The initialization of an instance property that has an attached
property delegate involves the initial value written on the property
declaration, the implicit memberwise initializer, and the default
arguments to the implicit memberwise initializer. Implement SILGen
support for each of these cases.
There is a small semantic change to the creation of the implicit
memberwise initializer due to SE-0242 (default arguments for the
memberwise initializer). Specifically, the memberwise initializer will
use the original property type for the parameter to memberwise
initializer when either of the following is true:
- The corresponding property has an initial value specified with the
`=` syntax, e.g., `@Lazy var i = 17`, or
- The corresponding property has no initial value, but the property
delegate type has an `init(initialValue:)`.
The specific case that changed is when a property has an initial value
specified as a direct initialization of the delegate *and* the
property delegate type has an `init(initialValue:)`, e.g.,
```swift
struct X {
@Lazy(closure: { ... })
var i: Int
}
```
Previously, this would have synthesized an initializer:
```swift
init(i: Int = ???) { ... }
```
However, there is no way for the initialization specified within the
declaration of i to be expressed via the default argument. Now, it
synthesizes an initializer:
```swift
init(i: Lazy<Int> = Lazy(closure: { ... }))
```
The initializer associated with a lazy property should not be executed
directly, because it is subsumed by code synthesized into the
getter. Generalize the terminology here so we can re-use this path for
property delegate initialization.
Introduce stored property default argument kind
Fix indent
Assign nil to optionals with no initializers
Don't emit generator for stored property default arg
Fix problem with rebase
Indentation
Serialize stored property default arg text
Fix some tests
Add missing constructor in test
Print stored property's initializer expression
cleanups
preserve switch
complete_constructor
formatting
fix conflict
Each call site will soon have to think about passing in the right expansion
instead of just assuming the default will be OK. But there are now only a
few call sites left, because most have been refactored to use convenience
APIs that pass in the right resilience expansion already.
A SIL function that's initially only emitted as a declaration may later
be prepared for definition. When this happens, set up a profiler for the
definition.
This makes code coverage visible for private methods (the frontend
follows a declare-then-define pattern for these).
rdar://47759243
This undoes some of Joe's work in 8665342 to add a guarantee: if an
@objc convenience initializer only calls other @objc initializers that
eventually call a designated initializer, it won't result in an extra
allocation. While Objective-C /allows/ returning a different object
from an initializer than the allocation you were given, doing so
doesn't play well with some very hairy implementation details of
compiled nib files (or NSCoding archives with cyclic references in
general).
This guarantee only applies to
(1) calling `self.init`
(2) where the delegated-to initializer is @objc
because convenience initializers must do dynamic dispatch when they
delegate, and Swift only stores allocating entry points for
initializers in a class's vtable. To dynamically find an initializing
entry point, ObjC dispatch must be used instead.
(It's worth noting that this patch does NOT check that the calling
initializer is a convenience initializer when deciding whether to use
ObjC dispatch for `self.init`. If we ever add peer delegation to
designated initializers, which is totally a valid feature, that should
use static dispatch and therefore should not go through objc_msgSend.)
This change doesn't /always/ result in fewer allocations; if the
delegated-to initializer ends up returning a different object after
all, the original allocation was wasted. Objective-C has the same
problem (one of the reasons why factory methods exist for things like
NSNumber and NSArray).
We do still get most of the benefits of Joe's original change. In
particular, vtables only ever contain allocating initializer entry
points, never the initializing ones, and never /both/ (which was a
thing that could happen with 'required' before).
rdar://problem/46823518
The terrible hack in SILGen here is to not visit opaque accessors of
global variables if they were added to the decls list by the parser.
That needs to include the setter for an observed global variable,
which we apparently did not have tests of.
rdar://46472759
Instead of passing in a DeclContext, which we don't have when emitting a keypath
accessor, pass in a ModuleDecl and ResilienceExpansion.
Keypaths now work well enough in inlinable contexts that we can check in an
end-to-end resilience test.
Previously, the stdlib provided:
- getters for AnyKeyPath and PartialKeyPath, which have remained;
- a getter for KeyPath, which still exists alongside a new read
coroutine; and
- a pair of owned mutable addressors that provided modify-like behavior
for WritableKeyPath and ReferenceWritableKeyPath, which have been
replaced with modify coroutines and augmented with dedicated setters.
SILGen then uses the most efficient accessor available for the access
it's been asked to do: for example, if it's been asked to produce a
borrowed r-value, it uses the read accessor.
Providing a broad spectrum of accessor functions here seems acceptable
because the code-size hit is fixed-size: we don't need to generate
extra code per storage declaration to support more alternatives for
key paths.
Note that this is just the compiler ABI; the implementation is still
basically what it was. That means the implementation of the setters
and the read accessor is pretty far from optimal. But we can improve
the implementation later; we can't improve the ABI.
The coroutine accessors have to be implemented in C++ and used via
hand-rolled declarations in SILGen because it's not currently possible
to declare independent coroutine accessors in Swift.
This is not strictly necessary since we are going to be exiting the program, but
the ownership verifier thinks that the error is leaked otherwise. By using the
end_lifetime we avoid having a small increase in code-size since it is a no-op
after ownership is removed.
rdar://29791263
The `Stmt` and `Expr` classes had both `dump` and `print` methods that behaved similarly, making it unclear what each method was for. Following a conversation in https://forums.swift.org/t/unifying-printing-logic-in-astdumper/15995/6 the `dump` methods will be used to print the S-Expression-like ASTs, and the `print` methods will be used to print the more textual ASTPrinter-based representations. The `Stmt` and `Expr` classes seem to be where this distinction was more ambiguous. These changes should fix that ambiguity.
A few other classes also have `print` methods used to print straightforward representations that are neither the S-Expressions nor ASTPrinters. These were left as they are, as they don't cause the same ambiguity.
It should be noted that the ASTPrinter implementations themselves haven't yet been finished and aren't a part of these changes.
In general we'll want to investigate what we are and aren't SILGen-ing
for textual interfaces of resilient modules, but for fragile modules
we may as well generate everything we can for potential optimization
purposes.
No functionality change. Unfortunately we still need the flag in
SILModule itself because of the ability to create an empty SILModule
and parse SIL into it incrementally, which can happen before there's
a FileUnit to use as the associated DeclContext instead of a
CompilerInstance's main module.
This was only used by the integrated REPL, and is now a dead option.
The "StartElem" option for performTypeChecking is still used for
reading SIL files, which have AST and SIL blocks alternate.
This silences the instances of the warning from Visual Studio about not all
codepaths returning a value. This makes the output more readable and less
likely to lose useful warnings. NFC.
Most of this patch is just removing special cases for materializeForSet
or other fairly mechanical replacements. Unfortunately, the rest is
still a fairly big change, and not one that can be easily split apart
because of the quite reasonable reliance on metaprogramming throughout
the compiler. And, of course, there are a bunch of test updates that
have to be sync'ed with the actual change to code-generation.
This is SR-7134.
This makes it easier to grep for and eventually remove the
remaining usages.
It also allows you to write FunctionType::get({}, ...) to call the
ArrayRef overload empty parameter list, instead of picking the Type
overload and calling it with an empty Type() value.
While I"m at it, in a few places instead of renaming just clean up
usages where it was completely mechanical to do so.
- getAsDeclOrDeclExtensionContext -> getAsDecl
This is basically the same as a dyn_cast, so it should use a 'getAs'
name like TypeBase does.
- getAsNominalTypeOrNominalTypeExtensionContext -> getSelfNominalTypeDecl
- getAsClassOrClassExtensionContext -> getSelfClassDecl
- getAsEnumOrEnumExtensionContext -> getSelfEnumDecl
- getAsStructOrStructExtensionContext -> getSelfStructDecl
- getAsProtocolOrProtocolExtensionContext -> getSelfProtocolDecl
- getAsTypeOrTypeExtensionContext -> getSelfTypeDecl (private)
These do /not/ return some form of 'this'; instead, they get the
extended types when 'this' is an extension. They started off life with
'is' names, which makes sense, but changed to this at some point. The
names I went with match up with getSelfInterfaceType and
getSelfTypeInContext, even though strictly speaking they're closer to
what getDeclaredInterfaceType does. But it didn't seem right to claim
that an extension "declares" the ClassDecl here.
- getAsProtocolExtensionContext -> getExtendedProtocolDecl
Like the above, this didn't return the ExtensionDecl; it returned its
extended type.
This entire commit is a mechanical change: find-and-replace, followed
by manual reformatted but no code changes.
