Qin Shi Huang's National Road System
Time Limit: 2000/1000 MS (Java/Others) Memory Limit: 32768/32768 K (Java/Others)
Total Submission(s): 4139 Accepted Submission(s): 1440
Problem Description
During
the Warring States Period of ancient China(476 BC to 221 BC), there
were seven kingdoms in China ---- they were Qi, Chu, Yan, Han, Zhao, Wei
and Qin. Ying Zheng was the king of the kingdom Qin. Through 9 years of
wars, he finally conquered all six other kingdoms and became the first
emperor of a unified China in 221 BC. That was Qin dynasty ---- the
first imperial dynasty of China(not to be confused with the Qing
Dynasty, the last dynasty of China). So Ying Zheng named himself "Qin
Shi Huang" because "Shi Huang" means "the first emperor" in Chinese.
Qin Shi Huang undertook gigantic projects, including the first version of the Great Wall of China, the now famous city-sized mausoleum guarded by a life-sized Terracotta Army, and a massive national road system. There is a story about the road system:
There were n cities in China and Qin Shi Huang wanted them all be connected by n-1 roads, in order that he could go to every city from the capital city Xianyang.
Although Qin Shi Huang was a tyrant, he wanted the total length of all roads to be minimum,so that the road system may not cost too many people's life. A daoshi (some kind of monk) named Xu Fu told Qin Shi Huang that he could build a road by magic and that magic road would cost no money and no labor. But Xu Fu could only build ONE magic road for Qin Shi Huang. So Qin Shi Huang had to decide where to build the magic road. Qin Shi Huang wanted the total length of all none magic roads to be as small as possible, but Xu Fu wanted the magic road to benefit as many people as possible ---- So Qin Shi Huang decided that the value of A/B (the ratio of A to B) must be the maximum, which A is the total population of the two cites connected by the magic road, and B is the total length of none magic roads.
Would you help Qin Shi Huang?
A city can be considered as a point, and a road can be considered as a line segment connecting two points.
Qin Shi Huang undertook gigantic projects, including the first version of the Great Wall of China, the now famous city-sized mausoleum guarded by a life-sized Terracotta Army, and a massive national road system. There is a story about the road system:
There were n cities in China and Qin Shi Huang wanted them all be connected by n-1 roads, in order that he could go to every city from the capital city Xianyang.
Although Qin Shi Huang was a tyrant, he wanted the total length of all roads to be minimum,so that the road system may not cost too many people's life. A daoshi (some kind of monk) named Xu Fu told Qin Shi Huang that he could build a road by magic and that magic road would cost no money and no labor. But Xu Fu could only build ONE magic road for Qin Shi Huang. So Qin Shi Huang had to decide where to build the magic road. Qin Shi Huang wanted the total length of all none magic roads to be as small as possible, but Xu Fu wanted the magic road to benefit as many people as possible ---- So Qin Shi Huang decided that the value of A/B (the ratio of A to B) must be the maximum, which A is the total population of the two cites connected by the magic road, and B is the total length of none magic roads.
Would you help Qin Shi Huang?
A city can be considered as a point, and a road can be considered as a line segment connecting two points.
Input
The first line contains an integer t meaning that there are t test cases(t <= 10).
For each test case:
The first line is an integer n meaning that there are n cities(2 < n <= 1000).
Then n lines follow. Each line contains three integers X, Y and P ( 0 <= X, Y <= 1000, 0 < P < 100000). (X, Y) is the coordinate of a city and P is the population of that city.
It is guaranteed that each city has a distinct location.
For each test case:
The first line is an integer n meaning that there are n cities(2 < n <= 1000).
Then n lines follow. Each line contains three integers X, Y and P ( 0 <= X, Y <= 1000, 0 < P < 100000). (X, Y) is the coordinate of a city and P is the population of that city.
It is guaranteed that each city has a distinct location.
Output
For
each test case, print a line indicating the above mentioned maximum
ratio A/B. The result should be rounded to 2 digits after decimal point.
Sample Input
2
4
1 1 20
1 2 30
200 2 80
200 1 100
3
1 1 20
1 2 30
2 2 40
Sample Output
65.00
70.00
求完最小生成树之后 , 记录树上的n-1条边。
然后删去最小生成树上的边。
再dfs出两棵分割开来的子树中的population最大的两个点,把它们连起来作为免费边再取答案。
#include <iostream> #include <algorithm> #include <cstdio> #include <cmath> #include <cstring> #include <vector> using namespace std ; typedef long long LL ; const int N = 1010; const int M = 1000010; struct edge { int u , v , p ; double w ; bool operator < ( const edge &a ) const { if( w != a.w )return w < a.w ; else return p > a.p ; } }e[M]; int n , m , fa[N] ; bool vis[M] ; double x[N] , y[N] ; int p[N] , tot ; int find( int k ) { return k == fa[k] ? k : find(fa[k]); } double mst() { double ans = 0 ; sort( e , e + tot ); memset( vis , false , sizeof vis ) ; for( int i = 0 ; i <= n ; ++i ) fa[i] = i ; for( int i = 0 ; i < tot ; ++i ) { int fu = find( e[i].u ) , fv = find( e[i].v ); if( fu == fv ) continue ; fa[fv] = fu; ans += e[i].w ; vis[i] = true ; } return ans ; } vector<int>g[N]; int dfs( int u , int fa ) { int ans = p[u] ; for( int i = 0 ; i < g[u].size() ; ++i ) { int v = g[u][i] ; if( v == fa ) continue ; ans = max( ans , dfs( v , u ) ); } return ans ; } void Work() { double cost = mst() , ans = 0; for( int i = 0 ; i <= n ; ++i ) g[i].clear(); for( int i = 0 ; i < tot ; ++i ) if( vis[i] ){ g[e[i].u].push_back(e[i].v); g[e[i].v].push_back(e[i].u); } for( int i = 0 ; i < tot ; ++i ) if( vis[i] ) { int a = dfs( e[i].u , e[i].v ) , b = dfs( e[i].v , e[i].u ) ; ans = max( ans , ( 1.0*(a+b)/(cost-e[i].w) ) ); } printf("%.2lf ",ans); } int main () { //freopen("in.txt","r",stdin); int _ ; scanf("%d",&_); while( _-- ) { scanf("%d",&n); for( int i = 0 ; i < n ; ++i ) { scanf("%lf%lf%d",&x[i],&y[i],&p[i]); } tot = 0 ; for( int i = 0 ; i < n ; ++i ) { for( int j = i + 1 ; j < n ; ++j ) { e[tot].u = i , e[tot].v = j ; e[tot].p = p[i] + p[j] ; e[tot].w = sqrt((x[i]-x[j])*(x[i]-x[j])+(y[i]-y[j])*(y[i]-y[j])); tot++; } } Work(); } }