**Question:** There is an **m** x **n** grid ( **0 <= m, n <= 500**). Each cell in the grid contains **k** coins (k could be negative or 0 too). You start from **0, 0** and end at **m-1, n-1**, and you can move either 1 step down or 1 step right, collecting as many coins as you can. If **k < 0**, then that particular cell has a robber and you can't move into that cell. If you move into any of the **8** neighboring cells, you will be robbed of **k** coins. How many coins will you have when you reach **m-1, n-1** ?

For example in the grid:

```
0,23,20,-32
13,14,44,-44
23,19,41,9
46,27,20,0
```

ans = 129 (by following the path: 0-13-23-46-27-20-0)

**Time limit: 5 sec**

I don't think this program can be solved using dynamic programming. And I haven't studied graph theory (in case it could be used to solve this problem). The straightforward recursive approach is the only thing I can think of, which is too inefficient under the given constraints.

So what would be a good approach to solve it? Don't just post code, tell me how to begin. If its related to graph theory, then indicating which theorem is involved would be very useful.