There may be a clever way to find the tightest triplet, as Anders Lindahl is pursuing, but I will focus on a more basic approach.

If I generate *all* triplets, then I can filter them afterward however I want, so I will start there. The best way I know to generate these uses recursion:

```
f[n_, 1] := {{n}}
f[n_, k_] := Join @@
Table[
{q, ##} & @@@ Select[f[n/q, k - 1], #[[1]] >= q &],
{q, #[[2 ;; ⌈ Length@#/k ⌉ ]] & @ Divisors @ n}
]
```

This function `f`

takes two integer arguments, the number to factor `n`

, and the number of factors to produce `k`

.

The section `#[[2 ;; ⌈ Length@#/k ⌉ ]] & @ Divisors @ n`

uses `Divisors`

to produce a list of all divisors of `n`

(including `1`

), and then takes from these from the second (to drop the `1`

) to the Ceiling of the number of divisors divided by `k`

.

For example, for `{n = 240, k = 3}`

the output is `{2, 3, 4, 5, 6, 8}`

The `Table`

command iterates over this list while accumulating results, assigning each element to `q`

.

The body of the `Table`

is `Select[f[n/q, k - 1], #[[1]] >= q &]`

. This calls `f`

recursively, and then selects from the result all lists that begin with a number `>= q`

.

`{q, ##} & @@@`

(also in the body) then "prepends" `q`

to each of these selected lists.

Finally, `Join @@`

merges the lists of these selected lists that are produced by each loop of `Table`

.

The result is all of the integer factors of `n`

into `k`

parts, in lexicographical order. Example:

```
In[]:= f[240, 3]
Out[]= {{2, 2, 60}, {2, 3, 40}, {2, 4, 30}, {2, 5, 24}, {2, 6, 20},
{2, 8, 15}, {2, 10, 12}, {3, 4, 20}, {3, 5, 16}, {3, 8, 10},
{4, 4, 15}, {4, 5, 12}, {4, 6, 10}, {5, 6, 8}}
```

With the output of the function/algorithm given above, one can then test triplets for quality however desired.

Notice that because of the ordering the last triplet in the output is the one with the greatest minimum factor. This will usually be the most "cubic" of the results, but occasionally it is not.

If the true optimum must be found, it makes sense to test starting from the right side of the list, abandoning the search if a better result is not found quickly, as the quality of the results decrease as you move left.

Obviously this method relies upon a fast `Divisors`

function, but I presume that this is either a standard library function, or you can find a good implementation here on StackOverflow. With that in place, this should be quite fast. The code above finds all triplets for n from 1 to 10,000 in 1.26 seconds on my machine.