system_wrappers/source/rtp_to_ntp_estimator.cc - mirrors/cros/chromiumos/third_party/webrtc-apm - Git at Google

 /*
  *  Copyright (c) 2012 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 "system_wrappers/include/rtp_to_ntp_estimator.h"

 #include <stddef.h>
 #include <cmath>
 #include <vector>

 #include "api/array_view.h"
 #include "rtc_base/checks.h"
 #include "rtc_base/logging.h"

 namespace webrtc {
 namespace {
 // Maximum number of RTCP SR reports to use to map between RTP and NTP.
 const size_t kNumRtcpReportsToUse = 20;
 // Don't allow NTP timestamps to jump more than 1 hour. Chosen arbitrary as big
 // enough to not affect normal use-cases. Yet it is smaller than RTP wrap-around
 // half-period (90khz RTP clock wrap-arounds every 13.25 hours). After half of
 // wrap-around period it is impossible to unwrap RTP timestamps correctly.
 const int kMaxAllowedRtcpNtpIntervalMs = 60 * 60 * 1000;

 bool Contains(const std::list<RtpToNtpEstimator::RtcpMeasurement>& measurements,
               const RtpToNtpEstimator::RtcpMeasurement& other) {
   for (const auto& measurement : measurements) {
     if (measurement.IsEqual(other))
       return true;
   }
   return false;
 }

 // Given x[] and y[] writes out such k and b that line y=k*x+b approximates
 // given points in the best way (Least Squares Method).
 bool LinearRegression(rtc::ArrayView<const double> x,
                       rtc::ArrayView<const double> y,
                       double* k,
                       double* b) {
   size_t n = x.size();
   if (n < 2)
     return false;

   if (y.size() != n)
     return false;

   double avg_x = 0;
   double avg_y = 0;
   for (size_t i = 0; i < n; ++i) {
     avg_x += x[i];
     avg_y += y[i];
   }
   avg_x /= n;
   avg_y /= n;

   double variance_x = 0;
   double covariance_xy = 0;
   for (size_t i = 0; i < n; ++i) {
     double normalized_x = x[i] - avg_x;
     double normalized_y = y[i] - avg_y;
     variance_x += normalized_x * normalized_x;
     covariance_xy += normalized_x * normalized_y;
   }

   if (std::fabs(variance_x) < 1e-8)
     return false;

   *k = static_cast<double>(covariance_xy / variance_x);
   *b = static_cast<double>(avg_y - (*k) * avg_x);
   return true;
 }

 }  // namespace

 RtpToNtpEstimator::RtcpMeasurement::RtcpMeasurement(uint32_t ntp_secs,
                                                     uint32_t ntp_frac,
                                                     int64_t unwrapped_timestamp)
     : ntp_time(ntp_secs, ntp_frac),
       unwrapped_rtp_timestamp(unwrapped_timestamp) {}

 bool RtpToNtpEstimator::RtcpMeasurement::IsEqual(
     const RtcpMeasurement& other) const {
   // Use || since two equal timestamps will result in zero frequency and in
   // RtpToNtpMs, |rtp_timestamp_ms| is estimated by dividing by the frequency.
   return (ntp_time == other.ntp_time) ||
          (unwrapped_rtp_timestamp == other.unwrapped_rtp_timestamp);
 }

 // Class for converting an RTP timestamp to the NTP domain.
 RtpToNtpEstimator::RtpToNtpEstimator() : consecutive_invalid_samples_(0) {}

 RtpToNtpEstimator::~RtpToNtpEstimator() {}

 void RtpToNtpEstimator::UpdateParameters() {
   if (measurements_.size() < 2)
     return;

   std::vector<double> x;
   std::vector<double> y;
   x.reserve(measurements_.size());
   y.reserve(measurements_.size());
   for (auto it = measurements_.begin(); it != measurements_.end(); ++it) {
     x.push_back(it->unwrapped_rtp_timestamp);
     y.push_back(it->ntp_time.ToMs());
   }
   double slope, offset;

   if (!LinearRegression(x, y, &slope, &offset)) {
     return;
   }

   params_.emplace(1 / slope, offset);
 }

 bool RtpToNtpEstimator::UpdateMeasurements(uint32_t ntp_secs,
                                            uint32_t ntp_frac,
                                            uint32_t rtp_timestamp,
                                            bool* new_rtcp_sr) {
   *new_rtcp_sr = false;

   int64_t unwrapped_rtp_timestamp = unwrapper_.Unwrap(rtp_timestamp);

   RtcpMeasurement new_measurement(ntp_secs, ntp_frac, unwrapped_rtp_timestamp);

   if (Contains(measurements_, new_measurement)) {
     // RTCP SR report already added.
     return true;
   }

   if (!new_measurement.ntp_time.Valid())
     return false;

   int64_t ntp_ms_new = new_measurement.ntp_time.ToMs();
   bool invalid_sample = false;
   if (!measurements_.empty()) {
     int64_t old_rtp_timestamp = measurements_.front().unwrapped_rtp_timestamp;
     int64_t old_ntp_ms = measurements_.front().ntp_time.ToMs();
     if (ntp_ms_new <= old_ntp_ms ||
         ntp_ms_new > old_ntp_ms + kMaxAllowedRtcpNtpIntervalMs) {
       invalid_sample = true;
     } else if (unwrapped_rtp_timestamp <= old_rtp_timestamp) {
       RTC_LOG(LS_WARNING)
           << "Newer RTCP SR report with older RTP timestamp, dropping";
       invalid_sample = true;
     } else if (unwrapped_rtp_timestamp - old_rtp_timestamp > (1 << 25)) {
       // Sanity check. No jumps too far into the future in rtp.
       invalid_sample = true;
     }
   }

   if (invalid_sample) {
     ++consecutive_invalid_samples_;
     if (consecutive_invalid_samples_ < kMaxInvalidSamples) {
       return false;
     }
     RTC_LOG(LS_WARNING) << "Multiple consecutively invalid RTCP SR reports, "
                            "clearing measurements.";
     measurements_.clear();
     params_ = absl::nullopt;
   }
   consecutive_invalid_samples_ = 0;

   // Insert new RTCP SR report.
   if (measurements_.size() == kNumRtcpReportsToUse)
     measurements_.pop_back();

   measurements_.push_front(new_measurement);
   *new_rtcp_sr = true;

   // List updated, calculate new parameters.
   UpdateParameters();
   return true;
 }

 bool RtpToNtpEstimator::Estimate(int64_t rtp_timestamp,
                                  int64_t* ntp_timestamp_ms) const {
   if (!params_)
     return false;

   int64_t rtp_timestamp_unwrapped = unwrapper_.Unwrap(rtp_timestamp);

   // params_calculated_ should not be true unless ms params.frequency_khz has
   // been calculated to something non zero.
   RTC_DCHECK_NE(params_->frequency_khz, 0.0);
   double rtp_ms =
       static_cast<double>(rtp_timestamp_unwrapped) / params_->frequency_khz +
       params_->offset_ms + 0.5f;

   if (rtp_ms < 0)
     return false;

   *ntp_timestamp_ms = rtp_ms;

   return true;
 }

 const absl::optional<RtpToNtpEstimator::Parameters> RtpToNtpEstimator::params()
     const {
   return params_;
 }
 }  // namespace webrtc
	/*
	* Copyright (c) 2012 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 "system_wrappers/include/rtp_to_ntp_estimator.h"

	#include <stddef.h>
	#include <cmath>
	#include <vector>

	#include "api/array_view.h"
	#include "rtc_base/checks.h"
	#include "rtc_base/logging.h"

	namespace webrtc {
	namespace {
	// Maximum number of RTCP SR reports to use to map between RTP and NTP.
	const size_t kNumRtcpReportsToUse = 20;
	// Don't allow NTP timestamps to jump more than 1 hour. Chosen arbitrary as big
	// enough to not affect normal use-cases. Yet it is smaller than RTP wrap-around
	// half-period (90khz RTP clock wrap-arounds every 13.25 hours). After half of
	// wrap-around period it is impossible to unwrap RTP timestamps correctly.
	const int kMaxAllowedRtcpNtpIntervalMs = 60 * 60 * 1000;

	bool Contains(const std::list<RtpToNtpEstimator::RtcpMeasurement>& measurements,
	const RtpToNtpEstimator::RtcpMeasurement& other) {
	for (const auto& measurement : measurements) {
	if (measurement.IsEqual(other))
	return true;
	}
	return false;
	}

	// Given x[] and y[] writes out such k and b that line y=k*x+b approximates
	// given points in the best way (Least Squares Method).
	bool LinearRegression(rtc::ArrayView<const double> x,
	rtc::ArrayView<const double> y,
	double* k,
	double* b) {
	size_t n = x.size();
	if (n < 2)
	return false;

	if (y.size() != n)
	return false;

	double avg_x = 0;
	double avg_y = 0;
	for (size_t i = 0; i < n; ++i) {
	avg_x += x[i];
	avg_y += y[i];
	}
	avg_x /= n;
	avg_y /= n;

	double variance_x = 0;
	double covariance_xy = 0;
	for (size_t i = 0; i < n; ++i) {
	double normalized_x = x[i] - avg_x;
	double normalized_y = y[i] - avg_y;
	variance_x += normalized_x * normalized_x;
	covariance_xy += normalized_x * normalized_y;
	}

	if (std::fabs(variance_x) < 1e-8)
	return false;

	*k = static_cast<double>(covariance_xy / variance_x);
	b = static_cast<double>(avg_y - (k) * avg_x);
	return true;
	}

	} // namespace

	RtpToNtpEstimator::RtcpMeasurement::RtcpMeasurement(uint32_t ntp_secs,
	uint32_t ntp_frac,
	int64_t unwrapped_timestamp)
	: ntp_time(ntp_secs, ntp_frac),
	unwrapped_rtp_timestamp(unwrapped_timestamp) {}

	bool RtpToNtpEstimator::RtcpMeasurement::IsEqual(
	const RtcpMeasurement& other) const {
	// Use \|\| since two equal timestamps will result in zero frequency and in
	// RtpToNtpMs, \|rtp_timestamp_ms\| is estimated by dividing by the frequency.
	return (ntp_time == other.ntp_time) \|\|
	(unwrapped_rtp_timestamp == other.unwrapped_rtp_timestamp);
	}

	// Class for converting an RTP timestamp to the NTP domain.
	RtpToNtpEstimator::RtpToNtpEstimator() : consecutive_invalid_samples_(0) {}

	RtpToNtpEstimator::~RtpToNtpEstimator() {}

	void RtpToNtpEstimator::UpdateParameters() {
	if (measurements_.size() < 2)
	return;

	std::vector<double> x;
	std::vector<double> y;
	x.reserve(measurements_.size());
	y.reserve(measurements_.size());
	for (auto it = measurements_.begin(); it != measurements_.end(); ++it) {
	x.push_back(it->unwrapped_rtp_timestamp);
	y.push_back(it->ntp_time.ToMs());
	}
	double slope, offset;

	if (!LinearRegression(x, y, &slope, &offset)) {
	return;
	}

	params_.emplace(1 / slope, offset);
	}

	bool RtpToNtpEstimator::UpdateMeasurements(uint32_t ntp_secs,
	uint32_t ntp_frac,
	uint32_t rtp_timestamp,
	bool* new_rtcp_sr) {
	*new_rtcp_sr = false;

	int64_t unwrapped_rtp_timestamp = unwrapper_.Unwrap(rtp_timestamp);

	RtcpMeasurement new_measurement(ntp_secs, ntp_frac, unwrapped_rtp_timestamp);

	if (Contains(measurements_, new_measurement)) {
	// RTCP SR report already added.
	return true;
	}

	if (!new_measurement.ntp_time.Valid())
	return false;

	int64_t ntp_ms_new = new_measurement.ntp_time.ToMs();
	bool invalid_sample = false;
	if (!measurements_.empty()) {
	int64_t old_rtp_timestamp = measurements_.front().unwrapped_rtp_timestamp;
	int64_t old_ntp_ms = measurements_.front().ntp_time.ToMs();
	if (ntp_ms_new <= old_ntp_ms \|\|
	ntp_ms_new > old_ntp_ms + kMaxAllowedRtcpNtpIntervalMs) {
	invalid_sample = true;
	} else if (unwrapped_rtp_timestamp <= old_rtp_timestamp) {
	RTC_LOG(LS_WARNING)
	<< "Newer RTCP SR report with older RTP timestamp, dropping";
	invalid_sample = true;
	} else if (unwrapped_rtp_timestamp - old_rtp_timestamp > (1 << 25)) {
	// Sanity check. No jumps too far into the future in rtp.
	invalid_sample = true;
	}
	}

	if (invalid_sample) {
	++consecutive_invalid_samples_;
	if (consecutive_invalid_samples_ < kMaxInvalidSamples) {
	return false;
	}
	RTC_LOG(LS_WARNING) << "Multiple consecutively invalid RTCP SR reports, "
	"clearing measurements.";
	measurements_.clear();
	params_ = absl::nullopt;
	}
	consecutive_invalid_samples_ = 0;

	// Insert new RTCP SR report.
	if (measurements_.size() == kNumRtcpReportsToUse)
	measurements_.pop_back();

	measurements_.push_front(new_measurement);
	*new_rtcp_sr = true;

	// List updated, calculate new parameters.
	UpdateParameters();
	return true;
	}

	bool RtpToNtpEstimator::Estimate(int64_t rtp_timestamp,
	int64_t* ntp_timestamp_ms) const {
	if (!params_)
	return false;

	int64_t rtp_timestamp_unwrapped = unwrapper_.Unwrap(rtp_timestamp);

	// params_calculated_ should not be true unless ms params.frequency_khz has
	// been calculated to something non zero.
	RTC_DCHECK_NE(params_->frequency_khz, 0.0);
	double rtp_ms =
	static_cast<double>(rtp_timestamp_unwrapped) / params_->frequency_khz +
	params_->offset_ms + 0.5f;

	if (rtp_ms < 0)
	return false;

	*ntp_timestamp_ms = rtp_ms;

	return true;
	}

	const absl::optional<RtpToNtpEstimator::Parameters> RtpToNtpEstimator::params()
	const {
	return params_;
	}
	} // namespace webrtc