tests/TracingTest.cpp - platform/external/skia - Gitiles

 /*
  * Copyright 2017 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #include "SkCommandLineFlags.h"
 #include "SkImageInfo.h"
 #include "SkLeanWindows.h"
 #include "SkPoint.h"
 #include "SkRect.h"
 #include "SkTraceEvent.h"
 #include "Test.h"

 DEFINE_bool(slowTracingTest, false, "Artificially slow down tracing test to produce nicer JSON");

 namespace {

 /**
  * Helper types for demonstrating usage of TRACE_EVENT_OBJECT_XXX macros.
  */
 struct TracingShape {
     TracingShape() {
         TRACE_EVENT_OBJECT_CREATED_WITH_ID("skia.objects", this->typeName(), this);
     }
     virtual ~TracingShape() {
         TRACE_EVENT_OBJECT_DELETED_WITH_ID("skia.objects", this->typeName(), this);
     }
     void traceSnapshot() {
         // The state of an object can be specified at any point with the OBJECT_SNAPSHOT macro.
         // This takes the "name" (actually the type name), the ID of the object (typically a
         // pointer), and a single (unnnamed) argument, which is the "snapshot" of that object.
         //
         // Tracing viewer requires that all object macros use the same name and id for creation,
         // deletion, and snapshots. However: It's convenient to put creation and deletion in the
         // base-class constructor/destructor where the actual type name isn't known yet. That's
         // what we're doing here. The JSON for snapshots can therefore include the actual type
         // name, and a special tag that refers to the type name originally used at creation time.
         // Skia's JSON tracer handles this automatically, so SNAPSHOT macros can simply use the
         // derived type name, and the JSON will be formatted correctly to link the events.
         TRACE_EVENT_OBJECT_SNAPSHOT_WITH_ID("skia.objects", this->typeName(), this,
                                             TRACE_STR_COPY(this->toString().c_str()));
     }

     virtual const char* typeName() { return "TracingShape"; }
     virtual SkString toString() { return SkString("Shape()"); }
 };

 struct TracingCircle : public TracingShape {
     TracingCircle(SkPoint center, SkScalar radius) : fCenter(center), fRadius(radius) {}
     const char* typeName() override { return "TracingCircle"; }
     SkString toString() override {
         return SkStringPrintf("Circle(%f, %f, %f)", fCenter.fX, fCenter.fY, fRadius);
     }

     SkPoint fCenter;
     SkScalar fRadius;
 };

 struct TracingRect : public TracingShape {
     TracingRect(SkRect rect) : fRect(rect) {}
     const char* typeName() override { return "TracingRect"; }
     SkString toString() override {
         return SkStringPrintf("Rect(%f, %f, %f, %f)",
                               fRect.fLeft, fRect.fTop, fRect.fRight, fRect.fBottom);
     }

     SkRect fRect;
 };

 }

 static SkScalar gTracingTestWorkSink = 1.0f;

 static void do_work(int howMuchWork) {
     // Do busy work so the trace marker durations are large enough to be readable in trace viewer
     if (FLAGS_slowTracingTest) {
         for (int i = 0; i < howMuchWork * 100; ++i) {
             gTracingTestWorkSink += SkScalarSin(i);
         }
     }
 }

 static void test_trace_simple() {
     // Simple event that lasts until the end of the current scope. TRACE_FUNC is an easy way
     // to insert the current function name.
     TRACE_EVENT0("skia", TRACE_FUNC);

     {
         // There are versions of the macro that take 1 or 2 named arguments. The arguments
         // can be any simple type. Strings need to be static/literal - we just copy pointers.
         // Argument names & values are shown when the event is selected in the viewer.
         TRACE_EVENT1("skia", "Nested work",
                      "isBGRA", kN32_SkColorType == kBGRA_8888_SkColorType);
         do_work(500);
     }

     {
         // If you must copy a string as an argument value, use the TRACE_STR_COPY macro.
         // This will instruct the tracing system (if one is active) to make a copy.
         SkString message = SkStringPrintf("%s %s", "Hello", "World");
         TRACE_EVENT1("skia", "Dynamic String", "message", TRACE_STR_COPY(message.c_str()));
         do_work(500);
     }
 }

 static void test_trace_counters() {
     TRACE_EVENT0("skia", TRACE_FUNC);

     {
         TRACE_EVENT0("skia", "Single Counter");

         // Counter macros allow recording a named value (which must be a 32-bit integer).
         // The value will be graphed in the viewer.
         for (int i = 0; i < 180; ++i) {
             SkScalar rad = SkDegreesToRadians(SkIntToScalar(i));
             TRACE_COUNTER1("skia", "sin", SkScalarSin(rad) * 1000.0f + 1000.0f);
             do_work(10);
         }
     }

     {
         TRACE_EVENT0("skia", "Independent Counters");

         // Recording multiple counters with separate COUNTER1 macros will make separate graphs.
         for (int i = 0; i < 180; ++i) {
             SkScalar rad = SkDegreesToRadians(SkIntToScalar(i));
             SkScalar cos;
             SkScalar sin = SkScalarSinCos(rad, &cos);
             TRACE_COUNTER1("skia", "sin", sin * 1000.0f + 1000.0f);
             TRACE_COUNTER1("skia", "cos", cos * 1000.0f + 1000.0f);
             do_work(10);
         }
     }

     {
         TRACE_EVENT0("skia", "Stacked Counters");

         // Two counters can be recorded together with COUNTER2. They will be graphed together,
         // as a stacked bar graph. The combined graph needs a name, as does each data series.
         for (int i = 0; i < 180; ++i) {
             SkScalar rad = SkDegreesToRadians(SkIntToScalar(i));
             SkScalar cos;
             SkScalar sin = SkScalarSinCos(rad, &cos);
             TRACE_COUNTER2("skia", "trig",
                            "sin", sin * 1000.0f + 1000.0f,
                            "cos", cos * 1000.0f + 1000.0f);
             do_work(10);
         }
     }
 }

 static void test_trace_objects() {
     TRACE_EVENT0("skia", TRACE_FUNC);

     // Objects can be tracked through time with the TRACE_EVENT_OBJECT_ macros.
     // The macros in use (and their idiosyncracies) are commented in the TracingShape class above.

     TracingCircle* circle = new TracingCircle(SkPoint::Make(20, 20), 15);
     circle->traceSnapshot();
     do_work(100);

     // Make another object. Objects with the same base type are shown in the same row in the viewer.
     TracingRect* rect = new TracingRect(SkRect::MakeWH(100, 50));
     rect->traceSnapshot();
     do_work(100);

     // We can create multiple snapshots of objects to reflect their state over time.
     circle->fCenter.offset(10, 10);
     circle->traceSnapshot();

     {
         // Other events (duration or instant) can refer directly to objects. For Skia's JSON
         // tracer, having an argument whose name starts with '#' will trigger the creation of JSON
         // that links the event to the object (with a direct link to the most recent snapshot).
         TRACE_EVENT1("skia", "Processing Shape", "#shape", circle);
         do_work(100);
     }

     delete circle;
     delete rect;
 }

 DEF_TEST(Tracing, reporter) {
     test_trace_simple();
     test_trace_counters();
     test_trace_objects();
 }
	/*
	* Copyright 2017 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#include "SkCommandLineFlags.h"
	#include "SkImageInfo.h"
	#include "SkLeanWindows.h"
	#include "SkPoint.h"
	#include "SkRect.h"
	#include "SkTraceEvent.h"
	#include "Test.h"

	DEFINE_bool(slowTracingTest, false, "Artificially slow down tracing test to produce nicer JSON");

	namespace {

	/**
	* Helper types for demonstrating usage of TRACE_EVENT_OBJECT_XXX macros.
	*/
	struct TracingShape {
	TracingShape() {
	TRACE_EVENT_OBJECT_CREATED_WITH_ID("skia.objects", this->typeName(), this);
	}
	virtual ~TracingShape() {
	TRACE_EVENT_OBJECT_DELETED_WITH_ID("skia.objects", this->typeName(), this);
	}
	void traceSnapshot() {
	// The state of an object can be specified at any point with the OBJECT_SNAPSHOT macro.
	// This takes the "name" (actually the type name), the ID of the object (typically a
	// pointer), and a single (unnnamed) argument, which is the "snapshot" of that object.
	//
	// Tracing viewer requires that all object macros use the same name and id for creation,
	// deletion, and snapshots. However: It's convenient to put creation and deletion in the
	// base-class constructor/destructor where the actual type name isn't known yet. That's
	// what we're doing here. The JSON for snapshots can therefore include the actual type
	// name, and a special tag that refers to the type name originally used at creation time.
	// Skia's JSON tracer handles this automatically, so SNAPSHOT macros can simply use the
	// derived type name, and the JSON will be formatted correctly to link the events.
	TRACE_EVENT_OBJECT_SNAPSHOT_WITH_ID("skia.objects", this->typeName(), this,
	TRACE_STR_COPY(this->toString().c_str()));
	}

	virtual const char* typeName() { return "TracingShape"; }
	virtual SkString toString() { return SkString("Shape()"); }
	};

	struct TracingCircle : public TracingShape {
	TracingCircle(SkPoint center, SkScalar radius) : fCenter(center), fRadius(radius) {}
	const char* typeName() override { return "TracingCircle"; }
	SkString toString() override {
	return SkStringPrintf("Circle(%f, %f, %f)", fCenter.fX, fCenter.fY, fRadius);
	}

	SkPoint fCenter;
	SkScalar fRadius;
	};

	struct TracingRect : public TracingShape {
	TracingRect(SkRect rect) : fRect(rect) {}
	const char* typeName() override { return "TracingRect"; }
	SkString toString() override {
	return SkStringPrintf("Rect(%f, %f, %f, %f)",
	fRect.fLeft, fRect.fTop, fRect.fRight, fRect.fBottom);
	}

	SkRect fRect;
	};

	}

	static SkScalar gTracingTestWorkSink = 1.0f;

	static void do_work(int howMuchWork) {
	// Do busy work so the trace marker durations are large enough to be readable in trace viewer
	if (FLAGS_slowTracingTest) {
	for (int i = 0; i < howMuchWork * 100; ++i) {
	gTracingTestWorkSink += SkScalarSin(i);
	}
	}
	}

	static void test_trace_simple() {
	// Simple event that lasts until the end of the current scope. TRACE_FUNC is an easy way
	// to insert the current function name.
	TRACE_EVENT0("skia", TRACE_FUNC);

	{
	// There are versions of the macro that take 1 or 2 named arguments. The arguments
	// can be any simple type. Strings need to be static/literal - we just copy pointers.
	// Argument names & values are shown when the event is selected in the viewer.
	TRACE_EVENT1("skia", "Nested work",
	"isBGRA", kN32_SkColorType == kBGRA_8888_SkColorType);
	do_work(500);
	}

	{
	// If you must copy a string as an argument value, use the TRACE_STR_COPY macro.
	// This will instruct the tracing system (if one is active) to make a copy.
	SkString message = SkStringPrintf("%s %s", "Hello", "World");
	TRACE_EVENT1("skia", "Dynamic String", "message", TRACE_STR_COPY(message.c_str()));
	do_work(500);
	}
	}

	static void test_trace_counters() {
	TRACE_EVENT0("skia", TRACE_FUNC);

	{
	TRACE_EVENT0("skia", "Single Counter");

	// Counter macros allow recording a named value (which must be a 32-bit integer).
	// The value will be graphed in the viewer.
	for (int i = 0; i < 180; ++i) {
	SkScalar rad = SkDegreesToRadians(SkIntToScalar(i));
	TRACE_COUNTER1("skia", "sin", SkScalarSin(rad) * 1000.0f + 1000.0f);
	do_work(10);
	}
	}

	{
	TRACE_EVENT0("skia", "Independent Counters");

	// Recording multiple counters with separate COUNTER1 macros will make separate graphs.
	for (int i = 0; i < 180; ++i) {
	SkScalar rad = SkDegreesToRadians(SkIntToScalar(i));
	SkScalar cos;
	SkScalar sin = SkScalarSinCos(rad, &cos);
	TRACE_COUNTER1("skia", "sin", sin * 1000.0f + 1000.0f);
	TRACE_COUNTER1("skia", "cos", cos * 1000.0f + 1000.0f);
	do_work(10);
	}
	}

	{
	TRACE_EVENT0("skia", "Stacked Counters");

	// Two counters can be recorded together with COUNTER2. They will be graphed together,
	// as a stacked bar graph. The combined graph needs a name, as does each data series.
	for (int i = 0; i < 180; ++i) {
	SkScalar rad = SkDegreesToRadians(SkIntToScalar(i));
	SkScalar cos;
	SkScalar sin = SkScalarSinCos(rad, &cos);
	TRACE_COUNTER2("skia", "trig",
	"sin", sin * 1000.0f + 1000.0f,
	"cos", cos * 1000.0f + 1000.0f);
	do_work(10);
	}
	}
	}

	static void test_trace_objects() {
	TRACE_EVENT0("skia", TRACE_FUNC);

	// Objects can be tracked through time with the TRACE_EVENT_OBJECT_ macros.
	// The macros in use (and their idiosyncracies) are commented in the TracingShape class above.

	TracingCircle* circle = new TracingCircle(SkPoint::Make(20, 20), 15);
	circle->traceSnapshot();
	do_work(100);

	// Make another object. Objects with the same base type are shown in the same row in the viewer.
	TracingRect* rect = new TracingRect(SkRect::MakeWH(100, 50));
	rect->traceSnapshot();
	do_work(100);

	// We can create multiple snapshots of objects to reflect their state over time.
	circle->fCenter.offset(10, 10);
	circle->traceSnapshot();

	{
	// Other events (duration or instant) can refer directly to objects. For Skia's JSON
	// tracer, having an argument whose name starts with '#' will trigger the creation of JSON
	// that links the event to the object (with a direct link to the most recent snapshot).
	TRACE_EVENT1("skia", "Processing Shape", "#shape", circle);
	do_work(100);
	}

	delete circle;
	delete rect;
	}

	DEF_TEST(Tracing, reporter) {
	test_trace_simple();
	test_trace_counters();
	test_trace_objects();
	}