Connect 4 check for a win algorithm

Question

I know there is a lot of of questions regarding connect 4 check for a win. The issue is that most of other algorithms make my program have runtime errors, because they try to access an index outside of my array. My algorithm is like this:

private int checkWin(int[][] gridTable,int rowNum,int colNum, int maxRow, int maxCol) 
{
//  For checking whether any win or lose condition is reached. Returns 1 if win or lose is reached. else returns 0
//  gridTable[][] is the game matrix(can be any number of rows and columns between 4 and 40)
//  colNum is the column number where the last token was placed
//  rowNum is the row number where the last token was placed
//  maxRow is the number of rows in my grid
//  maxCol is the number of columns in my grid

int player = gridTable[rowNum][colNum]; //player ID
int count=0;

// Horizontal check
for (int i=0;i<maxCol;i++)
{
    if (gridTable[rowNum][i]==player)
        count++;
    else
        count=0;

    if (count>=4)
        return 1;
}
//Vertical check
for (int i=0;i<maxRow;i++)
{
    if (gridTable[i][colNum]==player)
        count++;
    else
        count=0;

    if (count>=4)
        return 1;
} 
count=0;
// 4 in a row diagonally
for(int i=colNum+1,j=rowNum+1;i<maxRow && j<maxCol;i++,j++) 
{ 
    if(gridTable[j][i]!=player)
    {
        count=1;
        break;        
    }
    count++;
}
// 4 in a row diagonally
for(int i=colNum-1,j=rowNum-1;i>=0 && j>=0;i--,j--) 
{ 
    if(gridTable[j][i]!=player)
    {
        count=1;
        break;        
    }
    count++;
}
// 4 in a row diagonally
for(int i=colNum+1,j=rowNum-1;i<maxRow && j>=0;i++,j--) 
{ 
    if(gridTable[j][i]!=player)
    {
        count=1;
        break;        
    }
    count++;
}

for(int i=colNum-1,j=rowNum+1;i>=0 && j<maxCol;i--,j++) 
{ // 4 in a row diagonally
    if(gridTable[j][i]!=player)
    {
        count=1;
        break;        
    }
    count++;
}

if(count>=4)
    return 1;

return 0;
}

count is the variable that checks for a win if count is equal or more than 4 means they should be 4 or more consecutive tokens of the same player.

THE PROBLEM: sometimes the method checks for a win without being 4 tokens in order and other times does not check for a win when 4 tokens are in order.

Answer 1

For some reason I am not so fond of counters, so I did it this way (It works for boards with different sizes).

public boolean areFourConnected(int player){

    // horizontalCheck 
    for (int j = 0; j<getHeight()-3 ; j++ ){
        for (int i = 0; i<getWidth(); i++){
            if (this.board[i][j] == player && this.board[i][j+1] == player && this.board[i][j+2] == player && this.board[i][j+3] == player){
                return true;
            }           
        }
    }
    // verticalCheck
    for (int i = 0; i<getWidth()-3 ; i++ ){
        for (int j = 0; j<this.getHeight(); j++){
            if (this.board[i][j] == player && this.board[i+1][j] == player && this.board[i+2][j] == player && this.board[i+3][j] == player){
                return true;
            }           
        }
    }
    // ascendingDiagonalCheck 
    for (int i=3; i<getWidth(); i++){
        for (int j=0; j<getHeight()-3; j++){
            if (this.board[i][j] == player && this.board[i-1][j+1] == player && this.board[i-2][j+2] == player && this.board[i-3][j+3] == player)
                return true;
        }
    }
    // descendingDiagonalCheck
    for (int i=3; i<getWidth(); i++){
        for (int j=3; j<getHeight(); j++){
            if (this.board[i][j] == player && this.board[i-1][j-1] == player && this.board[i-2][j-2] == player && this.board[i-3][j-3] == player)
                return true;
        }
    }
    return false;
}

Answer 2

Looks like your code is correct for the horizontal and vertical cases. The tricky part is the diagonal case.

Let's try a picture:

For the green lines, your starting row position is 0 ... maxRow - 4. The column would be 0 ... startingRow -

Pseudocode:

// top-left to bottom-right - green diagonals
for( rowStart = 0; rowStart < rowMax - 4; rowStart++){
    count = 0;
    int row, col;
    for( row = rowStart, col = 0; row < rowMax && col < colMax; row++, col++ ){
        if(gridTable[row][col] == player){
            count++;
            if(count >= 4) return 1;
        }
        else {
            count = 0;
        }
    }
}

// top-left to bottom-right - red diagonals
for( colStart = 1; colStart < colMax - 4; colStart++){
    count = 0;
    int row, col;
    for( row = 0, col = colStart; row < rowMax && col < colMax; row++, col++ ){
        if(gridTable[row][col] == player){
            count++;
            if(count >= 4) return 1;
        }
        else {
            count = 0;
        }
    }
}

You could do something similar for diagonals going the other way (from bottom-left to top-right).

Answer 3

So, having dug through your code, it would seem that the diagonal check can only win in a single direction (what happens if I add a token to the lowest row and lowest column?)

Instead, the basic check algorithm is always the same process, regardless of which direction you're checking in.

You need a start point (x/y) and x/y delta (direction of movement). You can summarise this down into a single method...

public boolean didWin(int[][] grid, int check, int row, int col, int rowDelta, int colDelta) {

    boolean win = true;
    for (int count = 0; count < 4; count++) {
        if (row < ROWS && row >= 0 && col < COLUMNS && col >= 0) {
            int test = grid[row][col];
            if (test != check) {
                win = false;
                break;
            }
        }
        row += rowDelta;
        col += colDelta;
    }
    return win;

}

This will basically allow you to check in four directions, but also do them backwards

So, if we were to use something like...

int[][] gridTable = new int[ROWS][COLUMNS];

gridTable[ROWS - 1][3] = 1;
gridTable[ROWS - 2][3] = 1;
gridTable[ROWS - 3][3] = 1;
gridTable[ROWS - 4][3] = 1;

System.out.println("Vertical");

System.out.println(didWin(gridTable, 1, ROWS - 4, 3, 1, 0) ? "Win" : "Lose");
System.out.println(didWin(gridTable, 1, ROWS - 1, 3, -1, 0) ? "Win" : "Lose");
System.out.println(didWin(gridTable, 1, 0, 3, 1, 0) ? "Win" : "Lose");

gridTable = new int[ROWS][COLUMNS];
gridTable[3][1] = 1;
gridTable[3][2] = 1;
gridTable[3][3] = 1;
gridTable[3][4] = 1;

System.out.println("");
System.out.println("Horizontal");
System.out.println(didWin(gridTable, 1, 3, 1, 0, 1) ? "Win" : "Lose");
System.out.println(didWin(gridTable, 1, 3, 4, 0, -1) ? "Win" : "Lose");
System.out.println(didWin(gridTable, 1, 3, 0, 0, 1) ? "Win" : "Lose");

gridTable = new int[ROWS][COLUMNS];
gridTable[0][1] = 1;
gridTable[1][2] = 1;
gridTable[2][3] = 1;
gridTable[3][4] = 1;

System.out.println("");
System.out.println("Diag");
System.out.println(didWin(gridTable, 1, 0, 1, 1, 1) ? "Win" : "Lose");
System.out.println(didWin(gridTable, 1, 3, 4, -1, -1) ? "Win" : "Lose");
System.out.println(didWin(gridTable, 1, 1, 2, 1, 1) ? "Win" : "Lose");

Which outputs...

Vertical
Win
Win
Lose

Horizontal
Win
Win
Lose

Diag
Win
Win
Lose

Now, you could just summarise it down to...

public boolean didWin(int[][] grid, int check, int row, int col) {
    return didWin(grid, check, row, col, 1, 0) ||
                    didWin(grid, check, row, col, -1, 0) ||
                    didWin(grid, check, row, col, 0, 1) ||
                    didWin(grid, check, row, col, 0, -1) ||
                    didWin(grid, check, row, col, 1, 1) ||
                    didWin(grid, check, row, col, -1, -1) ||
                    didWin(grid, check, row, col, -1, 1) ||
                    didWin(grid, check, row, col, 1, -1);
}

So, using something like...

int[][] gridTable = new int[ROWS][COLUMNS];

gridTable[ROWS - 1][3] = 1;
gridTable[ROWS - 2][3] = 1;
gridTable[ROWS - 3][3] = 1;
gridTable[ROWS - 4][3] = 1;

System.out.println("Vertical");

System.out.println(didWin(gridTable, 1, ROWS - 1, 3) ? "Win" : "Lose");
System.out.println(didWin(gridTable, 1, ROWS - 4, 3) ? "Win" : "Lose");

gridTable = new int[ROWS][COLUMNS];
gridTable[3][1] = 1;
gridTable[3][2] = 1;
gridTable[3][3] = 1;
gridTable[3][4] = 1;

System.out.println("");
System.out.println("Horizontal");
System.out.println(didWin(gridTable, 1, 3, 1) ? "Win" : "Lose");
System.out.println(didWin(gridTable, 1, 3, 4) ? "Win" : "Lose");

gridTable = new int[ROWS][COLUMNS];
gridTable[0][1] = 1;
gridTable[1][2] = 1;
gridTable[2][3] = 1;
gridTable[3][4] = 1;

System.out.println("");
System.out.println("Diag");
System.out.println(didWin(gridTable, 1, 0, 1) ? "Win" : "Lose");
System.out.println(didWin(gridTable, 1, 3, 4) ? "Win" : "Lose");

Which prints out something like...

Vertical
Win
Win

Horizontal
Win
Win

Diag
Win
Win

I would add that this approach does only work if you provide the correct start of the 4 chips on a row. For example didWin(gridTable, 1, 3, 3) will provide false instead of true for your horizontal check, because the loop can only check one direction.

The intention wasn't to provide a "full fledged, out of the box" solution, but a concept from which a broader solution could be developed (I mean, I'd hate for people to actually have to think ;)). I also designed the solution based on the idea that the OP would know where the last piece was placed, ie, the starting point ;)

By modifying the didWin method ever so slightly, it's possible to check a n by n grid from any point...

public boolean didWin(int[][] grid, int check, int row, int col, int rowDelta, int colDelta) {
    boolean match = false;
    int matches = 0;
    while (row < ROWS && row >= 0 && col < COLUMNS && col >= 0) {
        int test = grid[row][col];
        if (test != check && match) {
            break;
        } else if (test == check) {
            match = true;
            matches++;
        }
        row += rowDelta;
        col += colDelta;
    }
    return matches == 4;
}

So, I used...

public static final int ROWS = 8;
public static final int COLUMNS = 8;
//...
int[][] gridTable = new int[ROWS][COLUMNS];

gridTable[ROWS - 1][3] = 1;
gridTable[ROWS - 2][3] = 1;
gridTable[ROWS - 3][3] = 1;
gridTable[ROWS - 4][3] = 1;
for (int[] row : gridTable) {
    StringJoiner sj = new StringJoiner("|", "|", "|");
    for (int col : row) {
        sj.add(Integer.toString(col));
    }
    System.out.println(sj);
}
System.out.println(didWin(gridTable, 1, 3, 3));

and was able to get it to work. Sometimes an answer isn't a complete solution, but a seed for an idea which takes someone to a new place ;)

A further enhancement would include providing the number of expected conjoined pieces, but I'm pretty sure that's an enhancement I really don't need to demonstrate ;)

Answer 4

I did my own version in the C language and I think that it's quite easy to reinterpret in another language.

//Return values: 1 for Player 1, 2 for Player 2 and 0 for a tie.
// '-' represents an empty tile, 'X' Player 1, 'O' Player 2
#include <stddef.h>

int connect4(char *game[], size_t columns, size_t lines)
{
    int winner = -1;
    for (size_t l = 0; l < lines; l++)
    {
        for (size_t c = 0; c < columns; c++)
        {
            char player = game[l][c];
            if (player == '-')
                continue;
            if (c + 3 < columns && player == game[l][c + 1]
                && player == game[l][c + 2] && player == game[l][c + 3])
                winner = winner < 0 ? player : 0;
            if (l + 3 < lines && player == game[l + 1][c]
                && player == game[l + 2][c] && player == game[l + 3][c])
                winner = winner < 0 ? player : 0;
            if (c + 3 < columns && l + 3 < lines && player == game[l + 1][c + 1]
                && player == game[l + 2][c + 2] && player == game[l + 3][c + 3])
                winner = winner < 0 ? player : 0;
            if (c >= 3 && l + 3 < lines && player == game[l + 1][c - 1]
                && player == game[l + 2][c - 2] && player == game[l + 3][c - 3])
                winner = winner < 0 ? player : 0;
        }
    }
    if (winner < 1)
        return 0;
    else
        return winner == 88 ? 1 : 2;
}

Answer 5

If someone still needs the solution, I write a function in c# and put in GitHub repo.

/// <summary>
    /// WinnerCalc check if blue or red win the game.
    /// </summary>
    /// <returns>Return 1 if 1 win and 2 if 2 win and -1 if no one win.</returns>
    /// <param name="matrix">2d array</param>
    /// <param name="lastRow">The row number.</param>
    /// <param name="lastColumn">The column number.</param>
    public static int WinnerCalc(int[,] matrix, int lastRow, int lastColumn)
    {
        int lastValue = matrix[lastRow, lastColumn];
        Console.WriteLine("drop in row: " + (lastRow) + " and column: " + (lastColumn) + " , the value is: " + lastValue);
        int rows = matrix.GetLength(0); //6
        int columns = matrix.GetLength(1); //7
        Console.WriteLine("number of rows is " + rows + ", and number of colums is " + columns);

        int numToWin = 4;
        int winner = -1;//is now one win tha game
        int match;

        match = 0;
        //check Horizontal
        for (int c = 0; c < columns; c++)
        {
            int currentValue = matrix[lastRow, c];
            if (currentValue == lastValue)
                match++;
            else match = 0;
            if(match == numToWin)
            {
                winner = lastValue;
                break;
            }
        }
        if (winner != -1)
        {
            Console.WriteLine("win Horizontal !");
            return winner;
        }

        match = 0;
        //check Vertical
        for (int r = 0; r < rows; r++)
        {
            int currentValue = matrix[r, lastColumn];
            if (currentValue == lastValue)
                match++;
            else match = 0;
            if (match == numToWin)
            {
                winner = lastValue;
                break;
            }
        }
        if (winner != -1)
        {
            Console.WriteLine("win Vertical !");
            return winner;
        }

        //check diagonal top-left to bottom-right - include middle
        match = 0;
        for (int r = 0; r <= rows - 4; r++)
        {
            int rowPosition = r;
            for (int column = 0; column < columns && rowPosition < rows; column++)
            {
                int currentValue = matrix[rowPosition, column];
                if (currentValue == lastValue)
                    match++;
                else match = 0;
                if (match == numToWin)
                {
                    winner = lastValue;
                    break;
                }
                rowPosition++;
            }
            if (winner != -1) break;
        }
        if (winner != -1)
        {
            Console.WriteLine("win Diagonal Top left! - include middle");
            return winner;
        }

        //check diagonal top-left to bottom-right - after middle
        match = 0;
        for (int c = 1; c <= columns - 4; c++)
        {
            int columnPosition = c;
            for (int row = 0; row < rows && columnPosition < columns; row++)
            {
                int currentValue = matrix[row, columnPosition];
                if (currentValue == lastValue)
                    match++;
                else match = 0;
                if (match == numToWin)
                {
                    winner = lastValue;
                    break;
                }
                columnPosition++;
            }
            if (winner != -1) break;
        }
        if (winner != -1)
        {
            Console.WriteLine("win Diagonal Top left! - after middle");
            return winner;
        }


        //check diagonal bottom-left to top-right - include middle
        match = 0;
        for (int r = rows - 1; r >= rows - 4; r--)
        {
            int rowPosition = r;
            for (int column = 0; column < columns && rowPosition < rows && rowPosition >= 0; column++)
            {
                int currentValue = matrix[rowPosition, column];
                if (currentValue == lastValue)
                    match++;
                else match = 0;
                if (match == numToWin)
                {
                    winner = lastValue;
                    break;
                }
                rowPosition--;
            }
            if (winner != -1) break;
        }
        if (winner != -1)
        {
            Console.WriteLine("win Diagonal Bottom left! - include middle");
            return winner;
        }


        //check diagonal bottom-left to top-right - after middle
        match = 0;
        for (int c = 1; c < columns; c++)
        {
            int columnPosition = c;
            for (int row = rows - 1; row < rows && columnPosition < columns && columnPosition >= 1; row--)
            {
                int currentValue = matrix[row, columnPosition];
                if (currentValue == lastValue)
                    match++;
                else match = 0;
                if (match == numToWin)
                {
                    winner = lastValue;
                    break;
                }
                columnPosition++;
            }
            if (winner != -1) break;
        }
        if (winner != -1)
        {
            Console.WriteLine("win Diagonal Bottom left! - after middle");
            return winner;
        }



        return winner; // no winner return -1
    }

}

and this is the repo: https://github.com/JoshK2/connect-four-winner

Answer 6

this is what worked for me, it also did not take as long as it seems:
these are methods with row, column, diagonal, and anti-diagonal for x and o ;

public static void checkVertO(){
    if (board[0][0] == 'O' && board[1][0] == 'O' && board[2][0] == 'O' && board[3][0] == 'O' || board[1][0] == 'O' && board[2][0] == 'O' && board[3][0] == 'O' && board[4][0] == 'O' ||
    board[2][0] == 'O' && board[3][0] == 'O' && board[4][0] == 'O' && board[5][0] == 'O' || board[0][1] == 'O' && board[1][1] == 'O' && board[2][1] == 'O' && board[3][1] == 'O' || 
    board[1][1] == 'O' && board[2][1] == 'O' && board[3][1] == 'O' && board[4][1] == 'O' || board[2][1] == 'O' && board[3][1] == 'O' && board[4][1] == 'O' && board[5][1] == 'O' || 
    board[0][2] == 'O' && board[1][2] == 'O' && board[2][2] == 'O' && board[3][2] == 'O' || board[1][2] == 'O' && board[2][2] == 'O' && board[3][2] == 'O' && board[4][2] == 'O' ||
    board[2][2] == 'O' && board[3][2] == 'O' && board[4][2] == 'O' && board[5][2] == 'O' || board[0][3] == 'O' && board[1][3] == 'O' && board[2][3] == 'O' && board[3][3] == 'O' || 
    board[1][3] == 'O' && board[2][3] == 'O' && board[3][3] == 'O' && board[4][3] == 'O' || board[2][3] == 'O' && board[3][3] == 'O' && board[4][3] == 'O' && board[5][3] == 'O' ||
    board[0][4] == 'O' && board[1][4] == 'O' && board[2][4] == 'O' && board[3][4] == 'O' || board[1][4] == 'O' && board[2][4] == 'O' && board[3][4] == 'O' && board[4][4] == 'O' ||
    board[2][4] == 'O' && board[3][4] == 'O' && board[4][4] == 'O' && board[5][4] == 'O' || board[0][5] == 'O' && board[1][5] == 'O' && board[2][5] == 'O' && board[3][5] == 'O' || 
    board[1][5] == 'O' && board[2][5] == 'O' && board[3][5] == 'O' && board[4][5] == 'O' || board[2][5] == 'O' && board[3][5] == 'O' && board[4][5] == 'O' && board[5][5] == 'O' ||
    board[0][6] == 'O' && board[1][6] == 'O' && board[2][6] == 'O' && board[3][6] == 'O' || board[1][6] == 'O' && board[2][6] == 'O' && board[3][6] == 'O' && board[4][6] == 'O'||
    board[2][6] == 'O' && board[3][6] == 'O' && board[4][6] == 'O' && board[5][6] == 'O'){
        System.out.println("Game over, O won.");
        printBoard();
        doIt();
    }else {
        return;
    }
}

public static void checkHorzO(){
    if (board[0][0] == 'O' && board[0][1] == 'O' && board[0][2] == 'O' && board[0][3] == 'O' || board[0][1] == 'O' && board[0][2] == 'O' && board[0][3] == 'O' && board[0][4] == 'O' ||
    board[0][2] == 'O' && board[0][3] == 'O' && board[0][4] == 'O' && board[0][5] == 'O' || board[0][3] == 'O' && board[0][4] == 'O' && board[0][5] == 'O' && board[0][6] == 'O' ||
    board[1][0] == 'O' && board[1][1] == 'O' && board[1][2] == 'O' && board[1][3] == 'O' || board[1][1] == 'O' && board[1][2] == 'O' && board[1][3] == 'O' && board[1][4] == 'O' ||
    board[1][2] == 'O' && board[1][3] == 'O' && board[1][4] == 'O' && board[1][5] == 'O' || board[1][3] == 'O' && board[1][4] == 'O' && board[1][5] == 'O' && board[1][6] == 'O' ||
    board[2][0] == 'O' && board[2][1] == 'O' && board[2][2] == 'O' && board[2][3] == 'O' || board[2][1] == 'O' && board[2][2] == 'O' && board[2][3] == 'O' && board[2][4] == 'O' ||
    board[2][2] == 'O' && board[2][3] == 'O' && board[2][4] == 'O' && board[2][5] == 'O' || board[2][3] == 'O' && board[2][4] == 'O' && board[2][5] == 'O' && board[2][6] == 'O' ||
    board[3][0] == 'O' && board[3][1] == 'O' && board[3][2] == 'O' && board[3][3] == 'O' || board[3][1] == 'O' && board[3][2] == 'O' && board[3][3] == 'O' && board[3][4] == 'O' ||
    board[3][2] == 'O' && board[3][3] == 'O' && board[3][4] == 'O' && board[3][5] == 'O' || board[3][3] == 'O' && board[3][4] == 'O' && board[3][5] == 'O' && board[3][6] == 'O' ||
    board[4][0] == 'O' && board[4][1] == 'O' && board[4][2] == 'O' && board[4][3] == 'O' || board[4][1] == 'O' && board[4][2] == 'O' && board[4][3] == 'O' && board[4][4] == 'O' ||
    board[4][2] == 'O' && board[4][3] == 'O' && board[4][4] == 'O' && board[4][5] == 'O' || board[4][3] == 'O' && board[4][4] == 'O' && board[4][5] == 'O' && board[4][6] == 'O' ||
    board[5][0] == 'O' && board[5][1] == 'O' && board[5][2] == 'O' && board[5][3] == 'O' || board[5][1] == 'O' && board[5][2] == 'O' && board[5][3] == 'O' && board[5][4] == 'O' ||
    board[5][2] == 'O' && board[5][3] == 'O' && board[5][4] == 'O' && board[5][5] == 'O' || board[5][3] == 'O' && board[5][4] == 'O' && board[5][5] == 'O' && board[5][6] == 'O' ){
        System.out.println("Game over, O won.");
        printBoard();
        doIt();
    }else {
        return;
    }
}

public static void checkHorzX(){
    if (board[0][0] == 'X' && board[0][1] == 'X' && board[0][2] == 'X' && board[0][3] == 'X' || board[0][1] == 'X' && board[0][2] == 'X' && board[0][3] == 'X' && board[0][4] == 'X' ||
    board[0][2] == 'X' && board[0][3] == 'X' && board[0][4] == 'X' && board[0][5] == 'X' || board[0][3] == 'X' && board[0][4] == 'X' && board[0][5] == 'X' && board[0][6] == 'X' ||
    board[1][0] == 'X' && board[1][1] == 'X' && board[1][2] == 'X' && board[1][3] == 'X' || board[1][1] == 'X' && board[1][2] == 'X' && board[1][3] == 'X' && board[1][4] == 'X' ||
    board[1][2] == 'X' && board[1][3] == 'X' && board[1][4] == 'X' && board[1][5] == 'X' || board[1][3] == 'X' && board[1][4] == 'X' && board[1][5] == 'X' && board[1][6] == 'X' ||
    board[2][0] == 'X' && board[2][3] == 'X' && board[2][4] == 'X' && board[2][5] == 'X' || board[2][3] == 'X' && board[2][4] == 'X' && board[2][5] == 'X' && board[2][6] == 'X' ||
    board[3][0] == 'X' && board[3][1] == 'X' && board[3][2] == 'X' && board[3][3] == 'X' || board[3][1] == 'X' && board[3][2] == 'X' && board[3][3] == 'X' && board[3][4] == 'X' ||
    board[3][2] == 'X' && board[3][3] == 'X' && board[3][4] == 'X' && board[3][5] == 'X' || board[3][3] == 'X' && board[3][4] == 'X' && board[3][5] == 'X' && board[3][6] == 'X' ||
    board[4][0] == 'X' && board[4][3] == 'X' && board[4][4] == 'X' && board[4][5] == 'X' || board[4][3] == 'X' && board[4][4] == 'X' && board[4][5] == 'X' && board[4][6] == 'X' ||
    board[5][0] == 'X' && board[5][1] == 'X' && board[5][2] == 'X' && board[5][3] == 'X' || board[5][1] == 'X' && board[5][2] == 'X' && board[5][3] == 'X' && board[5][4] == 'X' ||
    board[5][2] == 'X' && board[5][3] == 'X' && board[5][4] == 'X' && board[5][5] == 'X' || board[5][3] == 'X' && board[5][4] == 'X' && board[5][5] == 'X' && board[5][6] == 'X' ){
        System.out.println("Game over, X won.");
        printBoard();
        doIt();
    }else {
        return;
    }
}

public static void checkDiagX(){
    if (board[2][0] == 'X' && board[3][1] == 'X' && board[4][2] == 'X' && board[5][3] == 'X'|| board[1][0] == 'X' && board[2][1] == 'X' && board[3][2] == 'X' && board[4][3] == 'X'||
    board[0][0] == 'X' && board[1][1] == 'X' && board[2][2] == 'X' && board[3][3] == 'X'|| board[0][1] == 'X' && board[1][2] == 'X' && board[2][3] == 'X' && board[3][4] == 'X'||
    board[1][1] == 'X' && board[2][2] == 'X' && board[3][3] == 'X' && board[4][4] == 'X'|| board[2][1] == 'X' && board[3][2] == 'X' && board[4][3] == 'X' && board[5][4] == 'X'||
    board[0][2] == 'X' && board[1][3] == 'X' && board[2][4] == 'X' && board[3][5] == 'X'|| board[1][2] == 'X' && board[2][3] == 'X' && board[3][4] == 'X' && board[4][5] == 'X'||
    board[2][2] == 'X' && board[3][3] == 'X' && board[4][4] == 'X' && board[5][5] == 'X'|| board[0][3] == 'X' && board[1][4] == 'X' && board[2][5] == 'X' && board[3][6] == 'X'||
    board[1][3] == 'X' && board[2][4] == 'X' && board[3][5] == 'X' && board[4][6] == 'X'|| board[2][3] == 'X' && board[3][4] == 'X' && board[4][5] == 'X' && board[5][6] == 'X'){
        System.out.println("Game over, X won.");
        printBoard();
        doIt();
    }else {
        return;
    }
}

public static void checkDiagO(){
    if (board[2][0] == 'O' && board[3][1] == 'O' && board[4][2] == 'O' && board[5][3] == 'O'|| board[1][0] == 'O' && board[2][1] == 'O' && board[3][2] == 'O' && board[4][3] == 'O'||
    board[0][0] == 'O' && board[1][1] == 'O' && board[2][2] == 'O' && board[3][3] == 'O'|| board[0][1] == 'O' && board[1][2] == 'O' && board[2][3] == 'O' && board[3][4] == 'O'||
    board[1][1] == 'O' && board[2][2] == 'O' && board[3][3] == 'O' && board[4][4] == 'O'|| board[2][1] == 'O' && board[3][2] == 'O' && board[4][3] == 'O' && board[5][4] == 'O'||
    board[0][2] == 'O' && board[1][3] == 'O' && board[2][4] == 'O' && board[3][5] == 'O'|| board[1][2] == 'O' && board[2][3] == 'O' && board[3][4] == 'O' && board[4][5] == 'O'||
    board[2][2] == 'O' && board[3][3] == 'O' && board[4][4] == 'O' && board[5][5] == 'O'|| board[0][3] == 'O' && board[1][4] == 'O' && board[2][5] == 'O' && board[3][6] == 'O'||
    board[1][3] == 'O' && board[2][4] == 'O' && board[3][5] == 'O' && board[4][6] == 'O'|| board[2][3] == 'O' && board[3][4] == 'O' && board[4][5] == 'O' && board[5][6] == 'O'){
        System.out.println("Game over, O won.");
        printBoard();
        doIt();
    }else {
        return;
    }
}

public static void checkAntiDiagX(){
    if (board[3][0] == 'X' && board[2][1] == 'X' && board[1][2] == 'X' && board[0][3] == 'X'|| board[4][0] == 'X' && board[3][1] == 'X' && board[2][2] == 'X' && board[1][3] == 'X'||
    board[3][1] == 'X' && board[2][2] == 'X' && board[1][3] == 'X' && board[0][4] == 'X'|| board[5][0] == 'X' && board[4][1] == 'X' && board[3][2] == 'X' && board[2][3] == 'X'||        
    board[4][1] == 'X' && board[3][2] == 'X' && board[2][3] == 'X' && board[1][4] == 'X'|| board[3][2] == 'X' && board[2][2] == 'X' && board[1][4] == 'X' && board[0][5] == 'X'||
    board[5][1] == 'X' && board[4][2] == 'X' && board[3][3] == 'X' && board[2][4] == 'X'|| board[4][2] == 'X' && board[3][3] == 'X' && board[2][4] == 'X' && board[1][5] == 'X'||
    board[3][3] == 'X' && board[2][4] == 'X' && board[1][5] == 'X' && board[0][6] == 'X'|| board[5][2] == 'X' && board[4][3] == 'X' && board[3][4] == 'X' && board[2][5] == 'X'||
    board[4][3] == 'X' && board[3][4] == 'X' && board[2][5] == 'X' && board[1][6] == 'X'|| board[5][3] == 'X' && board[4][4] == 'X' && board[3][5] == 'X' && board[2][6] == 'X'){
        System.out.println("Game over, X won.");
        printBoard();
        doIt();
    }else {
        return;
    }
}

 public static void checkAntiDiagO(){
    if (board[3][0] == 'O' && board[2][1] == 'O' && board[1][2] == 'O' && board[0][3] == 'O'|| board[4][0] == 'O' && board[3][1] == 'O' && board[2][2] == 'O' && board[1][3] == 'O'||
    board[3][1] == 'O' && board[2][2] == 'O' && board[1][3] == 'O' && board[0][4] == 'O'|| board[5][0] == 'O' && board[4][1] == 'O' && board[3][2] == 'O' && board[2][3] == 'O'||        
    board[4][1] == 'O' && board[3][2] == 'O' && board[2][3] == 'O' && board[1][4] == 'O'|| board[3][2] == 'O' && board[2][2] == 'O' && board[1][4] == 'O' && board[0][5] == 'O'||
    board[5][1] == 'O' && board[4][2] == 'O' && board[3][3] == 'O' && board[2][4] == 'O'|| board[4][2] == 'O' && board[3][3] == 'O' && board[2][4] == 'O' && board[1][5] == 'O'||
    board[3][3] == 'O' && board[2][4] == 'O' && board[1][5] == 'O' && board[0][6] == 'O'|| board[5][2] == 'O' && board[4][3] == 'O' && board[3][4] == 'O' && board[2][5] == 'O'||
    board[4][3] == 'O' && board[3][4] == 'O' && board[2][5] == 'O' && board[1][6] == 'O'|| board[5][3] == 'O' && board[4][4] == 'O' && board[3][5] == 'O' && board[2][6] == 'O'){
        System.out.println("Game over, O won.");
        printBoard();
        doIt();
    }else {
        return;
    }
}