daemon:
Linux Daemon(守護(hù)進(jìn)程)是運(yùn)行在后臺(tái)的一種特殊進(jìn)程。它獨(dú)立于控制終端并且周期性地執(zhí)行某種任務(wù)或等待處理某些發(fā)生的事件。它不需要用戶輸入就能運(yùn)行而且提供某種服務(wù),不是對(duì)整個(gè)系統(tǒng)就是對(duì)某個(gè)用戶程序提供服務(wù)。Linux系統(tǒng)的大多數(shù)服務(wù)器就是通過守護(hù)進(jìn)程實(shí)現(xiàn)的。常見的守護(hù)進(jìn)程包括系統(tǒng)日志進(jìn)程syslogd、 web服務(wù)器httpd、郵件服務(wù)器sendmail和數(shù)據(jù)庫服務(wù)器mysqld等。
守護(hù)進(jìn)程一般在系統(tǒng)啟動(dòng)時(shí)開始運(yùn)行,除非強(qiáng)行終止,否則直到系統(tǒng)關(guān)機(jī)都保持運(yùn)行。守護(hù)進(jìn)程經(jīng)常以超級(jí)用戶(root)權(quán)限運(yùn)行,因?yàn)樗鼈円褂锰厥獾亩丝冢?-1024)或訪問某些特殊的資源。
一個(gè)守護(hù)進(jìn)程的父進(jìn)程是init進(jìn)程,因?yàn)樗嬲母高M(jìn)程在fork出子進(jìn)程后就先于子進(jìn)程exit退出了,所以它是一個(gè)由init繼承的孤兒進(jìn)程。守護(hù)進(jìn)程是非交互式程序,沒有控制終端,所以任何輸出,無論是向標(biāo)準(zhǔn)輸出設(shè)備stdout還是標(biāo)準(zhǔn)出錯(cuò)設(shè)備stderr的輸出都需要特殊處理。
守護(hù)進(jìn)程的名稱通常以d結(jié)尾,比如sshd、xinetd、crond等
二,創(chuàng)建守護(hù)進(jìn)程步驟
首先我們要了解一些基本概念:
進(jìn)程組 :
每個(gè)進(jìn)程也屬于一個(gè)進(jìn)程組
每個(gè)進(jìn)程主都有一個(gè)進(jìn)程組號(hào),該號(hào)等于該進(jìn)程組組長(zhǎng)的PID號(hào) .
一個(gè)進(jìn)程只能為它自己或子進(jìn)程設(shè)置進(jìn)程組ID號(hào)
會(huì)話期:
會(huì)話期(session)是一個(gè)或多個(gè)進(jìn)程組的集合。
setsid()函數(shù)可以建立一個(gè)對(duì)話期:
如果,調(diào)用setsid的進(jìn)程不是一個(gè)進(jìn)程組的組長(zhǎng),此函數(shù)創(chuàng)建一個(gè)新的會(huì)話期。
(1)此進(jìn)程變成該對(duì)話期的首進(jìn)程
(2)此進(jìn)程變成一個(gè)新進(jìn)程組的組長(zhǎng)進(jìn)程。
(3)此進(jìn)程沒有控制終端,如果在調(diào)用setsid前,該進(jìn)程有控制終端,那么與該終端的聯(lián)系被解除。 如果該進(jìn)程是一個(gè)進(jìn)程組的組長(zhǎng),此函數(shù)返回錯(cuò)誤。
(4)為了保證這一點(diǎn),我們先調(diào)用fork()然后exit(),此時(shí)只有子進(jìn)程在運(yùn)行
現(xiàn)在我們來給出創(chuàng)建守護(hù)進(jìn)程所需步驟:
編寫守護(hù)進(jìn)程的一般步驟步驟:
(1)在父進(jìn)程中執(zhí)行fork并exit推出;
(2)在子進(jìn)程中調(diào)用setsid函數(shù)創(chuàng)建新的會(huì)話;
(3)在子進(jìn)程中調(diào)用chdir函數(shù),讓根目錄 ”/” 成為子進(jìn)程的工作目錄;
(4)在子進(jìn)程中調(diào)用umask函數(shù),設(shè)置進(jìn)程的umask為0;
(5)在子進(jìn)程中關(guān)閉任何不需要的文件描述符
摘抄于(linux系統(tǒng)編程之進(jìn)程(八):守護(hù)進(jìn)程詳解及創(chuàng)建,daemon()使用)
然后我們來看下nginx的處理
ngx_int_t
ngx_daemon(ngx_log_t *log)
{
int fd;
switch (fork()) {//fork進(jìn)行進(jìn)程創(chuàng)建
case -1://失敗了
ngx_log_error(NGX_LOG_EMERG, log, ngx_errno, "fork() failed");
return NGX_ERROR;
case 0://子進(jìn)程
break;
default://pid>0 代表是父進(jìn)程
exit(0);//調(diào)用exit
}
ngx_pid = ngx_getpid();//重新獲取pid
/*
有必要先介紹一下Linux中的進(jìn)程與控制終端,登錄會(huì)話和進(jìn)程組之間的關(guān)系:進(jìn)程屬于一個(gè)進(jìn)程組,進(jìn)程組號(hào)(GID)就是進(jìn)程組長(zhǎng)的進(jìn)程號(hào)(PID)。
登錄會(huì)話可以包含多個(gè)進(jìn)程組。這些進(jìn)程組共享一個(gè)控制終端。這個(gè)控制終端通常是創(chuàng)建進(jìn)程的登錄終端。 控制終端,登錄會(huì)話和進(jìn)程組通常是從父進(jìn)程繼承下來的。
我們的目的就是要擺脫它們,使之不受它們的影響。調(diào)用setsid()使進(jìn)程成為會(huì)話組長(zhǎng):
setsid()調(diào)用成功后,進(jìn)程成為新的會(huì)話組長(zhǎng)和新的進(jìn)程組長(zhǎng),并與原來的登錄會(huì)話和進(jìn)程組脫離。由于會(huì)話過程對(duì)控制終端的獨(dú)占性,進(jìn)程同時(shí)與控制終端脫離。
*/
if (setsid() == -1) {
ngx_log_error(NGX_LOG_EMERG, log, ngx_errno, "setsid() failed");
return NGX_ERROR;
}
umask(0);//進(jìn)程從創(chuàng)建它的父進(jìn)程那里繼承了文件創(chuàng)建掩模。它可能修改守護(hù)進(jìn)程所創(chuàng)建的文件的存取位。為防止這一點(diǎn),將文件創(chuàng)建掩模清除
fd = open("/dev/null", O_RDWR);
if (fd == -1) {
ngx_log_error(NGX_LOG_EMERG, log, ngx_errno,
"open(\"/dev/null\") failed");
return NGX_ERROR;
}
if (dup2(fd, STDIN_FILENO) == -1) {
ngx_log_error(NGX_LOG_EMERG, log, ngx_errno, "dup2(STDIN) failed");
return NGX_ERROR;
}
if (dup2(fd, STDOUT_FILENO) == -1) {
ngx_log_error(NGX_LOG_EMERG, log, ngx_errno, "dup2(STDOUT) failed");
return NGX_ERROR;
}
#if 0
if (dup2(fd, STDERR_FILENO) == -1) {
ngx_log_error(NGX_LOG_EMERG, log, ngx_errno, "dup2(STDERR) failed");
return NGX_ERROR;
}
#endif
//進(jìn)程從創(chuàng)建它的父進(jìn)程那里繼承了打開的文件描述符。如不關(guān)閉,將會(huì)浪費(fèi)系統(tǒng)資源,造成進(jìn)程所在的文件系統(tǒng)無法卸下以及引起無法預(yù)料的錯(cuò)誤
if (fd > STDERR_FILENO) {
if (close(fd) == -1) {
ngx_log_error(NGX_LOG_EMERG, log, ngx_errno, "close() failed");
return NGX_ERROR;
}
}
return NGX_OK;
}
到此,daemon模式啟動(dòng)完成了
master-worker
master-worker是一個(gè)nginx最常用的運(yùn)行模式來看下master-worker的定義。
- master: master進(jìn)程主要是用來管理worker進(jìn)程,包括接收外界的信號(hào),像worker進(jìn)程發(fā)送信號(hào),監(jiān)控worker進(jìn)程的運(yùn)行狀態(tài),當(dāng)worker進(jìn)程異常退出的時(shí)候,重新啟動(dòng)worker進(jìn)程,mater不進(jìn)行事件處理了。
- worker: 工作進(jìn)程,多個(gè)worker進(jìn)程直接是對(duì)等的,他們同等競(jìng)爭(zhēng)來自客戶端的請(qǐng)求,一個(gè)請(qǐng)求只可能在一個(gè)進(jìn)程被處理,worker進(jìn)程的數(shù)目是可以設(shè)置,一個(gè)設(shè)置得和我們的cpu核心數(shù)一致。
master-worker之間的通信
worker-mater直接的通信實(shí)際上是通過socketpair來構(gòu)造一對(duì)socket來進(jìn)行通信的,master使用第一個(gè)套接字來發(fā)數(shù)據(jù),worker使用第二個(gè)套接字來讀數(shù)據(jù)。
這個(gè)構(gòu)造在創(chuàng)建子進(jìn)程之前調(diào)用,master-worker之間的通信封裝為一個(gè) ngx_channel_t 結(jié)構(gòu)體
typedef struct {
ngx_uint_t command;//發(fā)送的命令
ngx_pid_t pid;//一般是發(fā)送方的命令id
ngx_int_t slot;//在全局進(jìn)程表中的位置
ngx_fd_t fd;//套接字
} ngx_channel_t;
ngx_channel_t提供四個(gè)方法的,讀,寫,關(guān)閉,增加事件偵聽
ngx_int_t ngx_write_channel(ngx_socket_t s, ngx_channel_t *ch, size_t size,
ngx_log_t *log);//寫數(shù)據(jù)(一般都是master往worker發(fā)送cmd)
ngx_int_t ngx_read_channel(ngx_socket_t s, ngx_channel_t *ch, size_t size,
ngx_log_t *log);//讀數(shù)據(jù)(一般都是worker讀取master發(fā)送的命令)
ngx_int_t ngx_add_channel_event(ngx_cycle_t *cycle, ngx_fd_t fd,
ngx_int_t event, ngx_event_handler_pt handler);//加入事件偵聽(一般都是worker操作)
void ngx_close_channel(ngx_fd_t *fd, ngx_log_t *log);//套接字關(guān)閉
進(jìn)程的創(chuàng)建
nginx提供了ngx_process_t來對(duì)進(jìn)程信息的保存的結(jié)構(gòu)體,用來保存子進(jìn)程信息
定義了一個(gè)全局?jǐn)?shù)組
ngx_process_t ngx_processes[NGX_MAX_PROCESSES];用來存放所有的子進(jìn)程 NGX_MAX_PROCESSES = 1024
typedef struct {
ngx_pid_t pid;//進(jìn)程id
int status;//子進(jìn)程退出后,父進(jìn)程收到sigchld,父進(jìn)程由waitpid系統(tǒng)調(diào)用去獲得進(jìn)程狀態(tài)
ngx_socket_t channel[2];//socktpair產(chǎn)生的用于進(jìn)程間通信的句柄
ngx_spawn_proc_pt proc;//啟動(dòng)子進(jìn)程后的執(zhí)行方法
/*
上面的ngx_spawn_proc_pt方法中第2個(gè)參數(shù)雷要傳遞1個(gè)指針,它是可選的。例如,worker子進(jìn)程就不需要,而cache manage進(jìn)程
就需要ngx_cache_manager_ctx上下文成員。這時(shí),data一般與ngx_spawn_proc_pt方法中第2個(gè)參數(shù)是等價(jià)的
*/
void *data;//
char *name;//進(jìn)程的名字
unsigned respawn:1;//為1表示重新生成子進(jìn)程
unsigned just_spawn:1;//表示正在生成子進(jìn)程
unsigned detached:1;//表示父子進(jìn)程分離
unsigned exiting:1;//表示進(jìn)程正在退出
unsigned exited:1;//表示進(jìn)程已經(jīng)退出
} ngx_process_t;
進(jìn)程的創(chuàng)建的方法
流程:
- 找出一個(gè)可用ngx_processes
- 如果不是熱代碼替換的話使用socketpair創(chuàng)建通信sock
- 設(shè)置sock的屬性,非阻塞,異步等。
- 調(diào)用fork創(chuàng)建子進(jìn)程
- 子進(jìn)程中將調(diào)用proc方法,回不來了,主進(jìn)程中保存子進(jìn)程的信息,設(shè)置狀態(tài)。
ngx_pid_t
ngx_spawn_process(ngx_cycle_t *cycle, ngx_spawn_proc_pt proc, void *data,
char *name, ngx_int_t respawn)
{
/*
proc 創(chuàng)建完成之后的執(zhí)行方法
data 方法需要的執(zhí)行參數(shù)
name 進(jìn)程的名字
respawn 創(chuàng)建方式
*/
u_long on;
ngx_pid_t pid;
ngx_int_t s;//將要?jiǎng)?chuàng)建的子進(jìn)程在進(jìn)程表中的位置
// 如果respawn不小于0,則視為當(dāng)前進(jìn)程已經(jīng)退出,需要重啟
if (respawn >= 0) {
s = respawn;
} else {
for (s = 0; s < ngx_last_process; s++) {
if (ngx_processes[s].pid == -1) {//找個(gè)可用的
break;
}
}
if (s == NGX_MAX_PROCESSES) {//最多只能創(chuàng)建1024個(gè)子進(jìn)程
ngx_log_error(NGX_LOG_ALERT, cycle->log, 0,
"no more than %d processes can be spawned",
NGX_MAX_PROCESSES);
return NGX_INVALID_PID;
}
}
if (respawn != NGX_PROCESS_DETACHED) {//不是分離的子進(jìn)程 /* 不是熱代碼替換 */
/* Solaris 9 still has no AF_LOCAL */
/*
這里相當(dāng)于Master進(jìn)程調(diào)用socketpair()為新的worker進(jìn)程創(chuàng)建一對(duì)全雙工的socket
實(shí)際上socketpair 函數(shù)跟pipe 函數(shù)是類似的,也只能在同個(gè)主機(jī)上具有親緣關(guān)系的進(jìn)程間通信,但pipe 創(chuàng)建的匿名管道是半雙工的,
而socketpair 可以認(rèn)為是創(chuàng)建一個(gè)全雙工的管道。*/
if (socketpair(AF_UNIX, SOCK_STREAM, 0, ngx_processes[s].channel) == -1)
{
ngx_log_error(NGX_LOG_ALERT, cycle->log, ngx_errno,
"socketpair() failed while spawning \"%s\"", name);
return NGX_INVALID_PID;
}
/*
protocol必須傳遞0
當(dāng)socketpair執(zhí)行成功時(shí),sv[2]這兩個(gè)套接字具備下列關(guān)系:向sv[0]套接字寫入數(shù)據(jù),將可以從sv[l]套接字中讀取到剛寫入的數(shù)據(jù);
同樣,向sv[l]套接字寫入數(shù)據(jù),也可以從sv[0]中讀取到寫入的數(shù)據(jù)
通常,在父、子進(jìn)程通信前,會(huì)先調(diào)用socketpair方法創(chuàng)建這樣一組
套接字,在調(diào)用fork方法創(chuàng)建出子進(jìn)程后,將會(huì)在父進(jìn)程中關(guān)閉sv[l]套接字,僅使用sv[0]套接字用于向子進(jìn)程發(fā)送數(shù)據(jù)以及接收子進(jìn)程發(fā)
送來的數(shù)據(jù):
而在子進(jìn)程中則關(guān)閉sv[0]套接字,僅使用sv[l]套接字既可以接收父進(jìn)程發(fā)來的數(shù)據(jù),也可以向父進(jìn)程發(fā)送數(shù)據(jù)。
注意socketpair的協(xié)議族為AF_UNIX UNXI域
*/
ngx_log_debug2(NGX_LOG_DEBUG_CORE, cycle->log, 0,
"channel %d:%d",
ngx_processes[s].channel[0],
ngx_processes[s].channel[1]);
if (ngx_nonblocking(ngx_processes[s].channel[0]) == -1) {//設(shè)置為非阻塞
ngx_log_error(NGX_LOG_ALERT, cycle->log, ngx_errno,
ngx_nonblocking_n " failed while spawning \"%s\"",
name);
ngx_close_channel(ngx_processes[s].channel, cycle->log);
return NGX_INVALID_PID;
}
if (ngx_nonblocking(ngx_processes[s].channel[1]) == -1) {
ngx_log_error(NGX_LOG_ALERT, cycle->log, ngx_errno,
ngx_nonblocking_n " failed while spawning \"%s\"",
name);
ngx_close_channel(ngx_processes[s].channel, cycle->log);
return NGX_INVALID_PID;
}
on = 1;
/*
設(shè)置異步模式:
*/
/*
設(shè)置channel[0]的信號(hào)驅(qū)動(dòng)異步I/O標(biāo)志
FIOASYNC:該狀態(tài)標(biāo)志決定是否收取針對(duì)socket的異步I/O信號(hào)(SIGIO)
其與O_ASYNC文件狀態(tài)標(biāo)志等效,可通過fcntl的F_SETFL命令設(shè)置or清除
*/
if (ioctl(ngx_processes[s].channel[0], FIOASYNC, &on) == -1) {
ngx_log_error(NGX_LOG_ALERT, cycle->log, ngx_errno,
"ioctl(FIOASYNC) failed while spawning \"%s\"", name);
ngx_close_channel(ngx_processes[s].channel, cycle->log);
return NGX_INVALID_PID;
}
/* F_SETOWN:用于指定接收SIGIO和SIGURG信號(hào)的socket屬主(進(jìn)程ID或進(jìn)程組ID)
* 這里意思是指定Master進(jìn)程接收SIGIO和SIGURG信號(hào)
* SIGIO信號(hào)必須是在socket設(shè)置為信號(hào)驅(qū)動(dòng)異步I/O才能產(chǎn)生,即上一步操作
* SIGURG信號(hào)是在新的帶外數(shù)據(jù)到達(dá)socket時(shí)產(chǎn)生的
*/
if (fcntl(ngx_processes[s].channel[0], F_SETOWN, ngx_pid) == -1) {
ngx_log_error(NGX_LOG_ALERT, cycle->log, ngx_errno,
"fcntl(F_SETOWN) failed while spawning \"%s\"", name);
ngx_close_channel(ngx_processes[s].channel, cycle->log);
return NGX_INVALID_PID;
}
/* FD_CLOEXEC:用來設(shè)置文件的close-on-exec狀態(tài)標(biāo)準(zhǔn)
* 在exec()調(diào)用后,close-on-exec標(biāo)志為0的情況下,此文件不被關(guān)閉;非零則在exec()后被關(guān)閉
* 默認(rèn)close-on-exec狀態(tài)為0,需要通過FD_CLOEXEC設(shè)置
* 這里意思是當(dāng)Master父進(jìn)程執(zhí)行了exec()調(diào)用后,關(guān)閉socket
*/
if (fcntl(ngx_processes[s].channel[0], F_SETFD, FD_CLOEXEC) == -1) {
ngx_log_error(NGX_LOG_ALERT, cycle->log, ngx_errno,
"fcntl(FD_CLOEXEC) failed while spawning \"%s\"",
name);
ngx_close_channel(ngx_processes[s].channel, cycle->log);
return NGX_INVALID_PID;
}
/* 同上,這里意思是當(dāng)Worker子進(jìn)程執(zhí)行了exec()調(diào)用后,關(guān)閉socket */
if (fcntl(ngx_processes[s].channel[1], F_SETFD, FD_CLOEXEC) == -1) {
ngx_log_error(NGX_LOG_ALERT, cycle->log, ngx_errno,
"fcntl(FD_CLOEXEC) failed while spawning \"%s\"",
name);
ngx_close_channel(ngx_processes[s].channel, cycle->log);
return NGX_INVALID_PID;
}
ngx_channel = ngx_processes[s].channel[1];
} else {
ngx_processes[s].channel[0] = -1;
ngx_processes[s].channel[1] = -1;
}
ngx_process_slot = s;// 這一步將在ngx_pass_open_channel()中用到,就是設(shè)置下標(biāo),用于尋找本次創(chuàng)建的子進(jìn)程
pid = fork();//fork 創(chuàng)建子進(jìn)程
switch (pid) {
case -1://創(chuàng)建失敗了
ngx_log_error(NGX_LOG_ALERT, cycle->log, ngx_errno,
"fork() failed while spawning \"%s\"", name);
ngx_close_channel(ngx_processes[s].channel, cycle->log);
return NGX_INVALID_PID;
case 0:
ngx_pid = ngx_getpid();//在子進(jìn)程了
proc(cycle, data);//執(zhí)行回調(diào)方法 出不來了 這里是子進(jìn)程執(zhí)行的方法
break;
default:
break;
}
ngx_log_error(NGX_LOG_NOTICE, cycle->log, 0, "start %s %P", name, pid);
ngx_processes[s].pid = pid;//保存pid
ngx_processes[s].exited = 0;//沒退出
if (respawn >= 0) {//如果是大于0的操作 說明是重啟子進(jìn)程 下面不重復(fù)了
return pid;
}
ngx_processes[s].proc = proc;
ngx_processes[s].data = data;
ngx_processes[s].name = name;
ngx_processes[s].exiting = 0;
switch (respawn) {//設(shè)置狀態(tài)信息
case NGX_PROCESS_NORESPAWN:
ngx_processes[s].respawn = 0;
ngx_processes[s].just_spawn = 0;
ngx_processes[s].detached = 0;
break;
case NGX_PROCESS_JUST_SPAWN:
ngx_processes[s].respawn = 0;
ngx_processes[s].just_spawn = 1;
ngx_processes[s].detached = 0;
break;
case NGX_PROCESS_RESPAWN:
ngx_processes[s].respawn = 1;
ngx_processes[s].just_spawn = 0;
ngx_processes[s].detached = 0;
break;
case NGX_PROCESS_JUST_RESPAWN:
ngx_processes[s].respawn = 1;
ngx_processes[s].just_spawn = 1;
ngx_processes[s].detached = 0;
break;
case NGX_PROCESS_DETACHED:
ngx_processes[s].respawn = 0;
ngx_processes[s].just_spawn = 0;
ngx_processes[s].detached = 1;
break;
}
if (s == ngx_last_process) {
ngx_last_process++;
}
return pid;
}
在創(chuàng)建子進(jìn)程中子進(jìn)程將會(huì)調(diào)用一個(gè)proc方法這個(gè)方法,這個(gè)方法主要是進(jìn)行worker進(jìn)程的初始化和事件的循環(huán),這個(gè)方法是
static void ngx_worker_process_cycle(ngx_cycle_t *cycle, void *data),他將會(huì)調(diào)用ngx_worker_process_init方法進(jìn)行一些初始化操作。這些初始化操作主要是:(1)優(yōu)先級(jí)設(shè)置;(2)文件最大描述符設(shè)置;(3)core文件尺寸設(shè)置;(4)用戶信息設(shè)置;(5)工作目錄的改變;(6):改變當(dāng)前阻塞信號(hào)集(7)隨機(jī)種子設(shè)置(8) init_process (9): 關(guān)閉其他進(jìn)程的channel[1] 和自己進(jìn)程的channel[0] ;(10):把channel[1]加入事件偵聽
static void
ngx_worker_process_init(ngx_cycle_t *cycle, ngx_int_t worker)
{
sigset_t set;
uint64_t cpu_affinity;
ngx_int_t n;
ngx_uint_t i;
struct rlimit rlmt;
ngx_core_conf_t *ccf;
ngx_listening_t *ls;
if (ngx_set_environment(cycle, NULL) == NULL) {//環(huán)境變量
/* fatal */
exit(2);
}
ccf = (ngx_core_conf_t *) ngx_get_conf(cycle->conf_ctx, ngx_core_module);
if (worker >= 0 && ccf->priority != 0) {//優(yōu)先級(jí)的設(shè)置
if (setpriority(PRIO_PROCESS, 0, ccf->priority) == -1) {
ngx_log_error(NGX_LOG_ALERT, cycle->log, ngx_errno,
"setpriority(%d) failed", ccf->priority);
}
}
if (ccf->rlimit_nofile != NGX_CONF_UNSET) {
rlmt.rlim_cur = (rlim_t) ccf->rlimit_nofile;
rlmt.rlim_max = (rlim_t) ccf->rlimit_nofile;
//RLIMIT_NOFILE指定此進(jìn)程可打開的最大文件描述詞大一的值,超出此值,將會(huì)產(chǎn)生EMFILE錯(cuò)誤。
if (setrlimit(RLIMIT_NOFILE, &rlmt) == -1) {
ngx_log_error(NGX_LOG_ALERT, cycle->log, ngx_errno,
"setrlimit(RLIMIT_NOFILE, %i) failed",
ccf->rlimit_nofile);
}
}
if (ccf->rlimit_core != NGX_CONF_UNSET) {
rlmt.rlim_cur = (rlim_t) ccf->rlimit_core;
rlmt.rlim_max = (rlim_t) ccf->rlimit_core;
//修改工作進(jìn)程的core文件尺寸的最大值限制(RLIMIT_CORE),用于在不重啟主進(jìn)程的情況下增大該限制。
if (setrlimit(RLIMIT_CORE, &rlmt) == -1) {
ngx_log_error(NGX_LOG_ALERT, cycle->log, ngx_errno,
"setrlimit(RLIMIT_CORE, %O) failed",
ccf->rlimit_core);
}
}
#ifdef RLIMIT_SIGPENDING
if (ccf->rlimit_sigpending != NGX_CONF_UNSET) {
rlmt.rlim_cur = (rlim_t) ccf->rlimit_sigpending;
rlmt.rlim_max = (rlim_t) ccf->rlimit_sigpending;
if (setrlimit(RLIMIT_SIGPENDING, &rlmt) == -1) {
ngx_log_error(NGX_LOG_ALERT, cycle->log, ngx_errno,
"setrlimit(RLIMIT_SIGPENDING, %i) failed",
ccf->rlimit_sigpending);
}
}
#endif
//設(shè)置用戶信息
if (geteuid() == 0) {
if (setgid(ccf->group) == -1) {
ngx_log_error(NGX_LOG_EMERG, cycle->log, ngx_errno,
"setgid(%d) failed", ccf->group);
/* fatal */
exit(2);
}
if (initgroups(ccf->username, ccf->group) == -1) {
ngx_log_error(NGX_LOG_EMERG, cycle->log, ngx_errno,
"initgroups(%s, %d) failed",
ccf->username, ccf->group);
}
if (setuid(ccf->user) == -1) {
ngx_log_error(NGX_LOG_EMERG, cycle->log, ngx_errno,
"setuid(%d) failed", ccf->user);
/* fatal */
exit(2);
}
}
if (worker >= 0) {
cpu_affinity = ngx_get_cpu_affinity(worker);
if (cpu_affinity) {
ngx_setaffinity(cpu_affinity, cycle->log);
}
}
#if (NGX_HAVE_PR_SET_DUMPABLE)
/* allow coredump after setuid() in Linux 2.4.x */
if (prctl(PR_SET_DUMPABLE, 1, 0, 0, 0) == -1) {
ngx_log_error(NGX_LOG_ALERT, cycle->log, ngx_errno,
"prctl(PR_SET_DUMPABLE) failed");
}
#endif
if (ccf->working_directory.len) {//更改當(dāng)前工作目錄
if (chdir((char *) ccf->working_directory.data) == -1) {
ngx_log_error(NGX_LOG_ALERT, cycle->log, ngx_errno,
"chdir(\"%s\") failed", ccf->working_directory.data);
/* fatal */
exit(2);
}
}
sigemptyset(&set);
if (sigprocmask(SIG_SETMASK, &set, NULL) == -1) {//改變進(jìn)程的當(dāng)前阻塞信號(hào)集
ngx_log_error(NGX_LOG_ALERT, cycle->log, ngx_errno,
"sigprocmask() failed");
}
srandom((ngx_pid << 16) ^ ngx_time());//設(shè)置隨機(jī)種子
/*
* disable deleting previous events for the listening sockets because
* in the worker processes there are no events at all at this point
*/
ls = cycle->listening.elts;
for (i = 0; i < cycle->listening.nelts; i++) {
ls[i].previous = NULL;
}
//調(diào)用init_process
for (i = 0; ngx_modules[i]; i++) {
if (ngx_modules[i]->init_process) {
if (ngx_modules[i]->init_process(cycle) == NGX_ERROR) {
/* fatal */
exit(2);
}
}
}
//關(guān)閉其他進(jìn)程的channel[1] 和自己進(jìn)程的channel[0] 然主進(jìn)程使用channel[0] 寫數(shù)據(jù)自己使用channel[1]讀數(shù)據(jù)
for (n = 0; n < ngx_last_process; n++) {
if (ngx_processes[n].pid == -1) {
continue;
}
if (n == ngx_process_slot) {
continue;
}
if (ngx_processes[n].channel[1] == -1) {
continue;
}
if (close(ngx_processes[n].channel[1]) == -1) {
ngx_log_error(NGX_LOG_ALERT, cycle->log, ngx_errno,
"close() channel failed");
}
}
if (close(ngx_processes[ngx_process_slot].channel[0]) == -1) {
ngx_log_error(NGX_LOG_ALERT, cycle->log, ngx_errno,
"close() channel failed");
}
#if 0
ngx_last_process = 0;
#endif
if (ngx_add_channel_event(cycle, ngx_channel, NGX_READ_EVENT,
ngx_channel_handler)//添加到事件偵聽
== NGX_ERROR)
{
/* fatal */
exit(2);
}
}
然后ngx_worker_process_cycle 進(jìn)行事件的循環(huán),如果收到了對(duì)應(yīng)的信號(hào)信息,就進(jìn)行對(duì)應(yīng)的信號(hào)操作,比如quit reopen terminate操作,就不貼代碼了自己參考代碼。
我們發(fā)現(xiàn)我們?cè)黾恿藢?duì)channel[1]的事件偵聽這個(gè)socket收到的消息就是我們的master發(fā)送的指令,具體的處理函數(shù)就是ngx_channel_handler里面,可以查看具體命令的處理。
master的信號(hào)處理和對(duì)子進(jìn)程的管理和監(jiān)控
master進(jìn)程的主要作用就是對(duì)外界信號(hào)的處理和對(duì)子進(jìn)程的監(jiān)控,對(duì)外界信號(hào)的處理主要是通過信號(hào)量的偵聽來實(shí)現(xiàn)的
下面來看下nginx對(duì)信號(hào)量的處理
在main函數(shù)中會(huì)調(diào)用一個(gè)ngx_init_signals方法來初始化信號(hào)量處理
nginx簡(jiǎn)單封裝了下singal
typedef struct {
int signo;//需要處理的信號(hào)
char *signame;//信號(hào)對(duì)應(yīng)的字符串名稱
char *name;//信號(hào)對(duì)應(yīng)的nginx命令
void (*handler)(int signo);//收到signo信號(hào)后的處理方法
} ngx_signal_t;
nginx定義了一個(gè)ngx_signal_t signals[]的數(shù)組,用來保存需要初始化的信號(hào)量
ngx_signal_t signals[] = {
{ ngx_signal_value(NGX_RECONFIGURE_SIGNAL),
"SIG" ngx_value(NGX_RECONFIGURE_SIGNAL),
"reload",
ngx_signal_handler },
{ ngx_signal_value(NGX_REOPEN_SIGNAL),
"SIG" ngx_value(NGX_REOPEN_SIGNAL),
"reopen",
ngx_signal_handler },
{ ngx_signal_value(NGX_NOACCEPT_SIGNAL),
"SIG" ngx_value(NGX_NOACCEPT_SIGNAL),
"",
ngx_signal_handler },
{ ngx_signal_value(NGX_TERMINATE_SIGNAL),
"SIG" ngx_value(NGX_TERMINATE_SIGNAL),
"stop",
ngx_signal_handler },
{ ngx_signal_value(NGX_SHUTDOWN_SIGNAL),
"SIG" ngx_value(NGX_SHUTDOWN_SIGNAL),
"quit",
ngx_signal_handler },
{ ngx_signal_value(NGX_CHANGEBIN_SIGNAL),
"SIG" ngx_value(NGX_CHANGEBIN_SIGNAL),
"",
ngx_signal_handler },
{ SIGALRM, "SIGALRM", "", ngx_signal_handler },
{ SIGINT, "SIGINT", "", ngx_signal_handler },
{ SIGIO, "SIGIO", "", ngx_signal_handler },
{ SIGCHLD, "SIGCHLD", "", ngx_signal_handler },
{ SIGSYS, "SIGSYS, SIG_IGN", "", SIG_IGN },
{ SIGPIPE, "SIGPIPE, SIG_IGN", "", SIG_IGN },
{ 0, NULL, "", NULL }
};
init_signals的作用就是將signals里面的內(nèi)容加入到系統(tǒng)偵聽
當(dāng)信號(hào)的到來就將會(huì)調(diào)用ngx_signal_handler方法來處理,轉(zhuǎn)換成當(dāng)前對(duì)應(yīng)的狀態(tài)(不貼代碼)
當(dāng)收到的信號(hào)是SIGCHLD的時(shí)候(子線程掛了)將還會(huì)調(diào)用ngx_process_get_status()來獲取子線程信息。然后把對(duì)應(yīng)掛了的子進(jìn)程的exit設(shè)置為1
static void
ngx_process_get_status(void)
{
int status;
char *process;
ngx_pid_t pid;
ngx_err_t err;
ngx_int_t i;
ngx_uint_t one;
one = 0;
for ( ;; ) {
pid = waitpid(-1, &status, WNOHANG);//獲取掛了的子進(jìn)程的id
if (pid == 0) {
return;
}
if (pid == -1) {
err = ngx_errno;
if (err == NGX_EINTR) {
continue;
}
if (err == NGX_ECHILD && one) {
return;
}
/*
* Solaris always calls the signal handler for each exited process
* despite waitpid() may be already called for this process.
*
* When several processes exit at the same time FreeBSD may
* erroneously call the signal handler for exited process
* despite waitpid() may be already called for this process.
*/
if (err == NGX_ECHILD) {
ngx_log_error(NGX_LOG_INFO, ngx_cycle->log, err,
"waitpid() failed");
return;
}
ngx_log_error(NGX_LOG_ALERT, ngx_cycle->log, err,
"waitpid() failed");
return;
}
one = 1;
process = "unknown process";
for (i = 0; i < ngx_last_process; i++) {//找到子進(jìn)程
if (ngx_processes[i].pid == pid) {
ngx_processes[i].status = status;
ngx_processes[i].exited = 1;//設(shè)置退出
process = ngx_processes[i].name;
break;
}
}
if (WTERMSIG(status)) {
#ifdef WCOREDUMP
ngx_log_error(NGX_LOG_ALERT, ngx_cycle->log, 0,
"%s %P exited on signal %d%s",
process, pid, WTERMSIG(status),
WCOREDUMP(status) ? " (core dumped)" : "");
#else
ngx_log_error(NGX_LOG_ALERT, ngx_cycle->log, 0,
"%s %P exited on signal %d",
process, pid, WTERMSIG(status));
#endif
} else {
ngx_log_error(NGX_LOG_NOTICE, ngx_cycle->log, 0,
"%s %P exited with code %d",
process, pid, WEXITSTATUS(status));
}
if (WEXITSTATUS(status) == 2 && ngx_processes[i].respawn) {//2 致命的錯(cuò)誤
ngx_log_error(NGX_LOG_ALERT, ngx_cycle->log, 0,
"%s %P exited with fatal code %d "
"and cannot be respawned",
process, pid, WEXITSTATUS(status));
ngx_processes[i].respawn = 0;//再打開也沒用了
}
ngx_unlock_mutexes(pid);
}
}
在master的主循環(huán)中會(huì)發(fā)現(xiàn)ngx_reap被設(shè)置為1,然后會(huì)被調(diào)用ngx_reap_childern來重啟子進(jìn)程
static ngx_uint_t
ngx_reap_children(ngx_cycle_t *cycle)
{
ngx_int_t i, n;
ngx_uint_t live;
ngx_channel_t ch;
ngx_core_conf_t *ccf;
ngx_memzero(&ch, sizeof(ngx_channel_t));
ch.command = NGX_CMD_CLOSE_CHANNEL;
ch.fd = -1;
live = 0;
for (i = 0; i < ngx_last_process; i++) {
ngx_log_debug7(NGX_LOG_DEBUG_EVENT, cycle->log, 0,
"child: %d %P e:%d t:%d d:%d r:%d j:%d",
i,
ngx_processes[i].pid,
ngx_processes[i].exiting,
ngx_processes[i].exited,
ngx_processes[i].detached,
ngx_processes[i].respawn,
ngx_processes[i].just_spawn);
if (ngx_processes[i].pid == -1) {//當(dāng)前在被用
continue;
}
if (ngx_processes[i].exited) {//被退出了
if (!ngx_processes[i].detached) {//不是分離的
ngx_close_channel(ngx_processes[i].channel, cycle->log);//關(guān)閉通信channel
ngx_processes[i].channel[0] = -1;
ngx_processes[i].channel[1] = -1;
ch.pid = ngx_processes[i].pid;
ch.slot = i;
for (n = 0; n < ngx_last_process; n++) {//掃描所有的
if (ngx_processes[n].exited
|| ngx_processes[n].pid == -1
|| ngx_processes[n].channel[0] == -1)
{
continue;
}
ngx_log_debug3(NGX_LOG_DEBUG_CORE, cycle->log, 0,
"pass close channel s:%i pid:%P to:%P",
ch.slot, ch.pid, ngx_processes[n].pid);
/* TODO: NGX_AGAIN */
ngx_write_channel(ngx_processes[n].channel[0],
&ch, sizeof(ngx_channel_t), cycle->log);//關(guān)閉所有子進(jìn)程和退出進(jìn)程的通信通道
}
}
if (ngx_processes[i].respawn
&& !ngx_processes[i].exiting
&& !ngx_terminate
&& !ngx_quit)//如果不是新開的進(jìn)程就不啟動(dòng)了,如果是致命的錯(cuò)誤,也不啟動(dòng)了
{
if (ngx_spawn_process(cycle, ngx_processes[i].proc,
ngx_processes[i].data,
ngx_processes[i].name, i)//重新啟動(dòng)這個(gè)進(jìn)程
== NGX_INVALID_PID)
{
ngx_log_error(NGX_LOG_ALERT, cycle->log, 0,
"could not respawn %s",
ngx_processes[i].name);
continue;
}
ch.command = NGX_CMD_OPEN_CHANNEL;
ch.pid = ngx_processes[ngx_process_slot].pid;
ch.slot = ngx_process_slot;
ch.fd = ngx_processes[ngx_process_slot].channel[0];
ngx_pass_open_channel(cycle, &ch);//通知其他進(jìn)程新的聯(lián)系方式
live = 1;
continue;
}
if (ngx_processes[i].pid == ngx_new_binary) {//熱代碼替換
ccf = (ngx_core_conf_t *) ngx_get_conf(cycle->conf_ctx,
ngx_core_module);
if (ngx_rename_file((char *) ccf->oldpid.data,
(char *) ccf->pid.data)
== NGX_FILE_ERROR)
{
ngx_log_error(NGX_LOG_ALERT, cycle->log, ngx_errno,
ngx_rename_file_n " %s back to %s failed "
"after the new binary process \"%s\" exited",
ccf->oldpid.data, ccf->pid.data, ngx_argv[0]);
}
ngx_new_binary = 0;
if (ngx_noaccepting) {
ngx_restart = 1;
ngx_noaccepting = 0;
}
}
if (i == ngx_last_process - 1) {
ngx_last_process--;
} else {
ngx_processes[i].pid = -1;
}
} else if (ngx_processes[i].exiting || !ngx_processes[i].detached) {//正在退出
live = 1;
}
}
return live;
}
其中有一點(diǎn)就是當(dāng)上一個(gè)進(jìn)程是因?yàn)橹旅e(cuò)誤退出的exit(2)那就不用再打開了,反正也打不開
整體的連接起來
到這里每一個(gè)小項(xiàng)已經(jīng)基本差不多了。來整體看來最后的啟動(dòng)
void
ngx_master_process_cycle(ngx_cycle_t *cycle)
{
char *title;
u_char *p;
size_t size;
ngx_int_t i;
ngx_uint_t n, sigio;
sigset_t set;
struct itimerval itv;
ngx_uint_t live;
ngx_msec_t delay;
ngx_listening_t *ls;
ngx_core_conf_t *ccf;
sigemptyset(&set);
sigaddset(&set, SIGCHLD);
sigaddset(&set, SIGALRM);
sigaddset(&set, SIGIO);
sigaddset(&set, SIGINT);
sigaddset(&set, ngx_signal_value(NGX_RECONFIGURE_SIGNAL));
sigaddset(&set, ngx_signal_value(NGX_REOPEN_SIGNAL));
sigaddset(&set, ngx_signal_value(NGX_NOACCEPT_SIGNAL));
sigaddset(&set, ngx_signal_value(NGX_TERMINATE_SIGNAL));
sigaddset(&set, ngx_signal_value(NGX_SHUTDOWN_SIGNAL));
sigaddset(&set, ngx_signal_value(NGX_CHANGEBIN_SIGNAL));
if (sigprocmask(SIG_BLOCK, &set, NULL) == -1) {//信號(hào)阻塞
ngx_log_error(NGX_LOG_ALERT, cycle->log, ngx_errno,
"sigprocmask() failed");
}
sigemptyset(&set);
size = sizeof(master_process);
for (i = 0; i < ngx_argc; i++) {
size += ngx_strlen(ngx_argv[i]) + 1;
}
title = ngx_pnalloc(cycle->pool, size);
p = ngx_cpymem(title, master_process, sizeof(master_process) - 1);
for (i = 0; i < ngx_argc; i++) {
*p++ = ' ';
p = ngx_cpystrn(p, (u_char *) ngx_argv[i], size);
}
ngx_setproctitle(title);//設(shè)置進(jìn)程的名字
ccf = (ngx_core_conf_t *) ngx_get_conf(cycle->conf_ctx, ngx_core_module);
ngx_start_worker_processes(cycle, ccf->worker_processes,
NGX_PROCESS_RESPAWN);//啟動(dòng)worker
ngx_start_cache_manager_processes(cycle, 0);//啟動(dòng)manager
ngx_new_binary = 0;
delay = 0;
sigio = 0;
live = 1;
for ( ;; ) {
/*
delay用來等待子進(jìn)程退出的時(shí)間,由于我們接受到SIGINT信號(hào)后,我們需要先發(fā)送信號(hào)給子進(jìn)程,而子進(jìn)程的退出需要一定的時(shí)間,
超時(shí)時(shí)如果子進(jìn)程已退出,我們父進(jìn)程就直接退出,否則發(fā)送sigkill信號(hào)給子進(jìn)程(強(qiáng)制退出),然后再退出。
*/
if (delay) {
if (ngx_sigalrm) {
sigio = 0;
delay *= 2;
ngx_sigalrm = 0;
}
ngx_log_debug1(NGX_LOG_DEBUG_EVENT, cycle->log, 0,
"termination cycle: %d", delay);
itv.it_interval.tv_sec = 0;
itv.it_interval.tv_usec = 0;
itv.it_value.tv_sec = delay / 1000;
itv.it_value.tv_usec = (delay % 1000 ) * 1000;
/*
setitimer(int which, const struct itimerval *value, struct itimerval *ovalue));
setitimer()比alarm功能強(qiáng)大,支持3種類型的定時(shí)器:
ITIMER_REAL: 設(shè)定絕對(duì)時(shí)間;經(jīng)過指定的時(shí)間后,內(nèi)核將發(fā)送SIGALRM信號(hào)給本進(jìn)程;
ITIMER_VIRTUAL 設(shè)定程序執(zhí)行時(shí)間;經(jīng)過指定的時(shí)間后,內(nèi)核將發(fā)送SIGVTALRM信號(hào)給本進(jìn)程;
ITIMER_PROF 設(shè)定進(jìn)程執(zhí)行以及內(nèi)核因本進(jìn)程而消耗的時(shí)間和,經(jīng)過指定的時(shí)間后,內(nèi)核將發(fā)送ITIMER_VIRTUAL信號(hào)給本進(jìn)程;
*/ //設(shè)置定時(shí)器,以系統(tǒng)真實(shí)時(shí)間來計(jì)算,送出SIGALRM信號(hào),這個(gè)信號(hào)反過來會(huì)設(shè)置ngx_sigalrm為1,這樣delay就會(huì)不斷翻倍。
if (setitimer(ITIMER_REAL, &itv, NULL) == -1) {
ngx_log_error(NGX_LOG_ALERT, cycle->log, ngx_errno,
"setitimer() failed");
}
}
ngx_log_debug0(NGX_LOG_DEBUG_EVENT, cycle->log, 0, "sigsuspend");
sigsuspend(&set);//等待定時(shí)器超時(shí),通過ngx_init_signals執(zhí)行ngx_signal_handler中的SIGALRM信號(hào),信號(hào)處理函數(shù)返回后,繼續(xù)該函數(shù)后面的操作
ngx_time_update();
ngx_log_debug1(NGX_LOG_DEBUG_EVENT, cycle->log, 0,
"wake up, sigio %i", sigio);
if (ngx_reap) {//父進(jìn)程收到一個(gè)子進(jìn)程退出的信號(hào)
ngx_reap = 0;
ngx_log_debug0(NGX_LOG_DEBUG_EVENT, cycle->log, 0, "reap children");
///這個(gè)里面處理退出的子進(jìn)程(有的worker異常退出,這時(shí)我們就需要重啟這個(gè)worker ),如果所有子進(jìn)程都退出則會(huì)返回0.
live = ngx_reap_children(cycle);// 有子進(jìn)程意外結(jié)束,這時(shí)需要監(jiān)控所有的子進(jìn)程
}
//如果沒有存活的子進(jìn)程,并且收到了ngx_terminate或者ngx_quit信號(hào),則master退出。
if (!live && (ngx_terminate || ngx_quit)) {
ngx_master_process_exit(cycle);
}
if (ngx_terminate) {//收到了sigint信號(hào)。
if (delay == 0) {//設(shè)置延時(shí)。
delay = 50;
}
if (sigio) {
sigio--;
continue;
}
sigio = ccf->worker_processes + 2 /* cache processes */;
if (delay > 1000) {//如果超時(shí)就強(qiáng)制殺死進(jìn)程
ngx_signal_worker_processes(cycle, SIGKILL);
} else {
ngx_signal_worker_processes(cycle,
ngx_signal_value(NGX_TERMINATE_SIGNAL));//否則就發(fā)送退出信號(hào)
}
continue;
}
if (ngx_quit) {//如果收到了退出信號(hào)
ngx_signal_worker_processes(cycle,
ngx_signal_value(NGX_SHUTDOWN_SIGNAL));//發(fā)送信號(hào)
ls = cycle->listening.elts;
for (n = 0; n < cycle->listening.nelts; n++) {//關(guān)閉偵聽數(shù)組
if (ngx_close_socket(ls[n].fd) == -1) {
ngx_log_error(NGX_LOG_EMERG, cycle->log, ngx_socket_errno,
ngx_close_socket_n " %V failed",
&ls[n].addr_text);
}
}
cycle->listening.nelts = 0;
continue;
}
if (ngx_reconfigure) {//收到reconfig信號(hào)
ngx_reconfigure = 0;
if (ngx_new_binary) {//判斷是否熱代碼替換后的新的代碼還在運(yùn)行中(也就是還沒退出當(dāng)前的master)。如果還在運(yùn)行中,則不需要重新初始化config。
ngx_start_worker_processes(cycle, ccf->worker_processes,
NGX_PROCESS_RESPAWN);//重啟worker進(jìn)程
ngx_start_cache_manager_processes(cycle, 0);//重啟cache進(jìn)程
ngx_noaccepting = 0;
continue;
}
ngx_log_error(NGX_LOG_NOTICE, cycle->log, 0, "reconfiguring");
cycle = ngx_init_cycle(cycle);//重新初始化config,并重新啟動(dòng)新的worker
if (cycle == NULL) {
cycle = (ngx_cycle_t *) ngx_cycle;
continue;
}
ngx_cycle = cycle;
ccf = (ngx_core_conf_t *) ngx_get_conf(cycle->conf_ctx,
ngx_core_module);
ngx_start_worker_processes(cycle, ccf->worker_processes,//重啟worker進(jìn)程
NGX_PROCESS_JUST_RESPAWN);
ngx_start_cache_manager_processes(cycle, 1);//重啟cache進(jìn)程
/* allow new processes to start */
ngx_msleep(100);
live = 1;
ngx_signal_worker_processes(cycle,
ngx_signal_value(NGX_SHUTDOWN_SIGNAL));//發(fā)送退出命令
}
if (ngx_restart) {//重啟
ngx_restart = 0;
ngx_start_worker_processes(cycle, ccf->worker_processes,
NGX_PROCESS_RESPAWN);
ngx_start_cache_manager_processes(cycle, 0);
live = 1;
}
if (ngx_reopen) {//重新打開文件
ngx_reopen = 0;
ngx_log_error(NGX_LOG_NOTICE, cycle->log, 0, "reopening logs");
ngx_reopen_files(cycle, ccf->user);
ngx_signal_worker_processes(cycle,
ngx_signal_value(NGX_REOPEN_SIGNAL));
}
/*
檢查ngx_change_binary標(biāo)志位,如果ngx_change_binary為1,則表示需要平滑升級(jí)Nginx,這時(shí)將調(diào)用ngx_exec_new_binary方法用新的子
進(jìn)程啟動(dòng)新版本的Nginx程序, 同時(shí)將ngx_change_binary標(biāo)志位置為0。
*/
if (ngx_change_binary) {
ngx_change_binary = 0;
ngx_log_error(NGX_LOG_NOTICE, cycle->log, 0, "changing binary");
ngx_new_binary = ngx_exec_new_binary(cycle, ngx_argv);
}
if (ngx_noaccept) {//不進(jìn)行accept
ngx_noaccept = 0;
ngx_noaccepting = 1;
ngx_signal_worker_processes(cycle,
ngx_signal_value(NGX_SHUTDOWN_SIGNAL));//退出子進(jìn)程
}
}
}
static void
ngx_start_worker_processes(ngx_cycle_t *cycle, ngx_int_t n, ngx_int_t type)
{
ngx_int_t i;
ngx_channel_t ch;
ngx_log_error(NGX_LOG_NOTICE, cycle->log, 0, "start worker processes");
ngx_memzero(&ch, sizeof(ngx_channel_t));
ch.command = NGX_CMD_OPEN_CHANNEL;
for (i = 0; i < n; i++) {//n是配置的worker 數(shù)量
ngx_spawn_process(cycle, ngx_worker_process_cycle,
(void *) (intptr_t) i, "worker process", type);
ch.pid = ngx_processes[ngx_process_slot].pid;//配置當(dāng)前的channel
ch.slot = ngx_process_slot;
ch.fd = ngx_processes[ngx_process_slot].channel[0];
// 把該子進(jìn)程的相關(guān)channel信息傳遞給已經(jīng)創(chuàng)建好的其他所有子進(jìn)程
ngx_pass_open_channel(cycle, &ch);
}
}
/*
在Nginx中,如果啟用了proxy(fastcgi) cache功能,master process會(huì)在啟動(dòng)的時(shí)候啟動(dòng)管理緩存的兩個(gè)子進(jìn)程(區(qū)別于處理請(qǐng)求的子進(jìn)程)來管理內(nèi)
存和磁盤的緩存?zhèn)€體。第一個(gè)進(jìn)程的功能是定期檢查緩存,并將過期的緩存刪除;第二個(gè)進(jìn)程的作用是在啟動(dòng)的時(shí)候?qū)⒋疟P中已經(jīng)緩存的個(gè)
體映射到內(nèi)存中(目前Nginx設(shè)定為啟動(dòng)以后60秒),然后退出。
具體的,在這兩個(gè)進(jìn)程的ngx_process_events_and_timers()函數(shù)中,會(huì)調(diào)用ngx_event_expire_timers()。Nginx的ngx_event_timer_rbtree(紅黑樹)里
面按照?qǐng)?zhí)行的時(shí)間的先后存放著一系列的事件。每次取執(zhí)行時(shí)間最早的事件,如果當(dāng)前時(shí)間已經(jīng)到了應(yīng)該執(zhí)行該事件,就會(huì)調(diào)用事件的handler。兩個(gè)
進(jìn)程的handler分別是ngx_cache_manager_process_handler和ngx_cache_loader_process_handler
*/
static void
ngx_start_cache_manager_processes(ngx_cycle_t *cycle, ngx_uint_t respawn)
{
ngx_uint_t i, manager, loader;
ngx_path_t **path;
ngx_channel_t ch;
manager = 0;
loader = 0;
path = ngx_cycle->paths.elts;
for (i = 0; i < ngx_cycle->paths.nelts; i++) {
if (path[i]->manager) {
manager = 1;
}
if (path[i]->loader) {
loader = 1;
}
}
if (manager == 0) {
return;
}
ngx_spawn_process(cycle, ngx_cache_manager_process_cycle,
&ngx_cache_manager_ctx, "cache manager process",
respawn ? NGX_PROCESS_JUST_RESPAWN : NGX_PROCESS_RESPAWN);//第一個(gè)函數(shù)
ngx_memzero(&ch, sizeof(ngx_channel_t));
ch.command = NGX_CMD_OPEN_CHANNEL;
ch.pid = ngx_processes[ngx_process_slot].pid;
ch.slot = ngx_process_slot;
ch.fd = ngx_processes[ngx_process_slot].channel[0];
ngx_pass_open_channel(cycle, &ch);//通知
if (loader == 0) {
return;
}
ngx_spawn_process(cycle, ngx_cache_manager_process_cycle,
&ngx_cache_loader_ctx, "cache loader process",
respawn ? NGX_PROCESS_JUST_SPAWN : NGX_PROCESS_NORESPAWN);
ch.command = NGX_CMD_OPEN_CHANNEL;
ch.pid = ngx_processes[ngx_process_slot].pid;
ch.slot = ngx_process_slot;
ch.fd = ngx_processes[ngx_process_slot].channel[0];
ngx_pass_open_channel(cycle, &ch);//通知
}
到這里我們所有關(guān)于master worker的東西都差不多了。補(bǔ)充一個(gè)外部像master發(fā)送命令 比如我們的nginx -s stop
像master發(fā)送命令
比如我們的 nginx -s stop 等等命令 其實(shí)這些命令在發(fā)送的時(shí)候是重新開了一個(gè)nginx的進(jìn)程,在解析完命令的時(shí)候,發(fā)現(xiàn)這個(gè)是用來執(zhí)行命令的 這個(gè)時(shí)候就會(huì)調(diào)用 ngx_signal_process 發(fā)送命令
其實(shí)很簡(jiǎn)單,就只是讀取pidfile文件獲取pid 然后通過kill像nginx發(fā)送命令。就不寫了