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orig.py
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orig.py
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'''
Naming convention followed across the simulator is:
- BigBoard = big_boards[0] + big_boards[1]
- big_board[i] = small_boards[0] + small_boards[1] + small_boards[2] + .... + small_boards[7] + small_boards[8]
- small_board[i] = cell[0] + cell[1] + cell[2] + .... + cell[7] + cell[8]
'''
import sys
import random
import signal
import time
import copy
import traceback
TIME = 24
MAX_PTS = 86
class TimedOutExc(Exception):
pass
def handler(signum, frame):
#print 'Signal handler called with signal', signum
raise TimedOutExc()
class Random_Player():
def __init__(self):
pass
def move(self, board, old_move, flag):
#You have to implement the move function with the same signature as this
#Find the list of valid cells allowed
cells = board.find_valid_move_cells(old_move)
return cells[random.randrange(len(cells))]
class Manual_Player:
def __init__(self):
pass
def move(self, board, old_move, flag):
print 'Enter your move: <format:board row column> (you\'re playing with', flag + ")"
mvp = raw_input()
mvp = mvp.split()
return (int(mvp[0]), int(mvp[1]), int(mvp[2]))
class BigBoard:
def __init__(self):
# big_boards_status is the game board
# small_boards_status shows which small_boards have been won/drawn and by which player
self.big_boards_status = ([['-' for i in range(9)] for j in range(9)], [['-' for i in range(9)] for j in range(9)])
self.small_boards_status = ([['-' for i in range(3)] for j in range(3)], [['-' for i in range(3)] for j in range(3)])
def print_board(self):
# for printing the state of the board
print '================BigBoard State================'
for i in range(9):
if i%3 == 0:
print
for k in range(2):
for j in range(9):
if j%3 == 0:
print "",
print self.big_boards_status[k][i][j],
if k==0:
print " ",
print
print
print '==============SmallBoards States=============='
for i in range(3):
for k in range(2):
for j in range(3):
print self.small_boards_status[k][i][j],
if k==0:
print " ",
print
print '=============================================='
print
print
def find_valid_move_cells(self, old_move):
#returns the valid cells allowed given the last move and the current board state
allowed_cells = []
allowed_small_board = [old_move[1]%3, old_move[2]%3]
#checks if the move is a free move or not based on the rules
if old_move == (-1,-1,-1) or (self.small_boards_status[0][allowed_small_board[0]][allowed_small_board[1]] != '-' and self.small_boards_status[1][allowed_small_board[0]][allowed_small_board[1]] != '-'):
for k in range(2):
for i in range(9):
for j in range(9):
if self.big_boards_status[k][i][j] == '-' and self.small_boards_status[k][i/3][j/3] == '-':
allowed_cells.append((k,i,j))
else:
for k in range(2):
if self.small_boards_status[k][allowed_small_board[0]][allowed_small_board[1]] == "-":
for i in range(3*allowed_small_board[0], 3*allowed_small_board[0]+3):
for j in range(3*allowed_small_board[1], 3*allowed_small_board[1]+3):
if self.big_boards_status[k][i][j] == '-':
allowed_cells.append((k,i,j))
return allowed_cells
def find_terminal_state(self):
#checks if the game is over(won or drawn) and returns the player who have won the game or the player who has higher small_boards in case of a draw
cntx = 0
cnto = 0
cntd = 0
for k in range(2):
bs = self.small_boards_status[k]
for i in range(3):
for j in range(3):
if bs[i][j] == 'x':
cntx += 1
if bs[i][j] == 'o':
cnto += 1
if bs[i][j] == 'd':
cntd += 1
for i in range(3):
row = bs[i]
col = [x[i] for x in bs]
#print row,col
#checking if i'th row or i'th column has been won or not
if (row[0] =='x' or row[0] == 'o') and (row.count(row[0]) == 3):
return (row[0],'WON')
if (col[0] =='x' or col[0] == 'o') and (col.count(col[0]) == 3):
return (col[0],'WON')
#check diagonals
if(bs[0][0] == bs[1][1] == bs[2][2]) and (bs[0][0] == 'x' or bs[0][0] == 'o'):
return (bs[0][0],'WON')
if(bs[0][2] == bs[1][1] == bs[2][0]) and (bs[0][2] == 'x' or bs[0][2] == 'o'):
return (bs[0][2],'WON')
if cntx+cnto+cntd < 18: #if all small_boards have not yet been won, continue
return ('CONTINUE', '-')
elif cntx+cnto+cntd == 18: #if game is drawn
return ('NONE', 'DRAW')
def check_valid_move(self, old_move, new_move):
#checks if a move is valid or not given the last move
if (len(old_move) != 3) or (len(new_move) != 3):
return False
for i in range(3):
if (type(old_move[i]) is not int) or (type(new_move[i]) is not int):
return False
if (old_move != (-1,-1,-1)) and (old_move[0] < 0 or old_move[0] > 1 or old_move[1] < 0 or old_move[1] > 8 or old_move[2] < 0 or old_move[2] > 8):
return False
cells = self.find_valid_move_cells(old_move)
return new_move in cells
def update(self, old_move, new_move, ply):
#updating the game board and small_board status as per the move that has been passed in the arguements
if(self.check_valid_move(old_move, new_move)) == False:
return 'UNSUCCESSFUL', False
self.big_boards_status[new_move[0]][new_move[1]][new_move[2]] = ply
x = new_move[1]/3
y = new_move[2]/3
k = new_move[0]
fl = 0
#checking if a small_board has been won or drawn or not after the current move
bs = self.big_boards_status[k]
for i in range(3):
#checking for horizontal pattern(i'th row)
if (bs[3*x+i][3*y] == bs[3*x+i][3*y+1] == bs[3*x+i][3*y+2]) and (bs[3*x+i][3*y] == ply):
self.small_boards_status[k][x][y] = ply
return 'SUCCESSFUL', True
#checking for vertical pattern(i'th column)
if (bs[3*x][3*y+i] == bs[3*x+1][3*y+i] == bs[3*x+2][3*y+i]) and (bs[3*x][3*y+i] == ply):
self.small_boards_status[k][x][y] = ply
return 'SUCCESSFUL', True
#checking for diagonal patterns
#diagonal 1
if (bs[3*x][3*y] == bs[3*x+1][3*y+1] == bs[3*x+2][3*y+2]) and (bs[3*x][3*y] == ply):
self.small_boards_status[k][x][y] = ply
return 'SUCCESSFUL', True
#diagonal 2
if (bs[3*x][3*y+2] == bs[3*x+1][3*y+1] == bs[3*x+2][3*y]) and (bs[3*x][3*y+2] == ply):
self.small_boards_status[k][x][y] = ply
return 'SUCCESSFUL', True
#checking if a small_board has any more cells left or has it been drawn
for i in range(3):
for j in range(3):
if bs[3*x+i][3*y+j] =='-':
return 'SUCCESSFUL', False
self.small_boards_status[k][x][y] = 'd'
return 'SUCCESSFUL', False
def player_turn(game_board, old_move, obj, ply, opp, flg):
temp_big_boards_status = copy.deepcopy(game_board.big_boards_status)
temp_small_boards_status = copy.deepcopy(game_board.small_boards_status)
signal.alarm(TIME)
WINNER = ''
MESSAGE = ''
pts = {"P1" : 0, "P2" : 0}
to_break = False
p_move = ''
try: #try to get player 1's move
p_move = obj.move(game_board, old_move, flg)
except TimedOutExc: #timeout error
# print e
WINNER = opp
MESSAGE = 'TIME OUT'
pts[opp] = MAX_PTS
return p_move, WINNER, MESSAGE, pts["P1"], pts["P2"], True, False
except Exception as e:
WINNER = opp
MESSAGE = "THREW AN EXCEPTION"
traceback.print_exc()
pts[opp] = MAX_PTS
return p_move, WINNER, MESSAGE, pts["P1"], pts["P2"], True, False
signal.alarm(0)
#check if board is not modified and move returned is valid
if (game_board.small_boards_status != temp_small_boards_status) or (game_board.big_boards_status != temp_big_boards_status):
WINNER = opp
MESSAGE = 'MODIFIED THE BOARD'
pts[opp] = MAX_PTS
return p_move, WINNER, MESSAGE, pts["P1"], pts["P2"], True, False
update_status, small_board_won = game_board.update(old_move, p_move, flg)
if update_status == 'UNSUCCESSFUL':
WINNER = opp
MESSAGE = 'INVALID MOVE'
pts[opp] = MAX_PTS
return p_move, WINNER, MESSAGE, pts["P1"], pts["P2"], True, False
status = game_board.find_terminal_state() #find if the game has ended and if yes, find the winner
print status
if status[1] == 'WON': #if the game has ended after a player1 move, player 1 would win
pts[ply] = MAX_PTS
WINNER = ply
MESSAGE = 'WON'
return p_move, WINNER, MESSAGE, pts["P1"], pts["P2"], True, False
elif status[1] == 'DRAW': #in case of a draw, each player gets points equal to the number of small_boards won
WINNER = 'NONE'
MESSAGE = 'DRAW'
return p_move, WINNER, MESSAGE, pts["P1"], pts["P2"], True, False
return p_move, WINNER, MESSAGE, pts["P1"], pts["P2"], False, small_board_won
def gameplay(obj1, obj2): #game simulator
game_board = BigBoard()
fl1 = 'x'
fl2 = 'o'
old_move = (-1,-1,-1)
WINNER = ''
MESSAGE = ''
pts1 = 0
pts2 = 0
game_board.print_board()
signal.signal(signal.SIGALRM, handler)
while(1):
#player 1 turn
p1_move, WINNER, MESSAGE, pts1, pts2, to_break, small_board_won = player_turn(game_board, old_move, obj1, "P1", "P2", fl1)
if to_break:
break
old_move = p1_move
game_board.print_board()
if small_board_won:
p1_move, WINNER, MESSAGE, pts1, pts2, to_break, small_board_won = player_turn(game_board, old_move, obj1, "P1", "P2", fl1)
if to_break:
break
old_move = p1_move
game_board.print_board()
#do the same thing for player 2
p2_move, WINNER, MESSAGE, pts1, pts2, to_break, small_board_won = player_turn(game_board, old_move, obj2, "P2", "P1", fl2)
if to_break:
break
game_board.print_board()
old_move = p2_move
if small_board_won:
p2_move, WINNER, MESSAGE, pts1, pts2, to_break, small_board_won = player_turn(game_board, old_move, obj2, "P2", "P1", fl2)
if to_break:
break
old_move = p2_move
game_board.print_board()
game_board.print_board()
print "Winner:", WINNER
print "Message", MESSAGE
x = 0
d = 0
o = 0
for k in range(2):
for i in range(3):
for j in range(3):
if game_board.small_boards_status[k][i][j] == 'x':
x += 1
if game_board.small_boards_status[k][i][j] == 'o':
o += 1
if game_board.small_boards_status[k][i][j] == 'd':
d += 1
print 'x:', x, ' o:',o,' d:',d
if MESSAGE == 'DRAW':
for k in range(2):
for i in range(3):
for j in range(3):
val = 6
if is_corner(i,j):
val = 4
elif is_centre(i,j):
val = 3
if game_board.small_boards_status[k][i][j] == 'x':
pts1 += val
if game_board.small_boards_status[k][i][j] == 'o':
pts2 += val
return (pts1,pts2)
def is_centre(row, col):
if row == 1 and col == 1:
return 1
return 0
def is_corner(row, col):
if row == 0 and col == 0:
return 1
if row == 0 and col == 2:
return 1
if row == 2 and col == 0:
return 1
if row == 2 and col == 2:
return 1
return 0
if __name__ == '__main__':
if len(sys.argv) != 2:
print 'Usage: python simulator.py <option>'
print '<option> can be 1 => Random player vs. Random player'
print ' 2 => Human vs. Random Player'
print ' 3 => Human vs. Human'
sys.exit(1)
obj1 = ''
obj2 = ''
option = sys.argv[1]
if option == '1':
obj1 = Random_Player()
obj2 = Random_Player()
elif option == '2':
obj1 = Random_Player()
obj2 = Manual_Player()
elif option == '3':
obj1 = Manual_Player()
obj2 = Manual_Player()
else:
print 'Invalid option'
sys.exit(1)
x = gameplay(obj1, obj2)
print "Player 1 points:", x[0]
print "Player 2 points:", x[1]