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#!/usr/bin/env python
#
# Electrum - lightweight Bitcoin client
# Copyright (C) 2013 thomasv@gitorious
#
# This program is free software: you can redistribute it and/or modify
# it under the terms of the GNU General Public License as published by
# the Free Software Foundation, either version 3 of the License, or
# (at your option) any later version.
#
# This program is distributed in the hope that it will be useful,
# but WITHOUT ANY WARRANTY; without even the implied warranty of
# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
# GNU General Public License for more details.
#
# You should have received a copy of the GNU General Public License
# along with this program. If not, see <http://www.gnu.org/licenses/>.
from bitcoin import *
from transaction import Transaction
class Account(object):
def __init__(self, v):
self.addresses = v.get('0', [])
self.change = v.get('1', [])
def dump(self):
return {'0':self.addresses, '1':self.change}
def get_addresses(self, for_change):
return self.change[:] if for_change else self.addresses[:]
def create_new_address(self, for_change):
addresses = self.change if for_change else self.addresses
n = len(addresses)
address = self.get_address( for_change, n)
addresses.append(address)
print address
return address
def get_address(self, for_change, n):
pass
class OldAccount(Account):
""" Privatekey(type,n) = Master_private_key + H(n|S|type) """
def __init__(self, v):
self.addresses = v.get(0, [])
self.change = v.get(1, [])
self.mpk = v['mpk'].decode('hex')
def dump(self):
return {0:self.addresses, 1:self.change}
@classmethod
def mpk_from_seed(klass, seed):
curve = SECP256k1
secexp = klass.stretch_key(seed)
master_private_key = ecdsa.SigningKey.from_secret_exponent( secexp, curve = SECP256k1 )
master_public_key = master_private_key.get_verifying_key().to_string().encode('hex')
return master_public_key
@classmethod
def stretch_key(self,seed):
oldseed = seed
for i in range(100000):
seed = hashlib.sha256(seed + oldseed).digest()
return string_to_number( seed )
def get_sequence(self, for_change, n):
return string_to_number( Hash( "%d:%d:"%(n,for_change) + self.mpk ) )
def get_address(self, for_change, n):
pubkey = self.get_pubkey(for_change, n)
address = public_key_to_bc_address( pubkey.decode('hex') )
return address
def get_pubkey(self, for_change, n):
curve = SECP256k1
mpk = self.mpk
z = self.get_sequence(for_change, n)
master_public_key = ecdsa.VerifyingKey.from_string( mpk, curve = SECP256k1 )
pubkey_point = master_public_key.pubkey.point + z*curve.generator
public_key2 = ecdsa.VerifyingKey.from_public_point( pubkey_point, curve = SECP256k1 )
return '04' + public_key2.to_string().encode('hex')
def get_private_key_from_stretched_exponent(self, for_change, n, secexp):
order = generator_secp256k1.order()
secexp = ( secexp + self.get_sequence(for_change, n) ) % order
pk = number_to_string( secexp, generator_secp256k1.order() )
compressed = False
return SecretToASecret( pk, compressed )
def get_private_key(self, seed, sequence):
for_change, n = sequence
secexp = self.stretch_key(seed)
return self.get_private_key_from_stretched_exponent(for_change, n, secexp)
def check_seed(self, seed):
curve = SECP256k1
secexp = self.stretch_key(seed)
master_private_key = ecdsa.SigningKey.from_secret_exponent( secexp, curve = SECP256k1 )
master_public_key = master_private_key.get_verifying_key().to_string().encode('hex')
if master_public_key != self.mpk:
print_error('invalid password (mpk)')
raise BaseException('Invalid password')
return True
def redeem_script(self, sequence):
return None
class BIP32_Account(Account):
def __init__(self, v):
Account.__init__(self, v)
self.c = v['c'].decode('hex')
self.K = v['K'].decode('hex')
self.cK = v['cK'].decode('hex')
def dump(self):
d = Account.dump(self)
d['c'] = self.c.encode('hex')
d['K'] = self.K.encode('hex')
d['cK'] = self.cK.encode('hex')
return d
def get_address(self, for_change, n):
pubkey = self.get_pubkey(for_change, n)
address = public_key_to_bc_address( pubkey.decode('hex') )
return address
def first_address(self):
return self.get_address(0,0)
def get_pubkey(self, for_change, n):
K = self.K
chain = self.c
for i in [for_change, n]:
K, K_compressed, chain = CKD_prime(K, chain, i)
return K_compressed.encode('hex')
def redeem_script(self, sequence):
return None
class BIP32_Account_2of2(BIP32_Account):
def __init__(self, v):
BIP32_Account.__init__(self, v)
self.c2 = v['c2'].decode('hex')
self.K2 = v['K2'].decode('hex')
self.cK2 = v['cK2'].decode('hex')
def dump(self):
d = BIP32_Account.dump(self)
d['c2'] = self.c2.encode('hex')
d['K2'] = self.K2.encode('hex')
d['cK2'] = self.cK2.encode('hex')
return d
def get_pubkey2(self, for_change, n):
K = self.K2
chain = self.c2
for i in [for_change, n]:
K, K_compressed, chain = CKD_prime(K, chain, i)
return K_compressed.encode('hex')
def redeem_script(self, sequence):
chain, i = sequence
pubkey1 = self.get_pubkey(chain, i)
pubkey2 = self.get_pubkey2(chain, i)
return Transaction.multisig_script([pubkey1, pubkey2], 2)
def get_address(self, for_change, n):
address = hash_160_to_bc_address(hash_160(self.redeem_script((for_change, n)).decode('hex')), 5)
return address
class BIP32_Account_2of3(BIP32_Account_2of2):
def __init__(self, v):
BIP32_Account_2of2.__init__(self, v)
self.c3 = v['c3'].decode('hex')
self.K3 = v['K3'].decode('hex')
self.cK3 = v['cK3'].decode('hex')
def dump(self):
d = BIP32_Account_2of2.dump(self)
d['c3'] = self.c3.encode('hex')
d['K3'] = self.K3.encode('hex')
d['cK3'] = self.cK3.encode('hex')
return d
def get_pubkey3(self, for_change, n):
K = self.K3
chain = self.c3
for i in [for_change, n]:
K, K_compressed, chain = CKD_prime(K, chain, i)
return K_compressed.encode('hex')
def get_redeem_script(self, sequence):
chain, i = sequence
pubkey1 = self.get_pubkey(chain, i)
pubkey2 = self.get_pubkey2(chain, i)
pubkey3 = self.get_pubkey3(chain, i)
return Transaction.multisig_script([pubkey1, pubkey2, pubkey3], 3)