#include using namespace std; typedef signed long long ll; #define _P(...) (void)printf(__VA_ARGS__) #define FOR(x,to) for(x=0;x<(to);x++) #define FORR(x,arr) for(auto& x:arr) #define FORR2(x,y,arr) for(auto& [x,y]:arr) #define ALL(a) (a.begin()),(a.end()) #define ZERO(a) memset(a,0,sizeof(a)) #define MINUS(a) memset(a,0xff,sizeof(a)) template bool chmax(T &a, const T &b) { if(a bool chmin(T &a, const T &b) { if(a>b){a=b;return 1;}return 0;} //------------------------------------------------------- template class MinCostFlow { public: struct edge { int to; V capacity; V cost; int reve;}; vector E[NV]; int prev_v[NV], prev_e[NV]; V dist[NV]; void add_edge(int x,int y, V cap, V cost) { E[x].push_back((edge){y,cap,cost,(int)E[y].size()}); E[y].push_back((edge){x,0, -cost,(int)E[x].size()-1}); /* rev edge */ } V mincost(int from, int to, ll flow) { V res=0; int i,v; ZERO(prev_v); ZERO(prev_e); while(flow>0) { fill(dist, dist+NV, numeric_limits::max()/2); dist[from]=0; priority_queue > Q; Q.push(make_pair(0,from)); while(Q.size()) { V d=-Q.top().first; int cur=Q.top().second; Q.pop(); if(dist[cur]!=d) continue; if(d==numeric_limits::max()/2) break; FOR(i,E[cur].size()) { edge &e=E[cur][i]; if(e.capacity>0 && dist[e.to]>d+e.cost) { dist[e.to]=d+e.cost; prev_v[e.to]=cur; prev_e[e.to]=i; Q.push(make_pair(-dist[e.to],e.to)); } } } if(dist[to]==numeric_limits::max()/2) return -1; V lc=flow; for(v=to;v!=from;v=prev_v[v]) lc = min(lc, E[prev_v[v]][prev_e[v]].capacity); flow -= lc; res += lc*dist[to]; for(v=to;v!=from;v=prev_v[v]) { edge &e=E[prev_v[v]][prev_e[v]]; e.capacity -= lc; E[v][e.reve].capacity += lc; } } return res; } }; MinCostFlow<404,int> mcf; int N,K; int A[202],B[202]; int P[202][202]; void solve() { int i,j,k,l,r,x,y; string s; cin>>N>>K; FOR(i,N) { cin>>A[i]; mcf.add_edge(400,i,A[i],0); } FOR(i,N) { cin>>B[i]; mcf.add_edge(200+i,401,B[i],0); } int sum=0; FOR(y,N) FOR(x,N) { cin>>P[y][x]; sum+=P[y][x]*P[y][x]; FOR(i,202) mcf.add_edge(y,200+x,1,(P[y][x]-i-1)*(P[y][x]-i-1)-(P[y][x]-i)*(P[y][x]-i)); } cout<