Rename existentialConformsToSelf() to existentialTypeSupported(). This
predicate is the "protocol has no Self or associated type requirements"
check, which is a looser condition than self-conformance. This was being
tested to see if the user could refer to the protocol via an existential
type.
The new existentialConformsToSelf() now checks for protocol being @objc,
and for the absence of static methods. This is used as part of the
argument type matching logic in matchType() to determine if the
existential can be bound to a generic type parameter.
The latter condition is stricter, for two reasons:
1) We allow binding existentials to multiple type parameters all sharing
the same generic type parameter T, so we don't want the user to be
able to see any static methods on T.
2) There is an IRGen limitation whereby only existentials without witness
tables can be passed in this manner.
Using the above, the representsNonTrivialGenericParameter() function
has been renamed to canBindGenericParamToExistential(). It now allows
an existential type to be bound to a generic type parameter only under
the following circumstances:
A) If the generic type parameter has no conformances, the match is allowed.
B) If the generic type parameter has at least one conformance, then all
of the conformances on the generic type parameter must be
existentialConformsToSelf() (condition 1 above), and all conformances
on the existential must be @objc (condition 2 above).
Fixes <rdar://problem/18378390> and <rdar://problem/18683843>, and lays
the groundwork for fixing a few other related issues.
Swift SVN r29337
initializer has been type-checked, rather than a bit for the entire
PatternBindingDecl.
<rdar://problem/21057425> Crash while compiling attached test-app.
Swift SVN r29049
Based on Dave’s hack, this allows one to define a “default implementation” as, e.g.,
protocol P {
func foo()
}
extension P {
final func foo() { … }
}
Swift SVN r28949
into account accesibility, assignments to self in a non-mutating
method (consistently), recursive components of an lvalue that makes it
non-settable, etc. Now we tell you what the *problem* was, instead of
just whining.
This fixes:
<rdar://problem/19370429> QoI: fixit to add "mutating" when assigning to a member of self in a struct
<rdar://problem/17632908> QoI: Modifying struct member in non-mutating function produces difficult to understand error message
in their full generality.
Swift SVN r28867
We were printing getter/setter names when the property came from
Objective-C initially, which is incorrect: we should print them when
the names differ from what Objective-C would compute by default. This
finishes rdar://problem/19408726, which was mostly in place a while
ago.
Swift SVN r28783
Fix a nullptr dereference when looking for a base expression
in a member access. Remove use of Optional<T*>, it wasn't providing
any value versus nullptr checking.
Swift SVN r28648
When in an initializer, we allow setting into immutable properties
provided that the type of base in `base.member` matches that of that
initializer's containing type. This was an approximation for allowing
full access into `self` during initialization but this doesn't work when
passing in a different struct of the same type because that struct
should be still be immutable.
Check whether the base of the member access is the implicit self
parameter of the initializer before allowing mutation.
rdar://problem/19814302
Swift SVN r28634
Now that we don't have generic parameter lists at arbitrary positions
within the extended type of an extension declaration, simplify the
representation of the extended type down to a TypeLoc along with a
(compiler-synthesized) generic parameter list.
On the parsing side, just parse a type for the extended type, rather
than having a special grammar. We still reject anything that is not a
nominal type (of course), but it's simpler just to call it a type.
As a drive-by, fix the crasher when extending a type with module
qualification, rdar://problem/20900870.
Swift SVN r28469
Modules occupy a weird space in the AST now: they can be treated like
types (Swift.Int), which is captured by ModuleType. They can be
treated like values for disambiguation (Swift.print), which is
captured by ModuleExpr. And we jump through hoops in various places to
store "either a module or a decl".
Start cleaning this up by transforming Module into ModuleDecl, a
TypeDecl that's implicitly created to describe a module. Subsequent
changes will start folding away the special cases (ModuleExpr ->
DeclRefExpr, name lookup results stop having a separate Module case,
etc.).
Note that the Module -> ModuleDecl typedef is there to limit the
changes needed. Much of this patch is actually dealing with the fact
that Module used to have Ctx and Name public members that now need to
be accessed via getASTContext() and getName(), respectively.
Swift SVN r28284
When reading the generic parameters of a constrained protocol
extension, cross-refencing an associated type would perform name
lookup into the protocol extension itself, causing fatal recursion
during deserialization. Fixed by avoiding additional deserialization
when looking for an associated type. Fixes rdar://problem/20812303.
Swift SVN r28228
Within the where clause of a constrained (protocol) extension, allow
us to find associated types of that protocol and anything it inherits
via unqualified lookup, e.g.,
extension SequenceType where Generator.Element : Equatable { }
rather than
extension SequenceType where Self.Generator.Element : Equatable { }
Implements rdar://problem/20722467.
Swift SVN r28208
Currently GenericSignature::getCanonicalSignature isn't able to canonicalize the set of requirements due to fragile dependencies on generic signatures matching AllArchetypes order of their originating GenericParamLists. However, we shouldn't let that stop us from getting the mangling right, so implement a "getCanonicalManglingSignature" that builds the true canonical signature by feeding it into an ArchetypeBuilder and shedding unnecessary constraints. For now, just handle conformance and base class constraints; still to do are same-type constraints.
Swift SVN r28191
There was a fair amount of code duplication in handling the various
places where @objc could either be explictly specified or be inferred;
centralize these in a new shouldMarkAsObjC() function. NFC
Swift SVN r28125
When deserializing a protocol, the conformance lookup table would not
contain entries for the inherited protocols of that protocol. They
were stashed in the "Protocols" array in TypeDecl (which will
eventually go away), but since there are no conformances for a
protocol, the conformance lookup table never got updated.
Nothing important seems to query this now; that will change soon.
Swift SVN r27967
Extensions cannot be uniquely cross-referenced, so cross-references to
extensions are serialized with the extended nominal type name and the
module in which the extension resides. This is not sufficient when
cross-referencing the generic type parameters of a constrained
protocol extension, because we don't know whether to get the
archetypes of the nominal type or some extension thereof. Serialize
the canonical generic signature so that we can pick an extension with
the same generic signature; it doesn't matter which we pick, so long
as we're consistent.
Fixes rdar://problem/20680169. Triggering this involves some
interesting interactions between the optimizer and standard library;
the standard library updates in the radar will test this.
Swift SVN r27825
- <rdar://problem/16306600> QoI: passing a 'let' value as an inout results in an unfriendly diagnostic
- <rdar://problem/16927246> provide a fixit to change "let" to "var" if needing to mutate a variable
We now refer to an inout argument as such, e.g.:
t.swift:7:9: error: cannot pass 'let' value 'a' as inout argument
swap(&a, &b)
^
we also produce a note with a fixit to rewrite let->var in trivial cases where mutation is
being assed for, e.g.:
t.swift:3:3: note: change 'let' to 'var' to make it mutable
let a = 42
^~~
var
The note is produced by both Sema and DI.
Swift SVN r27774
the printed interface.
Previously we printed the typechecked and uniqued requirements and the result was non-sensical.
Long-term the requirements will be preserved in a better form but for now print the requirements
and serialize them.
rdar://19963093
Swift SVN r27680
Add syntax "[#Color(...)#]" for object literals, to be used by
Playgrounds for inline color wells etc. The arguments are forwarded to
the relevant constructor (although we will probably change this soon,
since (colorLiteralRed:... blue:... green:... alpha) is kind of
verbose). Add _ColorLiteralConvertible and _ImageLiteralConvertible
protocols, and link them to the new expressions in the type checker.
CSApply replaces the object literal expressions with a call to the
appropriate protocol witness.
Swift SVN r27479
Move the map that keeps track of conforming decl -> requirement from ASTContext
to a nominal type's ConformanceLookupTable, and populate it lazily.
This allows getSatisfiedProtocolRequirements() to work with declarations from module files.
Test on the SourceKit side.
Part of rdar://20526240.
Swift SVN r27353
Refactor the Objective-C selector computation code for all forms of
methods, collapsing it into a single routine to eliminate
duplication. Test that we're computing Objective-C selectors for
throwing initializers correctly, as well as that we're printing the
appropriate Objective-C method declarations for throwing
initializers.
Swift SVN r27293
Introduce basic validation for throwing @objc initializers, e.g., a
failable @objc initializer cannot also be throwing. However,
Objective-C selector computation is broken.
Swift SVN r27292
FuncDecl::throws() is misleading because it only tells us whether the
'throws' keyword was present on the declaration. Since source
locations are lost during deserialization, it would give the wrong
result. Nobody was making this mistake now, but it's better not to
leave this trap in the ASTs.
Use AbstractFuncitonDecl::isBodyThrowing() to determine whether a
particular function (or initializer, eventually) can throw.
Swift SVN r27257
