I recently had a SonarQube rule (https://rules.sonarsource.com/java/RSPEC-4784) bring to my attention some performance issues which could be used as a denial of service against a Java regular expression implementation.

Indeed, the following Java test shows how slow the wrong regular expression can be:

    import org.junit.Test;

    public class RegexTest {

    public void fastRegex1() {

    public void fastRegex2() {

    public void slowRegex() {

As you can see, the first two tests are fast, the third one is incredibly slow (in Java 8)

Enter image description here

The same data and regex in Perl or Python, however, is not at all slow, which leads me to wonder why it is that this regular expression is so slow to evaluate in Java.

$ time perl -e '"aaaaaaaaaaaaaaaaaaaaaaaaaaaabs" =~ /(a+)+b/ && print "$1\n"'

real    0m0.004s
user    0m0.000s
sys     0m0.004s

$ time python3 -c 'import re; m=re.search("(a+)+b","aaaaaaaaaaaaaaaaaaaaaaaaaaaabs"); print(m.group(0))'

real    0m0.018s
user    0m0.015s
sys     0m0.004s

What is it about the extra matching modifier + or trailing character s in the data which makes this regular expression so slow, and why is it only specific to Java?

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    How often did you run the tests? Try using JMH. – JCWasmx86 Aug 7 at 8:10
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    Why you use (a+)+b why not just a+b? if you are looking to just match and not to get the group before the b, then I don't see any reason to use group and + after group! – YCF_L Aug 7 at 8:10
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    On the site linked by you there is a link to OWASP, it explains the problem a little bit more: owasp.org/www-community/attacks/… – Amongalen Aug 7 at 8:16
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    For your information: what you're experiencing is called catastrophic backtracking – Thomas Aug 7 at 8:18
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    Java's .matches("(a+)b") is actually equivalent to Perl's /^(a+)+b\z/ – ikegami Aug 8 at 3:31

Caveat: I don't really know much about regex internals, and this is really conjecture. And I can't answer why Java suffers from this, but not the others (also, it is substantially faster than your 12 seconds in jshell 11 when I run it, so it perhaps only affects certain versions).


There are lots of ways that lots of as could match:


For the input string "aaaaaaaaaaaaaaaaaaaaaaaaaaaab", it will greedily match all of those as in a single pass, match the b, job done.

For "aaaaaaaaaaaaaaaaaaaaaaaaaaaabs", when it gets to the end and finds that the string doesn't match (because of the s), it's not correctly recognizing that the s means it can never match. So, having gone through and likely matched as


it thinks "Oh, maybe it failed because of the way I grouped the as - and goes back and tries all the other combinations of the as.

(aaaaaaaaaaaaaaaaaaaaaaaaaaa)(a)bs  // Nope, still no match
(aaaaaaaaaaaaaaaaaaaaaaaaaa)(aa)bs  // ...
(aaaaaaaaaaaaaaaaaaaaaaaaa)(aaa)bs  // ...
(a)(aaaaaaaaaaaaaaaaaaaaaaaaaaa)bs  // ...
(aaaaaaaaaaaaaaaaaaaaaaaaaa(a)(a)bs  // ...
(aaaaaaaaaaaaaaaaaaaaaaaaa(aa)(a)bs  // ...
(aaaaaaaaaaaaaaaaaaaaaaaa(aaa)(a)bs  // ...

There are lots of these (I think there are something like 2^27 - that's 134,217,728 - combinations for 28 as, because each a can either be part of the previous group, or start its own group), so it takes a long time.

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    If I'm not mistaken there are 2^n possible combinations, where n is equal to amount of as in input string. – Amongalen Aug 7 at 8:24
  • @Amongalen yes, I was just pondering that and edited in as you commented. – Andy Turner Aug 7 at 8:24
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    "And I can't answer why Java suffers from this but not the others" Python has similarly poor performance (maybe worse). It's just that the Python search is not doing the same thing as Java matches. – JimmyJames Aug 7 at 18:09
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    Re. "this is really conjecture": This is essentially correct. That's how Java regexes work. Although the order of the attempts is not quite right. – Matt Timmermans Aug 7 at 22:20
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    Re "I can't answer why Java suffers from this but not the others", Well, for starters, "aaaaaaaaaaaaaaaaaaaaaaaaaaaabs" =~ /(a+)+b/ matches with no backtracking whatsoever. /^(a+)+b\z/ should have been used. That said, /^(a+)+b\z/ is also very fast because the optimizer looks for ab<EOS> right off the bat, and realizes the pattern can't possibly match. You can see that using perl -Mre=debug -e '"aaaaaaaaaaaaaaaaaaaaaaaaaaaabs" =~ /^(a+)+b\z/' – ikegami Aug 8 at 3:33

I don't know Perl too well but the Python version is not equivalent to the Java one. You are using search() but the Java version is using matches(). The equivalent method in Python would be fullmatch()

When I run your examples in Python (3.8.2) with search() I get quick results as you do. When I run it with fullmatch() I get poor (multi-second) execution time. Could it be that your Perl example is also not doing a full match?

BTW: if you want to try the Java version of search you would use:


There might be some slight difference in the semantics but it should be close enough for this purpose.

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    The Perl code is equivalent to the Python search() code: if any substring matches the regular expression, it's considered a successful match. – Mark Aug 7 at 21:15
  • @Mark Thanks. Would you happen to know the equivalent of 'fullmatch' in Perl? – JimmyJames Aug 7 at 21:44
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    In Perl, you'd do it by changing the regular expression to include start and end anchors: /^(a+)+b$/. – Mark Aug 7 at 21:47
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    It's very fast in perl v5.30: echo aaaaaaaaaaaaaaaaaaaaaaaaaaaabs | perl -wne '/^((a+)+b)$/' – kubanczyk Aug 7 at 22:00
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    Re "Could it be that your Perl example is also not doing a full match?", Correct. The Perl equivalent would be /^(a+)+b\z/ (not /^(a+)+b$/). That said, the optimizer realizes the pattern can't possibly match before it even starts matching, and aborts. So unlike Java and Python, "aaa...aaabs" =~ /^(a+)+b\z/ fails instantly. You can see this using perl -Mre=debug -e '"aaaaaaaaaaaaaaaaaaaaaaaaaaaabs" =~ /^(a+)+b\z/' (Did not find floating substr "ab"$... Match rejected by optimizer) – ikegami Aug 8 at 3:40

The extra + causes a lot of backtracking (in a naive regexp implementation) when the string cannot be matched. If the string can be matched, the answer is known in the first try. This explains why the case 2 is fast and only case 3 is slow.

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  • I agree with the backtracking, but would it really be as slow as 12 seconds?! – f1sh Aug 7 at 8:14
  • I couldn't reproduce the slow regex with a quick and dirty script (50000 iterations): 13055 ns (Measured with System.nanoTime()) – JCWasmx86 Aug 7 at 8:15
  • @JCWasmx86 What input string did you use? – Amongalen Aug 7 at 8:16
  • @Amongalen To measure: long l=System.nanoTime();for(int i=0;i<50000;i++)"aaaaaaaaaaaaaaaaaaaaaaaaaaaabs".matches("(a+)+b");long l1=System.nanoTime();System.out.println(((double)l-l1)/50000); – JCWasmx86 Aug 7 at 8:17
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    Now with 5 million iterations, it's still around 10000 ns – JCWasmx86 Aug 7 at 8:17

The site https://swtch.com/~rsc/regexp/regexp1.html has some detailed information on regular expression implementation techniques and the theory behind them. I know link only answers are bad, but this is worth reading, showing an example regular expression that completes in 30 micro seconds with the better implementation, and 60 seconds (2 million times slower) with the better known and more obvious way.

It says

"Today, regular expressions have also become a shining example of how ignoring good theory leads to bad programs. The regular expression implementations used by today's popular tools are significantly slower than the ones used in many of those thirty-year-old Unix tools."

Other answers saying that the extra + causes too much backtracking are correct, but only if you ignore the good theory.

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    Using an NFA will run into exactly the same issue here as the more complex algorithms. (An NFA with n states can have up to 2^n paths through it). You have to understand the particular pathological RE used in that paper why an NFA is faster on that one and why that doesn't apply in the general case. – Voo Aug 8 at 8:50
  • @Voo Why does the number of paths through an NFA matter? To simulate an NFA, all you have to store is the set of possible states at each step, that set will be of size at most n. – gmatht Aug 9 at 6:51
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    Quick sanity check - isn't 30us vs 60s a factor of 2 million (rather than 2000)? – SusanW Aug 9 at 10:12
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    @SusanW Yes, of course, edited. Thanks. – icarus Aug 9 at 13:42
  • @gmath The runtime depends on the number of possible paths through the automaton and not on the number of states. The point is if you're not running some optimizer that recognises certain patterns (and you can surely trick the optimizer) certain regular expressions will simply have 2^n runtime and which algorithm you pick doesn't matter. – Voo Aug 9 at 17:46

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