armv7a/usr/armv7a-cros-linux-gnueabihf/usr/include/c++/v1/__type_traits/common_reference.h - manifest_repos/toolchain - 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___TYPE_TRAITS_COMMON_REFERENCE_H
 #define _LIBCPP___TYPE_TRAITS_COMMON_REFERENCE_H

 #include <__config>
 #include <__type_traits/common_type.h>
 #include <__type_traits/copy_cv.h>
 #include <__type_traits/copy_cvref.h>
 #include <__type_traits/is_convertible.h>
 #include <__type_traits/is_reference.h>
 #include <__type_traits/remove_cv.h>
 #include <__type_traits/remove_cvref.h>
 #include <__type_traits/remove_reference.h>
 #include <__utility/declval.h>

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

 _LIBCPP_BEGIN_NAMESPACE_STD

 // common_reference
 #if _LIBCPP_STD_VER > 17
 // Let COND_RES(X, Y) be:
 template <class _Xp, class _Yp>
 using __cond_res =
     decltype(false ? declval<_Xp(&)()>()() : declval<_Yp(&)()>()());

 // Let `XREF(A)` denote a unary alias template `T` such that `T<U>` denotes the same type as `U`
 // with the addition of `A`'s cv and reference qualifiers, for a non-reference cv-unqualified type
 // `U`.
 // [Note: `XREF(A)` is `__xref<A>::template __apply`]
 template <class _Tp>
 struct __xref {
   template<class _Up>
   using __apply = __copy_cvref_t<_Tp, _Up>;
 };

 // Given types A and B, let X be remove_reference_t<A>, let Y be remove_reference_t<B>,
 // and let COMMON-REF(A, B) be:
 template<class _Ap, class _Bp, class _Xp = remove_reference_t<_Ap>, class _Yp = remove_reference_t<_Bp>>
 struct __common_ref;

 template<class _Xp, class _Yp>
 using __common_ref_t = typename __common_ref<_Xp, _Yp>::__type;

 template<class _Xp, class _Yp>
 using __cv_cond_res = __cond_res<__copy_cv_t<_Xp, _Yp>&, __copy_cv_t<_Yp, _Xp>&>;


 //    If A and B are both lvalue reference types, COMMON-REF(A, B) is
 //    COND-RES(COPYCV(X, Y)&, COPYCV(Y, X)&) if that type exists and is a reference type.
 template<class _Ap, class _Bp, class _Xp, class _Yp>
 requires requires { typename __cv_cond_res<_Xp, _Yp>; } && is_reference_v<__cv_cond_res<_Xp, _Yp>>
 struct __common_ref<_Ap&, _Bp&, _Xp, _Yp>
 {
     using __type = __cv_cond_res<_Xp, _Yp>;
 };

 //    Otherwise, let C be remove_reference_t<COMMON-REF(X&, Y&)>&&. ...
 template <class _Xp, class _Yp>
 using __common_ref_C = remove_reference_t<__common_ref_t<_Xp&, _Yp&>>&&;


 //    .... If A and B are both rvalue reference types, C is well-formed, and
 //    is_convertible_v<A, C> && is_convertible_v<B, C> is true, then COMMON-REF(A, B) is C.
 template<class _Ap, class _Bp, class _Xp, class _Yp>
 requires
   requires { typename __common_ref_C<_Xp, _Yp>; } &&
   is_convertible_v<_Ap&&, __common_ref_C<_Xp, _Yp>> &&
   is_convertible_v<_Bp&&, __common_ref_C<_Xp, _Yp>>
 struct __common_ref<_Ap&&, _Bp&&, _Xp, _Yp>
 {
     using __type = __common_ref_C<_Xp, _Yp>;
 };

 //    Otherwise, let D be COMMON-REF(const X&, Y&). ...
 template <class _Tp, class _Up>
 using __common_ref_D = __common_ref_t<const _Tp&, _Up&>;

 //    ... If A is an rvalue reference and B is an lvalue reference and D is well-formed and
 //    is_convertible_v<A, D> is true, then COMMON-REF(A, B) is D.
 template<class _Ap, class _Bp, class _Xp, class _Yp>
 requires requires { typename __common_ref_D<_Xp, _Yp>; } &&
          is_convertible_v<_Ap&&, __common_ref_D<_Xp, _Yp>>
 struct __common_ref<_Ap&&, _Bp&, _Xp, _Yp>
 {
     using __type = __common_ref_D<_Xp, _Yp>;
 };

 //    Otherwise, if A is an lvalue reference and B is an rvalue reference, then
 //    COMMON-REF(A, B) is COMMON-REF(B, A).
 template<class _Ap, class _Bp, class _Xp, class _Yp>
 struct __common_ref<_Ap&, _Bp&&, _Xp, _Yp> : __common_ref<_Bp&&, _Ap&> {};

 //    Otherwise, COMMON-REF(A, B) is ill-formed.
 template<class _Ap, class _Bp, class _Xp, class _Yp>
 struct __common_ref {};

 // Note C: For the common_reference trait applied to a parameter pack [...]

 template <class...>
 struct common_reference;

 template <class... _Types>
 using common_reference_t = typename common_reference<_Types...>::type;

 // bullet 1 - sizeof...(T) == 0
 template<>
 struct common_reference<> {};

 // bullet 2 - sizeof...(T) == 1
 template <class _Tp>
 struct common_reference<_Tp>
 {
     using type = _Tp;
 };

 // bullet 3 - sizeof...(T) == 2
 template <class _Tp, class _Up> struct __common_reference_sub_bullet3;
 template <class _Tp, class _Up> struct __common_reference_sub_bullet2 : __common_reference_sub_bullet3<_Tp, _Up> {};
 template <class _Tp, class _Up> struct __common_reference_sub_bullet1 : __common_reference_sub_bullet2<_Tp, _Up> {};

 // sub-bullet 1 - If T1 and T2 are reference types and COMMON-REF(T1, T2) is well-formed, then
 // the member typedef `type` denotes that type.
 template <class _Tp, class _Up> struct common_reference<_Tp, _Up> : __common_reference_sub_bullet1<_Tp, _Up> {};

 template <class _Tp, class _Up>
 requires is_reference_v<_Tp> && is_reference_v<_Up> && requires { typename __common_ref_t<_Tp, _Up>; }
 struct __common_reference_sub_bullet1<_Tp, _Up>
 {
     using type = __common_ref_t<_Tp, _Up>;
 };

 // sub-bullet 2 - Otherwise, if basic_common_reference<remove_cvref_t<T1>, remove_cvref_t<T2>, XREF(T1), XREF(T2)>::type
 // is well-formed, then the member typedef `type` denotes that type.
 template <class, class, template <class> class, template <class> class> struct basic_common_reference {};

 template <class _Tp, class _Up>
 using __basic_common_reference_t = typename basic_common_reference<
     remove_cvref_t<_Tp>, remove_cvref_t<_Up>,
     __xref<_Tp>::template __apply, __xref<_Up>::template __apply>::type;

 template <class _Tp, class _Up>
 requires requires { typename __basic_common_reference_t<_Tp, _Up>; }
 struct __common_reference_sub_bullet2<_Tp, _Up>
 {
     using type = __basic_common_reference_t<_Tp, _Up>;
 };

 // sub-bullet 3 - Otherwise, if COND-RES(T1, T2) is well-formed,
 // then the member typedef `type` denotes that type.
 template <class _Tp, class _Up>
 requires requires { typename __cond_res<_Tp, _Up>; }
 struct __common_reference_sub_bullet3<_Tp, _Up>
 {
     using type = __cond_res<_Tp, _Up>;
 };


 // sub-bullet 4 & 5 - Otherwise, if common_type_t<T1, T2> is well-formed,
 //                    then the member typedef `type` denotes that type.
 //                  - Otherwise, there shall be no member `type`.
 template <class _Tp, class _Up> struct __common_reference_sub_bullet3 : common_type<_Tp, _Up> {};

 // bullet 4 - If there is such a type `C`, the member typedef type shall denote the same type, if
 //            any, as `common_reference_t<C, Rest...>`.
 template <class _Tp, class _Up, class _Vp, class... _Rest>
 requires requires { typename common_reference_t<_Tp, _Up>; }
 struct common_reference<_Tp, _Up, _Vp, _Rest...>
     : common_reference<common_reference_t<_Tp, _Up>, _Vp, _Rest...>
 {};

 // bullet 5 - Otherwise, there shall be no member `type`.
 template <class...> struct common_reference {};

 #endif // _LIBCPP_STD_VER > 17

 _LIBCPP_END_NAMESPACE_STD

 #endif // _LIBCPP___TYPE_TRAITS_COMMON_REFERENCE_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___TYPE_TRAITS_COMMON_REFERENCE_H
	#define _LIBCPP___TYPE_TRAITS_COMMON_REFERENCE_H

	#include <__config>
	#include <__type_traits/common_type.h>
	#include <__type_traits/copy_cv.h>
	#include <__type_traits/copy_cvref.h>
	#include <__type_traits/is_convertible.h>
	#include <__type_traits/is_reference.h>
	#include <__type_traits/remove_cv.h>
	#include <__type_traits/remove_cvref.h>
	#include <__type_traits/remove_reference.h>
	#include <__utility/declval.h>

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

	_LIBCPP_BEGIN_NAMESPACE_STD

	// common_reference
	#if _LIBCPP_STD_VER > 17
	// Let COND_RES(X, Y) be:
	template <class _Xp, class _Yp>
	using __cond_res =
	decltype(false ? declval<_Xp(&)()>()() : declval<_Yp(&)()>()());

	// Let `XREF(A)` denote a unary alias template `T` such that `T<U>` denotes the same type as `U`
	// with the addition of `A`'s cv and reference qualifiers, for a non-reference cv-unqualified type
	// `U`.
	// [Note: `XREF(A)` is `__xref<A>::template __apply`]
	template <class _Tp>
	struct __xref {
	template<class _Up>
	using __apply = __copy_cvref_t<_Tp, _Up>;
	};

	// Given types A and B, let X be remove_reference_t<A>, let Y be remove_reference_t<B>,
	// and let COMMON-REF(A, B) be:
	template<class _Ap, class _Bp, class _Xp = remove_reference_t<_Ap>, class _Yp = remove_reference_t<_Bp>>
	struct __common_ref;

	template<class _Xp, class _Yp>
	using __common_ref_t = typename __common_ref<_Xp, _Yp>::__type;

	template<class _Xp, class _Yp>
	using __cv_cond_res = __cond_res<__copy_cv_t<_Xp, _Yp>&, __copy_cv_t<_Yp, _Xp>&>;


	// If A and B are both lvalue reference types, COMMON-REF(A, B) is
	// COND-RES(COPYCV(X, Y)&, COPYCV(Y, X)&) if that type exists and is a reference type.
	template<class _Ap, class _Bp, class _Xp, class _Yp>
	requires requires { typename __cv_cond_res<_Xp, _Yp>; } && is_reference_v<__cv_cond_res<_Xp, _Yp>>
	struct __common_ref<_Ap&, _Bp&, _Xp, _Yp>
	{
	using __type = __cv_cond_res<_Xp, _Yp>;
	};

	// Otherwise, let C be remove_reference_t<COMMON-REF(X&, Y&)>&&. ...
	template <class _Xp, class _Yp>
	using __common_ref_C = remove_reference_t<__common_ref_t<_Xp&, _Yp&>>&&;


	// .... If A and B are both rvalue reference types, C is well-formed, and
	// is_convertible_v<A, C> && is_convertible_v<B, C> is true, then COMMON-REF(A, B) is C.
	template<class _Ap, class _Bp, class _Xp, class _Yp>
	requires
	requires { typename __common_ref_C<_Xp, _Yp>; } &&
	is_convertible_v<_Ap&&, __common_ref_C<_Xp, _Yp>> &&
	is_convertible_v<_Bp&&, __common_ref_C<_Xp, _Yp>>
	struct __common_ref<_Ap&&, _Bp&&, _Xp, _Yp>
	{
	using __type = __common_ref_C<_Xp, _Yp>;
	};

	// Otherwise, let D be COMMON-REF(const X&, Y&). ...
	template <class _Tp, class _Up>
	using __common_ref_D = __common_ref_t<const _Tp&, _Up&>;

	// ... If A is an rvalue reference and B is an lvalue reference and D is well-formed and
	// is_convertible_v<A, D> is true, then COMMON-REF(A, B) is D.
	template<class _Ap, class _Bp, class _Xp, class _Yp>
	requires requires { typename __common_ref_D<_Xp, _Yp>; } &&
	is_convertible_v<_Ap&&, __common_ref_D<_Xp, _Yp>>
	struct __common_ref<_Ap&&, _Bp&, _Xp, _Yp>
	{
	using __type = __common_ref_D<_Xp, _Yp>;
	};

	// Otherwise, if A is an lvalue reference and B is an rvalue reference, then
	// COMMON-REF(A, B) is COMMON-REF(B, A).
	template<class _Ap, class _Bp, class _Xp, class _Yp>
	struct __common_ref<_Ap&, _Bp&&, _Xp, _Yp> : __common_ref<_Bp&&, _Ap&> {};

	// Otherwise, COMMON-REF(A, B) is ill-formed.
	template<class _Ap, class _Bp, class _Xp, class _Yp>
	struct __common_ref {};

	// Note C: For the common_reference trait applied to a parameter pack [...]

	template <class...>
	struct common_reference;

	template <class... _Types>
	using common_reference_t = typename common_reference<_Types...>::type;

	// bullet 1 - sizeof...(T) == 0
	template<>
	struct common_reference<> {};

	// bullet 2 - sizeof...(T) == 1
	template <class _Tp>
	struct common_reference<_Tp>
	{
	using type = _Tp;
	};

	// bullet 3 - sizeof...(T) == 2
	template <class _Tp, class _Up> struct __common_reference_sub_bullet3;
	template <class _Tp, class _Up> struct __common_reference_sub_bullet2 : __common_reference_sub_bullet3<_Tp, _Up> {};
	template <class _Tp, class _Up> struct __common_reference_sub_bullet1 : __common_reference_sub_bullet2<_Tp, _Up> {};

	// sub-bullet 1 - If T1 and T2 are reference types and COMMON-REF(T1, T2) is well-formed, then
	// the member typedef `type` denotes that type.
	template <class _Tp, class _Up> struct common_reference<_Tp, _Up> : __common_reference_sub_bullet1<_Tp, _Up> {};

	template <class _Tp, class _Up>
	requires is_reference_v<_Tp> && is_reference_v<_Up> && requires { typename __common_ref_t<_Tp, _Up>; }
	struct __common_reference_sub_bullet1<_Tp, _Up>
	{
	using type = __common_ref_t<_Tp, _Up>;
	};

	// sub-bullet 2 - Otherwise, if basic_common_reference<remove_cvref_t<T1>, remove_cvref_t<T2>, XREF(T1), XREF(T2)>::type
	// is well-formed, then the member typedef `type` denotes that type.
	template <class, class, template <class> class, template <class> class> struct basic_common_reference {};

	template <class _Tp, class _Up>
	using __basic_common_reference_t = typename basic_common_reference<
	remove_cvref_t<_Tp>, remove_cvref_t<_Up>,
	__xref<_Tp>::template __apply, __xref<_Up>::template __apply>::type;

	template <class _Tp, class _Up>
	requires requires { typename __basic_common_reference_t<_Tp, _Up>; }
	struct __common_reference_sub_bullet2<_Tp, _Up>
	{
	using type = __basic_common_reference_t<_Tp, _Up>;
	};

	// sub-bullet 3 - Otherwise, if COND-RES(T1, T2) is well-formed,
	// then the member typedef `type` denotes that type.
	template <class _Tp, class _Up>
	requires requires { typename __cond_res<_Tp, _Up>; }
	struct __common_reference_sub_bullet3<_Tp, _Up>
	{
	using type = __cond_res<_Tp, _Up>;
	};


	// sub-bullet 4 & 5 - Otherwise, if common_type_t<T1, T2> is well-formed,
	// then the member typedef `type` denotes that type.
	// - Otherwise, there shall be no member `type`.
	template <class _Tp, class _Up> struct __common_reference_sub_bullet3 : common_type<_Tp, _Up> {};

	// bullet 4 - If there is such a type `C`, the member typedef type shall denote the same type, if
	// any, as `common_reference_t<C, Rest...>`.
	template <class _Tp, class _Up, class _Vp, class... _Rest>
	requires requires { typename common_reference_t<_Tp, _Up>; }
	struct common_reference<_Tp, _Up, _Vp, _Rest...>
	: common_reference<common_reference_t<_Tp, _Up>, _Vp, _Rest...>
	{};

	// bullet 5 - Otherwise, there shall be no member `type`.
	template <class...> struct common_reference {};

	#endif // _LIBCPP_STD_VER > 17

	_LIBCPP_END_NAMESPACE_STD

	#endif // _LIBCPP___TYPE_TRAITS_COMMON_REFERENCE_H