If you want to know the **number of ways** to do this, then you can use generating functions.

Essentially, you are interested in integer partitions. An integer partition of `X`

is a way to write `X`

as a sum of positive integers. Let `p(n)`

be the number of integer partitions of `n`

. For example, if `n=5`

then `p(n)=7`

corresponding to the partitions:

```
5
4,1
3,2
3,1,1
2,2,1
2,1,1,1
1,1,1,1,1
```

The the generating function for `p(n)`

is

```
sum_{n >= 0} p(n) z^n = Prod_{i >= 1} ( 1 / (1 - z^i) )
```

**What does this do for you?** By expanding the right hand side and taking the coefficient of `z^n`

you can recover `p(n)`

. Don't worry that the product is infinite since you'll only ever be taking finitely many terms to compute `p(n)`

. In fact, if that's all you want, then just truncate the product and stop at `i=n`

.

**Why does this work?** Remember that

```
1 / (1 - z^i) = 1 + z^i + z^{2i} + z^{3i} + ...
```

So the coefficient of `z^n`

is the number of ways to write

n = 1*a_1 + 2*a_2 + 3*a_3 +...

where now I'm thinking of `a_i`

as the number of times `i`

appears in the partition of `n`

.

**How does this generalize?** Easily, as it turns out. From the description above, if you only want the parts of the partition to be in a given set `A`

, then instead of taking the product over all `i >= 1`

, take the product over only `i in A`

. Let `p_A(n)`

be the number of integer partitions of `n`

whose parts come from the set `A`

. Then

```
sum_{n >= 0} p_A(n) z^n = Prod_{i in A} ( 1 / (1 - z^i) )
```

Again, taking the coefficient of `z^n`

in this expansion solves your problem. But we can go further and track the **number of parts** of the partition. To do this, add in another place holder `q`

to keep track of how many parts we're using. Let `p_A(n,k)`

be the number of integer partitions of `n`

into `k`

parts where the parts come from the set `A`

. Then

```
sum_{n >= 0} sum_{k >= 0} p_A(n,k) q^k z^n = Prod_{i in A} ( 1 / (1 - q*z^i) )
```

so taking the coefficient of `q^k z^n`

gives the number of integer partitions of `n`

into `k`

parts where the parts come from the set `A`

.

**How can you code this?** The generating function approach actually gives you an algorithm for generating all of the solutions to the problem as well as a way to uniformly sample from the set of solutions. Once `n`

and `k`

are chosen, the product on the right is finite.