The solution can be found using a chopping algorithm.

Use for example the 6. Then we have:

```
6
5+1
4+2
3+3
```

but we are not finished yet.

If we take the 5+1, and consider the +1 part as finished, because all other ending combinations are handled by the 4+2 and 3+3. So we need to apply the same trick to the 5.

```
4+1+1
3+2+1
```

And we can continue. But not mindlessly. Because for example 4+2 produces 3+1+2 and 2+2+2. But we don't want the 3+1+2 because we will have a 3+2+1. So we only use all productions of 4 where the lowest number is greater or equal than 2.

```
6
5+1
4+1+1
3+1+1+1
2+1+1+1+1
1+1+1+1+1+1
2+2+1+1
3+2+1
4+2
2+2+2
3+3
```

Next step is to put this in an algorithm.

Ok we need a recursive function that takes two parameters. The number to be chopped and the minimal value:

```
func CountCombinations(Number, Minimal)
temp = 1
if Number<=1 then return 1
for i = 1 to Floor(Number/2)
if i>=Minimal then
temp := temp + CountCombinations(Number-i, i)
end for
return temp
end func
```

To check the algorithm:

```
C(6,1) = 1 + C(5,1) + C(4,2) + C(3,3) = 11, which is correct.
C(5,1) = 1 + C(4,1) + C(3,2) = 7
C(4,1) = 1 + C(3,1) + C(2,2) = 5
C(3,1) = 1 + C(2,1) = 3
C(2,1) = 1 + C(1,1) = 2
C(1,1) = 1
C(2,2) = 1
C(3,2) = 1
C(4,2) = 1 + C(2,2) = 2
C(3,3) = 1
```

By the way, the number of combinations of 100:

```
CC(100) = 190569292
CC(100) = 190569291 (if we don't take into account 100 + 0)
```