136

Is there a more concise, efficient or simply pythonic way to do the following?

def product(list):
    p = 1
    for i in list:
        p *= i
    return p

EDIT:

I actually find that this is marginally faster than using operator.mul:

from operator import mul
# from functools import reduce # python3 compatibility

def with_lambda(list):
    reduce(lambda x, y: x * y, list)

def without_lambda(list):
    reduce(mul, list)

def forloop(list):
    r = 1
    for x in list:
        r *= x
    return r

import timeit

a = range(50)
b = range(1,50)#no zero
t = timeit.Timer("with_lambda(a)", "from __main__ import with_lambda,a")
print("with lambda:", t.timeit())
t = timeit.Timer("without_lambda(a)", "from __main__ import without_lambda,a")
print("without lambda:", t.timeit())
t = timeit.Timer("forloop(a)", "from __main__ import forloop,a")
print("for loop:", t.timeit())

t = timeit.Timer("with_lambda(b)", "from __main__ import with_lambda,b")
print("with lambda (no 0):", t.timeit())
t = timeit.Timer("without_lambda(b)", "from __main__ import without_lambda,b")
print("without lambda (no 0):", t.timeit())
t = timeit.Timer("forloop(b)", "from __main__ import forloop,b")
print("for loop (no 0):", t.timeit())

gives me

('with lambda:', 17.755449056625366)
('without lambda:', 8.2084708213806152)
('for loop:', 7.4836349487304688)
('with lambda (no 0):', 22.570688009262085)
('without lambda (no 0):', 12.472226858139038)
('for loop (no 0):', 11.04065990447998)
  • 3
    There's a functional difference between the options given here in that for an empty list the reduce answers raise a TypeError, whereas the for loop answer returns 1. This is a bug in the for loop answer (the product of an empty list is no more 1 than it is 17 or 'armadillo'). – Scott Griffiths Jan 24 '10 at 8:28
  • 4
    Please try to avoid using names of built-ins (such as list) for the names of your variables. – Mark Byers Aug 4 '12 at 10:22
  • 2
    Old answer, but I am tempted to edit so it doesn't use list as a variable name... – beroe Apr 17 '14 at 5:50
  • 11
    The product of an empty list is 1. en.wikipedia.org/wiki/Empty_product – Paul Crowley Oct 27 '15 at 12:02
  • 1
    @ScottGriffiths I should have specified that I meant a list of numbers. And I would say that the sum of an empty list is the identity element of + for that type of list (likewise for product / *). Now I realize that Python is dynamically typed which makes things harder, but this is a solved problem in sane languages with static type systems like Haskell. But Python only allows sum to work on numbers anyway, since sum(['a', 'b']) doesn't even work, so I again say that 0 makes sense for sum and 1 for product. – semicolon Jul 7 '17 at 13:58

13 Answers 13

155

Without using lambda:

from operator import mul
reduce(mul, list, 1)

it is better and faster. With python 2.7.5

from operator import mul
import numpy as np
import numexpr as ne
# from functools import reduce # python3 compatibility

a = range(1, 101)
%timeit reduce(lambda x, y: x * y, a)   # (1)
%timeit reduce(mul, a)                  # (2)
%timeit np.prod(a)                      # (3)
%timeit ne.evaluate("prod(a)")          # (4)

In the following configuration:

a = range(1, 101)  # A
a = np.array(a)    # B
a = np.arange(1, 1e4, dtype=int) #C
a = np.arange(1, 1e5, dtype=float) #D

Results with python 2.7.5


       |     1     |     2     |     3     |     4     |
-------+-----------+-----------+-----------+-----------+
 A       20.8 µs     13.3 µs     22.6 µs     39.6 µs     
 B        106 µs     95.3 µs     5.92 µs     26.1 µs
 C       4.34 ms     3.51 ms     16.7 µs     38.9 µs
 D       46.6 ms     38.5 ms      180 µs      216 µs

Result: np.prod is the fastest one, if you use np.array as data structure (18x for small array, 250x for large array)

with python 3.3.2:


       |     1     |     2     |     3     |     4     |
-------+-----------+-----------+-----------+-----------+
 A       23.6 µs     12.3 µs     68.6 µs     84.9 µs     
 B        133 µs      107 µs     7.42 µs     27.5 µs
 C       4.79 ms     3.74 ms     18.6 µs     40.9 µs
 D       48.4 ms     36.8 ms      187 µs      214 µs

Is python 3 slower?

  • 1
    Very interesting, thanks. Any idea why python 3 might be slower? – Simon Watkins Jan 20 '10 at 22:16
  • 3
    Possible reasons: (1) Python 3 int is Python 2 long. Python 2 will be using "int" until it overflows 32 bits; Python 3 will use "long" from the start. (2) Python 3.0 was a "proof of concept". Upgrade to 3.1 ASAP! – John Machin Jan 20 '10 at 22:30
  • 1
    I've redone the same test on an other machine: python 2.6 ('with lambda:', 21.843887090682983) ('without lambda:', 9.7096879482269287) python 3.1: with lambda: 24.7712180614 without lambda: 10.7758350372 – Ruggero Turra Jan 21 '10 at 11:25
  • 1
    both fail with empty lists. – bug Jan 26 '13 at 18:44
  • 5
    Note that you must import the reduce operator from the functools module in Python 3. I.E. from functools import reduce. – Chris Mueller Sep 20 '17 at 13:19
43
reduce(lambda x, y: x * y, list, 1)
  • 3
    +1 but see @wiso's answer about operator.mul for a better way to do it. – Chris Lutz Jan 20 '10 at 21:37
  • why is operator.mul preferrable to x*y? – Adam Hughes Feb 26 '15 at 17:04
  • 2
    operator.mul is a function and would thus be a replacement not only for x*y but for the entire lambda expression (i.e. the first argument to reduce) – Johannes Charra Mar 19 '15 at 10:36
  • 3
    You have to do an import from functools import reduce to make it work in Python 3. – lifebalance Jun 15 '17 at 15:41
36

if you just have numbers in your list:

from numpy import prod
prod(list)

EDIT: as pointed out by @off99555 this does not work for large integer results in which case it returns a result of type numpy.int64 while Ian Clelland's solution based on operator.mul and reduce works for large integer results because it returns long.

  • this is slower if the list is short – endolith Apr 25 '16 at 16:03
  • 1
    I tried evaluating from numpy import prod; prod(list(range(5,101))) and it outputted 0, can you reproduce this result on Python 3? – off99555 Nov 27 '16 at 11:57
  • because prod returns a result of type numpy.int64 in this case and you get an overflow (a negative value actually) already for range(5,23). Use @Ian Clelland's solution based on operator.mul and reduce for large integers (it returns a long in this case which seems to have arbitrary precision). – Andre Holzner Nov 27 '16 at 13:31
17
import operator
reduce(operator.mul, list, 1)
  • 1
    is the last argument (1) really necessary? – Ruggero Turra Jan 20 '10 at 21:47
  • 7
    The last argument is necessary if the list may be empty, otherwise it will throw a TypeError exception. Of course, sometimes an exception will be what you want. – Dave Kirby Jan 21 '10 at 0:06
  • 2
    For me it returns 0 without that argument, so you can also consider it necessary to enforce the empty product convention. – bug Jan 26 '13 at 18:42
  • or functools.reduce(..) in python3 – Andre Holzner Nov 27 '16 at 13:38
15

Well if you really wanted to make it one line without importing anything you could do:

eval('*'.join(str(item) for item in list))

But don't.

  • Now let's pass in a list of interesting strings (to emphasize why "don't")... – Mad Physicist Feb 10 at 3:31
14

I remember some long discussions on comp.lang.python (sorry, too lazy to produce pointers now) which concluded that your original product() definition is the most Pythonic.

Note that the proposal is not to write a for loop every time you want to do it, but to write a function once (per type of reduction) and call it as needed! Calling reduction functions is very Pythonic - it works sweetly with generator expressions, and since the sucessful introduction of sum(), Python keeps growing more and more builtin reduction functions - any() and all() are the latest additions...

This conclusion is kinda official - reduce() was removed from builtins in Python 3.0, saying:

"Use functools.reduce() if you really need it; however, 99 percent of the time an explicit for loop is more readable."

See also The fate of reduce() in Python 3000 for a supporting quote from Guido (and some less supporting comments by Lispers that read that blog).

P.S. if by chance you need product() for combinatorics, see math.factorial() (new 2.6).

  • 2
    +1 for an accurate (to the best of my knowledge) account of the prevailing moods in the Python community -- while I definately prefer going against said prevailing moods in this case, it's best to know them for what they are anyway. Also, I like the bit about unsupportive Lispers from LtU (I'd be one of those, I guess). :-) – Michał Marczyk Jan 23 '10 at 20:42
7

The intent of this answer is to provide a calculation that is useful in certain circumstances -- namely when a) there are a large number of values being multiplied such that the final product may be extremely large or extremely small, and b) you don't really care about the exact answer, but instead have a number of sequences, and want to be able to order them based on each one's product.

If you want to multiply the elements of a list, where l is the list, you can do:

import math
math.exp(sum(map(math.log, l)))

Now, that approach is not as readable as

from operator import mul
reduce(mul, list)

If you're a mathematician who isn't familiar with reduce() the opposite might be true, but I wouldn't advise using it under normal circumstances. It's also less readable than the product() function mentioned in the question (at least to non-mathematicians).

However, if you're ever in a situation where you risk underflow or overflow, such as in

>>> reduce(mul, [10.]*309)
inf

and your purpose is to compare the products of different sequences rather than to know what the products are, then

>>> sum(map(math.log, [10.]*309))
711.49879373515785

is the way to go because it's virtually impossible to have a real-world problem in which you would overflow or underflow with this approach. (The larger the result of that calculation is, the larger the product would be if you could calculate it.)

  • It's clever, but fails if you have any negative or zero values. :/ – Alex Meiburg Mar 9 '17 at 12:19
5

Starting Python 3.8, a prod function has been included to the math module in the standard library:

math.prod(iterable, *, start=1)

which returns the product of a start value (default: 1) times an iterable of numbers:

import math

math.prod([2, 3, 4]) # 24

Note that if the iterable is empty, this will produce 1 (or the start value if provided).

2

I am surprised no-one has suggested using itertools.accumulate with operator.mul. This avoids using reduce, which is different for Python 2 and 3 (due to the functools import required for Python 3), and moreover is considered un-pythonic by Guido van Rossum himself:

from itertools import accumulate
from operator import mul

def prod(lst):
    for value in accumulate(lst, mul):
        pass
    return value

Example:

prod([1,5,4,3,5,6])
# 1800
1

One option is to use numba and the @jit or @njit decorator. I also made one or two little tweaks to your code (at least in Python 3, "list" is a keyword that shouldn't be used for a variable name):

@njit
def njit_product(lst):
    p = lst[0]  # first element
    for i in lst[1:]:  # loop over remaining elements
        p *= i
    return p

For timing purposes, you need to run once to compile the function first using numba. In general, the function will be compiled the first time it is called, and then called from memory after that (faster).

njit_product([1, 2])  # execute once to compile

Now when you execute your code, it will run with the compiled version of the function. I timed them using a Jupyter notebook and the %timeit magic function:

product(b)  # yours
# 32.7 µs ± 510 ns per loop (mean ± std. dev. of 7 runs, 10000 loops each)

njit_product(b)
# 92.9 µs ± 392 ns per loop (mean ± std. dev. of 7 runs, 10000 loops each)

Note that on my machine, running Python 3.5, the native Python for loop was actually the fastest. There may be a trick here when it comes to measuring numba-decorated performance with Jupyter notebooks and the %timeit magic function. I am not sure that the timings above are correct, so I recommend trying it out on your system and seeing if numba gives you a performance boost.

0

The fastest way I found was, using while:

mysetup = '''
import numpy as np
from find_intervals import return_intersections 
'''

# code snippet whose execution time is to be measured
mycode = '''

x = [4,5,6,7,8,9,10]
prod = 1
i = 0
while True:
    prod = prod * x[i]
    i = i + 1
    if i == len(x):
        break
'''

# timeit statement for while:
print("using while : ",
timeit.timeit(setup=mysetup,
              stmt=mycode))

# timeit statement for mul:
print("using mul : ",
    timeit.timeit('from functools import reduce;
    from operator import mul;
    c = reduce(mul, [4,5,6,7,8,9,10])'))

# timeit statement for mul:
print("using lambda : ",      
    timeit.timeit('from functools import reduce;
    from operator import mul;
    c = reduce(lambda x, y: x * y, [4,5,6,7,8,9,10])'))

and the timings are:

>>> using while : 0.8887967770060641

>>> using mul : 2.0838719510065857

>>> using lambda : 2.4227715369997895
0

I've tested various solutions with perfplot (a small project of mine) and found that

numpy.prod(lst)

is by far the fastest solution (if the list isn't very short).

enter image description here


Code to reproduce the plot:

import perfplot
import numpy

from operator import mul
from functools import reduce

from itertools import accumulate


def reduce_lambda(lst):
    return reduce(lambda x, y: x * y, lst)


def reduce_mul(lst):
    return reduce(mul, lst)


def forloop(lst):
    r = 1
    for x in lst:
        r *= x
    return r


def numpy_prod(lst):
    return numpy.prod(lst)


def itertools_accumulate(lst):
    for value in accumulate(lst, mul):
        pass
    return value


perfplot.show(
    setup=numpy.random.rand,
    kernels=[
       reduce_lambda,
       reduce_mul,
       forloop,
       numpy_prod,
       itertools_accumulate,
    ],
    n_range=[2**k for k in range(15)],
    xlabel='len(a)',
    logx=True,
    logy=True,
    )
-3

This also works though its cheating

def factorial(n):
    x=[]
    if n <= 1:
        return 1
    else:
        for i in range(1,n+1): 
            p*=i
            x.append(p)
        print x[n-1]    
  • I've fixed the indentation, but I think you should replace the last print with a return. Also, there's no need to store the intermediate values in a list, you just need to store p betweens iterations. – BoppreH Oct 18 '13 at 18:54
  • factorial? Product of a list is not a factorial.... – Fábio Dias Aug 31 '16 at 18:55

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