# Electrum - lightweight bitcoinprivate client # Copyright (C) 2015 Thomas Voegtlin # # Permission is hereby granted, free of charge, to any person # obtaining a copy of this software and associated documentation files # (the "Software"), to deal in the Software without restriction, # including without limitation the rights to use, copy, modify, merge, # publish, distribute, sublicense, and/or sell copies of the Software, # and to permit persons to whom the Software is furnished to do so, # subject to the following conditions: # # The above copyright notice and this permission notice shall be # included in all copies or substantial portions of the Software. # # THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, # EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF # MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND # NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS # BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN # ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN # CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE # SOFTWARE. # Wallet classes: # - Imported_Wallet: imported address, no keystore # - Standard_Wallet: one keystore, P2PKH # - Multisig_Wallet: several keystores, P2SH import os import threading import random import time import json import copy import errno import traceback from functools import partial from collections import defaultdict from numbers import Number from decimal import Decimal import itertools import sys from .i18n import _ from .util import (NotEnoughFunds, PrintError, UserCancelled, profiler, format_satoshis, NoDynamicFeeEstimates, TimeoutException, WalletFileException, BitcoinException) from .bitcoin import * from .version import * from .keystore import load_keystore, Hardware_KeyStore from .storage import multisig_type, STO_EV_PLAINTEXT, STO_EV_USER_PW, STO_EV_XPUB_PW from . import transaction from .transaction import Transaction from .plugins import run_hook from . import bitcoin from . import coinchooser from .synchronizer import Synchronizer from .verifier import SPV from . import paymentrequest from .paymentrequest import PR_PAID, PR_UNPAID, PR_UNKNOWN, PR_EXPIRED from .paymentrequest import InvoiceStore from .contacts import Contacts TX_STATUS = [ _('Unconfirmed'), _('Unconfirmed parent'), _('Not Verified'), _('Local'), ] TX_HEIGHT_LOCAL = -2 TX_HEIGHT_UNCONF_PARENT = -1 TX_HEIGHT_UNCONFIRMED = 0 def relayfee(network): from .simple_config import FEERATE_DEFAULT_RELAY MAX_RELAY_FEE = 10000 f = network.relay_fee if network and network.relay_fee else FEERATE_DEFAULT_RELAY return min(f, MAX_RELAY_FEE) def dust_threshold(network): # Change <= dust threshold is added to the tx fee return 182 * 3 * relayfee(network) / 1000 def append_utxos_to_inputs(inputs, network, pubkey, txin_type, imax): if txin_type != 'p2pk': address = bitcoin.pubkey_to_address(txin_type, pubkey) sh = bitcoin.address_to_scripthash(address) else: script = bitcoin.public_key_to_p2pk_script(pubkey) sh = bitcoin.script_to_scripthash(script) address = '(pubkey)' u = network.synchronous_get(('blockchain.scripthash.listunspent', [sh])) for item in u: if len(inputs) >= imax: break item['address'] = address item['type'] = txin_type item['prevout_hash'] = item['tx_hash'] item['prevout_n'] = item['tx_pos'] item['pubkeys'] = [pubkey] item['x_pubkeys'] = [pubkey] item['signatures'] = [None] item['num_sig'] = 1 inputs.append(item) def sweep_preparations(privkeys, network, imax=100): def find_utxos_for_privkey(txin_type, privkey, compressed): pubkey = bitcoin.public_key_from_private_key(privkey, compressed) append_utxos_to_inputs(inputs, network, pubkey, txin_type, imax) keypairs[pubkey] = privkey, compressed inputs = [] keypairs = {} for sec in privkeys: txin_type, privkey, compressed = bitcoin.deserialize_privkey(sec) find_utxos_for_privkey(txin_type, privkey, compressed) # do other lookups to increase support coverage if is_minikey(sec): # minikeys don't have a compressed byte # we lookup both compressed and uncompressed pubkeys find_utxos_for_privkey(txin_type, privkey, not compressed) elif txin_type == 'p2pkh': # WIF serialization does not distinguish p2pkh and p2pk # we also search for pay-to-pubkey outputs find_utxos_for_privkey('p2pk', privkey, compressed) if not inputs: raise Exception(_('No inputs found. (Note that inputs need to be confirmed)')) # FIXME actually inputs need not be confirmed now, see https://github.com/kyuupichan/electrumx/issues/365 return inputs, keypairs def sweep(privkeys, network, config, recipient, fee=None, imax=100): inputs, keypairs = sweep_preparations(privkeys, network, imax) total = sum(i.get('value') for i in inputs) if fee is None: outputs = [(TYPE_ADDRESS, recipient, total)] tx = Transaction.from_io(inputs, outputs) fee = config.estimate_fee(tx.estimated_size()) if total - fee < 0: raise Exception(_('Not enough funds on address.') + '\nTotal: %d satoshis\nFee: %d'%(total, fee)) if total - fee < dust_threshold(network): raise Exception(_('Not enough funds on address.') + '\nTotal: %d satoshis\nFee: %d\nDust Threshold: %d'%(total, fee, dust_threshold(network))) outputs = [(TYPE_ADDRESS, recipient, total - fee)] locktime = network.get_local_height() tx = Transaction.from_io(inputs, outputs, locktime=locktime) tx.BIP_LI01_sort() tx.sign(keypairs) return tx class AddTransactionException(Exception): pass class UnrelatedTransactionException(AddTransactionException): def __str__(self): return _("Transaction is unrelated to this wallet.") class NotIsMineTransactionException(AddTransactionException): def __str__(self): return _("Only transactions with inputs owned by the wallet can be added.") 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. """ max_change_outputs = 3 def __init__(self, storage): self.electrum_version = ELECTRUM_VERSION self.storage = storage self.network = None # verifier (SPV) and synchronizer are started in start_threads self.synchronizer = None self.verifier = None self.gap_limit_for_change = 6 # constant # locks: if you need to take multiple ones, acquire them in the order they are defined here! self.lock = threading.RLock() self.transaction_lock = threading.RLock() # saved fields self.use_change = storage.get('use_change', True) self.multiple_change = storage.get('multiple_change', False) self.labels = storage.get('labels', {}) self.frozen_addresses = set(storage.get('frozen_addresses',[])) self.history = storage.get('addr_history',{}) # address -> list(txid, height) self.fiat_value = storage.get('fiat_value', {}) self.receive_requests = storage.get('payment_requests', {}) # Verified transactions. Each value is a (height, timestamp, block_pos) tuple. Access with self.lock. self.verified_tx = storage.get('verified_tx3', {}) # Transactions pending verification. A map from tx hash to transaction # height. Access is not contended so no lock is needed. self.unverified_tx = defaultdict(int) self.load_keystore() self.load_addresses() self.test_addresses_sanity() self.load_transactions() self.check_history() self.load_unverified_transactions() self.load_local_history() self.build_spent_outpoints() self.remove_local_transactions_we_dont_have() # 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 # save wallet type the first time if self.storage.get('wallet_type') is None: self.storage.put('wallet_type', self.wallet_type) # invoices and contacts self.invoices = InvoiceStore(self.storage) self.contacts = Contacts(self.storage) self.coin_price_cache = {} def diagnostic_name(self): return self.basename() def __str__(self): return self.basename() def get_master_public_key(self): return None @profiler def load_transactions(self): self.txi = self.storage.get('txi', {}) self.txo = self.storage.get('txo', {}) self.tx_fees = self.storage.get('tx_fees', {}) 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 load_local_history(self): self._history_local = {} # address -> set(txid) for txid in itertools.chain(self.txi, self.txo): self._add_tx_to_local_history(txid) def remove_local_transactions_we_dont_have(self): txid_set = set(self.txi) | set(self.txo) for txid in txid_set: tx_height = self.get_tx_height(txid)[0] if tx_height == TX_HEIGHT_LOCAL and txid not in self.transactions: self.remove_transaction(txid) @profiler def save_transactions(self, write=False): with self.transaction_lock: tx = {} for k,v in self.transactions.items(): tx[k] = str(v) self.storage.put('transactions', tx) self.storage.put('txi', self.txi) self.storage.put('txo', self.txo) self.storage.put('tx_fees', self.tx_fees) self.storage.put('pruned_txo', self.pruned_txo) self.storage.put('addr_history', self.history) if write: self.storage.write() def clear_history(self): with self.lock: with self.transaction_lock: self.txi = {} self.txo = {} self.tx_fees = {} self.pruned_txo = {} self.spent_outpoints = {} self.history = {} self.verified_tx = {} self.transactions = {} self.save_transactions() @profiler def build_spent_outpoints(self): self.spent_outpoints = {} for txid, items in self.txi.items(): for addr, l in items.items(): for ser, v in l: self.spent_outpoints[ser] = txid @profiler def check_history(self): save = False hist_addrs_mine = list(filter(lambda k: self.is_mine(k), self.history.keys())) hist_addrs_not_mine = list(filter(lambda k: not self.is_mine(k), self.history.keys())) for addr in hist_addrs_not_mine: self.history.pop(addr) save = True for addr in hist_addrs_mine: hist = self.history[addr] 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: self.add_transaction(tx_hash, tx) save = True if save: self.save_transactions() def basename(self): return os.path.basename(self.storage.path) def save_addresses(self): self.storage.put('addresses', {'receiving':self.receiving_addresses, 'change':self.change_addresses}) def load_addresses(self): d = self.storage.get('addresses', {}) if type(d) != dict: d={} self.receiving_addresses = d.get('receiving', []) self.change_addresses = d.get('change', []) def test_addresses_sanity(self): addrs = self.get_receiving_addresses() if len(addrs) > 0: if not bitcoin.is_address(addrs[0]): raise WalletFileException('The addresses in this wallet are not bitcoinprivate addresses.') def synchronize(self): pass def is_deterministic(self): return self.keystore.is_deterministic() def set_up_to_date(self, up_to_date): with self.lock: self.up_to_date = up_to_date if up_to_date: self.save_transactions(write=True) def is_up_to_date(self): with self.lock: return self.up_to_date def set_label(self, name, text = None): changed = False old_text = self.labels.get(name) if text: text = text.replace("\n", " ") 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) return changed def set_fiat_value(self, txid, ccy, text): if txid not in self.transactions: return if not text: d = self.fiat_value.get(ccy, {}) if d and txid in d: d.pop(txid) else: return else: try: Decimal(text) except: return if ccy not in self.fiat_value: self.fiat_value[ccy] = {} self.fiat_value[ccy][txid] = text self.storage.put('fiat_value', self.fiat_value) def get_fiat_value(self, txid, ccy): fiat_value = self.fiat_value.get(ccy, {}).get(txid) try: return Decimal(fiat_value) except: return def is_mine(self, address): return address in self.get_addresses() def is_change(self, address): if not self.is_mine(address): return False return self.get_address_index(address)[0] def get_address_index(self, address): raise NotImplementedError() def get_redeem_script(self, address): return None def export_private_key(self, address, password): if self.is_watching_only(): return [] index = self.get_address_index(address) pk, compressed = self.keystore.get_private_key(index, password) txin_type = self.get_txin_type(address) redeem_script = self.get_redeem_script(address) serialized_privkey = bitcoin.serialize_privkey(pk, compressed, txin_type) return serialized_privkey, redeem_script def get_public_keys(self, address): return [self.get_public_key(address)] def add_unverified_tx(self, tx_hash, tx_height): if tx_height in (TX_HEIGHT_UNCONFIRMED, TX_HEIGHT_UNCONF_PARENT) \ and tx_hash in self.verified_tx: self.verified_tx.pop(tx_hash) if self.verifier: self.verifier.merkle_roots.pop(tx_hash, None) # tx will be verified only if height > 0 if 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) height, conf, timestamp = self.get_tx_height(tx_hash) self.network.trigger_callback('verified', tx_hash, height, conf, timestamp) def get_unverified_txs(self): '''Returns a map from tx hash to transaction height''' return self.unverified_tx def undo_verifications(self, blockchain, height): '''Used by the verifier when a reorg has happened''' txs = set() with self.lock: for tx_hash, item in list(self.verified_tx.items()): tx_height, timestamp, pos = item if tx_height >= height: header = blockchain.read_header(tx_height) # fixme: use block hash, not timestamp if not header or header.get('timestamp') != timestamp: self.verified_tx.pop(tx_hash, None) txs.add(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.storage.get('stored_height', 0) def get_tx_height(self, tx_hash): """ Given a transaction, returns (height, conf, timestamp) """ with self.lock: if tx_hash in self.verified_tx: height, timestamp, pos = self.verified_tx[tx_hash] conf = max(self.get_local_height() - height + 1, 0) return height, conf, timestamp elif tx_hash in self.unverified_tx: height = self.unverified_tx[tx_hash] return height, 0, None else: # local transaction return TX_HEIGHT_LOCAL, 0, None def get_txpos(self, tx_hash): "return position, even if the tx is unverified" with self.lock: if tx_hash in self.verified_tx: height, timestamp, pos = self.verified_tx[tx_hash] return height, pos elif tx_hash in self.unverified_tx: height = self.unverified_tx[tx_hash] return (height, 0) if height > 0 else ((1e9 - height), 0) else: return (1e9+1, 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_tx_value(self, txid): " effect of tx on the entire domain" delta = 0 for addr, d in self.txi.get(txid, {}).items(): for n, v in d: delta -= v for addr, d in self.txo.get(txid, {}).items(): for n, v, cb in d: delta += v return delta def get_wallet_delta(self, tx): """ effect of tx on wallet """ addresses = self.get_addresses() is_relevant = False is_mine = 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_mine = 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_mine: 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_mine: 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 else: # all inputs are mine fee = v_in - v_out if not is_mine: fee = None return is_relevant, is_mine, v, fee def get_tx_info(self, tx): is_relevant, is_mine, v, fee = self.get_wallet_delta(tx) exp_n = None can_broadcast = False label = '' height = conf = timestamp = None tx_hash = tx.txid() if tx.is_complete(): if tx_hash in self.transactions.keys(): label = self.get_label(tx_hash) height, conf, timestamp = self.get_tx_height(tx_hash) if height > 0: if conf: status = _("{} confirmations").format(conf) else: status = _('Not verified') elif height in (TX_HEIGHT_UNCONF_PARENT, TX_HEIGHT_UNCONFIRMED): status = _('Unconfirmed') if fee is None: fee = self.tx_fees.get(tx_hash) if fee and self.network and self.network.config.has_fee_mempool(): size = tx.estimated_size() fee_per_kb = round(fee * 1000 / size) exp_n = self.network.config.fee_to_depth(fee_per_kb) else: status = _('Local') can_broadcast = self.network is not None else: status = _("Signed") can_broadcast = self.network is not None else: s, r = tx.signature_count() status = _("Unsigned") if s == 0 else _('Partially signed') + ' (%d/%d)'%(s,r) if is_relevant: if is_mine: if fee is not None: amount = v + fee else: amount = v else: amount = v else: amount = None return tx_hash, status, label, can_broadcast, amount, fee, height, conf, timestamp, exp_n def get_addr_io(self, address): h = self.get_address_history(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) out = {} for txo, v in coins.items(): tx_height, value, is_cb = v prevout_hash, prevout_n = txo.split(':') x = { 'address':address, 'value':value, 'prevout_n':int(prevout_n), 'prevout_hash':prevout_hash, 'height':tx_height, 'coinbase':is_cb } out[txo] = x return out # 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 local_height = self.get_local_height() for txo, (tx_height, v, is_cb) in received.items(): if is_cb and tx_height + COINBASE_MATURITY > 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, config): confirmed_only = config.get('confirmed_only', False) return self.get_utxos(domain, exclude_frozen=True, mature=True, confirmed_only=confirmed_only) def get_utxos(self, domain = None, exclude_frozen = False, mature = False, confirmed_only = False): coins = [] if domain is None: domain = self.get_addresses() if exclude_frozen: domain = set(domain) - self.frozen_addresses for addr in domain: utxos = self.get_addr_utxo(addr) for x in utxos.values(): if confirmed_only and x['height'] <= 0: continue if mature and x['coinbase'] and x['height'] + COINBASE_MATURITY > self.get_local_height(): continue coins.append(x) continue return coins def dummy_address(self): return self.get_receiving_addresses()[0] def get_addresses(self): out = [] out += self.get_receiving_addresses() out += self.get_change_addresses() return out def get_frozen_balance(self): return self.get_balance(self.frozen_addresses) def get_balance(self, domain=None): if domain is None: domain = self.get_addresses() 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, addr): h = [] # we need self.transaction_lock but get_tx_height will take self.lock # so we need to take that too here, to enforce order of locks with self.lock, self.transaction_lock: related_txns = self._history_local.get(addr, set()) for tx_hash in related_txns: tx_height = self.get_tx_height(tx_hash)[0] h.append((tx_hash, tx_height)) return h def _add_tx_to_local_history(self, txid): with self.transaction_lock: for addr in itertools.chain(self.txi.get(txid, []), self.txo.get(txid, [])): cur_hist = self._history_local.get(addr, set()) cur_hist.add(txid) self._history_local[addr] = cur_hist def _remove_tx_from_local_history(self, txid): with self.transaction_lock: for addr in itertools.chain(self.txi.get(txid, []), self.txo.get(txid, [])): cur_hist = self._history_local.get(addr, set()) try: cur_hist.remove(txid) except KeyError: pass else: self._history_local[addr] = cur_hist def get_txin_address(self, txi): addr = txi.get('address') if addr != "(pubkey)": return addr prevout_hash = txi.get('prevout_hash') prevout_n = txi.get('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 get_txout_address(self, txo): _type, x, v = txo if _type == TYPE_ADDRESS: addr = x elif _type == TYPE_PUBKEY: addr = bitcoin.public_key_to_p2pkh(bfh(x)) else: addr = None return addr def get_conflicting_transactions(self, tx): """Returns a set of transaction hashes from the wallet history that are directly conflicting with tx, i.e. they have common outpoints being spent with tx. If the tx is already in wallet history, that will not be reported as a conflict. """ conflicting_txns = set() with self.transaction_lock: for txi in tx.inputs(): ser = Transaction.get_outpoint_from_txin(txi) if ser is None: continue spending_tx_hash = self.spent_outpoints.get(ser, None) if spending_tx_hash is None: continue # this outpoint (ser) has already been spent, by spending_tx assert spending_tx_hash in self.transactions conflicting_txns |= {spending_tx_hash} txid = tx.txid() if txid in conflicting_txns: # this tx is already in history, so it conflicts with itself if len(conflicting_txns) > 1: raise Exception('Found conflicting transactions already in wallet history.') conflicting_txns -= {txid} return conflicting_txns def add_transaction(self, tx_hash, tx): assert tx_hash, tx_hash assert tx, tx assert tx.is_complete() # we need self.transaction_lock but get_tx_height will take self.lock # so we need to take that too here, to enforce order of locks with self.lock, self.transaction_lock: # NOTE: returning if tx in self.transactions might seem like a good idea # BUT we track is_mine inputs in a txn, and during subsequent calls # of add_transaction tx, we might learn of more-and-more inputs of # being is_mine, as we roll the gap_limit forward is_coinbase = len(tx.inputs()) and tx.inputs()[0]['type'] == 'coinbase' tx_height = self.get_tx_height(tx_hash)[0] is_mine = any([self.is_mine(txin['address']) for txin in tx.inputs()]) # do not save if tx is local and not mine if tx_height == TX_HEIGHT_LOCAL and not is_mine: # FIXME the test here should be for "not all is_mine"; cannot detect conflict in some cases raise NotIsMineTransactionException() # raise exception if unrelated to wallet is_for_me = any([self.is_mine(self.get_txout_address(txo)) for txo in tx.outputs()]) if not is_mine and not is_for_me: raise UnrelatedTransactionException() # Find all conflicting transactions. # In case of a conflict, # 1. confirmed > mempool > local # 2. this new txn has priority over existing ones # When this method exits, there must NOT be any conflict, so # either keep this txn and remove all conflicting (along with dependencies) # or drop this txn conflicting_txns = self.get_conflicting_transactions(tx) if conflicting_txns: existing_mempool_txn = any( self.get_tx_height(tx_hash2)[0] in (TX_HEIGHT_UNCONFIRMED, TX_HEIGHT_UNCONF_PARENT) for tx_hash2 in conflicting_txns) existing_confirmed_txn = any( self.get_tx_height(tx_hash2)[0] > 0 for tx_hash2 in conflicting_txns) if existing_confirmed_txn and tx_height <= 0: # this is a non-confirmed tx that conflicts with confirmed txns; drop. return False if existing_mempool_txn and tx_height == TX_HEIGHT_LOCAL: # this is a local tx that conflicts with non-local txns; drop. return False # keep this txn and remove all conflicting to_remove = set() to_remove |= conflicting_txns for conflicting_tx_hash in conflicting_txns: to_remove |= self.get_depending_transactions(conflicting_tx_hash) for tx_hash2 in to_remove: self.remove_transaction(tx_hash2) # add inputs self.txi[tx_hash] = d = {} for txi in tx.inputs(): addr = self.get_txin_address(txi) if txi['type'] != 'coinbase': prevout_hash = txi['prevout_hash'] prevout_n = txi['prevout_n'] ser = prevout_hash + ':%d'%prevout_n if addr and self.is_mine(addr): # we only track is_mine spends self.spent_outpoints[ser] = tx_hash # find value from prev output 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()): v = txo[2] ser = tx_hash + ':%d'%n addr = self.get_txout_address(txo) 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)) self._add_tx_to_local_history(next_tx) # add to local history self._add_tx_to_local_history(tx_hash) # save self.transactions[tx_hash] = tx return True def remove_transaction(self, tx_hash): with self.transaction_lock: self.print_error("removing tx from history", tx_hash) self.transactions.pop(tx_hash, None) # undo spent_outpoints that are in txi for addr, l in self.txi[tx_hash].items(): for ser, v in l: self.spent_outpoints.pop(ser, None) # undo spent_outpoints that are in pruned_txo for ser, hh in list(self.pruned_txo.items()): if hh == tx_hash: self.spent_outpoints.pop(ser, None) self.pruned_txo.pop(ser) self._remove_tx_from_local_history(tx_hash) # add tx to pruned_txo, and undo the txi addition for next_tx, dd in self.txi.items(): for addr, l in list(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, None) self.txo.pop(tx_hash, None) def receive_tx_callback(self, tx_hash, tx, tx_height): self.add_unverified_tx(tx_hash, tx_height) self.add_transaction(tx_hash, tx) def receive_history_callback(self, addr, hist, tx_fees): with self.lock: old_hist = self.get_address_history(addr) for tx_hash, height in old_hist: if (tx_hash, height) not in hist: # make tx local self.unverified_tx.pop(tx_hash, None) self.verified_tx.pop(tx_hash, None) if self.verifier: self.verifier.merkle_roots.pop(tx_hash, None) # but remove completely if not is_mine if self.txi[tx_hash] == {}: # FIXME the test here should be for "not all is_mine"; cannot detect conflict in some cases self.remove_transaction(tx_hash) self.history[addr] = hist for tx_hash, tx_height in hist: # add it in case it was previously unconfirmed self.add_unverified_tx(tx_hash, tx_height) # 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: self.add_transaction(tx_hash, tx) # Store fees self.tx_fees.update(tx_fees) def get_history(self, domain=None): # get domain if domain is None: domain = self.get_addresses() # 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 in tx_deltas: delta = tx_deltas[tx_hash] height, conf, timestamp = self.get_tx_height(tx_hash) history.append((tx_hash, height, conf, timestamp, delta)) 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 tx_hash, height, conf, timestamp, delta in history: h2.append((tx_hash, height, conf, timestamp, delta, 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 balance_at_timestamp(self, domain, target_timestamp): h = self.get_history(domain) for tx_hash, height, conf, timestamp, value, balance in h: if timestamp > target_timestamp: return balance - value # return last balance return balance @profiler def get_full_history(self, domain=None, from_timestamp=None, to_timestamp=None, fx=None, show_addresses=False): from .util import timestamp_to_datetime, Satoshis, Fiat out = [] income = 0 expenditures = 0 capital_gains = Decimal(0) fiat_income = Decimal(0) fiat_expenditures = Decimal(0) h = self.get_history(domain) for tx_hash, height, conf, timestamp, value, balance in h: if from_timestamp and (timestamp or time.time()) < from_timestamp: continue if to_timestamp and (timestamp or time.time()) >= to_timestamp: continue item = { 'txid':tx_hash, 'height':height, 'confirmations':conf, 'timestamp':timestamp, 'value': Satoshis(value), 'balance': Satoshis(balance) } item['date'] = timestamp_to_datetime(timestamp) item['label'] = self.get_label(tx_hash) if show_addresses: tx = self.transactions.get(tx_hash) tx.deserialize() input_addresses = [] output_addresses = [] for x in tx.inputs(): if x['type'] == 'coinbase': continue addr = self.get_txin_address(x) if addr is None: continue input_addresses.append(addr) for addr, v in tx.get_outputs(): output_addresses.append(addr) item['input_addresses'] = input_addresses item['output_addresses'] = output_addresses # value may be None if wallet is not fully synchronized if value is None: continue # fixme: use in and out values if value < 0: expenditures += -value else: income += value # fiat computations if fx and fx.is_enabled(): date = timestamp_to_datetime(timestamp) fiat_value = self.get_fiat_value(tx_hash, fx.ccy) fiat_default = fiat_value is None fiat_value = fiat_value if fiat_value is not None else value / Decimal(COIN) * self.price_at_timestamp(tx_hash, fx.timestamp_rate) item['fiat_value'] = Fiat(fiat_value, fx.ccy) item['fiat_default'] = fiat_default if value < 0: acquisition_price = - value / Decimal(COIN) * self.average_price(tx_hash, fx.timestamp_rate, fx.ccy) liquidation_price = - fiat_value item['acquisition_price'] = Fiat(acquisition_price, fx.ccy) cg = liquidation_price - acquisition_price item['capital_gain'] = Fiat(cg, fx.ccy) capital_gains += cg fiat_expenditures += -fiat_value else: fiat_income += fiat_value out.append(item) # add summary if out: b, v = out[0]['balance'].value, out[0]['value'].value start_balance = None if b is None or v is None else b - v end_balance = out[-1]['balance'].value if from_timestamp is not None and to_timestamp is not None: start_date = timestamp_to_datetime(from_timestamp) end_date = timestamp_to_datetime(to_timestamp) else: start_date = None end_date = None summary = { 'start_date': start_date, 'end_date': end_date, 'start_balance': Satoshis(start_balance), 'end_balance': Satoshis(end_balance), 'income': Satoshis(income), 'expenditures': Satoshis(expenditures) } if fx and fx.is_enabled(): unrealized = self.unrealized_gains(domain, fx.timestamp_rate, fx.ccy) summary['capital_gains'] = Fiat(capital_gains, fx.ccy) summary['fiat_income'] = Fiat(fiat_income, fx.ccy) summary['fiat_expenditures'] = Fiat(fiat_expenditures, fx.ccy) summary['unrealized_gains'] = Fiat(unrealized, fx.ccy) summary['start_fiat_balance'] = Fiat(fx.historical_value(start_balance, start_date), fx.ccy) summary['end_fiat_balance'] = Fiat(fx.historical_value(end_balance, end_date), fx.ccy) else: summary = {} return { 'transactions': out, 'summary': summary } def get_label(self, tx_hash): label = self.labels.get(tx_hash, '') if label is '': label = self.get_default_label(tx_hash) return label 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 get_tx_status(self, tx_hash, height, conf, timestamp): from .util import format_time extra = [] if conf == 0: tx = self.transactions.get(tx_hash) if not tx: return 2, 'unknown' fee = self.get_wallet_delta(tx)[3] if fee is None: fee = self.tx_fees.get(tx_hash) if fee is not None: size = tx.estimated_size() fee_per_kb = round(fee * 1000 / size) extra.append('%s sat/kB'%(fee_per_kb)) if fee is not None and height in (TX_HEIGHT_UNCONF_PARENT, TX_HEIGHT_UNCONFIRMED) \ and self.network and self.network.config.has_fee_mempool(): exp_n = self.network.config.fee_to_depth(fee_per_kb) if exp_n: extra.append('%.2f MB'%(exp_n/1000000)) if height == TX_HEIGHT_LOCAL: status = 3 elif height == TX_HEIGHT_UNCONF_PARENT: status = 1 elif height == TX_HEIGHT_UNCONFIRMED: status = 0 else: status = 2 else: status = 3 + min(conf, 6) time_str = format_time(timestamp) if timestamp else _("unknown") status_str = TX_STATUS[status] if status < 4 else time_str if extra: status_str += ' [%s]'%(', '.join(extra)) return status, status_str def relayfee(self): return relayfee(self.network) def dust_threshold(self): return dust_threshold(self.network) def make_unsigned_transaction(self, inputs, outputs, config, fixed_fee=None, change_addr=None, is_sweep=False): # check outputs i_max = None for i, o in enumerate(outputs): _type, data, value = o if _type == TYPE_ADDRESS: if not is_address(data): raise Exception("Invalid bitcoinprivate address: {}".format(data)) if value == '!': if i_max is not None: raise Exception("More than one output set to spend max") i_max = i # Avoid index-out-of-range with inputs[0] below if not inputs: raise NotEnoughFunds() if fixed_fee is None and config.fee_per_kb() is None: raise NoDynamicFeeEstimates() if not is_sweep: for item in inputs: self.add_input_info(item) # change address if change_addr: change_addrs = [change_addr] else: addrs = self.get_change_addresses()[-self.gap_limit_for_change:] if self.use_change and addrs: # New change addresses are created only after a few # confirmations. Select the unused addresses within the # gap limit; if none take one at random change_addrs = [addr for addr in addrs if self.get_num_tx(addr) == 0] if not change_addrs: change_addrs = [random.choice(addrs)] else: # coin_chooser will set change address change_addrs = [] # Fee estimator if fixed_fee is None: fee_estimator = config.estimate_fee elif isinstance(fixed_fee, Number): fee_estimator = lambda size: fixed_fee elif callable(fixed_fee): fee_estimator = fixed_fee else: raise Exception('Invalid argument fixed_fee: %s' % fixed_fee) if i_max is None: # Let the coin chooser select the coins to spend max_change = self.max_change_outputs if self.multiple_change else 1 coin_chooser = coinchooser.get_coin_chooser(config) tx = coin_chooser.make_tx(inputs, outputs, change_addrs[:max_change], fee_estimator, self.dust_threshold()) else: # FIXME?? this might spend inputs with negative effective value... sendable = sum(map(lambda x:x['value'], inputs)) _type, data, value = outputs[i_max] outputs[i_max] = (_type, data, 0) tx = Transaction.from_io(inputs, outputs[:]) fee = fee_estimator(tx.estimated_size()) amount = max(0, sendable - tx.output_value() - fee) outputs[i_max] = (_type, data, amount) tx = Transaction.from_io(inputs, outputs[:]) # Sort the inputs and outputs deterministically tx.BIP_LI01_sort() # Timelock tx to current height. tx.locktime = self.get_local_height() 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, config) tx = self.make_unsigned_transaction(coins, outputs, config, fee, change_addr) self.sign_transaction(tx, password) return tx 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)) return True return False def load_unverified_transactions(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) def start_threads(self, network): self.network = network if self.network is not None: 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.release() self.synchronizer = None self.verifier = None # Now no references to the synchronizer or verifier # remain so they will be GC-ed self.storage.put('stored_height', self.get_local_height()) self.save_transactions() self.storage.put('verified_tx3', self.verified_tx) self.storage.write() def wait_until_synchronized(self, callback=None): def wait_for_wallet(): self.set_up_to_date(False) while not self.is_up_to_date(): if callback: msg = "%s\n%s %d"%( _("Please wait..."), _("Addresses generated:"), len(self.addresses(True))) callback(msg) time.sleep(0.1) def wait_for_network(): while not self.network.is_connected(): if callback: msg = "%s \n" % (_("Connecting...")) 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 can_export(self): return not self.is_watching_only() and hasattr(self.keystore, 'get_private_key') def is_used(self, address): h = self.history.get(address,[]) if len(h) == 0: return False c, u, x = self.get_addr_balance(address) return 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 add_input_info(self, txin): address = txin['address'] if self.is_mine(address): txin['type'] = self.get_txin_type(address) self.add_input_sig_info(txin, address) def can_sign(self, tx): if tx.is_complete(): return False for k in self.get_keystores(): if k.can_sign(tx): return True return False def get_input_tx(self, tx_hash): # First look up an input transaction in the wallet where it # will likely be. If co-signing a transaction it may not have # all the input txs, in which case we ask the network. tx = self.transactions.get(tx_hash, None) if not tx and self.network: request = ('blockchain.transaction.get', [tx_hash]) try: tx = Transaction(self.network.synchronous_get(request)) except TimeoutException as e: self.print_error('getting input txn from network timed out for {}'.format(tx_hash)) raise e return tx def add_hw_info(self, tx): # add previous tx for hw wallets for txin in tx.inputs(): tx_hash = txin['prevout_hash'] txin['prev_tx'] = self.get_input_tx(tx_hash) # add output info for hw wallets info = {} xpubs = self.get_master_public_keys() for txout in tx.outputs(): _type, addr, amount = txout if self.is_mine(addr): index = self.get_address_index(addr) pubkeys = self.get_public_keys(addr) # sort xpubs using the order of pubkeys sorted_pubkeys, sorted_xpubs = zip(*sorted(zip(pubkeys, xpubs))) info[addr] = index, sorted_xpubs, self.m if isinstance(self, Multisig_Wallet) else None tx.output_info = info def sign_transaction(self, tx, password): if self.is_watching_only(): return # hardware wallets require extra info if any([(isinstance(k, Hardware_KeyStore) and k.can_sign(tx)) for k in self.get_keystores()]): self.add_hw_info(tx) # sign. start with ready keystores. for k in sorted(self.get_keystores(), key=lambda ks: ks.ready_to_sign(), reverse=True): try: if k.can_sign(tx): k.sign_transaction(tx, password) except UserCancelled: continue def get_unused_addresses(self): # fixme: use slots from expired requests domain = self.get_receiving_addresses() return [addr for addr in domain if not self.history.get(addr) and addr not in self.receive_requests.keys()] def get_unused_address(self): addrs = self.get_unused_addresses() if addrs: return addrs[0] def get_receiving_address(self): # always return an address domain = self.get_receiving_addresses() if not domain: return choice = domain[0] for addr in domain: if not self.history.get(addr): if addr not in self.receive_requests.keys(): return addr else: choice = addr return choice def get_payment_status(self, address, amount): local_height = self.get_local_height() received, sent = self.get_addr_io(address) l = [] for txo, x in received.items(): h, v, is_cb = x txid, n = txo.split(':') info = self.verified_tx.get(txid) if info: tx_height, timestamp, pos = info conf = local_height - tx_height else: conf = 0 l.append((conf, v)) vsum = 0 for conf, v in reversed(sorted(l)): vsum += v if vsum >= amount: return True, conf return False, None def get_payment_request(self, addr, config): r = self.receive_requests.get(addr) if not r: return out = copy.copy(r) out['URI'] = 'bitcoinprivate:' + addr + '?amount=' + format_satoshis(out.get('amount')) status, conf = self.get_request_status(addr) out['status'] = status if conf is not None: out['confirmations'] = conf # check if bip70 file exists rdir = config.get('requests_dir') if rdir: key = out.get('id', addr) path = os.path.join(rdir, 'req', key[0], key[1], key) if os.path.exists(path): baseurl = 'file://' + rdir rewrite = config.get('url_rewrite') if rewrite: try: baseurl = baseurl.replace(*rewrite) except BaseException as e: self.print_stderr('Invalid config setting for "url_rewrite". err:', e) out['request_url'] = os.path.join(baseurl, 'req', key[0], key[1], key, key) out['URI'] += '&r=' + out['request_url'] out['index_url'] = os.path.join(baseurl, 'index.html') + '?id=' + key websocket_server_announce = config.get('websocket_server_announce') if websocket_server_announce: out['websocket_server'] = websocket_server_announce else: out['websocket_server'] = config.get('websocket_server', 'localhost') websocket_port_announce = config.get('websocket_port_announce') if websocket_port_announce: out['websocket_port'] = websocket_port_announce else: out['websocket_port'] = config.get('websocket_port', 9999) return out def get_request_status(self, key): r = self.receive_requests.get(key) if r is None: return PR_UNKNOWN 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 conf = None if amount: if self.up_to_date: paid, conf = self.get_payment_status(address, amount) 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, conf def make_payment_request(self, addr, amount, message, expiration): timestamp = int(time.time()) _id = bh2u(Hash(addr + "%d"%timestamp))[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.export_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'] = bh2u(pr.signature) self.receive_requests[key] = req self.storage.put('payment_requests', self.receive_requests) def add_payment_request(self, req, config): addr = req['address'] if not bitcoin.is_address(addr): raise Exception(_('Invalid bitcoinprivate address.')) if not self.is_mine(addr): raise Exception(_('Address not in wallet.')) 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, 'req', key[0], key[1], key) if not os.path.exists(path): try: os.makedirs(path) except OSError as exc: if exc.errno != errno.EEXIST: raise with open(os.path.join(path, key), 'wb') as f: f.write(pr.SerializeToString()) # reload req = self.get_payment_request(addr, config) with open(os.path.join(path, key + '.json'), 'w', encoding='utf-8') 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, 'req', key[0], key[1], key, 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): def f(addr): try: return self.get_address_index(addr) except: return keys = map(lambda x: (f(x), x), self.receive_requests.keys()) sorted_keys = sorted(filter(lambda x: x[0] is not None, keys)) return [self.get_payment_request(x[1], config) for x in sorted_keys] def get_fingerprint(self): raise NotImplementedError() def can_import_privkey(self): return False def can_import_address(self): return False def can_delete_address(self): return False def add_address(self, address): if address not in self.history: self.history[address] = [] if self.synchronizer: self.synchronizer.add(address) def has_password(self): return self.has_keystore_encryption() or self.has_storage_encryption() def can_have_keystore_encryption(self): return self.keystore and self.keystore.may_have_password() def get_available_storage_encryption_version(self): """Returns the type of storage encryption offered to the user. A wallet file (storage) is either encrypted with this version or is stored in plaintext. """ if isinstance(self.keystore, Hardware_KeyStore): return STO_EV_XPUB_PW else: return STO_EV_USER_PW def has_keystore_encryption(self): """Returns whether encryption is enabled for the keystore. If True, e.g. signing a transaction will require a password. """ if self.can_have_keystore_encryption(): return self.storage.get('use_encryption', False) return False def has_storage_encryption(self): """Returns whether encryption is enabled for the wallet file on disk.""" return self.storage.is_encrypted() @classmethod def may_have_password(cls): return True def check_password(self, password): if self.has_keystore_encryption(): self.keystore.check_password(password) self.storage.check_password(password) def update_password(self, old_pw, new_pw, encrypt_storage=False): if old_pw is None and self.has_password(): raise InvalidPassword() self.check_password(old_pw) if encrypt_storage: enc_version = self.get_available_storage_encryption_version() else: enc_version = STO_EV_PLAINTEXT self.storage.set_password(new_pw, enc_version) # note: Encrypting storage with a hw device is currently only # allowed for non-multisig wallets. Further, # Hardware_KeyStore.may_have_password() == False. # If these were not the case, # extra care would need to be taken when encrypting keystores. self._update_password_for_keystore(old_pw, new_pw) encrypt_keystore = self.can_have_keystore_encryption() self.storage.set_keystore_encryption(bool(new_pw) and encrypt_keystore) self.storage.write() def sign_message(self, address, message, password): index = self.get_address_index(address) return self.keystore.sign_message(index, message, password) def decrypt_message(self, pubkey, message, password): addr = self.pubkeys_to_address(pubkey) index = self.get_address_index(addr) return self.keystore.decrypt_message(index, message, password) def get_depending_transactions(self, tx_hash): """Returns all (grand-)children of tx_hash in this wallet.""" children = set() for other_hash, tx in self.transactions.items(): for input in (tx.inputs()): if input["prevout_hash"] == tx_hash: children.add(other_hash) children |= self.get_depending_transactions(other_hash) return children def txin_value(self, txin): txid = txin['prevout_hash'] prev_n = txin['prevout_n'] for address, d in self.txo.get(txid, {}).items(): for n, v, cb in d: if n == prev_n: return v # may occur if wallet is not synchronized return None def price_at_timestamp(self, txid, price_func): """Returns fiat price of bitcoin at the time tx got confirmed.""" height, conf, timestamp = self.get_tx_height(txid) return price_func(timestamp if timestamp else time.time()) def unrealized_gains(self, domain, price_func, ccy): coins = self.get_utxos(domain) now = time.time() p = price_func(now) ap = sum(self.coin_price(coin['prevout_hash'], price_func, ccy, self.txin_value(coin)) for coin in coins) lp = sum([coin['value'] for coin in coins]) * p / Decimal(COIN) return lp - ap def average_price(self, txid, price_func, ccy): """ Average acquisition price of the inputs of a transaction """ input_value = 0 total_price = 0 for addr, d in self.txi.get(txid, {}).items(): for ser, v in d: input_value += v total_price += self.coin_price(ser.split(':')[0], price_func, ccy, v) return total_price / (input_value/Decimal(COIN)) def coin_price(self, txid, price_func, ccy, txin_value): """ Acquisition price of a coin. This assumes that either all inputs are mine, or no input is mine. """ if txin_value is None: return Decimal('NaN') cache_key = "{}:{}:{}".format(str(txid), str(ccy), str(txin_value)) result = self.coin_price_cache.get(cache_key, None) if result is not None: return result if self.txi.get(txid, {}) != {}: result = self.average_price(txid, price_func, ccy) * txin_value/Decimal(COIN) self.coin_price_cache[cache_key] = result return result else: fiat_value = self.get_fiat_value(txid, ccy) if fiat_value is not None: return fiat_value else: p = self.price_at_timestamp(txid, price_func) return p * txin_value/Decimal(COIN) class Simple_Wallet(Abstract_Wallet): # wallet with a single keystore def get_keystore(self): return self.keystore def get_keystores(self): return [self.keystore] def is_watching_only(self): return self.keystore.is_watching_only() def _update_password_for_keystore(self, old_pw, new_pw): if self.keystore and self.keystore.may_have_password(): self.keystore.update_password(old_pw, new_pw) self.save_keystore() def save_keystore(self): self.storage.put('keystore', self.keystore.dump()) class Imported_Wallet(Simple_Wallet): # wallet made of imported addresses wallet_type = 'imported' txin_type = 'address' def __init__(self, storage): Abstract_Wallet.__init__(self, storage) def is_watching_only(self): return self.keystore is None def get_keystores(self): return [self.keystore] if self.keystore else [] def can_import_privkey(self): return bool(self.keystore) def load_keystore(self): self.keystore = load_keystore(self.storage, 'keystore') if self.storage.get('keystore') else None def save_keystore(self): self.storage.put('keystore', self.keystore.dump()) def load_addresses(self): self.addresses = self.storage.get('addresses', {}) # fixme: a reference to addresses is needed if self.keystore: self.keystore.addresses = self.addresses def save_addresses(self): self.storage.put('addresses', self.addresses) def can_import_address(self): return self.is_watching_only() def can_delete_address(self): return True def has_seed(self): return False def is_deterministic(self): return False def is_change(self, address): return False def get_master_public_keys(self): return [] def is_beyond_limit(self, address): return False def is_mine(self, address): return address in self.addresses def get_fingerprint(self): return '' def get_addresses(self, include_change=False): return sorted(self.addresses.keys()) def get_receiving_addresses(self): return self.get_addresses() def get_change_addresses(self): return [] def import_address(self, address): if not bitcoin.is_address(address): return '' if address in self.addresses: return '' self.addresses[address] = {} self.storage.put('addresses', self.addresses) self.storage.write() self.add_address(address) return address def delete_address(self, address): if address not in self.addresses: return transactions_to_remove = set() # only referred to by this address transactions_new = set() # txs that are not only referred to by address with self.lock: for addr, details in self.history.items(): if addr == address: for tx_hash, height in details: transactions_to_remove.add(tx_hash) else: for tx_hash, height in details: transactions_new.add(tx_hash) transactions_to_remove -= transactions_new self.history.pop(address, None) for tx_hash in transactions_to_remove: self.remove_transaction(tx_hash) self.tx_fees.pop(tx_hash, None) self.verified_tx.pop(tx_hash, None) self.unverified_tx.pop(tx_hash, None) self.transactions.pop(tx_hash, None) # FIXME: what about pruned_txo? self.storage.put('verified_tx3', self.verified_tx) self.save_transactions() self.set_label(address, None) self.remove_payment_request(address, {}) self.set_frozen_state([address], False) pubkey = self.get_public_key(address) self.addresses.pop(address) if pubkey: # delete key iff no other address uses it (e.g. p2pkh and p2wpkh for same key) for txin_type in bitcoin.SCRIPT_TYPES.keys(): try: addr2 = bitcoin.pubkey_to_address(txin_type, pubkey) except NotImplementedError: pass else: if addr2 in self.addresses: break else: self.keystore.delete_imported_key(pubkey) self.save_keystore() self.storage.put('addresses', self.addresses) self.storage.write() def get_address_index(self, address): return self.get_public_key(address) def get_public_key(self, address): return self.addresses[address].get('pubkey') def import_private_key(self, sec, pw, redeem_script=None): try: txin_type, pubkey = self.keystore.import_privkey(sec, pw) except Exception: neutered_privkey = str(sec)[:3] + '..' + str(sec)[-2:] raise BitcoinException('Invalid private key: {}'.format(neutered_privkey)) if txin_type in ['p2pkh']: if redeem_script is not None: raise BitcoinException('Cannot use redeem script with script type {}'.format(txin_type)) addr = bitcoin.pubkey_to_address(txin_type, pubkey) elif txin_type in ['p2sh']: if redeem_script is None: raise BitcoinException('Redeem script required for script type {}'.format(txin_type)) addr = bitcoin.redeem_script_to_address(txin_type, redeem_script) else: raise NotImplementedError(txin_type) self.addresses[addr] = {'type':txin_type, 'pubkey':pubkey, 'redeem_script':redeem_script} self.save_keystore() self.save_addresses() self.storage.write() self.add_address(addr) return addr def get_redeem_script(self, address): d = self.addresses[address] redeem_script = d['redeem_script'] return redeem_script def get_txin_type(self, address): return self.addresses[address].get('type', 'address') def add_input_sig_info(self, txin, address): if self.is_watching_only(): x_pubkey = 'fd' + address_to_script(address) txin['x_pubkeys'] = [x_pubkey] txin['signatures'] = [None] return if txin['type'] in ['p2pkh']: pubkey = self.addresses[address]['pubkey'] txin['num_sig'] = 1 txin['x_pubkeys'] = [pubkey] txin['signatures'] = [None] else: redeem_script = self.addresses[address]['redeem_script'] num_sig = 2 num_keys = 3 txin['num_sig'] = num_sig txin['redeem_script'] = redeem_script txin['signatures'] = [None] * num_keys def pubkeys_to_address(self, pubkey): for addr, v in self.addresses.items(): if v.get('pubkey') == pubkey: return addr class Deterministic_Wallet(Abstract_Wallet): def __init__(self, storage): Abstract_Wallet.__init__(self, storage) self.gap_limit = storage.get('gap_limit', 20) def has_seed(self): return self.keystore.has_seed() def get_receiving_addresses(self): return self.receiving_addresses def get_change_addresses(self): return self.change_addresses def get_seed(self, password): return self.keystore.get_seed(password) def add_seed(self, seed, pw): self.keystore.add_seed(seed, pw) def change_gap_limit(self, value): '''This method is not called in the code, it is kept for console use''' if value >= self.gap_limit: self.gap_limit = value self.storage.put('gap_limit', self.gap_limit) return True elif value >= self.min_acceptable_gap(): addresses = self.get_receiving_addresses() k = self.num_unused_trailing_addresses(addresses) n = len(addresses) - k + value self.receiving_addresses = self.receiving_addresses[0:n] self.gap_limit = value self.storage.put('gap_limit', self.gap_limit) self.save_addresses() 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 addresses = self.get_receiving_addresses() 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 load_addresses(self): super().load_addresses() self._addr_to_addr_index = {} # key: address, value: (is_change, index) for i, addr in enumerate(self.receiving_addresses): self._addr_to_addr_index[addr] = (False, i) for i, addr in enumerate(self.change_addresses): self._addr_to_addr_index[addr] = (True, i) def create_new_address(self, for_change=False): assert type(for_change) is bool with self.lock: addr_list = self.change_addresses if for_change else self.receiving_addresses n = len(addr_list) x = self.derive_pubkeys(for_change, n) address = self.pubkeys_to_address(x) addr_list.append(address) self._addr_to_addr_index[address] = (for_change, n) self.save_addresses() self.add_address(address) return address def synchronize_sequence(self, for_change): limit = self.gap_limit_for_change if for_change else self.gap_limit while True: addresses = self.get_change_addresses() if for_change else self.get_receiving_addresses() if len(addresses) < limit: self.create_new_address(for_change) continue if list(map(lambda a: self.address_is_old(a), addresses[-limit:] )) == limit*[False]: break else: self.create_new_address(for_change) def synchronize(self): with self.lock: self.synchronize_sequence(False) self.synchronize_sequence(True) def is_beyond_limit(self, address): is_change, i = self.get_address_index(address) addr_list = self.get_change_addresses() if is_change else self.get_receiving_addresses() limit = self.gap_limit_for_change if is_change else self.gap_limit if i < limit: return False prev_addresses = addr_list[max(0, i - limit):max(0, i)] for addr in prev_addresses: if self.history.get(addr): return False return True def is_mine(self, address): return address in self._addr_to_addr_index def get_address_index(self, address): return self._addr_to_addr_index[address] def get_master_public_keys(self): return [self.get_master_public_key()] def get_fingerprint(self): return self.get_master_public_key() def get_txin_type(self, address): return self.txin_type class Simple_Deterministic_Wallet(Simple_Wallet, Deterministic_Wallet): """ Deterministic Wallet with a single pubkey per address """ def __init__(self, storage): Deterministic_Wallet.__init__(self, storage) def get_public_key(self, address): sequence = self.get_address_index(address) pubkey = self.get_pubkey(*sequence) return pubkey def load_keystore(self): self.keystore = load_keystore(self.storage, 'keystore') try: xtype = bitcoin.xpub_type(self.keystore.xpub) except: xtype = 'standard' self.txin_type = 'p2pkh' if xtype == 'standard' else xtype def get_pubkey(self, c, i): return self.derive_pubkeys(c, i) def add_input_sig_info(self, txin, address): derivation = self.get_address_index(address) x_pubkey = self.keystore.get_xpubkey(*derivation) txin['x_pubkeys'] = [x_pubkey] txin['signatures'] = [None] txin['num_sig'] = 1 def get_master_public_key(self): return self.keystore.get_master_public_key() def derive_pubkeys(self, c, i): return self.keystore.derive_pubkey(c, i) class Standard_Wallet(Simple_Deterministic_Wallet): wallet_type = 'standard' def pubkeys_to_address(self, pubkey): return bitcoin.pubkey_to_address(self.txin_type, pubkey) class Multisig_Wallet(Deterministic_Wallet): # generic m of n gap_limit = 20 def __init__(self, storage): self.wallet_type = storage.get('wallet_type') self.m, self.n = multisig_type(self.wallet_type) Deterministic_Wallet.__init__(self, storage) def get_pubkeys(self, c, i): return self.derive_pubkeys(c, i) def get_public_keys(self, address): sequence = self.get_address_index(address) return self.get_pubkeys(*sequence) def pubkeys_to_address(self, pubkeys): redeem_script = self.pubkeys_to_redeem_script(pubkeys) return bitcoin.redeem_script_to_address(self.txin_type, redeem_script) def pubkeys_to_redeem_script(self, pubkeys): return transaction.multisig_script(sorted(pubkeys), self.m) def get_redeem_script(self, address): pubkeys = self.get_public_keys(address) redeem_script = self.pubkeys_to_redeem_script(pubkeys) return redeem_script def derive_pubkeys(self, c, i): return [k.derive_pubkey(c, i) for k in self.get_keystores()] def load_keystore(self): self.keystores = {} for i in range(self.n): name = 'x%d/'%(i+1) self.keystores[name] = load_keystore(self.storage, name) self.keystore = self.keystores['x1/'] xtype = bitcoin.xpub_type(self.keystore.xpub) self.txin_type = 'p2sh' if xtype == 'standard' else xtype def save_keystore(self): for name, k in self.keystores.items(): self.storage.put(name, k.dump()) def get_keystore(self): return self.keystores.get('x1/') def get_keystores(self): return [self.keystores[i] for i in sorted(self.keystores.keys())] def can_have_keystore_encryption(self): return any([k.may_have_password() for k in self.get_keystores()]) def _update_password_for_keystore(self, old_pw, new_pw): for name, keystore in self.keystores.items(): if keystore.may_have_password(): keystore.update_password(old_pw, new_pw) self.storage.put(name, keystore.dump()) def check_password(self, password): for name, keystore in self.keystores.items(): if keystore.may_have_password(): keystore.check_password(password) self.storage.check_password(password) def get_available_storage_encryption_version(self): # multisig wallets are not offered hw device encryption return STO_EV_USER_PW def has_seed(self): return self.keystore.has_seed() def is_watching_only(self): return not any([not k.is_watching_only() for k in self.get_keystores()]) def get_master_public_key(self): return self.keystore.get_master_public_key() def get_master_public_keys(self): return [k.get_master_public_key() for k in self.get_keystores()] def get_fingerprint(self): return ''.join(sorted(self.get_master_public_keys())) def add_input_sig_info(self, txin, address): # x_pubkeys are not sorted here because it would be too slow # they are sorted in transaction.get_sorted_pubkeys # pubkeys is set to None to signal that x_pubkeys are unsorted derivation = self.get_address_index(address) txin['x_pubkeys'] = [k.get_xpubkey(*derivation) for k in self.get_keystores()] txin['pubkeys'] = None # we need n place holders txin['signatures'] = [None] * self.n txin['num_sig'] = self.m wallet_types = ['standard', 'multisig', 'imported'] def register_wallet_type(category): wallet_types.append(category) wallet_constructors = { 'standard': Standard_Wallet, 'old': Standard_Wallet, 'xpub': Standard_Wallet, 'imported': Imported_Wallet } def register_constructor(wallet_type, constructor): wallet_constructors[wallet_type] = constructor # 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): wallet_type = storage.get('wallet_type') WalletClass = Wallet.wallet_class(wallet_type) wallet = WalletClass(storage) # Convert hardware wallets restored with older versions of # Electrum to BIP44 wallets. A hardware wallet does not have # a seed and plugins do not need to handle having one. rwc = getattr(wallet, 'restore_wallet_class', None) if rwc and storage.get('seed', ''): storage.print_error("converting wallet type to " + rwc.wallet_type) storage.put('wallet_type', rwc.wallet_type) wallet = rwc(storage) return wallet @staticmethod def wallet_class(wallet_type): if multisig_type(wallet_type): return Multisig_Wallet if wallet_type in wallet_constructors: return wallet_constructors[wallet_type] raise RuntimeError("Unknown wallet type: " + str(wallet_type))