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A rotated palindrome is like "1234321", "3432112". The naive method will be cut the string into different pieces and concate them back and see if the string is a palindrome. That would take O(n^2) since there are n cuts and for each cut we need O(n) to check if the string is a palindrome. I'm wondering if there's a better solution than this. I guess so, please advice.

Thanks!

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questions: is a single digit a palindrome? is this 123217898 a rotated palindrome?(in other words can it cut in more than two substrings) –  saul672 Sep 5 '12 at 16:53
    
123217898 is not a rotated palindrome. –  DarthVader Sep 5 '12 at 16:54

3 Answers 3

According to this wikipedia article it is possible for each string S of length n in time O(n) compute an array A of the same size, such that:

A[i]==1 iff the prefix of S of length i is a palindrome.

http://en.wikipedia.org/wiki/Longest_palindromic_substring

The algorithm should be possible to find in:

Manacher, Glenn (1975), "A new linear-time "on-line" algorithm for finding the smallest initial palindrome of a string"

In other words we can check which prefixes of the string are palindromes in linear time. We will use this result to solve the proposed problem.

Each (non-rotating) palindrome S has the following form S = psxs^Rp^R.

Where "x" is the center of the palindrome (either empty string or one letter string), "p" and "s" are (possibly empty) strings and "s^R" means "s" string reversed.

Each rotating palindrome created from this string has one of the two following forms (for some p):

  1. sxs^Rp^Rp
  2. p^Rpsxs^R

This is true, because you can choose if to cut some substring before or after the middle of the palindrome and then paste it on the other end.

As one can see the substrings "p^Rp" and "sxs^R" are both palindromes, one of then of even length and the other on odd length iff S is of odd length.

We can use the algorithm mentioned in the wikipedia link to create two arrays A and B. The array A is created by checking which prefixes are palindromes and B for suffixes. Then we search for a value i such that A[i]==B[i]==1 such that either prefix or suffix has even length. We will find such index iff the proposed string is a rotated palindrome and the even part is the "p^Rp" substring, so we can easily recover the original palindrome by moving half of this string to the other end of the string.


One remark to the solution by rks, this solution doesn't work, as for a string S = 1121 it will create string 11211121 which has palindrome of length longer or equal than the length of S, but it is not a rotated palindrome. If we change the solution such that it checks whether there exist a palindrome of length equal to length of S, it would work, but i don't see any direct solution how to change the algorithm searching for longest substring in such a way that it would search for substring of fixed length (len(S)). (i didn't write this as a comment under the solution as i'm new to Stackoverflow and don't have enough reputation to do so)


Second remark -- I'm sorry not to include the algorithm of Manacher, if someone has link to either the idea of the algorithm or some implementation please include it in the comments.

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Oh yes, thanks for the counter-example! I didn't manage to find one myself, so I assumed my algorithm was right. As for the "i don't see how to change the algorithm searching for the longest substring", you can always get all the palindromes, and then take only the one of the right size. But would the algorithm be correct with an equality instead of >= ? I'm not sure anymore. –  rks Sep 5 '12 at 18:37
    
yes, equality will be enough, suppose that the you create an string XX from the rotated plindrome X and the found palindrome string S of length n starts at index i in the concatenated word, it ends at n+i and if you take the substring starting at n and ending at n+i and put this in front of the string, you get the string X. –  Richard Stefanec Sep 5 '12 at 18:44
    
Good point. Thank you. –  rks Sep 5 '12 at 18:47
    
To the other remark. I'm not sure about the "you can always get all palindromes" as there are O(n^2) possible palindromes in the worst case, so this might break the time bound. But as far as I read and understood the algorithm it uses some clever insides how the palindromes might look like, so there might be some way how to alter it, but unless someone will show me how to alter it, I wouldn't automatically expect it to be trivial. –  Richard Stefanec Sep 5 '12 at 18:52
    
as I still cannot write under your solution, you should probably edit it in such a way, that it is clear that we still need to find an algorithm solving the problem of "palindromic substring of length exactly n", as it is not clear if such algorithm is just an trivial variation of the "longest palindromic substring problem" and it might be interesting to find out if it is. –  Richard Stefanec Sep 5 '12 at 19:00

Concatenate the string to itself, then do the classical palindrome research in the new string. If you find a palindrome whose length is longer or equal to the length of your original string, you know your string is a rotated palindrome.

For your example, you would do your research in 34321123432112 , finding 21123432112, which is longer than your initial string, so it's a rotated palindrome.

EDIT: as Richard Stefanec noted, my algorithm fails on 1121, he proposed that we change the >= test on the length by =.

EDIT2: it should be noted than finding a palindrome of a given size isn't obviously easy. Read the discussion under Richard Stefanec post for more information.

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and what s the O notation here? how do u you search 34321123432112 for a palindrome? –  DarthVader Sep 5 '12 at 17:04
    
The same as for finding the longest palindromic substring of a given string. Which can be done in linear time, see : en.wikipedia.org/wiki/Longest_palindromic_substring –  rks Sep 5 '12 at 17:05

I would like to propose one simple solution, using only conventional algorithms. It will not solve any harder problem, but it should be sufficient for your task. It is somewhat similar to the other two proposed solutions, but none of them seems to be concise enough for me to read carefully.

First step: concatenate the string to itself (abvc - > abvcabvc) as in all other proposed solutions.

Second step: do Rabin-Karp precalculation (which uses rolling hash) on the newly obtained string and its reversed.

Third step: Let the string be with length n. For each index iin 0...n-1 check if the substring of the doubled string [i, i + n - 1] is palindrome in constant time, using the Rabin-Karp precalculations (basically the obtained value in for the substring in the forward and the reversed direction should be equal).

Conclusion: if third step found any palindrome - then the string is rotated palindrome. If not - then it is not.

PS: Rabin Karp uses hashes, and collisions are possible even for non-coinciding strings. Thus it is a good idea to make verifying brute force check for equality if such is induced by the hash checks. Still if the hash functions used in the Rabin Karp are good, the amortized speed of the solution should remain O(n).

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