src/views/SkEvent.cpp - platform/external/skqp - Gitiles

 /*
  * Copyright 2006 The Android Open Source Project
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */


 #include "SkDOM.h"
 #include "SkEvent.h"

 void SkEvent::initialize(const char* type, size_t typeLen,
                          SkEventSinkID targetID) {
     fType = nullptr;
     setType(type, typeLen);
     f32 = 0;
     fTargetID = targetID;
     fTargetProc = nullptr;
 #ifdef SK_DEBUG
     fTime = 0;
     fNextEvent = nullptr;
 #endif
 }

 SkEvent::SkEvent()
 {
     initialize("", 0, 0);
 }

 SkEvent::SkEvent(const SkEvent& src)
 {
     *this = src;
     if (((size_t) fType & 1) == 0)
         setType(src.fType);
 }

 SkEvent::SkEvent(const SkString& type, SkEventSinkID targetID)
 {
     initialize(type.c_str(), type.size(), targetID);
 }

 SkEvent::SkEvent(const char type[], SkEventSinkID targetID)
 {
     SkASSERT(type);
     initialize(type, strlen(type), targetID);
 }

 SkEvent::~SkEvent()
 {
     if (((size_t) fType & 1) == 0)
         sk_free((void*) fType);
 }

 static size_t makeCharArray(char* buffer, size_t compact)
 {
     size_t bits = (size_t) compact >> 1;
     memcpy(buffer, &bits, sizeof(compact));
     buffer[sizeof(compact)] = 0;
     return strlen(buffer);
 }

 void SkEvent::getType(SkString* str) const
 {
     if (str)
     {
         if ((size_t) fType & 1) // not a pointer
         {
             char chars[sizeof(size_t) + 1];
             size_t len = makeCharArray(chars, (size_t) fType);
             str->set(chars, len);
         }
         else
             str->set(fType);
     }
 }

 bool SkEvent::isType(const SkString& str) const
 {
     return this->isType(str.c_str(), str.size());
 }

 bool SkEvent::isType(const char type[], size_t typeLen) const
 {
     if (typeLen == 0)
         typeLen = strlen(type);
     if ((size_t) fType & 1) {   // not a pointer
         char chars[sizeof(size_t) + 1];
         size_t len = makeCharArray(chars, (size_t) fType);
         return len == typeLen && strncmp(chars, type, typeLen) == 0;
     }
     return strncmp(fType, type, typeLen) == 0 && fType[typeLen] == 0;
 }

 void SkEvent::setType(const char type[], size_t typeLen)
 {
     if (typeLen == 0)
         typeLen = strlen(type);
     if (typeLen <= sizeof(fType)) {
         size_t slot = 0;
         memcpy(&slot, type, typeLen);
         if (slot << 1 >> 1 != slot)
             goto useCharStar;
         slot <<= 1;
         slot |= 1;
         fType = (char*) slot;
     } else {
 useCharStar:
         fType = (char*) sk_malloc_throw(typeLen + 1);
         SkASSERT(((size_t) fType & 1) == 0);
         memcpy(fType, type, typeLen);
         fType[typeLen] = 0;
     }
 }

 void SkEvent::setType(const SkString& type)
 {
     setType(type.c_str());
 }

 ////////////////////////////////////////////////////////////////////////////

 #include "SkParse.h"

 void SkEvent::inflate(const SkDOM& dom, const SkDOM::Node* node)
 {
     const char* name = dom.findAttr(node, "type");
     if (name)
         this->setType(name);

     const char* value;
     if ((value = dom.findAttr(node, "fast32")) != nullptr)
     {
         int32_t n;
         if (SkParse::FindS32(value, &n))
             this->setFast32(n);
     }

     for (node = dom.getFirstChild(node); node; node = dom.getNextSibling(node))
     {
         if (strcmp(dom.getName(node), "data"))
         {
             SkDEBUGCODE(SkDebugf("SkEvent::inflate unrecognized subelement <%s>\n", dom.getName(node));)
             continue;
         }

         name = dom.findAttr(node, "name");
         if (name == nullptr)
         {
             SkDEBUGCODE(SkDebugf("SkEvent::inflate missing required \"name\" attribute in <data> subelement\n");)
             continue;
         }

         if ((value = dom.findAttr(node, "s32")) != nullptr)
         {
             int32_t n;
             if (SkParse::FindS32(value, &n))
                 this->setS32(name, n);
         }
         else if ((value = dom.findAttr(node, "scalar")) != nullptr)
         {
             SkScalar x;
             if (SkParse::FindScalar(value, &x))
                 this->setScalar(name, x);
         }
         else if ((value = dom.findAttr(node, "string")) != nullptr)
             this->setString(name, value);
 #ifdef SK_DEBUG
         else
         {
             SkDebugf("SkEvent::inflate <data name=\"%s\"> subelement missing required type attribute [S32 | scalar | string]\n", name);
         }
 #endif
     }
 }

 #ifdef SK_DEBUG

     #ifndef SkScalarToFloat
         #define SkScalarToFloat(x)  ((x) / 65536.f)
     #endif

     void SkEvent::dump(const char title[])
     {
         if (title)
             SkDebugf("%s ", title);

         SkString    etype;
         this->getType(&etype);
         SkDebugf("event<%s> fast32=%d", etype.c_str(), this->getFast32());

         const SkMetaData&   md = this->getMetaData();
         SkMetaData::Iter    iter(md);
         SkMetaData::Type    mtype;
         int                 count;
         const char*         name;

         while ((name = iter.next(&mtype, &count)) != nullptr)
         {
             SkASSERT(count > 0);

             SkDebugf(" <%s>=", name);
             switch (mtype) {
             case SkMetaData::kS32_Type:     // vector version???
                 {
                     int32_t value;
                     md.findS32(name, &value);
                     SkDebugf("%d ", value);
                 }
                 break;
             case SkMetaData::kScalar_Type:
                 {
                     const SkScalar* values = md.findScalars(name, &count, nullptr);
                     SkDebugf("%f", SkScalarToFloat(values[0]));
                     for (int i = 1; i < count; i++)
                         SkDebugf(", %f", SkScalarToFloat(values[i]));
                     SkDebugf(" ");
                 }
                 break;
             case SkMetaData::kString_Type:
                 {
                     const char* value = md.findString(name);
                     SkASSERT(value);
                     SkDebugf("<%s> ", value);
                 }
                 break;
             case SkMetaData::kPtr_Type:     // vector version???
                 {
                     void*   value;
                     md.findPtr(name, &value);
                     SkDebugf("%p ", value);
                 }
                 break;
             case SkMetaData::kBool_Type:    // vector version???
                 {
                     bool    value;
                     md.findBool(name, &value);
                     SkDebugf("%s ", value ? "true" : "false");
                 }
                 break;
             default:
                 SkDEBUGFAIL("unknown metadata type returned from iterator");
                 break;
             }
         }
         SkDebugf("\n");
     }
 #endif

 ///////////////////////////////////////////////////////////////////////////////////////

 #ifdef SK_DEBUG
 // #define SK_TRACE_EVENTSx
 #endif

 #ifdef SK_TRACE_EVENTS
     static void event_log(const char s[])
     {
         SkDEBUGF(("%s\n", s));
     }

     #define EVENT_LOG(s)        event_log(s)
     #define EVENT_LOGN(s, n)    do { SkString str(s); str.append(" "); str.appendS32(n); event_log(str.c_str()); } while (0)
 #else
     #define EVENT_LOG(s)
     #define EVENT_LOGN(s, n)
 #endif

 #include "SkMutex.h"
 #include "SkTime.h"

 class SkEvent_Globals {
 public:
     SkEvent_Globals() {
         fEventQHead = nullptr;
         fEventQTail = nullptr;
         fDelayQHead = nullptr;
         SkDEBUGCODE(fEventCounter = 0;)
     }

     SkMutex     fEventMutex;
     SkEvent*    fEventQHead, *fEventQTail;
     SkEvent*    fDelayQHead;
     SkDEBUGCODE(int fEventCounter;)
 };

 static SkEvent_Globals& getGlobals() {
     // leak this, so we don't incure any shutdown perf hit
     static SkEvent_Globals* gGlobals = new SkEvent_Globals;
     return *gGlobals;
 }

 ///////////////////////////////////////////////////////////////////////////////

 void SkEvent::postDelay(SkMSec delay) {
     if (!fTargetID && !fTargetProc) {
         delete this;
         return;
     }

     if (delay) {
         this->postTime(GetMSecsSinceStartup() + delay);
         return;
     }

     SkEvent_Globals& globals = getGlobals();

     globals.fEventMutex.acquire();
     bool wasEmpty = SkEvent::Enqueue(this);
     globals.fEventMutex.release();

     // call outside of us holding the mutex
     if (wasEmpty) {
         SkEvent::SignalNonEmptyQueue();
     }
 }

 void SkEvent::postTime(SkMSec time) {
     if (!fTargetID && !fTargetProc) {
         delete this;
         return;
     }

     SkEvent_Globals& globals = getGlobals();

     globals.fEventMutex.acquire();
     SkMSec queueDelay = SkEvent::EnqueueTime(this, time);
     globals.fEventMutex.release();

     // call outside of us holding the mutex
     if ((int32_t)queueDelay != ~0) {
         SkEvent::SignalQueueTimer(queueDelay);
     }
 }

 bool SkEvent::Enqueue(SkEvent* evt) {
     SkEvent_Globals& globals = getGlobals();
     //  gEventMutex acquired by caller

     SkASSERT(evt);

     bool wasEmpty = globals.fEventQHead == nullptr;

     if (globals.fEventQTail)
         globals.fEventQTail->fNextEvent = evt;
     globals.fEventQTail = evt;
     if (globals.fEventQHead == nullptr)
         globals.fEventQHead = evt;
     evt->fNextEvent = nullptr;

     SkDEBUGCODE(++globals.fEventCounter);

     return wasEmpty;
 }

 SkEvent* SkEvent::Dequeue() {
     SkEvent_Globals& globals = getGlobals();
     globals.fEventMutex.acquire();

     SkEvent* evt = globals.fEventQHead;
     if (evt) {
         SkDEBUGCODE(--globals.fEventCounter);

         globals.fEventQHead = evt->fNextEvent;
         if (globals.fEventQHead == nullptr) {
             globals.fEventQTail = nullptr;
         }
     }
     globals.fEventMutex.release();

     return evt;
 }

 bool SkEvent::QHasEvents() {
     SkEvent_Globals& globals = getGlobals();

     // this is not thread accurate, need a semaphore for that
     return globals.fEventQHead != nullptr;
 }

 #ifdef SK_TRACE_EVENTS
     static int gDelayDepth;
 #endif

 SkMSec SkEvent::EnqueueTime(SkEvent* evt, SkMSec time) {
     SkEvent_Globals& globals = getGlobals();
     //  gEventMutex acquired by caller

     SkEvent* curr = globals.fDelayQHead;
     SkEvent* prev = nullptr;

     while (curr) {
         if (SkMSec_LT(time, curr->fTime)) {
             break;
         }
         prev = curr;
         curr = curr->fNextEvent;
     }

     evt->fTime = time;
     evt->fNextEvent = curr;
     if (prev == nullptr) {
         globals.fDelayQHead = evt;
     } else {
         prev->fNextEvent = evt;
     }

     SkMSec delay = globals.fDelayQHead->fTime - GetMSecsSinceStartup();
     if ((int32_t)delay <= 0) {
         delay = 1;
     }
     return delay;
 }

 ///////////////////////////////////////////////////////////////////////////////

 #include "SkEventSink.h"

 bool SkEvent::ProcessEvent() {
     std::unique_ptr<SkEvent> evt(SkEvent::Dequeue());
     bool                     again = false;

     EVENT_LOGN("ProcessEvent", (int32_t)evt);

     if (evt) {
         (void)SkEventSink::DoEvent(*evt);
         again = SkEvent::QHasEvents();
     }
     return again;
 }

 void SkEvent::ServiceQueueTimer()
 {
     SkEvent_Globals& globals = getGlobals();

     globals.fEventMutex.acquire();

     bool        wasEmpty = false;
     SkMSec      now = GetMSecsSinceStartup();
     SkEvent*    evt = globals.fDelayQHead;

     while (evt)
     {
         if (SkMSec_LT(now, evt->fTime))
             break;

 #ifdef SK_TRACE_EVENTS
         --gDelayDepth;
         SkDebugf("dequeue-delay %s (%d)", evt->getType(), gDelayDepth);
         const char* idStr = evt->findString("id");
         if (idStr)
             SkDebugf(" (%s)", idStr);
         SkDebugf("\n");
 #endif

         SkEvent* next = evt->fNextEvent;
         if (SkEvent::Enqueue(evt))
             wasEmpty = true;
         evt = next;
     }
     globals.fDelayQHead = evt;

     SkMSec time = evt ? evt->fTime - now : 0;

     globals.fEventMutex.release();

     if (wasEmpty)
         SkEvent::SignalNonEmptyQueue();

     SkEvent::SignalQueueTimer(time);
 }

 int SkEvent::CountEventsOnQueue() {
     SkEvent_Globals& globals = getGlobals();
     globals.fEventMutex.acquire();

     int count = 0;
     const SkEvent* evt = globals.fEventQHead;
     while (evt) {
         count += 1;
         evt = evt->fNextEvent;
     }
     globals.fEventMutex.release();

     return count;
 }

 SkMSec SkEvent::GetMSecsSinceStartup() {
     static const double kEpoch = SkTime::GetMSecs();
     return static_cast<SkMSec>(SkTime::GetMSecs() - kEpoch);
 }

 ///////////////////////////////////////////////////////////////////////////////

 void SkEvent::Init() {}

 void SkEvent::Term() {
     SkEvent_Globals& globals = getGlobals();

     SkEvent* evt = globals.fEventQHead;
     while (evt) {
         SkEvent* next = evt->fNextEvent;
         delete evt;
         evt = next;
     }

     evt = globals.fDelayQHead;
     while (evt) {
         SkEvent* next = evt->fNextEvent;
         delete evt;
         evt = next;
     }
 }
	/*
	* Copyright 2006 The Android Open Source Project
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/


	#include "SkDOM.h"
	#include "SkEvent.h"

	void SkEvent::initialize(const char* type, size_t typeLen,
	SkEventSinkID targetID) {
	fType = nullptr;
	setType(type, typeLen);
	f32 = 0;
	fTargetID = targetID;
	fTargetProc = nullptr;
	#ifdef SK_DEBUG
	fTime = 0;
	fNextEvent = nullptr;
	#endif
	}

	SkEvent::SkEvent()
	{
	initialize("", 0, 0);
	}

	SkEvent::SkEvent(const SkEvent& src)
	{
	*this = src;
	if (((size_t) fType & 1) == 0)
	setType(src.fType);
	}

	SkEvent::SkEvent(const SkString& type, SkEventSinkID targetID)
	{
	initialize(type.c_str(), type.size(), targetID);
	}

	SkEvent::SkEvent(const char type[], SkEventSinkID targetID)
	{
	SkASSERT(type);
	initialize(type, strlen(type), targetID);
	}

	SkEvent::~SkEvent()
	{
	if (((size_t) fType & 1) == 0)
	sk_free((void*) fType);
	}

	static size_t makeCharArray(char* buffer, size_t compact)
	{
	size_t bits = (size_t) compact >> 1;
	memcpy(buffer, &bits, sizeof(compact));
	buffer[sizeof(compact)] = 0;
	return strlen(buffer);
	}

	void SkEvent::getType(SkString* str) const
	{
	if (str)
	{
	if ((size_t) fType & 1) // not a pointer
	{
	char chars[sizeof(size_t) + 1];
	size_t len = makeCharArray(chars, (size_t) fType);
	str->set(chars, len);
	}
	else
	str->set(fType);
	}
	}

	bool SkEvent::isType(const SkString& str) const
	{
	return this->isType(str.c_str(), str.size());
	}

	bool SkEvent::isType(const char type[], size_t typeLen) const
	{
	if (typeLen == 0)
	typeLen = strlen(type);
	if ((size_t) fType & 1) { // not a pointer
	char chars[sizeof(size_t) + 1];
	size_t len = makeCharArray(chars, (size_t) fType);
	return len == typeLen && strncmp(chars, type, typeLen) == 0;
	}
	return strncmp(fType, type, typeLen) == 0 && fType[typeLen] == 0;
	}

	void SkEvent::setType(const char type[], size_t typeLen)
	{
	if (typeLen == 0)
	typeLen = strlen(type);
	if (typeLen <= sizeof(fType)) {
	size_t slot = 0;
	memcpy(&slot, type, typeLen);
	if (slot << 1 >> 1 != slot)
	goto useCharStar;
	slot <<= 1;
	slot \|= 1;
	fType = (char*) slot;
	} else {
	useCharStar:
	fType = (char*) sk_malloc_throw(typeLen + 1);
	SkASSERT(((size_t) fType & 1) == 0);
	memcpy(fType, type, typeLen);
	fType[typeLen] = 0;
	}
	}

	void SkEvent::setType(const SkString& type)
	{
	setType(type.c_str());
	}

	////////////////////////////////////////////////////////////////////////////

	#include "SkParse.h"

	void SkEvent::inflate(const SkDOM& dom, const SkDOM::Node* node)
	{
	const char* name = dom.findAttr(node, "type");
	if (name)
	this->setType(name);

	const char* value;
	if ((value = dom.findAttr(node, "fast32")) != nullptr)
	{
	int32_t n;
	if (SkParse::FindS32(value, &n))
	this->setFast32(n);
	}

	for (node = dom.getFirstChild(node); node; node = dom.getNextSibling(node))
	{
	if (strcmp(dom.getName(node), "data"))
	{
	SkDEBUGCODE(SkDebugf("SkEvent::inflate unrecognized subelement <%s>\n", dom.getName(node));)
	continue;
	}

	name = dom.findAttr(node, "name");
	if (name == nullptr)
	{
	SkDEBUGCODE(SkDebugf("SkEvent::inflate missing required \"name\" attribute in <data> subelement\n");)
	continue;
	}

	if ((value = dom.findAttr(node, "s32")) != nullptr)
	{
	int32_t n;
	if (SkParse::FindS32(value, &n))
	this->setS32(name, n);
	}
	else if ((value = dom.findAttr(node, "scalar")) != nullptr)
	{
	SkScalar x;
	if (SkParse::FindScalar(value, &x))
	this->setScalar(name, x);
	}
	else if ((value = dom.findAttr(node, "string")) != nullptr)
	this->setString(name, value);
	#ifdef SK_DEBUG
	else
	{
	SkDebugf("SkEvent::inflate <data name=\"%s\"> subelement missing required type attribute [S32 \| scalar \| string]\n", name);
	}
	#endif
	}
	}

	#ifdef SK_DEBUG

	#ifndef SkScalarToFloat
	#define SkScalarToFloat(x) ((x) / 65536.f)
	#endif

	void SkEvent::dump(const char title[])
	{
	if (title)
	SkDebugf("%s ", title);

	SkString etype;
	this->getType(&etype);
	SkDebugf("event<%s> fast32=%d", etype.c_str(), this->getFast32());

	const SkMetaData& md = this->getMetaData();
	SkMetaData::Iter iter(md);
	SkMetaData::Type mtype;
	int count;
	const char* name;

	while ((name = iter.next(&mtype, &count)) != nullptr)
	{
	SkASSERT(count > 0);

	SkDebugf(" <%s>=", name);
	switch (mtype) {
	case SkMetaData::kS32_Type: // vector version???
	{
	int32_t value;
	md.findS32(name, &value);
	SkDebugf("%d ", value);
	}
	break;
	case SkMetaData::kScalar_Type:
	{
	const SkScalar* values = md.findScalars(name, &count, nullptr);
	SkDebugf("%f", SkScalarToFloat(values[0]));
	for (int i = 1; i < count; i++)
	SkDebugf(", %f", SkScalarToFloat(values[i]));
	SkDebugf(" ");
	}
	break;
	case SkMetaData::kString_Type:
	{
	const char* value = md.findString(name);
	SkASSERT(value);
	SkDebugf("<%s> ", value);
	}
	break;
	case SkMetaData::kPtr_Type: // vector version???
	{
	void* value;
	md.findPtr(name, &value);
	SkDebugf("%p ", value);
	}
	break;
	case SkMetaData::kBool_Type: // vector version???
	{
	bool value;
	md.findBool(name, &value);
	SkDebugf("%s ", value ? "true" : "false");
	}
	break;
	default:
	SkDEBUGFAIL("unknown metadata type returned from iterator");
	break;
	}
	}
	SkDebugf("\n");
	}
	#endif

	///////////////////////////////////////////////////////////////////////////////////////

	#ifdef SK_DEBUG
	// #define SK_TRACE_EVENTSx
	#endif

	#ifdef SK_TRACE_EVENTS
	static void event_log(const char s[])
	{
	SkDEBUGF(("%s\n", s));
	}

	#define EVENT_LOG(s) event_log(s)
	#define EVENT_LOGN(s, n) do { SkString str(s); str.append(" "); str.appendS32(n); event_log(str.c_str()); } while (0)
	#else
	#define EVENT_LOG(s)
	#define EVENT_LOGN(s, n)
	#endif

	#include "SkMutex.h"
	#include "SkTime.h"

	class SkEvent_Globals {
	public:
	SkEvent_Globals() {
	fEventQHead = nullptr;
	fEventQTail = nullptr;
	fDelayQHead = nullptr;
	SkDEBUGCODE(fEventCounter = 0;)
	}

	SkMutex fEventMutex;
	SkEvent* fEventQHead, *fEventQTail;
	SkEvent* fDelayQHead;
	SkDEBUGCODE(int fEventCounter;)
	};

	static SkEvent_Globals& getGlobals() {
	// leak this, so we don't incure any shutdown perf hit
	static SkEvent_Globals* gGlobals = new SkEvent_Globals;
	return *gGlobals;
	}

	///////////////////////////////////////////////////////////////////////////////

	void SkEvent::postDelay(SkMSec delay) {
	if (!fTargetID && !fTargetProc) {
	delete this;
	return;
	}

	if (delay) {
	this->postTime(GetMSecsSinceStartup() + delay);
	return;
	}

	SkEvent_Globals& globals = getGlobals();

	globals.fEventMutex.acquire();
	bool wasEmpty = SkEvent::Enqueue(this);
	globals.fEventMutex.release();

	// call outside of us holding the mutex
	if (wasEmpty) {
	SkEvent::SignalNonEmptyQueue();
	}
	}

	void SkEvent::postTime(SkMSec time) {
	if (!fTargetID && !fTargetProc) {
	delete this;
	return;
	}

	SkEvent_Globals& globals = getGlobals();

	globals.fEventMutex.acquire();
	SkMSec queueDelay = SkEvent::EnqueueTime(this, time);
	globals.fEventMutex.release();

	// call outside of us holding the mutex
	if ((int32_t)queueDelay != ~0) {
	SkEvent::SignalQueueTimer(queueDelay);
	}
	}

	bool SkEvent::Enqueue(SkEvent* evt) {
	SkEvent_Globals& globals = getGlobals();
	// gEventMutex acquired by caller

	SkASSERT(evt);

	bool wasEmpty = globals.fEventQHead == nullptr;

	if (globals.fEventQTail)
	globals.fEventQTail->fNextEvent = evt;
	globals.fEventQTail = evt;
	if (globals.fEventQHead == nullptr)
	globals.fEventQHead = evt;
	evt->fNextEvent = nullptr;

	SkDEBUGCODE(++globals.fEventCounter);

	return wasEmpty;
	}

	SkEvent* SkEvent::Dequeue() {
	SkEvent_Globals& globals = getGlobals();
	globals.fEventMutex.acquire();

	SkEvent* evt = globals.fEventQHead;
	if (evt) {
	SkDEBUGCODE(--globals.fEventCounter);

	globals.fEventQHead = evt->fNextEvent;
	if (globals.fEventQHead == nullptr) {
	globals.fEventQTail = nullptr;
	}
	}
	globals.fEventMutex.release();

	return evt;
	}

	bool SkEvent::QHasEvents() {
	SkEvent_Globals& globals = getGlobals();

	// this is not thread accurate, need a semaphore for that
	return globals.fEventQHead != nullptr;
	}

	#ifdef SK_TRACE_EVENTS
	static int gDelayDepth;
	#endif

	SkMSec SkEvent::EnqueueTime(SkEvent* evt, SkMSec time) {
	SkEvent_Globals& globals = getGlobals();
	// gEventMutex acquired by caller

	SkEvent* curr = globals.fDelayQHead;
	SkEvent* prev = nullptr;

	while (curr) {
	if (SkMSec_LT(time, curr->fTime)) {
	break;
	}
	prev = curr;
	curr = curr->fNextEvent;
	}

	evt->fTime = time;
	evt->fNextEvent = curr;
	if (prev == nullptr) {
	globals.fDelayQHead = evt;
	} else {
	prev->fNextEvent = evt;
	}

	SkMSec delay = globals.fDelayQHead->fTime - GetMSecsSinceStartup();
	if ((int32_t)delay <= 0) {
	delay = 1;
	}
	return delay;
	}

	///////////////////////////////////////////////////////////////////////////////

	#include "SkEventSink.h"

	bool SkEvent::ProcessEvent() {
	std::unique_ptr<SkEvent> evt(SkEvent::Dequeue());
	bool again = false;

	EVENT_LOGN("ProcessEvent", (int32_t)evt);

	if (evt) {
	(void)SkEventSink::DoEvent(*evt);
	again = SkEvent::QHasEvents();
	}
	return again;
	}

	void SkEvent::ServiceQueueTimer()
	{
	SkEvent_Globals& globals = getGlobals();

	globals.fEventMutex.acquire();

	bool wasEmpty = false;
	SkMSec now = GetMSecsSinceStartup();
	SkEvent* evt = globals.fDelayQHead;

	while (evt)
	{
	if (SkMSec_LT(now, evt->fTime))
	break;

	#ifdef SK_TRACE_EVENTS
	--gDelayDepth;
	SkDebugf("dequeue-delay %s (%d)", evt->getType(), gDelayDepth);
	const char* idStr = evt->findString("id");
	if (idStr)
	SkDebugf(" (%s)", idStr);
	SkDebugf("\n");
	#endif

	SkEvent* next = evt->fNextEvent;
	if (SkEvent::Enqueue(evt))
	wasEmpty = true;
	evt = next;
	}
	globals.fDelayQHead = evt;

	SkMSec time = evt ? evt->fTime - now : 0;

	globals.fEventMutex.release();

	if (wasEmpty)
	SkEvent::SignalNonEmptyQueue();

	SkEvent::SignalQueueTimer(time);
	}

	int SkEvent::CountEventsOnQueue() {
	SkEvent_Globals& globals = getGlobals();
	globals.fEventMutex.acquire();

	int count = 0;
	const SkEvent* evt = globals.fEventQHead;
	while (evt) {
	count += 1;
	evt = evt->fNextEvent;
	}
	globals.fEventMutex.release();

	return count;
	}

	SkMSec SkEvent::GetMSecsSinceStartup() {
	static const double kEpoch = SkTime::GetMSecs();
	return static_cast<SkMSec>(SkTime::GetMSecs() - kEpoch);
	}

	///////////////////////////////////////////////////////////////////////////////

	void SkEvent::Init() {}

	void SkEvent::Term() {
	SkEvent_Globals& globals = getGlobals();

	SkEvent* evt = globals.fEventQHead;
	while (evt) {
	SkEvent* next = evt->fNextEvent;
	delete evt;
	evt = next;
	}

	evt = globals.fDelayQHead;
	while (evt) {
	SkEvent* next = evt->fNextEvent;
	delete evt;
	evt = next;
	}
	}