I have already written the following piece of code, which does exactly what I want, but it goes way too slow. I am certain that there is a way to make it faster, but I cant seem to find how it should be done. The first part of the code is just to show what is of which shape.
two images of measurements (
VV simulated and
HH simulated, which both depend on 3 parameters (precomputed for
(101, 31, 11) values)
the index 2 is just to put the
HH images in the same ndarray, instead of making two 3darrays
VV1 = numpy.ndarray((54, 43)).flatten() HH1 = numpy.ndarray((54, 43)).flatten() precomp = numpy.ndarray((101, 31, 11, 2))
two of the three parameters we let vary
comp = numpy.zeros((len(parameter1), len(parameter2))) for i,(vv,hh) in enumerate(zip(VV1,HH1)): comp0 = numpy.zeros((len(parameter1),len(parameter2))) for j in range(len(parameter1)): for jj in range(len(parameter2)): comp0[j,jj] = numpy.min((vv-precomp[j,jj,:,0])**2+(hh-precomp[j,jj,:,1])**2) comp+=comp0
The obvious thing i know i should do is get rid of as many for-loops as I can, but I don't know how to make the
numpy.min behave properly when working with more dimensions.
A second thing (less important if it can get vectorized, but still interesting) i noticed is that it takes mostly CPU time, and not RAM, but i searched a long time already, but i cant find a way to write something like "parfor" instead of "for" in matlab, (is it possible to make an
@parallel decorator, if i just put the for-loop in a separate method?)
edit: in reply to Janne Karila: yeah that definately improves it a lot,
for (vv,hh) in zip(VV1,HH1): comp+= numpy.min((vv-precomp[...,0])**2+(hh-precomp[...,1])**2, axis=2)
Is definitely a lot faster, but is there any possibility to remove the outer for-loop too? And is there a way to make a for-loop parallel, with an
@parallel or something?