Assuming here you are looking for a way to get number of possibilities and not the actual possibilities.

First let's find a **recursive function**:

`f(n) = (f(n-6) >= 0? f(n-6) : 0) + (f(n-1) >= 0 ? f(n-1) : 0) + (f(n-2) >= 0 ? f(n-2) : 0) + (f(n-3) >= 0 ? f(n-3) : 0)`

base: `f(0) = 1`

and `f(n) = -infinity [n<0]`

The idea behind it is: You can always get to `0`

, by a no scoring game. If you can get to `f(n-6)`

, you can also get to `f(n)`

, and so on for each possibility.

Using the above formula one can easily create a recursive solution.

Note that you can even use **dynamic programming** with it, initialize a table with [-5,n], init `f[0] = 0`

and `f[-1] = f[-2] = f[-3] = f[-4] = f[-5] = -infinity`

and iterate over indexes `[1,n]`

to achieve the number of possibilities based on the the recursive formula above.

**EDIT:**

I just realized that a simplified version of the above formula could be:

`f(n) = f(n-6) + f(n-1) + f(n-2) + f(n-3)`

and base will be: `f(0) = 1`

, `f(n) = 0 [n<0]`

The two formulas will yield exactly the same result.