/* * 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/network/cross_traffic.h" #include #include #include "absl/memory/memory.h" #include "absl/types/optional.h" #include "cross_traffic.h" #include "rtc_base/logging.h" #include "rtc_base/numerics/safe_minmax.h" namespace webrtc { namespace test { RandomWalkCrossTraffic::RandomWalkCrossTraffic(RandomWalkConfig config, CrossTrafficRoute* traffic_route) : config_(config), traffic_route_(traffic_route), random_(config_.random_seed) { sequence_checker_.Detach(); } RandomWalkCrossTraffic::~RandomWalkCrossTraffic() = default; void RandomWalkCrossTraffic::Process(Timestamp at_time) { RTC_DCHECK_RUN_ON(&sequence_checker_); if (last_process_time_.IsMinusInfinity()) { last_process_time_ = at_time; } TimeDelta delta = at_time - last_process_time_; last_process_time_ = at_time; if (at_time - last_update_time_ >= config_.update_interval) { intensity_ += random_.Gaussian(config_.bias, config_.variance) * sqrt((at_time - last_update_time_).seconds()); intensity_ = rtc::SafeClamp(intensity_, 0.0, 1.0); last_update_time_ = at_time; } pending_size_ += TrafficRate() * delta; if (pending_size_ >= config_.min_packet_size && at_time >= last_send_time_ + config_.min_packet_interval) { traffic_route_->SendPacket(pending_size_.bytes()); pending_size_ = DataSize::Zero(); last_send_time_ = at_time; } } TimeDelta RandomWalkCrossTraffic::GetProcessInterval() const { return config_.min_packet_interval; } DataRate RandomWalkCrossTraffic::TrafficRate() const { RTC_DCHECK_RUN_ON(&sequence_checker_); return config_.peak_rate * intensity_; } ColumnPrinter RandomWalkCrossTraffic::StatsPrinter() { return ColumnPrinter::Lambda( "random_walk_cross_traffic_rate", [this](rtc::SimpleStringBuilder& sb) { sb.AppendFormat("%.0lf", TrafficRate().bps() / 8.0); }, 32); } PulsedPeaksCrossTraffic::PulsedPeaksCrossTraffic( PulsedPeaksConfig config, CrossTrafficRoute* traffic_route) : config_(config), traffic_route_(traffic_route) { sequence_checker_.Detach(); } PulsedPeaksCrossTraffic::~PulsedPeaksCrossTraffic() = default; void PulsedPeaksCrossTraffic::Process(Timestamp at_time) { RTC_DCHECK_RUN_ON(&sequence_checker_); TimeDelta time_since_toggle = at_time - last_update_time_; if (time_since_toggle.IsInfinite() || (sending_ && time_since_toggle >= config_.send_duration)) { sending_ = false; last_update_time_ = at_time; } else if (!sending_ && time_since_toggle >= config_.hold_duration) { sending_ = true; last_update_time_ = at_time; // Start sending period. last_send_time_ = at_time; } if (sending_) { DataSize pending_size = config_.peak_rate * (at_time - last_send_time_); if (pending_size >= config_.min_packet_size && at_time >= last_send_time_ + config_.min_packet_interval) { traffic_route_->SendPacket(pending_size.bytes()); last_send_time_ = at_time; } } } TimeDelta PulsedPeaksCrossTraffic::GetProcessInterval() const { return config_.min_packet_interval; } DataRate PulsedPeaksCrossTraffic::TrafficRate() const { RTC_DCHECK_RUN_ON(&sequence_checker_); return sending_ ? config_.peak_rate : DataRate::Zero(); } ColumnPrinter PulsedPeaksCrossTraffic::StatsPrinter() { return ColumnPrinter::Lambda( "pulsed_peaks_cross_traffic_rate", [this](rtc::SimpleStringBuilder& sb) { sb.AppendFormat("%.0lf", TrafficRate().bps() / 8.0); }, 32); } TcpMessageRouteImpl::TcpMessageRouteImpl(Clock* clock, TaskQueueBase* task_queue, EmulatedRoute* send_route, EmulatedRoute* ret_route) : clock_(clock), task_queue_(task_queue), request_route_(send_route, [this](TcpPacket packet, Timestamp) { OnRequest(std::move(packet)); }), response_route_(ret_route, [this](TcpPacket packet, Timestamp arrival_time) { OnResponse(std::move(packet), arrival_time); }) {} void TcpMessageRouteImpl::SendMessage(size_t size, std::function on_received) { task_queue_->PostTask( [this, size, handler = std::move(on_received)] { // If we are currently sending a message we won't reset the connection, // we'll act as if the messages are sent in the same TCP stream. This is // intended to simulate recreation of a TCP session for each message // in the typical case while avoiding the complexity overhead of // maintaining multiple virtual TCP sessions in parallel. if (pending_.empty() && in_flight_.empty()) { cwnd_ = 10; ssthresh_ = INFINITY; } int64_t data_left = static_cast(size); int64_t kMaxPacketSize = 1200; int64_t kMinPacketSize = 4; Message message{std::move(handler)}; while (data_left > 0) { int64_t packet_size = std::min(data_left, kMaxPacketSize); int fragment_id = next_fragment_id_++; pending_.push_back(MessageFragment{ fragment_id, static_cast(std::max(kMinPacketSize, packet_size))}); message.pending_fragment_ids.insert(fragment_id); data_left -= packet_size; } messages_.emplace_back(message); SendPackets(clock_->CurrentTime()); }); } void TcpMessageRouteImpl::OnRequest(TcpPacket packet_info) { for (auto it = messages_.begin(); it != messages_.end(); ++it) { if (it->pending_fragment_ids.count(packet_info.fragment.fragment_id) != 0) { it->pending_fragment_ids.erase(packet_info.fragment.fragment_id); if (it->pending_fragment_ids.empty()) { it->handler(); messages_.erase(it); } break; } } const size_t kAckPacketSize = 20; response_route_.SendPacket(kAckPacketSize, packet_info); } void TcpMessageRouteImpl::OnResponse(TcpPacket packet_info, Timestamp at_time) { auto it = in_flight_.find(packet_info.sequence_number); if (it != in_flight_.end()) { last_rtt_ = at_time - packet_info.send_time; in_flight_.erase(it); } auto lost_end = in_flight_.lower_bound(packet_info.sequence_number); for (auto lost_it = in_flight_.begin(); lost_it != lost_end; lost_it = in_flight_.erase(lost_it)) { pending_.push_front(lost_it->second.fragment); } if (packet_info.sequence_number - last_acked_seq_num_ > 1) { HandleLoss(at_time); } else if (cwnd_ <= ssthresh_) { cwnd_ += 1; } else { cwnd_ += 1.0f / cwnd_; } last_acked_seq_num_ = std::max(packet_info.sequence_number, last_acked_seq_num_); SendPackets(at_time); } void TcpMessageRouteImpl::HandleLoss(Timestamp at_time) { if (at_time - last_reduction_time_ < last_rtt_) return; last_reduction_time_ = at_time; ssthresh_ = std::max(static_cast(in_flight_.size() / 2), 2); cwnd_ = ssthresh_; } void TcpMessageRouteImpl::SendPackets(Timestamp at_time) { const TimeDelta kPacketTimeout = TimeDelta::Seconds(1); int cwnd = std::ceil(cwnd_); int packets_to_send = std::max(cwnd - static_cast(in_flight_.size()), 0); while (packets_to_send-- > 0 && !pending_.empty()) { auto seq_num = next_sequence_number_++; TcpPacket send; send.sequence_number = seq_num; send.send_time = at_time; send.fragment = pending_.front(); pending_.pop_front(); request_route_.SendPacket(send.fragment.size, send); in_flight_.insert({seq_num, send}); task_queue_->PostDelayedTask( [this, seq_num] { HandlePacketTimeout(seq_num, clock_->CurrentTime()); }, kPacketTimeout); } } void TcpMessageRouteImpl::HandlePacketTimeout(int seq_num, Timestamp at_time) { auto lost = in_flight_.find(seq_num); if (lost != in_flight_.end()) { pending_.push_front(lost->second.fragment); in_flight_.erase(lost); HandleLoss(at_time); SendPackets(at_time); } } FakeTcpCrossTraffic::FakeTcpCrossTraffic(FakeTcpConfig config, EmulatedRoute* send_route, EmulatedRoute* ret_route) : conf_(config), route_(this, send_route, ret_route) {} TimeDelta FakeTcpCrossTraffic::GetProcessInterval() const { return conf_.process_interval; } void FakeTcpCrossTraffic::Process(Timestamp at_time) { SendPackets(at_time); } void FakeTcpCrossTraffic::OnRequest(int sequence_number, Timestamp at_time) { const size_t kAckPacketSize = 20; route_.SendResponse(kAckPacketSize, sequence_number); } void FakeTcpCrossTraffic::OnResponse(int sequence_number, Timestamp at_time) { ack_received_ = true; auto it = in_flight_.find(sequence_number); if (it != in_flight_.end()) { last_rtt_ = at_time - in_flight_.at(sequence_number); in_flight_.erase(sequence_number); } if (sequence_number - last_acked_seq_num_ > 1) { HandleLoss(at_time); } else if (cwnd_ <= ssthresh_) { cwnd_ += 1; } else { cwnd_ += 1.0f / cwnd_; } last_acked_seq_num_ = std::max(sequence_number, last_acked_seq_num_); SendPackets(at_time); } void FakeTcpCrossTraffic::HandleLoss(Timestamp at_time) { if (at_time - last_reduction_time_ < last_rtt_) return; last_reduction_time_ = at_time; ssthresh_ = std::max(static_cast(in_flight_.size() / 2), 2); cwnd_ = ssthresh_; } void FakeTcpCrossTraffic::SendPackets(Timestamp at_time) { int cwnd = std::ceil(cwnd_); int packets_to_send = std::max(cwnd - static_cast(in_flight_.size()), 0); bool timeouts = false; for (auto it = in_flight_.begin(); it != in_flight_.end();) { if (it->second < at_time - conf_.packet_timeout) { it = in_flight_.erase(it); timeouts = true; } else { ++it; } } if (timeouts) HandleLoss(at_time); for (int i = 0; i < packets_to_send; ++i) { if ((total_sent_ + conf_.packet_size) > conf_.send_limit) { break; } in_flight_.insert({next_sequence_number_, at_time}); route_.SendRequest(conf_.packet_size.bytes(), next_sequence_number_++); total_sent_ += conf_.packet_size; } } } // namespace test } // namespace webrtc