OJ-Problems-Source/.ACM-Templates/Graph/图论-网络流.cpp

//最大流
//SAP + 邻接矩阵 O(V^2*E) 点的编号默认从0开始
typedef long long ftype;
int n, dis[N], pre[N], cur[N], gap[N];
ftype cap[N][N];
ftype SAP(int src, int sink, int n) {
  memset(dis, 0, sizeof(dis));
  memset(cur, 0, sizeof(cur));
  memset(gap, 0, sizeof(gap));
  int u = src; ftype mxflow = 0, aug = -1; pre[src] = src; gap[0] = n;
  while (dis[src] < n) {
loop:
    for (int v = cur[u]; v < n; ++v) {
      if (cap[u][v] > 0 && dis[u] == dis[v] + 1) {
        if (aug == -1 || aug > cap[u][v]) { aug = cap[u][v]; }
        pre[v] = u; u = cur[u] = v;
        if (v == sink) {
          for (u = pre[u]; v != src; v = u, u = pre[u]) {
            cap[u][v] -= aug; cap[v][u] += aug;
          }
          mxflow += aug; aug = -1;
        }
        goto loop;
      }
    }
    int mndis = n - 1;
    for (int v = 0; v < n; v++) {
      if (cap[u][v] > 0 && mndis > dis[v]) { cur[u] = v; mndis = dis[v]; }
    }
    if (--gap[dis[u]] == 0) { break; }
    dis[u] = mndis + 1; gap[dis[u]]++; u = pre[u];
  }
  return mxflow;
}
//ISAP + 邻接表 O(V^2*E)
typedef long long ftype;
const ftype INF = 0x3f3f3f3f;
int head[N], to[M], nxt[M], tot, dis[N], pre[N], cur[N], gap[N];
ftype cap[M];
inline void init() { tot = 0; memset(head, -1, sizeof(head)); }
inline void addedge(int x, int y, ftype w, ftype rw = 0) {
  to[tot] = y; cap[tot] = w; nxt[tot] = head[x]; head[x] = tot++;
  to[tot] = x; cap[tot] = rw; nxt[tot] = head[y]; head[y] = tot++;
}
ftype ISAP(int src, int sink, int n) {
  memset(dis, 0, sizeof(dis));
  memset(gap, 0, sizeof(gap));
  memcpy(cur, head, sizeof(head));
  int u = src, v; ftype mxflow = 0; pre[u] = -1; gap[0] = n;
  while (dis[src] < n) {
    if (u == sink) {
      ftype mndis = INF;
      for (int i = pre[u]; ~i; i = pre[to[i ^ 1]]) {
        if (mndis > cap[i]) { mndis = cap[i]; }
      }
      for (int i = pre[u]; ~i; i = pre[to[i ^ 1]]) {
        cap[i] -= mndis; cap[i ^ 1] += mndis;
      }
      u = src; mxflow += mndis;
      continue;
    }
    bool flag = false;
    for (int i = cur[u]; ~i; i = nxt[i]) {
      v = to[i];
      if (cap[i] > 0 && dis[v] + 1 == dis[u]) {
        flag = true; cur[u] = pre[v] = i; break;
      }
    }
    if (flag) { u = v; continue; }
    int mndis = n;
    for (int i = head[u]; ~i; i = nxt[i]) {
      if (cap[i] > 0 && dis[to[i]] < mndis) { mndis = dis[to[i]]; cur[u] = i; }
    }
    if (--gap[dis[u]] == 0) { return mxflow; }
    dis[u] = mndis + 1; gap[dis[u]]++;
    if (u != src) { u = to[pre[u] ^ 1]; }
  }
  return mxflow;
}
//ISAP + bfs标号 + queue + 邻接表 O(V^2*E)
typedef long long ftype;
const ftype INF = 0x3f3f3f3f;
int n, head[N], to[M], nxt[M], tot, dis[N], pre[N], cur[N], gap[N];
ftype cap[M];
inline void init() { tot = 0; memset(head, -1, sizeof(head)); }
inline void addedge(int x, int y, ftype w, ftype rw = 0) {
  to[tot] = y; cap[tot] = w; nxt[tot] = head[x]; head[x] = tot++;
  to[tot] = x; cap[tot] = rw; nxt[tot] = head[y]; head[y] = tot++;
}
void bfs(int sink) {
  memset(dis, -1, sizeof(dis));
  memset(gap, 0, sizeof(gap));
  dis[sink] = 0; gap[0] = 1;
  queue<int> que; que.push(sink);
  while (!que.empty()) {
    int u = que.front(); que.pop();
    for (int i = head[u], v; ~i; i = nxt[i]) {
      v = to[i];
      if (~dis[v]) { continue; }
      dis[v] = dis[u] + 1; gap[dis[v]]++; que.push(v);
    }
  }
}
ftype ISAP(int src, int sink, int n) {
  bfs(sink);
  memcpy(cur, head, sizeof(head));
  int u = pre[src] = src, v, i; ftype mxflow = 0;
  while (dis[sink] < n) {
    if (u == sink) {
      ftype mndis = INF; int inser;
      for (i = src; i != sink; i = to[cur[i]]) {
        if (mndis > cap[cur[i]]) { mndis = cap[cur[i]]; inser = i; }
      }
      for (i = src; i != sink; i = to[cur[i]]) {
        cap[cur[i]] -= mndis; cap[cur[i] ^ 1] += mndis;
      }
      mxflow += mndis; u = inser;
    }
    for (i = cur[u]; ~i; i = nxt[i]) {
      v = to[i];
      if (dis[v] + 1 == dis[u] && cap[i] > 0) { break; }
    }
    if (~i) { cur[u] = i; pre[to[i]] = u; u = to[i]; }
    else {
      if (--gap[dis[u]] == 0) { break; }
      int mndis = n;
      for (i = head[u]; ~i; i = nxt[i]) {
        if (cap[i] > 0 && mndis > dis[to[i]]) { cur[u] = i; mndis = dis[to[i]]; }
      }
      dis[u] = mndis + 1; gap[dis[u]]++; u = pre[u];
    }
  }
  return mxflow;
}
//Dinic O(V^2*E)
typedef long long ftype;
const ftype INF = 0x3f3f3f3f;
int head[N], to[M], nxt[M], tot, dis[N], cur[N], src, sink;
ftype cap[M];
inline void init() { tot = 0; memset(head, -1, sizeof(head)); }
inline void addedge(int x, int y, ftype w, ftype rw = 0) {
  to[tot] = y; cap[tot] = w; nxt[tot] = head[x]; head[x] = tot++;
  to[tot] = x; cap[tot] = rw; nxt[tot] = head[y]; head[y] = tot++;
}
bool bfs() {
  memset(dis, 0, sizeof(dis)); dis[src] = 1;
  queue<int> que; que.push(src);
  while (!que.empty()) {
    int u = que.front(); que.pop();
    for (int i = head[u], v; ~i; i = nxt[i]) {
      v = to[i];
      if (cap[i] > 0 && !dis[v]) { dis[v] = dis[u] + 1; que.push(v); }
    }
  }
  return dis[sink];
}
ftype dfs(int u, ftype delta) {
  if (u == sink || delta == 0) { return delta; }
  ftype ret = 0;
  for (int &i = cur[u], v; delta && ~i; i = nxt[i]) {
    v = to[i];
    if (cap[i] > 0 && dis[v] == dis[u] + 1) {
      ftype aug = dfs(v, min(cap[i], delta));
      if (!aug) { continue; }
      cap[i] -= aug; cap[i ^ 1] += aug; delta -= aug; ret += aug;
      if (!delta) { break; }
    }
  }
  return ret;
}
ftype Dinic() {
  ftype ret = 0;
  while (bfs()) {
    memcpy(cur, head, sizeof(head));
    ret += dfs(src, INF);
  }
  return ret;
}
//HLPP Highest Label Preflow Push O(V^3)
typedef long long ftype;
struct Edge { int v; ftype c; } edge[M];
vector<int> e[N];
int n, m, src, sink, c[N << 1], d[N], done[N];
ftype w[N];
bool vis[N];
void init(int _n, int _src, int _sink) {
  n = _n; m = 0; src = _src; sink = _sink;
  for (int i = 0; i <= n; ++i) { e[i].clear(); }
}
inline void addEdge(int x, int y, ftype w, ftype rw = 0) {
  edge[m].v = y; edge[m].c = w; e[x].push_back(m++);
  edge[m].v = x; edge[m].c = rw; e[y].push_back(m++);
}
void bfs() {
  memset(c, 0, sizeof(c));
  fill(d, d + n, n + 1);
  queue<int> que; que.push(sink);
  c[n + 1] = n - 1; d[src] = n; d[sink] = 0;
  while (!que.empty()) {
    int u = que.front(); que.pop();
    c[n + 1]++; c[d[u]]++;
    for (int i = 0, v; i < (int)e[u].size(); i++) {
      v = edge[e[u][i]].v; ftype c = edge[e[u][i] ^ 1].c;
      if (d[v] == n + 1 && c > 0) { d[v] = d[u] + 1; que.push(v); }
    }
  }
}
int HLPP(int n) {
  memset(w, 0, sizeof(w));
  memset(done, 0, sizeof(done));
  memset(vis, 0, sizeof(vis));
  bfs();
  int todo = -1;
  vector<queue<int>> que(n << 1);
  vis[src] = vis[sink] = true;
  for (int i = 0, v; i < (int)e[src].size(); i++) {
    Edge &arc = edge[e[src][i]], &cra = edge[e[src][i] ^ 1]; v = arc.v;
    w[v] += arc.c; cra.c += arc.c; arc.c = 0;
    if (!vis[v]) { vis[v] = true; que[d[v]].push(v); todo = max(todo, d[v]); }
  }
  while (todo >= 0) {
    if (que[todo].empty()) { todo--; continue; }
    int u = que[todo].front(); que[todo].pop();
    vis[u] = false;
    while (done[u] < (int)e[u].size()) {
      Edge &arc = edge[e[u][done[u]]]; int v = arc.v;
      if (d[u] == d[v] + 1 && arc.c > 0) {
        Edge &cra = edge[e[u][done[u]] ^ 1]; ftype f = min(w[u], arc.c);
        w[u] -= f; w[v] += f; arc.c -= f; cra.c += f;
        if (!vis[v]) { vis[v] = true; que[d[v]].push(v); }
        if (w[u] == 0) { break; }
      }
      done[u]++;
    }
    if (w[u] > 0) {
      int du = d[u];
      c[d[u]]--; d[u] = n << 1;
      for (int i = 0, v; i < (int)e[u].size(); i++) {
        Edge &arc = edge[e[u][i]]; v = arc.v;
        if (d[u] > d[v] + 1 && arc.c > 0) { d[u] = d[v] + 1; done[u] = i; }
      }
      c[d[u]]++;
      if (c[du] == 0) {
        for (int i = 0; i < n; ++i) {
          if (d[i] > du && d[i] < n + 1) { c[d[i]]--; c[n + 1]++; d[i] = n + 1; }
        }
      }
      vis[u] = true; que[d[u]].push(u); todo = d[u];
    }
  }
  return w[sink];
}
//有上下界的网络流
//无源汇上下界最大流
//增加超级源汇点, 边的容量变为原弧的上界减去下界的差, 记录每个点的入流下界和-出流下界和
//当下界和大于0时连一条超级源点到这个点的边, 容量为这个下界和
//当下界和小于0时连一条这个点到超级汇点的边, 容量为下界和的绝对值
//求一遍最大流, 如果源的出度满流的话, 即存在最大流, 否则则不存在最大流
//有源汇上下界最大流
//从汇连一条容量INF的边到源, 将有源汇转化为无源汇
//判断是否满流后, 去掉超级源汇及其边(head[]删除即可, 调用最大流算法时, 点的数量要包括超级源汇)
//再跑一遍原源到原汇的最大流, 输出即可
//有源汇上下界最小流
//增加超级源汇点, 求一遍超级源到超级汇的最大流
//从原汇点连一条容量INF的边到原源点, 再求一遍超级源到超级汇的最大流
//当且仅当超级源的出度满流时有可行解, 解为原汇点到原源点的反向弧
////最小费用最大流 MCMF O(V*E*f)
//最小费用流: 若dis[sink]为负则继续增广
//最小费用最大流: 若dis[sink]不为INF则继续增广
//求最大费用只需取相反数, 结果取相反数即可
typedef long long ftype;
const ftype INF = 0x3f3f3f3f;
int head[N], to[M], nxt[M], tot, cur[N];
ftype cap[M], cost[M], flow[N], dis[N], mncost, mxflow;
bool vis[N];
inline void init() { tot = 0; memset(head, -1, sizeof(head)); }
inline void addedge(int x, int y, ftype w, ftype c) {
  to[tot] = y; cap[tot] = w; cost[tot] = c; nxt[tot] = head[x]; head[x] = tot++;
  to[tot] = x; cap[tot] = 0; cost[tot] = -c; nxt[tot] = head[y]; head[y] = tot++;
}
bool SPFA(int src, int sink) {
  memset(dis, 0x3f, sizeof(dis));
  memset(vis, 0, sizeof(vis));
  dis[src] = 0; cur[src] = -1; flow[src] = INF;
  queue<int> que; que.push(src);
  while (!que.empty()) {
    int u = que.front(); que.pop();
    vis[u] = false;
    for (int i = head[u], v; ~i; i = nxt[i]) {
      v = to[i];
      if (cap[i] > 0 && dis[v] > dis[u] + cost[i]) {
        dis[v] = dis[u] + cost[i]; flow[v] = min(flow[u], cap[i]); cur[v] = i;
        if (!vis[v]) { vis[v] = true; que.push(v); }
      }
    }
  }
  if (dis[sink] == INF) { return false; }
  mxflow += flow[sink]; mncost += flow[sink] * dis[sink];
  for (int i = cur[sink]; ~i; i = cur[to[i ^ 1]]) {
    cap[i] -= flow[sink]; cap[i ^ 1] += flow[sink];
  }
  return true;
}
ftype MCMF(int src, int sink) {
  mxflow = mncost = 0;
  while (SPFA(src, sink));
  return mncost;
}
Fetch from rsolar/ACM-Template 2016-08-13 23:07:20 +08:00			`//最大流`
			`//SAP + 邻接矩阵 O(V^2*E) 点的编号默认从0开始`
			`typedef long long ftype;`
			`int n, dis[N], pre[N], cur[N], gap[N];`
			`ftype cap[N][N];`
			`ftype SAP(int src, int sink, int n) {`
			`memset(dis, 0, sizeof(dis));`
			`memset(cur, 0, sizeof(cur));`
			`memset(gap, 0, sizeof(gap));`
			`int u = src; ftype mxflow = 0, aug = -1; pre[src] = src; gap[0] = n;`
			`while (dis[src] < n) {`
			`loop:`
			`for (int v = cur[u]; v < n; ++v) {`
			`if (cap[u][v] > 0 && dis[u] == dis[v] + 1) {`
			`if (aug == -1 \|\| aug > cap[u][v]) { aug = cap[u][v]; }`
			`pre[v] = u; u = cur[u] = v;`
			`if (v == sink) {`
			`for (u = pre[u]; v != src; v = u, u = pre[u]) {`
			`cap[u][v] -= aug; cap[v][u] += aug;`
			`}`
			`mxflow += aug; aug = -1;`
			`}`
			`goto loop;`
			`}`
			`}`
			`int mndis = n - 1;`
			`for (int v = 0; v < n; v++) {`
			`if (cap[u][v] > 0 && mndis > dis[v]) { cur[u] = v; mndis = dis[v]; }`
			`}`
			`if (--gap[dis[u]] == 0) { break; }`
			`dis[u] = mndis + 1; gap[dis[u]]++; u = pre[u];`
			`}`
			`return mxflow;`
			`}`
			`//ISAP + 邻接表 O(V^2*E)`
			`typedef long long ftype;`
			`const ftype INF = 0x3f3f3f3f;`
			`int head[N], to[M], nxt[M], tot, dis[N], pre[N], cur[N], gap[N];`
			`ftype cap[M];`
			`inline void init() { tot = 0; memset(head, -1, sizeof(head)); }`
			`inline void addedge(int x, int y, ftype w, ftype rw = 0) {`
			`to[tot] = y; cap[tot] = w; nxt[tot] = head[x]; head[x] = tot++;`
			`to[tot] = x; cap[tot] = rw; nxt[tot] = head[y]; head[y] = tot++;`
			`}`
			`ftype ISAP(int src, int sink, int n) {`
			`memset(dis, 0, sizeof(dis));`
			`memset(gap, 0, sizeof(gap));`
			`memcpy(cur, head, sizeof(head));`
			`int u = src, v; ftype mxflow = 0; pre[u] = -1; gap[0] = n;`
			`while (dis[src] < n) {`
			`if (u == sink) {`
			`ftype mndis = INF;`
			`for (int i = pre[u]; ~i; i = pre[to[i ^ 1]]) {`
			`if (mndis > cap[i]) { mndis = cap[i]; }`
			`}`
			`for (int i = pre[u]; ~i; i = pre[to[i ^ 1]]) {`
			`cap[i] -= mndis; cap[i ^ 1] += mndis;`
			`}`
			`u = src; mxflow += mndis;`
			`continue;`
			`}`
			`bool flag = false;`
			`for (int i = cur[u]; ~i; i = nxt[i]) {`
			`v = to[i];`
			`if (cap[i] > 0 && dis[v] + 1 == dis[u]) {`
			`flag = true; cur[u] = pre[v] = i; break;`
			`}`
			`}`
			`if (flag) { u = v; continue; }`
			`int mndis = n;`
			`for (int i = head[u]; ~i; i = nxt[i]) {`
			`if (cap[i] > 0 && dis[to[i]] < mndis) { mndis = dis[to[i]]; cur[u] = i; }`
			`}`
			`if (--gap[dis[u]] == 0) { return mxflow; }`
			`dis[u] = mndis + 1; gap[dis[u]]++;`
			`if (u != src) { u = to[pre[u] ^ 1]; }`
			`}`
			`return mxflow;`
			`}`
			`//ISAP + bfs标号 + queue + 邻接表 O(V^2*E)`
			`typedef long long ftype;`
			`const ftype INF = 0x3f3f3f3f;`
			`int n, head[N], to[M], nxt[M], tot, dis[N], pre[N], cur[N], gap[N];`
			`ftype cap[M];`
			`inline void init() { tot = 0; memset(head, -1, sizeof(head)); }`
			`inline void addedge(int x, int y, ftype w, ftype rw = 0) {`
			`to[tot] = y; cap[tot] = w; nxt[tot] = head[x]; head[x] = tot++;`
			`to[tot] = x; cap[tot] = rw; nxt[tot] = head[y]; head[y] = tot++;`
			`}`
			`void bfs(int sink) {`
			`memset(dis, -1, sizeof(dis));`
			`memset(gap, 0, sizeof(gap));`
			`dis[sink] = 0; gap[0] = 1;`
			`queue<int> que; que.push(sink);`
			`while (!que.empty()) {`
			`int u = que.front(); que.pop();`
			`for (int i = head[u], v; ~i; i = nxt[i]) {`
			`v = to[i];`
			`if (~dis[v]) { continue; }`
			`dis[v] = dis[u] + 1; gap[dis[v]]++; que.push(v);`
			`}`
			`}`
			`}`
			`ftype ISAP(int src, int sink, int n) {`
			`bfs(sink);`
			`memcpy(cur, head, sizeof(head));`
			`int u = pre[src] = src, v, i; ftype mxflow = 0;`
			`while (dis[sink] < n) {`
			`if (u == sink) {`
			`ftype mndis = INF; int inser;`
			`for (i = src; i != sink; i = to[cur[i]]) {`
			`if (mndis > cap[cur[i]]) { mndis = cap[cur[i]]; inser = i; }`
			`}`
			`for (i = src; i != sink; i = to[cur[i]]) {`
			`cap[cur[i]] -= mndis; cap[cur[i] ^ 1] += mndis;`
			`}`
			`mxflow += mndis; u = inser;`
			`}`
			`for (i = cur[u]; ~i; i = nxt[i]) {`
			`v = to[i];`
			`if (dis[v] + 1 == dis[u] && cap[i] > 0) { break; }`
			`}`
			`if (~i) { cur[u] = i; pre[to[i]] = u; u = to[i]; }`
			`else {`
			`if (--gap[dis[u]] == 0) { break; }`
			`int mndis = n;`
			`for (i = head[u]; ~i; i = nxt[i]) {`
			`if (cap[i] > 0 && mndis > dis[to[i]]) { cur[u] = i; mndis = dis[to[i]]; }`
			`}`
			`dis[u] = mndis + 1; gap[dis[u]]++; u = pre[u];`
			`}`
			`}`
			`return mxflow;`
			`}`
			`//Dinic O(V^2*E)`
			`typedef long long ftype;`
			`const ftype INF = 0x3f3f3f3f;`
			`int head[N], to[M], nxt[M], tot, dis[N], cur[N], src, sink;`
			`ftype cap[M];`
			`inline void init() { tot = 0; memset(head, -1, sizeof(head)); }`
			`inline void addedge(int x, int y, ftype w, ftype rw = 0) {`
			`to[tot] = y; cap[tot] = w; nxt[tot] = head[x]; head[x] = tot++;`
			`to[tot] = x; cap[tot] = rw; nxt[tot] = head[y]; head[y] = tot++;`
			`}`
			`bool bfs() {`
			`memset(dis, 0, sizeof(dis)); dis[src] = 1;`
			`queue<int> que; que.push(src);`
			`while (!que.empty()) {`
			`int u = que.front(); que.pop();`
			`for (int i = head[u], v; ~i; i = nxt[i]) {`
			`v = to[i];`
			`if (cap[i] > 0 && !dis[v]) { dis[v] = dis[u] + 1; que.push(v); }`
			`}`
			`}`
			`return dis[sink];`
			`}`
			`ftype dfs(int u, ftype delta) {`
			`if (u == sink \|\| delta == 0) { return delta; }`
			`ftype ret = 0;`
			`for (int &i = cur[u], v; delta && ~i; i = nxt[i]) {`
			`v = to[i];`
			`if (cap[i] > 0 && dis[v] == dis[u] + 1) {`
			`ftype aug = dfs(v, min(cap[i], delta));`
			`if (!aug) { continue; }`
			`cap[i] -= aug; cap[i ^ 1] += aug; delta -= aug; ret += aug;`
			`if (!delta) { break; }`
			`}`
			`}`
			`return ret;`
			`}`
			`ftype Dinic() {`
			`ftype ret = 0;`
			`while (bfs()) {`
			`memcpy(cur, head, sizeof(head));`
			`ret += dfs(src, INF);`
			`}`
			`return ret;`
			`}`
			`//HLPP Highest Label Preflow Push O(V^3)`
			`typedef long long ftype;`
			`struct Edge { int v; ftype c; } edge[M];`
			`vector<int> e[N];`
			`int n, m, src, sink, c[N << 1], d[N], done[N];`
			`ftype w[N];`
			`bool vis[N];`
			`void init(int _n, int _src, int _sink) {`
			`n = _n; m = 0; src = _src; sink = _sink;`
			`for (int i = 0; i <= n; ++i) { e[i].clear(); }`
			`}`
			`inline void addEdge(int x, int y, ftype w, ftype rw = 0) {`
			`edge[m].v = y; edge[m].c = w; e[x].push_back(m++);`
			`edge[m].v = x; edge[m].c = rw; e[y].push_back(m++);`
			`}`
			`void bfs() {`
			`memset(c, 0, sizeof(c));`
			`fill(d, d + n, n + 1);`
			`queue<int> que; que.push(sink);`
			`c[n + 1] = n - 1; d[src] = n; d[sink] = 0;`
			`while (!que.empty()) {`
			`int u = que.front(); que.pop();`
			`c[n + 1]++; c[d[u]]++;`
			`for (int i = 0, v; i < (int)e[u].size(); i++) {`
			`v = edge[e[u][i]].v; ftype c = edge[e[u][i] ^ 1].c;`
			`if (d[v] == n + 1 && c > 0) { d[v] = d[u] + 1; que.push(v); }`
			`}`
			`}`
			`}`
			`int HLPP(int n) {`
			`memset(w, 0, sizeof(w));`
			`memset(done, 0, sizeof(done));`
			`memset(vis, 0, sizeof(vis));`
			`bfs();`
			`int todo = -1;`
			`vector<queue<int>> que(n << 1);`
			`vis[src] = vis[sink] = true;`
			`for (int i = 0, v; i < (int)e[src].size(); i++) {`
			`Edge &arc = edge[e[src][i]], &cra = edge[e[src][i] ^ 1]; v = arc.v;`
			`w[v] += arc.c; cra.c += arc.c; arc.c = 0;`
			`if (!vis[v]) { vis[v] = true; que[d[v]].push(v); todo = max(todo, d[v]); }`
			`}`
			`while (todo >= 0) {`
			`if (que[todo].empty()) { todo--; continue; }`
			`int u = que[todo].front(); que[todo].pop();`
			`vis[u] = false;`
			`while (done[u] < (int)e[u].size()) {`
			`Edge &arc = edge[e[u][done[u]]]; int v = arc.v;`
			`if (d[u] == d[v] + 1 && arc.c > 0) {`
			`Edge &cra = edge[e[u][done[u]] ^ 1]; ftype f = min(w[u], arc.c);`
			`w[u] -= f; w[v] += f; arc.c -= f; cra.c += f;`
			`if (!vis[v]) { vis[v] = true; que[d[v]].push(v); }`
			`if (w[u] == 0) { break; }`
			`}`
			`done[u]++;`
			`}`
			`if (w[u] > 0) {`
			`int du = d[u];`
			`c[d[u]]--; d[u] = n << 1;`
			`for (int i = 0, v; i < (int)e[u].size(); i++) {`
			`Edge &arc = edge[e[u][i]]; v = arc.v;`
			`if (d[u] > d[v] + 1 && arc.c > 0) { d[u] = d[v] + 1; done[u] = i; }`
			`}`
			`c[d[u]]++;`
			`if (c[du] == 0) {`
			`for (int i = 0; i < n; ++i) {`
			`if (d[i] > du && d[i] < n + 1) { c[d[i]]--; c[n + 1]++; d[i] = n + 1; }`
			`}`
			`}`
			`vis[u] = true; que[d[u]].push(u); todo = d[u];`
			`}`
			`}`
			`return w[sink];`
			`}`
			`//有上下界的网络流`
			`//无源汇上下界最大流`
			`//增加超级源汇点, 边的容量变为原弧的上界减去下界的差, 记录每个点的入流下界和-出流下界和`
			`//当下界和大于0时连一条超级源点到这个点的边, 容量为这个下界和`
			`//当下界和小于0时连一条这个点到超级汇点的边, 容量为下界和的绝对值`
			`//求一遍最大流, 如果源的出度满流的话, 即存在最大流, 否则则不存在最大流`
			`//有源汇上下界最大流`
			`//从汇连一条容量INF的边到源, 将有源汇转化为无源汇`
			`//判断是否满流后, 去掉超级源汇及其边(head[]删除即可, 调用最大流算法时, 点的数量要包括超级源汇)`
			`//再跑一遍原源到原汇的最大流, 输出即可`
			`//有源汇上下界最小流`
			`//增加超级源汇点, 求一遍超级源到超级汇的最大流`
			`//从原汇点连一条容量INF的边到原源点, 再求一遍超级源到超级汇的最大流`
			`//当且仅当超级源的出度满流时有可行解, 解为原汇点到原源点的反向弧`
			`////最小费用最大流 MCMF O(VEf)`
			`//最小费用流: 若dis[sink]为负则继续增广`
			`//最小费用最大流: 若dis[sink]不为INF则继续增广`
			`//求最大费用只需取相反数, 结果取相反数即可`
			`typedef long long ftype;`
			`const ftype INF = 0x3f3f3f3f;`
			`int head[N], to[M], nxt[M], tot, cur[N];`
			`ftype cap[M], cost[M], flow[N], dis[N], mncost, mxflow;`
			`bool vis[N];`
			`inline void init() { tot = 0; memset(head, -1, sizeof(head)); }`
			`inline void addedge(int x, int y, ftype w, ftype c) {`
			`to[tot] = y; cap[tot] = w; cost[tot] = c; nxt[tot] = head[x]; head[x] = tot++;`
			`to[tot] = x; cap[tot] = 0; cost[tot] = -c; nxt[tot] = head[y]; head[y] = tot++;`
			`}`
			`bool SPFA(int src, int sink) {`
			`memset(dis, 0x3f, sizeof(dis));`
			`memset(vis, 0, sizeof(vis));`
			`dis[src] = 0; cur[src] = -1; flow[src] = INF;`
			`queue<int> que; que.push(src);`
			`while (!que.empty()) {`
			`int u = que.front(); que.pop();`
			`vis[u] = false;`
			`for (int i = head[u], v; ~i; i = nxt[i]) {`
			`v = to[i];`
			`if (cap[i] > 0 && dis[v] > dis[u] + cost[i]) {`
			`dis[v] = dis[u] + cost[i]; flow[v] = min(flow[u], cap[i]); cur[v] = i;`
			`if (!vis[v]) { vis[v] = true; que.push(v); }`
			`}`
			`}`
			`}`
			`if (dis[sink] == INF) { return false; }`
			`mxflow += flow[sink]; mncost += flow[sink] * dis[sink];`
			`for (int i = cur[sink]; ~i; i = cur[to[i ^ 1]]) {`
			`cap[i] -= flow[sink]; cap[i ^ 1] += flow[sink];`
			`}`
			`return true;`
			`}`
			`ftype MCMF(int src, int sink) {`
			`mxflow = mncost = 0;`
			`while (SPFA(src, sink));`
			`return mncost;`
			`}`