ui/events/latency_info.h - chromium/src - Git at Google

 // 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.

 #ifndef UI_EVENTS_LATENCY_INFO_H_
 #define UI_EVENTS_LATENCY_INFO_H_

 #include <stdint.h>

 #include <memory>
 #include <string>
 #include <utility>
 #include <vector>

 #include "base/containers/small_map.h"
 #include "base/time/time.h"
 #include "base/trace_event/trace_event.h"
 #include "ui/events/events_base_export.h"

 #if !defined(OS_IOS)
 #include "ipc/ipc_param_traits.h"  // nogncheck
 #endif

 namespace ui {

 // When adding new components, or new metrics based on LatencyInfo,
 // please update latency_info.dot.
 enum LatencyComponentType {
   // ---------------------------BEGIN COMPONENT-------------------------------
   // BEGIN COMPONENT is when we show the latency begin in chrome://tracing.
   // Timestamp when the input event is sent from RenderWidgetHost to renderer.
   INPUT_EVENT_LATENCY_BEGIN_RWH_COMPONENT,
   // In threaded scrolling, main thread scroll listener update is async to
   // scroll processing in impl thread. This is the timestamp when we consider
   // the main thread scroll listener update is begun.
   LATENCY_BEGIN_SCROLL_LISTENER_UPDATE_MAIN_COMPONENT,
   // ---------------------------NORMAL COMPONENT-------------------------------
   // The original timestamp of the touch event which converts to scroll update.
   INPUT_EVENT_LATENCY_SCROLL_UPDATE_ORIGINAL_COMPONENT,
   // The original timestamp of the touch event which converts to the *first*
   // scroll update in a scroll gesture sequence.
   INPUT_EVENT_LATENCY_FIRST_SCROLL_UPDATE_ORIGINAL_COMPONENT,
   // Original timestamp for input event (e.g. timestamp from kernel).
   INPUT_EVENT_LATENCY_ORIGINAL_COMPONENT,
   // Timestamp when the UI event is created.
   INPUT_EVENT_LATENCY_UI_COMPONENT,
   // Timestamp when the event is dispatched on the main thread of the renderer.
   INPUT_EVENT_LATENCY_RENDERER_MAIN_COMPONENT,
   // This is special component indicating there is rendering scheduled for
   // the event associated with this LatencyInfo on main thread.
   INPUT_EVENT_LATENCY_RENDERING_SCHEDULED_MAIN_COMPONENT,
   // This is special component indicating there is rendering scheduled for
   // the event associated with this LatencyInfo on impl thread.
   INPUT_EVENT_LATENCY_RENDERING_SCHEDULED_IMPL_COMPONENT,
   // Timestamp when a scroll update is forwarded to the main thread.
   INPUT_EVENT_LATENCY_FORWARD_SCROLL_UPDATE_TO_MAIN_COMPONENT,
   // Timestamp when the event's ack is received by the RWH.
   INPUT_EVENT_LATENCY_ACK_RWH_COMPONENT,
   // Frame number when a window snapshot was requested. The snapshot
   // is taken when the rendering results actually reach the screen.
   WINDOW_SNAPSHOT_FRAME_NUMBER_COMPONENT,
   // Timestamp when a tab is requested to be shown.
   TAB_SHOW_COMPONENT,
   // Timestamp when the frame is swapped in renderer.
   INPUT_EVENT_LATENCY_RENDERER_SWAP_COMPONENT,
   // Timestamp of when the browser process receives a buffer swap notification
   // from the renderer.
   INPUT_EVENT_BROWSER_RECEIVED_RENDERER_SWAP_COMPONENT,
   // Timestamp of when the gpu service began swap buffers, unlike
   // INPUT_EVENT_LATENCY_TERMINATED_FRAME_SWAP_COMPONENT which measures after.
   INPUT_EVENT_GPU_SWAP_BUFFER_COMPONENT,
   // Timestamp of when the gesture scroll update is generated from a mouse wheel
   // event.
   INPUT_EVENT_LATENCY_GENERATE_SCROLL_UPDATE_FROM_MOUSE_WHEEL,
   // ---------------------------TERMINAL COMPONENT-----------------------------
   // TERMINAL COMPONENT is when we show the latency end in chrome://tracing.
   // Timestamp when the mouse event is acked from renderer and it does not
   // cause any rendering scheduled.
   INPUT_EVENT_LATENCY_TERMINATED_MOUSE_COMPONENT,
   // Timestamp when the mouse wheel event is acked from renderer and it does not
   // cause any rendering scheduled.
   INPUT_EVENT_LATENCY_TERMINATED_MOUSE_WHEEL_COMPONENT,
   // Timestamp when the keyboard event is acked from renderer and it does not
   // cause any rendering scheduled.
   INPUT_EVENT_LATENCY_TERMINATED_KEYBOARD_COMPONENT,
   // Timestamp when the touch event is acked from renderer and it does not
   // cause any rendering scheduled and does not generate any gesture event.
   INPUT_EVENT_LATENCY_TERMINATED_TOUCH_COMPONENT,
   // Timestamp when the gesture event is acked from renderer, and it does not
   // cause any rendering scheduled.
   INPUT_EVENT_LATENCY_TERMINATED_GESTURE_COMPONENT,
   // Timestamp when the frame is swapped (i.e. when the rendering caused by
   // input event actually takes effect).
   INPUT_EVENT_LATENCY_TERMINATED_FRAME_SWAP_COMPONENT,
   // This component indicates that the input causes a commit to be scheduled
   // but the commit failed.
   INPUT_EVENT_LATENCY_TERMINATED_COMMIT_FAILED_COMPONENT,
   // This component indicates that the input causes a commit to be scheduled
   // but the commit was aborted since it carried no new information.
   INPUT_EVENT_LATENCY_TERMINATED_COMMIT_NO_UPDATE_COMPONENT,
   // This component indicates that the input causes a swap to be scheduled
   // but the swap failed.
   INPUT_EVENT_LATENCY_TERMINATED_SWAP_FAILED_COMPONENT,
   LATENCY_COMPONENT_TYPE_LAST =
       INPUT_EVENT_LATENCY_TERMINATED_SWAP_FAILED_COMPONENT,
 };

 class EVENTS_BASE_EXPORT LatencyInfo {
  public:
   struct LatencyComponent {
     // Nondecreasing number that can be used to determine what events happened
     // in the component at the time this struct was sent on to the next
     // component.
     int64_t sequence_number;
     // Average time of events that happened in this component.
     base::TimeTicks event_time;
     // Count of events that happened in this component
     uint32_t event_count;
   };

   struct EVENTS_BASE_EXPORT InputCoordinate {
     InputCoordinate();
     InputCoordinate(float x, float y);

     float x;
     float y;
   };

   // Empirically determined constant based on a typical scroll sequence.
   enum { kTypicalMaxComponentsPerLatencyInfo = 10 };

   enum { kMaxInputCoordinates = 2 };

   // Map a Latency Component (with a component-specific int64_t id) to a
   // component info.
   typedef base::SmallMap<
       std::map<std::pair<LatencyComponentType, int64_t>, LatencyComponent>,
       kTypicalMaxComponentsPerLatencyInfo> LatencyMap;

   LatencyInfo();
   LatencyInfo(const LatencyInfo& other);
   ~LatencyInfo();

   // For test only.
   LatencyInfo(int64_t trace_id, bool terminated);

   // Returns true if the vector |latency_info| is valid. Returns false
   // if it is not valid and log the |referring_msg|.
   // This function is mainly used to check the latency_info vector that
   // is passed between processes using IPC message has reasonable size
   // so that we are confident the IPC message is not corrupted/compromised.
   // This check will go away once the IPC system has better built-in scheme
   // for corruption/compromise detection.
   static bool Verify(const std::vector<LatencyInfo>& latency_info,
                      const char* referring_msg);

   // Copy LatencyComponents with type |type| from |other| into |this|.
   void CopyLatencyFrom(const LatencyInfo& other, LatencyComponentType type);

   // Add LatencyComponents that are in |other| but not in |this|.
   void AddNewLatencyFrom(const LatencyInfo& other);

   // Modifies the current sequence number for a component, and adds a new
   // sequence number with the current timestamp.
   void AddLatencyNumber(LatencyComponentType component,
                         int64_t id,
                         int64_t component_sequence_number);

   // Similar to |AddLatencyNumber|, and also appends |trace_name_str| to
   // the trace event's name.
   // This function should only be called when adding a BEGIN component.
   void AddLatencyNumberWithTraceName(LatencyComponentType component,
                                      int64_t id,
                                      int64_t component_sequence_number,
                                      const char* trace_name_str);

   // Modifies the current sequence number and adds a certain number of events
   // for a specific component.
   void AddLatencyNumberWithTimestamp(LatencyComponentType component,
                                      int64_t id,
                                      int64_t component_sequence_number,
                                      base::TimeTicks time,
                                      uint32_t event_count);

   // Returns true if the a component with |type| and |id| is found in
   // the latency_components and the component is stored to |output| if
   // |output| is not NULL. Returns false if no such component is found.
   bool FindLatency(LatencyComponentType type,
                    int64_t id,
                    LatencyComponent* output) const;

   void RemoveLatency(LatencyComponentType type);

   // Returns true if there is still room for keeping the |input_coordinate|,
   // false otherwise.
   bool AddInputCoordinate(const InputCoordinate& input_coordinate);

   uint32_t input_coordinates_size() const { return input_coordinates_size_; }
   const InputCoordinate* input_coordinates() const {
     return input_coordinates_;
   }

   const LatencyMap& latency_components() const { return latency_components_; }

   bool terminated() const { return terminated_; }
   void set_coalesced() { coalesced_ = true; }
   bool coalesced() const { return coalesced_; }
   int64_t trace_id() const { return trace_id_; }

  private:
   void AddLatencyNumberWithTimestampImpl(LatencyComponentType component,
                                          int64_t id,
                                          int64_t component_sequence_number,
                                          base::TimeTicks time,
                                          uint32_t event_count,
                                          const char* trace_name_str);

   // Converts latencyinfo into format that can be dumped into trace buffer.
   std::unique_ptr<base::trace_event::ConvertableToTraceFormat>
   AsTraceableData();
   std::unique_ptr<base::trace_event::ConvertableToTraceFormat>
   CoordinatesAsTraceableData();

   // Shown as part of the name of the trace event for this LatencyInfo.
   // String is empty if no tracing is enabled.
   std::string trace_name_;

   LatencyMap latency_components_;

   // These coordinates represent window coordinates of the original input event.
   uint32_t input_coordinates_size_;
   InputCoordinate input_coordinates_[kMaxInputCoordinates];

   // The unique id for matching the ASYNC_BEGIN/END trace event.
   int64_t trace_id_;
   // Whether this event has been coalesced into another event.
   bool coalesced_;
   // Whether a terminal component has been added.
   bool terminated_;

 #if !defined(OS_IOS)
   friend struct IPC::ParamTraits<ui::LatencyInfo>;
 #endif
 };

 }  // namespace ui

 #endif  // UI_EVENTS_LATENCY_INFO_H_
	// 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.

	#ifndef UI_EVENTS_LATENCY_INFO_H_
	#define UI_EVENTS_LATENCY_INFO_H_

	#include <stdint.h>

	#include <memory>
	#include <string>
	#include <utility>
	#include <vector>

	#include "base/containers/small_map.h"
	#include "base/time/time.h"
	#include "base/trace_event/trace_event.h"
	#include "ui/events/events_base_export.h"

	#if !defined(OS_IOS)
	#include "ipc/ipc_param_traits.h" // nogncheck
	#endif

	namespace ui {

	// When adding new components, or new metrics based on LatencyInfo,
	// please update latency_info.dot.
	enum LatencyComponentType {
	// ---------------------------BEGIN COMPONENT-------------------------------
	// BEGIN COMPONENT is when we show the latency begin in chrome://tracing.
	// Timestamp when the input event is sent from RenderWidgetHost to renderer.
	INPUT_EVENT_LATENCY_BEGIN_RWH_COMPONENT,
	// In threaded scrolling, main thread scroll listener update is async to
	// scroll processing in impl thread. This is the timestamp when we consider
	// the main thread scroll listener update is begun.
	LATENCY_BEGIN_SCROLL_LISTENER_UPDATE_MAIN_COMPONENT,
	// ---------------------------NORMAL COMPONENT-------------------------------
	// The original timestamp of the touch event which converts to scroll update.
	INPUT_EVENT_LATENCY_SCROLL_UPDATE_ORIGINAL_COMPONENT,
	// The original timestamp of the touch event which converts to the first
	// scroll update in a scroll gesture sequence.
	INPUT_EVENT_LATENCY_FIRST_SCROLL_UPDATE_ORIGINAL_COMPONENT,
	// Original timestamp for input event (e.g. timestamp from kernel).
	INPUT_EVENT_LATENCY_ORIGINAL_COMPONENT,
	// Timestamp when the UI event is created.
	INPUT_EVENT_LATENCY_UI_COMPONENT,
	// Timestamp when the event is dispatched on the main thread of the renderer.
	INPUT_EVENT_LATENCY_RENDERER_MAIN_COMPONENT,
	// This is special component indicating there is rendering scheduled for
	// the event associated with this LatencyInfo on main thread.
	INPUT_EVENT_LATENCY_RENDERING_SCHEDULED_MAIN_COMPONENT,
	// This is special component indicating there is rendering scheduled for
	// the event associated with this LatencyInfo on impl thread.
	INPUT_EVENT_LATENCY_RENDERING_SCHEDULED_IMPL_COMPONENT,
	// Timestamp when a scroll update is forwarded to the main thread.
	INPUT_EVENT_LATENCY_FORWARD_SCROLL_UPDATE_TO_MAIN_COMPONENT,
	// Timestamp when the event's ack is received by the RWH.
	INPUT_EVENT_LATENCY_ACK_RWH_COMPONENT,
	// Frame number when a window snapshot was requested. The snapshot
	// is taken when the rendering results actually reach the screen.
	WINDOW_SNAPSHOT_FRAME_NUMBER_COMPONENT,
	// Timestamp when a tab is requested to be shown.
	TAB_SHOW_COMPONENT,
	// Timestamp when the frame is swapped in renderer.
	INPUT_EVENT_LATENCY_RENDERER_SWAP_COMPONENT,
	// Timestamp of when the browser process receives a buffer swap notification
	// from the renderer.
	INPUT_EVENT_BROWSER_RECEIVED_RENDERER_SWAP_COMPONENT,
	// Timestamp of when the gpu service began swap buffers, unlike
	// INPUT_EVENT_LATENCY_TERMINATED_FRAME_SWAP_COMPONENT which measures after.
	INPUT_EVENT_GPU_SWAP_BUFFER_COMPONENT,
	// Timestamp of when the gesture scroll update is generated from a mouse wheel
	// event.
	INPUT_EVENT_LATENCY_GENERATE_SCROLL_UPDATE_FROM_MOUSE_WHEEL,
	// ---------------------------TERMINAL COMPONENT-----------------------------
	// TERMINAL COMPONENT is when we show the latency end in chrome://tracing.
	// Timestamp when the mouse event is acked from renderer and it does not
	// cause any rendering scheduled.
	INPUT_EVENT_LATENCY_TERMINATED_MOUSE_COMPONENT,
	// Timestamp when the mouse wheel event is acked from renderer and it does not
	// cause any rendering scheduled.
	INPUT_EVENT_LATENCY_TERMINATED_MOUSE_WHEEL_COMPONENT,
	// Timestamp when the keyboard event is acked from renderer and it does not
	// cause any rendering scheduled.
	INPUT_EVENT_LATENCY_TERMINATED_KEYBOARD_COMPONENT,
	// Timestamp when the touch event is acked from renderer and it does not
	// cause any rendering scheduled and does not generate any gesture event.
	INPUT_EVENT_LATENCY_TERMINATED_TOUCH_COMPONENT,
	// Timestamp when the gesture event is acked from renderer, and it does not
	// cause any rendering scheduled.
	INPUT_EVENT_LATENCY_TERMINATED_GESTURE_COMPONENT,
	// Timestamp when the frame is swapped (i.e. when the rendering caused by
	// input event actually takes effect).
	INPUT_EVENT_LATENCY_TERMINATED_FRAME_SWAP_COMPONENT,
	// This component indicates that the input causes a commit to be scheduled
	// but the commit failed.
	INPUT_EVENT_LATENCY_TERMINATED_COMMIT_FAILED_COMPONENT,
	// This component indicates that the input causes a commit to be scheduled
	// but the commit was aborted since it carried no new information.
	INPUT_EVENT_LATENCY_TERMINATED_COMMIT_NO_UPDATE_COMPONENT,
	// This component indicates that the input causes a swap to be scheduled
	// but the swap failed.
	INPUT_EVENT_LATENCY_TERMINATED_SWAP_FAILED_COMPONENT,
	LATENCY_COMPONENT_TYPE_LAST =
	INPUT_EVENT_LATENCY_TERMINATED_SWAP_FAILED_COMPONENT,
	};

	class EVENTS_BASE_EXPORT LatencyInfo {
	public:
	struct LatencyComponent {
	// Nondecreasing number that can be used to determine what events happened
	// in the component at the time this struct was sent on to the next
	// component.
	int64_t sequence_number;
	// Average time of events that happened in this component.
	base::TimeTicks event_time;
	// Count of events that happened in this component
	uint32_t event_count;
	};

	struct EVENTS_BASE_EXPORT InputCoordinate {
	InputCoordinate();
	InputCoordinate(float x, float y);

	float x;
	float y;
	};

	// Empirically determined constant based on a typical scroll sequence.
	enum { kTypicalMaxComponentsPerLatencyInfo = 10 };

	enum { kMaxInputCoordinates = 2 };

	// Map a Latency Component (with a component-specific int64_t id) to a
	// component info.
	typedef base::SmallMap<
	std::map<std::pair<LatencyComponentType, int64_t>, LatencyComponent>,
	kTypicalMaxComponentsPerLatencyInfo> LatencyMap;

	LatencyInfo();
	LatencyInfo(const LatencyInfo& other);
	~LatencyInfo();

	// For test only.
	LatencyInfo(int64_t trace_id, bool terminated);

	// Returns true if the vector \|latency_info\| is valid. Returns false
	// if it is not valid and log the \|referring_msg\|.
	// This function is mainly used to check the latency_info vector that
	// is passed between processes using IPC message has reasonable size
	// so that we are confident the IPC message is not corrupted/compromised.
	// This check will go away once the IPC system has better built-in scheme
	// for corruption/compromise detection.
	static bool Verify(const std::vector<LatencyInfo>& latency_info,
	const char* referring_msg);

	// Copy LatencyComponents with type \|type\| from \|other\| into \|this\|.
	void CopyLatencyFrom(const LatencyInfo& other, LatencyComponentType type);

	// Add LatencyComponents that are in \|other\| but not in \|this\|.
	void AddNewLatencyFrom(const LatencyInfo& other);

	// Modifies the current sequence number for a component, and adds a new
	// sequence number with the current timestamp.
	void AddLatencyNumber(LatencyComponentType component,
	int64_t id,
	int64_t component_sequence_number);

	// Similar to \|AddLatencyNumber\|, and also appends \|trace_name_str\| to
	// the trace event's name.
	// This function should only be called when adding a BEGIN component.
	void AddLatencyNumberWithTraceName(LatencyComponentType component,
	int64_t id,
	int64_t component_sequence_number,
	const char* trace_name_str);

	// Modifies the current sequence number and adds a certain number of events
	// for a specific component.
	void AddLatencyNumberWithTimestamp(LatencyComponentType component,
	int64_t id,
	int64_t component_sequence_number,
	base::TimeTicks time,
	uint32_t event_count);

	// Returns true if the a component with \|type\| and \|id\| is found in
	// the latency_components and the component is stored to \|output\| if
	// \|output\| is not NULL. Returns false if no such component is found.
	bool FindLatency(LatencyComponentType type,
	int64_t id,
	LatencyComponent* output) const;

	void RemoveLatency(LatencyComponentType type);

	// Returns true if there is still room for keeping the \|input_coordinate\|,
	// false otherwise.
	bool AddInputCoordinate(const InputCoordinate& input_coordinate);

	uint32_t input_coordinates_size() const { return input_coordinates_size_; }
	const InputCoordinate* input_coordinates() const {
	return input_coordinates_;
	}

	const LatencyMap& latency_components() const { return latency_components_; }

	bool terminated() const { return terminated_; }
	void set_coalesced() { coalesced_ = true; }
	bool coalesced() const { return coalesced_; }
	int64_t trace_id() const { return trace_id_; }

	private:
	void AddLatencyNumberWithTimestampImpl(LatencyComponentType component,
	int64_t id,
	int64_t component_sequence_number,
	base::TimeTicks time,
	uint32_t event_count,
	const char* trace_name_str);

	// Converts latencyinfo into format that can be dumped into trace buffer.
	std::unique_ptr<base::trace_event::ConvertableToTraceFormat>
	AsTraceableData();
	std::unique_ptr<base::trace_event::ConvertableToTraceFormat>
	CoordinatesAsTraceableData();

	// Shown as part of the name of the trace event for this LatencyInfo.
	// String is empty if no tracing is enabled.
	std::string trace_name_;

	LatencyMap latency_components_;

	// These coordinates represent window coordinates of the original input event.
	uint32_t input_coordinates_size_;
	InputCoordinate input_coordinates_[kMaxInputCoordinates];

	// The unique id for matching the ASYNC_BEGIN/END trace event.
	int64_t trace_id_;
	// Whether this event has been coalesced into another event.
	bool coalesced_;
	// Whether a terminal component has been added.
	bool terminated_;

	#if !defined(OS_IOS)
	friend struct IPC::ParamTraits<ui::LatencyInfo>;
	#endif
	};

	} // namespace ui

	#endif // UI_EVENTS_LATENCY_INFO_H_