retrace/metric_backend_opengl.cpp - chromium.googlesource.com/chromiumos/third_party/apitrace - Gitiles

 /**************************************************************************
  *
  * Copyright 2015 Alexander Trukhin
  * All Rights Reserved.
  *
  * Permission is hereby granted, free of charge, to any person obtaining a copy
  * of this software and associated documentation files (the "Software"), to deal
  * in the Software without restriction, including without limitation the rights
  * to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
  * copies of the Software, and to permit persons to whom the Software is
  * furnished to do so, subject to the following conditions:
  *
  * The above copyright notice and this permission notice shall be included in
  * all copies or substantial portions of the Software.
  *
  * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
  * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
  * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
  * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
  * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
  * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
  * THE SOFTWARE.
  *
  **************************************************************************/

 #include "metric_backend_opengl.hpp"
 #include "os_time.hpp"
 #include "os_memory.hpp"

 void
 MetricBackend_opengl::Storage::addData(QueryBoundary boundary, int64_t data) {
     this->data[boundary].push_back(data);
 }

 int64_t* MetricBackend_opengl::Storage::getData(QueryBoundary boundary,
                                                  unsigned eventId)
 {
     return &(data[boundary][eventId]);
 }

 Metric_opengl::Metric_opengl(unsigned gId, unsigned id, const std::string &name,
                              const std::string &desc, MetricNumType nT, MetricType t)
     : m_gId(gId), m_id(id), m_name(name), m_desc(desc), m_nType(nT),
       m_type(t), available(false)
 {
     for (int i = 0; i < QUERY_BOUNDARY_LIST_END; i++) {
         profiled[i] = false;
         enabled[i] = false;
     }
 }

 unsigned Metric_opengl::id() {
     return m_id;
 }

 unsigned Metric_opengl::groupId() {
     return m_gId;
 }

 std::string Metric_opengl::name() {
     return m_name;
 }

 std::string Metric_opengl::description() {
     return m_desc;
 }

 MetricNumType Metric_opengl::numType() {
     return m_nType;
 }

 MetricType Metric_opengl::type() {
     return m_type;
 }

 MetricBackend_opengl::MetricBackend_opengl(glretrace::Context* context,
                                            MmapAllocator<char> &alloc)
     : alloc(alloc)
 {
     glfeatures::Profile currentProfile = context->actualProfile();
     supportsTimestamp   = currentProfile.versionGreaterOrEqual(glfeatures::API_GL, 3, 3) ||
                           context->hasExtension("GL_ARB_timer_query");
     supportsElapsed     = context->hasExtension("GL_EXT_timer_query") || supportsTimestamp;
     supportsOcclusion   = currentProfile.versionGreaterOrEqual(glfeatures::API_GL, 1, 5);

     #ifdef __APPLE__
         // GL_TIMESTAMP doesn't work on Apple.  GL_TIME_ELAPSED still does however.
         // http://lists.apple.com/archives/mac-opengl/2014/Nov/threads.html#00001
         supportsTimestamp   = false;
     #endif

     // Add metrics below
     metrics.emplace_back(0, 0, "CPU Start", "", CNT_NUM_INT64, CNT_TYPE_TIMESTAMP);
     metrics.emplace_back(0, 1, "CPU Duration", "", CNT_NUM_INT64, CNT_TYPE_DURATION);
     metrics.emplace_back(1, 0, "GPU Start", "", CNT_NUM_INT64, CNT_TYPE_TIMESTAMP);
     metrics.emplace_back(1, 1, "GPU Duration", "", CNT_NUM_INT64, CNT_TYPE_DURATION);
     metrics.emplace_back(1, 2, "Pixels Drawn", "", CNT_NUM_INT64, CNT_TYPE_GENERIC);
     metrics.emplace_back(0, 2, "VSIZE Start", "", CNT_NUM_INT64, CNT_TYPE_GENERIC);
     metrics.emplace_back(0, 3, "VSIZE Duration", "", CNT_NUM_INT64, CNT_TYPE_GENERIC);
     metrics.emplace_back(0, 4, "RSS Start", "", CNT_NUM_INT64, CNT_TYPE_GENERIC);
     metrics.emplace_back(0, 5, "RSS Duration", "", CNT_NUM_INT64, CNT_TYPE_GENERIC);

     metrics[METRIC_CPU_START].available = true;
     metrics[METRIC_CPU_DURATION].available = true;
     metrics[METRIC_CPU_VSIZE_START].available = true;
     metrics[METRIC_CPU_VSIZE_DURATION].available = true;
     metrics[METRIC_CPU_RSS_START].available = true;
     metrics[METRIC_CPU_RSS_DURATION].available = true;
     if (supportsTimestamp) metrics[METRIC_GPU_START].available = true;
     if (supportsElapsed) {
         GLint bits = 0;
         glGetQueryiv(GL_TIME_ELAPSED, GL_QUERY_COUNTER_BITS, &bits);
         if (bits) metrics[METRIC_GPU_DURATION].available = true;
     }
     if (supportsOcclusion) {
         metrics[METRIC_GPU_PIXELS].available = true;
     }

     // populate lookups
     for (auto &m : metrics) {
         idLookup[std::make_pair(m.groupId(), m.id())] = &m;
         nameLookup[m.name()] = &m;
     }
 }

 int64_t MetricBackend_opengl::getCurrentTime(void) {
     if (supportsTimestamp && cpugpuSync) {
         /* Get the current GL time without stalling */
         GLint64 timestamp = 0;
         glGetInteger64v(GL_TIMESTAMP, &timestamp);
         return timestamp;
     } else {
         return os::getTime();
     }
 }

 int64_t MetricBackend_opengl::getTimeFrequency(void) {
     if (supportsTimestamp && cpugpuSync) {
         return 1000000000;
     } else {
         return os::timeFrequency;
     }
 }


 bool MetricBackend_opengl::isSupported() {
     return true;
     // though individual metrics might be not supported
 }

 void MetricBackend_opengl::enumGroups(enumGroupsCallback callback, void* userData) {
     callback(0, 0, userData); // cpu group
     callback(1, 0, userData); // gpu group
 }

 std::string MetricBackend_opengl::getGroupName(unsigned group) {
     switch(group) {
         case 0:
             return "CPU";
         case 1:
             return "GPU";
         default:
             return "";
     }
 }

 void MetricBackend_opengl::enumMetrics(unsigned group, enumMetricsCallback callback, void* userData) {
     for (auto &m : metrics) {
         if (m.groupId() == group && m.available) {
             callback(&m, 0, userData);
         }
     }
 }

 std::unique_ptr<Metric>
 MetricBackend_opengl::getMetricById(unsigned groupId, unsigned metricId) {
     auto entryToCopy = idLookup.find(std::make_pair(groupId, metricId));
     if (entryToCopy != idLookup.end()) {
         return std::unique_ptr<Metric>(new Metric_opengl(*entryToCopy->second));
     } else {
         return nullptr;
     }
 }

 std::unique_ptr<Metric>
 MetricBackend_opengl::getMetricByName(std::string metricName) {
     auto entryToCopy = nameLookup.find(metricName);
     if (entryToCopy != nameLookup.end()) {
         return std::unique_ptr<Metric>(new Metric_opengl(*entryToCopy->second));
     } else {
         return nullptr;
     }
 }


 int MetricBackend_opengl::enableMetric(Metric* metric, QueryBoundary pollingRule) {
     // metric is not necessarily the same object as in metrics[]
     auto entry = idLookup.find(std::make_pair(metric->groupId(), metric->id()));
     if ((entry != idLookup.end()) && entry->second->available) {
         entry->second->enabled[pollingRule] = true;
         return 0;
     }
     return 1;
 }

 unsigned MetricBackend_opengl::generatePasses() {
     // draw calls profiling not needed if all calls are profiled
     for (int i = 0; i < METRIC_LIST_END; i++) {
         if (metrics[i].enabled[QUERY_BOUNDARY_CALL]) {
             metrics[i].enabled[QUERY_BOUNDARY_DRAWCALL] = false;
         }
     }
     // setup storage for profiled metrics
     for (int i = 0; i < METRIC_LIST_END; i++) {
         for (int j = 0; j < QUERY_BOUNDARY_LIST_END; j++) {
             if (metrics[i].enabled[j]) {
                 data[i][j] = std::unique_ptr<Storage>(new Storage(alloc));
             }
         }
     }
     // check if GL queries are needed
     glQueriesNeededAnyBoundary = false;
     for (int i = 0; i < QUERY_BOUNDARY_LIST_END; i++) {
         if (metrics[METRIC_GPU_START].enabled[i] ||
             metrics[METRIC_GPU_DURATION].enabled[i] ||
             metrics[METRIC_GPU_PIXELS].enabled[i])
         {
             glQueriesNeeded[i] = true;
             glQueriesNeededAnyBoundary = true;
         } else {
             glQueriesNeeded[i] = false;
         }
     }
     // check if CPU <-> GPU sync is required
     // this is the case if any gpu time is requested
     cpugpuSync = false;
     for (int i = 0; i < QUERY_BOUNDARY_LIST_END; i++) {
         if (metrics[METRIC_GPU_START].enabled[i] ||
             metrics[METRIC_GPU_DURATION].enabled[i])
         {
             cpugpuSync = true;
             break;
         }
     }
     // check if two passes are needed
     // GL_TIME_ELAPSED (gpu dur) and GL_SAMPLES_PASSED (pixels) cannot be nested
     if (!supportsTimestamp &&
         metrics[METRIC_GPU_DURATION].enabled[QUERY_BOUNDARY_FRAME] &&
        (metrics[METRIC_GPU_DURATION].enabled[QUERY_BOUNDARY_CALL] ||
         metrics[METRIC_GPU_DURATION].enabled[QUERY_BOUNDARY_DRAWCALL]))
     {
         twoPasses = true;
     }
     if (metrics[METRIC_GPU_PIXELS].enabled[QUERY_BOUNDARY_FRAME] &&
        (metrics[METRIC_GPU_PIXELS].enabled[QUERY_BOUNDARY_CALL] ||
         metrics[METRIC_GPU_PIXELS].enabled[QUERY_BOUNDARY_DRAWCALL]))
     {
         twoPasses = true;
     }

     curPass = 1;
     return twoPasses ? 2 : 1;
 }

 void MetricBackend_opengl::beginPass() {
     if (curPass == 1) {
         for (int i = 0; i < QUERY_BOUNDARY_LIST_END; i++) {
             for (auto &m : metrics) {
                 if (m.enabled[i]) m.profiled[i] = true;
             }
         }
         // profile frames in first pass
         if (twoPasses) {
             if (!supportsTimestamp) {
                 metrics[METRIC_GPU_DURATION].profiled[QUERY_BOUNDARY_DRAWCALL] = false;
                 metrics[METRIC_GPU_DURATION].profiled[QUERY_BOUNDARY_CALL] = false;
             }
             metrics[METRIC_GPU_PIXELS].profiled[QUERY_BOUNDARY_DRAWCALL] = false;
             metrics[METRIC_GPU_PIXELS].profiled[QUERY_BOUNDARY_CALL] = false;
         }
     }
     else if (curPass == 2) {
         for (int i = 0; i < QUERY_BOUNDARY_LIST_END; i++) {
             for (auto &m : metrics) {
                 m.profiled[i] = false;
             }
         }
         // profile calls/draw calls in second pass
         if (!supportsTimestamp) {
             if (metrics[METRIC_GPU_DURATION].enabled[QUERY_BOUNDARY_DRAWCALL]) {
                 metrics[METRIC_GPU_DURATION].profiled[QUERY_BOUNDARY_DRAWCALL] = true;
             }
             if (metrics[METRIC_GPU_DURATION].enabled[QUERY_BOUNDARY_CALL]) {
                 metrics[METRIC_GPU_DURATION].profiled[QUERY_BOUNDARY_CALL] = true;
             }
         }
         if (metrics[METRIC_GPU_PIXELS].enabled[QUERY_BOUNDARY_DRAWCALL]) {
             metrics[METRIC_GPU_PIXELS].profiled[QUERY_BOUNDARY_DRAWCALL] = true;
         }
         if (metrics[METRIC_GPU_PIXELS].enabled[QUERY_BOUNDARY_CALL]) {
             metrics[METRIC_GPU_PIXELS].profiled[QUERY_BOUNDARY_CALL] = true;
         }
     }
     // setup times
     cpuTimeScale = 1.0E9 / getTimeFrequency();
     baseTime = getCurrentTime() * cpuTimeScale;
 }

 void MetricBackend_opengl::processQueries() {
     int64_t gpuStart, gpuEnd, pixels;
     for (int i = 0; i < QUERY_BOUNDARY_LIST_END; i++) {
         QueryBoundary boundary = static_cast<QueryBoundary>(i);
         while (!queries[i].empty()) {
             auto &query = queries[i].front();
             if (metrics[METRIC_GPU_START].profiled[i]) {
                 glGetQueryObjecti64v(query[QUERY_GPU_START], GL_QUERY_RESULT,
                                      &gpuStart);
                 int64_t value = gpuStart - baseTime;
                 data[METRIC_GPU_START][i]->addData(boundary, value);
             }
             if (metrics[METRIC_GPU_DURATION].profiled[i]) {
                 if (supportsTimestamp) {
                     glGetQueryObjecti64v(query[QUERY_GPU_DURATION], GL_QUERY_RESULT,
                                          &gpuEnd);
                     gpuEnd -= gpuStart;
                 } else {
                     glGetQueryObjecti64vEXT(query[QUERY_GPU_DURATION], GL_QUERY_RESULT,
                                             &gpuEnd);
                 }
                 data[METRIC_GPU_DURATION][i]->addData(boundary, gpuEnd);
             }
             if (metrics[METRIC_GPU_PIXELS].profiled[i]) {
                 if (supportsTimestamp) {
                     glGetQueryObjecti64v(query[QUERY_OCCLUSION], GL_QUERY_RESULT, &pixels);
                 } else if (supportsElapsed) {
                     glGetQueryObjecti64vEXT(query[QUERY_OCCLUSION], GL_QUERY_RESULT, &pixels);
                 } else {
                     uint32_t pixels32;
                     glGetQueryObjectuiv(query[QUERY_OCCLUSION], GL_QUERY_RESULT, &pixels32);
                     pixels = static_cast<int64_t>(pixels32);
                 }
                 data[METRIC_GPU_PIXELS][i]->addData(boundary, pixels);
             }
             glDeleteQueries(QUERY_LIST_END, query.data());
             queries[i].pop();
         }
     }
 }

 void MetricBackend_opengl::endPass() {
     // process rest of the queries (it can be the last frame)
     processQueries();
     curPass++;
 }

 void MetricBackend_opengl::pausePass() {
     if (queryInProgress[QUERY_BOUNDARY_FRAME]) endQuery(QUERY_BOUNDARY_FRAME);
     processQueries();
 }

 void MetricBackend_opengl::continuePass() {
     // TODO if context switches check what it actually supports
 }

 void MetricBackend_opengl::beginQuery(QueryBoundary boundary) {
     // GPU related
     if (glQueriesNeeded[boundary]) {
         std::array<GLuint, QUERY_LIST_END> query;
         glGenQueries(QUERY_LIST_END, query.data());

         if (metrics[METRIC_GPU_START].profiled[boundary] ||
            (metrics[METRIC_GPU_DURATION].profiled[boundary] && supportsTimestamp))
         {
             glQueryCounter(query[QUERY_GPU_START], GL_TIMESTAMP);
         }
         if (metrics[METRIC_GPU_DURATION].profiled[boundary] && !supportsTimestamp) {
             glBeginQuery(GL_TIME_ELAPSED, query[QUERY_GPU_DURATION]);
         }
         if (metrics[METRIC_GPU_PIXELS].profiled[boundary]) {
             glBeginQuery(GL_SAMPLES_PASSED, query[QUERY_OCCLUSION]);
         }
         queries[boundary].push(std::move(query));
     }


     // CPU related
     if (metrics[METRIC_CPU_START].profiled[boundary] ||
         metrics[METRIC_CPU_DURATION].profiled[boundary])
     {
         cpuStart[boundary] = getCurrentTime();
         if (metrics[METRIC_CPU_START].profiled[boundary]) {
             int64_t time = cpuStart[boundary] * cpuTimeScale - baseTime;
             data[METRIC_CPU_START][boundary]->addData(boundary, time);
         }
     }
     if (metrics[METRIC_CPU_VSIZE_START].profiled[boundary] ||
         metrics[METRIC_CPU_VSIZE_DURATION].profiled[boundary])
     {
         vsizeStart[boundary] = os::getVsize();
         if (metrics[METRIC_CPU_VSIZE_START].profiled[boundary]) {
             int64_t time = vsizeStart[boundary];
             data[METRIC_CPU_VSIZE_START][boundary]->addData(boundary, time);
         }
     }
     if (metrics[METRIC_CPU_RSS_START].profiled[boundary] ||
         metrics[METRIC_CPU_RSS_DURATION].profiled[boundary])
     {
         rssStart[boundary] = os::getRss();
         if (metrics[METRIC_CPU_RSS_START].profiled[boundary]) {
             int64_t time = rssStart[boundary];
             data[METRIC_CPU_RSS_START][boundary]->addData(boundary, time);
         }
     }
     queryInProgress[boundary] = true;
     // DRAWCALL is a CALL
     if (boundary == QUERY_BOUNDARY_DRAWCALL) beginQuery(QUERY_BOUNDARY_CALL);
 }

 void MetricBackend_opengl::endQuery(QueryBoundary boundary) {
     if (queryInProgress[boundary]) {
         // CPU related
         if (metrics[METRIC_CPU_DURATION].profiled[boundary])
         {
             cpuEnd[boundary] = getCurrentTime();
             int64_t time = (cpuEnd[boundary] - cpuStart[boundary]) * cpuTimeScale;
             data[METRIC_CPU_DURATION][boundary]->addData(boundary, time);
         }
         if (metrics[METRIC_CPU_VSIZE_DURATION].profiled[boundary])
         {
             vsizeEnd[boundary] = os::getVsize();
             int64_t time = vsizeEnd[boundary] - vsizeStart[boundary];
             data[METRIC_CPU_VSIZE_DURATION][boundary]->addData(boundary, time);
         }
         if (metrics[METRIC_CPU_RSS_DURATION].profiled[boundary])
         {
             rssEnd[boundary] = os::getRss();
             int64_t time = rssEnd[boundary] - rssStart[boundary];
             data[METRIC_CPU_RSS_DURATION][boundary]->addData(boundary, time);
         }
         // GPU related
         if (glQueriesNeeded[boundary]) {
             std::array<GLuint, QUERY_LIST_END> &query = queries[boundary].back();
             if (metrics[METRIC_GPU_DURATION].profiled[boundary] && supportsTimestamp) {
                 // GL_TIME_ELAPSED cannot be used in nested queries
                 // so prefer this if timestamps are supported
                 glQueryCounter(query[QUERY_GPU_DURATION], GL_TIMESTAMP);
             }
             if (metrics[METRIC_GPU_PIXELS].profiled[boundary]) {
                 glEndQuery(GL_SAMPLES_PASSED);
             }
         }
         queryInProgress[boundary] = false;
     }
     // DRAWCALL is a CALL
     if (boundary == QUERY_BOUNDARY_DRAWCALL) endQuery(QUERY_BOUNDARY_CALL);
     // clear queries after each frame
     if (boundary == QUERY_BOUNDARY_FRAME && glQueriesNeededAnyBoundary) {
         processQueries();
     }
 }

 void MetricBackend_opengl::enumDataQueryId(unsigned id, enumDataCallback callback,
                                            QueryBoundary boundary, void* userData) {
     for (int i = 0; i < METRIC_LIST_END; i++) {
         Metric_opengl &metric = metrics[i];
         if (metric.enabled[boundary]) {
             callback(&metric, id, data[i][boundary]->getData(boundary, id), 0,
                      userData);
         }
     }
 }

 unsigned MetricBackend_opengl::getNumPasses() {
     return twoPasses ? 2 : 1;
 }

 MetricBackend_opengl&
 MetricBackend_opengl::getInstance(glretrace::Context* context, MmapAllocator<char> &alloc) {
     static MetricBackend_opengl backend(context, alloc);
     return backend;
 }
	/**************************************************************************
	*
	* Copyright 2015 Alexander Trukhin
	* All Rights Reserved.
	*
	* Permission is hereby granted, free of charge, to any person obtaining a copy
	* of this software and associated documentation files (the "Software"), to deal
	* in the Software without restriction, including without limitation the rights
	* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
	* copies of the Software, and to permit persons to whom the Software is
	* furnished to do so, subject to the following conditions:
	*
	* The above copyright notice and this permission notice shall be included in
	* all copies or substantial portions of the Software.
	*
	* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
	* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
	* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
	* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
	* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
	* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
	* THE SOFTWARE.
	*
	**************************************************************************/

	#include "metric_backend_opengl.hpp"
	#include "os_time.hpp"
	#include "os_memory.hpp"

	void
	MetricBackend_opengl::Storage::addData(QueryBoundary boundary, int64_t data) {
	this->data[boundary].push_back(data);
	}

	int64_t* MetricBackend_opengl::Storage::getData(QueryBoundary boundary,
	unsigned eventId)
	{
	return &(data[boundary][eventId]);
	}

	Metric_opengl::Metric_opengl(unsigned gId, unsigned id, const std::string &name,
	const std::string &desc, MetricNumType nT, MetricType t)
	: m_gId(gId), m_id(id), m_name(name), m_desc(desc), m_nType(nT),
	m_type(t), available(false)
	{
	for (int i = 0; i < QUERY_BOUNDARY_LIST_END; i++) {
	profiled[i] = false;
	enabled[i] = false;
	}
	}

	unsigned Metric_opengl::id() {
	return m_id;
	}

	unsigned Metric_opengl::groupId() {
	return m_gId;
	}

	std::string Metric_opengl::name() {
	return m_name;
	}

	std::string Metric_opengl::description() {
	return m_desc;
	}

	MetricNumType Metric_opengl::numType() {
	return m_nType;
	}

	MetricType Metric_opengl::type() {
	return m_type;
	}

	MetricBackend_opengl::MetricBackend_opengl(glretrace::Context* context,
	MmapAllocator<char> &alloc)
	: alloc(alloc)
	{
	glfeatures::Profile currentProfile = context->actualProfile();
	supportsTimestamp = currentProfile.versionGreaterOrEqual(glfeatures::API_GL, 3, 3) \|\|
	context->hasExtension("GL_ARB_timer_query");
	supportsElapsed = context->hasExtension("GL_EXT_timer_query") \|\| supportsTimestamp;
	supportsOcclusion = currentProfile.versionGreaterOrEqual(glfeatures::API_GL, 1, 5);

	#ifdef __APPLE__
	// GL_TIMESTAMP doesn't work on Apple. GL_TIME_ELAPSED still does however.
	// http://lists.apple.com/archives/mac-opengl/2014/Nov/threads.html#00001
	supportsTimestamp = false;
	#endif

	// Add metrics below
	metrics.emplace_back(0, 0, "CPU Start", "", CNT_NUM_INT64, CNT_TYPE_TIMESTAMP);
	metrics.emplace_back(0, 1, "CPU Duration", "", CNT_NUM_INT64, CNT_TYPE_DURATION);
	metrics.emplace_back(1, 0, "GPU Start", "", CNT_NUM_INT64, CNT_TYPE_TIMESTAMP);
	metrics.emplace_back(1, 1, "GPU Duration", "", CNT_NUM_INT64, CNT_TYPE_DURATION);
	metrics.emplace_back(1, 2, "Pixels Drawn", "", CNT_NUM_INT64, CNT_TYPE_GENERIC);
	metrics.emplace_back(0, 2, "VSIZE Start", "", CNT_NUM_INT64, CNT_TYPE_GENERIC);
	metrics.emplace_back(0, 3, "VSIZE Duration", "", CNT_NUM_INT64, CNT_TYPE_GENERIC);
	metrics.emplace_back(0, 4, "RSS Start", "", CNT_NUM_INT64, CNT_TYPE_GENERIC);
	metrics.emplace_back(0, 5, "RSS Duration", "", CNT_NUM_INT64, CNT_TYPE_GENERIC);

	metrics[METRIC_CPU_START].available = true;
	metrics[METRIC_CPU_DURATION].available = true;
	metrics[METRIC_CPU_VSIZE_START].available = true;
	metrics[METRIC_CPU_VSIZE_DURATION].available = true;
	metrics[METRIC_CPU_RSS_START].available = true;
	metrics[METRIC_CPU_RSS_DURATION].available = true;
	if (supportsTimestamp) metrics[METRIC_GPU_START].available = true;
	if (supportsElapsed) {
	GLint bits = 0;
	glGetQueryiv(GL_TIME_ELAPSED, GL_QUERY_COUNTER_BITS, &bits);
	if (bits) metrics[METRIC_GPU_DURATION].available = true;
	}
	if (supportsOcclusion) {
	metrics[METRIC_GPU_PIXELS].available = true;
	}

	// populate lookups
	for (auto &m : metrics) {
	idLookup[std::make_pair(m.groupId(), m.id())] = &m;
	nameLookup[m.name()] = &m;
	}
	}

	int64_t MetricBackend_opengl::getCurrentTime(void) {
	if (supportsTimestamp && cpugpuSync) {
	/* Get the current GL time without stalling */
	GLint64 timestamp = 0;
	glGetInteger64v(GL_TIMESTAMP, &timestamp);
	return timestamp;
	} else {
	return os::getTime();
	}
	}

	int64_t MetricBackend_opengl::getTimeFrequency(void) {
	if (supportsTimestamp && cpugpuSync) {
	return 1000000000;
	} else {
	return os::timeFrequency;
	}
	}


	bool MetricBackend_opengl::isSupported() {
	return true;
	// though individual metrics might be not supported
	}

	void MetricBackend_opengl::enumGroups(enumGroupsCallback callback, void* userData) {
	callback(0, 0, userData); // cpu group
	callback(1, 0, userData); // gpu group
	}

	std::string MetricBackend_opengl::getGroupName(unsigned group) {
	switch(group) {
	case 0:
	return "CPU";
	case 1:
	return "GPU";
	default:
	return "";
	}
	}

	void MetricBackend_opengl::enumMetrics(unsigned group, enumMetricsCallback callback, void* userData) {
	for (auto &m : metrics) {
	if (m.groupId() == group && m.available) {
	callback(&m, 0, userData);
	}
	}
	}

	std::unique_ptr<Metric>
	MetricBackend_opengl::getMetricById(unsigned groupId, unsigned metricId) {
	auto entryToCopy = idLookup.find(std::make_pair(groupId, metricId));
	if (entryToCopy != idLookup.end()) {
	return std::unique_ptr<Metric>(new Metric_opengl(*entryToCopy->second));
	} else {
	return nullptr;
	}
	}

	std::unique_ptr<Metric>
	MetricBackend_opengl::getMetricByName(std::string metricName) {
	auto entryToCopy = nameLookup.find(metricName);
	if (entryToCopy != nameLookup.end()) {
	return std::unique_ptr<Metric>(new Metric_opengl(*entryToCopy->second));
	} else {
	return nullptr;
	}
	}


	int MetricBackend_opengl::enableMetric(Metric* metric, QueryBoundary pollingRule) {
	// metric is not necessarily the same object as in metrics[]
	auto entry = idLookup.find(std::make_pair(metric->groupId(), metric->id()));
	if ((entry != idLookup.end()) && entry->second->available) {
	entry->second->enabled[pollingRule] = true;
	return 0;
	}
	return 1;
	}

	unsigned MetricBackend_opengl::generatePasses() {
	// draw calls profiling not needed if all calls are profiled
	for (int i = 0; i < METRIC_LIST_END; i++) {
	if (metrics[i].enabled[QUERY_BOUNDARY_CALL]) {
	metrics[i].enabled[QUERY_BOUNDARY_DRAWCALL] = false;
	}
	}
	// setup storage for profiled metrics
	for (int i = 0; i < METRIC_LIST_END; i++) {
	for (int j = 0; j < QUERY_BOUNDARY_LIST_END; j++) {
	if (metrics[i].enabled[j]) {
	data[i][j] = std::unique_ptr<Storage>(new Storage(alloc));
	}
	}
	}
	// check if GL queries are needed
	glQueriesNeededAnyBoundary = false;
	for (int i = 0; i < QUERY_BOUNDARY_LIST_END; i++) {
	if (metrics[METRIC_GPU_START].enabled[i] \|\|
	metrics[METRIC_GPU_DURATION].enabled[i] \|\|
	metrics[METRIC_GPU_PIXELS].enabled[i])
	{
	glQueriesNeeded[i] = true;
	glQueriesNeededAnyBoundary = true;
	} else {
	glQueriesNeeded[i] = false;
	}
	}
	// check if CPU <-> GPU sync is required
	// this is the case if any gpu time is requested
	cpugpuSync = false;
	for (int i = 0; i < QUERY_BOUNDARY_LIST_END; i++) {
	if (metrics[METRIC_GPU_START].enabled[i] \|\|
	metrics[METRIC_GPU_DURATION].enabled[i])
	{
	cpugpuSync = true;
	break;
	}
	}
	// check if two passes are needed
	// GL_TIME_ELAPSED (gpu dur) and GL_SAMPLES_PASSED (pixels) cannot be nested
	if (!supportsTimestamp &&
	metrics[METRIC_GPU_DURATION].enabled[QUERY_BOUNDARY_FRAME] &&
	(metrics[METRIC_GPU_DURATION].enabled[QUERY_BOUNDARY_CALL] \|\|
	metrics[METRIC_GPU_DURATION].enabled[QUERY_BOUNDARY_DRAWCALL]))
	{
	twoPasses = true;
	}
	if (metrics[METRIC_GPU_PIXELS].enabled[QUERY_BOUNDARY_FRAME] &&
	(metrics[METRIC_GPU_PIXELS].enabled[QUERY_BOUNDARY_CALL] \|\|
	metrics[METRIC_GPU_PIXELS].enabled[QUERY_BOUNDARY_DRAWCALL]))
	{
	twoPasses = true;
	}

	curPass = 1;
	return twoPasses ? 2 : 1;
	}

	void MetricBackend_opengl::beginPass() {
	if (curPass == 1) {
	for (int i = 0; i < QUERY_BOUNDARY_LIST_END; i++) {
	for (auto &m : metrics) {
	if (m.enabled[i]) m.profiled[i] = true;
	}
	}
	// profile frames in first pass
	if (twoPasses) {
	if (!supportsTimestamp) {
	metrics[METRIC_GPU_DURATION].profiled[QUERY_BOUNDARY_DRAWCALL] = false;
	metrics[METRIC_GPU_DURATION].profiled[QUERY_BOUNDARY_CALL] = false;
	}
	metrics[METRIC_GPU_PIXELS].profiled[QUERY_BOUNDARY_DRAWCALL] = false;
	metrics[METRIC_GPU_PIXELS].profiled[QUERY_BOUNDARY_CALL] = false;
	}
	}
	else if (curPass == 2) {
	for (int i = 0; i < QUERY_BOUNDARY_LIST_END; i++) {
	for (auto &m : metrics) {
	m.profiled[i] = false;
	}
	}
	// profile calls/draw calls in second pass
	if (!supportsTimestamp) {
	if (metrics[METRIC_GPU_DURATION].enabled[QUERY_BOUNDARY_DRAWCALL]) {
	metrics[METRIC_GPU_DURATION].profiled[QUERY_BOUNDARY_DRAWCALL] = true;
	}
	if (metrics[METRIC_GPU_DURATION].enabled[QUERY_BOUNDARY_CALL]) {
	metrics[METRIC_GPU_DURATION].profiled[QUERY_BOUNDARY_CALL] = true;
	}
	}
	if (metrics[METRIC_GPU_PIXELS].enabled[QUERY_BOUNDARY_DRAWCALL]) {
	metrics[METRIC_GPU_PIXELS].profiled[QUERY_BOUNDARY_DRAWCALL] = true;
	}
	if (metrics[METRIC_GPU_PIXELS].enabled[QUERY_BOUNDARY_CALL]) {
	metrics[METRIC_GPU_PIXELS].profiled[QUERY_BOUNDARY_CALL] = true;
	}
	}
	// setup times
	cpuTimeScale = 1.0E9 / getTimeFrequency();
	baseTime = getCurrentTime() * cpuTimeScale;
	}

	void MetricBackend_opengl::processQueries() {
	int64_t gpuStart, gpuEnd, pixels;
	for (int i = 0; i < QUERY_BOUNDARY_LIST_END; i++) {
	QueryBoundary boundary = static_cast<QueryBoundary>(i);
	while (!queries[i].empty()) {
	auto &query = queries[i].front();
	if (metrics[METRIC_GPU_START].profiled[i]) {
	glGetQueryObjecti64v(query[QUERY_GPU_START], GL_QUERY_RESULT,
	&gpuStart);
	int64_t value = gpuStart - baseTime;
	data[METRIC_GPU_START][i]->addData(boundary, value);
	}
	if (metrics[METRIC_GPU_DURATION].profiled[i]) {
	if (supportsTimestamp) {
	glGetQueryObjecti64v(query[QUERY_GPU_DURATION], GL_QUERY_RESULT,
	&gpuEnd);
	gpuEnd -= gpuStart;
	} else {
	glGetQueryObjecti64vEXT(query[QUERY_GPU_DURATION], GL_QUERY_RESULT,
	&gpuEnd);
	}
	data[METRIC_GPU_DURATION][i]->addData(boundary, gpuEnd);
	}
	if (metrics[METRIC_GPU_PIXELS].profiled[i]) {
	if (supportsTimestamp) {
	glGetQueryObjecti64v(query[QUERY_OCCLUSION], GL_QUERY_RESULT, &pixels);
	} else if (supportsElapsed) {
	glGetQueryObjecti64vEXT(query[QUERY_OCCLUSION], GL_QUERY_RESULT, &pixels);
	} else {
	uint32_t pixels32;
	glGetQueryObjectuiv(query[QUERY_OCCLUSION], GL_QUERY_RESULT, &pixels32);
	pixels = static_cast<int64_t>(pixels32);
	}
	data[METRIC_GPU_PIXELS][i]->addData(boundary, pixels);
	}
	glDeleteQueries(QUERY_LIST_END, query.data());
	queries[i].pop();
	}
	}
	}

	void MetricBackend_opengl::endPass() {
	// process rest of the queries (it can be the last frame)
	processQueries();
	curPass++;
	}

	void MetricBackend_opengl::pausePass() {
	if (queryInProgress[QUERY_BOUNDARY_FRAME]) endQuery(QUERY_BOUNDARY_FRAME);
	processQueries();
	}

	void MetricBackend_opengl::continuePass() {
	// TODO if context switches check what it actually supports
	}

	void MetricBackend_opengl::beginQuery(QueryBoundary boundary) {
	// GPU related
	if (glQueriesNeeded[boundary]) {
	std::array<GLuint, QUERY_LIST_END> query;
	glGenQueries(QUERY_LIST_END, query.data());

	if (metrics[METRIC_GPU_START].profiled[boundary] \|\|
	(metrics[METRIC_GPU_DURATION].profiled[boundary] && supportsTimestamp))
	{
	glQueryCounter(query[QUERY_GPU_START], GL_TIMESTAMP);
	}
	if (metrics[METRIC_GPU_DURATION].profiled[boundary] && !supportsTimestamp) {
	glBeginQuery(GL_TIME_ELAPSED, query[QUERY_GPU_DURATION]);
	}
	if (metrics[METRIC_GPU_PIXELS].profiled[boundary]) {
	glBeginQuery(GL_SAMPLES_PASSED, query[QUERY_OCCLUSION]);
	}
	queries[boundary].push(std::move(query));
	}


	// CPU related
	if (metrics[METRIC_CPU_START].profiled[boundary] \|\|
	metrics[METRIC_CPU_DURATION].profiled[boundary])
	{
	cpuStart[boundary] = getCurrentTime();
	if (metrics[METRIC_CPU_START].profiled[boundary]) {
	int64_t time = cpuStart[boundary] * cpuTimeScale - baseTime;
	data[METRIC_CPU_START][boundary]->addData(boundary, time);
	}
	}
	if (metrics[METRIC_CPU_VSIZE_START].profiled[boundary] \|\|
	metrics[METRIC_CPU_VSIZE_DURATION].profiled[boundary])
	{
	vsizeStart[boundary] = os::getVsize();
	if (metrics[METRIC_CPU_VSIZE_START].profiled[boundary]) {
	int64_t time = vsizeStart[boundary];
	data[METRIC_CPU_VSIZE_START][boundary]->addData(boundary, time);
	}
	}
	if (metrics[METRIC_CPU_RSS_START].profiled[boundary] \|\|
	metrics[METRIC_CPU_RSS_DURATION].profiled[boundary])
	{
	rssStart[boundary] = os::getRss();
	if (metrics[METRIC_CPU_RSS_START].profiled[boundary]) {
	int64_t time = rssStart[boundary];
	data[METRIC_CPU_RSS_START][boundary]->addData(boundary, time);
	}
	}
	queryInProgress[boundary] = true;
	// DRAWCALL is a CALL
	if (boundary == QUERY_BOUNDARY_DRAWCALL) beginQuery(QUERY_BOUNDARY_CALL);
	}

	void MetricBackend_opengl::endQuery(QueryBoundary boundary) {
	if (queryInProgress[boundary]) {
	// CPU related
	if (metrics[METRIC_CPU_DURATION].profiled[boundary])
	{
	cpuEnd[boundary] = getCurrentTime();
	int64_t time = (cpuEnd[boundary] - cpuStart[boundary]) * cpuTimeScale;
	data[METRIC_CPU_DURATION][boundary]->addData(boundary, time);
	}
	if (metrics[METRIC_CPU_VSIZE_DURATION].profiled[boundary])
	{
	vsizeEnd[boundary] = os::getVsize();
	int64_t time = vsizeEnd[boundary] - vsizeStart[boundary];
	data[METRIC_CPU_VSIZE_DURATION][boundary]->addData(boundary, time);
	}
	if (metrics[METRIC_CPU_RSS_DURATION].profiled[boundary])
	{
	rssEnd[boundary] = os::getRss();
	int64_t time = rssEnd[boundary] - rssStart[boundary];
	data[METRIC_CPU_RSS_DURATION][boundary]->addData(boundary, time);
	}
	// GPU related
	if (glQueriesNeeded[boundary]) {
	std::array<GLuint, QUERY_LIST_END> &query = queries[boundary].back();
	if (metrics[METRIC_GPU_DURATION].profiled[boundary] && supportsTimestamp) {
	// GL_TIME_ELAPSED cannot be used in nested queries
	// so prefer this if timestamps are supported
	glQueryCounter(query[QUERY_GPU_DURATION], GL_TIMESTAMP);
	}
	if (metrics[METRIC_GPU_PIXELS].profiled[boundary]) {
	glEndQuery(GL_SAMPLES_PASSED);
	}
	}
	queryInProgress[boundary] = false;
	}
	// DRAWCALL is a CALL
	if (boundary == QUERY_BOUNDARY_DRAWCALL) endQuery(QUERY_BOUNDARY_CALL);
	// clear queries after each frame
	if (boundary == QUERY_BOUNDARY_FRAME && glQueriesNeededAnyBoundary) {
	processQueries();
	}
	}

	void MetricBackend_opengl::enumDataQueryId(unsigned id, enumDataCallback callback,
	QueryBoundary boundary, void* userData) {
	for (int i = 0; i < METRIC_LIST_END; i++) {
	Metric_opengl &metric = metrics[i];
	if (metric.enabled[boundary]) {
	callback(&metric, id, data[i][boundary]->getData(boundary, id), 0,
	userData);
	}
	}
	}

	unsigned MetricBackend_opengl::getNumPasses() {
	return twoPasses ? 2 : 1;
	}

	MetricBackend_opengl&
	MetricBackend_opengl::getInstance(glretrace::Context* context, MmapAllocator<char> &alloc) {
	static MetricBackend_opengl backend(context, alloc);
	return backend;
	}