Here is a solution that generalizes the good properties of the corners.

Let's assume that we could find a perfect drop point for a given field, that is, a best way to decrease the value in it. Then to find the minimum number of bombs to be dropped, a first draft of an algorithm could be (the code is copy-pasted from a ruby implementation):

```
dropped_bomb_count = 0
while there_are_cells_with_non_zero_count_left
coordinates = choose_a_perfect_drop_point
drop_bomb(coordinates)
dropped_bomb_count += 1
end
return dropped_bomb_count
```

The challenge is `choose_a_perfect_drop_point`

. First, let's define what a perfect drop point is.

- A
*drop point* for `(x, y)`

decreases the value in `(x, y)`

. It may also decrease values in other cells.
- A drop point
*a* for `(x, y)`

is *better* than a drop point *b* for `(x, y)`

if it decreases the values in a proper superset of the cells that *b* decreases.
- A drop point is
*maximal* if there is no other better drop point.
- Two drop points for
`(x, y)`

are *equivalent* if they decrease the same set of cells.
- A drop point for
`(x, y)`

is *perfect* if it is equivalent to all maximal drop points for `(x, y)`

.

If there is a perfect drop point for `(x, y)`

, you cannot decrease the value at `(x, y)`

more effectively than to drop a bomb on one of the perfect drop points for `(x, y)`

.

A perfect drop point for a given field is a perfect drop point for any of its cells.

Here are few examples:

```
1 0 1 0 0
0 0 0 0 0
1 0 0 0 0
0 0 0 0 0
0 0 0 0 0
```

The perfect drop point for the cell `(0, 0)`

(zero-based index) is `(1, 1)`

. All other drop points for `(1, 1)`

, that is `(0, 0)`

, `(0, 1)`

, and `(1, 0)`

, decrease less cells.

```
0 0 0 0 0
0 0 0 0 0
0 0 1 0 0
0 0 0 0 0
0 0 0 0 0
```

A perfect drop point for the cell `(2, 2)`

(zero-based index) is `(2, 2)`

, and also all the surrounding cells `(1, 1)`

, `(1, 2)`

, `(1, 3)`

, `(2, 1)`

, `(2, 3)`

, `(3, 1)`

, `(3, 2)`

, and `(3, 3)`

.

```
0 0 0 0 1
0 0 0 0 0
0 0 1 0 0
0 0 0 0 0
0 0 0 0 0
```

a perfect drop points for the cell `(2, 2)`

is `(3, 1)`

: It decreases the value in `(2, 2)`

, and the value in `(4, 0)`

. All other drop points for `(2, 2)`

are not maximal, as they decrease one cell less. The perfect drop point for `(2, 2)`

is also the perfect drop point for `(4, 0)`

, and it is the only perfect drop point for the field. It leads to the perfect solution for this field (one bomb drop).

```
1 0 0 0 0
0 0 0 0 0
0 0 1 0 0
0 0 0 0 0
1 0 0 0 0
```

There is no perfect drop point for `(2, 2)`

: Both `(1, 1)`

and `(1, 3)`

decrease `(2, 2)`

and another cell (they are maximal drop points for `(2, 2)`

), but they are not equivalent. However, `(1, 1)`

is a perfect drop point for `(0, 0)`

, and `(1, 3)`

is a perfect drop point for `(0, 4)`

.

With that definition of perfect drop points and a certain order of checks, I get the following result for the example in the question:

```
Drop bomb on 1, 1
Drop bomb on 1, 1
Drop bomb on 1, 5
Drop bomb on 1, 5
Drop bomb on 1, 5
Drop bomb on 1, 6
Drop bomb on 1, 2
Drop bomb on 1, 2
Drop bomb on 0, 6
Drop bomb on 0, 6
Drop bomb on 2, 1
Drop bomb on 2, 5
Drop bomb on 2, 5
Drop bomb on 2, 5
Drop bomb on 3, 1
Drop bomb on 3, 0
Drop bomb on 3, 0
Drop bomb on 3, 0
Drop bomb on 3, 0
Drop bomb on 3, 0
Drop bomb on 3, 4
Drop bomb on 3, 4
Drop bomb on 3, 3
Drop bomb on 3, 3
Drop bomb on 3, 6
Drop bomb on 3, 6
Drop bomb on 3, 6
Drop bomb on 4, 6
28
```

However, the algorithm only works if there is at least one perfect drop point after each step. It is possible to construct examples where there are no perfect drop points:

```
0 1 1 0
1 0 0 1
1 0 0 1
0 1 1 0
```

For these cases, we can modify the algorithm so that instead of a perfect drop point, we choose a coordinate with a minimal choice of maximal drop points, then calculate the minimum for each choice. In the case above, all cells with values have two maximal drop points. For example, `(0, 1)`

has the maximal drop points `(1, 1)`

and `(1, 2)`

. Choosing either one and then calcualting the minimum leads to this result:

```
Drop bomb on 1, 1
Drop bomb on 2, 2
Drop bomb on 1, 2
Drop bomb on 2, 1
2
```

`what's the minimum amount of bombs required to clean the board?`

Does this means that it is not necessarily needed to find an actual bombing pattern, but just the minimal number of bombs? – Lie Ryan Mar 8 '13 at 21:25