Problem J
Lines of X
Tic-tac-toe is boring. The optimal strategy is simple to work out. But what about a generalization to an $N \times N$ board. That also does not seem interesting, and you probably won’t convince anyone to play with you. So you decide to have your own fun with such grids.
Given a $N \times N$ grid $G$ where each cell contains a single X, O, or . (the latter meaning the space is empty), you want to calculate the number of ways one can fill out the empty cells in $G$ so that there is at least one line that is all X. The lines of the grid are the $N$ rows, the $N$ columns, and the $2$ diagonals.
More precisely, compute the number of $N \times N$ grids $H$ that have the following properties:
-
$H$ contains only X or O entries, no empty cells.
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The only cells where $G$ and $H$ can differ is at the empty cells in $G$.
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At least one row, column, or diagonal line of $H$ only contains X.
Input
The first line of input contains a single integer $N$ ($2 \leq N \leq 8$) indicating the dimensions of the grid. The next $N$ lines describe the rows of the grid, each row is a string of length exactly $N$ containing only characters ., O, X.
Output
Output a single number indicating the number of ways to fill out the . characters in the grid with either O or X so that the resulting grid has at least one line with all characters being X.
| Sample Input 1 | Sample Output 1 |
|---|---|
2 X. .. |
7 |
| Sample Input 2 | Sample Output 2 |
|---|---|
2 X. .O |
3 |
| Sample Input 3 | Sample Output 3 |
|---|---|
3 XO. O.X OXO |
0 |
| Sample Input 4 | Sample Output 4 |
|---|---|
2 XX XX |
1 |
