32

I'm looking at matching glob-style patterns similar the what the Redis KEYS command accepts. Quoting:

  • h?llo matches hello, hallo and hxllo
  • h*llo matches hllo and heeeello
  • h[ae]llo matches hello and hallo, but not hillo

But I am not matching against a text string, but matching the pattern against another pattern with all operators being meaningful on both ends.

For example these patterns should match against each other in the same row:

prefix*       prefix:extended*
*suffix       *:extended:suffix
left*right    left*middle*right
a*b*c         a*b*d*b*c
hello*        *ok
pre[ab]fix*   pre[bc]fix*

And these should not match:

prefix*       wrong:prefix:*
*suffix       *suffix:wrong
left*right    right*middle*left
pre[ab]fix*   pre[xy]fix*
?*b*?         bcb

So I'm wondering ...

  • if this is possible to do (implement a verification algorithm), if at all?
  • if not possible, what subset of regex would be possible? (i.e. disallow * wildcard?)
  • if it is indeed possible, what is an efficient algorithm?
  • what are the time complexity required?

EDIT: Found this other question on RegEx subset but this is not exactly the same as the words that hello* and *ok matches is not a subset/superset of each other but they do intersect.

So I guess mathematically, this might be phrased as; is it possible to deterministically check that a set of words that one pattern match, intersecting with a set of words that another pattern matches, result in a non-empty set?


EDIT: A friend @neizod drew up this elimination table which neatly visualize what might be a potential/partial solution: Elimination rule


EDIT: Will adds extra bounty for those who can also provide working code (in any language) and test cases that proves it.


EDIT: Added the ?*b*? test case discovered by @DanielGimenez in the comments.

21
  • As I understand this question, you're asking if there's a way to determine if a pattern A matches a superset or subset of the words that another pattern B matches. Is that correct?
    – jpmc26
    Sep 9, 2013 at 10:01
  • @jpmc26 Yes that's correct.
    – chakrit
    Sep 9, 2013 at 10:03
  • Out of my league, for sure, but looks like it's just plain hard: stackoverflow.com/a/6364335/1394393. The part about "extensions" is probably referring to look around and modifiers like case sensitivity, but it doesn't sound like you need those.
    – jpmc26
    Sep 9, 2013 at 10:05
  • Also, I don't think hello* and *ok have that kind of relationship. The first would match hello world, but the second would not. The second would match grok, but the first would not. So while they do have an intersection, neither is a subset of the other.
    – jpmc26
    Sep 9, 2013 at 10:08
  • 2
    Possibly related? Sep 12, 2013 at 16:45

5 Answers 5

24
+150

Now witness the firepower of this fully ARMED and OPERATIONAL battle station!

(I have worked too much on this answer and my brain has broken; There should be a badge for that.)

In order to determine if two patterns intersect, I have created a recursive backtracking parser -- when Kleene stars are encountered a new stack is created so that if it fails in the future everything is rolled back and and the star consumes the next character.

You can view the history of this answer to determine how arrived at all this and why it was necessary, but basically it wasn't sufficient to determine an intersection by looking ahead only one token, which was what I was doing before.

This was the case that broke the old answer [abcd]d => *d. The set matches the d after the star, so the left side would still have tokens remaining, while the right side would be complete. However, these patterns two intersect on ad, bd, cd and dd, so that needed to be fixed. My almost O(N) answer was thrown out.

Lexer

The lexing process is trivial, except that is processes escape characters and removes redundant stars. Tokens are broken out into sets, stars, wild character (?), and character. This is different than my previous versions where one token was a string of characters instead of a single character. As more cases come up, having strings as tokens was more of a hindrance than advantage.

Parser

Most of the functions of the parser are pretty trivial. A switch given the left side's type, calls a function that is a switch that determines the appropriate function to compare it with the right side's type. The result from the comparison bubbles up the two switches to the original callee, typically the main loop of the parser.

Parsing Stars

The simplicity ends with the star. When that is encountered it takes over everything. First it compares its side's next token with the other side's, advancing the other side until if finds a match.

Once the match is found, it then checks if everything matches all the way up to the end of both patterns. If it does then the patterns intersect. Otherwise, it advances the other side's next token from the original one it was compared against and repeats the process.

When two anys are encountered then the take off into their own alternative branches starting from each others' next token.

function intersects(left, right) {
    var lt, rt,
        result = new CompareResult(null, null, true);

    lt = (!left || left instanceof Token) ? left : tokenize(left);
    rt = (!right || right instanceof Token) ? right : tokenize(right);

    while (result.isGood && (lt || rt)) {
        result = tokensCompare(lt, rt);

        lt = result.leftNext;
        rt = result.rightNext;
    }

    return result;
}

function tokensCompare(lt, rt) {
    if (!lt && rt) return tokensCompare(rt, lt).swapTokens();

    switch (lt.type) {
        case TokenType.Char: return charCompare(lt, rt);
        case TokenType.Single: return singleCompare(lt, rt);
        case TokenType.Set: return setCompare(lt, rt);
        case TokenType.AnyString: return anyCompare(lt, rt);
    }
}

function anyCompare(tAny, tOther) {
    if (!tOther) return new CompareResult(tAny.next, null);

    var result = CompareResult.BadResult;

    while (tOther && !result.isGood) {
        while (tOther && !result.isGood) {
            switch (tOther.type) {
                case TokenType.Char: result = charCompare(tOther, tAny.next).swapTokens(); break;
                case TokenType.Single: result = singleCompare(tOther, tAny.next).swapTokens(); break;
                case TokenType.Set: result = setCompare(tOther, tAny.next).swapTokens(); break;
                case TokenType.AnyString:
                    // the anyCompare from the intersects will take over the processing.
                    result = intersects(tAny, tOther.next);
                    if (result.isGood) return result;
                    return intersects(tOther, tAny.next).swapTokens();
            }

            if (!result.isGood) tOther = tOther.next;
        }

        if (result.isGood) {
            // we've found a starting point, but now we want to make sure this will always work.
            result = intersects(result.leftNext, result.rightNext);
            if (!result.isGood) tOther = tOther.next;
        }
    }

    // If we never got a good result that means we've eaten everything.
    if (!result.isGood) result = new CompareResult(tAny.next, null, true);

    return result;
}

function charCompare(tChar, tOther) {
    if (!tOther) return CompareResult.BadResult;

    switch (tOther.type) {
        case TokenType.Char: return charCharCompare(tChar, tOther); 
        case TokenType.Single: return new CompareResult(tChar.next, tOther.next);
        case TokenType.Set: return setCharCompare(tOther, tChar).swapTokens(); 
        case TokenType.AnyString: return anyCompare(tOther, tChar).swapTokens();
    }
}

function singleCompare(tSingle, tOther) {
    if (!tOther) return CompareResult.BadResult;

    switch (tOther.type) {
        case TokenType.Char: return new CompareResult(tSingle.next, tOther.next);
        case TokenType.Single: return new CompareResult(tSingle.next, tOther.next);
        case TokenType.Set: return new CompareResult(tSingle.next, tOther.next);
        case TokenType.AnyString: return anyCompare(tOther, tSingle).swapTokens();
    }
}
function setCompare(tSet, tOther) {
    if (!tOther) return CompareResult.BadResult;

    switch (tOther.type) {
        case TokenType.Char: return setCharCompare(tSet, tOther);
        case TokenType.Single: return new CompareResult(tSet.next, tOther.next);
        case TokenType.Set: return setSetCompare(tSet, tOther);
        case TokenType.AnyString: return anyCompare(tOther, tSet).swapTokens();
    }
}

function anySingleCompare(tAny, tSingle) {
    var nextResult = (tAny.next) ? singleCompare(tSingle, tAny.next).swapTokens() :
        new CompareResult(tAny, tSingle.next);
    return (nextResult.isGood) ? nextResult: new CompareResult(tAny, tSingle.next);
}

function anyCharCompare(tAny, tChar) {
    var nextResult = (tAny.next) ? charCompare(tChar, tAny.next).swapTokens() :
        new CompareResult(tAny, tChar.next);

    return (nextResult.isGood) ? nextResult : new CompareResult(tAny, tChar.next);
}

function charCharCompare(litA, litB) {
    return (litA.val === litB.val) ?
        new CompareResult(litA.next, litB.next) : CompareResult.BadResult;
}

function setCharCompare(tSet, tChar) {
    return (tSet.val.indexOf(tChar.val) > -1) ?
        new CompareResult(tSet.next, tChar.next) : CompareResult.BadResult;
}

function setSetCompare(tSetA, tSetB) {
    var setA = tSetA.val,
        setB = tSetB.val;

    for (var i = 0, il = setA.length; i < il; i++) {
        if (setB.indexOf(setA.charAt(i)) > -1) return new CompareResult(tSetA.next, tSetB.next);
    }
    return CompareResult.BadResult;
}

jsFiddle

Time Complexity

Anything with the words "recursive backtracking" in it is at least O(N2).

Maintainability and Readability

I purposely broke out any branches into there own functions with a singular switch. Assitionally I used named constants when a one character string would suffice. Doing this made the code longer and more verbose, but I think it makes it easier to follow.

Tests

You can view all the tests in the Fiddle. You can view the comments in the Fiddle output to glean their purposes. Each token type was tested against each token type, but I haven't made one that tried all possible comparisons in a single test. I also came up with a few random tough ones like the one below.

abc[def]?fghi?*nop*[tuv]uv[wxy]?yz => a?[cde]defg*?ilmn[opq]*tu*[xyz]*

I added an interface on the jsFiddle if anybody wants to test this out themselves. The logging is broken once I added the recursion.

I don't think I tried enough negative tests, especially with the last version I created.

Optimization

Currently the solution is a brute force one, but is sufficient to handle any case. I would like to come back to this at some point to improve the time complexity with some simple optimizations.

Checks at the start to reduce comparisons could increase processing time for certain common scenarios. For example, if one pattern starts with a star and one ends with one then we already know they will intersect. I can also check all the characters from the start and end of the patterns and remove them if the match on both patterns. This way they are excluded from any future recursion.

Acknowledgements

I used @m.buettner's tests initially to test my code before I came up with my own. Also I walked through his code to help me understand the problem better.

4
  • I have always wanted to see someone propose a proper parser for a pattern matching problem. =) +1 (Wish it could be more.)
    – jpmc26
    Sep 30, 2013 at 22:35
  • This is insane. Very powerful, thank you for your hard work on this one. Jul 2, 2016 at 5:24
  • If I wanted to update this code to handle cases like the ones below, what would be the best approach? "hello.one.world" matches "hello.(one|two).world" also "hello.one.world" matches "hello.one|two.world" Thank you! Jul 2, 2016 at 18:16
  • 1
    @KirkOuimet, this is probably an SO question on its own. I would start by creating the token types for alternation, scope open/close, and escaping characters. Alternation will break things the most. If a match fails then the parser will have to keep looking ahead to see if the alternation character exists, and then begin checking again where the scope starts. Creating scopes might be simple, they're just indexes where the "(" is found. If ")" is found and there is no scope then just treat it like a literal. Comparing an alternation to an alternation will be the hardest case.Good luck. Jul 5, 2016 at 13:04
7

With your very reduced pattern language, the pastebin link in your question and jpmc26's comments are pretty much all the way there: the main question is, whether the literal left and right end of your input strings match. If they do, and both contain at least one *, the strings match (because you can always match the other strings intermediate literal text with that star). There is one special case: if only one of them is empty (after removing pre- and suffix), they can still match if the other consists entirely of *s.

Of course, when checking whether the ends of the string match, you need to take into account the single-character wildcard ? and character classes, too. The single-character wildcard is easy: it cannot fail, because it will always match whatever the other character is. If it's a character class, and the other is just a character, you need to check whether the character is in the class. If they are both classes, you need to check for an intersection of the classes (which is a simple set intersection).

Here is all of that in JavaScript (check out the code comments to see how the algorithm I outlined above maps to the code):

var trueInput = [
    { left: 'prefix*', right: 'prefix:extended*' },
    { left: '*suffix', right: '*:extended:suffix' },
    { left: 'left*right', right: 'left*middle*right' },
    { left: 'a*b*c', right: 'a*b*d*b*c' },
    { left: 'hello*', right: '*ok' },
    { left: '*', right: '*'},
    { left: '*', right: '**'},
    { left: '*', right: ''},
    { left: '', right: ''},
    { left: 'abc', right: 'a*c'},
    { left: 'a*c', right: 'a*c'},
    { left: 'a[bc]d', right: 'acd'},
    { left: 'a[bc]d', right: 'a[ce]d'},
    { left: 'a?d', right: 'acd'},
    { left: 'a[bc]d*wyz', right: 'abd*w[xy]z'},
];

var falseInput = [
    { left: 'prefix*', right: 'wrong:prefix:*' },
    { left: '*suffix', right: '*suffix:wrong' },
    { left: 'left*right', right: 'right*middle*left' },
    { left: 'abc', right: 'abcde'},
    { left: 'abcde', right: 'abc'},
    { left: 'a[bc]d', right: 'aed'},
    { left: 'a[bc]d', right: 'a[fe]d'},
    { left: 'a?e', right: 'acd'},
    { left: 'a[bc]d*wyz', right: 'abc*w[ab]z'},
];

// Expects either a single-character string (for literal strings
// and single-character wildcards) or an array (for character
// classes).
var characterIntersect = function(a,b) {
    // If one is a wildcard, there is an intersection.
    if (a === '?' || b === '?')
        return true;

    // If both are characters, they must be the same.
    if (typeof a === 'string' && typeof b === 'string')
        return a === b;

    // If one is a character class, we check that the other
    // is contained in the class.
    if (a instanceof Array && typeof b === 'string')
        return (a.indexOf(b) > -1);
    if (b instanceof Array && typeof a === 'string')
        return (b.indexOf(a) > -1);

    // Now both have to be arrays, so we need to check whether
    // they intersect.
    return a.filter(function(character) {
        return (b.indexOf(character) > -1);
    }).length > 0;
};

var patternIntersect = function(a,b) {
    // Turn the strings into character arrays because they are
    // easier to deal with.
    a = a.split("");
    b = b.split("");

    // Check the beginnings of the string (up until the first *
    // in either of them).
    while (a.length && b.length && a[0] !== '*' && b[0] !== '*')
    {
        // Remove the first character from each. If it's a [,
        // extract an array of all characters in the class.
        aChar = a.shift();
        if (aChar == '[')
        {
            aChar = a.splice(0, a.indexOf(']'));
            a.shift(); // remove the ]
        }
        bChar = b.shift();
        if (bChar == '[')
        {
            bChar = b.splice(0, b.indexOf(']'));
            b.shift(); // remove the ]
        }

        // Check if the two characters or classes overlap.
        if (!characterIntersect(aChar, bChar))
            return false;
    }

    // Same thing, but for the end of the string.
    while (a.length && b.length && a[a.length-1] !== '*' && b[b.length-1] !== '*')
    {
        aChar = a.pop();
        if (aChar == ']')
        {
            aChar = a.splice(a.indexOf('[')+1, Number.MAX_VALUE);
            a.pop(); // remove the [
        }
        bChar = b.pop();
        if (bChar == ']')
        {
            bChar = b.splice(b.indexOf('[')+1, Number.MAX_VALUE);
            b.pop(); // remove the [
        }

        if (!characterIntersect(aChar, bChar))
            return false;
    }

    // If one string is empty, the other has to be empty, too, or
    // consist only of stars.
    if (!a.length && /[^*]/.test(b.join('')) ||
        !b.length && /[^*]/.test(b.join('')))
        return false;

    // The only case not covered above is that both strings contain
    // a * in which case they certainly overlap.
    return true;
};

console.log('Should be all true:');
console.log(trueInput.map(function(pair) {
    return patternIntersect(pair.left, pair.right);
}));

console.log('Should be all false:');
console.log(falseInput.map(function(pair) {
    return patternIntersect(pair.left, pair.right);
}));

It's not the neatest implementation, but it works and is (hopefully) still quite readable. There is a fair bit of code duplication with checking the beginning and the end (which could be alleviated with a simple reverse after checking the beginning - but I figured that would just obscure things). And there are probably tons of other bits that could be greatly improved, but I think the logic is all in place.

A few more remarks: the implementation assumes that the patterns are well-formatted (no unmatched opening or closing brackets). Also, I took the array intersection code from this answer because it's compact - you could certainly improve on the efficiency of that if necessary.

Regardless of those implementation details, I think I can answer your complexity question, too: the outer loop goes over both strings at the same time, a character at a time. So that's linear complexity. Everything inside the loop can be done in constant time, except the character class tests. If one character is a character class and the other isn't, you need linear time (with the size of the class being the parameter) to check whether the character is in the class. But this doesn't make it quadratic, because each character in the class means one less iteration of the outer loop. So that's still linear. The most costly thing is hence the intersection of two character classes. This might be more complex that linear time, but the worst it could get is O(N log N): after all, you could just sort both character classes, and then find an intersection in linear time. I think you might even be able to get overall linear time complexity, by hashing the characters in the character class to their Unicode code point (.charCodeAt(0) in JS) or some other number - and finding an intersection in a hashed set is possible in linear time. So, if you really want to, I think you should be able to get down to O(N).

And what is N? The upper limit is sum of the length of both patterns, but in most cases it will actually be less (depending on the length of prefixes and suffixes of both patterns).

Please point me to any edge-cases my algorithm is missing. I'm also happy about suggested improvements, if they improve or at least don't reduce the clarity of the code.

Here is a live demo on JSBin (thanks to chakrit for pasting it there).


EDIT: As Daniel pointed out, there is a conceptual edge-case that my algorithm misses out on. If (before or after elimination of the beginning and end) one string contains no * and the other does, there are cases, where the two still clash. Unfortunately, I don't have the time right now to adjust my code snippet to accommodate that problem, but I can outline how to resolve it.

After eliminating both ends of the strings, if both strings are either empty or both contain at least *, they will always match (go through the possible *-distributions after complete elimination to see this). The only case that's not trivial is if one string still contains *, but the other doesn't (be it empty or not). What we now need to do is walk both strings again from left to right. Let me call the string that contains * A and the one that doesn't contain * B.

We walk A from left to right, skipping all * (paying attention only to ?, character classes and literal characters). For each of the relevant tokens, we check from left to right, if it can be matched in B (stopping at the first occurrence) and advance our B-cursor to that position. If we ever find a token in A that cannot be found in B any more, they do not match. If we manage to find a match for each token in A, they do match. This way, we still use linear time, because there is no backtracking involved. Here are two examples. These two should match:

A: *a*[bc]*?*d* --- B: db?bdfdc
    ^                    ^
A: *a*[bc]*?*d* --- B: db?bdfdc
      ^                   ^
A: *a*[bc]*?*d* --- B: db?bdfdc
           ^               ^
A: *a*[bc]*?*d* --- B: db?bdfdc
             ^               ^

These two should not match:

A: *a*[bc]*?*d* --- B: dbabdfc
    ^                    ^
A: *a*[bc]*?*d* --- B: dbabdfc
      ^                   ^
A: *a*[bc]*?*d* --- B: dbabdfc
           ^               ^
A: *a*[bc]*?*d* --- B: dbabdfc
             !               

It fails, because the ? cannot possibly match before the second d, after which there is no further d in B to accommodate for the last d in A.

This would probably be easy to add to my current implementation, if I had taken the time to properly parse the string into token objects. But now, I'd have to go through the trouble of parsing those character classes again. I hope this written outline of the addition is sufficient help.

PS: Of course, my implementation does also not account for escaping metacharacters, and might choke on * inside character classes.

5
  • wow thanks for the extensive reply! I took the liberty and jsbin-ed your code over: jsbin.com/oVACiXe/3/edit?js,console .. will come back and read this over at end of day.
    – chakrit
    Sep 13, 2013 at 6:00
  • After re-reading your answer... and looking at that pastebin link again. I wonder if this can be done recursively which might be easier/ more clear&readable. (but yeah, it'd probably be less performant in the case of JS)
    – chakrit
    Sep 13, 2013 at 9:35
  • @DanielGimenez nice find for that test case!
    – chakrit
    Sep 18, 2013 at 4:43
  • @DanielGimenez oh, that's a good one. I think that might even be a conceptual flaw in my assumptions. I'll give it a closer look later on. Sep 18, 2013 at 5:41
  • @chakrit I figured out the flaw in my algorithm and added an explanation for how to correctly treat these cases as well. It can be done in another linear-time step after eliminating both ends of the string. Unfortunately, I lack the time to actually add this to my implementation, but I've written a (hopefully) extensive description for how to do it. Sep 19, 2013 at 19:46
6

These special patterns are considerably less powerful that full regular expressions, but I'll point out that it is possible to do what you want even with general regular expressions. These must be "true" regexes, i.e. those that use only Kleene star, alternation ( the | operation ), and concatenation with any fixed alphabet plus the empty string and empty set. Of course you can also use any syntactic sugar on these ops: one-or-more (+), optional (?). Character sets are just a special kind of alternation [a-c] == a|b|c.

The algorithm is simple in principle: Convert each regex to a DFA using the standard constructions: Thompson followed by powerset. Then use the cross product construction to compute the intersection DFA of the two originals. Finally check this intersection DFA to determine if it accepts at least one string. This is just a dfs from the start state to see if an accepting state can be reached.

If you are not familiar with these algorithms, it's easy to find Internet references.

If at least one string is accepted by the intersection DFA, there is a match between the original regexes, and the path discovered by the dfs gives a string that satisfies both. Else there is no match.

3
  • I don't know anything about automa theory, is there any way you can add a little psuedo code or something? This problem was very intersting to solve, and I think I got it, but I don't think I could tackle anything more complicated. Your help is appreciated. Sep 18, 2013 at 2:30
  • Intersection DFA. Guess I gotta look that up. And yeah, some pseudo code would be nice.
    – chakrit
    Sep 18, 2013 at 4:48
  • @chakrit It's a coupld of hours' work I don't have time for right now, unfortunately. The algorithms are not conceptually hard, but are quite detailed. github.com/bniemczyk/automata has some of the pieces but not all. The source code is commented in detail.
    – Gene
    Sep 19, 2013 at 4:30
5

Good question!

The main complexity here is handling character classes ([...]). My approach is to replace each one with a regular expression that looks for either exactly one of the specified characters (or ?) or another character class that includes at least one of the specified characters. So for [xyz], this would be: ([xyz?]|\[[^\]]*[xyz].*?\]) - see below:

Regular expression visualization

Then for "prefixes" (everything before the first *), put ^ at the beginning or for "suffixes" (everything after the last *), put $ at the end.

Further details:-

  1. Also need to replace all instances of ? with (\[.*?\]|[^\\]]) to make it match either a character class or single character (excluding an opening square bracket).
  2. Also need to replace each individual character that is not in a character class and is not ? to make it match either the same character, ? or a character class that includes the character. E.g. a would become ([a?]|\[[^\]]*a.*?\]). (A bit long-winded but turned out to be necessary - see comments below).
  3. The testing should be done both ways round as follows: Test prefix #1 converted into regex against prefix #2 then test prefix #2 converted into regex against prefix #1. If either match, the prefixes can be said to "intersect".
  4. Repeat step (3.) for suffixes: For a positive result, both prefixes and suffixes must intersect.

EDIT: In addition to the above, there is a special case when one of the patterns contains at least one * but the other doesn't. In this case, the whole of the pattern with * should be converted into a regular expression: * should match against anything but with the proviso that it only includes whole character classes. This can be done by replacing all instances of * with (\[.*?\]|[^\\]]).

To avoid this answer becoming bulky I won't post the full code but there is a working demo with unit tests here: http://jsfiddle.net/mb3Hn/4/

EDIT #2 - Known incompleteness: In its current form, the demo doesn't cater for escaped characters (e.g. \[). Not a great excuse but I only noticed these late in the day - they aren't mentioned in the question, only the link. To handle them, a bit of additional regex complexity would be needed, e.g. to check for non-existence of a backslash immediately before the [. This should be fairly painless with negative lookbehind but unfortunately Javascript doesn't support it. There are workarounds such as reversing both the string and regular expression with negative lookahead but I'm not keen on making the code less readable with this extra complexity and not sure how important it is to the OP so will leave it as an "exercise for ther reader". In retrospect, should maybe have chosen a language with more comprehensive regex support!

7
  • 1
    Check out the one I posted for @m.buettner. It's a bit more helpful because I walked through what the matches should be. Sep 16, 2013 at 16:23
  • Thanks again for the rigorous testing. Found a bug with the prefix/suffix when there is no wildcard that fixed the example in your comment above. However, the one you posted for m.buettner revealed a more serious flaw. In its most simple form, a? matched against ?b is returning false. Will have a think about what to do about this and hopefully come back to it tomorrow... Sep 16, 2013 at 21:58
  • 1
    @DanielGimenez Well that made things a bit more complicated! Have now updated the answer and fiddle with the extra use cases - now working for everything I can think of but please let me know if you find anything else... Sep 17, 2013 at 14:11
  • 1
    Another one for you ?*b*? => bcb is incorrectly true. Are you guy's treating ? as valid for zero-length? ?=b *=c b=b and *? go unmatched. I thought ? would need to get matched. Sep 18, 2013 at 0:00
  • Great spot! Looks like it's a special case when one of the patterns includes one or more *s but the other doesn't. Have edited my answer and fiddle + included these as extra unit tests. Sep 18, 2013 at 11:36
0

Determining whether a regex matches a subset of another regex using greenery:

First, pip3 install https://github.com/ferno/greenery/archive/master.zip.

Then:

from greenery.lego import parse as p
a_z = p("[a-z]")
b_x = p("[b-x]")
assert a_z | b_x == a_z
m_n = p("m|n")
zero_nine = p("[0-9]")
assert not m_n | zero_nine == m_n

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