Is there an algorithm that can produce a regular expression (maybe limited to a simplified grammar) from a set of strings such that the evaluation of all possible strings that match the regular expression reproduces the initial set of strings?

It is probably unrealistic to find such a algorithm for grammars of regular expressions with very "complicated" syntax (including arbitrary repetitions, assertions etc.), so let's start with a simplified one which only allows for an `OR`

of substrings:

`foo(a|b|cd)bar`

should match `fooabar`

, `foobbar`

and `foocdbar`

.

## Examples

Given the set of strings `h_q1_a`

, `h_q1_b`

, `h_q1_c`

, `h_p2_a`

, `h_p2_b`

, `h_p2_c`

, the desired output of the algorithm would be `h_(q1|p2)_(a|b|c)`

.

Given the set of strings `h_q1_a`

, `h_q1_b`

, `h_p2_a`

, the desired output of the algorithm would be `h_(q1_(a|b)|p2_a)`

. *Note that h_(q1|p2)_(a|b) would* not

*be correct because that expand to 4 strings, including*

`h_p2_b`

, which was not in the original set of strings.## Use case

I have a long list of labels which were all produced by putting together substrings. Instead of printing the vast list of strings, I would like to have a compact output indicating what labels are in the list. As the full list has been produced programmatically (using a finite set of pre- and suffixes) I expect the compact notation to be (potentially) much shorter than the initial list.

(The (simplified) regex should be as short as possible, although I am more interested in a practical solution than the best. The trivial answer is of course to just concatenate all strings like A|B|C|D|... which is, however, not helpful.)

`regexp-opt`

. See the source and a description. The code is well commented, so you might be able to port some of it. – legoscia Apr 4 '13 at 15:24`h_(?:q1|p2)_[a-c]`

, right? :) – zx81 Jun 7 at 11:47`?:`

is needed? But you're right that`[a-c]`

is shorter than`(a|b|c)`

. Usually, however, the substrings would be longer than one character. – fuenfundachtzig Jun 10 at 6:40