📌 相关文章
- 数据结构-单链表
- 数据结构-循环单链表
- 数据结构-循环单链表(1)
- 单链表 (1)
- c# 单链表 - C# (1)
- c# 单链表 - C# 代码示例
- 单链表 - 任何代码示例
- java代码示例中的单链表
- java中的单链表(1)
- 数据结构示例-创建N个节点单链表与计数
- 数据结构示例-创建n个节点的单链表列表并反序打印
- 数据结构示例-从头部删除单链表节点(1)
- 数据结构示例-从头部删除单链表节点
- 单链表的定义 - C++ 代码示例
- 将字符串转换为单链表
- 单链表的定义 - C++ (1)
- 单链表所有素节点的和与积(1)
- 单链表所有素节点的和与积
- c++ 数据结构 - C++ 代码示例
- c++ 数据结构 - C++ (1)
- 树数据结构
- 堆数据结构
- 数据结构-图(1)
- C++数据结构(1)
- 数据结构 (1)
- 数据结构-图
- C++数据结构
- 堆数据结构
- 数据结构-树
📜 数据结构示例-创建单链表并打印
📅 最后修改于: 2020-10-15 04:47:18 🧑 作者: Mango
程序创建和显示单链列表
说明
在此程序中,我们需要创建一个单链列表并显示列表中存在的所有节点。
单链表
单链接列表是线性数据结构,其中列表的每个元素都包含一个指向列表中下一个元素的指针。单链列表中的每个元素都称为节点。每个节点都有两个部分:数据和下一个指向列表中下一个节点的指针。列表的第一个节点称为头,列表的最后一个节点称为尾。列表的最后一个节点包含一个指向null的指针。通过从头到尾遍历列表,可以线性访问列表中的每个节点。
考虑上面的例子;节点1是列表的开头,节点4是列表的结尾。每个节点的连接方式如下:节点1指向节点2,节点2依次指向节点3。节点3再次指向节点4。节点4指向null,因为它是列表的最后一个节点。
算法
- 创建一个具有两个属性的类Node:data和next。下一个是指向下一个节点的指针。
- 创建另一个具有两个属性的类:head和tail。
- addNode()将向列表添加一个新节点:
- 创建一个新节点。
- 它首先检查head是否等于null,这意味着列表为空。
- 如果列表为空,头和尾都将指向新添加的节点。
- 如果列表不为空,则新节点将被添加到列表的末尾,使得尾部的下一个将指向新添加的节点。这个新节点将成为列表的新尾部。
- display()将显示列表中存在的节点:
- 定义一个节点电流,该电流最初指向列表的开头。
- 遍历列表,直到当前指向null。
- 通过在每次迭代中使电流指向其旁边的节点来显示每个节点。
示例:
Python
#Represent a node of the singly linked list
class Node:
def __init__(self,data):
self.data = data;
self.next = None;
class SinglyLinkedList:
#Represent the head and tail of the singly linked list
def __init__(self):
self.head = None;
self.tail = None;
#addNode() will add a new node to the list
def addNode(self, data):
#Create a new node
newNode = Node(data);
#Checks if the list is empty
if(self.head == None):
#If list is empty, both head and tail will point to new node
self.head = newNode;
self.tail = newNode;
else:
#newNode will be added after tail such that tail's next will point to newNode
self.tail.next = newNode;
#newNode will become new tail of the list
self.tail = newNode;
#display() will display all the nodes present in the list
def display(self):
#Node current will point to head
current = self.head;
if(self.head == None):
print("List is empty");
return;
print("Nodes of singly linked list: ");
while(current != None):
#Prints each node by incrementing pointer
print(current.data),
current = current.next;
sList = SinglyLinkedList();
#Add nodes to the list
sList.addNode(1);
sList.addNode(2);
sList.addNode(3);
sList.addNode(4);
#Displays the nodes present in the list
sList.display();
输出:
Nodes of singly linked list:
1 2 3 4
C
#include
#include
//Represent a node of singly linked list
struct node{
int data;
struct node *next;
};
//Represent the head and tail of the singly linked list
struct node *head, *tail = NULL;
//addNode() will add a new node to the list
void addNode(int data) {
//Create a new node
struct node *newNode = (struct node*)malloc(sizeof(struct node));
newNode->data = data;
newNode->next = NULL;
//Checks if the list is empty
if(head == NULL) {
//If list is empty, both head and tail will point to new node
head = newNode;
tail = newNode;
}
else {
//newNode will be added after tail such that tail's next will point to newNode
tail->next = newNode;
//newNode will become new tail of the list
tail = newNode;
}
}
//display() will display all the nodes present in the list
void display() {
//Node current will point to head
struct node *current = head;
if(head == NULL) {
printf("List is empty\n");
return;
}
printf("Nodes of singly linked list: \n");
while(current != NULL) {
//Prints each node by incrementing pointer
printf("%d ", current->data);
current = current->next;
}
printf("\n");
}
int main()
{
//Add nodes to the list
addNode(1);
addNode(2);
addNode(3);
addNode(4);
//Displays the nodes present in the list
display();
return 0;
}
输出:
Nodes of singly linked list:
1 2 3 4
JAVA
public class SinglyLinkedList {
//Represent a node of the singly linked list
class Node{
int data;
Node next;
public Node(int data) {
this.data = data;
this.next = null;
}
}
//Represent the head and tail of the singly linked list
public Node head = null;
public Node tail = null;
//addNode() will add a new node to the list
public void addNode(int data) {
//Create a new node
Node newNode = new Node(data);
//Checks if the list is empty
if(head == null) {
//If list is empty, both head and tail will point to new node
head = newNode;
tail = newNode;
}
else {
//newNode will be added after tail such that tail's next will point to newNode
tail.next = newNode;
//newNode will become new tail of the list
tail = newNode;
}
}
//display() will display all the nodes present in the list
public void display() {
//Node current will point to head
Node current = head;
if(head == null) {
System.out.println("List is empty");
return;
}
System.out.println("Nodes of singly linked list: ");
while(current != null) {
//Prints each node by incrementing pointer
System.out.print(current.data + " ");
current = current.next;
}
System.out.println();
}
public static void main(String[] args) {
SinglyLinkedList sList = new SinglyLinkedList();
//Add nodes to the list
sList.addNode(1);
sList.addNode(2);
sList.addNode(3);
sList.addNode(4);
//Displays the nodes present in the list
sList.display();
}
}
输出:
Nodes of singly linked list:
1 2 3 4
C#
using System;
public class CreateList
{
//Represent a node of the singly linked list
public class Node{
public T data;
public Node next;
public Node(T value) {
data = value;
next = null;
}
}
public class SinglyLinkedList{
//Represent the head and tail of the singly linked list
public Node head = null;
public Node tail = null;
//addNode() will add a new node to the list
public void addNode(T data) {
//Create a new node
Node newNode = new Node(data);
//Checks if the list is empty
if(head == null) {
//If list is empty, both head and tail will point to new node
head = newNode;
tail = newNode;
}
else {
//newNode will be added after tail such that tail's next will point to newNode
tail.next = newNode;
//newNode will become new tail of the list
tail = newNode;
}
}
//display() will display all the nodes present in the list
public void display() {
//Node current will point to head
Node current = head;
if(head == null) {
Console.WriteLine("List is empty");
return;
}
Console.WriteLine("Nodes of singly linked list: ");
while(current != null) {
//Prints each node by incrementing pointer
Console.Write(current.data + " ");
current = current.next;
}
Console.WriteLine();
}
}
public static void Main()
{
SinglyLinkedList sList = new SinglyLinkedList();
//Add nodes to the list
sList.addNode(1);
sList.addNode(2);
sList.addNode(3);
sList.addNode(4);
//Displays the nodes present in the list
sList.display();
}
}
输出:
Nodes of singly linked list:
1 2 3 4
PHP
data = $data;
$this->next = NULL;
}
}
class SinglyLinkedList{
//Represent the head and tail of the singly linked list
public $head;
public $tail;
function __construct(){
$this->head = NULL;
$this->tail = NULL;
}
//addNode() will add a new node to the list
function addNode($data) {
//Create a new node
$newNode = new Node($data);
//Checks if the list is empty
if($this->head == NULL) {
//If list is empty, both head and tail will point to new node
$this->head = $newNode;
$this->tail = $newNode;
}
else {
//newNode will be added after tail such that tail's next will point to newNode
$this->tail->next = $newNode;
//newNode will become new tail of the list
$this->tail = $newNode;
}
}
//display() will display all the nodes present in the list
function display() {
//Node current will point to head
$current = $this->head;
if($this->head == NULL) {
print("List is empty
");
return;
}
print("Nodes of singly linked list:
");
while($current != NULL) {
//Prints each node by incrementing pointer
print($current->data . " ");
$current = $current->next;
}
print("
");
}
}
$sList = new SinglyLinkedList();
//Add nodes to the list
$sList->addNode(1);
$sList->addNode(2);
$sList->addNode(3);
$sList->addNode(4);
//Displays the nodes present in the list
$sList->display();
?>
输出:
Nodes of singly linked list:
1 2 3 4