本文實例講述了PHP信號量基本用法。分享給大家供大家參考,具體如下:
一些理論基礎:
信號量:又稱為信號燈、旗語 用來解決進程(線程同步的問題),類似於一把鎖,訪問前獲取鎖(獲取不到則等待),訪問後釋放鎖。
臨界資源:每次僅允許一個進程訪問的資源。
臨界區:每個進程中訪問臨界資源的那段代碼叫臨界區
進程互斥:兩個或以上的進程不能同時進入關於同一組共享變量的臨界區域,即一個進程正在訪問臨界資源,另一個進程要想訪問必須等待。
進程同步主要研究如何確定數個進程之間的執行順序和避免數據競爭的問題 即,如何讓多個進程能一塊很好的協作運行
舉例子:(來自百度百科)
以一個停車場的運作為例。簡單起見,假設停車場只有三個車位,一開始三個車位都是空的。這時如果同時來了五輛車,看門人允許其中三輛直接進入,然後放下車攔,剩下的車則必須在入口等待,此後來的車也都不得不在入口處等待。這時,有一輛車離開停車場,看門人得知後,打開車攔,放入外面的一輛進去,如果又離開兩輛,則又可以放入兩輛,如此往復。
在這個停車場系統中,車位是公共資源,每輛車好比一個線程,看門人起的就是信號量的作用。
$key=ftok(__FILE__,'t'); /** * 獲取一個信號量資源 int $key [, int $max_acquire = 1 [, int $perm = 0666 [, int $auto_release = 1 ]]] $max_acquire:最多可以多少個進程同時獲取信號 $perm:權限 默認 0666 $auto_release:是否自動釋放信號量 */ $sem_id=sem_get($key); #獲取信號 sem_acquire($seg_id); //do something 這裡是一個原子性操作 //釋放信號量 sem_release($seg_id); //把次信號從系統中移除 sem_remove($sem_id); //可能出現的問題 $fp = sem_get(fileinode(__DIR__), 100); sem_acquire($fp); $fp2 = sem_get(fileinode(__DIR__), 1)); sem_acquire($fp2);
Implementation of a read-write semaphore in PHP:
class rw_semaphore { const READ_ACCESS = 0; const WRITE_ACCESS = 1; /** * @access private * @var resource - mutex semaphore */ private $mutex; /** * @access private * @var resource - read/write semaphore */ private $resource; /** * @access private * @var int */ private $writers = 0; /** * @access private * @var int */ private $readers = 0; /** * Default constructor * * Initialize the read/write semaphore */ public function __construct() { $mutex_key = ftok('/home/cyrus/development/php/sysvipc/rw_semaphore.php', 'm'); $resource_key = ftok('/home/cyrus/development/php/sysvipc/rw_semaphore.php', 'r'); $this->mutex = sem_get($mutex_key, 1); $this->resource = sem_get($resource_key, 1); } /** * Destructor * * Remove the read/write semaphore */ public function __destruct() { sem_remove($this->mutex); sem_remove($this->resource); } /** * Request acess to the resource * * @param int $mode * @return void */ private function request_access($access_type = self::READ_ACCESS) { if ($access_type == self::WRITE_ACCESS) { sem_acquire($this->mutex); /* update the writers counter */ $this->writers++; sem_release($this->mutex); sem_acquire($this->resource); } else { sem_acquire($this->mutex); if ($this->writers > 0 || $this->readers == 0) { sem_release($this->mutex); sem_acquire($this->resource); sem_acquire($this->mutex); } /* update the readers counter */ $this->readers++; sem_release($this->mutex); } } private function request_release($access_type = self::READ_ACCESS) { if ($access_type == self::WRITE_ACCESS) { sem_acquire($this->mutex); /* update the writers counter */ $this->writers--; sem_release($this->mutex); sem_release($this->resource); } else { sem_acquire($this->mutex); /* update the readers counter */ $this->readers--; if ($this->readers == 0) sem_release($this->resource); sem_release($this->mutex); } } /** * Request read access to the resource * * @return void */ public function read_access() { $this->request_access(self::READ_ACCESS); } /** * Release read access to the resource * * @return void */ public function read_release() { $this->request_release(self::READ_ACCESS); } /** * Request write access to the resource * * @return void */ public function write_access() { $this->request_access(self::WRITE_ACCESS); } /** * Release write access to the resource * * @return void */ public function write_release() { $this->request_release(self::WRITE_ACCESS); } }
共享內存+信號 實現原子性操作
$SHM_KEY = ftok("/home/joeldg/homeymail/shmtest.php", 'R'); $shmid = sem_get($SHM_KEY, 1024, 0644 | IPC_CREAT); $data = shm_attach($shmid, 1024); // we now have our shm segment // lets place a variable in there shm_put_var ($data, $inmem, "test"); // now lets get it back. we could be in a forked process and still have // access to this variable. printf("shared contents: %s\n", shm_get_var($data, $inmem)); shm_detach($data);
以上列子來源php手冊 sem_get 函數comment
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