solanaceae_ngc_ft1/solanaceae/ngc_ft1/ngcft1.cpp

816 lines
22 KiB
C++

#include "./ngcft1.hpp"
#include "./flow_only.hpp"
#include "./cubic.hpp"
#include "./ledbat.hpp"
#include <solanaceae/util/utils.hpp>
#include <sodium.h>
#include <cstdint>
#include <iostream>
#include <set>
#include <algorithm>
#include <cassert>
#include <vector>
void NGCFT1::updateSendTransfer(float time_delta, uint32_t group_number, uint32_t peer_number, Group::Peer& peer, size_t idx, std::set<CCAI::SeqIDType>& timeouts_set, int64_t& can_packet_size) {
auto& tf_opt = peer.send_transfers.at(idx);
assert(tf_opt.has_value());
auto& tf = tf_opt.value();
tf.time_since_activity += time_delta;
switch (tf.state) {
using State = Group::Peer::SendTransfer::State;
case State::INIT_SENT:
if (tf.time_since_activity >= init_retry_timeout_after) {
if (tf.inits_sent >= 3) {
// delete, timed out 3 times
std::cerr << "NGCFT1 warning: ft init timed out, deleting\n";
dispatch(
NGCFT1_Event::send_done,
Events::NGCFT1_send_done{
group_number, peer_number,
static_cast<uint8_t>(idx),
}
);
tf_opt.reset();
} else {
// timed out, resend
std::cerr << "NGCFT1 warning: ft init timed out, resending\n";
//sendPKG_FT1_INIT(group_number, peer_number, tf.file_kind, tf.file_size, idx, tf.file_id.data(), tf.file_id.size());
_neep.send_ft1_init(group_number, peer_number, tf.file_kind, tf.file_size, idx, tf.file_id.data(), tf.file_id.size());
tf.inits_sent++;
tf.time_since_activity = 0.f;
}
}
//break;
return;
case State::FINISHING: // we still have unacked packets
tf.ssb.for_each(time_delta, [&](uint16_t id, const std::vector<uint8_t>& data, float& time_since_activity) {
if (can_packet_size >= data.size() && timeouts_set.count({idx, id})) {
_neep.send_ft1_data(group_number, peer_number, idx, id, data.data(), data.size());
peer.cca->onLoss({idx, id}, false);
time_since_activity = 0.f;
timeouts_set.erase({idx, id});
can_packet_size -= data.size();
}
});
if (tf.time_since_activity >= sending_give_up_after) {
// no ack after 30sec, close ft
std::cerr << "NGCFT1 warning: sending ft finishing timed out, deleting\n";
dispatch(
NGCFT1_Event::send_done,
Events::NGCFT1_send_done{
group_number, peer_number,
static_cast<uint8_t>(idx),
}
);
// clean up cca
tf.ssb.for_each(time_delta, [&](uint16_t id, const std::vector<uint8_t>& data, float& time_since_activity) {
peer.cca->onLoss({idx, id}, true);
timeouts_set.erase({idx, id});
});
tf_opt.reset();
}
break;
case State::SENDING: {
// first handle overall timeout (could otherwise do resends directly before, which is useless)
// timeout increases with active transfers (otherwise we could starve them)
if (tf.time_since_activity >= (sending_give_up_after * peer.active_send_transfers)) {
// no ack after 30sec, close ft
std::cerr << "NGCFT1 warning: sending ft in progress timed out, deleting (ifc:" << peer.cca->inFlightCount() << ")\n";
dispatch(
NGCFT1_Event::send_done,
Events::NGCFT1_send_done{
group_number, peer_number,
static_cast<uint8_t>(idx),
}
);
// clean up cca
tf.ssb.for_each(time_delta, [&](uint16_t id, const std::vector<uint8_t>& data, float& time_since_activity) {
peer.cca->onLoss({idx, id}, true);
timeouts_set.erase({idx, id});
});
tf_opt.reset();
//continue; // dangerous control flow
return;
}
// do resends
tf.ssb.for_each(time_delta, [&](uint16_t id, const std::vector<uint8_t>& data, float& time_since_activity) {
if (can_packet_size >= data.size() && time_since_activity >= peer.cca->getCurrentDelay() && timeouts_set.count({idx, id})) {
// TODO: can fail
_neep.send_ft1_data(group_number, peer_number, idx, id, data.data(), data.size());
peer.cca->onLoss({idx, id}, false);
time_since_activity = 0.f;
timeouts_set.erase({idx, id});
can_packet_size -= data.size();
}
});
// if chunks in flight < window size (2)
while (can_packet_size > 0 && tf.file_size > 0) {
std::vector<uint8_t> new_data;
size_t chunk_size = std::min<size_t>({
peer.cca->MAXIMUM_SEGMENT_DATA_SIZE,
static_cast<size_t>(can_packet_size),
static_cast<size_t>(tf.file_size - tf.file_size_current),
});
if (chunk_size == 0) {
tf.state = State::FINISHING;
break; // we done
}
new_data.resize(chunk_size);
assert(idx <= 0xffu);
// TODO: check return value
dispatch(
NGCFT1_Event::send_data,
Events::NGCFT1_send_data{
group_number, peer_number,
static_cast<uint8_t>(idx),
tf.file_size_current,
new_data.data(), static_cast<uint32_t>(new_data.size()),
}
);
uint16_t seq_id = tf.ssb.add(std::move(new_data));
const bool sent = _neep.send_ft1_data(group_number, peer_number, idx, seq_id, tf.ssb.entries.at(seq_id).data.data(), tf.ssb.entries.at(seq_id).data.size());
if (sent) {
peer.cca->onSent({idx, seq_id}, chunk_size);
} else {
std::cerr << "NGCFT1: failed to send packet (queue full?) --------------\n";
peer.cca->onLoss({idx, seq_id}, false); // HACK: fake congestion event
// TODO: onCongestion
can_packet_size = 0;
}
tf.file_size_current += chunk_size;
can_packet_size -= chunk_size;
}
}
break;
default: // invalid state, delete
std::cerr << "NGCFT1 error: ft in invalid state, deleting\n";
assert(false && "ft in invalid state");
tf_opt.reset();
return;
}
}
void NGCFT1::iteratePeer(float time_delta, uint32_t group_number, uint32_t peer_number, Group::Peer& peer) {
if (peer.cca) {
auto timeouts = peer.cca->getTimeouts();
std::set<CCAI::SeqIDType> timeouts_set{timeouts.cbegin(), timeouts.cend()};
int64_t can_packet_size {peer.cca->canSend(time_delta)}; // might get more space while iterating (time)
// get number current running transfers TODO: improve
peer.active_send_transfers = 0;
for (const auto& it : peer.send_transfers) {
if (it.has_value()) {
peer.active_send_transfers++;
}
}
// change iterate start position to not starve transfers in the back
size_t iterated_count = 0;
bool last_send_found = false;
for (size_t idx = peer.next_send_transfer_send_idx; iterated_count < peer.send_transfers.size(); idx++, iterated_count++) {
idx = idx % peer.send_transfers.size();
if (peer.send_transfers.at(idx).has_value()) {
if (!last_send_found && can_packet_size <= 0) {
peer.next_send_transfer_send_idx = idx;
last_send_found = true; // only set once
}
updateSendTransfer(time_delta, group_number, peer_number, peer, idx, timeouts_set, can_packet_size);
}
}
}
//for (auto& transfer_opt : peer.recv_transfers) {
for (size_t idx = 0; idx < peer.recv_transfers.size(); idx++) {
if (!peer.recv_transfers.at(idx).has_value()) {
continue;
}
auto& transfer = peer.recv_transfers.at(idx).value();
// proper switch case?
if (transfer.state == Group::Peer::RecvTransfer::State::FINISHING) {
transfer.finishing_timer -= time_delta;
if (transfer.finishing_timer <= 0.f) {
//dispatch(
// NGCFT1_Event::recv_done,
// Events::NGCFT1_recv_done{
// group_number, peer_number,
// uint8_t(idx)
// }
//);
peer.recv_transfers.at(idx).reset();
}
}
}
}
const CCAI* NGCFT1::getPeerCCA(
uint32_t group_number,
uint32_t peer_number
) const {
auto group_it = groups.find(group_number);
if (group_it == groups.end()) {
return nullptr;;
}
auto peer_it = group_it->second.peers.find(peer_number);
if (peer_it == group_it->second.peers.end()) {
return nullptr;;
}
const auto& cca_ptr = peer_it->second.cca;
if (!cca_ptr) {
return nullptr;;
}
return cca_ptr.get();
}
NGCFT1::NGCFT1(
ToxI& t,
ToxEventProviderI& tep,
NGCEXTEventProvider& neep
) : _t(t), _tep(tep), _tep_sr(_tep.newSubRef(this)), _neep(neep), _neep_sr(_neep.newSubRef(this))
{
_neep_sr
.subscribe(NGCEXT_Event::FT1_REQUEST)
.subscribe(NGCEXT_Event::FT1_INIT)
.subscribe(NGCEXT_Event::FT1_INIT_ACK)
.subscribe(NGCEXT_Event::FT1_DATA)
.subscribe(NGCEXT_Event::FT1_DATA_ACK)
.subscribe(NGCEXT_Event::FT1_MESSAGE)
;
_tep_sr.subscribe(Tox_Event_Type::TOX_EVENT_GROUP_PEER_EXIT);
}
float NGCFT1::iterate(float time_delta) {
_time_since_activity += time_delta;
bool transfer_in_progress {false};
for (auto& [group_number, group] : groups) {
for (auto& [peer_number, peer] : group.peers) {
iteratePeer(time_delta, group_number, peer_number, peer);
// find any active transfer
if (!transfer_in_progress) {
for (const auto& t : peer.send_transfers) {
if (t.has_value()) {
transfer_in_progress = true;
break;
}
}
}
if (!transfer_in_progress) {
for (const auto& t : peer.recv_transfers) {
if (t.has_value()) {
transfer_in_progress = true;
break;
}
}
}
}
}
if (transfer_in_progress) {
_time_since_activity = 0.f;
// ~15ms for up to 1mb/s
// ~5ms for up to 4mb/s
return 0.005f; // 5ms
} else if (_time_since_activity < 0.5f) {
// bc of temporality
return 0.025f;
} else {
return 1.f; // once a sec might be too little
}
}
void NGCFT1::NGC_FT1_send_request_private(
uint32_t group_number, uint32_t peer_number,
uint32_t file_kind,
const uint8_t* file_id, uint32_t file_id_size
) {
// TODO: error check
_neep.send_ft1_request(group_number, peer_number, file_kind, file_id, file_id_size);
}
bool NGCFT1::NGC_FT1_send_init_private(
uint32_t group_number, uint32_t peer_number,
uint32_t file_kind,
const uint8_t* file_id, uint32_t file_id_size,
uint64_t file_size,
uint8_t* transfer_id,
bool can_compress
) {
if (std::get<0>(_t.toxGroupPeerGetConnectionStatus(group_number, peer_number)).value_or(TOX_CONNECTION_NONE) == TOX_CONNECTION_NONE) {
std::cerr << "NGCFT1 error: cant init ft, peer offline\n";
return false;
}
auto& peer = groups[group_number].peers[peer_number];
// allocate transfer_id
size_t idx = peer.next_send_transfer_idx;
peer.next_send_transfer_idx = (peer.next_send_transfer_idx + 1) % 256;
{ // TODO: extract
size_t i = idx;
bool found = false;
do {
if (!peer.send_transfers[i].has_value()) {
// free slot
idx = i;
found = true;
break;
}
i = (i + 1) % 256;
} while (i != idx);
if (!found) {
std::cerr << "NGCFT1 error: cant init ft, no free transfer slot\n";
return false;
}
idx = i;
}
// TODO: check return value
_neep.send_ft1_init(group_number, peer_number, file_kind, file_size, idx, file_id, file_id_size);
peer.send_transfers[idx] = Group::Peer::SendTransfer{
file_kind,
std::vector(file_id, file_id+file_id_size),
Group::Peer::SendTransfer::State::INIT_SENT,
1,
0.f,
file_size,
0,
{}, // ssb
};
if (transfer_id != nullptr) {
*transfer_id = idx;
}
return true;
}
bool NGCFT1::NGC_FT1_send_message_public(
uint32_t group_number,
uint32_t& message_id,
uint32_t file_kind,
const uint8_t* file_id, uint32_t file_id_size
) {
// create msg_id
message_id = randombytes_random();
// TODO: check return value
return _neep.send_all_ft1_message(group_number, message_id, file_kind, file_id, file_id_size);
}
float NGCFT1::getPeerDelay(uint32_t group_number, uint32_t peer_number) const {
auto* cca_ptr = getPeerCCA(group_number, peer_number);
if (cca_ptr == nullptr) {
return -1.f;
}
return cca_ptr->getCurrentDelay();
}
float NGCFT1::getPeerWindow(uint32_t group_number, uint32_t peer_number) const {
auto* cca_ptr = getPeerCCA(group_number, peer_number);
if (cca_ptr == nullptr) {
return -1.f;
}
return cca_ptr->getWindow();
}
int64_t NGCFT1::getPeerInFlightPackets(
uint32_t group_number,
uint32_t peer_number
) const {
auto* cca_ptr = getPeerCCA(group_number, peer_number);
if (cca_ptr == nullptr) {
return -1;
}
return cca_ptr->inFlightCount();
}
int64_t NGCFT1::getPeerInFlightBytes(
uint32_t group_number,
uint32_t peer_number
) const {
auto* cca_ptr = getPeerCCA(group_number, peer_number);
if (cca_ptr == nullptr) {
return -1;
}
return cca_ptr->inFlightCount();
}
bool NGCFT1::onEvent(const Events::NGCEXT_ft1_request& e) {
//#if !NDEBUG
std::cout << "NGCFT1: got FT1_REQUEST fk:" << e.file_kind << " [" << bin2hex(e.file_id) << "]\n";
//#endif
// .... just rethrow??
// TODO: dont
return dispatch(
NGCFT1_Event::recv_request,
Events::NGCFT1_recv_request{
e.group_number, e.peer_number,
static_cast<NGCFT1_file_kind>(e.file_kind),
e.file_id.data(), static_cast<uint32_t>(e.file_id.size())
}
);
}
bool NGCFT1::onEvent(const Events::NGCEXT_ft1_init& e) {
//#if !NDEBUG
std::cout << "NGCFT1: got FT1_INIT fk:" << e.file_kind << " fs:" << e.file_size << " tid:" << int(e.transfer_id) << " [" << bin2hex(e.file_id) << "]\n";
//#endif
#if 0
bool accept = false;
dispatch(
NGCFT1_Event::recv_init,
Events::NGCFT1_recv_init{
e.group_number, e.peer_number,
static_cast<NGCFT1_file_kind>(e.file_kind),
e.file_id.data(), static_cast<uint32_t>(e.file_id.size()),
e.transfer_id,
e.file_size,
accept
}
);
if (!accept) {
std::cout << "NGCFT1: rejected init\n";
return true; // return true?
}
_neep.send_ft1_init_ack(e.group_number, e.peer_number, e.transfer_id);
std::cout << "NGCFT1: accepted init\n";
auto& peer = groups[e.group_number].peers[e.peer_number];
if (peer.recv_transfers[e.transfer_id].has_value()) {
std::cerr << "NGCFT1 warning: overwriting existing recv_transfer " << int(e.transfer_id) << ", other peer started new transfer on preexising\n";
}
peer.recv_transfers[e.transfer_id] = Group::Peer::RecvTransfer{
e.file_kind,
e.file_id,
Group::Peer::RecvTransfer::State::INITED,
e.file_size,
0u,
{} // rsb
};
return true;
#else
// HACK: simply forward to init2 hanlder
return onEvent(Events::NGCEXT_ft1_init2{
e.group_number,
e.peer_number,
e.file_kind,
e.file_size,
e.transfer_id,
0x00, // non set
e.file_id, // sadly a copy, wont matter in the future
});
#endif
}
bool NGCFT1::onEvent(const Events::NGCEXT_ft1_init_ack& e) {
//#if !NDEBUG
std::cout << "NGCFT1: got FT1_INIT_ACK mds:" << e.max_lossy_data_size << "\n";
//#endif
// we now should start sending data
if (!groups.count(e.group_number)) {
std::cerr << "NGCFT1 warning: init_ack for unknown group\n";
return true;
}
Group::Peer& peer = groups[e.group_number].peers[e.peer_number];
if (!peer.send_transfers[e.transfer_id].has_value()) {
std::cerr << "NGCFT1 warning: init_ack for unknown transfer\n";
return true;
}
Group::Peer::SendTransfer& transfer = peer.send_transfers[e.transfer_id].value();
using State = Group::Peer::SendTransfer::State;
if (transfer.state != State::INIT_SENT) {
std::cerr << "NGCFT1 error: init_ack but not in INIT_SENT state\n";
return true;
}
if (e.max_lossy_data_size < 16) {
std::cerr << "NGCFT1 error: init_ack max_lossy_data_size is less than 16 bytes\n";
return true;
}
// negotiated packet_data_size
const auto negotiated_packet_data_size = std::min<uint32_t>(e.max_lossy_data_size, _t.toxGroupMaxCustomLossyPacketLength()-4);
// TODO: reset cca with new pkg size
if (!peer.cca) {
// make random max of [1020-1220]
const uint32_t random_max_data_size = (1024-4) + _rng()%201;
const uint32_t randomized_negotiated_packet_data_size = std::min(negotiated_packet_data_size, random_max_data_size);
peer.max_packet_data_size = randomized_negotiated_packet_data_size;
std::cerr << "NGCFT1: creating cca with max:" << peer.max_packet_data_size << "\n";
peer.cca = std::make_unique<CUBIC>(peer.max_packet_data_size);
//peer.cca = std::make_unique<LEDBAT>(peer.max_packet_data_size);
//peer.cca = std::make_unique<FlowOnly>(peer.max_packet_data_size);
//peer.cca->max_byterate_allowed = 1.f *1024*1024;
} else {
std::cerr << "NGCFT1: reusing cca. rtt:" << peer.cca->getCurrentDelay() << " w:" << peer.cca->getWindow() << " ifc:" << peer.cca->inFlightCount() << "\n";
}
// iterate will now call NGC_FT1_send_data_cb
transfer.state = State::SENDING;
transfer.time_since_activity = 0.f;
return true;
}
bool NGCFT1::onEvent(const Events::NGCEXT_ft1_data& e) {
#if !NDEBUG
//std::cout << "NGCFT1: got FT1_DATA " << e.sequence_id << "\n";
#endif
if (e.data.empty()) {
std::cerr << "NGCFT1 error: data of size 0!\n";
return true;
}
if (!groups.count(e.group_number)) {
std::cerr << "NGCFT1 warning: data for unknown group\n";
return true;
}
Group::Peer& peer = groups[e.group_number].peers[e.peer_number];
if (!peer.recv_transfers[e.transfer_id].has_value()) {
std::cerr << "NGCFT1 warning: data for unknown transfer\n";
return true;
}
auto& transfer = peer.recv_transfers[e.transfer_id].value();
// do reassembly, ignore dups
transfer.rsb.add(e.sequence_id, std::vector<uint8_t>(e.data)); // TODO: ugly explicit copy for what should just be a move
// loop for chunks without holes
while (transfer.rsb.canPop()) {
auto data = transfer.rsb.pop();
// TODO: check return value
dispatch(
NGCFT1_Event::recv_data,
Events::NGCFT1_recv_data{
e.group_number, e.peer_number,
e.transfer_id,
transfer.file_size_current,
data.data(), static_cast<uint32_t>(data.size())
}
);
transfer.file_size_current += data.size();
}
// send acks
// reverse, last seq is most recent
std::vector<uint16_t> ack_seq_ids(transfer.rsb.ack_seq_ids.crbegin(), transfer.rsb.ack_seq_ids.crend());
// TODO: check if this caps at max acks
if (!ack_seq_ids.empty()) {
// TODO: check return value
_neep.send_ft1_data_ack(e.group_number, e.peer_number, e.transfer_id, ack_seq_ids.data(), ack_seq_ids.size());
}
if (transfer.file_size_current == transfer.file_size) {
// all data received
transfer.state = Group::Peer::RecvTransfer::State::FINISHING;
// TODO: keep around for remote timeout + delay + offset, so we can be sure all acks where received
// or implement a dedicated finished that needs to be acked
transfer.finishing_timer = 0.75f; // TODO: we are receiving, we dont know delay
dispatch(
NGCFT1_Event::recv_done,
Events::NGCFT1_recv_done{
e.group_number, e.peer_number,
e.transfer_id
}
);
}
return true;
}
bool NGCFT1::onEvent(const Events::NGCEXT_ft1_data_ack& e) {
#if !NDEBUG
//std::cout << "NGCFT1: got FT1_DATA_ACK\n";
#endif
if (!groups.count(e.group_number)) {
std::cerr << "NGCFT1 warning: data_ack for unknown group\n";
return true;
}
Group::Peer& peer = groups[e.group_number].peers[e.peer_number];
if (!peer.send_transfers[e.transfer_id].has_value()) {
// we delete directly, packets might still be in flight (in practice they are when ce)
// update: we no longer delete directly, but its kinda hacky
std::cerr << "NGCFT1 warning: data_ack for unknown transfer\n";
return true;
}
Group::Peer::SendTransfer& transfer = peer.send_transfers[e.transfer_id].value();
using State = Group::Peer::SendTransfer::State;
if (transfer.state != State::SENDING && transfer.state != State::FINISHING) {
std::cerr << "NGCFT1 error: data_ack but not in SENDING or FINISHING state (" << int(transfer.state) << ")\n";
return true;
}
transfer.time_since_activity = 0.f;
{
std::vector<CCAI::SeqIDType> seqs;
for (const auto it : e.sequence_ids) {
// TODO: improve this o.o
seqs.push_back({e.transfer_id, it});
transfer.ssb.erase(it);
}
peer.cca->onAck(std::move(seqs));
}
// delete if all packets acked
if (transfer.file_size == transfer.file_size_current && transfer.ssb.size() == 0) {
std::cout << "NGCFT1: " << int(e.transfer_id) << " done. wnd:" << peer.cca->getWindow() << "\n";
dispatch(
NGCFT1_Event::send_done,
Events::NGCFT1_send_done{
e.group_number, e.peer_number,
e.transfer_id,
}
);
// TODO: check for FINISHING state
peer.send_transfers[e.transfer_id].reset();
}
return true;
}
bool NGCFT1::onEvent(const Events::NGCEXT_ft1_message& e) {
std::cout << "NGCFT1: got FT1_MESSAGE mid:" << e.message_id << " fk:" << e.file_kind << " [" << bin2hex(e.file_id) << "]\n";
// .... just rethrow??
// TODO: dont
return dispatch(
NGCFT1_Event::recv_message,
Events::NGCFT1_recv_message{
e.group_number, e.peer_number,
e.message_id,
static_cast<NGCFT1_file_kind>(e.file_kind),
e.file_id.data(), static_cast<uint32_t>(e.file_id.size())
}
);
}
bool NGCFT1::onEvent(const Events::NGCEXT_ft1_init2& e) {
//#if !NDEBUG
std::cout << "NGCFT1: got FT1_INIT2 fk:" << e.file_kind << " fs:" << e.file_size << " tid:" << int(e.transfer_id) << " ff:" << int(e.feature_flags) << " [" << bin2hex(e.file_id) << "]\n";
//#endif
bool accept = false;
dispatch(
NGCFT1_Event::recv_init,
Events::NGCFT1_recv_init{
e.group_number, e.peer_number,
static_cast<NGCFT1_file_kind>(e.file_kind),
e.file_id.data(), static_cast<uint32_t>(e.file_id.size()),
e.transfer_id,
e.file_size,
accept
}
);
if (!accept) {
std::cout << "NGCFT1: rejected init2\n";
return true; // return true?
}
_neep.send_ft1_init_ack(e.group_number, e.peer_number, e.transfer_id);
std::cout << "NGCFT1: accepted init2\n";
auto& peer = groups[e.group_number].peers[e.peer_number];
if (peer.recv_transfers[e.transfer_id].has_value()) {
std::cerr << "NGCFT1 warning: overwriting existing recv_transfer " << int(e.transfer_id) << ", other peer started new transfer on preexising\n";
}
peer.recv_transfers[e.transfer_id] = Group::Peer::RecvTransfer{
e.file_kind,
e.file_id,
Group::Peer::RecvTransfer::State::INITED,
e.file_size,
0u,
{} // rsb
};
return true;
}
bool NGCFT1::onToxEvent(const Tox_Event_Group_Peer_Exit* e) {
const auto group_number = tox_event_group_peer_exit_get_group_number(e);
const auto peer_number = tox_event_group_peer_exit_get_peer_id(e);
// peer disconnected, end all transfers
if (!groups.count(group_number)) {
return false;
}
auto& group = groups.at(group_number);
if (!group.peers.count(peer_number)) {
return false;
}
auto& peer = group.peers.at(peer_number);
for (size_t i = 0; i < peer.send_transfers.size(); i++) {
auto& it_opt = peer.send_transfers.at(i);
if (!it_opt.has_value()) {
continue;
}
std::cout << "NGCFT1: sending " << int(i) << " canceled bc peer offline\n";
dispatch(
NGCFT1_Event::send_done,
Events::NGCFT1_send_done{
group_number, peer_number,
static_cast<uint8_t>(i),
}
);
it_opt.reset();
}
for (size_t i = 0; i < peer.recv_transfers.size(); i++) {
auto& it_opt = peer.recv_transfers.at(i);
if (!it_opt.has_value()) {
continue;
}
std::cout << "NGCFT1: receiving " << int(i) << " canceled bc peer offline\n";
dispatch(
NGCFT1_Event::recv_done,
Events::NGCFT1_recv_done{
group_number, peer_number,
static_cast<uint8_t>(i),
}
);
it_opt.reset();
}
// reset cca
peer.cca.reset(); // dont actually reallocate
return false;
}