what would be the most efficient way to calculate the sum of Fibonacci numbers as:
sum between(inclusive of both) F(n) and F(m) where F(n) is the nth Fibonacci number and F(m) is the mth (with F(0)=0;F(1)=1).
E.g.
if n=0, m=3 the we need to find F(0)+F(1)+F(2)+F(3)=4;
Just by brute force it will take long time(as 0=<n<=m<10^9
). If it can be done via matrix exponentiation then how?
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Literally, the sum of your upper bound m, minus the sum of your lower bound n. 


Given that "the sum of the first n Fibonacci numbers is the (n + 2)nd Fibonacci number minus 1." (thanks, Wikipedia), you can calculate Update: found an old SO post, "nth fibonacci number in sublinear time", and (due to accuracy as mjv and Jim Lewis have pointed out in the comments), you can't really escape an 


Algorithm via matrix property explanation found here and here



F(m+2)  F(n+2)  2
isn't quite correct but you can figure it out given that the sum of fibo # to n is effectively F(n+2) 1 (hint: you want the sum inclusive of F(n) and hence you need to substract the sum of fibo # up ton1
and substract this from F(m+2) 2). Anyway... it looking and smelling likeHOMEWORK
, the SO community shouldn't help too much ;) – mjv Dec 5 '10 at 4:50