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# Fast Fibonacci recursion

I'm trying to recall an algorithm on Fibonacci recursion. The following:

``````public int fibonacci(int n)  {
if(n == 0)
return 0;
else if(n == 1)
return 1;
else
return fibonacci(n - 1) + fibonacci(n - 2);
}
``````

is not what I'm looking for because it's greedy. This will grow exponentially (just look at Java recursive Fibonacci sequence - the bigger the initial argument the more useless calls will be made).

There is probably something like a "cyclic argument shift", where calling previous Fibonacci value will retrieve value instead of calculating it again.

-

maybe like this:

``````int fib(int term, int val = 1, int prev = 0)
{
if(term == 0) return prev;
if(term == 1) return val;
return fib(term - 1, val+prev, val);
}
``````

this function is tail recursive. this means it could be optimized and executed very efficiently. In fact, it gets optimized into a simple loop..

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This was exactly what I was looking for. I didn't know that it's called "tail recursion" in English. Great thanks, mate! – ducin Dec 11 '12 at 20:34
Or you could just implement it as a loop in the first place, doh! – Tyler Durden Dec 11 '12 at 20:46
@TylerDurden: the question is about fast recursion. – duedl0r Dec 12 '12 at 8:26
This still grows in O(n), you can find O(log n) algorithms which are way faster nayuki.io/page/fast-fibonacci-algorithms (linked in other answers) – Ludovic Migneault May 31 at 17:15

This kind of problems are linear recurrence types and they are solved fastest via fast matrix exponentiation. Here's the blogpost that describes this kind of approach concisely.

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You can do a pretty fast version of recursive Fibonacci by using memoization (meaning: storing previous results to avoid recalculating them). for example, here's a proof of concept in Python, where a dictionary is used for saving previous results:

``````results = { 0:0, 1:1 }

def memofib(n):
if n not in results:
results[n] = memofib(n-1) + memofib(n-2)
return results[n]
``````

It returns quickly for input values that would normally block the "normal" recursive version. Just bear in mind that an `int` data type won't be enough for holding large results, and using arbitrary precision integers is recommended.

A different option altogether - rewriting this iterative version ...

``````def iterfib(n):
a, b = 0, 1
for i in xrange(n):
a, b = b, a + b
return a
``````

... as a tail-recursive function, called `loop` in my code:

``````def tailfib(n):
return loop(n, 0, 1)

def loop(i, a, b):
if i == 0:
return a
return loop(i-1, b, a+b)
``````
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@tkoomzaaskz I updated my answer with another possible solution, FYI. – Óscar López Dec 11 '12 at 20:50

I found interesting article about fibonacci problem

here the code snippet

``````# Returns F(n)
def fibonacci(n):
if n < 0:
raise ValueError("Negative arguments not implemented")
return _fib(n)[0]

# Returns a tuple (F(n), F(n+1))
def _fib(n):
if n == 0:
return (0, 1)
else:
a, b = _fib(n // 2)
c = a * (2 * b - a)
d = b * b + a * a
if n % 2 == 0:
return (c, d)
else:
return (d, c + d)

# added iterative version base on C# example
def iterFib(n):
a = 0
b = 1
i=31
while i>=0:
d = a * (b * 2 - a)
e = a * a + b * b
a = d
b = e
if ((n >> i) & 1) != 0:
c = a + b;
a = b
b = c
i=i-1
return a
``````
-
How about an iterative version? – Tolo Palmer Apr 26 '15 at 12:29
From article also included iterative version on C# nayuki.io/res/fast-fibonacci-algorithms/fastfibonacci.cs – Moch Lutfi Apr 28 '15 at 6:07

Say you want to have the the n'th fib number then build an array containing the preceeding numbers

``````int a[n];
a[0] = 0;
a[1] =1;
a[i] = n[i-1]+n[n-2];
``````
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There is a solution without storing values in an array. If you call f(n), each numbers (n, n-1, n-2, ..., 1, 0) will be calculated exactly once. – ducin Dec 11 '12 at 19:14

An example in JavaScript that uses recursion and a lazily initialized cache for added efficiency:

``````var cache = {};

function fibonacciOf (n) {
if(n == 0) return 0;
if(n == 1) return 1;
var previous = cache[n-1] || fibonacciOf(n-1);
cache[n-1] = previous;
return previous + fibonacciOf(n-2);
};
``````
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duedl0r's algorithm translated to Swift:

``````func fib(n: Int, previous: (Int, Int) = (0,1)) -> Int {
guard n > 0 else { return 0 }
if n == 1 { return previous.1 }
return fib(n - 1, previous: (previous.1, previous.0 + previous.1))
}
``````

worked example:

``````fib(4)
= fib(4, (0,1) )
= fib(3, (1,1) )
= fib(2, (1,2) )
= fib(1, (2,3) )
= 3
``````
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