实验5
#include <stdio.h> #define N 5 void input(int x[], int n); void output(int x[], int n); void find_min_max(int x[], int n, int *pmin, int *pmax); int main() { int a[N]; int min, max; printf("录入%d个数据:\n", N); input(a, N); printf("数据是: \n"); output(a, N); printf("数据处理...\n"); find_min_max(a, N, &min, &max); printf("输出结果:\n"); printf("min = %d, max = %d\n", min, max); return 0; } void input(int x[], int n) { int i; for(i = 0; i < n; ++i) scanf("%d", &x[i]); } void output(int x[], int n) { int i; for(i = 0; i < n; ++i) printf("%d ", x[i]); printf("\n"); } void find_min_max(int x[], int n, int *pmin, int *pmax) { int i; *pmin = *pmax = x[0]; for(i = 0; i < n; ++i) if(x[i] < *pmin) *pmin = x[i]; else if(x[i] > *pmax) *pmax = x[i]; }
(1)函数find_min_max实现的功能是找出录入数据中的最大值和最小值
(2)45行时,pmin和pmax都指向x[0]的地址,即第一个录入的数据的地址
实验1.2
#include <stdio.h> #define N 5 void input(int x[], int n); void output(int x[], int n); int *find_max(int x[], int n); int main() { int a[N]; int *pmax; printf("录入%d个数据:\n", N); input(a, N); printf("数据是: \n"); output(a, N); printf("数据处理...\n"); pmax = find_max(a, N); printf("输出结果:\n"); printf("max = %d\n", *pmax); return 0; } void input(int x[], int n) { int i; for(i = 0; i < n; ++i) scanf("%d", &x[i]); } void output(int x[], int n) { int i; for(i = 0; i < n; ++i) printf("%d ", x[i]); printf("\n"); } int *find_max(int x[], int n) { int max_index = 0; int i; for(i = 0; i < n; ++i) if(x[i] > x[max_index]) max_index = i; return &x[max_index]; }
(1)函数find_max实现的功能是找出数据中的最大值并返回其地址
(2)可以
实验2.1
#include <stdio.h> #include <string.h> #define N 80 int main() { char s1[N] = "Learning makes me happy"; char s2[N] = "Learning makes me sleepy"; char tmp[N]; printf("sizeof(s1) vs. strlen(s1): \n"); printf("sizeof(s1) = %d\n", sizeof(s1)); printf("strlen(s1) = %d\n", strlen(s1)); printf("\nbefore swap: \n"); printf("s1: %s\n", s1); printf("s2: %s\n", s2); printf("\nswapping...\n"); strcpy(tmp, s1); strcpy(s1, s2); strcpy(s2, tmp); printf("\nafter swap: \n"); printf("s1: %s\n", s1); printf("s2: %s\n", s2); return 0; }
(1)数组1的大小是80个字节;sizof(s1)计算的是数组1所占的字节数;strlen(s1)计算的是字符的个数
(2)不可以,数组名是地址,不能直接用等于,而应该用strcpy
(3)交换了
2.2
#include <stdio.h> #include <string.h> #define N 80 int main() { char *s1 = "Learning makes me happy"; char *s2 = "Learning makes me sleepy"; char *tmp; printf("sizeof(s1) vs. strlen(s1): \n"); printf("sizeof(s1) = %d\n", sizeof(s1)); printf("strlen(s1) = %d\n", strlen(s1)); printf("\nbefore swap: \n"); printf("s1: %s\n", s1); printf("s2: %s\n", s2); printf("\nswapping...\n"); tmp = s1; s1 = s2; s2 = tmp; printf("\nafter swap: \n"); printf("s1: %s\n", s1); printf("s2: %s\n", s2); return 0; }
(1)存放的是字符串“Learning makes me happy”的首地址;sizeof(s1)计算的是指针变量所占的字节数;strlen(s1)统计的是字符数
(2)可以。char *s1定义了一个字符串数组用来存储字符串,然后再把字符串的首地址赋值给s1
(3)交换的是指针所指的地址,并没有交换两个字符串常量。
实验3
#include <stdio.h> int main() { int x[2][4] = {{1, 9, 8, 4}, {2, 0, 4, 9}}; int i, j; int *ptr1; // 指针变量,存放int类型数据的地址 int(*ptr2)[4]; // 指针变量,指向包含4个int元素的一维数组 printf("输出1: 使用数组名、下标直接访问二维数组元素\n"); for (i = 0; i < 2; ++i) { for (j = 0; j < 4; ++j) printf("%d ", x[i][j]); printf("\n"); } printf("\n输出2: 使用指针变量ptr1(指向元素)间接访问\n"); for (ptr1 = &x[0][0], i = 0; ptr1 < &x[0][0] + 8; ++ptr1, ++i) { printf("%d ", *ptr1); if ((i + 1) % 4 == 0) printf("\n"); } printf("\n输出3: 使用指针变量ptr2(指向一维数组)间接访问\n"); for (ptr2 = x; ptr2 < x + 2; ++ptr2) { for (j = 0; j < 4; ++j) printf("%d ", *(*ptr2 + j)); printf("\n"); } return 0; }
实验4
#include <stdio.h> #define N 80 void replace(char *str, char old_char, char new_char); // 函数声明 int main() { char text[N] = "Programming is difficult or not, it is a question."; printf("原始文本: \n"); printf("%s\n", text); replace(text, 'i', '*'); // 函数调用 注意字符形参写法,单引号不能少 printf("处理后文本: \n"); printf("%s\n", text); return 0; } // 函数定义 void replace(char *str, char old_char, char new_char) { int i; while(*str) { if(*str == old_char) *str = new_char; str++; } }
(1)检索指定字符i,并把它替换成*
(2)可以
实验5
#include <stdio.h> #define N 80 char *str_trunc(char *str, char x); int main() { char str[N]; char ch; while(printf("输入字符串: "), gets(str) != NULL) { printf("输入一个字符: "); ch = getchar(); printf("截断处理...\n"); str_trunc(str, ch); // 函数调用 printf("截断处理后的字符串: %s\n\n", str); getchar(); } return 0; } char *str_trunc(char *str,char x) { while(*str) { if(*str!=x) { str++; } else { *str='\0'; break; } } return str; }
getchar()可防止在输入字符串后读入空串
实验6
#include <stdio.h> #include <string.h> #define N 5 int check_id(char *str); // 函数声明 int main() { char *pid[N] = {"31010120000721656X", "3301061996X0203301", "53010220051126571", "510104199211197977", "53010220051126133Y"}; int i; for (i = 0; i < N; ++i) if (check_id(pid[i])) // 函数调用 printf("%s\tTrue\n", pid[i]); else printf("%s\tFalse\n", pid[i]); return 0; } int check_id(char *str) { int i; if (strlen(str) != 18) return 0; for (i = 0; i < 17; i++) if (str[i] < '0'||str[i]>'9') return 0; if ((str[17] <= '9' && str[17] >= '0') || str[17] == 'X') return 1; else return 0; }
实验7
#include <stdio.h> #define N 80 void encoder(char *str, int n); // 函数声明 void decoder(char *str, int n); // 函数声明 int main() { char words[N]; int n; printf("输入英文文本: "); gets(words); printf("输入n: "); scanf("%d", &n); printf("编码后的英文文本: "); encoder(words, n); // 函数调用 printf("%s\n", words); printf("对编码后的英文文本解码: "); decoder(words, n); // 函数调用 printf("%s\n", words); return 0; } void encoder(char *str, int n) { while (*str) { if (*str >= 'a' && *str <= 'z') *str = (*str - 'a' + n ) % 26 + 'a'; if (*str >= 'A' && *str <= 'Z') *str = (*str - 'A' + n ) % 26 + 'A'; str++; } } void decoder(char *str, int n) { while (*str) { if (*str >= 'a' && *str <= 'z') *str = (*str - 'a' - n + 26) % 26 + 'a'; if (*str >= 'A' && *str <= 'Z') *str = (*str - 'A' - n + 26) % 26 + 'A'; str++; } }
实验8
#include <stdio.h> int main(int argc, char *argv[]) { int i,j; for(i=1;i<argc;i++) { for(j=1;j<argc-i;j++) { char *tmp; if(strcmp(argv[j],argv[j+1])>0) { tmp=argv[j]; argv[j]=argv[j+1]; argv[j+1]=tmp; } } } for(i = 1; i < argc; ++i) printf("hello, %s\n", argv[i]); return 0; }
浙公网安备 33010602011771号