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.
The "local context" was only used to prevent parsing of closures in a
non-local context, and also string interpolations because they are
similar-ish to closures. However, this isn't something a parser should
decide, so remove this special-case semantic check from the parser and
eliminate the notion of "local context" entirely.
Initializer declarations were missing support for `async`, in part
because they deplicated most of the `FunctionSignature` production.
Instead, use `FunctionSignature` consistently and let the presence of a
result type be a semantic error.
When recovering from a parser error in an expression, we resumed parsing at a '{'. I assume this was because we wanted to continue inside e.g. an if-body if parsing the condition failed, but it's actually causing more issue because when parsing e.g.
```swift
expr + has - error +
functionTakesClosure {
}
```
we continue parsing at the `{` of the trailing closure, which is a completely garbage location to continue parsing.
The motivating example for this change was (in a result builder)
```swift
Text("\(island.#^COMPLETE^#)")
takeTrailingClosure {}
```
Here `Text(…)` has an error (because it contains a code completion token) and thus we skip `takeTrailingClosure`, effectively parsing
```swift
Text(….) {}
```
which the type checker wasn’t very happy with and thus refused to provide code completion. With this change, we completely drop `takeTrailingClosure {}`. The type checker is a lot happier with that.
At the moment, if there is an error in the `switch` statement expression or if the `{` is missing, we return `nullptr` from `parseStmtSwitch`, but we consume tokens while trying to parse the `switch` statement. This causes the AST to not contain any nodes for the tokens that were consumed while trying to parse the `switch` statement.
While this doesn’t cause any issues during compilation (compiling fails anyway so not having the `switch` statement in the AST is not a problem) this causes issues when trying to complete inside an expression that was consumed while trying to parse the `switch` statement but doesn’t have a representation in the AST. The solver-based completion approach can’t find the expression that contains the completion token (because it’s not part of the AST) and thus return empty results.
To fix this, make sure we are always creating a `SwitchStmt` when consuming tokens for it.
Previously, one could always assume that a `SwitchStmt` had a valid `LBraceLoc` and `RBraceLoc`. This is no longer the case because of the recovery. In order to form the `SwitchStmt`’s `SourceRange`, I needed to add a `EndLoc` property to `SwitchStmt` that keeps track of the last token in the `SwitchStmt`. Theoretically we should be able to compute this location by traversing the right brace, case stmts, subject expression, … in reverse order until we find something that’s not missing. But if the `SubjectExpr` is an `ErrorExpr`, representing a missing expression, it might have a source range that points to one after the last token in the statement (this is due to the way the `ErrorExpr` is being constructed), therefore returning an invalid range. So overall I thought it was easier and safer to add another property.
Fixes rdar://76688441 [SR-14490]
Since we only call one parsing function (i.e. parseAbstructFunctionBody,
parseDecl, or parseStmtOrExpr), the parser stops at the end of the node.
It's not necessary to limit the Lexer to set an ArtificialEOF.
To minimize the parsing range, modify the Parser to *not* parse the body
if the completion happens in the signature.
* [TypeChecker] Enclosing stubs protocol note within editor mode
* [test] Removing note from test where there is no -diagnostics-editor-mode flag
* Formatting modified code
* [tests] Fixing tests under validation-tests
Patch up all the places that are making a syntactic judgement about the
isInvalid() bit in a ValueDecl. They may continue to use that query,
but most guard themselves on whether the interface type has been set.
This is an amalgam of simplifications to the way VarDecls are checked
and assigned interface types.
First, remove TypeCheckPattern's ability to assign the interface and
contextual types for a given var decl. Instead, replace it with the
notion of a "naming pattern". This is the pattern that semantically
binds a given VarDecl into scope, and whose type will be used to compute
the interface type. Note that not all VarDecls have a naming pattern
because they may not be canonical.
Second, remove VarDecl's separate contextual type member, and force the
contextual type to be computed the way it always was: by mapping the
interface type into the parent decl context.
Third, introduce a catch-all diagnostic to properly handle the change in
the way that circularity checking occurs. This is also motivated by
TypeCheckPattern not being principled about which parts of the AST it
chooses to invalidate, especially the parent pattern and naming patterns
for a given VarDecl. Once VarDecls are invalidated along with their
parent patterns, a large amount of this diagnostic churn can disappear.
Unfortunately, if this isn't here, we will fail to catch a number of
obviously circular cases and fail to emit a diagnostic.
- Utilize ignoreToken() to skip tokens while keeping them in syntax tree
- SyntaxParsedResult now holds ParsedRawSyntaxNode and ParserStatus
- Simplify migration support for 'TypeName[]' type
- Use builder for generic argument clause parsing
Instead of creating the AST directly in the parser (and libSyntax or
SwiftSyntax via SyntaxParsingContext), make Parser to explicitly create
a tree of ParsedSyntaxNodes. Their OpaqueSyntaxNodes can be either
libSyntax or SwiftSyntax. If AST is needed, it can be generated from the
libSyntax tree.
Under non-editor mode, the fixit for inserting protocol stubs is associated with a note
pointing to the missing protocol member declaration which could stay in a separate file from
the conforming type, leading to the behavior of rdar://51534405. This change checks if
the fixit is in a separate file and issues another note to carry the fixit if so.
rdar://51534405
- When parsing a type or extension declaration, attempt to parse a function or property declaration when meeting an identifier, an operator or a paren (for tuple declarations).
- Produce the diagnostic with a fix-it suggesting to insert the needed keyword
- Recover parsing as if the declaration with the missing keyword is a function/property declaration
Resolves https://bugs.swift.org/browse/SR-10477
