Mathematically, it is impossible to validate a regular expression using a regular expression. This is so because (formal) regular expressions can only recognize *regular languages*. A language is any *set* of strings. For example, the set of all decimal numbers is a language (which by the way can be described using a regular expression); the set of all valid regular expressions is also a language. *Regular* languages are languages that require only *fixed finite memory* (not a function of the input size) to be recognized.

The language that contains all valid regular expressions is not a regular language; hence it is impossible to recognize a regular expression using a regular expression.

To understand this, notice that regular expressions contain parentheses in them that must match. Hence, if an "(" has occurred, a ")" must occur later on. This is impossible to describe with a machine that has only fixed finite memory. For, if there *were* a way to do it, and your regular expression had a finite memory of *K* different states (for some integer K), an expression with K opening parentheses followed by K closing parentheses, though a valid regular expression would have been *unable* to be recognized by that machine -- a *contradiction* (notice that in formal languages, our assumption is that text processing occurs one character at a time, from left to right, which is the same for applied regular expressions). We call languages such as the one that describes regular expressions *context-free* and not *regular*.

(It is trivial to prove that regular expressions do not form a regular language using the *Pumping Lemma*)

So, there is a fundamental computer science problem in recognizing regular expressions using regular expressions: **It is mathematically impossible to do so.**

Regular languages are possible to be recognized by *finite-state automata*, i.e. machines with finite *states* but without memory. To overcome your problem, you need to add some memory which is dependant on the input size. Regular expressions, as they are context-free (fortunately they're not some obscure, hard-to-recognize type of language) can be recognized in linear time using a *push-down* automaton. This is a "for" loop that goes through the expression one token (usually a character) at a time and keeps track of what it's seen on a *stack*, i.e. it "pushes" data that it laters "pops" in a first-in-last-out fashion. (Example of data pushed to the stack: "I need to remember to find a matching `)' later on!"; you can "push" this as many times as you need; you can "pop" it later, when you need to check if you actually *needed* to have matched an opening parenthesis previously).

Of course, writing your own recognition engine for regular expressions would be a bit of an overhead -- but if you want to do it, you should know the above limitations. It would be more wise to employ an already existing mechanism to do it -- I suspect you could give that job to a regular expression library or a language that is more keen on handling regular expressions such as Perl; but the @-method doesn't sound like too bad of an idea after all: It may be slow, but your users may input terribly slow regular expressions anyway; and it may be a bad practice, but in your case it seems the best possible solution available.

Some related articles in Wikipedia:

I hope this helped!