Linux高性能服务器编程——I/O复用

时间:2022-11-23 17:57:23


IO复用

I/O复用使得程序能同时监听多个文件描述符,通常网络程序在下列情况下需要使用I/O复用技术:

  1. 客户端程序要同时处理多个socket

  2. 客户端程序要同时处理用户输入和网络连接

  3. TCP服务器要同时处理监听socket和连接socket,这是I/O复用使用最多的场合

  4. 服务器要同时处理TCP请求和UDP请求。比如本章将要讨论的会社服务器

  5. 服务器要同时监听多个端口,或者处理多种服务。

I/O复用虽然能同时监听多个文件描述符,但它本身是阻塞的。并且当多个文件描述符同时就绪时,如果不采用额外措施,程序就只能按顺序依次处理其中的每一个文件描述符,这使得服务器程序看起来像是串行工作。如果要实现并发,只能使用多进程或多线程等变成手段。

select系统复用

select系统调用的用途是:在一段指定时间内,监听用户感兴趣的文件描述符上的可读可写和异常等事件。

#include <sys/select.h>

int select(int nfds, fd_set *readfds,fd_set *writefds, fd_set *exceptfds, struct timeval *timeout);

  1. nfds参数指定被监听的文件描述符的总数。通常被设置为select监听的所有文件描述符中的最大值加1,因为文件描述符是从0开始计数的

  2. readfds, writefdsexceptfds参数分别指向可读、可写和异常等事件对应的文件描述符集合。

    fd_set结构体仅包含一个整形数组,高数组的每个元素的每一位标记一个文件描述符。

    可用如下宏来访问fd_set结构体中的位:

    voidFD_CLR(int fd, fd_set *set);

    int  FD_ISSET(int fd, fd_set *set);

    voidFD_SET(int fd, fd_set *set);

        void FD_ZERO(fd_set*set);

  3. timeout参数用来设置select函数的超时时间。它是一个timeval指针,timeval结构体定义如下:

struct timeval {

              long   tv_sec;        /* seconds */

              long   tv_usec;       /* microseconds */

          };

如果给timeout传递NULL,则select将一直阻塞,直到某个文件描述符就绪。

select成功时返回就绪文件描述符的总数,如果在超时时间内没有任何文件描述符就绪返回0,失败返回-1,并设置errno;如果select在等待期间收到信号,则select立即返回-1,并设置errnoEINTR

poll系统调用

poll系统调用和select类似,也是在指定时间内伦旭一定数量的文件描述符,以测试其中是否有就绪。poll原型如下:

#include<poll.h>

int poll(structpollfd *fds, nfds_t nfds, int timeout);

1)fds参数是一个pollfd结构类型的数组,它指定所以我们感兴趣的文件描述符上发生的刻度、可写和异常等时间。其结构定义如下:

struct pollfd {

              int  fd;        /* file descriptor */

              short events;    /* requested events */

              short revents;   /* returned events */

          };

其中fd成员指定文件描述符;events成员告诉poll监听f上的那些时间,它是一系列时间的按位或;revents成员则由内核修改,以通知应用程序fd上实际发生了哪些事件。

2)nfds参数指定被监听事件集合的大小。其类型nfds_t定义如下:

typedef unsignedlong int nfds_t;

  1. timeout参数指定poll的超时时间,单位是毫秒。当timeout-1时,poll调用将永远阻塞,直到某个事件发生;当为0时,poll调用立即返回。

    poll返回值含义与select相同。

epoll系列系统调用

内核事件表

epollLinux特有的I/O复用函数。它在实现和使用上与selectpoll有很大差异。首先,epoll使用一组函数来完成任务,而不是单个函数。其次,epoll把用户关心的文件描述符上的时间放在内核里的一个时间表中,从而无需向selectpoll那样每次调用都要重复传入文件描述符集或事件集。但epoll需要使用一个额外的文件描述符,来唯一标识内核中的这个时间表。这个文件描述符使用如下epoll_create函数创建:

#include <sys/epoll.h>

int epoll_create(int size);

size参数给内核一个提示,告诉它时间表需要多大。该函数返回的文件描述符将作用其他所有epoll系统调用的第一个参数,以指定要访问的内核事件表。

下面的函数用来操作epoll的内核事件表:

#include <sys/epoll.h>

int epoll_ctl(int epfd, int op, int fd,struct epoll_event *event);

fd参数是要操作的文件描述符,op参数则制定操作类型,操作类型有如下3种:

EPOLL_CTL_ADD:往事件表中注册fd上的事件

EPOLL_CTL_MOD:修改fd上的注册事件

EPOLL_CTL_DEL:删除fd上的注册事件

event参数指定时间,它是epoll_event结构指针类型。epoll_event的定义如下:

struct epoll_event {

              uint32_t    events;     /* Epoll events */

              epoll_data_t data;       /* User data variable */

          };

其中events成员描述事件类型。data成员用于存储用户数据,其类型epoll_data的定义如下:

typedef union epoll_data {

              void       *ptr;

              int         fd;

              uint32_t    u32;

              uint64_t    u64;

          } epoll_data_t;

epoll_data_t是一个联合体,其中4个成员中使用最多的是fd,它指定事件所丛书的目标文件描述符。

epoll_ctl成功时返回0,失败时返回-1并设置errno

epoll_wait函数

epoll系列系统调用的主要接口是epoll_wait函数。它在一段超时时间内等待一组文件描述符上的事件,其原型如下:

#include <sys/epoll.h>

int epoll_wait(int epfd, struct epoll_event*events, int maxevents, int timeout);

该函数成功时返回就绪的文件描述符的个数,失败是返回-1,并设置errno

maxevents参数指定最多监听多少时间,必须大于0.

epoll_wait函数如果检测到事件,就将所有就绪的事件从内核事件表中复制到它的第二个参数events指向的数组中。这个数组只用于输出epoll_wait检测到的就绪时间,而不像selectpoll数组那样即用于传入用户注册的时间,有用于输出内核检测到的就绪时间。这就极大的提高了应用程序索引就绪文件描述符的效率。下面的代码体现了这个差别:

/*如何索引poll返回的就绪文件描述符*/

int ret = poll(fds, MAX_EVENT_NUMBER, -1);

/*必须遍历所有注册文件描述符并找到其中的就绪着*/

for(int i=0;i<MAX_EVENT_NUMBER; ++i)

{

        if(fds[i].revents & POLLIN)

{

        int sockfd = fds[i].fd;

        /*处理sockfd*/

}

}

 

/*如何索引epoll返回的就绪文件描述符*/

int ret =epoll_wait( epollfd, events, MAX_EVENT_NUMBER, -1);

/*遍历就绪的ret个文件描述符*/

for( int i=0;i<ret; i++)

{

        int socketfd = events[i].data.fd;

        /*socket肯定就绪,直接处理*/

}

 

LTET模式

epoll对文件描述符的操作有两种模式:LT模式(Levek Trigger,电平触发)和ET模式(E多个Trigger,边沿触发)。LT模式是默认的工作模式,这种模式下epoll相当于一个效率较高的poll。当往epoll内核事件表中注册一个文件描述符上的EPOLLET事件时,epoll将以ET模式来操作该文件描述符。ET模式是epoll的搞笑工作模式。

对于采用LT工作模式的文件描述符,当epoll_wait检测到其上有时间发生并将此事件通知应用程序后,应用程序可以不立即处理该事件。这样,当应用程序下一次调用epoll_wait时,epoll_wait还会再次向应用程序通告此事件,直到该事件被处理。而对于采用ET工作模式的文件描述符,当epoll_wait检测到其上有时间发生并将此时间通知应用程序后,应用程序必须立即处理该事件,因为后续的epoll_wait调用将不再向用用程序通知这一事件。可见,ET在很大程度上降低了同一个epoll事件被重复触发的次数,因此效率比LT模式高。

文章最后的程序清单1比较了两种模式:

当在客户端telnet传输“abcdefghijklmnopqrstuvwxyz”字符串时,输出如下

ET模式输出:

event trigger once

get 9 bytes of content: abcdefghi

get 9 bytes of content: jklmnopqr

get 9 bytes of content: stuvwxyz

get 1 bytes of content:

LT模式输出:

event trigger once

get 9 bytes of content: abcdefghi

event trigger once

get 9 bytes of content: jklmnopqr

event trigger once

get 9 bytes of content: stuvwxyz

event trigger once

get 1 bytes of content:

可以看到正如我们预期,ET模式下时间只被触发一次,要比LT模式下少很多。

EPOLLONESHOT事件

即使我们使用ET模式,一个socket上的某个事件还是可能被触发多次。这在并发程序中会引起一个问题。比如一个县城在读取完某个socket上的数据后开始处理这些数据,二在数据的处理工程中该socket上又有新数据可读,此时另外一个县城北唤醒来读取这些新的数据。于是就出现了两个线程同时操作一个socket的局面,这当然不是我们期望的。我们期望的是一个socket连接在任一时刻都只被一个线程处理,这一点可以使用spollEPOLLONESHOT事件实现。

        对于注册了EPOLLONESHOT事件的文件描述符,操作系统最多触发其上注册的一个可读、可写或者异常事件,而且只触发一次,除非我们使用epoll_ctl函数重置该文件描述符上注册的EPOLLONESHOT事件ain.zheyang,当一个线程在处理某个socket时,其他线程是不可能有机会操作该socket的。但反过来思考,注册了EPOLLONESHOT事件的socket一旦被某个线程处理完毕,该线程就应该立即重置这个socket上的EPOLLONESHOT事件,以确保这个socket下一次可读时,其EPOLLIN事件能被触发,进而让其他工作线程有机会处理这个socket

程序清单2展示了EPOLLONESHOT事件的使用。

三组I/O复用函数的比较

系统调用

select

poll

epoll

事件集合

用户通过3个参数分别传入感兴趣的可读、可写及异常等事件,内核通过对这些参数在线修改来反馈其中的就绪事件。这使得用户每次调用select都要重置这3个参数

统一处理所有事件类型,因此只需要一个事件集参数。用户通过pollfd.events传入感兴趣的事件,内核通过修改pollfd.revents反馈其中就绪的事件

内核通过一个时间表直接管理用户感兴趣的所有事件。因此每次调用epoll_wait时,无需反复传入用户感兴趣的时间。epoll_wait系统调用的参数events仅用来反馈就绪的事件。

应用程序索引就绪文件描述符的时间复杂度

O(N)

O(N)

O(1)

最大支持文件描述符数

一般有最大值限制

65535

65535

工作模式

LT

LT

支持ET高效模式

内核实现和工作效率

采用轮询方法来检测就绪事件,算法复杂度为O(N)

采用轮询方式检测就绪事件,算法复杂度为O(N)

采用回调方式来检测就绪事件,算法复杂度为O(1)

 

聊天程序见程序(poll实现)见清单3

同时处理TCPUDP服务的回射服务器程序(epoll程序)见清单4



程序清单1:
#include <sys/types.h>
#include <sys/socket.h>
#include <netinet/in.h>
#include <arpa/inet.h>
#include <assert.h>
#include <stdio.h>
#include <unistd.h>
#include <errno.h>
#include <string.h>
#include <fcntl.h>
#include <stdlib.h>
#include <sys/epoll.h>
#include <pthread.h>

#define MAX_EVENT_NUMBER 1024
#define BUFFER_SIZE 10

int setnonblocking( int fd )
{
int old_option = fcntl( fd, F_GETFL );
int new_option = old_option | O_NONBLOCK;
fcntl( fd, F_SETFL, new_option );
return old_option;
}

void addfd( int epollfd, int fd, bool enable_et )
{
epoll_event event;
event.data.fd = fd;
event.events = EPOLLIN;
if( enable_et )
{
event.events |= EPOLLET;
}
epoll_ctl( epollfd, EPOLL_CTL_ADD, fd, &event );
setnonblocking( fd );
}

void lt( epoll_event* events, int number, int epollfd, int listenfd )
{
char buf[ BUFFER_SIZE ];
for ( int i = 0; i < number; i++ )
{
int sockfd = events[i].data.fd;
if ( sockfd == listenfd )
{
struct sockaddr_in client_address;
socklen_t client_addrlength = sizeof( client_address );
int connfd = accept( listenfd, ( struct sockaddr* )&client_address, &client_addrlength );
addfd( epollfd, connfd, false );
}
else if ( events[i].events & EPOLLIN )
{
printf( "event trigger once\n" );
memset( buf, '\0', BUFFER_SIZE );
int ret = recv( sockfd, buf, BUFFER_SIZE-1, 0 );
if( ret <= 0 )
{
close( sockfd );
continue;
}
printf( "get %d bytes of content: %s\n", ret, buf );
}
else
{
printf( "something else happened \n" );
}
}
}

void et( epoll_event* events, int number, int epollfd, int listenfd )
{
char buf[ BUFFER_SIZE ];
for ( int i = 0; i < number; i++ )
{
int sockfd = events[i].data.fd;
if ( sockfd == listenfd )
{
struct sockaddr_in client_address;
socklen_t client_addrlength = sizeof( client_address );
int connfd = accept( listenfd, ( struct sockaddr* )&client_address, &client_addrlength );
addfd( epollfd, connfd, true );
}
else if ( events[i].events & EPOLLIN )
{
printf( "event trigger once\n" );
while( 1 )
{
memset( buf, '\0', BUFFER_SIZE );
int ret = recv( sockfd, buf, BUFFER_SIZE-1, 0 );
if( ret < 0 )
{
if( ( errno == EAGAIN ) || ( errno == EWOULDBLOCK ) )
{
printf( "read later\n" );
break;
}
close( sockfd );
break;
}
else if( ret == 0 )
{
close( sockfd );
}
else
{
printf( "get %d bytes of content: %s\n", ret, buf );
}
}
}
else
{
printf( "something else happened \n" );
}
}
}

int main( int argc, char* argv[] )
{
if( argc <= 2 )
{
printf( "usage: %s ip_address port_number\n", basename( argv[0] ) );
return 1;
}
const char* ip = argv[1];
int port = atoi( argv[2] );

int ret = 0;
struct sockaddr_in address;
bzero( &address, sizeof( address ) );
address.sin_family = AF_INET;
inet_pton( AF_INET, ip, &address.sin_addr );
address.sin_port = htons( port );

int listenfd = socket( PF_INET, SOCK_STREAM, 0 );
assert( listenfd >= 0 );

ret = bind( listenfd, ( struct sockaddr* )&address, sizeof( address ) );
assert( ret != -1 );

ret = listen( listenfd, 5 );
assert( ret != -1 );

epoll_event events[ MAX_EVENT_NUMBER ];
int epollfd = epoll_create( 5 );
assert( epollfd != -1 );
addfd( epollfd, listenfd, true );

while( 1 )
{
int ret = epoll_wait( epollfd, events, MAX_EVENT_NUMBER, -1 );
if ( ret < 0 )
{
printf( "epoll failure\n" );
break;
}

lt( events, ret, epollfd, listenfd );
//et( events, ret, epollfd, listenfd );
}

close( listenfd );
return 0;
}
程序清单2#include <sys/types.h>#include <sys/socket.h>#include <netinet/in.h>#include <arpa/inet.h>#include <assert.h>#include <stdio.h>#include <unistd.h>#include <errno.h>#include <string.h>#include <fcntl.h>#include <stdlib.h>#include <sys/epoll.h>#include <pthread.h>#define MAX_EVENT_NUMBER 1024#define BUFFER_SIZE 1024struct fds{   int epollfd;   int sockfd;};int setnonblocking( int fd ){    int old_option = fcntl( fd, F_GETFL );    int new_option = old_option | O_NONBLOCK;    fcntl( fd, F_SETFL, new_option );    return old_option;}void addfd( int epollfd, int fd, bool oneshot ){    epoll_event event;    event.data.fd = fd;    event.events = EPOLLIN | EPOLLET;    if( oneshot )    {        event.events |= EPOLLONESHOT;    }    epoll_ctl( epollfd, EPOLL_CTL_ADD, fd, &event );    setnonblocking( fd );}void reset_oneshot( int epollfd, int fd ){    epoll_event event;    event.data.fd = fd;    event.events = EPOLLIN | EPOLLET | EPOLLONESHOT;    epoll_ctl( epollfd, EPOLL_CTL_MOD, fd, &event );}void* worker( void* arg ){    int sockfd = ( (fds*)arg )->sockfd;    int epollfd = ( (fds*)arg )->epollfd;    printf( "start new thread to receive data on fd: %d\n", sockfd );    char buf[ BUFFER_SIZE ];    memset( buf, '\0', BUFFER_SIZE );    while( 1 )    {        int ret = recv( sockfd, buf, BUFFER_SIZE-1, 0 );        if( ret == 0 )        {            close( sockfd );            printf( "foreiner closed the connection\n" );            break;        }        else if( ret < 0 )        {            if( errno == EAGAIN )            {                reset_oneshot( epollfd, sockfd );                printf( "read later\n" );                break;            }        }        else        {            printf( "get content: %s\n", buf );            sleep( 5 );        }    }    printf( "end thread receiving data on fd: %d\n", sockfd );}int main( int argc, char* argv[] ){    if( argc <= 2 )    {        printf( "usage: %s ip_address port_number\n", basename( argv[0] ) );        return 1;    }    const char* ip = argv[1];    int port = atoi( argv[2] );    int ret = 0;    struct sockaddr_in address;    bzero( &address, sizeof( address ) );    address.sin_family = AF_INET;    inet_pton( AF_INET, ip, &address.sin_addr );    address.sin_port = htons( port );    int listenfd = socket( PF_INET, SOCK_STREAM, 0 );    assert( listenfd >= 0 );    ret = bind( listenfd, ( struct sockaddr* )&address, sizeof( address ) );    assert( ret != -1 );    ret = listen( listenfd, 5 );    assert( ret != -1 );    epoll_event events[ MAX_EVENT_NUMBER ];    int epollfd = epoll_create( 5 );    assert( epollfd != -1 );    addfd( epollfd, listenfd, false );    while( 1 )    {        int ret = epoll_wait( epollfd, events, MAX_EVENT_NUMBER, -1 );        if ( ret < 0 )        {            printf( "epoll failure\n" );            break;        }            for ( int i = 0; i < ret; i++ )        {            int sockfd = events[i].data.fd;            if ( sockfd == listenfd )            {                struct sockaddr_in client_address;                socklen_t client_addrlength = sizeof( client_address );                int connfd = accept( listenfd, ( struct sockaddr* )&client_address, &client_addrlength );                addfd( epollfd, connfd, true );            }            else if ( events[i].events & EPOLLIN )            {                pthread_t thread;                fds fds_for_new_worker;                fds_for_new_worker.epollfd = epollfd;                fds_for_new_worker.sockfd = sockfd;                pthread_create( &thread, NULL, worker, ( void* )&fds_for_new_worker );            }            else            {                printf( "something else happened \n" );            }        }    }    close( listenfd );    return 0;}

程序清单3
客户端程序
#define _GNU_SOURCE 1
#include <sys/types.h>
#include <sys/socket.h>
#include <netinet/in.h>
#include <arpa/inet.h>
#include <assert.h>
#include <stdio.h>
#include <unistd.h>
#include <string.h>
#include <stdlib.h>
#include <poll.h>
#include <fcntl.h>

#define BUFFER_SIZE 64

int main( int argc, char* argv[] )
{
if( argc <= 2 )
{
printf( "usage: %s ip_address port_number\n", basename( argv[0] ) );
return 1;
}
const char* ip = argv[1];
int port = atoi( argv[2] );

struct sockaddr_in server_address;
bzero( &server_address, sizeof( server_address ) );
server_address.sin_family = AF_INET;
inet_pton( AF_INET, ip, &server_address.sin_addr );
server_address.sin_port = htons( port );

int sockfd = socket( PF_INET, SOCK_STREAM, 0 );
assert( sockfd >= 0 );
if ( connect( sockfd, ( struct sockaddr* )&server_address, sizeof( server_address ) ) < 0 )
{
printf( "connection failed\n" );
close( sockfd );
return 1;
}

pollfd fds[2];
fds[0].fd = 0;
fds[0].events = POLLIN;
fds[0].revents = 0;
fds[1].fd = sockfd;
fds[1].events = POLLIN | POLLRDHUP;
fds[1].revents = 0;
char read_buf[BUFFER_SIZE];
int pipefd[2];
int ret = pipe( pipefd );
assert( ret != -1 );

while( 1 )
{
ret = poll( fds, 2, -1 );
if( ret < 0 )
{
printf( "poll failure\n" );
break;
}

if( fds[1].revents & POLLRDHUP )
{
printf( "server close the connection\n" );
break;
}
else if( fds[1].revents & POLLIN )
{
memset( read_buf, '\0', BUFFER_SIZE );
recv( fds[1].fd, read_buf, BUFFER_SIZE-1, 0 );
printf( "%s\n", read_buf );
}

if( fds[0].revents & POLLIN )
{
ret = splice( 0, NULL, pipefd[1], NULL, 32768, SPLICE_F_MORE | SPLICE_F_MOVE );
ret = splice( pipefd[0], NULL, sockfd, NULL, 32768, SPLICE_F_MORE | SPLICE_F_MOVE );
}
}

close( sockfd );
return 0;
}

服务器程序
#define _GNU_SOURCE 1
#include <sys/types.h>
#include <sys/socket.h>
#include <netinet/in.h>
#include <arpa/inet.h>
#include <assert.h>
#include <stdio.h>
#include <unistd.h>
#include <errno.h>
#include <string.h>
#include <fcntl.h>
#include <stdlib.h>
#include <poll.h>

#define USER_LIMIT 5
#define BUFFER_SIZE 64
#define FD_LIMIT 65535

struct client_data
{
sockaddr_in address;
char* write_buf;
char buf[ BUFFER_SIZE ];
};

int setnonblocking( int fd )
{
int old_option = fcntl( fd, F_GETFL );
int new_option = old_option | O_NONBLOCK;
fcntl( fd, F_SETFL, new_option );
return old_option;
}

int main( int argc, char* argv[] )
{
if( argc <= 2 )
{
printf( "usage: %s ip_address port_number\n", basename( argv[0] ) );
return 1;
}
const char* ip = argv[1];
int port = atoi( argv[2] );

int ret = 0;
struct sockaddr_in address;
bzero( &address, sizeof( address ) );
address.sin_family = AF_INET;
inet_pton( AF_INET, ip, &address.sin_addr );
address.sin_port = htons( port );

int listenfd = socket( PF_INET, SOCK_STREAM, 0 );
assert( listenfd >= 0 );

ret = bind( listenfd, ( struct sockaddr* )&address, sizeof( address ) );
assert( ret != -1 );

ret = listen( listenfd, 5 );
assert( ret != -1 );

client_data* users = new client_data[FD_LIMIT];
pollfd fds[USER_LIMIT+1];
int user_counter = 0;
for( int i = 1; i <= USER_LIMIT; ++i )
{
fds[i].fd = -1;
fds[i].events = 0;
}
fds[0].fd = listenfd;
fds[0].events = POLLIN | POLLERR;
fds[0].revents = 0;

while( 1 )
{
ret = poll( fds, user_counter+1, -1 );
if ( ret < 0 )
{
printf( "poll failure\n" );
break;
}

for( int i = 0; i < user_counter+1; ++i )
{
if( ( fds[i].fd == listenfd ) && ( fds[i].revents & POLLIN ) )
{
struct sockaddr_in client_address;
socklen_t client_addrlength = sizeof( client_address );
int connfd = accept( listenfd, ( struct sockaddr* )&client_address, &client_addrlength );
if ( connfd < 0 )
{
printf( "errno is: %d\n", errno );
continue;
}
if( user_counter >= USER_LIMIT )
{
const char* info = "too many users\n";
printf( "%s", info );
send( connfd, info, strlen( info ), 0 );
close( connfd );
continue;
}
user_counter++;
users[connfd].address = client_address;
setnonblocking( connfd );
fds[user_counter].fd = connfd;
fds[user_counter].events = POLLIN | POLLRDHUP | POLLERR;
fds[user_counter].revents = 0;
printf( "comes a new user, now have %d users\n", user_counter );
}
else if( fds[i].revents & POLLERR )
{
printf( "get an error from %d\n", fds[i].fd );
char errors[ 100 ];
memset( errors, '\0', 100 );
socklen_t length = sizeof( errors );
if( getsockopt( fds[i].fd, SOL_SOCKET, SO_ERROR, &errors, &length ) < 0 )
{
printf( "get socket option failed\n" );
}
continue;
}
else if( fds[i].revents & POLLRDHUP )
{
users[fds[i].fd] = users[fds[user_counter].fd];
close( fds[i].fd );
fds[i] = fds[user_counter];
i--;
user_counter--;
printf( "a client left\n" );
}
else if( fds[i].revents & POLLIN )
{
int connfd = fds[i].fd;
memset( users[connfd].buf, '\0', BUFFER_SIZE );
ret = recv( connfd, users[connfd].buf, BUFFER_SIZE-1, 0 );
printf( "get %d bytes of client data %s from %d\n", ret, users[connfd].buf, connfd );
if( ret < 0 )
{
if( errno != EAGAIN )
{
close( connfd );
users[fds[i].fd] = users[fds[user_counter].fd];
fds[i] = fds[user_counter];
i--;
user_counter--;
}
}
else if( ret == 0 )
{
printf( "code should not come to here\n" );
}
else
{
for( int j = 1; j <= user_counter; ++j )
{
if( fds[j].fd == connfd )
{
continue;
}

fds[j].events |= ~POLLIN;
fds[j].events |= POLLOUT;
users[fds[j].fd].write_buf = users[connfd].buf;
}
}
}
else if( fds[i].revents & POLLOUT )
{
int connfd = fds[i].fd;
if( ! users[connfd].write_buf )
{
continue;
}
ret = send( connfd, users[connfd].write_buf, strlen( users[connfd].write_buf ), 0 );
users[connfd].write_buf = NULL;
fds[i].events |= ~POLLOUT;
fds[i].events |= POLLIN;
}
}
}

delete [] users;
close( listenfd );
return 0;
}
程序清单4 回射服务器程序#include <sys/types.h>#include <sys/socket.h>#include <netinet/in.h>#include <arpa/inet.h>#include <assert.h>#include <stdio.h>#include <unistd.h>#include <errno.h>#include <string.h>#include <fcntl.h>#include <stdlib.h>#include <sys/epoll.h>#include <pthread.h>#define MAX_EVENT_NUMBER 1024#define TCP_BUFFER_SIZE 512#define UDP_BUFFER_SIZE 1024int setnonblocking( int fd ){    int old_option = fcntl( fd, F_GETFL );    int new_option = old_option | O_NONBLOCK;    fcntl( fd, F_SETFL, new_option );    return old_option;}void addfd( int epollfd, int fd ){    epoll_event event;    event.data.fd = fd;    //event.events = EPOLLIN | EPOLLET;    event.events = EPOLLIN;    epoll_ctl( epollfd, EPOLL_CTL_ADD, fd, &event );    setnonblocking( fd );}int main( int argc, char* argv[] ){    if( argc <= 2 )    {        printf( "usage: %s ip_address port_number\n", basename( argv[0] ) );        return 1;    }    const char* ip = argv[1];    int port = atoi( argv[2] );    int ret = 0;    struct sockaddr_in address;    bzero( &address, sizeof( address ) );    address.sin_family = AF_INET;    inet_pton( AF_INET, ip, &address.sin_addr );    address.sin_port = htons( port );    int listenfd = socket( PF_INET, SOCK_STREAM, 0 );    assert( listenfd >= 0 );    ret = bind( listenfd, ( struct sockaddr* )&address, sizeof( address ) );    assert( ret != -1 );    ret = listen( listenfd, 5 );    assert( ret != -1 );    bzero( &address, sizeof( address ) );    address.sin_family = AF_INET;    inet_pton( AF_INET, ip, &address.sin_addr );    address.sin_port = htons( port );    int udpfd = socket( PF_INET, SOCK_DGRAM, 0 );    assert( udpfd >= 0 );    ret = bind( udpfd, ( struct sockaddr* )&address, sizeof( address ) );    assert( ret != -1 );    epoll_event events[ MAX_EVENT_NUMBER ];    int epollfd = epoll_create( 5 );    assert( epollfd != -1 );    addfd( epollfd, listenfd );    addfd( epollfd, udpfd );    while( 1 )    {        int number = epoll_wait( epollfd, events, MAX_EVENT_NUMBER, -1 );        if ( number < 0 )        {            printf( "epoll failure\n" );            break;        }            for ( int i = 0; i < number; i++ )        {            int sockfd = events[i].data.fd;            if ( sockfd == listenfd )            {                struct sockaddr_in client_address;                socklen_t client_addrlength = sizeof( client_address );                int connfd = accept( listenfd, ( struct sockaddr* )&client_address, &client_addrlength );                addfd( epollfd, connfd );            }            else if ( sockfd == udpfd )            {                char buf[ UDP_BUFFER_SIZE ];                memset( buf, '\0', UDP_BUFFER_SIZE );                struct sockaddr_in client_address;                socklen_t client_addrlength = sizeof( client_address );                ret = recvfrom( udpfd, buf, UDP_BUFFER_SIZE-1, 0, ( struct sockaddr* )&client_address, &client_addrlength );                if( ret > 0 )                {                    sendto( udpfd, buf, UDP_BUFFER_SIZE-1, 0, ( struct sockaddr* )&client_address, client_addrlength );                }            }            else if ( events[i].events & EPOLLIN )            {                char buf[ TCP_BUFFER_SIZE ];                while( 1 )                {                    memset( buf, '\0', TCP_BUFFER_SIZE );                    ret = recv( sockfd, buf, TCP_BUFFER_SIZE-1, 0 );                    if( ret < 0 )                    {                        if( ( errno == EAGAIN ) || ( errno == EWOULDBLOCK ) )                        {                            break;                        }                        close( sockfd );                        break;                    }                    else if( ret == 0 )                    {                        close( sockfd );                    }                    else                    {                        send( sockfd, buf, ret, 0 );                    }                }            }            else            {                printf( "something else happened \n" );            }        }    }    close( listenfd );    return 0;}