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The context: my Python code pass arrays of 2D vertices to OpenGL.

I tested 2 approaches, one with ctypes, the other with struct, the latter being more than twice faster.

from random import random
points = [(random(), random()) for _ in xrange(1000)]

from ctypes import c_float
def array_ctypes(points):
    n = len(points)
    return n, (c_float*(2*n))(*[u for point in points for u in point])

from struct import pack
def array_struct(points):
    n = len(points)
    return n, pack("f"*2*n, *[u for point in points for u in point])

Any other alternative? Any hint on how to accelerate such code (and yes, this is one bottleneck of my code)?

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I cross-posted this question to newsgroup gmane.comp.python.opengl.user too, which returned similar answers as below. –  Jonathan Hartley Nov 21 '10 at 10:35

4 Answers 4

up vote 2 down vote accepted

You could try Cython. For me, this gives:

function       usec per loop:
               Python  Cython
array_ctypes   1370    1220
array_struct    384     249
array_numpy     336     339

So Numpy only gives 15% benefit on my hardware (old laptop running WindowsXP), whereas Cython gives about 35% (without any extra dependency in your distributed code).

If you can loosen your requirement that each point is a tuple of floats, and simply make 'points' a flattened list of floats:

def array_struct_flat(points):
    n = len(points)
    return pack(
        "f"*n,
        *[
            coord
            for coord in points
        ]
    )

points = [random() for _ in xrange(1000 * 2)]

then the resulting output is the same, but the timing goes down further:

function            usec per loop:
                    Python  Cython
array_struct_flat           157

Cython might be capable of substantially better than this too, if someone smarter than me wanted to add static type declarations to the code. (Running 'cython -a test.pyx' is invaluable for this, it produces an html file showing you where the slowest (yellow) plain Python is in your code, versus python that has been converted to pure C (white). That's why I spread the code above out onto so many lines, because the coloring is done per-line, so it helps to spread it out like that.)

Full Cython instructions are here: http://docs.cython.org/src/quickstart/build.html

Cython might produce similar performance benefits across your whole codebase, and in ideal conditions, with proper static typing applied, can improve speed by factors of ten or a hundred.

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You can pass numpy arrays to PyOpenGL without incurring any overhead. (The data attribute of the numpy array is a buffer that points to the underlying C data structure that contains the same information as the array you're building)

import numpy as np  
def array_numpy(points):
    n = len(points)
    return n, np.array(points, dtype=np.float32)

On my computer, this is about 40% faster than the struct-based approach.

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Impressive! I did not want to add the numpy dependency to my code, but it looks like it is worth it. (side note: not specifying the dtype parameter kills the perf by a factor 10) –  rndblnch Nov 11 '10 at 17:57
    
Can this technique be improved further, by creating the numpy array up-front, and then just updating elements as required every frame. I'm imagining situations where vertices would mostly be static, but sometime a portion of them would need updating for animations. –  Jonathan Hartley Nov 21 '10 at 11:03
    
You might also get additional benefits from using numpy to manipulate the arrays once they exist. e.g. you could add an array of velocities to an array of positions. This might be especially good for things like particle systems, where your Python code doesn't need frequent access to the value of the resulting positions. –  Jonathan Hartley Nov 23 '10 at 15:58

You can use array (notice also the generator expression instead of the list comprehension):

array("f", (u for point in points for u in point)).tostring()

Another optimization would be to keep the points flattened from the beginning.

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I tried generators in my first attempts, and it turns out that it slows down the functions. –  rndblnch Nov 11 '10 at 17:26
    
(and it also slows down this array version). by the way, even with list comprehension, the array based solution is still 20% slower than the struct version... –  rndblnch Nov 11 '10 at 17:30

There's another idea I stumbled across. I don't have time to profile it right now, but in case someone else does:

 # untested, but I'm fairly confident it runs
 # using 'flattened points' list, i.e. a list of n*2 floats
 points = [random() for _ in xrange(1000 * 2)]
 c_array = c_float * len(points * 2)
 c_array[:] = points

That is, first we create the ctypes array but don't populate it. Then we populate it using the slice notation. People smarter than I tell me that assigning to a slice like this may help performance. It allows us to pass a list or iterable directly on the RHS of the assignment, without having to use the *iterable syntax, which would perform some intermediate wrangling of the iterable. I suspect that this is what happens in the depths of creating pyglet's Batches.

Presumably you could just create c_array once, then just reassign to it (the final line in the above code) every time the points list changes.

There is probably an alternative formulation which accepts the original definition of points (a list of (x,y) tuples.) Something like this:

 # very untested, likely contains errors
 # using a list of n tuples of two floats
 points = [(random(), random()) for _ in xrange(1000)]
 c_array = c_float * len(points * 2)
 c_array[:] = chain(p for p in points)
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