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electrum/lib/wallet.py

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#!/usr/bin/env python
#
# Electrum - lightweight Bitcoin client
# Copyright (C) 2011 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/>.
import os
import hashlib
import ast
import threading
import random
import time
import json
import copy
from operator import itemgetter
from util import NotEnoughFunds, PrintError, profiler
from bitcoin import *
from account import *
from version import *
from transaction import Transaction
from plugins import run_hook
import bitcoin
from synchronizer import Synchronizer
from mnemonic import Mnemonic
import paymentrequest
# internal ID for imported account
IMPORTED_ACCOUNT = '/x'
class WalletStorage(PrintError):
def __init__(self, path):
self.lock = threading.RLock()
self.data = {}
self.path = path
self.file_exists = False
self.modified = False
self.print_error("wallet path", self.path)
if self.path:
self.read(self.path)
def read(self, path):
"""Read the contents of the wallet file."""
try:
with open(self.path, "r") as f:
data = f.read()
except IOError:
return
try:
self.data = json.loads(data)
except:
try:
d = ast.literal_eval(data) #parse raw data from reading wallet file
except Exception as e:
raise IOError("Cannot read wallet file '%s'" % self.path)
self.data = {}
# In old versions of Electrum labels were latin1 encoded, this fixes breakage.
labels = d.get('labels', {})
for i, label in labels.items():
try:
unicode(label)
except UnicodeDecodeError:
d['labels'][i] = unicode(label.decode('latin1'))
for key, value in d.items():
try:
json.dumps(key)
json.dumps(value)
except:
self.print_error('Failed to convert label to json format', key)
continue
self.data[key] = value
self.file_exists = True
def get(self, key, default=None):
with self.lock:
v = self.data.get(key)
if v is None:
v = default
else:
v = copy.deepcopy(v)
return v
def put(self, key, value, save = True):
try:
json.dumps(key)
json.dumps(value)
except:
self.print_error("json error: cannot save", key)
return
with self.lock:
if value is not None:
if self.data.get(key) != value:
self.modified = True
self.data[key] = copy.deepcopy(value)
elif key in self.data:
self.modified = True
self.data.pop(key)
if save:
self.write()
def write(self):
assert not threading.currentThread().isDaemon()
if not self.modified:
return
s = json.dumps(self.data, indent=4, sort_keys=True)
temp_path = "%s.tmp.%s" % (self.path, os.getpid())
with open(temp_path, "w") as f:
f.write(s)
f.flush()
os.fsync(f.fileno())
# perform atomic write on POSIX systems
try:
os.rename(temp_path, self.path)
except:
os.remove(self.path)
os.rename(temp_path, self.path)
if 'ANDROID_DATA' not in os.environ:
import stat
os.chmod(self.path,stat.S_IREAD | stat.S_IWRITE)
self.print_error("saved")
class Abstract_Wallet(PrintError):
"""
Wallet classes are created to handle various address generation methods.
Completion states (watching-only, single account, no seed, etc) are handled inside classes.
"""
def __init__(self, storage):
self.storage = storage
self.network = None
self.electrum_version = ELECTRUM_VERSION
self.gap_limit_for_change = 6 # constant
# saved fields
self.seed_version = storage.get('seed_version', NEW_SEED_VERSION)
self.use_change = storage.get('use_change',True)
self.use_encryption = storage.get('use_encryption', False)
self.seed = storage.get('seed', '') # encrypted
self.labels = storage.get('labels', {})
self.frozen_addresses = set(storage.get('frozen_addresses',[]))
self.stored_height = storage.get('stored_height', 0) # last known height (for offline mode)
self.history = storage.get('addr_history',{}) # address -> list(txid, height)
# This attribute is set when wallet.start_threads is called.
self.synchronizer = None
# imported_keys is deprecated. The GUI should call convert_imported_keys
self.imported_keys = self.storage.get('imported_keys',{})
self.load_accounts()
self.load_transactions()
self.build_reverse_history()
# load requests
self.receive_requests = self.storage.get('payment_requests', {})
# spv
self.verifier = None
# Transactions pending verification. A map from tx hash to transaction
# height. Access is not contended so no lock is needed.
self.unverified_tx = {}
# Verified transactions. Each value is a (height, timestamp, block_pos) tuple. Access with self.lock.
self.verified_tx = storage.get('verified_tx3',{})
# there is a difference between wallet.up_to_date and interface.is_up_to_date()
# interface.is_up_to_date() returns true when all requests have been answered and processed
# wallet.up_to_date is true when the wallet is synchronized (stronger requirement)
self.up_to_date = False
self.lock = threading.Lock()
self.transaction_lock = threading.Lock()
self.tx_event = threading.Event()
self.check_history()
# save wallet type the first time
if self.storage.get('wallet_type') is None:
self.storage.put('wallet_type', self.wallet_type, True)
def diagnostic_name(self):
return self.basename()
@profiler
def load_transactions(self):
self.txi = self.storage.get('txi', {})
self.txo = self.storage.get('txo', {})
self.pruned_txo = self.storage.get('pruned_txo', {})
tx_list = self.storage.get('transactions', {})
self.transactions = {}
for tx_hash, raw in tx_list.items():
tx = Transaction(raw)
self.transactions[tx_hash] = tx
if self.txi.get(tx_hash) is None and self.txo.get(tx_hash) is None and (tx_hash not in self.pruned_txo.values()):
self.print_error("removing unreferenced tx", tx_hash)
self.transactions.pop(tx_hash)
@profiler
def save_transactions(self):
with self.transaction_lock:
tx = {}
for k,v in self.transactions.items():
tx[k] = str(v)
# Flush storage only with the last put
self.storage.put('transactions', tx, False)
self.storage.put('txi', self.txi, False)
self.storage.put('txo', self.txo, False)
self.storage.put('pruned_txo', self.pruned_txo, True)
def clear_history(self):
with self.transaction_lock:
self.txi = {}
self.txo = {}
self.pruned_txo = {}
self.save_transactions()
with self.lock:
self.history = {}
self.tx_addr_hist = {}
self.storage.put('addr_history', self.history, True)
@profiler
def build_reverse_history(self):
self.tx_addr_hist = {}
for addr, hist in self.history.items():
for tx_hash, h in hist:
s = self.tx_addr_hist.get(tx_hash, set())
s.add(addr)
self.tx_addr_hist[tx_hash] = s
@profiler
def check_history(self):
save = False
for addr, hist in self.history.items():
if not self.is_mine(addr):
self.history.pop(addr)
save = True
continue
for tx_hash, tx_height in hist:
if tx_hash in self.pruned_txo.values() or self.txi.get(tx_hash) or self.txo.get(tx_hash):
continue
tx = self.transactions.get(tx_hash)
if tx is not None:
tx.deserialize()
self.add_transaction(tx_hash, tx)
if save:
self.storage.put('addr_history', self.history, True)
# wizard action
def get_action(self):
pass
def basename(self):
return os.path.basename(self.storage.path)
def convert_imported_keys(self, password):
for k, v in self.imported_keys.items():
sec = pw_decode(v, password)
pubkey = public_key_from_private_key(sec)
address = public_key_to_bc_address(pubkey.decode('hex'))
if address != k:
raise InvalidPassword()
self.import_key(sec, password)
self.imported_keys.pop(k)
self.storage.put('imported_keys', self.imported_keys)
def load_accounts(self):
self.accounts = {}
d = self.storage.get('accounts', {})
for k, v in d.items():
if self.wallet_type == 'old' and k in [0, '0']:
v['mpk'] = self.storage.get('master_public_key')
self.accounts['0'] = OldAccount(v)
elif v.get('imported'):
self.accounts[k] = ImportedAccount(v)
elif v.get('xpub'):
self.accounts[k] = BIP32_Account(v)
elif v.get('pending'):
try:
self.accounts[k] = PendingAccount(v)
except:
pass
else:
self.print_error("cannot load account", v)
def synchronize(self):
pass
def can_create_accounts(self):
return False
def set_up_to_date(self,b):
with self.lock: self.up_to_date = b
def is_up_to_date(self):
with self.lock: return self.up_to_date
def update(self):
self.up_to_date = False
while not self.is_up_to_date():
time.sleep(0.1)
def is_imported(self, addr):
account = self.accounts.get(IMPORTED_ACCOUNT)
if account:
return addr in account.get_addresses(0)
else:
return False
def has_imported_keys(self):
account = self.accounts.get(IMPORTED_ACCOUNT)
return account is not None
def import_key(self, sec, password):
assert self.can_import(), 'This wallet cannot import private keys'
try:
pubkey = public_key_from_private_key(sec)
address = public_key_to_bc_address(pubkey.decode('hex'))
except Exception:
raise Exception('Invalid private key')
if self.is_mine(address):
raise Exception('Address already in wallet')
if self.accounts.get(IMPORTED_ACCOUNT) is None:
self.accounts[IMPORTED_ACCOUNT] = ImportedAccount({'imported':{}})
self.accounts[IMPORTED_ACCOUNT].add(address, pubkey, sec, password)
self.save_accounts()
# force resynchronization, because we need to re-run add_transaction
if address in self.history:
self.history.pop(address)
if self.synchronizer:
self.synchronizer.add(address)
return address
def delete_imported_key(self, addr):
account = self.accounts[IMPORTED_ACCOUNT]
account.remove(addr)
if not account.get_addresses(0):
self.accounts.pop(IMPORTED_ACCOUNT)
self.save_accounts()
def set_label(self, name, text = None):
changed = False
old_text = self.labels.get(name)
if text:
if old_text != text:
self.labels[name] = text
changed = True
else:
if old_text:
self.labels.pop(name)
changed = True
if changed:
run_hook('set_label', self, name, text)
self.storage.put('labels', self.labels, True)
return changed
def addresses(self, include_change = True):
return list(addr for acc in self.accounts for addr in self.get_account_addresses(acc, include_change))
def is_mine(self, address):
return address in self.addresses(True)
def is_change(self, address):
if not self.is_mine(address): return False
acct, s = self.get_address_index(address)
if s is None: return False
return s[0] == 1
def get_address_index(self, address):
for acc_id in self.accounts:
for for_change in [0,1]:
addresses = self.accounts[acc_id].get_addresses(for_change)
if address in addresses:
return acc_id, (for_change, addresses.index(address))
raise Exception("Address not found", address)
def get_private_key(self, address, password):
if self.is_watching_only():
return []
account_id, sequence = self.get_address_index(address)
return self.accounts[account_id].get_private_key(sequence, self, password)
def get_public_keys(self, address):
account_id, sequence = self.get_address_index(address)
return self.accounts[account_id].get_pubkeys(*sequence)
def sign_message(self, address, message, password):
keys = self.get_private_key(address, password)
assert len(keys) == 1
sec = keys[0]
key = regenerate_key(sec)
compressed = is_compressed(sec)
return key.sign_message(message, compressed, address)
def decrypt_message(self, pubkey, message, password):
address = public_key_to_bc_address(pubkey.decode('hex'))
keys = self.get_private_key(address, password)
secret = keys[0]
ec = regenerate_key(secret)
decrypted = ec.decrypt_message(message)
return decrypted
def add_unverified_tx(self, tx_hash, tx_height):
# Only add if confirmed and not verified
if tx_height > 0 and tx_hash not in self.verified_tx:
self.unverified_tx[tx_hash] = tx_height
def add_verified_tx(self, tx_hash, info):
# Remove from the unverified map and add to the verified map and
self.unverified_tx.pop(tx_hash, None)
with self.lock:
self.verified_tx[tx_hash] = info # (tx_height, timestamp, pos)
self.storage.put('verified_tx3', self.verified_tx, True)
conf, timestamp = self.get_confirmations(tx_hash)
self.network.trigger_callback('verified', (tx_hash, conf, timestamp))
def get_unverified_txs(self):
'''Returns a map from tx hash to transaction height'''
return self.unverified_tx
def undo_verifications(self, height):
'''Used by the verifier when a reorg has happened'''
txs = []
with self.lock:
for tx_hash, item in self.verified_tx:
tx_height, timestamp, pos = item
if tx_height >= height:
self.verified_tx.pop(tx_hash, None)
txs.append(tx_hash)
return txs
def get_local_height(self):
""" return last known height if we are offline """
return self.network.get_local_height() if self.network else self.stored_height
def get_confirmations(self, tx):
""" return the number of confirmations of a monitored transaction. """
with self.lock:
if tx in self.verified_tx:
height, timestamp, pos = self.verified_tx[tx]
conf = (self.get_local_height() - height + 1)
if conf <= 0: timestamp = None
elif tx in self.unverified_tx:
conf = -1
timestamp = None
else:
conf = 0
timestamp = None
return conf, timestamp
def get_txpos(self, tx_hash):
"return position, even if the tx is unverified"
with self.lock:
x = self.verified_tx.get(tx_hash)
y = self.unverified_tx.get(tx_hash)
if x:
height, timestamp, pos = x
return height, pos
elif y:
return y, 0
else:
return 1e12, 0
def is_found(self):
return self.history.values() != [[]] * len(self.history)
def get_num_tx(self, address):
""" return number of transactions where address is involved """
return len(self.history.get(address, []))
def get_tx_delta(self, tx_hash, address):
"effect of tx on address"
# pruned
if tx_hash in self.pruned_txo.values():
return None
delta = 0
# substract the value of coins sent from address
d = self.txi.get(tx_hash, {}).get(address, [])
for n, v in d:
delta -= v
# add the value of the coins received at address
d = self.txo.get(tx_hash, {}).get(address, [])
for n, v, cb in d:
delta += v
return delta
def get_wallet_delta(self, tx):
""" effect of tx on wallet """
addresses = self.addresses(True)
is_relevant = False
is_send = False
is_pruned = False
is_partial = False
v_in = v_out = v_out_mine = 0
for item in tx.inputs:
addr = item.get('address')
if addr in addresses:
is_send = True
is_relevant = True
d = self.txo.get(item['prevout_hash'], {}).get(addr, [])
for n, v, cb in d:
if n == item['prevout_n']:
value = v
break
else:
value = None
if value is None:
is_pruned = True
else:
v_in += value
else:
is_partial = True
if not is_send:
is_partial = False
for addr, value in tx.get_outputs():
v_out += value
if addr in addresses:
v_out_mine += value
is_relevant = True
if is_pruned:
# some inputs are mine:
fee = None
if is_send:
v = v_out_mine - v_out
else:
# no input is mine
v = v_out_mine
else:
v = v_out_mine - v_in
if is_partial:
# some inputs are mine, but not all
fee = None
is_send = v < 0
else:
# all inputs are mine
fee = v_out - v_in
return is_relevant, is_send, v, fee
def get_addr_io(self, address):
h = self.history.get(address, [])
received = {}
sent = {}
for tx_hash, height in h:
l = self.txo.get(tx_hash, {}).get(address, [])
for n, v, is_cb in l:
received[tx_hash + ':%d'%n] = (height, v, is_cb)
for tx_hash, height in h:
l = self.txi.get(tx_hash, {}).get(address, [])
for txi, v in l:
sent[txi] = height
return received, sent
def get_addr_utxo(self, address):
coins, spent = self.get_addr_io(address)
for txi in spent:
coins.pop(txi)
return coins
# return the total amount ever received by an address
def get_addr_received(self, address):
received, sent = self.get_addr_io(address)
return sum([v for height, v, is_cb in received.values()])
# return the balance of a bitcoin address: confirmed and matured, unconfirmed, unmatured
def get_addr_balance(self, address):
received, sent = self.get_addr_io(address)
c = u = x = 0
for txo, (tx_height, v, is_cb) in received.items():
if is_cb and tx_height + COINBASE_MATURITY > self.get_local_height():
x += v
elif tx_height > 0:
c += v
else:
u += v
if txo in sent:
if sent[txo] > 0:
c -= v
else:
u -= v
return c, u, x
def get_spendable_coins(self, domain = None, exclude_frozen = True):
coins = []
if domain is None:
domain = self.addresses(True)
if exclude_frozen:
domain = set(domain) - self.frozen_addresses
for addr in domain:
c = self.get_addr_utxo(addr)
for txo, v in c.items():
tx_height, value, is_cb = v
if is_cb and tx_height + COINBASE_MATURITY > self.get_local_height():
continue
prevout_hash, prevout_n = txo.split(':')
output = {
'address':addr,
'value':value,
'prevout_n':int(prevout_n),
'prevout_hash':prevout_hash,
'height':tx_height,
'coinbase':is_cb
}
coins.append((tx_height, output))
continue
# sort by age
if coins:
coins = sorted(coins)
if coins[-1][0] != 0:
while coins[0][0] == 0:
coins = coins[1:] + [ coins[0] ]
return [value for height, value in coins]
def get_account_name(self, k):
return self.labels.get(k, self.accounts[k].get_name(k))
def get_account_names(self):
account_names = {}
for k in self.accounts.keys():
account_names[k] = self.get_account_name(k)
return account_names
def get_account_addresses(self, acc_id, include_change=True):
if acc_id is None:
addr_list = self.addresses(include_change)
elif acc_id in self.accounts:
acc = self.accounts[acc_id]
addr_list = acc.get_addresses(0)
if include_change:
addr_list += acc.get_addresses(1)
return addr_list
def get_account_from_address(self, addr):
"Returns the account that contains this address, or None"
for acc_id in self.accounts: # similar to get_address_index but simpler
if addr in self.get_account_addresses(acc_id):
return acc_id
return None
def get_account_balance(self, account):
return self.get_balance(self.get_account_addresses(account))
def get_frozen_balance(self):
return self.get_balance(self.frozen_addresses)
def get_balance(self, domain=None):
if domain is None:
domain = self.addresses(True)
cc = uu = xx = 0
for addr in domain:
c, u, x = self.get_addr_balance(addr)
cc += c
uu += u
xx += x
return cc, uu, xx
def get_address_history(self, address):
with self.lock:
return self.history.get(address, [])
def get_status(self, h):
if not h:
return None
status = ''
for tx_hash, height in h:
status += tx_hash + ':%d:' % height
return hashlib.sha256( status ).digest().encode('hex')
def find_pay_to_pubkey_address(self, prevout_hash, prevout_n):
dd = self.txo.get(prevout_hash, {})
for addr, l in dd.items():
for n, v, is_cb in l:
if n == prevout_n:
self.print_error("found pay-to-pubkey address:", addr)
return addr
def add_transaction(self, tx_hash, tx):
is_coinbase = tx.inputs[0].get('is_coinbase') == True
with self.transaction_lock:
# add inputs
self.txi[tx_hash] = d = {}
for txi in tx.inputs:
addr = txi.get('address')
if not txi.get('is_coinbase'):
prevout_hash = txi['prevout_hash']
prevout_n = txi['prevout_n']
ser = prevout_hash + ':%d'%prevout_n
if addr == "(pubkey)":
addr = self.find_pay_to_pubkey_address(prevout_hash, prevout_n)
# find value from prev output
if addr and self.is_mine(addr):
dd = self.txo.get(prevout_hash, {})
for n, v, is_cb in dd.get(addr, []):
if n == prevout_n:
if d.get(addr) is None:
d[addr] = []
d[addr].append((ser, v))
break
else:
self.pruned_txo[ser] = tx_hash
# add outputs
self.txo[tx_hash] = d = {}
for n, txo in enumerate(tx.outputs):
ser = tx_hash + ':%d'%n
_type, x, v = txo
if _type == 'address':
addr = x
elif _type == 'pubkey':
addr = public_key_to_bc_address(x.decode('hex'))
else:
addr = None
if addr and self.is_mine(addr):
if d.get(addr) is None:
d[addr] = []
d[addr].append((n, v, is_coinbase))
# give v to txi that spends me
next_tx = self.pruned_txo.get(ser)
if next_tx is not None:
self.pruned_txo.pop(ser)
dd = self.txi.get(next_tx, {})
if dd.get(addr) is None:
dd[addr] = []
dd[addr].append((ser, v))
# save
self.transactions[tx_hash] = tx
def remove_transaction(self, tx_hash):
with self.transaction_lock:
self.print_error("removing tx from history", tx_hash)
#tx = self.transactions.pop(tx_hash)
for ser, hh in self.pruned_txo.items():
if hh == tx_hash:
self.pruned_txo.pop(ser)
# add tx to pruned_txo, and undo the txi addition
for next_tx, dd in self.txi.items():
for addr, l in dd.items():
ll = l[:]
for item in ll:
ser, v = item
prev_hash, prev_n = ser.split(':')
if prev_hash == tx_hash:
l.remove(item)
self.pruned_txo[ser] = next_tx
if l == []:
dd.pop(addr)
else:
dd[addr] = l
self.txi.pop(tx_hash)
self.txo.pop(tx_hash)
def receive_tx_callback(self, tx_hash, tx, tx_height):
self.add_transaction(tx_hash, tx)
self.add_unverified_tx(tx_hash, tx_height)
def receive_history_callback(self, addr, hist):
with self.lock:
old_hist = self.history.get(addr, [])
for tx_hash, height in old_hist:
if (tx_hash, height) not in hist:
# remove tx if it's not referenced in histories
self.tx_addr_hist[tx_hash].remove(addr)
if not self.tx_addr_hist[tx_hash]:
self.remove_transaction(tx_hash)
self.history[addr] = hist
self.storage.put('addr_history', self.history, True)
for tx_hash, tx_height in hist:
# add it in case it was previously unconfirmed
self.add_unverified_tx(tx_hash, tx_height)
# add reference in tx_addr_hist
s = self.tx_addr_hist.get(tx_hash, set())
s.add(addr)
self.tx_addr_hist[tx_hash] = s
# if addr is new, we have to recompute txi and txo
tx = self.transactions.get(tx_hash)
if tx is not None and self.txi.get(tx_hash, {}).get(addr) is None and self.txo.get(tx_hash, {}).get(addr) is None:
tx.deserialize()
self.add_transaction(tx_hash, tx)
def get_history(self, domain=None):
from collections import defaultdict
# get domain
if domain is None:
domain = self.get_account_addresses(None)
# 1. Get the history of each address in the domain, maintain the
# delta of a tx as the sum of its deltas on domain addresses
tx_deltas = defaultdict(int)
for addr in domain:
h = self.get_address_history(addr)
for tx_hash, height in h:
delta = self.get_tx_delta(tx_hash, addr)
if delta is None or tx_deltas[tx_hash] is None:
tx_deltas[tx_hash] = None
else:
tx_deltas[tx_hash] += delta
# 2. create sorted history
history = []
for tx_hash, delta in tx_deltas.items():
conf, timestamp = self.get_confirmations(tx_hash)
history.append((tx_hash, conf, delta, timestamp))
history.sort(key = lambda x: self.get_txpos(x[0]))
history.reverse()
# 3. add balance
c, u, x = self.get_balance(domain)
balance = c + u + x
h2 = []
for item in history:
tx_hash, conf, delta, timestamp = item
h2.append((tx_hash, conf, delta, timestamp, balance))
if balance is None or delta is None:
balance = None
else:
balance -= delta
h2.reverse()
# fixme: this may happen if history is incomplete
if balance not in [None, 0]:
self.print_error("Error: history not synchronized")
return []
return h2
def get_label(self, tx_hash):
label = self.labels.get(tx_hash)
is_default = (label == '') or (label is None)
if is_default:
label = self.get_default_label(tx_hash)
return label, is_default
def get_default_label(self, tx_hash):
if self.txi.get(tx_hash) == {}:
d = self.txo.get(tx_hash, {})
labels = []
for addr in d.keys():
label = self.labels.get(addr)
if label:
labels.append(label)
return ', '.join(labels)
return ''
def fee_per_kb(self, config):
b = config.get('dynamic_fees')
f = config.get('fee_factor', 50)
F = config.get('fee_per_kb', bitcoin.RECOMMENDED_FEE)
return min(F, self.network.fee*(50 + f)/100) if b and self.network and self.network.fee else F
def get_tx_fee(self, tx):
# this method can be overloaded
return tx.get_fee()
@profiler
def estimated_fee(self, tx, fee_per_kb):
estimated_size = len(tx.serialize(-1))/2
fee = int(fee_per_kb * estimated_size / 1000.)
if fee < MIN_RELAY_TX_FEE: # and tx.requires_fee(self):
fee = MIN_RELAY_TX_FEE
return fee
def make_unsigned_transaction(self, coins, outputs, config, fixed_fee=None, change_addr=None):
# check outputs
for type, data, value in outputs:
if type == 'address':
assert is_address(data), "Address " + data + " is invalid!"
fee_per_kb = self.fee_per_kb(config)
amount = sum(map(lambda x:x[2], outputs))
total = 0
inputs = []
tx = Transaction.from_io(inputs, outputs)
fee = fixed_fee if fixed_fee is not None else 0
# add inputs, sorted by age
for item in coins:
v = item.get('value')
total += v
self.add_input_info(item)
tx.add_input(item)
# no need to estimate fee until we have reached desired amount
if total < amount + fee:
continue
fee = fixed_fee if fixed_fee is not None else self.estimated_fee(tx, fee_per_kb)
if total >= amount + fee:
break
else:
raise NotEnoughFunds()
# remove unneeded inputs.
removed = False
for item in sorted(tx.inputs, key=itemgetter('value')):
v = item.get('value')
if total - v >= amount + fee:
tx.inputs.remove(item)
total -= v
removed = True
continue
else:
break
if removed:
fee = fixed_fee if fixed_fee is not None else self.estimated_fee(tx, fee_per_kb)
for item in sorted(tx.inputs, key=itemgetter('value')):
v = item.get('value')
if total - v >= amount + fee:
tx.inputs.remove(item)
total -= v
fee = fixed_fee if fixed_fee is not None else self.estimated_fee(tx, fee_per_kb)
continue
break
self.print_error("using %d inputs"%len(tx.inputs))
# change address
if not change_addr:
# send change to one of the accounts involved in the tx
address = inputs[0].get('address')
account, _ = self.get_address_index(address)
if self.use_change and self.accounts[account].has_change():
# New change addresses are created only after a few confirmations.
# Choose an unused change address if any, otherwise take one at random
change_addrs = self.accounts[account].get_addresses(1)[-self.gap_limit_for_change:]
for change_addr in change_addrs:
if self.get_num_tx(change_addr) == 0:
break
else:
change_addr = random.choice(change_addrs)
else:
change_addr = address
# if change is above dust threshold, add a change output.
change_amount = total - ( amount + fee )
if fixed_fee is not None and change_amount > 0:
tx.outputs.append(('address', change_addr, change_amount))
elif change_amount > DUST_THRESHOLD:
tx.outputs.append(('address', change_addr, change_amount))
# recompute fee including change output
fee = self.estimated_fee(tx, fee_per_kb)
# remove change output
tx.outputs.pop()
# if change is still above dust threshold, re-add change output.
change_amount = total - ( amount + fee )
if change_amount > DUST_THRESHOLD:
tx.outputs.append(('address', change_addr, change_amount))
self.print_error('change', change_amount)
else:
self.print_error('not keeping dust', change_amount)
else:
self.print_error('not keeping dust', change_amount)
# Sort the inputs and outputs deterministically
tx.BIP_LI01_sort()
run_hook('make_unsigned_transaction', self, tx)
return tx
def mktx(self, outputs, password, config, fee=None, change_addr=None, domain=None):
coins = self.get_spendable_coins(domain)
tx = self.make_unsigned_transaction(coins, outputs, config, fee, change_addr)
self.sign_transaction(tx, password)
return tx
def add_input_info(self, txin):
address = txin['address']
account_id, sequence = self.get_address_index(address)
account = self.accounts[account_id]
redeemScript = account.redeem_script(*sequence)
pubkeys = account.get_pubkeys(*sequence)
x_pubkeys = account.get_xpubkeys(*sequence)
# sort pubkeys and x_pubkeys, using the order of pubkeys
pubkeys, x_pubkeys = zip( *sorted(zip(pubkeys, x_pubkeys)))
txin['pubkeys'] = list(pubkeys)
txin['x_pubkeys'] = list(x_pubkeys)
txin['signatures'] = [None] * len(pubkeys)
if redeemScript:
txin['redeemScript'] = redeemScript
txin['num_sig'] = account.m
else:
txin['redeemPubkey'] = account.get_pubkey(*sequence)
txin['num_sig'] = 1
def sign_transaction(self, tx, password):
if self.is_watching_only():
return
# Raise if password is not correct.
self.check_password(password)
# Add derivation for utxo in wallets
for i, addr in self.utxo_can_sign(tx):
txin = tx.inputs[i]
txin['address'] = addr
self.add_input_info(txin)
# Add private keys
keypairs = {}
for x in self.xkeys_can_sign(tx):
sec = self.get_private_key_from_xpubkey(x, password)
if sec:
keypairs[x] = sec
# Sign
if keypairs:
tx.sign(keypairs)
# Run hook, and raise if error
tx.error = None
run_hook('sign_transaction', self, tx, password)
if tx.error:
raise BaseException(tx.error)
def sendtx(self, tx):
# synchronous
h = self.send_tx(tx)
self.tx_event.wait()
return self.receive_tx(h, tx)
def send_tx(self, tx):
# asynchronous
self.tx_event.clear()
self.network.send([('blockchain.transaction.broadcast', [str(tx)])], self.on_broadcast)
return tx.hash()
def on_broadcast(self, r):
self.tx_result = r.get('result')
self.tx_event.set()
def receive_tx(self, tx_hash, tx):
out = self.tx_result
if out != tx_hash:
return False, "error: " + out
run_hook('receive_tx', tx, self)
return True, out
def update_password(self, old_password, new_password):
if new_password == '':
new_password = None
if self.has_seed():
decoded = self.get_seed(old_password)
self.seed = pw_encode( decoded, new_password)
self.storage.put('seed', self.seed, True)
imported_account = self.accounts.get(IMPORTED_ACCOUNT)
if imported_account:
imported_account.update_password(old_password, new_password)
self.save_accounts()
if hasattr(self, 'master_private_keys'):
for k, v in self.master_private_keys.items():
b = pw_decode(v, old_password)
c = pw_encode(b, new_password)
self.master_private_keys[k] = c
self.storage.put('master_private_keys', self.master_private_keys, True)
self.use_encryption = (new_password != None)
self.storage.put('use_encryption', self.use_encryption,True)
def is_frozen(self, addr):
return addr in self.frozen_addresses
def set_frozen_state(self, addrs, freeze):
'''Set frozen state of the addresses to FREEZE, True or False'''
if all(self.is_mine(addr) for addr in addrs):
if freeze:
self.frozen_addresses |= set(addrs)
else:
self.frozen_addresses -= set(addrs)
self.storage.put('frozen_addresses', list(self.frozen_addresses), True)
return True
return False
def prepare_for_verifier(self):
# review transactions that are in the history
for addr, hist in self.history.items():
for tx_hash, tx_height in hist:
# add it in case it was previously unconfirmed
self.add_unverified_tx (tx_hash, tx_height)
# if we are on a pruning server, remove unverified transactions
with self.lock:
vr = self.verified_tx.keys() + self.unverified_tx.keys()
for tx_hash in self.transactions.keys():
if tx_hash not in vr:
self.print_error("removing transaction", tx_hash)
self.transactions.pop(tx_hash)
def start_threads(self, network):
from verifier import SPV
self.network = network
if self.network is not None:
self.prepare_for_verifier()
self.verifier = SPV(self.network, self)
self.synchronizer = Synchronizer(self, network)
network.add_jobs([self.verifier, self.synchronizer])
else:
self.verifier = None
self.synchronizer = None
def stop_threads(self):
if self.network:
self.network.remove_jobs([self.synchronizer, self.verifier])
self.synchronizer = None
self.verifier = None
self.storage.put('stored_height', self.get_local_height(), True)
def restore(self, cb):
pass
def get_accounts(self):
return self.accounts
def add_account(self, account_id, account):
self.accounts[account_id] = account
self.save_accounts()
def save_accounts(self):
d = {}
for k, v in self.accounts.items():
d[k] = v.dump()
self.storage.put('accounts', d, True)
def can_import(self):
return not self.is_watching_only()
def can_export(self):
return not self.is_watching_only()
def is_used(self, address):
h = self.history.get(address,[])
c, u, x = self.get_addr_balance(address)
return len(h) > 0 and c + u + x == 0
def is_empty(self, address):
c, u, x = self.get_addr_balance(address)
return c+u+x == 0
def address_is_old(self, address, age_limit=2):
age = -1
h = self.history.get(address, [])
for tx_hash, tx_height in h:
if tx_height == 0:
tx_age = 0
else:
tx_age = self.get_local_height() - tx_height + 1
if tx_age > age:
age = tx_age
return age > age_limit
def can_sign(self, tx):
if self.is_watching_only():
return False
if tx.is_complete():
return False
if self.xkeys_can_sign(tx):
return True
if self.utxo_can_sign(tx):
return True
return False
def utxo_can_sign(self, tx):
out = set()
coins = self.get_spendable_coins()
for i in tx.inputs_without_script():
txin = tx.inputs[i]
for item in coins:
if txin.get('prevout_hash') == item.get('prevout_hash') and txin.get('prevout_n') == item.get('prevout_n'):
out.add((i, item.get('address')))
return out
def xkeys_can_sign(self, tx):
out = set()
for x in tx.inputs_to_sign():
if self.can_sign_xpubkey(x):
out.add(x)
return out
def get_private_key_from_xpubkey(self, x_pubkey, password):
if x_pubkey[0:2] in ['02','03','04']:
addr = bitcoin.public_key_to_bc_address(x_pubkey.decode('hex'))
if self.is_mine(addr):
return self.get_private_key(addr, password)[0]
elif x_pubkey[0:2] == 'ff':
xpub, sequence = BIP32_Account.parse_xpubkey(x_pubkey)
for k, v in self.master_public_keys.items():
if v == xpub:
xprv = self.get_master_private_key(k, password)
if xprv:
_, _, _, c, k = deserialize_xkey(xprv)
return bip32_private_key(sequence, k, c)
elif x_pubkey[0:2] == 'fe':
xpub, sequence = OldAccount.parse_xpubkey(x_pubkey)
for k, account in self.accounts.items():
if xpub in account.get_master_pubkeys():
pk = account.get_private_key(sequence, self, password)
return pk[0]
elif x_pubkey[0:2] == 'fd':
addrtype = ord(x_pubkey[2:4].decode('hex'))
addr = hash_160_to_bc_address(x_pubkey[4:].decode('hex'), addrtype)
if self.is_mine(addr):
return self.get_private_key(addr, password)[0]
else:
raise BaseException("z")
def can_sign_xpubkey(self, x_pubkey):
if x_pubkey[0:2] in ['02','03','04']:
addr = bitcoin.public_key_to_bc_address(x_pubkey.decode('hex'))
return self.is_mine(addr)
elif x_pubkey[0:2] == 'ff':
if not isinstance(self, BIP32_Wallet): return False
xpub, sequence = BIP32_Account.parse_xpubkey(x_pubkey)
return xpub in [ self.master_public_keys[k] for k in self.master_private_keys.keys() ]
elif x_pubkey[0:2] == 'fe':
if not isinstance(self, OldWallet): return False
xpub, sequence = OldAccount.parse_xpubkey(x_pubkey)
return xpub == self.get_master_public_key()
elif x_pubkey[0:2] == 'fd':
addrtype = ord(x_pubkey[2:4].decode('hex'))
addr = hash_160_to_bc_address(x_pubkey[4:].decode('hex'), addrtype)
return self.is_mine(addr)
else:
raise BaseException("z")
def is_watching_only(self):
False
def can_change_password(self):
return not self.is_watching_only()
def get_unused_address(self, account):
# fixme: use slots from expired requests
domain = self.get_account_addresses(account, include_change=False)
for addr in domain:
if not self.history.get(addr) and addr not in self.receive_requests.keys():
return addr
def get_payment_request(self, addr, config):
import util
r = self.receive_requests.get(addr)
if not r:
return
out = copy.copy(r)
out['URI'] = 'bitcoin:' + addr + '?amount=' + util.format_satoshis(out.get('amount'))
out['status'] = self.get_request_status(addr)
# check if bip70 file exists
rdir = config.get('requests_dir')
if rdir:
key = out.get('id', addr)
path = os.path.join(rdir, key)
if os.path.exists(path):
baseurl = 'file://' + rdir
rewrite = config.get('url_rewrite')
if rewrite:
baseurl = baseurl.replace(*rewrite)
out['request_url'] = os.path.join(baseurl, key)
out['URI'] += '&r=' + out['request_url']
out['index_url'] = os.path.join(baseurl, 'index.html') + '?id=' + key
return out
def get_request_status(self, key):
from paymentrequest import PR_PAID, PR_UNPAID, PR_UNKNOWN, PR_EXPIRED
r = self.receive_requests[key]
address = r['address']
amount = r.get('amount')
timestamp = r.get('time', 0)
if timestamp and type(timestamp) != int:
timestamp = 0
expiration = r.get('exp')
if expiration and type(expiration) != int:
expiration = 0
if amount:
if self.up_to_date:
paid = amount <= self.get_addr_received(address)
status = PR_PAID if paid else PR_UNPAID
if status == PR_UNPAID and expiration is not None and time.time() > timestamp + expiration:
status = PR_EXPIRED
else:
status = PR_UNKNOWN
else:
status = PR_UNKNOWN
return status
def make_payment_request(self, addr, amount, message, expiration):
timestamp = int(time.time())
_id = Hash(addr + "%d"%timestamp).encode('hex')[0:10]
r = {'time':timestamp, 'amount':amount, 'exp':expiration, 'address':addr, 'memo':message, 'id':_id}
return r
def sign_payment_request(self, key, alias, alias_addr, password):
req = self.receive_requests.get(key)
alias_privkey = self.get_private_key(alias_addr, password)[0]
pr = paymentrequest.make_unsigned_request(req)
paymentrequest.sign_request_with_alias(pr, alias, alias_privkey)
req['name'] = pr.pki_data
req['sig'] = pr.signature.encode('hex')
self.receive_requests[key] = req
self.storage.put('payment_requests', self.receive_requests)
def add_payment_request(self, req, config):
import os
addr = req['address']
amount = req.get('amount')
message = req.get('memo')
self.receive_requests[addr] = req
self.storage.put('payment_requests', self.receive_requests)
self.set_label(addr, message) # should be a default label
rdir = config.get('requests_dir')
if rdir and amount is not None:
key = req.get('id', addr)
pr = paymentrequest.make_request(config, req)
path = os.path.join(rdir, key)
with open(path, 'w') as f:
f.write(pr.SerializeToString())
# reload
req = self.get_payment_request(addr, config)
with open(os.path.join(rdir, key + '.json'), 'w') as f:
f.write(json.dumps(req))
return req
def remove_payment_request(self, addr, config):
if addr not in self.receive_requests:
return False
r = self.receive_requests.pop(addr)
rdir = config.get('requests_dir')
if rdir:
key = r.get('id', addr)
for s in ['.json', '']:
n = os.path.join(rdir, key + s)
if os.path.exists(n):
os.unlink(n)
self.storage.put('payment_requests', self.receive_requests)
return True
def get_sorted_requests(self, config):
return sorted(map(lambda x: self.get_payment_request(x, config), self.receive_requests.keys()), key=lambda x: x.get('time', 0))
class Imported_Wallet(Abstract_Wallet):
wallet_type = 'imported'
def __init__(self, storage):
Abstract_Wallet.__init__(self, storage)
a = self.accounts.get(IMPORTED_ACCOUNT)
if not a:
self.accounts[IMPORTED_ACCOUNT] = ImportedAccount({'imported':{}})
def is_watching_only(self):
acc = self.accounts[IMPORTED_ACCOUNT]
n = acc.keypairs.values()
return len(n) > 0 and n == [[None, None]] * len(n)
def has_seed(self):
return False
def is_deterministic(self):
return False
def check_password(self, password):
self.accounts[IMPORTED_ACCOUNT].get_private_key((0,0), self, password)
def is_used(self, address):
return False
def get_master_public_keys(self):
return {}
def is_beyond_limit(self, address, account, is_change):
return False
class Deterministic_Wallet(Abstract_Wallet):
def __init__(self, storage):
Abstract_Wallet.__init__(self, storage)
def has_seed(self):
return self.seed != ''
def is_deterministic(self):
return True
def is_watching_only(self):
return not self.has_seed()
def add_seed(self, seed, password):
if self.seed:
raise Exception("a seed exists")
self.seed_version, self.seed = self.format_seed(seed)
if password:
self.seed = pw_encode( self.seed, password)
self.use_encryption = True
else:
self.use_encryption = False
self.storage.put('seed', self.seed, False)
self.storage.put('seed_version', self.seed_version, False)
self.storage.put('use_encryption', self.use_encryption,True)
def get_seed(self, password):
return pw_decode(self.seed, password)
def get_mnemonic(self, password):
return self.get_seed(password)
def change_gap_limit(self, value):
assert isinstance(value, int), 'gap limit must be of type int, not of %s'%type(value)
if value >= self.gap_limit:
self.gap_limit = value
self.storage.put('gap_limit', self.gap_limit, True)
return True
elif value >= self.min_acceptable_gap():
for key, account in self.accounts.items():
addresses = account.get_addresses(False)
k = self.num_unused_trailing_addresses(addresses)
n = len(addresses) - k + value
account.receiving_pubkeys = account.receiving_pubkeys[0:n]
account.receiving_addresses = account.receiving_addresses[0:n]
self.gap_limit = value
self.storage.put('gap_limit', self.gap_limit, True)
self.save_accounts()
return True
else:
return False
def num_unused_trailing_addresses(self, addresses):
k = 0
for a in addresses[::-1]:
if self.history.get(a):break
k = k + 1
return k
def min_acceptable_gap(self):
# fixme: this assumes wallet is synchronized
n = 0
nmax = 0
for account in self.accounts.values():
addresses = account.get_addresses(0)
k = self.num_unused_trailing_addresses(addresses)
for a in addresses[0:-k]:
if self.history.get(a):
n = 0
else:
n += 1
if n > nmax: nmax = n
return nmax + 1
def default_account(self):
return self.accounts['0']
def create_new_address(self, account=None, for_change=0):
if account is None:
account = self.default_account()
address = account.create_new_address(for_change)
self.add_address(address)
return address
def add_address(self, address):
if address not in self.history:
self.history[address] = []
if self.synchronizer:
self.synchronizer.add(address)
self.save_accounts()
def synchronize(self):
with self.lock:
for account in self.accounts.values():
account.synchronize(self)
def restore(self, callback):
from i18n import _
def wait_for_wallet():
self.set_up_to_date(False)
while not self.is_up_to_date():
msg = "%s\n%s %d"%(
_("Please wait..."),
_("Addresses generated:"),
len(self.addresses(True)))
apply(callback, (msg,))
time.sleep(0.1)
def wait_for_network():
while not self.network.is_connected():
msg = "%s \n" % (_("Connecting..."))
apply(callback, (msg,))
time.sleep(0.1)
# wait until we are connected, because the user might have selected another server
if self.network:
wait_for_network()
wait_for_wallet()
else:
self.synchronize()
def is_beyond_limit(self, address, account, is_change):
if type(account) == ImportedAccount:
return False
addr_list = account.get_addresses(is_change)
i = addr_list.index(address)
prev_addresses = addr_list[:max(0, i)]
limit = self.gap_limit_for_change if is_change else self.gap_limit
if len(prev_addresses) < limit:
return False
prev_addresses = prev_addresses[max(0, i - limit):]
for addr in prev_addresses:
if self.history.get(addr):
return False
return True
def get_action(self):
if not self.get_master_public_key():
return 'create_seed'
if not self.accounts:
return 'create_accounts'
def get_master_public_keys(self):
out = {}
for k, account in self.accounts.items():
if type(account) == ImportedAccount:
continue
name = self.get_account_name(k)
mpk_text = '\n\n'.join(account.get_master_pubkeys())
out[name] = mpk_text
return out
class BIP32_Wallet(Deterministic_Wallet):
# abstract class, bip32 logic
root_name = 'x/'
def __init__(self, storage):
Deterministic_Wallet.__init__(self, storage)
self.master_public_keys = storage.get('master_public_keys', {})
self.master_private_keys = storage.get('master_private_keys', {})
self.gap_limit = storage.get('gap_limit', 20)
def is_watching_only(self):
return not bool(self.master_private_keys)
def can_import(self):
return False
def get_master_public_key(self):
return self.master_public_keys.get(self.root_name)
def get_master_private_key(self, account, password):
k = self.master_private_keys.get(account)
if not k: return
xprv = pw_decode(k, password)
try:
deserialize_xkey(xprv)
except:
raise InvalidPassword()
return xprv
def check_password(self, password):
xpriv = self.get_master_private_key(self.root_name, password)
xpub = self.master_public_keys[self.root_name]
if deserialize_xkey(xpriv)[3] != deserialize_xkey(xpub)[3]:
raise InvalidPassword()
def add_master_public_key(self, name, xpub):
if xpub in self.master_public_keys.values():
raise BaseException('Duplicate master public key')
self.master_public_keys[name] = xpub
self.storage.put('master_public_keys', self.master_public_keys, True)
def add_master_private_key(self, name, xpriv, password):
self.master_private_keys[name] = pw_encode(xpriv, password)
self.storage.put('master_private_keys', self.master_private_keys, True)
def derive_xkeys(self, root, derivation, password):
x = self.master_private_keys[root]
root_xprv = pw_decode(x, password)
xprv, xpub = bip32_private_derivation(root_xprv, root, derivation)
return xpub, xprv
def create_master_keys(self, password):
seed = self.get_seed(password)
self.add_cosigner_seed(seed, self.root_name, password)
def add_cosigner_seed(self, seed, name, password, passphrase=''):
# we don't store the seed, only the master xpriv
xprv, xpub = bip32_root(self.mnemonic_to_seed(seed, passphrase))
xprv, xpub = bip32_private_derivation(xprv, "m/", self.root_derivation)
self.add_master_public_key(name, xpub)
self.add_master_private_key(name, xprv, password)
def add_cosigner_xpub(self, seed, name):
# store only master xpub
xprv, xpub = bip32_root(self.mnemonic_to_seed(seed,''))
xprv, xpub = bip32_private_derivation(xprv, "m/", self.root_derivation)
self.add_master_public_key(name, xpub)
def mnemonic_to_seed(self, seed, password):
return Mnemonic.mnemonic_to_seed(seed, password)
def make_seed(self, lang=None):
return Mnemonic(lang).make_seed()
def format_seed(self, seed):
return NEW_SEED_VERSION, ' '.join(seed.split())
class BIP32_Simple_Wallet(BIP32_Wallet):
# Wallet with a single BIP32 account, no seed
# gap limit 20
wallet_type = 'xpub'
def create_xprv_wallet(self, xprv, password):
xpub = bitcoin.xpub_from_xprv(xprv)
account = BIP32_Account({'xpub':xpub})
self.storage.put('seed_version', self.seed_version, True)
self.add_master_private_key(self.root_name, xprv, password)
self.add_master_public_key(self.root_name, xpub)
self.add_account('0', account)
self.use_encryption = (password != None)
self.storage.put('use_encryption', self.use_encryption,True)
def create_xpub_wallet(self, xpub):
account = BIP32_Account({'xpub':xpub})
self.storage.put('seed_version', self.seed_version, True)
self.add_master_public_key(self.root_name, xpub)
self.add_account('0', account)
class BIP32_HD_Wallet(BIP32_Wallet):
# wallet that can create accounts
def __init__(self, storage):
self.next_account = storage.get('next_account2', None)
BIP32_Wallet.__init__(self, storage)
def can_create_accounts(self):
return self.root_name in self.master_private_keys.keys()
def addresses(self, b=True):
l = BIP32_Wallet.addresses(self, b)
if self.next_account:
_, _, _, next_address = self.next_account
if next_address not in l:
l.append(next_address)
return l
def get_address_index(self, address):
if self.next_account:
next_id, next_xpub, next_pubkey, next_address = self.next_account
if address == next_address:
return next_id, (0,0)
return BIP32_Wallet.get_address_index(self, address)
def num_accounts(self):
keys = []
for k, v in self.accounts.items():
if type(v) != BIP32_Account:
continue
keys.append(k)
i = 0
while True:
account_id = '%d'%i
if account_id not in keys:
break
i += 1
return i
def get_next_account(self, password):
account_id = '%d'%self.num_accounts()
derivation = self.root_name + "%d'"%int(account_id)
xpub, xprv = self.derive_xkeys(self.root_name, derivation, password)
self.add_master_public_key(derivation, xpub)
if xprv:
self.add_master_private_key(derivation, xprv, password)
account = BIP32_Account({'xpub':xpub})
addr, pubkey = account.first_address()
self.add_address(addr)
return account_id, xpub, pubkey, addr
def create_main_account(self, password):
# First check the password is valid (this raises if it isn't).
self.check_password(password)
assert self.num_accounts() == 0
self.create_account('Main account', password)
def create_account(self, name, password):
account_id, xpub, _, _ = self.get_next_account(password)
account = BIP32_Account({'xpub':xpub})
self.add_account(account_id, account)
self.set_label(account_id, name)
# add address of the next account
self.next_account = self.get_next_account(password)
self.storage.put('next_account2', self.next_account)
def account_is_pending(self, k):
return type(self.accounts.get(k)) == PendingAccount
def delete_pending_account(self, k):
assert type(self.accounts.get(k)) == PendingAccount
self.accounts.pop(k)
self.save_accounts()
def create_pending_account(self, name, password):
if self.next_account is None:
self.next_account = self.get_next_account(password)
self.storage.put('next_account2', self.next_account)
next_id, next_xpub, next_pubkey, next_address = self.next_account
if name:
self.set_label(next_id, name)
self.accounts[next_id] = PendingAccount({'pending':True, 'address':next_address, 'pubkey':next_pubkey})
self.save_accounts()
def synchronize(self):
# synchronize existing accounts
BIP32_Wallet.synchronize(self)
if self.next_account is None and not self.use_encryption:
try:
self.next_account = self.get_next_account(None)
self.storage.put('next_account2', self.next_account)
except:
self.print_error('cannot get next account')
# check pending account
if self.next_account is not None:
next_id, next_xpub, next_pubkey, next_address = self.next_account
if self.address_is_old(next_address):
self.print_error("creating account", next_id)
self.add_account(next_id, BIP32_Account({'xpub':next_xpub}))
# here the user should get a notification
self.next_account = None
self.storage.put('next_account2', self.next_account)
elif self.history.get(next_address, []):
if next_id not in self.accounts:
self.print_error("create pending account", next_id)
self.accounts[next_id] = PendingAccount({'pending':True, 'address':next_address, 'pubkey':next_pubkey})
self.save_accounts()
class NewWallet(BIP32_Wallet, Mnemonic):
# Standard wallet
root_derivation = "m/"
wallet_type = 'standard'
def create_main_account(self, password):
xpub = self.master_public_keys.get("x/")
account = BIP32_Account({'xpub':xpub})
self.add_account('0', account)
class Multisig_Wallet(BIP32_Wallet, Mnemonic):
# generic m of n
root_name = "x1/"
root_derivation = "m/"
def __init__(self, storage):
BIP32_Wallet.__init__(self, storage)
self.wallet_type = storage.get('wallet_type')
m = re.match('(\d+)of(\d+)', self.wallet_type)
self.m = int(m.group(1))
self.n = int(m.group(2))
def load_accounts(self):
self.accounts = {}
d = self.storage.get('accounts', {})
v = d.get('0')
if v:
if v.get('xpub3'):
v['xpubs'] = [v['xpub'], v['xpub2'], v['xpub3']]
elif v.get('xpub2'):
v['xpubs'] = [v['xpub'], v['xpub2']]
self.accounts = {'0': Multisig_Account(v)}
def create_main_account(self, password):
account = Multisig_Account({'xpubs': self.master_public_keys.values(), 'm': self.m})
self.add_account('0', account)
def get_master_public_keys(self):
return self.master_public_keys
def get_action(self):
for i in range(self.n):
if self.master_public_keys.get("x%d/"%(i+1)) is None:
return 'create_seed' if i == 0 else 'add_cosigners'
if not self.accounts:
return 'create_accounts'
class OldWallet(Deterministic_Wallet):
wallet_type = 'old'
def __init__(self, storage):
Deterministic_Wallet.__init__(self, storage)
self.gap_limit = storage.get('gap_limit', 5)
def make_seed(self):
import old_mnemonic
seed = random_seed(128)
return ' '.join(old_mnemonic.mn_encode(seed))
def format_seed(self, seed):
import old_mnemonic
# see if seed was entered as hex
seed = seed.strip()
try:
assert seed
seed.decode('hex')
return OLD_SEED_VERSION, str(seed)
except Exception:
pass
words = seed.split()
seed = old_mnemonic.mn_decode(words)
if not seed:
raise Exception("Invalid seed")
return OLD_SEED_VERSION, seed
def create_master_keys(self, password):
seed = self.get_seed(password)
mpk = OldAccount.mpk_from_seed(seed)
self.storage.put('master_public_key', mpk, True)
def get_master_public_key(self):
return self.storage.get("master_public_key")
def get_master_public_keys(self):
return {'Main Account':self.get_master_public_key()}
def create_main_account(self, password):
mpk = self.storage.get("master_public_key")
self.create_account(mpk)
def create_account(self, mpk):
self.accounts['0'] = OldAccount({'mpk':mpk, 0:[], 1:[]})
self.save_accounts()
def create_watching_only_wallet(self, mpk):
self.seed_version = OLD_SEED_VERSION
self.storage.put('seed_version', self.seed_version, False)
self.storage.put('master_public_key', mpk, True)
self.create_account(mpk)
def get_seed(self, password):
seed = pw_decode(self.seed, password).encode('utf8')
return seed
def check_password(self, password):
seed = self.get_seed(password)
self.accounts['0'].check_seed(seed)
def get_mnemonic(self, password):
import old_mnemonic
s = self.get_seed(password)
return ' '.join(old_mnemonic.mn_encode(s))
wallet_types = [
# category type description constructor
('standard', 'old', ("Old wallet"), OldWallet),
('standard', 'xpub', ("BIP32 Import"), BIP32_Simple_Wallet),
('standard', 'standard', ("Standard wallet"), NewWallet),
('standard', 'imported', ("Imported wallet"), Imported_Wallet),
('multisig', '2of2', ("Multisig wallet (2 of 2)"), Multisig_Wallet),
('multisig', '2of3', ("Multisig wallet (2 of 3)"), Multisig_Wallet)
]
# former WalletFactory
class Wallet(object):
"""The main wallet "entry point".
This class is actually a factory that will return a wallet of the correct
type when passed a WalletStorage instance."""
def __new__(self, storage):
seed_version = storage.get('seed_version')
if not seed_version:
seed_version = OLD_SEED_VERSION if len(storage.get('master_public_key','')) == 128 else NEW_SEED_VERSION
if seed_version not in [OLD_SEED_VERSION, NEW_SEED_VERSION]:
msg = "Your wallet has an unsupported seed version."
msg += '\n\nWallet file: %s' % os.path.abspath(storage.path)
if seed_version in [5, 7, 8, 9, 10]:
msg += "\n\nTo open this wallet, try 'git checkout seed_v%d'"%seed_version
if seed_version == 6:
# version 1.9.8 created v6 wallets when an incorrect seed was entered in the restore dialog
msg += '\n\nThis file was created because of a bug in version 1.9.8.'
if storage.get('master_public_keys') is None and storage.get('master_private_keys') is None and storage.get('imported_keys') is None:
# pbkdf2 was not included with the binaries, and wallet creation aborted.
msg += "\nIt does not contain any keys, and can safely be removed."
else:
# creation was complete if electrum was run from source
msg += "\nPlease open this file with Electrum 1.9.8, and move your coins to a new wallet."
raise BaseException(msg)
wallet_type = storage.get('wallet_type')
if wallet_type:
for cat, t, name, loader in wallet_types:
if t == wallet_type:
if cat in ['hardware', 'twofactor']:
WalletClass = lambda storage: apply(loader().constructor, (storage,))
else:
WalletClass = loader
break
else:
if re.match('(\d+)of(\d+)', wallet_type):
WalletClass = Multisig_Wallet
else:
raise BaseException('unknown wallet type', wallet_type)
else:
if seed_version == OLD_SEED_VERSION:
WalletClass = OldWallet
else:
WalletClass = NewWallet
return WalletClass(storage)
@classmethod
def is_seed(self, seed):
if not seed:
return False
elif is_old_seed(seed):
return True
elif is_new_seed(seed):
return True
else:
return False
@classmethod
def is_old_mpk(self, mpk):
try:
int(mpk, 16)
assert len(mpk) == 128
return True
except:
return False
@classmethod
def is_xpub(self, text):
try:
assert text[0:4] == 'xpub'
deserialize_xkey(text)
return True
except:
return False
@classmethod
def is_xprv(self, text):
try:
assert text[0:4] == 'xprv'
deserialize_xkey(text)
return True
except:
return False
@classmethod
def is_address(self, text):
if not text:
return False
for x in text.split():
if not bitcoin.is_address(x):
return False
return True
@classmethod
def is_private_key(self, text):
if not text:
return False
for x in text.split():
if not bitcoin.is_private_key(x):
return False
return True
@classmethod
def from_seed(self, seed, password, storage):
if is_old_seed(seed):
klass = OldWallet
elif is_new_seed(seed):
klass = NewWallet
w = klass(storage)
w.add_seed(seed, password)
w.create_master_keys(password)
w.create_main_account(password)
return w
@classmethod
def from_address(self, text, storage):
w = Imported_Wallet(storage)
for x in text.split():
w.accounts[IMPORTED_ACCOUNT].add(x, None, None, None)
w.save_accounts()
return w
@classmethod
def from_private_key(self, text, password, storage):
w = Imported_Wallet(storage)
w.update_password(None, password)
for x in text.split():
w.import_key(x, password)
return w
@classmethod
def from_old_mpk(self, mpk, storage):
w = OldWallet(storage)
w.seed = ''
w.create_watching_only_wallet(mpk)
return w
@classmethod
def from_xpub(self, xpub, storage):
w = BIP32_Simple_Wallet(storage)
w.create_xpub_wallet(xpub)
return w
@classmethod
def from_xprv(self, xprv, password, storage):
w = BIP32_Simple_Wallet(storage)
w.create_xprv_wallet(xprv, password)
return w
@classmethod
def from_multisig(klass, key_list, password, storage, wallet_type):
storage.put('wallet_type', wallet_type, True)
self = Multisig_Wallet(storage)
key_list = sorted(key_list, key = lambda x: klass.is_xpub(x))
for i, text in enumerate(key_list):
assert klass.is_seed(text) or klass.is_xprv(text) or klass.is_xpub(text)
name = "x%d/"%(i+1)
if klass.is_xprv(text):
xpub = bitcoin.xpub_from_xprv(text)
self.add_master_public_key(name, xpub)
self.add_master_private_key(name, text, password)
elif klass.is_xpub(text):
self.add_master_public_key(name, text)
elif klass.is_seed(text):
if name == 'x1/':
self.add_seed(text, password)
self.create_master_keys(password)
else:
self.add_cosigner_seed(text, name, password)
self.use_encryption = (password != None)
self.storage.put('use_encryption', self.use_encryption, True)
self.create_main_account(password)
return self