weex_core/Source/include/wtf/ParkingLot.h - incubator-weex - Git at Google

 /*
  * Copyright (C) 2015-2016 Apple Inc. All rights reserved.
  *
  * Redistribution and use in source and binary forms, with or without
  * modification, are permitted provided that the following conditions
  * are met:
  * 1. Redistributions of source code must retain the above copyright
  *    notice, this list of conditions and the following disclaimer.
  * 2. Redistributions in binary form must reproduce the above copyright
  *    notice, this list of conditions and the following disclaimer in the
  *    documentation and/or other materials provided with the distribution.
  *
  * THIS SOFTWARE IS PROVIDED BY APPLE INC. ``AS IS'' AND ANY
  * EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
  * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL APPLE INC. OR
  * CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
  * EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
  * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
  * PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY
  * OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
  * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
  * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
  */

 #ifndef WTF_ParkingLot_h
 #define WTF_ParkingLot_h

 #include <functional>
 #include <wtf/Atomics.h>
 #include <wtf/ScopedLambda.h>
 #include <wtf/Threading.h>
 #include <wtf/TimeWithDynamicClockType.h>

 namespace WTF {

 class ParkingLot {
     ParkingLot() = delete;
     ParkingLot(const ParkingLot&) = delete;

 public:
     // ParkingLot will accept any kind of time and convert it internally, but this typedef tells
     // you what kind of time ParkingLot would be able to use without conversions. It's sad that
     // this is WallTime not MonotonicTime, but that's just how OS wait functions work. However,
     // because ParkingLot evaluates whether it should wait by checking if your time has passed
     // using whatever clock you used, specifying timeouts in MonotonicTime is semantically better.
     // For example, if the user sets his computer's clock back during the time that you wanted to
     // wait for one second, and you specified the timeout using the MonotonicTime, then ParkingLot
     // will be smart enough to know that your one second has elapsed.
     typedef WallTime Time;

     // Parks the thread in a queue associated with the given address, which cannot be null. The
     // parking only succeeds if the validation function returns true while the queue lock is held.
     //
     // If validation returns false, it will unlock the internal parking queue and then it will
     // return a null ParkResult (wasUnparked = false, token = 0) without doing anything else.
     //
     // If validation returns true, it will enqueue the thread, unlock the parking queue lock, call
     // the beforeSleep function, and then it will sleep so long as the thread continues to be on the
     // queue and the timeout hasn't fired. Finally, this returns wasUnparked = true if we actually
     // got unparked or wasUnparked = false if the timeout was hit. When wasUnparked = true, the
     // token will contain whatever token was returned from the callback to unparkOne(), or 0 if the
     // thread was unparked using unparkAll() or the form of unparkOne() that doesn't take a
     // callback.
     //
     // Note that beforeSleep is called with no locks held, so it's OK to do pretty much anything so
     // long as you don't recursively call parkConditionally(). You can call unparkOne()/unparkAll()
     // though. It's useful to use beforeSleep() to unlock some mutex in the implementation of
     // Condition::wait().
     struct ParkResult {
         bool wasUnparked { false };
         intptr_t token { 0 };
     };
     template<typename ValidationFunctor, typename BeforeSleepFunctor>
     static ParkResult parkConditionally(
         const void* address,
         const ValidationFunctor& validation,
         const BeforeSleepFunctor& beforeSleep,
         const TimeWithDynamicClockType& timeout)
     {
         return parkConditionallyImpl(
             address,
             scopedLambdaRef<bool()>(validation),
             scopedLambdaRef<void()>(beforeSleep),
             timeout);
     }

     // Simple version of parkConditionally() that covers the most common case: you want to park
     // indefinitely so long as the value at the given address hasn't changed.
     template<typename T, typename U>
     static ParkResult compareAndPark(const Atomic<T>* address, U expected)
     {
         return parkConditionally(
             address,
             [address, expected] () -> bool {
                 U value = address->load();
                 return value == expected;
             },
             [] () { },
             Time::infinity());
     }

     // Unparking status given to you anytime you unparkOne().
     struct UnparkResult {
         // True if some thread was unparked.
         bool didUnparkThread { false };
         // True if there may be more threads on this address. This may be conservatively true.
         bool mayHaveMoreThreads { false };
         // This bit is randomly set to true indicating that it may be profitable to unlock the lock
         // using a fair unlocking protocol. This is most useful when used in conjunction with
         // unparkOne(address, callback).
         bool timeToBeFair { false };
     };

     // Unparks one thread from the queue associated with the given address, which cannot be null.
     // Returns true if there may still be other threads on that queue, or false if there definitely
     // are no more threads on the queue.
     WTF_EXPORT_PRIVATE static UnparkResult unparkOne(const void* address);

     // This is an expert-mode version of unparkOne() that allows for really good thundering herd
     // avoidance and eventual stochastic fairness in adaptive mutexes.
     //
     // Unparks one thread from the queue associated with the given address, and calls the given
     // callback while the address is locked. Reports to the callback whether any thread got
     // unparked, whether there may be any other threads still on the queue, and whether this may be
     // a good time to do fair unlocking. The callback returns an intptr_t token, which is returned
     // to the unparked thread via ParkResult::token.
     //
     // WTF::Lock and WTF::Condition both use this form of unparkOne() because it allows them to use
     // the ParkingLot's internal queue lock to serialize some decision-making. For example, if
     // UnparkResult::mayHaveMoreThreads is false inside the callback, then we know that at that
     // moment nobody can add any threads to the queue because the queue lock is still held. Also,
     // WTF::Lock uses the timeToBeFair and token mechanism to implement eventual fairness.
     template<typename Callback>
     static void unparkOne(const void* address, const Callback& callback)
     {
         unparkOneImpl(address, scopedLambdaRef<intptr_t(UnparkResult)>(callback));
     }

     WTF_EXPORT_PRIVATE static unsigned unparkCount(const void* address, unsigned count);

     // Unparks every thread from the queue associated with the given address, which cannot be null.
     WTF_EXPORT_PRIVATE static void unparkAll(const void* address);

     // Locks the parking lot and walks all of the parked threads and the addresses they are waiting
     // on. Threads that are on the same queue are guaranteed to be walked from first to last, but the
     // queues may be randomly interleaved. For example, if the queue for address A1 has T1 and T2 and
     // the queue for address A2 has T3 and T4, then you might see iteration orders like:
     //
     // A1,T1 A1,T2 A2,T3 A2,T4
     // A2,T3 A2,T4 A1,T1 A1,T2
     // A1,T1 A2,T3 A1,T2 A2,T4
     // A1,T1 A2,T3 A2,T4 A1,T2
     //
     // As well as many other possible interleavings that all have T1 before T2 and T3 before T4 but are
     // otherwise unconstrained. This method is useful primarily for debugging. It's also used by unit
     // tests.
     template<typename Func>
     static void forEach(const Func& func)
     {
         forEachImpl(scopedLambdaRef<void(ThreadIdentifier, const void*)>(func));
     }

 private:
     WTF_EXPORT_PRIVATE static ParkResult parkConditionallyImpl(
         const void* address,
         const ScopedLambda<bool()>& validation,
         const ScopedLambda<void()>& beforeSleep,
         const TimeWithDynamicClockType& timeout);

     WTF_EXPORT_PRIVATE static void unparkOneImpl(
         const void* address, const ScopedLambda<intptr_t(UnparkResult)>& callback);

     WTF_EXPORT_PRIVATE static void forEachImpl(const ScopedLambda<void(ThreadIdentifier, const void*)>&);
 };

 } // namespace WTF

 using WTF::ParkingLot;

 #endif // WTF_ParkingLot_h
	/*
	* Copyright (C) 2015-2016 Apple Inc. All rights reserved.
	*
	* Redistribution and use in source and binary forms, with or without
	* modification, are permitted provided that the following conditions
	* are met:
	* 1. Redistributions of source code must retain the above copyright
	* notice, this list of conditions and the following disclaimer.
	* 2. Redistributions in binary form must reproduce the above copyright
	* notice, this list of conditions and the following disclaimer in the
	* documentation and/or other materials provided with the distribution.
	*
	* THIS SOFTWARE IS PROVIDED BY APPLE INC. ``AS IS'' AND ANY
	* EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
	* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
	* PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL APPLE INC. OR
	* CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
	* EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
	* PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
	* PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY
	* OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
	* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
	* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
	*/

	#ifndef WTF_ParkingLot_h
	#define WTF_ParkingLot_h

	#include <functional>
	#include <wtf/Atomics.h>
	#include <wtf/ScopedLambda.h>
	#include <wtf/Threading.h>
	#include <wtf/TimeWithDynamicClockType.h>

	namespace WTF {

	class ParkingLot {
	ParkingLot() = delete;
	ParkingLot(const ParkingLot&) = delete;

	public:
	// ParkingLot will accept any kind of time and convert it internally, but this typedef tells
	// you what kind of time ParkingLot would be able to use without conversions. It's sad that
	// this is WallTime not MonotonicTime, but that's just how OS wait functions work. However,
	// because ParkingLot evaluates whether it should wait by checking if your time has passed
	// using whatever clock you used, specifying timeouts in MonotonicTime is semantically better.
	// For example, if the user sets his computer's clock back during the time that you wanted to
	// wait for one second, and you specified the timeout using the MonotonicTime, then ParkingLot
	// will be smart enough to know that your one second has elapsed.
	typedef WallTime Time;

	// Parks the thread in a queue associated with the given address, which cannot be null. The
	// parking only succeeds if the validation function returns true while the queue lock is held.
	//
	// If validation returns false, it will unlock the internal parking queue and then it will
	// return a null ParkResult (wasUnparked = false, token = 0) without doing anything else.
	//
	// If validation returns true, it will enqueue the thread, unlock the parking queue lock, call
	// the beforeSleep function, and then it will sleep so long as the thread continues to be on the
	// queue and the timeout hasn't fired. Finally, this returns wasUnparked = true if we actually
	// got unparked or wasUnparked = false if the timeout was hit. When wasUnparked = true, the
	// token will contain whatever token was returned from the callback to unparkOne(), or 0 if the
	// thread was unparked using unparkAll() or the form of unparkOne() that doesn't take a
	// callback.
	//
	// Note that beforeSleep is called with no locks held, so it's OK to do pretty much anything so
	// long as you don't recursively call parkConditionally(). You can call unparkOne()/unparkAll()
	// though. It's useful to use beforeSleep() to unlock some mutex in the implementation of
	// Condition::wait().
	struct ParkResult {
	bool wasUnparked { false };
	intptr_t token { 0 };
	};
	template<typename ValidationFunctor, typename BeforeSleepFunctor>
	static ParkResult parkConditionally(
	const void* address,
	const ValidationFunctor& validation,
	const BeforeSleepFunctor& beforeSleep,
	const TimeWithDynamicClockType& timeout)
	{
	return parkConditionallyImpl(
	address,
	scopedLambdaRef<bool()>(validation),
	scopedLambdaRef<void()>(beforeSleep),
	timeout);
	}

	// Simple version of parkConditionally() that covers the most common case: you want to park
	// indefinitely so long as the value at the given address hasn't changed.
	template<typename T, typename U>
	static ParkResult compareAndPark(const Atomic<T>* address, U expected)
	{
	return parkConditionally(
	address,
	[address, expected] () -> bool {
	U value = address->load();
	return value == expected;
	},
	[] () { },
	Time::infinity());
	}

	// Unparking status given to you anytime you unparkOne().
	struct UnparkResult {
	// True if some thread was unparked.
	bool didUnparkThread { false };
	// True if there may be more threads on this address. This may be conservatively true.
	bool mayHaveMoreThreads { false };
	// This bit is randomly set to true indicating that it may be profitable to unlock the lock
	// using a fair unlocking protocol. This is most useful when used in conjunction with
	// unparkOne(address, callback).
	bool timeToBeFair { false };
	};

	// Unparks one thread from the queue associated with the given address, which cannot be null.
	// Returns true if there may still be other threads on that queue, or false if there definitely
	// are no more threads on the queue.
	WTF_EXPORT_PRIVATE static UnparkResult unparkOne(const void* address);

	// This is an expert-mode version of unparkOne() that allows for really good thundering herd
	// avoidance and eventual stochastic fairness in adaptive mutexes.
	//
	// Unparks one thread from the queue associated with the given address, and calls the given
	// callback while the address is locked. Reports to the callback whether any thread got
	// unparked, whether there may be any other threads still on the queue, and whether this may be
	// a good time to do fair unlocking. The callback returns an intptr_t token, which is returned
	// to the unparked thread via ParkResult::token.
	//
	// WTF::Lock and WTF::Condition both use this form of unparkOne() because it allows them to use
	// the ParkingLot's internal queue lock to serialize some decision-making. For example, if
	// UnparkResult::mayHaveMoreThreads is false inside the callback, then we know that at that
	// moment nobody can add any threads to the queue because the queue lock is still held. Also,
	// WTF::Lock uses the timeToBeFair and token mechanism to implement eventual fairness.
	template<typename Callback>
	static void unparkOne(const void* address, const Callback& callback)
	{
	unparkOneImpl(address, scopedLambdaRef<intptr_t(UnparkResult)>(callback));
	}

	WTF_EXPORT_PRIVATE static unsigned unparkCount(const void* address, unsigned count);

	// Unparks every thread from the queue associated with the given address, which cannot be null.
	WTF_EXPORT_PRIVATE static void unparkAll(const void* address);

	// Locks the parking lot and walks all of the parked threads and the addresses they are waiting
	// on. Threads that are on the same queue are guaranteed to be walked from first to last, but the
	// queues may be randomly interleaved. For example, if the queue for address A1 has T1 and T2 and
	// the queue for address A2 has T3 and T4, then you might see iteration orders like:
	//
	// A1,T1 A1,T2 A2,T3 A2,T4
	// A2,T3 A2,T4 A1,T1 A1,T2
	// A1,T1 A2,T3 A1,T2 A2,T4
	// A1,T1 A2,T3 A2,T4 A1,T2
	//
	// As well as many other possible interleavings that all have T1 before T2 and T3 before T4 but are
	// otherwise unconstrained. This method is useful primarily for debugging. It's also used by unit
	// tests.
	template<typename Func>
	static void forEach(const Func& func)
	{
	forEachImpl(scopedLambdaRef<void(ThreadIdentifier, const void*)>(func));
	}

	private:
	WTF_EXPORT_PRIVATE static ParkResult parkConditionallyImpl(
	const void* address,
	const ScopedLambda<bool()>& validation,
	const ScopedLambda<void()>& beforeSleep,
	const TimeWithDynamicClockType& timeout);

	WTF_EXPORT_PRIVATE static void unparkOneImpl(
	const void* address, const ScopedLambda<intptr_t(UnparkResult)>& callback);

	WTF_EXPORT_PRIVATE static void forEachImpl(const ScopedLambda<void(ThreadIdentifier, const void*)>&);
	};

	} // namespace WTF

	using WTF::ParkingLot;

	#endif // WTF_ParkingLot_h