////////////////////////////////////////////////////////////////////////////// // // (C) Copyright Ion Gaztanaga 2015-2016. // Distributed under the Boost Software License, Version 1.0. // (See accompanying file LICENSE_1_0.txt or copy at // http://www.boost.org/LICENSE_1_0.txt) // // See http://www.boost.org/libs/move for documentation. // ////////////////////////////////////////////////////////////////////////////// #ifndef BOOST_MOVE_MERGE_HPP #define BOOST_MOVE_MERGE_HPP #include #include #include #include #include #include namespace boost { namespace movelib { // @cond /* template inline Unsigned gcd(Unsigned x, Unsigned y) { if(0 == ((x &(x-1)) | (y & (y-1)))){ return x < y ? x : y; } else{ do { Unsigned t = x % y; x = y; y = t; } while (y); return x; } } */ //Modified version from "An Optimal In-Place Array Rotation Algorithm", Ching-Kuang Shene template Unsigned gcd(Unsigned x, Unsigned y) { if(0 == ((x &(x-1)) | (y & (y-1)))){ return x < y ? x : y; } else{ Unsigned z = 1; while((!(x&1)) & (!(y&1))){ z <<=1, x>>=1, y>>=1; } while(x && y){ if(!(x&1)) x >>=1; else if(!(y&1)) y >>=1; else if(x >=y) x = (x-y) >> 1; else y = (y-x) >> 1; } return z*(x+y); } } template RandIt rotate_gcd(RandIt first, RandIt middle, RandIt last) { typedef typename iterator_traits::size_type size_type; typedef typename iterator_traits::value_type value_type; if(first == middle) return last; if(middle == last) return first; const size_type middle_pos = size_type(middle - first); RandIt ret = last - middle_pos; if (middle == ret){ boost::adl_move_swap_ranges(first, middle, middle); } else{ const size_type length = size_type(last - first); for( RandIt it_i(first), it_gcd(it_i + gcd(length, middle_pos)) ; it_i != it_gcd ; ++it_i){ value_type temp(boost::move(*it_i)); RandIt it_j = it_i; RandIt it_k = it_j+middle_pos; do{ *it_j = boost::move(*it_k); it_j = it_k; size_type const left = size_type(last - it_j); it_k = left > middle_pos ? it_j + middle_pos : first + (middle_pos - left); } while(it_k != it_i); *it_j = boost::move(temp); } } return ret; } template RandIt lower_bound (RandIt first, const RandIt last, const T& key, Compare comp) { typedef typename iterator_traits ::size_type size_type; size_type len = size_type(last - first); RandIt middle; while (len) { size_type step = len >> 1; middle = first; middle += step; if (comp(*middle, key)) { first = ++middle; len -= step + 1; } else{ len = step; } } return first; } template RandIt upper_bound (RandIt first, const RandIt last, const T& key, Compare comp) { typedef typename iterator_traits ::size_type size_type; size_type len = size_type(last - first); RandIt middle; while (len) { size_type step = len >> 1; middle = first; middle += step; if (!comp(key, *middle)) { first = ++middle; len -= step + 1; } else{ len = step; } } return first; } template void op_merge_left( RandIt buf_first , RandIt first1 , RandIt const last1 , RandIt const last2 , Compare comp , Op op) { for(RandIt first2=last1; first2 != last2; ++buf_first){ if(first1 == last1){ op(forward_t(), first2, last2, buf_first); return; } else if(comp(*first2, *first1)){ op(first2, buf_first); ++first2; } else{ op(first1, buf_first); ++first1; } } if(buf_first != first1){//In case all remaining elements are in the same place //(e.g. buffer is exactly the size of the second half //and all elements from the second half are less) op(forward_t(), first1, last1, buf_first); } else{ buf_first = buf_first; } } // [buf_first, first1) -> buffer // [first1, last1) merge [last1,last2) -> [buf_first,buf_first+(last2-first1)) // Elements from buffer are moved to [last2 - (first1-buf_first), last2) // Note: distance(buf_first, first1) >= distance(last1, last2), so no overlapping occurs template void merge_left (RandIt buf_first, RandIt first1, RandIt const last1, RandIt const last2, Compare comp) { op_merge_left(buf_first, first1, last1, last2, comp, move_op()); } // [buf_first, first1) -> buffer // [first1, last1) merge [last1,last2) -> [buf_first,buf_first+(last2-first1)) // Elements from buffer are swapped to [last2 - (first1-buf_first), last2) // Note: distance(buf_first, first1) >= distance(last1, last2), so no overlapping occurs template void swap_merge_left (RandIt buf_first, RandIt first1, RandIt const last1, RandIt const last2, Compare comp) { op_merge_left(buf_first, first1, last1, last2, comp, swap_op()); } template void op_merge_right (RandIt const first1, RandIt last1, RandIt last2, RandIt buf_last, Compare comp, Op op) { RandIt const first2 = last1; while(first1 != last1){ if(last2 == first2){ op(backward_t(), first1, last1, buf_last); return; } --last2; --last1; --buf_last; if(comp(*last2, *last1)){ op(last1, buf_last); ++last2; } else{ op(last2, buf_last); ++last1; } } if(last2 != buf_last){ //In case all remaining elements are in the same place //(e.g. buffer is exactly the size of the first half //and all elements from the second half are less) op(backward_t(), first2, last2, buf_last); } } // [last2, buf_last) - buffer // [first1, last1) merge [last1,last2) -> [first1+(buf_last-last2), buf_last) // Note: distance[last2, buf_last) >= distance[first1, last1), so no overlapping occurs template void merge_right (RandIt first1, RandIt last1, RandIt last2, RandIt buf_last, Compare comp) { op_merge_right(first1, last1, last2, buf_last, comp, move_op()); } // [last2, buf_last) - buffer // [first1, last1) merge [last1,last2) -> [first1+(buf_last-last2), buf_last) // Note: distance[last2, buf_last) >= distance[first1, last1), so no overlapping occurs template void swap_merge_right (RandIt first1, RandIt last1, RandIt last2, RandIt buf_last, Compare comp) { op_merge_right(first1, last1, last2, buf_last, comp, swap_op()); } template void merge_bufferless_ONlogN_recursive (BidirIt first, BidirIt middle, BidirIt last, Distance len1, Distance len2, Compare comp) { typedef typename iterator_traits::size_type size_type; while(1) { //#define MERGE_BUFFERLESS_RECURSIVE_OPT #ifndef MERGE_BUFFERLESS_RECURSIVE_OPT if (len2 == 0) { return; } if (!len1) { return; } if ((len1 | len2) == 1) { if (comp(*middle, *first)) adl_move_swap(*first, *middle); return; } #else if (len2 == 0) { return; } if (!len1) { return; } BidirIt middle_prev = middle; --middle_prev; if(!comp(*middle, *middle_prev)) return; while(true) { if (comp(*middle, *first)) break; ++first; if(--len1 == 1) break; } if (len1 == 1 && len2 == 1) { //comp(*middle, *first) == true already tested in the loop adl_move_swap(*first, *middle); return; } #endif BidirIt first_cut = first; BidirIt second_cut = middle; Distance len11 = 0; Distance len22 = 0; if (len1 > len2) { len11 = len1 / 2; first_cut += len11; second_cut = lower_bound(middle, last, *first_cut, comp); len22 = size_type(second_cut - middle); } else { len22 = len2 / 2; second_cut += len22; first_cut = upper_bound(first, middle, *second_cut, comp); len11 = size_type(first_cut - first); } BidirIt new_middle = rotate_gcd(first_cut, middle, second_cut); //Avoid one recursive call doing a manual tail call elimination on the biggest range const Distance len_internal = len11+len22; if( len_internal < (len1 + len2 - len_internal) ) { merge_bufferless_ONlogN_recursive(first, first_cut, new_middle, len11, len22, comp); //merge_bufferless_recursive(new_middle, second_cut, last, len1 - len11, len2 - len22, comp); first = new_middle; middle = second_cut; len1 -= len11; len2 -= len22; } else { //merge_bufferless_recursive(first, first_cut, new_middle, len11, len22, comp); merge_bufferless_ONlogN_recursive(new_middle, second_cut, last, len1 - len11, len2 - len22, comp); middle = first_cut; last = new_middle; len1 = len11; len2 = len22; } } } //Complexity: NlogN template void merge_bufferless_ONlogN(BidirIt first, BidirIt middle, BidirIt last, Compare comp) { merge_bufferless_ONlogN_recursive (first, middle, last, middle - first, last - middle, comp); } //Complexity: min(len1,len2)^2 + max(len1,len2) template void merge_bufferless_ON2(RandIt first, RandIt middle, RandIt last, Compare comp) { if((middle - first) < (last - middle)){ while(first != middle){ RandIt const old_last1 = middle; middle = lower_bound(middle, last, *first, comp); first = rotate_gcd(first, old_last1, middle); if(middle == last){ break; } do{ ++first; } while(first != middle && !comp(*middle, *first)); } } else{ while(middle != last){ RandIt p = upper_bound(first, middle, last[-1], comp); last = rotate_gcd(p, middle, last); middle = p; if(middle == first){ break; } --p; do{ --last; } while(middle != last && !comp(last[-1], *p)); } } } template void merge_bufferless(RandIt first, RandIt middle, RandIt last, Compare comp) { //#define BOOST_ADAPTIVE_MERGE_NLOGN_MERGE #ifdef BOOST_ADAPTIVE_MERGE_NLOGN_MERGE merge_bufferless_ONlogN(first, middle, last, comp); #else merge_bufferless_ON2(first, middle, last, comp); #endif //BOOST_ADAPTIVE_MERGE_NLOGN_MERGE } template struct antistable { explicit antistable(Comp &comp) : m_comp(comp) {} template bool operator()(const U &u, const V & v) { return !m_comp(v, u); } private: antistable & operator=(const antistable &); Comp &m_comp; }; template class negate { public: negate() {} explicit negate(Comp comp) : m_comp(comp) {} template bool operator()(const T1& l, const T2& r) { return !m_comp(l, r); } private: Comp m_comp; }; template class inverse { public: inverse() {} explicit inverse(Comp comp) : m_comp(comp) {} template bool operator()(const T1& l, const T2& r) { return m_comp(r, l); } private: Comp m_comp; }; // [r_first, r_last) are already in the right part of the destination range. template void op_merge_with_right_placed ( InputIterator first, InputIterator last , InputOutIterator dest_first, InputOutIterator r_first, InputOutIterator r_last , Compare comp, Op op) { BOOST_ASSERT((last - first) == (r_first - dest_first)); while ( first != last ) { if (r_first == r_last) { InputOutIterator end = op(forward_t(), first, last, dest_first); BOOST_ASSERT(end == r_last); (void)end; return; } else if (comp(*r_first, *first)) { op(r_first, dest_first); ++r_first; } else { op(first, dest_first); ++first; } ++dest_first; } // Remaining [r_first, r_last) already in the correct place } template void swap_merge_with_right_placed ( InputIterator first, InputIterator last , InputOutIterator dest_first, InputOutIterator r_first, InputOutIterator r_last , Compare comp) { op_merge_with_right_placed(first, last, dest_first, r_first, r_last, comp, swap_op()); } // [first, last) are already in the right part of the destination range. template void op_merge_with_left_placed ( BidirOutIterator const first, BidirOutIterator last, BidirOutIterator dest_last , BidirIterator const r_first, BidirIterator r_last , Compare comp, Op op) { BOOST_ASSERT((dest_last - last) == (r_last - r_first)); while( r_first != r_last ) { if(first == last) { BidirOutIterator res = op(backward_t(), r_first, r_last, dest_last); BOOST_ASSERT(last == res); (void)res; return; } --r_last; --last; if(comp(*r_last, *last)){ ++r_last; --dest_last; op(last, dest_last); } else{ ++last; --dest_last; op(r_last, dest_last); } } // Remaining [first, last) already in the correct place } // @endcond // [irst, last) are already in the right part of the destination range. template void merge_with_left_placed ( BidirOutIterator const first, BidirOutIterator last, BidirOutIterator dest_last , BidirIterator const r_first, BidirIterator r_last , Compare comp) { op_merge_with_left_placed(first, last, dest_last, r_first, r_last, comp, move_op()); } // [r_first, r_last) are already in the right part of the destination range. template void merge_with_right_placed ( InputIterator first, InputIterator last , InputOutIterator dest_first, InputOutIterator r_first, InputOutIterator r_last , Compare comp) { op_merge_with_right_placed(first, last, dest_first, r_first, r_last, comp, move_op()); } // [r_first, r_last) are already in the right part of the destination range. // [dest_first, r_first) is uninitialized memory template void uninitialized_merge_with_right_placed ( InputIterator first, InputIterator last , InputOutIterator dest_first, InputOutIterator r_first, InputOutIterator r_last , Compare comp) { BOOST_ASSERT((last - first) == (r_first - dest_first)); typedef typename iterator_traits::value_type value_type; InputOutIterator const original_r_first = r_first; destruct_n d(&*dest_first); while ( first != last && dest_first != original_r_first ) { if (r_first == r_last) { for(; dest_first != original_r_first; ++dest_first, ++first){ ::new(&*dest_first) value_type(::boost::move(*first)); d.incr(); } d.release(); InputOutIterator end = ::boost::move(first, last, original_r_first); BOOST_ASSERT(end == r_last); (void)end; return; } else if (comp(*r_first, *first)) { ::new(&*dest_first) value_type(::boost::move(*r_first)); d.incr(); ++r_first; } else { ::new(&*dest_first) value_type(::boost::move(*first)); d.incr(); ++first; } ++dest_first; } d.release(); merge_with_right_placed(first, last, original_r_first, r_first, r_last, comp); } /* // [r_first, r_last) are already in the right part of the destination range. // [dest_first, r_first) is uninitialized memory template void uninitialized_merge_with_left_placed ( BidirOutIterator dest_first, BidirOutIterator r_first, BidirOutIterator r_last , BidirIterator first, BidirIterator last , Compare comp) { BOOST_ASSERT((last - first) == (r_last - r_first)); typedef typename iterator_traits::value_type value_type; BidirOutIterator const original_r_last = r_last; destruct_n d(&*dest_last); while ( first != last && dest_first != original_r_first ) { if (r_first == r_last) { for(; dest_first != original_r_first; ++dest_first, ++first){ ::new(&*dest_first) value_type(::boost::move(*first)); d.incr(); } d.release(); BidirOutIterator end = ::boost::move(first, last, original_r_first); BOOST_ASSERT(end == r_last); (void)end; return; } else if (comp(*r_first, *first)) { ::new(&*dest_first) value_type(::boost::move(*r_first)); d.incr(); ++r_first; } else { ::new(&*dest_first) value_type(::boost::move(*first)); d.incr(); ++first; } ++dest_first; } d.release(); merge_with_right_placed(first, last, original_r_first, r_first, r_last, comp); } */ } //namespace movelib { } //namespace boost { #endif //#define BOOST_MOVE_MERGE_HPP