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As we all know, the simplest algorithm to generate Fibonacci sequence is as follows:

if(n<=0) return 0;
else if(n==1) return 1;
f(n) = f(n-1) + f(n-2);

But this algorithm has some repetitive calculation. For example, if you calculate f(5), if will calculate f(4) and f(3). when you calculate f(4), it will calculate f(3) again and f(2). Could someone give me a more time-efficient recursive algorithm?

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f(n - 1) = f(n - 2) + f(n - 3) so f(n) = 2 * f(n - 2) + f(n - 3). You can cache f(n - 2). Of course, doing it iteratively is much better, especially if your language of choice has yield. –  minitech Jun 7 '12 at 0:33
@minitech if I want to use the cache method, can you give me the complete code? –  chaonextdoor Jun 7 '12 at 3:04
Which language? –  minitech Jun 7 '12 at 3:04
@minitech Is javascript ok with you? –  chaonextdoor Jun 7 '12 at 16:15

7 Answers 7

One simple way is to calculate it iteratively instead of recursively. This will calculate F(n) in linear time.

def fib(n):
    a,b = 0,1
    for i in range(n):
        a,b = a+b,a
    return a
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There is way how to compute in O(M(n)log n) where M(n) is multiplication cost. Your code is actually O(n^2) for big numbers. See mine answer for fast and accurate computation for big n. Anyway you have to use some big numbers library or language with this support. –  Hynek -Pichi- Vychodil Jan 4 '14 at 9:18

Hint: One way you achieve faster results is by using Binet's formula:

Here is a way of doing it in Python:

from decimal import *

def fib(n):
    return int((Decimal(1.6180339)**Decimal(n)-Decimal(-0.6180339)**Decimal(n))/Decimal(2.236067977))
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Binet's formula as you presented it is not accurate for big n due rounding error in your constants as 1.6180339. See mine answer for fast and accurate computation for big n. –  Hynek -Pichi- Vychodil Jan 4 '14 at 9:15

you can save your results and use them :

public static long[] fibs;

public long fib(int n) {
    fibs = new long[n];
    return internalFib(n);
public long internalFib(int n) {
    if (n<=2) return 1;
    fibs[n-1] = fibs[n-1]==0 ? internalFib(n-1) : fibs[n-1];
    fibs[n-2] = fibs[n-2]==0 ? internalFib(n-2) : fibs[n-2];
    return fibs[n-1]+fibs[n-2];
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F(n) = (φ^n)/√5 and round to nearest integer, where φ is the golden ratio....

φ^n can be calculated in O(lg(n)) time hence F(n) can be calculated in O(lg(n)) time.

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Look here for implementation in Erlang which uses formula \begin{pmatrix}1&1\\1&0\end{pmatrix}^{n-1}=\begin{pmatrix}\mathrm{fib}(n)&\mathrm{fib}(n-1)\ \mathrm{fib}(n-1)&\mathrm{fib}(n-2)\end{pmatrix} . It shows nice linear resulting behavior because in O(M(n) log n) part M(n) is exponential for big numbers. It calculates fib of one million in 2s where result has 208988 digits. The trick is that you can compute exponentiation in O(log n) multiplications using (tail) recursive formula (tail means with O(1) space when used proper compiler or rewrite to cycle):

% compute X^N
power(X, N) when is_integer(N), N >= 0 ->
    power(N, X, 1).

power(0, _, Acc) ->
power(N, X, Acc) ->
    if N rem 2 =:= 1 ->
            power(N - 1,   X,     Acc * X);
        true ->
            power(N div 2, X * X, Acc)

where X and Acc you substitute with matrices. X will be initiated with \begin{pmatrix}1&1\1&0\end{pmatrix} and Acc with identity I equals to \begin{pmatrix}1&0\0&1\end{pmatrix}.

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// D Programming Language 

void vFibonacci ( const ulong X, const ulong Y, const int Limit ) {    
       // Equivalent : if ( Limit != 10 ). Former ( Limit ^ 0xA ) is More Efficient However.
       if ( Limit ^ 0xA ) {    
           write ( Y, " " ) ;
           vFibonacci ( Y, Y + X, Limit + 1 ) ;
       } ;
} ;

// Call As    
// By Default the Limit is 10 Numbers
vFibonacci ( 0, 1, 0 ) ;
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Some plain language explanation of code is almost always beneficial for the clarity of answers. –  Thomas Nov 22 '14 at 20:41

EDIT: I actually think Hynek Vychodil's answer is superior to mine, but I'm leaving this here just in case someone is looking for an alternate method.

I think the other methods are all valid, but not optimal. Using Binet's formula should give you the right answer in principle, but rounding to the closest integer will give some problems for large values of n. The other solutions will unnecessarily recalculate the values upto n every time you call the function, and so the function is not optimized for repeated calling.

In my opinion the best thing to do is to define a global array and then to add new values to the array IF needed. In Python:

import numpy


def fib(n):
    global fibo,last_index
    if (n>0):
            for i in range(last_index+1,n+1):
        return fibo[n-1]
        print "fib called for index less than 1"

Naturally, if you need to call fib for n>80 (approximately) then you will need to implement arbitrary precision integers, which is easy to do in python.

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