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/*
* Copyright (c) 2017-2019 Cisco and/or its affiliates.
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at:
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#include <hicn/transport/core/global_object_pool.h>
#include <hicn/transport/interfaces/socket_consumer.h>
#include <implementation/socket_consumer.h>
#include <math.h>
#include <protocols/rtc/rtc.h>
#include <protocols/rtc/rtc_consts.h>
#include <protocols/rtc/rtc_rc_queue.h>
#include <algorithm>
namespace transport {
namespace protocol {
namespace rtc {
using namespace interface;
RTCTransportProtocol::RTCTransportProtocol(
implementation::ConsumerSocket *icn_socket)
: TransportProtocol(icn_socket, nullptr),
DatagramReassembly(icn_socket, this),
number_(0) {
icn_socket->getSocketOption(PORTAL, portal_);
round_timer_ = std::make_unique<asio::steady_timer>(portal_->getIoService());
scheduler_timer_ =
std::make_unique<asio::steady_timer>(portal_->getIoService());
}
RTCTransportProtocol::~RTCTransportProtocol() {}
void RTCTransportProtocol::resume() {
if (is_running_) return;
is_running_ = true;
newRound();
portal_->runEventsLoop();
is_running_ = false;
}
// private
void RTCTransportProtocol::initParams() {
portal_->setConsumerCallback(this);
rc_ = std::make_shared<RTCRateControlQueue>();
ldr_ = std::make_shared<RTCLossDetectionAndRecovery>(
std::bind(&RTCTransportProtocol::sendRtxInterest, this,
std::placeholders::_1),
portal_->getIoService());
state_ = std::make_shared<RTCState>(
std::bind(&RTCTransportProtocol::sendProbeInterest, this,
std::placeholders::_1),
std::bind(&RTCTransportProtocol::discoveredRtt, this),
portal_->getIoService());
rc_->setState(state_);
// TODO: for the moment we keep the congestion control disabled
// rc_->tunrOnRateControl();
ldr_->setState(state_);
// protocol state
start_send_interest_ = false;
current_state_ = SyncState::catch_up;
// Cancel timer
number_++;
round_timer_->cancel();
scheduler_timer_->cancel();
scheduler_timer_on_ = false;
// delete all timeouts and future nacks
timeouts_or_nacks_.clear();
// cwin vars
current_sync_win_ = INITIAL_WIN;
max_sync_win_ = INITIAL_WIN_MAX;
// names/packets var
next_segment_ = 0;
socket_->setSocketOption(GeneralTransportOptions::INTEREST_LIFETIME,
RTC_INTEREST_LIFETIME);
}
// private
void RTCTransportProtocol::reset() {
TRANSPORT_LOGD("reset called");
initParams();
newRound();
}
void RTCTransportProtocol::inactiveProducer() {
// when the producer is inactive we reset the consumer state
// cwin vars
current_sync_win_ = INITIAL_WIN;
max_sync_win_ = INITIAL_WIN_MAX;
TRANSPORT_LOGD("Current window: %u, max_sync_win_: %u", current_sync_win_,
max_sync_win_);
// names/packets var
next_segment_ = 0;
ldr_->clear();
}
void RTCTransportProtocol::newRound() {
round_timer_->expires_from_now(std::chrono::milliseconds(ROUND_LEN));
// TODO pass weak_ptr here
round_timer_->async_wait([this, n{number_}](std::error_code ec) {
if (ec) return;
if (n != number_) {
return;
}
// saving counters that will be reset on new round
uint32_t sent_retx = state_->getSentRtxInRound();
uint32_t received_bytes = state_->getReceivedBytesInRound();
uint32_t sent_interest = state_->getSentInterestInRound();
uint32_t lost_data = state_->getLostData();
uint32_t recovered_losses = state_->getRecoveredLosses();
uint32_t received_nacks = state_->getReceivedNacksInRound();
bool in_sync = (current_state_ == SyncState::in_sync);
state_->onNewRound((double)ROUND_LEN, in_sync);
rc_->onNewRound((double)ROUND_LEN);
// update sync state if needed
if (current_state_ == SyncState::in_sync) {
double cache_rate = state_->getPacketFromCacheRatio();
if (cache_rate > MAX_DATA_FROM_CACHE) {
current_state_ = SyncState::catch_up;
}
} else {
double target_rate = state_->getProducerRate() * PRODUCTION_RATE_FRACTION;
double received_rate = state_->getReceivedRate();
uint32_t round_without_nacks = state_->getRoundsWithoutNacks();
double cache_ratio = state_->getPacketFromCacheRatio();
if (round_without_nacks >= ROUNDS_IN_SYNC_BEFORE_SWITCH &&
received_rate >= target_rate && cache_ratio < MAX_DATA_FROM_CACHE) {
current_state_ = SyncState::in_sync;
}
}
TRANSPORT_LOGD("Calling updateSyncWindow in newRound function");
updateSyncWindow();
sendStatsToApp(sent_retx, received_bytes, sent_interest, lost_data,
recovered_losses, received_nacks);
newRound();
});
}
void RTCTransportProtocol::discoveredRtt() {
start_send_interest_ = true;
ldr_->turnOnRTX();
updateSyncWindow();
}
void RTCTransportProtocol::computeMaxSyncWindow() {
double production_rate = state_->getProducerRate();
double packet_size = state_->getAveragePacketSize();
if (production_rate == 0.0 || packet_size == 0.0) {
// the consumer has no info about the producer,
// keep the previous maxCWin
TRANSPORT_LOGD(
"Returning in computeMaxSyncWindow because: prod_rate: %d || "
"packet_size: %d",
(int)(production_rate == 0.0), (int)(packet_size == 0.0));
return;
}
uint32_t lifetime = default_values::interest_lifetime;
socket_->getSocketOption(GeneralTransportOptions::INTEREST_LIFETIME,
lifetime);
double lifetime_ms = (double)lifetime / MILLI_IN_A_SEC;
max_sync_win_ =
(uint32_t)ceil((production_rate * lifetime_ms *
INTEREST_LIFETIME_REDUCTION_FACTOR) / packet_size);
max_sync_win_ = std::min(max_sync_win_, rc_->getCongesionWindow());
}
void RTCTransportProtocol::updateSyncWindow() {
computeMaxSyncWindow();
if (max_sync_win_ == INITIAL_WIN_MAX) {
if (TRANSPORT_EXPECT_FALSE(!state_->isProducerActive())) return;
current_sync_win_ = INITIAL_WIN;
scheduleNextInterests();
return;
}
double prod_rate = state_->getProducerRate();
double rtt = (double)state_->getRTT() / MILLI_IN_A_SEC;
double packet_size = state_->getAveragePacketSize();
// if some of the info are not available do not update the current win
if (prod_rate != 0.0 && rtt != 0.0 && packet_size != 0.0) {
current_sync_win_ = (uint32_t)ceil(prod_rate * rtt / packet_size);
current_sync_win_ += (uint32_t)
ceil(prod_rate * (PRODUCER_BUFFER_MS / MILLI_IN_A_SEC) / packet_size);
if(current_state_ == SyncState::catch_up) {
current_sync_win_ = (uint32_t) (current_sync_win_ * CATCH_UP_WIN_INCREMENT);
}
current_sync_win_ = std::min(current_sync_win_, max_sync_win_);
current_sync_win_ = std::max(current_sync_win_, WIN_MIN);
}
scheduleNextInterests();
}
void RTCTransportProtocol::decreaseSyncWindow() {
// called on future nack
// we have a new sample of the production rate, so update max win first
computeMaxSyncWindow();
current_sync_win_--;
current_sync_win_ = std::max(current_sync_win_, WIN_MIN);
scheduleNextInterests();
}
void RTCTransportProtocol::sendInterest(Name *interest_name) {
TRANSPORT_LOGD("Sending interest for name %s",
interest_name->toString().c_str());
auto interest = core::PacketManager<>::getInstance().getPacket<Interest>();
interest->setName(*interest_name);
uint32_t lifetime = default_values::interest_lifetime;
socket_->getSocketOption(GeneralTransportOptions::INTEREST_LIFETIME,
lifetime);
interest->setLifetime(uint32_t(lifetime));
if (*on_interest_output_) {
(*on_interest_output_)(*socket_->getInterface(), *interest);
}
if (TRANSPORT_EXPECT_FALSE(!is_running_ && !is_first_)) {
return;
}
portal_->sendInterest(std::move(interest));
}
void RTCTransportProtocol::sendRtxInterest(uint32_t seq) {
if (!is_running_ && !is_first_) return;
if(!start_send_interest_) return;
Name *interest_name = nullptr;
socket_->getSocketOption(GeneralTransportOptions::NETWORK_NAME,
&interest_name);
TRANSPORT_LOGD("send rtx %u", seq);
interest_name->setSuffix(seq);
sendInterest(interest_name);
}
void RTCTransportProtocol::sendProbeInterest(uint32_t seq) {
if (!is_running_ && !is_first_) return;
Name *interest_name = nullptr;
socket_->getSocketOption(GeneralTransportOptions::NETWORK_NAME,
&interest_name);
TRANSPORT_LOGD("send probe %u", seq);
interest_name->setSuffix(seq);
sendInterest(interest_name);
}
void RTCTransportProtocol::scheduleNextInterests() {
TRANSPORT_LOGD("Schedule next interests");
if (!is_running_ && !is_first_) return;
if(!start_send_interest_) return; // RTT discovering phase is not finished so
// do not start to send interests
if (scheduler_timer_on_) return; // wait befor send other interests
if (TRANSPORT_EXPECT_FALSE(!state_->isProducerActive())) {
TRANSPORT_LOGD("Inactive producer.");
// here we keep seding the same interest until the producer
// does not start again
if (next_segment_ != 0) {
// the producer just become inactive, reset the state
inactiveProducer();
}
Name *interest_name = nullptr;
socket_->getSocketOption(GeneralTransportOptions::NETWORK_NAME,
&interest_name);
TRANSPORT_LOGD("send interest %u", next_segment_);
interest_name->setSuffix(next_segment_);
if (portal_->interestIsPending(*interest_name)) {
// if interest 0 is already pending we return
return;
}
sendInterest(interest_name);
state_->onSendNewInterest(interest_name);
return;
}
TRANSPORT_LOGD("Pending interest number: %d -- current_sync_win_: %d",
state_->getPendingInterestNumber(), current_sync_win_);
// skip nacked pacekts
if (next_segment_ <= state_->getLastSeqNacked()) {
next_segment_ = state_->getLastSeqNacked() + 1;
}
// skipe received packets
if (next_segment_ <= state_->getHighestSeqReceivedInOrder()) {
next_segment_ = state_->getHighestSeqReceivedInOrder() + 1;
}
uint32_t sent_interests = 0;
while ((state_->getPendingInterestNumber() < current_sync_win_) &&
(sent_interests < MAX_INTERESTS_IN_BATCH)) {
TRANSPORT_LOGD("In while loop. Window size: %u", current_sync_win_);
Name *interest_name = nullptr;
socket_->getSocketOption(GeneralTransportOptions::NETWORK_NAME,
&interest_name);
interest_name->setSuffix(next_segment_);
// send the packet only if:
// 1) it is not pending yet (not true for rtx)
// 2) the packet is not received or lost
// 3) is not in the rtx list
if (portal_->interestIsPending(*interest_name) ||
state_->isReceivedOrLost(next_segment_) != PacketState::UNKNOWN ||
ldr_->isRtx(next_segment_)) {
TRANSPORT_LOGD(
"skip interest %u because: pending %u, recv %u, rtx %u",
next_segment_, (portal_->interestIsPending(*interest_name)),
(state_->isReceivedOrLost(next_segment_) != PacketState::UNKNOWN),
(ldr_->isRtx(next_segment_)));
next_segment_ = (next_segment_ + 1) % MIN_PROBE_SEQ;
continue;
}
sent_interests++;
TRANSPORT_LOGD("send interest %u", next_segment_);
sendInterest(interest_name);
state_->onSendNewInterest(interest_name);
next_segment_ = (next_segment_ + 1) % MIN_PROBE_SEQ;
}
if (state_->getPendingInterestNumber() < current_sync_win_) {
// we still have space in the window but we already sent a batch of
// MAX_INTERESTS_IN_BATCH interest. for the following ones wait one
// WAIT_BETWEEN_INTEREST_BATCHES to avoid local packets drop
scheduler_timer_on_ = true;
scheduler_timer_->expires_from_now(
std::chrono::microseconds(WAIT_BETWEEN_INTEREST_BATCHES));
scheduler_timer_->async_wait([this](std::error_code ec) {
if (ec) return;
if (!scheduler_timer_on_) return;
scheduler_timer_on_ = false;
scheduleNextInterests();
});
}
}
void RTCTransportProtocol::onTimeout(Interest::Ptr &&interest) {
uint32_t segment_number = interest->getName().getSuffix();
TRANSPORT_LOGD("timeout for packet %u", segment_number);
if (segment_number >= MIN_PROBE_SEQ) {
// this is a timeout on a probe, do nothing
return;
}
timeouts_or_nacks_.insert(segment_number);
if (TRANSPORT_EXPECT_TRUE(state_->isProducerActive()) &&
segment_number <= state_->getHighestSeqReceivedInOrder()) {
// we retransmit packets only if the producer is active, otherwise we
// use timeouts to avoid to send too much traffic
//
// a timeout is sent using RTX only if it is an old packet. if it is for a
// seq number that we didn't reach yet, we send the packet using the normal
// schedule next interest
TRANSPORT_LOGD("handle timeout for packet %u using rtx", segment_number);
ldr_->onTimeout(segment_number);
state_->onTimeout(segment_number);
scheduleNextInterests();
return;
}
TRANSPORT_LOGD("handle timeout for packet %u using normal interests",
segment_number);
if (segment_number < next_segment_) {
// this is a timeout for a packet that will be generated in the future but
// we are asking for higher sequence numbers. we need to go back like in the
// case of future nacks
TRANSPORT_LOGD("on timeout next seg = %u, jump to %u",
next_segment_, segment_number);
next_segment_ = segment_number;
}
state_->onTimeout(segment_number);
scheduleNextInterests();
}
void RTCTransportProtocol::onNack(const ContentObject &content_object) {
struct nack_packet_t *nack =
(struct nack_packet_t *)content_object.getPayload()->data();
uint32_t production_seg = nack->getProductionSegement();
uint32_t nack_segment = content_object.getName().getSuffix();
bool is_rtx = ldr_->isRtx(nack_segment);
// check if the packet got a timeout
TRANSPORT_LOGD("Nack received %u. Production segment: %u", nack_segment,
production_seg);
bool compute_stats = true;
auto tn_it = timeouts_or_nacks_.find(nack_segment);
if (tn_it != timeouts_or_nacks_.end() || is_rtx) {
compute_stats = false;
// remove packets from timeouts_or_nacks only in case of a past nack
}
state_->onNackPacketReceived(content_object, compute_stats);
ldr_->onNackPacketReceived(content_object);
// both in case of past and future nack we set next_segment_ equal to the
// production segment in the nack. In case of past nack we will skip unneded
// interest (this is already done in the scheduleNextInterest in any case)
// while in case of future nacks we can go back in time and ask again for the
// content that generated the nack
TRANSPORT_LOGD("on nack next seg = %u, jump to %u",
next_segment_, production_seg);
next_segment_ = production_seg;
if (production_seg > nack_segment) {
// remove the nack is it exists
if (tn_it != timeouts_or_nacks_.end()) timeouts_or_nacks_.erase(tn_it);
// the client is asking for content in the past
// switch to catch up state and increase the window
// this is true only if the packet is not an RTX
if (!is_rtx) current_state_ = SyncState::catch_up;
updateSyncWindow();
} else {
// if production_seg == nack_segment we consider this a future nack, since
// production_seg is not yet created. this may happen in case of low
// production rate (e.g. ping at 1pps)
// if a future nack was also retransmitted add it to the timeout_or_nacks
// set
if (is_rtx) timeouts_or_nacks_.insert(nack_segment);
// the client is asking for content in the future
// switch to in sync state and decrease the window
current_state_ = SyncState::in_sync;
decreaseSyncWindow();
}
}
void RTCTransportProtocol::onProbe(const ContentObject &content_object) {
bool valid = state_->onProbePacketReceived(content_object);
if(!valid) return;
struct nack_packet_t *probe =
(struct nack_packet_t *)content_object.getPayload()->data();
uint32_t production_seg = probe->getProductionSegement();
// as for the nacks set next_segment_
TRANSPORT_LOGD("on probe next seg = %u, jump to %u",
next_segment_, production_seg);
next_segment_ = production_seg;
ldr_->onProbePacketReceived(content_object);
updateSyncWindow();
}
void RTCTransportProtocol::onContentObject(Interest &interest,
ContentObject &content_object) {
TRANSPORT_LOGD("Received content object of size: %zu",
content_object.payloadSize());
uint32_t payload_size = (uint32_t) content_object.payloadSize();
uint32_t segment_number = content_object.getName().getSuffix();
if (segment_number >= MIN_PROBE_SEQ) {
TRANSPORT_LOGD("Received probe %u", segment_number);
if (*on_content_object_input_) {
(*on_content_object_input_)(*socket_->getInterface(), content_object);
}
onProbe(content_object);
return;
}
if (payload_size == NACK_HEADER_SIZE) {
TRANSPORT_LOGD("Received nack %u", segment_number);
if (*on_content_object_input_) {
(*on_content_object_input_)(*socket_->getInterface(), content_object);
}
onNack(content_object);
return;
}
TRANSPORT_LOGD("Received content %u", segment_number);
rc_->onDataPacketReceived(content_object);
bool compute_stats = true;
auto tn_it = timeouts_or_nacks_.find(segment_number);
if (tn_it != timeouts_or_nacks_.end()) {
compute_stats = false;
timeouts_or_nacks_.erase(tn_it);
}
if (ldr_->isRtx(segment_number)) {
compute_stats = false;
}
// check if the packet was already received
PacketState state = state_->isReceivedOrLost(segment_number);
state_->onDataPacketReceived(content_object, compute_stats);
ldr_->onDataPacketReceived(content_object);
// if the stat for this seq number is received do not send the packet to app
if (state != PacketState::RECEIVED) {
if (*on_content_object_input_) {
(*on_content_object_input_)(*socket_->getInterface(), content_object);
}
reassemble(content_object);
} else {
TRANSPORT_LOGD("Received duplicated content %u, drop it", segment_number);
}
updateSyncWindow();
}
void RTCTransportProtocol::sendStatsToApp(
uint32_t retx_count, uint32_t received_bytes, uint32_t sent_interests,
uint32_t lost_data, uint32_t recovered_losses, uint32_t received_nacks) {
if (*stats_summary_) {
// Send the stats to the app
stats_->updateQueuingDelay(state_->getQueuing());
// stats_->updateInterestFecTx(0); //todo must be implemented
// stats_->updateBytesFecRecv(0); //todo must be implemented
stats_->updateRetxCount(retx_count);
stats_->updateBytesRecv(received_bytes);
stats_->updateInterestTx(sent_interests);
stats_->updateReceivedNacks(received_nacks);
stats_->updateAverageWindowSize(current_sync_win_);
stats_->updateLossRatio(state_->getLossRate());
stats_->updateAverageRtt(state_->getRTT());
stats_->updateLostData(lost_data);
stats_->updateRecoveredData(recovered_losses);
stats_->updateCCState((unsigned int)current_state_ ? 1 : 0);
(*stats_summary_)(*socket_->getInterface(), *stats_);
}
}
void RTCTransportProtocol::reassemble(ContentObject &content_object) {
auto read_buffer = content_object.getPayload();
TRANSPORT_LOGD("Size of payload: %zu", read_buffer->length());
read_buffer->trimStart(DATA_HEADER_SIZE);
Reassembly::read_buffer_ = std::move(read_buffer);
Reassembly::notifyApplication();
}
} // end namespace rtc
} // end namespace protocol
} // end namespace transport
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