You are given an m x n integer array grid. There is a robot initially located at the top-left corner (i.e., grid[0][0]). The robot tries to move to the bottom-right corner (i.e., grid[m-1][n-1]). The robot can only move either down or right at any point in time.
An obstacle and space are marked as 1 or 0 respectively in grid. A path that the robot takes cannot include any square that is an obstacle.
Return the number of possible unique paths that the robot can take to reach the bottom-right corner.
The testcases are generated so that the answer will be less than or equal to 2 * 109.
Example 1:
Input: obstacleGrid = [[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:
- Right -> Right -> Down -> Down
- Down -> Down -> Right -> Right
Example 2:
Input: obstacleGrid = [[0,1],[0,0]]
Output: 1
Constraints:
-
m == obstacleGrid.length -
n == obstacleGrid[i].length -
1 <= m, n <= 100 -
obstacleGrid[i][j]is0or1.
SOLUTION:
class Solution:
memo = {}
def uniquePathsRec(self, m, n, i, j, obstacleGrid):
if i == m - 1 and j == n - 1:
if obstacleGrid[i][j] != 1:
return 1
return 0
if obstacleGrid[i][j] == 1:
return 0
if (i, j) not in self.memo:
self.memo[(i, j)] = 0
if i + 1 < m:
self.memo[(i, j)] += self.uniquePathsRec(m, n, i + 1, j, obstacleGrid)
if j + 1 < n:
self.memo[(i, j)] += self.uniquePathsRec(m, n, i, j + 1, obstacleGrid)
return self.memo[(i , j)]
def uniquePathsWithObstacles(self, obstacleGrid: List[List[int]]) -> int:
self.memo = {}
return self.uniquePathsRec(len(obstacleGrid), len(obstacleGrid[0]), 0, 0, obstacleGrid)
Top comments (0)