// Core algorithmic facilities -*- C++ -*- // Copyright (C) 2020-2022 Free Software Foundation, Inc. // // This file is part of the GNU ISO C++ Library. This library is free // software; you can redistribute it and/or modify it under the // terms of the GNU General Public License as published by the // Free Software Foundation; either version 3, or (at your option) // any later version. // This library is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU General Public License for more details. // Under Section 7 of GPL version 3, you are granted additional // permissions described in the GCC Runtime Library Exception, version // 3.1, as published by the Free Software Foundation. // You should have received a copy of the GNU General Public License and // a copy of the GCC Runtime Library Exception along with this program; // see the files COPYING3 and COPYING.RUNTIME respectively. If not, see // . /** @file bits/ranges_algobase.h * This is an internal header file, included by other library headers. * Do not attempt to use it directly. @headername{algorithm} */ #ifndef _RANGES_ALGOBASE_H #define _RANGES_ALGOBASE_H 1 #if __cplusplus > 201703L #include #include #include #include #include // ranges::begin, ranges::range etc. #include // __invoke #include // __is_byte #if __cpp_lib_concepts namespace std _GLIBCXX_VISIBILITY(default) { _GLIBCXX_BEGIN_NAMESPACE_VERSION namespace ranges { namespace __detail { template constexpr inline bool __is_normal_iterator = false; template constexpr inline bool __is_normal_iterator<__gnu_cxx::__normal_iterator<_Iterator, _Container>> = true; template constexpr inline bool __is_reverse_iterator = false; template constexpr inline bool __is_reverse_iterator> = true; template constexpr inline bool __is_move_iterator = false; template constexpr inline bool __is_move_iterator> = true; } // namespace __detail struct __equal_fn { template _Sent1, input_iterator _Iter2, sentinel_for<_Iter2> _Sent2, typename _Pred = ranges::equal_to, typename _Proj1 = identity, typename _Proj2 = identity> requires indirectly_comparable<_Iter1, _Iter2, _Pred, _Proj1, _Proj2> constexpr bool operator()(_Iter1 __first1, _Sent1 __last1, _Iter2 __first2, _Sent2 __last2, _Pred __pred = {}, _Proj1 __proj1 = {}, _Proj2 __proj2 = {}) const { // TODO: implement more specializations to at least have parity with // std::equal. if constexpr (__detail::__is_normal_iterator<_Iter1> && same_as<_Iter1, _Sent1>) return (*this)(__first1.base(), __last1.base(), std::move(__first2), std::move(__last2), std::move(__pred), std::move(__proj1), std::move(__proj2)); else if constexpr (__detail::__is_normal_iterator<_Iter2> && same_as<_Iter2, _Sent2>) return (*this)(std::move(__first1), std::move(__last1), __first2.base(), __last2.base(), std::move(__pred), std::move(__proj1), std::move(__proj2)); else if constexpr (sized_sentinel_for<_Sent1, _Iter1> && sized_sentinel_for<_Sent2, _Iter2>) { auto __d1 = ranges::distance(__first1, __last1); auto __d2 = ranges::distance(__first2, __last2); if (__d1 != __d2) return false; using _ValueType1 = iter_value_t<_Iter1>; constexpr bool __use_memcmp = ((is_integral_v<_ValueType1> || is_pointer_v<_ValueType1>) && __memcmpable<_Iter1, _Iter2>::__value && is_same_v<_Pred, ranges::equal_to> && is_same_v<_Proj1, identity> && is_same_v<_Proj2, identity>); if constexpr (__use_memcmp) { if (const size_t __len = (__last1 - __first1)) return !std::__memcmp(__first1, __first2, __len); return true; } else { for (; __first1 != __last1; ++__first1, (void)++__first2) if (!(bool)std::__invoke(__pred, std::__invoke(__proj1, *__first1), std::__invoke(__proj2, *__first2))) return false; return true; } } else { for (; __first1 != __last1 && __first2 != __last2; ++__first1, (void)++__first2) if (!(bool)std::__invoke(__pred, std::__invoke(__proj1, *__first1), std::__invoke(__proj2, *__first2))) return false; return __first1 == __last1 && __first2 == __last2; } } template requires indirectly_comparable, iterator_t<_Range2>, _Pred, _Proj1, _Proj2> constexpr bool operator()(_Range1&& __r1, _Range2&& __r2, _Pred __pred = {}, _Proj1 __proj1 = {}, _Proj2 __proj2 = {}) const { return (*this)(ranges::begin(__r1), ranges::end(__r1), ranges::begin(__r2), ranges::end(__r2), std::move(__pred), std::move(__proj1), std::move(__proj2)); } }; inline constexpr __equal_fn equal{}; template struct in_out_result { [[no_unique_address]] _Iter in; [[no_unique_address]] _Out out; template requires convertible_to && convertible_to constexpr operator in_out_result<_Iter2, _Out2>() const & { return {in, out}; } template requires convertible_to<_Iter, _Iter2> && convertible_to<_Out, _Out2> constexpr operator in_out_result<_Iter2, _Out2>() && { return {std::move(in), std::move(out)}; } }; template using copy_result = in_out_result<_Iter, _Out>; template using move_result = in_out_result<_Iter, _Out>; template using move_backward_result = in_out_result<_Iter1, _Iter2>; template using copy_backward_result = in_out_result<_Iter1, _Iter2>; template _Sent, bidirectional_iterator _Out> requires (_IsMove ? indirectly_movable<_Iter, _Out> : indirectly_copyable<_Iter, _Out>) constexpr __conditional_t<_IsMove, move_backward_result<_Iter, _Out>, copy_backward_result<_Iter, _Out>> __copy_or_move_backward(_Iter __first, _Sent __last, _Out __result); template _Sent, weakly_incrementable _Out> requires (_IsMove ? indirectly_movable<_Iter, _Out> : indirectly_copyable<_Iter, _Out>) constexpr __conditional_t<_IsMove, move_result<_Iter, _Out>, copy_result<_Iter, _Out>> __copy_or_move(_Iter __first, _Sent __last, _Out __result) { // TODO: implement more specializations to be at least on par with // std::copy/std::move. using __detail::__is_move_iterator; using __detail::__is_reverse_iterator; using __detail::__is_normal_iterator; if constexpr (__is_move_iterator<_Iter> && same_as<_Iter, _Sent>) { auto [__in, __out] = ranges::__copy_or_move(std::move(__first).base(), std::move(__last).base(), std::move(__result)); return {move_iterator{std::move(__in)}, std::move(__out)}; } else if constexpr (__is_reverse_iterator<_Iter> && same_as<_Iter, _Sent> && __is_reverse_iterator<_Out>) { auto [__in,__out] = ranges::__copy_or_move_backward<_IsMove>(std::move(__last).base(), std::move(__first).base(), std::move(__result).base()); return {reverse_iterator{std::move(__in)}, reverse_iterator{std::move(__out)}}; } else if constexpr (__is_normal_iterator<_Iter> && same_as<_Iter, _Sent>) { auto [__in,__out] = ranges::__copy_or_move<_IsMove>(__first.base(), __last.base(), __result); return {decltype(__first){__in}, std::move(__out)}; } else if constexpr (__is_normal_iterator<_Out>) { auto [__in,__out] = ranges::__copy_or_move<_IsMove>(std::move(__first), __last, __result.base()); return {std::move(__in), decltype(__result){__out}}; } else if constexpr (sized_sentinel_for<_Sent, _Iter>) { if (!std::__is_constant_evaluated()) { if constexpr (__memcpyable<_Iter, _Out>::__value) { using _ValueTypeI = iter_value_t<_Iter>; static_assert(_IsMove ? is_move_assignable_v<_ValueTypeI> : is_copy_assignable_v<_ValueTypeI>); auto __num = __last - __first; if (__num) __builtin_memmove(__result, __first, sizeof(_ValueTypeI) * __num); return {__first + __num, __result + __num}; } } for (auto __n = __last - __first; __n > 0; --__n) { if constexpr (_IsMove) *__result = std::move(*__first); else *__result = *__first; ++__first; ++__result; } return {std::move(__first), std::move(__result)}; } else { while (__first != __last) { if constexpr (_IsMove) *__result = std::move(*__first); else *__result = *__first; ++__first; ++__result; } return {std::move(__first), std::move(__result)}; } } struct __copy_fn { template _Sent, weakly_incrementable _Out> requires indirectly_copyable<_Iter, _Out> constexpr copy_result<_Iter, _Out> operator()(_Iter __first, _Sent __last, _Out __result) const { return ranges::__copy_or_move(std::move(__first), std::move(__last), std::move(__result)); } template requires indirectly_copyable, _Out> constexpr copy_result, _Out> operator()(_Range&& __r, _Out __result) const { return (*this)(ranges::begin(__r), ranges::end(__r), std::move(__result)); } }; inline constexpr __copy_fn copy{}; struct __move_fn { template _Sent, weakly_incrementable _Out> requires indirectly_movable<_Iter, _Out> constexpr move_result<_Iter, _Out> operator()(_Iter __first, _Sent __last, _Out __result) const { return ranges::__copy_or_move(std::move(__first), std::move(__last), std::move(__result)); } template requires indirectly_movable, _Out> constexpr move_result, _Out> operator()(_Range&& __r, _Out __result) const { return (*this)(ranges::begin(__r), ranges::end(__r), std::move(__result)); } }; inline constexpr __move_fn move{}; template _Sent, bidirectional_iterator _Out> requires (_IsMove ? indirectly_movable<_Iter, _Out> : indirectly_copyable<_Iter, _Out>) constexpr __conditional_t<_IsMove, move_backward_result<_Iter, _Out>, copy_backward_result<_Iter, _Out>> __copy_or_move_backward(_Iter __first, _Sent __last, _Out __result) { // TODO: implement more specializations to be at least on par with // std::copy_backward/std::move_backward. using __detail::__is_reverse_iterator; using __detail::__is_normal_iterator; if constexpr (__is_reverse_iterator<_Iter> && same_as<_Iter, _Sent> && __is_reverse_iterator<_Out>) { auto [__in,__out] = ranges::__copy_or_move<_IsMove>(std::move(__last).base(), std::move(__first).base(), std::move(__result).base()); return {reverse_iterator{std::move(__in)}, reverse_iterator{std::move(__out)}}; } else if constexpr (__is_normal_iterator<_Iter> && same_as<_Iter, _Sent>) { auto [__in,__out] = ranges::__copy_or_move_backward<_IsMove>(__first.base(), __last.base(), std::move(__result)); return {decltype(__first){__in}, std::move(__out)}; } else if constexpr (__is_normal_iterator<_Out>) { auto [__in,__out] = ranges::__copy_or_move_backward<_IsMove>(std::move(__first), std::move(__last), __result.base()); return {std::move(__in), decltype(__result){__out}}; } else if constexpr (sized_sentinel_for<_Sent, _Iter>) { if (!std::__is_constant_evaluated()) { if constexpr (__memcpyable<_Out, _Iter>::__value) { using _ValueTypeI = iter_value_t<_Iter>; static_assert(_IsMove ? is_move_assignable_v<_ValueTypeI> : is_copy_assignable_v<_ValueTypeI>); auto __num = __last - __first; if (__num) __builtin_memmove(__result - __num, __first, sizeof(_ValueTypeI) * __num); return {__first + __num, __result - __num}; } } auto __lasti = ranges::next(__first, __last); auto __tail = __lasti; for (auto __n = __last - __first; __n > 0; --__n) { --__tail; --__result; if constexpr (_IsMove) *__result = std::move(*__tail); else *__result = *__tail; } return {std::move(__lasti), std::move(__result)}; } else { auto __lasti = ranges::next(__first, __last); auto __tail = __lasti; while (__first != __tail) { --__tail; --__result; if constexpr (_IsMove) *__result = std::move(*__tail); else *__result = *__tail; } return {std::move(__lasti), std::move(__result)}; } } struct __copy_backward_fn { template _Sent1, bidirectional_iterator _Iter2> requires indirectly_copyable<_Iter1, _Iter2> constexpr copy_backward_result<_Iter1, _Iter2> operator()(_Iter1 __first, _Sent1 __last, _Iter2 __result) const { return ranges::__copy_or_move_backward(std::move(__first), std::move(__last), std::move(__result)); } template requires indirectly_copyable, _Iter> constexpr copy_backward_result, _Iter> operator()(_Range&& __r, _Iter __result) const { return (*this)(ranges::begin(__r), ranges::end(__r), std::move(__result)); } }; inline constexpr __copy_backward_fn copy_backward{}; struct __move_backward_fn { template _Sent1, bidirectional_iterator _Iter2> requires indirectly_movable<_Iter1, _Iter2> constexpr move_backward_result<_Iter1, _Iter2> operator()(_Iter1 __first, _Sent1 __last, _Iter2 __result) const { return ranges::__copy_or_move_backward(std::move(__first), std::move(__last), std::move(__result)); } template requires indirectly_movable, _Iter> constexpr move_backward_result, _Iter> operator()(_Range&& __r, _Iter __result) const { return (*this)(ranges::begin(__r), ranges::end(__r), std::move(__result)); } }; inline constexpr __move_backward_fn move_backward{}; template using copy_n_result = in_out_result<_Iter, _Out>; struct __copy_n_fn { template requires indirectly_copyable<_Iter, _Out> constexpr copy_n_result<_Iter, _Out> operator()(_Iter __first, iter_difference_t<_Iter> __n, _Out __result) const { if constexpr (random_access_iterator<_Iter>) { if (__n > 0) return ranges::copy(__first, __first + __n, std::move(__result)); } else { for (; __n > 0; --__n, (void)++__result, (void)++__first) *__result = *__first; } return {std::move(__first), std::move(__result)}; } }; inline constexpr __copy_n_fn copy_n{}; struct __fill_n_fn { template _Out> constexpr _Out operator()(_Out __first, iter_difference_t<_Out> __n, const _Tp& __value) const { // TODO: implement more specializations to be at least on par with // std::fill_n if (__n <= 0) return __first; if constexpr (is_scalar_v<_Tp>) { // TODO: Generalize this optimization to contiguous iterators. if constexpr (is_pointer_v<_Out> // Note that __is_byte already implies !is_volatile. && __is_byte>::__value && integral<_Tp>) { if (!std::__is_constant_evaluated()) { __builtin_memset(__first, static_cast(__value), __n); return __first + __n; } } const auto __tmp = __value; for (; __n > 0; --__n, (void)++__first) *__first = __tmp; return __first; } else { for (; __n > 0; --__n, (void)++__first) *__first = __value; return __first; } } }; inline constexpr __fill_n_fn fill_n{}; struct __fill_fn { template _Out, sentinel_for<_Out> _Sent> constexpr _Out operator()(_Out __first, _Sent __last, const _Tp& __value) const { // TODO: implement more specializations to be at least on par with // std::fill if constexpr (sized_sentinel_for<_Sent, _Out>) { const auto __len = __last - __first; return ranges::fill_n(__first, __len, __value); } else if constexpr (is_scalar_v<_Tp>) { const auto __tmp = __value; for (; __first != __last; ++__first) *__first = __tmp; return __first; } else { for (; __first != __last; ++__first) *__first = __value; return __first; } } template _Range> constexpr borrowed_iterator_t<_Range> operator()(_Range&& __r, const _Tp& __value) const { return (*this)(ranges::begin(__r), ranges::end(__r), __value); } }; inline constexpr __fill_fn fill{}; } _GLIBCXX_END_NAMESPACE_VERSION } // namespace std #endif // concepts #endif // C++20 #endif // _RANGES_ALGOBASE_H