# Cannot get ball to bounce in pygame

I have a function to map the path of my ball (`gravity(t)` returns 4.9t^2):

``````def path(x, y, p, a, t, bounce=False):
vx, vy = p * math.cos(a), p * math.sin(a)  #Velocities
if bounce: vx, vy = -vx, -vy
dx, dy = vx * t, -(vy * t - gravity(t))  #Distances Traveled

print(f'    x-pos: {dx + x:.0f}px')
print(f'    y-pos: {abs(dy - y):.0f}px')

return round(dx + x), round(dy + y)
``````

I call it here:

``````else:
time += .3 * speed_multiplier
print('\n   time: %ss' % round(time, 2))
if ball.y <= START_Y:
if BARRIER < ball.x < SCREEN_WIDTH:
po = ball.path(x, y, power, ang, time)
ball.x, ball.y = po[0], po[1]
else:
print('Out of Bounds!')
penalty = True
p_ticks = pg.time.get_ticks()
strokes += 1
shoot = False
if BARRIER < xb < SCREEN_WIDTH:
ball.x = xb
else:
ball.x = START_X
ball.y = yb
else:
shoot = False
ball.y = START_Y
``````

This works perfectly. Now, wanting to add bounce, I tried this:

``````else:
time += .3 * speed_multiplier
print('\n   time: %ss' % round(time, 2))
if ball.y <= START_Y:
if BARRIER < ball.x < SCREEN_WIDTH:
po = ball.path(x, y, power, ang, time)
ball.x, ball.y = po[0], po[1]
else:
print('Out of Bounds!')
penalty = True
p_ticks = pg.time.get_ticks()
strokes += 1
shoot = False
if BARRIER < xb < SCREEN_WIDTH:
ball.x = xb
else:
ball.x = START_X
ball.y = yb
else:
po = ball.path(x, y, power, ang, time, True)
ball.x, ball.y = po[0], po[1]
``````

Bounce doesn't work, and the ball goes a bit down after each stroke after falling off the screen.

Any suggestions?

Edit – Here's the full code for those who'd like to run it:

``````import math
import pygame as pg

SCREEN_WIDTH = 1500
SCREEN_HEIGHT = 800
WINDOW_COLOR = (100, 100, 100)
LINE_COLOR = (0, 0, 255)
ALINE_COLOR = (0, 0, 0)
BARRIER = 1
START_X = int(.5 * SCREEN_WIDTH)
START_Y = int(.99 * SCREEN_HEIGHT)

pg.font.init()
strokeFont = pg.font.SysFont("monospace", 50)
STROKECOLOR = (255, 255, 0)

powerFont = pg.font.SysFont("arial", 15, bold=True)
POWERCOLOR = (0, 255, 0)

angleFont = pg.font.SysFont("arial", 15, bold=True)
ANGLECOLOR = (0, 255, 0)

penaltyFont = pg.font.SysFont("georgia", 40, bold=True)
PENALTYCOLOR = (255, 0, 0)

speedMultiplierFont = pg.font.SysFont("courier new", 13)
SPEEDMULTIPLIERCOLOR = (255, 0, 0)

powerMultiplierFont = pg.font.SysFont("courier new", 13)
POWERMULTIPLIERCOLOR = (255, 0, 0)

class Ball(object):
def __init__(self, x, y):
self.x = x
self.y = y
self.color = (255, 255, 255)
self.outlinecolor = (255, 0, 0)

def show(self, window):

@staticmethod
def path(x, y, p, a, t, bounce=False):
vx, vy = p * math.cos(a), p * math.sin(a)  #Velocities
if bounce: vx, vy = -vx, -vy
dx, dy = vx * t, -(vy * t - gravity(t))  #Distances Traveled

if bounce: pass

print(f'    x-pos: {dx + x:.0f}px')
print(f'    y-pos: {abs(dy - y):.0f}px')

return round(dx + x), round(dy + y)

@staticmethod
if ym < y and xm > x:
return 1
elif ym < y and xm < x:
return 2
elif ym > y and xm < x:
return 3
elif ym > y and xm > x:
return 4
else:
return False

def draw_window():
window.fill(WINDOW_COLOR)
ball.show(window)
if not shoot:
pg.draw.arrow(window, ALINE_COLOR, ALINE_COLOR, aline[0], aline[1], 5)
pg.draw.arrow(window, LINE_COLOR, LINE_COLOR, line[0], line[1], 5)

stroke_text = 'Strokes: %s' % strokes
stroke_label = strokeFont.render(stroke_text, 1, STROKECOLOR)
if not strokes:
window.blit(stroke_label, (SCREEN_WIDTH - .21 * SCREEN_WIDTH, SCREEN_HEIGHT - .985 * SCREEN_HEIGHT))
else:
window.blit(stroke_label, (SCREEN_WIDTH - (.21+.02*math.floor(math.log10(strokes))) * SCREEN_WIDTH, SCREEN_HEIGHT - .985 * SCREEN_HEIGHT))

power_text = 'Shot Strength: %sN' % power_display
power_label = powerFont.render(power_text, 1, POWERCOLOR)
if not shoot: window.blit(power_label, (cursor_pos[0] + .008 * SCREEN_WIDTH, cursor_pos[1]))

angle_text = 'Angle: %s°' % angle_display
angle_label = angleFont.render(angle_text, 1, ANGLECOLOR)
if not shoot: window.blit(angle_label, (ball.x - .06 * SCREEN_WIDTH, ball.y - .01 * SCREEN_HEIGHT))

if penalty:
penalty_text = 'Out of Bounds! +1 Stroke'
penalty_label = penaltyFont.render(penalty_text, 1, PENALTYCOLOR)
penalty_rect = penalty_label.get_rect(center=(SCREEN_WIDTH/2, .225*SCREEN_HEIGHT))
window.blit(penalty_label, penalty_rect)

speed_multiplier_text = 'Speed: {:2.2f} m/s'.format(speed_multiplier)
speed_multiplier_label = speedMultiplierFont.render(speed_multiplier_text, 1, SPEEDMULTIPLIERCOLOR)
window.blit(speed_multiplier_label, (.91*SCREEN_WIDTH,.98*SCREEN_HEIGHT))

power_multiplier_text = f'Strength: {int(power_multiplier*100)}%'
power_multiplier_label = powerMultiplierFont.render(power_multiplier_text, 1, POWERMULTIPLIERCOLOR)
window.blit(power_multiplier_label, (.01*SCREEN_WIDTH,.98*SCREEN_HEIGHT))

#strength

pg.display.flip()

def angle(cursor_pos):
x, y, xm, ym = ball.x, ball.y, cursor_pos[0], cursor_pos[1]
if x-xm:
angle = math.atan((y - ym) / (x - xm))
elif y > ym:
angle = math.pi/2
else:
angle = 3*math.pi/2

if q: angle = math.pi*math.floor(q/2) - angle

if round(angle*deg) == 360:
angle = 0

if x > xm and not round(angle*deg):
angle = math.pi

return angle

def gravity(t):
return 4.9*t**2

def arrow(screen, lcolor, tricolor, start, end, trirad):
pg.draw.line(screen, lcolor, start, end, 2)
rotation = (math.atan2(start[1] - end[1], end[0] - start[0])) + math.pi/2
pg.draw.polygon(screen, tricolor, ((end[0] + trirad * math.sin(rotation),
setattr(pg.draw, 'arrow', arrow)

def distance(x, y):
return math.sqrt(x**2 + y**2)

def initialize():
pg.init()
pg.display.set_caption('Golf')
window = pg.display.set_mode((SCREEN_WIDTH, SCREEN_HEIGHT))
pg.event.set_grab(True)
pg.mouse.set_cursor((8, 8), (0, 0), (0, 0, 0, 0, 0, 0, 0, 0), (0, 0, 0, 0, 0, 0, 0, 0))

return window

x, y, time, power, ang, strokes = 0, 0, 0, 0, 0, 0
xb, yb = None, None
shoot, penalty = False, False
p_ticks = 0

ball = Ball(START_X, START_Y)
quit = False

strength_dict = {0: .01, 1: .02, 2: .04, 3: .08, 4: .16, 5: .25, 6: .50, 7: .75, 8: 1}; stkey = 6
speed_dict = {0: .25, 1: .5, 2: 1, 3: 1.5, 4: 2, 5: 2.5, 6: 3, 7: 3.5, 8: 4, 9: 5, 10: 7.5, 11: 10}; spkey = 4

window = initialize()
try:
while not quit:
power_multiplier = strength_dict[stkey]
speed_multiplier = speed_dict[spkey]

seconds = (pg.time.get_ticks()-p_ticks)/1000
if seconds > 1.2: penalty = False

cursor_pos = pg.mouse.get_pos()
line = [(ball.x, ball.y), cursor_pos]
line_ball_x, line_ball_y = cursor_pos[0] - ball.x, cursor_pos[1] - ball.y

aline = [(ball.x, ball.y), (ball.x + .015 * SCREEN_WIDTH, ball.y)]

if not shoot:
power_display = round(
distance(line_ball_x, line_ball_y) * power_multiplier/5)

angle_display = round(angle(cursor_pos) * deg)

else:
time += .3 * speed_multiplier
print('\n   time: %ss' % round(time, 2))
if ball.y <= START_Y:
if BARRIER < ball.x < SCREEN_WIDTH:
po = ball.path(x, y, power, ang, time)
ball.x, ball.y = po[0], po[1]
else:
print('Out of Bounds!')
penalty = True
p_ticks = pg.time.get_ticks()
strokes += 1
shoot = False
if BARRIER < xb < SCREEN_WIDTH:
ball.x = xb
else:
ball.x = START_X
ball.y = yb
else:
po = ball.path(x, y, power, ang, time, True)
ball.x, ball.y = po[0], po[1]

for event in pg.event.get():
if event.type == pg.QUIT:
quit = True

if event.type == pg.KEYDOWN:
if event.key == pg.K_ESCAPE:
quit = True

if event.key == pg.K_RIGHT:
if spkey != max(speed_dict):
spkey += 1

if event.key == pg.K_LEFT:
if spkey != min(speed_dict):
spkey -= 1

if event.key == pg.K_UP:
if stkey != max(strength_dict):
stkey += 1

if event.key == pg.K_DOWN:
if stkey != min(strength_dict):
stkey -= 1

if event.type == pg.MOUSEBUTTONDOWN:
if not shoot:
shoot = True
x, y = ball.x, ball.y
xb, yb = ball.x, ball.y
time, power = 0, (
distance(line_ball_x, line_ball_y)) * power_multiplier/6
print('\n\nBall Hit!')
print('\npower: %sN' % round(power, 2))
ang = angle(cursor_pos)
print('angle: %s°' % round(ang * deg, 2))
print('cos(a): %s' % round(math.cos(ang), 2)), print('sin(a): %s' % round(math.sin(ang), 2))
strokes += 1

draw_window()

print("\nShutting down...")
pg.quit()

except Exception as error:
print(f'A fatal error ({error}) has occurred. The program is shutting down.')
pg.quit()
``````

Edit 2 – For those who'd like to see the final solution, here's my current code:

``````import math
import pygame as pg

SCREEN_WIDTH = 1500
SCREEN_HEIGHT = 800
WINDOW_COLOR = (100, 100, 100)

LINE_COLOR = (0, 0, 255)
ALINE_COLOR = (0, 0, 0)

BARRIER = 1
BOUNCE_FUZZ = 0

START_X = int(.5 * SCREEN_WIDTH)
START_Y = int(.99 * SCREEN_HEIGHT)

pg.font.init()
strokeFont = pg.font.SysFont("monospace", 50)
STROKECOLOR = (255, 255, 0)

powerFont = pg.font.SysFont("arial", 15, bold=True)
POWERCOLOR = (0, 255, 0)

angleFont = pg.font.SysFont("arial", 15, bold=True)
ANGLECOLOR = (0, 255, 0)

penaltyFont = pg.font.SysFont("georgia", 40, bold=True)
PENALTYCOLOR = (255, 0, 0)

speedMultiplierFont = pg.font.SysFont("courier new", 13)
SPEEDMULTIPLIERCOLOR = (255, 0, 0)

powerMultiplierFont = pg.font.SysFont("courier new", 13)
POWERMULTIPLIERCOLOR = (255, 0, 0)

class Ball(object):
def __init__(self, x, y, dx = 0, dy = 0, brate = .8):
self.x = x
self.y = y
self.dx = dx
self.dy = dy
self.brate = brate
self.color = (255, 255, 255)
self.outlinecolor = (255, 0, 0)

def show(self, window):

def update(self, update_frame):
update_frame += 1
ax = 0
ay = 9.81

dt = 0.2 * speed_multiplier
self.vx += ax * dt
self.vy += ay * dt

self.x += self.vx * dt
self.y += self.vy * dt

bounced = False
if self.y + self.radius > SCREEN_HEIGHT:
self.vy = -self.vy
bounced = True

# if (self.x - self.radius < BARRIER):
#     self.x = BARRIER + self.radius
#     self.vx = -self.vx
#     bounced = True

# if (self.x + self.radius > SCREEN_WIDTH - BARRIER):
#     self.x = SCREEN_WIDTH - BARRIER - self.radius
#     self.vx = -self.vx
#     bounced = True

if bounced:
self.vx *= self.brate
self.vy *= self.brate

print(f'\n    Update Frame: {update_frame}\n'
'    x-pos: %spx' % round(self.x),
'    y-pos: %spx' % round(self.y),
'    x-vel: %spx/u' % round(self.vx),
'    y-vel: %spx/u' % round(self.vy),
sep='\n')

return update_frame

@staticmethod
if ym < y and xm > x:
return 1
elif ym < y and xm < x:
return 2
elif ym > y and xm < x:
return 3
elif ym > y and xm > x:
return 4
else:
return False

def draw_window():
window.fill(WINDOW_COLOR)
ball.show(window)
if not shoot:
pg.draw.arrow(window, ALINE_COLOR, ALINE_COLOR, aline[0], aline[1], 5)
pg.draw.arrow(window, LINE_COLOR, LINE_COLOR, line[0], line[1], 5)

stroke_text = 'Strokes: %s' % strokes
stroke_label = strokeFont.render(stroke_text, 1, STROKECOLOR)
if not strokes:
window.blit(stroke_label, (SCREEN_WIDTH - .21 * SCREEN_WIDTH, SCREEN_HEIGHT - .985 * SCREEN_HEIGHT))
else:
window.blit(stroke_label, (SCREEN_WIDTH - (.21+.02*math.floor(math.log10(strokes))) * SCREEN_WIDTH, SCREEN_HEIGHT - .985 * SCREEN_HEIGHT))

power_text = 'Shot Strength: %sN' % power_display
power_label = powerFont.render(power_text, 1, POWERCOLOR)
if not shoot: window.blit(power_label, (cursor_pos[0] + .008 * SCREEN_WIDTH, cursor_pos[1]))

angle_text = 'Angle: %s°' % angle_display
angle_label = angleFont.render(angle_text, 1, ANGLECOLOR)
if not shoot: window.blit(angle_label, (ball.x - .06 * SCREEN_WIDTH, ball.y - .01 * SCREEN_HEIGHT))

if penalty:
penalty_text = 'Out of Bounds! +1 Stroke'
penalty_label = penaltyFont.render(penalty_text, 1, PENALTYCOLOR)
penalty_rect = penalty_label.get_rect(center=(SCREEN_WIDTH/2, .225*SCREEN_HEIGHT))
window.blit(penalty_label, penalty_rect)

speed_multiplier_text = 'Speed: {:2.2f} m/s'.format(speed_multiplier)
speed_multiplier_label = speedMultiplierFont.render(speed_multiplier_text, 1, SPEEDMULTIPLIERCOLOR)
window.blit(speed_multiplier_label, (.91*SCREEN_WIDTH,.98*SCREEN_HEIGHT))

power_multiplier_text = f'Strength: {int(power_multiplier*100)}%'
power_multiplier_label = powerMultiplierFont.render(power_multiplier_text, 1, POWERMULTIPLIERCOLOR)
window.blit(power_multiplier_label, (.01*SCREEN_WIDTH,.98*SCREEN_HEIGHT))

#strength

pg.display.flip()

def angle(cursor_pos):
x, y, xm, ym = ball.x, ball.y, cursor_pos[0], cursor_pos[1]
if x-xm:
angle = math.atan((y - ym) / (x - xm))
elif y > ym:
angle = math.pi/2
else:
angle = 3*math.pi/2

if q: angle = math.pi*math.floor(q/2) - angle

if round(angle*deg) == 360:
angle = 0

if x > xm and not round(angle*deg):
angle = math.pi

return angle

def gravity(t):
return 4.9*t**2

def arrow(screen, lcolor, tricolor, start, end, trirad):
pg.draw.line(screen, lcolor, start, end, 2)
rotation = (math.atan2(start[1] - end[1], end[0] - start[0])) + math.pi/2
pg.draw.polygon(screen, tricolor, ((end[0] + trirad * math.sin(rotation),
setattr(pg.draw, 'arrow', arrow)

def distance(x, y):
return math.sqrt(x**2 + y**2)

def initialize():
pg.init()
pg.display.set_caption('Golf')
window = pg.display.set_mode((SCREEN_WIDTH, SCREEN_HEIGHT))
pg.event.set_grab(True)
pg.mouse.set_cursor((8, 8), (0, 0), (0, 0, 0, 0, 0, 0, 0, 0), (0, 0, 0, 0, 0, 0, 0, 0))

return window

x, y, power, ang, strokes = [0]*5
xb, yb = None, None
shoot, penalty = False, False
p_ticks, update_frame = 0, 0

ball = Ball(START_X, START_Y)
quit = False

strength_dict = {0: .01, 1: .02, 2: .04, 3: .08, 4: .16, 5: .25, 6: .50, 7: .75, 8: 1}; stkey = 6
speed_dict = {0: .25, 1: .5, 2: 1, 3: 1.5, 4: 2, 5: 2.5, 6: 3, 7: 3.5, 8: 4, 9: 5, 10: 7.5, 11: 10}; spkey = 4

window = initialize()
while not quit:
power_multiplier = strength_dict[stkey]
speed_multiplier = speed_dict[spkey]

seconds = (pg.time.get_ticks()-p_ticks)/1000
if seconds > 1.2: penalty = False

cursor_pos = pg.mouse.get_pos()
line = [(ball.x, ball.y), cursor_pos]
line_ball_x, line_ball_y = cursor_pos[0] - ball.x, cursor_pos[1] - ball.y

aline = [(ball.x, ball.y), (ball.x + .015 * SCREEN_WIDTH, ball.y)]

if not shoot:
power_display = round(
distance(line_ball_x, line_ball_y) * power_multiplier/5)

angle_display = round(angle(cursor_pos) * deg)

else:
if abs(ball.vy) < 5 and abs(ball.vx) < 1 and abs(ball.y - (START_Y - 2*BARRIER)) <= BOUNCE_FUZZ:
shoot = False
ball.y = START_Y
print('\nThe ball has come to a rest!')
update_frame = 0
else:
update_frame = ball.update(update_frame)

if not BARRIER < ball.x < SCREEN_WIDTH:
shoot = False
print('\nOut of Bounds!')
penalty = True
p_ticks = pg.time.get_ticks()
strokes += 1

if BARRIER < xb < SCREEN_WIDTH:
ball.x = xb
else:
ball.x = START_X
ball.y = yb

for event in pg.event.get():
if event.type == pg.QUIT:
quit = True

if event.type == pg.KEYDOWN:
if event.key == pg.K_ESCAPE:
quit = True

if event.key == pg.K_RIGHT:
if spkey != max(speed_dict):
spkey += 1

if event.key == pg.K_LEFT:
if spkey != min(speed_dict):
spkey -= 1

if event.key == pg.K_UP:
if stkey != max(strength_dict):
stkey += 1

if event.key == pg.K_DOWN:
if stkey != min(strength_dict):
stkey -= 1

if event.type == pg.MOUSEBUTTONDOWN:
if not shoot:
shoot = True
x, y = ball.x, ball.y
xb, yb = ball.x, ball.y
power = (distance(line_ball_x, line_ball_y)) / 10
print('\n\nBall Hit!')
print('\npower: %sN' % round(power, 2))
ang = angle(cursor_pos)
print('angle: %s°' % round(ang * deg, 2))
print('cos(a): %s' % round(math.cos(ang), 2)), print('sin(a): %s' % round(math.sin(ang), 2))

ball.vx, ball.vy = power * math.cos(ang), -power * math.sin(ang)

strokes += 1

draw_window()

print("\nShutting down...")
pg.quit()
``````
• it is hard to say anything when we can't run it. You can always use `print()` to display values in variables in different moments. You can also use `print()` to display information which part of code is executed Maybe it will helps to see problem. Or you will have to learn how to use debugger. – furas Apr 14 at 2:01
• I edited in the full code – alec_a Apr 14 at 7:47
• @alec935 When the ball bounce, then you've to limit the y coordinate to the ground `ball.y = START_Y` and you've to reset the time which is used to calculate the gravity `time = 0.0` – Rabbid76 Apr 14 at 8:24
• @Rabbid76 that simply creates an infinite loop where the ball teleports back to where it started – alec_a Apr 14 at 9:31
• @alec935 May be, I didn't verify it. This was a comment not an answer. I just looked over your code and found this obvious issues.The suggestions solve only a part of the problem, of course. – Rabbid76 Apr 14 at 9:39

I'm really not sure how you want to manage your physics update but here is how I would do it:

When the user clicks, an initial velocity for the ball is computed. Using the angle and the distance as you did is perfectly fine.

Please note I added `vx` and `vy` members to the `Ball` class.

``````if event.type == pg.MOUSEBUTTONDOWN:
if not shoot:
shoot = True
power = distance(line_ball_x, line_ball_y)) / 10
ang = angle(cursor_pos)
ball.vx, ball.vy = power * math.cos(ang), -power * math.sin(ang)

strokes += 1
``````

Now, I replaced all the logic you had to manage the position of the ball by an `update()` member function.

The idea of this method, is to update the velocity and the position of the ball using euler integration. At every timestep, you calculate the new speed given the acceleration of gravity (9.81 m.s⁻² is the acceleration of gravity on earth at see level, but you can take whatever value your want here), and you compute the new position given that updated speed*.

Here it is in practice:

``````def update(self, dt):
ax = 0 # Acceleration along x axis
ay = 9.81 # Acceleration along y axis. The value is positive here since y=0 is on the top of the window and you want the ball to go down

# New velocity is the old one with the acceleration multiplied by the time elapsed since last call
self.vx += ax * dt
self.vy += ay * dt

# New position is the old one with the velocity multiplied by the time elapsed since last call
self.x += self.vx * dt
self.y += self.vy * dt
``````

So now you have a nicely moving ball when you click (which is the state you were in if I understood correctly). Now, to answer your question, here is how you can handle the bounces using this method.

The idea is to check, after updating the velocity, if the ball is leaving the window, and if it is, reverse the velocity for the concerned axis (and only this one):

``````    # Check if the ball is falling through the floor
# You need to take the radius into account if you do not want it to leave the screen at all.
if self.y + self.radius > SCREEN_HEIGHT:
# If it's outside, we move it along the floor
# And we invert the y velocity
self.vy = -self.vy

# You can do the same for the edges:
if self.x - self.radius < 0:
self.vx = -self.vx

if self.x + self.radius > SCREEN_WIDTH:
self.vx = -self.vx
``````

Here you have a nicely bouncing ball. The problem is that it never stops bouncing etc. What you can do is to take into account the energy lost when hitting a wall or the floor by multiplying the velocity by a factor when a hit occurs:

``````    bounced = False
# Make this variable true when hitting the ground or a wall

# And update the velocities if needed
if bounced:
self.vx *= 0.9 # Or any other value < 1, at your will.
self.vy *= 0.9
``````

So now you have a bouncing ball that stops after some time. Here is the complete code (from your example)

``````import math
import pygame as pg

SCREEN_WIDTH = 1500
SCREEN_HEIGHT = 800
WINDOW_COLOR = (100, 100, 100)
LINE_COLOR = (0, 0, 255)
ALINE_COLOR = (0, 0, 0)
BARRIER = 1
START_X = int(.5 * SCREEN_WIDTH)
START_Y = int(.99 * SCREEN_HEIGHT)

pg.font.init()
strokeFont = pg.font.SysFont("monospace", 50)
STROKECOLOR = (255, 255, 0)

powerFont = pg.font.SysFont("arial", 15, bold=True)
POWERCOLOR = (0, 255, 0)

angleFont = pg.font.SysFont("arial", 15, bold=True)
ANGLECOLOR = (0, 255, 0)

penaltyFont = pg.font.SysFont("georgia", 40, bold=True)
PENALTYCOLOR = (255, 0, 0)

speedMultiplierFont = pg.font.SysFont("courier new", 13)
SPEEDMULTIPLIERCOLOR = (255, 0, 0)

powerMultiplierFont = pg.font.SysFont("courier new", 13)
POWERMULTIPLIERCOLOR = (255, 0, 0)

class Ball(object):
def __init__(self, x, y, dx = 0, dy = 0):
self.x = x
self.y = y
self.dx = dx
self.dy = dy
self.color = (255, 255, 255)
self.outlinecolor = (255, 0, 0)

def show(self, window):

def update(self):
ax = 0
ay = 9.81

dt = 0.1
self.vx += ax * dt
self.vy += ay * dt

self.x += self.vx * dt
self.y += self.vy * dt

bounced = False
if (self.y + self.radius > SCREEN_HEIGHT):
self.vy = -self.vy
bounced = True

if (self.x - self.radius < BARRIER):
self.vx = -self.vx
bounced = True

if (self.x + self.radius > SCREEN_WIDTH - BARRIER):
self.x = SCREEN_WIDTH - BARRIER - self.radius
self.vx = -self.vx
bounced = True

if bounced:
self.vx *= 0.9
self.vy *= 0.9

print(self.x, self.y, self.vx, self.vy)

@staticmethod
if ym < y and xm > x:
return 1
elif ym < y and xm < x:
return 2
elif ym > y and xm < x:
return 3
elif ym > y and xm > x:
return 4
else:
return False

def draw_window():
window.fill(WINDOW_COLOR)
ball.show(window)
if not shoot:
pg.draw.arrow(window, ALINE_COLOR, ALINE_COLOR, aline[0], aline[1], 5)
pg.draw.arrow(window, LINE_COLOR, LINE_COLOR, line[0], line[1], 5)

stroke_text = 'Strokes: %s' % strokes
stroke_label = strokeFont.render(stroke_text, 1, STROKECOLOR)
if not strokes:
window.blit(stroke_label, (SCREEN_WIDTH - .21 * SCREEN_WIDTH, SCREEN_HEIGHT - .985 * SCREEN_HEIGHT))
else:
window.blit(stroke_label, (SCREEN_WIDTH - (.21+.02*math.floor(math.log10(strokes))) * SCREEN_WIDTH, SCREEN_HEIGHT - .985 * SCREEN_HEIGHT))

power_text = 'Shot Strength: %sN' % power_display
power_label = powerFont.render(power_text, 1, POWERCOLOR)
if not shoot: window.blit(power_label, (cursor_pos[0] + .008 * SCREEN_WIDTH, cursor_pos[1]))

angle_text = 'Angle: %s°' % angle_display
angle_label = angleFont.render(angle_text, 1, ANGLECOLOR)
if not shoot: window.blit(angle_label, (ball.x - .06 * SCREEN_WIDTH, ball.y - .01 * SCREEN_HEIGHT))

if penalty:
penalty_text = 'Out of Bounds! +1 Stroke'
penalty_label = penaltyFont.render(penalty_text, 1, PENALTYCOLOR)
penalty_rect = penalty_label.get_rect(center=(SCREEN_WIDTH/2, .225*SCREEN_HEIGHT))
window.blit(penalty_label, penalty_rect)

speed_multiplier_text = 'Speed: {:2.2f} m/s'.format(speed_multiplier)
speed_multiplier_label = speedMultiplierFont.render(speed_multiplier_text, 1, SPEEDMULTIPLIERCOLOR)
window.blit(speed_multiplier_label, (.91*SCREEN_WIDTH,.98*SCREEN_HEIGHT))

power_multiplier_text = f'Strength: {int(power_multiplier*100)}%'
power_multiplier_label = powerMultiplierFont.render(power_multiplier_text, 1, POWERMULTIPLIERCOLOR)
window.blit(power_multiplier_label, (.01*SCREEN_WIDTH,.98*SCREEN_HEIGHT))

#strength

pg.display.flip()

def angle(cursor_pos):
x, y, xm, ym = ball.x, ball.y, cursor_pos[0], cursor_pos[1]
if x-xm:
angle = math.atan((y - ym) / (x - xm))
elif y > ym:
angle = math.pi/2
else:
angle = 3*math.pi/2

if q: angle = math.pi*math.floor(q/2) - angle

if round(angle*deg) == 360:
angle = 0

if x > xm and not round(angle*deg):
angle = math.pi

return angle

def gravity(t):
return 4.9*t**2

def arrow(screen, lcolor, tricolor, start, end, trirad):
pg.draw.line(screen, lcolor, start, end, 2)
rotation = (math.atan2(start[1] - end[1], end[0] - start[0])) + math.pi/2
pg.draw.polygon(screen, tricolor, ((end[0] + trirad * math.sin(rotation),
setattr(pg.draw, 'arrow', arrow)

def distance(x, y):
return math.sqrt(x**2 + y**2)

def initialize():
pg.init()
pg.display.set_caption('Golf')
window = pg.display.set_mode((SCREEN_WIDTH, SCREEN_HEIGHT))
pg.event.set_grab(True)
pg.mouse.set_cursor((8, 8), (0, 0), (0, 0, 0, 0, 0, 0, 0, 0), (0, 0, 0, 0, 0, 0, 0, 0))

return window

x, y, time, power, ang, strokes = 0, 0, 0, 0, 0, 0
xb, yb = None, None
shoot, penalty = False, False
p_ticks = 0

ball = Ball(START_X, START_Y)
quit = False

strength_dict = {0: .01, 1: .02, 2: .04, 3: .08, 4: .16, 5: .25, 6: .50, 7: .75, 8: 1}; stkey = 6
speed_dict = {0: .25, 1: .5, 2: 1, 3: 1.5, 4: 2, 5: 2.5, 6: 3, 7: 3.5, 8: 4, 9: 5, 10: 7.5, 11: 10}; spkey = 4

window = initialize()
try:
while not quit:
power_multiplier = strength_dict[stkey]
speed_multiplier = speed_dict[spkey]

seconds = (pg.time.get_ticks()-p_ticks)/1000
if seconds > 1.2: penalty = False

cursor_pos = pg.mouse.get_pos()
line = [(ball.x, ball.y), cursor_pos]
line_ball_x, line_ball_y = cursor_pos[0] - ball.x, cursor_pos[1] - ball.y

aline = [(ball.x, ball.y), (ball.x + .015 * SCREEN_WIDTH, ball.y)]

if not shoot:
power_display = round(
distance(line_ball_x, line_ball_y) * power_multiplier/5)

angle_display = round(angle(cursor_pos) * deg)

else:
ball.update()

# time += .3 * speed_multiplier
# print('\n   time: %ss' % round(time, 2))
# if ball.y <= START_Y:
#     if BARRIER < ball.x and ball.x < SCREEN_WIDTH:
#         po = ball.path(x, y, power, ang, time)
#         ball.x, ball.y = po[0], po[1]
#     else:
#         print('Out of Bounds!')
#         penalty = True
#         p_ticks = pg.time.get_ticks()
#         strokes += 1
#         shoot = False
#         if BARRIER < xb < SCREEN_WIDTH:
#             ball.x = xb
#         else:
#             ball.x = START_X
#         ball.y = yb
# else:
#     po = ball.path(x, y, power, ang, time, True)
#     ball.x, ball.y = po[0], po[1]

for event in pg.event.get():
if event.type == pg.QUIT:
quit = True

if event.type == pg.KEYDOWN:
if event.key == pg.K_ESCAPE:
quit = True

if event.key == pg.K_RIGHT:
if spkey != max(speed_dict):
spkey += 1

if event.key == pg.K_LEFT:
if spkey != min(speed_dict):
spkey -= 1

if event.key == pg.K_UP:
if stkey != max(strength_dict):
stkey += 1

if event.key == pg.K_DOWN:
if stkey != min(strength_dict):
stkey -= 1

if event.type == pg.MOUSEBUTTONDOWN:
if not shoot:
shoot = True
x, y = ball.x, ball.y
xb, yb = ball.x, ball.y
time, power = 0, (
distance(line_ball_x, line_ball_y)) / 10
print('\n\nBall Hit!')
print('\npower: %sN' % round(power, 2))
ang = angle(cursor_pos)
print('angle: %s°' % round(ang * deg, 2))
print('cos(a): %s' % round(math.cos(ang), 2)), print('sin(a): %s' % round(math.sin(ang), 2))

ball.vx, ball.vy = power * math.cos(ang), -power * math.sin(ang)

strokes += 1

draw_window()

print("\nShutting down...")
pg.quit()

except Exception as error:
print(f'A fatal error ({error}) has occurred. The program is shutting down.')
pg.quit()
``````

Again, please keep in mind that this is A way to handle the physics, this might not be the way you want to handle it.

(* Actually this is not "classic" euler method, this is the semi-implicit one, which is more stable)

• This is almost perfect. I don't want the ball bouncing off the left and right edges, but I can fix that myself. The bigger issue here is that after the ball comes to rest, I can't shoot it anymore. – alec_a Apr 14 at 19:00
• You can just check the velocity each frame. If the ball comes to rest (vx and vy < some epsilon value) you just enable back shooting – Zouch Apr 14 at 19:51
• Got it! For anyone reading in the future, I also had to check if `ball.y` was within a certain distance of `START_Y` to make sure it didn't stop in the air. – alec_a Apr 14 at 23:09