Suppose you want to maximize the minimum distance. First, count how many of each type of item you have (the sum of all of these should be the number of items,
n, in the list). Sort the list of unique kinds of items according to their frequencies. Then, prepare an output tape with
n cells. Starting with the most frequent element, evenly place the elements in the output tape at regular intervals. Continue in decreasing order of item frequency, considering only empty cells on the tape. This is
O(n + m log m), where
n is the total number of items and
m is the number of unique items (i.e., kinds of items). Note that, in this case, you can probably get away with using a linear sorting algorithm on the kinds of items, so you could lose the
log m factor, although in practice (for 100 items, and presumably many fewer kinds of items) I don't know whether it would be worth it.
On your example: [M, M, F, B, F, B]. We have (M, 2), (F, 2), (B, 2). We get [M, _, _, M, _, _] after the first pass, [M, F, _, M, F, _] after the second and [M, F, B, M, F, B] after the third.
Note that this is a heuristic, and I suspect that it may be optimal, but I have not attempted to demonstrate that this is optimal, not even to myself. However, if you have
n elements and the most frequent element appears
x times, the most the minimum distance could possibly be is
floor(n/x) (EDIT: this isn't actually true, see my comment)... and that's what this heuristic is shooting for. There's a question, I suppose, of how to space items "evenly" if the numbers aren't even divisors... but even for examples I try where this occurs, just about any choice is OK w.r.t. the criterion we're optimizing against. A slightly harder example:
[A, A, A, A, A, B, B, B, C, C, D] gives us (A, 5), (B, 3), (C, 2), (D, 1); we get [A, _, A, _, A, _, A, _, A, _, _] after the first pass, [A, B, A, _, A, B, A, _, A, B, _] after the second pass, [A, B, A, C, A, B, A, C, A, B, _] after the third pass and we end up with [A, B, A, C, A, B, A, C, A, B, D]. Good enough for government work.
I can't think of an easy way to do better than this for minimizing the average distance, in fact. This should be plenty fast... is it close enough for your friend's needs?