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I was wondering about how can one find the nth term of fibonacci sequence for a very large value of n say, 1000000. Using the grade-school recurrence equation fib(n)=fib(n-1)+fib(n-2), it takes 2-3 min to find the 50th term!

After googling, I came to know about Binet's formula but it is not appropriate for values of n>79 as it is said here

Is there an algorithm to do so just like we have for finding prime numbers?

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6  
Just like we have for finding prime numbers? –  Joseph Mansfield Feb 2 '13 at 11:59
    
I mean, is there any known algorithm to do this like we have Sieve of Atkins/Eratosthenes for prime numbers! –  stalin Feb 2 '13 at 12:01
    
    
possible duplicate of nth fibonacci number in sublinear time –  amit Feb 4 '13 at 15:12

12 Answers 12

up vote 17 down vote accepted

You can use the matrix exponentiation method(linear recurrence method). You can find detailed explanation and procedure in this blog. Run time is O( log n).

I dont think there is a better way of doing this.

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Very good method! The simple iterative method is good but it has the problem of storing very large numbers, so anyhow I have to use array there. –  stalin Feb 2 '13 at 12:41
2  
The runtime of O(log n) ignores the work required to multiply together the numbers, which isn't trivial because the Fibonacci numbers grow exponentially. Only O(log n) multiplies are required, but those multiplies can take a long time. –  templatetypedef Aug 29 '13 at 0:06

You can save a lot time by use of memoization. For example, compare the following two versions(in JavsScript):

Version 1: normal recursion

var fib = function(n) {
  return n < 2 ? n : fib(n - 1) + fib(n - 2);
};

Version 2: memoization

A. take use of underscore library

var fib2 = _.memoize(function(n) {
  return n < 2 ? n : fib2(n - 1) + fib2(n - 2);
});

B. library-free

var fib3 = (function(){
    var memo = {};
    return function(n) {
        if (memo[n]) {return memo[n];}
        return memo[n] = (n <= 2) ? 1 : fib3(n-2) + fib3(n-1);
    };
})();

The first version takes over 3 minutes for n = 50(on Chrome), while the second only takes less than 5ms! You can check this in the jsFiddle.

It's not that surprising if we know version 1's time complexity is exponential(O(2^(N/2))), while version 2's is linear(O(N)).

Version 3: matrix multiplication

Furthermore, we can even cut down the time complexity to O(log(N)) by computing the multiplication of N matrices.

matrix

where Fn denotes the n-th term of Fibonacci sequence.

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Use recurrence identities http://en.wikipedia.org/wiki/Fibonacci_number#Other_identities to find n-th number in log(n) steps. You will have to use arbitrary precision integers for that. Or you can calculate the precise answer modulo some factor by using modular arithmetic at each step.

recurrence formula 1

recurrence formula 2

recurrence formula 3

Noticing that 3n+3 == 3(n+1), we can devise a single-recursive function which calculates two sequential Fibonacci numbers at each step dividing the n by 3 and choosing the appropriate formula according to the remainder value. IOW it calculates a pair @(3n+r,3n+r+1), r=0,1,2 from a pair @(n,n+1) in one step, so there's no double recursion and no memoization is necessary.

A Haskell code is here.

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This is a very intersting solution. I made a python implementation to see how it compared with using Lucas sequence identities (as implemented, for example, here), but the calculations for F3n+1 and F3n+2 seem to be too expensive to be an advantage. For n with several factors of 3, there was a notable gain, though, so it may be worthwhile special casing n%3 == 0. –  primo Nov 1 '13 at 19:36
    
@primo yeah, I later compared it with the usual doubling impl and it was of comparable performance IIRC: F_{2n-1} = F_n^2 + F_{n-1}^2 ; F_{2n} = (2F_{n-1}+F_n)F_n. (will need an occasional addition, F_{n-2} + F_{n-1} = F_n, when n is odd). –  Will Ness Nov 1 '13 at 20:09
    
I've compared four functions, one which returns F_n, L_n in binary descent (L_n the nth Lucas number), one with F_n, F_n+1 in binary descent, one with F_n-1, F_n in binary descent, and the last with F_n, F_n+1 in ternary descent (as in your post above). Each tested with small values ( < 10000) and large values ( > 1000000). Code can be found here. Results on my comp: (0.570897, 0.481219), (0.618591, 0.57380), (0.655304, 0.596477), and (0.793330, 0.830549) respectively. –  primo Nov 2 '13 at 6:09
    
@primo great, thanks! :) so the cost of complicated calculations overtakes the little-bit reduced number of steps, for the ternary descent. I never tried the Lucas numbers, very interesting. Perhaps you should add your code to rosettacode.org if it's not already there. I should add some in Haskell, too. Your data shows that the ternary version really isn't the way to go. :) –  Will Ness Nov 2 '13 at 10:01
    
@primo also maybe add your Lucas code here as a new answer, since it looks like it's the fastest! –  Will Ness Nov 2 '13 at 10:06

For calculating the Fibonacci numbers, the recursive algorithm is one of the worst way. By simply adding the two previous numbers in a for cycle (called iterative method) will not take 2-3 minutes, to calculate the 50th element.

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1  
yup! I was using pure recurssion :D –  stalin Feb 2 '13 at 12:38
    
@stalin good; just maintain two last numbers at each step, not one. –  Will Ness Feb 2 '13 at 12:40

For calculating arbitrarily large elements of the Fibonacci sequence, you're going to have to use the closed-form solution -- Binet's formula, and use arbitrary-precision math to provide enough precision to calculate the answer.

Just using the recurrence relation, though, should not require 2-3 minutes to calculate the 50th term -- you should be able to calculate terms out into the billions within a few seconds on any modern machine. It sounds like you're using the fully-recursive formula, which does lead to a combinatorial explosion of recursive calculations. The simple iterative formula is much faster.

To wit: the recursive solution is:

int fib(int n) {
  if (n < 2)
    return 1;
  return fib(n-1) + fib(n-2)
}

... and sit back and watch the stack overflow.

The iterative solution is:

int fib(int n) {
  if (n < 2)
    return 1;
  int n_1 = 1, n_2 = 1;
  for (int i = 2; i <= n; i += 1) {
    int n_new = n_1 + n_2;
    n_1 = n_2;
    n_2 = n_new;
  }
  return n_2;
}

Notice how we're essentially calculating the next term n_new from previous terms n_1 and n_2, then "shuffling" all the terms down for the next iteration. With a running time linear on the value of n, it's a matter of a few seconds for n in the billions (well after integer overflow for your intermediate variables) on a modern gigahertz machine.

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arbitrary precision for sqrt(5) :D –  Andreas Grapentin Feb 2 '13 at 12:00
    
@AndreasGrapentin: yep. Do the analysis, figure out how much precision you need, and then approximate at that precision. –  sheu Feb 2 '13 at 12:01
    
I know the drill. I just wanted to point out that the iterative way is probably more efficient than arbitrary length floating point operations. :) –  Andreas Grapentin Feb 2 '13 at 12:08
    
@AndreasGrapentin: not necessarily. There's a crossover point at which (cheap) iterative integer arithmetic, which still requires iterating all the way up to n, becomes more expensive in aggregate than arbitrary-precision math. –  sheu Feb 2 '13 at 12:09
    
all the way up to n in logarithmic number of steps is not too bad. WP has it all. –  Will Ness Feb 2 '13 at 12:16

Most of the people already gave you link explaining the finding of Nth Fibonacci number, by the way Power algorithm works the same with minor change.

Anyways This is my O(log N) solution.

package edu.algo1;

/**
 * <u>Fibonacci algorithm</u>
 * @author Orel Eraki
 *
 */
public class algFibonacci {

    // O(log2 n)
    public static int Fibonacci(int n) {

        int num = Math.abs(n);
        if (num == 0) {
            return 0;
        }
        else if (num <= 2) {
            return 1;
        }

        int[][] number = { { 1, 1 }, { 1, 0 } };
        int[][] result = { { 1, 1 }, { 1, 0 } };

        while (num > 0) {
            if (num%2 == 1) result = MultiplyMatrix(result, number);
            number = MultiplyMatrix(number, number);
            num/= 2;
        }
        return result[1][1]*((n < 0) ? -1:1);
    }

    public static int[][] MultiplyMatrix(int[][] mat1, int[][] mat2) {
        return new int[][] {
                { mat1[0][0]*mat2[0][0] + mat1[0][1]*mat2[1][0], mat1[0][0]*mat2[0][1] + mat1[0][1]*mat2[1][1] },
                { mat1[1][0]*mat2[0][0] + mat1[1][1]*mat2[1][0], mat1[1][0]*mat2[0][1] + mat1[1][1]*mat2[1][1] }
        };
    }

    public static void main(String[] args) {
        System.out.println(Fibonacci(-8));
    }
}
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First, you can formed an idea of ​​the highest term from largest known Fibonacci term. also see stepping through recursive Fibonacci function presentation. A interested approach about this subject is in this article. Also, try to read about it in the worst algorithm in the world?.

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I have a source code in c to calculate even 3500th fibonacci number :- for more details visit

http://codingloverlavi.blogspot.in/2013/04/fibonacci-series.html

source code in C :-

#include<stdio.h>
#include<conio.h>
#define max 2000

int arr1[max],arr2[max],arr3[max];

void fun(void);

int main()
{
    int num,i,j,tag=0;
    clrscr();
    for(i=0;i<max;i++)
        arr1[i]=arr2[i]=arr3[i]=0;

    arr2[max-1]=1;

    printf("ENTER THE TERM : ");
    scanf("%d",&num);

    for(i=0;i<num;i++)
    {
        fun();

        if(i==num-3)
            break;

        for(j=0;j<max;j++)
            arr1[j]=arr2[j];

        for(j=0;j<max;j++)
            arr2[j]=arr3[j];

    }

    for(i=0;i<max;i++)
    {
        if(tag||arr3[i])
        {
            tag=1;
            printf("%d",arr3[i]);
        }
    }


    getch();
    return 1;
}

void fun(void)
{
    int i,temp;
    for(i=0;i<max;i++)
        arr3[i]=arr1[i]+arr2[i];

    for(i=max-1;i>0;i--)
    {
        if(arr3[i]>9)
        {
            temp=arr3[i];
            arr3[i]%=10;
            arr3[i-1]+=(temp/10);
        }
    }
}
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here is a short python code, works well upto 7 digits. Just requires a 3 element array

def fibo(n):
    i=3
    l=[0,1,1]
    if n>2:
        while i<=n:
            l[i%3]= l[(i-1) % 3] + l[(i-2) % 3]
            i+=1
    return l[n%3]
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I agree with @WayneRooney. I just want to supplement his answer with some references of interest:

Here you can find the implementation of the algorithm in C++:

Elements of Programming, 3.6 Linear Recurrences, by Alexander Stepanov and Paul McJones
http://www.amazon.com/Elements-Programming-Alexander-Stepanov/dp/032163537X

And here other important references:

The Art of Computer Programming, Volume 2, 4.6.3. Evaluation of Powers, exercise 26, by Donald Knuth

An algorithm for evaluation of remote terms in a linear recurrence sequence, Comp. J. 9 (1966), by J. C. P. Miller and D. J. Spencer Brown
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More elegant solution in python

def fib(n):
  if n == 0: 
    return 0
  a, b = 0, 1
  for i in range(2, n+1):
    a, b = a+b, max(a, b)
  return max(a, b)
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I have written a small code to compute Fibonacci for large number which is faster than conversational recursion way.

I am using memorizing technique to get last Fibonacci number instead of recomputing it.


public class FabSeries { private static Map memo = new TreeMap<>();

public static BigInteger fabMemorizingTech(BigInteger n) {
    BigInteger ret;
    if (memo.containsKey(n))
        return memo.get(n);
    else {
        if (n.compareTo(BigInteger.valueOf(2)) <= 0)
            ret = BigInteger.valueOf(1);
        else
            ret = fabMemorizingTech(n.subtract(BigInteger.valueOf(1))).add(
                    fabMemorizingTech(n.subtract(BigInteger.valueOf(2))));
        memo.put(n, ret);
        return ret;
    }

}

public static BigInteger fabWithoutMemorizingTech(BigInteger n) {
    BigInteger ret;
    if (n.compareTo(BigInteger.valueOf(2)) <= 0)
        ret = BigInteger.valueOf(1);
    else

        ret = fabWithoutMemorizingTech(n.subtract(BigInteger.valueOf(1))).add(
                fabWithoutMemorizingTech(n.subtract(BigInteger.valueOf(2))));
    return ret;
}

   public static void main(String[] args) {
    Scanner scanner = new Scanner(System.in);
    System.out.println("Enter Number");

    BigInteger num = scanner.nextBigInteger();

    // Try with memorizing technique
    Long preTime = new Date().getTime();
    System.out.println("Stats with memorizing technique ");
    System.out.println("Fibonacci Value : " + fabMemorizingTech(num) + "  ");
    System.out.println("Time Taken : " + (new Date().getTime() - preTime));
    System.out.println("Memory Map: " + memo);

    // Try without memorizing technique.. This is not responsive for large
    // value .. can 50 or so..
    preTime = new Date().getTime();
    System.out.println("Stats with memorizing technique ");
    System.out.println("Fibonacci Value : " + fabWithoutMemorizingTech(num) + " ");
    System.out.println("Time Taken : " + (new Date().getTime() - preTime));

}

}

Enter Number

40

Stats with memorizing technique

Fibonacci Value : 102334155

Time Taken : 5

Memory Map: {1=1, 2=1, 3=2, 4=3, 5=5, 6=8, 7=13, 8=21, 9=34, 10=55, 11=89, 12=144, 13=233, 14=377, 15=610, 16=987, 17=1597, 18=2584, 19=4181, 20=6765, 21=10946, 22=17711, 23=28657, 24=46368, 25=75025, 26=121393, 27=196418, 28=317811, 29=514229, 30=832040, 31=1346269, 32=2178309, 33=3524578, 34=5702887, 35=9227465, 36=14930352, 37=24157817, 38=39088169, 39=63245986, 40=102334155}

Stats without memorizing technique

Fibonacci Value : 102334155

Time Taken : 11558

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