#include <cmath>

#include <iostream>

#include <vector>

class RobotHerb {

 public:

  long long getdist(int T, std::vector<int> a) {

    struct node {

      int x, y, dir;

    };

    const int kDirX[] = {0, 1, 0, -1};

    const int kDirY[] = {1, 0, -1, 0};

    auto Go = [&](int dir) -> node {

      int x = 0, y = 0;

      for (size_t i = 0; i < a.size(); ++i) {

        if (kDirX[dir] != 0) {

          x += kDirX[dir] * a[i];

        } else {

          y += kDirY[dir] * a[i];

        }

        dir = (dir + a[i]) & 3;

      }

      return {x, y, dir};

    };

    auto Add = [](const node &a, long long *x, long long *y) {

      *x += a.x;

      *y += a.y;

    };

    node t[4];

    for (int i = 0; i < 4; ++i) {

      t[i] = Go(i);

    }

    long long start_x = 0, start_y = 0;

    int current_dir = 0;

    int times = 0;

    do {

      Add(t[current_dir], &start_x, &start_y);

      current_dir = t[current_dir].dir;

      ++times;

    } while (current_dir != 0);

    start_x *= T / times;

    start_y *= T / times;

    T %= times;

    for (int i = 0; i < T; ++i) {

      Add(t[current_dir], &start_x, &start_y);

      current_dir = t[current_dir].dir;

    }

    return (start_x < 0 ? -start_x : start_x) +

           (start_y < 0 ? -start_y : start_y);

  }

};

#include <algorithm>

#include <cstring>

#include <iostream>

#include <vector>

const int MAX = 36;

long long f[MAX][2][MAX + 1][MAX + 1];

long long g[2][MAX + 1][MAX + 1];

long long g1[2][MAX + 1][MAX + 1];

class CentaurCompany {

 public:

  double getvalue(std::vector<int> a, std::vector<int> b) {

    node_number_ = static_cast<int>(a.size() + 1);

    tree_.resize(node_number_);

    for (int i = 0; i < node_number_ - 1; ++i) {

      int u = a[i] - 1;

      int v = b[i] - 1;

      tree_[u].push_back(v);

      tree_[v].push_back(u);

    }

    Dfs(0, -1);

    long long result = 0;

    for (int n = 1; n <= node_number_; ++n) {

      for (int c = 1; c <= n; ++c) {

        if (Cost(n, c) > 0) {

          result += Cost(n, c) * Count(n, c);

        }

      }

    }

    return 2.0 * result / (1ll << node_number_);

  }

 private:

  int Cost(int n, int c) { return std::max(0, c + c - n - 2); }

  long long Count(int n, int c) { return f[0][0][n][c] + f[0][1][n][c]; }

  void Copy(long long source[2][MAX + 1][MAX + 1],

            long long sink[2][MAX + 1][MAX + 1]) {

    for (int i = 0; i <= node_number_; ++i) {

      for (int j = 0; j <= i; ++j) {

        sink[0][i][j] = source[0][i][j];

        sink[1][i][j] = source[1][i][j];

      }

    }

  }

  void Dfs(int rt, int parent) {

    for (size_t i = 0; i < tree_[rt].size(); ++i) {

      if (tree_[rt][i] != parent) {

        Dfs(tree_[rt][i], rt);

      }

    }

    memset(g, 0, sizeof(g));

    g[0][0][0] = 1;

    g[1][1][1] = 1;

    for (size_t i = 0; i < tree_[rt].size(); ++i) {

      if (tree_[rt][i] != parent) {

        int son = tree_[rt][i];

        for (int n = node_number_; n >= 0; --n) {

          for (int c = n; c >= 0; --c) {

            g1[0][n][c] = 0;

            g1[1][n][c] = 0;

            for (int n1 = n; n1 >= 0; --n1) {

              for (int c1 = c; c1 >= 0; --c1) {

                g1[0][n][c] += g[0][n1][c1] * (f[son][0][n - n1][c - c1] +

                                               f[son][1][n - n1][c - c1]);

                g1[1][n][c] +=

                    g[1][n1][c1] * (f[son][0][n - n1][c - c1] +

                                    (c1 > 0 ? f[son][1][n - n1][c - c1 + 1]

                                            : f[son][1][n - n1][c - c1]));

              }

            }

          }

        }

        Copy(g1, g);

      }

    }

    Copy(g, f[rt]);

  }

  int node_number_;

  std::vector<std::vector<int>> tree_;

};

#include <iostream>

#include <limits>

#include <queue>

#include <string>

#include <unordered_map>

#include <vector>

template <typename FlowType, typename CostType>

class MaxFlowMinimunCost {

  static constexpr FlowType kMaxFlow = std::numeric_limits<FlowType>::max();

  static constexpr FlowType kZeroFlow = static_cast<FlowType>(0);

  static constexpr CostType kMaxCost = std::numeric_limits<CostType>::max();

  static constexpr CostType kZeroCost = static_cast<CostType>(0);

 public:

  void Clear() {

    index_normalizer_.clear();

    node_number_ = 0;

    all_edges_.clear();

  }

  void AddEdge(int from, int to, FlowType flow, CostType cost) {

    from = GetIndex(from);

    to = GetIndex(to);

    auto idx0 = Add(from, to, flow, cost);

    auto idx1 = Add(to, from, kZeroFlow, -cost);

    all_edges_[from][idx0].sym_node_index = idx1;

    all_edges_[to][idx1].sym_node_index = idx0;

  }

  std::pair<FlowType, CostType> GetResult(int source, int sink) {

    source = GetIndex(source);

    sink = GetIndex(sink);

    struct Node {

      FlowType flow;

      CostType cost;

      int previous_node;

      int previous_edge_index;

      bool visited;

    };

    std::vector<Node> dp(node_number_);

    auto SPFA = [&]() -> FlowType {

      for (int i = 0; i < node_number_; ++i) {

        dp[i].previous_edge_index = -1;

        dp[i].flow = kZeroFlow;

        dp[i].visited = false;

        dp[i].cost = kMaxCost;

      }

      std::queue<int> bfs_queue;

      bfs_queue.push(source);

      dp[source].cost = kZeroCost;

      dp[source].flow = kMaxFlow;

      while (!bfs_queue.empty()) {

        int current_node = bfs_queue.front();

        bfs_queue.pop();

        dp[current_node].visited = false;

        for (size_t i = 0; i < all_edges_[current_node].size(); ++i) {

          int next_node = all_edges_[current_node][i].to;

          CostType cost = all_edges_[current_node][i].cost;

          FlowType flow = all_edges_[current_node][i].flow;

          if (flow > kZeroFlow &&

              dp[next_node].cost > dp[current_node].cost + cost) {

            dp[next_node].cost = dp[current_node].cost + cost;

            dp[next_node].flow = std::min(dp[current_node].flow, flow);

            dp[next_node].previous_node = current_node;

            dp[next_node].previous_edge_index = static_cast<int>(i);

            if (!dp[next_node].visited) {

              dp[next_node].visited = true;

              bfs_queue.push(next_node);

            }

          }

        }

      }

      return dp[sink].flow;

    };

    FlowType total_flow = kZeroFlow;

    CostType total_cost = kZeroCost;

    while (true) {

      FlowType flow = SPFA();

      if (IsNoFlow(flow)) {

        break;

      }

      total_flow += flow;

      for (int i = sink; i != source;) {

        int idx = dp[i].previous_edge_index;

        int pre_node = dp[i].previous_node;

        total_cost += flow * all_edges_[pre_node][idx].cost;

        all_edges_[pre_node][idx].flow -= flow;

        all_edges_[i][all_edges_[pre_node][idx].sym_node_index].flow += flow;

        i = pre_node;

      }

    }

    return {total_flow, total_cost};

  }

 private:

  bool IsNoFlow(FlowType flow) {

    constexpr double kEpsilon = 1e-3;

    return static_cast<double>(flow) < kEpsilon;

  }

  int GetIndex(int t) {

    if (index_normalizer_.find(t) != index_normalizer_.end()) {

      return index_normalizer_[t];

    }

    index_normalizer_[t] = node_number_++;

    all_edges_.push_back({});

    return node_number_ - 1;

  }

  size_t Add(int from, int to, FlowType flow, CostType cost) {

    EdgeNode node;

    node.to = to;

    node.flow = flow;

    node.cost = cost;

    all_edges_[from].push_back(node);

    return all_edges_[from].size() - 1;

  }

  struct EdgeNode {

    int to;

    FlowType flow;

    CostType cost;

    int sym_node_index;

  };

  std::vector<std::vector<EdgeNode>> all_edges_;

  std::unordered_map<int, int> index_normalizer_;

  int node_number_ = 0;

};

class CurvyonRails {

 public:

  int getmin(std::vector<std::string> field) {

    int n = static_cast<int>(field.size());

    int m = static_cast<int>(field[0].size());

    auto GetIndex = [&](int i, int j, int t) { return (i * m + j) << 1 | t; };

    auto IsGreen = [](int i, int j) { return (i & 1) == (j & 1); };

    auto IsValid = [&](int i, int j) {

      return i >= 0 && i < n && j >= 0 && j < m && field[i][j] != 'w';

    };

    MaxFlowMinimunCost<int, int> solver;

    const int source = GetIndex(n, m, 0);

    const int sink = source + 1;

    int delta_x[] = {0, 0, 1, -1};

    int delta_y[] = {1, -1, 0, 0};

    int total = 0;

    for (int i = 0; i < n; ++i) {

      for (int j = 0; j < m; ++j) {

        if (!IsValid(i, j)) {

          continue;

        }

        ++total;

        if (IsGreen(i, j)) {

          solver.AddEdge(source, GetIndex(i, j, 0), 1, 0);

          solver.AddEdge(source, GetIndex(i, j, 1), 1, 0);

          for (int d = 0; d < 4; ++d) {

            int x = i + delta_x[d];

            int y = j + delta_y[d];

            if (IsValid(x, y)) {

              int t = d >> 1;

              solver.AddEdge(GetIndex(i, j, t), GetIndex(x, y, t^1), 1, 0);

            }

          }

        } else {

          solver.AddEdge(GetIndex(i, j, 0), sink, 1, 0);

          solver.AddEdge(GetIndex(i, j, 1), sink, 1, 0);

        }

        int self_cost = field[i][j] == 'C' ? 1 : 0;

        solver.AddEdge(GetIndex(i, j, 0), GetIndex(i, j, 1), 1, self_cost);

        solver.AddEdge(GetIndex(i, j, 1), GetIndex(i, j, 0), 1, self_cost);

      }

    }

    auto result = solver.GetResult(source, sink);

    int max_flow = result.first;

    int min_cost = result.second;

    if (max_flow != total) {

      return -1;

    }

    return min_cost;

  }

};