# Detect winning game in nought and crosses

I need to know the best way to detect a winning move in a game of noughts and crosses. Source code doesn't matter, I just need a example or something I can start with.

The only thing I can come up with is to use loops and test every direction for every move a player makes, to search for e.g five in a row. Is there a faster and more efficient way?

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–  KennyTM Apr 19 '10 at 19:42
You said in a comment that the board does not need to be 3x3...and a 5x5 game is essentially unwinnable if you need 5 in a row to win, so I'm assuming that the winning length can be less than the board length...is that correct? You may want to update your question to make it a bit clearer. –  Beska Apr 19 '10 at 21:16

I'm not aware of a better method then looping, but the board is so small, it's quite trivial.

A little Python psuedo code:

``````def get_winner(board):
if board[0][0] != EMPTY and board[0][0] == board[1][1] == board[2][2]:
return board[0][0]
if board[2][0] != EMPTY and board[2][0] == board[1][1] == board[0][2]:
return board[2][0]
for i in xrange(3):
if board[i][0] != EMPTY and board[i][0] == board[i][1] == board[i][2]:
return board[i][0]
if board[0][i] != EMPTY and board[0][i] == board[1][i] == board[2][i]:
return board[0][i]
``````
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i am sorry i forgot to mention it i need to detect a winning game in a board that can be any size, not just 3x3 –  Dennis Apr 19 '10 at 19:41

There are more efficient ways, but they really only matter when you extend this game for much, much larger board configurations. For example, if you stored groupings of noughts and crosses in directional objects (store a diagonal configuration, for example), you could sort by those with length `winLength-1`, and only test the new move against these groupings. You save some iterations, but you have to maintain a lot of extra information in memory.

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It's a question of representation. How do you store the game board? Now think outside the box; how else could you store it? You might for example represent the board as a pair of bitmaps - one for noughts and one for crosses - then do a numerical pattern match to detect winning conditions.

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+1. downvote with no explanation. –  EvilTeach Apr 19 '10 at 20:50
@EvilTeach: Bleh. Pity votes give people undeserved rep. My guess as to downvote reason: This solution would work, but I can't imagine it scaling well, and trying to read and maintain it would be ugly. Why go for the difficult when the simple is obvious? (If I'm missing how this is straightforward, please set me straight). –  Beska Apr 19 '10 at 21:09
@Beska: I don't deny that I was alluding to potentially ugly code. I was trying to make the point that there may be more ways to represent the data than the naive one, and with a careful representation you might be able to set yourself up for an algorithmic win. –  crazyscot Apr 20 '10 at 8:55
Absolutely, and that's always a good point. –  Beska Apr 20 '10 at 12:35

The real easy solution is to just check from the last move made...obviously, no prior move could have won the game, or you wouldn't be here...so you just need to check to see if there are 5 (or however many) in a row/column/diagonal around the move that was just placed.

For example, if the board looks like this, and X marks the most recent move:

``````.............
.............
.............
.............
.....X.......
.............
.............
.............
.............
.............
``````

You don't need to check anything outside the range of "C":

``````.C...C...C...
..C..C..C....
...C.C.C.....
....CCC......
.CCCCXCCCC...
....CCC......
...C.C.C.....
..C..C..C....
.C...C...C...
.............
``````

Does that help? (It looked like you might be alluding to this in your original question, but I wasn't sure.)

Beyond this, simple loops are going to be your best friend. You could probably do some micro-optimization, but (depending on what your actual application is doing) it's probably not worth it.

One thing to keep track of is that you can't just jump out 5 in any direction from the most recent move looking for that many in a row, because this move might be in the middle of a streak. So I'd do something like

``````From the new move
left = how many in a row we have to the left of the lastest move
right = how many in a row we have to the right of the latest move
if (left + right + 1 >= 5) then you have a winner

up = how many in a row we have above the latest move
down = how many in a row we have below the latest move
if (up + down + 1 >= 5) then you have a winner

// repeat for both diagonal directions.
``````
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Consider the 3X3 board

Let X = 1 Let O = -1 and a space is represented by a zero.

So if the top row looks like this [X][X][X] the sum is 3, hence it is a win [O][O][O] the sum is -3, hence it is the other win.

[X][X][ ] is 2, hence if it is X turn, he can win by moving to the blank, or O must block.

[X][O][X] is 1, hence no win.

In a 3x3 board there are 8 positions to evaluate.

In NXN the number gets larger but the idea remains the same

if N=8 and a row or column sums to 7, then you know there is a winning move for X on that row/column

That method worked for me in high school.

Best Wishes

Evil

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This doesn't work if the board size is larger than the number needed to win. For example, if the board width is 12, and it takes 3 in a row to win, and the top row has OOXXXOOXOOXO you'll have a score of -2...and yet X has won. (The OP has said in a comment that the board does not need to be 3x3...and a 5x5 game is essentially unwinnable if you need 5 in a row to win, so I'm assuming that the winning length can be less than the board length) –  Beska Apr 19 '10 at 21:22
Yep, +1 In my view if your board is N X N you need n in a row to win. –  EvilTeach Apr 19 '10 at 23:45

Noughts and crosses is a neat programming challenge, because there's alot of mathematical tricks you can use to simplify the problem.

Noughts and crosses is typically a 3-by-3 grid. If you assign each position in your grid a number from one to nine (not in numerical order) you can arrange the numbers so that every horizontal, vertical, and diagonal row adds up to 15

+----+----+----+

| 4 | 3 | 8 |

| | | |

+----+----+----+

| 9 | 5 | 1 |

| | | |

+----+----+----+

| 2 | 7 | 6 |

| | | |

+----+----+----+

Why's that useful? If you can pick any three squares belonging to either 'O' or 'X', and those three squares add up to a total sum of 15, you know that player has won the game.

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This is known as a magic square. Larger magic squares do exist. –  Michael J. Barber Apr 12 '11 at 6:57