We used to give witness thunks public linkage if the
conforming type and the protocol are public.
This is completely unnecessary. If the conformance is
fragile, the thunk should be [shared] [serialized],
allowing the thunk to be serialized into callers after
devirtualization.
Otherwise for private protocols or resilient modules,
witness thunks can just always be private.
This should reduce the size of compiled binaries.
There are two other mildly interesting consequences:
1) In the bridged cast tests, we now inline the witness
thunks from the bridgeable conformances, which removes
one level of indirection.
2) This uncovered a flaw in our accessibility checking
model. Usually, we reject a witness that is less
visible than the protocol; however, we fail to
reject it in the case that it comes from an
extension.
This is because members of an extension can be
declared 'public' even if the extended type is not
public, and it appears that in this case the 'public'
keyword has no effect.
I would prefer it if a) 'public' generated a warning
here, and b) the conformance also generated a warning.
In Swift 4 mode, we could then make this kind of
sillyness into an error. But for now, live with the
broken behavior, and add a test to exercise it to ensure
we don't crash.
There are other places where this "allow public but
ignore it, kinda, except respect it in some places"
behavior causes problems. I don't know if it was intentional
or just emergent behavior from general messiness in Sema.
3) In the TBD code, there is one less 'failure' because now
that witness thunks are no longer public, TBDGen does not
need to reason about them (except for the case #2 above,
which will probably require a similar workaround in TBDGen
as what I put into SILGen).
This fixes a crash when referencing partially-applied methods
from @_inlineable functions.
Also, curry thunks for private methods do not need shared
linkage; private is sufficient.
Also, add a third [serializable] state for functions whose bodies we
*can* serialize, but only do so if they're referenced from another
serialized function.
This will be used for bodies synthesized for imported definitions,
such as init(rawValue:), etc, and various thunks, but for now this
change is NFC.
Instead of appending a character for each substitution, we now prefix the substitution with the repeat count, e.g.
AbbbbB -> A5B
The same is done for known-type substitutions, e.g.
SiSiSi -> S3i
This significantly shrinks mangled names which contain large lists of the same type, like
func foo(_ x: (Int, Int, Int, Int, Int, Int, Int, Int, Int, Int, Int, Int))
rdar://problem/30707433
Textual SIL was sometimes ambiguous when SILDeclRefs were used, because the textual representation of SILDeclRefs was the same for functions that have the same name, but different signatures.
Textual SIL was sometimes ambiguous when SILDeclRefs were used, because the textual representation of SILDeclRefs was the same for functions that have the same name, but different signatures.
Also, mark witness thunks for [fragile] witnesses as [fragile].
This allows us to serialize the witness table, as well as any thunks
for witnesses declared @_transparent and @inline(__always).
A transparent function might be deserialized and inlined into a function
in another module, which would cause problems if the function referenced
local functions.
Previously we would force local functions to have public linkage instead,
which worked, but was not resilient if the body of the transparent
function changed in the module that contained it.
Add a library evolution test ensuring that such a change is resilient
now.
Part of https://bugs.swift.org/browse/SR-267.
And include some supplementary mangling changes:
- Give the first generic param (depth=0, index=0) a single character mangling. Even after removing the self type from method declaration types, 'Self' still shows up very frequently in protocol requirement signatures.
- Fix the mangling of generic parameter counts to elide the count when there's only one parameter at the starting depth of the mangling.
Together these carve another 154KB out of a debug standard library. There's some awkwardness in demangled strings that I'll clean up in subsequent commits; since decl types now only mangle the number of generic params at their own depth, it's context-dependent what depths those represent, which we get wrong now. Currying markers are also wrong, but since free function currying is going away, we can mangle the partial application thunks in different ways.
Swift SVN r32896
Canonical dependent member types are always based from a generic parameter, so we can use a more optimal mangling that assumes this. We can also introduce substitutions for AssociatedTypeDecls, and when a generic parameter in a signature is constrained by a single protocol, we can leave that protocol qualification out of the unsubstituted associated type mangling. These optimizations together shrink the standard library by 117KB, and bring the length of the longest Swift symbol in the stdlib down from 578 to 334 characters, shorter than the longest C++ symbol in the stdlib.
Swift SVN r32786
Swift generates two entry points to @objc methods where one of
them is a thunk, and the inliner happily inlines the swift code
into the @objc thunk, effectively doubling the code size of some
@objc classes.
The performance inliner already knows not to inline large functions
into callers that are marked as thunks. This commit adds the [thunk]
attribute to the @objc thunks in an attempt to reduce code size.
rdar://22403108
Swift SVN r31498
Most tests were using %swift or similar substitutions, which did not
include the target triple and SDK. The driver was defaulting to the
host OS. Thus, we could not run the tests when the standard library was
not built for OS X.
Swift SVN r24504
Doing so is safe even though we have mock SDK. The include paths for
modules with the same name in the real and mock SDKs are different, and
the module files will be distinct (because they will have a different
hash).
This reduces test runtime on OS X by 30% and brings it under a minute on
a 16-core machine.
This also uncovered some problems with some tests -- even when run for
iOS configurations, some tests would still run with macosx triple. I
fixed the tests where I noticed this issue.
rdar://problem/19125022
Swift SVN r23683
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
- the type of a const global variable
- the type of a parameter, always
- the return type of a function that has been audited
or has an explicit retained/not-retained attribute
- the return type of an ObjC method that has an explicit
retain/not-retained/inner-pointer attribute
Additionally, choose the correct conventions for all
these cases during SIL type lowering.
All this importing logic is still only enabled under
-Xfrontend -import-cf-types.
Swift SVN r17543
