Python 3.2 vs Python 2.7 code problems

I have a code to graph the mandlebrot set using pygame. Here is the code.

import pygame, sys, math
from decimal import *
window=pygame.display.set_mode((1000, 1000))
window.fill((255, 255, 255))
pygame.display.update()
winrect=window.get_rect()
hq=3
getcontext().prec=20
colors=((255, 0, 0), (255, 128, 0), (255, 255, 0), (128, 255, 0), (0, 255, 0), (0, 255, 128), (0, 255, 255), (0, 128, 255), (0, 0, 255), (128, 0, 255), (255, 0, 255), (255, 0, 128))
def graph(scale):#left, right, bottom, top
window.fill((0, 0, 0))
minimum=-1
y=((scale[3]-scale[2]))/(winrect.height)+scale[2]
for a in range(winrect.width):
x=((scale[1]-scale[0])*(a))/(winrect.width)+scale[0]
d, e=x**2-y**2+x, 2*x*y+y
for i in range(int(1/(50*(scale[1]-scale[0]))+25)):
d, e=d**2-e**2+x, 2*d*e+y
if math.sqrt(d**2+e**2)>2:
if i<minimum or minimum==-1:
minimum=i
break
y=((scale[3]-scale[2])*winrect.height)/(winrect.height)+scale[2]
for a in range(winrect.width):
x=((scale[1]-scale[0])*a)/winrect.width+scale[0]
d, e=x**2-y**2+x, 2*x*y+y
for i in range(int(1/(50*(scale[1]-scale[0]))+25)):
d, e=d**2-e**2+x, 2*d*e+y
if math.sqrt(d**2+e**2)>2:
if i<minimum or minimum==-1:
minimum=i
break
x=((scale[1]-scale[0])*1)/winrect.width+scale[0]
for b in range(winrect.height):
y=((scale[3]-scale[2])*b)/winrect.height+scale[2]
d, e=x**2-y**2+x, 2*x*y+y
for i in range(int(1/(50*(scale[1]-scale[0]))+25)):
d, e=d**2-e**2+x, 2*d*e+y
if math.sqrt(d**2+e**2)>2:
if i<minimum or minimum==-1:
minimum=i
break
x=((scale[1]-scale[0])*winrect.width)/winrect.width+scale[0]
for b in range(winrect.height):
y=((scale[3]-scale[2])*b)/winrect.height+scale[2]
d, e=x**2-y**2+x, 2*x*y+y
for i in range(int(1/(50*(scale[1]-scale[0]))+25)):
d, e=d**2-e**2+x, 2*d*e+y
if math.sqrt(d**2+e**2)>2:
if i<minimum or minimum==-1:
minimum=i
break
for a in range(winrect.width):
for b in range(winrect.height):
x=((scale[1]-scale[0])*a)/winrect.width+scale[0]
y=((scale[3]-scale[2])*b)/winrect.height+scale[2]
d, e=x**2-y**2+x, 2*x*y+y
for i in range(minimum):
d, e=d**2-e**2+x, 2*d*e+y
for i in range(20*hq):
d, e=d**2-e**2+x, 2*d*e+y
if math.sqrt(d**2+e**2)>2:
window.set_at((a, b), colors[i-(int(i/len(colors))*len(colors))])
break
for event in pygame.event.get():
if event.type==pygame.QUIT:
pygame.quit()
sys.exit()
if event.type==pygame.KEYDOWN:
if event.key==pygame.K_ESCAPE:
pygame.quit()
sys.exit()
pygame.display.update()
pygame.display.update()
graph([-3, 2, -2.5, 2.5, 0])#
scale=[-3, 2, -2.5, 2.5, 0]
scalea=scale[:]
while True:
for event in pygame.event.get():
if event.type==pygame.QUIT:
pygame.quit()
sys.exit()
if event.type==pygame.KEYDOWN:
if event.key==pygame.K_ESCAPE:
pygame.quit()
sys.exit()
if event.key==pygame.K_r:
graph([-3, 2, -2.5, 2.5, 0])
scale=[-3, 2, -2.5, 2.5, 0]
scalea=scale[:]
if event.key==pygame.K_p:
hq+=1
graph(scale)
if event.key==pygame.K_o:
if not hq==1:
hq-=1
graph(scale)
if event.key==pygame.K_SPACE:
print(scale)
print(scale[1]-scale[0])
if event.type==pygame.MOUSEBUTTONDOWN:
if not scalea[4]:
scalea[0]=(((scale[1]-scale[0])*event.pos[0])/winrect.width)+scale[0]
scalea[2]=(((scale[3]-scale[2])*event.pos[1])/winrect.height)+scale[2]
scalea[4]=1
else:
scalea[1]=(((scale[1]-scale[0])*event.pos[0])/winrect.width)+scale[0]
scalea[3]=(((scale[3]-scale[2])*event.pos[1])/winrect.height)+scale[2]
scalea[4]=0
if scalea[1]<scalea[0]:
scalea=[scalea[1], scalea[0], scalea[2], scalea[3], 0]
if scalea[3]<scalea[2]:
scalea=[scalea[0], scalea[1], scalea[3], scalea[2], 0]
scale=scalea[:]
if scale[1]-scale[0]<scale[3]-scale[2]:
scale[1]+=((scalea[3]-scalea[2])-(scalea[1]-scalea[0]))/2
scale[0]-=((scalea[3]-scalea[2])-(scalea[1]-scalea[0]))/2
else:
scale[2]-=((scalea[1]-scalea[0])-(scalea[3]-scalea[2]))/2
scale[3]+=((scalea[1]-scalea[0])-(scalea[3]-scalea[2]))/2
graph(scale)


When I run it in python 3.2, it works fine. The image looks like this:

However, when I run it in python 2.7, I get a horrible looking image which looks like this:

Is there any way I can fix this?

-
You only say "horrible" because it's not what you expected. I think it looks great! –  Todd Apr 18 '13 at 14:32
Looks like a “BIT.TRIP Mandelbrot”… ^^ –  poke Apr 18 '13 at 14:39
@Todd You must be into modern art. –  PygameNerd Apr 18 '13 at 15:57

from __future__ import division


Python 2 uses integer division (floor division) when using integer inputs by default; Python 3 switched to floating point division even when using integer inputs.

See the PEP 238, which documents the change:

The current division (/) operator has an ambiguous meaning for numerical arguments: it returns the floor of the mathematical result of division if the arguments are ints or longs, but it returns a reasonable approximation of the division result if the arguments are floats or complex. This makes expressions expecting float or complex results error-prone when integers are not expected but possible as inputs.

-
This worked perfectly, but I have another question. Even when I'm on 3.2, once I zoom in a lot, I get a similar picture to the former 2.7, which I think is due to a lack of precision in Python. I used the decimal module to try to get rid of it, but it takes way longer when I do so. Any solutions to this? –  PygameNerd Apr 18 '13 at 14:40
Not really; floating point indeed have precision limits, but because they are handled by your PC hardware, they are also much faster to process. You could switch to using integers to calculate the mandelbrot instead. That's how I played with fractals 20-odd years ago, anyway, with FRACTINT. :-) –  Martijn Pieters Apr 18 '13 at 14:54
Add from __future__ import division at the top.