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/*-------------------------------------------------------------------------
 * 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 Invariance tests.
 *//*--------------------------------------------------------------------*/

#include "es2fShaderInvarianceTests.hpp"
#include "deStringUtil.hpp"
#include "deRandom.hpp"
#include "gluContextInfo.hpp"
#include "gluRenderContext.hpp"
#include "gluShaderProgram.hpp"
#include "gluPixelTransfer.hpp"
#include "glwFunctions.hpp"
#include "glwEnums.hpp"
#include "tcuRenderTarget.hpp"
#include "tcuTestLog.hpp"
#include "tcuSurface.hpp"
#include "tcuTextureUtil.hpp"
#include "tcuStringTemplate.hpp"


namespace deqp
{
namespace gles2
{
namespace Functional
{
namespace
{

class FormatArgumentList;

static tcu::Vec4 genRandomVector (de::Random& rnd)
{
	tcu::Vec4 retVal;

	retVal.x() = rnd.getFloat(-1.0f, 1.0f);
	retVal.y() = rnd.getFloat(-1.0f, 1.0f);
	retVal.z() = rnd.getFloat(-1.0f, 1.0f);
	retVal.w() = rnd.getFloat( 0.2f, 1.0f);

	return retVal;
}

class FormatArgument
{
public:
						FormatArgument (const char* name, const std::string& value);

private:
	friend class FormatArgumentList;

	const char* const	m_name;
	const std::string	m_value;
};

FormatArgument::FormatArgument (const char* name, const std::string& value)
	: m_name	(name)
	, m_value	(value)
{
}

class FormatArgumentList
{
public:
												FormatArgumentList	(void);

	FormatArgumentList&							operator<<			(const FormatArgument&);
	const std::map<std::string, std::string>&	getArguments		(void) const;

private:
	std::map<std::string, std::string>			m_formatArguments;
};

FormatArgumentList::FormatArgumentList (void)
{
}

FormatArgumentList&	FormatArgumentList::operator<< (const FormatArgument& arg)
{
	m_formatArguments[arg.m_name] = arg.m_value;
	return *this;
}

const std::map<std::string, std::string>& FormatArgumentList::getArguments (void) const
{
	return m_formatArguments;
}

static std::string formatGLSL (const char* templateString, const FormatArgumentList& args)
{
	const std::map<std::string, std::string>& params = args.getArguments();

	return tcu::StringTemplate(std::string(templateString)).specialize(params);
}

/*--------------------------------------------------------------------*//*!
 * \brief Vertex shader invariance test
 *
 * Test vertex shader invariance by drawing a test pattern two times, each
 * time with a different shader. Shaders have set identical values to
 * invariant gl_Position using identical expressions. No fragments from the
 * first pass using should remain visible.
 *//*--------------------------------------------------------------------*/
class InvarianceTest : public TestCase
{
public:
	struct ShaderPair
	{
		std::string vertexShaderSource0;
		std::string fragmentShaderSource0;
		std::string vertexShaderSource1;
		std::string fragmentShaderSource1;
	};

							InvarianceTest		(Context& ctx, const char* name, const char* desc);
							~InvarianceTest		(void);

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

private:
	virtual ShaderPair		genShaders			(void) const = DE_NULL;
	bool					checkImage			(const tcu::Surface&) const;

	glu::ShaderProgram*		m_shader0;
	glu::ShaderProgram*		m_shader1;
	glw::GLuint				m_arrayBuf;
	int						m_verticesInPattern;

	const int				m_renderSize;
};

InvarianceTest::InvarianceTest (Context& ctx, const char* name, const char* desc)
	: TestCase				(ctx, name, desc)
	, m_shader0				(DE_NULL)
	, m_shader1				(DE_NULL)
	, m_arrayBuf			(0)
	, m_verticesInPattern	(0)
	, m_renderSize			(256)
{
}

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

void InvarianceTest::init (void)
{
	// Invariance tests require drawing to the screen and reading back results.
	// Tests results are not reliable if the resolution is too small
	{
		if (m_context.getRenderTarget().getWidth()  < m_renderSize ||
			m_context.getRenderTarget().getHeight() < m_renderSize)
			throw tcu::NotSupportedError(std::string("Render target size must be at least ") + de::toString(m_renderSize) + "x" + de::toString(m_renderSize));
	}

	// Gen shaders
	{
		ShaderPair vertexShaders = genShaders();

		m_shader0 = new glu::ShaderProgram(m_context.getRenderContext(), glu::ProgramSources() << glu::VertexSource(vertexShaders.vertexShaderSource0) << glu::FragmentSource(vertexShaders.fragmentShaderSource0));
		if (!m_shader0->isOk())
		{
			m_testCtx.getLog() << *m_shader0;
			throw tcu::TestError("Test shader compile failed.");
		}

		m_shader1 = new glu::ShaderProgram(m_context.getRenderContext(), glu::ProgramSources() << glu::VertexSource(vertexShaders.vertexShaderSource1) << glu::FragmentSource(vertexShaders.fragmentShaderSource1));
		if (!m_shader1->isOk())
		{
			m_testCtx.getLog() << *m_shader1;
			throw tcu::TestError("Test shader compile failed.");
		}

		// log
		m_testCtx.getLog()
			<< tcu::TestLog::Message << "Shader 1:" << tcu::TestLog::EndMessage
			<< *m_shader0
			<< tcu::TestLog::Message << "Shader 2:" << tcu::TestLog::EndMessage
			<< *m_shader1;
	}

	// Gen test pattern
	{
		const int				numTriangles	= 72;
		de::Random				rnd				(123);
		std::vector<tcu::Vec4>	triangles		(numTriangles * 3 * 2);
		const glw::Functions&	gl				= m_context.getRenderContext().getFunctions();

		// Narrow triangle pattern
		for (int triNdx = 0; triNdx < numTriangles; ++triNdx)
		{
			const tcu::Vec4 vertex1 = genRandomVector(rnd);
			const tcu::Vec4 vertex2 = genRandomVector(rnd);
			const tcu::Vec4 vertex3 = vertex2 + genRandomVector(rnd) * 0.01f; // generate narrow triangles

			triangles[triNdx*3 + 0] = vertex1;
			triangles[triNdx*3 + 1] = vertex2;
			triangles[triNdx*3 + 2] = vertex3;
		}

		// Normal triangle pattern
		for (int triNdx = 0; triNdx < numTriangles; ++triNdx)
		{
			triangles[(numTriangles + triNdx)*3 + 0] = genRandomVector(rnd);
			triangles[(numTriangles + triNdx)*3 + 1] = genRandomVector(rnd);
			triangles[(numTriangles + triNdx)*3 + 2] = genRandomVector(rnd);
		}

		// upload
		gl.genBuffers(1, &m_arrayBuf);
		gl.bindBuffer(GL_ARRAY_BUFFER, m_arrayBuf);
		gl.bufferData(GL_ARRAY_BUFFER, (int)(triangles.size() * sizeof(tcu::Vec4)), &triangles[0], GL_STATIC_DRAW);
		GLU_EXPECT_NO_ERROR(gl.getError(), "buffer gen");

		m_verticesInPattern = numTriangles * 3;
	}
}

void InvarianceTest::deinit (void)
{
	delete m_shader0;
	delete m_shader1;

	m_shader0 = DE_NULL;
	m_shader1 = DE_NULL;

	if (m_arrayBuf)
	{
		m_context.getRenderContext().getFunctions().deleteBuffers(1, &m_arrayBuf);
		m_arrayBuf = 0;
	}
}

InvarianceTest::IterateResult InvarianceTest::iterate (void)
{
	const glw::Functions&	gl					= m_context.getRenderContext().getFunctions();
	const bool				depthBufferExists	= m_context.getRenderTarget().getDepthBits() != 0;
	tcu::Surface			resultSurface		(m_renderSize, m_renderSize);
	bool					error				= false;

	// Prepare draw
	gl.clearColor		(0.0f, 0.0f, 0.0f, 1.0f);
	gl.clear			(GL_COLOR_BUFFER_BIT);
	gl.viewport			(0, 0, m_renderSize, m_renderSize);
	gl.bindBuffer		(GL_ARRAY_BUFFER, m_arrayBuf);
	GLU_EXPECT_NO_ERROR	(gl.getError(), "setup draw");

	m_testCtx.getLog() << tcu::TestLog::Message << "Testing position invariance." << tcu::TestLog::EndMessage;

	// Draw position check passes
	for (int passNdx = 0; passNdx < 2; ++passNdx)
	{
		const glu::ShaderProgram&	shader		= (passNdx == 0) ? (*m_shader0) : (*m_shader1);
		const glw::GLint			positionLoc = gl.getAttribLocation(shader.getProgram(), "a_input");
		const glw::GLint			colorLoc	= gl.getUniformLocation(shader.getProgram(), "u_color");
		const tcu::Vec4				red			= tcu::Vec4(1.0f, 0.0f, 0.0f, 1.0f);
		const tcu::Vec4				green		= tcu::Vec4(0.0f, 1.0f, 0.0f, 1.0f);
		const tcu::Vec4				color		= (passNdx == 0) ? (red) : (green);
		const char* const			colorStr	= (passNdx == 0) ? ("red - purple") : ("green");

		m_testCtx.getLog() << tcu::TestLog::Message << "Drawing position test pattern using shader " << (passNdx+1) << ". Primitive color: " << colorStr << "." << tcu::TestLog::EndMessage;

		gl.useProgram				(shader.getProgram());
		gl.uniform4fv				(colorLoc, 1, color.getPtr());
		gl.enableVertexAttribArray	(positionLoc);
		gl.vertexAttribPointer		(positionLoc, 4, GL_FLOAT, GL_FALSE, sizeof(tcu::Vec4), DE_NULL);
		gl.drawArrays				(GL_TRIANGLES, 0, m_verticesInPattern);
		gl.disableVertexAttribArray	(positionLoc);
		GLU_EXPECT_NO_ERROR			(gl.getError(), "draw pass");
	}

	// Read result
	glu::readPixels(m_context.getRenderContext(), 0, 0, resultSurface.getAccess());

	// Check there are no red pixels
	m_testCtx.getLog() << tcu::TestLog::Message << "Verifying output. Expecting only green or background colored pixels." << tcu::TestLog::EndMessage;
	error |= !checkImage(resultSurface);

	if (!depthBufferExists)
	{
		m_testCtx.getLog() << tcu::TestLog::Message << "Depth buffer not available, skipping z-test." << tcu::TestLog::EndMessage;
	}
	else
	{
		// Test with Z-test
		gl.clearDepthf		(1.0f);
		gl.clear			(GL_COLOR_BUFFER_BIT | GL_DEPTH_BUFFER_BIT);
		gl.enable			(GL_DEPTH_TEST);

		m_testCtx.getLog() << tcu::TestLog::Message << "Testing position invariance with z-test. Enabling GL_DEPTH_TEST." << tcu::TestLog::EndMessage;

		// Draw position check passes
		for (int passNdx = 0; passNdx < 2; ++passNdx)
		{
			const glu::ShaderProgram&	shader			= (passNdx == 0) ? (*m_shader0) : (*m_shader1);
			const glw::GLint			positionLoc		= gl.getAttribLocation(shader.getProgram(), "a_input");
			const glw::GLint			colorLoc		= gl.getUniformLocation(shader.getProgram(), "u_color");
			const tcu::Vec4				red				= tcu::Vec4(1.0f, 0.0f, 0.0f, 1.0f);
			const tcu::Vec4				green			= tcu::Vec4(0.0f, 1.0f, 0.0f, 1.0f);
			const tcu::Vec4				color			= (passNdx == 0) ? (red) : (green);
			const glw::GLenum			depthFunc		= (passNdx == 0) ? (GL_ALWAYS) : (GL_EQUAL);
			const char* const			depthFuncStr	= (passNdx == 0) ? ("GL_ALWAYS") : ("GL_EQUAL");
			const char* const			colorStr		= (passNdx == 0) ? ("red - purple") : ("green");

			m_testCtx.getLog() << tcu::TestLog::Message << "Drawing Z-test pattern using shader " << (passNdx+1) << ". Primitive color: " << colorStr << ". DepthFunc: " << depthFuncStr << tcu::TestLog::EndMessage;

			gl.useProgram				(shader.getProgram());
			gl.uniform4fv				(colorLoc, 1, color.getPtr());
			gl.depthFunc				(depthFunc);
			gl.enableVertexAttribArray	(positionLoc);
			gl.vertexAttribPointer		(positionLoc, 4, GL_FLOAT, GL_FALSE, sizeof(tcu::Vec4), DE_NULL);
			gl.drawArrays				(GL_TRIANGLES, m_verticesInPattern, m_verticesInPattern); // !< buffer contains 2 m_verticesInPattern-sized patterns
			gl.disableVertexAttribArray	(positionLoc);
			GLU_EXPECT_NO_ERROR			(gl.getError(), "draw pass");
		}

		// Read result
		glu::readPixels(m_context.getRenderContext(), 0, 0, resultSurface.getAccess());

		// Check there are no red pixels
		m_testCtx.getLog() << tcu::TestLog::Message << "Verifying output. Expecting only green or background colored pixels." << tcu::TestLog::EndMessage;
		error |= !checkImage(resultSurface);
	}

	// Report result
	if (error)
		m_testCtx.setTestResult(QP_TEST_RESULT_FAIL, "Detected variance between two invariant values");
	else
		m_testCtx.setTestResult(QP_TEST_RESULT_PASS, "Pass");

	return STOP;
}

bool InvarianceTest::checkImage (const tcu::Surface& surface) const
{
	const tcu::IVec4	okColor		= tcu::IVec4(0, 255, 0, 255);
	const tcu::RGBA		errColor	= tcu::RGBA(255, 0, 0, 255);
	bool				error		= false;
	tcu::Surface		errorMask	(m_renderSize, m_renderSize);

	tcu::clear(errorMask.getAccess(), okColor);

	for (int y = 0; y < m_renderSize; ++y)
	for (int x = 0; x < m_renderSize; ++x)
	{
		const tcu::RGBA col = surface.getPixel(x, y);

		if (col.getRed() != 0)
		{
			errorMask.setPixel(x, y, errColor);
			error = true;
		}
	}

	// report error
	if (error)
	{
		m_testCtx.getLog() << tcu::TestLog::Message << "Invalid pixels found (fragments from first render pass found). Variance detected." << tcu::TestLog::EndMessage;
		m_testCtx.getLog()
			<< tcu::TestLog::ImageSet("Results", "Result verification")
			<< tcu::TestLog::Image("Result",		"Result",		surface)
			<< tcu::TestLog::Image("Error mask",	"Error mask",	errorMask)
			<< tcu::TestLog::EndImageSet;

		return false;
	}
	else
	{
		m_testCtx.getLog() << tcu::TestLog::Message << "No variance found." << tcu::TestLog::EndMessage;
		m_testCtx.getLog()
			<< tcu::TestLog::ImageSet("Results", "Result verification")
			<< tcu::TestLog::Image("Result", "Result", surface)
			<< tcu::TestLog::EndImageSet;

		return true;
	}
}

class BasicInvarianceTest : public InvarianceTest
{
public:
								BasicInvarianceTest		(Context& ctx, const char* name, const char* desc, const std::string& vertexShader1, const std::string& vertexShader2);
								BasicInvarianceTest		(Context& ctx, const char* name, const char* desc, const std::string& vertexShader1, const std::string& vertexShader2, const std::string& fragmentShader);
	ShaderPair					genShaders				(void) const;

private:
	const std::string			m_vertexShader1;
	const std::string			m_vertexShader2;
	const std::string			m_fragmentShader;
	static const char* const	s_basicFragmentShader;
};

const char* const BasicInvarianceTest::s_basicFragmentShader =	"uniform mediump vec4 u_color;\n"
																"varying mediump vec4 v_unrelated;\n"
																"void main ()\n"
																"{\n"
																"	mediump float blue = dot(v_unrelated, vec4(1.0, 1.0, 1.0, 1.0));\n"
																"	gl_FragColor = vec4(u_color.r, u_color.g, blue, u_color.a);\n"
																"}\n";

BasicInvarianceTest::BasicInvarianceTest (Context& ctx, const char* name, const char* desc, const std::string& vertexShader1, const std::string& vertexShader2)
	: InvarianceTest	(ctx, name, desc)
	, m_vertexShader1	(vertexShader1)
	, m_vertexShader2	(vertexShader2)
	, m_fragmentShader	(s_basicFragmentShader)
{
}

BasicInvarianceTest::BasicInvarianceTest (Context& ctx, const char* name, const char* desc, const std::string& vertexShader1, const std::string& vertexShader2, const std::string& fragmentShader)
	: InvarianceTest	(ctx, name, desc)
	, m_vertexShader1	(vertexShader1)
	, m_vertexShader2	(vertexShader2)
	, m_fragmentShader	(fragmentShader)
{
}

BasicInvarianceTest::ShaderPair BasicInvarianceTest::genShaders (void) const
{
	ShaderPair retVal;

	retVal.vertexShaderSource0 = m_vertexShader1;
	retVal.vertexShaderSource1 = m_vertexShader2;
	retVal.fragmentShaderSource0 = m_fragmentShader;
	retVal.fragmentShaderSource1 = m_fragmentShader;

	return retVal;
}

} // anonymous

ShaderInvarianceTests::ShaderInvarianceTests (Context& context)
	: TestCaseGroup(context, "invariance", "Invariance tests")
{
}

ShaderInvarianceTests::~ShaderInvarianceTests (void)
{
}

void ShaderInvarianceTests::init (void)
{
	static const struct PrecisionCase
	{
		glu::Precision	prec;
		const char*		name;

		// set literals in the glsl to be in the representable range
		const char*		highValue;		// !< highValue < maxValue
		const char*		invHighValue;
		const char*		mediumValue;	// !< mediumValue^2 < maxValue
		const char*		lowValue;		// !< lowValue^4 < maxValue
		const char*		invlowValue;
		int				loopIterations;
		int				loopPartialIterations;
		int				loopNormalizationExponent;
		const char*		loopNormalizationConstantLiteral;
		const char*		loopMultiplier;
		const char*		sumLoopNormalizationConstantLiteral;
	} precisions[] =
	{
		{ glu::PRECISION_HIGHP,		"highp",	"1.0e20",	"1.0e-20",	"1.0e14",	"1.0e9",	"1.0e-9",	14,	11,	2,	"1.0e4",	"1.9",	"1.0e3"	},
		{ glu::PRECISION_MEDIUMP,	"mediump",	"1.0e4",	"1.0e-4",	"1.0e2",	"1.0e1",	"1.0e-1",	13,	11,	2,	"1.0e4",	"1.9",	"1.0e3"	},
		{ glu::PRECISION_LOWP,		"lowp",		"0.9",		"1.1",		"1.1",		"1.15",		"0.87",		6,	2,	0,	"2.0",		"1.1",	"1.0"	},
	};

	for (int precNdx = 0; precNdx < DE_LENGTH_OF_ARRAY(precisions); ++precNdx)
	{
		const char* const			precisionName	= precisions[precNdx].name;
		const glu::Precision		precision		= precisions[precNdx].prec;
		tcu::TestCaseGroup* const	group			= new tcu::TestCaseGroup(m_testCtx, precisionName, "Invariance tests using the given precision.");

		const FormatArgumentList	args			= FormatArgumentList()
														<< FormatArgument("VERSION",				"")
														<< FormatArgument("IN",						"attribute")
														<< FormatArgument("OUT",					"varying")
														<< FormatArgument("IN_PREC",				precisionName)
														<< FormatArgument("HIGH_VALUE",				de::toString(precisions[precNdx].highValue))
														<< FormatArgument("HIGH_VALUE_INV",			de::toString(precisions[precNdx].invHighValue))
														<< FormatArgument("MEDIUM_VALUE",			de::toString(precisions[precNdx].mediumValue))
														<< FormatArgument("LOW_VALUE",				de::toString(precisions[precNdx].lowValue))
														<< FormatArgument("LOW_VALUE_INV",			de::toString(precisions[precNdx].invlowValue))
														<< FormatArgument("LOOP_ITERS",				de::toString(precisions[precNdx].loopIterations))
														<< FormatArgument("LOOP_ITERS_PARTIAL",		de::toString(precisions[precNdx].loopPartialIterations))
														<< FormatArgument("LOOP_NORM_FRACT_EXP",	de::toString(precisions[precNdx].loopNormalizationExponent))
														<< FormatArgument("LOOP_NORM_LITERAL",		precisions[precNdx].loopNormalizationConstantLiteral)
														<< FormatArgument("LOOP_MULTIPLIER",		precisions[precNdx].loopMultiplier)
														<< FormatArgument("SUM_LOOP_NORM_LITERAL",	precisions[precNdx].sumLoopNormalizationConstantLiteral);

		addChild(group);

		// subexpression cases
		{
			// First shader shares "${HIGH_VALUE}*a_input.x*a_input.xxxx + ${HIGH_VALUE}*a_input.y*a_input.yyyy" with unrelated output variable. Reordering might result in accuracy loss
			// due to the high exponent. In the second shader, the high exponent may be removed during compilation.

			group->addChild(new BasicInvarianceTest(m_context, "common_subexpression_0", "Shader shares a subexpression with an unrelated variable.",
				formatGLSL(	"${VERSION}"
							"${IN} ${IN_PREC} vec4 a_input;\n"
							"${OUT} mediump vec4 v_unrelated;\n"
							"invariant gl_Position;\n"
							"void main ()\n"
							"{\n"
							"	v_unrelated = a_input.xzxz + (${HIGH_VALUE}*a_input.x*a_input.xxxx + ${HIGH_VALUE}*a_input.y*a_input.yyyy) * (1.08 * a_input.zyzy * a_input.xzxz) * ${HIGH_VALUE_INV} * (a_input.z * a_input.zzxz - a_input.z * a_input.zzxz) + (${HIGH_VALUE}*a_input.x*a_input.xxxx + ${HIGH_VALUE}*a_input.y*a_input.yyyy) / ${HIGH_VALUE};\n"
							"	gl_Position = a_input + (${HIGH_VALUE}*a_input.x*a_input.xxxx + ${HIGH_VALUE}*a_input.y*a_input.yyyy) * ${HIGH_VALUE_INV};\n"
							"}\n", args),
				formatGLSL(	"${VERSION}"
							"${IN} ${IN_PREC} vec4 a_input;\n"
							"${OUT} mediump vec4 v_unrelated;\n"
							"invariant gl_Position;\n"
							"void main ()\n"
							"{\n"
							"	v_unrelated = vec4(0.0, 0.0, 0.0, 0.0);\n"
							"	gl_Position = a_input + (${HIGH_VALUE}*a_input.x*a_input.xxxx + ${HIGH_VALUE}*a_input.y*a_input.yyyy) * ${HIGH_VALUE_INV};\n"
							"}\n", args)));

			// In the first shader, the unrelated variable "d" has mathematically the same expression as "e", but the different
			// order of calculation might cause different results.

			group->addChild(new BasicInvarianceTest(m_context, "common_subexpression_1", "Shader shares a subexpression with an unrelated variable.",
				formatGLSL(	"${VERSION}"
							"${IN} ${IN_PREC} vec4 a_input;\n"
							"${OUT} mediump vec4 v_unrelated;\n"
							"invariant gl_Position;\n"
							"void main ()\n"
							"{\n"
							"	${IN_PREC} vec4 a = ${HIGH_VALUE} * a_input.zzxx + a_input.xzxy - ${HIGH_VALUE} * a_input.zzxx;\n"
							"	${IN_PREC} vec4 b = ${HIGH_VALUE} * a_input.zzxx;\n"
							"	${IN_PREC} vec4 c = b - ${HIGH_VALUE} * a_input.zzxx + a_input.xzxy;\n"
							"	${IN_PREC} vec4 d = (${LOW_VALUE} * a_input.yzxx) * (${LOW_VALUE} * a_input.yzzw) * (1.1*${LOW_VALUE_INV} * a_input.yzxx) * (${LOW_VALUE_INV} * a_input.xzzy);\n"
							"	${IN_PREC} vec4 e = ((${LOW_VALUE} * a_input.yzxx) * (1.1*${LOW_VALUE_INV} * a_input.yzxx)) * ((${LOW_VALUE_INV} * a_input.xzzy) * (${LOW_VALUE} * a_input.yzzw));\n"
							"	v_unrelated = a + b + c + d + e;\n"
							"	gl_Position = a_input + fract(c) + e;\n"
							"}\n", args),
				formatGLSL(	"${VERSION}"
							"${IN} ${IN_PREC} vec4 a_input;\n"
							"${OUT} mediump vec4 v_unrelated;\n"
							"invariant gl_Position;\n"
							"void main ()\n"
							"{\n"
							"	${IN_PREC} vec4 b = ${HIGH_VALUE} * a_input.zzxx;\n"
							"	${IN_PREC} vec4 c = b - ${HIGH_VALUE} * a_input.zzxx + a_input.xzxy;\n"
							"	${IN_PREC} vec4 e = ((${LOW_VALUE} * a_input.yzxx) * (1.1*${LOW_VALUE_INV} * a_input.yzxx)) * ((${LOW_VALUE_INV} * a_input.xzzy) * (${LOW_VALUE} * a_input.yzzw));\n"
							"	v_unrelated = vec4(0.0, 0.0, 0.0, 0.0);\n"
							"	gl_Position = a_input + fract(c) + e;\n"
							"}\n", args)));

			// Intermediate values used by an unrelated output variable

			group->addChild(new BasicInvarianceTest(m_context, "common_subexpression_2", "Shader shares a subexpression with an unrelated variable.",
				formatGLSL(	"${VERSION}"
							"${IN} ${IN_PREC} vec4 a_input;\n"
							"${OUT} mediump vec4 v_unrelated;\n"
							"invariant gl_Position;\n"
							"void main ()\n"
							"{\n"
							"	${IN_PREC} vec4 a = ${MEDIUM_VALUE} * (a_input.xxxx + a_input.yyyy);\n"
							"	${IN_PREC} vec4 b = (${MEDIUM_VALUE} * (a_input.xxxx + a_input.yyyy)) * (${MEDIUM_VALUE} * (a_input.xxxx + a_input.yyyy)) / ${MEDIUM_VALUE} / ${MEDIUM_VALUE};\n"
							"	${IN_PREC} vec4 c = a * a;\n"
							"	${IN_PREC} vec4 d = c / ${MEDIUM_VALUE} / ${MEDIUM_VALUE};\n"
							"	v_unrelated = a + b + c + d;\n"
							"	gl_Position = a_input + d;\n"
							"}\n", args),
				formatGLSL(	"${VERSION}"
							"${IN} ${IN_PREC} vec4 a_input;\n"
							"${OUT} mediump vec4 v_unrelated;\n"
							"invariant gl_Position;\n"
							"void main ()\n"
							"{\n"
							"	${IN_PREC} vec4 a = ${MEDIUM_VALUE} * (a_input.xxxx + a_input.yyyy);\n"
							"	${IN_PREC} vec4 c = a * a;\n"
							"	${IN_PREC} vec4 d = c / ${MEDIUM_VALUE} / ${MEDIUM_VALUE};\n"
							"	v_unrelated = vec4(0.0, 0.0, 0.0, 0.0);\n"
							"	gl_Position = a_input + d;\n"
							"}\n", args)));

			// Invariant value can be calculated using unrelated value

			group->addChild(new BasicInvarianceTest(m_context, "common_subexpression_3", "Shader shares a subexpression with an unrelated variable.",
				formatGLSL(	"${VERSION}"
							"${IN} ${IN_PREC} vec4 a_input;\n"
							"${OUT} mediump vec4 v_unrelated;\n"
							"invariant gl_Position;\n"
							"void main ()\n"
							"{\n"
							"	${IN_PREC} float x = a_input.x * 0.2;\n"
							"	${IN_PREC} vec4 a = a_input.xxyx * 0.7;\n"
							"	${IN_PREC} vec4 b = a_input.yxyz * 0.7;\n"
							"	${IN_PREC} vec4 c = a_input.zxyx * 0.5;\n"
							"	${IN_PREC} vec4 f = x*a + x*b + x*c;\n"
							"	v_unrelated = f;\n"
							"	${IN_PREC} vec4 g = x * (a + b + c);\n"
							"	gl_Position = a_input + g;\n"
							"}\n", args),
				formatGLSL(	"${VERSION}"
							"${IN} ${IN_PREC} vec4 a_input;\n"
							"${OUT} mediump vec4 v_unrelated;\n"
							"invariant gl_Position;\n"
							"void main ()\n"
							"{\n"
							"	${IN_PREC} float x = a_input.x * 0.2;\n"
							"	${IN_PREC} vec4 a = a_input.xxyx * 0.7;\n"
							"	${IN_PREC} vec4 b = a_input.yxyz * 0.7;\n"
							"	${IN_PREC} vec4 c = a_input.zxyx * 0.5;\n"
							"	v_unrelated = vec4(0.0, 0.0, 0.0, 0.0);\n"
							"	${IN_PREC} vec4 g = x * (a + b + c);\n"
							"	gl_Position = a_input + g;\n"
							"}\n", args)));
		}

		// shared subexpression of different precision
		{
			for (int precisionOther = glu::PRECISION_LOWP; precisionOther != glu::PRECISION_LAST; ++precisionOther)
			{
				const char* const		unrelatedPrec				= glu::getPrecisionName((glu::Precision)precisionOther);
				const glu::Precision	minPrecision				= (precisionOther < (int)precision) ? ((glu::Precision)precisionOther) : (precision);
				const char* const		multiplierStr				= (minPrecision == glu::PRECISION_LOWP) ? ("0.8, 0.4, -0.2, 0.3") : ("1.0e1, 5.0e2, 2.0e2, 1.0");
				const char* const		normalizationStrUsed		= (minPrecision == glu::PRECISION_LOWP) ? ("vec4(fract(used2).xyz, 0.0)") : ("vec4(fract(used2 / 1.0e2).xyz - fract(used2 / 1.0e3).xyz, 0.0)");
				const char* const		normalizationStrUnrelated	= (minPrecision == glu::PRECISION_LOWP) ? ("vec4(fract(unrelated2).xyz, 0.0)") : ("vec4(fract(unrelated2 / 1.0e2).xyz - fract(unrelated2 / 1.0e3).xyz, 0.0)");

				group->addChild(new BasicInvarianceTest(m_context, ("subexpression_precision_" + std::string(unrelatedPrec)).c_str(), "Shader shares subexpression of different precision with an unrelated variable.",
					formatGLSL(	"${VERSION}"
								"${IN} ${IN_PREC} vec4 a_input;\n"
								"${OUT} ${UNRELATED_PREC} vec4 v_unrelated;\n"
								"invariant gl_Position;\n"
								"void main ()\n"
								"{\n"
								"	${UNRELATED_PREC} vec4 unrelated0 = a_input + vec4(0.1, 0.2, 0.3, 0.4);\n"
								"	${UNRELATED_PREC} vec4 unrelated1 = vec4(${MULTIPLIER}) * unrelated0.xywz + unrelated0;\n"
								"	${UNRELATED_PREC} vec4 unrelated2 = refract(unrelated1, unrelated0, distance(unrelated0, unrelated1));\n"
								"	v_unrelated = a_input + 0.02 * ${NORMALIZE_UNRELATED};\n"
								"	${IN_PREC} vec4 used0 = a_input + vec4(0.1, 0.2, 0.3, 0.4);\n"
								"	${IN_PREC} vec4 used1 = vec4(${MULTIPLIER}) * used0.xywz + used0;\n"
								"	${IN_PREC} vec4 used2 = refract(used1, used0, distance(used0, used1));\n"
								"	gl_Position = a_input + 0.02 * ${NORMALIZE_USED};\n"
								"}\n", FormatArgumentList(args)
											<< FormatArgument("UNRELATED_PREC",			unrelatedPrec)
											<< FormatArgument("MULTIPLIER",				multiplierStr)
											<< FormatArgument("NORMALIZE_USED",			normalizationStrUsed)
											<< FormatArgument("NORMALIZE_UNRELATED",	normalizationStrUnrelated)),
					formatGLSL(	"${VERSION}"
								"${IN} ${IN_PREC} vec4 a_input;\n"
								"${OUT} ${UNRELATED_PREC} vec4 v_unrelated;\n"
								"invariant gl_Position;\n"
								"void main ()\n"
								"{\n"
								"	v_unrelated = vec4(0.0, 0.0, 0.0, 0.0);\n"
								"	${IN_PREC} vec4 used0 = a_input + vec4(0.1, 0.2, 0.3, 0.4);\n"
								"	${IN_PREC} vec4 used1 = vec4(${MULTIPLIER}) * used0.xywz + used0;\n"
								"	${IN_PREC} vec4 used2 = refract(used1, used0, distance(used0, used1));\n"
								"	gl_Position = a_input + 0.02 * ${NORMALIZE_USED};\n"
								"}\n", FormatArgumentList(args)
											<< FormatArgument("UNRELATED_PREC",			unrelatedPrec)
											<< FormatArgument("MULTIPLIER",				multiplierStr)
											<< FormatArgument("NORMALIZE_USED",			normalizationStrUsed)
											<< FormatArgument("NORMALIZE_UNRELATED",	normalizationStrUnrelated))));
			}
		}

		// loops
		{
			group->addChild(new BasicInvarianceTest(m_context, "loop_0", "Invariant value set using a loop",
				formatGLSL(	"${VERSION}"
							"${IN} ${IN_PREC} vec4 a_input;\n"
							"${OUT} highp vec4 v_unrelated;\n"
							"invariant gl_Position;\n"
							"void main ()\n"
							"{\n"
							"	${IN_PREC} vec4 value = a_input;\n"
							"	v_unrelated = vec4(0.0, 0.0, 0.0, 0.0);\n"
							"	for (mediump int i = 0; i < ${LOOP_ITERS}; ++i)\n"
							"	{\n"
							"		value *= ${LOOP_MULTIPLIER};\n"
							"		v_unrelated += value;\n"
							"	}\n"
							"	gl_Position = vec4(value.xyz / ${LOOP_NORM_LITERAL} + a_input.xyz * 0.1, 1.0);\n"
							"}\n", args),
				formatGLSL(	"${VERSION}"
							"${IN} ${IN_PREC} vec4 a_input;\n"
							"${OUT} highp vec4 v_unrelated;\n"
							"invariant gl_Position;\n"
							"void main ()\n"
							"{\n"
							"	${IN_PREC} vec4 value = a_input;\n"
							"	v_unrelated = vec4(0.0, 0.0, 0.0, 0.0);\n"
							"	for (mediump int i = 0; i < ${LOOP_ITERS}; ++i)\n"
							"	{\n"
							"		value *= ${LOOP_MULTIPLIER};\n"
							"	}\n"
							"	gl_Position = vec4(value.xyz / ${LOOP_NORM_LITERAL} + a_input.xyz * 0.1, 1.0);\n"
							"}\n", args)));

			group->addChild(new BasicInvarianceTest(m_context, "loop_1", "Invariant value set using a loop",
				formatGLSL(	"${VERSION}"
							"${IN} ${IN_PREC} vec4 a_input;\n"
							"${OUT} mediump vec4 v_unrelated;\n"
							"invariant gl_Position;\n"
							"void main ()\n"
							"{\n"
							"	${IN_PREC} vec4 value = a_input;\n"
							"	for (mediump int i = 0; i < ${LOOP_ITERS}; ++i)\n"
							"	{\n"
							"		value *= ${LOOP_MULTIPLIER};\n"
							"		if (i == ${LOOP_ITERS_PARTIAL})\n"
							"			v_unrelated = value;\n"
							"	}\n"
							"	gl_Position = vec4(value.xyz / ${LOOP_NORM_LITERAL} + a_input.xyz * 0.1, 1.0);\n"
							"}\n", args),
				formatGLSL(	"${VERSION}"
							"${IN} ${IN_PREC} vec4 a_input;\n"
							"${OUT} mediump vec4 v_unrelated;\n"
							"invariant gl_Position;\n"
							"void main ()\n"
							"{\n"
							"	${IN_PREC} vec4 value = a_input;\n"
							"	v_unrelated = vec4(0.0, 0.0, 0.0, 0.0);\n"
							"	for (mediump int i = 0; i < ${LOOP_ITERS}; ++i)\n"
							"	{\n"
							"		value *= ${LOOP_MULTIPLIER};\n"
							"	}\n"
							"	gl_Position = vec4(value.xyz / ${LOOP_NORM_LITERAL} + a_input.xyz * 0.1, 1.0);\n"
							"}\n", args)));

			group->addChild(new BasicInvarianceTest(m_context, "loop_2", "Invariant value set using a loop",
				formatGLSL(	"${VERSION}"
							"${IN} ${IN_PREC} vec4 a_input;\n"
							"${OUT} mediump vec4 v_unrelated;\n"
							"invariant gl_Position;\n"
							"void main ()\n"
							"{\n"
							"	${IN_PREC} vec4 value = a_input;\n"
							"	v_unrelated = vec4(0.0, 0.0, -1.0, 1.0);\n"
							"	for (mediump int i = 0; i < ${LOOP_ITERS}; ++i)\n"
							"	{\n"
							"		value *= ${LOOP_MULTIPLIER};\n"
							"		if (i == ${LOOP_ITERS_PARTIAL})\n"
							"			gl_Position = a_input + 0.05 * vec4(fract(value.xyz / 1.0e${LOOP_NORM_FRACT_EXP}), 1.0);\n"
							"		else\n"
							"			v_unrelated = value + a_input;\n"
							"	}\n"
							"}\n", args),
				formatGLSL(	"${VERSION}"
							"${IN} ${IN_PREC} vec4 a_input;\n"
							"${OUT} mediump vec4 v_unrelated;\n"
							"invariant gl_Position;\n"
							"void main ()\n"
							"{\n"
							"	${IN_PREC} vec4 value = a_input;\n"
							"	v_unrelated = vec4(0.0, 0.0, -1.0, 1.0);\n"
							"	for (mediump int i = 0; i < ${LOOP_ITERS}; ++i)\n"
							"	{\n"
							"		value *= ${LOOP_MULTIPLIER};\n"
							"		if (i == ${LOOP_ITERS_PARTIAL})\n"
							"			gl_Position = a_input + 0.05 * vec4(fract(value.xyz / 1.0e${LOOP_NORM_FRACT_EXP}), 1.0);\n"
							"		else\n"
							"			v_unrelated = vec4(0.0, 0.0, 0.0, 0.0);\n"
							"	}\n"
							"}\n", args)));

			group->addChild(new BasicInvarianceTest(m_context, "loop_3", "Invariant value set using a loop",
				formatGLSL(	"${VERSION}"
							"${IN} ${IN_PREC} vec4 a_input;\n"
							"${OUT} mediump vec4 v_unrelated;\n"
							"invariant gl_Position;\n"
							"void main ()\n"
							"{\n"
							"	${IN_PREC} vec4 value = a_input;\n"
							"	gl_Position = vec4(0.0, 0.0, 0.0, 0.0);\n"
							"	v_unrelated = vec4(0.0, 0.0, 0.0, 0.0);\n"
							"	for (mediump int i = 0; i < ${LOOP_ITERS}; ++i)\n"
							"	{\n"
							"		value *= ${LOOP_MULTIPLIER};\n"
							"		gl_Position += vec4(value.xyz / ${SUM_LOOP_NORM_LITERAL} + a_input.xyz * 0.1, 1.0);\n"
							"		v_unrelated = gl_Position.xyzx * a_input;\n"
							"	}\n"
							"}\n", args),
				formatGLSL(	"${VERSION}"
							"${IN} ${IN_PREC} vec4 a_input;\n"
							"${OUT} mediump vec4 v_unrelated;\n"
							"invariant gl_Position;\n"
							"void main ()\n"
							"{\n"
							"	${IN_PREC} vec4 value = a_input;\n"
							"	gl_Position = vec4(0.0, 0.0, 0.0, 0.0);\n"
							"	v_unrelated = vec4(0.0, 0.0, 0.0, 0.0);\n"
							"	for (mediump int i = 0; i < ${LOOP_ITERS}; ++i)\n"
							"	{\n"
							"		value *= ${LOOP_MULTIPLIER};\n"
							"		gl_Position += vec4(value.xyz / ${SUM_LOOP_NORM_LITERAL} + a_input.xyz * 0.1, 1.0);\n"
							"	}\n"
							"}\n", args)));

			group->addChild(new BasicInvarianceTest(m_context, "loop_4", "Invariant value set using a loop",
				formatGLSL(	"${VERSION}"
							"${IN} ${IN_PREC} vec4 a_input;\n"
							"${OUT} mediump vec4 v_unrelated;\n"
							"invariant gl_Position;\n"
							"void main ()\n"
							"{\n"
							"	${IN_PREC} vec4 position = vec4(0.0, 0.0, 0.0, 0.0);\n"
							"	${IN_PREC} vec4 value1 = a_input;\n"
							"	${IN_PREC} vec4 value2 = a_input;\n"
							"	v_unrelated = vec4(0.0, 0.0, 0.0, 0.0);\n"
							"	for (mediump int i = 0; i < ${LOOP_ITERS}; ++i)\n"
							"	{\n"
							"		value1 *= ${LOOP_MULTIPLIER};\n"
							"		v_unrelated = v_unrelated*1.3 + a_input.xyzx * value1.xyxw;\n"
							"	}\n"
							"	for (mediump int i = 0; i < ${LOOP_ITERS}; ++i)\n"
							"	{\n"
							"		value2 *= ${LOOP_MULTIPLIER};\n"
							"		position = position*1.3 + a_input.xyzx * value2.xyxw;\n"
							"	}\n"
							"	gl_Position = a_input + 0.05 * vec4(fract(position.xyz / 1.0e${LOOP_NORM_FRACT_EXP}), 1.0);\n"
							"}\n", args),
				formatGLSL(	"${VERSION}"
							"${IN} ${IN_PREC} vec4 a_input;\n"
							"${OUT} mediump vec4 v_unrelated;\n"
							"invariant gl_Position;\n"
							"void main ()\n"
							"{\n"
							"	${IN_PREC} vec4 position = vec4(0.0, 0.0, 0.0, 0.0);\n"
							"	${IN_PREC} vec4 value2 = a_input;\n"
							"	v_unrelated = vec4(0.0, 0.0, 0.0, 0.0);\n"
							"	for (mediump int i = 0; i < ${LOOP_ITERS}; ++i)\n"
							"	{\n"
							"		value2 *= ${LOOP_MULTIPLIER};\n"
							"		position = position*1.3 + a_input.xyzx * value2.xyxw;\n"
							"	}\n"
							"	gl_Position = a_input + 0.05 * vec4(fract(position.xyz / 1.0e${LOOP_NORM_FRACT_EXP}), 1.0);\n"
							"}\n", args)));
		}
	}
}

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