内容简介:Swoole 源码分析——Server 模块之 Start
Server 的启动
- 在
server启动之前,swoole首先要调用php_swoole_register_callback将PHP的回调函数注册到server的对象函数中去 - 之后调用
php_swoole_server_before_start创建swReactorThread数组对象、workers进程池对象 - 最后调用
swServer_start函数创建reactor线程,work、manager等进程,开启事件循环
PHP_METHOD(swoole_server, start)
{
zval *zobject = getThis();
int ret;
swServer *serv = swoole_get_object(getThis());
if (serv->gs->start > 0)
{
swoole_php_fatal_error(E_WARNING, "server is running. unable to execute swoole_server->start.");
RETURN_FALSE;
}
php_swoole_register_callback(serv);
//-------------------------------------------------------------
serv->onReceive = php_swoole_onReceive;
php_swoole_server_before_start(serv, zobject TSRMLS_CC);
ret = swServer_start(serv);
if (ret < 0)
{
swoole_php_fatal_error(E_ERROR, "failed to start server. Error: %s", sw_error);
RETURN_LONG(ret);
}
RETURN_TRUE;
}
注册 PHP 回调函数
void php_swoole_register_callback(swServer *serv)
{
/*
* optional callback
*/
if (php_sw_server_callbacks[SW_SERVER_CB_onStart] != NULL)
{
serv->onStart = php_swoole_onStart;
}
serv->onShutdown = php_swoole_onShutdown;
/**
* require callback, set the master/manager/worker PID
*/
serv->onWorkerStart = php_swoole_onWorkerStart;
if (php_sw_server_callbacks[SW_SERVER_CB_onWorkerStop] != NULL)
{
serv->onWorkerStop = php_swoole_onWorkerStop;
}
if (php_sw_server_callbacks[SW_SERVER_CB_onWorkerExit] != NULL)
{
serv->onWorkerExit = php_swoole_onWorkerExit;
}
/**
* UDP Packet
*/
if (php_sw_server_callbacks[SW_SERVER_CB_onPacket] != NULL)
{
serv->onPacket = php_swoole_onPacket;
}
/**
* Task Worker
*/
if (php_sw_server_callbacks[SW_SERVER_CB_onTask] != NULL)
{
serv->onTask = php_swoole_onTask;
}
if (php_sw_server_callbacks[SW_SERVER_CB_onFinish] != NULL)
{
serv->onFinish = php_swoole_onFinish;
}
if (php_sw_server_callbacks[SW_SERVER_CB_onWorkerError] != NULL)
{
serv->onWorkerError = php_swoole_onWorkerError;
}
if (php_sw_server_callbacks[SW_SERVER_CB_onManagerStart] != NULL)
{
serv->onManagerStart = php_swoole_onManagerStart;
}
if (php_sw_server_callbacks[SW_SERVER_CB_onManagerStop] != NULL)
{
serv->onManagerStop = php_swoole_onManagerStop;
}
if (php_sw_server_callbacks[SW_SERVER_CB_onPipeMessage] != NULL)
{
serv->onPipeMessage = php_swoole_onPipeMessage;
}
if (php_sw_server_callbacks[SW_SERVER_CB_onBufferFull] != NULL)
{
serv->onBufferFull = php_swoole_onBufferFull;
}
if (php_sw_server_callbacks[SW_SERVER_CB_onBufferEmpty] != NULL || serv->send_yield)
{
serv->onBufferEmpty = php_swoole_onBufferEmpty;
}
}
创建 reactor 线程池对象与 work 进程池对象
php_swoole_server_before_start主要调用swServer_create函数swServer_create函数主要任务是swReactorThread_create创建reactor多线程
void php_swoole_server_before_start(swServer *serv, zval *zobject TSRMLS_DC)
{
/**
* create swoole server
*/
if (swServer_create(serv) < 0)
{
swoole_php_fatal_error(E_ERROR, "failed to create the server. Error: %s", sw_error);
return;
}
}
int swServer_create(swServer *serv)
{
if (SwooleG.main_reactor)
{
swoole_error_log(SW_LOG_ERROR, SW_ERROR_SERVER_MUST_CREATED_BEFORE_CLIENT, "The swoole_server must create before client");
return SW_ERR;
}
SwooleG.factory = &serv->factory;
serv->factory.ptr = serv;
/**
* init current time
*/
swServer_update_time(serv);
#ifdef SW_REACTOR_USE_SESSION
serv->session_list = sw_shm_calloc(SW_SESSION_LIST_SIZE, sizeof(swSession));
if (serv->session_list == NULL)
{
swError("sw_shm_calloc(%ld) for session_list failed", SW_SESSION_LIST_SIZE * sizeof(swSession));
return SW_ERR;
}
#endif
if (serv->factory_mode == SW_MODE_SINGLE)
{
return swReactorProcess_create(serv);
}
else
{
return swReactorThread_create(serv);
}
}swReactorThread_create 创建线程池对象
- 函数首先申请内存构建
reactor_threads用于存储多线程的各种信息,创建connection_list保存已建立连接的socket信息 - 利用
swFactoryThread_create创建reactor多线程
int swReactorThread_create(swServer *serv)
{
int ret = 0;
/**
* init reactor thread pool
*/
serv->reactor_threads = SwooleG.memory_pool->alloc(SwooleG.memory_pool, (serv->reactor_num * sizeof(swReactorThread)));
if (serv->reactor_threads == NULL)
{
swError("calloc[reactor_threads] fail.alloc_size=%d", (int )(serv->reactor_num * sizeof(swReactorThread)));
return SW_ERR;
}
/**
* alloc the memory for connection_list
*/
if (serv->factory_mode == SW_MODE_PROCESS)
{
serv->connection_list = sw_shm_calloc(serv->max_connection, sizeof(swConnection));
}
else
{
serv->connection_list = sw_calloc(serv->max_connection, sizeof(swConnection));
}
//create factry object
if (serv->factory_mode == SW_MODE_PROCESS)
{
if (serv->worker_num < 1)
{
swError("Fatal Error: serv->worker_num < 1");
return SW_ERR;
}
ret = swFactoryProcess_create(&(serv->factory), serv->worker_num);
}
if (ret < 0)
{
swError("create factory failed");
return SW_ERR;
}
return SW_OK;
}
swFactoryProcess_create 创建进程池对象
int swFactoryProcess_create(swFactory *factory, int worker_num)
{
swFactoryProcess *object;
object = SwooleG.memory_pool->alloc(SwooleG.memory_pool, sizeof(swFactoryProcess));
if (object == NULL)
{
swWarn("[Master] malloc[object] failed");
return SW_ERR;
}
factory->object = object;
factory->dispatch = swFactoryProcess_dispatch;
factory->finish = swFactoryProcess_finish;
factory->start = swFactoryProcess_start;
factory->notify = swFactoryProcess_notify;
factory->shutdown = swFactoryProcess_shutdown;
factory->end = swFactoryProcess_end;
return SW_OK;
}
swServer_start 函数
swServer_start函数是启动整个swoole的关键swServer_start_check函数用于检查各种回调函数已经被正确设置- 如果当前
swoole是守护程序(daemonize),那么要设置日志输出目录,调用daemon函数设置自身进程会话 - 从内存池中申请构建
worker对象,设置全局共享对象event_workers - 申请
reactor线程的buffer_input - 如果存在
task_worker进程,那么申请worker进程与task_worker进程用于通讯的pipe - 如果存在用户
task进程,要设置用户task进程的id factory->start(factory)启动创建manager、worker、task_worker、user_task_worker进程swServer_signal_init进行信号初始化swServer_start_proxy创建reactor多线程,开启事件循环
int swServer_start(swServer *serv)
{
swFactory *factory = &serv->factory;
int ret;
ret = swServer_start_check(serv);
if (ret < 0)
{
return SW_ERR;
}
if (SwooleG.hooks[SW_GLOBAL_HOOK_BEFORE_SERVER_START])
{
swoole_call_hook(SW_GLOBAL_HOOK_BEFORE_SERVER_START, serv);
}
//cann't start 2 servers at the same time, please use process->exec.
if (!sw_atomic_cmp_set(&serv->gs->start, 0, 1))
{
swoole_error_log(SW_LOG_ERROR, SW_ERROR_SERVER_ONLY_START_ONE, "must only start one server.");
return SW_ERR;
}
//init loggger
if (SwooleG.log_file)
{
swLog_init(SwooleG.log_file);
}
//run as daemon
if (serv->daemonize > 0)
{
/**
* redirect STDOUT to log file
*/
if (SwooleG.log_fd > STDOUT_FILENO)
{
swoole_redirect_stdout(SwooleG.log_fd);
}
/**
* redirect STDOUT_FILENO/STDERR_FILENO to /dev/null
*/
else
{
SwooleG.null_fd = open("/dev/null", O_WRONLY);
if (SwooleG.null_fd > 0)
{
swoole_redirect_stdout(SwooleG.null_fd);
}
else
{
swoole_error_log(SW_LOG_ERROR, SW_ERROR_SYSTEM_CALL_FAIL, "open(/dev/null) failed. Error: %s[%d]", strerror(errno), errno);
}
}
if (daemon(0, 1) < 0)
{
return SW_ERR;
}
}
//master pid
serv->gs->master_pid = getpid();
serv->gs->now = serv->stats->start_time = time(NULL);
serv->send = swServer_tcp_send;
serv->sendwait = swServer_tcp_sendwait;
serv->sendfile = swServer_tcp_sendfile;
serv->close = swServer_tcp_close;
serv->workers = SwooleG.memory_pool->alloc(SwooleG.memory_pool, serv->worker_num * sizeof(swWorker));
if (serv->workers == NULL)
{
swoole_error_log(SW_LOG_ERROR, SW_ERROR_SYSTEM_CALL_FAIL, "gmalloc[server->workers] failed.");
return SW_ERR;
}
/**
* store to swProcessPool object
*/
serv->gs->event_workers.workers = serv->workers;
serv->gs->event_workers.worker_num = serv->worker_num;
serv->gs->event_workers.use_msgqueue = 0;
int i;
for (i = 0; i < serv->worker_num; i++)
{
serv->gs->event_workers.workers[i].pool = &serv->gs->event_workers;
}
#ifdef SW_USE_RINGBUFFER
for (i = 0; i < serv->reactor_num; i++)
{
serv->reactor_threads[i].buffer_input = swRingBuffer_new(SwooleG.serv->buffer_input_size, 1);
if (!serv->reactor_threads[i].buffer_input)
{
return SW_ERR;
}
}
#endif
/*
* For swoole_server->taskwait, create notify pipe and result shared memory.
*/
if (serv->task_worker_num > 0 && serv->worker_num > 0)
{
serv->task_result = sw_shm_calloc(serv->worker_num, sizeof(swEventData));
serv->task_notify = sw_calloc(serv->worker_num, sizeof(swPipe));
for (i = 0; i < serv->worker_num; i++)
{
if (swPipeNotify_auto(&serv->task_notify[i], 1, 0))
{
return SW_ERR;
}
}
}
/**
* user worker process
*/
if (serv->user_worker_list)
{
swUserWorker_node *user_worker;
i = 0;
LL_FOREACH(serv->user_worker_list, user_worker)
{
user_worker->worker->id = serv->worker_num + serv->task_worker_num + i;
i++;
}
}
//factory start
if (factory->start(factory) < 0)
{
return SW_ERR;
}
//signal Init
swServer_signal_init(serv);
//write PID file
if (serv->pid_file)
{
ret = snprintf(SwooleTG.buffer_stack->str, SwooleTG.buffer_stack->size, "%d", getpid());
swoole_file_put_contents(serv->pid_file, SwooleTG.buffer_stack->str, ret);
}
if (serv->factory_mode == SW_MODE_SINGLE)
{
ret = swReactorProcess_start(serv);
}
else
{
ret = swServer_start_proxy(serv);
}
swServer_free(serv);
serv->gs->start = 0;
//remove PID file
if (serv->pid_file)
{
unlink(serv->pid_file);
}
return SW_OK;
}
daemon
如果想要进程 daemon 化,必要的步骤如下:
- 切换目录为根目录
- 将
stdin,stdout,stderr重定向到/dev/null fork开启一个新进程- 退出父进程,在子进程中开启一个新的会话
int daemon(int nochdir, int noclose)
{
pid_t pid;
if (!nochdir && chdir("/") != 0)
{
swWarn("chdir() failed. Error: %s[%d]", strerror(errno), errno);
return -1;
}
if (!noclose)
{
int fd = open("/dev/null", O_RDWR);
if (fd < 0)
{
swWarn("open() failed. Error: %s[%d]", strerror(errno), errno);
return -1;
}
if (dup2(fd, 0) < 0 || dup2(fd, 1) < 0 || dup2(fd, 2) < 0)
{
close(fd);
swWarn("dup2() failed. Error: %s[%d]", strerror(errno), errno);
return -1;
}
close(fd);
}
pid = fork();
if (pid < 0)
{
swWarn("fork() failed. Error: %s[%d]", strerror(errno), errno);
return -1;
}
if (pid > 0)
{
_exit(0);
}
if (setsid() < 0)
{
swWarn("setsid() failed. Error: %s[%d]", strerror(errno), errno);
return -1;
}
return 0;
}
factory->start 开启 manager、work 进程
swServer_get_worker函数用于从event_workersswWorker_create函数用于初始化send_shm、lockswManager_start函数用于启动manager进程
static int swFactoryProcess_start(swFactory *factory)
{
int i;
swServer *serv = factory->ptr;
swWorker *worker;
for (i = 0; i < serv->worker_num; i++)
{
worker = swServer_get_worker(serv, i);
if (swWorker_create(worker) < 0)
{
return SW_ERR;
}
}
serv->reactor_pipe_num = serv->worker_num / serv->reactor_num;
//必须先启动manager进程组,否则会带线程fork
if (swManager_start(factory) < 0)
{
swWarn("swFactoryProcess_manager_start failed.");
return SW_ERR;
}
//主进程需要设置为直写模式
factory->finish = swFactory_finish;
return SW_OK;
}
static sw_inline swWorker* swServer_get_worker(swServer *serv, uint16_t worker_id)
{
//Event Worker
if (worker_id < serv->worker_num)
{
return &(serv->gs->event_workers.workers[worker_id]);
}
//Task Worker
uint16_t task_worker_max = serv->task_worker_num + serv->worker_num;
if (worker_id < task_worker_max)
{
return &(serv->gs->task_workers.workers[worker_id - serv->worker_num]);
}
//User Worker
uint16_t user_worker_max = task_worker_max + serv->user_worker_num;
if (worker_id < user_worker_max)
{
return &(serv->user_workers[worker_id - task_worker_max]);
}
return NULL;
}
int swWorker_create(swWorker *worker)
{
/**
* Create shared memory storage
*/
worker->send_shm = sw_shm_malloc(SwooleG.serv->buffer_output_size);
if (worker->send_shm == NULL)
{
swWarn("malloc for worker->store failed.");
return SW_ERR;
}
swMutex_create(&worker->lock, 1);
return SW_OK;
}
swManager_start 函数
- 首先需要准备好
pipes作为master进程与worker进行的通讯管道 - 设置每个
worker进程的pipe_master(master进程向worker进程传递消息)、pipe_worker(worker进程向master进程传递消息) - 如果存在
task_worker进程,需要调用swServer_create_task_worker函数创建serv->gs->task_workers,之后将对其进行初始化 - 如果存在
user_workers进程,那么就要创建相应的serv->user_workers,并初始化 - 调用
fork,启动manager进程 - 在
manager进程中,调用swServer_close_listen_port关闭监听的socket - 对于
task_worker进程,利用swProcessPool_start启动task_worker进程 - 对于
worker进程,调用swManager_spawn_worker启动worker进程 - 对于
user_worker进程,调用swManager_spawn_user_worker启动user_worker进程 - 调用
swManager_loop进行事件循环,管理worker等进程
void swServer_store_pipe_fd(swServer *serv, swPipe *p)
{
int master_fd = p->getFd(p, SW_PIPE_MASTER);
serv->connection_list[p->getFd(p, SW_PIPE_WORKER)].object = p;
serv->connection_list[master_fd].object = p;
if (master_fd > swServer_get_minfd(serv))
{
swServer_set_minfd(serv, master_fd);
}
}
int swManager_start(swFactory *factory)
{
swFactoryProcess *object = factory->object;
int i;
pid_t pid;
swServer *serv = factory->ptr;
object->pipes = sw_calloc(serv->worker_num, sizeof(swPipe));
if (object->pipes == NULL)
{
swError("malloc[worker_pipes] failed. Error: %s [%d]", strerror(errno), errno);
return SW_ERR;
}
//worker进程的pipes
for (i = 0; i < serv->worker_num; i++)
{
if (swPipeUnsock_create(&object->pipes[i], 1, SOCK_DGRAM) < 0)
{
return SW_ERR;
}
serv->workers[i].pipe_master = object->pipes[i].getFd(&object->pipes[i], SW_PIPE_MASTER);
serv->workers[i].pipe_worker = object->pipes[i].getFd(&object->pipes[i], SW_PIPE_WORKER);
serv->workers[i].pipe_object = &object->pipes[i];
swServer_store_pipe_fd(serv, serv->workers[i].pipe_object);
}
if (serv->task_worker_num > 0)
{
if (swServer_create_task_worker(serv) < 0)
{
return SW_ERR;
}
swProcessPool *pool = &serv->gs->task_workers;
swTaskWorker_init(pool);
swWorker *worker;
for (i = 0; i < serv->task_worker_num; i++)
{
worker = &pool->workers[i];
if (swWorker_create(worker) < 0)
{
return SW_ERR;
}
if (serv->task_ipc_mode == SW_TASK_IPC_UNIXSOCK)
{
swServer_store_pipe_fd(SwooleG.serv, worker->pipe_object);
}
}
}
//User Worker Process
if (serv->user_worker_num > 0)
{
serv->user_workers = SwooleG.memory_pool->alloc(SwooleG.memory_pool, serv->user_worker_num * sizeof(swWorker));
if (serv->user_workers == NULL)
{
swoole_error_log(SW_LOG_ERROR, SW_ERROR_SYSTEM_CALL_FAIL, "gmalloc[server->user_workers] failed.");
return SW_ERR;
}
swUserWorker_node *user_worker;
i = 0;
LL_FOREACH(serv->user_worker_list, user_worker)
{
memcpy(&serv->user_workers[i], user_worker->worker, sizeof(swWorker));
if (swWorker_create(&serv->user_workers[i]) < 0)
{
return SW_ERR;
}
i++;
}
}
serv->message_box = swChannel_new(65536, sizeof(swWorkerStopMessage), SW_CHAN_LOCK | SW_CHAN_SHM);
if (serv->message_box == NULL)
{
return SW_ERR;
}
pid = fork();
switch (pid)
{
//fork manager process
case 0:
//wait master process
SW_START_SLEEP;
if (serv->gs->start == 0)
{
return SW_OK;
}
swServer_close_listen_port(serv);
/**
* create task worker process
*/
if (serv->task_worker_num > 0)
{
swProcessPool_start(&serv->gs->task_workers);
}
/**
* create worker process
*/
for (i = 0; i < serv->worker_num; i++)
{
//close(worker_pipes[i].pipes[0]);
pid = swManager_spawn_worker(factory, i);
if (pid < 0)
{
swError("fork() failed.");
return SW_ERR;
}
else
{
serv->workers[i].pid = pid;
}
}
/**
* create user worker process
*/
if (serv->user_worker_list)
{
swUserWorker_node *user_worker;
LL_FOREACH(serv->user_worker_list, user_worker)
{
/**
* store the pipe object
*/
if (user_worker->worker->pipe_object)
{
swServer_store_pipe_fd(serv, user_worker->worker->pipe_object);
}
swManager_spawn_user_worker(serv, user_worker->worker);
}
}
SwooleG.process_type = SW_PROCESS_MANAGER;
SwooleG.pid = getpid();
exit(swManager_loop(factory));
break;
//master process
default:
serv->gs->manager_pid = pid;
break;
case -1:
swError("fork() failed.");
return SW_ERR;
}
return SW_OK;
}
swManager_spawn_worker 启动 worker 进程
static pid_t swManager_spawn_worker(swFactory *factory, int worker_id)
{
pid_t pid;
int ret;
pid = fork();
//fork() failed
if (pid < 0)
{
swWarn("Fork Worker failed. Error: %s [%d]", strerror(errno), errno);
return SW_ERR;
}
//worker child processor
else if (pid == 0)
{
ret = swWorker_loop(factory, worker_id);
exit(ret);
}
//parent,add to writer
else
{
return pid;
}
}
swManager_spawn_user_worker 启动 user_worker 进程
pid_t swManager_spawn_user_worker(swServer *serv, swWorker* worker)
{
pid_t pid = fork();
if (pid < 0)
{
swWarn("Fork Worker failed. Error: %s [%d]", strerror(errno), errno);
return SW_ERR;
}
//child
else if (pid == 0)
{
SwooleG.process_type = SW_PROCESS_USERWORKER;
SwooleWG.worker = worker;
SwooleWG.id = worker->id;
worker->pid = getpid();
//close tcp listen socket
if (serv->factory_mode == SW_MODE_SINGLE)
{
swServer_close_port(serv, SW_TRUE);
}
serv->onUserWorkerStart(serv, worker);
exit(0);
}
//parent
else
{
if (worker->pid)
{
swHashMap_del_int(serv->user_worker_map, worker->pid);
}
worker->pid = pid;
swHashMap_add_int(serv->user_worker_map, pid, worker);
return pid;
}
}
swServer_start_proxy 开启 reactor 多线程
- 直到这个时候,
main_reactor才真正的被创建出来,并进行初始化 - 如果当前系统支持
signalfd,那么就要调用swSignalfd_setup函数对signalfd进行初始化 - 对于
listen_list里面的tcp监听socket,需要调用swPort_listen进行监听 stream_fd是为了worker准备的,对于master进程,直接关闭即可swReactorThread_start函数用于创建reactor线程- 如果系统不支持时间轮算法,那么就要利用
swHeartbeatThread_start启动一个进程,专门踢掉空闲的连接 - 对于定时任务,利用
swTimer_init初始化SwooleG.timer - 设置
master主线程的线程特有数据 - 利用
main_reactor->wait等待新的连接
static int swServer_start_proxy(swServer *serv)
{
int ret;
swReactor *main_reactor = SwooleG.memory_pool->alloc(SwooleG.memory_pool, sizeof(swReactor));
ret = swReactor_create(main_reactor, SW_REACTOR_MAXEVENTS);
if (ret < 0)
{
swWarn("Reactor create failed");
return SW_ERR;
}
main_reactor->thread = 1;
main_reactor->socket_list = serv->connection_list;
main_reactor->disable_accept = 0;
main_reactor->enable_accept = swServer_enable_accept;
#ifdef HAVE_SIGNALFD
if (SwooleG.use_signalfd)
{
swSignalfd_setup(main_reactor);
}
#endif
//set listen socket options
swListenPort *ls;
LL_FOREACH(serv->listen_list, ls)
{
if (swSocket_is_dgram(ls->type))
{
continue;
}
if (swPort_listen(ls) < 0)
{
return SW_ERR;
}
}
if (serv->stream_fd > 0)
{
close(serv->stream_fd);
}
/**
* create reactor thread
*/
ret = swReactorThread_start(serv, main_reactor);
if (ret < 0)
{
swWarn("ReactorThread start failed");
return SW_ERR;
}
#ifndef SW_USE_TIMEWHEEL
/**
* heartbeat thread
*/
if (serv->heartbeat_check_interval >= 1 && serv->heartbeat_check_interval <= serv->heartbeat_idle_time)
{
swTrace("hb timer start, time: %d live time:%d", serv->heartbeat_check_interval, serv->heartbeat_idle_time);
swHeartbeatThread_start(serv);
}
#endif
/**
* master thread loop
*/
SwooleTG.type = SW_THREAD_MASTER;
SwooleTG.factory_target_worker = -1;
SwooleTG.factory_lock_target = 0;
SwooleTG.id = serv->reactor_num;
SwooleTG.update_time = 1;
SwooleG.main_reactor = main_reactor;
SwooleG.pid = getpid();
SwooleG.process_type = SW_PROCESS_MASTER;
/**
* set a special id
*/
main_reactor->id = serv->reactor_num;
main_reactor->ptr = serv;
main_reactor->setHandle(main_reactor, SW_FD_LISTEN, swServer_master_onAccept);
if (serv->hooks[SW_SERVER_HOOK_MASTER_START])
{
swServer_call_hook(serv, SW_SERVER_HOOK_MASTER_START, serv);
}
/**
* init timer
*/
if (swTimer_init(1000) < 0)
{
return SW_ERR;
}
/**
* 1 second timer, update serv->gs->now
*/
if (SwooleG.timer.add(&SwooleG.timer, 1000, 1, serv, swServer_master_onTimer) == NULL)
{
return SW_ERR;
}
if (serv->onStart != NULL)
{
serv->onStart(serv);
}
return main_reactor->wait(main_reactor, NULL);
}
swPort_listen 开启端口监听
tcp_defer_accept:当一个TCP连接有数据发送时才触发accepttcp_fastopen: 开启TCP快速握手特性。此项特性,可以提升TCP短连接的响应速度,在客户端完成握手的第三步,发送SYN包时携带数据。open_tcp_keepalive: 在TCP中有一个Keep-Alive的机制可以检测死连接,应用层如果对于死链接周期不敏感或者没有实现心跳机制,可以使用操作系统提供的keepalive机制来踢掉死链接。buffer_high_watermark是缓存区高水位线,达到了说明缓冲区即将满了
int swPort_listen(swListenPort *ls)
{
int sock = ls->sock;
int option = 1;
//listen stream socket
if (listen(sock, ls->backlog) < 0)
{
swWarn("listen(%s:%d, %d) failed. Error: %s[%d]", ls->host, ls->port, ls->backlog, strerror(errno), errno);
return SW_ERR;
}
#ifdef TCP_DEFER_ACCEPT
if (ls->tcp_defer_accept)
{
if (setsockopt(sock, IPPROTO_TCP, TCP_DEFER_ACCEPT, (const void*) &ls->tcp_defer_accept, sizeof(int)) < 0)
{
swSysError("setsockopt(TCP_DEFER_ACCEPT) failed.");
}
}
#endif
#ifdef TCP_FASTOPEN
if (ls->tcp_fastopen)
{
if (setsockopt(sock, IPPROTO_TCP, TCP_FASTOPEN, (const void*) &ls->tcp_fastopen, sizeof(int)) < 0)
{
swSysError("setsockopt(TCP_FASTOPEN) failed.");
}
}
#endif
#ifdef SO_KEEPALIVE
if (ls->open_tcp_keepalive == 1)
{
if (setsockopt(sock, SOL_SOCKET, SO_KEEPALIVE, (void *) &option, sizeof(option)) < 0)
{
swSysError("setsockopt(SO_KEEPALIVE) failed.");
}
#ifdef TCP_KEEPIDLE
setsockopt(sock, IPPROTO_TCP, TCP_KEEPIDLE, (void*) &ls->tcp_keepidle, sizeof(int));
setsockopt(sock, IPPROTO_TCP, TCP_KEEPINTVL, (void *) &ls->tcp_keepinterval, sizeof(int));
setsockopt(sock, IPPROTO_TCP, TCP_KEEPCNT, (void *) &ls->tcp_keepcount, sizeof(int));
#endif
}
#endif
ls->buffer_high_watermark = ls->socket_buffer_size * 0.8;
ls->buffer_low_watermark = 0;
return SW_OK;
}
swReactorThread_start 创建 reactor 线程
swServer_store_listen_socket函数用于将监控的socket存放于connection_list中- 向
main_reactor中添加监听的socket文件描述符 pthread_barrier_init、pthread_barrier_wait等待所有的reactor线程开启事件循环- 利用
pthread_create创建reactor线程,线程启动函数是swReactorThread_loop
int swReactorThread_start(swServer *serv, swReactor *main_reactor_ptr)
{
swThreadParam *param;
swReactorThread *thread;
pthread_t pidt;
int i;
swServer_store_listen_socket(serv);
#ifdef HAVE_REUSEPORT
SwooleG.reuse_port = 0;
#endif
swListenPort *ls;
LL_FOREACH(serv->listen_list, ls)
{
if (ls->type == SW_SOCK_UDP || ls->type == SW_SOCK_UDP6 || ls->type == SW_SOCK_UNIX_DGRAM)
{
continue;
}
main_reactor_ptr->add(main_reactor_ptr, ls->sock, SW_FD_LISTEN);
}
#ifdef HAVE_PTHREAD_BARRIER
//init thread barrier
pthread_barrier_init(&serv->barrier, NULL, serv->reactor_num + 1);
#endif
//create reactor thread
for (i = 0; i < serv->reactor_num; i++)
{
thread = &(serv->reactor_threads[i]);
param = SwooleG.memory_pool->alloc(SwooleG.memory_pool, sizeof(swThreadParam));
if (param == NULL)
{
swError("malloc failed");
return SW_ERR;
}
param->object = serv;
param->pti = i;
if (pthread_create(&pidt, NULL, (void * (*)(void *)) swReactorThread_loop, (void *) param) < 0)
{
swError("pthread_create[tcp_reactor] failed. Error: %s[%d]", strerror(errno), errno);
}
thread->thread_id = pidt;
}
#ifdef HAVE_PTHREAD_BARRIER
//wait reactor thread
pthread_barrier_wait(&serv->barrier);
#else
SW_START_SLEEP;
#endif
return SW_OK;
}
swServer_store_listen_socket 保存监听
- 本函数将用于监听的
socket存放到connection_list当中,并设置相应的info属性;
void swServer_store_listen_socket(swServer *serv)
{
swListenPort *ls;
int sockfd;
LL_FOREACH(serv->listen_list, ls)
{
sockfd = ls->sock;
//save server socket to connection_list
serv->connection_list[sockfd].fd = sockfd;
//socket type
serv->connection_list[sockfd].socket_type = ls->type;
//save listen_host object
serv->connection_list[sockfd].object = ls;
if (swSocket_is_dgram(ls->type))
{
if (ls->type == SW_SOCK_UDP)
{
serv->connection_list[sockfd].info.addr.inet_v4.sin_port = htons(ls->port);
}
else if (ls->type == SW_SOCK_UDP6)
{
SwooleG.serv->udp_socket_ipv6 = sockfd;
serv->connection_list[sockfd].info.addr.inet_v6.sin6_port = htons(ls->port);
}
}
else
{
//IPv4
if (ls->type == SW_SOCK_TCP)
{
serv->connection_list[sockfd].info.addr.inet_v4.sin_port = htons(ls->port);
}
//IPv6
else if (ls->type == SW_SOCK_TCP6)
{
serv->connection_list[sockfd].info.addr.inet_v6.sin6_port = htons(ls->port);
}
}
if (sockfd >= 0)
{
swServer_set_minfd(serv, sockfd);
swServer_set_maxfd(serv, sockfd);
}
}
}
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