Unique Paths III LeetCode Solution

Difficulty Level Hard
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Problem Statement:

Unique Paths III LeetCode Solution: You are given an m x n integer array grid where grid[i][j] could be:

  • 1 representing the starting square. There is exactly one starting square.
  • 2 representing the ending square. There is exactly one ending square.
  • 0 representing empty squares we can walk over.
  • -1 representing 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.

Examples:

Example 1:

Unique Paths III LeetCode Solution

Input:

 grid = [[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 2:

Unique Paths III LeetCode Solution

Input:

 grid = [[1,0,0,0],[0,0,0,0],[0,0,0,2]]

Output:

 4

Explanation:

 We have the following four paths: 
1. (0,0),(0,1),(0,2),(0,3),(1,3),(1,2),(1,1),(1,0),(2,0),(2,1),(2,2),(2,3)
2. (0,0),(0,1),(1,1),(1,0),(2,0),(2,1),(2,2),(1,2),(0,2),(0,3),(1,3),(2,3)
3. (0,0),(1,0),(2,0),(2,1),(2,2),(1,2),(1,1),(0,1),(0,2),(0,3),(1,3),(2,3)
4. (0,0),(1,0),(2,0),(2,1),(1,1),(0,1),(0,2),(0,3),(1,3),(1,2),(2,2),(2,3)

Example 3:

Unique Paths III LeetCode Solution

Input:

 grid = [[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.

Approach:

Idea:

The problem can be solved with the concept of backtracking and DFS. First, we will count the total number of non-obstacle cells. Starting from the initial cell we will do a DFS. Once we reach the destination cell after covering all the non-obstacle cells we will increment our count, considering this path valid. We will use a visited array to mark all the visited cells.

If you look carefully at your problem constraints: m*n <= 20, where m and n your grid sizes, we can guess, that we need to use dfs in this problem: that is try to check all possible options. So, we need to do several steps:

  1. Find our starting point: traverse all grid and find cell with value 1. Also count number of cells we need to visit, I denoted them empty.
  2. Now, use recursive dfs(x,y, rest) function, where x and y are current coordinates in our cell and rest is how many empty cells we need to traverse.
    2.1 First we check if we can move to the current cell: if it is outside our grid and it is already visited or have obstacle, we return
    2.2 If current cell is end cell and we already visited all cells, we add 1 to self.ans.
    2.3 Define list of neighbours and for each of them run our dfs: mark visited cell with -2 and then mark it back when we go outside recursion. It is important to do this, because in python grid is global variable and we need to change it back.
  3. FInally, we just run dfs(sx, sy, empty - 1), where (sx, sy) is coordinates of starting cell and return self.ans.

Code:

Unique Paths III C++ Solution:

class Solution {
public:
    int cells = 0;
    int n,m;
    int ans = 0;
    vector<vector<int>> dirs = {{0,1},{1,0},{0,-1},{-1,0}};
    
    void helper(int i,int j,int cnt,vector<vector<int>>& grid,vector<vector<int>>& vis){
        if(grid[i][j] == 2 and cnt == cells){
            ans++;
            return;
        }
        for(auto it:dirs){
            int x = i + it[0];
            int y = j + it[1];
            
            if(x>=0 and y>=0 and x<n and y<m and grid[x][y] != -1 and vis[x][y] == 0){
                vis[x][y] = 1;
                helper(x,y,cnt+1,grid,vis);
                vis[x][y] = 0;
            }
        }
    }
    
    int uniquePathsIII(vector<vector<int>>& grid) {
        n = grid.size();
        m = grid[0].size();
        vector<vector<int>> vis(n,vector<int>(m,0));
        int x = 0;
        int y = 0;
        for(int i=0;i<n;i++){
            for(int j=0;j<m;j++){
                if(grid[i][j] == 1){
                    x = i;
                    y = j;
                }
                if(grid[i][j] == 0)
                    cells++;
            }
        }
        vis[x][y] = 1;
        cells++;
        helper(x,y,0,grid,vis);
        return ans;
    }
};

Complexity Analysis of  Unique Paths III  LeetCode Solution:

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