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I am baffled by this

def main():
    for i in xrange(2560000):
        a = [0.0, 0.0, 0.0]

main()

$ time python test.py

real     0m0.793s

Let's now see with numpy:

import numpy

def main():
    for i in xrange(2560000):
        a = numpy.array([0.0, 0.0, 0.0])

main()

$ time python test.py

real    0m39.338s

Holy CPU cycles batman!

Using numpy.zeros(3) improves, but still not enough IMHO

$ time python test.py

real    0m5.610s
user    0m5.449s
sys 0m0.070s

numpy.version.version = '1.5.1'

If you are wondering if the list creation is skipped for optimization in the first example, it is not:

  5          19 LOAD_CONST               2 (0.0)
             22 LOAD_CONST               2 (0.0)
             25 LOAD_CONST               2 (0.0)
             28 BUILD_LIST               3
             31 STORE_FAST               1 (a)
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1  
A quick thought: numpy.array is actually a more complex data structure than a list. And in the second snippet, you create a list and an numpy array (in the first only a list). Whether this is the only reason for such a big difference, I cannot say. –  Felix Kling Jul 2 '11 at 20:38
    
@Felix: ok, but the creation of the list is fast, so even if I create a list and a numpy array in the second case, it's still the numpy creation that is the hot spot here, and regardless how complex the structure may be, it's still damn expensive... –  Stefano Borini Jul 2 '11 at 20:40
3  
But consider: Creating the data is rarely the bottleneck in an application that so complex it uses numpy. I don't know what happens under the hood either, but it obviously makes math-heavy programs faster at the end of the day, so there's no reason to complain ;) –  delnan Jul 2 '11 at 20:49
    
@delnan : in my case, it is. –  Stefano Borini Jul 2 '11 at 20:53
4  
@Stefano: aren't you including the import of numpy in the timings? (Also python has a builtin timings module.) –  katrielalex Jul 2 '11 at 21:09
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2 Answers

up vote 25 down vote accepted

Numpy is optimised for large amounts of data. Give it a tiny 3 length array and, unsurprisingly, it performs poorly.

Consider a separate test

import timeit

reps = 100

pythonTest = timeit.Timer('a = [0.] * 1000000')
numpyTest = timeit.Timer('a = numpy.zeros(1000000)', setup='import numpy')
uninitialised = timeit.Timer('a = numpy.empty(1000000)', setup='import numpy')
# empty simply allocates the memory. Thus the initial contents of the array 
# is random noise

print 'python list:', pythonTest.timeit(reps), 'seconds'
print 'numpy array:', numpyTest.timeit(reps), 'seconds'
print 'uninitialised array:', uninitialised.timeit(reps), 'seconds'

And the output is

python list: 1.22042918205 seconds
numpy array: 1.05412316322 seconds
uninitialised array: 0.0016028881073 seconds

It would seem that it is the zeroing of the array that is taking all the time for numpy. So unless you need the array to be initialised then try using empty.

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1  
For fairness, you should have done pythonTest = timeit.Timer('a = [0.] * 1000000'), it still performs slower than numpy but it's quite faster than a LC. And it is "closer" to a list literal (as given in the question) in that it doesn't run a Python loop. –  Rosh Oxymoron Jul 2 '11 at 21:43
    
@Rosh Good point. I think I've always shied away from the * operator for lists as it puts the same object in each index. Though since numbers are immutable that doesn't matter in this case. Though try performing a mass operation on the list/array then numpy is way out in the lead again (eg. arr += 1). –  Dunes Jul 2 '11 at 21:56
    
Very good point, thank you. Considering the result, what would you suggest for small arrays ? I mean, lists and tuples are not really nice when it comes to basic array operations (such as vector-vector product, multiplication of array times a number etc, determinant of small matrices) Of course I can reimplement the algos by myself, it's not the big problem here, but if there's already something for that, I consider it the preferred solution. –  Stefano Borini Jul 2 '11 at 22:02
    
Separate question? But anyway itertools docs suggest that you can make very efficient vector functions with a combination of itertool and operator functions. –  Dunes Jul 2 '11 at 22:17
1  
@Stefano Borini: Simply; do not try to optimize with small numpy arrays. Instead, try to consolidate the operations for much bigger chunks. Anyway, it seems that your rant is based only on creation of small arrays. Please describe your real problem, in order to figure out whether it's more suitable to solve it in 'pure python' or 'numpy' realm. Thanks –  eat Jul 2 '11 at 22:22
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Holy CPU cycles batman!, indeed.

But please rather consider something very fundamental related to numpy; sophisticated linear algebra based functionality (like random numbers or singular value decomposition). Now, consider these seamingly simple calculations:

In []: A= rand(2560000, 3)
In []: %timeit rand(2560000, 3)
1 loops, best of 3: 296 ms per loop
In []: %timeit u, s, v= svd(A, full_matrices= False)
1 loops, best of 3: 571 ms per loop

and please trust me that this kind of performance will not be beaten significantly by any package currently available.

So, please describe your real problem, and I'll try to figure out decent numpy based solution for it.

Update:
Here is some simply code for ray sphere intersection:

import numpy as np

def mag(X):
    # magnitude
    return (X** 2).sum(0)** .5

def closest(R, c):
    # closest point on ray to center and its distance
    P= np.dot(c.T, R)* R
    return P, mag(P- c)

def intersect(R, P, h, r):
    # intersection of rays and sphere
    return P- (h* (2* r- h))** .5* R

# set up
c, r= np.array([10, 10, 10])[:, None], 2. # center, radius
n= 5e5
R= np.random.rand(3, n) # some random rays in first octant
R= R/ mag(R) # normalized to unit length

# find rays which will intersect sphere
P, b= closest(R, c)
wi= b<= r

# and for those which will, find the intersection
X= intersect(R[:, wi], P[:, wi], r- b[wi], r)

Apparently we calculated correctly:

In []: allclose(mag(X- c), r)
Out[]: True

And some timings:

In []: % timeit P, b= closest(R, c)
10 loops, best of 3: 93.4 ms per loop
In []: n/ 0.0934
Out[]: 5353319 #=> more than 5 million detection's of possible intersections/ s
In []: %timeit X= intersect(R[:, wi], P[:, wi], r- b[wi])
10 loops, best of 3: 32.7 ms per loop
In []: X.shape[1]/ 0.0327
Out[]: 874037 #=> almost 1 million actual intersections/ s

These timings are done with very modest machine. With modern machine, a significant speed-up can be still expected.

Anyway, this is only a short demonstration how to code with numpy.

share|improve this answer
    
my real problem : stackoverflow.com/questions/6528214/… –  Stefano Borini Jul 2 '11 at 23:13
    
@Stefano Borini: Updated my answer. Thanks –  eat Jul 3 '11 at 10:14
    
good. However, it does not really allow you to deal with Sphere objects directly this way. You must have a backend that converts the high level design into an aggregated set of coordinates that are then fed to numpy. –  Stefano Borini Jul 3 '11 at 10:55
    
+1 for "please rather consider something very fundamental related to numpy" –  doug Jul 3 '11 at 11:05
1  
@Stefano Borini: FWIW at least you seem to have plenty of rays. I still would recommend to keep all your 'permanent' points in array and write such code which let numpy to handle the temporaries, i.e. minimize the need to create small numpy arrays. Good luck! Thanks –  eat Jul 3 '11 at 11:54
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