# I want to generate the nth term of the sequence 1,3,8,22,60 ,164 in Order(1) or order of (nlogn)

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
#include<stdlib.h>
int ans[100000001]={0};

big m  =1000000007;
using namespace std;
int main()
{
//cout << "Hello world!" << endl;
big t,n;
cin>>t;
big a,b,c;
a=1;
b=3;
c=8;
ans[0]=0;
ans[1]=1;
ans[2]=3;
ans[3]=8;
for(big i=3;i<=100000000;i++)
{
ans[i]=(((((ans[i-2])+(ans[i-1])))%m)<<1)%m;

}

//    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;
//        }
//    }
while(t--)
{
cin>>n;
if(n<=100000000)
cout<<ans[n]<<endl;
else
cout<<rand()%m;
}
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?

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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

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)|
``````

thus

``````|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.

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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.

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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