# Copyright (c) 2021-2023 Status Research & Development GmbH # Licensed and distributed under either of # * MIT license (license terms in the root directory or at https://opensource.org/licenses/MIT). # * Apache v2 license (license terms in the root directory or at https://www.apache.org/licenses/LICENSE-2.0). # at your option. This file may not be copied, modified, or distributed except according to those terms. {.push raises: [].} import std/[sugar, deques], chronos, chronicles, stew/[results, bitops2], ./growable_buffer, ./packets, ./ledbat_congestion_control, ./delay_histogram, ./utp_utils, ./clock_drift_calculator export chronicles logScope: topics = "eth utp utp_socket" type ConnectionState* = enum SynSent, SynRecv, Connected, Destroy ConnectionDirection = enum Outgoing, Incoming UtpSocketKey*[A] = object remoteAddress*: A rcvId*: uint16 OutgoingPacket = object packetBytes: seq[byte] transmissions: uint16 needResend: bool payloadLength: uint32 timeSent: Moment AckResult = enum PacketAcked, PacketAlreadyAcked, PacketNotSentYet # Socket callback to send data to remote peer SendCallback*[A] = proc (to: A, data: seq[byte]): Future[void] {.gcsafe, raises: []} SocketConfig* = object # This is configurable (in contrast to reference impl), as with standard 2 # SYN resends, the default timeout of 3 seconds and the doubling of the # timeout with each resend, it means that the initial connection would # timeout only after 21s, which seems rather long. initialSynTimeout*: Duration # Number of resend retries of each data packet, before declaring the # connection as failed. dataResendsBeforeFailure*: uint16 # Maximal size of receive buffer in bytes optRcvBuffer*: uint32 # Maximal size of send buffer in bytes optSndBuffer*: uint32 # If set to some(`Duration`), the incoming socket will be initialized in # `SynRecv` state and the remote peer will have `Duration` to transfer data # to move the socket in `Connected` state. # If set to none, the incoming socket will immediately be set to `Connected` # state and will be able to transfer data. incomingSocketReceiveTimeout*: Option[Duration] # Timeout after which the send window will be reset to its minimal value # after it dropped to zero. # i.e when a packet is received from a peer with `wndSize` set to 0. remoteWindowResetTimeout*: Duration # Size of reorder buffer calculated as fraction of optRcvBuffer maxSizeOfReorderBuffer: uint32 # Maximal number of payload bytes per data packet. Total packet size will be # equal to payloadSize + 20 (size of header of data packet). # TODO: for now we enable only static configuration of packet sizes. In the # future it would be nice to add option which enables automatic packet size # discovery based on traffic. payloadSize*: uint32 # Maximal number of open uTP connections. When hit, no more incoming # connections will be allowed, but it will still be possible to open new # outgoing uTP connections. maxNumberOfOpenConnections*: int WriteErrorType* = enum SocketNotWriteable, FinSent WriteError* = object case kind*: WriteErrorType of SocketNotWriteable: currentState*: ConnectionState of FinSent: discard WriteResult* = Result[int, WriteError] WriteRequestType = enum Data, Close WriteRequest = object case kind: WriteRequestType of Data: data: seq[byte] writer: Future[WriteResult] of Close: discard SocketEventType = enum NewPacket, CheckTimeouts, CloseReq, WriteReq, ReadReqType ReadReq = object bytesToRead: int bytesAvailable: seq[uint8] reader: Future[seq[uint8]] ReadResult = enum ReadCancelled, ReadFinished, ReadNotFinished, SocketAlreadyFinished SocketEvent = object case kind: SocketEventType of CheckTimeouts: discard of NewPacket: packet: Packet of CloseReq: discard of WriteReq: data: seq[byte] writer: Future[WriteResult] of ReadReqType: readReq: ReadReq UtpSocket*[A] = ref object remoteAddress*: A state: ConnectionState direction: ConnectionDirection socketConfig: SocketConfig # Connection id for received packets connectionIdRcv*: uint16 # Connection id for send packets connectionIdSnd*: uint16 # Sequence number for the next packet to be sent. seqNr: uint16 # All sequence numbers up to this have been correctly acked by us. ackNr: uint16 # Should be completed after successful connection to remote host or after # timeout for the first SYN packet. connectionFuture: Future[void] # The number of packets in the send queue. Packets that haven't # been sent yet and packets marked as needing to be resend count. # The oldest un-acked packet in the send queue is seq_nr - cur_window_packets curWindowPackets: uint16 # outgoing buffer for all send packets outBuffer: GrowableCircularBuffer[OutgoingPacket] # current number of bytes in send buffer outBufferBytes: uint32 # current number of bytes in flight currentWindow: uint32 # current max window broadcasted by remote peer maxRemoteWindow: uint32 # current max window calculated by ledbat congestion controller maxWindow: uint32 # incoming buffer for out of order packets inBuffer: GrowableCircularBuffer[Packet] # number of bytes in reorder buffer inBufferBytes: uint32 # Number of packets waiting in reorder buffer reorderCount: uint16 # current retransmit Timeout used to calculate rtoTimeout retransmitTimeout: Duration # calculated round trip time during communication with remote peer rtt: Duration # calculated round trip time variance rttVar: Duration # Round trip timeout dynamically updated based on acks received from remote # peer rto: Duration # RTO timeout will happen when currenTime > rtoTimeout rtoTimeout: Moment # rcvBuffer rcvBuffer: seq[byte] # current size of rcv buffer offset: int # readers waiting for data pendingReads: Deque[ReadReq] # loop called every 500ms to check for on going timeout status checkTimeoutsLoop: Future[void] # number on consecutive re-transmissions retransmitCount: uint32 # Event which will complete whenever socket gets in destroy state closeEvent: AsyncEvent # All callback to be called whenever socket gets in destroy state closeCallbacks: seq[Future[void]] # socket is closed for reading readShutdown: bool # we sent out fin packet finSent: bool # we requested to close the socket by sending fin packet sendFinRequested: bool # have our fin been acked finAcked: bool # have we received remote fin gotFin: bool # have we reached remote fin packet reachedFin: bool # sequence number of remoted fin packet eofPktNr: uint16 pendingWrites: Deque[WriteRequest] eventQueue: AsyncQueue[SocketEvent] eventLoop: Future[void] # timer which is started when peer max window drops below current packet size zeroWindowTimer: Option[Moment] # last measured delay between current local timestamp, and remote sent # timestamp. In microseconds replayMicro: uint32 # indicator if we're in slow-start (exponential growth) phase slowStart: bool # indicator if we're in fast time out mode i.e we will resend # oldest packet un-acked in case of newer packet arriving fastTimeout: bool # Sequence number of the next packet we are allowed to fast-resend. This is # necessary to make sure we only fast resend once per packet fastResendSeqNr: uint16 # last time we decreased max window lastWindowDecay: Moment # counter of duplicate acks duplicateAck: uint16 #the slow-start threshold, in bytes slowStartThreshold: uint32 # history of our delays ourHistogram: DelayHistogram # history of remote delays remoteHistogram: DelayHistogram # calculator of drifting between local and remote clocks driftCalculator: ClockDriftCalculator # socket identifier socketKey*: UtpSocketKey[A] send: SendCallback[A] # User driven call back to be called whenever socket is permanently closed i.e # reaches destroy state SocketCloseCallback* = proc (): void {.gcsafe, raises: [].} ConnectionError* = object of CatchableError OutgoingConnectionErrorType* = enum SocketAlreadyExists, ConnectionTimedOut OutgoingConnectionError* = object case kind*: OutgoingConnectionErrorType of SocketAlreadyExists, ConnectionTimedOut: discard ConnectionResult*[A] = Result[UtpSocket[A], OutgoingConnectionError] const # Default maximum size of the data packet payload. With this configuration # data packets will have 508 bytes (488 + 20 header). # 508 bytes of UDP payload can translate into 576 bytes UDP packet i.e # 508 bytes + 60 bytes (max IP header) + 8 bytes (UDP header) = 576 bytes. # 576 bytes is defined as minimum reassembly buffer size, i.e the minimum # datagram size that any implementation must support. # From RFC791: All hosts must be prepared to accept datagrams of up to 576 # octets (whether they arrive whole or in fragments). defaultPayloadSize = 488 # How often each socket check its different ongoing timers checkTimeoutsLoopInterval = milliseconds(500) # Default initial timeout for first SYN packet defaultInitialSynTimeout = milliseconds(3000) # Initial timeout to receive first Data data packet after receiving initial # SYN packet. defaultRcvRetransmitTimeout = milliseconds(10000) # Number of times each data packet will be resend before declaring connection # dead. 4 is taken from reference implementation. defaultDataResendsBeforeFailure = 4'u16 # default size of rcv buffer in bytes # rationale form C reference impl: # 1 MB of receive buffer (i.e. max bandwidth delay product) # means that from a peer with 200 ms RTT, we cannot receive # faster than 5 MB/s # from a peer with 10 ms RTT, we cannot receive faster than # 100 MB/s. This is assumed to be good enough, since bandwidth # often is proportional to RTT anyway defaultOptRcvBuffer: uint32 = 1024 * 1024 # rationale from C reference impl: # Allow a reception window of at least 3 ack_nrs behind seq_nr # A non-SYN packet with an ack_nr difference greater than this is # considered suspicious and ignored allowedAckWindow*: uint16 = 3 # Timeout after which the send window will be reset to its minimal value after # it dropped lower than our current packet size. i.e when we received a packet # from remote peer with `wndSize` set to number <= current packet size. defaultResetWindowTimeout = seconds(15) reorderBufferMaxSize = 1024 duplicateAcksBeforeResend = 3 # minimal time before subsequent window decays maxWindowDecay = milliseconds(100) # Maximal size of reorder buffer as fraction of optRcvBuffer size. # Following semantics apply based on a rcvBuffer set to 1000 bytes: # - if there are already 1000 bytes in rcvBuffer no more bytes will be # accepted to reorder buffer # - if there are already 500 bytes in reorder buffer, no more bytes will be # accepted to it, and only 500 bytes can be accepted to rcvBuffer # This way there is always a space in rcvBuffer to fit new data if the # reordering happens. maxReorderBufferSize = 0.5 # Default number of of open utp connections # - libutp uses 3000 # - libtorrent uses ~16000 defaultMaxOpenConnections = 8000 proc init*[A](T: type UtpSocketKey, remoteAddress: A, rcvId: uint16): T = UtpSocketKey[A](remoteAddress: remoteAddress, rcvId: rcvId) proc init( T: type OutgoingPacket, packetBytes: seq[byte], transmissions: uint16, needResend: bool, payloadLength: uint32, timeSent: Moment = getMonoTimestamp().moment): T = OutgoingPacket( packetBytes: packetBytes, transmissions: transmissions, needResend: needResend, payloadLength: payloadLength, timeSent: timeSent ) proc init*( T: type SocketConfig, initialSynTimeout: Duration = defaultInitialSynTimeout, dataResendsBeforeFailure: uint16 = defaultDataResendsBeforeFailure, optRcvBuffer: uint32 = defaultOptRcvBuffer, incomingSocketReceiveTimeout: Option[Duration] = some(defaultRcvRetransmitTimeout), remoteWindowResetTimeout: Duration = defaultResetWindowTimeout, optSndBuffer: uint32 = defaultOptRcvBuffer, payloadSize: uint32 = defaultPayloadSize, maxNumberOfOpenConnections: int = defaultMaxOpenConnections ): T = # Make sure there is always some payload in data packets, and that packets are # not to large. With 1480 packet boundary, data packets will have 1500 bytes # which seems reasonable. doAssert(payloadSize > 0 and payloadSize <= 1480, "payloadSize should always be positive number <= 1480") # TODO make sure optRcvBuffer is nicely divisible by maxReorderBufferSize let reorderBufferSize = uint32(maxReorderBufferSize * float64(optRcvBuffer)) SocketConfig( initialSynTimeout: initialSynTimeout, dataResendsBeforeFailure: dataResendsBeforeFailure, optRcvBuffer: optRcvBuffer, optSndBuffer: optSndBuffer, incomingSocketReceiveTimeout: incomingSocketReceiveTimeout, remoteWindowResetTimeout: remoteWindowResetTimeout, maxSizeOfReorderBuffer: reorderBufferSize, payloadSize: payloadSize, maxNumberOfOpenConnections: maxNumberOfOpenConnections ) # number of bytes which will fit in current send window proc freeWindowBytes(socket: UtpSocket): uint32 = let maxSend = min(socket.maxRemoteWindow, socket.maxWindow) if (maxSend <= socket.currentWindow): return 0 else: return maxSend - socket.currentWindow proc getRcvWindowSize(socket: UtpSocket): uint32 = let currentDataSize = socket.offset if currentDataSize > int(socket.socketConfig.optRcvBuffer): 0'u32 else: socket.socketConfig.optRcvBuffer - uint32(currentDataSize) proc registerOutgoingPacket(socket: UtpSocket, oPacket: OutgoingPacket) = ## Adds packet to outgoing buffer and updates all related fields socket.outBuffer.ensureSize(socket.seqNr, socket.curWindowPackets) socket.outBuffer.put(socket.seqNr, oPacket) socket.outBufferBytes = socket.outBufferBytes + oPacket.payloadLength inc socket.seqNr inc socket.curWindowPackets proc sendData(socket: UtpSocket, data: seq[byte]) = let f = socket.send(socket.remoteAddress, data) f.callback = proc(data: pointer) {.gcsafe.} = if f.failed: warn "UTP send failed", msg = f.readError.msg proc sendPacket(socket: UtpSocket, seqNr: uint16) = proc setSend(p: var OutgoingPacket): seq[byte] = let timestampInfo = getMonoTimestamp() if p.transmissions == 0 or p.needResend: socket.currentWindow = socket.currentWindow + p.payloadLength inc p.transmissions p.needResend = false p.timeSent = timestampInfo.moment # all bytearrays in outgoing buffer should be properly encoded utp packets # so it is safe to directly modify fields modifyTimeStampAndAckNr(p.packetBytes, timestampInfo.timestamp, socket.ackNr) return p.packetBytes socket.sendData(setSend(socket.outBuffer[seqNr])) proc resetSendTimeout(socket: UtpSocket) = socket.retransmitTimeout = socket.rto socket.rtoTimeout = getMonoTimestamp().moment + socket.retransmitTimeout proc flushPackets(socket: UtpSocket) = let oldestOutgoingPacketSeqNr = socket.seqNr - socket.curWindowPackets var i: uint16 = oldestOutgoingPacketSeqNr while i != socket.seqNr: # sending only packet which were not transmitted yet or need a resend let shouldSendPacket = socket.outBuffer.exists( i, (p: OutgoingPacket) => (p.transmissions == 0 or p.needResend == true)) if (shouldSendPacket): if (socket.freeWindowBytes() > 0): # this our first send packet reset rto timeout if i == oldestOutgoingPacketSeqNr and socket.curWindowPackets == 1 and socket.outBuffer[i].transmissions == 0: socket.resetSendTimeout() debug "Flushing packet", pkSeqNr = i socket.sendPacket(i) else: debug "Should resend packet during flush but there is no place in send window", currentBytesWindow = socket.currentWindow, maxRemoteWindow = socket.maxRemoteWindow, maxWindow = socket.maxWindow, pkSeqNr = i # there is no place in send buffer, stop flushing return inc i proc markAllPacketAsLost(s: UtpSocket) = var i = 0'u16 while i < s.curWindowPackets: let packetSeqNr = s.seqNr - 1 - i if (s.outBuffer.exists( packetSeqNr, (p: OutgoingPacket) => p.transmissions > 0 and p.needResend == false)): debug "Marking packet as lost", pkSeqNr = packetSeqNr s.outBuffer[packetSeqNr].needResend = true let packetPayloadLength = s.outBuffer[packetSeqNr].payloadLength doAssert(s.currentWindow >= packetPayloadLength, "Window should always be larger than packet length") s.currentWindow = s.currentWindow - packetPayloadLength inc i proc isOpened(socket:UtpSocket): bool = return ( socket.state == SynRecv or socket.state == SynSent or socket.state == Connected ) proc shouldDisconnectFromFailedRemote(socket: UtpSocket): bool = (socket.state == SynSent and socket.retransmitCount >= 2) or (socket.retransmitCount >= socket.socketConfig.dataResendsBeforeFailure) proc checkTimeouts(socket: UtpSocket) = let currentTime = getMonoTimestamp().moment # flush all packets which needs to be re-send if socket.state != Destroy: socket.flushPackets() if socket.isOpened(): let currentPacketSize = socket.getPacketSize() if (socket.zeroWindowTimer.isSome() and currentTime > socket.zeroWindowTimer.unsafeGet()): if socket.maxRemoteWindow <= currentPacketSize: # Reset remote window, to minimal value which will fit at least two packet let minimalRemoteWindow = 2 * socket.socketConfig.payloadSize socket.maxRemoteWindow = minimalRemoteWindow debug "Reset remote window to minimal value", minRemote = minimalRemoteWindow socket.zeroWindowTimer = none[Moment]() if (currentTime > socket.rtoTimeout): debug "CheckTimeouts rto timeout", socketKey = socket.socketKey, state = socket.state, maxWindow = socket.maxWindow, curWindowPackets = socket.curWindowPackets, curWindowBytes = socket.currentWindow # TODO add handling of probe time outs. Reference implementation has mechanism # of sending probes to determine mtu size. Probe timeouts do not count to standard # timeouts calculations # client initiated connections, but did not send following data packet in rto # time and our socket is configured to start in SynRecv state. if (socket.state == SynRecv): socket.destroy() return if socket.shouldDisconnectFromFailedRemote(): debug "Remote host failed", state = socket.state, retransmitCount = socket.retransmitCount if socket.state == SynSent and (not socket.connectionFuture.finished()): socket.connectionFuture.fail(newException(ConnectionError, "Connection to peer timed out")) socket.destroy() return let newTimeout = socket.retransmitTimeout * 2 socket.retransmitTimeout = newTimeout socket.rtoTimeout = currentTime + newTimeout # on timeout reset duplicate ack counter socket.duplicateAck = 0 if (socket.curWindowPackets == 0 and socket.maxWindow > currentPacketSize): # there are no packets in flight even though there is place for more than whole packet # this means connection is just idling. Reset window by 1/3'rd but no more # than to fit at least one packet. let oldMaxWindow = socket.maxWindow let newMaxWindow = max((oldMaxWindow * 2) div 3, currentPacketSize) debug "Decaying max window due to socket idling", oldMaxWindow = oldMaxWindow, newMaxWindow = newMaxWindow socket.maxWindow = newMaxWindow elif (socket.maxWindow < currentPacketSize): # due to high delay window has shrunk below packet size # which means that we cannot send more data # reset it to fit at least one packet debug "Resetting window size do fit a least one packet", oldWindowSize = socket.maxWindow, newWindowSize = currentPacketSize # delay was so high that window has shrunk below one packet. Reset window # to fit a least one packet and start with slow start socket.maxWindow = currentPacketSize socket.slowStart = true # This will have much more sense when we will add handling of selective acks # as then every selectively acked packet resets timeout timer and removes packet # from out buffer. markAllPacketAsLost(socket) let oldestPacketSeqNr = socket.seqNr - socket.curWindowPackets # resend oldest packet if there are some packets in flight, and oldestpacket was already sent if (socket.curWindowPackets > 0 and socket.outBuffer[oldestPacketSeqNr].transmissions > 0): inc socket.retransmitCount socket.fastTimeout = true debug "Resending oldest packet", pkSeqNr = oldestPacketSeqNr, retransmitCount = socket.retransmitCount, curWindowPackets = socket.curWindowPackets # Oldest packet should always be present, so it is safe to call force # resend socket.sendPacket(oldestPacketSeqNr) # TODO add sending keep alives when necessary proc checkTimeoutsLoop(s: UtpSocket) {.async.} = ## Loop that check timeouts in the socket. try: while true: await sleepAsync(checkTimeoutsLoopInterval) s.eventQueue.putNoWait(SocketEvent(kind: CheckTimeouts)) except CancelledError as exc: # check timeouts loop is last running future managed by socket, if its # cancelled we can fire closeEvent s.closeEvent.fire() trace "checkTimeoutsLoop canceled" raise exc proc startTimeoutLoop(s: UtpSocket) = s.checkTimeoutsLoop = checkTimeoutsLoop(s) proc getPacketSize*(socket: UtpSocket): uint32 = socket.socketConfig.payloadSize proc handleDataWrite(socket: UtpSocket, data: seq[byte]): int = let pSize = int(socket.getPacketSize()) let endIndex = data.high() var i = 0 var bytesWritten = 0 while i <= endIndex: let lastIndex = i + pSize - 1 let lastOrEnd = min(lastIndex, endIndex) let dataSlice = data[i..lastOrEnd] let payloadLength = uint32(len(dataSlice)) if (socket.outBufferBytes + payloadLength <= socket.socketConfig.optSndBuffer): let wndSize = socket.getRcvWindowSize() let dataPacket = dataPacket( socket.seqNr, socket.connectionIdSnd, socket.ackNr, wndSize, dataSlice, socket.replayMicro ) let outgoingPacket = OutgoingPacket.init( encodePacket(dataPacket), 0, false, payloadLength) socket.registerOutgoingPacket(outgoingPacket) bytesWritten = bytesWritten + len(dataSlice) # TODO: When flushPackets early ended because of send window being full, # it keeps trying here again for each dataSlice. Sounds waistfull? socket.flushPackets() else: debug "No more place in write buffer", currentBufferSize = socket.outBufferBytes, maxBufferSize = socket.socketConfig.optSndBuffer, nexPacketSize = payloadLength break i = lastOrEnd + 1 return bytesWritten proc handleClose(socket: UtpSocket) = let finEncoded = encodePacket( finPacket( socket.seqNr, socket.connectionIdSnd, socket.ackNr, socket.getRcvWindowSize(), socket.replayMicro ) ) socket.finSent = true socket.registerOutgoingPacket(OutgoingPacket.init(finEncoded, 0, false, 0)) socket.flushPackets() proc isConnected*(socket: UtpSocket): bool = socket.state == Connected proc isClosed*(socket: UtpSocket): bool = socket.state == Destroy and socket.closeEvent.isSet() proc isClosedAndCleanedUpAllResources*(socket: UtpSocket): bool = ## Test Api to check that all resources are properly cleaned up socket.isClosed() and socket.eventLoop.cancelled() and socket.checkTimeoutsLoop.cancelled() proc destroy*(s: UtpSocket) = debug "Destroying socket", to = s.socketKey ## Moves socket to destroy state and clean all resources. ## Remote is not notified in any way about socket end of life s.state = Destroy s.eventLoop.cancel() # This procedure initiate cleanup process which goes like: # Cancel EventLoop -> Cancel timeoutsLoop -> Fire closeEvent # This is necessary due to how evenLoop look like i.e it has only one await # point on `eventQueue.get` which trigger cancellation exception only when # someone will try run `eventQueue.put`. Without `eventQueue.put` , eventLoop # future shows as cancelled, but handler for CancelledError is not run proc destroyWait*(s: UtpSocket) {.async.} = ## Moves socket to destroy state and clean all reasources and wait for all registered ## callback to fire ## Remote is not notified in any way about socket end of life s.destroy() await s.closeEvent.wait() await allFutures(s.closeCallbacks) proc setCloseCallback(s: UtpSocket, cb: SocketCloseCallback) {.async.} = ## Set callback which will be called whenever the socket is permanently closed try: await s.closeEvent.wait() cb() except CancelledError: trace "closeCallback cancelled" proc registerCloseCallback*(s: UtpSocket, cb: SocketCloseCallback) = s.closeCallbacks.add(s.setCloseCallback(cb)) proc updateTimeouts(socket: UtpSocket, timeSent: Moment, currentTime: Moment) = ## Update timeouts according to spec: ## delta = rtt - packet_rtt ## rtt_var += (abs(delta) - rtt_var) / 4; ## rtt += (packet_rtt - rtt) / 8; let packetRtt = currentTime - timeSent if (socket.rtt.isZero): socket.rtt = packetRtt socket.rttVar = packetRtt div 2 else: let packetRttMicro = packetRtt.microseconds() let rttVarMicro = socket.rttVar.microseconds() let rttMicro = socket.rtt.microseconds() let delta = rttMicro - packetRttMicro let newVar = microseconds(rttVarMicro + (abs(delta) - rttVarMicro) div 4) let newRtt = socket.rtt - (socket.rtt div 8) + (packetRtt div 8) socket.rttVar = newVar socket.rtt = newRtt # according to spec it should be: timeout = max(rtt + rtt_var * 4, 500) # but usually spec lags after implementation so milliseconds(1000) is used socket.rto = max(socket.rtt + (socket.rttVar * 4), milliseconds(1000)) proc ackPacket(socket: UtpSocket, seqNr: uint16, currentTime: Moment): AckResult = let packetOpt = socket.outBuffer.get(seqNr) if packetOpt.isSome(): let packet = packetOpt.get() if packet.transmissions == 0: # according to reference impl it can happen when we get an ack_nr that # does not exceed what we have stuffed into the outgoing buffer, # but does exceed what we have sent # TODO analyze if this case can happen with our impl return PacketNotSentYet socket.outBuffer.delete(seqNr) debug "Acked packet (deleted from outgoing buffer)", pkSeqNr = seqNr, pkTransmissions = packet.transmissions, pkNeedResend = packet.needResend # from spec: The rtt and rtt_var is only updated for packets that were sent only once. # This avoids problems with figuring out which packet was acked, the first or the second one. # it is standard solution to retransmission ambiguity problem if packet.transmissions == 1: socket.updateTimeouts(packet.timeSent, currentTime) socket.retransmitTimeout = socket.rto socket.rtoTimeout = currentTime + socket.rto # if need_resend is set, this packet has already # been considered timed-out, and is not included in # the cur_window anymore if (not packet.needResend): doAssert(socket.currentWindow >= packet.payloadLength, "Window should always be larger than packet length") socket.currentWindow = socket.currentWindow - packet.payloadLength # we removed packet from our out going buffer socket.outBufferBytes = socket.outBufferBytes - packet.payloadLength socket.retransmitCount = 0 PacketAcked else: debug "Tried to ack packet which was already acked or not sent yet" # the packet has already been acked (or not sent) PacketAlreadyAcked proc ackPackets(socket: UtpSocket, nrPacketsToAck: uint16, currentTime: Moment) = ## Ack packets in outgoing buffer based on ack number in the received packet var i = 0 while i < int(nrPacketsToAck): let result = socket.ackPacket(socket.seqNr - socket.curWindowPackets, currentTime) case result of PacketAcked: dec socket.curWindowPackets of PacketAlreadyAcked: dec socket.curWindowPackets of PacketNotSentYet: debug "Tried to ack packed which was not sent yet" break inc i proc calculateAckedbytes(socket: UtpSocket, nrPacketsToAck: uint16, now: Moment): (uint32, Duration) = var i: uint16 = 0 var ackedBytes: uint32 = 0 var minRtt: Duration = InfiniteDuration while i < nrPacketsToAck: let seqNr = socket.seqNr - socket.curWindowPackets + i let packetOpt = socket.outBuffer.get(seqNr) if (packetOpt.isSome() and packetOpt.unsafeGet().transmissions > 0): let packet = packetOpt.unsafeGet() ackedBytes = ackedBytes + packet.payloadLength # safety check in case clock is not monotonic if packet.timeSent < now: minRtt = min(minRtt, now - packet.timeSent) else: minRtt = min(minRtt, microseconds(50000)) inc i (ackedBytes, minRtt) proc initializeAckNr(socket: UtpSocket, packetSeqNr: uint16) = if (socket.state == SynSent): # Different from the uTP spec but in accordance with libutp and libtorrent. # When receiving the ACK of a SYN packet, the socket ackNr gets initialized # as the packet seqNr - 1. This way, the socket ackNr is set up as one less # the next seqNr for an incoming DATA packet. The seqNr in STATE packets # should basically be seen as the seqNr for the next DATA or FIN packet. # See also: # - libutp: https://github.com/bittorrent/libutp/blob/master/utp_internal.cpp#L1874 # - libtorrent: https://github.com/arvidn/libtorrent/blob/RC_2_0/src/utp_stream.cpp#L2924 socket.ackNr = packetSeqNr - 1 proc isAckNrInvalid(socket: UtpSocket, packet: Packet): bool = let ackWindow = max(socket.curWindowPackets + allowedAckWindow, allowedAckWindow) ( (packet.header.pType != ST_SYN or socket.state != SynRecv) and ( # packet ack number must be smaller than our last send packet i.e # remote should not ack packets from the future wrapCompareLess(socket.seqNr - 1, packet.header.ackNr) or # packet ack number should not be too old wrapCompareLess(packet.header.ackNr, socket.seqNr - 1 - ackWindow) ) ) # counts the number of bytes acked by selective ack header proc calculateSelectiveAckBytes*(socket: UtpSocket, receivedPackedAckNr: uint16, ext: SelectiveAckExtension): uint32 = # we add 2, as the first bit in the mask therefore represents ackNr + 2 because # ackNr + 1 (i.e next expected packet) is considered lost. let base = receivedPackedAckNr + 2 if socket.curWindowPackets == 0: return 0 var ackedBytes = 0'u32 var bits = (len(ext.acks)) * 8 - 1 while bits >= 0: let v = base + uint16(bits) if (socket.seqNr - v - 1) >= socket.curWindowPackets - 1: dec bits continue let maybePacket = socket.outBuffer.get(v) if (maybePacket.isNone() or maybePacket.unsafeGet().transmissions == 0): dec bits continue let pkt = maybePacket.unsafeGet() if (getBit(ext.acks, bits)): ackedBytes = ackedBytes + pkt.payloadLength dec bits return ackedBytes # decays maxWindow size by half if time is right i.e it is at least 100m since last # window decay proc tryDecayWindow(socket: UtpSocket, now: Moment) = if (now - socket.lastWindowDecay >= maxWindowDecay): socket.lastWindowDecay = now let newMaxWindow = max(uint32(0.5 * float64(socket.maxWindow)), uint32(minWindowSize)) debug "Decaying maxWindow", oldWindow = socket.maxWindow, newWindow = newMaxWindow socket.maxWindow = newMaxWindow socket.slowStart = false socket.slowStartThreshold = newMaxWindow # ack packets (removes them from out going buffer) based on selective ack extension header proc selectiveAckPackets(socket: UtpSocket, receivedPackedAckNr: uint16, ext: SelectiveAckExtension, currentTime: Moment): void = # we add 2, as the first bit in the mask therefore represents ackNr + 2 because # ackNr + 1 (i.e next expected packet) is considered lost. let base = receivedPackedAckNr + 2 if socket.curWindowPackets == 0: return var bits = (len(ext.acks)) * 8 - 1 # number of packets acked by this selective acks, it also works as duplicate ack # counter. # from spec: Each packet that is acked in the selective ack message counts as one duplicate ack var counter = 0 # sequence numbers of packets which should be resend var resends: seq[uint16] = @[] while bits >= 0: let v = base + uint16(bits) if (socket.seqNr - v - 1) >= socket.curWindowPackets - 1: dec bits continue let bitSet: bool = getBit(ext.acks, bits) if bitSet: inc counter let maybePacket = socket.outBuffer.get(v) if (maybePacket.isNone() or maybePacket.unsafeGet().transmissions == 0): dec bits continue let pkt = maybePacket.unsafeGet() if bitSet: debug "Packet acked by selective ack", pkSeqNr = v discard socket.ackPacket(v, currentTime) dec bits continue if counter >= duplicateAcksBeforeResend and (v - socket.fastResendSeqNr) <= reorderBufferMaxSize: debug "No ack for packet", pkAckNr = v, dupAckCounter = counter, fastResSeqNr = socket.fastResendSeqNr resends.add(v) dec bits let nextExpectedPacketSeqNr = base - 1'u16 # if we are about to start to resending first packet should be the first unacked packet # ie. base - 1 if counter >= duplicateAcksBeforeResend and (nextExpectedPacketSeqNr - socket.fastResendSeqNr) <= reorderBufferMaxSize: debug "No ack for packet", pkAckNr = nextExpectedPacketSeqNr, dupAckCounter = counter, fastResSeqNr = socket.fastResendSeqNr resends.add(nextExpectedPacketSeqNr) var i = high(resends) var registerLoss: bool = false var packetsSent = 0 while i >= 0: let seqNrToResend: uint16 = resends[i] let maybePkt = socket.outBuffer.get(seqNrToResend) if maybePkt.isNone(): # packet is no longer in send buffer ignore whole further processing dec i continue registerLoss = true # it is safe to call as we already checked that packet is in send buffer socket.sendPacket(seqNrToResend) socket.fastResendSeqNr = seqNrToResend + 1 debug "Resent packet", pkSeqNr = seqNrToResend, fastResendSeqNr = socket.fastResendSeqNr inc packetsSent # resend max 4 packets, this is not defined in spec but reference impl has # that check if packetsSent >= 4: break dec i if registerLoss: socket.tryDecayWindow(Moment.now()) socket.duplicateAck = uint16(counter) # Public mainly for test purposes # generates bit mask which indicates which packets are already in socket # reorder buffer # from speck: # The bitmask has reverse byte order. The first byte represents packets [ack_nr + 2, ack_nr + 2 + 7] in reverse order # The least significant bit in the byte represents ack_nr + 2, the most significant bit in the byte represents ack_nr + 2 + 7 # The next byte in the mask represents [ack_nr + 2 + 8, ack_nr + 2 + 15] in reverse order, and so on proc generateSelectiveAckBitMask*(socket: UtpSocket): array[4, byte] = let window = min(32, socket.inBuffer.len()) var arr: array[4, uint8] = [0'u8, 0, 0, 0] var i = 0 while i < window: if (socket.inBuffer.get(socket.ackNr + uint16(i) + 2).isSome()): setBit(arr, i) inc i return arr # Generates ack packet based on current state of the socket. proc generateAckPacket*(socket: UtpSocket): Packet = let bitmask = if (socket.reorderCount != 0 and (not socket.reachedFin)): some(socket.generateSelectiveAckBitMask()) else: none[array[4, byte]]() let bufferSize = socket.getRcvWindowSize() ackPacket( socket.seqNr, socket.connectionIdSnd, socket.ackNr, bufferSize, socket.replayMicro, bitmask ) proc sendAck(socket: UtpSocket) = ## Creates and sends ack, based on current socket state. Acks are different ## from other packets as we do not track them in outgoing buffer. let ackPacket = socket.generateAckPacket() debug "Sending STATE packet", pkSeqNr = ackPacket.header.seqNr, pkAckNr = ackPacket.header.ackNr, gotEACK = ackPacket.eack.isSome() socket.sendData(encodePacket(ackPacket)) proc tryfinalizeConnection(socket: UtpSocket, p: Packet) = # To avoid amplification attacks, server socket is in SynRecv state until # it receives first data transfer # https://www.usenix.org/system/files/conference/woot15/woot15-paper-adamsky.pdf # Socket is in SynRecv state only when recv timeout is configured if (socket.state == SynRecv and p.header.pType == ST_DATA): socket.state = Connected if (socket.state == SynSent and p.header.pType == ST_STATE): socket.state = Connected socket.ackNr = p.header.seqNr - 1 debug "Received Syn-Ack finalizing connection", socketAckNr = socket.ackNr if (not socket.connectionFuture.finished()): socket.connectionFuture.complete() # TODO: at socket level we should handle only FIN/DATA/ACK packets. Refactor to # make it enforceable by type system proc processPacketInternal(socket: UtpSocket, p: Packet) = debug "Process packet", socketKey = socket.socketKey, socketAckNr = socket.ackNr, socketSeqNr = socket.seqNr, windowPackets = socket.curWindowPackets, rcvBufferSize = socket.offset, packetType = p.header.pType, seqNr = p.header.seqNr, ackNr = p.header.ackNr, timestamp = p.header.timestamp, timestampDiff = p.header.timestampDiff, remoteWindow = p.header.wndSize let timestampInfo = getMonoTimestamp() if socket.isAckNrInvalid(p): debug "Received packet with invalid ack number", ackNr = p.header.ackNr, localSeqNr = socket.seqNr, lastUnacked = socket.seqNr - socket.curWindowPackets return ## Updates socket state based on received packet, and sends ack when necessary. ## Should be called in main packet receiving loop let pkSeqNr = p.header.seqNr let pkAckNr = p.header.ackNr socket.initializeAckNr(pkSeqNr) # number of packets past the expected # ack_nr is the last acked, seq_nr is the # current. Subtracting 1 makes 0 mean "this is the next expected packet" let pastExpected = pkSeqNr - socket.ackNr - 1 # acks is the number of packets that was acked, in normal case - no selective # acks, no losses, no resends, it will usually be equal to 1 # we can calculate it here and not only for ST_STATE packet, as each utp # packet has info about remote side last acked packet. var acks = pkAckNr - (socket.seqNr - 1 - socket.curWindowPackets) if acks > socket.curWindowPackets: # this case happens if the we already received this ack nr acks = 0 # rationale from c reference impl: # if we get the same ack_nr as in the last packet # increase the duplicate_ack counter, otherwise reset # it to 0. # It's important to only count ACKs in ST_STATE packets. Any other # packet (primarily ST_DATA) is likely to have been sent because of the # other end having new outgoing data, not in response to incoming data. # For instance, if we're receiving a steady stream of payload with no # outgoing data, and we suddently have a few bytes of payload to send (say, # a bittorrent HAVE message), we're very likely to see 3 duplicate ACKs # immediately after sending our payload packet. This effectively disables # the fast-resend on duplicate-ack logic for bi-directional connections # (except in the case of a selective ACK). This is in line with BSD4.4 TCP # implementation. if socket.curWindowPackets > 0 and pkAckNr == socket.seqNr - socket.curWindowPackets - 1 and p.header.pType == ST_STATE: inc socket.duplicateAck debug "Received duplicated ack", pkAckNr = pkAckNr, duplicateAckCounter = socket.duplicateAck else: socket.duplicateAck = 0 # spec says that in case of duplicate ack counter larger that duplicateAcksBeforeResend # we should re-send oldest packet, on the other hand reference implementation # has code path which does it commented out with todo. Currently to be as close # to reference impl we do not resend packets in that case debug "Packet state variables", pastExpected = pastExpected, acks = acks # If packet is totally off the mark, short-circuit the processing if pastExpected >= reorderBufferMaxSize: # if `pastExpected` is really big number (for example: uint16.high) then most # probably we are receiving packet which we already received # example: we already received packet with `seqNr = 10` so our `socket.ackNr = 10` # if we receive this packet once again then `pastExpected = 10 - 10 - 1` which # equals (due to wrapping) 65535 # this means that remote most probably did not receive our ack, so we need to resend # it. We are doing it for last `reorderBufferMaxSize` packets let isPossibleDuplicatedOldPacket = pastExpected >= (int(uint16.high) + 1) - reorderBufferMaxSize if (isPossibleDuplicatedOldPacket and p.header.pType != ST_STATE): socket.sendAck() debug "Got an invalid packet sequence number, too far off", pastExpected = pastExpected return var (ackedBytes, minRtt) = socket.calculateAckedbytes(acks, timestampInfo.moment) debug "Bytes acked by classic ack", bytesAcked = ackedBytes if (p.eack.isSome()): let selectiveAckedBytes = socket.calculateSelectiveAckBytes(pkAckNr, p.eack.unsafeGet()) debug "Bytes acked by selective ack", bytesAcked = selectiveAckedBytes ackedBytes = ackedBytes + selectiveAckedBytes let sentTimeRemote = p.header.timestamp # we are using uint32 not a Duration, to wrap a round in case of # sentTimeRemote > receipTimestamp. This can happen as local and remote # clock can be not synchronized or even using different system clock. # i.e this number itself does not tell anything and is only used to feedback it # to remote peer with each sent packet let remoteDelay = if (sentTimeRemote == 0): 0'u32 else: timestampInfo.timestamp - sentTimeRemote socket.replayMicro = remoteDelay let prevRemoteDelayBase = socket.remoteHistogram.delayBase if (remoteDelay != 0): socket.remoteHistogram.addSample(remoteDelay, timestampInfo.moment) # remote new delay base is less than previous # shift our delay base in other direction to take clock skew into account # but no more than 10ms if (prevRemoteDelayBase != 0 and wrapCompareLess(socket.remoteHistogram.delayBase, prevRemoteDelayBase) and prevRemoteDelayBase - socket.remoteHistogram.delayBase <= 10000'u32): socket.ourHistogram.shift(prevRemoteDelayBase - socket.remoteHistogram.delayBase) let actualDelay = p.header.timestampDiff if actualDelay != 0: socket.ourHistogram.addSample(actualDelay, timestampInfo.moment) socket.driftCalculator.addSample(actualDelay, timestampInfo.moment) # adjust base delay if delay estimates exceeds rtt if (socket.ourHistogram.getValue() > minRtt): let diff = uint32((socket.ourHistogram.getValue() - minRtt).microseconds()) socket.ourHistogram.shift(diff) let currentPacketSize = socket.getPacketSize() let (newMaxWindow, newSlowStartThreshold, newSlowStart) = applyCongestionControl( socket.maxWindow, socket.slowStart, socket.slowStartThreshold, socket.socketConfig.optSndBuffer, currentPacketSize, microseconds(actualDelay), ackedBytes, minRtt, socket.ourHistogram.getValue(), socket.driftCalculator.clockDrift ) # update remote window size and max window socket.maxWindow = newMaxWindow socket.maxRemoteWindow = p.header.wndSize socket.slowStart = newSlowStart socket.slowStartThreshold = newSlowStartThreshold debug "Applied ledbat congestion controller", maxWindow = newMaxWindow, remoteWindow = p.header.wndSize, slowStartThreshold = newSlowStartThreshold, slowstart = newSlowStart if (socket.zeroWindowTimer.isNone() and socket.maxRemoteWindow <= currentPacketSize): # when zeroWindowTimer will be hit and maxRemoteWindow still will be equal to 0 # then it will be reset to minimal value socket.zeroWindowTimer = some(timestampInfo.moment + socket.socketConfig.remoteWindowResetTimeout) debug "Remote window size dropped below packet size", currentTime = timestampInfo.moment, resetZeroWindowTime = socket.zeroWindowTimer, currentPacketSize = currentPacketSize socket.tryfinalizeConnection(p) # socket.curWindowPackets == acks means that this packet acked all remaining packets # including the sent fin packets if (socket.finSent and socket.curWindowPackets == acks): debug "FIN acked, destroying socket" socket.finAcked = true # this bit of utp spec is a bit under specified (i.e there is not specification at all) # reference implementation moves socket to destroy state in case that our fin was acked # and socket is considered closed for reading and writing. # but in theory remote could stil write some data on this socket (or even its own fin) socket.destroy() # Update fast resend counter to avoid resending old packet twice if wrapCompareLess(socket.fastResendSeqNr, pkAckNr + 1): socket.fastResendSeqNr = pkAckNr + 1 socket.ackPackets(acks, timestampInfo.moment) # packets in front may have been acked by selective ack, decrease window until we hit # a packet that is still waiting to be acked while (socket.curWindowPackets > 0 and socket.outBuffer.get(socket.seqNr - socket.curWindowPackets).isNone()): dec socket.curWindowPackets debug "Packet in front hase been acked by selective ack. Decrese window", windowPackets = socket.curWindowPackets # fast timeout if socket.fastTimeout: let oldestOutstandingPktSeqNr = socket.seqNr - socket.curWindowPackets debug "Hit fast timeout re-send", curWindowPackets = socket.curWindowPackets, oldesPkSeqNr = oldestOutstandingPktSeqNr, fastResendSeqNr = socket.fastResendSeqNr if oldestOutstandingPktSeqNr != socket.fastResendSeqNr: # fastResendSeqNr do not point to oldest unacked packet, we probably already resent # packet that timed-out. Leave fast timeout mode socket.fastTimeout = false else: let shouldReSendPacket = socket.outBuffer.exists(oldestOutstandingPktSeqNr, (p: OutgoingPacket) => p.transmissions > 0) if shouldReSendPacket: debug "Packet fast timeout resend", pkSeqNr = oldestOutstandingPktSeqNr inc socket.fastResendSeqNr # Is is safe to call force resend as we already checked shouldReSendPacket # condition socket.sendPacket(oldestOutstandingPktSeqNr) if (p.eack.isSome()): socket.selectiveAckPackets(pkAckNr, p.eack.unsafeGet(), timestampInfo.moment) if p.header.pType == ST_DATA or p.header.pType == ST_FIN: if socket.state != Connected: debug "Unexpected packet", socketState = socket.state, packetType = p.header.pType # we have received user generated packet (DATA or FIN), in not connected # state. Stop processing it. return if (p.header.pType == ST_FIN and (not socket.gotFin)): debug "Received FIN packet", eofPktNr = pkSeqNr, curAckNr = socket.ackNr socket.gotFin = true socket.eofPktNr = pkSeqNr # we got in order packet if (pastExpected == 0 and (not socket.reachedFin)): debug "Received in order packet" let payloadLength = len(p.payload) if (payloadLength > 0 and (not socket.readShutdown)): # we need to sum both rcv buffer and reorder buffer if (uint32(socket.offset) + socket.inBufferBytes + uint32(payloadLength) > socket.socketConfig.optRcvBuffer): # even though packet is in order and passes all the checks, it would # overflow our receive buffer, it means that we are receiving data # faster than we are reading it. Do not ack this packet, and drop received # data debug "Recevied packet would overflow receive buffer dropping it", pkSeqNr = p.header.seqNr, bytesReceived = payloadLength, rcvbufferSize = socket.offset, reorderBufferSize = socket.inBufferBytes return debug "Received data packet", bytesReceived = payloadLength # we are getting in order data packet, we can flush data directly to the incoming buffer # await upload(addr socket.buffer, unsafeAddr p.payload[0], p.payload.len()) moveMem(addr socket.rcvBuffer[socket.offset], unsafeAddr p.payload[0], payloadLength) socket.offset = socket.offset + payloadLength # Bytes have been passed to upper layer, we can increase number of last # acked packet inc socket.ackNr # check if the following packets are in reorder buffer debug "Looking for packets in re-order buffer", reorderCount = socket.reorderCount while true: # We are doing this in reorder loop, to handle the case when we already received # fin but there were some gaps before eof # we have reached remote eof, and should not receive more packets from remote if ((not socket.reachedFin) and socket.gotFin and socket.eofPktNr == socket.ackNr): debug "Reached socket EOF" # In case of reaching eof, it is up to user of library what to to with # it. With the current implementation, the most appropriate way would be to # destroy it (as with our implementation we know that remote is destroying its acked fin) # as any other send will either generate timeout, or socket will be forcefully # closed by reset socket.reachedFin = true # this is not necessarily true, but as we have already reached eof we can # ignore following packets socket.reorderCount = 0 if socket.reorderCount == 0: break let nextPacketNum = socket.ackNr + 1 let maybePacket = socket.inBuffer.get(nextPacketNum) if maybePacket.isNone(): break let packet = maybePacket.unsafeGet() let reorderPacketPayloadLength = len(packet.payload) if (reorderPacketPayloadLength > 0 and (not socket.readShutdown)): debug "Got packet from reorder buffer", packetBytes = len(packet.payload), packetSeqNr = packet.header.seqNr, packetAckNr = packet.header.ackNr, socketSeqNr = socket.seqNr, socketAckNr = socket.ackNr, rcvbufferSize = socket.offset, reorderBufferSize = socket.inBufferBytes # Rcv buffer and reorder buffer are sized that it is always possible to # move data from reorder buffer to rcv buffer without overflow moveMem(addr socket.rcvBuffer[socket.offset], unsafeAddr packet.payload[0], reorderPacketPayloadLength) socket.offset = socket.offset + reorderPacketPayloadLength debug "Deleting packet", seqNr = nextPacketNum socket.inBuffer.delete(nextPacketNum) inc socket.ackNr dec socket.reorderCount socket.inBufferBytes = socket.inBufferBytes - uint32(reorderPacketPayloadLength) debug "Socket state after processing in order packet", socketKey = socket.socketKey, socketAckNr = socket.ackNr, reorderCount = socket.reorderCount, windowPackets = socket.curWindowPackets # TODO for now we just schedule concurrent task with ack sending. It may # need improvement, as with this approach there is no direct control over # how many concurrent tasks there are and how to cancel them when socket # is closed socket.sendAck() # we got packet out of order else: debug "Got out of order packet" if (socket.gotFin and pkSeqNr > socket.eofPktNr): debug "Got packet past eof", pkSeqNr = pkSeqNr, eofPktNr = socket.eofPktNr return # growing buffer before checking the packet is already there to avoid # looking at older packet due to indices wrap aroud socket.inBuffer.ensureSize(pkSeqNr + 1, pastExpected + 1) if (socket.inBuffer.get(pkSeqNr).isSome()): debug "Packet with seqNr already received", seqNr = pkSeqNr else: let payloadLength = uint32(len(p.payload)) if (socket.inBufferBytes + payloadLength <= socket.socketConfig.maxSizeOfReorderBuffer and socket.inBufferBytes + uint32(socket.offset) + payloadLength <= socket.socketConfig.optRcvBuffer): debug "store packet in reorder buffer", packetBytes = payloadLength, packetSeqNr = p.header.seqNr, packetAckNr = p.header.ackNr, socketSeqNr = socket.seqNr, socketAckNr = socket.ackNr, rcvbufferSize = socket.offset, reorderBufferSize = socket.inBufferBytes socket.inBuffer.put(pkSeqNr, p) inc socket.reorderCount socket.inBufferBytes = socket.inBufferBytes + payloadLength debug "added out of order packet to reorder buffer", reorderCount = socket.reorderCount # we send ack packet, as we reorder count is > 0, so the eack bitmask will be # generated socket.sendAck() proc processPacket*(socket: UtpSocket, p: Packet): Future[void] = socket.eventQueue.put(SocketEvent(kind: NewPacket, packet: p)) template shiftBuffer(t, c: untyped) = if (t).offset > c: if c > 0: moveMem(addr((t).rcvBuffer[0]), addr((t).rcvBuffer[(c)]), (t).offset - (c)) (t).offset = (t).offset - (c) else: (t).offset = 0 proc onRead(socket: UtpSocket, readReq: var ReadReq): ReadResult = debug "Handling incoming read", rcvBufferSize = socket.offset, reorderBufferSize = socket.inBufferBytes, socketAtEOF = socket.atEof(), readTillEOF = readReq.bytesToRead == 0 if readReq.reader.finished(): return ReadCancelled if socket.atEof(): # buffer is already empty and we reached remote fin, just finish read with whatever # was already read readReq.reader.complete(readReq.bytesAvailable) return SocketAlreadyFinished if readReq.bytesToRead == 0: # treat is as read till eof readReq.bytesAvailable.add(socket.rcvBuffer.toOpenArray(0, socket.offset - 1)) socket.shiftBuffer(socket.offset) if (socket.atEof()): debug "Read finished", bytesRead = len(readReq.bytesAvailable), socketAtEof = socket.atEof() readReq.reader.complete(readReq.bytesAvailable) return ReadFinished else: debug "Read not finished", bytesRead = len(readReq.bytesAvailable), socketAtEof = socket.atEof() return ReadNotFinished else: let bytesAlreadyRead = len(readReq.bytesAvailable) let bytesLeftToRead = readReq.bytesToRead - bytesAlreadyRead let count = min(socket.offset, bytesLeftToRead) readReq.bytesAvailable.add(socket.rcvBuffer.toOpenArray(0, count - 1)) socket.shiftBuffer(count) if (len(readReq.bytesAvailable) == readReq.bytesToRead): debug "Read finished", bytesRead = len(readReq.bytesAvailable), socketAtEof = socket.atEof() readReq.reader.complete(readReq.bytesAvailable) return ReadFinished else: debug "Read not finished", bytesRead = len(readReq.bytesAvailable), socketAtEof = socket.atEof() return ReadNotFinished proc eventLoop(socket: UtpSocket) {.async.} = try: while true: let socketEvent = await socket.eventQueue.get() case socketEvent.kind of NewPacket: socket.processPacketInternal(socketEvent.packet) # we processed a packet and rcv buffer size is larger than 0, # check if we can finish some pending readers while socket.pendingReads.len() > 0: let readResult = socket.onRead(socket.pendingReads[0]) case readResult of ReadFinished: discard socket.pendingReads.popFirst() of ReadNotFinished: # there was not enough bytes in buffer to finish this read request, # stop processing further reads break else: # read was cancelled or socket is already finished move on to next # read request discard socket.pendingReads.popFirst() # we processed packet, so there could more place in the send buffer while socket.pendingWrites.len() > 0: let pendingWrite = socket.pendingWrites.popFirst() case pendingWrite.kind of Close: socket.handleClose() # close should be last packet send break of Data: # check if writing was not cancelled in the mean time. This approach # can create partial writes as part of the data could be written with # with WriteReq if (not pendingWrite.writer.finished()): let bytesWritten = socket.handleDataWrite(pendingWrite.data) if (bytesWritten == len(pendingWrite.data)): # all bytes were written we can finish external future pendingWrite.writer.complete( WriteResult.ok(bytesWritten) ) else: let bytesLeft = pendingWrite.data[bytesWritten..pendingWrite.data.high] # bytes partially written to buffer, schedule rest of data for # later socket.pendingWrites.addFirst( WriteRequest( kind: Data, data: bytesLeft, writer: pendingWrite.writer ) ) # there is no more place in the buffer break from the loop break of CheckTimeouts: discard of CloseReq: if (socket.pendingWrites.len() > 0): # there are still some unfinished writes, waiting to be finished socket.pendingWrites.addLast(WriteRequest(kind: Close)) else: socket.handleClose() of WriteReq: # check if the writer was not cancelled in mean time if (not socketEvent.writer.finished()): if (socket.pendingWrites.len() > 0): # there are still some unfinished writes, waiting to be finished # schedule this batch for later socket.pendingWrites.addLast( WriteRequest( kind: Data, data: socketEvent.data, writer: socketEvent.writer ) ) else: let bytesWritten = socket.handleDataWrite(socketEvent.data) if (bytesWritten == len(socketEvent.data)): # all bytes were written we can finish external future socketEvent.writer.complete( WriteResult.ok(bytesWritten) ) else: let bytesLeft = socketEvent.data[bytesWritten..socketEvent.data.high] # bytes partially written to buffer, schedule rest of data for later socket.pendingWrites.addLast( WriteRequest( kind: Data, data: bytesLeft, writer: socketEvent.writer ) ) of ReadReqType: # check if the writer was not cancelled in mean time if (not socketEvent.readReq.reader.finished()): if (socket.pendingReads.len() > 0): # there is already pending unfinished read request, schedule this # one for later socket.pendingReads.addLast(socketEvent.readReq) else: var readReq = socketEvent.readReq let readResult = socket.onRead(readReq) case readResult of ReadNotFinished: socket.pendingReads.addLast(readReq) else: # in any other case we do not need to do any thing discard socket.checkTimeouts() except CancelledError as exc: for w in socket.pendingWrites.items(): if w.kind == Data and (not w.writer.finished()): let res = WriteResult.err( WriteError(kind: SocketNotWriteable, currentState: socket.state) ) w.writer.complete(res) for r in socket.pendingReads.items(): # complete every reader with already read bytes # TODO: it may be better to refine read API to return # Future[Result[seq[byte], E]] and return errors for not finished reads if (not r.reader.finished()): r.reader.complete(r.bytesAvailable) socket.pendingWrites.clear() socket.pendingReads.clear() # main eventLoop has been cancelled, try to cancel `checkTimeoutsLoop` socket.checkTimeoutsLoop.cancel() trace "main socket event loop cancelled" raise exc proc startEventLoop(s: UtpSocket) = s.eventLoop = eventLoop(s) proc atEof*(socket: UtpSocket): bool = # The socket is considered at eof when the remote side sent us a FIN packet # and all packets up to the FIN have been processed. socket.offset == 0 and socket.reachedFin proc readingClosed(socket: UtpSocket): bool = socket.atEof() or socket.state == Destroy proc close*(socket: UtpSocket) = ## Gracefully close the connection (send FIN) if the socket is in the ## connected state. Does not wait for the socket to close. if socket.state != Destroy: case socket.state of Connected: socket.readShutdown = true if (not socket.sendFinRequested): try: debug "Sending FIN", dst = socket.socketKey # With this approach, all pending writes will be executed before # sending the FIN packet. socket.eventQueue.putNoWait(SocketEvent(kind: CloseReq)) except AsyncQueueFullError as e: # Should not happen as our write queue is unbounded. raiseAssert e.msg socket.sendFinRequested = true else: # When connection is not established, sending FIN makes no sense, just # destroy the socket. socket.destroy() proc closeWait*(socket: UtpSocket) {.async.} = ## Gracefully close the connection (send FIN) if the socket is in the ## connected state and wait for the socket to be closed. ## Warning: if the FIN packet is lost, then the socket might get closed due to ## retransmission failures, which will take some time. ## The default is 4 retransmissions with doubling of rto between each ## retransmission. socket.close() await socket.closeEvent.wait() proc write*(socket: UtpSocket, data: seq[byte]): Future[WriteResult] = debug "Write data", dst = socket.socketKey, length = len(data) let retFuture = newFuture[WriteResult]("UtpSocket.write") if (socket.state != Connected): let res = WriteResult.err(WriteError(kind: SocketNotWriteable, currentState: socket.state)) retFuture.complete(res) return retFuture # fin should be last packet received by remote side, therefore trying to write # after sending fin is considered error if socket.sendFinRequested or socket.finSent: let res = WriteResult.err(WriteError(kind: FinSent)) retFuture.complete(res) return retFuture var bytesWritten = 0 if len(data) == 0: let res = WriteResult.ok(bytesWritten) retFuture.complete(res) return retFuture try: socket.eventQueue.putNoWait(SocketEvent( kind: WriteReq, data: data, writer: retFuture)) except AsyncQueueFullError as e: # this should not happen as out write queue is unbounded raiseAssert e.msg return retFuture proc read*(socket: UtpSocket, n: Natural): Future[seq[byte]] = ## Read all bytes from socket ``socket``. ## ## This procedure allocates buffer seq[byte] and return it as result. let fut = newFuture[seq[uint8]]() if socket.readingClosed(): fut.complete(newSeq[uint8]()) return fut try: socket.eventQueue.putNoWait( SocketEvent( kind:ReadReqType, readReq: ReadReq( bytesToRead: n, bytesAvailable: newSeq[uint8](), reader: fut)) ) except AsyncQueueFullError as e: # should not happen as our write queue is unbounded raiseAssert e.msg return fut proc read*(socket: UtpSocket): Future[seq[byte]] = ## Read all bytes from socket ``socket``. ## ## This procedure allocates buffer seq[byte] and return it as result. let fut = newFuture[seq[uint8]]() if socket.readingClosed(): fut.complete(newSeq[uint8]()) return fut try: socket.eventQueue.putNoWait( SocketEvent( kind:ReadReqType, readReq: ReadReq( bytesToRead: 0, bytesAvailable: newSeq[uint8](), reader: fut)) ) except AsyncQueueFullError as e: # should not happen as our write queue is unbounded raiseAssert e.msg return fut # Check how many packets are still in the out going buffer, usefully for tests or # debugging. proc numPacketsInOutGoingBuffer*(socket: UtpSocket): int = var num = 0 for e in socket.outBuffer.items(): if e.isSome(): inc num num # Check how many payload bytes are still in flight proc numOfBytesInFlight*(socket: UtpSocket): uint32 = socket.currentWindow # Check how many bytes are in incoming buffer proc numOfBytesInIncomingBuffer*(socket: UtpSocket): uint32 = uint32(socket.offset) # Check how many packets are still in the reorder buffer, useful for tests or # debugging. # It throws assertion error when number of elements in buffer do not equal kept counter proc numPacketsInReorderedBuffer*(socket: UtpSocket): int = var num = 0 for e in socket.inBuffer.items(): if e.isSome(): inc num doAssert(num == int(socket.reorderCount)) num proc numOfEventsInEventQueue*(socket: UtpSocket): int = len(socket.eventQueue) proc connectionId*[A](socket: UtpSocket[A]): uint16 = ## Connection id is id which is used in first SYN packet which establishes the connection ## so for Outgoing side it is actually its rcv_id, and for Incoming side it is ## its snd_id case socket.direction of Incoming: socket.connectionIdSnd of Outgoing: socket.connectionIdRcv # Check what is current available window size for this socket proc currentMaxWindowSize*[A](socket: UtpSocket[A]): uint32 = socket.maxWindow proc new[A]( T: type UtpSocket[A], to: A, snd: SendCallback[A], state: ConnectionState, cfg: SocketConfig, direction: ConnectionDirection, rcvId: uint16, sndId: uint16, initialSeqNr: uint16, initialAckNr: uint16, initialTimeout: Duration ): T = let currentTime = getMonoTimestamp().moment # Initial max window size. Reference implementation uses value which enables one packet # to be transferred. # We use value two times higher as we do not yet have proper mtu estimation, and # our impl should work over udp and discovery v5 (where proper estimation may be harder # as packets already have discoveryv5 envelope) let initMaxWindow = 2 * cfg.payloadSize T( remoteAddress: to, state: state, direction: direction, socketConfig: cfg, connectionIdRcv: rcvId, connectionIdSnd: sndId, seqNr: initialSeqNr, ackNr: initialAckNr, connectionFuture: newFuture[void](), outBuffer: GrowableCircularBuffer[OutgoingPacket].init(), outBufferBytes: 0, currentWindow: 0, # start with 1mb assumption, field will be updated with first received packet maxRemoteWindow: 1024 * 1024, maxWindow: initMaxWindow, inBuffer: GrowableCircularBuffer[Packet].init(), retransmitTimeout: initialTimeout, rtoTimeout: currentTime + initialTimeout, # Initial timeout values taken from reference implemntation rtt: milliseconds(0), rttVar: milliseconds(800), rto: milliseconds(3000), rcvBuffer: newSeq[uint8](int(cfg.optRcvBuffer)), pendingReads: initDeque[ReadReq](), closeEvent: newAsyncEvent(), closeCallbacks: newSeq[Future[void]](), pendingWrites: initDeque[WriteRequest](), eventQueue: newAsyncQueue[SocketEvent](), zeroWindowTimer: none[Moment](), socketKey: UtpSocketKey.init(to, rcvId), slowStart: true, fastTimeout: false, fastResendSeqNr: initialSeqNr, lastWindowDecay: currentTime - maxWindowDecay, slowStartThreshold: cfg.optSndBuffer, ourHistogram: DelayHistogram.init(currentTime), remoteHistogram: DelayHistogram.init(currentTime), driftCalculator: ClockDriftCalculator.init(currentTime), send: snd ) proc newOutgoingSocket*[A]( to: A, snd: SendCallback[A], cfg: SocketConfig, rcvConnectionId: uint16, rng: var HmacDrbgContext ): UtpSocket[A] = let sndConnectionId = rcvConnectionId + 1 let initialSeqNr = randUint16(rng) UtpSocket[A].new( to, snd, SynSent, cfg, Outgoing, rcvConnectionId, sndConnectionId, initialSeqNr, # Initially ack nr is 0, as we do not know remote initial seqnr 0, cfg.initialSynTimeout ) proc newIncomingSocket*[A]( to: A, snd: SendCallback[A], cfg: SocketConfig, connectionId: uint16, ackNr: uint16, rng: var HmacDrbgContext ): UtpSocket[A] = let initialSeqNr = randUint16(rng) let (initialState, initialTimeout) = if (cfg.incomingSocketReceiveTimeout.isNone()): # it does not matter what timeout value we put here, as socket will be in # connected state without outgoing packets in buffer so any timeout hit will # just double rto without any penalties # although we cannot use 0, as then timeout will be constantly re-set to 500ms # and there will be a lot of not useful work done (Connected, defaultInitialSynTimeout) else: let timeout = cfg.incomingSocketReceiveTimeout.unsafeGet() (SynRecv, timeout) UtpSocket[A].new( to, snd, initialState, cfg, Incoming, connectionId + 1, connectionId, initialSeqNr, ackNr, initialTimeout ) proc getSocketConfig*(socket: UtpSocket): SocketConfig = socket.socketConfig proc startIncomingSocket*(socket: UtpSocket) = # Make sure ack was flushed before moving forward socket.sendAck() socket.startEventLoop() socket.startTimeoutLoop() proc startOutgoingSocket*(socket: UtpSocket): Future[void] = doAssert(socket.state == SynSent) let packet = synPacket(socket.seqNr, socket.connectionIdRcv, socket.getRcvWindowSize()) debug "Sending SYN packet", seqNr = packet.header.seqNr, connectionId = packet.header.connectionId # set number of transmissions to 1 as syn packet will be send just after # initialization let outgoingPacket = OutgoingPacket.init(encodePacket(packet), 1, false, 0) socket.registerOutgoingPacket(outgoingPacket) socket.startEventLoop() socket.startTimeoutLoop() socket.sendData(outgoingPacket.packetBytes) return socket.connectionFuture