boost_1_45_0/libs/thread/test/util.inl - nest-learning-thermostat/5.0/boost - Git at Google

 // Copyright (C) 2001-2003
 // William E. Kempf
 // Copyright (C) 2007-8 Anthony Williams
 //
 //  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)

 #if !defined(UTIL_INL_WEK01242003)
 #define UTIL_INL_WEK01242003

 #include <boost/thread/xtime.hpp>
 #include <boost/thread/mutex.hpp>
 #include <boost/thread/condition.hpp>
 #include <boost/thread/thread.hpp>

 #ifndef DEFAULT_EXECUTION_MONITOR_TYPE
 #   define DEFAULT_EXECUTION_MONITOR_TYPE execution_monitor::use_condition
 #endif

 // boostinspect:nounnamed

 namespace
 {
 inline boost::xtime delay(int secs, int msecs=0, int nsecs=0)
 {
     const int MILLISECONDS_PER_SECOND = 1000;
     const int NANOSECONDS_PER_SECOND = 1000000000;
     const int NANOSECONDS_PER_MILLISECOND = 1000000;

     boost::xtime xt;
     if (boost::TIME_UTC != boost::xtime_get (&xt, boost::TIME_UTC))
         BOOST_ERROR ("boost::xtime_get != boost::TIME_UTC");

     nsecs += xt.nsec;
     msecs += nsecs / NANOSECONDS_PER_MILLISECOND;
     secs += msecs / MILLISECONDS_PER_SECOND;
     nsecs += (msecs % MILLISECONDS_PER_SECOND) * NANOSECONDS_PER_MILLISECOND;
     xt.nsec = nsecs % NANOSECONDS_PER_SECOND;
     xt.sec += secs + (nsecs / NANOSECONDS_PER_SECOND);

     return xt;
 }

 inline bool in_range(const boost::xtime& xt, int secs=1)
 {
     boost::xtime min = delay(-secs);
     boost::xtime max = delay(0);
     return (boost::xtime_cmp(xt, min) >= 0) &&
         (boost::xtime_cmp(xt, max) <= 0);
 }

 class execution_monitor
 {
 public:
     enum wait_type { use_sleep_only, use_mutex, use_condition };

     execution_monitor(wait_type type, int secs)
         : done(false), type(type), secs(secs) { }
     void start()
     {
         if (type != use_sleep_only) {
             boost::mutex::scoped_lock lock(mutex); done = false;
         } else {
             done = false;
         }
     }
     void finish()
     {
         if (type != use_sleep_only) {
             boost::mutex::scoped_lock lock(mutex);
             done = true;
             if (type == use_condition)
                 cond.notify_one();
         } else {
             done = true;
         }
     }
     bool wait()
     {
         boost::xtime xt = delay(secs);
         if (type != use_condition)
             boost::thread::sleep(xt);
         if (type != use_sleep_only) {
             boost::mutex::scoped_lock lock(mutex);
             while (type == use_condition && !done) {
                 if (!cond.timed_wait(lock, xt))
                     break;
             }
             return done;
         }
         return done;
     }

 private:
     boost::mutex mutex;
     boost::condition cond;
     bool done;
     wait_type type;
     int secs;
 };

 template <typename F>
 class indirect_adapter
 {
 public:
     indirect_adapter(F func, execution_monitor& monitor)
         : func(func), monitor(monitor) { }
     void operator()() const
     {
         try
         {
             boost::thread thrd(func);
             thrd.join();
         }
         catch (...)
         {
             monitor.finish();
             throw;
         }
         monitor.finish();
     }

 private:
     F func;
     execution_monitor& monitor;
     void operator=(indirect_adapter&);
 };

 template <typename F>
 void timed_test(F func, int secs,
     execution_monitor::wait_type type=DEFAULT_EXECUTION_MONITOR_TYPE)
 {
     execution_monitor monitor(type, secs);
     indirect_adapter<F> ifunc(func, monitor);
     monitor.start();
     boost::thread thrd(ifunc);
     BOOST_REQUIRE_MESSAGE(monitor.wait(),
         "Timed test didn't complete in time, possible deadlock.");
 }

 template <typename F, typename T>
 class thread_binder
 {
 public:
     thread_binder(const F& func, const T& param)
         : func(func), param(param) { }
     void operator()() const { func(param); }

 private:
     F func;
     T param;
 };

 template <typename F, typename T>
 thread_binder<F, T> bind(const F& func, const T& param)
 {
     return thread_binder<F, T>(func, param);
 }

 template <typename R, typename T>
 class thread_member_binder
 {
 public:
     thread_member_binder(R (T::*func)(), T& param)
         : func(func), param(param) { }
     void operator()() const { (param.*func)(); }

 private:
     void operator=(thread_member_binder&);

     R (T::*func)();
     T& param;
 };


 template <typename R, typename T>
 thread_member_binder<R, T> bind(R (T::*func)(), T& param)
 {
     return thread_member_binder<R, T>(func, param);
 }
 } // namespace

 #endif
	// Copyright (C) 2001-2003
	// William E. Kempf
	// Copyright (C) 2007-8 Anthony Williams
	//
	// 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)

	#if !defined(UTIL_INL_WEK01242003)
	#define UTIL_INL_WEK01242003

	#include <boost/thread/xtime.hpp>
	#include <boost/thread/mutex.hpp>
	#include <boost/thread/condition.hpp>
	#include <boost/thread/thread.hpp>

	#ifndef DEFAULT_EXECUTION_MONITOR_TYPE
	# define DEFAULT_EXECUTION_MONITOR_TYPE execution_monitor::use_condition
	#endif

	// boostinspect:nounnamed

	namespace
	{
	inline boost::xtime delay(int secs, int msecs=0, int nsecs=0)
	{
	const int MILLISECONDS_PER_SECOND = 1000;
	const int NANOSECONDS_PER_SECOND = 1000000000;
	const int NANOSECONDS_PER_MILLISECOND = 1000000;

	boost::xtime xt;
	if (boost::TIME_UTC != boost::xtime_get (&xt, boost::TIME_UTC))
	BOOST_ERROR ("boost::xtime_get != boost::TIME_UTC");

	nsecs += xt.nsec;
	msecs += nsecs / NANOSECONDS_PER_MILLISECOND;
	secs += msecs / MILLISECONDS_PER_SECOND;
	nsecs += (msecs % MILLISECONDS_PER_SECOND) * NANOSECONDS_PER_MILLISECOND;
	xt.nsec = nsecs % NANOSECONDS_PER_SECOND;
	xt.sec += secs + (nsecs / NANOSECONDS_PER_SECOND);

	return xt;
	}

	inline bool in_range(const boost::xtime& xt, int secs=1)
	{
	boost::xtime min = delay(-secs);
	boost::xtime max = delay(0);
	return (boost::xtime_cmp(xt, min) >= 0) &&
	(boost::xtime_cmp(xt, max) <= 0);
	}

	class execution_monitor
	{
	public:
	enum wait_type { use_sleep_only, use_mutex, use_condition };

	execution_monitor(wait_type type, int secs)
	: done(false), type(type), secs(secs) { }
	void start()
	{
	if (type != use_sleep_only) {
	boost::mutex::scoped_lock lock(mutex); done = false;
	} else {
	done = false;
	}
	}
	void finish()
	{
	if (type != use_sleep_only) {
	boost::mutex::scoped_lock lock(mutex);
	done = true;
	if (type == use_condition)
	cond.notify_one();
	} else {
	done = true;
	}
	}
	bool wait()
	{
	boost::xtime xt = delay(secs);
	if (type != use_condition)
	boost::thread::sleep(xt);
	if (type != use_sleep_only) {
	boost::mutex::scoped_lock lock(mutex);
	while (type == use_condition && !done) {
	if (!cond.timed_wait(lock, xt))
	break;
	}
	return done;
	}
	return done;
	}

	private:
	boost::mutex mutex;
	boost::condition cond;
	bool done;
	wait_type type;
	int secs;
	};

	template <typename F>
	class indirect_adapter
	{
	public:
	indirect_adapter(F func, execution_monitor& monitor)
	: func(func), monitor(monitor) { }
	void operator()() const
	{
	try
	{
	boost::thread thrd(func);
	thrd.join();
	}
	catch (...)
	{
	monitor.finish();
	throw;
	}
	monitor.finish();
	}

	private:
	F func;
	execution_monitor& monitor;
	void operator=(indirect_adapter&);
	};

	template <typename F>
	void timed_test(F func, int secs,
	execution_monitor::wait_type type=DEFAULT_EXECUTION_MONITOR_TYPE)
	{
	execution_monitor monitor(type, secs);
	indirect_adapter<F> ifunc(func, monitor);
	monitor.start();
	boost::thread thrd(ifunc);
	BOOST_REQUIRE_MESSAGE(monitor.wait(),
	"Timed test didn't complete in time, possible deadlock.");
	}

	template <typename F, typename T>
	class thread_binder
	{
	public:
	thread_binder(const F& func, const T& param)
	: func(func), param(param) { }
	void operator()() const { func(param); }

	private:
	F func;
	T param;
	};

	template <typename F, typename T>
	thread_binder<F, T> bind(const F& func, const T& param)
	{
	return thread_binder<F, T>(func, param);
	}

	template <typename R, typename T>
	class thread_member_binder
	{
	public:
	thread_member_binder(R (T::*func)(), T& param)
	: func(func), param(param) { }
	void operator()() const { (param.*func)(); }

	private:
	void operator=(thread_member_binder&);

	R (T::*func)();
	T& param;
	};


	template <typename R, typename T>
	thread_member_binder<R, T> bind(R (T::*func)(), T& param)
	{
	return thread_member_binder<R, T>(func, param);
	}
	} // namespace

	#endif