链表结点的数据域包括:序号、数值。
功能:
1、输入一个双向链表;
2、显示此双向链表所有结点;
3、对此双向链表分别按序号或数值进行排序;
4、删除双向链表中的结点。
/************************************************************************/
/*
文件名 doublelnk.h
作用 定义必要的结构体,并对双向链表的操作函数做声明
*/
/************************************************************************/
#ifndef DList_H
#define DList_H
typedef int Item;
typedef struct Node * PNode;
typedef PNode Position;
/*定义节点类型*/
typedef struct Node
{
Item id; /*编号*/
Item data; /*数据域*/
PNode previous; /*指向前驱*/
PNode next; /*指向后继*/
}Node;
/*定义链表类型*/
typedef struct
{
PNode head; /*指向头节点*/
PNode tail; /*指向尾节点*/
int size;
}DList;
enum enumSortType
{
ID,
DATA
};
/*分配值为i的节点,并返回节点地址*/
Position MakeNode(Item id, Item data);
/*释放p所指的节点*/
void FreeNode(PNode p);
/*构造一个空的双向链表*/
DList* InitList();
/*摧毁一个双向链表*/
void DestroyList(DList *plist);
/*将一个链表置为空表,释放原链表节点空间*/
void ClearList(DList *plist);
/*返回头节点地址*/
Position GetHead(DList *plist);
/*返回尾节点地址*/
Position GetTail(DList *plist);
/*返回链表大小*/
int GetSize(DList *plist);
/*返回p的直接后继位置*/
Position GetNext(Position p);
/*返回p的直接前驱位置*/
Position GetPrevious(Position p);
/*将pnode所指节点插入第一个节点之前*/
PNode InsFirst(DList *plist,PNode pnode);
/*将链表第一个节点删除并返回其地址*/
PNode DelFirst(DList *plist);
/*获得节点的数据项*/
Item GetItem(Position p);
/*设置节点的数据项*/
void SetItem(Position p,Item i);
/*删除链表中的尾节点并返回其地址,改变链表的尾指针指向新的尾节点*/
PNode Remove(DList *plist);
/*在链表中p位置之前插入新节点S*/
PNode InsBefore(DList *plist,Position p,PNode s);
/*在链表中p位置之后插入新节点s*/
PNode InsAfter(DList *plist,Position p,PNode s);
/*返回在链表中第i个节点的位置*/
PNode LocatePos(DList *plist,int i);
void ListTraverse(DList *plist,void (*visit)(Node));
/*对双向链表按照执行的排序方式进行排序*/
void SortDLnk(DList * plist, enumSortType sortType);
void SortDLnkbyID(DList * plist);
void SortDLnkbyData(DList * plist);
void swapnode(PNode anode, PNode bnode);
#endif
/************************************************************************/
/*
文件名 doublelnk.cpp
作用 对双向链表的操作函数进行具体实现
*/
/************************************************************************/
#include"doublelnk.h"
#include<malloc.h>
#include<stdlib.h>
/*分配值为i的节点,并返回节点地址*/
Position MakeNode(Item id, Item data)
{
PNode p = NULL;
p = (PNode)malloc(sizeof(Node));
if(p!=NULL)
{
p->id =id;
p->data = data;
p->previous = NULL;
p->next = NULL;
}
return p;
}
/*释放p所指的节点*/
void FreeNode(PNode p)
{
free(p);
}
/*构造一个空的双向链表*/
DList * InitList()
{
DList *plist = (DList *)malloc(sizeof(DList));
PNode head = MakeNode(0, 0);
if(plist!=NULL)
{
if(head!=NULL)
{
plist->head = head;
plist->tail = head;
plist->size = 0;
}
else
return NULL;
}
return plist;
}
/*摧毁一个双向链表*/
void DestroyList(DList *plist)
{
ClearList(plist);
free(GetHead(plist));
free(plist);
}
/*判断链表是否为空表*/
int IsEmpty(DList *plist)
{
if(GetSize(plist)==0&&GetTail(plist)==GetHead(plist))
return 1;
else
return 0;
}
/*将一个链表置为空表,释放原链表节点空间*/
void ClearList(DList *plist)
{
PNode temp,p;
p = GetTail(plist);
while(!IsEmpty(plist))
{
temp = GetPrevious(p);
FreeNode(p);
p = temp;
plist->tail = temp;
plist->size--;
}
}
/*返回头节点地址*/
Position GetHead(DList *plist)
{
return plist->head;
}
/*返回尾节点地址*/
Position GetTail(DList *plist)
{
return plist->tail;
}
/*返回链表大小*/
int GetSize(DList *plist)
{
return plist->size;
}
/*返回p的直接后继位置*/
Position GetNext(Position p)
{
return p->next;
}
/*返回p的直接前驱位置*/
Position GetPrevious(Position p)
{
return p->previous;
}
/*将pnode所指节点插入第一个节点之前*/
PNode InsFirst(DList *plist,PNode pnode)
{
Position head = GetHead(plist);
if(IsEmpty(plist))
plist->tail = pnode;
plist->size++;
pnode->next = head->next;
pnode->previous = head;
if(head->next!=NULL)
head->next->previous = pnode;
head->next = pnode;
return pnode;
}
/*将链表第一个节点删除,返回该节点的地址*/
PNode DelFirst(DList *plist)
{
Position head = GetHead(plist);
Position p=head->next;
if(p!=NULL)
{
if(p==GetTail(plist))
plist->tail = p->previous;
head->next = p->next;
head->next->previous = head;
plist->size--;
}
return p;
}
/*获得节点的数据项*/
Item GetItem(Position p)
{
return p->data;
}
/*设置节点的数据项*/
void SetItem(Position p,Item i)
{
p->data = i;
}
/*删除链表中的尾节点并返回地址,改变链表的尾指针指向新的尾节点*/
PNode Remove(DList *plist)
{
Position p=NULL;
if(IsEmpty(plist))
return NULL;
else
{
p = GetTail(plist);
p->previous->next = p->next;
plist->tail = p->previous;
plist->size--;
return p;
}
}
/*在链表中p位置之前插入新节点s*/
PNode InsBefore(DList *plist,Position p,PNode s)
{
s->previous = p->previous;
s->next = p;
p->previous->next = s;
p->previous = s;
plist->size++;
return s;
}
/*在链表中p位置之后插入新节点s*/
PNode InsAfter(DList *plist,Position p,PNode s)
{
s->next = p->next;
s->previous = p;
if(p->next != NULL)
p->next->previous = s;
p->next = s;
if(p = GetTail(plist))
plist->tail = s;
plist->size++;
return s;
}
/*返回在链表中第i个节点的位置*/
PNode LocatePos(DList *plist,int i)
{
int cnt = 0;
Position p = GetHead(plist);
if(i>GetSize(plist)||i<1)
return NULL;
while(++cnt<=i)
{
p=p->next;
}
return p;
}
/*依次对链表中每个元素调用函数visit()*/
void ListTraverse(DList *plist,void (*visit)(Node))
{
Position p = GetHead(plist);
if(IsEmpty(plist))
exit(0);
else
{
while(p->next!=NULL)
{
p = p->next;
visit(*p);
}
}
}
void SortDLnk(DList * plist, enumSortType sortType)
{
switch(sortType)
{
case ID:
SortDLnkbyID(plist);
break;
case DATA:
SortDLnkbyData(plist);
break;
}
}
void SortDLnkbyID(DList * plist)
{
PNode head = plist->head;
Node tmpnode;
Position currnode = head;
Position bianlinode;
while ((currnode=currnode->next) != NULL)
{
bianlinode =currnode;
while((bianlinode=bianlinode->next) != NULL)
{
if (currnode->id > bianlinode->id)
{
swapnode(currnode, bianlinode);
}
}
}
}
void SortDLnkbyData(DList * plist)
{
PNode head = plist->head;
Node tmpnode;
Position currnode = head;
Position bianlinode;
while ((currnode=currnode->next) != NULL)
{
bianlinode =currnode;
while((bianlinode=bianlinode->next) != NULL)
{
if (currnode->data > bianlinode->data)
{
swapnode(currnode, bianlinode);
}
}
}
}
void swapnode(PNode anode, PNode bnode)
{// 这里面要特别注意防止前驱节点是头结点和后驱节点是Null的情况
Node tmpnode;
tmpnode.id = anode->id;
tmpnode.data = anode->data;
anode->id = bnode->id;
anode->data = bnode->data;
bnode->id = tmpnode.id;
bnode->data = tmpnode.data;
}
/************************************************************************/
/*
文件名 program.cpp
作用 对双向链表的操作函数进行测试
*/
/************************************************************************/
#include"doublelnk.h"
#include<stdio.h>
void print(Node node)
{
printf("数据项: id=%d, data=%d \n",node.id, node.data);
}
int main()
{
DList *plist = NULL;
PNode p = NULL;
plist = InitList();
p = InsFirst(plist,MakeNode(12, 23));
InsBefore(plist,p,MakeNode(2, 54));
InsAfter(plist,p,MakeNode(3, 34));
printf("p前驱位置的值为%d\n",GetItem(GetPrevious(p)));
printf("p位置的值为%d\n",GetItem(p));
printf("p后继位置的值为%d\n",GetItem(GetNext(p)));
printf("遍历输出各节点数据项:\n");
ListTraverse(plist,print);
printf("按照ID排序后遍历输出:\n");
SortDLnk(plist, ID);
ListTraverse(plist,print);
printf("按照Data排序后遍历输出:\n");
SortDLnk(plist, DATA);
ListTraverse(plist,print);
printf("除了头节点该链表共有%d个节点\n",GetSize(plist));
FreeNode(DelFirst(plist));
printf("删除第一个节点后重新遍历输出为:\n");
ListTraverse(plist,print);
printf("除了头节点该链表共有%d个节点\n",GetSize(plist));
DestroyList(plist);
printf("链表已被销毁\n");
return 0;
}
/*
文件名 doublelnk.h
作用 定义必要的结构体,并对双向链表的操作函数做声明
*/
/************************************************************************/
#ifndef DList_H
#define DList_H
typedef int Item;
typedef struct Node * PNode;
typedef PNode Position;
/*定义节点类型*/
typedef struct Node
{
Item id; /*编号*/
Item data; /*数据域*/
PNode previous; /*指向前驱*/
PNode next; /*指向后继*/
}Node;
/*定义链表类型*/
typedef struct
{
PNode head; /*指向头节点*/
PNode tail; /*指向尾节点*/
int size;
}DList;
enum enumSortType
{
ID,
DATA
};
/*分配值为i的节点,并返回节点地址*/
Position MakeNode(Item id, Item data);
/*释放p所指的节点*/
void FreeNode(PNode p);
/*构造一个空的双向链表*/
DList* InitList();
/*摧毁一个双向链表*/
void DestroyList(DList *plist);
/*将一个链表置为空表,释放原链表节点空间*/
void ClearList(DList *plist);
/*返回头节点地址*/
Position GetHead(DList *plist);
/*返回尾节点地址*/
Position GetTail(DList *plist);
/*返回链表大小*/
int GetSize(DList *plist);
/*返回p的直接后继位置*/
Position GetNext(Position p);
/*返回p的直接前驱位置*/
Position GetPrevious(Position p);
/*将pnode所指节点插入第一个节点之前*/
PNode InsFirst(DList *plist,PNode pnode);
/*将链表第一个节点删除并返回其地址*/
PNode DelFirst(DList *plist);
/*获得节点的数据项*/
Item GetItem(Position p);
/*设置节点的数据项*/
void SetItem(Position p,Item i);
/*删除链表中的尾节点并返回其地址,改变链表的尾指针指向新的尾节点*/
PNode Remove(DList *plist);
/*在链表中p位置之前插入新节点S*/
PNode InsBefore(DList *plist,Position p,PNode s);
/*在链表中p位置之后插入新节点s*/
PNode InsAfter(DList *plist,Position p,PNode s);
/*返回在链表中第i个节点的位置*/
PNode LocatePos(DList *plist,int i);
void ListTraverse(DList *plist,void (*visit)(Node));
/*对双向链表按照执行的排序方式进行排序*/
void SortDLnk(DList * plist, enumSortType sortType);
void SortDLnkbyID(DList * plist);
void SortDLnkbyData(DList * plist);
void swapnode(PNode anode, PNode bnode);
#endif
/************************************************************************/
/*
文件名 doublelnk.cpp
作用 对双向链表的操作函数进行具体实现
*/
/************************************************************************/
#include"doublelnk.h"
#include<malloc.h>
#include<stdlib.h>
/*分配值为i的节点,并返回节点地址*/
Position MakeNode(Item id, Item data)
{
PNode p = NULL;
p = (PNode)malloc(sizeof(Node));
if(p!=NULL)
{
p->id =id;
p->data = data;
p->previous = NULL;
p->next = NULL;
}
return p;
}
/*释放p所指的节点*/
void FreeNode(PNode p)
{
free(p);
}
/*构造一个空的双向链表*/
DList * InitList()
{
DList *plist = (DList *)malloc(sizeof(DList));
PNode head = MakeNode(0, 0);
if(plist!=NULL)
{
if(head!=NULL)
{
plist->head = head;
plist->tail = head;
plist->size = 0;
}
else
return NULL;
}
return plist;
}
/*摧毁一个双向链表*/
void DestroyList(DList *plist)
{
ClearList(plist);
free(GetHead(plist));
free(plist);
}
/*判断链表是否为空表*/
int IsEmpty(DList *plist)
{
if(GetSize(plist)==0&&GetTail(plist)==GetHead(plist))
return 1;
else
return 0;
}
/*将一个链表置为空表,释放原链表节点空间*/
void ClearList(DList *plist)
{
PNode temp,p;
p = GetTail(plist);
while(!IsEmpty(plist))
{
temp = GetPrevious(p);
FreeNode(p);
p = temp;
plist->tail = temp;
plist->size--;
}
}
/*返回头节点地址*/
Position GetHead(DList *plist)
{
return plist->head;
}
/*返回尾节点地址*/
Position GetTail(DList *plist)
{
return plist->tail;
}
/*返回链表大小*/
int GetSize(DList *plist)
{
return plist->size;
}
/*返回p的直接后继位置*/
Position GetNext(Position p)
{
return p->next;
}
/*返回p的直接前驱位置*/
Position GetPrevious(Position p)
{
return p->previous;
}
/*将pnode所指节点插入第一个节点之前*/
PNode InsFirst(DList *plist,PNode pnode)
{
Position head = GetHead(plist);
if(IsEmpty(plist))
plist->tail = pnode;
plist->size++;
pnode->next = head->next;
pnode->previous = head;
if(head->next!=NULL)
head->next->previous = pnode;
head->next = pnode;
return pnode;
}
/*将链表第一个节点删除,返回该节点的地址*/
PNode DelFirst(DList *plist)
{
Position head = GetHead(plist);
Position p=head->next;
if(p!=NULL)
{
if(p==GetTail(plist))
plist->tail = p->previous;
head->next = p->next;
head->next->previous = head;
plist->size--;
}
return p;
}
/*获得节点的数据项*/
Item GetItem(Position p)
{
return p->data;
}
/*设置节点的数据项*/
void SetItem(Position p,Item i)
{
p->data = i;
}
/*删除链表中的尾节点并返回地址,改变链表的尾指针指向新的尾节点*/
PNode Remove(DList *plist)
{
Position p=NULL;
if(IsEmpty(plist))
return NULL;
else
{
p = GetTail(plist);
p->previous->next = p->next;
plist->tail = p->previous;
plist->size--;
return p;
}
}
/*在链表中p位置之前插入新节点s*/
PNode InsBefore(DList *plist,Position p,PNode s)
{
s->previous = p->previous;
s->next = p;
p->previous->next = s;
p->previous = s;
plist->size++;
return s;
}
/*在链表中p位置之后插入新节点s*/
PNode InsAfter(DList *plist,Position p,PNode s)
{
s->next = p->next;
s->previous = p;
if(p->next != NULL)
p->next->previous = s;
p->next = s;
if(p = GetTail(plist))
plist->tail = s;
plist->size++;
return s;
}
/*返回在链表中第i个节点的位置*/
PNode LocatePos(DList *plist,int i)
{
int cnt = 0;
Position p = GetHead(plist);
if(i>GetSize(plist)||i<1)
return NULL;
while(++cnt<=i)
{
p=p->next;
}
return p;
}
/*依次对链表中每个元素调用函数visit()*/
void ListTraverse(DList *plist,void (*visit)(Node))
{
Position p = GetHead(plist);
if(IsEmpty(plist))
exit(0);
else
{
while(p->next!=NULL)
{
p = p->next;
visit(*p);
}
}
}
void SortDLnk(DList * plist, enumSortType sortType)
{
switch(sortType)
{
case ID:
SortDLnkbyID(plist);
break;
case DATA:
SortDLnkbyData(plist);
break;
}
}
void SortDLnkbyID(DList * plist)
{
PNode head = plist->head;
Node tmpnode;
Position currnode = head;
Position bianlinode;
while ((currnode=currnode->next) != NULL)
{
bianlinode =currnode;
while((bianlinode=bianlinode->next) != NULL)
{
if (currnode->id > bianlinode->id)
{
swapnode(currnode, bianlinode);
}
}
}
}
void SortDLnkbyData(DList * plist)
{
PNode head = plist->head;
Node tmpnode;
Position currnode = head;
Position bianlinode;
while ((currnode=currnode->next) != NULL)
{
bianlinode =currnode;
while((bianlinode=bianlinode->next) != NULL)
{
if (currnode->data > bianlinode->data)
{
swapnode(currnode, bianlinode);
}
}
}
}
void swapnode(PNode anode, PNode bnode)
{// 这里面要特别注意防止前驱节点是头结点和后驱节点是Null的情况
Node tmpnode;
tmpnode.id = anode->id;
tmpnode.data = anode->data;
anode->id = bnode->id;
anode->data = bnode->data;
bnode->id = tmpnode.id;
bnode->data = tmpnode.data;
}
/************************************************************************/
/*
文件名 program.cpp
作用 对双向链表的操作函数进行测试
*/
/************************************************************************/
#include"doublelnk.h"
#include<stdio.h>
void print(Node node)
{
printf("数据项: id=%d, data=%d \n",node.id, node.data);
}
int main()
{
DList *plist = NULL;
PNode p = NULL;
plist = InitList();
p = InsFirst(plist,MakeNode(12, 23));
InsBefore(plist,p,MakeNode(2, 54));
InsAfter(plist,p,MakeNode(3, 34));
printf("p前驱位置的值为%d\n",GetItem(GetPrevious(p)));
printf("p位置的值为%d\n",GetItem(p));
printf("p后继位置的值为%d\n",GetItem(GetNext(p)));
printf("遍历输出各节点数据项:\n");
ListTraverse(plist,print);
printf("按照ID排序后遍历输出:\n");
SortDLnk(plist, ID);
ListTraverse(plist,print);
printf("按照Data排序后遍历输出:\n");
SortDLnk(plist, DATA);
ListTraverse(plist,print);
printf("除了头节点该链表共有%d个节点\n",GetSize(plist));
FreeNode(DelFirst(plist));
printf("删除第一个节点后重新遍历输出为:\n");
ListTraverse(plist,print);
printf("除了头节点该链表共有%d个节点\n",GetSize(plist));
DestroyList(plist);
printf("链表已被销毁\n");
return 0;
}
程序总共分三部分, 分别是双向链表的头文件、源文件和测试程序
建立工程后,分别建立相应的文件并添加相应代码应该就可以
下面的图片是我的运行效果(声明:程序中很多代码参考了以为前辈的代码http://blog.csdn.net/hopeyouknow/article/details/6716177)
温馨提示:答案为网友推荐,仅供参考
第1个回答 2013-09-10
/*
请输入链表结点数 : 5
序号 : 60357
数据 : 8693
序号 : 63415
数据 : 3487
序号 : 38419
数据 : 2685
序号 : 65478
数据 : 6303
序号 : 87657
数据 : 3628
60357 : 8693
63415 : 3487
38419 : 2685
65478 : 6303
87657 : 3628
87657 : 3628
65478 : 6303
38419 : 2685
63415 : 3487
60357 : 8693
排序后 :
87657 : 3628
65478 : 6303
63415 : 3487
60357 : 8693
38419 : 2685
38419 : 2685
60357 : 8693
63415 : 3487
65478 : 6303
87657 : 3628
请按任意键继续. . .
*/
#include <stdio.h>#include <stdlib.h>
typedef struct node {
unsigned sn;
int data;
node *prior,*next;
}*DLinkList;
DLinkList CreateList(int n) { // 创建双向环形链表
DLinkList p,q,head;
head = p = (DLinkList)malloc(sizeof(node));
head->sn = 0;
head->data = 0;
for(int i = 0;i < n;i++) {
p->next = (DLinkList)malloc(sizeof(node));
if(p->next== NULL) {
printf("申请动态内存失败。\n");
break;
}
printf("序号 : ");
scanf("%u",&p->next->sn);
printf("数据 : ");
scanf("%d",&p->next->data);
p->next->next = head; // 始终保持环形连接
p->next->prior = p; // 新结点的反向链接
p = p->next; // 为连接新节点做准备
}
head->prior = p;// 头结点的prior指向最后的结点,是实现双向环形链表的最后一步
return head;
}
void Print(DLinkList head) { // 顺向输出链表数据
DLinkList p;
p = head->next;
while(p != head) {
printf("%u : %d\n",p->sn,p->data);
p = p->next;
}
printf("\n");
}
void SortSN(DLinkList head) { // 按序号升排序
DLinkList p = head,q,pt;
q = p->next;
while(p->next != head) {
while(q->next != head) {
if(q->next->sn > p->next->sn) {
pt = p->next;
p->next = q->next;
q->next = q->next->next;
q->next->prior = q;
p->next->next = pt;
pt->prior = p->next;
pt->prior->prior = p;
}
else q = q->next;
}
p = p->next;
}
}
void DCprint(DLinkList head) { // 反向输出链表数据
DLinkList p = head->prior;
while(p != head) {
printf("%u : %d\n",p->sn,p->data);
p = p->prior;
}
printf("\n");
}
void Deleteheap(DLinkList head) { // 释放占用的堆空间
DLinkList p,q;
p = head;
q = p->next;
while(q != head) {
p = q;
q = p->next;
free(p);
}
free(head);
}
int main () {
DLinkList head;
int n;
printf("请输入链表结点数 : ");
scanf("%d",&n);
head = CreateList(n);
Print(head);
DCprint(head);
SortSN(head);
printf("排序后 :\n");
Print(head);
DCprint(head);
Deleteheap(head);
return 0;
}追问
这个有错诶。。。
追答有什么样的错误呢?请具体点。
建议仔细观察代码上面数据的输入过程。
我是渣渣。。链表没学过。。所以求助大神。。要写报告的。。输完之后没法运行。。
追答请输入链表结点数 :
序号 :
数据 :
............
余下类推,直到所有结点数据输入完毕,此后代码输出结果。
建议把链表排序部分仔细看看,其次是创建链表函数也有一定难度。
第2个回答 2013-09-09
C语言
程序,
严格
程序,
严格
