root/ui/events/latency_info.cc

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DEFINITIONS

This source file includes following definitions.
  1. GetComponentName
  2. IsTerminalComponent
  3. IsBeginComponent
  4. FromValue
  5. AppendAsTraceFormat
  6. AsTraceableData
  7. terminated
  8. Verify
  9. CopyLatencyFrom
  10. AddNewLatencyFrom
  11. AddLatencyNumber
  12. AddLatencyNumberWithTimestamp
  13. FindLatency
  14. RemoveLatency
  15. Clear
  16. TraceEventType

// Copyright 2013 The Chromium 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 "base/debug/trace_event.h"
#include "base/json/json_writer.h"
#include "base/memory/scoped_ptr.h"
#include "base/strings/stringprintf.h"
#include "ui/events/latency_info.h"

#include <algorithm>

namespace {

const size_t kMaxLatencyInfoNumber = 100;

const char* GetComponentName(ui::LatencyComponentType type) {
#define CASE_TYPE(t) case ui::t:  return #t
  switch (type) {
    CASE_TYPE(INPUT_EVENT_LATENCY_BEGIN_RWH_COMPONENT);
    CASE_TYPE(INPUT_EVENT_LATENCY_SCROLL_UPDATE_RWH_COMPONENT);
    CASE_TYPE(INPUT_EVENT_LATENCY_SCROLL_UPDATE_ORIGINAL_COMPONENT);
    CASE_TYPE(INPUT_EVENT_LATENCY_ORIGINAL_COMPONENT);
    CASE_TYPE(INPUT_EVENT_LATENCY_UI_COMPONENT);
    CASE_TYPE(INPUT_EVENT_LATENCY_RENDERING_SCHEDULED_COMPONENT);
    CASE_TYPE(INPUT_EVENT_LATENCY_ACKED_TOUCH_COMPONENT);
    CASE_TYPE(WINDOW_SNAPSHOT_FRAME_NUMBER_COMPONENT);
    CASE_TYPE(INPUT_EVENT_LATENCY_TERMINATED_MOUSE_COMPONENT);
    CASE_TYPE(INPUT_EVENT_LATENCY_TERMINATED_TOUCH_COMPONENT);
    CASE_TYPE(INPUT_EVENT_LATENCY_TERMINATED_GESTURE_COMPONENT);
    CASE_TYPE(INPUT_EVENT_LATENCY_TERMINATED_FRAME_SWAP_COMPONENT);
    CASE_TYPE(INPUT_EVENT_LATENCY_TERMINATED_COMMIT_FAILED_COMPONENT);
    CASE_TYPE(INPUT_EVENT_LATENCY_TERMINATED_SWAP_FAILED_COMPONENT);
    CASE_TYPE(LATENCY_INFO_LIST_TERMINATED_OVERFLOW_COMPONENT);
    default:
      DLOG(WARNING) << "Unhandled LatencyComponentType.\n";
      break;
  }
#undef CASE_TYPE
  return "unknown";
}

bool IsTerminalComponent(ui::LatencyComponentType type) {
  switch (type) {
    case ui::INPUT_EVENT_LATENCY_TERMINATED_MOUSE_COMPONENT:
    case ui::INPUT_EVENT_LATENCY_TERMINATED_TOUCH_COMPONENT:
    case ui::INPUT_EVENT_LATENCY_TERMINATED_GESTURE_COMPONENT:
    case ui::INPUT_EVENT_LATENCY_TERMINATED_FRAME_SWAP_COMPONENT:
    case ui::INPUT_EVENT_LATENCY_TERMINATED_COMMIT_FAILED_COMPONENT:
    case ui::INPUT_EVENT_LATENCY_TERMINATED_SWAP_FAILED_COMPONENT:
    case ui::LATENCY_INFO_LIST_TERMINATED_OVERFLOW_COMPONENT:
      return true;
    default:
      return false;
  }
}

bool IsBeginComponent(ui::LatencyComponentType type) {
  return (type == ui::INPUT_EVENT_LATENCY_BEGIN_RWH_COMPONENT);
}

// This class is for converting latency info to trace buffer friendly format.
class LatencyInfoTracedValue : public base::debug::ConvertableToTraceFormat {
 public:
  static scoped_refptr<ConvertableToTraceFormat> FromValue(
      scoped_ptr<base::Value> value);

  virtual void AppendAsTraceFormat(std::string* out) const OVERRIDE;

 private:
  explicit LatencyInfoTracedValue(base::Value* value);
  virtual ~LatencyInfoTracedValue();

  scoped_ptr<base::Value> value_;

  DISALLOW_COPY_AND_ASSIGN(LatencyInfoTracedValue);
};

scoped_refptr<base::debug::ConvertableToTraceFormat>
LatencyInfoTracedValue::FromValue(scoped_ptr<base::Value> value) {
  return scoped_refptr<base::debug::ConvertableToTraceFormat>(
      new LatencyInfoTracedValue(value.release()));
}

LatencyInfoTracedValue::~LatencyInfoTracedValue() {
}

void LatencyInfoTracedValue::AppendAsTraceFormat(std::string* out) const {
  std::string tmp;
  base::JSONWriter::Write(value_.get(), &tmp);
  *out += tmp;
}

LatencyInfoTracedValue::LatencyInfoTracedValue(base::Value* value)
    : value_(value) {
}

// Converts latencyinfo into format that can be dumped into trace buffer.
scoped_refptr<base::debug::ConvertableToTraceFormat> AsTraceableData(
    const ui::LatencyInfo& latency) {
  scoped_ptr<base::DictionaryValue> record_data(new base::DictionaryValue());
  for (ui::LatencyInfo::LatencyMap::const_iterator it =
           latency.latency_components.begin();
       it != latency.latency_components.end(); ++it) {
    base::DictionaryValue* component_info = new base::DictionaryValue();
    component_info->SetDouble("comp_id", it->first.second);
    component_info->SetDouble("time", it->second.event_time.ToInternalValue());
    component_info->SetDouble("count", it->second.event_count);
    record_data->Set(GetComponentName(it->first.first), component_info);
  }
  record_data->SetDouble("trace_id", latency.trace_id);
  return LatencyInfoTracedValue::FromValue(record_data.PassAs<base::Value>());
}

}  // namespace

namespace ui {

LatencyInfo::LatencyInfo() : trace_id(-1), terminated(false) {
}

LatencyInfo::~LatencyInfo() {
}

bool LatencyInfo::Verify(const std::vector<LatencyInfo>& latency_info,
                         const char* referring_msg) {
  if (latency_info.size() > kMaxLatencyInfoNumber) {
    LOG(ERROR) << referring_msg << ", LatencyInfo vector size "
               << latency_info.size() << " is too big.";
    return false;
  }
  return true;
}

void LatencyInfo::CopyLatencyFrom(const LatencyInfo& other,
                                  LatencyComponentType type) {
  for (LatencyMap::const_iterator it = other.latency_components.begin();
       it != other.latency_components.end();
       ++it) {
    if (it->first.first == type) {
      AddLatencyNumberWithTimestamp(it->first.first,
                                    it->first.second,
                                    it->second.sequence_number,
                                    it->second.event_time,
                                    it->second.event_count);
    }
  }
}

void LatencyInfo::AddNewLatencyFrom(const LatencyInfo& other) {
    for (LatencyMap::const_iterator it = other.latency_components.begin();
         it != other.latency_components.end();
         ++it) {
      if (!FindLatency(it->first.first, it->first.second, NULL)) {
        AddLatencyNumberWithTimestamp(it->first.first,
                                      it->first.second,
                                      it->second.sequence_number,
                                      it->second.event_time,
                                      it->second.event_count);
      }
    }
}

void LatencyInfo::AddLatencyNumber(LatencyComponentType component,
                                   int64 id,
                                   int64 component_sequence_number) {
  AddLatencyNumberWithTimestamp(component, id, component_sequence_number,
                                base::TimeTicks::HighResNow(), 1);
}

void LatencyInfo::AddLatencyNumberWithTimestamp(LatencyComponentType component,
                                                int64 id,
                                                int64 component_sequence_number,
                                                base::TimeTicks time,
                                                uint32 event_count) {
  if (IsBeginComponent(component)) {
    // Should only ever add begin component once.
    CHECK_EQ(-1, trace_id);
    trace_id = component_sequence_number;
    TRACE_EVENT_ASYNC_BEGIN0("benchmark",
                             "InputLatency",
                             TRACE_ID_DONT_MANGLE(trace_id));
    TRACE_EVENT_FLOW_BEGIN0(
        "input", "LatencyInfo.Flow", TRACE_ID_DONT_MANGLE(trace_id));
  }

  LatencyMap::key_type key = std::make_pair(component, id);
  LatencyMap::iterator it = latency_components.find(key);
  if (it == latency_components.end()) {
    LatencyComponent info = {component_sequence_number, time, event_count};
    latency_components[key] = info;
  } else {
    it->second.sequence_number = std::max(component_sequence_number,
                                          it->second.sequence_number);
    uint32 new_count = event_count + it->second.event_count;
    if (event_count > 0 && new_count != 0) {
      // Do a weighted average, so that the new event_time is the average of
      // the times of events currently in this structure with the time passed
      // into this method.
      it->second.event_time += (time - it->second.event_time) * event_count /
          new_count;
      it->second.event_count = new_count;
    }
  }

  if (IsTerminalComponent(component) && trace_id != -1) {
    // Should only ever add terminal component once.
    CHECK(!terminated);
    terminated = true;
    TRACE_EVENT_ASYNC_END1("benchmark",
                           "InputLatency",
                           TRACE_ID_DONT_MANGLE(trace_id),
                           "data", AsTraceableData(*this));
    TRACE_EVENT_FLOW_END0(
        "input", "LatencyInfo.Flow", TRACE_ID_DONT_MANGLE(trace_id));
  }
}

bool LatencyInfo::FindLatency(LatencyComponentType type,
                              int64 id,
                              LatencyComponent* output) const {
  LatencyMap::const_iterator it = latency_components.find(
      std::make_pair(type, id));
  if (it == latency_components.end())
    return false;
  if (output)
    *output = it->second;
  return true;
}

void LatencyInfo::RemoveLatency(LatencyComponentType type) {
  LatencyMap::iterator it = latency_components.begin();
  while (it != latency_components.end()) {
    if (it->first.first == type) {
      LatencyMap::iterator tmp = it;
      ++it;
      latency_components.erase(tmp);
    } else {
      it++;
    }
  }
}

void LatencyInfo::Clear() {
  latency_components.clear();
}

void LatencyInfo::TraceEventType(const char* event_type) {
  TRACE_EVENT_ASYNC_STEP_INTO0("benchmark",
                               "InputLatency",
                               TRACE_ID_DONT_MANGLE(trace_id),
                               event_type);
}

}  // namespace ui

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