KNOWPIA
WELCOME TO KNOWPIA

In computer science, a **doubly linked list** is a linked data structure that consists of a set of sequentially linked records called nodes. Each node contains three fields: two link fields (references to the previous and to the next node in the sequence of nodes) and one data field. The beginning and ending nodes' **previous** and **next** links, respectively, point to some kind of terminator, typically a sentinel node or null, to facilitate traversal of the list. If there is only one sentinel node, then the list is circularly linked via the sentinel node. It can be conceptualized as two singly linked lists formed from the same data items, but in opposite sequential orders.

The two node links allow traversal of the list in either direction. While adding or removing a node in a doubly linked list requires changing more links than the same operations on a singly linked list, the operations are simpler and potentially more efficient (for nodes other than first nodes) because there is no need to keep track of the previous node during traversal or no need to traverse the list to find the previous node, so that its link can be modified.

The first and last nodes of a doubly linked list for all practical applications are immediately accessible (i.e., accessible without traversal, and usually called *head* and *tail*) and therefore allow traversal of the list from the beginning or end of the list, respectively: e.g., traversing the list from beginning to end, or from end to beginning, in a search of the list for a node with specific data value. Any node of a doubly linked list, once obtained, can be used to begin a new traversal of the list, in either direction (towards beginning or end), from the given node.

The link fields of a doubly linked list node are often called **next** and **previous** or **forward** and **backward**. The references stored in the link fields are usually implemented as pointers, but (as in any linked data structure) they may also be address offsets or indices into an array where the nodes live.

Consider the following basic algorithms written in Ada:

recordDoublyLinkedNode{ next// A reference to the next nodeprev// A reference to the previous nodedata// Data or a reference to data}

recordDoublyLinkedList{DoublyLinkedNodefirstNode// points to first node of listDoublyLinkedNodelastNode// points to last node of list}

Traversal of a doubly linked list can be in either direction. In fact, the direction of traversal can change many times, if desired. **Traversal** is often called **iteration**, but that choice of terminology is unfortunate, for **iteration** has well-defined semantics (e.g., in mathematics) which are not analogous to **traversal**.

*Forwards*

node := list.firstNodewhilenode ≠null<do something with node.data> node := node.next

*Backwards*

node := list.lastNodewhilenode ≠null<do something with node.data> node := node.prev

These symmetric functions insert a node either after or before a given node:

functioninsertAfter(Listlist,Nodenode,NodenewNode) newNode.prev := nodeifnode.next ==nullnewNode.next :=null-- (not always necessary)list.lastNode := newNodeelsenewNode.next := node.next node.next.prev := newNode node.next := newNode

functioninsertBefore(Listlist,Nodenode,NodenewNode) newNode.next := nodeifnode.prev ==nullnewNode.prev :=null-- (not always necessary)list.firstNode := newNodeelsenewNode.prev := node.prev node.prev.next := newNode node.prev := newNode

We also need a function to insert a node at the beginning of a possibly empty list:

functioninsertBeginning(Listlist,NodenewNode)iflist.firstNode ==nulllist.firstNode := newNode list.lastNode := newNode newNode.prev := null newNode.next := nullelseinsertBefore(list, list.firstNode, newNode)

A symmetric function inserts at the end:

functioninsertEnd(Listlist,NodenewNode)iflist.lastNode ==nullinsertBeginning(list, newNode)elseinsertAfter(list, list.lastNode, newNode)

Removal of a node is easier than insertion, but requires special handling if the node to be removed is the *firstNode* or *lastNode*:

functionremove(Listlist,Nodenode)ifnode.prev ==nulllist.firstNode := node.nextelsenode.prev.next := node.nextifnode.next ==nulllist.lastNode := node.prevelsenode.next.prev := node.prev

One subtle consequence of the above procedure is that deleting the last node of a list sets both *firstNode* and *lastNode* to *null*, and so it handles removing the last node from a one-element list correctly. Notice that we also don't need separate "removeBefore" or "removeAfter" methods, because in a doubly linked list we can just use "remove(node.prev)" or "remove(node.next)" where these are valid. This also assumes that the node being removed is guaranteed to exist. If the node does not exist in this list, then some error handling would be required.

Assuming that *someNode* is some node in a non-empty list, this code traverses through that list starting with *someNode* (any node will do):

*Forwards*

node := someNodedodo something with node.value node := node.nextwhilenode ≠ someNode

*Backwards*

node := someNodedodo something with node.value node := node.prevwhilenode ≠ someNode

Notice the postponing of the test to the end of the loop. This is important for the case where the list contains only the single node *someNode*.

This simple function inserts a node into a doubly linked circularly linked list after a given element:

functioninsertAfter(Nodenode,NodenewNode) newNode.next := node.next newNode.prev := node node.next.prev := newNode node.next := newNode

To do an "insertBefore", we can simply "insertAfter(node.prev, newNode)".

Inserting an element in a possibly empty list requires a special function:

functioninsertEnd(Listlist,Nodenode)iflist.lastNode ==nullnode.prev := node node.next := nodeelseinsertAfter(list.lastNode, node) list.lastNode := node

To insert at the beginning we simply "insertAfter(list.lastNode, node)".

Finally, removing a node must deal with the case where the list empties:

functionremove(Listlist,Nodenode);ifnode.next == node list.lastNode :=nullelsenode.next.prev := node.prev node.prev.next := node.nextifnode == list.lastNode list.lastNode := node.prev;destroynode

As in doubly linked lists, "removeAfter" and "removeBefore" can be implemented with "remove(list, node.prev)" and "remove(list, node.next)".

An asymmetric doubly linked list is somewhere between the singly linked list and the regular doubly linked list. It shares some features with the singly linked list (single-direction traversal) and others from the doubly linked list (ease of modification)

It is a list where each node's *previous* link points not to the previous node, but to the link to itself. While this makes little difference between nodes (it just points to an offset within the previous node), it changes the head of the list: It allows the first node to modify the *firstNode* link easily.^{[1]}^{[2]}

As long as a node is in a list, its *previous* link is never null.

To insert a node before another, we change the link that pointed to the old node, using the *prev* link; then set the new node's *next* link to point to the old node, and change that node's *prev* link accordingly.

functioninsertBefore(Nodenode,NodenewNode)ifnode.prev ==nullerror"The node is not in a list" newNode.prev := node.prev atAddress(newNode.prev) := newNode newNode.next := node node.prev = addressOf(newNode.next)

functioninsertAfter(Nodenode,NodenewNode) newNode.next := node.nextifnewNode.next !=nullnewNode.next.prev = addressOf(newNode.next) node.next := newNode newNode.prev := addressOf(node.next)

To remove a node, we simply modify the link pointed by *prev*, regardless of whether the node was the first one of the list.

functionremove(Nodenode) atAddress(node.prev) := node.nextifnode.next !=nullnode.next.prev = node.prevdestroynode