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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 <implementation/socket_producer.h>
#include <protocols/prod_protocol_rtc.h>
#include <protocols/rtc/rtc_consts.h>
#include <stdlib.h>
#include <time.h>
#include <unordered_set>
namespace transport {
namespace protocol {
RTCProductionProtocol::RTCProductionProtocol(
implementation::ProducerSocket *icn_socket)
: ProductionProtocol(icn_socket),
current_seg_(1),
produced_bytes_(0),
produced_packets_(0),
max_packet_production_(1),
bytes_production_rate_(0),
packets_production_rate_(0),
last_round_(std::chrono::duration_cast<std::chrono::milliseconds>(
std::chrono::steady_clock::now().time_since_epoch())
.count()),
allow_delayed_nacks_(false),
queue_timer_on_(false),
consumer_in_sync_(false),
on_consumer_in_sync_(nullptr) {
srand((unsigned int)time(NULL));
prod_label_ = rand() % 256;
interests_queue_timer_ =
std::make_unique<asio::steady_timer>(portal_->getIoService());
round_timer_ = std::make_unique<asio::steady_timer>(portal_->getIoService());
setOutputBufferSize(10000);
scheduleRoundTimer();
}
RTCProductionProtocol::~RTCProductionProtocol() {}
void RTCProductionProtocol::registerNamespaceWithNetwork(
const Prefix &producer_namespace) {
ProductionProtocol::registerNamespaceWithNetwork(producer_namespace);
flow_name_ = producer_namespace.getName();
auto family = flow_name_.getAddressFamily();
switch (family) {
case AF_INET6:
header_size_ = (uint32_t)Packet::getHeaderSizeFromFormat(HF_INET6_TCP);
break;
case AF_INET:
header_size_ = (uint32_t)Packet::getHeaderSizeFromFormat(HF_INET_TCP);
break;
default:
throw errors::RuntimeException("Unknown name format.");
}
}
void RTCProductionProtocol::scheduleRoundTimer() {
round_timer_->expires_from_now(
std::chrono::milliseconds(rtc::PRODUCER_STATS_INTERVAL));
round_timer_->async_wait([this](std::error_code ec) {
if (ec) return;
updateStats();
});
}
void RTCProductionProtocol::updateStats() {
uint64_t now = std::chrono::duration_cast<std::chrono::milliseconds>(
std::chrono::steady_clock::now().time_since_epoch())
.count();
uint64_t duration = now - last_round_;
if (duration == 0) duration = 1;
double per_second = rtc::MILLI_IN_A_SEC / duration;
uint32_t prev_packets_production_rate = packets_production_rate_;
bytes_production_rate_ = ceil((double)produced_bytes_ * per_second);
packets_production_rate_ = ceil((double)produced_packets_ * per_second);
TRANSPORT_LOGD("Updating production rate: produced_bytes_ = %u bps = %u",
produced_bytes_, bytes_production_rate_);
// update the production rate as soon as it increases by 10% with respect to
// the last round
max_packet_production_ =
produced_packets_ + ceil((double)produced_packets_ * 0.1);
if (max_packet_production_ < rtc::WIN_MIN)
max_packet_production_ = rtc::WIN_MIN;
if (packets_production_rate_ != 0) {
allow_delayed_nacks_ = false;
} else if (prev_packets_production_rate == 0) {
// at least 2 rounds with production rate = 0
allow_delayed_nacks_ = true;
}
// check if the production rate is decreased. if yes send nacks if needed
if (prev_packets_production_rate < packets_production_rate_) {
sendNacksForPendingInterests();
}
produced_bytes_ = 0;
produced_packets_ = 0;
last_round_ = now;
scheduleRoundTimer();
}
uint32_t RTCProductionProtocol::produceStream(
const Name &content_name, std::unique_ptr<utils::MemBuf> &&buffer,
bool is_last, uint32_t start_offset) {
throw errors::NotImplementedException();
}
uint32_t RTCProductionProtocol::produceStream(const Name &content_name,
const uint8_t *buffer,
size_t buffer_size, bool is_last,
uint32_t start_offset) {
throw errors::NotImplementedException();
}
void RTCProductionProtocol::produce(ContentObject &content_object) {
throw errors::NotImplementedException();
}
uint32_t RTCProductionProtocol::produceDatagram(
const Name &content_name, std::unique_ptr<utils::MemBuf> &&buffer) {
std::size_t buffer_size = buffer->length();
if (TRANSPORT_EXPECT_FALSE(buffer_size == 0)) return 0;
uint32_t data_packet_size;
socket_->getSocketOption(interface::GeneralTransportOptions::DATA_PACKET_SIZE,
data_packet_size);
if (TRANSPORT_EXPECT_FALSE((buffer_size + header_size_ +
rtc::DATA_HEADER_SIZE) > data_packet_size)) {
return 0;
}
auto content_object =
core::PacketManager<>::getInstance().getPacket<ContentObject>();
// add rtc header to the payload
struct rtc::data_packet_t header;
content_object->appendPayload((const uint8_t *)&header,
rtc::DATA_HEADER_SIZE);
content_object->appendPayload(buffer->data(), buffer->length());
std::shared_ptr<ContentObject> co = std::move(content_object);
// schedule actual sending on internal thread
portal_->getIoService().dispatch(
[this, content_object{std::move(co)}, content_name]() mutable {
produceInternal(std::move(content_object), content_name);
});
return 1;
}
void RTCProductionProtocol::produceInternal(
std::shared_ptr<ContentObject> &&content_object, const Name &content_name) {
// set rtc header
struct rtc::data_packet_t *data_pkt =
(struct rtc::data_packet_t *)content_object->getPayload()->data();
uint64_t now = std::chrono::duration_cast<std::chrono::milliseconds>(
std::chrono::steady_clock::now().time_since_epoch())
.count();
data_pkt->setTimestamp(now);
data_pkt->setProductionRate(bytes_production_rate_);
// set hicn stuff
Name n(content_name);
content_object->setName(n.setSuffix(current_seg_));
content_object->setLifetime(500); // XXX this should be set by the APP
content_object->setPathLabel(prod_label_);
// update stats
produced_bytes_ +=
content_object->headerSize() + content_object->payloadSize();
produced_packets_++;
if (produced_packets_ >= max_packet_production_) {
// in this case all the pending interests may be used to accomodate the
// sudden increase in the production rate. calling the updateStats we will
// notify all the clients
round_timer_->cancel();
updateStats();
}
TRANSPORT_LOGD("Sending content object: %s", n.toString().c_str());
output_buffer_.insert(content_object);
if (*on_content_object_in_output_buffer_) {
on_content_object_in_output_buffer_->operator()(*socket_->getInterface(),
*content_object);
}
portal_->sendContentObject(*content_object);
if (*on_content_object_output_) {
on_content_object_output_->operator()(*socket_->getInterface(),
*content_object);
}
// remove interests from the interest cache if it exists
removeFromInterestQueue(current_seg_);
current_seg_ = (current_seg_ + 1) % rtc::MIN_PROBE_SEQ;
}
void RTCProductionProtocol::onInterest(Interest &interest) {
uint32_t interest_seg = interest.getName().getSuffix();
uint32_t lifetime = interest.getLifetime();
if (interest_seg == 0) {
// first packet from the consumer, reset sync state
consumer_in_sync_ = false;
}
if (*on_interest_input_) {
on_interest_input_->operator()(*socket_->getInterface(), interest);
}
uint64_t now = std::chrono::duration_cast<std::chrono::milliseconds>(
std::chrono::steady_clock::now().time_since_epoch())
.count();
if (interest_seg > rtc::MIN_PROBE_SEQ) {
TRANSPORT_LOGD("received probe %u", interest_seg);
sendNack(interest_seg);
return;
}
TRANSPORT_LOGD("received interest %u", interest_seg);
const std::shared_ptr<ContentObject> content_object =
output_buffer_.find(interest);
if (content_object) {
if (*on_interest_satisfied_output_buffer_) {
on_interest_satisfied_output_buffer_->operator()(*socket_->getInterface(),
interest);
}
if (*on_content_object_output_) {
on_content_object_output_->operator()(*socket_->getInterface(),
*content_object);
}
TRANSPORT_LOGD("Send content %u (onInterest)",
content_object->getName().getSuffix());
portal_->sendContentObject(*content_object);
return;
} else {
if (*on_interest_process_) {
on_interest_process_->operator()(*socket_->getInterface(), interest);
}
}
// if the production rate 0 use delayed nacks
if (allow_delayed_nacks_ && interest_seg >= current_seg_) {
uint64_t next_timer = ~0;
if (!timers_map_.empty()) {
next_timer = timers_map_.begin()->first;
}
uint64_t expiration = now + rtc::SENTINEL_TIMER_INTERVAL;
addToInterestQueue(interest_seg, expiration);
// here we have at least one interest in the queue, we need to start or
// update the timer
if (!queue_timer_on_) {
// set timeout
queue_timer_on_ = true;
scheduleQueueTimer(timers_map_.begin()->first - now);
} else {
// re-schedule the timer because a new interest will expires sooner
if (next_timer > timers_map_.begin()->first) {
interests_queue_timer_->cancel();
scheduleQueueTimer(timers_map_.begin()->first - now);
}
}
return;
}
if (queue_timer_on_) {
// the producer is producing. Send nacks to packets that will expire before
// the data production and remove the timer
queue_timer_on_ = false;
interests_queue_timer_->cancel();
sendNacksForPendingInterests();
}
uint32_t max_gap = (uint32_t)floor(
(double)((double)((double)lifetime *
rtc::INTEREST_LIFETIME_REDUCTION_FACTOR /
rtc::MILLI_IN_A_SEC) *
(double)packets_production_rate_));
if (interest_seg < current_seg_ || interest_seg > (max_gap + current_seg_)) {
sendNack(interest_seg);
} else {
if (!consumer_in_sync_ && on_consumer_in_sync_) {
// we consider the remote consumer to be in sync as soon as it covers 70%
// of the production window with interests
uint32_t perc = ceil((double)max_gap * 0.7);
if (interest_seg > (perc + current_seg_)) {
consumer_in_sync_ = true;
on_consumer_in_sync_(*socket_->getInterface(), interest);
}
}
uint64_t expiration =
now + floor((double)lifetime * rtc::INTEREST_LIFETIME_REDUCTION_FACTOR);
addToInterestQueue(interest_seg, expiration);
}
}
void RTCProductionProtocol::onError(std::error_code ec) {}
void RTCProductionProtocol::scheduleQueueTimer(uint64_t wait) {
interests_queue_timer_->expires_from_now(std::chrono::milliseconds(wait));
interests_queue_timer_->async_wait([this](std::error_code ec) {
if (ec) return;
interestQueueTimer();
});
}
void RTCProductionProtocol::addToInterestQueue(uint32_t interest_seg,
uint64_t expiration) {
// check if the seq number exists already
auto it_seqs = seqs_map_.find(interest_seg);
if (it_seqs != seqs_map_.end()) {
// the seq already exists
if (expiration < it_seqs->second) {
// we need to update the timer becasue we got a smaller one
// 1) remove the entry from the multimap
// 2) update this entry
auto range = timers_map_.equal_range(it_seqs->second);
for (auto it_timers = range.first; it_timers != range.second;
it_timers++) {
if (it_timers->second == it_seqs->first) {
timers_map_.erase(it_timers);
break;
}
}
timers_map_.insert(
std::pair<uint64_t, uint32_t>(expiration, interest_seg));
it_seqs->second = expiration;
} else {
// nothing to do here
return;
}
} else {
// add the new seq
timers_map_.insert(std::pair<uint64_t, uint32_t>(expiration, interest_seg));
seqs_map_.insert(std::pair<uint32_t, uint64_t>(interest_seg, expiration));
}
}
void RTCProductionProtocol::sendNacksForPendingInterests() {
std::unordered_set<uint32_t> to_remove;
uint32_t packet_gap = 100000; // set it to a high value (100sec)
if (packets_production_rate_ != 0)
packet_gap = ceil(rtc::MILLI_IN_A_SEC / (double)packets_production_rate_);
uint64_t now = std::chrono::duration_cast<std::chrono::milliseconds>(
std::chrono::steady_clock::now().time_since_epoch())
.count();
for (auto it = seqs_map_.begin(); it != seqs_map_.end(); it++) {
if (it->first > current_seg_) {
uint64_t production_time =
((it->first - current_seg_) * packet_gap) + now;
if (production_time >= it->second) {
sendNack(it->first);
to_remove.insert(it->first);
}
}
}
// delete nacked interests
for (auto it = to_remove.begin(); it != to_remove.end(); it++) {
removeFromInterestQueue(*it);
}
}
void RTCProductionProtocol::removeFromInterestQueue(uint32_t interest_seg) {
auto seq_it = seqs_map_.find(interest_seg);
if (seq_it != seqs_map_.end()) {
auto range = timers_map_.equal_range(seq_it->second);
for (auto it_timers = range.first; it_timers != range.second; it_timers++) {
if (it_timers->second == seq_it->first) {
timers_map_.erase(it_timers);
break;
}
}
seqs_map_.erase(seq_it);
}
}
void RTCProductionProtocol::interestQueueTimer() {
uint64_t now = std::chrono::duration_cast<std::chrono::milliseconds>(
std::chrono::steady_clock::now().time_since_epoch())
.count();
for (auto it_timers = timers_map_.begin(); it_timers != timers_map_.end();) {
uint64_t expire = it_timers->first;
if (expire <= now) {
uint32_t seq = it_timers->second;
sendNack(seq);
// remove the interest from the other map
seqs_map_.erase(seq);
it_timers = timers_map_.erase(it_timers);
} else {
// stop, we are done!
break;
}
}
if (timers_map_.empty()) {
queue_timer_on_ = false;
} else {
queue_timer_on_ = true;
scheduleQueueTimer(timers_map_.begin()->first - now);
}
}
void RTCProductionProtocol::sendNack(uint32_t sequence) {
auto nack = core::PacketManager<>::getInstance().getPacket<ContentObject>();
uint64_t now = std::chrono::duration_cast<std::chrono::milliseconds>(
std::chrono::steady_clock::now().time_since_epoch())
.count();
uint32_t next_packet = current_seg_;
uint32_t prod_rate = bytes_production_rate_;
struct rtc::nack_packet_t header;
header.setTimestamp(now);
header.setProductionRate(prod_rate);
header.setProductionSegement(next_packet);
nack->appendPayload((const uint8_t *)&header, rtc::NACK_HEADER_SIZE);
Name n(flow_name_);
n.setSuffix(sequence);
nack->setName(n);
nack->setLifetime(0);
nack->setPathLabel(prod_label_);
if (!consumer_in_sync_ && on_consumer_in_sync_ &&
sequence < rtc::MIN_PROBE_SEQ && sequence > next_packet) {
consumer_in_sync_ = true;
auto interest = core::PacketManager<>::getInstance().getPacket<Interest>();
interest->setName(n);
on_consumer_in_sync_(*socket_->getInterface(), *interest);
}
if (*on_content_object_output_) {
on_content_object_output_->operator()(*socket_->getInterface(), *nack);
}
TRANSPORT_LOGD("Send nack %u", sequence);
portal_->sendContentObject(*nack);
}
} // namespace protocol
} // end namespace transport
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