The main idea is a combination of dynamic programming and (as others have said already) computing maximum length of palindrome with center in a given letter.
What we really want to calculate is radius of the longest palindrome, not the length.
The radius is simply
(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 palindromes are, well, palindromes) skip further 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
- no palindrome (
radius = 0) at
i - k
radius = 0 at
i + k, too)
- inner palindrome, which means it fits in range
i + k is the same as at
i - k)
- outer palindrome, which means it doesn't fit in range
i + k is cut down to fit in range, i.e because
i + k + radius > i + pr we reduce
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.