modules/video_coding/utility/frame_dropper.cc - src - Git at Google

 /*
  *  Copyright (c) 2011 The WebRTC project authors. All Rights Reserved.
  *
  *  Use of this source code is governed by a BSD-style license
  *  that can be found in the LICENSE file in the root of the source
  *  tree. An additional intellectual property rights grant can be found
  *  in the file PATENTS.  All contributing project authors may
  *  be found in the AUTHORS file in the root of the source tree.
  */

 #include "modules/video_coding/utility/frame_dropper.h"

 #include <algorithm>

 namespace webrtc {

 namespace {

 const float kDefaultFrameSizeAlpha = 0.9f;
 const float kDefaultKeyFrameRatioAlpha = 0.99f;
 // 1 key frame every 10th second in 30 fps.
 const float kDefaultKeyFrameRatioValue = 1 / 300.0f;

 const float kDefaultDropRatioAlpha = 0.9f;
 const float kDefaultDropRatioValue = 0.96f;
 // Maximum duration over which frames are continuously dropped.
 const float kDefaultMaxDropDurationSecs = 4.0f;

 // Default target bitrate.
 // TODO(isheriff): Should this be higher to avoid dropping too many packets when
 // the bandwidth is unknown at the start ?
 const float kDefaultTargetBitrateKbps = 300.0f;
 const float kDefaultIncomingFrameRate = 30;
 const float kLeakyBucketSizeSeconds = 0.5f;

 // A delta frame that is bigger than |kLargeDeltaFactor| times the average
 // delta frame is a large frame that is spread out for accumulation.
 const int kLargeDeltaFactor = 3;

 // Cap on the frame size accumulator to prevent excessive drops.
 const float kAccumulatorCapBufferSizeSecs = 3.0f;
 }  // namespace

 FrameDropper::FrameDropper()
     : key_frame_ratio_(kDefaultKeyFrameRatioAlpha),
       delta_frame_size_avg_kbits_(kDefaultFrameSizeAlpha),
       drop_ratio_(kDefaultDropRatioAlpha, kDefaultDropRatioValue),
       enabled_(true),
       max_drop_duration_secs_(kDefaultMaxDropDurationSecs) {
   Reset();
 }

 FrameDropper::~FrameDropper() = default;

 void FrameDropper::Reset() {
   key_frame_ratio_.Reset(kDefaultKeyFrameRatioAlpha);
   key_frame_ratio_.Apply(1.0f, kDefaultKeyFrameRatioValue);
   delta_frame_size_avg_kbits_.Reset(kDefaultFrameSizeAlpha);

   accumulator_ = 0.0f;
   accumulator_max_ = kDefaultTargetBitrateKbps / 2;
   target_bitrate_ = kDefaultTargetBitrateKbps;
   incoming_frame_rate_ = kDefaultIncomingFrameRate;

   large_frame_accumulation_count_ = 0;
   large_frame_accumulation_chunk_size_ = 0;
   large_frame_accumulation_spread_ = 0.5 * kDefaultIncomingFrameRate;

   drop_next_ = false;
   drop_ratio_.Reset(0.9f);
   drop_ratio_.Apply(0.0f, 0.0f);
   drop_count_ = 0;
   was_below_max_ = true;
 }

 void FrameDropper::Enable(bool enable) {
   enabled_ = enable;
 }

 void FrameDropper::Fill(size_t framesize_bytes, bool delta_frame) {
   if (!enabled_) {
     return;
   }
   float framesize_kbits = 8.0f * static_cast<float>(framesize_bytes) / 1000.0f;
   if (!delta_frame) {
     key_frame_ratio_.Apply(1.0, 1.0);
     // Do not spread if we are already doing it (or we risk dropping bits that
     // need accumulation). Given we compute the key frame ratio and spread
     // based on that, this should not normally happen.
     if (large_frame_accumulation_count_ == 0) {
       if (key_frame_ratio_.filtered() > 1e-5 &&
           1 / key_frame_ratio_.filtered() < large_frame_accumulation_spread_) {
         large_frame_accumulation_count_ =
             static_cast<int32_t>(1 / key_frame_ratio_.filtered() + 0.5);
       } else {
         large_frame_accumulation_count_ =
             static_cast<int32_t>(large_frame_accumulation_spread_ + 0.5);
       }
       large_frame_accumulation_chunk_size_ =
           framesize_kbits / large_frame_accumulation_count_;
       framesize_kbits = 0;
     }
   } else {
     // Identify if it is an unusually large delta frame and spread accumulation
     // if that is the case.
     if (delta_frame_size_avg_kbits_.filtered() != -1 &&
         (framesize_kbits >
          kLargeDeltaFactor * delta_frame_size_avg_kbits_.filtered()) &&
         large_frame_accumulation_count_ == 0) {
       large_frame_accumulation_count_ =
           static_cast<int32_t>(large_frame_accumulation_spread_ + 0.5);
       large_frame_accumulation_chunk_size_ =
           framesize_kbits / large_frame_accumulation_count_;
       framesize_kbits = 0;
     } else {
       delta_frame_size_avg_kbits_.Apply(1, framesize_kbits);
     }
     key_frame_ratio_.Apply(1.0, 0.0);
   }
   // Change the level of the accumulator (bucket)
   accumulator_ += framesize_kbits;
   CapAccumulator();
 }

 void FrameDropper::Leak(uint32_t input_framerate) {
   if (!enabled_) {
     return;
   }
   if (input_framerate < 1) {
     return;
   }
   if (target_bitrate_ < 0.0f) {
     return;
   }
   // Add lower bound for large frame accumulation spread.
   large_frame_accumulation_spread_ = std::max(0.5 * input_framerate, 5.0);
   // Expected bits per frame based on current input frame rate.
   float expected_bits_per_frame = target_bitrate_ / input_framerate;
   if (large_frame_accumulation_count_ > 0) {
     expected_bits_per_frame -= large_frame_accumulation_chunk_size_;
     --large_frame_accumulation_count_;
   }
   accumulator_ -= expected_bits_per_frame;
   if (accumulator_ < 0.0f) {
     accumulator_ = 0.0f;
   }
   UpdateRatio();
 }

 void FrameDropper::UpdateRatio() {
   if (accumulator_ > 1.3f * accumulator_max_) {
     // Too far above accumulator max, react faster.
     drop_ratio_.UpdateBase(0.8f);
   } else {
     // Go back to normal reaction.
     drop_ratio_.UpdateBase(0.9f);
   }
   if (accumulator_ > accumulator_max_) {
     // We are above accumulator max, and should ideally drop a frame. Increase
     // the drop_ratio_ and drop the frame later.
     if (was_below_max_) {
       drop_next_ = true;
     }
     drop_ratio_.Apply(1.0f, 1.0f);
     drop_ratio_.UpdateBase(0.9f);
   } else {
     drop_ratio_.Apply(1.0f, 0.0f);
   }
   was_below_max_ = accumulator_ < accumulator_max_;
 }

 // This function signals when to drop frames to the caller. It makes use of the
 // drop_ratio_ to smooth out the drops over time.
 bool FrameDropper::DropFrame() {
   if (!enabled_) {
     return false;
   }
   if (drop_next_) {
     drop_next_ = false;
     drop_count_ = 0;
   }

   if (drop_ratio_.filtered() >= 0.5f) {  // Drops per keep
     // Limit is the number of frames we should drop between each kept frame
     // to keep our drop ratio. limit is positive in this case.
     float denom = 1.0f - drop_ratio_.filtered();
     if (denom < 1e-5) {
       denom = 1e-5f;
     }
     int32_t limit = static_cast<int32_t>(1.0f / denom - 1.0f + 0.5f);
     // Put a bound on the max amount of dropped frames between each kept
     // frame, in terms of frame rate and window size (secs).
     int max_limit =
         static_cast<int>(incoming_frame_rate_ * max_drop_duration_secs_);
     if (limit > max_limit) {
       limit = max_limit;
     }
     if (drop_count_ < 0) {
       // Reset the drop_count_ since it was negative and should be positive.
       drop_count_ = -drop_count_;
     }
     if (drop_count_ < limit) {
       // As long we are below the limit we should drop frames.
       drop_count_++;
       return true;
     } else {
       // Only when we reset drop_count_ a frame should be kept.
       drop_count_ = 0;
       return false;
     }
   } else if (drop_ratio_.filtered() > 0.0f &&
              drop_ratio_.filtered() < 0.5f) {  // Keeps per drop
     // Limit is the number of frames we should keep between each drop
     // in order to keep the drop ratio. limit is negative in this case,
     // and the drop_count_ is also negative.
     float denom = drop_ratio_.filtered();
     if (denom < 1e-5) {
       denom = 1e-5f;
     }
     int32_t limit = -static_cast<int32_t>(1.0f / denom - 1.0f + 0.5f);
     if (drop_count_ > 0) {
       // Reset the drop_count_ since we have a positive
       // drop_count_, and it should be negative.
       drop_count_ = -drop_count_;
     }
     if (drop_count_ > limit) {
       if (drop_count_ == 0) {
         // Drop frames when we reset drop_count_.
         drop_count_--;
         return true;
       } else {
         // Keep frames as long as we haven't reached limit.
         drop_count_--;
         return false;
       }
     } else {
       drop_count_ = 0;
       return false;
     }
   }
   drop_count_ = 0;
   return false;
 }

 void FrameDropper::SetRates(float bitrate, float incoming_frame_rate) {
   // Bit rate of -1 means infinite bandwidth.
   accumulator_max_ = bitrate * kLeakyBucketSizeSeconds;
   if (target_bitrate_ > 0.0f && bitrate < target_bitrate_ &&
       accumulator_ > accumulator_max_) {
     // Rescale the accumulator level if the accumulator max decreases
     accumulator_ = bitrate / target_bitrate_ * accumulator_;
   }
   target_bitrate_ = bitrate;
   CapAccumulator();
   incoming_frame_rate_ = incoming_frame_rate;
 }

 // Put a cap on the accumulator, i.e., don't let it grow beyond some level.
 // This is a temporary fix for screencasting where very large frames from
 // encoder will cause very slow response (too many frame drops).
 // TODO(isheriff): Remove this now that large delta frames are also spread out ?
 void FrameDropper::CapAccumulator() {
   float max_accumulator = target_bitrate_ * kAccumulatorCapBufferSizeSecs;
   if (accumulator_ > max_accumulator) {
     accumulator_ = max_accumulator;
   }
 }
 }  // namespace webrtc
	/*
	* Copyright (c) 2011 The WebRTC project authors. All Rights Reserved.
	*
	* Use of this source code is governed by a BSD-style license
	* that can be found in the LICENSE file in the root of the source
	* tree. An additional intellectual property rights grant can be found
	* in the file PATENTS. All contributing project authors may
	* be found in the AUTHORS file in the root of the source tree.
	*/

	#include "modules/video_coding/utility/frame_dropper.h"

	#include <algorithm>

	namespace webrtc {

	namespace {

	const float kDefaultFrameSizeAlpha = 0.9f;
	const float kDefaultKeyFrameRatioAlpha = 0.99f;
	// 1 key frame every 10th second in 30 fps.
	const float kDefaultKeyFrameRatioValue = 1 / 300.0f;

	const float kDefaultDropRatioAlpha = 0.9f;
	const float kDefaultDropRatioValue = 0.96f;
	// Maximum duration over which frames are continuously dropped.
	const float kDefaultMaxDropDurationSecs = 4.0f;

	// Default target bitrate.
	// TODO(isheriff): Should this be higher to avoid dropping too many packets when
	// the bandwidth is unknown at the start ?
	const float kDefaultTargetBitrateKbps = 300.0f;
	const float kDefaultIncomingFrameRate = 30;
	const float kLeakyBucketSizeSeconds = 0.5f;

	// A delta frame that is bigger than \|kLargeDeltaFactor\| times the average
	// delta frame is a large frame that is spread out for accumulation.
	const int kLargeDeltaFactor = 3;

	// Cap on the frame size accumulator to prevent excessive drops.
	const float kAccumulatorCapBufferSizeSecs = 3.0f;
	} // namespace

	FrameDropper::FrameDropper()
	: key_frame_ratio_(kDefaultKeyFrameRatioAlpha),
	delta_frame_size_avg_kbits_(kDefaultFrameSizeAlpha),
	drop_ratio_(kDefaultDropRatioAlpha, kDefaultDropRatioValue),
	enabled_(true),
	max_drop_duration_secs_(kDefaultMaxDropDurationSecs) {
	Reset();
	}

	FrameDropper::~FrameDropper() = default;

	void FrameDropper::Reset() {
	key_frame_ratio_.Reset(kDefaultKeyFrameRatioAlpha);
	key_frame_ratio_.Apply(1.0f, kDefaultKeyFrameRatioValue);
	delta_frame_size_avg_kbits_.Reset(kDefaultFrameSizeAlpha);

	accumulator_ = 0.0f;
	accumulator_max_ = kDefaultTargetBitrateKbps / 2;
	target_bitrate_ = kDefaultTargetBitrateKbps;
	incoming_frame_rate_ = kDefaultIncomingFrameRate;

	large_frame_accumulation_count_ = 0;
	large_frame_accumulation_chunk_size_ = 0;
	large_frame_accumulation_spread_ = 0.5 * kDefaultIncomingFrameRate;

	drop_next_ = false;
	drop_ratio_.Reset(0.9f);
	drop_ratio_.Apply(0.0f, 0.0f);
	drop_count_ = 0;
	was_below_max_ = true;
	}

	void FrameDropper::Enable(bool enable) {
	enabled_ = enable;
	}

	void FrameDropper::Fill(size_t framesize_bytes, bool delta_frame) {
	if (!enabled_) {
	return;
	}
	float framesize_kbits = 8.0f * static_cast<float>(framesize_bytes) / 1000.0f;
	if (!delta_frame) {
	key_frame_ratio_.Apply(1.0, 1.0);
	// Do not spread if we are already doing it (or we risk dropping bits that
	// need accumulation). Given we compute the key frame ratio and spread
	// based on that, this should not normally happen.
	if (large_frame_accumulation_count_ == 0) {
	if (key_frame_ratio_.filtered() > 1e-5 &&
	1 / key_frame_ratio_.filtered() < large_frame_accumulation_spread_) {
	large_frame_accumulation_count_ =
	static_cast<int32_t>(1 / key_frame_ratio_.filtered() + 0.5);
	} else {
	large_frame_accumulation_count_ =
	static_cast<int32_t>(large_frame_accumulation_spread_ + 0.5);
	}
	large_frame_accumulation_chunk_size_ =
	framesize_kbits / large_frame_accumulation_count_;
	framesize_kbits = 0;
	}
	} else {
	// Identify if it is an unusually large delta frame and spread accumulation
	// if that is the case.
	if (delta_frame_size_avg_kbits_.filtered() != -1 &&
	(framesize_kbits >
	kLargeDeltaFactor * delta_frame_size_avg_kbits_.filtered()) &&
	large_frame_accumulation_count_ == 0) {
	large_frame_accumulation_count_ =
	static_cast<int32_t>(large_frame_accumulation_spread_ + 0.5);
	large_frame_accumulation_chunk_size_ =
	framesize_kbits / large_frame_accumulation_count_;
	framesize_kbits = 0;
	} else {
	delta_frame_size_avg_kbits_.Apply(1, framesize_kbits);
	}
	key_frame_ratio_.Apply(1.0, 0.0);
	}
	// Change the level of the accumulator (bucket)
	accumulator_ += framesize_kbits;
	CapAccumulator();
	}

	void FrameDropper::Leak(uint32_t input_framerate) {
	if (!enabled_) {
	return;
	}
	if (input_framerate < 1) {
	return;
	}
	if (target_bitrate_ < 0.0f) {
	return;
	}
	// Add lower bound for large frame accumulation spread.
	large_frame_accumulation_spread_ = std::max(0.5 * input_framerate, 5.0);
	// Expected bits per frame based on current input frame rate.
	float expected_bits_per_frame = target_bitrate_ / input_framerate;
	if (large_frame_accumulation_count_ > 0) {
	expected_bits_per_frame -= large_frame_accumulation_chunk_size_;
	--large_frame_accumulation_count_;
	}
	accumulator_ -= expected_bits_per_frame;
	if (accumulator_ < 0.0f) {
	accumulator_ = 0.0f;
	}
	UpdateRatio();
	}

	void FrameDropper::UpdateRatio() {
	if (accumulator_ > 1.3f * accumulator_max_) {
	// Too far above accumulator max, react faster.
	drop_ratio_.UpdateBase(0.8f);
	} else {
	// Go back to normal reaction.
	drop_ratio_.UpdateBase(0.9f);
	}
	if (accumulator_ > accumulator_max_) {
	// We are above accumulator max, and should ideally drop a frame. Increase
	// the drop_ratio_ and drop the frame later.
	if (was_below_max_) {
	drop_next_ = true;
	}
	drop_ratio_.Apply(1.0f, 1.0f);
	drop_ratio_.UpdateBase(0.9f);
	} else {
	drop_ratio_.Apply(1.0f, 0.0f);
	}
	was_below_max_ = accumulator_ < accumulator_max_;
	}

	// This function signals when to drop frames to the caller. It makes use of the
	// drop_ratio_ to smooth out the drops over time.
	bool FrameDropper::DropFrame() {
	if (!enabled_) {
	return false;
	}
	if (drop_next_) {
	drop_next_ = false;
	drop_count_ = 0;
	}

	if (drop_ratio_.filtered() >= 0.5f) { // Drops per keep
	// Limit is the number of frames we should drop between each kept frame
	// to keep our drop ratio. limit is positive in this case.
	float denom = 1.0f - drop_ratio_.filtered();
	if (denom < 1e-5) {
	denom = 1e-5f;
	}
	int32_t limit = static_cast<int32_t>(1.0f / denom - 1.0f + 0.5f);
	// Put a bound on the max amount of dropped frames between each kept
	// frame, in terms of frame rate and window size (secs).
	int max_limit =
	static_cast<int>(incoming_frame_rate_ * max_drop_duration_secs_);
	if (limit > max_limit) {
	limit = max_limit;
	}
	if (drop_count_ < 0) {
	// Reset the drop_count_ since it was negative and should be positive.
	drop_count_ = -drop_count_;
	}
	if (drop_count_ < limit) {
	// As long we are below the limit we should drop frames.
	drop_count_++;
	return true;
	} else {
	// Only when we reset drop_count_ a frame should be kept.
	drop_count_ = 0;
	return false;
	}
	} else if (drop_ratio_.filtered() > 0.0f &&
	drop_ratio_.filtered() < 0.5f) { // Keeps per drop
	// Limit is the number of frames we should keep between each drop
	// in order to keep the drop ratio. limit is negative in this case,
	// and the drop_count_ is also negative.
	float denom = drop_ratio_.filtered();
	if (denom < 1e-5) {
	denom = 1e-5f;
	}
	int32_t limit = -static_cast<int32_t>(1.0f / denom - 1.0f + 0.5f);
	if (drop_count_ > 0) {
	// Reset the drop_count_ since we have a positive
	// drop_count_, and it should be negative.
	drop_count_ = -drop_count_;
	}
	if (drop_count_ > limit) {
	if (drop_count_ == 0) {
	// Drop frames when we reset drop_count_.
	drop_count_--;
	return true;
	} else {
	// Keep frames as long as we haven't reached limit.
	drop_count_--;
	return false;
	}
	} else {
	drop_count_ = 0;
	return false;
	}
	}
	drop_count_ = 0;
	return false;
	}

	void FrameDropper::SetRates(float bitrate, float incoming_frame_rate) {
	// Bit rate of -1 means infinite bandwidth.
	accumulator_max_ = bitrate * kLeakyBucketSizeSeconds;
	if (target_bitrate_ > 0.0f && bitrate < target_bitrate_ &&
	accumulator_ > accumulator_max_) {
	// Rescale the accumulator level if the accumulator max decreases
	accumulator_ = bitrate / target_bitrate_ * accumulator_;
	}
	target_bitrate_ = bitrate;
	CapAccumulator();
	incoming_frame_rate_ = incoming_frame_rate;
	}

	// Put a cap on the accumulator, i.e., don't let it grow beyond some level.
	// This is a temporary fix for screencasting where very large frames from
	// encoder will cause very slow response (too many frame drops).
	// TODO(isheriff): Remove this now that large delta frames are also spread out ?
	void FrameDropper::CapAccumulator() {
	float max_accumulator = target_bitrate_ * kAccumulatorCapBufferSizeSecs;
	if (accumulator_ > max_accumulator) {
	accumulator_ = max_accumulator;
	}
	}
	} // namespace webrtc