One option is the 'one-vs-all' approach, in which you create one classifier for each set you want to partition into, and select the set with the highest probability.

For example, say you want to classify objects with a label from `{1,2,3}`

. Then you can create three binary classifiers:

- C1 = 1 or (not 1)
- C2 = 2 or (not 2)
- C3 = 3 or (not 3)

If you run these classifiers on a new piece of data X, then they might return:

- C1(X) = 31.6% chance of being in 1
- C2(X) = 63.3% chance of being in 2
- C3(X) = 89.3% chance of being in 3

Based on these outputs, you could classify X as most likely being from class 3. (The probabilities don't add up to 1 - that's because the classifiers don't know about each other).

If your output labels are ordered (with some kind of meaningful, rather than arbitrary ordering). For example, in finance you want to classify stocks into {BUY, SELL, HOLD}. Although you can't *legitimately* perform a regression on these (the data is ordinal rather than ratio data) you *can* assign the values of -1, 0 and 1 to SELL, HOLD and BUY and then *pretend* that you have ratio data. Sometimes this can give good results even though it's not theoretically justified.