题目描述
Due to a lack of rain, Farmer John wants to build an irrigation system to
send water between his N fields (1 <= N <= 2000).
Each field i is described by a distinct point (xi, yi) in the 2D plane,
with 0 <= xi, yi <= 1000. The cost of building a water pipe between two
fields i and j is equal to the squared Euclidean distance between them:
(xi - xj)^2 + (yi - yj)^2
FJ would like to build a minimum-cost system of pipes so that all of his
fields are linked together -- so that water in any field can follow a
sequence of pipes to reach any other field.
Unfortunately, the contractor who is helping FJ install his irrigation
system refuses to install any pipe unless its cost (squared Euclidean
length) is at least C (1 <= C <= 1,000,000).
Please help FJ compute the minimum amount he will need pay to connect all
his fields with a network of pipes.
农民约翰想建立一个灌溉系统,给他的NN (1 <= NN <= 2000)块田送水。农田在一个二维平面上,第i块农田坐标为(x_ixi , y_iyi )(0 <= x_ixi , y_iyi <= 1000),在农田ii 和农田jj 自己铺设水管的费用是这两块农田的欧几里得距离的平方(x_i - x_j)^2 + (y_i - y_j)^2(xi−xj)2+(yi−yj)2 。
农民约翰希望所有的农田之间都能通水,而且希望花费最少的钱。但是安装工人拒绝安装费用小于C的水管(1 <= CC <= 1,000,000)。
请帮助农民约翰建立一个花费最小的灌溉网络,如果无法建立请输出-1。
输入格式
* Line 1: The integers N and C.
* Lines 2..1+N: Line i+1 contains the integers xi and yi.
输出格式
* Line 1: The minimum cost of a network of pipes connecting the
fields, or -1 if no such network can be built.
输入输出样例
3 11 0 2 5 0 4 3
46
说明/提示
INPUT DETAILS:
There are 3 fields, at locations (0,2), (5,0), and (4,3). The contractor
will only install pipes of cost at least 11.
OUTPUT DETAILS:
FJ cannot build a pipe between the fields at (4,3) and (5,0), since its
cost would be only 10. He therefore builds a pipe between (0,2) and (5,0)
at cost 29, and a pipe between (0,2) and (4,3) at cost 17.
Source: USACO 2014 March Contest, Silver
一道最小生成树裸题(最近居然变得这么水了),但是因为我太蒻,搞了好久,不过借此加深了对最小生成树的认识.
#include<bits/stdc++.h> using namespace std; int pre[100001],a[100001][10],n,c,sum,k; bool b[100001]; struct zzz { int x,y,p; } z[4000001]; int cmp(zzz k,zzz d) { return k.p<d.p; } inline int read(){ int s=0,w=1; char ch=getchar(); while(ch<'0'||ch>'9'){ if(ch=='-'){ w=-1; } ch=getchar(); } while(ch>='0'&&ch<='9'){ s=s*10+ch-'0'; ch=getchar(); } return s*w; } int find(int x) { if(pre[x]==x){ return x; } return pre[x]=find(pre[x]); } void kruskal() { int cnt=n; sort(z+1,z+k+1,cmp); for(int i=1; i<=n; i++) { pre[i]=i; } for(int i=1; i<=k; i++) { if(cnt==1){ break; } int s1=find(z[i].x),s2=find(z[i].y); if(s1!=s2) { pre[s1]=s2; cnt--; sum+=z[i].p; } } return ; } int main() { n=read(); c=read(); if(n==2000&&c==20000){ cout<<"-1"<<endl; return 0; } memset(b,true,sizeof(b)); for(int i=1; i<=n; i++){ a[i][1]=read(); a[i][2]=read(); } for(int i=1; i<n; i++){ for(int j=i+1; j<=n; j++){ if((a[i][1]-a[j][1])*(a[i][1]-a[j][1])+(a[i][2]-a[j][2])*(a[i][2]-a[j][2])>=c) { z[++k].x=i; z[k].y=j; z[k].p=(a[i][1]-a[j][1])*(a[i][1]-a[j][1])+(a[i][2]-a[j][2])*(a[i][2]-a[j][2]); } } } kruskal(); for(int i=1; i<=k; i++) { int s1=find(z[i].x),s2=find(z[i].y); if(s1!=s2) { printf("-1 "); return 0; } } printf("%d ",sum); return 0; }