A Bug's Life
Time Limit: 10000MS | Memory Limit: 65536K | |
Total Submissions: 30130 | Accepted: 9869 |
Description
Background
Professor Hopper is researching the sexual behavior of a rare species of bugs. He assumes that they feature two different genders and that they only interact with bugs of the opposite gender. In his experiment, individual bugs and their interactions were easy to identify, because numbers were printed on their backs.
Problem
Given a list of bug interactions, decide whether the experiment supports his assumption of two genders with no homosexual bugs or if it contains some bug interactions that falsify it.
Professor Hopper is researching the sexual behavior of a rare species of bugs. He assumes that they feature two different genders and that they only interact with bugs of the opposite gender. In his experiment, individual bugs and their interactions were easy to identify, because numbers were printed on their backs.
Problem
Given a list of bug interactions, decide whether the experiment supports his assumption of two genders with no homosexual bugs or if it contains some bug interactions that falsify it.
Input
The first line of the input contains the number of scenarios. Each scenario starts with one line giving the number of bugs (at least one, and up to 2000) and the number of interactions (up to 1000000) separated by a single space. In the following lines, each interaction is given in the form of two distinct bug numbers separated by a single space. Bugs are numbered consecutively starting from one.
Output
The output for every scenario is a line containing "Scenario #i:", where i is the number of the scenario starting at 1, followed by one line saying either "No suspicious bugs found!" if the experiment is consistent with his assumption about the bugs' sexual behavior, or "Suspicious bugs found!" if Professor Hopper's assumption is definitely wrong.
Sample Input
2 3 3 1 2 2 3 1 3 4 2 1 2 3 4
Sample Output
Scenario #1: Suspicious bugs found! Scenario #2: No suspicious bugs found!
判断两只虫子是否同性。
1 #include <iostream> 2 #include <cstdio> 3 #include <string> 4 #include <queue> 5 #include <vector> 6 #include <map> 7 #include <algorithm> 8 #include <cstring> 9 #include <cctype> 10 #include <cstdlib> 11 #include <cmath> 12 #include <ctime> 13 using namespace std; 14 15 const int SIZE = 2005; 16 int FATHER[SIZE],MARK[SIZE],RANK[SIZE]; 17 18 void ini(int); 19 int get_father(int); 20 void unite(int,int); 21 bool same(int,int); 22 23 int main(void) 24 { 25 int t,n,m,x,y,count = 0; 26 bool flag; 27 28 scanf("%d",&t); 29 while(t --) 30 { 31 count ++; 32 scanf("%d%d",&n,&m); 33 ini(n); 34 flag = false; 35 while(m --) 36 { 37 scanf("%d%d",&x,&y); 38 if(flag) 39 continue; 40 if(same(x,y)) 41 flag = true; 42 if(!MARK[x] && !MARK[y]) 43 { 44 MARK[x] = y; 45 MARK[y] = x; 46 } 47 else if(!MARK[x]) 48 { 49 MARK[x] = y; 50 unite(x,MARK[y]); 51 } 52 else if(!MARK[y]) 53 { 54 MARK[y] = x; 55 unite(y,MARK[x]); 56 } 57 else 58 { 59 unite(x,MARK[y]); 60 unite(y,MARK[x]); 61 } 62 } 63 printf("Scenario #%d: ",count); 64 if(flag) 65 puts("Suspicious bugs found!"); 66 else 67 puts("No suspicious bugs found!"); 68 puts(""); 69 } 70 71 72 return 0; 73 } 74 75 void ini(int n) 76 { 77 for(int i = 1;i <= n;i ++) 78 { 79 MARK[i] = RANK[i] = 0; 80 FATHER[i] = i; 81 } 82 } 83 84 int get_father(int n) 85 { 86 if(n == FATHER[n]) 87 return n; 88 return FATHER[n] = get_father(FATHER[n]); 89 } 90 91 void unite(int x,int y) 92 { 93 x = get_father(x); 94 y = get_father(y); 95 96 if(x == y) 97 return ; 98 if(RANK[x] < RANK[y]) 99 FATHER[x] = y; 100 else 101 { 102 FATHER[y] = x; 103 if(RANK[x] == RANK[y]) 104 RANK[x] ++; 105 } 106 } 107 108 bool same(int x,int y) 109 { 110 return get_father(x) == get_father(y); 111 }