/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */ /* vim: set ts=2 et sw=2 tw=80: */ /* This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this file, * You can obtain one at http://mozilla.org/MPL/2.0/. */ #include #include #include #if !defined(__Userspace_os_Windows) # include #endif // usrsctp.h expects to have errno definitions prior to its inclusion. #include #define SCTP_DEBUG 1 #define SCTP_STDINT_INCLUDE #ifdef _MSC_VER // Disable "warning C4200: nonstandard extension used : zero-sized array in // struct/union" // ...which the third-party file usrsctp.h runs afoul of. # pragma warning(push) # pragma warning(disable : 4200) #endif #include "usrsctp.h" #ifdef _MSC_VER # pragma warning(pop) #endif #include "nsServiceManagerUtils.h" #include "nsIInputStream.h" #include "nsIObserverService.h" #include "nsIObserver.h" #include "nsIPrefBranch.h" #include "nsIPrefService.h" #include "mozilla/Services.h" #include "mozilla/Sprintf.h" #include "nsProxyRelease.h" #include "nsThread.h" #include "nsThreadUtils.h" #include "nsNetUtil.h" #include "nsNetCID.h" #include "mozilla/RandomNum.h" #include "mozilla/StaticMutex.h" #include "mozilla/UniquePtrExtensions.h" #include "mozilla/Unused.h" #include "mozilla/dom/RTCDataChannelBinding.h" #include "mozilla/dom/RTCStatsReportBinding.h" #ifdef MOZ_PEERCONNECTION # include "transport/runnable_utils.h" # include "jsapi/MediaTransportHandler.h" # include "mediapacket.h" #endif #include "DataChannel.h" #include "DataChannelProtocol.h" // Let us turn on and off important assertions in non-debug builds #ifdef DEBUG # define ASSERT_WEBRTC(x) MOZ_ASSERT((x)) #elif defined(MOZ_WEBRTC_ASSERT_ALWAYS) # define ASSERT_WEBRTC(x) \ do { \ if (!(x)) { \ MOZ_CRASH(); \ } \ } while (0) #endif namespace mozilla { LazyLogModule gDataChannelLog("DataChannel"); static LazyLogModule gSCTPLog("SCTP"); #define SCTP_LOG(args) \ MOZ_LOG(mozilla::gSCTPLog, mozilla::LogLevel::Debug, args) static void debug_printf(const char* format, ...) { va_list ap; char buffer[1024]; if (MOZ_LOG_TEST(gSCTPLog, LogLevel::Debug)) { va_start(ap, format); #ifdef _WIN32 if (vsnprintf_s(buffer, sizeof(buffer), _TRUNCATE, format, ap) > 0) { #else if (VsprintfLiteral(buffer, format, ap) > 0) { #endif SCTP_LOG(("%s", buffer)); } va_end(ap); } } class DataChannelRegistry : public nsIObserver { public: NS_DECL_THREADSAFE_ISUPPORTS static uintptr_t Register(DataChannelConnection* aConnection) { StaticMutexAutoLock lock(sInstanceMutex); if (NS_WARN_IF(!Instance())) { return 0; } return Instance()->RegisterImpl(aConnection); } static void Deregister(uintptr_t aId) { StaticMutexAutoLock lock(sInstanceMutex); if (NS_WARN_IF(!Instance())) { return; } Instance()->DeregisterImpl(aId); } static RefPtr Lookup(uintptr_t aId) { StaticMutexAutoLock lock(sInstanceMutex); if (NS_WARN_IF(!Instance())) { return nullptr; } return Instance()->LookupImpl(aId); } private: // This is a singleton class, so don't let just anyone create one of these DataChannelRegistry() { ASSERT_WEBRTC(NS_IsMainThread()); nsCOMPtr observerService = mozilla::services::GetObserverService(); if (!observerService) return; nsresult rv = observerService->AddObserver(this, "xpcom-will-shutdown", false); MOZ_ASSERT(rv == NS_OK); (void)rv; // TODO(bug 1646716): usrsctp_finish is racy, so we init in the c'tor. InitUsrSctp(); } static RefPtr& Instance() { // Lazy-create static registry. static RefPtr sRegistry = new DataChannelRegistry; return sRegistry; } NS_IMETHOD Observe(nsISupports* aSubject, const char* aTopic, const char16_t* aData) override { ASSERT_WEBRTC(NS_IsMainThread()); if (strcmp(aTopic, "xpcom-will-shutdown") == 0) { RefPtr self = this; { StaticMutexAutoLock lock(sInstanceMutex); Instance() = nullptr; } // |self| is the only reference now if (NS_WARN_IF(!mConnections.empty())) { MOZ_ASSERT(false); mConnections.clear(); } // TODO(bug 1646716): usrsctp_finish is racy, so we wait until xpcom // shutdown for this. DeinitUsrSctp(); nsCOMPtr observerService = mozilla::services::GetObserverService(); if (NS_WARN_IF(!observerService)) { return NS_ERROR_FAILURE; } nsresult rv = observerService->RemoveObserver(this, "xpcom-will-shutdown"); MOZ_ASSERT(rv == NS_OK); (void)rv; } return NS_OK; } uintptr_t RegisterImpl(DataChannelConnection* aConnection) { ASSERT_WEBRTC(NS_IsMainThread()); // TODO(bug 1646716): usrsctp_finish is racy, so we init in the c'tor. // if (mConnections.empty()) { // InitUsrSctp(); //} mConnections.emplace(mNextId, aConnection); return mNextId++; } void DeregisterImpl(uintptr_t aId) { ASSERT_WEBRTC(NS_IsMainThread()); mConnections.erase(aId); // TODO(bug 1646716): usrsctp_finish is racy, so we wait until xpcom // shutdown for this. // if (mConnections.empty()) { // DeinitUsrSctp(); //} } RefPtr LookupImpl(uintptr_t aId) { auto it = mConnections.find(aId); if (NS_WARN_IF(it == mConnections.end())) { return nullptr; } return it->second; } virtual ~DataChannelRegistry() = default; #ifdef SCTP_DTLS_SUPPORTED static int SctpDtlsOutput(void* addr, void* buffer, size_t length, uint8_t tos, uint8_t set_df) { uintptr_t id = reinterpret_cast(addr); RefPtr connection = DataChannelRegistry::Lookup(id); if (NS_WARN_IF(!connection)) { return 0; } return connection->SctpDtlsOutput(addr, buffer, length, tos, set_df); } #endif void InitUsrSctp() { DC_DEBUG(("sctp_init")); #ifdef MOZ_PEERCONNECTION usrsctp_init(0, DataChannelRegistry::SctpDtlsOutput, debug_printf); #else MOZ_CRASH("Trying to use SCTP/DTLS without dom/media/webrtc/transport"); #endif // Set logging to SCTP:LogLevel::Debug to get SCTP debugs if (MOZ_LOG_TEST(gSCTPLog, LogLevel::Debug)) { usrsctp_sysctl_set_sctp_debug_on(SCTP_DEBUG_ALL); } // Do not send ABORTs in response to INITs (1). // Do not send ABORTs for received Out of the Blue packets (2). usrsctp_sysctl_set_sctp_blackhole(2); // Disable the Explicit Congestion Notification extension (currently not // supported by the Firefox code) usrsctp_sysctl_set_sctp_ecn_enable(0); // Enable interleaving messages for different streams (incoming) // See: https://tools.ietf.org/html/rfc6458#section-8.1.20 usrsctp_sysctl_set_sctp_default_frag_interleave(2); // Disabling authentication and dynamic address reconfiguration as neither // of them are used for data channel and only result in additional code // paths being used. usrsctp_sysctl_set_sctp_asconf_enable(0); usrsctp_sysctl_set_sctp_auth_enable(0); } void DeinitUsrSctp() { DC_DEBUG(("Shutting down SCTP")); usrsctp_finish(); } uintptr_t mNextId = 1; std::map> mConnections; static StaticMutex sInstanceMutex; }; StaticMutex DataChannelRegistry::sInstanceMutex; NS_IMPL_ISUPPORTS(DataChannelRegistry, nsIObserver); OutgoingMsg::OutgoingMsg(struct sctp_sendv_spa& info, const uint8_t* data, size_t length) : mLength(length), mData(data) { mInfo = &info; mPos = 0; } void OutgoingMsg::Advance(size_t offset) { mPos += offset; if (mPos > mLength) { mPos = mLength; } } BufferedOutgoingMsg::BufferedOutgoingMsg(OutgoingMsg& msg) { size_t length = msg.GetLeft(); auto* tmp = new uint8_t[length]; // infallible malloc! memcpy(tmp, msg.GetData(), length); mLength = length; mData = tmp; mInfo = new sctp_sendv_spa; *mInfo = msg.GetInfo(); mPos = 0; } BufferedOutgoingMsg::~BufferedOutgoingMsg() { delete mInfo; delete[] mData; } static int receive_cb(struct socket* sock, union sctp_sockstore addr, void* data, size_t datalen, struct sctp_rcvinfo rcv, int flags, void* ulp_info) { DC_DEBUG(("In receive_cb, ulp_info=%p", ulp_info)); uintptr_t id = reinterpret_cast(ulp_info); RefPtr connection = DataChannelRegistry::Lookup(id); if (!connection) { MOZ_ASSERT(false); return 0; } return connection->ReceiveCallback(sock, data, datalen, rcv, flags); } static RefPtr GetConnectionFromSocket( struct socket* sock) { struct sockaddr* addrs = nullptr; int naddrs = usrsctp_getladdrs(sock, 0, &addrs); if (naddrs <= 0 || addrs[0].sa_family != AF_CONN) { return nullptr; } // usrsctp_getladdrs() returns the addresses bound to this socket, which // contains the SctpDataMediaChannel* as sconn_addr. Read the pointer, // then free the list of addresses once we have the pointer. We only open // AF_CONN sockets, and they should all have the sconn_addr set to the // pointer that created them, so [0] is as good as any other. struct sockaddr_conn* sconn = reinterpret_cast(&addrs[0]); uintptr_t id = reinterpret_cast(sconn->sconn_addr); RefPtr connection = DataChannelRegistry::Lookup(id); usrsctp_freeladdrs(addrs); return connection; } // called when the buffer empties to the threshold value static int threshold_event(struct socket* sock, uint32_t sb_free) { RefPtr connection = GetConnectionFromSocket(sock); if (connection) { connection->SendDeferredMessages(); } else { DC_ERROR(("Can't find connection for socket %p", sock)); } return 0; } DataChannelConnection::~DataChannelConnection() { DC_DEBUG(("Deleting DataChannelConnection %p", (void*)this)); // This may die on the MainThread, or on the STS thread ASSERT_WEBRTC(mState == CLOSED); MOZ_ASSERT(!mMasterSocket); MOZ_ASSERT(mPending.GetSize() == 0); if (!IsSTSThread()) { ASSERT_WEBRTC(NS_IsMainThread()); if (mInternalIOThread) { // Avoid spinning the event thread from here (which if we're mainthread // is in the event loop already) nsCOMPtr r = WrapRunnable( nsCOMPtr(mInternalIOThread), &nsIThread::AsyncShutdown); Dispatch(r.forget()); } } else { // on STS, safe to call shutdown if (mInternalIOThread) { mInternalIOThread->Shutdown(); } } } void DataChannelConnection::Destroy() { // Though it's probably ok to do this and close the sockets; // if we really want it to do true clean shutdowns it can // create a dependant Internal object that would remain around // until the network shut down the association or timed out. DC_DEBUG(("Destroying DataChannelConnection %p", (void*)this)); ASSERT_WEBRTC(NS_IsMainThread()); CloseAll(); MutexAutoLock lock(mLock); // If we had a pending reset, we aren't waiting for it - clear the list so // we can deregister this DataChannelConnection without leaking. ClearResets(); MOZ_ASSERT(mSTS); ASSERT_WEBRTC(NS_IsMainThread()); mListener = nullptr; // Finish Destroy on STS thread to avoid bug 876167 - once that's fixed, // the usrsctp_close() calls can move back here (and just proxy the // disconnect_all()) RUN_ON_THREAD(mSTS, WrapRunnable(RefPtr(this), &DataChannelConnection::DestroyOnSTS, mSocket, mMasterSocket), NS_DISPATCH_NORMAL); // These will be released on STS mSocket = nullptr; mMasterSocket = nullptr; // also a flag that we've Destroyed this connection // We can't get any more new callbacks from the SCTP library // All existing callbacks have refs to DataChannelConnection // nsDOMDataChannel objects have refs to DataChannels that have refs to us } void DataChannelConnection::DestroyOnSTS(struct socket* aMasterSocket, struct socket* aSocket) { if (aSocket && aSocket != aMasterSocket) usrsctp_close(aSocket); if (aMasterSocket) usrsctp_close(aMasterSocket); usrsctp_deregister_address(reinterpret_cast(mId)); DC_DEBUG( ("Deregistered %p from the SCTP stack.", reinterpret_cast(mId))); #ifdef MOZ_DIAGNOSTIC_ASSERT_ENABLED mShutdown = true; #endif disconnect_all(); mTransportHandler = nullptr; GetMainThreadEventTarget()->Dispatch(NS_NewRunnableFunction( "DataChannelConnection::Destroy", [id = mId]() { DataChannelRegistry::Deregister(id); })); } Maybe> DataChannelConnection::Create( DataChannelConnection::DataConnectionListener* aListener, nsISerialEventTarget* aTarget, MediaTransportHandler* aHandler, const uint16_t aLocalPort, const uint16_t aNumStreams, const Maybe& aMaxMessageSize) { ASSERT_WEBRTC(NS_IsMainThread()); RefPtr connection = new DataChannelConnection( aListener, aTarget, aHandler); // Walks into a bar return connection->Init(aLocalPort, aNumStreams, aMaxMessageSize) ? Some(connection) : Nothing(); } DataChannelConnection::DataChannelConnection( DataChannelConnection::DataConnectionListener* aListener, nsISerialEventTarget* aTarget, MediaTransportHandler* aHandler) : NeckoTargetHolder(aTarget), mLock("netwerk::sctp::DataChannelConnection"), mListener(aListener), mTransportHandler(aHandler) { DC_VERBOSE(("Constructor DataChannelConnection=%p, listener=%p", this, mListener.get())); #ifdef MOZ_DIAGNOSTIC_ASSERT_ENABLED mShutdown = false; #endif } bool DataChannelConnection::Init(const uint16_t aLocalPort, const uint16_t aNumStreams, const Maybe& aMaxMessageSize) { ASSERT_WEBRTC(NS_IsMainThread()); struct sctp_initmsg initmsg; struct sctp_assoc_value av; struct sctp_event event; socklen_t len; uint16_t event_types[] = { SCTP_ASSOC_CHANGE, SCTP_PEER_ADDR_CHANGE, SCTP_REMOTE_ERROR, SCTP_SHUTDOWN_EVENT, SCTP_ADAPTATION_INDICATION, SCTP_PARTIAL_DELIVERY_EVENT, SCTP_SEND_FAILED_EVENT, SCTP_STREAM_RESET_EVENT, SCTP_STREAM_CHANGE_EVENT}; { // MutexAutoLock lock(mLock); Not needed since we're on mainthread always mLocalPort = aLocalPort; SetMaxMessageSize(aMaxMessageSize.isSome(), aMaxMessageSize.valueOr(0)); } mId = DataChannelRegistry::Register(this); // XXX FIX! make this a global we get once // Find the STS thread nsresult rv; mSTS = do_GetService(NS_SOCKETTRANSPORTSERVICE_CONTRACTID, &rv); MOZ_ASSERT(NS_SUCCEEDED(rv)); // Open sctp with a callback if ((mMasterSocket = usrsctp_socket( AF_CONN, SOCK_STREAM, IPPROTO_SCTP, receive_cb, threshold_event, usrsctp_sysctl_get_sctp_sendspace() / 2, reinterpret_cast(mId))) == nullptr) { return false; } int buf_size = 1024 * 1024; if (usrsctp_setsockopt(mMasterSocket, SOL_SOCKET, SO_RCVBUF, (const void*)&buf_size, sizeof(buf_size)) < 0) { DC_ERROR(("Couldn't change receive buffer size on SCTP socket")); goto error_cleanup; } if (usrsctp_setsockopt(mMasterSocket, SOL_SOCKET, SO_SNDBUF, (const void*)&buf_size, sizeof(buf_size)) < 0) { DC_ERROR(("Couldn't change send buffer size on SCTP socket")); goto error_cleanup; } // Make non-blocking for bind/connect. SCTP over UDP defaults to non-blocking // in associations for normal IO if (usrsctp_set_non_blocking(mMasterSocket, 1) < 0) { DC_ERROR(("Couldn't set non_blocking on SCTP socket")); // We can't handle connect() safely if it will block, not that this will // even happen. goto error_cleanup; } // Make sure when we close the socket, make sure it doesn't call us back // again! This would cause it try to use an invalid DataChannelConnection // pointer struct linger l; l.l_onoff = 1; l.l_linger = 0; if (usrsctp_setsockopt(mMasterSocket, SOL_SOCKET, SO_LINGER, (const void*)&l, (socklen_t)sizeof(struct linger)) < 0) { DC_ERROR(("Couldn't set SO_LINGER on SCTP socket")); // unsafe to allow it to continue if this fails goto error_cleanup; } // XXX Consider disabling this when we add proper SDP negotiation. // We may want to leave enabled for supporting 'cloning' of SDP offers, which // implies re-use of the same pseudo-port number, or forcing a renegotiation. { const int option_value = 1; if (usrsctp_setsockopt(mMasterSocket, IPPROTO_SCTP, SCTP_REUSE_PORT, (const void*)&option_value, (socklen_t)sizeof(option_value)) < 0) { DC_WARN(("Couldn't set SCTP_REUSE_PORT on SCTP socket")); } if (usrsctp_setsockopt(mMasterSocket, IPPROTO_SCTP, SCTP_NODELAY, (const void*)&option_value, (socklen_t)sizeof(option_value)) < 0) { DC_WARN(("Couldn't set SCTP_NODELAY on SCTP socket")); } } // Set explicit EOR { const int option_value = 1; if (usrsctp_setsockopt(mMasterSocket, IPPROTO_SCTP, SCTP_EXPLICIT_EOR, (const void*)&option_value, (socklen_t)sizeof(option_value)) < 0) { DC_ERROR(("*** failed to enable explicit EOR mode %d", errno)); goto error_cleanup; } } // Enable ndata // TODO: Bug 1381145, enable this once ndata has been deployed #if 0 av.assoc_id = SCTP_FUTURE_ASSOC; av.assoc_value = 1; if (usrsctp_setsockopt(mMasterSocket, IPPROTO_SCTP, SCTP_INTERLEAVING_SUPPORTED, &av, (socklen_t)sizeof(struct sctp_assoc_value)) < 0) { DC_ERROR(("*** failed enable ndata errno %d", errno)); goto error_cleanup; } #endif av.assoc_id = SCTP_ALL_ASSOC; av.assoc_value = SCTP_ENABLE_RESET_STREAM_REQ | SCTP_ENABLE_CHANGE_ASSOC_REQ; if (usrsctp_setsockopt(mMasterSocket, IPPROTO_SCTP, SCTP_ENABLE_STREAM_RESET, &av, (socklen_t)sizeof(struct sctp_assoc_value)) < 0) { DC_ERROR(("*** failed enable stream reset errno %d", errno)); goto error_cleanup; } /* Enable the events of interest. */ memset(&event, 0, sizeof(event)); event.se_assoc_id = SCTP_ALL_ASSOC; event.se_on = 1; for (unsigned short event_type : event_types) { event.se_type = event_type; if (usrsctp_setsockopt(mMasterSocket, IPPROTO_SCTP, SCTP_EVENT, &event, sizeof(event)) < 0) { DC_ERROR(("*** failed setsockopt SCTP_EVENT errno %d", errno)); goto error_cleanup; } } memset(&initmsg, 0, sizeof(initmsg)); len = sizeof(initmsg); if (usrsctp_getsockopt(mMasterSocket, IPPROTO_SCTP, SCTP_INITMSG, &initmsg, &len) < 0) { DC_ERROR(("*** failed getsockopt SCTP_INITMSG")); goto error_cleanup; } DC_DEBUG(("Setting number of SCTP streams to %u, was %u/%u", aNumStreams, initmsg.sinit_num_ostreams, initmsg.sinit_max_instreams)); initmsg.sinit_num_ostreams = aNumStreams; initmsg.sinit_max_instreams = MAX_NUM_STREAMS; if (usrsctp_setsockopt(mMasterSocket, IPPROTO_SCTP, SCTP_INITMSG, &initmsg, (socklen_t)sizeof(initmsg)) < 0) { DC_ERROR(("*** failed setsockopt SCTP_INITMSG, errno %d", errno)); goto error_cleanup; } mSocket = nullptr; mSTS->Dispatch( NS_NewRunnableFunction("DataChannelConnection::Init", [id = mId]() { usrsctp_register_address(reinterpret_cast(id)); DC_DEBUG(("Registered %p within the SCTP stack.", reinterpret_cast(id))); })); return true; error_cleanup: usrsctp_close(mMasterSocket); mMasterSocket = nullptr; return false; } void DataChannelConnection::SetMaxMessageSize(bool aMaxMessageSizeSet, uint64_t aMaxMessageSize) { MutexAutoLock lock(mLock); // TODO: Needed? if (mMaxMessageSizeSet && !aMaxMessageSizeSet) { // Don't overwrite already set MMS with default values return; } mMaxMessageSizeSet = aMaxMessageSizeSet; mMaxMessageSize = aMaxMessageSize; nsresult rv; nsCOMPtr prefs = do_GetService("@mozilla.org/preferences-service;1", &rv); if (!NS_WARN_IF(NS_FAILED(rv))) { nsCOMPtr branch = do_QueryInterface(prefs); if (branch) { int32_t temp; if (!NS_FAILED(branch->GetIntPref( "media.peerconnection.sctp.force_maximum_message_size", &temp))) { if (temp >= 0) { mMaxMessageSize = (uint64_t)temp; } } } } // Fix remote MMS. This code exists, so future implementations of // RTCSctpTransport.maxMessageSize can simply provide that value from // GetMaxMessageSize. // TODO: Bug 1382779, once resolved, can be increased to // min(Uint8ArrayMaxSize, UINT32_MAX) // TODO: Bug 1381146, once resolved, can be increased to whatever we support // then (hopefully // SIZE_MAX) if (mMaxMessageSize == 0 || mMaxMessageSize > WEBRTC_DATACHANNEL_MAX_MESSAGE_SIZE_REMOTE) { mMaxMessageSize = WEBRTC_DATACHANNEL_MAX_MESSAGE_SIZE_REMOTE; } DC_DEBUG(("Maximum message size (outgoing data): %" PRIu64 " (set=%s, enforced=%s)", mMaxMessageSize, mMaxMessageSizeSet ? "yes" : "no", aMaxMessageSize != mMaxMessageSize ? "yes" : "no")); } uint64_t DataChannelConnection::GetMaxMessageSize() { return mMaxMessageSize; } void DataChannelConnection::AppendStatsToReport( const UniquePtr& aReport, const DOMHighResTimeStamp aTimestamp) const { ASSERT_WEBRTC(NS_IsMainThread()); nsString temp; for (const RefPtr& chan : mChannels.GetAll()) { // If channel is empty, ignore if (!chan) { continue; } mozilla::dom::RTCDataChannelStats stats; nsString id = u"dc"_ns; id.AppendInt(chan->GetStream()); stats.mId.Construct(id); chan->GetLabel(temp); stats.mTimestamp.Construct(aTimestamp); stats.mType.Construct(mozilla::dom::RTCStatsType::Data_channel); stats.mLabel.Construct(temp); chan->GetProtocol(temp); stats.mProtocol.Construct(temp); stats.mDataChannelIdentifier.Construct(chan->GetStream()); { using State = mozilla::dom::RTCDataChannelState; State state; switch (chan->GetReadyState()) { case CONNECTING: state = State::Connecting; break; case OPEN: state = State::Open; break; case CLOSING: state = State::Closing; break; case CLOSED: state = State::Closed; break; default: MOZ_ASSERT(false, "Unknown DataChannel state"); continue; }; stats.mState.Construct(state); } auto counters = chan->GetTrafficCounters(); stats.mMessagesSent.Construct(counters.mMessagesSent); stats.mBytesSent.Construct(counters.mBytesSent); stats.mMessagesReceived.Construct(counters.mMessagesReceived); stats.mBytesReceived.Construct(counters.mBytesReceived); if (!aReport->mDataChannelStats.AppendElement(stats, fallible)) { mozalloc_handle_oom(0); } } } #ifdef MOZ_PEERCONNECTION bool DataChannelConnection::ConnectToTransport(const std::string& aTransportId, const bool aClient, const uint16_t aLocalPort, const uint16_t aRemotePort) { MutexAutoLock lock(mLock); MOZ_ASSERT(mMasterSocket, "SCTP wasn't initialized before ConnectToTransport!"); static const auto paramString = [](const std::string& tId, const Maybe& client, const uint16_t localPort, const uint16_t remotePort) -> std::string { std::ostringstream stream; stream << "Transport ID: '" << tId << "', Role: '" << (client ? (client.value() ? "client" : "server") : "") << "', Local Port: '" << localPort << "', Remote Port: '" << remotePort << "'"; return stream.str(); }; const auto params = paramString(aTransportId, Some(aClient), aLocalPort, aRemotePort); DC_DEBUG(("ConnectToTransport connecting DTLS transport with parameters: %s", params.c_str())); const auto currentReadyState = GetReadyState(); if (currentReadyState == OPEN) { if (aTransportId == mTransportId && mAllocateEven.isSome() && mAllocateEven.value() == aClient && mLocalPort == aLocalPort && mRemotePort == aRemotePort) { DC_WARN( ("Skipping attempt to connect to an already OPEN transport with " "identical parameters.")); return true; } DC_WARN( ("Attempting to connect to an already OPEN transport, because " "different parameters were provided.")); DC_WARN(("Original transport parameters: %s", paramString(mTransportId, mAllocateEven, mLocalPort, aRemotePort) .c_str())); DC_WARN(("New transport parameters: %s", params.c_str())); } if (NS_WARN_IF(aTransportId.empty())) { return false; } mLocalPort = aLocalPort; mRemotePort = aRemotePort; SetReadyState(CONNECTING); mAllocateEven = Some(aClient); // Could be faster. Probably doesn't matter. while (auto channel = mChannels.Get(INVALID_STREAM)) { mChannels.Remove(channel); channel->mStream = FindFreeStream(); if (channel->mStream != INVALID_STREAM) { mChannels.Insert(channel); } } RUN_ON_THREAD(mSTS, WrapRunnable(RefPtr(this), &DataChannelConnection::SetSignals, aTransportId), NS_DISPATCH_NORMAL); return true; } void DataChannelConnection::SetSignals(const std::string& aTransportId) { ASSERT_WEBRTC(IsSTSThread()); mTransportId = aTransportId; mTransportHandler->SignalPacketReceived.connect( this, &DataChannelConnection::SctpDtlsInput); mTransportHandler->SignalStateChange.connect( this, &DataChannelConnection::TransportStateChange); // SignalStateChange() doesn't call you with the initial state if (mTransportHandler->GetState(mTransportId, false) == TransportLayer::TS_OPEN) { DC_DEBUG(("Setting transport signals, dtls already open")); CompleteConnect(); } else { DC_DEBUG(("Setting transport signals, dtls not open yet")); } } void DataChannelConnection::TransportStateChange( const std::string& aTransportId, TransportLayer::State aState) { if (aTransportId == mTransportId) { if (aState == TransportLayer::TS_OPEN) { DC_DEBUG(("Transport is open!")); CompleteConnect(); } else if (aState == TransportLayer::TS_CLOSED || aState == TransportLayer::TS_NONE || aState == TransportLayer::TS_ERROR) { DC_DEBUG(("Transport is closed!")); Stop(); } } } void DataChannelConnection::CompleteConnect() { MutexAutoLock lock(mLock); DC_DEBUG(("dtls open")); ASSERT_WEBRTC(IsSTSThread()); if (!mMasterSocket) { return; } struct sockaddr_conn addr; memset(&addr, 0, sizeof(addr)); addr.sconn_family = AF_CONN; # if defined(__Userspace_os_Darwin) addr.sconn_len = sizeof(addr); # endif addr.sconn_port = htons(mLocalPort); addr.sconn_addr = reinterpret_cast(mId); DC_DEBUG(("Calling usrsctp_bind")); int r = usrsctp_bind(mMasterSocket, reinterpret_cast(&addr), sizeof(addr)); if (r < 0) { DC_ERROR(("usrsctp_bind failed: %d", r)); } else { // This is the remote addr addr.sconn_port = htons(mRemotePort); DC_DEBUG(("Calling usrsctp_connect")); r = usrsctp_connect( mMasterSocket, reinterpret_cast(&addr), sizeof(addr)); if (r >= 0 || errno == EINPROGRESS) { struct sctp_paddrparams paddrparams; socklen_t opt_len; memset(&paddrparams, 0, sizeof(struct sctp_paddrparams)); memcpy(&paddrparams.spp_address, &addr, sizeof(struct sockaddr_conn)); opt_len = (socklen_t)sizeof(struct sctp_paddrparams); r = usrsctp_getsockopt(mMasterSocket, IPPROTO_SCTP, SCTP_PEER_ADDR_PARAMS, &paddrparams, &opt_len); if (r < 0) { DC_ERROR(("usrsctp_getsockopt failed: %d", r)); } else { // draft-ietf-rtcweb-data-channel-13 section 5: max initial MTU IPV4 // 1200, IPV6 1280 paddrparams.spp_pathmtu = 1200; // safe for either paddrparams.spp_flags &= ~SPP_PMTUD_ENABLE; paddrparams.spp_flags |= SPP_PMTUD_DISABLE; opt_len = (socklen_t)sizeof(struct sctp_paddrparams); r = usrsctp_setsockopt(mMasterSocket, IPPROTO_SCTP, SCTP_PEER_ADDR_PARAMS, &paddrparams, opt_len); if (r < 0) { DC_ERROR(("usrsctp_getsockopt failed: %d", r)); } else { DC_ERROR(("usrsctp: PMTUD disabled, MTU set to %u", paddrparams.spp_pathmtu)); } } } if (r < 0) { if (errno == EINPROGRESS) { // non-blocking return; } DC_ERROR(("usrsctp_connect failed: %d", errno)); SetReadyState(CLOSED); } else { // We fire ON_CONNECTION via SCTP_COMM_UP when we get that return; } } // Note: currently this doesn't actually notify the application Dispatch(do_AddRef(new DataChannelOnMessageAvailable( DataChannelOnMessageAvailable::ON_CONNECTION, this))); } // Process any pending Opens void DataChannelConnection::ProcessQueuedOpens() { // The nsDeque holds channels with an AddRef applied. Another reference // (may) be held by the DOMDataChannel, unless it's been GC'd. No other // references should exist. // Can't copy nsDeque's. Move into temp array since any that fail will // go back to mPending nsRefPtrDeque temp; RefPtr temp_channel; while (nullptr != (temp_channel = mPending.PopFront())) { temp.Push(temp_channel.forget()); } RefPtr channel; while (nullptr != (channel = temp.PopFront())) { if (channel->mFlags & DATA_CHANNEL_FLAGS_FINISH_OPEN) { DC_DEBUG(("Processing queued open for %p (%u)", channel.get(), channel->mStream)); channel->mFlags &= ~DATA_CHANNEL_FLAGS_FINISH_OPEN; // OpenFinish returns a reference itself, so we need to take it can // Release it channel = OpenFinish(channel.forget()); // may reset the flag and re-push } else { NS_ASSERTION( false, "How did a DataChannel get queued without the FINISH_OPEN flag?"); } } } void DataChannelConnection::SctpDtlsInput(const std::string& aTransportId, const MediaPacket& packet) { if ((packet.type() != MediaPacket::SCTP) || (mTransportId != aTransportId)) { return; } if (MOZ_LOG_TEST(gSCTPLog, LogLevel::Debug)) { char* buf; if ((buf = usrsctp_dumppacket((void*)packet.data(), packet.len(), SCTP_DUMP_INBOUND)) != nullptr) { SCTP_LOG(("%s", buf)); usrsctp_freedumpbuffer(buf); } } // Pass the data to SCTP MutexAutoLock lock(mLock); usrsctp_conninput(reinterpret_cast(mId), packet.data(), packet.len(), 0); } void DataChannelConnection::SendPacket(std::unique_ptr&& packet) { mSTS->Dispatch(NS_NewRunnableFunction( "DataChannelConnection::SendPacket", [this, self = RefPtr(this), packet = std::move(packet)]() mutable { // DC_DEBUG(("%p: SCTP/DTLS sent %ld bytes", this, len)); if (!mTransportId.empty() && mTransportHandler) { mTransportHandler->SendPacket(mTransportId, std::move(*packet)); } })); } int DataChannelConnection::SctpDtlsOutput(void* addr, void* buffer, size_t length, uint8_t tos, uint8_t set_df) { MOZ_DIAGNOSTIC_ASSERT(!mShutdown); if (MOZ_LOG_TEST(gSCTPLog, LogLevel::Debug)) { char* buf; if ((buf = usrsctp_dumppacket(buffer, length, SCTP_DUMP_OUTBOUND)) != nullptr) { SCTP_LOG(("%s", buf)); usrsctp_freedumpbuffer(buf); } } // We're async proxying even if on the STSThread because this is called // with internal SCTP locks held in some cases (such as in usrsctp_connect()). // SCTP has an option for Apple, on IP connections only, to release at least // one of the locks before calling a packet output routine; with changes to // the underlying SCTP stack this might remove the need to use an async proxy. std::unique_ptr packet(new MediaPacket); packet->SetType(MediaPacket::SCTP); packet->Copy(static_cast(buffer), length); if (NS_IsMainThread() && mDeferSend) { mDeferredSend.emplace_back(std::move(packet)); return 0; } SendPacket(std::move(packet)); return 0; // cheat! Packets can always be dropped later anyways } #endif #ifdef ALLOW_DIRECT_SCTP_LISTEN_CONNECT // listen for incoming associations // Blocks! - Don't call this from main thread! bool DataChannelConnection::Listen(unsigned short port) { struct sockaddr_in addr; socklen_t addr_len; NS_WARNING_ASSERTION(!NS_IsMainThread(), "Blocks, do not call from main thread!!!"); /* Acting as the 'server' */ memset((void*)&addr, 0, sizeof(addr)); # ifdef HAVE_SIN_LEN addr.sin_len = sizeof(struct sockaddr_in); # endif addr.sin_family = AF_INET; addr.sin_port = htons(port); addr.sin_addr.s_addr = htonl(INADDR_ANY); DC_DEBUG(("Waiting for connections on port %u", ntohs(addr.sin_port))); { MutexAutoLock lock(mLock); SetReadyState(CONNECTING); } if (usrsctp_bind(mMasterSocket, reinterpret_cast(&addr), sizeof(struct sockaddr_in)) < 0) { DC_ERROR(("***Failed userspace_bind")); return false; } if (usrsctp_listen(mMasterSocket, 1) < 0) { DC_ERROR(("***Failed userspace_listen")); return false; } DC_DEBUG(("Accepting connection")); addr_len = 0; if ((mSocket = usrsctp_accept(mMasterSocket, nullptr, &addr_len)) == nullptr) { DC_ERROR(("***Failed accept")); return false; } { MutexAutoLock lock(mLock); SetReadyState(OPEN); } struct linger l; l.l_onoff = 1; l.l_linger = 0; if (usrsctp_setsockopt(mSocket, SOL_SOCKET, SO_LINGER, (const void*)&l, (socklen_t)sizeof(struct linger)) < 0) { DC_WARN(("Couldn't set SO_LINGER on SCTP socket")); } // Notify Connection open // XXX We need to make sure connection sticks around until the message is // delivered DC_DEBUG(("%s: sending ON_CONNECTION for %p", __FUNCTION__, this)); Dispatch(do_AddRef(new DataChannelOnMessageAvailable( DataChannelOnMessageAvailable::ON_CONNECTION, this, (DataChannel*)nullptr))); return true; } // Blocks! - Don't call this from main thread! bool DataChannelConnection::Connect(const char* addr, unsigned short port) { struct sockaddr_in addr4; struct sockaddr_in6 addr6; NS_WARNING_ASSERTION(!NS_IsMainThread(), "Blocks, do not call from main thread!!!"); /* Acting as the connector */ DC_DEBUG(("Connecting to %s, port %u", addr, port)); memset((void*)&addr4, 0, sizeof(struct sockaddr_in)); memset((void*)&addr6, 0, sizeof(struct sockaddr_in6)); # ifdef HAVE_SIN_LEN addr4.sin_len = sizeof(struct sockaddr_in); # endif # ifdef HAVE_SIN6_LEN addr6.sin6_len = sizeof(struct sockaddr_in6); # endif addr4.sin_family = AF_INET; addr6.sin6_family = AF_INET6; addr4.sin_port = htons(port); addr6.sin6_port = htons(port); { MutexAutoLock lock(mLock); SetReadyState(CONNECTING); } # if !defined(__Userspace_os_Windows) if (inet_pton(AF_INET6, addr, &addr6.sin6_addr) == 1) { if (usrsctp_connect(mMasterSocket, reinterpret_cast(&addr6), sizeof(struct sockaddr_in6)) < 0) { DC_ERROR(("*** Failed userspace_connect")); return false; } } else if (inet_pton(AF_INET, addr, &addr4.sin_addr) == 1) { if (usrsctp_connect(mMasterSocket, reinterpret_cast(&addr4), sizeof(struct sockaddr_in)) < 0) { DC_ERROR(("*** Failed userspace_connect")); return false; } } else { DC_ERROR(("*** Illegal destination address.")); } # else { struct sockaddr_storage ss; int sslen = sizeof(ss); if (!WSAStringToAddressA(const_cast(addr), AF_INET6, nullptr, (struct sockaddr*)&ss, &sslen)) { addr6.sin6_addr = (reinterpret_cast(&ss))->sin6_addr; if (usrsctp_connect(mMasterSocket, reinterpret_cast(&addr6), sizeof(struct sockaddr_in6)) < 0) { DC_ERROR(("*** Failed userspace_connect")); return false; } } else if (!WSAStringToAddressA(const_cast(addr), AF_INET, nullptr, (struct sockaddr*)&ss, &sslen)) { addr4.sin_addr = (reinterpret_cast(&ss))->sin_addr; if (usrsctp_connect(mMasterSocket, reinterpret_cast(&addr4), sizeof(struct sockaddr_in)) < 0) { DC_ERROR(("*** Failed userspace_connect")); return false; } } else { DC_ERROR(("*** Illegal destination address.")); } } # endif mSocket = mMasterSocket; DC_DEBUG(("connect() succeeded! Entering connected mode")); { MutexAutoLock lock(mLock); SetReadyState(OPEN); } // Notify Connection open // XXX We need to make sure connection sticks around until the message is // delivered DC_DEBUG(("%s: sending ON_CONNECTION for %p", __FUNCTION__, this)); Dispatch(do_AddRef(new DataChannelOnMessageAvailable( DataChannelOnMessageAvailable::ON_CONNECTION, this, (DataChannel*)nullptr))); return true; } #endif DataChannel* DataChannelConnection::FindChannelByStream(uint16_t stream) { return mChannels.Get(stream).get(); } uint16_t DataChannelConnection::FindFreeStream() { ASSERT_WEBRTC(NS_IsMainThread()); uint16_t i, limit; limit = MAX_NUM_STREAMS; MOZ_ASSERT(mAllocateEven.isSome()); for (i = (*mAllocateEven ? 0 : 1); i < limit; i += 2) { if (mChannels.Get(i)) { continue; } // Verify it's not still in the process of closing size_t j; for (j = 0; j < mStreamsResetting.Length(); ++j) { if (mStreamsResetting[j] == i) { break; } } if (j == mStreamsResetting.Length()) { return i; } } return INVALID_STREAM; } uint32_t DataChannelConnection::UpdateCurrentStreamIndex() { RefPtr channel = mChannels.GetNextChannel(mCurrentStream); if (!channel) { mCurrentStream = 0; } else { mCurrentStream = channel->mStream; } return mCurrentStream; } uint32_t DataChannelConnection::GetCurrentStreamIndex() { return mCurrentStream; } bool DataChannelConnection::RequestMoreStreams(int32_t aNeeded) { struct sctp_status status; struct sctp_add_streams sas; uint32_t outStreamsNeeded; socklen_t len; if (aNeeded + mNegotiatedIdLimit > MAX_NUM_STREAMS) { aNeeded = MAX_NUM_STREAMS - mNegotiatedIdLimit; } if (aNeeded <= 0) { return false; } len = (socklen_t)sizeof(struct sctp_status); if (usrsctp_getsockopt(mMasterSocket, IPPROTO_SCTP, SCTP_STATUS, &status, &len) < 0) { DC_ERROR(("***failed: getsockopt SCTP_STATUS")); return false; } outStreamsNeeded = aNeeded; // number to add // Note: if multiple channel opens happen when we don't have enough space, // we'll call RequestMoreStreams() multiple times memset(&sas, 0, sizeof(sas)); sas.sas_instrms = 0; sas.sas_outstrms = (uint16_t)outStreamsNeeded; /* XXX error handling */ // Doesn't block, we get an event when it succeeds or fails if (usrsctp_setsockopt(mMasterSocket, IPPROTO_SCTP, SCTP_ADD_STREAMS, &sas, (socklen_t)sizeof(struct sctp_add_streams)) < 0) { if (errno == EALREADY) { DC_DEBUG(("Already have %u output streams", outStreamsNeeded)); return true; } DC_ERROR(("***failed: setsockopt ADD errno=%d", errno)); return false; } DC_DEBUG(("Requested %u more streams", outStreamsNeeded)); // We add to mNegotiatedIdLimit when we get a SCTP_STREAM_CHANGE_EVENT and the // values are larger than mNegotiatedIdLimit return true; } // Returns a POSIX error code. int DataChannelConnection::SendControlMessage(const uint8_t* data, uint32_t len, uint16_t stream) { struct sctp_sendv_spa info = {0}; // General flags info.sendv_flags = SCTP_SEND_SNDINFO_VALID; // Set stream identifier, protocol identifier and flags info.sendv_sndinfo.snd_sid = stream; info.sendv_sndinfo.snd_flags = SCTP_EOR; info.sendv_sndinfo.snd_ppid = htonl(DATA_CHANNEL_PPID_CONTROL); // Create message instance and send // Note: Main-thread IO, but doesn't block #if (UINT32_MAX > SIZE_MAX) if (len > SIZE_MAX) { return EMSGSIZE; } #endif OutgoingMsg msg(info, data, (size_t)len); bool buffered; int error = SendMsgInternalOrBuffer(mBufferedControl, msg, buffered, nullptr); // Set pending type (if buffered) if (!error && buffered && !mPendingType) { mPendingType = PENDING_DCEP; } return error; } // Returns a POSIX error code. int DataChannelConnection::SendOpenAckMessage(uint16_t stream) { struct rtcweb_datachannel_ack ack; memset(&ack, 0, sizeof(struct rtcweb_datachannel_ack)); ack.msg_type = DATA_CHANNEL_ACK; return SendControlMessage((const uint8_t*)&ack, sizeof(ack), stream); } // Returns a POSIX error code. int DataChannelConnection::SendOpenRequestMessage( const nsACString& label, const nsACString& protocol, uint16_t stream, bool unordered, uint16_t prPolicy, uint32_t prValue) { const int label_len = label.Length(); // not including nul const int proto_len = protocol.Length(); // not including nul // careful - request struct include one char for the label const int req_size = sizeof(struct rtcweb_datachannel_open_request) - 1 + label_len + proto_len; UniqueFreePtr req( (struct rtcweb_datachannel_open_request*)moz_xmalloc(req_size)); memset(req.get(), 0, req_size); req->msg_type = DATA_CHANNEL_OPEN_REQUEST; switch (prPolicy) { case SCTP_PR_SCTP_NONE: req->channel_type = DATA_CHANNEL_RELIABLE; break; case SCTP_PR_SCTP_TTL: req->channel_type = DATA_CHANNEL_PARTIAL_RELIABLE_TIMED; break; case SCTP_PR_SCTP_RTX: req->channel_type = DATA_CHANNEL_PARTIAL_RELIABLE_REXMIT; break; default: return EINVAL; } if (unordered) { // Per the current types, all differ by 0x80 between ordered and unordered req->channel_type |= 0x80; // NOTE: be careful if new types are added in the future } req->reliability_param = htonl(prValue); req->priority = htons(0); /* XXX: add support */ req->label_length = htons(label_len); req->protocol_length = htons(proto_len); memcpy(&req->label[0], PromiseFlatCString(label).get(), label_len); memcpy(&req->label[label_len], PromiseFlatCString(protocol).get(), proto_len); // TODO: req_size is an int... that looks hairy int error = SendControlMessage((const uint8_t*)req.get(), req_size, stream); return error; } // XXX This should use a separate thread (outbound queue) which should // select() to know when to *try* to send data to the socket again. // Alternatively, it can use a timeout, but that's guaranteed to be wrong // (just not sure in what direction). We could re-implement NSPR's // PR_POLL_WRITE/etc handling... with a lot of work. // Better yet, use the SCTP stack's notifications on buffer state to avoid // filling the SCTP's buffers. // returns if we're still blocked (true) bool DataChannelConnection::SendDeferredMessages() { RefPtr channel; // we may null out the refs to this // This may block while something is modifying channels, but should not block // for IO ASSERT_WEBRTC(!NS_IsMainThread()); mLock.AssertCurrentThreadOwns(); DC_DEBUG(("SendDeferredMessages called, pending type: %d", mPendingType)); if (!mPendingType) { return false; } // Send pending control messages // Note: If ndata is not active, check if DCEP messages are currently // outstanding. These need to // be sent first before other streams can be used for sending. if (!mBufferedControl.IsEmpty() && (mSendInterleaved || mPendingType == PENDING_DCEP)) { if (SendBufferedMessages(mBufferedControl, nullptr)) { return true; } // Note: There may or may not be pending data messages mPendingType = PENDING_DATA; } bool blocked = false; uint32_t i = GetCurrentStreamIndex(); uint32_t end = i; do { channel = mChannels.Get(i); // Should already be cleared if closing/closed if (!channel || channel->mBufferedData.IsEmpty()) { i = UpdateCurrentStreamIndex(); continue; } // Send buffered data messages // Warning: This will fail in case ndata is inactive and a previously // deallocated data channel has not been closed properly. If you // ever see that no messages can be sent on any channel, this is // likely the cause (an explicit EOR message partially sent whose // remaining chunks are still being waited for). size_t written = 0; mDeferSend = true; blocked = SendBufferedMessages(channel->mBufferedData, &written); mDeferSend = false; if (written) { channel->DecrementBufferedAmount(written); } for (auto&& packet : mDeferredSend) { MOZ_ASSERT(written); SendPacket(std::move(packet)); } mDeferredSend.clear(); // Update current stream index // Note: If ndata is not active, the outstanding data messages on this // stream need to be sent first before other streams can be used for // sending. if (mSendInterleaved || !blocked) { i = UpdateCurrentStreamIndex(); } } while (!blocked && i != end); if (!blocked) { mPendingType = mBufferedControl.IsEmpty() ? PENDING_NONE : PENDING_DCEP; } return blocked; } // Called with mLock locked! // buffer MUST have at least one item! // returns if we're still blocked (true) bool DataChannelConnection::SendBufferedMessages( nsTArray>& buffer, size_t* aWritten) { do { // Re-send message int error = SendMsgInternal(*buffer[0], aWritten); switch (error) { case 0: buffer.RemoveElementAt(0); break; case EAGAIN: #if (EAGAIN != EWOULDBLOCK) case EWOULDBLOCK: #endif return true; default: buffer.RemoveElementAt(0); DC_ERROR(("error on sending: %d", error)); break; } } while (!buffer.IsEmpty()); return false; } // Caller must ensure that length <= SIZE_MAX void DataChannelConnection::HandleOpenRequestMessage( const struct rtcweb_datachannel_open_request* req, uint32_t length, uint16_t stream) { RefPtr channel; uint32_t prValue; uint16_t prPolicy; ASSERT_WEBRTC(!NS_IsMainThread()); mLock.AssertCurrentThreadOwns(); const size_t requiredLength = (sizeof(*req) - 1) + ntohs(req->label_length) + ntohs(req->protocol_length); if (((size_t)length) != requiredLength) { if (((size_t)length) < requiredLength) { DC_ERROR( ("%s: insufficient length: %u, should be %zu. Unable to continue.", __FUNCTION__, length, requiredLength)); return; } DC_WARN(("%s: Inconsistent length: %u, should be %zu", __FUNCTION__, length, requiredLength)); } DC_DEBUG(("%s: length %u, sizeof(*req) = %zu", __FUNCTION__, length, sizeof(*req))); switch (req->channel_type) { case DATA_CHANNEL_RELIABLE: case DATA_CHANNEL_RELIABLE_UNORDERED: prPolicy = SCTP_PR_SCTP_NONE; break; case DATA_CHANNEL_PARTIAL_RELIABLE_REXMIT: case DATA_CHANNEL_PARTIAL_RELIABLE_REXMIT_UNORDERED: prPolicy = SCTP_PR_SCTP_RTX; break; case DATA_CHANNEL_PARTIAL_RELIABLE_TIMED: case DATA_CHANNEL_PARTIAL_RELIABLE_TIMED_UNORDERED: prPolicy = SCTP_PR_SCTP_TTL; break; default: DC_ERROR(("Unknown channel type %d", req->channel_type)); /* XXX error handling */ return; } prValue = ntohl(req->reliability_param); bool ordered = !(req->channel_type & 0x80); if ((channel = FindChannelByStream(stream))) { if (!channel->mNegotiated) { DC_ERROR( ("HandleOpenRequestMessage: channel for pre-existing stream " "%u that was not externally negotiated. JS is lying to us, or " "there's an id collision.", stream)); /* XXX: some error handling */ } else { DC_DEBUG(("Open for externally negotiated channel %u", stream)); // XXX should also check protocol, maybe label if (prPolicy != channel->mPrPolicy || prValue != channel->mPrValue || ordered != channel->mOrdered) { DC_WARN( ("external negotiation mismatch with OpenRequest:" "channel %u, policy %u/%u, value %u/%u, ordered %d/%d", stream, prPolicy, channel->mPrPolicy, prValue, channel->mPrValue, static_cast(ordered), static_cast(channel->mOrdered))); } } return; } if (stream >= mNegotiatedIdLimit) { DC_ERROR(("%s: stream %u out of bounds (%zu)", __FUNCTION__, stream, mNegotiatedIdLimit)); return; } nsCString label( nsDependentCSubstring(&req->label[0], ntohs(req->label_length))); nsCString protocol(nsDependentCSubstring( &req->label[ntohs(req->label_length)], ntohs(req->protocol_length))); channel = new DataChannel(this, stream, DataChannel::OPEN, label, protocol, prPolicy, prValue, ordered, false, nullptr, nullptr); mChannels.Insert(channel); DC_DEBUG(("%s: sending ON_CHANNEL_CREATED for %s/%s: %u", __FUNCTION__, channel->mLabel.get(), channel->mProtocol.get(), stream)); Dispatch(do_AddRef(new DataChannelOnMessageAvailable( DataChannelOnMessageAvailable::ON_CHANNEL_CREATED, this, channel))); DC_DEBUG(("%s: deferring sending ON_CHANNEL_OPEN for %p", __FUNCTION__, channel.get())); channel->AnnounceOpen(); // Note that any message can be buffered; SendOpenAckMessage may // error later than this check. const auto error = SendOpenAckMessage(channel->mStream); if (error) { DC_ERROR(("SendOpenRequest failed, error = %d", error)); Dispatch(NS_NewRunnableFunction( "DataChannelConnection::HandleOpenRequestMessage", [channel, connection = RefPtr(this)]() { MutexAutoLock mLock(connection->mLock); // Close the channel on failure connection->CloseInt(channel); })); return; } DeliverQueuedData(channel->mStream); } // NOTE: the updated spec from the IETF says we should set in-order until we // receive an ACK. That would make this code moot. Keep it for now for // backwards compatibility. void DataChannelConnection::DeliverQueuedData(uint16_t stream) { mLock.AssertCurrentThreadOwns(); mQueuedData.RemoveElementsBy([stream, this](const auto& dataItem) { const bool match = dataItem->mStream == stream; if (match) { DC_DEBUG(("Delivering queued data for stream %u, length %u", stream, dataItem->mLength)); // Deliver the queued data HandleDataMessage(dataItem->mData, dataItem->mLength, dataItem->mPpid, dataItem->mStream, dataItem->mFlags); } return match; }); } // Caller must ensure that length <= SIZE_MAX void DataChannelConnection::HandleOpenAckMessage( const struct rtcweb_datachannel_ack* ack, uint32_t length, uint16_t stream) { DataChannel* channel; mLock.AssertCurrentThreadOwns(); channel = FindChannelByStream(stream); if (NS_WARN_IF(!channel)) { return; } DC_DEBUG(("OpenAck received for stream %u, waiting=%d", stream, (channel->mFlags & DATA_CHANNEL_FLAGS_WAITING_ACK) ? 1 : 0)); channel->mFlags &= ~DATA_CHANNEL_FLAGS_WAITING_ACK; } // Caller must ensure that length <= SIZE_MAX void DataChannelConnection::HandleUnknownMessage(uint32_t ppid, uint32_t length, uint16_t stream) { /* XXX: Send an error message? */ DC_ERROR(("unknown DataChannel message received: %u, len %u on stream %d", ppid, length, stream)); // XXX Log to JS error console if possible } uint8_t DataChannelConnection::BufferMessage(nsACString& recvBuffer, const void* data, uint32_t length, uint32_t ppid, int flags) { const char* buffer = (const char*)data; uint8_t bufferFlags = 0; if ((flags & MSG_EOR) && ppid != DATA_CHANNEL_PPID_BINARY_PARTIAL && ppid != DATA_CHANNEL_PPID_DOMSTRING_PARTIAL) { bufferFlags |= DATA_CHANNEL_BUFFER_MESSAGE_FLAGS_COMPLETE; // Return directly if nothing has been buffered if (recvBuffer.IsEmpty()) { return bufferFlags; } } // Ensure it doesn't blow up our buffer // TODO: Change 'WEBRTC_DATACHANNEL_MAX_MESSAGE_SIZE_LOCAL' to whatever the // new buffer is capable of holding. if (((uint64_t)recvBuffer.Length()) + ((uint64_t)length) > WEBRTC_DATACHANNEL_MAX_MESSAGE_SIZE_LOCAL) { bufferFlags |= DATA_CHANNEL_BUFFER_MESSAGE_FLAGS_TOO_LARGE; return bufferFlags; } // Copy & add to receive buffer recvBuffer.Append(buffer, length); bufferFlags |= DATA_CHANNEL_BUFFER_MESSAGE_FLAGS_BUFFERED; return bufferFlags; } void DataChannelConnection::HandleDataMessage(const void* data, size_t length, uint32_t ppid, uint16_t stream, int flags) { DataChannel* channel; const char* buffer = (const char*)data; mLock.AssertCurrentThreadOwns(); channel = FindChannelByStream(stream); // Note: Until we support SIZE_MAX sized messages, we need this check #if (SIZE_MAX > UINT32_MAX) if (length > UINT32_MAX) { DC_ERROR(("DataChannel: Cannot handle message of size %zu (max=%" PRIu32 ")", length, UINT32_MAX)); CloseInt(channel); return; } #endif uint32_t data_length = (uint32_t)length; // XXX A closed channel may trip this... check // NOTE: the updated spec from the IETF says we should set in-order until we // receive an ACK. That would make this code moot. Keep it for now for // backwards compatibility. if (!channel) { // In the updated 0-RTT open case, the sender can send data immediately // after Open, and doesn't set the in-order bit (since we don't have a // response or ack). Also, with external negotiation, data can come in // before we're told about the external negotiation. We need to buffer // data until either a) Open comes in, if the ordering get messed up, // or b) the app tells us this channel was externally negotiated. When // these occur, we deliver the data. // Since this is rare and non-performance, keep a single list of queued // data messages to deliver once the channel opens. DC_DEBUG(("Queuing data for stream %u, length %u", stream, data_length)); // Copies data mQueuedData.AppendElement( new QueuedDataMessage(stream, ppid, flags, data, data_length)); return; } bool is_binary = true; uint8_t bufferFlags; int32_t type; const char* info = ""; if (ppid == DATA_CHANNEL_PPID_DOMSTRING_PARTIAL || ppid == DATA_CHANNEL_PPID_DOMSTRING) { is_binary = false; } if (is_binary != channel->mIsRecvBinary && !channel->mRecvBuffer.IsEmpty()) { NS_WARNING("DataChannel message aborted by fragment type change!"); // TODO: Maybe closing would be better as this is a hard to detect protocol // violation? channel->mRecvBuffer.Truncate(0); } channel->mIsRecvBinary = is_binary; // Remaining chunks of previously truncated message (due to the buffer being // full)? if (channel->mFlags & DATA_CHANNEL_FLAGS_CLOSING_TOO_LARGE) { DC_ERROR( ("DataChannel: Ignoring partial message of length %u, buffer full and " "closing", data_length)); // Only unblock if unordered if (!channel->mOrdered && (flags & MSG_EOR)) { channel->mFlags &= ~DATA_CHANNEL_FLAGS_CLOSING_TOO_LARGE; } } // Buffer message until complete bufferFlags = BufferMessage(channel->mRecvBuffer, buffer, data_length, ppid, flags); if (bufferFlags & DATA_CHANNEL_BUFFER_MESSAGE_FLAGS_TOO_LARGE) { DC_ERROR( ("DataChannel: Buffered message would become too large to handle, " "closing channel")); channel->mRecvBuffer.Truncate(0); channel->mFlags |= DATA_CHANNEL_FLAGS_CLOSING_TOO_LARGE; CloseInt(channel); return; } if (!(bufferFlags & DATA_CHANNEL_BUFFER_MESSAGE_FLAGS_COMPLETE)) { DC_DEBUG( ("DataChannel: Partial %s message of length %u (total %u) on channel " "id %u", is_binary ? "binary" : "string", data_length, channel->mRecvBuffer.Length(), channel->mStream)); return; // Not ready to notify application } if (bufferFlags & DATA_CHANNEL_BUFFER_MESSAGE_FLAGS_BUFFERED) { data_length = channel->mRecvBuffer.Length(); } // Complain about large messages (only complain - we can handle it) if (data_length > WEBRTC_DATACHANNEL_MAX_MESSAGE_SIZE_LOCAL) { DC_WARN( ("DataChannel: Received message of length %u is > announced maximum " "message size (%u)", data_length, WEBRTC_DATACHANNEL_MAX_MESSAGE_SIZE_LOCAL)); } switch (ppid) { case DATA_CHANNEL_PPID_DOMSTRING: DC_DEBUG( ("DataChannel: Received string message of length %u on channel %u", data_length, channel->mStream)); type = DataChannelOnMessageAvailable::ON_DATA_STRING; if (bufferFlags & DATA_CHANNEL_BUFFER_MESSAGE_FLAGS_BUFFERED) { info = " (string fragmented)"; } // else send using recvData normally // WebSockets checks IsUTF8() here; we can try to deliver it break; case DATA_CHANNEL_PPID_BINARY: DC_DEBUG( ("DataChannel: Received binary message of length %u on channel id %u", data_length, channel->mStream)); type = DataChannelOnMessageAvailable::ON_DATA_BINARY; if (bufferFlags & DATA_CHANNEL_BUFFER_MESSAGE_FLAGS_BUFFERED) { info = " (binary fragmented)"; } // else send using recvData normally break; default: NS_ERROR("Unknown data PPID"); DC_ERROR(("Unknown data PPID %" PRIu32, ppid)); return; } channel->WithTrafficCounters( [&data_length](DataChannel::TrafficCounters& counters) { counters.mMessagesReceived++; counters.mBytesReceived += data_length; }); // Notify onmessage DC_DEBUG(("%s: sending ON_DATA_%s%s for %p", __FUNCTION__, (type == DataChannelOnMessageAvailable::ON_DATA_STRING) ? "STRING" : "BINARY", info, channel)); if (bufferFlags & DATA_CHANNEL_BUFFER_MESSAGE_FLAGS_BUFFERED) { channel->SendOrQueue(new DataChannelOnMessageAvailable( type, this, channel, channel->mRecvBuffer)); channel->mRecvBuffer.Truncate(0); } else { nsAutoCString recvData(buffer, data_length); // copies (<64) or allocates channel->SendOrQueue( new DataChannelOnMessageAvailable(type, this, channel, recvData)); } } void DataChannelConnection::HandleDCEPMessage(const void* buffer, size_t length, uint32_t ppid, uint16_t stream, int flags) { const struct rtcweb_datachannel_open_request* req; const struct rtcweb_datachannel_ack* ack; // Note: Until we support SIZE_MAX sized messages, we need this check #if (SIZE_MAX > UINT32_MAX) if (length > UINT32_MAX) { DC_ERROR(("DataChannel: Cannot handle message of size %zu (max=%u)", length, UINT32_MAX)); Stop(); return; } #endif uint32_t data_length = (uint32_t)length; mLock.AssertCurrentThreadOwns(); // Buffer message until complete const uint8_t bufferFlags = BufferMessage(mRecvBuffer, buffer, data_length, ppid, flags); if (bufferFlags & DATA_CHANNEL_BUFFER_MESSAGE_FLAGS_TOO_LARGE) { DC_ERROR( ("DataChannel: Buffered message would become too large to handle, " "closing connection")); mRecvBuffer.Truncate(0); Stop(); return; } if (!(bufferFlags & DATA_CHANNEL_BUFFER_MESSAGE_FLAGS_COMPLETE)) { DC_DEBUG(("Buffered partial DCEP message of length %u", data_length)); return; } if (bufferFlags & DATA_CHANNEL_BUFFER_MESSAGE_FLAGS_BUFFERED) { buffer = reinterpret_cast(mRecvBuffer.BeginReading()); data_length = mRecvBuffer.Length(); } req = static_cast(buffer); DC_DEBUG(("Handling DCEP message of length %u", data_length)); // Ensure minimum message size (ack is the smallest DCEP message) if ((size_t)data_length < sizeof(*ack)) { DC_WARN(("Ignored invalid DCEP message (too short)")); return; } switch (req->msg_type) { case DATA_CHANNEL_OPEN_REQUEST: // structure includes a possibly-unused char label[1] (in a packed // structure) if (NS_WARN_IF((size_t)data_length < sizeof(*req) - 1)) { return; } HandleOpenRequestMessage(req, data_length, stream); break; case DATA_CHANNEL_ACK: // >= sizeof(*ack) checked above ack = static_cast(buffer); HandleOpenAckMessage(ack, data_length, stream); break; default: HandleUnknownMessage(ppid, data_length, stream); break; } // Reset buffer mRecvBuffer.Truncate(0); } // Called with mLock locked! void DataChannelConnection::HandleMessage(const void* buffer, size_t length, uint32_t ppid, uint16_t stream, int flags) { mLock.AssertCurrentThreadOwns(); switch (ppid) { case DATA_CHANNEL_PPID_CONTROL: HandleDCEPMessage(buffer, length, ppid, stream, flags); break; case DATA_CHANNEL_PPID_DOMSTRING_PARTIAL: case DATA_CHANNEL_PPID_DOMSTRING: case DATA_CHANNEL_PPID_BINARY_PARTIAL: case DATA_CHANNEL_PPID_BINARY: HandleDataMessage(buffer, length, ppid, stream, flags); break; default: DC_ERROR(( "Unhandled message of length %zu PPID %u on stream %u received (%s).", length, ppid, stream, (flags & MSG_EOR) ? "complete" : "partial")); break; } } void DataChannelConnection::HandleAssociationChangeEvent( const struct sctp_assoc_change* sac) { mLock.AssertCurrentThreadOwns(); uint32_t i, n; const auto readyState = GetReadyState(); switch (sac->sac_state) { case SCTP_COMM_UP: DC_DEBUG(("Association change: SCTP_COMM_UP")); if (readyState == CONNECTING) { mSocket = mMasterSocket; SetReadyState(OPEN); DC_DEBUG(("Negotiated number of incoming streams: %" PRIu16, sac->sac_inbound_streams)); DC_DEBUG(("Negotiated number of outgoing streams: %" PRIu16, sac->sac_outbound_streams)); mNegotiatedIdLimit = std::max(mNegotiatedIdLimit, static_cast(std::max(sac->sac_outbound_streams, sac->sac_inbound_streams))); Dispatch(do_AddRef(new DataChannelOnMessageAvailable( DataChannelOnMessageAvailable::ON_CONNECTION, this))); DC_DEBUG(("DTLS connect() succeeded! Entering connected mode")); // Open any streams pending... ProcessQueuedOpens(); } else if (readyState == OPEN) { DC_DEBUG(("DataConnection Already OPEN")); } else { DC_ERROR(("Unexpected state: %d", readyState)); } break; case SCTP_COMM_LOST: DC_DEBUG(("Association change: SCTP_COMM_LOST")); // This association is toast, so also close all the channels -- from // mainthread! Stop(); break; case SCTP_RESTART: DC_DEBUG(("Association change: SCTP_RESTART")); break; case SCTP_SHUTDOWN_COMP: DC_DEBUG(("Association change: SCTP_SHUTDOWN_COMP")); Stop(); break; case SCTP_CANT_STR_ASSOC: DC_DEBUG(("Association change: SCTP_CANT_STR_ASSOC")); break; default: DC_DEBUG(("Association change: UNKNOWN")); break; } DC_DEBUG(("Association change: streams (in/out) = (%u/%u)", sac->sac_inbound_streams, sac->sac_outbound_streams)); if (NS_WARN_IF(!sac)) { return; } n = sac->sac_length - sizeof(*sac); if ((sac->sac_state == SCTP_COMM_UP) || (sac->sac_state == SCTP_RESTART)) { if (n > 0) { for (i = 0; i < n; ++i) { switch (sac->sac_info[i]) { case SCTP_ASSOC_SUPPORTS_PR: DC_DEBUG(("Supports: PR")); break; case SCTP_ASSOC_SUPPORTS_AUTH: DC_DEBUG(("Supports: AUTH")); break; case SCTP_ASSOC_SUPPORTS_ASCONF: DC_DEBUG(("Supports: ASCONF")); break; case SCTP_ASSOC_SUPPORTS_MULTIBUF: DC_DEBUG(("Supports: MULTIBUF")); break; case SCTP_ASSOC_SUPPORTS_RE_CONFIG: DC_DEBUG(("Supports: RE-CONFIG")); break; #if defined(SCTP_ASSOC_SUPPORTS_INTERLEAVING) case SCTP_ASSOC_SUPPORTS_INTERLEAVING: DC_DEBUG(("Supports: NDATA")); // TODO: This should probably be set earlier above in 'case // SCTP_COMM_UP' but we also need this for 'SCTP_RESTART'. mSendInterleaved = true; break; #endif default: DC_ERROR(("Supports: UNKNOWN(0x%02x)", sac->sac_info[i])); break; } } } } else if (((sac->sac_state == SCTP_COMM_LOST) || (sac->sac_state == SCTP_CANT_STR_ASSOC)) && (n > 0)) { DC_DEBUG(("Association: ABORT =")); for (i = 0; i < n; ++i) { DC_DEBUG((" 0x%02x", sac->sac_info[i])); } } if ((sac->sac_state == SCTP_CANT_STR_ASSOC) || (sac->sac_state == SCTP_SHUTDOWN_COMP) || (sac->sac_state == SCTP_COMM_LOST)) { return; } } void DataChannelConnection::HandlePeerAddressChangeEvent( const struct sctp_paddr_change* spc) { const char* addr = ""; #if !defined(__Userspace_os_Windows) char addr_buf[INET6_ADDRSTRLEN]; struct sockaddr_in* sin; struct sockaddr_in6* sin6; #endif switch (spc->spc_aaddr.ss_family) { case AF_INET: #if !defined(__Userspace_os_Windows) sin = (struct sockaddr_in*)&spc->spc_aaddr; addr = inet_ntop(AF_INET, &sin->sin_addr, addr_buf, INET6_ADDRSTRLEN); #endif break; case AF_INET6: #if !defined(__Userspace_os_Windows) sin6 = (struct sockaddr_in6*)&spc->spc_aaddr; addr = inet_ntop(AF_INET6, &sin6->sin6_addr, addr_buf, INET6_ADDRSTRLEN); #endif break; case AF_CONN: addr = "DTLS connection"; break; default: break; } DC_DEBUG(("Peer address %s is now ", addr)); switch (spc->spc_state) { case SCTP_ADDR_AVAILABLE: DC_DEBUG(("SCTP_ADDR_AVAILABLE")); break; case SCTP_ADDR_UNREACHABLE: DC_DEBUG(("SCTP_ADDR_UNREACHABLE")); break; case SCTP_ADDR_REMOVED: DC_DEBUG(("SCTP_ADDR_REMOVED")); break; case SCTP_ADDR_ADDED: DC_DEBUG(("SCTP_ADDR_ADDED")); break; case SCTP_ADDR_MADE_PRIM: DC_DEBUG(("SCTP_ADDR_MADE_PRIM")); break; case SCTP_ADDR_CONFIRMED: DC_DEBUG(("SCTP_ADDR_CONFIRMED")); break; default: DC_ERROR(("UNKNOWN SCP STATE")); break; } if (spc->spc_error) { DC_ERROR((" (error = 0x%08x).\n", spc->spc_error)); } } void DataChannelConnection::HandleRemoteErrorEvent( const struct sctp_remote_error* sre) { size_t i, n; n = sre->sre_length - sizeof(struct sctp_remote_error); DC_WARN(("Remote Error (error = 0x%04x): ", sre->sre_error)); for (i = 0; i < n; ++i) { DC_WARN((" 0x%02x", sre->sre_data[i])); } } void DataChannelConnection::HandleShutdownEvent( const struct sctp_shutdown_event* sse) { DC_DEBUG(("Shutdown event.")); /* XXX: notify all channels. */ // Attempts to actually send anything will fail } void DataChannelConnection::HandleAdaptationIndication( const struct sctp_adaptation_event* sai) { DC_DEBUG(("Adaptation indication: %x.", sai->sai_adaptation_ind)); } void DataChannelConnection::HandlePartialDeliveryEvent( const struct sctp_pdapi_event* spde) { // Note: Be aware that stream and sequence number being u32 instead of u16 is // a bug in the SCTP API. This may change in the future. DC_DEBUG(("Partial delivery event: ")); switch (spde->pdapi_indication) { case SCTP_PARTIAL_DELIVERY_ABORTED: DC_DEBUG(("delivery aborted ")); break; default: DC_ERROR(("??? ")); break; } DC_DEBUG(("(flags = %x), stream = %" PRIu32 ", sn = %" PRIu32, spde->pdapi_flags, spde->pdapi_stream, spde->pdapi_seq)); // Validate stream ID if (spde->pdapi_stream >= UINT16_MAX) { DC_ERROR(("Invalid stream id in partial delivery event: %" PRIu32 "\n", spde->pdapi_stream)); return; } // Find channel and reset buffer DataChannel* channel = FindChannelByStream((uint16_t)spde->pdapi_stream); if (channel) { DC_WARN(("Abort partially delivered message of %u bytes\n", channel->mRecvBuffer.Length())); channel->mRecvBuffer.Truncate(0); } } void DataChannelConnection::HandleSendFailedEvent( const struct sctp_send_failed_event* ssfe) { size_t i, n; if (ssfe->ssfe_flags & SCTP_DATA_UNSENT) { DC_DEBUG(("Unsent ")); } if (ssfe->ssfe_flags & SCTP_DATA_SENT) { DC_DEBUG(("Sent ")); } if (ssfe->ssfe_flags & ~(SCTP_DATA_SENT | SCTP_DATA_UNSENT)) { DC_DEBUG(("(flags = %x) ", ssfe->ssfe_flags)); } DC_DEBUG( ("message with PPID = %u, SID = %d, flags: 0x%04x due to error = 0x%08x", ntohl(ssfe->ssfe_info.snd_ppid), ssfe->ssfe_info.snd_sid, ssfe->ssfe_info.snd_flags, ssfe->ssfe_error)); n = ssfe->ssfe_length - sizeof(struct sctp_send_failed_event); for (i = 0; i < n; ++i) { DC_DEBUG((" 0x%02x", ssfe->ssfe_data[i])); } } void DataChannelConnection::ClearResets() { // Clear all pending resets if (!mStreamsResetting.IsEmpty()) { DC_DEBUG(("Clearing resets for %zu streams", mStreamsResetting.Length())); } for (uint32_t i = 0; i < mStreamsResetting.Length(); ++i) { RefPtr channel; channel = FindChannelByStream(mStreamsResetting[i]); if (channel) { DC_DEBUG(("Forgetting channel %u (%p) with pending reset", channel->mStream, channel.get())); // TODO: Do we _really_ want to remove this? Are we allowed to reuse the // id? mChannels.Remove(channel); } } mStreamsResetting.Clear(); } void DataChannelConnection::ResetOutgoingStream(uint16_t stream) { uint32_t i; mLock.AssertCurrentThreadOwns(); DC_DEBUG( ("Connection %p: Resetting outgoing stream %u", (void*)this, stream)); // Rarely has more than a couple items and only for a short time for (i = 0; i < mStreamsResetting.Length(); ++i) { if (mStreamsResetting[i] == stream) { return; } } mStreamsResetting.AppendElement(stream); } void DataChannelConnection::SendOutgoingStreamReset() { struct sctp_reset_streams* srs; uint32_t i; size_t len; DC_DEBUG(("Connection %p: Sending outgoing stream reset for %zu streams", (void*)this, mStreamsResetting.Length())); mLock.AssertCurrentThreadOwns(); if (mStreamsResetting.IsEmpty()) { DC_DEBUG(("No streams to reset")); return; } len = sizeof(sctp_assoc_t) + (2 + mStreamsResetting.Length()) * sizeof(uint16_t); srs = static_cast( moz_xmalloc(len)); // infallible malloc memset(srs, 0, len); srs->srs_flags = SCTP_STREAM_RESET_OUTGOING; srs->srs_number_streams = mStreamsResetting.Length(); for (i = 0; i < mStreamsResetting.Length(); ++i) { srs->srs_stream_list[i] = mStreamsResetting[i]; } if (usrsctp_setsockopt(mMasterSocket, IPPROTO_SCTP, SCTP_RESET_STREAMS, srs, (socklen_t)len) < 0) { DC_ERROR(("***failed: setsockopt RESET, errno %d", errno)); // if errno == EALREADY, this is normal - we can't send another reset // with one pending. // When we get an incoming reset (which may be a response to our // outstanding one), see if we have any pending outgoing resets and // send them } else { mStreamsResetting.Clear(); } free(srs); } void DataChannelConnection::HandleStreamResetEvent( const struct sctp_stream_reset_event* strrst) { uint32_t n, i; RefPtr channel; // since we may null out the ref to the channel if (!(strrst->strreset_flags & SCTP_STREAM_RESET_DENIED) && !(strrst->strreset_flags & SCTP_STREAM_RESET_FAILED)) { n = (strrst->strreset_length - sizeof(struct sctp_stream_reset_event)) / sizeof(uint16_t); for (i = 0; i < n; ++i) { if (strrst->strreset_flags & SCTP_STREAM_RESET_INCOMING_SSN) { channel = FindChannelByStream(strrst->strreset_stream_list[i]); if (channel) { // The other side closed the channel // We could be in three states: // 1. Normal state (input and output streams (OPEN) // Notify application, send a RESET in response on our // outbound channel. Go to CLOSED // 2. We sent our own reset (CLOSING); either they crossed on the // wire, or this is a response to our Reset. // Go to CLOSED // 3. We've sent a open but haven't gotten a response yet (CONNECTING) // I believe this is impossible, as we don't have an input stream // yet. DC_DEBUG(("Incoming: Channel %u closed", channel->mStream)); if (mChannels.Remove(channel)) { // Mark the stream for reset (the reset is sent below) ResetOutgoingStream(channel->mStream); } DC_DEBUG(("Disconnected DataChannel %p from connection %p", (void*)channel.get(), (void*)channel->mConnection.get())); channel->StreamClosedLocked(); } else { DC_WARN(("Can't find incoming channel %d", i)); } } } } // Process any pending resets now: if (!mStreamsResetting.IsEmpty()) { DC_DEBUG(("Sending %zu pending resets", mStreamsResetting.Length())); SendOutgoingStreamReset(); } } void DataChannelConnection::HandleStreamChangeEvent( const struct sctp_stream_change_event* strchg) { ASSERT_WEBRTC(!NS_IsMainThread()); if (strchg->strchange_flags == SCTP_STREAM_CHANGE_DENIED) { DC_ERROR(("*** Failed increasing number of streams from %zu (%u/%u)", mNegotiatedIdLimit, strchg->strchange_instrms, strchg->strchange_outstrms)); // XXX FIX! notify pending opens of failure return; } if (strchg->strchange_instrms > mNegotiatedIdLimit) { DC_DEBUG(("Other side increased streams from %zu to %u", mNegotiatedIdLimit, strchg->strchange_instrms)); } uint16_t old_limit = mNegotiatedIdLimit; uint16_t new_limit = std::max(strchg->strchange_outstrms, strchg->strchange_instrms); if (new_limit > mNegotiatedIdLimit) { DC_DEBUG(("Increasing number of streams from %u to %u - adding %u (in: %u)", old_limit, new_limit, new_limit - old_limit, strchg->strchange_instrms)); // make sure both are the same length mNegotiatedIdLimit = new_limit; DC_DEBUG(("New length = %zu (was %d)", mNegotiatedIdLimit, old_limit)); // Re-process any channels waiting for streams. // Linear search, but we don't increase channels often and // the array would only get long in case of an app error normally // Make sure we request enough streams if there's a big jump in streams // Could make a more complex API for OpenXxxFinish() and avoid this loop auto channels = mChannels.GetAll(); size_t num_needed = channels.Length() ? (channels.LastElement()->mStream + 1) : 0; MOZ_ASSERT(num_needed != INVALID_STREAM); if (num_needed > new_limit) { int32_t more_needed = num_needed - ((int32_t)mNegotiatedIdLimit) + 16; DC_DEBUG(("Not enough new streams, asking for %d more", more_needed)); // TODO: parameter is an int32_t but we pass size_t RequestMoreStreams(more_needed); } else if (strchg->strchange_outstrms < strchg->strchange_instrms) { DC_DEBUG(("Requesting %d output streams to match partner", strchg->strchange_instrms - strchg->strchange_outstrms)); RequestMoreStreams(strchg->strchange_instrms - strchg->strchange_outstrms); } ProcessQueuedOpens(); } // else probably not a change in # of streams if ((strchg->strchange_flags & SCTP_STREAM_CHANGE_DENIED) || (strchg->strchange_flags & SCTP_STREAM_CHANGE_FAILED)) { // Other side denied our request. Need to AnnounceClosed some stuff. for (auto& channel : mChannels.GetAll()) { if (channel->mStream >= mNegotiatedIdLimit) { /* XXX: Signal to the other end. */ channel->AnnounceClosed(); // maybe fire onError (bug 843625) } } } } // Called with mLock locked! void DataChannelConnection::HandleNotification( const union sctp_notification* notif, size_t n) { mLock.AssertCurrentThreadOwns(); if (notif->sn_header.sn_length != (uint32_t)n) { return; } switch (notif->sn_header.sn_type) { case SCTP_ASSOC_CHANGE: HandleAssociationChangeEvent(&(notif->sn_assoc_change)); break; case SCTP_PEER_ADDR_CHANGE: HandlePeerAddressChangeEvent(&(notif->sn_paddr_change)); break; case SCTP_REMOTE_ERROR: HandleRemoteErrorEvent(&(notif->sn_remote_error)); break; case SCTP_SHUTDOWN_EVENT: HandleShutdownEvent(&(notif->sn_shutdown_event)); break; case SCTP_ADAPTATION_INDICATION: HandleAdaptationIndication(&(notif->sn_adaptation_event)); break; case SCTP_AUTHENTICATION_EVENT: DC_DEBUG(("SCTP_AUTHENTICATION_EVENT")); break; case SCTP_SENDER_DRY_EVENT: // DC_DEBUG(("SCTP_SENDER_DRY_EVENT")); break; case SCTP_NOTIFICATIONS_STOPPED_EVENT: DC_DEBUG(("SCTP_NOTIFICATIONS_STOPPED_EVENT")); break; case SCTP_PARTIAL_DELIVERY_EVENT: HandlePartialDeliveryEvent(&(notif->sn_pdapi_event)); break; case SCTP_SEND_FAILED_EVENT: HandleSendFailedEvent(&(notif->sn_send_failed_event)); break; case SCTP_STREAM_RESET_EVENT: HandleStreamResetEvent(&(notif->sn_strreset_event)); break; case SCTP_ASSOC_RESET_EVENT: DC_DEBUG(("SCTP_ASSOC_RESET_EVENT")); break; case SCTP_STREAM_CHANGE_EVENT: HandleStreamChangeEvent(&(notif->sn_strchange_event)); break; default: DC_ERROR(("unknown SCTP event: %u", (uint32_t)notif->sn_header.sn_type)); break; } } int DataChannelConnection::ReceiveCallback(struct socket* sock, void* data, size_t datalen, struct sctp_rcvinfo rcv, int flags) { ASSERT_WEBRTC(!NS_IsMainThread()); DC_DEBUG(("In ReceiveCallback")); if (!data) { DC_DEBUG(("ReceiveCallback: SCTP has finished shutting down")); } else { bool locked = false; if (!IsSTSThread()) { mLock.Lock(); locked = true; } else { mLock.AssertCurrentThreadOwns(); } if (flags & MSG_NOTIFICATION) { HandleNotification(static_cast(data), datalen); } else { HandleMessage(data, datalen, ntohl(rcv.rcv_ppid), rcv.rcv_sid, flags); } if (locked) { mLock.Unlock(); } } // sctp allocates 'data' with malloc(), and expects the receiver to free // it (presumably with free). // XXX future optimization: try to deliver messages without an internal // alloc/copy, and if so delay the free until later. free(data); // usrsctp defines the callback as returning an int, but doesn't use it return 1; } already_AddRefed DataChannelConnection::Open( const nsACString& label, const nsACString& protocol, Type type, bool inOrder, uint32_t prValue, DataChannelListener* aListener, nsISupports* aContext, bool aExternalNegotiated, uint16_t aStream) { ASSERT_WEBRTC(NS_IsMainThread()); if (!aExternalNegotiated) { if (mAllocateEven.isSome()) { aStream = FindFreeStream(); if (aStream == INVALID_STREAM) { return nullptr; } } else { // We do not yet know whether we are client or server, and an id has not // been chosen for us. We will need to choose later. aStream = INVALID_STREAM; } } uint16_t prPolicy = SCTP_PR_SCTP_NONE; DC_DEBUG( ("DC Open: label %s/%s, type %u, inorder %d, prValue %u, listener %p, " "context %p, external: %s, stream %u", PromiseFlatCString(label).get(), PromiseFlatCString(protocol).get(), type, inOrder, prValue, aListener, aContext, aExternalNegotiated ? "true" : "false", aStream)); switch (type) { case DATA_CHANNEL_RELIABLE: prPolicy = SCTP_PR_SCTP_NONE; break; case DATA_CHANNEL_PARTIAL_RELIABLE_REXMIT: prPolicy = SCTP_PR_SCTP_RTX; break; case DATA_CHANNEL_PARTIAL_RELIABLE_TIMED: prPolicy = SCTP_PR_SCTP_TTL; break; default: DC_ERROR(("unsupported channel type: %u", type)); MOZ_ASSERT(false); return nullptr; } if ((prPolicy == SCTP_PR_SCTP_NONE) && (prValue != 0)) { return nullptr; } if (aStream != INVALID_STREAM && mChannels.Get(aStream)) { DC_ERROR(("external negotiation of already-open channel %u", aStream)); return nullptr; } RefPtr channel(new DataChannel( this, aStream, DataChannel::CONNECTING, label, protocol, prPolicy, prValue, inOrder, aExternalNegotiated, aListener, aContext)); mChannels.Insert(channel); MutexAutoLock lock(mLock); // OpenFinish assumes this return OpenFinish(channel.forget()); } // Separate routine so we can also call it to finish up from pending opens already_AddRefed DataChannelConnection::OpenFinish( already_AddRefed&& aChannel) { RefPtr channel(aChannel); // takes the reference passed in // Normally 1 reference if called from ::Open(), or 2 if called from // ProcessQueuedOpens() unless the DOMDataChannel was gc'd const uint16_t stream = channel->mStream; mLock.AssertCurrentThreadOwns(); // Cases we care about: // Pre-negotiated: // Not Open: // Doesn't fit: // -> change initial ask or renegotiate after open // -> queue open // Open: // Doesn't fit: // -> RequestMoreStreams && queue // Does fit: // -> open // Not negotiated: // Not Open: // -> queue open // Open: // -> Try to get a stream // Doesn't fit: // -> RequestMoreStreams && queue // Does fit: // -> open // So the Open cases are basically the same // Not Open cases are simply queue for non-negotiated, and // either change the initial ask or possibly renegotiate after open. const auto readyState = GetReadyState(); if (readyState != OPEN || stream >= mNegotiatedIdLimit) { if (readyState == OPEN) { MOZ_ASSERT(stream != INVALID_STREAM); // RequestMoreStreams() limits to MAX_NUM_STREAMS -- allocate extra // streams to avoid going back immediately for more if the ask to N, N+1, // etc int32_t more_needed = stream - ((int32_t)mNegotiatedIdLimit) + 16; if (!RequestMoreStreams(more_needed)) { // Something bad happened... we're done goto request_error_cleanup; } } DC_DEBUG(("Queuing channel %p (%u) to finish open", channel.get(), stream)); // Also serves to mark we told the app channel->mFlags |= DATA_CHANNEL_FLAGS_FINISH_OPEN; mPending.Push(channel); return channel.forget(); } MOZ_ASSERT(stream != INVALID_STREAM); MOZ_ASSERT(stream < mNegotiatedIdLimit); #ifdef TEST_QUEUED_DATA // It's painful to write a test for this... channel->AnnounceOpen(); SendDataMsgInternalOrBuffer(channel, "Help me!", 8, DATA_CHANNEL_PPID_DOMSTRING); #endif if (!channel->mOrdered) { // Don't send unordered until this gets cleared channel->mFlags |= DATA_CHANNEL_FLAGS_WAITING_ACK; } if (!channel->mNegotiated) { int error = SendOpenRequestMessage(channel->mLabel, channel->mProtocol, stream, !channel->mOrdered, channel->mPrPolicy, channel->mPrValue); if (error) { DC_ERROR(("SendOpenRequest failed, error = %d", error)); if (channel->mFlags & DATA_CHANNEL_FLAGS_FINISH_OPEN) { // We already returned the channel to the app. NS_ERROR("Failed to send open request"); channel->AnnounceClosed(); } // If we haven't returned the channel yet, it will get destroyed when we // exit this function. mChannels.Remove(channel); // we'll be destroying the channel return nullptr; /* NOTREACHED */ } } // Either externally negotiated or we sent Open // FIX? Move into DOMDataChannel? I don't think we can send it yet here channel->AnnounceOpen(); return channel.forget(); request_error_cleanup: if (channel->mFlags & DATA_CHANNEL_FLAGS_FINISH_OPEN) { // We already returned the channel to the app. NS_ERROR("Failed to request more streams"); channel->AnnounceClosed(); return channel.forget(); } // we'll be destroying the channel, but it never really got set up // Alternative would be to RUN_ON_THREAD(channel.forget(),::Destroy,...) and // Dispatch it to ourselves return nullptr; } // Requires mLock to be locked! // Returns a POSIX error code directly instead of setting errno. int DataChannelConnection::SendMsgInternal(OutgoingMsg& msg, size_t* aWritten) { auto& info = msg.GetInfo().sendv_sndinfo; int error; // EOR set? bool eor_set = info.snd_flags & SCTP_EOR ? true : false; // Send until buffer is empty size_t left = msg.GetLeft(); do { size_t length; // Carefully chunk the buffer if (left > DATA_CHANNEL_MAX_BINARY_FRAGMENT) { length = DATA_CHANNEL_MAX_BINARY_FRAGMENT; // Unset EOR flag info.snd_flags &= ~SCTP_EOR; } else { length = left; // Set EOR flag if (eor_set) { info.snd_flags |= SCTP_EOR; } } // Send (or try at least) // SCTP will return EMSGSIZE if the message is bigger than the buffer // size (or EAGAIN if there isn't space). However, we can avoid EMSGSIZE // by carefully crafting small enough message chunks. ssize_t written = usrsctp_sendv( mSocket, msg.GetData(), length, nullptr, 0, (void*)&msg.GetInfo(), (socklen_t)sizeof(struct sctp_sendv_spa), SCTP_SENDV_SPA, 0); if (written < 0) { error = errno; goto out; } if (aWritten) { *aWritten += written; } DC_DEBUG(("Sent buffer (written=%zu, len=%zu, left=%zu)", (size_t)written, length, left - (size_t)written)); // TODO: Remove once resolved // (https://github.com/sctplab/usrsctp/issues/132) if (written == 0) { DC_ERROR(("@tuexen: usrsctp_sendv returned 0")); error = EAGAIN; goto out; } // If not all bytes have been written, this obviously means that usrsctp's // buffer is full and we need to try again later. if ((size_t)written < length) { msg.Advance((size_t)written); error = EAGAIN; goto out; } // Update buffer position msg.Advance((size_t)written); // Get amount of bytes left in the buffer left = msg.GetLeft(); } while (left > 0); // Done error = 0; out: // Reset EOR flag if (eor_set) { info.snd_flags |= SCTP_EOR; } return error; } // Requires mLock to be locked! // Returns a POSIX error code directly instead of setting errno. // IMPORTANT: Ensure that the buffer passed is guarded by mLock! int DataChannelConnection::SendMsgInternalOrBuffer( nsTArray>& buffer, OutgoingMsg& msg, bool& buffered, size_t* aWritten) { NS_WARNING_ASSERTION(msg.GetLength() > 0, "Length is 0?!"); int error = 0; bool need_buffering = false; // Note: Main-thread IO, but doesn't block! // XXX FIX! to deal with heavy overruns of JS trying to pass data in // (more than the buffersize) queue data onto another thread to do the // actual sends. See netwerk/protocol/websocket/WebSocketChannel.cpp // Avoid a race between buffer-full-failure (where we have to add the // packet to the buffered-data queue) and the buffer-now-only-half-full // callback, which happens on a different thread. Otherwise we might // fail here, then before we add it to the queue get the half-full // callback, find nothing to do, then on this thread add it to the // queue - which would sit there. Also, if we later send more data, it // would arrive ahead of the buffered message, but if the buffer ever // got to 1/2 full, the message would get sent - but at a semi-random // time, after other data it was supposed to be in front of. // Must lock before empty check for similar reasons! mLock.AssertCurrentThreadOwns(); if (buffer.IsEmpty() && (mSendInterleaved || !mPendingType)) { error = SendMsgInternal(msg, aWritten); switch (error) { case 0: break; case EAGAIN: #if (EAGAIN != EWOULDBLOCK) case EWOULDBLOCK: #endif need_buffering = true; break; default: DC_ERROR(("error %d on sending", error)); break; } } else { need_buffering = true; } if (need_buffering) { // queue data for resend! And queue any further data for the stream until // it is... auto* bufferedMsg = new BufferedOutgoingMsg(msg); // infallible malloc buffer.AppendElement(bufferedMsg); // owned by mBufferedData array DC_DEBUG(("Queued %zu buffers (left=%zu, total=%zu)", buffer.Length(), msg.GetLeft(), msg.GetLength())); buffered = true; return 0; } buffered = false; return error; } // Caller must ensure that length <= UINT32_MAX // Returns a POSIX error code. int DataChannelConnection::SendDataMsgInternalOrBuffer(DataChannel& channel, const uint8_t* data, size_t len, uint32_t ppid) { if (NS_WARN_IF(channel.GetReadyState() != OPEN)) { return EINVAL; // TODO: Find a better error code } struct sctp_sendv_spa info = {0}; // General flags info.sendv_flags = SCTP_SEND_SNDINFO_VALID; // Set stream identifier, protocol identifier and flags info.sendv_sndinfo.snd_sid = channel.mStream; info.sendv_sndinfo.snd_flags = SCTP_EOR; info.sendv_sndinfo.snd_ppid = htonl(ppid); MutexAutoLock lock(mLock); // Need to protect mFlags... :( // Unordered? // To avoid problems where an in-order OPEN is lost and an // out-of-order data message "beats" it, require data to be in-order // until we get an ACK. if (!channel.mOrdered && !(channel.mFlags & DATA_CHANNEL_FLAGS_WAITING_ACK)) { info.sendv_sndinfo.snd_flags |= SCTP_UNORDERED; } // Partial reliability policy if (channel.mPrPolicy != SCTP_PR_SCTP_NONE) { info.sendv_prinfo.pr_policy = channel.mPrPolicy; info.sendv_prinfo.pr_value = channel.mPrValue; info.sendv_flags |= SCTP_SEND_PRINFO_VALID; } // Create message instance and send OutgoingMsg msg(info, data, len); bool buffered; size_t written = 0; mDeferSend = true; int error = SendMsgInternalOrBuffer(channel.mBufferedData, msg, buffered, &written); mDeferSend = false; if (written) { channel.DecrementBufferedAmount(written); } for (auto&& packet : mDeferredSend) { MOZ_ASSERT(written); SendPacket(std::move(packet)); } mDeferredSend.clear(); // Set pending type and stream index (if buffered) if (!error && buffered && !mPendingType) { mPendingType = PENDING_DATA; mCurrentStream = channel.mStream; } return error; } // Caller must ensure that length <= UINT32_MAX // Returns a POSIX error code. int DataChannelConnection::SendDataMsg(DataChannel& channel, const uint8_t* data, size_t len, uint32_t ppidPartial, uint32_t ppidFinal) { // We *really* don't want to do this from main thread! - and // SendDataMsgInternalOrBuffer avoids blocking. if (mMaxMessageSize != 0 && len > mMaxMessageSize) { DC_ERROR(("Message rejected, too large (%zu > %" PRIu64 ")", len, mMaxMessageSize)); return EMSGSIZE; } // This will use EOR-based fragmentation if the message is too large (> 64 // KiB) return SendDataMsgInternalOrBuffer(channel, data, len, ppidFinal); } class ReadBlobRunnable : public Runnable { public: ReadBlobRunnable(DataChannelConnection* aConnection, uint16_t aStream, nsIInputStream* aBlob) : Runnable("ReadBlobRunnable"), mConnection(aConnection), mStream(aStream), mBlob(aBlob) {} NS_IMETHOD Run() override { // ReadBlob() is responsible to releasing the reference DataChannelConnection* self = mConnection; self->ReadBlob(mConnection.forget(), mStream, mBlob); return NS_OK; } private: // Make sure the Connection doesn't die while there are jobs outstanding. // Let it die (if released by PeerConnectionImpl while we're running) // when we send our runnable back to MainThread. Then ~DataChannelConnection // can send the IOThread to MainThread to die in a runnable, avoiding // unsafe event loop recursion. Evil. RefPtr mConnection; uint16_t mStream; // Use RefCount for preventing the object is deleted when SendBlob returns. RefPtr mBlob; }; // Returns a POSIX error code. int DataChannelConnection::SendBlob(uint16_t stream, nsIInputStream* aBlob) { RefPtr channel = mChannels.Get(stream); if (NS_WARN_IF(!channel)) { return EINVAL; // TODO: Find a better error code } // Spawn a thread to send the data if (!mInternalIOThread) { nsresult rv = NS_NewNamedThread("DataChannel IO", getter_AddRefs(mInternalIOThread)); if (NS_FAILED(rv)) { return EINVAL; // TODO: Find a better error code } } mInternalIOThread->Dispatch( do_AddRef(new ReadBlobRunnable(this, stream, aBlob)), NS_DISPATCH_NORMAL); return 0; } class DataChannelBlobSendRunnable : public Runnable { public: DataChannelBlobSendRunnable( already_AddRefed& aConnection, uint16_t aStream) : Runnable("DataChannelBlobSendRunnable"), mConnection(aConnection), mStream(aStream) {} ~DataChannelBlobSendRunnable() override { if (!NS_IsMainThread() && mConnection) { MOZ_ASSERT(false); // explicitly leak the connection if destroyed off mainthread Unused << mConnection.forget().take(); } } NS_IMETHOD Run() override { ASSERT_WEBRTC(NS_IsMainThread()); mConnection->SendBinaryMsg(mStream, mData); mConnection = nullptr; return NS_OK; } // explicitly public so we can avoid allocating twice and copying nsCString mData; private: // Note: we can be destroyed off the target thread, so be careful not to let // this get Released()ed on the temp thread! RefPtr mConnection; uint16_t mStream; }; static auto readyStateToCStr(const uint16_t state) -> const char* { switch (state) { case DataChannelConnection::CONNECTING: return "CONNECTING"; case DataChannelConnection::OPEN: return "OPEN"; case DataChannelConnection::CLOSING: return "CLOSING"; case DataChannelConnection::CLOSED: return "CLOSED"; default: { MOZ_ASSERT(false); return "UNKNOWW"; } } }; void DataChannelConnection::SetReadyState(const uint16_t aState) { mLock.AssertCurrentThreadOwns(); DC_DEBUG( ("DataChannelConnection labeled %s (%p) switching connection state %s -> " "%s", mTransportId.c_str(), this, readyStateToCStr(mState), readyStateToCStr(aState))); mState = aState; } void DataChannelConnection::ReadBlob( already_AddRefed aThis, uint16_t aStream, nsIInputStream* aBlob) { // NOTE: 'aThis' has been forgotten by the caller to avoid releasing // it off mainthread; if PeerConnectionImpl has released then we want // ~DataChannelConnection() to run on MainThread // XXX to do this safely, we must enqueue these atomically onto the // output socket. We need a sender thread(s?) to enqueue data into the // socket and to avoid main-thread IO that might block. Even on a // background thread, we may not want to block on one stream's data. // I.e. run non-blocking and service multiple channels. // Must not let Dispatching it cause the DataChannelConnection to get // released on the wrong thread. Using // WrapRunnable(RefPtr(aThis),... will occasionally // cause aThis to get released on this thread. Also, an explicit Runnable // lets us avoid copying the blob data an extra time. RefPtr runnable = new DataChannelBlobSendRunnable(aThis, aStream); // avoid copying the blob data by passing the mData from the runnable if (NS_FAILED(NS_ReadInputStreamToString(aBlob, runnable->mData, -1))) { // Bug 966602: Doesn't return an error to the caller via onerror. // We must release DataChannelConnection on MainThread to avoid issues (bug // 876167) aThis is now owned by the runnable; release it there NS_ReleaseOnMainThread("DataChannelBlobSendRunnable", runnable.forget()); return; } aBlob->Close(); Dispatch(runnable.forget()); } // Returns a POSIX error code. int DataChannelConnection::SendDataMsgCommon(uint16_t stream, const nsACString& aMsg, bool isBinary) { ASSERT_WEBRTC(NS_IsMainThread()); // We really could allow this from other threads, so long as we deal with // asynchronosity issues with channels closing, in particular access to // mChannels, and issues with the association closing (access to mSocket). const uint8_t* data = (const uint8_t*)aMsg.BeginReading(); uint32_t len = aMsg.Length(); #if (UINT32_MAX > SIZE_MAX) if (len > SIZE_MAX) { return EMSGSIZE; } #endif DC_DEBUG(("Sending %sto stream %u: %u bytes", isBinary ? "binary " : "", stream, len)); // XXX if we want more efficiency, translate flags once at open time RefPtr channelPtr = mChannels.Get(stream); if (NS_WARN_IF(!channelPtr)) { return EINVAL; // TODO: Find a better error code } auto& channel = *channelPtr; int err = 0; if (isBinary) { err = SendDataMsg(channel, data, len, DATA_CHANNEL_PPID_BINARY_PARTIAL, DATA_CHANNEL_PPID_BINARY); } else { err = SendDataMsg(channel, data, len, DATA_CHANNEL_PPID_DOMSTRING_PARTIAL, DATA_CHANNEL_PPID_DOMSTRING); } if (!err) { channel.WithTrafficCounters([&len](DataChannel::TrafficCounters& counters) { counters.mMessagesSent++; counters.mBytesSent += len; }); } return err; } void DataChannelConnection::Stop() { // Note: This will call 'CloseAll' from the main thread Dispatch(do_AddRef(new DataChannelOnMessageAvailable( DataChannelOnMessageAvailable::ON_DISCONNECTED, this))); } void DataChannelConnection::Close(DataChannel* aChannel) { MutexAutoLock lock(mLock); CloseInt(aChannel); } // So we can call Close() with the lock already held // Called from someone who holds a ref via ::Close(), or from ~DataChannel void DataChannelConnection::CloseInt(DataChannel* aChannel) { MOZ_ASSERT(aChannel); RefPtr channel(aChannel); // make sure it doesn't go away on us mLock.AssertCurrentThreadOwns(); DC_DEBUG(("Connection %p/Channel %p: Closing stream %u", channel->mConnection.get(), channel.get(), channel->mStream)); aChannel->mBufferedData.Clear(); if (GetReadyState() == CLOSED) { // If we're CLOSING, we might leave this in place until we can send a // reset. mChannels.Remove(channel); } // This is supposed to only be accessed from Main thread, but this has // been accessed here from the STS thread for a long time now. // See Bug 1586475 auto channelState = aChannel->mReadyState; // re-test since it may have closed before the lock was grabbed if (channelState == CLOSED || channelState == CLOSING) { DC_DEBUG(("Channel already closing/closed (%u)", channelState)); return; } if (channel->mStream != INVALID_STREAM) { ResetOutgoingStream(channel->mStream); if (GetReadyState() != CLOSED) { // Individual channel is being closed, send reset now. SendOutgoingStreamReset(); } } aChannel->SetReadyState(CLOSING); if (GetReadyState() == CLOSED) { // we're not going to hang around waiting channel->StreamClosedLocked(); } // At this point when we leave here, the object is a zombie held alive only by // the DOM object } void DataChannelConnection::CloseAll() { DC_DEBUG(("Closing all channels (connection %p)", (void*)this)); // Don't need to lock here // Make sure no more channels will be opened { MutexAutoLock lock(mLock); SetReadyState(CLOSED); } // Close current channels // If there are runnables, they hold a strong ref and keep the channel // and/or connection alive (even if in a CLOSED state) for (auto& channel : mChannels.GetAll()) { channel->Close(); } // Clean up any pending opens for channels RefPtr channel; while (nullptr != (channel = mPending.PopFront())) { DC_DEBUG(("closing pending channel %p, stream %u", channel.get(), channel->mStream)); channel->Close(); // also releases the ref on each iteration } // It's more efficient to let the Resets queue in shutdown and then // SendOutgoingStreamReset() here. MutexAutoLock lock(mLock); SendOutgoingStreamReset(); } bool DataChannelConnection::Channels::IdComparator::Equals( const RefPtr& aChannel, uint16_t aId) const { return aChannel->mStream == aId; } bool DataChannelConnection::Channels::IdComparator::LessThan( const RefPtr& aChannel, uint16_t aId) const { return aChannel->mStream < aId; } bool DataChannelConnection::Channels::IdComparator::Equals( const RefPtr& a1, const RefPtr& a2) const { return Equals(a1, a2->mStream); } bool DataChannelConnection::Channels::IdComparator::LessThan( const RefPtr& a1, const RefPtr& a2) const { return LessThan(a1, a2->mStream); } void DataChannelConnection::Channels::Insert( const RefPtr& aChannel) { DC_DEBUG(("Inserting channel %u : %p", aChannel->mStream, aChannel.get())); MutexAutoLock lock(mMutex); if (aChannel->mStream != INVALID_STREAM) { MOZ_ASSERT(!mChannels.ContainsSorted(aChannel, IdComparator())); } MOZ_ASSERT(!mChannels.Contains(aChannel)); mChannels.InsertElementSorted(aChannel, IdComparator()); } bool DataChannelConnection::Channels::Remove( const RefPtr& aChannel) { DC_DEBUG(("Removing channel %u : %p", aChannel->mStream, aChannel.get())); MutexAutoLock lock(mMutex); if (aChannel->mStream == INVALID_STREAM) { return mChannels.RemoveElement(aChannel); } return mChannels.RemoveElementSorted(aChannel, IdComparator()); } RefPtr DataChannelConnection::Channels::Get(uint16_t aId) const { MutexAutoLock lock(mMutex); auto index = mChannels.BinaryIndexOf(aId, IdComparator()); if (index == ChannelArray::NoIndex) { return nullptr; } return mChannels[index]; } RefPtr DataChannelConnection::Channels::GetNextChannel( uint16_t aCurrentId) const { MutexAutoLock lock(mMutex); if (mChannels.IsEmpty()) { return nullptr; } auto index = mChannels.IndexOfFirstElementGt(aCurrentId, IdComparator()); if (index == mChannels.Length()) { index = 0; } return mChannels[index]; } DataChannel::~DataChannel() { // NS_ASSERTION since this is more "I think I caught all the cases that // can cause this" than a true kill-the-program assertion. If this is // wrong, nothing bad happens. A worst it's a leak. NS_ASSERTION(mReadyState == CLOSED || mReadyState == CLOSING, "unexpected state in ~DataChannel"); } void DataChannel::Close() { if (mConnection) { // ensure we don't get deleted RefPtr connection(mConnection); connection->Close(this); } } // Used when disconnecting from the DataChannelConnection void DataChannel::StreamClosedLocked() { mConnection->mLock.AssertCurrentThreadOwns(); ENSURE_DATACONNECTION; DC_DEBUG(("Destroying Data channel %u", mStream)); MOZ_ASSERT_IF(mStream != INVALID_STREAM, !mConnection->FindChannelByStream(mStream)); AnnounceClosed(); // We leave mConnection live until the DOM releases us, to avoid races } void DataChannel::ReleaseConnection() { ASSERT_WEBRTC(NS_IsMainThread()); mConnection = nullptr; } void DataChannel::SetListener(DataChannelListener* aListener, nsISupports* aContext) { ASSERT_WEBRTC(NS_IsMainThread()); mContext = aContext; mListener = aListener; } void DataChannel::SendErrnoToErrorResult(int error, size_t aMessageSize, ErrorResult& aRv) { switch (error) { case 0: break; case EMSGSIZE: { nsPrintfCString err("Message size (%zu) exceeds maxMessageSize", aMessageSize); aRv.ThrowTypeError(err); break; } default: aRv.Throw(NS_ERROR_DOM_OPERATION_ERR); break; } } void DataChannel::IncrementBufferedAmount(uint32_t aSize, ErrorResult& aRv) { ASSERT_WEBRTC(NS_IsMainThread()); if (mBufferedAmount > UINT32_MAX - aSize) { aRv.Throw(NS_ERROR_FILE_TOO_BIG); return; } mBufferedAmount += aSize; } void DataChannel::DecrementBufferedAmount(uint32_t aSize) { mMainThreadEventTarget->Dispatch(NS_NewRunnableFunction( "DataChannel::DecrementBufferedAmount", [this, self = RefPtr(this), aSize] { MOZ_ASSERT(aSize <= mBufferedAmount); bool wasLow = mBufferedAmount <= mBufferedThreshold; mBufferedAmount -= aSize; if (!wasLow && mBufferedAmount <= mBufferedThreshold) { DC_DEBUG(("%s: sending BUFFER_LOW_THRESHOLD for %s/%s: %u", __FUNCTION__, mLabel.get(), mProtocol.get(), mStream)); mListener->OnBufferLow(mContext); } if (mBufferedAmount == 0) { DC_DEBUG(("%s: sending NO_LONGER_BUFFERED for %s/%s: %u", __FUNCTION__, mLabel.get(), mProtocol.get(), mStream)); mListener->NotBuffered(mContext); } })); } void DataChannel::AnnounceOpen() { mMainThreadEventTarget->Dispatch(NS_NewRunnableFunction( "DataChannel::AnnounceOpen", [this, self = RefPtr(this)] { auto state = GetReadyState(); // Special-case; spec says to put brand-new remote-created DataChannel // in "open", but queue the firing of the "open" event. if (state != CLOSING && state != CLOSED && mListener) { SetReadyState(OPEN); DC_DEBUG(("%s: sending ON_CHANNEL_OPEN for %s/%s: %u", __FUNCTION__, mLabel.get(), mProtocol.get(), mStream)); mListener->OnChannelConnected(mContext); } })); } void DataChannel::AnnounceClosed() { mMainThreadEventTarget->Dispatch(NS_NewRunnableFunction( "DataChannel::AnnounceClosed", [this, self = RefPtr(this)] { if (GetReadyState() == CLOSED) { return; } SetReadyState(CLOSED); mBufferedData.Clear(); if (mListener) { DC_DEBUG(("%s: sending ON_CHANNEL_CLOSED for %s/%s: %u", __FUNCTION__, mLabel.get(), mProtocol.get(), mStream)); mListener->OnChannelClosed(mContext); } })); } // Set ready state void DataChannel::SetReadyState(const uint16_t aState) { MOZ_ASSERT(NS_IsMainThread()); DC_DEBUG( ("DataChannelConnection labeled %s(%p) (stream %d) changing ready state " "%s -> %s", mLabel.get(), this, mStream, readyStateToCStr(mReadyState), readyStateToCStr(aState))); mReadyState = aState; } void DataChannel::SendMsg(const nsACString& aMsg, ErrorResult& aRv) { if (!EnsureValidStream(aRv)) { return; } SendErrnoToErrorResult(mConnection->SendMsg(mStream, aMsg), aMsg.Length(), aRv); if (!aRv.Failed()) { IncrementBufferedAmount(aMsg.Length(), aRv); } } void DataChannel::SendBinaryMsg(const nsACString& aMsg, ErrorResult& aRv) { if (!EnsureValidStream(aRv)) { return; } SendErrnoToErrorResult(mConnection->SendBinaryMsg(mStream, aMsg), aMsg.Length(), aRv); if (!aRv.Failed()) { IncrementBufferedAmount(aMsg.Length(), aRv); } } void DataChannel::SendBinaryBlob(dom::Blob& aBlob, ErrorResult& aRv) { if (!EnsureValidStream(aRv)) { return; } uint64_t msgLength = aBlob.GetSize(aRv); if (aRv.Failed()) { return; } if (msgLength > UINT32_MAX) { aRv.Throw(NS_ERROR_FILE_TOO_BIG); return; } // We convert to an nsIInputStream here, because Blob is not threadsafe, and // we don't convert it earlier because we need to know how large this is so we // can update bufferedAmount. nsCOMPtr msgStream; aBlob.CreateInputStream(getter_AddRefs(msgStream), aRv); if (NS_WARN_IF(aRv.Failed())) { return; } SendErrnoToErrorResult(mConnection->SendBlob(mStream, msgStream), msgLength, aRv); if (!aRv.Failed()) { IncrementBufferedAmount(msgLength, aRv); } } dom::Nullable DataChannel::GetMaxPacketLifeTime() const { if (mPrPolicy == SCTP_PR_SCTP_TTL) { return dom::Nullable(mPrValue); } return dom::Nullable(); } dom::Nullable DataChannel::GetMaxRetransmits() const { if (mPrPolicy == SCTP_PR_SCTP_RTX) { return dom::Nullable(mPrValue); } return dom::Nullable(); } uint32_t DataChannel::GetBufferedAmountLowThreshold() { return mBufferedThreshold; } // Never fire immediately, as it's defined to fire on transitions, not state void DataChannel::SetBufferedAmountLowThreshold(uint32_t aThreshold) { mBufferedThreshold = aThreshold; } // Called with mLock locked! void DataChannel::SendOrQueue(DataChannelOnMessageAvailable* aMessage) { nsCOMPtr runnable = aMessage; mMainThreadEventTarget->Dispatch(runnable.forget()); } DataChannel::TrafficCounters DataChannel::GetTrafficCounters() const { MutexAutoLock lock(mStatsLock); return mTrafficCounters; } bool DataChannel::EnsureValidStream(ErrorResult& aRv) { MOZ_ASSERT(mConnection); if (mConnection && mStream != INVALID_STREAM) { return true; } aRv.Throw(NS_ERROR_DOM_INVALID_STATE_ERR); return false; } void DataChannel::WithTrafficCounters( const std::function& aFn) { MutexAutoLock lock(mStatsLock); aFn(mTrafficCounters); } } // namespace mozilla