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#pragma once
#include <typeinfo>
#include <type_traits>
#include <stdexcept>
namespace mbgl {
namespace util {
class bad_any_cast : public std::bad_cast {
public:
const char* what() const noexcept override {
return "bad any_cast<>()";
}
};
/**
* A variant of `std::any` for non-copyable types.
*
* Use `unique_any` for non-copyable types (e.g. `std::unique_ptr<T>`)
* or to ensure that no copies are made of copyable types that are
* moved in.
*
* `uniqe_any` differs from `std::any` in that it does not support copy construction
* or copy assignment. It also does not require the contained type to be copy
* constructible.
*
* The `any_cast<T>()` methods work similar to `std::any_cast<T>()` except that
* non-copyable types may only be cast to references.
*
* Example usage:
* unique_any u1(3);
* auto u2 = unique_any(std::move(u1)); // u1 is moved from
* int i = any_cast<int>(u2);
*
* unique_any u2;
* u2 = std::unique_ptr<int>(new int);
* std::unique_ptr<int> iPtr = any_cast<std::unique_ptr<int>>(std::move(u2));
*
* Inspired by linb::any (https://github.com/thelink2012/any) and the
* libc++ implementation (https://github.com/llvm-mirror/libcxx).
*/
class unique_any final
{
public:
unique_any() = default;
//Copy constructor (deleted)
unique_any(const unique_any& rhs) = delete;
unique_any(unique_any&& rhs) : vtable(rhs.vtable) {
if (vtable) {
vtable->move(std::move(rhs.storage), storage);
}
rhs.vtable = nullptr;
}
// Constructs with a direct-initilizated object of type ValueType
template <typename ValueType,
typename _Vt = std::decay_t<ValueType>,
typename = std::enable_if_t<!std::is_same<_Vt, unique_any>::value> >
unique_any(ValueType&& value) {
create(std::forward<ValueType>(value));
}
~unique_any() {
reset();
}
unique_any& operator=(unique_any&& rhs) {
unique_any(std::move(rhs)).swap(*this);
return *this;
}
template <class ValueType,
typename = std::enable_if_t<!std::is_same<std::decay_t<ValueType>, unique_any>::value> >
unique_any& operator=(ValueType&& rhs) {
unique_any(std::forward<ValueType>(rhs)).swap(*this);
return *this;
}
void reset() {
if (vtable) {
vtable->destroy(storage);
vtable = nullptr;
}
}
void swap(unique_any& rhs) {
if (this == &rhs) {
return;
} else {
unique_any tmp(std::move(rhs));
rhs.vtable = vtable;
if (rhs.vtable) {
rhs.vtable->move(std::move(storage), rhs.storage);
}
vtable = tmp.vtable;
if (vtable) {
vtable->move(std::move(tmp.storage), storage);
}
}
}
const std::type_info& type() const {
return !has_value()? typeid(void) : vtable->type();
}
bool has_value() const {
return vtable != nullptr;
}
private:
union Storage {
using StackStorage = std::aligned_storage_t<3*sizeof(void*), std::alignment_of<void*>::value>;
Storage() = default;
void * dynamic { nullptr };
StackStorage stack;
};
template<typename T>
struct AllocateOnStack : std::integral_constant<bool,
sizeof(T) <= sizeof(Storage::stack)
&& std::alignment_of<T>::value <= std::alignment_of<Storage::StackStorage>::value
&& std::is_nothrow_move_constructible<T>::value> {
};
struct VTable {
virtual ~VTable() = default;
virtual void move(Storage&& src, Storage& dest) = 0;
virtual void destroy(Storage&) = 0;
virtual const std::type_info& type() = 0;
};
template <typename ValueType>
struct VTableHeap : public VTable {
void move(Storage&& src, Storage& dest) override {
destroy(dest);
dest.dynamic = src.dynamic;
}
void destroy(Storage& s) override {
if (s.dynamic) {
delete reinterpret_cast<ValueType*>(s.dynamic);
}
s.dynamic = nullptr;
}
const std::type_info& type() override {
return typeid(ValueType);
}
};
template <typename ValueType>
struct VTableStack : public VTable {
void move(Storage&& src, Storage& dest) override {
auto srcValue = reinterpret_cast<ValueType&&>(src.stack);
new (static_cast<void*>(&dest.stack)) ValueType(std::move(srcValue));
srcValue.~ValueType();
}
void destroy(Storage& s) override {
reinterpret_cast<ValueType&>(s.stack).~ValueType();
}
const std::type_info& type() override {
return typeid(ValueType);
}
};
template <typename ValueType>
static VTable* vtableForType() {
using VTableType = std::conditional_t<AllocateOnStack<ValueType>::value, VTableStack<ValueType>, VTableHeap<ValueType> >;
static VTableType vtable;
return &vtable;
}
template <typename ValueType, typename _Vt>
std::enable_if_t<AllocateOnStack<_Vt>::value>
createStorage(ValueType&& value) {
new (static_cast<void*>(&storage.stack)) _Vt(std::forward<ValueType>(value));
}
template <typename ValueType, typename _Vt>
std::enable_if_t<!AllocateOnStack<_Vt>::value>
createStorage(ValueType&& value) {
storage.dynamic = static_cast<void*>(new _Vt(std::forward<ValueType>(value)));
}
template <typename ValueType>
void create(ValueType&& value) {
using _Vt = std::decay_t<ValueType>;
vtable = vtableForType<_Vt>();
createStorage<ValueType, _Vt>(std::forward<ValueType>(value));
}
VTable* vtable { nullptr };
Storage storage;
protected:
template<class ValueType>
friend const ValueType* any_cast(const unique_any* operand) ;
template<class ValueType>
friend ValueType* any_cast(unique_any* operand) ;
template<typename ValueType, typename _Vt = std::decay_t<ValueType> >
ValueType* cast()
{
return reinterpret_cast<ValueType *>(
AllocateOnStack<_Vt>::value ? &storage.stack : storage.dynamic);
}
};
template<typename ValueType>
inline const ValueType* any_cast(const unique_any* any)
{
return any_cast<ValueType>(const_cast<unique_any *>(any));
}
template<typename ValueType>
inline ValueType* any_cast(unique_any* any)
{
if(any == nullptr || any->type() != typeid(ValueType))
return nullptr;
else
return any->cast<ValueType>();
}
template<typename ValueType, typename _Vt = std::decay_t<ValueType> >
inline ValueType any_cast(const unique_any& any)
{
static_assert(std::is_constructible<ValueType, const _Vt&>::value,
"any_cast type can't construct copy of contained object");
auto temp = any_cast<_Vt>(&any);
if (temp == nullptr) {
throw bad_any_cast();
}
return static_cast<ValueType>(*temp);
}
template<typename ValueType, typename _Vt = std::decay_t<ValueType> >
inline ValueType any_cast(unique_any& any)
{
static_assert(std::is_constructible<ValueType, const _Vt&>::value,
"any_cast type can't construct copy of contained object");
auto temp = any_cast<_Vt>(&any);
if (temp == nullptr) {
throw bad_any_cast();
}
return static_cast<ValueType>(*temp);
}
template<typename ValueType, typename _Vt = std::remove_cv_t<ValueType> >
inline ValueType any_cast(unique_any&& any)
{
auto temp = any_cast<_Vt>(&any);
if (temp == nullptr) {
throw bad_any_cast();
}
auto retValue = static_cast<ValueType>(std::move(*temp));
any.reset();
return std::move(retValue);
}
} // namespace util
} // namespace mbgl
namespace std {
inline void swap(mbgl::util::unique_any& lhs, mbgl::util::unique_any& rhs) {
lhs.swap(rhs);
}
} // namespace std
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