219 lines
5.4 KiB
C++
219 lines
5.4 KiB
C++
#include "./flow_only.hpp"
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#include <cmath>
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#include <cassert>
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#include <iostream>
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#include <algorithm>
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float FlowOnly::getCurrentDelay(void) const {
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// below 1ms is useless
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return std::clamp(_rtt_ema, 0.001f, RTT_MAX);
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}
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void FlowOnly::addRTT(float new_delay) {
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if (new_delay > _rtt_ema * RTT_UP_MAX) {
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// too large a jump up, to be taken into account
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return;
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}
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// lerp(new_delay, rtt_ema, 0.1)
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_rtt_ema = RTT_EMA_ALPHA * new_delay + (1.f - RTT_EMA_ALPHA) * _rtt_ema;
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}
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void FlowOnly::updateWindow(void) {
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const float current_delay {getCurrentDelay()};
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_fwnd = max_byterate_allowed * current_delay;
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//_fwnd *= 1.3f; // try do balance conservative algo a bit, current_delay
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_fwnd = std::max(_fwnd, 2.f * MAXIMUM_SEGMENT_DATA_SIZE);
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}
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void FlowOnly::updateCongestion(void) {
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const auto tmp_window = getWindow();
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// packet window * 0.3
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// but atleast 4
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int32_t max_consecutive_events = std::clamp<int32_t>(
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(tmp_window/MAXIMUM_SEGMENT_DATA_SIZE) * 0.3f,
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4,
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50 // limit TODO: fix idle/time starved algo
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);
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// TODO: magic number
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#if 0
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std::cout << "NGC_FT1 Flow: pkg out of order"
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<< " w:" << tmp_window
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<< " pw:" << tmp_window/MAXIMUM_SEGMENT_DATA_SIZE
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<< " coe:" << _consecutive_events
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<< " mcoe:" << max_consecutive_events
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<< "\n";
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#endif
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if (_consecutive_events > max_consecutive_events) {
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//std::cout << "CONGESTION! NGC_FT1 flow: pkg out of order\n";
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onCongestion();
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// TODO: set _consecutive_events to zero?
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}
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}
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float FlowOnly::getWindow(void) {
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updateWindow();
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return _fwnd;
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}
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int64_t FlowOnly::canSend(float time_delta) {
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if (_in_flight.empty()) {
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assert(_in_flight_bytes == 0);
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return MAXIMUM_SEGMENT_DATA_SIZE;
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}
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updateWindow();
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int64_t fspace = _fwnd - _in_flight_bytes;
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if (fspace < MAXIMUM_SEGMENT_DATA_SIZE) {
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return 0u;
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}
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// also limit to max sendrate per tick, which is usually smaller than window
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// this is mostly to prevent spikes on empty windows
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fspace = std::min<int64_t>(fspace, max_byterate_allowed * time_delta + 0.5f);
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// limit to whole packets
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return (fspace / MAXIMUM_SEGMENT_DATA_SIZE) * MAXIMUM_SEGMENT_DATA_SIZE;
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}
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std::vector<FlowOnly::SeqIDType> FlowOnly::getTimeouts(void) const {
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std::vector<SeqIDType> list;
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// after 3 rtt delay, we trigger timeout
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const auto now_adjusted = getTimeNow() - getCurrentDelay()*3.f;
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for (const auto& [seq, time_stamp, size, _] : _in_flight) {
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if (now_adjusted > time_stamp) {
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list.push_back(seq);
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}
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}
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return list;
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}
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int64_t FlowOnly::inFlightCount(void) const {
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return _in_flight.size();
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}
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void FlowOnly::onSent(SeqIDType seq, size_t data_size) {
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if constexpr (true) {
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for (const auto& it : _in_flight) {
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assert(it.id != seq);
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}
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}
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const auto& new_entry = _in_flight.emplace_back(
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FlyingBunch{
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seq,
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static_cast<float>(getTimeNow()),
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data_size + SEGMENT_OVERHEAD,
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false
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}
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);
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_in_flight_bytes += new_entry.bytes;
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_time_point_last_update = getTimeNow();
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}
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void FlowOnly::onAck(std::vector<SeqIDType> seqs) {
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if (seqs.empty()) {
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assert(false && "got empty list of acks???");
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return;
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}
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const auto now {getTimeNow()};
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_time_point_last_update = now;
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// first seq in seqs is the actual value, all extra are for redundency
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{ // skip in ack is congestion event
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// 1. look at primary ack of packet
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auto it = std::find_if(_in_flight.begin(), _in_flight.end(), [seq = seqs.front()](const auto& v) -> bool {
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return v.id == seq;
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});
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if (it != _in_flight.end() && !it->ignore) {
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// find first non ignore, it should be the expected
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auto first_it = std::find_if_not(_in_flight.cbegin(), _in_flight.cend(), [](const auto& v) -> bool { return v.ignore; });
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if (first_it != _in_flight.cend() && it != first_it) {
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// not next expected seq -> skip detected
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_consecutive_events++;
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it->ignore = true; // only handle once
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updateCongestion();
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} else {
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// only mesure delay, if not a congestion
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addRTT(now - it->timestamp);
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_consecutive_events = 0;
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}
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} else { // TOOD: if ! ignore too
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// !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
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#if 0
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// assume we got a duplicated packet
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std::cout << "CONGESTION duplicate\n";
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onCongestion();
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#endif
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}
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}
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for (const auto& seq : seqs) {
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auto it = std::find_if(_in_flight.begin(), _in_flight.end(), [seq](const auto& v) -> bool {
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return v.id == seq;
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});
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if (it == _in_flight.end()) {
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continue; // not found, ignore
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} else {
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//most_recent = std::max(most_recent, std::get<1>(*it));
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_in_flight_bytes -= it->bytes;
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assert(_in_flight_bytes >= 0);
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//_recently_acked_data += std::get<2>(*it);
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_in_flight.erase(it);
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}
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}
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}
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void FlowOnly::onLoss(SeqIDType seq, bool discard) {
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auto it = std::find_if(_in_flight.begin(), _in_flight.end(), [seq](const auto& v) -> bool {
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assert(!std::isnan(v.timestamp));
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return v.id == seq;
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});
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if (it == _in_flight.end()) {
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// error
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return; // not found, ignore ??
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}
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//std::cerr << "FLOW loss\n";
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// "if data lost is not to be retransmitted"
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if (discard) {
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_in_flight_bytes -= it->bytes;
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assert(_in_flight_bytes >= 0);
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_in_flight.erase(it);
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} else {
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// and not take into rtt
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it->timestamp = getTimeNow();
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it->ignore = true;
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}
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// usually after data arrived out-of-order/duplicate
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if (!it->ignore) {
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it->ignore = true; // only handle once
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//_consecutive_events++;
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//updateCongestion();
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// this is usually a safe indicator for congestion/maxed connection
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onCongestion();
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}
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}
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