// Perform an extensive test of all the ACE_Reactor's event handler // dispatching mechanisms. These mechanisms illustrate how I/O, // timeout, and signal events, as well as ACE_Message_Queues, can all // be handled within the same demultiplexing and dispatching // framework. In addition, this example illustrates how to use the // ACE_Reactor for devices that perform I/O via signals (such as SVR4 // message queues). #include "ace/ACE.h" #include "ace/Service_Config.h" #include "ace/Reactor.h" #include "ace/Task.h" #include "ace/Reactor_Notification_Strategy.h" #include "ace/Signal.h" #include "ace/OS_NS_fcntl.h" #include "ace/OS_NS_unistd.h" // Default is to have a 2 second timeout. static int timeout = 2; // This class illustrates how to handle signal-driven I/O using // the framework. Note that signals may be caught // and processed without requiring the use of global signal // handler functions or global signal handler data. class Sig_Handler : public ACE_Event_Handler { public: Sig_Handler (); virtual ACE_HANDLE get_handle () const; virtual int handle_input (ACE_HANDLE); //FUZZ: disable check_for_lack_ACE_OS virtual int shutdown (ACE_HANDLE, ACE_Reactor_Mask); //FUZZ: enable check_for_lack_ACE_OS virtual int handle_signal (int signum, siginfo_t * = 0, ucontext_t * = 0); private: ACE_HANDLE handle_; }; // A dummy_handle is required to reserve a slot in the ACE_Reactor's // descriptor table. Sig_Handler::Sig_Handler () { // Assign the Sig_Handler a dummy I/O descriptor. Note that even // though we open this file "Write Only" we still need to use the // ACE_Event_Handler::NULL_MASK when registering this with the // ACE_Reactor (see below). this->handle_ = ACE_OS::open (ACE_DEV_NULL, O_WRONLY); ACE_ASSERT (this->handle_ != ACE_INVALID_HANDLE); // Register signal handler object. Note that NULL_MASK is used to // keep the ACE_Reactor from calling us back on the "/dev/null" // descriptor. NULL_MASK just reserves a "slot" in the Reactor's // internal demuxing table, but doesn't cause it to dispatch the // event handler directly. Instead, we use the signal handler to do // this. ACE_Reactor_Mask mask = ACE_Event_Handler::NULL_MASK; if (ACE_Reactor::instance ()->register_handler (this, mask) == -1) ACE_ERROR ((LM_ERROR, "%p\n%a", "register_handler", 1)); // Create a sigset_t corresponding to the signals we want to catch. ACE_Sig_Set sig_set; sig_set.sig_add (SIGINT); sig_set.sig_add (SIGQUIT); sig_set.sig_add (SIGALRM); // Register the signal handler object to catch the signals. if (ACE_Reactor::instance ()->register_handler (sig_set, this) == -1) ACE_ERROR ((LM_ERROR, "%p\n%a", "register_handler", 1)); } // Called by the ACE_Reactor to extract the handle. ACE_HANDLE Sig_Handler::get_handle () const { return this->handle_; } // In a real application, this method would be where the read on the // signal-driven I/O device would occur asynchronously. For now we'll // just print a greeting to let you know that everything is working // properly! int Sig_Handler::handle_input (ACE_HANDLE) { ACE_DEBUG ((LM_DEBUG, "(%t) handling asynchonrous input...\n")); return 0; } // In a real application, this method would do any cleanup activities // required when shutting down the I/O device. int Sig_Handler::shutdown (ACE_HANDLE, ACE_Reactor_Mask) { ACE_DEBUG ((LM_DEBUG, "(%t) closing down Sig_Handler...\n")); return 0; } // This method handles all the signals that are being caught by this // object. In our simple example, we are simply catching SIGALRM, // SIGINT, and SIGQUIT. Anything else is logged and ignored. Note // that the ACE_Reactor's signal handling mechanism eliminates the // need to use global signal handler functions and data. int Sig_Handler::handle_signal (int signum, siginfo_t *, ucontext_t *) { switch (signum) { #if !defined (ACE_WIN32) case SIGALRM: // Rearm the alarm. ACE_OS::alarm (4); break; #endif /* !ACE_WIN32 */ case SIGINT: // Tell the ACE_Reactor to enable the ready bit for // this->handle_. The ACE_Reactor will subsequently call the // method from within its event // loop, i.e., the behavior triggered by the signal is handled // in the main event loop, rather than in the signal handler. return ACE_Reactor::instance ()->ready_ops (this->handle_, ACE_Event_Handler::READ_MASK, ACE_Reactor::ADD_MASK); #if defined (SIGTERM) && (SIGTERM != 0) case SIGTERM: // This is coded thusly to avoid problems if SIGQUIT is a legit // value but is not a preprocessor macro. #elif !defined (SIGQUIT) || (SIGQUIT != 0) case SIGQUIT: #endif /* SIGTERM != 0 */ ACE_Reactor::end_event_loop (); break; default: ACE_ERROR_RETURN ((LM_ERROR, "invalid signal"), -1); /* NOTREACHED */ } return 0; } class STDIN_Handler : public ACE_Event_Handler { // = TITLE // This class illustrates that the ACE_Reactor can handle signals, // STDIO, and timeouts using the same mechanisms. public: STDIN_Handler (void); ~STDIN_Handler (void); virtual int handle_input (ACE_HANDLE); virtual int handle_timeout (const ACE_Time_Value &, const void *arg); }; STDIN_Handler::STDIN_Handler (void) { if (ACE_Event_Handler::register_stdin_handler (this, ACE_Reactor::instance (), ACE_Thread_Manager::instance ()) == -1) ACE_ERROR ((LM_ERROR, "%p\n", "register_stdin_handler")); // Register the to be dispatched once every // seconds starting in seconds. This example // uses the "interval timer" feature of the 's timer // queue. else if (ACE_Reactor::instance ()->schedule_timer (this, 0, ACE_Time_Value (timeout), ACE_Time_Value (timeout)) == -1) ACE_ERROR ((LM_ERROR, "%p\n%a", "schedule_timer", 1)); } STDIN_Handler::~STDIN_Handler (void) { if (ACE_Event_Handler::remove_stdin_handler (ACE_Reactor::instance (), ACE_Thread_Manager::instance ()) == -1) ACE_ERROR ((LM_ERROR, "%p\n", "remove_stdin_handler")); else if (ACE_Reactor::instance ()->cancel_timer (this) == -1) ACE_ERROR ((LM_ERROR, "%p\n%a", "cancel_timer", 1)); } int STDIN_Handler::handle_timeout (const ACE_Time_Value &tv, const void *) { ACE_DEBUG ((LM_DEBUG, "(%t) timeout occurred at %d sec, %d usec\n", tv.sec (), tv.usec ())); return 0; } // Read from input handle and write to stdout handle. int STDIN_Handler::handle_input (ACE_HANDLE handle) { char buf[BUFSIZ]; ssize_t n = ACE_OS::read (handle, buf, sizeof buf); switch (n) { case -1: if (errno == EINTR) return 0; /* NOTREACHED */ else ACE_ERROR ((LM_ERROR, "%p\n", "read")); ACE_FALLTHROUGH; case 0: ACE_Reactor::end_event_loop (); break; default: { ssize_t result = ACE::write_n (ACE_STDOUT, buf, n); if (result != n) ACE_ERROR_RETURN ((LM_ERROR, "%p\n", "write"), result == -1 && errno == EINTR ? 0 : -1); } } return 0; } class Message_Handler : public ACE_Task { public: Message_Handler (void); virtual int handle_input (ACE_HANDLE); // Called back within the context of the Singleton to // dequeue and process the message on the . virtual int svc (); // Run the "event-loop" periodically putting messages to our // internal that we inherit from . private: ACE_Reactor_Notification_Strategy notification_strategy_; // This strategy will notify the Singleton when a new // message is enqueued. }; Message_Handler::Message_Handler (void) : notification_strategy_ (ACE_Reactor::instance (), this, ACE_Event_Handler::READ_MASK) { // Set this to the Reactor notification strategy. this->msg_queue ()->notification_strategy (&this->notification_strategy_); if (this->activate ()) ACE_ERROR ((LM_ERROR, "%p\n", "activate")); } int Message_Handler::svc (void) { for (int i = 0;; i++) { ACE_Message_Block *mb = 0; ACE_NEW_RETURN (mb, ACE_Message_Block (1), 0); mb->msg_priority (i); ACE_OS::sleep (1); // Note that this putq() call with automagically invoke the // notify() hook of our ACE_Reactor_Notification_Strategy, // thereby informing the Singleton to call our // method. if (this->putq (mb) == -1) { if (errno == ESHUTDOWN) ACE_ERROR_RETURN ((LM_ERROR, "(%t) queue is deactivated"), 0); else ACE_ERROR_RETURN ((LM_ERROR, "(%t) %p\n", "putq"), -1); } } ACE_NOTREACHED (return 0); } int Message_Handler::handle_input (ACE_HANDLE) { ACE_DEBUG ((LM_DEBUG, "(%t) Message_Handler::handle_input\n")); ACE_Message_Block *mb = 0; if (this->getq (mb, (ACE_Time_Value *) &ACE_Time_Value::zero) == -1) ACE_ERROR ((LM_ERROR, "(%t) %p\n", "dequeue_head")); else { ACE_DEBUG ((LM_DEBUG, "(%t) priority = %d\n", mb->msg_priority ())); mb->release (); } return 0; } int ACE_TMAIN (int argc, ACE_TCHAR *argv[]) { ACE_Service_Config daemon (argv [0]); // Optionally start the alarm. if (argc > 1) { ACE_OS::alarm (4); timeout = ACE_OS::atoi (argv[1]); } // Signal handler. Sig_Handler sh; // Define an I/O handler object. STDIN_Handler ioh; // Define a message handler. Message_Handler mh; // Loop handling signals and I/O events until SIGQUIT occurs. while (ACE_Reactor::instance ()->event_loop_done () == 0) ACE_Reactor::instance ()->run_reactor_event_loop (); // Deactivate the message queue. mh.msg_queue ()->deactivate (); // Wait for the thread to exit. ACE_Thread_Manager::instance ()->wait (); ACE_DEBUG ((LM_DEBUG, ACE_TEXT ("(%t) leaving main\n"))); return 0; }