Add testing for sparse D/S/DS images.

[platform/upstream/VK-GL-CTS.git] / modules / glshared / glsFragOpInteractionCase.cpp

/*-------------------------------------------------------------------------
 * drawElements Quality Program OpenGL (ES) 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 Shader - render state interaction case.
 *//*--------------------------------------------------------------------*/

#include "glsFragOpInteractionCase.hpp"

#include "glsRandomShaderProgram.hpp"
#include "glsFragmentOpUtil.hpp"
#include "glsInteractionTestUtil.hpp"

#include "gluRenderContext.hpp"
#include "gluContextInfo.hpp"

#include "rsgShader.hpp"
#include "rsgProgramGenerator.hpp"
#include "rsgUtils.hpp"

#include "sglrContext.hpp"
#include "sglrReferenceContext.hpp"
#include "sglrGLContext.hpp"
#include "sglrContextUtil.hpp"

#include "tcuRenderTarget.hpp"
#include "tcuImageCompare.hpp"

#include "deRandom.hpp"
#include "deString.h"
#include "deStringUtil.hpp"

#include "glwEnums.hpp"

#include "gluDrawUtil.hpp"

namespace deqp
{
namespace gls
{

using std::vector;
using std::string;
using tcu::Vec2;
using tcu::Vec4;
using tcu::IVec2;
using tcu::IVec4;

using gls::InteractionTestUtil::RenderState;
using gls::InteractionTestUtil::StencilState;

enum
{
        NUM_ITERATIONS                                  = 5,
        NUM_COMMANDS_PER_ITERATION              = 5,
        VIEWPORT_WIDTH                                  = 64,
        VIEWPORT_HEIGHT                                 = 64
};

namespace
{

static void computeVertexLayout (const vector<rsg::ShaderInput*>& attributes, int numVertices, vector<glu::VertexArrayBinding>* layout, int* stride)
{
        DE_ASSERT(layout->empty());

        int curOffset = 0;

        for (vector<rsg::ShaderInput*>::const_iterator iter = attributes.begin(); iter != attributes.end(); ++iter)
        {
                const rsg::ShaderInput*         attrib          = *iter;
                const rsg::Variable*            var                     = attrib->getVariable();
                const rsg::VariableType&        type            = var->getType();
                const int                                       numComps        = type.getNumElements();

                TCU_CHECK_INTERNAL(type.getBaseType() == rsg::VariableType::TYPE_FLOAT && de::inRange(type.getNumElements(), 1, 4));

                layout->push_back(glu::va::Float(var->getName(), numComps, numVertices, 0 /* computed later */, (const float*)(deUintptr)curOffset));

                curOffset += numComps * (int)sizeof(float);
        }

        for (vector<glu::VertexArrayBinding>::iterator vaIter = layout->begin(); vaIter != layout->end(); ++vaIter)
                vaIter->pointer.stride = curOffset;

        *stride = curOffset;
}

class VertexDataStorage
{
public:
                                                                                                VertexDataStorage       (const vector<rsg::ShaderInput*>& attributes, int numVertices);

        int                                                                                     getDataSize                     (void) const    { return (int)m_data.size();                                    }
        void*                                                                           getBasePtr                      (void)                  { return m_data.empty() ? DE_NULL : &m_data[0]; }
        const void*                                                                     getBasePtr                      (void) const    { return m_data.empty() ? DE_NULL : &m_data[0]; }

        const std::vector<glu::VertexArrayBinding>&     getLayout                       (void) const    { return m_layout; }

        int                                                                                     getNumEntries           (void) const    { return (int)m_layout.size();  }
        const glu::VertexArrayBinding&                          getLayoutEntry          (int ndx) const { return m_layout[ndx];                 }

private:
        std::vector<deUint8>                                            m_data;
        std::vector<glu::VertexArrayBinding>            m_layout;
};

VertexDataStorage::VertexDataStorage (const vector<rsg::ShaderInput*>& attributes, int numVertices)
{
        int stride = 0;
        computeVertexLayout(attributes, numVertices, &m_layout, &stride);
        m_data.resize(stride * numVertices);
}

static inline glu::VertexArrayBinding getEntryWithPointer (const VertexDataStorage& data, int ndx)
{
        const glu::VertexArrayBinding& entry = data.getLayoutEntry(ndx);
        return glu::VertexArrayBinding(entry.binding, glu::VertexArrayPointer(entry.pointer.componentType,
                                                                                                                                                  entry.pointer.convert,
                                                                                                                                                  entry.pointer.numComponents,
                                                                                                                                                  entry.pointer.numElements,
                                                                                                                                                  entry.pointer.stride,
                                                                                                                                                  (const void*)((deUintptr)entry.pointer.data+(deUintptr)data.getBasePtr())));
}

template<int Size>
static void setVertex (const glu::VertexArrayPointer& pointer, int vertexNdx, const tcu::Vector<float, Size>& value)
{
        // \todo [2013-12-14 pyry] Implement other modes.
        DE_ASSERT(pointer.componentType == glu::VTX_COMP_FLOAT && pointer.convert == glu::VTX_COMP_CONVERT_NONE);
        DE_ASSERT(pointer.numComponents == Size);
        DE_ASSERT(de::inBounds(vertexNdx, 0, pointer.numElements));

        float* dst = (float*)((deUint8*)pointer.data + pointer.stride*vertexNdx);

        for (int ndx = 0; ndx < Size; ndx++)
                dst[ndx] = value[ndx];
}

template<int Size>
static tcu::Vector<float, Size> interpolateRange (const rsg::ConstValueRangeAccess& range, const tcu::Vector<float, Size>& t)
{
        tcu::Vector<float, Size> result;

        for (int ndx = 0; ndx < Size; ndx++)
                result[ndx] = range.getMin().component(ndx).asFloat()*(1.0f - t[ndx]) + range.getMax().component(ndx).asFloat()*t[ndx];

        return result;
}

struct Quad
{
        tcu::IVec2      posA;
        tcu::IVec2      posB;
};

struct RenderCommand
{
        Quad            quad;
        float           depth;
        RenderState     state;

        RenderCommand (void) : depth(0.0f) {}
};

static Quad getRandomQuad (de::Random& rnd, int targetW, int targetH)
{
        // \note In viewport coordinates.
        // \todo [2012-12-18 pyry] Out-of-bounds values.
        const int               maxOutOfBounds  = 0;
        const float             minSize                 = 0.5f;

        const int               minW                    = deCeilFloatToInt32(minSize * (float)targetW);
        const int               minH                    = deCeilFloatToInt32(minSize * (float)targetH);
        const int               maxW                    = targetW + 2*maxOutOfBounds;
        const int               maxH                    = targetH + 2*maxOutOfBounds;

        const int               width                   = rnd.getInt(minW, maxW);
        const int               height                  = rnd.getInt(minH, maxH);
        const int               x                               = rnd.getInt(-maxOutOfBounds, targetW+maxOutOfBounds-width);
        const int               y                               = rnd.getInt(-maxOutOfBounds, targetH+maxOutOfBounds-height);

        const bool              flipX                   = rnd.getBool();
        const bool              flipY                   = rnd.getBool();

        Quad                    quad;

        quad.posA       = tcu::IVec2(flipX ? (x+width-1) : x, flipY ? (y+height-1) : y);
        quad.posB       = tcu::IVec2(flipX ? x : (x+width-1), flipY ? y : (y+height-1));

        return quad;
}

static float getRandomDepth (de::Random& rnd)
{
        // \note Not using depth 1.0 since clearing with 1.0 and rendering with 1.0 may not be same value.
        static const float depthValues[] = { 0.0f, 0.2f, 0.4f, 0.5f, 0.51f, 0.6f, 0.8f, 0.95f };
        return rnd.choose<float>(DE_ARRAY_BEGIN(depthValues), DE_ARRAY_END(depthValues));
}

static void computeRandomRenderCommand (de::Random& rnd, RenderCommand& command, glu::ApiType apiType, int targetW, int targetH)
{
        command.quad    = getRandomQuad(rnd, targetW, targetH);
        command.depth   = getRandomDepth(rnd);
        gls::InteractionTestUtil::computeRandomRenderState(rnd, command.state, apiType, targetW, targetH);
}

static void setRenderState (sglr::Context& ctx, const RenderState& state)
{
        if (state.scissorTestEnabled)
        {
                ctx.enable(GL_SCISSOR_TEST);
                ctx.scissor(state.scissorRectangle.left, state.scissorRectangle.bottom,
                                        state.scissorRectangle.width, state.scissorRectangle.height);
        }
        else
                ctx.disable(GL_SCISSOR_TEST);

        if (state.stencilTestEnabled)
        {
                ctx.enable(GL_STENCIL_TEST);

                for (int face = 0; face < rr::FACETYPE_LAST; face++)
                {
                        deUint32                                glFace  = face == rr::FACETYPE_BACK ? GL_BACK : GL_FRONT;
                        const StencilState&             sParams = state.stencil[face];

                        ctx.stencilFuncSeparate(glFace, sParams.function, sParams.reference, sParams.compareMask);
                        ctx.stencilOpSeparate(glFace, sParams.stencilFailOp, sParams.depthFailOp, sParams.depthPassOp);
                        ctx.stencilMaskSeparate(glFace, sParams.writeMask);
                }
        }
        else
                ctx.disable(GL_STENCIL_TEST);

        if (state.depthTestEnabled)
        {
                ctx.enable(GL_DEPTH_TEST);
                ctx.depthFunc(state.depthFunc);
                ctx.depthMask(state.depthWriteMask ? GL_TRUE : GL_FALSE);
        }
        else
                ctx.disable(GL_DEPTH_TEST);

        if (state.blendEnabled)
        {
                ctx.enable(GL_BLEND);
                ctx.blendEquationSeparate(state.blendRGBState.equation, state.blendAState.equation);
                ctx.blendFuncSeparate(state.blendRGBState.srcFunc, state.blendRGBState.dstFunc, state.blendAState.srcFunc, state.blendAState.dstFunc);
                ctx.blendColor(state.blendColor.x(), state.blendColor.y(), state.blendColor.z(), state.blendColor.w());
        }
        else
                ctx.disable(GL_BLEND);

        if (state.ditherEnabled)
                ctx.enable(GL_DITHER);
        else
                ctx.disable(GL_DITHER);

        ctx.colorMask(state.colorMask[0] ? GL_TRUE : GL_FALSE,
                                  state.colorMask[1] ? GL_TRUE : GL_FALSE,
                                  state.colorMask[2] ? GL_TRUE : GL_FALSE,
                                  state.colorMask[3] ? GL_TRUE : GL_FALSE);
}

static void renderQuad (sglr::Context& ctx, const glu::VertexArrayPointer& posPtr, const Quad& quad, const float depth)
{
        const deUint16  indices[]       = { 0, 1, 2, 2, 1, 3 };

        const bool              flipX           = quad.posB.x() < quad.posA.x();
        const bool              flipY           = quad.posB.y() < quad.posA.y();
        const int               viewportX       = de::min(quad.posA.x(), quad.posB.x());
        const int               viewportY       = de::min(quad.posA.y(), quad.posB.y());
        const int               viewportW       = de::abs(quad.posA.x()-quad.posB.x())+1;
        const int               viewportH       = de::abs(quad.posA.y()-quad.posB.y())+1;

        const Vec2              pA                      (flipX ? 1.0f : -1.0f, flipY ? 1.0f : -1.0f);
        const Vec2              pB                      (flipX ? -1.0f : 1.0f, flipY ? -1.0f : 1.0f);

        setVertex(posPtr, 0, Vec4(pA.x(), pA.y(), depth, 1.0f));
        setVertex(posPtr, 1, Vec4(pB.x(), pA.y(), depth, 1.0f));
        setVertex(posPtr, 2, Vec4(pA.x(), pB.y(), depth, 1.0f));
        setVertex(posPtr, 3, Vec4(pB.x(), pB.y(), depth, 1.0f));

        ctx.viewport(viewportX, viewportY, viewportW, viewportH);
        ctx.drawElements(GL_TRIANGLES, DE_LENGTH_OF_ARRAY(indices), GL_UNSIGNED_SHORT, &indices[0]);
}

static void render (sglr::Context& ctx, const glu::VertexArrayPointer& posPtr, const RenderCommand& cmd)
{
        setRenderState(ctx, cmd.state);
        renderQuad(ctx, posPtr, cmd.quad, cmd.depth);
}

static void setupAttributes (sglr::Context& ctx, const VertexDataStorage& vertexData, deUint32 program)
{
        for (int attribNdx = 0; attribNdx < vertexData.getNumEntries(); ++attribNdx)
        {
                const glu::VertexArrayBinding   bindingPtr      = getEntryWithPointer(vertexData, attribNdx);
                const int                                               attribLoc       = bindingPtr.binding.type == glu::BindingPoint::TYPE_NAME ? ctx.getAttribLocation(program, bindingPtr.binding.name.c_str()) : bindingPtr.binding.location;

                DE_ASSERT(bindingPtr.pointer.componentType == glu::VTX_COMP_FLOAT);

                if (attribLoc >= 0)
                {
                        ctx.enableVertexAttribArray(attribLoc);
                        ctx.vertexAttribPointer(attribLoc, bindingPtr.pointer.numComponents, GL_FLOAT, GL_FALSE, bindingPtr.pointer.stride, bindingPtr.pointer.data);
                }
        }
}

void setUniformValue (sglr::Context& ctx, int location, rsg::ConstValueAccess value)
{
        DE_STATIC_ASSERT(sizeof(rsg::Scalar) == sizeof(float));
        DE_STATIC_ASSERT(sizeof(rsg::Scalar) == sizeof(int));

        switch (value.getType().getBaseType())
        {
                case rsg::VariableType::TYPE_FLOAT:
                        switch (value.getType().getNumElements())
                        {
                                case 1:         ctx.uniform1fv(location, 1, (float*)value.value().getValuePtr());       break;
                                case 2:         ctx.uniform2fv(location, 1, (float*)value.value().getValuePtr());       break;
                                case 3:         ctx.uniform3fv(location, 1, (float*)value.value().getValuePtr());       break;
                                case 4:         ctx.uniform4fv(location, 1, (float*)value.value().getValuePtr());       break;
                                default:        TCU_FAIL("Unsupported type");                                                                           break;
                        }
                        break;

                case rsg::VariableType::TYPE_INT:
                case rsg::VariableType::TYPE_BOOL:
                case rsg::VariableType::TYPE_SAMPLER_2D:
                case rsg::VariableType::TYPE_SAMPLER_CUBE:
                        switch (value.getType().getNumElements())
                        {
                                case 1:         ctx.uniform1iv(location, 1, (int*)value.value().getValuePtr());         break;
                                case 2:         ctx.uniform2iv(location, 1, (int*)value.value().getValuePtr());         break;
                                case 3:         ctx.uniform3iv(location, 1, (int*)value.value().getValuePtr());         break;
                                case 4:         ctx.uniform4iv(location, 1, (int*)value.value().getValuePtr());         break;
                                default:        TCU_FAIL("Unsupported type");                                                                           break;
                        }
                        break;

                default:
                        throw tcu::InternalError("Unsupported type", "", __FILE__, __LINE__);
        }
}

static int findShaderInputIndex (const vector<rsg::ShaderInput*>& vars, const char* name)
{
        for (int ndx = 0; ndx < (int)vars.size(); ++ndx)
        {
                if (deStringEqual(vars[ndx]->getVariable()->getName(), name))
                        return ndx;
        }

        throw tcu::InternalError(string(name) + " not found in shader inputs");
}

static float getWellBehavingChannelColor (float v, int numBits)
{
        DE_ASSERT(de::inRange(numBits, 0, 32));

        // clear color may not be accurately representable in the target format. If the clear color is
        // on a representable value mapping range border, it could be rounded differently by the GL and in
        // SGLR adding an unexpected error source. However, selecting an accurately representable background
        // color would effectively disable dithering. To allow dithering and to prevent undefined rounding
        // direction from affecting results, round accurate color to target color format with 8 sub-units
        // (3 bits). If the selected sub-unit value is 3 or 4 (bordering 0.5), replace it with 2 and 5,
        // respectively.

        if (numBits == 0 || v <= 0.0f || v >= 1.0f)
        {
                // already accurately representable
                return v;
        }
        else
        {
                const deUint64 numSubBits               = 3;
                const deUint64 subUnitBorderLo  = (1u << (numSubBits - 1u)) - 1u;
                const deUint64 subUnitBorderHi  = 1u << (numSubBits - 1u);
                const deUint64 maxFixedValue    = (1u << (numBits + numSubBits)) - 1u;
                const deUint64 fixedValue               = deRoundFloatToInt64(v * (float)maxFixedValue);

                const deUint64 units                    = fixedValue >> numSubBits;
                const deUint64 subUnits                 = fixedValue & ((1u << numSubBits) - 1u);

                const deUint64 tweakedSubUnits  = (subUnits == subUnitBorderLo) ? (subUnitBorderLo - 1)
                                                                                : (subUnits == subUnitBorderHi) ? (subUnitBorderHi + 1)
                                                                                : (subUnits);
                const deUint64 tweakedValue             = (units << numSubBits) | (tweakedSubUnits);

                return float(tweakedValue) / float(maxFixedValue);
        }
}

static tcu::Vec4 getWellBehavingColor (const tcu::Vec4& accurateColor, const tcu::PixelFormat& format)
{
        return tcu::Vec4(getWellBehavingChannelColor(accurateColor[0], format.redBits),
                                         getWellBehavingChannelColor(accurateColor[1], format.greenBits),
                                         getWellBehavingChannelColor(accurateColor[2], format.blueBits),
                                         getWellBehavingChannelColor(accurateColor[3], format.alphaBits));
}

} // anonymous

struct FragOpInteractionCase::ReferenceContext
{
        const sglr::ReferenceContextLimits      limits;
        sglr::ReferenceContextBuffers           buffers;
        sglr::ReferenceContext                          context;

        ReferenceContext (glu::RenderContext& renderCtx, int width, int height)
                : limits        (renderCtx)
                , buffers       (renderCtx.getRenderTarget().getPixelFormat(), renderCtx.getRenderTarget().getDepthBits(), renderCtx.getRenderTarget().getStencilBits(), width, height)
                , context       (limits, buffers.getColorbuffer(), buffers.getDepthbuffer(), buffers.getStencilbuffer())
        {
        }
};

FragOpInteractionCase::FragOpInteractionCase (tcu::TestContext& testCtx, glu::RenderContext& renderCtx, const glu::ContextInfo& ctxInfo, const char* name, const rsg::ProgramParameters& params)
        : TestCase                      (testCtx, name, "")
        , m_renderCtx           (renderCtx)
        , m_ctxInfo                     (ctxInfo)
        , m_params                      (params)
        , m_vertexShader        (rsg::Shader::TYPE_VERTEX)
        , m_fragmentShader      (rsg::Shader::TYPE_FRAGMENT)
        , m_program                     (DE_NULL)
        , m_glCtx                       (DE_NULL)
        , m_referenceCtx        (DE_NULL)
        , m_glProgram           (0)
        , m_refProgram          (0)
        , m_iterNdx                     (0)
{
}

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

void FragOpInteractionCase::init (void)
{
        de::Random                              rnd                             (m_params.seed ^ 0x232faac);
        const int                               viewportW               = de::min<int>(m_renderCtx.getRenderTarget().getWidth(),        VIEWPORT_WIDTH);
        const int                               viewportH               = de::min<int>(m_renderCtx.getRenderTarget().getHeight(),       VIEWPORT_HEIGHT);
        const int                               viewportX               = rnd.getInt(0, m_renderCtx.getRenderTarget().getWidth()        - viewportW);
        const int                               viewportY               = rnd.getInt(0, m_renderCtx.getRenderTarget().getHeight()       - viewportH);

        rsg::ProgramGenerator   generator;

        generator.generate(m_params, m_vertexShader, m_fragmentShader);
        rsg::computeUnifiedUniforms(m_vertexShader, m_fragmentShader, m_unifiedUniforms);

        try
        {
                DE_ASSERT(!m_program);
                m_program = new gls::RandomShaderProgram(m_vertexShader, m_fragmentShader, (int)m_unifiedUniforms.size(), m_unifiedUniforms.empty() ? DE_NULL : &m_unifiedUniforms[0]);

                DE_ASSERT(!m_referenceCtx);
                m_referenceCtx = new ReferenceContext(m_renderCtx, viewportW, viewportH);

                DE_ASSERT(!m_glCtx);
                m_glCtx = new sglr::GLContext(m_renderCtx, m_testCtx.getLog(), sglr::GLCONTEXT_LOG_CALLS|sglr::GLCONTEXT_LOG_PROGRAMS, IVec4(viewportX, viewportY, viewportW, viewportH));

                m_refProgram    = m_referenceCtx->context.createProgram(m_program);
                m_glProgram             = m_glCtx->createProgram(m_program);

                m_viewportSize  = tcu::IVec2(viewportW, viewportH);
                m_iterNdx               = 0;
                m_testCtx.setTestResult(QP_TEST_RESULT_PASS, "Pass");
        }
        catch (...)
        {
                // Save some memory by cleaning up stuff.
                FragOpInteractionCase::deinit();
                throw;
        }
}

void FragOpInteractionCase::deinit (void)
{
        delete m_referenceCtx;
        m_referenceCtx = DE_NULL;

        delete m_glCtx;
        m_glCtx = DE_NULL;

        delete m_program;
        m_program = DE_NULL;
}

FragOpInteractionCase::IterateResult FragOpInteractionCase::iterate (void)
{
        de::Random                                                      rnd                                     (m_params.seed ^ deInt32Hash(m_iterNdx));
        const tcu::ScopedLogSection                     section                         (m_testCtx.getLog(), string("Iter") + de::toString(m_iterNdx), string("Iteration ") + de::toString(m_iterNdx));

        const int                                                       positionNdx                     = findShaderInputIndex(m_vertexShader.getInputs(), "dEQP_Position");

        const int                                                       numVertices                     = 4;
        VertexDataStorage                                       vertexData                      (m_vertexShader.getInputs(), numVertices);
        std::vector<rsg::VariableValue>         uniformValues;
        std::vector<RenderCommand>                      renderCmds                      (NUM_COMMANDS_PER_ITERATION);

        tcu::Surface                                            rendered                        (m_viewportSize.x(), m_viewportSize.y());
        tcu::Surface                                            reference                       (m_viewportSize.x(), m_viewportSize.y());

        const tcu::Vec4                                         vtxInterpFactors[]      =
        {
                tcu::Vec4(0.0f, 0.0f, 0.0f, 1.0f),
                tcu::Vec4(1.0f, 0.0f, 0.5f, 0.5f),
                tcu::Vec4(0.0f, 1.0f, 0.5f, 0.5f),
                tcu::Vec4(1.0f, 1.0f, 1.0f, 0.0f)
        };

        rsg::computeUniformValues(rnd, uniformValues, m_unifiedUniforms);

        for (int attribNdx = 0; attribNdx < (int)m_vertexShader.getInputs().size(); ++attribNdx)
        {
                if (attribNdx == positionNdx)
                        continue;

                const rsg::ShaderInput*                         shaderIn                = m_vertexShader.getInputs()[attribNdx];
                const rsg::VariableType&                        varType                 = shaderIn->getVariable()->getType();
                const rsg::ConstValueRangeAccess        valueRange              = shaderIn->getValueRange();
                const int                                                       numComponents   = varType.getNumElements();
                const glu::VertexArrayBinding           layoutEntry             = getEntryWithPointer(vertexData, attribNdx);

                DE_ASSERT(varType.getBaseType() == rsg::VariableType::TYPE_FLOAT);

                for (int vtxNdx = 0; vtxNdx < 4; vtxNdx++)
                {
                        const int                       fNdx    = (attribNdx+vtxNdx+m_iterNdx)%DE_LENGTH_OF_ARRAY(vtxInterpFactors);
                        const tcu::Vec4&        f               = vtxInterpFactors[fNdx];

                        switch (numComponents)
                        {
                                case 1: setVertex(layoutEntry.pointer, vtxNdx, interpolateRange(valueRange, f.toWidth<1>()));   break;
                                case 2: setVertex(layoutEntry.pointer, vtxNdx, interpolateRange(valueRange, f.toWidth<2>()));   break;
                                case 3: setVertex(layoutEntry.pointer, vtxNdx, interpolateRange(valueRange, f.toWidth<3>()));   break;
                                case 4: setVertex(layoutEntry.pointer, vtxNdx, interpolateRange(valueRange, f.toWidth<4>()));   break;
                                default:
                                        DE_ASSERT(false);
                        }
                }
        }

        for (vector<RenderCommand>::iterator cmdIter = renderCmds.begin(); cmdIter != renderCmds.end(); ++cmdIter)
                computeRandomRenderCommand(rnd, *cmdIter, m_renderCtx.getType().getAPI(), m_viewportSize.x(), m_viewportSize.y());

        // Workaround for inaccurate barycentric/depth computation in current reference renderer:
        // Small bias is added to the draw call depths, in increasing order, to avoid accuracy issues in depth comparison.
        for (int cmdNdx = 0; cmdNdx < (int)renderCmds.size(); cmdNdx++)
                renderCmds[cmdNdx].depth += 0.0231725f * float(cmdNdx);

        {
                const glu::VertexArrayPointer           posPtr                          = getEntryWithPointer(vertexData, positionNdx).pointer;

                sglr::Context* const                            contexts[]                      = { m_glCtx, &m_referenceCtx->context };
                const deUint32                                          programs[]                      = { m_glProgram, m_refProgram };
                tcu::PixelBufferAccess                          readDst[]                       = { rendered.getAccess(), reference.getAccess() };

                const tcu::Vec4                                         accurateClearColor      = tcu::Vec4(0.0f, 0.25f, 0.5f, 1.0f);
                const tcu::Vec4                                         clearColor                      = getWellBehavingColor(accurateClearColor, m_renderCtx.getRenderTarget().getPixelFormat());

                for (int ndx = 0; ndx < DE_LENGTH_OF_ARRAY(contexts); ndx++)
                {
                        sglr::Context&  ctx                     = *contexts[ndx];
                        const deUint32  program         = programs[ndx];

                        setupAttributes(ctx, vertexData, program);

                        ctx.disable             (GL_SCISSOR_TEST);
                        ctx.colorMask   (GL_TRUE, GL_TRUE, GL_TRUE, GL_TRUE);
                        ctx.depthMask   (GL_TRUE);
                        ctx.stencilMask (~0u);
                        ctx.clearColor  (clearColor.x(), clearColor.y(), clearColor.z(), clearColor.w());
                        ctx.clear               (GL_COLOR_BUFFER_BIT|GL_DEPTH_BUFFER_BIT|GL_STENCIL_BUFFER_BIT);

                        ctx.useProgram  (program);

                        for (vector<rsg::VariableValue>::const_iterator uniformIter = uniformValues.begin(); uniformIter != uniformValues.end(); ++uniformIter)
                                setUniformValue(ctx, ctx.getUniformLocation(program, uniformIter->getVariable()->getName()), uniformIter->getValue());

                        for (vector<RenderCommand>::const_iterator cmdIter = renderCmds.begin(); cmdIter != renderCmds.end(); ++cmdIter)
                                render(ctx, posPtr, *cmdIter);

                        GLU_EXPECT_NO_ERROR(ctx.getError(), "Rendering failed");

                        ctx.readPixels(0, 0, m_viewportSize.x(), m_viewportSize.y(), GL_RGBA, GL_UNSIGNED_BYTE, readDst[ndx].getDataPtr());
                }
        }

        {
                const tcu::RGBA         threshold               = m_renderCtx.getRenderTarget().getPixelFormat().getColorThreshold()+tcu::RGBA(3,3,3,3);
                const bool                      compareOk               = tcu::bilinearCompare(m_testCtx.getLog(), "CompareResult", "Image comparison result", reference.getAccess(), rendered.getAccess(), threshold, tcu::COMPARE_LOG_RESULT);

                if (!compareOk)
                {
                        m_testCtx.setTestResult(QP_TEST_RESULT_FAIL, "Image comparison failed");
                        return STOP;
                }
        }

        m_iterNdx += 1;
        return (m_iterNdx < NUM_ITERATIONS) ? CONTINUE : STOP;
}

} // gls
} // deqp