def build_flake(self):
# Spoke line
spoke = randint(1, 6)
first_line = Lines(self.hexes,
start=helpfunc.get_random_center(),
direction=0,
length=spoke,
color=white())
self.line.append(first_line)
# 2nd line
spoke2 = randint(0, spoke)
if first_line.get_line():
second_line = Lines(self.hexes,
start=choice(first_line.get_line()),
direction=1,
length=spoke2,
color=rgb_to_hsv((250, 250, 255)))
self.line.append(second_line)
# 3rd line
spoke3 = randint(0, spoke2)
if second_line.get_line():
third_line = Lines(self.hexes,
start=choice(second_line.get_line()),
direction=5,
length=spoke3,
color=rgb_to_hsv((245, 245, 255)))
self.line.append(third_line)
def set_colors(self):
skies = [(0, 0, 200), (50, 50, 255), (0, 0, 255), (0, 0, 100),
(100, 100, 255)]
grounds = [(255, 255, 0), (200, 255, 0), (0, 25, 0), (200, 200, 0),
(100, 200, 0)]
self.sky_color = rgb_to_hsv(skies[self.scene])
self.ground_color = rgb_to_hsv(grounds[self.scene])
def next_frame(self):
while True:
if not self.candles:
for h in range(NUM_HEXES):
self.candles += [
Candle(self.hexes, (h, 0, 5), 9), # center candle
Candle(self.hexes, (h, -3, 5), 6), # left candle
Candle(self.hexes, (h, 3, 2), 6)
] # center candle
candle_gray = 255 * self.tot_candles() / (20.0 * NUM_HEXES)
wind = randint(0, 5) if one_in(5) else 10
self.hexes.black_all_cells()
# self.hexes.set_all_cells(rgb_to_hsv((0, 0, candle_gray))) # Set background to blue-ish
for candle in self.candles:
candle.draw_candle(
rgb_to_hsv((candle_gray, candle_gray, candle_gray)), wind)
if not candle.burn_candle():
self.candles.remove(candle)
yield self.speed
def beacon_shader(self,p):
# use progress
if self.show:
color_hsv = rgb_to_hsv(self.color)
if self.all:
dist_x = 1-abs(p['point'][0])
dist_y = 1-abs(p['point'][1])
dist_z = 1-abs(p['point'][2])
if dist_x < 0.02:
return hsv (color_hsv[0], color_hsv[1], 1-dist_x)
if dist_y < 0.02:
return hsv (color_hsv[0], color_hsv[1], 1-dist_y)
if dist_z < 0.2:
return hsv (color_hsv[0], color_hsv[1], 1-dist_z)
return (0,0,0)
else:
dist = abs(p['point'][2]-1)
if dist > 0.1:
dist=1
return hsv (color_hsv[0], color_hsv[1], 1-dist)
else:
return (0,0,0)
def __init__(self, hexmodel):
self.name = "Storm"
self.hexes = hexmodel
self.drops = [] # List that holds Raindrop objects
self.bolts = [] # List that holds Lighting bolts
self.wind = (4 + randint(0, 2)) % 6
self.speed = 0.1
self.drop_length = 2
self.rain_intense = helpfunc.NUM_HEXES
self.rain_hue = 235 # Grey
self.rain_color = rgb_to_hsv(
(self.rain_hue, self.rain_hue, self.rain_hue))
self.background_hue = 15
self.background_color = rgb_to_hsv(
(self.background_hue, self.background_hue, self.background_hue))
self.clock = 0
def next_frame(self):
self.square.clear()
while (True):
for i in range(self.density):
self.raindrops.add_brick(random_color_range(self.blue, 0.05),
life=self.square.height + 2,
pos=(randint(-10,
10 + self.square.width),
self.square.height),
length=0,
pitch=1,
length_x=0,
length_y=-1,
dx=self.wind / 10.0,
dy=-1,
accel_x=0,
accel_y=0,
use_faders=False)
self.raindrops.move_bricks()
if one_in(20):
self.density = up_or_down(self.density, 1, 2, 10)
if one_in(20):
self.wind = up_or_down(self.wind, 1, -10, 10)
self.raindrops.set_all_dx(self.wind / 10.0)
if one_in(500):
self.square.set_all_cells(rgb_to_hsv((255, 255, 100)))
yield self.speed # random time set in init function
def __init__(self, hexmodel):
self.name = "Seasons"
self.hexes = hexmodel
self.treespot = [] # List that holds branch cells
self.leaves = [] # List that holds leaf objects
self.sky_color = black() # Set for each season
self.ground_color = black() # Set for each season
self.treecolor = rgb_to_hsv((54, 0, 0)) # Dark brown
def draw_stuff(self, clock):
pos = get_cell((self.h, self.x_coord, self.y_coord))
color = rgb_to_hsv((self.gray, self.gray, self.gray))
# Draw two lines
self.hexes.set_cells(helpfunc.hex_line_in_direction(pos, 1, 1), color)
hex1 = helpfunc.hex_in_direction(pos, 0, 1)
self.hexes.set_cells(helpfunc.hex_line_in_direction(hex1, 1, 1), color)
def __init__(self, squaremodel):
self.name = "Rain"
self.square = squaremodel
self.raindrops = Bricks(squaremodel)
self.speed = 0.04
self.blue = rgb_to_hsv((0, 0, 255))
self.density = randint(2, 10)
self.wind = 0
def __init__(self, squaremodel):
self.name = "Fireworks"
self.square = squaremodel
self.tails = Bricks(squaremodel, bounce=False)
self.heads = Bricks(squaremodel, bounce=False)
self.speed = 0.1
self.tail_color = rgb_to_hsv((255, 255, 255)) # white
self.head_color = rand_color()
self.density = randint(2, 20)
self.counter = 0
def __init__(self, hexmodel):
self.name = "Driving"
self.hexes = hexmodel
self.stuffs = [] # List that holds stuffs objects
self.sky_color = black() # Set for each season
self.ground_color = rgb_to_hsv((255, 255, 0)) # Set for each season
self.cars_speed = 1.0 # How fast the scene moves
self.clock = 0
self.scene = 0
self.max_scene = 6
def __init__(self, hexmodel):
self.name = "Volcano"
self.hexes = hexmodel
self.rocks = [] # List that holds rocks
self.rock_intense = [randint(3, 8) for _ in helpfunc.all_hexes()
] # Lower = more rocks
self.lava_color = random_color(reds=True)
self.volcano_color = rgb_to_hsv((100, 100, 100)) # Grey: (x,x,x)
self.background_color = black()
self.speed = 0.05 * randint(1, 5)
self.clock = 0
def __init__(self, squaremodel):
self.name = "WavePendulumFilled"
self.square = squaremodel
self.speed = 0.05
self.counter = 0
self.color = rand_color()
self.min_freq = 10 # fastest pendulum does this many cycles in one loop
self.cycle_time = 5 # speed of one cycle
self.cycles = int(self.cycle_time / self.speed)
self.black = rgb_to_hsv((0, 0, 0))
self.gradient = 10
self.up_down = True
def shader(self, p):
x = p['point'][0]
dist_x = abs(x - self.dx) # trail - small is large tail
if dist_x < self.trail:
color_hsv = rgb_to_hsv(self.color) # set the intesity to the distance
dist_x = dist_x / self.trail
return hsv (color_hsv[0], color_hsv[1], 1-dist_x)
else:
return self.background
def shader(self, p):
z = p['point'][2]
dist_z = abs(z - self.dz)
if dist_z < self.trail:
color_hsv = rgb_to_hsv(self.color) # set the intesity to the distance
dist_z = dist_z / self.trail
return hsv (color_hsv[0], color_hsv[1], 1-dist_z)
else:
return self.background
def plot_grid(xs, ys, vals, title, xlabel="", ylabel=""):
fig, ax = plt.subplots()
d = 5
xmin = min(0, min(xs)) - d
xmax = max(100, max(xs)) + d
ymin = min(0, min(ys)) - d
ymax = max(100, max(ys)) + d
print(int(xmin), int(xmax), int(ymin), int(ymax))
ax.set_xlim(xmin=xmin, xmax=xmax)
ax.set_ylim(ymin=ymin, ymax=ymax)
smallest_val = min(vals)
biggest_val = max(vals)
value_range = biggest_val - smallest_val
smallest_circle = 0.1
biggest_circle = 2
circle_range = value_range
color_range = value_range
start_color = color.rgb_to_hsv(0, 1, 0)
end_color = color.rgb_to_hsv(1, 0, 0)
for (x, y, val) in zip(xs, ys, vals):
current_color = color.hsv_to_rgb(
*color.lerp3(start_color, end_color, val -
smallest_val, color_range))
current_radius = smallest_circle + (
val - smallest_val) * biggest_circle / value_range
ax.add_artist(plt.Circle((x, y), current_radius, color=current_color))
plt.xlabel(xlabel)
plt.ylabel(ylabel)
plt.title(title)
def next_frame(self):
while self.clock < self.show_length * 2:
# Background the screen to a shade of blue
self.hexes.set_all_cells(rgb_to_hsv((0, 0, self.background)))
# Which sub-show are we in?
if self.clock > self.show_length: # in show: Snow Fall
for i in range(self.rain_intense * helpfunc.NUM_HEXES):
self.drops.append(Snow(self.hexes, self.wind))
# Draw all the snow
for drop in self.drops:
drop.draw_snow()
if not drop.move_snow(): # Drop off screen
self.drops.remove(drop)
else: # in show: Big Flake
self.big_flake.move_flake()
self.big_flake.draw_flake()
self.clock += 1
if self.clock >= self.show_length * 2:
self.clock = 0
# Randomly change the wind direction, speed and drop length
if helpfunc.one_in(100):
self.wind = (4 + randint(0, 2)) % 6
if helpfunc.one_in(100):
self.rain_intense = helpfunc.up_or_down(
self.rain_intense, 1, 1, 5)
if helpfunc.one_in(50):
self.speed = helpfunc.up_or_down(self.speed, 0.05, 0.05, 0.5)
# Randomly change the colors
if helpfunc.one_in(50):
self.background = helpfunc.up_or_down(self.background, 4, 50,
255)
yield self.speed
def draw_candle(self, candle_color, wind):
# Draw glow
glow_size = int(self.height / 2)
glow_cent = self.get_wick() if wind == 10 else hex_in_direction(
self.get_wick(), wind)
self.hexes.set_cell(glow_cent, rgb_to_hsv((200, 200, 0)))
for rings in range(1, glow_size + 1):
self.hexes.set_cells(
hex_ring(glow_cent, rings),
rgb_to_hsv((255 - (rings * 30), 255 - (rings * 30), 0)))
# Draw wax
self.draw_line(self.bottom, 2, self.height - 1, candle_color)
self.draw_line(hex_in_direction(self.bottom, 4), 2, self.height,
candle_color)
self.draw_line(hex_in_direction(self.bottom, 0), 2, self.height,
candle_color)
# Draw Flame
if one_in(2):
self.hexes.set_cell(self.get_wick(),
rgb_to_hsv((255, randint(125, 255), 0)))
def next_frame(self):
while True:
self.hexes.set_all_cells(rgb_to_hsv(
(255, 255, 255))) # Set background to white
for eye in self.eyes:
eye.draw_ball()
eye.draw_lids()
eye.draw_rays()
eye.wink()
eye.move_eye_ball()
eye.update_rays()
yield self.speed # random time set in init function
def build_set(_dict, sort_by='hsv'):
image_list = []
_list = _dict.keys()
if sort_by == 'hls':
_list.sort(key=lambda rgb: color.rgb_to_hls(to_tuple(rgb)))
elif sort_by == 'hsl':
_list.sort(key=lambda rgb: color.rgb_to_hsl(to_tuple(rgb)))
elif sort_by == 'hsv':
_list.sort(key=lambda rgb: color.rgb_to_hsv(to_tuple(rgb)))
elif sort_by == 'lum':
_list.sort(key=lambda rgb: color.luminance(to_tuple(rgb)))
rgb_list = map(to_tuple, _list)
for c_item in _list:
image_list += _dict.get("{}".format(c_item))
return image_list
def shader(self,p):
x = p['point'][0]
y = p['point'][1]
z = p['point'][2]
x_ = x*cos(self.angle)-y*sin(self.angle)
y_ = x*sin(self.angle)+y*cos(self.angle)
col = rgb_to_hsv(self.flag)
if (abs(x_)<0.3 and abs(z)<0.6 and y_>0):
return hsv(col[0], col[1], 1-abs(x_))
#return hsv(0.3, 0, 1-abs(x_))
if (abs(z)<0.2 and abs(x_)<0.6 and y_>0):
return hsv(col[0], col[1], 1-abs(z))
#return hsv(0.3, 0, 1-abs(z))
# background
return self.background
def shader(self, p):
x = p['point'][0]
y = p['point'][1]
z = p['point'][2]
x_rot = x
# y_rot = y # will hold the rotated variables
# moving packman - we need to rotate x and y
if self.move:
rotate = self.progress * 2*pi # mouth opens 4 times and one
# progress is one revolution
# map to circle
x_rot = x * cos(rotate) - y * sin(rotate)
#y_rot = y * cos(rotate) + x * sin(rotate)
# This is PacMan, believe it or not, well, almost
# y_ = 1 - x_rot**2 - z**2
z_ = tan(self.angle) * x_rot
# Learning: The perfect math does not always create the best visual representation
# and cheating is more fun and faster too ;)
if x_rot < 0: return self.color # the non-mouth half of pacman
#if y_ < abs(y_rot) and z_ < abs(z):
if z_ < abs(z):
color_hsv = rgb_to_hsv(self.color)
# -- dist = ((x_rot-x)**2 + (y_rot-y_)**2 + (z-z_)**2) * 4
# working: dist = ((y_rot-y_)**2 + (z-z_)**2) * 4
dist = abs(z-z_)
intensity = 1
if dist < 0.1:
#intensity = 10*dist
intensity = 10*dist
#if dist > 1: dist = 1
# intensity = cos(dist)
return hsv (color_hsv[0], color_hsv[1], intensity)
else:
return self.background
def rotate_x_shader(self, p):
y = p['point'][1]
x = p['point'][0]
# the shape itself
z_ = y*sin(self.angle)+z*cos(self.angle)
# don't change the z-position
dist_z = abs(z_)
if dist_z < self.trail:
color_hsv = rgb_to_hsv(self.color) # set the intesity to the distance
dist_z = dist_z / self.trail
return hsv (color_hsv[0], color_hsv[1], 1-dist_z)
else:
return self.background
def shader(self, p):
z = p['point'][2]
y = p['point'][1]
x = p['point'][0]
# shape tilt
x_ = x*cos(self.tilt)-z*sin(self.tilt)
z_ = z*sin(self.tilt)+x*cos(self.tilt)
y_ = y
# rotate
x__ = x_
y__ = y_*cos(self.angle)-z_*sin(self.angle)
z__ = y_*sin(self.angle)+z_*cos(self.angle)
self.dz = 0
dist_z = abs(z__ - self.dz)
#dist_z = abs(z_ - self.dz)
#dist = sqrt((z_-z) ** 2 + (y_-y) ** 2 + (x_-x) ** 2)
#dist_2 = sqrt((z_-z) **2 + (y_-y) **2)
#if (abs(x_)<0.3 and abs(y_)<0.6 and y_>0):
#if (abs(x_)<self.trail and abs(y_)<self.trail and abs(z_)<self.trail):
#if dist_z < self.trail and dist_y < self.trail:
if dist_z < self.trail:
color_hsv = rgb_to_hsv(self.color) # set the intesity to the distance
dist_z = dist_z / self.trail
#return hsv (color_hsv[0], color_hsv[1], 1-dist_z)
return hsv (color_hsv[0], color_hsv[1], 1-dist_z)
else:
return self.background
def Testing_shader(self, p):
x = p['point'][0]
y = p['point'][1]
z = p['point'][2]
#print 's', self.z
x_ = cos(self.theta) * sin(self.phi)
y_ = cos(self.theta) * cos(self.phi)
z_ = sin(self.theta)
dist = sqrt((z_-z) ** 2 + (y_-y) ** 2 + (x_-x) ** 2)
if dist < self.trail:
color_hsv = rgb_to_hsv(self.color) # set the intesity to the distance
#return hsv (color_hsv[0], color_hsv[1], 1.0-dist*1/self.trail)
dist = dist / self.trail
intensity = 1-dist
# intensity = cos(dist)
return hsv (color_hsv[0], color_hsv[1], intensity)
else:
return self.background
def build_set_complementary(_dict, sort_by='hsv', every=4):
image_list = []
_list = _dict.keys()
if sort_by == 'hls':
_list.sort(key=lambda rgb: color.rgb_to_hls(to_tuple(rgb)))
elif sort_by == 'hsl':
_list.sort(key=lambda rgb: color.rgb_to_hsl(to_tuple(rgb)))
elif sort_by == 'hsv':
_list.sort(key=lambda rgb: color.rgb_to_hsv(to_tuple(rgb)))
elif sort_by == 'lum':
_list.sort(key=lambda rgb: color.luminance(to_tuple(rgb)))
n = 0
for c_item in _list:
if n % every == 0:
complementary = color.complementary_rgb(to_tuple(c_item))
closest_color = color.find_closest(complementary,
map(to_tuple, _list))
image_list += _dict.get("{}".format(str(closest_color)))
image_list += _dict.get("{}".format(c_item))
n += 1
return image_list
def next_frame(self):
while (True):
# Start new rocks
for h in helpfunc.all_hexes():
if helpfunc.one_in(self.rock_intense[h]):
self.rocks.append(Rock(self.hexes, h, self.lava_color))
# Background the screen - occasionally set to lava red
if helpfunc.one_in(100):
self.hexes.set_all_cells(rgb_to_hsv((200, 0, 0)))
else:
self.hexes.black_all_cells()
self.draw_volcano()
# Draw all the rocks
for rock in self.rocks:
rock.draw_rock()
if not rock.move_rock(): # Is rock dead?
self.rocks.remove(rock)
self.clock += 1
for h in helpfunc.all_hexes():
if helpfunc.one_in(20):
self.rock_intense[h] = helpfunc.up_or_down(
self.rock_intense[h], 1, 3, 8)
if self.clock > 100:
self.clock = 0
if helpfunc.one_in(10):
self.lava_color = random_color_range(self.lava_color, 0.05)
yield self.speed
def shader_rotate_y(self, p):
z = p['point'][2]
y = p['point'][1]
x = p['point'][0]
# shape tilt
z_ = z*sin(self.tilt)+x*cos(self.tilt)
y_ = y
# rotate
z__ = y_*sin(self.angle)+z_*cos(self.angle)
dist_z = abs(z__)
if dist_z < self.trail:
color_hsv = rgb_to_hsv(self.color) # set the intesity to the distance
dist_z = dist_z / self.trail
return hsv (color_hsv[0], color_hsv[1], 1-dist_z)
else:
return self.background
def __init__(self, hexmodel, h):
super(Tree, self).__init__(hexmodel, h)
self.y_coord = randint(0, 5)
self.color = rgb_to_hsv((0, randint(100,
255), 0)) # Some sort of green
self.trunk = rgb_to_hsv((randint(40, 60), 0, 0)) # Dark Brown
def turn_red(self):
r, g, b = self.color
self.color = rgb_to_hsv((255, g, 0))
def draw_stuff(self, clock):
pos = get_cell((self.h, self.x_coord, self.y_coord))
color = rgb_to_hsv((self.gray, self.gray, self.gray))
self.hexes.set_cells(get_triangle(pos, self.size, self.size), color)
def next_frame(self):
self.fill_branches() # Figure out the position of the tree branches
while True:
# Spring
self.sky_color = rgb_to_hsv((100, 100, 255))
self.ground_color = rgb_to_hsv((154, 150, 100))
self.draw_ground(self.sky_color, self.ground_color)
self.draw_tree()
yield 5
self.sky_color = rgb_to_hsv((50, 50, 255))
self.ground_color = rgb_to_hsv((54, 255, 50))
self.draw_ground(self.sky_color, self.ground_color)
self.draw_tree()
yield 0.1
shuffle(self.treespot)
for cell in self.treespot:
if self.hexes.cell_exists(cell):
self.hexes.set_cell(cell, rgb_to_hsv((255, 230, 230)))
yield 0.2
shuffle(self.treespot)
for cell in self.treespot:
if self.hexes.cell_exists(cell):
self.hexes.set_cell(cell, rgb_to_hsv((0, 255, 0)))
yield 0.2
# Big leaves
shuffle(self.treespot)
for cell in self.treespot:
green = rgb_to_hsv((0, randint(50, 255), 0))
self.leaves.append(Leaf(self.hexes, cell, green))
for cell in helpfunc.hex_ring(cell, 1):
self.leaves.append(Leaf(self.hexes, cell, green))
self.draw_leaves()
yield 0.5
# Apples
apple_color = rgb_to_hsv((255, 0, 0))
for i in range(5):
apple = choice(self.treespot)
if self.hexes.cell_exists(apple):
self.hexes.set_cell(apple, apple_color)
yield 0.5
yield 5
# Fall foliage
shuffle(self.leaves)
for leaf in self.leaves:
leaf.turn_red()
self.draw_leaves()
yield 0.05
# Drop leaves
self.sky_color = rgb_to_hsv((0, 0, 200))
self.ground_color = rgb_to_hsv((54, 155, 50))
shuffle(self.leaves)
for leaf in self.leaves:
leaf.fall()
for leaf2 in self.leaves:
leaf2.move_leaf()
self.draw_ground(self.sky_color, self.ground_color)
self.draw_tree()
self.draw_leaves()
yield 0.1
self.sky_color = rgb_to_hsv((0, 0, 100))
self.ground_color = rgb_to_hsv((25, 105, 25))
for _ in range(10):
for l2 in self.leaves:
l2.move_leaf()
self.draw_ground(self.sky_color, self.ground_color)
self.draw_tree()
self.draw_leaves()
yield 0.1
self.sky_color = rgb_to_hsv((0, 0, 50))
self.ground_color = rgb_to_hsv((25, 50, 25))
# Remove leaves
for leaf in self.leaves:
self.leaves.remove(leaf)
self.draw_ground(self.sky_color, self.ground_color)
self.draw_tree()
self.draw_leaves()
yield 0.1
yield 5
# Destroy tree
self.branches = []
self.hexes.black_all_cells()
yield 4
def next_frame(self):
while True:
for _ in range(self.rain_intense):
if len(self.drops) <= self.clock / (20 * helpfunc.NUM_HEXES):
self.drops.append(
Raindrop(hexmodel=self.hexes,
color=self.rain_color,
direction=self.wind))
self.hexes.set_all_cells(self.background_color)
# Draw all the drops
for drop in self.drops:
for _ in range(self.drop_length):
drop.draw_drop()
if not drop.move_drop(): # Drop off screen
self.drops.remove(drop)
break
self.clock = (self.clock + 1) % 100
# Randomly change the wind direction and drop length
if helpfunc.one_in(100):
self.wind = (4 + randint(0, 2)) % 6
if helpfunc.one_in(100):
self.drop_length = helpfunc.up_or_down(self.drop_length, 1, 1,
3)
if helpfunc.one_in(100):
self.rain_intense = helpfunc.up_or_down(
self.rain_intense, 1, 1, 5)
# Randomly change the colors
if helpfunc.one_in(50):
self.rain_hue = helpfunc.up_or_down(self.rain_hue, 4, 220, 255)
self.rain_color = rgb_to_hsv(
(self.rain_hue, self.rain_hue, self.rain_hue))
if helpfunc.one_in(50):
self.background_hue = helpfunc.up_or_down(
self.background_hue, 4, 0, 50)
self.background_color = rgb_to_hsv(
(self.background_hue, self.background_hue,
self.background_hue))
# draw flash lighting
if helpfunc.one_in(100):
self.hexes.set_all_cells(rgb_to_hsv((255, 255, 127)))
yield 0.3
# draw bolt lighting - a bolt is just a quickly-moving raindrop that does not erase
if helpfunc.one_in(50):
# set background to dark blue
self.hexes.set_all_cells(rgb_to_hsv(
(0, 0, 127))) # Dark blue background
yield 0.05
for _ in range(
randint(
1 * helpfunc.NUM_HEXES, 3 *
helpfunc.NUM_HEXES)): # number of lighting bolts
self.bolts.append(
Raindrop(hexmodel=self.hexes,
color=rgb_to_hsv((255, 255, 0)),
direction=5))
for _ in range(10): # bolt length
yield 0.05
# draw all the bolts
for bolt in self.bolts:
bolt.draw_drop()
if helpfunc.one_in(8):
branch = Raindrop(hexmodel=self.hexes,
color=rgb_to_hsv((255, 255, 0)),
direction=5)
branch.set_pos(branch.pos)
branch.wiggle_drop()
self.bolts.append(branch)
if helpfunc.one_in(5):
bolt.wiggle_drop()
if not bolt.move_drop(): # Drop off screen
self.bolts.remove(bolt)
yield 0.05
self.bolts = [] # need to clear bolts
yield self.speed
def __init__(self, hexmodel, h):
super(RedTree, self).__init__(hexmodel, h)
red = randint(200, 255)
self.color = rgb_to_hsv(
(randint(200, 255), randint(0, red), 0)) # Some sort of yellow/red
