# Speeding up the generation of the sequence using my code [duplicate]

I am trying to generate a sequence 1,3,8,22,60... which is basically a[n]=2*(a[n-1]+a[n-2]); Please refer to my question here I want to generate the nth term of the sequence 1,3,8,22,60 ,164 in Order(1) or order of (nlogn)

Here is my implementation of it in c++.But I think it is too slow.The code runs in around 5 seconds for the worst case whereas I want it to run it in less than 1 second. The method is order of log n. So 10^9 takes only 29 steps. Here is my code.Please suggest ways to speed it up or any mistake I am doing

``````#include <iostream>
#define big long long unsigned int
#include<vector>
#include<stdio.h>
#define _SECURE_SCL 0
big m =1000000007;
using namespace std;
vector <vector <big> > vectin(vector<vector <big> > a)
{
for(int i=0;i<2;i++)
{
vector <big> t;
for(int j=0;j<2;j++)
{
t.push_back(0);
}
a.push_back(t);
}
return a;
}
vector <vector <big> > unit(vector<vector <big> > a)
{
for(int i=0;i<2;i++)
{
vector <big> t;
for(int j=0;j<2;j++)
{   if(i!=j)
t.push_back(0);
else
t.push_back(1);
}
a.push_back(t);
}
return a;
}
vector<vector <big> > multi(vector<vector <big> > a,vector<vector <big> >b )
{
vector<vector <big> > c;
c=vectin(c);
for(big i=0;i<2;i++){

for(big j=0;j<2;j++)
{
for(big k=0;k<2;k++)
{
c[i][j]+=((a[i][k])*(b[k][j]))%m;
}
}
}
return c;
}

big modexp_rl(big a,big b, big n)
{
big r = 1;
while (1){
if (b&1)
r = ((r )*(a) ) % n;
b /= 2;
if (!b )
break;
a = ((a )* (a) )% n;
}
return r;
}

vector <vector <big> > modexs (big b,vector <vector <big> > a )
{
vector < vector <big > > r;
r=unit(r);
while(1)
{  // cout<<b<<endl;
if(b&1)
r=multi(r,a);
b/=2;

if(!b)
break;
a=multi(a,a);
}
return r;
}

void displayvector(vector < vector <big> > s)
{
for(big i=0;i<2;i++)
{
for(big j=0;j<2;j++)
{
cout<<s[i][j]<<"\t";
}
cout<<endl;
}

}

vector <big> mul2( vector < vector <big> > a)
{
vector <big> d;
d.push_back(3*a[0][0]+1*a[0][1]);
d.push_back(3*a[1][0]+1*a[1][1]);
return d;
}
int main()
{

vector < vector <big> > a;
vector <big> t1,t2;
t1.push_back(2);
t1.push_back(2);
a.push_back(t1);
t2.push_back(1);
t2.push_back(0);
a.push_back(t2);
//dv(a);
vector < vector <big> > ans;
big t,n;
//cin>>t;
//scanf("%lld,&t);
t=10000;
while(t--){
//cin>>n;
//scanf("%lld",&n);
n=1000000000;
ans=modexs(n-1,a);
vector <big> p;
p=mul2(ans);
//cout<<p[1]<<endl;
printf("%lld\n",p[1]);
//dv(ans);
}
return 0;
}
``````
-

## marked as duplicate by Alexey Frunze, Henrik, Paul R, Bo Persson, GravitonJul 5 '12 at 10:43

`a[n]=2*(a[n-1]+a[n]);` is it correct? – hamed Jul 4 '12 at 7:33
why `for` indices are declared as big not int? – hamed Jul 4 '12 at 7:40
Why ask the same question again? – Alexey Frunze Jul 4 '12 at 7:43
I think it's `1 1 3 8 22 60`, and `a[n] = 2*(a[n-1] + a[n-2])`. – Kerrek SB Jul 4 '12 at 7:43
Sir Frunze ,the purpose of the questions are different.The first question ask for approaches and this question seeks some optimization techniques. – Ajax Aristodemos Jul 4 '12 at 8:00

If there is no way to enhance the function, you can try to research multi-core programming and learn how to implement it. Take this as a reference. It will increase performance of processing. However, it will consume resources. Hope this helps.

-

If you know how many elements are going into your `a` vector, you should reserve space for that many before you run your algorithm. This is to avoid data copying when the vectors do dynamic resizing.

-
Or you can use deque instead of vector! – hamed Jul 4 '12 at 8:24
@hamed: True, it would be more efficient than dynamically resizing a vector. – jxh Jul 4 '12 at 8:31
I have tried deque no such improvement – Ajax Aristodemos Jul 4 '12 at 10:13

I plugged the generating function of the series into Wolfram Alpha, and it appears that the n th term is:

``````[ (1 + Q)^(1+n) - (1 - Q)^(1+n) ] / (4Q) ,
``````

where `Q = sqrt(3)`.

You may observe that `1 - Q` is smaller than unity in absolute value, and so the entire term is exponentially small for large `n`. That means that for large `n` you can just compute the first term and take the next biggest integer.

-