blob: f90ce6c687c6ac7651d031d9779d5d6afe438667 [file] [log] [blame]
/*
* Copyright (c) 2016 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/congestion_controller/goog_cc/delay_based_bwe.h"
#include <algorithm>
#include <cmath>
#include <cstdio>
#include <string>
#include "logging/rtc_event_log/events/rtc_event_bwe_update_delay_based.h"
#include "logging/rtc_event_log/rtc_event_log.h"
#include "modules/congestion_controller/goog_cc/trendline_estimator.h"
#include "modules/pacing/paced_sender.h"
#include "modules/remote_bitrate_estimator/include/remote_bitrate_estimator.h"
#include "modules/remote_bitrate_estimator/test/bwe_test_logging.h"
#include "rtc_base/checks.h"
#include "rtc_base/constructormagic.h"
#include "rtc_base/logging.h"
#include "rtc_base/ptr_util.h"
#include "rtc_base/thread_annotations.h"
#include "system_wrappers/include/field_trial.h"
#include "system_wrappers/include/metrics.h"
#include "typedefs.h" // NOLINT(build/include)
namespace {
constexpr int kTimestampGroupLengthMs = 5;
constexpr int kAbsSendTimeFraction = 18;
constexpr int kAbsSendTimeInterArrivalUpshift = 8;
constexpr int kInterArrivalShift =
kAbsSendTimeFraction + kAbsSendTimeInterArrivalUpshift;
constexpr double kTimestampToMs =
1000.0 / static_cast<double>(1 << kInterArrivalShift);
// This ssrc is used to fulfill the current API but will be removed
// after the API has been changed.
constexpr uint32_t kFixedSsrc = 0;
// Parameters for linear least squares fit of regression line to noisy data.
constexpr size_t kDefaultTrendlineWindowSize = 20;
constexpr double kDefaultTrendlineSmoothingCoeff = 0.9;
constexpr double kDefaultTrendlineThresholdGain = 4.0;
constexpr int kMaxConsecutiveFailedLookups = 5;
const char kBweWindowSizeInPacketsExperiment[] =
"WebRTC-BweWindowSizeInPackets";
size_t ReadTrendlineFilterWindowSize() {
std::string experiment_string =
webrtc::field_trial::FindFullName(kBweWindowSizeInPacketsExperiment);
size_t window_size;
int parsed_values =
sscanf(experiment_string.c_str(), "Enabled-%zu", &window_size);
if (parsed_values == 1) {
if (window_size > 1)
return window_size;
RTC_LOG(WARNING) << "Window size must be greater than 1.";
}
RTC_LOG(LS_WARNING) << "Failed to parse parameters for BweTrendlineFilter "
"experiment from field trial string. Using default.";
return kDefaultTrendlineWindowSize;
}
} // namespace
namespace webrtc {
DelayBasedBwe::Result::Result()
: updated(false),
probe(false),
target_bitrate_bps(0),
recovered_from_overuse(false) {}
DelayBasedBwe::Result::Result(bool probe, uint32_t target_bitrate_bps)
: updated(true),
probe(probe),
target_bitrate_bps(target_bitrate_bps),
recovered_from_overuse(false) {}
DelayBasedBwe::Result::~Result() {}
DelayBasedBwe::DelayBasedBwe(RtcEventLog* event_log)
: event_log_(event_log),
inter_arrival_(),
delay_detector_(),
last_seen_packet_ms_(-1),
uma_recorded_(false),
probe_bitrate_estimator_(event_log),
trendline_window_size_(
webrtc::field_trial::IsEnabled(kBweWindowSizeInPacketsExperiment)
? ReadTrendlineFilterWindowSize()
: kDefaultTrendlineWindowSize),
trendline_smoothing_coeff_(kDefaultTrendlineSmoothingCoeff),
trendline_threshold_gain_(kDefaultTrendlineThresholdGain),
consecutive_delayed_feedbacks_(0),
prev_bitrate_(0),
prev_state_(BandwidthUsage::kBwNormal) {
RTC_LOG(LS_INFO)
<< "Using Trendline filter for delay change estimation with window size "
<< trendline_window_size_;
delay_detector_.reset(new TrendlineEstimator(trendline_window_size_,
trendline_smoothing_coeff_,
trendline_threshold_gain_));
}
DelayBasedBwe::~DelayBasedBwe() {}
DelayBasedBwe::Result DelayBasedBwe::IncomingPacketFeedbackVector(
const std::vector<PacketFeedback>& packet_feedback_vector,
rtc::Optional<uint32_t> acked_bitrate_bps,
int64_t at_time_ms) {
RTC_DCHECK(std::is_sorted(packet_feedback_vector.begin(),
packet_feedback_vector.end(),
PacketFeedbackComparator()));
RTC_DCHECK_RUNS_SERIALIZED(&network_race_);
// TOOD(holmer): An empty feedback vector here likely means that
// all acks were too late and that the send time history had
// timed out. We should reduce the rate when this occurs.
if (packet_feedback_vector.empty()) {
RTC_LOG(LS_WARNING) << "Very late feedback received.";
return DelayBasedBwe::Result();
}
if (!uma_recorded_) {
RTC_HISTOGRAM_ENUMERATION(kBweTypeHistogram,
BweNames::kSendSideTransportSeqNum,
BweNames::kBweNamesMax);
uma_recorded_ = true;
}
bool delayed_feedback = true;
bool recovered_from_overuse = false;
BandwidthUsage prev_detector_state = delay_detector_->State();
for (const auto& packet_feedback : packet_feedback_vector) {
if (packet_feedback.send_time_ms < 0)
continue;
delayed_feedback = false;
IncomingPacketFeedback(packet_feedback, at_time_ms);
if (prev_detector_state == BandwidthUsage::kBwUnderusing &&
delay_detector_->State() == BandwidthUsage::kBwNormal) {
recovered_from_overuse = true;
}
prev_detector_state = delay_detector_->State();
}
if (delayed_feedback) {
++consecutive_delayed_feedbacks_;
if (consecutive_delayed_feedbacks_ >= kMaxConsecutiveFailedLookups) {
consecutive_delayed_feedbacks_ = 0;
return OnLongFeedbackDelay(packet_feedback_vector.back().arrival_time_ms);
}
} else {
consecutive_delayed_feedbacks_ = 0;
return MaybeUpdateEstimate(acked_bitrate_bps, recovered_from_overuse,
at_time_ms);
}
return Result();
}
DelayBasedBwe::Result DelayBasedBwe::OnLongFeedbackDelay(
int64_t arrival_time_ms) {
// Estimate should always be valid since a start bitrate always is set in the
// Call constructor. An alternative would be to return an empty Result here,
// or to estimate the throughput based on the feedback we received.
RTC_DCHECK(rate_control_.ValidEstimate());
rate_control_.SetEstimate(rate_control_.LatestEstimate() / 2,
arrival_time_ms);
Result result;
result.updated = true;
result.probe = false;
result.target_bitrate_bps = rate_control_.LatestEstimate();
RTC_LOG(LS_WARNING) << "Long feedback delay detected, reducing BWE to "
<< result.target_bitrate_bps;
return result;
}
void DelayBasedBwe::IncomingPacketFeedback(
const PacketFeedback& packet_feedback,
int64_t at_time_ms) {
int64_t now_ms = at_time_ms;
// Reset if the stream has timed out.
if (last_seen_packet_ms_ == -1 ||
now_ms - last_seen_packet_ms_ > kStreamTimeOutMs) {
inter_arrival_.reset(
new InterArrival((kTimestampGroupLengthMs << kInterArrivalShift) / 1000,
kTimestampToMs, true));
delay_detector_.reset(new TrendlineEstimator(trendline_window_size_,
trendline_smoothing_coeff_,
trendline_threshold_gain_));
}
last_seen_packet_ms_ = now_ms;
uint32_t send_time_24bits =
static_cast<uint32_t>(
((static_cast<uint64_t>(packet_feedback.send_time_ms)
<< kAbsSendTimeFraction) +
500) /
1000) &
0x00FFFFFF;
// Shift up send time to use the full 32 bits that inter_arrival works with,
// so wrapping works properly.
uint32_t timestamp = send_time_24bits << kAbsSendTimeInterArrivalUpshift;
uint32_t ts_delta = 0;
int64_t t_delta = 0;
int size_delta = 0;
if (inter_arrival_->ComputeDeltas(timestamp, packet_feedback.arrival_time_ms,
now_ms, packet_feedback.payload_size,
&ts_delta, &t_delta, &size_delta)) {
double ts_delta_ms = (1000.0 * ts_delta) / (1 << kInterArrivalShift);
delay_detector_->Update(t_delta, ts_delta_ms,
packet_feedback.arrival_time_ms);
}
if (packet_feedback.pacing_info.probe_cluster_id !=
PacedPacketInfo::kNotAProbe) {
probe_bitrate_estimator_.HandleProbeAndEstimateBitrate(packet_feedback);
}
}
DelayBasedBwe::Result DelayBasedBwe::MaybeUpdateEstimate(
rtc::Optional<uint32_t> acked_bitrate_bps,
bool recovered_from_overuse,
int64_t at_time_ms) {
Result result;
int64_t now_ms = at_time_ms;
rtc::Optional<int> probe_bitrate_bps =
probe_bitrate_estimator_.FetchAndResetLastEstimatedBitrateBps();
// Currently overusing the bandwidth.
if (delay_detector_->State() == BandwidthUsage::kBwOverusing) {
if (acked_bitrate_bps &&
rate_control_.TimeToReduceFurther(now_ms, *acked_bitrate_bps)) {
result.updated =
UpdateEstimate(now_ms, acked_bitrate_bps, &result.target_bitrate_bps);
} else if (!acked_bitrate_bps && rate_control_.ValidEstimate() &&
rate_control_.TimeToReduceFurther(
now_ms, rate_control_.LatestEstimate() / 2 - 1)) {
// Overusing before we have a measured acknowledged bitrate. We check
// TimeToReduceFurther (with a fake acknowledged bitrate) to avoid
// reducing too often.
// TODO(tschumim): Improve this and/or the acknowledged bitrate estimator
// so that we (almost) always have a bitrate estimate.
rate_control_.SetEstimate(rate_control_.LatestEstimate() / 2, now_ms);
result.updated = true;
result.probe = false;
result.target_bitrate_bps = rate_control_.LatestEstimate();
}
} else {
if (probe_bitrate_bps) {
result.probe = true;
result.updated = true;
result.target_bitrate_bps = *probe_bitrate_bps;
rate_control_.SetEstimate(*probe_bitrate_bps, now_ms);
} else {
result.updated =
UpdateEstimate(now_ms, acked_bitrate_bps, &result.target_bitrate_bps);
result.recovered_from_overuse = recovered_from_overuse;
}
}
BandwidthUsage detector_state = delay_detector_->State();
if ((result.updated && prev_bitrate_ != result.target_bitrate_bps) ||
detector_state != prev_state_) {
uint32_t bitrate_bps =
result.updated ? result.target_bitrate_bps : prev_bitrate_;
BWE_TEST_LOGGING_PLOT(1, "target_bitrate_bps", now_ms, bitrate_bps);
if (event_log_) {
event_log_->Log(rtc::MakeUnique<RtcEventBweUpdateDelayBased>(
bitrate_bps, detector_state));
}
prev_bitrate_ = bitrate_bps;
prev_state_ = detector_state;
}
return result;
}
bool DelayBasedBwe::UpdateEstimate(int64_t now_ms,
rtc::Optional<uint32_t> acked_bitrate_bps,
uint32_t* target_bitrate_bps) {
// TODO(terelius): RateControlInput::noise_var is deprecated and will be
// removed. In the meantime, we set it to zero.
const RateControlInput input(delay_detector_->State(), acked_bitrate_bps, 0);
*target_bitrate_bps = rate_control_.Update(&input, now_ms);
return rate_control_.ValidEstimate();
}
void DelayBasedBwe::OnRttUpdate(int64_t avg_rtt_ms) {
rate_control_.SetRtt(avg_rtt_ms);
}
bool DelayBasedBwe::LatestEstimate(std::vector<uint32_t>* ssrcs,
uint32_t* bitrate_bps) const {
// Currently accessed from both the process thread (see
// ModuleRtpRtcpImpl::Process()) and the configuration thread (see
// Call::GetStats()). Should in the future only be accessed from a single
// thread.
RTC_DCHECK(ssrcs);
RTC_DCHECK(bitrate_bps);
if (!rate_control_.ValidEstimate())
return false;
*ssrcs = {kFixedSsrc};
*bitrate_bps = rate_control_.LatestEstimate();
return true;
}
void DelayBasedBwe::SetStartBitrate(int start_bitrate_bps) {
RTC_LOG(LS_WARNING) << "BWE Setting start bitrate to: " << start_bitrate_bps;
rate_control_.SetStartBitrate(start_bitrate_bps);
}
void DelayBasedBwe::SetMinBitrate(int min_bitrate_bps) {
// Called from both the configuration thread and the network thread. Shouldn't
// be called from the network thread in the future.
rate_control_.SetMinBitrate(min_bitrate_bps);
}
int64_t DelayBasedBwe::GetExpectedBwePeriodMs() const {
return rate_control_.GetExpectedBandwidthPeriodMs();
}
} // namespace webrtc