# How to find the winner of a tic-tac-toe game of any size?

This is an interview question. "How would you determine if someone has won a game of tic-tac-toe on a board of any size?" I heard the algorithm complexity was O(1). Does it make sense ? Can anybody explain the algorithm ?

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Possible duplicate : stackoverflow.com/questions/1056316/… – Eternal Noob Nov 16 '10 at 21:07
How does the game work? Played on an N x N board, do you still win by making 3 in a line, or do you now need to make N in a line? – Colonel Panic Jul 29 '13 at 21:56

The answer is right on that page, but I'll explain it anyway.

The algorithm's complexity is O(1) for determining if a given move will win the game. It cannot be O(1) in general since you need to know the state of the board to determine a winner. However, you can build that state incrementally such that you can determine whether a move wins in O(1).

To start, have an array of numbers for each row, column, and diagonal for each player. On each move, increment the elements corresponding to the player for the row, column, and diagonal (the move may not necessarily be on a diagonal) influenced by that move. If the count for that player is equal to the dimension of the board, that player wins.

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Can you please explain this with small example!! your statement is not clear!! please. – AGeek Mar 22 '11 at 16:41
@AGeek it is pretty simple, for example to check if a move wins by filling a row... Each time a piece is placed you increment the count for that player for that row. If the player's count for a particular row equals the number of squares in the row, he wins. – Alan Jul 29 '13 at 22:48
If you're interested in saving tiny amounts of space, you don't need to set up arrays for each player. Increment for `X`, decrement for `O`. Check for negative and positive `N` to determine winners. – Bigtoes Aug 29 '13 at 16:05
You don't have to have an array of numbers for each row, column and diagonal for each player. You need 2 arrays. One to hold level data (O and X) on the board and second for tracking sum of all rows, columns, diagonal and anti-diagonal. Check example PHP implementation in answer bellow. – Tomasz Rybakiewicz Sep 7 '13 at 2:04
That is not my understanding of the meaning of "a won game." To say that a move is winning does not mean that the move terminates the game in a win/loss condition; it merely means that the given move assures the player that the game can be won eventually. "Mate in three." – johnwbyrd Dec 27 '15 at 8:40

Fastest way of detecting win condition is to keep track of all rows, cols, diagonal and anti-diagonal scores.

Let's say you have 3x3 grid. Create score array of size 2*3+2 that will hold scores as following [row1, row2, row3, col1, col2, col3, diag1, diag2]. Of course don't forget to initialize it with 0.

Next after every move you add +1 for player 1 or subtract -1 for player 2 as following.

score[row] += point; // where point is either +1 or -1

score[gridSize + col] += point;

if (row == col) score[2*gridSize] += point;

if (gridSize - 1 - col == row) score[2*gridSize + 1] += point;

Then all you have to do is iterate over score array once and detect +3 or -3 (GRID_SIZE or -GRID_SIZE).

I know code tells more then words so here is a prototype in PHP. It's pretty straight forward so I don't think you'll have problems translating it into other lang.

``````<?php

class TicTacToe {
const PLAYER1 = 'X';
const PLAYER1_POINT = 1;

const PLAYER2 = 'O';
const PLAYER2_POINT = -1; // must be the opposite of PLAYER1_POINT

const BLANK = '';

/**
* Level size.
*/
private \$gridSize;

/**
* Level data.
* Two dimensional array of size GRID_SIZE x GRID_SIZE.
* Each player move is stored as either 'X' or 'O'
*/
private \$grid;

/**
* Score array that tracks score for rows, cols and diagonals.
* e.g. for 3x3 grid [row1, row2, row3, col1, col2, col3, diag1, diag2]
*/
private \$score;

/**
* Avaialable moves count for current game.
*/
private \$movesLeft = 0;

/**
* Winner of the game.
*/
private \$winner = null;

public function __construct(\$size = 3) {
\$this->gridSize = \$size;
\$this->grid = array();
for (\$i = 0; \$i < \$this->gridSize; ++\$i) {
\$this->grid[\$i] = array_fill(0, \$this->gridSize, self::BLANK);
}

\$this->score = array_fill(0, 2*\$this->gridSize + 2, 0);
\$this->movesLeft = \$this->gridSize * \$this->gridSize;
\$this->winner = null;
}

public function getWinner() {
return \$this->winner;
}

public function displayGrid() {
\$this->display("--------\n");
for (\$row = 0; \$row < \$this->gridSize; ++\$row) {
for (\$col = 0; \$col < \$this->gridSize; ++\$col) {
if (self::BLANK == \$this->grid[\$row][\$col]) \$this->display('  ');
else \$this->display(\$this->grid[\$row][\$col].' ');
}
\$this->display("\n");
}
\$this->display("--------\n");
}

public function play(MoveInput \$input) {
\$this->display("NEW GAME\n");
\$nextPlayer = self::PLAYER1;
\$done = false;
while(!\$done) {
\$move = \$input->getNextMove(\$nextPlayer);
if (NULL == \$move) {
\$this->display("ERROR! NO MORE MOVES\n");
break;
}

\$error = false;
\$this->makeMove(\$move['player'], \$move['row'], \$move['col'], \$error);
if (\$error) {
continue;
}
\$nextPlayer = (\$nextPlayer == self::PLAYER1) ? self::PLAYER2 : self::PLAYER1;
\$this->displayGrid();
\$done = \$this->checkScore();
}
}

private function makeMove(\$player, \$row, \$col, &\$error) {
\$error = false;
if (!\$this->isValidMove(\$row, \$col) || self::BLANK != \$this->grid[\$row][\$col]) {
\$error = true;
return;
}

\$this->grid[\$row][\$col] = \$player;
--\$this->movesLeft;

\$point = 0;
if (self::PLAYER1 == \$player) \$point = self::PLAYER1_POINT;
if (self::PLAYER2 == \$player) \$point = self::PLAYER2_POINT;

\$this->score[\$row] += \$point;
\$this->score[\$this->gridSize + \$col] += \$point;
if (\$row == \$col) \$this->score[2*\$this->gridSize] += \$point;
if (\$this->gridSize - 1 - \$col == \$row) \$this->score[2*\$this->gridSize + 1] += \$point;
}

private function checkScore() {
if (0 == \$this->movesLeft) {
\$this->display("game is a DRAW\n");
return true;
}

for (\$i = 0; \$i < count(\$this->score); ++\$i) {
if (\$this->player1TargetScore() == \$this->score[\$i]) {
\$this->display("player 1 WIN\n");
\$this->winner = self::PLAYER1;
return true;
}

if (\$this->player2TargetScore() == \$this->score[\$i]) {
\$this->display("player 2 WIN\n");
\$this->winner = self::PLAYER2;
return true;
}
}

return false;
}

private function isValidMove(\$row, \$col) {
return (0 <= \$row && \$row < \$this->gridSize) &&
(0 <= \$col && \$col < \$this->gridSize);
}

private function player1TargetScore() {
return \$this->gridSize * self::PLAYER1_POINT;
}

private function player2TargetScore() {
return \$this->gridSize * self::PLAYER2_POINT;
}

private function display(\$string) {
echo \$string;
}
}

interface MoveInput {
public function getNextMove(\$player);
}

class QueuedMoveInput implements MoveInput {
private \$moves;

public function __construct(\$movesArray) {
\$this->moves = \$movesArray;
}

public function getNextMove(\$player) {
return array_shift(\$this->moves);
}
}

class InteractiveMoveInput implements MoveInput {
public function getNextMove(\$player) {
while(true) {
echo "Please enter next move for player \$player: [row,col] ";
\$line = trim(fgets(STDIN));
list(\$row, \$col) = sscanf(\$line, "%D,%D");
if (is_numeric(\$row) && is_numeric(\$col)) {
return array('player' => \$player, 'row' => \$row, 'col' => \$col);
}
}
}
}

// helpers
function p1(\$row, \$col) {
return array('player' => TicTacToe::PLAYER1, 'row' => \$row, 'col' => \$col);
}

function p2(\$row, \$col) {
return array('player' => TicTacToe::PLAYER2, 'row' => \$row, 'col' => \$col);
}

// TESTING!!!!! ;]

// GAME 1 - testing diagonal (0,0) -> (2,2) win condition
\$game = new TicTacToe();
\$moves = new QueuedMoveInput(array(p1(1,1), p2(0,1), p1(2,0), p2(0,2), p1(0,0), p2(1,0), p1(2,2), p2(2,1)));
\$game->play(\$moves);
assert(\$game->getWinner() == TicTacToe::PLAYER1);

// GAME 2 - using invalid move, testing straight line (0,0) -> (0,2) win condition
\$game = new TicTacToe();
\$moves = new QueuedMoveInput(array(p1(1,1), p2(1,1), p2(2,0), p1(2,1), p2(0,1), p1(2,2), p2(0,0), p1(1,0), p2(0,2)));
\$game->play(\$moves);
assert(\$game->getWinner() == TicTacToe::PLAYER2);

// GAME 3 - testing draw condition
\$game = new TicTacToe();
\$moves = new QueuedMoveInput(array(p1(1,1), p2(2, 2), p1(1,2), p2(1,0), p1(2,0), p2(0,2), p1(0,1), p2(2,1), p1(0,0)));
\$game->play(\$moves);
assert(\$game->getWinner() == NULL);

// GAME 4 - testing diagonal (2,0) -> (0,2) win condition
\$game = new TicTacToe();
\$moves = new QueuedMoveInput(array(p1(2,0), p2(1, 2), p1(0,2), p2(2,2), p1(0,1), p2(0,0), p1(1,1)));
\$game->play(\$moves);
assert(\$game->getWinner() == TicTacToe::PLAYER1);

// GAME 5 - testing straight line (0,0) -> (2,0) win condition
\$game = new TicTacToe();
\$moves = new QueuedMoveInput(array(p2(1,1), p1(0,0), p2(0,2), p1(2,0), p2(2,1), p1(1,0)));
\$game->play(\$moves);
assert(\$game->getWinner() == TicTacToe::PLAYER1);

// GAME 6 - 5x5 grid, testing diagonal (0,0) -> (4,4) win condition
\$game = new TicTacToe(5);
\$moves = new QueuedMoveInput(array(p1(1,1), p2(0,1), p1(2,0), p2(0,2), p1(0,0), p2(1,0), p1(2,2), p2(4,2), p1(3,3), p2(4,3), p1(4,4)));
\$game->play(\$moves);
assert(\$game->getWinner() == TicTacToe::PLAYER1);

// GAME 7 - Interactive game.
\$game = new TicTacToe();
\$game->play(new InteractiveMoveInput());
``````

Hope that helps ;]

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I just got asked this question in a programming interview as well. " Given a tic-tac-toe board, how to check the move was a winning move in CONSTANT time"

it took me well over 20 minutes, but I THINK was able to find the answer and solve it in O(1)

So say let's start with a simple 3 by 3 tic - tac toe board, put a number corresponding to each block on the board 123 456 789

So my answer to the question is pretty simple, HASH all the winning combinations into a Hash table, such as 123, 456, 789, 159 etc...

Have two lists of numbers to keep track of the individual player's move

The alg is described below

``````    So when player_1 puts a X on a square, he will get the corresponding
number into his number list
When player_2 puts a O on a square, he will also get the corresponding
number into his number list.
At the end of every round, look through the Hash table to see if any
of the two players have the winning combination
``````

So I think that's O(1)

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No offense, but given a 3x3 tic-tac-toe board, isn't checking all winning combinations explicitly in the naive way, O(1) time? I mean what the hell would be N unless you let the size of the board change? – Alan Jul 29 '13 at 22:44
The OP says "on a board of any size", so I'd assume `N` is the board's size. I'm not sure if this qualifies as O(1), though, because the number of winning hashes is dependent on the board size `(2N + 2)`, so looking through them still takes O(N) time, same as naive checking. – Bigtoes Aug 29 '13 at 16:01
This solution only works if you can guarantee that your hash function has no collisions. If you cannot, the solution goes to slightly more than O(1). – johnwbyrd Dec 27 '15 at 8:09

This problem, and a bunch of related problems, may be solved in O(1) time, assuming that at least memory regions exist and assuming that a lookup table can be precomputed. This solution does not require previous state tracking, as other answers describe, and the run-time portion of the algorithm doesn't require summing columns or rows, as other answers describe.

Treat the n * n board state as a single integer B. To do this, represent a single cell c at position (x,y) as an integer where = 0 indicates O, = 1 indicates X, and = 2 indicates an empty cell.

Next, represent each square as:

Then, represent the entire board state B as:

Assuming you have represented your board thusly, you can look at memory position B within a pre-computed table that describes the answer to the question given.

This system is referred to as Gödelization, but I've applied the basic concept to tic-tac-toe boards instead of proofs.

The encoding I've provided can represent any n * n tic-tac-toe board configuration compactly, including positions that cannot be arrived at in normal play. However, you can use any unique board encoding method you like, such as strings or arrays, so long as you interpret the board representation as a long, unique integer, indexing into a table of precomputed solutions. This board representation provided also permits go-like handicaps where a player is granted an arbitrary number of free initial moves.

Interestingly, if you have sufficient memory, you may also at this point look up answers to questions such as whether the current game is won or lost with perfect play, which move is ideal from the position, and if the game is a guaranteed win or loss, how many maximum moves exist to the win or loss. This technique is used, importantly, in computer chess; the lookup table everyone uses is referred to as the Nalimov tablebase.

The generalization of tic-tac-toe into any size board, where the player who gets k stones in a row wins, is called the m,n,k game and there are many interesting proofs about this type of game.

tl:dr; if you're going for a speed record, it's nearly impossible to beat the lowly lookup table.

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Your representation of tic-tac-toe board is not really correct. Consider the 3*3 board (n=3) Let's compute the board state B1 for c(x,y) =0 when x=1,y=1; =1 when x=1,y=2; =2 otherwise. B1= 3*(3*0+0)+0 +3*(3*0+1)+1 +the_rest_of_sum = 0 + 4 + the_rest_of_sum = 4 + the_rest_of_sum. Now let's compute the other board state B2 for c(x,y) =1 when x=1,y=1; =0 when x=1,y=2; =2 otherwise. B2= 3*(3*0+0)+1 +3*(3*0+1)+0 +the_rest_of_sum = 1 + 3 + the_rest_of_sum = 4 + the_rest_of_sum. As you can see we've got the same state for different board. – Dimchansky Mar 21 at 15:08
The correct way to encode the board state is to use the following formula for each square S(x,y) = c(x,y)*3^(n*(x-1)+(y-1)) – Dimchansky Mar 21 at 18:34
I've rather got out of the mindset I was in when I wrote this, so I'm gonna go ahead and assume your brain is clearer than mine at the moment and modify. Thanks for the change request. – johnwbyrd Mar 22 at 21:18
``````    class TicTacToe
{

//http://basicalgos.blogspot.com/#!/2012/03/13-test-winning-condition-of-tic-tac.html
//No time for test case

int[,] board = null;

int diag = 0;
int antiDiag = 0;
int[] rows = null;
int[] cols = null;

int diagonalLen = 0;

public TicTacToe(int rowLen, int colLen)
{
board = new int[rowLen, colLen];

rows = new int[rowLen];
cols = new int[colLen];

if (rowLen == colLen)
diag = (int)(rowLen * Math.Sqrt(2));//Square formula
else
diagonalLen = (int)Math.Sqrt(Math.Pow(rowLen, 2) + Math.Pow(colLen, 2));//rectangle formula

}

public bool hasWon(int rowIdx, int colIdx, int player)
{
if (player == 1)
{
rows[rowIdx]++;
cols[colIdx]++;

if (rowIdx == colIdx) diag++;
if (rowIdx + colIdx == rows.Length - 1) antiDiag++;//This is IMPORTANT finding.............

}
else
{
rows[rowIdx]--;
cols[colIdx]--;

if (rowIdx == colIdx) diag--;
if (rowIdx + colIdx == rows.Length - 1) antiDiag--;
}

return diag == diagonalLen || rows[rowIdx] == rows.Length || cols[colIdx] == cols.Length || antiDiag == diagonalLen;
}

public void markOnBoard(int row, int col, int player)
{
if (player == 1)
board[row, col]++;
else
board[row, col]--;
}
}
``````
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you are not answering directly to the question nor explaining the algorithm! – mamdouh alramadan Jan 2 '13 at 0:08