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If the input is 'abba' then the possible palindromes are a, b, b, a, bb, abba.
I understand that determining if string is palindrome is easy. It would be like:

public static boolean isPalindrome(String str) {
 int len = str.length();
 for(int i=0; i<len/2; i++) {
     if(str.charAt(i)!=str.charAt(len-i-1) {
         return false;
     }
 return true;  
}

But what is the efficient way of finding palindrome substrings?

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using your example, would you expect to get "bab" and "baab" too? –  Daniel Kaplan Nov 5 '13 at 23:23
    
I would have expected not, since bab and baab is not a part of the String unless you change the order of the characters first. –  Simon André Forsberg Nov 5 '13 at 23:24
    
it's not an efficient way, but you can take every substring, and check whether it's a palindrome. It would only take O(n^3) time –  Sam I am Nov 5 '13 at 23:26
1  
"possible palindromes are a, b, b, a, bb, abba" So we can count some of them twice based on their position in the original string? This looks like it could simplify the problem greatly. –  Zong Zheng Li Nov 5 '13 at 23:32
3  
Perhaps you could iterate across potential middle character (odd length palindromes) and middle points between characters (even length palindromes) and extend each until you cannot get any further (next left and right characters don't match). That would save a lot of computation when there are no many palidromes in the string. In such case the cost would be O(n) for sparse palidrome strings. For palindrome dense would be O(n^2) as each position cannot be extended more than the length of the array / 2. Obviously this is even less towards the ends of the array. –  Valentin Ruano Nov 5 '13 at 23:35

5 Answers 5

up vote 14 down vote accepted

This can be done in O(n), using Manacher's algorithm.

The main idea is combination of dynamic programming and (as others have said already) computing maximum length of palindrome with center in given letter.


What we really want to calculate it radius of the longest palindrome, not the length. The radius is simply length/2 or (length - 1)/2 (for odd-length palindromes).

After computing palindrome radius pr at given position i we use already computed radiuses to find palindromes in range [i - pr ; i]. This lets us (because palindroms are, well, palindroms) skip futher computation of radiuses for range [i ; i + pr].

While we search in range [i - pr ; i], there are four basic cases for each position i - k (where k is in 1,2,... pr):

  • no palindrome (radius = 0) at i - k
    (this means radius = 0 at i + k, too)
  • inner palindrome, which means it fits in range
    (this means radius at i + k is the same as at i - k)
  • outer palindrome, which means it doesn't fit in range
    (this means radius at i + k is cut down to fit in range, i.e because i + k + radius > i + pr we reduce radius to pr - k)
  • sticky palindrome, which means i + k + radius = i + pr
    (in that case we need to search for potentially bigger radius at i + k)

Full, detailed explanation would be rather long. What about some code samples? :)

I've found C++ implementation of this algorithm by Polish teacher, mgr Jerzy Wałaszek.
I've translated comments to english, added some other comments and simplified it a bit to be easier to catch the main part.
Take a look here.


Note: in case of problems understanding why this is O(n), try to look this way:
after finding radius (let's call it r) at some position, we need to iterate over r elements back, but as a result we can skip computation for r elements forward. Therefore, total number of iterated elements stays the same.

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+1 Thanks. It is clear that dynamic algorithm for filling array of radiuses is O(n), however I am not super sure anymore that iterating over all possible palindromes represented by this array is O(n) too. –  kiruwka Nov 6 '13 at 8:55
    
Do you mean the part that prints results? This cannot be O(n), as results (printed out as strings) are of size O(n^2) - consider string "aaaaaaaaaa", results here. Hovewer, array itself is O(n) size and contains all data neccessary to print out the palindromes. Which representation of results to choose (just print the array in O(n) or print all palindromes in O(n^2)?) is totally separate from the algorithm itself. –  Michał Rybak Nov 6 '13 at 9:41
    
Thanks for a detailed answer. It has definitely helped me to understand it. –  Himanshu Yadav Nov 11 '13 at 19:30
    
I personally don't think this answers OP's question - as this is the algorithm for "longest palindromic substring", not "list all substrings that are palindromes". –  Nhan Feb 21 '14 at 9:26
    
@Nhan please analyze the algorithm more carefully. It first finds longest palindromic substring at given position, then uses it to find palindromes inside the longest one. Then it searches for longest palindromic substring at next not yet analyzed position... and so on. Try to draw the steps on paper and it will become crystal clear. –  Michał Rybak Feb 21 '14 at 13:44

So, each distinct letter is already a palindrome - so you already have N + 1 palindromes, where N is the number of distinct letters (plus empty string). You can do that in single run - O(N).

Now, for non-trivial palindromes, you can test each point of your string to be a center of potential palindrome - grow in both directions - something that Valentin Ruano suggested.
This solution will take O(N^2) since each test is O(N) and number of possible "centers" is also O(N) - the center is either a letter or space between two letters, again as in Valentin's solution.

Note, there is also O(N) solution to your problem, based on Manacher's algoritm (article describes "longest palindrome", but algorithm could be used to count all of them)

share|improve this answer

Perhaps you could iterate across potential middle character (odd length palindromes) and middle points between characters (even length palindromes) and extend each until you cannot get any further (next left and right characters don't match).

That would save a lot of computation when there are no many palidromes in the string. In such case the cost would be O(n) for sparse palidrome strings.

For palindrome dense inputs it would be O(n^2) as each position cannot be extended more than the length of the array / 2. Obviously this is even less towards the ends of the array.

  public Set<String> palindromes(final String input) {

     final Set<String> result = new HashSet<>();

     for (int i = 0; i < input.length(); i++) {
         // expanding even length palindromes:
         expandPalindromes(result,input,i,i+1);
         // expanding odd length palindromes:
         expandPalindromes(result,input,i,i);
     } 
     return result;
  }

  public void expandPalindromes(final Set<String> result, final String s, int i, int j) {
      while (i >= 0 && j < s.length() && s[i] == s[j]) {
            result.add(s.substring(i,j+1));
            i--; j++;
      }
  }
share|improve this answer
    
Nice. Note that in the OP's original example, this would return "a" and "b" only once. If it's necessary to track each occurrence, it's easy enough to define a class that contains both a String and a starting position, then make result a Set of that instead of Set<String>. –  ajb Nov 5 '13 at 23:52
    
A map return where the key is the string and the value the (e.g. the first found) start point would do nicely. –  Valentin Ruano Nov 5 '13 at 23:56

I just came up with my own logic which helps to solve this problem. Happy coding.. :-)

System.out.println("Finding all palindromes in a given string : ");
        subPal("abcacbbbca");

private static void subPal(String str) {
        String s1 = "";
        int N = str.length(), count = 0;
        Set<String> palindromeArray = new HashSet<String>();
        System.out.println("Given string : " + str);
        System.out.println("******** Ignoring single character as substring palindrome");
        for (int i = 2; i <= N; i++) {
            for (int j = 0; j <= N; j++) {
                int k = i + j - 1;
                if (k >= N)
                    continue;
                s1 = str.substring(j, i + j);
                if (s1.equals(new StringBuilder(s1).reverse().toString())) {
                    palindromeArray.add(s1);
                }
            }

        }
        System.out.println(palindromeArray);
        for (String s : palindromeArray)
            System.out.println(s + " - is a palindrome string.");
        System.out.println("The no.of substring that are palindrome : "
                + palindromeArray.size());
    }
Output:-
Finding all palindromes in a given string : 
Given string : abcacbbbca
******** Ignoring single character as substring palindrome ********
[cac, acbbbca, cbbbc, bb, bcacb, bbb]
cac - is a palindrome string.
acbbbca - is a palindrome string.
cbbbc - is a palindrome string.
bb - is a palindrome string.
bcacb - is a palindrome string.
bbb - is a palindrome string.
The no.of substring that are palindrome : 6
share|improve this answer

I suggest building up from a base case and expanding until you have all of the palindomes.

There are two types of palindromes: even numbered and odd-numbered. I haven't figured out how to handle both in the same way so I'll break it up.

1) Add all single letters

2) With this list you have all of the starting points for your palindromes. Run each both of these for each index in the string (or 1 -> length-1 because you need at least 2 length):

findAllEvenFrom(int index){
  int i=0;
  while(true) {
    //check if index-i and index+i+1 is within string bounds

    if(str.charAt(index-i) != str.charAt(index+i+1)) 
      return; // Here we found out that this index isn't a center for palindromes of >=i size, so we can give up

    outputList.add(str.substring(index-i, index+i+1));
    i++;
  }
}
//Odd looks about the same, but with a change in the bounds.
findAllOddFrom(int index){
  int i=0;
  while(true) {
    //check if index-i and index+i+1 is within string bounds

    if(str.charAt(index-i-1) != str.charAt(index+i+1)) 
      return;

    outputList.add(str.substring(index-i-1, index+i+1));
    i++;
  }
}

I'm not sure if this helps the Big-O for your runtime, but it should be much more efficient than trying each substring. Worst case would be a string of all the same letter which may be worse than the "find every substring" plan, but with most inputs it will cut out most substrings because you can stop looking at one once you realize it's not the center of a palindrome.

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You can simply reduce two possible cases to only odd-length palindromes by inserting some "special character", let's say #, between every two adjacent letters, ex. abba -> a#b#b#a. –  Michał Rybak Nov 5 '13 at 23:54
    
You can treat both cases the same way if you use two end indices rather than the center (index) and a radius (i). Check out the solution I posted above. –  Valentin Ruano Nov 6 '13 at 0:06

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