# How can I expand a finite pattern into all its possible matches?

For example, given the pattern

``````[a-zA-Z]_[0-9]{2}
``````

a function would take the pattern and return an array or list containing

``````a_00, a_01, a_02, ... , a_98, a_99, ... , z_98, z_99
``````

Only numbers and letters (and finite groupings thereof) need be expanded. How would I go about doing this? An example in Python or Perl would be preferred. Thank you!

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That are 5200 matches. Sure you want to have it? And sorry, I can't do python or perl. – Dykam Aug 8 '09 at 10:41
I'd be cautious too. The number of possible combinations grows exponentially with respect to the regex lenght, so anything but short strings can be very time and memory consuming. – Agos Aug 8 '09 at 10:47
@etotheipi: instead of explaining your percieved solution to the problem, instead tell us what you are actually trying to achieve... – Mitch Wheat Aug 8 '09 at 10:48
@Mitch Wheat: This is in the top 10 of the "forever comments". I wish I could upvote it more than once. – Tomalak Aug 8 '09 at 10:50

First, parse the expression and build a tree reflecting the syntactic structure of the regular expression, and include a terminator node that logically appears at the end. For example, in lisp notation, your example might look like this:

``````(concat
(repeat 2
(concat
(charset
(range a z)
(range A Z))
(literal _)
(charset
(range 0 9))))
terminator)
``````

Next, thread the tree so that you can use recursion to generate the combinatorial expansion. By that, I mean e.g. that nodes `a..z` in `(concat a .. z)` all need to have pointers from one to the next, so `a` points to `b`, and so on, and the `concat` node itself points to its successor. The idea is that you can produce one version of the current element in the expansion, and recurse into the next element, and when the next element returns you can try the next version of the current element, etc., until all versions are exhausted and you return to your caller (the predecessor or parent). This threading is easiest done with a stack and a post-order traversal of the tree. If you carefully push nodes during post-order traversal, the top of the stack will be the next element in sequence.

(An alternative to threading is to structure the tree so that the next element in every `concat` node is a child of the previous node, and `repeat` nodes' children point back to the repeat node.)

Then write a routine (or set of routines using pattern matching, or virtual methods if nodes in the tree are implemented using polymorphism in an object-oriented language) that, for any given node type, produces the correct output and recurses into the next node or children in the appropriate way. For example, in pseudocode:

``````if node is of form (repeat n): # non-variable repeat
for i in 1 to n
recurse into child

if node is of form (concat ...):
recurse into first element # last element will recurse into successor

if node is of form (literal x):
emit x
recurse into successor
remove x

if node is of form (charset ...):
for each element in charset:
emit element
recurse into successor
remove element

if node is terminator:
add string created thus far to final output list
``````

etc. As you can observe, children of a repeat node mustn't recurse into the successor of the `repeat` node, so that needs to be taken into account when threading the tree. Similar care needs to be taken that "current progress" isn't lost when reaching the end of child nodes of a `repeat` node; alternatively, the successor of child nodes could point to the repeat node itself (i.e. a true closure over the graph of nodes), but that will require storing a counter somewhere.

All in all, completing this could take several days, depending on how flexible and performant it needs to be. Also note that certain constructs, such as Kleene star or closure (`*` or `+` in extended regex) will result in an infinite list. A language that supports generators (e.g. C#'s iterator syntax) or coroutines / continuations (e.g. Scheme's call/cc) or lazy evaluation (e.g. Haskell) can permit iteration over the first few elements of the list without having to evaluate the entire list. Alternatively, choosing random potential output rather than exhaustive iteration may be preferable for providing examples corresponding to a regular expression.

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Answers like this make SO work. Thank you for such a comprehensive answer. – juanpaco Jan 10 '13 at 16:39

Given that you can figure out the length of strings of matching lengths, you could brute force it by generating all possible strings with the correct lengths and then just try to match.

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