迭代法
- 初始化三个指针prev为NULL,curr为head,next为NULL。
- 通过链表迭代。在循环中,执行以下操作。
//在更改当前节点的下一个节点之前,
//存储下一个节点
next = curr-> next
//现在改变当前节点的下一节点
//这是实际逆转发生的地方
curr-> next = prev
//将prev和curr向前移动一步
prev = curr
curr = next
总结为:先存储当前节点的下一节点,再反转当前节点的pnext指针,最后重置head头部。
注意:若head指向Null而不放数据,则prev、curr、next应相应改变
class Link:
def __init__(self):
self.phead = None
self.length = 0
def creat(self, datas):
self.phead = Node(None) # 创建空的头部,不存数据
pend = self.phead # 借用临时量,方便后续操作
for i in datas: # 依次从所给入参中拿数据
node = Node(i) # 创建节点
pend.pnext = node # 上一节点的pnext指针,指向这个新创建的节点
pend = node # 这个节点赋值给临时量,方便进行下一轮循环
self.length += 1 # 链表长度+1
pend.pnext = None # 末尾节点的pnxet指针为空,表示后面无数据
return self.phead # 返回生成的链表的头指针
def display(self):
cursor = self.phead.pnext # 定位到第一个节点
for i in range(self.length): # 根据长度判断是否到末尾
print(cursor.data, end=' ') # 输出节点数据
cursor = cursor.pnext # 指向下一节点
print()
def reverse(self):
prev = self.phead # 上一指针
curr = self.phead.pnext # 当前指针
next = self.phead # 下一指针
while curr:
next = curr.pnext # 先存储下一节点
curr.pnext = prev # 反转pnext指针指向
prev = curr # 反转完成后,上一节点后移
curr = next # 反转完成后,当前节点后移
self.phead.pnext = prev # 重置节点
if __name__ == '__main__':
link = Link() # 实例化链表Link
new = link.creat([1,2,3,4,5,6])
link.display()
link.reverse()
link.display()
# Output:
# 1 2 3 4 5 6
# 6 5 4 3 2 1 递归方法:
1)将列表分为两部分 - 第一节点和
其余的链表。
2)对链表的其余部分进行反向调用。
3)将休息链接到第一个。
4)修复头指针
// Recursive C++ program to reverse
// a linked list
#include <iostream>
using namespace std;
/* Link list node */
struct Node {
int data;
struct Node* next;
Node(int data)
{
this->data = data;
next = NULL;
}
};
struct LinkedList {
Node* head;
LinkedList()
{
head = NULL;
}
Node* reverse(Node* head)
{
if (head == NULL || head->next == NULL)
return head;
/* reverse the rest list and put
the first element at the end */
Node* rest = reverse(head->next);
head->next->next = head;
/* tricky step -- see the diagram */
head->next = NULL;
/* fix the head pointer */
return rest;
}
/* Function to print linked list */
void print()
{
struct Node* temp = head;
while (temp != NULL) {
cout << temp->data << " ";
temp = temp->next;
}
}
void push(int data)
{
Node* temp = new Node(data);
temp->next = head;
head = temp;
}
};
/* Driver program to test above function*/
int main()
{
/* Start with the empty list */
LinkedList ll;
ll.push(20);
ll.push(4);
ll.push(15);
ll.push(85);
cout << "Given linked list\n";
ll.print();
ll.head = ll.reverse(ll.head);
cout << "\nReversed Linked list \n";
ll.print();
return 0;
} 更简单和尾递归方法
# Node class
class Node:
# Constructor to initialize the node object
def __init__(self, data):
self.data = data
self.next = None
class LinkedList:
# Function to initialize head
def __init__(self):
self.head = None
def reverseUtil(self, curr, prev):
# If last node mark it head
if curr.next is None :
self.head = curr
# Update next to prev node
curr.next = prev
return
# Save curr.next node for recursive call
next = curr.next
# And update next
curr.next = prev
self.reverseUtil(next, curr)
# This function mainly calls reverseUtil()
# with previous as None
def reverse(self):
if self.head is None:
return
self.reverseUtil(self.head, None)
# Function to insert a new node at the beginning
def push(self, new_data):
new_node = Node(new_data)
new_node.next = self.head
self.head = new_node
# Utility function to print the linked LinkedList
def printList(self):
temp = self.head
while(temp):
print temp.data,
temp = temp.next
# Driver program
llist = LinkedList()
llist.push(8)
llist.push(7)
llist.push(6)
llist.push(5)
llist.push(4)
llist.push(3)
llist.push(2)
llist.push(1)
print "Given linked list"
llist.printList()
llist.reverse()
print "\nReverse linked list"
llist.printList() 
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