HDU4185(KB10-G 二分图最大匹配)
Oil Skimming
Time Limit: 2000/1000 MS (Java/Others) Memory Limit: 32768/32768 K (Java/Others)
Total Submission(s): 2917 Accepted Submission(s): 1210
Problem Description
Thanks to a certain "green" resources company, there is a new profitable industry of oil skimming. There are large slicks of crude oil floating in the Gulf of Mexico just waiting to be scooped up by enterprising oil barons. One such oil baron has a special plane that can skim the surface of the water collecting oil on the water's surface. However, each scoop covers a 10m by 20m rectangle (going either east/west or north/south). It also requires that the rectangle be completely covered in oil, otherwise the product is contaminated by pure ocean water and thus unprofitable! Given a map of an oil slick, the oil baron would like you to compute the maximum number of scoops that may be extracted. The map is an NxN grid where each cell represents a 10m square of water, and each cell is marked as either being covered in oil or pure water.
Input
The input starts with an integer K (1 <= K <= 100) indicating the number of cases. Each case starts with an integer N (1 <= N <= 600) indicating the size of the square grid. Each of the following N lines contains N characters that represent the cells of a row in the grid. A character of '#' represents an oily cell, and a character of '.' represents a pure water cell.
Output
For each case, one line should be produced, formatted exactly as follows: "Case X: M" where X is the case number (starting from 1) and M is the maximum number of scoops of oil that may be extracted.
Sample Input
1
6
......
.##...
.##...
....#.
....##
......
Sample Output
Case 1: 3
Source
每个‘#’向其左边和上边的‘#’连边,然后跑最大匹配
//2017-08-26 #include <cstdio> #include <cstring> #include <iostream> #include <algorithm> using namespace std; const int N = 100000; const int M = 5000000; int head[N], tot; struct Edge{ int to, next; }edge[M]; void init(){ tot = 0; memset(head, -1, sizeof(head)); } void add_edge(int u, int v){ edge[tot].to = v; edge[tot].next = head[u]; head[u] = tot++; edge[tot].to = u; edge[tot].next = head[v]; head[v] = tot++; } int n; int matching[N]; int check[N]; string G[700]; int id[700][700], idcnt; bool dfs(int u){ for(int i = head[u]; i != -1; i = edge[i].next){ int v = edge[i].to; if(!check[v]){//要求不在交替路 check[v] = 1;//放入交替路 if(matching[v] == -1 || dfs(matching[v])){ //如果是未匹配点,说明交替路为增广路,则交换路径,并返回成功 matching[u] = v; matching[v] = u; return true; } } } return false;//不存在增广路 } //hungarian: 二分图最大匹配匈牙利算法 //input: null //output: ans 最大匹配数 int hungarian(){ int ans = 0; memset(matching, -1, sizeof(matching)); for(int u = 1; u < idcnt; u++){ if(matching[u] == -1){ memset(check, 0, sizeof(check)); if(dfs(u)) ans++; } } return ans; } int main() { std::ios::sync_with_stdio(false); //freopen("inputG.txt", "r", stdin); int T, kase = 0; cin>>T; while(T--){ cin>>n; init(); idcnt = 1; for(int i = 0; i < n; i++){ cin>>G[i]; for(int j = 0; j < n; j++){ if(G[i][j] == '#'){ id[i][j] = idcnt++; if(i-1>=0 && G[i-1][j] == '#') add_edge(id[i][j], id[i-1][j]); if(j-1>=0 && G[i][j-1] == '#') add_edge(id[i][j], id[i][j-1]); } } } cout<<"Case "<<++kase<<": "<<hungarian()<<endl; } return 0; }