예제 #1
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파일: Population.py 프로젝트: RyTaus/SURP
def fill_coords(XCoords, OCoords):
    testBoard = GameBoard()
    for x in range(len(XCoords)):
        testBoard.board[XCoords[x][0]][XCoords[x][1]] = 'X'
    for o in range(len(OCoords)):
        testBoard.board[OCoords[o][0]][OCoords[o][1]] = 'O'
    return testBoard
예제 #2
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def play_tic_tac_toe():

    gb = GameBoard()
    gb.turnNumber = random.choice([0, 1])
    # gb.print_board()

    while True:
        # print()
        currPlayer, otherPlayer = activePlayer[gb.turnNumber], activePlayer[(gb.turnNumber + 1) % 2]
        coord = currPlayer.make_move(gb)
        gb.place_piece(coord)

        results = gb.get_results()
        if results == currPlayer.piece:
            currPlayer.update(1, gb)
            otherPlayer.update(-1, gb)
            break
        if results == "-": # tie game
            currPlayer.update(0.5, gb)
            otherPlayer.update(0.5, gb)
            break
        otherPlayer.update(0, gb)



        if player[0] != "persona" or player[1] != "persona":
            gb.print_board()

        gb.switch_turn()
예제 #3
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파일: Population.py 프로젝트: RyTaus/SURP
    def assess(self, other):
        for c1 in self.chromosomes:
            for c2 in other.chromosomes:
                # print("new battle")
                for games in range(10):
                    p1 = Players.Chromo("O", c1)
                    p2 = Players.Chromo("X", c2)
                    players = [p1, p2]
                    gb = GameBoard()
                    while True:
                        active, nextP = players[gb.turnState], players[(gb.turnState + 1) % 2]
                        move = active.make_move(gb)
                        # print(move)
                        # gb.print_board()
                        gb.place_piece(move)
                        gb.increment_turn()
                        r = gb.get_results()

                        if r == "O":
                            # gb.print_board()
                            c1.update(1)
                            c2.update(-1)
                            break
                        if r == "X":
                            # gb.print_board()
                            c1.update(-1)
                            c2.update(1)
                            break
                        if r == "-":
                            c1.update(.2)
                            c2.update(.2)
                            break
                        gb.switch_turn()
예제 #4
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파일: Connect4.py 프로젝트: RyTaus/SURP
def train(numberOfGames):
    gb = GameBoard()
    p1 = Players.Merlin("O")
    p2 = Players.Merlin("X")
    players = [p1, p2]

    for i in range(numberOfGames):
        if i % 100 == 0:
            print(i)
        gb = GameBoard()
        gb.turnNumber = random.choice([0, 1])
        while True:
            # gb.print_board()
            active, nextP = players[gb.turnNumber], players[(gb.turnNumber + 1) % 2]
            move = active.make_move(gb)
            gb.place_piece(move)

            r = gb.get_results()
            # print(r)

            if r == "O" or r == "X":
                active.update(1, gb)
                nextP.update(-1, gb)
                break
            if r == "-":
                active.update(0, gb)
                nextP.update(0, gb)
                break
            active.update(0, gb)
            nextP.update(0, gb)
            gb.switch_turn()
    p2.write_history()
예제 #5
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파일: Persona.py 프로젝트: RyTaus/SURP
 def __init__(self, t):
     self.memory = self.read_history("history.txt")
     self.currBoard = GameBoard()
     self.boardStates = [GameBoard().to_string_one_line()]
     self.piece = t
     self.UNRESEARCHEDBOARDVALUE = .5
     self.TIEWORTH = .7
예제 #6
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def test_has_won():
    print("\nTesting has_won...")
    gb = GameBoard()
    gb.place_piece([0,0])
    gb.place_piece([1,0])
    gb.place_piece([1,1])
    gb.place_piece([2,0])
    gb.place_piece([2,2])
    gb.place_piece([2,1])
    if (gb.has_won(gb.pieces[gb.turnNumber])):
        print("Success")
예제 #7
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파일: Connect4.py 프로젝트: RyTaus/SURP
def play_vs_merlin(numberOfGames):
    p1 = Players.Player("O")
    p2 = Players.Merlin("X", learning = False)
    players = [p1, p2]

    for i in range(numberOfGames):
        gb = GameBoard()
        gb.turnNumber = random.choice([0, 1])
        while True:
            gb.print_board()
            move = players[gb.turnNumber].make_move(gb)
            gb.place_piece(move)
            gb.switch_turn()
            if (gb.get_results() != None):
                break
예제 #8
0
파일: Connect4.py 프로젝트: RyTaus/SURP
def play(numberOfGames):
    p1 = Players.Player("O")
    p2 = Players.Player("X")
    players = [p1, p2]

    for i in range(numberOfGames):
        gb = GameBoard()
        while True:
            print(gb.valid_actions())
            gb.print_board()
            move = players[gb.turnNumber].make_move(gb)
            gb.place_piece(move)
            if (gb.get_results() != None):
                break
            gb.switch_turn()
예제 #9
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 def __init__(self):
     self._atom_list = sample(list(product(range(
         1, 9), repeat=2)), k=5)  # initialize random list of atom locations
     self._gameB = GameBoard(
         self._atom_list)  # initialize a game board with the atom list
     self._board = self._gameB.get_board(
     )  # get the game board for calculating ray path
     self._score = 25  # initialize the starting points for the game
     self._ray_locations = []  # empty list to store ray entry/exit squares
     self._wrong_atom_guesses = [
     ]  # empty list to store incorrect atom guesses
     self._correct_atom_guesses = [
     ]  # empty list to store correct atom guesses
     self._ray_status = None
     self._ray_row = None
     self._ray_column = None
     self._screen = pygame.display.set_mode((600, 800))
     self._font = pygame.font.Font('freesansbold.ttf', 36)
     self.background = pygame.image.load('board_grid.png')
     self.background = pygame.transform.scale(self.background, (600, 600))
     self._game_status = True
     self._ray_color = None
예제 #10
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파일: Persona.py 프로젝트: RyTaus/SURP
    def evaluate_options(self):
        Temperature = 5
        currWinner = None
        editBoard = GameBoard()
        editBoard.board = self.copy_board(self.currBoard)
        score = 0
        strng = ""

        prob = list()
        self.currBoard.print_board()
        for i in range(3):
            for j in range(3):
                if (self.currBoard.is_valid_move((i, j))):
                    editBoard.board[i][j] = self.piece
                    strng = editBoard.to_string_one_line()
                    score = 0
                    
                    prob.append(((i, j), self.evaluate_option(strng, (i, j), Temperature)))


                    editBoard.board = self.copy_board(self.currBoard)
        bot = 0
        for dub in prob:
            bot += dub[1]
        for dub in range(len(prob)):
            # print(prob[dub])
            if dub == 0:
                prob[dub] = (prob[dub][0], prob[dub][1] / bot)
            else :
                prob[dub] = (prob[dub][0], prob[dub][1] / bot + prob[dub - 1][1])

        rand = random()
        # print(prob)
        for dub in prob:
            if (rand < dub[1]):
                return dub[0]
        print("F**K")
        return (0, 0)
예제 #11
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class Player(ABC):
    '''
    abstract base class of a player
    '''
    def __init__(self):
        self.__game_board = GameBoard()
        self.__opponent_map = GameBoard()
        self.__game_board.populate_board()

    @property
    def game_board(self):
        return self.__game_board

    @property
    def opponent_map(self):
        return self.__opponent_map

    @abstractmethod
    def strike_opponent(self, opponent):
        pass

    @property
    def has_won(self):
        '''
        Checks if a player has already discovered all enemy ships
        '''
        for ship, found in self.opponent_map.revealed.items():
            if found != BoardStates(ship).value:
                return False
        return True

    def print_map(self, map):
        '''
        Debugging utility for printing out current board space
        '''
        with np.printoptions(precision=3, floatmode='maxprec', suppress=True):
            print(map, end='\n\n')
예제 #12
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def test_is_valid_move():
    print("Testing is_valid_move...")
    gb = GameBoard()
    gb.place_piece([1,1])
    if (not(gb.is_valid_move([1,1]))):
        print(" Success")
    if (gb.is_valid_move([1, 2])):
        print(" Success")
    if (not(gb.is_valid_move([1,3]))):
        print(" Success")
예제 #13
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class Game(object):
	def __init__(self, Player1, Player2):
		self.player1 = Player1
		self.player2 = Player2
		self.board = GameBoard()
		self.turn = 1
		
	@staticmethod	
	def checkwin(board): #check if someone has won
		curboard  = 0 
		if isinstance(board,GameBoard): #typechecking is not working consistently. 
			curboard = board
		elif isinstance(board, list):
			curboard = GameBoard(board)
		else:
			return 1 #SOMETHING WENT WRONG.
			
		if(
			#horizontals
			(curboard.is1(0,0) and curboard.is1(0,1) and curboard.is1(0,2)) or
			(curboard.is1(1,0) and board.is1(1,1) and curboard.is1(1,2)) or
			(curboard.is1(2,0) and curboard.is1(2,1) and curboard.is1(2,2)) or
			#verticals
			(curboard.is1(0,0) and curboard.is1(1,0) and curboard.is1(2,0)) or
			(curboard.is1(0,1) and curboard.is1(1,1) and curboard.is1(2,1)) or
			(curboard.is1(0,2) and curboard.is1(1,2) and curboard.is1(2,2)) or
			#diagonals
			(curboard.is1(0,0) and curboard.is1(1,1) and curboard.is1(2,2)) or
			(curboard.is1(0,2) and curboard.is1(1,1) and curboard.is1(2,0))
		  ):
			return 1 #1 wins
		elif (
			#horizontals
			(curboard.is2(0,0) and curboard.is2(0,1) and curboard.is2(0,2)) or
			(curboard.is2(1,0) and curboard.is2(1,1) and curboard.is2(1,2)) or
			(curboard.is2(2,0) and curboard.is2(2,1) and curboard.is2(2,2)) or
			#verticals
			(curboard.is2(0,0) and curboard.is2(1,0) and curboard.is2(2,0)) or
			(curboard.is2(0,1) and curboard.is2(1,1) and curboard.is2(2,1)) or
			(curboard.is2(0,2) and curboard.is2(1,2) and curboard.is2(2,2)) or
			#diagonals
			(curboard.is2(0,0) and curboard.is2(1,1) and curboard.is2(2,2)) or
			(curboard.is2(0,2) and curboard.is2(1,1) and curboard.is2(2,0))
		  ):
			return 2 # 2 wins
		else:
			has_valid_move = False
			for i in range(3):
				for j in range(3):
					if not curboard.is1(i,j) and not curboard.is2(i,j):
						has_valid_move = True
						break;
				if has_valid_move:
					break;
			
			if has_valid_move:
				return 0 # keep going
			else:
				return -1 # draw.
		
	def prompt_for_move(self):
		move = [-1,-1]
		if self.turn == 1:
			move = self.player1.get_move(self.board)
		elif self.turn == 2:
			move = self.player2.get_move(self.board)	
			
		self.board.makemove(self.turn,move[0],move[1])
		if self.turn == 1:
			self.turn = 2
		else:
			self.turn = 1
		
	def play(self):
		while self.checkwin(self.board) == 0:
			self.board.printboard_debug()
			self.prompt_for_move()
			
		self.board.printboard();
		if self.checkwin(self.board) == 1:
			self.player1.report_win()
			self.player2.report_loss()
		elif self.checkwin(self.board) == 2:
			self.player2.report_win()
			self.player1.report_loss()
		elif self.checkwin(self.board) == -1:
			self.player1.report_draw()
			self.player2.report_draw()
		else:
			print("Something went wrong, checkwin is {0}".format(self.checkwin(self.board)))
예제 #14
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if __name__ == "__main__":

    # check the  style guide for import!
    from Board import GameBoard

    filename = "file1.txt"

    print("running")
    board = GameBoard()
    board.load_board(filename)

    game_time = board.time
    time = 0
    board.print_board()

    while time < game_time:

        time += 1
        board.spread()
        board.air_flow()

    board.print_board()
    board.get_sum()
예제 #15
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 def __init__(self):
     self.__game_board = GameBoard()
     self.__opponent_map = GameBoard()
     self.__game_board.populate_board()
예제 #16
0
파일: Persona.py 프로젝트: RyTaus/SURP
 def copy_board(self, board):
     tempBoard = GameBoard()
     for i in range(3):
         for j in range(3):
             tempBoard.board[i][j] = board.board[i][j]
     return tempBoard.board
예제 #17
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class BlackBoxGame:
    """Implementation of the Black Box game. Contains method to create a GameBoard instance with indicated atom
    placement. Contains methods to shoot rays, adjust the game score, guess atom locations, get the current score,
    and get how many atoms are left to guess."""
    def __init__(self):
        self._atom_list = sample(list(product(range(
            1, 9), repeat=2)), k=5)  # initialize random list of atom locations
        self._gameB = GameBoard(
            self._atom_list)  # initialize a game board with the atom list
        self._board = self._gameB.get_board(
        )  # get the game board for calculating ray path
        self._score = 25  # initialize the starting points for the game
        self._ray_locations = []  # empty list to store ray entry/exit squares
        self._wrong_atom_guesses = [
        ]  # empty list to store incorrect atom guesses
        self._correct_atom_guesses = [
        ]  # empty list to store correct atom guesses
        self._ray_status = None
        self._ray_row = None
        self._ray_column = None
        self._screen = pygame.display.set_mode((600, 800))
        self._font = pygame.font.Font('freesansbold.ttf', 36)
        self.background = pygame.image.load('board_grid.png')
        self.background = pygame.transform.scale(self.background, (600, 600))
        self._game_status = True
        self._ray_color = None

    def shoot_ray(self, row, column):
        """Accepts as parameters a row and column that designates the entry point of a ray. Simulates the ray path
        with appropriate hit, detours and/or reflections. Returns 'False' if the entry row and column are not legal
        plays (non-corner border squares). Returns 'None' if the play is a hit. Returns a tuple of exit square row and
        column if the play exits the game black box. Deducts from the player's score: 1 point for ray entry and 1 point
        for ray exit, if the squares have not already been used."""

        # check if ray is being shot from corner square
        if (row == 0 or row == 9) and (column == 0 or column == 9):
            return False

        # check if ray is being shot from non-border square
        if row in range(1, 9) and column in range(1, 9):
            return False

        if self._ray_color is None:
            self._ray_color = 0
        else:
            self._ray_color += 1

        self.adjust_score(
            row, column,
            self._ray_color)  # adjust score for entry ray position
        self._ray_status = 'Play'  # set flag variable for ray status

        if column == 0 or column == 9:  # if shooting from horizontal position
            if column == 0:  # if ray is moving to the right
                self.horiz_move_right(row, column)
            elif column == 9:  # if ray is moving to the left
                self.horiz_move_left(row, column)

        if row == 0 or row == 9:  # if shooting from vertical position
            if row == 0:  # if ray is moving down
                self.vert_move_down(row, column)
            elif row == 9:  # if ray is moving up
                self.vert_move_up(row, column)

        if self._ray_status == "Hit":  # if ray hits an atom
            return None

        elif self._ray_status == "Exit":  # if ray is a miss
            self.adjust_score(
                self._ray_row, self._ray_column,
                self._ray_color)  # adjust score with exit ray position
            return self._ray_row, self._ray_column

    def horiz_move_right(self, ray_path_r, ray_path_c):
        """Accepts as parameters the current row and column of the ray path. Calculates the next square of
        a horizontal ray path to the right and determines if there are any atoms resulting in a hit or detour.
        Adjusts ray status variable if there is a Hit or Exit. Returns nothing."""

        self._ray_row = ray_path_r
        self._ray_column = ray_path_c

        while self._ray_status == "Play":  # continue ray path determination while still in "play"

            # check for edge case reflection
            if ray_path_c == 0 and self._ray_column == 0:
                if (self._board[ray_path_r + 1][ray_path_c + 1]) or (
                        self._board[ray_path_r - 1][ray_path_c + 1]) == 'A':
                    self._ray_column -= 1
                    self._ray_status = "Exit"

            self._ray_column += 1  # move ray path one square to the right

            # check if ray is exiting 'black box'
            if self._ray_column == 9:
                self._ray_status = "Exit"

            # check for hit
            elif self._board[self._ray_row][
                    self.
                    _ray_column] == 'A':  # if atom is in next ray path square
                self._ray_status = "Hit"

            # check for reflection
            elif (self._board[self._ray_row + 1][self._ray_column]) and (
                    self._board[self._ray_row - 1][self._ray_column]) == 'A':
                self._ray_column -= 1
                self.horiz_move_left(self._ray_row, self._ray_column)

            # check for detour (change ray path to 'up)
            elif self._board[self._ray_row + 1][self._ray_column] == 'A':
                self._ray_column -= 1
                self.vert_move_up(self._ray_row, self._ray_column)

            # check for detour (change ray path to 'down)
            elif self._board[self._ray_row - 1][self._ray_column] == 'A':
                self._ray_column -= 1
                self.vert_move_down(self._ray_row, self._ray_column)

    def horiz_move_left(self, ray_path_r, ray_path_c):
        """Accepts as parameters the current row and column of the ray path. Calculates the next square of
        a horizontal ray path moving to the left and determines if there are any atoms resulting in a hit or detour.
        Adjusts ray status variable if there is a Hit or Exit. Returns nothing."""

        self._ray_row = ray_path_r
        self._ray_column = ray_path_c

        while self._ray_status == "Play":  # continue ray path determination while still in "play"

            # check for edge case reflection
            if ray_path_c == 9 and self._ray_column == 9:
                if (self._board[ray_path_r + 1][ray_path_c - 1]) or (
                        self._board[ray_path_r - 1][ray_path_c - 1]) == 'A':
                    self._ray_column += 1
                    self._ray_status = "Exit"

            self._ray_column -= 1  # move ray path one square to the left

            # check for exit
            if self._ray_column == 0:
                self._ray_status = "Exit"

            # check for hit
            elif self._board[self._ray_row][
                    self.
                    _ray_column] == 'A':  # if atom is in next ray path square
                self._ray_status = "Hit"

            # check for reflection
            elif (self._board[self._ray_row + 1][self._ray_column]) and (
                    self._board[self._ray_row - 1][self._ray_column]) == 'A':
                self._ray_column += 1
                self.horiz_move_right(self._ray_row, self._ray_column)

            # check for detour (change to 'up' direction)
            elif self._board[self._ray_row + 1][self._ray_column] == 'A':
                self._ray_column += 1
                self.vert_move_up(self._ray_row, self._ray_column)

            # check for detour (change to 'down' direction)
            elif self._board[self._ray_row - 1][self._ray_column] == 'A':
                self._ray_column += 1
                self.vert_move_down(self._ray_row, self._ray_column)

    def vert_move_down(self, ray_path_r, ray_path_c):
        """Accepts as parameters the current row and column of the ray path. Calculates the next square of a vertical
        ray path moving down and determines if there are any atoms resulting in a hit or detour. Adjusts ray status
        variable if there is a Hit or Exit. Returns nothing."""

        self._ray_row = ray_path_r
        self._ray_column = ray_path_c

        while self._ray_status == "Play":  # continue ray path determination while still in "play"

            # check for edge case reflection
            if ray_path_r == 0 and self._ray_row == 0:
                if (self._board[ray_path_r + 1][ray_path_c + 1]) or (
                        self._board[ray_path_r + 1][ray_path_c - 1]) == 'A':
                    self._ray_row -= 1
                    self._ray_status = "Exit"

            self._ray_row += 1  # adjust ray path one square 'down'

            # check for exit
            if self._ray_row == 9:
                self._ray_status = "Exit"

            # check for hit
            elif self._board[self._ray_row][
                    self.
                    _ray_column] == 'A':  # if atom is in next ray path square
                self._ray_status = "Hit"

            # check for reflection
            elif (self._board[self._ray_row][self._ray_column + 1]) and (
                    self._board[self._ray_row][self._ray_column - 1]) == 'A':
                self._ray_row -= 1
                self.vert_move_up(self._ray_row, self._ray_column)

            # check for detour (change direction to 'left' direction)
            elif self._board[self._ray_row][self._ray_column + 1] == 'A':
                self._ray_row -= 1
                self.horiz_move_left(self._ray_row, self._ray_column)

            # check for detour (change direction to 'right' direction
            elif self._board[self._ray_row][self._ray_column - 1] == 'A':
                self._ray_row -= 1
                self.horiz_move_right(self._ray_row, self._ray_column)

    def vert_move_up(self, ray_path_r, ray_path_c):
        """Accepts as parameters the current row and column of the ray path. Calculates the next square of a vertical
        ray path moving up and determines if there are any atoms resulting in a hit or detour. Adjusts ray status
        variable if there is a Hit or Exit. Returns nothing."""

        self._ray_row = ray_path_r
        self._ray_column = ray_path_c

        while self._ray_status == "Play":  # continue ray path determination while still in "play"

            # check for edge case reflection
            if ray_path_r == 9 and self._ray_row == 9:
                if (self._board[ray_path_r - 1][ray_path_c + 1]) or (
                        self._board[ray_path_r - 1][ray_path_c - 1]) == 'A':
                    self._ray_row += 1
                    self._ray_status = "Exit"

            self._ray_row -= 1  # adjust ray path one square in 'up' direction

            # check for exit
            if self._ray_row == 0:
                self._ray_status = "Exit"

            # check for hit
            elif self._board[self._ray_row][
                    self.
                    _ray_column] == 'A':  # if atom is in next ray path square
                self._ray_status = "Hit"

            # check for reflection
            elif (self._board[self._ray_row][self._ray_column + 1]) and (
                    self._board[self._ray_row][self._ray_column - 1]) == 'A':
                # self._ray_row +=1
                self.vert_move_down(self._ray_row, self._ray_column)

            # check for detour (change direction to 'left' direction)
            elif self._board[self._ray_row][self._ray_column + 1] == 'A':
                self._ray_row += 1
                self.horiz_move_left(self._ray_row, self._ray_column)

            # check for detour (change direction to 'right' direction)
            elif self._board[self._ray_row][self._ray_column - 1] == 'A':
                self._ray_row += 1
                self.horiz_move_right(self._ray_row, self._ray_column)

    def update_game_status(self):
        """Update the game status for game win or loss. Display message to screen."""

        # update for a game loss, score below 0
        if self._score <= 0:  # check if game is over (score of 0 or less)
            game_loss = self._font.render(
                'YOU LOSE!   FINAL SCORE: ' + str(self._score), True,
                (0, 0, 0))
            self._screen.blit(game_loss, (10, 750))
            for atom in self._atom_list:
                self.draw_marker((0, 0, 0), atom)
            pygame.display.update()

        if len(self._atom_list
               ) == 0:  # once all atoms are guessed, the game is over
            game_win = self._font.render(
                'YOU WIN!   FINAL SCORE: ' + str(self._score), True, (0, 0, 0))
            self._screen.blit(game_win, (10, 750))

    def adjust_score(self, row, column, color, atom_guess=None):
        """Accepts as parameters a row and column and assignment for the variable atom_guess (default
        argument of None). If the method call initiates from shoot_ray method, the default argument of None is used
        and decrements the player's score by 1 point if the entry/exit square has not already been used. If the method
        call originates from the guess_atom method, the atom_guess default argument is utilized and 5 points are
        deducted from the player's score if the guess is not a previous guess. Does not return anything."""

        # decrement the score for a ray entry/exit point
        if atom_guess is None:
            if (row, column) not in self._ray_locations:
                self._ray_locations.append(
                    (row, column, color))  # add to ray locations list
                self._gameB.update_ray_points(
                    row, column
                )  # update the used ray location to game board visual
                self._score -= 1  # decrement the score by 1 point

        # decrement the score for an atom guess
        if atom_guess is True:
            if (row, column) not in self._wrong_atom_guesses:
                self._wrong_atom_guesses.append(
                    (row, column))  # add to atom_guesses list
                self._score -= 5  # decrement the score by 5 points

    def guess_atom(self, row, column):
        """Accepts as parameters a row and column that represents the player's guess for an atom location. Returns True
        if the guess is correct. If the guess is incorrect, decrements the player's score and returns False."""

        if (row, column) in self._atom_list:
            self._atom_list.remove(
                (row, column))  # if guess is in atom list, remove from list
            self._correct_atom_guesses.append(
                (row, column))  # add to correct atom guess list
            return True

        else:
            # if guess is incorrect, send the guess to adjust_score and include parameter 'True' to indicate atom guess
            self.adjust_score(row, column, None, True)
            return False

    def atoms_left(self):
        """Accepts no parameters and returns the number of atoms that haven't been guessed."""
        atoms_left = self._font.render(
            'Atoms Left: ' + str(len(self._atom_list)), True, (0, 0, 0))
        self._screen.blit(atoms_left, (10, 670))

    def get_score(self):
        current_score = self._font.render('Score: ' + str(self._score), True,
                                          (0, 0, 0))
        self._screen.blit(current_score, (10, 610))

    def calculate_square(self, coord):
        """Accepts as a parameter the x- y- coordinates of a mouse click and calculates the corredsponding row and column
        of the board game square. The x- coordinate is equivalent to the column and the y-coordinate is equivalent to
        the column"""
        col = (coord[0] // 60)
        row = (coord[1] // 60)
        return col, row

    def check_events(self):
        """Accepts no parameters. Checks the events of the pygame. Quits game when necessary. Otherwise, checks
        detection of mouseclick, gets the x-y coordinates of mouseclick, sends to function to calculate corresponding
        square on game board. Sends square to shoot_ray or guess_atom function."""

        for event in pygame.event.get():
            if event.type == pygame.QUIT:
                self._game_status = False

            # get coordinates of mouse click
            if event.type == pygame.MOUSEBUTTONDOWN:
                pos = pygame.mouse.get_pos()
                pos_tup = self.calculate_square(
                    pos)  # change x-y coord to square of row, column
                row = pos_tup[0]
                column = pos_tup[1]
                if (row == 0 or row == 9) or (column == 0 or column == 9):
                    self.shoot_ray(row, column)
                elif 0 < row < 9 and 0 < column < 9:
                    self.guess_atom(row, column)

    def update_screen(self):
        """Update display screen with ray locations, atom location, current score, and atoms left to guess"""

        color_list = [(91, 109, 212), (237, 210, 159), (195, 124, 242),
                      (182, 252, 251), (45, 51, 237), (247, 243, 2),
                      (123, 31, 181), (237, 104, 2), (242, 124, 226),
                      (62, 47, 135), (106, 33, 122)]

        self._screen.fill((240, 240, 240))
        self._screen.blit(self.background, (0, 0))
        self.get_score()
        self.atoms_left()
        for ray in self._ray_locations:
            self.draw_marker(color_list[ray[2]], (ray[0], ray[1]))
        for atom in self._wrong_atom_guesses:
            self.draw_marker((255, 0, 0), atom)
        for atom in self._correct_atom_guesses:
            self.draw_marker((20, 255, 3), atom)

        self.update_game_status()

        pygame.display.update()

    def draw_marker(self, color, pos):
        """Accepts a color as a parameter. Draws a marker at the indicated position (x-y coordinates)"""

        x_coord = pos[1] * 60 + 30
        y_coord = pos[0] * 60 + 30
        pygame.draw.circle(self._screen, color, (y_coord, x_coord), 20, 50)

    def get_game_status(self):
        return self._game_status
예제 #18
0
####################
# Load Configuration File
####################
configuration_path = sys.argv[1]

with open(configuration_path) as f:
    try:
        lines = f.readlines()
        board_size = lines[0].replace("\n", "").split(" ")
        ship_data_array = []
        for x in lines[1:]:
            ship_data = x.replace("\n", "").split(" ")
            ship_data[1] = int(ship_data[1])
            ship_data_array.append(tuple(ship_data))
        board1 = GameBoard(board_size)
        board2 = GameBoard(board_size)
    except:
        print("Some error is in the configuration file. Please check the file.")
        sys.exit()


####################
# Create Players and Ships
####################
#

player1_name = input("Player 1 please enter your name: ")
player1 = Player(player1_name, board1)
for shipData in ship_data_array:
    name = shipData[0]
예제 #19
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from Board import GameBoard
from HumanPlayer import HumanPlayer
from DumbAI import DumbAI
from SmartAI import SmartAI

# draw board
# while not game finished
# get player move
# redraw board
# check for game over

board = GameBoard()
player1 = SmartAI("SmartAI", 'O', board)
player2 = DumbAI("DumbAI", 'X')

players = [player1, player2]

for i in range(0, 100):
    print(i)
    board.reset()
    while board.game_over() == 0:
        for player in players:
            move = player.get_move()

            while board.submit_move(move) != 1:
                move = player.get_move()

            if board.game_over() != 0:
                if board.game_over() != 'TIE':
                    player.Winner()
                break
예제 #20
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	def __init__(self, Player1, Player2):
		self.player1 = Player1
		self.player2 = Player2
		self.board = GameBoard()
		self.turn = 1
예제 #21
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	def checkwin(board): #check if someone has won
		curboard  = 0 
		if isinstance(board,GameBoard): #typechecking is not working consistently. 
			curboard = board
		elif isinstance(board, list):
			curboard = GameBoard(board)
		else:
			return 1 #SOMETHING WENT WRONG.
			
		if(
			#horizontals
			(curboard.is1(0,0) and curboard.is1(0,1) and curboard.is1(0,2)) or
			(curboard.is1(1,0) and board.is1(1,1) and curboard.is1(1,2)) or
			(curboard.is1(2,0) and curboard.is1(2,1) and curboard.is1(2,2)) or
			#verticals
			(curboard.is1(0,0) and curboard.is1(1,0) and curboard.is1(2,0)) or
			(curboard.is1(0,1) and curboard.is1(1,1) and curboard.is1(2,1)) or
			(curboard.is1(0,2) and curboard.is1(1,2) and curboard.is1(2,2)) or
			#diagonals
			(curboard.is1(0,0) and curboard.is1(1,1) and curboard.is1(2,2)) or
			(curboard.is1(0,2) and curboard.is1(1,1) and curboard.is1(2,0))
		  ):
			return 1 #1 wins
		elif (
			#horizontals
			(curboard.is2(0,0) and curboard.is2(0,1) and curboard.is2(0,2)) or
			(curboard.is2(1,0) and curboard.is2(1,1) and curboard.is2(1,2)) or
			(curboard.is2(2,0) and curboard.is2(2,1) and curboard.is2(2,2)) or
			#verticals
			(curboard.is2(0,0) and curboard.is2(1,0) and curboard.is2(2,0)) or
			(curboard.is2(0,1) and curboard.is2(1,1) and curboard.is2(2,1)) or
			(curboard.is2(0,2) and curboard.is2(1,2) and curboard.is2(2,2)) or
			#diagonals
			(curboard.is2(0,0) and curboard.is2(1,1) and curboard.is2(2,2)) or
			(curboard.is2(0,2) and curboard.is2(1,1) and curboard.is2(2,0))
		  ):
			return 2 # 2 wins
		else:
			has_valid_move = False
			for i in range(3):
				for j in range(3):
					if not curboard.is1(i,j) and not curboard.is2(i,j):
						has_valid_move = True
						break;
				if has_valid_move:
					break;
			
			if has_valid_move:
				return 0 # keep going
			else:
				return -1 # draw.
예제 #22
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파일: TicTacToe.py 프로젝트: RyTaus/SURP
screen = pygame.display.set_mode((SCREEN_WIDTH, SCREEN_HEIGHT))

BLACK = (0, 0, 0)
RED = (250, 0, 0)
BLUE = (0, 0, 250)
WHITE = (250, 250, 250)

done = False
clock = pygame.time.Clock()

cellStates = ["-", "O", "X"]
colors = [WHITE, RED, BLUE]


gb = GameBoard()
p1 = Player("O")
p2 = Persona("X", learning = False)
players = [p1, p2]



def get_cell(msx, msy):
    return (msx // 200, msy // 200)


count = 0
# -------- Game Loop -----------
while not done:
    # --- Main event loop
    for event in pygame.event.get(): # User did something
예제 #23
0
파일: Persona.py 프로젝트: RyTaus/SURP
class Persona:
    def copy_board(self, board):
        tempBoard = GameBoard()
        for i in range(3):
            for j in range(3):
                tempBoard.board[i][j] = board.board[i][j]
        return tempBoard.board

    def rev_board(self, board):
        d = {"-": "-", "O": "X", "X": "O"}
        s = ""
        for c in board:
            s = s + d[c]
        return s

    # this is where end of game / memory file stuff is
    def read_history(self, fileName):
        mem = dict()
        with open(fileName, "r") as file:
            split = [] 
            # print(file.read())
            for line in file.readlines():
                # print(line)
                split = line.split(" ")
                split[2] = split[2][:-1]
                # print(split)
                mem[split[0]] = (float(split[1]), float(split[2]))
        file.close()
        # print(mem)
        return mem


    def write_history(self, fileName):
        file = open(fileName, "w")
        for brd in self.memory:
            file.write(brd)
            file.write(" ")
            file.write(str(self.memory[brd][0])[:7])
            file.write(" ")
            file.write(str(self.memory[brd][1]))
            file.write("\n")
        file.close()

    def add_board_to_memory(self, board, w):
        if board in self.memory:
            self.memory[board] = ((self.memory[board][0] * self.memory[board][1] + w) / (self.memory[board][1] + 1), self.memory[board][1] + 1)
        else:
            self.memory[board] = (w, 1)
        
        rBoard = self.rev_board(board)

        d = {0: 1, 1: 0, self.TIEWORTH: self.TIEWORTH}

        if rBoard in self.memory:
            # self.memory[rBoard] = ((self.memory[rBoard][0] * self.memory[rBoard][1] + d[w]) / (self.memory[rBoard][1] + 1), self.memory[rBoard][1] + 1)
            t = True
        else:
            self.memory[rBoard] = (d[w], 1)

    # this is where in game memory is
    def add_board(self, brdStrng):
        if brdStrng not in self.boardStates:
            self.boardStates.append(brdStrng)


    def __init__(self, t):
        self.memory = self.read_history("history.txt")
        self.currBoard = GameBoard()
        self.boardStates = [GameBoard().to_string_one_line()]
        self.piece = t
        self.UNRESEARCHEDBOARDVALUE = .5
        self.TIEWORTH = .7

    # default operations of a "player"
    def Q(self, board, move):
        posBonus = 0

        if board in self.memory:
            print("IN MEMORY")
            prevQ = self.memory[board][0] * math.log(self.memory[board][1], 10)
            posBonus = posBonus / self.memory[board][1]
        else:
            print("NEW MOVE")
            prevQ = self.UNRESEARCHEDBOARDVALUE

        return prevQ + posBonus


    def evaluate_option(self, board, move, temp):
        top = math.e ** (self.Q(board, move) / temp)
        return top

    def evaluate_options(self):
        Temperature = 5
        currWinner = None
        editBoard = GameBoard()
        editBoard.board = self.copy_board(self.currBoard)
        score = 0
        strng = ""

        prob = list()
        self.currBoard.print_board()
        for i in range(3):
            for j in range(3):
                if (self.currBoard.is_valid_move((i, j))):
                    editBoard.board[i][j] = self.piece
                    strng = editBoard.to_string_one_line()
                    score = 0
                    
                    prob.append(((i, j), self.evaluate_option(strng, (i, j), Temperature)))


                    editBoard.board = self.copy_board(self.currBoard)
        bot = 0
        for dub in prob:
            bot += dub[1]
        for dub in range(len(prob)):
            # print(prob[dub])
            if dub == 0:
                prob[dub] = (prob[dub][0], prob[dub][1] / bot)
            else :
                prob[dub] = (prob[dub][0], prob[dub][1] / bot + prob[dub - 1][1])

        rand = random()
        # print(prob)
        for dub in prob:
            if (rand < dub[1]):
                return dub[0]
        print("F**K")
        return (0, 0)

    def make_move(self):
        return self.evaluate_options()

    def update(self, board, pos):
        self.add_board(board.to_string_one_line())
        if (board.to_string_one_line() != self.currBoard.to_string_one_line()):
            self.currBoard.board = self.copy_board(board)

    def end_game(self, board, w):
        d = {"-": self.TIEWORTH, "O": 1 if self.piece == w else 0, "X": 1 if self.piece == w else 0}


        # print(self.boardStates)
        # print("")

        self.add_board(board.to_string_one_line())
        [self.add_board_to_memory(b, d[w]) for b in self.boardStates]
        self.boardStates = [GameBoard().to_string_one_line()]