third_party/chromium/media/capture/content/video_capture_oracle.h - cobalt - Git at Google

 // Copyright (c) 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 MEDIA_CAPTURE_CONTENT_VIDEO_CAPTURE_ORACLE_H_
 #define MEDIA_CAPTURE_CONTENT_VIDEO_CAPTURE_ORACLE_H_

 #include <string>

 #include "base/callback.h"
 #include "base/time/time.h"
 #include "media/base/feedback_signal_accumulator.h"
 #include "media/capture/capture_export.h"
 #include "media/capture/content/animated_content_sampler.h"
 #include "media/capture/content/capture_resolution_chooser.h"
 #include "media/capture/content/smooth_event_sampler.h"
 #include "media/capture/video/video_capture_feedback.h"
 #include "ui/gfx/geometry/rect.h"

 namespace media {

 // VideoCaptureOracle manages the producer-side throttling of captured frames
 // from a video capture device.  It is informed of every update by the device;
 // this empowers it to look into the future and decide if a particular frame
 // ought to be captured in order to achieve its target frame rate.
 class CAPTURE_EXPORT VideoCaptureOracle {
  public:
   enum Event {
     kCompositorUpdate,
     kRefreshRequest,
     kNumEvents,
   };

   // Constructs a VideoCaptureOracle with a default min capture period and
   // capture size constraints. Clients should call SetMinCapturePeriod() and
   // SetCaptureSizeConstraints() to provide more-accurate hard limits.
   //
   // See SetAutoThrottlingEnabled() for |enable_auto_throttling| semantics.
   explicit VideoCaptureOracle(bool enable_auto_throttling);

   virtual ~VideoCaptureOracle();

   // Get/Update the minimum capture period.
   base::TimeDelta min_capture_period() const {
     return smoothing_sampler_.min_capture_period();
   }
   void SetMinCapturePeriod(base::TimeDelta period);

   // Sets the range of acceptable capture sizes and whether a fixed aspect ratio
   // is required. If a fixed aspect ratio is required, the aspect ratio of
   // |max_size| is used.
   void SetCaptureSizeConstraints(const gfx::Size& min_size,
                                  const gfx::Size& max_size,
                                  bool use_fixed_aspect_ratio);

   // Specifies whether the oracle should propose varying capture sizes, in
   // response to consumer feedback. If not |enabled|, capture_size() will always
   // return the source_size().
   //
   // See: SetMinSizeChangePeriod().
   void SetAutoThrottlingEnabled(bool enabled);

   // Get/Update the source content size.  Changes may not have an immediate
   // effect on the proposed capture size, as the oracle will prevent too-
   // frequent changes from occurring.
   gfx::Size source_size() const { return resolution_chooser_.source_size(); }
   void SetSourceSize(const gfx::Size& source_size);

   // Record a event of type |event|, and decide whether the caller should do a
   // frame capture.  |damage_rect| is the region of a frame about to be drawn,
   // and may be an empty Rect, if this is not known.  If the caller accepts the
   // oracle's proposal, it should call RecordCapture() to indicate this.
   bool ObserveEventAndDecideCapture(Event event,
                                     const gfx::Rect& damage_rect,
                                     base::TimeTicks event_time);

   // Returns the |frame_number| to be used with CompleteCapture().
   int next_frame_number() const { return next_frame_number_; }

   // Record and update internal state based on whether the frame capture will be
   // started.  |pool_utilization| is a value in the range 0.0 to 1.0 to indicate
   // the current buffer pool utilization relative to a sustainable maximum (not
   // the absolute maximum).  This method should only be called if the last call
   // to ObserveEventAndDecideCapture() returned true.
   void RecordCapture(double pool_utilization);
   void RecordWillNotCapture(double pool_utilization);

   // Notify of the completion of a capture, and whether it was successful.
   // Returns true iff the captured frame should be delivered.  |frame_timestamp|
   // is set to the timestamp that should be provided to the consumer of the
   // frame.
   virtual bool CompleteCapture(int frame_number,
                                bool capture_was_successful,
                                base::TimeTicks* frame_timestamp);

   // Notify that all in-flight captures have been canceled.  This has the same
   // effect as calling CompleteCapture() with a non-success status for all
   // outstanding frames.
   void CancelAllCaptures();

   // Record the resource utilization feedback for a frame that was processed by
   // the consumer.  This allows the oracle to reduce/increase future data volume
   // if the consumer is overloaded/under-utilized.  |resource_utilization| is a
   // value in the range 0.0 to 1.0 to indicate the current consumer resource
   // utilization relative to a sustainable maximum (not the absolute maximum).
   // This method should only be called for frames where CompleteCapture()
   // returned true.
   void RecordConsumerFeedback(int frame_number,
                               const media::VideoCaptureFeedback& feedback);

   // Sets the minimum amount of time that must pass between changes to the
   // capture size due to autothrottling. This throttles the rate of size
   // changes, to avoid stressing consumers and to allow the end-to-end system
   // sufficient time to stabilize before re-evaluating the capture size.
   void SetMinSizeChangePeriod(base::TimeDelta period);

   // Returns the oracle's estimate of the duration of the next frame.  This
   // should be called just after ObserveEventAndDecideCapture(), and will only
   // be non-zero if the call returned true.
   base::TimeDelta estimated_frame_duration() const {
     return duration_of_next_frame_;
   }

   // Returns the capture frame size the client should use.  This is updated by
   // calls to ObserveEventAndDecideCapture().  The oracle prevents too-frequent
   // changes to the capture size, to avoid stressing the end-to-end pipeline.
   virtual gfx::Size capture_size() const;

   // Returns the oracle's estimate of the last time animation was detected.
   base::TimeTicks last_time_animation_was_detected() const {
     return last_time_animation_was_detected_;
   }

   // Returns a NUL-terminated string containing a short, human-readable form of
   // |event|.
   static const char* EventAsString(Event event);

   // Default minimum capture period. This is a rather low framerate for safety.
   // Clients are expected to set a better minimum capture period after
   // VideoCaptureOracle is constructed.
   static constexpr base::TimeDelta kDefaultMinCapturePeriod =
       base::Microseconds(1000000 / 5);  // 5 FPS

   // Default minimum size change period if SetMinSizeChangePeriod is not called.
   static constexpr base::TimeDelta kDefaultMinSizeChangePeriod =
       base::Seconds(3);

   void SetLogCallback(
       base::RepeatingCallback<void(const std::string&)> emit_log_cb);

   void Log(const std::string& message);

  private:
   // Retrieve/Assign a frame timestamp by capture |frame_number|.  Only valid
   // when IsFrameInRecentHistory(frame_number) returns true.
   base::TimeTicks GetFrameTimestamp(int frame_number) const;
   void SetFrameTimestamp(int frame_number, base::TimeTicks timestamp);

   // Returns true if the frame timestamp ring-buffer currently includes a
   // slot for the given |frame_number|.
   bool IsFrameInRecentHistory(int frame_number) const;

   // Queries the ResolutionChooser to update |capture_size_|, and resets all the
   // FeedbackSignalAccumulator members to stable-state starting values.  The
   // accumulators are reset such that they can only apply feedback updates for
   // future frames (those with a timestamp after |last_frame_time|).
   void CommitCaptureSizeAndReset(base::TimeTicks last_frame_time);

   // Called after a capture or no-capture decision was recorded.  This analyzes
   // current state and may result in a future change to the capture size.
   void AnalyzeAndAdjust(base::TimeTicks analyze_time);

   // Analyzes current feedback signal accumulators for an indication that the
   // capture size should be decreased.  Returns either a decreased area, or -1
   // if no decrease should be made.
   int AnalyzeForDecreasedArea(base::TimeTicks analyze_time);

   // Analyzes current feedback signal accumulators for an indication that the
   // the system has had excellent long-term performance and the capture size
   // should be increased to improve quality.  Returns either an increased area,
   // or -1 if no increase should be made.
   int AnalyzeForIncreasedArea(base::TimeTicks analyze_time);

   // Returns the amount of time, since the source size last changed, to allow
   // frequent increases in capture area.  This allows the system a period of
   // time to quickly explore up and down to find an ideal point before being
   // more careful about capture size increases.
   base::TimeDelta GetExplorationPeriodAfterSourceSizeChange();

   // Returns true if updates have been accumulated by |accumulator| for a
   // sufficient amount of time and the latest update was fairly recent, relative
   // to |now|.
   bool HasSufficientRecentFeedback(
       const FeedbackSignalAccumulator<base::TimeTicks>& accumulator,
       base::TimeTicks now);

   // Set to disabled/enabled via SetAutoThrottlingEnabled(). Data collection and
   // analysis for capture size changes only occurs while in "active" mode, which
   // is only engaged when in "enabled" mode and consumer feedback is received
   // for the first time.
   enum {
     kThrottlingDisabled,
     kThrottlingEnabled,
     kThrottlingActive
   } capture_size_throttling_mode_;

   // The minimum amount of time that must pass between changes to the capture
   // size.
   base::TimeDelta min_size_change_period_;

   // Incremented every time RecordCapture() is called.
   int next_frame_number_;

   // Stores the last |event_time| from the last observation/decision.  Used to
   // sanity-check that event times are monotonically non-decreasing.
   base::TimeTicks last_event_time_[kNumEvents];

   // Updated by the last call to ObserveEventAndDecideCapture() with the
   // estimated duration of the next frame to sample.  This is zero if the method
   // returned false.
   base::TimeDelta duration_of_next_frame_;

   // Stores the frame number from the last successfully delivered frame.
   int last_successfully_delivered_frame_number_;

   // Stores the number of pending frame captures.
   int num_frames_pending_;

   // These track present/paint history and propose whether to sample each event
   // for capture.  |smoothing_sampler_| uses a "works for all" heuristic, while
   // |content_sampler_| specifically detects animated content (e.g., video
   // playback) and decides which events to sample to "lock into" that content.
   SmoothEventSampler smoothing_sampler_;
   AnimatedContentSampler content_sampler_;

   // This is the overall setting, provided in the last call to
   // SetMinCapturePeriod(), but the live setting in |smoothing_sampler_| and
   // |content_sampler_| could be greater if the consumer feedback requests it.
   base::TimeDelta min_capture_period_;

   // Determines video capture frame sizes.
   CaptureResolutionChooser resolution_chooser_;

   // The timestamp of the frame just before the last call to SetSourceSize().
   base::TimeTicks source_size_change_time_;

   // The current capture size.  |resolution_chooser_| may hold an updated value
   // because the oracle prevents this size from changing too frequently.  This
   // avoids over-stressing consumers (e.g., when a window is being activly
   // drag-resized) and allowing the end-to-end system time to stabilize.
   gfx::Size capture_size_;

   // Recent history of frame timestamps proposed by VideoCaptureOracle.  This is
   // a ring-buffer, and should only be accessed by the Get/SetFrameTimestamp()
   // methods.
   enum { kMaxFrameTimestamps = 16 };
   base::TimeTicks frame_timestamps_[kMaxFrameTimestamps];

   // Recent average buffer pool utilization for capture.
   FeedbackSignalAccumulator<base::TimeTicks> buffer_pool_utilization_;

   // Estimated maximum frame area that currently can be handled by the consumer,
   // in number of pixels per frame.  This is used to adjust the capture size up
   // or down to a data volume the consumer can handle.  Note that some consumers
   // do not provide feedback, and the analysis logic should account for that.
   FeedbackSignalAccumulator<base::TimeTicks> estimated_capable_area_;

   // The time of the first analysis which concluded the end-to-end system was
   // under-utilized.  If null, the system is not currently under-utilized.  This
   // is used to determine when a proving period has elapsed that justifies an
   // increase in capture size.
   base::TimeTicks start_time_of_underutilization_;

   // The timestamp of the frame where |content_sampler_| last detected
   // animation.  This determines whether capture size increases will be
   // aggressive (because content is not animating).
   base::TimeTicks last_time_animation_was_detected_;

   // Callback for webrtc native log. It should check for corresponding feature
   // inside.
   base::RepeatingCallback<void(const std::string&)> emit_log_message_cb_;
 };

 }  // namespace media

 #endif  // MEDIA_CAPTURE_CONTENT_VIDEO_CAPTURE_ORACLE_H_
	// Copyright (c) 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 MEDIA_CAPTURE_CONTENT_VIDEO_CAPTURE_ORACLE_H_
	#define MEDIA_CAPTURE_CONTENT_VIDEO_CAPTURE_ORACLE_H_

	#include <string>

	#include "base/callback.h"
	#include "base/time/time.h"
	#include "media/base/feedback_signal_accumulator.h"
	#include "media/capture/capture_export.h"
	#include "media/capture/content/animated_content_sampler.h"
	#include "media/capture/content/capture_resolution_chooser.h"
	#include "media/capture/content/smooth_event_sampler.h"
	#include "media/capture/video/video_capture_feedback.h"
	#include "ui/gfx/geometry/rect.h"

	namespace media {

	// VideoCaptureOracle manages the producer-side throttling of captured frames
	// from a video capture device. It is informed of every update by the device;
	// this empowers it to look into the future and decide if a particular frame
	// ought to be captured in order to achieve its target frame rate.
	class CAPTURE_EXPORT VideoCaptureOracle {
	public:
	enum Event {
	kCompositorUpdate,
	kRefreshRequest,
	kNumEvents,
	};

	// Constructs a VideoCaptureOracle with a default min capture period and
	// capture size constraints. Clients should call SetMinCapturePeriod() and
	// SetCaptureSizeConstraints() to provide more-accurate hard limits.
	//
	// See SetAutoThrottlingEnabled() for \|enable_auto_throttling\| semantics.
	explicit VideoCaptureOracle(bool enable_auto_throttling);

	virtual ~VideoCaptureOracle();

	// Get/Update the minimum capture period.
	base::TimeDelta min_capture_period() const {
	return smoothing_sampler_.min_capture_period();
	}
	void SetMinCapturePeriod(base::TimeDelta period);

	// Sets the range of acceptable capture sizes and whether a fixed aspect ratio
	// is required. If a fixed aspect ratio is required, the aspect ratio of
	// \|max_size\| is used.
	void SetCaptureSizeConstraints(const gfx::Size& min_size,
	const gfx::Size& max_size,
	bool use_fixed_aspect_ratio);

	// Specifies whether the oracle should propose varying capture sizes, in
	// response to consumer feedback. If not \|enabled\|, capture_size() will always
	// return the source_size().
	//
	// See: SetMinSizeChangePeriod().
	void SetAutoThrottlingEnabled(bool enabled);

	// Get/Update the source content size. Changes may not have an immediate
	// effect on the proposed capture size, as the oracle will prevent too-
	// frequent changes from occurring.
	gfx::Size source_size() const { return resolution_chooser_.source_size(); }
	void SetSourceSize(const gfx::Size& source_size);

	// Record a event of type \|event\|, and decide whether the caller should do a
	// frame capture. \|damage_rect\| is the region of a frame about to be drawn,
	// and may be an empty Rect, if this is not known. If the caller accepts the
	// oracle's proposal, it should call RecordCapture() to indicate this.
	bool ObserveEventAndDecideCapture(Event event,
	const gfx::Rect& damage_rect,
	base::TimeTicks event_time);

	// Returns the \|frame_number\| to be used with CompleteCapture().
	int next_frame_number() const { return next_frame_number_; }

	// Record and update internal state based on whether the frame capture will be
	// started. \|pool_utilization\| is a value in the range 0.0 to 1.0 to indicate
	// the current buffer pool utilization relative to a sustainable maximum (not
	// the absolute maximum). This method should only be called if the last call
	// to ObserveEventAndDecideCapture() returned true.
	void RecordCapture(double pool_utilization);
	void RecordWillNotCapture(double pool_utilization);

	// Notify of the completion of a capture, and whether it was successful.
	// Returns true iff the captured frame should be delivered. \|frame_timestamp\|
	// is set to the timestamp that should be provided to the consumer of the
	// frame.
	virtual bool CompleteCapture(int frame_number,
	bool capture_was_successful,
	base::TimeTicks* frame_timestamp);

	// Notify that all in-flight captures have been canceled. This has the same
	// effect as calling CompleteCapture() with a non-success status for all
	// outstanding frames.
	void CancelAllCaptures();

	// Record the resource utilization feedback for a frame that was processed by
	// the consumer. This allows the oracle to reduce/increase future data volume
	// if the consumer is overloaded/under-utilized. \|resource_utilization\| is a
	// value in the range 0.0 to 1.0 to indicate the current consumer resource
	// utilization relative to a sustainable maximum (not the absolute maximum).
	// This method should only be called for frames where CompleteCapture()
	// returned true.
	void RecordConsumerFeedback(int frame_number,
	const media::VideoCaptureFeedback& feedback);

	// Sets the minimum amount of time that must pass between changes to the
	// capture size due to autothrottling. This throttles the rate of size
	// changes, to avoid stressing consumers and to allow the end-to-end system
	// sufficient time to stabilize before re-evaluating the capture size.
	void SetMinSizeChangePeriod(base::TimeDelta period);

	// Returns the oracle's estimate of the duration of the next frame. This
	// should be called just after ObserveEventAndDecideCapture(), and will only
	// be non-zero if the call returned true.
	base::TimeDelta estimated_frame_duration() const {
	return duration_of_next_frame_;
	}

	// Returns the capture frame size the client should use. This is updated by
	// calls to ObserveEventAndDecideCapture(). The oracle prevents too-frequent
	// changes to the capture size, to avoid stressing the end-to-end pipeline.
	virtual gfx::Size capture_size() const;

	// Returns the oracle's estimate of the last time animation was detected.
	base::TimeTicks last_time_animation_was_detected() const {
	return last_time_animation_was_detected_;
	}

	// Returns a NUL-terminated string containing a short, human-readable form of
	// \|event\|.
	static const char* EventAsString(Event event);

	// Default minimum capture period. This is a rather low framerate for safety.
	// Clients are expected to set a better minimum capture period after
	// VideoCaptureOracle is constructed.
	static constexpr base::TimeDelta kDefaultMinCapturePeriod =
	base::Microseconds(1000000 / 5); // 5 FPS

	// Default minimum size change period if SetMinSizeChangePeriod is not called.
	static constexpr base::TimeDelta kDefaultMinSizeChangePeriod =
	base::Seconds(3);

	void SetLogCallback(
	base::RepeatingCallback<void(const std::string&)> emit_log_cb);

	void Log(const std::string& message);

	private:
	// Retrieve/Assign a frame timestamp by capture \|frame_number\|. Only valid
	// when IsFrameInRecentHistory(frame_number) returns true.
	base::TimeTicks GetFrameTimestamp(int frame_number) const;
	void SetFrameTimestamp(int frame_number, base::TimeTicks timestamp);

	// Returns true if the frame timestamp ring-buffer currently includes a
	// slot for the given \|frame_number\|.
	bool IsFrameInRecentHistory(int frame_number) const;

	// Queries the ResolutionChooser to update \|capture_size_\|, and resets all the
	// FeedbackSignalAccumulator members to stable-state starting values. The
	// accumulators are reset such that they can only apply feedback updates for
	// future frames (those with a timestamp after \|last_frame_time\|).
	void CommitCaptureSizeAndReset(base::TimeTicks last_frame_time);

	// Called after a capture or no-capture decision was recorded. This analyzes
	// current state and may result in a future change to the capture size.
	void AnalyzeAndAdjust(base::TimeTicks analyze_time);

	// Analyzes current feedback signal accumulators for an indication that the
	// capture size should be decreased. Returns either a decreased area, or -1
	// if no decrease should be made.
	int AnalyzeForDecreasedArea(base::TimeTicks analyze_time);

	// Analyzes current feedback signal accumulators for an indication that the
	// the system has had excellent long-term performance and the capture size
	// should be increased to improve quality. Returns either an increased area,
	// or -1 if no increase should be made.
	int AnalyzeForIncreasedArea(base::TimeTicks analyze_time);

	// Returns the amount of time, since the source size last changed, to allow
	// frequent increases in capture area. This allows the system a period of
	// time to quickly explore up and down to find an ideal point before being
	// more careful about capture size increases.
	base::TimeDelta GetExplorationPeriodAfterSourceSizeChange();

	// Returns true if updates have been accumulated by \|accumulator\| for a
	// sufficient amount of time and the latest update was fairly recent, relative
	// to \|now\|.
	bool HasSufficientRecentFeedback(
	const FeedbackSignalAccumulator<base::TimeTicks>& accumulator,
	base::TimeTicks now);

	// Set to disabled/enabled via SetAutoThrottlingEnabled(). Data collection and
	// analysis for capture size changes only occurs while in "active" mode, which
	// is only engaged when in "enabled" mode and consumer feedback is received
	// for the first time.
	enum {
	kThrottlingDisabled,
	kThrottlingEnabled,
	kThrottlingActive
	} capture_size_throttling_mode_;

	// The minimum amount of time that must pass between changes to the capture
	// size.
	base::TimeDelta min_size_change_period_;

	// Incremented every time RecordCapture() is called.
	int next_frame_number_;

	// Stores the last \|event_time\| from the last observation/decision. Used to
	// sanity-check that event times are monotonically non-decreasing.
	base::TimeTicks last_event_time_[kNumEvents];

	// Updated by the last call to ObserveEventAndDecideCapture() with the
	// estimated duration of the next frame to sample. This is zero if the method
	// returned false.
	base::TimeDelta duration_of_next_frame_;

	// Stores the frame number from the last successfully delivered frame.
	int last_successfully_delivered_frame_number_;

	// Stores the number of pending frame captures.
	int num_frames_pending_;

	// These track present/paint history and propose whether to sample each event
	// for capture. \|smoothing_sampler_\| uses a "works for all" heuristic, while
	// \|content_sampler_\| specifically detects animated content (e.g., video
	// playback) and decides which events to sample to "lock into" that content.
	SmoothEventSampler smoothing_sampler_;
	AnimatedContentSampler content_sampler_;

	// This is the overall setting, provided in the last call to
	// SetMinCapturePeriod(), but the live setting in \|smoothing_sampler_\| and
	// \|content_sampler_\| could be greater if the consumer feedback requests it.
	base::TimeDelta min_capture_period_;

	// Determines video capture frame sizes.
	CaptureResolutionChooser resolution_chooser_;

	// The timestamp of the frame just before the last call to SetSourceSize().
	base::TimeTicks source_size_change_time_;

	// The current capture size. \|resolution_chooser_\| may hold an updated value
	// because the oracle prevents this size from changing too frequently. This
	// avoids over-stressing consumers (e.g., when a window is being activly
	// drag-resized) and allowing the end-to-end system time to stabilize.
	gfx::Size capture_size_;

	// Recent history of frame timestamps proposed by VideoCaptureOracle. This is
	// a ring-buffer, and should only be accessed by the Get/SetFrameTimestamp()
	// methods.
	enum { kMaxFrameTimestamps = 16 };
	base::TimeTicks frame_timestamps_[kMaxFrameTimestamps];

	// Recent average buffer pool utilization for capture.
	FeedbackSignalAccumulator<base::TimeTicks> buffer_pool_utilization_;

	// Estimated maximum frame area that currently can be handled by the consumer,
	// in number of pixels per frame. This is used to adjust the capture size up
	// or down to a data volume the consumer can handle. Note that some consumers
	// do not provide feedback, and the analysis logic should account for that.
	FeedbackSignalAccumulator<base::TimeTicks> estimated_capable_area_;

	// The time of the first analysis which concluded the end-to-end system was
	// under-utilized. If null, the system is not currently under-utilized. This
	// is used to determine when a proving period has elapsed that justifies an
	// increase in capture size.
	base::TimeTicks start_time_of_underutilization_;

	// The timestamp of the frame where \|content_sampler_\| last detected
	// animation. This determines whether capture size increases will be
	// aggressive (because content is not animating).
	base::TimeTicks last_time_animation_was_detected_;

	// Callback for webrtc native log. It should check for corresponding feature
	// inside.
	base::RepeatingCallback<void(const std::string&)> emit_log_message_cb_;
	};

	} // namespace media

	#endif // MEDIA_CAPTURE_CONTENT_VIDEO_CAPTURE_ORACLE_H_