refactor(templates): refactor FAny to a non-template class
This commit is contained in:
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6b42dbdc05
commit
a8e1852b34
@ -624,24 +624,6 @@ void TestAny()
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TempZ = FTracker();
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}
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{
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always_check(GetTypeHash(FAny(114)) == GetTypeHash(FAny(114)));
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always_check(GetTypeHash(FAny(114)) != GetTypeHash(FAny(514)));
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}
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{
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FAny TempA = Invalid;
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FAny TempB = static_cast<int16>(16);
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FAny TempC = static_cast<int32>(16);
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FAny TempD = static_cast<int32>(32);
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always_check(TempA == TempA);
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always_check(TempA != TempB);
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always_check(TempB != TempC);
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always_check(TempB != TempC);
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always_check(TempD >= TempC);
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always_check(TempA <=> TempB == partial_ordering::unordered);
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}
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}
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void TestTuple()
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@ -13,122 +13,67 @@ NAMESPACE_REDCRAFT_BEGIN
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NAMESPACE_MODULE_BEGIN(Redcraft)
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NAMESPACE_MODULE_BEGIN(Utility)
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// TAny's CustomStorage concept, see FAnyDefaultStorage
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template <typename T>
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concept CAnyCustomStorage = CDefaultConstructible<T>
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&& !CCopyConstructible<T> && !CMoveConstructible<T>
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&& !CCopyAssignable<T> && !CMoveAssignable<T>
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&& CDestructible<T>
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&& CSameAs<decltype(T::InlineSize), const size_t>
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&& CSameAs<decltype(T::InlineAlignment), const size_t>
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&& requires(const T& A)
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{
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{ A.InlineAllocation() } -> CSameAs<const void*>;
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{ A.HeapAllocation() } -> CSameAs<void*>;
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{ A.TypeInfo() } -> CSameAs<uintptr>;
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}
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&& requires(T& A)
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{
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{ A.InlineAllocation() } -> CSameAs<void*>;
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{ A.HeapAllocation() } -> CSameAs<void*&>;
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{ A.TypeInfo() } -> CSameAs<uintptr&>;
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}
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&& requires(T& A, const T& B, T&& C)
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{
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A.CopyCustom(B);
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A.MoveCustom(MoveTemp(C));
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};
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// NOTE: In the STL, the assignment operation of the std::any type uses the copy-and-swap idiom
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// instead of directly calling the assignment operation of the contained value.
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// The purpose of this is as follows:
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// 1) the copy assignment might not exist.
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// 2) the typical case is that the objects are different.
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// 3) it is less exception-safe
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// But we don't follow the the copy-and-swap idiom, because we assume that no function throws an exception.
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// TAny's default storage structure
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struct alignas(16) FAnyDefaultStorage : FSingleton
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{
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// The built-in copy/move operators are disabled and CopyCustom/MoveCustom is used instead of them
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// You can add custom variables like this
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//Type Variable;
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//~ Begin CAnyCustomStorage Interface
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inline static constexpr size_t InlineSize = 64 - sizeof(uintptr);
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inline static constexpr size_t InlineAlignment = 16;
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constexpr void* InlineAllocation() { return &InlineAllocationImpl; }
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constexpr const void* InlineAllocation() const { return &InlineAllocationImpl; }
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constexpr void*& HeapAllocation() { return HeapAllocationImpl; }
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constexpr void* HeapAllocation() const { return HeapAllocationImpl; }
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constexpr uintptr& TypeInfo() { return TypeInfoImpl; }
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constexpr uintptr TypeInfo() const { return TypeInfoImpl; }
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constexpr void CopyCustom(const FAnyDefaultStorage& InValue) { /* Variable = InValue.Variable; */ } // You just need to copy the custom variables
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constexpr void MoveCustom( FAnyDefaultStorage&& InValue) { /* Variable = MoveTemp(InValue.Variable); */ } // You just need to move the custom variables
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//~ End CAnyCustomStorage Interface
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union
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{
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uint8 InlineAllocationImpl[InlineSize];
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void* HeapAllocationImpl;
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};
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uintptr TypeInfoImpl;
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};
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static_assert(CAnyCustomStorage<FAnyDefaultStorage>);
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// You can add custom storage area through CustomStorage, such as TFunction
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// It is not recommended to use this, FAny is recommended
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template <CAnyCustomStorage CustomStorage>
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class TAny
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class alignas(16) FAny
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{
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public:
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inline static constexpr size_t InlineSize = CustomStorage::InlineSize;
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inline static constexpr size_t InlineAlignment = CustomStorage::InlineAlignment;
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FORCEINLINE constexpr FAny() { Invalidate(); }
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constexpr TAny() { Storage.TypeInfo() = 0; }
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FORCEINLINE constexpr FAny(FInvalid) : FAny() { }
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constexpr TAny(FInvalid) : TAny() { }
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FORCEINLINE TAny(const TAny& InValue)
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FORCEINLINE FAny(const FAny& InValue)
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: TypeInfo(InValue.TypeInfo)
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{
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Storage.CopyCustom(InValue.Storage);
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Storage.TypeInfo() = InValue.Storage.TypeInfo();
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if (!IsValid()) return;
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switch (GetRepresentation())
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{
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case ERepresentation::Empty:
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break;
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case ERepresentation::Trivial:
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Memory::Memcpy(Storage.InlineAllocation(), InValue.Storage.InlineAllocation(), Storage.InlineSize);
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Memory::Memcpy(TrivialStorage.Internal, InValue.TrivialStorage.Internal);
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break;
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case ERepresentation::Small:
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GetTypeInfoImpl().CopyConstructImpl(GetAllocation(), InValue.GetAllocation());
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SmallStorage.RTTI = InValue.SmallStorage.RTTI;
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SmallStorage.RTTI->CopyConstruct(&SmallStorage.Internal, &InValue.SmallStorage.Internal);
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break;
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case ERepresentation::Big:
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Storage.HeapAllocation() = Memory::Malloc(GetTypeInfoImpl().TypeSize, GetTypeInfoImpl().TypeAlignment);
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GetTypeInfoImpl().CopyConstructImpl(GetAllocation(), InValue.GetAllocation());
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BigStorage.RTTI = InValue.BigStorage.RTTI;
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BigStorage.External = Memory::Malloc(BigStorage.RTTI->TypeSize, BigStorage.RTTI->TypeAlignment);
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BigStorage.RTTI->CopyConstruct(BigStorage.External, InValue.BigStorage.External);
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break;
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default: check_no_entry();
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}
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}
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FORCEINLINE TAny(TAny&& InValue)
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FORCEINLINE FAny(FAny&& InValue)
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: TypeInfo(InValue.TypeInfo)
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{
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Storage.MoveCustom(MoveTemp(InValue.Storage));
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Storage.TypeInfo() = InValue.Storage.TypeInfo();
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if (!IsValid()) return;
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switch (GetRepresentation())
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{
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case ERepresentation::Empty:
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break;
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case ERepresentation::Trivial:
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Memory::Memcpy(Storage.InlineAllocation(), InValue.Storage.InlineAllocation(), Storage.InlineSize);
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Memory::Memmove(TrivialStorage.Internal, InValue.TrivialStorage.Internal);
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break;
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case ERepresentation::Small:
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GetTypeInfoImpl().MoveConstructImpl(GetAllocation(), InValue.GetAllocation());
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SmallStorage.RTTI = InValue.SmallStorage.RTTI;
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SmallStorage.RTTI->MoveConstruct(&SmallStorage.Internal, &InValue.SmallStorage.Internal);
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break;
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case ERepresentation::Big:
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Storage.HeapAllocation() = InValue.Storage.HeapAllocation();
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InValue.Storage.TypeInfo() = 0;
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BigStorage.RTTI = InValue.BigStorage.RTTI;
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BigStorage.External = InValue.BigStorage.External;
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InValue.Invalidate();
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break;
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default: check_no_entry();
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}
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@ -136,28 +81,25 @@ public:
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template <typename T, typename... Ts> requires (CDestructible<TDecay<T>>
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&& CConstructibleFrom<TDecay<T>, Ts&&...>)
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FORCEINLINE explicit TAny(TInPlaceType<T>, Ts&&... Args)
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FORCEINLINE explicit FAny(TInPlaceType<T>, Ts&&... Args)
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{
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using SelectedType = TDecay<T>;
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EmplaceImpl<SelectedType>(Forward<Ts>(Args)...);
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EmplaceImpl<T>(Forward<Ts>(Args)...);
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}
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template <typename T> requires (!CBaseOf<TAny, TDecay<T>> && !CTInPlaceType<TDecay<T>>
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template <typename T> requires (!CBaseOf<FAny, TDecay<T>> && !CTInPlaceType<TDecay<T>>
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&& CDestructible<TDecay<T>> && CConstructibleFrom<TDecay<T>, T&&>)
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FORCEINLINE TAny(T&& InValue) : TAny(InPlaceType<TDecay<T>>, Forward<T>(InValue))
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FORCEINLINE FAny(T&& InValue) : FAny(InPlaceType<TDecay<T>>, Forward<T>(InValue))
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{ }
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FORCEINLINE ~TAny()
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FORCEINLINE ~FAny()
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{
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ResetImpl();
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Destroy();
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}
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FORCEINLINE TAny& operator=(const TAny& InValue)
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FORCEINLINE FAny& operator=(const FAny& InValue)
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{
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if (&InValue == this) return *this;
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Storage.CopyCustom(InValue.Storage);
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if (!InValue.IsValid())
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{
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Reset();
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@ -166,33 +108,43 @@ public:
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{
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switch (GetRepresentation())
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{
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case ERepresentation::Empty:
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break;
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case ERepresentation::Trivial:
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Memory::Memcpy(Storage.InlineAllocation(), InValue.Storage.InlineAllocation(), Storage.InlineSize);
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Memory::Memcpy(TrivialStorage.Internal, InValue.TrivialStorage.Internal);
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break;
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case ERepresentation::Small:
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SmallStorage.RTTI = InValue.SmallStorage.RTTI;
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SmallStorage.RTTI->CopyAssign(&SmallStorage.Internal, &InValue.SmallStorage.Internal);
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break;
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case ERepresentation::Big:
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GetTypeInfoImpl().CopyAssignImpl(GetAllocation(), InValue.GetAllocation());
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BigStorage.RTTI = InValue.BigStorage.RTTI;
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BigStorage.RTTI->CopyAssign(BigStorage.External, InValue.BigStorage.External);
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break;
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default: check_no_entry();
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}
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}
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else
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{
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ResetImpl();
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Destroy();
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Storage.TypeInfo() = InValue.Storage.TypeInfo();
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TypeInfo = InValue.TypeInfo;
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switch (GetRepresentation())
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{
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case ERepresentation::Empty:
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break;
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case ERepresentation::Trivial:
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Memory::Memcpy(Storage.InlineAllocation(), InValue.Storage.InlineAllocation(), Storage.InlineSize);
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Memory::Memcpy(TrivialStorage.Internal, InValue.TrivialStorage.Internal);
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break;
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case ERepresentation::Small:
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GetTypeInfoImpl().CopyConstructImpl(GetAllocation(), InValue.GetAllocation());
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SmallStorage.RTTI = InValue.SmallStorage.RTTI;
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SmallStorage.RTTI->CopyConstruct(&SmallStorage.Internal, &InValue.SmallStorage.Internal);
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break;
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case ERepresentation::Big:
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Storage.HeapAllocation() = Memory::Malloc(GetTypeInfoImpl().TypeSize, GetTypeInfoImpl().TypeAlignment);
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GetTypeInfoImpl().CopyConstructImpl(GetAllocation(), InValue.GetAllocation());
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BigStorage.RTTI = InValue.BigStorage.RTTI;
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BigStorage.External = Memory::Malloc(BigStorage.RTTI->TypeSize, BigStorage.RTTI->TypeAlignment);
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BigStorage.RTTI->CopyConstruct(BigStorage.External, InValue.BigStorage.External);
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break;
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default: check_no_entry();
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}
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@ -201,12 +153,10 @@ public:
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return *this;
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}
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FORCEINLINE TAny& operator=(TAny&& InValue)
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FORCEINLINE FAny& operator=(FAny&& InValue)
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{
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if (&InValue == this) return *this;
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Storage.MoveCustom(MoveTemp(InValue.Storage));
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if (!InValue.IsValid())
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{
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Reset();
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@ -215,37 +165,45 @@ public:
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{
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switch (GetRepresentation())
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{
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case ERepresentation::Empty:
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break;
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case ERepresentation::Trivial:
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Memory::Memcpy(Storage.InlineAllocation(), InValue.Storage.InlineAllocation(), Storage.InlineSize);
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Memory::Memmove(TrivialStorage.Internal, InValue.TrivialStorage.Internal);
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break;
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case ERepresentation::Small:
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GetTypeInfoImpl().MoveAssignImpl(GetAllocation(), InValue.GetAllocation());
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SmallStorage.RTTI = InValue.SmallStorage.RTTI;
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SmallStorage.RTTI->MoveAssign(&SmallStorage.Internal, &InValue.SmallStorage.Internal);
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break;
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case ERepresentation::Big:
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ResetImpl();
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Storage.HeapAllocation() = InValue.Storage.HeapAllocation();
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InValue.Storage.TypeInfo() = 0;
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Destroy();
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BigStorage.RTTI = InValue.BigStorage.RTTI;
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BigStorage.External = InValue.BigStorage.External;
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InValue.Invalidate();
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break;
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default: check_no_entry();
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}
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}
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else
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{
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ResetImpl();
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Destroy();
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Storage.TypeInfo() = InValue.Storage.TypeInfo();
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TypeInfo = InValue.TypeInfo;
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switch (GetRepresentation())
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{
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case ERepresentation::Empty:
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break;
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case ERepresentation::Trivial:
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Memory::Memcpy(Storage.InlineAllocation(), InValue.Storage.InlineAllocation(), Storage.InlineSize);
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Memory::Memmove(TrivialStorage.Internal, InValue.TrivialStorage.Internal);
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break;
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case ERepresentation::Small:
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GetTypeInfoImpl().MoveConstructImpl(GetAllocation(), InValue.GetAllocation());
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SmallStorage.RTTI = InValue.SmallStorage.RTTI;
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SmallStorage.RTTI->MoveConstruct(&SmallStorage.Internal, &InValue.SmallStorage.Internal);
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break;
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case ERepresentation::Big:
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Storage.HeapAllocation() = InValue.Storage.HeapAllocation();
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InValue.Storage.TypeInfo() = 0;
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BigStorage.RTTI = InValue.BigStorage.RTTI;
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BigStorage.External = InValue.BigStorage.External;
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InValue.Invalidate();
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break;
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default: check_no_entry();
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}
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@ -254,20 +212,20 @@ public:
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return *this;
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}
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template <typename T> requires (!CBaseOf<TAny, TDecay<T>> && !CTInPlaceType<TDecay<T>>
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&& CDestructible<TDecay<T>> && CConstructibleFrom<TDecay<T>, T&&>)
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FORCEINLINE TAny& operator=(T&& InValue)
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template <typename T> requires (!CBaseOf<FAny, TDecay<T>> && !CTInPlaceType<TDecay<T>>
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&& CDestructible<TDecay<T>>&& CConstructibleFrom<TDecay<T>, T&&>)
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FORCEINLINE FAny& operator=(T&& InValue)
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{
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using SelectedType = TDecay<T>;
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using DecayedType = TDecay<T>;
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if (HoldsAlternative<SelectedType>())
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if (HoldsAlternative<DecayedType>())
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{
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GetValue<SelectedType>() = Forward<T>(InValue);
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GetValue<DecayedType>() = Forward<T>(InValue);
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}
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else
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{
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ResetImpl();
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EmplaceImpl<SelectedType>(Forward<T>(InValue));
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Destroy();
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EmplaceImpl<DecayedType>(Forward<T>(InValue));
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}
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return *this;
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@ -277,55 +235,43 @@ public:
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&& CConstructibleFrom<TDecay<T>, Ts&&...>)
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FORCEINLINE TDecay<T>& Emplace(Ts&&... Args)
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{
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ResetImpl();
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using SelectedType = TDecay<T>;
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EmplaceImpl<SelectedType>(Forward<Ts>(Args)...);
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return GetValue<SelectedType>();
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Destroy();
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EmplaceImpl<T>(Forward<Ts>(Args)...);
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return GetValue<TDecay<T>>();
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}
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constexpr const type_info& GetTypeInfo() const { return IsValid() ? *GetTypeInfoImpl().NativeTypeInfo : typeid(void); }
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FORCEINLINE constexpr const type_info& GetTypeInfo() const { return IsValid() ? GetTypeInfoImpl() : typeid(void); }
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constexpr bool IsValid() const { return Storage.TypeInfo() != 0; }
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constexpr explicit operator bool() const { return Storage.TypeInfo() != 0; }
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FORCEINLINE constexpr bool IsValid() const { return TypeInfo != 0; }
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FORCEINLINE constexpr explicit operator bool() const { return TypeInfo != 0; }
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template <typename T> constexpr bool HoldsAlternative() const { return IsValid() ? GetTypeInfo() == typeid(T) : false; }
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template <typename T> FORCEINLINE constexpr bool HoldsAlternative() const { return IsValid() ? GetTypeInfo() == typeid(T) : false; }
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template <typename T> requires (CDestructible<TDecay<T>>)
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constexpr T& GetValue() & { checkf(HoldsAlternative<T>(), TEXT("It is an error to call GetValue() on an wrong TAny. Please either check HoldsAlternative() or use Get(DefaultValue) instead.")); return *reinterpret_cast< T*>(GetAllocation()); }
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template <typename T> requires (CSameAs<T, TDecay<T>>&& CDestructible<TDecay<T>>)
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FORCEINLINE constexpr T& GetValue() & { checkf(HoldsAlternative<T>(), TEXT("It is an error to call GetValue() on an wrong TAny. Please either check HoldsAlternative() or use Get(DefaultValue) instead.")); return *reinterpret_cast< T*>(GetStorage()); }
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template <typename T> requires (CDestructible<TDecay<T>>)
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constexpr T&& GetValue() && { checkf(HoldsAlternative<T>(), TEXT("It is an error to call GetValue() on an wrong TAny. Please either check HoldsAlternative() or use Get(DefaultValue) instead.")); return MoveTemp(*reinterpret_cast< T*>(GetAllocation())); }
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template <typename T> requires (CSameAs<T, TDecay<T>>&& CDestructible<TDecay<T>>)
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FORCEINLINE constexpr T&& GetValue() && { checkf(HoldsAlternative<T>(), TEXT("It is an error to call GetValue() on an wrong TAny. Please either check HoldsAlternative() or use Get(DefaultValue) instead.")); return MoveTemp(*reinterpret_cast< T*>(GetStorage())); }
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template <typename T> requires (CDestructible<TDecay<T>>)
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constexpr const T& GetValue() const& { checkf(HoldsAlternative<T>(), TEXT("It is an error to call GetValue() on an wrong TAny. Please either check HoldsAlternative() or use Get(DefaultValue) instead.")); return *reinterpret_cast<const T*>(GetAllocation()); }
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template <typename T> requires (CSameAs<T, TDecay<T>>&& CDestructible<TDecay<T>>)
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FORCEINLINE constexpr const T& GetValue() const& { checkf(HoldsAlternative<T>(), TEXT("It is an error to call GetValue() on an wrong TAny. Please either check HoldsAlternative() or use Get(DefaultValue) instead.")); return *reinterpret_cast<const T*>(GetStorage()); }
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template <typename T> requires (CDestructible<TDecay<T>>)
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constexpr const T&& GetValue() const&& { checkf(HoldsAlternative<T>(), TEXT("It is an error to call GetValue() on an wrong TAny. Please either check HoldsAlternative() or use Get(DefaultValue) instead.")); return MoveTemp(*reinterpret_cast<const T*>(GetAllocation())); }
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template <typename T> requires (CSameAs<T, TDecay<T>>&& CDestructible<TDecay<T>>)
|
||||
FORCEINLINE constexpr const T&& GetValue() const&& { checkf(HoldsAlternative<T>(), TEXT("It is an error to call GetValue() on an wrong TAny. Please either check HoldsAlternative() or use Get(DefaultValue) instead.")); return MoveTemp(*reinterpret_cast<const T*>(GetStorage())); }
|
||||
|
||||
template <typename T> requires (CSameAs<T, TDecay<T>> && CDestructible<TDecay<T>>)
|
||||
constexpr T& Get( T& DefaultValue) & { return HoldsAlternative<T>() ? GetValue<T>() : DefaultValue; }
|
||||
FORCEINLINE constexpr T& Get( T& DefaultValue) & { return HoldsAlternative<T>() ? GetValue<T>() : DefaultValue; }
|
||||
|
||||
template <typename T> requires (CSameAs<T, TDecay<T>> && CDestructible<TDecay<T>>)
|
||||
constexpr const T& Get(const T& DefaultValue) const& { return HoldsAlternative<T>() ? GetValue<T>() : DefaultValue; }
|
||||
|
||||
constexpr CustomStorage& GetCustomStorage() requires (!CSameAs<CustomStorage, FAnyDefaultStorage>) { return Storage; }
|
||||
constexpr const CustomStorage& GetCustomStorage() const requires (!CSameAs<CustomStorage, FAnyDefaultStorage>) { return Storage; }
|
||||
FORCEINLINE constexpr const T& Get(const T& DefaultValue) const& { return HoldsAlternative<T>() ? GetValue<T>() : DefaultValue; }
|
||||
|
||||
FORCEINLINE void Reset()
|
||||
{
|
||||
ResetImpl();
|
||||
Storage.TypeInfo() = 0;
|
||||
Destroy();
|
||||
Invalidate();
|
||||
}
|
||||
|
||||
FORCEINLINE size_t GetTypeHash() const
|
||||
{
|
||||
using NAMESPACE_REDCRAFT::GetTypeHash;
|
||||
if (!IsValid()) return 20090007;
|
||||
return HashCombine(GetTypeHash(GetTypeInfo()), GetTypeInfoImpl().HashImpl(GetAllocation()));
|
||||
}
|
||||
|
||||
FORCEINLINE void Swap(TAny& InValue)
|
||||
FORCEINLINE void Swap(FAny& InValue)
|
||||
{
|
||||
if (!IsValid() && !InValue.IsValid()) return;
|
||||
|
||||
@ -345,170 +291,253 @@ public:
|
||||
|
||||
if (GetTypeInfo() == InValue.GetTypeInfo())
|
||||
{
|
||||
GetTypeInfoImpl().SwapImpl(GetAllocation(), InValue.GetAllocation());
|
||||
switch (GetRepresentation())
|
||||
{
|
||||
case ERepresentation::Empty:
|
||||
break;
|
||||
case ERepresentation::Trivial:
|
||||
uint8 Buffer[sizeof(TrivialStorage.Internal)];
|
||||
Memory::Memmove(Buffer, TrivialStorage.Internal);
|
||||
Memory::Memmove(TrivialStorage.Internal, InValue.TrivialStorage.Internal);
|
||||
Memory::Memmove(InValue.TrivialStorage.Internal, Buffer);
|
||||
break;
|
||||
case ERepresentation::Small:
|
||||
SmallStorage.RTTI->SwapObject(&SmallStorage.Internal, &InValue.SmallStorage.Internal);
|
||||
break;
|
||||
case ERepresentation::Big:
|
||||
NAMESPACE_REDCRAFT::Swap(BigStorage.External, InValue.BigStorage.External);
|
||||
break;
|
||||
default: check_no_entry();
|
||||
}
|
||||
|
||||
return;
|
||||
}
|
||||
|
||||
TAny Temp = MoveTemp(*this);
|
||||
FAny Temp = MoveTemp(*this);
|
||||
*this = MoveTemp(InValue);
|
||||
InValue = MoveTemp(Temp);
|
||||
}
|
||||
|
||||
private:
|
||||
|
||||
CustomStorage Storage;
|
||||
|
||||
static constexpr uintptr_t RepresentationMask = 3;
|
||||
|
||||
enum class ERepresentation : uint8
|
||||
struct FRTTI
|
||||
{
|
||||
Trivial, // Trivial & Inline
|
||||
Small, // InlineAllocation
|
||||
Big, // HeapAllocation
|
||||
};
|
||||
|
||||
struct FTypeInfoImpl
|
||||
{
|
||||
const type_info* NativeTypeInfo;
|
||||
|
||||
const size_t TypeSize;
|
||||
const size_t TypeAlignment;
|
||||
|
||||
using FCopyConstructImpl = void(*)(void*, const void*);
|
||||
using FMoveConstructImpl = void(*)(void*, void*);
|
||||
using FCopyAssignImpl = void(*)(void*, const void*);
|
||||
using FMoveAssignImpl = void(*)(void*, void*);
|
||||
using FDestroyImpl = void(*)(void* );
|
||||
using FCopyConstruct = void(*)(void*, const void*);
|
||||
using FMoveConstruct = void(*)(void*, void*);
|
||||
using FCopyAssign = void(*)(void*, const void*);
|
||||
using FMoveAssign = void(*)(void*, void*);
|
||||
using FDestruct = void(*)(void* );
|
||||
using FSwapObject = void(*)(void*, void*);
|
||||
|
||||
using FEqualityCompareImpl = bool (*)(const void*, const void*);
|
||||
using FSynthThreeWayCompareImpl = partial_ordering (*)(const void*, const void*);
|
||||
using FHashImpl = size_t (*)(const void* );
|
||||
using FSwapImpl = void (*)( void*, void*);
|
||||
|
||||
const FCopyConstructImpl CopyConstructImpl;
|
||||
const FMoveConstructImpl MoveConstructImpl;
|
||||
const FCopyAssignImpl CopyAssignImpl;
|
||||
const FMoveAssignImpl MoveAssignImpl;
|
||||
const FDestroyImpl DestroyImpl;
|
||||
|
||||
const FEqualityCompareImpl EqualityCompareImpl;
|
||||
const FSynthThreeWayCompareImpl SynthThreeWayCompareImpl;
|
||||
const FHashImpl HashImpl;
|
||||
const FSwapImpl SwapImpl;
|
||||
const FCopyConstruct CopyConstruct;
|
||||
const FMoveConstruct MoveConstruct;
|
||||
const FCopyAssign CopyAssign;
|
||||
const FMoveAssign MoveAssign;
|
||||
const FDestruct Destruct;
|
||||
const FSwapObject SwapObject;
|
||||
|
||||
template <typename T>
|
||||
constexpr FTypeInfoImpl(TInPlaceType<T>)
|
||||
|
||||
: NativeTypeInfo (&typeid(T))
|
||||
, TypeSize ( sizeof(T))
|
||||
, TypeAlignment (alignof(T))
|
||||
|
||||
, CopyConstructImpl ([](void* A, const void* B) { if constexpr (requires(T* A, const T* B) { Memory::CopyConstruct (A, B); }) Memory::CopyConstruct (reinterpret_cast<T*>(A), reinterpret_cast<const T*>(B)); else checkf(false, TEXT("The type '%s' is not copy constructible."), typeid(T).name()); })
|
||||
, MoveConstructImpl ([](void* A, void* B) { if constexpr (requires(T* A, T* B) { Memory::MoveConstruct (A, B); }) Memory::MoveConstruct (reinterpret_cast<T*>(A), reinterpret_cast< T*>(B)); else checkf(false, TEXT("The type '%s' is not move constructible."), typeid(T).name()); })
|
||||
, CopyAssignImpl ([](void* A, const void* B) { if constexpr (requires(T* A, const T* B) { Memory::CopyAssign (A, B); }) Memory::CopyAssign (reinterpret_cast<T*>(A), reinterpret_cast<const T*>(B)); else checkf(false, TEXT("The type '%s' is not copy assignable."), typeid(T).name()); })
|
||||
, MoveAssignImpl ([](void* A, void* B) { if constexpr (requires(T* A, T* B) { Memory::MoveAssign (A, B); }) Memory::MoveAssign (reinterpret_cast<T*>(A), reinterpret_cast< T*>(B)); else checkf(false, TEXT("The type '%s' is not move assignable."), typeid(T).name()); })
|
||||
, DestroyImpl ([](void* A ) { if constexpr (requires(T* A ) { Memory::Destruct (A ); }) Memory::Destruct (reinterpret_cast<T*>(A) ); else checkf(false, TEXT("The type '%s' is not destructible."), typeid(T).name()); })
|
||||
|
||||
, EqualityCompareImpl ([](const void* A, const void* B) -> bool { if constexpr (CEqualityComparable<T> ) return (*reinterpret_cast<const T*>(A) == *reinterpret_cast<const T*>(B)); else checkf(false, TEXT("The type '%s' is not equality comparable."), typeid(T).name()); return false; })
|
||||
, SynthThreeWayCompareImpl ([](const void* A, const void* B) -> partial_ordering { if constexpr (CSynthThreeWayComparable<T>) return NAMESPACE_REDCRAFT::SynthThreeWayCompare (*reinterpret_cast<const T*>(A), *reinterpret_cast<const T*>(B)); else checkf(false, TEXT("The type '%s' is not synth three-way comparable."), typeid(T).name()); return partial_ordering::unordered; })
|
||||
, HashImpl ([](const void* A ) -> size_t { if constexpr (CHashable<T> ) return NAMESPACE_REDCRAFT::GetTypeHash (*reinterpret_cast<const T*>(A) ); else checkf(false, TEXT("The type '%s' is not hashable."), typeid(T).name()); return 1080551797; })
|
||||
, SwapImpl ([]( void* A, void* B) -> void { if constexpr (CSwappable<T> ) NAMESPACE_REDCRAFT::Swap (*reinterpret_cast< T*>(A), *reinterpret_cast< T*>(B)); else checkf(false, TEXT("The type '%s' is not swappable."), typeid(T).name()); })
|
||||
|
||||
FORCEINLINE constexpr FRTTI(TInPlaceType<T>)
|
||||
: TypeSize( sizeof(T)), TypeAlignment(alignof(T))
|
||||
, CopyConstruct(
|
||||
[](void* A, const void* B)
|
||||
{
|
||||
new (A) T(*reinterpret_cast<const T*>(B));
|
||||
}
|
||||
)
|
||||
, MoveConstruct(
|
||||
[](void* A, void* B)
|
||||
{
|
||||
new (A) T(MoveTemp(*reinterpret_cast<T*>(B)));
|
||||
}
|
||||
)
|
||||
, CopyAssign(
|
||||
[](void* A, const void* B)
|
||||
{
|
||||
if constexpr (CCopyAssignable<T>)
|
||||
{
|
||||
*reinterpret_cast<T*>(A) = *reinterpret_cast<const T*>(B);
|
||||
}
|
||||
else
|
||||
{
|
||||
reinterpret_cast<T*>(A)->~T();
|
||||
new (A) T(*reinterpret_cast<const T*>(B));
|
||||
}
|
||||
}
|
||||
)
|
||||
, MoveAssign(
|
||||
[](void* A, void* B)
|
||||
{
|
||||
if constexpr (CMoveAssignable<T>)
|
||||
{
|
||||
*reinterpret_cast<T*>(A) = MoveTemp(*reinterpret_cast<T*>(B));
|
||||
}
|
||||
else
|
||||
{
|
||||
reinterpret_cast<T*>(A)->~T();
|
||||
new (A) T(MoveTemp(*reinterpret_cast<T*>(B)));
|
||||
}
|
||||
}
|
||||
)
|
||||
, Destruct(
|
||||
[](void* A)
|
||||
{
|
||||
reinterpret_cast<T*>(A)->~T();
|
||||
}
|
||||
)
|
||||
, SwapObject{
|
||||
[](void* A, void* B)
|
||||
{
|
||||
NAMESPACE_REDCRAFT::Swap(*reinterpret_cast<T*>(A), *reinterpret_cast<T*>(B));
|
||||
}
|
||||
}
|
||||
{ }
|
||||
};
|
||||
|
||||
constexpr ERepresentation GetRepresentation() const { return static_cast<ERepresentation>(Storage.TypeInfo() & RepresentationMask); }
|
||||
constexpr const FTypeInfoImpl& GetTypeInfoImpl() const { return *reinterpret_cast<const FTypeInfoImpl*>(Storage.TypeInfo() & ~RepresentationMask); }
|
||||
|
||||
constexpr void* GetAllocation() { return GetRepresentation() == ERepresentation::Trivial || GetRepresentation() == ERepresentation::Small ? Storage.InlineAllocation() : Storage.HeapAllocation(); }
|
||||
constexpr const void* GetAllocation() const { return GetRepresentation() == ERepresentation::Trivial || GetRepresentation() == ERepresentation::Small ? Storage.InlineAllocation() : Storage.HeapAllocation(); }
|
||||
|
||||
template <typename SelectedType, typename... Ts>
|
||||
FORCEINLINE void EmplaceImpl(Ts&&... Args)
|
||||
struct FTrivialStorage
|
||||
{
|
||||
static constexpr const FTypeInfoImpl SelectedTypeInfo(InPlaceType<SelectedType>);
|
||||
Storage.TypeInfo() = reinterpret_cast<uintptr>(&SelectedTypeInfo);
|
||||
uint8 Internal[64 - sizeof(uintptr)];
|
||||
};
|
||||
|
||||
constexpr bool bIsInlineStorable = sizeof(SelectedType) <= Storage.InlineSize && alignof(SelectedType) <= Storage.InlineAlignment;
|
||||
constexpr bool bIsTriviallyStorable = bIsInlineStorable && CTrivial<SelectedType> && CTriviallyCopyable<SelectedType>;
|
||||
struct FSmallStorage
|
||||
{
|
||||
uint8 Internal[sizeof(FTrivialStorage) - sizeof(const FRTTI*)];
|
||||
const FRTTI* RTTI;
|
||||
};
|
||||
|
||||
if constexpr (bIsTriviallyStorable)
|
||||
struct FBigStorage
|
||||
{
|
||||
uint8 Padding[sizeof(FTrivialStorage) - sizeof(void*) - sizeof(const FRTTI*)];
|
||||
void* External;
|
||||
const FRTTI* RTTI;
|
||||
};
|
||||
|
||||
static_assert(sizeof(FTrivialStorage) == sizeof(FSmallStorage));
|
||||
static_assert(sizeof(FTrivialStorage) == sizeof( FBigStorage));
|
||||
|
||||
static_assert(alignof(type_info) >= 4);
|
||||
|
||||
static constexpr uintptr_t RepresentationMask = 3;
|
||||
|
||||
enum class ERepresentation : uintptr
|
||||
{
|
||||
Empty = 0, // EmptyType
|
||||
Trivial = 1, // TrivialStorage
|
||||
Small = 2, // SmallStorage
|
||||
Big = 3, // BigStorage
|
||||
};
|
||||
|
||||
union
|
||||
{
|
||||
FTrivialStorage TrivialStorage;
|
||||
FSmallStorage SmallStorage;
|
||||
FBigStorage BigStorage;
|
||||
};
|
||||
|
||||
uintptr TypeInfo;
|
||||
|
||||
FORCEINLINE ERepresentation GetRepresentation() const { return static_cast<ERepresentation>(TypeInfo & RepresentationMask); }
|
||||
FORCEINLINE const type_info& GetTypeInfoImpl() const { return *reinterpret_cast<const type_info*>(TypeInfo & ~RepresentationMask); }
|
||||
|
||||
FORCEINLINE void* GetStorage()
|
||||
{
|
||||
switch (GetRepresentation())
|
||||
{
|
||||
new(Storage.InlineAllocation()) SelectedType(Forward<Ts>(Args)...);
|
||||
Storage.TypeInfo() |= static_cast<uintptr>(ERepresentation::Trivial);
|
||||
}
|
||||
else if constexpr (bIsInlineStorable)
|
||||
{
|
||||
new(Storage.InlineAllocation()) SelectedType(Forward<Ts>(Args)...);
|
||||
Storage.TypeInfo() |= static_cast<uintptr>(ERepresentation::Small);
|
||||
}
|
||||
else
|
||||
{
|
||||
Storage.HeapAllocation() = new SelectedType(Forward<Ts>(Args)...);
|
||||
Storage.TypeInfo() |= static_cast<uintptr>(ERepresentation::Big);
|
||||
case ERepresentation::Empty: return nullptr;
|
||||
case ERepresentation::Trivial: return &TrivialStorage.Internal;
|
||||
case ERepresentation::Small: return &SmallStorage.Internal;
|
||||
case ERepresentation::Big: return BigStorage.External;
|
||||
default: check_no_entry(); return nullptr;
|
||||
}
|
||||
}
|
||||
|
||||
FORCEINLINE void ResetImpl()
|
||||
FORCEINLINE const void* GetStorage() const
|
||||
{
|
||||
switch (GetRepresentation())
|
||||
{
|
||||
case ERepresentation::Empty: return nullptr;
|
||||
case ERepresentation::Trivial: return &TrivialStorage.Internal;
|
||||
case ERepresentation::Small: return &SmallStorage.Internal;
|
||||
case ERepresentation::Big: return BigStorage.External;
|
||||
default: check_no_entry(); return nullptr;
|
||||
}
|
||||
}
|
||||
|
||||
template <typename T, typename... Ts>
|
||||
FORCEINLINE void EmplaceImpl(Ts&&... Args)
|
||||
{
|
||||
using DecayedType = TDecay<T>;
|
||||
|
||||
TypeInfo = reinterpret_cast<uintptr>(&typeid(DecayedType));
|
||||
|
||||
if constexpr (CEmpty<DecayedType> && CTrivial<DecayedType>) return; // ERepresentation::Empty
|
||||
|
||||
constexpr bool bIsTriviallyStorable = sizeof(DecayedType) <= sizeof(TrivialStorage.Internal) && alignof(DecayedType) <= alignof(FAny) && CTriviallyCopyable<DecayedType>;
|
||||
constexpr bool bIsSmallStorable = sizeof(DecayedType) <= sizeof( SmallStorage.Internal) && alignof(DecayedType) <= alignof(FAny);
|
||||
|
||||
static constexpr const FRTTI SelectedRTTI(InPlaceType<DecayedType>);
|
||||
|
||||
if constexpr (bIsTriviallyStorable)
|
||||
{
|
||||
new (&TrivialStorage.Internal) DecayedType(Forward<Ts>(Args)...);
|
||||
TypeInfo |= static_cast<uintptr>(ERepresentation::Trivial);
|
||||
}
|
||||
else if constexpr (bIsSmallStorable)
|
||||
{
|
||||
new (&SmallStorage.Internal) DecayedType(Forward<Ts>(Args)...);
|
||||
SmallStorage.RTTI = &SelectedRTTI;
|
||||
TypeInfo |= static_cast<uintptr>(ERepresentation::Small);
|
||||
}
|
||||
else
|
||||
{
|
||||
BigStorage.External = Memory::Malloc(sizeof(DecayedType), alignof(DecayedType));
|
||||
new (BigStorage.External) DecayedType(Forward<Ts>(Args)...);
|
||||
BigStorage.RTTI = &SelectedRTTI;
|
||||
TypeInfo |= static_cast<uintptr>(ERepresentation::Big);
|
||||
}
|
||||
}
|
||||
|
||||
FORCEINLINE void Destroy()
|
||||
{
|
||||
if (!IsValid()) return;
|
||||
|
||||
switch (GetRepresentation())
|
||||
{
|
||||
case ERepresentation::Empty:
|
||||
case ERepresentation::Trivial:
|
||||
break;
|
||||
case ERepresentation::Small:
|
||||
GetTypeInfoImpl().DestroyImpl(GetAllocation());
|
||||
SmallStorage.RTTI->Destruct(&SmallStorage.Internal);
|
||||
break;
|
||||
case ERepresentation::Big:
|
||||
GetTypeInfoImpl().DestroyImpl(GetAllocation());
|
||||
Memory::Free(Storage.HeapAllocation());
|
||||
BigStorage.RTTI->Destruct(BigStorage.External);
|
||||
Memory::Free(BigStorage.External);
|
||||
break;
|
||||
default: check_no_entry();
|
||||
}
|
||||
}
|
||||
|
||||
friend FORCEINLINE bool operator==(const TAny& LHS, const TAny& RHS)
|
||||
FORCEINLINE constexpr void Invalidate() { TypeInfo = 0; }
|
||||
|
||||
template <typename T> requires (!CBaseOf<FAny, TRemoveCVRef<T>>)
|
||||
friend FORCEINLINE constexpr bool operator==(const FAny& LHS, const T& RHS)
|
||||
{
|
||||
if (LHS.GetTypeInfo() != RHS.GetTypeInfo()) return false;
|
||||
if (LHS.IsValid() == false) return true;
|
||||
return LHS.GetTypeInfoImpl().EqualityCompareImpl(LHS.GetAllocation(), RHS.GetAllocation());
|
||||
return LHS.template HoldsAlternative<T>() ? LHS.template GetValue<T>() == RHS : false;
|
||||
}
|
||||
|
||||
friend FORCEINLINE partial_ordering operator<=>(const TAny& LHS, const TAny& RHS)
|
||||
friend FORCEINLINE constexpr bool operator==(const FAny& LHS, FInvalid)
|
||||
{
|
||||
if (LHS.GetTypeInfo() != RHS.GetTypeInfo()) return partial_ordering::unordered;
|
||||
if (LHS.IsValid() == false) return partial_ordering::equivalent;
|
||||
return LHS.GetTypeInfoImpl().SynthThreeWayCompareImpl(LHS.GetAllocation(), RHS.GetAllocation());;
|
||||
return !LHS.IsValid();
|
||||
}
|
||||
|
||||
};
|
||||
|
||||
class FAny : STRONG_INHERIT(TAny<FAnyDefaultStorage>);
|
||||
|
||||
static_assert(sizeof(FAny) == 64, "The byte size of FAny is unexpected");
|
||||
|
||||
template <typename T, CAnyCustomStorage StorageType> requires (!CBaseOf<FAny, TRemoveCVRef<T>>)
|
||||
constexpr bool operator==(const TAny<StorageType>& LHS, const T& RHS)
|
||||
{
|
||||
return LHS.template HoldsAlternative<T>() ? LHS.template GetValue<T>() == RHS : false;
|
||||
}
|
||||
|
||||
template <CAnyCustomStorage StorageType>
|
||||
constexpr bool operator==(const TAny<StorageType>& LHS, FInvalid)
|
||||
{
|
||||
return !LHS.IsValid();
|
||||
}
|
||||
|
||||
NAMESPACE_PRIVATE_BEGIN
|
||||
|
||||
template <typename T> struct TIsTAny : FFalse { };
|
||||
template <CAnyCustomStorage StorageType> struct TIsTAny<TAny<StorageType>> : FTrue { };
|
||||
|
||||
NAMESPACE_PRIVATE_END
|
||||
|
||||
template <typename T>
|
||||
concept CTAny = NAMESPACE_PRIVATE::TIsTAny<TRemoveCV<T>>::Value;
|
||||
static_assert(alignof(FAny) == 16, "The byte alignment of FAny is unexpected");
|
||||
|
||||
NAMESPACE_MODULE_END(Utility)
|
||||
NAMESPACE_MODULE_END(Redcraft)
|
||||
|
@ -321,15 +321,6 @@ public:
|
||||
|
||||
private:
|
||||
|
||||
union
|
||||
{
|
||||
uint8 InternalStorage[64 - sizeof(uintptr) - sizeof(uintptr)];
|
||||
void* ExternalStorage;
|
||||
};
|
||||
|
||||
uintptr RTTI;
|
||||
uintptr Callable;
|
||||
|
||||
struct FMovableRTTI
|
||||
{
|
||||
const size_t TypeSize;
|
||||
@ -391,6 +382,15 @@ private:
|
||||
Big = 3, // ExternalStorage
|
||||
};
|
||||
|
||||
union
|
||||
{
|
||||
uint8 InternalStorage[64 - sizeof(uintptr) - sizeof(uintptr)];
|
||||
void* ExternalStorage;
|
||||
};
|
||||
|
||||
uintptr RTTI;
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uintptr Callable;
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FORCEINLINE constexpr ERepresentation GetRepresentation() const { return static_cast<ERepresentation>(RTTI & RepresentationMask); }
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FORCEINLINE constexpr const FRTTI& GetRTTI() const { return *reinterpret_cast<const FRTTI*>(RTTI & ~RepresentationMask); }
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|
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Loading…
Reference in New Issue
Block a user