doTimingAttackMitigation = False import base64 import datetime import errno import math import time import threading import shared import hashlib import os import Queue import select import socket import random import ssl from struct import unpack, pack import sys import traceback from binascii import hexlify #import string #from subprocess import call # used when the API must execute an outside program #from pyelliptic.openssl import OpenSSL #import highlevelcrypto from addresses import * from bmconfigparser import BMConfigParser from class_objectHashHolder import objectHashHolder from helper_generic import addDataPadding, isHostInPrivateIPRange from helper_sql import sqlQuery import knownnodes from debug import logger import paths import protocol from inventory import Inventory, PendingDownload, PendingUpload import queues import state import throttle import tr from version import softwareVersion # This thread is created either by the synSenderThread(for outgoing # connections) or the singleListenerThread(for incoming connections). class receiveDataThread(threading.Thread): def __init__(self): threading.Thread.__init__(self, name="receiveData") self.data = '' self.verackSent = False self.verackReceived = False def setup( self, sock, HOST, port, streamNumber, someObjectsOfWhichThisRemoteNodeIsAlreadyAware, selfInitiatedConnections, sendDataThreadQueue, objectHashHolderInstance): self.sock = sock self.peer = state.Peer(HOST, port) self.name = "receiveData-" + self.peer.host.replace(":", ".") # ":" log parser field separator self.streamNumber = state.streamsInWhichIAmParticipating self.remoteStreams = [] self.selfInitiatedConnections = selfInitiatedConnections self.sendDataThreadQueue = sendDataThreadQueue # used to send commands and data to the sendDataThread self.hostIdent = self.peer.port if ".onion" in BMConfigParser().get('bitmessagesettings', 'onionhostname') and protocol.checkSocksIP(self.peer.host) else self.peer.host shared.connectedHostsList[ self.hostIdent] = 0 # The very fact that this receiveData thread exists shows that we are connected to the remote host. Let's add it to this list so that an outgoingSynSender thread doesn't try to connect to it. self.connectionIsOrWasFullyEstablished = False # set to true after the remote node and I accept each other's version messages. This is needed to allow the user interface to accurately reflect the current number of connections. self.services = 0 if streamNumber == -1: # This was an incoming connection. Send out a version message if we accept the other node's version message. self.initiatedConnection = False else: self.initiatedConnection = True for stream in self.streamNumber: self.selfInitiatedConnections[stream][self] = 0 self.someObjectsOfWhichThisRemoteNodeIsAlreadyAware = someObjectsOfWhichThisRemoteNodeIsAlreadyAware self.objectHashHolderInstance = objectHashHolderInstance self.startTime = time.time() def run(self): logger.debug('receiveDataThread starting. ID ' + str(id(self)) + '. The size of the shared.connectedHostsList is now ' + str(len(shared.connectedHostsList))) while state.shutdown == 0: dataLen = len(self.data) try: isSSL = False if ((self.services & protocol.NODE_SSL == protocol.NODE_SSL) and self.connectionIsOrWasFullyEstablished and protocol.haveSSL(not self.initiatedConnection)): isSSL = True dataRecv = self.sslSock.recv(throttle.ReceiveThrottle().chunkSize) else: dataRecv = self.sock.recv(throttle.ReceiveThrottle().chunkSize) self.data += dataRecv throttle.ReceiveThrottle().wait(len(dataRecv)) except socket.timeout: if self.connectionIsOrWasFullyEstablished: self.sendping("Still around!") continue logger.error("Timeout during protocol initialisation") break except ssl.SSLError as err: if err.errno == ssl.SSL_ERROR_WANT_READ: select.select([self.sslSock], [], [], 10) logger.debug('sock.recv retriable SSL error') continue if err.errno is None and 'timed out' in str(err): if self.connectionIsOrWasFullyEstablished: self.sendping("Still around!") continue logger.error ('SSL error: %i/%s', err.errno if err.errno else 0, str(err)) break except socket.error as err: if err.errno in (errno.EAGAIN, errno.EWOULDBLOCK) or \ (sys.platform.startswith('win') and \ err.errno == errno.WSAEWOULDBLOCK): select.select([self.sslSock if isSSL else self.sock], [], [], 10) logger.debug('sock.recv retriable error') continue logger.error('sock.recv error. Closing receiveData thread (' + str(self.peer) + ', Thread ID: ' + str(id(self)) + ').' + str(err.errno) + "/" + str(err)) break # print 'Received', repr(self.data) if len(self.data) == dataLen: # If self.sock.recv returned no data: logger.debug('Connection to ' + str(self.peer) + ' closed. Closing receiveData thread. (ID: ' + str(id(self)) + ')') break else: self.processData() try: for stream in self.streamNumber: try: del self.selfInitiatedConnections[stream][self] except KeyError: pass logger.debug('removed self (a receiveDataThread) from selfInitiatedConnections') except: pass self.sendDataThreadQueue.put((0, 'shutdown','no data')) # commands the corresponding sendDataThread to shut itself down. try: del shared.connectedHostsList[self.hostIdent] except Exception as err: logger.error('Could not delete ' + str(self.hostIdent) + ' from shared.connectedHostsList.' + str(err)) PendingDownload().threadEnd() queues.UISignalQueue.put(('updateNetworkStatusTab', 'no data')) self.checkTimeOffsetNotification() logger.debug('receiveDataThread ending. ID ' + str(id(self)) + '. The size of the shared.connectedHostsList is now ' + str(len(shared.connectedHostsList))) def antiIntersectionDelay(self, initial = False): # estimated time for a small object to propagate across the whole network delay = math.ceil(math.log(max(len(knownnodes.knownNodes[x]) for x in knownnodes.knownNodes) + 2, 20)) * (0.2 + objectHashHolder.size/2) # take the stream with maximum amount of nodes # +2 is to avoid problems with log(0) and log(1) # 20 is avg connected nodes count # 0.2 is avg message transmission time now = time.time() if initial and now - delay < self.startTime: logger.debug("Initial sleeping for %.2fs", delay - (now - self.startTime)) time.sleep(delay - (now - self.startTime)) elif not initial: logger.debug("Sleeping due to missing object for %.2fs", delay) time.sleep(delay) def checkTimeOffsetNotification(self): if shared.timeOffsetWrongCount >= 4 and not self.connectionIsOrWasFullyEstablished: queues.UISignalQueue.put(('updateStatusBar', tr._translate("MainWindow", "The time on your computer, %1, may be wrong. Please verify your settings.").arg(datetime.datetime.now().strftime("%H:%M:%S")))) def processData(self): if len(self.data) < protocol.Header.size: # if so little of the data has arrived that we can't even read the checksum then wait for more data. return magic,command,payloadLength,checksum = protocol.Header.unpack(self.data[:protocol.Header.size]) if magic != 0xE9BEB4D9: self.data = "" return if payloadLength > 1600100: # ~1.6 MB which is the maximum possible size of an inv message. logger.info('The incoming message, which we have not yet download, is too large. Ignoring it. (unfortunately there is no way to tell the other node to stop sending it except to disconnect.) Message size: %s' % payloadLength) self.data = self.data[payloadLength + protocol.Header.size:] del magic,command,payloadLength,checksum # we don't need these anymore and better to clean them now before the recursive call rather than after self.processData() return if len(self.data) < payloadLength + protocol.Header.size: # check if the whole message has arrived yet. return payload = self.data[protocol.Header.size:payloadLength + protocol.Header.size] if checksum != hashlib.sha512(payload).digest()[0:4]: # test the checksum in the message. logger.error('Checksum incorrect. Clearing this message.') self.data = self.data[payloadLength + protocol.Header.size:] del magic,command,payloadLength,checksum,payload # better to clean up before the recursive call self.processData() return # The time we've last seen this node is obviously right now since we # just received valid data from it. So update the knownNodes list so # that other peers can be made aware of its existance. if self.initiatedConnection and self.connectionIsOrWasFullyEstablished: # The remote port is only something we should share with others if it is the remote node's incoming port (rather than some random operating-system-assigned outgoing port). with knownnodes.knownNodesLock: for stream in self.streamNumber: knownnodes.knownNodes[stream][self.peer] = int(time.time()) #Strip the nulls command = command.rstrip('\x00') logger.debug('remoteCommand ' + repr(command) + ' from ' + str(self.peer)) try: #TODO: Use a dispatcher here if command == 'error': self.recerror(payload) elif not self.connectionIsOrWasFullyEstablished: if command == 'version': self.recversion(payload) elif command == 'verack': self.recverack() else: if command == 'addr': self.recaddr(payload) elif command == 'inv': self.recinv(payload) elif command == 'getdata': self.recgetdata(payload) elif command == 'object': self.recobject(payload) elif command == 'ping': self.sendpong(payload) elif command == 'pong': pass else: logger.info("Unknown command %s, ignoring", command) except varintDecodeError as e: logger.debug("There was a problem with a varint while processing a message from the wire. Some details: %s" % e) except Exception as e: logger.critical("Critical error in a receiveDataThread: \n%s" % traceback.format_exc()) del payload self.data = self.data[payloadLength + protocol.Header.size:] # take this message out and then process the next message if self.data == '': # if there are no more messages try: self.sendgetdata(PendingDownload().pull(100)) except Queue.Full: pass self.processData() def sendpong(self, payload): logger.debug('Sending pong') self.sendDataThreadQueue.put((0, 'sendRawData', protocol.CreatePacket('pong', payload))) def sendping(self, payload): logger.debug('Sending ping') self.sendDataThreadQueue.put((0, 'sendRawData', protocol.CreatePacket('ping', payload))) def recverack(self): logger.debug('verack received') self.verackReceived = True if self.verackSent: # We have thus both sent and received a verack. self.connectionFullyEstablished() def sslHandshake(self): self.sslSock = self.sock if ((self.services & protocol.NODE_SSL == protocol.NODE_SSL) and protocol.haveSSL(not self.initiatedConnection)): logger.debug("Initialising TLS") if sys.version_info >= (2,7,9): context = ssl.SSLContext(protocol.sslProtocolVersion) context.set_ciphers(protocol.sslProtocolCiphers) context.set_ecdh_curve("secp256k1") context.check_hostname = False context.verify_mode = ssl.CERT_NONE # also exclude TLSv1 and TLSv1.1 in the future context.options = ssl.OP_ALL | ssl.OP_NO_SSLv2 | ssl.OP_NO_SSLv3 | ssl.OP_SINGLE_ECDH_USE | ssl.OP_CIPHER_SERVER_PREFERENCE self.sslSock = context.wrap_socket(self.sock, server_side = not self.initiatedConnection, do_handshake_on_connect=False) else: self.sslSock = ssl.wrap_socket(self.sock, keyfile = os.path.join(paths.codePath(), 'sslkeys', 'key.pem'), certfile = os.path.join(paths.codePath(), 'sslkeys', 'cert.pem'), server_side = not self.initiatedConnection, ssl_version=protocol.sslProtocolVersion, do_handshake_on_connect=False, ciphers=protocol.sslProtocolCiphers) self.sendDataThreadQueue.join() while True: try: self.sslSock.do_handshake() logger.debug("TLS handshake success") break except ssl.SSLError as e: if sys.hexversion >= 0x02070900: if isinstance (e, ssl.SSLWantReadError): logger.debug("Waiting for SSL socket handhake read") select.select([self.sslSock], [], [], 10) continue elif isinstance (e, ssl.SSLWantWriteError): logger.debug("Waiting for SSL socket handhake write") select.select([], [self.sslSock], [], 10) continue else: if e.args[0] == ssl.SSL_ERROR_WANT_READ: logger.debug("Waiting for SSL socket handhake read") select.select([self.sslSock], [], [], 10) continue elif e.args[0] == ssl.SSL_ERROR_WANT_WRITE: logger.debug("Waiting for SSL socket handhake write") select.select([], [self.sslSock], [], 10) continue logger.error("SSL socket handhake failed: %s, shutting down connection", str(e)) self.sendDataThreadQueue.put((0, 'shutdown','tls handshake fail %s' % (str(e)))) return False except Exception: logger.error("SSL socket handhake failed, shutting down connection", exc_info=True) self.sendDataThreadQueue.put((0, 'shutdown','tls handshake fail')) return False # SSL in the background should be blocking, otherwise the error handling is difficult self.sslSock.settimeout(None) return True # no SSL return True def peerValidityChecks(self): if self.remoteProtocolVersion < 3: self.sendDataThreadQueue.put((0, 'sendRawData',protocol.assembleErrorMessage( fatal=2, errorText="Your is using an old protocol. Closing connection."))) logger.debug ('Closing connection to old protocol version ' + str(self.remoteProtocolVersion) + ' node: ' + str(self.peer)) return False if self.timeOffset > 3600: self.sendDataThreadQueue.put((0, 'sendRawData', protocol.assembleErrorMessage( fatal=2, errorText="Your time is too far in the future compared to mine. Closing connection."))) logger.info("%s's time is too far in the future (%s seconds). Closing connection to it.", self.peer, self.timeOffset) shared.timeOffsetWrongCount += 1 time.sleep(2) return False elif self.timeOffset < -3600: self.sendDataThreadQueue.put((0, 'sendRawData', protocol.assembleErrorMessage( fatal=2, errorText="Your time is too far in the past compared to mine. Closing connection."))) logger.info("%s's time is too far in the past (timeOffset %s seconds). Closing connection to it.", self.peer, self.timeOffset) shared.timeOffsetWrongCount += 1 return False else: shared.timeOffsetWrongCount = 0 if len(self.streamNumber) == 0: self.sendDataThreadQueue.put((0, 'sendRawData', protocol.assembleErrorMessage( fatal=2, errorText="We don't have shared stream interests. Closing connection."))) logger.debug ('Closed connection to ' + str(self.peer) + ' because there is no overlapping interest in streams.') return False return True def connectionFullyEstablished(self): if self.connectionIsOrWasFullyEstablished: # there is no reason to run this function a second time return if not self.sslHandshake(): return if self.peerValidityChecks() == False: time.sleep(2) self.sendDataThreadQueue.put((0, 'shutdown','no data')) self.checkTimeOffsetNotification() return self.connectionIsOrWasFullyEstablished = True shared.timeOffsetWrongCount = 0 # Command the corresponding sendDataThread to set its own connectionIsOrWasFullyEstablished variable to True also self.sendDataThreadQueue.put((0, 'connectionIsOrWasFullyEstablished', (self.services, self.sslSock))) if not self.initiatedConnection: shared.clientHasReceivedIncomingConnections = True queues.UISignalQueue.put(('setStatusIcon', 'green')) self.sock.settimeout( 600) # We'll send out a ping every 5 minutes to make sure the connection stays alive if there has been no other traffic to send lately. queues.UISignalQueue.put(('updateNetworkStatusTab', 'no data')) logger.debug('Connection fully established with ' + str(self.peer) + "\n" + \ 'The size of the connectedHostsList is now ' + str(len(shared.connectedHostsList)) + "\n" + \ 'The length of sendDataQueues is now: ' + str(len(state.sendDataQueues)) + "\n" + \ 'broadcasting addr from within connectionFullyEstablished function.') if self.initiatedConnection: state.networkProtocolAvailability[protocol.networkType(self.peer.host)] = True # we need to send our own objects to this node PendingUpload().add() # Let all of our peers know about this new node. for stream in self.remoteStreams: dataToSend = (int(time.time()), stream, self.services, self.peer.host, self.remoteNodeIncomingPort) protocol.broadcastToSendDataQueues(( stream, 'advertisepeer', dataToSend)) self.sendaddr() # This is one large addr message to this one peer. if len(shared.connectedHostsList) > \ BMConfigParser().safeGetInt("bitmessagesettings", "maxtotalconnections", 200): logger.info ('We are connected to too many people. Closing connection.') if self.initiatedConnection: self.sendDataThreadQueue.put((0, 'sendRawData', protocol.assembleErrorMessage(fatal=2, errorText="Thank you for providing a listening node."))) else: self.sendDataThreadQueue.put((0, 'sendRawData', protocol.assembleErrorMessage(fatal=2, errorText="Server full, please try again later."))) self.sendDataThreadQueue.put((0, 'shutdown','no data')) return self.sendBigInv() def sendBigInv(self): # Select all hashes for objects in this stream. bigInvList = {} for stream in self.streamNumber: for hash in Inventory().unexpired_hashes_by_stream(stream): if hash not in self.someObjectsOfWhichThisRemoteNodeIsAlreadyAware and not self.objectHashHolderInstance.hasHash(hash): bigInvList[hash] = 0 numberOfObjectsInInvMessage = 0 payload = '' # Now let us start appending all of these hashes together. They will be # sent out in a big inv message to our new peer. for hash, storedValue in bigInvList.items(): payload += hash numberOfObjectsInInvMessage += 1 if numberOfObjectsInInvMessage == 50000: # We can only send a max of 50000 items per inv message but we may have more objects to advertise. They must be split up into multiple inv messages. self.sendinvMessageToJustThisOnePeer( numberOfObjectsInInvMessage, payload) payload = '' numberOfObjectsInInvMessage = 0 if numberOfObjectsInInvMessage > 0: self.sendinvMessageToJustThisOnePeer( numberOfObjectsInInvMessage, payload) # Used to send a big inv message when the connection with a node is # first fully established. Notice that there is also a broadcastinv # function for broadcasting invs to everyone in our stream. def sendinvMessageToJustThisOnePeer(self, numberOfObjects, payload): payload = encodeVarint(numberOfObjects) + payload logger.debug('Sending huge inv message with ' + str(numberOfObjects) + ' objects to just this one peer') self.sendDataThreadQueue.put((0, 'sendRawData', protocol.CreatePacket('inv', payload))) def _sleepForTimingAttackMitigation(self, sleepTime): # We don't need to do the timing attack mitigation if we are # only connected to the trusted peer because we can trust the # peer not to attack if sleepTime > 0 and doTimingAttackMitigation and state.trustedPeer == None: logger.debug('Timing attack mitigation: Sleeping for ' + str(sleepTime) + ' seconds.') time.sleep(sleepTime) def recerror(self, data): """ The remote node has been polite enough to send you an error message. """ fatalStatus, readPosition = decodeVarint(data[:10]) banTime, banTimeLength = decodeVarint(data[readPosition:readPosition+10]) readPosition += banTimeLength inventoryVectorLength, inventoryVectorLengthLength = decodeVarint(data[readPosition:readPosition+10]) if inventoryVectorLength > 100: return readPosition += inventoryVectorLengthLength inventoryVector = data[readPosition:readPosition+inventoryVectorLength] readPosition += inventoryVectorLength errorTextLength, errorTextLengthLength = decodeVarint(data[readPosition:readPosition+10]) if errorTextLength > 1000: return readPosition += errorTextLengthLength errorText = data[readPosition:readPosition+errorTextLength] if fatalStatus == 0: fatalHumanFriendly = 'Warning' elif fatalStatus == 1: fatalHumanFriendly = 'Error' elif fatalStatus == 2: fatalHumanFriendly = 'Fatal' message = '%s message received from %s: %s.' % (fatalHumanFriendly, self.peer, errorText) if inventoryVector: message += " This concerns object %s" % hexlify(inventoryVector) if banTime > 0: message += " Remote node says that the ban time is %s" % banTime logger.error(message) def recobject(self, data): self.messageProcessingStartTime = time.time() lengthOfTimeWeShouldUseToProcessThisMessage = shared.checkAndShareObjectWithPeers(data) """ Sleeping will help guarantee that we can process messages faster than a remote node can send them. If we fall behind, the attacker could observe that we are are slowing down the rate at which we request objects from the network which would indicate that we own a particular address (whichever one to which they are sending all of their attack messages). Note that if an attacker connects to a target with many connections, this mitigation mechanism might not be sufficient. """ sleepTime = lengthOfTimeWeShouldUseToProcessThisMessage - (time.time() - self.messageProcessingStartTime) self._sleepForTimingAttackMitigation(sleepTime) # We have received an inv message def recinv(self, data): numberOfItemsInInv, lengthOfVarint = decodeVarint(data[:10]) if numberOfItemsInInv > 50000: sys.stderr.write('Too many items in inv message!') return if len(data) < lengthOfVarint + (numberOfItemsInInv * 32): logger.info('inv message doesn\'t contain enough data. Ignoring.') return startTime = time.time() advertisedSet = set() for i in range(numberOfItemsInInv): advertisedSet.add(data[lengthOfVarint + (32 * i):32 + lengthOfVarint + (32 * i)]) objectsNewToMe = advertisedSet for stream in self.streamNumber: objectsNewToMe -= Inventory().hashes_by_stream(stream) logger.info('inv message lists %s objects. Of those %s are new to me. It took %s seconds to figure that out.', numberOfItemsInInv, len(objectsNewToMe), time.time()-startTime) for item in objectsNewToMe: PendingDownload().add(item) self.someObjectsOfWhichThisRemoteNodeIsAlreadyAware[item] = 0 # helps us keep from sending inv messages to peers that already know about the objects listed therein # Send a getdata message to our peer to request the object with the given # hash def sendgetdata(self, hashes): if len(hashes) == 0: return logger.debug('sending getdata to retrieve %i objects', len(hashes)) payload = encodeVarint(len(hashes)) + ''.join(hashes) self.sendDataThreadQueue.put((0, 'sendRawData', protocol.CreatePacket('getdata', payload)), False) # We have received a getdata request from our peer def recgetdata(self, data): numberOfRequestedInventoryItems, lengthOfVarint = decodeVarint( data[:10]) if len(data) < lengthOfVarint + (32 * numberOfRequestedInventoryItems): logger.debug('getdata message does not contain enough data. Ignoring.') return self.antiIntersectionDelay(True) # only handle getdata requests if we have been connected long enough for i in xrange(numberOfRequestedInventoryItems): hash = data[lengthOfVarint + ( i * 32):32 + lengthOfVarint + (i * 32)] logger.debug('received getdata request for item:' + hexlify(hash)) if self.objectHashHolderInstance.hasHash(hash): self.antiIntersectionDelay() else: if hash in Inventory(): self.sendObject(hash, Inventory()[hash].payload) else: self.antiIntersectionDelay() logger.warning('%s asked for an object with a getdata which is not in either our memory inventory or our SQL inventory. We probably cleaned it out after advertising it but before they got around to asking for it.' % (self.peer,)) # Our peer has requested (in a getdata message) that we send an object. def sendObject(self, hash, payload): logger.debug('sending an object.') self.sendDataThreadQueue.put((0, 'sendRawData', (hash, protocol.CreatePacket('object',payload)))) def _checkIPAddress(self, host): if host[0:12] == '\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\xFF\xFF': hostStandardFormat = socket.inet_ntop(socket.AF_INET, host[12:]) return self._checkIPv4Address(host[12:], hostStandardFormat) elif host[0:6] == '\xfd\x87\xd8\x7e\xeb\x43': # Onion, based on BMD/bitcoind hostStandardFormat = base64.b32encode(host[6:]).lower() + ".onion" return hostStandardFormat else: hostStandardFormat = socket.inet_ntop(socket.AF_INET6, host) if hostStandardFormat == "": # This can happen on Windows systems which are not 64-bit compatible # so let us drop the IPv6 address. return False return self._checkIPv6Address(host, hostStandardFormat) def _checkIPv4Address(self, host, hostStandardFormat): if host[0] == '\x7F': # 127/8 logger.debug('Ignoring IP address in loopback range: ' + hostStandardFormat) return False if host[0] == '\x0A': # 10/8 logger.debug('Ignoring IP address in private range: ' + hostStandardFormat) return False if host[0:2] == '\xC0\xA8': # 192.168/16 logger.debug('Ignoring IP address in private range: ' + hostStandardFormat) return False if host[0:2] >= '\xAC\x10' and host[0:2] < '\xAC\x20': # 172.16/12 logger.debug('Ignoring IP address in private range:' + hostStandardFormat) return False return hostStandardFormat def _checkIPv6Address(self, host, hostStandardFormat): if host == ('\x00' * 15) + '\x01': logger.debug('Ignoring loopback address: ' + hostStandardFormat) return False if host[0] == '\xFE' and (ord(host[1]) & 0xc0) == 0x80: logger.debug ('Ignoring local address: ' + hostStandardFormat) return False if (ord(host[0]) & 0xfe) == 0xfc: logger.debug ('Ignoring unique local address: ' + hostStandardFormat) return False return hostStandardFormat # We have received an addr message. def recaddr(self, data): numberOfAddressesIncluded, lengthOfNumberOfAddresses = decodeVarint( data[:10]) if shared.verbose >= 1: logger.debug('addr message contains ' + str(numberOfAddressesIncluded) + ' IP addresses.') if numberOfAddressesIncluded > 1000 or numberOfAddressesIncluded == 0: return if len(data) != lengthOfNumberOfAddresses + (38 * numberOfAddressesIncluded): logger.debug('addr message does not contain the correct amount of data. Ignoring.') return for i in range(0, numberOfAddressesIncluded): fullHost = data[20 + lengthOfNumberOfAddresses + (38 * i):36 + lengthOfNumberOfAddresses + (38 * i)] recaddrStream, = unpack('>I', data[8 + lengthOfNumberOfAddresses + ( 38 * i):12 + lengthOfNumberOfAddresses + (38 * i)]) if recaddrStream == 0: continue if recaddrStream not in self.streamNumber and (recaddrStream / 2) not in self.streamNumber: # if the embedded stream number and its parent are not in my streams then ignore it. Someone might be trying funny business. continue recaddrServices, = unpack('>Q', data[12 + lengthOfNumberOfAddresses + ( 38 * i):20 + lengthOfNumberOfAddresses + (38 * i)]) recaddrPort, = unpack('>H', data[36 + lengthOfNumberOfAddresses + ( 38 * i):38 + lengthOfNumberOfAddresses + (38 * i)]) hostStandardFormat = self._checkIPAddress(fullHost) if hostStandardFormat is False: continue if recaddrPort == 0: continue timeSomeoneElseReceivedMessageFromThisNode, = unpack('>Q', data[lengthOfNumberOfAddresses + ( 38 * i):8 + lengthOfNumberOfAddresses + (38 * i)]) # This is the 'time' value in the received addr message. 64-bit. if recaddrStream not in knownnodes.knownNodes: # knownNodes is a dictionary of dictionaries with one outer dictionary for each stream. If the outer stream dictionary doesn't exist yet then we must make it. with knownnodes.knownNodesLock: knownnodes.knownNodes[recaddrStream] = {} peerFromAddrMessage = state.Peer(hostStandardFormat, recaddrPort) if peerFromAddrMessage not in knownnodes.knownNodes[recaddrStream]: knownnodes.trimKnownNodes(recaddrStream) # only if recent if timeSomeoneElseReceivedMessageFromThisNode > (int(time.time()) - 10800) and timeSomeoneElseReceivedMessageFromThisNode < (int(time.time()) + 10800): logger.debug('added new node ' + str(peerFromAddrMessage) + ' to knownNodes in stream ' + str(recaddrStream)) # bootstrap provider? if BMConfigParser().safeGetInt('bitmessagesettings', 'maxoutboundconnections') >= \ BMConfigParser().safeGetInt('bitmessagesettings', 'maxtotalconnections', 200): with knownnodes.knownNodesLock: knownnodes.knownNodes[recaddrStream][peerFromAddrMessage] = int(time.time()) - 10800 # normal mode else: with knownnodes.knownNodesLock: knownnodes.knownNodes[recaddrStream][peerFromAddrMessage] = timeSomeoneElseReceivedMessageFromThisNode hostDetails = ( timeSomeoneElseReceivedMessageFromThisNode, recaddrStream, recaddrServices, hostStandardFormat, recaddrPort) protocol.broadcastToSendDataQueues(( recaddrStream, 'advertisepeer', hostDetails)) shared.needToWriteKnownNodesToDisk = True # only update if normal mode elif BMConfigParser().safeGetInt('bitmessagesettings', 'maxoutboundconnections') < \ BMConfigParser().safeGetInt('bitmessagesettings', 'maxtotalconnections', 200): timeLastReceivedMessageFromThisNode = knownnodes.knownNodes[recaddrStream][ peerFromAddrMessage] if (timeLastReceivedMessageFromThisNode < timeSomeoneElseReceivedMessageFromThisNode) and (timeSomeoneElseReceivedMessageFromThisNode < int(time.time())+900): # 900 seconds for wiggle-room in case other nodes' clocks aren't quite right. with knownnodes.knownNodesLock: knownnodes.knownNodes[recaddrStream][peerFromAddrMessage] = timeSomeoneElseReceivedMessageFromThisNode for stream in self.streamNumber: logger.debug('knownNodes currently has %i nodes for stream %i', len(knownnodes.knownNodes[stream]), stream) # Send a huge addr message to our peer. This is only used # when we fully establish a connection with a # peer (with the full exchange of version and verack # messages). def sendaddr(self): def sendChunk(): if numberOfAddressesInAddrMessage == 0: return self.sendDataThreadQueue.put((0, 'sendRawData', \ protocol.CreatePacket('addr', \ encodeVarint(numberOfAddressesInAddrMessage) + payload))) # We are going to share a maximum number of 1000 addrs (per overlapping # stream) with our peer. 500 from overlapping streams, 250 from the # left child stream, and 250 from the right child stream. maxAddrCount = BMConfigParser().safeGetInt("bitmessagesettings", "maxaddrperstreamsend", 500) # protocol defines this as a maximum in one chunk protocolAddrLimit = 1000 # init numberOfAddressesInAddrMessage = 0 payload = '' for stream in self.streamNumber: addrsInMyStream = {} addrsInChildStreamLeft = {} addrsInChildStreamRight = {} with knownnodes.knownNodesLock: if len(knownnodes.knownNodes[stream]) > 0: filtered = {k: v for k, v in knownnodes.knownNodes[stream].items() if v > (int(time.time()) - shared.maximumAgeOfNodesThatIAdvertiseToOthers)} elemCount = len(filtered) if elemCount > maxAddrCount: elemCount = maxAddrCount # only if more recent than 3 hours addrsInMyStream = random.sample(filtered.items(), elemCount) # sent 250 only if the remote isn't interested in it if len(knownnodes.knownNodes[stream * 2]) > 0 and stream not in self.streamNumber: filtered = {k: v for k, v in knownnodes.knownNodes[stream*2].items() if v > (int(time.time()) - shared.maximumAgeOfNodesThatIAdvertiseToOthers)} elemCount = len(filtered) if elemCount > maxAddrCount / 2: elemCount = int(maxAddrCount / 2) addrsInChildStreamLeft = random.sample(filtered.items(), elemCount) if len(knownnodes.knownNodes[(stream * 2) + 1]) > 0 and stream not in self.streamNumber: filtered = {k: v for k, v in knownnodes.knownNodes[stream*2+1].items() if v > (int(time.time()) - shared.maximumAgeOfNodesThatIAdvertiseToOthers)} elemCount = len(filtered) if elemCount > maxAddrCount / 2: elemCount = int(maxAddrCount / 2) addrsInChildStreamRight = random.sample(filtered.items(), elemCount) for (HOST, PORT), timeLastReceivedMessageFromThisNode in addrsInMyStream: numberOfAddressesInAddrMessage += 1 payload += pack( '>Q', timeLastReceivedMessageFromThisNode) # 64-bit time payload += pack('>I', stream) payload += pack( '>q', 1) # service bit flags offered by this node payload += protocol.encodeHost(HOST) payload += pack('>H', PORT) # remote port if numberOfAddressesInAddrMessage >= protocolAddrLimit: sendChunk() payload = '' numberOfAddressesInAddrMessage = 0 for (HOST, PORT), timeLastReceivedMessageFromThisNode in addrsInChildStreamLeft: numberOfAddressesInAddrMessage += 1 payload += pack( '>Q', timeLastReceivedMessageFromThisNode) # 64-bit time payload += pack('>I', stream * 2) payload += pack( '>q', 1) # service bit flags offered by this node payload += protocol.encodeHost(HOST) payload += pack('>H', PORT) # remote port if numberOfAddressesInAddrMessage >= protocolAddrLimit: sendChunk() payload = '' numberOfAddressesInAddrMessage = 0 for (HOST, PORT), timeLastReceivedMessageFromThisNode in addrsInChildStreamRight: numberOfAddressesInAddrMessage += 1 payload += pack( '>Q', timeLastReceivedMessageFromThisNode) # 64-bit time payload += pack('>I', (stream * 2) + 1) payload += pack( '>q', 1) # service bit flags offered by this node payload += protocol.encodeHost(HOST) payload += pack('>H', PORT) # remote port if numberOfAddressesInAddrMessage >= protocolAddrLimit: sendChunk() payload = '' numberOfAddressesInAddrMessage = 0 # flush sendChunk() # We have received a version message def recversion(self, data): if len(data) < 83: # This version message is unreasonably short. Forget it. return if self.verackSent: """ We must have already processed the remote node's version message. There might be a time in the future when we Do want to process a new version message, like if the remote node wants to update the streams in which they are interested. But for now we'll ignore this version message """ return self.remoteProtocolVersion, = unpack('>L', data[:4]) self.services, = unpack('>q', data[4:12]) timestamp, = unpack('>Q', data[12:20]) self.timeOffset = timestamp - int(time.time()) self.myExternalIP = socket.inet_ntoa(data[40:44]) # print 'myExternalIP', self.myExternalIP self.remoteNodeIncomingPort, = unpack('>H', data[70:72]) # print 'remoteNodeIncomingPort', self.remoteNodeIncomingPort useragentLength, lengthOfUseragentVarint = decodeVarint( data[80:84]) readPosition = 80 + lengthOfUseragentVarint self.userAgent = data[readPosition:readPosition + useragentLength] # version check try: userAgentName, userAgentVersion = self.userAgent[1:-1].split(":", 2) except: userAgentName = self.userAgent userAgentVersion = "0.0.0" if userAgentName == "PyBitmessage": myVersion = [int(n) for n in softwareVersion.split(".")] try: remoteVersion = [int(n) for n in userAgentVersion.split(".")] except: remoteVersion = 0 # remote is newer, but do not cross between stable and unstable try: if cmp(remoteVersion, myVersion) > 0 and \ (myVersion[1] % 2 == remoteVersion[1] % 2): queues.UISignalQueue.put(('newVersionAvailable', remoteVersion)) except: pass readPosition += useragentLength numberOfStreamsInVersionMessage, lengthOfNumberOfStreamsInVersionMessage = decodeVarint( data[readPosition:]) readPosition += lengthOfNumberOfStreamsInVersionMessage self.remoteStreams = [] for i in range(numberOfStreamsInVersionMessage): newStreamNumber, lengthOfRemoteStreamNumber = decodeVarint(data[readPosition:]) readPosition += lengthOfRemoteStreamNumber self.remoteStreams.append(newStreamNumber) logger.debug('Remote node useragent: %s, streams: (%s), time offset: %is.', self.userAgent, ', '.join(str(x) for x in self.remoteStreams), self.timeOffset) # find shared streams self.streamNumber = sorted(set(state.streamsInWhichIAmParticipating).intersection(self.remoteStreams)) shared.connectedHostsList[ self.hostIdent] = 1 # We use this data structure to not only keep track of what hosts we are connected to so that we don't try to connect to them again, but also to list the connections count on the Network Status tab. self.sendDataThreadQueue.put((0, 'setStreamNumber', self.remoteStreams)) if data[72:80] == protocol.eightBytesOfRandomDataUsedToDetectConnectionsToSelf: self.sendDataThreadQueue.put((0, 'shutdown','no data')) logger.debug('Closing connection to myself: ' + str(self.peer)) return # The other peer's protocol version is of interest to the sendDataThread but we learn of it # in this version message. Let us inform the sendDataThread. self.sendDataThreadQueue.put((0, 'setRemoteProtocolVersion', self.remoteProtocolVersion)) if not isHostInPrivateIPRange(self.peer.host): with knownnodes.knownNodesLock: for stream in self.remoteStreams: knownnodes.knownNodes[stream][state.Peer(self.peer.host, self.remoteNodeIncomingPort)] = int(time.time()) if not self.initiatedConnection: # bootstrap provider? if BMConfigParser().safeGetInt('bitmessagesettings', 'maxoutboundconnections') >= \ BMConfigParser().safeGetInt('bitmessagesettings', 'maxtotalconnections', 200): knownnodes.knownNodes[stream][state.Peer(self.peer.host, self.remoteNodeIncomingPort)] -= 10800 # penalise inbound, 3 hours else: knownnodes.knownNodes[stream][state.Peer(self.peer.host, self.remoteNodeIncomingPort)] -= 7200 # penalise inbound, 2 hours shared.needToWriteKnownNodesToDisk = True self.sendverack() if self.initiatedConnection == False: self.sendversion() # Sends a version message def sendversion(self): logger.debug('Sending version message') self.sendDataThreadQueue.put((0, 'sendRawData', protocol.assembleVersionMessage( self.peer.host, self.peer.port, state.streamsInWhichIAmParticipating, not self.initiatedConnection))) # Sends a verack message def sendverack(self): logger.debug('Sending verack') self.sendDataThreadQueue.put((0, 'sendRawData', protocol.CreatePacket('verack'))) self.verackSent = True if self.verackReceived: self.connectionFullyEstablished()