The `Qr` mangling is used to refer to the opaque type within the
declaration that produces the opaque type. When there are multiple
opaque types, e.g., due to structural or named opaque result types, it
does not specify which of the opaque type parameters it refers to.
Introduce a new mangling `QR INDEX` for opaque type parameters after
the first, retaining the `Qr` mangling for the first opaque type
parameter. This way, existing (non-structural) uses of opaque result
types retain the same manglings, but uses of structural or named
opaque result types (new features) will have distinct manglings.
Note that this mangling within a declaration is only used for the
declaration itself, and not for references to the opaque type of the
declaration, so there is no impact on the runtime demangler.
Distributed thunks were using the same mangling as direct method
reference thunks (i.e., for "super" calls). Although not technically
conflicting so long as actors never gain inheritance, it's confusing
and could cause problems in the future. So, introduce a distinct
mangling for distributed thunks and plumb them through the demangling
and remangler.
Isolated parameters are part of function types. Encode them in function
type manglings and metadata, and ensure that they round-trip through
the various mangling and metadata facilities. This nails down the ABI
for isolated parameters.
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.
For `async` function types, an actor constraint can be enforced by the callee by hopping executors,
unlike with `sync` functions, so doesn't need to influence the outward type of the function.
rdar://76248452
`@noDerivative` was not mangled in function types, and was resolved incorrectly when there's an ownership specifier. It is fixed by this patch with the following changes:
* Add `NoDerivative` demangle node represented by a `k` operator.
```
list-type ::= type identifier? 'k'? 'z'? 'h'? 'n'? 'd'? // type with optional label, '@noDerivative', inout convention, shared convention, owned convention, and variadic specifier
```
* Fix `NoDerivative`'s overflown offset in `ParameterTypeFlags` (`7` -> `6`).
* In type decoder and type resolver where attributed type nodes are processed, add support for nested attributed nodes, e.g. `inout @noDerivative T`.
* Add `TypeResolverContext::InoutFunctionInput` so that when we resolve an `inout @noDerivative T` parameter, the `@noDerivative T` checking logic won't get a `TypeResolverContext::None` set by the caller.
Resolves rdar://75916833.
* 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.
Add the following new mangling rules.
```
global ::= from-type to-type 'TJO' AUTODIFF-FUNCTION-KIND // autodiff self-reordering reabstraction thunk
global ::= from-type 'TJS' AUTODIFF-FUNCTION-KIND INDEX-SUBSET 'p' INDEX-SUBSET 'r' INDEX-SUBSET 'P' // autodiff linear map subset parameters thunk
global ::= global to-type 'TJS' AUTODIFF-FUNCTION-KIND INDEX-SUBSET 'p' INDEX-SUBSET 'r' INDEX-SUBSET 'P' // autodiff derivative function subset parameters thunk
```
Example:
```console
$s13TangentVector16_Differentiation14DifferentiablePQzAaDQy_SdAFIegnnnr_TJSdSSSpSrSUSP ---> autodiff subset parameters thunk for differential from @escaping @callee_guaranteed (@in_guaranteed A._Differentiation.Differentiable.TangentVector, @in_guaranteed B._Differentiation.Differentiable.TangentVector, @in_guaranteed Swift.Double) -> (@out B._Differentiation.Differentiable.TangentVector) with respect to parameters {0, 1, 2} and results {0} to parameters {0, 2}
$sS2f8mangling3FooV13TangentVectorVIegydd_SfAESfIegydd_TJOp ---> autodiff self-reordering reabstraction thunk for pullback from @escaping @callee_guaranteed (@unowned Swift.Float) -> (@unowned Swift.Float, @unowned mangling.Foo.TangentVector) to @escaping @callee_guaranteed (@unowned Swift.Float) -> (@unowned mangling.Foo.TangentVector, @unowned Swift.Float)
```
Resolves rdar://72666310 / SR-13508.
Also fix a bug in `AutoDiffFunction` mangling where the original may be a global that contains more than 1 node (rdar://74151229 / SR-14106).
Compiler:
- Add `Forward` and `Reverse` to `DifferentiabilityKind`.
- Expand `DifferentiabilityMask` in `ExtInfo` to 3 bits so that it now holds all 4 cases of `DifferentiabilityKind`.
- Parse `@differentiable(reverse)` and `@differentiable(_forward)` declaration attributes and type attributes.
- Emit a warning for `@differentiable` without `reverse`.
- Emit an error for `@differentiable(_forward)`.
- Rename `@differentiable(linear)` to `@differentiable(_linear)`.
- Make `@differentiable(reverse)` type lowering go through today's `@differentiable` code path. We will specialize it to reverse-mode in a follow-up patch.
ABI:
- Add `Forward` and `Reverse` to `FunctionMetadataDifferentiabilityKind`.
- Extend `TargetFunctionTypeFlags` by 1 bit to store the highest bit of differentiability kind (linear). Note that there is a 2-bit gap in `DifferentiabilityMask` which is reserved for `AsyncMask` and `ConcurrentMask`; `AsyncMask` is ABI-stable so we cannot change that.
_Differentiation module:
- Replace all occurrences of `@differentiable` with `@differentiable(reverse)`.
- Delete `_transpose(of:)`.
Resolves rdar://69980056.
- Add `DispatchThunkDerivative` and `MethodDescriptorDerivative` as link entities. The derivative functions of initializers, subscripts, properties, and methods are **all methods**, so we don't need other link entities for this purpose.
- Mangle dispatch thunks and method descriptors. Make `AutoDiffFunction` a context node since it can be nested.
Resolves SR-13866 (rdar://71318828) and SR-13125 (rdar://65240599).
Introduce `@concurrent` attribute on function types, including:
* Parsing as a type attribute
* (De-/re-/)mangling for concurrent function types
* Implicit conversion from @concurrent to non-@concurrent
- (De-)serialization for concurrent function types
- AST printing and dumping support
- `Mangle::ASTMangler::mangleAutoDiffDerivativeFunction()` and `Mangle::ASTMangler::mangleAutoDiffLinearMap()` accept original function declarations and return a mangled name for a derivative function or linear map. This is called during SILGen and TBDGen.
- `Mangle::DifferentiationMangler` handles differentiation function mangling in the differentiation transform. This part is necessary because we need to perform demangling on the original function and remangle it as part of a differentiation function mangling tree in order to get the correct substitutions in the mangled derivative generic signature.
A mangled differentiation function name includes:
- The original function.
- The differentiation function kind.
- The parameter indices for differentiation.
- The result indices for differentiation.
- The derivative generic signature.
Previously, the suffix "AD" was used to mangle AsyncFunctionPointers.
That was incorrect because it was already used in the mangling scheme.
Here, that error is fixed by using 'u' under the thunk or specialization
operator 'T' to mangle AsyncFunctionPointers. Additionally, printing
and demangling support is added.
rdar://problem/72336407
"TB" is used instead of "Tg" in case the specialized function has a resilient argument type and this argument is re-abstracted (from indirect to direct passing).
It can be re-abstracted in case the specialization is compiled in the type's resilience domain (i.e. in it's module).
We need a separate mangling for this to distinguish from specializations - with the same type - but in different resilience domains.
Note that this change does not affect the ABI: it's only used for generated module-internal specializations.
To manage code size in user binaries, we want to be able to implement common completion handler signatures in
the Swift runtime once. Using a different mangling for these lets us add new ones without clobbering symbols in
existing binaries.
Emit a once token when adding canonical prespecialized metadata records
to a nominal type descriptor and add the token itself as a trailing
object to the type descriptor. The new token will, in subsequent
commits, enable the canonical prespecialized metadata records attached
to the type descriptor to be added to the metadata cache exactly once.
This attribute allows to define a pre-specialized entry point of a
generic function in a library.
The following definition provides a pre-specialized entry point for
`genericFunc(_:)` for the parameter type `Int` that clients of the
library can call.
```
@_specialize(exported: true, where T == Int)
public func genericFunc<T>(_ t: T) { ... }
```
Pre-specializations of internal `@inlinable` functions are allowed.
```
@usableFromInline
internal struct GenericThing<T> {
@_specialize(exported: true, where T == Int)
@inlinable
internal func genericMethod(_ t: T) {
}
}
```
There is syntax to pre-specialize a method from a different module.
```
import ModuleDefiningGenericFunc
@_specialize(exported: true, target: genericFunc(_:), where T == Double)
func prespecialize_genericFunc(_ t: T) { fatalError("dont call") }
```
Specially marked extensions allow for pre-specialization of internal
methods accross module boundries (respecting `@inlinable` and
`@usableFromInline`).
```
import ModuleDefiningGenericThing
public struct Something {}
@_specializeExtension
extension GenericThing {
@_specialize(exported: true, target: genericMethod(_:), where T == Something)
func prespecialize_genericMethod(_ t: T) { fatalError("dont call") }
}
```
rdar://64993425
Add `async` to the type system. `async` can be written as part of a
function type or function declaration, following the parameter list, e.g.,
func doSomeWork() async { ... }
`async` functions are distinct from non-`async` functions and there
are no conversions amongst them. At present, `async` functions do not
*do* anything, but this commit fully supports them as a distinct kind
of function throughout:
* Parsing of `async`
* AST representation of `async` in declarations and types
* Syntactic type representation of `async`
* (De-/re-)mangling of function types involving 'async'
* Runtime type representation and reconstruction of function types
involving `async`.
* Dynamic casting restrictions for `async` function types
* (De-)serialization of `async` function types
* Disabling overriding, witness matching, and conversions with
differing `async`
When a generic type from a different module is not resilient within the
current module and at least one of its arguments is from the current
module, emit a non-canonical prespecialized record, and access that
metadata via a call to swift_getCanonicalSpecializedMetadata, passing in
the non-canonical record.
rdar://problem/56996727
rdar://problem/56997022
When generic metadata for a class is requested in the same module where
the class is defined, rather than a call to the generic metadata
accessor or to a variant of typeForMangledNode, a call to a new
accessor--a canonical specialized generic metadata accessor--is emitted.
The new function is defined schematically as follows:
MetadataResponse `canonical specialized metadata accessor for C<K>`(MetadataRequest request) {
(void)`canonical specialized metadata accessor for superclass(C<K>)`(::Complete)
(void)`canonical specialized metadata accessor for generic_argument_class(C<K>, 1)`(::Complete)
...
(void)`canonical specialized metadata accessor for generic_argument_class(C<K>, count)`(::Complete)
auto *metadata = objc_opt_self(`canonical specialized metadata for C<K>`);
return {metadata, MetadataState::Complete};
}
where generic_argument_class(C<K>, N) denotes the Nth generic argument
which is both (1) itself a specialized generic type and is also (2) a
class. These calls to the specialized metadata accessors for these
related types ensure that all generic class types are registered with
the Objective-C runtime.
To enable these new canonical specialized generic metadata accessors,
metadata for generic classes is prespecialized as needed. So are the
metaclasses and the corresponding rodata.
Previously, the lazy objc naming hook was registered during process
execution when the first generic class metadata was instantiated. Since
that instantiation may occur "before process launch" (i.e. if the
generic metadata is prespecialized), the lazy naming hook is now
installed at process launch.
Mangle `@noDerivative` parameters to fix type reconstruction errors.
Resolves SR-12650. The new mangling is non-breaking.
When differentiation supports multiple result indices and `@noDerivative`
results are added, we can reuse some of this mangling support.
Add mangling scheme for `@differentiable` and `@differentiable(linear)` function
types. Mangling support is important for debug information, among other things.
Update docs and add tests.
Resolves TF-948.
In order to allow this, I've had to rework the syntax of substituted function types; what was previously spelled `<T> in () -> T for <X>` is now spelled `@substituted <T> () -> T for <X>`. I think this is a nice improvement for readability, but it did require me to churn a lot of test cases.
Distinguishing the substitutions has two chief advantages over the existing representation. First, the semantics seem quite a bit clearer at use points; the `implicit` bit was very subtle and not always obvious how to use. More importantly, it allows the expression of generic function types that must satisfy a particular generic abstraction pattern, which was otherwise impossible to express.
As an example of the latter, consider the following protocol conformance:
```
protocol P { func foo() }
struct A<T> : P { func foo() {} }
```
The lowered signature of `P.foo` is `<Self: P> (@in_guaranteed Self) -> ()`. Without this change, the lowered signature of `A.foo`'s witness would be `<T> (@in_guaranteed A<T>) -> ()`, which does not preserve information about the conformance substitution in any useful way. With this change, the lowered signature of this witness could be `<T> @substituted <Self: P> (@in_guaranteed Self) -> () for <A<T>>`, which nicely preserves the exact substitutions which relate the witness to the requirement.
When we adopt this, it will both obviate the need for the special witness-table conformance field in SILFunctionType and make it far simpler for the SILOptimizer to devirtualize witness methods. This patch does not actually take that step, however; it merely makes it possible to do so.
As another piece of unfinished business, while `SILFunctionType::substGenericArgs()` conceptually ought to simply set the given substitutions as the invocation substitutions, that would disturb a number of places that expect that method to produce an unsubstituted type. This patch only set invocation arguments when the generic type is a substituted type, which we currently never produce in type-lowering.
My plan is to start by producing substituted function types for accessors. Accessors are an important case because the coroutine continuation function is essentially an implicit component of the function type which the current substitution rules simply erase the intended abstraction of. They're also used in narrower ways that should exercise less of the optimizer.
Teach SILGen to emit a separate SIL function to capture the
initialization of the backing storage type for a wrapped property
based on the wrapped value. This eliminates manual code expansion at
every use site.
When we generate code that asks for complete metadata for a fully concrete specific type that
doesn't have trivial metadata access, like `(Int, String)` or `[String: [Any]]`,
generate a cache variable that points to a mangled name, and use a common accessor function
that turns that cache variable into a pointer to the instantiated metadata. This saves a bunch
of code size, and should have minimal runtime impact, since the demangling of any string only
has to happen once.
This mostly just works, though it exposed a couple of issues:
- Mangling a type ref including objc protocols didn't cause the objc protocol record to get
instantiated. Fixed as part of this patch.
- The runtime type demangler doesn't correctly handle retroactive conformances. If there are
multiple retroactive conformances in a process at runtime, then even though the mangled string
refers to a specific conformance, the runtime still just picks one without listening to the
mangler. This is left to fix later, rdar://problem/53828345.
There is some more follow-up work that we can do to further improve the gains:
- We could improve the runtime-provided entry points, adding versions that don't require size
to be cached, and which can handle arbitrary metadata requests. This would allow for mangled
names to also be used for incomplete metadata accesses and improve code size of some generic
type accessors. However, we'd only be able to take advantage of the new entry points in
OSes that ship a new runtime.
- We could choose to always symbolic reference all type references, which would generally reduce
the size of mangled strings, as well as make runtime demangling more efficient, since it wouldn't
need to hit the runtime caches. This would however require that we be able to handle symbolic
references across files in the MetadataReader in order to avoid regressing remote mirror
functionality.
When mangling a dependent protocol conformance ref, the mangler currently uses `0_` to mean an unknown index and `N_` to mean the index `N - 1`. Unfortunately, this is somewhat confused: `0_` is actually the mangling for index 1, and index 0 is supposed to be mangled as just `_`, so true indexes are actually offset by 2. So the first thing to do here is to clarify what's going on throughout the mangler, demangler, and ABI documentation.
Also, the demangler attempts to produce a `DependentProtocolConformance*` node with the appropriate child nodes and an optional index payload. Unfortunately, demangle nodes cannot have both children and a value payload, so whenever it creates a node with an index payload, the demangler will assert. It does this whenever the mangled index is not 0; since (per above) the mangler always produces a non-zero mangled index in this production, the demangler will always assert when processing these. So clearly this is well-tested code, since +asserts builds will always trigger the demangler when mangling a name in the first place. To fix this, we need to make the index a child of the mangling node instead of its payload; at the same time, we can make it store the semantically correct index value and just introduce a new `UnknownIndex` node to handle the `0_` case. This is easy because all current clients ignore this information.
Finally, due to an apparent copy-and-paste error, the demangler attempts to produce a `DependentProtocolConformanceRoot` node for associated protocol conformances; this is easily resolved.
This fixes the crash in SR-10926 (rdar://51710424). The obscurity of this crash --- which originally made us think it might be related to Error self-conformance --- is because it is only triggered when a function signature takes advantage of a concrete-but-dependent retroactive conformance, which (to be both concrete and dependent) must furthermore be conditional. Testing the other cases besides a root conformance requires an even more obscure testcase.
Our mangling did not encode if an Objective-C block was escaping or
not. This is not a huge problem in practice, but for debug info we
want type reconstruction to round-trip exactly. There was a previous
workaround to paper over this specific problem.
Remove the workaround, and add a new 'XL' mangling for escaping
blocks. Since we don't actually want to break ABI compatibility,
only use the new mangling in DWARF debug info.
This is to support dynamic function replacement of functions with opaque
result type.
This approach requires that all state is thrown away (that could contain the
old returned type for an opaque type) between replacements.
rdar://48887938
