# Palindrome Partitioning problem in O(N^2) time

Problem description:

Given a string s, partition s such that every substring of the partition is a palindrome. Return the minimum cuts needed for a palindrome partitioning of s.

Though I was able to code O(N^3) solution but facing problem in O(N^2) optimization

This is the optimized solution explanation

In the very first line "cut[i] is the minimum of cut[j - 1] + 1 (j <= i), if [j, i] is palindrome"

Why is this the case? Formal proof is not essential, intuition will also do.

• I'm sure leetcode has a question / answer forum. It seems someone has directed a lot of the online judge website traffic here. Apr 10 '20 at 17:50
• somebody has asked this question in the comments on leetcode, but the answer is not satifactory and has been voted down Apr 10 '20 at 17:57

If `S[j..i]` is a palindrome, that section (from `j` to `i`) accounts for the `ith` valid cut (and the `+ 1` in the formula). Since we have fixed a valid `ith` cut for this iteration, all we need to do is find the best overall minimal cut for the preceding part of the string. In a dynamic program, each iteration typically stores the overall cumulative best, which means we don't need to look farther back than `j-1`, but we have multiple `j`s to try.

• Why are we evaluating only when S[j...i] is a palindrome, why not otherwise? I think we should evalute for all positions of j and take the minimum. Am i wrong? Apr 16 '20 at 12:46
• @Light71192 that's exactly what we're doing. Hence `for(int j = 0; j <= i; j++)` in the code. Apr 16 '20 at 13:08
• @Light71192 but it seems to me that you asked about the logic behind each evaluation in that iteration. Apr 16 '20 at 13:23

We are basically trying to get the minimum cuts required for the substring[0 to i] to make the partitions palindromic. Hence, we are checking if the substring[j+1, i-1] is a palindrome. If that is a palindrome we are trying to update it by considering the substring [j+1, i-1](1 extra cut between j-1 and j positions) + c[j](which is the minimum cuts required for substring[0, j]).

Basically, the difference between the O(n^3) approach and the O(n^2) approach is the dimensions we use for the dp matrix.

Since we have already computed the minimum cut values from the start for each c[i] = minimum cuts of substring[0,i], the jth loop's(2nd loop) function is to check where to partition. We only partition the substring[0 to i] into two parts every time we run the second loop because the minimum cuts required for the former string is already calculated and the latter is already a palindrome. We do this until i = n-1 so the min cuts are calculated for substring[1 to n-1].

I highly recommend you to please check with multiple cases and traverse the loops. Trust me! that would be more helpful.