STL/stl/inc/any

// any standard header

// Copyright (c) Microsoft Corporation.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception

#ifndef _ANY_
#define _ANY_
#include <yvals_core.h>
#if _STL_COMPILER_PREPROCESSOR

#if !_HAS_CXX17
_EMIT_STL_WARNING(STL4038, "The contents of <any> are available only with C++17 or later.");
#elif !_HAS_STATIC_RTTI // ^^^ !_HAS_CXX17 / _HAS_CXX17 vvv
_EMIT_STL_WARNING(STL4040, "The contents of <any> require static RTTI.");
#else // ^^^ !_HAS_STATIC_RTTI / _HAS_STATIC_RTTI vvv
#include <initializer_list>
#include <type_traits>
#include <typeinfo>
#include <utility>
#include <xmemory>

#pragma pack(push, _CRT_PACKING)
#pragma warning(push, _STL_WARNING_LEVEL)
#pragma warning(disable : _STL_DISABLED_WARNINGS)
_STL_DISABLE_CLANG_WARNINGS
#pragma push_macro("new")
#undef new

_STD_BEGIN

_EXPORT_STD class bad_any_cast : public bad_cast { // thrown by failed any_cast
public:
    _NODISCARD const char* __CLR_OR_THIS_CALL what() const noexcept override {
        return "Bad any_cast";
    }
};

[[noreturn]] inline void _Throw_bad_any_cast() {
    _THROW(bad_any_cast{});
}

inline constexpr size_t _Any_trivial_space_size = (_Small_object_num_ptrs - 1) * sizeof(void*);

template <class _Ty>
inline constexpr bool _Any_is_trivial =
    alignof(_Ty) <= alignof(max_align_t) && is_trivially_copyable_v<_Ty> && sizeof(_Ty) <= _Any_trivial_space_size;

inline constexpr size_t _Any_small_space_size = (_Small_object_num_ptrs - 2) * sizeof(void*);

template <class _Ty>
inline constexpr bool _Any_is_small = alignof(_Ty) <= alignof(max_align_t)
                                   && is_nothrow_move_constructible_v<_Ty> && sizeof(_Ty) <= _Any_small_space_size;

enum class _Any_representation : uintptr_t { _Trivial, _Big, _Small };

struct _Any_big_RTTI { // Hand-rolled vtable for types that must be heap allocated in an any
    using _Destroy_fn = void __CLRCALL_PURE_OR_CDECL(void*) _NOEXCEPT_FNPTR;
    using _Copy_fn    = void* __CLRCALL_PURE_OR_CDECL(const void*);

    template <class _Ty>
    static void __CLRCALL_PURE_OR_CDECL _Destroy_impl(void* const _Target) noexcept {
        ::delete static_cast<_Ty*>(_Target);
    }

    template <class _Ty>
    _NODISCARD static void* __CLRCALL_PURE_OR_CDECL _Copy_impl(const void* const _Source) {
        return ::new _Ty(*static_cast<const _Ty*>(_Source));
    }

    _Destroy_fn* _Destroy;
    _Copy_fn* _Copy;
};

struct _Any_small_RTTI { // Hand-rolled vtable for nontrivial types that can be stored internally in an any
    using _Destroy_fn = void __CLRCALL_PURE_OR_CDECL(void*) _NOEXCEPT_FNPTR;
    using _Copy_fn    = void __CLRCALL_PURE_OR_CDECL(void*, const void*);
    using _Move_fn    = void __CLRCALL_PURE_OR_CDECL(void*, void*) _NOEXCEPT_FNPTR;

    template <class _Ty>
    static void __CLRCALL_PURE_OR_CDECL _Destroy_impl(void* const _Target) noexcept {
        _STD _Destroy_in_place(*static_cast<_Ty*>(_Target));
    }

    template <class _Ty>
    static void __CLRCALL_PURE_OR_CDECL _Copy_impl(void* const _Target, const void* const _Source) {
        _STD _Construct_in_place(*static_cast<_Ty*>(_Target), *static_cast<const _Ty*>(_Source));
    }

    template <class _Ty>
    static void __CLRCALL_PURE_OR_CDECL _Move_impl(void* const _Target, void* const _Source) noexcept {
        _STD _Construct_in_place(*static_cast<_Ty*>(_Target), _STD move(*static_cast<_Ty*>(_Source)));
    }

    _Destroy_fn* _Destroy;
    _Copy_fn* _Copy;
    _Move_fn* _Move;
};

template <class _Ty>
inline constexpr _Any_big_RTTI _Any_big_RTTI_obj = {
    &_Any_big_RTTI::_Destroy_impl<_Ty>, &_Any_big_RTTI::_Copy_impl<_Ty>};

template <class _Ty>
inline constexpr _Any_small_RTTI _Any_small_RTTI_obj = {
    &_Any_small_RTTI::_Destroy_impl<_Ty>, &_Any_small_RTTI::_Copy_impl<_Ty>, &_Any_small_RTTI::_Move_impl<_Ty>};

_EXPORT_STD class any { // storage for any (CopyConstructible) type
public:
    // Construction and destruction [any.cons]
    constexpr any() noexcept {}

    any(const any& _That) {
        _Storage._TypeData = _That._Storage._TypeData;
        switch (_Rep()) {
        case _Any_representation::_Small:
            _Storage._SmallStorage._RTTI = _That._Storage._SmallStorage._RTTI;
            _Storage._SmallStorage._RTTI->_Copy(&_Storage._SmallStorage._Data, &_That._Storage._SmallStorage._Data);
            break;
        case _Any_representation::_Big:
            _Storage._BigStorage._RTTI = _That._Storage._BigStorage._RTTI;
            _Storage._BigStorage._Ptr  = _Storage._BigStorage._RTTI->_Copy(_That._Storage._BigStorage._Ptr);
            break;
        case _Any_representation::_Trivial:
        default:
            _CSTD memcpy(_Storage._TrivialData, _That._Storage._TrivialData, sizeof(_Storage._TrivialData));
            break;
        }
    }

    any(any&& _That) noexcept {
        _Move_from(_That);
    }

    template <class _ValueType, enable_if_t<conjunction_v<negation<is_same<decay_t<_ValueType>, any>>,
                                                negation<_Is_specialization<decay_t<_ValueType>, in_place_type_t>>,
                                                is_copy_constructible<decay_t<_ValueType>>>,
                                    int> = 0>
    any(_ValueType&& _Value) { // initialize with _Value
        _Emplace<decay_t<_ValueType>>(_STD forward<_ValueType>(_Value));
    }

    template <class _ValueType, class... _Types,
        enable_if_t<
            conjunction_v<is_constructible<decay_t<_ValueType>, _Types...>, is_copy_constructible<decay_t<_ValueType>>>,
            int> = 0>
    explicit any(in_place_type_t<_ValueType>, _Types&&... _Args) {
        // in-place initialize a value of type decay_t<_ValueType> with _Args...
        _Emplace<decay_t<_ValueType>>(_STD forward<_Types>(_Args)...);
    }

    template <class _ValueType, class _Elem, class... _Types,
        enable_if_t<conjunction_v<is_constructible<decay_t<_ValueType>, initializer_list<_Elem>&, _Types...>,
                        is_copy_constructible<decay_t<_ValueType>>>,
            int> = 0>
    explicit any(in_place_type_t<_ValueType>, initializer_list<_Elem> _Ilist, _Types&&... _Args) {
        // in-place initialize a value of type decay_t<_ValueType> with _Ilist and _Args...
        _Emplace<decay_t<_ValueType>>(_Ilist, _STD forward<_Types>(_Args)...);
    }

    ~any() noexcept {
        reset();
    }

    // Assignment [any.assign]
    any& operator=(const any& _That) {
        _Assign(_That);
        return *this;
    }

    any& operator=(any&& _That) noexcept {
        _Assign(_STD move(_That));
        return *this;
    }

    template <class _ValueType, enable_if_t<conjunction_v<negation<is_same<decay_t<_ValueType>, any>>,
                                                is_copy_constructible<decay_t<_ValueType>>>,
                                    int> = 0>
    any& operator=(_ValueType&& _Value) {
        // replace contained value with an object of type decay_t<_ValueType> initialized from _Value
        _Assign(_STD forward<_ValueType>(_Value));
        return *this;
    }

    // Modifiers [any.modifiers]
    template <class _ValueType, class... _Types,
        enable_if_t<
            conjunction_v<is_constructible<decay_t<_ValueType>, _Types...>, is_copy_constructible<decay_t<_ValueType>>>,
            int> = 0>
    decay_t<_ValueType>& emplace(_Types&&... _Args) {
        // replace contained value with an object of type decay_t<_ValueType> initialized from _Args...
        reset();
        return _Emplace<decay_t<_ValueType>>(_STD forward<_Types>(_Args)...);
    }
    template <class _ValueType, class _Elem, class... _Types,
        enable_if_t<conjunction_v<is_constructible<decay_t<_ValueType>, initializer_list<_Elem>&, _Types...>,
                        is_copy_constructible<decay_t<_ValueType>>>,
            int> = 0>
    decay_t<_ValueType>& emplace(initializer_list<_Elem> _Ilist, _Types&&... _Args) {
        // replace contained value with an object of type decay_t<_ValueType> initialized from _Ilist and _Args...
        reset();
        return _Emplace<decay_t<_ValueType>>(_Ilist, _STD forward<_Types>(_Args)...);
    }

    void reset() noexcept { // transition to the empty state
        switch (_Rep()) {
        case _Any_representation::_Small:
            _Storage._SmallStorage._RTTI->_Destroy(&_Storage._SmallStorage._Data);
            break;
        case _Any_representation::_Big:
            _Storage._BigStorage._RTTI->_Destroy(_Storage._BigStorage._Ptr);
            break;
        case _Any_representation::_Trivial:
        default:
            break;
        }
        _Storage._TypeData = 0;
    }

    void swap(any& _That) noexcept {
        _That = _STD exchange(*this, _STD move(_That));
    }

    // Observers [any.observers]
    _NODISCARD bool has_value() const noexcept {
        return _Storage._TypeData != 0;
    }

    _NODISCARD const type_info& type() const noexcept {
        // if *this contains a value of type T, return typeid(T); otherwise typeid(void)
        const type_info* const _Info = _TypeInfo();
        if (_Info) {
            return *_Info;
        }

        return typeid(void);
    }

    template <class _Decayed>
    _NODISCARD const _Decayed* _Cast() const noexcept {
        // if *this contains a value of type _Decayed, return a pointer to it
        const type_info* const _Info = _TypeInfo();
        if (!_Info || *_Info != typeid(_Decayed)) {
            return nullptr;
        }

        if constexpr (_Any_is_trivial<_Decayed>) {
            // get a pointer to the contained _Trivial value of type _Decayed
            return reinterpret_cast<const _Decayed*>(&_Storage._TrivialData);
        } else if constexpr (_Any_is_small<_Decayed>) {
            // get a pointer to the contained _Small value of type _Decayed
            return reinterpret_cast<const _Decayed*>(&_Storage._SmallStorage._Data);
        } else {
            // get a pointer to the contained _Big value of type _Decayed
            return static_cast<const _Decayed*>(_Storage._BigStorage._Ptr);
        }
    }

    template <class _Decayed>
    _NODISCARD _Decayed* _Cast() noexcept { // if *this contains a value of type _Decayed, return a pointer to it
        return const_cast<_Decayed*>(static_cast<const any*>(this)->_Cast<_Decayed>());
    }

private:
    static constexpr uintptr_t _Rep_mask = 3;

    _NODISCARD _Any_representation _Rep() const noexcept { // extract the representation format from _TypeData
        return static_cast<_Any_representation>(_Storage._TypeData & _Rep_mask);
    }
    _NODISCARD const type_info* _TypeInfo() const noexcept { // extract the type_info from _TypeData
        return reinterpret_cast<const type_info*>(_Storage._TypeData & ~_Rep_mask);
    }

    void _Move_from(any& _That) noexcept {
        _Storage._TypeData = _That._Storage._TypeData;
        switch (_Rep()) {
        case _Any_representation::_Small:
            _Storage._SmallStorage._RTTI = _That._Storage._SmallStorage._RTTI;
            _Storage._SmallStorage._RTTI->_Move(&_Storage._SmallStorage._Data, &_That._Storage._SmallStorage._Data);
            break;
        case _Any_representation::_Big:
            _Storage._BigStorage._RTTI = _That._Storage._BigStorage._RTTI;
            _Storage._BigStorage._Ptr  = _That._Storage._BigStorage._Ptr;
            _That._Storage._TypeData   = 0;
            break;
        case _Any_representation::_Trivial:
        default:
            _CSTD memcpy(_Storage._TrivialData, _That._Storage._TrivialData, sizeof(_Storage._TrivialData));
            break;
        }
    }

    void _Assign(any _That) noexcept { // intentionally pass by value
        reset();
        _Move_from(_That);
    }

    template <class _Decayed, class... _Types>
    _Decayed& _Emplace(_Types&&... _Args) { // emplace construct _Decayed
        if constexpr (_Any_is_trivial<_Decayed>) {
            // using the _Trivial representation
            auto& _Obj = reinterpret_cast<_Decayed&>(_Storage._TrivialData);
            _STD _Construct_in_place(_Obj, _STD forward<_Types>(_Args)...);
            _Storage._TypeData =
                reinterpret_cast<uintptr_t>(&typeid(_Decayed)) | static_cast<uintptr_t>(_Any_representation::_Trivial);
            return _Obj;
        } else if constexpr (_Any_is_small<_Decayed>) {
            // using the _Small representation
            auto& _Obj = reinterpret_cast<_Decayed&>(_Storage._SmallStorage._Data);
            _STD _Construct_in_place(_Obj, _STD forward<_Types>(_Args)...);
            _Storage._SmallStorage._RTTI = &_Any_small_RTTI_obj<_Decayed>;
            _Storage._TypeData =
                reinterpret_cast<uintptr_t>(&typeid(_Decayed)) | static_cast<uintptr_t>(_Any_representation::_Small);
            return _Obj;
        } else {
            // using the _Big representation
            _Decayed* const _Ptr       = ::new _Decayed(_STD forward<_Types>(_Args)...);
            _Storage._BigStorage._Ptr  = _Ptr;
            _Storage._BigStorage._RTTI = &_Any_big_RTTI_obj<_Decayed>;
            _Storage._TypeData =
                reinterpret_cast<uintptr_t>(&typeid(_Decayed)) | static_cast<uintptr_t>(_Any_representation::_Big);
            return *_Ptr;
        }
    }

    struct _Small_storage_t {
        unsigned char _Data[_Any_small_space_size];
        const _Any_small_RTTI* _RTTI;
    };
    static_assert(sizeof(_Small_storage_t) == _Any_trivial_space_size);

    struct _Big_storage_t {
        // Pad so that _Ptr and _RTTI might share _TypeData's cache line
        unsigned char _Padding[_Any_small_space_size - sizeof(void*)];
        void* _Ptr;
        const _Any_big_RTTI* _RTTI;
    };
    static_assert(sizeof(_Big_storage_t) == _Any_trivial_space_size);

    struct _Storage_t {
        union {
            unsigned char _TrivialData[_Any_trivial_space_size];
            _Small_storage_t _SmallStorage;
            _Big_storage_t _BigStorage;
        };
        uintptr_t _TypeData;
    };
    static_assert(sizeof(_Storage_t) == _Any_trivial_space_size + sizeof(void*));
    static_assert(is_standard_layout_v<_Storage_t>);

    union {
        _Storage_t _Storage{};
        max_align_t _Dummy;
    };
};

// Non-member functions [any.nonmembers]
_EXPORT_STD inline void swap(any& _Left, any& _Right) noexcept {
    _Left.swap(_Right);
}

_EXPORT_STD template <class _ValueType, class... _Types,
    enable_if_t<is_constructible_v<any, in_place_type_t<_ValueType>, _Types...>, int> = 0>
_NODISCARD any make_any(_Types&&... _Args) { // construct an any containing a _ValueType initialized with _Args...
    return any{in_place_type<_ValueType>, _STD forward<_Types>(_Args)...};
}
_EXPORT_STD template <class _ValueType, class _Elem, class... _Types,
    enable_if_t<is_constructible_v<any, in_place_type_t<_ValueType>, initializer_list<_Elem>&, _Types...>, int> = 0>
_NODISCARD any make_any(initializer_list<_Elem> _Ilist, _Types&&... _Args) {
    // construct an any containing a _ValueType initialized with _Ilist and _Args...
    return any{in_place_type<_ValueType>, _Ilist, _STD forward<_Types>(_Args)...};
}

_EXPORT_STD template <class _ValueType>
_NODISCARD const _ValueType* any_cast(const any* const _Any) noexcept {
    // retrieve a pointer to the _ValueType contained in _Any, or null
    static_assert(!is_void_v<_ValueType>, "std::any cannot contain void.");

    if constexpr (is_function_v<_ValueType> || is_array_v<_ValueType>) {
        return nullptr;
    } else {
        if (!_Any) {
            return nullptr;
        }

        return _Any->_Cast<_Remove_cvref_t<_ValueType>>();
    }
}
_EXPORT_STD template <class _ValueType>
_NODISCARD _ValueType* any_cast(any* const _Any) noexcept {
    // retrieve a pointer to the _ValueType contained in _Any, or null
    static_assert(!is_void_v<_ValueType>, "std::any cannot contain void.");

    if constexpr (is_function_v<_ValueType> || is_array_v<_ValueType>) {
        return nullptr;
    } else {
        if (!_Any) {
            return nullptr;
        }

        return _Any->_Cast<_Remove_cvref_t<_ValueType>>();
    }
}

_EXPORT_STD template <class _Ty>
_NODISCARD remove_cv_t<_Ty> any_cast(const any& _Any) {
    static_assert(is_constructible_v<remove_cv_t<_Ty>, const _Remove_cvref_t<_Ty>&>,
        "any_cast<T>(const any&) requires remove_cv_t<T> to be constructible from "
        "const remove_cv_t<remove_reference_t<T>>&");

    const auto _Ptr = _STD any_cast<_Remove_cvref_t<_Ty>>(&_Any);
    if (!_Ptr) {
        _Throw_bad_any_cast();
    }

    return static_cast<remove_cv_t<_Ty>>(*_Ptr);
}
_EXPORT_STD template <class _Ty>
_NODISCARD remove_cv_t<_Ty> any_cast(any& _Any) {
    static_assert(is_constructible_v<remove_cv_t<_Ty>, _Remove_cvref_t<_Ty>&>,
        "any_cast<T>(any&) requires remove_cv_t<T> to be constructible from remove_cv_t<remove_reference_t<T>>&");

    const auto _Ptr = _STD any_cast<_Remove_cvref_t<_Ty>>(&_Any);
    if (!_Ptr) {
        _Throw_bad_any_cast();
    }

    return static_cast<remove_cv_t<_Ty>>(*_Ptr);
}
_EXPORT_STD template <class _Ty>
_NODISCARD remove_cv_t<_Ty> any_cast(any&& _Any) {
    static_assert(is_constructible_v<remove_cv_t<_Ty>, _Remove_cvref_t<_Ty>>,
        "any_cast<T>(any&&) requires remove_cv_t<T> to be constructible from remove_cv_t<remove_reference_t<T>>");

    const auto _Ptr = _STD any_cast<_Remove_cvref_t<_Ty>>(&_Any);
    if (!_Ptr) {
        _Throw_bad_any_cast();
    }

    return static_cast<remove_cv_t<_Ty>>(_STD move(*_Ptr));
}

_STD_END

#pragma pop_macro("new")
_STL_RESTORE_CLANG_WARNINGS
#pragma warning(pop)
#pragma pack(pop)
#endif // ^^^ _HAS_STATIC_RTTI ^^^

#endif // _STL_COMPILER_PREPROCESSOR
#endif // _ANY_