First of all, I believe you mean the *complement* of a regular expression, not it's inverse. The inverse of a regular expression doesn't make much sense; but if viewed as a function, I suppose you could say that the inverse of the matcher is the generator which generates all matching strings - or something. On the other hand, the *complement* of a language is all those strings *not* in the original language.

Then, there are two views to consider here:

## Fundamentally

The complement of a regular language is regular. That means it's possible to generate an accepting DFA for the complement (and doing so is very simple, actually: just swap the non-accepting state set with the accepting state set). Any such DFA can be expressed as a regular expression - so in principle you can indeed make such a regex.

See the wikipedia article on Regular Languages as a starting point.

## Practically

The typical perl-compatible regex syntax used in most modern languages nowadays does not have a complementation operator. For a *complete* regex, you can get something similar by using the negative lookahead operator: `(?!X)`

will match a string precisely when `X`

will not. However, this is a poor replacement for complement operator as you will not be able to use it as a part of a larger regex in the usual fashion; this regex doesn't "consume" input which means it behaves differently in conjunction with other operators.

For example, if you match numeric strings as `[0-9]*`

, to match the entire string you'd prepend `^`

and append `$`

, but to use this technique to find the complement you'd need to write `^(?!^[0-9]*$).*$`

- and the usual concatenation of such a negated regex is, as far as I can tell, undoable.

Somewhat ironically, the practical incarnation of regexes is *theoretically* more powerful due to backreferences, but *practically* less flexible since the language can't quite express the complement and intersection operations easily.