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connect4_with_ai.py
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connect4_with_ai.py
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import numpy as np
import random
import pygame
import sys
import math
BLUE = (0,0,255)
BLACK = (0,0,0)
RED = (255,0,0)
YELLOW = (255,255,0)
ROW_COUNT = 6
COLUMN_COUNT = 7
PLAYER = 0
AI = 1
EMPTY = 0
PLAYER_PIECE = 1
AI_PIECE = 2
WINDOW_LENGTH = 4
def create_board():
board = np.zeros((ROW_COUNT,COLUMN_COUNT))
return board
def drop_piece(board, row, col, piece):
board[row][col] = piece
def is_valid_location(board, col):
return board[ROW_COUNT-1][col] == 0
def get_next_open_row(board, col):
for r in range(ROW_COUNT):
if board[r][col] == 0:
return r
def print_board(board):
print(np.flip(board, 0))
def winning_move(board, piece):
# Check horizontal locations for win
for c in range(COLUMN_COUNT-3):
for r in range(ROW_COUNT):
if board[r][c] == piece and board[r][c+1] == piece and board[r][c+2] == piece and board[r][c+3] == piece:
return True
# Check vertical locations for win
for c in range(COLUMN_COUNT):
for r in range(ROW_COUNT-3):
if board[r][c] == piece and board[r+1][c] == piece and board[r+2][c] == piece and board[r+3][c] == piece:
return True
# Check positively sloped diaganols
for c in range(COLUMN_COUNT-3):
for r in range(ROW_COUNT-3):
if board[r][c] == piece and board[r+1][c+1] == piece and board[r+2][c+2] == piece and board[r+3][c+3] == piece:
return True
# Check negatively sloped diaganols
for c in range(COLUMN_COUNT-3):
for r in range(3, ROW_COUNT):
if board[r][c] == piece and board[r-1][c+1] == piece and board[r-2][c+2] == piece and board[r-3][c+3] == piece:
return True
def evaluate_window(window, piece):
score = 0
opp_piece = PLAYER_PIECE
if piece == PLAYER_PIECE:
opp_piece = AI_PIECE
if window.count(piece) == 4:
score += 100
elif window.count(piece) == 3 and window.count(EMPTY) == 1:
score += 5
elif window.count(piece) == 2 and window.count(EMPTY) == 2:
score += 2
if window.count(opp_piece) == 3 and window.count(EMPTY) == 1:
score -= 4
return score
def score_position(board, piece):
score = 0
## Score center column
center_array = [int(i) for i in list(board[:, COLUMN_COUNT//2])]
center_count = center_array.count(piece)
score += center_count * 3
## Score Horizontal
for r in range(ROW_COUNT):
row_array = [int(i) for i in list(board[r,:])]
for c in range(COLUMN_COUNT-3):
window = row_array[c:c+WINDOW_LENGTH]
score += evaluate_window(window, piece)
## Score Vertical
for c in range(COLUMN_COUNT):
col_array = [int(i) for i in list(board[:,c])]
for r in range(ROW_COUNT-3):
window = col_array[r:r+WINDOW_LENGTH]
score += evaluate_window(window, piece)
## Score posiive sloped diagonal
for r in range(ROW_COUNT-3):
for c in range(COLUMN_COUNT-3):
window = [board[r+i][c+i] for i in range(WINDOW_LENGTH)]
score += evaluate_window(window, piece)
for r in range(ROW_COUNT-3):
for c in range(COLUMN_COUNT-3):
window = [board[r+3-i][c+i] for i in range(WINDOW_LENGTH)]
score += evaluate_window(window, piece)
return score
def is_terminal_node(board):
return winning_move(board, PLAYER_PIECE) or winning_move(board, AI_PIECE) or len(get_valid_locations(board)) == 0
def minimax(board, depth, alpha, beta, maximizingPlayer):
valid_locations = get_valid_locations(board)
is_terminal = is_terminal_node(board)
if depth == 0 or is_terminal:
if is_terminal:
if winning_move(board, AI_PIECE):
return (None, 100000000000000)
elif winning_move(board, PLAYER_PIECE):
return (None, -10000000000000)
else: # Game is over, no more valid moves
return (None, 0)
else: # Depth is zero
return (None, score_position(board, AI_PIECE))
if maximizingPlayer:
value = -math.inf
column = random.choice(valid_locations)
for col in valid_locations:
row = get_next_open_row(board, col)
b_copy = board.copy()
drop_piece(b_copy, row, col, AI_PIECE)
new_score = minimax(b_copy, depth-1, alpha, beta, False)[1]
if new_score > value:
value = new_score
column = col
alpha = max(alpha, value)
if alpha >= beta:
break
return column, value
else: # Minimizing player
value = math.inf
column = random.choice(valid_locations)
for col in valid_locations:
row = get_next_open_row(board, col)
b_copy = board.copy()
drop_piece(b_copy, row, col, PLAYER_PIECE)
new_score = minimax(b_copy, depth-1, alpha, beta, True)[1]
if new_score < value:
value = new_score
column = col
beta = min(beta, value)
if alpha >= beta:
break
return column, value
def get_valid_locations(board):
valid_locations = []
for col in range(COLUMN_COUNT):
if is_valid_location(board, col):
valid_locations.append(col)
return valid_locations
def pick_best_move(board, piece):
valid_locations = get_valid_locations(board)
best_score = -10000
best_col = random.choice(valid_locations)
for col in valid_locations:
row = get_next_open_row(board, col)
temp_board = board.copy()
drop_piece(temp_board, row, col, piece)
score = score_position(temp_board, piece)
if score > best_score:
best_score = score
best_col = col
return best_col
def draw_board(board):
for c in range(COLUMN_COUNT):
for r in range(ROW_COUNT):
pygame.draw.rect(screen, BLUE, (c*SQUARESIZE, r*SQUARESIZE+SQUARESIZE, SQUARESIZE, SQUARESIZE))
pygame.draw.circle(screen, BLACK, (int(c*SQUARESIZE+SQUARESIZE/2), int(r*SQUARESIZE+SQUARESIZE+SQUARESIZE/2)), RADIUS)
for c in range(COLUMN_COUNT):
for r in range(ROW_COUNT):
if board[r][c] == PLAYER_PIECE:
pygame.draw.circle(screen, RED, (int(c*SQUARESIZE+SQUARESIZE/2), height-int(r*SQUARESIZE+SQUARESIZE/2)), RADIUS)
elif board[r][c] == AI_PIECE:
pygame.draw.circle(screen, YELLOW, (int(c*SQUARESIZE+SQUARESIZE/2), height-int(r*SQUARESIZE+SQUARESIZE/2)), RADIUS)
pygame.display.update()
board = create_board()
print_board(board)
game_over = False
pygame.init()
SQUARESIZE = 100
width = COLUMN_COUNT * SQUARESIZE
height = (ROW_COUNT+1) * SQUARESIZE
size = (width, height)
RADIUS = int(SQUARESIZE/2 - 5)
screen = pygame.display.set_mode(size)
draw_board(board)
pygame.display.update()
myfont = pygame.font.SysFont("monospace", 75)
turn = random.randint(PLAYER, AI)
while not game_over:
for event in pygame.event.get():
if event.type == pygame.QUIT:
sys.exit()
if event.type == pygame.MOUSEMOTION:
pygame.draw.rect(screen, BLACK, (0,0, width, SQUARESIZE))
posx = event.pos[0]
if turn == PLAYER:
pygame.draw.circle(screen, RED, (posx, int(SQUARESIZE/2)), RADIUS)
pygame.display.update()
if event.type == pygame.MOUSEBUTTONDOWN:
pygame.draw.rect(screen, BLACK, (0,0, width, SQUARESIZE))
#print(event.pos)
# Ask for Player 1 Input
if turn == PLAYER:
posx = event.pos[0]
col = int(math.floor(posx/SQUARESIZE))
if is_valid_location(board, col):
row = get_next_open_row(board, col)
drop_piece(board, row, col, PLAYER_PIECE)
if winning_move(board, PLAYER_PIECE):
label = myfont.render("Player 1 wins!!", 1, RED)
screen.blit(label, (40,10))
game_over = True
turn += 1
turn = turn % 2
print_board(board)
draw_board(board)
# # Ask for Player 2 Input
if turn == AI and not game_over:
#col = random.randint(0, COLUMN_COUNT-1)
#col = pick_best_move(board, AI_PIECE)
col, minimax_score = minimax(board, 5, -math.inf, math.inf, True)
if is_valid_location(board, col):
#pygame.time.wait(500)
row = get_next_open_row(board, col)
drop_piece(board, row, col, AI_PIECE)
if winning_move(board, AI_PIECE):
label = myfont.render("Player 2 wins!!", 1, YELLOW)
screen.blit(label, (40,10))
game_over = True
print_board(board)
draw_board(board)
turn += 1
turn = turn % 2
if game_over:
pygame.time.wait(3000)