# How to convert this non-tail-recursion function to a loop or a tail-recursion version?

I've been curious for this for long. It is really very easy and elegant for human to create a non-tail-recursive function to get something complicated, but the speed is very slow and easily hit the limit of Python recursion:

``````def moves_three(n, ini=0, med=1, des=2):
'''give a int -> return a list '''
if n == 1:
return ((ini,des),)
return moves_three(n-1, ini=ini, med=des, des=med) + \
((ini, des),) + \
moves_three(n-1, ini=med, med=ini, des=des)

if __name__ == '__main__':
moves_three(100) # may be after several hours you can see the result.
len(moves_three(10000))
``````

So, how to change `moves_three` to a tail recursion one or a loop (better)? More important, are there any essays to talk about this? Thanks.

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Python doesn't do tail optimization, so don't bother making a tail recursive version :) –  thefourtheye Feb 22 '14 at 10:09
@thefourtheye thanks I know that. Python have ways to TCO, I know two ways, so both is OK... –  Pythoner Feb 22 '14 at 10:19
@thefourtheye But they can be made iterative, solving the recursion problem. :) –  Pradyun Feb 22 '14 at 10:59
@Schoolboy There isn't much point in using a decorator. The conversion to a loop is absolutely trivial that it wouldn't take much time to refactor the function into a loop, which would also avoid all the overhead of the decorator and of the function-calls. –  Bakuriu Feb 22 '14 at 12:19
@Bakuriu Yes, most tail-recursive functions can be converted to loops.. And the decorator is just an example that I found interesting... –  Pradyun Feb 22 '14 at 14:35

Even with an iterative form, this isn't going to get any faster. The problem isn't the recursion limit; you're still an order of magnitude below the recursion limit. The problem is that the size of your output is `O(2^n)`. For `n=100`, you have to build a tuple of about a thousand billion billion billion elements. It doesn't matter how you build it; you'll never finish.

If you want to convert this to iteration anyway, that can be done by managing state with an explicit stack instead of the call stack:

``````def moves_three(n, a=0, b=1, c=2):
first_entry = True
stack = [(first_entry, n, a, b, c)]
output = []
while stack:
first_entry, n1, a1, b1, c1 = stack.pop()
if n1 == 1:
output.append((a1, c1))
elif first_entry:
stack.append((False, n1, a1, b1, c1))
stack.append((True, n1-1, a1, c1, b1))
else:
output.append((a1, c1))
stack.append((True, n1-1, b1, a1, c1))
return tuple(output)
``````

Confusing, isn't it? A tuple `(True, n, a, b, c)` on the stack represents entering a function call with arguments `n, a, b, c`. A tuple `(False, n, a, b, c)` represents returning to the `(True, n, a, b, c)` call after `moves_three(n-1, a, c, b)` ends.

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Thank you very much. I make a yield version of your answer, so even it is very huge, it can still output. –  Pythoner Feb 22 '14 at 14:33