tools/VisualBench/VisualLightweightBenchModule.cpp - platform/external/skqp - Gitiles

 /*
  * Copyright 2015 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  *
  */

 #include "VisualLightweightBenchModule.h"

 #include "ProcStats.h"
 #include "SkApplication.h"
 #include "SkCanvas.h"
 #include "SkCommandLineFlags.h"
 #include "SkForceLinking.h"
 #include "SkGraphics.h"
 #include "SkGr.h"
 #include "SkImageDecoder.h"
 #include "SkOSFile.h"
 #include "SkStream.h"
 #include "Stats.h"
 #include "gl/GrGLInterface.h"

 __SK_FORCE_IMAGE_DECODER_LINKING;

 // Between samples we reset context
 // Between frames we swap buffers

 DEFINE_int32(gpuFrameLag, 5, "Overestimate of maximum number of frames GPU allows to lag.");
 DEFINE_int32(samples, 10, "Number of times to time each skp.");
 DEFINE_int32(frames, 5, "Number of frames of each skp to render per sample.");
 DEFINE_double(loopMs, 5, "Target loop time in millseconds.");
 DEFINE_bool2(verbose, v, false, "enable verbose output from the test driver.");
 DEFINE_string(outResultsFile, "", "If given, write results here as JSON.");
 DEFINE_string(key, "",
               "Space-separated key/value pairs to add to JSON identifying this builder.");
 DEFINE_string(properties, "",
               "Space-separated key/value pairs to add to JSON identifying this run.");

 static SkString humanize(double ms) {
     if (FLAGS_verbose) {
         return SkStringPrintf("%llu", (uint64_t)(ms*1e6));
     }
     return HumanizeMs(ms);
 }

 #define HUMANIZE(time) humanize(time).c_str()

 VisualLightweightBenchModule::VisualLightweightBenchModule(VisualBench* owner)
     : fCurrentSample(0)
     , fCurrentFrame(0)
     , fLoops(1)
     , fState(kPreWarmLoops_State)
     , fBenchmark(nullptr)
     , fOwner(SkRef(owner))
     , fResults(new ResultsWriter) {
     fBenchmarkStream.reset(new VisualBenchmarkStream);

     // Print header
     SkDebugf("curr/maxrss\tloops\tflushes\tmin\tmedian\tmean\tmax\tstddev\tbench\n");

     // setup json logging if required
     if (!FLAGS_outResultsFile.isEmpty()) {
         fResults.reset(new NanoJSONResultsWriter(FLAGS_outResultsFile[0]));
     }

     if (1 == FLAGS_key.count() % 2) {
         SkDebugf("ERROR: --key must be passed with an even number of arguments.\n");
     } else {
         for (int i = 1; i < FLAGS_key.count(); i += 2) {
             fResults->key(FLAGS_key[i - 1], FLAGS_key[i]);
         }
     }

     if (1 == FLAGS_properties.count() % 2) {
         SkDebugf("ERROR: --properties must be passed with an even number of arguments.\n");
     } else {
         for (int i = 1; i < FLAGS_properties.count(); i += 2) {
             fResults->property(FLAGS_properties[i - 1], FLAGS_properties[i]);
         }
     }
 }

 inline void VisualLightweightBenchModule::renderFrame(SkCanvas* canvas) {
     fBenchmark->draw(fLoops, canvas);
     canvas->flush();
     fOwner->present();
 }

 void VisualLightweightBenchModule::printStats() {
     const SkTArray<double>& measurements = fRecords.back().fMeasurements;
     const char* shortName = fBenchmark->getUniqueName();

     // update log
     // Note: We currently log only the minimum.  It would be interesting to log more information
     SkString configName;
     if (FLAGS_msaa > 0) {
         configName.appendf("msaa_%d", FLAGS_msaa);
     } else {
         configName.appendf("gpu");
     }
     fResults->config(configName.c_str());
     fResults->configOption("name", fBenchmark->getUniqueName());
     SkASSERT(measurements.count());
     Stats stats(measurements);
     fResults->metric("min_ms",    stats.min);

     // Print output
     if (FLAGS_verbose) {
         for (int i = 0; i < measurements.count(); i++) {
             SkDebugf("%s  ", HUMANIZE(measurements[i]));
         }
         SkDebugf("%s\n", shortName);
     } else {
         const double stdDevPercent = 100 * sqrt(stats.var) / stats.mean;
         SkDebugf("%4d/%-4dMB\t%d\t%s\t%s\t%s\t%s\t%.0f%%\t%s\n",
                  sk_tools::getCurrResidentSetSizeMB(),
                  sk_tools::getMaxResidentSetSizeMB(),
                  fLoops,
                  HUMANIZE(stats.min),
                  HUMANIZE(stats.median),
                  HUMANIZE(stats.mean),
                  HUMANIZE(stats.max),
                  stdDevPercent,
                  shortName);
     }
 }

 bool VisualLightweightBenchModule::advanceRecordIfNecessary(SkCanvas* canvas) {
     if (fBenchmark) {
         return true;
     }

     fBenchmark.reset(fBenchmarkStream->next());
     if (!fBenchmark) {
         return false;
     }

     fOwner->clear(canvas, SK_ColorWHITE, 2);


     fBenchmark->preDraw();
     fRecords.push_back();

     // Log bench name
     fResults->bench(fBenchmark->getUniqueName(), fBenchmark->getSize().fX,
                     fBenchmark->getSize().fY);
     return true;
 }

 inline void VisualLightweightBenchModule::nextState(State nextState) {
     fState = nextState;
 }

 void VisualLightweightBenchModule::perCanvasPreDraw(SkCanvas* canvas, State nextState) {
     fBenchmark->perCanvasPreDraw(canvas);
     fCurrentFrame = 0;
     this->nextState(nextState);
 }

 void VisualLightweightBenchModule::preWarm(State nextState) {
     if (fCurrentFrame >= FLAGS_gpuFrameLag) {
         // we currently time across all frames to make sure we capture all GPU work
         this->nextState(nextState);
         fCurrentFrame = 0;
         fTimer.start();
     } else {
         fCurrentFrame++;
     }
 }

 void VisualLightweightBenchModule::draw(SkCanvas* canvas) {
     if (!this->advanceRecordIfNecessary(canvas)) {
         SkDebugf("Exiting VisualBench successfully\n");
         fOwner->closeWindow();
         return;
     }
     this->renderFrame(canvas);
     switch (fState) {
         case kPreWarmLoopsPerCanvasPreDraw_State: {
             this->perCanvasPreDraw(canvas, kPreWarmLoops_State);
             break;
         }
         case kPreWarmLoops_State: {
             this->preWarm(kTuneLoops_State);
             break;
         }
         case kTuneLoops_State: {
             this->tuneLoops();
             break;
         }
         case kPreWarmTimingPerCanvasPreDraw_State: {
             this->perCanvasPreDraw(canvas, kPreWarmTiming_State);
             break;
         }
         case kPreWarmTiming_State: {
             this->preWarm(kTiming_State);
             break;
         }
         case kTiming_State: {
             this->timing(canvas);
             break;
         }
     }
 }

 inline double VisualLightweightBenchModule::elapsed() {
     fTimer.end();
     return fTimer.fWall;
 }

 void VisualLightweightBenchModule::resetTimingState() {
     fCurrentFrame = 0;
     fTimer = WallTimer();
     fOwner->reset();
 }

 void VisualLightweightBenchModule::scaleLoops(double elapsedMs) {
     // Scale back the number of loops
     fLoops = (int)ceil(fLoops * FLAGS_loopMs / elapsedMs);
 }

 inline void VisualLightweightBenchModule::tuneLoops() {
     if (1 << 30 == fLoops) {
         // We're about to wrap.  Something's wrong with the bench.
         SkDebugf("InnerLoops wrapped\n");
         fLoops = 0;
     } else {
         double elapsedMs = this->elapsed();
         if (elapsedMs > FLAGS_loopMs) {
             this->scaleLoops(elapsedMs);
             this->nextState(kPreWarmTimingPerCanvasPreDraw_State);
         } else {
             fLoops *= 2;
             this->nextState(kPreWarmLoops_State);
         }
         this->resetTimingState();
     }
 }

 void VisualLightweightBenchModule::recordMeasurement() {
     double measurement = this->elapsed() / (FLAGS_frames * fLoops);
     fRecords.back().fMeasurements.push_back(measurement);
 }

 void VisualLightweightBenchModule::postDraw(SkCanvas* canvas) {
     fBenchmark->perCanvasPostDraw(canvas);
     fBenchmark.reset(nullptr);
     fCurrentSample = 0;
     fLoops = 1;
 }

 inline void VisualLightweightBenchModule::timing(SkCanvas* canvas) {
     if (fCurrentFrame >= FLAGS_frames) {
         this->recordMeasurement();
         if (fCurrentSample++ >= FLAGS_samples) {
             this->printStats();
             this->postDraw(canvas);
             this->nextState(kPreWarmLoopsPerCanvasPreDraw_State);
         } else {
             this->nextState(kPreWarmTimingPerCanvasPreDraw_State);
         }
         this->resetTimingState();
     } else {
         fCurrentFrame++;
     }
 }

 bool VisualLightweightBenchModule::onHandleChar(SkUnichar c) {
     return true;
 }
	/*
	* Copyright 2015 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*
	*/

	#include "VisualLightweightBenchModule.h"

	#include "ProcStats.h"
	#include "SkApplication.h"
	#include "SkCanvas.h"
	#include "SkCommandLineFlags.h"
	#include "SkForceLinking.h"
	#include "SkGraphics.h"
	#include "SkGr.h"
	#include "SkImageDecoder.h"
	#include "SkOSFile.h"
	#include "SkStream.h"
	#include "Stats.h"
	#include "gl/GrGLInterface.h"

	__SK_FORCE_IMAGE_DECODER_LINKING;

	// Between samples we reset context
	// Between frames we swap buffers

	DEFINE_int32(gpuFrameLag, 5, "Overestimate of maximum number of frames GPU allows to lag.");
	DEFINE_int32(samples, 10, "Number of times to time each skp.");
	DEFINE_int32(frames, 5, "Number of frames of each skp to render per sample.");
	DEFINE_double(loopMs, 5, "Target loop time in millseconds.");
	DEFINE_bool2(verbose, v, false, "enable verbose output from the test driver.");
	DEFINE_string(outResultsFile, "", "If given, write results here as JSON.");
	DEFINE_string(key, "",
	"Space-separated key/value pairs to add to JSON identifying this builder.");
	DEFINE_string(properties, "",
	"Space-separated key/value pairs to add to JSON identifying this run.");

	static SkString humanize(double ms) {
	if (FLAGS_verbose) {
	return SkStringPrintf("%llu", (uint64_t)(ms*1e6));
	}
	return HumanizeMs(ms);
	}

	#define HUMANIZE(time) humanize(time).c_str()

	VisualLightweightBenchModule::VisualLightweightBenchModule(VisualBench* owner)
	: fCurrentSample(0)
	, fCurrentFrame(0)
	, fLoops(1)
	, fState(kPreWarmLoops_State)
	, fBenchmark(nullptr)
	, fOwner(SkRef(owner))
	, fResults(new ResultsWriter) {
	fBenchmarkStream.reset(new VisualBenchmarkStream);

	// Print header
	SkDebugf("curr/maxrss\tloops\tflushes\tmin\tmedian\tmean\tmax\tstddev\tbench\n");

	// setup json logging if required
	if (!FLAGS_outResultsFile.isEmpty()) {
	fResults.reset(new NanoJSONResultsWriter(FLAGS_outResultsFile[0]));
	}

	if (1 == FLAGS_key.count() % 2) {
	SkDebugf("ERROR: --key must be passed with an even number of arguments.\n");
	} else {
	for (int i = 1; i < FLAGS_key.count(); i += 2) {
	fResults->key(FLAGS_key[i - 1], FLAGS_key[i]);
	}
	}

	if (1 == FLAGS_properties.count() % 2) {
	SkDebugf("ERROR: --properties must be passed with an even number of arguments.\n");
	} else {
	for (int i = 1; i < FLAGS_properties.count(); i += 2) {
	fResults->property(FLAGS_properties[i - 1], FLAGS_properties[i]);
	}
	}
	}

	inline void VisualLightweightBenchModule::renderFrame(SkCanvas* canvas) {
	fBenchmark->draw(fLoops, canvas);
	canvas->flush();
	fOwner->present();
	}

	void VisualLightweightBenchModule::printStats() {
	const SkTArray<double>& measurements = fRecords.back().fMeasurements;
	const char* shortName = fBenchmark->getUniqueName();

	// update log
	// Note: We currently log only the minimum. It would be interesting to log more information
	SkString configName;
	if (FLAGS_msaa > 0) {
	configName.appendf("msaa_%d", FLAGS_msaa);
	} else {
	configName.appendf("gpu");
	}
	fResults->config(configName.c_str());
	fResults->configOption("name", fBenchmark->getUniqueName());
	SkASSERT(measurements.count());
	Stats stats(measurements);
	fResults->metric("min_ms", stats.min);

	// Print output
	if (FLAGS_verbose) {
	for (int i = 0; i < measurements.count(); i++) {
	SkDebugf("%s ", HUMANIZE(measurements[i]));
	}
	SkDebugf("%s\n", shortName);
	} else {
	const double stdDevPercent = 100 * sqrt(stats.var) / stats.mean;
	SkDebugf("%4d/%-4dMB\t%d\t%s\t%s\t%s\t%s\t%.0f%%\t%s\n",
	sk_tools::getCurrResidentSetSizeMB(),
	sk_tools::getMaxResidentSetSizeMB(),
	fLoops,
	HUMANIZE(stats.min),
	HUMANIZE(stats.median),
	HUMANIZE(stats.mean),
	HUMANIZE(stats.max),
	stdDevPercent,
	shortName);
	}
	}

	bool VisualLightweightBenchModule::advanceRecordIfNecessary(SkCanvas* canvas) {
	if (fBenchmark) {
	return true;
	}

	fBenchmark.reset(fBenchmarkStream->next());
	if (!fBenchmark) {
	return false;
	}

	fOwner->clear(canvas, SK_ColorWHITE, 2);


	fBenchmark->preDraw();
	fRecords.push_back();

	// Log bench name
	fResults->bench(fBenchmark->getUniqueName(), fBenchmark->getSize().fX,
	fBenchmark->getSize().fY);
	return true;
	}

	inline void VisualLightweightBenchModule::nextState(State nextState) {
	fState = nextState;
	}

	void VisualLightweightBenchModule::perCanvasPreDraw(SkCanvas* canvas, State nextState) {
	fBenchmark->perCanvasPreDraw(canvas);
	fCurrentFrame = 0;
	this->nextState(nextState);
	}

	void VisualLightweightBenchModule::preWarm(State nextState) {
	if (fCurrentFrame >= FLAGS_gpuFrameLag) {
	// we currently time across all frames to make sure we capture all GPU work
	this->nextState(nextState);
	fCurrentFrame = 0;
	fTimer.start();
	} else {
	fCurrentFrame++;
	}
	}

	void VisualLightweightBenchModule::draw(SkCanvas* canvas) {
	if (!this->advanceRecordIfNecessary(canvas)) {
	SkDebugf("Exiting VisualBench successfully\n");
	fOwner->closeWindow();
	return;
	}
	this->renderFrame(canvas);
	switch (fState) {
	case kPreWarmLoopsPerCanvasPreDraw_State: {
	this->perCanvasPreDraw(canvas, kPreWarmLoops_State);
	break;
	}
	case kPreWarmLoops_State: {
	this->preWarm(kTuneLoops_State);
	break;
	}
	case kTuneLoops_State: {
	this->tuneLoops();
	break;
	}
	case kPreWarmTimingPerCanvasPreDraw_State: {
	this->perCanvasPreDraw(canvas, kPreWarmTiming_State);
	break;
	}
	case kPreWarmTiming_State: {
	this->preWarm(kTiming_State);
	break;
	}
	case kTiming_State: {
	this->timing(canvas);
	break;
	}
	}
	}

	inline double VisualLightweightBenchModule::elapsed() {
	fTimer.end();
	return fTimer.fWall;
	}

	void VisualLightweightBenchModule::resetTimingState() {
	fCurrentFrame = 0;
	fTimer = WallTimer();
	fOwner->reset();
	}

	void VisualLightweightBenchModule::scaleLoops(double elapsedMs) {
	// Scale back the number of loops
	fLoops = (int)ceil(fLoops * FLAGS_loopMs / elapsedMs);
	}

	inline void VisualLightweightBenchModule::tuneLoops() {
	if (1 << 30 == fLoops) {
	// We're about to wrap. Something's wrong with the bench.
	SkDebugf("InnerLoops wrapped\n");
	fLoops = 0;
	} else {
	double elapsedMs = this->elapsed();
	if (elapsedMs > FLAGS_loopMs) {
	this->scaleLoops(elapsedMs);
	this->nextState(kPreWarmTimingPerCanvasPreDraw_State);
	} else {
	fLoops *= 2;
	this->nextState(kPreWarmLoops_State);
	}
	this->resetTimingState();
	}
	}

	void VisualLightweightBenchModule::recordMeasurement() {
	double measurement = this->elapsed() / (FLAGS_frames * fLoops);
	fRecords.back().fMeasurements.push_back(measurement);
	}

	void VisualLightweightBenchModule::postDraw(SkCanvas* canvas) {
	fBenchmark->perCanvasPostDraw(canvas);
	fBenchmark.reset(nullptr);
	fCurrentSample = 0;
	fLoops = 1;
	}

	inline void VisualLightweightBenchModule::timing(SkCanvas* canvas) {
	if (fCurrentFrame >= FLAGS_frames) {
	this->recordMeasurement();
	if (fCurrentSample++ >= FLAGS_samples) {
	this->printStats();
	this->postDraw(canvas);
	this->nextState(kPreWarmLoopsPerCanvasPreDraw_State);
	} else {
	this->nextState(kPreWarmTimingPerCanvasPreDraw_State);
	}
	this->resetTimingState();
	} else {
	fCurrentFrame++;
	}
	}

	bool VisualLightweightBenchModule::onHandleChar(SkUnichar c) {
	return true;
	}