2019-2020-1 20175335 20175303 20175304 20275327 实验三 并发程序
小组成员:
20175335、20175303、20175304、20175327
实验目的:
并发程序
一、实验三-并发程序-1
学习使用Linux命令wc(1)
基于Linux Socket程序设计实现wc(1)服务器(端口号是你学号的后6位)和客户端
客户端传一个文本文件给服务器
服务器返加文本文件中的单词数
实验过程
wc功能:统计指定文件中的字节数、字数、行数,并将统计结果显示输出。
wc参数:
-c 统计字节数。
-l 统计行数。
-m 统计字符数。
-w 统计字数。
-L 打印最长行的长度。
socket编程模型:
实验代码如下:
server.c服务器
#include// sockaddr_in #include // socket #include // socket #include // printf #include // exit #include // bzero #define SERVER_PORT 175335 #define LENGTH_OF_LISTEN_QUEUE 20 #define BUFFER_SIZE 1024 #define FILE_NAME_MAX_SIZE 512 int main(void) { struct sockaddr_in server_addr; bzero(&server_addr, sizeof(server_addr)); server_addr.sin_family = AF_INET; server_addr.sin_addr.s_addr = htons(INADDR_ANY); server_addr.sin_port = htons(SERVER_PORT); int server_socket_fd = socket(PF_INET, SOCK_STREAM, 0); if(server_socket_fd < 0) { perror("Create Socket Failed:"); exit(1); } int opt = 1; setsockopt(server_socket_fd, SOL_SOCKET, SO_REUSEADDR, &opt, sizeof(opt)); if(-1 == (bind(server_socket_fd, (struct sockaddr*)&server_addr, sizeof(server_addr)))) { perror("Server Bind Failed:"); exit(1); } if(-1 == (listen(server_socket_fd, LENGTH_OF_LISTEN_QUEUE))) { perror("Server Listen Failed:"); exit(1); } while(1) { struct sockaddr_in client_addr; socklen_t client_addr_length = sizeof(client_addr); int new_server_socket_fd = accept(server_socket_fd, (struct sockaddr*)&client_addr, &client_addr_length); if(new_server_socket_fd < 0) { perror("Server Accept Failed:"); break; } char buffer[BUFFER_SIZE]; bzero(buffer, BUFFER_SIZE); if(recv(new_server_socket_fd, buffer, BUFFER_SIZE, 0) < 0) { perror("Server Recieve Data Failed:"); break; } char file_name[FILE_NAME_MAX_SIZE+1]; bzero(file_name, FILE_NAME_MAX_SIZE+1); strncpy(file_name, buffer, strlen(buffer)>FILE_NAME_MAX_SIZE?FILE_NAME_MAX_SIZE:strlen(buffer)); printf("%s\n", file_name); FILE *fp = fopen(file_name, "w"); if(NULL == fp) { printf("File:\t%s Can Not Open To Write\n", file_name); exit(1); } bzero(buffer, BUFFER_SIZE); int length = 0; while((length = recv(new_server_socket_fd, buffer, BUFFER_SIZE, 0)) > 0) { if(strcmp(buffer,"OK")==0) break; if(fwrite(buffer, sizeof(char), length, fp) < length) { printf("File:\t%s Write Failed\n", file_name); break; } bzero(buffer, BUFFER_SIZE); } printf("\t%s 接收成功\n", file_name); fclose(fp); int words=0; char s[100]; FILE *fp2; if((fp2=fopen(file_name,"r"))==NULL){ printf("文件打开失败!\n"); exit(0); } while(fscanf(fp2,"%s",s)!=EOF) words++; fclose(fp2); sprintf(buffer,"%d",words); send(new_server_socket_fd,buffer,BUFFER_SIZE,0); close(new_server_socket_fd); } close(server_socket_fd); return 0; }
client.c客户端
#include// sockaddr_in #include // socket #include // socket #include // printf #include // exit #include // bzero #define SERVER_PORT 175335 #define BUFFER_SIZE 1024 #define FILE_NAME_MAX_SIZE 512 int main() { // 声明并初始化一个客户端的socket地址结构 struct sockaddr_in client_addr; bzero(&client_addr, sizeof(client_addr)); client_addr.sin_family = AF_INET; client_addr.sin_addr.s_addr = htons(INADDR_ANY); client_addr.sin_port = htons(0); // 创建socket,若成功,返回socket描述符 int client_socket_fd = socket(AF_INET, SOCK_STREAM, 0); if(client_socket_fd < 0) { perror("Create Socket Failed:"); exit(1); } // 绑定客户端的socket和客户端的socket地址结构 非必需 if(-1 == (bind(client_socket_fd, (struct sockaddr*)&client_addr, sizeof(client_addr)))) { perror("Client Bind Failed:"); exit(1); } // 声明一个服务器端的socket地址结构,并用服务器那边的IP地址及端口对其进行初始化,用于后面的连接 struct sockaddr_in server_addr; bzero(&server_addr, sizeof(server_addr)); server_addr.sin_family = AF_INET; if(inet_pton(AF_INET, "127.0.0.1", &server_addr.sin_addr) == 0) { perror("Server IP Address Error:"); exit(1); } server_addr.sin_port = htons(SERVER_PORT); socklen_t server_addr_length = sizeof(server_addr); // 向服务器发起连接,连接成功后client_socket_fd代表了客户端和服务器的一个socket连接 if(connect(client_socket_fd, (struct sockaddr*)&server_addr, server_addr_length) < 0) { perror("Can Not Connect To Server IP:"); exit(0); } // 输入文件名,并放到缓冲区buffer中等待发送 char file_name[FILE_NAME_MAX_SIZE+1]; bzero(file_name, FILE_NAME_MAX_SIZE+1); printf("请输入文件名:"); scanf("%s", file_name); char buffer[BUFFER_SIZE]; bzero(buffer, BUFFER_SIZE); strncpy(buffer, file_name, strlen(file_name)>BUFFER_SIZE?BUFFER_SIZE:strlen(file_name)); // 向服务器发送buffer中的数据 if(send(client_socket_fd, buffer, BUFFER_SIZE, 0) < 0) { perror("Send File Name Failed:"); exit(1); } // 打开文件并读取文件数据 FILE *fp = fopen(file_name, "r"); if(NULL == fp) { printf("File:%s Not Found\n", file_name); } else { bzero(buffer, BUFFER_SIZE); int length = 0; // 每读取一段数据,便将其发送给服务器,循环直到文件读完为止 while((length = fread(buffer, sizeof(char), BUFFER_SIZE, fp)) > 0) { if(send(client_socket_fd, buffer, length, 0) < 0) { printf("Send File:%s Failed./n", file_name); break; } bzero(buffer, BUFFER_SIZE); } // 关闭文件 fclose(fp); printf("%s 传输成功\n", file_name); char s[50]; scanf("%s",s); send(client_socket_fd,"OK",BUFFER_SIZE,0); recv(client_socket_fd,buffer,BUFFER_SIZE,0); printf("%d %s\n",atoi(buffer),file_name); } close(client_socket_fd); return 0; }
实验结果如下:
二、实验三-并发程序-2
实验内容及要求:
使用多线程实现wc服务器并使用同步互斥机制保证计数正确
上方提交代码
下方提交测试
对比单线程版本的性能,并分析原因。
实验过程:
多线程的优点:
(1)多线程技术使程序的响应速度更快 ,因为用户界面可以在进行其它工作的同时一直处于活动状态;
(2)当前没有进行处理的任务时可以将处理器时间让给其它任务;
(3)占用大量处理时间的任务可以定期将处理器时间让给其它任务;
(4)可以随时停止任务;
(5)可以分别设置各个任务的优先级以优化性能。
(6)多线程一定程度上提高响应速度,在多核的情况下更能充分利用CPU资源。
实验结果:
thread_client.c
#include#include #include //pthread_t , pthread_attr_t and so on. #include #include //structure sockaddr_in #include //Func : htonl; htons; ntohl; ntohs #include //Func :assert #include //Func :memset bzero #include //Func :close,write,read #define SOCK_PORT 9988 #define BUFFER_LENGTH 1024 int main() { int sockfd; int tempfd; struct sockaddr_in s_addr_in; char data_send[BUFFER_LENGTH]; char data_recv[BUFFER_LENGTH]; memset(data_send,0,BUFFER_LENGTH); memset(data_recv,0,BUFFER_LENGTH); sockfd = socket(AF_INET,SOCK_STREAM,0); //ipv4,TCP if(sockfd == -1) { fprintf(stderr,"socket error!\n"); exit(1); } //before func connect, set the attr of structure sockaddr. memset(&s_addr_in,0,sizeof(s_addr_in)); s_addr_in.sin_addr.s_addr = inet_addr("127.0.0.1"); //trans char * to in_addr_t s_addr_in.sin_family = AF_INET; s_addr_in.sin_port = htons(SOCK_PORT); tempfd = connect(sockfd,(struct sockaddr *)(&s_addr_in),sizeof(s_addr_in)); if(tempfd == -1) { fprintf(stderr,"Connect error! \n"); exit(1); } while(1) { printf("Please Input File Name On Server(input \"quit\" to quit):\t"); scanf("%s", data_send); //gets(data_send); //scanf("%[^\n]",data_send); //or you can also use this tempfd = write(sockfd,data_send,BUFFER_LENGTH); if(tempfd == -1) { fprintf(stderr,"write error\n"); exit(0); } if(strcmp(data_send,"quit") == 0) //quit,write the quit request and shutdown client { break; } else { tempfd = read(sockfd,data_recv,BUFFER_LENGTH); assert(tempfd != -1); printf("%s\n",data_recv); memset(data_send,0,BUFFER_LENGTH); memset(data_recv,0,BUFFER_LENGTH); } char buffer[BUFFER_LENGTH]; int length=0; bzero(buffer, BUFFER_LENGTH); length = recv(sockfd, buffer, BUFFER_LENGTH, 0); buffer[length] = '\0'; printf("count=%s\n", buffer); bzero(buffer, BUFFER_LENGTH); } int ret = shutdown(sockfd,SHUT_WR); //or you can use func close()-- to close the fd assert(ret != -1); return 0; }
thread_server.c
#include#include #include #include //pthread_t , pthread_attr_t and so on. #include #include //structure sockaddr_in #include //Func : htonl; htons; ntohl; ntohs #include //Func :assert #include //Func :memset bzero #include //Func :close,write,read #define SOCK_PORT 9988 #define BUFFER_LENGTH 1024 #define MAX_CONN_LIMIT 512 //MAX connection limit static void Data_handle(void * sock_fd); //Only can be seen in the file int CountWordsOfEuropeanTxtFile(char *szFileName); int CountWordsInOneLine(const char *szLine); int main() { int sockfd_server; int sockfd; int fd_temp; struct sockaddr_in s_addr_in; struct sockaddr_in s_addr_client; int client_length; sockfd_server = socket(AF_INET,SOCK_STREAM,0); //ipv4,TCP assert(sockfd_server != -1); //before bind(), set the attr of structure sockaddr. memset(&s_addr_in,0,sizeof(s_addr_in)); s_addr_in.sin_family = AF_INET; s_addr_in.sin_addr.s_addr = htonl(INADDR_ANY); //trans addr from uint32_t host byte order to network byte order. s_addr_in.sin_port = htons(SOCK_PORT); //trans port from uint16_t host byte order to network byte order. fd_temp = bind(sockfd_server,(const struct sockaddr *)(&s_addr_in),sizeof(s_addr_in)); if(fd_temp == -1) { fprintf(stderr,"bind error!\n"); exit(1); } fd_temp = listen(sockfd_server,MAX_CONN_LIMIT); if(fd_temp == -1) { fprintf(stderr,"listen error!\n"); exit(1); } while(1) { printf("waiting for new connection...\n"); pthread_t thread_id; client_length = sizeof(s_addr_client); //Block here. Until server accpets a new connection. sockfd = accept(sockfd_server,(struct sockaddr * restrict)(&s_addr_client),(socklen_t *)(&client_length)); if(sockfd == -1) { fprintf(stderr,"Accept error!\n"); continue; //ignore current socket ,continue while loop. } printf("A new connection occurs!\n"); if(pthread_create(&thread_id,NULL,(void *)(&Data_handle),(void *)(&sockfd)) == -1) { fprintf(stderr,"pthread_create error!\n"); break; //break while loop } } //Clear int ret = shutdown(sockfd_server,SHUT_WR); //shut down the all or part of a full-duplex connection. assert(ret != -1); printf("Server shuts down\n"); return 0; } static void Data_handle(void * sock_fd) { int fd = *((int *)sock_fd); int i_recvBytes; char data_recv[BUFFER_LENGTH]; const char * data_send = "Server has received your request!\n"; while(1) { printf("waiting for file_name...\n"); //Reset data. memset(data_recv,0,BUFFER_LENGTH); i_recvBytes = read(fd,data_recv,BUFFER_LENGTH); if(i_recvBytes == 0) { printf("Maybe the client has closed\n"); break; } if(i_recvBytes == -1) { fprintf(stderr,"read error!\n"); break; } if(strcmp(data_recv,"quit")==0) { printf("Quit command!\n"); break; //Break the while loop. } printf("read from client : %s\n",data_recv); char buffer[BUFFER_LENGTH]; int count=0; bzero(buffer, BUFFER_LENGTH); count = CountWordsOfEuropeanTxtFile(data_recv); sprintf(buffer,"%d", count); send(fd, buffer, sizeof(buffer), 0); if(write(fd,data_send,strlen(data_send)) == -1) { break; } } //Clear printf("terminating current client_connection...\n"); close(fd); //close a file descriptor. pthread_exit(NULL); //terminate calling thread! } int CountWordsOfEuropeanTxtFile(char *szFileName) { int nWords = 0;//词计数变量,初始值为0 FILE *fp; //文件指针 char carrBuffer[1024];//每行字符缓冲,每行最多1024个字符 //打开文件 if ((fp = fopen(szFileName, "r")) == NULL) { return -1; //文件打开不成功是返回-1 } while (!feof(fp))//如果没有读到文件末尾 { //从文件中读一行 if (fgets(carrBuffer, sizeof(carrBuffer),fp) != NULL) //统计每行词数 nWords += CountWordsInOneLine(carrBuffer); } //关闭文件 fclose(fp); return nWords; } int CountWordsInOneLine(const char *szLine) { int nWords = 0; int i=0; for (;i
实验截图:
三、实验三-并发程序-3
一、实验内容:
1.交叉编译多线程版本服务器并部署到实验箱中
2.PC机作客户端测试wc服务器。
二、实验步骤:
1.参考实验1在Ubuntu中对服务器代码交叉编译。
2.将实验箱与电脑连接好,配置好网络模式并能ping通;
3.打开虚拟机命令行终端,配置/etc/exports;sudo vim /etc/exports
NFS允许挂载的目录及权限在文件/etc/exports
中进行了定义。需要把/home/linux/175204zyz/sy3
目录共享出来,那么我们只需要在/etc/exports
文件末添加如下一行:/home/linux/175204zyz/sy3 *(rw,sync,no_root_squash,no_subtree_check)
保存并推出,随后重启服务:sudo /etc/init.d/nfs-kernel-server restart
4.在超级终端中mount -t nfs -o nolock 192.168.0.230(宿主机IP):/home/linux/175204zyz/sy3
;
5.然后运行程序。
三、实验截图
超级终端:
四、实验里遇到的困难及解决办法:
- 问题1:
Fatal error: stdafx.h : No such file or directory
-
问题1解决办法:建工程自带,将其删除即可;或者是手动添加头文件
- 问题2:
-
问题2 解决办法:pthread并非linux系统默认的库,编译时需要引入pthread,可在编译时加入-lpthread来完成。
- 问题3:在使用超级终端时无法ping通。
- 问题3 的解决办法:1、关闭防火墙和打开本地网络连接。
2、勾选本地连接属性里的VMware Bridge Protocol(百度)。
3、关闭本机的WLAN连接,将虚拟机设置里的网络适配器选择为桥接模式。