Convert a bunch of places where we're dumping to stderr and calling
`abort` over to using `ABORT` such that the message gets printed to
the pretty stack trace. This ensures it gets picked up by
CrashReporter.
Store specialize witness tables in a separate lookup table in the module. This allows that for a normal conformance there can exist the original _and_ a specialized witness table.
Also, add a boolean property `isSpecialized` to `WitnessTable` which indicates whether the witness table is specialized or not.
If we're using the macro-specific local discriminator, we need to
make sure we avoid mangling the regular local discriminator in
`appendDeclName`, since that could prematurely kick local discriminator
assignment before type-checking has finished.
rdar://143834482
I am doing this in preparation for adding the ability to represent in the SIL
type system that a function is global actor isolated. Since we have isolated
parameters in SIL, we do not need to represent parameter, nonisolated, or
nonisolated caller in the type system. So this should be sufficient for our
purposes.
I am adding this since I need to ensure that we mangle into thunks that convert
execution(caller) functions to `global actor` functions what the global actor
is. Otherwise, we cannot tell the difference in between such a thunk and a thunk
that converts execution(caller) to execution(concurrent).
An "abstract" ProtocolConformanceRef is a conformance of a type
parameter or archetype to a given protocol. Previously, we would only
store the protocol requirement itself---but not track the actual
conforming type, requiring clients of ProtocolConformanceRef to keep
track of this information separately.
Record the conforming type as part of an abstract ProtocolConformanceRef,
so that clients will be able to recover it later. This is handled by a uniqued
AbstractConformance structure, so that ProtocolConformanceRef itself stays one
pointer.
There remain a small number of places where we create an abstract
ProtocolConformanceRef with a null type. We'll want to chip away at
those and establish some stronger invariants on the abstract conformance
in the future.
* [CS] Decline to handle InlineArray in shrink
Previously we would try the contextual type `(<int>, <element>)`,
which is wrong. Given we want to eliminate shrink, let's just bail.
* [Sema] Sink `ValueMatchVisitor` into `applyUnboundGenericArguments`
Make sure it's called for sugar code paths too. Also let's just always
run it since it should be a pretty cheap check.
* [Sema] Diagnose passing integer to non-integer type parameter
This was previously missed, though would have been diagnosed later
as a requirement failure.
* [Parse] Split up `canParseType`
While here, address the FIXME in `canParseTypeSimpleOrComposition`
and only check to see if we can parse a type-simple, including
`each`, `some`, and `any` for better recovery.
* Introduce type sugar for InlineArray
Parse e.g `[3 x Int]` as type sugar for InlineArray. Gated behind
an experimental feature flag for now.
Imported C++ template specializations receive identifiers that contain
their type signature; e.g., `X<Y, Z>`. Since this means the identifier
contains non-identifier characters, the new behavior was trying to
escape them with backticks in ASTPrinter, ASTMangler, and the runtime
metadata. This pulls that back to preserve the current behavior for
specifically those types.
Raw identifiers are backtick-delimited identifiers that can contain any
non-identifier character other than the backtick itself, CR, LF, or other
non-printable ASCII code units, and which are also not composed entirely
of operator characters.
To pave the way for the new experimental feature which will operate on '@const' attribute and expand the scope of what's currently handled by '_const' without breaking compatibility, for now.
Element archetypes can occur here when mangling the USR for local
variables for e.g SourceKit cursor info, as well as for regular
compilation for things like lazy variables.
Update `getDeclTypeForMangling` to map local archetypes out of
context, using both the captured generic environments and the
archetypes present in the type. More work is needed to support lazy
variable though (now it crashes in SILGen).
This patch doesn't handle mangling standalone element archetypes for
e.g `printTypeUSR`, ideally we'd fix the clients there to not pass
local archetypes.
rdar://143077965
This would make sure that async function types marked as `@execution(caller)`
have correct isolation.
Also defines all of the possible conversions to and from `caller`
isolated function types.
This commit removes the guardrails in ImportDecl.cpp:SwiftDeclConverter
that prevent it from importing non-public C++ members. It also
accordingly adjusts all code that assumes generated Swift decls should
be public. This commit does not import non-public inherited members;
that needs its own follow-up patch.
Note that Swift enforces stricter invariants about access levels than C++.
For instance, public typealiases cannot be assigned private underlying types,
and public functions cannot take or return private types. Meanwhile,
both of these patterns are supported in C++, where exposing private types
from a class's public interface is considered feature. As far as I am aware,
Swift was already importing such private-containing public decls from C++
already, but I added a test suite, access inversion, that checks and
documents this scenario, to ensure that it doesn't trip any assertions.
The issue here is that the demangler (since we have a postfix mangling) parses
parameters/results/etc and then uses earlier postfix type arguments to attach
the relevant types to the parameters/results/etc. Since the flag for a sending
result was placed in between the parameters and results, we get an off by one
error.
Rather than fix that specific issue by introducing an offset for the off by one
error, I used the fact that the impl-function part of the mangling is not ABI
and can be modified to move the bit used to signify a sending result to before
the parameters so the whole problem is avoided.
I also while I was doing this looked through the sending result mangling for any
further issues and fixed them as I found them.
rdar://141962865
What’s implemented now is actually *far* more thorough than what the surface syntax can currently express, mainly because I can’t apply @abi to nominal types yet.
Emit an imported declaration for @_originallyDefinedIn under the
real module that these types live in.
This patch also changes the mangling for the debugger to respect
@_originallyDefinedIn, and fixes a bug where @_originallyDefinedIn
that should be ignored was still being used when mangling.
rdar://137146961
Since the introduction of custom attributes (as part of property
wrappers), we've modeled the context of expressions within these
attributes as PatternBindingInitializers. These
PatternBindingInitializers would get wired in to the variable
declarations they apply to, establishing the appropriate declaration
context hierarchy. This worked because property wrappers only every
applied to---you guessed it!---properties, so the
PatternBindingInitializer would always get filled in.
When custom attributes were extended to apply to anything for the
purposes of macros, the use of PatternBindingInitializer became less
appropriate. Specifically, the binding declaration would never get
filled in (it's always NULL), so any place in the compiler that
accesses the binding might have to deal with it being NULL, which is a
new requirement. Few did, crashes ensued.
Rather than continue to play whack-a-mole with the abused
PatternBindingInitializer, introduce a new CustomAttributeInitializer
to model the context of custom attribute arguments. When the
attributes are assigned to a declaration that has a
PatternBindingInitializer, we reparent this new initializer to the
PatternBindingInitializer. This helps separate out the logic for
custom attributes vs. actual initializers.
Fixes https://github.com/swiftlang/swift/issues/76409 / rdar://136997841
The mangling of macro expansions relies on having a type-checked AST
for its enclosing context. When that enclosing context is within a
local context (say, a local type), mangling would trigger type
checking of that local type, which could then involve assigning local
discriminators. However, if this happens before type checking of the
enclosing function body, we would end up failing to assign closure
discriminators to (e.g.) autoclosures within the body.
The fundamental problem here is the interaction between discriminator
assignment (which can only happen after type checking) and mangling of
macro expansion buffers (which can happen during that type checking).
Break this cycle by providing a different approach to mangling macro
expansions within local contexts as the innermost non-local context +
a name-based discriminator within that local context. These manglings
are not ABI and are not stable, so we can adjust them later if we come
up with a scheme we like better. However, by breaking this cycle, we
eliminate assertions and miscompiles that come from missing
discriminators in this case.
Fixes rdar://139734958.
