# python 2.7 - Recursive Fibonacci blows up

I have two functions `fib1` and `fib2` to calculate Fibonacci.

``````def fib1(n):
if n < 2:
return 1
else:
return fib1(n-1) + fib1(n-2)

def fib2(n):
def fib2h(s, c, n):
if n < 1:
return s
else:
return fib2h(c, s + c, n-1)
return fib2h(1, 1, n)
``````

`fib2` works fine until it blows up the recursion limit. If understand correctly, Python doesn't optimize for tail recursion. That is fine by me.

What gets me is `fib1` starts to slow down to a halt even with very small values of `n`. Why is that happening? How come it doesn't hit the recursion limit before it gets sluggish?

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CPU times: user 0.35 s, sys: 0.00 s, total: 0.35 s Wall time: 0.35 s ... thats how long it took me for `fib1(30)` .. seems reasonable –  Joran Beasley Oct 11 '12 at 0:04
`fib2(30)`, real: 0m0.032s, user: 0m0.025s, sys: 0m0.006s on Python 3. What version of Python are you using? –  Waleed Khan Oct 11 '12 at 0:06
@JoranBeasley Try fib1(100) –  JBoyer Oct 11 '12 at 0:09
@JBoyer: This will have a runtime that blows up exponentially. –  Omnifarious Oct 11 '12 at 0:10
@JoranBeasley: Actually, memoization works regardless of where you start, as long as the recursive calls are also memoized. Fibonacci is the classic case for memoization in many examples of the technique. –  Omnifarious Oct 11 '12 at 0:16

Basically, you are wasting lots of time by computing the fib1 for the same values of n over and over. You can easily memoize the function like this

``````def fib1(n, memo={}):
if n in memo:
return memo[n]
if n < 2:
memo[n] = 1
else:
memo[n] =  fib1(n-1) + fib1(n-2)
return memo[n]
``````

You'll notice that I am using an empty dict as a default argument. This is usually a bad idea because the same dict is used as the default for every function call.

Here I am taking advantage of that by using it to memoize each result I calculate

You can also prime the memo with 0 and 1 to avoid needing the `n < 2` test

``````def fib1(n, memo={0: 1, 1: 1}):
if n in memo:
return memo[n]
else:
memo[n] =  fib1(n-1) + fib1(n-2)
return memo[n]
``````

Which becomes

``````def fib1(n, memo={0: 1, 1: 1}):
return memo.setdefault(n, memo.get(n) or fib1(n-1) + fib1(n-2))
``````
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+1 for teaching me something new today by actually taking advantage of having a default argument reference the same object across multiple calls. –  Platinum Azure Oct 11 '12 at 0:32
This is pretty clever –  JBoyer Oct 11 '12 at 0:34
The later versions will result in infinite recursion for `n < 0`, though admittedly that isn't within the problem domain anyway. –  Platinum Azure Oct 11 '12 at 14:10
wouldnt a decorator be prettier? :P –  Joran Beasley Oct 11 '12 at 15:52

Your problem isn't python, it's your algorithm. `fib1` is a good example of tree recursion. You can find a proof here on stackoverflow that this particular algorithm is (~`θ(1.6``n``)`).

`n=30` (apparently from the comments) takes about a third of a second. If computational time scales up as `1.6^n`, we'd expect `n=100` to take about 2.1 million years.

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nice :) I like your explanation of how long n=100 would take :) ... time to get about 2.1 million cores... then you can be done in only one year :P –  Joran Beasley Oct 11 '12 at 15:53
The first version, on the other hand, requires 2 recursion branches at EACH level! So the number of potential executions of the function skyrockets considerably. Not only that, but most of the work is repeated twice! Consider: `fib1(n-1)` eventually calls `fib1(n-1)` again, which is the same as calling `fib1(n-2)` from the point of reference of the first call frame. But after that value is calculated, it must be added to the value of `fib1(n-2)` again! So the work is needlessly duplicated many times.