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
return C
```

*fast_expo* function calculates and returns (matrix^power) and this is the function responsible for O(logn) running time.

```
def fast_expo(matrix, power):
if(power==1):
return matrix
else:
if(power%2==0):
matrix1 = fast_expo(matrix, power/2)
return matrix_mult(matrix1, matrix1)
else:
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[0][0] + matrix_n[0][1]) % 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).