package LeetCode_980 /** * 980. Unique Paths III * https://leetcode.com/problems/unique-paths-iii/ * * On a 2-dimensional grid, there are 4 types of squares: 1 represents the starting square. There is exactly one starting square. 2 represents the ending square. There is exactly one ending square. 0 represents empty squares we can walk over. -1 represents obstacles that we cannot walk over. Return the number of 4-directional walks from the starting square to the ending square, that walk over every non-obstacle square exactly once. Example 1: Input: [ [1,0,0,0], [0,0,0,0], [0,0,2,-1]] Output: 2 Explanation: We have the following two paths: 1. (0,0),(0,1),(0,2),(0,3),(1,3),(1,2),(1,1),(1,0),(2,0),(2,1),(2,2) 2. (0,0),(1,0),(2,0),(2,1),(1,1),(0,1),(0,2),(0,3),(1,3),(1,2),(2,2) Example 3: Input: [ [0,1], [2,0]] Output: 0 Explanation: There is no path that walks over every empty square exactly once. Note that the starting and ending square can be anywhere in the grid. Note: 1 <= grid.length * grid[0].length <= 20 * */ class Solution { /* * solution: DFS+Backtracking, * count the empty and start dfs from starting point, check if can reach the ending through by 4 directions. * Time: O(4^(m*n)), each position has 4 path to go, * Space: O(m*n) * */ fun uniquePathsIII(grid: Array<IntArray>): Int { val m = grid.size val n = grid[0].size var startX = 0 var startY = 0 //init to 1, meaning the starting point have to go through also var needThroughCount = 1 for (i in 0 until m) { for (j in 0 until n) { if (grid[i][j] == 0) { needThroughCount++ } else if (grid[i][j] == 1) { startX = i startY = j } } } return dfs(grid, startX, startY, needThroughCount) } private fun dfs(grid: Array<IntArray>, x: Int, y: Int, needCount: Int): Int { if (x < 0 || y < 0 || x >= grid.size || y >= grid[0].size || grid[x][y] == -1) { return 0 } //reach ending if (grid[x][y] == 2) { if (needCount == 0) { return 1 } else { return 0 } } //-1 represents obstacles that we cannot walk over grid[x][y] = -1 var total = 0 total += dfs(grid, x + 1, y, needCount) total += dfs(grid, x - 1, y, needCount) total += dfs(grid, x, y + 1, needCount) total += dfs(grid, x, y - 1, needCount) grid[x][y] = 0//for backtracking return total } }