bench/nanobench.cpp - platform/external/chromium_org/third_party/skia - Git at Google

 /*
  * Copyright 2014 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #include <ctype.h>

 #include "Benchmark.h"
 #include "CrashHandler.h"
 #include "ResultsWriter.h"
 #include "Stats.h"
 #include "Timer.h"

 #include "SkCanvas.h"
 #include "SkCommandLineFlags.h"
 #include "SkForceLinking.h"
 #include "SkGraphics.h"
 #include "SkString.h"
 #include "SkSurface.h"

 #if SK_SUPPORT_GPU
     #include "GrContextFactory.h"
     GrContextFactory gGrFactory;
 #endif

 __SK_FORCE_IMAGE_DECODER_LINKING;

 #if SK_DEBUG
     DEFINE_bool(runOnce, true, "Run each benchmark just once?");
 #else
     DEFINE_bool(runOnce, false, "Run each benchmark just once?");
 #endif

 DEFINE_int32(samples, 10, "Number of samples to measure for each bench.");
 DEFINE_int32(overheadLoops, 100000, "Loops to estimate timer overhead.");
 DEFINE_double(overheadGoal, 0.0001,
               "Loop until timer overhead is at most this fraction of our measurments.");
 DEFINE_string(match, "", "The usual filters on file names of benchmarks to measure.");
 DEFINE_bool2(quiet, q, false, "Print only bench name and minimum sample.");
 DEFINE_bool2(verbose, v, false, "Print all samples.");
 DEFINE_string(config, "nonrendering 8888 gpu", "Configs to measure. Options: "
               "565 8888 gpu nonrendering debug nullgpu msaa4 msaa16 nvprmsaa4 nvprmsaa16 angle");
 DEFINE_double(gpuMs, 5, "Target bench time in millseconds for GPU.");
 DEFINE_int32(gpuFrameLag, 5, "Overestimate of maximum number of frames GPU allows to lag.");

 DEFINE_bool(cpu, true, "Master switch for CPU-bound work.");
 DEFINE_bool(gpu, true, "Master switch for GPU-bound work.");

 DEFINE_string(outResultsFile, "", "If given, write results here as JSON.");
 DEFINE_bool(resetGpuContext, true, "Reset the GrContext before running each bench.");
 DEFINE_int32(maxCalibrationAttempts, 3,
              "Try up to this many times to guess loops for a bench, or skip the bench.");
 DEFINE_int32(maxLoops, 1000000, "Never run a bench more times than this.");


 static SkString humanize(double ms) {
     if (ms > 1e+3) return SkStringPrintf("%.3gs",  ms/1e3);
     if (ms < 1e-3) return SkStringPrintf("%.3gns", ms*1e6);
 #ifdef SK_BUILD_FOR_WIN
     if (ms < 1)    return SkStringPrintf("%.3gus", ms*1e3);
 #else
     if (ms < 1)    return SkStringPrintf("%.3gµs", ms*1e3);
 #endif
     return SkStringPrintf("%.3gms", ms);
 }
 #define HUMANIZE(ms) humanize(ms).c_str()

 static double time(int loops, Benchmark* bench, SkCanvas* canvas, SkGLContextHelper* gl) {
     WallTimer timer;
     timer.start();
     if (bench) {
         bench->draw(loops, canvas);
     }
     if (canvas) {
         canvas->flush();
     }
 #if SK_SUPPORT_GPU
     if (gl) {
         SK_GL(*gl, Flush());
         gl->swapBuffers();
     }
 #endif
     timer.end();
     return timer.fWall;
 }

 static double estimate_timer_overhead() {
     double overhead = 0;
     for (int i = 0; i < FLAGS_overheadLoops; i++) {
         overhead += time(1, NULL, NULL, NULL);
     }
     return overhead / FLAGS_overheadLoops;
 }

 static int clamp_loops(int loops) {
     if (loops < 1) {
         SkDebugf("ERROR: clamping loops from %d to 1.\n", loops);
         return 1;
     }
     if (loops > FLAGS_maxLoops) {
         SkDebugf("WARNING: clamping loops from %d to FLAGS_maxLoops, %d.\n", loops, FLAGS_maxLoops);
         return FLAGS_maxLoops;
     }
     return loops;
 }

 static int cpu_bench(const double overhead, Benchmark* bench, SkCanvas* canvas, double* samples) {
     // First figure out approximately how many loops of bench it takes to make overhead negligible.
     double bench_plus_overhead;
     int round = 0;
     do {
         bench_plus_overhead = time(1, bench, canvas, NULL);
         if (++round == FLAGS_maxCalibrationAttempts) {
             SkDebugf("WARNING: Can't estimate loops for %s (%s vs. %s); skipping.\n",
                      bench->getName(), HUMANIZE(bench_plus_overhead), HUMANIZE(overhead));
             return 0;
         }
     } while (bench_plus_overhead < overhead);

     // Later we'll just start and stop the timer once but loop N times.
     // We'll pick N to make timer overhead negligible:
     //
     //          overhead
     //  -------------------------  < FLAGS_overheadGoal
     //  overhead + N * Bench Time
     //
     // where bench_plus_overhead ≈ overhead + Bench Time.
     //
     // Doing some math, we get:
     //
     //  (overhead / FLAGS_overheadGoal) - overhead
     //  ------------------------------------------  < N
     //       bench_plus_overhead - overhead)
     //
     // Luckily, this also works well in practice. :)
     const double numer = overhead / FLAGS_overheadGoal - overhead;
     const double denom = bench_plus_overhead - overhead;
     const int loops = clamp_loops(FLAGS_runOnce ? 1 : (int)ceil(numer / denom));

     for (int i = 0; i < FLAGS_samples; i++) {
         samples[i] = time(loops, bench, canvas, NULL) / loops;
     }
     return loops;
 }

 #if SK_SUPPORT_GPU
 static int gpu_bench(SkGLContextHelper* gl,
                      Benchmark* bench,
                      SkCanvas* canvas,
                      double* samples) {
     // Make sure we're done with whatever came before.
     SK_GL(*gl, Finish());

     // First, figure out how many loops it'll take to get a frame up to FLAGS_gpuMs.
     int loops = 1;
     if (!FLAGS_runOnce) {
         double elapsed = 0;
         do {
             loops *= 2;
             // If the GPU lets frames lag at all, we need to make sure we're timing
             // _this_ round, not still timing last round.  We force this by looping
             // more times than any reasonable GPU will allow frames to lag.
             for (int i = 0; i < FLAGS_gpuFrameLag; i++) {
                 elapsed = time(loops, bench, canvas, gl);
             }
         } while (elapsed < FLAGS_gpuMs);

         // We've overshot at least a little.  Scale back linearly.
         loops = (int)ceil(loops * FLAGS_gpuMs / elapsed);

         // Might as well make sure we're not still timing our calibration.
         SK_GL(*gl, Finish());
     }
     loops = clamp_loops(loops);

     // Pretty much the same deal as the calibration: do some warmup to make
     // sure we're timing steady-state pipelined frames.
     for (int i = 0; i < FLAGS_gpuFrameLag; i++) {
         time(loops, bench, canvas, gl);
     }

     // Now, actually do the timing!
     for (int i = 0; i < FLAGS_samples; i++) {
         samples[i] = time(loops, bench, canvas, gl) / loops;
     }
     return loops;
 }
 #endif

 static SkString to_lower(const char* str) {
     SkString lower(str);
     for (size_t i = 0; i < lower.size(); i++) {
         lower[i] = tolower(lower[i]);
     }
     return lower;
 }

 struct Target {
     const char* config;
     Benchmark::Backend backend;
     SkAutoTDelete<SkSurface> surface;
 #if SK_SUPPORT_GPU
     SkGLContextHelper* gl;
 #endif
 };

 // If bench is enabled for backend/config, returns a Target* for them, otherwise NULL.
 static Target* is_enabled(Benchmark* bench, Benchmark::Backend backend, const char* config) {
     if (!bench->isSuitableFor(backend)) {
         return NULL;
     }

     for (int i = 0; i < FLAGS_config.count(); i++) {
         if (to_lower(FLAGS_config[i]).equals(config)) {
             Target* target = new Target;
             target->config  = config;
             target->backend = backend;
             return target;
         }
     }
     return NULL;
 }

 // Append all targets that are suitable for bench.
 static void create_targets(Benchmark* bench, SkTDArray<Target*>* targets) {
     const int w = bench->getSize().fX,
               h = bench->getSize().fY;
     const SkImageInfo _8888 = { w, h, kN32_SkColorType,     kPremul_SkAlphaType },
                        _565 = { w, h, kRGB_565_SkColorType, kOpaque_SkAlphaType };

     #define CPU_TARGET(config, backend, code)                              \
         if (Target* t = is_enabled(bench, Benchmark::backend, #config)) {  \
             t->surface.reset(code);                                        \
             targets->push(t);                                              \
         }
     if (FLAGS_cpu) {
         CPU_TARGET(nonrendering, kNonRendering_Backend, NULL)
         CPU_TARGET(8888, kRaster_Backend, SkSurface::NewRaster(_8888))
         CPU_TARGET(565,  kRaster_Backend, SkSurface::NewRaster(_565))
     }

 #if SK_SUPPORT_GPU

     #define GPU_TARGET(config, ctxType, info, samples)                                            \
         if (Target* t = is_enabled(bench, Benchmark::kGPU_Backend, #config)) {                    \
             t->surface.reset(SkSurface::NewRenderTarget(gGrFactory.get(ctxType), info, samples)); \
             t->gl = gGrFactory.getGLContext(ctxType);                                             \
             targets->push(t);                                                                     \
         }
     if (FLAGS_gpu) {
         GPU_TARGET(gpu,      GrContextFactory::kNative_GLContextType, _8888, 0)
         GPU_TARGET(msaa4,    GrContextFactory::kNative_GLContextType, _8888, 4)
         GPU_TARGET(msaa16,   GrContextFactory::kNative_GLContextType, _8888, 16)
         GPU_TARGET(nvprmsaa4,  GrContextFactory::kNVPR_GLContextType, _8888, 4)
         GPU_TARGET(nvprmsaa16, GrContextFactory::kNVPR_GLContextType, _8888, 16)
         GPU_TARGET(debug,     GrContextFactory::kDebug_GLContextType, _8888, 0)
         GPU_TARGET(nullgpu,    GrContextFactory::kNull_GLContextType, _8888, 0)
         #if SK_ANGLE
             GPU_TARGET(angle, GrContextFactory::kANGLE_GLContextType, _8888, 0)
         #endif
     }
 #endif
 }

 static void fill_static_options(ResultsWriter* log) {
 #if defined(SK_BUILD_FOR_WIN32)
     log->option("system", "WIN32");
 #elif defined(SK_BUILD_FOR_MAC)
     log->option("system", "MAC");
 #elif defined(SK_BUILD_FOR_ANDROID)
     log->option("system", "ANDROID");
 #elif defined(SK_BUILD_FOR_UNIX)
     log->option("system", "UNIX");
 #else
     log->option("system", "other");
 #endif
 #if defined(SK_DEBUG)
     log->option("build", "DEBUG");
 #else
     log->option("build", "RELEASE");
 #endif
 }

 int tool_main(int argc, char** argv);
 int tool_main(int argc, char** argv) {
     SetupCrashHandler();
     SkAutoGraphics ag;
     SkCommandLineFlags::Parse(argc, argv);

     if (FLAGS_runOnce) {
         FLAGS_samples     = 1;
         FLAGS_gpuFrameLag = 0;
     }

     MultiResultsWriter log;
     SkAutoTDelete<JSONResultsWriter> json;
     if (!FLAGS_outResultsFile.isEmpty()) {
         json.reset(SkNEW(JSONResultsWriter(FLAGS_outResultsFile[0])));
         log.add(json.get());
     }
     CallEnd<MultiResultsWriter> ender(log);
     fill_static_options(&log);

     const double overhead = estimate_timer_overhead();
     SkDebugf("Timer overhead: %s\n", HUMANIZE(overhead));

     SkAutoTMalloc<double> samples(FLAGS_samples);

     if (FLAGS_runOnce) {
         SkDebugf("--runOnce is true; times would only be misleading so we won't print them.\n");
     } else if (FLAGS_verbose) {
         // No header.
     } else if (FLAGS_quiet) {
         SkDebugf("median\tbench\tconfig\n");
     } else {
         SkDebugf("loops\tmin\tmedian\tmean\tmax\tstddev\tsamples\tconfig\tbench\n");
     }

     for (const BenchRegistry* r = BenchRegistry::Head(); r != NULL; r = r->next()) {
         SkAutoTDelete<Benchmark> bench(r->factory()(NULL));
         if (SkCommandLineFlags::ShouldSkip(FLAGS_match, bench->getName())) {
             continue;
         }
         log.bench(bench->getName(), bench->getSize().fX, bench->getSize().fY);

         SkTDArray<Target*> targets;
         create_targets(bench.get(), &targets);

         bench->preDraw();
         for (int j = 0; j < targets.count(); j++) {
             SkCanvas* canvas = targets[j]->surface.get() ? targets[j]->surface->getCanvas() : NULL;
             const char* config = targets[j]->config;

             const int loops =
 #if SK_SUPPORT_GPU
                 Benchmark::kGPU_Backend == targets[j]->backend
                 ? gpu_bench(targets[j]->gl, bench.get(), canvas, samples.get())
                 :
 #endif
                  cpu_bench(       overhead, bench.get(), canvas, samples.get());

             if (loops == 0) {
                 SkDebugf("Unable to time %s\t%s (overhead %s)\n",
                          bench->getName(), config, HUMANIZE(overhead));
                 continue;
             }

             Stats stats(samples.get(), FLAGS_samples);
             log.config(config);
             log.timer("min_ms",    stats.min);
             log.timer("median_ms", stats.median);
             log.timer("mean_ms",   stats.mean);
             log.timer("max_ms",    stats.max);
             log.timer("stddev_ms", sqrt(stats.var));

             if (FLAGS_runOnce) {
                 if (targets.count() == 1) {
                     config = ""; // Only print the config if we run the same bench on more than one.
                 }
                 SkDebugf("%s\t%s\n", bench->getName(), config);
             } else if (FLAGS_verbose) {
                 for (int i = 0; i < FLAGS_samples; i++) {
                     SkDebugf("%s  ", HUMANIZE(samples[i]));
                 }
                 SkDebugf("%s\n", bench->getName());
             } else if (FLAGS_quiet) {
                 if (targets.count() == 1) {
                     config = ""; // Only print the config if we run the same bench on more than one.
                 }
                 SkDebugf("%s\t%s\t%s\n", HUMANIZE(stats.median), bench->getName(), config);
             } else {
                 const double stddev_percent = 100 * sqrt(stats.var) / stats.mean;
                 SkDebugf("%d\t%s\t%s\t%s\t%s\t%.0f%%\t%s\t%s\t%s\n"
                         , loops
                         , HUMANIZE(stats.min)
                         , HUMANIZE(stats.median)
                         , HUMANIZE(stats.mean)
                         , HUMANIZE(stats.max)
                         , stddev_percent
                         , stats.plot.c_str()
                         , config
                         , bench->getName()
                         );
             }
         }
         targets.deleteAll();

     #if SK_SUPPORT_GPU
         if (FLAGS_resetGpuContext) {
             gGrFactory.destroyContexts();
         }
     #endif
     }

     return 0;
 }

 #if !defined SK_BUILD_FOR_IOS
 int main(int argc, char * const argv[]) {
     return tool_main(argc, (char**) argv);
 }
 #endif
	/*
	* Copyright 2014 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#include <ctype.h>

	#include "Benchmark.h"
	#include "CrashHandler.h"
	#include "ResultsWriter.h"
	#include "Stats.h"
	#include "Timer.h"

	#include "SkCanvas.h"
	#include "SkCommandLineFlags.h"
	#include "SkForceLinking.h"
	#include "SkGraphics.h"
	#include "SkString.h"
	#include "SkSurface.h"

	#if SK_SUPPORT_GPU
	#include "GrContextFactory.h"
	GrContextFactory gGrFactory;
	#endif

	__SK_FORCE_IMAGE_DECODER_LINKING;

	#if SK_DEBUG
	DEFINE_bool(runOnce, true, "Run each benchmark just once?");
	#else
	DEFINE_bool(runOnce, false, "Run each benchmark just once?");
	#endif

	DEFINE_int32(samples, 10, "Number of samples to measure for each bench.");
	DEFINE_int32(overheadLoops, 100000, "Loops to estimate timer overhead.");
	DEFINE_double(overheadGoal, 0.0001,
	"Loop until timer overhead is at most this fraction of our measurments.");
	DEFINE_string(match, "", "The usual filters on file names of benchmarks to measure.");
	DEFINE_bool2(quiet, q, false, "Print only bench name and minimum sample.");
	DEFINE_bool2(verbose, v, false, "Print all samples.");
	DEFINE_string(config, "nonrendering 8888 gpu", "Configs to measure. Options: "
	"565 8888 gpu nonrendering debug nullgpu msaa4 msaa16 nvprmsaa4 nvprmsaa16 angle");
	DEFINE_double(gpuMs, 5, "Target bench time in millseconds for GPU.");
	DEFINE_int32(gpuFrameLag, 5, "Overestimate of maximum number of frames GPU allows to lag.");

	DEFINE_bool(cpu, true, "Master switch for CPU-bound work.");
	DEFINE_bool(gpu, true, "Master switch for GPU-bound work.");

	DEFINE_string(outResultsFile, "", "If given, write results here as JSON.");
	DEFINE_bool(resetGpuContext, true, "Reset the GrContext before running each bench.");
	DEFINE_int32(maxCalibrationAttempts, 3,
	"Try up to this many times to guess loops for a bench, or skip the bench.");
	DEFINE_int32(maxLoops, 1000000, "Never run a bench more times than this.");


	static SkString humanize(double ms) {
	if (ms > 1e+3) return SkStringPrintf("%.3gs", ms/1e3);
	if (ms < 1e-3) return SkStringPrintf("%.3gns", ms*1e6);
	#ifdef SK_BUILD_FOR_WIN
	if (ms < 1) return SkStringPrintf("%.3gus", ms*1e3);
	#else
	if (ms < 1) return SkStringPrintf("%.3gµs", ms*1e3);
	#endif
	return SkStringPrintf("%.3gms", ms);
	}
	#define HUMANIZE(ms) humanize(ms).c_str()

	static double time(int loops, Benchmark* bench, SkCanvas* canvas, SkGLContextHelper* gl) {
	WallTimer timer;
	timer.start();
	if (bench) {
	bench->draw(loops, canvas);
	}
	if (canvas) {
	canvas->flush();
	}
	#if SK_SUPPORT_GPU
	if (gl) {
	SK_GL(*gl, Flush());
	gl->swapBuffers();
	}
	#endif
	timer.end();
	return timer.fWall;
	}

	static double estimate_timer_overhead() {
	double overhead = 0;
	for (int i = 0; i < FLAGS_overheadLoops; i++) {
	overhead += time(1, NULL, NULL, NULL);
	}
	return overhead / FLAGS_overheadLoops;
	}

	static int clamp_loops(int loops) {
	if (loops < 1) {
	SkDebugf("ERROR: clamping loops from %d to 1.\n", loops);
	return 1;
	}
	if (loops > FLAGS_maxLoops) {
	SkDebugf("WARNING: clamping loops from %d to FLAGS_maxLoops, %d.\n", loops, FLAGS_maxLoops);
	return FLAGS_maxLoops;
	}
	return loops;
	}

	static int cpu_bench(const double overhead, Benchmark* bench, SkCanvas* canvas, double* samples) {
	// First figure out approximately how many loops of bench it takes to make overhead negligible.
	double bench_plus_overhead;
	int round = 0;
	do {
	bench_plus_overhead = time(1, bench, canvas, NULL);
	if (++round == FLAGS_maxCalibrationAttempts) {
	SkDebugf("WARNING: Can't estimate loops for %s (%s vs. %s); skipping.\n",
	bench->getName(), HUMANIZE(bench_plus_overhead), HUMANIZE(overhead));
	return 0;
	}
	} while (bench_plus_overhead < overhead);

	// Later we'll just start and stop the timer once but loop N times.
	// We'll pick N to make timer overhead negligible:
	//
	// overhead
	// ------------------------- < FLAGS_overheadGoal
	// overhead + N * Bench Time
	//
	// where bench_plus_overhead ≈ overhead + Bench Time.
	//
	// Doing some math, we get:
	//
	// (overhead / FLAGS_overheadGoal) - overhead
	// ------------------------------------------ < N
	// bench_plus_overhead - overhead)
	//
	// Luckily, this also works well in practice. :)
	const double numer = overhead / FLAGS_overheadGoal - overhead;
	const double denom = bench_plus_overhead - overhead;
	const int loops = clamp_loops(FLAGS_runOnce ? 1 : (int)ceil(numer / denom));

	for (int i = 0; i < FLAGS_samples; i++) {
	samples[i] = time(loops, bench, canvas, NULL) / loops;
	}
	return loops;
	}

	#if SK_SUPPORT_GPU
	static int gpu_bench(SkGLContextHelper* gl,
	Benchmark* bench,
	SkCanvas* canvas,
	double* samples) {
	// Make sure we're done with whatever came before.
	SK_GL(*gl, Finish());

	// First, figure out how many loops it'll take to get a frame up to FLAGS_gpuMs.
	int loops = 1;
	if (!FLAGS_runOnce) {
	double elapsed = 0;
	do {
	loops *= 2;
	// If the GPU lets frames lag at all, we need to make sure we're timing
	// _this_ round, not still timing last round. We force this by looping
	// more times than any reasonable GPU will allow frames to lag.
	for (int i = 0; i < FLAGS_gpuFrameLag; i++) {
	elapsed = time(loops, bench, canvas, gl);
	}
	} while (elapsed < FLAGS_gpuMs);

	// We've overshot at least a little. Scale back linearly.
	loops = (int)ceil(loops * FLAGS_gpuMs / elapsed);

	// Might as well make sure we're not still timing our calibration.
	SK_GL(*gl, Finish());
	}
	loops = clamp_loops(loops);

	// Pretty much the same deal as the calibration: do some warmup to make
	// sure we're timing steady-state pipelined frames.
	for (int i = 0; i < FLAGS_gpuFrameLag; i++) {
	time(loops, bench, canvas, gl);
	}

	// Now, actually do the timing!
	for (int i = 0; i < FLAGS_samples; i++) {
	samples[i] = time(loops, bench, canvas, gl) / loops;
	}
	return loops;
	}
	#endif

	static SkString to_lower(const char* str) {
	SkString lower(str);
	for (size_t i = 0; i < lower.size(); i++) {
	lower[i] = tolower(lower[i]);
	}
	return lower;
	}

	struct Target {
	const char* config;
	Benchmark::Backend backend;
	SkAutoTDelete<SkSurface> surface;
	#if SK_SUPPORT_GPU
	SkGLContextHelper* gl;
	#endif
	};

	// If bench is enabled for backend/config, returns a Target* for them, otherwise NULL.
	static Target* is_enabled(Benchmark* bench, Benchmark::Backend backend, const char* config) {
	if (!bench->isSuitableFor(backend)) {
	return NULL;
	}

	for (int i = 0; i < FLAGS_config.count(); i++) {
	if (to_lower(FLAGS_config[i]).equals(config)) {
	Target* target = new Target;
	target->config = config;
	target->backend = backend;
	return target;
	}
	}
	return NULL;
	}

	// Append all targets that are suitable for bench.
	static void create_targets(Benchmark* bench, SkTDArray<Target> targets) {
	const int w = bench->getSize().fX,
	h = bench->getSize().fY;
	const SkImageInfo _8888 = { w, h, kN32_SkColorType, kPremul_SkAlphaType },
	_565 = { w, h, kRGB_565_SkColorType, kOpaque_SkAlphaType };

	#define CPU_TARGET(config, backend, code) \
	if (Target* t = is_enabled(bench, Benchmark::backend, #config)) { \
	t->surface.reset(code); \
	targets->push(t); \
	}
	if (FLAGS_cpu) {
	CPU_TARGET(nonrendering, kNonRendering_Backend, NULL)
	CPU_TARGET(8888, kRaster_Backend, SkSurface::NewRaster(_8888))
	CPU_TARGET(565, kRaster_Backend, SkSurface::NewRaster(_565))
	}

	#if SK_SUPPORT_GPU

	#define GPU_TARGET(config, ctxType, info, samples) \
	if (Target* t = is_enabled(bench, Benchmark::kGPU_Backend, #config)) { \
	t->surface.reset(SkSurface::NewRenderTarget(gGrFactory.get(ctxType), info, samples)); \
	t->gl = gGrFactory.getGLContext(ctxType); \
	targets->push(t); \
	}
	if (FLAGS_gpu) {
	GPU_TARGET(gpu, GrContextFactory::kNative_GLContextType, _8888, 0)
	GPU_TARGET(msaa4, GrContextFactory::kNative_GLContextType, _8888, 4)
	GPU_TARGET(msaa16, GrContextFactory::kNative_GLContextType, _8888, 16)
	GPU_TARGET(nvprmsaa4, GrContextFactory::kNVPR_GLContextType, _8888, 4)
	GPU_TARGET(nvprmsaa16, GrContextFactory::kNVPR_GLContextType, _8888, 16)
	GPU_TARGET(debug, GrContextFactory::kDebug_GLContextType, _8888, 0)
	GPU_TARGET(nullgpu, GrContextFactory::kNull_GLContextType, _8888, 0)
	#if SK_ANGLE
	GPU_TARGET(angle, GrContextFactory::kANGLE_GLContextType, _8888, 0)
	#endif
	}
	#endif
	}

	static void fill_static_options(ResultsWriter* log) {
	#if defined(SK_BUILD_FOR_WIN32)
	log->option("system", "WIN32");
	#elif defined(SK_BUILD_FOR_MAC)
	log->option("system", "MAC");
	#elif defined(SK_BUILD_FOR_ANDROID)
	log->option("system", "ANDROID");
	#elif defined(SK_BUILD_FOR_UNIX)
	log->option("system", "UNIX");
	#else
	log->option("system", "other");
	#endif
	#if defined(SK_DEBUG)
	log->option("build", "DEBUG");
	#else
	log->option("build", "RELEASE");
	#endif
	}

	int tool_main(int argc, char** argv);
	int tool_main(int argc, char** argv) {
	SetupCrashHandler();
	SkAutoGraphics ag;
	SkCommandLineFlags::Parse(argc, argv);

	if (FLAGS_runOnce) {
	FLAGS_samples = 1;
	FLAGS_gpuFrameLag = 0;
	}

	MultiResultsWriter log;
	SkAutoTDelete<JSONResultsWriter> json;
	if (!FLAGS_outResultsFile.isEmpty()) {
	json.reset(SkNEW(JSONResultsWriter(FLAGS_outResultsFile[0])));
	log.add(json.get());
	}
	CallEnd<MultiResultsWriter> ender(log);
	fill_static_options(&log);

	const double overhead = estimate_timer_overhead();
	SkDebugf("Timer overhead: %s\n", HUMANIZE(overhead));

	SkAutoTMalloc<double> samples(FLAGS_samples);

	if (FLAGS_runOnce) {
	SkDebugf("--runOnce is true; times would only be misleading so we won't print them.\n");
	} else if (FLAGS_verbose) {
	// No header.
	} else if (FLAGS_quiet) {
	SkDebugf("median\tbench\tconfig\n");
	} else {
	SkDebugf("loops\tmin\tmedian\tmean\tmax\tstddev\tsamples\tconfig\tbench\n");
	}

	for (const BenchRegistry* r = BenchRegistry::Head(); r != NULL; r = r->next()) {
	SkAutoTDelete<Benchmark> bench(r->factory()(NULL));
	if (SkCommandLineFlags::ShouldSkip(FLAGS_match, bench->getName())) {
	continue;
	}
	log.bench(bench->getName(), bench->getSize().fX, bench->getSize().fY);

	SkTDArray<Target*> targets;
	create_targets(bench.get(), &targets);

	bench->preDraw();
	for (int j = 0; j < targets.count(); j++) {
	SkCanvas* canvas = targets[j]->surface.get() ? targets[j]->surface->getCanvas() : NULL;
	const char* config = targets[j]->config;

	const int loops =
	#if SK_SUPPORT_GPU
	Benchmark::kGPU_Backend == targets[j]->backend
	? gpu_bench(targets[j]->gl, bench.get(), canvas, samples.get())
	:
	#endif
	cpu_bench( overhead, bench.get(), canvas, samples.get());

	if (loops == 0) {
	SkDebugf("Unable to time %s\t%s (overhead %s)\n",
	bench->getName(), config, HUMANIZE(overhead));
	continue;
	}

	Stats stats(samples.get(), FLAGS_samples);
	log.config(config);
	log.timer("min_ms", stats.min);
	log.timer("median_ms", stats.median);
	log.timer("mean_ms", stats.mean);
	log.timer("max_ms", stats.max);
	log.timer("stddev_ms", sqrt(stats.var));

	if (FLAGS_runOnce) {
	if (targets.count() == 1) {
	config = ""; // Only print the config if we run the same bench on more than one.
	}
	SkDebugf("%s\t%s\n", bench->getName(), config);
	} else if (FLAGS_verbose) {
	for (int i = 0; i < FLAGS_samples; i++) {
	SkDebugf("%s ", HUMANIZE(samples[i]));
	}
	SkDebugf("%s\n", bench->getName());
	} else if (FLAGS_quiet) {
	if (targets.count() == 1) {
	config = ""; // Only print the config if we run the same bench on more than one.
	}
	SkDebugf("%s\t%s\t%s\n", HUMANIZE(stats.median), bench->getName(), config);
	} else {
	const double stddev_percent = 100 * sqrt(stats.var) / stats.mean;
	SkDebugf("%d\t%s\t%s\t%s\t%s\t%.0f%%\t%s\t%s\t%s\n"
	, loops
	, HUMANIZE(stats.min)
	, HUMANIZE(stats.median)
	, HUMANIZE(stats.mean)
	, HUMANIZE(stats.max)
	, stddev_percent
	, stats.plot.c_str()
	, config
	, bench->getName()
	);
	}
	}
	targets.deleteAll();

	#if SK_SUPPORT_GPU
	if (FLAGS_resetGpuContext) {
	gGrFactory.destroyContexts();
	}
	#endif
	}

	return 0;
	}

	#if !defined SK_BUILD_FOR_IOS
	int main(int argc, char * const argv[]) {
	return tool_main(argc, (char**) argv);
	}
	#endif