Minimum cost to convert the given String into Palindrome

Given a string S of length N and 2 integers X and Y, the task is to find the minimum cost of converting the string to a palindrome by performing the following operations any number of times in any order:

• Move the leftmost character to the rightmost end of the string at cost X. i.e S₁S₂…S_N gets converted into S₂S₃…S_NS₁.
• Replace any character of the string with any lowercase letter at cost Y.

Examples:

Input: N = 5, S = “rrefa”, X = 1, Y = 2
Output: 3
Explanation: First pay Y = 2 amount and replace S5 (i.e. ‘a’) with ‘e’. Now the string becomes “rrefe”. Now pay X = 1 amount to rotate the string once. Now the string becomes “refer”  which is a palindrome. The total cost to achieve the same is 2 + 1 = 3.

Input: N = 8, S = “bcdfcgaa”, X = 1000000000, Y = 1000000000
Output: 4000000000

Approach: This can be solved by the following idea:

It does not matter whether we replace a character before or after we move it. So, we will perform all the operation 1s before operation 2s for the sake of simplicity. We will fix how many times we will perform operation 1. Note that after N rotations the string becomes equal to the initial string. So, N-1 rotations are sufficient to arrive at the answer. Then, for each of the first N/2 characters we will check whether it matches with (N – i + 1)^th character 
(say its palindromic pair). If not, we have to pay cost Y to change any one of them.

The following steps can be used to solve the problem :

• Initialize a variable (say answer) to store the final answer.
• Iterate from i = 0 to N – 1, i.e. fix the number of rotations of the string (operation 1).
• Initialize a variable (say count) by 0 to store the number of operations 2 to be performed.
• Iterate from j = 0 to N – 1 (in the nested loop) to check how many characters of the string are not equal to their palindromic pair.
• If any character is not equal to its palindromic pair, increment the count.
• Calculate the cost of converting the string into palindrome for the current ‘i’.
• The minimum of all costs for each iteration would be the final answer.

Following is the code based on the above approach:

3

Time Complexity: O(N*N)
Auxiliary Space: O(1)

New Approach:- Here Another approach to solve this problem is to use dynamic programming. We can define a state dp[i][j] as the minimum cost required to make the substring from i to j a palindrome. We can then use this state to compute the minimum cost required to make the entire string a palindrome.

We can start by initializing all the diagonal elements of the dp matrix to 0, as the minimum cost required to make a single character a palindrome is 0. We can then iterate over all possible substrings of length 2 to N, and compute the minimum cost required to make each substring a palindrome. We can do this by checking if the first and last characters of the substring match, and then adding the cost of either inserting a character or deleting a character based on which operation gives the minimum cost.

The final answer would be the value of dp[0][N-1], which represents the minimum cost required to make the entire string a palindrome.

Following is the code based on the above approach:-

3

Time Complexity:- The time complexity of the given code is O(N^2) because there are two nested loops, where the outer loop iterates N-1 times and the inner loop iterates N-L+1 times (where L ranges from 2 to N). Each iteration of the inner loop takes constant time, so the total time complexity is O((N-1) * (N-1)) = O(N^2).

Space Complexity:- The space complexity of the given code is also O(N^2) because it uses a 2D array (dp) of size NxN to store the minimum cost required to make each substring a palindrome.