POJ1251 Jungle Roads(Kruskal)(并查集)
2024-08-28 00:49:01
Jungle Roads
| Time Limit: 1000MS | Memory Limit: 10000K | |
| Total Submissions: 23882 | Accepted: 11193 |
Description
The Head Elder of the tropical island of Lagrishan has a problem. A
burst of foreign aid money was spent on extra roads between villages
some years ago. But the jungle overtakes roads relentlessly, so the
large road network is too expensive to maintain. The Council of Elders
must choose to stop maintaining some roads. The map above on the left
shows all the roads in use now and the cost in aacms per month to
maintain them. Of course there needs to be some way to get between all
the villages on maintained roads, even if the route is not as short as
before. The Chief Elder would like to tell the Council of Elders what
would be the smallest amount they could spend in aacms per month to
maintain roads that would connect all the villages. The villages are
labeled A through I in the maps above. The map on the right shows the
roads that could be maintained most cheaply, for 216 aacms per month.
Your task is to write a program that will solve such problems.
Input
The
input consists of one to 100 data sets, followed by a final line
containing only 0. Each data set starts with a line containing only a
number n, which is the number of villages, 1 < n < 27, and the
villages are labeled with the first n letters of the alphabet,
capitalized. Each data set is completed with n-1 lines that start with
village labels in alphabetical order. There is no line for the last
village. Each line for a village starts with the village label followed
by a number, k, of roads from this village to villages with labels later
in the alphabet. If k is greater than 0, the line continues with data
for each of the k roads. The data for each road is the village label for
the other end of the road followed by the monthly maintenance cost in
aacms for the road. Maintenance costs will be positive integers less
than 100. All data fields in the row are separated by single blanks. The
road network will always allow travel between all the villages. The
network will never have more than 75 roads. No village will have more
than 15 roads going to other villages (before or after in the alphabet).
In the sample input below, the first data set goes with the map above.
input consists of one to 100 data sets, followed by a final line
containing only 0. Each data set starts with a line containing only a
number n, which is the number of villages, 1 < n < 27, and the
villages are labeled with the first n letters of the alphabet,
capitalized. Each data set is completed with n-1 lines that start with
village labels in alphabetical order. There is no line for the last
village. Each line for a village starts with the village label followed
by a number, k, of roads from this village to villages with labels later
in the alphabet. If k is greater than 0, the line continues with data
for each of the k roads. The data for each road is the village label for
the other end of the road followed by the monthly maintenance cost in
aacms for the road. Maintenance costs will be positive integers less
than 100. All data fields in the row are separated by single blanks. The
road network will always allow travel between all the villages. The
network will never have more than 75 roads. No village will have more
than 15 roads going to other villages (before or after in the alphabet).
In the sample input below, the first data set goes with the map above.
Output
The
output is one integer per line for each data set: the minimum cost in
aacms per month to maintain a road system that connect all the villages.
Caution: A brute force solution that examines every possible set of
roads will not finish within the one minute time limit.
output is one integer per line for each data set: the minimum cost in
aacms per month to maintain a road system that connect all the villages.
Caution: A brute force solution that examines every possible set of
roads will not finish within the one minute time limit.
Sample Input
9
A 2 B 12 I 25
B 3 C 10 H 40 I 8
C 2 D 18 G 55
D 1 E 44
E 2 F 60 G 38
F 0
G 1 H 35
H 1 I 35
3
A 2 B 10 C 40
B 1 C 20
0
Sample Output
216
30
【分析】话不多说,又是最小生成树,直接套模板。
#include <iostream>
#include <cstdio>
#include <cstdlib>
#include <cmath>
#include <algorithm>
#include <climits>
#include <cstring>
#include <string>
#include <set>
#include <map>
#include <queue>
#include <stack>
#include <vector>
#include <list>
#include<functional>
#define mod 1000000007
#define inf 0x3f3f3f3f
#define pi acos(-1.0)
using namespace std;
typedef long long ll;
const int N=;
const int M=; struct Edg {
int v,u;
int w;
} edg[M];
bool cmp(Edg g,Edg h) {
return g.w<h.w;
}
int n,m,maxn,cnt;
int parent[N];
void init() {
for(int i=; i<n; i++)parent[i]=i;
}
void Build() {
int w,k;
char u,v;
for(int i=; i<n-; i++) {
cin>>u>>k;
while(k--) {
cin>>v>>w;
edg[++cnt].u=u-'A';
edg[cnt].v=v-'A';
edg[cnt].w=w;
}
}
sort(edg,edg+cnt+,cmp);
}
int Find(int x) {
if(parent[x] != x) parent[x] = Find(parent[x]);
return parent[x];
}//查找并返回节点x所属集合的根节点
void Union(int x,int y) {
x = Find(x);
y = Find(y);
if(x == y) return;
parent[y] = x;
}//将两个不同集合的元素进行合并
void Kruskal() {
int sum=;
int num=;
int u,v;
for(int i=; i<=cnt; i++) {
u=edg[i].u;
v=edg[i].v;
if(Find(u)!=Find(v)) {
sum+=edg[i].w;
num++;
Union(u,v);
}
//printf("!!!%d %d\n",num,sum);
if(num>=n-) {
printf("%d\n",sum); break;
}
}
}
int main() {
while(~scanf("%d",&n)&&n) {
cnt=-;
init();
Build();
Kruskal();
}
return ;
}
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