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I would like to speed up this short piece of code

      max_x=array([max(x[(id==dummy)]) for dummy in ids])

x and id are numpy arrays of the same dimensions and ids is an array of smaller dimension. What is the fast way to do it using vectorial operation?

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you're right, thanks for the comments. maybe I should rephrase my question because what I'm most interested in is to speed up my code –  Matteo Aug 15 '12 at 10:18
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3 Answers

up vote 3 down vote accepted

This is not easy to do vectorize further (as far as I see), unless id has some structure. Otherwise a bottleneck might be doing id==dummy often, but the only solution I can think of would be the use of sorting, and due to the lack of a reduce functionality for np.max() still requires quite a bit of python code (Edit: There actually is a reduce function through np.fmax available). This is about 3x faster for a x being 1000x1000 and id/ids being in 0..100, but as its rather complex, its only worth it for larger problems with many ids:

def max_at_ids(x, id, ids):
    # create a 1D view of x and id:
    r_x = x.ravel()
    r_id = id.ravel()
    sorter = np.argsort(r_id)

    # create new sorted arrays:
    r_id = r_id[sorter]; r_x = r_x[sorter]

    # unfortunatly there is no reduce functionality for np.max...

    ids = np.unique(ids) # create a sorted, unique copy, just in case

    # w gives the places where the sorted arrays id changes:
    w = np.where(r_id[:-1] != r_id[1:])[0] + 1

I originally offered this solution which does a pure python loop over the slices, but below is a shorter (and faster) version:

    # The result array:
    max_x = np.empty(len(ids), dtype=r_x.dtype)
    start_idx = 0; end_idx = w[0]
    i_ids = 0
    i_w = 0

    while i_ids < len(ids) and i_w < len(w) + 1:
        if ids[i_ids] == r_id[start_idx]:
            max_x[i_ids] = r_x[start_idx:end_idx].max()
            i_ids += 1
            i_w += 1
        elif ids[i_ids] > r_id[start_idx]:
            i_w += 1
        else:
            i_ids += 1
            continue # skip updating start_idx/end_idx

        start_idx = end_idx
        # Set it to None for the last slice (might be faster to do differently)
        end_idx = w[i_w] if i_w < len(w) else None

    return ids, max_x

EDIT: improved version for calculation of the maxium for each slice:

There is a way to remove the python loop by the use of np.fmax.reduceat, which might outperform the previous one a lot if the slices are small (and is actually quite elgant):

# just to 0 at the start of w
# (or calculate first slice by hand and use out=... keyword argument to avoid even
# this copy.
w = np.concatenate(([0], w))
max_x = np.fmin.reduceat(r_x, w)
return ids, max_x

Now there are probably some small things where it is possible to make this a little faster. If id/ids has some structure it should be possible to simplify the code, and maybe use a different approach to achieve a much larger speedup. Otherwise the speedup of this code should be large, as long as there are many (unique) ids (and x/id arrays are not very small). Note that the code enforces np.unique(ids), which is probably a good assumption though.

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Thanks for you answer! It's been extremely useful. It speeds up the calculation by roughly 98%. –  Matteo Aug 15 '12 at 14:08
    
Edited the answer to include a shorter/faster version by using np.fmax.reduceat to avoid the python loop over all slices. –  seberg Aug 22 '12 at 13:34
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Using x[(id==dummy)].max() instead of the built-in max should give some speed-up.

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Great suggestion, but that speed up my calculation of only 2%. It is really the only possible way? –  Matteo Aug 15 '12 at 11:29
    
Probably not, let's hope someone else chimes in. –  Janne Karila Aug 15 '12 at 11:36
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scipy.ndimage.maximumdoes exactly that:

import numpy as np
from scipy import ndimage as nd

N = 100  # number of values
K = 10   # number of class

# generate random data
x   = np.random.rand(N)
ID  = np.random.randint(0,K,N)  # random id class for each xi's
ids = np.random.randint(0,K,5)  # select 5 random class

# do what you ask
max_per_id = nd.maximum(x,labels=ID,index=ids)

print dict(zip(ids,max_per_id))

If you want to compute the max for all ids, do ids = ID

Note that if a particular class in ids is not found in ID(i.e. no x is labeled by that class) then the maximum return for that class is 0.

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