Fast algorithm for searching for substrings in a string

I'd like an efficient algorithm (or library) that I can use in Java to search for substrings in a string.

What I would like to do is:

Given an input string - INSTR:

"BCDEFGH"

And a set of candidate strings - CAND:

"AB", "CDE", "FG", "H", "IJ"

Find any CAND strings that match as substrings within INSTR

In this example I would match "CDE", "FG", and "H" (but not "AB" and "IJ")

There could be many thousand candidate strings (in CAND), but more importantly I will be doing this search many millions of times so I need it to be FAST.

I'd like to work with char arrays. Also, I'm not intested in architectural solutions, like distributing the search - just the most efficient function/algorithm for doing it locally.

Additionally, all the strings in CAND and INSTR will all be relatively small (< 50 chars) - i.e. the target string INSTR is NOT long relative to the candidate strings.

Update I should have mentioned, the set of CAND strings is invariant across all values of INSTR.

Update I only need to know that there was a match - and i don't need to know what the match was.

Final Update I opted to try AhoCorsick and Rabin-Karp, due to simplicity of implementation. Because I have variable length patterns I used a modified Rabin-Karp that hashes the first n characters of each pattern, where n is the length of the smallest pattern, N was then the length of my rolling substring search window. For the Aho Corsick I used this

In my test i searched for 1000 patterns in two documents news paper articles, averaged across 1000 iterations etc... Normalised times to complete were:

AhoCorsick: 1

RabinKarp: 1.8

Naive Search (check each pattern & use string.contains): 50

*Some resources describing the algos mentioned in the answers below:

http://www.seas.gwu.edu/~simhaweb/cs151/lectures/module5/module5.html

http://www.cs.princeton.edu/courses/archive/spr09/cos226/lectures/18SubstringSearch-2x2.pdf

• How long are the input strings in relation to the candidate strings? – Thomas Jung Nov 19 '09 at 18:43
• They are short. Input strings are typically less then 40 characters, as are the candidate strings. – Joel Nov 19 '09 at 18:47
• but there could be many thousand candidate strings - and i want to do this repeatedly across many input strings millions of times. – Joel Nov 19 '09 at 18:47
• Given the details a FSM is probably your best choice. – Daniel Brückner Nov 19 '09 at 18:53
• Curious what you expect as output. Is knowing that one was found good enough or do you need to know which were found? Do you need to know how many times each substring was found? – PSpeed Nov 19 '09 at 19:34

Read up on the Aho-Corasick algorithm and the Rabin-Karp algorithm.

If the input is not too large, you don't want to repeat the search many times and you do not have many patterns, it might be a good idea to use a single pattern algorithm several times. The Wikipedia article on search algorithms gives many algorithms with running and preprocessing times.

Implementations:

Presentations:

Convert the set of candidate strings into a deterministic finite state automaton and then run through the input string in linear time. Converting a single string into a DFS is well-covered in the standard books. You can convert a set of strings by first constructing a non-deterministic automaton and then determinizing it. That can create exponential blow-up in the worst case in the size of the automaton but the search afterwards is fast; especially if the target string is long and the candidates short that's going to work well.

• +1 for mentioning FSMs. Absolutely the fastest solution. – Anton Nov 19 '09 at 18:42
• Is this as soln as relevant given that the input strings and candidate strings are all very short e.g. < 50 chars? – Joel Nov 19 '09 at 18:49
• @Joel I think it depends on what you mean when you write above that "I want to do this repeatedly across many input strings". The DFS does not depend on the input string, so if the set of candidate strings is constant across multiple input strings then that's equivalent to one long input string and thus the solution is definitely relevant. If all strings are short AND the candidates change every time then it might not be the optimal solution. – Antti Huima Nov 19 '09 at 18:53
• How does this compare to the Rabin-Karp multiple pattern search algo suggested above? Given the large number of possible substrings, and the relatively short inputstring length this would have seemed like a good solution? – Joel Nov 19 '09 at 19:09
• @Joel Rabin-Karp is definitely another good solution, it just has different asymptotic behavior. The DFS solution has best asymptotic complexity for matching because it is O(n) in the length of the input string only. Rabin-Karp has extra terms in the complexity. However it is simpler to implement from scratch. – Antti Huima Nov 19 '09 at 20:01

This is what regular expressions are for. As noted above, finite state automata are what you need, but that is exactly how a standard regexp-matcher is implemented.

In java you could write something like:

``````StringBuilder sb = new StringBuilder();
bool first = true;
for (String subStr : substrings) {
if (first)
first = false;
else
sb.append('|');
sb.append(escape(subStr));
}
Pattern p = Pattern.compile(sb.toString());
``````

the method `escape` should escape any characters which have special meanings in a regexp.

• I can't speak for why it was down voted but I can say that due to the way Java regex is implemented, this regex can be way less efficient than searching for each substring individually. – PSpeed Nov 19 '09 at 19:32
• I like this solution and upvoted it. However, I'd like to point out two potential problems: (1) Given a thousand or so search strings, it's possible the pattern compiler will explode. I worry memory use grows exponentially with the complexity of the match expression. (2) I believe the FSM/DFS built by the pattern compiler will on occasion back up. If it does, then one of the specialized algorithms that moves strictly forward may end up being faster yet. – Carl Smotricz Nov 19 '09 at 19:41
• I don't claim that my solution is perfect. It may very well be adequate though. YMMV. – Jørgen Fogh Nov 19 '09 at 21:19
• The way regex executes a pattern like "a|b|c|d" is to start at position 0, try all options, move to position 1, try all options, move to position 2, try all options, etc.. Faster ways to do this without a big regex OR are pretty trivial to write I'd think. It will never be any worse to search all of INSTR for CAND1, then search for CAND2, etc. and will often be much better. Furthermore, that kind of search is much easier to optimize. – PSpeed Nov 20 '09 at 2:00
• @PSpeed: I can't imagine any real regexp library being implemented like that. Anyway, if speed is really important, you might try [this library][0]. [0]: brics.dk/automaton – Jørgen Fogh Nov 20 '09 at 10:51

Rabin-Karp multiple pattern search appears to be the fastest.

You might want to look into Aho-Corasick algorithm and related algorithms. I don't know of any libraries that implement this, offhand, but this is the classic way of solving this problem.

Also check the Boyer-Moore algorithm for single-string pattern matching.

We can take advantage of the small size (< 50 char) of the strings to build a super fast algo for this case, at the cost of memory.

We can hash all possible substrings of INSTR in a hash one time that will cost O(n^2) time. Then regardless of the number of CAND strings, the lookup will be O(1). Worth it for a very large number of CAND strings.

If INSTR is large, then we can build a suffix array and not sort it, so that the top item is the longest (=N) and bottom item is the last char of INSTR. Now for each CAND string, only search from the top as long as length(CAND) <= length(suffix). Each of those comparisons will be O(n).

• I'm a little hazy on this so I could be off base here, but would the hash time be O(n+1)(n/2) instead of O(n^2) since thats how many different substrings that there should be? – Chris Dutrow Jan 21 '10 at 0:01
• Big-O ignores coefficients. Drop the `1` and `2` out of your expression and you are left with `O((n)(n))` which is the same as `O(n^2)`. – Tripp Kinetics Jul 15 '15 at 15:14

Another solution is to use a suffix array for the INSTR.
Since the INSTR is small you can sort it with bubble sort.

Afterwards you can search for a specific CAND string in O(logN) time,
where N = length(suffix_array) = length(INSTR).

Here are some implementation of fast String search algorithms in Java.

• where? Did you forgot to copy paste the link? – Tushar Dec 22 '15 at 13:13
• If you click on th "Here" text you will be redirected to the website with the algorithms. – Mike Dec 23 '15 at 16:30
``````import java.util.Scanner;

public class StringMatch
{
static int temp,i=0,j=0; static boolean flag=true,matcher=false;

static String str=null,mstr=null;static char astr[],amstr[];

static void getter(){
Scanner sc = new Scanner(System.in);
str = sc.nextLine();
//String str="today is Monday";
astr=str.toCharArray();
mstr = sc.nextLine();
//String mstr="is";
amstr=mstr.toCharArray();
}

static void stringMatch(){
while(i<astr.length){
if(astr[i]==amstr[j]){
while((j!=amstr.length)&&flag){temp=i;
if(astr[i]!=amstr[j]) {flag=false;matcher=false;}
else{matcher=true;}
i++;j++;
//System.out.println(i+"\t"+j);
}if(matcher==true)break;i=temp;}i++;j=0;flag=true;

}
if(matcher==true) {System.out.println("true");}
else    {System.out.println("false");}
}

public static void main(String[] args) {

StringMatch.getter();
StringMatch.stringMatch();

}
}
``````