Linked List is a linear data structure, in which elements are not stored at a contiguous location, rather they are linked using pointers. Linked List forms a series of connected nodes, where each node stores the data and the address of the next node.
Node Structure: A node in a linked list typically consists of two components:
Data: It holds the actual value or data associated with the node.
Next Pointer: It stores the memory address (reference) of the next node in the sequence.
Head and Tail: The linked list is accessed through the head node, which points to the first node in the list. The last node in the list points to NULL or nullptr, indicating the end of the list. This node is known as the tail node.
Why linked list data structure needed?
Here are a few advantages of a linked list that is listed below, it will help you understand why it is necessary to know.
- Dynamic Data structure: The size of memory can be allocated or de-allocated at run time based on the operation insertion or deletion.
- Ease of Insertion/Deletion: The insertion and deletion of elements are simpler than arrays since no elements need to be shifted after insertion and deletion, Just the address needed to be updated.
- Efficient Memory Utilization: As we know Linked List is a dynamic data structure the size increases or decreases as per the requirement so this avoids the wastage of memory.
- Implementation: Various advanced data structures can be implemented using a linked list like a stack, queue, graph, hash maps, etc.
In a system, if we maintain a sorted list of IDs in an array id = [1000, 1010, 1050, 2000, 2040].
If we want to insert a new ID 1005, then to maintain the sorted order, we have to move all the elements after 1000 (excluding 1000).
Deletion is also expensive with arrays until unless some special techniques are used. For example, to delete 1010 in id, everything after 1010 has to be moved due to this so much work is being done which affects the efficiency of the code.
There are mainly three types of linked lists:
- Single-linked list
- Double linked list
- Circular linked list
In a singly linked list, each node contains a reference to the next node in the sequence. Traversing a singly linked list is done in a forward direction.
In a doubly linked list, each node contains references to both the next and previous nodes. This allows for traversal in both forward and backward directions, but it requires additional memory for the backward reference.
In a circular linked list, the last node points back to the head node, creating a circular structure. It can be either singly or doubly linked.
Circular linked list
Operations on Linked Lists
- Insertion: Adding a new node to a linked list involves adjusting the pointers of the existing nodes to maintain the proper sequence. Insertion can be performed at the beginning, end, or any position within the list
- Deletion: Removing a node from a linked list requires adjusting the pointers of the neighboring nodes to bridge the gap left by the deleted node. Deletion can be performed at the beginning, end, or any position within the list.
- Searching: Searching for a specific value in a linked list involves traversing the list from the head node until the value is found or the end of the list is reached.
Advantages of Linked Lists
- Dynamic Size: Linked lists can grow or shrink dynamically, as memory allocation is done at runtime.
- Insertion and Deletion: Adding or removing elements from a linked list is efficient, especially for large lists.
- Flexibility: Linked lists can be easily reorganized and modified without requiring a contiguous block of memory.
Disadvantages of Linked Lists
- Random Access: Unlike arrays, linked lists do not allow direct access to elements by index. Traversal is required to reach a specific node.
- Extra Memory: Linked lists require additional memory for storing the pointers, compared to arrays.
Linked lists are versatile data structures that provide dynamic memory allocation and efficient insertion and deletion operations. Understanding the basics of linked lists is essential for any programmer or computer science enthusiast. With this knowledge, you can implement linked lists to solve various problems and expand your understanding of data structures and algorithms.
Feeling lost in the world of random DSA topics, wasting time without progress? It's time for a change! Join our DSA course, where we'll guide you on an exciting journey to master DSA efficiently and on schedule.
Ready to dive in? Explore our Free Demo Content and join our DSA course, trusted by over 100,000 geeks!