remoting/protocol/webrtc_frame_scheduler_simple.cc - chromium/src - Git at Google

 // Copyright 2016 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 "remoting/protocol/webrtc_frame_scheduler_simple.h"

 #include <algorithm>

 #include "base/time/default_tick_clock.h"
 #include "remoting/base/constants.h"
 #include "remoting/protocol/frame_stats.h"
 #include "remoting/protocol/webrtc_bandwidth_estimator.h"
 #include "remoting/protocol/webrtc_dummy_video_encoder.h"
 #include "third_party/webrtc/modules/desktop_capture/desktop_frame.h"

 namespace remoting {
 namespace protocol {

 namespace {

 // Number of samples used to estimate processing time for the next frame.
 const int kStatsWindow = 5;

 constexpr base::TimeDelta kTargetFrameInterval =
     base::TimeDelta::FromMilliseconds(1000 / kTargetFrameRate);

 // Target quantizer at which stop the encoding top-off.
 const int kTargetQuantizerForVp8TopOff = 30;

 // Maximum quantizer at which to encode frames. Lowering this value will
 // improve image quality (in cases of low-bandwidth or large frames) at the
 // cost of latency. Increasing the value will improve latency (in these cases)
 // at the cost of image quality, resulting in longer top-off times.
 // TODO(lambroslambrou): Move this, and any other encoder-specific parameters
 // into the WebrtcVideoEncoderXXX implementations.
 const int kMaxQuantizer = 50;

 const int64_t kPixelsPerMegapixel = 1000000;

 // Threshold in number of updated pixels used to detect "big" frames. These
 // frames update significant portion of the screen compared to the preceding
 // frames. For these frames min quantizer may need to be adjusted in order to
 // ensure that they get delivered to the client as soon as possible, in exchange
 // for lower-quality image.
 const int kBigFrameThresholdPixels = 300000;

 // Estimated size (in bytes per megapixel) of encoded frame at target quantizer
 // value (see kTargetQuantizerForVp8TopOff). Compression ratio varies depending
 // on the image, so this is just a rough estimate. It's used to predict when
 // encoded "big" frame may be too large to be delivered to the client quickly.
 const int kEstimatedBytesPerMegapixel = 100000;

 // Minimum interval between frames needed to keep the connection alive. The
 // client will request a key-frame if it does not receive any frames for a
 // 3-second period. This is effectively a minimum frame-rate, so the value
 // should not be too small, otherwise the client may waste CPU cycles on
 // processing and rendering lots of identical frames.
 constexpr base::TimeDelta kKeepAliveInterval =
     base::TimeDelta::FromMilliseconds(2000);

 int64_t GetRegionArea(const webrtc::DesktopRegion& region) {
   int64_t result = 0;
   for (webrtc::DesktopRegion::Iterator r(region); !r.IsAtEnd(); r.Advance()) {
     result += r.rect().width() * r.rect().height();
   }
   return result;
 }

 }  // namespace

 // TODO(zijiehe): Use |options| to select bandwidth estimator.
 WebrtcFrameSchedulerSimple::WebrtcFrameSchedulerSimple(
     const SessionOptions& options)
     : tick_clock_(base::DefaultTickClock::GetInstance()),
       pacing_bucket_(LeakyBucket::kUnlimitedDepth, 0),
       updated_region_area_(kStatsWindow),
       bandwidth_estimator_(new WebrtcBandwidthEstimator()),
       weak_factory_(this) {}

 WebrtcFrameSchedulerSimple::~WebrtcFrameSchedulerSimple() {
   DCHECK(thread_checker_.CalledOnValidThread());
 }

 void WebrtcFrameSchedulerSimple::OnKeyFrameRequested() {
   DCHECK(thread_checker_.CalledOnValidThread());
   encoder_ready_ = true;
   key_frame_request_ = true;
   ScheduleNextFrame();
 }

 void WebrtcFrameSchedulerSimple::OnChannelParameters(int packet_loss,
                                                      base::TimeDelta rtt) {
   DCHECK(thread_checker_.CalledOnValidThread());

   bandwidth_estimator_->UpdateRtt(rtt);
   rtt_estimate_ = rtt;
 }

 void WebrtcFrameSchedulerSimple::OnTargetBitrateChanged(int bandwidth_kbps) {
   DCHECK(thread_checker_.CalledOnValidThread());
   bandwidth_estimator_->OnReceivedAck();
   bandwidth_estimator_->OnBitrateEstimation(bandwidth_kbps);
   processing_time_estimator_.SetBandwidthKbps(
       bandwidth_estimator_->GetBitrateKbps());
   pacing_bucket_.UpdateRate(bandwidth_estimator_->GetBitrateKbps() * 1000 / 8,
                             tick_clock_->NowTicks());
   ScheduleNextFrame();
 }

 void WebrtcFrameSchedulerSimple::Start(
     WebrtcDummyVideoEncoderFactory* video_encoder_factory,
     const base::Closure& capture_callback) {
   DCHECK(thread_checker_.CalledOnValidThread());
   capture_callback_ = capture_callback;
   video_encoder_factory->SetVideoChannelStateObserver(
       weak_factory_.GetWeakPtr());
 }

 void WebrtcFrameSchedulerSimple::Pause(bool pause) {
   DCHECK(thread_checker_.CalledOnValidThread());

   paused_ = pause;
   if (paused_) {
     capture_timer_.Stop();
   } else {
     ScheduleNextFrame();
   }
 }

 bool WebrtcFrameSchedulerSimple::OnFrameCaptured(
     const webrtc::DesktopFrame* frame,
     WebrtcVideoEncoder::FrameParams* params_out) {
   DCHECK(thread_checker_.CalledOnValidThread());

   base::TimeTicks now = tick_clock_->NowTicks();

   // Null |frame| indicates a capturer error.
   if (!frame) {
     frame_pending_ = false;
     ScheduleNextFrame();
     return false;
   }

   if (frame->updated_region().is_empty()) {
     // If we've captured an empty frame we still need to encode and send the
     // previous frame when top-off is active or a key-frame was requested. But
     // it makes sense only when we have a frame to send, i.e. there is nothing
     // to send if first capture request failed.
     // Also send previous frame if there haven't been any frame updates for a
     // while, to keep the video stream alive. Otherwise, the client will
     // think the video stream is frozen and will attempt to recover it by
     // requesting a key-frame every few seconds, wasting network resources.
     bool send_frame =
         top_off_is_active_ || key_frame_request_ ||
         (now - latest_frame_encode_start_time_ > kKeepAliveInterval);
     if (!send_frame) {
       frame_pending_ = false;
       ScheduleNextFrame();
       return false;
     }
   }

   // Encoder uses frame duration to calculate portion of the target bitrate it
   // can use for this frame. Higher values normally will cause bigger encoded
   // frames that will take longer to be delivered to the client. To keep
   // end-to-end latency low always pass the target frame duration. The actual
   // interval between frames can be longer than the target value, depending on
   // the size of the encoded frames.
   params_out->duration = kTargetFrameInterval;
   params_out->fps = processing_time_estimator_.EstimatedFrameRate();

   latest_frame_encode_start_time_ = now;

   params_out->bitrate_kbps = pacing_bucket_.rate() * 8 / 1000;
   params_out->key_frame = key_frame_request_;
   key_frame_request_ = false;

   params_out->vpx_min_quantizer = 10;

   int64_t updated_area = params_out->key_frame
                              ? frame->size().width() * frame->size().height()
                              : GetRegionArea(frame->updated_region());

   // TODO(zijiehe): This logic should be removed if a codec without top-off
   // supported is used.
   // If bandwidth is being underutilized then libvpx is likely to choose the
   // minimum allowed quantizer value, which means that encoded frame size may
   // be significantly bigger than the bandwidth allows. Detect this case and set
   // vpx_min_quantizer to the maximum value. The quality will be topped off
   // later.
   if (updated_area - updated_region_area_.Max() > kBigFrameThresholdPixels) {
     int expected_frame_size =
         updated_area * kEstimatedBytesPerMegapixel / kPixelsPerMegapixel;
     base::TimeDelta expected_send_delay =
         pacing_bucket_.rate() ? base::TimeDelta::FromMicroseconds(
                                     base::Time::kMicrosecondsPerSecond *
                                     expected_frame_size / pacing_bucket_.rate())
                               : base::TimeDelta::Max();
     if (expected_send_delay > kTargetFrameInterval) {
       params_out->vpx_min_quantizer = kMaxQuantizer;
     }
   }

   updated_region_area_.Record(updated_area);

   params_out->vpx_max_quantizer = kMaxQuantizer;

   params_out->clear_active_map = !top_off_is_active_;

   return true;
 }

 void WebrtcFrameSchedulerSimple::OnFrameEncoded(
     const WebrtcVideoEncoder::EncodedFrame* encoded_frame,
     HostFrameStats* frame_stats) {
   DCHECK(thread_checker_.CalledOnValidThread());
   DCHECK(frame_pending_);
   frame_pending_ = false;

   base::TimeTicks now = tick_clock_->NowTicks();

   if (frame_stats) {
     // Calculate |send_pending_delay| before refilling |pacing_bucket_|.
     frame_stats->send_pending_delay =
         std::max(base::TimeDelta(), pacing_bucket_.GetEmptyTime() - now);
   }

   // TODO(zijiehe): |encoded_frame|->data.empty() is unreasonable, we should try
   // to get rid of it in WebrtcVideoEncoder layer.
   if (!encoded_frame || encoded_frame->data.empty()) {
     top_off_is_active_ = false;
   } else {
     pacing_bucket_.RefillOrSpill(encoded_frame->data.size(), now);

     processing_time_estimator_.FinishFrame(*encoded_frame);

     // Top-off until the target quantizer value is reached.
     top_off_is_active_ =
         encoded_frame->quantizer > kTargetQuantizerForVp8TopOff;
   }

   ScheduleNextFrame();

   if (frame_stats) {
     frame_stats->rtt_estimate = rtt_estimate_;
     frame_stats->bandwidth_estimate_kbps =
         bandwidth_estimator_->GetBitrateKbps();
   }

   bandwidth_estimator_->OnSendingFrame(*encoded_frame);
 }

 void WebrtcFrameSchedulerSimple::SetTickClockForTest(
     const base::TickClock* tick_clock) {
   tick_clock_ = tick_clock;
 }

 void WebrtcFrameSchedulerSimple::ScheduleNextFrame() {
   DCHECK(thread_checker_.CalledOnValidThread());
   base::TimeTicks now = tick_clock_->NowTicks();

   if (!encoder_ready_ || paused_ || pacing_bucket_.rate() == 0 ||
       capture_callback_.is_null() || frame_pending_) {
     return;
   }

   base::TimeTicks target_capture_time;
   if (!last_capture_started_time_.is_null()) {
     // Try to set the capture time so that (if the estimated processing time is
     // accurate) the new frame is ready to be sent just when the previous frame
     // is finished sending.
     target_capture_time = pacing_bucket_.GetEmptyTime() -
         processing_time_estimator_.EstimatedProcessingTime(key_frame_request_);

     // Ensure that the capture rate is capped by kTargetFrameInterval, to avoid
     // excessive CPU usage by the capturer.
     target_capture_time = std::max(
         target_capture_time, last_capture_started_time_ + kTargetFrameInterval);
   }

   target_capture_time = std::max(target_capture_time, now);

   capture_timer_.Start(FROM_HERE, target_capture_time - now,
                        base::Bind(&WebrtcFrameSchedulerSimple::CaptureNextFrame,
                                   base::Unretained(this)));
 }

 void WebrtcFrameSchedulerSimple::CaptureNextFrame() {
   DCHECK(thread_checker_.CalledOnValidThread());
   DCHECK(!frame_pending_);
   last_capture_started_time_ = tick_clock_->NowTicks();
   processing_time_estimator_.StartFrame();
   frame_pending_ = true;
   capture_callback_.Run();
 }

 }  // namespace protocol
 }  // namespace remoting
	// Copyright 2016 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 "remoting/protocol/webrtc_frame_scheduler_simple.h"

	#include <algorithm>

	#include "base/time/default_tick_clock.h"
	#include "remoting/base/constants.h"
	#include "remoting/protocol/frame_stats.h"
	#include "remoting/protocol/webrtc_bandwidth_estimator.h"
	#include "remoting/protocol/webrtc_dummy_video_encoder.h"
	#include "third_party/webrtc/modules/desktop_capture/desktop_frame.h"

	namespace remoting {
	namespace protocol {

	namespace {

	// Number of samples used to estimate processing time for the next frame.
	const int kStatsWindow = 5;

	constexpr base::TimeDelta kTargetFrameInterval =
	base::TimeDelta::FromMilliseconds(1000 / kTargetFrameRate);

	// Target quantizer at which stop the encoding top-off.
	const int kTargetQuantizerForVp8TopOff = 30;

	// Maximum quantizer at which to encode frames. Lowering this value will
	// improve image quality (in cases of low-bandwidth or large frames) at the
	// cost of latency. Increasing the value will improve latency (in these cases)
	// at the cost of image quality, resulting in longer top-off times.
	// TODO(lambroslambrou): Move this, and any other encoder-specific parameters
	// into the WebrtcVideoEncoderXXX implementations.
	const int kMaxQuantizer = 50;

	const int64_t kPixelsPerMegapixel = 1000000;

	// Threshold in number of updated pixels used to detect "big" frames. These
	// frames update significant portion of the screen compared to the preceding
	// frames. For these frames min quantizer may need to be adjusted in order to
	// ensure that they get delivered to the client as soon as possible, in exchange
	// for lower-quality image.
	const int kBigFrameThresholdPixels = 300000;

	// Estimated size (in bytes per megapixel) of encoded frame at target quantizer
	// value (see kTargetQuantizerForVp8TopOff). Compression ratio varies depending
	// on the image, so this is just a rough estimate. It's used to predict when
	// encoded "big" frame may be too large to be delivered to the client quickly.
	const int kEstimatedBytesPerMegapixel = 100000;

	// Minimum interval between frames needed to keep the connection alive. The
	// client will request a key-frame if it does not receive any frames for a
	// 3-second period. This is effectively a minimum frame-rate, so the value
	// should not be too small, otherwise the client may waste CPU cycles on
	// processing and rendering lots of identical frames.
	constexpr base::TimeDelta kKeepAliveInterval =
	base::TimeDelta::FromMilliseconds(2000);

	int64_t GetRegionArea(const webrtc::DesktopRegion& region) {
	int64_t result = 0;
	for (webrtc::DesktopRegion::Iterator r(region); !r.IsAtEnd(); r.Advance()) {
	result += r.rect().width() * r.rect().height();
	}
	return result;
	}

	} // namespace

	// TODO(zijiehe): Use \|options\| to select bandwidth estimator.
	WebrtcFrameSchedulerSimple::WebrtcFrameSchedulerSimple(
	const SessionOptions& options)
	: tick_clock_(base::DefaultTickClock::GetInstance()),
	pacing_bucket_(LeakyBucket::kUnlimitedDepth, 0),
	updated_region_area_(kStatsWindow),
	bandwidth_estimator_(new WebrtcBandwidthEstimator()),
	weak_factory_(this) {}

	WebrtcFrameSchedulerSimple::~WebrtcFrameSchedulerSimple() {
	DCHECK(thread_checker_.CalledOnValidThread());
	}

	void WebrtcFrameSchedulerSimple::OnKeyFrameRequested() {
	DCHECK(thread_checker_.CalledOnValidThread());
	encoder_ready_ = true;
	key_frame_request_ = true;
	ScheduleNextFrame();
	}

	void WebrtcFrameSchedulerSimple::OnChannelParameters(int packet_loss,
	base::TimeDelta rtt) {
	DCHECK(thread_checker_.CalledOnValidThread());

	bandwidth_estimator_->UpdateRtt(rtt);
	rtt_estimate_ = rtt;
	}

	void WebrtcFrameSchedulerSimple::OnTargetBitrateChanged(int bandwidth_kbps) {
	DCHECK(thread_checker_.CalledOnValidThread());
	bandwidth_estimator_->OnReceivedAck();
	bandwidth_estimator_->OnBitrateEstimation(bandwidth_kbps);
	processing_time_estimator_.SetBandwidthKbps(
	bandwidth_estimator_->GetBitrateKbps());
	pacing_bucket_.UpdateRate(bandwidth_estimator_->GetBitrateKbps() * 1000 / 8,
	tick_clock_->NowTicks());
	ScheduleNextFrame();
	}

	void WebrtcFrameSchedulerSimple::Start(
	WebrtcDummyVideoEncoderFactory* video_encoder_factory,
	const base::Closure& capture_callback) {
	DCHECK(thread_checker_.CalledOnValidThread());
	capture_callback_ = capture_callback;
	video_encoder_factory->SetVideoChannelStateObserver(
	weak_factory_.GetWeakPtr());
	}

	void WebrtcFrameSchedulerSimple::Pause(bool pause) {
	DCHECK(thread_checker_.CalledOnValidThread());

	paused_ = pause;
	if (paused_) {
	capture_timer_.Stop();
	} else {
	ScheduleNextFrame();
	}
	}

	bool WebrtcFrameSchedulerSimple::OnFrameCaptured(
	const webrtc::DesktopFrame* frame,
	WebrtcVideoEncoder::FrameParams* params_out) {
	DCHECK(thread_checker_.CalledOnValidThread());

	base::TimeTicks now = tick_clock_->NowTicks();

	// Null \|frame\| indicates a capturer error.
	if (!frame) {
	frame_pending_ = false;
	ScheduleNextFrame();
	return false;
	}

	if (frame->updated_region().is_empty()) {
	// If we've captured an empty frame we still need to encode and send the
	// previous frame when top-off is active or a key-frame was requested. But
	// it makes sense only when we have a frame to send, i.e. there is nothing
	// to send if first capture request failed.
	// Also send previous frame if there haven't been any frame updates for a
	// while, to keep the video stream alive. Otherwise, the client will
	// think the video stream is frozen and will attempt to recover it by
	// requesting a key-frame every few seconds, wasting network resources.
	bool send_frame =
	top_off_is_active_ \|\| key_frame_request_ \|\|
	(now - latest_frame_encode_start_time_ > kKeepAliveInterval);
	if (!send_frame) {
	frame_pending_ = false;
	ScheduleNextFrame();
	return false;
	}
	}

	// Encoder uses frame duration to calculate portion of the target bitrate it
	// can use for this frame. Higher values normally will cause bigger encoded
	// frames that will take longer to be delivered to the client. To keep
	// end-to-end latency low always pass the target frame duration. The actual
	// interval between frames can be longer than the target value, depending on
	// the size of the encoded frames.
	params_out->duration = kTargetFrameInterval;
	params_out->fps = processing_time_estimator_.EstimatedFrameRate();

	latest_frame_encode_start_time_ = now;

	params_out->bitrate_kbps = pacing_bucket_.rate() * 8 / 1000;
	params_out->key_frame = key_frame_request_;
	key_frame_request_ = false;

	params_out->vpx_min_quantizer = 10;

	int64_t updated_area = params_out->key_frame
	? frame->size().width() * frame->size().height()
	: GetRegionArea(frame->updated_region());

	// TODO(zijiehe): This logic should be removed if a codec without top-off
	// supported is used.
	// If bandwidth is being underutilized then libvpx is likely to choose the
	// minimum allowed quantizer value, which means that encoded frame size may
	// be significantly bigger than the bandwidth allows. Detect this case and set
	// vpx_min_quantizer to the maximum value. The quality will be topped off
	// later.
	if (updated_area - updated_region_area_.Max() > kBigFrameThresholdPixels) {
	int expected_frame_size =
	updated_area * kEstimatedBytesPerMegapixel / kPixelsPerMegapixel;
	base::TimeDelta expected_send_delay =
	pacing_bucket_.rate() ? base::TimeDelta::FromMicroseconds(
	base::Time::kMicrosecondsPerSecond *
	expected_frame_size / pacing_bucket_.rate())
	: base::TimeDelta::Max();
	if (expected_send_delay > kTargetFrameInterval) {
	params_out->vpx_min_quantizer = kMaxQuantizer;
	}
	}

	updated_region_area_.Record(updated_area);

	params_out->vpx_max_quantizer = kMaxQuantizer;

	params_out->clear_active_map = !top_off_is_active_;

	return true;
	}

	void WebrtcFrameSchedulerSimple::OnFrameEncoded(
	const WebrtcVideoEncoder::EncodedFrame* encoded_frame,
	HostFrameStats* frame_stats) {
	DCHECK(thread_checker_.CalledOnValidThread());
	DCHECK(frame_pending_);
	frame_pending_ = false;

	base::TimeTicks now = tick_clock_->NowTicks();

	if (frame_stats) {
	// Calculate \|send_pending_delay\| before refilling \|pacing_bucket_\|.
	frame_stats->send_pending_delay =
	std::max(base::TimeDelta(), pacing_bucket_.GetEmptyTime() - now);
	}

	// TODO(zijiehe): \|encoded_frame\|->data.empty() is unreasonable, we should try
	// to get rid of it in WebrtcVideoEncoder layer.
	if (!encoded_frame \|\| encoded_frame->data.empty()) {
	top_off_is_active_ = false;
	} else {
	pacing_bucket_.RefillOrSpill(encoded_frame->data.size(), now);

	processing_time_estimator_.FinishFrame(*encoded_frame);

	// Top-off until the target quantizer value is reached.
	top_off_is_active_ =
	encoded_frame->quantizer > kTargetQuantizerForVp8TopOff;
	}

	ScheduleNextFrame();

	if (frame_stats) {
	frame_stats->rtt_estimate = rtt_estimate_;
	frame_stats->bandwidth_estimate_kbps =
	bandwidth_estimator_->GetBitrateKbps();
	}

	bandwidth_estimator_->OnSendingFrame(*encoded_frame);
	}

	void WebrtcFrameSchedulerSimple::SetTickClockForTest(
	const base::TickClock* tick_clock) {
	tick_clock_ = tick_clock;
	}

	void WebrtcFrameSchedulerSimple::ScheduleNextFrame() {
	DCHECK(thread_checker_.CalledOnValidThread());
	base::TimeTicks now = tick_clock_->NowTicks();

	if (!encoder_ready_ \|\| paused_ \|\| pacing_bucket_.rate() == 0 \|\|
	capture_callback_.is_null() \|\| frame_pending_) {
	return;
	}

	base::TimeTicks target_capture_time;
	if (!last_capture_started_time_.is_null()) {
	// Try to set the capture time so that (if the estimated processing time is
	// accurate) the new frame is ready to be sent just when the previous frame
	// is finished sending.
	target_capture_time = pacing_bucket_.GetEmptyTime() -
	processing_time_estimator_.EstimatedProcessingTime(key_frame_request_);

	// Ensure that the capture rate is capped by kTargetFrameInterval, to avoid
	// excessive CPU usage by the capturer.
	target_capture_time = std::max(
	target_capture_time, last_capture_started_time_ + kTargetFrameInterval);
	}

	target_capture_time = std::max(target_capture_time, now);

	capture_timer_.Start(FROM_HERE, target_capture_time - now,
	base::Bind(&WebrtcFrameSchedulerSimple::CaptureNextFrame,
	base::Unretained(this)));
	}

	void WebrtcFrameSchedulerSimple::CaptureNextFrame() {
	DCHECK(thread_checker_.CalledOnValidThread());
	DCHECK(!frame_pending_);
	last_capture_started_time_ = tick_clock_->NowTicks();
	processing_time_estimator_.StartFrame();
	frame_pending_ = true;
	capture_callback_.Run();
	}

	} // namespace protocol
	} // namespace remoting