• C/C++ 结构体与指针笔记


    结构体的定义与使用:

    #include <stdio.h>
    #include <stdlib.h>
    
    struct Student
    {
    	int num;
    	char name[30];
    	char age;
    };
    
    
    int main(int argc, char* argv[])
    {
    	struct Student stu = { 1001, "lyshark", 22 };
    
    	printf("普通引用: %d --> %s \n", stu.num, stu.name);
    
    	struct Student *ptr;   // 定义结构指针
    	ptr = &stu;            // 指针的赋值
    
    	printf("指针引用: %d --> %s \n", ptr->num, ptr->name);
    
    
    	system("pause");
    	return 0;
    }
    

    动态分配结构体成员:

    #include <stdio.h>
    #include <stdlib.h>
    
    int main(int argc, char* argv[])
    {
    	struct Student
    	{
    		int num;
    		char name[30];
    		char age;
    	};
    
    	struct Student *stu = malloc(sizeof(struct Student));
    	stu->num = 1001;
    	stu->age = 24;
    	strcpy(stu->name, "lyshark");
    	printf("姓名: %s 年龄: %d \n", stu->name, stu->age);
    
    	// ----------------------------------------------------------
    	struct Person
    	{
    		char *name;
    		int age;
    	}person;
    
    	struct Person *ptr = &person;
    
    	ptr->name = (char *)malloc(sizeof(char)* 20);
    	strcpy(ptr->name, "lyshark");
    	ptr->age = 23;
    
    	printf("姓名: %s 年龄: %d \n", ptr->name, ptr->age);
    	free(ptr->name);
    
    	system("pause");
    	return 0;
    }
    

    结构体变量数组:

    #include <stdio.h>
    #include <stdlib.h>
    
    typedef struct Person
    {
    	int uid;
    	char name[64];
    }Person;
    
    
    
    void Print(struct Person *p,int len)
    {
    	for (int x = 0; x < len; x++)
    	{
    		printf("%d \n", p[x].uid);
    	}
    }
    
    int main(int argc, char* argv[])
    {
    	// 栈上分配结构体(聚合初始化)
    	struct Person p1[] = {
    		{ 1, "aaa" },
    		{ 2, "bbb" },
    		{ 3, "ccc" },
    	};
    
    	int len = sizeof(p1) / sizeof(struct Person);
    	Print(p1, len);
    
    	// 在堆上分配
    	struct Person *p2 = malloc(sizeof(struct Person) * 5);
    
    	for (int x = 0; x < 5; x++)
    	{
    		p2[x].uid = x;
    		strcpy(p2[x].name, "aaa");
    	}
    	Print(p2, 5);
    
    	system("pause");
    	return 0;
    }
    

    结构体深浅拷贝

    #include <stdio.h>
    #include <stdlib.h>
    
    typedef struct Person
    {
    	int uid;
    	char *name;
    }Person;
    
    int main(int argc, char* argv[])
    {
    
    	struct Person p1,p2;
    
    	p1.name = malloc(sizeof(char)* 64);
    	strcpy(p1.name, "admin");
    	p1.uid = 1;
    
    	p2.name = malloc(sizeof(char)* 64);
    	strcpy(p2.name, "guest");
    	p2.uid = 2;
    
    	// p2 = p1;  浅拷贝
    
    	// 深拷贝
    
    	if (p1.name != NULL)
    	{
    		free(p1.name);
    		p1.name == NULL;
    	}
    
    	p1.name = malloc(strlen(p2.name) + 1);
    	strcpy(p2.name, p1.name);
    	p2.uid = p1.uid;
    
    	printf("p2 -> %s \n", p2.name);
    
    	system("pause");
    	return 0;
    }
    
    

    结构体字段排序: 首先对比结构中的UID,通过冒泡排序将UID从小到大排列,也可以通过Name字段进行排序.

    #include <stdio.h>
    #include <stdlib.h>
    
    struct Student
    {
    	int uid;
    	char name[32];
    	double score;
    };
    
    int StructSort(struct Student *stu,int len)
    {
    	for (int x = 0; x < len - 1; x++)
    	{
    		for (int y = 0; y < len - x - 1; y++)
    		{
    			// if (strcmp(stu[y].name, stu[y + 1].name) > 0)
    			if (stu[y].uid > stu[y + 1].uid)
    			{
    				// 结构体变量互换,将用户UID从小到大排列
    				struct Student tmp = stu[y];
    				stu[y] = stu[y + 1];
    				stu[y+1] = tmp;
    			}
    		}
    	}
    	return 0;
    }
    
    void MyPrint(struct Student *stu,int len)
    {
    	for (int x = 0; x < len; x++)
    		printf("Uid: %d  Name: %s  Score: %.1f \n", stu[x].uid,stu[x].name,stu[x].score);
    }
    
    int main(int argc, char* argv[])
    {
    	struct Student stu[3] = {
    		{8,"admin",79.5},
    		{5,"guest",89.5},
    		{1,"root",99},
    	};
    
    	StructSort(stu, 3);    // 调用排序
    	MyPrint(stu, 3);       // 输出结果
    
    	system("pause");
    	return 0;
    }
    

    结构体数据之间的交换:

    #include <stdio.h>
    #include <stdlib.h>
    #include <string.h>
    
    struct Student
    {
    	char *name;
    	int score[3];
    };
    
    int StructExchange(struct Student *stu, int len, char *str1,char *str2)
    {
    	struct Student *ptr1;
    	struct Student *ptr2;
    
    	// 找到两个名字所对应的成绩
    	for (int x = 0; x < len; ++x)
    	{
    		if (!strcmp(stu[x].name, str1))
    			ptr1 = &stu[x];
    		if (!strcmp(stu[x].name, str2))
    			ptr2 = &stu[x];
    	}
    
    	// 开始交换两个人的成绩
    	for (int y = 0; y < 3; y++)
    	{
    		int tmp = ptr1->score[y];
    		ptr1->score[y] = ptr2->score[y];
    		ptr2->score[y] = tmp;
    	}
    	return 0;
    }
    
    void MyPrint(struct Student *stu,int len)
    {
    	for (int x = 0; x < len; x++)
    	{
    		printf("Name: %s --> score: %d %d %d \n", stu[x].name, stu[x].score[0], stu[x].score[1], stu[x].score[2]);
    	}
    }
    
    int main(int argc, char* argv[])
    {
    	struct Student stu[3];
    
    	// 动态开辟空间,并动态输入姓名与成绩
    	// admin 1 1 1 / guest 2 2 2 / root 3 3 3
    	for (int x = 0; x < 3; x++)
    	{
    		stu[x].name = (char *)malloc(sizeof(char) * 64);    // 开辟空间
    		scanf("%s%d%d%d", stu[x].name, &stu[x].score[0], &stu[x].score[1], &stu[x].score[2]);
    	}
    
    	MyPrint(&stu, 3);
    	// 开始交换两个人名的成绩
    	StructExchange(&stu, 3, "root", "admin");
    	printf("----------------------------\n");
    
    	MyPrint(&stu, 3);
    
    	// 动态内存的释放
    	for (int y = 0; y < 3; y++)
    		free(stu[y].name);
    
    	system("pause");
    	return 0;
    }
    

    结构体偏移量计算:

    #include <stdio.h>
    #include <stdlib.h>
    #include <stddef.h>
    
    int main(int argc, char* argv[])
    {
    
    	struct Student
    	{
    		int uid;
    		char *name;
    	};
    
    	struct Student stu = { 1, "lyshark" };
    	int offset = (int *)( (char *)&stu + offsetof(struct Student, name) );
    	printf("指针首地址: %x \n", offset);
    
    	// =================================================================
    	// 第二种嵌套结构体取地址
    
    	struct SuperClass
    	{
    		int uid;
    		char *name;
    		struct stu
    		{
    			int sid;
    			char *s_name;
    		}stu;
    	};
    
    	struct SuperClass super = { 1001, "lyshark" ,1,"xiaowang"};
    
    	int offset1 = offsetof(struct SuperClass, stu);
    	int offset2 = offsetof(struct stu, sid);
    
    	// SuperClass + stu 找到 sid 首地址
    	int struct_offset = ((char *)&super + offset1) + offset2;
    	printf("sid首地址: %x --> %x \n", struct_offset, &super.stu.sid);
    
    	int stu_sid = *(int *) ((char *)&super + offset1) + offset2;
    	printf("sid里面的数值是: %d \n", stu_sid);
    
    	int stu_sid_struct = ((struct stu *)((char *)&super + offset1))->sid;
    	printf("sid里面的数值是: %d \n", stu_sid_struct);
    
    	system("pause");
    	return 0;
    }
    

    结构体嵌套一级指针

    #include <stdio.h>
    #include <stdlib.h>
    
    typedef struct Person
    {
    	int id;
    	char *name;
    	int age;
    }Person;
    
    // 分配内存空间,每一个二级指针中存放一个一级指针
    struct Person ** allocateSpace()
    {
    	// 分配3个一级指针,每一个指针指向一个结构首地址
    	struct Person **tmp = malloc(sizeof(struct Person *) * 3);
    	for (int x = 0; x < 3; x++)
    	{
    		tmp[x] = malloc(sizeof(struct Person));    // (真正的)分配一个存储空间
    		tmp[x]->name = malloc(sizeof(char) * 64);  // 分配存储name的空间
    		sprintf(tmp[x]->name, "name_%d", x);
    		tmp[x]->id = x;
    		tmp[x]->age = x + 10;
    	}
    	return tmp;
    }
    
    // 循环输出数据
    void MyPrint(struct Person **person)
    {
    	for (int x = 0; x < 3; x++)
    	{
    		printf("Name: %s \n", person[x]->name);
    	}
    }
    
    // 释放内存空间,从后向前,从小到大释放
    void freeSpace(struct Person **person)
    {
    	if (person != NULL)
    	{
    		for (int x = 0; x < 3; x++)
    		{
    			if (person[x]->name != NULL)
    			{
    				printf("%s 内存被释放 \n",person[x]->name);
    				free(person[x]->name);
    				person[x]->name = NULL;
    			}
    			
    			free(person[x]);
    			person[x] = NULL;
    		}
    		free(person);
    		person = NULL;
    	}
    }
    
    
    int main(int argc, char* argv[])
    {
    	struct Person **person = NULL;
    
    	person = allocateSpace();
    	MyPrint(person);
    	freeSpace(person);
    
    	system("pause");
    	return 0;
    }
    

    结构体嵌套二级指针

    #include <stdio.h>
    #include <stdlib.h>
    
    struct Student
    {
    	char * name;
    }Student;
    
    struct Teacher
    {
    	char *name;
    	char **student;
    }Teacher;
    
    void allocateSpace(struct Teacher ***ptr)
    {
    	// 首先分配三个二级指针,分别指向三个老师的结构首地址
    	struct Teacher **teacher_ptr = malloc(sizeof(struct Teacher *) * 3);
    	
    	for (int x = 0; x < 3; x++)
    	{
    		// 先来分配老师姓名存储字符串,然后赋初值
    		teacher_ptr[x] = malloc(sizeof(struct Teacher));  // 给teacher_ptr整体分配空间
    		teacher_ptr[x]->name = malloc(sizeof(char)* 64);  // 给teacher_ptr里面的name分配空间
    		sprintf(teacher_ptr[x]->name, "teacher_%d", x);   // 分配好空间之后,将数据拷贝到name里面
    		
    // -------------------------------------------------------------------------------------
    		// 接着分配该老师管理的学生数据,默认管理四个学生
    		teacher_ptr[x]->student = malloc(sizeof(char *) * 4);   // 给teacher_ptr 里面的student分配空间
    		for (int y = 0; y < 4; y++)
    		{
    			teacher_ptr[x]->student[y] = malloc(sizeof(char) * 64);
    			sprintf(teacher_ptr[x]->student[y], "%s_stu_%d", teacher_ptr[x]->name, y);
    		}
    	}
    	// 最后将结果抛出去
    	*ptr = teacher_ptr;
    }
    
    // 输出老师和学生数据
    void MyPrint(struct Teacher **ptr)
    {
    	for (int x = 0; x < 3; x++)
    	{
    		printf("老师姓名: %s \n", ptr[x]->name);
    		for (int y = 0; y < 4; y++)
    		{
    			printf("--> 学生: %s \n", ptr[x]->student[y]);
    		}
    	}
    }
    
    // 最后释放内存
    void freeSpace(struct Teacher **ptr)
    {
    	for (int x = 0; x < 3; x++)
    	{
    		if (ptr[x]->name != NULL)
    		{
    			free(ptr[x]->name);
    			ptr[x]->name = NULL;
    		}
    		
    		for (int y = 0; y < 4; y++)
    		{
    			if (ptr[x]->student[y] != NULL)
    			{
    				free(ptr[x]->student[y]);
    				ptr[x]->student[y] = NULL;
    			}
    		}
    		free(ptr[x]->student);
    		ptr[x]->student = NULL;
    	}
    }
    
    int main(int argc, char* argv[])
    {
    	struct Teacher **teacher_ptr = NULL;
    
    	allocateSpace(&teacher_ptr);
    	MyPrint(teacher_ptr);
    	freeSpace(teacher_ptr);
    
    	system("pause");
    	return 0;
    }
    

    结构体内嵌共用体:

    #define _CRT_SECURE_NO_WARNINGS
    #include <stdio.h>
    #include <stdlib.h>
    
    struct Person
    {
    	int uid;             // 编号
    	char name[20];       // 姓名
    	char jobs;           // 老师=t 或 学生 = s
    	union
    	{
    		char stu_class[32];   // 学生所在班级
    		char tea_class[32];   // 老师的所教课程
    	}category;
    };
    
    int main(int argc, char* argv[])
    {
    	struct Person person[3];
    
    	for (int x = 0; x < 3; x++)
    	{
    		// 首先输入前三项,因为这三个数据是通用的,老师学生都存在的属性
    		printf("输入: ID 姓名 工作类型(s/t) \n");
    		scanf("%d %s %c", &person[x].uid, &person[x].name, &person[x].jobs);
    
    		if (person[x].jobs == 's')                     // 如果是学生,输入stu_class
    			scanf("%s", person[x].category.stu_class);
    		if (person[x].jobs == 't')                     // 如果是老师,输入tea_class
    			scanf("%s", person[x].category.tea_class);
    	}
    
    	printf("--------------------------------------------------------------\n");
    
    	for (int y = 0; y < 3; y++)
    	{
    		if (person[y].jobs == 's')
    			printf("老师: %s 职务: %s \n", person[y].name, person[y].category.tea_class);
    		if (person[y].jobs == 't')
    			printf("学生: %s 班级: %s \n", person[y].name, person[y].category.stu_class);
    	}
    	system("pause");
    	return 0;
    }
    

    结构体与链表

    结构体基本定义:

    #include <stdio.h>
    
    typedef struct Person
    {
    	int uid;
    	char name[64];
    }Person;
    
    int main(int argc, char* argv[])
    {
    	// 在栈上分配空间
    	struct Person s1 = { 100, "admin" };
    	printf("%s \n", s1.name);
    	
    	// 在堆上分配空间
    	struct Person *s2 = malloc(sizeof(struct Person));
    	strcpy(s2->name, "lyshark");
    	printf("%s \n", s2->name);
    
    
    	system("pause");
    	return 0;
    }
    

    结构体变量数组:

    #include <stdio.h>
    #include <stdlib.h>
    
    typedef struct Person
    {
    	int uid;
    	char name[64];
    }Person;
    
    
    
    void Print(struct Person *p,int len)
    {
    	for (int x = 0; x < len; x++)
    	{
    		printf("%d \n", p[x].uid);
    	}
    }
    
    int main(int argc, char* argv[])
    {
    	// 栈上分配结构体(聚合初始化)
    	struct Person p1[] = {
    		{ 1, "aaa" },
    		{ 2, "bbb" },
    		{ 3, "ccc" },
    	};
    
    	int len = sizeof(p1) / sizeof(struct Person);
    	Print(p1, len);
    
    	// 在堆上分配
    	struct Person *p2 = malloc(sizeof(struct Person) * 5);
    
    	for (int x = 0; x < 5; x++)
    	{
    		p2[x].uid = x;
    		strcpy(p2[x].name, "aaa");
    	}
    	Print(p2, 5);
    
    	system("pause");
    	return 0;
    }
    

    结构体深浅拷贝

    #include <stdio.h>
    #include <stdlib.h>
    
    typedef struct Person
    {
    	int uid;
    	char *name;
    }Person;
    
    int main(int argc, char* argv[])
    {
    
    	struct Person p1,p2;
    
    	p1.name = malloc(sizeof(char)* 64);
    	strcpy(p1.name, "admin");
    	p1.uid = 1;
    
    	p2.name = malloc(sizeof(char)* 64);
    	strcpy(p2.name, "guest");
    	p2.uid = 2;
    
    	// p2 = p1;  浅拷贝
    
    	// 深拷贝
    
    	if (p1.name != NULL)
    	{
    		free(p1.name);
    		p1.name == NULL;
    	}
    
    	p1.name = malloc(strlen(p2.name) + 1);
    	strcpy(p2.name, p1.name);
    	p2.uid = p1.uid;
    
    	printf("p2 -> %s \n", p2.name);
    
    
    
    
    
    
    
    	system("pause");
    	return 0;
    }
    
    

    结构体嵌套一级指针

    #include <stdio.h>
    #include <stdlib.h>
    
    typedef struct Person
    {
    	int id;
    	char *name;
    	int age;
    }Person;
    
    // 分配内存空间,每一个二级指针中存放一个一级指针
    struct Person ** allocateSpace()
    {
    	// 分配3个一级指针,每一个指针指向一个结构首地址
    	struct Person **tmp = malloc(sizeof(struct Person *) * 3);
    	for (int x = 0; x < 3; x++)
    	{
    		tmp[x] = malloc(sizeof(struct Person));    // (真正的)分配一个存储空间
    		tmp[x]->name = malloc(sizeof(char) * 64);  // 分配存储name的空间
    		sprintf(tmp[x]->name, "name_%d", x);
    		tmp[x]->id = x;
    		tmp[x]->age = x + 10;
    	}
    	return tmp;
    }
    
    // 循环输出数据
    void MyPrint(struct Person **person)
    {
    	for (int x = 0; x < 3; x++)
    	{
    		printf("Name: %s \n", person[x]->name);
    	}
    }
    
    // 释放内存空间,从后向前,从小到大释放
    void freeSpace(struct Person **person)
    {
    	if (person != NULL)
    	{
    		for (int x = 0; x < 3; x++)
    		{
    			if (person[x]->name != NULL)
    			{
    				printf("%s 内存被释放 \n",person[x]->name);
    				free(person[x]->name);
    				person[x]->name = NULL;
    			}
    			
    			free(person[x]);
    			person[x] = NULL;
    		}
    		free(person);
    		person = NULL;
    	}
    }
    
    int main(int argc, char* argv[])
    {
    	struct Person **person = NULL;
    
    	person = allocateSpace();
    	MyPrint(person);
    	freeSpace(person);
    
    	system("pause");
    	return 0;
    }
    

    结构体嵌套二级指针

    #include <stdio.h>
    #include <stdlib.h>
    
    struct Student
    {
    	char * name;
    }Student;
    
    struct Teacher
    {
    	char *name;
    	char **student;
    }Teacher;
    
    void allocateSpace(struct Teacher ***ptr)
    {
    	// 首先分配三个二级指针,分别指向三个老师的结构首地址
    	struct Teacher **teacher_ptr = malloc(sizeof(struct Teacher *) * 3);
    	
    	for (int x = 0; x < 3; x++)
    	{
    		// 先来分配老师姓名存储字符串,然后赋初值
    		teacher_ptr[x] = malloc(sizeof(struct Teacher));  // 给teacher_ptr整体分配空间
    		teacher_ptr[x]->name = malloc(sizeof(char)* 64);  // 给teacher_ptr里面的name分配空间
    		sprintf(teacher_ptr[x]->name, "teacher_%d", x);   // 分配好空间之后,将数据拷贝到name里面
    		
    // -------------------------------------------------------------------------------------
    		// 接着分配该老师管理的学生数据,默认管理四个学生
    		teacher_ptr[x]->student = malloc(sizeof(char *) * 4);   // 给teacher_ptr 里面的student分配空间
    		for (int y = 0; y < 4; y++)
    		{
    			teacher_ptr[x]->student[y] = malloc(sizeof(char) * 64);
    			sprintf(teacher_ptr[x]->student[y], "%s_stu_%d", teacher_ptr[x]->name, y);
    		}
    	}
    	// 最后将结果抛出去
    	*ptr = teacher_ptr;
    }
    
    // 输出老师和学生数据
    void MyPrint(struct Teacher **ptr)
    {
    	for (int x = 0; x < 3; x++)
    	{
    		printf("老师姓名: %s \n", ptr[x]->name);
    		for (int y = 0; y < 4; y++)
    		{
    			printf("--> 学生: %s \n", ptr[x]->student[y]);
    		}
    	}
    }
    
    // 最后释放内存
    void freeSpace(struct Teacher **ptr)
    {
    	for (int x = 0; x < 3; x++)
    	{
    		if (ptr[x]->name != NULL)
    		{
    			free(ptr[x]->name);
    			ptr[x]->name = NULL;
    		}
    		
    		for (int y = 0; y < 4; y++)
    		{
    			if (ptr[x]->student[y] != NULL)
    			{
    				free(ptr[x]->student[y]);
    				ptr[x]->student[y] = NULL;
    			}
    		}
    		free(ptr[x]->student);
    		ptr[x]->student = NULL;
    	}
    }
    
    int main(int argc, char* argv[])
    {
    	struct Teacher **teacher_ptr = NULL;
    
    	allocateSpace(&teacher_ptr);
    	MyPrint(teacher_ptr);
    	freeSpace(teacher_ptr);
    
    	system("pause");
    	return 0;
    }
    

    静态链表 理解一下

    #include <stdio.h>
    #include <stdlib.h>
    
    // 定义链表节点类型
    struct LinkNode
    {
    	int data;
    	struct LinkNode *next;
    };
    
    
    int main(int argc, char* argv[])
    {
    	struct LinkNode node1 = { 10, NULL };
    	struct LinkNode node2 = { 20, NULL };
    	struct LinkNode node3 = { 30, NULL };
    	struct LinkNode node4 = { 40, NULL };
    	
    	node1.next = &node2;
    	node2.next = &node3;
    	node3.next = &node4;
    	node4.next = NULL;
    
    	// 遍历链表结构
    
    	struct LinkNode *ptr = &node1;
    
    	while (ptr != NULL)
    	{
    		printf("%d \n", ptr->data);
    		ptr = ptr->next;
    	}
    
    	system("pause");
    	return 0;
    }
    

    动态链表

    #include <stdio.h>
    #include <stdlib.h>
    
    // 定义链表节点类型
    struct LinkNode
    {
    	int data;
    	struct LinkNode *next;
    };
    
    struct LinkNode *init_link()
    {  // 创建一个头结点,头结点不需要添加任何数据
    	struct LinkNode *header = malloc(sizeof(struct LinkNode));
    	header->data = 0;
    	header->next = NULL;
    
    	struct LinkNode *p_end = header;    // 创建一个尾指针
    
    	int val = -1;
    	while (1)
    	{
    		scanf("%d", &val);  // 输入插入的数据
    		if (val == -1)      // 如果输入-1说明输入结束了
    			break;
    
    		// 先创建新节点
    		struct LinkNode *newnode = malloc(sizeof(struct LinkNode));
    		newnode->data = val;
    		newnode->next = NULL;
    
    		// 将节点插入到链表中
    		p_end->next = newnode;
    		// 更新尾部指针指向
    		p_end = newnode;
    	}
    	return header;
    }
    
    // 遍历链表
    int foreach_link(struct LinkNode *header)
    {
    	if (NULL == header || header->next == NULL)
    		return 0;
    
    	while (header->next != NULL)
    	{
    		printf("%d \n", header->data);
    		header = header->next;
    	}
    	return 1;
    }
    
    // 在header节点中oldval插入数据
    void insert_link(struct LinkNode *header,int oldval,int newval)
    {
    	struct LinkNode *pPrev = header;
    	struct LinkNode *Current = pPrev->next;
    
    	if (NULL == header)
    		return;
    
    
    	while (Current != NULL)
    	{
    		if (Current->data == oldval)
    			break;
    
    		pPrev = Current;
    		Current = Current->next;
    	}
    	// 如果值不存在则默认插入到尾部
    	//if (Current == NULL)
    	//	return;
    
    	// 创建新节点
    
    	struct LinkNode *newnode = malloc(sizeof(struct LinkNode));
    	newnode->data = newval;
    	newnode->next = NULL;
    
    	// 新节点插入到链表中
    	newnode->next = Current;
    	pPrev->next = newnode;
    }
    
    // 清空链表
    void clear_link(struct LinkNode *header)
    {
    	// 辅助指针
    	struct LinkNode *Current = header->next;
    
    	while (Current != NULL)
    	{
    		// 保存下一个节点地址
    		struct LinkNode *pNext = Current->next;
    		printf("清空数据: %d \n", Current->data);
    		free(Current);
    		Current = pNext;
    	}
    	header->next = NULL;
    }
    
    
    // 删除值为val的节点
    int remove_link(struct LinkNode *header, int delValue)
    {
    	if (NULL == header)
    		return;
    
    	// 设置两个指针,指向头结点和尾结点
    	struct LinkNode *pPrev = header;
    	struct LinkNode *Current = pPrev->next;
    
    	while (Current != NULL)
    	{
    		if (Current->data == delValue)
    		{
    			// 删除节点的过程
    			pPrev->next = Current->next;
    			free(Current);
    			Current = NULL;
    		}
    	}
    
    	// 移动两个辅助指针
    	pPrev = Current;
    	Current = Current->next;
    
    
    }
    
    // 销毁链表
    void destroy_link(struct LinkNode *header)
    {
    	if (NULL == header)
    		return;
    
    	struct LinkNode *Curent = header;
    	while (Curent != NULL)
    	{
    		// 先来保存一下下一个节点地址
    		struct LinkNode *pNext = Curent->next;
    
    		free(Curent);
    
    		// 指针向后移动
    		Curent = pNext;
    	}
    }
    
    // 反响排序
    void reverse_link(struct LinkNode *header)
    {
    	if (NULL == header)
    		return;
    
    	struct LinkNode *pPrev = NULL;
    	struct LinkNode *Current = header->next;
    	struct LinkNode * pNext = NULL;
    
    	while (Current != NULL)
    	{
    		pNext = Current->next;
    		Current->next = pPrev;
    
    		pPrev = Current;
    		Current = pNext;
    	}
    	header->next = pPrev;
    }
    
    int main(int argc, char* argv[])
    {
    	struct LinkNode * header = init_link();
    
    	reverse_link(header);
    	foreach_link(header);
    
    	clear_link(header);
    	system("pause");
    	return 0;
    }
    
    文章出处:https://www.cnblogs.com/LyShark/p/12863352.html
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  • 原文地址:https://www.cnblogs.com/LyShark/p/12863352.html
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