图的广度优先搜索基本思想和树的层次遍历差不错。与树的层次遍历不同的是,图中可能包含回路,我们遍历完一个节点,继续进行遍历,可能会回到已经遍历过的节点。为了避免遍历一个节点两次,需要开辟一个bool型的数组来标记该节点是否已经遍历过。
#include <iostream> #include <list> #include <queue> using namespace std; //This class represents a directed graph using adjacency list representation class Graph { private: int v;// Number of vertices list<int> *adj;//Pointer to an array containing adjacency lists public: Graph(int v);//Constructor void addEdge(int v, int w);//function to add an edge to graph void BFS(int s);//prints BFS tracersal from a given sources }; Graph::Graph(int v) { this->v = v; adj = new list<int>[v]; } void Graph::addEdge(int v, int w) { adj[v].push_back(w);//Add w to v's list } void Graph::BFS(int s) { //Mark all the vertices as not visited bool *visited = new bool[v]; for(int i = 0; i < v; i++) { visited[i] = false; } //Create a queue for BFS list<int> queue; //Mark the current node as visited and enqueue it visited[s] = true; queue.push_back(s); //i will be used to get all adjacent vertices fo a vertex list<int>::iterator i; while( !queue.empty() ) { //Dequeue a vertex from queue and print it s = queue.front(); cout << s << " "; queue.pop_front(); //Get all adjacent vertices of the dequeued vertex s //If a adjacent has not been visited, then mark it visited //and enqueue it for( i = adj[s].begin(); i != adj[s].end(); i++) { if( !visited[*i] ) { visited[*i] = true; queue.push_back(*i); } } } cout << endl; } //Driver program to test methonds of graph class int main(int argc, char* argv[]) { //Create a graph given in the above diagram Graph g(4); g.addEdge( 0, 1); g.addEdge( 0, 2); g.addEdge( 1, 2); g.addEdge( 2, 0); g.addEdge( 2, 3); g.addEdge( 3, 3); cout <<"Followint is Breadth First Travesal( starting from vertex 2 ) "; g.BFS(2); return 0; }
输出结果:
Following is Breadth First Traversal ( starting from vertex 2)
2 0 3 1