예제 #1
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 def check_for_jump(self, player: str, row: int, col: int):
     """ Checks the two front diagonals for possible jumps.
         Black begins on the bottom side, white begins at the top side.
         left and right directions in perspective of the board side.
     """
     found_jumps = []
     other_player = self._checkers.other_player(player)
     # Check the player to correspond to direction
     if player == CheckersBoard.player_1:
         # If black then check row+1,col-1 and row+1,col+1
         left = self._checkers.get(row + 1, col - 1)
         right = self._checkers.get(row + 1, col + 1)
         further_left = self._checkers.get(row + 2, col - 2)
         further_right = self._checkers.get(row + 2, col + 2)
         # Checks if the moves can be made and adds to the found jumps
         if left == other_player and further_left == CheckersBoard.empty:
             found_jumps.append(Move(row, col, 1, -1))
         if right == other_player and further_right == CheckersBoard.empty:
             found_jumps.append(Move(row, col, 1, 1))
     elif player == CheckersBoard.player_2:
         # If red then check row-1,col-1 and row-1,col+1
         left = self._checkers.get(row - 1, col - 1)
         right = self._checkers.get(row - 1, col + 1)
         further_left = self._checkers.get(row - 2, col - 2)
         further_right = self._checkers.get(row - 2, col + 2)
         # Checks if the moves can be made and adds to the found jumps
         if left == other_player and further_left == CheckersBoard.empty:
             found_jumps.append(Move(row, col, -1, -1))
         if right == other_player and further_right == CheckersBoard.empty:
             found_jumps.append(Move(row, col, -1, 1))
     return found_jumps
예제 #2
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파일: Rook.py 프로젝트: andreivlad17/Chess
    def getRookMoves(self, row, column, whiteToMove, board, moves, pins):
        piecePinned = False
        pinDirection = ()
        for i in range(len(pins) - 1, -1, -1):
            if pins[i][0] == row and pins[i][1] == column:
                piecePinned = True
                pinDirection = (pins[i][2], pins[i][3])
                if not isinstance(board[row][column], Queen):
                    pins.remove(pins[i])
                break

        directions = ((-1, 0), (0, -1), (1, 0), (0, 1))
        enemyColor = 'black' if whiteToMove else 'white'
        for currentDirection in directions:
            for i in range(1, 8):
                endRow = row + currentDirection[0] * i
                endCol = column + currentDirection[1] * i
                if 0 <= endRow < 8 and 0 <= endCol < 8:
                    if not piecePinned or pinDirection == currentDirection or pinDirection == (
                            -currentDirection[0], -currentDirection[1]):
                        endPiece = board[endRow][endCol]
                        if endPiece == "--":
                            moves.append(
                                Move((row, column), (endRow, endCol), board))
                        elif isinstance(
                                endPiece,
                                Piece) and endPiece.color == enemyColor:
                            moves.append((Move((row, column), (endRow, endCol),
                                               board)))
                            break
                        else:
                            break
                else:
                    break
예제 #3
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    def check_for_jump(self, player: str, row: int, col: int):
        found_jumps = []
        other_player = self._checkers.other_player(player)

        # Tiles where an opponent might be
        north_west = self._checkers.get(row - 1, col - 1)
        north_east = self._checkers.get(row - 1, col + 1)
        south_west = self._checkers.get(row + 1, col - 1)
        south_east = self._checkers.get(row + 1, col + 1)
        # Tiles where a blank space might be
        further_nw = self._checkers.get(row - 2, col - 2)
        further_ne = self._checkers.get(row - 2, col + 2)
        further_sw = self._checkers.get(row + 2, col - 2)
        further_se = self._checkers.get(row + 2, col + 2)

        # Checks if a jump is possible and adds the possible Move to the list
        if north_west == other_player and further_nw == CheckersBoard.empty:
            found_jumps.append(Move(row, col, -1, -1))
        if north_east == other_player and further_ne == CheckersBoard.empty:
            found_jumps.append(Move(row, col, -1, 1))
        if south_west == other_player and further_sw == CheckersBoard.empty:
            found_jumps.append(Move(row, col, 1, -1))
        if south_east == other_player and further_se == CheckersBoard.empty:
            found_jumps.append(Move(row, col, 1, 1))

        return found_jumps
예제 #4
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    def testExistsMove(self):
        repoMoves = RepoMoves(4, 4)
        move = Move(2, 3, "x")
        otherMove = Move(1, 1, "o")

        repoMoves.moves.append(move)

        assert repoMoves.existsMove(move) == True
        assert repoMoves.existsMove(otherMove) == False
예제 #5
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    def testAddNeighbours(self):
        repoMoves = RepoMoves(4, 4)
        move = Move(0, 0, "x")

        repoMoves.moves.append(move)
        repoMoves.addNeighbours(move)

        assert repoMoves.moves == [
            move, Move(0, 1, "#"),
            Move(1, 1, "#"),
            Move(1, 0, "#")
        ]
        assert len(repoMoves.moves) == 4
예제 #6
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    def makeMove(self, destination: List):
        curr_x = self.selected[0]
        curr_y = self.selected[1]
        move_x = destination[0]
        move_y = destination[1]
        move_dx = destination[0] - self.selected[0]
        move_dy = destination[1] - self.selected[1]
        if move_dx == 2 and move_dy == 2:
            move_dx = 1
            move_dy = 1
        if move_dx == 2 and move_dy == -2:
            move_dx = 1
            move_dy = -1
        if move_dx == -2 and move_dy == 2:
            move_dx = -1
            move_dy = 1
        if move_dx == -2 and move_dy == -2:
            move_dx = -1
            move_dy = -1
        if move_dx >= 2 or move_dx <= -2 or move_dy >= 2 or move_dy <= -2:
            self.selected = [-1, -1]
            return
        m = Move(curr_x, curr_y, move_dx, move_dy)

        print(self.controller.play(m))
        print("from " + str(self.selected))
        print("to " + str(destination))
        self.selected = [-1, -1]
예제 #7
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 def get_move(self, row: int, col: int, drow: int, dcol: int):
     """ Pygame will retrieve the coordinates of the tile and pass those
     into getMove to return a Move object.
     """
     # Row, col are the coordinates of the piece you are moving onto some
     # tile: final_row, final_col
     return Move(row, col, drow, dcol)
예제 #8
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    def getPawnMoves(self, row, column, whiteToMove, board, moves, pins):
        piecePinned = False
        pinDirection = ()
        for i in range(len(pins) - 1, -1, -1):
            if pins[i][0] == row and pins[i][1] == column:
                piecePinned = True
                pinDirection = (pins[i][2], pins[i][3])
                pins.remove(pins[i])
                break

        if whiteToMove:  # white's turn
            if row > 0 and board[row - 1][column] == "--":
                if not piecePinned or pinDirection == (-1, 0):
                    moves.append((Move((row, column), (row - 1, column),
                                       board)))
                    if row == 6 and board[row - 2][column] == "--":
                        moves.append(
                            Move((row, column), (row - 2, column), board))
            # capturing other pieces cases
            if row > 0 and column - 1 >= 0:  # left
                if isinstance(
                        board[row - 1][column - 1],
                        Piece) and board[row - 1][column - 1].color == 'black':
                    if not piecePinned or pinDirection == (-1, -1):
                        moves.append(
                            Move((row, column), (row - 1, column - 1), board))
            if row > 0 and column + 1 <= 7:  # right
                if isinstance(
                        board[row - 1][column + 1],
                        Piece) and board[row - 1][column + 1].color == 'black':
                    if not piecePinned or pinDirection == (-1, 1):
                        moves.append(
                            Move((row, column), (row - 1, column + 1), board))

        else:  # black's turn
            if row < 7 and board[row + 1][column] == "--":
                if not piecePinned or pinDirection == (1, 0):
                    moves.append((Move((row, column), (row + 1, column),
                                       board)))
                    if row == 1 and board[row + 2][column] == "--":
                        moves.append(
                            Move((row, column), (row + 2, column), board))
            # capturing other pieces
            if row < 7 and column + 1 <= 7:  # right
                if isinstance(
                        board[row + 1][column + 1],
                        Piece) and board[row + 1][column + 1].color == 'white':
                    if not piecePinned or pinDirection == (1, -1):
                        moves.append(
                            Move((row, column), (row + 1, column + 1), board))
            if row < 7 and column - 1 >= 0:  # left
                if isinstance(
                        board[row + 1][column - 1],
                        Piece) and board[row + 1][column - 1].color == 'white':
                    if not piecePinned or pinDirection == (1, 1):
                        moves.append(
                            Move((row, column), (row + 1, column - 1), board))
예제 #9
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    def addNeighbours(self, move):
        currentX = move.getX()
        currentY = move.getY()

        dl = [-1, -1, 0, 1, 1, 1, 0, -1]
        dc = [0, 1, 1, 1, 0, -1, -1, -1]

        for i in range(0, 8):
            newX = currentX + dl[i]
            newY = currentY + dc[i]
            if newX >= 0 and newX < self.row and newY >= 0 and newY < self.column:
                neighbour = Move(newX, newY, "#")
                if self.existsMove(neighbour) == False:
                    self.moves.append(neighbour)
예제 #10
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    def testAddMove(self):
        repoMoves = RepoMoves(5, 4)
        move = Move(0, 0, "x")

        repoMoves.addMove(move)

        assert len(repoMoves.moves) == 4

        try:
            repoMoves.addMove(move)
            assert False
        except:
            assert True

        repoMoves.drawTable()
예제 #11
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    def drawTable(self):
        for i in range(0, self.row):
            row = ""
            for j in range(0, self.column):

                emptyMove = Move(i, j, "-")
                found = False
                for move in self.moves:
                    if emptyMove == move:
                        row += move.getMark()
                        found = True

                if found == False:
                    row += "-"

            print(row)
예제 #12
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    def getKnightMoves(self, row, column, whiteToMove, board, moves, pins):
        piecePinned = False
        pinDirection = ()
        for i in range(len(pins) - 1, -1, -1):
            if pins[i][0] == row and pins[i][1] == column:
                piecePinned = True
                pinDirection = (pins[i][2], pins[i][3])
                pins.remove(pins[i])
                break

        knightMoves = ((-2, -1), (-2, 1), (-1, -2), (-1, 2), (1, -2), (1, 2),
                       (2, -1), (2, 1))
        enemyColor = 'black' if whiteToMove else 'white'
        for currentMove in knightMoves:
            endRow = row + currentMove[0]
            endCol = column + currentMove[1]
            if 0 <= endRow < 8 and 0 <= endCol < 8:
                if not piecePinned:
                    endPiece = board[endRow][endCol]
                    if (isinstance(endPiece, Piece) and endPiece.color
                            == enemyColor) or endPiece == "--":
                        moves.append(
                            Move((row, column), (endRow, endCol), board))
예제 #13
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파일: King.py 프로젝트: andreivlad17/Chess
 def getKingMoves(self, row, column, whiteToMove, board, moves,
                  whiteKingPos, blackKingPos, pinsAndChecks):
     rowMoves = (-1, -1, -1, 0, 0, 1, 1, 1)
     colMoves = (-1, 0, 1, -1, 1, -1, 0, 1)
     enemyColor = 'black' if whiteToMove else 'white'
     for currentMove in range(8):
         endRow = row + rowMoves[currentMove]
         endCol = column + colMoves[currentMove]
         if 0 <= endRow < 8 and 0 <= endCol < 8:
             endPiece = board[endRow][endCol]
             if (isinstance(endPiece, Piece)
                     and endPiece.color == enemyColor) or endPiece == "--":
                 if enemyColor == "black":
                     whiteKingPos = (endRow, endCol)
                 else:
                     blackKingPos = (endRow, endCol)
                 inCheck, pins, checks = pinsAndChecks
                 if not inCheck:
                     moves.append(
                         Move((row, column), (endRow, endCol), board))
                 if enemyColor == "black":
                     whiteKingPos = (row, column)
                 else:
                     blackKingPos = (row, column)
예제 #14
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 def _get_easy_move(self):
     """ Easy mode will calculate a random move to make
         Checks if any piece can jump, if so does that. Otherwise makes
         random move. This method will return either a list containing
         a single more or a list containing multiple moves representing
         a path of multiple jumps.
     """
     # Stores the possible moves and jump paths found
     moves = []
     required_jumps = []
     for row in range(self._checkers.dimension):
         for col in range(self._checkers.dimension):
             # Check same color pieces as player to see if they can jump.
             if self._checkers.get(row, col) == self._player:
                 path_made = False
                 found_jumps = []
                 # Attempt to build a jump path in the two forward
                 # directions
                 for i in range(1):
                     current_path = []
                     while (not path_made):
                         jumps = self.check_for_jump(self._player, row, col)
                         if jumps == []:
                             path_made = True
                             break
                         current_path += (jumps)
                         incrow = 0
                         inccol = 0
                         # The forward direction depends on the player's
                         # perspective.
                         if (self._player == CheckersBoard.player_1):
                             # Black looks downwards
                             if i == 0:
                                 incrow = 2
                                 inccol = 2
                             elif i == 1:
                                 incrow = 2
                                 incrow = -2
                         elif (self._player == CheckersBoard.player_2):
                             # Red looks upwards
                             if i == 0:
                                 incrow = -2
                                 inccol = -2
                             elif i == 1:
                                 incrow = -2
                                 incrow = 2
                         row += incrow
                         col += inccol
                     found_jumps.append(current_path)
                 # If some jump paths were found then add them to the jumps
                 # list
                 if len(found_jumps) > 0:
                     required_jumps += found_jumps
                 else:
                     # Checks for regular moves in the forward direction
                     if self._player == CheckersBoard.player_1:
                         # If player is black
                         left = self._checkers.get(row + 1, col + 1)
                         right = self._checkers.get(row + 1, col - 1)
                         if left == CheckersBoard.empty:
                             moves.append(Move(row, col, 1, 1))
                         if right == CheckersBoard.empty:
                             moves.append(Move(row, col, 1, -1))
                     else:
                         # If player is red
                         left = self._checkers.get(row - 1, col - 1)
                         right = self._checkers.get(row - 1, col + 1)
                         if left == CheckersBoard.empty:
                             moves.append(Move(row, col, -1, -1))
                         if right == CheckersBoard.empty:
                             moves.append(Move(row, col, -1, 1))
     # Calculates a random move or move path from the two built lists
     # If a move can be made we prioritize the list with possible moves
     random_index = 0
     if len(required_jumps) != 0:
         random_index = random.randint(0, len(required_jumps))
         move_path = required_jumps[random_index]
         return move_path
     else:
         random_index = random.randint(0, len(moves))
         move = moves[random_index]
         return [move]
예제 #15
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 def _get_easy_move(self):
     """ Easy mode for the computer king will search the four diagonals
         around the player for empty spots and potential pieces to jump.
         If it finds pieces to jump it prioritizes them.This method will
         return either a list containing a single more or a list containing
         multiple moves representing a path of multiple jumps.
     """
     # Two lists keep track of regular moves and paths of possible jumps
     moves = []
     required_jumps = []
     for row in range(self._checkers.dimension):
         for col in range(self._checkers.dimension):
             # Check same color pieces as player to see if they can jump.
             if self._checkers.get(row, col) == self._player:
                 path_made = False
                 found_jumps = []
                 # i represents an option of direction to check
                 for i in range(3):
                     current_path = []
                     # Builds a path of jumps by checking for a jump each
                     # move
                     while (not path_made):
                         jumps = self.check_for_jump(self._player, row, col)
                         if jumps == []:
                             path_made = True
                             break
                         current_path += (jumps)
                         incrow = 0
                         inccol = 0
                         # South west and east
                         if i == 0:
                             incrow = 2
                             inccol = 2
                         elif i == 1:
                             incrow = 2
                             incrow = -2
                         # North west and east
                         elif i == 2:
                             incrow = -2
                             inccol = -2
                         elif i == 3:
                             incrow = -2
                             incrow = 2
                         row += incrow
                         col += inccol
                     found_jumps.append(current_path)
                 if len(found_jumps) > 0:
                     # If there is at least one path then we append it
                     # to the list of jumps
                     required_jumps += found_jumps
                 else:
                     # Checks if a move can be made in each direction
                     north_west = self._checkers.get(row - 1, col - 1)
                     north_east = self._checkers.get(row - 1, col + 1)
                     south_west = self._checkers.get(row + 1, col + 1)
                     south_east = self._checkers.get(row + 1, col - 1)
                     if north_west == CheckersBoard.empty:
                         moves.append(Move(row, col, -1, -1))
                     if north_east == CheckersBoard.empty:
                         moves.append(Move(row, col, -1, 1))
                     if south_west == CheckersBoard.empty:
                         moves.append(Move(row, col, 1, 1))
                     if south_east == CheckersBoard.empty:
                         moves.append(Move(row, col, 1, -1))
     # A random move is calculated for the lists of moves
     # If a move can be made we prioritize the list with possible moves
     random_index = 0
     if len(required_jumps) != 0:
         random_index = random.randint(0, len(required_jumps))
         move_path = required_jumps[random_index]
         return move_path
     else:
         random_index = random.randint(0, len(moves))
         move = moves[random_index]
         return [move]