In Python, if I have a child function within a parent function, is the child function "initialised" (created) every time the parent function is called? Is there any overhead associated with nesting a function within another?


Yes, a new object would be created each time. It's likely not an issue unless you have it in a tight loop. Profiling will tell you if it's a problem.

In [80]: def foo():
   ....:     def bar():
   ....:         pass
   ....:     return bar

In [81]: id(foo())
Out[81]: 29654024

In [82]: id(foo())
Out[82]: 29651384
  • 44
    To be clear, a new function object is created each time. The underlying code object is reused. So, the overhead is constant regardless of the length of the inner function. – Raymond Hettinger Oct 20 '11 at 17:53
  • 4
    FWIW, if the function is decorated, the decorator is called whenever the function object is recreated as well. – kindall Oct 20 '11 at 18:40
  • ... though in many cases that just means you get two or three O(1) function object creations. Decorators that do heavy lifting on creation are rare, most just create a small object or a closure. – user395760 Oct 20 '11 at 18:51
  • The two ids are the same by mere chance. Python happens to use the same memory for the second bar() because the first one is immediately garbage collected. Try a = foo(); b = foo() and compare the ids (they'll be different). See stackoverflow.com/questions/2906177/… for a related explanation. – Sven Marnach Oct 28 '11 at 20:49
  • 1
    @SvenMarnach: I'm aware of what you're trying to say, but the ids are not the same in my answer. (Also ipython holds the result of the call in a variable automatically, so they both would not have been gc'd anyway) – Daenyth Oct 29 '11 at 1:52

The code object is pre-compiled so that part has no overhead. The function object gets built on every invocation -- it binds the function name to the code object, records default variables, etc.

Executive summary: It's not free.

>>> from dis import dis
>>> def foo():
        def bar():
        return bar

>>> dis(foo)
  2           0 LOAD_CONST               1 (<code object bar at 0x1017e2b30, file "<pyshell#5>", line 2>)
              3 MAKE_FUNCTION            0
              6 STORE_FAST               0 (bar)

  4           9 LOAD_FAST                0 (bar)
             12 RETURN_VALUE 

There is an impact, but in most situations it is so small that you shouldn't worry about it - most non-trivial applications probably already have performance bottlenecks whose impacts are several orders of magnitude larger than this one. Worry instead about the readability and reusability of the code.

Here some code that compares the performance of redefining a function each time through a loop to reusing a predefined function instead.

import gc
from datetime import datetime

class StopWatch:
     def __init__(self, name):
         self.name = name

     def __enter__(self):
         self.start = datetime.now()

     def __exit__(self, type, value, traceback):
         elapsed = datetime.now()-self.start
         print '** Test "%s" took %s **' % (self.name, elapsed)

def foo():
     def bar():
     return bar

def bar2():

def foo2():
    return bar2

num_iterations = 1000000

with StopWatch('FunctionDefinedEachTime') as sw:
    result_foo = [foo() for i in range(num_iterations)]

with StopWatch('FunctionDefinedOnce') as sw:
    result_foo2 = [foo2() for i in range(num_iterations)]

When I run this in Python 2.7 on my Macbook Air running OS X Lion I get:

** Test "FunctionDefinedEachTime" took 0:00:01.138531 **
** Test "FunctionDefinedOnce" took 0:00:00.270347 **

I was curious about this too, so I decided to figure out how much overhead this incurred. TL;DR, the answer is not much.

Python 3.5.2 (default, Nov 23 2017, 16:37:01) 
[GCC 5.4.0 20160609] on linux
Type "help", "copyright", "credits" or "license" for more information.
>>> from timeit import timeit
>>> def subfunc():
...     pass
>>> def no_inner():
...     return subfunc()
>>> def with_inner():
...     def s():
...         pass
...     return s()
>>> timeit('[no_inner() for _ in range(1000000)]', setup='from __main__     import no_inner', number=1)
>>> timeit('[with_inner() for _ in range(1000000)]', setup='from __main__ import with_inner', number=1)

My instinct was to look at percents (with_inner is 24% slower), but that number is misleading in this case, since we'll never actually just return the value of an inner function from an outer function, especially with functions that don't actually do anything.
After making that mistake, I decided to compare it to other common things, to see when this does and does not matter:

    >>> def no_inner():
    ...     a = {}
    ...     return subfunc()
    >>> timeit('[no_inner() for _ in range(1000000)]', setup='from __main__ import no_inner', number=1)

Looking at this, we can see that it takes less time than creating an empty dict (the fast way), so if you're doing anything non-trivial, this probably does not matter at all.


The other answers are great and really answer the question well. I wanted to add that most inner functions can be avoided in python using for loops, generating functions, etc.

Consider the following Example:

def foo():
    # I need to execute a function on two sets of arguments:
    argSet1 = (1, 3, 5, 7)
    argSet2 = (2, 4, 6, 8)

    # A Function could be executed on each set of args
    def bar(arg1, arg2, arg3, arg4):
        return (arg1 + arg2 + arg3 + arg4)

    total = 0
    for argSet in [argSet1, argSet2]:
      total += bar(*argSet)
    print( total )

    # Or a loop could be used on the argument sets
    total = 0
    for arg1, arg2, arg3, arg4 in [argSet1, argSet2]:
        total += arg1 + arg2 + arg3 + arg4
    print( total )

This example is a little goofy, but I hope you can see my point nonetheless. Inner functions are often not needed.


Yes. This enables closures, as well as function factories.

A closure causes the inner function to remember the state of its environment when called.

def generate_power(number):

    # Define the inner function ...
    def nth_power(power):
        return number ** power

    return nth_power


>>> raise_two = generate_power(2)
>>> raise_three = generate_power(3)

>>> print(raise_two(3))
>>> print(raise_three(5))

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