24

When programming in python, I now avoid map, lambda and filter by using list comprehensions because it is easier to read and faster in execution. But can reduce be replaced as well?

E.g. an object has an operator union() that works on another object, a1.union(a2), and gives a 3rd object of same type.

I have a list of objects:

L = [a1, a2, a3, ...]

How to have the union() of all these objects with list comprehensions, the equivalent of:

result = reduce(lambda a, b :a.union(b), L[1:], L[0])
  • 1
    In some cases: no. But depends. Please provide a specific query that you have in mind – sshashank124 Jun 25 '14 at 13:44
  • 1
    @sshashank124 - any examples? – mhawke Jun 25 '14 at 13:53
  • Set unions are a bad example, because you can simply do result = set().union(*L), which has the bonus of working even if L is an empty list. At any rate, lambda a, b :a.union(b) can be written more concisely as set.union, since in python obj.method(args) is the same as cls.method(obj, args) – Eric Mar 11 '16 at 7:07
  • Guido says to use a for loop instead of reduce. He's not a fan of FP constructs. – Didier A. Nov 4 '16 at 20:32
18

It is no secret that reduce is not among the favored functions of the Pythonistas.

Generically, reduce is a left fold on a list

It is conceptually easy to write a fold in Python that will fold left or right on a iterable:

def fold(func, iterable, initial=None, reverse=False):
    x=initial
    if reverse:
        iterable=reversed(iterable)
    for e in iterable:
        x=func(x,e) if x is not None else e
    return x

Without some atrocious hack, this cannot be replicated in a comprehension because there is not accumulator type function in a comprehension.

Just use reduce -- or write one that makes more sense to you.

4

Not really. List comprehensions are more similar to map, and possibly filter.

4

Since a list comprehension definitionally generates another list, you can't use it to generate a single value. The aren't for that. (Well... there is this nasty trick that uses a leaked implementation detail in old versions of python that can do it. I'm not even going to copy the example code here. Don't do this.)

If you're worried about the stylistic aspects of reduce() and its ilk, don't be. Name your reductions and you'll be fine. So while:

all_union = reduce(lambda a, b: a.union(b), L[1:], L[0])

isn't great, this:

def full_union(input):
    """ Compute the union of a list of sets """

    return reduce(lambda a, b: a.union(b), input[1:], input[0])

result = full_union(L)

is pretty clear.

If you're worried about speed, check out the toolz and cytoolz packages, which are 'fast' and 'insanely fast,' respectively. On large datasets, they'll often let you avoid processing your data more than once or loading the whole set in memory at once, in contrast to list comprehensions.

  • 1
    To make the reduce() expression itself readable, make the first argument not a lambda. For example: reduce(set.union, <list of sets>) Sometimes this will require you to define (and therefore name) the operator somewhere outside the call to reduce. – Jordan Oct 11 '17 at 0:12
2

A common use of reduce is to flatten a list of lists. You can use a list comprehension instead.

L = [[1, 2, 3], [2, 3, 4], [3, 4, 5]]

with reduce

from functools import reduce  # python 3
flattened = reduce(lambda x, y: x + y, L)

print(flattened)

[1, 2, 3, 2, 3, 4, 3, 4, 5]

with list comp

flattened = [item for sublist in L for item in sublist]

print(flattened)

[1, 2, 3, 2, 3, 4, 3, 4, 5]

If your problem can be solved by operating on the flattened list, this is an effective replacement. Contrast these one-liners for the given example:

all_union = reduce(lambda a, b: set(a).union(set(b)), L)

{1, 2, 3, 4, 5}

all_union = set([item for sublist in L for item in sublist])

{1, 2, 3, 4, 5}
  • 1
    Use sum(L, []). That said, the sum/list comprehension creates a "full-length" list, where reduce(operator.or_, map(set, L), set()) would not. – Andy Hayden Nov 9 '17 at 6:02

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.