webrtc_m130/webrtc/modules/bitrate_controller/send_side_bandwidth_estimation.cc

/*
 *  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 "webrtc/modules/bitrate_controller/send_side_bandwidth_estimation.h"

#include <algorithm>
#include <cmath>

#include "webrtc/base/checks.h"
#include "webrtc/base/logging.h"
#include "webrtc/logging/rtc_event_log/rtc_event_log.h"
#include "webrtc/modules/remote_bitrate_estimator/include/bwe_defines.h"
#include "webrtc/system_wrappers/include/field_trial.h"
#include "webrtc/system_wrappers/include/metrics.h"

namespace webrtc {
namespace {
const int64_t kBweIncreaseIntervalMs = 1000;
const int64_t kBweDecreaseIntervalMs = 300;
const int64_t kStartPhaseMs = 2000;
const int64_t kBweConverganceTimeMs = 20000;
const int kLimitNumPackets = 20;
const int kDefaultMaxBitrateBps = 1000000000;
const int64_t kLowBitrateLogPeriodMs = 10000;
const int64_t kRtcEventLogPeriodMs = 5000;
// Expecting that RTCP feedback is sent uniformly within [0.5, 1.5]s intervals.
const int64_t kFeedbackIntervalMs = 1500;
const int64_t kFeedbackTimeoutIntervals = 3;
const int64_t kTimeoutIntervalMs = 1000;

struct UmaRampUpMetric {
  const char* metric_name;
  int bitrate_kbps;
};

const UmaRampUpMetric kUmaRampupMetrics[] = {
    {"WebRTC.BWE.RampUpTimeTo500kbpsInMs", 500},
    {"WebRTC.BWE.RampUpTimeTo1000kbpsInMs", 1000},
    {"WebRTC.BWE.RampUpTimeTo2000kbpsInMs", 2000}};
const size_t kNumUmaRampupMetrics =
    sizeof(kUmaRampupMetrics) / sizeof(kUmaRampupMetrics[0]);

}  // namespace

SendSideBandwidthEstimation::SendSideBandwidthEstimation(RtcEventLog* event_log)
    : lost_packets_since_last_loss_update_Q8_(0),
      expected_packets_since_last_loss_update_(0),
      bitrate_(0),
      min_bitrate_configured_(congestion_controller::GetMinBitrateBps()),
      max_bitrate_configured_(kDefaultMaxBitrateBps),
      last_low_bitrate_log_ms_(-1),
      has_decreased_since_last_fraction_loss_(false),
      last_feedback_ms_(-1),
      last_packet_report_ms_(-1),
      last_timeout_ms_(-1),
      last_fraction_loss_(0),
      last_logged_fraction_loss_(0),
      last_round_trip_time_ms_(0),
      bwe_incoming_(0),
      delay_based_bitrate_bps_(0),
      time_last_decrease_ms_(0),
      first_report_time_ms_(-1),
      initially_lost_packets_(0),
      bitrate_at_2_seconds_kbps_(0),
      uma_update_state_(kNoUpdate),
      rampup_uma_stats_updated_(kNumUmaRampupMetrics, false),
      event_log_(event_log),
      last_rtc_event_log_ms_(-1),
      in_timeout_experiment_(
          webrtc::field_trial::IsEnabled("WebRTC-FeedbackTimeout")) {
  RTC_DCHECK(event_log);
}

SendSideBandwidthEstimation::~SendSideBandwidthEstimation() {}

void SendSideBandwidthEstimation::SetBitrates(int send_bitrate,
                                              int min_bitrate,
                                              int max_bitrate) {
  if (send_bitrate > 0)
    SetSendBitrate(send_bitrate);
  SetMinMaxBitrate(min_bitrate, max_bitrate);
}

void SendSideBandwidthEstimation::SetSendBitrate(int bitrate) {
  RTC_DCHECK_GT(bitrate, 0);
  bitrate_ = bitrate;

  // Clear last sent bitrate history so the new value can be used directly
  // and not capped.
  min_bitrate_history_.clear();
}

void SendSideBandwidthEstimation::SetMinMaxBitrate(int min_bitrate,
                                                   int max_bitrate) {
  RTC_DCHECK_GE(min_bitrate, 0);
  min_bitrate_configured_ =
      std::max(min_bitrate, congestion_controller::GetMinBitrateBps());
  if (max_bitrate > 0) {
    max_bitrate_configured_ =
        std::max<uint32_t>(min_bitrate_configured_, max_bitrate);
  } else {
    max_bitrate_configured_ = kDefaultMaxBitrateBps;
  }
}

int SendSideBandwidthEstimation::GetMinBitrate() const {
  return min_bitrate_configured_;
}

void SendSideBandwidthEstimation::CurrentEstimate(int* bitrate,
                                                  uint8_t* loss,
                                                  int64_t* rtt) const {
  *bitrate = bitrate_;
  *loss = last_fraction_loss_;
  *rtt = last_round_trip_time_ms_;
}

void SendSideBandwidthEstimation::UpdateReceiverEstimate(
    int64_t now_ms, uint32_t bandwidth) {
  bwe_incoming_ = bandwidth;
  bitrate_ = CapBitrateToThresholds(now_ms, bitrate_);
}

void SendSideBandwidthEstimation::UpdateDelayBasedEstimate(
    int64_t now_ms,
    uint32_t bitrate_bps) {
  delay_based_bitrate_bps_ = bitrate_bps;
  bitrate_ = CapBitrateToThresholds(now_ms, bitrate_);
}

void SendSideBandwidthEstimation::UpdateReceiverBlock(uint8_t fraction_loss,
                                                      int64_t rtt,
                                                      int number_of_packets,
                                                      int64_t now_ms) {
  last_feedback_ms_ = now_ms;
  if (first_report_time_ms_ == -1)
    first_report_time_ms_ = now_ms;

  // Update RTT.
  last_round_trip_time_ms_ = rtt;

  // Check sequence number diff and weight loss report
  if (number_of_packets > 0) {
    // Calculate number of lost packets.
    const int num_lost_packets_Q8 = fraction_loss * number_of_packets;
    // Accumulate reports.
    lost_packets_since_last_loss_update_Q8_ += num_lost_packets_Q8;
    expected_packets_since_last_loss_update_ += number_of_packets;

    // Don't generate a loss rate until it can be based on enough packets.
    if (expected_packets_since_last_loss_update_ < kLimitNumPackets)
      return;

    has_decreased_since_last_fraction_loss_ = false;
    last_fraction_loss_ = lost_packets_since_last_loss_update_Q8_ /
                          expected_packets_since_last_loss_update_;

    // Reset accumulators.
    lost_packets_since_last_loss_update_Q8_ = 0;
    expected_packets_since_last_loss_update_ = 0;
    last_packet_report_ms_ = now_ms;
    UpdateEstimate(now_ms);
  }
  UpdateUmaStats(now_ms, rtt, (fraction_loss * number_of_packets) >> 8);
}

void SendSideBandwidthEstimation::UpdateUmaStats(int64_t now_ms,
                                                 int64_t rtt,
                                                 int lost_packets) {
  int bitrate_kbps = static_cast<int>((bitrate_ + 500) / 1000);
  for (size_t i = 0; i < kNumUmaRampupMetrics; ++i) {
    if (!rampup_uma_stats_updated_[i] &&
        bitrate_kbps >= kUmaRampupMetrics[i].bitrate_kbps) {
      RTC_HISTOGRAMS_COUNTS_100000(i, kUmaRampupMetrics[i].metric_name,
                                   now_ms - first_report_time_ms_);
      rampup_uma_stats_updated_[i] = true;
    }
  }
  if (IsInStartPhase(now_ms)) {
    initially_lost_packets_ += lost_packets;
  } else if (uma_update_state_ == kNoUpdate) {
    uma_update_state_ = kFirstDone;
    bitrate_at_2_seconds_kbps_ = bitrate_kbps;
    RTC_HISTOGRAM_COUNTS("WebRTC.BWE.InitiallyLostPackets",
                         initially_lost_packets_, 0, 100, 50);
    RTC_HISTOGRAM_COUNTS("WebRTC.BWE.InitialRtt", static_cast<int>(rtt), 0,
                         2000, 50);
    RTC_HISTOGRAM_COUNTS("WebRTC.BWE.InitialBandwidthEstimate",
                         bitrate_at_2_seconds_kbps_, 0, 2000, 50);
  } else if (uma_update_state_ == kFirstDone &&
             now_ms - first_report_time_ms_ >= kBweConverganceTimeMs) {
    uma_update_state_ = kDone;
    int bitrate_diff_kbps =
        std::max(bitrate_at_2_seconds_kbps_ - bitrate_kbps, 0);
    RTC_HISTOGRAM_COUNTS("WebRTC.BWE.InitialVsConvergedDiff", bitrate_diff_kbps,
                         0, 2000, 50);
  }
}

void SendSideBandwidthEstimation::UpdateEstimate(int64_t now_ms) {
  // We trust the REMB and/or delay-based estimate during the first 2 seconds if
  // we haven't had any packet loss reported, to allow startup bitrate probing.
  if (last_fraction_loss_ == 0 && IsInStartPhase(now_ms)) {
    uint32_t prev_bitrate = bitrate_;
    if (bwe_incoming_ > bitrate_)
      bitrate_ = CapBitrateToThresholds(now_ms, bwe_incoming_);
    if (delay_based_bitrate_bps_ > bitrate_) {
      bitrate_ = CapBitrateToThresholds(now_ms, delay_based_bitrate_bps_);
    }
    if (bitrate_ != prev_bitrate) {
      min_bitrate_history_.clear();
      min_bitrate_history_.push_back(std::make_pair(now_ms, bitrate_));
      return;
    }
  }
  UpdateMinHistory(now_ms);
  if (last_packet_report_ms_ == -1) {
    // No feedback received.
    bitrate_ = CapBitrateToThresholds(now_ms, bitrate_);
    return;
  }
  int64_t time_since_packet_report_ms = now_ms - last_packet_report_ms_;
  int64_t time_since_feedback_ms = now_ms - last_feedback_ms_;
  if (time_since_packet_report_ms < 1.2 * kFeedbackIntervalMs) {
    if (last_fraction_loss_ <= 5) {
      // Loss < 2%: Increase rate by 8% of the min bitrate in the last
      // kBweIncreaseIntervalMs.
      // Note that by remembering the bitrate over the last second one can
      // rampup up one second faster than if only allowed to start ramping
      // at 8% per second rate now. E.g.:
      //   If sending a constant 100kbps it can rampup immediatly to 108kbps
      //   whenever a receiver report is received with lower packet loss.
      //   If instead one would do: bitrate_ *= 1.08^(delta time), it would
      //   take over one second since the lower packet loss to achieve
      //   108kbps.
      bitrate_ = static_cast<uint32_t>(
          min_bitrate_history_.front().second * 1.08 + 0.5);

      // Add 1 kbps extra, just to make sure that we do not get stuck
      // (gives a little extra increase at low rates, negligible at higher
      // rates).
      bitrate_ += 1000;
    } else if (last_fraction_loss_ <= 26) {
      // Loss between 2% - 10%: Do nothing.
    } else {
      // Loss > 10%: Limit the rate decreases to once a kBweDecreaseIntervalMs
      // + rtt.
      if (!has_decreased_since_last_fraction_loss_ &&
          (now_ms - time_last_decrease_ms_) >=
              (kBweDecreaseIntervalMs + last_round_trip_time_ms_)) {
        time_last_decrease_ms_ = now_ms;

        // Reduce rate:
        //   newRate = rate * (1 - 0.5*lossRate);
        //   where packetLoss = 256*lossRate;
        bitrate_ = static_cast<uint32_t>(
            (bitrate_ * static_cast<double>(512 - last_fraction_loss_)) /
            512.0);
        has_decreased_since_last_fraction_loss_ = true;
      }
    }
  } else if (time_since_feedback_ms >
                 kFeedbackTimeoutIntervals * kFeedbackIntervalMs &&
             (last_timeout_ms_ == -1 ||
              now_ms - last_timeout_ms_ > kTimeoutIntervalMs)) {
    if (in_timeout_experiment_) {
      LOG(LS_WARNING) << "Feedback timed out (" << time_since_feedback_ms
                      << " ms), reducing bitrate.";
      bitrate_ *= 0.8;
      // Reset accumulators since we've already acted on missing feedback and
      // shouldn't to act again on these old lost packets.
      lost_packets_since_last_loss_update_Q8_ = 0;
      expected_packets_since_last_loss_update_ = 0;
      last_timeout_ms_ = now_ms;
    }
  }
  uint32_t capped_bitrate = CapBitrateToThresholds(now_ms, bitrate_);
  if (capped_bitrate != bitrate_ ||
      last_fraction_loss_ != last_logged_fraction_loss_ ||
      last_rtc_event_log_ms_ == -1 ||
      now_ms - last_rtc_event_log_ms_ > kRtcEventLogPeriodMs) {
    event_log_->LogLossBasedBweUpdate(capped_bitrate, last_fraction_loss_,
                                      expected_packets_since_last_loss_update_);
    last_logged_fraction_loss_ = last_fraction_loss_;
    last_rtc_event_log_ms_ = now_ms;
  }
  bitrate_ = capped_bitrate;
}

bool SendSideBandwidthEstimation::IsInStartPhase(int64_t now_ms) const {
  return first_report_time_ms_ == -1 ||
         now_ms - first_report_time_ms_ < kStartPhaseMs;
}

void SendSideBandwidthEstimation::UpdateMinHistory(int64_t now_ms) {
  // Remove old data points from history.
  // Since history precision is in ms, add one so it is able to increase
  // bitrate if it is off by as little as 0.5ms.
  while (!min_bitrate_history_.empty() &&
         now_ms - min_bitrate_history_.front().first + 1 >
             kBweIncreaseIntervalMs) {
    min_bitrate_history_.pop_front();
  }

  // Typical minimum sliding-window algorithm: Pop values higher than current
  // bitrate before pushing it.
  while (!min_bitrate_history_.empty() &&
         bitrate_ <= min_bitrate_history_.back().second) {
    min_bitrate_history_.pop_back();
  }

  min_bitrate_history_.push_back(std::make_pair(now_ms, bitrate_));
}

uint32_t SendSideBandwidthEstimation::CapBitrateToThresholds(
    int64_t now_ms, uint32_t bitrate) {
  if (bwe_incoming_ > 0 && bitrate > bwe_incoming_) {
    bitrate = bwe_incoming_;
  }
  if (delay_based_bitrate_bps_ > 0 && bitrate > delay_based_bitrate_bps_) {
    bitrate = delay_based_bitrate_bps_;
  }
  if (bitrate > max_bitrate_configured_) {
    bitrate = max_bitrate_configured_;
  }
  if (bitrate < min_bitrate_configured_) {
    if (last_low_bitrate_log_ms_ == -1 ||
        now_ms - last_low_bitrate_log_ms_ > kLowBitrateLogPeriodMs) {
      LOG(LS_WARNING) << "Estimated available bandwidth " << bitrate / 1000
                      << " kbps is below configured min bitrate "
                      << min_bitrate_configured_ / 1000 << " kbps.";
      last_low_bitrate_log_ms_ = now_ms;
    }
    bitrate = min_bitrate_configured_;
  }
  return bitrate;
}
}  // namespace webrtc