. This
thunk is used to ensure that the main function explicitly calls "exit",
and to properly unwrap and report any unhandled errors returned from the
user-written main. The function takes on the name `@async_main` in the
emitted SIL.
Summary:
As part of SR-14273, the type layout infrastructure needs to be able to be able
to differentiate between types of scalars so it knows how to release/retain
appropriately. Right now, for example, to destroy a scalar, it blindly calls
into typeInfo's irgen functions which means it's not able to generate any of
the needed information for itself.
This patch adds a field to ScalarTypeLayout to allow them to know what kind of
reference they are and strings through the machinery to provide the information
to set it.
This also moves ScalarTypeLayout::destroy to use the new information.
Test Plan: ninja check-swift
Reviewers: mren, #pika_compiler
Reviewed By: mren
Subscribers: apl, phabricatorlinter
Differential Revision: https://phabricator.intern.facebook.com/D30983093
Tasks: T100580959
Tags: swift-adoption
Signature: 30983093:1632340205:3bdd3218ae86ad6b3d199cc1b504a625e3650ec0
Allow SILDeclRef to refer to the main program
entry-point, which will either be for a main
SourceFile, or a synthetic main such as an `@main`
decl. Adjust the various SILDeclRef related
functions to handle this new case, and change the
emission to go through `emitFunctionDefinition`.
This change will allow the entry-point for an `@main`
decl (and eventually a main SourceFile) to be
emitted on-demand from its symbol name.
The address of the function to be called when generating code to invoke
the function associated with FunctionPointer which is produced via
direct reference is by definition statically known; it is neither necessary
nor desireable to load this address out of the AsyncFunctionPointer
corresponding to the function.
Here, that spurious additional work is skipped. The approach is to add
a second value to the FunctionPointer struct. For FunctionPointers
whose kind is AsyncFunctionPointer, this value is either null or else
the address of the corresponding function.
rdar://71376092
The current code generation will emit an autibsp after adjusting the
stack pointe for the tail call. If callee and caller argument area does
not match this would fail.
First, just call an async -> T function instead of forcing the caller
to piece together which case we're in and perform its own copy. This
ensures that the task is actually kept alive properly.
Second, now that we no longer implicitly depend on the waiting tasks
being run synchronously, go ahead and schedule them to run on the
global executor.
This solves some problems which were blocking the work on TLS-ifying
the task/executor state.
This is conditional on UseAsyncLowering and in the future should also be
conditional on `clangTargetInfo.isSwiftAsyncCCSupported()` once that
support is merged.
Update tests to work either with swiftcc or swifttailcc.
For `@objc async` methods, all of the important information about the
"result" type and whether it throws or not is within the type of the
completion handler block. Enable extended type information for the
generated Objective-C metadata of such methods, so that clients can
understand how to invoke them using reflection facilities.
Implements rdar://73048313.
An AsyncFunctionPointer, defined in Task.h, is a struct consisting of
two i32s: (1) the relative address of the async function and (2) the
size of the async context to be allocated when calling that function.
Here, such structs are emitted for every async SILFunction that is
emitted.
Here, the following is implemented:
- Construction of SwiftContext struct with the fields needed for calling
functions.
- Allocating and deallocating these swift context via runtime calls
before calling async functions and after returning from them.
- Storing arguments (including bindings and the self parameter but not
including protocol fields for witness methods) and returns (both
direct and indirect).
- Calling async functions.
Additional things that still need to be done:
- protocol extension methods
- protocol witness methods
- storing yields
- partial applies
```
class Generic<T> {
@objc dynamic func method() {}
}
extension Generic {
@_dynamicReplacement(for:method())
func replacement() {}
}
```
The standard mechanism of using Objective-C categories for dynamically
replacing @objc methods in generic classes does not work.
Instead we mark the native entry point as replaceable.
Because this affects all @objc methods in generic classes (whether there
is a replacement or not) by making the native entry point
`[dynamically_replaceable]` (regardless of optimization mode) we guard this by
the -enable-implicit-dynamic flag because we are late in the release cycle.
* Replace isNativeDynamic and isObjcDynamic by calls to shouldUse*Dispatch and
shouldUse*Replacement
This disambiguates between which dispatch method we should use at call
sites and how these methods should implement dynamic function
replacement.
* Don't emit the method entry for @_dynamicReplacement(for:) of generic class
methods
There is not way to call this entry point since we can't generate an
objective-c category for generic classes.
rdar://63679357
