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1004 lines
31 KiB
1004 lines
31 KiB
# -*- coding: utf-8 -*-
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#
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# Electrum - lightweight Bitcoin client
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# Copyright (C) 2011 thomasv@gitorious
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#
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# Permission is hereby granted, free of charge, to any person
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# obtaining a copy of this software and associated documentation files
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# (the "Software"), to deal in the Software without restriction,
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# including without limitation the rights to use, copy, modify, merge,
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# publish, distribute, sublicense, and/or sell copies of the Software,
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# and to permit persons to whom the Software is furnished to do so,
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# subject to the following conditions:
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#
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# The above copyright notice and this permission notice shall be
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# included in all copies or substantial portions of the Software.
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#
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# THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
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# EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
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# MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND
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# NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS
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# BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN
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# ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN
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# CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
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# SOFTWARE.
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import hashlib
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import base64
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import hmac
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import os
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import json
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import ecdsa
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import pyaes
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from .util import bfh, bh2u, to_string
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from . import version
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from .util import print_error, InvalidPassword, assert_bytes, to_bytes, inv_dict
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from . import segwit_addr
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from . import constants
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################################## transactions
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COINBASE_MATURITY = 100
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COIN = 100000000
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# supported types of transction outputs
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TYPE_ADDRESS = 0
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TYPE_PUBKEY = 1
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TYPE_SCRIPT = 2
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# AES encryption
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try:
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from Cryptodome.Cipher import AES
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except:
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AES = None
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class InvalidPadding(Exception):
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pass
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def append_PKCS7_padding(data):
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assert_bytes(data)
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padlen = 16 - (len(data) % 16)
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return data + bytes([padlen]) * padlen
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def strip_PKCS7_padding(data):
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assert_bytes(data)
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if len(data) % 16 != 0 or len(data) == 0:
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raise InvalidPadding("invalid length")
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padlen = data[-1]
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if padlen > 16:
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raise InvalidPadding("invalid padding byte (large)")
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for i in data[-padlen:]:
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if i != padlen:
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raise InvalidPadding("invalid padding byte (inconsistent)")
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return data[0:-padlen]
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def aes_encrypt_with_iv(key, iv, data):
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assert_bytes(key, iv, data)
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data = append_PKCS7_padding(data)
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if AES:
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e = AES.new(key, AES.MODE_CBC, iv).encrypt(data)
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else:
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aes_cbc = pyaes.AESModeOfOperationCBC(key, iv=iv)
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aes = pyaes.Encrypter(aes_cbc, padding=pyaes.PADDING_NONE)
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e = aes.feed(data) + aes.feed() # empty aes.feed() flushes buffer
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return e
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def aes_decrypt_with_iv(key, iv, data):
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assert_bytes(key, iv, data)
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if AES:
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cipher = AES.new(key, AES.MODE_CBC, iv)
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data = cipher.decrypt(data)
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else:
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aes_cbc = pyaes.AESModeOfOperationCBC(key, iv=iv)
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aes = pyaes.Decrypter(aes_cbc, padding=pyaes.PADDING_NONE)
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data = aes.feed(data) + aes.feed() # empty aes.feed() flushes buffer
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try:
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return strip_PKCS7_padding(data)
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except InvalidPadding:
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raise InvalidPassword()
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def EncodeAES(secret, s):
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assert_bytes(s)
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iv = bytes(os.urandom(16))
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ct = aes_encrypt_with_iv(secret, iv, s)
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e = iv + ct
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return base64.b64encode(e)
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def DecodeAES(secret, e):
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e = bytes(base64.b64decode(e))
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iv, e = e[:16], e[16:]
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s = aes_decrypt_with_iv(secret, iv, e)
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return s
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def pw_encode(s, password):
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if password:
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secret = Hash(password)
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return EncodeAES(secret, to_bytes(s, "utf8")).decode('utf8')
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else:
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return s
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def pw_decode(s, password):
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if password is not None:
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secret = Hash(password)
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try:
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d = to_string(DecodeAES(secret, s), "utf8")
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except Exception:
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raise InvalidPassword()
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return d
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else:
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return s
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def rev_hex(s):
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return bh2u(bfh(s)[::-1])
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def int_to_hex(i, length=1):
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assert isinstance(i, int)
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s = hex(i)[2:].rstrip('L')
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s = "0"*(2*length - len(s)) + s
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return rev_hex(s)
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def var_int(i):
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# https://en.bitcoin.it/wiki/Protocol_specification#Variable_length_integer
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if i<0xfd:
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return int_to_hex(i)
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elif i<=0xffff:
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return "fd"+int_to_hex(i,2)
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elif i<=0xffffffff:
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return "fe"+int_to_hex(i,4)
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else:
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return "ff"+int_to_hex(i,8)
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def op_push(i):
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if i<0x4c:
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return int_to_hex(i)
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elif i<0xff:
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return '4c' + int_to_hex(i)
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elif i<0xffff:
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return '4d' + int_to_hex(i,2)
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else:
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return '4e' + int_to_hex(i,4)
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def push_script(x):
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return op_push(len(x)//2) + x
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def sha256(x):
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x = to_bytes(x, 'utf8')
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return bytes(hashlib.sha256(x).digest())
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def Hash(x):
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x = to_bytes(x, 'utf8')
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out = bytes(sha256(sha256(x)))
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return out
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hash_encode = lambda x: bh2u(x[::-1])
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hash_decode = lambda x: bfh(x)[::-1]
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hmac_sha_512 = lambda x, y: hmac.new(x, y, hashlib.sha512).digest()
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def is_new_seed(x, prefix=version.SEED_PREFIX):
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from . import mnemonic
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x = mnemonic.normalize_text(x)
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s = bh2u(hmac_sha_512(b"Seed version", x.encode('utf8')))
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return s.startswith(prefix)
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def is_old_seed(seed):
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from . import old_mnemonic, mnemonic
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seed = mnemonic.normalize_text(seed)
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words = seed.split()
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try:
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# checks here are deliberately left weak for legacy reasons, see #3149
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old_mnemonic.mn_decode(words)
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uses_electrum_words = True
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except Exception:
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uses_electrum_words = False
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try:
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seed = bfh(seed)
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is_hex = (len(seed) == 16 or len(seed) == 32)
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except Exception:
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is_hex = False
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return is_hex or (uses_electrum_words and (len(words) == 12 or len(words) == 24))
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def seed_type(x):
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if is_old_seed(x):
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return 'old'
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elif is_new_seed(x):
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return 'standard'
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elif is_new_seed(x, version.SEED_PREFIX_SW):
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return 'segwit'
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elif is_new_seed(x, version.SEED_PREFIX_2FA):
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return '2fa'
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return ''
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is_seed = lambda x: bool(seed_type(x))
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# pywallet openssl private key implementation
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def i2o_ECPublicKey(pubkey, compressed=False):
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# public keys are 65 bytes long (520 bits)
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# 0x04 + 32-byte X-coordinate + 32-byte Y-coordinate
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# 0x00 = point at infinity, 0x02 and 0x03 = compressed, 0x04 = uncompressed
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# compressed keys: <sign> <x> where <sign> is 0x02 if y is even and 0x03 if y is odd
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if compressed:
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if pubkey.point.y() & 1:
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key = '03' + '%064x' % pubkey.point.x()
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else:
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key = '02' + '%064x' % pubkey.point.x()
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else:
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key = '04' + \
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'%064x' % pubkey.point.x() + \
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'%064x' % pubkey.point.y()
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return bfh(key)
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# end pywallet openssl private key implementation
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############ functions from pywallet #####################
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def hash_160(public_key):
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try:
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md = hashlib.new('ripemd160')
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md.update(sha256(public_key))
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return md.digest()
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except BaseException:
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from . import ripemd
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md = ripemd.new(sha256(public_key))
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return md.digest()
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def hash160_to_b58_address(h160, addrtype, witness_program_version=1):
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s = bytes([addrtype])
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s += h160
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return base_encode(s+Hash(s)[0:4], base=58)
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def b58_address_to_hash160(addr):
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addr = to_bytes(addr, 'ascii')
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_bytes = base_decode(addr, 25, base=58)
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return _bytes[0], _bytes[1:21]
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def hash160_to_p2pkh(h160):
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return hash160_to_b58_address(h160, constants.net.ADDRTYPE_P2PKH)
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def hash160_to_p2sh(h160):
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return hash160_to_b58_address(h160, constants.net.ADDRTYPE_P2SH)
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def public_key_to_p2pkh(public_key):
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return hash160_to_p2pkh(hash_160(public_key))
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def hash_to_segwit_addr(h):
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return segwit_addr.encode(constants.net.SEGWIT_HRP, 0, h)
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def public_key_to_p2wpkh(public_key):
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return hash_to_segwit_addr(hash_160(public_key))
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def script_to_p2wsh(script):
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return hash_to_segwit_addr(sha256(bfh(script)))
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def p2wpkh_nested_script(pubkey):
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pkh = bh2u(hash_160(bfh(pubkey)))
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return '00' + push_script(pkh)
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def p2wsh_nested_script(witness_script):
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wsh = bh2u(sha256(bfh(witness_script)))
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return '00' + push_script(wsh)
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def pubkey_to_address(txin_type, pubkey):
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if txin_type == 'p2pkh':
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return public_key_to_p2pkh(bfh(pubkey))
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elif txin_type == 'p2wpkh':
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return hash_to_segwit_addr(hash_160(bfh(pubkey)))
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elif txin_type == 'p2wpkh-p2sh':
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scriptSig = p2wpkh_nested_script(pubkey)
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return hash160_to_p2sh(hash_160(bfh(scriptSig)))
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else:
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raise NotImplementedError(txin_type)
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def redeem_script_to_address(txin_type, redeem_script):
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if txin_type == 'p2sh':
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return hash160_to_p2sh(hash_160(bfh(redeem_script)))
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elif txin_type == 'p2wsh':
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return script_to_p2wsh(redeem_script)
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elif txin_type == 'p2wsh-p2sh':
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scriptSig = p2wsh_nested_script(redeem_script)
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return hash160_to_p2sh(hash_160(bfh(scriptSig)))
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else:
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raise NotImplementedError(txin_type)
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def script_to_address(script):
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from .transaction import get_address_from_output_script
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t, addr = get_address_from_output_script(bfh(script))
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assert t == TYPE_ADDRESS
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return addr
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def address_to_script(addr):
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witver, witprog = segwit_addr.decode(constants.net.SEGWIT_HRP, addr)
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if witprog is not None:
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assert (0 <= witver <= 16)
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OP_n = witver + 0x50 if witver > 0 else 0
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script = bh2u(bytes([OP_n]))
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script += push_script(bh2u(bytes(witprog)))
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return script
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addrtype, hash_160 = b58_address_to_hash160(addr)
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if addrtype == constants.net.ADDRTYPE_P2PKH:
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script = '76a9' # op_dup, op_hash_160
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script += push_script(bh2u(hash_160))
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script += '88ac' # op_equalverify, op_checksig
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elif addrtype == constants.net.ADDRTYPE_P2SH:
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script = 'a9' # op_hash_160
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script += push_script(bh2u(hash_160))
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script += '87' # op_equal
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else:
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raise BaseException('unknown address type')
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return script
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def address_to_scripthash(addr):
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script = address_to_script(addr)
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return script_to_scripthash(script)
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def script_to_scripthash(script):
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h = sha256(bytes.fromhex(script))[0:32]
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return bh2u(bytes(reversed(h)))
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def public_key_to_p2pk_script(pubkey):
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script = push_script(pubkey)
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script += 'ac' # op_checksig
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return script
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__b58chars = b'123456789ABCDEFGHJKLMNPQRSTUVWXYZabcdefghijkmnopqrstuvwxyz'
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assert len(__b58chars) == 58
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__b43chars = b'0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZ$*+-./:'
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assert len(__b43chars) == 43
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def base_encode(v, base):
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""" encode v, which is a string of bytes, to base58."""
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assert_bytes(v)
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assert base in (58, 43)
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chars = __b58chars
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if base == 43:
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chars = __b43chars
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long_value = 0
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for (i, c) in enumerate(v[::-1]):
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long_value += (256**i) * c
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result = bytearray()
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while long_value >= base:
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div, mod = divmod(long_value, base)
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result.append(chars[mod])
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long_value = div
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result.append(chars[long_value])
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# Bitcoin does a little leading-zero-compression:
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# leading 0-bytes in the input become leading-1s
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nPad = 0
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for c in v:
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if c == 0x00:
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nPad += 1
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else:
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break
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result.extend([chars[0]] * nPad)
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result.reverse()
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return result.decode('ascii')
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def base_decode(v, length, base):
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""" decode v into a string of len bytes."""
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# assert_bytes(v)
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v = to_bytes(v, 'ascii')
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assert base in (58, 43)
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chars = __b58chars
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if base == 43:
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chars = __b43chars
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long_value = 0
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for (i, c) in enumerate(v[::-1]):
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digit = chars.find(bytes([c]))
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if digit == -1:
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raise ValueError('Forbidden character {} for base {}'.format(c, base))
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long_value += digit * (base**i)
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result = bytearray()
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while long_value >= 256:
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div, mod = divmod(long_value, 256)
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result.append(mod)
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long_value = div
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result.append(long_value)
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nPad = 0
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for c in v:
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if c == chars[0]:
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nPad += 1
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else:
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break
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result.extend(b'\x00' * nPad)
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if length is not None and len(result) != length:
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return None
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result.reverse()
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return bytes(result)
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class InvalidChecksum(Exception):
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pass
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def EncodeBase58Check(vchIn):
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hash = Hash(vchIn)
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return base_encode(vchIn + hash[0:4], base=58)
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def DecodeBase58Check(psz):
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vchRet = base_decode(psz, None, base=58)
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key = vchRet[0:-4]
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csum = vchRet[-4:]
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hash = Hash(key)
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cs32 = hash[0:4]
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if cs32 != csum:
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raise InvalidChecksum('expected {}, actual {}'.format(bh2u(cs32), bh2u(csum)))
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else:
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return key
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# backwards compat
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# extended WIF for segwit (used in 3.0.x; but still used internally)
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SCRIPT_TYPES = {
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'p2pkh':0,
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'p2wpkh':1,
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'p2wpkh-p2sh':2,
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'p2sh':5,
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'p2wsh':6,
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'p2wsh-p2sh':7
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}
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def serialize_privkey(secret, compressed, txin_type, internal_use=False):
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if internal_use:
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prefix = bytes([(SCRIPT_TYPES[txin_type] + constants.net.WIF_PREFIX) & 255])
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else:
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prefix = bytes([constants.net.WIF_PREFIX])
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suffix = b'\01' if compressed else b''
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vchIn = prefix + secret + suffix
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base58_wif = EncodeBase58Check(vchIn)
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if internal_use:
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return base58_wif
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else:
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return '{}:{}'.format(txin_type, base58_wif)
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def deserialize_privkey(key):
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if is_minikey(key):
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return 'p2pkh', minikey_to_private_key(key), True
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txin_type = None
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if ':' in key:
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txin_type, key = key.split(sep=':', maxsplit=1)
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assert txin_type in SCRIPT_TYPES
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try:
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vch = DecodeBase58Check(key)
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except BaseException:
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neutered_privkey = str(key)[:3] + '..' + str(key)[-2:]
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raise BaseException("cannot deserialize", neutered_privkey)
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if txin_type is None:
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# keys exported in version 3.0.x encoded script type in first byte
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txin_type = inv_dict(SCRIPT_TYPES)[vch[0] - constants.net.WIF_PREFIX]
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else:
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assert vch[0] == constants.net.WIF_PREFIX
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assert len(vch) in [33, 34]
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compressed = len(vch) == 34
|
|
return txin_type, vch[1:33], compressed
|
|
|
|
|
|
def regenerate_key(pk):
|
|
assert len(pk) == 32
|
|
return EC_KEY(pk)
|
|
|
|
|
|
def GetPubKey(pubkey, compressed=False):
|
|
return i2o_ECPublicKey(pubkey, compressed)
|
|
|
|
|
|
def GetSecret(pkey):
|
|
return bfh('%064x' % pkey.secret)
|
|
|
|
|
|
def is_compressed(sec):
|
|
return deserialize_privkey(sec)[2]
|
|
|
|
|
|
def public_key_from_private_key(pk, compressed):
|
|
pkey = regenerate_key(pk)
|
|
public_key = GetPubKey(pkey.pubkey, compressed)
|
|
return bh2u(public_key)
|
|
|
|
def address_from_private_key(sec):
|
|
txin_type, privkey, compressed = deserialize_privkey(sec)
|
|
public_key = public_key_from_private_key(privkey, compressed)
|
|
return pubkey_to_address(txin_type, public_key)
|
|
|
|
def is_segwit_address(addr):
|
|
try:
|
|
witver, witprog = segwit_addr.decode(constants.net.SEGWIT_HRP, addr)
|
|
except Exception as e:
|
|
return False
|
|
return witprog is not None
|
|
|
|
def is_b58_address(addr):
|
|
try:
|
|
addrtype, h = b58_address_to_hash160(addr)
|
|
except Exception as e:
|
|
return False
|
|
if addrtype not in [constants.net.ADDRTYPE_P2PKH, constants.net.ADDRTYPE_P2SH]:
|
|
return False
|
|
return addr == hash160_to_b58_address(h, addrtype)
|
|
|
|
def is_address(addr):
|
|
return is_segwit_address(addr) or is_b58_address(addr)
|
|
|
|
|
|
def is_private_key(key):
|
|
try:
|
|
k = deserialize_privkey(key)
|
|
return k is not False
|
|
except:
|
|
return False
|
|
|
|
|
|
########### end pywallet functions #######################
|
|
|
|
def is_minikey(text):
|
|
# Minikeys are typically 22 or 30 characters, but this routine
|
|
# permits any length of 20 or more provided the minikey is valid.
|
|
# A valid minikey must begin with an 'S', be in base58, and when
|
|
# suffixed with '?' have its SHA256 hash begin with a zero byte.
|
|
# They are widely used in Casascius physical bitcoins.
|
|
return (len(text) >= 20 and text[0] == 'S'
|
|
and all(ord(c) in __b58chars for c in text)
|
|
and sha256(text + '?')[0] == 0x00)
|
|
|
|
def minikey_to_private_key(text):
|
|
return sha256(text)
|
|
|
|
from ecdsa.ecdsa import curve_secp256k1, generator_secp256k1
|
|
from ecdsa.curves import SECP256k1
|
|
from ecdsa.ellipticcurve import Point
|
|
from ecdsa.util import string_to_number, number_to_string
|
|
|
|
|
|
def msg_magic(message):
|
|
length = bfh(var_int(len(message)))
|
|
return b"\x18Bitcoin Signed Message:\n" + length + message
|
|
|
|
|
|
def verify_message(address, sig, message):
|
|
assert_bytes(sig, message)
|
|
try:
|
|
h = Hash(msg_magic(message))
|
|
public_key, compressed = pubkey_from_signature(sig, h)
|
|
# check public key using the address
|
|
pubkey = point_to_ser(public_key.pubkey.point, compressed)
|
|
for txin_type in ['p2pkh','p2wpkh','p2wpkh-p2sh']:
|
|
addr = pubkey_to_address(txin_type, bh2u(pubkey))
|
|
if address == addr:
|
|
break
|
|
else:
|
|
raise Exception("Bad signature")
|
|
# check message
|
|
public_key.verify_digest(sig[1:], h, sigdecode = ecdsa.util.sigdecode_string)
|
|
return True
|
|
except Exception as e:
|
|
print_error("Verification error: {0}".format(e))
|
|
return False
|
|
|
|
|
|
def encrypt_message(message, pubkey, magic=b'BIE1'):
|
|
return EC_KEY.encrypt_message(message, bfh(pubkey), magic)
|
|
|
|
|
|
def chunks(l, n):
|
|
return [l[i:i+n] for i in range(0, len(l), n)]
|
|
|
|
|
|
def ECC_YfromX(x,curved=curve_secp256k1, odd=True):
|
|
_p = curved.p()
|
|
_a = curved.a()
|
|
_b = curved.b()
|
|
for offset in range(128):
|
|
Mx = x + offset
|
|
My2 = pow(Mx, 3, _p) + _a * pow(Mx, 2, _p) + _b % _p
|
|
My = pow(My2, (_p+1)//4, _p )
|
|
|
|
if curved.contains_point(Mx,My):
|
|
if odd == bool(My&1):
|
|
return [My,offset]
|
|
return [_p-My,offset]
|
|
raise Exception('ECC_YfromX: No Y found')
|
|
|
|
|
|
def negative_point(P):
|
|
return Point( P.curve(), P.x(), -P.y(), P.order() )
|
|
|
|
|
|
def point_to_ser(P, comp=True ):
|
|
if comp:
|
|
return bfh( ('%02x'%(2+(P.y()&1)))+('%064x'%P.x()) )
|
|
return bfh( '04'+('%064x'%P.x())+('%064x'%P.y()) )
|
|
|
|
|
|
def ser_to_point(Aser):
|
|
curve = curve_secp256k1
|
|
generator = generator_secp256k1
|
|
_r = generator.order()
|
|
assert Aser[0] in [0x02, 0x03, 0x04]
|
|
if Aser[0] == 0x04:
|
|
return Point( curve, string_to_number(Aser[1:33]), string_to_number(Aser[33:]), _r )
|
|
Mx = string_to_number(Aser[1:])
|
|
return Point( curve, Mx, ECC_YfromX(Mx, curve, Aser[0] == 0x03)[0], _r )
|
|
|
|
|
|
class MyVerifyingKey(ecdsa.VerifyingKey):
|
|
@classmethod
|
|
def from_signature(klass, sig, recid, h, curve):
|
|
""" See http://www.secg.org/download/aid-780/sec1-v2.pdf, chapter 4.1.6 """
|
|
from ecdsa import util, numbertheory
|
|
from . import msqr
|
|
curveFp = curve.curve
|
|
G = curve.generator
|
|
order = G.order()
|
|
# extract r,s from signature
|
|
r, s = util.sigdecode_string(sig, order)
|
|
# 1.1
|
|
x = r + (recid//2) * order
|
|
# 1.3
|
|
alpha = ( x * x * x + curveFp.a() * x + curveFp.b() ) % curveFp.p()
|
|
beta = msqr.modular_sqrt(alpha, curveFp.p())
|
|
y = beta if (beta - recid) % 2 == 0 else curveFp.p() - beta
|
|
# 1.4 the constructor checks that nR is at infinity
|
|
R = Point(curveFp, x, y, order)
|
|
# 1.5 compute e from message:
|
|
e = string_to_number(h)
|
|
minus_e = -e % order
|
|
# 1.6 compute Q = r^-1 (sR - eG)
|
|
inv_r = numbertheory.inverse_mod(r,order)
|
|
Q = inv_r * ( s * R + minus_e * G )
|
|
return klass.from_public_point( Q, curve )
|
|
|
|
|
|
def pubkey_from_signature(sig, h):
|
|
if len(sig) != 65:
|
|
raise Exception("Wrong encoding")
|
|
nV = sig[0]
|
|
if nV < 27 or nV >= 35:
|
|
raise Exception("Bad encoding")
|
|
if nV >= 31:
|
|
compressed = True
|
|
nV -= 4
|
|
else:
|
|
compressed = False
|
|
recid = nV - 27
|
|
return MyVerifyingKey.from_signature(sig[1:], recid, h, curve = SECP256k1), compressed
|
|
|
|
|
|
class MySigningKey(ecdsa.SigningKey):
|
|
"""Enforce low S values in signatures"""
|
|
|
|
def sign_number(self, number, entropy=None, k=None):
|
|
curve = SECP256k1
|
|
G = curve.generator
|
|
order = G.order()
|
|
r, s = ecdsa.SigningKey.sign_number(self, number, entropy, k)
|
|
if s > order//2:
|
|
s = order - s
|
|
return r, s
|
|
|
|
|
|
class EC_KEY(object):
|
|
|
|
def __init__( self, k ):
|
|
secret = string_to_number(k)
|
|
self.pubkey = ecdsa.ecdsa.Public_key( generator_secp256k1, generator_secp256k1 * secret )
|
|
self.privkey = ecdsa.ecdsa.Private_key( self.pubkey, secret )
|
|
self.secret = secret
|
|
|
|
def get_public_key(self, compressed=True):
|
|
return bh2u(point_to_ser(self.pubkey.point, compressed))
|
|
|
|
def sign(self, msg_hash):
|
|
private_key = MySigningKey.from_secret_exponent(self.secret, curve = SECP256k1)
|
|
public_key = private_key.get_verifying_key()
|
|
signature = private_key.sign_digest_deterministic(msg_hash, hashfunc=hashlib.sha256, sigencode = ecdsa.util.sigencode_string)
|
|
assert public_key.verify_digest(signature, msg_hash, sigdecode = ecdsa.util.sigdecode_string)
|
|
return signature
|
|
|
|
def sign_message(self, message, is_compressed):
|
|
message = to_bytes(message, 'utf8')
|
|
signature = self.sign(Hash(msg_magic(message)))
|
|
for i in range(4):
|
|
sig = bytes([27 + i + (4 if is_compressed else 0)]) + signature
|
|
try:
|
|
self.verify_message(sig, message)
|
|
return sig
|
|
except Exception as e:
|
|
continue
|
|
else:
|
|
raise Exception("error: cannot sign message")
|
|
|
|
def verify_message(self, sig, message):
|
|
assert_bytes(message)
|
|
h = Hash(msg_magic(message))
|
|
public_key, compressed = pubkey_from_signature(sig, h)
|
|
# check public key
|
|
if point_to_ser(public_key.pubkey.point, compressed) != point_to_ser(self.pubkey.point, compressed):
|
|
raise Exception("Bad signature")
|
|
# check message
|
|
public_key.verify_digest(sig[1:], h, sigdecode = ecdsa.util.sigdecode_string)
|
|
|
|
|
|
# ECIES encryption/decryption methods; AES-128-CBC with PKCS7 is used as the cipher; hmac-sha256 is used as the mac
|
|
|
|
@classmethod
|
|
def encrypt_message(self, message, pubkey, magic=b'BIE1'):
|
|
assert_bytes(message)
|
|
|
|
pk = ser_to_point(pubkey)
|
|
if not ecdsa.ecdsa.point_is_valid(generator_secp256k1, pk.x(), pk.y()):
|
|
raise Exception('invalid pubkey')
|
|
|
|
ephemeral_exponent = number_to_string(ecdsa.util.randrange(pow(2,256)), generator_secp256k1.order())
|
|
ephemeral = EC_KEY(ephemeral_exponent)
|
|
ecdh_key = point_to_ser(pk * ephemeral.privkey.secret_multiplier)
|
|
key = hashlib.sha512(ecdh_key).digest()
|
|
iv, key_e, key_m = key[0:16], key[16:32], key[32:]
|
|
ciphertext = aes_encrypt_with_iv(key_e, iv, message)
|
|
ephemeral_pubkey = bfh(ephemeral.get_public_key(compressed=True))
|
|
encrypted = magic + ephemeral_pubkey + ciphertext
|
|
mac = hmac.new(key_m, encrypted, hashlib.sha256).digest()
|
|
|
|
return base64.b64encode(encrypted + mac)
|
|
|
|
def decrypt_message(self, encrypted, magic=b'BIE1'):
|
|
encrypted = base64.b64decode(encrypted)
|
|
if len(encrypted) < 85:
|
|
raise Exception('invalid ciphertext: length')
|
|
magic_found = encrypted[:4]
|
|
ephemeral_pubkey = encrypted[4:37]
|
|
ciphertext = encrypted[37:-32]
|
|
mac = encrypted[-32:]
|
|
if magic_found != magic:
|
|
raise Exception('invalid ciphertext: invalid magic bytes')
|
|
try:
|
|
ephemeral_pubkey = ser_to_point(ephemeral_pubkey)
|
|
except AssertionError as e:
|
|
raise Exception('invalid ciphertext: invalid ephemeral pubkey')
|
|
if not ecdsa.ecdsa.point_is_valid(generator_secp256k1, ephemeral_pubkey.x(), ephemeral_pubkey.y()):
|
|
raise Exception('invalid ciphertext: invalid ephemeral pubkey')
|
|
ecdh_key = point_to_ser(ephemeral_pubkey * self.privkey.secret_multiplier)
|
|
key = hashlib.sha512(ecdh_key).digest()
|
|
iv, key_e, key_m = key[0:16], key[16:32], key[32:]
|
|
if mac != hmac.new(key_m, encrypted[:-32], hashlib.sha256).digest():
|
|
raise InvalidPassword()
|
|
return aes_decrypt_with_iv(key_e, iv, ciphertext)
|
|
|
|
|
|
###################################### BIP32 ##############################
|
|
|
|
random_seed = lambda n: "%032x"%ecdsa.util.randrange( pow(2,n) )
|
|
BIP32_PRIME = 0x80000000
|
|
|
|
|
|
def get_pubkeys_from_secret(secret):
|
|
# public key
|
|
private_key = ecdsa.SigningKey.from_string( secret, curve = SECP256k1 )
|
|
public_key = private_key.get_verifying_key()
|
|
K = public_key.to_string()
|
|
K_compressed = GetPubKey(public_key.pubkey,True)
|
|
return K, K_compressed
|
|
|
|
|
|
# Child private key derivation function (from master private key)
|
|
# k = master private key (32 bytes)
|
|
# c = master chain code (extra entropy for key derivation) (32 bytes)
|
|
# n = the index of the key we want to derive. (only 32 bits will be used)
|
|
# If n is negative (i.e. the 32nd bit is set), the resulting private key's
|
|
# corresponding public key can NOT be determined without the master private key.
|
|
# However, if n is positive, the resulting private key's corresponding
|
|
# public key can be determined without the master private key.
|
|
def CKD_priv(k, c, n):
|
|
is_prime = n & BIP32_PRIME
|
|
return _CKD_priv(k, c, bfh(rev_hex(int_to_hex(n,4))), is_prime)
|
|
|
|
|
|
def _CKD_priv(k, c, s, is_prime):
|
|
order = generator_secp256k1.order()
|
|
keypair = EC_KEY(k)
|
|
cK = GetPubKey(keypair.pubkey,True)
|
|
data = bytes([0]) + k + s if is_prime else cK + s
|
|
I = hmac.new(c, data, hashlib.sha512).digest()
|
|
k_n = number_to_string( (string_to_number(I[0:32]) + string_to_number(k)) % order , order )
|
|
c_n = I[32:]
|
|
return k_n, c_n
|
|
|
|
# Child public key derivation function (from public key only)
|
|
# K = master public key
|
|
# c = master chain code
|
|
# n = index of key we want to derive
|
|
# This function allows us to find the nth public key, as long as n is
|
|
# non-negative. If n is negative, we need the master private key to find it.
|
|
def CKD_pub(cK, c, n):
|
|
if n & BIP32_PRIME: raise
|
|
return _CKD_pub(cK, c, bfh(rev_hex(int_to_hex(n,4))))
|
|
|
|
# helper function, callable with arbitrary string
|
|
def _CKD_pub(cK, c, s):
|
|
order = generator_secp256k1.order()
|
|
I = hmac.new(c, cK + s, hashlib.sha512).digest()
|
|
curve = SECP256k1
|
|
pubkey_point = string_to_number(I[0:32])*curve.generator + ser_to_point(cK)
|
|
public_key = ecdsa.VerifyingKey.from_public_point( pubkey_point, curve = SECP256k1 )
|
|
c_n = I[32:]
|
|
cK_n = GetPubKey(public_key.pubkey,True)
|
|
return cK_n, c_n
|
|
|
|
|
|
def xprv_header(xtype, *, net=None):
|
|
if net is None:
|
|
net = constants.net
|
|
return bfh("%08x" % net.XPRV_HEADERS[xtype])
|
|
|
|
|
|
def xpub_header(xtype, *, net=None):
|
|
if net is None:
|
|
net = constants.net
|
|
return bfh("%08x" % net.XPUB_HEADERS[xtype])
|
|
|
|
|
|
def serialize_xprv(xtype, c, k, depth=0, fingerprint=b'\x00'*4,
|
|
child_number=b'\x00'*4, *, net=None):
|
|
xprv = xprv_header(xtype, net=net) \
|
|
+ bytes([depth]) + fingerprint + child_number + c + bytes([0]) + k
|
|
return EncodeBase58Check(xprv)
|
|
|
|
|
|
def serialize_xpub(xtype, c, cK, depth=0, fingerprint=b'\x00'*4,
|
|
child_number=b'\x00'*4, *, net=None):
|
|
xpub = xpub_header(xtype, net=net) \
|
|
+ bytes([depth]) + fingerprint + child_number + c + cK
|
|
return EncodeBase58Check(xpub)
|
|
|
|
|
|
def deserialize_xkey(xkey, prv, *, net=None):
|
|
if net is None:
|
|
net = constants.net
|
|
xkey = DecodeBase58Check(xkey)
|
|
if len(xkey) != 78:
|
|
raise BaseException('Invalid length')
|
|
depth = xkey[4]
|
|
fingerprint = xkey[5:9]
|
|
child_number = xkey[9:13]
|
|
c = xkey[13:13+32]
|
|
header = int('0x' + bh2u(xkey[0:4]), 16)
|
|
headers = net.XPRV_HEADERS if prv else net.XPUB_HEADERS
|
|
if header not in headers.values():
|
|
raise BaseException('Invalid xpub format', hex(header))
|
|
xtype = list(headers.keys())[list(headers.values()).index(header)]
|
|
n = 33 if prv else 32
|
|
K_or_k = xkey[13+n:]
|
|
return xtype, depth, fingerprint, child_number, c, K_or_k
|
|
|
|
|
|
def deserialize_xpub(xkey, *, net=None):
|
|
return deserialize_xkey(xkey, False, net=net)
|
|
|
|
def deserialize_xprv(xkey, *, net=None):
|
|
return deserialize_xkey(xkey, True, net=net)
|
|
|
|
def xpub_type(x):
|
|
return deserialize_xpub(x)[0]
|
|
|
|
|
|
def is_xpub(text):
|
|
try:
|
|
deserialize_xpub(text)
|
|
return True
|
|
except:
|
|
return False
|
|
|
|
|
|
def is_xprv(text):
|
|
try:
|
|
deserialize_xprv(text)
|
|
return True
|
|
except:
|
|
return False
|
|
|
|
|
|
def xpub_from_xprv(xprv):
|
|
xtype, depth, fingerprint, child_number, c, k = deserialize_xprv(xprv)
|
|
K, cK = get_pubkeys_from_secret(k)
|
|
return serialize_xpub(xtype, c, cK, depth, fingerprint, child_number)
|
|
|
|
|
|
def bip32_root(seed, xtype):
|
|
I = hmac.new(b"Bitcoin seed", seed, hashlib.sha512).digest()
|
|
master_k = I[0:32]
|
|
master_c = I[32:]
|
|
K, cK = get_pubkeys_from_secret(master_k)
|
|
xprv = serialize_xprv(xtype, master_c, master_k)
|
|
xpub = serialize_xpub(xtype, master_c, cK)
|
|
return xprv, xpub
|
|
|
|
|
|
def xpub_from_pubkey(xtype, cK):
|
|
assert cK[0] in [0x02, 0x03]
|
|
return serialize_xpub(xtype, b'\x00'*32, cK)
|
|
|
|
|
|
def bip32_derivation(s):
|
|
assert s.startswith('m/')
|
|
s = s[2:]
|
|
for n in s.split('/'):
|
|
if n == '': continue
|
|
i = int(n[:-1]) + BIP32_PRIME if n[-1] == "'" else int(n)
|
|
yield i
|
|
|
|
def is_bip32_derivation(x):
|
|
try:
|
|
[ i for i in bip32_derivation(x)]
|
|
return True
|
|
except :
|
|
return False
|
|
|
|
def bip32_private_derivation(xprv, branch, sequence):
|
|
assert sequence.startswith(branch)
|
|
if branch == sequence:
|
|
return xprv, xpub_from_xprv(xprv)
|
|
xtype, depth, fingerprint, child_number, c, k = deserialize_xprv(xprv)
|
|
sequence = sequence[len(branch):]
|
|
for n in sequence.split('/'):
|
|
if n == '': continue
|
|
i = int(n[:-1]) + BIP32_PRIME if n[-1] == "'" else int(n)
|
|
parent_k = k
|
|
k, c = CKD_priv(k, c, i)
|
|
depth += 1
|
|
_, parent_cK = get_pubkeys_from_secret(parent_k)
|
|
fingerprint = hash_160(parent_cK)[0:4]
|
|
child_number = bfh("%08X"%i)
|
|
K, cK = get_pubkeys_from_secret(k)
|
|
xpub = serialize_xpub(xtype, c, cK, depth, fingerprint, child_number)
|
|
xprv = serialize_xprv(xtype, c, k, depth, fingerprint, child_number)
|
|
return xprv, xpub
|
|
|
|
|
|
def bip32_public_derivation(xpub, branch, sequence):
|
|
xtype, depth, fingerprint, child_number, c, cK = deserialize_xpub(xpub)
|
|
assert sequence.startswith(branch)
|
|
sequence = sequence[len(branch):]
|
|
for n in sequence.split('/'):
|
|
if n == '': continue
|
|
i = int(n)
|
|
parent_cK = cK
|
|
cK, c = CKD_pub(cK, c, i)
|
|
depth += 1
|
|
fingerprint = hash_160(parent_cK)[0:4]
|
|
child_number = bfh("%08X"%i)
|
|
return serialize_xpub(xtype, c, cK, depth, fingerprint, child_number)
|
|
|
|
|
|
def bip32_private_key(sequence, k, chain):
|
|
for i in sequence:
|
|
k, chain = CKD_priv(k, chain, i)
|
|
return k
|
|
|