1. 103E
大意: 给定$n$个集合, 满足对于任意的$k$, 任意$k$个集合的并集都不少于$k$. 要求选出$k$个集合$(k> 0)$, 使得并恰好等于$k$, 输出最少花费.
Hall定理: 二分图的$X$部到$Y$部有完美匹配等价于$X$中任意$k$个点与$Y$中至少$k$个点相邻.
所有集合为$X$部, 每个数为$Y$部, 集合向所含数连边, 那么一定存在完美匹配. 假设求出一组匹配, 数字$i$对应集合$C_i$, 那么最终若选取集合$A_i$, 则$A_i$中所有数字$x$对应的集合$C_x$一定也要选, 把权值取负就转化为最大权闭合子图模型. 对于最大权闭合子图问题, 源点连所有正权点, 容量为该点权值, 所有负权点连汇点, 容量为该点权值的绝对值, 其余边与原图一样, 容量为无穷, 求出源点到汇点的最小割, 那么答案为正权和-最小割, 与源点间的割的含义为不选择该点, 与汇点间的割的含义为选择该点.
#include <iostream> #include <cstdio> #include <queue> #define REP(i,a,n) for(int i=a;i<=n;++i) #define pb push_back using namespace std; const int N = 1e6+10, INF = 0x3f3f3f3f; int n, S, T, clk, f[N], vis[N]; vector<int> g[N]; int dfs(int x) { for (int y:g[x]) if (vis[y]!=clk) { vis[y] = clk; if (!f[y]||dfs(f[y])) return f[y]=x; } return 0; } struct edge { int v,w,next; } e[N]; int head[N], dep[N], cur[N], cnt=1; queue<int> Q; void add(int u, int v, int w) { e[++cnt] = {v,w,head[u]}; head[u] = cnt; e[++cnt] = {u,0,head[v]}; head[v] = cnt; } int bfs() { REP(i,1,T) dep[i]=INF,vis[i]=0,cur[i]=head[i]; dep[S]=0,Q.push(S); while (Q.size()) { int u = Q.front(); Q.pop(); for (int i=head[u]; i; i=e[i].next) { if (dep[e[i].v]>dep[u]+1&&e[i].w) { dep[e[i].v]=dep[u]+1; Q.push(e[i].v); } } } return dep[T]!=INF; } int dfs(int x, int w) { if (x==T) return w; int used = 0; for (int i=cur[x]; i; i=e[i].next) { cur[x] = i; if (dep[e[i].v]==dep[x]+1&&e[i].w) { int flow = dfs(e[i].v,min(w-used,e[i].w)); if (flow) { used += flow; e[i].w -= flow; e[i^1].w += flow; if (used==w) break; } } } return used; } int dinic() { int ans = 0; while (bfs()) ans+=dfs(S,INF); return ans; } int main() { scanf("%d", &n), S = n+1, T = S+1; REP(i,1,n) { int k, t; scanf("%d", &k); while (k--) { scanf("%d", &t); g[i].pb(t+n); g[t+n].pb(i); } } REP(i,1,n) ++clk, dfs(i); int sum = 0; REP(i,1,n) { int t; scanf("%d", &t); t = -t; if (t>=0) add(S,i,t),sum+=t; else add(i,T,-t); } REP(i,1,n) for (int j:g[i]) add(i,f[j],INF); printf("%d ", dinic()-sum); }
2. 164C
大意: $k$台机器, $n$个任务, 任务$i$开始时间$s_i$, 持续时间$t_i$, 获利$c_i$, 每台机器可以处理任何任务, 没处理完不能切换, 求完成哪些任务收益最大.
最大$k$重区间集问题, 时间离散化, 每个时间向下一个时间连容量$k$, 花费$0$, 任务$i$起点向终点连容量$1$, 花费$c_i$, 求出最大费用最大流即可.
#include <iostream> #include <algorithm> #include <cstdio> #include <queue> #define REP(i,a,n) for(int i=a;i<=n;++i) using namespace std; const int N = 5e4+10,S=N-2,T=N-1,INF=0x3f3f3f3f; int n,m,cost,flow,b[N]; struct edge { int to,next,w,v; edge(int to=0,int next=0,int w=0,int v=0):to(to),next(next),w(w),v(v){} } e[N]; int head[N],dep[N],vis[N],cnt=1; queue<int> Q; int spfa() { REP(i,1,*b) dep[i]=-INF,vis[i]=0; dep[T]=-INF; dep[S]=0,Q.push(S); while (Q.size()) { int u = Q.front(); Q.pop(); vis[u] = 0; for (int i=head[u]; i; i=e[i].next) { if (e[i].w&&dep[e[i].to]<dep[u]+e[i].v) { dep[e[i].to]=dep[u]+e[i].v; if (!vis[e[i].to]) { vis[e[i].to]=1; Q.push(e[i].to); } } } } return dep[T]!=-INF; } int dfs(int x, int w) { if (x==T) { cost = cost+w*dep[T]; flow += w; return w; } vis[x] = 1; int used = 0; for (int i=head[x]; i; i=e[i].next) { if (!vis[e[i].to]&&dep[e[i].to]==dep[x]+e[i].v&&e[i].w) { int f = dfs(e[i].to,min(w-used,e[i].w)); if (f) { used += f; e[i].w -= f; e[i^1].w += f; if(used==w) break; } } } return used; } void dinic(){ while(spfa()) dfs(S,INF); } void add(int x,int y,int k,int v) { e[++cnt] = edge(y,head[x],k,v); head[x] = cnt; e[++cnt] = edge(x,head[y],0,-v); head[y] = cnt; } int k,L[N],R[N],c[N],no[N]; int main() { scanf("%d%d", &n, &k); REP(i,1,n) { int s,t; scanf("%d%d%d",&s,&t,c+i); b[++*b]=L[i]=s; b[++*b]=R[i]=s+t; } sort(b+1,b+1+*b),*b=unique(b+1,b+1+*b)-b-1; REP(i,1,n) { L[i]=lower_bound(b+1,b+1+*b,L[i])-b; R[i]=lower_bound(b+1,b+1+*b,R[i])-b; } add(S,1,k,0),add(*b,T,k,0); REP(i,2,*b) add(i-1,i,k,0); REP(i,1,n) no[i]=cnt+1,add(L[i],R[i],1,c[i]); dinic(); REP(i,1,n) printf("%d ", !e[no[i]].w); puts(""); }
3. 237E
大意: 给定字符串$t$, 给定$n$个子串, 第$i$个子串$s_i$最多可以选出$a_i$个字符, 每个字符花费为$i$, 求组成字符串$t$的最少花费.
裸的费用流, 源点向子串$i$连容量$a_i$, 费用$0$, $i$向每个字符$x$连容量$cnt_s[x]$, 费用$i$, 最后每个字符$x$向汇点连容量$cnt_t[x]$, 费用0. 求最小费用即可.
#include <iostream> #include <cstdio> #include <queue> #define REP(i,a,n) for(int i=a;i<=n;++i) using namespace std; const int N = 5e4+10,S=N-2,T=N-1,INF=0x3f3f3f3f; int n,m,cost,flow,b[N]; struct edge { int to,next,w,v; edge(int to=0,int next=0,int w=0,int v=0):to(to),next(next),w(w),v(v){} } e[N]; int head[N],dep[N],vis[N],cnt=1; queue<int> Q; int spfa() { REP(i,1,n+30) dep[i]=INF,vis[i]=0; dep[T]=INF; dep[S]=0,Q.push(S); while (Q.size()) { int u = Q.front(); Q.pop(); vis[u] = 0; for (int i=head[u]; i; i=e[i].next) { if (e[i].w&&dep[e[i].to]>dep[u]+e[i].v) { dep[e[i].to]=dep[u]+e[i].v; if (!vis[e[i].to]) { vis[e[i].to]=1; Q.push(e[i].to); } } } } return dep[T]!=INF; } int dfs(int x, int w) { if (x==T) { cost = cost+w*dep[T]; flow += w; return w; } vis[x] = 1; int used = 0; for (int i=head[x]; i; i=e[i].next) { if (!vis[e[i].to]&&dep[e[i].to]==dep[x]+e[i].v&&e[i].w) { int f = dfs(e[i].to,min(w-used,e[i].w)); if (f) { used += f; e[i].w -= f; e[i^1].w += f; if(used==w) break; } } } return used; } void dinic(){ while(spfa()) dfs(S,INF); } void add(int x,int y,int k,int v) { e[++cnt] = edge(y,head[x],k,v); head[x] = cnt; e[++cnt] = edge(x,head[y],0,-v); head[y] = cnt; } int f[N]; char s[N]; int main() { scanf("%s%d", s+1, &n); m = strlen(s+1); REP(i,1,m) ++f[s[i]]; int sum = 0; REP(i,'a','z') if (f[i]) { add(n+i-'a'+1,T,f[i],0),sum+=f[i],f[i]=0; } REP(i,1,n) { int x; scanf("%s%d", s+1, &x); m = strlen(s+1); REP(i,1,m) ++f[s[i]]; add(S,i,x,0); REP(j,'a','z') if (f[j]) add(i,n+j-'a'+1,f[j],i); REP(i,'a','z') f[i]=0; } dinic(); if (flow!=sum) return puts("-1"),0; printf("%d ", cost); }
4. 269C
大意:给定无向图, 求将边定向, 使它成为一个$1$到$n$的流.
拓扑排序即可.
#include <iostream> #include <cstdio> #include <queue> #define REP(i,a,n) for(int i=a;i<=n;++i) #define pb push_back using namespace std; const int N = 1e6+10; int n,m,deg[N],ans[N],vis[N]; struct _ {int to,w,id;}; vector<_> g[N]; int main() { scanf("%d%d", &n, &m); REP(i,1,m) { int u,v,w; scanf("%d%d%d",&u,&v,&w); g[u].pb({v,w,i}); g[v].pb({u,w,-i}); deg[u]+=w,deg[v]+=w; } queue<int> q; q.push(1),vis[n]=1; memset(ans,-1,sizeof ans); while (q.size()) { int x = q.front(); q.pop(); vis[x] = 1; for (_ e:g[x]) { if (e.id<0) { if (ans[-e.id]==-1) ans[-e.id]=1; } else if (ans[e.id]==-1) ans[e.id]=0; if (!vis[e.to]) { if (!(deg[e.to]-=2*e.w)) { q.push(e.to); } } } } REP(i,1,m) printf("%d ",ans[i]); }
5. 277E
大意: 给定$n$个平面点, $y$值大的可以向$y$值小的连有向边, 求一棵边权和最小的有根二叉树.
每个点入度1, 出度不超过2, 建图跑费用流即可.
#include <iostream> #include <cstdio> #include <queue> #include <math.h> #define REP(i,a,n) for(int i=a;i<=n;++i) #define pb push_back using namespace std; const int N = 1e5+10, INF = 0x3f3f3f3f; int n, m, k; struct _ {int from,to,w;double f;}; vector<_> E; vector<int> g[N]; int a[N], pre[N], inq[N]; double d[N]; int mf; double mc; queue<int> q; void add(int x, int y, int c, double w) { g[x].pb(E.size()); E.pb({x,y,c,w}); g[y].pb(E.size()); E.pb({y,x,0,-w}); } void mfmc(int S, int T) { while (1) { REP(i,1,T) a[i]=INF,d[i]=1e15,inq[i]=0; q.push(S),d[S]=0; while (!q.empty()) { int x=q.front(); q.pop(); inq[x] = 0; for (auto t:g[x]) { auto e=E[t]; if (e.w>0&&d[e.to]>d[x]+e.f) { d[e.to]=d[x]+e.f; pre[e.to]=t; a[e.to]=min(a[x],e.w); if (!inq[e.to]) { inq[e.to]=1; q.push(e.to); } } } } if (a[T]==INF) break; for (int u=T;u!=S;u=E[pre[u]].from) { E[pre[u]].w-=a[T]; E[pre[u]^1].w+=a[T]; } mf+=a[T],mc+=a[T]*d[T]; } } int x[N],y[N]; int main() { scanf("%d", &n); int S=2*n+1,T=S+1; REP(i,1,n) { scanf("%d%d",x+i,y+i); add(S,i,2,0); add(i+n,T,1,0); } REP(i,1,n) REP(j,1,n) if (y[i]>y[j]) { add(i,j+n,1,sqrt((x[i]-x[j])*(x[i]-x[j])+(y[i]-y[j])*(y[i]-y[j]))); } mfmc(S,T); if (mf!=n-1) return puts("-1"),0; printf("%.10lf ",mc); }
6. 311E
大意: $n$个点, 颜色黑或白, 翻转第$i$个点的颜色花费$v_i$, $m$个需求, 要求一些点全白或全黑, 满足则有一定收益. 有些特殊需求若不满足则要花费$g$, 求最大收益.
最大权闭合子图问题, 最大收益转为总收益减去最小割. $S$连黑点和黑需求, 白点和白需求连$T$, 再对每个需求关系连一下边即可.
#include <iostream> #include <cstdio> #include <queue> #define REP(i,a,n) for(int i=a;i<=n;++i) using namespace std; const int N = 1e6+10, S = N-2, T = N-1, INF = 0x3f3f3f3f; int n, m, g, a[N], b[N]; struct edge { int to,w,next; edge(int to=0,int w=0,int next=0):to(to),w(w),next(next){} } e[N]; int head[N], dep[N], vis[N], cur[N], cnt=1; queue<int> Q; void add(int u, int v, int w) { e[++cnt] = edge(v,w,head[u]); head[u] = cnt; e[++cnt] = edge(u,0,head[v]); head[v] = cnt; } int bfs() { REP(i,1,n+m) dep[i]=INF,vis[i]=0,cur[i]=head[i]; dep[S]=INF,vis[S]=0,cur[S]=head[S]; dep[T]=INF,vis[T]=0,cur[T]=head[T]; dep[S]=0,Q.push(S); while (Q.size()) { int u = Q.front(); Q.pop(); for (int i=head[u]; i; i=e[i].next) { if (dep[e[i].to]>dep[u]+1&&e[i].w) { dep[e[i].to]=dep[u]+1; Q.push(e[i].to); } } } return dep[T]!=INF; } int dfs(int x, int w) { if (x==T) return w; int used = 0; for (int i=cur[x]; i; i=e[i].next) { cur[x] = i; if (dep[e[i].to]==dep[x]+1&&e[i].w) { int f = dfs(e[i].to,min(w-used,e[i].w)); if (f) used+=f,e[i].w-=f,e[i^1].w+=f; if (used==w) break; } } return used; } int dinic() { int ans = 0; while (bfs()) ans+=dfs(S,INF); return ans; } int main() { scanf("%d%d%d", &n, &m, &g); REP(i,1,n) scanf("%d",a+i); REP(i,1,n) scanf("%d",b+i); REP(i,1,n) { if (a[i]) add(S,i,b[i]); else add(i,T,b[i]); } int sum = 0; REP(i,1,m) { int c,w,k,t,f; scanf("%d%d%d",&c,&w,&k); sum += w; while (k--) { scanf("%d", &t); if (c) add(i+n,t,INF); else add(t,i+n,INF); } scanf("%d", &f); if (f) f = g; if (c) add(S,i+n,f+w); else add(i+n,T,f+w); } printf("%d ",sum-dinic()); }
7. 316C
大意: 给定$n*m$矩阵, $n*m$为偶数, $[1,frac{nm}{2}]$每个数均出现$2$次, 求最少交换数使得相同数字相邻.
二分图最佳完美匹配, 每个点向相邻格子连边, 同色连费用0, 异色连费用1, 求出费用最小的完美匹配即为答案
#include <iostream> #include <queue> #define REP(i,a,b) for(int i=a;i<=b;++i) using namespace std; const int N = 1e6+10, S = N-2, T = N-1, INF = 0x3f3f3f3f; int n, m, flow, cost; struct edge { int to,w,v,next; edge(int to=0,int w=0,int v=0,int next=0):to(to),v(v),w(w),next(next){} } e[N]; int head[N], dep[N], vis[N], cur[N], f[N], cnt=1; pair<int,int> pre[N]; queue<int> Q; void add(int u, int v, int w, int k) { e[++cnt] = edge(v,w,k,head[u]); head[u] = cnt; e[++cnt] = edge(u,0,-k,head[v]); head[v] = cnt; } int spfa() { REP(i,1,n*m) f[i]=dep[i]=INF,vis[i]=0; f[S]=dep[S]=f[T]=dep[T]=INF; dep[S]=0,Q.push(S); while (Q.size()) { int u = Q.front(); Q.pop(); vis[u] = 0; for (int i=head[u]; i; i=e[i].next) { if (dep[e[i].to]>dep[u]+e[i].v&&e[i].w) { dep[e[i].to]=dep[u]+e[i].v; pre[e[i].to]=pair<int,int>(u,i); f[e[i].to]=min(f[u],e[i].w); if (!vis[e[i].to]) { vis[e[i].to]=1; Q.push(e[i].to); } } } } return dep[T]!=INF; } int dfs(int x, int w) { if (x==T) return w; int used = 0; for (int i=cur[x]; i; i=e[i].next) { cur[x] = i; if (dep[e[i].to]==dep[x]+1&&e[i].w) { int f = dfs(e[i].to,min(w-used,e[i].w)); if (f) used+=f,e[i].w-=f,e[i^1].w+=f; if (used==w) break; } } return used; } void EK(){ while(spfa()) { int w = f[T]; for (int u=T; u!=S; u=pre[u].first) { e[pre[u].second].w-=w; e[pre[u].second^1].w+=w; } flow += w, cost += w*dep[T]; } } int a[99][99]; const int dx[]={0,0,-1,1}; const int dy[]={-1,1,0,0}; int ID(int x, int y) { return (x-1)*m+y; } int main() { scanf("%d%d", &n, &m); REP(i,1,n) REP(j,1,m) scanf("%d",a[i]+j); REP(i,1,n) REP(j,1,m) { if (i!=n) { int x=ID(i,j),y=ID(i+1,j); if (i+j&1) swap(x,y); add(x,y,1,a[i][j]!=a[i+1][j]); } if (j!=m) { int x=ID(i,j),y=ID(i,j+1); if (i+j&1) swap(x,y); add(x,y,1,a[i][j]!=a[i][j+1]); } if (i+j&1) add(ID(i,j),T,1,0); else add(S,ID(i,j),1,0); } EK(); printf("%d ",cost); }
8. 321B
大意: 对手$n$只怪, 你有$m$只怪, 现在是你的回合. 对面怪全有嘲讽, 分为攻击怪和防御怪. 若你攻击对面攻击怪, 要满足你怪的能力不少于对面, 攻击后对面怪死亡, 对英雄伤害为能力差. 若你攻击对面防御怪, 要满足你怪的能力大于对面, 攻击后对面怪死亡, 对英雄伤害$0$. 若对面没怪可以直接攻击对面英雄, 伤害为你的怪的能力值. 求英雄造成的最大伤害.
不攻击英雄的情况贪心判掉. 攻击英雄的情况, 显然是一个最大带权匹配问题, 用费用流或者$KM$即可.
#include <iostream> #include <cstdio> #include <queue> #define REP(i,a,n) for(int i=a;i<=n;++i) using namespace std; const int N = 1e6+10, INF = 0x3f3f3f3f, S = N-2, T = N-1; int n, m, flow, cost; struct edge { int to,w,v,next; edge(int to=0,int w=0,int v=0,int next=0):to(to),w(w),v(v),next(next){} } e[N]; int head[N], dep[N], vis[N], cur[N], f[N], cnt=1; int pre[N],pre2[N]; queue<int> Q; void add(int u, int v, int w, int k) { e[++cnt] = edge(v,w,k,head[u]); head[u] = cnt; e[++cnt] = edge(u,0,-k,head[v]); head[v] = cnt; } int spfa() { REP(i,1,n+m) f[i]=dep[i]=INF,vis[i]=0; f[S]=dep[S]=f[T]=dep[T]=INF; dep[S]=0,Q.push(S); while (Q.size()) { int u = Q.front(); Q.pop(); vis[u] = 0; for (int i=head[u]; i; i=e[i].next) { if (dep[e[i].to]>dep[u]+e[i].v&&e[i].w) { dep[e[i].to]=dep[u]+e[i].v; pre[e[i].to]=u,pre2[e[i].to]=i; f[e[i].to]=min(f[u],e[i].w); if (!vis[e[i].to]) { vis[e[i].to]=1; Q.push(e[i].to); } } } } return dep[T]!=INF; } void EK(){ while(spfa()) { int w = f[T]; for (int u=T; u!=S; u=pre[u]) { e[pre2[u]].w-=w; e[pre2[u]^1].w+=w; } flow += w, cost += w*dep[T]; } } int a[N], b[N], c[N]; char s[110][10]; int main() { scanf("%d%d", &n, &m); REP(i,1,n) scanf("%s%d",s[i],a+i); int sum = 0; REP(i,1,m) scanf("%d",b+i),sum+=b[i]; REP(i,1,m) add(S,i,1,0); REP(i,1,n) add(i+m,T,1,0); REP(i,1,m) REP(j,1,n) { if (s[j][0]=='A') { if (b[i]>=a[j]) add(i,j+m,1,a[j]); else add(i,j+m,1,1e6); } else { if (b[i]>a[j]) add(i,j+m,1,b[i]); else add(i,j+m,1,1e6); } } EK(); int ans = sum-cost; REP(i,1,n) if (s[i][0]=='A') c[++*c]=a[i]; sort(b+1,b+1+m,greater<int>()); sort(c+1,c+1+*c); int ret = 0; REP(i,1,min(m,*c)) ret += max(0,b[i]-c[i]); printf("%d ",max(ans,ret)); }
9. 343E
最小割树
10. 362E
大意: 给定$n$个点的网络图, 每次操作选一条边流量$+1$, 最多$k$次, 求最大流.
先求一次最大流, 然后对残量网络上每条边加一条容量$k$, 费用为$1$的边, 再跑一次费用流, 当费用达到$k$时停止.
#include <iostream> #include <cstdio> #include <queue> #define REP(i,a,n) for(int i=a;i<=n;++i) using namespace std; typedef pair<int,int> pii; const int N = 5e4+10,INF=0x3f3f3f3f; int n,m,cost,flow,S,T; struct edge { int to,next,w,v; edge(int to=0,int next=0,int w=0,int v=0):to(to),next(next),w(w),v(v){} } e[N]; int head[N],dep[N],vis[N],f[N],cnt=1; pii pre[N]; queue<int> Q; int spfa() { REP(i,1,n) f[i]=dep[i]=INF,vis[i]=0; dep[S]=0,Q.push(S); while (Q.size()) { int u = Q.front(); Q.pop(); vis[u] = 0; for (int i=head[u]; i; i=e[i].next) { if (e[i].w&&dep[e[i].to]>dep[u]+e[i].v) { dep[e[i].to]=dep[u]+e[i].v; pre[e[i].to]=pii(u,i); f[e[i].to]=min(f[u],e[i].w); if (!vis[e[i].to]) { vis[e[i].to]=1; Q.push(e[i].to); } } } } return cost+dep[T]<=m; } void EK(){ while(spfa()) { int w = f[T]; if (cost+(long long)w*dep[T]>m) w = (m-cost)/dep[T]; for (int u=T; u!=S; u=pre[u].first) { e[pre[u].second].w-=w; e[pre[u].second^1].w+=w; } flow += w, cost += w*dep[T]; } } void add(int x,int y,int k,int v) { e[++cnt] = edge(y,head[x],k,v); head[x] = cnt; e[++cnt] = edge(x,head[y],0,-v); head[y] = cnt; } int a[66][66]; int main() { scanf("%d%d", &n, &m); S=1,T=n; REP(i,1,n) REP(j,1,n) { scanf("%d", a[i]+j); if (a[i][j]) add(i,j,a[i][j],0); } EK(); REP(i,1,n) REP(j,1,n) { if (a[i][j]) add(i,j,m,1); } EK(); printf("%d ", flow); }
11. 434D
大意: $n$个数, 范围$[l,r]$, 第$i$个数若选$x$则有贡献$a_ix^2+b_ix+c$, 有$m$个限制$(u,v,d)$, 表示$x_ule x_v+d$, 求贡献最大值.
最小割经典应用, 建图可以参照[HNOI2013]切糕. 本题是要求最大值, 流量取相反数, 转为最小, 但是因为流量不能有负数, 再全部增加一个值, 转为正.
#include <iostream> #include <cstdio> #include <queue> #include <map> #define REP(i,a,n) for(int i=a;i<=n;++i) using namespace std; typedef pair<int,int> pii; const int N = 1e6+10, S = N-2, T = N-1, INF = 0x3f3f3f3f; int tot; map<pii,int> mp; int ID(int x, int y) { if (mp.count(pii(x,y))) return mp[pii(x,y)]; return mp[pii(x,y)] = ++tot; } struct edge { int to,w,next; edge(int to=0,int w=0,int next=0):to(to),w(w),next(next){} } e[N]; int head[N], dep[N], vis[N], cur[N], cnt=1; queue<int> Q; int bfs() { REP(i,1,tot) dep[i]=INF,vis[i]=0,cur[i]=head[i]; dep[S]=INF,vis[S]=0,cur[S]=head[S]; dep[T]=INF,vis[T]=0,cur[T]=head[T]; dep[S]=0,Q.push(S); while (Q.size()) { int u = Q.front(); Q.pop(); for (int i=head[u]; i; i=e[i].next) { if (dep[e[i].to]>dep[u]+1&&e[i].w) { dep[e[i].to]=dep[u]+1; Q.push(e[i].to); } } } return dep[T]!=INF; } int dfs(int x, int w) { if (x==T) return w; int used = 0; for (int i=cur[x]; i; i=e[i].next) { cur[x] = i; if (dep[e[i].to]==dep[x]+1&&e[i].w) { int f = dfs(e[i].to,min(w-used,e[i].w)); if (f) used+=f,e[i].w-=f,e[i^1].w+=f; if (used==w) break; } } return used; } int dinic() { int ans = 0; while (bfs()) ans+=dfs(S,INF); return ans; } void add(int u, int v, int w) { e[++cnt] = edge(v,w,head[u]); head[u] = cnt; e[++cnt] = edge(u,0,head[v]); head[v] = cnt; } int n,m,a[N],b[N],c[N],l[N],r[N]; int f(int i, int x) { return a[i]*x*x+b[i]*x+c[i]; } int main() { scanf("%d%d", &n, &m); REP(i,1,n) scanf("%d%d%d",a+i,b+i,c+i); int ma = -1e9; REP(i,1,n) { scanf("%d%d", l+i, r+i); REP(j,l[i],r[i]) ma=max(ma,f(i,j)); } REP(i,1,n) { --l[i],++r[i]; add(S,ID(i,l[i]),INF); REP(j,l[i]+1,r[i]-1) add(ID(i,j-1),ID(i,j),-f(i,j)); add(ID(i,r[i]-1),ID(i,r[i]),INF),add(ID(i,r[i]),T,INF); } REP(i,1,m) { int u,v,d; scanf("%d%d%d",&u,&v,&d); REP(j,l[v],r[v]) { int k = j+d; if (l[u]<=k&&k<=r[u]) { add(ID(u,k),ID(v,j),INF); } } } printf("%d ", -dinic()); }
12. 491C
大意:给定两个长为$n$的串, 求改变第一个字符串的字母映射关系, 使得两个串对应位置相等的个数最大.
裸的最大带权匹配.
#include <iostream> #include <cstdio> #include <queue> #include <map> #define REP(i,a,n) for(int i=a;i<=n;++i) using namespace std; const int N = 2e6+10, INF = 0x3f3f3f3f, S = N-2, T = N-1; int flow, cost, k, n; struct edge { int to,w,v,next; edge(int to=0,int w=0,int v=0,int next=0):to(to),w(w),v(v),next(next){} } e[N]; int head[N], dep[N], vis[N], cur[N], f[N], cnt=1; int pre[N],pre2[N]; queue<int> Q; int spfa() { REP(i,1,2*k) f[i]=dep[i]=INF,vis[i]=0; f[S]=dep[S]=f[T]=dep[T]=INF; dep[S]=0,Q.push(S); while (Q.size()) { int u = Q.front(); Q.pop(); vis[u] = 0; for (int i=head[u]; i; i=e[i].next) { if (dep[e[i].to]>dep[u]+e[i].v&&e[i].w) { dep[e[i].to]=dep[u]+e[i].v; pre[e[i].to]=u,pre2[e[i].to]=i; f[e[i].to]=min(f[u],e[i].w); if (!vis[e[i].to]) { vis[e[i].to]=1; Q.push(e[i].to); } } } } return dep[T]!=INF; } void EK(){ while(spfa()) { int w = f[T]; for (int u=T; u!=S; u=pre[u]) { e[pre2[u]].w-=w; e[pre2[u]^1].w+=w; } flow += w, cost += w*dep[T]; } } void add(int u, int v, int w, int k) { e[++cnt] = edge(v,w,k,head[u]); head[u] = cnt; e[++cnt] = edge(u,0,-k,head[v]); head[v] = cnt; } int a[111][111],b[111][111],ans[N],ID[N]; char s[N],ss[N],t[N],val[N]; int main() { scanf("%d%d", &n, &k); REP(i,1,min(26,k)) ID[val[i]=i-1+'a']=i; REP(i,27,k) ID[val[i]=i-27+'A']=i; scanf("%s%s",s+1,ss+1); REP(i,1,n) ++a[ID[s[i]]][ID[ss[i]]]; REP(i,1,k) add(S,i,1,0),add(i+k,T,1,0); REP(i,1,k) REP(j,1,k) b[i][j]=cnt+1,add(i,j+k,1,-a[i][j]); EK(); printf("%d ", -cost); REP(i,1,k) REP(j,1,k) if (!e[b[i][j]].w) ans[i]=val[j]; REP(i,1,k) putchar(ans[i]);puts(""); }
13. 498C
大意: 给定序列$a$, $m$个二元组$(x,y)$, 保证$x+y$为奇数, 每次操作任选一个二元组$(x,y)$, 选择一个$k>1$, 且$k$能整除$a_x$和$a_y$, 然后将$a_x,a_y$除以$k$, 求最多进行多少次操作.
裸的最大流.
#include <iostream> #include <cstdio> #include <cmath> #include <map> #include <queue> #define REP(i,a,n) for(int i=a;i<=n;++i) #define x first #define y second using namespace std; typedef pair<int,int> pii; inline int rd() {int x=0;char p=getchar();while(p<'0'||p>'9')p=getchar();while(p>='0'&&p<='9')x=x*10+p-'0',p=getchar();return x;} const int N = 1e6+10, S = N-2, T = N-1, INF = 0x3f3f3f3f; int n,m,tot; struct edge { int to,w,next; edge(int to=0,int w=0,int next=0):to(to),w(w),next(next){} } e[N]; int head[N], dep[N], vis[N], cur[N], cnt=1; queue<int> Q; int bfs() { REP(i,1,tot) dep[i]=INF,vis[i]=0,cur[i]=head[i]; dep[S]=INF,vis[S]=0,cur[S]=head[S]; dep[T]=INF,vis[T]=0,cur[T]=head[T]; dep[S]=0,Q.push(S); while (Q.size()) { int u = Q.front(); Q.pop(); for (int i=head[u]; i; i=e[i].next) { if (dep[e[i].to]>dep[u]+1&&e[i].w) { dep[e[i].to]=dep[u]+1; Q.push(e[i].to); } } } return dep[T]!=INF; } int dfs(int x, int w) { if (x==T) return w; int used = 0; for (int i=cur[x]; i; i=e[i].next) { cur[x] = i; if (dep[e[i].to]==dep[x]+1&&e[i].w) { int f = dfs(e[i].to,min(w-used,e[i].w)); if (f) used+=f,e[i].w-=f,e[i^1].w+=f; if (used==w) break; } } return used; } int dinic() { int ans = 0; while (bfs()) ans+=dfs(S,INF); return ans; } void add(int u, int v, int w) { e[++cnt] = edge(v,w,head[u]); head[u] = cnt; e[++cnt] = edge(u,0,head[v]); head[v] = cnt; } map<int,int> f[N]; map<pii,int> mp; int ID(int x, int y) { if (mp.count(pii(x,y))) return mp[pii(x,y)]; return mp[pii(x,y)] = ++tot; } map<int,int> fac(int x) { int mx = sqrt(x+0.5); map<int,int> v; REP(i,2,mx) { while (x%i==0) x/=i,++v[i]; } if (x>1) ++v[x]; return v; } int main() { scanf("%d%d", &n, &m); REP(i,1,n) { f[i]=fac(rd()); if (i&1) for (auto t:f[i]) add(ID(i,t.x),T,t.y); else for (auto t:f[i]) add(S,ID(i,t.x),t.y); } REP(i,1,m) { int u=rd(),v=rd(); if (u&1) swap(u,v); for (auto t:f[u]) { if (f[v].count(t.x)) add(ID(u,t.x),ID(v,t.x),INF); } } printf("%d ", dinic()); }
14. 510E
大意: n只狐狸, 要求分成若干个环, 每个环的狐狸不少于三只, 相邻狐狸年龄和为素数.
年龄大于$1$, 那么两个数和为素数必然是一奇一偶, 奇偶分开建图跑最大流即可.
#include <iostream> #include <cstdio> #include <cmath> #include <map> #include <queue> #define REP(i,a,n) for(int i=a;i<=n;++i) #define pb push_back #define x first #define y second using namespace std; typedef pair<int,int> pii; inline int rd() {int x=0;char p=getchar();while(p<'0'||p>'9')p=getchar();while(p>='0'&&p<='9')x=x*10+p-'0',p=getchar();return x;} const int N = 1e6+10, S = N-2, T = N-1, INF = 0x3f3f3f3f; int n; struct edge { int to,w,next; edge(int to=0,int w=0,int next=0):to(to),w(w),next(next){} } e[N]; int head[N], dep[N], vis[N], cur[N], cnt=1; queue<int> Q; int bfs() { REP(i,1,n) dep[i]=INF,vis[i]=0,cur[i]=head[i]; dep[S]=INF,vis[S]=0,cur[S]=head[S]; dep[T]=INF,vis[T]=0,cur[T]=head[T]; dep[S]=0,Q.push(S); while (Q.size()) { int u = Q.front(); Q.pop(); for (int i=head[u]; i; i=e[i].next) { if (dep[e[i].to]>dep[u]+1&&e[i].w) { dep[e[i].to]=dep[u]+1; Q.push(e[i].to); } } } return dep[T]!=INF; } int dfs(int x, int w) { if (x==T) return w; int used = 0; for (int i=cur[x]; i; i=e[i].next) { cur[x] = i; if (dep[e[i].to]==dep[x]+1&&e[i].w) { int f = dfs(e[i].to,min(w-used,e[i].w)); if (f) used+=f,e[i].w-=f,e[i^1].w+=f; if (used==w) break; } } return used; } int dinic() { int ans = 0; while (bfs()) ans+=dfs(S,INF); return ans; } void add(int u, int v, int w) { e[++cnt] = edge(v,w,head[u]); head[u] = cnt; e[++cnt] = edge(u,0,head[v]); head[v] = cnt; } int f[N],a[N]; vector<int> g[N],ans[N]; void seive(int n) { int mx = sqrt(n+0.5); REP(i,2,mx) if (!f[i]) { for (int j=i*i; j<=n; j+=i) f[j] = 1; } } int main() { seive(20100); scanf("%d", &n); REP(i,1,n) { if ((a[i]=rd())&1) add(S,i,2); else add(i,T,2); } REP(i,1,n) if (a[i]&1) REP(j,1,n) if (a[j]&1^1) { if (!f[a[i]+a[j]]) add(i,j,1); } if (dinic()!=n) return puts("Impossible"),0; REP(i,1,n) if (a[i]&1) { for (int t=head[i]; t; t=e[t].next) { if (!e[t].w&&e[t].to<=n) { g[i].pb(e[t].to); g[e[t].to].pb(i); } } } REP(i,1,n) vis[i] = 0; int cnt = 0; REP(i,1,n) if (!vis[i]) { ++cnt; int j = i; while (1) { vis[j] = 1; ans[cnt].pb(j); if (vis[g[j][0]]&&vis[g[j][1]]) break; if (vis[g[j][0]]) j=g[j][1]; else j=g[j][0]; } } printf("%d ", cnt); REP(i,1,cnt) { printf("%d ", (int)ans[i].size()); for (int j:ans[i]) printf("%d ",j); puts(""); } }
15. 513F
大意: $n*m$的矩阵, 每个格子能住两个人, 给定每个人的位置以及移动速度, 求最短多少时间, 能使所有人都和一个异性分到一个房间.
二分答案, 建图, 看最大流是否满流.
#include <iostream> #include <cstdio> #include <queue> #include <string.h> #define REP(i,a,n) for(int i=a;i<=n;++i) using namespace std; typedef long long ll; const int N = 1e6+10, S = N-2, T = N-1, INF = 0x3f3f3f3f; struct edge { int to,w,next; edge(int to=0,int w=0,int next=0):to(to),w(w),next(next){} } e[N]; int head[N], dep[N], vis[N], cur[N], cnt=1; queue<int> Q; int bfs(int n) { REP(i,1,n) dep[i]=INF,vis[i]=0,cur[i]=head[i]; dep[S]=INF,vis[S]=0,cur[S]=head[S]; dep[T]=INF,vis[T]=0,cur[T]=head[T]; dep[S]=0,Q.push(S); while (Q.size()) { int u = Q.front(); Q.pop(); for (int i=head[u]; i; i=e[i].next) { if (dep[e[i].to]>dep[u]+1&&e[i].w) { dep[e[i].to]=dep[u]+1; Q.push(e[i].to); } } } return dep[T]!=INF; } int dfs(int x, int w) { if (x==T) return w; int used = 0; for (int i=cur[x]; i; i=e[i].next) { cur[x] = i; if (dep[e[i].to]==dep[x]+1&&e[i].w) { int f = dfs(e[i].to,min(w-used,e[i].w)); if (f) used+=f,e[i].w-=f,e[i^1].w+=f; if (used==w) break; } } return used; } int dinic(int n) { int ans = 0; while (bfs(n)) ans+=dfs(S,INF); return ans; } void add(int u, int v, int w) { e[++cnt] = edge(v,w,head[u]); head[u] = cnt; e[++cnt] = edge(u,0,head[v]); head[v] = cnt; } int n,m,x,y; struct _ {int x,y,t;} h, a[N], b[N]; char s[33][33]; int v[33][33]; int ID(int x, int y) { return (x-1)*m+y; } const int dx[]={0,0,-1,1}; const int dy[]={-1,1,0,0}; int chk(ll tot) { cnt = 1; REP(i,1,2*x+2*n*m) head[i]=0; head[S]=head[T]=0; queue<_> q; REP(i,1,x) { add(S,i,1); q.push({a[i].x,a[i].y,0}); memset(v,0,sizeof v); while (q.size()) { _ u = q.front(); q.pop(); if (s[u.x][u.y]=='#'||v[u.x][u.y]) continue; if (a[i].t&&u.t>tot/a[i].t) continue; v[u.x][u.y] = 1; REP(k,0,3) { int xx=u.x+dx[k],yy=u.y+dy[k]; if (1<=xx&&xx<=n&&1<=yy&&yy<=m) { q.push({xx,yy,u.t+1}); } } } REP(j,1,n) REP(k,1,m) if (v[j][k]) add(i,ID(j,k)+2*x,1); } REP(i,1,x) { add(i+x,T,1); q.push({b[i].x,b[i].y,0}); memset(v,0,sizeof v); while (q.size()) { _ u = q.front(); q.pop(); if (s[u.x][u.y]=='#'||v[u.x][u.y]) continue; if (b[i].t&&u.t>tot/b[i].t) continue; v[u.x][u.y] = 1; REP(k,0,3) { int xx=u.x+dx[k],yy=u.y+dy[k]; if (1<=xx&&xx<=n&&1<=yy&&yy<=m) { q.push({xx,yy,u.t+1}); } } } REP(j,1,n) REP(k,1,m) if (v[j][k]) add(ID(j,k)+2*x+n*m,i+x,1); } REP(i,1,n) REP(j,1,m) if (s[i][j]!='#') add(ID(i,j)+2*x,ID(i,j)+2*x+n*m,1); return dinic(2*x+2*n*m)==x; } int main() { scanf("%d%d%d%d", &n, &m, &x, &y); if (abs(x-y)!=1) return puts("-1"),0; REP(i,1,n) scanf("%s",s[i]+1); scanf("%d%d%d",&h.x,&h.y,&h.t); REP(i,1,x) scanf("%d%d%d",&a[i].x,&a[i].y,&a[i].t); REP(i,1,y) scanf("%d%d%d",&b[i].x,&b[i].y,&b[i].t); if (x>y) b[++y]=h; else a[++x]=h; ll l=0,r=1e18,ans=-1; while (l<=r) { ll mid = (l+r)/2; if (chk(mid)) ans=mid,r=mid-1; else l=mid+1; } printf("%lld ", ans); }
16. 546E
大意: 给定无向图, 点$i$有$a_i$个士兵, 士兵只能移动不超过$1$, 求是否能使点$i$有$b_i$个士兵.
每个点拆成入点和出点, $S$连入点, 出点连$T$, 入点连接所有距离不超过$1$的出点, 判断能否满流即可.
#include <iostream> #include <cstdio> #include <queue> #define REP(i,a,n) for(int i=a;i<=n;++i) using namespace std; const int N = 1e6+10, S = N-2, T = N-1, INF = 0x3f3f3f3f; int n, m, s1, s2, ans[111][111]; struct edge { int to,w,next; edge(int to=0,int w=0,int next=0):to(to),w(w),next(next){} } e[N]; int head[N], dep[N], vis[N], cur[N], cnt=1; queue<int> Q; int bfs() { REP(i,1,2*n) dep[i]=INF,vis[i]=0,cur[i]=head[i]; dep[S]=INF,vis[S]=0,cur[S]=head[S]; dep[T]=INF,vis[T]=0,cur[T]=head[T]; dep[S]=0,Q.push(S); while (Q.size()) { int u = Q.front(); Q.pop(); for (int i=head[u]; i; i=e[i].next) { if (dep[e[i].to]>dep[u]+1&&e[i].w) { dep[e[i].to]=dep[u]+1; Q.push(e[i].to); } } } return dep[T]!=INF; } int dfs(int x, int w) { if (x==T) return w; int used = 0; for (int i=cur[x]; i; i=e[i].next) { cur[x] = i; if (dep[e[i].to]==dep[x]+1&&e[i].w) { int f = dfs(e[i].to,min(w-used,e[i].w)); if (f) used+=f,e[i].w-=f,e[i^1].w+=f; if (used==w) break; } } return used; } int dinic() { int ans = 0; while (bfs()) ans+=dfs(S,INF); return ans; } void add(int u, int v, int w) { e[++cnt] = edge(v,w,head[u]); head[u] = cnt; e[++cnt] = edge(u,0,head[v]); head[v] = cnt; } int main() { scanf("%d%d", &n, &m); REP(i,1,n) { int t; scanf("%d", &t); s1 += t; add(S,i,t),add(i,i+n,INF); } REP(i,1,n) { int t; scanf("%d", &t); s2 += t; add(i+n,T,t); } while (m--) { int u, v; scanf("%d%d", &u, &v); add(u,v+n,INF),add(v,u+n,INF); } if (s1!=s2||dinic()!=s1) return puts("NO"),0; puts("YES"); REP(i,1,n) { for (int j=head[i]; j; j=e[j].next) { if (1<=e[j].to-n&&e[j].to-n<=n) ans[i][e[j].to-n] = e[j^1].w; } } REP(i,1,n) { REP(j,1,n) printf("%d ",ans[i][j]); puts(""); } }
17. 611H
18. 628F
大意: $n$元素集合, $n$被$5$整除, 模$5$后每种余数个数相同, 每个数范围在$[1,b]$内. 有$q$个限制$(x,y)$, 要求在$[1,x]$中恰好有$y$个数. 求是否能构造出该集合.
$q$个限制可以做一下差, 转化为$q$个不相交的区间$[l,r]$内恰有$y$个数, 然后就是很简单的建图了, 看能否满流即可.
#include <iostream> #include <cstdio> #include <queue> #define REP(i,a,n) for(int i=a;i<=n;++i) using namespace std; const int N = 1e6+10, S = N-2, T = N-1, INF = 0x3f3f3f3f; int n, b, q, a[N]; struct edge { int to,w,next; edge(int to=0,int w=0,int next=0):to(to),w(w),next(next){} } e[N]; int head[N], dep[N], vis[N], cur[N], cnt=1; queue<int> Q; int bfs() { REP(i,1,2*b+10) dep[i]=INF,vis[i]=0,cur[i]=head[i]; dep[S]=INF,vis[S]=0,cur[S]=head[S]; dep[T]=INF,vis[T]=0,cur[T]=head[T]; dep[S]=0,Q.push(S); while (Q.size()) { int u = Q.front(); Q.pop(); for (int i=head[u]; i; i=e[i].next) { if (dep[e[i].to]>dep[u]+1&&e[i].w) { dep[e[i].to]=dep[u]+1; Q.push(e[i].to); } } } return dep[T]!=INF; } int dfs(int x, int w) { if (x==T) return w; int used = 0; for (int i=cur[x]; i; i=e[i].next) { cur[x] = i; if (dep[e[i].to]==dep[x]+1&&e[i].w) { int f = dfs(e[i].to,min(w-used,e[i].w)); if (f) used+=f,e[i].w-=f,e[i^1].w+=f; if (used==w) break; } } return used; } int dinic() { int ans = 0; while (bfs()) ans+=dfs(S,INF); return ans; } void add(int u, int v, int w) { e[++cnt] = edge(v,w,head[u]); head[u] = cnt; e[++cnt] = edge(u,0,head[v]); head[v] = cnt; } int main() { scanf("%d%d%d", &n, &b, &q); REP(i,1,b) { a[i] = -1; add(i,2*b+1+i%5,1); } REP(i,1,5) add(2*b+1+i%5,T,n/5); REP(i,1,q) { int x, y; scanf("%d%d", &x, &y); if (a[x]!=-1&&a[x]!=y) return puts("unfair"),0; a[x] = y; } if (a[b]!=-1&&a[b]!=n) return puts("unfair"),0; a[b] = n; int tot = 0, pre = 0; REP(i,1,b) if (a[i]!=-1) { if (a[i]<tot) return puts("unfair"),0; if (a[i]!=tot) { add(S,i+b,a[i]-tot); REP(j,pre+1,i) add(i+b,j,1); } tot = a[i], pre = i; } puts(dinic()==n?"fair":"unfair"); }
19. 653D
大意: 给定有向图, 有$x$只熊, 每只熊重量相同, 从节点$1$走到节点$n$, 每条路经过熊的总重量不能超过边权, 求每只熊重量最大值.
裸的最大流.
#include <iostream> #include <cmath> #include <cstdio> #include <queue> #define REP(i,a,n) for(int i=a;i<=n;++i) using namespace std; typedef long long ll; const double eps = 1e-8; const int N = 1e6+10, INF = 0x3f3f3f3f; int n, m, x, S, T; int a[N],b[N],c[N]; struct edge { int to; ll w; int next; edge(int to=0,ll w=0,int next=0):to(to),w(w),next(next){} } e[N]; int head[N], dep[N], vis[N], cur[N], cnt=1; queue<int> Q; int bfs() { REP(i,1,n) dep[i]=INF,vis[i]=0,cur[i]=head[i]; dep[S]=0,Q.push(S); while (Q.size()) { int u = Q.front(); Q.pop(); for (int i=head[u]; i; i=e[i].next) { if (dep[e[i].to]>dep[u]+1&&e[i].w) { dep[e[i].to]=dep[u]+1; Q.push(e[i].to); } } } return dep[T]!=INF; } ll dfs(int x, ll w) { if (x==T) return w; ll used = 0; for (int i=cur[x]; i; i=e[i].next) { cur[x] = i; if (dep[e[i].to]==dep[x]+1&&e[i].w) { int f = dfs(e[i].to,min(w-used,e[i].w)); if (f) used+=f,e[i].w-=f,e[i^1].w+=f; if (used==w) break; } } return used; } ll dinic() { ll ans = 0; while (bfs()) ans+=dfs(S,1e15); return ans; } void add(int u, int v, ll w) { e[++cnt] = edge(v,w,head[u]); head[u] = cnt; e[++cnt] = edge(u,0,head[v]); head[v] = cnt; } int chk(double w) { w /= x; if (fabs(w)<=eps) return 1; cnt = 1, S = 1, T = n; REP(i,1,n) head[i] = 0; REP(i,1,m) add(a[i],b[i],c[i]/w); return dinic()>=x; } int main() { scanf("%d%d%d", &n, &m, &x); REP(i,1,m) scanf("%d%d%d",a+i,b+i,c+i); double l=0,r=1e11,ans; REP(i,1,100) { double mid=(l+r)/2; if (chk(mid)) ans=mid,l=mid+eps; else r=mid-eps; } printf("%.10000lf ", ans); }
20. 704D
大意: 给定平面上$n$个点, 每个点染为红色花费$r$, 蓝色花费$b$. 给定$m$个限制$(t,l,d)$, $t$为$1$表示直线$x=l$上红蓝点差不超过$d$, 否则是$y=l$上红蓝点差不超过$d$, 求最少花费.
21. 708D
22. 717G
大意: 给定一个串$s$, $n$个模式串, 模式串与主串匹配可以获得一定权值, 主串每个位置最多匹配$x$个模式串, 求最大权值.
裸的最长$k$重区间集, 费用流跑一下即可.
#include <iostream> #include <string.h> #include <cstdio> #include <queue> #define REP(i,a,n) for(int i=a;i<=n;++i) using namespace std; const int N = 1e6+10, INF = 0x3f3f3f3f, S = N-2, T = N-1; int flow, cost; int n,m,x,w[N]; char s[510],p[110][510]; struct edge { int to,w,v,next; edge(int to=0,int w=0,int v=0,int next=0):to(to),w(w),v(v),next(next){} } e[N]; int head[N], dep[N], vis[N], cur[N], f[N], cnt=1; int pre[N],pre2[N]; queue<int> Q; int spfa() { REP(i,1,n+1) f[i]=dep[i]=INF,vis[i]=0; f[S]=dep[S]=f[T]=dep[T]=INF; dep[S]=0,Q.push(S); while (Q.size()) { int u = Q.front(); Q.pop(); vis[u] = 0; for (int i=head[u]; i; i=e[i].next) { if (dep[e[i].to]>dep[u]+e[i].v&&e[i].w) { dep[e[i].to]=dep[u]+e[i].v; pre[e[i].to]=u,pre2[e[i].to]=i; f[e[i].to]=min(f[u],e[i].w); if (!vis[e[i].to]) { vis[e[i].to]=1; Q.push(e[i].to); } } } } return dep[T]!=INF; } void EK(){ while(spfa()) { int w = f[T]; for (int u=T; u!=S; u=pre[u]) { e[pre2[u]].w-=w; e[pre2[u]^1].w+=w; } flow += w, cost += w*dep[T]; } } void add(int u, int v, int w, int k) { e[++cnt] = edge(v,w,k,head[u]); head[u] = cnt; e[++cnt] = edge(u,0,-k,head[v]); head[v] = cnt; } int main() { scanf("%d%s",&n,s); scanf("%d",&m); REP(i,1,m) scanf("%s%d",p[i],w+i); scanf("%d",&x); add(S,1,x,0); REP(i,1,n) add(i,i+1,x,0); add(n+1,T,x,0); REP(i,1,m) { int len = strlen(p[i]); REP(j,0,n-1) { if (strncmp(s+j,p[i],len)==0) add(j+1,j+1+len,1,-w[i]); } } EK(); printf("%d ",-cost); }
23. 720B
大意: 给定一个边仙人掌, 边有颜色, 求删除一些边, 使它变为树, 且剩余边颜色种类数最大.
非环边直接从$S$连向对应颜色, $S$向每个环连一条$size-1$的边, 每个环再向每种颜色对应连边, 每种颜色连向$T$, 求最大流即为答案.
#include <iostream> #include <cstdio> #include <queue> #define REP(i,a,n) for(int i=a;i<=n;++i) #define pb push_back using namespace std; const int N = 1e6+10; int n, m, tot, dep[N], vis[N], u[N], v[N], w[N]; struct _ {int to,w,id;} fa[N]; vector<_> g[N]; namespace Dinic { const int S = N-2, T = N-1, INF = 0x3f3f3f3f; struct edge { int to,w,next; edge(int to=0,int w=0,int next=0):to(to),w(w),next(next){} } e[N]; int head[N], dep[N], vis[N], cur[N], cnt=1; queue<int> Q; int bfs() { REP(i,1,tot) dep[i]=INF,vis[i]=0,cur[i]=head[i]; dep[S]=INF,vis[S]=0,cur[S]=head[S]; dep[T]=INF,vis[T]=0,cur[T]=head[T]; dep[S]=0,Q.push(S); while (Q.size()) { int u = Q.front(); Q.pop(); for (int i=head[u]; i; i=e[i].next) { if (dep[e[i].to]>dep[u]+1&&e[i].w) { dep[e[i].to]=dep[u]+1; Q.push(e[i].to); } } } return dep[T]!=INF; } int dfs(int x, int w) { if (x==T) return w; int used = 0; for (int i=cur[x]; i; i=e[i].next) { cur[x] = i; if (dep[e[i].to]==dep[x]+1&&e[i].w) { int f = dfs(e[i].to,min(w-used,e[i].w)); if (f) used+=f,e[i].w-=f,e[i^1].w+=f; if (used==w) break; } } return used; } int dinic() { int ans = 0; while (bfs()) ans+=dfs(S,INF); return ans; } void add(int u, int v, int w) { e[++cnt] = edge(v,w,head[u]); head[u] = cnt; e[++cnt] = edge(u,0,head[v]); head[v] = cnt; } } void get(int x, int y, _ e) { if (dep[x]<dep[y]) return; int sz = 0; for (int t=x; t!=y; t=fa[t].to) ++sz; Dinic::add(Dinic::S,++tot,sz); Dinic::add(tot,e.w,1), vis[e.id] = 1; for (int t=x; t!=y; t=fa[t].to) { Dinic::add(tot,fa[t].w,1), vis[fa[t].id] = 1; } } void dfs(int x, int f) { dep[x]=dep[f]+1; for (_ e:g[x]) if (e.to!=f) { int y = e.to; if (dep[y]) get(x,y,e); else fa[y]={x,e.w,e.id},dfs(y,x); } } int main() { scanf("%d%d", &n, &m), tot = m; REP(i,1,m) { scanf("%d%d%d", u+i, v+i, w+i); g[u[i]].pb({v[i],w[i],i}),g[v[i]].pb({u[i],w[i],i}); Dinic::add(i,Dinic::T,1); } dfs(1,0); REP(i,1,m) if (!vis[i]) Dinic::add(Dinic::S,w[i],1); printf("%d ", Dinic::dinic()); }
24. 723E
大意: 给定无向图, 无重边自环, 不保证连通, 要求把每条边定向, 使得入度等于出度的点最多.
25. 724E
大意: 给定有向图, 所有编号小的点与编号大的点间有一条有向边, 每条边流量均为$c$, 点$i$产出为$p_i$, 最多购入$s_i$, 求所有城市总购入量的最大值.
26. 727D
大意: $6$种衬衫, 每个人有两种或一种需求, 问是否能满足所有人的需求.
裸最大流
#include <iostream> #include <sstream> #include <cstdio> #include <map> #include <queue> #define REP(i,a,n) for(int i=a;i<=n;++i) using namespace std; const int N = 1e6+10, S = N-2, T = N-1, INF = 0x3f3f3f3f; int n; struct edge { int to,w,next; edge(int to=0,int w=0,int next=0):to(to),w(w),next(next){} } e[N]; int head[N], dep[N], vis[N], cur[N], cnt=1; queue<int> Q; int bfs() { REP(i,1,n) dep[i]=INF,vis[i]=0,cur[i]=head[i]; REP(i,S-6,T) dep[i]=INF,vis[i]=0,cur[i]=head[i]; dep[S]=0,Q.push(S); while (Q.size()) { int u = Q.front(); Q.pop(); for (int i=head[u]; i; i=e[i].next) { if (dep[e[i].to]>dep[u]+1&&e[i].w) { dep[e[i].to]=dep[u]+1; Q.push(e[i].to); } } } return dep[T]!=INF; } int dfs(int x, int w) { if (x==T) return w; int used = 0; for (int i=cur[x]; i; i=e[i].next) { cur[x] = i; if (dep[e[i].to]==dep[x]+1&&e[i].w) { int f = dfs(e[i].to,min(w-used,e[i].w)); if (f) used+=f,e[i].w-=f,e[i^1].w+=f; if (used==w) break; } } return used; } int dinic() { int ans = 0; while (bfs()) ans+=dfs(S,INF); return ans; } void add(int u, int v, int w) { e[++cnt] = edge(v,w,head[u]); head[u] = cnt; e[++cnt] = edge(u,0,head[v]); head[v] = cnt; } map<string,int> s; string val[N]; int now = S; int ID(string x) { if (s.count(x)) return s[x]; val[now-1] = x; return s[x] = --now; } int main() { ID("S"),ID("M"),ID("L"),ID("XL"),ID("XXL"),ID("XXXL"); REP(i,1,6) { int t; scanf("%d", &t); if (t) add(S-i,T,t); } scanf("%d", &n); REP(i,1,n) { string t; cin>>t; for (auto &c:t) if (c==',') c=' '; stringstream ss(t); while (ss>>t) add(i,ID(t),1); add(S,i,1); } if (dinic()!=n) return puts("NO"),0; puts("YES"); REP(i,1,n) { for (int j=head[i]; j; j=e[j].next) { if (!e[j].w) cout<<val[e[j].to]<<endl; } } }
27. 730I
大意: $n$个人, 选出$p$个人的编程组, $s$个人的运动组, 每个组价值为编程能力和或运动能力和, 求总能力和的最大值.
裸费用流. 数据范围比较大, 试了一下EK+spfa还是可过, 也可以用堆模拟费用流.
#include <iostream> #include <cstdio> #include <queue> #define REP(i,a,n) for(int i=a;i<=n;++i) using namespace std; const int N = 1e6+10, INF = 0x3f3f3f3f, S = N-2, T = N-1; int n, p, s, flow, cost; struct edge { int to,w,v,next; edge(int to=0,int w=0,int v=0,int next=0):to(to),w(w),v(v),next(next){} } e[N]; int head[N], dep[N], vis[N], cur[N], f[N], cnt=1; int pre[N],pre2[N]; vector<int> g[N]; queue<int> Q; int spfa() { REP(i,1,n) f[i]=dep[i]=INF,vis[i]=0; REP(i,S-2,T) f[i]=dep[i]=INF,vis[i]=0; dep[S]=0,Q.push(S); while (Q.size()) { int u = Q.front(); Q.pop(); vis[u] = 0; for (int i=head[u]; i; i=e[i].next) { if (dep[e[i].to]>dep[u]+e[i].v&&e[i].w) { dep[e[i].to]=dep[u]+e[i].v; pre[e[i].to]=u,pre2[e[i].to]=i; f[e[i].to]=min(f[u],e[i].w); if (!vis[e[i].to]) { vis[e[i].to]=1; Q.push(e[i].to); } } } } return dep[T]!=INF; } void EK(){ while(spfa()) { int w = f[T]; for (int u=T; u!=S; u=pre[u]) { e[pre2[u]].w-=w; e[pre2[u]^1].w+=w; } flow += w, cost += w*dep[T]; } } void add(int u, int v, int w, int k) { e[++cnt] = edge(v,w,k,head[u]); head[u] = cnt; e[++cnt] = edge(u,0,-k,head[v]); head[v] = cnt; } int main() { scanf("%d%d%d", &n, &p, &s); REP(i,1,n) { int t; scanf("%d", &t); add(S,i,1,0); add(i,S-1,1,-t); } REP(i,1,n) { int t; scanf("%d", &t); add(i,S-2,1,-t); } add(S-1,T,p,0),add(S-2,T,s,0); EK(); REP(i,1,n) { for (int j(head[i]); j; j=e[j].next) { if (!e[j].w) g[e[j].to].push_back(i); } } printf("%d ", -cost); for (int i:g[S-1]) printf("%d ",i);puts(""); for (int i:g[S-2]) printf("%d ",i);puts(""); }
28. 736E
29. 739E
大意: $n$只精灵, $a$个普通球, $b$个高级球, 第$i$只精灵用普通球成功率$u_i$, 高级球$v_i$, 每只精灵同一种球最多用一次, 可以同时使用两种球, 求获得精灵期望最大值.
裸费用流, 同时扔两种球概率会减少$u_iv_i$, 从源点连一条流量$1$费用$0$, 和流量$1$费用$u_iv_i$的边即可, 这样一个点流量为$2$时, 费用一定会减去, 否则一定不会.
#include <iostream> #include <cstdio> #include <queue> #define REP(i,a,n) for(int i=a;i<=n;++i) using namespace std; const int N = 1e6+10, INF = 0x3f3f3f3f; const int X = N-4, Y = N-3, S = N-2, T = N-1; const double eps = 1e-8; int n, a, b, flow; double cost, u[N], v[N], dep[N]; struct edge { int to,w; double v; int next; edge(int to=0,int w=0,double v=0,int next=0):to(to),w(w),v(v),next(next){} } e[N]; int head[N], vis[N], cur[N], f[N], cnt=1; int pre[N],pre2[N],x[N],y[N]; vector<int> g[N]; queue<int> Q; int spfa() { REP(i,1,n) f[i]=dep[i]=INF,vis[i]=0; REP(i,N-4,N-1) f[i]=dep[i]=INF,vis[i]=0; dep[S]=0,Q.push(S); while (Q.size()) { int p = Q.front(); Q.pop(); vis[p] = 0; for (int i=head[p]; i; i=e[i].next) if (e[i].w) { double dis = dep[p]+e[i].v; if (dep[e[i].to]>dis+eps) { dep[e[i].to]=dis; pre[e[i].to]=p,pre2[e[i].to]=i; f[e[i].to]=min(f[p],e[i].w); if (!vis[e[i].to]) { vis[e[i].to]=1; Q.push(e[i].to); } } } } return dep[T]!=INF; } void EK(){ while(spfa()) { int w = f[T]; for (int u=T; u!=S; u=pre[u]) { e[pre2[u]].w-=w; e[pre2[u]^1].w+=w; } flow += w, cost += w*dep[T]; } } void add(int u, int v, int w, double k) { e[++cnt] = edge(v,w,k,head[u]); head[u] = cnt; e[++cnt] = edge(u,0,-k,head[v]); head[v] = cnt; } int main() { scanf("%d%d%d", &n, &a, &b); REP(i,1,n) scanf("%lf", u+i); REP(i,1,n) scanf("%lf", v+i); REP(i,1,n) { add(S,i,1,0); add(S,i,1,u[i]*v[i]); add(i,X,1,-u[i]); add(i,Y,1,-v[i]); } add(X,T,a,0),add(Y,T,b,0); EK(); printf("%.5lf ", -cost); }
30. 786E
大意: 给定树, 给定$m$个人行走路线, 要求要么每个人自带一条狗, 要么路线上每条边都放一条狗, 求最少要多少只狗.
31. 793G
大意: $n*n$棋盘, 每行每列只能有一个棋子, 有$q$个矩形区域不能放棋子, 求最多放多少棋子
32. 802C
大意: 书架容量为$k$, 有$n$种书, 第$i$种$c_i$元, $n$个人按顺序来借书, 借完立刻还回, 第$i$个人要第$a_i$种, 若此时书架无$a_i$, 则要花费$c_{a_i}$元买书, 若书架满了, 则要扔掉一本. 求最少花费.
费用流好题, 开$2n$个点, $S$向$i$连一条费用$c_{a_i}$的边, 表示第$i$天新买一本书, $i$向$i+n$连费用$0$的边, 表示当天借完直接扔掉, $i+n$向$T$连费用$0$的边, 表示借书. $i$向$i+1$连容量$k-1$的边, 表示前一天最多向后一天保留$k-1$本书, 假设$a_i$的上次出现位置为$lst_{a_i}$, $i-1$向$lst_{a_i}+n$连费用$-c_{a_i}$的边, 表示撤销掉第$lst_{a_i}$的扔书操作, 使该书一直保留到$i-1$天. 最后跑一次最小费用最大流即为答案.
#include <iostream> #include <cstdio> #include <queue> #define REP(i,a,n) for(int i=a;i<=n;++i) using namespace std; const int N = 1e6+10, INF = 0x3f3f3f3f, S = N-2, T = N-1; int n, k, flow, cost, a[N], c[N], lst[N]; struct edge { int to,w,v,next; edge(int to=0,int w=0,int v=0,int next=0):to(to),w(w),v(v),next(next){} } e[N]; int head[N], dep[N], vis[N], cur[N], f[N], cnt=1; int pre[N],pre2[N]; queue<int> Q; int spfa() { REP(i,1,n) f[i]=dep[i]=INF,vis[i]=0; f[S]=dep[S]=f[T]=dep[T]=INF; dep[S]=0,Q.push(S); while (Q.size()) { int u = Q.front(); Q.pop(); vis[u] = 0; for (int i=head[u]; i; i=e[i].next) { if (dep[e[i].to]>dep[u]+e[i].v&&e[i].w) { dep[e[i].to]=dep[u]+e[i].v; pre[e[i].to]=u,pre2[e[i].to]=i; f[e[i].to]=min(f[u],e[i].w); if (!vis[e[i].to]) { vis[e[i].to]=1; Q.push(e[i].to); } } } } return dep[T]!=INF; } void EK(){ while(spfa()) { int w = f[T]; for (int u=T; u!=S; u=pre[u]) { e[pre2[u]].w-=w; e[pre2[u]^1].w+=w; } flow += w, cost += w*dep[T]; } } void add(int u, int v, int w, int k) { e[++cnt] = edge(v,w,k,head[u]); head[u] = cnt; e[++cnt] = edge(u,0,-k,head[v]); head[v] = cnt; } int main() { scanf("%d%d", &n, &k); REP(i,1,n) scanf("%d",a+i); REP(i,1,n) scanf("%d",c+i); REP(i,1,n) { add(S,i,1,c[a[i]]); add(i,i+n,1,0); add(i+n,T,1,0); if (i!=1) add(i-1,i,k-1,0); if (lst[a[i]]) add(i-1,lst[a[i]]+n,1,-c[a[i]]); lst[a[i]] = i; } EK(); printf("%d ", cost); }
33. 802O
大意: $n$道题, 第$i$天可以花费$a_i$准备一道题, 花费$b_i$打印一道题, 每天最多准备一道, 最多打印一道, 准备的题可以留到以后打印, 求最少花费使得准备并打印$k$道题.
中等难度就是裸的费用流, 困难用堆模拟费用流.
34. 808F
大意: $n$张牌, 第$i$张能力$p_i$,魔法值$c_i$,等级$l_i$, 要求组一套牌, 使得任意两张牌的魔法值和不为素数, 且能力和不少于$k$, 求所需牌的等级最大值的最小值.
先二分答案, 素数可以按奇偶分开转化为二分图最大带权独立集, 然后最小割即可. 需要特判一下$1$, 多个$1$时只取$p$值最大的那个.
#include <iostream> #include <algorithm> #include <math.h> #include <cstdio> #include <queue> #define REP(i,a,n) for(int i=a;i<=n;++i) using namespace std; const int N = 1e6+10, S = N-2, T = N-1, INF = 0x3f3f3f3f; int n, k, v[N]; struct _ {int p,c,l;} a[N]; struct edge { int to,w,next; edge(int to=0,int w=0,int next=0):to(to),w(w),next(next){} } e[N]; int head[N], dep[N], vis[N], cur[N], cnt=1; queue<int> Q; int bfs() { REP(i,1,n) dep[i]=INF,vis[i]=0,cur[i]=head[i]; dep[S]=INF,vis[S]=0,cur[S]=head[S]; dep[T]=INF,vis[T]=0,cur[T]=head[T]; dep[S]=0,Q.push(S); while (Q.size()) { int u = Q.front(); Q.pop(); for (int i=head[u]; i; i=e[i].next) { if (dep[e[i].to]>dep[u]+1&&e[i].w) { dep[e[i].to]=dep[u]+1; Q.push(e[i].to); } } } return dep[T]!=INF; } int dfs(int x, int w) { if (x==T) return w; int used = 0; for (int i=cur[x]; i; i=e[i].next) { cur[x] = i; if (dep[e[i].to]==dep[x]+1&&e[i].w) { int f = dfs(e[i].to,min(w-used,e[i].w)); if (f) used+=f,e[i].w-=f,e[i^1].w+=f; if (used==w) break; } } return used; } int dinic() { int ans = 0; while (bfs()) ans+=dfs(S,INF); return ans; } void add(int u, int v, int w) { e[++cnt] = edge(v,w,head[u]); head[u] = cnt; e[++cnt] = edge(u,0,head[v]); head[v] = cnt; } void seive(int n) { int mx = sqrt(n+0.5); REP(i,2,mx) if (!v[i]) { for (int j=i*i; j<=n; j+=i) v[j]=1; } } int chk(int n) { cnt = 1; REP(i,1,n) head[i] = 0; REP(i,S,T) head[i] = 0; REP(i,1,n) if ((a[i].c&1)&&a[i].c>1) REP(j,1,n) { if (!v[a[i].c+a[j].c]) add(i,j,INF); } REP(i,1,n) if (a[i].c==1) { REP(j,1,n) if (i!=j) { if (a[j].c==1) a[j].p=0; else if (!v[1+a[j].c]) add(i,j,INF); } } int sum = 0; REP(i,1,n) { sum += a[i].p; if (a[i].c&1) add(S,i,a[i].p); else add(i,T,a[i].p); } return sum-dinic()>=k; } int main() { seive(2e5); scanf("%d%d", &n, &k); REP(i,1,n) scanf("%d%d%d",&a[i].p,&a[i].c,&a[i].l); sort(a+1,a+1+n,[](_ a,_ b){return a.l<b.l||a.l==b.l&&a.p>b.p;}); int l=1,r=n,ans=-1; while (l<=r) { int mid=(l+r)/2; if (chk(mid)) ans=mid,r=mid-1; else l=mid+1; } if (ans==-1) return puts("-1"),0; printf("%d ", a[ans].l); }
35. 813D & 818G
大意: 给定$n$元素序列, 求选出$4$个不相交的链, 链中相邻元素满足模7同余或差不超过$1$.
这题感觉建图没什么错但一直WA, 没调出来.
36. 843E
37. 848D
38. 847J
39. 852D
大意: 给定$V$节点$E$条边无向图, 给定$n$个队伍起始位置, 求最短多少时间$n$个队伍的结束位置不少于$k$.
先$floyd$求一下最短路, 然后二分答案看最大流是否超过$k$即可.
#include <iostream> #include <cstdio> #include <queue> #include <string.h> #define REP(i,a,n) for(int i=a;i<=n;++i) using namespace std; const int N = 1e6+10, S = N-2, T = N-1, INF = 0x3f3f3f3f; int V,E,n,k,a[N]; int dis[666][666]; struct edge { int to,w,next; edge(int to=0,int w=0,int next=0):to(to),w(w),next(next){} } e[N]; int head[N], dep[N], vis[N], cur[N], cnt=1; queue<int> Q; int bfs() { REP(i,1,n+V) dep[i]=INF,vis[i]=0,cur[i]=head[i]; dep[S]=INF,vis[S]=0,cur[S]=head[S]; dep[T]=INF,vis[T]=0,cur[T]=head[T]; dep[S]=0,Q.push(S); while (Q.size()) { int u = Q.front(); Q.pop(); for (int i=head[u]; i; i=e[i].next) { if (dep[e[i].to]>dep[u]+1&&e[i].w) { dep[e[i].to]=dep[u]+1; Q.push(e[i].to); } } } return dep[T]!=INF; } int dfs(int x, int w) { if (x==T) return w; int used = 0; for (int i=cur[x]; i; i=e[i].next) { cur[x] = i; if (dep[e[i].to]==dep[x]+1&&e[i].w) { int f = dfs(e[i].to,min(w-used,e[i].w)); if (f) used+=f,e[i].w-=f,e[i^1].w+=f; if (used==w) break; } } return used; } int dinic() { int ans = 0; while (bfs()) ans+=dfs(S,INF); return ans; } void add(int u, int v, int w) { e[++cnt] = edge(v,w,head[u]); head[u] = cnt; e[++cnt] = edge(u,0,head[v]); head[v] = cnt; } int chk(int x) { cnt = 1; REP(i,1,n+V) head[i] = 0; REP(i,S,T) head[i] = 0; REP(i,1,n) REP(j,1,V) { if (dis[a[i]][j]<=x) add(i,j+n,1); } REP(i,1,n) add(S,i,1); REP(i,1,V) add(i+n,T,1); return dinic()>=k; } int main() { scanf("%d%d%d%d", &V, &E, &n, &k); REP(i,1,n) scanf("%d",a+i); memset(dis,0x3f,sizeof dis); REP(i,1,V) dis[i][i]=0; REP(i,1,E) { int a,b,t; scanf("%d%d%d",&a,&b,&t); dis[a][b]=dis[b][a]=min(dis[a][b],t); } REP(k,1,V)REP(i,1,V)REP(j,1,V) { dis[i][j]=min(dis[i][j],dis[i][k]+dis[k][j]); } int l=0,r=1731311,ans=-1; while (l<=r) { int mid=(l+r)/2; if (chk(mid)) ans=mid,r=mid-1; else l=mid+1; } printf("%d ", ans); }
40. 863F
大意: $n$元素序列, 每个元素取值范围$[1,n]$, 有$q$个限制$(t,l,r,x)$, 表示$[l,r]$内的元素$le x$或$ge x$, 定义$cnt_i$为元素$i$的出现次数, 求$sum cnt_i^2$的最小值.
费用流水题, 贡献为平方可以拆成$n$条流量为$1$, 费用为$1,3,5,7...$的边.
#include <iostream> #include <cstdio> #include <queue> #include <map> #define REP(i,a,n) for(int i=a;i<=n;++i) using namespace std; typedef pair<int,int> pii; const int N = 1e6+10, INF = 0x3f3f3f3f, S = N-2, T = N-1; int n, tot, q, flow, cost; int L[N], R[N]; struct edge { int to,w,v,next; edge(int to=0,int w=0,int v=0,int next=0):to(to),w(w),v(v),next(next){} } e[N]; int head[N], dep[N], vis[N], cur[N], f[N], cnt=1; int pre[N],pre2[N]; queue<int> Q; int spfa() { REP(i,1,tot) f[i]=dep[i]=INF,vis[i]=0; f[S]=dep[S]=f[T]=dep[T]=INF; dep[S]=0,Q.push(S); while (Q.size()) { int u = Q.front(); Q.pop(); vis[u] = 0; for (int i=head[u]; i; i=e[i].next) { if (dep[e[i].to]>dep[u]+e[i].v&&e[i].w) { dep[e[i].to]=dep[u]+e[i].v; pre[e[i].to]=u,pre2[e[i].to]=i; f[e[i].to]=min(f[u],e[i].w); if (!vis[e[i].to]) { vis[e[i].to]=1; Q.push(e[i].to); } } } } return dep[T]!=INF; } void EK(){ while(spfa()) { int w = f[T]; for (int u=T; u!=S; u=pre[u]) { e[pre2[u]].w-=w; e[pre2[u]^1].w+=w; } flow += w, cost += w*dep[T]; } } void add(int u, int v, int w, int k) { e[++cnt] = edge(v,w,k,head[u]); head[u] = cnt; e[++cnt] = edge(u,0,-k,head[v]); head[v] = cnt; } map<pii,int> mp; int ID(int x, int y) { if (mp.count(pii(x,y))) return mp[pii(x,y)]; return mp[pii(x,y)] = ++tot; } int main() { scanf("%d%d", &n, &q); REP(i,1,n) L[i]=1,R[i]=n; REP(i,1,q) { int op,l,r,x; scanf("%d%d%d%d",&op,&l,&r,&x); if (op==1) { REP(j,l,r) L[j]=max(L[j],x); } else { REP(j,l,r) R[j]=min(R[j],x); } } REP(i,1,n) { if (L[i]>R[i]) return puts("-1"),0; add(S,ID(n+2,i),1,0); REP(j,L[i],R[i]) { add(ID(n+2,i),ID(i,j),1,0); add(ID(i,j),ID(n+1,j),1,0); } } REP(i,1,n) REP(j,1,n) add(ID(n+1,i),T,1,2*j-1); EK(); printf("%d ", cost); }
41. 884F
大意: 定义一个长为$n$的串$s$为反回文串, 当且仅当对于$1le ile n$有$s[i]!=s[n-i+1]$. 给定串$s$, 求将$s$重排为一个反回文串$t$, 对于$1le ile n$, 若$s[i]=t[i]$, 则得分$b[i]$, 求最大得分值.
挺不错的费用流题, 也可以贪心做.
统计一下每个字符的出现次数$c_i$, 从$S$向字符$x$连$c_x$. 每个位置$i$拆成$26$个点, 从字符$x$连向每个点, 若$s[i]=x$则加一个费用$-b_i$. 然后就是处理反回文的限制, 对于每对限制$(i,n-i+1)$, 再新开$26$个点, $i$和$n-i+1$分别向新开的点连容量$1$, 最后再开个点限制两边流量和为$2$即可. 这样建图的话实际上会导致一个错误: 每对限制$(i,n-i+1)$, 可能取了$i$两个, 而$n-i+1$没有取到. 但是思考一下很容易发现这样并不影响最终结果.
#include <iostream> #include <cstdio> #include <queue> #include <map> #define REP(i,a,n) for(int i=a;i<=n;++i) using namespace std; typedef pair<int,int> pii; const int N = 1e6+10, INF = 0x3f3f3f3f, S = N-2, T = N-1; int n, tot, flow, cost, b[N], c[N]; char s[N]; struct edge { int to,w,v,next; edge(int to=0,int w=0,int v=0,int next=0):to(to),w(w),v(v),next(next){} } e[N]; int head[N], dep[N], vis[N], cur[N], f[N], cnt=1; int pre[N],pre2[N]; queue<int> Q; int spfa() { REP(i,1,tot) f[i]=dep[i]=INF,vis[i]=0; f[S]=dep[S]=f[T]=dep[T]=INF; dep[S]=0,Q.push(S); while (Q.size()) { int u = Q.front(); Q.pop(); vis[u] = 0; for (int i=head[u]; i; i=e[i].next) { if (dep[e[i].to]>dep[u]+e[i].v&&e[i].w) { dep[e[i].to]=dep[u]+e[i].v; pre[e[i].to]=u,pre2[e[i].to]=i; f[e[i].to]=min(f[u],e[i].w); if (!vis[e[i].to]) { vis[e[i].to]=1; Q.push(e[i].to); } } } } return dep[T]!=INF; } void EK(){ while(spfa()) { int w = f[T]; for (int u=T; u!=S; u=pre[u]) { e[pre2[u]].w-=w; e[pre2[u]^1].w+=w; } flow += w, cost += w*dep[T]; } } void add(int u, int v, int w, int k) { e[++cnt] = edge(v,w,k,head[u]); head[u] = cnt; e[++cnt] = edge(u,0,-k,head[v]); head[v] = cnt; } map<pii,int> mp; int ID(int x, int y) { if (mp.count(pii(x,y))) return mp[pii(x,y)]; return mp[pii(x,y)] = ++tot; } int main() { scanf("%d%s", &n, s+1); REP(i,1,n) ++c[s[i]]; REP(i,1,n) scanf("%d",b+i); REP(i,'a','z') add(S,ID(-1,i),c[i],0); REP(i,1,n) REP(j,'a','z') { add(ID(-1,j),ID(i,j),1,s[i]==j?-b[i]:0); } REP(i,1,n/2) { REP(j,'a','z') { add(ID(i,j),ID(i+n,j),1,0); add(ID(n-i+1,j),ID(i+n,j),1,0); add(ID(i+n,j),ID(i,1),1,0); } add(ID(i,1),T,2,0); } EK(); printf("%d ", -cost); }
42. 903G
大意:两个n元素集合$A$, $B$, $A_i$与$A_{i+1}$连一条有向边, $B_i$与$B_{i+1}$连一条有向边, 给定$m$条从$A_i$连向$B_j$的有向边, 每次询问修改$A_x->A_{x+1}$的边权, 求$A_1$->$B_n$的最大流.
43. 925F
44. 965D
大意: 河宽$w$, 青蛙每步能跳不超过$l$, 有$w-1$块石头, 石头每踩一次就会消失, 求最大过河青蛙数.
45. 976F
大意: 给定二分图, 对于$k in [0,minDegree]$, 输出最小$k$覆盖.
46. 1009G
47. 1016D
大意: 有一个$nm$矩阵, 给定每行每列异或和, 求是否存在. 若存在输出一个方案.
1045A
1054F
1061E
1070I
1107F
1119B
1139E
1146G