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This sequence satisfies a(n+2) = 2 a(n+1) + 2 a(n).

and also a(n)=[(1+sqrt(3))^(n+2)-(1-sqrt(3))^(n+2)]/(4sqrt(3)).

I am using C++ for me n can vary from 1 to 10^ 9. I need the answers modulo (10^9)+7 But speed here is very important

My code with formula1 is slow for numbers > 10^7

#include <iostream>
#define big unsigned long long int
int ans[100000001]={0};

big m  =1000000007;
using namespace std;
int main()
    //cout << "Hello world!" << endl;
    big t,n;
    big a,b,c;
    for(big i=3;i<=100000000;i++)


//    while(t--)
//    {
//        int f=0;
//        cin>>n;
//        if(n==1){
//        cout<<1<<endl;f++;}
//        if(n==2){
//        cout<<3<<endl;
//        f++;
//        }
//        if(!f){
//        a=1;
//        b=3;
//        c=8;
//        for(big i=3;i<=n;i++)
//        {
//            c=(((((a)+(b
//                         )))%m)<<1)%m;
//            a=b%m ;
//            b=c%m;
//        }
//        cout<<ans[n]<<endl;
//        }
//    }
    return 0;

I want a faster method. How can I compute the nth term using the second formula.Is there any trick to calculate modular powers of decimals very quickly? Do you have any suggestions for faster generation of this sequence?

Please help

share|improve this question
Why is there a seemingly endless series of questions on SO involving mod 1e9+7? –  Oliver Charlesworth Jul 2 '12 at 22:55
@OliCharlesworth It's a common modulus for online judges. I guess it's used so often because it's simple in decimal form, prime, and there's no problem calculating powers modulo that with 64-bit integers. –  Daniel Fischer Jul 2 '12 at 22:57
The reason for this one is codechef.com/JULY12/problems/CSUMD. The OP should probably be honest about these things –  nikhil Jul 3 '12 at 5:07
Well Nilhil no offence,but I did know that fibonacci sequence could be generated in logn times .I didnt know that method could bee generalized to solve any linear recursion.Also,I am not a shallow minded person to just ask for code,I am asking for approach,also I did derive the recursion.They are somethings you can not come to know even with google as you don't know what to search for.Good luck to you.Hope you don't mind.Thanks everyone. –  Ajax Aristodemos Jul 3 '12 at 19:10

2 Answers 2

up vote 10 down vote accepted

You can calculate values of sequences with a linear recurrence relation in O(log n) steps using the matrix method. In this case, the recurrence matrix is

2 2
1 0

The n-th term of the sequence is then obtained by multiplying the n-th power of that matrix with the two initial values.

The recurrence immediately translates to

|x_n    |   |2 2|   |x_(n-1)|
|x_(n-1)| = |1 0| * |x_(n-2)|


|x_(n+1)|   |2 2|^n   |x_1|
|x_n    | = |1 0|   * |x_0|.

In this case the initial conditions give, x_1 = 1, x_2 = 3 lead to x_0 = 0.5, a non-integer value, hence the calculation should rather be

|x_(n+1)|   |2 2|^(n-1)   |x_2|
|x_n    | = |1 0|       * |x_1|.

To get the value modulo some number, calculate the power of the matrix modulo that number.

share|improve this answer
This is fascinating - in all the maths I have studied I have never seen this approach before. I don't suppose you would be good enough to provide a link to where this is explained or at least the name for this method so I can go and take a more in depth look??? –  mathematician1975 Jul 2 '12 at 22:40
For the Fibonacci sequence, see here, more general here. For recurrences including many previous values, it's better to reduce it to calculating X^n modulo the characteristic polynomial (thanks for Cayley-Hamilton ;), but for just the two previous values that's usually not a big difference. –  Daniel Fischer Jul 2 '12 at 22:51
Thanks for that. –  mathematician1975 Jul 2 '12 at 22:56
@nikhil You have to multiply with [3,1], [[2 2],[1 0]] * [3,1] = [2*3+2*1,1*3+0*1] = [8,3], next, [[2 2],[1 0]] * [8,3] = [22,8] etc. Will edit to make that clear. –  Daniel Fischer Jul 3 '12 at 9:59
Ask you may, @nikhil, but I'm afraid I can't answer that, lost in the distant past. Besides, I wasn't the first to rediscover that recursion, afaik it's classical (meaning it's known since at least the 19-th century) and everybody investigating linear recursive sequences rediscovers it unless (s)he finds it in the literature before. –  Daniel Fischer Jul 3 '12 at 12:43

I don't want to spoil of the fun of exploring the solution of algorithmic puzzles, so I'll just give you a starting hint: What you have there is basically a Fibonacci sequence with a few confusing elements.

share|improve this answer
There is a very specific question posted by OP. Numbers greater than 10E7 is a problem. This is not a good answer nor hint. –  Captain Giraffe Jul 2 '12 at 22:44
The problem is that he wants to calculate it linearly, and he needs to think out of the box first, before he can go on with solving it: see DF's answer for example, which I tried evade, but shows the path more in depth. At any rate, the first step is always to know what information are you looking for. IMHO –  hege Jul 2 '12 at 22:50
I was unaware of the online competition stuff. However this is a comment you can make. Not an answer. –  Captain Giraffe Jul 2 '12 at 23:13
In my opinion it's a great hint. What's the point of spoon feeding the OP when they are trying to solve a problem in a coding contest. –  nikhil Jul 3 '12 at 5:10

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