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swift-mirror/stdlib/public/runtime/MetadataImpl.h
Mike Ash 29c350e813 [Runtime] Create an external generic metadata builder. 
Create a version of the metadata specialization code which is abstracted so that it can work in different contexts, such as building specialized metadata from dylibs on disk rather than from inside a running process.

The GenericMetadataBuilder class is templatized on a ReaderWriter. The ReaderWriter abstracts out everything that's different between in-process and external construction of this data. Instead of reading and writing pointers directly, the builder calls the ReaderWriter to resolve and write pointers. The ReaderWriter also handles symbol lookups and looking up other Swift types by name.

This is accompanied by a simple implementation of the ReaderWriter which works in-process. The abstracted calls to resolve and write pointers are implemented using standard pointer dereferencing.

A new SWIFT_DEBUG_VALIDATE_EXTERNAL_GENERIC_METADATA_BUILDER environment variable uses the in-process ReaderWriter to validate the builder by running it in parallel with the existing metadata builder code in the runtime. When enabled, the GenericMetadataBuilder is used to build a second copy of metadata built by the runtime, and the two are compared to ensure that they match. When this environment variable is not set, the new builder code is inactive.

The builder is incomplete, and this initial version only works on structs. Any unsupported type produces an error, and skips the validation.

rdar://116592420
2024-01-11 09:15:02 -05:00

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//===--- MetadataImpl.h - Metadata implementation routines ------*- C++ -*-===//
//
// This source file is part of the Swift.org open source project
//
// Copyright (c) 2014 - 2017 Apple Inc. and the Swift project authors
// Licensed under Apache License v2.0 with Runtime Library Exception
//
// See https://swift.org/LICENSE.txt for license information
// See https://swift.org/CONTRIBUTORS.txt for the list of Swift project authors
//
//===----------------------------------------------------------------------===//
//
// Declarations used to implement value witnesses for native C/C++ types.
//
// A box class defines some static members which describe the basic
// value-witness properties of a value:
//
// - NativeBox derives a box from a C++ type
// - SwiftRetainableBox is a box for Swift object pointers which uses
// swift_{retain,release}.
// - FunctionPointerBox is a box for function pointers.
// - ObjCRetainableBox is a box for Objective-C object pointers,
// using objc_{retain,release}.
// - UnknownObjectRetainableBox is a box for void* using
// swift_unknownObject{Retain,Release}.
// - AggregateBox<T...> is a box which uses swift layout rules to
// combine a number of different boxes.
//
// ValueWitnesses<T> takes a box class and defines all the necessary
// values and functions necessary to build a value witness table.
//
// ValueWitnessTableGenerator<T> takes an instance of ValueWitnesses
// and uses it to build a static member 'table', which can be used to
// constant-initialize a value witness table.
//
// ValueWitnessTable
//
//===----------------------------------------------------------------------===//
#ifndef SWIFT_RUNTIME_METADATAIMPL_H
#define SWIFT_RUNTIME_METADATAIMPL_H
#include "swift/Basic/MathUtils.h"
#include "swift/Runtime/Config.h"
#include "swift/Runtime/Metadata.h"
#include "swift/Runtime/HeapObject.h"
#if SWIFT_OBJC_INTEROP
#include "swift/Runtime/ObjCBridge.h"
#endif
#include "WeakReference.h"
#include "EnumImpl.h"
#include <cstring>
#include <new>
#include <type_traits>
namespace swift {
namespace metadataimpl {
// concept Box<typename T> {
// using type = T;
// static constexpr size_t size;
// static constexpr size_t alignment;
// static constexpr size_t stride;
// static constexpr bool isPOD;
// static constexpr bool isBitwiseTakable;
// static constexpr unsigned numExtraInhabitants;
// static void destroy(T *);
// static T *initializeWithCopy(T *dest, T *src);
// static T *initializeWithTake(T *dest, T *src);
// static T *assignWithCopy(T *dest, T *src);
// static T *assignWithTake(T *dest, T *src);
// // Only if numExtraInhabitants is non-zero:
// static void storeExtraInhabitantTag(T *dest, unsigned index);
// static unsigned getExtraInhabitantTag(const T *src);
// };
/// A box class implemented in terms of C/C++ primitive operations.
/// The type is assumed to be non-polymorphic and to have no extra
/// inhabitants.
///
/// The size/alignment/stride template arguments are for when we want
/// to override the language defaults for a type.
template <class T,
size_t Alignment = alignof(T),
size_t Size = sizeof(T),
size_t Stride = sizeof(T)>
struct NativeBox {
using type = T;
static constexpr size_t size = Size;
static constexpr size_t alignment = Alignment;
static constexpr size_t stride = Stride;
static constexpr size_t isPOD = std::is_pod<T>::value;
static constexpr bool isBitwiseTakable = isPOD;
static constexpr unsigned numExtraInhabitants = 0;
static constexpr bool hasLayoutString = false;
static void destroy(T *value) {
value->T::~T();
}
static T *initializeWithCopy(T *dest, T *src) {
return ::new (dest) T(*src);
}
static T *initializeWithTake(T *dest, T *src) {
T *result = ::new (dest) T(std::move(*src));
src->T::~T();
return result;
}
static T *assignWithCopy(T *dest, T *src) {
*dest = *src;
return dest;
}
static T *assignWithTake(T *dest, T *src) {
*dest = std::move(*src);
src->T::~T();
return dest;
}
private:
static T *next(T *ptr, size_t n = 1) {
return (T*)((char*)ptr + stride * n);
}
static T *prev(T *ptr, size_t n = 1) {
return (T*)((char*)ptr - stride * n);
}
};
/// A CRTP base class for defining boxes of retainable pointers.
template <class Impl, class T> struct RetainableBoxBase {
using type = T;
static constexpr size_t size = sizeof(T);
static constexpr size_t alignment = alignof(T);
static constexpr size_t stride = sizeof(T);
static constexpr bool isPOD = false;
static constexpr bool isBitwiseTakable = true;
#ifdef SWIFT_THREADING_NONE
static constexpr bool isAtomic = false;
#else
static constexpr bool isAtomic = true;
#endif
static constexpr bool hasLayoutString = false;
static void destroy(T *addr) {
Impl::release(*addr);
}
static T *initializeWithCopy(T *dest, T *src) {
*dest = Impl::retain(*src);
return dest;
}
static T *initializeWithTake(T *dest, T *src) {
*dest = *src;
return dest;
}
static T *assignWithCopy(T *dest, T *src) {
T oldValue = *dest;
*dest = Impl::retain(*src);
Impl::release(oldValue);
return dest;
}
static T *assignWithTake(T *dest, T *src) {
T oldValue = *dest;
*dest = *src;
Impl::release(oldValue);
return dest;
}
// Right now, all object pointers are brought down to the least
// common denominator for extra inhabitants, so that we don't have
// to worry about e.g. type substitution on an enum type
// fundamentally changing the layout.
static constexpr unsigned numExtraInhabitants =
swift_getHeapObjectExtraInhabitantCount();
static void storeExtraInhabitantTag(T *dest, unsigned tag) {
swift_storeHeapObjectExtraInhabitant((HeapObject**) dest, tag - 1);
}
static unsigned getExtraInhabitantTag(const T *src) {
return swift_getHeapObjectExtraInhabitantIndex((HeapObject* const *) src) +1;
}
};
/// A box implementation class for Swift object pointers.
struct SwiftRetainableBox :
RetainableBoxBase<SwiftRetainableBox, HeapObject*> {
static HeapObject *retain(HeapObject *obj) {
if (isAtomic) {
swift_retain(obj);
} else {
swift_nonatomic_retain(obj);
}
return obj;
}
static void release(HeapObject *obj) {
if (isAtomic) {
swift_release(obj);
} else {
swift_nonatomic_release(obj);
}
}
};
/// A box implementation class for Swift unowned object pointers.
struct SwiftUnownedRetainableBox :
RetainableBoxBase<SwiftUnownedRetainableBox, HeapObject*> {
static HeapObject *retain(HeapObject *obj) {
if (isAtomic) {
swift_unownedRetain(obj);
} else {
swift_nonatomic_unownedRetain(obj);
}
return obj;
}
static void release(HeapObject *obj) {
if (isAtomic) {
swift_unownedRelease(obj);
} else {
swift_nonatomic_unownedRelease(obj);
}
}
#if SWIFT_OBJC_INTEROP
// The implementation from RetainableBoxBase is valid when interop is
// disabled.
static constexpr unsigned numExtraInhabitants = 1;
static void storeExtraInhabitant(HeapObject **dest, unsigned index) {
assert(index == 1);
*dest = nullptr;
}
static unsigned getExtraInhabitantTag(const HeapObject * const *src) {
return (*src == nullptr ? 1 : 0);
}
#endif
};
/// CRTP base class for weak reference boxes.
template<typename Impl, typename T>
struct WeakRetainableBoxBase {
using type = T;
static constexpr size_t size = sizeof(type);
static constexpr size_t alignment = alignof(type);
static constexpr size_t stride = sizeof(type);
static constexpr bool isPOD = false;
static constexpr bool isBitwiseTakable = false;
static constexpr unsigned numExtraInhabitants = 0;
static constexpr bool hasLayoutString = false;
// The implementation must provide implementations of:
// static void destroy(T *);
// static T *initializeWithCopy(T *dest, T *src);
// static T *initializeWithTake(T *dest, T *src);
// static T *assignWithCopy(T *dest, T *src);
// static T *assignWithTake(T *dest, T *src);
};
/// A box implementation class for Swift weak object pointers.
struct SwiftWeakRetainableBox :
WeakRetainableBoxBase<SwiftWeakRetainableBox, WeakReference> {
static void destroy(WeakReference *ref) {
swift_weakDestroy(ref);
}
static WeakReference *initializeWithCopy(WeakReference *dest,
WeakReference *src) {
swift_weakCopyInit(dest, src);
return dest;
}
static WeakReference *initializeWithTake(WeakReference *dest,
WeakReference *src) {
swift_weakTakeInit(dest, src);
return dest;
}
static WeakReference *assignWithCopy(WeakReference *dest,
WeakReference *src) {
swift_weakCopyAssign(dest, src);
return dest;
}
static WeakReference *assignWithTake(WeakReference *dest,
WeakReference *src) {
swift_weakTakeAssign(dest, src);
return dest;
}
};
#if SWIFT_OBJC_INTEROP
/// A box implementation class for Objective-C object pointers.
struct ObjCRetainableBox : RetainableBoxBase<ObjCRetainableBox, void*> {
static constexpr unsigned numExtraInhabitants =
swift_getHeapObjectExtraInhabitantCount();
static void *retain(void *obj) {
return objc_retain((id)obj);
}
static void release(void *obj) {
objc_release((id)obj);
}
};
/// A box implementation class for unowned Objective-C object pointers.
struct ObjCUnownedRetainableBox
: WeakRetainableBoxBase<ObjCUnownedRetainableBox, UnownedReference> {
static constexpr unsigned numExtraInhabitants = 1;
static void storeExtraInhabitantTag(UnownedReference *dest, unsigned index) {
assert(index == 1);
dest->Value = nullptr;
}
static unsigned getExtraInhabitantTag(const UnownedReference *src) {
return (src->Value == nullptr ? 1 : 0);
}
static void destroy(UnownedReference *ref) {
swift_unknownObjectUnownedDestroy(ref);
}
static UnownedReference *initializeWithCopy(UnownedReference *dest,
UnownedReference *src) {
swift_unknownObjectUnownedCopyInit(dest, src);
return dest;
}
static UnownedReference *initializeWithTake(UnownedReference *dest,
UnownedReference *src) {
swift_unknownObjectUnownedTakeInit(dest, src);
return dest;
}
static UnownedReference *assignWithCopy(UnownedReference *dest,
UnownedReference *src) {
swift_unknownObjectUnownedCopyAssign(dest, src);
return dest;
}
static UnownedReference *assignWithTake(UnownedReference *dest,
UnownedReference *src) {
swift_unknownObjectUnownedTakeAssign(dest, src);
return dest;
}
};
/// A box implementation class for ObjC weak object pointers.
struct ObjCWeakRetainableBox :
WeakRetainableBoxBase<ObjCWeakRetainableBox, WeakReference> {
static void destroy(WeakReference *ref) {
swift_unknownObjectWeakDestroy(ref);
}
static WeakReference *initializeWithCopy(WeakReference *dest,
WeakReference *src) {
swift_unknownObjectWeakCopyInit(dest, src);
return dest;
}
static WeakReference *initializeWithTake(WeakReference *dest,
WeakReference *src) {
swift_unknownObjectWeakTakeInit(dest, src);
return dest;
}
static WeakReference *assignWithCopy(WeakReference *dest,
WeakReference *src) {
swift_unknownObjectWeakCopyAssign(dest, src);
return dest;
}
static WeakReference *assignWithTake(WeakReference *dest,
WeakReference *src) {
swift_unknownObjectWeakTakeAssign(dest, src);
return dest;
}
};
#endif
/// A box implementation class for unknown-retainable object pointers.
struct UnknownObjectRetainableBox
: RetainableBoxBase<UnknownObjectRetainableBox, void *> {
static void *retain(void *obj) {
#if SWIFT_OBJC_INTEROP
swift_unknownObjectRetain(obj);
return obj;
#else
if (isAtomic) {
swift_retain(static_cast<HeapObject *>(obj));
} else {
swift_nonatomic_retain(static_cast<HeapObject *>(obj));
}
return static_cast<HeapObject *>(obj);
#endif
}
static void release(void *obj) {
#if SWIFT_OBJC_INTEROP
swift_unknownObjectRelease(obj);
#else
if (isAtomic) {
swift_release(static_cast<HeapObject *>(obj));
} else {
swift_nonatomic_release(static_cast<HeapObject *>(obj));
}
#endif
}
};
/// A box implementation class for BridgeObject.
struct BridgeObjectBox :
RetainableBoxBase<BridgeObjectBox, void*> {
static void *retain(void *obj) {
return swift_bridgeObjectRetain(obj);
}
static void release(void *obj) {
swift_bridgeObjectRelease(obj);
}
};
/// A box implementation class for unmanaged, pointer-aligned pointers.
/// Metatype values have this layout.
struct PointerPointerBox : NativeBox<void**> {
// TODO: we can do a lot better than this: we don't need to mask off
// the ObjC reserved bits, and we have spare bits.
static constexpr unsigned numExtraInhabitants =
swift_getHeapObjectExtraInhabitantCount();
static void storeExtraInhabitantTag(void ***dest, unsigned tag) {
swift_storeHeapObjectExtraInhabitant((HeapObject**) dest, tag - 1);
}
static unsigned getExtraInhabitantTag(void ** const *src) {
return swift_getHeapObjectExtraInhabitantIndex((HeapObject* const *) src)+1;
}
};
/// A box implementation class for raw pointers.
///
/// Note that this is used for imported `void * _Nonnull`, which may include
/// reinterpret_cast-ed integers, so we only get NULL as an extra inhabitant.
struct RawPointerBox : NativeBox<void*> {
static constexpr unsigned numExtraInhabitants = 1;
static void storeExtraInhabitantTag(void **dest, unsigned tag) {
assert(tag == 1);
*dest = nullptr;
}
static unsigned getExtraInhabitantTag(void* const *src) {
return *src == nullptr ? 1 : 0;
}
};
/// A box implementation class for unmanaged function pointers.
/// @convention(thin) functions have this layout, as do the first elements of
/// Swift thick functions.
struct FunctionPointerBox : NativeBox<void*> {
static constexpr unsigned numExtraInhabitants =
swift_getFunctionPointerExtraInhabitantCount();
static void storeExtraInhabitantTag(void **dest, unsigned tag) {
swift_storeFunctionPointerExtraInhabitant(dest, tag - 1);
}
static unsigned getExtraInhabitantTag(void * const *src) {
return swift_getFunctionPointerExtraInhabitantIndex(src) + 1;
}
};
// A helper template for building an AggregateBox. The more natural
// way to do this would be to left-recurse, but we have to
// right-recurse because C++ only lets you pattern-match things off
// the beginning of a pack.
template <size_t StartOffset, class... EltBoxes>
struct AggregateBoxHelper;
// Base case: empty list.
template <size_t StartOffset>
struct AggregateBoxHelper<StartOffset> {
public:
static constexpr size_t endOffset = StartOffset;
static constexpr size_t alignment = 1;
static constexpr bool isPOD = true;
static constexpr bool isBitwiseTakable = true;
public:
#define COPY_OP(OP) \
static char *OP(char *dest, char *src) { \
return dest; \
}
COPY_OP(initializeWithCopy)
COPY_OP(initializeWithTake)
COPY_OP(assignWithCopy)
COPY_OP(assignWithTake)
#undef COPY_OP
static void destroy(char *addr) {}
};
// Recursive case: add an element to the start.
template <size_t StartOffset, class EltBox, class... NextBoxes>
struct AggregateBoxHelper<StartOffset, EltBox, NextBoxes...> {
private:
static constexpr size_t eltOffset =
roundUpToAlignment(StartOffset, EltBox::alignment);
static constexpr size_t startToEltOffset = (eltOffset - StartOffset);
static constexpr size_t nextOffset = eltOffset + EltBox::size;
using NextHelper = AggregateBoxHelper<nextOffset, NextBoxes...>;
public:
static constexpr size_t endOffset = NextHelper::endOffset;
static constexpr size_t alignment =
(NextHelper::alignment > EltBox::alignment
? NextHelper::alignment : EltBox::alignment);
static constexpr bool isPOD = EltBox::isPOD && NextHelper::isPOD;
static constexpr bool isBitwiseTakable =
EltBox::isBitwiseTakable && NextHelper::isBitwiseTakable;
private:
static constexpr size_t eltToNextOffset = (nextOffset - eltOffset);
static constexpr size_t startToNextOffset = (nextOffset - StartOffset);
public:
#define COPY_OP(OP) \
static char *OP(char *dest, char *src) { \
dest += startToEltOffset; \
src += startToEltOffset; \
dest = (char*) EltBox::OP((typename EltBox::type*) dest, \
(typename EltBox::type*) src); \
dest = NextHelper::OP(dest + eltToNextOffset, src + eltToNextOffset); \
return dest - startToNextOffset; \
}
COPY_OP(initializeWithCopy)
COPY_OP(initializeWithTake)
COPY_OP(assignWithCopy)
COPY_OP(assignWithTake)
#undef COPY_OP
static void destroy(char *addr) {
// We have no particular reason to destroy in either order.
addr += startToEltOffset;
EltBox::destroy((typename EltBox::type*) addr);
NextHelper::destroy(addr + eltToNextOffset);
}
};
/// A class which produces a tuple-like box (with Swift layout rules)
/// for a list of element boxes.
///
/// The aggregate box is monomorphic and has no extra inhabitants.
template <class... EltBoxes>
struct AggregateBox {
using type = char;
using Helper = AggregateBoxHelper<0, EltBoxes...>;
static constexpr size_t size = Helper::endOffset;
static constexpr size_t alignment = Helper::alignment;
static constexpr size_t rawStride = roundUpToAlignment(size, alignment);
static constexpr size_t stride = rawStride == 0 ? 1 : rawStride;
static constexpr bool isPOD = Helper::isPOD;
static constexpr bool isBitwiseTakable = Helper::isBitwiseTakable;
/// Don't collect extra inhabitants from the members by default.
static constexpr unsigned numExtraInhabitants = 0;
static void destroy(char *value) {
Helper::destroy(value);
}
static char *initializeWithCopy(char *dest, char *src) {
return Helper::initializeWithCopy(dest, src);
}
static char *initializeWithTake(char *dest, char *src) {
return Helper::initializeWithTake(dest, src);
}
static char *assignWithCopy(char *dest, char *src) {
return Helper::assignWithCopy(dest, src);
}
static char *assignWithTake(char *dest, char *src) {
return Helper::assignWithTake(dest, src);
}
};
/// A template for using the Swift allocation APIs with a known size
/// and alignment.
template <size_t Size, size_t Alignment>
struct SwiftAllocator {
static void *alloc() {
return swift_slowAlloc(Size, Alignment-1);
}
static void dealloc(void *addr) {
swift_slowDealloc(addr, Size, Alignment-1);
}
};
/// A CRTP class which provides basic implementations for a number of
/// value witnesses relating to buffers.
template <class Impl>
struct BufferValueWitnessesBase {};
/// How should a type be packed into a fixed-size buffer?
enum class FixedPacking {
Allocate,
OffsetZero
};
constexpr FixedPacking getFixedPacking(bool isBitwiseTakable, size_t size,
size_t alignment) {
return (canBeInline(isBitwiseTakable, size, alignment)
? FixedPacking::OffsetZero
: FixedPacking::Allocate);
}
/// A CRTP base class which provides default implementations of a
/// number of value witnesses.
template <class Impl, bool isBitwiseTakable, size_t Size, size_t Alignment,
FixedPacking Packing =
getFixedPacking(isBitwiseTakable, Size, Alignment)>
struct BufferValueWitnesses;
/// An implementation of ValueBase suitable for classes that can be
/// allocated inline.
template <class Impl, bool isBitwiseTakable, size_t Size, size_t Alignment>
struct BufferValueWitnesses<Impl, isBitwiseTakable, Size, Alignment,
FixedPacking::OffsetZero>
: BufferValueWitnessesBase<Impl> {
static constexpr bool isInline = true;
static OpaqueValue *initializeBufferWithCopyOfBuffer(ValueBuffer *dest,
ValueBuffer *src,
const Metadata *self) {
return Impl::initializeWithCopy(reinterpret_cast<OpaqueValue *>(dest),
reinterpret_cast<OpaqueValue *>(src), self);
}
};
/// An implementation of BufferValueWitnesses suitable for types that
/// cannot be allocated inline.
template <class Impl, bool isBitwiseTakable, size_t Size, size_t Alignment>
struct BufferValueWitnesses<Impl, isBitwiseTakable, Size, Alignment,
FixedPacking::Allocate>
: BufferValueWitnessesBase<Impl> {
static constexpr bool isInline = false;
static OpaqueValue *initializeBufferWithCopyOfBuffer(ValueBuffer *dest,
ValueBuffer *src,
const Metadata *self) {
auto wtable = self->getValueWitnesses();
auto reference = src->PrivateData[0];
dest->PrivateData[0] = reference;
swift_retain(reinterpret_cast<HeapObject *>(reference));
// Project the address of the value in the buffer.
unsigned alignMask = wtable->getAlignmentMask();
// Compute the byte offset of the object in the box.
unsigned byteOffset = (sizeof(HeapObject) + alignMask) & ~alignMask;
auto *bytePtr = reinterpret_cast<char *>(reference);
return reinterpret_cast<OpaqueValue *>(bytePtr + byteOffset);
}
};
/// A class which provides BufferValueWitnesses for types that are not
/// fixed in size.
template <class Impl, bool IsKnownAllocated>
struct NonFixedBufferValueWitnesses : BufferValueWitnessesBase<Impl> {
static OpaqueValue *initializeBufferWithCopyOfBuffer(ValueBuffer *dest,
ValueBuffer *src,
const Metadata *self) {
auto vwtable = self->getValueWitnesses();
(void)vwtable;
if (!IsKnownAllocated && vwtable->isValueInline()) {
return Impl::initializeWithCopy(reinterpret_cast<OpaqueValue*>(dest),
reinterpret_cast<OpaqueValue*>(src),
self);
} else {
auto reference = src->PrivateData[0];
dest->PrivateData[0] = reference;
swift_retain(reinterpret_cast<HeapObject*>(reference));
// Project the address of the value in the buffer.
unsigned alignMask = vwtable->getAlignmentMask();
// Compute the byte offset of the object in the box.
unsigned byteOffset = (sizeof(HeapObject) + alignMask) & ~alignMask;
auto *bytePtr = reinterpret_cast<char *>(reference);
return reinterpret_cast<OpaqueValue *>(bytePtr + byteOffset);
}
}
};
/// Provides implementations for
/// getEnumTagSinglePayload/storeEnumTagSinglePayload.
template <class Impl, bool isBitwiseTakable, size_t Size, size_t Alignment,
bool hasExtraInhabitants>
struct FixedSizeBufferValueWitnesses;
/// A fixed size buffer value witness that can rely on the presence of the extra
/// inhabitant functions.
template <class Impl, bool isBitwiseTakable, size_t Size, size_t Alignment>
struct FixedSizeBufferValueWitnesses<Impl, isBitwiseTakable, Size, Alignment,
true /*hasExtraInhabitants*/>
: BufferValueWitnesses<Impl, isBitwiseTakable, Size, Alignment> {
static unsigned getEnumTagSinglePayload(const OpaqueValue *enumAddr,
unsigned numEmptyCases,
const Metadata *self) {
return getEnumTagSinglePayloadImpl(enumAddr, numEmptyCases, self, Size,
Impl::extraInhabitantCount,
Impl::getExtraInhabitantTag);
}
static void storeEnumTagSinglePayload(OpaqueValue *enumAddr,
unsigned whichCase,
unsigned numEmptyCases,
const Metadata *self) {
return storeEnumTagSinglePayloadImpl(enumAddr, whichCase, numEmptyCases,
self, Size, Impl::extraInhabitantCount,
Impl::storeExtraInhabitantTag);
}
};
/// A fixed size buffer value witness that cannot rely on the presence of the
/// extra inhabitant functions.
template <class Impl, bool isBitwiseTakable, size_t Size, size_t Alignment>
struct FixedSizeBufferValueWitnesses<Impl, isBitwiseTakable, Size, Alignment,
false /*hasExtraInhabitants*/>
: BufferValueWitnesses<Impl, isBitwiseTakable, Size, Alignment> {
static unsigned getEnumTagSinglePayload(const OpaqueValue *enumAddr,
unsigned numEmptyCases,
const Metadata *self) {
return getEnumTagSinglePayloadImpl(enumAddr, numEmptyCases, self, Size, 0,
nullptr);
}
static void storeEnumTagSinglePayload(OpaqueValue *enumAddr,
unsigned whichCase,
unsigned numEmptyCases,
const Metadata *self) {
return storeEnumTagSinglePayloadImpl(enumAddr, whichCase, numEmptyCases,
self, Size, 0, nullptr);
}
};
static constexpr bool hasExtraInhabitants(unsigned numExtraInhabitants) {
return numExtraInhabitants != 0;
}
/// A class which provides default implementations of various value
/// witnesses based on a box's value operations.
///
/// The box type has to provide a numExtraInhabitants member, but as
/// long as it's zero, the rest is fine.
template <class Box>
struct ValueWitnesses
: FixedSizeBufferValueWitnesses<
ValueWitnesses<Box>, Box::isBitwiseTakable, Box::size, Box::alignment,
hasExtraInhabitants(Box::numExtraInhabitants)> {
using Base = FixedSizeBufferValueWitnesses<
ValueWitnesses<Box>, Box::isBitwiseTakable, Box::size, Box::alignment,
hasExtraInhabitants(Box::numExtraInhabitants)>;
static constexpr size_t size = Box::size;
static constexpr size_t stride = Box::stride;
static constexpr size_t alignment = Box::alignment;
static constexpr bool isPOD = Box::isPOD;
static constexpr bool isBitwiseTakable = Box::isBitwiseTakable;
static constexpr unsigned extraInhabitantCount = Box::numExtraInhabitants;
static constexpr bool hasExtraInhabitants = (extraInhabitantCount != 0);
static constexpr ValueWitnessFlags flags =
ValueWitnessFlags().withAlignmentMask(alignment - 1)
.withInlineStorage(Base::isInline && isBitwiseTakable)
.withPOD(isPOD)
.withBitwiseTakable(isBitwiseTakable);
static constexpr bool hasLayoutString = Box::hasLayoutString;
static void destroy(OpaqueValue *value, const Metadata *self) {
return Box::destroy((typename Box::type*) value);
}
static OpaqueValue *initializeWithCopy(OpaqueValue *dest, OpaqueValue *src,
const Metadata *self) {
return (OpaqueValue*) Box::initializeWithCopy((typename Box::type*) dest,
(typename Box::type*) src);
}
static OpaqueValue *initializeWithTake(OpaqueValue *dest, OpaqueValue *src,
const Metadata *self) {
return (OpaqueValue*) Box::initializeWithTake((typename Box::type*) dest,
(typename Box::type*) src);
}
static OpaqueValue *assignWithCopy(OpaqueValue *dest, OpaqueValue *src,
const Metadata *self) {
return (OpaqueValue*) Box::assignWithCopy((typename Box::type*) dest,
(typename Box::type*) src);
}
static OpaqueValue *assignWithTake(OpaqueValue *dest, OpaqueValue *src,
const Metadata *self) {
return (OpaqueValue*) Box::assignWithTake((typename Box::type*) dest,
(typename Box::type*) src);
}
// These should not get instantiated if the type doesn't have extra
// inhabitants.
SWIFT_CC(swift)
static void storeExtraInhabitantTag(OpaqueValue *dest, unsigned tag,
unsigned xiCount, const Metadata *self) {
Box::storeExtraInhabitantTag((typename Box::type*) dest, tag);
}
SWIFT_CC(swift)
static unsigned getExtraInhabitantTag(const OpaqueValue *src,
unsigned xiCount,
const Metadata *self) {
return Box::getExtraInhabitantTag((typename Box::type const *) src);
}
};
/// A class which provides basic implementations of various function
/// value witnesses based on a type that is not fixed in size.
///
/// The 'Box' concept here is slightly different from the one for
/// fixed-size types: it does not need to provide size/alignment/isPOD
/// members, and its functions all take an extra 'const Metadata *self'
/// argument.
///
/// \tparam IsKnownAllocated - whether the type is known to not fit in
/// a fixed-size buffer
template <class Box, bool IsKnownAllocated>
struct NonFixedValueWitnesses :
NonFixedBufferValueWitnesses<NonFixedValueWitnesses<Box, IsKnownAllocated>,
IsKnownAllocated>
{
static constexpr unsigned numExtraInhabitants = Box::numExtraInhabitants;
static constexpr bool hasExtraInhabitants = (numExtraInhabitants != 0);
static void destroy(OpaqueValue *value, const Metadata *self) {
return Box::destroy((typename Box::type*) value, self);
}
static OpaqueValue *initializeWithCopy(OpaqueValue *dest, OpaqueValue *src,
const Metadata *self) {
return (OpaqueValue*) Box::initializeWithCopy((typename Box::type*) dest,
(typename Box::type*) src,
self);
}
static OpaqueValue *initializeWithTake(OpaqueValue *dest, OpaqueValue *src,
const Metadata *self) {
return (OpaqueValue*) Box::initializeWithTake((typename Box::type*) dest,
(typename Box::type*) src,
self);
}
static OpaqueValue *assignWithCopy(OpaqueValue *dest, OpaqueValue *src,
const Metadata *self) {
return (OpaqueValue*) Box::assignWithCopy((typename Box::type*) dest,
(typename Box::type*) src,
self);
}
static OpaqueValue *assignWithTake(OpaqueValue *dest, OpaqueValue *src,
const Metadata *self) {
return (OpaqueValue*) Box::assignWithTake((typename Box::type*) dest,
(typename Box::type*) src,
self);
}
static unsigned getEnumTagSinglePayload(const OpaqueValue *enumAddr,
unsigned numEmptyCases,
const Metadata *self) {
auto *payloadWitnesses = self->getValueWitnesses();
auto size = payloadWitnesses->getSize();
auto numExtraInhabitants = payloadWitnesses->getNumExtraInhabitants();
return getEnumTagSinglePayloadImpl(enumAddr, numEmptyCases, self, size,
numExtraInhabitants,
getExtraInhabitantTag);
}
static void storeEnumTagSinglePayload(OpaqueValue *enumAddr,
unsigned whichCase,
unsigned numEmptyCases,
const Metadata *self) {
auto *payloadWitnesses = self->getValueWitnesses();
auto size = payloadWitnesses->getSize();
auto numExtraInhabitants = payloadWitnesses->getNumExtraInhabitants();
storeEnumTagSinglePayloadImpl(enumAddr, whichCase, numEmptyCases, self,
size, numExtraInhabitants,
storeExtraInhabitantTag);
}
// These should not get instantiated if the type doesn't have extra
// inhabitants.
SWIFT_CC(swift)
static void storeExtraInhabitantTag(OpaqueValue *dest, unsigned tag,
unsigned xiCount, const Metadata *self) {
Box::storeExtraInhabitantTag((typename Box::type*) dest, tag);
}
SWIFT_CC(swift)
static unsigned getExtraInhabitantTag(const OpaqueValue *src,
unsigned xiCount,
const Metadata *self) {
return Box::getExtraInhabitantTag((typename Box::type const *) src);
}
};
/// A class which defines a ValueWitnessTable.
template <class Witnesses>
struct ValueWitnessTableGenerator {
static constexpr const ValueWitnessTable table = {
#define WANT_ONLY_REQUIRED_VALUE_WITNESSES
#define VALUE_WITNESS(LOWER_ID, UPPER_ID) Witnesses::LOWER_ID,
#include "swift/ABI/ValueWitness.def"
};
};
/// A convenient way to get the value witness table for a box class.
template <class Box>
using ValueWitnessTableForBox = ValueWitnessTableGenerator<ValueWitnesses<Box>>;
} // end namespace metadataimpl
} // end namespace swift
#endif /* SWIFT_RUNTIME_METADATAIMPL_H */
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