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.
Rather than using RequirementRequest::visitRequirements() for its side
effects, then reading from the TypeLocs left behind, start eliminating
TypeLoc-based APIs so we pass Type and TypeRepr separately.
Add some utilities to dig into a possibly-null RequirementRepr* and dig
out the appropriate TypeReprs.
Introduce a new form of request that produces the ith Requirement of the
where clause of a given entity, which could be a protocol, associated type,
or anything with generic parameters. The requirement can be evaluated
at any type resolution stage; the “interface” type stage will be cached
in the existing RequirementReprs.
Fixes SR-8119 / rdar://problem/41498944.
Extend the inputs to InheritedTypeRequest, SuperclassTypeRequest, and
EnumRawTypeRequest to also take a TypeResolutionStage, describing what
level of type checking is required. The GenericSignatureBuilder relies
only on structural information, while other clients care about the
full interface type.
Only the full interface type will be cached, and the contextual type
(if requested) will depend on that.
Previously, TBDGen skipped emitting lazy initializers for globals that
appeared in any file with an entry point. This breaks, however on files
that have an NSApplicationMain/UIApplicationMain class in them, where
the entry point is synthesized but top-level globals are not locally
scoped. This change re-uses SILGen's check and only skips variable
declarations that appear at top level in a script mode file.
Resolves rdar://43549749
In-place initialization means the class has a symbol we can reference
from the category, so there's nothing to do on the IRGen side.
For JIT mode, we just need to realize the class metadata by calling an
accessor instead of directly referencing the symbol though.
- 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's already a field for this in GenericContext, which ProtocolDecl
indirectly inherits. Protocols may have slightly different treatment
of their where-clauses, but not enough to justify a separate field.
No functionality change.
This is mostly NFC; the output of the api-digester test changed because
the interface type of an enum element now has parentheses around the
'Self' parameter type. This is more consistent with everything else
(and in the future, all function types will have "parentheses").
This allows us to dump it in the generated interface, though it's
still not syntax-highlighted. This is necessary for textual module
interfaces, but it's also just a longstanding request for Xcode's
"Generated Interface" / "Jump to Definition" feature.
rdar://problem/18675831
Use ExtensionDecl::getExtendedNominal() to wire up extensions to their
nominal types early in type checking (the bindExtensions()) operation,
rather than going through type validation to do so.
Introduce a request for ExtensionDecl::getExtendedNominal() that
uses TypeRepr-based resolution to find the extended nominal
type declaration without going through type resolution.
Introduce ExtensionDecl::getExtendedNominal() to provide the nominal
type declaration that the extension declaration extends. Move most
of the existing callers of the callers to getExtendedType() over to
getExtendedNominal(), because they don’t need the full type information.
ExtensionDecl::getExtendedNominal() is itself not very interesting yet,
because it depends on getExtendedType().
ClassDecl::getSuperclass() produces a complete interface type describing the
superclass of a class, including any generic arguments (for a generic type).
Most callers only need the referenced ClassDecl, which is (now) cheaper
to compute: switch those callers over to ClassDecl::getSuperclassDecl().
Fixes an existing test for SR-5993.
Introduce three new requests for name lookup operations that avoid performing
type checking/semantic analysis. They work using syntactic information
(e.g., TypeReprs) and AST-level name lookup operations that will (eventually)
avoid and calls back into type checking. The new requests are:
* Retrieve the superclass declaration of a protocol or class declaration. Use
this request for ClassDecl::getSuperclassDecl() and
ProtocolDecl::getSuperclassDecl().
* Retrieve the types “directly referenced” by a particular location in
an inheritance clause. This query is based on looking at the TypeReprs
and performing fairly-minimal lookup, so it does not involve any Type
computations.
* Retrieve the types “directly referenced” by the underlying type of
a typealias. This query allows us to desugar a typealias without forming
a type.
Along with these is a core operation to transform a set of TypeDecl*s
into a set of NominalTypeDecl*s, looking through typealiases, and
without involving Type at all. The superclass-decl request does this
to find a ClassDecl; other requests will eventually do this to (e.g.)
find all of the protocols mentioned in an inheritance clause.
...and collapse StaticVar/ClassVar and StaticLet/ClassLet into
StaticProperty/ClassProperty.
"var" and "let" aren't great nouns to use in diagnostics to begin with,
especially alongside semantic terms like "instance method". Focus on
the type vs. non-type aspect instead with "property", which better
matches how people talk about member vars (and lets) anyway.
We handle layout through finalization of the declaration,
which already has its own approach to eliminating redundant work.
We don’t need an extra bit getting in the way.
This gets adjustAccessLevelForProtocolExtension, a hack of sorts to
begin with, out of ValueDecl's general API, and down to a helper for
isAccessibleFrom and isSetterAccessibleFrom. (The only reason these
two don't go through access scopes is as an optimization.)
...to push people towards getFormalAccessScope. The one use case that
isn't covered by that is checking whether a declaration behaves as
'open' in the current file; I've added ValueDecl::hasOpenAccess to
handle that specific case.
No intended functionality change.
For now, the accessors have been underscored as `_read` and `_modify`.
I'll prepare an evolution proposal for this feature which should allow
us to remove the underscores or, y'know, rename them to `purple` and
`lettuce`.
`_read` accessors do not make any effort yet to avoid copying the
value being yielded. I'll work on it in follow-up patches.
Opaque accesses to properties and subscripts defined with `_modify`
accessors will use an inefficient `materializeForSet` pattern that
materializes the value to a temporary instead of accessing it in-place.
That will be fixed by migrating to `modify` over `materializeForSet`,
which is next up after the `read` optimizations.
SIL ownership verification doesn't pass yet for the test cases here
because of a general fault in SILGen where borrows can outlive their
borrowed value due to being cleaned up on the general cleanup stack
when the borrowed value is cleaned up on the formal-access stack.
Michael, Andy, and I discussed various ways to fix this, but it seems
clear to me that it's not in any way specific to coroutine accesses.
rdar://35399664
Now, an AbstractFunctionDecl always stores a single parameter list.
Furthermore, ConstructorDecl and DestructorDecl always store a
ParamDecl for 'self'.
FuncDecl only has a 'self' if it is a member of a nominal type or
extension, so we tail-allocate the storage for it.
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.
Returns "the" parameter list for the function. The other methods,
such as getParameterLists(), getParameterList(unsigned) and
getNumParameterLists() are going away.
Constructors and methods had two parameter lists, one for self and one
for the formal parameters. Destructors only had one parameter list,
which introduced an annoying corner case.
Separate out the semantic state for the ‘dynamic’ check (from the
presence of the attribute), and move all of the computation of the
‘dynamic’ bit into the request-evaluator.
In the process, this fixes a bug where implicitly-synthesized initializers
in subclasses of imported classes would not be implicitly made ‘final’.
