PyBitmessage-2021-04-27/src/class_addressGenerator.py
2013-09-21 13:30:46 -04:00

312 lines
18 KiB
Python

import shared
import threading
import time
import sys
from pyelliptic.openssl import OpenSSL
import ctypes
import hashlib
import highlevelcrypto
from addresses import *
from pyelliptic import arithmetic
import tr
class addressGenerator(threading.Thread):
def __init__(self):
# QThread.__init__(self, parent)
threading.Thread.__init__(self)
def run(self):
while True:
queueValue = shared.addressGeneratorQueue.get()
nonceTrialsPerByte = 0
payloadLengthExtraBytes = 0
if queueValue[0] == 'createChan':
command, addressVersionNumber, streamNumber, label, deterministicPassphrase = queueValue
eighteenByteRipe = False
numberOfAddressesToMake = 1
numberOfNullBytesDemandedOnFrontOfRipeHash = 1
elif queueValue[0] == 'joinChan':
command, chanAddress, label, deterministicPassphrase = queueValue
eighteenByteRipe = False
addressVersionNumber = decodeAddress(chanAddress)[1]
streamNumber = decodeAddress(chanAddress)[2]
numberOfAddressesToMake = 1
numberOfNullBytesDemandedOnFrontOfRipeHash = 1
elif len(queueValue) == 7:
command, addressVersionNumber, streamNumber, label, numberOfAddressesToMake, deterministicPassphrase, eighteenByteRipe = queueValue
try:
numberOfNullBytesDemandedOnFrontOfRipeHash = shared.config.getint(
'bitmessagesettings', 'numberofnullbytesonaddress')
except:
if eighteenByteRipe:
numberOfNullBytesDemandedOnFrontOfRipeHash = 2
else:
numberOfNullBytesDemandedOnFrontOfRipeHash = 1 # the default
elif len(queueValue) == 9:
command, addressVersionNumber, streamNumber, label, numberOfAddressesToMake, deterministicPassphrase, eighteenByteRipe, nonceTrialsPerByte, payloadLengthExtraBytes = queueValue
try:
numberOfNullBytesDemandedOnFrontOfRipeHash = shared.config.getint(
'bitmessagesettings', 'numberofnullbytesonaddress')
except:
if eighteenByteRipe:
numberOfNullBytesDemandedOnFrontOfRipeHash = 2
else:
numberOfNullBytesDemandedOnFrontOfRipeHash = 1 # the default
else:
sys.stderr.write(
'Programming error: A structure with the wrong number of values was passed into the addressGeneratorQueue. Here is the queueValue: %s\n' % repr(queueValue))
if addressVersionNumber < 3 or addressVersionNumber > 4:
sys.stderr.write(
'Program error: For some reason the address generator queue has been given a request to create at least one version %s address which it cannot do.\n' % addressVersionNumber)
if nonceTrialsPerByte == 0:
nonceTrialsPerByte = shared.config.getint(
'bitmessagesettings', 'defaultnoncetrialsperbyte')
if nonceTrialsPerByte < shared.networkDefaultProofOfWorkNonceTrialsPerByte:
nonceTrialsPerByte = shared.networkDefaultProofOfWorkNonceTrialsPerByte
if payloadLengthExtraBytes == 0:
payloadLengthExtraBytes = shared.config.getint(
'bitmessagesettings', 'defaultpayloadlengthextrabytes')
if payloadLengthExtraBytes < shared.networkDefaultPayloadLengthExtraBytes:
payloadLengthExtraBytes = shared.networkDefaultPayloadLengthExtraBytes
if command == 'createRandomAddress':
shared.UISignalQueue.put((
'updateStatusBar', tr.translateText("MainWindow", "Generating one new address")))
# This next section is a little bit strange. We're going to generate keys over and over until we
# find one that starts with either \x00 or \x00\x00. Then when we pack them into a Bitmessage address,
# we won't store the \x00 or \x00\x00 bytes thus making the
# address shorter.
startTime = time.time()
numberOfAddressesWeHadToMakeBeforeWeFoundOneWithTheCorrectRipePrefix = 0
potentialPrivSigningKey = OpenSSL.rand(32)
potentialPubSigningKey = pointMult(potentialPrivSigningKey)
while True:
numberOfAddressesWeHadToMakeBeforeWeFoundOneWithTheCorrectRipePrefix += 1
potentialPrivEncryptionKey = OpenSSL.rand(32)
potentialPubEncryptionKey = pointMult(
potentialPrivEncryptionKey)
# print 'potentialPubSigningKey', potentialPubSigningKey.encode('hex')
# print 'potentialPubEncryptionKey',
# potentialPubEncryptionKey.encode('hex')
ripe = hashlib.new('ripemd160')
sha = hashlib.new('sha512')
sha.update(
potentialPubSigningKey + potentialPubEncryptionKey)
ripe.update(sha.digest())
# print 'potential ripe.digest',
# ripe.digest().encode('hex')
if ripe.digest()[:numberOfNullBytesDemandedOnFrontOfRipeHash] == '\x00' * numberOfNullBytesDemandedOnFrontOfRipeHash:
break
print 'Generated address with ripe digest:', ripe.digest().encode('hex')
print 'Address generator calculated', numberOfAddressesWeHadToMakeBeforeWeFoundOneWithTheCorrectRipePrefix, 'addresses at', numberOfAddressesWeHadToMakeBeforeWeFoundOneWithTheCorrectRipePrefix / (time.time() - startTime), 'addresses per second before finding one with the correct ripe-prefix.'
address = encodeAddress(addressVersionNumber, streamNumber, ripe.digest())
# An excellent way for us to store our keys is in Wallet Import Format. Let us convert now.
# https://en.bitcoin.it/wiki/Wallet_import_format
privSigningKey = '\x80' + potentialPrivSigningKey
checksum = hashlib.sha256(hashlib.sha256(
privSigningKey).digest()).digest()[0:4]
privSigningKeyWIF = arithmetic.changebase(
privSigningKey + checksum, 256, 58)
# print 'privSigningKeyWIF',privSigningKeyWIF
privEncryptionKey = '\x80' + potentialPrivEncryptionKey
checksum = hashlib.sha256(hashlib.sha256(
privEncryptionKey).digest()).digest()[0:4]
privEncryptionKeyWIF = arithmetic.changebase(
privEncryptionKey + checksum, 256, 58)
# print 'privEncryptionKeyWIF',privEncryptionKeyWIF
shared.config.add_section(address)
shared.config.set(address, 'label', label)
shared.config.set(address, 'enabled', 'true')
shared.config.set(address, 'decoy', 'false')
shared.config.set(address, 'noncetrialsperbyte', str(
nonceTrialsPerByte))
shared.config.set(address, 'payloadlengthextrabytes', str(
payloadLengthExtraBytes))
shared.config.set(
address, 'privSigningKey', privSigningKeyWIF)
shared.config.set(
address, 'privEncryptionKey', privEncryptionKeyWIF)
with open(shared.appdata + 'keys.dat', 'wb') as configfile:
shared.config.write(configfile)
# The API and the join and create Chan functionality
# both need information back from the address generator.
shared.apiAddressGeneratorReturnQueue.put(address)
shared.UISignalQueue.put((
'updateStatusBar', tr.translateText("MainWindow", "Done generating address. Doing work necessary to broadcast it...")))
shared.UISignalQueue.put(('writeNewAddressToTable', (
label, address, streamNumber)))
shared.reloadMyAddressHashes()
if addressVersionNumber == 3:
shared.workerQueue.put((
'sendOutOrStoreMyV3Pubkey', ripe.digest()))
elif addressVersionNumber == 4:
shared.workerQueue.put((
'sendOutOrStoreMyV4Pubkey', address))
elif command == 'createDeterministicAddresses' or command == 'getDeterministicAddress' or command == 'createChan' or command == 'joinChan':
if len(deterministicPassphrase) == 0:
sys.stderr.write(
'WARNING: You are creating deterministic address(es) using a blank passphrase. Bitmessage will do it but it is rather stupid.')
if command == 'createDeterministicAddresses':
statusbar = 'Generating ' + str(
numberOfAddressesToMake) + ' new addresses.'
shared.UISignalQueue.put((
'updateStatusBar', statusbar))
signingKeyNonce = 0
encryptionKeyNonce = 1
listOfNewAddressesToSendOutThroughTheAPI = [
] # We fill out this list no matter what although we only need it if we end up passing the info to the API.
for i in range(numberOfAddressesToMake):
# This next section is a little bit strange. We're going to generate keys over and over until we
# find one that has a RIPEMD hash that starts with either \x00 or \x00\x00. Then when we pack them
# into a Bitmessage address, we won't store the \x00 or
# \x00\x00 bytes thus making the address shorter.
startTime = time.time()
numberOfAddressesWeHadToMakeBeforeWeFoundOneWithTheCorrectRipePrefix = 0
while True:
numberOfAddressesWeHadToMakeBeforeWeFoundOneWithTheCorrectRipePrefix += 1
potentialPrivSigningKey = hashlib.sha512(
deterministicPassphrase + encodeVarint(signingKeyNonce)).digest()[:32]
potentialPrivEncryptionKey = hashlib.sha512(
deterministicPassphrase + encodeVarint(encryptionKeyNonce)).digest()[:32]
potentialPubSigningKey = pointMult(
potentialPrivSigningKey)
potentialPubEncryptionKey = pointMult(
potentialPrivEncryptionKey)
# print 'potentialPubSigningKey', potentialPubSigningKey.encode('hex')
# print 'potentialPubEncryptionKey',
# potentialPubEncryptionKey.encode('hex')
signingKeyNonce += 2
encryptionKeyNonce += 2
ripe = hashlib.new('ripemd160')
sha = hashlib.new('sha512')
sha.update(
potentialPubSigningKey + potentialPubEncryptionKey)
ripe.update(sha.digest())
# print 'potential ripe.digest',
# ripe.digest().encode('hex')
if ripe.digest()[:numberOfNullBytesDemandedOnFrontOfRipeHash] == '\x00' * numberOfNullBytesDemandedOnFrontOfRipeHash:
break
print 'ripe.digest', ripe.digest().encode('hex')
print 'Address generator calculated', numberOfAddressesWeHadToMakeBeforeWeFoundOneWithTheCorrectRipePrefix, 'addresses at', numberOfAddressesWeHadToMakeBeforeWeFoundOneWithTheCorrectRipePrefix / (time.time() - startTime), 'keys per second.'
address = encodeAddress(addressVersionNumber, streamNumber, ripe.digest())
saveAddressToDisk = True
# If we are joining an existing chan, let us check to make sure it matches the provided Bitmessage address
if command == 'joinChan':
if address != chanAddress:
shared.apiAddressGeneratorReturnQueue.put('chan name does not match address')
saveAddressToDisk = False
if command == 'getDeterministicAddress':
saveAddressToDisk = False
if saveAddressToDisk:
# An excellent way for us to store our keys is in Wallet Import Format. Let us convert now.
# https://en.bitcoin.it/wiki/Wallet_import_format
privSigningKey = '\x80' + potentialPrivSigningKey
checksum = hashlib.sha256(hashlib.sha256(
privSigningKey).digest()).digest()[0:4]
privSigningKeyWIF = arithmetic.changebase(
privSigningKey + checksum, 256, 58)
privEncryptionKey = '\x80' + \
potentialPrivEncryptionKey
checksum = hashlib.sha256(hashlib.sha256(
privEncryptionKey).digest()).digest()[0:4]
privEncryptionKeyWIF = arithmetic.changebase(
privEncryptionKey + checksum, 256, 58)
addressAlreadyExists = False
try:
shared.config.add_section(address)
except:
print address, 'already exists. Not adding it again.'
addressAlreadyExists = True
if not addressAlreadyExists:
print 'label:', label
shared.config.set(address, 'label', label)
shared.config.set(address, 'enabled', 'true')
shared.config.set(address, 'decoy', 'false')
if command == 'joinChan' or command == 'createChan':
shared.config.set(address, 'chan', 'true')
shared.config.set(address, 'noncetrialsperbyte', str(
nonceTrialsPerByte))
shared.config.set(address, 'payloadlengthextrabytes', str(
payloadLengthExtraBytes))
shared.config.set(
address, 'privSigningKey', privSigningKeyWIF)
shared.config.set(
address, 'privEncryptionKey', privEncryptionKeyWIF)
with open(shared.appdata + 'keys.dat', 'wb') as configfile:
shared.config.write(configfile)
shared.UISignalQueue.put(('writeNewAddressToTable', (
label, address, str(streamNumber))))
listOfNewAddressesToSendOutThroughTheAPI.append(
address)
shared.myECCryptorObjects[ripe.digest()] = highlevelcrypto.makeCryptor(
potentialPrivEncryptionKey.encode('hex'))
shared.myAddressesByHash[ripe.digest()] = address
tag = hashlib.sha512(hashlib.sha512(encodeVarint(
addressVersionNumber) + encodeVarint(streamNumber) + ripe.digest()).digest()).digest()[32:]
shared.myAddressesByTag[tag] = address
if addressVersionNumber == 3:
shared.workerQueue.put((
'sendOutOrStoreMyV3Pubkey', ripe.digest())) # If this is a chan address,
# the worker thread won't send out the pubkey over the network.
elif addressVersionNumber == 4:
shared.workerQueue.put((
'sendOutOrStoreMyV4Pubkey', address))
# Done generating addresses.
if command == 'createDeterministicAddresses' or command == 'joinChan' or command == 'createChan':
shared.apiAddressGeneratorReturnQueue.put(
listOfNewAddressesToSendOutThroughTheAPI)
shared.UISignalQueue.put((
'updateStatusBar', tr.translateText("MainWindow", "Done generating address")))
# shared.reloadMyAddressHashes()
elif command == 'getDeterministicAddress':
shared.apiAddressGeneratorReturnQueue.put(address)
#todo: return things to the API if createChan or joinChan assuming saveAddressToDisk
else:
raise Exception(
"Error in the addressGenerator thread. Thread was given a command it could not understand: " + command)
# Does an EC point multiplication; turns a private key into a public key.
def pointMult(secret):
# ctx = OpenSSL.BN_CTX_new() #This value proved to cause Seg Faults on
# Linux. It turns out that it really didn't speed up EC_POINT_mul anyway.
k = OpenSSL.EC_KEY_new_by_curve_name(OpenSSL.get_curve('secp256k1'))
priv_key = OpenSSL.BN_bin2bn(secret, 32, 0)
group = OpenSSL.EC_KEY_get0_group(k)
pub_key = OpenSSL.EC_POINT_new(group)
OpenSSL.EC_POINT_mul(group, pub_key, priv_key, None, None, None)
OpenSSL.EC_KEY_set_private_key(k, priv_key)
OpenSSL.EC_KEY_set_public_key(k, pub_key)
# print 'priv_key',priv_key
# print 'pub_key',pub_key
size = OpenSSL.i2o_ECPublicKey(k, 0)
mb = ctypes.create_string_buffer(size)
OpenSSL.i2o_ECPublicKey(k, ctypes.byref(ctypes.pointer(mb)))
# print 'mb.raw', mb.raw.encode('hex'), 'length:', len(mb.raw)
# print 'mb.raw', mb.raw, 'length:', len(mb.raw)
OpenSSL.EC_POINT_free(pub_key)
# OpenSSL.BN_CTX_free(ctx)
OpenSSL.BN_free(priv_key)
OpenSSL.EC_KEY_free(k)
return mb.raw