Let’s represent his enemy’s transportation system as a simple
directed graph G with n nodes and m edges. Each node is a city and each
directed edge is a directed road. Each edge from node u to node v is
associated with two values D and B, D is the cost to destroy/remove such
edge, B is the cost to build an undirected edge between u and v.
His enemy can deliver supplies from city u to city v if and only if
there is a directed path from u to v. At first they can deliver supplies
from any city to any other cities. So the graph is a strongly-connected
graph.
He will choose a non-empty proper subset of cities,
let’s denote this set as S. Let’s denote the complement set of S as T.
He will command his soldiers to destroy all the edges (u, v) that u
belongs to set S and v belongs to set T.
To destroy an edge, he must pay the related cost D. The total cost he will pay is X. You can use this formula to calculate X:
After that, all the edges from S to T are destroyed. In order to
deliver huge number of supplies from S to T, his enemy will change all
the remained directed edges (u, v) that u belongs to set T and v belongs
to set S into undirected edges. (Surely, those edges exist because the
original graph is strongly-connected)
To change an edge, they
must remove the original directed edge at first, whose cost is D, then
they have to build a new undirected edge, whose cost is B. The total
cost they will pay is Y. You can use this formula to calculate Y:
At last, if Y>=X, Tom will achieve his goal. But Tom is so lazy
that he is unwilling to take a cup of time to choose a set S to make
Y>=X, he hope to choose set S randomly! So he asks you if there is a
set S, such that Y<X. If such set exists, he will feel unhappy,
because he must choose set S carefully, otherwise he will become very
happy.
The first line contains an integer T(T<=200), indicates the number of cases.
For each test case, the first line has two numbers n and m.
Next m lines describe each edge. Each line has four numbers u, v, D, B.
(2=<n<=200, 2=<m<=5000, 1=<u, v<=n, 0=<D, B<=100000)
The meaning of all characters are described above. It is guaranteed that the input graph is strongly-connected.
starting from 1.If such set doesn’t exist, print “happy”, else print
“unhappy”.
题意
给你N个点M条边强连通的有向简单图,D代表删掉这个边的花费,D+B代表重建为双向边的花费,让你选择一个集合S,其余的点在T集合,X为u在S集合v在T集合的所有边的D之和,Y为u在T集合v在S集合的所有边的D+B之和,求是否存在一个集合S,使得X>Y,若存在输出unhappy,否则输出happy
题解
无源汇上下界网络流,下界D,上界D+B,判断是否存在可行流
若存在,则说明对于任意集合S,流出的流量=流入的流量,X<=流出的流量<=Y
建图每条边建为*流(u,v,B)
对于每个点,设M为总流入-总流出
若M>0,则建(S,i,M)说明i需要多流出M
若M<0,则建(i,T,M)说明i需要多流入M
最后判断与S连的边是否全满流
代码
#include<bits/stdc++.h>
using namespace std; const int maxn=1e5+;
const int maxm=2e5+;
const int INF=0x3f3f3f3f; int TO[maxm],CAP[maxm],NEXT[maxm],tote;
int FIR[maxn],gap[maxn],cur[maxn],d[maxn],q[];
int n,m,S,T; void add(int u,int v,int cap)
{
TO[tote]=v;
CAP[tote]=cap;
NEXT[tote]=FIR[u];
FIR[u]=tote++; TO[tote]=u;
CAP[tote]=;
NEXT[tote]=FIR[v];
FIR[v]=tote++;
}
void bfs()
{
memset(gap,,sizeof gap);
memset(d,,sizeof d);
++gap[d[T]=];
for(int i=;i<=n;++i)cur[i]=FIR[i];
int head=,tail=;
q[]=T;
while(head<=tail)
{
int u=q[head++];
for(int v=FIR[u];v!=-;v=NEXT[v])
if(!d[TO[v]])
++gap[d[TO[v]]=d[u]+],q[++tail]=TO[v];
}
}
int dfs(int u,int fl)
{
if(u==T)return fl;
int flow=;
for(int &v=cur[u];v!=-;v=NEXT[v])
if(CAP[v]&&d[u]==d[TO[v]]+)
{
int Min=dfs(TO[v],min(fl,CAP[v]));
flow+=Min,fl-=Min,CAP[v]-=Min,CAP[v^]+=Min;
if(!fl)return flow;
}
if(!(--gap[d[u]]))d[S]=n+;
++gap[++d[u]],cur[u]=FIR[u];
return flow;
}
int ISAP()
{
bfs();
int ret=;
while(d[S]<=n)ret+=dfs(S,INF);
return ret;
}
void init()
{
tote=;
memset(FIR,-,sizeof FIR);
}
int in[maxn];
int main()
{
int t;
scanf("%d",&t);
for(int ca=;ca<=t;ca++)
{
init();
memset(in,,sizeof in);
scanf("%d%d",&n,&m);
for(int i=,u,v,d,b;i<m;i++)
{
scanf("%d%d%d%d",&u,&v,&d,&b);
add(u,v,b);
in[u]-=d;
in[v]+=d;
}
S=n+,T=S+,n+=;
int sum=;
for(int i=;i<=n;i++)
if(in[i]>)
{
add(S,i,in[i]);
sum+=in[i];
}
else if(in[i]<)
add(i,T,-in[i]);
printf("Case #%d: %s\n",ca,ISAP()==sum?"happy":"unhappy");
}
return ;
}