Brief description :
判断流网络的边集,在最小割中,是否有可能成为割边的?是否一定会成为割边?
Analyse :
Orz hf46中 MSK 神牛的题。。。
http://hi.baidu.com/matrush/blog/item/091adb03b4eedd0d728da54c.html
/*
Author : xiaodao
Problem : AHOI 2009 Mincut 最小割
Status : Accepted
Last Modify : GMT +8. Sept 14th 08:12.
Tags : 网络流,最小割,强连通分量
*/
#include <iostream>
#include <cstdio>
#include <cstring>
#include <vector>
#include <cmath>
using namespace std;
const int INF = 0x7fffffff;
const int N = 40100, M = 123001;
struct edge{
int v, c;
void insert(int, int);
};
struct node{
vector<int> adj;
int D, scc;
};
struct network_flow{
node V[N+1]; edge E[M+1];
int edge_count; int max_flow;
int n, m, s, t;
bool C[N+1]; int F[N+1] ,time;
int component;
void init();
void print();
void add_edge(int, int, int);
void bfs(); void dfs1(int); void dfs2(int);
void Dinitz();
void Kosaraju();
};
inline int _r(int x){
return x ^ 1;
}
void edge::insert(int a, int b){
v = a; c = b;
};
void network_flow::add_edge(int x, int y, int z){
V[x].adj.push_back(edge_count); E[edge_count++].insert(y, z);
}
void network_flow::bfs(){
int Q[N+1] = {s}, head = 0, tail = 1;
for (int i=1;i<=n;i++) V[i].D = -1;
V[s].D = 0;
int u;
while (head<tail){
u = Q[head];
for (size_t i=0;i<V[u].adj.size();i++){
edge &arc = E[V[u].adj[i]];
if (V[arc.v].D==-1 && arc.c>0){
Q[tail] = arc.v; V[arc.v].D = V[u].D + 1;
if (arc.v == t) return;
tail++;
}
}
head++;
}
}
void network_flow::Dinitz(){
max_flow = 0;
bfs();
while (V[t].D!=-1){
int stack[n+1], cur[n+1], top = 0;
memset(cur, 0, sizeof(cur));
stack[0] = M;
int u; size_t i;
while (top!=-1){
u = E[stack[top]].v;
if (u == t){
int delta = INF; int handle;
for (int i=1;i<=top;i++){
edge &arc = E[stack[i]];
if (arc.c < delta){
delta = arc.c;
handle = i;
}
}
max_flow += delta;
for (int i=1;i<=top;i++){
E[stack[i]].c -= delta;
E[_r(stack[i])].c += delta;
}
//for (int i=handle;i<=top;i++){
// cur[stack[i]] = 0;
//} // ?
top = handle-1;
continue;
}
for (i=cur[u];i<V[u].adj.size();i++){
edge &arc = E[V[u].adj[i]];
if (V[arc.v].D == V[u].D + 1 && arc.c>0) break;
}
if (i == V[u].adj.size()){
V[u].D = -1, top--;
}
else {
cur[u] = i + 1;
stack[++top] = V[u].adj[i];
}
}
bfs();
}
}
void network_flow::dfs1(int u){
C[u] = true;
for (int i=0;i<V[u].adj.size();i++){
edge &arc = E[V[u].adj[i]];
if (!C[arc.v] && arc.c!=0)
dfs1(arc.v);
}
F[time++] = u;
}
void network_flow::dfs2(int u){
C[u] = true; V[u].scc = component;
for (int i=0;i<V[u].adj.size();i++){
edge &rev_arc = E[_r(V[u].adj[i])];
edge &arc = E[V[u].adj[i]];
if (!C[arc.v] && rev_arc.c!=0)
dfs2(arc.v);
}
}
void network_flow::Kosaraju(){
memset(C, false , sizeof(C)); time = 0;
for (int i=1;i<=n;i++)
if (!C[i]) dfs1(i);
memset(C, false, sizeof(C));
component = 0;
for (int i=n-1;i>=0;i--)
if (!C[F[i]]) dfs2(F[i]), component++;
}
void network_flow::init(){
for (int i=1;i<=n;i++) V[i].adj.clear();
edge_count = 0; E[M].v = s;
int x, y, z;
for (int i=0;i<m;i++){
scanf("%d%d%d", &x, &y, &z);
add_edge(x, y, z);
add_edge(y, x, 0);
}
}
void network_flow::print(){
for (int i=0;i<m;i++)
if (E[2*i].c !=0 || V[E[2*i+1].v].scc == V[E[2*i].v].scc) printf("0 0\n");
else {
if (V[E[2*i+1].v].scc != V[s].scc || V[E[2*i].v].scc != V[t].scc) printf("1 0\n");
else printf("1 1\n");
}
}
network_flow G;
int main(){
//freopen("in.txt", "r", stdin);
while (scanf("%d%d%d%d", &G.n, &G.m, &G.s, &G.t)==4){
G.init(); G.Dinitz(); G.Kosaraju();
G.print();
}
}
— UPD —
https://gist.github.com/lychees/3a09545e29380bed4a00
