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For a given int sequence check number of double palindromes, where by double palindrome we mean sequence of two same palindromes without break between them. So for example:

in 1 0 1 1 0 1 we have 1 0 1 as a palindrome which appears 2 times without a break,

in 1 0 1 5 1 0 1 we have 1 0 1 but it's separated

(apart from the other palindromes in these sequences)

Problem example test data is:

3

12 0 1 1 0 0 1 1 0 0 1 1 0

12 1 0 1 0 1 0 1 0 1 0 1 0

6 3 3 3 3 3 3

with answers

8 0 9

Manacher is obvious for the begging, but I'm not sure what to do next. Any ideas appreciated. Complexity should be below n^2 I guess.

EDIT: int is here treated as single element of alphabet

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Is this homework? It doesn't seem like a problem with practical relevance... –  Mark Byers Jun 9 '10 at 20:15
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Are you looking for ALL palindromes or just the longest ones? Your examples contain the palindromes 11 and 00 as sub-palindromes of others. Should they all be recognized, or not? (I'm assuming that a requirement is length(palindrome)>1). –  FrustratedWithFormsDesigner Jun 9 '10 at 20:16
    
Yes, answer is a number of all palindromes, length of single part might be 1 as it seems from example test data. @Mark - You could call it this way. It has no practical relevance... Its part of usual algorithms subject on university. –  jakubmal Jun 9 '10 at 20:22
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@jakubmal: Did your professor discuss algorithms for finding all palindromes? What if we restricted those palindromes to be even length? –  Aryabhatta Jun 9 '10 at 20:29
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@Moron: I meant Manacher to be the algorithm for finding all palindromes (and it was presented). I get rid of even/odd palindromes problem by inserting -1 between every element when reading from io. Actually I'm in High School, but we have a kind of AP program. –  jakubmal Jun 9 '10 at 20:39

2 Answers 2

up vote 1 down vote accepted

Since you already know an algorithm for finding all palindromes (which BTW is pretty awesome), all you need to do is the following. Note that a "double palindrome" is also a palindrome:
reverse(PP) = reverse(P)reverse(P) = PP.

So among all palindromes (a,b) you find (where by (a,b) I mean a palindrome from position a to position b), you need to find (i,j,k) such that (i,j), (j,k), and (i,k) are all palindromes, and j-i=k-j. Equivalently, for each palindrome (i,j) you find, you just need to set k = 2j-i, and check whether both (k,j) and (i,k) are palindromes.

If the first step returns M palindromes in all, this takes O(M) time (assuming you stored them such that checking whether a palindrome exists is O(1)), so O(n2) in the worst case. I believe this should be optimal in the worst case (consider a string of all 1s).

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Basically that's it. We can further decrease complexity by applying some clever algorithm for counting double-palindromes. It's quite similar to Manacher, since it only checks current greatest palindrome and automatically appends smaller ones to interval (??) tree. –  jakubmal Jul 17 '10 at 8:23

I would start with 2 collections:

  • a collection of 'growing' sequences
  • a collection of 'shrinking' sequences

The algorithm works like this:

  • Initially both collections are empty
  • Handle the values of the vector one by one, assume we are now looking at value V
  • Loop over all 'growing' sequences
    • If the last value of a growing sequence is equal to V, copy the growing sequence to the collection of shrinking sequences, remove V from the end of the new shrinking sequence
    • If the one-but-last value of the growing sequence is equal to V, copy the growing sequence to the collection of shrinking sequences, remove the last 2 elements (V and the last one) from the shrinking sequence
  • Loop over all 'shrinking' sequences
    • If the last value of the shrinking sequence is equal to V, remove it from the shrinking sequence. If a shrinking sequence becomes empty, we have found a palindrome.
    • If the last value of the shrinking sequence is not equal to V, delete this shrinking sequence
  • Finally make a new growing sequence consisting of only V

In fact the growing sequences are sequences that might become a palindrome once, while the shrinking sequences are 'partially' a palindrome.

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