lib/cpp/src/concurrency/TimerManager.cpp - thrift - Git at Google

 /*
  * Licensed to the Apache Software Foundation (ASF) under one
  * or more contributor license agreements. See the NOTICE file
  * distributed with this work for additional information
  * regarding copyright ownership. The ASF licenses this file
  * to you under the Apache License, Version 2.0 (the
  * "License"); you may not use this file except in compliance
  * with the License. You may obtain a copy of the License at
  *
  *   http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing,
  * software distributed under the License is distributed on an
  * "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY
  * KIND, either express or implied. See the License for the
  * specific language governing permissions and limitations
  * under the License.
  */

 #include "TimerManager.h"
 #include "Exception.h"
 #include "Util.h"

 #include <assert.h>
 #include <iostream>
 #include <set>

 namespace apache { namespace thrift { namespace concurrency {

 using boost::shared_ptr;

 typedef std::multimap<int64_t, shared_ptr<TimerManager::Task> >::iterator task_iterator;
 typedef std::pair<task_iterator, task_iterator> task_range;

 /**
  * TimerManager class
  *
  * @version $Id:$
  */
 class TimerManager::Task : public Runnable {

  public:
   enum STATE {
     WAITING,
     EXECUTING,
     CANCELLED,
     COMPLETE
   };

   Task(shared_ptr<Runnable> runnable) :
     runnable_(runnable),
     state_(WAITING) {}

   ~Task() {
   }

   void run() {
     if (state_ == EXECUTING) {
       runnable_->run();
       state_ = COMPLETE;
     }
   }

  private:
   shared_ptr<Runnable> runnable_;
   class TimerManager::Dispatcher;
   friend class TimerManager::Dispatcher;
   STATE state_;
 };

 class TimerManager::Dispatcher: public Runnable {

  public:
   Dispatcher(TimerManager* manager) :
     manager_(manager) {}

   ~Dispatcher() {}

   /**
    * Dispatcher entry point
    *
    * As long as dispatcher thread is running, pull tasks off the task taskMap_
    * and execute.
    */
   void run() {
     {
       Synchronized s(manager_->monitor_);
       if (manager_->state_ == TimerManager::STARTING) {
         manager_->state_ = TimerManager::STARTED;
         manager_->monitor_.notifyAll();
       }
     }

     do {
       std::set<shared_ptr<TimerManager::Task> > expiredTasks;
       {
         Synchronized s(manager_->monitor_);
         task_iterator expiredTaskEnd;
         int64_t now = Util::currentTime();
         while (manager_->state_ == TimerManager::STARTED &&
                (expiredTaskEnd = manager_->taskMap_.upper_bound(now)) == manager_->taskMap_.begin()) {
           int64_t timeout = 0LL;
           if (!manager_->taskMap_.empty()) {
             timeout = manager_->taskMap_.begin()->first - now;
           }
           assert((timeout != 0 && manager_->taskCount_ > 0) || (timeout == 0 && manager_->taskCount_ == 0));
           try {
             manager_->monitor_.wait(timeout);
           } catch (TimedOutException &e) {}
           now = Util::currentTime();
         }

         if (manager_->state_ == TimerManager::STARTED) {
           for (task_iterator ix = manager_->taskMap_.begin(); ix != expiredTaskEnd; ix++) {
             shared_ptr<TimerManager::Task> task = ix->second;
             expiredTasks.insert(task);
             if (task->state_ == TimerManager::Task::WAITING) {
               task->state_ = TimerManager::Task::EXECUTING;
             }
             manager_->taskCount_--;
           }
           manager_->taskMap_.erase(manager_->taskMap_.begin(), expiredTaskEnd);
         }
       }

       for (std::set<shared_ptr<Task> >::iterator ix =  expiredTasks.begin(); ix != expiredTasks.end(); ix++) {
         (*ix)->run();
       }

     } while (manager_->state_ == TimerManager::STARTED);

     {
       Synchronized s(manager_->monitor_);
       if (manager_->state_ == TimerManager::STOPPING) {
         manager_->state_ = TimerManager::STOPPED;
         manager_->monitor_.notify();
       }
     }
     return;
   }

  private:
   TimerManager* manager_;
   friend class TimerManager;
 };

 TimerManager::TimerManager() :
   taskCount_(0),
   state_(TimerManager::UNINITIALIZED),
   dispatcher_(shared_ptr<Dispatcher>(new Dispatcher(this))) {
 }


 TimerManager::~TimerManager() {

   // If we haven't been explicitly stopped, do so now.  We don't need to grab
   // the monitor here, since stop already takes care of reentrancy.

   if (state_ != STOPPED) {
     try {
       stop();
     } catch(...) {
       throw;
       // uhoh
     }
   }
 }

 void TimerManager::start() {
   bool doStart = false;
   {
     Synchronized s(monitor_);
     if (threadFactory_ == NULL) {
       throw InvalidArgumentException();
     }
     if (state_ == TimerManager::UNINITIALIZED) {
       state_ = TimerManager::STARTING;
       doStart = true;
     }
   }

   if (doStart) {
     dispatcherThread_ = threadFactory_->newThread(dispatcher_);
     dispatcherThread_->start();
   }

   {
     Synchronized s(monitor_);
     while (state_ == TimerManager::STARTING) {
       monitor_.wait();
     }
     assert(state_ != TimerManager::STARTING);
   }
 }

 void TimerManager::stop() {
   bool doStop = false;
   {
     Synchronized s(monitor_);
     if (state_ == TimerManager::UNINITIALIZED) {
       state_ = TimerManager::STOPPED;
     } else if (state_ != STOPPING &&  state_ != STOPPED) {
       doStop = true;
       state_ = STOPPING;
       monitor_.notifyAll();
     }
     while (state_ != STOPPED) {
       monitor_.wait();
     }
   }

   if (doStop) {
     // Clean up any outstanding tasks
     for (task_iterator ix =  taskMap_.begin(); ix != taskMap_.end(); ix++) {
       taskMap_.erase(ix);
     }

     // Remove dispatcher's reference to us.
     dispatcher_->manager_ = NULL;
   }
 }

 shared_ptr<const ThreadFactory> TimerManager::threadFactory() const {
   Synchronized s(monitor_);
   return threadFactory_;
 }

 void TimerManager::threadFactory(shared_ptr<const ThreadFactory>  value) {
   Synchronized s(monitor_);
   threadFactory_ = value;
 }

 size_t TimerManager::taskCount() const {
   return taskCount_;
 }

 void TimerManager::add(shared_ptr<Runnable> task, int64_t timeout) {
   int64_t now = Util::currentTime();
   timeout += now;

   {
     Synchronized s(monitor_);
     if (state_ != TimerManager::STARTED) {
       throw IllegalStateException();
     }

     taskCount_++;
     taskMap_.insert(std::pair<int64_t, shared_ptr<Task> >(timeout, shared_ptr<Task>(new Task(task))));

     // If the task map was empty, or if we have an expiration that is earlier
     // than any previously seen, kick the dispatcher so it can update its
     // timeout
     if (taskCount_ == 1 || timeout < taskMap_.begin()->first) {
       monitor_.notify();
     }
   }
 }

 void TimerManager::add(shared_ptr<Runnable> task, const struct timespec& value) {

   int64_t expiration;
   Util::toMilliseconds(expiration, value);

   int64_t now = Util::currentTime();

   if (expiration < now) {
     throw  InvalidArgumentException();
   }

   add(task, expiration - now);
 }


 void TimerManager::remove(shared_ptr<Runnable> task) {
   Synchronized s(monitor_);
   if (state_ != TimerManager::STARTED) {
     throw IllegalStateException();
   }
 }

 const TimerManager::STATE TimerManager::state() const { return state_; }

 }}} // apache::thrift::concurrency
	/*
	* Licensed to the Apache Software Foundation (ASF) under one
	* or more contributor license agreements. See the NOTICE file
	* distributed with this work for additional information
	* regarding copyright ownership. The ASF licenses this file
	* to you under the Apache License, Version 2.0 (the
	* "License"); you may not use this file except in compliance
	* with the License. You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing,
	* software distributed under the License is distributed on an
	* "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY
	* KIND, either express or implied. See the License for the
	* specific language governing permissions and limitations
	* under the License.
	*/

	#include "TimerManager.h"
	#include "Exception.h"
	#include "Util.h"

	#include <assert.h>
	#include <iostream>
	#include <set>

	namespace apache { namespace thrift { namespace concurrency {

	using boost::shared_ptr;

	typedef std::multimap<int64_t, shared_ptr<TimerManager::Task> >::iterator task_iterator;
	typedef std::pair<task_iterator, task_iterator> task_range;

	/**
	* TimerManager class
	*
	* @version $Id:$
	*/
	class TimerManager::Task : public Runnable {

	public:
	enum STATE {
	WAITING,
	EXECUTING,
	CANCELLED,
	COMPLETE
	};

	Task(shared_ptr<Runnable> runnable) :
	runnable_(runnable),
	state_(WAITING) {}

	~Task() {
	}

	void run() {
	if (state_ == EXECUTING) {
	runnable_->run();
	state_ = COMPLETE;
	}
	}

	private:
	shared_ptr<Runnable> runnable_;
	class TimerManager::Dispatcher;
	friend class TimerManager::Dispatcher;
	STATE state_;
	};

	class TimerManager::Dispatcher: public Runnable {

	public:
	Dispatcher(TimerManager* manager) :
	manager_(manager) {}

	~Dispatcher() {}

	/**
	* Dispatcher entry point
	*
	* As long as dispatcher thread is running, pull tasks off the task taskMap_
	* and execute.
	*/
	void run() {
	{
	Synchronized s(manager_->monitor_);
	if (manager_->state_ == TimerManager::STARTING) {
	manager_->state_ = TimerManager::STARTED;
	manager_->monitor_.notifyAll();
	}
	}

	do {
	std::set<shared_ptr<TimerManager::Task> > expiredTasks;
	{
	Synchronized s(manager_->monitor_);
	task_iterator expiredTaskEnd;
	int64_t now = Util::currentTime();
	while (manager_->state_ == TimerManager::STARTED &&
	(expiredTaskEnd = manager_->taskMap_.upper_bound(now)) == manager_->taskMap_.begin()) {
	int64_t timeout = 0LL;
	if (!manager_->taskMap_.empty()) {
	timeout = manager_->taskMap_.begin()->first - now;
	}
	assert((timeout != 0 && manager_->taskCount_ > 0) \|\| (timeout == 0 && manager_->taskCount_ == 0));
	try {
	manager_->monitor_.wait(timeout);
	} catch (TimedOutException &e) {}
	now = Util::currentTime();
	}

	if (manager_->state_ == TimerManager::STARTED) {
	for (task_iterator ix = manager_->taskMap_.begin(); ix != expiredTaskEnd; ix++) {
	shared_ptr<TimerManager::Task> task = ix->second;
	expiredTasks.insert(task);
	if (task->state_ == TimerManager::Task::WAITING) {
	task->state_ = TimerManager::Task::EXECUTING;
	}
	manager_->taskCount_--;
	}
	manager_->taskMap_.erase(manager_->taskMap_.begin(), expiredTaskEnd);
	}
	}

	for (std::set<shared_ptr<Task> >::iterator ix = expiredTasks.begin(); ix != expiredTasks.end(); ix++) {
	(*ix)->run();
	}

	} while (manager_->state_ == TimerManager::STARTED);

	{
	Synchronized s(manager_->monitor_);
	if (manager_->state_ == TimerManager::STOPPING) {
	manager_->state_ = TimerManager::STOPPED;
	manager_->monitor_.notify();
	}
	}
	return;
	}

	private:
	TimerManager* manager_;
	friend class TimerManager;
	};

	TimerManager::TimerManager() :
	taskCount_(0),
	state_(TimerManager::UNINITIALIZED),
	dispatcher_(shared_ptr<Dispatcher>(new Dispatcher(this))) {
	}


	TimerManager::~TimerManager() {

	// If we haven't been explicitly stopped, do so now. We don't need to grab
	// the monitor here, since stop already takes care of reentrancy.

	if (state_ != STOPPED) {
	try {
	stop();
	} catch(...) {
	throw;
	// uhoh
	}
	}
	}

	void TimerManager::start() {
	bool doStart = false;
	{
	Synchronized s(monitor_);
	if (threadFactory_ == NULL) {
	throw InvalidArgumentException();
	}
	if (state_ == TimerManager::UNINITIALIZED) {
	state_ = TimerManager::STARTING;
	doStart = true;
	}
	}

	if (doStart) {
	dispatcherThread_ = threadFactory_->newThread(dispatcher_);
	dispatcherThread_->start();
	}

	{
	Synchronized s(monitor_);
	while (state_ == TimerManager::STARTING) {
	monitor_.wait();
	}
	assert(state_ != TimerManager::STARTING);
	}
	}

	void TimerManager::stop() {
	bool doStop = false;
	{
	Synchronized s(monitor_);
	if (state_ == TimerManager::UNINITIALIZED) {
	state_ = TimerManager::STOPPED;
	} else if (state_ != STOPPING && state_ != STOPPED) {
	doStop = true;
	state_ = STOPPING;
	monitor_.notifyAll();
	}
	while (state_ != STOPPED) {
	monitor_.wait();
	}
	}

	if (doStop) {
	// Clean up any outstanding tasks
	for (task_iterator ix = taskMap_.begin(); ix != taskMap_.end(); ix++) {
	taskMap_.erase(ix);
	}

	// Remove dispatcher's reference to us.
	dispatcher_->manager_ = NULL;
	}
	}

	shared_ptr<const ThreadFactory> TimerManager::threadFactory() const {
	Synchronized s(monitor_);
	return threadFactory_;
	}

	void TimerManager::threadFactory(shared_ptr<const ThreadFactory> value) {
	Synchronized s(monitor_);
	threadFactory_ = value;
	}

	size_t TimerManager::taskCount() const {
	return taskCount_;
	}

	void TimerManager::add(shared_ptr<Runnable> task, int64_t timeout) {
	int64_t now = Util::currentTime();
	timeout += now;

	{
	Synchronized s(monitor_);
	if (state_ != TimerManager::STARTED) {
	throw IllegalStateException();
	}

	taskCount_++;
	taskMap_.insert(std::pair<int64_t, shared_ptr<Task> >(timeout, shared_ptr<Task>(new Task(task))));

	// If the task map was empty, or if we have an expiration that is earlier
	// than any previously seen, kick the dispatcher so it can update its
	// timeout
	if (taskCount_ == 1 \|\| timeout < taskMap_.begin()->first) {
	monitor_.notify();
	}
	}
	}

	void TimerManager::add(shared_ptr<Runnable> task, const struct timespec& value) {

	int64_t expiration;
	Util::toMilliseconds(expiration, value);

	int64_t now = Util::currentTime();

	if (expiration < now) {
	throw InvalidArgumentException();
	}

	add(task, expiration - now);
	}


	void TimerManager::remove(shared_ptr<Runnable> task) {
	Synchronized s(monitor_);
	if (state_ != TimerManager::STARTED) {
	throw IllegalStateException();
	}
	}

	const TimerManager::STATE TimerManager::state() const { return state_; }

	}}} // apache::thrift::concurrency