Source/WebCore/platform/Timer.cpp - WebKit - Git at Google

 /*
  * Copyright (C) 2006, 2008 Apple Inc. All rights reserved.
  * Copyright (C) 2009 Google 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.
  */

 #include "config.h"
 #include "Timer.h"

 #include "RuntimeApplicationChecks.h"
 #include "SharedTimer.h"
 #include "ThreadGlobalData.h"
 #include "ThreadTimers.h"
 #include <limits>
 #include <math.h>
 #include <wtf/MainThread.h>
 #include <wtf/Vector.h>

 #if PLATFORM(COCOA)
 #include <wtf/spi/darwin/dyldSPI.h>
 #endif

 namespace WebCore {

 class TimerHeapReference;

 // Timers are stored in a heap data structure, used to implement a priority queue.
 // This allows us to efficiently determine which timer needs to fire the soonest.
 // Then we set a single shared system timer to fire at that time.
 //
 // When a timer's "next fire time" changes, we need to move it around in the priority queue.
 #if !ASSERT_DISABLED
 static ThreadTimerHeap& threadGlobalTimerHeap()
 {
     return threadGlobalData().threadTimers().timerHeap();
 }
 #endif

 inline ThreadTimerHeapItem::ThreadTimerHeapItem(TimerBase& timer, MonotonicTime time, unsigned insertionOrder)
     : time(time)
     , insertionOrder(insertionOrder)
     , m_threadTimers(threadGlobalData().threadTimers())
     , m_timer(&timer)
 {
     ASSERT(m_timer);
 }

 inline RefPtr<ThreadTimerHeapItem> ThreadTimerHeapItem::create(TimerBase& timer, MonotonicTime time, unsigned insertionOrder)
 {
     return adoptRef(*new ThreadTimerHeapItem { timer, time, insertionOrder });
 }

 // ----------------

 class TimerHeapPointer {
 public:
     TimerHeapPointer(RefPtr<ThreadTimerHeapItem>* pointer)
         : m_pointer(pointer)
     { }

     TimerHeapReference operator*() const;
     RefPtr<ThreadTimerHeapItem>& operator->() const { return *m_pointer; }
 private:
     RefPtr<ThreadTimerHeapItem>* m_pointer;
 };

 class TimerHeapReference {
 public:
     TimerHeapReference(RefPtr<ThreadTimerHeapItem>& reference)
         : m_reference(reference)
     { }

     TimerHeapReference(const TimerHeapReference& other)
         : m_reference(other.m_reference)
     { }

     operator RefPtr<ThreadTimerHeapItem>&() const { return m_reference; }
     TimerHeapPointer operator&() const { return &m_reference; }
     TimerHeapReference& operator=(TimerHeapReference&&);
     TimerHeapReference& operator=(RefPtr<ThreadTimerHeapItem>&&);

     void swap(TimerHeapReference& other);

     void updateHeapIndex();

 private:
     RefPtr<ThreadTimerHeapItem>& m_reference;

     friend void swap(TimerHeapReference a, TimerHeapReference b);
 };

 inline TimerHeapReference TimerHeapPointer::operator*() const
 {
     return TimerHeapReference { *m_pointer };
 }

 inline TimerHeapReference& TimerHeapReference::operator=(TimerHeapReference&& other)
 {
     m_reference = WTFMove(other.m_reference);
     updateHeapIndex();
     return *this;
 }

 inline TimerHeapReference& TimerHeapReference::operator=(RefPtr<ThreadTimerHeapItem>&& item)
 {
     m_reference = WTFMove(item);
     updateHeapIndex();
     return *this;
 }

 inline void TimerHeapReference::swap(TimerHeapReference& other)
 {
     m_reference.swap(other.m_reference);
     updateHeapIndex();
     other.updateHeapIndex();
 }

 inline void TimerHeapReference::updateHeapIndex()
 {
     auto& heap = m_reference->timerHeap();
     if (&m_reference >= heap.data() && &m_reference < heap.data() + heap.size())
         m_reference->setHeapIndex(&m_reference - heap.data());
 }

 inline void swap(TimerHeapReference a, TimerHeapReference b)
 {
     a.swap(b);
 }

 // ----------------

 // Class to represent iterators in the heap when calling the standard library heap algorithms.
 // Uses a custom pointer and reference type that update indices for pointers in the heap.
 class TimerHeapIterator : public std::iterator<std::random_access_iterator_tag, RefPtr<ThreadTimerHeapItem>, ptrdiff_t, TimerHeapPointer, TimerHeapReference> {
 public:
     explicit TimerHeapIterator(RefPtr<ThreadTimerHeapItem>* pointer) : m_pointer(pointer) { checkConsistency(); }

     TimerHeapIterator& operator++() { checkConsistency(); ++m_pointer; checkConsistency(); return *this; }
     TimerHeapIterator operator++(int) { checkConsistency(1); return TimerHeapIterator(m_pointer++); }

     TimerHeapIterator& operator--() { checkConsistency(); --m_pointer; checkConsistency(); return *this; }
     TimerHeapIterator operator--(int) { checkConsistency(-1); return TimerHeapIterator(m_pointer--); }

     TimerHeapIterator& operator+=(ptrdiff_t i) { checkConsistency(); m_pointer += i; checkConsistency(); return *this; }
     TimerHeapIterator& operator-=(ptrdiff_t i) { checkConsistency(); m_pointer -= i; checkConsistency(); return *this; }

     TimerHeapReference operator*() const { return TimerHeapReference(*m_pointer); }
     TimerHeapReference operator[](ptrdiff_t i) const { return TimerHeapReference(m_pointer[i]); }
     RefPtr<ThreadTimerHeapItem>& operator->() const { return *m_pointer; }

 private:
     void checkConsistency(ptrdiff_t offset = 0) const
     {
         ASSERT(m_pointer >= threadGlobalTimerHeap().data());
         ASSERT(m_pointer <= threadGlobalTimerHeap().data() + threadGlobalTimerHeap().size());
         ASSERT_UNUSED(offset, m_pointer + offset >= threadGlobalTimerHeap().data());
         ASSERT_UNUSED(offset, m_pointer + offset <= threadGlobalTimerHeap().data() + threadGlobalTimerHeap().size());
     }

     friend bool operator==(TimerHeapIterator, TimerHeapIterator);
     friend bool operator!=(TimerHeapIterator, TimerHeapIterator);
     friend bool operator<(TimerHeapIterator, TimerHeapIterator);
     friend bool operator>(TimerHeapIterator, TimerHeapIterator);
     friend bool operator<=(TimerHeapIterator, TimerHeapIterator);
     friend bool operator>=(TimerHeapIterator, TimerHeapIterator);

     friend TimerHeapIterator operator+(TimerHeapIterator, size_t);
     friend TimerHeapIterator operator+(size_t, TimerHeapIterator);

     friend TimerHeapIterator operator-(TimerHeapIterator, size_t);
     friend ptrdiff_t operator-(TimerHeapIterator, TimerHeapIterator);

     RefPtr<ThreadTimerHeapItem>* m_pointer;
 };

 inline bool operator==(TimerHeapIterator a, TimerHeapIterator b) { return a.m_pointer == b.m_pointer; }
 inline bool operator!=(TimerHeapIterator a, TimerHeapIterator b) { return a.m_pointer != b.m_pointer; }
 inline bool operator<(TimerHeapIterator a, TimerHeapIterator b) { return a.m_pointer < b.m_pointer; }
 inline bool operator>(TimerHeapIterator a, TimerHeapIterator b) { return a.m_pointer > b.m_pointer; }
 inline bool operator<=(TimerHeapIterator a, TimerHeapIterator b) { return a.m_pointer <= b.m_pointer; }
 inline bool operator>=(TimerHeapIterator a, TimerHeapIterator b) { return a.m_pointer >= b.m_pointer; }

 inline TimerHeapIterator operator+(TimerHeapIterator a, size_t b) { return TimerHeapIterator(a.m_pointer + b); }
 inline TimerHeapIterator operator+(size_t a, TimerHeapIterator b) { return TimerHeapIterator(a + b.m_pointer); }

 inline TimerHeapIterator operator-(TimerHeapIterator a, size_t b) { return TimerHeapIterator(a.m_pointer - b); }
 inline ptrdiff_t operator-(TimerHeapIterator a, TimerHeapIterator b) { return a.m_pointer - b.m_pointer; }

 // ----------------

 class TimerHeapLessThanFunction {
 public:
     static bool compare(const TimerBase& a, const RefPtr<ThreadTimerHeapItem>& b)
     {
         return compare(a.m_heapItem->time, a.m_heapItem->insertionOrder, b->time, b->insertionOrder);
     }

     static bool compare(const RefPtr<ThreadTimerHeapItem>& a, const TimerBase& b)
     {
         return compare(a->time, a->insertionOrder, b.m_heapItem->time, b.m_heapItem->insertionOrder);
     }

     bool operator()(const RefPtr<ThreadTimerHeapItem>& a, const RefPtr<ThreadTimerHeapItem>& b) const
     {
         return compare(a->time, a->insertionOrder, b->time, b->insertionOrder);
     }

 private:
     static bool compare(MonotonicTime aTime, unsigned aOrder, MonotonicTime bTime, unsigned bOrder)
     {
         // The comparisons below are "backwards" because the heap puts the largest
         // element first and we want the lowest time to be the first one in the heap.
         if (bTime != aTime)
             return bTime < aTime;
         // We need to look at the difference of the insertion orders instead of comparing the two
         // outright in case of overflow.
         unsigned difference = aOrder - bOrder;
         return difference < std::numeric_limits<unsigned>::max() / 2;
     }
 };

 // ----------------

 static bool shouldSuppressThreadSafetyCheck()
 {
 #if PLATFORM(IOS_FAMILY)
     return WebThreadIsEnabled() || applicationSDKVersion() < DYLD_IOS_VERSION_12_0;
 #elif PLATFORM(MAC)
     return !isInWebProcess() && applicationSDKVersion() < DYLD_MACOSX_VERSION_10_14;
 #else
     return false;
 #endif
 }

 TimerBase::TimerBase()
 {
 }

 TimerBase::~TimerBase()
 {
     ASSERT(canAccessThreadLocalDataForThread(m_thread.get()));
     RELEASE_ASSERT(canAccessThreadLocalDataForThread(m_thread.get()) || shouldSuppressThreadSafetyCheck());
     stop();
     ASSERT(!inHeap());
     if (m_heapItem)
         m_heapItem->clearTimer();
     m_unalignedNextFireTime = MonotonicTime::nan();
 }

 void TimerBase::start(Seconds nextFireInterval, Seconds repeatInterval)
 {
     ASSERT(canAccessThreadLocalDataForThread(m_thread.get()));

     m_repeatInterval = repeatInterval;
     setNextFireTime(MonotonicTime::now() + nextFireInterval);
 }

 void TimerBase::stop()
 {
     ASSERT(canAccessThreadLocalDataForThread(m_thread.get()));

     m_repeatInterval = 0_s;
     setNextFireTime(MonotonicTime { });

     ASSERT(!static_cast<bool>(nextFireTime()));
     ASSERT(m_repeatInterval == 0_s);
     ASSERT(!inHeap());
 }

 Seconds TimerBase::nextFireInterval() const
 {
     ASSERT(isActive());
     ASSERT(m_heapItem);
     MonotonicTime current = MonotonicTime::now();
     auto fireTime = nextFireTime();
     if (fireTime < current)
         return 0_s;
     return fireTime - current;
 }

 inline void TimerBase::checkHeapIndex() const
 {
 #if !ASSERT_DISABLED
     ASSERT(m_heapItem);
     auto& heap = m_heapItem->timerHeap();
     ASSERT(&heap == &threadGlobalTimerHeap());
     ASSERT(!heap.isEmpty());
     ASSERT(m_heapItem->isInHeap());
     ASSERT(m_heapItem->heapIndex() < m_heapItem->timerHeap().size());
     ASSERT(heap[m_heapItem->heapIndex()] == m_heapItem);
     for (unsigned i = 0, size = heap.size(); i < size; i++)
         ASSERT(heap[i]->heapIndex() == i);
 #endif
 }

 inline void TimerBase::checkConsistency() const
 {
     // Timers should be in the heap if and only if they have a non-zero next fire time.
     ASSERT(inHeap() == static_cast<bool>(nextFireTime()));
     if (inHeap())
         checkHeapIndex();
 }

 void TimerBase::heapDecreaseKey()
 {
     ASSERT(static_cast<bool>(nextFireTime()));
     ASSERT(m_heapItem);
     checkHeapIndex();
     auto* heapData = m_heapItem->timerHeap().data();
     push_heap(TimerHeapIterator(heapData), TimerHeapIterator(heapData + m_heapItem->heapIndex() + 1), TimerHeapLessThanFunction());
     checkHeapIndex();
 }

 inline void TimerBase::heapDelete()
 {
     ASSERT(!static_cast<bool>(nextFireTime()));
     heapPop();
     m_heapItem->timerHeap().removeLast();
     m_heapItem->setNotInHeap();
 }

 void TimerBase::heapDeleteMin()
 {
     ASSERT(!static_cast<bool>(nextFireTime()));
     heapPopMin();
     m_heapItem->timerHeap().removeLast();
     m_heapItem->setNotInHeap();
 }

 inline void TimerBase::heapIncreaseKey()
 {
     ASSERT(static_cast<bool>(nextFireTime()));
     heapPop();
     heapDecreaseKey();
 }

 inline void TimerBase::heapInsert()
 {
     ASSERT(!inHeap());
     ASSERT(m_heapItem);
     auto& heap = m_heapItem->timerHeap();
     heap.append(m_heapItem.copyRef());
     m_heapItem->setHeapIndex(heap.size() - 1);
     heapDecreaseKey();
 }

 inline void TimerBase::heapPop()
 {
     ASSERT(m_heapItem);
     // Temporarily force this timer to have the minimum key so we can pop it.
     MonotonicTime fireTime = m_heapItem->time;
     m_heapItem->time = -MonotonicTime::infinity();
     heapDecreaseKey();
     heapPopMin();
     m_heapItem->time = fireTime;
 }

 void TimerBase::heapPopMin()
 {
     ASSERT(m_heapItem == m_heapItem->timerHeap().first());
     checkHeapIndex();
     auto& heap = m_heapItem->timerHeap();
     auto* heapData = heap.data();
     pop_heap(TimerHeapIterator(heapData), TimerHeapIterator(heapData + heap.size()), TimerHeapLessThanFunction());
     checkHeapIndex();
     ASSERT(m_heapItem == m_heapItem->timerHeap().last());
 }

 void TimerBase::heapDeleteNullMin(ThreadTimerHeap& heap)
 {
     RELEASE_ASSERT(!heap.first()->hasTimer());
     heap.first()->time = -MonotonicTime::infinity();
     auto* heapData = heap.data();
     pop_heap(TimerHeapIterator(heapData), TimerHeapIterator(heapData + heap.size()), TimerHeapLessThanFunction());
     heap.removeLast();
 }

 static inline bool parentHeapPropertyHolds(const TimerBase* current, const ThreadTimerHeap& heap, unsigned currentIndex)
 {
     if (!currentIndex)
         return true;
     unsigned parentIndex = (currentIndex - 1) / 2;
     return TimerHeapLessThanFunction::compare(*current, heap[parentIndex]);
 }

 static inline bool childHeapPropertyHolds(const TimerBase* current, const ThreadTimerHeap& heap, unsigned childIndex)
 {
     if (childIndex >= heap.size())
         return true;
     return TimerHeapLessThanFunction::compare(heap[childIndex], *current);
 }

 bool TimerBase::hasValidHeapPosition() const
 {
     ASSERT(nextFireTime());
     ASSERT(m_heapItem);
     if (!inHeap())
         return false;
     // Check if the heap property still holds with the new fire time. If it does we don't need to do anything.
     // This assumes that the STL heap is a standard binary heap. In an unlikely event it is not, the assertions
     // in updateHeapIfNeeded() will get hit.
     const auto& heap = m_heapItem->timerHeap();
     unsigned heapIndex = m_heapItem->heapIndex();
     if (!parentHeapPropertyHolds(this, heap, heapIndex))
         return false;
     unsigned childIndex1 = 2 * heapIndex + 1;
     unsigned childIndex2 = childIndex1 + 1;
     return childHeapPropertyHolds(this, heap, childIndex1) && childHeapPropertyHolds(this, heap, childIndex2);
 }

 void TimerBase::updateHeapIfNeeded(MonotonicTime oldTime)
 {
     auto fireTime = nextFireTime();
     if (fireTime && hasValidHeapPosition())
         return;

 #if !ASSERT_DISABLED
     Optional<unsigned> oldHeapIndex;
     if (m_heapItem->isInHeap())
         oldHeapIndex = m_heapItem->heapIndex();
 #endif

     if (!oldTime)
         heapInsert();
     else if (!fireTime)
         heapDelete();
     else if (fireTime < oldTime)
         heapDecreaseKey();
     else
         heapIncreaseKey();

 #if !ASSERT_DISABLED
     Optional<unsigned> newHeapIndex;
     if (m_heapItem->isInHeap())
         newHeapIndex = m_heapItem->heapIndex();
     ASSERT(newHeapIndex != oldHeapIndex);
 #endif

     ASSERT(!inHeap() || hasValidHeapPosition());
 }

 void TimerBase::setNextFireTime(MonotonicTime newTime)
 {
     ASSERT(canAccessThreadLocalDataForThread(m_thread.get()));
     RELEASE_ASSERT(canAccessThreadLocalDataForThread(m_thread.get()) || shouldSuppressThreadSafetyCheck());
     bool timerHasBeenDeleted = std::isnan(m_unalignedNextFireTime);
     RELEASE_ASSERT_WITH_SECURITY_IMPLICATION(!timerHasBeenDeleted);

     if (m_unalignedNextFireTime != newTime) {
         RELEASE_ASSERT(!std::isnan(newTime));
         m_unalignedNextFireTime = newTime;
     }

     // Keep heap valid while changing the next-fire time.
     MonotonicTime oldTime = nextFireTime();
     // Don't realign zero-delay timers.
     if (newTime) {
         if (auto newAlignedTime = alignedFireTime(newTime))
             newTime = newAlignedTime.value();
     }

     if (oldTime != newTime) {
         auto newOrder = threadGlobalData().threadTimers().nextHeapInsertionCount();

         if (!m_heapItem)
             m_heapItem = ThreadTimerHeapItem::create(*this, newTime, 0);
         m_heapItem->time = newTime;
         m_heapItem->insertionOrder = newOrder;

         bool wasFirstTimerInHeap = m_heapItem->isFirstInHeap();

         updateHeapIfNeeded(oldTime);

         bool isFirstTimerInHeap = m_heapItem->isFirstInHeap();

         if (wasFirstTimerInHeap || isFirstTimerInHeap)
             threadGlobalData().threadTimers().updateSharedTimer();
     }

     checkConsistency();
 }

 void TimerBase::fireTimersInNestedEventLoop()
 {
     // Redirect to ThreadTimers.
     threadGlobalData().threadTimers().fireTimersInNestedEventLoop();
 }

 void TimerBase::didChangeAlignmentInterval()
 {
     setNextFireTime(m_unalignedNextFireTime);
 }

 Seconds TimerBase::nextUnalignedFireInterval() const
 {
     ASSERT(isActive());
     auto result = std::max(m_unalignedNextFireTime - MonotonicTime::now(), 0_s);
     RELEASE_ASSERT(std::isfinite(result));
     return result;
 }

 } // namespace WebCore
	/*
	* Copyright (C) 2006, 2008 Apple Inc. All rights reserved.
	* Copyright (C) 2009 Google 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.
	*/

	#include "config.h"
	#include "Timer.h"

	#include "RuntimeApplicationChecks.h"
	#include "SharedTimer.h"
	#include "ThreadGlobalData.h"
	#include "ThreadTimers.h"
	#include <limits>
	#include <math.h>
	#include <wtf/MainThread.h>
	#include <wtf/Vector.h>

	#if PLATFORM(COCOA)
	#include <wtf/spi/darwin/dyldSPI.h>
	#endif

	namespace WebCore {

	class TimerHeapReference;

	// Timers are stored in a heap data structure, used to implement a priority queue.
	// This allows us to efficiently determine which timer needs to fire the soonest.
	// Then we set a single shared system timer to fire at that time.
	//
	// When a timer's "next fire time" changes, we need to move it around in the priority queue.
	#if !ASSERT_DISABLED
	static ThreadTimerHeap& threadGlobalTimerHeap()
	{
	return threadGlobalData().threadTimers().timerHeap();
	}
	#endif

	inline ThreadTimerHeapItem::ThreadTimerHeapItem(TimerBase& timer, MonotonicTime time, unsigned insertionOrder)
	: time(time)
	, insertionOrder(insertionOrder)
	, m_threadTimers(threadGlobalData().threadTimers())
	, m_timer(&timer)
	{
	ASSERT(m_timer);
	}

	inline RefPtr<ThreadTimerHeapItem> ThreadTimerHeapItem::create(TimerBase& timer, MonotonicTime time, unsigned insertionOrder)
	{
	return adoptRef(*new ThreadTimerHeapItem { timer, time, insertionOrder });
	}

	// ----------------

	class TimerHeapPointer {
	public:
	TimerHeapPointer(RefPtr<ThreadTimerHeapItem>* pointer)
	: m_pointer(pointer)
	{ }

	TimerHeapReference operator*() const;
	RefPtr<ThreadTimerHeapItem>& operator->() const { return *m_pointer; }
	private:
	RefPtr<ThreadTimerHeapItem>* m_pointer;
	};

	class TimerHeapReference {
	public:
	TimerHeapReference(RefPtr<ThreadTimerHeapItem>& reference)
	: m_reference(reference)
	{ }

	TimerHeapReference(const TimerHeapReference& other)
	: m_reference(other.m_reference)
	{ }

	operator RefPtr<ThreadTimerHeapItem>&() const { return m_reference; }
	TimerHeapPointer operator&() const { return &m_reference; }
	TimerHeapReference& operator=(TimerHeapReference&&);
	TimerHeapReference& operator=(RefPtr<ThreadTimerHeapItem>&&);

	void swap(TimerHeapReference& other);

	void updateHeapIndex();

	private:
	RefPtr<ThreadTimerHeapItem>& m_reference;

	friend void swap(TimerHeapReference a, TimerHeapReference b);
	};

	inline TimerHeapReference TimerHeapPointer::operator*() const
	{
	return TimerHeapReference { *m_pointer };
	}

	inline TimerHeapReference& TimerHeapReference::operator=(TimerHeapReference&& other)
	{
	m_reference = WTFMove(other.m_reference);
	updateHeapIndex();
	return *this;
	}

	inline TimerHeapReference& TimerHeapReference::operator=(RefPtr<ThreadTimerHeapItem>&& item)
	{
	m_reference = WTFMove(item);
	updateHeapIndex();
	return *this;
	}

	inline void TimerHeapReference::swap(TimerHeapReference& other)
	{
	m_reference.swap(other.m_reference);
	updateHeapIndex();
	other.updateHeapIndex();
	}

	inline void TimerHeapReference::updateHeapIndex()
	{
	auto& heap = m_reference->timerHeap();
	if (&m_reference >= heap.data() && &m_reference < heap.data() + heap.size())
	m_reference->setHeapIndex(&m_reference - heap.data());
	}

	inline void swap(TimerHeapReference a, TimerHeapReference b)
	{
	a.swap(b);
	}

	// ----------------

	// Class to represent iterators in the heap when calling the standard library heap algorithms.
	// Uses a custom pointer and reference type that update indices for pointers in the heap.
	class TimerHeapIterator : public std::iterator<std::random_access_iterator_tag, RefPtr<ThreadTimerHeapItem>, ptrdiff_t, TimerHeapPointer, TimerHeapReference> {
	public:
	explicit TimerHeapIterator(RefPtr<ThreadTimerHeapItem>* pointer) : m_pointer(pointer) { checkConsistency(); }

	TimerHeapIterator& operator++() { checkConsistency(); ++m_pointer; checkConsistency(); return *this; }
	TimerHeapIterator operator++(int) { checkConsistency(1); return TimerHeapIterator(m_pointer++); }

	TimerHeapIterator& operator--() { checkConsistency(); --m_pointer; checkConsistency(); return *this; }
	TimerHeapIterator operator--(int) { checkConsistency(-1); return TimerHeapIterator(m_pointer--); }

	TimerHeapIterator& operator+=(ptrdiff_t i) { checkConsistency(); m_pointer += i; checkConsistency(); return *this; }
	TimerHeapIterator& operator-=(ptrdiff_t i) { checkConsistency(); m_pointer -= i; checkConsistency(); return *this; }

	TimerHeapReference operator() const { return TimerHeapReference(m_pointer); }
	TimerHeapReference operator[](ptrdiff_t i) const { return TimerHeapReference(m_pointer[i]); }
	RefPtr<ThreadTimerHeapItem>& operator->() const { return *m_pointer; }

	private:
	void checkConsistency(ptrdiff_t offset = 0) const
	{
	ASSERT(m_pointer >= threadGlobalTimerHeap().data());
	ASSERT(m_pointer <= threadGlobalTimerHeap().data() + threadGlobalTimerHeap().size());
	ASSERT_UNUSED(offset, m_pointer + offset >= threadGlobalTimerHeap().data());
	ASSERT_UNUSED(offset, m_pointer + offset <= threadGlobalTimerHeap().data() + threadGlobalTimerHeap().size());
	}

	friend bool operator==(TimerHeapIterator, TimerHeapIterator);
	friend bool operator!=(TimerHeapIterator, TimerHeapIterator);
	friend bool operator<(TimerHeapIterator, TimerHeapIterator);
	friend bool operator>(TimerHeapIterator, TimerHeapIterator);
	friend bool operator<=(TimerHeapIterator, TimerHeapIterator);
	friend bool operator>=(TimerHeapIterator, TimerHeapIterator);

	friend TimerHeapIterator operator+(TimerHeapIterator, size_t);
	friend TimerHeapIterator operator+(size_t, TimerHeapIterator);

	friend TimerHeapIterator operator-(TimerHeapIterator, size_t);
	friend ptrdiff_t operator-(TimerHeapIterator, TimerHeapIterator);

	RefPtr<ThreadTimerHeapItem>* m_pointer;
	};

	inline bool operator==(TimerHeapIterator a, TimerHeapIterator b) { return a.m_pointer == b.m_pointer; }
	inline bool operator!=(TimerHeapIterator a, TimerHeapIterator b) { return a.m_pointer != b.m_pointer; }
	inline bool operator<(TimerHeapIterator a, TimerHeapIterator b) { return a.m_pointer < b.m_pointer; }
	inline bool operator>(TimerHeapIterator a, TimerHeapIterator b) { return a.m_pointer > b.m_pointer; }
	inline bool operator<=(TimerHeapIterator a, TimerHeapIterator b) { return a.m_pointer <= b.m_pointer; }
	inline bool operator>=(TimerHeapIterator a, TimerHeapIterator b) { return a.m_pointer >= b.m_pointer; }

	inline TimerHeapIterator operator+(TimerHeapIterator a, size_t b) { return TimerHeapIterator(a.m_pointer + b); }
	inline TimerHeapIterator operator+(size_t a, TimerHeapIterator b) { return TimerHeapIterator(a + b.m_pointer); }

	inline TimerHeapIterator operator-(TimerHeapIterator a, size_t b) { return TimerHeapIterator(a.m_pointer - b); }
	inline ptrdiff_t operator-(TimerHeapIterator a, TimerHeapIterator b) { return a.m_pointer - b.m_pointer; }

	// ----------------

	class TimerHeapLessThanFunction {
	public:
	static bool compare(const TimerBase& a, const RefPtr<ThreadTimerHeapItem>& b)
	{
	return compare(a.m_heapItem->time, a.m_heapItem->insertionOrder, b->time, b->insertionOrder);
	}

	static bool compare(const RefPtr<ThreadTimerHeapItem>& a, const TimerBase& b)
	{
	return compare(a->time, a->insertionOrder, b.m_heapItem->time, b.m_heapItem->insertionOrder);
	}

	bool operator()(const RefPtr<ThreadTimerHeapItem>& a, const RefPtr<ThreadTimerHeapItem>& b) const
	{
	return compare(a->time, a->insertionOrder, b->time, b->insertionOrder);
	}

	private:
	static bool compare(MonotonicTime aTime, unsigned aOrder, MonotonicTime bTime, unsigned bOrder)
	{
	// The comparisons below are "backwards" because the heap puts the largest
	// element first and we want the lowest time to be the first one in the heap.
	if (bTime != aTime)
	return bTime < aTime;
	// We need to look at the difference of the insertion orders instead of comparing the two
	// outright in case of overflow.
	unsigned difference = aOrder - bOrder;
	return difference < std::numeric_limits<unsigned>::max() / 2;
	}
	};

	// ----------------

	static bool shouldSuppressThreadSafetyCheck()
	{
	#if PLATFORM(IOS_FAMILY)
	return WebThreadIsEnabled() \|\| applicationSDKVersion() < DYLD_IOS_VERSION_12_0;
	#elif PLATFORM(MAC)
	return !isInWebProcess() && applicationSDKVersion() < DYLD_MACOSX_VERSION_10_14;
	#else
	return false;
	#endif
	}

	TimerBase::TimerBase()
	{
	}

	TimerBase::~TimerBase()
	{
	ASSERT(canAccessThreadLocalDataForThread(m_thread.get()));
	RELEASE_ASSERT(canAccessThreadLocalDataForThread(m_thread.get()) \|\| shouldSuppressThreadSafetyCheck());
	stop();
	ASSERT(!inHeap());
	if (m_heapItem)
	m_heapItem->clearTimer();
	m_unalignedNextFireTime = MonotonicTime::nan();
	}

	void TimerBase::start(Seconds nextFireInterval, Seconds repeatInterval)
	{
	ASSERT(canAccessThreadLocalDataForThread(m_thread.get()));

	m_repeatInterval = repeatInterval;
	setNextFireTime(MonotonicTime::now() + nextFireInterval);
	}

	void TimerBase::stop()
	{
	ASSERT(canAccessThreadLocalDataForThread(m_thread.get()));

	m_repeatInterval = 0_s;
	setNextFireTime(MonotonicTime { });

	ASSERT(!static_cast<bool>(nextFireTime()));
	ASSERT(m_repeatInterval == 0_s);
	ASSERT(!inHeap());
	}

	Seconds TimerBase::nextFireInterval() const
	{
	ASSERT(isActive());
	ASSERT(m_heapItem);
	MonotonicTime current = MonotonicTime::now();
	auto fireTime = nextFireTime();
	if (fireTime < current)
	return 0_s;
	return fireTime - current;
	}

	inline void TimerBase::checkHeapIndex() const
	{
	#if !ASSERT_DISABLED
	ASSERT(m_heapItem);
	auto& heap = m_heapItem->timerHeap();
	ASSERT(&heap == &threadGlobalTimerHeap());
	ASSERT(!heap.isEmpty());
	ASSERT(m_heapItem->isInHeap());
	ASSERT(m_heapItem->heapIndex() < m_heapItem->timerHeap().size());
	ASSERT(heap[m_heapItem->heapIndex()] == m_heapItem);
	for (unsigned i = 0, size = heap.size(); i < size; i++)
	ASSERT(heap[i]->heapIndex() == i);
	#endif
	}

	inline void TimerBase::checkConsistency() const
	{
	// Timers should be in the heap if and only if they have a non-zero next fire time.
	ASSERT(inHeap() == static_cast<bool>(nextFireTime()));
	if (inHeap())
	checkHeapIndex();
	}

	void TimerBase::heapDecreaseKey()
	{
	ASSERT(static_cast<bool>(nextFireTime()));
	ASSERT(m_heapItem);
	checkHeapIndex();
	auto* heapData = m_heapItem->timerHeap().data();
	push_heap(TimerHeapIterator(heapData), TimerHeapIterator(heapData + m_heapItem->heapIndex() + 1), TimerHeapLessThanFunction());
	checkHeapIndex();
	}

	inline void TimerBase::heapDelete()
	{
	ASSERT(!static_cast<bool>(nextFireTime()));
	heapPop();
	m_heapItem->timerHeap().removeLast();
	m_heapItem->setNotInHeap();
	}

	void TimerBase::heapDeleteMin()
	{
	ASSERT(!static_cast<bool>(nextFireTime()));
	heapPopMin();
	m_heapItem->timerHeap().removeLast();
	m_heapItem->setNotInHeap();
	}

	inline void TimerBase::heapIncreaseKey()
	{
	ASSERT(static_cast<bool>(nextFireTime()));
	heapPop();
	heapDecreaseKey();
	}

	inline void TimerBase::heapInsert()
	{
	ASSERT(!inHeap());
	ASSERT(m_heapItem);
	auto& heap = m_heapItem->timerHeap();
	heap.append(m_heapItem.copyRef());
	m_heapItem->setHeapIndex(heap.size() - 1);
	heapDecreaseKey();
	}

	inline void TimerBase::heapPop()
	{
	ASSERT(m_heapItem);
	// Temporarily force this timer to have the minimum key so we can pop it.
	MonotonicTime fireTime = m_heapItem->time;
	m_heapItem->time = -MonotonicTime::infinity();
	heapDecreaseKey();
	heapPopMin();
	m_heapItem->time = fireTime;
	}

	void TimerBase::heapPopMin()
	{
	ASSERT(m_heapItem == m_heapItem->timerHeap().first());
	checkHeapIndex();
	auto& heap = m_heapItem->timerHeap();
	auto* heapData = heap.data();
	pop_heap(TimerHeapIterator(heapData), TimerHeapIterator(heapData + heap.size()), TimerHeapLessThanFunction());
	checkHeapIndex();
	ASSERT(m_heapItem == m_heapItem->timerHeap().last());
	}

	void TimerBase::heapDeleteNullMin(ThreadTimerHeap& heap)
	{
	RELEASE_ASSERT(!heap.first()->hasTimer());
	heap.first()->time = -MonotonicTime::infinity();
	auto* heapData = heap.data();
	pop_heap(TimerHeapIterator(heapData), TimerHeapIterator(heapData + heap.size()), TimerHeapLessThanFunction());
	heap.removeLast();
	}

	static inline bool parentHeapPropertyHolds(const TimerBase* current, const ThreadTimerHeap& heap, unsigned currentIndex)
	{
	if (!currentIndex)
	return true;
	unsigned parentIndex = (currentIndex - 1) / 2;
	return TimerHeapLessThanFunction::compare(*current, heap[parentIndex]);
	}

	static inline bool childHeapPropertyHolds(const TimerBase* current, const ThreadTimerHeap& heap, unsigned childIndex)
	{
	if (childIndex >= heap.size())
	return true;
	return TimerHeapLessThanFunction::compare(heap[childIndex], *current);
	}

	bool TimerBase::hasValidHeapPosition() const
	{
	ASSERT(nextFireTime());
	ASSERT(m_heapItem);
	if (!inHeap())
	return false;
	// Check if the heap property still holds with the new fire time. If it does we don't need to do anything.
	// This assumes that the STL heap is a standard binary heap. In an unlikely event it is not, the assertions
	// in updateHeapIfNeeded() will get hit.
	const auto& heap = m_heapItem->timerHeap();
	unsigned heapIndex = m_heapItem->heapIndex();
	if (!parentHeapPropertyHolds(this, heap, heapIndex))
	return false;
	unsigned childIndex1 = 2 * heapIndex + 1;
	unsigned childIndex2 = childIndex1 + 1;
	return childHeapPropertyHolds(this, heap, childIndex1) && childHeapPropertyHolds(this, heap, childIndex2);
	}

	void TimerBase::updateHeapIfNeeded(MonotonicTime oldTime)
	{
	auto fireTime = nextFireTime();
	if (fireTime && hasValidHeapPosition())
	return;

	#if !ASSERT_DISABLED
	Optional<unsigned> oldHeapIndex;
	if (m_heapItem->isInHeap())
	oldHeapIndex = m_heapItem->heapIndex();
	#endif

	if (!oldTime)
	heapInsert();
	else if (!fireTime)
	heapDelete();
	else if (fireTime < oldTime)
	heapDecreaseKey();
	else
	heapIncreaseKey();

	#if !ASSERT_DISABLED
	Optional<unsigned> newHeapIndex;
	if (m_heapItem->isInHeap())
	newHeapIndex = m_heapItem->heapIndex();
	ASSERT(newHeapIndex != oldHeapIndex);
	#endif

	ASSERT(!inHeap() \|\| hasValidHeapPosition());
	}

	void TimerBase::setNextFireTime(MonotonicTime newTime)
	{
	ASSERT(canAccessThreadLocalDataForThread(m_thread.get()));
	RELEASE_ASSERT(canAccessThreadLocalDataForThread(m_thread.get()) \|\| shouldSuppressThreadSafetyCheck());
	bool timerHasBeenDeleted = std::isnan(m_unalignedNextFireTime);
	RELEASE_ASSERT_WITH_SECURITY_IMPLICATION(!timerHasBeenDeleted);

	if (m_unalignedNextFireTime != newTime) {
	RELEASE_ASSERT(!std::isnan(newTime));
	m_unalignedNextFireTime = newTime;
	}

	// Keep heap valid while changing the next-fire time.
	MonotonicTime oldTime = nextFireTime();
	// Don't realign zero-delay timers.
	if (newTime) {
	if (auto newAlignedTime = alignedFireTime(newTime))
	newTime = newAlignedTime.value();
	}

	if (oldTime != newTime) {
	auto newOrder = threadGlobalData().threadTimers().nextHeapInsertionCount();

	if (!m_heapItem)
	m_heapItem = ThreadTimerHeapItem::create(*this, newTime, 0);
	m_heapItem->time = newTime;
	m_heapItem->insertionOrder = newOrder;

	bool wasFirstTimerInHeap = m_heapItem->isFirstInHeap();

	updateHeapIfNeeded(oldTime);

	bool isFirstTimerInHeap = m_heapItem->isFirstInHeap();

	if (wasFirstTimerInHeap \|\| isFirstTimerInHeap)
	threadGlobalData().threadTimers().updateSharedTimer();
	}

	checkConsistency();
	}

	void TimerBase::fireTimersInNestedEventLoop()
	{
	// Redirect to ThreadTimers.
	threadGlobalData().threadTimers().fireTimersInNestedEventLoop();
	}

	void TimerBase::didChangeAlignmentInterval()
	{
	setNextFireTime(m_unalignedNextFireTime);
	}

	Seconds TimerBase::nextUnalignedFireInterval() const
	{
	ASSERT(isActive());
	auto result = std::max(m_unalignedNextFireTime - MonotonicTime::now(), 0_s);
	RELEASE_ASSERT(std::isfinite(result));
	return result;
	}

	} // namespace WebCore