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The function scipy.optimize.fmin_bfgs allows the user to input both a target function and a gradient. Since I have an 8-core machine on my desktop, I thought I could parallelize the solver by running

from scipy import optimize
import itertools
import numpy as np

def single_grad_point((idx,px)):
    p = px.copy()
    epsilon = 10**(-6.0)
    p[idx] += epsilon
    d1 = err_func(p)
    p[idx] -= 2*epsilon
    d2 = err_func(p)
    return (d1-d2)/(2*epsilon)

def err_func_gradient(p):
    P = multiprocessing.Pool()   
    input_args = zip(*(xrange(len(p)), itertools.cycle((p,))))
    sol = P.imap(single_grad_point, input_args)
    return np.array(list(sol))

optimize.fmin_bfgs(err_func, p0, fprime=err_func_gradient)

In a nutshell, I'm using multiprocessing to compute each direction of the gradient. If the target function err_func is expensive, this seems to gain substantial speedup. My question however is about the usage and con/destruction of all the multiprocessing.Pools. Since it's possible that err_func_gradient can be called tens of thousands of times, will this cause a slowdown or leak somewhere?

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I've looked, but scipy does not seem to have a parallel non-linear optimizer. If I'm wrong, I'll take it as an answer instead. –  Hooked Jul 3 '13 at 19:07
    
Could you not create your multiprocessing.Pool once, then pass it as an additional argument to f and fprime? That way you could perhaps avoid the overhead involved with constructing/destroying pools on every iteration. –  ali_m Jul 9 '13 at 18:49
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