Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I am creating random Toeplitz matrices to estimate the probability that they are invertible. My current code is

import random
from scipy.linalg import toeplitz
import numpy as np
for n in xrange(1,25):
    rankzero = 0
    for repeats in xrange(50000):
        column = [random.choice([0,1]) for x in xrange(n)]
        row = [column[0]]+[random.choice([0,1]) for x in xrange(n-1)]
        matrix = toeplitz(column, row)
        if  (np.linalg.matrix_rank(matrix) < n):
            rankzero += 1
    print n, (rankzero*1.0)/50000

Can this be sped up?

I would like to increase the value 50000 to get more accuracy but it is too slow to do so currently.

Profiling using only for n in xrange(10,14) shows

  400000    9.482    0.000    9.482    0.000 {numpy.linalg.lapack_lite.dgesdd}
  4400000    7.591    0.000   11.089    0.000 random.py:272(choice)
   200000    6.836    0.000   10.903    0.000 index_tricks.py:144(__getitem__)
        1    5.473    5.473   62.668   62.668 toeplitz.py:3(<module>)
   800065    4.333    0.000    4.333    0.000 {numpy.core.multiarray.array}
   200000    3.513    0.000   19.949    0.000 special_matrices.py:128(toeplitz)
   200000    3.484    0.000   20.250    0.000 linalg.py:1194(svd)
6401273/6401237    2.421    0.000    2.421    0.000 {len}
   200000    2.252    0.000   26.047    0.000 linalg.py:1417(matrix_rank)
  4400000    1.863    0.000    1.863    0.000 {method 'random' of '_random.Random' objects}
  2201015    1.240    0.000    1.240    0.000 {isinstance}
[...]
share|improve this question

3 Answers 3

up vote 3 down vote accepted

One way is to save some work from repeated calling of toeplitz() function by caching the indexes where the values are being put. The following code is ~ 30% faster than the original code. The rest of the performance is in the rank calculation... And I don't know whether there exists a faster rank calculation for toeplitz matrices with 0s and 1s.

(update) The code is actually ~ 4 times faster if you replace matrix_rank by scipy.linalg.det() == 0 (determinant is faster then rank calculation for small matrices)

import random
from scipy.linalg import toeplitz, det
import numpy as np,numpy.random

class si:
    #cache of info for toeplitz matrix construction
    indx = None
    l = None

def xtoeplitz(c,r):
    vals = np.concatenate((r[-1:0:-1], c))
    if si.indx is None or si.l != len(c):
        a, b = np.ogrid[0:len(c), len(r) - 1:-1:-1]
        si.indx = a + b
        si.l = len(c)
    # `indx` is a 2D array of indices into the 1D array `vals`, arranged so
    # that `vals[indx]` is the Toeplitz matrix.
    return vals[si.indx]

def doit():
    for n in xrange(1,25):
        rankzero = 0
        si.indx=None

        for repeats in xrange(5000):

            column = np.random.randint(0,2,n)
            #column=[random.choice([0,1]) for x in xrange(n)] # original code

            row = np.r_[column[0], np.random.randint(0,2,n-1)]
            #row=[column[0]]+[random.choice([0,1]) for x in xrange(n-1)] #origi

            matrix = xtoeplitz(column, row)
            #matrix=toeplitz(column,row) # original code

            #if  (np.linalg.matrix_rank(matrix) < n): # original code
            if  np.abs(det(matrix))<1e-4: # should be faster for small matrices
                rankzero += 1
        print n, (rankzero*1.0)/50000
share|improve this answer
    
Thanks very much. Do you have any idea when rank becomes quicker than det by any chance? A very small thing, the 5000 should match the 50000 at the bottom. –  marshall Apr 30 '13 at 19:13
    
det() vs rank() -- it may depend on your CPU. I just suggest to do a small test %timeit det(np.random.randint(0,2,size=(25,25)) vs %timeit matrix_rank(np.random.randint(0,2,size=(25,25)) Regarding 5000 vs 50000, I intentionally made it smaller for easier testing –  sega_sai Apr 30 '13 at 19:18
    
det(np.random.randint(0,2,size=(25,25))) is about 42 us and matrix_rank(np.random.randint(0,2,size=(25,25))) is about 190 us. Pretty clear. –  marshall Apr 30 '13 at 19:24

These two lines that build the lists of 0s and 1s:

column = [random.choice([0,1]) for x in xrange(n)]
row = [column[0]]+[random.choice([0,1]) for x in xrange(n-1)]

have a number of inefficiences. They build, expand, and discard lots of lists unnecessarily, and they call random.choice() on a list to get what's really just one random bit. I sped them up by about 500% like this:

column = [0 for i in xrange(n)]
row = [0 for i in xrange(n)]

# NOTE: n must be less than 32 here, or remove int() and lose some speed
cbits = int(random.getrandbits(n))
rbits = int(random.getrandbits(n))

for i in xrange(n):
    column[i] = cbits & 1
    cbits >>= 1
    row[i] = rbits & 1
    rbits >>= 1

row[0] = column[0]
share|improve this answer

It looks like your original code is calling the lapack routine dgesdd to solve a linear system by first computing an LU decomposition of the input matrix.

Replacing matrix_rank with det computes the determinant using lapack's dgetrf, which computes only the LU decomposition of the input matrix (http://docs.scipy.org/doc/numpy/reference/generated/numpy.linalg.det.html).

The asymptotic complexity of both of the matrix_rank and det calls are therefore O(n^3), the complexity of LU decomposition.

Toepelitz systems, however, can be solved in O(n^2) (according to Wikipedia). So, if you want to run your code on large matrices, it would make sense to write a python extension to call a specialized library.

share|improve this answer
    
That's a very good point! –  marshall Apr 30 '13 at 20:38

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.