A substring `S'`

of a string `S`

is a maximal palindrome of radius `i`

iff starting at the middle it reads the same in both directions for `i`

characters, but not for `i+1`

characters.

Any palindrome in a string must be a substring of a maximal palindrome with the same center. Conversely, every substring of a maximal palindrome with the same center must also be a palindrome. We can also easily count the number of sub-palindromes with the same center: a palindrome of length `k`

contains `Ceiling(k/2)`

of them.

Seeing as we can find all maximal palindromes using Manacher's algorithm in linear time, we have a linear time algorithm for your problem: find the array of lengths of the maximal palindromes, divide by two, take the ceiling, sum the array.

Example 1: on "xyxyx", the maximal palindromes are

```
x, xyx, xyxyx, xyx, x
```

and Manacher's can be used to calculate an array

```
1, 0, 3, 0, 5, 0, 3, 0, 1
```

representing the lengths of the maximal palindromes centered at each letter and in each gap between letters. Anyway, applying the map `Ceiling(k/2)`

to the entries, we get

```
1, 0, 2, 0, 3, 0, 2, 0, 1
```

which sums to 9.

Example 2: "abba". Maximal palindromes are

```
a, b, abba, b, a
```

Manacher's can be used to get the array

```
1, 0, 1, 4, 1, 0, 1
```

and the `Ceiling(k/2)`

'd array is

```
1, 0, 1, 2, 1, 0, 1
```

for a sum of 6 (a, b, b, a, bb, abba).

`O(n²)`

, since the mere act of incrementing a counter for each of the substrings would be`O(n²)`

given a highly-palindromic input. – StriplingWarrior Jan 4 '14 at 0:31