Description
This is an interactive problem.
There is a robot in a hidden grid, and you are trying to get it from its starting cell to the target cell in this grid. The grid is of size m x n, and each cell in the grid is either empty or blocked. It is guaranteed that the starting cell and the target cell are different, and neither of them is blocked.
Each cell has a cost that you need to pay each time you move to the cell. The starting cell's cost is not applied before the robot moves.
You want to find the minimum total cost to move the robot to the target cell. However, you do not know the grid's dimensions, the starting cell, nor the target cell. You are only allowed to ask queries to the GridMaster object.
The GridMaster class has the following functions:
boolean canMove(char direction)Returnstrueif the robot can move in that direction. Otherwise, it returnsfalse.int move(char direction)Moves the robot in that direction and returns the cost of moving to that cell. If this move would move the robot to a blocked cell or off the grid, the move will be ignored, the robot will remain in the same position, and the function will return-1.boolean isTarget()Returnstrueif the robot is currently on the target cell. Otherwise, it returnsfalse.
Note that direction in the above functions should be a character from {'U','D','L','R'}, representing the directions up, down, left, and right, respectively.
Return the minimum total cost to get the robot from its initial starting cell to the target cell. If there is no valid path between the cells, return -1.
Custom testing:
The test input is read as a 2D matrix grid of size m x n and four integers r1, c1, r2, and c2 where:
grid[i][j] == 0indicates that the cell(i, j)is blocked.grid[i][j] >= 1indicates that the cell(i, j)is empty andgrid[i][j]is the cost to move to that cell.(r1, c1)is the starting cell of the robot.(r2, c2)is the target cell of the robot.
Remember that you will not have this information in your code.
Example 1:
Input: grid = [[2,3],[1,1]], r1 = 0, c1 = 1, r2 = 1, c2 = 0
Output: 2
Explanation: One possible interaction is described below:
The robot is initially standing on cell (0, 1), denoted by the 3.
- master.canMove('U') returns false.
- master.canMove('D') returns true.
- master.canMove('L') returns true.
- master.canMove('R') returns false.
- master.move('L') moves the robot to the cell (0, 0) and returns 2.
- master.isTarget() returns false.
- master.canMove('U') returns false.
- master.canMove('D') returns true.
- master.canMove('L') returns false.
- master.canMove('R') returns true.
- master.move('D') moves the robot to the cell (1, 0) and returns 1.
- master.isTarget() returns true.
- master.move('L') doesn't move the robot and returns -1.
- master.move('R') moves the robot to the cell (1, 1) and returns 1.
We now know that the target is the cell (1, 0), and the minimum total cost to reach it is 2.
Example 2:
Input: grid = [[0,3,1],[3,4,2],[1,2,0]], r1 = 2, c1 = 0, r2 = 0, c2 = 2 Output: 9 Explanation: The minimum cost path is (2,0) -> (2,1) -> (1,1) -> (1,2) -> (0,2).
Example 3:
Input: grid = [[1,0],[0,1]], r1 = 0, c1 = 0, r2 = 1, c2 = 1 Output: -1 Explanation: There is no path from the robot to the target cell.
Constraints:
1 <= n, m <= 100m == grid.lengthn == grid[i].length0 <= grid[i][j] <= 100
Solutions
Solution 1: DFS Graph Construction + Heap-Optimized Dijkstra Algorithm
We observe that the grid size is m × n, where m, n ≤ 100. Therefore, we can initialize the starting coordinates as (sx, sy) = (100, 100) and assume the grid size is 200 × 200. Then, we can use depth-first search (DFS) to explore the entire grid and construct a 2D array g representing the grid, where g[i][j] represents the movement cost from the starting point (sx, sy) to coordinates (i, j). If a cell is unreachable, we set its value to -1. We store the target coordinates in target, and if the target cannot be reached, then target = (-1, -1).
Next, we can use the heap-optimized Dijkstra algorithm to calculate the minimum cost path from the starting point (sx, sy) to the target target. We use a priority queue to store the current path cost and coordinates, and use a 2D array dist to record the minimum cost from the starting point to each cell. When we pop a node from the priority queue, if that node is the target, we return the current path cost as the answer. If the path cost of that node is greater than the value recorded in dist, we skip that node. Otherwise, we traverse the four neighbors of that node. If a neighbor is reachable and the path cost to reach the neighbor through this node is smaller, we update the neighbor's path cost and add it to the priority queue.
The time complexity is O(m × n log(m × n)), and the space complexity is O(m × n). Where m and n are the number of rows and columns in the grid, respectively.
# """ # This is GridMaster's API interface. # You should not implement it, or speculate about its implementation # """ # class GridMaster(object): # def canMove(self, direction: str) -> bool: # # # def move(self, direction: str) -> int: # # # def isTarget(self) -> bool: # # class Solution(object): def findShortestPath(self, master: "GridMaster") -> int: def dfs(x: int, y: int) -> None: nonlocal target if master.isTarget(): target = (x, y) for k in range(4): dx, dy = dirs[k], dirs[k + 1] nx, ny = x + dx, y + dy if ( 0 <= nx < m and 0 <= ny < n and g[nx][ny] == -1 and master.canMove(s[k]) ): g[nx][ny] = master.move(s[k]) dfs(nx, ny) master.move(s[(k + 2) % 4]) dirs = (-1, 0, 1, 0, -1) s = "URDL" m = n = 200 g = [[-1] * n for _ in range(m)] target = (-1, -1) sx = sy = 100 dfs(sx, sy) if target == (-1, -1): return -1 pq = [(0, sx, sy)] dist = [[inf] * n for _ in range(m)] dist[sx][sy] = 0 while pq: w, x, y = heappop(pq) if (x, y) == target: return w for dx, dy in pairwise(dirs): nx, ny = x + dx, y + dy if ( 0 <= nx < m and 0 <= ny < n and g[nx][ny] != -1 and w + g[nx][ny] < dist[nx][ny] ): dist[nx][ny] = w + g[nx][ny] heappush(pq, (dist[nx][ny], nx, ny)) return -1(code-box)
