We introduce a new macro called #SwiftSettings that can be used in conjunction
with a new stdlib type called SwiftSetting to control the default isolation at
the file level. It overrides the current default isolation whether it is the
current nonisolated state or main actor (when -enable-experimental-feature
UnspecifiedMeansMainActorIsolated is set).
When deserialization a protocol conformance from a binary swiftmodule
file the compiler can encounter inconsistencies caused by stale module
files. Replace the hard crash with a proper error and print the list of
requirements and conformances being compared to stderr for manual
inspection. Recover silently when we can afford to, during indexing or
in LLDB.
Failures in `readNormalProtocolConformanceXRef` are usually caused by a
dependency change without the required rebuild of its dependents.
Display a proper error instead of crashing when encountering such an
issue during normal compilation. Recover silently when we can afford to,
during indexing or in LLDB.
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.
Map the lifetime dependencies described in terms of the formal AST-level parameters
to the correct parameter(s) in the lowered SIL function type. There can be 0, 1,
or many SIL parameters per formal parameter because of tuple exploding. Also,
record which dependencies are on addressable parameters (meaning that the dependency
includes not only the value of the parameter, but its specific memory location).
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.
Update signature and implementation of `maybeReadGenericParams` to pass
up errors to the caller. Also update all of its callers to pass up any
error.
rdar://126582124
On reading out a 'ProtocolConformanceXrefLayout', instead of querying the protocol on the 'NominalDecl' referenced by the Xref, use the general-purpose lookup that resolves implicit conformances to e.g. 'Sendable'.
Otherwise, we can end up in a situation where a library serializes some type as (implicitly) conforming to Sendable, but the client, upon deserialization, has not yet run implicit Sendable inference logic, so its representation of said type will not match.
decl being accessed is correct. When this assumption fails due to a deserialization error
of its members, the use site accesses the layout with a wrong field offset, resulting in
UB or a crash. The deserialization error is currently not caught at compile time due to
LangOpts.EnableDeserializationRecovery being enabled by default to allow for recovery of some
of the deserialization errors at a later time. In case of member deserialization, however,
it's not necessarily recovered later on.
This PR tracks whether member deserialization had an error by recursively loading members and
checking for deserialization error, and fails and emits a diagnostic. It provides a way to
prevent resilience bypassing when the deserialized decl's layout is incorrect.
Resolves rdar://132411524
Right now it is basically a version of nonisolated beyond a few simple cases
like constructors/destructors where we are pretty sure we want to not support
this.
This is part of my bringup strategy for changing nonisolated/unspecified to be
caller isolation inheriting.
I need this today to add the implicit isolated parameter... but I can imagine us
adding more implicit parameters in the future, so it makes sense to formalize it
so it is easier to do in the future.
Protocol conformances have a handful attributes that can apply to them
directly, including @unchecked (for Sendable), @preconcurrency, and
@retroactive. Generalize this into an option set that we carry around,
so it's a bit easier to add them, as well as reworking the
serialization logic to deal with an arbitrary number of such options.
Use this generality to add support for @unsafe conformances, which are
needed when unsafe witnesses are used to conform to safe requirements.
Implement general support for @unsafe conformances, including
producing a single diagnostic per missing @unsafe that provides a
Fix-It and collects together all of the unsafe witnesses as notes.
This attribute will allow you to specify an alternate version of the declaration used for mangling. It will allow minor adjustments to be made to declarations so long as they’re still compatible at the calling convention level, such as refining isolation or sendability, renaming without breaking ABI, etc.
The attribute is behind the experimental feature flag `ABIAttribute`.
Introduce an attribute to allow unsafe code within the annotated
declaration without presenting an unsafe interface to users. This is,
by its nature, and unsafe construct, and is used to document where
unsafe behavior is encapsulated in safe constructs.
There is an optional message that can be used as part of an audit
trail.
Many APIs using nonescapable types would like to vend interior pointers to their
parameter bindings, but this isn't normally always possible because of representation
changes the caller may do around the call, such as moving the value in or out of memory,
bridging or reabstracting it, etc. `@_addressable` forces the corresponding parameter
to be passed indirectly in memory, in its maximally-abstracted representation.
[TODO] If return values have a lifetime dependency on this parameter, the caller must
keep this in-memory representation alive for the duration of the dependent value's
lifetime.
The renamed decl is now stored exclusively in the split request evaluator
storage, which is more efficient since most availability attributes do not
specify a renamed decl.
Rename decls are typically derived from the rename strings attached to a
`@available` attributes. It shouldn't be necessary to serialize the cached
rename decls since they can be rederived. The only decls that have rename decls
and don't have reanme strings are synthesized by ClangImporter and don't get
serialized.
It doesn't make sense to use `VersionRange::empty()` to represent "universally
available" since something that is available in an empty version range is
effectively never available.
Mangling and looking up the opaque result type decl
for serialized decls is a fairly expensive
operation. Instead, fallthrough to the request
which will have a cached value set by deserialization.
This shaves ~30ms off the cached completion for:
```swift
import SwiftUI
struct V: View {
var body: some View {
Table(#^CC^#
}
}
```
Today ParenType is used:
1. As the type of ParenExpr
2. As the payload type of an unlabeled single
associated value enum case (and the type of
ParenPattern).
3. As the type for an `(X)` TypeRepr
For 1, this leads to some odd behavior, e.g the
type of `(5.0 * 5).squareRoot()` is `(Double)`. For
2, we should be checking the arity of the enum case
constructor parameters and the presence of
ParenPattern respectively. Eventually we ought to
consider replacing Paren/TuplePattern with a
PatternList node, similar to ArgumentList.
3 is one case where it could be argued that there's
some utility in preserving the sugar of the type
that the user wrote. However it's really not clear
to me that this is particularly desirable since a
bunch of diagnostic logic is already stripping
ParenTypes. In cases where we care about how the
type was written in source, we really ought to be
consulting the TypeRepr.
