verdnatura-chat/ios/Pods/Flipper-Folly/folly/lang/PropagateConst.h

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/*
* Copyright (c) Facebook, Inc. and its affiliates.
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#pragma once
#include <functional>
#include <type_traits>
#include <utility>
#include <folly/Traits.h>
#include <folly/Utility.h>
namespace folly {
template <typename Pointer>
class propagate_const;
template <typename Pointer>
constexpr Pointer& get_underlying(propagate_const<Pointer>& obj) {
return obj.pointer_;
}
template <typename Pointer>
constexpr Pointer const& get_underlying(propagate_const<Pointer> const& obj) {
return obj.pointer_;
}
namespace detail {
template <class Pointer>
using is_propagate_const = is_instantiation_of<propagate_const, Pointer>;
template <typename T>
using is_decay_propagate_const = is_propagate_const<std::decay_t<T>>;
namespace propagate_const_adl {
using std::swap;
template <typename T>
auto adl_swap(T& a, T& b) noexcept(noexcept(swap(a, b)))
-> decltype(swap(a, b)) {
swap(a, b);
}
} // namespace propagate_const_adl
} // namespace detail
// mimic: std::experimental::propagate_const, C++ Library Fundamentals TS v2
template <typename Pointer>
class propagate_const {
public:
using element_type =
std::remove_reference_t<decltype(*std::declval<Pointer&>())>;
constexpr propagate_const() = default;
constexpr propagate_const(propagate_const&&) = default;
propagate_const(propagate_const const&) = delete;
template <
typename OtherPointer,
std::enable_if_t<
std::is_constructible<Pointer, OtherPointer&&>::value &&
!std::is_convertible<OtherPointer&&, Pointer>::value,
int> = 0>
constexpr explicit propagate_const(propagate_const<OtherPointer>&& other)
: pointer_(static_cast<OtherPointer&&>(other.pointer_)) {}
template <
typename OtherPointer,
std::enable_if_t<
std::is_constructible<Pointer, OtherPointer&&>::value &&
std::is_convertible<OtherPointer&&, Pointer>::value,
int> = 0>
constexpr propagate_const(propagate_const<OtherPointer>&& other)
: pointer_(static_cast<OtherPointer&&>(other.pointer_)) {}
template <
typename OtherPointer,
std::enable_if_t<
!detail::is_decay_propagate_const<OtherPointer>::value &&
std::is_constructible<Pointer, OtherPointer&&>::value &&
!std::is_convertible<OtherPointer&&, Pointer>::value,
int> = 0>
constexpr explicit propagate_const(OtherPointer&& other)
: pointer_(static_cast<OtherPointer&&>(other)) {}
template <
typename OtherPointer,
std::enable_if_t<
!detail::is_decay_propagate_const<OtherPointer>::value &&
std::is_constructible<Pointer, OtherPointer&&>::value &&
std::is_convertible<OtherPointer&&, Pointer>::value,
int> = 0>
constexpr propagate_const(OtherPointer&& other)
: pointer_(static_cast<OtherPointer&&>(other)) {}
constexpr propagate_const& operator=(propagate_const&&) = default;
propagate_const& operator=(propagate_const const&) = delete;
template <
typename OtherPointer,
typename =
std::enable_if_t<std::is_convertible<OtherPointer&&, Pointer>::value>>
constexpr propagate_const& operator=(propagate_const<OtherPointer>&& other) {
pointer_ = static_cast<OtherPointer&&>(other.pointer_);
}
template <
typename OtherPointer,
typename = std::enable_if_t<
!detail::is_decay_propagate_const<OtherPointer>::value &&
std::is_convertible<OtherPointer&&, Pointer>::value>>
constexpr propagate_const& operator=(OtherPointer&& other) {
pointer_ = static_cast<OtherPointer&&>(other);
return *this;
}
constexpr void swap(propagate_const& other) noexcept(
noexcept(detail::propagate_const_adl::adl_swap(
std::declval<Pointer&>(),
other.pointer_))) {
detail::propagate_const_adl::adl_swap(pointer_, other.pointer_);
}
constexpr element_type* get() {
return get_(pointer_);
}
constexpr element_type const* get() const {
return get_(pointer_);
}
constexpr explicit operator bool() const {
return static_cast<bool>(pointer_);
}
constexpr element_type& operator*() {
return *get();
}
constexpr element_type const& operator*() const {
return *get();
}
constexpr element_type* operator->() {
return get();
}
constexpr element_type const* operator->() const {
return get();
}
template <
typename OtherPointer = Pointer,
typename = std::enable_if_t<
std::is_pointer<OtherPointer>::value ||
std::is_convertible<OtherPointer, element_type*>::value>>
constexpr operator element_type*() {
return get();
}
template <
typename OtherPointer = Pointer,
typename = std::enable_if_t<
std::is_pointer<OtherPointer>::value ||
std::is_convertible<OtherPointer, element_type const*>::value>>
constexpr operator element_type const*() const {
return get();
}
private:
friend Pointer& get_underlying<>(propagate_const&);
friend Pointer const& get_underlying<>(propagate_const const&);
template <typename OtherPointer>
friend class propagate_const;
template <typename T>
constexpr static T* get_(T* t) {
return t;
}
template <typename T>
constexpr static auto get_(T& t) -> decltype(t.get()) {
return t.get();
}
Pointer pointer_;
};
template <typename Pointer>
constexpr void swap(
propagate_const<Pointer>& a,
propagate_const<Pointer>& b) noexcept(noexcept(a.swap(b))) {
a.swap(b);
}
template <typename Pointer>
constexpr bool operator==(propagate_const<Pointer> const& a, std::nullptr_t) {
return get_underlying(a) == nullptr;
}
template <typename Pointer>
constexpr bool operator==(std::nullptr_t, propagate_const<Pointer> const& a) {
return nullptr == get_underlying(a);
}
template <typename Pointer>
constexpr bool operator!=(propagate_const<Pointer> const& a, std::nullptr_t) {
return get_underlying(a) != nullptr;
}
template <typename Pointer>
constexpr bool operator!=(std::nullptr_t, propagate_const<Pointer> const& a) {
return nullptr != get_underlying(a);
}
template <typename Pointer>
constexpr bool operator==(
propagate_const<Pointer> const& a,
propagate_const<Pointer> const& b) {
return get_underlying(a) == get_underlying(b);
}
template <typename Pointer>
constexpr bool operator!=(
propagate_const<Pointer> const& a,
propagate_const<Pointer> const& b) {
return get_underlying(a) != get_underlying(b);
}
template <typename Pointer>
constexpr bool operator<(
propagate_const<Pointer> const& a,
propagate_const<Pointer> const& b) {
return get_underlying(a) < get_underlying(b);
}
template <typename Pointer>
constexpr bool operator<=(
propagate_const<Pointer> const& a,
propagate_const<Pointer> const& b) {
return get_underlying(a) <= get_underlying(b);
}
template <typename Pointer>
constexpr bool operator>(
propagate_const<Pointer> const& a,
propagate_const<Pointer> const& b) {
return get_underlying(a) > get_underlying(b);
}
template <typename Pointer>
constexpr bool operator>=(
propagate_const<Pointer> const& a,
propagate_const<Pointer> const& b) {
return get_underlying(a) >= get_underlying(b);
}
// Note: contrary to the specification, the heterogeneous comparison operators
// only participate in overload resolution when the equivalent heterogeneous
// comparison operators on the underlying pointers, as returned by invocation
// of get_underlying, would also participate in overload resolution.
template <typename Pointer, typename Other>
constexpr auto operator==(propagate_const<Pointer> const& a, Other const& b)
-> decltype(get_underlying(a) == b, false) {
return get_underlying(a) == b;
}
template <typename Pointer, typename Other>
constexpr auto operator!=(propagate_const<Pointer> const& a, Other const& b)
-> decltype(get_underlying(a) != b, false) {
return get_underlying(a) != b;
}
template <typename Pointer, typename Other>
constexpr auto operator<(propagate_const<Pointer> const& a, Other const& b)
-> decltype(get_underlying(a) < b, false) {
return get_underlying(a) < b;
}
template <typename Pointer, typename Other>
constexpr auto operator<=(propagate_const<Pointer> const& a, Other const& b)
-> decltype(get_underlying(a) <= b, false) {
return get_underlying(a) <= b;
}
template <typename Pointer, typename Other>
constexpr auto operator>(propagate_const<Pointer> const& a, Other const& b)
-> decltype(get_underlying(a) > b, false) {
return get_underlying(a) > b;
}
template <typename Pointer, typename Other>
constexpr auto operator>=(propagate_const<Pointer> const& a, Other const& b)
-> decltype(get_underlying(a) >= b, false) {
return get_underlying(a) >= b;
}
template <typename Other, typename Pointer>
constexpr auto operator==(Other const& a, propagate_const<Pointer> const& b)
-> decltype(a == get_underlying(b), false) {
return a == get_underlying(b);
}
template <typename Other, typename Pointer>
constexpr auto operator!=(Other const& a, propagate_const<Pointer> const& b)
-> decltype(a != get_underlying(b), false) {
return a != get_underlying(b);
}
template <typename Other, typename Pointer>
constexpr auto operator<(Other const& a, propagate_const<Pointer> const& b)
-> decltype(a < get_underlying(b), false) {
return a < get_underlying(b);
}
template <typename Other, typename Pointer>
constexpr auto operator<=(Other const& a, propagate_const<Pointer> const& b)
-> decltype(a <= get_underlying(b), false) {
return a <= get_underlying(b);
}
template <typename Other, typename Pointer>
constexpr auto operator>(Other const& a, propagate_const<Pointer> const& b)
-> decltype(a > get_underlying(b), false) {
return a > get_underlying(b);
}
template <typename Other, typename Pointer>
constexpr auto operator>=(Other const& a, propagate_const<Pointer> const& b)
-> decltype(a >= get_underlying(b), false) {
return a >= get_underlying(b);
}
} // namespace folly
namespace std {
template <typename Pointer>
struct hash<folly::propagate_const<Pointer>> : private hash<Pointer> {
using hash<Pointer>::hash;
size_t operator()(folly::propagate_const<Pointer> const& obj) const {
return hash<Pointer>::operator()(folly::get_underlying(obj));
}
};
template <typename Pointer>
struct equal_to<folly::propagate_const<Pointer>> : private equal_to<Pointer> {
using equal_to<Pointer>::equal_to;
constexpr bool operator()(
folly::propagate_const<Pointer> const& a,
folly::propagate_const<Pointer> const& b) {
return equal_to<Pointer>::operator()(
folly::get_underlying(a), folly::get_underlying(b));
}
};
template <typename Pointer>
struct not_equal_to<folly::propagate_const<Pointer>>
: private not_equal_to<Pointer> {
using not_equal_to<Pointer>::not_equal_to;
constexpr bool operator()(
folly::propagate_const<Pointer> const& a,
folly::propagate_const<Pointer> const& b) {
return not_equal_to<Pointer>::operator()(
folly::get_underlying(a), folly::get_underlying(b));
}
};
template <typename Pointer>
struct less<folly::propagate_const<Pointer>> : private less<Pointer> {
using less<Pointer>::less;
constexpr bool operator()(
folly::propagate_const<Pointer> const& a,
folly::propagate_const<Pointer> const& b) {
return less<Pointer>::operator()(
folly::get_underlying(a), folly::get_underlying(b));
}
};
template <typename Pointer>
struct greater<folly::propagate_const<Pointer>> : private greater<Pointer> {
using greater<Pointer>::greater;
constexpr bool operator()(
folly::propagate_const<Pointer> const& a,
folly::propagate_const<Pointer> const& b) {
return greater<Pointer>::operator()(
folly::get_underlying(a), folly::get_underlying(b));
}
};
template <typename Pointer>
struct less_equal<folly::propagate_const<Pointer>>
: private less_equal<Pointer> {
using less_equal<Pointer>::less_equal;
constexpr bool operator()(
folly::propagate_const<Pointer> const& a,
folly::propagate_const<Pointer> const& b) {
return less_equal<Pointer>::operator()(
folly::get_underlying(a), folly::get_underlying(b));
}
};
template <typename Pointer>
struct greater_equal<folly::propagate_const<Pointer>>
: private greater_equal<Pointer> {
using greater_equal<Pointer>::greater_equal;
constexpr bool operator()(
folly::propagate_const<Pointer> const& a,
folly::propagate_const<Pointer> const& b) {
return greater_equal<Pointer>::operator()(
folly::get_underlying(a), folly::get_underlying(b));
}
};
} // namespace std