Open In App

Maximum circular subarray sum

Improve
Improve
Like Article
Like
Save
Share
Report

Given a circular array of size n, find the maximum subarray sum of the non-empty subarray.

Examples: 

Input: arr[] = {8, -8, 9, -9, 10, -11, 12}
Output: 22 
Explanation: Subarray 12, 8, -8, 9, -9, 10 gives the maximum sum, that is 22.

Input: arr[] = {10, -3, -4, 7, 6, 5, -4, -1} 
Output:  23 
Explanation: Subarray 7, 6, 5, -4, -1, 10 gives the maximum sum, that is 23.

Input: arr[] = {-1, 40, -14, 7, 6, 5, -4, -1}
Output: 52 
Explanation: Subarray 7, 6, 5, -4, -1, -1, 40 gives the maximum sum, that is 52.

Recommended Practice

Maximum Circular Subarray Sum using Kadane’s Algorithm:

The idea is to modify Kadane’s algorithm to find a minimum contiguous subarray sum and the maximum contiguous subarray sum, then check for the maximum value between the max_value and the value left after subtracting min_value from the total sum.

Illustration:

Input: arr[] = {8, -8, 9, -9, 10, -11, 12}, N = 7

sum = 11

Initialise: curr_max = arr[0], max_so_far = arr[0], curr_min = arr[0], min_so_far = arr[0]

At i = 1:

  • curr_max = max(curr_max + arr[1], arr[1]) = max(8 + (-8), -8) = 0
  • max_so_far = max(max_so_far, curr_max) = max(8, 0) = 8
  • curr_min = min(curr_min + a[1], a[1]) = min(8 + (-8), -8) = -8
  • min_so_far = min(curr_min, min_so_far) = min(-8, 8) = -8

At i = 2:

  • curr_max = max(curr_max + arr[2], arr[2]) = max(0 + 9, 9) = 9
  • max_so_far = max(max_so_far, curr_max) = max(8, 9) = 9
  • curr_min = min(curr_min + a[2], a[2]) = min(-8 + 9, 9) = 1
  • min_so_far = min(curr_min, min_so_far) = min(1, -8) = -8

At i = 3:

  • curr_max = max(curr_max + arr[3], arr[3]) = max(9 + (-9), -9) = 0
  • max_so_far = max(max_so_far, curr_max) = max(9, 0) = 9
  • curr_min = min(curr_min + a[3], a[3]) = min(1 + (-9), -9) = -9
  • min_so_far = min(curr_min, min_so_far) = min(-9, -8) = -9

At i = 4:

  • curr_max = max(curr_max + arr[4], arr[4]) = max(0 + 10, 10) = 10
  • max_so_far = max(max_so_far, curr_max) = max(9, 10) = 10
  • curr_min = min(curr_min + a[4], a[4]) = min(-9 + 10, 10) = 1
  • min_so_far = min(curr_min, min_so_far) = min(1, -9) = -9

At i = 5:

  • curr_max = max(curr_max + arr[5], arr[5]) = max(10 + (-11), -11) = -1
  • max_so_far = max(max_so_far, curr_max) = max(10, -1) = 10
  • curr_min = min(curr_min + a[5], a[5]) = min(1 + (-11), -11) = -11
  • min_so_far = min(curr_min, min_so_far) = min(-11, -9) = -11

At i = 6:

  • curr_max = max(curr_max + arr[6], arr[6]) = max(-1 + 12, 12) = 12
  • max_so_far = max(max_so_far, curr_max) = max(10, 12) = 12
  • curr_min = min(curr_min + a[6], a[6]) = min(-11+ 12, 12) = 1
  • min_so_far = min(curr_min, min_so_far) = min(1, -11) = -11

ans = max(max_so_far, sum – min_so_far) = (12, 11 – (-11)) = 22

Hence, maximum circular subarray sum is 22

Follow the steps below to solve the given problem:

  • We will calculate the total sum of the given array.
  • We will declare the variable curr_max, max_so_far, curr_min, min_so_far as the first value of the array.
  • Now we will use Kadane’s Algorithm to find the maximum subarray sum and minimum subarray sum.
  • Check for all the values in the array:- 
    • If min_so_far is equaled to sum, i.e. all values are negative, then we return max_so_far.
    • Else, we will calculate the maximum value of max_so_far and (sum – min_so_far) and return it.

Below is the implementation of above approach:

C++




// C++ program for maximum contiguous circular sum problem
#include <bits/stdc++.h>
using namespace std;
 
// The function returns maximum
// circular contiguous sum in a[]
int maxCircularSum(int a[], int n)
{
    // Corner Case
    if (n == 1)
        return a[0];
 
    // Initialize sum variable which store total sum of the array.
    int sum = 0;
    for (int i = 0; i < n; i++) {
        sum += a[i];
    }
 
    // Initialize every variable with first value of array.
    int curr_max = a[0], max_so_far = a[0], curr_min = a[0], min_so_far = a[0];
 
    // Concept of Kadane's Algorithm
    for (int i = 1; i < n; i++) {
        // Kadane's Algorithm to find Maximum subarray sum.
        curr_max = max(curr_max + a[i], a[i]);
        max_so_far = max(max_so_far, curr_max);
 
        // Kadane's Algorithm to find Minimum subarray sum.
        curr_min = min(curr_min + a[i], a[i]);
        min_so_far = min(min_so_far, curr_min);
    }
 
    if (min_so_far == sum)
        return max_so_far;
 
    // returning the maximum value
    return max(max_so_far, sum - min_so_far);
}
 
/* Driver program to test maxCircularSum() */
int main()
{
    int a[] = { 11, 10, -20, 5, -3, -5, 8, -13, 10 };
    int n = sizeof(a) / sizeof(a[0]);
    cout << "Maximum circular sum is " << maxCircularSum(a, n) << endl;
    return 0;
}


Java




/*package whatever //do not write package name here */
import java.io.*;
 
class GFG {
  public static int maxCircularSum(int a[], int n)
  {
    // Corner Case
    if (n == 1)
      return a[0];
 
    // Initialize sum variable which store total sum of
    // the array.
    int sum = 0;
    for (int i = 0; i < n; i++) {
      sum += a[i];
    }
 
    // Initialize every variable with first value of
    // array.
    int curr_max = a[0], max_so_far = a[0],
    curr_min = a[0], min_so_far = a[0];
 
    // Concept of Kadane's Algorithm
    for (int i = 1; i < n; i++)
    {
 
      // Kadane's Algorithm to find Maximum subarray
      // sum.
      curr_max = Math.max(curr_max + a[i], a[i]);
      max_so_far = Math.max(max_so_far, curr_max);
 
      // Kadane's Algorithm to find Minimum subarray
      // sum.
      curr_min = Math.min(curr_min + a[i], a[i]);
      min_so_far = Math.min(min_so_far, curr_min);
    }
    if (min_so_far == sum) {
      return max_so_far;
    }
 
    // returning the maximum value
    return Math.max(max_so_far, sum - min_so_far);
  }
 
  // Driver code
  public static void main(String[] args)
  {
    int a[] = { 11, 10, -20, 5, -3, -5, 8, -13, 10 };
    int n = 9;
    System.out.println("Maximum circular sum is "
                       + maxCircularSum(a, n));
  }
}
 
// This code is contributed by aditya7409


Python3




# Python program for maximum contiguous circular sum problem
 
# The function returns maximum
# circular contiguous sum in a[]
def maxCircularSum(a, n):
     
    # Corner Case
    if (n == 1):
        return a[0]
 
    # Initialize sum variable which
    # store total sum of the array.
    sum = 0
    for i in range(n):
        sum += a[i]
 
    # Initialize every variable
    # with first value of array.
    curr_max = a[0]
    max_so_far = a[0]
    curr_min = a[0]
    min_so_far = a[0]
 
    # Concept of Kadane's Algorithm
    for i in range(1, n):
       
        # Kadane's Algorithm to find Maximum subarray sum.
        curr_max = max(curr_max + a[i], a[i])
        max_so_far = max(max_so_far, curr_max)
 
        # Kadane's Algorithm to find Minimum subarray sum.
        curr_min = min(curr_min + a[i], a[i])
        min_so_far = min(min_so_far, curr_min)
    if (min_so_far == sum):
        return max_so_far
 
    # returning the maximum value
    return max(max_so_far, sum - min_so_far)
 
# Driver code
a = [11, 10, -20, 5, -3, -5, 8, -13, 10]
n = len(a)
print("Maximum circular sum is", maxCircularSum(a, n))
 
# This code is contributes by subhammahato348


C#




// C# program for maximum contiguous circular sum problem
using System;
class GFG
{
    public static int maxCircularSum(int[] a, int n)
    {
        // Corner Case
        if (n == 1)
            return a[0];
 
        // Initialize sum variable which store total sum of
        // the array.
        int sum = 0;
        for (int i = 0; i < n; i++)
        {
            sum += a[i];
        }
 
        // Initialize every variable with first value of
        // array.
        int curr_max = a[0], max_so_far = a[0],
            curr_min = a[0], min_so_far = a[0];
 
        // Concept of Kadane's Algorithm
        for (int i = 1; i < n; i++)
        {
 
            // Kadane's Algorithm to find Maximum subarray
            // sum.
            curr_max = Math.Max(curr_max + a[i], a[i]);
            max_so_far = Math.Max(max_so_far, curr_max);
 
            // Kadane's Algorithm to find Minimum subarray
            // sum.
            curr_min = Math.Min(curr_min + a[i], a[i]);
            min_so_far = Math.Min(min_so_far, curr_min);
        }
        if (min_so_far == sum)
        {
            return max_so_far;
        }
 
        // returning the maximum value
        return Math.Max(max_so_far, sum - min_so_far);
    }
 
    // Driver code
    public static void Main()
    {
        int[] a = { 11, 10, -20, 5, -3, -5, 8, -13, 10 };
        int n = 9;
        Console.WriteLine("Maximum circular sum is "
                          + maxCircularSum(a, n));
    }
}
 
// This code is contributed by subhammahato348


Javascript




<script>
       // JavaScript program for the above approach
 
 
       // The function returns maximum
       // circular contiguous sum in a[]
       function maxCircularSum(a, n) {
           // Corner Case
           if (n == 1)
               return a[0];
 
           // Initialize sum variable which store total sum of the array.
           let sum = 0;
           for (let i = 0; i < n; i++) {
               sum += a[i];
           }
 
           // Initialize every variable with first value of array.
           let curr_max = a[0], max_so_far = a[0], curr_min = a[0], min_so_far = a[0];
 
           // Concept of Kadane's Algorithm
           for (let i = 1; i < n; i++) {
               // Kadane's Algorithm to find Maximum subarray sum.
               curr_max = Math.max(curr_max + a[i], a[i]);
               max_so_far = Math.max(max_so_far, curr_max);
 
               // Kadane's Algorithm to find Minimum subarray sum.
               curr_min = Math.min(curr_min + a[i], a[i]);
               min_so_far = Math.min(min_so_far, curr_min);
           }
 
           if (min_so_far == sum)
               return max_so_far;
 
           // returning the maximum value
           return Math.max(max_so_far, sum - min_so_far);
       }
 
       // Driver program to test maxCircularSum()
 
       let a = [11, 10, -20, 5, -3, -5, 8, -13, 10];
       let n = a.length;
       document.write("Maximum circular sum is " + maxCircularSum(a, n));
 
   // This code is contributed by Potta Lokesh
 
   </script>


Output

Maximum circular sum is 31

Time Complexity: O(n), where n is the number of elements in the input array. Linear traversal of the array is needed.
Auxiliary Space: O(1), No extra space is required.



Last Updated : 13 Jun, 2023
Like Article
Save Article
Previous
Next
Share your thoughts in the comments
Similar Reads