Is there any algorithm that can be used to find the most common phrases (or substrings) in a string? For example, the following string would have "hello world" as its most common two-word phrase:

"hello world this is hello world. hello world repeats three times in this string!"

In the string above, the most common string (after the empty string character, which repeats an infinite number of times) would be the space character .

Is there any way to generate a list of common substrings in this string, from most common to least common?

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    Define what do you mean by phrase, the substring "l" is more common then "hello world". And obviously "hello" is at least as common as "hello world". – amit Feb 3 '13 at 8:17
  • @amit I really meant "most common substring in a string". – Anderson Green Feb 3 '13 at 8:18
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    Then the most common substring is the empty string (repeats infinite number of times). The second after that is the most common character. Finding it can be easily done using a histogram in O(n). – amit Feb 3 '13 at 8:18
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    @amit After finding the most common character, I would try to find the most common two-character strings that began with each character. Then I would try to find the most common three-character strings that began with the most common two-character strings, and so on. – Anderson Green Feb 3 '13 at 8:21
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    "hello world" answer suggests that you want to find the longest duplicate substring – jfs Feb 3 '13 at 9:14

This is as task similar to Nussinov algorithm and actually even simpler as we do not allow any gaps, insertions or mismatches in the alignment.

For the string A having the length N, define a F[-1 .. N, -1 .. N] table and fill in using the following rules:

  for i = 0 to N
    for j = 0 to N
      if i != j
          if A[i] == A[j]
            F[i,j] = F [i-1,j-1] + 1;
            F[i,j] = 0;

For instance, for B A O B A B:


This runs in O(n^2) time. The largest values in the table now point to the end positions of the longest self-matching subquences (i - the end of one occurence, j - another). In the beginning, the array is assumed to be zero-initialized. I have added condition to exclude the diagonal that is the longest but probably not interesting self-match.

Thinking more, this table is symmetric over diagonal so it is enough to compute only half of it. Also, the array is zero initialized so assigning zero is redundant. That remains

  for i = 0 to N
    for j = i + 1 to N
      if A[i] == A[j]
         F[i,j] = F [i-1,j-1] + 1;

Shorter but potentially more difficult to understand. The computed table contains all matches, short and long. You can add further filtering as you need.

On the next step, you need to recover strings, following from the non zero cells up and left by diagonal. During this step is also trivial to use some hashmap to count the number of self-similarity matches for the same string. With normal string and normal minimal length only small number of table cells will be processed through this map.

I think that using hashmap directly actually requires O(n^3) as the key strings at the end of access must be compared somehow for equality. This comparison is probably O(n).

  • Not sure this answers the question. This is an easy method to find the longest self-matching substrings. The question is for the most common self-matching substring. – G. Bach Feb 3 '13 at 14:08
  • I have added explanation this can be easily done during the string recovery stage. The algorithm is efficient if only strings above the certain threshold are interesting. – h22 Feb 3 '13 at 14:30

Python. This is somewhat quick and dirty, with the data structures doing most of the lifting.

from collections import Counter
accumulator = Counter()
text = 'hello world this is hello world.'
for length in range(1,len(text)+1):
    for start in range(len(text) - length):
        accumulator[text[start:start+length]] += 1

The Counter structure is a hash-backed dictionary designed for counting how many times you've seen something. Adding to a nonexistent key will create it, while retrieving a nonexistent key will give you zero instead of an error. So all you have to do is iterate over all the substrings.

  • You can use for start in range(len(text) - length) and kill the if. – Jon Purdy Feb 3 '13 at 8:37
  • True. Saves some ops as well. – Jim Gray Feb 3 '13 at 8:38
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    why is it downvoted? The code works. – jfs Feb 3 '13 at 10:12
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    This solution is much easier to read – Nathan Feb 3 '13 at 12:56
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    Probably because OP was looking for an algorithm, rather than an implementation. If I posted "I need an algorithm for a sort thats O(n log(n)) but doesn't degrade on mostly-sorted data, I'd rather see "Check out en.wikipedia.org/Timsort" than "Java's sort is already optimized for that use case."--even though it is Timsort-based. – Tim Lesher Sep 27 '13 at 12:55

just pseudo code, and maybe this isn't the most beautiful solution, but I would solve like this:

function separateWords(String incomingString) returns StringArray{

function findMax(Map map) returns String{

function mainAlgorithm(String incomingString) returns String{
    StringArray sArr = separateWords(incomingString);
    Map<String, Integer> map; //init with no content
    for(word: sArr){
        Integer count = map.get(word);
        if(count == null){
        } else {
            //remove if neccessary
   return findMax(map);

Where map can contain a key, value pairs like in Java HashMap.


Perl, O(n²) solution

my $str = "hello world this is hello world. hello world repeats three times in this string!";

my @words = split(/[^a-z]+/i, $str);
my ($display,$ix,$i,%ocur) = 10;

# calculate

for ($ix=0 ; $ix<=$#words ; $ix++) {
  for ($i=$ix ; $i<=$#words ; $i++) {
    $ocur{ join(':', @words[$ix .. $i]) }++;

# display 

foreach (sort { my $c = $ocur{$b} <=> $ocur{$a} ; return $c ? $c : split(/:/,$b)-split(/:/,$a); } keys %ocur) {
  print "$_: $ocur{$_}\n";
  last if !--$display;

displays the 10 best scores of the most common sub strings (in case of tie, show the longest chain of words first). Change $display to 1 to have only the result.
There are n(n+1)/2 iterations.


Since for every substring of a String of length >= 2 the text contains at least one substring of length 2 at least as many times, we only need to investigate substrings of length 2.

val s = "hello world this is hello world. hello world repeats three times in this string!"

val li = s.sliding (2, 1).toList
// li: List[String] = List(he, el, ll, lo, "o ", " w", wo, or, rl, ld, "d ", " t", th, hi, is, "s ", " i", is, "s ", " h", he, el, ll, lo, "o ", " w", wo, or, rl, ld, d., ". ", " h", he, el, ll, lo, "o ", " w", wo, or, rl, ld, "d ", " r", re, ep, pe, ea, at, ts, "s ", " t", th, hr, re, ee, "e ", " t", ti, im, me, es, "s ", " i", in, "n ", " t", th, hi, is, "s ", " s", st, tr, ri, in, ng, g!)

val uniques = li.toSet
uniques.toList.map (u => li.count (_ == u))
// res18: List[Int] = List(1, 2, 1, 1, 3, 1, 5, 1, 1, 3, 1, 1, 3, 2, 1, 3, 1, 3, 2, 3, 1, 1, 1, 1, 1, 3, 1, 3, 3, 1, 3, 1, 1, 1, 3, 3, 2, 4, 1, 2, 2, 1)

res19: String = "s "

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