/usr/lib/python3/dist-packages/bitcoin/deterministic.py is in python3-bitcoin 1.1.42-1.
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1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 119 120 121 122 123 124 125 126 127 128 129 130 131 132 133 134 135 136 137 138 139 140 141 142 143 144 145 146 147 148 149 150 151 152 153 154 155 156 157 158 159 160 161 162 163 164 165 166 167 168 169 170 171 172 173 174 175 176 177 178 179 180 181 182 183 184 185 186 187 188 189 190 191 192 193 194 195 196 197 198 199 | from bitcoin.main import *
import hmac
import hashlib
from binascii import hexlify
# Electrum wallets
def electrum_stretch(seed):
return slowsha(seed)
# Accepts seed or stretched seed, returns master public key
def electrum_mpk(seed):
if len(seed) == 32:
seed = electrum_stretch(seed)
return privkey_to_pubkey(seed)[2:]
# Accepts (seed or stretched seed), index and secondary index
# (conventionally 0 for ordinary addresses, 1 for change) , returns privkey
def electrum_privkey(seed, n, for_change=0):
if len(seed) == 32:
seed = electrum_stretch(seed)
mpk = electrum_mpk(seed)
offset = dbl_sha256(from_int_representation_to_bytes(n)+b':'+from_int_representation_to_bytes(for_change)+b':'+binascii.unhexlify(mpk))
return add_privkeys(seed, offset)
# Accepts (seed or stretched seed or master pubkey), index and secondary index
# (conventionally 0 for ordinary addresses, 1 for change) , returns pubkey
def electrum_pubkey(masterkey, n, for_change=0):
if len(masterkey) == 32:
mpk = electrum_mpk(electrum_stretch(masterkey))
elif len(masterkey) == 64:
mpk = electrum_mpk(masterkey)
else:
mpk = masterkey
bin_mpk = encode_pubkey(mpk, 'bin_electrum')
offset = bin_dbl_sha256(from_int_representation_to_bytes(n)+b':'+from_int_representation_to_bytes(for_change)+b':'+bin_mpk)
return add_pubkeys('04'+mpk, privtopub(offset))
# seed/stretched seed/pubkey -> address (convenience method)
def electrum_address(masterkey, n, for_change=0, version=0):
return pubkey_to_address(electrum_pubkey(masterkey, n, for_change), version)
# Given a master public key, a private key from that wallet and its index,
# cracks the secret exponent which can be used to generate all other private
# keys in the wallet
def crack_electrum_wallet(mpk, pk, n, for_change=0):
bin_mpk = encode_pubkey(mpk, 'bin_electrum')
offset = dbl_sha256(str(n)+':'+str(for_change)+':'+bin_mpk)
return subtract_privkeys(pk, offset)
# Below code ASSUMES binary inputs and compressed pubkeys
MAINNET_PRIVATE = b'\x04\x88\xAD\xE4'
MAINNET_PUBLIC = b'\x04\x88\xB2\x1E'
TESTNET_PRIVATE = b'\x04\x35\x83\x94'
TESTNET_PUBLIC = b'\x04\x35\x87\xCF'
PRIVATE = [MAINNET_PRIVATE, TESTNET_PRIVATE]
PUBLIC = [MAINNET_PUBLIC, TESTNET_PUBLIC]
# BIP32 child key derivation
def raw_bip32_ckd(rawtuple, i):
vbytes, depth, fingerprint, oldi, chaincode, key = rawtuple
i = int(i)
if vbytes in PRIVATE:
priv = key
pub = privtopub(key)
else:
pub = key
if i >= 2**31:
if vbytes in PUBLIC:
raise Exception("Can't do private derivation on public key!")
I = hmac.new(chaincode, b'\x00'+priv[:32]+encode(i, 256, 4), hashlib.sha512).digest()
else:
I = hmac.new(chaincode, pub+encode(i, 256, 4), hashlib.sha512).digest()
if vbytes in PRIVATE:
newkey = add_privkeys(I[:32]+B'\x01', priv)
fingerprint = bin_hash160(privtopub(key))[:4]
if vbytes in PUBLIC:
newkey = add_pubkeys(compress(privtopub(I[:32])), key)
fingerprint = bin_hash160(key)[:4]
return (vbytes, depth + 1, fingerprint, i, I[32:], newkey)
def bip32_serialize(rawtuple):
vbytes, depth, fingerprint, i, chaincode, key = rawtuple
i = encode(i, 256, 4)
chaincode = encode(hash_to_int(chaincode), 256, 32)
keydata = b'\x00'+key[:-1] if vbytes in PRIVATE else key
bindata = vbytes + from_int_to_byte(depth % 256) + fingerprint + i + chaincode + keydata
return changebase(bindata+bin_dbl_sha256(bindata)[:4], 256, 58)
def bip32_deserialize(data):
dbin = changebase(data, 58, 256)
if bin_dbl_sha256(dbin[:-4])[:4] != dbin[-4:]:
raise Exception("Invalid checksum")
vbytes = dbin[0:4]
depth = from_byte_to_int(dbin[4])
fingerprint = dbin[5:9]
i = decode(dbin[9:13], 256)
chaincode = dbin[13:45]
key = dbin[46:78]+b'\x01' if vbytes in PRIVATE else dbin[45:78]
return (vbytes, depth, fingerprint, i, chaincode, key)
def raw_bip32_privtopub(rawtuple):
vbytes, depth, fingerprint, i, chaincode, key = rawtuple
newvbytes = MAINNET_PUBLIC if vbytes == MAINNET_PRIVATE else TESTNET_PUBLIC
return (newvbytes, depth, fingerprint, i, chaincode, privtopub(key))
def bip32_privtopub(data):
return bip32_serialize(raw_bip32_privtopub(bip32_deserialize(data)))
def bip32_ckd(data, i):
return bip32_serialize(raw_bip32_ckd(bip32_deserialize(data), i))
def bip32_master_key(seed, vbytes=MAINNET_PRIVATE):
I = hmac.new(from_string_to_bytes("Bitcoin seed"), seed, hashlib.sha512).digest()
return bip32_serialize((vbytes, 0, b'\x00'*4, 0, I[32:], I[:32]+b'\x01'))
def bip32_bin_extract_key(data):
return bip32_deserialize(data)[-1]
def bip32_extract_key(data):
return safe_hexlify(bip32_deserialize(data)[-1])
# Exploits the same vulnerability as above in Electrum wallets
# Takes a BIP32 pubkey and one of the child privkeys of its corresponding
# privkey and returns the BIP32 privkey associated with that pubkey
def raw_crack_bip32_privkey(parent_pub, priv):
vbytes, depth, fingerprint, i, chaincode, key = priv
pvbytes, pdepth, pfingerprint, pi, pchaincode, pkey = parent_pub
i = int(i)
if i >= 2**31:
raise Exception("Can't crack private derivation!")
I = hmac.new(pchaincode, pkey+encode(i, 256, 4), hashlib.sha512).digest()
pprivkey = subtract_privkeys(key, I[:32]+b'\x01')
newvbytes = MAINNET_PRIVATE if vbytes == MAINNET_PUBLIC else TESTNET_PRIVATE
return (newvbytes, pdepth, pfingerprint, pi, pchaincode, pprivkey)
def crack_bip32_privkey(parent_pub, priv):
dsppub = bip32_deserialize(parent_pub)
dspriv = bip32_deserialize(priv)
return bip32_serialize(raw_crack_bip32_privkey(dsppub, dspriv))
def coinvault_pub_to_bip32(*args):
if len(args) == 1:
args = args[0].split(' ')
vals = map(int, args[34:])
I1 = ''.join(map(chr, vals[:33]))
I2 = ''.join(map(chr, vals[35:67]))
return bip32_serialize((MAINNET_PUBLIC, 0, b'\x00'*4, 0, I2, I1))
def coinvault_priv_to_bip32(*args):
if len(args) == 1:
args = args[0].split(' ')
vals = map(int, args[34:])
I2 = ''.join(map(chr, vals[35:67]))
I3 = ''.join(map(chr, vals[72:104]))
return bip32_serialize((MAINNET_PRIVATE, 0, b'\x00'*4, 0, I2, I3+b'\x01'))
def bip32_descend(*args):
if len(args) == 2 and isinstance(args[1], list):
key, path = args
else:
key, path = args[0], map(int, args[1:])
for p in path:
key = bip32_ckd(key, p)
return bip32_extract_key(key)
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