public void solveProblemGreedy() { Greedy greedyAlgorithm = new Greedy(Cities); Route = greedyAlgorithm.RunGreedyTSP(); bssf = new TSPSolution(Route); // update the cost of the tour. Program.MainForm.tbCostOfTour.Text = " " + bssf.costOfRoute(); Program.MainForm.tbElapsedTime.Text = greedyAlgorithm.time.TotalSeconds.ToString(); // do a refresh. Program.MainForm.Invalidate(); }
public ArrayList RunTSP(City[] Cities) { Route = new ArrayList(); Stopwatch timer = new Stopwatch(); bAndBTime = new TimeSpan(); timer.Start(); Greedy greedyAlgorithm = new Greedy(Cities); ArrayList greedyRoute = greedyAlgorithm.RunGreedyTSP(); double[,] matrix = new double[Cities.Length, Cities.Length]; //Populate each array item with each respective edge cost for (int i = 0; i < Cities.Length; i++) {//O(n^2) for (int j = 0; j < Cities.Length; j++) { if (i == j) { matrix[i, j] = double.PositiveInfinity; } else { matrix[i, j] = Cities[i].costToGetTo(Cities[j]); } } } IntervalHeap<State> queue = new IntervalHeap<State>(); double bestSolutionSoFar = greedyAlgorithm.BestSolutionSoFar(); bssfUpdatesAmt = 0; prunedAmt = 0; State bssfState = null; totalStatesCreated = 0; //Start with some problem State curState = new State(matrix, 0, new Edge(-1, -1)); totalStatesCreated++; //Reduce Matrix //O(4n^2) curState.Reduce(); //Let the queue be the set of active subproblems //O(log(n)) queue.Add(curState); maxQueueCount = 0; bool timesUp = false; while (queue.Count > 0) {//O(2^n) or O(2^(8n^2 + 9n + 2log(n))) if (timer.Elapsed.Seconds >= 30) { timesUp = true; break; } //Choose a subproblem and remove it from the queue if (queue.Count > maxQueueCount) { maxQueueCount = queue.Count; } //O(log(n)) curState = queue.DeleteMin(); if (curState.Cost() < bestSolutionSoFar) {//O(8n^2 + 9n + 2log(n)) //For each lowest cost (each 0) double highestScore = double.NegativeInfinity; State[] includeExcludeStates = new State[2]; foreach (Edge edge in curState.LowestNums()) {//O(8n^2 + 9n) //Include Matrix State includeState = new State(curState, edge); //O(n) totalStatesCreated++; includeState.IncludeMatrix(edge.Row(), edge.Col()); //O(4n^2 + 7n) //Exclude Matrix State excludeState = new State(curState, edge); //O(n) totalStatesCreated++; excludeState.ExcludeMatrix(edge.Row(), edge.Col());//O(4n^2) //Find the score for that edge (Exclude cost - Include cost) double score = excludeState.Cost() - includeState.Cost(); if (score > highestScore) { includeExcludeStates[0] = includeState; includeExcludeStates[1] = excludeState; highestScore = score; } } foreach (State subproblemState in includeExcludeStates) {//O(2log(n)) //if each P (subproblem) chosen is a complete solution, update the bssf if (subproblemState.CompleteSolution() && subproblemState.Cost() < bestSolutionSoFar) { bestSolutionSoFar = subproblemState.Cost(); bssfState = subproblemState; bssfUpdatesAmt++; } //else if lowerBound < bestSolutionSoFar else if (!subproblemState.CompleteSolution() && subproblemState.Cost() < bestSolutionSoFar) { //O(log(n)) queue.Add(subproblemState); } else { prunedAmt++; } } } } if (!timesUp) prunedAmt += queue.Count; //Call this the best solution so far. bssf is the route that will be drawn by the Draw method. if (bssfState != null) { int index = bssfState.Exited(0); Route.Add(Cities[index]); index = bssfState.Exited(bssfState.Exited(0)); while (index != bssfState.Exited(0)) {//O(n) Route.Add(Cities[index]); index = bssfState.Exited(index); } } else { Route = greedyRoute; } timer.Stop(); bAndBTime = timer.Elapsed; this.count = bssfState.Cost(); // update the cost of the tour. timer.Reset(); return Route; }
public ArrayList RunTSP(City[] Cities) { Route = new ArrayList(); Stopwatch timer = new Stopwatch(); bAndBTime = new TimeSpan(); timer.Start(); Greedy greedyAlgorithm = new Greedy(Cities); ArrayList greedyRoute = greedyAlgorithm.RunGreedyTSP(); double[,] matrix = new double[Cities.Length, Cities.Length]; //Populate each array item with each respective edge cost for (int i = 0; i < Cities.Length; i++) {//O(n^2) for (int j = 0; j < Cities.Length; j++) { if (i == j) { matrix[i, j] = double.PositiveInfinity; } else { matrix[i, j] = Cities[i].costToGetTo(Cities[j]); } } } IntervalHeap <State> queue = new IntervalHeap <State>(); double bestSolutionSoFar = greedyAlgorithm.BestSolutionSoFar(); bssfUpdatesAmt = 0; prunedAmt = 0; State bssfState = null; totalStatesCreated = 0; //Start with some problem State curState = new State(matrix, 0, new Edge(-1, -1)); totalStatesCreated++; //Reduce Matrix //O(4n^2) curState.Reduce(); //Let the queue be the set of active subproblems //O(log(n)) queue.Add(curState); maxQueueCount = 0; bool timesUp = false; while (queue.Count > 0) {//O(2^n) or O(2^(8n^2 + 9n + 2log(n))) if (timer.Elapsed.Seconds >= 30) { timesUp = true; break; } //Choose a subproblem and remove it from the queue if (queue.Count > maxQueueCount) { maxQueueCount = queue.Count; } //O(log(n)) curState = queue.DeleteMin(); if (curState.Cost() < bestSolutionSoFar) {//O(8n^2 + 9n + 2log(n)) //For each lowest cost (each 0) double highestScore = double.NegativeInfinity; State[] includeExcludeStates = new State[2]; foreach (Edge edge in curState.LowestNums()) { //O(8n^2 + 9n) //Include Matrix State includeState = new State(curState, edge); //O(n) totalStatesCreated++; includeState.IncludeMatrix(edge.Row(), edge.Col()); //O(4n^2 + 7n) //Exclude Matrix State excludeState = new State(curState, edge); //O(n) totalStatesCreated++; excludeState.ExcludeMatrix(edge.Row(), edge.Col()); //O(4n^2) //Find the score for that edge (Exclude cost - Include cost) double score = excludeState.Cost() - includeState.Cost(); if (score > highestScore) { includeExcludeStates[0] = includeState; includeExcludeStates[1] = excludeState; highestScore = score; } } foreach (State subproblemState in includeExcludeStates) {//O(2log(n)) //if each P (subproblem) chosen is a complete solution, update the bssf if (subproblemState.CompleteSolution() && subproblemState.Cost() < bestSolutionSoFar) { bestSolutionSoFar = subproblemState.Cost(); bssfState = subproblemState; bssfUpdatesAmt++; } //else if lowerBound < bestSolutionSoFar else if (!subproblemState.CompleteSolution() && subproblemState.Cost() < bestSolutionSoFar) { //O(log(n)) queue.Add(subproblemState); } else { prunedAmt++; } } } } if (!timesUp) { prunedAmt += queue.Count; } //Call this the best solution so far. bssf is the route that will be drawn by the Draw method. if (bssfState != null) { int index = bssfState.Exited(0); Route.Add(Cities[index]); index = bssfState.Exited(bssfState.Exited(0)); while (index != bssfState.Exited(0)) {//O(n) Route.Add(Cities[index]); index = bssfState.Exited(index); } } else { Route = greedyRoute; } timer.Stop(); bAndBTime = timer.Elapsed; this.count = bssfState.Cost(); // update the cost of the tour. timer.Reset(); return(Route); }