# Knight Jump

You are given a two dimensional chess board of size
$N \times N$ ($1$-based indexing). Some of the cells
on this board are ‘**.**’ denoting an empty
cell. Some of the cells on this board are ‘**#**’ denoting a blocked cell, which you are not
allowed to visit. Exactly one of the cells on this board is
‘**K**’ denoting the initial position of
the knight.

A knight at position $(r, c)$ can move to any of the valid positions in set $S$ = $\{ (r + 2, c + 1)$, $(r + 2, c - 1)$, $(r - 2, c + 1)$, $(r - 2, c - 1)$, $(r + 1, c + 2)$, $(r + 1, c - 2)$, $(r - 1, c + 2)$, $(r - 1, c - 2)\} $. Here valid position means that the resulting $(r’, c’)$ should be within the bounds of the chess grid, i.e. $1 \leq r’ \leq N$ and $1 \leq c’ \leq N$.

The question is you have to **determine
the minimum number of steps required for the Knight to reach
cell $(1, 1)$ avoiding
cells with ‘#’ in the path.**

Note - There will be exactly one ‘**K**’
in the grid and cell $(1,
1)$ will NOT be a ‘**#**’.

## Input

The first line contains an integer $N$ ($1 \le N \le 10^2$) denoting the dimension of the chess board. Each of the next $N$ lines contains a string denoting the $i^{th}$ row. The length of these strings will be $N$.

## Output

Print the value of minimum number of steps. However, if
$(1, 1)$ is not reachable,
print ‘**-$1$**’ (without the quotes).

Sample Input 1 | Sample Output 1 |
---|---|

4 .... .... .... ...K |
2 |

Sample Input 2 | Sample Output 2 |
---|---|

3 ..K ... ### |
-1 |