| 试题编号: | 201509-4 |
| 试题名称: | 高速公路 |
| 时间限制: | 1.0s |
| 内存限制: | 256.0MB |
| 问题描述: |
问题描述
某国有n个城市,为了使得城市间的交通更便利,该国国王打算在城市之间修一些高速公路,由于经费限制,国王打算第一阶段先在部分城市之间修一些单向的高速公路。
现在,大臣们帮国王拟了一个修高速公路的计划。看了计划后,国王发现,有些城市之间可以通过高速公路直接(不经过其他城市)或间接(经过一个或多个其他城市)到达,而有的却不能。如果城市A可以通过高速公路到达城市B,而且城市B也可以通过高速公路到达城市A,则这两个城市被称为便利城市对。 国王想知道,在大臣们给他的计划中,有多少个便利城市对。 输入格式
输入的第一行包含两个整数n, m,分别表示城市和单向高速公路的数量。
接下来m行,每行两个整数a, b,表示城市a有一条单向的高速公路连向城市b。 输出格式
输出一行,包含一个整数,表示便利城市对的数量。
样例输入
5 5
1 2 2 3 3 4 4 2 3 5 样例输出
3
样例说明
 城市间的连接如图所示。有3个便利城市对,它们分别是(2, 3), (2, 4), (3, 4),请注意(2, 3)和(3, 2)看成同一个便利城市对。 评测用例规模与约定
前30%的评测用例满足1 ≤ n ≤ 100, 1 ≤ m ≤ 1000;
前60%的评测用例满足1 ≤ n ≤ 1000, 1 ≤ m ≤ 10000; 所有评测用例满足1 ≤ n ≤ 10000, 1 ≤ m ≤ 100000。 |
问题链接:CCF201509试题。
问题描述:(参见上文)。
问题分析:这是一个强联通图的问题,用Tarjan算法来解决。另外一个算法是kosaraju算法,也用于解决强联通图问题。
程序说明:本程序采用Tarjan算法。主函数main()中,创建图对象是参数本应该用n,但是提交后出现了运行错误,所有改成n+1。程序通过使用Tarjan算法类(参见以下链接)来实现,做了简单修改,使用变量ans来存储结果,其中增加了中间变量count。
求得强联通子图后,对于每一个强联通子图如果有k个结点,若k>1则强联通对结点的数量为k*(k-1)/2,若k=1则为0。
相关链接:Tarjan算法查找强联通组件。
提交后得100分的C++语言程序如下:
/* CCF201509-4 高速公路 */
#include <iostream>
#include <list>
#include <stack>
using namespace std;
const int NIL = -1;
int ans = 0;
// A class that represents an directed graph
class Graph
{
int V; // No. of vertices
list<int> *adj; // A dynamic array of adjacency lists
// A Recursive DFS based function used by SCC()
void SCCUtil(int u, int disc[], int low[],
stack<int> *st, bool stackMember[]);
public:
Graph(int V); // Constructor
void addEdge(int v, int w); // function to add an edge to graph
void SCC(); // prints strongly connected components
};
Graph::Graph(int V)
{
this->V = V;
adj = new list<int>[V];
}
void Graph::addEdge(int v, int w)
{
adj[v].push_back(w);
}
// A recursive function that finds and prints strongly connected
// components using DFS traversal
// u --> The vertex to be visited next
// disc[] --> Stores discovery times of visited vertices
// low[] -- >> earliest visited vertex (the vertex with minimum
// discovery time) that can be reached from subtree
// rooted with current vertex
// *st -- >> To store all the connected ancestors (could be part
// of SCC)
// stackMember[] --> bit/index array for faster check whether
// a node is in stack
void Graph::SCCUtil(int u, int disc[], int low[], stack<int> *st,
bool stackMember[])
{
// A static variable is used for simplicity, we can avoid use
// of static variable by passing a pointer.
static int time = 0;
// Initialize discovery time and low value
disc[u] = low[u] = ++time;
st->push(u);
stackMember[u] = true;
// Go through all vertices adjacent to this
list<int>::iterator i;
for (i = adj[u].begin(); i != adj[u].end(); ++i)
{
int v = *i; // v is current adjacent of 'u'
// If v is not visited yet, then recur for it
if (disc[v] == -1)
{
SCCUtil(v, disc, low, st, stackMember);
// Check if the subtree rooted with 'v' has a
// connection to one of the ancestors of 'u'
// Case 1 (per above discussion on Disc and Low value)
low[u] = min(low[u], low[v]);
}
// Update low value of 'u' only of 'v' is still in stack
// (i.e. it's a back edge, not cross edge).
// Case 2 (per above discussion on Disc and Low value)
else if (stackMember[v] == true)
low[u] = min(low[u], disc[v]);
}
// head node found, pop the stack and print an SCC
int w = 0; // To store stack extracted vertices
int count = 0;
if (low[u] == disc[u])
{
while (st->top() != u)
{
w = (int) st->top();
// cout << w << " ";
count++;
stackMember[w] = false;
st->pop();
}
w = (int) st->top();
// cout << w << "
";
count++;
stackMember[w] = false;
st->pop();
}
if(count > 1)
ans += count * (count -1) / 2;
}
// The function to do DFS traversal. It uses SCCUtil()
void Graph::SCC()
{
int *disc = new int[V];
int *low = new int[V];
bool *stackMember = new bool[V];
stack<int> *st = new stack<int>();
// Initialize disc and low, and stackMember arrays
for (int i = 0; i < V; i++)
{
disc[i] = NIL;
low[i] = NIL;
stackMember[i] = false;
}
// Call the recursive helper function to find strongly
// connected components in DFS tree with vertex 'i'
for (int i = 0; i < V; i++)
if (disc[i] == NIL)
SCCUtil(i, disc, low, st, stackMember);
}
int main()
{
int n, m, src, dest;
cin >> n >> m;
Graph g(n+1);
for(int i=1; i<=m; i++) {
cin >> src >> dest;
g.addEdge(src, dest);
}
g.SCC();
cout << ans << endl;
return 0;
}