Hello there! Today, we will unveil Queues in coding, likening them to a line in a coffee shop or a queue of print requests. Queues in computer science are First-In, First-Out (FIFO) structures. Consider this example: you're at a theme park — the first person in line for the roller coaster gets on first. Today's lesson revolves around this straightforward yet powerful concept. So, let's dive in!

Let's explore the implementation of Queues in C#. An array is ideal for implementing a Queue. Let's define the Queue:

In the Queue class above, the IsFull() method checks if our queue is already at maximum capacity.

Enqueue, a fancy term, denotes adding an item to the queue — the item lines up at the rear. Here's how it plays out in our Queue class:

rear = (rear + 1) % capacity uses the modulo operator to calculate the new position for the rear pointer, ensuring it wraps around to the start of the queue when it surpasses the maximum index, thereby maintaining a circular behavior.

Just as Enqueue adds an element to our queue, Dequeue removes it. It extracts the element at the queue's front, reducing its size. However, we encounter an underflow condition if there are no elements to remove.

The Dequeue() method checks for emptiness before dispatching the item.

The time complexity of enqueue and dequeue operations remains constant: O(1). However, the space complexity varies with the size of the queue, making it O(n).

While it is essential to understand the queue's inner structure, we won't implement it ourselves. Instead, we will use C#'s built-in Queue<T> class. Think of any system that needs to handle requests in a fair, first-come-first-served order. These are all excellent candidates for using a queue. Here's how you can declare, initialize, and utilize a Queue<T> using C#:

In the above example, we create an instance of Queue<int> using C#. Key Queue operations include:

• Enqueue(): Inserts the specified element into the Queue.
• Dequeue(): Removes and returns the head of the Queue.
• Peek(): Retrieves, but does not remove, the head of the Queue, returning null if the queue is empty.
• Count: Returns the number of elements in the Queue.

C#'s Queue<T> class is versatile and can accommodate diverse data types.

We've learned about the Queue, its operations, and its implementation in C#. Furthermore, these techniques are fundamental for smooth functioning in daily life. They are invaluable and versatile in various applications, from data buffering in hardware to process scheduling in operating systems.

With your newfound knowledge of the Queue data structure, it's time to level up! Next are some practice problems to enhance your understanding of these concepts. Let's dive in!