There's a trick. Let `G(n) = F(n) + 1`

. The equation

```
F(n) = F(n-1) + F(n-2) + F(n-1)*F(n-2)
```

becomes

```
G(n) - 1 = G(n-1) - 1 + G(n-2) - 1 + (G(n-1) - 1) * (G(n-2) - 1)
= G(n-1) - 1 + G(n-2) - 1 + G(n-1)*G(n-2) - G(n-1) - G(n-2) + 1
= G(n-1)*G(n-2) - 1,
```

so adding `1`

to both sides,

```
G(n) = G(n-1)*G(n-2).
```

This is the multiplicative equivalent of the familiar Fibonacci recurrence. The solution is

```
G(n) = G(0)^Fib(n-1) * G(1)^Fib(n),
```

by analogy with the theory of linear recurrences (where `Fib(-1) = 1`

and `Fib(0) = 0`

and `Fib(1) = 1`

), since

```
G(n-1)*G(n-2) = G(0)^Fib(n-2) * G(1)^Fib(n-1)
* G(0)^Fib(n-3) * G(1)^Fib(n-2)
= G(0)^Fib(n-1) * G(1)^Fib(n)
= G(n).
```

Hence,

```
F(n) = (F(0)+1)^Fib(n-1) * (F(1)+1)^Fib(n) - 1,
```

doing the `Fib`

computations via the matrix power method mod `p-1`

per Fermat's little theorem and the exponentiation mod `p`

.

`matrix exponentiation`

`N`

is`10^9`

and you need the whole number, not just it's value modulo something?8more comments