def setFutureTile(self):
# princess move inside of the box, just east and west
# set the new tile target, where she is going to
if self.direction == 'e':
future_tile_number = self.get_number() + Tile.H
if future_tile_number in range(1, Tile.total_tiles + 1):
future_tile = Tile.get_tile(future_tile_number)
if future_tile.walkable: # if player can move for that direction(future tile), we set the target with that tile
# and the method will take cara of how to move the player smothly - on object-classes.py
self.set_target(future_tile)
self.rotate('e')
else:
self.direction = 'w'
#print('w')
elif self.direction == 'w':
future_tile_number = self.get_number() - Tile.H
#print('Position ',self.get_number())
if future_tile_number in range(1, Tile.total_tiles + 1):
future_tile = Tile.get_tile(future_tile_number)
if future_tile.walkable:
self.set_target(future_tile)
self.rotate('w')
#print(future_tile_number)
elif future_tile_number <= 32*15:
self.direction = 'e'
async def discard_tile(self):
dm = self.disc.dm_channel
hand_picture = player_image(self, False, False)
hand = discord.File(hand_picture, filename="hand.png")
if not dm:
dm = await self.disc.create_dm()
await dm.send('your hand', file=hand)
discard = Tile('8', 'z')
query = "What tile do you want to discard?\n" + str(self.hand)
while discard not in self.hand.tiles:
try:
discard = await self.user_input(query)
discard = Tile(discard[0], discard[1])
except asyncio.exceptions.TimeoutError:
discard = random.choice(self.hand.tiles)
except ValueError:
discard = Tile('8', 'z')
except IndexError:
discard = Tile('8', 'z')
query = "Invalid discard, please try again."
self.temp_furiten = False
self.hand.remove_tiles(discard)
hand_picture = player_image(self, True, True, str(discard))
return discard, hand_picture
async def riichi(self, draw, game):
#this *should* check the hand to make sure its closed
opened = [meld for meld in self.melds.melds if meld.opened]
if opened:
return False
#determine what tiles are discardable to be in tenpai
shanten = shanten_calculator(str(self.hand) + str(draw))
if (shanten == 0 or shanten
== -1) and self.points >= 1000 and not self.in_riichi:
riichi_tiles = []
temp_hand = Tiles()
temp_hand.tiles = self.hand.tiles[:]
temp_hand.add_tiles(draw)
for tile in temp_hand.tiles:
temp = Tiles()
temp.tiles = temp_hand.tiles[:]
temp.remove_tiles(tile)
if winning_tiles(str(temp)) and tile not in riichi_tiles:
riichi_tiles.append(tile)
if riichi_tiles:
try:
reach = await self.user_input('Would you like to riichi?')
except asyncio.exceptions.TimeoutError:
reach = 'n'
if reach != 'y' and reach != 'yes':
return False
else:
return False
discard = Tile('8', 'z')
while discard not in self.hand.tiles and discard != draw:
try:
query = "Which tile would you like to riichi on? Type cancel to cancel riichi.\n" + ' '.join(
map(str, riichi_tiles))
discard = await self.user_input(query)
discard = Tile(discard[0], discard[1])
except asyncio.exceptions.TimeoutError:
return False
except ValueError:
discard = Tile('8', 'z')
except IndexError:
discard = Tile('8', 'z')
#self.discard_tile(choice)
if game.tenhou and game.wall.remaining > 65:
self.double_riichi = True
self.in_riichi = True
self.ippatsu = True
self.points -= 1000
game.riichi += 1
return discard
else:
return False
'''
def resetMaze(self):
Maze.timeExecuted = 1
widthMaze = 0
Maze.heightMaze = 0
Maze.yPos = 0
Maze.xPos = 0
Maze.size_maze = 0
Maze.tilesMaze.clear()
Tile.reset()
def test_end_of_path(self):
paths = [('s1', 'e2'), ('s2', 'w1'), ('e1', 'n2'), ('n1', 'w2')]
tile = Tile(paths)
self.assertAlmostEqual(tile.end_of_path('s1'), 'e2')
self.assertAlmostEqual(tile.end_of_path('e2'), 's1')
hand_tile = HandTile(paths)
self.assertAlmostEqual(hand_tile.end_of_path('e1'), 'n2')
self.assertAlmostEqual(hand_tile.end_of_path('n2'), 'e1')
def construct_tile(tile_dict):
'''
:param tile_dict: dict containing tile obj
:return: constructed tile obj
'''
tile = Tile(tile_dict['idx'], None)
if not tile_dict['position'] == None:
tile.position = (tile_dict['position'][0], tile_dict['position'][1])
tile.list_of_path = tile_dict['list_of_path']
return tile
def spawn(total_frames, FPS):
if total_frames % (FPS * FruitsBonus.bonusTimeGeneration) == 0 and total_frames >0:
# have to put the music
randTile = randint(1,601) # get a randow number tile, we have 600 tiles in the screen
while(not Tile.isTileFree(randTile)): # check if actually, that tile is free, or other words, it's an empty path
randTile = randint(1,601) # get a randow number tile, we have 600 tiles in the screen
tile = Tile.get_tile(randTile) # get the tile, randTile is just the tile number
FruitsBonus(tile.x, tile.y) # have to get the x and y from the tile number now
def setup(self):
"""STEP 2: Sets up the two dimentional list of tiles"""
print("Generating tiles...")
# List of calculated spaces and the rooms
self.spacelist = []
self.roomlist = []
self.corridorlist = []
self.wall_image = pg.image.load("images/wall2.png").convert_alpha()
self.wall_image = pg.transform.scale(self.wall_image, (TILESIZE, TILESIZE))
self.floor_image = pg.image.load("images/floor2.png").convert_alpha()
self.floor_image = pg.transform.scale(self.floor_image, (TILESIZE, TILESIZE))
self.hordoor = pg.image.load("images/hor_door.png").convert_alpha()
self.hordoor = pg.transform.scale(self.hordoor, (TILESIZE, TILESIZE))
self.vertdoor = pg.image.load("images/vert_door.png").convert_alpha()
self.vertdoor = pg.transform.scale(self.vertdoor, (TILESIZE, TILESIZE))
self.rockimage = pg.image.load("images/rock.png").convert_alpha()
self.rockimage = pg.transform.scale(self.rockimage, (TILESIZE, TILESIZE))
self.enterimage = pg.image.load("images/enter.png").convert_alpha()
self.enterimage = pg.transform.scale(self.enterimage, (TILESIZE, TILESIZE))
self.exitimage = pg.image.load("images/exit.png").convert_alpha()
self.exitimage = pg.transform.scale(self.exitimage, (TILESIZE, TILESIZE))
self.playerimage = pg.image.load("images/alfa.png").convert_alpha()
self.playerimage = pg.transform.scale(self.playerimage, (TILESIZE, TILESIZE))
self.map = [[Tile(w*TILESIZE, h*TILESIZE, 0, self.rockimage, self.wall_image, self.floor_image, self.vertdoor, self.hordoor, self.enterimage, self.exitimage, self.playerimage) for h in range(self.height_tiles)] for w in range(self.width_tiles)]
self.playerx = 0
self.playery = 0
self.new_level_x = 0
self.new_level_y = 0
print("Done")
def construct_bag(self):
""" adds tile objects to bag object """
testing = self._are_we_testing()
alphabet = self.config['test']['bag']['word'].lower() if testing \
else self.config['bag']['letters'].keys()
for letter in alphabet:
bag_amount = self.config['test']['bag']['letters'][letter]['bag_amount'] if testing \
else self.config['bag']['letters'][letter]['bag_amount']
point_val = self.config['test']['bag']['letters'][letter]['point_val'] if testing \
else self.config['bag']['letters'][letter]['point_val']
count = 0
while count < bag_amount:
tile = Tile(letter=letter.upper(),
point_val=point_val,
id=count + 1,
bag_amount=bag_amount)
self.contents.append(tile)
count += 1
# check tile amount
tile_count = len(self.contents)
if tile_count < 100 and not testing:
raise ValueError(
"Letter bag only contains {} tiles. Must contain a total of 100."
.format(tile_count))
return None
def spawn(total_frames, FPS):
if total_frames % (FPS * LifeBonus.bonusTimeGeneration) == 0 and total_frames >0:
luckBonus = randint(1,4) # in other words, player has 33.33% of gain a heart life, each 30 seconds
if luckBonus == 1: # new heart will show up if the rand luck bonus is 1
# have to put the music
randTile = randint(1,601) # get a randow number tile, we have 600 tiles in the screen
while(not Tile.isTileFree(randTile)): # check if actually, that tile is free, or other words, it's an empty path
randTile = randint(1,601) # get a randow number tile, we have 600 tiles in the screen
tile = Tile.get_tile(randTile) # get the tile, randTile is just the tile number
LifeBonus(tile.x, tile.y) # have to get the x and y from the tile number now
def load(self, filename, world):
for y, line in enumerate(open(filename, 'r')):
for x, column in enumerate(line):
if column not in TileType.__dict__:
continue
t = Tile(getattr(TileType, column), world, x=x, y=y)
self.tiles[(x, y)] = t
def spawn():
for tile_num in Zombie.zombies:
if tile_num not in Tile.invalidsSideWalls and tile_num not in Tile.invalidsCenterWalls:
spawn_node = Tile.get_tile(
tile_num) # get the tile that represents that tile
Zombie(spawn_node.x, spawn_node.y)
def __init__(self, columns=COLUMNS, rows=ROWS, demo=False,
fadeColor=(100, 100, 100)):
self.tileBatch = pyglet.graphics.Batch()
self.tokenBatch = pyglet.graphics.Batch()
self.tiles = []
self.tokens = []
self.people = []
self.playerBoxes = []
self.dragTile = False
self.moving = False
self.movingTiles = []
self.columns = columns
self.rows = rows
self.ourTurn = False
# make the colour dimmer if we're not running in a real game
self.started = False
self.demo = demo
self.color = (255, 255, 255)
self.fadeColor = fadeColor
self.settings = settings.GameSettings()
# XXX - fix me with something dynamic
offset_x = OFFSET_X
if columns == 7:
offset_x = BOARD_OFFSET_X
offset_y = OFFSET_Y
if rows == 7:
offset_y = BOARD_OFFSET_Y
for y in range(rows):
for x in range(columns):
self.tiles.append(Tile(x * 81 + offset_x,
768 - (y * 81) - offset_y,
x, y,
color=self.color,
tileType=random.randint(1, 3),
tileRotation=random.randint(0, 3),
batch=self.tileBatch))
self.floatingTile = Tile(-100, -100, -1, -1,
color=self.color,
tileType=random.randint(1, 3),
tileRotation=random.randint(0, 3),
batch=self.tileBatch)
events.addListener(self)
pyglet.clock.schedule(self.update)
def construct_obj(res):
'''
:param res: response received from client
:return: constructed tile, and avatar object received from client
'''
tile_dict = res[0]
avatar_dict = res[1]
tile = Tile(tile_dict['idx'], None)
if not tile_dict['position'] == None:
tile.position = (tile_dict['position'][0], tile_dict['position'][1])
tile.list_of_path = tile_dict['list_of_path']
avatar = Avatar(avatar_dict['color'], None)
if not avatar_dict['position'] == None:
pos = avatar_dict['position'][0]
port = avatar_dict['position'][1]
avatar.position = ((pos[0], pos[1]), port)
return tile, avatar
def create_landscape_sprite(self, tile: tiles.Tile) -> None:
'''
Creates four arcade.Sprite for landscape element of tile.
'''
if tile.entity != None:
tile.calculate_view()
sprite_alignment = self.sprite_alignment.get(tile.view['entity'])
sprites = []
for i in range(4):
sprite = TileSprite(self.get_landscape_texture_file(tile, i),
tile, SPRITE_SCALING)
sprite_y, sprite_x = self.map_sprite_coordinate(
tile.y, tile.x, i)
sprite.left = sprite_x
sprite.bottom = sprite_y
self.landscape_sprite_list.append(sprite)
sprites.append(sprite)
self.landscape_sprite_map[(tile.y, tile.x)] = sprites
def _loadTilestacks(self): ret = [] for y in xrange(self.heightInTiles): for x in xrange(self.widthInTiles): ts = Tilestack() ts.addBaseTile(Tile(self.tileFactory, self.baseTile)) ret.append(ts) return ret
def idx_to_tiles(list_idx):
'''
@param: list_idx list of index
@return: list of tile obejcts
'''
tiles = []
for i in list_idx:
tiles.append(Tile(i % 35, None))
return tiles
def defend(self, damage):
if random.randint(1, 20) > self.defense:
self.health -= damage
self.health = max(0, self.health)
if self.health <= 0:
self.level.floor.add(
Tile("images/monsters/grave.gif",
(self.rect.x - 15, self.rect.y - 25)))
self.image = pygame.image.load("images/terrain/bones.gif")
self.alive = False
def createTileList(self, filename):
layout = numpy.loadtxt(filename, dtype=str)
col, row = layout.shape
for i in range(row):
for j in range(col):
value = layout[j][i]
if (value == '0'):
pos = (i*self.width, j*self.height)
self.tilelist.append(Tile((self.width, self.height), pos))
return self.tilelist
def defend(self, damage):
if random.randint(1, 20) > self.defense:
self.health -= damage
self.heath = max(0, self.heath)
self.level.messages.add(movingMessage("--{}".format(damage), self.rect.topleft, (255, 0, 0)))
if self.heath <= 0:
self.level.message.add(Message("rip", self.ract.center))
self.level.floor.add(Tile("images/monsters/grave.gif", (self.rect.x-15, self.rect.y-25)))
self.image = pygame.image.load("images/terrain/bones.glf")
self.alive= False
def load(self, filename):
f = open(filename, "rb")
data = f.read(struct.calcsize("<i"))
data = struct.unpack("<i", data)
self.tiles = []
for i in range(0, data[0]):
self.tiles.append(Tile.load(f))
f.close()
self.update_neighbors()
def boardToSprites(self):
gameBoard = self.settings.board
self.rows = gameBoard.rows
self.columns = gameBoard.columns
# is this going to gc correctly?
self.tiles = []
self.tokens = []
for y in range(gameBoard.rows):
for x in range(gameBoard.columns):
tile = gameBoard.board[y][x]
self.tiles.append(
Tile(x * 81 + BOARD_OFFSET_X,
768 - (y * 81) - BOARD_OFFSET_Y,
x, y,
color=(255, 255, 255),
tileType=tile.tileType,
tileRotation=tile.tileRotation,
batch=self.tileBatch))
if tile.boardItem and not tile.boardItem.found:
self.tokens.append(
Token(int(tile.boardItem.itemNumber),
self.tiles[-1].x,
self.tiles[-1].y,
x, y,
batch=self.tokenBatch))
self.floatingTile = \
Tile(FLOATINGTILE_LOCATION_X,
FLOATINGTILE_LOCATION_Y,
-1, -1,
color=(255, 255, 255),
tileType=gameBoard.floatingTile.tileType,
tileRotation=gameBoard.floatingTile.tileRotation,
batch=self.tileBatch)
for player in self.settings.board.players:
column, row = player.getLocation()
playerSprite = character.Character(column, row)
tile = self.getTile(column, row)
playerSprite.x, playerSprite.y = tile.xy
self.people.append(playerSprite)
self.playerBoxes.append(PlayerBox(player.playerNumber))
for item in player.boardItems:
self.playerBoxes[-1].addToken(item.itemNumber)
pass
def load( self, filename ):
f = open( filename, "rb" )
data = f.read( struct.calcsize("<i") )
data = struct.unpack( "<i", data )
self.tiles = []
for i in range(0, data[0]):
self.tiles.append( Tile.load( f ) )
f.close()
self.update_neighbors()
def player_pick_tile_from_middle(self) -> None:
"""
Handle everything if a player choses to draw from the middle.
This includes taking the starting player marker, but also removing tile
type from the middle and adding it to the pattern lines
"""
if self.the_middle.is_untouched:
self.starting_player = self.current_player
self.the_middle.is_untouched = False
minus_counter = TileCounter(Tile(99), 1)
self.players[self.current_player].board.floor_line += minus_counter
style = int(
input(
"What tile type or you picking? (0=black, 1=blue, 2=red, 3=yellow, 4=white) "
))
tile = Tile(style)
tile_count = self.the_middle.pop(tile)
tile_counter = TileCounter(tile, tile_count)
self.players[self.current_player].board.add_tile_count(tile_counter)
def generate(self):
sea_tile = TILE_TYPES.get('water')
land_tile = TILE_TYPES.get('land')
seeds = self.place_seeds()
for x in range(self.width):
new_row = list()
for y in range(self.height):
new_tile = Tile(sea_tile, x, y) if (x,
y) not in seeds else Tile(
land_tile, x, y)
new_row.append(new_tile)
self._tiles.append(new_row)
self.generate_continents()
self.generate_bioms()
self.clear_glitches()
self.place_resources()
self.place_states(6)
return {
'tiles': self._tiles,
'cities': self._cities,
'resources': self._resources
}
def importer(name, texture_size):
with open(name, "r") as file:
lines = file.readlines()
size = lines[0].split(",")
size = int(size[0]), int(size[1])
grid = Grid(size)
useless = None
collision = False
x, y = 0, 0
state = "new"
for line in lines[1:]:
if "/" in line:
state = "new"
x += 1
if x >= size[0]:
y += 1
x = 0
continue
if "|" in line:
useless, collision = line.split(",")
continue
if state == "new":
texture, position = line.split(",")
tile = Tile(Texture(texture, int(position), texture_size))
tile.collision = bool(int(collision))
grid.put(x, y, tile)
state = "added"
continue
if state == "added":
texture, position = line.split(",")
grid.get(x,
y).add(Texture(texture, int(position), texture_size))
return grid
def setup_level(self, layout):
self.tiles = pygame.sprite.Group()
self.player = pygame.sprite.GroupSingle()
for row_index, row in enumerate(layout):
for col_index, cell in enumerate(row):
x = col_index * tile_size
y = row_index * tile_size
if cell == 'X':
tile = Tile((x, y), tile_size)
self.tiles.add(tile)
elif cell == "P":
player_sprite = Player((x, y), self.display_surface)
self.player.add(player_sprite)
def get_surrounding_tiles(base_node):
# makes an array that save all the combinations of tiles surround the zombie( base_node == zombieTile)
# so if zombie moves to N, W, or etc, we have all these combinations numbers (position + 1 or - 1 or + 18, etc)
# so then we can use them to our math to predict the better path
array =(
(base_node.number + N),
(base_node.number + NE),
(base_node.number + E),
(base_node.number + SE),
(base_node.number + S),
(base_node.number + SW),
(base_node.number + W),
(base_node.number + NW),
)
tiles = []
# *****
# make this change to make the zombie to be able to walk just N,S,E,W - not NE,SW, etc
# original node number
onn = base_node.number
diagonals = [onn + NE, onn + NW, onn + SE, onn + SW]
# *****
# this for get all the new position(number of the tiles) from the array, that represet the tiles sorround from the Zombie
# and get the tile, from Tile list in Tile class. Then we check if zombie can really go in the direction(tile)
# if it does, we add that tile for the tile list
for tile_number in array:
surrounding_tile = Tile.get_tile(tile_number)
# to avoid a zombie to get possible new path in tiles that doen's exist, for example if the zombie is in the
# border, it cannot go up, for that we have to avoid with this if below
if tile_number not in range(1, Tile.total_tiles + 1):
continue # if there'e not that tile, we jump the for for the next loop, so then, it doen's run the lines below
# and consequently, it doen't calculate the path for that tile
if surrounding_tile.walkable and surrounding_tile not in closed_list:
#tiles.append(surrounding_tile) # Diagonal movement - just add this and coment next line
tiles = blocky(tiles, diagonals, surrounding_tile) # make sure to add the tile just if it is n,s,w,e
return tiles
def __init__(self, sizeMAze, WIDTH, HEIGHT):
Maze.widthMaze = WIDTH
Maze.heightMaze = HEIGHT
Maze.size_maze = sizeMAze
Maze.cost_walk = 10
tileWidth = WIDTH // sizeMAze
tileHeight = HEIGHT // sizeMAze
# gonna make N * N maze, each position being a tile ID
mode = sizeMAze # used to check each colum each tile belongs to
yPos = 0 # everytime we change column, it increases by tileHeight
xPos = 0
# calculate x and y positions for each tile
for idMaze in range(1, (sizeMAze * sizeMAze) + 1):
if (
idMaze // mode < 1
): # if it's the number by itself, the tile still belongs to that column
x = xPos * tileWidth
y = yPos
xPos += 1
else:
if (idMaze //
mode == 1): # update y position and reset X variables
x = xPos * tileWidth
y = yPos
xPos = 0
yPos += tileHeight
mode += sizeMAze
Maze.tilesMaze[idMaze] = Tile(tileWidth, tileHeight, x, y)
pygame.Rect.__init__(self, Maze.xPos, Maze.yPos, Maze.widthMaze,
Maze.heightMaze)
self._setNeighbors(sizeMAze)
self._setWalls(sizeMAze)
# get a cell(node) randomly
randomNode = random.randrange(sizeMAze * sizeMAze) + 1
self._generateMazeDFS(Maze.tilesMaze[randomNode])
#self._createMultiplePathsBFS( ) Not good, runs exponetial time by doing BFS from every node to all nodes
self._createMultiplePathsRandom()
def score_floor_line(self) -> List[TileCounter]:
"""
Score and flush the minus point area. Returns a list with TileCounter
that represent the discarded tiles.
The method makes sure that the minus-tile (=Tile(99)) does not end up
in the discarded tiles. The minus-point tile implicitly returns to
TheMiddle (actually it is recreated whenever somebody takes a
'first draw' from TheMiddle)
"""
self.point_total -= self.floor_line.count_minus_points
discarded_tile_list = self.floor_line[:]
self.floor_line = FloorLine()
return [
TileCounter(tile, 1)
for tile in discarded_tile_list
if tile != Tile(99) # Tile(99) is the minus-point tile
]
def update(self, screen, clock_elapsed):
self.img = Survivor.survivor_img[self.current]
rotateDirection = self.direction
self.direction = ''
self.rotate(rotateDirection)
# check if next tile/target is a portal, if it's, we change the player position to one of the other portal tile
if self.tx != None and self.ty != None:
self.movement(clock_elapsed)
# have to change here, instead get where we are, get where we are going to
targetTileNumber = ((self.x // self.width) + Tile.H) + ((self.y // self.height) * Tile.V)
# check if the next tile number is actually inside of the portals list, in the tile class
# it holds the tile numbers that has a portal
if self.future_tile_number in Tile.portals:
sortNewPortalTile = randint(0, 3)
# make sure if actually move from the portal to another one
while Tile.portals[sortNewPortalTile]==targetTileNumber:
sortNewPortalTile = randint(0, 3)
# then change the position of player to the new portal x and y position
futureSortPortal = Tile.get_tile(Tile.portals[sortNewPortalTile])
"""for i in range(10000):
for i in range(10000):
a=i
"""
self.x = futureSortPortal.x
self.y = futureSortPortal.y
self.tx = None
self.ty = None
# after move to the new portal, we move the player, just to make the action of walking throught the portal
"""self.tx = self.x + 32
self.ty = self.y + 32
self.movement()
"""
screen.blit(self.img, (self.x, self.y))
def player_pick_tile_from_factory(self) -> None:
factory_nr = int(input("What factory are you choosing from? "))
style = int(
input(
"What tile type or you picking? (0=black, 1=blue, 2=red, 3=yellow, 4=white) "
))
tile = Tile(style)
tile_count = self.factories[factory_nr].pop(tile)
tile_counter = TileCounter(tile, tile_count)
# Add factory leftovers to the middle
factory_leftover = self.factories[factory_nr]
for k, v in factory_leftover.items():
self.the_middle[k] += v
# Make sure that the factory is empty
self.factories[factory_nr] = Factory()
# Add tiles to player's pattern lines
self.players[self.current_player].board.add_tile_count(tile_counter)
def create(self, tile: tiles.Tile, texture: str, scale: int = 1) -> None:
'''
Creates new static object on specified tile with chosen texture.
'''
new_object = StaticMapObject()
new_object.texture = texture
new_object.sprite = arcade.Sprite(texture, scale)
new_object.size = (new_object.sprite.height, new_object.sprite.width)
new_object.bottom = random.random() + tile.y
new_object.sprite.bottom = int(new_object.bottom * tile.size)
new_object.left = random.random() + tile.x
new_object.sprite.left = int(new_object.left * tile.size)
new_object.tiles = self.game_map.get_tiles(
(int(new_object.bottom), int(new_object.left)),
(int(new_object.bottom + new_object.size[0] / tile.size),
int(new_object.left + new_object.size[1] / tile.size)))
for tile in new_object.tiles:
if tile.entity != None:
return None
for tile in new_object.tiles:
tile.entity = new_object
self.sprite_list.append(new_object.sprite)
self.static_objects_list.append(new_object)
def spawn(total_frames, FPS):
if total_frames % (FPS * Zombie.zombieTimeGeneration) == 0: # how much new zombies will show up per frame
# select one of the musics for when the zombie is create
# however, we create a new zombie around each 3 second, but we don't want to make a zombie sound every 3 second
# so then we put * 6, to the zombie make sound, roundly choose for the list, in each 6 seconds(around)
if total_frames % (FPS * 6) == 0 and total_frames >0:
r = randint(0, 4)
sounds = [pygame.mixer.Sound('../Sound_Effects/I_will_kill_you.wav'),
pygame.mixer.Sound('../Sound_Effects/zombie_attack.wav'),
pygame.mixer.Sound('../Sound_Effects/zombie_scream1.wav'),
pygame.mixer.Sound('../Sound_Effects/zombie_scream2.wav'),
pygame.mixer.Sound('../Sound_Effects/zombie_come_here.wav')]
sound = sounds[ r ]
sound.play()
r = randint(0, len(Tile.dangeounZombies) - 1) # get a random position from spawn_tiles, to put the zombie on screen
tile_num = Tile.dangeounZombies[r] # get the number in that random position of the list
spawn_node = Tile.get_tile(tile_num) # get the tile that represents that tile
Zombie(spawn_node.x, spawn_node.y) # create a new zombie with that tile x and y position, and add to the static
def __init__(self, hex1, hex2, hex3):
self.coordinate = sorted([hex1,hex2,hex3])
self.x = self.coordinate[0]
self.y = self.coordinate[1]
self.z = self.coordinate[2]
self.vertex = False
self.building = 0 #empty = 0, settlement = 1, city == 2
self.building_ownership = 0 #set this equal to the player.index
self.tk_index = None # Tkinter index of settlement or city
port_tile_pairs = [[15,16],[2,9],[4,10],
[12,19],[27,26],[40,33],
[46,38],[44,37],[29,30]]
self.is_port = False
for pair in port_tile_pairs:
if (pair[0] in self.coordinate) and (pair[1] in self.coordinate):
self.is_port = True
#self.settlement_owner = 0 # Owner of settlement on point
#self.city_owner = 0 # Owner of city on point
# Check whether point is valid on board
tile_1 = Tile(self.x)
tile_2 = Tile(self.y)
tile_3 = Tile(self.z)
if tile_1.has_neighbor(tile_2) and tile_2.has_neighbor(tile_3) and \
tile_3.has_neighbor(tile_1):
if not(tile_1.visible) and not(tile_2.visible) and \
not(tile_3.visible):
self.valid = False
else:
self.valid = True
else:
self.valid = False
def interaction(screen, survivor):
for event in pygame.event.get():
if event.type == pygame.QUIT:
pygame.quit()
sys.exit()
# you can change the gun when you press the key/letter 'e'
if event.type == pygame.KEYDOWN:
if event.key == pygame.K_e:
survivor.current += 1
survivor.current %= 3 # to make sure it goes to 0,1,2 - because when you get 3, mode 3 by 3 =0
# Movemnt of the player is gonna be not just when you press a key, but when you press or you are holding
# that's why it goes outside of the loop events
keys = pygame.key.get_pressed()
if keys[pygame.K_w]:# North
# first, before move we have to ckeck if that position is walkable
# so them, you first get the "new" position for that character
# in this case we get the number of the character, that represents
# his position on screen, minus how many we can move, Remember that is is to
# left or right, is gonna move always 1 block, if it's up or down, 18 block
future_tile_number = survivor.get_number() - Tile.V
# then we check if that number of tile is walkable, for the we move
# the character
# first if check if the new tile actually exist, if the tile number is in the Tile list, it can move
if future_tile_number in range(1, Tile.total_tiles + 1):
future_tile = Tile.get_tile(future_tile_number)
if future_tile.walkable: # if player can move for that direction(future tile), we set the target with that tile
# and the method will take cara of how to move the player smothly - on object-classes.py
survivor.set_target(future_tile) # it make the movemnt
survivor.rotate('n') # since we are moving north, we change the rotation of the picture to north
survivor.future_tile_number = future_tile_number
if keys[pygame.K_s]: # South
future_tile_number = survivor.get_number() + Tile.V
if future_tile_number in range(1, Tile.total_tiles + 1):
future_tile = Tile.get_tile(future_tile_number)
if future_tile.walkable: # if player can move for that direction(future tile), we set the target with that tile
# and the method will take cara of how to move the player smothly - on object-classes.py
survivor.set_target(future_tile)
survivor.rotate('s')
survivor.future_tile_number = future_tile_number
if keys[pygame.K_a]: # West
future_tile_number = survivor.get_number() - Tile.H
if future_tile_number in range(1, Tile.total_tiles + 1):
future_tile = Tile.get_tile(future_tile_number)
if future_tile.walkable: # if player can move for that direction(future tile), we set the target with that tile
# and the method will take cara of how to move the player smothly - on object-classes.py
survivor.set_target(future_tile)
survivor.rotate('w')
survivor.future_tile_number = future_tile_number
if keys[pygame.K_d]: # East
future_tile_number = survivor.get_number() + Tile.H
# print("Future left ",future_tile_number)
if future_tile_number in range(1, Tile.total_tiles + 1):
future_tile = Tile.get_tile(future_tile_number)
if future_tile.walkable: # if player can move for that direction(future tile), we set the target with that tile
# and the method will take cara of how to move the player smothly - on object-classes.py
survivor.set_target(future_tile)
survivor.rotate('e')
survivor.future_tile_number = future_tile_number
# you use the arrow to rotate the character, to point for with direction you want to shot. so you can walk left
# pressind 'A', but zombies are coming from right, so you can turn your face to right and shot in that direction
# but keep walking for left
if keys[pygame.K_LEFT]:
survivor.rotate('w')
Bullet(survivor.centerx, survivor.centery +5, -20, 0, 'w', survivor.get_bullet_type() )
elif keys[pygame.K_RIGHT]:
survivor.rotate('e')
Bullet(survivor.centerx, survivor.centery +5, 20, 0, 'e', survivor.get_bullet_type() )
elif keys[pygame.K_UP]:
survivor.rotate('n')
Bullet(survivor.centerx, survivor.centery +5, 0, -20, 'n', survivor.get_bullet_type() )
elif keys[pygame.K_DOWN]:
survivor.rotate('s')
Bullet(survivor.centerx, survivor.centery +5, 0, 20, 's', survivor.get_bullet_type() )
GREEN = [0, 255, 0]
RED = [255, 0, 0]
WIDTH = 960
HEiGHT = 640
pygame.init()
pygame.mixer.pre_init()
pygame.mixer.set_num_channels(3)
pygame.font.init() # initialize font class in pygame
pygame.mixer.init()
screen = pygame.display.set_mode((WIDTH, HEiGHT)) # 32 x 32 size of tiles
pygame.display.set_caption("Maze Game")
# set up all the tiles
Tile.pre_init(screen)
survivor = Survivor(32, 32 * 6)
clock = pygame.time.Clock()
FPS = 24 # if we increase this number, the speed of character will be lower
total_frames = 0
total_frames_welcome = 0
pygame.mouse.set_visible(True)
# load and play background welcome page sound again
pygame.mixer.music.load('../Sounds/htd.wav')
pygame.mixer.music.play(-1) # -1 put to loop the music forever
# Loop until the user clicks the close button.
done = False
Zombie.spawn()
while True:
def get_tile_n(self, number):
return Tile.get_tile(number)
def get_tile(self):
return Tile.get_tile(self.get_number())
def get_pos(img, pos_x, pos_y, depth):
res = img.copy()
h, w = img.shape[:2]
M = cv2.getRotationMatrix2D((w / 2, h / 2), (imu_yaw) * 180 / math.pi, 1)
img = cv2.warpAffine(img, M, (w, h))
# circle mask
circle_mask = np.zeros_like(img)
circle_mask = cv2.circle(circle_mask, (int(w / 2), int(h / 2)), int(h / 2),
[255, 255, 255], -1)
circle_mask = circle_mask[:, :, 0]
# print(h,w)
img = img_correction(img)
blur = cv2.GaussianBlur(img, (7, 7), 0)
hsv = cv2.cvtColor(blur, cv2.COLOR_BGR2HSV)
mask = cv2.adaptiveThreshold(hsv[:, :, 2], 255, cv2.ADAPTIVE_THRESH_GAUSSIAN_C, \
cv2.THRESH_BINARY, 21, 2)
kernel = np.ones((5, 5), np.uint8)
opening = cv2.morphologyEx(mask, cv2.MORPH_OPEN, kernel)
opening = 255 - opening
opening = cv2.dilate(opening, None, iterations=1)
contour_mask = 255 - opening
opening[circle_mask == 0] = 0
# fit lines to extract major direction
minLineLength = 100
lines = cv2.HoughLinesP(image=opening,
rho=1,
theta=np.pi / 180,
threshold=100,
lines=np.array([]),
minLineLength=minLineLength,
maxLineGap=12)
grad = np.zeros((len(lines), 1))
i = 0
for line in lines:
# find two major gradients
x1, y1, x2, y2 = line[0][0], line[0][1], line[0][2], line[0][3]
theta = math.atan(float(y2 - y1) / (x2 - x1)) * 180 / math.pi
grad[i] = theta
i += 1
# cv2.line(img, (x1, y1), (x2, y2), (0, 0, 255), 3, cv2.LINE_AA)
cv2.line(contour_mask, (x1, y1), (x2, y2), 0, 1, cv2.LINE_AA)
hist, bin_edges = np.histogram(grad, density=False)
ind = np.argmax(hist)
best_grad = round((bin_edges[ind] + bin_edges[ind + 1]) / 2, 2)
ind = np.where(np.abs(grad - best_grad) < 10)
good_grads = grad[ind]
best_grad = np.mean(good_grads)
# contour_mask=self.mask_correction(contour_mask)
M = cv2.getRotationMatrix2D((w / 2, h / 2), best_grad, 1)
contour_mask = cv2.warpAffine(contour_mask, M, (w, h))
(contours, _) = cv2.findContours(contour_mask, cv2.RETR_EXTERNAL,
cv2.CHAIN_APPROX_NONE)
contour_mask = cv2.cvtColor(contour_mask, cv2.COLOR_GRAY2BGR)
areas = []
border = 0
r = []
for contour in contours:
rect = cv2.boundingRect(contour)
if rect[0] > border and rect[0] + rect[2] < w - border and rect[
1] > border and rect[3] + rect[1] < h - border:
area = int(rect[3] * rect[2])
# print(area)
ar = float(rect[2]) / rect[3]
real_ar = 0.25 / 0.12
if area > 1000 and area < 120000 and abs(ar / real_ar - 1) < 0.3:
cv2.rectangle(contour_mask, (rect[0], rect[1]),
(rect[2] + rect[0], rect[3] + rect[1]),
(0, 255, 0), 2)
areas.append(area)
r.append(rect)
areas = np.asarray(areas)
hist, bin_edges = np.histogram(areas, bins='fd', density=False)
ind = np.argmax(hist)
# best_area=(bin_edges[ind]+bin_edges[ind+1])/2
best_area = round((bin_edges[ind] + bin_edges[ind + 1]) / 2, 2)
ind = np.where(np.abs(areas - best_area) < 0.1 * best_area)
if len(ind) > 5:
good_areas = areas[ind]
best_area = np.mean(good_areas)
pred_depth = predict_depth(best_area)
pred_depth = pred_depth * math.cos(imu_pitch) * math.cos(imu_roll)
for tile in tiles:
r = tile.one_step_update(r)
for rect in r:
tiles.append(Tile(rect, ind_count))
ind_count += 1
for tile in tiles:
if tile.alive == False:
tiles.remove(tile)
del_x = []
del_y = []
for tile in tiles:
color = colors[tile.ind % 20]
color = tuple([int(x) for x in color])
if len(tile.centers) > 2:
del_x.append(tile.centers[-1][1] - tile.centers[-2][1])
del_y.append(tile.centers[-1][0] - tile.centers[-2][0])
contour_mask = cv2.circle(
contour_mask, (int(tile.centers[-1][0]), int(tile.centers[-1][1])),
5, color, -1)
cv2.putText(contour_mask, str(tile.ind),
(tile.bb[0] + 10, tile.bb[1] + 10), font, 0.8, color, 1,
cv2.LINE_AA)
hist, bin_edges = np.histogram(np.asarray(del_x), bins='fd', density=False)
ind = np.argmax(hist)
best_del_x = round((bin_edges[ind] + bin_edges[ind + 1]) / 2, 2)
hist, bin_edges = np.histogram(np.asarray(del_y), bins='fd', density=False)
ind = np.argmax(hist)
best_del_y = round((bin_edges[ind] + bin_edges[ind + 1]) / 2, 2)
# tile real world dimension
fov_w, fov_h = 48 * math.pi / 180, 36 * math.pi / 180
px_W, px_H = 640, 480
W = 2 * pred_depth * math.tan(fov_w / 2) + 0.0001
ppm = px_W / W
pos_x -= best_del_x / ppm
pos_y -= best_del_y / ppm
return pos_x, pos_y, pred_depth
# -*- coding: utf-8 -*-
from tiles import Tile
from shanten import Shanten
import utils
hand_str = input("input your hand tiles: ")
your_tile = Tile(hand_str)
your_shanten = 8
error_state = your_tile.error_state
rest_tiles = your_tile.rest_card
if error_state:
print("please input right 14 tiles")
hand_tiles = your_tile.hand_tiles
discard_list = []
while not error_state:
shanten_data = Shanten.get_shanten_data(hand_tiles)
your_shanten = shanten_data["all_shanten"]
if your_shanten == -1:
print("win")
break
print("hand_str:", utils.codes_to_str(hand_tiles))
Shanten.print_shanten_message(shanten_data, rest_tiles)
print("------")
discard = input("to discard: ")
discard_code = utils.str_to_code(discard)
hand_tiles.remove(discard_code)
discard_list.append(discard_code)
remove_tiles = input("to remove form deck: ")
remove_card = Tile(remove_tiles).hand_tiles
rest_tiles = Shanten.remove_item(remove_card, rest_tiles)
in_tile = input("in: ")
class Board(AnimateBoard):
def __init__(self, columns=COLUMNS, rows=ROWS, demo=False,
fadeColor=(100, 100, 100)):
self.tileBatch = pyglet.graphics.Batch()
self.tokenBatch = pyglet.graphics.Batch()
self.tiles = []
self.tokens = []
self.people = []
self.playerBoxes = []
self.dragTile = False
self.moving = False
self.movingTiles = []
self.columns = columns
self.rows = rows
self.ourTurn = False
# make the colour dimmer if we're not running in a real game
self.started = False
self.demo = demo
self.color = (255, 255, 255)
self.fadeColor = fadeColor
self.settings = settings.GameSettings()
# XXX - fix me with something dynamic
offset_x = OFFSET_X
if columns == 7:
offset_x = BOARD_OFFSET_X
offset_y = OFFSET_Y
if rows == 7:
offset_y = BOARD_OFFSET_Y
for y in range(rows):
for x in range(columns):
self.tiles.append(Tile(x * 81 + offset_x,
768 - (y * 81) - offset_y,
x, y,
color=self.color,
tileType=random.randint(1, 3),
tileRotation=random.randint(0, 3),
batch=self.tileBatch))
self.floatingTile = Tile(-100, -100, -1, -1,
color=self.color,
tileType=random.randint(1, 3),
tileRotation=random.randint(0, 3),
batch=self.tileBatch)
events.addListener(self)
pyglet.clock.schedule(self.update)
def getTile(self, column, row):
for tile in self.tiles:
if tile.column == column and tile.row == row:
return tile
def boardToSprites(self):
gameBoard = self.settings.board
self.rows = gameBoard.rows
self.columns = gameBoard.columns
# is this going to gc correctly?
self.tiles = []
self.tokens = []
for y in range(gameBoard.rows):
for x in range(gameBoard.columns):
tile = gameBoard.board[y][x]
self.tiles.append(
Tile(x * 81 + BOARD_OFFSET_X,
768 - (y * 81) - BOARD_OFFSET_Y,
x, y,
color=(255, 255, 255),
tileType=tile.tileType,
tileRotation=tile.tileRotation,
batch=self.tileBatch))
if tile.boardItem and not tile.boardItem.found:
self.tokens.append(
Token(int(tile.boardItem.itemNumber),
self.tiles[-1].x,
self.tiles[-1].y,
x, y,
batch=self.tokenBatch))
self.floatingTile = \
Tile(FLOATINGTILE_LOCATION_X,
FLOATINGTILE_LOCATION_Y,
-1, -1,
color=(255, 255, 255),
tileType=gameBoard.floatingTile.tileType,
tileRotation=gameBoard.floatingTile.tileRotation,
batch=self.tileBatch)
for player in self.settings.board.players:
column, row = player.getLocation()
playerSprite = character.Character(column, row)
tile = self.getTile(column, row)
playerSprite.x, playerSprite.y = tile.xy
self.people.append(playerSprite)
self.playerBoxes.append(PlayerBox(player.playerNumber))
for item in player.boardItems:
self.playerBoxes[-1].addToken(item.itemNumber)
pass
# XXX - remove this later
def placePeople(self):
positions = [(0, 0), (self.columns-1, self.rows-1),
(0, self.rows-1), (self.columns-1, 0)]
for count, person in enumerate(self.people):
pos = positions[count]
for tile in self.tiles:
if tile.row == pos[1] and tile.column == pos[0]:
person.x = tile.x
person.y = tile.y
def on_mousePress(self, args):
print "!!! button pressed"
x, y, button, modifiers = args
#self.checkTileClicked(x, y)
if self.ourTurn:
self.pickupFloatingTile(x, y)
def on_mouseRelease(self, args):
print "!!! button released"
x, y, button, modifiers = args
if self.ourTurn:
self.checkTileClicked(x, y)
if self.dragTile:
self.dropFloatingTile(x, y)
def on_mouseDrag(self, args):
x, y, dx, dy, buttons, modifiers = args
if self.dragTile:
self.dragFloatingTile(x, y)
def on_keyPress(self, args):
print "!!! key pressed"
symbol, modifiers = args
if symbol == key.RIGHT:
self.settings.client.send('/rotate clockwise')
elif symbol == key.LEFT:
self.settings.client.send('/rotate counterclockwise')
elif symbol == key.SPACE:
if self.ourTurn:
self.ourTurn = False
self.settings.client.send('/end')
def on_tileRotated(self, args):
print "!!! tile rotated"
print args
self.floatingTile.rotate(int(args[0]))
def on_playerSetup(self, args):
print "!!! player setup"
print args
def on_turnChanged(self, args):
print "!!! player turn changed"
print args
self.settings.board.playerTurn = int(args[1])
print "player turn = %d" % self.settings.board.playerTurn
def on_playerTookObject(self, args):
print "!!! player took object"
print args
playerNum = self.settings.board.playerTurn - 1
player = self.people[playerNum]
for token in self.tokens:
if token.column == player.column and \
token.row == player.row:
tokenId = token.tokenId
for player in self.playerBoxes:
for playerToken in player.tokens:
if playerToken.tokenId == tokenId:
playerToken.setHighlight(True)
self.tokens.remove(token)
break
def on_boardData(self, args):
boardData = args[0]
print "!!! board data = %s" % args[0]
self.settings.board.deserialize(boardData)
if not self.started:
self.boardToSprites()
self.started = True
print "player turn = %d" % self.settings.board.playerTurn
def on_startGame(self, args):
print "!!! start game"
self.demo = False
#self.fallOut()
#self.settings.fallingTiles = True
def on_tilePushed(self, args):
nick, pos, direction = args
self.moveTiles(int(pos), int(direction))
self.settings.client.send('/data')
def on_playerTurn(self, args):
print "!!! your turn"
self.ourTurn = True
self.tilePushed = False
def on_playerMoved(self, args):
nick, column, row = args
print "!!! player moved"
print args
column = int(column)
row = int(row)
traverseGraph = traverse.TraversalGraph(self.settings.board)
playerNum = self.settings.board.playerTurn - 1
startLocation = self.settings.board.players[playerNum].location
print [x.location for x in self.settings.board.players]
pygame.mixer.pre_init()
pygame.mixer.set_num_channels(3)
pygame.font.init() # initialize font class in pygame
pygame.mixer.init()
# 30 tiles horizontal per line
# 30 columns of blocks in total
# and 20 vertical per vertical line
# 20 lines of block in total
screen = pygame.display.set_mode((WIDTH, HEiGHT)) # 32 x 32 size of tiles
pygame.display.set_caption("Hunted")
# set up all the tiles
Tile.pre_init(screen)
clock = pygame.time.Clock()
FPS = 24 # if we increase this number, the speed of character will be lower
total_frames = 0
total_frames_welcome = 0
survivor = Survivor(32, 32*6)
princess = Princess()
# set the welcome/final page of the game
Welcome.set_welcome(screen)
# load the background music
#pygame.mixer.music.load('../Sound_Effects/background2.wav')
def get_tile(self):
return Tile.get_tile(self.get_number())
def load_level(num):
Config.config_level(num)
Drawable.recreateWindow()
Tile.load_level(num)
Character.load_characters(num)
