def main():
## create compound yellow/blue turtleshape for planets
global s
s = Screen()
s.setup(1120,840)
s.reset()
s.tracer(0, 0)
t = Turtle()
t.ht()
t.pu()
t.fd(6)
t.lt(90)
t.begin_poly()
t.circle(6, 180)
t.end_poly()
m1 = t.get_poly()
t.begin_poly()
t.circle(6,180)
t.end_poly()
m2 = t.get_poly()
planetshape = Shape("compound")
planetshape.addcomponent(m1,"orange")
planetshape.addcomponent(m2,"blue")
s.register_shape("planet", planetshape)
#s.tracer(1,0)
s.update()
## setup gravitational system
gs = GravSys()
sun = Star(1000000, Vec(-250,0), Vec(0,-0.35), gs, "circle")
sun.color("yellow")
sun.pensize(1.8)
sun.pu()
earth = Star(5000, Vec(450,0), Vec(0,70), gs, "planet")
earth.pencolor("green")
earth.shapesize(0.8)
rm=12.0583
vm=(8.0*5000/rm)**.5
moon = Star(1, Vec(450+rm,0), Vec(0,70+vm), gs, "planet")
moon.pencolor("blue")
moon.shapesize(0.5)
gs.init()
gs.start()
return "Done!"
def create_player_shapes(self, color: str = 'black') -> None:
"""Creates custom turtle shapes for the x and o player markers.
This method sets up custom shapes that can be used with the
turtle.shape() method. Recall that you could make your turtle look
like an actual turtle (instead of the default arrow shape) by calling
turtle.shape('turtle'). After this method has been called, you can
change the sape of your turtle to an x or an o by calling
turtle.shape('x marker') or turtle.shape('o marker').
These shapes are initialized at a size appropriate for display on a
3x3 grid on a 300px game board.
"""
# Build the x out of a backslash and forward slash.
# These numbers are the vertices of the slashes.
backslash = ((-25,-25), (25,25))
forwardslash = ((-25,25), (25,-25))
shape = Shape('compound')
shape.addcomponent(backslash, '', color)
shape.addcomponent(forwardslash, '', color)
self.screen.register_shape('x marker', shape)
# Approximate the o with a 20-sided polygon.
# These numbers are the vertices of the polygon.
circle = (( 00.00,-25.00), ( 07.73,-23.78), ( 14.69,-20.23),
( 20.23,-14.69), ( 23.78,-07.73), ( 25.00, 00.00),
( 23.78, 07.73), ( 20.23, 14.69), ( 14.69, 20.23),
( 07.73, 23.78), ( 00.00, 25.00), (-07.73, 23.78),
(-14.69, 20.23), (-20.23, 14.69), (-23.78, 07.73),
(-25.00, 00.00), (-23.78,-07.73), (-20.23,-14.69),
(-14.69,-20.23), (-07.73,-23.78),)
shape = Shape('compound')
shape.addcomponent(circle, '', color)
self.screen.register_shape('o marker', shape)
def __init__(self, color, x, y):
self.color = color
self.t = Turtle(shape='circle')
self.t.penup()
self.xpos = x
self.ypos = y
self.f = Shape('compound')
def make_paddle_shape(paddle_width_half, paddle_height_half):
paddle_shape = Shape(
"compound") # Compound need to make more complex shape.
# Add points to new shape.
paddle_points = ((-paddle_height_half, -paddle_width_half),
(-paddle_height_half, paddle_width_half),
(paddle_height_half, paddle_width_half),
(paddle_height_half, -paddle_width_half))
# Add points and set color.
paddle_shape.addcomponent(paddle_points, "black")
return paddle_shape
class Person:
def __init__(self, color, x, y):
self.color = color
self.t = Turtle(shape='circle')
self.t.penup()
self.xpos = x
self.ypos = y
self.f = Shape('compound')
def birth(self, s, name):
self.t.shapesize(0.7)
arms = ((15, -10), (15, 10))
body = ((9, 0), (30, 0))
leftleg = ((30, 0), (38, -8))
rightleg = ((30, 0), (38, 8))
self.f.addcomponent(arms, self.color)
self.f.addcomponent(body, self.color)
self.f.addcomponent(leftleg, self.color)
self.f.addcomponent(rightleg, self.color)
self.f.addcomponent(self.t.get_shapepoly(), self.color)
s.register_shape(name, self.f)
self.t.shape(name)
#Compound Shapes here: https://docs.python.org/3/library/turtle.html#compound-shapes
def goTo(self):
self.t.speed('fastest')
self.t.goto(self.xpos, self.ypos)
def death(self):
self.t.clear()
def main():
screen = Screen()
screen.setup(width=1.0, height=1.0) # for fullscreen
screen.bgcolor('black')
screen.title("Apollo 8 Free Return Simulation")
gravsys = GravSys()
image_earth = 'earth_100x100.gif'
screen.register_shape(image_earth)
earth = Body(1000000, (0, -25), Vec(0,-2.5), gravsys, image_earth)
earth.pencolor('white')
earth.getscreen().tracer(n=0, delay=0)
image_moon = 'moon_27x27.gif'
screen.register_shape(image_moon)
moon = Body(32000, (344, 42), Vec(-27, 147), gravsys, image_moon)
moon.pencolor('gray')
csm = Shape('compound')
cm = ((0, 30), (0, -30), (30, 0))
csm.addcomponent(cm, 'white', 'white')
sm = ((-60, 30), (0, 30), (0, -30), (-60, -30))
csm.addcomponent(sm, 'white', 'black')
nozzle = ((-55, 0), (-90, 20), (-90, -20))
csm.addcomponent(nozzle, 'white', 'white')
screen.register_shape('csm', csm)
ship = Body(1, (Ro_X, Ro_Y), Vec(Vo_X, Vo_Y), gravsys, 'csm')
ship.shapesize(0.2)
ship.color('white')
ship.getscreen().tracer(1,0)
ship.setheading(90)
gravsys.sim_loop()
input()
def main():
# Setup screen
screen = Screen()
screen.setup(width=1.0, height=1.0) # for fullscreen
screen.bgcolor('black')
screen.title("Gravity Assist Example")
# Instantiate gravitational system
gravsys = GravSys()
# Instantiate Planet
image_moon = 'moon_27x27.gif'
screen.register_shape(image_moon)
moon = Body(MOON_MASS, (500, 0), Vec(-500, 0), gravsys, image_moon)
moon.pencolor('gray')
# Build command-service-module (csm) shape
csm = Shape('compound')
cm = ((0, 30), (0, -30), (30, 0))
csm.addcomponent(cm, 'red', 'red')
sm = ((-60, 30), (0, 30), (0, -30), (-60, -30))
csm.addcomponent(sm, 'red', 'black')
nozzle = ((-55, 0), (-90, 20), (-90, -20))
csm.addcomponent(nozzle, 'red', 'red')
screen.register_shape('csm', csm)
# Instantiate Apollo 8 CSM turtle
ship = Body(1, (Ro_X, Ro_Y), Vec(Vo_X, Vo_Y), gravsys, "csm")
ship.shapesize(0.2)
ship.color('red') # path color
ship.getscreen().tracer(1, 0)
ship.setheading(90)
gravsys.sim_loop()
def __init__(self):
turtle.Turtle.__init__(self)
goal = PhotoImage(file="images/goal.png").zoom(1, 1)
myscreen.addshape("goal", Shape("image", goal))
self.shape("goal")
self.penup()
self.speed(0)
def main():
# Setup screen
screen = Screen()
screen.setup(width=1.0, height=1.0) # For fullscreen.
screen.bgcolor('black')
screen.title("Apollo 8 Free Return Simulation")
# Instantiate gravitational system
gravsys = GravSys()
# Instantiate Earth turtle
#image_earth = 'earth_100x100.gif'
#screen.register_shape(image_earth)
t = Turtle()
screen.register_shape('earth', drawCircle(6.371, 72, t))
earth = Body(1000000, (-200, 0), Vec(0, -2.5), gravsys, 'earth')
earth.pencolor('white')
earth.fillcolor('white')
earth.getscreen().tracer(0, 0) # So csm polys won't show while drawing.
# Instantiate moon turtle
#image_moon = 'moon_27x27.gif'
#screen.register_shape(image_moon)
#moon_circle = circle(1.737)
screen.register_shape('moon', drawCircle(1.737, 72, t))
moon = Body(32000, (156.7, 0), Vec(-27, 147), gravsys, 'moon')
moon.pencolor('gray')
moon.fillcolor('gray')
# Build command-service-module(csm)shape
csm = Shape('compound')
cm = ((0, 0.1), (0, -0.1), (0.1, 0))
csm.addcomponent(cm, 'Silver', 'red') # Silver and red are also good.
screen.register_shape('csm', csm)
# Instantiate Apollo 8 CSM turtle
ship = Body(1, (Ro_X, Ro_Y), Vec(Vo_X, Vo_Y), gravsys, 'csm')
ship.shapesize(0.1)
ship.color('white') # Path color. Silver and red are also good.
ship.getscreen().tracer(1, 0)
ship.setheading(90)
gravsys.sim_loop()
screen.bye() #close window automatically
def createPlanetShape():
s.tracer(0,0)
t = Turtle()
t.ht()
t.pu()
t.fd(6)
t.lt(90)
t.begin_poly()
t.circle(6, 180)
t.end_poly()
m1 = t.get_poly()
t.begin_poly()
t.circle(6,180)
t.end_poly()
m2 = t.get_poly()
planetshape = Shape("compound")
planetshape.addcomponent(m1,"orange")
planetshape.addcomponent(m2,"blue")
s.register_shape("planet", planetshape)
s.tracer(True,0)
def main():
s = Turtle()
s.reset()
s.getscreen().tracer(0, 0)
s.ht()
s.pu()
s.fd(6)
s.lt(90)
s.begin_poly()
s.circle(6, 180)
s.end_poly()
m1 = s.get_poly()
s.begin_poly()
s.circle(6, 180)
s.end_poly()
m2 = s.get_poly()
planetshape = Shape('compound')
planetshape.addcomponent(m1, 'orange')
planetshape.addcomponent(m2, 'blue')
s.getscreen().register_shape('planet', planetshape)
s.getscreen().tracer(1, 0)
gs = GravSys()
sun = Star(1000000, Vec(0, 0), Vec(0, -2.5), gs, 'circle')
sun.color('yellow')
sun.shapesize(1.8)
sun.pu()
earth = Star(12500, Vec(210, 0), Vec(0, 195), gs, 'planet')
earth.pencolor('green')
earth.shapesize(0.8)
moon = Star(1, Vec(220, 0), Vec(0, 295), gs, 'planet')
moon.pencolor('blue')
moon.shapesize(0.5)
gs.init()
gs.start()
return 'Done!'
def main():
s = Turtle()
s.reset()
s.getscreen().tracer(0,0)
s.ht()
s.pu()
s.fd(6)
s.lt(90)
s.begin_poly()
s.circle(6, 180)
s.end_poly()
m1 = s.get_poly()
s.begin_poly()
s.circle(6,180)
s.end_poly()
m2 = s.get_poly()
planetshape = Shape("compound")
planetshape.addcomponent(m1,"orange")
planetshape.addcomponent(m2,"blue")
s.getscreen().register_shape("planet", planetshape)
s.getscreen().tracer(1,0)
## setup gravitational system
gs = GravSys()
sun = Star(1000000, Vec(0,0), Vec(0,-2.5), gs, "circle")
sun.color("yellow")
sun.shapesize(1.8)
sun.pu()
earth = Star(12500, Vec(210,0), Vec(0,195), gs, "planet")
earth.pencolor("green")
earth.shapesize(0.8)
moon = Star(1, Vec(220,0), Vec(0,295), gs, "planet")
moon.pencolor("blue")
moon.shapesize(0.5)
gs.init()
gs.start()
return "Done!"
def __init__(self, fen, color, nom, taille):
"""Initialise correctement la tortue"""
super().__init__(fen)
self.deplacer((3, 3)) # enlever après
pacman = Shape('polygon', corps)
self.right(90)
self.taille = taille / 25
self.nom = nom
fen.register_shape('j' + self.nom, pacman)
self.color(color)
self.orienter('est')
self.shapesize(self.taille, self.taille)
self.shape('j' + self.nom)
def dibuja_estrella(self, lapiz):
'''
Define una figura de estrella como el lapiz que dibujará
'''
fig = Shape("compound")
lapiz.setx(0)
lapiz.sety(4)
lapiz.begin_poly()
lapiz.goto(1, 1)
lapiz.goto(3.5, 1)
lapiz.goto(1.5, -0.5)
lapiz.goto(2.5, -3)
lapiz.goto(0, 1.5)
lapiz.goto(-2.5, -3)
lapiz.goto(-1.5, -0.5)
lapiz.goto(-3.5, 1)
lapiz.goto(-1, 1)
lapiz.end_poly()
fig.addcomponent(lapiz.get_poly(), "purple", "purple")
self.screen.register_shape("estrella", fig)
lapiz.reset()
def main():
# Setup screen
screen = Screen()
screen.setup(width=1.0, height=1.0) # For fullscreen.
screen.bgcolor('black')
screen.title("Apollo 8 Free Return Simulation")
# Instantiate gravitational system
gravsys = GravSys()
# Instantiate Earth turtle
image_earth = 'earth_100x100.gif'
screen.register_shape(image_earth)
earth = Body(1000000, (0, -25), Vec(0, -2.5), gravsys, image_earth)
earth.pencolor('white')
earth.getscreen().tracer(0, 0) # So csm polys won't show while drawing.
# Instantiate moon turtle
image_moon = 'moon_27x27.gif'
screen.register_shape(image_moon)
moon = Body(32000, (344, 42), Vec(-27, 147), gravsys, image_moon)
moon.pencolor('gray')
# Build command-service-module(csm)shape
csm = Shape('compound')
cm = ((0, 30), (0, -30), (30, 0))
csm.addcomponent(cm, 'white', 'white') # Silver and red are also good.
sm = ((-60, 30), (0, 30), (0, -30), (-60, -30))
csm.addcomponent(sm, 'white', 'black')
nozzle = ((-55, 0), (-90, 20), (-90, -20))
csm.addcomponent(nozzle, 'white', 'white')
screen.register_shape('csm', csm)
# Instantiate Apollo 8 CSM turtle
ship = Body(1, (Ro_X, Ro_Y), Vec(Vo_X, Vo_Y), gravsys, 'csm')
ship.shapesize(0.2)
ship.color('white') # Path color. Silver and red are also good.
ship.getscreen().tracer(1, 0)
ship.setheading(90)
gravsys.sim_loop()
def main():
## create compound yellow/blue turtleshape for planets
global s
s = Screen()
s.setup(1120, 840)
s.reset()
s.tracer(0, 0)
t = Turtle()
t.ht()
t.pu()
t.fd(6)
t.lt(90)
t.begin_poly()
t.circle(6, 180)
t.end_poly()
m1 = t.get_poly()
t.begin_poly()
t.circle(6, 180)
t.end_poly()
m2 = t.get_poly()
planetshape = Shape("compound")
planetshape.addcomponent(m1, "orange")
planetshape.addcomponent(m2, "blue")
s.register_shape("planet", planetshape)
s.update()
## setup gravitational system
gs = GravSys()
sun = Star(1000000, Vec(-250, 0), Vec(0, -0.35), gs, "circle")
sun.color("yellow")
sun.pensize(1.8)
sun.pu()
earth = Star(5000, Vec(450, 0), Vec(0, 70), gs, "planet")
earth.pencolor("green")
earth.shapesize(0.8)
rm = 12.0583
vm = (8.0 * 5000 / rm)**.5
moon = Star(1, Vec(450 + rm, 0), Vec(0, 70 + vm), gs, "planet")
moon.pencolor("blue")
moon.shapesize(0.5)
gs.init()
gs.start()
s.tracer(True)
return "Done!"
def __drawEyeBrows():
__startFunction()
eyebrows = Shape("compound")
#draw Left eye Brow
turtle.begin_poly()
turtle.penup()
turtle.goto(-80, 0)
turtle.left(5)
turtle.pendown()
turtle.fd(15)
turtle.left(90)
turtle.fd(5)
turtle.left(90)
turtle.fd(30)
turtle.left(90)
turtle.fd(5)
turtle.left(90)
turtle.fd(15)
turtle.end_poly()
leftbro = turtle.get_poly()
eyebrows.addcomponent(leftbro, "black", "cyan")
#draw Right Eye Borw
turtle.penup()
turtle.right(5)
turtle.goto(80, 0)
turtle.begin_poly()
turtle.left(180)
turtle.right(5)
turtle.fd(15)
turtle.right(90)
turtle.fd(5)
turtle.right(90)
turtle.fd(30)
turtle.right(90)
turtle.fd(5)
turtle.right(90)
turtle.fd(15)
turtle.end_poly()
rightbro = turtle.get_poly()
eyebrows.addcomponent(rightbro, "black", "cyan")
screen.addshape("EyeBrows", eyebrows)
__drawEndFunction()
def createPlanetShape():
s.tracer(0,0)
t = Turtle()
t.ht()
t.pu()
t.fd(6)
t.lt(90)
t.begin_poly()
t.circle(6, 180)
t.end_poly()
m1 = t.get_poly()
t.begin_poly()
t.circle(6,180)
t.end_poly()
m2 = t.get_poly()
planetshape = Shape("compound")
planetshape.addcomponent(m1,"orange")
planetshape.addcomponent(m2,"blue")
s.register_shape("planet", planetshape)
s.tracer(True,0)
def main():
s = Turtle()
s.reset()
s.getscreen().tracer(0,0)
s.ht()
s.pu()
s.fd(6)
s.lt(90)
s.begin_poly()
s.circle(6, 180)
s.end_poly()
m1 = s.get_poly()
s.begin_poly()
s.circle(6,180)
s.end_poly()
m2 = s.get_poly()
planetshape = Shape("compound")
planetshape.addcomponent(m1,"orange")
planetshape.addcomponent(m2,"blue")
s.getscreen().register_shape("planet", planetshape)
s.getscreen().tracer(1,0)
## setup gravitational system
gs = GravSys()
sun = Star(1000000, Vec(0,0), Vec(0,-2.5), gs, "circle")
sun.color("yellow")
sun.shapesize(1.8)
sun.pu()
earth = Star(12500, Vec(210,0), Vec(0,195), gs, "planet")
earth.pencolor("green")
earth.shapesize(0.8)
moon = Star(1, Vec(220,0), Vec(0,295), gs, "planet")
moon.pencolor("blue")
moon.shapesize(0.5)
gs.init()
gs.start()
return "Done!"
def __init__(self, fen, color, nom, taille):
"""Initialise l'instance de monstre"""
super().__init__(fen)
self.right(90)
self.nom = nom
self.taille = taille / 25 # taille du sprite
fantomee = Shape('compound')
fantomee.addcomponent(fantomeCorps, color)
fantomee.addcomponent(fantomeOeilG, 'white')
fantomee.addcomponent(fantomeOeilD, 'white')
fantomee.addcomponent
(tuple((x + 1, y) for x, y in fantomePupilleG), 'blue')
fantomee.addcomponent
(tuple((x + 1, y) for x, y in fantomePupilleD), 'blue')
fantomeo = Shape('compound')
fantomeo.addcomponent(fantomeCorps, color)
fantomeo.addcomponent(fantomeOeilG, 'white')
fantomeo.addcomponent(fantomeOeilD, 'white')
fantomeo.addcomponent
(tuple((x - 1, y) for x, y in fantomePupilleG), 'blue')
fantomeo.addcomponent
(tuple((x - 1, y) for x, y in fantomePupilleD), 'blue')
fantomen = Shape('compound')
fantomen.addcomponent(fantomeCorps, color)
fantomen.addcomponent(fantomeOeilG, 'white')
fantomen.addcomponent(fantomeOeilD, 'white')
fantomen.addcomponent
(tuple((x, y + 2) for x, y in fantomePupilleG), 'blue')
fantomen.addcomponent
(tuple((x, y + 2) for x, y in fantomePupilleD), 'blue')
fantomes = Shape('compound')
fantomes.addcomponent(fantomeCorps, color)
fantomes.addcomponent(fantomeOeilG, 'white')
fantomes.addcomponent(fantomeOeilD, 'white')
fantomes.addcomponent
(tuple((x, y - 1) for x, y in fantomePupilleG), 'blue')
fantomes.addcomponent
(tuple((x, y - 1) for x, y in fantomePupilleD), 'blue')
fen.register_shape(self.nom + 'est', fantomee)
fen.register_shape(self.nom + 'ouest', fantomeo)
fen.register_shape(self.nom + 'nord', fantomen)
fen.register_shape(self.nom + 'sud', fantomes)
self.orienter('est')
self.shapesize(self.taille, self.taille)
score_pen = turtle.Turtle()
score_pen.speed(0)
score_pen.color('white')
score_pen.penup()
score_pen.setposition(-290, 280)
scorestring = "Score: %s" % score
score_pen.write(scorestring,
False,
align='left',
font=("Times New Roman", 14, 'normal'))
score_pen.hideturtle()
player = turtle.Turtle()
smallerPlayer = PhotoImage(file='boris.gif').subsample(3, 3)
window.addshape('larger', Shape('image', smallerPlayer))
player.shape('larger')
player.penup()
player.speed(0)
player.setposition(0, -250)
player.setheading(90)
playerspeed = 15
enemies = 10
enemies_list = []
for i in range(enemies):
enemies_list.append(turtle.Turtle())
for enemy in enemies_list:
area.penup()
area.goto(play_right, play_top)
area.pendown()
area.goto(play_left, play_top)
area.goto(play_left, play_bottom)
area.goto(play_right, play_bottom)
area.goto(play_right, play_top)
# PADDLES
L = Turtle()
R = Turtle()
L.penup()
R.penup()
# Paddles shape
paddle_w_half = 10 / 2 # 10 units wide
paddle_h_half = 40 / 2 # 40 units high
paddle_shape = Shape("compound")
paddle_points = ((-paddle_h_half, -paddle_w_half), (-paddle_h_half,
paddle_w_half),
(paddle_h_half, paddle_w_half), (paddle_h_half,
-paddle_w_half))
paddle_shape.addcomponent(paddle_points, "black")
screen.register_shape("paddle", paddle_shape)
L.shape("paddle")
R.shape("paddle")
# Move paddles into position
L.setx(play_left + 10)
R.setx(play_right - 10)
paddle_L_move_direction = 0 # L paddle movement direction in next frame
paddle_R_move_direction = 0 # R paddle movement direction in next frame
paddle_move_vert = 4 # Vertical movement distance per frame
#initialisering, setter "vindu" konfigurasjon.
eksempel = turtle.Screen()
#eksempel.screensize(500, 500)
eksempel.setup(1000, 1000) #alternativ konfigurasjon av stage (arbeidsflate)
eksempel.title("Eks. 364, sett inn bilde.")
#eksempel.bgpic("./turtlelpg.png")
#initialisering, definerer hvor turtle starter, farge, hastighet mv.
figur = Turtle("turtle")
figur.hideturtle()
figur.penup()
figur.setposition(-200, -200) # Starter i "Origo", for Turtle er det midt i skjermen.
#Same size as imported image:
#eksempel.addshape(name="./bilder/Solbergfoss_photo3364_200x150.gif",shape=None)
#figur.shape("spaceship.gif")
#Bigger image,resize:
larger = PhotoImage(file="./turtlelpg.png").zoom(3, 3)
eksempel.addshape("larger", Shape("image", larger))
figur.shape("larger")
#Lesser image, resize:
#lesser = PhotoImage(file="./turtlelpg.png").subsample(5, 5)
#eksempel.addshape("lesser", Shape("image", lesser))
#figur.shape("lesser")
figur.showturtle()
eksempel.mainloop()
# Create variable score
score = 0
# Create player turtle
player = turtle.Turtle()
#player.color('Teal')
#player.shape('turtle')
#player.penup()
#player.speed(0)
beeimage = "bee.gif"
#wn.addshape(beeimage)
#player.shape(beeimage)
smallerBee = PhotoImage(file="bee.gif").subsample(10, 10)
wn.addshape("smaller", Shape("image", smallerBee))
player = Turtle("smaller")
player.penup()
player.speed(0)
# Create opponent turtle
comp = turtle.Turtle()
comp.color('black')
comp.shape('turtle')
comp.penup()
comp.setposition(random.randint(-290, 290), random.randint(-290, 290))
# Create food
maxFoods = 20
foods = []
for count in range(maxFoods):
def __drawEyes():
__startFunction()
#draw the eye when opened with mid cornea
openeyes1 = Shape("compound")
turtle.begin_poly()
turtle.goto(-80, 0)
turtle.pendown()
turtle.circle(15)
turtle.penup()
turtle.end_poly()
lefteye1 = turtle.get_poly()
openeyes1.addcomponent(lefteye1, "black", "cyan")
turtle.begin_poly()
turtle.goto(80, 0)
turtle.pendown()
turtle.circle(15)
turtle.penup()
turtle.end_poly()
righteye1 = turtle.get_poly()
openeyes1.addcomponent(righteye1, "black", "cyan")
#place the cornea mid the openedeyes
turtle.begin_poly()
turtle.penup()
turtle.goto(-80, 0)
turtle.pendown()
turtle.circle(8)
turtle.penup()
turtle.end_poly()
leftcornea1 = turtle.get_poly()
openeyes1.addcomponent(leftcornea1, "cyan", "cyan")
turtle.begin_poly()
turtle.penup()
turtle.goto(80, 0)
turtle.pendown()
turtle.circle(8)
turtle.penup()
turtle.end_poly()
rightcornea1 = turtle.get_poly()
openeyes1.addcomponent(rightcornea1, "cyan", "cyan")
screen.addshape("OpenedEyesM", openeyes1)
# draw the eye when opened with left cornea
openeyes2 = Shape("compound")
turtle.begin_poly()
turtle.goto(-80, 0)
turtle.pendown()
turtle.circle(15)
turtle.penup()
turtle.end_poly()
lefteye2 = turtle.get_poly()
openeyes2.addcomponent(lefteye2, "black", "cyan")
turtle.begin_poly()
turtle.goto(80, 0)
turtle.pendown()
turtle.circle(15)
turtle.penup()
turtle.end_poly()
righteye2 = turtle.get_poly()
openeyes2.addcomponent(righteye2, "black", "cyan")
# place the cornea left the openedeyes
turtle.begin_poly()
turtle.penup()
turtle.goto(-83, 0)
turtle.pendown()
turtle.circle(8)
turtle.penup()
turtle.end_poly()
leftcornea2 = turtle.get_poly()
openeyes2.addcomponent(leftcornea2, "cyan", "cyan")
turtle.begin_poly()
turtle.penup()
turtle.goto(77, 0)
turtle.pendown()
turtle.circle(8)
turtle.penup()
turtle.end_poly()
rightcornea2 = turtle.get_poly()
openeyes2.addcomponent(rightcornea2, "cyan", "cyan")
screen.addshape("OpenedEyesL", openeyes2)
# draw the eye when opened with Right cornea
openeyes3 = Shape("compound")
turtle.begin_poly()
turtle.goto(-80, 0)
turtle.pendown()
turtle.circle(15)
turtle.penup()
turtle.end_poly()
lefteye3 = turtle.get_poly()
openeyes3.addcomponent(lefteye3, "black", "cyan")
turtle.begin_poly()
turtle.goto(80, 0)
turtle.pendown()
turtle.circle(15)
turtle.penup()
turtle.end_poly()
righteye3 = turtle.get_poly()
openeyes3.addcomponent(righteye3, "black", "cyan")
# place the cornea Right the openedeyes
turtle.begin_poly()
turtle.penup()
turtle.goto(-77, 0)
turtle.pendown()
turtle.circle(8)
turtle.penup()
turtle.end_poly()
leftcornea3 = turtle.get_poly()
openeyes3.addcomponent(leftcornea3, "cyan", "cyan")
turtle.begin_poly()
turtle.penup()
turtle.goto(83, 0)
turtle.pendown()
turtle.circle(8)
turtle.penup()
turtle.end_poly()
rightcornea3 = turtle.get_poly()
openeyes3.addcomponent(rightcornea3, "cyan", "cyan")
screen.addshape("OpenedEyesR", openeyes3)
#draw the eye when closed
closeeyes = Shape("compound")
turtle.begin_poly()
turtle.goto(-80, 0)
turtle.pendown()
turtle.fd(28)
turtle.left(90)
turtle.fd(2)
turtle.left(90)
turtle.fd(28)
turtle.left(90)
turtle.fd(2)
turtle.end_poly()
leftcloseeye = turtle.get_poly()
closeeyes.addcomponent(leftcloseeye, "black", "cyan")
turtle.penup()
turtle.begin_poly()
turtle.goto(80, 0)
turtle.pendown()
turtle.left(90)
turtle.fd(28)
turtle.left(90)
turtle.fd(2)
turtle.left(90)
turtle.fd(28)
turtle.left(90)
turtle.fd(2)
turtle.end_poly()
rightcloseeye = turtle.get_poly()
closeeyes.addcomponent(rightcloseeye, "black", "cyan")
screen.addshape("ClosedEyes", closeeyes)
__drawEndFunction()
ball = Turtle()
ball.penup()
ball.shape("circle")
ball.shapesize(0.65, 0.65)
ball_radius = 10 * 0.5
#plate
L = Turtle()
R = Turtle()
L.penup()
R.penup()
#shape of plate
paddle_w_half = 10 / 2
paddle_h_half = 40 / 2
paddle_shape = Shape("compound")
paddle_points = ((-paddle_h_half, -paddle_w_half), (-paddle_h_half,
paddle_w_half),
(paddle_h_half, paddle_w_half), (paddle_h_half,
-paddle_w_half))
paddle_shape.addcomponent(paddle_points, "Blue")
screen.register_shape("paddle", paddle_shape)
L.shape("paddle")
R.shape("paddle")
L.setx(left + 10)
R.setx(right - 10)
#score
score = Turtle()
score.penup()
