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Here is some code that I wrote using Python:

from math import sqrt
abundant_list = []

for i in range(12,28123+1):
    dividor_list = [1]
    for j in range(2, int(sqrt(i))+1):
        if i%j == 0:
            dividor_list.extend([i/j,j])
    if sum(dividor_list) > i:
        abundant_list.append(i)

print abundant_list

As you can see, the code is really trying to be efficient as much as possible.

There is any difference if I use list.append twice, or list.extend just once? I know it can be minor differences, but I would really like to know that :)

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3
  • 9
    If you'd like to know, measure.
    – NPE
    Jan 21, 2013 at 19:51
  • 1
    I would be pretty surprised if extend wasn't faster than 2 .appends
    – mgilson
    Jan 21, 2013 at 19:52
  • 1
    If I were to optimize this, I'd use the sieve of Eratosthenes to find primes up to sqrt(28123), then for each i, I'd factorize it and use itertools.product to get all ways to combine the factors into divisors, and finally sum those.
    – Lauritz V. Thaulow
    Jan 21, 2013 at 20:19

3 Answers 3

Reset to default
26 
import timeit

def append2x(foo):
    foo.append(1)
    foo.append(1)

def extend_lst(foo):
    foo.extend([1,1])

def extend_tup(foo):
    foo.extend((1,1))


l1 = []
l2 = []
l3 = []

print timeit.timeit('append2x(l1)',setup = 'from __main__ import append2x,l1')
print timeit.timeit('extend_lst(l2)',setup = 'from __main__ import extend_lst,l2')
print timeit.timeit('extend_tup(l3)',setup = 'from __main__ import extend_tup,l3')

Here's a simple benchmark. My results (os-X, 10.5.8, core2duo, FWIW):

0.520906925201  #append
0.602569103241  #extend-list
0.357008934021  #extend-tuple

And the same ordering of the results my linux box (Ubuntu, x86-64 core i7):

0.307395935059  #append
0.319436073303  #extend-list
0.238317012787  #extend-tuple

To me, this says that extend is quicker than append, but that creating a list is relatively expensive compared to creating a tuple

EDIT

Pointed out in the comments below, because of the immutability of tuples, the interpreter can optimize the creation of the tuple out (it creates the tuple once and re-uses it over and over). If we change the code to:

def extend_lst(foo):  
    v = 1
    foo.extend([v,v]) 

def extend_tup(foo):
    v = 1
    foo.extend((v,v))

The timings are virtually identical:

0.297003984451  #append
0.344678163528  #extend-list
0.292304992676  #extend-tuple

Although tuple still consistently beats the list version and barely edges out the append version for all of the trials I have done.

One thing that I'm taking away from this is that if you're iterating over an object that consists of all literals, choose a tuple over a list. If it doesn't consist entirely of literals, then it really doesn't matter whether you choose list or tuple.

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10
  • Well, just learned the "time.clock" function, and suprisingly, it's shows that extend is much slower... will edit my message
    – Yam Mesicka
    Jan 21, 2013 at 20:00
  • 5
    The tuple version is faster because the tuple you use is a literal and hence re-used (cf. the bytecode), so it doesn't have to be constructed again and again. Use variables (e.g. pass an object to append to all functions) and the difference will be reduced.
    – user395760
    Jan 21, 2013 at 20:02
  • 1
    Great answers guys, thanks. Always worth opening new question, always learning new stuff :)
    – Yam Mesicka
    Jan 21, 2013 at 20:05
  • @delnan -- Great catch! Although, tuple still edges it out after a few repeated runs.
    – mgilson
    Jan 21, 2013 at 20:05
  • 2
    @delnan -- I was working on it. I've added an edit explaining this stuff. I don't usually leave the poor timings in the answer, but in this case, I felt it was instructive to leave both versions to show how literal tuples are much faster than literal lists, but when using variables they're relatively close.
    – mgilson
    Jan 21, 2013 at 20:11
20

It is also worth pointing out that the answer to this question hinges on the small size of the list/tuple that is added on each iteration. For larger lists, extend is clearly superior (and lists vs tuples does not make a difference). Starting with mgilson's answer, I checked behaviour for collections with 600 items, rather than 2: Calling append 600 times takes 8 times as long as using extend() with a manually defined list/tuple (i.e. [v,v,v,v,v,v,v...]):

42.4969689846
5.45146393776
5.38034892082

The bulk of these five seconds is actually the list/tuple creation. Preparing it before the timeit call brings times for extend down to

1.42491698265
0.657584905624

for list and tuple, respectively.

For a more realistic (and fairer) case, one can dynamically generate the data within the function call:

import timeit

def append_loop(foo, reps):
    for i in range(reps):
        foo.append(i)

def append_comp(foo, reps):
    [foo.append(i) for i in range(reps)]

def extend_lst(foo, reps):
    foo.extend([i for i in range(reps)])

def extend_tup(foo, reps):
    foo.extend((i for i in range(reps)))

repetitions = 600

print timeit.timeit('append_loop([], repetitions)', setup='from __main__ import append_loop, repetitions')
print timeit.timeit('append_comp([], repetitions)', setup='from __main__ import append_comp, repetitions')
print timeit.timeit('extend_lst([], repetitions)', setup='from __main__ import extend_lst, repetitions')
print timeit.timeit('extend_tup([], repetitions)', setup='from __main__ import extend_tup, repetitions')

(Append is implemented both via for-loop and list comprehension to factor out efficiency differences between the two ways of looping.)

Timings are:

53.8211231232
57.1711571217
19.8829259872
28.5986201763

As we can see, extend with list comprehension is still over two times faster than appending. Also, tuple comprehension appears noticeably slower than list comprehension, and append_comp only introduces unnecessary list creation overhead.

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6
  • 4
    The later (extend_tup) is in fact a genexp and not a tuple, which explains the slowness.
    – yoch
    Nov 13, 2017 at 14:41
  • 1
    You're right about the output type, my mistake. However, I just tested tuple comprehension and it provides the same speed as the genexp. List comprehension is still faster. Obviously, if the tuple was precomputed the call would be faster, but the same is true for a precomputed list.
    – Marc Schulder
    Nov 14, 2017 at 15:39
  • 1
    Your benchmark is biased, because its include the time needed to built the lists and tuples. Without that, extending a list with a tuple is a bit faster (at least for me, using python 3.5).
    – yoch
    Dec 4, 2017 at 18:36
  • Your test is misleading and the proper test shows that append is the fastest method. Both appends tests that you used are appending an item at a time, but the extend() are for whole list. When I changed the code of the append_comp so the append is out of the comprehension list (as in the last 2 tests) the times are (in my tests on my slow machine using Jupyter lab interpreter) for the last 3 tests: 91, 104, 148 seconds respectfully.
    – Zvi
    Dec 26, 2020 at 7:34
  • @Zvi, I'm not sure what you find misleading. The original question asked whether using append multiple times is faster or slower than using extend once, so that code difference is by design. Your suggested change does not provide the correct result, as it would append the entire reps list as a single item, rather than appending the individual elements, i.e. you would get [[1,2,3...]] instead of [1,2,3...].
    – Marc Schulder
    Jan 4, 2021 at 16:16
0

They take exact same time.

Here is the time taken for your code:

With dividor_list.extend([i/j,j])

>>> 
0:00:00.410000
>>> 
0:00:00.383000
>>> 
0:00:00.389000

With dividor_list.append(i/j); dividor_list.append(j)

>>> 
0:00:00.400000
>>> 
0:00:00.390000
>>> 
0:00:00.381000
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4
  • 5
    You'll have to include your timing code, as that's easy to mess up. And since you apparently didn't use timeit, you'll have to justify not using timeit ;-)
    – user395760
    Jan 21, 2013 at 20:03
  • mgilson's benchmark suggests dividor_list.extend((i/j,j)) is more efficient than both because it doesn't create an intermediate list. Creating an intermediate tuple is cheaper.
    – Steven Rumbalski
    Jan 21, 2013 at 20:03
  • @StevenRumbalski No, it just shows that one LOAD_CONST is faster than a 2 to 3 LOAD_FASTs, some other operations, and a BUILD_LIST ;-)
    – user395760
    Jan 21, 2013 at 20:05
  • 1
    @delnan. Point taken. The tuple version still clocks a little faster on my system with your suggested modifications. But it's too little improvement to really care which is used.
    – Steven Rumbalski
    Jan 21, 2013 at 20:08

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