Goal: find a way to formally define a grammar that recognizes elements from a set 0 or 1 times in any order. Subsequently, I want to parse it and generate an AST as well.

For example: Say the set of valid strings in my language is `{A, B, C}`

. I want to define a grammar that recognizes all valid permutations of any number of those elements.

Syntactically valid strings would include:

- (the empty string)
`A`

,`B A`

, and`C A B`

Syntactically invalid strings would include:

`A A`

, and`B A C B`

To be clear, defining all possible permutations explicitly in a CFG is unacceptable for my purposes, since larger sets would be impossible to maintain.

From what I understand, such a language fails the pumping lemma for context free languages, so the solution will not be context free or regular.

## Update

What I'm after is called a "permutation language", which Benedek Nagy has done some theoretical work on as an extension to context free languages.

Regarding a parser generator, I've only found talk of implementing parsers with a permutation phase (link). Parsers evidently have an exponential lower bound on the size of resulting CFG, and I haven't found any parser generators that support it anyhow.

A sort-of solution to this problem was written in ANTLR. It uses semantic predicates to 'code around' the issue.

`w1|w2|w3|w4...|wlast`

, which is obviously a regular expression.) That fact is not of much use to you, but it's still a fact. – rici Aug 27 '13 at 1:52