from collections import deque class mf_graph: n=1 g=[[] for i in range(1)] pos=[] def __init__(self,N): self.n=N self.g=[[] for i in range(N)] self.pos=[] def add_edge(self,From,To,cap): assert 0<=From and From=0:continue level[to]=level[v]+1 if to==t:return level que.append(to) return level def dfs(v,up): if (v==s):return up res=0 level_v=level[v] for i in range(Iter[v],len(self.g[v])): to,rev,cap=self.g[v][i] if (level_v<=level[to] or self.g[to][rev][2]==0):continue d=dfs(to,min(up-res,self.g[to][rev][2])) if d<=0:continue self.g[v][i][2]+=d self.g[to][rev][2]-=d res+=d if res==up:return res level[v]=self.n return res flow=0 while(flow0): p=que.popleft() visited[p]=True for to,rev,cap in self.g[p]: if cap and not(visited[to]): visited[to]=True que.append(to) return visited N,S,T=map(int,input().split()) X=[-1]*N E=list(map(int,input().split())) R=list(map(int,input().split())) C=[list(map(int,input().split())) for i in range(N)] for i in range(S): X[E[i]-1]=0 for i in range(T): X[R[i]-1]=1 SZ=N*N*2+N*2+2 G=mf_graph(SZ) s,t=SZ-2,SZ-1 for i in range(N): if X[i]==0: G.add_edge(s,i,10**15) if X[i]==1: G.add_edge(i,t,10**15) ANS=0 v=N for i in range(N): for j in range(i+1,N): ANS+=C[i][j] G.add_edge(s,v,C[i][j]) G.add_edge(v,i,10**15) G.add_edge(v,j,10**15) v+=1 ANS+=C[i][j] G.add_edge(v,t,C[i][j]) G.add_edge(i,v,10**15) G.add_edge(j,v,10**15) v+=1 print(ANS-G.flow(s,t))