The error recovery logic around derived conformances is a little bit
tricky. Make sure we don't crash if a type explicitly provides a
RawValue type witness that is not equatable, but omits the witnesses
for init(rawValue:) and the rawValue property.
Fixes <rdar://problem/58127114>.
Hashable doesn't quite have the know-how to reject invalid derivation contexts before hand. Give it a little help by adding a way to retrieve if a decl added to the conformance context was invalid after type checking completes. Otherwise we'll emit "Hashable is broken".
This used to be a lot more relevant a long time ago when typeCheckFunctionsAndExternalDecls actually did type check external functions defined in C. Now, it serves no purpose.
The validation order change from just type checking these things eagerly doesn't seem to affect anything.
ProtocolConformanceRef already has an invalid state. Drop all of the
uses of Optional<ProtocolConformanceRef> and just use
ProtocolConformanceRef::forInvalid() to represent it. Mechanically
translate all of the callers and callsites to use this new
representation.
The only place this was used in Decl.h was the failability kind of a
constructor.
I decided to replace this with a boolean isFailable() bit. Now that
we have isImplicitlyUnwrappedOptional(), it seems to make more sense
to not have ConstructorDecl represent redundant information which
might not be internally consistent.
Most callers of getFailability() actually only care if the result is
failable or not; the few callers that care about it being IUO can
check isImplicitlyUnwrappedOptional() as well.
Implicit accessors are sometimes transparent for performance reasons.
Previously this was done in Sema by maybeMarkTransparent(), which would
add a TransparentAttr. Replace this with a request.
We want to compute the former independently of the latter.
It's only 16 bits so storing it inside the Decl is fine;
it also allows us to eliminate the 'compact' representation
where an AbstractStorageDecl without an accessor record is
assumed to be stored.
If a struct/enum cannot have Equatable/Hashable conformance automatically synthesized because a member's type is not Equatable/Hashable, add a note to the existing 'does not conform' diagnostic pointing out the type that blocked synthesis.
* [AST] Remove stored TypeLoc from TypedPattern
TypedPattern was only using this TypeLoc as a means to a TypeRepr, which
caused it to store the pattern type twice (through the superclass and through
the TypeLoc itself.)
This also fixes a bug where deserializing a TypedPattern doesn't store
the type correctly and generally cleans up TypedPattern initialization.
Resolves rdar://44144435
* Address review comments
Parsed declarations would create an untyped 'self' parameter;
synthesized, imported and deserialized declarations would get a
typed one.
In reality the type, if any, depends completely on the properties
of the function in question, so we can just lazily create the
'self' parameter when needed.
If the function already has a type, we give it a type right there;
otherwise, we check if a 'self' was already created when we
compute a function's type and set the type of 'self' then.
Use the usual bag of tricks to eliminating dependence on the
TypeChecker instance: static functions, LazyResolver callbacks, and
emitting diagnostics on decls/ASTContext.
- getAsDeclOrDeclExtensionContext -> getAsDecl
This is basically the same as a dyn_cast, so it should use a 'getAs'
name like TypeBase does.
- getAsNominalTypeOrNominalTypeExtensionContext -> getSelfNominalTypeDecl
- getAsClassOrClassExtensionContext -> getSelfClassDecl
- getAsEnumOrEnumExtensionContext -> getSelfEnumDecl
- getAsStructOrStructExtensionContext -> getSelfStructDecl
- getAsProtocolOrProtocolExtensionContext -> getSelfProtocolDecl
- getAsTypeOrTypeExtensionContext -> getSelfTypeDecl (private)
These do /not/ return some form of 'this'; instead, they get the
extended types when 'this' is an extension. They started off life with
'is' names, which makes sense, but changed to this at some point. The
names I went with match up with getSelfInterfaceType and
getSelfTypeInContext, even though strictly speaking they're closer to
what getDeclaredInterfaceType does. But it didn't seem right to claim
that an extension "declares" the ClassDecl here.
- getAsProtocolExtensionContext -> getExtendedProtocolDecl
Like the above, this didn't return the ExtensionDecl; it returned its
extended type.
This entire commit is a mechanical change: find-and-replace, followed
by manual reformatted but no code changes.
There are two general constructor forms here:
- One took the number of parameter lists, to be filled in later.
Now, this takes a boolean indicating if there is an implicit
'self'.
- The other one took the actual parameter lists and filled them
in right away. This now takes a separate 'self' ParamDecl and
ParameterList.
Instead of storing the number of parameter lists, an
AbstractFunctionDecl now only needs to store if there is a 'self'
or not.
I've updated most places that construct AbstractFunctionDecls to
properly use these new forms. In the ClangImporter, there is
more code that remains to be untangled, so we continue to build
multiple ParameterLists and unpack them into a ParamDecl and
ParameterList at the last minute.
Previously, some PBDs weren't being marked implicit even though the associated vars were implicit. PatternBindingDecl::createImplicit will be even nicer when we start parsing the location of the equals token.
The storage kind has been replaced with three separate "impl kinds",
one for each of the basic access kinds (read, write, and read/write).
This makes it far easier to mix-and-match implementations of different
accessors, as well as subtleties like implementing both a setter
and an independent read/write operation.
AccessStrategy has become a bit more explicit about how exactly the
access should be implemented. For example, the accessor-based kinds
now carry the exact accessor intended to be used. Also, I've shifted
responsibilities slightly between AccessStrategy and AccessSemantics
so that AccessSemantics::Ordinary can be used except in the sorts of
semantic-bypasses that accessor synthesis wants. This requires
knowing the correct DC of the access when computing the access strategy;
the upshot is that SILGenFunction now needs a DC.
Accessor synthesis has been reworked so that only the declarations are
built immediately; body synthesis can be safely delayed out of the main
decl-checking path. This caused a large number of ramifications,
especially for lazy properties, and greatly inflated the size of this
patch. That is... really regrettable. The impetus for changing this
was necessity: I needed to rework accessor synthesis to end its reliance
on distinctions like Stored vs. StoredWithTrivialAccessors, and those
fixes were exposing serious re-entrancy problems, and fixing that... well.
Breaking the fixes apart at this point would be a serious endeavor.
Introduce some metaprogramming of accessors and generally prepare
for storing less-structured accessor lists.
NFC except for a change to the serialization format.
'private' properties can't be accessed in extensions in Swift 3, so synthesizing
a conformance that reads from such things is going to be incorrect in an
extension.
This works for all protocols except for Decodable on non-final classes, because
the init requirement has to be 'required' and thus in the type's declaration.
Fixes most of https://bugs.swift.org/browse/SR-6803.
Instead of passing around a TypeChecker and three Decls (the nominal type, the
protocol, and the decl declaring the conformance) everywhere, we can just pass
one object.
This should be [NFC].
This removes the default implementation of hash(into:), and replaces it with automatic synthesis built into the compiler. Hashable can now be implemented by defining either hashValue or hash(into:) -- the compiler supplies the missing half automatically, in all cases.
To determine which hash(into:) implementation to generate, the synthesizer resolves hashValue -- if it finds a synthesized definition for it, then the generated hash(into:) body implements hashing from scratch, feeding components into the hasher. Otherwise, the body implements hash(into:) in terms of hashValue.
