The Fibonacci sequence is the sequence defined by

```
F(0) = 0
F(1) = 1
F(n + 2) = F(n) + F(n + 1).
```

The first few terms are 0, 1, 1, 2, 3, 5, and 8.

The most efficient way to compute the first N values is to iterate over an array using the above formula, resulting in `O(N)`

operations (`O(N²)`

if digit or bit operations are counted). The recursive implementation should be generally avoided, since it is `O(φ`

where ^{N})`φ`

is the golden ratio and is equal to `(1+sqrt(5))/2`

. However, by using a cache for already computed values, it can be as fast as the iterative implementation.

One efficient method for computing single Fibonacci numbers is

```
Fib(n) = Round( Power( 0.5*(1+Sqrt(5)), n ) / Sqrt(5) );
```

The square root and power have to be computed in sufficient precision, roughly, Fib(n) requires about 0.2*n decimal digits or about 0.7*n bits in the integer result.

Another method is based on the fact that the matrix

`( Fib[n+1] Fib[ n ] )`

`( Fib[ n ] Fib[n-1] )`

is the n-th power of the matrix

`( 1 1 )`

which is `( Fib[2] Fib[1] )`

`( 1 0 )`

equal to `( Fib[1] Fib[0] )`

This is the basis of a halving-and-squaring method that computes Fib[N] in `O(log(N))`

operations, completely in (big) integer arithmetic.

If one accounts for the complexity of big integer multiplication, the complexity raises to O( M(N) ) digit or bit operations, where M(d) is the complexity of the multiplication of numbers of bit length d. Typical methods have M(d)=O(d*log(d)) for FFT based multiplication, M(d)=O(d^{w}) with w=log_{2}(3) for Karatsuba and smaller w for the Toom-Cook methods.