softwareVersion = '0.4.2' verbose = 1 maximumAgeOfAnObjectThatIAmWillingToAccept = 216000 # Equals two days and 12 hours. lengthOfTimeToLeaveObjectsInInventory = 237600 # Equals two days and 18 hours. This should be longer than maximumAgeOfAnObjectThatIAmWillingToAccept so that we don't process messages twice. lengthOfTimeToHoldOnToAllPubkeys = 2419200 # Equals 4 weeks. You could make this longer if you want but making it shorter would not be advisable because there is a very small possibility that it could keep you from obtaining a needed pubkey for a period of time. maximumAgeOfObjectsThatIAdvertiseToOthers = 216000 # Equals two days and 12 hours maximumAgeOfNodesThatIAdvertiseToOthers = 10800 # Equals three hours useVeryEasyProofOfWorkForTesting = False # If you set this to True while on the normal network, you won't be able to send or sometimes receive messages. # Libraries. import collections import ConfigParser import os import pickle import Queue import random import socket import sys import stat import threading import time from os import path, environ # Project imports. from addresses import * import highlevelcrypto import shared import helper_startup from helper_sql import * config = ConfigParser.SafeConfigParser() myECCryptorObjects = {} MyECSubscriptionCryptorObjects = {} myAddressesByHash = {} #The key in this dictionary is the RIPE hash which is encoded in an address and value is the address itself. myAddressesByTag = {} # The key in this dictionary is the tag generated from the address. broadcastSendersForWhichImWatching = {} workerQueue = Queue.Queue() UISignalQueue = Queue.Queue() addressGeneratorQueue = Queue.Queue() knownNodesLock = threading.Lock() knownNodes = {} sendDataQueues = [] #each sendData thread puts its queue in this list. inventory = {} #of objects (like msg payloads and pubkey payloads) Does not include protocol headers (the first 24 bytes of each packet). inventoryLock = threading.Lock() #Guarantees that two receiveDataThreads don't receive and process the same message concurrently (probably sent by a malicious individual) printLock = threading.Lock() objectProcessorQueueSizeLock = threading.Lock() objectProcessorQueueSize = 0 # in Bytes. We maintain this to prevent nodes from flooing us with objects which take up too much memory. If this gets too big we'll sleep before asking for further objects. appdata = '' #holds the location of the application data storage directory statusIconColor = 'red' connectedHostsList = {} #List of hosts to which we are connected. Used to guarantee that the outgoingSynSender threads won't connect to the same remote node twice. shutdown = 0 #Set to 1 by the doCleanShutdown function. Used to tell the proof of work worker threads to exit. alreadyAttemptedConnectionsList = { } # This is a list of nodes to which we have already attempted a connection alreadyAttemptedConnectionsListLock = threading.Lock() alreadyAttemptedConnectionsListResetTime = int( time.time()) # used to clear out the alreadyAttemptedConnectionsList periodically so that we will retry connecting to hosts to which we have already tried to connect. numberOfObjectsThatWeHaveYetToGetPerPeer = {} neededPubkeys = {} eightBytesOfRandomDataUsedToDetectConnectionsToSelf = pack( '>Q', random.randrange(1, 18446744073709551615)) successfullyDecryptMessageTimings = [ ] # A list of the amounts of time it took to successfully decrypt msg messages apiAddressGeneratorReturnQueue = Queue.Queue( ) # The address generator thread uses this queue to get information back to the API thread. ackdataForWhichImWatching = {} clientHasReceivedIncomingConnections = False #used by API command clientStatus numberOfMessagesProcessed = 0 numberOfBroadcastsProcessed = 0 numberOfPubkeysProcessed = 0 numberOfInventoryLookupsPerformed = 0 numberOfBytesReceived = 0 numberOfBytesSent = 0 daemon = False inventorySets = {} # key = streamNumer, value = a set which holds the inventory object hashes that we are aware of. This is used whenever we receive an inv message from a peer to check to see what items are new to us. We don't delete things out of it; instead, the singleCleaner thread clears and refills it every couple hours. needToWriteKnownNodesToDisk = False # If True, the singleCleaner will write it to disk eventually. maximumLengthOfTimeToBotherResendingMessages = 0 objectProcessorQueue = Queue.Queue( ) # receiveDataThreads dump objects they hear on the network into this queue to be processed. streamsInWhichIAmParticipating = {} #If changed, these values will cause particularly unexpected behavior: You won't be able to either send or receive messages because the proof of work you do (or demand) won't match that done or demanded by others. Don't change them! networkDefaultProofOfWorkNonceTrialsPerByte = 320 #The amount of work that should be performed (and demanded) per byte of the payload. Double this number to double the work. networkDefaultPayloadLengthExtraBytes = 14000 #To make sending short messages a little more difficult, this value is added to the payload length for use in calculating the proof of work target. # Remember here the RPC port read from namecoin.conf so we can restore to # it as default whenever the user changes the "method" selection for # namecoin integration to "namecoind". namecoinDefaultRpcPort = "8336" # When using py2exe or py2app, the variable frozen is added to the sys # namespace. This can be used to setup a different code path for # binary distributions vs source distributions. frozen = getattr(sys,'frozen', None) # If the trustedpeer option is specified in keys.dat then this will # contain a Peer which will be connected to instead of using the # addresses advertised by other peers. The client will only connect to # this peer and the timing attack mitigation will be disabled in order # to download data faster. The expected use case is where the user has # a fast connection to a trusted server where they run a BitMessage # daemon permanently. If they then run a second instance of the client # on a local machine periodically when they want to check for messages # it will sync with the network a lot faster without compromising # security. trustedPeer = None def isInSqlInventory(hash): queryreturn = sqlQuery('''select hash from inventory where hash=?''', hash) return queryreturn != [] def encodeHost(host): if host.find(':') == -1: return '\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\xFF\xFF' + \ socket.inet_aton(host) else: return socket.inet_pton(socket.AF_INET6, host) def assembleVersionMessage(remoteHost, remotePort, myStreamNumber): payload = '' payload += pack('>L', 2) # protocol version. payload += pack('>q', 1) # bitflags of the services I offer. payload += pack('>q', int(time.time())) payload += pack( '>q', 1) # boolservices of remote connection; ignored by the remote host. payload += encodeHost(remoteHost) payload += pack('>H', remotePort) # remote IPv6 and port payload += pack('>q', 1) # bitflags of the services I offer. payload += '\x00\x00\x00\x00\x00\x00\x00\x00\x00\x00\xFF\xFF' + pack( '>L', 2130706433) # = 127.0.0.1. This will be ignored by the remote host. The actual remote connected IP will be used. payload += pack('>H', shared.config.getint( 'bitmessagesettings', 'port')) random.seed() payload += eightBytesOfRandomDataUsedToDetectConnectionsToSelf userAgent = '/PyBitmessage:' + shared.softwareVersion + '/' payload += encodeVarint(len(userAgent)) payload += userAgent payload += encodeVarint( 1) # The number of streams about which I care. PyBitmessage currently only supports 1 per connection. payload += encodeVarint(myStreamNumber) datatosend = '\xe9\xbe\xb4\xd9' # magic bits, slighly different from Bitcoin's magic bits. datatosend = datatosend + 'version\x00\x00\x00\x00\x00' # version command datatosend = datatosend + pack('>L', len(payload)) # payload length datatosend = datatosend + hashlib.sha512(payload).digest()[0:4] return datatosend + payload def lookupAppdataFolder(): APPNAME = "PyBitmessage" if "BITMESSAGE_HOME" in environ: dataFolder = environ["BITMESSAGE_HOME"] if dataFolder[-1] not in [os.path.sep, os.path.altsep]: dataFolder += os.path.sep elif sys.platform == 'darwin': if "HOME" in environ: dataFolder = path.join(os.environ["HOME"], "Library/Application Support/", APPNAME) + '/' else: stringToLog = 'Could not find home folder, please report this message and your OS X version to the BitMessage Github.' if 'logger' in globals(): logger.critical(stringToLog) else: print stringToLog sys.exit() elif 'win32' in sys.platform or 'win64' in sys.platform: dataFolder = path.join(environ['APPDATA'].decode(sys.getfilesystemencoding(), 'ignore'), APPNAME) + path.sep else: from shutil import move try: dataFolder = path.join(environ["XDG_CONFIG_HOME"], APPNAME) except KeyError: dataFolder = path.join(environ["HOME"], ".config", APPNAME) # Migrate existing data to the proper location if this is an existing install try: move(path.join(environ["HOME"], ".%s" % APPNAME), dataFolder) stringToLog = "Moving data folder to %s" % (dataFolder) if 'logger' in globals(): logger.info(stringToLog) else: print stringToLog except IOError: # Old directory may not exist. pass dataFolder = dataFolder + '/' return dataFolder def isAddressInMyAddressBook(address): queryreturn = sqlQuery( '''select address from addressbook where address=?''', address) return queryreturn != [] #At this point we should really just have a isAddressInMy(book, address)... def isAddressInMySubscriptionsList(address): queryreturn = sqlQuery( '''select * from subscriptions where address=?''', str(address)) return queryreturn != [] def isAddressInMyAddressBookSubscriptionsListOrWhitelist(address): if isAddressInMyAddressBook(address): return True queryreturn = sqlQuery('''SELECT address FROM whitelist where address=? and enabled = '1' ''', address) if queryreturn <> []: return True queryreturn = sqlQuery( '''select address from subscriptions where address=? and enabled = '1' ''', address) if queryreturn <> []: return True return False def safeConfigGetBoolean(section,field): try: return config.getboolean(section,field) except Exception, err: return False def decodeWalletImportFormat(WIFstring): fullString = arithmetic.changebase(WIFstring,58,256) privkey = fullString[:-4] if fullString[-4:] != hashlib.sha256(hashlib.sha256(privkey).digest()).digest()[:4]: logger.critical('Major problem! When trying to decode one of your private keys, the checksum ' 'failed. Here are the first 6 characters of the PRIVATE key: %s' % str(WIFstring)[:6]) os._exit(0) return "" else: #checksum passed if privkey[0] == '\x80': return privkey[1:] else: logger.critical('Major problem! When trying to decode one of your private keys, the ' 'checksum passed but the key doesn\'t begin with hex 80. Here is the ' 'PRIVATE key: %s' % str(WIFstring)) os._exit(0) return "" def reloadMyAddressHashes(): logger.debug('reloading keys from keys.dat file') myECCryptorObjects.clear() myAddressesByHash.clear() myAddressesByTag.clear() #myPrivateKeys.clear() keyfileSecure = checkSensitiveFilePermissions(appdata + 'keys.dat') configSections = config.sections() hasEnabledKeys = False for addressInKeysFile in configSections: if addressInKeysFile <> 'bitmessagesettings': isEnabled = config.getboolean(addressInKeysFile, 'enabled') if isEnabled: hasEnabledKeys = True status,addressVersionNumber,streamNumber,hash = decodeAddress(addressInKeysFile) if addressVersionNumber == 2 or addressVersionNumber == 3 or addressVersionNumber == 4: # Returns a simple 32 bytes of information encoded in 64 Hex characters, # or null if there was an error. privEncryptionKey = decodeWalletImportFormat( config.get(addressInKeysFile, 'privencryptionkey')).encode('hex') if len(privEncryptionKey) == 64:#It is 32 bytes encoded as 64 hex characters myECCryptorObjects[hash] = highlevelcrypto.makeCryptor(privEncryptionKey) myAddressesByHash[hash] = addressInKeysFile tag = hashlib.sha512(hashlib.sha512(encodeVarint( addressVersionNumber) + encodeVarint(streamNumber) + hash).digest()).digest()[32:] myAddressesByTag[tag] = addressInKeysFile else: logger.error('Error in reloadMyAddressHashes: Can\'t handle address versions other than 2, 3, or 4.\n') if not keyfileSecure: fixSensitiveFilePermissions(appdata + 'keys.dat', hasEnabledKeys) def reloadBroadcastSendersForWhichImWatching(): broadcastSendersForWhichImWatching.clear() MyECSubscriptionCryptorObjects.clear() queryreturn = sqlQuery('SELECT address FROM subscriptions where enabled=1') logger.debug('reloading subscriptions...') for row in queryreturn: address, = row status,addressVersionNumber,streamNumber,hash = decodeAddress(address) if addressVersionNumber == 2: broadcastSendersForWhichImWatching[hash] = 0 #Now, for all addresses, even version 2 addresses, we should create Cryptor objects in a dictionary which we will use to attempt to decrypt encrypted broadcast messages. if addressVersionNumber <= 3: privEncryptionKey = hashlib.sha512(encodeVarint(addressVersionNumber)+encodeVarint(streamNumber)+hash).digest()[:32] MyECSubscriptionCryptorObjects[hash] = highlevelcrypto.makeCryptor(privEncryptionKey.encode('hex')) else: doubleHashOfAddressData = hashlib.sha512(hashlib.sha512(encodeVarint( addressVersionNumber) + encodeVarint(streamNumber) + hash).digest()).digest() tag = doubleHashOfAddressData[32:] privEncryptionKey = doubleHashOfAddressData[:32] MyECSubscriptionCryptorObjects[tag] = highlevelcrypto.makeCryptor(privEncryptionKey.encode('hex')) def isProofOfWorkSufficient( data, nonceTrialsPerByte=0, payloadLengthExtraBytes=0): if nonceTrialsPerByte < networkDefaultProofOfWorkNonceTrialsPerByte: nonceTrialsPerByte = networkDefaultProofOfWorkNonceTrialsPerByte if payloadLengthExtraBytes < networkDefaultPayloadLengthExtraBytes: payloadLengthExtraBytes = networkDefaultPayloadLengthExtraBytes POW, = unpack('>Q', hashlib.sha512(hashlib.sha512(data[ :8] + hashlib.sha512(data[8:]).digest()).digest()).digest()[0:8]) return POW <= 2 ** 64 / ((len(data) + payloadLengthExtraBytes) * (nonceTrialsPerByte)) def doCleanShutdown(): global shutdown shutdown = 1 #Used to tell proof of work worker threads and the objectProcessorThread to exit. broadcastToSendDataQueues((0, 'shutdown', 'all')) with shared.objectProcessorQueueSizeLock: data = 'no data' shared.objectProcessorQueueSize += len(data) objectProcessorQueue.put(('checkShutdownVariable',data)) knownNodesLock.acquire() UISignalQueue.put(('updateStatusBar','Saving the knownNodes list of peers to disk...')) output = open(appdata + 'knownnodes.dat', 'wb') logger.info('finished opening knownnodes.dat. Now pickle.dump') pickle.dump(knownNodes, output) logger.info('Completed pickle.dump. Closing output...') output.close() knownNodesLock.release() logger.info('Finished closing knownnodes.dat output file.') UISignalQueue.put(('updateStatusBar','Done saving the knownNodes list of peers to disk.')) logger.info('Flushing inventory in memory out to disk...') UISignalQueue.put(( 'updateStatusBar', 'Flushing inventory in memory out to disk. This should normally only take a second...')) flushInventory() # Verify that the objectProcessor has finished exiting. It should have incremented the # shutdown variable from 1 to 2. This must finish before we command the sqlThread to exit. while shutdown == 1: time.sleep(.1) # This one last useless query will guarantee that the previous flush committed and that the # objectProcessorThread committed before we close the program. sqlQuery('SELECT address FROM subscriptions') logger.info('Finished flushing inventory.') sqlStoredProcedure('exit') # Wait long enough to guarantee that any running proof of work worker threads will check the # shutdown variable and exit. If the main thread closes before they do then they won't stop. time.sleep(.25) if safeConfigGetBoolean('bitmessagesettings','daemon'): logger.info('Clean shutdown complete.') os._exit(0) # When you want to command a sendDataThread to do something, like shutdown or send some data, this # function puts your data into the queues for each of the sendDataThreads. The sendDataThreads are # responsible for putting their queue into (and out of) the sendDataQueues list. def broadcastToSendDataQueues(data): # logger.debug('running broadcastToSendDataQueues') for q in sendDataQueues: q.put(data) def flushInventory(): #Note that the singleCleanerThread clears out the inventory dictionary from time to time, although it only clears things that have been in the dictionary for a long time. This clears the inventory dictionary Now. with SqlBulkExecute() as sql: for hash, storedValue in inventory.items(): objectType, streamNumber, payload, receivedTime, tag = storedValue sql.execute('''INSERT INTO inventory VALUES (?,?,?,?,?,?)''', hash,objectType,streamNumber,payload,receivedTime,tag) del inventory[hash] def fixPotentiallyInvalidUTF8Data(text): try: unicode(text,'utf-8') return text except: output = 'Part of the message is corrupt. The message cannot be displayed the normal way.\n\n' + repr(text) return output # Checks sensitive file permissions for inappropriate umask during keys.dat creation. # (Or unwise subsequent chmod.) # # Returns true iff file appears to have appropriate permissions. def checkSensitiveFilePermissions(filename): if sys.platform == 'win32': # TODO: This might deserve extra checks by someone familiar with # Windows systems. return True elif sys.platform[:7] == 'freebsd': # FreeBSD file systems are the same as major Linux file systems present_permissions = os.stat(filename)[0] disallowed_permissions = stat.S_IRWXG | stat.S_IRWXO return present_permissions & disallowed_permissions == 0 else: try: # Skip known problems for non-Win32 filesystems without POSIX permissions. import subprocess fstype = subprocess.check_output('stat -f -c "%%T" %s' % (filename), shell=True, stderr=subprocess.STDOUT) if 'fuseblk' in fstype: logger.info('Skipping file permissions check for %s. Filesystem fuseblk detected.', filename) return True except: # Swallow exception here, but we might run into trouble later! logger.error('Could not determine filesystem type. %s', filename) present_permissions = os.stat(filename)[0] disallowed_permissions = stat.S_IRWXG | stat.S_IRWXO return present_permissions & disallowed_permissions == 0 # Fixes permissions on a sensitive file. def fixSensitiveFilePermissions(filename, hasEnabledKeys): if hasEnabledKeys: logger.warning('Keyfile had insecure permissions, and there were enabled keys. ' 'The truly paranoid should stop using them immediately.') else: logger.warning('Keyfile had insecure permissions, but there were no enabled keys.') try: present_permissions = os.stat(filename)[0] disallowed_permissions = stat.S_IRWXG | stat.S_IRWXO allowed_permissions = ((1<<32)-1) ^ disallowed_permissions new_permissions = ( allowed_permissions & present_permissions) os.chmod(filename, new_permissions) logger.info('Keyfile permissions automatically fixed.') except Exception, e: logger.exception('Keyfile permissions could not be fixed.') raise def isBitSetWithinBitfield(fourByteString, n): # Uses MSB 0 bit numbering across 4 bytes of data n = 31 - n x, = unpack('>L', fourByteString) return x & 2**n != 0 def decryptAndCheckPubkeyPayload(payload, address): status, addressVersion, streamNumber, ripe = decodeAddress(address) doubleHashOfAddressData = hashlib.sha512(hashlib.sha512(encodeVarint( addressVersion) + encodeVarint(streamNumber) + ripe).digest()).digest() readPosition = 8 # bypass the nonce readPosition += 8 # bypass the time embeddedVersionNumber, varintLength = decodeVarint( payload[readPosition:readPosition + 10]) if embeddedVersionNumber != addressVersion: logger.info('Pubkey decryption was UNsuccessful due to address version mismatch. This shouldn\'t have happened.') return 'failed' readPosition += varintLength embeddedStreamNumber, varintLength = decodeVarint( payload[readPosition:readPosition + 10]) if embeddedStreamNumber != streamNumber: logger.info('Pubkey decryption was UNsuccessful due to stream number mismatch. This shouldn\'t have happened.') return 'failed' readPosition += varintLength signedData = payload[8:readPosition] # Some of the signed data is not encrypted so let's keep it for now. toTag = payload[readPosition:readPosition+32] readPosition += 32 #for the tag encryptedData = payload[readPosition:] # Let us try to decrypt the pubkey privEncryptionKey = doubleHashOfAddressData[:32] cryptorObject = highlevelcrypto.makeCryptor(privEncryptionKey.encode('hex')) try: decryptedData = cryptorObject.decrypt(encryptedData) except: # Someone must have encrypted some data with a different key # but tagged it with a tag for which we are watching. logger.info('Pubkey decryption was UNsuccessful. This shouldn\'t have happened.') return 'failed' logger.debug('Pubkey decryption successful') readPosition = 4 # bypass the behavior bitfield publicSigningKey = '\x04' + decryptedData[readPosition:readPosition + 64] # Is it possible for a public key to be invalid such that trying to # encrypt or check a sig with it will cause an error? If it is, we should # probably test these keys here. readPosition += 64 publicEncryptionKey = '\x04' + decryptedData[readPosition:readPosition + 64] readPosition += 64 specifiedNonceTrialsPerByte, specifiedNonceTrialsPerByteLength = decodeVarint( decryptedData[readPosition:readPosition + 10]) readPosition += specifiedNonceTrialsPerByteLength specifiedPayloadLengthExtraBytes, specifiedPayloadLengthExtraBytesLength = decodeVarint( decryptedData[readPosition:readPosition + 10]) readPosition += specifiedPayloadLengthExtraBytesLength signedData += decryptedData[:readPosition] signatureLength, signatureLengthLength = decodeVarint( decryptedData[readPosition:readPosition + 10]) readPosition += signatureLengthLength signature = decryptedData[readPosition:readPosition + signatureLength] try: if not highlevelcrypto.verify(signedData, signature, publicSigningKey.encode('hex')): logger.info('ECDSA verify failed (within decryptAndCheckPubkeyPayload).') return 'failed' logger.debug('ECDSA verify passed (within decryptAndCheckPubkeyPayload)') except Exception as err: logger.debug('ECDSA verify failed (within decryptAndCheckPubkeyPayload) %s' % err) return 'failed' sha = hashlib.new('sha512') sha.update(publicSigningKey + publicEncryptionKey) ripeHasher = hashlib.new('ripemd160') ripeHasher.update(sha.digest()) embeddedRipe = ripeHasher.digest() if embeddedRipe != ripe: # Although this pubkey object had the tag were were looking for and was # encrypted with the correct encryption key, it doesn't contain the # correct keys. Someone is either being malicious or using buggy software. logger.info('Pubkey decryption was UNsuccessful due to RIPE mismatch. This shouldn\'t have happened.') return 'failed' t = (ripe, addressVersion, signedData, int(time.time()), 'yes') sqlExecute('''INSERT INTO pubkeys VALUES (?,?,?,?,?)''', *t) return 'successful' Peer = collections.namedtuple('Peer', ['host', 'port']) def checkAndShareMsgWithPeers(data): # Let us check to make sure that the proof of work is sufficient. if not isProofOfWorkSufficient(data): logger.debug('Proof of work in msg message insufficient.') return readPosition = 8 embeddedTime, = unpack('>I', data[readPosition:readPosition + 4]) # This section is used for the transition from 32 bit time to 64 bit # time in the protocol. if embeddedTime == 0: embeddedTime, = unpack('>Q', data[readPosition:readPosition + 8]) readPosition += 8 else: readPosition += 4 if embeddedTime > (int(time.time()) + 10800): logger.debug('The embedded time in this msg message is more than three hours in the future. That doesn\'t make sense. Ignoring message.') return if embeddedTime < (int(time.time()) - maximumAgeOfAnObjectThatIAmWillingToAccept): logger.debug('The embedded time in this msg message is too old. Ignoring message.') return streamNumberAsClaimedByMsg, streamNumberAsClaimedByMsgLength = decodeVarint( data[readPosition:readPosition + 9]) if not streamNumberAsClaimedByMsg in streamsInWhichIAmParticipating: logger.debug('The streamNumber %s isn\'t one we are interested in.' % streamNumberAsClaimedByMsg) return readPosition += streamNumberAsClaimedByMsgLength inventoryHash = calculateInventoryHash(data) shared.numberOfInventoryLookupsPerformed += 1 inventoryLock.acquire() if inventoryHash in inventory: logger.debug('We have already received this msg message. Ignoring.') inventoryLock.release() return elif isInSqlInventory(inventoryHash): logger.debug('We have already received this msg message (it is stored on disk in the SQL inventory). Ignoring it.') inventoryLock.release() return # This msg message is valid. Let's let our peers know about it. objectType = 'msg' inventory[inventoryHash] = ( objectType, streamNumberAsClaimedByMsg, data, embeddedTime,'') inventorySets[streamNumberAsClaimedByMsg].add(inventoryHash) inventoryLock.release() logger.debug('advertising inv with hash: %s' % inventoryHash.encode('hex')) broadcastToSendDataQueues((streamNumberAsClaimedByMsg, 'advertiseobject', inventoryHash)) # Now let's enqueue it to be processed ourselves. # If we already have too much data in the queue to be processed, just sleep for now. while shared.objectProcessorQueueSize > 120000000: time.sleep(2) with shared.objectProcessorQueueSizeLock: shared.objectProcessorQueueSize += len(data) objectProcessorQueue.put((objectType,data)) def checkAndSharegetpubkeyWithPeers(data): if not isProofOfWorkSufficient(data): logger.debug('Proof of work in getpubkey message insufficient.') return if len(data) < 34: logger.debug('getpubkey message doesn\'t contain enough data. Ignoring.') return readPosition = 8 # bypass the nonce embeddedTime, = unpack('>I', data[readPosition:readPosition + 4]) # This section is used for the transition from 32 bit time to 64 bit # time in the protocol. if embeddedTime == 0: embeddedTime, = unpack('>Q', data[readPosition:readPosition + 8]) readPosition += 8 else: readPosition += 4 if embeddedTime > int(time.time()) + 10800: logger.debug('The time in this getpubkey message is too new. Ignoring it. Time: %s' % embeddedTime) return if embeddedTime < int(time.time()) - maximumAgeOfAnObjectThatIAmWillingToAccept: logger.debug('The time in this getpubkey message is too old. Ignoring it. Time: %s' % embeddedTime) return requestedAddressVersionNumber, addressVersionLength = decodeVarint( data[readPosition:readPosition + 10]) readPosition += addressVersionLength streamNumber, streamNumberLength = decodeVarint( data[readPosition:readPosition + 10]) if not streamNumber in streamsInWhichIAmParticipating: logger.debug('The streamNumber %s isn\'t one we are interested in.' % streamNumber) return readPosition += streamNumberLength shared.numberOfInventoryLookupsPerformed += 1 inventoryHash = calculateInventoryHash(data) inventoryLock.acquire() if inventoryHash in inventory: logger.debug('We have already received this getpubkey request. Ignoring it.') inventoryLock.release() return elif isInSqlInventory(inventoryHash): logger.debug('We have already received this getpubkey request (it is stored on disk in the SQL inventory). Ignoring it.') inventoryLock.release() return objectType = 'getpubkey' inventory[inventoryHash] = ( objectType, streamNumber, data, embeddedTime,'') inventorySets[streamNumber].add(inventoryHash) inventoryLock.release() # This getpubkey request is valid. Forward to peers. logger.debug('advertising inv with hash: %s' % inventoryHash.encode('hex')) broadcastToSendDataQueues((streamNumber, 'advertiseobject', inventoryHash)) # Now let's queue it to be processed ourselves. # If we already have too much data in the queue to be processed, just sleep for now. while shared.objectProcessorQueueSize > 120000000: time.sleep(2) with shared.objectProcessorQueueSizeLock: shared.objectProcessorQueueSize += len(data) objectProcessorQueue.put((objectType,data)) def checkAndSharePubkeyWithPeers(data): if len(data) < 146 or len(data) > 420: # sanity check return # Let us make sure that the proof of work is sufficient. if not isProofOfWorkSufficient(data): logger.debug('Proof of work in pubkey message insufficient.') return readPosition = 8 # for the nonce embeddedTime, = unpack('>I', data[readPosition:readPosition + 4]) # This section is used for the transition from 32 bit time to 64 bit # time in the protocol. if embeddedTime == 0: embeddedTime, = unpack('>Q', data[readPosition:readPosition + 8]) readPosition += 8 else: readPosition += 4 if embeddedTime < int(time.time()) - lengthOfTimeToHoldOnToAllPubkeys: logger.debug('The embedded time in this pubkey message is too old. Ignoring. Embedded time is: %s' % embeddedTime) return if embeddedTime > int(time.time()) + 10800: logger.debug('The embedded time in this pubkey message more than several hours in the future. This is irrational. Ignoring message.') return addressVersion, varintLength = decodeVarint( data[readPosition:readPosition + 10]) readPosition += varintLength streamNumber, varintLength = decodeVarint( data[readPosition:readPosition + 10]) readPosition += varintLength if not streamNumber in streamsInWhichIAmParticipating: logger.debug('The streamNumber %s isn\'t one we are interested in.' % streamNumber) return if addressVersion >= 4: tag = data[readPosition:readPosition + 32] logger.debug('tag in received pubkey is: %s' % tag.encode('hex')) else: tag = '' shared.numberOfInventoryLookupsPerformed += 1 inventoryHash = calculateInventoryHash(data) inventoryLock.acquire() if inventoryHash in inventory: logger.debug('We have already received this pubkey. Ignoring it.') inventoryLock.release() return elif isInSqlInventory(inventoryHash): logger.debug('We have already received this pubkey (it is stored on disk in the SQL inventory). Ignoring it.') inventoryLock.release() return objectType = 'pubkey' inventory[inventoryHash] = ( objectType, streamNumber, data, embeddedTime, tag) inventorySets[streamNumber].add(inventoryHash) inventoryLock.release() # This object is valid. Forward it to peers. logger.debug('advertising inv with hash: %s' % inventoryHash.encode('hex')) broadcastToSendDataQueues((streamNumber, 'advertiseobject', inventoryHash)) # Now let's queue it to be processed ourselves. # If we already have too much data in the queue to be processed, just sleep for now. while shared.objectProcessorQueueSize > 120000000: time.sleep(2) with shared.objectProcessorQueueSizeLock: shared.objectProcessorQueueSize += len(data) objectProcessorQueue.put((objectType,data)) def checkAndShareBroadcastWithPeers(data): # Let us verify that the proof of work is sufficient. if not isProofOfWorkSufficient(data): logger.debug('Proof of work in broadcast message insufficient.') return readPosition = 8 # bypass the nonce embeddedTime, = unpack('>I', data[readPosition:readPosition + 4]) # This section is used for the transition from 32 bit time to 64 bit # time in the protocol. if embeddedTime == 0: embeddedTime, = unpack('>Q', data[readPosition:readPosition + 8]) readPosition += 8 else: readPosition += 4 if embeddedTime > (int(time.time()) + 10800): # prevent funny business logger.debug('The embedded time in this broadcast message is more than three hours in the future. That doesn\'t make sense. Ignoring message.') return if embeddedTime < (int(time.time()) - maximumAgeOfAnObjectThatIAmWillingToAccept): logger.debug('The embedded time in this broadcast message is too old. Ignoring message.') return if len(data) < 180: logger.debug('The payload length of this broadcast packet is unreasonably low. Someone is probably trying funny business. Ignoring message.') return broadcastVersion, broadcastVersionLength = decodeVarint( data[readPosition:readPosition + 10]) readPosition += broadcastVersionLength if broadcastVersion >= 2: streamNumber, streamNumberLength = decodeVarint(data[readPosition:readPosition + 10]) readPosition += streamNumberLength if not streamNumber in streamsInWhichIAmParticipating: logger.debug('The streamNumber %s isn\'t one we are interested in.' % streamNumber) return if broadcastVersion >= 3: tag = data[readPosition:readPosition+32] else: tag = '' shared.numberOfInventoryLookupsPerformed += 1 inventoryLock.acquire() inventoryHash = calculateInventoryHash(data) if inventoryHash in inventory: logger.debug('We have already received this broadcast object. Ignoring.') inventoryLock.release() return elif isInSqlInventory(inventoryHash): logger.debug('We have already received this broadcast object (it is stored on disk in the SQL inventory). Ignoring it.') inventoryLock.release() return # It is valid. Let's let our peers know about it. objectType = 'broadcast' inventory[inventoryHash] = ( objectType, streamNumber, data, embeddedTime, tag) inventorySets[streamNumber].add(inventoryHash) inventoryLock.release() # This object is valid. Forward it to peers. logger.debug('advertising inv with hash: %s' % inventoryHash.encode('hex')) broadcastToSendDataQueues((streamNumber, 'advertiseobject', inventoryHash)) # Now let's queue it to be processed ourselves. # If we already have too much data in the queue to be processed, just sleep for now. while shared.objectProcessorQueueSize > 120000000: time.sleep(2) with shared.objectProcessorQueueSizeLock: shared.objectProcessorQueueSize += len(data) objectProcessorQueue.put((objectType,data)) helper_startup.loadConfig() from debug import logger