#include #define FOR(i,a,b) for(int i= (a); i<((int)b); ++i) #define RFOR(i,a) for(int i=(a); i >= 0; --i) #define FOE(i,a) for(auto i : a) #define ALL(c) (c).begin(), (c).end() #define RALL(c) (c).rbegin(), (c).rend() #define DUMP(x) cerr << #x << " = " << (x) << endl; #define SUM(x) std::accumulate(ALL(x), 0LL) #define MIN(v) *std::min_element(v.begin(), v.end()) #define MAX(v) *std::max_element(v.begin(), v.end()) #define EXIST(v,x) (std::find(v.begin(), v.end(), x) != v.end()) #define BIT_ON(bit, i) (bit & (1LL << i)) #define BIT_COUNT(bit) (__builtin_popcount(bit)) typedef long long LL; template using V = std::vector; template using VV = std::vector>; template using VVV = std::vector>>; template using VVVV = std::vector>>>; template inline T ceil(T a, T b) { return (a + b - 1) / b; } template inline void print(T x) { std::cout << x << std::endl; } template inline void print_vec(const std::vector &v) { for (int i = 0; i < v.size(); ++i) { if (i != 0) {std::cout << " ";} std::cout << v[i];} std::cout << "\n"; } template inline void print_2vec(const std::vector> &v) { for (int i = 0; i < v.size(); ++i) { for (int j = 0; j < v[0].size(); ++j) { if (j != 0) { std::cout << " "; } std::cout << std::setw(13) << std::left << v[i][j]; } std::cout << "\n";}} template inline bool inside(T y, T x, T H, T W) {return 0 <= y and y < H and 0 <= x and x < W; } template inline double euclidean_distance(T y1, T x1, T y2, T x2) { return sqrt((x1 - x2) * (x1 - x2) + (y1 - y2) * (y1 - y2)); } template inline double manhattan_distance(T y1, T x1, T y2, T x2) { return abs(x1 - x2) + abs(y1 - y2); } template T &chmin(T &a, const T &b) { return a = std::min(a, b); } template T &chmax(T &a, const T &b) { return a = std::max(a, b); } template inline std::vector unique(std::vector v) { sort(v.begin(), v.end()); v.erase(unique(v.begin(), v.end()), v.end()); return v; } // 初項s, 交差dのn個の数列の和 long long sum_of_arithmetic_progression(long long s, long long d, long long n) { return n * (2 * s + (n - 1) * d) / 2; } const int INF = 1 << 30; const double EPS = 1e-9; const std::string YES = "YES", Yes = "Yes", NO = "NO", No = "No"; const std::vector dy4 = {0, -1, 0, 1}, dx4 = {1, 0, -1, 0}; const std::vector dy8 = { 0, -1, 0, 1, 1, -1, -1, 1 }, dx8 = { 1, 0, -1, 0, 1, 1, -1, -1 }; using namespace std; enum { NOTFOUND = 0xFFFFFFFFFFFFFFFFLLU }; class SuccinctBitVector { private: const uint64_t size; // ビットベクトルのサイズ const uint32_t blockBitNum = 64; std::vector B; // ビットベクトル const uint32_t LEVEL_L = 65536; const uint32_t LEVEL_S = 256; std::vector L; // 大ブロック std::vector S; // 小ブロック uint64_t numOne = 0; // 1bitの数 public: explicit SuccinctBitVector(uint64_t n) : size(n) { const uint64_t s = (n + blockBitNum - 1) / blockBitNum + 1; // ceil(n, blockSize) this->B.assign(s, 0); this->L.assign(n / LEVEL_L + 1, 0); this->S.assign(n / LEVEL_S + 1, 0); } // B[pos] = bit void setBit(uint64_t bit, uint64_t pos){ assert(bit == 0 or bit == 1); assert(pos < this->size); const uint64_t blockPos = pos / blockBitNum; const uint64_t offset = pos % blockBitNum; if (bit == 1) { B.at(blockPos) |= (1LLU << offset); } else { B.at(blockPos) &= (~(1LLU << offset)); } } // B[pos] uint64_t access(uint64_t pos) { assert(pos < this->size); const uint64_t blockPos = pos / blockBitNum; const uint64_t offset = pos % blockBitNum; return ((B.at(blockPos) >> offset) & 1); } void build(){ uint64_t num = 0; for (uint64_t i = 0; i <= size; i++){ if (i % LEVEL_L == 0) { L.at(i / LEVEL_L) = num; } if (i % LEVEL_S == 0) { S.at(i / LEVEL_S) = num - L.at(i / LEVEL_L); } if (i != size and i % blockBitNum == 0) { num += this->popCount(this->B.at(i / blockBitNum)); } } this-> numOne = num; } // B[0, pos)のbitの数 uint64_t rank(uint64_t bit, uint64_t pos) { assert(bit == 0 or bit == 1); assert(pos <= this->size); if (bit) { return rank1(pos); } else { return pos - rank1(pos); } } // rank番目のbitの位置 + 1(rankは1-origin) uint64_t select(const uint64_t bit, const uint64_t rank) { assert(bit == 0 or bit == 1); assert(rank > 0); if (bit == 0 and rank > this->size - this-> numOne) { return NOTFOUND; } if (bit == 1 and rank > this-> numOne) { return NOTFOUND; } // 大ブロックL内を検索 uint64_t large_idx = 0; { uint64_t left = 0; uint64_t right = L.size(); while (right - left > 1) { uint64_t mid = (left + right) / 2; uint64_t r = L.at(mid); r = (bit) ? r : mid * LEVEL_L - L.at(mid); if (r < rank) { left = mid; large_idx = mid; } else { right = mid; } } } // 小ブロックS内を検索 uint64_t small_idx = (large_idx * LEVEL_L) / LEVEL_S; { uint64_t left = (large_idx * LEVEL_L) / LEVEL_S; uint64_t right = std::min(((large_idx + 1) * LEVEL_L) / LEVEL_S, S.size()); while (right - left > 1) { uint64_t mid = (left + right) / 2; uint64_t r = L.at(large_idx) + S.at(mid); r = (bit) ? r :mid * LEVEL_S - r; if (r < rank) { left = mid; small_idx = mid; } else { right = mid; } } } // Bをブロック単位で順番に探索 uint64_t rank_pos = 0; { const uint64_t begin_block_idx = (small_idx * LEVEL_S) / blockBitNum; uint64_t total_bit = L.at(large_idx) + S.at(small_idx); if (bit == 0) { total_bit = small_idx * LEVEL_S - total_bit; } for (uint64_t i = 0;; ++i) { uint64_t b = popCount(B.at(begin_block_idx + i)); if (bit == 0) { b = blockBitNum - b; } if (total_bit + b >= rank) { uint64_t block = (bit) ? B.at(begin_block_idx + i) : ~B.at(begin_block_idx + i); rank_pos = (begin_block_idx + i) * blockBitNum + selectInBlock(block, rank - total_bit); break; } total_bit += b; } } return rank_pos + 1; } uint64_t getNumOne() const { return numOne; } void debug() { std::cout << "LEVEL_L(" << L.size() << ")" << std::endl; for (uint64_t i = 0 ; i < L.size(); ++i) { std::cout << L.at(i) << ", "; } std::cout << std::endl; std::cout << "LEVEL_S(" << S.size() << ")" << std::endl; for (uint64_t i = 0 ; i < S.size(); ++i) { std::cout << S.at(i) << ", "; } std::cout << std::endl; } private: uint64_t rank1(uint64_t pos) { uint64_t rank = L.at(pos / LEVEL_L) + S.at(pos / LEVEL_S); const uint64_t begin = (pos / LEVEL_S) * LEVEL_S / blockBitNum; const uint64_t end = pos / blockBitNum; for (uint64_t i = begin; i < end; ++i) { rank += popCount(this->B.at(i)); } const uint64_t remain = (pos % LEVEL_S) % blockBitNum; rank += popCount(this->B.at(end) & ((1LLU << remain) - 1)); return rank; } uint64_t popCount(uint64_t x) { x = (x & 0x5555555555555555ULL) + ((x >> 1) & 0x5555555555555555ULL); x = (x & 0x3333333333333333ULL) + ((x >> 2) & 0x3333333333333333ULL); x = (x + (x >> 4)) & 0x0f0f0f0f0f0f0f0fULL; x = x + (x >> 8); x = x + (x >> 16); x = x + (x >> 32); return x & 0x7FLLU; } uint64_t selectInBlock(uint64_t x, uint64_t rank) { uint64_t x1 = x - ((x & 0xAAAAAAAAAAAAAAAALLU) >> 1); uint64_t x2 = (x1 & 0x3333333333333333LLU) + ((x1 >> 2) & 0x3333333333333333LLU); uint64_t x3 = (x2 + (x2 >> 4)) & 0x0F0F0F0F0F0F0F0FLLU; uint64_t pos = 0; for (;; pos += 8){ uint64_t rank_next = (x3 >> pos) & 0xFFLLU; if (rank <= rank_next) break; rank -= rank_next; } uint64_t v2 = (x2 >> pos) & 0xFLLU; if (rank > v2) { rank -= v2; pos += 4; } uint64_t v1 = (x1 >> pos) & 0x3LLU; if (rank > v1){ rank -= v1; pos += 2; } uint64_t v0 = (x >> pos) & 0x1LLU; if (v0 < rank){ rank -= v0; pos += 1; } return pos; } }; class WaveletMatrix { private: std::vector bit_arrays; std::vector begin_one; // 各bitに着目したときの1の開始位置 std::map begin_alphabet; // 最後のソートされた配列で各文字の開始位置 uint64_t size; // 与えられた配列のサイズ uint64_t maximum_element; // 文字数 uint64_t bit_size; // 文字を表すのに必要なbit数 public: WaveletMatrix (const std::vector &array) { assert(array.size() > 0); size = array.size(); maximum_element = *max_element(array.begin(), array.end()) + 1; bit_size = get_num_of_bit(maximum_element); if (bit_size == 0) { bit_size = 1; } for (uint64_t i = 0; i < bit_size; ++i) { SuccinctBitVector sv(size); bit_arrays.push_back(sv); } this->begin_one.resize(bit_size); std::vector v(array); for (uint64_t i = 0; i < bit_size; ++i) { std::vector temp; // 0をtempにいれてく for (uint64_t j = 0; j < v.size(); ++j) { uint64_t c = v.at(j); uint64_t bit = (c >> (bit_size - i - 1)) & 1; // 上からi番目のbit if (bit == 0) { temp.push_back(c); bit_arrays.at(i).setBit(0, j); } } this->begin_one.at(i) = temp.size(); // 1をtempにいれてく for (uint64_t j = 0; j < v.size(); ++j) { uint64_t c = v.at(j); uint64_t bit = (c >> (bit_size - i - 1)) & 1; // 上からi番目のbit if (bit == 1) { temp.push_back(c); bit_arrays.at(i).setBit(1, j); } } bit_arrays.at(i).build(); v = temp; } // ソートされた配列内での各文字の位置を取得 for (int i = v.size() - 1; i >= 0; --i) { this->begin_alphabet[v.at(i)] = i; } } // v[pos] uint64_t access(uint64_t pos) { if (pos >= this->size) { return NOTFOUND; } uint64_t c = 0; for (uint64_t i = 0; i < bit_arrays.size(); ++i) { uint64_t bit = bit_arrays.at(i).access(pos); // もとの数値がのi番目のbit c = (c <<= 1) | bit; pos = bit_arrays.at(i).rank(bit, pos); if (bit) { pos += this->begin_one.at(i); } } return c; } // i番目のcの位置 + 1を返す。rankは1-origin uint64_t select(uint64_t c, uint64_t rank) { assert(rank > 0); if (c >= maximum_element) { return NOTFOUND; } if (this->begin_alphabet.find(c) == this->begin_alphabet.end()) { return NOTFOUND; } uint64_t index = this->begin_alphabet.at(c) + rank; for (uint64_t i = 0; i < bit_arrays.size(); ++i){ uint64_t bit = ((c >> i) & 1); // 下からi番目のbit if (bit == 1) { index -= this->begin_one.at(bit_size - i - 1); } index = this->bit_arrays.at(bit_size - i - 1).select(bit, index); } return index; } // v[begin_pos, end_pos)で最大値のindexを返す uint64_t maxRange(uint64_t begin_pos, uint64_t end_pos) { return quantileRange(begin_pos, end_pos, end_pos - begin_pos - 1); } // v[begin_pos, end_pos)で最小値のindexを返す uint64_t minRange(uint64_t begin_pos, uint64_t end_pos) { return quantileRange(begin_pos, end_pos, 0); } // v[begin_pos, end_pos)でk番目に小さい数値のindexを返す(kは0-origin) // つまり小さい順に並べてk番目の値 uint64_t quantileRange(uint64_t begin_pos, uint64_t end_pos, uint64_t k) { if ((end_pos > size || begin_pos >= end_pos) || (k >= end_pos - begin_pos)) { return NOTFOUND; } uint64_t val = 0; for (uint64_t i = 0; i < bit_size; ++i) { const uint64_t num_of_zero_begin = bit_arrays.at(i).rank(0, begin_pos); const uint64_t num_of_zero_end = bit_arrays.at(i).rank(0, end_pos); const uint64_t num_of_zero = num_of_zero_end - num_of_zero_begin; // beginからendまでにある0の数 const uint64_t bit = (k < num_of_zero) ? 0 : 1; // k番目の値の上からi番目のbitが0か1か if (bit) { k -= num_of_zero; begin_pos = this->begin_one.at(i) + begin_pos - num_of_zero_begin; end_pos = this->begin_one.at(i) + end_pos - num_of_zero_end; } else { begin_pos = num_of_zero_begin; end_pos = num_of_zero_begin + num_of_zero; } val = ((val << 1) | bit); } uint64_t left = 0; for (uint64_t i = 0; i < bit_size; ++i) { const uint64_t bit = (val >> (bit_size - i - 1)) & 1; // 上からi番目のbit left = bit_arrays.at(i).rank(bit, left); // cのi番目のbitと同じ数値の数 if (bit) { left += this->begin_one.at(i); } } const uint64_t rank = begin_pos + k - left + 1; return select(val, rank) - 1; } // v[0, pos)のcの数 uint64_t rank(uint64_t c, uint64_t pos) { assert(pos < size); if (c >= maximum_element) { return 0; } if (this->begin_alphabet.find(c) == this->begin_alphabet.end()) { return 0; } for (uint64_t i = 0; i < bit_size; ++i) { uint64_t bit = (c >> (bit_size - i - 1)) & 1; // 上からi番目のbit pos = bit_arrays.at(i).rank(bit, pos); // cのi番目のbitと同じ数値の数 if (bit) { pos += this->begin_one.at(i); } } uint64_t begin_pos = this->begin_alphabet.at(c); return pos - begin_pos; } // v[begin_pos, end_pos)で[min, max)に入る値の個数 uint64_t rangeFreq(uint64_t begin_pos, uint64_t end_pos, uint64_t min_c, uint64_t max_c) { if ((end_pos > size || begin_pos >= end_pos) || (min_c >= max_c) || min_c >= maximum_element) { return 0; } const auto maxi_t = rankAll(max_c, begin_pos, end_pos); const auto mini_t = rankAll(min_c, begin_pos, end_pos); return std::get<1>(maxi_t) - std::get<1>(mini_t); } // v[0, pos)でcより小さい文字の数 uint64_t rankLessThan(uint64_t c, uint64_t begin, uint64_t end) { auto t = rankAll(c, begin, end); return std::get<1>(t); } // v[0, pos)でcより大きい文字の数 uint64_t rankMoreThan(uint64_t c, uint64_t begin, uint64_t end) { auto t = rankAll(c, begin, end); return std::get<2>(t); } // v[begin, end)で(cと同じ値の数、cより小さい値の数、cより大きい値の数)を求める std::tuple rankAll(const uint64_t c, uint64_t begin, uint64_t end) { assert(end <= size); const uint64_t num = end - begin; if (begin >= end) { return std::make_tuple(0, 0, 0); } if (c >= maximum_element || end == 0) { return std::make_tuple(0, num, 0); } uint64_t rank_less_than = 0, rank_more_than = 0; for (size_t i = 0; i < bit_size && begin < end; ++i) { const uint64_t bit = (c >> (bit_size - i - 1)) & 1; const uint64_t rank0_begin = this->bit_arrays.at(i).rank(0, begin); const uint64_t rank0_end = this->bit_arrays.at(i).rank(0, end); const uint64_t rank1_begin = begin - rank0_begin; const uint64_t rank1_end = end - rank0_end; if (bit) { rank_less_than += (rank0_end - rank0_begin); // i番目のbitが0のものは除外される begin = this->begin_one.at(i) + rank1_begin; end = this->begin_one.at(i) + rank1_end; } else { rank_more_than += (rank1_end - rank1_begin); // i番目のbitが1のものは除外される begin = rank0_begin; end = rank0_end; } } const uint64_t rank = num - rank_less_than - rank_more_than; return std::make_tuple(rank, rank_less_than, rank_more_than); } // T[s, e)で出現回数が多い順にk個の(値,頻度)を返す // 頻度が同じ場合は値が小さいものが優先される std::vector> topk(uint64_t s, uint64_t e, uint64_t k) { assert(s < e); std::vector> result; // (頻度,深さ,値)の順でソート auto c = [](const std::tuple &l, const std::tuple &r) { // width if (std::get<0>(l) != std::get<0>(r)) { return std::get<0>(l) < std::get<0>(r); } // depth if (std::get<3>(l) != std::get<3>(r)) { return std::get<3>(l) > std::get<3>(r); } // value if (std::get<4>(l) != std::get<4>(r)) { return std::get<4>(l) > std::get<4>(r); } return true; }; std::priority_queue, std::vector>, decltype(c)> que(c); // width, left, right, depth, value que.push(std::make_tuple(e - s, s, e, 0, 0)); while (not que.empty()) { auto element = que.top(); que.pop(); uint64_t width, left, right, depth, value; std::tie(width, left, right, depth, value) = element; if (depth >= this->bit_size) { result.emplace_back(std::make_pair(value, right - left)); if (result.size() >= k) { break; } continue; } // 0 const uint64_t left0 = this->bit_arrays.at(depth).rank(0, left); const uint64_t right0 = this->bit_arrays.at(depth).rank(0, right); if (left0 < right0) { que.push(std::make_tuple(right0 - left0, left0, right0, depth + 1, value)); } // 1 const uint64_t left1 = this->begin_one.at(depth) + this->bit_arrays.at(depth).rank(1, left); const uint64_t right1 = this->begin_one.at(depth) + this->bit_arrays.at(depth).rank(1, right); if (left1 < right1) { que.push(std::make_tuple(right1 - left1, left1, right1, depth + 1, value | (1 << (bit_size - depth - 1)))); } } return result; }; // T[s, e)の中で[low, high]に入っている数値の合計を返す uint64_t sum(uint64_t s, uint64_t e, uint64_t low, uint64_t high) { assert(s < e); assert(low <= high); uint64_t total = 0; std::queue> que; // (left, right, depth, value) que.push(std::make_tuple(s, e, 0, 0)); while (not que.empty()) { uint64_t left, right, depth, value; std::tie(left, right, depth, value) = que.front(); que.pop(); if (depth >= this->bit_size) { if (low <= value and value <= high) { total += value * (right - left); } continue; } // 0 const uint64_t left0 = this->bit_arrays.at(depth).rank(0, left); const uint64_t right0 = this->bit_arrays.at(depth).rank(0, right); if (left0 < right0) { que.push(std::make_tuple(left0, right0, depth + 1, value)); } // 1 const uint64_t left1 = this->begin_one.at(depth) + this->bit_arrays.at(depth).rank(1, left); const uint64_t right1 = this->begin_one.at(depth) + this->bit_arrays.at(depth).rank(1, right); if (left1 < right1) { que.push(std::make_tuple(left1, right1, depth + 1, value | (1 << (bit_size - depth - 1)))); } } return total; }; // T[begin_pos, end_pos)でx <= c < yを満たす最大のcを返す uint64_t prevValue(const uint64_t begin_pos, const uint64_t end_pos, const uint64_t x, uint64_t y) { assert(end_pos <= size); const uint64_t num = end_pos - begin_pos; if (x >= y or y == 0) { return NOTFOUND; } if (y > maximum_element) { y = maximum_element; } if (begin_pos >= end_pos) { return NOTFOUND; } if (x >= maximum_element || end_pos == 0) { return NOTFOUND; } y--; // x <= c <= yにする std::stack> s; // (begin, end, depth, c, tight) s.emplace(std::make_tuple(begin_pos, end_pos, 0, 0, true)); while (not s.empty()) { uint64_t b, e, depth, c; bool tight; std::tie(b, e, depth, c, tight) = s.top(); s.pop(); if (depth == bit_size) { if (c >= x) { return c; } continue; } const uint64_t bit = (y >> (bit_size - depth - 1)) & 1; const uint64_t rank0_begin = this->bit_arrays.at(depth).rank(0, b); const uint64_t rank0_end = this->bit_arrays.at(depth).rank(0, e); const uint64_t rank1_begin = b - rank0_begin; const uint64_t rank1_end = e - rank0_end; // d番目のbitが0のものを使う const uint64_t b0 = rank0_begin; const uint64_t e0 = rank0_end; if (b0 != e0) { // 範囲がつぶれてない const uint64_t c0 = ((c << 1) | 0); s.emplace(std::make_tuple(b0, e0, depth + 1, c0, tight and bit == 0)); } // d番目のbitが1のものを使う const uint64_t b1 = this->begin_one.at(depth) + rank1_begin; const uint64_t e1 = this->begin_one.at(depth) + rank1_end; if (b1 != e1) { if (not tight or bit == 1) { const auto c1 = ((c << 1) | 1); s.emplace(std::make_tuple(b1, e1, depth + 1, c1, tight)); } } } return NOTFOUND; } // T[begin_pos, end_pos)でx <= c < yを満たす最小のcを返す uint64_t nextValue(const uint64_t begin_pos, const uint64_t end_pos, const uint64_t x, const uint64_t y) { assert(end_pos <= size); const uint64_t num = end_pos - begin_pos; if (x >= y or y == 0) { return NOTFOUND; } if (begin_pos >= end_pos) { return NOTFOUND; } if (x >= maximum_element || end_pos == 0) { return NOTFOUND; } std::stack> s; // (begin, end, depth, c, tight) s.emplace(std::make_tuple(begin_pos, end_pos, 0, 0, true)); while (not s.empty()) { uint64_t b, e, depth, c; bool tight; std::tie(b, e, depth, c, tight) = s.top(); s.pop(); if (depth == bit_size) { if (c < y) { return c; } continue; } const uint64_t bit = (x >> (bit_size - depth - 1)) & 1; const uint64_t rank0_begin = this->bit_arrays.at(depth).rank(0, b); const uint64_t rank0_end = this->bit_arrays.at(depth).rank(0, e); const uint64_t rank1_begin = b - rank0_begin; const uint64_t rank1_end = e - rank0_end; // d番目のbitが1のものを使う const uint64_t b1 = this->begin_one.at(depth) + rank1_begin; const uint64_t e1 = this->begin_one.at(depth) + rank1_end; if (b1 != e1) { const auto c1 = ((c << 1) | 1); s.emplace(std::make_tuple(b1, e1, depth + 1, c1, tight and bit == 1)); } // d番目のbitが0のものを使う const uint64_t b0 = rank0_begin; const uint64_t e0 = rank0_end; if (b0 != e0) { if (not tight or bit == 0) { const uint64_t c0 = ((c << 1) | 0); s.emplace(std::make_tuple(b0, e0, depth + 1, c0, tight)); } } } return NOTFOUND; } // T[s1, e1)とT[s2, e2)に共通して出現する要素を求める std::vector> intersect(uint64_t _s1, uint64_t _e1, uint64_t _s2, uint64_t _e2) { assert(_s1 < _e1); assert(_s2 < _e2); std::vector> intersection; std::queue> que; // s1, e1, s2, e2, depth, value que.push(std::make_tuple(_s1, _e1, _s2, _e2, 0, 0)); while (not que.empty()) { auto e = que.front(); que.pop(); uint64_t s1, e1, s2, e2, depth, value; std::tie(s1, e1, s2, e2, depth, value) = e; if (depth >= this->bit_size) { intersection.emplace_back(std::make_tuple(value, e1 - s1, e2 - s2)); continue; } // 0 uint64_t s1_0 = this->bit_arrays.at(depth).rank(0, s1); uint64_t e1_0 = this->bit_arrays.at(depth).rank(0, e1); uint64_t s2_0 = this->bit_arrays.at(depth).rank(0, s2); uint64_t e2_0 = this->bit_arrays.at(depth).rank(0, e2); if (s1_0 != e1_0 and s2_0 != e2_0) { que.push(std::make_tuple(s1_0, e1_0, s2_0, e2_0, depth + 1, value)); } // 1 uint64_t s1_1 = this->begin_one.at(depth) + this->bit_arrays.at(depth).rank(1, s1); uint64_t e1_1 = this->begin_one.at(depth) + this->bit_arrays.at(depth).rank(1, e1); uint64_t s2_1 = this->begin_one.at(depth) + this->bit_arrays.at(depth).rank(1, s2); uint64_t e2_1 = this->begin_one.at(depth) + this->bit_arrays.at(depth).rank(1, e2); if (s1_1 != e1_1 and s2_1 != e2_1) { que.push(std::make_tuple(s1_1, e1_1, s2_1, e2_1, depth + 1, value | (1 << bit_size - depth - 1))); } } return intersection; }; private: uint64_t get_num_of_bit(uint64_t x) { if (x == 0) return 0; x--; uint64_t bit_num = 0; while (x >> bit_num) { ++bit_num; } return bit_num; } }; int main() { int N, K; cin >> N >> K; V A(N); FOR(i, 0, N) { cin >> A[i]; } WaveletMatrix wm(A); uint64_t ans = INF; FOR(i, 0, N - K + 1) { uint64_t begin = i; uint64_t end = i + K; uint64_t idx = wm.quantileRange(begin, end, K / 2); uint64_t m = wm.access(idx); auto ps = wm.topk(begin, end, K + 1); uint64_t a = 0; FOE(&p, ps) { uint64_t diff = max(p.first, m) - min(p.first, m); a += diff * p.second; } ans = min(ans, a); } print(ans); return 0; }