First of all, lets observe that it can be two diagonals.
Easiest solution is expanding in four possible directions until value
is different or we hit the border of matrix. If we finish on the border
in both endpoints that means that it belongs to diagonal.
Pseudocode for this could as follows

```
boolean expands(x, y, dir_x, dir_y, matrix):
x1 = x
y1 = y
while positionInBorder(x1, y1):
if matrix[x][y] != matrix[x1][y1]:
return false
x1 += dir_x
y1 += dir_y
return true
boolean inDiagonal(x, y, matrix):
return (expands(x, y, -1, -1, matrix) and expands(x, y, +1, +1, matrix)) or
(expands(x, y, +1, -1, matrix) and expands(x, y, -1, +1, matrix))
```

In case you needed to calculate all such points, which is quite
natural keeping in mind game context, you could use more efficient algorithm.
You check all possible diagonals and if they have the same value,
set flag for all elements in it:

```
isInDiagonal[n][n] = False for all i, j.
for start_position in top_row and left_column of matrix:
go down right while same value:
if reached bondary:
pass again and set isInDiagonal[x][y] for each item in diagonal
for start_position in top_row and right_column of matrix:
go down left while same value:
if reached bondary:
pass again and set isInDiagonal[x][y] for each item in diagonal
return isInDiagonal
```