//===----------------------------------------------------------------------===// // // 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_SORT_H #define _LIBCPP___ALGORITHM_SORT_H #include <__algorithm/comp.h> #include <__algorithm/comp_ref_type.h> #include <__algorithm/iter_swap.h> #include <__algorithm/iterator_operations.h> #include <__algorithm/min_element.h> #include <__algorithm/partial_sort.h> #include <__algorithm/unwrap_iter.h> #include <__assert> #include <__bit/blsr.h> #include <__bit/countl.h> #include <__bit/countr.h> #include <__config> #include <__debug_utils/randomize_range.h> #include <__debug_utils/strict_weak_ordering_check.h> #include <__functional/operations.h> #include <__functional/ranges_operations.h> #include <__iterator/iterator_traits.h> #include <__type_traits/conditional.h> #include <__type_traits/disjunction.h> #include <__type_traits/is_arithmetic.h> #include <__type_traits/is_constant_evaluated.h> #include <__utility/move.h> #include <__utility/pair.h> #include #include #if !defined(_LIBCPP_HAS_NO_PRAGMA_SYSTEM_HEADER) # pragma GCC system_header #endif _LIBCPP_PUSH_MACROS #include <__undef_macros> _LIBCPP_BEGIN_NAMESPACE_STD // stable, 2-3 compares, 0-2 swaps template _LIBCPP_HIDE_FROM_ABI _LIBCPP_CONSTEXPR_SINCE_CXX14 unsigned __sort3(_ForwardIterator __x, _ForwardIterator __y, _ForwardIterator __z, _Compare __c) { using _Ops = _IterOps<_AlgPolicy>; unsigned __r = 0; if (!__c(*__y, *__x)) // if x <= y { if (!__c(*__z, *__y)) // if y <= z return __r; // x <= y && y <= z // x <= y && y > z _Ops::iter_swap(__y, __z); // x <= z && y < z __r = 1; if (__c(*__y, *__x)) // if x > y { _Ops::iter_swap(__x, __y); // x < y && y <= z __r = 2; } return __r; // x <= y && y < z } if (__c(*__z, *__y)) // x > y, if y > z { _Ops::iter_swap(__x, __z); // x < y && y < z __r = 1; return __r; } _Ops::iter_swap(__x, __y); // x > y && y <= z __r = 1; // x < y && x <= z if (__c(*__z, *__y)) // if y > z { _Ops::iter_swap(__y, __z); // x <= y && y < z __r = 2; } return __r; } // x <= y && y <= z // stable, 3-6 compares, 0-5 swaps template _LIBCPP_HIDE_FROM_ABI void __sort4(_ForwardIterator __x1, _ForwardIterator __x2, _ForwardIterator __x3, _ForwardIterator __x4, _Compare __c) { using _Ops = _IterOps<_AlgPolicy>; std::__sort3<_AlgPolicy, _Compare>(__x1, __x2, __x3, __c); if (__c(*__x4, *__x3)) { _Ops::iter_swap(__x3, __x4); if (__c(*__x3, *__x2)) { _Ops::iter_swap(__x2, __x3); if (__c(*__x2, *__x1)) { _Ops::iter_swap(__x1, __x2); } } } } // stable, 4-10 compares, 0-9 swaps template _LIBCPP_HIDE_FROM_ABI void __sort5(_ForwardIterator __x1, _ForwardIterator __x2, _ForwardIterator __x3, _ForwardIterator __x4, _ForwardIterator __x5, _Comp __comp) { using _Ops = _IterOps<_AlgPolicy>; std::__sort4<_AlgPolicy, _Comp>(__x1, __x2, __x3, __x4, __comp); if (__comp(*__x5, *__x4)) { _Ops::iter_swap(__x4, __x5); if (__comp(*__x4, *__x3)) { _Ops::iter_swap(__x3, __x4); if (__comp(*__x3, *__x2)) { _Ops::iter_swap(__x2, __x3); if (__comp(*__x2, *__x1)) { _Ops::iter_swap(__x1, __x2); } } } } } // The comparator being simple is a prerequisite for using the branchless optimization. template struct __is_simple_comparator : false_type {}; template <> struct __is_simple_comparator<__less<>&> : true_type {}; template struct __is_simple_comparator&> : true_type {}; template struct __is_simple_comparator&> : true_type {}; #if _LIBCPP_STD_VER >= 20 template <> struct __is_simple_comparator : true_type {}; template <> struct __is_simple_comparator : true_type {}; #endif template ::value_type> using __use_branchless_sort = integral_constant::value && sizeof(_Tp) <= sizeof(void*) && is_arithmetic<_Tp>::value && __is_simple_comparator<_Compare>::value>; namespace __detail { // Size in bits for the bitset in use. enum { __block_size = sizeof(uint64_t) * 8 }; } // namespace __detail // Ensures that __c(*__x, *__y) is true by swapping *__x and *__y if necessary. template inline _LIBCPP_HIDE_FROM_ABI void __cond_swap(_RandomAccessIterator __x, _RandomAccessIterator __y, _Compare __c) { // Note: this function behaves correctly even with proxy iterators (because it relies on `value_type`). using value_type = typename iterator_traits<_RandomAccessIterator>::value_type; bool __r = __c(*__x, *__y); value_type __tmp = __r ? *__x : *__y; *__y = __r ? *__y : *__x; *__x = __tmp; } // Ensures that *__x, *__y and *__z are ordered according to the comparator __c, // under the assumption that *__y and *__z are already ordered. template inline _LIBCPP_HIDE_FROM_ABI void __partially_sorted_swap(_RandomAccessIterator __x, _RandomAccessIterator __y, _RandomAccessIterator __z, _Compare __c) { // Note: this function behaves correctly even with proxy iterators (because it relies on `value_type`). using value_type = typename iterator_traits<_RandomAccessIterator>::value_type; bool __r = __c(*__z, *__x); value_type __tmp = __r ? *__z : *__x; *__z = __r ? *__x : *__z; __r = __c(__tmp, *__y); *__x = __r ? *__x : *__y; *__y = __r ? *__y : __tmp; } template ::value, int> = 0> inline _LIBCPP_HIDE_FROM_ABI void __sort3_maybe_branchless( _RandomAccessIterator __x1, _RandomAccessIterator __x2, _RandomAccessIterator __x3, _Compare __c) { std::__cond_swap<_Compare>(__x2, __x3, __c); std::__partially_sorted_swap<_Compare>(__x1, __x2, __x3, __c); } template ::value, int> = 0> inline _LIBCPP_HIDE_FROM_ABI void __sort3_maybe_branchless( _RandomAccessIterator __x1, _RandomAccessIterator __x2, _RandomAccessIterator __x3, _Compare __c) { std::__sort3<_AlgPolicy, _Compare>(__x1, __x2, __x3, __c); } template ::value, int> = 0> inline _LIBCPP_HIDE_FROM_ABI void __sort4_maybe_branchless( _RandomAccessIterator __x1, _RandomAccessIterator __x2, _RandomAccessIterator __x3, _RandomAccessIterator __x4, _Compare __c) { std::__cond_swap<_Compare>(__x1, __x3, __c); std::__cond_swap<_Compare>(__x2, __x4, __c); std::__cond_swap<_Compare>(__x1, __x2, __c); std::__cond_swap<_Compare>(__x3, __x4, __c); std::__cond_swap<_Compare>(__x2, __x3, __c); } template ::value, int> = 0> inline _LIBCPP_HIDE_FROM_ABI void __sort4_maybe_branchless( _RandomAccessIterator __x1, _RandomAccessIterator __x2, _RandomAccessIterator __x3, _RandomAccessIterator __x4, _Compare __c) { std::__sort4<_AlgPolicy, _Compare>(__x1, __x2, __x3, __x4, __c); } template ::value, int> = 0> inline _LIBCPP_HIDE_FROM_ABI void __sort5_maybe_branchless( _RandomAccessIterator __x1, _RandomAccessIterator __x2, _RandomAccessIterator __x3, _RandomAccessIterator __x4, _RandomAccessIterator __x5, _Compare __c) { std::__cond_swap<_Compare>(__x1, __x2, __c); std::__cond_swap<_Compare>(__x4, __x5, __c); std::__partially_sorted_swap<_Compare>(__x3, __x4, __x5, __c); std::__cond_swap<_Compare>(__x2, __x5, __c); std::__partially_sorted_swap<_Compare>(__x1, __x3, __x4, __c); std::__partially_sorted_swap<_Compare>(__x2, __x3, __x4, __c); } template ::value, int> = 0> inline _LIBCPP_HIDE_FROM_ABI void __sort5_maybe_branchless( _RandomAccessIterator __x1, _RandomAccessIterator __x2, _RandomAccessIterator __x3, _RandomAccessIterator __x4, _RandomAccessIterator __x5, _Compare __c) { std::__sort5<_AlgPolicy, _Compare, _RandomAccessIterator>( std::move(__x1), std::move(__x2), std::move(__x3), std::move(__x4), std::move(__x5), __c); } // Assumes size > 0 template _LIBCPP_HIDE_FROM_ABI _LIBCPP_CONSTEXPR_SINCE_CXX14 void __selection_sort(_BidirectionalIterator __first, _BidirectionalIterator __last, _Compare __comp) { _BidirectionalIterator __lm1 = __last; for (--__lm1; __first != __lm1; ++__first) { _BidirectionalIterator __i = std::__min_element<_Compare>(__first, __last, __comp); if (__i != __first) _IterOps<_AlgPolicy>::iter_swap(__first, __i); } } // Sort the iterator range [__first, __last) using the comparator __comp using // the insertion sort algorithm. template _LIBCPP_HIDE_FROM_ABI void __insertion_sort(_BidirectionalIterator __first, _BidirectionalIterator __last, _Compare __comp) { using _Ops = _IterOps<_AlgPolicy>; typedef typename iterator_traits<_BidirectionalIterator>::value_type value_type; if (__first == __last) return; _BidirectionalIterator __i = __first; for (++__i; __i != __last; ++__i) { _BidirectionalIterator __j = __i; --__j; if (__comp(*__i, *__j)) { value_type __t(_Ops::__iter_move(__i)); _BidirectionalIterator __k = __j; __j = __i; do { *__j = _Ops::__iter_move(__k); __j = __k; } while (__j != __first && __comp(__t, *--__k)); *__j = std::move(__t); } } } // Sort the iterator range [__first, __last) using the comparator __comp using // the insertion sort algorithm. Insertion sort has two loops, outer and inner. // The implementation below has no bounds check (unguarded) for the inner loop. // Assumes that there is an element in the position (__first - 1) and that each // element in the input range is greater or equal to the element at __first - 1. template _LIBCPP_HIDE_FROM_ABI void __insertion_sort_unguarded(_RandomAccessIterator const __first, _RandomAccessIterator __last, _Compare __comp) { using _Ops = _IterOps<_AlgPolicy>; typedef typename iterator_traits<_RandomAccessIterator>::difference_type difference_type; typedef typename iterator_traits<_RandomAccessIterator>::value_type value_type; if (__first == __last) return; const _RandomAccessIterator __leftmost = __first - difference_type(1); (void)__leftmost; // can be unused when assertions are disabled for (_RandomAccessIterator __i = __first + difference_type(1); __i != __last; ++__i) { _RandomAccessIterator __j = __i - difference_type(1); if (__comp(*__i, *__j)) { value_type __t(_Ops::__iter_move(__i)); _RandomAccessIterator __k = __j; __j = __i; do { *__j = _Ops::__iter_move(__k); __j = __k; _LIBCPP_ASSERT_VALID_ELEMENT_ACCESS( __k != __leftmost, "Would read out of bounds, does your comparator satisfy the strict-weak ordering requirement?"); } while (__comp(__t, *--__k)); // No need for bounds check due to the assumption stated above. *__j = std::move(__t); } } } template _LIBCPP_HIDE_FROM_ABI bool __insertion_sort_incomplete(_RandomAccessIterator __first, _RandomAccessIterator __last, _Comp __comp) { using _Ops = _IterOps<_AlgPolicy>; typedef typename iterator_traits<_RandomAccessIterator>::difference_type difference_type; switch (__last - __first) { case 0: case 1: return true; case 2: if (__comp(*--__last, *__first)) _Ops::iter_swap(__first, __last); return true; case 3: std::__sort3_maybe_branchless<_AlgPolicy, _Comp>(__first, __first + difference_type(1), --__last, __comp); return true; case 4: std::__sort4_maybe_branchless<_AlgPolicy, _Comp>( __first, __first + difference_type(1), __first + difference_type(2), --__last, __comp); return true; case 5: std::__sort5_maybe_branchless<_AlgPolicy, _Comp>( __first, __first + difference_type(1), __first + difference_type(2), __first + difference_type(3), --__last, __comp); return true; } typedef typename iterator_traits<_RandomAccessIterator>::value_type value_type; _RandomAccessIterator __j = __first + difference_type(2); std::__sort3_maybe_branchless<_AlgPolicy, _Comp>(__first, __first + difference_type(1), __j, __comp); const unsigned __limit = 8; unsigned __count = 0; for (_RandomAccessIterator __i = __j + difference_type(1); __i != __last; ++__i) { if (__comp(*__i, *__j)) { value_type __t(_Ops::__iter_move(__i)); _RandomAccessIterator __k = __j; __j = __i; do { *__j = _Ops::__iter_move(__k); __j = __k; } while (__j != __first && __comp(__t, *--__k)); *__j = std::move(__t); if (++__count == __limit) return ++__i == __last; } __j = __i; } return true; } template inline _LIBCPP_HIDE_FROM_ABI void __swap_bitmap_pos( _RandomAccessIterator __first, _RandomAccessIterator __last, uint64_t& __left_bitset, uint64_t& __right_bitset) { using _Ops = _IterOps<_AlgPolicy>; typedef typename std::iterator_traits<_RandomAccessIterator>::difference_type difference_type; // Swap one pair on each iteration as long as both bitsets have at least one // element for swapping. while (__left_bitset != 0 && __right_bitset != 0) { difference_type __tz_left = __libcpp_ctz(__left_bitset); __left_bitset = __libcpp_blsr(__left_bitset); difference_type __tz_right = __libcpp_ctz(__right_bitset); __right_bitset = __libcpp_blsr(__right_bitset); _Ops::iter_swap(__first + __tz_left, __last - __tz_right); } } template ::value_type> inline _LIBCPP_HIDE_FROM_ABI void __populate_left_bitset(_RandomAccessIterator __first, _Compare __comp, _ValueType& __pivot, uint64_t& __left_bitset) { // Possible vectorization. With a proper "-march" flag, the following loop // will be compiled into a set of SIMD instructions. _RandomAccessIterator __iter = __first; for (int __j = 0; __j < __detail::__block_size;) { bool __comp_result = !__comp(*__iter, __pivot); __left_bitset |= (static_cast(__comp_result) << __j); __j++; ++__iter; } } template ::value_type> inline _LIBCPP_HIDE_FROM_ABI void __populate_right_bitset(_RandomAccessIterator __lm1, _Compare __comp, _ValueType& __pivot, uint64_t& __right_bitset) { // Possible vectorization. With a proper "-march" flag, the following loop // will be compiled into a set of SIMD instructions. _RandomAccessIterator __iter = __lm1; for (int __j = 0; __j < __detail::__block_size;) { bool __comp_result = __comp(*__iter, __pivot); __right_bitset |= (static_cast(__comp_result) << __j); __j++; --__iter; } } template ::value_type> inline _LIBCPP_HIDE_FROM_ABI void __bitset_partition_partial_blocks( _RandomAccessIterator& __first, _RandomAccessIterator& __lm1, _Compare __comp, _ValueType& __pivot, uint64_t& __left_bitset, uint64_t& __right_bitset) { typedef typename std::iterator_traits<_RandomAccessIterator>::difference_type difference_type; difference_type __remaining_len = __lm1 - __first + 1; difference_type __l_size; difference_type __r_size; if (__left_bitset == 0 && __right_bitset == 0) { __l_size = __remaining_len / 2; __r_size = __remaining_len - __l_size; } else if (__left_bitset == 0) { // We know at least one side is a full block. __l_size = __remaining_len - __detail::__block_size; __r_size = __detail::__block_size; } else { // if (__right_bitset == 0) __l_size = __detail::__block_size; __r_size = __remaining_len - __detail::__block_size; } // Record the comparison outcomes for the elements currently on the left side. if (__left_bitset == 0) { _RandomAccessIterator __iter = __first; for (int __j = 0; __j < __l_size; __j++) { bool __comp_result = !__comp(*__iter, __pivot); __left_bitset |= (static_cast(__comp_result) << __j); ++__iter; } } // Record the comparison outcomes for the elements currently on the right // side. if (__right_bitset == 0) { _RandomAccessIterator __iter = __lm1; for (int __j = 0; __j < __r_size; __j++) { bool __comp_result = __comp(*__iter, __pivot); __right_bitset |= (static_cast(__comp_result) << __j); --__iter; } } std::__swap_bitmap_pos<_AlgPolicy, _RandomAccessIterator>(__first, __lm1, __left_bitset, __right_bitset); __first += (__left_bitset == 0) ? __l_size : 0; __lm1 -= (__right_bitset == 0) ? __r_size : 0; } template inline _LIBCPP_HIDE_FROM_ABI void __swap_bitmap_pos_within( _RandomAccessIterator& __first, _RandomAccessIterator& __lm1, uint64_t& __left_bitset, uint64_t& __right_bitset) { using _Ops = _IterOps<_AlgPolicy>; typedef typename std::iterator_traits<_RandomAccessIterator>::difference_type difference_type; if (__left_bitset) { // Swap within the left side. Need to find set positions in the reverse // order. while (__left_bitset != 0) { difference_type __tz_left = __detail::__block_size - 1 - __libcpp_clz(__left_bitset); __left_bitset &= (static_cast(1) << __tz_left) - 1; _RandomAccessIterator __it = __first + __tz_left; if (__it != __lm1) { _Ops::iter_swap(__it, __lm1); } --__lm1; } __first = __lm1 + difference_type(1); } else if (__right_bitset) { // Swap within the right side. Need to find set positions in the reverse // order. while (__right_bitset != 0) { difference_type __tz_right = __detail::__block_size - 1 - __libcpp_clz(__right_bitset); __right_bitset &= (static_cast(1) << __tz_right) - 1; _RandomAccessIterator __it = __lm1 - __tz_right; if (__it != __first) { _Ops::iter_swap(__it, __first); } ++__first; } } } // Partition [__first, __last) using the comparator __comp. *__first has the // chosen pivot. Elements that are equivalent are kept to the left of the // pivot. Returns the iterator for the pivot and a bool value which is true if // the provided range is already sorted, false otherwise. We assume that the // length of the range is at least three elements. // // __bitset_partition uses bitsets for storing outcomes of the comparisons // between the pivot and other elements. template _LIBCPP_HIDE_FROM_ABI std::pair<_RandomAccessIterator, bool> __bitset_partition(_RandomAccessIterator __first, _RandomAccessIterator __last, _Compare __comp) { using _Ops = _IterOps<_AlgPolicy>; typedef typename std::iterator_traits<_RandomAccessIterator>::value_type value_type; typedef typename std::iterator_traits<_RandomAccessIterator>::difference_type difference_type; _LIBCPP_ASSERT_INTERNAL(__last - __first >= difference_type(3), ""); const _RandomAccessIterator __begin = __first; // used for bounds checking, those are not moved around const _RandomAccessIterator __end = __last; (void)__end; // value_type __pivot(_Ops::__iter_move(__first)); // Find the first element greater than the pivot. if (__comp(__pivot, *(__last - difference_type(1)))) { // Not guarded since we know the last element is greater than the pivot. do { ++__first; _LIBCPP_ASSERT_VALID_ELEMENT_ACCESS( __first != __end, "Would read out of bounds, does your comparator satisfy the strict-weak ordering requirement?"); } while (!__comp(__pivot, *__first)); } else { while (++__first < __last && !__comp(__pivot, *__first)) { } } // Find the last element less than or equal to the pivot. if (__first < __last) { // It will be always guarded because __introsort will do the median-of-three // before calling this. do { _LIBCPP_ASSERT_VALID_ELEMENT_ACCESS( __last != __begin, "Would read out of bounds, does your comparator satisfy the strict-weak ordering requirement?"); --__last; } while (__comp(__pivot, *__last)); } // If the first element greater than the pivot is at or after the // last element less than or equal to the pivot, then we have covered the // entire range without swapping elements. This implies the range is already // partitioned. bool __already_partitioned = __first >= __last; if (!__already_partitioned) { _Ops::iter_swap(__first, __last); ++__first; } // In [__first, __last) __last is not inclusive. From now on, it uses last // minus one to be inclusive on both sides. _RandomAccessIterator __lm1 = __last - difference_type(1); uint64_t __left_bitset = 0; uint64_t __right_bitset = 0; // Reminder: length = __lm1 - __first + 1. while (__lm1 - __first >= 2 * __detail::__block_size - 1) { // Record the comparison outcomes for the elements currently on the left // side. if (__left_bitset == 0) std::__populate_left_bitset<_Compare>(__first, __comp, __pivot, __left_bitset); // Record the comparison outcomes for the elements currently on the right // side. if (__right_bitset == 0) std::__populate_right_bitset<_Compare>(__lm1, __comp, __pivot, __right_bitset); // Swap the elements recorded to be the candidates for swapping in the // bitsets. std::__swap_bitmap_pos<_AlgPolicy, _RandomAccessIterator>(__first, __lm1, __left_bitset, __right_bitset); // Only advance the iterator if all the elements that need to be moved to // other side were moved. __first += (__left_bitset == 0) ? difference_type(__detail::__block_size) : difference_type(0); __lm1 -= (__right_bitset == 0) ? difference_type(__detail::__block_size) : difference_type(0); } // Now, we have a less-than a block worth of elements on at least one of the // sides. std::__bitset_partition_partial_blocks<_AlgPolicy, _Compare>( __first, __lm1, __comp, __pivot, __left_bitset, __right_bitset); // At least one the bitsets would be empty. For the non-empty one, we need to // properly partition the elements that appear within that bitset. std::__swap_bitmap_pos_within<_AlgPolicy>(__first, __lm1, __left_bitset, __right_bitset); // Move the pivot to its correct position. _RandomAccessIterator __pivot_pos = __first - difference_type(1); if (__begin != __pivot_pos) { *__begin = _Ops::__iter_move(__pivot_pos); } *__pivot_pos = std::move(__pivot); return std::make_pair(__pivot_pos, __already_partitioned); } // Partition [__first, __last) using the comparator __comp. *__first has the // chosen pivot. Elements that are equivalent are kept to the right of the // pivot. Returns the iterator for the pivot and a bool value which is true if // the provided range is already sorted, false otherwise. We assume that the // length of the range is at least three elements. template _LIBCPP_HIDE_FROM_ABI std::pair<_RandomAccessIterator, bool> __partition_with_equals_on_right(_RandomAccessIterator __first, _RandomAccessIterator __last, _Compare __comp) { using _Ops = _IterOps<_AlgPolicy>; typedef typename iterator_traits<_RandomAccessIterator>::difference_type difference_type; typedef typename std::iterator_traits<_RandomAccessIterator>::value_type value_type; _LIBCPP_ASSERT_INTERNAL(__last - __first >= difference_type(3), ""); const _RandomAccessIterator __begin = __first; // used for bounds checking, those are not moved around const _RandomAccessIterator __end = __last; (void)__end; // value_type __pivot(_Ops::__iter_move(__first)); // Find the first element greater or equal to the pivot. It will be always // guarded because __introsort will do the median-of-three before calling // this. do { ++__first; _LIBCPP_ASSERT_VALID_ELEMENT_ACCESS( __first != __end, "Would read out of bounds, does your comparator satisfy the strict-weak ordering requirement?"); } while (__comp(*__first, __pivot)); // Find the last element less than the pivot. if (__begin == __first - difference_type(1)) { while (__first < __last && !__comp(*--__last, __pivot)) ; } else { // Guarded. do { _LIBCPP_ASSERT_VALID_ELEMENT_ACCESS( __last != __begin, "Would read out of bounds, does your comparator satisfy the strict-weak ordering requirement?"); --__last; } while (!__comp(*__last, __pivot)); } // If the first element greater than or equal to the pivot is at or after the // last element less than the pivot, then we have covered the entire range // without swapping elements. This implies the range is already partitioned. bool __already_partitioned = __first >= __last; // Go through the remaining elements. Swap pairs of elements (one to the // right of the pivot and the other to left of the pivot) that are not on the // correct side of the pivot. while (__first < __last) { _Ops::iter_swap(__first, __last); do { ++__first; _LIBCPP_ASSERT_VALID_ELEMENT_ACCESS( __first != __end, "Would read out of bounds, does your comparator satisfy the strict-weak ordering requirement?"); } while (__comp(*__first, __pivot)); do { _LIBCPP_ASSERT_VALID_ELEMENT_ACCESS( __last != __begin, "Would read out of bounds, does your comparator satisfy the strict-weak ordering requirement?"); --__last; } while (!__comp(*__last, __pivot)); } // Move the pivot to its correct position. _RandomAccessIterator __pivot_pos = __first - difference_type(1); if (__begin != __pivot_pos) { *__begin = _Ops::__iter_move(__pivot_pos); } *__pivot_pos = std::move(__pivot); return std::make_pair(__pivot_pos, __already_partitioned); } // Similar to the above function. Elements equivalent to the pivot are put to // the left of the pivot. Returns the iterator to the pivot element. template _LIBCPP_HIDE_FROM_ABI _RandomAccessIterator __partition_with_equals_on_left(_RandomAccessIterator __first, _RandomAccessIterator __last, _Compare __comp) { using _Ops = _IterOps<_AlgPolicy>; typedef typename iterator_traits<_RandomAccessIterator>::difference_type difference_type; typedef typename std::iterator_traits<_RandomAccessIterator>::value_type value_type; const _RandomAccessIterator __begin = __first; // used for bounds checking, those are not moved around const _RandomAccessIterator __end = __last; (void)__end; // value_type __pivot(_Ops::__iter_move(__first)); if (__comp(__pivot, *(__last - difference_type(1)))) { // Guarded. do { ++__first; _LIBCPP_ASSERT_VALID_ELEMENT_ACCESS( __first != __end, "Would read out of bounds, does your comparator satisfy the strict-weak ordering requirement?"); } while (!__comp(__pivot, *__first)); } else { while (++__first < __last && !__comp(__pivot, *__first)) { } } if (__first < __last) { // It will be always guarded because __introsort will do the // median-of-three before calling this. do { _LIBCPP_ASSERT_VALID_ELEMENT_ACCESS( __last != __begin, "Would read out of bounds, does your comparator satisfy the strict-weak ordering requirement?"); --__last; } while (__comp(__pivot, *__last)); } while (__first < __last) { _Ops::iter_swap(__first, __last); do { ++__first; _LIBCPP_ASSERT_VALID_ELEMENT_ACCESS( __first != __end, "Would read out of bounds, does your comparator satisfy the strict-weak ordering requirement?"); } while (!__comp(__pivot, *__first)); do { _LIBCPP_ASSERT_VALID_ELEMENT_ACCESS( __last != __begin, "Would read out of bounds, does your comparator satisfy the strict-weak ordering requirement?"); --__last; } while (__comp(__pivot, *__last)); } _RandomAccessIterator __pivot_pos = __first - difference_type(1); if (__begin != __pivot_pos) { *__begin = _Ops::__iter_move(__pivot_pos); } *__pivot_pos = std::move(__pivot); return __first; } // The main sorting function. Implements introsort combined with other ideas: // - option of using block quick sort for partitioning, // - guarded and unguarded insertion sort for small lengths, // - Tuckey's ninther technique for computing the pivot, // - check on whether partition was not required. // The implementation is partly based on Orson Peters' pattern-defeating // quicksort, published at: . template void __introsort(_RandomAccessIterator __first, _RandomAccessIterator __last, _Compare __comp, typename iterator_traits<_RandomAccessIterator>::difference_type __depth, bool __leftmost = true) { using _Ops = _IterOps<_AlgPolicy>; typedef typename iterator_traits<_RandomAccessIterator>::difference_type difference_type; using _Comp_ref = __comp_ref_type<_Compare>; // Upper bound for using insertion sort for sorting. _LIBCPP_CONSTEXPR difference_type __limit = 24; // Lower bound for using Tuckey's ninther technique for median computation. _LIBCPP_CONSTEXPR difference_type __ninther_threshold = 128; while (true) { difference_type __len = __last - __first; switch (__len) { case 0: case 1: return; case 2: if (__comp(*--__last, *__first)) _Ops::iter_swap(__first, __last); return; case 3: std::__sort3_maybe_branchless<_AlgPolicy, _Compare>(__first, __first + difference_type(1), --__last, __comp); return; case 4: std::__sort4_maybe_branchless<_AlgPolicy, _Compare>( __first, __first + difference_type(1), __first + difference_type(2), --__last, __comp); return; case 5: std::__sort5_maybe_branchless<_AlgPolicy, _Compare>( __first, __first + difference_type(1), __first + difference_type(2), __first + difference_type(3), --__last, __comp); return; } // Use insertion sort if the length of the range is below the specified limit. if (__len < __limit) { if (__leftmost) { std::__insertion_sort<_AlgPolicy, _Compare>(__first, __last, __comp); } else { std::__insertion_sort_unguarded<_AlgPolicy, _Compare>(__first, __last, __comp); } return; } if (__depth == 0) { // Fallback to heap sort as Introsort suggests. std::__partial_sort<_AlgPolicy, _Compare>(__first, __last, __last, __comp); return; } --__depth; { difference_type __half_len = __len / 2; // Use Tuckey's ninther technique or median of 3 for pivot selection // depending on the length of the range being sorted. if (__len > __ninther_threshold) { std::__sort3<_AlgPolicy, _Compare>(__first, __first + __half_len, __last - difference_type(1), __comp); std::__sort3<_AlgPolicy, _Compare>( __first + difference_type(1), __first + (__half_len - 1), __last - difference_type(2), __comp); std::__sort3<_AlgPolicy, _Compare>( __first + difference_type(2), __first + (__half_len + 1), __last - difference_type(3), __comp); std::__sort3<_AlgPolicy, _Compare>( __first + (__half_len - 1), __first + __half_len, __first + (__half_len + 1), __comp); _Ops::iter_swap(__first, __first + __half_len); } else { std::__sort3<_AlgPolicy, _Compare>(__first + __half_len, __first, __last - difference_type(1), __comp); } } // The elements to the left of the current iterator range are already // sorted. If the current iterator range to be sorted is not the // leftmost part of the entire iterator range and the pivot is same as // the highest element in the range to the left, then we know that all // the elements in the range [first, pivot] would be equal to the pivot, // assuming the equal elements are put on the left side when // partitioned. This also means that we do not need to sort the left // side of the partition. if (!__leftmost && !__comp(*(__first - difference_type(1)), *__first)) { __first = std::__partition_with_equals_on_left<_AlgPolicy, _RandomAccessIterator, _Comp_ref>( __first, __last, _Comp_ref(__comp)); continue; } // Use bitset partition only if asked for. auto __ret = _UseBitSetPartition ? std::__bitset_partition<_AlgPolicy, _RandomAccessIterator, _Compare>(__first, __last, __comp) : std::__partition_with_equals_on_right<_AlgPolicy, _RandomAccessIterator, _Compare>( __first, __last, __comp); _RandomAccessIterator __i = __ret.first; // [__first, __i) < *__i and *__i <= [__i+1, __last) // If we were given a perfect partition, see if insertion sort is quick... if (__ret.second) { bool __fs = std::__insertion_sort_incomplete<_AlgPolicy, _Compare>(__first, __i, __comp); if (std::__insertion_sort_incomplete<_AlgPolicy, _Compare>(__i + difference_type(1), __last, __comp)) { if (__fs) return; __last = __i; continue; } else { if (__fs) { __first = ++__i; continue; } } } // Sort the left partiton recursively and the right partition with tail recursion elimination. std::__introsort<_AlgPolicy, _Compare, _RandomAccessIterator, _UseBitSetPartition>( __first, __i, __comp, __depth, __leftmost); __leftmost = false; __first = ++__i; } } template inline _LIBCPP_HIDE_FROM_ABI _Number __log2i(_Number __n) { if (__n == 0) return 0; if (sizeof(__n) <= sizeof(unsigned)) return sizeof(unsigned) * CHAR_BIT - 1 - __libcpp_clz(static_cast(__n)); if (sizeof(__n) <= sizeof(unsigned long)) return sizeof(unsigned long) * CHAR_BIT - 1 - __libcpp_clz(static_cast(__n)); if (sizeof(__n) <= sizeof(unsigned long long)) return sizeof(unsigned long long) * CHAR_BIT - 1 - __libcpp_clz(static_cast(__n)); _Number __log2 = 0; while (__n > 1) { __log2++; __n >>= 1; } return __log2; } template void __sort(_RandomAccessIterator, _RandomAccessIterator, _Comp); extern template _LIBCPP_EXPORTED_FROM_ABI void __sort<__less&, char*>(char*, char*, __less&); #ifndef _LIBCPP_HAS_NO_WIDE_CHARACTERS extern template _LIBCPP_EXPORTED_FROM_ABI void __sort<__less&, wchar_t*>(wchar_t*, wchar_t*, __less&); #endif extern template _LIBCPP_EXPORTED_FROM_ABI void __sort<__less&, signed char*>(signed char*, signed char*, __less&); extern template _LIBCPP_EXPORTED_FROM_ABI void __sort<__less&, unsigned char*>(unsigned char*, unsigned char*, __less&); extern template _LIBCPP_EXPORTED_FROM_ABI void __sort<__less&, short*>(short*, short*, __less&); extern template _LIBCPP_EXPORTED_FROM_ABI void __sort<__less&, unsigned short*>(unsigned short*, unsigned short*, __less&); extern template _LIBCPP_EXPORTED_FROM_ABI void __sort<__less&, int*>(int*, int*, __less&); extern template _LIBCPP_EXPORTED_FROM_ABI void __sort<__less&, unsigned*>(unsigned*, unsigned*, __less&); extern template _LIBCPP_EXPORTED_FROM_ABI void __sort<__less&, long*>(long*, long*, __less&); extern template _LIBCPP_EXPORTED_FROM_ABI void __sort<__less&, unsigned long*>(unsigned long*, unsigned long*, __less&); extern template _LIBCPP_EXPORTED_FROM_ABI void __sort<__less&, long long*>(long long*, long long*, __less&); extern template _LIBCPP_EXPORTED_FROM_ABI void __sort<__less&, unsigned long long*>( unsigned long long*, unsigned long long*, __less&); extern template _LIBCPP_EXPORTED_FROM_ABI void __sort<__less&, float*>(float*, float*, __less&); extern template _LIBCPP_EXPORTED_FROM_ABI void __sort<__less&, double*>(double*, double*, __less&); extern template _LIBCPP_EXPORTED_FROM_ABI void __sort<__less&, long double*>(long double*, long double*, __less&); template _LIBCPP_HIDE_FROM_ABI _LIBCPP_CONSTEXPR_SINCE_CXX20 void __sort_dispatch(_RandomAccessIterator __first, _RandomAccessIterator __last, _Comp& __comp) { typedef typename iterator_traits<_RandomAccessIterator>::difference_type difference_type; difference_type __depth_limit = 2 * std::__log2i(__last - __first); // Only use bitset partitioning for arithmetic types. We should also check // that the default comparator is in use so that we are sure that there are no // branches in the comparator. std::__introsort<_AlgPolicy, _Comp&, _RandomAccessIterator, __use_branchless_sort<_Comp, _RandomAccessIterator>::value>(__first, __last, __comp, __depth_limit); } template using __is_any_of = _Or...>; template using __sort_is_specialized_in_library = __is_any_of< _Type, char, #ifndef _LIBCPP_HAS_NO_WIDE_CHARACTERS wchar_t, #endif signed char, unsigned char, short, unsigned short, int, unsigned int, long, unsigned long, long long, unsigned long long, float, double, long double>; template ::value, int> = 0> _LIBCPP_HIDE_FROM_ABI void __sort_dispatch(_Type* __first, _Type* __last, __less<>&) { __less<_Type> __comp; std::__sort<__less<_Type>&, _Type*>(__first, __last, __comp); } template ::value, int> = 0> _LIBCPP_HIDE_FROM_ABI void __sort_dispatch(_Type* __first, _Type* __last, less<_Type>&) { __less<_Type> __comp; std::__sort<__less<_Type>&, _Type*>(__first, __last, __comp); } #if _LIBCPP_STD_VER >= 14 template ::value, int> = 0> _LIBCPP_HIDE_FROM_ABI void __sort_dispatch(_Type* __first, _Type* __last, less<>&) { __less<_Type> __comp; std::__sort<__less<_Type>&, _Type*>(__first, __last, __comp); } #endif #if _LIBCPP_STD_VER >= 20 template ::value, int> = 0> _LIBCPP_HIDE_FROM_ABI void __sort_dispatch(_Type* __first, _Type* __last, ranges::less&) { __less<_Type> __comp; std::__sort<__less<_Type>&, _Type*>(__first, __last, __comp); } #endif template inline _LIBCPP_HIDE_FROM_ABI _LIBCPP_CONSTEXPR_SINCE_CXX20 void __sort_impl(_RandomAccessIterator __first, _RandomAccessIterator __last, _Comp& __comp) { std::__debug_randomize_range<_AlgPolicy>(__first, __last); if (__libcpp_is_constant_evaluated()) { std::__partial_sort<_AlgPolicy>( std::__unwrap_iter(__first), std::__unwrap_iter(__last), std::__unwrap_iter(__last), __comp); } else { std::__sort_dispatch<_AlgPolicy>(std::__unwrap_iter(__first), std::__unwrap_iter(__last), __comp); } std::__check_strict_weak_ordering_sorted(std::__unwrap_iter(__first), std::__unwrap_iter(__last), __comp); } template inline _LIBCPP_HIDE_FROM_ABI _LIBCPP_CONSTEXPR_SINCE_CXX20 void sort(_RandomAccessIterator __first, _RandomAccessIterator __last, _Comp __comp) { std::__sort_impl<_ClassicAlgPolicy>(std::move(__first), std::move(__last), __comp); } template inline _LIBCPP_HIDE_FROM_ABI _LIBCPP_CONSTEXPR_SINCE_CXX20 void sort(_RandomAccessIterator __first, _RandomAccessIterator __last) { std::sort(__first, __last, __less<>()); } _LIBCPP_END_NAMESPACE_STD _LIBCPP_POP_MACROS #endif // _LIBCPP___ALGORITHM_SORT_H