Nagram/TMessagesProj/jni/voip/tgcalls/NetworkManager.cpp
2023-10-29 00:52:06 +04:00

398 lines
13 KiB
C++

#include "NetworkManager.h"
#include "Message.h"
#include "p2p/base/basic_packet_socket_factory.h"
#include "v2/ReflectorRelayPortFactory.h"
#include "p2p/client/basic_port_allocator.h"
#include "p2p/base/p2p_transport_channel.h"
#include "p2p/base/basic_async_resolver_factory.h"
#include "api/packet_socket_factory.h"
#include "p2p/base/ice_credentials_iterator.h"
#include "api/jsep_ice_candidate.h"
#include "rtc_base/network_monitor_factory.h"
#include "TurnCustomizerImpl.h"
#include "platform/PlatformInterface.h"
extern "C" {
#include <openssl/sha.h>
#include <openssl/aes.h>
#ifndef OPENSSL_IS_BORINGSSL
#include <openssl/modes.h>
#endif
#include <openssl/rand.h>
#include <openssl/crypto.h>
} // extern "C"
namespace tgcalls {
class TgCallsCryptStringImpl : public rtc::CryptStringImpl {
public:
TgCallsCryptStringImpl(std::string const &value) :
_value(value) {
}
virtual ~TgCallsCryptStringImpl() override {
}
virtual size_t GetLength() const override {
return _value.size();
}
virtual void CopyTo(char* dest, bool nullterminate) const override {
memcpy(dest, _value.data(), _value.size());
if (nullterminate) {
dest[_value.size()] = 0;
}
}
virtual std::string UrlEncode() const override {
return _value;
}
virtual CryptStringImpl* Copy() const override {
return new TgCallsCryptStringImpl(_value);
}
virtual void CopyRawTo(std::vector<unsigned char>* dest) const override {
dest->resize(_value.size());
memcpy(dest->data(), _value.data(), _value.size());
}
private:
std::string _value;
};
NetworkManager::NetworkManager(
rtc::Thread *thread,
EncryptionKey encryptionKey,
bool enableP2P,
bool enableTCP,
bool enableStunMarking,
std::vector<RtcServer> const &rtcServers,
std::unique_ptr<Proxy> proxy,
std::function<void(const NetworkManager::State &)> stateUpdated,
std::function<void(DecryptedMessage &&)> transportMessageReceived,
std::function<void(Message &&)> sendSignalingMessage,
std::function<void(int delayMs, int cause)> sendTransportServiceAsync) :
_thread(thread),
_enableP2P(enableP2P),
_enableTCP(enableTCP),
_enableStunMarking(enableStunMarking),
_rtcServers(rtcServers),
_proxy(std::move(proxy)),
_transport(
EncryptedConnection::Type::Transport,
encryptionKey,
[=](int delayMs, int cause) { sendTransportServiceAsync(delayMs, cause); }),
_isOutgoing(encryptionKey.isOutgoing),
_stateUpdated(std::move(stateUpdated)),
_transportMessageReceived(std::move(transportMessageReceived)),
_sendSignalingMessage(std::move(sendSignalingMessage)),
_localIceParameters(rtc::CreateRandomString(cricket::ICE_UFRAG_LENGTH), rtc::CreateRandomString(cricket::ICE_PWD_LENGTH), false) {
assert(_thread->IsCurrent());
_networkMonitorFactory = PlatformInterface::SharedInstance()->createNetworkMonitorFactory();
}
NetworkManager::~NetworkManager() {
assert(_thread->IsCurrent());
RTC_LOG(LS_INFO) << "NetworkManager::~NetworkManager()";
_transportChannel.reset();
_asyncResolverFactory.reset();
_portAllocator.reset();
_networkManager.reset();
_socketFactory.reset();
_networkMonitorFactory.reset();
}
void NetworkManager::start() {
_socketFactory.reset(new rtc::BasicPacketSocketFactory(_thread->socketserver()));
_networkManager = std::make_unique<rtc::BasicNetworkManager>(_networkMonitorFactory.get(), _thread->socketserver());
if (_enableStunMarking) {
_turnCustomizer.reset(new TurnCustomizerImpl());
}
_relayPortFactory.reset(new ReflectorRelayPortFactory(_rtcServers));
_portAllocator.reset(new cricket::BasicPortAllocator(_networkManager.get(), _socketFactory.get(), _turnCustomizer.get(), _relayPortFactory.get()));
uint32_t flags = _portAllocator->flags();
flags |=
//cricket::PORTALLOCATOR_ENABLE_SHARED_SOCKET |
cricket::PORTALLOCATOR_ENABLE_IPV6 |
cricket::PORTALLOCATOR_ENABLE_IPV6_ON_WIFI;
if (!_enableTCP) {
flags |= cricket::PORTALLOCATOR_DISABLE_TCP;
}
if (!_enableP2P) {
flags |= cricket::PORTALLOCATOR_DISABLE_UDP;
flags |= cricket::PORTALLOCATOR_DISABLE_STUN;
uint32_t candidateFilter = _portAllocator->candidate_filter();
candidateFilter &= ~(cricket::CF_REFLEXIVE);
_portAllocator->SetCandidateFilter(candidateFilter);
}
_portAllocator->set_step_delay(cricket::kMinimumStepDelay);
if (_proxy) {
rtc::ProxyInfo proxyInfo;
proxyInfo.type = rtc::ProxyType::PROXY_SOCKS5;
proxyInfo.address = rtc::SocketAddress(_proxy->host, _proxy->port);
proxyInfo.username = _proxy->login;
proxyInfo.password = rtc::CryptString(TgCallsCryptStringImpl(_proxy->password));
_portAllocator->set_proxy("t/1.0", proxyInfo);
}
_portAllocator->set_flags(flags);
_portAllocator->Initialize();
cricket::ServerAddresses stunServers;
std::vector<cricket::RelayServerConfig> turnServers;
for (auto &server : _rtcServers) {
if (server.isTcp) {
continue;
}
if (server.isTurn) {
turnServers.push_back(cricket::RelayServerConfig(
rtc::SocketAddress(server.host, server.port),
server.login,
server.password,
cricket::PROTO_UDP
));
} else {
rtc::SocketAddress stunAddress = rtc::SocketAddress(server.host, server.port);
stunServers.insert(stunAddress);
}
}
_portAllocator->SetConfiguration(stunServers, turnServers, 2, webrtc::NO_PRUNE, _turnCustomizer.get());
_asyncResolverFactory = std::make_unique<webrtc::BasicAsyncResolverFactory>();
webrtc::IceTransportInit iceTransportInit;
iceTransportInit.set_port_allocator(_portAllocator.get());
iceTransportInit.set_async_resolver_factory(_asyncResolverFactory.get());
_transportChannel = cricket::P2PTransportChannel::Create("transport", 0, std::move(iceTransportInit));
cricket::IceConfig iceConfig;
iceConfig.continual_gathering_policy = cricket::GATHER_CONTINUALLY;
iceConfig.prioritize_most_likely_candidate_pairs = true;
iceConfig.regather_on_failed_networks_interval = 8000;
_transportChannel->SetIceConfig(iceConfig);
cricket::IceParameters localIceParameters(
_localIceParameters.ufrag,
_localIceParameters.pwd,
false
);
_transportChannel->SetIceParameters(localIceParameters);
_transportChannel->SetIceRole(_isOutgoing ? cricket::ICEROLE_CONTROLLING : cricket::ICEROLE_CONTROLLED);
_transportChannel->SignalCandidateGathered.connect(this, &NetworkManager::candidateGathered);
_transportChannel->SignalGatheringState.connect(this, &NetworkManager::candidateGatheringState);
_transportChannel->SignalIceTransportStateChanged.connect(this, &NetworkManager::transportStateChanged);
_transportChannel->SignalReadPacket.connect(this, &NetworkManager::transportPacketReceived);
_transportChannel->SignalNetworkRouteChanged.connect(this, &NetworkManager::transportRouteChanged);
_transportChannel->MaybeStartGathering();
_transportChannel->SetRemoteIceMode(cricket::ICEMODE_FULL);
_lastNetworkActivityMs = rtc::TimeMillis();
checkConnectionTimeout();
}
void NetworkManager::receiveSignalingMessage(DecryptedMessage &&message) {
const auto list = absl::get_if<CandidatesListMessage>(&message.message.data);
assert(list != nullptr);
if (!_remoteIceParameters.has_value()) {
PeerIceParameters parameters(list->iceParameters.ufrag, list->iceParameters.pwd, false);
_remoteIceParameters = parameters;
cricket::IceParameters remoteIceParameters(
parameters.ufrag,
parameters.pwd,
false
);
_transportChannel->SetRemoteIceParameters(remoteIceParameters);
}
for (const auto &candidate : list->candidates) {
_transportChannel->AddRemoteCandidate(candidate);
}
}
uint32_t NetworkManager::sendMessage(const Message &message) {
if (const auto prepared = _transport.prepareForSending(message)) {
rtc::PacketOptions packetOptions;
_transportChannel->SendPacket((const char *)prepared->bytes.data(), prepared->bytes.size(), packetOptions, 0);
addTrafficStats(prepared->bytes.size(), false);
return prepared->counter;
}
return 0;
}
void NetworkManager::sendTransportService(int cause) {
if (const auto prepared = _transport.prepareForSendingService(cause)) {
rtc::PacketOptions packetOptions;
_transportChannel->SendPacket((const char *)prepared->bytes.data(), prepared->bytes.size(), packetOptions, 0);
addTrafficStats(prepared->bytes.size(), false);
}
}
void NetworkManager::setIsLocalNetworkLowCost(bool isLocalNetworkLowCost) {
_isLocalNetworkLowCost = isLocalNetworkLowCost;
logCurrentNetworkState();
}
TrafficStats NetworkManager::getNetworkStats() {
TrafficStats stats;
stats.bytesSentWifi = _trafficStatsWifi.outgoing;
stats.bytesReceivedWifi = _trafficStatsWifi.incoming;
stats.bytesSentMobile = _trafficStatsCellular.outgoing;
stats.bytesReceivedMobile = _trafficStatsCellular.incoming;
return stats;
}
void NetworkManager::fillCallStats(CallStats &callStats) {
callStats.networkRecords = _networkRecords;
}
void NetworkManager::logCurrentNetworkState() {
if (!_currentEndpointType.has_value()) {
return;
}
CallStatsNetworkRecord record;
record.timestamp = (int32_t)(rtc::TimeMillis() / 1000);
record.endpointType = *_currentEndpointType;
record.isLowCost = _isLocalNetworkLowCost;
_networkRecords.push_back(std::move(record));
}
void NetworkManager::checkConnectionTimeout() {
const auto weak = std::weak_ptr<NetworkManager>(shared_from_this());
_thread->PostDelayedTask([weak]() {
auto strong = weak.lock();
if (!strong) {
return;
}
int64_t currentTimestamp = rtc::TimeMillis();
const int64_t maxTimeout = 20000;
if (strong->_lastNetworkActivityMs + maxTimeout < currentTimestamp) {
NetworkManager::State emitState;
emitState.isReadyToSendData = false;
emitState.isFailed = true;
strong->_stateUpdated(emitState);
}
strong->checkConnectionTimeout();
}, webrtc::TimeDelta::Millis(1000));
}
void NetworkManager::candidateGathered(cricket::IceTransportInternal *transport, const cricket::Candidate &candidate) {
assert(_thread->IsCurrent());
_sendSignalingMessage({ CandidatesListMessage{ { 1, candidate }, _localIceParameters } });
}
void NetworkManager::candidateGatheringState(cricket::IceTransportInternal *transport) {
assert(_thread->IsCurrent());
}
void NetworkManager::transportStateChanged(cricket::IceTransportInternal *transport) {
assert(_thread->IsCurrent());
auto state = transport->GetIceTransportState();
bool isConnected = false;
switch (state) {
case webrtc::IceTransportState::kConnected:
case webrtc::IceTransportState::kCompleted:
isConnected = true;
break;
default:
break;
}
NetworkManager::State emitState;
emitState.isReadyToSendData = isConnected;
_stateUpdated(emitState);
}
void NetworkManager::transportReadyToSend(cricket::IceTransportInternal *transport) {
assert(_thread->IsCurrent());
}
void NetworkManager::transportPacketReceived(rtc::PacketTransportInternal *transport, const char *bytes, size_t size, const int64_t &timestamp, int unused) {
assert(_thread->IsCurrent());
_lastNetworkActivityMs = rtc::TimeMillis();
addTrafficStats(size, true);
if (auto decrypted = _transport.handleIncomingPacket(bytes, size)) {
if (_transportMessageReceived) {
_transportMessageReceived(std::move(decrypted->main));
for (auto &message : decrypted->additional) {
_transportMessageReceived(std::move(message));
}
}
}
}
void NetworkManager::transportRouteChanged(absl::optional<rtc::NetworkRoute> route) {
assert(_thread->IsCurrent());
if (route.has_value()) {
RTC_LOG(LS_INFO) << "NetworkManager route changed: " << route->DebugString();
bool localIsWifi = route->local.adapter_type() == rtc::AdapterType::ADAPTER_TYPE_WIFI;
bool remoteIsWifi = route->remote.adapter_type() == rtc::AdapterType::ADAPTER_TYPE_WIFI;
RTC_LOG(LS_INFO) << "NetworkManager is wifi: local=" << localIsWifi << ", remote=" << remoteIsWifi;
CallStatsConnectionEndpointType endpointType;
if (route->local.uses_turn()) {
endpointType = CallStatsConnectionEndpointType::ConnectionEndpointTURN;
} else {
endpointType = CallStatsConnectionEndpointType::ConnectionEndpointP2P;
}
if (!_currentEndpointType.has_value() || _currentEndpointType != endpointType) {
_currentEndpointType = endpointType;
logCurrentNetworkState();
}
}
}
void NetworkManager::addTrafficStats(int64_t byteCount, bool isIncoming) {
if (_isLocalNetworkLowCost) {
if (isIncoming) {
_trafficStatsWifi.incoming += byteCount;
} else {
_trafficStatsWifi.outgoing += byteCount;
}
} else {
if (isIncoming) {
_trafficStatsCellular.incoming += byteCount;
} else {
_trafficStatsCellular.outgoing += byteCount;
}
}
}
} // namespace tgcalls