You should *specify your optimization criterion*, that is, how much weight you give to "squareness" versus "emptiness".

As an example of such criterion, the following code minimizes emptiness subject to the number of rows and columns being greater than 1; and picks the more square-like option if there are several minimizing sizes:

```
mm = ceil(sqrt(N)):-1:2; %//possible numbers of rows. Reverse order. Do not consider 1
nn = ceil(N./mm); %//corresponding numbers of columns
excess = mm.*nn-N; %//number of empty cells
[val ind] = min(excess);
m = mm(ind)
n = nn(ind)
```

Note that `mm`

in the code is defined in reverse order so that `min`

will find the *last* minimizing value (more square-like) if there are more than one.

For example, `N=113`

gives the solution `m=6`

, `n=19`

, resulting in `1`

empty cell (=6*19-113). This solution is preferred to `m=57`

, `n=2`

or `m=38`

, `n=3`

(which also leave give 1 empty cell) because it is more square-like.

`[1 2 3 4 5 6 7]`

? How do you define "compact"? Minimize the number of wasted elements? Minimize the product of the dimensions? Minimize the sumo f the dimensions? – Dan Oct 23 '13 at 10:09`[1 2 3; 4 5 6; 7 NaN NaN]`

also preferred to`[1 2 3 4; 6 7 8 NaN]`

? And if so, why... can you give a rule that can be applied to all vectors? – Dennis Jaheruddin Oct 23 '13 at 10:27