src/common/SynchronizedValue.h - angle/angle - Git at Google

 //
 // Copyright 2021 The ANGLE Project Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.
 //
 // SynchronizedValue.h:
 //   A class that ensures that the correct mutex is locked when the encapsulated data is accessed.
 //   Based on boost::synchronized_value, which probably becomes part of the next C++ standard.
 // https://www.boost.org/doc/libs/1_76_0/doc/html/thread/sds.html#thread.sds.synchronized_valuesxxx

 #ifndef COMMON_SYNCHRONIZEDVALUE_H_
 #define COMMON_SYNCHRONIZEDVALUE_H_

 #include "common/SimpleMutex.h"
 #include "common/debug.h"

 #include <mutex>
 #include <type_traits>

 namespace angle
 {

 template <typename T, typename Lockable = angle::SimpleMutex>
 class ConstStrictLockPtr
 {
   public:
     using value_type = T;
     using mutex_type = Lockable;

     ConstStrictLockPtr(const T &value, Lockable &mutex) : mLock(mutex), mValue(value) {}
     ConstStrictLockPtr(const T &value, Lockable &mutex, std::adopt_lock_t) noexcept
         : mLock(mutex, std::adopt_lock), mValue(value)
     {}

     ConstStrictLockPtr(ConstStrictLockPtr &&other) noexcept
         : mLock(std::move(other.mLock)), mValue(other.mValue)
     {}

     ConstStrictLockPtr(const ConstStrictLockPtr &)            = delete;
     ConstStrictLockPtr &operator=(const ConstStrictLockPtr &) = delete;

     ~ConstStrictLockPtr() = default;

     const T *operator->() const { return &mValue; }
     const T &operator*() const { return mValue; }

   protected:
     std::unique_lock<Lockable> mLock;
     T const &mValue;
 };

 template <typename T, typename Lockable = angle::SimpleMutex>
 class StrictLockPtr : public ConstStrictLockPtr<T, Lockable>
 {
   private:
     using BaseType = ConstStrictLockPtr<T, Lockable>;

   public:
     StrictLockPtr(T &value, Lockable &mutex) : BaseType(value, mutex) {}
     StrictLockPtr(T &value, Lockable &mutex, std::adopt_lock_t) noexcept
         : BaseType(value, mutex, std::adopt_lock)
     {}

     StrictLockPtr(StrictLockPtr &&other) noexcept
         : BaseType(std::move(static_cast<BaseType &&>(other)))
     {}

     StrictLockPtr(const StrictLockPtr &)            = delete;
     StrictLockPtr &operator=(const StrictLockPtr &) = delete;

     ~StrictLockPtr() = default;

     T *operator->() { return const_cast<T *>(&this->mValue); }
     T &operator*() { return const_cast<T &>(this->mValue); }
 };

 template <typename SV>
 struct SynchronizedValueStrictLockPtr
 {
     using type = StrictLockPtr<typename SV::value_type, typename SV::mutex_type>;
 };

 template <typename SV>
 struct SynchronizedValueStrictLockPtr<const SV>
 {
     using type = ConstStrictLockPtr<typename SV::value_type, typename SV::mutex_type>;
 };

 template <typename T, typename Lockable = angle::SimpleMutex>
 class ConstUniqueLockPtr : public std::unique_lock<Lockable>
 {
   private:
     using BaseType = std::unique_lock<Lockable>;

   public:
     using value_type = T;
     using mutex_type = Lockable;

     ConstUniqueLockPtr(const T &value, Lockable &mutex) : BaseType(mutex), mValue(value) {}
     ConstUniqueLockPtr(const T &value, Lockable &mutex, std::adopt_lock_t) noexcept
         : BaseType(mutex, std::adopt_lock), mValue(value)
     {}
     ConstUniqueLockPtr(const T &value, Lockable &mutex, std::defer_lock_t) noexcept
         : BaseType(mutex, std::defer_lock), mValue(value)
     {}
     ConstUniqueLockPtr(const T &value, Lockable &mutex, std::try_to_lock_t) noexcept
         : BaseType(mutex, std::try_to_lock), mValue(value)
     {}

     ConstUniqueLockPtr(ConstUniqueLockPtr &&other) noexcept
         : BaseType(std::move(static_cast<BaseType &&>(other))), mValue(other.mValue)
     {}

     ConstUniqueLockPtr(const ConstUniqueLockPtr &)            = delete;
     ConstUniqueLockPtr &operator=(const ConstUniqueLockPtr &) = delete;

     ~ConstUniqueLockPtr() = default;

     const T *operator->() const
     {
         ASSERT(this->owns_lock());
         return &mValue;
     }
     const T &operator*() const
     {
         ASSERT(this->owns_lock());
         return mValue;
     }

   protected:
     T const &mValue;
 };

 template <typename T, typename Lockable = angle::SimpleMutex>
 class UniqueLockPtr : public ConstUniqueLockPtr<T, Lockable>
 {
   private:
     using BaseType = ConstUniqueLockPtr<T, Lockable>;

   public:
     UniqueLockPtr(T &value, Lockable &mutex) : BaseType(value, mutex) {}
     UniqueLockPtr(T &value, Lockable &mutex, std::adopt_lock_t) noexcept
         : BaseType(value, mutex, std::adopt_lock)
     {}
     UniqueLockPtr(T &value, Lockable &mutex, std::defer_lock_t) noexcept
         : BaseType(value, mutex, std::defer_lock)
     {}
     UniqueLockPtr(T &value, Lockable &mutex, std::try_to_lock_t) noexcept
         : BaseType(value, mutex, std::try_to_lock)
     {}

     UniqueLockPtr(UniqueLockPtr &&other) noexcept
         : BaseType(std::move(static_cast<BaseType &&>(other)))
     {}

     UniqueLockPtr(const UniqueLockPtr &)            = delete;
     UniqueLockPtr &operator=(const UniqueLockPtr &) = delete;

     ~UniqueLockPtr() = default;

     T *operator->()
     {
         ASSERT(this->owns_lock());
         return const_cast<T *>(&this->mValue);
     }
     T &operator*()
     {
         ASSERT(this->owns_lock());
         return const_cast<T &>(this->mValue);
     }
 };

 template <typename SV>
 struct SynchronizedValueUniqueLockPtr
 {
     using type = UniqueLockPtr<typename SV::value_type, typename SV::mutex_type>;
 };

 template <typename SV>
 struct SynchronizedValueUniqueLockPtr<const SV>
 {
     using type = ConstUniqueLockPtr<typename SV::value_type, typename SV::mutex_type>;
 };

 template <typename T, typename Lockable = angle::SimpleMutex>
 class SynchronizedValue
 {
   public:
     using value_type = T;
     using mutex_type = Lockable;

     SynchronizedValue() noexcept(std::is_nothrow_default_constructible<T>::value) : mValue() {}

     SynchronizedValue(const T &other) noexcept(std::is_nothrow_copy_constructible<T>::value)
         : mValue(other)
     {}

     SynchronizedValue(T &&other) noexcept(std::is_nothrow_move_constructible<T>::value)
         : mValue(std::move(other))
     {}

     template <typename... Args>
     SynchronizedValue(Args &&...args) noexcept(noexcept(T(std::forward<Args>(args)...)))
         : mValue(std::forward<Args>(args)...)
     {}

     SynchronizedValue(const SynchronizedValue &other)
     {
         std::lock_guard<Lockable> lock(other.mMutex);
         mValue = other.mValue;
     }

     SynchronizedValue(SynchronizedValue &&other)
     {
         std::lock_guard<Lockable> lock(other.mMutex);
         mValue = std::move(other.mValue);
     }

     SynchronizedValue &operator=(const SynchronizedValue &other)
     {
         if (&other != this)
         {
             std::unique_lock<Lockable> lock1(mMutex, std::defer_lock);
             std::unique_lock<Lockable> lock2(other.mMutex, std::defer_lock);
             std::lock(lock1, lock2);
             mValue = other.mValue;
         }
         return *this;
     }

     SynchronizedValue &operator=(SynchronizedValue &&other)
     {
         if (&other != this)
         {
             std::unique_lock<Lockable> lock1(mMutex, std::defer_lock);
             std::unique_lock<Lockable> lock2(other.mMutex, std::defer_lock);
             std::lock(lock1, lock2);
             mValue = std::move(other.mValue);
         }
         return *this;
     }

     SynchronizedValue &operator=(const T &value)
     {
         {
             std::lock_guard<Lockable> lock(mMutex);
             mValue = value;
         }
         return *this;
     }

     SynchronizedValue &operator=(T &&value)
     {
         {
             std::lock_guard<Lockable> lock(mMutex);
             mValue = std::move(value);
         }
         return *this;
     }

     T get() const
     {
         std::lock_guard<Lockable> lock(mMutex);
         return mValue;
     }

     explicit operator T() const { return get(); }

     void swap(SynchronizedValue &other)
     {
         if (this == &other)
         {
             return;
         }
         std::unique_lock<Lockable> lock1(mMutex, std::defer_lock);
         std::unique_lock<Lockable> lock2(other.mMutex, std::defer_lock);
         std::lock(lock1, lock2);
         std::swap(mValue, other.mValue);
     }

     void swap(T &other)
     {
         std::lock_guard<Lockable> lock(mMutex);
         std::swap(mValue, other);
     }

     StrictLockPtr<T, Lockable> operator->() { return StrictLockPtr<T, Lockable>(mValue, mMutex); }
     ConstStrictLockPtr<T, Lockable> operator->() const
     {
         return ConstStrictLockPtr<T, Lockable>(mValue, mMutex);
     }

     StrictLockPtr<T, Lockable> synchronize() { return StrictLockPtr<T, Lockable>(mValue, mMutex); }
     ConstStrictLockPtr<T, Lockable> synchronize() const
     {
         return ConstStrictLockPtr<T, Lockable>(mValue, mMutex);
     }

     UniqueLockPtr<T, Lockable> unique_synchronize()
     {
         return UniqueLockPtr<T, Lockable>(mValue, mMutex);
     }
     ConstUniqueLockPtr<T, Lockable> unique_synchronize() const
     {
         return ConstUniqueLockPtr<T, Lockable>(mValue, mMutex);
     }

     UniqueLockPtr<T, Lockable> defer_synchronize() noexcept
     {
         return UniqueLockPtr<T, Lockable>(mValue, mMutex, std::defer_lock);
     }
     ConstUniqueLockPtr<T, Lockable> defer_synchronize() const noexcept
     {
         return ConstUniqueLockPtr<T, Lockable>(mValue, mMutex, std::defer_lock);
     }

     UniqueLockPtr<T, Lockable> try_to_synchronize() noexcept
     {
         return UniqueLockPtr<T, Lockable>(mValue, mMutex, std::try_to_lock);
     }
     ConstUniqueLockPtr<T, Lockable> try_to_synchronize() const noexcept
     {
         return ConstUniqueLockPtr<T, Lockable>(mValue, mMutex, std::try_to_lock);
     }

     UniqueLockPtr<T, Lockable> adopt_synchronize() noexcept
     {
         return UniqueLockPtr<T, Lockable>(mValue, mMutex, std::adopt_lock);
     }
     ConstUniqueLockPtr<T, Lockable> adopt_synchronize() const noexcept
     {
         return ConstUniqueLockPtr<T, Lockable>(mValue, mMutex, std::adopt_lock);
     }

     class DerefValue
     {
       public:
         DerefValue(DerefValue &&other) : mLock(std::move(other.mLock)), mValue(other.mValue) {}

         DerefValue(const DerefValue &)            = delete;
         DerefValue &operator=(const DerefValue &) = delete;

         operator T &() { return mValue; }

         DerefValue &operator=(const T &other)
         {
             mValue = other;
             return *this;
         }

       private:
         explicit DerefValue(SynchronizedValue &outer) : mLock(outer.mMutex), mValue(outer.mValue) {}

         std::unique_lock<Lockable> mLock;
         T &mValue;

         friend class SynchronizedValue;
     };

     class ConstDerefValue
     {
       public:
         ConstDerefValue(ConstDerefValue &&other)
             : mLock(std::move(other.mLock)), mValue(other.mValue)
         {}

         ConstDerefValue(const ConstDerefValue &)            = delete;
         ConstDerefValue &operator=(const ConstDerefValue &) = delete;

         operator const T &() { return mValue; }

       private:
         explicit ConstDerefValue(const SynchronizedValue &outer)
             : mLock(outer.mMutex), mValue(outer.mValue)
         {}

         std::unique_lock<Lockable> mLock;
         const T &mValue;

         friend class SynchronizedValue;
     };

     DerefValue operator*() { return DerefValue(*this); }
     ConstDerefValue operator*() const { return ConstDerefValue(*this); }

     template <typename OStream>
     void save(OStream &os) const
     {
         std::lock_guard<Lockable> lock(mMutex);
         os << mValue;
     }

     template <typename IStream>
     void load(IStream &is)
     {
         std::lock_guard<Lockable> lock(mMutex);
         is >> mValue;
     }

     bool operator==(const SynchronizedValue &other) const
     {
         std::unique_lock<Lockable> lock1(mMutex, std::defer_lock);
         std::unique_lock<Lockable> lock2(other.mMutex, std::defer_lock);
         std::lock(lock1, lock2);
         return mValue == other.mValue;
     }

     bool operator!=(const SynchronizedValue &other) const
     {
         std::unique_lock<Lockable> lock1(mMutex, std::defer_lock);
         std::unique_lock<Lockable> lock2(other.mMutex, std::defer_lock);
         std::lock(lock1, lock2);
         return mValue != other.mValue;
     }

     bool operator<(const SynchronizedValue &other) const
     {
         std::unique_lock<Lockable> lock1(mMutex, std::defer_lock);
         std::unique_lock<Lockable> lock2(other.mMutex, std::defer_lock);
         std::lock(lock1, lock2);
         return mValue < other.mValue;
     }

     bool operator>(const SynchronizedValue &other) const
     {
         std::unique_lock<Lockable> lock1(mMutex, std::defer_lock);
         std::unique_lock<Lockable> lock2(other.mMutex, std::defer_lock);
         std::lock(lock1, lock2);
         return mValue > other.mValue;
     }

     bool operator<=(const SynchronizedValue &other) const
     {
         std::unique_lock<Lockable> lock1(mMutex, std::defer_lock);
         std::unique_lock<Lockable> lock2(other.mMutex, std::defer_lock);
         std::lock(lock1, lock2);
         return mValue <= other.mValue;
     }

     bool operator>=(const SynchronizedValue &other) const
     {
         std::unique_lock<Lockable> lock1(mMutex, std::defer_lock);
         std::unique_lock<Lockable> lock2(other.mMutex, std::defer_lock);
         std::lock(lock1, lock2);
         return mValue >= other.mValue;
     }

     bool operator==(const T &other) const
     {
         std::lock_guard<Lockable> lock(mMutex);
         return mValue == other;
     }

     bool operator!=(const T &other) const
     {
         std::lock_guard<Lockable> lock(mMutex);
         return mValue != other;
     }

     bool operator<(const T &other) const
     {
         std::lock_guard<Lockable> lock(mMutex);
         return mValue < other;
     }

     bool operator>(const T &other) const
     {
         std::lock_guard<Lockable> lock(mMutex);
         return mValue > other;
     }

     bool operator<=(const T &other) const
     {
         std::lock_guard<Lockable> lock(mMutex);
         return mValue <= other;
     }

     bool operator>=(const T &other) const
     {
         std::lock_guard<Lockable> lock(mMutex);
         return mValue >= other;
     }

   private:
     T mValue;
     mutable Lockable mMutex;
 };

 template <typename OStream, typename T, typename L>
 inline OStream &operator<<(OStream &os, SynchronizedValue<T, L> const &sv)
 {
     sv.save(os);
     return os;
 }

 template <typename IStream, typename T, typename L>
 inline IStream &operator>>(IStream &is, SynchronizedValue<T, L> &sv)
 {
     sv.load(is);
     return is;
 }

 template <typename T, typename L>
 bool operator==(const T &lhs, const SynchronizedValue<T, L> &rhs)
 {
     return rhs == lhs;
 }

 template <typename T, typename L>
 bool operator!=(const T &lhs, const SynchronizedValue<T, L> &rhs)
 {
     return rhs != lhs;
 }

 template <typename T, typename L>
 bool operator<(const T &lhs, const SynchronizedValue<T, L> &rhs)
 {
     return rhs < lhs;
 }

 template <typename T, typename L>
 bool operator>(const T &lhs, const SynchronizedValue<T, L> &rhs)
 {
     return rhs > lhs;
 }

 template <typename T, typename L>
 bool operator<=(const T &lhs, const SynchronizedValue<T, L> &rhs)
 {
     return rhs <= lhs;
 }

 template <typename T, typename L>
 bool operator>=(const T &lhs, const SynchronizedValue<T, L> &rhs)
 {
     return rhs >= lhs;
 }

 }  // namespace angle

 #endif  // COMMON_SYNCHRONIZEDVALUE_H_
	//
	// Copyright 2021 The ANGLE Project Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.
	//
	// SynchronizedValue.h:
	// A class that ensures that the correct mutex is locked when the encapsulated data is accessed.
	// Based on boost::synchronized_value, which probably becomes part of the next C++ standard.
	// https://www.boost.org/doc/libs/1_76_0/doc/html/thread/sds.html#thread.sds.synchronized_valuesxxx

	#ifndef COMMON_SYNCHRONIZEDVALUE_H_
	#define COMMON_SYNCHRONIZEDVALUE_H_

	#include "common/SimpleMutex.h"
	#include "common/debug.h"

	#include <mutex>
	#include <type_traits>

	namespace angle
	{

	template <typename T, typename Lockable = angle::SimpleMutex>
	class ConstStrictLockPtr
	{
	public:
	using value_type = T;
	using mutex_type = Lockable;

	ConstStrictLockPtr(const T &value, Lockable &mutex) : mLock(mutex), mValue(value) {}
	ConstStrictLockPtr(const T &value, Lockable &mutex, std::adopt_lock_t) noexcept
	: mLock(mutex, std::adopt_lock), mValue(value)
	{}

	ConstStrictLockPtr(ConstStrictLockPtr &&other) noexcept
	: mLock(std::move(other.mLock)), mValue(other.mValue)
	{}

	ConstStrictLockPtr(const ConstStrictLockPtr &) = delete;
	ConstStrictLockPtr &operator=(const ConstStrictLockPtr &) = delete;

	~ConstStrictLockPtr() = default;

	const T *operator->() const { return &mValue; }
	const T &operator*() const { return mValue; }

	protected:
	std::unique_lock<Lockable> mLock;
	T const &mValue;
	};

	template <typename T, typename Lockable = angle::SimpleMutex>
	class StrictLockPtr : public ConstStrictLockPtr<T, Lockable>
	{
	private:
	using BaseType = ConstStrictLockPtr<T, Lockable>;

	public:
	StrictLockPtr(T &value, Lockable &mutex) : BaseType(value, mutex) {}
	StrictLockPtr(T &value, Lockable &mutex, std::adopt_lock_t) noexcept
	: BaseType(value, mutex, std::adopt_lock)
	{}

	StrictLockPtr(StrictLockPtr &&other) noexcept
	: BaseType(std::move(static_cast<BaseType &&>(other)))
	{}

	StrictLockPtr(const StrictLockPtr &) = delete;
	StrictLockPtr &operator=(const StrictLockPtr &) = delete;

	~StrictLockPtr() = default;

	T operator->() { return const_cast<T >(&this->mValue); }
	T &operator*() { return const_cast<T &>(this->mValue); }
	};

	template <typename SV>
	struct SynchronizedValueStrictLockPtr
	{
	using type = StrictLockPtr<typename SV::value_type, typename SV::mutex_type>;
	};

	template <typename SV>
	struct SynchronizedValueStrictLockPtr<const SV>
	{
	using type = ConstStrictLockPtr<typename SV::value_type, typename SV::mutex_type>;
	};

	template <typename T, typename Lockable = angle::SimpleMutex>
	class ConstUniqueLockPtr : public std::unique_lock<Lockable>
	{
	private:
	using BaseType = std::unique_lock<Lockable>;

	public:
	using value_type = T;
	using mutex_type = Lockable;

	ConstUniqueLockPtr(const T &value, Lockable &mutex) : BaseType(mutex), mValue(value) {}
	ConstUniqueLockPtr(const T &value, Lockable &mutex, std::adopt_lock_t) noexcept
	: BaseType(mutex, std::adopt_lock), mValue(value)
	{}
	ConstUniqueLockPtr(const T &value, Lockable &mutex, std::defer_lock_t) noexcept
	: BaseType(mutex, std::defer_lock), mValue(value)
	{}
	ConstUniqueLockPtr(const T &value, Lockable &mutex, std::try_to_lock_t) noexcept
	: BaseType(mutex, std::try_to_lock), mValue(value)
	{}

	ConstUniqueLockPtr(ConstUniqueLockPtr &&other) noexcept
	: BaseType(std::move(static_cast<BaseType &&>(other))), mValue(other.mValue)
	{}

	ConstUniqueLockPtr(const ConstUniqueLockPtr &) = delete;
	ConstUniqueLockPtr &operator=(const ConstUniqueLockPtr &) = delete;

	~ConstUniqueLockPtr() = default;

	const T *operator->() const
	{
	ASSERT(this->owns_lock());
	return &mValue;
	}
	const T &operator*() const
	{
	ASSERT(this->owns_lock());
	return mValue;
	}

	protected:
	T const &mValue;
	};

	template <typename T, typename Lockable = angle::SimpleMutex>
	class UniqueLockPtr : public ConstUniqueLockPtr<T, Lockable>
	{
	private:
	using BaseType = ConstUniqueLockPtr<T, Lockable>;

	public:
	UniqueLockPtr(T &value, Lockable &mutex) : BaseType(value, mutex) {}
	UniqueLockPtr(T &value, Lockable &mutex, std::adopt_lock_t) noexcept
	: BaseType(value, mutex, std::adopt_lock)
	{}
	UniqueLockPtr(T &value, Lockable &mutex, std::defer_lock_t) noexcept
	: BaseType(value, mutex, std::defer_lock)
	{}
	UniqueLockPtr(T &value, Lockable &mutex, std::try_to_lock_t) noexcept
	: BaseType(value, mutex, std::try_to_lock)
	{}

	UniqueLockPtr(UniqueLockPtr &&other) noexcept
	: BaseType(std::move(static_cast<BaseType &&>(other)))
	{}

	UniqueLockPtr(const UniqueLockPtr &) = delete;
	UniqueLockPtr &operator=(const UniqueLockPtr &) = delete;

	~UniqueLockPtr() = default;

	T *operator->()
	{
	ASSERT(this->owns_lock());
	return const_cast<T *>(&this->mValue);
	}
	T &operator*()
	{
	ASSERT(this->owns_lock());
	return const_cast<T &>(this->mValue);
	}
	};

	template <typename SV>
	struct SynchronizedValueUniqueLockPtr
	{
	using type = UniqueLockPtr<typename SV::value_type, typename SV::mutex_type>;
	};

	template <typename SV>
	struct SynchronizedValueUniqueLockPtr<const SV>
	{
	using type = ConstUniqueLockPtr<typename SV::value_type, typename SV::mutex_type>;
	};

	template <typename T, typename Lockable = angle::SimpleMutex>
	class SynchronizedValue
	{
	public:
	using value_type = T;
	using mutex_type = Lockable;

	SynchronizedValue() noexcept(std::is_nothrow_default_constructible<T>::value) : mValue() {}

	SynchronizedValue(const T &other) noexcept(std::is_nothrow_copy_constructible<T>::value)
	: mValue(other)
	{}

	SynchronizedValue(T &&other) noexcept(std::is_nothrow_move_constructible<T>::value)
	: mValue(std::move(other))
	{}

	template <typename... Args>
	SynchronizedValue(Args &&...args) noexcept(noexcept(T(std::forward<Args>(args)...)))
	: mValue(std::forward<Args>(args)...)
	{}

	SynchronizedValue(const SynchronizedValue &other)
	{
	std::lock_guard<Lockable> lock(other.mMutex);
	mValue = other.mValue;
	}

	SynchronizedValue(SynchronizedValue &&other)
	{
	std::lock_guard<Lockable> lock(other.mMutex);
	mValue = std::move(other.mValue);
	}

	SynchronizedValue &operator=(const SynchronizedValue &other)
	{
	if (&other != this)
	{
	std::unique_lock<Lockable> lock1(mMutex, std::defer_lock);
	std::unique_lock<Lockable> lock2(other.mMutex, std::defer_lock);
	std::lock(lock1, lock2);
	mValue = other.mValue;
	}
	return *this;
	}

	SynchronizedValue &operator=(SynchronizedValue &&other)
	{
	if (&other != this)
	{
	std::unique_lock<Lockable> lock1(mMutex, std::defer_lock);
	std::unique_lock<Lockable> lock2(other.mMutex, std::defer_lock);
	std::lock(lock1, lock2);
	mValue = std::move(other.mValue);
	}
	return *this;
	}

	SynchronizedValue &operator=(const T &value)
	{
	{
	std::lock_guard<Lockable> lock(mMutex);
	mValue = value;
	}
	return *this;
	}

	SynchronizedValue &operator=(T &&value)
	{
	{
	std::lock_guard<Lockable> lock(mMutex);
	mValue = std::move(value);
	}
	return *this;
	}

	T get() const
	{
	std::lock_guard<Lockable> lock(mMutex);
	return mValue;
	}

	explicit operator T() const { return get(); }

	void swap(SynchronizedValue &other)
	{
	if (this == &other)
	{
	return;
	}
	std::unique_lock<Lockable> lock1(mMutex, std::defer_lock);
	std::unique_lock<Lockable> lock2(other.mMutex, std::defer_lock);
	std::lock(lock1, lock2);
	std::swap(mValue, other.mValue);
	}

	void swap(T &other)
	{
	std::lock_guard<Lockable> lock(mMutex);
	std::swap(mValue, other);
	}

	StrictLockPtr<T, Lockable> operator->() { return StrictLockPtr<T, Lockable>(mValue, mMutex); }
	ConstStrictLockPtr<T, Lockable> operator->() const
	{
	return ConstStrictLockPtr<T, Lockable>(mValue, mMutex);
	}

	StrictLockPtr<T, Lockable> synchronize() { return StrictLockPtr<T, Lockable>(mValue, mMutex); }
	ConstStrictLockPtr<T, Lockable> synchronize() const
	{
	return ConstStrictLockPtr<T, Lockable>(mValue, mMutex);
	}

	UniqueLockPtr<T, Lockable> unique_synchronize()
	{
	return UniqueLockPtr<T, Lockable>(mValue, mMutex);
	}
	ConstUniqueLockPtr<T, Lockable> unique_synchronize() const
	{
	return ConstUniqueLockPtr<T, Lockable>(mValue, mMutex);
	}

	UniqueLockPtr<T, Lockable> defer_synchronize() noexcept
	{
	return UniqueLockPtr<T, Lockable>(mValue, mMutex, std::defer_lock);
	}
	ConstUniqueLockPtr<T, Lockable> defer_synchronize() const noexcept
	{
	return ConstUniqueLockPtr<T, Lockable>(mValue, mMutex, std::defer_lock);
	}

	UniqueLockPtr<T, Lockable> try_to_synchronize() noexcept
	{
	return UniqueLockPtr<T, Lockable>(mValue, mMutex, std::try_to_lock);
	}
	ConstUniqueLockPtr<T, Lockable> try_to_synchronize() const noexcept
	{
	return ConstUniqueLockPtr<T, Lockable>(mValue, mMutex, std::try_to_lock);
	}

	UniqueLockPtr<T, Lockable> adopt_synchronize() noexcept
	{
	return UniqueLockPtr<T, Lockable>(mValue, mMutex, std::adopt_lock);
	}
	ConstUniqueLockPtr<T, Lockable> adopt_synchronize() const noexcept
	{
	return ConstUniqueLockPtr<T, Lockable>(mValue, mMutex, std::adopt_lock);
	}

	class DerefValue
	{
	public:
	DerefValue(DerefValue &&other) : mLock(std::move(other.mLock)), mValue(other.mValue) {}

	DerefValue(const DerefValue &) = delete;
	DerefValue &operator=(const DerefValue &) = delete;

	operator T &() { return mValue; }

	DerefValue &operator=(const T &other)
	{
	mValue = other;
	return *this;
	}

	private:
	explicit DerefValue(SynchronizedValue &outer) : mLock(outer.mMutex), mValue(outer.mValue) {}

	std::unique_lock<Lockable> mLock;
	T &mValue;

	friend class SynchronizedValue;
	};

	class ConstDerefValue
	{
	public:
	ConstDerefValue(ConstDerefValue &&other)
	: mLock(std::move(other.mLock)), mValue(other.mValue)
	{}

	ConstDerefValue(const ConstDerefValue &) = delete;
	ConstDerefValue &operator=(const ConstDerefValue &) = delete;

	operator const T &() { return mValue; }

	private:
	explicit ConstDerefValue(const SynchronizedValue &outer)
	: mLock(outer.mMutex), mValue(outer.mValue)
	{}

	std::unique_lock<Lockable> mLock;
	const T &mValue;

	friend class SynchronizedValue;
	};

	DerefValue operator() { return DerefValue(this); }
	ConstDerefValue operator() const { return ConstDerefValue(this); }

	template <typename OStream>
	void save(OStream &os) const
	{
	std::lock_guard<Lockable> lock(mMutex);
	os << mValue;
	}

	template <typename IStream>
	void load(IStream &is)
	{
	std::lock_guard<Lockable> lock(mMutex);
	is >> mValue;
	}

	bool operator==(const SynchronizedValue &other) const
	{
	std::unique_lock<Lockable> lock1(mMutex, std::defer_lock);
	std::unique_lock<Lockable> lock2(other.mMutex, std::defer_lock);
	std::lock(lock1, lock2);
	return mValue == other.mValue;
	}

	bool operator!=(const SynchronizedValue &other) const
	{
	std::unique_lock<Lockable> lock1(mMutex, std::defer_lock);
	std::unique_lock<Lockable> lock2(other.mMutex, std::defer_lock);
	std::lock(lock1, lock2);
	return mValue != other.mValue;
	}

	bool operator<(const SynchronizedValue &other) const
	{
	std::unique_lock<Lockable> lock1(mMutex, std::defer_lock);
	std::unique_lock<Lockable> lock2(other.mMutex, std::defer_lock);
	std::lock(lock1, lock2);
	return mValue < other.mValue;
	}

	bool operator>(const SynchronizedValue &other) const
	{
	std::unique_lock<Lockable> lock1(mMutex, std::defer_lock);
	std::unique_lock<Lockable> lock2(other.mMutex, std::defer_lock);
	std::lock(lock1, lock2);
	return mValue > other.mValue;
	}

	bool operator<=(const SynchronizedValue &other) const
	{
	std::unique_lock<Lockable> lock1(mMutex, std::defer_lock);
	std::unique_lock<Lockable> lock2(other.mMutex, std::defer_lock);
	std::lock(lock1, lock2);
	return mValue <= other.mValue;
	}

	bool operator>=(const SynchronizedValue &other) const
	{
	std::unique_lock<Lockable> lock1(mMutex, std::defer_lock);
	std::unique_lock<Lockable> lock2(other.mMutex, std::defer_lock);
	std::lock(lock1, lock2);
	return mValue >= other.mValue;
	}

	bool operator==(const T &other) const
	{
	std::lock_guard<Lockable> lock(mMutex);
	return mValue == other;
	}

	bool operator!=(const T &other) const
	{
	std::lock_guard<Lockable> lock(mMutex);
	return mValue != other;
	}

	bool operator<(const T &other) const
	{
	std::lock_guard<Lockable> lock(mMutex);
	return mValue < other;
	}

	bool operator>(const T &other) const
	{
	std::lock_guard<Lockable> lock(mMutex);
	return mValue > other;
	}

	bool operator<=(const T &other) const
	{
	std::lock_guard<Lockable> lock(mMutex);
	return mValue <= other;
	}

	bool operator>=(const T &other) const
	{
	std::lock_guard<Lockable> lock(mMutex);
	return mValue >= other;
	}

	private:
	T mValue;
	mutable Lockable mMutex;
	};

	template <typename OStream, typename T, typename L>
	inline OStream &operator<<(OStream &os, SynchronizedValue<T, L> const &sv)
	{
	sv.save(os);
	return os;
	}

	template <typename IStream, typename T, typename L>
	inline IStream &operator>>(IStream &is, SynchronizedValue<T, L> &sv)
	{
	sv.load(is);
	return is;
	}

	template <typename T, typename L>
	bool operator==(const T &lhs, const SynchronizedValue<T, L> &rhs)
	{
	return rhs == lhs;
	}

	template <typename T, typename L>
	bool operator!=(const T &lhs, const SynchronizedValue<T, L> &rhs)
	{
	return rhs != lhs;
	}

	template <typename T, typename L>
	bool operator<(const T &lhs, const SynchronizedValue<T, L> &rhs)
	{
	return rhs < lhs;
	}

	template <typename T, typename L>
	bool operator>(const T &lhs, const SynchronizedValue<T, L> &rhs)
	{
	return rhs > lhs;
	}

	template <typename T, typename L>
	bool operator<=(const T &lhs, const SynchronizedValue<T, L> &rhs)
	{
	return rhs <= lhs;
	}

	template <typename T, typename L>
	bool operator>=(const T &lhs, const SynchronizedValue<T, L> &rhs)
	{
	return rhs >= lhs;
	}

	} // namespace angle

	#endif // COMMON_SYNCHRONIZEDVALUE_H_