We can solve this mathematically.

Let's call our solution `s`

, and `p`

the subset of `s`

, where `s[i] > 0`

, that is, the set of represented numbers (any zero is a number or index that is not represented).

We can say that `n = sum of all frequencies = sum p`

Now let's call `p'`

the subset of `p`

without `s[0]`

, which are frequencies only of numbers greater than zero.

Clearly `sum p' = sum p - s[0] = length p`

, which is simply the count of how many numbers in `s`

are greater than zero.

Remember that `length p = length p' + 1`

. Now if `length p > 4`

, we know that `sum p' > 4`

and we are left with an `m`

length partition (`p'`

) that must sum to `m+1`

, where `m > 3`

. The only way this can be done is with `(m-1)`

1's and one 2, e.g., `[1,1,1,2]`

in the case of `m=4`

(by definition there are no zeros in `p'`

). Such a partition could not make sense as a solution to our problem, and so we see that `p`

, or the subset of numbers greater than zero in our solution, must have less than 5 elements.

Now we can solve for specific cases:

Every solution must have `s[0] > 0`

since a zero in the zero column would invalidate the solution.

`length p = 1`

would only be possible if `s[0]`

could be both zero and greater than zero at the same time.

`length p = 2`

implies `p' = [2]`

, and so there are two zeros and two 2's, `s=[2,0,2,0]`

`length p = 3`

implies `p' = [1,2]`

. Since we know there is only one more `s[i]`

, which is `s[0] > 0`

, the 2 in `p'`

must either refer to itself, in which case we have `s=[2,1,2,0,0]`

; or to two 1's and therefore `s=[1,2,1,0]`

`length p = 4, p' = [2,1,1]`

. In this case the 2 could only be referring to the two 1's and we must assume `s[0] > 2`

, which also means `sum p >= (3+2+1+1 = 7)`

. This is the final / general case that user1125600 found: `s[1]=2, s[2]=1`

. The last 1 refers to `s[0]`

and so its index equals `s[0]`

. Remembering that `sum p - s[0] = length p`

, we get, `s[0] = n - 4`

, and the solution, for p = 4, n > 6: `s=[n - 4,2,1...1,0,0,0]`