I forgot to update this case from an implementation that doesn't work. Factor out the common implementation with the other cases and use it in both places. This enables the libraries and tests to build and run with -DSWIFT_RUNTIME_CHECKS=OFF.
Swift SVN r12609
Now that we unique equivalent archetypes and lower interface types from the AST, we can convert IRGen over to using the interface types of the SILFunctionType when expanding out an LLVM function signature.
Swift SVN r12566
We shouldn't store to one size and load as another, and shouldn't need
to handle things like truncation and extension of numeric types, either.
Swift SVN r12530
Previously we coerced only struct return types, but we actually need to
be able to coerce scalar types as well, e.g. differing pointer types
when the ABI type differs from the type used in the body of the
function.
Swift SVN r12527
Rename TypeInfo::isSingleRetainablePointer to TypeInfo::isSingleSwiftRetainablePointer, and add an isSingleUnknownRetainablePointer entry point to ask whether a type has any single-refcounted representation, native or not. Use that to provide the same nullable-pointer and pointer-with-tag optimizations for copying and destroying enums with ObjC payloads as we do for Swift class payloads.
Swift SVN r12410
In the long term we want more detailed configurability of runtime checks, but for our short-term performance work we just want a blanket on/off switch. Add a StripRuntimeChecks SIL pass that, as a start, converts invocations of checked overflow builtins to the equivalent unchecked builtins and kills cond_fails. Expose it through the compiler with a -disable-all-runtime-checks switch.
NB: I haven't tested building the stdlib or running the tests with the switch thrown yet.
Swift SVN r12379
A type may be treated as a by-value return in SIL but still be lowered to an indirect return in IR if it's big enough, so handle this case in the partial application forwarder. Fixes <rdar://problem/15826328>.
Swift SVN r12351
We want to be able to share this both for signature type generation and
Objective-C type encoding.
A separate implementation file will follow when I expand the
functionality for more than just imported struct types.
Swift SVN r12137
IRGen type conversion is invariant with respect to archetypes with the same set of constraints, so instead of redundantly generating a TypeInfo object and IR type for Optional<T> for every T everywhere, key TypeInfo objects using an "exemplar type" that we form using a folding set to collapse together archetypes with the same class-ness, superclass constraint, and protocol constraints.
This is a nice memory and IR size optimization, but will be essential for correctness when lowering interface types, because there is no unique context to ground a dependent type, and we need to lower the same generic parameter with the same context requirements to the same type whenever we instantiate it in order for the IR to type-check.
In this revision, we profile the nested archetypes of each recursively, which I neglected to take into account originally in r12112, causing failures when archetypes that differed by associated type constraints were incorrectly collapsed.
Swift SVN r12116
Teach SILGen to emit a -dealloc method that runs user code, destroys
instance variables, and then calls up to the superclass dealloc. Teach
IRGen to deal with Objective-C destructor methods and add -dealloc to
the instance method table.
There are a few things still wrong here: we're emitting both a Swift
destructor and -dealloc, even though only one of them should ever
actually be used. Additionally, instance variables shouldn't be
destroyed in -dealloc, but in .cxx_destruct, so they persist until the
last of the -dealloc methods is invoked.
Swift SVN r12115
IRGen type conversion is invariant with respect to archetypes with the same set of constraints, so instead of redundantly generating a TypeInfo object and IR type for Optional<T> for every T everywhere, key TypeInfo objects using an "exemplar type" that we form using a folding set to collapse together archetypes with the same class-ness, superclass constraint, and protocol constraints.
This is a nice memory and IR size optimization, but will be essential for correctness when lowering interface types, because there is no unique context to ground a dependent type, and we need to lower the same generic parameter with the same context requirements to the same type whenever we instantiate it in order for the IR to type-check.
Swift SVN r12112
In general, this forces SILGen and IRGen code that's grabbing
a declaration to state whether it's doing so to define it.
Change SIL serialization to serialize the linkage of functions
and global variables, which means also serializing declarations.
Change the deserializer to use this stored linkage, even when
only deserializing a declaration, and to call a callback to
inform the client that it has deserialized a new entity.
Take advantage of that callback in the linking pass to alter
the deserialized linkage as appropriate for the fact that we
imported the declaration. This computation should really take
advantage of the relationship between modules, but currently
it does not.
Swift SVN r12090
When partial_applying a generic we still need to handle trivial abstraction changes such as bitcasting pointers to archetypes at the IR level. Along with the previous commit this fixes <rdar://problem/15597271>.
Swift SVN r11621
We should be able to cut out another layer of IRGen grime now.
This does XFAIL one test, test/Prototypes/TextFormatting.swift, which fails because of a weird archetype ordering in a nested substitution list. This should get sorted out by switching to interface types, so I'm going to let it go until then.
Swift SVN r11618
Use the 'thin' bit set by SIL to decide whether a metatype lowers to an empty type or not. In GenPoly we still need to accommodate unlowered metatypes to keep protocol witnesses limping along; hopefully that code can be killed soon. With this change we now lower @cc(witness_method) consistently for static methods.
Swift SVN r11535
This change updates signature generation as well as IR generation for
calls and returns so that the correct ABI types are generated for the
results of @objc functions.
Swift SVN r11527
Add a new SourceKind for PolymorphicConvention, 'WitnessSelf', which always introduces a final 'Self' metadata argument to the signature and uses it to fulfill all of the generic parameters of the Self type, regardless of the SIL-level polymorphic signature of the function.
Swift SVN r11467
Derive the appropriate ExtraData for a SILFunctionType from its thinness and calling convention. Consider @!thin @cc(witness_method) as having ExtraData::Metatype. This should eliminate all of the unspoken gentleperson's agreements that let thin and witness functions survive IRGen currently when we can turn on SIL witness tables.
Swift SVN r11446
Reapply r11184 with fixes for makefile builds.
Use CodeGenABITypes to determine which return values should be indirect
in @objc methods.
Swift SVN r11226
This lowers to a call to a to-be-written swift_once runtime function and will be used for lazy global initialization. Having this be a builtin seemed appropriate to me given that:
- references to it will be implicitly emitted by SILGen for global initializers.
- there are restrictions on its correct use that are currently impossible to express in the language outside of the stdlib.
Swift SVN r10508
Add new builtins(by generalizing, renaming, and extending the builtins used for compile time integer literal checking). These new builtins truncate integers and check for overflow/truncation errors at runtime. Use these for FixedPoint conversion constructors.
Fix a routine in stdlib's String implementation and a test that relied on bitwise behavior of the constructors (and triggered overflows).
TODO:
- Teach CCP about these to get static checking.
- Add special builtins for same size signed <-> unsigned conversions.
Swift SVN r10432
Start using null-page values as extra inhabitants when laying out single-payload enums that contain class pointers as their payload type. Don't use inhabitants that set the lowest bit, to avoid trampling potential ObjC tagged pointer representations. This means that 'T?' for class type T now has a null pointer representation. Enums with multiple empty cases, as well as nested enums like 'T??', should now have optimal representations for class type T as well.
Note that we don't yet expose extra inhabitants for aggregates that contain heap object references, such as structs with class fields, Swift function types, or class-bounded existentials (even when the existential has no witness tables).
Swift SVN r10061
Introduces a new flag in SILLocation: InPrologue to mark instructions
that setup the stack and allocate storage for local variables/arguments.
Fixes rdar://problem/15290023: Breakpoint set on prologue - crash ensues.
Swift SVN r9686
(This only fails under -DSWIFT_OPTIMIZED=NO; most likely due to an llvm bug.)
We've decided that it's best to specialize each arithmetic builtin that could overflow, instead of calling a separate generic "staticReport" builtin and passing it enough info to produce the message. The main advantage of this approach is that it would be possible for the compiler to customize the message and better link it to the builtin that overflows. For example, the constants that participated in the computation could be printed. In addition, less code will be generated and the compiler could, in the future, automatically emit the overflow diagnostics/trap at runtime.
This patch introduces new versions of op_with_overflow swift builtins. Which are lowered to llvm.op_with_overflow builtins in IRGen after the static diagnostics. If the last argument to the builtins evaluates to true, the overflow is unintentional. CCP uses the builtins to diagnose the overflow detectable at compile time. FixedPoint is changed to rely on these in implementation of primitive arithmetic operations.
Swift SVN r9328
