def main():
"""
This program simulates a bouncing ball at (START_X, START_Y)
that has VX as x velocity and 0 as y velocity. Each bounce reduces
y velocity to REDUCE of itself.
"""
global times,switch,VY
ball=GOval(SIZE,SIZE,x=START_X,y=START_Y)
ball.filled= True
ball.fill_color='black'
window.add(ball)
switch = False
onmouseclicked(turn_on)
while True:
pause(DELAY)
if switch==True:
VY+=GRAVITY
ball.move(VX,VY)
pause(DELAY)
if ball.y>window.height:
VY=-REDUCE*VY
if ball.x>window.width:
ball.x=START_X
ball.y=START_Y
times +=1
if times>=3:
break
else:
pass
def main():
"""
This program simulates a bouncing ball at (START_X, START_Y)
that has VX as x velocity and 0 as y velocity. Each bounce reduces
y velocity to REDUCE of itself.
"""
onmouseclicked(bouncing)
def __init__(self,
window_width=WINDOW_WIDTH,
window_height=WINDOW_HEIGHT,
zone_width=ZONE_WIDTH,
zone_height=ZONE_HEIGHT,
ball_radius=BALL_RADIUS):
# Create window
self.window = GWindow(window_width, window_height, title='Zone Game')
# Create zone
self.zone = GRect(zone_width,
zone_height,
x=(window_width - zone_width) / 2,
y=(window_height - zone_height) / 2)
self.zone.color = 'blue'
self.window.add(self.zone)
# Create ball and initialize velocity/position
self.ball = GOval(2 * ball_radius, 2 * ball_radius)
self.ball.filled = True
self.ball.fill_color = 'salmon'
self.dx = 0
self.dy = 0
self.reset_ball()
# Initialize mouse listeners
onmouseclicked(self.handle_click)
def main():
"""
"""
ball.filled = True
ball.fill_color = 'black'
window.add(ball, START_X - SIZE / 2, START_Y - SIZE / 2)
onmouseclicked(start)
def start():
graphics.reset_ball_location()
graphics.window.add(life_label,
graphics.window.width - life_label.width - 30,
life_label.height + 20)
graphics.window.add(score_label, 20, score_label.height + 20)
onmouseclicked(serve)
def form_line(e):
# Form a line from the dot to the coordinate clicked.
path = GLine(dot.x+SIZE/2, dot.y+SIZE/2, e.x, e.y)
window.add(path)
# The dot will be removed when the line is formed.
window.remove(dot)
onmouseclicked(draw_dot)
def create_beeper(e):
# create 4 beepers
size = 50
for i in (1, 3, 7, 9):
beeper = GOval(size, size, x=i * 50 - size / 2, y=400 - size / 2)
beeper.filled = True
beeper.fill_color = 'blue'
window.add(beeper)
label1 = GLabel('001', x=50 - size / 2 + 9, y=400 - size / 2 + 37)
label2 = GLabel('101', x=150 - size / 2 + 9, y=400 - size / 2 + 37)
label3 = GLabel('201', x=350 - size / 2 + 9, y=400 - size / 2 + 37)
label4 = GLabel('202', x=450 - size / 2 + 9, y=400 - size / 2 + 37)
label1.font = '-15'
label2.font = '-15'
label3.font = '-15'
label4.font = '-15'
label1.color = 'white'
label2.color = 'white'
label3.color = 'white'
label4.color = 'white'
window.add(label1)
window.add(label2)
window.add(label3)
window.add(label4)
onmouseclicked(build_karel)
def __init__(self, window_width=WINDOW_WIDTH, window_height=WINDOW_HEIGHT,
zone_width=ZONE_WIDTH, zone_height=ZONE_HEIGHT, ball_radius=BALL_RADIUS):
# Create window
self.w = GWindow(width=window_width, height=window_height, title='Zone_Game')
# Create zone
self.zone = GRect(zone_width, zone_height, x=(self.w.width-zone_width)/2, y=(self.w.height-zone_height)/2)
self.zone.color = 'blue'
self.w.add(self.zone)
# Create ball and initialize velocity/position
self.ball = GOval(ball_radius*2, ball_radius*2)
self.ball.filled = True
self.dx = 0
self.dy = 0
self.lives = 3
self.reset_ball()
# Lives Word
self.lives_word = GLabel('Lives: ' + str(self.lives), x=WINDOW_WIDTH * 0.02, y=WINDOW_HEIGHT * 0.1)
self.lives_word.font = 'Courier-25-bold'
self.w.add(self.lives_word)
# Initialize mouse listeners
onmouseclicked(self.handle_click)
def draw_dot(event):
# Draw the first dot at the point clicked.
global dot
dot.move(event.x-dot.x-dot.width/2, event.y-dot.y-dot.height/2)
window.add(dot)
# The next click will activate the function: form_line.
onmouseclicked(form_line)
def play_again(n):
"""
After finishing the game, if player click the result label, which show Game over or You win, the login page will
show up again and player can start new run of game.
:param n: the mouse positional information after game finished.
"""
global log_in_page, NUM_LIVES
if graphics.window.get_object_at(n.x, n.y) is graphics.result_label:
NUM_LIVES = 3
log_in_page = Log_in_page()
graphics.window.remove(graphics.result_label)
graphics.window.close()
log_in_page.add_play_button()
log_in_page.add_fb_button()
log_in_page.solid_bar = GRect(log_in_page.load_bar.width,
log_in_page.load_bar.height)
log_in_page.loading()
log_in_page.window.add(log_in_page.solid_bar, log_in_page.load_bar.x,
log_in_page.load_bar.y)
log_in_page.load_label.text = '100%'
log_in_page.window.add(
log_in_page.load_label, log_in_page.load_bar.x +
log_in_page.load_bar.width - log_in_page.load_label.width,
log_in_page.load_bar.y + log_in_page.load_bar.height +
log_in_page.load_label.height + 5)
onmouseclicked(animation_loop)
def __init__(self, ball_radius=BALL_RADIUS, paddle_width=PADDLE_WIDTH,
paddle_height=PADDLE_HEIGHT, paddle_offset=PADDLE_OFFSET,
brick_rows=BRICK_ROWS, brick_cols=BRICK_COLS,
brick_width=BRICK_WIDTH, brick_height=BRICK_HEIGHT,
brick_offset=BRICK_OFFSET, brick_spacing=BRICK_SPACING,
title='Breakout'):
# Create a graphical window, with some extra space.
window_width = brick_cols * (brick_width + brick_spacing) - brick_spacing
window_height = brick_offset + 3 * (brick_rows * (brick_height + brick_spacing) - brick_spacing)
self.window = GWindow(width=window_width, height=window_height, title=title)
# Create a paddle.
self.paddle = GRect(paddle_width, paddle_height)
self.window.add(self.paddle, (self.window.width - paddle_width) / 2,
self.window.height - paddle_offset - paddle_height)
self.paddle.filled = True
self.paddle.fill_color = 'blue'
self.paddle.color = 'blue'
# Center a filled ball in the graphical window.
self.ball = GOval(ball_radius * 2, ball_radius * 2)
self.ball.filled = True
self.reset_ball()
# Default initial velocity for the ball.
self.__dx = 0
self.__dy = 0
self.switch = False
# Initialize our mouse listeners.
onmouseclicked(self.game_start)
onmousemoved(self.move_paddle)
# Draw bricks.
by = 0
for i in range(brick_rows):
bx = 0
for j in range(brick_cols):
self.brick = GRect(brick_width, brick_height)
self.brick.filled = True
if i < brick_cols / 5:
self.brick.fill_color = 'red'
elif brick_cols / 5 <= i < brick_cols / 5 * 2:
self.brick.fill_color = 'orange'
elif brick_cols / 5 * 2 <= i < brick_cols / 5 * 3:
self.brick.fill_color = 'yellow'
elif brick_cols / 5 * 3 <= i < brick_cols / 5 * 4:
self.brick.fill_color = 'green'
else:
self.brick.fill_color = 'blue'
self.window.add(self.brick, bx, brick_offset+by)
bx += brick_width + brick_spacing
by += brick_height + brick_spacing
# scoreboard
self.earned_score = 0
self.total_score = brick_cols * brick_rows
self.scoreboard = GLabel(f'score: {self.earned_score}/{self.total_score}', x=10, y=30)
self.scoreboard.font = 'courier-20'
self.window.add(self.scoreboard)
def main():
# Add animation loop here!
# make paddle and bricks
graphics.make_a_paddle()
graphics.brick()
onmouseclicked(function)
def __init__(self, ball_radius=BALL_RADIUS, paddle_width=PADDLE_WIDTH,
paddle_height=PADDLE_HEIGHT, paddle_offset=PADDLE_OFFSET,
brick_rows=BRICK_ROWS, brick_cols=BRICK_COLS,
brick_width=BRICK_WIDTH, brick_height=BRICK_HEIGHT,
brick_offset=BRICK_OFFSET, brick_spacing=BRICK_SPACING,
title='Breakout'):
# Create a graphical window, with some extra space
window_width = brick_cols * (brick_width + brick_spacing) - brick_spacing
window_height = brick_offset + 3 * (brick_rows * (brick_height + brick_spacing) - brick_spacing)
self.window = GWindow(width=window_width, height=window_height, title=title)
self.paddle_offset = PADDLE_OFFSET
self.ball_r = BALL_RADIUS
# Create a paddle
self.paddle = GRect(paddle_width, paddle_height, x=(window_width-paddle_width)/2, y=window_height-paddle_offset-paddle_height)
self.paddle.filled = True
self.paddle.fill_color = 'blue'
self.window.add(self.paddle)
# Center a filled ball in the graphical window
self.first_ball = GOval(ball_radius*2, ball_radius*2, x=(window_width-ball_radius)/2, y=(window_height-ball_radius)/2)
self.first_ball.filled = True
self.first_ball.fill_color = 'black'
self.window.add(self.first_ball)
self.initial_x = (window_width-ball_radius)/2
self.initial_y = (window_height-ball_radius)/2
# Default initial velocity for the ball
self.__dx = random.randint(1, MAX_X_SPEED)
self.__dy = INITIAL_Y_SPEED
if random.random() > 0.5:
self.__dx = -self.__dx
# Initialize our mouse listeners
self.activate = False
self.crash_is_paddle = False
self.crash_is_brick = False
self.point_count = 0
onmousemoved(self.paddle_move)
onmouseclicked(self.ball_start)
# Draw bricks
for y_pos in range(0, (BRICK_HEIGHT+BRICK_SPACING)*BRICK_ROWS-BRICK_SPACING, BRICK_HEIGHT+BRICK_SPACING):
for x_pos in range(0, (BRICK_WIDTH+BRICK_SPACING)*BRICK_COLS-BRICK_SPACING, BRICK_WIDTH+BRICK_SPACING):
self.brick = GRect(BRICK_WIDTH, BRICK_HEIGHT)
self.brick.filled = True
if y_pos < BRICK_HEIGHT+BRICK_SPACING * 2 + 1:
self.brick.fill_color = 'red'
elif y_pos < (BRICK_HEIGHT+BRICK_SPACING) * 4:
self.brick.fill_color = 'orange'
elif y_pos < (BRICK_HEIGHT+BRICK_SPACING) * 6:
self.brick.fill_color = 'yellow'
elif y_pos < (BRICK_HEIGHT+BRICK_SPACING) * 8:
self.brick.fill_color = 'green'
elif y_pos < (BRICK_HEIGHT+BRICK_SPACING) * 10:
self.brick.fill_color = 'blue'
else:
self.brick.fill_color = 'black'
self.window.add(self.brick, x=x_pos, y=y_pos)
def __init__(self,
ball_radius=BALL_RADIUS,
paddle_width=PADDLE_WIDTH,
paddle_height=PADDLE_HEIGHT,
paddle_offset=PADDLE_OFFSET,
brick_rows=BRICK_ROWS,
brick_cols=BRICK_COLS,
brick_width=BRICK_WIDTH,
brick_height=BRICK_HEIGHT,
brick_offset=BRICK_OFFSET,
brick_spacing=BRICK_SPACING,
title='Breakout'):
# Create a graphical window, with some extra space.
self.window_width = brick_cols * (brick_width +
brick_spacing) - brick_spacing
self.window_height = brick_offset + 3 * (
brick_rows * (brick_height + brick_spacing) - brick_spacing)
self.window = GWindow(width=self.window_width,
height=self.window_height,
title=title)
# Create a paddle.
self.pw = paddle_width
self.ph = paddle_height
self.paddle = GRect(self.pw,
self.ph,
x=(self.window_width - self.pw) / 2,
y=self.window_height - paddle_offset)
self.paddle.filled = True
self.window.add(self.paddle)
# Center a filled ball in the graphical window.
self.bra = ball_radius * 2
self.ball = GOval(self.bra, self.bra)
self.ball.filled = True
self.window.add(self.ball, (self.window_width - self.bra) / 2,
(self.window_height - self.bra) / 2)
# Default initial velocity for the ball.
self.__dx = 0
self.__dy = 0
# Initialize our mouse listeners.
onmousemoved(self.paddle_move)
onmouseclicked(self.ball_move)
# Draw bricks.
self.build_bricks()
self.score = 0
self.score_text = GLabel('Score: ' + str(self.score))
self.score_text.font = '-15-bold'
self.window.add(self.score_text, 0, self.window_height)
self.lives_text = GLabel('Lives: ' + str(3))
self.lives_text.font = '-15-bold'
self.window.add(self.lives_text, self.window_width - 80,
self.window_height)
def __init__(self,
ball_radius=BALL_RADIUS,
paddle_width=PADDLE_WIDTH,
paddle_height=PADDLE_HEIGHT,
paddle_offset=PADDLE_OFFSET,
brick_rows=BRICK_ROWS,
brick_cols=BRICK_COLS,
brick_width=BRICK_WIDTH,
brick_height=BRICK_HEIGHT,
brick_offset=BRICK_OFFSET,
brick_spacing=BRICK_SPACING,
title='Breakout'):
# Create a graphical window, with some extra space
window_width = brick_cols * (brick_width +
brick_spacing) - brick_spacing
window_height = brick_offset + 3 * (brick_rows *
(brick_height + brick_spacing) -
brick_spacing)
self.window = GWindow(width=window_width,
height=window_height,
title='Breakout')
# Element score label
self.score = 0
self.score_label = GLabel('Score: ' + str(self.score))
# Element for game winning
self.win_show = GLabel('Create by Mike Lin', x=100, y=100)
self.win_show2 = GLabel('March 20 stanCode SC101', x=135, y=115)
# Create a paddle
self.paddle = GRect(paddle_width,
paddle_height,
x=(window_width - paddle_width) / 2,
y=window_height - paddle_offset)
self.window.add(self.paddle)
self.paddle.filled = True
# Center a filled ball in the graphical window
self.ball = GOval(2 * ball_radius,
2 * ball_radius,
x=window_width / 2 - ball_radius,
y=window_height / 2 - ball_radius)
self.ball_x = window_width / 2 - ball_radius
self.ball_y = window_height / 2 - ball_radius
# Default initial velocity for the ball
self.__dx = 0
self.__dy = 0
# Other variables
self.total_bricks = 0
# Initialize our mouse listeners
onmousemoved(
self.paddle_move) # using own method must add 'self.' in the front
onmouseclicked(self.clicked)
self.draw_bricks_and_ball()
def main():
"""
This program is the game that the player controls a paddle to rebound the ball.
And the ball will break bricks that it hits.
:return:
"""
life_count.text = 'Live: ' + str(life_left)
onmouseclicked(click_start)
def main():
"""
This program will set attribute to the ball and add ball instance on window,
while listening to onmouseclicked and onmousemoved events.
"""
ball_setting()
onmouseclicked(click_event)
onmousemoved(move_event)
def main():
"""
This program will prepare canvas for drawing circle and line,
while listening to onmouseclicked and onmousemove events.
"""
prepare_canvas()
onmouseclicked(click_event)
onmousemoved(move_event)
def main():
onmouseclicked(hit)
while True:
mole=GImage('mole.jpeg')
mole_x=random.randint(0,window.width-mole.width)
mole_y=random.randint(0,window.height-mole.height)
window.add(mole,mole_x,mole_y)
pause(DELAY)
def main():
window.add(rect)
rect.filled = True
rect.color = COLOR
rect.fill_color = COLOR
onmousemoved(reset_position)
onmouseclicked(my_punch)
onmousedragged(draw)
def draw_line(event):
"""
When the user clicks the mouse again, this function will remove the former dot and draw a line.
"""
line = GLine(dot.x + SIZE / 2, dot.y + SIZE / 2, event.x, event.y)
window.add(line)
window.remove(dot)
onmouseclicked(function)
def function(event):
"""
When the user clicks the mouse, this function will make a dot at that point.
"""
global dot
dot = GOval(SIZE, SIZE, x=event.x - SIZE / 2, y=event.y - SIZE / 2)
window.add(dot)
onmouseclicked(draw_line)
def main():
opening()
life_ui.font = "-15"
score_ui.font = "-15"
w.add(life_ui, x=w.width - life_ui.width, y=w.height - life_ui.height)
w.add(score_ui, x=0, y=w.height - score_ui.height)
onmousemoved(mouse_move)
onmouseclicked(main_game)
def main():
"""
This program creates lines on an instance of GWindow class.
There is a circle indicating the user’s first click. A line appears
at the condition where the circle disappears as the user clicks
on the canvas for the second time.
"""
onmouseclicked(draw_line)
def __init__(self,
ball_radius=BALL_RADIUS,
paddle_width=PADDLE_WIDTH,
paddle_height=PADDLE_HEIGHT,
paddle_offset=PADDLE_OFFSET,
brick_rows=BRICK_ROWS,
brick_cols=BRICK_COLS,
brick_width=BRICK_WIDTH,
brick_height=BRICK_HEIGHT,
brick_offset=BRICK_OFFSET,
brick_spacing=BRICK_SPACING,
title='Breakout'):
# Create a graphical window, with some extra space.
window_width = brick_cols * (brick_width +
brick_spacing) - brick_spacing
window_height = brick_offset + 3 * (brick_rows *
(brick_height + brick_spacing) -
brick_spacing)
self.window = GWindow(width=window_width,
height=window_height,
title=title)
# Create a paddle.
self.pof = paddle_offset
self.paddle = GRect(paddle_width, paddle_height)
self.paddle.filled = True
self.window.add(self.paddle, (window_width - self.paddle.width) / 2,
window_height - self.pof)
# Center a filled ball in the graphical window.
self.ball = GOval(2 * ball_radius, 2 * ball_radius)
self.ball.filled = True
self.window.add(self.ball, self.window.width / 2 - self.ball.width / 2,
self.window.height / 2)
self.initial_x = self.window.width / 2 - self.ball.width / 2
self.initial_y = self.window.height / 2
# Default initial velocity for the ball.
self.__dx = 0
self.__dy = 0
self.set_speed()
self.get_dx()
self.get_dy()
# Initialize our mouse listeners.
self.click = False
onmousemoved(self.paddle_follow)
onmouseclicked(self.start)
# Draw bricks.
self.br = brick_rows
self.bc = brick_cols
self.sp = brick_spacing
self.of = brick_offset
self.set_brick()
# self.check()
# self.rest_ball()
self.total = self.br * self.bc
def __init__(self,
ball_radius=BALL_RADIUS,
paddle_width=PADDLE_WIDTH,
paddle_height=PADDLE_HEIGHT,
paddle_offset=PADDLE_OFFSET,
brick_rows=BRICK_ROWS,
brick_cols=BRICK_COLS,
brick_width=BRICK_WIDTH,
brick_height=BRICK_HEIGHT,
brick_offset=BRICK_OFFSET,
brick_spacing=BRICK_SPACING,
title='Breakout'):
num_bricks = 100
# Create a graphical window, with some extra space.
window_width = brick_cols * (brick_width +
brick_spacing) - brick_spacing
window_height = brick_offset + 3 * (brick_rows *
(brick_height + brick_spacing) -
brick_spacing)
self.window = GWindow(width=window_width,
height=window_height,
title=title)
self.paddle = GRect(paddle_width, paddle_height, x=(window_width - paddle_width)/2, y = window_height - \
paddle_offset)
# initializing the paddle
self.paddle.filled = True
self.paddle.fill_color = 'black'
self.window.add(self.paddle)
# initializing the ball
self.ball = GOval(width=ball_radius * 2,
height=ball_radius * 2,
x=window_width / 2 - BALL_RADIUS,
y=window_height / 2 - BALL_RADIUS)
self.ball.filled = True
self.ball.fill_color = 'black'
self.window.add(self.ball)
# initial velocity
self.vx = 0
self.vy = INITIAL_Y_SPEED
# draw bricks
self.draw_bricks()
# number of lives left
self.num_lives = 3
# running? big question mark
self.running = False
# brick count
self.brick_count = 100
# mouse listeners
onmouseclicked(self.start)
onmousemoved(self.move_paddle)
def __init__(self, ball_radius=BALL_RADIUS, paddle_width=PADDLE_WIDTH,
paddle_height=PADDLE_HEIGHT, paddle_offset=PADDLE_OFFSET,
brick_rows=BRICK_ROWS, brick_cols=BRICK_COLS,
brick_width=BRICK_WIDTH, brick_height=BRICK_HEIGHT,
brick_offset=BRICK_OFFSET, brick_spacing=BRICK_SPACING,
title='Breakout'):
# Create a graphical window, with some extra space
window_width = brick_cols * (brick_width + brick_spacing) - brick_spacing
window_height = brick_offset + 3 * (brick_rows * (brick_height + brick_spacing) - brick_spacing)
self.window = GWindow(width=window_width, height=window_height, title='Breakout')
# Create a paddle
self.paddle = GRect(paddle_width, paddle_height, x=(window_width-paddle_width)/2,
y=window_height-paddle_offset)
self.window.add(self.paddle)
self.paddle.filled = True
# Center a filled ball in the graphical window
self.ball = GOval(2*ball_radius, 2*ball_radius, x=window_width/2 - ball_radius,
y=window_height/2 - ball_radius)
self.window.add(self.ball)
self.ball.filled = True
self.ball_x = window_width/2 - ball_radius
self.ball_y = window_height/2 - ball_radius
# Default initial velocity for the ball
self.__dx = 0
self.__dy = 0
# Other variables
self.total_bricks = 0
self.__start = False
# Initialize our mouse listeners
onmousemoved(self.paddle_move) # using own method must add 'self.' in the front
onmouseclicked(self.clicked)
# Draw bricks
color_num = BRICK_COLS/5
for i in range(BRICK_ROWS):
for j in range(BRICK_COLS):
if j // color_num == 0:
color = 'red'
elif j // color_num == 1:
color = 'orange'
elif j // color_num == 2:
color = 'yellow'
elif j // color_num == 3:
color = 'green'
else:
color = 'blue'
bricks = GRect(BRICK_WIDTH, BRICK_HEIGHT)
self.window.add(bricks, x=0+i*(BRICK_WIDTH+BRICK_SPACING),
y=BRICK_OFFSET+j*(BRICK_HEIGHT+BRICK_SPACING))
bricks.filled = True
bricks.fill_color = color
self.total_bricks += 1
def build_karel(e):
# Build up the robot, Karel.
karel_head()
karel_eye()
karel_neck()
karel_body()
karel_limb()
karel_label()
onmouseclicked(move)
def start(self, e):
"""
Start the game
:param e: event
:return: None
"""
onmousemoved(self.paddle_move)
onmouseclicked(self.click)
self.window.remove(self.icon)
def main():
onmouseclicked(start_the_game)
label_1 = add_life()
graphics.window.add(label_1, x=graphics.window.width - label_life.width, \
y=graphics.window.height - label_life.height)
label_2 = add_score()
graphics.window.add(label_2,
x=0,
y=graphics.window.height - label_life.height)
