// $Id$ #ifndef ACE_TIMER_QUEUE_T_C #define ACE_TIMER_QUEUE_T_C #include "ace/Synch.h" #if !defined (ACE_LACKS_PRAGMA_ONCE) # pragma once #endif /* ACE_LACKS_PRAGMA_ONCE */ #include "ace/Signal.h" #include "ace/Timer_Queue_T.h" #include "ace/Log_Msg.h" #if !defined (__ACE_INLINE__) #include "ace/Timer_Queue_T.i" #endif /* __ACE_INLINE__ */ ACE_RCSID(ace, Timer_Queue_T, "$Id$") template void ACE_Timer_Node_T::dump (void) const { ACE_TRACE ("ACE_Timer_Node_T::dump"); ACE_DEBUG ((LM_DEBUG, ACE_BEGIN_DUMP, this)); ACE_DEBUG ((LM_DEBUG, ACE_TEXT ("\nact_ = %x"), this->act_)); this->timer_value_.dump (); this->interval_.dump (); ACE_DEBUG ((LM_DEBUG, ACE_TEXT ("\nprev_ = %x"), this->prev_)); ACE_DEBUG ((LM_DEBUG, ACE_TEXT ("\nnext_ = %x"), this->next_)); ACE_DEBUG ((LM_DEBUG, ACE_TEXT ("\ntimer_id_ = %d\n"), this->timer_id_)); ACE_DEBUG ((LM_DEBUG, ACE_END_DUMP)); } template ACE_Timer_Node_T::ACE_Timer_Node_T (void) { ACE_TRACE ("ACE_Timer_Node_T::ACE_Timer_Node_T"); } template ACE_Timer_Node_T::~ACE_Timer_Node_T (void) { ACE_TRACE ("ACE_Timer_Node_T::~ACE_Timer_Node_T"); } template ACE_Timer_Queue_Iterator_T::ACE_Timer_Queue_Iterator_T (void) { } template ACE_Timer_Queue_Iterator_T::~ACE_Timer_Queue_Iterator_T (void) { } // Determines the minimum amount of time that the Reactor must wait // before timing out. This is computed as the smaller of (1) the // amount the caller requested when calling handle_events() and (2) // the earliest time registered in the Timer Queue (if any). Must be // called with an external lock held since it returns a pointer to a // Time_Value type stored in the Timer_Queue type itself. If some // external lock isn't held we'll have reentrancy problems! template ACE_Time_Value * ACE_Timer_Queue_T::calculate_timeout (ACE_Time_Value *max_wait_time) { ACE_TRACE ("ACE_Timer_Queue_T::calculate_timeout"); ACE_MT (ACE_GUARD_RETURN (ACE_LOCK, ace_mon, this->mutex_, max_wait_time)); if (this->is_empty ()) // Nothing on the Timer_Queue, so use whatever the caller gave us. return max_wait_time; else { ACE_Time_Value cur_time = this->gettimeofday (); if (this->earliest_time () > cur_time) { // The earliest item on the Timer_Queue is still in the // future. Therefore, use the smaller of (1) caller's wait // time or (2) the delta time between now and the earliest // time on the Timer_Queue. this->timeout_ = this->earliest_time () - cur_time; if (max_wait_time == 0 || *max_wait_time > timeout_) return &this->timeout_; else return max_wait_time; } else { // The earliest item on the Timer_Queue is now in the past. // Therefore, we've got to "poll" the Reactor, i.e., it must // just check the descriptors and then dispatch timers, etc. this->timeout_ = ACE_Time_Value::zero; return &this->timeout_; } } } template ACE_Time_Value * ACE_Timer_Queue_T::calculate_timeout (ACE_Time_Value *max_wait_time, ACE_Time_Value *the_timeout) { ACE_TRACE ("ACE_Timer_Queue_T::calculate_timeout"); if (the_timeout == 0) return 0; if (this->is_empty ()) { // Nothing on the Timer_Queue, so use whatever the caller gave us. if (max_wait_time) *the_timeout = *max_wait_time; else return 0; } else { ACE_Time_Value cur_time = this->gettimeofday (); if (this->earliest_time () > cur_time) { // The earliest item on the Timer_Queue is still in the // future. Therefore, use the smaller of (1) caller's wait // time or (2) the delta time between now and the earliest // time on the Timer_Queue. *the_timeout = this->earliest_time () - cur_time; if (!(max_wait_time == 0 || *max_wait_time > *the_timeout)) *the_timeout = *max_wait_time; } else { // The earliest item on the Timer_Queue is now in the past. // Therefore, we've got to "poll" the Reactor, i.e., it must // just check the descriptors and then dispatch timers, etc. *the_timeout = ACE_Time_Value::zero; } } return the_timeout; } template void ACE_Timer_Queue_T::dump (void) const { ACE_TRACE ("ACE_Timer_Queue_T::dump"); ACE_DEBUG ((LM_DEBUG, ACE_BEGIN_DUMP, this)); this->timeout_.dump (); this->timer_skew_.dump (); ACE_DEBUG ((LM_DEBUG, ACE_END_DUMP)); } template ACE_Timer_Queue_T::ACE_Timer_Queue_T (FUNCTOR *upcall_functor, ACE_Free_List > *freelist) : free_list_ (freelist == 0 ? new ACE_Locked_Free_List, ACE_Null_Mutex> : freelist), gettimeofday_ (ACE_OS::gettimeofday), upcall_functor_ (upcall_functor == 0 ? new FUNCTOR : upcall_functor), delete_upcall_functor_ (upcall_functor == 0), delete_free_list_ (freelist == 0), timer_skew_ (0, ACE_TIMER_SKEW) { ACE_TRACE ("ACE_Timer_Queue_T::ACE_Timer_Queue_T"); } template ACE_Timer_Queue_T::~ACE_Timer_Queue_T (void) { ACE_TRACE ("ACE_Timer_Queue_T::~ACE_Timer_Queue_T"); // Cleanup the functor and free_list on the way out if (this->delete_upcall_functor_) delete this->upcall_functor_; if (this->delete_free_list_) delete this->free_list_; } template ACE_Timer_Node_T * ACE_Timer_Queue_T::alloc_node (void) { return this->free_list_->remove (); } template void ACE_Timer_Queue_T::free_node (ACE_Timer_Node_T *node) { this->free_list_->add (node); } template ACE_LOCK & ACE_Timer_Queue_T::mutex (void) { return this->mutex_; } // Run the method for all Timers whose values are <= // . template int ACE_Timer_Queue_T::expire (const ACE_Time_Value &cur_time) { ACE_TRACE ("ACE_Timer_Queue_T::expire"); ACE_MT (ACE_GUARD_RETURN (ACE_LOCK, ace_mon, this->mutex_, -1)); int number_of_timers_expired = 0; ACE_Timer_Node_T *expired; // Keep looping while there are timers remaining and the earliest // timer is <= the passed in to the method. if (this->is_empty ()) return 0; while (this->earliest_time () <= cur_time) { expired = this->remove_first (); TYPE &type = expired->get_type (); const void *act = expired->get_act (); int reclaim = 1; // Check if this is an interval timer. if (expired->get_interval () > ACE_Time_Value::zero) { // Make sure that we skip past values that have already // "expired". do expired->set_timer_value (expired->get_timer_value () + expired->get_interval ()); while (expired->get_timer_value () <= cur_time); // Since this is an interval timer, we need to reschedule // it. this->reschedule (expired); reclaim = 0; } // call the functor this->upcall (type, act, cur_time); if (reclaim) // Call the factory method to free up the node. this->free_node (expired); number_of_timers_expired++; if (this->is_empty ()) break; } return number_of_timers_expired; } template void ACE_Timer_Queue_T::return_node (ACE_Timer_Node_T *node) { ACE_MT (ACE_GUARD (ACE_LOCK, ace_mon, this->mutex_)); this->free_node (node); } template ACE_Event_Handler_Handle_Timeout_Upcall::ACE_Event_Handler_Handle_Timeout_Upcall (void) { } template ACE_Event_Handler_Handle_Timeout_Upcall::~ACE_Event_Handler_Handle_Timeout_Upcall (void) { } template int ACE_Event_Handler_Handle_Timeout_Upcall::timeout (ACE_Timer_Queue_T, ACE_LOCK> &timer_queue, ACE_Event_Handler *handler, const void *act, const ACE_Time_Value &cur_time) { // Upcall to the s handle_timeout method. if (handler->handle_timeout (cur_time, act) == -1) timer_queue.cancel (handler, 0); // 0 means "call handle_close()". return 0; } template int ACE_Event_Handler_Handle_Timeout_Upcall::cancellation (ACE_Timer_Queue_T, ACE_LOCK> &timer_queue, ACE_Event_Handler *handler) { ACE_UNUSED_ARG (timer_queue); // Upcall to the s handle_close method handler->handle_close (ACE_INVALID_HANDLE, ACE_Event_Handler::TIMER_MASK); return 0; } template int ACE_Event_Handler_Handle_Timeout_Upcall::deletion (ACE_Timer_Queue_T, ACE_LOCK> &timer_queue, ACE_Event_Handler *handler, const void *arg) { ACE_UNUSED_ARG (timer_queue); ACE_UNUSED_ARG (handler); ACE_UNUSED_ARG (arg); // Does nothing return 0; } #endif /* ACE_TIMER_QUEUE_T_C*/