Ejemplo n.º 1
0
    def __crateMaze(self):
        i = 0
        for y, row in enumerate(self.__matrix):
            for x, cell in enumerate(row):
                if cell == '#':
                    self.__maze[y, x] = model.Wall(i, (x, y),
                                                   color=(0, 0, 255))
                    self.__walls.append(self.__maze[y, x])
                elif cell == '-':
                    self.__maze[y, x] = model.Path(i, (x, y),
                                                   color=(0, 0, 255))
                    self.__paths.append(self.__maze[y, x])
                i += 1

        for y, row in enumerate(self.__maze):
            for x, cell in enumerate(row):
                if type(cell) is model.Path:
                    if type(self.__maze[y, x + 1]) is model.Path:
                        cell.neighbors["right"] = self.__maze[y, x + 1]
                    if type(self.__maze[y, x - 1]) is model.Path:
                        cell.neighbors["left"] = self.__maze[y, x - 1]
                    if type(self.__maze[y - 1, x]) is model.Path:
                        cell.neighbors["up"] = self.__maze[y - 1, x]
                    if type(self.__maze[y + 1, x]) is model.Path:
                        cell.neighbors["down"] = self.__maze[y + 1, x]
Ejemplo n.º 2
0
  def __init__(self, assets):
    super(TestView, self).__init__()
    self.assets = assets

    # Get events 
    nwidget.events.clear(cocos.director.director.window)
    self.is_event_handler = True

    # Ui layer
    ui = CocosWidget()
    self.add(ui, z=1)

    # Load background
    bg = model.Background(self.assets)
    self.add(bg.node)

    # Load marker
    marker = model.Marker(self.assets)
    marker.node.position = 50, 50
    marker.node.scale = 0.25
    self.add(marker.node)

    # Snake instructions
    ui.widgets.append(
      nwidget.Label(
        text="Press arrow keys to change snake sprite",
        size=13,
        color=(255, 255, 255, 255)
      ).bounds(20, 150, 600, 180)
    )

    # Load snake
    snake = model.Snake(self.assets)
    snake.node.position = 50, 100
    snake.node.scale = 0.5
    self.add(snake.node)
    self.snake = snake

    # Path instructions
    ui.widgets.append(
      nwidget.Label(
        text="Press arrow keys to move path in that direction\nL to increase length of path, R to reset path",
        size=13,
        color=(255, 255, 255, 255)
      ).bounds(20, 300, 600, 425)
    )

    # Load a path and draw it
    self.path = model.Path()
    self.reset_path()
    self.path.move(x=-50)
    self.path.move(y=-30)
    self.path.move(x=-100)
    self.path.move(y=-20)
    self.path.move(y=-20)
    self.add(self.path)
Ejemplo n.º 3
0
def cps_value(path=model.Path()):
    vals = [0] * len(model.buildings) * 2
    for i in range(len(model.buildings)):
        #cost_one, time_needed_one, num_one, excess_one = path.cost_of(model.buildings[i], path.index, False)
        cost_ten, time_needed_ten, num_ten, excess_ten = path.cost_of(
            model.buildings[i], path.index, True)
        vals[i] = model.buildings[i].rate
        vals[i + len(model.buildings)] = model.buildings[i].rate * num_ten

    return normalize(vals)
Ejemplo n.º 4
0
def weigh_functions(val_funcs, weights, path=model.Path()):
    if len(val_funcs) != len(weights):
        raise ValueError("Number of Functions and Weights don't match")
    for w in weights:
        if abs(w) > 1: raise ValueError("Weight not between -1 and 1")

    totals = [0] * len(model.buildings) * 2
    for i in range(len(val_funcs)):
        vals = val_funcs[i](path)
        for j in range(len(model.buildings)):
            totals[j] += vals[j] * weights[i]
    return totals
Ejemplo n.º 5
0
    def load_objects(self):

        assets = self.assets

        # Clear events from other views
        nwidget.events.clear(cocos.director.director.window)
        self.is_event_handler = True

        # View model & ui
        self.model = {
            "score": 0,
            "dead": False,
            "updated": False,
            "play_time": 0,
        }
        self.ui = model.Ui("game.py", self.model)
        self.add(self.ui, z=1)  # Above the background

        # bind events
        nwidget.listen("GAME_RESTART", self.on_restart)
        nwidget.listen("GAME_GOTO_MENU", self.on_menu)

        # Background
        bg = model.Background(assets)
        self.add(bg.node)

        # Add path and snake
        self.snake = model.Snake(assets)
        self.path = model.Path()
        width, height = cocos.director.director.get_window_size()
        x = width / 2
        y = height / 2
        self.snake.jump(x, y)
        self.path.jump(x, y)
        self.add(self.snake.node)
        self.add(self.path)
        self.bounds = (0, 0, width, height)

        # Direction
        self.snake.right()
        self.vector = "RIGHT"
        self.speed = SNAKE_SPEED

        # Are we paused because we died?
        self.dead = False

        # Start~
        self.marker = None
        self.inc_dt = 0
        self.generate_marker()
Ejemplo n.º 6
0
def rate_value(path=model.Path()):
    vals = [0] * len(model.buildings) * 2
    for i in range(len(model.buildings)):
        cost_one, time_needed_one, num_one, excess_one = path.cost_of(
            model.buildings[i], path.index, False)
        cost_ten, time_needed_ten, num_ten, excess_ten = path.cost_of(
            model.buildings[i], path.index, True)
        if path.total_cookies[path.index] + cost_one < model.FINAL_GOAL:
            vals[i] = ((
                (model.buildings[i].rate * num_one) / path.rate[path.index]) +
                       1)**(1 / time_needed_one)
        if path.total_cookies[path.index] + cost_ten < model.FINAL_GOAL:
            vals[i + len(model.buildings)] = ((
                (model.buildings[i].rate * num_ten) / path.rate[path.index]) +
                                              1)**(1 / time_needed_ten)

    return normalize(vals)
Ejemplo n.º 7
0
def excess_value(path=model.Path()):
    vals = [0] * len(model.buildings) * 2
    for i in range(len(model.buildings)):
        cost_one, time_needed_one, num_one, excess_one = path.cost_of(
            model.buildings[i], path.index, False)
        cost_ten, time_needed_ten, num_ten, excess_ten = path.cost_of(
            model.buildings[i], path.index, True)
        vals[i] += excess_one
        vals[i + len(model.buildings)] += excess_ten
        if path.total_cookies[path.index] + cost_one > model.FINAL_GOAL:
            vals[i] += model.FINAL_GOAL - path.total_cookies[path.index]
        if path.total_cookies[path.index] + cost_ten > model.FINAL_GOAL:
            vals[i +
                 len(model.buildings
                     )] += model.FINAL_GOAL - path.total_cookies[path.index]

    return normalize(vals)
def random_path(f, path=model.Path()):
    done = False
    while not done:
        building_vals = f(path)
        done = path.buy(vf.choose_weighted(building_vals))
    return path
Ejemplo n.º 9
0
from numpy import loadtxt, array, empty, append
matrix = array([[char for char in line if char != '\n']
                for line in open(MAP_LEVEL1)])
maze = empty((20, 40), dtype=object)

walls = []
paths = []

i = 0
for y, row in enumerate(matrix):
    for x, cell in enumerate(row):
        if cell == '#':
            maze[y, x] = model.Wall(i, (x, y), color=(0, 0, 255))
            walls.append(maze[y, x])
        elif cell == '-':
            maze[y, x] = model.Path(i, (x, y), color=(0, 0, 255))
            paths.append(maze[y, x])
        i += 1

for y, row in enumerate(maze):
    for x, cell in enumerate(row):
        if type(cell) is model.Path:
            if type(maze[y, x + 1]) is model.Path:
                cell.neighbors["right"] = maze[y, x + 1]
            if type(maze[y, x - 1]) is model.Path:
                cell.neighbors["left"] = maze[y, x - 1]
            if type(maze[y - 1, x]) is model.Path:
                cell.neighbors["up"] = maze[y - 1, x]
            if type(maze[y + 1, x]) is model.Path:
                cell.neighbors["down"] = maze[y + 1, x]
def make_path(f, path=model.Path()):
    done = False
    while not done:
        building_vals = f(path)
        done = path.buy(vf.choose_best(building_vals))
    return path
Ejemplo n.º 11
0
def equal_value(path=model.Path()):
    return normalize([1] * len(model.buildings) * 2)