what is the fastest method to calculate this, i saw some people using matrices and when i searched on the internet, they talked about eigen values and eigen vectors (no idea about this stuff)...there was a question which reduced to a recursive equation f(n) = (2*f(n1)) + 2 , and f(1) = 1, n could be upto 10^9.... i already tried using DP, storing upto 1000000 values and using the common fast exponentiation method, it all timed out im generally weak in these modulo questions, which require computing large values
3 Answers
f(n) = (2*f(n1)) + 2 with f(1)=1
is equivalent to
(f(n)+2) = 2 * (f(n1)+2)
= ...
= 2^(n1) * (f(1)+2) = 3 * 2^(n1)
so that finally
f(n) = 3 * 2^(n1)  2
where you can then apply fast modular power methods.

For the Germanspeaking ones interested, I vaguely remember the topic covered in the textbook "Algorithmische Zahlentheorie" by Otto Forster.– CodorMay 24, 2014 at 19:04
Modular exponentiation by the squareandmultiply method:
function powerMod(b, e, m)
x := 1
while e > 0
if e%2 == 1
x, e := (x*b)%m, e1
else b, e := (b*b)%m, e//2
return x
C code for calculating 2^n
const int mod = 1e9+7;
//Here base is assumed to be 2
int cal_pow(int x){
int res;
if (x == 0) res=1;
else if (x == 1) res=2;
else {
res = cal_pow(x/2);
if (x % 2 == 0)
res = (res * res) % mod;
else
res = (((res*res) % mod) * 2) % mod;
}
return res;
}


didn't check the result, but seeing it what it does, you should remove it from time being Jun 11, 2019 at 6:24

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