/*------------------------------------------------------------------------- * drawElements Quality Program OpenGL ES 3.0 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 Buffer data upload performance tests. *//*--------------------------------------------------------------------*/ #include "es3pBufferDataUploadTests.hpp" #include "glsCalibration.hpp" #include "tcuTestLog.hpp" #include "tcuVectorUtil.hpp" #include "tcuSurface.hpp" #include "tcuCPUWarmup.hpp" #include "tcuRenderTarget.hpp" #include "gluRenderContext.hpp" #include "gluShaderProgram.hpp" #include "gluStrUtil.hpp" #include "gluPixelTransfer.hpp" #include "gluObjectWrapper.hpp" #include "glwFunctions.hpp" #include "glwEnums.hpp" #include "deClock.h" #include "deMath.h" #include "deStringUtil.hpp" #include "deRandom.hpp" #include "deMemory.h" #include "deThread.h" #include "deMeta.hpp" #include #include #include namespace deqp { namespace gles3 { namespace Performance { namespace { using gls::theilSenSiegelLinearRegression; using gls::LineParametersWithConfidence; using de::meta::EnableIf; using de::meta::Not; static const char* const s_dummyVertexShader = "#version 300 es\n" "in highp vec4 a_position;\n" "void main (void)\n" "{\n" " gl_Position = a_position;\n" "}\n"; static const char* const s_dummyFragnentShader = "#version 300 es\n" "layout(location = 0) out mediump vec4 dEQP_FragColor;\n" "void main (void)\n" "{\n" " dEQP_FragColor = vec4(1.0, 0.0, 0.0, 1.0);\n" "}\n"; static const char* const s_colorVertexShader = "#version 300 es\n" "in highp vec4 a_position;\n" "in highp vec4 a_color;\n" "out highp vec4 v_color;\n" "void main (void)\n" "{\n" " gl_Position = a_position;\n" " v_color = a_color;\n" "}\n"; static const char* const s_colorFragmentShader = "#version 300 es\n" "layout(location = 0) out mediump vec4 dEQP_FragColor;\n" "in mediump vec4 v_color;\n" "void main (void)\n" "{\n" " dEQP_FragColor = v_color;\n" "}\n"; struct SingleOperationDuration { deUint64 totalDuration; deUint64 fitResponseDuration; // used for fitting }; struct MapBufferRangeDuration { deUint64 mapDuration; deUint64 unmapDuration; deUint64 writeDuration; deUint64 allocDuration; deUint64 totalDuration; deUint64 fitResponseDuration; }; struct MapBufferRangeDurationNoAlloc { deUint64 mapDuration; deUint64 unmapDuration; deUint64 writeDuration; deUint64 totalDuration; deUint64 fitResponseDuration; }; struct MapBufferRangeFlushDuration { deUint64 mapDuration; deUint64 unmapDuration; deUint64 writeDuration; deUint64 flushDuration; deUint64 allocDuration; deUint64 totalDuration; deUint64 fitResponseDuration; }; struct MapBufferRangeFlushDurationNoAlloc { deUint64 mapDuration; deUint64 unmapDuration; deUint64 writeDuration; deUint64 flushDuration; deUint64 totalDuration; deUint64 fitResponseDuration; }; struct RenderReadDuration { deUint64 renderDuration; deUint64 readDuration; deUint64 renderReadDuration; deUint64 totalDuration; deUint64 fitResponseDuration; }; struct UnrelatedUploadRenderReadDuration { deUint64 renderDuration; deUint64 readDuration; deUint64 renderReadDuration; deUint64 totalDuration; deUint64 fitResponseDuration; }; struct UploadRenderReadDuration { deUint64 uploadDuration; deUint64 renderDuration; deUint64 readDuration; deUint64 totalDuration; deUint64 renderReadDuration; deUint64 fitResponseDuration; }; struct UploadRenderReadDurationWithUnrelatedUploadSize { deUint64 uploadDuration; deUint64 renderDuration; deUint64 readDuration; deUint64 totalDuration; deUint64 renderReadDuration; deUint64 fitResponseDuration; }; struct RenderUploadRenderReadDuration { deUint64 firstRenderDuration; deUint64 uploadDuration; deUint64 secondRenderDuration; deUint64 readDuration; deUint64 totalDuration; deUint64 renderReadDuration; deUint64 fitResponseDuration; }; template struct UploadSampleResult { typedef SampleT SampleType; int bufferSize; int allocatedSize; int writtenSize; SampleType duration; }; template struct RenderSampleResult { typedef SampleT SampleType; int uploadedDataSize; int renderDataSize; int unrelatedDataSize; int numVertices; SampleT duration; }; struct SingleOperationStatistics { float minTime; float maxTime; float medianTime; float min2DecileTime; // !< minimum value in the 2nd decile float max9DecileTime; // !< maximum value in the 9th decile }; struct SingleCallStatistics { SingleOperationStatistics result; float medianRate; float maxDiffTime; float maxDiff9DecileTime; float medianDiffTime; float maxRelDiffTime; float max9DecileRelDiffTime; float medianRelDiffTime; }; struct MapCallStatistics { SingleOperationStatistics map; SingleOperationStatistics unmap; SingleOperationStatistics write; SingleOperationStatistics alloc; SingleOperationStatistics result; float medianRate; float maxDiffTime; float maxDiff9DecileTime; float medianDiffTime; float maxRelDiffTime; float max9DecileRelDiffTime; float medianRelDiffTime; }; struct MapFlushCallStatistics { SingleOperationStatistics map; SingleOperationStatistics unmap; SingleOperationStatistics write; SingleOperationStatistics flush; SingleOperationStatistics alloc; SingleOperationStatistics result; float medianRate; float maxDiffTime; float maxDiff9DecileTime; float medianDiffTime; float maxRelDiffTime; float max9DecileRelDiffTime; float medianRelDiffTime; }; struct RenderReadStatistics { SingleOperationStatistics render; SingleOperationStatistics read; SingleOperationStatistics result; SingleOperationStatistics total; float medianRate; float maxDiffTime; float maxDiff9DecileTime; float medianDiffTime; float maxRelDiffTime; float max9DecileRelDiffTime; float medianRelDiffTime; }; struct UploadRenderReadStatistics { SingleOperationStatistics upload; SingleOperationStatistics render; SingleOperationStatistics read; SingleOperationStatistics result; SingleOperationStatistics total; float medianRate; float maxDiffTime; float maxDiff9DecileTime; float medianDiffTime; float maxRelDiffTime; float max9DecileRelDiffTime; float medianRelDiffTime; }; struct RenderUploadRenderReadStatistics { SingleOperationStatistics firstRender; SingleOperationStatistics upload; SingleOperationStatistics secondRender; SingleOperationStatistics read; SingleOperationStatistics result; SingleOperationStatistics total; float medianRate; float maxDiffTime; float maxDiff9DecileTime; float medianDiffTime; float maxRelDiffTime; float max9DecileRelDiffTime; float medianRelDiffTime; }; template struct SampleTypeTraits { }; template <> struct SampleTypeTraits { typedef SingleCallStatistics StatsType; enum { HAS_MAP_STATS = 0 }; enum { HAS_UNMAP_STATS = 0 }; enum { HAS_WRITE_STATS = 0 }; enum { HAS_FLUSH_STATS = 0 }; enum { HAS_ALLOC_STATS = 0 }; enum { LOG_CONTRIBUTIONS = 0 }; }; template <> struct SampleTypeTraits { typedef MapCallStatistics StatsType; enum { HAS_MAP_STATS = 1 }; enum { HAS_UNMAP_STATS = 1 }; enum { HAS_WRITE_STATS = 1 }; enum { HAS_FLUSH_STATS = 0 }; enum { HAS_ALLOC_STATS = 1 }; enum { LOG_CONTRIBUTIONS = 1 }; }; template <> struct SampleTypeTraits { typedef MapCallStatistics StatsType; enum { HAS_MAP_STATS = 1 }; enum { HAS_UNMAP_STATS = 1 }; enum { HAS_WRITE_STATS = 1 }; enum { HAS_FLUSH_STATS = 0 }; enum { HAS_ALLOC_STATS = 0 }; enum { LOG_CONTRIBUTIONS = 1 }; }; template <> struct SampleTypeTraits { typedef MapFlushCallStatistics StatsType; enum { HAS_MAP_STATS = 1 }; enum { HAS_UNMAP_STATS = 1 }; enum { HAS_WRITE_STATS = 1 }; enum { HAS_FLUSH_STATS = 1 }; enum { HAS_ALLOC_STATS = 1 }; enum { LOG_CONTRIBUTIONS = 1 }; }; template <> struct SampleTypeTraits { typedef MapFlushCallStatistics StatsType; enum { HAS_MAP_STATS = 1 }; enum { HAS_UNMAP_STATS = 1 }; enum { HAS_WRITE_STATS = 1 }; enum { HAS_FLUSH_STATS = 1 }; enum { HAS_ALLOC_STATS = 0 }; enum { LOG_CONTRIBUTIONS = 1 }; }; template <> struct SampleTypeTraits { typedef RenderReadStatistics StatsType; enum { HAS_RENDER_STATS = 1 }; enum { HAS_READ_STATS = 1 }; enum { HAS_UPLOAD_STATS = 0 }; enum { HAS_TOTAL_STATS = 1 }; enum { HAS_FIRST_RENDER_STATS = 0 }; enum { HAS_SECOND_RENDER_STATS = 0 }; enum { LOG_CONTRIBUTIONS = 1 }; }; template <> struct SampleTypeTraits { typedef RenderReadStatistics StatsType; enum { HAS_RENDER_STATS = 1 }; enum { HAS_READ_STATS = 1 }; enum { HAS_UPLOAD_STATS = 0 }; enum { HAS_TOTAL_STATS = 1 }; enum { HAS_FIRST_RENDER_STATS = 0 }; enum { HAS_SECOND_RENDER_STATS = 0 }; enum { LOG_CONTRIBUTIONS = 1 }; }; template <> struct SampleTypeTraits { typedef UploadRenderReadStatistics StatsType; enum { HAS_RENDER_STATS = 1 }; enum { HAS_READ_STATS = 1 }; enum { HAS_UPLOAD_STATS = 1 }; enum { HAS_TOTAL_STATS = 1 }; enum { HAS_FIRST_RENDER_STATS = 0 }; enum { HAS_SECOND_RENDER_STATS = 0 }; enum { LOG_CONTRIBUTIONS = 1 }; enum { LOG_UNRELATED_UPLOAD_SIZE = 0 }; }; template <> struct SampleTypeTraits { typedef UploadRenderReadStatistics StatsType; enum { HAS_RENDER_STATS = 1 }; enum { HAS_READ_STATS = 1 }; enum { HAS_UPLOAD_STATS = 1 }; enum { HAS_TOTAL_STATS = 1 }; enum { HAS_FIRST_RENDER_STATS = 0 }; enum { HAS_SECOND_RENDER_STATS = 0 }; enum { LOG_CONTRIBUTIONS = 1 }; enum { LOG_UNRELATED_UPLOAD_SIZE = 1 }; }; template <> struct SampleTypeTraits { typedef RenderUploadRenderReadStatistics StatsType; enum { HAS_RENDER_STATS = 0 }; enum { HAS_READ_STATS = 1 }; enum { HAS_UPLOAD_STATS = 1 }; enum { HAS_TOTAL_STATS = 1 }; enum { HAS_FIRST_RENDER_STATS = 1 }; enum { HAS_SECOND_RENDER_STATS = 1 }; enum { LOG_CONTRIBUTIONS = 1 }; enum { LOG_UNRELATED_UPLOAD_SIZE = 1 }; }; struct UploadSampleAnalyzeResult { float transferRateMedian; float transferRateAtRange; float transferRateAtInfinity; }; struct RenderSampleAnalyzeResult { float renderRateMedian; float renderRateAtRange; float renderRateAtInfinity; }; class UnmapFailureError : public std::exception { public: UnmapFailureError (void) : std::exception() {} }; static std::string getHumanReadableByteSize (int numBytes) { std::ostringstream buf; if (numBytes < 1024) buf << numBytes << " byte(s)"; else if (numBytes < 1024 * 1024) buf << de::floatToString((float)numBytes/1024.0f, 1) << " KiB"; else buf << de::floatToString((float)numBytes/1024.0f/1024.0f, 1) << " MiB"; return buf.str(); } static deUint64 medianTimeMemcpy (void* dst, const void* src, int numBytes) { // Time used by memcpy is assumed to be asymptotically linear // With large numBytes, the probability of context switch or other random // event is high. Apply memcpy in parts and report how much time would // memcpy have used with the median transfer rate. // Less than 1MiB, no need to do anything special if (numBytes < 1048576) { deUint64 startTime; deUint64 endTime; deYield(); startTime = deGetMicroseconds(); deMemcpy(dst, src, numBytes); endTime = deGetMicroseconds(); return endTime - startTime; } else { // Do memcpy in multiple parts const int numSections = 5; const int sectionAlign = 16; int sectionStarts[numSections+1]; int sectionLens[numSections]; deUint64 sectionTimes[numSections]; deUint64 medianTime; deUint64 bestTime = 0; for (int sectionNdx = 0; sectionNdx < numSections; ++sectionNdx) sectionStarts[sectionNdx] = deAlign32((numBytes * sectionNdx / numSections), sectionAlign); sectionStarts[numSections] = numBytes; for (int sectionNdx = 0; sectionNdx < numSections; ++sectionNdx) sectionLens[sectionNdx] = sectionStarts[sectionNdx+1] - sectionStarts[sectionNdx]; // Memcpy is usually called after mapbuffer range which may take // a lot of time. To prevent power management from kicking in during // copy, warm up more. { deYield(); tcu::warmupCPU(); deYield(); } for (int sectionNdx = 0; sectionNdx < numSections; ++sectionNdx) { deUint64 startTime; deUint64 endTime; startTime = deGetMicroseconds(); deMemcpy((deUint8*)dst + sectionStarts[sectionNdx], (const deUint8*)src + sectionStarts[sectionNdx], sectionLens[sectionNdx]); endTime = deGetMicroseconds(); sectionTimes[sectionNdx] = endTime - startTime; if (!bestTime || sectionTimes[sectionNdx] < bestTime) bestTime = sectionTimes[sectionNdx]; // Detect if write takes 50% longer than it should, and warm up if that happened if (sectionNdx != numSections-1 && (float)sectionTimes[sectionNdx] > 1.5f * (float)bestTime) { deYield(); tcu::warmupCPU(); deYield(); } } std::sort(sectionTimes, sectionTimes + numSections); if ((numSections % 2) == 0) medianTime = (sectionTimes[numSections / 2 - 1] + sectionTimes[numSections / 2]) / 2; else medianTime = sectionTimes[numSections / 2]; return medianTime*numSections; } } static float dummyCalculation (float initial, int workSize) { float a = initial; int b = 123; for (int ndx = 0; ndx < workSize; ++ndx) { a = deFloatCos(a + (float)b); b = (b + 63) % 107 + de::abs((int)(a*10.0f)); } return a + (float)b; } static void busyWait (int microseconds) { const deUint64 maxSingleWaitTime = 1000; // 1ms const deUint64 endTime = deGetMicroseconds() + microseconds; float dummy = *tcu::warmupCPUInternal::g_dummy.m_v; int workSize = 500; // exponentially increase work, cap to 1ms while (deGetMicroseconds() < endTime) { const deUint64 startTime = deGetMicroseconds(); deUint64 totalTime; dummy = dummyCalculation(dummy, workSize); totalTime = deGetMicroseconds() - startTime; if (totalTime >= maxSingleWaitTime) break; else workSize *= 2; } // "wait" while (deGetMicroseconds() < endTime) dummy = dummyCalculation(dummy, workSize); *tcu::warmupCPUInternal::g_dummy.m_v = dummy; } // Sample from given values using linear interpolation at a given position as if values were laid to range [0, 1] template static float linearSample (const std::vector& values, float position) { DE_ASSERT(position >= 0.0f); DE_ASSERT(position <= 1.0f); const float floatNdx = (float)(values.size() - 1) * position; const int lowerNdx = (int)deFloatFloor(floatNdx); const int higherNdx = lowerNdx + 1; const float interpolationFactor = floatNdx - (float)lowerNdx; DE_ASSERT(lowerNdx >= 0 && lowerNdx < (int)values.size()); DE_ASSERT(higherNdx >= 0 && higherNdx < (int)values.size()); DE_ASSERT(interpolationFactor >= 0 && interpolationFactor < 1.0f); return tcu::mix((float)values[lowerNdx], (float)values[higherNdx], interpolationFactor); } template SingleOperationStatistics calculateSingleOperationStatistics (const std::vector& samples, deUint64 T::SampleType::*target) { SingleOperationStatistics stats; std::vector values(samples.size()); for (int ndx = 0; ndx < (int)samples.size(); ++ndx) values[ndx] = samples[ndx].duration.*target; std::sort(values.begin(), values.end()); stats.minTime = (float)values.front(); stats.maxTime = (float)values.back(); stats.medianTime = linearSample(values, 0.5f); stats.min2DecileTime = linearSample(values, 0.1f); stats.max9DecileTime = linearSample(values, 0.9f); return stats; } template void calculateBasicStatistics (StatisticsType& stats, const LineParametersWithConfidence& fit, const std::vector& samples, int SampleType::*predictor) { std::vector values(samples.size()); for (int ndx = 0; ndx < (int)samples.size(); ++ndx) values[ndx] = samples[ndx].duration.fitResponseDuration; // median rate { std::vector processingRates(samples.size()); for (int ndx = 0; ndx < (int)samples.size(); ++ndx) { const float timeInSeconds = (float)values[ndx] / 1000.0f / 1000.0f; processingRates[ndx] = (float)(samples[ndx].*predictor) / timeInSeconds; } std::sort(processingRates.begin(), processingRates.end()); stats.medianRate = linearSample(processingRates, 0.5f); } // results compared to the approximation { std::vector timeDiffs(samples.size()); for (int ndx = 0; ndx < (int)samples.size(); ++ndx) { const float prediction = (float)(samples[ndx].*predictor) * fit.coefficient + fit.offset; const float actual = (float)values[ndx]; timeDiffs[ndx] = actual - prediction; } std::sort(timeDiffs.begin(), timeDiffs.end()); stats.maxDiffTime = timeDiffs.back(); stats.maxDiff9DecileTime = linearSample(timeDiffs, 0.9f); stats.medianDiffTime = linearSample(timeDiffs, 0.5f); } // relative comparison to the approximation { std::vector relativeDiffs(samples.size()); for (int ndx = 0; ndx < (int)samples.size(); ++ndx) { const float prediction = (float)(samples[ndx].*predictor) * fit.coefficient + fit.offset; const float actual = (float)values[ndx]; // Ignore cases where we predict negative times, or if // ratio would be (nearly) infinite: ignore if predicted // time is less than 1 microsecond if (prediction < 1.0f) relativeDiffs[ndx] = 0.0f; else relativeDiffs[ndx] = (actual - prediction) / prediction; } std::sort(relativeDiffs.begin(), relativeDiffs.end()); stats.maxRelDiffTime = relativeDiffs.back(); stats.max9DecileRelDiffTime = linearSample(relativeDiffs, 0.9f); stats.medianRelDiffTime = linearSample(relativeDiffs, 0.5f); } // values calculated using sorted timings std::sort(values.begin(), values.end()); stats.result.minTime = (float)values.front(); stats.result.maxTime = (float)values.back(); stats.result.medianTime = linearSample(values, 0.5f); stats.result.min2DecileTime = linearSample(values, 0.1f); stats.result.max9DecileTime = linearSample(values, 0.9f); } template void calculateBasicTransferStatistics (StatisticsType& stats, const LineParametersWithConfidence& fit, const std::vector& samples) { calculateBasicStatistics(stats, fit, samples, &SampleType::writtenSize); } template void calculateBasicRenderStatistics (StatisticsType& stats, const LineParametersWithConfidence& fit, const std::vector& samples) { calculateBasicStatistics(stats, fit, samples, &SampleType::renderDataSize); } static SingleCallStatistics calculateSampleStatistics (const LineParametersWithConfidence& fit, const std::vector >& samples) { SingleCallStatistics stats; calculateBasicTransferStatistics(stats, fit, samples); return stats; } static MapCallStatistics calculateSampleStatistics (const LineParametersWithConfidence& fit, const std::vector >& samples) { MapCallStatistics stats; calculateBasicTransferStatistics(stats, fit, samples); stats.map = calculateSingleOperationStatistics(samples, &MapBufferRangeDuration::mapDuration); stats.unmap = calculateSingleOperationStatistics(samples, &MapBufferRangeDuration::unmapDuration); stats.write = calculateSingleOperationStatistics(samples, &MapBufferRangeDuration::writeDuration); stats.alloc = calculateSingleOperationStatistics(samples, &MapBufferRangeDuration::allocDuration); return stats; } static MapFlushCallStatistics calculateSampleStatistics (const LineParametersWithConfidence& fit, const std::vector >& samples) { MapFlushCallStatistics stats; calculateBasicTransferStatistics(stats, fit, samples); stats.map = calculateSingleOperationStatistics(samples, &MapBufferRangeFlushDuration::mapDuration); stats.unmap = calculateSingleOperationStatistics(samples, &MapBufferRangeFlushDuration::unmapDuration); stats.write = calculateSingleOperationStatistics(samples, &MapBufferRangeFlushDuration::writeDuration); stats.flush = calculateSingleOperationStatistics(samples, &MapBufferRangeFlushDuration::flushDuration); stats.alloc = calculateSingleOperationStatistics(samples, &MapBufferRangeFlushDuration::allocDuration); return stats; } static MapCallStatistics calculateSampleStatistics (const LineParametersWithConfidence& fit, const std::vector >& samples) { MapCallStatistics stats; calculateBasicTransferStatistics(stats, fit, samples); stats.map = calculateSingleOperationStatistics(samples, &MapBufferRangeDurationNoAlloc::mapDuration); stats.unmap = calculateSingleOperationStatistics(samples, &MapBufferRangeDurationNoAlloc::unmapDuration); stats.write = calculateSingleOperationStatistics(samples, &MapBufferRangeDurationNoAlloc::writeDuration); return stats; } static MapFlushCallStatistics calculateSampleStatistics (const LineParametersWithConfidence& fit, const std::vector >& samples) { MapFlushCallStatistics stats; calculateBasicTransferStatistics(stats, fit, samples); stats.map = calculateSingleOperationStatistics(samples, &MapBufferRangeFlushDurationNoAlloc::mapDuration); stats.unmap = calculateSingleOperationStatistics(samples, &MapBufferRangeFlushDurationNoAlloc::unmapDuration); stats.write = calculateSingleOperationStatistics(samples, &MapBufferRangeFlushDurationNoAlloc::writeDuration); stats.flush = calculateSingleOperationStatistics(samples, &MapBufferRangeFlushDurationNoAlloc::flushDuration); return stats; } static RenderReadStatistics calculateSampleStatistics (const LineParametersWithConfidence& fit, const std::vector >& samples) { RenderReadStatistics stats; calculateBasicRenderStatistics(stats, fit, samples); stats.render = calculateSingleOperationStatistics(samples, &RenderReadDuration::renderDuration); stats.read = calculateSingleOperationStatistics(samples, &RenderReadDuration::readDuration); stats.total = calculateSingleOperationStatistics(samples, &RenderReadDuration::totalDuration); return stats; } static RenderReadStatistics calculateSampleStatistics (const LineParametersWithConfidence& fit, const std::vector >& samples) { RenderReadStatistics stats; calculateBasicRenderStatistics(stats, fit, samples); stats.render = calculateSingleOperationStatistics(samples, &UnrelatedUploadRenderReadDuration::renderDuration); stats.read = calculateSingleOperationStatistics(samples, &UnrelatedUploadRenderReadDuration::readDuration); stats.total = calculateSingleOperationStatistics(samples, &UnrelatedUploadRenderReadDuration::totalDuration); return stats; } static UploadRenderReadStatistics calculateSampleStatistics (const LineParametersWithConfidence& fit, const std::vector >& samples) { UploadRenderReadStatistics stats; calculateBasicRenderStatistics(stats, fit, samples); stats.upload = calculateSingleOperationStatistics(samples, &UploadRenderReadDuration::uploadDuration); stats.render = calculateSingleOperationStatistics(samples, &UploadRenderReadDuration::renderDuration); stats.read = calculateSingleOperationStatistics(samples, &UploadRenderReadDuration::readDuration); stats.total = calculateSingleOperationStatistics(samples, &UploadRenderReadDuration::totalDuration); return stats; } static UploadRenderReadStatistics calculateSampleStatistics (const LineParametersWithConfidence& fit, const std::vector >& samples) { UploadRenderReadStatistics stats; calculateBasicRenderStatistics(stats, fit, samples); stats.upload = calculateSingleOperationStatistics(samples, &UploadRenderReadDurationWithUnrelatedUploadSize::uploadDuration); stats.render = calculateSingleOperationStatistics(samples, &UploadRenderReadDurationWithUnrelatedUploadSize::renderDuration); stats.read = calculateSingleOperationStatistics(samples, &UploadRenderReadDurationWithUnrelatedUploadSize::readDuration); stats.total = calculateSingleOperationStatistics(samples, &UploadRenderReadDurationWithUnrelatedUploadSize::totalDuration); return stats; } static RenderUploadRenderReadStatistics calculateSampleStatistics (const LineParametersWithConfidence& fit, const std::vector >& samples) { RenderUploadRenderReadStatistics stats; calculateBasicRenderStatistics(stats, fit, samples); stats.firstRender = calculateSingleOperationStatistics(samples, &RenderUploadRenderReadDuration::firstRenderDuration); stats.upload = calculateSingleOperationStatistics(samples, &RenderUploadRenderReadDuration::uploadDuration); stats.secondRender = calculateSingleOperationStatistics(samples, &RenderUploadRenderReadDuration::secondRenderDuration); stats.read = calculateSingleOperationStatistics(samples, &RenderUploadRenderReadDuration::readDuration); stats.total = calculateSingleOperationStatistics(samples, &RenderUploadRenderReadDuration::totalDuration); return stats; } template static LineParametersWithConfidence fitLineToSamples (const std::vector >& samples, int beginNdx, int endNdx, int step, deUint64 DurationType::*target = &DurationType::fitResponseDuration) { std::vector samplePoints; for (int sampleNdx = beginNdx; sampleNdx < endNdx; sampleNdx += step) { tcu::Vec2 point; point.x() = (float)(samples[sampleNdx].writtenSize); point.y() = (float)(samples[sampleNdx].duration.*target); samplePoints.push_back(point); } return theilSenSiegelLinearRegression(samplePoints, 0.6f); } template static LineParametersWithConfidence fitLineToSamples (const std::vector >& samples, int beginNdx, int endNdx, int step, deUint64 DurationType::*target = &DurationType::fitResponseDuration) { std::vector samplePoints; for (int sampleNdx = beginNdx; sampleNdx < endNdx; sampleNdx += step) { tcu::Vec2 point; point.x() = (float)(samples[sampleNdx].renderDataSize); point.y() = (float)(samples[sampleNdx].duration.*target); samplePoints.push_back(point); } return theilSenSiegelLinearRegression(samplePoints, 0.6f); } template static LineParametersWithConfidence fitLineToSamples (const std::vector& samples, int beginNdx, int endNdx, deUint64 T::SampleType::*target = &T::SampleType::fitResponseDuration) { return fitLineToSamples(samples, beginNdx, endNdx, 1, target); } template static LineParametersWithConfidence fitLineToSamples (const std::vector& samples, deUint64 T::SampleType::*target = &T::SampleType::fitResponseDuration) { return fitLineToSamples(samples, 0, (int)samples.size(), target); } static float getAreaBetweenLines (float xmin, float xmax, float lineAOffset, float lineACoefficient, float lineBOffset, float lineBCoefficient) { const float lineAMin = lineAOffset + lineACoefficient * xmin; const float lineAMax = lineAOffset + lineACoefficient * xmax; const float lineBMin = lineBOffset + lineBCoefficient * xmin; const float lineBMax = lineBOffset + lineBCoefficient * xmax; const bool aOverBAtBegin = (lineAMin > lineBMin); const bool aOverBAtEnd = (lineAMax > lineBMax); if (aOverBAtBegin == aOverBAtEnd) { // lines do not intersect const float midpoint = (xmin + xmax) / 2.0f; const float width = (xmax - xmin); const float lineAHeight = lineAOffset + lineACoefficient * midpoint; const float lineBHeight = lineBOffset + lineBCoefficient * midpoint; return width * de::abs(lineAHeight - lineBHeight); } else { // lines intersect const float approachCoeffient = de::abs(lineACoefficient - lineBCoefficient); const float epsilon = 0.0001f; const float leftHeight = de::abs(lineAMin - lineBMin); const float rightHeight = de::abs(lineAMax - lineBMax); if (approachCoeffient < epsilon) return 0.0f; return (0.5f * leftHeight * (leftHeight / approachCoeffient)) + (0.5f * rightHeight * (rightHeight / approachCoeffient)); } } template static float calculateSampleFitLinearity (const std::vector& samples, int T::*predictor) { // Compare the fitted line of first half of the samples to the fitted line of // the second half of the samples. Calculate a AABB that fully contains every // sample's x component and both fit lines in this range. Calculate the ratio // of the area between the lines and the AABB. const float epsilon = 1.e-6f; const int midPoint = (int)samples.size() / 2; const LineParametersWithConfidence startApproximation = fitLineToSamples(samples, 0, midPoint, &T::SampleType::fitResponseDuration); const LineParametersWithConfidence endApproximation = fitLineToSamples(samples, midPoint, (int)samples.size(), &T::SampleType::fitResponseDuration); const float aabbMinX = (float)(samples.front().*predictor); const float aabbMinY = de::min(startApproximation.offset + startApproximation.coefficient*aabbMinX, endApproximation.offset + endApproximation.coefficient*aabbMinX); const float aabbMaxX = (float)(samples.back().*predictor); const float aabbMaxY = de::max(startApproximation.offset + startApproximation.coefficient*aabbMaxX, endApproximation.offset + endApproximation.coefficient*aabbMaxX); const float aabbArea = (aabbMaxX - aabbMinX) * (aabbMaxY - aabbMinY); const float areaBetweenLines = getAreaBetweenLines(aabbMinX, aabbMaxX, startApproximation.offset, startApproximation.coefficient, endApproximation.offset, endApproximation.coefficient); const float errorAreaRatio = (aabbArea < epsilon) ? (1.0f) : (areaBetweenLines / aabbArea); return de::clamp(1.0f - errorAreaRatio, 0.0f, 1.0f); } template static float calculateSampleFitLinearity (const std::vector >& samples) { return calculateSampleFitLinearity(samples, &UploadSampleResult::writtenSize); } template static float calculateSampleFitLinearity (const std::vector >& samples) { return calculateSampleFitLinearity(samples, &RenderSampleResult::renderDataSize); } template static float calculateSampleTemporalStability (const std::vector& samples, int T::*predictor) { // Samples are sampled in the following order: 1) even samples (in random order) 2) odd samples (in random order) // Compare the fitted line of even samples to the fitted line of the odd samples. Calculate a AABB that fully // contains every sample's x component and both fit lines in this range. Calculate the ratio of the area between // the lines and the AABB. const float epsilon = 1.e-6f; const LineParametersWithConfidence evenApproximation = fitLineToSamples(samples, 0, (int)samples.size(), 2, &T::SampleType::fitResponseDuration); const LineParametersWithConfidence oddApproximation = fitLineToSamples(samples, 1, (int)samples.size(), 2, &T::SampleType::fitResponseDuration); const float aabbMinX = (float)(samples.front().*predictor); const float aabbMinY = de::min(evenApproximation.offset + evenApproximation.coefficient*aabbMinX, oddApproximation.offset + oddApproximation.coefficient*aabbMinX); const float aabbMaxX = (float)(samples.back().*predictor); const float aabbMaxY = de::max(evenApproximation.offset + evenApproximation.coefficient*aabbMaxX, oddApproximation.offset + oddApproximation.coefficient*aabbMaxX); const float aabbArea = (aabbMaxX - aabbMinX) * (aabbMaxY - aabbMinY); const float areaBetweenLines = getAreaBetweenLines(aabbMinX, aabbMaxX, evenApproximation.offset, evenApproximation.coefficient, oddApproximation.offset, oddApproximation.coefficient); const float errorAreaRatio = (aabbArea < epsilon) ? (1.0f) : (areaBetweenLines / aabbArea); return de::clamp(1.0f - errorAreaRatio, 0.0f, 1.0f); } template static float calculateSampleTemporalStability (const std::vector >& samples) { return calculateSampleTemporalStability(samples, &UploadSampleResult::writtenSize); } template static float calculateSampleTemporalStability (const std::vector >& samples) { return calculateSampleTemporalStability(samples, &RenderSampleResult::renderDataSize); } template static void bucketizeSamplesUniformly (const std::vector >& samples, std::vector >* buckets, int numBuckets, int& minBufferSize, int& maxBufferSize) { minBufferSize = 0; maxBufferSize = 0; for (int sampleNdx = 0; sampleNdx < (int)samples.size(); ++sampleNdx) { DE_ASSERT(samples[sampleNdx].allocatedSize != 0); if (!minBufferSize || samples[sampleNdx].allocatedSize < minBufferSize) minBufferSize = samples[sampleNdx].allocatedSize; if (!maxBufferSize || samples[sampleNdx].allocatedSize > maxBufferSize) maxBufferSize = samples[sampleNdx].allocatedSize; } for (int sampleNdx = 0; sampleNdx < (int)samples.size(); ++sampleNdx) { const float bucketNdxFloat = (float)(samples[sampleNdx].allocatedSize - minBufferSize) / (float)(maxBufferSize - minBufferSize) * (float)numBuckets; const int bucketNdx = de::clamp((int)deFloatFloor(bucketNdxFloat), 0, numBuckets-1); buckets[bucketNdx].push_back(samples[sampleNdx]); } } template static typename EnableIf::HAS_MAP_STATS>::Type logMapRangeStats (tcu::TestLog& log, const typename SampleTypeTraits::StatsType& stats) { log << tcu::TestLog::Float("MapRangeMin", "MapRange: Min time", "us", QP_KEY_TAG_TIME, stats.map.minTime) << tcu::TestLog::Float("MapRangeMax", "MapRange: Max time", "us", QP_KEY_TAG_TIME, stats.map.maxTime) << tcu::TestLog::Float("MapRangeMin90", "MapRange: 90%-Min time", "us", QP_KEY_TAG_TIME, stats.map.min2DecileTime) << tcu::TestLog::Float("MapRangeMax90", "MapRange: 90%-Max time", "us", QP_KEY_TAG_TIME, stats.map.max9DecileTime) << tcu::TestLog::Float("MapRangeMedian", "MapRange: Median time", "us", QP_KEY_TAG_TIME, stats.map.medianTime); } template static typename EnableIf::HAS_UNMAP_STATS>::Type logUnmapStats (tcu::TestLog& log, const typename SampleTypeTraits::StatsType& stats) { log << tcu::TestLog::Float("UnmapMin", "Unmap: Min time", "us", QP_KEY_TAG_TIME, stats.unmap.minTime) << tcu::TestLog::Float("UnmapMax", "Unmap: Max time", "us", QP_KEY_TAG_TIME, stats.unmap.maxTime) << tcu::TestLog::Float("UnmapMin90", "Unmap: 90%-Min time", "us", QP_KEY_TAG_TIME, stats.unmap.min2DecileTime) << tcu::TestLog::Float("UnmapMax90", "Unmap: 90%-Max time", "us", QP_KEY_TAG_TIME, stats.unmap.max9DecileTime) << tcu::TestLog::Float("UnmapMedian", "Unmap: Median time", "us", QP_KEY_TAG_TIME, stats.unmap.medianTime); } template static typename EnableIf::HAS_WRITE_STATS>::Type logWriteStats (tcu::TestLog& log, const typename SampleTypeTraits::StatsType& stats) { log << tcu::TestLog::Float("WriteMin", "Write: Min time", "us", QP_KEY_TAG_TIME, stats.write.minTime) << tcu::TestLog::Float("WriteMax", "Write: Max time", "us", QP_KEY_TAG_TIME, stats.write.maxTime) << tcu::TestLog::Float("WriteMin90", "Write: 90%-Min time", "us", QP_KEY_TAG_TIME, stats.write.min2DecileTime) << tcu::TestLog::Float("WriteMax90", "Write: 90%-Max time", "us", QP_KEY_TAG_TIME, stats.write.max9DecileTime) << tcu::TestLog::Float("WriteMedian", "Write: Median time", "us", QP_KEY_TAG_TIME, stats.write.medianTime); } template static typename EnableIf::HAS_FLUSH_STATS>::Type logFlushStats (tcu::TestLog& log, const typename SampleTypeTraits::StatsType& stats) { log << tcu::TestLog::Float("FlushMin", "Flush: Min time", "us", QP_KEY_TAG_TIME, stats.flush.minTime) << tcu::TestLog::Float("FlushMax", "Flush: Max time", "us", QP_KEY_TAG_TIME, stats.flush.maxTime) << tcu::TestLog::Float("FlushMin90", "Flush: 90%-Min time", "us", QP_KEY_TAG_TIME, stats.flush.min2DecileTime) << tcu::TestLog::Float("FlushMax90", "Flush: 90%-Max time", "us", QP_KEY_TAG_TIME, stats.flush.max9DecileTime) << tcu::TestLog::Float("FlushMedian", "Flush: Median time", "us", QP_KEY_TAG_TIME, stats.flush.medianTime); } template static typename EnableIf::HAS_ALLOC_STATS>::Type logAllocStats (tcu::TestLog& log, const typename SampleTypeTraits::StatsType& stats) { log << tcu::TestLog::Float("AllocMin", "Alloc: Min time", "us", QP_KEY_TAG_TIME, stats.alloc.minTime) << tcu::TestLog::Float("AllocMax", "Alloc: Max time", "us", QP_KEY_TAG_TIME, stats.alloc.maxTime) << tcu::TestLog::Float("AllocMin90", "Alloc: 90%-Min time", "us", QP_KEY_TAG_TIME, stats.alloc.min2DecileTime) << tcu::TestLog::Float("AllocMax90", "Alloc: 90%-Max time", "us", QP_KEY_TAG_TIME, stats.alloc.max9DecileTime) << tcu::TestLog::Float("AllocMedian", "Alloc: Median time", "us", QP_KEY_TAG_TIME, stats.alloc.medianTime); } template static typename EnableIf::HAS_MAP_STATS>::Value>::Type logMapRangeStats (tcu::TestLog& log, const typename SampleTypeTraits::StatsType& stats) { DE_UNREF(log); DE_UNREF(stats); } template static typename EnableIf::HAS_UNMAP_STATS>::Value>::Type logUnmapStats (tcu::TestLog& log, const typename SampleTypeTraits::StatsType& stats) { DE_UNREF(log); DE_UNREF(stats); } template static typename EnableIf::HAS_WRITE_STATS>::Value>::Type logWriteStats (tcu::TestLog& log, const typename SampleTypeTraits::StatsType& stats) { DE_UNREF(log); DE_UNREF(stats); } template static typename EnableIf::HAS_FLUSH_STATS>::Value>::Type logFlushStats (tcu::TestLog& log, const typename SampleTypeTraits::StatsType& stats) { DE_UNREF(log); DE_UNREF(stats); } template static typename EnableIf::HAS_ALLOC_STATS>::Value>::Type logAllocStats (tcu::TestLog& log, const typename SampleTypeTraits::StatsType& stats) { DE_UNREF(log); DE_UNREF(stats); } template static typename EnableIf::HAS_MAP_STATS>::Type logMapContribution (tcu::TestLog& log, const std::vector >& samples, const typename SampleTypeTraits::StatsType& stats) { const LineParametersWithConfidence contributionFitting = fitLineToSamples(samples, &SampleType::mapDuration); log << tcu::TestLog::Float("MapConstantCost", "Map: Approximated contant cost", "us", QP_KEY_TAG_TIME, contributionFitting.offset) << tcu::TestLog::Float("MapLinearCost", "Map: Approximated linear cost", "us / MB", QP_KEY_TAG_TIME, contributionFitting.coefficient * 1024.0f * 1024.0f) << tcu::TestLog::Float("MapMedianCost", "Map: Median cost", "us", QP_KEY_TAG_TIME, stats.map.medianTime); } template static typename EnableIf::HAS_UNMAP_STATS>::Type logUnmapContribution (tcu::TestLog& log, const std::vector >& samples, const typename SampleTypeTraits::StatsType& stats) { const LineParametersWithConfidence contributionFitting = fitLineToSamples(samples, &SampleType::unmapDuration); log << tcu::TestLog::Float("UnmapConstantCost", "Unmap: Approximated contant cost", "us", QP_KEY_TAG_TIME, contributionFitting.offset) << tcu::TestLog::Float("UnmapLinearCost", "Unmap: Approximated linear cost", "us / MB", QP_KEY_TAG_TIME, contributionFitting.coefficient * 1024.0f * 1024.0f) << tcu::TestLog::Float("UnmapMedianCost", "Unmap: Median cost", "us", QP_KEY_TAG_TIME, stats.unmap.medianTime); } template static typename EnableIf::HAS_WRITE_STATS>::Type logWriteContribution (tcu::TestLog& log, const std::vector >& samples, const typename SampleTypeTraits::StatsType& stats) { const LineParametersWithConfidence contributionFitting = fitLineToSamples(samples, &SampleType::writeDuration); log << tcu::TestLog::Float("WriteConstantCost", "Write: Approximated contant cost", "us", QP_KEY_TAG_TIME, contributionFitting.offset) << tcu::TestLog::Float("WriteLinearCost", "Write: Approximated linear cost", "us / MB", QP_KEY_TAG_TIME, contributionFitting.coefficient * 1024.0f * 1024.0f) << tcu::TestLog::Float("WriteMedianCost", "Write: Median cost", "us", QP_KEY_TAG_TIME, stats.write.medianTime); } template static typename EnableIf::HAS_FLUSH_STATS>::Type logFlushContribution (tcu::TestLog& log, const std::vector >& samples, const typename SampleTypeTraits::StatsType& stats) { const LineParametersWithConfidence contributionFitting = fitLineToSamples(samples, &SampleType::flushDuration); log << tcu::TestLog::Float("FlushConstantCost", "Flush: Approximated contant cost", "us", QP_KEY_TAG_TIME, contributionFitting.offset) << tcu::TestLog::Float("FlushLinearCost", "Flush: Approximated linear cost", "us / MB", QP_KEY_TAG_TIME, contributionFitting.coefficient * 1024.0f * 1024.0f) << tcu::TestLog::Float("FlushMedianCost", "Flush: Median cost", "us", QP_KEY_TAG_TIME, stats.flush.medianTime); } template static typename EnableIf::HAS_ALLOC_STATS>::Type logAllocContribution (tcu::TestLog& log, const std::vector >& samples, const typename SampleTypeTraits::StatsType& stats) { const LineParametersWithConfidence contributionFitting = fitLineToSamples(samples, &SampleType::allocDuration); log << tcu::TestLog::Float("AllocConstantCost", "Alloc: Approximated contant cost", "us", QP_KEY_TAG_TIME, contributionFitting.offset) << tcu::TestLog::Float("AllocLinearCost", "Alloc: Approximated linear cost", "us / MB", QP_KEY_TAG_TIME, contributionFitting.coefficient * 1024.0f * 1024.0f) << tcu::TestLog::Float("AllocMedianCost", "Alloc: Median cost", "us", QP_KEY_TAG_TIME, stats.alloc.medianTime); } template static typename EnableIf::HAS_RENDER_STATS>::Type logRenderContribution (tcu::TestLog& log, const std::vector >& samples, const typename SampleTypeTraits::StatsType& stats) { const LineParametersWithConfidence contributionFitting = fitLineToSamples(samples, &SampleType::renderDuration); log << tcu::TestLog::Float("DrawCallConstantCost", "DrawCall: Approximated contant cost", "us", QP_KEY_TAG_TIME, contributionFitting.offset) << tcu::TestLog::Float("DrawCallLinearCost", "DrawCall: Approximated linear cost", "us / MB", QP_KEY_TAG_TIME, contributionFitting.coefficient * 1024.0f * 1024.0f) << tcu::TestLog::Float("DrawCallMedianCost", "DrawCall: Median cost", "us", QP_KEY_TAG_TIME, stats.render.medianTime); } template static typename EnableIf::HAS_READ_STATS>::Type logReadContribution (tcu::TestLog& log, const std::vector >& samples, const typename SampleTypeTraits::StatsType& stats) { const LineParametersWithConfidence contributionFitting = fitLineToSamples(samples, &SampleType::readDuration); log << tcu::TestLog::Float("ReadConstantCost", "Read: Approximated contant cost", "us", QP_KEY_TAG_TIME, contributionFitting.offset) << tcu::TestLog::Float("ReadLinearCost", "Read: Approximated linear cost", "us / MB", QP_KEY_TAG_TIME, contributionFitting.coefficient * 1024.0f * 1024.0f) << tcu::TestLog::Float("ReadMedianCost", "Read: Median cost", "us", QP_KEY_TAG_TIME, stats.read.medianTime); } template static typename EnableIf::HAS_UPLOAD_STATS>::Type logUploadContribution (tcu::TestLog& log, const std::vector >& samples, const typename SampleTypeTraits::StatsType& stats) { const LineParametersWithConfidence contributionFitting = fitLineToSamples(samples, &SampleType::uploadDuration); log << tcu::TestLog::Float("UploadConstantCost", "Upload: Approximated contant cost", "us", QP_KEY_TAG_TIME, contributionFitting.offset) << tcu::TestLog::Float("UploadLinearCost", "Upload: Approximated linear cost", "us / MB", QP_KEY_TAG_TIME, contributionFitting.coefficient * 1024.0f * 1024.0f) << tcu::TestLog::Float("UploadMedianCost", "Upload: Median cost", "us", QP_KEY_TAG_TIME, stats.upload.medianTime); } template static typename EnableIf::HAS_TOTAL_STATS>::Type logTotalContribution (tcu::TestLog& log, const std::vector >& samples, const typename SampleTypeTraits::StatsType& stats) { const LineParametersWithConfidence contributionFitting = fitLineToSamples(samples, &SampleType::totalDuration); log << tcu::TestLog::Float("TotalConstantCost", "Total: Approximated contant cost", "us", QP_KEY_TAG_TIME, contributionFitting.offset) << tcu::TestLog::Float("TotalLinearCost", "Total: Approximated linear cost", "us / MB", QP_KEY_TAG_TIME, contributionFitting.coefficient * 1024.0f * 1024.0f) << tcu::TestLog::Float("TotalMedianCost", "Total: Median cost", "us", QP_KEY_TAG_TIME, stats.total.medianTime); } template static typename EnableIf::HAS_FIRST_RENDER_STATS>::Type logFirstRenderContribution (tcu::TestLog& log, const std::vector >& samples, const typename SampleTypeTraits::StatsType& stats) { const LineParametersWithConfidence contributionFitting = fitLineToSamples(samples, &SampleType::firstRenderDuration); log << tcu::TestLog::Float("FirstDrawCallConstantCost", "First DrawCall: Approximated contant cost", "us", QP_KEY_TAG_TIME, contributionFitting.offset) << tcu::TestLog::Float("FirstDrawCallLinearCost", "First DrawCall: Approximated linear cost", "us / MB", QP_KEY_TAG_TIME, contributionFitting.coefficient * 1024.0f * 1024.0f) << tcu::TestLog::Float("FirstDrawCallMedianCost", "First DrawCall: Median cost", "us", QP_KEY_TAG_TIME, stats.firstRender.medianTime); } template static typename EnableIf::HAS_SECOND_RENDER_STATS>::Type logSecondRenderContribution (tcu::TestLog& log, const std::vector >& samples, const typename SampleTypeTraits::StatsType& stats) { const LineParametersWithConfidence contributionFitting = fitLineToSamples(samples, &SampleType::secondRenderDuration); log << tcu::TestLog::Float("SecondDrawCallConstantCost", "Second DrawCall: Approximated contant cost", "us", QP_KEY_TAG_TIME, contributionFitting.offset) << tcu::TestLog::Float("SecondDrawCallLinearCost", "Second DrawCall: Approximated linear cost", "us / MB", QP_KEY_TAG_TIME, contributionFitting.coefficient * 1024.0f * 1024.0f) << tcu::TestLog::Float("SecondDrawCallMedianCost", "Second DrawCall: Median cost", "us", QP_KEY_TAG_TIME, stats.secondRender.medianTime); } template static typename EnableIf::HAS_MAP_STATS>::Value>::Type logMapContribution (tcu::TestLog& log, const std::vector >& samples, const typename SampleTypeTraits::StatsType& stats) { DE_UNREF(log); DE_UNREF(samples); DE_UNREF(stats); } template static typename EnableIf::HAS_UNMAP_STATS>::Value>::Type logUnmapContribution (tcu::TestLog& log, const std::vector >& samples, const typename SampleTypeTraits::StatsType& stats) { DE_UNREF(log); DE_UNREF(samples); DE_UNREF(stats); } template static typename EnableIf::HAS_WRITE_STATS>::Value>::Type logWriteContribution (tcu::TestLog& log, const std::vector >& samples, const typename SampleTypeTraits::StatsType& stats) { DE_UNREF(log); DE_UNREF(samples); DE_UNREF(stats); } template static typename EnableIf::HAS_FLUSH_STATS>::Value>::Type logFlushContribution (tcu::TestLog& log, const std::vector >& samples, const typename SampleTypeTraits::StatsType& stats) { DE_UNREF(log); DE_UNREF(samples); DE_UNREF(stats); } template static typename EnableIf::HAS_ALLOC_STATS>::Value>::Type logAllocContribution (tcu::TestLog& log, const std::vector >& samples, const typename SampleTypeTraits::StatsType& stats) { DE_UNREF(log); DE_UNREF(samples); DE_UNREF(stats); } template static typename EnableIf::HAS_RENDER_STATS>::Value>::Type logRenderContribution (tcu::TestLog& log, const std::vector >& samples, const typename SampleTypeTraits::StatsType& stats) { DE_UNREF(log); DE_UNREF(samples); DE_UNREF(stats); } template static typename EnableIf::HAS_READ_STATS>::Value>::Type logReadContribution (tcu::TestLog& log, const std::vector >& samples, const typename SampleTypeTraits::StatsType& stats) { DE_UNREF(log); DE_UNREF(samples); DE_UNREF(stats); } template static typename EnableIf::HAS_UPLOAD_STATS>::Value>::Type logUploadContribution (tcu::TestLog& log, const std::vector >& samples, const typename SampleTypeTraits::StatsType& stats) { DE_UNREF(log); DE_UNREF(samples); DE_UNREF(stats); } template static typename EnableIf::HAS_TOTAL_STATS>::Value>::Type logTotalContribution (tcu::TestLog& log, const std::vector >& samples, const typename SampleTypeTraits::StatsType& stats) { DE_UNREF(log); DE_UNREF(samples); DE_UNREF(stats); } template static typename EnableIf::HAS_FIRST_RENDER_STATS>::Value>::Type logFirstRenderContribution (tcu::TestLog& log, const std::vector >& samples, const typename SampleTypeTraits::StatsType& stats) { DE_UNREF(log); DE_UNREF(samples); DE_UNREF(stats); } template static typename EnableIf::HAS_SECOND_RENDER_STATS>::Value>::Type logSecondRenderContribution (tcu::TestLog& log, const std::vector >& samples, const typename SampleTypeTraits::StatsType& stats) { DE_UNREF(log); DE_UNREF(samples); DE_UNREF(stats); } void logSampleList (tcu::TestLog& log, const LineParametersWithConfidence& theilSenFitting, const std::vector >& samples) { log << tcu::TestLog::SampleList("Samples", "Samples") << tcu::TestLog::SampleInfo << tcu::TestLog::ValueInfo("WrittenSize", "Written size", "bytes", QP_SAMPLE_VALUE_TAG_PREDICTOR) << tcu::TestLog::ValueInfo("BufferSize", "Buffer size", "bytes", QP_SAMPLE_VALUE_TAG_PREDICTOR) << tcu::TestLog::ValueInfo("UploadTime", "Upload time", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::ValueInfo("FitResidual", "Fit residual", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::EndSampleInfo; for (int sampleNdx = 0; sampleNdx < (int)samples.size(); ++sampleNdx) { const float fitResidual = (float)samples[sampleNdx].duration.fitResponseDuration - (theilSenFitting.offset + theilSenFitting.coefficient * (float)samples[sampleNdx].writtenSize); log << tcu::TestLog::Sample << samples[sampleNdx].writtenSize << samples[sampleNdx].bufferSize << (int)samples[sampleNdx].duration.totalDuration << fitResidual << tcu::TestLog::EndSample; } log << tcu::TestLog::EndSampleList; } void logSampleList (tcu::TestLog& log, const LineParametersWithConfidence& theilSenFitting, const std::vector >& samples) { log << tcu::TestLog::SampleList("Samples", "Samples") << tcu::TestLog::SampleInfo << tcu::TestLog::ValueInfo("WrittenSize", "Written size", "bytes", QP_SAMPLE_VALUE_TAG_PREDICTOR) << tcu::TestLog::ValueInfo("BufferSize", "Buffer size", "bytes", QP_SAMPLE_VALUE_TAG_PREDICTOR) << tcu::TestLog::ValueInfo("TotalTime", "Total time", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::ValueInfo("AllocTime", "Alloc time", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::ValueInfo("MapTime", "Map time", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::ValueInfo("UnmapTime", "Unmap time", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::ValueInfo("WriteTime", "Write time", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::ValueInfo("FitResidual", "Fit residual", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::EndSampleInfo; for (int sampleNdx = 0; sampleNdx < (int)samples.size(); ++sampleNdx) { const float fitResidual = (float)samples[sampleNdx].duration.fitResponseDuration - (theilSenFitting.offset + theilSenFitting.coefficient * (float)samples[sampleNdx].writtenSize); log << tcu::TestLog::Sample << samples[sampleNdx].writtenSize << samples[sampleNdx].bufferSize << (int)samples[sampleNdx].duration.totalDuration << (int)samples[sampleNdx].duration.allocDuration << (int)samples[sampleNdx].duration.mapDuration << (int)samples[sampleNdx].duration.unmapDuration << (int)samples[sampleNdx].duration.writeDuration << fitResidual << tcu::TestLog::EndSample; } log << tcu::TestLog::EndSampleList; } void logSampleList (tcu::TestLog& log, const LineParametersWithConfidence& theilSenFitting, const std::vector >& samples) { log << tcu::TestLog::SampleList("Samples", "Samples") << tcu::TestLog::SampleInfo << tcu::TestLog::ValueInfo("WrittenSize", "Written size", "bytes", QP_SAMPLE_VALUE_TAG_PREDICTOR) << tcu::TestLog::ValueInfo("BufferSize", "Buffer size", "bytes", QP_SAMPLE_VALUE_TAG_PREDICTOR) << tcu::TestLog::ValueInfo("TotalTime", "Total time", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::ValueInfo("MapTime", "Map time", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::ValueInfo("UnmapTime", "Unmap time", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::ValueInfo("WriteTime", "Write time", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::ValueInfo("FitResidual", "Fit residual", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::EndSampleInfo; for (int sampleNdx = 0; sampleNdx < (int)samples.size(); ++sampleNdx) { const float fitResidual = (float)samples[sampleNdx].duration.fitResponseDuration - (theilSenFitting.offset + theilSenFitting.coefficient * (float)samples[sampleNdx].writtenSize); log << tcu::TestLog::Sample << samples[sampleNdx].writtenSize << samples[sampleNdx].bufferSize << (int)samples[sampleNdx].duration.totalDuration << (int)samples[sampleNdx].duration.mapDuration << (int)samples[sampleNdx].duration.unmapDuration << (int)samples[sampleNdx].duration.writeDuration << fitResidual << tcu::TestLog::EndSample; } log << tcu::TestLog::EndSampleList; } void logSampleList (tcu::TestLog& log, const LineParametersWithConfidence& theilSenFitting, const std::vector >& samples) { log << tcu::TestLog::SampleList("Samples", "Samples") << tcu::TestLog::SampleInfo << tcu::TestLog::ValueInfo("WrittenSize", "Written size", "bytes", QP_SAMPLE_VALUE_TAG_PREDICTOR) << tcu::TestLog::ValueInfo("BufferSize", "Buffer size", "bytes", QP_SAMPLE_VALUE_TAG_PREDICTOR) << tcu::TestLog::ValueInfo("TotalTime", "Total time", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::ValueInfo("AllocTime", "Alloc time", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::ValueInfo("MapTime", "Map time", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::ValueInfo("UnmapTime", "Unmap time", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::ValueInfo("WriteTime", "Write time", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::ValueInfo("FlushTime", "Flush time", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::ValueInfo("FitResidual", "Fit residual", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::EndSampleInfo; for (int sampleNdx = 0; sampleNdx < (int)samples.size(); ++sampleNdx) { const float fitResidual = (float)samples[sampleNdx].duration.fitResponseDuration - (theilSenFitting.offset + theilSenFitting.coefficient * (float)samples[sampleNdx].writtenSize); log << tcu::TestLog::Sample << samples[sampleNdx].writtenSize << samples[sampleNdx].bufferSize << (int)samples[sampleNdx].duration.totalDuration << (int)samples[sampleNdx].duration.allocDuration << (int)samples[sampleNdx].duration.mapDuration << (int)samples[sampleNdx].duration.unmapDuration << (int)samples[sampleNdx].duration.writeDuration << (int)samples[sampleNdx].duration.flushDuration << fitResidual << tcu::TestLog::EndSample; } log << tcu::TestLog::EndSampleList; } void logSampleList (tcu::TestLog& log, const LineParametersWithConfidence& theilSenFitting, const std::vector >& samples) { log << tcu::TestLog::SampleList("Samples", "Samples") << tcu::TestLog::SampleInfo << tcu::TestLog::ValueInfo("WrittenSize", "Written size", "bytes", QP_SAMPLE_VALUE_TAG_PREDICTOR) << tcu::TestLog::ValueInfo("BufferSize", "Buffer size", "bytes", QP_SAMPLE_VALUE_TAG_PREDICTOR) << tcu::TestLog::ValueInfo("TotalTime", "Total time", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::ValueInfo("MapTime", "Map time", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::ValueInfo("UnmapTime", "Unmap time", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::ValueInfo("WriteTime", "Write time", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::ValueInfo("FlushTime", "Flush time", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::ValueInfo("FitResidual", "Fit residual", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::EndSampleInfo; for (int sampleNdx = 0; sampleNdx < (int)samples.size(); ++sampleNdx) { const float fitResidual = (float)samples[sampleNdx].duration.fitResponseDuration - (theilSenFitting.offset + theilSenFitting.coefficient * (float)samples[sampleNdx].writtenSize); log << tcu::TestLog::Sample << samples[sampleNdx].writtenSize << samples[sampleNdx].bufferSize << (int)samples[sampleNdx].duration.totalDuration << (int)samples[sampleNdx].duration.mapDuration << (int)samples[sampleNdx].duration.unmapDuration << (int)samples[sampleNdx].duration.writeDuration << (int)samples[sampleNdx].duration.flushDuration << fitResidual << tcu::TestLog::EndSample; } log << tcu::TestLog::EndSampleList; } void logSampleList (tcu::TestLog& log, const LineParametersWithConfidence& theilSenFitting, const std::vector >& samples) { log << tcu::TestLog::SampleList("Samples", "Samples") << tcu::TestLog::SampleInfo << tcu::TestLog::ValueInfo("DataSize", "Data processed", "bytes", QP_SAMPLE_VALUE_TAG_PREDICTOR) << tcu::TestLog::ValueInfo("VertexCount", "Number of vertices", "vertices", QP_SAMPLE_VALUE_TAG_PREDICTOR) << tcu::TestLog::ValueInfo("TotalTime", "Total time", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::ValueInfo("DrawCallTime", "Draw call time", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::ValueInfo("ReadTime", "ReadPixels time", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::ValueInfo("FitResidual", "Fit residual", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::EndSampleInfo; for (int sampleNdx = 0; sampleNdx < (int)samples.size(); ++sampleNdx) { const float fitResidual = (float)samples[sampleNdx].duration.fitResponseDuration - (theilSenFitting.offset + theilSenFitting.coefficient * (float)samples[sampleNdx].renderDataSize); log << tcu::TestLog::Sample << samples[sampleNdx].renderDataSize << samples[sampleNdx].numVertices << (int)samples[sampleNdx].duration.renderReadDuration << (int)samples[sampleNdx].duration.renderDuration << (int)samples[sampleNdx].duration.readDuration << fitResidual << tcu::TestLog::EndSample; } log << tcu::TestLog::EndSampleList; } void logSampleList (tcu::TestLog& log, const LineParametersWithConfidence& theilSenFitting, const std::vector >& samples) { log << tcu::TestLog::SampleList("Samples", "Samples") << tcu::TestLog::SampleInfo << tcu::TestLog::ValueInfo("DataSize", "Data processed", "bytes", QP_SAMPLE_VALUE_TAG_PREDICTOR) << tcu::TestLog::ValueInfo("VertexCount", "Number of vertices", "vertices", QP_SAMPLE_VALUE_TAG_PREDICTOR) << tcu::TestLog::ValueInfo("UnrelatedUploadSize", "Unrelated upload size", "bytes", QP_SAMPLE_VALUE_TAG_PREDICTOR) << tcu::TestLog::ValueInfo("TotalTime", "Total time", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::ValueInfo("DrawCallTime", "Draw call time", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::ValueInfo("ReadTime", "ReadPixels time", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::ValueInfo("FitResidual", "Fit residual", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::EndSampleInfo; for (int sampleNdx = 0; sampleNdx < (int)samples.size(); ++sampleNdx) { const float fitResidual = (float)samples[sampleNdx].duration.fitResponseDuration - (theilSenFitting.offset + theilSenFitting.coefficient * (float)samples[sampleNdx].renderDataSize); log << tcu::TestLog::Sample << samples[sampleNdx].renderDataSize << samples[sampleNdx].numVertices << samples[sampleNdx].unrelatedDataSize << (int)samples[sampleNdx].duration.renderReadDuration << (int)samples[sampleNdx].duration.renderDuration << (int)samples[sampleNdx].duration.readDuration << fitResidual << tcu::TestLog::EndSample; } log << tcu::TestLog::EndSampleList; } void logSampleList (tcu::TestLog& log, const LineParametersWithConfidence& theilSenFitting, const std::vector >& samples) { log << tcu::TestLog::SampleList("Samples", "Samples") << tcu::TestLog::SampleInfo << tcu::TestLog::ValueInfo("DataSize", "Data processed", "bytes", QP_SAMPLE_VALUE_TAG_PREDICTOR) << tcu::TestLog::ValueInfo("UploadSize", "Data uploaded", "bytes", QP_SAMPLE_VALUE_TAG_PREDICTOR) << tcu::TestLog::ValueInfo("VertexCount", "Number of vertices", "vertices", QP_SAMPLE_VALUE_TAG_PREDICTOR) << tcu::TestLog::ValueInfo("DrawReadTime", "Draw call and ReadPixels time", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::ValueInfo("TotalTime", "Total time", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::ValueInfo("Upload time", "Upload time", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::ValueInfo("DrawCallTime", "Draw call time", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::ValueInfo("ReadTime", "ReadPixels time", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::ValueInfo("FitResidual", "Fit residual", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::EndSampleInfo; for (int sampleNdx = 0; sampleNdx < (int)samples.size(); ++sampleNdx) { const float fitResidual = (float)samples[sampleNdx].duration.fitResponseDuration - (theilSenFitting.offset + theilSenFitting.coefficient * (float)samples[sampleNdx].renderDataSize); log << tcu::TestLog::Sample << samples[sampleNdx].renderDataSize << samples[sampleNdx].uploadedDataSize << samples[sampleNdx].numVertices << (int)samples[sampleNdx].duration.renderReadDuration << (int)samples[sampleNdx].duration.totalDuration << (int)samples[sampleNdx].duration.uploadDuration << (int)samples[sampleNdx].duration.renderDuration << (int)samples[sampleNdx].duration.readDuration << fitResidual << tcu::TestLog::EndSample; } log << tcu::TestLog::EndSampleList; } void logSampleList (tcu::TestLog& log, const LineParametersWithConfidence& theilSenFitting, const std::vector >& samples) { log << tcu::TestLog::SampleList("Samples", "Samples") << tcu::TestLog::SampleInfo << tcu::TestLog::ValueInfo("DataSize", "Data processed", "bytes", QP_SAMPLE_VALUE_TAG_PREDICTOR) << tcu::TestLog::ValueInfo("UploadSize", "Data uploaded", "bytes", QP_SAMPLE_VALUE_TAG_PREDICTOR) << tcu::TestLog::ValueInfo("VertexCount", "Number of vertices", "vertices", QP_SAMPLE_VALUE_TAG_PREDICTOR) << tcu::TestLog::ValueInfo("UnrelatedUploadSize", "Unrelated upload size", "bytes", QP_SAMPLE_VALUE_TAG_PREDICTOR) << tcu::TestLog::ValueInfo("DrawReadTime", "Draw call and ReadPixels time", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::ValueInfo("TotalTime", "Total time", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::ValueInfo("Upload time", "Upload time", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::ValueInfo("DrawCallTime", "Draw call time", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::ValueInfo("ReadTime", "ReadPixels time", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::ValueInfo("FitResidual", "Fit residual", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::EndSampleInfo; for (int sampleNdx = 0; sampleNdx < (int)samples.size(); ++sampleNdx) { const float fitResidual = (float)samples[sampleNdx].duration.fitResponseDuration - (theilSenFitting.offset + theilSenFitting.coefficient * (float)samples[sampleNdx].renderDataSize); log << tcu::TestLog::Sample << samples[sampleNdx].renderDataSize << samples[sampleNdx].uploadedDataSize << samples[sampleNdx].numVertices << samples[sampleNdx].unrelatedDataSize << (int)samples[sampleNdx].duration.renderReadDuration << (int)samples[sampleNdx].duration.totalDuration << (int)samples[sampleNdx].duration.uploadDuration << (int)samples[sampleNdx].duration.renderDuration << (int)samples[sampleNdx].duration.readDuration << fitResidual << tcu::TestLog::EndSample; } log << tcu::TestLog::EndSampleList; } void logSampleList (tcu::TestLog& log, const LineParametersWithConfidence& theilSenFitting, const std::vector >& samples) { log << tcu::TestLog::SampleList("Samples", "Samples") << tcu::TestLog::SampleInfo << tcu::TestLog::ValueInfo("DataSize", "Data processed", "bytes", QP_SAMPLE_VALUE_TAG_PREDICTOR) << tcu::TestLog::ValueInfo("UploadSize", "Data uploaded", "bytes", QP_SAMPLE_VALUE_TAG_PREDICTOR) << tcu::TestLog::ValueInfo("VertexCount", "Number of vertices", "vertices", QP_SAMPLE_VALUE_TAG_PREDICTOR) << tcu::TestLog::ValueInfo("DrawReadTime", "Second draw call and ReadPixels time", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::ValueInfo("TotalTime", "Total time", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::ValueInfo("FirstDrawCallTime", "First draw call time", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::ValueInfo("Upload time", "Upload time", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::ValueInfo("SecondDrawCallTime", "Second draw call time", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::ValueInfo("ReadTime", "ReadPixels time", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::ValueInfo("FitResidual", "Fit residual", "us", QP_SAMPLE_VALUE_TAG_RESPONSE) << tcu::TestLog::EndSampleInfo; for (int sampleNdx = 0; sampleNdx < (int)samples.size(); ++sampleNdx) { const float fitResidual = (float)samples[sampleNdx].duration.fitResponseDuration - (theilSenFitting.offset + theilSenFitting.coefficient * (float)samples[sampleNdx].renderDataSize); log << tcu::TestLog::Sample << samples[sampleNdx].renderDataSize << samples[sampleNdx].uploadedDataSize << samples[sampleNdx].numVertices << (int)samples[sampleNdx].duration.renderReadDuration << (int)samples[sampleNdx].duration.totalDuration << (int)samples[sampleNdx].duration.firstRenderDuration << (int)samples[sampleNdx].duration.uploadDuration << (int)samples[sampleNdx].duration.secondRenderDuration << (int)samples[sampleNdx].duration.readDuration << fitResidual << tcu::TestLog::EndSample; } log << tcu::TestLog::EndSampleList; } template static UploadSampleAnalyzeResult analyzeSampleResults (tcu::TestLog& log, const std::vector >& samples, bool logBucketPerformance) { // Assume data is linear with some outliers, fit a line const LineParametersWithConfidence theilSenFitting = fitLineToSamples(samples); const typename SampleTypeTraits::StatsType resultStats = calculateSampleStatistics(theilSenFitting, samples); float approximatedTransferRate; float approximatedTransferRateNoConstant; // Output raw samples { const tcu::ScopedLogSection section(log, "Samples", "Samples"); logSampleList(log, theilSenFitting, samples); } // Calculate results for different ranges if (logBucketPerformance) { const int numBuckets = 4; int minBufferSize = 0; int maxBufferSize = 0; std::vector > buckets[numBuckets]; bucketizeSamplesUniformly(samples, &buckets[0], numBuckets, minBufferSize, maxBufferSize); for (int bucketNdx = 0; bucketNdx < numBuckets; ++bucketNdx) { if (buckets[bucketNdx].empty()) continue; // Print a nice result summary const int bucketRangeMin = minBufferSize + (int)(((float) bucketNdx / (float)numBuckets) * (float)(maxBufferSize - minBufferSize)); const int bucketRangeMax = minBufferSize + (int)(((float)(bucketNdx+1) / (float)numBuckets) * (float)(maxBufferSize - minBufferSize)); const typename SampleTypeTraits::StatsType stats = calculateSampleStatistics(theilSenFitting, buckets[bucketNdx]); const tcu::ScopedLogSection section (log, "BufferSizeRange", std::string("Transfer performance with buffer size in range [").append(getHumanReadableByteSize(bucketRangeMin).append(", ").append(getHumanReadableByteSize(bucketRangeMax).append("]")))); logMapRangeStats(log, stats); logUnmapStats(log, stats); logWriteStats(log, stats); logFlushStats(log, stats); logAllocStats(log, stats); log << tcu::TestLog::Float("Min", "Total: Min time", "us", QP_KEY_TAG_TIME, stats.result.minTime) << tcu::TestLog::Float("Max", "Total: Max time", "us", QP_KEY_TAG_TIME, stats.result.maxTime) << tcu::TestLog::Float("Min90", "Total: 90%-Min time", "us", QP_KEY_TAG_TIME, stats.result.min2DecileTime) << tcu::TestLog::Float("Max90", "Total: 90%-Max time", "us", QP_KEY_TAG_TIME, stats.result.max9DecileTime) << tcu::TestLog::Float("Median", "Total: Median time", "us", QP_KEY_TAG_TIME, stats.result.medianTime) << tcu::TestLog::Float("MedianTransfer", "Median transfer rate", "MB / s", QP_KEY_TAG_PERFORMANCE, stats.medianRate / 1024.0f / 1024.0f) << tcu::TestLog::Float("MaxDiff", "Max difference to approximated", "us", QP_KEY_TAG_TIME, stats.maxDiffTime) << tcu::TestLog::Float("Max90Diff", "90%-Max difference to approximated", "us", QP_KEY_TAG_TIME, stats.maxDiff9DecileTime) << tcu::TestLog::Float("MedianDiff", "Median difference to approximated", "us", QP_KEY_TAG_TIME, stats.medianDiffTime) << tcu::TestLog::Float("MaxRelDiff", "Max relative difference to approximated", "%", QP_KEY_TAG_NONE, stats.maxRelDiffTime * 100.0f) << tcu::TestLog::Float("Max90RelDiff", "90%-Max relative difference to approximated", "%", QP_KEY_TAG_NONE, stats.max9DecileRelDiffTime * 100.0f) << tcu::TestLog::Float("MedianRelDiff", "Median relative difference to approximated", "%", QP_KEY_TAG_NONE, stats.medianRelDiffTime * 100.0f); } } // Contributions if (SampleTypeTraits::LOG_CONTRIBUTIONS) { const tcu::ScopedLogSection section(log, "Contribution", "Contributions"); logMapContribution(log, samples, resultStats); logUnmapContribution(log, samples, resultStats); logWriteContribution(log, samples, resultStats); logFlushContribution(log, samples, resultStats); logAllocContribution(log, samples, resultStats); } // Print results { const tcu::ScopedLogSection section(log, "Results", "Results"); const int medianBufferSize = (samples.front().bufferSize + samples.back().bufferSize) / 2; const float approximatedTransferTime = (theilSenFitting.offset + theilSenFitting.coefficient * (float)medianBufferSize) / 1000.0f / 1000.0f; const float approximatedTransferTimeNoConstant = (theilSenFitting.coefficient * (float)medianBufferSize) / 1000.0f / 1000.0f; const float sampleLinearity = calculateSampleFitLinearity(samples); const float sampleTemporalStability = calculateSampleTemporalStability(samples); approximatedTransferRateNoConstant = (float)medianBufferSize / approximatedTransferTimeNoConstant; approximatedTransferRate = (float)medianBufferSize / approximatedTransferTime; log << tcu::TestLog::Float("ResultLinearity", "Sample linearity", "%", QP_KEY_TAG_QUALITY, sampleLinearity * 100.0f) << tcu::TestLog::Float("SampleTemporalStability", "Sample temporal stability", "%", QP_KEY_TAG_QUALITY, sampleTemporalStability * 100.0f) << tcu::TestLog::Float("ApproximatedConstantCost", "Approximated contant cost", "us", QP_KEY_TAG_TIME, theilSenFitting.offset) << tcu::TestLog::Float("ApproximatedConstantCostConfidence60Lower", "Approximated contant cost 60% confidence lower limit", "us", QP_KEY_TAG_TIME, theilSenFitting.offsetConfidenceLower) << tcu::TestLog::Float("ApproximatedConstantCostConfidence60Upper", "Approximated contant cost 60% confidence upper limit", "us", QP_KEY_TAG_TIME, theilSenFitting.offsetConfidenceUpper) << tcu::TestLog::Float("ApproximatedLinearCost", "Approximated linear cost", "us / MB", QP_KEY_TAG_TIME, theilSenFitting.coefficient * 1024.0f * 1024.0f) << tcu::TestLog::Float("ApproximatedLinearCostConfidence60Lower", "Approximated linear cost 60% confidence lower limit", "us / MB", QP_KEY_TAG_TIME, theilSenFitting.coefficientConfidenceLower * 1024.0f * 1024.0f) << tcu::TestLog::Float("ApproximatedLinearCostConfidence60Upper", "Approximated linear cost 60% confidence upper limit", "us / MB", QP_KEY_TAG_TIME, theilSenFitting.coefficientConfidenceUpper * 1024.0f * 1024.0f) << tcu::TestLog::Float("ApproximatedTransferRate", "Approximated transfer rate", "MB / s", QP_KEY_TAG_PERFORMANCE, approximatedTransferRate / 1024.0f / 1024.0f) << tcu::TestLog::Float("ApproximatedTransferRateNoConstant", "Approximated transfer rate without constant cost", "MB / s", QP_KEY_TAG_PERFORMANCE, approximatedTransferRateNoConstant / 1024.0f / 1024.0f) << tcu::TestLog::Float("SampleMedianTime", "Median sample time", "us", QP_KEY_TAG_TIME, resultStats.result.medianTime) << tcu::TestLog::Float("SampleMedianTransfer", "Median transfer rate", "MB / s", QP_KEY_TAG_PERFORMANCE, resultStats.medianRate / 1024.0f / 1024.0f); } // return approximated transfer rate { UploadSampleAnalyzeResult result; result.transferRateMedian = resultStats.medianRate; result.transferRateAtRange = approximatedTransferRate; result.transferRateAtInfinity = approximatedTransferRateNoConstant; return result; } } template static RenderSampleAnalyzeResult analyzeSampleResults (tcu::TestLog& log, const std::vector >& samples) { // Assume data is linear with some outliers, fit a line const LineParametersWithConfidence theilSenFitting = fitLineToSamples(samples); const typename SampleTypeTraits::StatsType resultStats = calculateSampleStatistics(theilSenFitting, samples); float approximatedProcessingRate; float approximatedProcessingRateNoConstant; // output raw samples { const tcu::ScopedLogSection section(log, "Samples", "Samples"); logSampleList(log, theilSenFitting, samples); } // Contributions if (SampleTypeTraits::LOG_CONTRIBUTIONS) { const tcu::ScopedLogSection section(log, "Contribution", "Contributions"); logFirstRenderContribution(log, samples, resultStats); logUploadContribution(log, samples, resultStats); logRenderContribution(log, samples, resultStats); logSecondRenderContribution(log, samples, resultStats); logReadContribution(log, samples, resultStats); logTotalContribution(log, samples, resultStats); } // print results { const tcu::ScopedLogSection section(log, "Results", "Results"); const int medianDataSize = (samples.front().renderDataSize + samples.back().renderDataSize) / 2; const float approximatedRenderTime = (theilSenFitting.offset + theilSenFitting.coefficient * (float)medianDataSize) / 1000.0f / 1000.0f; const float approximatedRenderTimeNoConstant = (theilSenFitting.coefficient * (float)medianDataSize) / 1000.0f / 1000.0f; const float sampleLinearity = calculateSampleFitLinearity(samples); const float sampleTemporalStability = calculateSampleTemporalStability(samples); approximatedProcessingRateNoConstant = (float)medianDataSize / approximatedRenderTimeNoConstant; approximatedProcessingRate = (float)medianDataSize / approximatedRenderTime; log << tcu::TestLog::Float("ResultLinearity", "Sample linearity", "%", QP_KEY_TAG_QUALITY, sampleLinearity * 100.0f) << tcu::TestLog::Float("SampleTemporalStability", "Sample temporal stability", "%", QP_KEY_TAG_QUALITY, sampleTemporalStability * 100.0f) << tcu::TestLog::Float("ApproximatedConstantCost", "Approximated contant cost", "us", QP_KEY_TAG_TIME, theilSenFitting.offset) << tcu::TestLog::Float("ApproximatedConstantCostConfidence60Lower", "Approximated contant cost 60% confidence lower limit", "us", QP_KEY_TAG_TIME, theilSenFitting.offsetConfidenceLower) << tcu::TestLog::Float("ApproximatedConstantCostConfidence60Upper", "Approximated contant cost 60% confidence upper limit", "us", QP_KEY_TAG_TIME, theilSenFitting.offsetConfidenceUpper) << tcu::TestLog::Float("ApproximatedLinearCost", "Approximated linear cost", "us / MB", QP_KEY_TAG_TIME, theilSenFitting.coefficient * 1024.0f * 1024.0f) << tcu::TestLog::Float("ApproximatedLinearCostConfidence60Lower", "Approximated linear cost 60% confidence lower limit", "us / MB", QP_KEY_TAG_TIME, theilSenFitting.coefficientConfidenceLower * 1024.0f * 1024.0f) << tcu::TestLog::Float("ApproximatedLinearCostConfidence60Upper", "Approximated linear cost 60% confidence upper limit", "us / MB", QP_KEY_TAG_TIME, theilSenFitting.coefficientConfidenceUpper * 1024.0f * 1024.0f) << tcu::TestLog::Float("ApproximatedProcessRate", "Approximated processing rate", "MB / s", QP_KEY_TAG_PERFORMANCE, approximatedProcessingRate / 1024.0f / 1024.0f) << tcu::TestLog::Float("ApproximatedProcessRateNoConstant", "Approximated processing rate without constant cost", "MB / s", QP_KEY_TAG_PERFORMANCE, approximatedProcessingRateNoConstant / 1024.0f / 1024.0f) << tcu::TestLog::Float("SampleMedianTime", "Median sample time", "us", QP_KEY_TAG_TIME, resultStats.result.medianTime) << tcu::TestLog::Float("SampleMedianProcess", "Median processing rate", "MB / s", QP_KEY_TAG_PERFORMANCE, resultStats.medianRate / 1024.0f / 1024.0f); } // return approximated render rate { RenderSampleAnalyzeResult result; result.renderRateMedian = resultStats.medianRate; result.renderRateAtRange = approximatedProcessingRate; result.renderRateAtInfinity = approximatedProcessingRateNoConstant; return result; } return RenderSampleAnalyzeResult(); } static void generateTwoPassRandomIterationOrder (std::vector& iterationOrder, int numSamples) { de::Random rnd (0xabc); const int midPoint = (numSamples+1) / 2; // !< ceil(m_numSamples / 2) DE_ASSERT((int)iterationOrder.size() == numSamples); // Two "passes" over range, randomize order in both passes // This allows to us detect if iterations are not independent // (first run and later run samples differ significantly?) for (int sampleNdx = 0; sampleNdx < midPoint; ++sampleNdx) iterationOrder[sampleNdx] = sampleNdx * 2; for (int sampleNdx = midPoint; sampleNdx < numSamples; ++sampleNdx) iterationOrder[sampleNdx] = (sampleNdx - midPoint) * 2 + 1; for (int ndx = 0; ndx < midPoint; ++ndx) std::swap(iterationOrder[ndx], iterationOrder[rnd.getInt(0, midPoint - 1)]); for (int ndx = midPoint; ndx < (int)iterationOrder.size(); ++ndx) std::swap(iterationOrder[ndx], iterationOrder[rnd.getInt(midPoint, (int)iterationOrder.size()-1)]); } template class BasicBufferCase : public TestCase { public: enum Flags { FLAG_ALLOCATE_LARGER_BUFFER = 0x01, }; BasicBufferCase (Context& context, const char* name, const char* desc, int bufferSizeMin, int bufferSizeMax, int numSamples, int flags); ~BasicBufferCase (void); virtual void init (void); virtual void deinit (void); protected: IterateResult iterate (void); virtual bool runSample (int iteration, UploadSampleResult& sample) = 0; virtual void logAndSetTestResult (const std::vector >& results) = 0; void disableGLWarmup (void); void waitGLResults (void); enum { DUMMY_RENDER_AREA_SIZE = 32 }; glu::ShaderProgram* m_dummyProgram; deInt32 m_dummyProgramPosLoc; deUint32 m_bufferID; const int m_numSamples; const int m_bufferSizeMin; const int m_bufferSizeMax; const bool m_allocateLargerBuffer; private: int m_iteration; std::vector m_iterationOrder; std::vector > m_results; bool m_useGL; int m_bufferRandomizerTimer; }; template BasicBufferCase::BasicBufferCase (Context& context, const char* name, const char* desc, int bufferSizeMin, int bufferSizeMax, int numSamples, int flags) : TestCase (context, tcu::NODETYPE_PERFORMANCE, name, desc) , m_dummyProgram (DE_NULL) , m_dummyProgramPosLoc (-1) , m_bufferID (0) , m_numSamples (numSamples) , m_bufferSizeMin (bufferSizeMin) , m_bufferSizeMax (bufferSizeMax) , m_allocateLargerBuffer ((flags & FLAG_ALLOCATE_LARGER_BUFFER) != 0) , m_iteration (0) , m_iterationOrder (numSamples) , m_results (numSamples) , m_useGL (true) , m_bufferRandomizerTimer (0) { // "randomize" iteration order. Deterministic, patternless generateTwoPassRandomIterationOrder(m_iterationOrder, m_numSamples); // choose buffer sizes for (int sampleNdx = 0; sampleNdx < m_numSamples; ++sampleNdx) { const int rawBufferSize = (int)deFloatFloor((float)bufferSizeMin + (float)(bufferSizeMax - bufferSizeMin) * ((float)(sampleNdx + 1) / (float)m_numSamples)); const int bufferSize = deAlign32(rawBufferSize, 16); const int allocatedBufferSize = deAlign32((m_allocateLargerBuffer) ? ((int)((float)bufferSize * 1.5f)) : (bufferSize), 16); m_results[sampleNdx].bufferSize = bufferSize; m_results[sampleNdx].allocatedSize = allocatedBufferSize; m_results[sampleNdx].writtenSize = -1; } } template BasicBufferCase::~BasicBufferCase (void) { deinit(); } template void BasicBufferCase::init (void) { const glw::Functions& gl = m_context.getRenderContext().getFunctions(); if (!m_useGL) return; // \note Viewport size is not checked, it won't matter if the render target actually is smaller hhan DUMMY_RENDER_AREA_SIZE // dummy shader m_dummyProgram = new glu::ShaderProgram(m_context.getRenderContext(), glu::ProgramSources() << glu::VertexSource(s_dummyVertexShader) << glu::FragmentSource(s_dummyFragnentShader)); if (!m_dummyProgram->isOk()) { m_testCtx.getLog() << *m_dummyProgram; throw tcu::TestError("failed to build shader program"); } m_dummyProgramPosLoc = gl.getAttribLocation(m_dummyProgram->getProgram(), "a_position"); if (m_dummyProgramPosLoc == -1) throw tcu::TestError("a_position location was -1"); } template void BasicBufferCase::deinit (void) { if (m_bufferID) { m_context.getRenderContext().getFunctions().deleteBuffers(1, &m_bufferID); m_bufferID = 0; } delete m_dummyProgram; m_dummyProgram = DE_NULL; } template TestCase::IterateResult BasicBufferCase::iterate (void) { const glw::Functions& gl = m_context.getRenderContext().getFunctions(); static bool buffersWarmedUp = false; static const deUint32 usages[] = { GL_STREAM_DRAW, GL_STREAM_READ, GL_STREAM_COPY, GL_STATIC_DRAW, GL_STATIC_READ, GL_STATIC_COPY, GL_DYNAMIC_DRAW, GL_DYNAMIC_READ, GL_DYNAMIC_COPY, }; // Allocate some random sized buffers and remove them to // make sure the first samples too have some buffers removed // just before their allocation. This is only needed by the // the first test. if (m_useGL && !buffersWarmedUp) { const int numRandomBuffers = 6; const int numRepeats = 10; const int maxBufferSize = 16777216; const std::vector zeroData (maxBufferSize, 0x00); de::Random rnd (0x1234); deUint32 bufferIDs[numRandomBuffers] = {0}; gl.useProgram(m_dummyProgram->getProgram()); gl.viewport(0, 0, DUMMY_RENDER_AREA_SIZE, DUMMY_RENDER_AREA_SIZE); gl.enableVertexAttribArray(m_dummyProgramPosLoc); for (int ndx = 0; ndx < numRepeats; ++ndx) { // Create buffer and maybe draw from it for (int randomBufferNdx = 0; randomBufferNdx < numRandomBuffers; ++randomBufferNdx) { const int randomSize = deAlign32(rnd.getInt(1, maxBufferSize), 4*4); const deUint32 usage = usages[rnd.getUint32() % (deUint32)DE_LENGTH_OF_ARRAY(usages)]; gl.genBuffers(1, &bufferIDs[randomBufferNdx]); gl.bindBuffer(GL_ARRAY_BUFFER, bufferIDs[randomBufferNdx]); gl.bufferData(GL_ARRAY_BUFFER, randomSize, &zeroData[0], usage); if (rnd.getBool()) { gl.vertexAttribPointer(m_dummyProgramPosLoc, 4, GL_FLOAT, GL_FALSE, 0, DE_NULL); gl.drawArrays(GL_POINTS, 0, 1); gl.drawArrays(GL_POINTS, randomSize / (int)sizeof(float[4]) - 1, 1); } } for (int randomBufferNdx = 0; randomBufferNdx < numRandomBuffers; ++randomBufferNdx) gl.deleteBuffers(1, &bufferIDs[randomBufferNdx]); waitGLResults(); GLU_EXPECT_NO_ERROR(gl.getError(), "Buffer gen"); m_testCtx.touchWatchdog(); } buffersWarmedUp = true; return CONTINUE; } else if (m_useGL && m_bufferRandomizerTimer++ % 8 == 0) { // Do some random buffer operations to every now and then // to make sure the previous test iterations won't affect // following test runs. const int numRandomBuffers = 3; const int maxBufferSize = 16777216; const std::vector zeroData (maxBufferSize, 0x00); de::Random rnd (0x1234 + 0xabc * m_bufferRandomizerTimer); // BufferData { deUint32 bufferIDs[numRandomBuffers] = {0}; for (int randomBufferNdx = 0; randomBufferNdx < numRandomBuffers; ++randomBufferNdx) { const int randomSize = deAlign32(rnd.getInt(1, maxBufferSize), 4*4); const deUint32 usage = usages[rnd.getUint32() % (deUint32)DE_LENGTH_OF_ARRAY(usages)]; gl.genBuffers(1, &bufferIDs[randomBufferNdx]); gl.bindBuffer(GL_ARRAY_BUFFER, bufferIDs[randomBufferNdx]); gl.bufferData(GL_ARRAY_BUFFER, randomSize, &zeroData[0], usage); } for (int randomBufferNdx = 0; randomBufferNdx < numRandomBuffers; ++randomBufferNdx) gl.deleteBuffers(1, &bufferIDs[randomBufferNdx]); } GLU_EXPECT_NO_ERROR(gl.getError(), "buffer ops"); // Do some memory mappings { deUint32 bufferIDs[numRandomBuffers] = {0}; for (int randomBufferNdx = 0; randomBufferNdx < numRandomBuffers; ++randomBufferNdx) { const int randomSize = deAlign32(rnd.getInt(1, maxBufferSize), 4*4); const deUint32 usage = usages[rnd.getUint32() % (deUint32)DE_LENGTH_OF_ARRAY(usages)]; void* ptr; gl.genBuffers(1, &bufferIDs[randomBufferNdx]); gl.bindBuffer(GL_ARRAY_BUFFER, bufferIDs[randomBufferNdx]); gl.bufferData(GL_ARRAY_BUFFER, randomSize, &zeroData[0], usage); gl.vertexAttribPointer(m_dummyProgramPosLoc, 4, GL_FLOAT, GL_FALSE, 0, DE_NULL); gl.drawArrays(GL_POINTS, 0, 1); gl.drawArrays(GL_POINTS, randomSize / (int)sizeof(float[4]) - 1, 1); if (rnd.getBool()) waitGLResults(); ptr = gl.mapBufferRange(GL_ARRAY_BUFFER, 0, randomSize, GL_MAP_WRITE_BIT); if (ptr) { medianTimeMemcpy(ptr, &zeroData[0], randomSize); gl.unmapBuffer(GL_ARRAY_BUFFER); } } for (int randomBufferNdx = 0; randomBufferNdx < numRandomBuffers; ++randomBufferNdx) gl.deleteBuffers(1, &bufferIDs[randomBufferNdx]); waitGLResults(); } GLU_EXPECT_NO_ERROR(gl.getError(), "buffer maps"); return CONTINUE; } else { const int currentIteration = m_iteration; const int sampleNdx = m_iterationOrder[currentIteration]; const bool sampleRunSuccessful = runSample(currentIteration, m_results[sampleNdx]); GLU_EXPECT_NO_ERROR(gl.getError(), "post runSample()"); // Retry failed samples if (!sampleRunSuccessful) return CONTINUE; if (++m_iteration >= m_numSamples) { logAndSetTestResult(m_results); return STOP; } else return CONTINUE; } } template void BasicBufferCase::disableGLWarmup (void) { m_useGL = false; } template void BasicBufferCase::waitGLResults (void) { tcu::Surface dummySurface(DUMMY_RENDER_AREA_SIZE, DUMMY_RENDER_AREA_SIZE); glu::readPixels(m_context.getRenderContext(), 0, 0, dummySurface.getAccess()); } template class BasicUploadCase : public BasicBufferCase { public: enum CaseType { CASE_NO_BUFFERS = 0, CASE_NEW_BUFFER, CASE_UNSPECIFIED_BUFFER, CASE_SPECIFIED_BUFFER, CASE_USED_BUFFER, CASE_USED_LARGER_BUFFER, CASE_LAST }; enum CaseFlags { FLAG_DONT_LOG_BUFFER_INFO = 0x01, FLAG_RESULT_BUFFER_UNSPECIFIED_CONTENT = 0x02, }; enum ResultType { RESULT_MEDIAN_TRANSFER_RATE = 0, RESULT_ASYMPTOTIC_TRANSFER_RATE, }; BasicUploadCase (Context& context, const char* name, const char* desc, int bufferSizeMin, int bufferSizeMax, int numSamples, deUint32 bufferUsage, CaseType caseType, ResultType resultType, int flags = 0); ~BasicUploadCase (void); virtual void init (void); virtual void deinit (void); private: bool runSample (int iteration, UploadSampleResult& sample); void createBuffer (int bufferSize, int iteration); void deleteBuffer (int bufferSize); void useBuffer (int bufferSize); virtual void testBufferUpload (UploadSampleResult& result, int writeSize) = 0; void logAndSetTestResult (const std::vector >& results); deUint32 m_dummyBufferID; protected: const CaseType m_caseType; const ResultType m_resultType; const deUint32 m_bufferUsage; const bool m_logBufferInfo; const bool m_bufferUnspecifiedContent; std::vector m_zeroData; using BasicBufferCase::m_testCtx; using BasicBufferCase::m_context; using BasicBufferCase::DUMMY_RENDER_AREA_SIZE; using BasicBufferCase::m_dummyProgram; using BasicBufferCase::m_dummyProgramPosLoc; using BasicBufferCase::m_bufferID; using BasicBufferCase::m_numSamples; using BasicBufferCase::m_bufferSizeMin; using BasicBufferCase::m_bufferSizeMax; using BasicBufferCase::m_allocateLargerBuffer; }; template BasicUploadCase::BasicUploadCase (Context& context, const char* name, const char* desc, int bufferSizeMin, int bufferSizeMax, int numSamples, deUint32 bufferUsage, CaseType caseType, ResultType resultType, int flags) : BasicBufferCase (context, name, desc, bufferSizeMin, bufferSizeMax, numSamples, (caseType == CASE_USED_LARGER_BUFFER) ? (BasicBufferCase::FLAG_ALLOCATE_LARGER_BUFFER) : (0)) , m_dummyBufferID (0) , m_caseType (caseType) , m_resultType (resultType) , m_bufferUsage (bufferUsage) , m_logBufferInfo ((flags & FLAG_DONT_LOG_BUFFER_INFO) == 0) , m_bufferUnspecifiedContent ((flags & FLAG_RESULT_BUFFER_UNSPECIFIED_CONTENT) != 0) , m_zeroData () { DE_ASSERT(m_caseType < CASE_LAST); } template BasicUploadCase::~BasicUploadCase (void) { deinit(); } template void BasicUploadCase::init (void) { const glw::Functions& gl = m_context.getRenderContext().getFunctions(); BasicBufferCase::init(); // zero buffer as upload source m_zeroData.resize(m_bufferSizeMax, 0x00); // dummy buffer gl.genBuffers(1, &m_dummyBufferID); GLU_EXPECT_NO_ERROR(gl.getError(), "Gen buf"); // log basic info m_testCtx.getLog() << tcu::TestLog::Message << "Testing performance with " << m_numSamples << " test samples. Sample order is randomized. All samples at even positions (first = 0) are tested before samples at odd positions.\n" << "Buffer sizes are in range [" << getHumanReadableByteSize(m_bufferSizeMin) << ", " << getHumanReadableByteSize(m_bufferSizeMax) << "]." << tcu::TestLog::EndMessage; if (m_logBufferInfo) { switch (m_caseType) { case CASE_NO_BUFFERS: break; case CASE_NEW_BUFFER: m_testCtx.getLog() << tcu::TestLog::Message << "Target buffer is generated but not specified (i.e glBufferData() not called)." << tcu::TestLog::EndMessage; break; case CASE_UNSPECIFIED_BUFFER: m_testCtx.getLog() << tcu::TestLog::Message << "Target buffer is allocated with glBufferData(NULL)." << tcu::TestLog::EndMessage; break; case CASE_SPECIFIED_BUFFER: m_testCtx.getLog() << tcu::TestLog::Message << "Target buffer contents are specified prior testing with glBufferData(data)." << tcu::TestLog::EndMessage; break; case CASE_USED_BUFFER: m_testCtx.getLog() << tcu::TestLog::Message << "Target buffer has been used in drawing before testing." << tcu::TestLog::EndMessage; break; case CASE_USED_LARGER_BUFFER: m_testCtx.getLog() << tcu::TestLog::Message << "Target buffer is larger and has been used in drawing before testing." << tcu::TestLog::EndMessage; break; default: DE_ASSERT(false); break; } } if (m_resultType == RESULT_MEDIAN_TRANSFER_RATE) m_testCtx.getLog() << tcu::TestLog::Message << "Test result is the median transfer rate of the test samples." << tcu::TestLog::EndMessage; else if (m_resultType == RESULT_ASYMPTOTIC_TRANSFER_RATE) m_testCtx.getLog() << tcu::TestLog::Message << "Test result is the asymptotic transfer rate as the buffer size approaches infinity." << tcu::TestLog::EndMessage; else DE_ASSERT(false); } template void BasicUploadCase::deinit (void) { if (m_dummyBufferID) { m_context.getRenderContext().getFunctions().deleteBuffers(1, &m_dummyBufferID); m_dummyBufferID = 0; } m_zeroData = std::vector(); BasicBufferCase::deinit(); } template bool BasicUploadCase::runSample (int iteration, UploadSampleResult& sample) { const glw::Functions& gl = m_context.getRenderContext().getFunctions(); const int allocatedBufferSize = sample.allocatedSize; const int bufferSize = sample.bufferSize; if (m_caseType != CASE_NO_BUFFERS) createBuffer(iteration, allocatedBufferSize); // warmup CPU before the test to make sure the power management governor // keeps us in the "high performance" mode { deYield(); tcu::warmupCPU(); deYield(); } testBufferUpload(sample, bufferSize); GLU_EXPECT_NO_ERROR(gl.getError(), "Buffer upload sample"); if (m_caseType != CASE_NO_BUFFERS) deleteBuffer(bufferSize); return true; } template void BasicUploadCase::createBuffer (int iteration, int bufferSize) { DE_ASSERT(!m_bufferID); DE_ASSERT(m_caseType != CASE_NO_BUFFERS); const glw::Functions& gl = m_context.getRenderContext().getFunctions(); // create buffer if (m_caseType == CASE_NO_BUFFERS) return; // create empty buffer gl.genBuffers(1, &m_bufferID); gl.bindBuffer(GL_ARRAY_BUFFER, m_bufferID); GLU_EXPECT_NO_ERROR(gl.getError(), "Buffer gen"); if (m_caseType == CASE_NEW_BUFFER) { // upload something else first, this should reduce noise in samples de::Random rng (0xbadc * iteration); const int sizeDelta = rng.getInt(0, 2097140); const int dummyUploadSize = deAlign32(1048576 + sizeDelta, 4*4); // Vary buffer size to make sure it is always reallocated const std::vector dummyData (dummyUploadSize, 0x20); gl.bindBuffer(GL_ARRAY_BUFFER, m_dummyBufferID); gl.bufferData(GL_ARRAY_BUFFER, dummyUploadSize, &dummyData[0], m_bufferUsage); // make sure upload won't interfere with the test useBuffer(dummyUploadSize); // don't kill the buffer so that the following upload cannot potentially reuse the buffer return; } // specify it if (m_caseType == CASE_UNSPECIFIED_BUFFER) gl.bufferData(GL_ARRAY_BUFFER, bufferSize, DE_NULL, m_bufferUsage); else { const std::vector dummyData(bufferSize, 0x20); gl.bufferData(GL_ARRAY_BUFFER, bufferSize, &dummyData[0], m_bufferUsage); } if (m_caseType == CASE_UNSPECIFIED_BUFFER || m_caseType == CASE_SPECIFIED_BUFFER) return; // use it and make sure it is uploaded useBuffer(bufferSize); DE_ASSERT(m_caseType == CASE_USED_BUFFER || m_caseType == CASE_USED_LARGER_BUFFER); } template void BasicUploadCase::deleteBuffer (int bufferSize) { DE_ASSERT(m_bufferID); DE_ASSERT(m_caseType != CASE_NO_BUFFERS); // render from the buffer to make sure it actually made it to the gpu. This is to // make sure that if the upload actually happens later or is happening right now in // the background, it will not interfere with further test runs // if buffer contains unspecified content, sourcing data from it results in undefined // results, possibly including program termination. Specify all data to prevent such // case from happening const glw::Functions& gl = m_context.getRenderContext().getFunctions(); gl.bindBuffer(GL_ARRAY_BUFFER, m_bufferID); if (m_bufferUnspecifiedContent) { const std::vector dummyData(bufferSize, 0x20); gl.bufferData(GL_ARRAY_BUFFER, bufferSize, &dummyData[0], m_bufferUsage); GLU_EXPECT_NO_ERROR(gl.getError(), "re-specify buffer"); } useBuffer(bufferSize); gl.deleteBuffers(1, &m_bufferID); m_bufferID = 0; } template void BasicUploadCase::useBuffer (int bufferSize) { const glw::Functions& gl = m_context.getRenderContext().getFunctions(); gl.useProgram(m_dummyProgram->getProgram()); gl.viewport(0, 0, DUMMY_RENDER_AREA_SIZE, DUMMY_RENDER_AREA_SIZE); gl.vertexAttribPointer(m_dummyProgramPosLoc, 4, GL_FLOAT, GL_FALSE, 0, DE_NULL); gl.enableVertexAttribArray(m_dummyProgramPosLoc); // use whole buffer to make sure buffer is uploaded by drawing first and last DE_ASSERT(bufferSize % (int)sizeof(float[4]) == 0); gl.drawArrays(GL_POINTS, 0, 1); gl.drawArrays(GL_POINTS, bufferSize / (int)sizeof(float[4]) - 1, 1); BasicBufferCase::waitGLResults(); } template void BasicUploadCase::logAndSetTestResult (const std::vector >& results) { const UploadSampleAnalyzeResult analysis = analyzeSampleResults(m_testCtx.getLog(), results, true); // with small buffers, report the median transfer rate of the samples // with large buffers, report the expected preformance of infinitely large buffers const float rate = (m_resultType == RESULT_ASYMPTOTIC_TRANSFER_RATE) ? (analysis.transferRateAtInfinity) : (analysis.transferRateMedian); if (rate == std::numeric_limits::infinity()) { // sample times are 1) invalid or 2) timer resolution too low // report speed 0 bytes / s since real value cannot be determined m_testCtx.setTestResult(QP_TEST_RESULT_PASS, de::floatToString(0.0f, 2).c_str()); } else { // report transfer rate in MB / s m_testCtx.setTestResult(QP_TEST_RESULT_PASS, de::floatToString(rate / 1024.0f / 1024.0f, 2).c_str()); } } class ReferenceMemcpyCase : public BasicUploadCase { public: ReferenceMemcpyCase (Context& ctx, const char* name, const char* desc, int minBufferSize, int maxBufferSize, int numSamples, bool largeBuffersCase); ~ReferenceMemcpyCase (void); void init (void); void deinit (void); private: void testBufferUpload (UploadSampleResult& result, int bufferSize); std::vector m_dstBuf; }; ReferenceMemcpyCase::ReferenceMemcpyCase (Context& ctx, const char* name, const char* desc, int minBufferSize, int maxBufferSize, int numSamples, bool largeBuffersCase) : BasicUploadCase (ctx, name, desc, minBufferSize, maxBufferSize, numSamples, 0, CASE_NO_BUFFERS, (largeBuffersCase) ? (RESULT_ASYMPTOTIC_TRANSFER_RATE) : (RESULT_MEDIAN_TRANSFER_RATE)) , m_dstBuf () { disableGLWarmup(); } ReferenceMemcpyCase::~ReferenceMemcpyCase (void) { } void ReferenceMemcpyCase::init (void) { // Describe what the test tries to do m_testCtx.getLog() << tcu::TestLog::Message << "Testing performance of memcpy()." << tcu::TestLog::EndMessage; m_dstBuf.resize(m_bufferSizeMax, 0x00); BasicUploadCase::init(); } void ReferenceMemcpyCase::deinit (void) { m_dstBuf = std::vector(); BasicUploadCase::deinit(); } void ReferenceMemcpyCase::testBufferUpload (UploadSampleResult& result, int bufferSize) { // write result.duration.totalDuration = medianTimeMemcpy(&m_dstBuf[0], &m_zeroData[0], bufferSize); result.duration.fitResponseDuration = result.duration.totalDuration; result.writtenSize = bufferSize; } class BufferDataUploadCase : public BasicUploadCase { public: BufferDataUploadCase (Context& ctx, const char* name, const char* desc, int minBufferSize, int maxBufferSize, int numSamples, deUint32 bufferUsage, CaseType caseType); ~BufferDataUploadCase (void); void init (void); private: void testBufferUpload (UploadSampleResult& result, int bufferSize); }; BufferDataUploadCase::BufferDataUploadCase (Context& ctx, const char* name, const char* desc, int minBufferSize, int maxBufferSize, int numSamples, deUint32 bufferUsage, CaseType caseType) : BasicUploadCase(ctx, name, desc, minBufferSize, maxBufferSize, numSamples, bufferUsage, caseType, RESULT_MEDIAN_TRANSFER_RATE) { } BufferDataUploadCase::~BufferDataUploadCase (void) { } void BufferDataUploadCase::init (void) { // Describe what the test tries to do m_testCtx.getLog() << tcu::TestLog::Message << "Testing glBufferData() function." << tcu::TestLog::EndMessage; BasicUploadCase::init(); } void BufferDataUploadCase::testBufferUpload (UploadSampleResult& result, int bufferSize) { const glw::Functions& gl = m_context.getRenderContext().getFunctions(); gl.bindBuffer(GL_ARRAY_BUFFER, m_bufferID); // upload { deUint64 startTime; deUint64 endTime; startTime = deGetMicroseconds(); gl.bufferData(GL_ARRAY_BUFFER, bufferSize, &m_zeroData[0], m_bufferUsage); endTime = deGetMicroseconds(); result.duration.totalDuration = endTime - startTime; result.duration.fitResponseDuration = result.duration.totalDuration; result.writtenSize = bufferSize; } } class BufferSubDataUploadCase : public BasicUploadCase { public: enum Flags { FLAG_FULL_UPLOAD = 0x01, FLAG_PARTIAL_UPLOAD = 0x02, FLAG_INVALIDATE_BEFORE_USE = 0x04, }; BufferSubDataUploadCase (Context& ctx, const char* name, const char* desc, int minBufferSize, int maxBufferSize, int numSamples, deUint32 bufferUsage, CaseType parentCase, int flags); ~BufferSubDataUploadCase (void); void init (void); private: void testBufferUpload (UploadSampleResult& result, int bufferSize); const bool m_fullUpload; const bool m_invalidateBeforeUse; }; BufferSubDataUploadCase::BufferSubDataUploadCase (Context& ctx, const char* name, const char* desc, int minBufferSize, int maxBufferSize, int numSamples, deUint32 bufferUsage, CaseType parentCase, int flags) : BasicUploadCase (ctx, name, desc, minBufferSize, maxBufferSize, numSamples, bufferUsage, parentCase, RESULT_MEDIAN_TRANSFER_RATE) , m_fullUpload ((flags & FLAG_FULL_UPLOAD) != 0) , m_invalidateBeforeUse ((flags & FLAG_INVALIDATE_BEFORE_USE) != 0) { DE_ASSERT((flags & (FLAG_FULL_UPLOAD | FLAG_PARTIAL_UPLOAD)) != 0); DE_ASSERT((flags & (FLAG_FULL_UPLOAD | FLAG_PARTIAL_UPLOAD)) != (FLAG_FULL_UPLOAD | FLAG_PARTIAL_UPLOAD)); } BufferSubDataUploadCase::~BufferSubDataUploadCase (void) { } void BufferSubDataUploadCase::init (void) { // Describe what the test tries to do m_testCtx.getLog() << tcu::TestLog::Message << "Testing glBufferSubData() function call performance. " << ((m_fullUpload) ? ("The whole buffer is updated with glBufferSubData. ") : ("Half of the buffer data is updated with glBufferSubData. ")) << ((m_invalidateBeforeUse) ? ("The buffer is cleared with glBufferData(..., NULL) before glBufferSubData upload.") : ("")) << "\n" << tcu::TestLog::EndMessage; BasicUploadCase::init(); } void BufferSubDataUploadCase::testBufferUpload (UploadSampleResult& result, int bufferSize) { const glw::Functions& gl = m_context.getRenderContext().getFunctions(); gl.bindBuffer(GL_ARRAY_BUFFER, m_bufferID); // "invalidate", upload null if (m_invalidateBeforeUse) gl.bufferData(GL_ARRAY_BUFFER, bufferSize, DE_NULL, m_bufferUsage); // upload { deUint64 startTime; deUint64 endTime; startTime = deGetMicroseconds(); if (m_fullUpload) gl.bufferSubData(GL_ARRAY_BUFFER, 0, bufferSize, &m_zeroData[0]); else { // upload to buffer center gl.bufferSubData(GL_ARRAY_BUFFER, bufferSize / 4, bufferSize / 2, &m_zeroData[0]); } endTime = deGetMicroseconds(); result.duration.totalDuration = endTime - startTime; result.duration.fitResponseDuration = result.duration.totalDuration; if (m_fullUpload) result.writtenSize = bufferSize; else result.writtenSize = bufferSize / 2; } } class MapBufferRangeCase : public BasicUploadCase { public: enum Flags { FLAG_PARTIAL = 0x01, FLAG_MANUAL_INVALIDATION = 0x02, FLAG_USE_UNUSED_UNSPECIFIED_BUFFER = 0x04, FLAG_USE_UNUSED_SPECIFIED_BUFFER = 0x08, }; MapBufferRangeCase (Context& ctx, const char* name, const char* desc, int minBufferSize, int maxBufferSize, int numSamples, deUint32 bufferUsage, deUint32 mapFlags, int caseFlags); ~MapBufferRangeCase (void); void init (void); private: static CaseType getBaseCaseType (int caseFlags); static int getBaseFlags (deUint32 mapFlags, int caseFlags); void testBufferUpload (UploadSampleResult& result, int bufferSize); void attemptBufferMap (UploadSampleResult& result, int bufferSize); const bool m_manualInvalidation; const bool m_fullUpload; const bool m_useUnusedUnspecifiedBuffer; const bool m_useUnusedSpecifiedBuffer; const deUint32 m_mapFlags; int m_unmapFailures; }; MapBufferRangeCase::MapBufferRangeCase (Context& ctx, const char* name, const char* desc, int minBufferSize, int maxBufferSize, int numSamples, deUint32 bufferUsage, deUint32 mapFlags, int caseFlags) : BasicUploadCase (ctx, name, desc, minBufferSize, maxBufferSize, numSamples, bufferUsage, getBaseCaseType(caseFlags), RESULT_MEDIAN_TRANSFER_RATE, getBaseFlags(mapFlags, caseFlags)) , m_manualInvalidation ((caseFlags&FLAG_MANUAL_INVALIDATION) != 0) , m_fullUpload ((caseFlags&FLAG_PARTIAL) == 0) , m_useUnusedUnspecifiedBuffer ((caseFlags&FLAG_USE_UNUSED_UNSPECIFIED_BUFFER) != 0) , m_useUnusedSpecifiedBuffer ((caseFlags&FLAG_USE_UNUSED_SPECIFIED_BUFFER) != 0) , m_mapFlags (mapFlags) , m_unmapFailures (0) { DE_ASSERT(!(m_useUnusedUnspecifiedBuffer && m_useUnusedSpecifiedBuffer)); DE_ASSERT(!((m_useUnusedUnspecifiedBuffer || m_useUnusedSpecifiedBuffer) && m_manualInvalidation)); } MapBufferRangeCase::~MapBufferRangeCase (void) { } void MapBufferRangeCase::init (void) { // Describe what the test tries to do m_testCtx.getLog() << tcu::TestLog::Message << "Testing glMapBufferRange() and glUnmapBuffer() function call performance.\n" << ((m_fullUpload) ? ("The whole buffer is mapped.") : ("Half of the buffer is mapped.")) << "\n" << ((m_useUnusedUnspecifiedBuffer) ? ("The buffer has not been used before mapping and is allocated with unspecified contents.\n") : ("")) << ((m_useUnusedSpecifiedBuffer) ? ("The buffer has not been used before mapping and is allocated with specified contents.\n") : ("")) << ((!m_useUnusedSpecifiedBuffer && !m_useUnusedUnspecifiedBuffer) ? ("The buffer has previously been used in a drawing operation.\n") : ("")) << ((m_manualInvalidation) ? ("The buffer is cleared with glBufferData(..., NULL) before mapping.\n") : ("")) << "Map bits:\n" << ((m_mapFlags & GL_MAP_WRITE_BIT) ? ("\tGL_MAP_WRITE_BIT\n") : ("")) << ((m_mapFlags & GL_MAP_READ_BIT) ? ("\tGL_MAP_READ_BIT\n") : ("")) << ((m_mapFlags & GL_MAP_INVALIDATE_RANGE_BIT) ? ("\tGL_MAP_INVALIDATE_RANGE_BIT\n") : ("")) << ((m_mapFlags & GL_MAP_INVALIDATE_BUFFER_BIT) ? ("\tGL_MAP_INVALIDATE_BUFFER_BIT\n") : ("")) << ((m_mapFlags & GL_MAP_UNSYNCHRONIZED_BIT) ? ("\tGL_MAP_UNSYNCHRONIZED_BIT\n") : ("")) << tcu::TestLog::EndMessage; BasicUploadCase::init(); } MapBufferRangeCase::CaseType MapBufferRangeCase::getBaseCaseType (int caseFlags) { if ((caseFlags & FLAG_USE_UNUSED_UNSPECIFIED_BUFFER) == 0 && (caseFlags & FLAG_USE_UNUSED_SPECIFIED_BUFFER) == 0) return CASE_USED_BUFFER; else return CASE_NEW_BUFFER; } int MapBufferRangeCase::getBaseFlags (deUint32 mapFlags, int caseFlags) { int flags = FLAG_DONT_LOG_BUFFER_INFO; // If buffer contains unspecified data when it is sourced (i.e drawn) // results are undefined, and system errors may occur. Signal parent // class to take this into account if (caseFlags & FLAG_PARTIAL) { if ((mapFlags & GL_MAP_INVALIDATE_BUFFER_BIT) != 0 || (caseFlags & FLAG_MANUAL_INVALIDATION) != 0 || (caseFlags & FLAG_USE_UNUSED_UNSPECIFIED_BUFFER) != 0) { flags |= FLAG_RESULT_BUFFER_UNSPECIFIED_CONTENT; } } return flags; } void MapBufferRangeCase::testBufferUpload (UploadSampleResult& result, int bufferSize) { const int unmapFailureThreshold = 4; for (; m_unmapFailures < unmapFailureThreshold; ++m_unmapFailures) { try { attemptBufferMap(result, bufferSize); return; } catch (UnmapFailureError&) { } } throw tcu::TestError("Unmapping failures exceeded limit"); } void MapBufferRangeCase::attemptBufferMap (UploadSampleResult& result, int bufferSize) { const glw::Functions& gl = m_context.getRenderContext().getFunctions(); gl.bindBuffer(GL_ARRAY_BUFFER, m_bufferID); if (m_fullUpload) result.writtenSize = bufferSize; else result.writtenSize = bufferSize / 2; // Create unused buffer if (m_manualInvalidation || m_useUnusedUnspecifiedBuffer) { deUint64 startTime; deUint64 endTime; // "invalidate" or allocate, upload null startTime = deGetMicroseconds(); gl.bufferData(GL_ARRAY_BUFFER, bufferSize, DE_NULL, m_bufferUsage); endTime = deGetMicroseconds(); result.duration.allocDuration = endTime - startTime; } else if (m_useUnusedSpecifiedBuffer) { deUint64 startTime; deUint64 endTime; // Specify buffer contents startTime = deGetMicroseconds(); gl.bufferData(GL_ARRAY_BUFFER, bufferSize, &m_zeroData[0], m_bufferUsage); endTime = deGetMicroseconds(); result.duration.allocDuration = endTime - startTime; } else { // No alloc, no time result.duration.allocDuration = 0; } // upload { void* mapPtr; // Map { deUint64 startTime; deUint64 endTime; startTime = deGetMicroseconds(); if (m_fullUpload) mapPtr = gl.mapBufferRange(GL_ARRAY_BUFFER, 0, result.writtenSize, m_mapFlags); else { // upload to buffer center mapPtr = gl.mapBufferRange(GL_ARRAY_BUFFER, bufferSize / 4, result.writtenSize, m_mapFlags); } endTime = deGetMicroseconds(); if (!mapPtr) throw tcu::Exception("MapBufferRange returned NULL"); result.duration.mapDuration = endTime - startTime; } // Write { result.duration.writeDuration = medianTimeMemcpy(mapPtr, &m_zeroData[0], result.writtenSize); } // Unmap { deUint64 startTime; deUint64 endTime; glw::GLboolean unmapSuccessful; startTime = deGetMicroseconds(); unmapSuccessful = gl.unmapBuffer(GL_ARRAY_BUFFER); endTime = deGetMicroseconds(); // if unmapping fails, just try again later if (!unmapSuccessful) throw UnmapFailureError(); result.duration.unmapDuration = endTime - startTime; } result.duration.totalDuration = result.duration.mapDuration + result.duration.writeDuration + result.duration.unmapDuration + result.duration.allocDuration; result.duration.fitResponseDuration = result.duration.totalDuration; } } class MapBufferRangeFlushCase : public BasicUploadCase { public: enum Flags { FLAG_PARTIAL = 0x01, FLAG_FLUSH_IN_PARTS = 0x02, FLAG_USE_UNUSED_UNSPECIFIED_BUFFER = 0x04, FLAG_USE_UNUSED_SPECIFIED_BUFFER = 0x08, FLAG_FLUSH_PARTIAL = 0x10, }; MapBufferRangeFlushCase (Context& ctx, const char* name, const char* desc, int minBufferSize, int maxBufferSize, int numSamples, deUint32 bufferUsage, deUint32 mapFlags, int caseFlags); ~MapBufferRangeFlushCase (void); void init (void); private: static CaseType getBaseCaseType (int caseFlags); static int getBaseFlags (deUint32 mapFlags, int caseFlags); void testBufferUpload (UploadSampleResult& result, int bufferSize); void attemptBufferMap (UploadSampleResult& result, int bufferSize); const bool m_fullUpload; const bool m_flushInParts; const bool m_flushPartial; const bool m_useUnusedUnspecifiedBuffer; const bool m_useUnusedSpecifiedBuffer; const deUint32 m_mapFlags; int m_unmapFailures; }; MapBufferRangeFlushCase::MapBufferRangeFlushCase (Context& ctx, const char* name, const char* desc, int minBufferSize, int maxBufferSize, int numSamples, deUint32 bufferUsage, deUint32 mapFlags, int caseFlags) : BasicUploadCase (ctx, name, desc, minBufferSize, maxBufferSize, numSamples, bufferUsage, getBaseCaseType(caseFlags), RESULT_MEDIAN_TRANSFER_RATE, getBaseFlags(mapFlags, caseFlags)) , m_fullUpload ((caseFlags&FLAG_PARTIAL) == 0) , m_flushInParts ((caseFlags&FLAG_FLUSH_IN_PARTS) != 0) , m_flushPartial ((caseFlags&FLAG_FLUSH_PARTIAL) != 0) , m_useUnusedUnspecifiedBuffer ((caseFlags&FLAG_USE_UNUSED_UNSPECIFIED_BUFFER) != 0) , m_useUnusedSpecifiedBuffer ((caseFlags&FLAG_USE_UNUSED_SPECIFIED_BUFFER) != 0) , m_mapFlags (mapFlags) , m_unmapFailures (0) { DE_ASSERT(!(m_flushPartial && m_flushInParts)); DE_ASSERT(!(m_flushPartial && !m_fullUpload)); } MapBufferRangeFlushCase::~MapBufferRangeFlushCase (void) { } void MapBufferRangeFlushCase::init (void) { // Describe what the test tries to do m_testCtx.getLog() << tcu::TestLog::Message << "Testing glMapBufferRange(), glFlushMappedBufferRange() and glUnmapBuffer() function call performance.\n" << ((m_fullUpload) ? ("The whole buffer is mapped.") : ("Half of the buffer is mapped.")) << "\n" << ((m_flushInParts) ? ("The mapped range is partitioned to 4 subranges and each partition is flushed separately.") : (m_flushPartial) ? ("Half of the buffer range is flushed.") : ("The whole mapped range is flushed in one flush call.")) << "\n" << ((m_useUnusedUnspecifiedBuffer) ? ("The buffer has not been used before mapping and is allocated with unspecified contents.\n") : ("")) << ((m_useUnusedSpecifiedBuffer) ? ("The buffer has not been used before mapping and is allocated with specified contents.\n") : ("")) << ((!m_useUnusedSpecifiedBuffer && !m_useUnusedUnspecifiedBuffer) ? ("The buffer has previously been used in a drawing operation.\n") : ("")) << "Map bits:\n" << ((m_mapFlags & GL_MAP_WRITE_BIT) ? ("\tGL_MAP_WRITE_BIT\n") : ("")) << ((m_mapFlags & GL_MAP_READ_BIT) ? ("\tGL_MAP_READ_BIT\n") : ("")) << ((m_mapFlags & GL_MAP_INVALIDATE_RANGE_BIT) ? ("\tGL_MAP_INVALIDATE_RANGE_BIT\n") : ("")) << ((m_mapFlags & GL_MAP_INVALIDATE_BUFFER_BIT) ? ("\tGL_MAP_INVALIDATE_BUFFER_BIT\n") : ("")) << ((m_mapFlags & GL_MAP_UNSYNCHRONIZED_BIT) ? ("\tGL_MAP_UNSYNCHRONIZED_BIT\n") : ("")) << ((m_mapFlags & GL_MAP_FLUSH_EXPLICIT_BIT) ? ("\tGL_MAP_FLUSH_EXPLICIT_BIT\n") : ("")) << tcu::TestLog::EndMessage; BasicUploadCase::init(); } MapBufferRangeFlushCase::CaseType MapBufferRangeFlushCase::getBaseCaseType (int caseFlags) { if ((caseFlags & FLAG_USE_UNUSED_UNSPECIFIED_BUFFER) == 0 && (caseFlags & FLAG_USE_UNUSED_SPECIFIED_BUFFER) == 0) return CASE_USED_BUFFER; else return CASE_NEW_BUFFER; } int MapBufferRangeFlushCase::getBaseFlags (deUint32 mapFlags, int caseFlags) { int flags = FLAG_DONT_LOG_BUFFER_INFO; // If buffer contains unspecified data when it is sourced (i.e drawn) // results are undefined, and system errors may occur. Signal parent // class to take this into account if (caseFlags & FLAG_PARTIAL) { if ((mapFlags & GL_MAP_INVALIDATE_BUFFER_BIT) != 0 || (caseFlags & FLAG_USE_UNUSED_UNSPECIFIED_BUFFER) != 0 || (caseFlags & FLAG_FLUSH_PARTIAL) != 0) { flags |= FLAG_RESULT_BUFFER_UNSPECIFIED_CONTENT; } } return flags; } void MapBufferRangeFlushCase::testBufferUpload (UploadSampleResult& result, int bufferSize) { const int unmapFailureThreshold = 4; for (; m_unmapFailures < unmapFailureThreshold; ++m_unmapFailures) { try { attemptBufferMap(result, bufferSize); return; } catch (UnmapFailureError&) { } } throw tcu::TestError("Unmapping failures exceeded limit"); } void MapBufferRangeFlushCase::attemptBufferMap (UploadSampleResult& result, int bufferSize) { const glw::Functions& gl = m_context.getRenderContext().getFunctions(); const int mappedSize = (m_fullUpload) ? (bufferSize) : (bufferSize / 2); if (m_fullUpload && !m_flushPartial) result.writtenSize = bufferSize; else result.writtenSize = bufferSize / 2; gl.bindBuffer(GL_ARRAY_BUFFER, m_bufferID); // Create unused buffer if (m_useUnusedUnspecifiedBuffer) { deUint64 startTime; deUint64 endTime; // Don't specify contents startTime = deGetMicroseconds(); gl.bufferData(GL_ARRAY_BUFFER, bufferSize, DE_NULL, m_bufferUsage); endTime = deGetMicroseconds(); result.duration.allocDuration = endTime - startTime; } else if (m_useUnusedSpecifiedBuffer) { deUint64 startTime; deUint64 endTime; // Specify buffer contents startTime = deGetMicroseconds(); gl.bufferData(GL_ARRAY_BUFFER, bufferSize, &m_zeroData[0], m_bufferUsage); endTime = deGetMicroseconds(); result.duration.allocDuration = endTime - startTime; } else { // No alloc, no time result.duration.allocDuration = 0; } // upload { void* mapPtr; // Map { deUint64 startTime; deUint64 endTime; startTime = deGetMicroseconds(); if (m_fullUpload) mapPtr = gl.mapBufferRange(GL_ARRAY_BUFFER, 0, mappedSize, m_mapFlags); else { // upload to buffer center mapPtr = gl.mapBufferRange(GL_ARRAY_BUFFER, bufferSize / 4, mappedSize, m_mapFlags); } endTime = deGetMicroseconds(); if (!mapPtr) throw tcu::Exception("MapBufferRange returned NULL"); result.duration.mapDuration = endTime - startTime; } // Write { if (!m_flushPartial) result.duration.writeDuration = medianTimeMemcpy(mapPtr, &m_zeroData[0], result.writtenSize); else result.duration.writeDuration = medianTimeMemcpy((deUint8*)mapPtr + bufferSize / 4, &m_zeroData[0], result.writtenSize); } // Flush { deUint64 startTime; deUint64 endTime; startTime = deGetMicroseconds(); if (m_flushPartial) gl.flushMappedBufferRange(GL_ARRAY_BUFFER, mappedSize/4, mappedSize/2); else if (!m_flushInParts) gl.flushMappedBufferRange(GL_ARRAY_BUFFER, 0, mappedSize); else { const int p1 = 0; const int p2 = mappedSize / 3; const int p3 = mappedSize / 2; const int p4 = mappedSize * 2 / 4; const int p5 = mappedSize; // flush in mixed order gl.flushMappedBufferRange(GL_ARRAY_BUFFER, p2, p3-p2); gl.flushMappedBufferRange(GL_ARRAY_BUFFER, p1, p2-p1); gl.flushMappedBufferRange(GL_ARRAY_BUFFER, p4, p5-p4); gl.flushMappedBufferRange(GL_ARRAY_BUFFER, p3, p4-p3); } endTime = deGetMicroseconds(); result.duration.flushDuration = endTime - startTime; } // Unmap { deUint64 startTime; deUint64 endTime; glw::GLboolean unmapSuccessful; startTime = deGetMicroseconds(); unmapSuccessful = gl.unmapBuffer(GL_ARRAY_BUFFER); endTime = deGetMicroseconds(); // if unmapping fails, just try again later if (!unmapSuccessful) throw UnmapFailureError(); result.duration.unmapDuration = endTime - startTime; } result.duration.totalDuration = result.duration.mapDuration + result.duration.writeDuration + result.duration.flushDuration + result.duration.unmapDuration + result.duration.allocDuration; result.duration.fitResponseDuration = result.duration.totalDuration; } } template class ModifyAfterBasicCase : public BasicBufferCase { public: ModifyAfterBasicCase (Context& context, const char* name, const char* description, int bufferSizeMin, int bufferSizeMax, deUint32 usage, bool bufferUnspecifiedAfterTest); ~ModifyAfterBasicCase (void); void init (void); void deinit (void); protected: void drawBufferRange (int begin, int end); private: enum { NUM_SAMPLES = 20, }; bool runSample (int iteration, UploadSampleResult& sample); bool prepareAndRunTest (int iteration, UploadSampleResult& result, int bufferSize); void logAndSetTestResult (const std::vector >& results); virtual void testWithBufferSize (UploadSampleResult& result, int bufferSize) = 0; int m_unmappingErrors; protected: const bool m_bufferUnspecifiedAfterTest; const deUint32 m_bufferUsage; std::vector m_zeroData; using BasicBufferCase::m_testCtx; using BasicBufferCase::m_context; using BasicBufferCase::DUMMY_RENDER_AREA_SIZE; using BasicBufferCase::m_dummyProgram; using BasicBufferCase::m_dummyProgramPosLoc; using BasicBufferCase::m_bufferID; using BasicBufferCase::m_numSamples; using BasicBufferCase::m_bufferSizeMin; using BasicBufferCase::m_bufferSizeMax; using BasicBufferCase::m_allocateLargerBuffer; }; template ModifyAfterBasicCase::ModifyAfterBasicCase (Context& context, const char* name, const char* description, int bufferSizeMin, int bufferSizeMax, deUint32 usage, bool bufferUnspecifiedAfterTest) : BasicBufferCase (context, name, description, bufferSizeMin, bufferSizeMax, NUM_SAMPLES, 0) , m_unmappingErrors (0) , m_bufferUnspecifiedAfterTest (bufferUnspecifiedAfterTest) , m_bufferUsage (usage) , m_zeroData () { } template ModifyAfterBasicCase::~ModifyAfterBasicCase (void) { BasicBufferCase::deinit(); } template void ModifyAfterBasicCase::init (void) { const glw::Functions& gl = m_context.getRenderContext().getFunctions(); // init parent BasicBufferCase::init(); // upload source m_zeroData.resize(m_bufferSizeMax, 0x00); // log basic info m_testCtx.getLog() << tcu::TestLog::Message << "Testing performance with " << (int)NUM_SAMPLES << " test samples. Sample order is randomized. All samples at even positions (first = 0) are tested before samples at odd positions.\n" << "Buffer sizes are in range [" << getHumanReadableByteSize(m_bufferSizeMin) << ", " << getHumanReadableByteSize(m_bufferSizeMax) << "]." << tcu::TestLog::EndMessage; // log which transfer rate is the test result and buffer info m_testCtx.getLog() << tcu::TestLog::Message << "Test result is the median transfer rate of the test samples.\n" << "Buffer usage = " << glu::getUsageName(m_bufferUsage) << tcu::TestLog::EndMessage; // Set state for drawing so that we don't have to change these during the iteration { gl.useProgram(m_dummyProgram->getProgram()); gl.viewport(0, 0, DUMMY_RENDER_AREA_SIZE, DUMMY_RENDER_AREA_SIZE); gl.enableVertexAttribArray(m_dummyProgramPosLoc); } } template void ModifyAfterBasicCase::deinit (void) { m_zeroData = std::vector(); BasicBufferCase::deinit(); } template void ModifyAfterBasicCase::drawBufferRange (int begin, int end) { DE_ASSERT(begin % (int)sizeof(float[4]) == 0); DE_ASSERT(end % (int)sizeof(float[4]) == 0); const glw::Functions& gl = m_context.getRenderContext().getFunctions(); // use given range gl.drawArrays(GL_POINTS, begin / (int)sizeof(float[4]), 1); gl.drawArrays(GL_POINTS, end / (int)sizeof(float[4]) - 1, 1); } template bool ModifyAfterBasicCase::runSample (int iteration, UploadSampleResult& sample) { const glw::Functions& gl = m_context.getRenderContext().getFunctions(); const int bufferSize = sample.bufferSize; bool testOk; testOk = prepareAndRunTest(iteration, sample, bufferSize); GLU_EXPECT_NO_ERROR(gl.getError(), "Buffer upload sample"); if (!testOk) { const int unmapFailureThreshold = 4; // only unmapping error can cause iteration failure if (++m_unmappingErrors >= unmapFailureThreshold) throw tcu::TestError("Too many unmapping errors, cannot continue."); // just try again return false; } return true; } template bool ModifyAfterBasicCase::prepareAndRunTest (int iteration, UploadSampleResult& result, int bufferSize) { DE_UNREF(iteration); DE_ASSERT(!m_bufferID); DE_ASSERT(deIsAligned32(bufferSize, 4*4)); // aligned to vec4 const glw::Functions& gl = m_context.getRenderContext().getFunctions(); bool testRunOk = true; bool unmappingFailed = false; // Upload initial buffer to the GPU... gl.genBuffers(1, &m_bufferID); gl.bindBuffer(GL_ARRAY_BUFFER, m_bufferID); gl.bufferData(GL_ARRAY_BUFFER, bufferSize, &m_zeroData[0], m_bufferUsage); // ...use it... gl.vertexAttribPointer(m_dummyProgramPosLoc, 4, GL_FLOAT, GL_FALSE, 0, DE_NULL); drawBufferRange(0, bufferSize); // ..and make sure it is uploaded BasicBufferCase::waitGLResults(); // warmup CPU before the test to make sure the power management governor // keeps us in the "high performance" mode { deYield(); tcu::warmupCPU(); deYield(); } // test try { // buffer is uploaded to the GPU. Draw from it. drawBufferRange(0, bufferSize); // and test upload testWithBufferSize(result, bufferSize); } catch (UnmapFailureError&) { testRunOk = false; unmappingFailed = true; } // clean up: make sure buffer is not in upload queue and delete it // sourcing unspecified data causes undefined results, possibly program termination if (m_bufferUnspecifiedAfterTest || unmappingFailed) gl.bufferData(GL_ARRAY_BUFFER, bufferSize, &m_zeroData[0], m_bufferUsage); drawBufferRange(0, bufferSize); BasicBufferCase::waitGLResults(); gl.deleteBuffers(1, &m_bufferID); m_bufferID = 0; return testRunOk; } template void ModifyAfterBasicCase::logAndSetTestResult (const std::vector >& results) { const UploadSampleAnalyzeResult analysis = analyzeSampleResults(m_testCtx.getLog(), results, false); // Return median transfer rate of the samples if (analysis.transferRateMedian == std::numeric_limits::infinity()) { // sample times are 1) invalid or 2) timer resolution too low // report speed 0 bytes / s since real value cannot be determined m_testCtx.setTestResult(QP_TEST_RESULT_PASS, de::floatToString(0.0f, 2).c_str()); } else { // report transfer rate in MB / s m_testCtx.setTestResult(QP_TEST_RESULT_PASS, de::floatToString(analysis.transferRateMedian / 1024.0f / 1024.0f, 2).c_str()); } } class ModifyAfterWithBufferDataCase : public ModifyAfterBasicCase { public: enum CaseFlags { FLAG_RESPECIFY_SIZE = 0x1, FLAG_UPLOAD_REPEATED = 0x2, }; ModifyAfterWithBufferDataCase (Context& context, const char* name, const char* desc, int bufferSizeMin, int bufferSizeMax, deUint32 usage, int flags); ~ModifyAfterWithBufferDataCase (void); void init (void); void deinit (void); private: void testWithBufferSize (UploadSampleResult& result, int bufferSize); enum { NUM_REPEATS = 2 }; const bool m_respecifySize; const bool m_repeatedUpload; const float m_sizeDifferenceFactor; }; ModifyAfterWithBufferDataCase::ModifyAfterWithBufferDataCase (Context& context, const char* name, const char* desc, int bufferSizeMin, int bufferSizeMax, deUint32 usage, int flags) : ModifyAfterBasicCase (context, name, desc, bufferSizeMin, bufferSizeMax, usage, false) , m_respecifySize ((flags & FLAG_RESPECIFY_SIZE) != 0) , m_repeatedUpload ((flags & FLAG_UPLOAD_REPEATED) != 0) , m_sizeDifferenceFactor (1.3f) { DE_ASSERT(!(m_repeatedUpload && m_respecifySize)); } ModifyAfterWithBufferDataCase::~ModifyAfterWithBufferDataCase (void) { deinit(); } void ModifyAfterWithBufferDataCase::init (void) { // Log the purpose of the test if (m_repeatedUpload) m_testCtx.getLog() << tcu::TestLog::Message << "Testing performance of BufferData() command after \"specify buffer contents - draw buffer\" command pair is repeated " << (int)NUM_REPEATS << " times." << tcu::TestLog::EndMessage; else m_testCtx.getLog() << tcu::TestLog::Message << "Testing performance of BufferData() command after a draw command that sources data from the target buffer." << tcu::TestLog::EndMessage; m_testCtx.getLog() << tcu::TestLog::Message << ((m_respecifySize) ? ("Buffer size is increased and contents are modified with BufferData().\n") : ("Buffer contents are modified with BufferData().\n")) << tcu::TestLog::EndMessage; // init parent ModifyAfterBasicCase::init(); // make sure our zeroBuffer is large enough if (m_respecifySize) { const int largerBufferSize = deAlign32((int)((float)m_bufferSizeMax * m_sizeDifferenceFactor), 4*4); m_zeroData.resize(largerBufferSize, 0x00); } } void ModifyAfterWithBufferDataCase::deinit (void) { ModifyAfterBasicCase::deinit(); } void ModifyAfterWithBufferDataCase::testWithBufferSize (UploadSampleResult& result, int bufferSize) { // always draw the same amount to make compares between cases sensible const int drawStart = deAlign32(bufferSize / 4, 4*4); const int drawEnd = deAlign32(bufferSize * 3 / 4, 4*4); const glw::Functions& gl = m_context.getRenderContext().getFunctions(); const int largerBufferSize = deAlign32((int)((float)bufferSize * m_sizeDifferenceFactor), 4*4); const int newBufferSize = (m_respecifySize) ? (largerBufferSize) : (bufferSize); deUint64 startTime; deUint64 endTime; // repeat upload-draw if (m_repeatedUpload) { for (int repeatNdx = 0; repeatNdx < NUM_REPEATS; ++repeatNdx) { gl.bufferData(GL_ARRAY_BUFFER, newBufferSize, &m_zeroData[0], m_bufferUsage); drawBufferRange(drawStart, drawEnd); } } // test upload startTime = deGetMicroseconds(); gl.bufferData(GL_ARRAY_BUFFER, newBufferSize, &m_zeroData[0], m_bufferUsage); endTime = deGetMicroseconds(); result.duration.totalDuration = endTime - startTime; result.duration.fitResponseDuration = result.duration.totalDuration; result.writtenSize = newBufferSize; } class ModifyAfterWithBufferSubDataCase : public ModifyAfterBasicCase { public: enum CaseFlags { FLAG_PARTIAL = 0x1, FLAG_UPLOAD_REPEATED = 0x2, }; ModifyAfterWithBufferSubDataCase (Context& context, const char* name, const char* desc, int bufferSizeMin, int bufferSizeMax, deUint32 usage, int flags); ~ModifyAfterWithBufferSubDataCase (void); void init (void); void deinit (void); private: void testWithBufferSize (UploadSampleResult& result, int bufferSize); enum { NUM_REPEATS = 2 }; const bool m_partialUpload; const bool m_repeatedUpload; }; ModifyAfterWithBufferSubDataCase::ModifyAfterWithBufferSubDataCase (Context& context, const char* name, const char* desc, int bufferSizeMin, int bufferSizeMax, deUint32 usage, int flags) : ModifyAfterBasicCase (context, name, desc, bufferSizeMin, bufferSizeMax, usage, false) , m_partialUpload ((flags & FLAG_PARTIAL) != 0) , m_repeatedUpload ((flags & FLAG_UPLOAD_REPEATED) != 0) { } ModifyAfterWithBufferSubDataCase::~ModifyAfterWithBufferSubDataCase (void) { deinit(); } void ModifyAfterWithBufferSubDataCase::init (void) { // Log the purpose of the test if (m_repeatedUpload) m_testCtx.getLog() << tcu::TestLog::Message << "Testing performance of BufferSubData() command after \"specify buffer contents - draw buffer\" command pair is repeated " << (int)NUM_REPEATS << " times." << tcu::TestLog::EndMessage; else m_testCtx.getLog() << tcu::TestLog::Message << "Testing performance of BufferSubData() command after a draw command that sources data from the target buffer." << tcu::TestLog::EndMessage; m_testCtx.getLog() << tcu::TestLog::Message << ((m_partialUpload) ? ("Half of the buffer contents are modified.\n") : ("Buffer contents are fully respecified.\n")) << tcu::TestLog::EndMessage; ModifyAfterBasicCase::init(); } void ModifyAfterWithBufferSubDataCase::deinit (void) { ModifyAfterBasicCase::deinit(); } void ModifyAfterWithBufferSubDataCase::testWithBufferSize (UploadSampleResult& result, int bufferSize) { // always draw the same amount to make compares between cases sensible const int drawStart = deAlign32(bufferSize / 4, 4*4); const int drawEnd = deAlign32(bufferSize * 3 / 4, 4*4); const glw::Functions& gl = m_context.getRenderContext().getFunctions(); const int subdataOffset = deAlign32((m_partialUpload) ? (bufferSize / 4) : (0), 4*4); const int subdataSize = deAlign32((m_partialUpload) ? (bufferSize / 2) : (bufferSize), 4*4); deUint64 startTime; deUint64 endTime; // make upload-draw stream if (m_repeatedUpload) { for (int repeatNdx = 0; repeatNdx < NUM_REPEATS; ++repeatNdx) { gl.bufferSubData(GL_ARRAY_BUFFER, subdataOffset, subdataSize, &m_zeroData[0]); drawBufferRange(drawStart, drawEnd); } } // test upload startTime = deGetMicroseconds(); gl.bufferSubData(GL_ARRAY_BUFFER, subdataOffset, subdataSize, &m_zeroData[0]); endTime = deGetMicroseconds(); result.duration.totalDuration = endTime - startTime; result.duration.fitResponseDuration = result.duration.totalDuration; result.writtenSize = subdataSize; } class ModifyAfterWithMapBufferRangeCase : public ModifyAfterBasicCase { public: enum CaseFlags { FLAG_PARTIAL = 0x1, }; ModifyAfterWithMapBufferRangeCase (Context& context, const char* name, const char* desc, int bufferSizeMin, int bufferSizeMax, deUint32 usage, int flags, deUint32 glMapFlags); ~ModifyAfterWithMapBufferRangeCase (void); void init (void); void deinit (void); private: static bool isBufferUnspecifiedAfterUpload (int flags, deUint32 mapFlags); void testWithBufferSize (UploadSampleResult& result, int bufferSize); const bool m_partialUpload; const deUint32 m_mapFlags; }; ModifyAfterWithMapBufferRangeCase::ModifyAfterWithMapBufferRangeCase (Context& context, const char* name, const char* desc, int bufferSizeMin, int bufferSizeMax, deUint32 usage, int flags, deUint32 glMapFlags) : ModifyAfterBasicCase (context, name, desc, bufferSizeMin, bufferSizeMax, usage, isBufferUnspecifiedAfterUpload(flags, glMapFlags)) , m_partialUpload ((flags & FLAG_PARTIAL) != 0) , m_mapFlags (glMapFlags) { } ModifyAfterWithMapBufferRangeCase::~ModifyAfterWithMapBufferRangeCase (void) { deinit(); } void ModifyAfterWithMapBufferRangeCase::init (void) { // Log the purpose of the test m_testCtx.getLog() << tcu::TestLog::Message << "Testing performance of MapBufferRange() command after a draw command that sources data from the target buffer.\n" << ((m_partialUpload) ? ("Half of the buffer is mapped.\n") : ("Whole buffer is mapped.\n")) << "Map bits:\n" << ((m_mapFlags & GL_MAP_WRITE_BIT) ? ("\tGL_MAP_WRITE_BIT\n") : ("")) << ((m_mapFlags & GL_MAP_READ_BIT) ? ("\tGL_MAP_READ_BIT\n") : ("")) << ((m_mapFlags & GL_MAP_INVALIDATE_RANGE_BIT) ? ("\tGL_MAP_INVALIDATE_RANGE_BIT\n") : ("")) << ((m_mapFlags & GL_MAP_INVALIDATE_BUFFER_BIT) ? ("\tGL_MAP_INVALIDATE_BUFFER_BIT\n") : ("")) << ((m_mapFlags & GL_MAP_UNSYNCHRONIZED_BIT) ? ("\tGL_MAP_UNSYNCHRONIZED_BIT\n") : ("")) << ((m_mapFlags & GL_MAP_FLUSH_EXPLICIT_BIT) ? ("\tGL_MAP_FLUSH_EXPLICIT_BIT\n") : ("")) << tcu::TestLog::EndMessage; ModifyAfterBasicCase::init(); } void ModifyAfterWithMapBufferRangeCase::deinit (void) { ModifyAfterBasicCase::deinit(); } bool ModifyAfterWithMapBufferRangeCase::isBufferUnspecifiedAfterUpload (int flags, deUint32 mapFlags) { if ((flags & FLAG_PARTIAL) != 0 && ((mapFlags & GL_MAP_INVALIDATE_BUFFER_BIT) != 0)) return true; return false; } void ModifyAfterWithMapBufferRangeCase::testWithBufferSize (UploadSampleResult& result, int bufferSize) { const glw::Functions& gl = m_context.getRenderContext().getFunctions(); const int subdataOffset = deAlign32((m_partialUpload) ? (bufferSize / 4) : (0), 4*4); const int subdataSize = deAlign32((m_partialUpload) ? (bufferSize / 2) : (bufferSize), 4*4); void* mapPtr; // map { deUint64 startTime; deUint64 endTime; startTime = deGetMicroseconds(); mapPtr = gl.mapBufferRange(GL_ARRAY_BUFFER, subdataOffset, subdataSize, m_mapFlags); endTime = deGetMicroseconds(); if (!mapPtr) throw tcu::TestError("mapBufferRange returned null"); result.duration.mapDuration = endTime - startTime; } // write { result.duration.writeDuration = medianTimeMemcpy(mapPtr, &m_zeroData[0], subdataSize); } // unmap { deUint64 startTime; deUint64 endTime; glw::GLboolean unmapSucceeded; startTime = deGetMicroseconds(); unmapSucceeded = gl.unmapBuffer(GL_ARRAY_BUFFER); endTime = deGetMicroseconds(); if (unmapSucceeded != GL_TRUE) throw UnmapFailureError(); result.duration.unmapDuration = endTime - startTime; } result.duration.totalDuration = result.duration.mapDuration + result.duration.writeDuration + result.duration.unmapDuration; result.duration.fitResponseDuration = result.duration.totalDuration; result.writtenSize = subdataSize; } class ModifyAfterWithMapBufferFlushCase : public ModifyAfterBasicCase { public: enum CaseFlags { FLAG_PARTIAL = 0x1, }; ModifyAfterWithMapBufferFlushCase (Context& context, const char* name, const char* desc, int bufferSizeMin, int bufferSizeMax, deUint32 usage, int flags, deUint32 glMapFlags); ~ModifyAfterWithMapBufferFlushCase (void); void init (void); void deinit (void); private: static bool isBufferUnspecifiedAfterUpload (int flags, deUint32 mapFlags); void testWithBufferSize (UploadSampleResult& result, int bufferSize); const bool m_partialUpload; const deUint32 m_mapFlags; }; ModifyAfterWithMapBufferFlushCase::ModifyAfterWithMapBufferFlushCase (Context& context, const char* name, const char* desc, int bufferSizeMin, int bufferSizeMax, deUint32 usage, int flags, deUint32 glMapFlags) : ModifyAfterBasicCase (context, name, desc, bufferSizeMin, bufferSizeMax, usage, isBufferUnspecifiedAfterUpload(flags, glMapFlags)) , m_partialUpload ((flags & FLAG_PARTIAL) != 0) , m_mapFlags (glMapFlags) { } ModifyAfterWithMapBufferFlushCase::~ModifyAfterWithMapBufferFlushCase (void) { deinit(); } void ModifyAfterWithMapBufferFlushCase::init (void) { // Log the purpose of the test m_testCtx.getLog() << tcu::TestLog::Message << "Testing performance of MapBufferRange() command after a draw command that sources data from the target buffer.\n" << ((m_partialUpload) ? ("Half of the buffer is mapped.\n") : ("Whole buffer is mapped.\n")) << "Map bits:\n" << ((m_mapFlags & GL_MAP_WRITE_BIT) ? ("\tGL_MAP_WRITE_BIT\n") : ("")) << ((m_mapFlags & GL_MAP_READ_BIT) ? ("\tGL_MAP_READ_BIT\n") : ("")) << ((m_mapFlags & GL_MAP_INVALIDATE_RANGE_BIT) ? ("\tGL_MAP_INVALIDATE_RANGE_BIT\n") : ("")) << ((m_mapFlags & GL_MAP_INVALIDATE_BUFFER_BIT) ? ("\tGL_MAP_INVALIDATE_BUFFER_BIT\n") : ("")) << ((m_mapFlags & GL_MAP_UNSYNCHRONIZED_BIT) ? ("\tGL_MAP_UNSYNCHRONIZED_BIT\n") : ("")) << ((m_mapFlags & GL_MAP_FLUSH_EXPLICIT_BIT) ? ("\tGL_MAP_FLUSH_EXPLICIT_BIT\n") : ("")) << tcu::TestLog::EndMessage; ModifyAfterBasicCase::init(); } void ModifyAfterWithMapBufferFlushCase::deinit (void) { ModifyAfterBasicCase::deinit(); } bool ModifyAfterWithMapBufferFlushCase::isBufferUnspecifiedAfterUpload (int flags, deUint32 mapFlags) { if ((flags & FLAG_PARTIAL) != 0 && ((mapFlags & GL_MAP_INVALIDATE_BUFFER_BIT) != 0)) return true; return false; } void ModifyAfterWithMapBufferFlushCase::testWithBufferSize (UploadSampleResult& result, int bufferSize) { const glw::Functions& gl = m_context.getRenderContext().getFunctions(); const int subdataOffset = deAlign32((m_partialUpload) ? (bufferSize / 4) : (0), 4*4); const int subdataSize = deAlign32((m_partialUpload) ? (bufferSize / 2) : (bufferSize), 4*4); void* mapPtr; // map { deUint64 startTime; deUint64 endTime; startTime = deGetMicroseconds(); mapPtr = gl.mapBufferRange(GL_ARRAY_BUFFER, subdataOffset, subdataSize, m_mapFlags); endTime = deGetMicroseconds(); if (!mapPtr) throw tcu::TestError("mapBufferRange returned null"); result.duration.mapDuration = endTime - startTime; } // write { result.duration.writeDuration = medianTimeMemcpy(mapPtr, &m_zeroData[0], subdataSize); } // flush { deUint64 startTime; deUint64 endTime; startTime = deGetMicroseconds(); gl.flushMappedBufferRange(GL_ARRAY_BUFFER, 0, subdataSize); endTime = deGetMicroseconds(); result.duration.flushDuration = endTime - startTime; } // unmap { deUint64 startTime; deUint64 endTime; glw::GLboolean unmapSucceeded; startTime = deGetMicroseconds(); unmapSucceeded = gl.unmapBuffer(GL_ARRAY_BUFFER); endTime = deGetMicroseconds(); if (unmapSucceeded != GL_TRUE) throw UnmapFailureError(); result.duration.unmapDuration = endTime - startTime; } result.duration.totalDuration = result.duration.mapDuration + result.duration.writeDuration + result.duration.unmapDuration + result.duration.flushDuration; result.duration.fitResponseDuration = result.duration.totalDuration; result.writtenSize = subdataSize; } enum DrawMethod { DRAWMETHOD_DRAW_ARRAYS = 0, DRAWMETHOD_DRAW_ELEMENTS, DRAWMETHOD_LAST }; enum TargetBuffer { TARGETBUFFER_VERTEX = 0, TARGETBUFFER_INDEX, TARGETBUFFER_LAST }; enum BufferState { BUFFERSTATE_NEW = 0, BUFFERSTATE_EXISTING, BUFFERSTATE_LAST }; enum UploadMethod { UPLOADMETHOD_BUFFER_DATA = 0, UPLOADMETHOD_BUFFER_SUB_DATA, UPLOADMETHOD_MAP_BUFFER_RANGE, UPLOADMETHOD_LAST }; enum UnrelatedBufferType { UNRELATEDBUFFERTYPE_NONE = 0, UNRELATEDBUFFERTYPE_VERTEX, UNRELATEDBUFFERTYPE_LAST }; enum UploadRange { UPLOADRANGE_FULL = 0, UPLOADRANGE_PARTIAL, UPLOADRANGE_LAST }; struct LayeredGridSpec { int gridWidth; int gridHeight; int gridLayers; }; static int getLayeredGridNumVertices (const LayeredGridSpec& scene) { return scene.gridWidth * scene.gridHeight * scene.gridLayers * 6; } static void generateLayeredGridVertexAttribData4C4V (std::vector& vertexData, const LayeredGridSpec& scene) { // interleave color & vertex data const tcu::Vec4 green (0.0f, 1.0f, 0.0f, 0.7f); const tcu::Vec4 yellow (1.0f, 1.0f, 0.0f, 0.8f); vertexData.resize(getLayeredGridNumVertices(scene) * 2); for (int cellY = 0; cellY < scene.gridHeight; ++cellY) for (int cellX = 0; cellX < scene.gridWidth; ++cellX) for (int cellZ = 0; cellZ < scene.gridLayers; ++cellZ) { const tcu::Vec4 color = (((cellX + cellY + cellZ) % 2) == 0) ? (green) : (yellow); const float cellLeft = (float(cellX ) / (float)scene.gridWidth - 0.5f) * 2.0f; const float cellRight = (float(cellX+1) / (float)scene.gridWidth - 0.5f) * 2.0f; const float cellTop = (float(cellY+1) / (float)scene.gridHeight - 0.5f) * 2.0f; const float cellBottom = (float(cellY ) / (float)scene.gridHeight - 0.5f) * 2.0f; vertexData[(cellY * scene.gridWidth * scene.gridLayers + cellX * scene.gridLayers + cellZ) * 12 + 0] = color; vertexData[(cellY * scene.gridWidth * scene.gridLayers + cellX * scene.gridLayers + cellZ) * 12 + 1] = tcu::Vec4(cellLeft, cellTop, 0.0f, 1.0f); vertexData[(cellY * scene.gridWidth * scene.gridLayers + cellX * scene.gridLayers + cellZ) * 12 + 2] = color; vertexData[(cellY * scene.gridWidth * scene.gridLayers + cellX * scene.gridLayers + cellZ) * 12 + 3] = tcu::Vec4(cellLeft, cellBottom, 0.0f, 1.0f); vertexData[(cellY * scene.gridWidth * scene.gridLayers + cellX * scene.gridLayers + cellZ) * 12 + 4] = color; vertexData[(cellY * scene.gridWidth * scene.gridLayers + cellX * scene.gridLayers + cellZ) * 12 + 5] = tcu::Vec4(cellRight, cellBottom, 0.0f, 1.0f); vertexData[(cellY * scene.gridWidth * scene.gridLayers + cellX * scene.gridLayers + cellZ) * 12 + 6] = color; vertexData[(cellY * scene.gridWidth * scene.gridLayers + cellX * scene.gridLayers + cellZ) * 12 + 7] = tcu::Vec4(cellLeft, cellTop, 0.0f, 1.0f); vertexData[(cellY * scene.gridWidth * scene.gridLayers + cellX * scene.gridLayers + cellZ) * 12 + 8] = color; vertexData[(cellY * scene.gridWidth * scene.gridLayers + cellX * scene.gridLayers + cellZ) * 12 + 9] = tcu::Vec4(cellRight, cellBottom, 0.0f, 1.0f); vertexData[(cellY * scene.gridWidth * scene.gridLayers + cellX * scene.gridLayers + cellZ) * 12 + 10] = color; vertexData[(cellY * scene.gridWidth * scene.gridLayers + cellX * scene.gridLayers + cellZ) * 12 + 11] = tcu::Vec4(cellRight, cellTop, 0.0f, 1.0f); } } static void generateLayeredGridIndexData (std::vector& indexData, const LayeredGridSpec& scene) { indexData.resize(getLayeredGridNumVertices(scene) * 2); for (int ndx = 0; ndx < scene.gridLayers * scene.gridHeight * scene.gridWidth * 6; ++ndx) indexData[ndx] = ndx; } class RenderPerformanceTestBase : public TestCase { public: RenderPerformanceTestBase (Context& context, const char* name, const char* description); ~RenderPerformanceTestBase (void); protected: void init (void); void deinit (void); void waitGLResults (void) const; void setupVertexAttribs (void) const; enum { RENDER_AREA_SIZE = 128 }; private: glu::ShaderProgram* m_renderProgram; int m_colorLoc; int m_positionLoc; }; RenderPerformanceTestBase::RenderPerformanceTestBase (Context& context, const char* name, const char* description) : TestCase (context, tcu::NODETYPE_PERFORMANCE, name, description) , m_renderProgram (DE_NULL) , m_colorLoc (0) , m_positionLoc (0) { } RenderPerformanceTestBase::~RenderPerformanceTestBase (void) { deinit(); } void RenderPerformanceTestBase::init (void) { const glw::Functions& gl = m_context.getRenderContext().getFunctions(); m_renderProgram = new glu::ShaderProgram(m_context.getRenderContext(), glu::ProgramSources() << glu::VertexSource(s_colorVertexShader) << glu::FragmentSource(s_colorFragmentShader)); if (!m_renderProgram->isOk()) { m_testCtx.getLog() << *m_renderProgram; throw tcu::TestError("could not build program"); } m_colorLoc = gl.getAttribLocation(m_renderProgram->getProgram(), "a_color"); m_positionLoc = gl.getAttribLocation(m_renderProgram->getProgram(), "a_position"); if (m_colorLoc == -1) throw tcu::TestError("Location of attribute a_color was -1"); if (m_positionLoc == -1) throw tcu::TestError("Location of attribute a_position was -1"); } void RenderPerformanceTestBase::deinit (void) { delete m_renderProgram; m_renderProgram = DE_NULL; } void RenderPerformanceTestBase::setupVertexAttribs (void) const { const glw::Functions& gl = m_context.getRenderContext().getFunctions(); // buffers are bound gl.enableVertexAttribArray(m_colorLoc); gl.enableVertexAttribArray(m_positionLoc); gl.vertexAttribPointer(m_colorLoc, 4, GL_FLOAT, GL_FALSE, (glw::GLsizei)(8 * sizeof(float)), (const tcu::Vec4*)DE_NULL + 0); gl.vertexAttribPointer(m_positionLoc, 4, GL_FLOAT, GL_FALSE, (glw::GLsizei)(8 * sizeof(float)), (const tcu::Vec4*)DE_NULL + 1); gl.useProgram(m_renderProgram->getProgram()); GLU_EXPECT_NO_ERROR(gl.getError(), "set up rendering"); } void RenderPerformanceTestBase::waitGLResults (void) const { tcu::Surface dummySurface(RENDER_AREA_SIZE, RENDER_AREA_SIZE); glu::readPixels(m_context.getRenderContext(), 0, 0, dummySurface.getAccess()); } template class RenderCase : public RenderPerformanceTestBase { public: RenderCase (Context& context, const char* name, const char* description, DrawMethod drawMethod); ~RenderCase (void); protected: void init (void); void deinit (void); private: IterateResult iterate (void); protected: struct SampleResult { LayeredGridSpec scene; RenderSampleResult result; }; int getMinWorkloadSize (void) const; int getMaxWorkloadSize (void) const; int getMinWorkloadDataSize (void) const; int getMaxWorkloadDataSize (void) const; int getVertexDataSize (void) const; int getNumSamples (void) const; void uploadScene (const LayeredGridSpec& scene); virtual void runSample (SampleResult& sample) = 0; virtual void logAndSetTestResult (const std::vector& results); void mapResultsToRenderRateFormat (std::vector >& dst, const std::vector& src) const; const DrawMethod m_drawMethod; private: glw::GLuint m_attributeBufferID; glw::GLuint m_indexBufferID; int m_iterationNdx; std::vector m_iterationOrder; std::vector m_results; int m_numUnmapFailures; }; template RenderCase::RenderCase (Context& context, const char* name, const char* description, DrawMethod drawMethod) : RenderPerformanceTestBase (context, name, description) , m_drawMethod (drawMethod) , m_attributeBufferID (0) , m_indexBufferID (0) , m_iterationNdx (0) , m_numUnmapFailures (0) { DE_ASSERT(drawMethod < DRAWMETHOD_LAST); } template RenderCase::~RenderCase (void) { deinit(); } template void RenderCase::init (void) { const glw::Functions& gl = m_context.getRenderContext().getFunctions(); RenderPerformanceTestBase::init(); // requirements if (m_context.getRenderTarget().getWidth() < RENDER_AREA_SIZE || m_context.getRenderTarget().getHeight() < RENDER_AREA_SIZE) throw tcu::NotSupportedError("Test case requires " + de::toString(RENDER_AREA_SIZE) + "x" + de::toString(RENDER_AREA_SIZE) + " render target"); // gl state gl.viewport(0, 0, RENDER_AREA_SIZE, RENDER_AREA_SIZE); // enable bleding to prevent grid layers from being discarded gl.blendFunc(GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA); gl.blendEquation(GL_FUNC_ADD); gl.enable(GL_BLEND); // generate iterations { const int gridSizes[] = { 20, 26, 32, 38, 44, 50, 56, 62, 68, 74, 80, 86, 92, 98, 104, 110, 116, 122, 128 }; for (int gridNdx = 0; gridNdx < DE_LENGTH_OF_ARRAY(gridSizes); ++gridNdx) { m_results.push_back(SampleResult()); m_results.back().scene.gridHeight = gridSizes[gridNdx]; m_results.back().scene.gridWidth = gridSizes[gridNdx]; m_results.back().scene.gridLayers = 5; m_results.back().result.numVertices = getLayeredGridNumVertices(m_results.back().scene); // test cases set these, initialize to dummy values m_results.back().result.renderDataSize = -1; m_results.back().result.uploadedDataSize = -1; m_results.back().result.unrelatedDataSize = -1; } } // randomize iteration order { m_iterationOrder.resize(m_results.size()); generateTwoPassRandomIterationOrder(m_iterationOrder, (int)m_iterationOrder.size()); } } template void RenderCase::deinit (void) { RenderPerformanceTestBase::deinit(); if (m_attributeBufferID) { m_context.getRenderContext().getFunctions().deleteBuffers(1, &m_attributeBufferID); m_attributeBufferID = 0; } if (m_indexBufferID) { m_context.getRenderContext().getFunctions().deleteBuffers(1, &m_indexBufferID); m_indexBufferID = 0; } } template