简介:
在用C/C++开发系统中,我们知道用数组或者单链表来开发,如果是数据比较大的话,性能很不好,效率也不高。因此常常需要考虑系统的实用性,常常采用双向链表来开发。
示例:
1.数据
typedef struct node{
int data; // 数据
struct node *last; // 前一个数据节点
struct node *next; // 后一个数据节点
}Node;
typedef struct {
Node *head;
Node *tail;
}LinkList;
2.创建链表
LinkList *createList()
{
LinkList *list = malloc(sizeof(LinkList));
list -> head = NULL;
lsit ->tail = NULL;
return list;
}
3.插入
3.1头插法
void addNodeBeHead(LinkList *list,int num)
{
Node *p = malloc(sizeof(Node));
p -> data = num;
p -> last = NULL;
P -> next = NULL; if(list - > head != NULL)
{
// 1.指向新的节点
// 2.新节点的next指向原来的节点
// 3.新节点变成头节点
list ->head->last = p;
node ->next = list ->head;
list -> head = p;
}
else{
list -> head = P;
list -> tail = p;
}
}
3.2尾插法
void addNodeAfterTail(LinkList *list,int num)
{
Node *p = malloc(sizeof(Node));
p -> data = num;
p -> last = NULL;
P -> next = NULL; if(list - > head != NULL)
{
// 1.指向新的节点
// 2.新节点的last指向原来的节点
// 3.新节点变成尾节点
list ->tail->next = p;
node ->last = list -> tail;
list -> tail = p;
}
else{
list -> head = P;
list -> tail = p;
}
}
4.打印链表
void printList(LinkList *list)
{
Node *p = list -> head;
if(p == NULL)
{
printf("当前为空链表");
}else
{
while(p != NULL)
{
printf("%s",p-> data);
p = p-> next;
} }
}
5.把链表的头结点删除,并返回头结点的数值
int popHeadNode(LinkList *list)
{
if(list -> head == NULL)
{
printf("the list is empty!");
return -;
}
else if (list -> head == list -> tail)
{
Node *node = list - > head;
int value = node ->data;
list -> head = NULL;
list -> tail = NULL;
free(node);
return value;
}
else
{
Node *node = list -> head;
int value = node -> data;
// 1.head指向下一个节点
// 2.并将下一个的last置空
list -> head = list -> head ->next;
list -> head -> last = NULL;
free(node);
return value; } }
6.统计节点总数
int countNodes(LinkList *list)
{
int count = ;
Node *p = list -> head;
if(list -> head != NULL)
{
while(p != NULL)
{
count++;
p = p -> next;
}
return count; }
return ;
}
7.链表转成数组(注意:数组一定要malloc初始化,否则无法返回)
int *listToArray(LinkList *list)
{
if(list -> head == NULL)
{
return NULL;
} int i = ;
int n = countNodes(list);
int *arr = malloc(sizeof(int) * n);
Node *p = list -> head;
while(p != NULL)
{
arr[i] = p -> data;
i++;
p = p -> next;
}
return arr;
}
8.把链表所有的节点头尾对调
1->2->3->NULL 对调后 NULL->3->2->1
void reverseList(LinkList *list)
{
if(list -> head != NULL)
{
int *arr = listToArray(list);
int i = countNodes(list) - ;
Node *node = list -> head;
while(p != NULL)
{
P -> data = arr[i];
i --;
p = p -> next;
}
}
}
第二种做法:(把原来的链表重新连接)
void reverseList(LinkList *list)
{ Node *prev = NULL;
Node *p = list -> head;
Node *temp;
list -> tail = p; // 尾部变头部
while(p != NULL)
{
temp = p -> next;
p -> next = prev;
prev = p;
p = temp;
}
list ->head = prev;
}