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I am working on a python project where I generate every possible tic-tac-toe game, and then draw conclusions, based on those games (ie. what is the best first move, in order to win the most games). I have a function to generate a possible game, then append two arrays with that game, one if the game is winning, and one for every single game. When I append the arrays, and print the last element in those arrays, I get the game that was just generated. However, once the function finished, and I check the arrays, they are all filled with multiples of the same element. My code is below:

print("running...")

allGames = []
winningGames = []
winningFirstMoves = [0] * 9

wins = {
        "top horizontal": 0,
        "middle horizontal": 0,
        "bottom horizontal": 0,
        "left vertical": 0,
        "middle vertical": 0,
        "right vertical": 0,
        "backward diagonal": 0,
        "forward diagonal": 0
    }

def checkFirstMove():
    print("checking winning first moves...")
    global winningGames
    global winningFirstMoves
    for game in winningGames:
        print(game) #this line is only here to test, I know it slows it down
        for move in range(len(game)):
            if (game[move][1] == 1):
                winningFirstMoves[move] += 1

def checkWin(gameToCheck):
    if (gameToCheck[0][0] == gameToCheck[1][0] == gameToCheck[2][0] and gameToCheck[0][0] != 10):
        wins["top horizontal"] += 1
        return "top horizontal"
    elif (gameToCheck[3][0] == gameToCheck[4][0] == gameToCheck[5][0] and gameToCheck[3][0] != 10):
        wins["middle horizontal"] += 1
        return "middle horizontal"
    elif (gameToCheck[6][0] == gameToCheck[7][0] == gameToCheck[8][0] and gameToCheck[6][0] != 10):
        wins["bottom horizontal"] += 1
        return "bottom horizontal"
    elif (gameToCheck[0][0] == gameToCheck[3][0] == gameToCheck[6][0] and gameToCheck[0][0] != 10):
        wins["left vertical"] += 1
        return "left vertical"
    elif (gameToCheck[1][0] == gameToCheck[4][0] == gameToCheck[7][0] and gameToCheck[1][0] != 10):
        wins["middle vertical"] += 1
        return "middle vertical"
    elif (gameToCheck[2][0] == gameToCheck[5][0] == gameToCheck[8][0] and gameToCheck[2][0] != 10):
        wins["right vertical"] += 1
        return "right vertical"
    elif (gameToCheck[0][0] == gameToCheck[4][0] == gameToCheck[8][0] and gameToCheck[0][0] != 10):
        wins["backward diagonal"] += 1
        return "backward diagonal"
    elif (gameToCheck[2][0] == gameToCheck[4][0] == gameToCheck[6][0] and gameToCheck[2][0] != 10):
        wins["forward diagonal"] += 1
        return "forward diagonal"
    else: return False

def cleanGame(gameToClean, moveNumber):
    for j in range(9):
        if (gameToClean[j][1] >= moveNumber):
            gameToClean[j] = [None, 0]

def generateGames():
    global allGames
    global winningGames
    currentGame= [[None, 0], [None, 0], [None, 0], [None, 0], [None, 0], [None, 0], [None, 0], [None, 0], [None, 0]]

    for a in range(9):
        if (a == 0):
            print("generating games.", end="")
        elif (a == 8):
            print(".")
        else:
            print(".", end="")
        cleanGame(currentGame, 1)
        currentGame[a] = [1, 1]
        for b in range(9):
            cleanGame(currentGame, 2)
            if (currentGame[b] == [None, 0]):
                currentGame[b] = [0, 2]
                for c in range(9):
                    cleanGame(currentGame, 3)
                    if (currentGame[c] == [None, 0]):
                        currentGame[c] = [1, 3]
                        for d in range(9):
                            cleanGame(currentGame, 4)
                            if (currentGame[d] == [None, 0]):
                                currentGame[d] = [0, 4]
                                for e in range(9):
                                    cleanGame(currentGame, 5)
                                    if (currentGame[e] == [None, 0]):
                                        currentGame[e] = [1, 5]
                                        if (checkWin(currentGame) != False):
                                            winningGames.append(currentGame)
                                            allGames.append(currentGame)
                                        else:
                                            for f in range(9):
                                                cleanGame(currentGame, 6)
                                                if (currentGame[f] == [None, 0]):
                                                    currentGame[f] = [0, 6]
                                                    if (checkWin(currentGame) != False):
                                                        winningGames.append(currentGame)
                                                        allGames.append(currentGame)
                                                    else:
                                                        for g in range(9):
                                                            cleanGame(currentGame, 7)
                                                            if (currentGame[g] == [None, 0]):
                                                                currentGame[g] = [1, 7]
                                                                if (checkWin(currentGame) != False):
                                                                    winningGames.append(currentGame)
                                                                    allGames.append(currentGame)
                                                                else:
                                                                    for h in range(9):
                                                                        cleanGame(currentGame, 8)
                                                                        if (currentGame[h] == [None, 0]):
                                                                            currentGame[h] = [0, 8]
                                                                            if (checkWin(currentGame) != False):
                                                                                winningGames.append(currentGame)
                                                                                allGames.append(currentGame)
                                                                            else:
                                                                                for i in range(9):
                                                                                    cleanGame(currentGame, 9)
                                                                                    if (currentGame[i] == [None, 0]):
                                                                                        currentGame[i] = [1, 9]
                                                                                        allGames.append(currentGame)
                                                                                        if (checkWin(currentGame) != False):
                                                                                            winningGames.append(currentGame)

generateGames()

print("Number of Possible Games:", len(allGames))
print("Number of Winning  Games:", len(winningGames))

checkFirstMove()

print(winningFirstMoves)

print("completed...")

A normal game would look something like this:

[[1, 1], [0, 2], [None, 0], [1, 3], [0, 4], [0, 6], [1, 7], [None, 0], [1, 5]]

However after the function completes, the arrays are filled with:

[[None, 0], [None, 0], [None, 0], [None, 0], [None, 0], [None, 0], [None, 0], [None, 0], [1, 1]]

How can I fix this?

  • @Jayjayyy I definitely will! I tried for quite a while to get this working using recursion, but wasn't able to. That's why I'm using nested for loops – Luke Schultz Dec 11 '18 at 20:25
  • 1
    use a debugger to go line by line, following what values are stored and maybe you see where it's getting hung up – chitown88 Dec 11 '18 at 20:26
1

Idea:

I changed the format of the data which stores the game information to a tuple which consists of two elements:

  1. The first element is a list which contains the sequence of player moves. We don't need to store which player is at which position because the order is always the same: first player, then second player, then first player again, and so on. So every odd element index is a move from the first player, every even element index from the second player. The board is indexed from left to right and top to bottom:

    [0][1][2]
    [3][4][5]
    [6][7][8]
    

    Example for some first 4 moves:

    [0, 2, 8, 4]
    

    Assuming X is the first player and O is the second player:

    [X][ ][ ]    [X][ ][O]    [X][ ][O]    [X][ ][O]
    [ ][ ][ ] -> [ ][ ][ ] -> [ ][ ][ ] -> [ ][O][ ]
    [ ][ ][ ]    [ ][ ][ ]    [ ][ ][X]    [ ][ ][X]
    
  2. The second element is the game outcome encoded as an integer: 0 for draw, 1 for first player win, 2 for second player win.


Example:

Again, assuming X is the first player and O is the second player. Examples:

                                      [X][O][X]
([0, 1, 2, 3, 4, 5, 6], 1)        ->  [O][X][O]  ->  First player won
                                      [X][ ][ ]

                                      [X][O][X]
([0, 1, 2, 3, 8, 7, 6, 4], 2)     ->  [O][O][ ]  ->  Second player won
                                      [X][O][X]

                                      [X][O][X]
([0, 1, 3, 8, 2, 6, 7, 4, 5], 0)  ->  [X][O][X]  ->  Draw
                                      [O][X][O]

Implementation:

def draw_board(board):
    template = ("[{}]" * 3 + "\n") * 3
    print(template.format(*board))

def has_winner(sequence):
    board = [" "] * 9
    for n, move in enumerate(sequence):
        board[move] = "X" if n % 2 == 0 else "O"
    #draw_board(board)
    tests = [
        board[0] == board[1] == board[2] != " ",
        board[3] == board[4] == board[5] != " ",
        board[6] == board[7] == board[8] != " ",
        board[0] == board[3] == board[6] != " ",
        board[1] == board[4] == board[7] != " ",
        board[2] == board[5] == board[8] != " ",
        board[0] == board[4] == board[8] != " ",
        board[2] == board[4] == board[6] != " ",
    ]
    return any(tests)

def no_moves_left(sequence):
    return len(sequence) == 9

def generate_games(sequence):
    if has_winner(sequence):
        winner = 2 - len(sequence) % 2
        return [(sequence, winner)]
    if no_moves_left(sequence):
        return [(sequence, 0)]
    games = []
    open_spaces = [i for i in range(9) if i not in sequence]
    for new_move in open_spaces:
        new_sequence = sequence.copy()
        new_sequence.append(new_move)
        new_games = generate_games(new_sequence)
        games.extend(new_games)
    return games

games = generate_games([])

This implementation is definitely not fully optimized! However, I think it's fast enough while still maintaining a simple code structure.


Minimal statistics:

statistics = [[0] * 9 for _ in range(3)]
for sequence, outcome in games:
    statistics[outcome][sequence[0]] += 1
print(*statistics, sep="\n")

Output:

[5184, 5184, 5184, 5184, 4608, 5184, 5184, 5184, 5184]
[14652, 14232, 14652, 14232, 15648, 14232, 14652, 14232, 14652]
[7896, 10176, 7896, 10176, 5616, 10176, 7896, 10176, 7896]

Plotting:

import matplotlib.pyplot as plt
import numpy as np

colors = "#6bc86b", "#5a9bd3", "#ed7d33"
labels = "Draw", "First player wins", "Second player wins"
explode = 0.05, 0.05, 0.05
data = list(map(sum, statistics))
plt.pie(data, colors=colors, labels=labels, explode=explode,
    autopct="%1.1f%%", shadow=True)
plt.axis("equal")
plt.title("Outcome for all {} possible Tic-tac-toe games".format(sum(data)))
plt.show()
plt.close()

colors = "#6bc86b", "#5a9bd3", "#ed7d33"
labels = "Draw", "Win", "Lose"
width = 0.3
for i, (data, color, label) in enumerate(zip(statistics, colors, labels)):
    index = [j + i * width for j in range(9)]
    plt.bar(index, data, width, color=color, label=label)
plt.xlabel("Space of the first move")
plt.ylabel("Number of games")
plt.title("Outcome depending on first player's first move")
plt.xticks([i + width for i in range(9)])
plt.gca().set_xticklabels(map(str, range(9)))
plt.legend()
plt.tight_layout()
plt.show()
plt.close()

Output:

pie chart

bar chart

  • 1
    @Luke Schultz Of course, you can add further code to analyze which was the most valuable first move for either player and so on. All the data is available in games. Let me know if I should explain something from the implementation. :-) – finefoot Dec 11 '18 at 22:17
  • 1
    Thank you so much for such a thorough answer!! This has helped me solve more than just the problem I asked in my question, and I've made more progress on this progress in the past day than the past two weeks – Luke Schultz Dec 13 '18 at 20:10

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