/*This is a C++ Program to find longest path in DAG. Given a Weighted Directed Acyclic Graph (DAG) and a source vertex s in it, find the longest distances from s to all other vertices in the given graph. Following is complete algorithm for finding longest distances. 1) Initialize dist[] = {NINF, NINF, ….} and dist[s] = 0 where s is the source vertex. Here NINF means negative infinite. 2) Create a toplogical order of all vertices. 3) Do following for every vertex u in topological order. ………..Do following for every adjacent vertex v of u ………………if (dist[v] < dist[u] + weight(u, v)) ………………………dist[v] = dist[u] + weight(u, v) */ // A C++ program to find single source longest distances in a DAG #include #include #include #include #define NINF INT_MIN using namespace std; // Graph is represented using adjacency list. Every node of adjacency list // contains vertex number of the vertex to which edge connects. It also // contains weight of the edge class AdjListNode { int v; int weight; public: AdjListNode(int _v, int _w) { v = _v; weight = _w; } int getV() { return v; } int getWeight() { return weight; } }; // Class to represent a graph using adjacency list representation class Graph { int V; // No. of vertices’ // Pointer to an array containing adjacency lists list *adj; // A function used by longestPath void topologicalSortUtil(int v, bool visited[], stack &Stack); public: Graph(int V); // Constructor // function to add an edge to graph void addEdge(int u, int v, int weight); // Finds longest distances from given source vertex void longestPath(int s); }; Graph::Graph(int V) // Constructor { this->V = V; adj = new list [V]; } void Graph::addEdge(int u, int v, int weight) { AdjListNode node(v, weight); adj[u].push_back(node); // Add v to u’s list } // A recursive function used by longestPath. See below link for details // http://www.geeksforgeeks.org/topological-sorting/ void Graph::topologicalSortUtil(int v, bool visited[], stack &Stack) { // Mark the current node as visited visited[v] = true; // Recur for all the vertices adjacent to this vertex list::iterator i; for (i = adj[v].begin(); i != adj[v].end(); ++i) { AdjListNode node = *i; if (!visited[node.getV()]) topologicalSortUtil(node.getV(), visited, Stack); } // Push current vertex to stack which stores topological sort Stack.push(v); } // The function to find longest distances from a given vertex. It uses // recursive topologicalSortUtil() to get topological sorting. void Graph::longestPath(int s) { stack Stack; int dist[V]; // Mark all the vertices as not visited bool *visited = new bool[V]; for (int i = 0; i < V; i++) visited[i] = false; // Call the recursive helper function to store Topological Sort // starting from all vertices one by one for (int i = 0; i < V; i++) if (visited[i] == false) topologicalSortUtil(i, visited, Stack); // Initialize distances to all vertices as infinite and distance // to source as 0 for (int i = 0; i < V; i++) dist[i] = NINF; dist[s] = 0; // Process vertices in topological order while (Stack.empty() == false) { // Get the next vertex from topological order int u = Stack.top(); Stack.pop(); // Update distances of all adjacent vertices list::iterator i; if (dist[u] != NINF) { for (i = adj[u].begin(); i != adj[u].end(); ++i) if (dist[i->getV()] < dist[u] + i->getWeight()) dist[i->getV()] = dist[u] + i->getWeight(); } } // Print the calculated longest distances for (int i = 0; i < V; i++) (dist[i] == NINF) ? cout << "INF " : cout << dist[i] << " "; } // Driver program to test above functions int main() { // Create a graph given in the above diagram. Here vertex numbers are // 0, 1, 2, 3, 4, 5 with following mappings: // 0=r, 1=s, 2=t, 3=x, 4=y, 5=z Graph g(6); g.addEdge(0, 1, 5); g.addEdge(0, 2, 3); g.addEdge(1, 3, 6); g.addEdge(1, 2, 2); g.addEdge(2, 4, 4); g.addEdge(2, 5, 2); g.addEdge(2, 3, 7); g.addEdge(3, 5, 1); g.addEdge(3, 4, -1); g.addEdge(4, 5, -2); int s = 1; cout << "Following are longest distances from source vertex " << s << " \n"; g.longestPath(s); return 0; } /* Following are longest distances from source vertex 1 INF 0 2 9 8 10