modules/video_coding/timing/rtt_filter.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/timing/rtt_filter.h"

 #include <math.h>
 #include <stdlib.h>
 #include <string.h>

 #include <algorithm>

 #include "absl/algorithm/container.h"
 #include "absl/container/inlined_vector.h"
 #include "api/units/time_delta.h"

 namespace webrtc {

 namespace {

 constexpr TimeDelta kMaxRtt = TimeDelta::Seconds(3);
 constexpr uint32_t kFilterFactorMax = 35;
 constexpr double kJumpStddev = 2.5;
 constexpr double kDriftStdDev = 3.5;

 }  // namespace

 RttFilter::RttFilter()
     : avg_rtt_(TimeDelta::Zero()),
       var_rtt_(0),
       max_rtt_(TimeDelta::Zero()),
       jump_buf_(kMaxDriftJumpCount, TimeDelta::Zero()),
       drift_buf_(kMaxDriftJumpCount, TimeDelta::Zero()) {
   Reset();
 }

 void RttFilter::Reset() {
   got_non_zero_update_ = false;
   avg_rtt_ = TimeDelta::Zero();
   var_rtt_ = 0;
   max_rtt_ = TimeDelta::Zero();
   filt_fact_count_ = 1;
   absl::c_fill(jump_buf_, TimeDelta::Zero());
   absl::c_fill(drift_buf_, TimeDelta::Zero());
 }

 void RttFilter::Update(TimeDelta rtt) {
   if (!got_non_zero_update_) {
     if (rtt.IsZero()) {
       return;
     }
     got_non_zero_update_ = true;
   }

   // Sanity check
   if (rtt > kMaxRtt) {
     rtt = kMaxRtt;
   }

   double filt_factor = 0;
   if (filt_fact_count_ > 1) {
     filt_factor = static_cast<double>(filt_fact_count_ - 1) / filt_fact_count_;
   }
   filt_fact_count_++;
   if (filt_fact_count_ > kFilterFactorMax) {
     // This prevents filt_factor from going above
     // (_filt_fact_max - 1) / filt_fact_max_,
     // e.g., filt_fact_max_ = 50 => filt_factor = 49/50 = 0.98
     filt_fact_count_ = kFilterFactorMax;
   }
   TimeDelta old_avg = avg_rtt_;
   int64_t old_var = var_rtt_;
   avg_rtt_ = filt_factor * avg_rtt_ + (1 - filt_factor) * rtt;
   int64_t delta_ms = (rtt - avg_rtt_).ms();
   var_rtt_ = filt_factor * var_rtt_ + (1 - filt_factor) * (delta_ms * delta_ms);
   max_rtt_ = std::max(rtt, max_rtt_);
   if (!JumpDetection(rtt) || !DriftDetection(rtt)) {
     // In some cases we don't want to update the statistics
     avg_rtt_ = old_avg;
     var_rtt_ = old_var;
   }
 }

 bool RttFilter::JumpDetection(TimeDelta rtt) {
   TimeDelta diff_from_avg = avg_rtt_ - rtt;
   // Unit of var_rtt_ is ms^2.
   TimeDelta jump_threshold = TimeDelta::Millis(kJumpStddev * sqrt(var_rtt_));
   if (diff_from_avg.Abs() > jump_threshold) {
     bool positive_diff = diff_from_avg >= TimeDelta::Zero();
     if (!jump_buf_.empty() && positive_diff != last_jump_positive_) {
       // Since the signs differ the samples currently
       // in the buffer is useless as they represent a
       // jump in a different direction.
       jump_buf_.clear();
     }
     if (jump_buf_.size() < kMaxDriftJumpCount) {
       // Update the buffer used for the short time statistics.
       // The sign of the diff is used for updating the counter since
       // we want to use the same buffer for keeping track of when
       // the RTT jumps down and up.
       jump_buf_.push_back(rtt);
       last_jump_positive_ = positive_diff;
     }
     if (jump_buf_.size() >= kMaxDriftJumpCount) {
       // Detected an RTT jump
       ShortRttFilter(jump_buf_);
       filt_fact_count_ = kMaxDriftJumpCount + 1;
       jump_buf_.clear();
     } else {
       return false;
     }
   } else {
     jump_buf_.clear();
   }
   return true;
 }

 bool RttFilter::DriftDetection(TimeDelta rtt) {
   // Unit of sqrt of var_rtt_ is ms.
   TimeDelta drift_threshold = TimeDelta::Millis(kDriftStdDev * sqrt(var_rtt_));
   if (max_rtt_ - avg_rtt_ > drift_threshold) {
     if (drift_buf_.size() < kMaxDriftJumpCount) {
       // Update the buffer used for the short time statistics.
       drift_buf_.push_back(rtt);
     }
     if (drift_buf_.size() >= kMaxDriftJumpCount) {
       // Detected an RTT drift
       ShortRttFilter(drift_buf_);
       filt_fact_count_ = kMaxDriftJumpCount + 1;
       drift_buf_.clear();
     }
   } else {
     drift_buf_.clear();
   }
   return true;
 }

 void RttFilter::ShortRttFilter(const BufferList& buf) {
   RTC_DCHECK_EQ(buf.size(), kMaxDriftJumpCount);
   max_rtt_ = TimeDelta::Zero();
   avg_rtt_ = TimeDelta::Zero();
   for (const TimeDelta& rtt : buf) {
     if (rtt > max_rtt_) {
       max_rtt_ = rtt;
     }
     avg_rtt_ += rtt;
   }
   avg_rtt_ = avg_rtt_ / static_cast<double>(buf.size());
 }

 TimeDelta RttFilter::Rtt() const {
   return max_rtt_;
 }

 }  // 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/timing/rtt_filter.h"

	#include <math.h>
	#include <stdlib.h>
	#include <string.h>

	#include <algorithm>

	#include "absl/algorithm/container.h"
	#include "absl/container/inlined_vector.h"
	#include "api/units/time_delta.h"

	namespace webrtc {

	namespace {

	constexpr TimeDelta kMaxRtt = TimeDelta::Seconds(3);
	constexpr uint32_t kFilterFactorMax = 35;
	constexpr double kJumpStddev = 2.5;
	constexpr double kDriftStdDev = 3.5;

	} // namespace

	RttFilter::RttFilter()
	: avg_rtt_(TimeDelta::Zero()),
	var_rtt_(0),
	max_rtt_(TimeDelta::Zero()),
	jump_buf_(kMaxDriftJumpCount, TimeDelta::Zero()),
	drift_buf_(kMaxDriftJumpCount, TimeDelta::Zero()) {
	Reset();
	}

	void RttFilter::Reset() {
	got_non_zero_update_ = false;
	avg_rtt_ = TimeDelta::Zero();
	var_rtt_ = 0;
	max_rtt_ = TimeDelta::Zero();
	filt_fact_count_ = 1;
	absl::c_fill(jump_buf_, TimeDelta::Zero());
	absl::c_fill(drift_buf_, TimeDelta::Zero());
	}

	void RttFilter::Update(TimeDelta rtt) {
	if (!got_non_zero_update_) {
	if (rtt.IsZero()) {
	return;
	}
	got_non_zero_update_ = true;
	}

	// Sanity check
	if (rtt > kMaxRtt) {
	rtt = kMaxRtt;
	}

	double filt_factor = 0;
	if (filt_fact_count_ > 1) {
	filt_factor = static_cast<double>(filt_fact_count_ - 1) / filt_fact_count_;
	}
	filt_fact_count_++;
	if (filt_fact_count_ > kFilterFactorMax) {
	// This prevents filt_factor from going above
	// (_filt_fact_max - 1) / filt_fact_max_,
	// e.g., filt_fact_max_ = 50 => filt_factor = 49/50 = 0.98
	filt_fact_count_ = kFilterFactorMax;
	}
	TimeDelta old_avg = avg_rtt_;
	int64_t old_var = var_rtt_;
	avg_rtt_ = filt_factor * avg_rtt_ + (1 - filt_factor) * rtt;
	int64_t delta_ms = (rtt - avg_rtt_).ms();
	var_rtt_ = filt_factor * var_rtt_ + (1 - filt_factor) * (delta_ms * delta_ms);
	max_rtt_ = std::max(rtt, max_rtt_);
	if (!JumpDetection(rtt) \|\| !DriftDetection(rtt)) {
	// In some cases we don't want to update the statistics
	avg_rtt_ = old_avg;
	var_rtt_ = old_var;
	}
	}

	bool RttFilter::JumpDetection(TimeDelta rtt) {
	TimeDelta diff_from_avg = avg_rtt_ - rtt;
	// Unit of var_rtt_ is ms^2.
	TimeDelta jump_threshold = TimeDelta::Millis(kJumpStddev * sqrt(var_rtt_));
	if (diff_from_avg.Abs() > jump_threshold) {
	bool positive_diff = diff_from_avg >= TimeDelta::Zero();
	if (!jump_buf_.empty() && positive_diff != last_jump_positive_) {
	// Since the signs differ the samples currently
	// in the buffer is useless as they represent a
	// jump in a different direction.
	jump_buf_.clear();
	}
	if (jump_buf_.size() < kMaxDriftJumpCount) {
	// Update the buffer used for the short time statistics.
	// The sign of the diff is used for updating the counter since
	// we want to use the same buffer for keeping track of when
	// the RTT jumps down and up.
	jump_buf_.push_back(rtt);
	last_jump_positive_ = positive_diff;
	}
	if (jump_buf_.size() >= kMaxDriftJumpCount) {
	// Detected an RTT jump
	ShortRttFilter(jump_buf_);
	filt_fact_count_ = kMaxDriftJumpCount + 1;
	jump_buf_.clear();
	} else {
	return false;
	}
	} else {
	jump_buf_.clear();
	}
	return true;
	}

	bool RttFilter::DriftDetection(TimeDelta rtt) {
	// Unit of sqrt of var_rtt_ is ms.
	TimeDelta drift_threshold = TimeDelta::Millis(kDriftStdDev * sqrt(var_rtt_));
	if (max_rtt_ - avg_rtt_ > drift_threshold) {
	if (drift_buf_.size() < kMaxDriftJumpCount) {
	// Update the buffer used for the short time statistics.
	drift_buf_.push_back(rtt);
	}
	if (drift_buf_.size() >= kMaxDriftJumpCount) {
	// Detected an RTT drift
	ShortRttFilter(drift_buf_);
	filt_fact_count_ = kMaxDriftJumpCount + 1;
	drift_buf_.clear();
	}
	} else {
	drift_buf_.clear();
	}
	return true;
	}

	void RttFilter::ShortRttFilter(const BufferList& buf) {
	RTC_DCHECK_EQ(buf.size(), kMaxDriftJumpCount);
	max_rtt_ = TimeDelta::Zero();
	avg_rtt_ = TimeDelta::Zero();
	for (const TimeDelta& rtt : buf) {
	if (rtt > max_rtt_) {
	max_rtt_ = rtt;
	}
	avg_rtt_ += rtt;
	}
	avg_rtt_ = avg_rtt_ / static_cast<double>(buf.size());
	}

	TimeDelta RttFilter::Rtt() const {
	return max_rtt_;
	}

	} // namespace webrtc