If you want to find out the value of fib(n) for large n, you need to use the Matrix Exponentiation Method i.e. the one used for solving linear recurrence equations.
The great advantage of matrix exponentiation is that its running time is simply O(k^3 * logN) where N is the power of the matrix we are calculating and k is the size of the matrix.
Check the below mentioned python code snippets which calculates fibonacci for large n (mods with 10^9+7, to have the number in int range). You can find the detailed explanation of the same in this blog.
matrix_mult function multiplies the two matrices given as argument and returns their product.
def matrix_mult(A, B):
C = [[0, 0], [0, 0]]
for i in range(2):
for j in range(2):
for k in range(2):
C[i][k] = (C[i][k] + (A[i][j]*B[j [k])%mod)%mod
fast_expo function calculates and returns (matrix^power) and this is the function responsible for O(logn) running time.
def fast_expo(matrix, power):
matrix1 = fast_expo(matrix, power/2)
return matrix_mult(matrix1, matrix1)
return matrix_mult(matrix, fast_expo(matrix, power-1))
The function is called with the precomputed matrix as one of the parameter. In the case of fibonacci, the matrix is [[1, 1], [1, 0]].
matrix = [[1, 1], [1, 0]]
matrix_n = fast_exponentiation(matrix, number-2)
print (matrix_n + matrix_n) % 1000000007
That power here should be M^(n-2) for all n>2 where M is the base Matrix, because you already have the first 2 values of f(n) i.e. f(1) and f(2).