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I have an array of elements whose key is a regex. I would like to come up with a fast algorithm that given a string (not a regex) will return in less than O(N) time what are the matching array values based on execution of the key regex.

Currently I do a linear scan of the array, for each element I execute the respective regex with posix regexec API, but this means that to find the matching elements I have to search across the whole array.

I understand if the aray was composed by only simple strings as key, I could have kept it orderer and use a bsearch style API, but with regex looks like is not so easy.

Am I missing something here?

Example follows

// this is mainly to be considered
// as pseudocode
typedef struct {
  regex_t  r;
  ... some other data
} value;

const char *key = "some/key";
value my_array[1024];
bool  my_matches[1024];
for(int i =0; i < 1024; ++i) {
  if(!regexec(&my_array[i].r, key, 0, 0, REG_EXTENDED))
    my_matches[i] = 1;
  else
    my_matches[i] = 0;
}

But the above, as you can see, is linear. Thanks

Addendum:

I've put together a simple executable which executed above algorithm and something proposed in below answer, where form a large regex it build a binary tree of sub-regex and navigates it to find all the matches.
Source code is here (GPLv3): http://qpsnr.youlink.org/data/regex_search.cpp
Compile with: g++ -O3 -o regex_search ./regex_search.cpp -lrt
And run with: ./regex_search "a/b" (or use --help flag for options)

Interestingly (and I would say as expected) when searching in the tree, it takes less number of regex to execute, but these are far more complex to run for each comparison, so eventually the time it takes balances out with the linear scan of vectors. Results are printed on std::cerr so you can see that those are the same.

When running with long strings and/or many token, watch out for memory usage; be ready to hit Ctrl-C to stop it from preventing your system to crash.

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Less than O(N) time? Assuming N = length of string, that doesn't seem possible. Every regex implementation I'm aware of runs linear in the size of the input string (case in point: RE2 by Google). –  delnan Jan 19 '13 at 19:51
1  
@delnan: I think he wants to search less than N keys (regex) to determine the bucket (key) to put the string in. –  nhahtdh Jan 19 '13 at 19:52
    
I don't think it is possible given the complexity of the modern regex. –  nhahtdh Jan 19 '13 at 19:53
1  
@nhahtdh Matching fewer than O(N) regexes, with N = number of regexes, doesn't appear possibly either, at least not without further knowledge about the regexes. In general, the results of running N-1 of the regexes against some string doesn't tell you a thing about what the Nth regex will do to it. (And even if one could skip a constant amount or fraction of the regexes, it would still be O(N), as that's kinda the point of big Oh notation.) –  delnan Jan 19 '13 at 19:53
1  
In the worst case, every regexp will match, so it's not possible to do better than O(N). –  Anonymous Jan 19 '13 at 20:36

1 Answer 1

This is possible but I think you would need to write your own regex library to achieve it.

Since you're using posix regexen, I'm going to assume that you intend to actually use regular expressions, as opposed to the random collection of computational features which modern regex libraries tend to implement. Regular expressions are closed under union (and many other operations), so you can construct a single regular expression from your array of regular expressions.

Every regular expression can be recognized by a DFA (deterministic finite-state automaton), and a DFA -- regardless of how complex -- recognizes (or fails to recognize) a string in time linear to the length of the string. Given a set of DFAs, you can construct a union DFA which recognizes the languages of all DFAs, and furthermore (with a slight modification of what it means for a DFA to accept a string), you can recover the information about which subset of the DFAs matched the string.

I'm going to try to use the same terminology as the Wikipedia article on DFAs. Let's suppose we have a set of DFAs M = {M1...Mn} which share a single alphabet Σ. So we have:

Mi = (Qi, Σ, δi, qi0, Fi) where Qi = {qij} for 0 ≤ j < |Qi|, and Qi ⊂ Fi.

We construct the union-DFA M = (Q, Σ, δ, q0) (yes, no F; I'll get to that) as follows:

q0 = <q10,...,qn0>

δ(<q1j1,...,qnjn>, α) = <δ1(q1j1, α),... , δn(qnjn, α)> for each α ∈ Σ

Q consists of all states reachable through δ starting from q0.

We can compute this using a standard closure algorithm in time proportional to the product of the sizes of the δi transition functions.

Now to do a union match on a string α1...αm, we run the union DFA in the usual fashion, starting with its start symbol and applying its transition function to each α in turn. Once we've read the last symbol in the string, the DFA will be in some state <q1j1,...,qnjn>. From that state, we can extract the set of Mi which would have matched the string as: {Mi | qiji ∈ Fi}.

In order for this to work, we need the individual DFAs to be complete (i.e., they have a transition from every state on every symbol). Some DFA construction algorithms produce DFAs which are lacking transitions on some symbols (indicating that no string with that prefix is in the language); such DFAs must be augmented with a non-accepting "sink" state which has a transition to itself on every symbol.

I don't know of any regex library which exposes its DFAs sufficiently to implement the above algorithm, but it's not too much work to write a simple regex library which does not attempt to implement any non-regular features. You might also be able to find a DFA library.

Constructing a DFA from a regular expression is potentially exponential in the size of the expression, although such cases are rare. (The non-deterministic FA can be constructed in linear time, but in some cases, the powerset construction on the NFA will require exponential time and space. See the Wikipedia article.) Once the DFAs are constructed, however, the union FA can be constructed in time proportional to the product of the sizes of the DFAs.

So it should be easy enough to allow dynamic modification to the set of regular expressions, by compiling each regex to a DFA once, and maintaining the set of DFAs. When the set of regular expressions changes, it is only necessary to regenerate the union DFA.

Hope that all helps.

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Is it equivalent to create a large regex with all regex keys like "^(key1|key2|another/key3|key4/.*|key5)$" to match a search key like key4/something and get all potential matches? Does this make sense? –  Emanuele Jan 19 '13 at 23:15
    
@Emanuele: exactly so. However, the large regex will not tell you which of the patterns matched; just that one of them did. It is also possible to do this: ^(key1)|(key2)|(another/key3)|(key4/.*)|(key5)$; this will tell you which was the first pattern which matched the entire string (by examining the captures and seeing which one is non-empty). But neither will tell you all of the patterns which matched, and that's where you would need your own regex functions. –  rici Jan 19 '13 at 23:37
    
Darn don't want to reinvent the wheel... –  Emanuele Jan 20 '13 at 0:00
    
@Emanuele, you might want to look at complang.org/ragel I haven't ever used it, but it's always seemed like something I ought to know more about :) –  rici Jan 20 '13 at 0:50
    
@rici: I am also thinking about something similar, but nice seeing a concrete answer. I still have some doubt about the complexity, so I will leave it for other to judge. –  nhahtdh Jan 20 '13 at 6:20

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