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 - 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
- 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.