#!/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/>.
# Note: The deserialization code originally comes from ABE.
import bitcoin
from bitcoin import *
from util import print_error
import time
import struct
#
# Workalike python implementation of Bitcoin's CDataStream class.
#
import struct
import StringIO
import mmap
NO_SIGNATURE = 'ff'
class SerializationError(Exception):
""" Thrown when there's a problem deserializing or serializing """
class BCDataStream(object):
def __init__(self):
self.input = None
self.read_cursor = 0
def clear(self):
self.input = None
self.read_cursor = 0
def write(self, bytes): # Initialize with string of bytes
if self.input is None:
self.input = bytes
else:
self.input += bytes
def map_file(self, file, start): # Initialize with bytes from file
self.input = mmap.mmap(file.fileno(), 0, access=mmap.ACCESS_READ)
self.read_cursor = start
def seek_file(self, position):
self.read_cursor = position
def close_file(self):
self.input.close()
def read_string(self):
# Strings are encoded depending on length:
# 0 to 252 : 1-byte-length followed by bytes (if any)
# 253 to 65,535 : byte'253' 2-byte-length followed by bytes
# 65,536 to 4,294,967,295 : byte '254' 4-byte-length followed by bytes
# ... and the Bitcoin client is coded to understand:
# greater than 4,294,967,295 : byte '255' 8-byte-length followed by bytes of string
# ... but I don't think it actually handles any strings that big.
if self.input is None:
raise SerializationError("call write(bytes) before trying to deserialize")
try:
length = self.read_compact_size()
except IndexError:
raise SerializationError("attempt to read past end of buffer")
return self.read_bytes(length)
def write_string(self, string):
# Length-encoded as with read-string
self.write_compact_size(len(string))
self.write(string)
def read_bytes(self, length):
try:
result = self.input[self.read_cursor:self.read_cursor+length]
self.read_cursor += length
return result
except IndexError:
raise SerializationError("attempt to read past end of buffer")
return ''
def read_boolean(self): return self.read_bytes(1)[0] != chr(0)
def read_int16(self): return self._read_num('<h')
def read_uint16(self): return self._read_num('<H')
def read_int32(self): return self._read_num('<i')
def read_uint32(self): return self._read_num('<I')
def read_int64(self): return self._read_num('<q')
def read_uint64(self): return self._read_num('<Q')
def write_boolean(self, val): return self.write(chr(1) if val else chr(0))
def write_int16(self, val): return self._write_num('<h', val)
def write_uint16(self, val): return self._write_num('<H', val)
def write_int32(self, val): return self._write_num('<i', val)
def write_uint32(self, val): return self._write_num('<I', val)
def write_int64(self, val): return self._write_num('<q', val)
def write_uint64(self, val): return self._write_num('<Q', val)
def read_compact_size(self):
size = ord(self.input[self.read_cursor])
self.read_cursor += 1
if size == 253:
size = self._read_num('<H')
elif size == 254:
size = self._read_num('<I')
elif size == 255:
size = self._read_num('<Q')
return size
def write_compact_size(self, size):
if size < 0:
raise SerializationError("attempt to write size < 0")
elif size < 253:
self.write(chr(size))
elif size < 2**16:
self.write('\xfd')
self._write_num('<H', size)
elif size < 2**32:
self.write('\xfe')
self._write_num('<I', size)
elif size < 2**64:
self.write('\xff')
self._write_num('<Q', size)
def _read_num(self, format):
(i,) = struct.unpack_from(format, self.input, self.read_cursor)
self.read_cursor += struct.calcsize(format)
return i
def _write_num(self, format, num):
s = struct.pack(format, num)
self.write(s)
#
# enum-like type
# From the Python Cookbook, downloaded from http://code.activestate.com/recipes/67107/
#
import types, string, exceptions
class EnumException(exceptions.Exception):
pass
class Enumeration:
def __init__(self, name, enumList):
self.__doc__ = name
lookup = { }
reverseLookup = { }
i = 0
uniqueNames = [ ]
uniqueValues = [ ]
for x in enumList:
if type(x) == types.TupleType:
x, i = x
if type(x) != types.StringType:
raise EnumException, "enum name is not a string: " + x
if type(i) != types.IntType:
raise EnumException, "enum value is not an integer: " + i
if x in uniqueNames:
raise EnumException, "enum name is not unique: " + x
if i in uniqueValues:
raise EnumException, "enum value is not unique for " + x
uniqueNames.append(x)
uniqueValues.append(i)
lookup[x] = i
reverseLookup[i] = x
i = i + 1
self.lookup = lookup
self.reverseLookup = reverseLookup
def __getattr__(self, attr):
if not self.lookup.has_key(attr):
raise AttributeError
return self.lookup[attr]
def whatis(self, value):
return self.reverseLookup[value]
# This function comes from bitcointools, bct-LICENSE.txt.
def long_hex(bytes):
return bytes.encode('hex_codec')
# This function comes from bitcointools, bct-LICENSE.txt.
def short_hex(bytes):
t = bytes.encode('hex_codec')
if len(t) < 11:
return t
return t[0:4]+"..."+t[-4:]
def parse_redeemScript(bytes):
dec = [ x for x in script_GetOp(bytes.decode('hex')) ]
# 2 of 2
match = [ opcodes.OP_2, opcodes.OP_PUSHDATA4, opcodes.OP_PUSHDATA4, opcodes.OP_2, opcodes.OP_CHECKMULTISIG ]
if match_decoded(dec, match):
pubkeys = [ dec[1][1].encode('hex'), dec[2][1].encode('hex') ]
return 2, pubkeys
# 2 of 3
match = [ opcodes.OP_2, opcodes.OP_PUSHDATA4, opcodes.OP_PUSHDATA4, opcodes.OP_PUSHDATA4, opcodes.OP_3, opcodes.OP_CHECKMULTISIG ]
if match_decoded(dec, match):
pubkeys = [ dec[1][1].encode('hex'), dec[2][1].encode('hex'), dec[3][1].encode('hex') ]
return 2, pubkeys
opcodes = Enumeration("Opcodes", [
("OP_0", 0), ("OP_PUSHDATA1",76), "OP_PUSHDATA2", "OP_PUSHDATA4", "OP_1NEGATE", "OP_RESERVED",
"OP_1", "OP_2", "OP_3", "OP_4", "OP_5", "OP_6", "OP_7",
"OP_8", "OP_9", "OP_10", "OP_11", "OP_12", "OP_13", "OP_14", "OP_15", "OP_16",
"OP_NOP", "OP_VER", "OP_IF", "OP_NOTIF", "OP_VERIF", "OP_VERNOTIF", "OP_ELSE", "OP_ENDIF", "OP_VERIFY",
"OP_RETURN", "OP_TOALTSTACK", "OP_FROMALTSTACK", "OP_2DROP", "OP_2DUP", "OP_3DUP", "OP_2OVER", "OP_2ROT", "OP_2SWAP",
"OP_IFDUP", "OP_DEPTH", "OP_DROP", "OP_DUP", "OP_NIP", "OP_OVER", "OP_PICK", "OP_ROLL", "OP_ROT",
"OP_SWAP", "OP_TUCK", "OP_CAT", "OP_SUBSTR", "OP_LEFT", "OP_RIGHT", "OP_SIZE", "OP_INVERT", "OP_AND",
"OP_OR", "OP_XOR", "OP_EQUAL", "OP_EQUALVERIFY", "OP_RESERVED1", "OP_RESERVED2", "OP_1ADD", "OP_1SUB", "OP_2MUL",
"OP_2DIV", "OP_NEGATE", "OP_ABS", "OP_NOT", "OP_0NOTEQUAL", "OP_ADD", "OP_SUB", "OP_MUL", "OP_DIV",
"OP_MOD", "OP_LSHIFT", "OP_RSHIFT", "OP_BOOLAND", "OP_BOOLOR",
"OP_NUMEQUAL", "OP_NUMEQUALVERIFY", "OP_NUMNOTEQUAL", "OP_LESSTHAN",
"OP_GREATERTHAN", "OP_LESSTHANOREQUAL", "OP_GREATERTHANOREQUAL", "OP_MIN", "OP_MAX",
"OP_WITHIN", "OP_RIPEMD160", "OP_SHA1", "OP_SHA256", "OP_HASH160",
"OP_HASH256", "OP_CODESEPARATOR", "OP_CHECKSIG", "OP_CHECKSIGVERIFY", "OP_CHECKMULTISIG",
"OP_CHECKMULTISIGVERIFY",
("OP_SINGLEBYTE_END", 0xF0),
("OP_DOUBLEBYTE_BEGIN", 0xF000),
"OP_PUBKEY", "OP_PUBKEYHASH",
("OP_INVALIDOPCODE", 0xFFFF),
])
def script_GetOp(bytes):
i = 0
while i < len(bytes):
vch = None
opcode = ord(bytes[i])
i += 1
if opcode >= opcodes.OP_SINGLEBYTE_END:
opcode <<= 8
opcode |= ord(bytes[i])
i += 1
if opcode <= opcodes.OP_PUSHDATA4:
nSize = opcode
if opcode == opcodes.OP_PUSHDATA1:
nSize = ord(bytes[i])
i += 1
elif opcode == opcodes.OP_PUSHDATA2:
(nSize,) = struct.unpack_from('<H', bytes, i)
i += 2
elif opcode == opcodes.OP_PUSHDATA4:
(nSize,) = struct.unpack_from('<I', bytes, i)
i += 4
vch = bytes[i:i+nSize]
i += nSize
yield (opcode, vch, i)
def script_GetOpName(opcode):
return (opcodes.whatis(opcode)).replace("OP_", "")
def decode_script(bytes):
result = ''
for (opcode, vch, i) in script_GetOp(bytes):
if len(result) > 0: result += " "
if opcode <= opcodes.OP_PUSHDATA4:
result += "%d:"%(opcode,)
result += short_hex(vch)
else:
result += script_GetOpName(opcode)
return result
def match_decoded(decoded, to_match):
if len(decoded) != len(to_match):
return False;
for i in range(len(decoded)):
if to_match[i] == opcodes.OP_PUSHDATA4 and decoded[i][0] <= opcodes.OP_PUSHDATA4 and decoded[i][0]>0:
continue # Opcodes below OP_PUSHDATA4 all just push data onto stack, and are equivalent.
if to_match[i] != decoded[i][0]:
return False
return True
def parse_sig(x_sig):
s = []
for sig in x_sig:
if sig[-2:] == '01':
s.append(sig[:-2])
else:
assert sig == NO_SIGNATURE
s.append(None)
return s
def is_extended_pubkey(x_pubkey):
return x_pubkey[0:2] in ['fe', 'ff']
def x_to_xpub(x_pubkey):
if x_pubkey[0:2] == 'ff':
from account import BIP32_Account
xpub, s = BIP32_Account.parse_xpubkey(x_pubkey)
return xpub
def parse_xpub(x_pubkey):
if x_pubkey[0:2] == 'ff':
from account import BIP32_Account
xpub, s = BIP32_Account.parse_xpubkey(x_pubkey)
pubkey = BIP32_Account.derive_pubkey_from_xpub(xpub, s[0], s[1])
elif x_pubkey[0:2] == 'fe':
from account import OldAccount
mpk, s = OldAccount.parse_xpubkey(x_pubkey)
pubkey = OldAccount.get_pubkey_from_mpk(mpk.decode('hex'), s[0], s[1])
else:
pubkey = x_pubkey
return pubkey
def parse_scriptSig(d, bytes):
try:
decoded = [ x for x in script_GetOp(bytes) ]
except Exception:
# coinbase transactions raise an exception
print_error("cannot find address in input script", bytes.encode('hex'))
return
# payto_pubkey
match = [ opcodes.OP_PUSHDATA4 ]
if match_decoded(decoded, match):
sig = decoded[0][1].encode('hex')
d['address'] = "(pubkey)"
d['signatures'] = [sig]
d['num_sig'] = 1
d['x_pubkeys'] = ["(pubkey)"]
d['pubkeys'] = ["(pubkey)"]
return
# non-generated TxIn transactions push a signature
# (seventy-something bytes) and then their public key
# (65 bytes) onto the stack:
match = [ opcodes.OP_PUSHDATA4, opcodes.OP_PUSHDATA4 ]
if match_decoded(decoded, match):
sig = decoded[0][1].encode('hex')
x_pubkey = decoded[1][1].encode('hex')
try:
signatures = parse_sig([sig])
pubkey = parse_xpub(x_pubkey)
except:
import traceback
traceback.print_exc(file=sys.stdout)
print_error("cannot find address in input script", bytes.encode('hex'))
return
d['signatures'] = signatures
d['x_pubkeys'] = [x_pubkey]
d['num_sig'] = 1
d['pubkeys'] = [pubkey]
d['address'] = public_key_to_bc_address(pubkey.decode('hex'))
return
# p2sh transaction, 2 of n
match = [ opcodes.OP_0 ]
while len(match) < len(decoded):
match.append(opcodes.OP_PUSHDATA4)
if not match_decoded(decoded, match):
print_error("cannot find address in input script", bytes.encode('hex'))
return
x_sig = map(lambda x:x[1].encode('hex'), decoded[1:-1])
d['signatures'] = parse_sig(x_sig)
d['num_sig'] = 2
dec2 = [ x for x in script_GetOp(decoded[-1][1]) ]
match_2of2 = [ opcodes.OP_2, opcodes.OP_PUSHDATA4, opcodes.OP_PUSHDATA4, opcodes.OP_2, opcodes.OP_CHECKMULTISIG ]
match_2of3 = [ opcodes.OP_2, opcodes.OP_PUSHDATA4, opcodes.OP_PUSHDATA4, opcodes.OP_PUSHDATA4, opcodes.OP_3, opcodes.OP_CHECKMULTISIG ]
if match_decoded(dec2, match_2of2):
x_pubkeys = [ dec2[1][1].encode('hex'), dec2[2][1].encode('hex') ]
elif match_decoded(dec2, match_2of3):
x_pubkeys = [ dec2[1][1].encode('hex'), dec2[2][1].encode('hex'), dec2[3][1].encode('hex') ]
else:
print_error("cannot find address in input script", bytes.encode('hex'))
return
d['x_pubkeys'] = x_pubkeys
pubkeys = map(parse_xpub, x_pubkeys)
d['pubkeys'] = pubkeys
redeemScript = Transaction.multisig_script(pubkeys,2)
d['redeemScript'] = redeemScript
d['address'] = hash_160_to_bc_address(hash_160(redeemScript.decode('hex')), 5)
def get_address_from_output_script(bytes):
decoded = [ x for x in script_GetOp(bytes) ]
# The Genesis Block, self-payments, and pay-by-IP-address payments look like:
# 65 BYTES:... CHECKSIG
match = [ opcodes.OP_PUSHDATA4, opcodes.OP_CHECKSIG ]
if match_decoded(decoded, match):
return 'pubkey', decoded[0][1].encode('hex')
# Pay-by-Bitcoin-address TxOuts look like:
# DUP HASH160 20 BYTES:... EQUALVERIFY CHECKSIG
match = [ opcodes.OP_DUP, opcodes.OP_HASH160, opcodes.OP_PUSHDATA4, opcodes.OP_EQUALVERIFY, opcodes.OP_CHECKSIG ]
if match_decoded(decoded, match):
return 'address', hash_160_to_bc_address(decoded[2][1])
# p2sh
match = [ opcodes.OP_HASH160, opcodes.OP_PUSHDATA4, opcodes.OP_EQUAL ]
if match_decoded(decoded, match):
return 'address', hash_160_to_bc_address(decoded[1][1],5)
return "(None)", "(None)"
def parse_input(vds):
d = {}
prevout_hash = hash_encode(vds.read_bytes(32))
prevout_n = vds.read_uint32()
d['scriptSig'] = scriptSig = vds.read_bytes(vds.read_compact_size())
sequence = vds.read_uint32()
if prevout_hash == '00'*32:
d['is_coinbase'] = True
else:
d['is_coinbase'] = False
d['prevout_hash'] = prevout_hash
d['prevout_n'] = prevout_n
d['sequence'] = sequence
d['pubkeys'] = []
d['signatures'] = {}
d['address'] = None
if scriptSig:
parse_scriptSig(d, scriptSig)
return d
def parse_output(vds, i):
d = {}
d['value'] = vds.read_int64()
scriptPubKey = vds.read_bytes(vds.read_compact_size())
type, address = get_address_from_output_script(scriptPubKey)
d['type'] = type
d['address'] = address
d['scriptPubKey'] = scriptPubKey.encode('hex')
d['prevout_n'] = i
return d
def deserialize(raw):
vds = BCDataStream()
vds.write(raw.decode('hex'))
d = {}
start = vds.read_cursor
d['version'] = vds.read_int32()
n_vin = vds.read_compact_size()
d['inputs'] = []
for i in xrange(n_vin):
d['inputs'].append(parse_input(vds))
n_vout = vds.read_compact_size()
d['outputs'] = []
for i in xrange(n_vout):
d['outputs'].append(parse_output(vds, i))
d['lockTime'] = vds.read_uint32()
return d
push_script = lambda x: op_push(len(x)/2) + x
class Transaction:
def __str__(self):
if self.raw is None:
self.raw = self.serialize(self.inputs, self.outputs, for_sig = None) # for_sig=-1 means do not sign
return self.raw
def __init__(self, inputs, outputs, locktime=0):
self.inputs = inputs
self.outputs = outputs
self.locktime = locktime
self.raw = None
@classmethod
def deserialize(klass, raw):
self = klass([],[])
self.update(raw)
return self
def update(self, raw):
d = deserialize(raw)
self.raw = raw
self.inputs = d['inputs']
self.outputs = map(lambda x: (x['type'], x['address'], x['value']), d['outputs'])
self.locktime = d['lockTime']
@classmethod
def sweep(klass, privkeys, network, to_address, fee):
inputs = []
for privkey in privkeys:
pubkey = public_key_from_private_key(privkey)
address = address_from_private_key(privkey)
u = network.synchronous_get([ ('blockchain.address.listunspent',[address])])[0]
pay_script = klass.pay_script('address', address)
for item in u:
item['scriptPubKey'] = pay_script
item['redeemPubkey'] = pubkey
item['address'] = address
item['prevout_hash'] = item['tx_hash']
item['prevout_n'] = item['tx_pos']
inputs += u
if not inputs:
return
total = sum( map(lambda x:int(x.get('value')), inputs) ) - fee
outputs = [('address', to_address, total)]
self = klass(inputs, outputs)
self.sign({ pubkey:privkey })
return self
@classmethod
def multisig_script(klass, public_keys, num=None):
n = len(public_keys)
if num is None: num = n
# supports only "2 of 2", and "2 of 3" transactions
assert num <= n and n in [2,3]
if num==2:
s = '52'
elif num == 3:
s = '53'
else:
raise
for k in public_keys:
s += op_push(len(k)/2)
s += k
if n==2:
s += '52'
elif n==3:
s += '53'
else:
raise
s += 'ae'
return s
@classmethod
def pay_script(self, type, addr):
if type == 'op_return':
h = addr.encode('hex')
return '6a' + push_script(h)
else:
assert type == 'address'
addrtype, hash_160 = bc_address_to_hash_160(addr)
if addrtype == 0:
script = '76a9' # op_dup, op_hash_160
script += push_script(hash_160.encode('hex'))
script += '88ac' # op_equalverify, op_checksig
elif addrtype == 5:
script = 'a9' # op_hash_160
script += push_script(hash_160.encode('hex'))
script += '87' # op_equal
else:
raise
return script
@classmethod
def serialize(klass, inputs, outputs, for_sig = None ):
s = int_to_hex(1,4) # version
s += var_int( len(inputs) ) # number of inputs
for i in range(len(inputs)):
txin = inputs[i]
s += txin['prevout_hash'].decode('hex')[::-1].encode('hex') # prev hash
s += int_to_hex(txin['prevout_n'],4) # prev index
p2sh = txin.get('redeemScript') is not None
num_sig = txin['num_sig']
address = txin['address']
x_signatures = txin['signatures']
signatures = filter(lambda x: x is not None, x_signatures)
is_complete = len(signatures) == num_sig
if for_sig is None:
# if we have enough signatures, we use the actual pubkeys
# use extended pubkeys (with bip32 derivation)
sig_list = []
if is_complete:
pubkeys = txin['pubkeys']
for signature in signatures:
sig_list.append(signature + '01')
else:
pubkeys = txin['x_pubkeys']
for signature in x_signatures:
sig_list.append((signature + '01') if signature is not None else NO_SIGNATURE)
sig_list = ''.join( map( lambda x: push_script(x), sig_list))
if not p2sh:
script = sig_list
script += push_script(pubkeys[0])
else:
script = '00' # op_0
script += sig_list
redeem_script = klass.multisig_script(pubkeys,2)
script += push_script(redeem_script)
elif for_sig==i:
script = txin['redeemScript'] if p2sh else klass.pay_script('address', address)
else:
script = ''
s += var_int( len(script)/2 ) # script length
s += script
s += "ffffffff" # sequence
s += var_int( len(outputs) ) # number of outputs
for output in outputs:
type, addr, amount = output
s += int_to_hex( amount, 8) # amount
script = klass.pay_script(type, addr)
s += var_int( len(script)/2 ) # script length
s += script # script
s += int_to_hex(0,4) # lock time
if for_sig is not None and for_sig != -1:
s += int_to_hex(1, 4) # hash type
return s
def tx_for_sig(self,i):
return self.serialize(self.inputs, self.outputs, for_sig = i)
def hash(self):
return Hash(self.raw.decode('hex') )[::-1].encode('hex')
def add_signature(self, i, pubkey, sig):
print_error("adding signature for", pubkey)
txin = self.inputs[i]
pubkeys = txin['pubkeys']
ii = pubkeys.index(pubkey)
txin['signatures'][ii] = sig
txin['x_pubkeys'][ii] = pubkey
self.inputs[i] = txin
self.raw = self.serialize(self.inputs, self.outputs)
def signature_count(self):
r = 0
s = 0
for txin in self.inputs:
if txin.get('is_coinbase'):
continue
signatures = filter(lambda x: x is not None, txin['signatures'])
s += len(signatures)
r += txin['num_sig']
return s, r
def is_complete(self):
s, r = self.signature_count()
return r == s
def inputs_to_sign(self):
from account import BIP32_Account, OldAccount
xpub_list = []
addr_list = set()
for txin in self.inputs:
x_signatures = txin['signatures']
signatures = filter(lambda x: x is not None, x_signatures)
if len(signatures) == txin['num_sig']:
# input is complete
continue
for k, x_pubkey in enumerate(txin['x_pubkeys']):
if x_signatures[k] is not None:
# this pubkey already signed
continue
if x_pubkey[0:2] == 'ff':
xpub, sequence = BIP32_Account.parse_xpubkey(x_pubkey)
xpub_list.append((xpub,sequence))
elif x_pubkey[0:2] == 'fe':
xpub, sequence = OldAccount.parse_xpubkey(x_pubkey)
xpub_list.append((xpub,sequence))
else:
addr_list.add(txin['address'])
return addr_list, xpub_list
def sign(self, keypairs):
print_error("tx.sign(), keypairs:", keypairs)
for i, txin in enumerate(self.inputs):
# continue if this txin is complete
signatures = filter(lambda x: x is not None, txin['signatures'])
num = txin['num_sig']
if len(signatures) == num:
continue
redeem_pubkeys = txin['pubkeys']
for_sig = Hash(self.tx_for_sig(i).decode('hex'))
for pubkey in redeem_pubkeys:
if pubkey in keypairs.keys():
# add signature
sec = keypairs[pubkey]
pkey = regenerate_key(sec)
secexp = pkey.secret
private_key = ecdsa.SigningKey.from_secret_exponent( secexp, curve = SECP256k1 )
public_key = private_key.get_verifying_key()
sig = private_key.sign_digest_deterministic( for_sig, hashfunc=hashlib.sha256, sigencode = ecdsa.util.sigencode_der )
assert public_key.verify_digest( sig, for_sig, sigdecode = ecdsa.util.sigdecode_der)
self.add_signature(i, pubkey, sig.encode('hex'))
print_error("is_complete", self.is_complete())
self.raw = self.serialize( self.inputs, self.outputs )
def add_pubkey_addresses(self, txlist):
for i in self.inputs:
if i.get("address") == "(pubkey)":
prev_tx = txlist.get(i.get('prevout_hash'))
if prev_tx:
address, value = prev_tx.get_outputs()[i.get('prevout_n')]
print_error("found pay-to-pubkey address:", address)
i["address"] = address
def get_outputs(self):
"""convert pubkeys to addresses"""
o = []
for type, x, v in self.outputs:
if type == 'address':
addr = x
elif type == 'pubkey':
addr = public_key_to_bc_address(x.decode('hex'))
else:
addr = "(None)"
o.append((addr,v))
return o
def get_output_addresses(self):
return map(lambda x:x[0], self.get_outputs())
def has_address(self, addr):
found = False
for txin in self.inputs:
if addr == txin.get('address'):
found = True
break
if addr in self.get_output_addresses():
found = True
return found
def get_value(self, addresses, prevout_values):
# return the balance for that tx
is_relevant = False
is_send = False
is_pruned = False
is_partial = False
v_in = v_out = v_out_mine = 0
for item in self.inputs:
addr = item.get('address')
if addr in addresses:
is_send = True
is_relevant = True
key = item['prevout_hash'] + ':%d'%item['prevout_n']
value = prevout_values.get( key )
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 self.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 as_dict(self):
import json
out = {
"hex":str(self),
"complete":self.is_complete()
}
return out
def requires_fee(self, verifier):
# see https://en.bitcoin.it/wiki/Transaction_fees
threshold = 57600000
size = len(str(self))/2
if size >= 10000:
return True
for o in self.get_outputs():
value = o[1]
if value < 1000000:
return True
sum = 0
for i in self.inputs:
age = verifier.get_confirmations(i["prevout_hash"])[0]
sum += i["value"] * age
priority = sum / size
print_error(priority, threshold)
return priority < threshold