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# Efficient memoization in Python

I have some task to solve and the most important part at the moment is to make the script as time-efficient as possible. One of the elements I am trying to optimize is memoization within one of the functions.

So my question is: Which of the following 3-4 methods is the most efficient / fastest method of implementing memoization in Python?

I have provided code only as an example - if one of the methods is more efficient, but not in the case I mentioned, please share what you know.

## Solution 1 - using mutable variable from outer scope

This solution is often shown as the example memoization, but I am not sure how efficient it is. I have heard that using global variables (in this case it is variable from outer, not global scope) is less efficient.

``````def main():
memo = {}
def power_div(n):
try:
return memo[n]
except (KeyError):
memo[n] = (n ** 2) % 4  # example expression, should not matter
return memo[n]
# extensive usage of power_div() here
``````

## Solution 2 - using default, mutable argument

I have found somewhere that using default mutable arguments has been used in the past to pass variables from outer scope, when Python searched the variable first in the local scope, then in the global scope, skipping the nonlocal scope (in this case the scope within function `main()`). Because default argument is initialized only at the time function is defined and is accessible only inside the inner function, maybe it is thus more efficient?

``````def main():
def power_div(n, memo={}):
try:
return memo[n]
except (KeyError):
memo[n] = (n ** 2) % 4  # example expression, should not matter
return memo[n]
# extensive usage of power_div() here
``````

Or maybe the following version (being in fact a combination of solutions 1&2) is more efficient?

``````def main():
memo = {}
def power_div(n, memo=memo):
try:
return memo[n]
except (KeyError):
memo[n] = (n ** 2) % 4  # example expression, should not matter
return memo[n]
# extensive usage of power_div() here
``````

## Solution 3 - function's attribute

This is another quite common example of memoization in Python - the memoization object is stored as an attribute of the function itself.

``````def main():
def power_div(n):
memo = power_div.memo
try:
return memo[n]
except (KeyError):
memo[n] = (n ** 2) % 4  # example expression, should not matter
return memo[n]
# extensive usage of power_div() here
``````

## Summary

I am very interested in your opinions about the four above solutions for memoization. It is important also, that the function that uses memoization is within another function.

I know that there are also other solutions for memoization (such as `Memoize` decorator), but it is hard for me to believe that this is more efficient solution than these listed above. Correct me if I am wrong.

-
As with most "which of these is faster" questions, the ultimate answer is "try it and find out". The `timeit` module provides a very good way to test things like this. – Amber Feb 2 '12 at 6:59
(Also: have you profiled your existing code and found the memoization to be a bottleneck? If no, why are you focusing on optimizing it?) – Amber Feb 2 '12 at 7:00
@Amber: The case is 1) I have not much to optimize in my existing code, so I am trying to improve everything I can, 2) this question is more about the efficiency of the mentioned cases and why one is better than another, it is more general. I am not trying to use `timeit`, because 1) I may be missing some other, more efficient solution. 2) My results may be biased because of the way I use memoization. I am trying to find the fastest way to use memoization to learn it and to let people know, not necessarily fix this one piece of code (such question would be too localized). – Tadeck Feb 2 '12 at 7:10
My immediate assumption would be that using the `get()` method of `dict` objects would be faster than catching `KeyError`. But it may be that the speed up would only affect the "cache miss" branch, in which case it's not worth it. But it's probably worth timing both ways. – Daniel Pryden Feb 2 '12 at 7:23
@DanielPryden: I have been thinking about using `get()`, but since you need to calculate something if the key has not been found, it would look like that: `memo.get(n, (n ** 2) % 4)`. In this case it would not make much sense, because `(n ** 2) % 4` would be executed every time function is called (thus memoization would be useless). – Tadeck Feb 2 '12 at 7:27

The different styles of variable access have already been timed and compared at: http://code.activestate.com/recipes/577834-compare-speeds-of-different-kinds-of-access-to-var Here's a quick summary: local access beats nonlocal (nested scopes) which beat global access (module scope) which beats access to builtins.

Your solution #2 (with local access) should win. Solution #3 has a slow-dotted lookup (which requires a dictionary lookup). Solution #1 uses nonlocal (nested scope) access which uses cell-variables (faster than a dict lookup but slower than locals).

Also note, the KeyError exception class is a global lookup and can be sped-up by localizing it. You could replace the try/except entirely and use a `memo.get(n, sentinel)` instead. And even that could be sped-up by using a bound method. Of course, your easiest speed boost may just come from trying out pypy :-)

In short, there are many ways to tweak this code. Just make sure it's worth it.

-
Thank you very much :) Do you think there is a difference in performance between using `memo=memo` (where `memo` is in the nonlocal scope) and `memo={}` (so there is no nonlocal scope involved)? – Tadeck Feb 2 '12 at 7:57
@Tadeck There should be no difference at all. Both ways end-up with a local variable pointing directly at the dict instance. – Raymond Hettinger Feb 2 '12 at 8:10

For the benefit of people who stumble on this question while looking for a way to do memoization in python, I recommend fastcache.

It works on python 2 and 3, is faster than any of the methods described above, and gives the option to limit cache size so that it does not inadvertently get too big:

``````from fastcache import clru_cache

@clru_cache(maxsize=128, typed=False)
def foo(cat_1, cat_2, cat_3):
return cat_1 + cat_2 + cat_3
``````

Installing fastcache is simple, using `pip`:

``````pip install fastcache
``````

or `conda`:

``````conda install fastcache
``````
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