Follow-up to ac6fd7214 that adds a similar feature for enums. This
probably doesn't come up much, but the infrastructure's already there.
(The previous commit showed that the other places we do recovery
already handle this from their normal collection of "dependency
types".)
The existing code already handles this, so it's just a matter of
testing what happens for these declarations that can be generic:
functions, initializers, and subscripts. (Enums are coming in the next
commit.) Note that we currently don't try to recover at all for a
struct or class whose generic requirements aren't valid anymore.
We could handle a typealias itself disappearing, but not if the
typealias was okay but the underlying type wasn't. This came up in
real Swift 3/4 mix-and-match code.
rdar://problem/34940079
If we can't resolve a cross-reference unambiguously, we're supposed to
produce an llvm::Error and let the calling code handle it. However, if
we couldn't even resolve the /type/ of the cross-reference, we would
just crash. Follow the supported error path in that case too -- in
many cases the error can just propagate upwards to something that can
handle it.
rdar://problem/34821187, plus an extra test case from
rdar://problem/35157494. (The latter will be fixed better later, but
meanwhile let's not regress on the crashing part.)
For now these are underscored attributes, i.e. compiler internal attributes:
@_optimize(speed)
@_optimize(size)
@_optimize(none)
Those attributes override the command-line specified optimization mode for a specific function.
The @_optimize(none) attribute is equivalent to the already existing @_semantics("optimize.sil.never") attribute
Currently when function types like `(_: Int...) -> Void` are mangled
their names are going to include enclosing sugar BoundGenericType(Array),
which is not necessary and doesn’t play well with `AnyFunctionType::Param`
which strips the sugar away.
Resolves: rdar://problem/34941557
When a conformance can either be synthesized or implied, we tend to prefer
implied. However, if the implied conformance comes from a deserialized
conformance, it will lead to an incomplete conformance and cause a crash.
This is a narrow fix for SR-6105 / rdar://problem/34911378.
It didn't, because the bitcode format said we only needed 8 possible
kinds of record within this block, which was a lie when both of these
flags were passed.
This is a backwards-compatible change, so no need to update the module
format version number.
This replaces the '[volatile]' flag. Now, class_method and
super_method are only used for vtable dispatch.
The witness_method instruction is still overloaded for use
with both ObjC protocol requirements and Swift protocol
requirements; the next step is to make it only mean the
latter, also using objc_method for ObjC protocol calls.
introduce a common superclass, SILNode.
This is in preparation for allowing instructions to have multiple
results. It is also a somewhat more elegant representation for
instructions that have zero results. Instructions that are known
to have exactly one result inherit from a class, SingleValueInstruction,
that subclasses both ValueBase and SILInstruction. Some care must be
taken when working with SILNode pointers and testing for equality;
please see the comment on SILNode for more information.
A number of SIL passes needed to be updated in order to handle this
new distinction between SIL values and SIL instructions.
Note that the SIL parser is now stricter about not trying to assign
a result value from an instruction (like 'return' or 'strong_retain')
that does not produce any.
The witness table had shared linkage, but we weren't serializing them,
which would cause linking errors if we emitted a reference to such a
witness table from a different module than the one where it was first
defined, as a result of deserializing and optimizing SIL.
This issue was introduced when SIL witness table serialization was
made conditional on the -sil-serialize-witness-tables flag, which is
normally only enabled for the standard library.
When the flag was added, existing tests were updated to pass the
flag, which masked the issue. Remove the flag from existing tests,
ensure that imported witness tables are still [serialized], and add
a new test specifically for the behavior enabled by this flag.
This commit contains:
-) adding the new instructions + infrastructure, like parsing, printing, etc.
-) support in IRGen to generate global object-variables (i.e. "heap" objects) which are statically initialized in the data section.
-) IRGen for global_value which lazily initializes the object header and returns a reference to the object.
For details see the documentation of the new instructions in SIL.rst.
This shows up with swift_wrapper typedefs, which get imported into
Swift as structs. If someone makes an extension of a swift_wrapper
type, but the swift_wrapper is only applied in Swift 4 mode, that
extension will break any Swift 3 clients. Recover by just dropping
the extension entirely.
There's still more complexity around extensions---what if a
requirement can't be deserialized? what if something's depending on
the protocol conformance provided by the extension?---but the missing
base type case should be pretty safe. If you can't see the type at
all, things that depend on its conformances are already in trouble.
rdar://problem/33636733
When there's an Objective-C protocol that adopts other protocols, the
other protocols become part of the requirement signature. If that can
change, Swift conformances to that protocol will get very confused
when it comes time to deserialize the conformances that satisfy the
requirement signature.
To recover from this, just deserialize /all/ trailing conformances,
rather than follow the requirement signature, and match them up after
the fact. (This only works for Objective-C protocols where we know all
conformance requirements represent inherited protocols, as opposed to
constraints on associated types.)
rdar://problem/33356098
This avoids having to bring in all members (and extensions!) for an
outer type just to look up a nested type. In the test case attached
(reduced from the project in SR-5284), this actually led to a circular
dependency between deserialization and the importer, which resulted in
a compiler crash.
This is not a new problem, but it's more important with the release of
Swift 4, where a number of Apple SDK types are now newly imported as
member types. (The one in the original bug was
NSView.AutoresizingMask, formerly NSAutoresizingMaskOptions.) Since we
always use the Swift 4 name for cross-references, this affected
everyone, even those still compiling in Swift 3 mode.
https://bugs.swift.org/browse/SR-5284
Currently some contextual errors are discovered too late
which leads to diagnostics of unrelated problems like argument
mismatches, these changes attempt to improve the situation
and try to diagnose contextual errors related to calls
before everything else.
Resolves: SR-5045, rdar://problem/32934129
