题目:
1.编写函数,采用链式存储实现栈的初始化、入栈、出栈操作
2.编写函数,采用顺序存储实现栈的初始化、入栈、出栈操作
3.编写函数,采用链式存储实现队列的初始化、入队、出队操作
4.编写函数,采用顺序存储实现队列的初始化、入队、出队操作
5.编写一个主函数,在主函数中设计一个简单的菜单,分别调试上述算法
题目分析:
1.顺序栈的类型定义
#define MAX 100 //栈的最大值 typedef struct { ElemType *base; int top; } SqStack;
2.链栈的类型定义
typedef struct SqNode { SElemType data; SqNode *Link; } *Sqptr; typedef struct { Sqptr top; //栈项指针 }
3.顺序队列的类型定义
#define MAX 100 //队列的最大长度 typedef struct { ElemType *base; int front,rear; } SqQueue;
4.单链队列的类型定义
typedef struct QNode { QElemType data; struct QNode *next; } *QueuePtr; typedef struct { QueuePtr frout; //队头指针 QueuePtr rear; //队尾指针 }
下面是具体的程序:
#define _CRT_SECURE_NO_WARNINGS 1 #include <stdio.h> #include <stdlib.h> #define OVERFLOW -2 #define ERROR 0 #define OK 1 #define MAX 100 //栈的最大值 typedef int SElemType; typedef int QElemType; typedef struct { SElemType *base; SElemType *top; }SqStack; SqStack InitStacka( ) //顺序存储实现栈的初始化 { SqStack S; S.base = ( SElemType * )malloc( MAX *sizeof( SElemType )); if( !S.base ) exit( OVERFLOW ); S.top = S.base; return(S); } void Pusha(SqStack &S, int x) //顺序存储实现栈的入栈操作 { if(S.top - S.base >= MAX) { exit(OVERFLOW); } *S.top++ = x; } void Popa(SqStack &S) //顺序存储实现栈的出栈操作 { SElemType *p; int x; if(S.top == S.base) { return ; } else { p = S.top; x = * --S.top; printf("\t删除的栈顶元素是%d\n\t出栈操作完成后的栈为:\n", x); } } void printa(SqStack S) //输出 { SElemType *p; p = S.base; printf("\t"); while(p != S.top) { printf("%d ", *(p++)); } printf("\n"); } typedef struct SqNode { SElemType data; SqNode *Link; }*Sqptr,NODE; typedef struct { Sqptr top; }Stack; Stack InitStackb() //链式存储实现栈的初始化 { Stack S; S.top = ( Sqptr )malloc( sizeof( NODE ) ); if( !S.top ) { exit (OVERFLOW); } S.top -> Link = NULL; return(S); } void Pushb(Stack &S, int x) //链式存储实现栈的入栈操作 { Sqptr p; p = ( Sqptr )malloc( sizeof( NODE ) ); if( !p ) { return ; } p -> data = x; p -> Link = S.top -> Link; S.top -> Link = p; } void Popb(Stack &S) //链式存储实现栈的出栈操作 { int x; Sqptr p; if(S.top -> Link == NULL) { return ; } else { p = S.top -> Link; x = p -> data; S.top -> Link = p -> Link; printf("\t删除的栈顶元素是%d\n", x); free(p); } } typedef struct QNode { QElemType data; struct QNode *next; }*QueuePtr,QNode; typedef struct { QueuePtr front; QueuePtr rear; }LinkQueue; LinkQueue InitQueue() //链式存储实现队列的初始化 { LinkQueue Q; Q.front = Q.rear = ( QueuePtr )malloc( sizeof( QNode ) ); if( !Q.front ) { exit (OVERFLOW); } Q.front -> next = NULL; return(Q); } void EnQueue(LinkQueue &Q, QElemType x) //链式存储实现队列的入队操作 { QueuePtr p; p = ( QueuePtr )malloc( sizeof( QNode ) ); if( !p ) { exit(OVERFLOW); } p -> data = x; p -> next = NULL; Q.rear -> next = p; Q.rear = p; } void DeQueue(LinkQueue &Q) //链式存储实现队列的出队操作 { int x; if(Q.front == Q.rear) { return ; } QueuePtr p; p = Q.front -> next; x = p -> data; printf("\t删除的队头元素是%d\n", x); Q.front -> next = p -> next; if(Q.rear == p) { Q.rear = Q.front; } free(p); return; } typedef struct { SElemType *base; int front, rear; }SqQueue; SqQueue InitQueueb() //顺序存储实现队列的初始化 { SqQueue S; S.base = ( SElemType * )malloc( MAX *sizeof( SElemType )); if( !S.base ) { exit(OVERFLOW); } S.front = S.rear = 0; return(S); } void EnQueueb(SqQueue &S, int x) //顺序存储实现队列的入队操作 { if((S.rear+1) % MAX == S.front) { return ; } S.base[S.rear] = x; S.rear = (S.rear+1) % MAX; } void DeQueueb(SqQueue &S) //顺序存储实现队列的出队操作 { int x; if(S.front == S.rear) { return ; } x = S.base[S.front]; S.front = (S.front+1) % MAX; printf("\t删除的队头元素是:%d\n", x); } int main() { int choice; int n, x; printf("\t1.使用链式存储实现栈的初始化、入栈、出栈操作\n"); printf("\t2.使用顺序存储实现栈的初始化、入栈、出栈操作\n"); printf("\t3.使用链式存储实现队列的初始化、入栈、出栈操作\n"); printf("\t4.使用顺序存储实现队列的初始化、入栈、出栈操作\n"); printf("\t请选择:"); scanf("%d", &choice); switch(choice) { case 1: Stack Sa; printf("\t1.链式存储实现栈的初始化\n"); printf("\t2.链式存储实现栈的入栈操作\n"); printf("\t3.链式存储实现栈的出栈操作\n"); while(1) { printf("\t请选择:"); scanf("%d", &n); switch(n) { case 1: Sa = InitStackb(); printf("\t链式存储栈的初始化完成!\n"); break; case 2: printf("\t以‘0‘结束\n"); printf("\t"); scanf("%d", &x); while(x) { Pushb(Sa, x); scanf("%d", &x); } printf("\t链式存储栈的入栈操作完成!\n"); break; case 3: Popb(Sa); break; } } break; case 2: SqStack S; printf("\t1.顺序存储实现栈的初始化\n"); printf("\t2.顺序存储实现栈的入栈操作\n"); printf("\t3.顺序存储实现栈的出栈操作\n"); while(1) { printf("\t请选择:"); scanf("%d", &n); switch(n) { case 1: S = InitStacka(); printf("\t顺序存储栈的初始化完成!\n"); break; case 2: printf("\t以‘0‘结束!\n"); printf("\t"); scanf("%d", &x); while(x) { Pusha(S, x); scanf("%d", &x); } printf("\t顺序存储栈的入栈操作完成!\n"); printa(S); break; case 3: Popa(S); printa(S); break; } } break; case 3: LinkQueue Q; printf("\t1.链式存储实现队的初始化\n"); printf("\t2.链式存储实现队的入栈操作\n"); printf("\t3.链式存储实现队的出栈操作\n"); while(1) { printf("\t请选择:"); scanf("%d", &n); switch(n) { case 1: Q = InitQueue(); printf("\t链式存储队的初始化完成!\n"); break; case 2: printf("\t以‘0‘结束\n"); printf("\t"); scanf("%d", &x); while(x) { EnQueue(Q, x); scanf("%d", &x); } printf("\t链式存储队的入栈操作完成!\n"); break; case 3: DeQueue(Q); break; } } break; case 4: SqQueue Sv; printf("\t1.顺序存储实现队的初始化\n"); printf("\t2.顺序存储实现队的入栈操作\n"); printf("\t3.顺序存储实现队的出栈操作\n"); while(1) { printf("\t请选择:"); scanf("%d", &n); switch(n) { case 1: Sv = InitQueueb(); printf("\t链式存储栈的初始化完成!\n"); break; case 2: printf("\t以‘0‘结束\n"); printf("\t"); scanf("%d", &x); while(x) { EnQueueb(Sv, x); scanf("%d", &x); } printf("\t链式存储栈的入栈操作完成!\n"); break; case 3: DeQueueb(Sv); break; } } break; } system("pause"); return 0; }
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原文地址:http://10740590.blog.51cto.com/10730590/1717161