This re-applies commit r31763 with a change to the predicate we
use for determining the linkage of a definition. It turns out we
could have definitions with a Clang body that were still public,
so instead of checking for a Clang body just check if the Clang
declaration is externally visible or not.
Swift SVN r31777
If an external SIL function has a Clang-generated body, I think this
means we have a static function, and we want to use Shared linkage,
not Public.
Add a new flag to SILFunction for this and plumb it through to
appease assertions from SILVerifier.
Swift SVN r31763
There's a hack to make closures in transparent contexts always public in order to support transparent inlining in user code, but it's the wrong thing to do with the artificial callback for materializeForSet, which will be generated in modules that need it. Any problems with this linkage would already be problems with referencing the other shared accessors, and this fixes a duplicate symbol bug when materializeForSet is demanded by multiple TUs (rdar://problem/21314681).
Swift SVN r30098
If a SILDeclRef references a decl that isn't explicit in the source code and can't be referenced externally, then we only need to emit it if it's referenced in the current TU. Partially addresses rdar://problem/21444126, though we still eagerly generate witness tables for generated conformances, which still pull in a bunch of noise.
Swift SVN r29536
Instead of immediately creating closures for local function declarations and treating them directly as capturable values, break function captures down and transitively capture the storage necessary to invoke the captured functions. Change the way SILGen emits calls to closures and local functions so that it treats the capture list as the first curry level of an invocation, so that full applications of closure literals or nested functions don't require a partial apply at all. This allows references among local functions with captures to work within the existing confines of partial_apply, and also has the nice benefit that circular references would work without creating reference cycles (though Sema unfortunately rejects them; something we arguably ought to fix.)
This fixes rdar://problem/11266246 and improves codegen of local functions. Full applications of functions, or immediate applications of closure literals like { }(), now never need to allocate a closure.
Swift SVN r28112
Keep track of a second set of "direct method reference" curry thunks that don't end in a dynamic dispatch in order to properly implement a partial application such as 'let foo = super.foo'. Fixes rdar://problem/20598526.
Swift SVN r27538
This should clear the way for removing isTransparent on apply entirely.
Previously we marked any apply of an autoclosure transparent, but now
that the mandatory inliner inlines anything marked transparent, we don't
need that.
Resolves rdar://problem/20286251.
Swift SVN r26525
Currently a no-op, but effective access for entities within the current
module will soon need to take testability into account. This declaration:
internal func foo() {}
has a formal access of 'internal', but an effective access of 'public' if
we're in a testable mode.
Part of rdar://problem/17732115 (testability)
Swift SVN r26472
If we have a C function pointer conversion, generate a thunk using the same logic we use for ObjC method thunks, and emit a pointer to that thunk as the C function pointer value. (This works for nongeneric, nonmember functions; generics will additionally need to apply generic parameters within the thunks. Static functions would need to gather the metatype as well.)
Swift SVN r25653
rdar://problem/19514920 is caused by a disagreement between IRGen and SILGen about which SILDeclRefs override vtable slots. Factor out the somewhat-hairy code in SILGen to a place IRGen will be able to share it. NFC yet.
Swift SVN r25063
The underlying problem is that e.g. even if a method is private but its class is public, the method can be referenced from another module - from the vtable of a derived class.
So far we handled this by setting the SILLinkage of such methods according to the visibility of the class. But this prevented dead method elimination.
Now I set the SILLinkage according to the visibility of the method. This enables dead method elimination, but it requires the following:
1) Still set the linkage in llvm so that it can be referenced from outside.
2) If the method is dead and eliminated, create a stub for it (which calls swift_reportMissingMethod).
Swift SVN r23889
Also handles mangling, demangling, printing and parsing.
This is the first patch to use global getter for "let" globals.
rdar://16614767
Swift SVN r23106
Methods which go into a vtable must be at least as visible as their classes.
Otherwise derived classes from "outside" cannot reference such base methods in their vtables.
Swift SVN r22889
Now the SILLinkage for functions and global variables is according to the swift visibility (private, internal or public).
In addition, the fact whether a function or global variable is considered as fragile, is kept in a separate flag at SIL level.
Previously the linkage was used for this (e.g. no inlining of less visible functions to more visible functions). But it had no effect,
because everything was public anyway.
For now this isFragile-flag is set for public transparent functions and for everything if a module is compiled with -sil-serialize-all,
i.e. for the stdlib.
For details see <rdar://problem/18201785> Set SILLinkage correctly and better handling of fragile functions.
The benefits of this change are:
*) Enable to eliminate unused private and internal functions
*) It should be possible now to use private in the stdlib
*) The symbol linkage is as one would expect (previously almost all symbols were public).
More details:
Specializations from fragile functions (e.g. from the stdlib) now get linkonce_odr,default
linkage instead of linkonce_odr,hidden, i.e. they have public visibility.
The reason is: if such a function is called from another fragile function (in the same module),
then it has to be visible from a third module, in case the fragile caller is inlined but not
the specialized function.
I had to update lots of test files, because many CHECK-LABEL lines include the linkage, which has changed.
The -sil-serialize-all option is now handled at SILGen and not at the Serializer.
This means that test files in sil format which are compiled with -sil-serialize-all
must have the [fragile] attribute set for all functions and globals.
The -disable-access-control option doesn't help anymore if the accessed module is not compiled
with -sil-serialize-all, because the linker will complain about unresolved symbols.
A final note: I tried to consider all the implications of this change, but it's not a low-risk change.
If you have any comments, please let me know.
Swift SVN r22215
This will let the performance inliner inline a function even if the costs are too high.
This attribute is only a hint to the inliner.
If the inliner has other good reasons not to inline a function,
it will ignore this attribute. For example if it is a recursive function (which is
currently not supported by the inliner).
Note that setting the inline threshold to 0 does disable performance inlining at all and in
this case also the @inline(__always) has no effect.
Swift SVN r21452
This disables inlining at the SIL level. LLVM inlining is still enabled. We can
use this to expose one function at the SIL level - which can participate in
dominance based optimizations but which is implemented in terms of a cheap check
and an expensive check (function call) that benefits from LLVM's inlining.
Example:
The inline(late) in the example below prevents inlining of the two checks. We
can now perform dominance based optimizations on isClassOrObjExistential.
Without blocking inlining the optimizations would apply to the sizeof check
only and we would have multiple expensive function calls.
@inline(late)
func isClassOrObjExistential(t: Type) -> Bool{
return sizeof(t) == sizeof(AnyObject) &&
swift_isClassOrObjExistential(t)
}
We do want inlining of this function to happen at the LLVM level because the
first check is constant folded away - IRGen replaces sizeof by constants.
rdar://17961249
Swift SVN r21286
- Change the parser to accept "objc" without an @ sign as a contextual
keyword, including the dance to handle the general parenthesized case.
- Update all comments to refer to "objc" instead of "@objc".
- Update all diagnostics accordingly.
- Update all tests that fail due to the diagnostics change.
- Switch the stdlib to use the new syntax.
This does not switch all tests to use the new syntax, nor does it warn about
the old syntax yet. That will be forthcoming. Also, this needs a bit of
refactoring, which will be coming up.
Swift SVN r19555
We do this hack for @objc methods at the top level, emitting them as external in SIL and making them private in IRGen, to prevent SIL optimizations from dropping the functions as unused (see <rdar://problem/17074598>), but we weren't doing so for @objc classes in local contexts, and they were getting dropped. Fixes <rdar://problem/16982281>.
Swift SVN r18668
attributes and create implicit conversions for them.
Also, when generating Clang modules for import, set the
appropriate macro to make CoreFoundation actually apply
those attributes to its typedefs.
Also, give shared linkage to imported class method
definitions.
The net effect is that CFString now automatically
converts to NSString and vice-versa.
Depends on Clang r208756 in order to preserve attributes
applied to tag types in multiple typedef declarations.
Swift SVN r18069
Eliminate the duplicate half-broken bridging logic in emitClassConstructorAllocator by referencing foreign initializers through their foreign-to-native thunks, which SILGen knows how to emit already. Do the same thing for factory initializers by suppressing their normal allocating initializer codegen and just referencing the usual foreign-to-native thunk for them. This fixes <rdar://problem/16853205> because we get the ownership thunking right now.
Swift SVN r17840
Once we have real access control at the AST level, this should be changed to
match whatever the access control of the local declcontext.
Swift SVN r16098
This representation is inspired by Clang's internal representation.
The current attribute representation, which is basically a union
of "stuff" in DeclAttributes, is not amendable to richer
attributes, such as @availability, that need to be implemented.
In Clang, attributes are modeled with actual objects that
encode both semantic and syntactic information (e.g., source ranges)
that facilitate richer checking, better diagnostics, and better tools.
This change is foundational for implementing @availability, but
also is a better long-term representation. As a migratory path,
it creates some duplications, with AttrKind and DeclAttrKind, the
two which should eventually become the same thing.
As part of this patch, there is some additional parser recovery
(for the new attribute representation) for duplicate attributes.
The parser now parses the entire duplicate attribute, which could
be quite complex, and then issues a diagnostic that the attribute
is a duplicate (and discarding it). This delayed diagnostic
also allows us to present ranges for the duplicate attribute, which
provides a better user experience.
Swift SVN r15365
In Sema, give derived '==' definitions the module's DerivedFileUnit as their decl context instead of the more general Module, and give it a backreference to the nominal type for which it was derived.
In SILGen, visit the derived global decls associated with Clang-imported enums, and give them shared linkage. Part of fixing <rdar://problem/16264703>.
Swift SVN r14875
