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/*
* Copyright (c) 2019 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 "test/pc/e2e/analyzer/video/default_video_quality_analyzer.h"
#include <algorithm>
#include <map>
#include <memory>
#include <set>
#include <string>
#include <utility>
#include <vector>
#include "api/array_view.h"
#include "api/numerics/samples_stats_counter.h"
#include "api/test/metrics/metric.h"
#include "api/units/time_delta.h"
#include "api/units/timestamp.h"
#include "api/video/video_frame.h"
#include "rtc_base/checks.h"
#include "rtc_base/logging.h"
#include "rtc_base/strings/string_builder.h"
#include "system_wrappers/include/clock.h"
#include "test/pc/e2e/analyzer/video/default_video_quality_analyzer_frame_in_flight.h"
#include "test/pc/e2e/analyzer/video/default_video_quality_analyzer_frames_comparator.h"
#include "test/pc/e2e/analyzer/video/default_video_quality_analyzer_internal_shared_objects.h"
#include "test/pc/e2e/analyzer/video/default_video_quality_analyzer_shared_objects.h"
#include "test/pc/e2e/analyzer/video/default_video_quality_analyzer_stream_state.h"
#include "test/pc/e2e/metric_metadata_keys.h"
namespace webrtc {
namespace {
using ::webrtc::test::ImprovementDirection;
using ::webrtc::test::Unit;
using ::webrtc::webrtc_pc_e2e::MetricMetadataKey;
constexpr int kBitsInByte = 8;
constexpr absl::string_view kSkipRenderedFrameReasonProcessed = "processed";
constexpr absl::string_view kSkipRenderedFrameReasonRendered = "rendered";
constexpr absl::string_view kSkipRenderedFrameReasonDropped =
"considered dropped";
void LogFrameCounters(const std::string& name, const FrameCounters& counters) {
RTC_LOG(LS_INFO) << "[" << name
<< "] Captured : " << counters.captured;
RTC_LOG(LS_INFO) << "[" << name
<< "] Pre encoded : " << counters.pre_encoded;
RTC_LOG(LS_INFO) << "[" << name
<< "] Encoded : " << counters.encoded;
RTC_LOG(LS_INFO) << "[" << name
<< "] Received : " << counters.received;
RTC_LOG(LS_INFO) << "[" << name
<< "] Decoded : " << counters.decoded;
RTC_LOG(LS_INFO) << "[" << name
<< "] Rendered : " << counters.rendered;
RTC_LOG(LS_INFO) << "[" << name
<< "] Dropped : " << counters.dropped;
RTC_LOG(LS_INFO) << "[" << name
<< "] Failed to decode : " << counters.failed_to_decode;
}
void LogStreamInternalStats(const std::string& name,
const StreamStats& stats,
Timestamp start_time) {
for (const auto& entry : stats.dropped_by_phase) {
RTC_LOG(LS_INFO) << "[" << name << "] Dropped at " << ToString(entry.first)
<< ": " << entry.second;
}
Timestamp first_encoded_frame_time = Timestamp::PlusInfinity();
for (const StreamCodecInfo& encoder : stats.encoders) {
RTC_DCHECK(encoder.switched_on_at.IsFinite());
RTC_DCHECK(encoder.switched_from_at.IsFinite());
if (first_encoded_frame_time.IsInfinite()) {
first_encoded_frame_time = encoder.switched_on_at;
}
RTC_LOG(LS_INFO)
<< "[" << name << "] Used encoder: \"" << encoder.codec_name
<< "\" used from (frame_id=" << encoder.first_frame_id
<< "; from_stream_start="
<< (encoder.switched_on_at - stats.stream_started_time).ms()
<< "ms, from_call_start=" << (encoder.switched_on_at - start_time).ms()
<< "ms) until (frame_id=" << encoder.last_frame_id
<< "; from_stream_start="
<< (encoder.switched_from_at - stats.stream_started_time).ms()
<< "ms, from_call_start="
<< (encoder.switched_from_at - start_time).ms() << "ms)";
}
for (const StreamCodecInfo& decoder : stats.decoders) {
RTC_DCHECK(decoder.switched_on_at.IsFinite());
RTC_DCHECK(decoder.switched_from_at.IsFinite());
RTC_LOG(LS_INFO)
<< "[" << name << "] Used decoder: \"" << decoder.codec_name
<< "\" used from (frame_id=" << decoder.first_frame_id
<< "; from_stream_start="
<< (decoder.switched_on_at - stats.stream_started_time).ms()
<< "ms, from_call_start=" << (decoder.switched_on_at - start_time).ms()
<< "ms) until (frame_id=" << decoder.last_frame_id
<< "; from_stream_start="
<< (decoder.switched_from_at - stats.stream_started_time).ms()
<< "ms, from_call_start="
<< (decoder.switched_from_at - start_time).ms() << "ms)";
}
}
template <typename T>
std::optional<T> MaybeGetValue(const std::map<size_t, T>& map, size_t key) {
auto it = map.find(key);
if (it == map.end()) {
return std::nullopt;
}
return it->second;
}
SamplesStatsCounter::StatsSample StatsSample(double value,
Timestamp sampling_time) {
return SamplesStatsCounter::StatsSample{value, sampling_time};
}
} // namespace
DefaultVideoQualityAnalyzer::DefaultVideoQualityAnalyzer(
webrtc::Clock* clock,
test::MetricsLogger* metrics_logger,
DefaultVideoQualityAnalyzerOptions options)
: options_(options),
clock_(clock),
metrics_logger_(metrics_logger),
frames_storage_(options.max_frames_storage_duration, clock_),
frames_comparator_(clock, cpu_measurer_, options) {
RTC_CHECK(metrics_logger_);
}
DefaultVideoQualityAnalyzer::~DefaultVideoQualityAnalyzer() {
Stop();
}
void DefaultVideoQualityAnalyzer::Start(
std::string test_case_name,
rtc::ArrayView<const std::string> peer_names,
int max_threads_count) {
test_label_ = std::move(test_case_name);
frames_comparator_.Start(max_threads_count);
{
MutexLock lock(&mutex_);
peers_ = std::make_unique<NamesCollection>(peer_names);
RTC_CHECK(start_time_.IsMinusInfinity());
RTC_CHECK_EQ(state_, State::kNew)
<< "DefaultVideoQualityAnalyzer is already started";
state_ = State::kActive;
start_time_ = Now();
}
}
uint16_t DefaultVideoQualityAnalyzer::OnFrameCaptured(
absl::string_view peer_name,
const std::string& stream_label,
const webrtc::VideoFrame& frame) {
// `next_frame_id` is atomic, so we needn't lock here.
Timestamp captured_time = Now();
Timestamp start_time = Timestamp::MinusInfinity();
size_t peer_index = -1;
size_t peers_count = -1;
size_t stream_index;
uint16_t frame_id = VideoFrame::kNotSetId;
{
MutexLock lock(&mutex_);
frame_id = GetNextFrameId();
RTC_CHECK_EQ(state_, State::kActive)
<< "DefaultVideoQualityAnalyzer has to be started before use";
// Create a local copy of `start_time_`, peer's index and total peers count
// to access it without holding a `mutex_` during access to
// `frames_comparator_`.
start_time = start_time_;
peer_index = peers_->index(peer_name);
peers_count = peers_->size();
stream_index = streams_.AddIfAbsent(stream_label);
}
// Ensure stats for this stream exists.
frames_comparator_.EnsureStatsForStream(stream_index, peer_index, peers_count,
captured_time, start_time);
{
MutexLock lock(&mutex_);
stream_to_sender_[stream_index] = peer_index;
frame_counters_.captured++;
for (size_t i : peers_->GetAllIndexes()) {
if (i != peer_index || options_.enable_receive_own_stream) {
InternalStatsKey key(stream_index, peer_index, i);
stream_frame_counters_[key].captured++;
}
}
std::set<size_t> frame_receivers_indexes = peers_->GetPresentIndexes();
if (!options_.enable_receive_own_stream) {
frame_receivers_indexes.erase(peer_index);
}
auto state_it = stream_states_.find(stream_index);
if (state_it == stream_states_.end()) {
stream_states_.emplace(stream_index,
StreamState(peer_index, frame_receivers_indexes,
captured_time, clock_));
}
StreamState* state = &stream_states_.at(stream_index);
state->PushBack(frame_id);
std::optional<TimeDelta> time_between_captured_frames = std::nullopt;
if (state->last_captured_frame_time().has_value()) {
time_between_captured_frames =
captured_time - *state->last_captured_frame_time();
}
state->SetLastCapturedFrameTime(captured_time);
// Update frames in flight info.
auto it = captured_frames_in_flight_.find(frame_id);
if (it != captured_frames_in_flight_.end()) {
// If we overflow uint16_t and hit previous frame id and this frame is
// still in flight, it means that this stream wasn't rendered for long
// time and we need to process existing frame as dropped.
for (size_t i : peers_->GetPresentIndexes()) {
if (i == peer_index && !options_.enable_receive_own_stream) {
continue;
}
uint16_t oldest_frame_id = state->PopFront(i);
RTC_DCHECK_EQ(frame_id, oldest_frame_id);
if (state->GetPausableState(i)->IsPaused()) {
continue;
}
frame_counters_.dropped++;
InternalStatsKey key(stream_index, peer_index, i);
stream_frame_counters_.at(key).dropped++;
analyzer_stats_.frames_in_flight_left_count.AddSample(
StatsSample(captured_frames_in_flight_.size(), Now()));
frames_comparator_.AddComparison(
InternalStatsKey(stream_index, peer_index, i),
/*captured=*/std::nullopt,
/*rendered=*/std::nullopt, FrameComparisonType::kDroppedFrame,
it->second.GetStatsForPeer(i));
}
frames_storage_.Remove(it->second.id());
captured_frames_in_flight_.erase(it);
}
captured_frames_in_flight_.emplace(
frame_id, FrameInFlight(stream_index, frame_id, captured_time,
time_between_captured_frames,
std::move(frame_receivers_indexes)));
// Store local copy of the frame with frame_id set.
VideoFrame local_frame(frame);
local_frame.set_id(frame_id);
frames_storage_.Add(std::move(local_frame), captured_time);
// Update history stream<->frame mapping
for (auto it = stream_to_frame_id_history_.begin();
it != stream_to_frame_id_history_.end(); ++it) {
it->second.erase(frame_id);
}
stream_to_frame_id_history_[stream_index].insert(frame_id);
stream_to_frame_id_full_history_[stream_index].push_back(frame_id);
if (options_.report_infra_metrics) {
analyzer_stats_.on_frame_captured_processing_time_ms.AddSample(
(Now() - captured_time).ms<double>());
}
}
return frame_id;
}
void DefaultVideoQualityAnalyzer::OnFramePreEncode(
absl::string_view peer_name,
const webrtc::VideoFrame& frame) {
Timestamp processing_started = Now();
MutexLock lock(&mutex_);
RTC_CHECK_EQ(state_, State::kActive)
<< "DefaultVideoQualityAnalyzer has to be started before use";
auto it = captured_frames_in_flight_.find(frame.id());
if (it == captured_frames_in_flight_.end()) {
// If the frame is not found, it is possible that it has been encoded twice
// and that it was received by all the participants the first time.
RTC_LOG(LS_WARNING) << "Frame id=" << frame.id() << " not found.";
return;
}
FrameInFlight& frame_in_flight = it->second;
frame_counters_.pre_encoded++;
size_t peer_index = peers_->index(peer_name);
for (size_t i : peers_->GetAllIndexes()) {
if (i != peer_index || options_.enable_receive_own_stream) {
InternalStatsKey key(frame_in_flight.stream(), peer_index, i);
stream_frame_counters_.at(key).pre_encoded++;
}
}
frame_in_flight.SetPreEncodeTime(Now());
if (options_.report_infra_metrics) {
analyzer_stats_.on_frame_pre_encode_processing_time_ms.AddSample(
(Now() - processing_started).ms<double>());
}
}
void DefaultVideoQualityAnalyzer::OnFrameEncoded(
absl::string_view peer_name,
uint16_t frame_id,
const webrtc::EncodedImage& encoded_image,
const EncoderStats& stats,
bool discarded) {
if (discarded)
return;
Timestamp processing_started = Now();
MutexLock lock(&mutex_);
RTC_CHECK_EQ(state_, State::kActive)
<< "DefaultVideoQualityAnalyzer has to be started before use";
auto it = captured_frames_in_flight_.find(frame_id);
if (it == captured_frames_in_flight_.end()) {
RTC_LOG(LS_WARNING)
<< "The encoding of video frame with id [" << frame_id << "] for peer ["
<< peer_name << "] finished after all receivers rendered this frame or "
<< "were removed. It can be OK for simulcast/SVC if higher quality "
<< "stream is not required or the last receiver was unregistered "
<< "between encoding of different layers, but it may indicate an ERROR "
<< "for singlecast or if it happens often.";
return;
}
FrameInFlight& frame_in_flight = it->second;
// For SVC we can receive multiple encoded images for one frame, so to cover
// all cases we have to pick the last encode time.
if (!frame_in_flight.HasEncodedTime()) {
// Increase counters only when we meet this frame first time.
frame_counters_.encoded++;
size_t peer_index = peers_->index(peer_name);
for (size_t i : peers_->GetAllIndexes()) {
if (i != peer_index || options_.enable_receive_own_stream) {
InternalStatsKey key(frame_in_flight.stream(), peer_index, i);
stream_frame_counters_.at(key).encoded++;
}
}
}
Timestamp now = Now();
StreamState& state = stream_states_.at(frame_in_flight.stream());
std::optional<TimeDelta> time_between_encoded_frames = std::nullopt;
if (state.last_encoded_frame_time().has_value()) {
time_between_encoded_frames = now - *state.last_encoded_frame_time();
}
state.SetLastEncodedFrameTime(now);
StreamCodecInfo used_encoder;
used_encoder.codec_name = stats.encoder_name;
used_encoder.first_frame_id = frame_id;
used_encoder.last_frame_id = frame_id;
used_encoder.switched_on_at = now;
used_encoder.switched_from_at = now;
// We could either have simulcast layers or spatial layers.
// simulcast and SVC we'll also need to consider the case where we have both
// simulcast and spatial indices.
size_t stream_index = encoded_image.SpatialIndex().value_or(
encoded_image.SimulcastIndex().value_or(0));
frame_in_flight.OnFrameEncoded(
now, time_between_encoded_frames, encoded_image._frameType,
DataSize::Bytes(encoded_image.size()), stats.target_encode_bitrate,
stream_index, stats.qp, used_encoder);
if (options_.report_infra_metrics) {
analyzer_stats_.on_frame_encoded_processing_time_ms.AddSample(
(Now() - processing_started).ms<double>());
}
}
void DefaultVideoQualityAnalyzer::OnFrameDropped(
absl::string_view peer_name,
webrtc::EncodedImageCallback::DropReason reason) {
// Here we do nothing, because we will see this drop on renderer side.
}
void DefaultVideoQualityAnalyzer::OnFramePreDecode(
absl::string_view peer_name,
uint16_t frame_id,
const webrtc::EncodedImage& input_image) {
Timestamp processing_started = Now();
MutexLock lock(&mutex_);
RTC_CHECK_EQ(state_, State::kActive)
<< "DefaultVideoQualityAnalyzer has to be started before use";
size_t peer_index = peers_->index(peer_name);
if (frame_id == VideoFrame::kNotSetId) {
frame_counters_.received++;
unknown_sender_frame_counters_[std::string(peer_name)].received++;
return;
}
auto it = captured_frames_in_flight_.find(frame_id);
if (it == captured_frames_in_flight_.end() ||
it->second.HasReceivedTime(peer_index)) {
// It means this frame was predecoded before, so we can skip it. It may
// happen when we have multiple simulcast streams in one track and received
// the same picture from two different streams because SFU can't reliably
// correlate two simulcast streams and started relaying the second stream
// from the same frame it has relayed right before for the first stream.
return;
}
frame_counters_.received++;
InternalStatsKey key(it->second.stream(),
stream_to_sender_.at(it->second.stream()), peer_index);
stream_frame_counters_.at(key).received++;
// Determine the time of the last received packet of this video frame.
RTC_DCHECK(!input_image.PacketInfos().empty());
Timestamp last_receive_time =
std::max_element(input_image.PacketInfos().cbegin(),
input_image.PacketInfos().cend(),
[](const RtpPacketInfo& a, const RtpPacketInfo& b) {
return a.receive_time() < b.receive_time();
})
->receive_time();
it->second.OnFramePreDecode(peer_index,
/*received_time=*/last_receive_time,
/*decode_start_time=*/Now(),
input_image._frameType,
DataSize::Bytes(input_image.size()));
if (options_.report_infra_metrics) {
analyzer_stats_.on_frame_pre_decode_processing_time_ms.AddSample(
(Now() - processing_started).ms<double>());
}
}
void DefaultVideoQualityAnalyzer::OnFrameDecoded(
absl::string_view peer_name,
const webrtc::VideoFrame& frame,
const DecoderStats& stats) {
Timestamp processing_started = Now();
MutexLock lock(&mutex_);
RTC_CHECK_EQ(state_, State::kActive)
<< "DefaultVideoQualityAnalyzer has to be started before use";
size_t peer_index = peers_->index(peer_name);
if (frame.id() == VideoFrame::kNotSetId) {
frame_counters_.decoded++;
unknown_sender_frame_counters_[std::string(peer_name)].decoded++;
return;
}
auto it = captured_frames_in_flight_.find(frame.id());
if (it == captured_frames_in_flight_.end() ||
it->second.HasDecodeEndTime(peer_index)) {
// It means this frame was decoded before, so we can skip it. It may happen
// when we have multiple simulcast streams in one track and received
// the same frame from two different streams because SFU can't reliably
// correlate two simulcast streams and started relaying the second stream
// from the same frame it has relayed right before for the first stream.
return;
}
frame_counters_.decoded++;
InternalStatsKey key(it->second.stream(),
stream_to_sender_.at(it->second.stream()), peer_index);
stream_frame_counters_.at(key).decoded++;
Timestamp now = Now();
StreamCodecInfo used_decoder;
used_decoder.codec_name = stats.decoder_name;
used_decoder.first_frame_id = frame.id();
used_decoder.last_frame_id = frame.id();
used_decoder.switched_on_at = now;
used_decoder.switched_from_at = now;
it->second.OnFrameDecoded(peer_index, now, frame.width(), frame.height(),
used_decoder, stats.qp);
if (options_.report_infra_metrics) {
analyzer_stats_.on_frame_decoded_processing_time_ms.AddSample(
(Now() - processing_started).ms<double>());
}
}
void DefaultVideoQualityAnalyzer::OnFrameRendered(
absl::string_view peer_name,
const webrtc::VideoFrame& frame) {
Timestamp processing_started = Now();
MutexLock lock(&mutex_);
RTC_CHECK_EQ(state_, State::kActive)
<< "DefaultVideoQualityAnalyzer has to be started before use";
size_t peer_index = peers_->index(peer_name);
if (frame.id() == VideoFrame::kNotSetId) {
frame_counters_.rendered++;
unknown_sender_frame_counters_[std::string(peer_name)].rendered++;
return;
}
auto frame_it = captured_frames_in_flight_.find(frame.id());
if (frame_it == captured_frames_in_flight_.end() ||
frame_it->second.HasRenderedTime(peer_index) ||
frame_it->second.IsDropped(peer_index)) {
// It means this frame was rendered or dropped before, so we can skip it.
// It may happen when we have multiple simulcast streams in one track and
// received the same frame from two different streams because SFU can't
// reliably correlate two simulcast streams and started relaying the second
// stream from the same frame it has relayed right before for the first
// stream.
absl::string_view reason = kSkipRenderedFrameReasonProcessed;
if (frame_it != captured_frames_in_flight_.end()) {
if (frame_it->second.HasRenderedTime(peer_index)) {
reason = kSkipRenderedFrameReasonRendered;
} else if (frame_it->second.IsDropped(peer_index)) {
reason = kSkipRenderedFrameReasonDropped;
}
}
RTC_LOG(LS_WARNING)
<< "Peer " << peer_name
<< "; Received frame out of order: received frame with id "
<< frame.id() << " which was " << reason << " before";
return;
}
// Find corresponding captured frame.
FrameInFlight* frame_in_flight = &frame_it->second;
std::optional<VideoFrame> captured_frame = frames_storage_.Get(frame.id());
const size_t stream_index = frame_in_flight->stream();
StreamState* state = &stream_states_.at(stream_index);
const InternalStatsKey stats_key(stream_index, state->sender(), peer_index);
// Update frames counters.
frame_counters_.rendered++;
stream_frame_counters_.at(stats_key).rendered++;
// Update current frame stats.
frame_in_flight->OnFrameRendered(peer_index, Now());
// After we received frame here we need to check if there are any dropped
// frames between this one and last one, that was rendered for this video
// stream.
int dropped_count = ProcessNotSeenFramesBeforeRendered(peer_index, frame.id(),
stats_key, *state);
RTC_DCHECK(!state->IsEmpty(peer_index));
state->PopFront(peer_index);
if (state->last_rendered_frame_time(peer_index).has_value()) {
TimeDelta time_between_rendered_frames =
state->GetPausableState(peer_index)
->GetActiveDurationFrom(
*state->last_rendered_frame_time(peer_index));
if (state->GetPausableState(peer_index)->IsPaused()) {
// If stream is currently paused for this receiver, but we still received
// frame, we have to add time from last pause up to Now() to the time
// between rendered frames.
time_between_rendered_frames +=
Now() - state->GetPausableState(peer_index)->GetLastEventTime();
}
frame_in_flight->SetTimeBetweenRenderedFrames(peer_index,
time_between_rendered_frames);
frame_in_flight->SetPrevFrameRenderedTime(
peer_index, *state->last_rendered_frame_time(peer_index));
}
state->SetLastRenderedFrameTime(peer_index,
frame_in_flight->rendered_time(peer_index));
analyzer_stats_.frames_in_flight_left_count.AddSample(
StatsSample(captured_frames_in_flight_.size(), Now()));
frames_comparator_.AddComparison(
stats_key, dropped_count, captured_frame, /*rendered=*/frame,
FrameComparisonType::kRegular,
frame_in_flight->GetStatsForPeer(peer_index));
if (frame_it->second.HaveAllPeersReceived()) {
frames_storage_.Remove(frame_it->second.id());
captured_frames_in_flight_.erase(frame_it);
}
if (options_.report_infra_metrics) {
analyzer_stats_.on_frame_rendered_processing_time_ms.AddSample(
(Now() - processing_started).ms<double>());
}
}
void DefaultVideoQualityAnalyzer::OnEncoderError(
absl::string_view peer_name,
const webrtc::VideoFrame& frame,
int32_t error_code) {
RTC_LOG(LS_ERROR) << "Encoder error for frame.id=" << frame.id()
<< ", code=" << error_code;
}
void DefaultVideoQualityAnalyzer::OnDecoderError(absl::string_view peer_name,
uint16_t frame_id,
int32_t error_code,
const DecoderStats& stats) {
RTC_LOG(LS_ERROR) << "Decoder error for frame_id=" << frame_id
<< ", code=" << error_code;
Timestamp processing_started = Now();
MutexLock lock(&mutex_);
RTC_CHECK_EQ(state_, State::kActive)
<< "DefaultVideoQualityAnalyzer has to be started before use";
size_t peer_index = peers_->index(peer_name);
if (frame_id == VideoFrame::kNotSetId) {
frame_counters_.failed_to_decode++;
unknown_sender_frame_counters_[std::string(peer_name)].failed_to_decode++;
return;
}
auto it = captured_frames_in_flight_.find(frame_id);
if (it == captured_frames_in_flight_.end() ||
it->second.HasDecodeEndTime(peer_index)) {
// It means this frame was decoded before, so we can skip it. It may happen
// when we have multiple simulcast streams in one track and received
// the same frame from two different streams because SFU can't reliably
// correlate two simulcast streams and started relaying the second stream
// from the same frame it has relayed right before for the first stream.
return;
}
frame_counters_.failed_to_decode++;
InternalStatsKey key(it->second.stream(),
stream_to_sender_.at(it->second.stream()), peer_index);
stream_frame_counters_.at(key).failed_to_decode++;
Timestamp now = Now();
StreamCodecInfo used_decoder;
used_decoder.codec_name = stats.decoder_name;
used_decoder.first_frame_id = frame_id;
used_decoder.last_frame_id = frame_id;
used_decoder.switched_on_at = now;
used_decoder.switched_from_at = now;
it->second.OnDecoderError(peer_index, used_decoder);
if (options_.report_infra_metrics) {
analyzer_stats_.on_decoder_error_processing_time_ms.AddSample(
(Now() - processing_started).ms<double>());
}
}
void DefaultVideoQualityAnalyzer::RegisterParticipantInCall(
absl::string_view peer_name) {
MutexLock lock(&mutex_);
RTC_CHECK(!peers_->HasName(peer_name));
size_t new_peer_index = peers_->AddIfAbsent(peer_name);
// Ensure stats for receiving (for frames from other peers to this one)
// streams exists. Since in flight frames will be sent to the new peer
// as well. Sending stats (from this peer to others) will be added by
// DefaultVideoQualityAnalyzer::OnFrameCaptured.
std::vector<std::pair<InternalStatsKey, Timestamp>> stream_started_time;
for (auto [stream_index, sender_peer_index] : stream_to_sender_) {
InternalStatsKey key(stream_index, sender_peer_index, new_peer_index);
// To initiate `FrameCounters` for the stream we should pick frame
// counters with the same stream index and the same sender's peer index
// and any receiver's peer index and copy from its sender side
// counters.
FrameCounters counters;
for (size_t i : peers_->GetPresentIndexes()) {
InternalStatsKey prototype_key(stream_index, sender_peer_index, i);
auto it = stream_frame_counters_.find(prototype_key);
if (it != stream_frame_counters_.end()) {
counters.captured = it->second.captured;
counters.pre_encoded = it->second.pre_encoded;
counters.encoded = it->second.encoded;
break;
}
}
// It may happen if we had only one peer before this method was invoked,
// then `counters` will be empty. In such case empty `counters` are ok.
stream_frame_counters_.insert({key, std::move(counters)});
stream_started_time.push_back(
{key, stream_states_.at(stream_index).stream_started_time()});
}
frames_comparator_.RegisterParticipantInCall(stream_started_time,
start_time_);
// Ensure, that frames states are handled correctly
// (e.g. dropped frames tracking).
for (auto& [stream_index, stream_state] : stream_states_) {
stream_state.AddPeer(new_peer_index);
}
// Register new peer for every frame in flight.
// It is guaranteed, that no garbage FrameInFlight objects will stay in
// memory because of adding new peer. Even if the new peer won't receive the
// frame, the frame will be removed by OnFrameRendered after next frame comes
// for the new peer. It is important because FrameInFlight is a large object.
for (auto& [frame_id, frame_in_flight] : captured_frames_in_flight_) {
frame_in_flight.AddExpectedReceiver(new_peer_index);
}
}
void DefaultVideoQualityAnalyzer::UnregisterParticipantInCall(
absl::string_view peer_name) {
MutexLock lock(&mutex_);
RTC_CHECK(peers_->HasName(peer_name));
std::optional<size_t> peer_index = peers_->RemoveIfPresent(peer_name);
RTC_CHECK(peer_index.has_value());
for (auto& [stream_index, stream_state] : stream_states_) {
if (!options_.enable_receive_own_stream &&
peer_index == stream_state.sender()) {
continue;
}
AddExistingFramesInFlightForStreamToComparator(stream_index, stream_state,
*peer_index);
stream_state.RemovePeer(*peer_index);
}
// Remove peer from every frame in flight. If we removed that last expected
// receiver for the frame, then we should removed this frame if it was
// already encoded. If frame wasn't encoded, it still will be used by sender
// side pipeline, so we can't delete it yet.
for (auto it = captured_frames_in_flight_.begin();
it != captured_frames_in_flight_.end();) {
FrameInFlight& frame_in_flight = it->second;
frame_in_flight.RemoveExpectedReceiver(*peer_index);
// If frame was fully sent and all receivers received it, then erase it.
// It may happen that when we remove FrameInFlight only some Simulcast/SVC
// layers were encoded and frame has encoded time, but more layers might be
// encoded after removal. In such case it's safe to still remove a frame,
// because OnFrameEncoded method will correctly handle the case when there
// is no FrameInFlight for the received encoded image.
if (frame_in_flight.HasEncodedTime() &&
frame_in_flight.HaveAllPeersReceived()) {
frames_storage_.Remove(frame_in_flight.id());
it = captured_frames_in_flight_.erase(it);
} else {
it++;
}
}
}
void DefaultVideoQualityAnalyzer::OnPauseAllStreamsFrom(
absl::string_view sender_peer_name,
absl::string_view receiver_peer_name) {
MutexLock lock(&mutex_);
if (peers_->HasName(sender_peer_name) &&
peers_->HasName(receiver_peer_name)) {
size_t sender_peer_index = peers_->index(sender_peer_name);
size_t receiver_peer_index = peers_->index(receiver_peer_name);
for (auto& [unused, stream_state] : stream_states_) {
if (stream_state.sender() == sender_peer_index) {
stream_state.GetPausableState(receiver_peer_index)->Pause();
}
}
}
}
void DefaultVideoQualityAnalyzer::OnResumeAllStreamsFrom(
absl::string_view sender_peer_name,
absl::string_view receiver_peer_name) {
MutexLock lock(&mutex_);
if (peers_->HasName(sender_peer_name) &&
peers_->HasName(receiver_peer_name)) {
size_t sender_peer_index = peers_->index(sender_peer_name);
size_t receiver_peer_index = peers_->index(receiver_peer_name);
for (auto& [unused, stream_state] : stream_states_) {
if (stream_state.sender() == sender_peer_index) {
stream_state.GetPausableState(receiver_peer_index)->Resume();
}
}
}
}
void DefaultVideoQualityAnalyzer::Stop() {
std::map<InternalStatsKey, Timestamp> last_rendered_frame_times;
{
MutexLock lock(&mutex_);
if (state_ == State::kStopped) {
return;
}
RTC_CHECK_EQ(state_, State::kActive)
<< "DefaultVideoQualityAnalyzer has to be started before use";
state_ = State::kStopped;
// Add the amount of frames in flight to the analyzer stats before all left
// frames in flight will be sent to the `frames_compartor_`.
analyzer_stats_.frames_in_flight_left_count.AddSample(
StatsSample(captured_frames_in_flight_.size(), Now()));
for (auto& state_entry : stream_states_) {
const size_t stream_index = state_entry.first;
StreamState& stream_state = state_entry.second;
// Populate `last_rendered_frame_times` map for all peers that were met in
// call, not only for the currently presented ones.
for (size_t peer_index : peers_->GetAllIndexes()) {
if (peer_index == stream_state.sender() &&
!options_.enable_receive_own_stream) {
continue;
}
InternalStatsKey stats_key(stream_index, stream_state.sender(),
peer_index);
// If there are no freezes in the call we have to report
// time_between_freezes_ms as call duration and in such case
// `stream_last_freeze_end_time` for this stream will be `start_time_`.
// If there is freeze, then we need add time from last rendered frame
// to last freeze end as time between freezes.
if (stream_state.last_rendered_frame_time(peer_index)) {
last_rendered_frame_times.emplace(
stats_key,
stream_state.last_rendered_frame_time(peer_index).value());
}
}
// Push left frame in flight for analysis for the peers that are still in
// the call.
for (size_t peer_index : peers_->GetPresentIndexes()) {
if (peer_index == stream_state.sender() &&
!options_.enable_receive_own_stream) {
continue;
}
AddExistingFramesInFlightForStreamToComparator(
stream_index, stream_state, peer_index);
}
}
}
frames_comparator_.Stop(last_rendered_frame_times);
// Perform final Metrics update. On this place analyzer is stopped and no one
// holds any locks.
{
MutexLock lock(&mutex_);
FramesComparatorStats frames_comparator_stats =
frames_comparator_.frames_comparator_stats();
analyzer_stats_.comparisons_queue_size =
std::move(frames_comparator_stats.comparisons_queue_size);
analyzer_stats_.comparisons_done = frames_comparator_stats.comparisons_done;
analyzer_stats_.cpu_overloaded_comparisons_done =
frames_comparator_stats.cpu_overloaded_comparisons_done;
analyzer_stats_.memory_overloaded_comparisons_done =
frames_comparator_stats.memory_overloaded_comparisons_done;
}
ReportResults();
}
std::string DefaultVideoQualityAnalyzer::GetStreamLabel(uint16_t frame_id) {
MutexLock lock(&mutex_);
return GetStreamLabelInternal(frame_id);
}
std::string DefaultVideoQualityAnalyzer::GetSenderPeerName(
uint16_t frame_id) const {
MutexLock lock(&mutex_);
std::string stream_label = GetStreamLabelInternal(frame_id);
size_t stream_index = streams_.index(stream_label);
size_t sender_peer_index = stream_states_.at(stream_index).sender();
return peers_->name(sender_peer_index);
}
std::set<StatsKey> DefaultVideoQualityAnalyzer::GetKnownVideoStreams() const {
MutexLock lock(&mutex_);
std::set<StatsKey> out;
for (auto& item : frames_comparator_.stream_stats()) {
RTC_LOG(LS_INFO) << item.first.ToString() << " ==> "
<< ToStatsKey(item.first).ToString();
out.insert(ToStatsKey(item.first));
}
return out;
}
VideoStreamsInfo DefaultVideoQualityAnalyzer::GetKnownStreams() const {
MutexLock lock(&mutex_);
std::map<std::string, std::string> stream_to_sender;
std::map<std::string, std::set<std::string>> sender_to_streams;
std::map<std::string, std::set<std::string>> stream_to_receivers;
for (auto& item : frames_comparator_.stream_stats()) {
const std::string& stream_label = streams_.name(item.first.stream);
const std::string& sender = peers_->name(item.first.sender);
const std::string& receiver = peers_->name(item.first.receiver);
RTC_LOG(LS_INFO) << item.first.ToString() << " ==> "
<< "stream=" << stream_label << "; sender=" << sender
<< "; receiver=" << receiver;
stream_to_sender.emplace(stream_label, sender);
auto streams_it = sender_to_streams.find(sender);
if (streams_it != sender_to_streams.end()) {
streams_it->second.emplace(stream_label);
} else {
sender_to_streams.emplace(sender, std::set<std::string>{stream_label});
}
auto receivers_it = stream_to_receivers.find(stream_label);
if (receivers_it != stream_to_receivers.end()) {
receivers_it->second.emplace(receiver);
} else {
stream_to_receivers.emplace(stream_label,
std::set<std::string>{receiver});
}
}
return VideoStreamsInfo(std::move(stream_to_sender),
std::move(sender_to_streams),
std::move(stream_to_receivers));
}
FrameCounters DefaultVideoQualityAnalyzer::GetGlobalCounters() const {
MutexLock lock(&mutex_);
return frame_counters_;
}
std::map<std::string, FrameCounters>
DefaultVideoQualityAnalyzer::GetUnknownSenderFrameCounters() const {
MutexLock lock(&mutex_);
return unknown_sender_frame_counters_;
}
std::map<StatsKey, FrameCounters>
DefaultVideoQualityAnalyzer::GetPerStreamCounters() const {
MutexLock lock(&mutex_);
std::map<StatsKey, FrameCounters> out;
for (auto& item : stream_frame_counters_) {
out.emplace(ToStatsKey(item.first), item.second);
}
return out;
}
std::map<StatsKey, StreamStats> DefaultVideoQualityAnalyzer::GetStats() const {
MutexLock lock1(&mutex_);
std::map<StatsKey, StreamStats> out;
for (auto& item : frames_comparator_.stream_stats()) {
out.emplace(ToStatsKey(item.first), item.second);
}
return out;
}
AnalyzerStats DefaultVideoQualityAnalyzer::GetAnalyzerStats() const {
MutexLock lock(&mutex_);
return analyzer_stats_;
}
uint16_t DefaultVideoQualityAnalyzer::GetNextFrameId() {
uint16_t frame_id = next_frame_id_++;
if (next_frame_id_ == VideoFrame::kNotSetId) {
next_frame_id_ = 1;
}
return frame_id;
}
void DefaultVideoQualityAnalyzer::
AddExistingFramesInFlightForStreamToComparator(size_t stream_index,
StreamState& stream_state,
size_t peer_index) {
InternalStatsKey stats_key(stream_index, stream_state.sender(), peer_index);
// Add frames in flight for this stream into frames comparator.
// Frames in flight were not rendered, so they won't affect stream's
// last rendered frame time.
while (!stream_state.IsEmpty(peer_index) &&
!stream_state.GetPausableState(peer_index)->IsPaused()) {
uint16_t frame_id = stream_state.PopFront(peer_index);
auto it = captured_frames_in_flight_.find(frame_id);
RTC_DCHECK(it != captured_frames_in_flight_.end());
FrameInFlight& frame = it->second;
frames_comparator_.AddComparison(stats_key, /*captured=*/std::nullopt,
/*rendered=*/std::nullopt,
FrameComparisonType::kFrameInFlight,
frame.GetStatsForPeer(peer_index));
}
}
int DefaultVideoQualityAnalyzer::ProcessNotSeenFramesBeforeRendered(
size_t peer_index,
uint16_t rendered_frame_id,
const InternalStatsKey& stats_key,
StreamState& state) {
int dropped_count = 0;
while (!state.IsEmpty(peer_index) &&
state.Front(peer_index) != rendered_frame_id) {
uint16_t next_frame_id = state.PopFront(peer_index);
auto next_frame_it = captured_frames_in_flight_.find(next_frame_id);
RTC_DCHECK(next_frame_it != captured_frames_in_flight_.end());
FrameInFlight& next_frame = next_frame_it->second;
// Depending if the receiver was subscribed to this stream or not at the
// time when frame was captured, the frame should be considered as dropped
// or superfluous (see below for explanation). Superfluous frames must be
// excluded from stats calculations.
//
// We should consider next cases:
// Legend:
// + - frame captured on the stream
// p - stream is paused
// r - stream is resumed
//
// last currently
// rendered rendered
// frame frame
// |---------------------- dropped -------------------------|
// (1) -[]---+---+---+---+---+---+---+---+---+---+---+---+---+---[]-> time
// | |
// | |
// |-- dropped ---┐ ┌- dropped -┐ ┌- dropped ---|
// (2) -[]---+---+---+-|-+---+-|-+---+---+-|-+---+-|-+---+---+---[]-> time
// | p r p r |
// | |
// |-- dropped ---┐ ┌------------ dropped ------------|
// (3) -[]---+---+---+-|-+---+-|-+---+---+---+---+---+-|-+---+---[]-> time
// p r p
//
// Cases explanation:
// (1) Regular media flow, frame is received after freeze.
// (2) Stream was paused and received multiple times. Frame is received
// after freeze from last resume.
// (3) Stream was paused and received multiple times. Frame is received
// after stream was paused because frame was already in the network.
//
// Based on that if stream wasn't paused when `next_frame_id` was captured,
// then `next_frame_id` should be considered as dropped. If stream was NOT
// resumed after `next_frame_id` was captured but we still received a
// `rendered_frame_id` on this stream, then `next_frame_id` also should
// be considered as dropped. In other cases `next_frame_id` should be
// considered as superfluous, because receiver wasn't expected to receive
// `next_frame_id` at all.
bool is_dropped = false;
bool is_paused = state.GetPausableState(peer_index)
->WasPausedAt(next_frame.captured_time());
if (!is_paused) {
is_dropped = true;
} else {
bool was_resumed_after =
state.GetPausableState(peer_index)
->WasResumedAfter(next_frame.captured_time());
if (!was_resumed_after) {
is_dropped = true;
}
}
if (is_dropped) {
dropped_count++;
// Frame with id `dropped_frame_id` was dropped. We need:
// 1. Update global and stream frame counters
// 2. Extract corresponding frame from `captured_frames_in_flight_`
// 3. Send extracted frame to comparison with dropped=true
// 4. Cleanup dropped frame
frame_counters_.dropped++;
stream_frame_counters_.at(stats_key).dropped++;
next_frame.MarkDropped(peer_index);
analyzer_stats_.frames_in_flight_left_count.AddSample(
StatsSample(captured_frames_in_flight_.size(), Now()));
frames_comparator_.AddComparison(stats_key, /*captured=*/std::nullopt,
/*rendered=*/std::nullopt,
FrameComparisonType::kDroppedFrame,
next_frame.GetStatsForPeer(peer_index));
} else {
next_frame.MarkSuperfluous(peer_index);
}
if (next_frame_it->second.HaveAllPeersReceived()) {
frames_storage_.Remove(next_frame_it->second.id());
captured_frames_in_flight_.erase(next_frame_it);
}
}
return dropped_count;
}
void DefaultVideoQualityAnalyzer::ReportResults() {
MutexLock lock(&mutex_);
for (auto& item : frames_comparator_.stream_stats()) {
ReportResults(item.first, item.second,
stream_frame_counters_.at(item.first));
}
// TODO(bugs.webrtc.org/14757): Remove kExperimentalTestNameMetadataKey.
metrics_logger_->LogSingleValueMetric(
"cpu_usage_%", test_label_, GetCpuUsagePercent(), Unit::kUnitless,
ImprovementDirection::kSmallerIsBetter,
{{MetricMetadataKey::kExperimentalTestNameMetadataKey, test_label_}});
LogFrameCounters("Global", frame_counters_);
if (!unknown_sender_frame_counters_.empty()) {
RTC_LOG(LS_INFO) << "Received frame counters with unknown frame id:";
for (const auto& [peer_name, frame_counters] :
unknown_sender_frame_counters_) {
LogFrameCounters(peer_name, frame_counters);
}
}
RTC_LOG(LS_INFO) << "Received frame counters per stream:";
for (const auto& [stats_key, stream_stats] :
frames_comparator_.stream_stats()) {
LogFrameCounters(ToStatsKey(stats_key).ToString(),
stream_frame_counters_.at(stats_key));
LogStreamInternalStats(ToStatsKey(stats_key).ToString(), stream_stats,
start_time_);
}
if (!analyzer_stats_.comparisons_queue_size.IsEmpty()) {
RTC_LOG(LS_INFO) << "comparisons_queue_size min="
<< analyzer_stats_.comparisons_queue_size.GetMin()
<< "; max="
<< analyzer_stats_.comparisons_queue_size.GetMax()
<< "; 99%="
<< analyzer_stats_.comparisons_queue_size.GetPercentile(
0.99);
}
RTC_LOG(LS_INFO) << "comparisons_done=" << analyzer_stats_.comparisons_done;
RTC_LOG(LS_INFO) << "cpu_overloaded_comparisons_done="
<< analyzer_stats_.cpu_overloaded_comparisons_done;
RTC_LOG(LS_INFO) << "memory_overloaded_comparisons_done="
<< analyzer_stats_.memory_overloaded_comparisons_done;
if (options_.report_infra_metrics) {
metrics_logger_->LogMetric("comparisons_queue_size", test_label_,
analyzer_stats_.comparisons_queue_size,
Unit::kCount,
ImprovementDirection::kSmallerIsBetter);
metrics_logger_->LogMetric("frames_in_flight_left_count", test_label_,
analyzer_stats_.frames_in_flight_left_count,
Unit::kCount,
ImprovementDirection::kSmallerIsBetter);
metrics_logger_->LogSingleValueMetric(
"comparisons_done", test_label_, analyzer_stats_.comparisons_done,
Unit::kCount, ImprovementDirection::kNeitherIsBetter);
metrics_logger_->LogSingleValueMetric(
"cpu_overloaded_comparisons_done", test_label_,
analyzer_stats_.cpu_overloaded_comparisons_done, Unit::kCount,
ImprovementDirection::kNeitherIsBetter);
metrics_logger_->LogSingleValueMetric(
"memory_overloaded_comparisons_done", test_label_,
analyzer_stats_.memory_overloaded_comparisons_done, Unit::kCount,
ImprovementDirection::kNeitherIsBetter);
metrics_logger_->LogSingleValueMetric(
"test_duration", test_label_, (Now() - start_time_).ms(),
Unit::kMilliseconds, ImprovementDirection::kNeitherIsBetter);
metrics_logger_->LogMetric(
"on_frame_captured_processing_time_ms", test_label_,
analyzer_stats_.on_frame_captured_processing_time_ms,
Unit::kMilliseconds, ImprovementDirection::kSmallerIsBetter);
metrics_logger_->LogMetric(
"on_frame_pre_encode_processing_time_ms", test_label_,
analyzer_stats_.on_frame_pre_encode_processing_time_ms,
Unit::kMilliseconds, ImprovementDirection::kSmallerIsBetter);
metrics_logger_->LogMetric(
"on_frame_encoded_processing_time_ms", test_label_,
analyzer_stats_.on_frame_encoded_processing_time_ms,
Unit::kMilliseconds, ImprovementDirection::kSmallerIsBetter);
metrics_logger_->LogMetric(
"on_frame_pre_decode_processing_time_ms", test_label_,
analyzer_stats_.on_frame_pre_decode_processing_time_ms,
Unit::kMilliseconds, ImprovementDirection::kSmallerIsBetter);
metrics_logger_->LogMetric(
"on_frame_decoded_processing_time_ms", test_label_,
analyzer_stats_.on_frame_decoded_processing_time_ms,
Unit::kMilliseconds, ImprovementDirection::kSmallerIsBetter);
metrics_logger_->LogMetric(
"on_frame_rendered_processing_time_ms", test_label_,
analyzer_stats_.on_frame_rendered_processing_time_ms,
Unit::kMilliseconds, ImprovementDirection::kSmallerIsBetter);
metrics_logger_->LogMetric(
"on_decoder_error_processing_time_ms", test_label_,
analyzer_stats_.on_decoder_error_processing_time_ms,
Unit::kMilliseconds, ImprovementDirection::kSmallerIsBetter);
}
}
void DefaultVideoQualityAnalyzer::ReportResults(
const InternalStatsKey& key,
const StreamStats& stats,
const FrameCounters& frame_counters) {
TimeDelta test_duration = Now() - start_time_;
std::string test_case_name = GetTestCaseName(ToMetricName(key));
// TODO(bugs.webrtc.org/14757): Remove kExperimentalTestNameMetadataKey.
std::map<std::string, std::string> metric_metadata{
{MetricMetadataKey::kPeerMetadataKey, peers_->name(key.sender)},
{MetricMetadataKey::kVideoStreamMetadataKey, streams_.name(key.stream)},
{MetricMetadataKey::kSenderMetadataKey, peers_->name(key.sender)},
{MetricMetadataKey::kReceiverMetadataKey, peers_->name(key.receiver)},
{MetricMetadataKey::kExperimentalTestNameMetadataKey, test_label_}};
metrics_logger_->LogMetric(
"psnr_dB", test_case_name, stats.psnr, Unit::kUnitless,
ImprovementDirection::kBiggerIsBetter, metric_metadata);
metrics_logger_->LogMetric(
"ssim", test_case_name, stats.ssim, Unit::kUnitless,
ImprovementDirection::kBiggerIsBetter, metric_metadata);
metrics_logger_->LogMetric("transport_time", test_case_name,
stats.transport_time_ms, Unit::kMilliseconds,
ImprovementDirection::kSmallerIsBetter,
metric_metadata);
metrics_logger_->LogMetric(
"total_delay_incl_transport", test_case_name,
stats.total_delay_incl_transport_ms, Unit::kMilliseconds,
ImprovementDirection::kSmallerIsBetter, metric_metadata);
metrics_logger_->LogMetric(
"time_between_rendered_frames", test_case_name,
stats.time_between_rendered_frames_ms, Unit::kMilliseconds,
ImprovementDirection::kSmallerIsBetter, metric_metadata);
metrics_logger_->LogSingleValueMetric(
"harmonic_framerate", test_case_name, stats.harmonic_framerate_fps,
Unit::kHertz, ImprovementDirection::kBiggerIsBetter, metric_metadata);
metrics_logger_->LogSingleValueMetric(
"encode_frame_rate", test_case_name,
stats.encode_frame_rate.IsEmpty()
? 0
: stats.encode_frame_rate.GetEventsPerSecond(),
Unit::kHertz, ImprovementDirection::kBiggerIsBetter, metric_metadata);
metrics_logger_->LogMetric(
"encode_time", test_case_name, stats.encode_time_ms, Unit::kMilliseconds,
ImprovementDirection::kSmallerIsBetter, metric_metadata);
metrics_logger_->LogMetric("time_between_freezes", test_case_name,
stats.time_between_freezes_ms, Unit::kMilliseconds,
ImprovementDirection::kBiggerIsBetter,
metric_metadata);
metrics_logger_->LogMetric("freeze_time_ms", test_case_name,
stats.freeze_time_ms, Unit::kMilliseconds,
ImprovementDirection::kSmallerIsBetter,
metric_metadata);
metrics_logger_->LogMetric(
"pixels_per_frame", test_case_name, stats.resolution_of_decoded_frame,
Unit::kCount, ImprovementDirection::kBiggerIsBetter, metric_metadata);
metrics_logger_->LogSingleValueMetric(
"min_psnr_dB", test_case_name,
stats.psnr.IsEmpty() ? 0 : stats.psnr.GetMin(), Unit::kUnitless,
ImprovementDirection::kBiggerIsBetter, metric_metadata);
metrics_logger_->LogMetric(
"decode_time", test_case_name, stats.decode_time_ms, Unit::kMilliseconds,
ImprovementDirection::kSmallerIsBetter, metric_metadata);
metrics_logger_->LogMetric(
"receive_to_render_time", test_case_name, stats.receive_to_render_time_ms,
Unit::kMilliseconds, ImprovementDirection::kSmallerIsBetter,
metric_metadata);
metrics_logger_->LogSingleValueMetric(
"dropped_frames", test_case_name, frame_counters.dropped, Unit::kCount,
ImprovementDirection::kSmallerIsBetter, metric_metadata);
metrics_logger_->LogSingleValueMetric(
"frames_in_flight", test_case_name,
frame_counters.captured - frame_counters.rendered -
frame_counters.dropped,
Unit::kCount, ImprovementDirection::kSmallerIsBetter, metric_metadata);
metrics_logger_->LogSingleValueMetric(
"rendered_frames", test_case_name, frame_counters.rendered, Unit::kCount,
ImprovementDirection::kBiggerIsBetter, metric_metadata);
metrics_logger_->LogMetric(
"max_skipped", test_case_name, stats.skipped_between_rendered,
Unit::kCount, ImprovementDirection::kSmallerIsBetter, metric_metadata);
metrics_logger_->LogMetric(
"target_encode_bitrate", test_case_name,
stats.target_encode_bitrate / 1000, Unit::kKilobitsPerSecond,
ImprovementDirection::kNeitherIsBetter, metric_metadata);
for (const auto& [spatial_layer, qp] : stats.spatial_layers_qp) {
std::map<std::string, std::string> qp_metadata = metric_metadata;
qp_metadata[MetricMetadataKey::kSpatialLayerMetadataKey] =
std::to_string(spatial_layer);
metrics_logger_->LogMetric("qp_sl" + std::to_string(spatial_layer),
test_case_name, qp, Unit::kUnitless,
ImprovementDirection::kSmallerIsBetter,
std::move(qp_metadata));
}
metrics_logger_->LogMetric(
"rendered_frame_qp", test_case_name, stats.rendered_frame_qp,
Unit::kUnitless, ImprovementDirection::kSmallerIsBetter, metric_metadata);
metrics_logger_->LogSingleValueMetric(
"actual_encode_bitrate", test_case_name,
static_cast<double>(stats.total_encoded_images_payload) /
test_duration.seconds<double>() * kBitsInByte / 1000,
Unit::kKilobitsPerSecond, ImprovementDirection::kNeitherIsBetter,
metric_metadata);
if (options_.report_detailed_frame_stats) {
metrics_logger_->LogSingleValueMetric(
"capture_frame_rate", test_case_name,
stats.capture_frame_rate.IsEmpty()
? 0
: stats.capture_frame_rate.GetEventsPerSecond(),
Unit::kHertz, ImprovementDirection::kBiggerIsBetter, metric_metadata);
metrics_logger_->LogSingleValueMetric(
"num_encoded_frames", test_case_name, frame_counters.encoded,
Unit::kCount, ImprovementDirection::kBiggerIsBetter, metric_metadata);
metrics_logger_->LogSingleValueMetric(
"num_decoded_frames", test_case_name, frame_counters.decoded,
Unit::kCount, ImprovementDirection::kBiggerIsBetter, metric_metadata);
metrics_logger_->LogSingleValueMetric(
"num_send_key_frames", test_case_name, stats.num_send_key_frames,
Unit::kCount, ImprovementDirection::kBiggerIsBetter, metric_metadata);
metrics_logger_->LogSingleValueMetric(
"num_recv_key_frames", test_case_name, stats.num_recv_key_frames,
Unit::kCount, ImprovementDirection::kBiggerIsBetter, metric_metadata);
metrics_logger_->LogMetric("recv_key_frame_size_bytes", test_case_name,
stats.recv_key_frame_size_bytes, Unit::kCount,
ImprovementDirection::kBiggerIsBetter,
metric_metadata);
metrics_logger_->LogMetric("recv_delta_frame_size_bytes", test_case_name,
stats.recv_delta_frame_size_bytes, Unit::kCount,
ImprovementDirection::kBiggerIsBetter,
metric_metadata);
}
}
std::string DefaultVideoQualityAnalyzer::GetTestCaseName(
const std::string& stream_label) const {
return test_label_ + "/" + stream_label;
}
Timestamp DefaultVideoQualityAnalyzer::Now() {
return clock_->CurrentTime();
}
StatsKey DefaultVideoQualityAnalyzer::ToStatsKey(
const InternalStatsKey& key) const {
return StatsKey(streams_.name(key.stream), peers_->name(key.receiver));
}
std::string DefaultVideoQualityAnalyzer::ToMetricName(
const InternalStatsKey& key) const {
const std::string& stream_label = streams_.name(key.stream);
if (peers_->GetKnownSize() <= 2 && key.sender != key.receiver) {
// TODO(titovartem): remove this special case.
return stream_label;
}
rtc::StringBuilder out;
out << stream_label << "_" << peers_->name(key.sender) << "_"
<< peers_->name(key.receiver);
return out.str();
}
std::string DefaultVideoQualityAnalyzer::GetStreamLabelInternal(
uint16_t frame_id) const {
auto it = captured_frames_in_flight_.find(frame_id);
if (it != captured_frames_in_flight_.end()) {
return streams_.name(it->second.stream());
}
for (auto hist_it = stream_to_frame_id_history_.begin();
hist_it != stream_to_frame_id_history_.end(); ++hist_it) {
auto hist_set_it = hist_it->second.find(frame_id);
if (hist_set_it != hist_it->second.end()) {
return streams_.name(hist_it->first);
}
}
RTC_CHECK(false) << "Unknown frame_id=" << frame_id;
}
double DefaultVideoQualityAnalyzer::GetCpuUsagePercent() const {
return cpu_measurer_.GetCpuUsagePercent();
}
std::map<std::string, std::vector<uint16_t>>
DefaultVideoQualityAnalyzer::GetStreamFrames() const {
MutexLock lock(&mutex_);
std::map<std::string, std::vector<uint16_t>> out;
for (auto entry_it : stream_to_frame_id_full_history_) {
out.insert({streams_.name(entry_it.first), entry_it.second});
}
return out;
}
} // namespace webrtc