C 结构体的定义
#include <stdio.h> struct student { int ID; char name[10]; int age; }; //注意这里的分号 int main() { // 初始化 struct student student1 = {1111,"Redhat",20}; struct student student2 = {.ID = 1111,.name = "Debian",.age = 20};//C99才有 struct student student3 = {1111,"BSD",.ID = 20,.age = 30}; //ID = 20 //使用 printf("%d,%s,%d \n",student1.ID,student1.name,student1.age); printf("%d,%s,%d \n",student2.ID,student2.name,student2.age); printf("%d,%s,%d \n",student3.ID,student3.name,student3.age); } chunli@ubuntu:~/pointer$ gcc -std=c99 main.c && ./a.out 1111,Redhat,20 1111,Debian,20 20,BSD,30
结构体内存分配情况
小的遵循大的数据类型,存在浪费内存的情况
#include <stdio.h> #include <string.h> struct student { unsigned char c1; unsigned char c2; unsigned int i1; unsigned char c3; unsigned char c4; unsigned char c5; unsigned char c6; unsigned int i2; }; int main() { printf("%ld \n",sizeof(struct student)); struct student student1; memset(&student1,0x55,sizeof(struct student)); student1.i1 = 0x12345678; student1.i2 = 0x23456789; student1.c1 = 0x21; student1.c2 = 0x22; student1.c3 = 0x23; student1.c4 = 0x24; student1.c5 = 0x25; student1.c6 = 0x26; int *p = (int*) &student1; for(int i = 0;i< sizeof(struct student)/4;i++) { printf("%p %x \n",p,*p); p++; } } chunli@ubuntu:~/pointer$ gcc -std=c99 main.c && ./a.out 16 0x7ffc7913b1c0 55552221 0x7ffc7913b1c4 12345678 0x7ffc7913b1c8 26252423 0x7ffc7913b1cc 23456789 可以看到内存初始化就是0X55,第一个的4个字节存在了浪费
结构体,自定义数据类型:
#include <stdio.h> #include <string.h> struct student { unsigned char c1:1; unsigned char c2:3; unsigned char c3:4; }; int main() { printf("%ld \n",sizeof(struct student)); struct student student1; student1.c1 = 1; student1.c2 = 6; student1.c3 = 14; char *p = (char *)& student1; printf("%x,%d,%d,%d \n",*p,student1.c1,student1.c2,student1.c3); } chunli@ubuntu:~/pointer$ gcc -std=c99 main.c && ./a.out 1 ffffffed,1,6,14
结构体嵌套:
#include <stdio.h> #include <string.h> struct man { unsigned char age; }; struct student { unsigned char name[20]; struct man a_man; }; int main() { printf("%ld \n",sizeof(struct student)); struct student student1; student1.a_man.age = 10; printf("student age = %d \n",student1.a_man.age); } chunli@ubuntu:~/pointer$ gcc -std=c99 main.c && ./a.out 21 student age = 10
结构体数组,结构体嵌套
#include <stdio.h> #include <string.h> struct man { char name[20]; unsigned char age; unsigned char heiget; }; struct human { struct man son; int money; }; int main() { printf("%ld \n",sizeof(struct human)); /* 结构体数组 */ struct man people[3]={ {"奥巴马",50,170}, {"金正恩",44,166}, {"朴槿惠",33,155}, }; /* 结构体嵌套 */ struct human a_human; a_human.son.age = 10; printf("son age = %d \n",a_human.son.age); } chunli@ubuntu:~/pointer$ gcc -std=c99 main.c && ./a.out 28 son age = 10
结构体赋值
#include <stdio.h> #include <string.h> struct man { char name[20]; unsigned char age; unsigned char height; }; int main() { struct man people1={"奥巴马",50,170}; struct man people2; people2 = people1; //结构体的赋值,people1的内存赋值到了people2,二者相互独立! //memcpy(&people2,&people1,sizeof(people1)); //相当于memcpy(&people2,&people1,sizeof(people1)); printf("%s,%d,%d \n",people2.name,people2.age,people2.height); /////////////////////////////////////////////////////// /*区别于数组 char str1[10] = {"Hello!"}; char str2[20]; str2 = str1; //这是不允许的。数组的名仅是一个地址,不允许赋值。 ////////////////////////////////////////////////////// //这个不是赋值,这个只能是指向了那个地址 char str3[] = {"Hello !"}; char *p1 = str3; char *p2 = p1; */ } chunli@ubuntu:~/pointer$ gcc -std=c99 main.c && ./a.out 奥巴马,50,170
结构体赋值里面的指针变量
#include <stdio.h> #include <stdlib.h> #include <string.h> struct man { char *name; unsigned char age; unsigned char height; }; int main() { struct man people1={"朴槿惠",40,170}; struct man people2; people2 = people1;//结构体赋值 printf("%s,%d,%d \n",people2.name,people2.age,people2.height); people2.name = "王麻子"; //指针指向常量"王麻子" printf("%s,%d,%d \n",people2.name,people2.age,people2.height); /*结构体指针*/ struct man people3; people3.name = malloc(20); strcpy(people3.name,"孙悟空"); printf("%s,%d,%d \n",people3.name,people3.age,people3.height); //free(people3.name); //堆释放会对下面的strcpy(people4.name,people3.name);有影响 /*如果结构体里面有指针,不能通过简单赋值完成操作,因为指向的是一样的*/ struct man people4; people4.name = malloc(strlen(people3.name)+1); strcpy(people4.name,people3.name); people4.age = people3.age; people4.height = people3.height; printf("%s,%d,%d \n",people4.name,people4.age,people4.height); free(people3.name); //堆释放 free(people4.name); //堆释放 } chunli@ubuntu:~/pointer$ gcc -std=c99 main.c && ./a.out 朴槿惠,40,170 王麻子,40,170 孙悟空,0,0 孙悟空,0,0
结构体指针 初步1
#include <stdio.h> #include <stdlib.h> #include <string.h> struct man { char *name; unsigned char age; unsigned char height; }; int main() { struct man people1; struct man *people2 = &people1; (*people2).name = malloc(10); (*people2).age = 20; (*people2).height = 170; /* 上面的形式可以写成一下:*/ people2 -> name = malloc(10); people2 -> age = 20; people2 -> height = 170; } 编译通过 chunli@ubuntu:~/pointer$ gcc -std=c99 main.c && ./a.out chunli@ubuntu:~/pointer$
结构体指针 初步2
#include <stdio.h> #include <stdlib.h> #include <string.h> struct man { unsigned char id; char name[20]; unsigned char height; }; int main() { struct man people[3] = { {1,"wang",181}, //wang属于常量 {2,"li",182}, {3,"zhang",189}, }; /* 定义一个结构体指针 */ struct man *people2 = &people[0]; printf("%d,%s,%d \n",people2->id,people2->name,people2->height); /* 访问方式2,也可以方便for循环 */ printf("%d,%s,%d \n",people2[1].id,people2[1].name,people2[1].height); people2++;//一次会移动一个结构体 printf("%d,%s,%d \n",people2->id,people2->name,people2->height); /* struct man people1 = {1,"wang",181}; struct man people2 = {2,"wang",181}; struct man people3 = {3,"wang",181}; 不要尝试用循环来遍历这样的数据,因为您不知道编译器是怎么安排的 最好放在同一个数组里面 */ } chunli@ubuntu:~/pointer$ gcc -std=c99 main.c && ./a.out 1,wang,181 2,li,182 2,li,182
结构体的指针,初步3
#include <stdlib.h> #include <string.h> struct man { unsigned char id; char *name; unsigned char age; }; int main() { struct man *sp = malloc(sizeof(struct man)); sp->id = 5; sp->age = 10; sp->name = malloc(10); strcpy(sp->name,"zhang"); printf("%d,%s,%d \n",sp->id,sp->name,sp->age); free(sp->name); // 一定先释放这个 free(sp); //要不然sp-name永远找不到了 return 0; } chunli@ubuntu:~/pointer$ gcc -std=c99 main.c && ./a.out 5,zhang,10
动态获取用户输入,不会浪费内存空间
#include <stdio.h> #include <stdlib.h> #include <string.h> struct test { char *name; //指针哦 }; struct man { unsigned char id; char *name; unsigned char age; //struct test *p; //有嵌套了一层,这是很难搞的 }; int main() { struct man *sp = malloc(sizeof(struct man) * 10); memset(sp,0,sizeof(struct man) * 10);// 内存清零 for(int i = 0;i<10;i++) { sp[i].id = i; sp[i].age = i; char buf[999]={0}; scanf("%s",buf); int len = strlen(buf); sp[i].name =malloc(len+1) ; sprintf(sp[i].name,"%s",buf); } for(int i = 0;i<10;i++) { printf("%d,%s,%d \n",sp[i].id,sp[i].name,sp[i].age); } for(int i = 0;i<10;i++)//循环释放 { free(sp[i].name); } free(sp); //全部释放 return 0; } chunli@ubuntu:~/pointer$ gcc -std=c99 main.c && ./a.out 12 1111111111111111111111111111111111111111111111111111111111111111111 2222222222222222222222222222222222222222222222222222222222222222222 a s wsswdwdwdwdwedfwefefvdvgdf,kvdfvdfvdvmdvm mcsfdmcdsmc'nv vnvpmvpwvm[sdv fsdv dvdf e fdf f 0,12,0 1,1111111111111111111111111111111111111111111111111111111111111111111,1 2,2222222222222222222222222222222222222222222222222222222222222222222,2 3,a,3 4,s,4 5,wsswdwdwdwdwedfwefefvdvgdf,kvdfvdfvdvmdvm,5 6,mcsfdmcdsmc'nv,6 7,vnvpmvpwvm[sdv,7 8,fsdv,8 9,dvdf,9
形参是结构体的函数
#include <stdio.h> #include <stdlib.h> #include <string.h> struct man { unsigned char id; char *name; unsigned char age; }; void fun1(struct man a_man) { printf("id = %d,age = %d,name = %s \n",a_man.id,a_man.age,a_man.name); strcpy(a_man.name,"haha"); //会影响传过来的数据,因为指向的是同一块内存 a_man.id = 99; //而id就不会发生变化 } int main() { //struct man people1 = {0,"wang",100}; struct man people1; people1.id = 0; people1.age = 10; people1.name = malloc(10); strcpy(people1.name,"wang"); fun1(people1); printf("id = %d,age = %d,name = %s \n",people1.id,people1.age,people1.name); return 0; } chunli@ubuntu:~/pointer$ gcc -std=c99 main.c && ./a.out id = 0,age = 10,name = wang id = 0,age = 10,name = haha
结构体参数,地址与传值
chunli@ubuntu:~/pointer$ cat main.c #include <stdio.h> #include <stdlib.h> #include <string.h> struct man { unsigned char id; char name[100]; unsigned char age; }; void fun1(struct man a_man)//传值过来 { printf("id = %d,age = %d,name = %s \n",a_man.id,a_man.age,a_man.name); strcpy(a_man.name,"haha"); //无法修改 a_man.id = 99; //无法修改 } void fun2(struct man *sp) //地址传过来 //void fun2(const struct man *sp) //保护起来,防止修改 { printf("id = %d,age = %d,name = %s \n",sp->id,sp->age,sp->name); strcpy(sp->name,"鲁智深"); //可以修改 sp->id = 66; //可以修改 } int main() { struct man people1; people1.id = 0; people1.age = 10; strcpy(people1.name,"wang"); fun1(people1);//fun1无法修改参数值 printf("id = %d,age = %d,name = %s \n",people1.id,people1.age,people1.name); fun2(&people1); printf("id = %d,age = %d,name = %s \n",people1.id,people1.age,people1.name); return 0; } chunli@ubuntu:~/pointer$ gcc -std=c99 main.c && ./a.out id = 0,age = 10,name = wang id = 0,age = 10,name = wang id = 0,age = 10,name = wang id = 66,age = 10,name = 鲁智深
如何修改机构体内部的数组
#include <stdio.h> #include <stdlib.h> #include <string.h> struct str { char buf[100]; }; void fun1(struct str s) { strcpy(s.buf,"hello "); } void fun2(char s[]) { strcpy(s,"hello"); } int main() { struct str s={"world!"}; ; fun1(s);//传结构体,相当于赋值过去了,不会改变变量 (会很消耗内存的性能) printf("%s \n",s.buf); char s1[100]="world!"; fun2(s1);//数组会把地址传过去,会修改变量 printf("%s \n",s1); return 0; } chunli@ubuntu:~/pointer$ gcc -std=c99 main.c && ./a.out world! hello
结构体函数 初始化结构体
#include <stdio.h> #include <stdlib.h> #include <string.h> struct str { char buf[100]; }; struct str getstr() { struct str s; strcpy(s.buf,"Hello World!"); return s; } char *getstr1() { char buf[100];//在栈区 strcpy(buf,"Hello World!"); //return buf;//无法返回有效数据 } int main() { //char *tmp = getstr1(); 非法执行 struct str tmp = getstr(); printf("%s \n",tmp.buf); return 0; } chunli@ubuntu:~/pointer$ gcc -std=c99 main.c && ./a.out Hello World!
【指向结构体的指针】
返回结构体,消耗很大
#include <stdio.h> #include <stdlib.h> #include <string.h> struct str { char buf[100]; }; struct str getstr() { struct str s; strcpy(s.buf,"Hello World!"); return s; } char *getstr1() { char buf[100];//在栈区 strcpy(buf,"Hello World!"); //return buf;//无法返回有效数据 } int main() { //char *tmp = getstr1(); 非法执行 struct str tmp = getstr(); //内存拷贝,消耗很大 printf("%s \n",tmp.buf); return 0; }
返回结构体指针,消耗很小
#include <stdio.h> #include <stdlib.h> #include <string.h> struct str { char buf[100]; }; struct str *getstr() { struct str *s = malloc(sizeof(struct str)); printf("%p \n",s); strcpy(s->buf,"Hello World!"); return s;//把指针返回去 } int main() { struct str *tmp = getstr(); //内存拷贝,消耗很大 printf("%p \n",tmp); printf("%s \n",tmp->buf); free(tmp); return 0; } chunli@ubuntu:~/pointer$ gcc -std=c99 main.c && ./a.out 0x8cc010 0x8cc010 Hello World!
联合体初步1
#include <stdio.h> #include <stdlib.h> #include <string.h> union var { char c; int i; short d; char *s;//很危险 }; struct str { char c; int i; short d; }; int main() { /* 结构体与联合体元素地址区别 */ union var v;//联合体元素公用用一个地址 printf("%p \n" ,&(v.c)); printf("%p \n" ,&(v.i)); printf("%p \n" ,&(v.d));//小端对齐,高位放高位,低位放低位 struct str s;//结构体,元素分别独立 printf("%p \n" ,&(s.c)); printf("%p \n" ,&(s.i)); printf("%p \n" ,&(s.d)); /* 修改联合体元素 */ printf("%ld \n",sizeof(v)); v.c = 100; printf("%d \n",v.c); v.i = 1; printf("%d \n",v.c); return 0; } chunli@ubuntu:~/pointer$ gcc -std=c99 main.c && ./a.out 0x7ffc3f56e5d0 0x7ffc3f56e5d0 0x7ffc3f56e5d0 0x7ffc3f56e5e0 0x7ffc3f56e5e4 0x7ffc3f56e5e8 8 100 1
枚举
#include <stdio.h> #include <stdlib.h> #include <string.h> enum spectrum {red,yellow,green,blue,white,black};//申明一个枚举 enum number {zero=10,one=9,two,three};//申明一个枚举 void test(int i) {printf("test \n");} void test1(int a,int b) {printf("test1\n");} void test2(int a,int b,int c) {printf("test2\n");} void *function_factory(enum number n) { if(n == zero) return test; if(n == one) return test1; if(n == two) return test2; } void getcolor(enum spectrum color) { if(color == red) printf("red \n"); if(color == yellow) printf("yellow \n"); if(color == green) printf("green \n"); if(color == blue) printf("blue \n"); } int main() { enum number b = one; void *p = function_factory(b); printf("%p ,%p \n",p,test1); enum spectrum color = red; getcolor(color); printf("%d,%d,%d \n",red,yellow,green); printf("%d,%d,%d \n",zero,one,two); return 0; } chunli@ubuntu:~/pointer$ gcc -std=c99 main.c && ./a.out 0x400594 ,0x400594 red 0,1,2 10,9,10
typedef 初步
#include <stdio.h> #include <stdlib.h> #include <string.h> typedef unsigned char BYTE; #define mybyte unsigned char typedef unsigned int UINT;//严格检查变量类型 #define MAX 100 //简单替换,不做变量类型检查,没有分号 struct student { int id; char name[100]; }; int main() { BYTE b1 = 0xff; printf("%x \n",b1); UINT u1 = 0xFF00FF00; printf("%x \n",u1); //正常使用 struct student student1; //typedef 来定义 typedef struct student STUDENT; //自定义 数据类型 STUDENT student2; return 0; } chunli@ubuntu:~/pointer$ gcc -std=c99 main.c && ./a.out ff ff00ff00
没有用typedef之前的代码,看着很晕
#include <stdio.h> #include <stdlib.h> #include <string.h> const char *func1(const char *str1,const char *str2) { char *p = malloc(strlen(str1) + strlen(str2) +1); strcpy(p,str1); strcat(p,str2); return p; } const char *func2(const char *(*p)(const char *str1,const char *str2),const char *s1,const char *s2) { return p(s1,s2); } int main() { const char *tmp1 = "Hello"; const char *tmp2 = "world!"; const char *s = func2(func1,tmp1,tmp2); printf("%s \n",s); return 0; } chunli@ubuntu:~/pointer$ gcc -std=c99 main.c && ./a.out Helloworld!
typedef优化 对比
#include <stdio.h> #include <stdlib.h> #include <string.h> //定义一个指向这种函数类型的指针 typedef const char *(*FUNC1)(const char *str1,const char *str2); const char *func1(const char *str1,const char *str2) { char *p = malloc(strlen(str1) + strlen(str2) +1); strcpy(p,str1); strcat(p,str2); return p; } const char *func2(FUNC1 p,const char *s1,const char *s2) { return p(s1,s2); } int main() { const char *tmp1 = "Hello"; const char *tmp2 = "world!"; const char *s = func2(func1,tmp1,tmp2); printf("%s \n",s); return 0; } chunli@ubuntu:~/pointer$ gcc -std=c99 main.c && ./a.out Helloworld!
typedef深入1
#include <stdio.h> #include <stdlib.h> #include <string.h> //定义一个指向这种函数类型的指针 的数据类型 typedef const char *(*FUNC1)(const char *str1,const char *str2); //这是函数的原始申明 const char *func1(const char *str1,const char *str2) { char *p = malloc(strlen(str1) + strlen(str2) +1); strcpy(p,str1); strcat(p,str2); return p; } const char *func2(FUNC1 p,const char *s1,const char *s2) { return p(s1,s2); } FUNC1 test() { FUNC1 tmp = func1; return tmp; } int main() { //定义10个FUNC1数据类型 FUNC1 f[10]; //定义一个数组10个元素,参数是const char *str1,const char *str2,返回值是 const char * const char *(*p[10])(const char *str1,const char *str2); const char *tmp1 = "Hello "; const char *tmp2 = "world!"; const char *s = func2(func1,tmp1,tmp2); printf("%s \n",s); return 0; } chunli@ubuntu:~/pointer$ gcc -std=c99 main.c && ./a.out Hello world!
超级复杂的typedef
chunli@ubuntu:~/pointer$ cat main.c #include <stdio.h> #include <stdlib.h> #include <string.h> typedef unsigned char BYTE; typedef unsigned int UINT; #define MYBYTE unsigned char #define MAX 100 //typedef 100 MYMAX; struct student { int ID; char name[MAX]; }; typedef struct student STUDENT; typedef const char *(*FUNC1)(const char *str1, const char *str2); const char *func1(const char *str1, const char *str2) { char *p = malloc(strlen(str1) + strlen(str2) + 1); strcpy(p, str1); strcat(p, str2); return p; } /* const char *(*)(const char *str1, const char *str2) test() { FUNC1 tmp = func1; return tmp; } */ const char *func2(const char *(*p[])(const char *str1, const char *str2), const char *s1, const char *s2) { return (p[0])(s1, s2); } int main() { FUNC1 f[10];// const char *tmp1 = "hello "; const char *tmp2 = "world"; f[0] = func1; const char *s = func2(f, tmp1, tmp2); printf("s = %s\n", s); BYTE b; b = 0x12; UINT i; i = 0xffff; STUDENT st; return 0; } chunli@ubuntu:~/pointer$ gcc -std=c99 main.c && ./a.out s = hello world chunli@ubuntu:~/pointer$
【复习================================】
联合体的指针,很危险
#include <stdio.h> #include <stdlib.h> #include <string.h> union var { char c; int i; short d; char *s;//很危险 }; int main() { union var v; v.s = (char *)malloc(100); v.c = 1; free(v.s);//致命错误! return 0; } chunli@ubuntu:~/pointer$ gcc -std=c99 main.c && ./a.out Segmentation fault (core dumped)
typedef 特别高级的用法
chunli@ubuntu:~/pointer$ cat main.c #include <stdio.h> #include <stdlib.h> #include <string.h> typedef struct student ST; struct student { char name[200]; int id; }; typedef const char *(*FUNC1)(const char *str1,const char *str2) ; const char *funcl(const char *str1,const char *str2) { printf("%s,%s \n",str1,str2); return NULL; } const char *func2(FUNC1 p, const char *str1,const char *str2) { return p(str1,str2); } int main() { ST student1; strcpy(student1.name,"奥巴马"); student1.id = 1; printf("%d,%s \n",student1.id,student1.name); return 0; } chunli@ubuntu:~/pointer$ gcc -std=c99 main.c && ./a.out 1,奥巴马
不使用typedef
使用typedef
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