////////////////////////////////////////////////////////////////////////////// // // (C) Copyright Ion Gaztanaga 2005-2012. Distributed under the Boost // Software License, Version 1.0. (See accompanying file // LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt) // // See http://www.boost.org/libs/interprocess for documentation. // ////////////////////////////////////////////////////////////////////////////// #ifndef BOOST_INTERPROCESS_DETAIL_SPIN_CONDITION_HPP #define BOOST_INTERPROCESS_DETAIL_SPIN_CONDITION_HPP #ifndef BOOST_CONFIG_HPP # include #endif # #if defined(BOOST_HAS_PRAGMA_ONCE) # pragma once #endif #include #include #include #include #include #include #include #include #include #include #include namespace boost { namespace interprocess { namespace ipcdetail { class spin_condition { spin_condition(const spin_condition &); spin_condition &operator=(const spin_condition &); public: spin_condition(); ~spin_condition(); void notify_one(); void notify_all(); template bool timed_wait(L& lock, const boost::posix_time::ptime &abs_time) { if (!lock) throw lock_exception(); //Handle infinity absolute time here to avoid complications in do_timed_wait if(abs_time.is_pos_infinity()){ this->wait(lock); return true; } return this->do_timed_wait(abs_time, *lock.mutex()); } template bool timed_wait(L& lock, const boost::posix_time::ptime &abs_time, Pr pred) { if (!lock) throw lock_exception(); //Handle infinity absolute time here to avoid complications in do_timed_wait if(abs_time.is_pos_infinity()){ this->wait(lock, pred); return true; } while (!pred()){ if (!this->do_timed_wait(abs_time, *lock.mutex())) return pred(); } return true; } template void wait(L& lock) { if (!lock) throw lock_exception(); do_wait(*lock.mutex()); } template void wait(L& lock, Pr pred) { if (!lock) throw lock_exception(); while (!pred()) do_wait(*lock.mutex()); } template void do_wait(InterprocessMutex &mut); template bool do_timed_wait(const boost::posix_time::ptime &abs_time, InterprocessMutex &mut); private: template bool do_timed_wait(bool tout_enabled, const boost::posix_time::ptime &abs_time, InterprocessMutex &mut); enum { SLEEP = 0, NOTIFY_ONE, NOTIFY_ALL }; spin_mutex m_enter_mut; volatile boost::uint32_t m_command; volatile boost::uint32_t m_num_waiters; void notify(boost::uint32_t command); }; inline spin_condition::spin_condition() { //Note that this class is initialized to zero. //So zeroed memory can be interpreted as an initialized //condition variable m_command = SLEEP; m_num_waiters = 0; } inline spin_condition::~spin_condition() { //Notify all waiting threads //to allow POSIX semantics on condition destruction this->notify_all(); } inline void spin_condition::notify_one() { this->notify(NOTIFY_ONE); } inline void spin_condition::notify_all() { this->notify(NOTIFY_ALL); } inline void spin_condition::notify(boost::uint32_t command) { //This mutex guarantees that no other thread can enter to the //do_timed_wait method logic, so that thread count will be //constant until the function writes a NOTIFY_ALL command. //It also guarantees that no other notification can be signaled //on this spin_condition before this one ends m_enter_mut.lock(); //Return if there are no waiters if(!atomic_read32(&m_num_waiters)) { m_enter_mut.unlock(); return; } //Notify that all threads should execute wait logic spin_wait swait; while(SLEEP != atomic_cas32(const_cast(&m_command), command, SLEEP)){ swait.yield(); } //The enter mutex will rest locked until the last waiting thread unlocks it } template inline void spin_condition::do_wait(InterprocessMutex &mut) { this->do_timed_wait(false, boost::posix_time::ptime(), mut); } template inline bool spin_condition::do_timed_wait (const boost::posix_time::ptime &abs_time, InterprocessMutex &mut) { return this->do_timed_wait(true, abs_time, mut); } template inline bool spin_condition::do_timed_wait(bool tout_enabled, const boost::posix_time::ptime &abs_time, InterprocessMutex &mut) { boost::posix_time::ptime now = microsec_clock::universal_time(); if(tout_enabled){ if(now >= abs_time) return false; } typedef boost::interprocess::scoped_lock InternalLock; //The enter mutex guarantees that while executing a notification, //no other thread can execute the do_timed_wait method. { //--------------------------------------------------------------- InternalLock lock; if(tout_enabled){ InternalLock dummy(m_enter_mut, abs_time); lock = boost::move(dummy); } else{ InternalLock dummy(m_enter_mut); lock = boost::move(dummy); } if(!lock) return false; //--------------------------------------------------------------- //We increment the waiting thread count protected so that it will be //always constant when another thread enters the notification logic. //The increment marks this thread as "waiting on spin_condition" atomic_inc32(const_cast(&m_num_waiters)); //We unlock the external mutex atomically with the increment mut.unlock(); } //By default, we suppose that no timeout has happened bool timed_out = false, unlock_enter_mut= false; //Loop until a notification indicates that the thread should //exit or timeout occurs while(1){ //The thread sleeps/spins until a spin_condition commands a notification //Notification occurred, we will lock the checking mutex so that spin_wait swait; while(atomic_read32(&m_command) == SLEEP){ swait.yield(); //Check for timeout if(tout_enabled){ now = microsec_clock::universal_time(); if(now >= abs_time){ //If we can lock the mutex it means that no notification //is being executed in this spin_condition variable timed_out = m_enter_mut.try_lock(); //If locking fails, indicates that another thread is executing //notification, so we play the notification game if(!timed_out){ //There is an ongoing notification, we will try again later continue; } //No notification in execution, since enter mutex is locked. //We will execute time-out logic, so we will decrement count, //release the enter mutex and return false. break; } } } //If a timeout occurred, the mutex will not execute checking logic if(tout_enabled && timed_out){ //Decrement wait count atomic_dec32(const_cast(&m_num_waiters)); unlock_enter_mut = true; break; } else{ boost::uint32_t result = atomic_cas32 (const_cast(&m_command), SLEEP, NOTIFY_ONE); if(result == SLEEP){ //Other thread has been notified and since it was a NOTIFY one //command, this thread must sleep again continue; } else if(result == NOTIFY_ONE){ //If it was a NOTIFY_ONE command, only this thread should //exit. This thread has atomically marked command as sleep before //so no other thread will exit. //Decrement wait count. unlock_enter_mut = true; atomic_dec32(const_cast(&m_num_waiters)); break; } else{ //If it is a NOTIFY_ALL command, all threads should return //from do_timed_wait function. Decrement wait count. unlock_enter_mut = 1 == atomic_dec32(const_cast(&m_num_waiters)); //Check if this is the last thread of notify_all waiters //Only the last thread will release the mutex if(unlock_enter_mut){ atomic_cas32(const_cast(&m_command), SLEEP, NOTIFY_ALL); } break; } } } //Unlock the enter mutex if it is a single notification, if this is //the last notified thread in a notify_all or a timeout has occurred if(unlock_enter_mut){ m_enter_mut.unlock(); } //Lock external again before returning from the method mut.lock(); return !timed_out; } } //namespace ipcdetail } //namespace interprocess } //namespace boost #include #endif //BOOST_INTERPROCESS_DETAIL_SPIN_CONDITION_HPP