Rather than inlining generic signatures in a half dozen places throughout
the serialization format, serialize (uniqued) generic signatures with their
own GenericSignatureID. Update various layouts (generic function types,
SIL function types, generic environments, extension cross-references) to
use GenericSignatureID.
Shaves ~187k off the size of Swift.swiftmodule.
Attach this attribute to VarDecls declared as IUO, and to function decls
that have a result type that is an IUO.
NFC at the moment. Eventually we'll use these to determine where to
implicitly unwrap optional values.
Otherwise, a protocol conformance where the witness was a dynamic
property in another module would trigger an assertion while building
the materializeForSet witness, or miscompile and fail at runtime
if asserts are off.
Support for @noescape SILFunctionTypes.
These are the underlying SIL changes necessary to implement the new
closure capture ABI.
Note: This includes a change to function name mangling that
primarily affects reabstraction thunks.
The new ABI will allow stack allocation of non-escaping closures as a
simple optimization.
The new ABI, and the stack allocation optimization, also require
closure context to be @guaranteed. That will be implemented as the
next step.
Many SIL passes pattern match partial_apply sequences. These all
needed to be fixed to handle the convert_function that SILGen now
emits. The conversion is now needed whenever a function declaration,
which has an escaping type, is passed into a @NoEscape argument.
In addition to supporting new SIL patterns, some optimizations like
inlining and SIL combine are now stronger which could perturb some
benchmark results.
These underlying SIL changes should be merged now to avoid conflicting
with other work. Minor benchmark discrepancies can be investigated as part of
the stack-allocation work.
* Add a noescape attribute to SILFunctionType.
And set this attribute correctly when lowering formal function types to SILFunctionTypes based on @escaping.
This will allow stack allocation of closures, and unblock a related ABI change.
* Flip the polarity on @noescape on SILFunctionType and clarify that
we don't default it.
* Emit withoutActuallyEscaping using a convert_function instruction.
It might be better to use a specialized instruction here, but I'll leave that up to Andy.
Andy: And I'll leave that to Arnold who is implementing SIL support for guaranteed ownership of thick function types.
* Fix SILGen and SIL Parsing.
* Fix the LoadableByAddress pass.
* Fix ClosureSpecializer.
* Fix performance inliner constant propagation.
* Fix the PartialApplyCombiner.
* Adjust SILFunctionType for thunks.
* Add mangling for @noescape/@escaping.
* Fix test cases for @noescape attribute, mangling, convert_function, etc.
* Fix exclusivity test cases.
* Fix AccessEnforcement.
* Fix SILCombine of convert_function -> apply.
* Fix ObjC bridging thunks.
* Various MandatoryInlining fixes.
* Fix SILCombine optimizeApplyOfConvertFunction.
* Fix more test cases after merging (again).
* Fix ClosureSpecializer. Hande convert_function cloning.
Be conservative when combining convert_function. Most of our code doesn't know
how to deal with function type mismatches yet.
* Fix MandatoryInlining.
Be conservative with function conversion. The inliner does not yet know how to
cast arguments or convert between throwing forms.
* Fix PartialApplyCombiner.
When an associated type declaration “overrides” (restates) an associated
type from a protocol it inherits, note that it overrides that declaration.
SourceKit now reports overrides of associated types.
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.
Previously we stored this inside each default argument
initializer context. This was overkill, because it is
the same for all default arguments in a single function,
and also insufficient, because initializer contexts are
not serialized and thus not available in SILGen when
the function is in a different module.
Instead store it directly inside the function and
serialize it.
NFC for now, since SILGen isn't using this yet.
The base mutability of storage is part of the signature, so be sure
to compute that during validation. Also, serialize it as part of
the storage declaration, and fix some places that synthesize
declarations to set it correctly.
The “inherited” types of an associated type are only needed to
type-check an associated type in the context of its protocol.
Once that is complete, the requirement signature of the protocol
is the “truth”, and we no longer rely on the “inherited” types.
Stop serializing them.
"Accessibility" has a different meaning for app developers, so we've
already deliberately excised it from our diagnostics in favor of terms
like "access control" and "access level". Do the same in the compiler
now that we aren't constantly pulling things into the release branch.
Rename AccessibilityAttr to AccessControlAttr and
SetterAccessibilityAttr to SetterAccessAttr, then track down the last
few uses of "accessibility" that don't have to do with
NSAccessibility. (I left the SourceKit XPC API alone because that's
supposed to be more stable.)
Pushes __consuming through the frontend and extends existing
attribute-based diagnsotics to cover it. Unlike `nonmutating`,
__consuming is allowed in class methods, though it makes little
sense to put it there.
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.
The number was limited to 3 attributes for some reason. Now a SILFunction may have up to 2^16 such attributes, which should be enough for a while ;-)
Fixes rdar://problem/34026325
Remove the cast consumption kind from all unconditional casts. It
doesn't make sense for unconditional casts, complicates SIL ownership,
and wasn't fully supported for all variants. Copies should be
explicit.
Consider a class hierarchy like the following:
class Base {
func m1() {}
func m2() {}
}
class Derived : Base {
override func m2() {}
func m3() {}
}
The SIL vtable for 'Derived' now records that the entry for m1
is inherited, the entry for m2 is an override, and the entry
for m3 is a new entry:
sil_vtable Derived {
#Base.m1!1: (Base) -> () -> () : _T01a4BaseC2m1yyF [inherited]
#Base.m2!1: (Base) -> () -> () : _T01a7DerivedC2m2yyF [override]
#Derived.m3!1: (Derived) -> () -> () : _T01a7DerivedC2m3yyF
}
This additional information will allow IRGen to emit the vtable
for Derived resiliently, without referencing the symbol for
the inherited method m1() directly.
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
Inheritance of a protocol from JavaScriptCore's JSExport protocol is
used to indicate that the methods and properties of that protocol
should be exported to JavaScript. The actual check to determine
whether a protocol (directly) inherits JSExport is performed via the
Objective-C runtime. Note that the presence of JSExport in the
protocol hierarchy is not sufficient; the protocol must directly
inherit JSExport.
Swift warns about redundant conformance requirements and eliminates
them from the requirement signature (and, therefore, the Objective-C
metadata). This behavior is incorrect for JSExport, because the
conformance is actually needed for this API to work properly.
Recognize a protocol's inheritance JSExport specifically (by
name) when computing the requirement signature of the protocol. When
we find such a redundancy, suppress the "redundant conformance
constraint" diagnostic and add a new (hidden) attribute
@_restatedObjCConformance(proto). The attribute is used only by Objective-C
protocol metadata emission to ensure that we get the expected metadata
in the Objective-C runtime.
Fixes rdar://problem/32674145.
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
Special DeclNames represent names that do not have an identifier in the
surface language. This implies serializing the information about whether
a name is special together with its identifier (if it is not special)
in both the module file and the swift lookup table.
Using these in declaration position has been deprecated and
removed in Swift 3. These attributes were not being parsed and
contained deadweight diagnostics that should have been moved
when these attributes became type attributes.
In anticipation of future attributes, and perhaps the ability to
declare lvalues with specifiers other than 'let' and 'var', expand
the "isLet" bit into a more general "specifier" field.
This is accomplished by recognizing this specific situation and
replacing the 'objc' attribute with a hidden '_objcRuntimeName'
attribute. This /only/ applies to classes that are themselves
non-generic (including any enclosing generic context) but that have
generic ancestry, and thus cannot be exposed directly to Objective-C.
This commit also eliminates '@NSKeyedArchiverClassName'. It was
decided that the distinction between '@NSKeyedArchiverClassName' and
'@objc' was too subtle to be worth explaining to developers, and that
any case where you'd use '@NSKeyedArchiverClassName' was already a
place where the ObjC name wasn't visible at compile time.
This commit does not update diagnostics to reflect this change; we're
going to change them anyway.
rdar://problem/32414557
Layout for an enum depends very intimately on its cases---both their
existence and what their payload types are. That means there's no way
to "partly" recover from failure to deserialize an individual case's
payload type, the way we can partly recover from failing to
deserialize an initializer in a class. Add deserialization recovery
to enums by validating all of their payload types up front, and
dropping the enum if we can't import all of the cases.
This is the first time where we're trying to do deserialization
recovery for a /type/, and that could have many more ripple effects
than for a var/func/subscript/init. A better answer here might be to
still import the enum but mark it as unavailable, but in that case
we'd have to make sure to propagate that unavailability to anything
that /used/ the enum as well. (In Swift, availability is checked based
on use of the name, so if someone manages to refer to an enum using
inferred types we'd be in trouble.)
There is one case here that's not covered: if an enum case has a
payload that references a type declaration nested within the enum, but
then that nested type /itself/ can't be loaded for some reason, we
have no way to check that up front, because we can't even try to load
the nested type without loading its parent DeclContext (the enum). I
can't think of an easy solution for this right now.
(In the future, we'll be able to support dropping a single case for
resilient enums. But we're not there right now.)
rdar://problem/31920901
Previously we recorded the canonical type of the declaration and made
sure we could deserialize that, but that's a lot of extra work
building up intermediate types that we mostly don't need. Instead,
record smaller types that represent the possible points of failure---
right now, just the nominal types that are referenced by the value
(function, variable/constant, subscript, or initializer). I chose to
use types instead of declarations here because types can potentially
encode more complicated constraints later (such as generic types
checking that their arguments still conform).
This gains us back 20% of type-checking time on a compile-time
microbenchmark: `let _ = [1, 2]`. I expect the effect is less dramatic
the more expressions you have, since we only need to deserialize
things once.
