Pull the implicit 'Self' associated type out of the protocol and into
an implicitly-declared generic parameter list for the protocol. This
makes all of the methods of a protocol polymorphic, e.g., given
protocol P {
typealias Assoc
func getAssoc() -> Assoc
}
the type of P.getAssoc is:
<Self : P> (self : @inout P) -> () -> Self.Assoc
This directly expresses the notion that protocol methods are
polymorphic, even though 'Self' is always implicitly bound. It can be
used to simplify IRgen and some parts of the type checker, as well as
laying more of the groundwork for default definitions within
protocols as well as sundry other improvements to the generics
system.
There are a number of moving parts that needed to be updated in tandem
for this. In no particular order:
- Protocols always get an implicit generic parameter list, with a
single generic parameter 'Self' that conforms to the protocol itself.
- The 'Self' archetype type now knows which protocol it is
associated with (since we can no longer point it at the Self
associated type declaration).
- Protocol methods now get interface types (i.e., canonicalizable
dependent function types).
- The "all archetypes" list for a polymorphic function type does not
include the Self archetype nor its nested types, because they are
handled implicitly. This avoids the need to rework IRGen's handling
of archetypes for now.
- When (de-)serializing a XREF for a function type that has an
interface type, use the canonicalized interface type, which can be
meaningfully compared during deserialization (unlike the
PolymorphicFunctionType we'd otherwise be dealing with).
- Added a SIL-specific type attribute @sil_self, which extracts the
'Self' archetype of a protocol, because we can no longer refer to
the associated type "P.Self".
Swift SVN r9066
Put generic nominal type declarations through the same dependent-type
validation as generic functions, then capture their generic parameters
and requirements in their generic signature. This allows us to
re-instate the requirements in their dependent forms, before the
archetypes ruin them completely.
Swift SVN r8958
When building the (dependent) interface type of generic functions,
don't resolve any generic parameter types to archetypes, even those at
outer levels. Instead, keep everything dependent.
As a special case, the type of 'self' gets baked into the parameter
patterns with archetypes, so reconstruct the 'self' type ourselves.
The actual output of this is still frustratingly untestable, but we
get decent coverage because all of the type checking of generic
functions goes through here first.
Swift SVN r8936
For derivable protocols, such as RawRepresentable on raw-typed enums, when checking the conformance, create a conforming decl if an explicit decl wasn't found. Refactor the conformance derivation for toRaw/fromRaw to be driven by conformance checking in this way.
Swift SVN r8930
Introduces a new kind of function type, GenericFunctionType, that
represents a polymorphic function type with all of its generic
parameters and requirements stored in a more readily canonicalizable
form. It is meant to eventually replace PolymorphicFunctionType, but
for now we build it up in parallel so we can switch over to it
pieacemeal.
Note: this representation is built and then thrown away. We'll start
recording it soon.
Swift SVN r8881
Attribute [transparent] on extensions should apply to all members(functions, properties) of that extension.
Addresses radar://15035271.
Swift SVN r8735
These are the terms sent out in the proposal last week and described in
StoredAndComputedVariables.rst.
variable
anything declared with 'var'
member variable
a variable inside a nominal type (may be an instance variable or not)
property
another term for "member variable"
computed variable
a variable with a custom getter or setter
stored variable
a variable with backing storage; any non-computed variable
These terms pre-exist in SIL and IRGen, so I only attempted to solidify
their definitions. Other than the use of "field" for "tuple element",
none of these should be exposed to users.
field
a tuple element, or
the underlying storage for a stored variable in a struct or class
physical
describes an entity whose value can be accessed directly
logical
describes an entity whose value must be accessed through some accessor
Swift SVN r8698
Instead of synthesizing Swift code for the property and subscript
getters and setters we import from Objective-C, just create the
declarations and mark them as being Objective-C (foreign) entry
points. This means that we'll use the Objective-C entry points (via
objc_msgSend).
Swift SVN r8692
Previously, we followed an early exit for bodiless constructors/destructors/subscripts.
This prevented some diagnostics and full AST class setup in SIL parsing mode and for bodiless subscripts in general.
Thanks for the suggestion Dmitry!
Swift SVN r8672
Introduce a bit in Expr to indicate whether the expression is implicit and decouple the implicitness
of an expression from whether it has a source location or not.
This allows implicit expressions to be able to point at the source location where they originated from.
It also allows decoupling the implicitness of a parent from its children, so for example, an implicit CallExpr
can have an explicit parameter value.
Swift SVN r8600
Iff an enum declares a raw type, its cases may declare raw values or else have them assigned to them implicitly by autoincrementing from zero, like in C. If the raw type is float-, string-, or char-literal-convertible, there is no autoincrement, and the raw values must all be explicit. The raw type is rejected if any cases have payloads.
We don't yet diagnose duplicate raw values. That'll come next. We also don't yet serialize or deserialize the raw values. We don't strictly need to do this, since the RawRepresentable protocol conformance will be exported from the module as API, but Jordan pointed out that, for fragile raw values, this would be good for documents/jump-to-definition purposes, so we have a plan for only serializing the literals without having to deal with fully general expression serialization.
Swift SVN r8545
Allow the inheritance clauses of enums to reference a non-protocol type as their raw type. For now, only diagnose that the raw type occurs first, that there's only one raw type, that there are no circularities in raw types, like we do for class inheritance, and additionally that the raw type is literal convertible, which we'll require for the raw values of the cases.
Swift SVN r8529
Introduce an EnumCaseDecl for source fidelity to track the 'case' location and ordering of EnumElementDecls. Parse a comma-separated list of EnumElementDecls after a 'case' token.
Swift SVN r8509
Improve the type checker to create implicit DestructorDecls, tighten the
assertion in ImplicitReturnLocation::getImplicitReturnLoc(), and add a verifier
check that a class in a type checked AST always has exactly one destructor.
SILGen used to generate a destructor if the class does not have a
DestructorDecl. SILGen used to put the ClassDecl inside the SILLocation for
the destructor SIL code. This is not a very clean solution: in this case
ImplicitReturnLocation SILLocations contain ClassDecl, which is surprising.
rdar://14970972 Implicit destructors should have AST nodes
Swift SVN r8498
Implement the new rules for mapping between selector names and
constructors. The selector for a given constructor is formed by
looking at the names of the constructor parameters:
* For the first parameter, prepend "init" to the parameter name and
uppercase the first letter of the parameter name. Append ':' if
there are > 1 parameters or the parameter has non-empty-tuple type.
* For the remaining parameters, the name of each parameter followed
by ':'.
When a parameter doesn't exist, assume that the parameter name is the
empty string.
And, because I failed to commit it separately, support selector-style
declarations of constructor parameters so that we can actually write
constructors nicely, e.g.:
// selector is initWithFoo:bar:
constructor withFoo(foo : Foo) bar(bar : Bar) { ... }
Swift SVN r8361
Given an object of type DynamicLookup.metatype, allow us to find both
static and instance methods.
Sema only; SILGen and IRGen changes to come.
Swift SVN r8290
AnyFunctionRef is a universal function reference that can wrap all AST nodes
that represent functions and exposes a common interface to them. Use it in two
places in SIL where CapturingExpr was used previously.
AnyFunctionRef allows further simplifications in other places, but these will
be done separately.
Swift SVN r8239
No testcase because this is not testable now -- this function is only used in
diagnostics of value redefinitions, which are broken now for redefinitions of
member functions.
Swift SVN r8187
ConstructorDecl::getBody() and DestructorDecl::getBody() return 'BraceStmt *'.
After changing the AST representation for functions, FuncDecl::getBody() will
return 'BraceStmt *' and FuncDecl::getFuncExpr() will be gone.
Swift SVN r8050
global variables used by functions in the capture list as well.
SILGen and other things that don't care about these (i.e., all
current current clients) filter the list to get what they want.
This is needed for future definite init improvements, and unblocked
by Doug's patch in r8039 (thanks! :)
No functionality change.
Swift SVN r8045
