Worst, Average & Best Cases | Algorithms - Computer Science Engineering (CSE) PDF Download

Introduction

We can have three cases to analyze an algorithm:

  1. The Worst Case
  2. Average Case 
  3. Best Case

Let us consider the following implementation of Linear Search:

C++
// C++ implementation of the approach
#include <bits/stdc++.h>
using namespace std;
// Linearly search x in arr[].
// If x is present then return the index,
// otherwise return -1
int search(int arr[], int n, int x)
{
    int i;
    for (i = 0; i < n; i++) {
        if (arr[i] == x)
            return i;
    }
    return -1;
}
// Driver Code
int main()
{
    int arr[] = { 1, 10, 30, 15 };
    int x = 30;
    int n = sizeof(arr) / sizeof(arr[0]);
    cout << x << " is present at index "
         << search(arr, n, x);
    getchar();
    return 0;
}
// This code is contributed
// by Akanksha Rai

C
// C implementation of the approach
#include <stdio.h>
// Linearly search x in arr[].
// If x is present then return the index,
// otherwise return -1
int search(int arr[], int n, int x)
{
    int i;
    for (i = 0; i < n; i++) {
        if (arr[i] == x)
            return i;
    }
    return -1;
}
/* Driver program to test above functions*/
int main()
{
    int arr[] = { 1, 10, 30, 15 };
    int x = 30;
    int n = sizeof(arr) / sizeof(arr[0]);
    printf("%d is present at index %d", x,
           search(arr, n, x));
    getchar();
    return 0;
}

Java
// Java implementation of the approach
public class GFG {
    // Linearly search x in arr[].  If x is present then
    // return the index, otherwise return -1
    static int search(int arr[], int n, int x)
    {
        int i;
        for (i = 0; i < n; i++) {
            if (arr[i] == x) {
                return i;
            }
        }

        return -1;
    }
    /* Driver program to test above functions*/
    public static void main(String[] args)
    {
        int arr[] = { 1, 10, 30, 15 };
        int x = 30;
        int n = arr.length;
        System.out.printf("%d is present at index %d", x,
                          search(arr, n, x));
    }
}
/*This code is contributed by PrinciRaj1992*/

Python3
# Python 3 implementation of the approach
# Linearly search x in arr[]. If x is present
# then return the index, otherwise return -1
def search(arr, x):
    for index, value in enumerate(arr):
        if value == x:
            return index
    return -1
# Driver Code
arr = [1, 10, 30, 15]
x = 30
print(x, "is present at index",
      search(arr, x))
# This code is contributed
# by PrinciRaj1992

C#
// C# implementation of the approach
using System;
public class GFG {
    // Linearly search x in arr[].  If x is present then
    // return the index, otherwise return -1
    static int search(int[] arr, int n, int x)
    {
        int i;
        for (i = 0; i < n; i++) {
            if (arr[i] == x) {
                return i;
            }
        }
        return -1;
    }
    /* Driver program to test above functions*/
    public static void Main()
    {
        int[] arr = { 1, 10, 30, 15 };
        int x = 30;
        int n = arr.Length;
        Console.WriteLine(x + " is present at index "
                          + search(arr, n, x));
    }
}
/*This code is contributed by PrinciRaj1992*/

PHP
<?php
// PHP implementation of the approach
// Linearly search x in arr[]. If x
// is present then return the index,
// otherwise return -1
function search($arr, $n, $x)
{
    for ($i = 0; $i < $n; $i++)
    {
    if ($arr[$i] == $x)
        return $i;
    }
    return -1;
}
// Driver Code
$arr = array(1, 10, 30, 15);
$x = 30;
$n = sizeof($arr);
echo $x . " is present at index ".
             search($arr, $n, $x);
// This code is contributed
// by Akanksha Rai

Output:
30 is present at index 2

Worst Case Analysis (Usually Done)

In the worst case analysis, we calculate upper bound on running time of an algorithm. We must know the case that causes maximum number of operations to be executed. For Linear Search, the worst case happens when the element to be searched (x in the above code) is not present in the array. When x is not present, the search() functions compares it with all the elements of arr[] one by one. Therefore, the worst case time complexity of linear search would be Θ(n).

Average Case Analysis (Sometimes done)

In average case analysis, we take all possible inputs and calculate computing time for all of the inputs. Sum all the calculated values and divide the sum by total number of inputs. We must know (or predict) distribution of cases. For the linear search problem, let us assume that all cases are uniformly distributed (including the case of x not being present in array). So we sum all the cases and divide the sum by (n+1). Following is the value of average case time complexity.

Worst, Average & Best Cases | Algorithms - Computer Science Engineering (CSE)

Best Case Analysis (Bogus)

In the best case analysis, we calculate lower bound on running time of an algorithm. We must know the case that causes minimum number of operations to be executed. In the linear search problem, the best case occurs when x is present at the first location. The number of operations in the best case is constant (not dependent on n). So time complexity in the best case would be Θ(1)
Most of the times, we do worst case analysis to analyze algorithms. In the worst analysis, we guarantee an upper bound on the running time of an algorithm which is good information.
The average case analysis is not easy to do in most of the practical cases and it is rarely done. In the average case analysis, we must know (or predict) the mathematical distribution of all possible inputs.
The Best Case analysis is bogus. Guaranteeing a lower bound on an algorithm doesn’t provide any information as in the worst case, an algorithm may take years to run.
For some algorithms, all the cases are asymptotically same, i.e., there are no worst and best cases. For example, Merge Sort. Merge Sort does Θ(nLogn) operations in all cases. Most of the other sorting algorithms have worst and best cases. For example, in the typical implementation of Quick Sort (where pivot is chosen as a corner element), the worst occurs when the input array is already sorted and the best occur when the pivot elements always divide array in two halves. For insertion sort, the worst case occurs when the array is reverse sorted and the best case occurs when the array is sorted in the same order as output.

The document Worst, Average & Best Cases | Algorithms - Computer Science Engineering (CSE) is a part of the Computer Science Engineering (CSE) Course Algorithms.
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FAQs on Worst, Average & Best Cases - Algorithms - Computer Science Engineering (CSE)

1. What are worst, average, and best cases in computer science engineering?
Ans. In computer science engineering, worst, average, and best cases refer to the different possible scenarios for the performance of an algorithm or program. The worst case represents the scenario where the algorithm takes the longest time or requires the most resources to complete. The best case represents the scenario where the algorithm performs optimally and completes in the shortest time or with the least resources. The average case represents the scenario that is expected to occur most frequently and provides a measure of the algorithm's typical performance.
2. Why is it important to analyze worst, average, and best cases in computer science engineering?
Ans. Analyzing worst, average, and best cases is important in computer science engineering because it helps in understanding the behavior and efficiency of algorithms or programs. By studying these cases, engineers can identify potential bottlenecks, optimize algorithms, and make informed decisions about which algorithms to use for specific tasks. It also helps in predicting the performance of an algorithm in real-world scenarios and comparing different algorithms based on their efficiency.
3. How are worst, average, and best cases analyzed in computer science engineering?
Ans. Worst, average, and best cases are analyzed in computer science engineering by considering the input size and the algorithm's time complexity. The worst case is determined by finding the scenario that maximizes the time or resource requirements of the algorithm. The best case is determined by finding the scenario that minimizes the time or resource requirements. The average case is calculated by taking into account the probabilities of different input scenarios and their corresponding time or resource requirements.
4. Can worst, average, and best cases be used to compare different algorithms?
Ans. Yes, worst, average, and best cases can be used to compare different algorithms. By analyzing these cases, engineers can evaluate the efficiency and performance of different algorithms in different scenarios. However, it is important to note that the worst, average, and best cases alone may not provide a complete picture of an algorithm's performance. Other factors such as memory usage, scalability, and real-world constraints should also be considered when comparing algorithms.
5. Are worst, average, and best cases only applicable to time complexity analysis?
Ans. No, worst, average, and best cases are not only applicable to time complexity analysis. While they are commonly used to analyze the time complexity of algorithms, they can also be applied to analyze other aspects such as space complexity, network bandwidth, or any other resource utilization. The concepts of worst, average, and best cases can be adapted to different performance metrics depending on the specific requirements of the problem being solved in computer science engineering.
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