编译器:vs2013
内容:
#include "stdafx.h"
#include<stdio.h>
#include<malloc.h>
#include<stdlib.h>
#define LINK_INIT_SIZE 100
#define LISTINCREAMENT 10
#define ElemType int
#define OVERFLOW -2
#define OK 1
#define ERROR 0
typedef int status;
//定义顺序表,并定义一个新类型Sqlist
typedef struct Sqlist{
ElemType *elem;
int listsize;
int length;
}Sqlist;
//函数声明
status InitList(Sqlist &L);
status CreatList(Sqlist &L);
status PrintfList1(Sqlist L);
status PrintfList2(Sqlist L);
status DeleteList(Sqlist &L, int i);
status ListEmpty(Sqlist L);
status ListLength(Sqlist L);
status InsertList(Sqlist &L, int i, ElemType e);
status DestroyList(Sqlist &L);
int main()
{
int i,n,j ;
ElemType e;
Sqlist L1;
InitList(L1); //顺序表初始化操作
ListEmpty(L1); //顺序表判空
CreatList(L1); //顺序表赋值操作
printf("正序输出为:\n");
PrintfList1(L1); //顺序表正序输出操作
printf("\n");
printf("逆序输出为:\n");
PrintfList2(L1); //顺序表逆序输出操作
printf("\n");
ListLength(L1); //求顺序表表长
printf("请输入插入的位置i=");
scanf_s("%d", &i);
e=rand() % 100 + 1;
InsertList(L1, i, e); //顺序表插入操作
PrintfList1(L1);
printf("\n");
printf("请输入删除的位置j=");
scanf_s("%d", &j);
DeleteList(L1,j); //顺序表删除操作
PrintfList1(L1);
DestroyList(L1); //顺序表销毁操作
PrintfList1(L1);
return 0;
}
//构建空的顺序表
status InitList(Sqlist &L)
{
L.elem = (ElemType*)malloc(LINK_INIT_SIZE*sizeof(ElemType));
if (!L.elem)
exit (OVERFLOW);
L.length = 0; //将新的顺序表长度定为0
L.listsize = LINK_INIT_SIZE; //初始化顺序表大小为LINK_INIT_SIZE
return OK;
}
//顺序表插入操作
status InsertList(Sqlist &L, int i, ElemType e)
{
ElemType *newbase, *q,*p;
if (i<1 || i>L.length + 1)
{
printf("未插入成功!!!\n");
return ERROR;
}
if (L.length >= L.listsize)
{
newbase = (ElemType*)realloc(L.elem, (L.listsize + LISTINCREAMENT)*sizeof(ElemType));
if (!newbase)
exit(OVERFLOW);
L.elem = newbase;
L.listsize += LISTINCREAMENT;
} //检验线性表是否满了,满了则重新增加存储空间
q = &(L.elem[i - 1]);
for (p = &(L.elem[L.length - 1]); p >= q; p--)
*(p + 1) = *p;
*q = e;
L.length++;
return OK;
}
//顺序表输入操作
status CreatList(Sqlist &L)
{
ElemType i=0,e;
for (i = 0; i < 10; i++) //顺序表赋值操作
{
L.elem[i] = rand() % 100 + 1;
L.length++;
}
return 0;
}
//顺序表正序输出操作
status PrintfList1(Sqlist L)
{
int i;
if (L.length == 0)
{
printf("该线性表为空!\n");
return 0;
}
for (i = 0; i < L.length; i++)
printf("L.elem[%d]=%d\n", i + 1, *(L.elem + i));
}
//顺序表删除操作
status DeleteList(Sqlist &L, int i)
{
int *p, *q,e;
if (i<1 || i>L.length + 1)
{
printf("不存在此删除位置!!!\n");
return ERROR;
} //检验输入的i是否在线性表所存在的范围内
p = &(L.elem[i - 1]);
e = *p;
q = L.elem + L.length - 1;
for (p++; p <= q; ++p)
*(p - 1) = *p;
L.length--;
printf("删除的元素为%d\n", e);
return 0;
}
//顺序表逆序输出操作
status PrintfList2(Sqlist L)
{
int i;
if (L.length == 0)
{
printf("该线性表为空!\n");
return 0;
}
for (i = L.length-1; i >=0; i--)
printf("L.elem[%d]=%d\n", i + 1, *(L.elem + i));
}
//求顺序表是否为空
status ListEmpty(Sqlist L)
{
if (L.length == 0)
printf("The List is Empty!!!\n");
else
printf("The List is not Empty!!!\n");
return 0;
}
//求顺序表长度
status ListLength(Sqlist L)
{
printf("线性表的长度为%d\n", L.length);
return OK;
}
status DestroyList(Sqlist &L)
{
free(&L.elem[0]);
L.length=0;
return 0;
}
实验结果
链表操作
#include<malloc.h>
#include<stdlib.h>
typedef int Elemtype;
typedef int Status;
typedef struct LNode{
Elemtype data;
struct LNode *next;
}LNode,*LinkList;
//函数声明
Status CreatList1(LinkList &L, int n); //头插法构建
Status PrintfList(LinkList L); //链表输出
Status CreatList2(LinkList &L, int n); //尾插法构建
Status InverseList(LinkList &L); //逆置链表
int main()
{
LinkList L;
int n,i,e;
printf("请输入建立的线性表结点个数n=");
scanf_s("%d", &n);
CreatList1(L, n);
PrintfList(L); //头插法建立链表
printf("请输入建立的线性表结点个数n=");
scanf_s("%d", &n);
CreatList2(L, n);
PrintfList(L); //尾插法建立链表
InverseList(L); //逆置链表
PrintfList(L);
}
//头插法创建链表
Status CreatList1(LinkList &L,int n)
{
int i;
LinkList p;
L = (LinkList)malloc(sizeof(LNode));
L->next = NULL;
for (i = n; i > 0; i--)
{
p = (LinkList)malloc(sizeof(LNode));
p->data = rand() % 100 + 1;
printf("头插法的第%d个数据:%d\n", i,p->data);
p->next = L->next;
L->next = p;
}
return 0;
}
//尾插法构建线性表
Status CreatList2(LinkList &L, int n)
{
LinkList p,q;
int i;
L = (LinkList)malloc(sizeof(LNode));
L->next = NULL;
for (q=L,i = 0; i < n;i++)
{
p = (LinkList)malloc(sizeof(LNode));
p->data = rand() % 100 + 1;
printf("尾插法的第%d个数据:%d", i + 1,p->data);
q->next = p;
q = p;
printf("\n");
}
q->next = NULL;
return 0;
}
//输出链表
Status PrintfList(LinkList L)
{
LNode *p;
if (L->next == NULL)
printf("The List is Empty!!!\n");
for (p = L->next; p != NULL; p = p->next)
printf("%3d ", p->data);
printf("\n");
return 0;
}
//逆置链表
Status InverseList(LinkList &L)
{
LinkList p,q;
for (p = L->next; p->next != NULL; p = p->next);
for (q = L->next; q != p; q = L->next)
{
L->next = q->next;
q->next = p->next;
p->next = q;
}
return 0;
}
实验结果