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You đang tìm kiếm từ khóa Delete last node in doubly linked list Python được Cập Nhật vào lúc : 2022-03-10 07:39:16 . Với phương châm chia sẻ Kinh Nghiệm Hướng dẫn trong nội dung bài viết một cách Chi Tiết Mới Nhất. Nếu sau khi đọc nội dung bài viết vẫn ko hiểu thì hoàn toàn có thể lại Comments ở cuối bài để Tác giả lý giải và hướng dẫn lại nha.

There are various linked list operations that allow us to perform different actions on linked lists. For example, the insertion operation adds a new element to the linked list.

Nội dung chính

    Things to Remember about Linked ListTraverse a Linked ListInsert Elements to a Linked List1. Insert the beginning2. Insert the End3. Insert the MiddleDelete from a Linked List1. Delete from beginning2. Delete from end3. Delete from middleSearch an Element on a Linked ListSort Elements of a Linked ListLinkedList Operations in Python, Java, C, and C++

Here’s a list of basic linked list operations that we will cover in this article.

    Traversal – access each element of the linked list Insertion – adds a new element to the linked list Deletion – removes the existing elements Search – find a node in the linked list Sort – sort the nodes of the linked list

Before you learn about linked list operations in detail, make sure to know about Linked List first.

Things to Remember about Linked List

    head points to the first node of the linked list next pointer of the last node is NULL, so if the next current node is NULL, we have reached the end of the linked list.

In all of the examples, we will assume that the linked list has three nodes 1 —>2 —>3 with node structure as below:

struct node
int data;
struct node *next;
;

Traverse a Linked List

Displaying the contents of a linked list is very simple. We keep moving the temp node to the next one and display its contents.

When temp is NULL, we know that we have reached the end of the linked list so we get out of the while loop.

struct node *temp = head;
printf(“nnList elements are – n”);
while(temp != NULL)
printf(“%d —>”,temp->data);
temp = temp->next;

The output of this program will be:

List elements are – 1 —>2 —>3 —>

Insert Elements to a Linked List

You can add elements to either the beginning, middle or end of the linked list.

1. Insert the beginning

    Allocate memory for new node Store data Change next of new node to point to head Change head to point to recently created node

struct node *newNode;
newNode = malloc(sizeof(struct node));
newNode->data = 4;
newNode->next = head;
head = newNode;

2. Insert the End

    Allocate memory for new node Store data Traverse to last node Change next of last node to recently created node

struct node *newNode;
newNode = malloc(sizeof(struct node));
newNode->data = 4;
newNode->next = NULL;

struct node *temp = head;
while(temp->next != NULL)
temp = temp->next;

temp->next = newNode;

3. Insert the Middle

    Allocate memory and store data for new node Traverse to node just before the required position of new node Change next pointers to include new node in between

struct node *newNode;
newNode = malloc(sizeof(struct node));
newNode->data = 4;

struct node *temp = head;

for(int i=2; i next != NULL)
temp = temp->next;

newNode->next = temp->next;
temp->next = newNode;

Delete from a Linked List

You can delete either from the beginning, end or from a particular position.

1. Delete from beginning

    Point head to the second node

head = head->next;

2. Delete from end

    Traverse to second last element Change its next pointer to null

struct node* temp = head;
while(temp->next->next!=NULL)
temp = temp->next;

temp->next = NULL;

3. Delete from middle

    Traverse to element before the element to be deleted Change next pointers to exclude the node from the chain

for(int i=2; inext!=NULL)
temp = temp->next;

temp->next = temp->next->next;

Search an Element on a Linked List

You can search an element on a linked list using a loop using the following steps. We are finding item on a linked list.

    Make head as the current node. Run a loop until the current node is NULL because the last element points to NULL. In each iteration, check if the key of the node is equal to item. If it the key matches the item, return true otherwise return false.

// Search a node
bool searchNode(struct Node** head_ref, int key)
struct Node* current = *head_ref;

while (current != NULL)
if (current->data == key) return true;
current = current->next;

return false;

Sort Elements of a Linked List

We will use a simple sorting algorithm, Bubble Sort, to sort the elements of a linked list in ascending order below.

Make the head as the current node and create another node index for later use. If head is null, return. Else, run a loop till the last node (i.e. NULL). In each iteration, follow the following step 5-6. Store the next node of current in index. Check if the data of the current node is greater than the next node. If it is greater, swap current and index.

Check the article on bubble sort for better understanding of its working.

// Sort the linked list
void sortLinkedList(struct Node** head_ref)
struct Node *current = *head_ref, *index = NULL;
int temp;

if (head_ref == NULL)
return;
else
while (current != NULL)
// index points to the node next to current
index = current->next;

while (index != NULL)
if (current->data > index->data)
temp = current->data;
current->data = index->data;
index->data = temp;

index = index->next;

current = current->next;

LinkedList Operations in Python, Java, C, and C++

# Linked list operations in Python

# Create a node
class Node:
def __init__(self, data):
self.data = data
self.next = None

class LinkedList:

def __init__(self):
self.head = None

# Insert the beginning
def insertAtBeginning(self, new_data):
new_node = Node(new_data)

new_node.next = self.head
self.head = new_node

# Insert after a node
def insertAfter(self, prev_node, new_data):

if prev_node is None:
print(“The given previous node must inLinkedList.”)
return

new_node = Node(new_data)
new_node.next = prev_node.next
prev_node.next = new_node

# Insert the end
def insertAtEnd(self, new_data):
new_node = Node(new_data)

if self.head is None:
self.head = new_node
return

last = self.head
while (last.next):
last = last.next

last.next = new_node

# Deleting a node
def deleteNode(self, position):

if self.head is None:
return

temp = self.head

if position == 0:
self.head = temp.next
temp = None
return

# Find the key to be deleted
for i in range(position – 1):
temp = temp.next
if temp is None:
break

# If the key is not present
if temp is None:
return

if temp.next is None:
return

next = temp.next.next

temp.next = None

temp.next = next

# Search an element
def search(self, key):

current = self.head

while current is not None:
if current.data == key:
return True

current = current.next

return False

# Sort the linked list
def sortLinkedList(self, head):
current = head
index = Node(None)

if head is None:
return
else:
while current is not None:
# index points to the node next to current
index = current.next

while index is not None:
if current.data > index.data:
current.data, index.data = index.data, current.data

index = index.next
current = current.next

# Print the linked list
def printList(self):
temp = self.head
while (temp):
print(str(temp.data) + ” “, end=””)
temp = temp.next

if __name__ == ‘__main__’:

llist = LinkedList()
llist.insertAtEnd(1)
llist.insertAtBeginning(2)
llist.insertAtBeginning(3)
llist.insertAtEnd(4)
llist.insertAfter(llist.head.next, 5)

print(‘linked list:’)
llist.printList()

print(“nAfter deleting an element:”)
llist.deleteNode(3)
llist.printList()

print()
item_to_find = 3
if llist.search(item_to_find):
print(str(item_to_find) + ” is found”)
else:
print(str(item_to_find) + ” is not found”)

llist.sortLinkedList(llist.head)
print(“Sorted List: “)
llist.printList()

// Linked list operations in Java

class LinkedList
Node head;

// Create a node
class Node
int data;
Node next;

Node(int d)
data = d;
next = null;

// Insert the beginning
public void insertAtBeginning(int new_data)
// insert the data
Node new_node = new Node(new_data);
new_node.next = head;
head = new_node;

// Insert after a node
public void insertAfter(Node prev_node, int new_data)
if (prev_node == null)
System.out.println(“The given previous node cannot be null”);
return;

Node new_node = new Node(new_data);
new_node.next = prev_node.next;
prev_node.next = new_node;

// Insert the end
public void insertAtEnd(int new_data)
Node new_node = new Node(new_data);

if (head == null)
head = new Node(new_data);
return;

new_node.next = null;

Node last = head;
while (last.next != null)
last = last.next;

last.next = new_node;
return;

// Delete a node
void deleteNode(int position)
if (head == null)
return;

Node temp = head;

if (position == 0)
head = temp.next;
return;

// Find the key to be deleted
for (int i = 0; temp != null && i index.data)
temp = current.data;
current.data = index.data;
index.data = temp;

index = index.next;

current = current.next;

// Print the linked list
public void printList()
Node tnode = head;
while (tnode != null)
System.out.print(tnode.data + ” “);
tnode = tnode.next;

public static void main(String[] args)
LinkedList llist = new LinkedList();

llist.insertAtEnd(1);
llist.insertAtBeginning(2);
llist.insertAtBeginning(3);
llist.insertAtEnd(4);
llist.insertAfter(llist.head.next, 5);

System.out.println(“Linked list: “);
llist.printList();

System.out.println(“nAfter deleting an element: “);
llist.deleteNode(3);
llist.printList();

System.out.println();
int item_to_find = 3;
if (llist.search(llist.head, item_to_find))
System.out.println(item_to_find + ” is found”);
else
System.out.println(item_to_find + ” is not found”);

llist.sortLinkedList(llist.head);
System.out.println(“nSorted List: “);
llist.printList();

// Linked list operations in C

#include
#include

// Create a node
struct Node
int data;
struct Node* next;
;

// Insert the beginning
void insertAtBeginning(struct Node** head_ref, int new_data)
// Allocate memory to a node
struct Node* new_node = (struct Node*)malloc(sizeof(struct Node));

// insert the data
new_node->data = new_data;

new_node->next = (*head_ref);

// Move head to new node
(*head_ref) = new_node;

// Insert a node after a node
void insertAfter(struct Node* prev_node, int new_data)
if (prev_node == NULL)
printf(“the given previous node cannot be NULL”);
return;

struct Node* new_node = (struct Node*)malloc(sizeof(struct Node));
new_node->data = new_data;
new_node->next = prev_node->next;
prev_node->next = new_node;

// Insert the the end
void insertAtEnd(struct Node** head_ref, int new_data)
struct Node* new_node = (struct Node*)malloc(sizeof(struct Node));
struct Node* last = *head_ref; /* used in step 5*/

new_node->data = new_data;
new_node->next = NULL;

if (*head_ref == NULL)
*head_ref = new_node;
return;

while (last->next != NULL) last = last->next;

last->next = new_node;
return;

// Delete a node
void deleteNode(struct Node** head_ref, int key)
struct Node *temp = *head_ref, *prev;

if (temp != NULL && temp->data == key)
*head_ref = temp->next;
không lấy phí(temp);
return;

// Find the key to be deleted
while (temp != NULL && temp->data != key)
prev = temp;
temp = temp->next;

// If the key is not present
if (temp == NULL) return;

// Remove the node
prev->next = temp->next;

không lấy phí(temp);

// Search a node
int searchNode(struct Node** head_ref, int key)
struct Node* current = *head_ref;

while (current != NULL)
if (current->data == key) return 1;
current = current->next;

return 0;

// Sort the linked list
void sortLinkedList(struct Node** head_ref)
struct Node *current = *head_ref, *index = NULL;
int temp;

if (head_ref == NULL)
return;
else
while (current != NULL)
// index points to the node next to current
index = current->next;

while (index != NULL)
if (current->data > index->data)
temp = current->data;
current->data = index->data;
index->data = temp;

index = index->next;

current = current->next;

// Print the linked list
void printList(struct Node* node)
while (node != NULL)
printf(” %d “, node->data);
node = node->next;

// Driver program
int main()
struct Node* head = NULL;

insertAtEnd(&head, 1);
insertAtBeginning(&head, 2);
insertAtBeginning(&head, 3);
insertAtEnd(&head, 4);
insertAfter(head->next, 5);

printf(“Linked list: “);
printList(head);

printf(“nAfter deleting an element: “);
deleteNode(&head, 3);
printList(head);

int item_to_find = 3;
if (searchNode(&head, item_to_find))
printf(“n%d is found”, item_to_find);
else
printf(“n%d is not found”, item_to_find);

sortLinkedList(&head);
printf(“nSorted List: “);
printList(head);

// Linked list operations in C++

#include

#include
using namespace std;

// Create a node
struct Node
int data;
struct Node* next;
;

void insertAtBeginning(struct Node** head_ref, int new_data)
// Allocate memory to a node
struct Node* new_node = (struct Node*)malloc(sizeof(struct Node));

// insert the data
new_node->data = new_data;
new_node->next = (*head_ref);

// Move head to new node
(*head_ref) = new_node;

// Insert a node after a node
void insertAfter(struct Node* prev_node, int new_data)
if (prev_node == NULL)
cout <data = new_data;
new_node->next = prev_node->next;
prev_node->next = new_node;

// Insert the end
void insertAtEnd(struct Node** head_ref, int new_data)
struct Node* new_node = (struct Node*)malloc(sizeof(struct Node));
struct Node* last = *head_ref; /* used in step 5*/

new_node->data = new_data;
new_node->next = NULL;

if (*head_ref == NULL)
*head_ref = new_node;
return;

while (last->next != NULL) last = last->next;

last->next = new_node;
return;

// Delete a node
void deleteNode(struct Node** head_ref, int key)
struct Node *temp = *head_ref, *prev;

if (temp != NULL && temp->data == key)
*head_ref = temp->next;
không lấy phí(temp);
return;

// Find the key to be deleted
while (temp != NULL && temp->data != key)
prev = temp;
temp = temp->next;

// If the key is not present
if (temp == NULL) return;

// Remove the node
prev->next = temp->next;

không lấy phí(temp);

// Search a node
bool searchNode(struct Node** head_ref, int key)
struct Node* current = *head_ref;

while (current != NULL)
if (current->data == key) return true;
current = current->next;

return false;

// Sort the linked list
void sortLinkedList(struct Node** head_ref)
struct Node *current = *head_ref, *index = NULL;
int temp;

if (head_ref == NULL)
return;
else
while (current != NULL)
// index points to the node next to current
index = current->next;

while (index != NULL)
if (current->data > index->data)
temp = current->data;
current->data = index->data;
index->data = temp;

index = index->next;

current = current->next;

// Print the linked list
void printList(struct Node* node)
while (node != NULL)
cout <data <next;

// Driver program
int main()
struct Node* head = NULL;

insertAtEnd(&head, 1);
insertAtBeginning(&head, 2);
insertAtBeginning(&head, 3);
insertAtEnd(&head, 4);
insertAfter(head->next, 5);

cout << "Linked list: ";
printList(head);

cout << "nAfter deleting an element: ";
deleteNode(&head, 3);
printList(head);

int item_to_find = 3;
if (searchNode(&head, item_to_find))
cout << endl << item_to_find << " is found";
else
cout << endl << item_to_find << " is not found";

sortLinkedList(&head);
cout << "nSorted List: ";
printList(head);

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