flow/instrumentation.cc - external/github.com/flutter/engine - Git at Google

 // Copyright 2013 The Flutter Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include "flutter/flow/instrumentation.h"

 #include <algorithm>
 #include <limits>

 #include "third_party/skia/include/core/SkPath.h"
 #include "third_party/skia/include/core/SkSurface.h"

 namespace flutter {

 static const size_t kMaxSamples = 120;
 static const size_t kMaxFrameMarkers = 8;

 Stopwatch::Stopwatch(fml::Milliseconds frame_budget)
     : start_(fml::TimePoint::Now()), current_sample_(0) {
   const fml::TimeDelta delta = fml::TimeDelta::Zero();
   laps_.resize(kMaxSamples, delta);
   cache_dirty_ = true;
   prev_drawn_sample_index_ = 0;
   frame_budget_ = frame_budget;
 }

 Stopwatch::~Stopwatch() = default;

 void Stopwatch::Start() {
   start_ = fml::TimePoint::Now();
   current_sample_ = (current_sample_ + 1) % kMaxSamples;
 }

 void Stopwatch::Stop() {
   laps_[current_sample_] = fml::TimePoint::Now() - start_;
 }

 void Stopwatch::SetLapTime(const fml::TimeDelta& delta) {
   current_sample_ = (current_sample_ + 1) % kMaxSamples;
   laps_[current_sample_] = delta;
 }

 const fml::TimeDelta& Stopwatch::LastLap() const {
   return laps_[(current_sample_ - 1) % kMaxSamples];
 }

 double Stopwatch::UnitFrameInterval(double raster_time_ms) const {
   return raster_time_ms / frame_budget_.count();
 }

 double Stopwatch::UnitHeight(double raster_time_ms,
                              double max_unit_interval) const {
   double unitHeight = UnitFrameInterval(raster_time_ms) / max_unit_interval;
   if (unitHeight > 1.0)
     unitHeight = 1.0;
   return unitHeight;
 }

 fml::TimeDelta Stopwatch::MaxDelta() const {
   fml::TimeDelta max_delta;
   for (size_t i = 0; i < kMaxSamples; i++) {
     if (laps_[i] > max_delta)
       max_delta = laps_[i];
   }
   return max_delta;
 }

 fml::TimeDelta Stopwatch::AverageDelta() const {
   fml::TimeDelta sum;  // default to 0
   for (size_t i = 0; i < kMaxSamples; i++) {
     sum = sum + laps_[i];
   }
   return sum / kMaxSamples;
 }

 // Initialize the SkSurface for drawing into. Draws the base background and any
 // timing data from before the initial Visualize() call.
 void Stopwatch::InitVisualizeSurface(const SkRect& rect) const {
   if (!cache_dirty_) {
     return;
   }
   cache_dirty_ = false;

   // TODO(garyq): Use a GPU surface instead of a CPU surface.
   visualize_cache_surface_ =
       SkSurface::MakeRasterN32Premul(rect.width(), rect.height());

   SkCanvas* cache_canvas = visualize_cache_surface_->getCanvas();

   // Establish the graph position.
   const SkScalar x = 0;
   const SkScalar y = 0;
   const SkScalar width = rect.width();
   const SkScalar height = rect.height();

   SkPaint paint;
   paint.setColor(0x99FFFFFF);
   cache_canvas->drawRect(SkRect::MakeXYWH(x, y, width, height), paint);

   // Scale the graph to show frame times up to those that are 3 times the frame
   // time.
   const double one_frame_ms = frame_budget_.count();
   const double max_interval = one_frame_ms * 3.0;
   const double max_unit_interval = UnitFrameInterval(max_interval);

   // Draw the old data to initially populate the graph.
   // Prepare a path for the data. We start at the height of the last point, so
   // it looks like we wrap around
   SkPath path;
   path.setIsVolatile(true);
   path.moveTo(x, height);
   path.lineTo(x, y + height * (1.0 - UnitHeight(laps_[0].ToMillisecondsF(),
                                                 max_unit_interval)));
   double unit_x;
   double unit_next_x = 0.0;
   for (size_t i = 0; i < kMaxSamples; i += 1) {
     unit_x = unit_next_x;
     unit_next_x = (static_cast<double>(i + 1) / kMaxSamples);
     const double sample_y =
         y + height * (1.0 - UnitHeight(laps_[i].ToMillisecondsF(),
                                        max_unit_interval));
     path.lineTo(x + width * unit_x, sample_y);
     path.lineTo(x + width * unit_next_x, sample_y);
   }
   path.lineTo(
       width,
       y + height * (1.0 - UnitHeight(laps_[kMaxSamples - 1].ToMillisecondsF(),
                                      max_unit_interval)));
   path.lineTo(width, height);
   path.close();

   // Draw the graph.
   paint.setColor(0xAA0000FF);
   cache_canvas->drawPath(path, paint);
 }

 void Stopwatch::Visualize(SkCanvas& canvas, const SkRect& rect) const {
   // Initialize visualize cache if it has not yet been initialized.
   InitVisualizeSurface(rect);

   SkCanvas* cache_canvas = visualize_cache_surface_->getCanvas();
   SkPaint paint;

   // Establish the graph position.
   const SkScalar x = 0;
   const SkScalar y = 0;
   const SkScalar width = rect.width();
   const SkScalar height = rect.height();

   // Scale the graph to show frame times up to those that are 3 times the frame
   // time.
   const double one_frame_ms = frame_budget_.count();
   const double max_interval = one_frame_ms * 3.0;
   const double max_unit_interval = UnitFrameInterval(max_interval);

   const double sample_unit_width = (1.0 / kMaxSamples);

   // Draw vertical replacement bar to erase old/stale pixels.
   paint.setColor(0x99FFFFFF);
   paint.setStyle(SkPaint::Style::kFill_Style);
   paint.setBlendMode(SkBlendMode::kSrc);
   double sample_x =
       x + width * (static_cast<double>(prev_drawn_sample_index_) / kMaxSamples);
   const auto eraser_rect = SkRect::MakeLTRB(
       sample_x, y, sample_x + width * sample_unit_width, height);
   cache_canvas->drawRect(eraser_rect, paint);

   // Draws blue timing bar for new data.
   paint.setColor(0xAA0000FF);
   paint.setBlendMode(SkBlendMode::kSrcOver);
   const auto bar_rect = SkRect::MakeLTRB(
       sample_x,
       y + height * (1.0 -
                     UnitHeight(laps_[current_sample_ == 0 ? kMaxSamples - 1
                                                           : current_sample_ - 1]
                                    .ToMillisecondsF(),
                                max_unit_interval)),
       sample_x + width * sample_unit_width, height);
   cache_canvas->drawRect(bar_rect, paint);

   // Draw horizontal frame markers.
   paint.setStrokeWidth(0);  // hairline
   paint.setStyle(SkPaint::Style::kStroke_Style);
   paint.setColor(0xCC000000);

   if (max_interval > one_frame_ms) {
     // Paint the horizontal markers
     size_t frame_marker_count =
         static_cast<size_t>(max_interval / one_frame_ms);

     // Limit the number of markers displayed. After a certain point, the graph
     // becomes crowded
     if (frame_marker_count > kMaxFrameMarkers)
       frame_marker_count = 1;

     for (size_t frame_index = 0; frame_index < frame_marker_count;
          frame_index++) {
       const double frame_height =
           height * (1.0 - (UnitFrameInterval((frame_index + 1) * one_frame_ms) /
                            max_unit_interval));
       cache_canvas->drawLine(x, y + frame_height, width, y + frame_height,
                              paint);
     }
   }

   // Paint the vertical marker for the current frame.
   // We paint it over the current frame, not after it, because when we
   // paint this we don't yet have all the times for the current frame.
   paint.setStyle(SkPaint::Style::kFill_Style);
   paint.setBlendMode(SkBlendMode::kSrcOver);
   if (UnitFrameInterval(LastLap().ToMillisecondsF()) > 1.0) {
     // budget exceeded
     paint.setColor(SK_ColorRED);
   } else {
     // within budget
     paint.setColor(SK_ColorGREEN);
   }
   sample_x = x + width * (static_cast<double>(current_sample_) / kMaxSamples);
   const auto marker_rect = SkRect::MakeLTRB(
       sample_x, y, sample_x + width * sample_unit_width, height);
   cache_canvas->drawRect(marker_rect, paint);
   prev_drawn_sample_index_ = current_sample_;

   // Draw the cached surface onto the output canvas.
   paint.reset();
   visualize_cache_surface_->draw(&canvas, rect.x(), rect.y(), &paint);
 }

 CounterValues::CounterValues() : current_sample_(kMaxSamples - 1) {
   values_.resize(kMaxSamples, 0);
 }

 CounterValues::~CounterValues() = default;

 void CounterValues::Add(int64_t value) {
   current_sample_ = (current_sample_ + 1) % kMaxSamples;
   values_[current_sample_] = value;
 }

 void CounterValues::Visualize(SkCanvas& canvas, const SkRect& rect) const {
   size_t max_bytes = GetMaxValue();

   if (max_bytes == 0) {
     // The backend for this counter probably did not fill in any values.
     return;
   }

   size_t min_bytes = GetMinValue();

   SkPaint paint;

   // Paint the background.
   paint.setColor(0x99FFFFFF);
   canvas.drawRect(rect, paint);

   // Establish the graph position.
   const SkScalar x = rect.x();
   const SkScalar y = rect.y();
   const SkScalar width = rect.width();
   const SkScalar height = rect.height();
   const SkScalar bottom = y + height;
   const SkScalar right = x + width;

   // Prepare a path for the data.
   SkPath path;
   path.moveTo(x, bottom);

   for (size_t i = 0; i < kMaxSamples; ++i) {
     int64_t current_bytes = values_[i];
     double ratio =
         (double)(current_bytes - min_bytes) / (max_bytes - min_bytes);
     path.lineTo(x + (((double)(i) / (double)kMaxSamples) * width),
                 y + ((1.0 - ratio) * height));
   }

   path.rLineTo(100, 0);
   path.lineTo(right, bottom);
   path.close();

   // Draw the graph.
   paint.setColor(0xAA0000FF);
   canvas.drawPath(path, paint);

   // Paint the vertical marker for the current frame.
   const double sample_unit_width = (1.0 / kMaxSamples);
   const double sample_margin_unit_width = sample_unit_width / 6.0;
   const double sample_margin_width = width * sample_margin_unit_width;
   paint.setStyle(SkPaint::Style::kFill_Style);
   paint.setColor(SK_ColorGRAY);
   double sample_x =
       x + width * (static_cast<double>(current_sample_) / kMaxSamples) -
       sample_margin_width;
   const auto marker_rect = SkRect::MakeLTRB(
       sample_x, y,
       sample_x + width * sample_unit_width + sample_margin_width * 2, bottom);
   canvas.drawRect(marker_rect, paint);
 }

 int64_t CounterValues::GetCurrentValue() const {
   return values_[current_sample_];
 }

 int64_t CounterValues::GetMaxValue() const {
   auto max = std::numeric_limits<int64_t>::min();
   for (size_t i = 0; i < kMaxSamples; ++i) {
     max = std::max<int64_t>(max, values_[i]);
   }
   return max;
 }

 int64_t CounterValues::GetMinValue() const {
   auto min = std::numeric_limits<int64_t>::max();
   for (size_t i = 0; i < kMaxSamples; ++i) {
     min = std::min<int64_t>(min, values_[i]);
   }
   return min;
 }

 }  // namespace flutter
	// Copyright 2013 The Flutter Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include "flutter/flow/instrumentation.h"

	#include <algorithm>
	#include <limits>

	#include "third_party/skia/include/core/SkPath.h"
	#include "third_party/skia/include/core/SkSurface.h"

	namespace flutter {

	static const size_t kMaxSamples = 120;
	static const size_t kMaxFrameMarkers = 8;

	Stopwatch::Stopwatch(fml::Milliseconds frame_budget)
	: start_(fml::TimePoint::Now()), current_sample_(0) {
	const fml::TimeDelta delta = fml::TimeDelta::Zero();
	laps_.resize(kMaxSamples, delta);
	cache_dirty_ = true;
	prev_drawn_sample_index_ = 0;
	frame_budget_ = frame_budget;
	}

	Stopwatch::~Stopwatch() = default;

	void Stopwatch::Start() {
	start_ = fml::TimePoint::Now();
	current_sample_ = (current_sample_ + 1) % kMaxSamples;
	}

	void Stopwatch::Stop() {
	laps_[current_sample_] = fml::TimePoint::Now() - start_;
	}

	void Stopwatch::SetLapTime(const fml::TimeDelta& delta) {
	current_sample_ = (current_sample_ + 1) % kMaxSamples;
	laps_[current_sample_] = delta;
	}

	const fml::TimeDelta& Stopwatch::LastLap() const {
	return laps_[(current_sample_ - 1) % kMaxSamples];
	}

	double Stopwatch::UnitFrameInterval(double raster_time_ms) const {
	return raster_time_ms / frame_budget_.count();
	}

	double Stopwatch::UnitHeight(double raster_time_ms,
	double max_unit_interval) const {
	double unitHeight = UnitFrameInterval(raster_time_ms) / max_unit_interval;
	if (unitHeight > 1.0)
	unitHeight = 1.0;
	return unitHeight;
	}

	fml::TimeDelta Stopwatch::MaxDelta() const {
	fml::TimeDelta max_delta;
	for (size_t i = 0; i < kMaxSamples; i++) {
	if (laps_[i] > max_delta)
	max_delta = laps_[i];
	}
	return max_delta;
	}

	fml::TimeDelta Stopwatch::AverageDelta() const {
	fml::TimeDelta sum; // default to 0
	for (size_t i = 0; i < kMaxSamples; i++) {
	sum = sum + laps_[i];
	}
	return sum / kMaxSamples;
	}

	// Initialize the SkSurface for drawing into. Draws the base background and any
	// timing data from before the initial Visualize() call.
	void Stopwatch::InitVisualizeSurface(const SkRect& rect) const {
	if (!cache_dirty_) {
	return;
	}
	cache_dirty_ = false;

	// TODO(garyq): Use a GPU surface instead of a CPU surface.
	visualize_cache_surface_ =
	SkSurface::MakeRasterN32Premul(rect.width(), rect.height());

	SkCanvas* cache_canvas = visualize_cache_surface_->getCanvas();

	// Establish the graph position.
	const SkScalar x = 0;
	const SkScalar y = 0;
	const SkScalar width = rect.width();
	const SkScalar height = rect.height();

	SkPaint paint;
	paint.setColor(0x99FFFFFF);
	cache_canvas->drawRect(SkRect::MakeXYWH(x, y, width, height), paint);

	// Scale the graph to show frame times up to those that are 3 times the frame
	// time.
	const double one_frame_ms = frame_budget_.count();
	const double max_interval = one_frame_ms * 3.0;
	const double max_unit_interval = UnitFrameInterval(max_interval);

	// Draw the old data to initially populate the graph.
	// Prepare a path for the data. We start at the height of the last point, so
	// it looks like we wrap around
	SkPath path;
	path.setIsVolatile(true);
	path.moveTo(x, height);
	path.lineTo(x, y + height * (1.0 - UnitHeight(laps_[0].ToMillisecondsF(),
	max_unit_interval)));
	double unit_x;
	double unit_next_x = 0.0;
	for (size_t i = 0; i < kMaxSamples; i += 1) {
	unit_x = unit_next_x;
	unit_next_x = (static_cast<double>(i + 1) / kMaxSamples);
	const double sample_y =
	y + height * (1.0 - UnitHeight(laps_[i].ToMillisecondsF(),
	max_unit_interval));
	path.lineTo(x + width * unit_x, sample_y);
	path.lineTo(x + width * unit_next_x, sample_y);
	}
	path.lineTo(
	width,
	y + height * (1.0 - UnitHeight(laps_[kMaxSamples - 1].ToMillisecondsF(),
	max_unit_interval)));
	path.lineTo(width, height);
	path.close();

	// Draw the graph.
	paint.setColor(0xAA0000FF);
	cache_canvas->drawPath(path, paint);
	}

	void Stopwatch::Visualize(SkCanvas& canvas, const SkRect& rect) const {
	// Initialize visualize cache if it has not yet been initialized.
	InitVisualizeSurface(rect);

	SkCanvas* cache_canvas = visualize_cache_surface_->getCanvas();
	SkPaint paint;

	// Establish the graph position.
	const SkScalar x = 0;
	const SkScalar y = 0;
	const SkScalar width = rect.width();
	const SkScalar height = rect.height();

	// Scale the graph to show frame times up to those that are 3 times the frame
	// time.
	const double one_frame_ms = frame_budget_.count();
	const double max_interval = one_frame_ms * 3.0;
	const double max_unit_interval = UnitFrameInterval(max_interval);

	const double sample_unit_width = (1.0 / kMaxSamples);

	// Draw vertical replacement bar to erase old/stale pixels.
	paint.setColor(0x99FFFFFF);
	paint.setStyle(SkPaint::Style::kFill_Style);
	paint.setBlendMode(SkBlendMode::kSrc);
	double sample_x =
	x + width * (static_cast<double>(prev_drawn_sample_index_) / kMaxSamples);
	const auto eraser_rect = SkRect::MakeLTRB(
	sample_x, y, sample_x + width * sample_unit_width, height);
	cache_canvas->drawRect(eraser_rect, paint);

	// Draws blue timing bar for new data.
	paint.setColor(0xAA0000FF);
	paint.setBlendMode(SkBlendMode::kSrcOver);
	const auto bar_rect = SkRect::MakeLTRB(
	sample_x,
	y + height * (1.0 -
	UnitHeight(laps_[current_sample_ == 0 ? kMaxSamples - 1
	: current_sample_ - 1]
	.ToMillisecondsF(),
	max_unit_interval)),
	sample_x + width * sample_unit_width, height);
	cache_canvas->drawRect(bar_rect, paint);

	// Draw horizontal frame markers.
	paint.setStrokeWidth(0); // hairline
	paint.setStyle(SkPaint::Style::kStroke_Style);
	paint.setColor(0xCC000000);

	if (max_interval > one_frame_ms) {
	// Paint the horizontal markers
	size_t frame_marker_count =
	static_cast<size_t>(max_interval / one_frame_ms);

	// Limit the number of markers displayed. After a certain point, the graph
	// becomes crowded
	if (frame_marker_count > kMaxFrameMarkers)
	frame_marker_count = 1;

	for (size_t frame_index = 0; frame_index < frame_marker_count;
	frame_index++) {
	const double frame_height =
	height * (1.0 - (UnitFrameInterval((frame_index + 1) * one_frame_ms) /
	max_unit_interval));
	cache_canvas->drawLine(x, y + frame_height, width, y + frame_height,
	paint);
	}
	}

	// Paint the vertical marker for the current frame.
	// We paint it over the current frame, not after it, because when we
	// paint this we don't yet have all the times for the current frame.
	paint.setStyle(SkPaint::Style::kFill_Style);
	paint.setBlendMode(SkBlendMode::kSrcOver);
	if (UnitFrameInterval(LastLap().ToMillisecondsF()) > 1.0) {
	// budget exceeded
	paint.setColor(SK_ColorRED);
	} else {
	// within budget
	paint.setColor(SK_ColorGREEN);
	}
	sample_x = x + width * (static_cast<double>(current_sample_) / kMaxSamples);
	const auto marker_rect = SkRect::MakeLTRB(
	sample_x, y, sample_x + width * sample_unit_width, height);
	cache_canvas->drawRect(marker_rect, paint);
	prev_drawn_sample_index_ = current_sample_;

	// Draw the cached surface onto the output canvas.
	paint.reset();
	visualize_cache_surface_->draw(&canvas, rect.x(), rect.y(), &paint);
	}

	CounterValues::CounterValues() : current_sample_(kMaxSamples - 1) {
	values_.resize(kMaxSamples, 0);
	}

	CounterValues::~CounterValues() = default;

	void CounterValues::Add(int64_t value) {
	current_sample_ = (current_sample_ + 1) % kMaxSamples;
	values_[current_sample_] = value;
	}

	void CounterValues::Visualize(SkCanvas& canvas, const SkRect& rect) const {
	size_t max_bytes = GetMaxValue();

	if (max_bytes == 0) {
	// The backend for this counter probably did not fill in any values.
	return;
	}

	size_t min_bytes = GetMinValue();

	SkPaint paint;

	// Paint the background.
	paint.setColor(0x99FFFFFF);
	canvas.drawRect(rect, paint);

	// Establish the graph position.
	const SkScalar x = rect.x();
	const SkScalar y = rect.y();
	const SkScalar width = rect.width();
	const SkScalar height = rect.height();
	const SkScalar bottom = y + height;
	const SkScalar right = x + width;

	// Prepare a path for the data.
	SkPath path;
	path.moveTo(x, bottom);

	for (size_t i = 0; i < kMaxSamples; ++i) {
	int64_t current_bytes = values_[i];
	double ratio =
	(double)(current_bytes - min_bytes) / (max_bytes - min_bytes);
	path.lineTo(x + (((double)(i) / (double)kMaxSamples) * width),
	y + ((1.0 - ratio) * height));
	}

	path.rLineTo(100, 0);
	path.lineTo(right, bottom);
	path.close();

	// Draw the graph.
	paint.setColor(0xAA0000FF);
	canvas.drawPath(path, paint);

	// Paint the vertical marker for the current frame.
	const double sample_unit_width = (1.0 / kMaxSamples);
	const double sample_margin_unit_width = sample_unit_width / 6.0;
	const double sample_margin_width = width * sample_margin_unit_width;
	paint.setStyle(SkPaint::Style::kFill_Style);
	paint.setColor(SK_ColorGRAY);
	double sample_x =
	x + width * (static_cast<double>(current_sample_) / kMaxSamples) -
	sample_margin_width;
	const auto marker_rect = SkRect::MakeLTRB(
	sample_x, y,
	sample_x + width * sample_unit_width + sample_margin_width * 2, bottom);
	canvas.drawRect(marker_rect, paint);
	}

	int64_t CounterValues::GetCurrentValue() const {
	return values_[current_sample_];
	}

	int64_t CounterValues::GetMaxValue() const {
	auto max = std::numeric_limits<int64_t>::min();
	for (size_t i = 0; i < kMaxSamples; ++i) {
	max = std::max<int64_t>(max, values_[i]);
	}
	return max;
	}

	int64_t CounterValues::GetMinValue() const {
	auto min = std::numeric_limits<int64_t>::max();
	for (size_t i = 0; i < kMaxSamples; ++i) {
	min = std::min<int64_t>(min, values_[i]);
	}
	return min;
	}

	} // namespace flutter