結果
問題 | No.5007 Steiner Space Travel |
ユーザー | yupiteru_kun |
提出日時 | 2022-07-30 17:57:11 |
言語 | C# (.NET 8.0.203) |
結果 |
TLE
|
実行時間 | - |
コード長 | 39,655 bytes |
コンパイル時間 | 6,430 ms |
実行使用メモリ | 138,468 KB |
スコア | 0 |
最終ジャッジ日時 | 2022-07-30 17:58:04 |
合計ジャッジ時間 | 43,273 ms |
ジャッジサーバーID (参考情報) |
judge16 / judge11 |
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テストケース
テストケース表示入力 | 結果 | 実行時間 実行使用メモリ |
---|---|---|
testcase_00 | TLE | - |
testcase_01 | TLE | - |
testcase_02 | TLE | - |
testcase_03 | TLE | - |
testcase_04 | TLE | - |
testcase_05 | TLE | - |
testcase_06 | TLE | - |
testcase_07 | TLE | - |
testcase_08 | TLE | - |
testcase_09 | TLE | - |
testcase_10 | TLE | - |
testcase_11 | TLE | - |
testcase_12 | TLE | - |
testcase_13 | TLE | - |
testcase_14 | TLE | - |
testcase_15 | TLE | - |
testcase_16 | TLE | - |
testcase_17 | TLE | - |
testcase_18 | TLE | - |
testcase_19 | TLE | - |
testcase_20 | TLE | - |
testcase_21 | TLE | - |
testcase_22 | TLE | - |
testcase_23 | TLE | - |
testcase_24 | TLE | - |
testcase_25 | TLE | - |
testcase_26 | TLE | - |
testcase_27 | TLE | - |
testcase_28 | TLE | - |
testcase_29 | TLE | - |
コンパイルメッセージ
Determining projects to restore... Restored /home/judge/data/code/main.csproj (in 108 ms). .NET 向け Microsoft (R) Build Engine バージョン 17.0.0-preview-21470-01+cb055d28f Copyright (C) Microsoft Corporation.All rights reserved. プレビュー版の .NET を使用しています。https://aka.ms/dotnet-core-preview をご覧ください main -> /home/judge/data/code/bin/Release/net6.0/main.dll main -> /home/judge/data/code/bin/Release/net6.0/publish/
ソースコード
using System; using System.Collections.Generic; using System.IO; using System.Linq; using static System.Math; using System.Text; using System.Threading; using System.Globalization; using System.Runtime.CompilerServices; using System.Runtime.InteropServices; using Library; namespace Program { public static class ProblemA { static bool SAIKI = false; static public int numberOfRandomCases = 0; static public void MakeTestCase(List<string> _input, List<string> _output, ref Func<string[], bool> _outputChecker) { } static int A = 5; static int N = 5; static int M = 5; static int TAYOU = 4; static public long Func1((int x, int y)[] ab, List<(int from, int to, int keiyu)> pathList) { var startTime = DateTime.Now; Func<int, int, long> calcDist = (f, t) => { var fromX = 0; var fromY = 0; var toX = 0; var toY = 0; var fromCoef = 1L; var toCoef = 1L; fromX = ab[f - 1].x; fromY = ab[f - 1].y; if (f <= N) { fromCoef = A; } toX = ab[t - 1].x; toY = ab[t - 1].y; if (t <= N) { toCoef = A; } return fromCoef * toCoef * ((fromX - toX) * (fromX - toX) + (fromY - toY) * (fromY - toY)); }; var score = 0L; { var done = new bool[N + 1]; var from = 1; done[from] = true; for (var i = 1; i < N; ++i) { var kouho = new LIB_PriorityQueue(); for (var j = 1; j <= N; ++j) { if (done[j]) continue; kouho.Push(-calcDist(from, j), j); if (kouho.Count > TAYOU) kouho.Pop(); } var kouhoList = new List<int>(); while (kouho.Count > 0) kouhoList.Add(kouho.Pop().Value); var minNum = kouhoList[(int)(xorshift % kouhoList.Count)]; score += calcDist(from, minNum); pathList.Add((from, minNum, -1)); from = minNum; done[from] = true; } score += calcDist(from, 1); pathList.Add((from, 1, -1)); } var hasEdge = ab.Select(_ => { var ret = new int[2]; ret[0] = ret[1] = -1; return ret; }).ToArray(); for (var i = 0; i < pathList.Count; ++i) { if (hasEdge[pathList[i].from - 1][0] == -1) hasEdge[pathList[i].from - 1][0] = i; else hasEdge[pathList[i].from - 1][1] = i; if (hasEdge[pathList[i].to - 1][0] == -1) hasEdge[pathList[i].to - 1][0] = i; else hasEdge[pathList[i].to - 1][1] = i; } while ((DateTime.Now - startTime).TotalMilliseconds < 130) { var p1 = (int)(xorshift % pathList.Count); var p2 = (int)(xorshift % (pathList.Count - 1)); if (p2 >= p1) ++p2; if (pathList[p1].from == pathList[p2].from || pathList[p1].from == pathList[p2].to || pathList[p1].to == pathList[p2].from || pathList[p1].to == pathList[p2].to) { continue; } var goal = 0; { var from = pathList[p1].from; goal = pathList[p1].to; while (true) { if (goal == pathList[p2].from || goal == pathList[p2].to) break; var to = 0; var pos1 = pathList[hasEdge[goal - 1][0]]; var pos2 = pathList[hasEdge[goal - 1][1]]; if (pos1.from == from || pos1.to == from) { if (pos2.from == goal) to = pos2.to; else to = pos2.from; } else { if (pos1.from == goal) to = pos1.to; else to = pos1.from; } from = goal; goal = to; } } var newScore = score; newScore -= calcDist(pathList[p1].from, pathList[p1].to); newScore -= calcDist(pathList[p2].from, pathList[p2].to); if (goal == pathList[p2].from) { newScore += calcDist(pathList[p1].from, pathList[p2].from); newScore += calcDist(pathList[p2].to, pathList[p1].to); if (newScore < score) { score = newScore; if (hasEdge[pathList[p1].to - 1][0] == p1) { hasEdge[pathList[p1].to - 1][0] = p2; } else { hasEdge[pathList[p1].to - 1][1] = p2; } if (hasEdge[pathList[p2].from - 1][0] == p2) { hasEdge[pathList[p2].from - 1][0] = p1; } else { hasEdge[pathList[p2].from - 1][1] = p1; } var newp1 = (pathList[p1].from, pathList[p2].from, -1); var newp2 = (pathList[p2].to, pathList[p1].to, -1); pathList[p1] = newp1; pathList[p2] = newp2; } } else { newScore += calcDist(pathList[p1].from, pathList[p2].to); newScore += calcDist(pathList[p2].from, pathList[p1].to); if (newScore < score) { score = newScore; if (hasEdge[pathList[p1].to - 1][0] == p1) { hasEdge[pathList[p1].to - 1][0] = p2; } else { hasEdge[pathList[p1].to - 1][1] = p2; } if (hasEdge[pathList[p2].to - 1][0] == p2) { hasEdge[pathList[p2].to - 1][0] = p1; } else { hasEdge[pathList[p2].to - 1][1] = p1; } var newp1 = (pathList[p1].from, pathList[p2].to, -1); var newp2 = (pathList[p2].from, pathList[p1].to, -1); pathList[p1] = newp1; pathList[p2] = newp2; } } } var addedNum = 0; { var maxKaizen = 0L; var maxNum = 0; for (var i = 0; i < pathList.Count; ++i) { var thisKaizen = calcDist(pathList[i].from, pathList[i].to) - calcDist(pathList[i].from, pathList[i].to) / 25; ab[N] = ab[pathList[i].from - 1]; ab[N + 1] = ab[pathList[i].to - 1]; for (var j = 0; j < pathList.Count; ++j) { if (i == j) continue; var item = pathList[j]; var kijunDist = calcDist(item.from, item.to); var newDist1 = calcDist(item.from, N + 1) + calcDist(N + 1, item.to); var newDist2 = calcDist(item.from, N + 2) + calcDist(N + 2, item.to); thisKaizen += Max(0, kijunDist - Min(newDist1, newDist2)); } if (maxKaizen.Chmax(thisKaizen)) maxNum = i; } ab[N] = ab[pathList[maxNum].from - 1]; ab[N + 1] = ab[pathList[maxNum].to - 1]; score -= calcDist(pathList[maxNum].from, pathList[maxNum].to); score += calcDist(N + 1, N + 2); var newForFrom = pathList.Count; pathList.Add((pathList[maxNum].from, N + 1, -1)); var newForTo = pathList.Count; pathList.Add((pathList[maxNum].to, N + 2, -1)); if (hasEdge[pathList[maxNum].from - 1][0] == maxNum) hasEdge[pathList[maxNum].from - 1][0] = newForFrom; else hasEdge[pathList[maxNum].from - 1][1] = newForFrom; if (hasEdge[pathList[maxNum].to - 1][0] == maxNum) hasEdge[pathList[maxNum].to - 1][0] = newForTo; else hasEdge[pathList[maxNum].to - 1][1] = newForTo; hasEdge[N + 0][0] = newForFrom; hasEdge[N + 1][0] = newForTo; hasEdge[N + 0][1] = maxNum; hasEdge[N + 1][1] = maxNum; pathList[maxNum] = (N + 1, N + 2, -1); addedNum += 2; } { var kouho = new List<(long kaizen, int x, int y)>(); for (var i = 0; i <= 1000; i += 5) { for (var j = 0; j <= 1000; j += 5) { ab[N + addedNum] = (i, j); var sum = 0L; foreach (var item in pathList) { var kijunDist = calcDist(item.from, item.to); var newDist = calcDist(item.from, N + addedNum + 1) + calcDist(N + addedNum + 1, item.to); sum += Max(0, kijunDist - newDist); } if (sum > 0) kouho.Add((sum, i, j)); } } { var sum = 0L; foreach (var item in pathList) { var kijunDist = calcDist(item.from, item.to); var newDist = calcDist(item.from, N + 1) + calcDist(N + 1, item.to); sum += Max(0, kijunDist - newDist); } if (sum > 0) kouho.Add((sum, -1, -1)); } { var sum = 0L; foreach (var item in pathList) { var kijunDist = calcDist(item.from, item.to); var newDist = calcDist(item.from, N + 2) + calcDist(N + 2, item.to); sum += Max(0, kijunDist - newDist); } if (sum > 0) kouho.Add((sum, -2, -2)); } kouho = kouho.OrderByDescending(e => e.kaizen).ToList(); foreach (var item2 in kouho) { var staNum = addedNum + N + 1; if (item2.x < 0) { staNum = -item2.x + N; } else { staNum = addedNum + N + 1; ab[staNum - 1] = (item2.x, item2.y); } var sum = 0L; foreach (var item in pathList) { if (item.keiyu != -1) continue; var kijunDist = calcDist(item.from, item.to); var newDist = calcDist(item.from, staNum) + calcDist(staNum, item.to); sum += Max(0, kijunDist - newDist); } if (sum >= item2.kaizen * 9 / 10 && sum > 0) { for (var i = 0; i < pathList.Count; ++i) { var item = pathList[i]; if (item.keiyu != -1) continue; var kijunDist = calcDist(item.from, item.to); var newDist = calcDist(item.from, staNum) + calcDist(staNum, item.to); var thisKaizen = kijunDist - newDist; if (thisKaizen > 0) { score -= thisKaizen; pathList[i] = (item.from, item.to, staNum); } } if (item2.x >= 0) ++addedNum; } if (addedNum == M) break; } } return score; } static public long Func2((int x, int y)[] ab, List<(int from, int to, int keiyu)> pathList) { var startTime = DateTime.Now; Func<int, int, long> calcDist = (f, t) => { var fromX = 0; var fromY = 0; var toX = 0; var toY = 0; var fromCoef = 1L; var toCoef = 1L; fromX = ab[f - 1].x; fromY = ab[f - 1].y; if (f <= N) { fromCoef = A; } toX = ab[t - 1].x; toY = ab[t - 1].y; if (t <= N) { toCoef = A; } return fromCoef * toCoef * ((fromX - toX) * (fromX - toX) + (fromY - toY) * (fromY - toY)); }; var score = 0L; { var done = new bool[N + 1]; var from = 1; done[from] = true; for (var i = 1; i < N; ++i) { var kouho = new LIB_PriorityQueue(); for (var j = 1; j <= N; ++j) { if (done[j]) continue; kouho.Push(-calcDist(from, j), j); if (kouho.Count > TAYOU) kouho.Pop(); } var kouhoList = new List<int>(); while (kouho.Count > 0) kouhoList.Add(kouho.Pop().Value); var minNum = kouhoList[(int)(xorshift % kouhoList.Count)]; score += calcDist(from, minNum); pathList.Add((from, minNum, -1)); from = minNum; done[from] = true; } score += calcDist(from, 1); pathList.Add((from, 1, -1)); } var hasEdge = ab.Select(_ => { var ret = new int[2]; ret[0] = ret[1] = -1; return ret; }).ToArray(); for (var i = 0; i < pathList.Count; ++i) { if (hasEdge[pathList[i].from - 1][0] == -1) hasEdge[pathList[i].from - 1][0] = i; else hasEdge[pathList[i].from - 1][1] = i; if (hasEdge[pathList[i].to - 1][0] == -1) hasEdge[pathList[i].to - 1][0] = i; else hasEdge[pathList[i].to - 1][1] = i; } while ((DateTime.Now - startTime).TotalMilliseconds < 130) { var p1 = (int)(xorshift % pathList.Count); var p2 = (int)(xorshift % (pathList.Count - 1)); if (p2 >= p1) ++p2; if (pathList[p1].from == pathList[p2].from || pathList[p1].from == pathList[p2].to || pathList[p1].to == pathList[p2].from || pathList[p1].to == pathList[p2].to) { continue; } var goal = 0; { var from = pathList[p1].from; goal = pathList[p1].to; while (true) { if (goal == pathList[p2].from || goal == pathList[p2].to) break; var to = 0; var pos1 = pathList[hasEdge[goal - 1][0]]; var pos2 = pathList[hasEdge[goal - 1][1]]; if (pos1.from == from || pos1.to == from) { if (pos2.from == goal) to = pos2.to; else to = pos2.from; } else { if (pos1.from == goal) to = pos1.to; else to = pos1.from; } from = goal; goal = to; } } var newScore = score; newScore -= calcDist(pathList[p1].from, pathList[p1].to); newScore -= calcDist(pathList[p2].from, pathList[p2].to); if (goal == pathList[p2].from) { newScore += calcDist(pathList[p1].from, pathList[p2].from); newScore += calcDist(pathList[p2].to, pathList[p1].to); if (newScore < score) { score = newScore; if (hasEdge[pathList[p1].to - 1][0] == p1) { hasEdge[pathList[p1].to - 1][0] = p2; } else { hasEdge[pathList[p1].to - 1][1] = p2; } if (hasEdge[pathList[p2].from - 1][0] == p2) { hasEdge[pathList[p2].from - 1][0] = p1; } else { hasEdge[pathList[p2].from - 1][1] = p1; } var newp1 = (pathList[p1].from, pathList[p2].from, -1); var newp2 = (pathList[p2].to, pathList[p1].to, -1); pathList[p1] = newp1; pathList[p2] = newp2; } } else { newScore += calcDist(pathList[p1].from, pathList[p2].to); newScore += calcDist(pathList[p2].from, pathList[p1].to); if (newScore < score) { score = newScore; if (hasEdge[pathList[p1].to - 1][0] == p1) { hasEdge[pathList[p1].to - 1][0] = p2; } else { hasEdge[pathList[p1].to - 1][1] = p2; } if (hasEdge[pathList[p2].to - 1][0] == p2) { hasEdge[pathList[p2].to - 1][0] = p1; } else { hasEdge[pathList[p2].to - 1][1] = p1; } var newp1 = (pathList[p1].from, pathList[p2].to, -1); var newp2 = (pathList[p2].from, pathList[p1].to, -1); pathList[p1] = newp1; pathList[p2] = newp2; } } } var addedNum = 0; { var kouho = new List<(long kaizen, int x, int y)>(); for (var i = 0; i <= 1000; i += 20) { for (var j = 0; j <= 1000; j += 20) { ab[N + addedNum] = (i, j); var sum = 0L; foreach (var item in pathList) { var kijunDist = calcDist(item.from, item.to); var newDist = calcDist(item.from, N + addedNum + 1) + calcDist(N + addedNum + 1, item.to); sum += Max(0, kijunDist - newDist); } if (sum > 0) kouho.Add((sum, i, j)); } } kouho = kouho.OrderByDescending(e => e.kaizen).ToList(); foreach (var item2 in kouho) { var staNum = addedNum + N + 1; ab[staNum - 1] = (item2.x, item2.y); var sum = 0L; foreach (var item in pathList) { if (item.keiyu != -1) continue; var kijunDist = calcDist(item.from, item.to); var newDist = calcDist(item.from, staNum) + calcDist(staNum, item.to); sum += Max(0, kijunDist - newDist); } if (sum >= item2.kaizen * 9 / 10 && sum > 0) { for (var i = 0; i < pathList.Count; ++i) { var item = pathList[i]; if (item.keiyu != -1) continue; var kijunDist = calcDist(item.from, item.to); var newDist = calcDist(item.from, staNum) + calcDist(staNum, item.to); var thisKaizen = kijunDist - newDist; if (thisKaizen > 0) { score -= thisKaizen; pathList[i] = (item.from, item.to, staNum); } } ++addedNum; } if (addedNum == M) break; } } return score; } static public void Solve() { N = (int)NN; M = (int)NN; (int x, int y)[] ab = Repeat(0, N).Select(_ => ((int)NN, (int)NN)).Concat(Repeat(0, M).Select(_ => (0, 0))).ToArray(); var pathList = new List<(int from, int to, int keiyu)>(); var ab1 = ab.ToArray(); var pathList1 = new List<(int from, int to, int keiyu)>(); var ab2 = ab.ToArray(); var pathList2 = new List<(int from, int to, int keiyu)>(); var ab3 = ab.ToArray(); var pathList3 = new List<(int from, int to, int keiyu)>(); var score1 = Func1(ab1, pathList1); var score2 = Func1(ab2, pathList2); var score3 = long.MaxValue;//Func2(ab3, pathList3); var max = Min(score1, Min(score2, score3)); if (max == score1) { ab = ab1; pathList = pathList1; } else if (max == score2) { ab = ab2; pathList = pathList2; } else { ab = ab3; pathList = pathList3; } { var hasEdge = ab.Select(_ => { var ret = new int[2]; ret[0] = ret[1] = -1; return ret; }).ToArray(); for (var i = 0; i < pathList.Count; ++i) { if (hasEdge[pathList[i].from - 1][0] == -1) hasEdge[pathList[i].from - 1][0] = i; else hasEdge[pathList[i].from - 1][1] = i; if (hasEdge[pathList[i].to - 1][0] == -1) hasEdge[pathList[i].to - 1][0] = i; else hasEdge[pathList[i].to - 1][1] = i; } for (var i = 0; i < M; ++i) { Console.WriteLine($"{ab[i + N].x} {ab[i + N].y}"); } var ansList = new List<string>(); var from = -1; var now = 1; ansList.Add($"1 1"); for (var i = 0; i < pathList.Count; ++i) { var to = 0; var p1 = pathList[hasEdge[now - 1][0]]; var p2 = pathList[hasEdge[now - 1][1]]; var keiyu = -1; if (p1.from == from || p1.to == from) { if (p2.from == now) to = p2.to; else to = p2.from; keiyu = p2.keiyu; } else { if (p1.from == now) to = p1.to; else to = p1.from; keiyu = p1.keiyu; } from = now; now = to; if (keiyu != -1) ansList.Add($"2 {keiyu - N}"); if (now > N) ansList.Add($"2 {now - N}"); else ansList.Add($"1 {now}"); } Console.WriteLine(ansList.Count); foreach (var item in ansList) { Console.WriteLine(item); } } } class Printer : StreamWriter { public override IFormatProvider FormatProvider { get { return CultureInfo.InvariantCulture; } } public Printer(Stream stream) : base(stream, new UTF8Encoding(false, true)) { base.AutoFlush = false; } public Printer(Stream stream, Encoding encoding) : base(stream, encoding) { base.AutoFlush = false; } } static LIB_FastIO fastio = new LIB_FastIODebug(); static public void Main(string[] args) { if (args.Length == 0) { fastio = new LIB_FastIO(); Console.SetOut(new Printer(Console.OpenStandardOutput())); } if (SAIKI) { var t = new Thread(Solve, 134217728); t.Start(); t.Join(); } else Solve(); Console.Out.Flush(); } static long NN => fastio.Long(); static double ND => fastio.Double(); static string NS => fastio.Scan(); static long[] NNList(long N) => Repeat(0, N).Select(_ => NN).ToArray(); static double[] NDList(long N) => Repeat(0, N).Select(_ => ND).ToArray(); static string[] NSList(long N) => Repeat(0, N).Select(_ => NS).ToArray(); static long Count<T>(this IEnumerable<T> x, Func<T, bool> pred) => Enumerable.Count(x, pred); static IEnumerable<T> Repeat<T>(T v, long n) => Enumerable.Repeat<T>(v, (int)n); static IEnumerable<int> Range(long s, long c) => Enumerable.Range((int)s, (int)c); static IOrderedEnumerable<T> OrderByRand<T>(this IEnumerable<T> x) => Enumerable.OrderBy(x, _ => xorshift); static IOrderedEnumerable<T> OrderBy<T>(this IEnumerable<T> x) => Enumerable.OrderBy(x.OrderByRand(), e => e); static IOrderedEnumerable<T1> OrderBy<T1, T2>(this IEnumerable<T1> x, Func<T1, T2> selector) => Enumerable.OrderBy(x.OrderByRand(), selector); static IOrderedEnumerable<T> OrderByDescending<T>(this IEnumerable<T> x) => Enumerable.OrderByDescending(x.OrderByRand(), e => e); static IOrderedEnumerable<T1> OrderByDescending<T1, T2>(this IEnumerable<T1> x, Func<T1, T2> selector) => Enumerable.OrderByDescending(x.OrderByRand(), selector); static IOrderedEnumerable<string> OrderBy(this IEnumerable<string> x) => x.OrderByRand().OrderBy(e => e, StringComparer.OrdinalIgnoreCase); static IOrderedEnumerable<T> OrderBy<T>(this IEnumerable<T> x, Func<T, string> selector) => x.OrderByRand().OrderBy(selector, StringComparer.OrdinalIgnoreCase); static IOrderedEnumerable<string> OrderByDescending(this IEnumerable<string> x) => x.OrderByRand().OrderByDescending(e => e, StringComparer.OrdinalIgnoreCase); static IOrderedEnumerable<T> OrderByDescending<T>(this IEnumerable<T> x, Func<T, string> selector) => x.OrderByRand().OrderByDescending(selector, StringComparer.OrdinalIgnoreCase); static string Join<T>(this IEnumerable<T> x, string separator = "") => string.Join(separator, x); static uint xorshift { get { _xsi.MoveNext(); return _xsi.Current; } } static IEnumerator<uint> _xsi = _xsc(); static IEnumerator<uint> _xsc() { uint x = 123456789, y = 362436069, z = 521288629, w = (uint)(DateTime.Now.Ticks & 0xffffffff); while (true) { var t = x ^ (x << 11); x = y; y = z; z = w; w = (w ^ (w >> 19)) ^ (t ^ (t >> 8)); yield return w; } } static bool Chmax<T>(this ref T lhs, T rhs) where T : struct, IComparable<T> { if (lhs.CompareTo(rhs) < 0) { lhs = rhs; return true; } return false; } static bool Chmin<T>(this ref T lhs, T rhs) where T : struct, IComparable<T> { if (lhs.CompareTo(rhs) > 0) { lhs = rhs; return true; } return false; } static void Fill<T>(this T[] array, T value) => array.AsSpan().Fill(value); static void Fill<T>(this T[,] array, T value) => MemoryMarshal.CreateSpan(ref array[0, 0], array.Length).Fill(value); static void Fill<T>(this T[,,] array, T value) => MemoryMarshal.CreateSpan(ref array[0, 0, 0], array.Length).Fill(value); static void Fill<T>(this T[,,,] array, T value) => MemoryMarshal.CreateSpan(ref array[0, 0, 0, 0], array.Length).Fill(value); } } namespace Library { class LIB_FastIO { [MethodImpl(MethodImplOptions.AggressiveInlining)] public LIB_FastIO() { str = Console.OpenStandardInput(); } readonly Stream str; readonly byte[] buf = new byte[2048]; int len, ptr; [MethodImpl(MethodImplOptions.AggressiveInlining)] byte read() { if (ptr >= len) { ptr = 0; if ((len = str.Read(buf, 0, 2048)) <= 0) { return 0; } } return buf[ptr++]; } [MethodImpl(MethodImplOptions.AggressiveInlining)] char Char() { byte b = 0; do b = read(); while (b < 33 || 126 < b); return (char)b; } [MethodImpl(MethodImplOptions.AggressiveInlining)] virtual public string Scan() { var sb = new StringBuilder(); for (var b = Char(); b >= 33 && b <= 126; b = (char)read()) sb.Append(b); return sb.ToString(); } [MethodImpl(MethodImplOptions.AggressiveInlining)] virtual public long Long() { long ret = 0; byte b = 0; var ng = false; do b = read(); while (b != '-' && (b < '0' || '9' < b)); if (b == '-') { ng = true; b = read(); } for (; true; b = read()) { if (b < '0' || '9' < b) return ng ? -ret : ret; else ret = (ret << 3) + (ret << 1) + b - '0'; } } [MethodImpl(MethodImplOptions.AggressiveInlining)] virtual public double Double() { return double.Parse(Scan(), CultureInfo.InvariantCulture); } } class LIB_FastIODebug : LIB_FastIO { Queue<string> param = new Queue<string>(); [MethodImpl(MethodImplOptions.AggressiveInlining)] string NextString() { if (param.Count == 0) foreach (var item in Console.ReadLine().Split(' ')) param.Enqueue(item); return param.Dequeue(); } [MethodImpl(MethodImplOptions.AggressiveInlining)] public LIB_FastIODebug() { } [MethodImpl(MethodImplOptions.AggressiveInlining)] public override string Scan() => NextString(); [MethodImpl(MethodImplOptions.AggressiveInlining)] public override long Long() => long.Parse(NextString()); [MethodImpl(MethodImplOptions.AggressiveInlining)] public override double Double() => double.Parse(NextString()); } class LIB_PriorityQueue { long[] heap; int[] dat; public (long Key, int Value) Peek => (heap[0], dat[0]); public long Count { get; private set; } [MethodImpl(MethodImplOptions.AggressiveInlining)] public LIB_PriorityQueue() { heap = new long[8]; dat = new int[8]; } [MethodImpl(MethodImplOptions.AggressiveInlining)] public void Push(long key) => Push(key, 0); [MethodImpl(MethodImplOptions.AggressiveInlining)] public void Push(long key, int val) { if (Count == heap.Length) Expand(); var i = (int)Count++; ref long heapref = ref heap[0]; ref int datref = ref dat[0]; Unsafe.Add<long>(ref heapref, i) = key; Unsafe.Add<int>(ref datref, i) = val; while (i > 0) { var ni = (i - 1) / 2; var heapni = Unsafe.Add<long>(ref heapref, ni); if (key >= heapni) break; Unsafe.Add<long>(ref heapref, i) = heapni; Unsafe.Add<int>(ref datref, i) = Unsafe.Add<int>(ref datref, ni); i = ni; } Unsafe.Add<long>(ref heapref, i) = key; Unsafe.Add<int>(ref datref, i) = val; } [MethodImpl(MethodImplOptions.AggressiveInlining)] public (long Key, int Value) Pop() { ref long heapref = ref heap[0]; ref int datref = ref dat[0]; var ret = (heapref, datref); var cnt = (int)(--Count); var key = Unsafe.Add<long>(ref heapref, cnt); var val = Unsafe.Add<int>(ref datref, cnt); if (cnt == 0) return ret; var i = 0; while ((i << 1) + 1 < cnt) { var i1 = (i << 1) + 1; var i2 = (i << 1) + 2; if (i2 < cnt && Unsafe.Add<long>(ref heapref, i1) > Unsafe.Add<long>(ref heapref, i2)) i1 = i2; var heapi1 = Unsafe.Add<long>(ref heapref, i1); if (key <= heapi1) break; Unsafe.Add<long>(ref heapref, i) = heapi1; Unsafe.Add<int>(ref datref, i) = Unsafe.Add<int>(ref datref, i1); i = i1; } Unsafe.Add<long>(ref heapref, i) = key; Unsafe.Add<int>(ref datref, i) = val; return ret; } [MethodImpl(MethodImplOptions.AggressiveInlining)] void Expand() { var len = heap.Length; var tmp = new long[len << 1]; var tmp2 = new int[len << 1]; Unsafe.CopyBlock(ref Unsafe.As<long, byte>(ref tmp[0]), ref Unsafe.As<long, byte>(ref heap[0]), (uint)(8 * len)); Unsafe.CopyBlock(ref Unsafe.As<int, byte>(ref tmp2[0]), ref Unsafe.As<int, byte>(ref dat[0]), (uint)(4 * len)); heap = tmp; dat = tmp2; } [MethodImpl(MethodImplOptions.AggressiveInlining)] public (long Key, int Value)[] NoSortList() { var ret = new (long Key, int Value)[Count]; ref long heapref = ref heap[0]; ref int datref = ref dat[0]; for (var i = 0; i < Count; ++i) { ret[i] = (Unsafe.Add<long>(ref heapref, i), Unsafe.Add<int>(ref datref, i)); } return ret; } } class LIB_PriorityQueue<T> { T[] heap; Comparison<T> comp; public T Peek => heap[0]; public long Count { get; private set; } [MethodImpl(MethodImplOptions.AggressiveInlining)] public LIB_PriorityQueue(long cap, Comparison<T> cmp, bool asc = true) { heap = new T[cap]; comp = asc ? cmp : (x, y) => cmp(y, x); } [MethodImpl(MethodImplOptions.AggressiveInlining)] public LIB_PriorityQueue(Comparison<T> cmp, bool asc = true) { heap = new T[8]; comp = asc ? cmp : (x, y) => cmp(y, x); } [MethodImpl(MethodImplOptions.AggressiveInlining)] public LIB_PriorityQueue(long cap, bool asc = true) : this(cap, Comparer<T>.Default.Compare, asc) { } [MethodImpl(MethodImplOptions.AggressiveInlining)] public LIB_PriorityQueue(bool asc = true) : this(Comparer<T>.Default.Compare, asc) { } [MethodImpl(MethodImplOptions.AggressiveInlining)] public void Push(T val) { if (Count == heap.Length) Expand(); var i = Count++; heap[i] = val; while (i > 0) { var ni = (i - 1) / 2; if (comp(val, heap[ni]) >= 0) break; heap[i] = heap[ni]; i = ni; } heap[i] = val; } [MethodImpl(MethodImplOptions.AggressiveInlining)] public T Pop() { var ret = heap[0]; var val = heap[--Count]; if (Count == 0) return ret; var i = 0; while ((i << 1) + 1 < Count) { var i1 = (i << 1) + 1; var i2 = (i << 1) + 2; if (i2 < Count && comp(heap[i1], heap[i2]) > 0) i1 = i2; if (comp(val, heap[i1]) <= 0) break; heap[i] = heap[i1]; i = i1; } heap[i] = val; return ret; } [MethodImpl(MethodImplOptions.AggressiveInlining)] void Expand() { var tmp = new T[Count << 1]; for (var i = 0; i < heap.Length; ++i) tmp[i] = heap[i]; heap = tmp; } [MethodImpl(MethodImplOptions.AggressiveInlining)] public T[] NoSortList() { var ret = new List<T>(); for (var i = 0; i < Count; ++i) { ret.Add(heap[i]); } return ret.ToArray(); } } class LIB_PriorityQueue<TK, TV> { LIB_PriorityQueue<KeyValuePair<TK, TV>> q; public KeyValuePair<TK, TV> Peek => q.Peek; public long Count => q.Count; [MethodImpl(MethodImplOptions.AggressiveInlining)] public LIB_PriorityQueue(long cap, Comparison<TK> cmp, bool asc = true) { q = new LIB_PriorityQueue<KeyValuePair<TK, TV>>(cap, (x, y) => cmp(x.Key, y.Key), asc); } [MethodImpl(MethodImplOptions.AggressiveInlining)] public LIB_PriorityQueue(Comparison<TK> cmp, bool asc = true) { q = new LIB_PriorityQueue<KeyValuePair<TK, TV>>((x, y) => cmp(x.Key, y.Key), asc); } [MethodImpl(MethodImplOptions.AggressiveInlining)] public LIB_PriorityQueue(long cap, bool asc = true) : this(cap, Comparer<TK>.Default.Compare, asc) { } [MethodImpl(MethodImplOptions.AggressiveInlining)] public LIB_PriorityQueue(bool asc = true) : this(Comparer<TK>.Default.Compare, asc) { } [MethodImpl(MethodImplOptions.AggressiveInlining)] public void Push(TK k, TV v) => q.Push(new KeyValuePair<TK, TV>(k, v)); [MethodImpl(MethodImplOptions.AggressiveInlining)] public KeyValuePair<TK, TV> Pop() => q.Pop(); [MethodImpl(MethodImplOptions.AggressiveInlining)] public KeyValuePair<TK, TV>[] NoSortList() => q.NoSortList(); } }