element environments.
This allows the constraint system to ensure that for a given pack expansion locator,
the given shape class is always the same when requesting the element environment.
If the shape class differs, it means there's a same-shape requirement failure, which
will be diagnosed via the ShapeOf constraint simplification.
The _Copyable constraint was implemented as a marker protocol.
That protocol is part of the KnownProtocol's in the compiler.
When `ASTContext::getProtocol(KnownProtocolKind kind)` tries
to find the ProtocolDecl for Copyable, it will look in the
stdlib module (i.e., Swift module), which is where I initially
planned to put it.
That created problems initially when some regression tests
use `-parse-stdlib` failed to do that protocol lookup, which is
essential for adding the constraint (given the current implementation).
That led to believe we need to pull Copyable out of the stdlib, but that's
wrong. In fact, when building the Swift module itself, we do `-parse-stdlib`
but we also include `-module-name Swift`. This causes the _Copyable protocol
defined in the Stdlib to be correctly discovered while building the stdlib
itself (see the test case in this commit). So, the only downside of
having the Copyable protocol in the Stdlib is that `-parse-stdlib` tests
in the compiler can't use move-only types correctly, as they'll be
allowed in generic contexts. No real program would build like this.
Until I have time to do a further refactoring, this is an acceptable trade-off.
fixes rdar://104898230
Currently, this is staged in as `_forget`,
as part of SE-390. It can only be used on
`self` for a move-only type within a consuming
method or accessor. There are other rules, see
Sema for the details.
A `forget self` really just consumes self and
performs memberwise destruction of its data.
Thus, the current expansion of this statement
just reuses what we inject into the end of a
deinit.
Parsing of `forget` is "contextual".
By contextual I mean that we do lookahead to
the next token and see if it's identifier-like.
If so, then we parse it as the `forget` statement.
Otherwise, we parse it as though "forget" is an
identifier as part of some expression.
This way, we won't introduce a source break for
people who wrote code that calls a forget
function.
This should make it seamless to change it from
`_forget` to `forget` in the future.
resolves rdar://105795731
Provide ASTWalker with a customization point to specify whether to
check macro arguments (which are type checked but never emitted), the
macro expansion (which is the result of applying the macro and is
actually emitted into the source), or both. Provide answers for the
~115 different ASTWalker visitors throughout the code base.
Fixes rdar://104042945, which concerns checking of effects in
macro arguments---which we shouldn't do.
Current logic attempts simplification of the base type only if it's
a type variable or a dependent member type. That's valid for correct
code but not for invalid code e.g. `(($T) -> Void).Element` is not
going to be simplified even if `$T` is bound, which causes crashes
in diagnostic mode because `matchTypes` is going to re-introduce
constraint with partially resolved dependent member types and by
doing so make it stale forever which trips constraint system state
verification logic.
Resolves: rdar://105149979
Sometimes the type variable itself doesn't have have an originator that can be replaced by an archetype but one of its equivalent type variable does.
Search thorough all equivalent type variables, looking for one that can be replaced by a generic parameter.
This fixes an issue if the range ends with a string literal that contains the IDE inspection target. In that case the end of the range will point to the start of the string literal but the IDE inspection target is inside the string literal and thus after the range’s end.
Since values of generic type are currently assumed to always
support copying, we need to prevent move-only types from
being substituted for generic type parameters.
This approach leans on a `_Copyable` marker protocol to which
all generic type parameters implicitly must conform.
A few other changes in this initial implementation:
- Now every concrete type that can conform to Copyable will do so. This fixes issues with conforming to a protocol that requires Copyable.
- Narrowly ban writing a concrete type `[T]` when `T` is move-only.
Introduce SingleValueStmtExpr, which allows the
embedding of a statement in an expression context.
This then allows us to parse and type-check `if`
and `switch` statements as expressions, gated
behind the `IfSwitchExpression` experimental
feature for now. In the future,
SingleValueStmtExpr could also be used for e.g
`do` expressions.
For now, only single expression branches are
supported for producing a value from an
`if`/`switch` expression, and each branch is
type-checked independently. A multi-statement
branch may only appear if it ends with a `throw`,
and it may not `break`, `continue`, or `return`.
The placement of `if`/`switch` expressions is also
currently limited by a syntactic use diagnostic.
Currently they're only allowed in bindings,
assignments, throws, and returns. But this could
be lifted in the future if desired.
associated failure diagnostic.
This constraint fix is unused now that MacroExpansionExpr always has an
argument list, and goes through the AddMissingArguments constraint fix for
this error.
Aggregate all requirement failures (regardless of kind) that belong
to the same locator and diagnose them as an ambiguity (if there is
more than one overload) or as the singular failure if all solutions
point to the same overload.
If we don't have an associated TypeRepr for a
contextual type in the constraint system, dump the
ASTNode that it's for instead.
Before:
```
Contextual Type: $T2
```
After:
```
Contextual Type: $T2 at DeclRef@/Users/hamish/src/swift-test-arena/swift-test-arena/main.swift:1493:21
```
