This problem is known as Partition Problem, see detail in the referenced link from wiki:

One way of getting a handle on the partition function involves an
intermediate function p(k, n), which represents the number of
partitions of n using only natural numbers at least as large as k. For
any given value of k, partitions counted by p(k, n) fit into exactly
one of the following categories:

```
smallest addend is k
smallest addend is strictly greater than k.
```

The number of partitions meeting the first condition is p(k, n − k).
To see this, imagine a list of all the partitions of the number n − k
into numbers of size at least k, then imagine appending "+ k" to each
partition in the list. Now what is it a list of? As a side note, one
can use this to define a sort of recursion relation for the partition
function in term of the intermediate function, namely

```
1+ sum{k=1 to floor (1/2)n} p(k,n-k) = p(n),
```

The number of partitions meeting the second condition is p(k + 1, n)
since a partition into parts of at least k that contains no parts of
exactly k must have all parts at least k + 1.

Since the two conditions are mutually exclusive, the number of
partitions meeting either condition is p(k + 1, n) + p(k, n − k). The
recursively defined function is thus:

```
p(k, n) = 0 if k > n
p(k, n) = 1 if k = n
p(k, n) = p(k+1, n) + p(k, n − k) otherwise.
```

In fact you can calculate all values by memoization, to prevent from extra recursive calls.

**Edit:** As unutbu mentioned in his comment, at the end of calculation you should subtract 1 to output the result. I.e. all of the `P`

values up to the last step should be calculated as wiki suggests, however at the very in the very end before outputting the result, You should subtract it by `1`

.