Originally I tried to implement a fancy redundant-inverse error
diagnostic that identifies the "previous" requirement already seen. I
ended up removing this error diagnostic because it was tricky to
implement well and we weren't diagnosing other redundant requirements.
Turns out we do have a mode of the compiler to diagnose redundant
requirements, but as warnings, using `-warn-redundant-requirements`.
This warning is much simpler in that it just points to one requirement
that is redundant.
Since there is no propagation of inverse constraints in the requirement
machine, we need to fully desugar these requirements at the point of
defining a generic parameter. That desugaring involves determining which
default conformance requirements need to be applied to a generic
parameter, accounting for inverses.
But, nested generic contexts in scope of those expanded generic
parameters can still write constraints on that outer parameter. For
example, this method's where clause can have its own constraints on `T`:
```
struct S<T> {
func f() where T: ~Copyable {}
}
```
But, the generic signature of `S` already has a `T: Copyable` that was
expanded. The method `f` will always see a `T` that conforms to
`Copyable`, so it's impossible for `f` to claim that it applies for
`T`'s that lack Copyable.
Put another way, it's not valid for this method `f`, whose generic
signature is based on its parent's `S`, to weaken or remove requirements
from parent's signature. Only positive requirements can be
added to them.
We're not yet going to allow noncopyable types into packs, so this
change prevents the use of `~Copyable` on an `each T` generic parameter.
It also fixes how we query for whether a `repeat X` parameter is
copyable.
Previously, inverses were only accounted-for in inheritance clauses.
This batch of changes handles inverses appearing in other places, like:
- Protocol compositions
- `some ~Copyable`
- where clauses
with proper attribution of default requirements in their absence.
Conflicts:
- `lib/AST/TypeCheckRequests.cpp` renamed `isMoveOnly` which requires
a static_cast on rebranch because `Optional` is now a `std::optional`.
The type that occurs as the thrown error type must conform to the
`Error` protocol. Infer this conformance when the type is a type
parameter in the signature of a function.
An initial implementation of a rework in how
we prevent noncopyable types from being
substituted in places they are not permitted.
Instead of generating a constraint for every
generic parameter in the solver, we produce
real Copyable conformance requirements. This
is much better for our longer-term goal of
supporting `~Copyable` in more places.
Replace the `front()` and `back()` accessors on `InheritedTypes` with dedicated
functions for accessing the start and end source locations of the inheritance
clause. NFC.
Wrap the `InheritedEntry` array available on both `ExtensionDecl` and
`TypeDecl` in a new `InheritedTypes` class. This class will provide shared
conveniences for working with inherited type clauses. NFC.
llvm::SmallSetVector changed semantics
(https://reviews.llvm.org/D152497) resulting in build failures in Swift.
The old semantics allowed usage of types that did not have an
`operator==` because `SmallDenseSet` uses `DenseSetInfo<T>::isEqual` to
determine equality. The new implementation switched to using
`std::find`, which internally uses `operator==`. This type is used
pretty frequently with `swift::Type`, which intentionally deletes
`operator==` as it is not the canonical type and therefore cannot be
compared in normal circumstances.
This patch adds a new type-alias to the Swift namespace that provides
the old semantic behavior for `SmallSetVector`. I've also gone through
and replaced usages of `llvm::SmallSetVector` with the
`Swift::SmallSetVector` in places where we're storing a type that
doesn't implement or explicitly deletes `operator==`. The changes to
`llvm::SmallSetVector` should improve compile-time performance, so I
left the `llvm::SmallSetVector` where possible.
getInheritedProtocols() skips type resolution and directly resolves
TypeReprs to TypeDecls.
On the other hand, when building a protocol requirement signature,
we use type resolution to resolve inheritance clause entries so
that we can properly support parameterized protocol types, and
protocol compositions that contain classes.
Since a TypeRepr with an invalid sub-component resolves to an
ErrorType, this meant that in invalid code, the first list of
protocols might contain protocols that don't appear in the second.
This broke rewrite system invariants. Fix this by checking if
type resolution failed when building the requirement signature of
a protocol, and if so, also look at getInheritedProtocols().
Fixes https://github.com/apple/swift/issues/61020.
RequirementSignatureRequest
=> TypeAliasRequirementsRequest
=> isConstrainedExtension()
=> GenericSignatureRequest
=> RequirementSignatureRequest
Instead, use getTrailingWhereClause() as an approximation of
isConstrainedExtension().
Fixes rdar://problem/97236936.
Every protocol gets an 'identity conformance' rule [P].[P] => [P].
A trivially-stated circularity is always redundant because of this
rule, and we diagnose circular inheritance elsewhere as a hard
error, so just add a special case to skip adding such a rule here
to avoid the useless warning on top of the existing error.
We want to allow this for all conformance requirements written in protocols
or the `where` clause of protocol extensions.
Fixes rdar://problem/91304291.
