We don't actually need to serialize these because they've already been
encoded in the VarDecl's type. However, we'll probably need to be careful
when pretty-printing these on the other side.
Also, be more precise about checking @class_protocol serialization --
before we'd accept any failure, not just rejecting the struct conformance.
Swift SVN r9356
specific to types. While we're at it, improve the diagnostic for when a decl-specific
attribute is applied to a type, or a type-specific attribute is applied to a decl.
Swift SVN r9268
of having a ton of ad-hoc bools in it. This allows us to consolidate a ton of
boilerplate, eliminating 250 lines of code:
17 files changed, 435 insertions(+), 662 deletions(-)
2) This eliminates the special case for weak and unowned attributes, which previously
didn't show up in Attr.def.
3) While we're at it, keep track of proper source locations for each attribute, and
use these to emit diagnostics pointing at the attribute in question instead of at
a funcdecl or the @ sign.
4) Fix axle attributes, which had vertex and fragment swapped.
Swift SVN r9263
Each one has a different kind of lookup cache anyway, and there's no real
reason to have them share storage at the cost of type-safety.
Swift SVN r9242
docs/Resilience.rst describes the notion of a resilience component:
if the current source file is in the same component as a module being
used, it can use fragile access for everything in the other module,
with the assumption that everything in a component will always be
recompiled together.
However, nothing is actually using this today, and the interface we
have is probably not what we'll want in 2.0, when we actually implement
resilience.
Swift SVN r9174
Right now this is just an extra layer of indirection for the decls,
operators, and imports in a TU, but it's the first step towards compiling
multiple source files at once without pretending they're all in a single
file. This is important for the "implicit visibility" feature, where
declarations from other source files in the same module are accessible
from the file currently being compiled.
Swift SVN r9072
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
Semantic context describes the origin of the declaration and serves the same
purpose as opaque numeric "priority" in Clang -- to determine the most likely
completion.
This is the initial implementation. There are a few opportunities to bump the
priority of a certain decl by giving it SemanticContextKind::ExprSpecific
context that are not implemented yet.
Swift SVN r9052
Simplify/clarify a condition that was attempting to avoid a particular
circularity: the value type of a NominalTypeDecl for type T is T.metatype.
Normally, we use the type of a value decl to verify that we actually have
the thing we want (and in the case of functions, to pick a particular
overload). In this case, however, trying to deserialize a reference to
T.metatype ends up just trying to deserialize T again -- it's not in our
lookup table because the deserializer isn't yet sure it's the /right/ T.
The existing code avoided this with a hack: check if the ValueDecl's type
is a metatype. The new code actually does the right thing and checks for
a TypeDecl.
Swift SVN r9038
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
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
When type checking, allow the caller to customize the resolution of generic
type parameter types based on the context, for example, by choosing to
substitute in an archetype (or not) and allowing one to resolve a dependent
member reference via a specific archetype.
No actual functionality change here.
Swift SVN r8797
Instead of relying on the subpattern being a well-formed TuplePattern, let's track our own subelements so we can associate them to properties and validate them ourselves.
Swift SVN r8771
Make ApplyInst and PartialApplyInst directly take substitutions for generic functions instead of trying to stage out substitutions separately. The legacy reasons for doing this are gone.
Swift SVN r8747
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
Replace the existing suite of checked cast instructions with:
- unconditional_checked_cast, which performs an unconditional cast that aborts on failure (like the former downcast unconditional); and
- checked_cast_br, which performs a conditional pass and branches on whether the cast succeeds, passing the result to the true branch as an argument.
Both instructions take a CheckedCastKind that discriminates the different casting modes formerly discriminated by instruction type. This eliminates a source of null references in SIL and eliminates null SIL addresses completely.
Swift SVN r8696
Doug pointed out that 'isObjC' incorrectly excludes C functions, for which we'll also need to be able to independently reference Swift and foreign entries.
Swift SVN r8669
We generate a module from .sil, then deserialize the module using
sil-link-all.
Fix serialization and deserialization of CopyAddrInst.
Fix serialization of ProjectExistentialRefInst.
Add registration of ReferenceStorageTypeLayout, which we forgot to register.
We now have testing coverage of 70+ SILInstructions.
Swift SVN r8635
Also fix serialization of ProjectExistentialRefInst. Add asserts
in SIL deserializer to make sure SIL serializer is using the
correct layout.
Swift SVN r8598
Add a SILLinkage mode "Deserialized" to make sure IRGen will emit
hidden symbols for deserialized SILFunction.
Inside SIL linker, set Linkage to external if we only have a declaration for
a callee function.
Both sil block and decl block in a module can emit an array of substitutions.
To share the serialization between SILSerializer and Serializer, we modify
the interface to pass in the abbreviation codes to write functions and to
pass in a cursor to read functions.
We now correctly handle the serialization of Substitutions in SpecializeInst.
For a deserialized SILFunction, we now temporarily set its SILLocation and
DebugScope to an empty FileLocation. Once mandatory inliner sets the SILLocation
to the location of ApplyInst, a null SILLocation and a null DebugScope
may work for a deserialized SILFunction.
Update testing cases to reflect that we are now inlining transparent functions
from modules, or to disable SILDeserializer for now (I am not sure how to update
those testing cases).
Swift SVN r8582
This mirrors the behavior of project_existential and simplifies some special cases in SILGen. It unfortunately makes dynamic_lookup sequences a bit noisier because of the need to explicitly cast the projection from DynamicLookup.Self to Builtin.ObjCPointer, but I think this modeling is more solid and will fit better with my planned redesign of archetype_method/protocol_method.
Swift SVN r8572
