#pragma once #include "CoreTypes.h" #include "Memory/Memory.h" #include "Memory/Alignment.h" #include "Templates/Utility.h" #include "Templates/TypeHash.h" #include "Memory/MemoryOperator.h" #include "TypeTraits/TypeTraits.h" #include "Miscellaneous/AssertionMacros.h" NAMESPACE_REDCRAFT_BEGIN NAMESPACE_MODULE_BEGIN(Redcraft) NAMESPACE_MODULE_BEGIN(Utility) // TAny's CustomStorage concept, see FAnyDefaultStorage template concept CAnyCustomStorage = CDefaultConstructible && !CCopyConstructible && !CMoveConstructible && !CCopyAssignable && !CMoveAssignable && CDestructible && CSameAs && CSameAs && requires(const T& A) { { A.InlineAllocation() } -> CSameAs; { A.HeapAllocation() } -> CSameAs; { A.TypeInfo() } -> CSameAs; } && requires(T& A) { { A.InlineAllocation() } -> CSameAs; { A.HeapAllocation() } -> CSameAs; { A.TypeInfo() } -> CSameAs; } && requires(T& A, const T& B, T&& C) { A.CopyCustom(B); A.MoveCustom(MoveTemp(C)); }; // TAny's default storage structure struct alignas(16) FAnyDefaultStorage : FSingleton { // The built-in copy/move operators are disabled and CopyCustom/MoveCustom is used instead of them // You can add custom variables like this //Type Variable; //~ Begin CAnyCustomStorage Interface inline static constexpr size_t InlineSize = 64 - sizeof(uintptr); inline static constexpr size_t InlineAlignment = 16; constexpr void* InlineAllocation() { return &InlineAllocationImpl; } constexpr const void* InlineAllocation() const { return &InlineAllocationImpl; } constexpr void*& HeapAllocation() { return HeapAllocationImpl; } constexpr void* HeapAllocation() const { return HeapAllocationImpl; } constexpr uintptr& TypeInfo() { return TypeInfoImpl; } constexpr uintptr TypeInfo() const { return TypeInfoImpl; } constexpr void CopyCustom(const FAnyDefaultStorage& InValue) { /* Variable = InValue.Variable; */ } // You just need to copy the custom variables constexpr void MoveCustom( FAnyDefaultStorage&& InValue) { /* Variable = MoveTemp(InValue.Variable); */ } // You just need to move the custom variables //~ End CAnyCustomStorage Interface union { uint8 InlineAllocationImpl[InlineSize]; void* HeapAllocationImpl; }; uintptr TypeInfoImpl; }; static_assert(CAnyCustomStorage); // You can add custom storage area through CustomStorage, such as TFunction // It is not recommended to use this, FAny is recommended template class TAny { public: inline static constexpr size_t InlineSize = CustomStorage::InlineSize; inline static constexpr size_t InlineAlignment = CustomStorage::InlineAlignment; constexpr TAny() { Storage.TypeInfo() = 0; } constexpr TAny(FInvalid) : TAny() { } FORCEINLINE TAny(const TAny& InValue) { Storage.CopyCustom(InValue.Storage); Storage.TypeInfo() = InValue.Storage.TypeInfo(); if (!IsValid()) return; switch (GetRepresentation()) { case ERepresentation::Trivial: Memory::Memcpy(Storage.InlineAllocation(), InValue.Storage.InlineAllocation(), Storage.InlineSize); break; case ERepresentation::Small: GetTypeInfoImpl().CopyConstructImpl(GetAllocation(), InValue.GetAllocation()); break; case ERepresentation::Big: Storage.HeapAllocation() = Memory::Malloc(GetTypeInfoImpl().TypeSize, GetTypeInfoImpl().TypeAlignment); GetTypeInfoImpl().CopyConstructImpl(GetAllocation(), InValue.GetAllocation()); break; default: check_no_entry(); } } FORCEINLINE TAny(TAny&& InValue) { Storage.MoveCustom(MoveTemp(InValue.Storage)); Storage.TypeInfo() = InValue.Storage.TypeInfo(); if (!IsValid()) return; switch (GetRepresentation()) { case ERepresentation::Trivial: Memory::Memcpy(Storage.InlineAllocation(), InValue.Storage.InlineAllocation(), Storage.InlineSize); break; case ERepresentation::Small: GetTypeInfoImpl().MoveConstructImpl(GetAllocation(), InValue.GetAllocation()); break; case ERepresentation::Big: Storage.HeapAllocation() = InValue.Storage.HeapAllocation(); InValue.Storage.TypeInfo() = 0; break; default: check_no_entry(); } } template requires (CDestructible> && CConstructibleFrom, Ts&&...>) FORCEINLINE explicit TAny(TInPlaceType, Ts&&... Args) { using SelectedType = TDecay; EmplaceImpl(Forward(Args)...); } template requires (!CSameAs, TAny> && !CTInPlaceType>) && CDestructible> && CConstructibleFrom, T&&> FORCEINLINE TAny(T&& InValue) : TAny(InPlaceType>, Forward(InValue)) { } FORCEINLINE ~TAny() { ResetImpl(); } FORCEINLINE TAny& operator=(const TAny& InValue) { if (&InValue == this) return *this; Storage.CopyCustom(InValue.Storage); if (!InValue.IsValid()) { Reset(); } else if (GetTypeInfo() == InValue.GetTypeInfo()) { switch (GetRepresentation()) { case ERepresentation::Trivial: Memory::Memcpy(Storage.InlineAllocation(), InValue.Storage.InlineAllocation(), Storage.InlineSize); break; case ERepresentation::Small: case ERepresentation::Big: GetTypeInfoImpl().CopyAssignImpl(GetAllocation(), InValue.GetAllocation()); break; default: check_no_entry(); } } else { ResetImpl(); Storage.TypeInfo() = InValue.Storage.TypeInfo(); switch (GetRepresentation()) { case ERepresentation::Trivial: Memory::Memcpy(Storage.InlineAllocation(), InValue.Storage.InlineAllocation(), Storage.InlineSize); break; case ERepresentation::Small: GetTypeInfoImpl().CopyConstructImpl(GetAllocation(), InValue.GetAllocation()); break; case ERepresentation::Big: Storage.HeapAllocation() = Memory::Malloc(GetTypeInfoImpl().TypeSize, GetTypeInfoImpl().TypeAlignment); GetTypeInfoImpl().CopyConstructImpl(GetAllocation(), InValue.GetAllocation()); break; default: check_no_entry(); } } return *this; } FORCEINLINE TAny& operator=(TAny&& InValue) { if (&InValue == this) return *this; Storage.MoveCustom(MoveTemp(InValue.Storage)); if (!InValue.IsValid()) { Reset(); } else if (GetTypeInfo() == InValue.GetTypeInfo()) { switch (GetRepresentation()) { case ERepresentation::Trivial: Memory::Memcpy(Storage.InlineAllocation(), InValue.Storage.InlineAllocation(), Storage.InlineSize); break; case ERepresentation::Small: GetTypeInfoImpl().MoveAssignImpl(GetAllocation(), InValue.GetAllocation()); break; case ERepresentation::Big: ResetImpl(); Storage.HeapAllocation() = InValue.Storage.HeapAllocation(); InValue.Storage.TypeInfo() = 0; break; default: check_no_entry(); } } else { ResetImpl(); Storage.TypeInfo() = InValue.Storage.TypeInfo(); switch (GetRepresentation()) { case ERepresentation::Trivial: Memory::Memcpy(Storage.InlineAllocation(), InValue.Storage.InlineAllocation(), Storage.InlineSize); break; case ERepresentation::Small: GetTypeInfoImpl().MoveConstructImpl(GetAllocation(), InValue.GetAllocation()); break; case ERepresentation::Big: Storage.HeapAllocation() = InValue.Storage.HeapAllocation(); InValue.Storage.TypeInfo() = 0; break; default: check_no_entry(); } } return *this; } template requires (!CSameAs, TAny> && !CTInPlaceType>) && CDestructible> && CConstructibleFrom, T&&> FORCEINLINE TAny& operator=(T&& InValue) { using SelectedType = TDecay; if (HoldsAlternative()) { GetValue() = Forward(InValue); } else { ResetImpl(); EmplaceImpl(Forward(InValue)); } return *this; } template requires (CDestructible> && CConstructibleFrom, Ts&&...>) FORCEINLINE TDecay& Emplace(Ts&&... Args) { ResetImpl(); using SelectedType = TDecay; EmplaceImpl(Forward(Args)...); return GetValue(); } constexpr const type_info& GetTypeInfo() const { return IsValid() ? *GetTypeInfoImpl().NativeTypeInfo : typeid(void); } constexpr bool IsValid() const { return Storage.TypeInfo() != 0; } constexpr explicit operator bool() const { return Storage.TypeInfo() != 0; } template constexpr bool HoldsAlternative() const { return IsValid() ? GetTypeInfo() == typeid(T) : false; } template requires (CDestructible>) constexpr T& GetValue() & { checkf(HoldsAlternative(), 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()); } template requires (CDestructible>) constexpr T&& GetValue() && { checkf(HoldsAlternative(), 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())); } template requires (CDestructible>) constexpr const T& GetValue() const& { checkf(HoldsAlternative(), TEXT("It is an error to call GetValue() on an wrong TAny. Please either check HoldsAlternative() or use Get(DefaultValue) instead.")); return *reinterpret_cast(GetAllocation()); } template requires (CDestructible>) constexpr const T&& GetValue() const&& { checkf(HoldsAlternative(), 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(GetAllocation())); } template requires (CSameAs> && CDestructible>) constexpr T& Get( T& DefaultValue) & { return HoldsAlternative() ? GetValue() : DefaultValue; } template requires (CSameAs> && CDestructible>) constexpr const T& Get(const T& DefaultValue) const& { return HoldsAlternative() ? GetValue() : DefaultValue; } constexpr CustomStorage& GetCustomStorage() requires (!CSameAs) { return Storage; } constexpr const CustomStorage& GetCustomStorage() const requires (!CSameAs) { return Storage; } FORCEINLINE void Reset() { ResetImpl(); Storage.TypeInfo() = 0; } 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) { if (!IsValid() && !InValue.IsValid()) return; if (IsValid() && !InValue.IsValid()) { InValue = MoveTemp(*this); Reset(); return; } if (InValue.IsValid() && !IsValid()) { *this = MoveTemp(InValue); InValue.Reset(); return; } if (GetTypeInfo() == InValue.GetTypeInfo()) { GetTypeInfoImpl().SwapImpl(GetAllocation(), InValue.GetAllocation()); return; } TAny Temp = MoveTemp(*this); *this = MoveTemp(InValue); InValue = MoveTemp(Temp); } private: CustomStorage Storage; static constexpr uintptr_t RepresentationMask = 3; enum class ERepresentation : uint8 { 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 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; template constexpr FTypeInfoImpl(TInPlaceType) : 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(A), reinterpret_cast(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(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(A), reinterpret_cast(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(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(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 ) return (*reinterpret_cast(A) == *reinterpret_cast(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) return NAMESPACE_REDCRAFT::SynthThreeWayCompare (*reinterpret_cast(A), *reinterpret_cast(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 ) return NAMESPACE_REDCRAFT::GetTypeHash (*reinterpret_cast(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 ) NAMESPACE_REDCRAFT::Swap (*reinterpret_cast< T*>(A), *reinterpret_cast< T*>(B)); else checkf(false, TEXT("The type '%s' is not swappable."), typeid(T).name()); }) { } }; constexpr ERepresentation GetRepresentation() const { return static_cast(Storage.TypeInfo() & RepresentationMask); } constexpr const FTypeInfoImpl& GetTypeInfoImpl() const { return *reinterpret_cast(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 FORCEINLINE void EmplaceImpl(Ts&&... Args) { static constexpr const FTypeInfoImpl SelectedTypeInfo(InPlaceType); Storage.TypeInfo() = reinterpret_cast(&SelectedTypeInfo); constexpr bool bIsInlineStorable = sizeof(SelectedType) <= Storage.InlineSize && alignof(SelectedType) <= Storage.InlineAlignment; constexpr bool bIsTriviallyStorable = bIsInlineStorable && CTrivial && CTriviallyCopyable; if constexpr (bIsTriviallyStorable) { new(Storage.InlineAllocation()) SelectedType(Forward(Args)...); Storage.TypeInfo() |= static_cast(ERepresentation::Trivial); } else if constexpr (bIsInlineStorable) { new(Storage.InlineAllocation()) SelectedType(Forward(Args)...); Storage.TypeInfo() |= static_cast(ERepresentation::Small); } else { Storage.HeapAllocation() = new SelectedType(Forward(Args)...); Storage.TypeInfo() |= static_cast(ERepresentation::Big); } } FORCEINLINE void ResetImpl() { if (!IsValid()) return; switch (GetRepresentation()) { case ERepresentation::Trivial: break; case ERepresentation::Small: GetTypeInfoImpl().DestroyImpl(GetAllocation()); break; case ERepresentation::Big: GetTypeInfoImpl().DestroyImpl(GetAllocation()); Memory::Free(Storage.HeapAllocation()); break; default: check_no_entry(); } } friend FORCEINLINE bool operator==(const TAny& LHS, const TAny& RHS) { if (LHS.GetTypeInfo() != RHS.GetTypeInfo()) return false; if (LHS.IsValid() == false) return true; return LHS.GetTypeInfoImpl().EqualityCompareImpl(LHS.GetAllocation(), RHS.GetAllocation()); } friend FORCEINLINE partial_ordering operator<=>(const TAny& LHS, const TAny& RHS) { 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());; } }; template constexpr bool operator==(const TAny& LHS, const T& RHS) { return LHS.template HoldsAlternative() ? LHS.template GetValue() == RHS : false; } template constexpr bool operator==(const TAny& LHS, FInvalid) { return !LHS.IsValid(); } NAMESPACE_PRIVATE_BEGIN template struct TIsTAny : FFalse { }; template struct TIsTAny> : FTrue { }; NAMESPACE_PRIVATE_END template concept CTAny = NAMESPACE_PRIVATE::TIsTAny>::Value; using FAny = TAny<>; static_assert(sizeof(FAny) == 64, "The byte size of FAny is unexpected"); NAMESPACE_MODULE_END(Utility) NAMESPACE_MODULE_END(Redcraft) NAMESPACE_REDCRAFT_END