lbry-sdk/torba/baseaccount.py
2018-06-13 23:00:53 -05:00

177 lines
6.7 KiB
Python

from typing import Dict
from twisted.internet import defer
import torba.baseledger
from torba.mnemonic import Mnemonic
from torba.bip32 import PrivateKey, PubKey, from_extended_key_string
from torba.hash import double_sha256, aes_encrypt, aes_decrypt
class KeyChain:
def __init__(self, account, parent_key, chain_number, gap, maximum_use_per_address):
# type: ('BaseAccount', PubKey, int, int, int) -> None
self.account = account
self.db = account.ledger.db
self.main_key = parent_key.child(chain_number)
self.chain_number = chain_number
self.gap = gap
self.maximum_use_per_address = maximum_use_per_address
def get_addresses(self, limit=None, details=False):
return self.db.get_addresses(self.account, self.chain_number, limit, details)
def get_usable_addresses(self, limit=None):
return self.db.get_usable_addresses(
self.account, self.chain_number, self.maximum_use_per_address, limit
)
@defer.inlineCallbacks
def generate_keys(self, start, end):
new_keys = []
for index in range(start, end+1):
new_keys.append((index, self.main_key.child(index)))
yield self.db.add_keys(
self.account, self.chain_number, new_keys
)
defer.returnValue([key[1].address for key in new_keys])
@defer.inlineCallbacks
def ensure_address_gap(self):
addresses = yield self.get_addresses(self.gap, True)
existing_gap = 0
for address in addresses:
if address['used_times'] == 0:
existing_gap += 1
else:
break
if existing_gap == self.gap:
defer.returnValue([])
start = addresses[0]['position']+1 if addresses else 0
end = start + (self.gap - existing_gap)
new_keys = yield self.generate_keys(start, end-1)
defer.returnValue(new_keys)
@defer.inlineCallbacks
def get_or_create_usable_address(self):
addresses = yield self.get_usable_addresses(1)
if addresses:
defer.returnValue(addresses[0])
addresses = yield self.ensure_address_gap()
defer.returnValue(addresses[0])
class BaseAccount:
mnemonic_class = Mnemonic
private_key_class = PrivateKey
public_key_class = PubKey
def __init__(self, ledger, seed, encrypted, private_key,
public_key, receiving_gap=20, change_gap=6,
receiving_maximum_use_per_address=2, change_maximum_use_per_address=2):
# type: (torba.baseledger.BaseLedger, str, bool, PrivateKey, PubKey, int, int, int, int) -> None
self.ledger = ledger
self.seed = seed
self.encrypted = encrypted
self.private_key = private_key
self.public_key = public_key
self.receiving, self.change = self.keychains = (
KeyChain(self, public_key, 0, receiving_gap, receiving_maximum_use_per_address),
KeyChain(self, public_key, 1, change_gap, change_maximum_use_per_address)
)
ledger.add_account(self)
@classmethod
def generate(cls, ledger, password): # type: (torba.baseledger.BaseLedger, str) -> BaseAccount
seed = cls.mnemonic_class().make_seed()
return cls.from_seed(ledger, seed, password)
@classmethod
def from_seed(cls, ledger, seed, password):
# type: (torba.baseledger.BaseLedger, str, str) -> BaseAccount
private_key = cls.get_private_key_from_seed(ledger, seed, password)
return cls(
ledger=ledger, seed=seed, encrypted=False,
private_key=private_key,
public_key=private_key.public_key
)
@classmethod
def get_private_key_from_seed(cls, ledger, seed, password):
# type: (torba.baseledger.BaseLedger, str, str) -> PrivateKey
return cls.private_key_class.from_seed(
ledger, cls.mnemonic_class.mnemonic_to_seed(seed, password)
)
@classmethod
def from_dict(cls, ledger, d): # type: (torba.baseledger.BaseLedger, Dict) -> BaseAccount
if not d['encrypted']:
private_key = from_extended_key_string(ledger, d['private_key'])
public_key = private_key.public_key
else:
private_key = d['private_key']
public_key = from_extended_key_string(ledger, d['public_key'])
return cls(
ledger=ledger,
seed=d['seed'],
encrypted=d['encrypted'],
private_key=private_key,
public_key=public_key,
receiving_gap=d['receiving_gap'],
change_gap=d['change_gap'],
receiving_maximum_use_per_address=d['receiving_maximum_use_per_address'],
change_maximum_use_per_address=d['change_maximum_use_per_address']
)
def to_dict(self):
return {
'ledger': self.ledger.get_id(),
'seed': self.seed,
'encrypted': self.encrypted,
'private_key': self.private_key if self.encrypted else
self.private_key.extended_key_string(),
'public_key': self.public_key.extended_key_string(),
'receiving_gap': self.receiving.gap,
'change_gap': self.change.gap,
'receiving_maximum_use_per_address': self.receiving.maximum_use_per_address,
'change_maximum_use_per_address': self.change.maximum_use_per_address
}
def decrypt(self, password):
assert self.encrypted, "Key is not encrypted."
secret = double_sha256(password)
self.seed = aes_decrypt(secret, self.seed)
self.private_key = from_extended_key_string(self.ledger, aes_decrypt(secret, self.private_key))
self.encrypted = False
def encrypt(self, password):
assert not self.encrypted, "Key is already encrypted."
secret = double_sha256(password)
self.seed = aes_encrypt(secret, self.seed)
self.private_key = aes_encrypt(secret, self.private_key.extended_key_string())
self.encrypted = True
@defer.inlineCallbacks
def ensure_address_gap(self):
addresses = []
for keychain in self.keychains:
new_addresses = yield keychain.ensure_address_gap()
addresses.extend(new_addresses)
defer.returnValue(addresses)
def get_addresses(self, limit=None, details=False):
return self.ledger.db.get_addresses(self, None, limit, details)
def get_unused_addresses(self):
return self.ledger.db.get_unused_addresses(self, None)
def get_private_key(self, chain, index):
assert not self.encrypted, "Cannot get private key on encrypted wallet account."
return self.private_key.child(chain).child(index)
def get_balance(self):
return self.ledger.db.get_balance_for_account(self)