kc3-lang/angle/src/tests/perf_tests/ANGLEPerfTest.cpp

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• Hash : 57b37b6b
  Author :
  Date : 2019-09-25T18:29:28
  

  Rename util/system_utils to util/test_utils.
  
  This removes a GN naming conflict between util/system_utils and
  common/system_utils. This conflict was preventing us from adding
  unit tests to utils' version of system_utils. Since these functions are
  only useful to tests and samples rename them test_utils for simplicity.
  
  Will enable further development of ANGLE's standalone testing harness.
  
  Bug: angleproject:3162
  Change-Id: I9e34fb69f96c5de6dc2453fce4148a0f285e15ed
  Reviewed-on: https://chromium-review.googlesource.com/c/angle/angle/+/1825268
  Reviewed-by: Jonah Ryan-Davis <jonahr@google.com>
  Reviewed-by: Yuly Novikov <ynovikov@chromium.org>
  Commit-Queue: Jamie Madill <jmadill@chromium.org>
  

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• src/tests/perf_tests/ANGLEPerfTest.cpp

• //
  // Copyright 2014 The ANGLE Project Authors. All rights reserved.
  // Use of this source code is governed by a BSD-style license that can be
  // found in the LICENSE file.
  //
  // ANGLEPerfTests:
  //   Base class for google test performance tests
  //
  
  #include "ANGLEPerfTest.h"
  
  #include "ANGLEPerfTestArgs.h"
  #include "common/platform.h"
  #include "common/system_utils.h"
  #include "third_party/perf/perf_test.h"
  #include "third_party/trace_event/trace_event.h"
  #include "util/shader_utils.h"
  #include "util/test_utils.h"
  
  #include <cassert>
  #include <cmath>
  #include <fstream>
  #include <iostream>
  #include <sstream>
  
  #include <json/json.h>
  
  #if defined(ANGLE_USE_UTIL_LOADER) && defined(ANGLE_PLATFORM_WINDOWS)
  #    include "util/windows/WGLWindow.h"
  #endif  // defined(ANGLE_USE_UTIL_LOADER) &&defined(ANGLE_PLATFORM_WINDOWS)
  
  using namespace angle;
  
  namespace
  {
  constexpr size_t kInitialTraceEventBufferSize = 50000;
  constexpr double kMicroSecondsPerSecond       = 1e6;
  constexpr double kNanoSecondsPerSecond        = 1e9;
  constexpr double kCalibrationRunTimeSeconds   = 1.0;
  constexpr double kMaximumRunTimeSeconds       = 10.0;
  constexpr unsigned int kNumTrials             = 3;
  
  struct TraceCategory
  {
      unsigned char enabled;
      const char *name;
  };
  
  constexpr TraceCategory gTraceCategories[2] = {
      {1, "gpu.angle"},
      {1, "gpu.angle.gpu"},
  };
  
  void EmptyPlatformMethod(angle::PlatformMethods *, const char *) {}
  
  void OverrideWorkaroundsD3D(angle::PlatformMethods *platform, angle::FeaturesD3D *featuresD3D)
  {
      auto *angleRenderTest = static_cast<ANGLERenderTest *>(platform->context);
      angleRenderTest->overrideWorkaroundsD3D(featuresD3D);
  }
  
  angle::TraceEventHandle AddPerfTraceEvent(angle::PlatformMethods *platform,
                                            char phase,
                                            const unsigned char *categoryEnabledFlag,
                                            const char *name,
                                            unsigned long long id,
                                            double timestamp,
                                            int numArgs,
                                            const char **argNames,
                                            const unsigned char *argTypes,
                                            const unsigned long long *argValues,
                                            unsigned char flags)
  {
      if (!gEnableTrace)
          return 0;
  
      // Discover the category name based on categoryEnabledFlag.  This flag comes from the first
      // parameter of TraceCategory, and corresponds to one of the entries in gTraceCategories.
      static_assert(offsetof(TraceCategory, enabled) == 0,
                    "|enabled| must be the first field of the TraceCategory class.");
      const TraceCategory *category = reinterpret_cast<const TraceCategory *>(categoryEnabledFlag);
  
      ANGLERenderTest *renderTest     = static_cast<ANGLERenderTest *>(platform->context);
      std::vector<TraceEvent> &buffer = renderTest->getTraceEventBuffer();
      buffer.emplace_back(phase, category->name, name, timestamp);
      return buffer.size();
  }
  
  const unsigned char *GetPerfTraceCategoryEnabled(angle::PlatformMethods *platform,
                                                   const char *categoryName)
  {
      if (gEnableTrace)
      {
          for (const TraceCategory &category : gTraceCategories)
          {
              if (strcmp(category.name, categoryName) == 0)
              {
                  return &category.enabled;
              }
          }
      }
  
      constexpr static unsigned char kZero = 0;
      return &kZero;
  }
  
  void UpdateTraceEventDuration(angle::PlatformMethods *platform,
                                const unsigned char *categoryEnabledFlag,
                                const char *name,
                                angle::TraceEventHandle eventHandle)
  {
      // Not implemented.
  }
  
  double MonotonicallyIncreasingTime(angle::PlatformMethods *platform)
  {
      // Move the time origin to the first call to this function, to avoid generating unnecessarily
      // large timestamps.
      static double origin = angle::GetCurrentTime();
      return angle::GetCurrentTime() - origin;
  }
  
  void DumpTraceEventsToJSONFile(const std::vector<TraceEvent> &traceEvents,
                                 const char *outputFileName)
  {
      Json::Value eventsValue(Json::arrayValue);
  
      for (const TraceEvent &traceEvent : traceEvents)
      {
          Json::Value value(Json::objectValue);
  
          std::stringstream phaseName;
          phaseName << traceEvent.phase;
  
          const auto microseconds =
              static_cast<Json::LargestInt>(traceEvent.timestamp * 1000.0 * 1000.0);
  
          value["name"] = traceEvent.name;
          value["cat"]  = traceEvent.categoryName;
          value["ph"]   = phaseName.str();
          value["ts"]   = microseconds;
          value["pid"]  = "ANGLE";
          value["tid"]  = strcmp(traceEvent.categoryName, "gpu.angle.gpu") == 0 ? "GPU" : "CPU";
  
          eventsValue.append(value);
      }
  
      Json::Value root(Json::objectValue);
      root["traceEvents"] = eventsValue;
  
      std::ofstream outFile;
      outFile.open(outputFileName);
  
      Json::StyledWriter styledWrite;
      outFile << styledWrite.write(root);
  
      outFile.close();
  }
  }  // anonymous namespace
  
  ANGLEPerfTest::ANGLEPerfTest(const std::string &name,
                               const std::string &backend,
                               const std::string &story,
                               unsigned int iterationsPerStep)
      : mName(name),
        mBackend(backend),
        mStory(story),
        mGPUTimeNs(0),
        mSkipTest(false),
        mStepsToRun(std::numeric_limits<unsigned int>::max()),
        mNumStepsPerformed(0),
        mIterationsPerStep(iterationsPerStep),
        mRunning(true)
  {
      if (mStory == "")
      {
          mStory = "baseline_story";
      }
      if (mStory[0] == '_')
      {
          mStory = mStory.substr(1);
      }
      mReporter = std::make_unique<perf_test::PerfResultReporter>(mName + mBackend, mStory);
      mReporter->RegisterImportantMetric(".wall_time", "ns");
      mReporter->RegisterImportantMetric(".gpu_time", "ns");
      mReporter->RegisterFyiMetric(".steps", "count");
  }
  
  ANGLEPerfTest::~ANGLEPerfTest() {}
  
  void ANGLEPerfTest::run()
  {
      if (mSkipTest)
      {
          return;
      }
  
      // Calibrate to a fixed number of steps during an initial set time.
      if (!gStepsToRunOverride.valid())
      {
          doRunLoop(kCalibrationRunTimeSeconds);
  
          // Scale steps down according to the time that exeeded one second.
          double scale = kCalibrationRunTimeSeconds / mTimer.getElapsedTime();
          mStepsToRun  = static_cast<size_t>(static_cast<double>(mNumStepsPerformed) * scale);
  
          // Calibration allows the perf test runner script to save some time.
          if (gCalibration)
          {
              mReporter->AddResult(".steps", static_cast<size_t>(mStepsToRun));
              return;
          }
      }
      else
      {
          mStepsToRun = gStepsToRunOverride.value();
      }
  
      // Do another warmup run. Seems to consistently improve results.
      doRunLoop(kMaximumRunTimeSeconds);
  
      double totalTime = 0.0;
      for (unsigned int trial = 0; trial < kNumTrials; ++trial)
      {
          doRunLoop(kMaximumRunTimeSeconds);
          totalTime += printResults();
      }
  }
  
  void ANGLEPerfTest::doRunLoop(double maxRunTime)
  {
      mNumStepsPerformed = 0;
      mRunning           = true;
      mTimer.start();
      startTest();
  
      while (mRunning)
      {
          step();
          if (mRunning)
          {
              ++mNumStepsPerformed;
              if (mTimer.getElapsedTime() > maxRunTime)
              {
                  mRunning = false;
              }
              else if (mNumStepsPerformed >= mStepsToRun)
              {
                  mRunning = false;
              }
          }
      }
      finishTest();
      mTimer.stop();
  }
  
  void ANGLEPerfTest::SetUp() {}
  
  void ANGLEPerfTest::TearDown() {}
  
  double ANGLEPerfTest::printResults()
  {
      double elapsedTimeSeconds[2] = {
          mTimer.getElapsedTime(),
          mGPUTimeNs * 1e-9,
      };
  
      const char *clockNames[2] = {
          ".wall_time",
          ".gpu_time",
      };
  
      // If measured gpu time is non-zero, print that too.
      size_t clocksToOutput = mGPUTimeNs > 0 ? 2 : 1;
  
      double retValue = 0.0;
      for (size_t i = 0; i < clocksToOutput; ++i)
      {
          double secondsPerStep = elapsedTimeSeconds[i] / static_cast<double>(mNumStepsPerformed);
          double secondsPerIteration = secondsPerStep / static_cast<double>(mIterationsPerStep);
  
          perf_test::MetricInfo metricInfo;
          std::string units;
          // Lazily register the metric, re-using the existing units if it is
          // already registered.
          if (!mReporter->GetMetricInfo(clockNames[i], &metricInfo))
          {
              units = secondsPerIteration > 1e-3 ? "us" : "ns";
              mReporter->RegisterImportantMetric(clockNames[i], units);
          }
          else
          {
              units = metricInfo.units;
          }
  
          if (units == "us")
          {
              retValue = secondsPerIteration * kMicroSecondsPerSecond;
          }
          else
          {
              retValue = secondsPerIteration * kNanoSecondsPerSecond;
          }
          mReporter->AddResult(clockNames[i], retValue);
      }
      return retValue;
  }
  
  double ANGLEPerfTest::normalizedTime(size_t value) const
  {
      return static_cast<double>(value) / static_cast<double>(mNumStepsPerformed);
  }
  
  std::string RenderTestParams::backend() const
  {
      std::stringstream strstr;
  
      switch (driver)
      {
          case angle::GLESDriverType::AngleEGL:
              break;
          case angle::GLESDriverType::SystemEGL:
              return "_native";
          case angle::GLESDriverType::SystemWGL:
              return "_wgl";
          default:
              assert(0);
              return "_unk";
      }
  
      switch (getRenderer())
      {
          case EGL_PLATFORM_ANGLE_TYPE_D3D11_ANGLE:
              strstr << "_d3d11";
              break;
          case EGL_PLATFORM_ANGLE_TYPE_D3D9_ANGLE:
              strstr << "_d3d9";
              break;
          case EGL_PLATFORM_ANGLE_TYPE_OPENGL_ANGLE:
              strstr << "_gl";
              break;
          case EGL_PLATFORM_ANGLE_TYPE_OPENGLES_ANGLE:
              strstr << "_gles";
              break;
          case EGL_PLATFORM_ANGLE_TYPE_DEFAULT_ANGLE:
              strstr << "_default";
              break;
          case EGL_PLATFORM_ANGLE_TYPE_VULKAN_ANGLE:
              strstr << "_vulkan";
              break;
          default:
              assert(0);
              return "_unk";
      }
  
      if (eglParameters.deviceType == EGL_PLATFORM_ANGLE_DEVICE_TYPE_NULL_ANGLE)
      {
          strstr << "_null";
      }
  
      return strstr.str();
  }
  
  std::string RenderTestParams::story() const
  {
      return "";
  }
  
  std::string RenderTestParams::backendAndStory() const
  {
      return backend() + story();
  }
  
  ANGLERenderTest::ANGLERenderTest(const std::string &name, const RenderTestParams &testParams)
      : ANGLEPerfTest(name,
                      testParams.backend(),
                      testParams.story(),
                      OneFrame() ? 1 : testParams.iterationsPerStep),
        mTestParams(testParams),
        mGLWindow(nullptr),
        mOSWindow(nullptr)
  {
      // Force fast tests to make sure our slowest bots don't time out.
      if (OneFrame())
      {
          const_cast<RenderTestParams &>(testParams).iterationsPerStep = 1;
      }
  
      // Try to ensure we don't trigger allocation during execution.
      mTraceEventBuffer.reserve(kInitialTraceEventBufferSize);
  
      switch (testParams.driver)
      {
          case angle::GLESDriverType::AngleEGL:
              mGLWindow = EGLWindow::New(testParams.majorVersion, testParams.minorVersion);
              mEntryPointsLib.reset(angle::OpenSharedLibrary(ANGLE_EGL_LIBRARY_NAME,
                                                             angle::SearchType::ApplicationDir));
              break;
          case angle::GLESDriverType::SystemEGL:
              std::cerr << "Not implemented." << std::endl;
              mSkipTest = true;
              break;
          case angle::GLESDriverType::SystemWGL:
  #if defined(ANGLE_USE_UTIL_LOADER) && defined(ANGLE_PLATFORM_WINDOWS)
              mGLWindow = WGLWindow::New(testParams.majorVersion, testParams.minorVersion);
              mEntryPointsLib.reset(
                  angle::OpenSharedLibrary("opengl32", angle::SearchType::SystemDir));
  #else
              std::cout << "WGL driver not available. Skipping test." << std::endl;
              mSkipTest = true;
  #endif  // defined(ANGLE_USE_UTIL_LOADER) && defined(ANGLE_PLATFORM_WINDOWS)
              break;
          default:
              std::cerr << "Error in switch." << std::endl;
              mSkipTest = true;
              break;
      }
  }
  
  ANGLERenderTest::~ANGLERenderTest()
  {
      OSWindow::Delete(&mOSWindow);
      GLWindowBase::Delete(&mGLWindow);
  }
  
  void ANGLERenderTest::addExtensionPrerequisite(const char *extensionName)
  {
      mExtensionPrerequisites.push_back(extensionName);
  }
  
  void ANGLERenderTest::SetUp()
  {
      if (mSkipTest)
      {
          return;
      }
  
      ANGLEPerfTest::SetUp();
  
      // Set a consistent CPU core affinity and high priority.
      angle::StabilizeCPUForBenchmarking();
  
      mOSWindow = OSWindow::New();
  
      if (!mGLWindow)
      {
          mSkipTest = true;
          return;
      }
  
      mPlatformMethods.overrideWorkaroundsD3D      = OverrideWorkaroundsD3D;
      mPlatformMethods.logError                    = EmptyPlatformMethod;
      mPlatformMethods.logWarning                  = EmptyPlatformMethod;
      mPlatformMethods.logInfo                     = EmptyPlatformMethod;
      mPlatformMethods.addTraceEvent               = AddPerfTraceEvent;
      mPlatformMethods.getTraceCategoryEnabledFlag = GetPerfTraceCategoryEnabled;
      mPlatformMethods.updateTraceEventDuration    = UpdateTraceEventDuration;
      mPlatformMethods.monotonicallyIncreasingTime = MonotonicallyIncreasingTime;
      mPlatformMethods.context                     = this;
  
      if (!mOSWindow->initialize(mName, mTestParams.windowWidth, mTestParams.windowHeight))
      {
          mSkipTest = true;
          FAIL() << "Failed initializing OSWindow";
          // FAIL returns.
      }
  
      // Override platform method parameter.
      EGLPlatformParameters withMethods = mTestParams.eglParameters;
      withMethods.platformMethods       = &mPlatformMethods;
  
      if (!mGLWindow->initializeGL(mOSWindow, mEntryPointsLib.get(), withMethods, mConfigParams))
      {
          mSkipTest = true;
          FAIL() << "Failed initializing GL Window";
          // FAIL returns.
      }
  
      // Disable vsync.
      if (!mGLWindow->setSwapInterval(0))
      {
          mSkipTest = true;
          FAIL() << "Failed setting swap interval";
          // FAIL returns.
      }
  
      if (!areExtensionPrerequisitesFulfilled())
      {
          mSkipTest = true;
      }
  
      if (mSkipTest)
      {
          return;
      }
  
      initializeBenchmark();
  
      if (mTestParams.iterationsPerStep == 0)
      {
          mSkipTest = true;
          FAIL() << "Please initialize 'iterationsPerStep'.";
          // FAIL returns.
      }
  }
  
  void ANGLERenderTest::TearDown()
  {
      if (!mSkipTest)
      {
          destroyBenchmark();
      }
  
      if (mGLWindow)
      {
          mGLWindow->destroyGL();
          mGLWindow = nullptr;
      }
  
      if (mOSWindow)
      {
          mOSWindow->destroy();
          mOSWindow = nullptr;
      }
  
      // Dump trace events to json file.
      if (gEnableTrace)
      {
          DumpTraceEventsToJSONFile(mTraceEventBuffer, gTraceFile);
      }
  
      ANGLEPerfTest::TearDown();
  }
  
  void ANGLERenderTest::beginInternalTraceEvent(const char *name)
  {
      if (gEnableTrace)
      {
          mTraceEventBuffer.emplace_back(TRACE_EVENT_PHASE_BEGIN, gTraceCategories[0].name, name,
                                         MonotonicallyIncreasingTime(&mPlatformMethods));
      }
  }
  
  void ANGLERenderTest::endInternalTraceEvent(const char *name)
  {
      if (gEnableTrace)
      {
          mTraceEventBuffer.emplace_back(TRACE_EVENT_PHASE_END, gTraceCategories[0].name, name,
                                         MonotonicallyIncreasingTime(&mPlatformMethods));
      }
  }
  
  void ANGLERenderTest::step()
  {
      beginInternalTraceEvent("step");
  
      // Clear events that the application did not process from this frame
      Event event;
      bool closed = false;
      while (popEvent(&event))
      {
          // If the application did not catch a close event, close now
          if (event.Type == Event::EVENT_CLOSED)
          {
              closed = true;
          }
      }
  
      if (closed)
      {
          abortTest();
      }
      else
      {
          drawBenchmark();
          // Swap is needed so that the GPU driver will occasionally flush its
          // internal command queue to the GPU. This is enabled for null back-end
          // devices because some back-ends (e.g. Vulkan) also accumulate internal
          // command queues.
          mGLWindow->swap();
          mOSWindow->messageLoop();
      }
  
      endInternalTraceEvent("step");
  }
  
  void ANGLERenderTest::startGpuTimer()
  {
      if (mTestParams.trackGpuTime)
      {
          glBeginQueryEXT(GL_TIME_ELAPSED_EXT, mTimestampQuery);
      }
  }
  
  void ANGLERenderTest::stopGpuTimer()
  {
      if (mTestParams.trackGpuTime)
      {
          glEndQueryEXT(GL_TIME_ELAPSED_EXT);
          uint64_t gpuTimeNs = 0;
          glGetQueryObjectui64vEXT(mTimestampQuery, GL_QUERY_RESULT_EXT, &gpuTimeNs);
  
          mGPUTimeNs += gpuTimeNs;
      }
  }
  
  void ANGLERenderTest::startTest()
  {
      if (mTestParams.trackGpuTime)
      {
          glGenQueriesEXT(1, &mTimestampQuery);
          mGPUTimeNs = 0;
      }
  }
  
  void ANGLERenderTest::finishTest()
  {
      if (mTestParams.trackGpuTime)
      {
          glDeleteQueriesEXT(1, &mTimestampQuery);
      }
      if (mTestParams.eglParameters.deviceType != EGL_PLATFORM_ANGLE_DEVICE_TYPE_NULL_ANGLE)
      {
          glFinish();
      }
  }
  
  bool ANGLERenderTest::popEvent(Event *event)
  {
      return mOSWindow->popEvent(event);
  }
  
  OSWindow *ANGLERenderTest::getWindow()
  {
      return mOSWindow;
  }
  
  bool ANGLERenderTest::areExtensionPrerequisitesFulfilled() const
  {
      for (const char *extension : mExtensionPrerequisites)
      {
          if (!CheckExtensionExists(reinterpret_cast<const char *>(glGetString(GL_EXTENSIONS)),
                                    extension))
          {
              std::cout << "Test skipped due to missing extension: " << extension << std::endl;
              return false;
          }
      }
      return true;
  }
  
  void ANGLERenderTest::setWebGLCompatibilityEnabled(bool webglCompatibility)
  {
      mConfigParams.webGLCompatibility = webglCompatibility;
  }
  
  void ANGLERenderTest::setRobustResourceInit(bool enabled)
  {
      mConfigParams.robustResourceInit = enabled;
  }
  
  std::vector<TraceEvent> &ANGLERenderTest::getTraceEventBuffer()
  {
      return mTraceEventBuffer;
  }
  

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