#include using namespace std; #define REP(i,a,n) for(int i=(a); i<(int)(n); i++) #define rep(i,n) REP(i,0,n) #define FOR(it,c) for(__typeof((c).begin()) it=(c).begin(); it!=(c).end(); ++it) #define ALLOF(c) (c).begin(), (c).end() typedef long long ll; typedef unsigned long long ull; class CostScalingMinCostFlow { static constexpr double alpha = 2; public: struct Node { int b; double p; int in_f, out_f; Node() : b(0), p(0), in_f(0), out_f(0) {} Node(int b, double p) : b(b), p(p), in_f(0), out_f(0) {} }; struct Edge { int from, to; int cap, cost; int rev; int f; bool isrev; Edge() : from(-1), to(-1), cap(0), cost(0), rev(-1), f(0), isrev(false) {} Edge(int from, int to, int cap, int cost, int rev, int f, bool isrev) : from(from), to(to), cap(cap), cost(cost), rev(rev), f(f), isrev(isrev) {} }; private: std::vector nodes; std::vector> G; double epsilon; std::queue active_nodes; int residual_cap(const Edge& e) const { if (!e.isrev) return e.cap - e.f; else return G[e.to][e.rev].f; } double reduced_cost(const Edge& e) const { return e.cost + nodes[e.from].p - nodes[e.to].p; } int excess(int i) const { return nodes[i].b - nodes[i].out_f + nodes[i].in_f; } bool is_active(int i) const { return excess(i) > 0; } void push(Edge& edge, int delta) { if (!edge.isrev) { edge.f += delta; nodes[edge.from].out_f += delta; nodes[edge.to].in_f += delta; } else { G[edge.to][edge.rev].f -= delta; nodes[edge.to].out_f -= delta; nodes[edge.from].in_f -= delta; } } void relabel(int v) { double mx = std::numeric_limits::lowest(); for (Edge& edge : G[v]) { if (residual_cap(edge) > 0) { mx = std::max(mx, nodes[edge.to].p - edge.cost - epsilon); } } nodes[v].p = mx; } void refine() { for (auto& edges : G) { for (Edge& edge : edges) { // if (edge.isrev) continue; if (reduced_cost(edge) >= 0) continue; if (residual_cap(edge) <= 0) continue; push(edge, residual_cap(edge)); } } for (int i = 0; i < nodes.size(); i++) { if (is_active(i)) active_nodes.push(i); } while (!active_nodes.empty()) { int v = active_nodes.front(); active_nodes.pop(); if (!is_active(v)) continue; bool is_pushed = false; for (Edge& edge : G[v]) { if (reduced_cost(edge) >= 0) continue; if (residual_cap(edge) <= 0) continue; push(edge, std::min(residual_cap(edge), excess(v))); if (is_active(edge.from)) active_nodes.push(edge.from); if (is_active(edge.to)) active_nodes.push(edge.to); is_pushed = true; break; } if (!is_pushed) { relabel(v); if (is_active(v)) active_nodes.push(v); } } } public: CostScalingMinCostFlow(int N) : nodes(N), G(N), epsilon(0) {} void add_edge(int from, int to, int cap, int cost) { epsilon = std::max(epsilon, (double)abs(cost)); G[from].emplace_back(from, to, cap, cost, G[to].size(), 0, false); G[to].emplace_back(to, from, cap, -cost, G[from].size() - 1, cap, true); } void set_b(int i, int b) { nodes[i].b = b; } long long mincostflow() { int N = nodes.size(); while (epsilon >= 1.0 / N) { epsilon /= alpha; refine(); } long long ret = 0; for (auto& edges : G) { for (Edge& edge : edges) { if (edge.isrev) continue; ret += edge.cost * edge.f; } } return ret; } }; int main(){ int N; cin >> N; string S; cin >> S; vector v; rep(i,N){ ll a; cin >> a; v.push_back(a); } CostScalingMinCostFlow mcf(2*N+2); int s = 2*N; int t = s+1; rep(i,N){ if(S[i] == 'y'){ mcf.add_edge(s, i, 1, -v[i]); } mcf.add_edge(i, i+N, 1, 0); if(S[i] == 'i'){ mcf.add_edge(i+N, t, 1, 0); } rep(j,N){ if(S[i] == 'y' && S[j] == 'u'){ if(i