third_party/llvm-project/libcxx/include/__algorithm/make_projected.h - cobalt - Git at Google

 //===----------------------------------------------------------------------===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//

 #ifndef _LIBCPP___ALGORITHM_MAKE_PROJECTED_H
 #define _LIBCPP___ALGORITHM_MAKE_PROJECTED_H

 #include <__concepts/same_as.h>
 #include <__config>
 #include <__functional/identity.h>
 #include <__functional/invoke.h>
 #include <__type_traits/decay.h>
 #include <__type_traits/enable_if.h>
 #include <__type_traits/integral_constant.h>
 #include <__type_traits/is_member_pointer.h>
 #include <__type_traits/is_same.h>
 #include <__utility/declval.h>
 #include <__utility/forward.h>

 #if !defined(_LIBCPP_HAS_NO_PRAGMA_SYSTEM_HEADER)
 #  pragma GCC system_header
 #endif

 _LIBCPP_BEGIN_NAMESPACE_STD

 template <class _Pred, class _Proj>
 struct _ProjectedPred {
   _Pred& __pred; // Can be a unary or a binary predicate.
   _Proj& __proj;

   _LIBCPP_CONSTEXPR _ProjectedPred(_Pred& __pred_arg, _Proj& __proj_arg) : __pred(__pred_arg), __proj(__proj_arg) {}

   template <class _Tp>
   typename __invoke_of<_Pred&,
                        decltype(std::__invoke(std::declval<_Proj&>(), std::declval<_Tp>()))
   >::type
   _LIBCPP_CONSTEXPR operator()(_Tp&& __v) const {
     return std::__invoke(__pred, std::__invoke(__proj, std::forward<_Tp>(__v)));
   }

   template <class _T1, class _T2>
   typename __invoke_of<_Pred&,
                        decltype(std::__invoke(std::declval<_Proj&>(), std::declval<_T1>())),
                        decltype(std::__invoke(std::declval<_Proj&>(), std::declval<_T2>()))
   >::type
   _LIBCPP_CONSTEXPR operator()(_T1&& __lhs, _T2&& __rhs) const {
     return std::__invoke(__pred,
                       std::__invoke(__proj, std::forward<_T1>(__lhs)),
                       std::__invoke(__proj, std::forward<_T2>(__rhs)));
   }

 };

 template <class _Pred,
           class _Proj,
           __enable_if_t<!(!is_member_pointer<__decay_t<_Pred> >::value &&
                             __is_identity<__decay_t<_Proj> >::value),
                         int> = 0>
 _LIBCPP_HIDE_FROM_ABI _LIBCPP_CONSTEXPR _ProjectedPred<_Pred, _Proj>
 __make_projected(_Pred& __pred, _Proj& __proj) {
   return _ProjectedPred<_Pred, _Proj>(__pred, __proj);
 }

 // Avoid creating the functor and just use the pristine comparator -- for certain algorithms, this would enable
 // optimizations that rely on the type of the comparator. Additionally, this results in less layers of indirection in
 // the call stack when the comparator is invoked, even in an unoptimized build.
 template <class _Pred,
           class _Proj,
           __enable_if_t<!is_member_pointer<__decay_t<_Pred> >::value &&
                           __is_identity<__decay_t<_Proj> >::value,
                         int> = 0>
 _LIBCPP_HIDE_FROM_ABI _LIBCPP_CONSTEXPR _Pred& __make_projected(_Pred& __pred, _Proj&) {
   return __pred;
 }

 _LIBCPP_END_NAMESPACE_STD

 #if _LIBCPP_STD_VER >= 20

 _LIBCPP_BEGIN_NAMESPACE_STD

 namespace ranges {

 template <class _Comp, class _Proj1, class _Proj2>
 _LIBCPP_HIDE_FROM_ABI constexpr
 decltype(auto) __make_projected_comp(_Comp& __comp, _Proj1& __proj1, _Proj2& __proj2) {
   if constexpr (__is_identity<decay_t<_Proj1>>::value && __is_identity<decay_t<_Proj2>>::value &&
                 !is_member_pointer_v<decay_t<_Comp>>) {
     // Avoid creating the lambda and just use the pristine comparator -- for certain algorithms, this would enable
     // optimizations that rely on the type of the comparator.
     return __comp;

   } else {
     return [&](auto&& __lhs, auto&& __rhs) {
       return std::invoke(__comp,
                         std::invoke(__proj1, std::forward<decltype(__lhs)>(__lhs)),
                         std::invoke(__proj2, std::forward<decltype(__rhs)>(__rhs)));
     };
   }
 }

 } // namespace ranges

 _LIBCPP_END_NAMESPACE_STD

 #endif // _LIBCPP_STD_VER >= 20

 #endif // _LIBCPP___ALGORITHM_MAKE_PROJECTED_H
	//===----------------------------------------------------------------------===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//

	#ifndef _LIBCPP___ALGORITHM_MAKE_PROJECTED_H
	#define _LIBCPP___ALGORITHM_MAKE_PROJECTED_H

	#include <__concepts/same_as.h>
	#include <__config>
	#include <__functional/identity.h>
	#include <__functional/invoke.h>
	#include <__type_traits/decay.h>
	#include <__type_traits/enable_if.h>
	#include <__type_traits/integral_constant.h>
	#include <__type_traits/is_member_pointer.h>
	#include <__type_traits/is_same.h>
	#include <__utility/declval.h>
	#include <__utility/forward.h>

	#if !defined(_LIBCPP_HAS_NO_PRAGMA_SYSTEM_HEADER)
	# pragma GCC system_header
	#endif

	_LIBCPP_BEGIN_NAMESPACE_STD

	template <class _Pred, class _Proj>
	struct _ProjectedPred {
	_Pred& __pred; // Can be a unary or a binary predicate.
	_Proj& __proj;

	_LIBCPP_CONSTEXPR _ProjectedPred(_Pred& __pred_arg, _Proj& __proj_arg) : __pred(__pred_arg), __proj(__proj_arg) {}

	template <class _Tp>
	typename __invoke_of<_Pred&,
	decltype(std::__invoke(std::declval<_Proj&>(), std::declval<_Tp>()))
	>::type
	_LIBCPP_CONSTEXPR operator()(_Tp&& __v) const {
	return std::__invoke(__pred, std::__invoke(__proj, std::forward<_Tp>(__v)));
	}

	template <class _T1, class _T2>
	typename __invoke_of<_Pred&,
	decltype(std::__invoke(std::declval<_Proj&>(), std::declval<_T1>())),
	decltype(std::__invoke(std::declval<_Proj&>(), std::declval<_T2>()))
	>::type
	_LIBCPP_CONSTEXPR operator()(_T1&& __lhs, _T2&& __rhs) const {
	return std::__invoke(__pred,
	std::__invoke(__proj, std::forward<_T1>(__lhs)),
	std::__invoke(__proj, std::forward<_T2>(__rhs)));
	}

	};

	template <class _Pred,
	class _Proj,
	__enable_if_t<!(!is_member_pointer<__decay_t<_Pred> >::value &&
	__is_identity<__decay_t<_Proj> >::value),
	int> = 0>
	_LIBCPP_HIDE_FROM_ABI _LIBCPP_CONSTEXPR _ProjectedPred<_Pred, _Proj>
	__make_projected(_Pred& __pred, _Proj& __proj) {
	return _ProjectedPred<_Pred, _Proj>(__pred, __proj);
	}

	// Avoid creating the functor and just use the pristine comparator -- for certain algorithms, this would enable
	// optimizations that rely on the type of the comparator. Additionally, this results in less layers of indirection in
	// the call stack when the comparator is invoked, even in an unoptimized build.
	template <class _Pred,
	class _Proj,
	__enable_if_t<!is_member_pointer<__decay_t<_Pred> >::value &&
	__is_identity<__decay_t<_Proj> >::value,
	int> = 0>
	_LIBCPP_HIDE_FROM_ABI _LIBCPP_CONSTEXPR _Pred& __make_projected(_Pred& __pred, _Proj&) {
	return __pred;
	}

	_LIBCPP_END_NAMESPACE_STD

	#if _LIBCPP_STD_VER >= 20

	_LIBCPP_BEGIN_NAMESPACE_STD

	namespace ranges {

	template <class _Comp, class _Proj1, class _Proj2>
	_LIBCPP_HIDE_FROM_ABI constexpr
	decltype(auto) __make_projected_comp(_Comp& __comp, _Proj1& __proj1, _Proj2& __proj2) {
	if constexpr (__is_identity<decay_t<_Proj1>>::value && __is_identity<decay_t<_Proj2>>::value &&
	!is_member_pointer_v<decay_t<_Comp>>) {
	// Avoid creating the lambda and just use the pristine comparator -- for certain algorithms, this would enable
	// optimizations that rely on the type of the comparator.
	return __comp;

	} else {
	return [&](auto&& __lhs, auto&& __rhs) {
	return std::invoke(__comp,
	std::invoke(__proj1, std::forward<decltype(__lhs)>(__lhs)),
	std::invoke(__proj2, std::forward<decltype(__rhs)>(__rhs)));
	};
	}
	}

	} // namespace ranges

	_LIBCPP_END_NAMESPACE_STD

	#endif // _LIBCPP_STD_VER >= 20

	#endif // _LIBCPP___ALGORITHM_MAKE_PROJECTED_H