zoukankan      html  css  js  c++  java
  • [LeetCode] Maximal Square

    Well, this problem desires for the use of dynamic programming. They key to any DP problem is to come up with the state equation. In this problem, we define the state to be the maximal size of the square that can be achieved at point (i, j), denoted as P[i][j]. Remember that we usesize instead of square as the state (square = size^2).

    Now let's try to come up with the formula for P[i][j].

    First, it is obvious that for the topmost row (i = 0) and the leftmost column (j = 0), S[i][j] = matrix[i][j]. This is easily understood. Let's suppose that the topmost row of matrix is like [1, 0, 0, 1]. Then we can immediately know that the first and last point can be a square of size 1while the two middle points cannot make any square, giving a size of 0. Thus, P = [1, 0, 0, 1], which is the same as matrix. The case is similar for the leftmost column. Till now, the boundary conditions of this DP problem are solved.

    Let's move to the more general case for P[i][j] in which i > 0 and j > 0. First of all, let's see another simple case in which matrix[i][j] = 0. It is obvious that P[i][j] = 0 too. Why? Well, since matrix[i][j] = 0, no square will contain matrix[i][j], according to our definition of P[i][j]P[i][j] is also 0.

    Now we are almost done. The only unsolved case is matrix[i][j] = 1. Let's see an example.

    Suppose matrix = [[0, 1], [1, 1]], it is obvious that P[0][0] = 0, P[0][1] = P[1][0] = 1, what about P[1][1]? Well, to give a square of size larger than 1 in P[1][1], all of its three neighbors (left, up, left-up) should be non-zero, right? In this case, the left-up neighbor P[0][0] = 0, so P[1][1] can only be 1, which means that it contains the square of itself.

    Now you are near the solution. In fact, P[i][j] = min(P[i - 1][j], P[i][j - 1], P[i - 1][j - 1]) + 1 in this case.

    Taking all these together, we have the following state equations.

    1. P[0][j] = matrix[0][j] (topmost row);
    2. P[i][0] = matrix[i][0] (leftmost column);
    3. For i > 0 and j > 0: if matrix[i][j] = 0P[i][j] = 0; if matrix[i][j] = 1P[i][j] = min(P[i - 1][j], P[i][j - 1], P[i - 1][j - 1]) + 1.

    Putting them into codes, and maintain a variable maxsize to record the maximum size of the square we have seen, we have the following (unoptimized) solution.

     1 int maximalSquare(vector<vector<char>>& matrix) {
     2     int m = matrix.size();
     3     if (!m) return 0;
     4     int n = matrix[0].size();
     5     vector<vector<int> > size(m, vector<int>(n, 0));
     6     int maxsize = 0;
     7     for (int j = 0; j < n; j++) {
     8         size[0][j] = matrix[0][j] - '0';
     9         maxsize = max(maxsize, size[0][j]);
    10     }
    11     for (int i = 1; i < m; i++) {
    12         size[i][0] = matrix[i][0] - '0';
    13         maxsize = max(maxsize, size[i][0]);
    14     }
    15     for (int i = 1; i < m; i++) {
    16         for (int j = 1; j < n; j++) {
    17             if (matrix[i][j] == '1') {
    18                 size[i][j] = min(size[i - 1][j - 1], min(size[i - 1][j], size[i][j - 1])) + 1;
    19                 maxsize = max(maxsize, size[i][j]);
    20             }
    22         }
    23     }
    24     return maxsize * maxsize;
    25 }

    Now let's try to optimize the above solution. As can be seen, each time when we update size[i][j], we only need size[i][j - 1], size[i - 1][j - 1] (at the previous left column) and size[i - 1][j] (at the current column). So we do not need to maintain the full m*n matrix. In fact, keeping two columns is enough. Now we have the following optimized solution.

     1 int maximalSquare(vector<vector<char>>& matrix) {
     2     int m = matrix.size();
     3     if (!m) return 0;
     4     int n = matrix[0].size();
     5     vector<int> pre(m, 0);
     6     vector<int> cur(m, 0);
     7     int maxsize = 0;
     8     for (int i = 0; i < m; i++) {
     9         pre[i] = matrix[i][0] - '0';
    10         maxsize = max(maxsize, pre[i]);
    11     }
    12     for (int j = 1; j < n; j++) {
    13         cur[0] = matrix[0][j] - '0';
    14         maxsize = max(maxsize, cur[0]);
    15         for (int i = 1; i < m; i++) {
    16             if (matrix[i][j] == '1') {
    17                 cur[i] = min(cur[i - 1], min(pre[i - 1], pre[i])) + 1;
    18                 maxsize = max(maxsize, cur[i]);
    19             }
    20         }
    21         pre = cur;
    22         fill(cur.begin(), cur.end(), 0);
    23     }
    24     return maxsize * maxsize;
    25 }

    As can be seen, line 21 of the above involves vector copying, which is a little unnecessary. We can simply maintain two points to the two vectors and just write and swap using the pointers, as in the following code.

     1     int maximalSquare(vector<vector<char>>& matrix) {
     2         if (matrix.empty()) return 0;
     3         int m = matrix.size(), n = matrix[0].size();
     4         vector<int> pre(m, 0), cur(m, 0);
     5         auto ppre = &pre, pcur = &cur;
     6         int maxsize = 0;
     7         for (int i = 0; i < m; i++) {
     8             (*ppre)[i] = matrix[i][0] - '0';
     9             maxsize = max(maxsize, pre[i]);
    10         }
    11         for (int j = 1; j < n; j++) {
    12             (*pcur)[0] = matrix[0][j] - '0';
    13             maxsize = max(maxsize, (*pcur)[0]);
    14             for (int i = 1; i < m; i++) {
    15                 if (matrix[i][j] == '1') {
    16                     (*pcur)[i] = min((*pcur)[i - 1], min((*ppre)[i - 1], (*ppre)[i])) + 1;
    17                     maxsize = max(maxsize, (*pcur)[i]);
    18                 }
    19             }
    20             swap(ppre, pcur);
    21             fill((*pcur).begin(), (*pcur).end(), 0);
    22         }
    23         return maxsize * maxsize;
    24     }

    Now the solution is finished? In fact, it can still be optimized! In fact, we need not maintain two vectors and one is enough. The idea is that we maintain two vectors simply to recover pre[i - 1] and this can stored in a single variable, thus eliminating the need for a full vector. Moreover, in the code above, we distinguish between the 0-th row and other rows since the 0-th row has no row above it. In fact, we can make all the rows the same by padding a 0 row on the top. Finally, we will have the following short code :) If you find it hard to understand, try to run it using your pen and paper and notice how it realizes what the two-vector solution does using only one vector.

     1 int maximalSquare(vector<vector<char>>& matrix) {
     2     if (matrix.empty()) return 0;
     3     int m = matrix.size(), n = matrix[0].size();
     4     vector<int> dp(m + 1, 0);
     5     int maxsize = 0, pre = 0;
     6     for (int j = 0; j < n; j++) {
     7         for (int i = 1; i <= m; i++) {
     8             int temp = dp[i];
     9             if (matrix[i - 1][j] == '1') {
    10                 dp[i] = min(dp[i], min(dp[i - 1], pre)) + 1;
    11                 maxsize = max(maxsize, dp[i]);
    12             }
    13             else dp[i] = 0;
    14             pre = temp;
    15         }
    16     }
    17     return maxsize * maxsize;
    18 }

     Well, someone even suggest not to use the pre variable and simply obtain the information from the matrix, which gives the following code.

     1     int maximalSquare(vector<vector<char>>& matrix) {
     2         if (matrix.empty()) return 0;
     3         int m = matrix.size(), n = matrix[0].size();
     4         vector<int> dp(m + 1, 0);
     5         int maxsize = 0;
     6         for (int j = 0; j < n; j++) {
     7             for (int i = 1; i <= m; i++) {
     8                 if (matrix[i - 1][j] == '1') {
     9                     int k = min(dp[i], dp[i - 1]);
    10                     dp[i] = matrix[i - k - 1][j - k] == '1' ? k + 1 : k;
    11                     maxsize = max(maxsize, dp[i]);
    12                 }
    13                 else dp[i] = 0;
    14             }
    15         }
    16         return maxsize * maxsize;
    17     }
  • 相关阅读:
    android界面横屏和竖屏的切换
    google 提供webrtc 的实例使用 turnserver的方式
    如何使官方提供的AppRTCDemo 运行在自己搭建的server(官方提供的apprtc)上(官方的server源码)
    android在全屏下第一次触摸屏幕没有触发事件
    ubuntu常用命令记录集
    python 一个包中的文件调用另外一个包文件 实例
    python-插入排序
    phantomjs submit click
    python socket.error: [Errno 10054] 解决方法
    python-快速排序,两种方法→易理解
  • 原文地址:https://www.cnblogs.com/jcliBlogger/p/4548751.html
Copyright © 2011-2022 走看看