Minimum increment or decrement operations required to make the array sorted

Given an array arr[] of N integers, the task is to sort the array in non-decreasing order by performing the minimum number of operations. In a single operation, an element of the array can either be incremented or decremented by 1. Print the minimum number of operations required.
Examples: 
 

Input: arr[] = {1, 2, 1, 4, 3} 
Output: 2 
Add 1 to the 3rd element(1) and subtract 1 from 
the 4th element(4) to get {1, 2, 2, 3, 3}
Input: arr[] = {1, 2, 2, 100} 
Output: 0 
Given array is already sorted. 
 

Observation: Since we would like to minimize the number of operations needed to sort the array the following should hold: 
 

• A number will never be decreased to value lesser than the minimum of the initial array.
• A number will never be increased to a value greater than the maximum of the initial array.
• The number of operations required to change a number from X to Y is abs(X – Y).

Approach : Based on the above observation, this problem can be solved using dynamic programming. 
 

1. Let DP(i, j) represent the minimum operations needed to make the 1^st i elements of the array sorted in non-decreasing order when the i^th element is equal to j.
2. Now DP(N, j) needs to be calculated for all possible values of j where N is the size of the array. According to the observations, j ? smallest element of the initial array and j ? the largest element of the initial array.
3. The base cases in the DP(i, j) where i = 1 can be easily answered. What are the minimum operations needs to sort the 1^st element in non-decreasing order such that the 1^st element is equal to j?. DP(1, j) = abs( array[1] – j).
4. Now consider DP(i, j) for i > 1. If i^th element is set to j then the 1^st i – 1 elements need to be sorted and the (i – 1)^th element has to be ? j i.e. DP(i, j) = (minimum of DP(i – 1, k) where k goes from 1 to j) + abs(array[i] – j) 
    
5. Using the above recurrence relation and the base cases, the result can be easily calculated.

Below is the implementation of the above approach: 
 

2

Complexity Analysis: 
Time Complexity: O(N*R), Time complexity for the above approach is O(N * R) where N is the number of elements in the array and R = largest – smallest element of the array + 1.
Auxiliary Space: O(N * large)

Efficient approach : Space optimization

In previous approach the current value dp[i][j] is only depend upon the current and previous row values of DP. So to optimize the space complexity we use a single 1D array to store the computations.

Implementation steps:

• Create a 1D vector dp of size large+1.
• Set a base case by initializing the values of DP .
• Now iterate over subproblems by the help of nested loop and get the current value from previous computations.
• Now Create a 1d vector curr used to store the current values from previous computations.
• After every iteration assign the value of curr to dp for further iteration.
• Initialize a variable ans to store the final answer and update it by iterating through the Dp.
• At last return and print the final answer stored in ans .

Implementation:
 

2

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