modules/gles2/functional/es2fFlushFinishTests.cpp - third_party/vulkan-cts - Git at Google

 /*-------------------------------------------------------------------------
  * drawElements Quality Program OpenGL ES 2.0 Module
  * -------------------------------------------------
  *
  * Copyright 2014 The Android Open Source Project
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  *
  *//*!
  * \file
  * \brief Flush and finish tests.
  *//*--------------------------------------------------------------------*/

 #include "es2fFlushFinishTests.hpp"

 #include "gluRenderContext.hpp"
 #include "gluObjectWrapper.hpp"
 #include "gluShaderProgram.hpp"
 #include "gluDrawUtil.hpp"

 #include "glsCalibration.hpp"

 #include "tcuTestLog.hpp"
 #include "tcuRenderTarget.hpp"
 #include "tcuCPUWarmup.hpp"

 #include "glwEnums.hpp"
 #include "glwFunctions.hpp"

 #include "deRandom.hpp"
 #include "deStringUtil.hpp"
 #include "deClock.h"
 #include "deThread.h"
 #include "deMath.h"

 #include <algorithm>

 namespace deqp
 {
 namespace gles2
 {
 namespace Functional
 {

 using std::vector;
 using std::string;
 using tcu::TestLog;
 using tcu::Vec2;
 using deqp::gls::theilSenLinearRegression;
 using deqp::gls::LineParameters;

 namespace
 {

 enum
 {
 	MAX_VIEWPORT_SIZE		= 128,
 	MAX_SAMPLE_DURATION_US	= 1000*1000,
 	WAIT_TIME_MS			= 1200,
 	NUM_SAMPLES				= 25,
 	MIN_DRAW_CALL_COUNT		= 10,
 	MAX_DRAW_CALL_COUNT		= 1<<20,
 	NUM_ITERS_IN_SHADER		= 10
 };

 const float		NO_CORR_COEF_THRESHOLD		= 0.1f;
 const float		FLUSH_COEF_THRESHOLD		= 0.2f;
 const float		CORRELATED_COEF_THRESHOLD	= 0.5f;

 static void busyWait (int milliseconds)
 {
 	const deUint64	startTime	= deGetMicroseconds();
 	float			v			= 2.0f;

 	for (;;)
 	{
 		for (int i = 0; i < 10; i++)
 			v = deFloatSin(v);

 		if (deGetMicroseconds()-startTime >= deUint64(1000*milliseconds))
 			break;
 	}
 }

 class CalibrationFailedException : public std::runtime_error
 {
 public:
 	CalibrationFailedException (const std::string& reason) : std::runtime_error(reason) {}
 };

 class FlushFinishCase : public TestCase
 {
 public:
 	enum ExpectedBehavior
 	{
 		EXPECT_COEF_LESS_THAN = 0,
 		EXPECT_COEF_GREATER_THAN,
 	};

 							FlushFinishCase		(Context&			context,
 												 const char*		name,
 												 const char*		description,
 												 ExpectedBehavior	waitBehavior,
 												 float				waitThreshold,
 												 ExpectedBehavior	readBehavior,
 												 float				readThreshold);
 							~FlushFinishCase	(void);

 	void					init				(void);
 	void					deinit				(void);
 	IterateResult			iterate				(void);

 	struct Sample
 	{
 		int			numDrawCalls;
 		deUint64	waitTime;
 		deUint64	readPixelsTime;
 	};

 	struct CalibrationParams
 	{
 		int			maxDrawCalls;
 	};

 protected:
 	virtual void			waitForGL			(void) = 0;

 private:
 							FlushFinishCase		(const FlushFinishCase&);
 	FlushFinishCase&		operator=			(const FlushFinishCase&);

 	CalibrationParams		calibrate			(void);
 	void					analyzeResults		(const std::vector<Sample>& samples, const CalibrationParams& calibrationParams);

 	void					setupRenderState	(void);
 	void					render				(int numDrawCalls);
 	void					readPixels			(void);

 	const ExpectedBehavior	m_waitBehavior;
 	const float				m_waitThreshold;
 	const ExpectedBehavior	m_readBehavior;
 	const float				m_readThreshold;

 	glu::ShaderProgram*		m_program;
 };

 FlushFinishCase::FlushFinishCase (Context& context, const char* name, const char* description, ExpectedBehavior waitBehavior, float waitThreshold, ExpectedBehavior readBehavior, float readThreshold)
 	: TestCase			(context, name, description)
 	, m_waitBehavior	(waitBehavior)
 	, m_waitThreshold	(waitThreshold)
 	, m_readBehavior	(readBehavior)
 	, m_readThreshold	(readThreshold)
 	, m_program			(DE_NULL)
 {
 }

 FlushFinishCase::~FlushFinishCase (void)
 {
 	FlushFinishCase::deinit();
 }

 void FlushFinishCase::init (void)
 {
 	DE_ASSERT(!m_program);

 	m_program = new glu::ShaderProgram(m_context.getRenderContext(),
 		glu::ProgramSources()
 			<< glu::VertexSource(
 				"attribute highp vec4 a_position;\n"
 				"varying highp vec4 v_coord;\n"
 				"void main (void)\n"
 				"{\n"
 				"	gl_Position = a_position;\n"
 				"	v_coord = a_position;\n"
 				"}\n")
 			<< glu::FragmentSource(
 				"uniform mediump int u_numIters;\n"
 				"varying mediump vec4 v_coord;\n"
 				"void main (void)\n"
 				"{\n"
 				"	highp vec4 color = v_coord;\n"
 				"	for (int i = 0; i < " + de::toString(int(NUM_ITERS_IN_SHADER)) + "; i++)\n"
 				"		color = sin(color);\n"
 				"	gl_FragColor = color;\n"
 				"}\n"));

 	if (!m_program->isOk())
 	{
 		m_testCtx.getLog() << *m_program;
 		delete m_program;
 		m_program = DE_NULL;
 		TCU_FAIL("Compile failed");
 	}
 }

 void FlushFinishCase::deinit (void)
 {
 	delete m_program;
 	m_program = DE_NULL;
 }

 tcu::TestLog& operator<< (tcu::TestLog& log, const FlushFinishCase::Sample& sample)
 {
 	log << TestLog::Message << sample.numDrawCalls << " calls:\t" << sample.waitTime << " us wait,\t" << sample.readPixelsTime << " us read" << TestLog::EndMessage;
 	return log;
 }

 void FlushFinishCase::setupRenderState (void)
 {
 	const glw::Functions&	gl				= m_context.getRenderContext().getFunctions();
 	const int				posLoc			= gl.getAttribLocation(m_program->getProgram(), "a_position");
 	const int				viewportW		= de::min<int>(m_context.getRenderTarget().getWidth(), MAX_VIEWPORT_SIZE);
 	const int				viewportH		= de::min<int>(m_context.getRenderTarget().getHeight(), MAX_VIEWPORT_SIZE);

 	static const float s_positions[] =
 	{
 		-1.0f, -1.0f,
 		+1.0f, -1.0f,
 		-1.0f, +1.0f,
 		+1.0f, +1.0f
 	};

 	TCU_CHECK(posLoc >= 0);

 	gl.viewport(0, 0, viewportW, viewportH);
 	gl.useProgram(m_program->getProgram());
 	gl.enableVertexAttribArray(posLoc);
 	gl.vertexAttribPointer(posLoc, 2, GL_FLOAT, GL_FALSE, 0, &s_positions[0]);
 	gl.enable(GL_BLEND);
 	gl.blendFunc(GL_ONE, GL_ONE);
 	gl.blendEquation(GL_FUNC_ADD);
 	GLU_EXPECT_NO_ERROR(gl.getError(), "Failed to set up render state");
 }

 void FlushFinishCase::render (int numDrawCalls)
 {
 	const glw::Functions&	gl	= m_context.getRenderContext().getFunctions();

 	const deUint8 indices[] = { 0, 1, 2, 2, 1, 3 };

 	gl.clear(GL_COLOR_BUFFER_BIT|GL_DEPTH_BUFFER_BIT|GL_STENCIL_BUFFER_BIT);

 	for (int ndx = 0; ndx < numDrawCalls; ndx++)
 		gl.drawElements(GL_TRIANGLES, DE_LENGTH_OF_ARRAY(indices), GL_UNSIGNED_BYTE, &indices[0]);
 }

 void FlushFinishCase::readPixels (void)
 {
 	const glw::Functions&	gl		= m_context.getRenderContext().getFunctions();
 	deUint8					tmp[4];

 	gl.readPixels(0, 0, 1, 1, GL_RGBA, GL_UNSIGNED_BYTE, &tmp);
 }

 FlushFinishCase::CalibrationParams FlushFinishCase::calibrate (void)
 {
 	tcu::ScopedLogSection		section				(m_testCtx.getLog(), "CalibrationInfo", "Calibration info");
 	CalibrationParams			params;

 	// Find draw call count that results in desired maximum time.
 	{
 		deUint64			prevDuration			= 0;
 		int					prevDrawCount			= 1;
 		int					curDrawCount			= 1;

 		m_testCtx.getLog() << TestLog::Message << "Calibrating maximum draw call count, target duration = " << int(MAX_SAMPLE_DURATION_US) << " us" << TestLog::EndMessage;

 		for (;;)
 		{
 			deUint64 curDuration;

 			{
 				const deUint64	startTime	= deGetMicroseconds();
 				render(curDrawCount);
 				readPixels();
 				curDuration = deGetMicroseconds()-startTime;
 			}

 			m_testCtx.getLog() << TestLog::Message << "Duration with " << curDrawCount << " draw calls = " << curDuration << " us" << TestLog::EndMessage;

 			if (curDuration > MAX_SAMPLE_DURATION_US)
 			{
 				if (curDrawCount > 1)
 				{
 					// Compute final count by using linear estimation.
 					const float		a		= float(curDuration - prevDuration) / float(curDrawCount - prevDrawCount);
 					const float		b		= float(prevDuration) - a*float(prevDrawCount);
 					const float		est		= (float(MAX_SAMPLE_DURATION_US) - b) / a;

 					curDrawCount = de::clamp(deFloorFloatToInt32(est), 1, int(MAX_DRAW_CALL_COUNT));
 				}
 				// else: Settle on 1.

 				break;
 			}
 			else if (curDrawCount >= MAX_DRAW_CALL_COUNT)
 				break; // Settle on maximum.
 			else
 			{
 				prevDrawCount	= curDrawCount;
 				prevDuration	= curDuration;
 				curDrawCount	= curDrawCount*2;
 			}
 		}

 		params.maxDrawCalls = curDrawCount;

 		m_testCtx.getLog() << TestLog::Integer("MaxDrawCalls", "Maximum number of draw calls", "", QP_KEY_TAG_NONE, params.maxDrawCalls);
 	}

 	// Sanity check.
 	if (params.maxDrawCalls < MIN_DRAW_CALL_COUNT)
 		throw CalibrationFailedException("Calibration failed, maximum draw call count is too low");

 	return params;
 }

 struct CompareSampleDrawCount
 {
 	bool operator() (const FlushFinishCase::Sample& a, const FlushFinishCase::Sample& b) const { return a.numDrawCalls < b.numDrawCalls; }
 };

 std::vector<Vec2> getPointsFromSamples (const std::vector<FlushFinishCase::Sample>& samples, const deUint64 FlushFinishCase::Sample::*field)
 {
 	vector<Vec2> points(samples.size());

 	for (size_t ndx = 0; ndx < samples.size(); ndx++)
 		points[ndx] = Vec2(float(samples[ndx].numDrawCalls), float(samples[ndx].*field));

 	return points;
 }

 template<typename T>
 T getMaximumValue (const std::vector<FlushFinishCase::Sample>& samples, const T FlushFinishCase::Sample::*field)
 {
 	DE_ASSERT(!samples.empty());

 	T maxVal = samples[0].*field;

 	for (size_t ndx = 1; ndx < samples.size(); ndx++)
 		maxVal = de::max(maxVal, samples[ndx].*field);

 	return maxVal;
 }

 void FlushFinishCase::analyzeResults (const std::vector<Sample>& samples, const CalibrationParams& calibrationParams)
 {
 	const vector<Vec2>		waitTimes		= getPointsFromSamples(samples, &Sample::waitTime);
 	const vector<Vec2>		readTimes		= getPointsFromSamples(samples, &Sample::readPixelsTime);
 	const LineParameters	waitLine		= theilSenLinearRegression(waitTimes);
 	const LineParameters	readLine		= theilSenLinearRegression(readTimes);
 	const float				normWaitCoef	= waitLine.coefficient * float(calibrationParams.maxDrawCalls) / float(MAX_SAMPLE_DURATION_US);
 	const float				normReadCoef	= readLine.coefficient * float(calibrationParams.maxDrawCalls) / float(MAX_SAMPLE_DURATION_US);
 	bool					allOk			= true;

 	{
 		tcu::ScopedLogSection	section			(m_testCtx.getLog(), "Samples", "Samples");
 		vector<Sample>			sortedSamples	(samples.begin(), samples.end());

 		std::sort(sortedSamples.begin(), sortedSamples.end(), CompareSampleDrawCount());

 		for (vector<Sample>::const_iterator iter = sortedSamples.begin(); iter != sortedSamples.end(); ++iter)
 			m_testCtx.getLog() << *iter;
 	}

 	m_testCtx.getLog() << TestLog::Float("WaitCoefficient",				"Wait coefficient", "", QP_KEY_TAG_NONE, waitLine.coefficient)
 					   << TestLog::Float("ReadCoefficient",				"Read coefficient", "", QP_KEY_TAG_NONE, readLine.coefficient)
 					   << TestLog::Float("NormalizedWaitCoefficient",	"Normalized wait coefficient", "", QP_KEY_TAG_NONE, normWaitCoef)
 					   << TestLog::Float("NormalizedReadCoefficient",	"Normalized read coefficient", "", QP_KEY_TAG_NONE, normReadCoef);

 	{
 		const bool		waitCorrelated		= normWaitCoef > CORRELATED_COEF_THRESHOLD;
 		const bool		readCorrelated		= normReadCoef > CORRELATED_COEF_THRESHOLD;
 		const bool		waitNotCorr			= normWaitCoef < NO_CORR_COEF_THRESHOLD;
 		const bool		readNotCorr			= normReadCoef < NO_CORR_COEF_THRESHOLD;

 		if (waitCorrelated || waitNotCorr)
 			m_testCtx.getLog() << TestLog::Message << "Wait time is" << (waitCorrelated ? "" : " NOT") << " correlated to rendering workload size." << TestLog::EndMessage;
 		else
 			m_testCtx.getLog() << TestLog::Message << "Warning: Wait time correlation to rendering workload size is unclear." << TestLog::EndMessage;

 		if (readCorrelated || readNotCorr)
 			m_testCtx.getLog() << TestLog::Message << "Read time is" << (readCorrelated ? "" : " NOT") << " correlated to rendering workload size." << TestLog::EndMessage;
 		else
 			m_testCtx.getLog() << TestLog::Message << "Warning: Read time correlation to rendering workload size is unclear." << TestLog::EndMessage;
 	}

 	for (int ndx = 0; ndx < 2; ndx++)
 	{
 		const float				coef		= ndx == 0 ? normWaitCoef : normReadCoef;
 		const char*				name		= ndx == 0 ? "wait" : "read";
 		const ExpectedBehavior	behavior	= ndx == 0 ? m_waitBehavior : m_readBehavior;
 		const float				threshold	= ndx == 0 ? m_waitThreshold : m_readThreshold;
 		const bool				isOk		= behavior == EXPECT_COEF_GREATER_THAN	? coef > threshold :
 											  behavior == EXPECT_COEF_LESS_THAN		? coef < threshold : false;
 		const char*				cmpName		= behavior == EXPECT_COEF_GREATER_THAN	? "greater than" :
 											  behavior == EXPECT_COEF_LESS_THAN		? "less than" : DE_NULL;

 		if (!isOk)
 		{
 			m_testCtx.getLog() << TestLog::Message << "ERROR: Expected " << name << " coefficient to be " << cmpName << " " << threshold << TestLog::EndMessage;
 			allOk = false;
 		}
 	}

 	m_testCtx.setTestResult(allOk ? QP_TEST_RESULT_PASS	: QP_TEST_RESULT_COMPATIBILITY_WARNING,
 							allOk ? "Pass"				: "Suspicious performance behavior");
 }

 FlushFinishCase::IterateResult FlushFinishCase::iterate (void)
 {
 	vector<Sample>		samples		(NUM_SAMPLES);
 	CalibrationParams	params;

 	tcu::warmupCPU();

 	setupRenderState();

 	// Do one full render cycle.
 	{
 		render(1);
 		readPixels();
 	}

 	// Calibrate.
 	try
 	{
 		params = calibrate();
 	}
 	catch (const CalibrationFailedException& e)
 	{
 		m_testCtx.setTestResult(QP_TEST_RESULT_COMPATIBILITY_WARNING, e.what());
 		return STOP;
 	}

 	// Do measurement.
 	{
 		de::Random	rnd		(123);

 		for (size_t ndx = 0; ndx < samples.size(); ndx++)
 		{
 			const int	drawCallCount	= rnd.getInt(1, params.maxDrawCalls);
 			deUint64	waitStartTime;
 			deUint64	readStartTime;
 			deUint64	readFinishTime;

 			render(drawCallCount);

 			waitStartTime = deGetMicroseconds();
 			waitForGL();

 			readStartTime = deGetMicroseconds();
 			readPixels();
 			readFinishTime = deGetMicroseconds();

 			samples[ndx].numDrawCalls	= drawCallCount;
 			samples[ndx].waitTime		= readStartTime-waitStartTime;
 			samples[ndx].readPixelsTime	= readFinishTime-readStartTime;

 			if (m_testCtx.getWatchDog())
 				qpWatchDog_touch(m_testCtx.getWatchDog());
 		}
 	}

 	// Analyze - sets test case result.
 	analyzeResults(samples, params);

 	return STOP;
 }

 class WaitOnlyCase : public FlushFinishCase
 {
 public:
 	WaitOnlyCase (Context& context)
 		: FlushFinishCase(context, "wait", "Wait only", EXPECT_COEF_LESS_THAN, NO_CORR_COEF_THRESHOLD, EXPECT_COEF_GREATER_THAN, -1000.0f /* practically nothing is expected */)
 	{
 	}

 	void init (void)
 	{
 		m_testCtx.getLog() << TestLog::Message << int(WAIT_TIME_MS) << " ms busy wait" << TestLog::EndMessage;
 		FlushFinishCase::init();
 	}

 protected:
 	void waitForGL (void)
 	{
 		busyWait(WAIT_TIME_MS);
 	}
 };

 class FlushOnlyCase : public FlushFinishCase
 {
 public:
 	FlushOnlyCase (Context& context)
 		: FlushFinishCase(context, "flush", "Flush only", EXPECT_COEF_LESS_THAN, FLUSH_COEF_THRESHOLD, EXPECT_COEF_GREATER_THAN, CORRELATED_COEF_THRESHOLD)
 	{
 	}

 	void init (void)
 	{
 		m_testCtx.getLog() << TestLog::Message << "Single call to glFlush()" << TestLog::EndMessage;
 		FlushFinishCase::init();
 	}

 protected:
 	void waitForGL (void)
 	{
 		m_context.getRenderContext().getFunctions().flush();
 	}
 };

 class FlushWaitCase : public FlushFinishCase
 {
 public:
 	FlushWaitCase (Context& context)
 		: FlushFinishCase(context, "flush_wait", "Wait after flushing", EXPECT_COEF_LESS_THAN, FLUSH_COEF_THRESHOLD, EXPECT_COEF_LESS_THAN, NO_CORR_COEF_THRESHOLD)
 	{
 	}

 	void init (void)
 	{
 		m_testCtx.getLog() << TestLog::Message << "glFlush() followed by " << int(WAIT_TIME_MS) << " ms busy wait" << TestLog::EndMessage;
 		FlushFinishCase::init();
 	}

 protected:
 	void waitForGL (void)
 	{
 		m_context.getRenderContext().getFunctions().flush();
 		busyWait(WAIT_TIME_MS);
 	}
 };

 class FinishOnlyCase : public FlushFinishCase
 {
 public:
 	FinishOnlyCase (Context& context)
 		: FlushFinishCase(context, "finish", "Finish only", EXPECT_COEF_GREATER_THAN, CORRELATED_COEF_THRESHOLD, EXPECT_COEF_LESS_THAN, NO_CORR_COEF_THRESHOLD)
 	{
 	}

 	void init (void)
 	{
 		m_testCtx.getLog() << TestLog::Message << "Single call to glFinish()" << TestLog::EndMessage;
 		FlushFinishCase::init();
 	}

 protected:
 	void waitForGL (void)
 	{
 		m_context.getRenderContext().getFunctions().finish();
 	}
 };

 class FinishWaitCase : public FlushFinishCase
 {
 public:
 	FinishWaitCase (Context& context)
 		: FlushFinishCase(context, "finish_wait", "Finish and wait", EXPECT_COEF_GREATER_THAN, CORRELATED_COEF_THRESHOLD, EXPECT_COEF_LESS_THAN, NO_CORR_COEF_THRESHOLD)
 	{
 	}

 	void init (void)
 	{
 		m_testCtx.getLog() << TestLog::Message << "glFinish() followed by " << int(WAIT_TIME_MS) << " ms busy wait" << TestLog::EndMessage;
 		FlushFinishCase::init();
 	}

 protected:
 	void waitForGL (void)
 	{
 		m_context.getRenderContext().getFunctions().finish();
 		busyWait(WAIT_TIME_MS);
 	}
 };

 } // anonymous

 FlushFinishTests::FlushFinishTests (Context& context)
 	: TestCaseGroup(context, "flush_finish", "Flush and Finish tests")
 {
 }

 FlushFinishTests::~FlushFinishTests (void)
 {
 }

 void FlushFinishTests::init (void)
 {
 	addChild(new WaitOnlyCase	(m_context));
 	addChild(new FlushOnlyCase	(m_context));
 	addChild(new FlushWaitCase	(m_context));
 	addChild(new FinishOnlyCase	(m_context));
 	addChild(new FinishWaitCase	(m_context));
 }

 } // Functional
 } // gles2
 } // deqp
	/*-------------------------------------------------------------------------
	* drawElements Quality Program OpenGL ES 2.0 Module
	* -------------------------------------------------
	*
	* Copyright 2014 The Android Open Source Project
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*
	//!
	* \file
	* \brief Flush and finish tests.
	//--------------------------------------------------------------------*/

	#include "es2fFlushFinishTests.hpp"

	#include "gluRenderContext.hpp"
	#include "gluObjectWrapper.hpp"
	#include "gluShaderProgram.hpp"
	#include "gluDrawUtil.hpp"

	#include "glsCalibration.hpp"

	#include "tcuTestLog.hpp"
	#include "tcuRenderTarget.hpp"
	#include "tcuCPUWarmup.hpp"

	#include "glwEnums.hpp"
	#include "glwFunctions.hpp"

	#include "deRandom.hpp"
	#include "deStringUtil.hpp"
	#include "deClock.h"
	#include "deThread.h"
	#include "deMath.h"

	#include <algorithm>

	namespace deqp
	{
	namespace gles2
	{
	namespace Functional
	{

	using std::vector;
	using std::string;
	using tcu::TestLog;
	using tcu::Vec2;
	using deqp::gls::theilSenLinearRegression;
	using deqp::gls::LineParameters;

	namespace
	{

	enum
	{
	MAX_VIEWPORT_SIZE = 128,
	MAX_SAMPLE_DURATION_US = 1000*1000,
	WAIT_TIME_MS = 1200,
	NUM_SAMPLES = 25,
	MIN_DRAW_CALL_COUNT = 10,
	MAX_DRAW_CALL_COUNT = 1<<20,
	NUM_ITERS_IN_SHADER = 10
	};

	const float NO_CORR_COEF_THRESHOLD = 0.1f;
	const float FLUSH_COEF_THRESHOLD = 0.2f;
	const float CORRELATED_COEF_THRESHOLD = 0.5f;

	static void busyWait (int milliseconds)
	{
	const deUint64 startTime = deGetMicroseconds();
	float v = 2.0f;

	for (;;)
	{
	for (int i = 0; i < 10; i++)
	v = deFloatSin(v);

	if (deGetMicroseconds()-startTime >= deUint64(1000*milliseconds))
	break;
	}
	}

	class CalibrationFailedException : public std::runtime_error
	{
	public:
	CalibrationFailedException (const std::string& reason) : std::runtime_error(reason) {}
	};

	class FlushFinishCase : public TestCase
	{
	public:
	enum ExpectedBehavior
	{
	EXPECT_COEF_LESS_THAN = 0,
	EXPECT_COEF_GREATER_THAN,
	};

	FlushFinishCase (Context& context,
	const char* name,
	const char* description,
	ExpectedBehavior waitBehavior,
	float waitThreshold,
	ExpectedBehavior readBehavior,
	float readThreshold);
	~FlushFinishCase (void);

	void init (void);
	void deinit (void);
	IterateResult iterate (void);

	struct Sample
	{
	int numDrawCalls;
	deUint64 waitTime;
	deUint64 readPixelsTime;
	};

	struct CalibrationParams
	{
	int maxDrawCalls;
	};

	protected:
	virtual void waitForGL (void) = 0;

	private:
	FlushFinishCase (const FlushFinishCase&);
	FlushFinishCase& operator= (const FlushFinishCase&);

	CalibrationParams calibrate (void);
	void analyzeResults (const std::vector<Sample>& samples, const CalibrationParams& calibrationParams);

	void setupRenderState (void);
	void render (int numDrawCalls);
	void readPixels (void);

	const ExpectedBehavior m_waitBehavior;
	const float m_waitThreshold;
	const ExpectedBehavior m_readBehavior;
	const float m_readThreshold;

	glu::ShaderProgram* m_program;
	};

	FlushFinishCase::FlushFinishCase (Context& context, const char* name, const char* description, ExpectedBehavior waitBehavior, float waitThreshold, ExpectedBehavior readBehavior, float readThreshold)
	: TestCase (context, name, description)
	, m_waitBehavior (waitBehavior)
	, m_waitThreshold (waitThreshold)
	, m_readBehavior (readBehavior)
	, m_readThreshold (readThreshold)
	, m_program (DE_NULL)
	{
	}

	FlushFinishCase::~FlushFinishCase (void)
	{
	FlushFinishCase::deinit();
	}

	void FlushFinishCase::init (void)
	{
	DE_ASSERT(!m_program);

	m_program = new glu::ShaderProgram(m_context.getRenderContext(),
	glu::ProgramSources()
	<< glu::VertexSource(
	"attribute highp vec4 a_position;\n"
	"varying highp vec4 v_coord;\n"
	"void main (void)\n"
	"{\n"
	" gl_Position = a_position;\n"
	" v_coord = a_position;\n"
	"}\n")
	<< glu::FragmentSource(
	"uniform mediump int u_numIters;\n"
	"varying mediump vec4 v_coord;\n"
	"void main (void)\n"
	"{\n"
	" highp vec4 color = v_coord;\n"
	" for (int i = 0; i < " + de::toString(int(NUM_ITERS_IN_SHADER)) + "; i++)\n"
	" color = sin(color);\n"
	" gl_FragColor = color;\n"
	"}\n"));

	if (!m_program->isOk())
	{
	m_testCtx.getLog() << *m_program;
	delete m_program;
	m_program = DE_NULL;
	TCU_FAIL("Compile failed");
	}
	}

	void FlushFinishCase::deinit (void)
	{
	delete m_program;
	m_program = DE_NULL;
	}

	tcu::TestLog& operator<< (tcu::TestLog& log, const FlushFinishCase::Sample& sample)
	{
	log << TestLog::Message << sample.numDrawCalls << " calls:\t" << sample.waitTime << " us wait,\t" << sample.readPixelsTime << " us read" << TestLog::EndMessage;
	return log;
	}

	void FlushFinishCase::setupRenderState (void)
	{
	const glw::Functions& gl = m_context.getRenderContext().getFunctions();
	const int posLoc = gl.getAttribLocation(m_program->getProgram(), "a_position");
	const int viewportW = de::min<int>(m_context.getRenderTarget().getWidth(), MAX_VIEWPORT_SIZE);
	const int viewportH = de::min<int>(m_context.getRenderTarget().getHeight(), MAX_VIEWPORT_SIZE);

	static const float s_positions[] =
	{
	-1.0f, -1.0f,
	+1.0f, -1.0f,
	-1.0f, +1.0f,
	+1.0f, +1.0f
	};

	TCU_CHECK(posLoc >= 0);

	gl.viewport(0, 0, viewportW, viewportH);
	gl.useProgram(m_program->getProgram());
	gl.enableVertexAttribArray(posLoc);
	gl.vertexAttribPointer(posLoc, 2, GL_FLOAT, GL_FALSE, 0, &s_positions[0]);
	gl.enable(GL_BLEND);
	gl.blendFunc(GL_ONE, GL_ONE);
	gl.blendEquation(GL_FUNC_ADD);
	GLU_EXPECT_NO_ERROR(gl.getError(), "Failed to set up render state");
	}

	void FlushFinishCase::render (int numDrawCalls)
	{
	const glw::Functions& gl = m_context.getRenderContext().getFunctions();

	const deUint8 indices[] = { 0, 1, 2, 2, 1, 3 };

	gl.clear(GL_COLOR_BUFFER_BIT\|GL_DEPTH_BUFFER_BIT\|GL_STENCIL_BUFFER_BIT);

	for (int ndx = 0; ndx < numDrawCalls; ndx++)
	gl.drawElements(GL_TRIANGLES, DE_LENGTH_OF_ARRAY(indices), GL_UNSIGNED_BYTE, &indices[0]);
	}

	void FlushFinishCase::readPixels (void)
	{
	const glw::Functions& gl = m_context.getRenderContext().getFunctions();
	deUint8 tmp[4];

	gl.readPixels(0, 0, 1, 1, GL_RGBA, GL_UNSIGNED_BYTE, &tmp);
	}

	FlushFinishCase::CalibrationParams FlushFinishCase::calibrate (void)
	{
	tcu::ScopedLogSection section (m_testCtx.getLog(), "CalibrationInfo", "Calibration info");
	CalibrationParams params;

	// Find draw call count that results in desired maximum time.
	{
	deUint64 prevDuration = 0;
	int prevDrawCount = 1;
	int curDrawCount = 1;

	m_testCtx.getLog() << TestLog::Message << "Calibrating maximum draw call count, target duration = " << int(MAX_SAMPLE_DURATION_US) << " us" << TestLog::EndMessage;

	for (;;)
	{
	deUint64 curDuration;

	{
	const deUint64 startTime = deGetMicroseconds();
	render(curDrawCount);
	readPixels();
	curDuration = deGetMicroseconds()-startTime;
	}

	m_testCtx.getLog() << TestLog::Message << "Duration with " << curDrawCount << " draw calls = " << curDuration << " us" << TestLog::EndMessage;

	if (curDuration > MAX_SAMPLE_DURATION_US)
	{
	if (curDrawCount > 1)
	{
	// Compute final count by using linear estimation.
	const float a = float(curDuration - prevDuration) / float(curDrawCount - prevDrawCount);
	const float b = float(prevDuration) - a*float(prevDrawCount);
	const float est = (float(MAX_SAMPLE_DURATION_US) - b) / a;

	curDrawCount = de::clamp(deFloorFloatToInt32(est), 1, int(MAX_DRAW_CALL_COUNT));
	}
	// else: Settle on 1.

	break;
	}
	else if (curDrawCount >= MAX_DRAW_CALL_COUNT)
	break; // Settle on maximum.
	else
	{
	prevDrawCount = curDrawCount;
	prevDuration = curDuration;
	curDrawCount = curDrawCount*2;
	}
	}

	params.maxDrawCalls = curDrawCount;

	m_testCtx.getLog() << TestLog::Integer("MaxDrawCalls", "Maximum number of draw calls", "", QP_KEY_TAG_NONE, params.maxDrawCalls);
	}

	// Sanity check.
	if (params.maxDrawCalls < MIN_DRAW_CALL_COUNT)
	throw CalibrationFailedException("Calibration failed, maximum draw call count is too low");

	return params;
	}

	struct CompareSampleDrawCount
	{
	bool operator() (const FlushFinishCase::Sample& a, const FlushFinishCase::Sample& b) const { return a.numDrawCalls < b.numDrawCalls; }
	};

	std::vector<Vec2> getPointsFromSamples (const std::vector<FlushFinishCase::Sample>& samples, const deUint64 FlushFinishCase::Sample::*field)
	{
	vector<Vec2> points(samples.size());

	for (size_t ndx = 0; ndx < samples.size(); ndx++)
	points[ndx] = Vec2(float(samples[ndx].numDrawCalls), float(samples[ndx].*field));

	return points;
	}

	template<typename T>
	T getMaximumValue (const std::vector<FlushFinishCase::Sample>& samples, const T FlushFinishCase::Sample::*field)
	{
	DE_ASSERT(!samples.empty());

	T maxVal = samples[0].*field;

	for (size_t ndx = 1; ndx < samples.size(); ndx++)
	maxVal = de::max(maxVal, samples[ndx].*field);

	return maxVal;
	}

	void FlushFinishCase::analyzeResults (const std::vector<Sample>& samples, const CalibrationParams& calibrationParams)
	{
	const vector<Vec2> waitTimes = getPointsFromSamples(samples, &Sample::waitTime);
	const vector<Vec2> readTimes = getPointsFromSamples(samples, &Sample::readPixelsTime);
	const LineParameters waitLine = theilSenLinearRegression(waitTimes);
	const LineParameters readLine = theilSenLinearRegression(readTimes);
	const float normWaitCoef = waitLine.coefficient * float(calibrationParams.maxDrawCalls) / float(MAX_SAMPLE_DURATION_US);
	const float normReadCoef = readLine.coefficient * float(calibrationParams.maxDrawCalls) / float(MAX_SAMPLE_DURATION_US);
	bool allOk = true;

	{
	tcu::ScopedLogSection section (m_testCtx.getLog(), "Samples", "Samples");
	vector<Sample> sortedSamples (samples.begin(), samples.end());

	std::sort(sortedSamples.begin(), sortedSamples.end(), CompareSampleDrawCount());

	for (vector<Sample>::const_iterator iter = sortedSamples.begin(); iter != sortedSamples.end(); ++iter)
	m_testCtx.getLog() << *iter;
	}

	m_testCtx.getLog() << TestLog::Float("WaitCoefficient", "Wait coefficient", "", QP_KEY_TAG_NONE, waitLine.coefficient)
	<< TestLog::Float("ReadCoefficient", "Read coefficient", "", QP_KEY_TAG_NONE, readLine.coefficient)
	<< TestLog::Float("NormalizedWaitCoefficient", "Normalized wait coefficient", "", QP_KEY_TAG_NONE, normWaitCoef)
	<< TestLog::Float("NormalizedReadCoefficient", "Normalized read coefficient", "", QP_KEY_TAG_NONE, normReadCoef);

	{
	const bool waitCorrelated = normWaitCoef > CORRELATED_COEF_THRESHOLD;
	const bool readCorrelated = normReadCoef > CORRELATED_COEF_THRESHOLD;
	const bool waitNotCorr = normWaitCoef < NO_CORR_COEF_THRESHOLD;
	const bool readNotCorr = normReadCoef < NO_CORR_COEF_THRESHOLD;

	if (waitCorrelated \|\| waitNotCorr)
	m_testCtx.getLog() << TestLog::Message << "Wait time is" << (waitCorrelated ? "" : " NOT") << " correlated to rendering workload size." << TestLog::EndMessage;
	else
	m_testCtx.getLog() << TestLog::Message << "Warning: Wait time correlation to rendering workload size is unclear." << TestLog::EndMessage;

	if (readCorrelated \|\| readNotCorr)
	m_testCtx.getLog() << TestLog::Message << "Read time is" << (readCorrelated ? "" : " NOT") << " correlated to rendering workload size." << TestLog::EndMessage;
	else
	m_testCtx.getLog() << TestLog::Message << "Warning: Read time correlation to rendering workload size is unclear." << TestLog::EndMessage;
	}

	for (int ndx = 0; ndx < 2; ndx++)
	{
	const float coef = ndx == 0 ? normWaitCoef : normReadCoef;
	const char* name = ndx == 0 ? "wait" : "read";
	const ExpectedBehavior behavior = ndx == 0 ? m_waitBehavior : m_readBehavior;
	const float threshold = ndx == 0 ? m_waitThreshold : m_readThreshold;
	const bool isOk = behavior == EXPECT_COEF_GREATER_THAN ? coef > threshold :
	behavior == EXPECT_COEF_LESS_THAN ? coef < threshold : false;
	const char* cmpName = behavior == EXPECT_COEF_GREATER_THAN ? "greater than" :
	behavior == EXPECT_COEF_LESS_THAN ? "less than" : DE_NULL;

	if (!isOk)
	{
	m_testCtx.getLog() << TestLog::Message << "ERROR: Expected " << name << " coefficient to be " << cmpName << " " << threshold << TestLog::EndMessage;
	allOk = false;
	}
	}

	m_testCtx.setTestResult(allOk ? QP_TEST_RESULT_PASS : QP_TEST_RESULT_COMPATIBILITY_WARNING,
	allOk ? "Pass" : "Suspicious performance behavior");
	}

	FlushFinishCase::IterateResult FlushFinishCase::iterate (void)
	{
	vector<Sample> samples (NUM_SAMPLES);
	CalibrationParams params;

	tcu::warmupCPU();

	setupRenderState();

	// Do one full render cycle.
	{
	render(1);
	readPixels();
	}

	// Calibrate.
	try
	{
	params = calibrate();
	}
	catch (const CalibrationFailedException& e)
	{
	m_testCtx.setTestResult(QP_TEST_RESULT_COMPATIBILITY_WARNING, e.what());
	return STOP;
	}

	// Do measurement.
	{
	de::Random rnd (123);

	for (size_t ndx = 0; ndx < samples.size(); ndx++)
	{
	const int drawCallCount = rnd.getInt(1, params.maxDrawCalls);
	deUint64 waitStartTime;
	deUint64 readStartTime;
	deUint64 readFinishTime;

	render(drawCallCount);

	waitStartTime = deGetMicroseconds();
	waitForGL();

	readStartTime = deGetMicroseconds();
	readPixels();
	readFinishTime = deGetMicroseconds();

	samples[ndx].numDrawCalls = drawCallCount;
	samples[ndx].waitTime = readStartTime-waitStartTime;
	samples[ndx].readPixelsTime = readFinishTime-readStartTime;

	if (m_testCtx.getWatchDog())
	qpWatchDog_touch(m_testCtx.getWatchDog());
	}
	}

	// Analyze - sets test case result.
	analyzeResults(samples, params);

	return STOP;
	}

	class WaitOnlyCase : public FlushFinishCase
	{
	public:
	WaitOnlyCase (Context& context)
	: FlushFinishCase(context, "wait", "Wait only", EXPECT_COEF_LESS_THAN, NO_CORR_COEF_THRESHOLD, EXPECT_COEF_GREATER_THAN, -1000.0f /* practically nothing is expected */)
	{
	}

	void init (void)
	{
	m_testCtx.getLog() << TestLog::Message << int(WAIT_TIME_MS) << " ms busy wait" << TestLog::EndMessage;
	FlushFinishCase::init();
	}

	protected:
	void waitForGL (void)
	{
	busyWait(WAIT_TIME_MS);
	}
	};

	class FlushOnlyCase : public FlushFinishCase
	{
	public:
	FlushOnlyCase (Context& context)
	: FlushFinishCase(context, "flush", "Flush only", EXPECT_COEF_LESS_THAN, FLUSH_COEF_THRESHOLD, EXPECT_COEF_GREATER_THAN, CORRELATED_COEF_THRESHOLD)
	{
	}

	void init (void)
	{
	m_testCtx.getLog() << TestLog::Message << "Single call to glFlush()" << TestLog::EndMessage;
	FlushFinishCase::init();
	}

	protected:
	void waitForGL (void)
	{
	m_context.getRenderContext().getFunctions().flush();
	}
	};

	class FlushWaitCase : public FlushFinishCase
	{
	public:
	FlushWaitCase (Context& context)
	: FlushFinishCase(context, "flush_wait", "Wait after flushing", EXPECT_COEF_LESS_THAN, FLUSH_COEF_THRESHOLD, EXPECT_COEF_LESS_THAN, NO_CORR_COEF_THRESHOLD)
	{
	}

	void init (void)
	{
	m_testCtx.getLog() << TestLog::Message << "glFlush() followed by " << int(WAIT_TIME_MS) << " ms busy wait" << TestLog::EndMessage;
	FlushFinishCase::init();
	}

	protected:
	void waitForGL (void)
	{
	m_context.getRenderContext().getFunctions().flush();
	busyWait(WAIT_TIME_MS);
	}
	};

	class FinishOnlyCase : public FlushFinishCase
	{
	public:
	FinishOnlyCase (Context& context)
	: FlushFinishCase(context, "finish", "Finish only", EXPECT_COEF_GREATER_THAN, CORRELATED_COEF_THRESHOLD, EXPECT_COEF_LESS_THAN, NO_CORR_COEF_THRESHOLD)
	{
	}

	void init (void)
	{
	m_testCtx.getLog() << TestLog::Message << "Single call to glFinish()" << TestLog::EndMessage;
	FlushFinishCase::init();
	}

	protected:
	void waitForGL (void)
	{
	m_context.getRenderContext().getFunctions().finish();
	}
	};

	class FinishWaitCase : public FlushFinishCase
	{
	public:
	FinishWaitCase (Context& context)
	: FlushFinishCase(context, "finish_wait", "Finish and wait", EXPECT_COEF_GREATER_THAN, CORRELATED_COEF_THRESHOLD, EXPECT_COEF_LESS_THAN, NO_CORR_COEF_THRESHOLD)
	{
	}

	void init (void)
	{
	m_testCtx.getLog() << TestLog::Message << "glFinish() followed by " << int(WAIT_TIME_MS) << " ms busy wait" << TestLog::EndMessage;
	FlushFinishCase::init();
	}

	protected:
	void waitForGL (void)
	{
	m_context.getRenderContext().getFunctions().finish();
	busyWait(WAIT_TIME_MS);
	}
	};

	} // anonymous

	FlushFinishTests::FlushFinishTests (Context& context)
	: TestCaseGroup(context, "flush_finish", "Flush and Finish tests")
	{
	}

	FlushFinishTests::~FlushFinishTests (void)
	{
	}

	void FlushFinishTests::init (void)
	{
	addChild(new WaitOnlyCase (m_context));
	addChild(new FlushOnlyCase (m_context));
	addChild(new FlushWaitCase (m_context));
	addChild(new FinishOnlyCase (m_context));
	addChild(new FinishWaitCase (m_context));
	}

	} // Functional
	} // gles2
	} // deqp