5

In the past I have faced myself dealing with averaging two paired lists and I have used the answers provided there successfully.

However with large (more than 20,000) items the procedure is somewhat slow, and I was wondering if using NumPy would make it faster.

I start from two lists, one of floats and one of strings:

names = ["a", "b", "b", "c", "d", "e", "e"]
values = [1.2, 4.5, 4.3, 2.0, 5.67, 8.08, 9.01]

I'm trying to calculate the mean of the identical values, so that after applying it, I'd get:

result_names = ["a", "b", "c", "d", "e"]
result_values = [1.2, 4.4, 2.0, 5.67, 8.54]

I put two lists as a result example, but having also a list of (name, value) tuples would suffice:

result = [("a", 1.2), ("b", 4.4), ("d", 5.67), ("e", 8.54)]

What's the best way to do this with NumPy?

4 Answers 4

4

With numpy you can write something yourself, or you can use groupby functionality (the rec_groupby function from matplotlib.mlab, but which is much slower. For more powerful groupby functionality, maybe look at pandas), and I compared it with the answer of Michael Dunn with a dictionary:

import numpy as np
import random
from matplotlib.mlab import rec_groupby

listA = [random.choice("abcdef") for i in range(20000)]
listB = [20 * random.random() for i in range(20000)]

names = np.array(listA)
values = np.array(listB)

def f_dict(listA, listB):
    d = {}

    for a, b in zip(listA, listB):
        d.setdefault(a, []).append(b)

    avg = []
    for key in d:
        avg.append(sum(d[key])/len(d[key]))

    return d.keys(), avg

def f_numpy(names, values):
    result_names = np.unique(names)
    result_values = np.empty(result_names.shape)

    for i, name in enumerate(result_names):
        result_values[i] = np.mean(values[names == name])

    return result_names, result_values     

This is the result for the three:

In [2]: f_dict(listA, listB)
Out[2]: 
(['a', 'c', 'b', 'e', 'd', 'f'],
 [9.9003182717213765,
  10.077784850173568,
  9.8623915728699636,
  9.9790599744319319,
  9.8811096512807097,
  10.118695410115953])

In [3]: f_numpy(names, values)
Out[3]: 
(array(['a', 'b', 'c', 'd', 'e', 'f'], 
      dtype='|S1'),
 array([  9.90031827,   9.86239157,  10.07778485,   9.88110965,
         9.97905997,  10.11869541]))

In [7]: rec_groupby(struct_array, ('names',), (('values', np.mean, 'resvalues'),))
Out[7]: 
rec.array([('a', 9.900318271721376), ('b', 9.862391572869964),
       ('c', 10.077784850173568), ('d', 9.88110965128071),
       ('e', 9.979059974431932), ('f', 10.118695410115953)], 
      dtype=[('names', '|S1'), ('resvalues', '<f8')])

And it seems that numpy is a little bit faster for this test (and the pre-defined groupby function much slower):

In [32]: %timeit f_dict(listA, listB)
10 loops, best of 3: 23 ms per loop

In [33]: %timeit f_numpy(names, values)
100 loops, best of 3: 9.78 ms per loop

In [8]: %timeit rec_groupby(struct_array, ('names',), (('values', np.mean, 'values'),))
1 loops, best of 3: 203 ms per loop
4
  • So it sounds like numpy is worth it: if your script does this 150 times the dict solution would cause a ~2 second delay. Oct 17, 2011 at 8:48
  • 1
    But a remark, in the timings I didn't count the conversion of the list to the numpy array. And this may compensate the little time gain with numpy (I tested it in the above case, and then f_numpy has almost the same speed: 19.3 ms). So maybe it depends on whether you have to convert the list to a numpy array each time.
    – joris
    Oct 17, 2011 at 8:58
  • As far as my tests go, I don't see an impact that large towards the conversion list -> array, but admittedly I haven't run comprehensive comparisons between the two versions.
    – Einar
    Oct 17, 2011 at 9:21
  • The Numpy way is actually way slower, by orders of magnitude, if you increase the number of unique keys. Your example only has 6 unique keys. When there are more, f_dict beats numpy way out of the water.
    – johnzilla
    Apr 25, 2017 at 18:26
3

Maybe a numpy solution is more elaborate than you need. Without doing anything fancy, I found the following to be "quick as a flash" (as in, there was no noticable wait with 20000 items in the list):

import random

listA = [random.choice("abcdef") for i in range(20000)]
listB = [20 * random.random() for i in range(20000)]

d = {}

for a, b in zip(listA, listB):
    d.setdefault(a, []).append(b)

for key in d:
    print key, sum(d[key])/len(d[key])

Your milage might vary, depending on whether 20000 is a typical length for your lists, and whether you do this only a couple of times in a script or whether you're doing it hundreds/thousands of times.

1
  • I should have mentioned it, you're right: I'm doing this for about 150 times and the average length is around 20K.
    – Einar
    Oct 17, 2011 at 8:17
1

A simple solution via numpy, assuming vA0 and vB0 as numpy.arrays, which are indexed by vA0.

import numpy as np

def avg_group(vA0, vB0):
    vA, ind, counts = np.unique(vA0, return_index=True, return_counts=True) # get unique values in vA0
    vB = vB0[ind]
    for dup in vB[counts>1]: # store the average (one may change as wished) of original elements in vA0 reference by the unique elements in vB
        vB[np.where(vA==dup)] = np.average(vB0[np.where(vA0==dup)])
    return vA, vB
1
  • This can be cleaned up a bit, but unique seems like the simplest method here. Mar 11, 2020 at 17:13
0

Somewhat late to the party, but seeing as numpy still seems to lack this feature, here is my best attempt at a pure numpy solution to achieve a grouping by key. It should be far faster than the other proposed solutions for problem sets of appreciable size. The crux here is the nifty reduceat functionality.

import numpy as np

def group(key, value):
    """
    group the values by key
    returns the unique keys, their corresponding per-key sum, and the keycounts
    """
    #upcast to numpy arrays
    key = np.asarray(key)
    value = np.asarray(value)
    #first, sort by key
    I = np.argsort(key)
    key = key[I]
    value = value[I]
    #the slicing points of the bins to sum over
    slices = np.concatenate(([0], np.where(key[:-1]!=key[1:])[0]+1))
    #first entry of each bin is a unique key
    unique_keys = key[slices]
    #sum over the slices specified by index
    per_key_sum = np.add.reduceat(value, slices)
    #number of counts per key is the difference of our slice points. cap off with number of keys for last bin
    key_count = np.diff(np.append(slices, len(key)))
    return unique_keys, per_key_sum, key_count


names = ["a", "b", "b", "c", "d", "e", "e"]
values = [1.2, 4.5, 4.3, 2.0, 5.67, 8.08, 9.01]

unique_keys, per_key_sum, key_count = group(names, values)
print per_key_sum / key_count

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