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I'm using python to do some Bayesian statistics. I've coded it up in python and in Fortran 95. The Fortran code is waaay faster... like a factor of 100. I expected the Fortran to be faster, but I was really hoping that by using numpy I could get the python code to come close, maybe within a factor of 2. I've profiled the python code and it looks like the majority of the time is spent doing the following things:

scipy.stats.rvs: taking a random draw from a distribution. I do this ~19000 times and it takes a total time of 3.552 sec

numpy.slogdet: computing the log of the determinant of a matrix. I do this ~10,000 and it takes a total of 2.48 s

numpy.solve: solve a linear system: I call this routine ~10,000 times for a total time of 2.557 s

In total my code runs in ~ 11 sec whereas my fortran code takes .092 sec. Is this a joke? I'm really not trying to be unrealistic in my expectations of python, and I certainly don't expect to get my python code to be as fast as Fortran.. but to be slower by a factor of > 100.. Python's gotta be able to do better than that. Just in case you are curious, here is the full output of my profiler:( I don't know why it broke the text into several blocks)

     1290611 function calls in 11.296 CPU seconds

Ordered by: internal time, function name

ncalls  tottime  percall  cumtime  percall filename:lineno(function)

18973    0.864    0.000    3.552    0.000 /usr/lib64/python2.6/site-packages/scipy/stats/distributions.py:484(rvs)
 9976    0.819    0.000    2.480    0.000 /usr/lib64/python2.6/site-packages/numpy/linalg/linalg.py:1559(slogdet)
 9976    0.627    0.000    6.659    0.001 /bluehome/legoses/bce/bayes_GP_integrated_out/python/ce_funcs.py:77(evaluate_posterior)
 9384    0.591    0.000    0.753    0.000 /bluehome/legoses/bce/bayes_GP_integrated_out/python/ce_funcs.py:39(construct_R_matrix)
77852    0.533    0.000    0.533    0.000 :0(array)
37946    0.520    0.000    1.489    0.000 /usr/lib64/python2.6/site-packages/numpy/core/fromnumeric.py:32(_wrapit)
77851    0.423    0.000    0.956    0.000 /usr/lib64/python2.6/site-packages/numpy/core/numeric.py:216(asarray)
37946    0.360    0.000    0.360    0.000 :0(all)
 9976    0.335    0.000    2.557    0.000 /usr/lib64/python2.6/sitepackages/scipy/linalg/basic.py:23(solve)
107799    0.322    0.000    0.322    0.000 :0(len)

109740    0.301    0.000    0.301    0.000 :0(issubclass)

28357    0.294    0.000    0.294    0.000 :0(prod)
 9976    0.287    0.000    0.957    0.000 /usr/lib64/python2.6/site-packages/scipy/linalg/lapack.py:45(find_best_lapack_type)
    1    0.282    0.282   11.294   11.294 /bluehome/legoses/bce/bayes_GP_integrated_out/python/ce_funcs.py:199(get_rho_lambda_draws)
 9976    0.269    0.000    1.386    0.000 /usr/lib64/python2.6/site-packages/scipy/linalg/lapack.py:60(get_lapack_funcs)
19952    0.263    0.000    0.476    0.000 /usr/lib64/python2.6/site-packages/scipy/linalg/lapack.py:23(cast_to_lapack_prefix)
19952    0.235    0.000    0.669    0.000 /usr/lib64/python2.6/site-packages/numpy/lib/function_base.py:483(asarray_chkfinite)
66833    0.212    0.000    0.212    0.000 :0(log)
18973    0.207    0.000    1.054    0.000 /usr/lib64/python2.6/site-packages/numpy/core/fromnumeric.py:1427(product)
29931    0.205    0.000    0.205    0.000 :0(reduce)
28949    0.187    0.000    0.856    0.000 :0(map)
 9976    0.175    0.000    0.175    0.000 :0(dot)
47922    0.163    0.000    0.163    0.000 :0(getattr)
 9976    0.157    0.000    0.206    0.000 /usr/lib64/python2.6/site-packages/numpy/lib/twodim_base.py:169(eye)
19952    0.154    0.000    0.271    0.000 /bluehome/legoses/bce/bayes_GP_integrated_out/python/ce_funcs.py:32(loggbeta)
18973    0.151    0.000    0.793    0.000 /usr/lib64/python2.6/site-packages/numpy/core/fromnumeric.py:1548(all)
19953    0.146    0.000    0.146    0.000 :0(any)
 9976    0.142    0.000    0.316    0.000 /usr/lib64/python2.6/site-packages/numpy/linalg/linalg.py:99(_commonType)
 9976    0.133    0.000    0.133    0.000 :0(dgetrf)
18973    0.125    0.000    0.175    0.000 /usr/lib64/python2.6/site-packages/scipy/stats/distributions.py:462(_fix_loc_scale)
39904    0.117    0.000    0.117    0.000 :0(append)
18973    0.105    0.000    0.292    0.000 /usr/lib64/python2.6/site-packages/numpy/core/fromnumeric.py:1461(alltrue)
19952    0.102    0.000    0.102    0.000 :0(zeros)
19952    0.093    0.000    0.154    0.000 /usr/lib64/python2.6/site-packages/numpy/linalg/linalg.py:71(isComplexType)
19952    0.090    0.000    0.090    0.000 :0(split)
 9976    0.089    0.000    2.569    0.000 /bluehome/legoses/bce/bayes_GP_integrated_out/python/ce_funcs.py:62(get_log_determinant_of_matrix)
19952    0.087    0.000    0.134    0.000 /bluehome/legoses/bce/bayes_GP_integrated_out/python/ce_funcs.py:35(logggamma)
 9976    0.083    0.000    0.154    0.000 /usr/lib64/python2.6/site-packages/numpy/linalg/linalg.py:139(_fastCopyAndTranspose)
 9976    0.076    0.000    0.125    0.000 /usr/lib64/python2.6/site-packages/numpy/linalg/linalg.py:157(_assertSquareness)
 9976    0.074    0.000    0.097    0.000 /usr/lib64/python2.6/site-packages/numpy/linalg/linalg.py:151(_assertRank2)
 9976    0.072    0.000    0.119    0.000 /usr/lib64/python2.6/site-packages/numpy/linalg/linalg.py:127(_to_native_byte_order)
18973    0.072    0.000    0.072    0.000 /usr/lib64/python2.6/site-packages/scipy/stats/distributions.py:832(_argcheck)
 9976    0.072    0.000    0.228    0.000 /usr/lib64/python2.6/site-packages/numpy/core/fromnumeric.py:901(diagonal)
 9976    0.070    0.000    0.070    0.000 :0(arange)
 9976    0.061    0.000    0.061    0.000 :0(diagonal)
 9976    0.055    0.000    0.055    0.000 :0(sum)
 9976    0.053    0.000    0.075    0.000 /usr/lib64/python2.6/site-packages/numpy/linalg/linalg.py:84(_realType)
11996    0.050    0.000    0.091    0.000 /usr/lib64/python2.6/site-packages/scipy/stats/distributions.py:1412(_rvs)
 9384    0.047    0.000    0.162    0.000 /usr/lib64/python2.6/site-packages/numpy/core/fromnumeric.py:1898(prod)
 9976    0.045    0.000    0.045    0.000 :0(sort)
11996    0.041    0.000    0.041    0.000 :0(standard_normal)
 9976    0.037    0.000    0.037    0.000 :0(_fastCopyAndTranspose)
 9976    0.037    0.000    0.037    0.000 :0(hasattr)
 9976    0.037    0.000    0.037    0.000 :0(range)
 6977    0.034    0.000    0.055    0.000 /usr/lib64/python2.6/site-packages/scipy/stats/distributions.py:3731(_rvs)
 9977    0.027    0.000    0.027    0.000 :0(max)
 9976    0.023    0.000    0.023    0.000 /usr/lib64/python2.6/site-packages/numpy/core/numeric.py:498(isfortran)
 9977    0.022    0.000    0.022    0.000 :0(min)
 9976    0.022    0.000    0.022    0.000 :0(get)
 6977    0.021    0.000    0.021    0.000 :0(uniform)
    1    0.001    0.001   11.295   11.295 <string>:1(<module>)
    1    0.001    0.001   11.296   11.296 profile:0(get_rho_lambda_draws(correlations,energies,rho_priors,lambda_e_prior,lambda_z_prior,candidate_sig2_rhos,candidate_sig2_lambda_e,candidate_sig2_lambda_z,3000))
    2    0.000    0.000    0.000    0.000 /usr/lib64/python2.6/site-packages/numpy/core/arrayprint.py:445(__call__)
    1    0.000    0.000    0.000    0.000 /usr/lib64/python2.6/site-packages/numpy/core/arrayprint.py:385(__init__)
    1    0.000    0.000    0.000    0.000 /usr/lib64/python2.6/site-packages/numpy/core/arrayprint.py:175(_array2string)
    2    0.000    0.000    0.000    0.000 /usr/lib64/python2.6/site-packages/numpy/core/arrayprint.py:475(_digits)
    2    0.000    0.000    0.000    0.000 /usr/lib64/python2.6/site-packages/numpy/core/arrayprint.py:309(_extendLine)
    1    0.000    0.000    0.000    0.000 /usr/lib64/python2.6/site-packages/numpy/core/arrayprint.py:317(_formatArray)
    1    0.000    0.000    0.000    0.000 /usr/lib64/python2.6/site-packages/numpy/core/fromnumeric.py:1477(any)
    1    0.000    0.000    0.000    0.000 /usr/lib64/python2.6/site-packages/numpy/core/arrayprint.py:243(array2string)
    1    0.000    0.000    0.000    0.000 /usr/lib64/python2.6/site-packages/numpy/core/numeric.py:1390(array_str)
    1    0.000    0.000    0.000    0.000 :0(compress)
    1    0.000    0.000    0.000    0.000 /usr/lib64/python2.6/site-packages/numpy/core/arrayprint.py:394(fillFormat)
    6    0.000    0.000    0.000    0.000 /usr/lib64/python2.6/site-packages/numpy/core/numeric.py:2166(geterr)
   12    0.000    0.000    0.000    0.000 :0(geterrobj)
    0    0.000             0.000          profile:0(profiler)
    1    0.000    0.000    0.000    0.000 /usr/lib64/python2.6/site-packages/numpy/core/fromnumeric.py:1043(ravel)
    1    0.000    0.000    0.000    0.000 :0(ravel)
    8    0.000    0.000    0.000    0.000 :0(rstrip)
    6    0.000    0.000    0.000    0.000 /usr/lib64/python2.6/site-packages/numpy/core/numeric.py:2070(seterr)
    6    0.000    0.000    0.000    0.000 :0(seterrobj)
    1    0.000    0.000    0.000    0.000 :0(setprofile)

EDIT:

Here is copy of the relevant routines

def get_rho_lambda_draws(correlations, energies, rho_priors, lam_e_prior, lam_z_prior,  
                         candidate_sig2_rhos, candidate_sig2_lambda_e, 
                         candidate_sig2_lambda_z, ndraws):

    nBasis = len(correlations[0])
    nStruct = len(correlations)

    rho _draws = [ [0.5 for x in xrange(nBasis)] for y in xrange(ndraws)]
    lambda_e_draws = [ 5 for x in xrange(ndraws)]
    lambda_z_draws = [ 5 for x in xrange(ndraws)]
            
    accept_rhos = array([0. for x in xrange(nBasis)])
    accept_lambda_e = 0.
    accept_lambda_z = 0.

    for i in xrange(1,ndraws):
        if i % 100 == 0:
            print i, "REP<---------------------------------------------------------------------------------"
        #do metropolis to get rho
        rho_draws[i] = [x for x in rho_draws[i-1]]
        lambda_e_draws[i] = lambda_e_draws[i-1]
        lambda_z_draws[i] = lambda_z_draws[i-1]

        rho_vec = [x for x in rho_draws[i-1]]
        R_matrix_before =construct_R_matrix(correlations,correlations,rho_vec)
        post_before = evaluate_posterior(R_matrix_before,rho_vec,energies,lambda_e_draws[i-1],lambda_z_draws[i-1],lam_e_prior,lam_z_prior,rho_priors)

        index = 0
        for j in xrange(nBasis):
            cand = norm.rvs(rho_draws[i-1][j],scale=candidate_sig2_rhos[j])
            if 0.0 < cand < 1.0:
                rho_vec[j] = cand

                R_matrix_after = construct_R_matrix(correlations,correlations,rho_vec)
                post_after = evaluate_posterior(R_matrix_after,rho_vec,energies,lambda_e_draws[i-1],lambda_z_draws[i-1],lam_e_prior,lam_z_prior,rho_priors)
                metrop_value = post_after - post_before
                unif = log(uniform.rvs(0,1))
                if metrop_value > unif:
                    rho_draws[i][j] = cand
                    post_before = post_after
                    accept_rhos[j] += 1
                else:
                    rho_vec[j] = rho_draws[i-1][j]



        R_matrix = construct_R_matrix(correlations,correlations,rho_vec)
        cand = norm.rvs(lambda_e_draws[i-1],scale=candidate_sig2_lambda_e)
        if cand > 0.0:
            post_after = evaluate_posterior(R_matrix,rho_vec,energies,cand,lambda_z_draws[i-1],lam_e_prior,lam_z_prior,rho_priors)

            metrop_value = post_after - post_before
            unif = log(uniform.rvs(0,1))
            if metrop_value > unif:
                lambda_e_draws[i] = cand
                post_before = post_after
                accept_lambda_e = accept_lambda_e + 1


        cand = norm.rvs(lambda_z_draws[i-1],scale=candidate_sig2_lambda_z)
        if cand > 0.0:
            post_after = evaluate_posterior(R_matrix,rho_vec,energies,lambda_e_draws[i],cand,lam_e_prior,lam_z_prior,rho_priors)
            metrop_value = post_after - post_before
            unif = log(uniform.rvs(0,1))
            if metrop_value > unif:
                lambda_z_draws[i] = cand
                post_before = post_after
                accept_lambda_z = accept_lambda_z + 1


    print accept_rhos/ndraws
    print accept_lambda_e/ndraws
    print accept_lambda_z/ndraws
    return [rho_draws,lambda_e_draws,lambda_z_draws]


def evaluate_posterior(R_matrix,rho_vec,energies,lambda_e,lambda_z,lam_e_prior,lam_z_prior,rho_prior_params):

    #    from scipy.linalg import solve
    #from numpy import allclose

    working_matrix = eye(len(R_matrix))/lambda_e + R_matrix/lambda_z
    logdet = get_log_determinant_of_matrix(working_matrix)

    x = solve(working_matrix,energies,sym_pos=True)
    #    if not allclose(dot(working_matrix,x),energies):
#        exit('solve routine didnt work')

    rho_priors = sum([loggbeta(rho_vec[j],rho_prior_params[j][0],rho_prior_params[j][1]) for j in xrange(len(rho_vec))])

    loggposterior = -.5 * logdet - .5*dot(energies,x) + logggamma(lambda_e,lam_e_prior[0],lam_e_prior[1]) + logggamma(lambda_z,lam_z_prior[0],lam_z_prior[1]) + rho_priors #(a_e-1)*log(lambda_e) - b_e*lambda_e + (a_z-1)*log(lambda_z) - b_z*lambda_z + rho_priors
    return loggposterior

def construct_R_matrix(listone,listtwo,rhos):

    return prod(rhos[:]**(4*(listone[:,newaxis]-listtwo)**2),axis=2)

(Once again... I don't know why It breaks my input up into several blocks when I post.. I hope you can decifer it)

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2  
Could you post a snippet of the python code? –  marshall.ward Mar 19 '12 at 23:26
    
do you call scipy.stats.rvs and others inside the loop as global methods with actual dots . in the statements or did you assign it to local variables like rvs = scipy.stats.rvs? in newer Python versions this should be optimised, but in 2.6 i'm not sure, it might create a difference... –  deathApril Mar 19 '12 at 23:42
1  
there are two factors here: the code and the coder, without code it is difficult to say which one the main responsible is for the coder asthonishment. –  joaquin Mar 20 '12 at 0:17
    
Just a small comment in the beginning. You can definitely replace set of calls "cand = norm.rvs(..)" inside the loop over j by a single one "cands = norm.rvs(loc=rho_draws[i-1],scale=candidate_sig2_rhos)" that should save you at least some of the time spent in .rvs() –  sega_sai Mar 20 '12 at 3:55
1  
Can you add full link to the code that can be run? including the data. otherwise it's a bit useless. –  fijal Mar 20 '12 at 10:16
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5 Answers

Try doing this:

import psyco
psyco.full()

Or using pypy, these can sometimes yield significant speed improvements, although pypy doesn't have full numpy support yet.

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It is hard to tell exactly what's going on with your code, But my suspicion is that you just have some data which is not (or could not be) very vectorized. Because obviously the call of .rvs() 19000 times is going to be way slower than the .rvs(size=19000). See:

  In [5]: %timeit x=[scipy.stats.norm().rvs() for i in range(19000)]
  1 loops, best of 3: 1.23 s per loop

  In [6]: %timeit x=scipy.stats.norm().rvs(size=19000)
  1000 loops, best of 3: 1.67 ms per loop

So if you indeed have a not very vectorized code or algorithm it is well expected to be slower than fortran.

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Yeah.. The problem is that I can't just take 19000 draws because the center of the distribution shifts from iteration to iteration.. –  legoses Mar 20 '12 at 2:43
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Check out the performance page created by the SciPy/NumPy folks. There are a number of remarkably easy extras that foster very fast code. Among them are (a) using the weave module, especially the inline and blitz options. (b) Using Cython to write some of your functions in C but be able to call and use them in Python.

I do a lot of large-scale scientific computing work in Python for statistics, finance, and (in grad school) computer vision. The reason why Python is excellent for these kinds of issues is not that my naive, first hack code would yield the fastest solution, but because in Python I can easily interface with tons of other tasks. I can easily issue Linux commands for other programs, easily read and parse most data files, easily interface with SQL and other databse software; I have all of the R statistics library available, use of OpenCV commands (in much much nicer syntax that the C++ version), and much more.

When the importance of my task was to manipulate a new dataset and get my hands dirty, feeling out the nuances of that data, then Python's ease of programming, along with matplotlib, made it much better. Later on, when I need to scale things up, I can always use PyCUDA, Cython, or just rewrite things in C++ if high-end performance is required. Since most machines have multiprocessors now, the multiprocessing module, as well as mpi4py, allow me to quickly and cheaply turn annoying for-loop style tasks into much shorter tasks, without needing to migrate to C++.

In short, the real utility of Python doesn't come from the language all by itself, but from becoming really proficient with the add-ons and extras that let you cheaply make your little set of common problems execute quickly on the data sets that matter in the day-to-day.

Real-time embedded communications software is going to be using C++ for a long time to come... same for high-frequency trading strategies. But then again, professional solutions to these types of things is not really what Python is meant for. And in some cases, folks prefer unusual solutions for that stuff anyway.

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Well I'm not super experienced with python but so far I love it and want to use it for everything. The thing that baffles me here is that it seems like the speed bottlenecks are calls to numpy linear algebra routines, which I thought were basically calls to BLAS/LAPACK. That should be as fast as it gets right? p.s. to all, thanks for you speedy and insightful comments. I really appreciate the help –  legoses Mar 20 '12 at 2:46
    
it might be worth noting that SciPy performance page is quite a fair bit outdated. They don't compare identical algos (that does make a huge difference in my runs) and on ancient hardware (or just significantly different than mine new xeon) –  fijal Mar 20 '12 at 11:03
    
I'm happy to use f2py and cython if it will help.. But in my case, what would I convert to cython and fortran code?... The routines that are taking the longest are the calls to LAPACK/BLAS. That should be just as fast in python? right? –  legoses Mar 20 '12 at 13:34
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recently I posted something about the performance of c/c++/fortran and that of python on Stackoverflow:

comparing python with c/fortran

what I concluded from that post was that is better to combine python with a low level programming language than using python itself for numeric computations. I am actually using F2PY.

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Get rid of the two for loops and two list comprehensions by replacing them with Numpy functions and constructs that use numpy.ndarrays. Also do not print in between the computation - that is also slow. You can probably get 10-50 fold speed increase just by following the above advice.

Also see http://www.scipy.org/PerformancePython/

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