modules/gles2/accuracy/es2aVaryingInterpolationTests.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 Varying interpolation accuracy tests.
  *//*--------------------------------------------------------------------*/

 #include "es2aVaryingInterpolationTests.hpp"
 #include "gluPixelTransfer.hpp"
 #include "gluShaderProgram.hpp"
 #include "gluShaderUtil.hpp"
 #include "tcuStringTemplate.hpp"
 #include "gluContextInfo.hpp"
 #include "glsTextureTestUtil.hpp"
 #include "tcuVector.hpp"
 #include "tcuVectorUtil.hpp"
 #include "tcuTestLog.hpp"
 #include "tcuFloat.hpp"
 #include "tcuImageCompare.hpp"
 #include "tcuRenderTarget.hpp"
 #include "tcuSurfaceAccess.hpp"
 #include "deRandom.hpp"
 #include "deStringUtil.hpp"
 #include "deString.h"

 #include "glw.h"

 using tcu::TestLog;
 using tcu::Vec3;
 using tcu::Vec4;
 using std::string;
 using std::vector;
 using std::map;
 using tcu::SurfaceAccess;

 namespace deqp
 {
 namespace gles2
 {
 namespace Accuracy
 {

 static inline float projectedTriInterpolate (const tcu::Vec3& s, const tcu::Vec3& w, float nx, float ny)
 {
 	return (s[0]*(1.0f-nx-ny)/w[0] + s[1]*ny/w[1] + s[2]*nx/w[2]) / ((1.0f-nx-ny)/w[0] + ny/w[1] + nx/w[2]);
 }

 static void renderReference (const SurfaceAccess& dst, const float coords[4*3], const Vec4& wCoord, const Vec3& scale, const Vec3& bias)
 {
 	float		dstW		= (float)dst.getWidth();
 	float		dstH		= (float)dst.getHeight();

 	Vec3		triR[2]		= { Vec3(coords[0*3+0], coords[1*3+0], coords[2*3+0]), Vec3(coords[3*3+0], coords[2*3+0], coords[1*3+0]) };
 	Vec3		triG[2]		= { Vec3(coords[0*3+1], coords[1*3+1], coords[2*3+1]), Vec3(coords[3*3+1], coords[2*3+1], coords[1*3+1]) };
 	Vec3		triB[2]		= { Vec3(coords[0*3+2], coords[1*3+2], coords[2*3+2]), Vec3(coords[3*3+2], coords[2*3+2], coords[1*3+2]) };
 	tcu::Vec3	triW[2]		= { wCoord.swizzle(0, 1, 2), wCoord.swizzle(3, 2, 1) };

 	for (int py = 0; py < dst.getHeight(); py++)
 	{
 		for (int px = 0; px < dst.getWidth(); px++)
 		{
 			float	wx		= (float)px + 0.5f;
 			float	wy		= (float)py + 0.5f;
 			float	nx		= wx / dstW;
 			float	ny		= wy / dstH;

 			int		triNdx	= nx + ny >= 1.0f ? 1 : 0;
 			float	triNx	= triNdx ? 1.0f - nx : nx;
 			float	triNy	= triNdx ? 1.0f - ny : ny;

 			float	r		= projectedTriInterpolate(triR[triNdx], triW[triNdx], triNx, triNy) * scale[0] + bias[0];
 			float	g		= projectedTriInterpolate(triG[triNdx], triW[triNdx], triNx, triNy) * scale[1] + bias[1];
 			float	b		= projectedTriInterpolate(triB[triNdx], triW[triNdx], triNx, triNy) * scale[2] + bias[2];

 			Vec4	color	= Vec4(r, g, b, 1.0f);

 			dst.setPixel(color, px, py);
 		}
 	}
 }

 class InterpolationCase : public TestCase
 {
 public:
 					InterpolationCase			(Context& context, const char* name, const char* desc, glu::Precision precision, const tcu::Vec3& minVal, const tcu::Vec3& maxVal, bool projective);
 					~InterpolationCase			(void);

 	IterateResult	iterate						(void);

 private:
 	glu::Precision	m_precision;
 	tcu::Vec3		m_min;
 	tcu::Vec3		m_max;
 	bool			m_projective;
 };

 InterpolationCase::InterpolationCase (Context& context, const char* name, const char* desc, glu::Precision precision, const tcu::Vec3& minVal, const tcu::Vec3& maxVal, bool projective)
 	: TestCase		(context, tcu::NODETYPE_ACCURACY, name, desc)
 	, m_precision	(precision)
 	, m_min			(minVal)
 	, m_max			(maxVal)
 	, m_projective	(projective)
 {
 }

 InterpolationCase::~InterpolationCase (void)
 {
 }

 static bool isValidFloat (glu::Precision precision, float val)
 {
 	if (precision == glu::PRECISION_MEDIUMP)
 	{
 		tcu::Float16 fp16(val);
 		return !fp16.isDenorm() && !fp16.isInf() && !fp16.isNaN();
 	}
 	else
 	{
 		tcu::Float32 fp32(val);
 		return !fp32.isDenorm() && !fp32.isInf() && !fp32.isNaN();
 	}
 }

 template <int Size>
 static bool isValidFloatVec (glu::Precision precision, const tcu::Vector<float, Size>& vec)
 {
 	for (int ndx = 0; ndx < Size; ndx++)
 	{
 		if (!isValidFloat(precision, vec[ndx]))
 			return false;
 	}
 	return true;
 }

 InterpolationCase::IterateResult InterpolationCase::iterate (void)
 {
 	TestLog&		log				= m_testCtx.getLog();
 	de::Random		rnd				(deStringHash(getName()));
 	int				viewportWidth	= 128;
 	int				viewportHeight	= 128;

 	if (m_context.getRenderTarget().getWidth() < viewportWidth ||
 		m_context.getRenderTarget().getHeight() < viewportHeight)
 		throw tcu::NotSupportedError("Too small viewport", "", __FILE__, __LINE__);

 	int				viewportX		= rnd.getInt(0, m_context.getRenderTarget().getWidth()	- viewportWidth);
 	int				viewportY		= rnd.getInt(0, m_context.getRenderTarget().getHeight()	- viewportHeight);

 	static const char* s_vertShaderTemplate =
 		"attribute highp vec4 a_position;\n"
 		"attribute ${PRECISION} vec3 a_coords;\n"
 		"varying ${PRECISION} vec3 v_coords;\n"
 		"\n"
 		"void main (void)\n"
 		"{\n"
 		"	gl_Position = a_position;\n"
 		"	v_coords = a_coords;\n"
 		"}\n";
 	static const char* s_fragShaderTemplate =
 		"varying ${PRECISION} vec3 v_coords;\n"
 		"uniform ${PRECISION} vec3 u_scale;\n"
 		"uniform ${PRECISION} vec3 u_bias;\n"
 		"\n"
 		"void main (void)\n"
 		"{\n"
 		"	gl_FragColor = vec4(v_coords * u_scale + u_bias, 1.0);\n"
 		"}\n";

 	map<string, string> templateParams;
 	templateParams["PRECISION"] = glu::getPrecisionName(m_precision);

 	glu::ShaderProgram program(m_context.getRenderContext(),
 							   glu::makeVtxFragSources(tcu::StringTemplate(s_vertShaderTemplate).specialize(templateParams),
 													   tcu::StringTemplate(s_fragShaderTemplate).specialize(templateParams)));
 	log << program;
 	if (!program.isOk())
 	{
 		if (m_precision == glu::PRECISION_HIGHP && !m_context.getContextInfo().isFragmentHighPrecisionSupported())
 			m_testCtx.setTestResult(QP_TEST_RESULT_NOT_SUPPORTED, "Fragment highp not supported");
 		else
 			m_testCtx.setTestResult(QP_TEST_RESULT_FAIL, "Compile failed");
 		return STOP;
 	}

 	// Position coordinates.
 	Vec4 wCoord = m_projective ? Vec4(1.3f, 0.8f, 0.6f, 2.0f) : Vec4(1.0f, 1.0f, 1.0f, 1.0f);
 	float positions[] =
 	{
 		-1.0f*wCoord.x(), -1.0f*wCoord.x(), 0.0f, wCoord.x(),
 		-1.0f*wCoord.y(), +1.0f*wCoord.y(), 0.0f, wCoord.y(),
 		+1.0f*wCoord.z(), -1.0f*wCoord.z(), 0.0f, wCoord.z(),
 		+1.0f*wCoord.w(), +1.0f*wCoord.w(), 0.0f, wCoord.w()
 	};

 	// Coordinates for interpolation.
 	tcu::Vec3 scale	= 1.0f / (m_max - m_min);
 	tcu::Vec3 bias	= -1.0f*m_min*scale;
 	float coords[] =
 	{
 		(0.0f - bias[0])/scale[0], (0.5f - bias[1])/scale[1], (1.0f - bias[2])/scale[2],
 		(0.5f - bias[0])/scale[0], (1.0f - bias[1])/scale[1], (0.5f - bias[2])/scale[2],
 		(0.5f - bias[0])/scale[0], (0.0f - bias[1])/scale[1], (0.5f - bias[2])/scale[2],
 		(1.0f - bias[0])/scale[0], (0.5f - bias[1])/scale[1], (0.0f - bias[2])/scale[2]
 	};

 	log << TestLog::Message << "a_coords = " << ((tcu::Vec3(0.0f) - bias)/scale) << " -> " << ((tcu::Vec3(1.0f) - bias)/scale) << TestLog::EndMessage;
 	log << TestLog::Message << "u_scale = " << scale << TestLog::EndMessage;
 	log << TestLog::Message << "u_bias = " << bias << TestLog::EndMessage;

 	// Verify that none of the inputs are denormalized / inf / nan.
 	TCU_CHECK(isValidFloatVec(m_precision, scale));
 	TCU_CHECK(isValidFloatVec(m_precision, bias));
 	for (int ndx = 0; ndx < DE_LENGTH_OF_ARRAY(coords); ndx++)
 	{
 		TCU_CHECK(isValidFloat(m_precision, coords[ndx]));
 		TCU_CHECK(isValidFloat(m_precision, coords[ndx] * scale[ndx % 3] + bias[ndx % 3]));
 	}

 	// Indices.
 	static const deUint16 indices[] = { 0, 1, 2, 2, 1, 3 };

 	{
 		const int	posLoc		= glGetAttribLocation(program.getProgram(), "a_position");
 		const int	coordLoc	= glGetAttribLocation(program.getProgram(), "a_coords");

 		glEnableVertexAttribArray(posLoc);
 		glVertexAttribPointer(posLoc, 4, GL_FLOAT, GL_FALSE, 0, &positions[0]);

 		glEnableVertexAttribArray(coordLoc);
 		glVertexAttribPointer(coordLoc, 3, GL_FLOAT, GL_FALSE, 0, &coords[0]);
 	}

 	glUseProgram(program.getProgram());
 	glUniform3f(glGetUniformLocation(program.getProgram(), "u_scale"), scale.x(), scale.y(), scale.z());
 	glUniform3f(glGetUniformLocation(program.getProgram(), "u_bias"), bias.x(), bias.y(), bias.z());

 	GLU_CHECK_MSG("After program setup");

 	// Frames.
 	tcu::Surface	rendered		(viewportWidth, viewportHeight);
 	tcu::Surface	reference		(viewportWidth, viewportHeight);

 	// Render with GL.
 	glViewport(viewportX, viewportY, viewportWidth, viewportHeight);
 	glDrawElements(GL_TRIANGLES, DE_LENGTH_OF_ARRAY(indices), GL_UNSIGNED_SHORT, &indices[0]);

 	// Render reference \note While GPU is hopefully doing our draw call.
 	renderReference(SurfaceAccess(reference, m_context.getRenderTarget().getPixelFormat()), coords, wCoord, scale, bias);

 	glu::readPixels(m_context.getRenderContext(), viewportX, viewportY, rendered.getAccess());

 	// Compute difference.
 	const int		bestScoreDiff	= 16;
 	const int		worstScoreDiff	= 300;
 	int				score			= tcu::measurePixelDiffAccuracy(log, "Result", "Image comparison result", reference, rendered, bestScoreDiff, worstScoreDiff, tcu::COMPARE_LOG_EVERYTHING);

 	m_testCtx.setTestResult(QP_TEST_RESULT_PASS, de::toString(score).c_str());
 	return STOP;
 }

 VaryingInterpolationTests::VaryingInterpolationTests (Context& context)
 	: TestCaseGroup(context, "interpolation", "Varying Interpolation Accuracy Tests")
 {
 }

 VaryingInterpolationTests::~VaryingInterpolationTests (void)
 {
 }

 void VaryingInterpolationTests::init (void)
 {
 	DE_STATIC_ASSERT(glu::PRECISION_LOWP+1		== glu::PRECISION_MEDIUMP);
 	DE_STATIC_ASSERT(glu::PRECISION_MEDIUMP+1	== glu::PRECISION_HIGHP);

 	// Exp = Emax-3, Mantissa = 0
 	float minF32 = tcu::Float32((0u<<31) | (0xfcu<<23) | 0x0u).asFloat();
 	float maxF32 = tcu::Float32((1u<<31) | (0xfcu<<23) | 0x0u).asFloat();
 	float minF16 = tcu::Float16((deUint16)((0u<<15) | (0x1cu<<10) | 0x0u)).asFloat();
 	float maxF16 = tcu::Float16((deUint16)((1u<<15) | (0x1cu<<10) | 0x0u)).asFloat();

 	static const struct
 	{
 		const char*		name;
 		Vec3			minVal;
 		Vec3			maxVal;
 		glu::Precision	minPrecision;
 	} coordRanges[] =
 	{
 		{ "zero_to_one",		Vec3(  0.0f,   0.0f,   0.0f), Vec3(  1.0f,   1.0f,   1.0f), glu::PRECISION_LOWP		},
 		{ "zero_to_minus_one",	Vec3(  0.0f,   0.0f,   0.0f), Vec3( -1.0f,  -1.0f,  -1.0f), glu::PRECISION_LOWP		},
 		{ "minus_one_to_one",	Vec3( -1.0f,  -1.0f,  -1.0f), Vec3(  1.0f,   1.0f,   1.0f), glu::PRECISION_LOWP		},
 		{ "minus_ten_to_ten",	Vec3(-10.0f, -10.0f, -10.0f), Vec3( 10.0f,  10.0f,  10.0f), glu::PRECISION_MEDIUMP	},
 		{ "thousands",			Vec3( -5e3f,   1e3f,   1e3f), Vec3(  3e3f,  -1e3f,   7e3f), glu::PRECISION_MEDIUMP	},
 		{ "full_mediump",		Vec3(minF16, minF16, minF16), Vec3(maxF16, maxF16, maxF16), glu::PRECISION_MEDIUMP	},
 		{ "full_highp",			Vec3(minF32, minF32, minF32), Vec3(maxF32, maxF32, maxF32), glu::PRECISION_HIGHP	},
 	};

 	for (int precision = glu::PRECISION_LOWP; precision <= glu::PRECISION_HIGHP; precision++)
 	{
 		for (int coordNdx = 0; coordNdx < DE_LENGTH_OF_ARRAY(coordRanges); coordNdx++)
 		{
 			if (precision < (int)coordRanges[coordNdx].minPrecision)
 				continue;

 			string baseName = string(glu::getPrecisionName((glu::Precision)precision)) + "_" + coordRanges[coordNdx].name;

 			addChild(new InterpolationCase(m_context, baseName.c_str(),				"",	(glu::Precision)precision, coordRanges[coordNdx].minVal, coordRanges[coordNdx].maxVal, false));
 			addChild(new InterpolationCase(m_context, (baseName + "_proj").c_str(),	"",	(glu::Precision)precision, coordRanges[coordNdx].minVal, coordRanges[coordNdx].maxVal, true));
 		}
 	}
 }

 } // Accuracy
 } // 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 Varying interpolation accuracy tests.
	//--------------------------------------------------------------------*/

	#include "es2aVaryingInterpolationTests.hpp"
	#include "gluPixelTransfer.hpp"
	#include "gluShaderProgram.hpp"
	#include "gluShaderUtil.hpp"
	#include "tcuStringTemplate.hpp"
	#include "gluContextInfo.hpp"
	#include "glsTextureTestUtil.hpp"
	#include "tcuVector.hpp"
	#include "tcuVectorUtil.hpp"
	#include "tcuTestLog.hpp"
	#include "tcuFloat.hpp"
	#include "tcuImageCompare.hpp"
	#include "tcuRenderTarget.hpp"
	#include "tcuSurfaceAccess.hpp"
	#include "deRandom.hpp"
	#include "deStringUtil.hpp"
	#include "deString.h"

	#include "glw.h"

	using tcu::TestLog;
	using tcu::Vec3;
	using tcu::Vec4;
	using std::string;
	using std::vector;
	using std::map;
	using tcu::SurfaceAccess;

	namespace deqp
	{
	namespace gles2
	{
	namespace Accuracy
	{

	static inline float projectedTriInterpolate (const tcu::Vec3& s, const tcu::Vec3& w, float nx, float ny)
	{
	return (s[0](1.0f-nx-ny)/w[0] + s[1]ny/w[1] + s[2]*nx/w[2]) / ((1.0f-nx-ny)/w[0] + ny/w[1] + nx/w[2]);
	}

	static void renderReference (const SurfaceAccess& dst, const float coords[4*3], const Vec4& wCoord, const Vec3& scale, const Vec3& bias)
	{
	float dstW = (float)dst.getWidth();
	float dstH = (float)dst.getHeight();

	Vec3 triR[2] = { Vec3(coords[03+0], coords[13+0], coords[23+0]), Vec3(coords[33+0], coords[23+0], coords[13+0]) };
	Vec3 triG[2] = { Vec3(coords[03+1], coords[13+1], coords[23+1]), Vec3(coords[33+1], coords[23+1], coords[13+1]) };
	Vec3 triB[2] = { Vec3(coords[03+2], coords[13+2], coords[23+2]), Vec3(coords[33+2], coords[23+2], coords[13+2]) };
	tcu::Vec3 triW[2] = { wCoord.swizzle(0, 1, 2), wCoord.swizzle(3, 2, 1) };

	for (int py = 0; py < dst.getHeight(); py++)
	{
	for (int px = 0; px < dst.getWidth(); px++)
	{
	float wx = (float)px + 0.5f;
	float wy = (float)py + 0.5f;
	float nx = wx / dstW;
	float ny = wy / dstH;

	int triNdx = nx + ny >= 1.0f ? 1 : 0;
	float triNx = triNdx ? 1.0f - nx : nx;
	float triNy = triNdx ? 1.0f - ny : ny;

	float r = projectedTriInterpolate(triR[triNdx], triW[triNdx], triNx, triNy) * scale[0] + bias[0];
	float g = projectedTriInterpolate(triG[triNdx], triW[triNdx], triNx, triNy) * scale[1] + bias[1];
	float b = projectedTriInterpolate(triB[triNdx], triW[triNdx], triNx, triNy) * scale[2] + bias[2];

	Vec4 color = Vec4(r, g, b, 1.0f);

	dst.setPixel(color, px, py);
	}
	}
	}

	class InterpolationCase : public TestCase
	{
	public:
	InterpolationCase (Context& context, const char* name, const char* desc, glu::Precision precision, const tcu::Vec3& minVal, const tcu::Vec3& maxVal, bool projective);
	~InterpolationCase (void);

	IterateResult iterate (void);

	private:
	glu::Precision m_precision;
	tcu::Vec3 m_min;
	tcu::Vec3 m_max;
	bool m_projective;
	};

	InterpolationCase::InterpolationCase (Context& context, const char* name, const char* desc, glu::Precision precision, const tcu::Vec3& minVal, const tcu::Vec3& maxVal, bool projective)
	: TestCase (context, tcu::NODETYPE_ACCURACY, name, desc)
	, m_precision (precision)
	, m_min (minVal)
	, m_max (maxVal)
	, m_projective (projective)
	{
	}

	InterpolationCase::~InterpolationCase (void)
	{
	}

	static bool isValidFloat (glu::Precision precision, float val)
	{
	if (precision == glu::PRECISION_MEDIUMP)
	{
	tcu::Float16 fp16(val);
	return !fp16.isDenorm() && !fp16.isInf() && !fp16.isNaN();
	}
	else
	{
	tcu::Float32 fp32(val);
	return !fp32.isDenorm() && !fp32.isInf() && !fp32.isNaN();
	}
	}

	template <int Size>
	static bool isValidFloatVec (glu::Precision precision, const tcu::Vector<float, Size>& vec)
	{
	for (int ndx = 0; ndx < Size; ndx++)
	{
	if (!isValidFloat(precision, vec[ndx]))
	return false;
	}
	return true;
	}

	InterpolationCase::IterateResult InterpolationCase::iterate (void)
	{
	TestLog& log = m_testCtx.getLog();
	de::Random rnd (deStringHash(getName()));
	int viewportWidth = 128;
	int viewportHeight = 128;

	if (m_context.getRenderTarget().getWidth() < viewportWidth \|\|
	m_context.getRenderTarget().getHeight() < viewportHeight)
	throw tcu::NotSupportedError("Too small viewport", "", __FILE__, __LINE__);

	int viewportX = rnd.getInt(0, m_context.getRenderTarget().getWidth() - viewportWidth);
	int viewportY = rnd.getInt(0, m_context.getRenderTarget().getHeight() - viewportHeight);

	static const char* s_vertShaderTemplate =
	"attribute highp vec4 a_position;\n"
	"attribute ${PRECISION} vec3 a_coords;\n"
	"varying ${PRECISION} vec3 v_coords;\n"
	"\n"
	"void main (void)\n"
	"{\n"
	" gl_Position = a_position;\n"
	" v_coords = a_coords;\n"
	"}\n";
	static const char* s_fragShaderTemplate =
	"varying ${PRECISION} vec3 v_coords;\n"
	"uniform ${PRECISION} vec3 u_scale;\n"
	"uniform ${PRECISION} vec3 u_bias;\n"
	"\n"
	"void main (void)\n"
	"{\n"
	" gl_FragColor = vec4(v_coords * u_scale + u_bias, 1.0);\n"
	"}\n";

	map<string, string> templateParams;
	templateParams["PRECISION"] = glu::getPrecisionName(m_precision);

	glu::ShaderProgram program(m_context.getRenderContext(),
	glu::makeVtxFragSources(tcu::StringTemplate(s_vertShaderTemplate).specialize(templateParams),
	tcu::StringTemplate(s_fragShaderTemplate).specialize(templateParams)));
	log << program;
	if (!program.isOk())
	{
	if (m_precision == glu::PRECISION_HIGHP && !m_context.getContextInfo().isFragmentHighPrecisionSupported())
	m_testCtx.setTestResult(QP_TEST_RESULT_NOT_SUPPORTED, "Fragment highp not supported");
	else
	m_testCtx.setTestResult(QP_TEST_RESULT_FAIL, "Compile failed");
	return STOP;
	}

	// Position coordinates.
	Vec4 wCoord = m_projective ? Vec4(1.3f, 0.8f, 0.6f, 2.0f) : Vec4(1.0f, 1.0f, 1.0f, 1.0f);
	float positions[] =
	{
	-1.0fwCoord.x(), -1.0fwCoord.x(), 0.0f, wCoord.x(),
	-1.0fwCoord.y(), +1.0fwCoord.y(), 0.0f, wCoord.y(),
	+1.0fwCoord.z(), -1.0fwCoord.z(), 0.0f, wCoord.z(),
	+1.0fwCoord.w(), +1.0fwCoord.w(), 0.0f, wCoord.w()
	};

	// Coordinates for interpolation.
	tcu::Vec3 scale = 1.0f / (m_max - m_min);
	tcu::Vec3 bias = -1.0fm_minscale;
	float coords[] =
	{
	(0.0f - bias[0])/scale[0], (0.5f - bias[1])/scale[1], (1.0f - bias[2])/scale[2],
	(0.5f - bias[0])/scale[0], (1.0f - bias[1])/scale[1], (0.5f - bias[2])/scale[2],
	(0.5f - bias[0])/scale[0], (0.0f - bias[1])/scale[1], (0.5f - bias[2])/scale[2],
	(1.0f - bias[0])/scale[0], (0.5f - bias[1])/scale[1], (0.0f - bias[2])/scale[2]
	};

	log << TestLog::Message << "a_coords = " << ((tcu::Vec3(0.0f) - bias)/scale) << " -> " << ((tcu::Vec3(1.0f) - bias)/scale) << TestLog::EndMessage;
	log << TestLog::Message << "u_scale = " << scale << TestLog::EndMessage;
	log << TestLog::Message << "u_bias = " << bias << TestLog::EndMessage;

	// Verify that none of the inputs are denormalized / inf / nan.
	TCU_CHECK(isValidFloatVec(m_precision, scale));
	TCU_CHECK(isValidFloatVec(m_precision, bias));
	for (int ndx = 0; ndx < DE_LENGTH_OF_ARRAY(coords); ndx++)
	{
	TCU_CHECK(isValidFloat(m_precision, coords[ndx]));
	TCU_CHECK(isValidFloat(m_precision, coords[ndx] * scale[ndx % 3] + bias[ndx % 3]));
	}

	// Indices.
	static const deUint16 indices[] = { 0, 1, 2, 2, 1, 3 };

	{
	const int posLoc = glGetAttribLocation(program.getProgram(), "a_position");
	const int coordLoc = glGetAttribLocation(program.getProgram(), "a_coords");

	glEnableVertexAttribArray(posLoc);
	glVertexAttribPointer(posLoc, 4, GL_FLOAT, GL_FALSE, 0, &positions[0]);

	glEnableVertexAttribArray(coordLoc);
	glVertexAttribPointer(coordLoc, 3, GL_FLOAT, GL_FALSE, 0, &coords[0]);
	}

	glUseProgram(program.getProgram());
	glUniform3f(glGetUniformLocation(program.getProgram(), "u_scale"), scale.x(), scale.y(), scale.z());
	glUniform3f(glGetUniformLocation(program.getProgram(), "u_bias"), bias.x(), bias.y(), bias.z());

	GLU_CHECK_MSG("After program setup");

	// Frames.
	tcu::Surface rendered (viewportWidth, viewportHeight);
	tcu::Surface reference (viewportWidth, viewportHeight);

	// Render with GL.
	glViewport(viewportX, viewportY, viewportWidth, viewportHeight);
	glDrawElements(GL_TRIANGLES, DE_LENGTH_OF_ARRAY(indices), GL_UNSIGNED_SHORT, &indices[0]);

	// Render reference \note While GPU is hopefully doing our draw call.
	renderReference(SurfaceAccess(reference, m_context.getRenderTarget().getPixelFormat()), coords, wCoord, scale, bias);

	glu::readPixels(m_context.getRenderContext(), viewportX, viewportY, rendered.getAccess());

	// Compute difference.
	const int bestScoreDiff = 16;
	const int worstScoreDiff = 300;
	int score = tcu::measurePixelDiffAccuracy(log, "Result", "Image comparison result", reference, rendered, bestScoreDiff, worstScoreDiff, tcu::COMPARE_LOG_EVERYTHING);

	m_testCtx.setTestResult(QP_TEST_RESULT_PASS, de::toString(score).c_str());
	return STOP;
	}

	VaryingInterpolationTests::VaryingInterpolationTests (Context& context)
	: TestCaseGroup(context, "interpolation", "Varying Interpolation Accuracy Tests")
	{
	}

	VaryingInterpolationTests::~VaryingInterpolationTests (void)
	{
	}

	void VaryingInterpolationTests::init (void)
	{
	DE_STATIC_ASSERT(glu::PRECISION_LOWP+1 == glu::PRECISION_MEDIUMP);
	DE_STATIC_ASSERT(glu::PRECISION_MEDIUMP+1 == glu::PRECISION_HIGHP);

	// Exp = Emax-3, Mantissa = 0
	float minF32 = tcu::Float32((0u<<31) \| (0xfcu<<23) \| 0x0u).asFloat();
	float maxF32 = tcu::Float32((1u<<31) \| (0xfcu<<23) \| 0x0u).asFloat();
	float minF16 = tcu::Float16((deUint16)((0u<<15) \| (0x1cu<<10) \| 0x0u)).asFloat();
	float maxF16 = tcu::Float16((deUint16)((1u<<15) \| (0x1cu<<10) \| 0x0u)).asFloat();

	static const struct
	{
	const char* name;
	Vec3 minVal;
	Vec3 maxVal;
	glu::Precision minPrecision;
	} coordRanges[] =
	{
	{ "zero_to_one", Vec3( 0.0f, 0.0f, 0.0f), Vec3( 1.0f, 1.0f, 1.0f), glu::PRECISION_LOWP },
	{ "zero_to_minus_one", Vec3( 0.0f, 0.0f, 0.0f), Vec3( -1.0f, -1.0f, -1.0f), glu::PRECISION_LOWP },
	{ "minus_one_to_one", Vec3( -1.0f, -1.0f, -1.0f), Vec3( 1.0f, 1.0f, 1.0f), glu::PRECISION_LOWP },
	{ "minus_ten_to_ten", Vec3(-10.0f, -10.0f, -10.0f), Vec3( 10.0f, 10.0f, 10.0f), glu::PRECISION_MEDIUMP },
	{ "thousands", Vec3( -5e3f, 1e3f, 1e3f), Vec3( 3e3f, -1e3f, 7e3f), glu::PRECISION_MEDIUMP },
	{ "full_mediump", Vec3(minF16, minF16, minF16), Vec3(maxF16, maxF16, maxF16), glu::PRECISION_MEDIUMP },
	{ "full_highp", Vec3(minF32, minF32, minF32), Vec3(maxF32, maxF32, maxF32), glu::PRECISION_HIGHP },
	};

	for (int precision = glu::PRECISION_LOWP; precision <= glu::PRECISION_HIGHP; precision++)
	{
	for (int coordNdx = 0; coordNdx < DE_LENGTH_OF_ARRAY(coordRanges); coordNdx++)
	{
	if (precision < (int)coordRanges[coordNdx].minPrecision)
	continue;

	string baseName = string(glu::getPrecisionName((glu::Precision)precision)) + "_" + coordRanges[coordNdx].name;

	addChild(new InterpolationCase(m_context, baseName.c_str(), "", (glu::Precision)precision, coordRanges[coordNdx].minVal, coordRanges[coordNdx].maxVal, false));
	addChild(new InterpolationCase(m_context, (baseName + "_proj").c_str(), "", (glu::Precision)precision, coordRanges[coordNdx].minVal, coordRanges[coordNdx].maxVal, true));
	}
	}
	}

	} // Accuracy
	} // gles2
	} // deqp