2

I'm in need of a method to quickly return the number of differences between two large lists. The contents of each list item is either 1 or 0 (single integers), and the amount of items in each list will always be 307200.

This is a sample of my current code:

list1 = <list1> # should be a list of integers containing 1's or 0's
list2 = <list2> # same rule as above, in a slightly different order

diffCount = 0
for index, item in enumerate(list1):
    if item != list2[index]:
        diffCount += 1

percent = float(diffCount) / float(307200)

The above works but it is way too slow for my purposes. What I would like to know is if there is a quicker way to obtain the number of differences between lists, or the percentage of items that differ?

I have looked at a few similar threads on this site but they all seem to work slightly different from what I want, and the set() examples don't seem to work for my purposes. :P

5
  • Don't think you can do any better with ints. If they were bytes, you could XOR them but I don't see how you can get better performance out of ints.
    – user684934
    Apr 4, 2011 at 4:14
  • @bdares, ty for your reply. Would it help if they were strings instead of int? the characters and list order when comparing are what's important here really.
    – AWainb
    Apr 4, 2011 at 4:19
  • Should the 6th line be if item != list2[index]? I'm not sure where i comes from.
    – hwiechers
    Apr 4, 2011 at 4:24
  • @bdares, it was a typo, list2[i] should have been list2[index], naturally ;)
    – AWainb
    Apr 4, 2011 at 4:27
  • @hwiechers you're right. it's a typo.
    – smessing
    Apr 4, 2011 at 4:30

6 Answers 6

10

You can get at least another 10X speedup if you use NumPy arrays instead of lists.

import random
import time
import numpy as np
list1 = [random.choice((0,1)) for x in xrange(307200)]
list2 = [random.choice((0,1)) for x in xrange(307200)]
a1 = np.array(list1)
a2 = np.array(list2)

def foo1():
    start = time.clock()
    counter = 0
    for i in xrange(307200):
        if list1[i] != list2[i]:
            counter += 1
    print "%d, %f" % (counter, time.clock()-start)

def foo2():
    start = time.clock()
    ct = np.sum(a1!=a2)
    print "%d, %f" % (ct, time.clock()-start)
    
foo1() #153490, 0.096215
foo2() #153490, 0.010224
9
  • On my machine, it's about three times faster to XOR them, np.sum(a1 ^ a2)
    – Jay P.
    Apr 4, 2011 at 5:19
  • @Jeff The OP should be able to change their code to always use arrays instead of Python lists, then you don't need to worry about the time taken to convert a list to an array via np.array()
    – Jay P.
    Apr 4, 2011 at 5:24
  • @Paul, thank you for your suggestion. You are correct, the numpy.array does work much faster than a list. The problen is that the conversion from list to numpy array has to be taken into consideration as well. When I add a1 = np.array(list1) & a2 = np.array(list2) to your foo function after start, then total time averages much higher: 0.199788, 0.165243, 0.164008, etc. It ends up doubling the time from my original example. :(
    – AWainb
    Apr 4, 2011 at 6:24
  • @Jay P, I will try your mod in a sec.
    – AWainb
    Apr 4, 2011 at 6:26
  • 1
    @AWainb. ImageCore objects translate very well to Numpy arrays. I do it all the time. (I even did so in the answer to your originating post) They both use the same buffer structure and translation is nearly instant. Just do something like: np.array(img)
    – Paul
    Apr 4, 2011 at 12:07
4

If possible, use Paul/JayP's answer of using numpy (with xor), if you can only use python's stdlib, itertools' izip in a list comprehension seems the fastest:

import random
import time
import numpy
import itertools
list1 = [random.choice((0,1)) for x in xrange(307200)]
list2 = [random.choice((0,1)) for x in xrange(307200)]
a1 = numpy.array(list1)
a2 = numpy.array(list2)

def given():
  diffCount = 0
  for index, item in enumerate(list1):
      if item != list2[index]:
          diffCount += 1
  return diffCount

def xrange_iter():
  counter = 0
  for i in xrange(len(list1)):
    if list1[i] != list2[i]:
      counter += 1
  return counter

def np_not_eq():
  return numpy.sum(a1!=a2)

def np_xor():
  return numpy.sum(a1^a2)

def np_not_eq_plus_array():
  arr1 = numpy.array(list1)
  arr2 = numpy.array(list2)
  return numpy.sum(arr1!=arr2)

def np_xor_plus_array():
  arr1 = numpy.array(list1)
  arr2 = numpy.array(list2)
  return numpy.sum(arr1^arr2)

def enumerate_comprehension():
  return len([0 for i,x in enumerate(list1) if x != list2[i]])

def izip_comprehension():
  return len([0 for a,b in itertools.izip(list1, list2) if a != b])

def zip_comprehension():
  return len([0 for a,b in zip(list1, list2) if a != b])

def functional():
  return sum(map(lambda (a,b): a^b, zip(list1,list2)))

def bench(func):
  diff = []
  for i in xrange(100):
    start = time.clock()
    result = func()
    stop = time.clock()
    diff.append(stop - start)
  print "%25s -- %d, %f" % (func.__name__, result, sum(diff)/float(len(diff)))

bench(given)
bench(xrange_iter)
bench(np_not_eq)
bench(np_xor)
bench(np_not_eq_plus_array)
bench(np_xor_plus_array)
bench(enumerate_comprehension)
bench(zip_comprehension)
bench(izip_comprehension)
bench(functional)

I got this (on Python 2.7.1, Snow Leopard):

                    given -- 153618, 0.046746
              xrange_iter -- 153618, 0.049081
                np_not_eq -- 153618, 0.003069
                   np_xor -- 153618, 0.001869
     np_not_eq_plus_array -- 153618, 0.081671
        np_xor_plus_array -- 153618, 0.080536
  enumerate_comprehension -- 153618, 0.037587
        zip_comprehension -- 153618, 0.083983
       izip_comprehension -- 153618, 0.034506
               functional -- 153618, 0.117359
3
  • thank you for your effort but you also forgot to take into consideration the fact that the np.array(list) calls have to be included within the bench test. your examples are much higher once this has been added into the mix: given = 0.218102, xrange_iter = 0.217878, np_not_eq = 0.164513, np_xor = 0.161727, enumerate_comprehension = 0.216057, zip_comprehension = 0.302612, izip_comprehension = 0.211152. Please add the array creation to your bench function, and please note that list_comprehension, zip_iter, and izip_iter are misnamed. ;)
    – AWainb
    Apr 4, 2011 at 7:14
  • This is still a great example as it demonstrates quite a few methods to accomplish the same goals. :P One thing I noticed with my results is that the two np-based functions return a lower difference count (153163) than the rest (153476), any idea why?
    – AWainb
    Apr 4, 2011 at 7:33
  • @AWainb thanks for the corrections. I'ved fixed them (I hope). I didn't take np.array(list) into consideration since the conversion was expected to be a one-time operation, but only the ones that use the numpy should be penalized, not all the other ones. I've created two more numpy tests to show the performance hit np.array causes. I'm not a numpy expert, but if there is a float in the array, the entire array will be coerced to floats, which could cause some mismatches then.
    – Jeff
    Apr 4, 2011 at 8:03
0

I don't actually know if this is faster, but you might experiment with some of the "functional" methods python offers. It's usually better for loops to be run by internal, hand-coded subroutines.

Something like this:

diffCount = sum(map(lambda (a,b): a^b, zip(list1,list2)))
2
  • I just ran a test on this function but it unfortunately takes almost twice the time as @Amber's approach. Either way, thanks for the suggestion! :D
    – AWainb
    Apr 4, 2011 at 5:08
  • 1
    If possible rather use a built-in than a lambda. Using map(operator.xor, list1, list2) is about 1.7 times faster on my machine than the lambda version.
    – lafras
    Apr 4, 2011 at 12:48
0
>>> import random
>>> import time
>>> list1 = [random.choice((0,1)) for x in xrange(307200)]
>>> list2 = [random.choice((0,1)) for x in xrange(307200)]
>>> def foo():
...   start = time.clock()
...   counter = 0
...   for i in xrange(307200):
...     if list1[i] != list2[i]:
...       counter += 1
...   print "%d, %f" % (counter, time.clock()-start)
...
>>> foo()
153901, 0.068593

Is 7 hundredths of a second too slow for your application?

11
  • @Amber, I'll let you know in a couple of minutes, fair enough?? :P I know that sounds small but this code is being run between frames from my webcam. The longer it takes the comparison, the choppier the video gets. Out of curiosity, how does xrange differ from regular range?
    – AWainb
    Apr 4, 2011 at 4:39
  • xrange returns an “xrange object” instead of a list, and does not load data to the memory, the data is created only when needed, which makes a difference when a very large range is used on a memory-starved machine or when all of the range’s elements are never used. (from python docs)
    – P2bM
    Apr 4, 2011 at 4:52
  • @AWainb xrange() is an iterator, it doesn't create an actual list up-front like range() does. This means it doesn't need to allocate the large chunk of memory required, and in many cases can result in faster code.
    – Jay P.
    Apr 4, 2011 at 4:53
  • @Amber, ty for that explanation. tested it out using xrange instead of range, I probably should have copied my above code to properly reflect my code, in my version I use range already, after comparing xrange and range results they appear to be the same; that said, yes, apparently 7 hundredths of a second is too slow. :( basically I am capturing an image from my cam, compare to the previous image, than place the image within a wxPanel in my gui. Without the comparison code I have a live cam feed in my gui which updates each new frame perfectly.
    – AWainb
    Apr 4, 2011 at 4:59
  • 1
    @AWainb - You might be able to do threading if you didn't try to run your motion detection diff-ing between every single frame - instead, compare every, say, 10th frame.
    – Amber
    Apr 5, 2011 at 8:15
0

I would also try the following stdlib-only method:

import itertools as it, operator as op

def list_difference_count(list1, list2):
    return sum(it.starmap(op.ne, it.izip(list1, list2)))

>>> list_difference_count([1, 2, 3, 4], [1, 2, 1, 2])
2

This works correctly for len(list1) == len(list2). If you are sure that the list items are always integers, you can substitute op.xor for op.ne (could improve performance).

The percentage of difference is: float(list_difference_count(l1, l2))/len(l1).

0

list3 and list4 are equivalent. Different methods to get the same results

list_size=307200
list1=[random.choice([0,1]) for i in range(list_size)]
list2=[random.choice([0,1]) for i in range(list_size)]

list3=[]
for i in range(list_size):
    list3.append(list1[i]&list2[i])

#print(list3)
print(sum(list3)/list_size)

#or

list4=[x&y for (x,y) in list(zip(list1,list2))]
print(sum(list4)/list_size)
 

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