// Copyright 2014 The Chromium Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #include "media/cast/logging/stats_event_subscriber.h" #include #include #include #include "base/format_macros.h" #include "base/logging.h" #include "base/strings/stringprintf.h" #include "base/values.h" #define STAT_ENUM_TO_STRING(enum) \ case enum: \ return #enum namespace media { namespace cast { namespace { using media::cast::CastLoggingEvent; using media::cast::EventMediaType; const size_t kMaxPacketEventTimeMapSize = 1000; bool IsReceiverEvent(CastLoggingEvent event) { return event == FRAME_DECODED || event == FRAME_PLAYOUT || event == FRAME_ACK_SENT || event == PACKET_RECEIVED; } } // namespace StatsEventSubscriber::SimpleHistogram::SimpleHistogram(int64_t min, int64_t max, int64_t width) : min_(min), max_(max), width_(width), buckets_((max - min) / width + 2) { CHECK_GT(buckets_.size(), 2u); CHECK_EQ(0, (max_ - min_) % width_); } StatsEventSubscriber::SimpleHistogram::~SimpleHistogram() { } void StatsEventSubscriber::SimpleHistogram::Add(int64_t sample) { if (sample < min_) { ++buckets_.front(); } else if (sample >= max_) { ++buckets_.back(); } else { size_t index = 1 + (sample - min_) / width_; DCHECK_LT(index, buckets_.size()); ++buckets_[index]; } } void StatsEventSubscriber::SimpleHistogram::Reset() { buckets_.assign(buckets_.size(), 0); } std::unique_ptr StatsEventSubscriber::SimpleHistogram::GetHistogram() const { std::unique_ptr histo(new base::ListValue); std::unique_ptr bucket(new base::DictionaryValue); if (buckets_.front()) { bucket->SetInteger(base::StringPrintf("<%" PRId64, min_), buckets_.front()); histo->Append(std::move(bucket)); } for (size_t i = 1; i < buckets_.size() - 1; i++) { if (!buckets_[i]) continue; bucket.reset(new base::DictionaryValue); int64_t lower = min_ + (i - 1) * width_; int64_t upper = lower + width_ - 1; bucket->SetInteger( base::StringPrintf("%" PRId64 "-%" PRId64, lower, upper), buckets_[i]); histo->Append(std::move(bucket)); } if (buckets_.back()) { bucket.reset(new base::DictionaryValue); bucket->SetInteger(base::StringPrintf(">=%" PRId64, max_), buckets_.back()); histo->Append(std::move(bucket)); } return histo; } StatsEventSubscriber::StatsEventSubscriber( EventMediaType event_media_type, base::TickClock* clock, ReceiverTimeOffsetEstimator* offset_estimator) : event_media_type_(event_media_type), clock_(clock), offset_estimator_(offset_estimator), capture_latency_datapoints_(0), encode_time_datapoints_(0), queueing_latency_datapoints_(0), network_latency_datapoints_(0), packet_latency_datapoints_(0), frame_latency_datapoints_(0), e2e_latency_datapoints_(0), num_frames_dropped_by_encoder_(0), num_frames_late_(0), start_time_(clock_->NowTicks()) { DCHECK(event_media_type == AUDIO_EVENT || event_media_type == VIDEO_EVENT); InitHistograms(); } StatsEventSubscriber::~StatsEventSubscriber() { DCHECK(thread_checker_.CalledOnValidThread()); } void StatsEventSubscriber::OnReceiveFrameEvent(const FrameEvent& frame_event) { DCHECK(thread_checker_.CalledOnValidThread()); CastLoggingEvent type = frame_event.type; if (frame_event.media_type != event_media_type_) return; FrameStatsMap::iterator it = frame_stats_.find(type); if (it == frame_stats_.end()) { FrameLogStats stats; stats.event_counter = 1; stats.sum_size = frame_event.size; stats.sum_delay = frame_event.delay_delta; frame_stats_.insert(std::make_pair(type, stats)); } else { ++(it->second.event_counter); it->second.sum_size += frame_event.size; it->second.sum_delay += frame_event.delay_delta; } bool is_receiver_event = IsReceiverEvent(type); UpdateFirstLastEventTime(frame_event.timestamp, is_receiver_event); if (type == FRAME_CAPTURE_BEGIN) { RecordFrameCaptureTime(frame_event); } else if (type == FRAME_CAPTURE_END) { RecordCaptureLatency(frame_event); } else if (type == FRAME_ENCODED) { RecordEncodeLatency(frame_event); } else if (type == FRAME_ACK_SENT) { RecordFrameTxLatency(frame_event); } else if (type == FRAME_PLAYOUT) { RecordE2ELatency(frame_event); base::TimeDelta delay_delta = frame_event.delay_delta; // Positive delay_delta means the frame is late. if (delay_delta > base::TimeDelta()) { num_frames_late_++; histograms_[LATE_FRAME_MS_HISTO]->Add(delay_delta.InMillisecondsF()); } } if (is_receiver_event) UpdateLastResponseTime(frame_event.timestamp); } void StatsEventSubscriber::OnReceivePacketEvent( const PacketEvent& packet_event) { DCHECK(thread_checker_.CalledOnValidThread()); CastLoggingEvent type = packet_event.type; if (packet_event.media_type != event_media_type_) return; PacketStatsMap::iterator it = packet_stats_.find(type); if (it == packet_stats_.end()) { PacketLogStats stats; stats.event_counter = 1; stats.sum_size = packet_event.size; packet_stats_.insert(std::make_pair(type, stats)); } else { ++(it->second.event_counter); it->second.sum_size += packet_event.size; } bool is_receiver_event = IsReceiverEvent(type); UpdateFirstLastEventTime(packet_event.timestamp, is_receiver_event); if (type == PACKET_SENT_TO_NETWORK || type == PACKET_RECEIVED) { RecordPacketRelatedLatencies(packet_event); } else if (type == PACKET_RETRANSMITTED) { // We only measure network latency using packets that doesn't have to be // retransmitted as there is precisely one sent-receive timestamp pairs. ErasePacketSentTime(packet_event); } if (is_receiver_event) UpdateLastResponseTime(packet_event.timestamp); } void StatsEventSubscriber::UpdateFirstLastEventTime(base::TimeTicks timestamp, bool is_receiver_event) { if (is_receiver_event) { base::TimeDelta receiver_offset; if (!GetReceiverOffset(&receiver_offset)) return; timestamp -= receiver_offset; } if (first_event_time_.is_null()) { first_event_time_ = timestamp; } else { first_event_time_ = std::min(first_event_time_, timestamp); } if (last_event_time_.is_null()) { last_event_time_ = timestamp; } else { last_event_time_ = std::max(last_event_time_, timestamp); } } std::unique_ptr StatsEventSubscriber::GetStats() const { StatsMap stats_map; GetStatsInternal(&stats_map); std::unique_ptr ret(new base::DictionaryValue); std::unique_ptr stats(new base::DictionaryValue); for (StatsMap::const_iterator it = stats_map.begin(); it != stats_map.end(); ++it) { // Round to 3 digits after the decimal point. stats->SetDouble(CastStatToString(it->first), round(it->second * 1000.0) / 1000.0); } // Populate all histograms. for (HistogramMap::const_iterator it = histograms_.begin(); it != histograms_.end(); ++it) { stats->Set(CastStatToString(it->first), it->second->GetHistogram().release()); } ret->Set(event_media_type_ == AUDIO_EVENT ? "audio" : "video", stats.release()); return ret; } void StatsEventSubscriber::Reset() { DCHECK(thread_checker_.CalledOnValidThread()); frame_stats_.clear(); packet_stats_.clear(); total_capture_latency_ = base::TimeDelta(); capture_latency_datapoints_ = 0; total_encode_time_ = base::TimeDelta(); encode_time_datapoints_ = 0; total_queueing_latency_ = base::TimeDelta(); queueing_latency_datapoints_ = 0; total_network_latency_ = base::TimeDelta(); network_latency_datapoints_ = 0; total_packet_latency_ = base::TimeDelta(); packet_latency_datapoints_ = 0; total_frame_latency_ = base::TimeDelta(); frame_latency_datapoints_ = 0; total_e2e_latency_ = base::TimeDelta(); e2e_latency_datapoints_ = 0; num_frames_dropped_by_encoder_ = 0; num_frames_late_ = 0; recent_frame_infos_.clear(); packet_sent_times_.clear(); start_time_ = clock_->NowTicks(); last_response_received_time_ = base::TimeTicks(); for (HistogramMap::iterator it = histograms_.begin(); it != histograms_.end(); ++it) { it->second->Reset(); } first_event_time_ = base::TimeTicks(); last_event_time_ = base::TimeTicks(); } // static const char* StatsEventSubscriber::CastStatToString(CastStat stat) { switch (stat) { STAT_ENUM_TO_STRING(CAPTURE_FPS); STAT_ENUM_TO_STRING(ENCODE_FPS); STAT_ENUM_TO_STRING(DECODE_FPS); STAT_ENUM_TO_STRING(AVG_CAPTURE_LATENCY_MS); STAT_ENUM_TO_STRING(AVG_ENCODE_TIME_MS); STAT_ENUM_TO_STRING(AVG_QUEUEING_LATENCY_MS); STAT_ENUM_TO_STRING(AVG_NETWORK_LATENCY_MS); STAT_ENUM_TO_STRING(AVG_PACKET_LATENCY_MS); STAT_ENUM_TO_STRING(AVG_FRAME_LATENCY_MS); STAT_ENUM_TO_STRING(AVG_E2E_LATENCY_MS); STAT_ENUM_TO_STRING(ENCODE_KBPS); STAT_ENUM_TO_STRING(TRANSMISSION_KBPS); STAT_ENUM_TO_STRING(RETRANSMISSION_KBPS); STAT_ENUM_TO_STRING(MS_SINCE_LAST_RECEIVER_RESPONSE); STAT_ENUM_TO_STRING(NUM_FRAMES_CAPTURED); STAT_ENUM_TO_STRING(NUM_FRAMES_DROPPED_BY_ENCODER); STAT_ENUM_TO_STRING(NUM_FRAMES_LATE); STAT_ENUM_TO_STRING(NUM_PACKETS_SENT); STAT_ENUM_TO_STRING(NUM_PACKETS_RETRANSMITTED); STAT_ENUM_TO_STRING(NUM_PACKETS_RECEIVED); STAT_ENUM_TO_STRING(NUM_PACKETS_RTX_REJECTED); STAT_ENUM_TO_STRING(FIRST_EVENT_TIME_MS); STAT_ENUM_TO_STRING(LAST_EVENT_TIME_MS); STAT_ENUM_TO_STRING(CAPTURE_LATENCY_MS_HISTO); STAT_ENUM_TO_STRING(ENCODE_TIME_MS_HISTO); STAT_ENUM_TO_STRING(QUEUEING_LATENCY_MS_HISTO); STAT_ENUM_TO_STRING(NETWORK_LATENCY_MS_HISTO); STAT_ENUM_TO_STRING(PACKET_LATENCY_MS_HISTO); STAT_ENUM_TO_STRING(FRAME_LATENCY_MS_HISTO); STAT_ENUM_TO_STRING(E2E_LATENCY_MS_HISTO); STAT_ENUM_TO_STRING(LATE_FRAME_MS_HISTO); } NOTREACHED(); return ""; } const int kDefaultMaxLatencyBucketMs = 800; const int kDefaultBucketWidthMs = 20; // For small latency values. const int kSmallMaxLatencyBucketMs = 100; const int kSmallBucketWidthMs = 5; // For large latency values. const int kLargeMaxLatencyBucketMs = 1200; const int kLargeBucketWidthMs = 50; void StatsEventSubscriber::InitHistograms() { histograms_[E2E_LATENCY_MS_HISTO].reset( new SimpleHistogram(0, kLargeMaxLatencyBucketMs, kLargeBucketWidthMs)); histograms_[QUEUEING_LATENCY_MS_HISTO].reset( new SimpleHistogram(0, kDefaultMaxLatencyBucketMs, kDefaultBucketWidthMs)); histograms_[NETWORK_LATENCY_MS_HISTO].reset( new SimpleHistogram(0, kDefaultMaxLatencyBucketMs, kDefaultBucketWidthMs)); histograms_[PACKET_LATENCY_MS_HISTO].reset( new SimpleHistogram(0, kDefaultMaxLatencyBucketMs, kDefaultBucketWidthMs)); histograms_[FRAME_LATENCY_MS_HISTO].reset( new SimpleHistogram(0, kDefaultMaxLatencyBucketMs, kDefaultBucketWidthMs)); histograms_[LATE_FRAME_MS_HISTO].reset( new SimpleHistogram(0, kDefaultMaxLatencyBucketMs, kDefaultBucketWidthMs)); histograms_[CAPTURE_LATENCY_MS_HISTO].reset( new SimpleHistogram(0, kSmallMaxLatencyBucketMs, kSmallBucketWidthMs)); histograms_[ENCODE_TIME_MS_HISTO].reset( new SimpleHistogram(0, kSmallMaxLatencyBucketMs, kSmallBucketWidthMs)); } void StatsEventSubscriber::GetStatsInternal(StatsMap* stats_map) const { DCHECK(thread_checker_.CalledOnValidThread()); stats_map->clear(); base::TimeTicks end_time = clock_->NowTicks(); PopulateFpsStat( end_time, FRAME_CAPTURE_BEGIN, CAPTURE_FPS, stats_map); PopulateFpsStat( end_time, FRAME_ENCODED, ENCODE_FPS, stats_map); PopulateFpsStat( end_time, FRAME_DECODED, DECODE_FPS, stats_map); PopulateFrameBitrateStat(end_time, stats_map); PopulatePacketBitrateStat(end_time, PACKET_SENT_TO_NETWORK, TRANSMISSION_KBPS, stats_map); PopulatePacketBitrateStat(end_time, PACKET_RETRANSMITTED, RETRANSMISSION_KBPS, stats_map); PopulateFrameCountStat(FRAME_CAPTURE_END, NUM_FRAMES_CAPTURED, stats_map); PopulatePacketCountStat(PACKET_SENT_TO_NETWORK, NUM_PACKETS_SENT, stats_map); PopulatePacketCountStat( PACKET_RETRANSMITTED, NUM_PACKETS_RETRANSMITTED, stats_map); PopulatePacketCountStat(PACKET_RECEIVED, NUM_PACKETS_RECEIVED, stats_map); PopulatePacketCountStat( PACKET_RTX_REJECTED, NUM_PACKETS_RTX_REJECTED, stats_map); if (capture_latency_datapoints_ > 0) { double avg_capture_latency_ms = total_capture_latency_.InMillisecondsF() / capture_latency_datapoints_; stats_map->insert( std::make_pair(AVG_CAPTURE_LATENCY_MS, avg_capture_latency_ms)); } if (encode_time_datapoints_ > 0) { double avg_encode_time_ms = total_encode_time_.InMillisecondsF() / encode_time_datapoints_; stats_map->insert( std::make_pair(AVG_ENCODE_TIME_MS, avg_encode_time_ms)); } if (queueing_latency_datapoints_ > 0) { double avg_queueing_latency_ms = total_queueing_latency_.InMillisecondsF() / queueing_latency_datapoints_; stats_map->insert( std::make_pair(AVG_QUEUEING_LATENCY_MS, avg_queueing_latency_ms)); } if (network_latency_datapoints_ > 0) { double avg_network_latency_ms = total_network_latency_.InMillisecondsF() / network_latency_datapoints_; stats_map->insert( std::make_pair(AVG_NETWORK_LATENCY_MS, avg_network_latency_ms)); } if (packet_latency_datapoints_ > 0) { double avg_packet_latency_ms = total_packet_latency_.InMillisecondsF() / packet_latency_datapoints_; stats_map->insert( std::make_pair(AVG_PACKET_LATENCY_MS, avg_packet_latency_ms)); } if (frame_latency_datapoints_ > 0) { double avg_frame_latency_ms = total_frame_latency_.InMillisecondsF() / frame_latency_datapoints_; stats_map->insert( std::make_pair(AVG_FRAME_LATENCY_MS, avg_frame_latency_ms)); } if (e2e_latency_datapoints_ > 0) { double avg_e2e_latency_ms = total_e2e_latency_.InMillisecondsF() / e2e_latency_datapoints_; stats_map->insert(std::make_pair(AVG_E2E_LATENCY_MS, avg_e2e_latency_ms)); } if (!last_response_received_time_.is_null()) { stats_map->insert( std::make_pair(MS_SINCE_LAST_RECEIVER_RESPONSE, (end_time - last_response_received_time_).InMillisecondsF())); } stats_map->insert(std::make_pair(NUM_FRAMES_DROPPED_BY_ENCODER, num_frames_dropped_by_encoder_)); stats_map->insert(std::make_pair(NUM_FRAMES_LATE, num_frames_late_)); if (!first_event_time_.is_null()) { stats_map->insert(std::make_pair( FIRST_EVENT_TIME_MS, (first_event_time_ - base::TimeTicks::UnixEpoch()).InMillisecondsF())); } if (!last_event_time_.is_null()) { stats_map->insert(std::make_pair( LAST_EVENT_TIME_MS, (last_event_time_ - base::TimeTicks::UnixEpoch()).InMillisecondsF())); } } StatsEventSubscriber::SimpleHistogram* StatsEventSubscriber::GetHistogramForTesting( CastStat stats) const { DCHECK(histograms_.find(stats) != histograms_.end()); return histograms_.find(stats)->second.get(); } bool StatsEventSubscriber::GetReceiverOffset(base::TimeDelta* offset) { base::TimeDelta receiver_offset_lower_bound; base::TimeDelta receiver_offset_upper_bound; if (!offset_estimator_->GetReceiverOffsetBounds( &receiver_offset_lower_bound, &receiver_offset_upper_bound)) { return false; } *offset = (receiver_offset_lower_bound + receiver_offset_upper_bound) / 2; return true; } void StatsEventSubscriber::MaybeInsertFrameInfo(RtpTimeTicks rtp_timestamp, const FrameInfo& frame_info) { // No need to insert if |rtp_timestamp| is the smaller than every key in the // map as it is just going to get erased anyway. if (recent_frame_infos_.size() == kMaxFrameInfoMapSize && rtp_timestamp < recent_frame_infos_.begin()->first) { return; } recent_frame_infos_.insert(std::make_pair(rtp_timestamp, frame_info)); if (recent_frame_infos_.size() >= kMaxFrameInfoMapSize) { FrameInfoMap::iterator erase_it = recent_frame_infos_.begin(); if (erase_it->second.encode_end_time.is_null()) num_frames_dropped_by_encoder_++; recent_frame_infos_.erase(erase_it); } } void StatsEventSubscriber::RecordFrameCaptureTime( const FrameEvent& frame_event) { FrameInfo frame_info; frame_info.capture_time = frame_event.timestamp; MaybeInsertFrameInfo(frame_event.rtp_timestamp, frame_info); } void StatsEventSubscriber::RecordCaptureLatency(const FrameEvent& frame_event) { FrameInfoMap::iterator it = recent_frame_infos_.find(frame_event.rtp_timestamp); if (it == recent_frame_infos_.end()) { return; } if (!it->second.capture_time.is_null()) { base::TimeDelta latency = frame_event.timestamp - it->second.capture_time; total_capture_latency_ += latency; capture_latency_datapoints_++; histograms_[CAPTURE_LATENCY_MS_HISTO]->Add(latency.InMillisecondsF()); } it->second.capture_end_time = frame_event.timestamp; } void StatsEventSubscriber::RecordEncodeLatency(const FrameEvent& frame_event) { FrameInfoMap::iterator it = recent_frame_infos_.find(frame_event.rtp_timestamp); if (it == recent_frame_infos_.end()) { FrameInfo frame_info; frame_info.encode_end_time = frame_event.timestamp; MaybeInsertFrameInfo(frame_event.rtp_timestamp, frame_info); return; } if (!it->second.capture_end_time.is_null()) { base::TimeDelta latency = frame_event.timestamp - it->second.capture_end_time; total_encode_time_ += latency; encode_time_datapoints_++; histograms_[ENCODE_TIME_MS_HISTO]->Add(latency.InMillisecondsF()); } it->second.encode_end_time = frame_event.timestamp; } void StatsEventSubscriber::RecordFrameTxLatency(const FrameEvent& frame_event) { FrameInfoMap::iterator it = recent_frame_infos_.find(frame_event.rtp_timestamp); if (it == recent_frame_infos_.end()) return; if (it->second.encode_end_time.is_null()) return; base::TimeDelta receiver_offset; if (!GetReceiverOffset(&receiver_offset)) return; base::TimeTicks sender_time = frame_event.timestamp - receiver_offset; base::TimeDelta latency = sender_time - it->second.encode_end_time; total_frame_latency_ += latency; frame_latency_datapoints_++; histograms_[FRAME_LATENCY_MS_HISTO]->Add(latency.InMillisecondsF()); } void StatsEventSubscriber::RecordE2ELatency(const FrameEvent& frame_event) { base::TimeDelta receiver_offset; if (!GetReceiverOffset(&receiver_offset)) return; FrameInfoMap::iterator it = recent_frame_infos_.find(frame_event.rtp_timestamp); if (it == recent_frame_infos_.end()) return; base::TimeTicks playout_time = frame_event.timestamp - receiver_offset; base::TimeDelta latency = playout_time - it->second.capture_time; total_e2e_latency_ += latency; e2e_latency_datapoints_++; histograms_[E2E_LATENCY_MS_HISTO]->Add(latency.InMillisecondsF()); } void StatsEventSubscriber::UpdateLastResponseTime( base::TimeTicks receiver_time) { base::TimeDelta receiver_offset; if (!GetReceiverOffset(&receiver_offset)) return; base::TimeTicks sender_time = receiver_time - receiver_offset; last_response_received_time_ = sender_time; } void StatsEventSubscriber::ErasePacketSentTime( const PacketEvent& packet_event) { std::pair key( std::make_pair(packet_event.rtp_timestamp, packet_event.packet_id)); packet_sent_times_.erase(key); } void StatsEventSubscriber::RecordPacketRelatedLatencies( const PacketEvent& packet_event) { // Log queueing latency. if (packet_event.type == PACKET_SENT_TO_NETWORK) { FrameInfoMap::iterator it = recent_frame_infos_.find(packet_event.rtp_timestamp); if (it != recent_frame_infos_.end()) { base::TimeDelta latency = packet_event.timestamp - it->second.encode_end_time; total_queueing_latency_ += latency; queueing_latency_datapoints_++; histograms_[QUEUEING_LATENCY_MS_HISTO]->Add( latency.InMillisecondsF()); } } // Log network latency and total packet latency; base::TimeDelta receiver_offset; if (!GetReceiverOffset(&receiver_offset)) return; std::pair key( std::make_pair(packet_event.rtp_timestamp, packet_event.packet_id)); PacketEventTimeMap::iterator it = packet_sent_times_.find(key); if (it == packet_sent_times_.end()) { std::pair value = std::make_pair(packet_event.timestamp, packet_event.type); packet_sent_times_.insert(std::make_pair(key, value)); if (packet_sent_times_.size() > kMaxPacketEventTimeMapSize) packet_sent_times_.erase(packet_sent_times_.begin()); } else { std::pair value = it->second; CastLoggingEvent recorded_type = value.second; bool match = false; base::TimeTicks packet_sent_time; base::TimeTicks packet_received_time; if (recorded_type == PACKET_SENT_TO_NETWORK && packet_event.type == PACKET_RECEIVED) { packet_sent_time = value.first; packet_received_time = packet_event.timestamp; match = true; } else if (recorded_type == PACKET_RECEIVED && packet_event.type == PACKET_SENT_TO_NETWORK) { packet_sent_time = packet_event.timestamp; packet_received_time = value.first; match = true; } if (match) { packet_sent_times_.erase(it); // Subtract by offset. packet_received_time -= receiver_offset; base::TimeDelta latency_delta = packet_received_time - packet_sent_time; total_network_latency_ += latency_delta; network_latency_datapoints_++; histograms_[NETWORK_LATENCY_MS_HISTO]->Add( latency_delta.InMillisecondsF()); // Log total network latency. FrameInfoMap::iterator frame_it = recent_frame_infos_.find(packet_event.rtp_timestamp); if (frame_it != recent_frame_infos_.end()) { base::TimeDelta latency = packet_received_time - frame_it->second.encode_end_time; total_packet_latency_ += latency; packet_latency_datapoints_++; histograms_[PACKET_LATENCY_MS_HISTO]->Add( latency.InMillisecondsF()); } } } } void StatsEventSubscriber::PopulateFpsStat(base::TimeTicks end_time, CastLoggingEvent event, CastStat stat, StatsMap* stats_map) const { FrameStatsMap::const_iterator it = frame_stats_.find(event); if (it != frame_stats_.end()) { double fps = 0.0; base::TimeDelta duration = (end_time - start_time_); int count = it->second.event_counter; if (duration > base::TimeDelta()) fps = count / duration.InSecondsF(); stats_map->insert(std::make_pair(stat, fps)); } } void StatsEventSubscriber::PopulateFrameCountStat(CastLoggingEvent event, CastStat stat, StatsMap* stats_map) const { FrameStatsMap::const_iterator it = frame_stats_.find(event); if (it != frame_stats_.end()) { stats_map->insert(std::make_pair(stat, it->second.event_counter)); } } void StatsEventSubscriber::PopulatePacketCountStat(CastLoggingEvent event, CastStat stat, StatsMap* stats_map) const { PacketStatsMap::const_iterator it = packet_stats_.find(event); if (it != packet_stats_.end()) { stats_map->insert(std::make_pair(stat, it->second.event_counter)); } } void StatsEventSubscriber::PopulateFrameBitrateStat(base::TimeTicks end_time, StatsMap* stats_map) const { FrameStatsMap::const_iterator it = frame_stats_.find(FRAME_ENCODED); if (it != frame_stats_.end()) { double kbps = 0.0; base::TimeDelta duration = end_time - start_time_; if (duration > base::TimeDelta()) { kbps = it->second.sum_size / duration.InMillisecondsF() * 8; } stats_map->insert(std::make_pair(ENCODE_KBPS, kbps)); } } void StatsEventSubscriber::PopulatePacketBitrateStat( base::TimeTicks end_time, CastLoggingEvent event, CastStat stat, StatsMap* stats_map) const { PacketStatsMap::const_iterator it = packet_stats_.find(event); if (it != packet_stats_.end()) { double kbps = 0; base::TimeDelta duration = end_time - start_time_; if (duration > base::TimeDelta()) { kbps = it->second.sum_size / duration.InMillisecondsF() * 8; } stats_map->insert(std::make_pair(stat, kbps)); } } StatsEventSubscriber::FrameLogStats::FrameLogStats() : event_counter(0), sum_size(0) {} StatsEventSubscriber::FrameLogStats::~FrameLogStats() {} StatsEventSubscriber::PacketLogStats::PacketLogStats() : event_counter(0), sum_size(0) {} StatsEventSubscriber::PacketLogStats::~PacketLogStats() {} StatsEventSubscriber::FrameInfo::FrameInfo() : encoded(false) { } StatsEventSubscriber::FrameInfo::~FrameInfo() { } } // namespace cast } // namespace media