C++实现LeetCode(63.不同的路径之二)

时间:2022-09-19 13:10:58

[LeetCode] 63. Unique Paths II 不同的路径之二

A robot is located at the top-left corner of a m x n grid (marked 'Start' in the diagram below).

The robot can only move either down or right at any point in time. The robot is trying to reach the bottom-right corner of the grid (marked 'Finish' in the diagram below).

Now consider if some obstacles are added to the grids. How many unique paths would there be?

C++实现LeetCode(63.不同的路径之二)

An obstacle and empty space is marked as 1 and 0 respectively in the grid.

Note: m and n will be at most 100.

Example 1:

Input:
[
[0,0,0],
[0,1,0],
[0,0,0]
]
Output: 2
Explanation:
There is one obstacle in the middle of the 3x3 grid above.
There are two ways to reach the bottom-right corner:
1. Right -> Right -> Down -> Down
2. Down -> Down -> Right -> Right

这道题是之前那道 Unique Paths 的延伸,在路径中加了一些障碍物,还是用动态规划 Dynamic Programming 来解,使用一个二维的 dp 数组,大小为 (m+1) x (n+1),这里的 dp[i][j] 表示到达 (i-1, j-1) 位置的不同路径的数量,那么i和j需要更新的范围就是 [1, m] 和 [1, n]。状态转移方程跟之前那道题是一样的,因为每个位置只能由其上面和左面的位置移动而来,所以也是由其上面和左边的 dp 值相加来更新当前的 dp 值,如下所示:

dp[i][j] = dp[i-1][j] + dp[i][j-1]

这里就能看出来初始化 d p数组的大小为 (m+1) x (n+1),是为了 handle 边缘情况,当i或j为0时,减1可能会出错。当某个位置是障碍物时,其 dp 值为0,直接跳过该位置即可。这里还需要初始化 dp 数组的某个值,使得其能正常累加。当起点不是障碍物时,其 dp 值应该为1,即dp[1][1] = 1,由于其是由 dp[0][1] + dp[1][0] 更新而来,所以二者中任意一个初始化为1即可。由于之后 LeetCode 更新了这道题的 test case,使得使用 int 型的 dp 数组会有溢出的错误,所以改为使用 long 型的数组来避免 overflow,代码如下:

解法一:

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class Solution {
public:
    int uniquePathsWithObstacles(vector<vector<int>>& obstacleGrid) {
        if (obstacleGrid.empty() || obstacleGrid[0].empty() || obstacleGrid[0][0] == 1) return 0;
        int m = obstacleGrid.size(), n = obstacleGrid[0].size();
        vector<vector<long>> dp(m + 1, vector<long>(n + 1, 0));
        dp[0][1] = 1;
        for (int i = 1; i <= m; ++i) {
            for (int j = 1; j <= n; ++j) {
                if (obstacleGrid[i - 1][j - 1] != 0) continue;
                dp[i][j] = dp[i - 1][j] + dp[i][j - 1];
            }
        }
        return dp[m][n];
    }
};

或者我们也可以使用一维 dp 数组来解,省一些空间,参见代码如下:

解法二:

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class Solution {
public:
    int uniquePathsWithObstacles(vector<vector<int>>& obstacleGrid) {
        if (obstacleGrid.empty() || obstacleGrid[0].empty() || obstacleGrid[0][0] == 1) return 0;
        int m = obstacleGrid.size(), n = obstacleGrid[0].size();
        vector<long> dp(n, 0);
        dp[0] = 1;
        for (int i = 0; i < m; ++i) {
            for (int j = 0; j < n; ++j) {
                if (obstacleGrid[i][j] == 1) dp[j] = 0;
                else if (j > 0) dp[j] += dp[j - 1];
            }
        }
        return dp[n - 1];
    }
};

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原文链接:https://www.cnblogs.com/grandyang/p/4353680.html