def ComputeChecksum(data_bytes):
""" Compute Base58 checksum.
Args:
data_bytes (bytes): Data bytes
Returns:
bytes: Computed checksum
"""
return CryptoUtils.Sha256(
CryptoUtils.Sha256(data_bytes))[:Base58Const.CHECKSUM_BYTE_LEN]
def FromEntropy(entropy_bytes: bytes) -> str:
""" Generate mnemonic from the specified entropy bytes.
Args:
entropy_bytes (bytes): Entropy bytes (accepted lengths in bits: 128, 160, 192, 224, 256)
Returns:
str: Generated mnemonic from specified entropy
Raises:
ValueError: If entropy length is not valid
"""
# Check entropy length in bits
entropy_bit_len = len(entropy_bytes) * 8
if entropy_bit_len not in Bip39Const.ENTROPY_BIT_LEN:
raise ValueError("Entropy length in bits (%d) is not valid" %
entropy_bit_len)
# Compute entropy hash
entropy_hash_bytes = CryptoUtils.Sha256(entropy_bytes)
# Convert entropy to binary string
entropy_bin = ConvUtils.BytesToBinaryStr(entropy_bytes,
len(entropy_bytes) * 8)
# Convert entropy hash to binary string
entropy_hash_bin = ConvUtils.BytesToBinaryStr(
entropy_hash_bytes,
CryptoUtils.Sha256DigestSize() * 8)
# Get checksum binary string
checksum_bin = entropy_hash_bin[:len(entropy_bytes) // 4]
# Create mnemonic entropy binary string by concatenating entropy and checksum, as specified in BIP39
mnemonic_entropy_bin = entropy_bin + checksum_bin
# Create mnemonic reader
mnemonic_reader = MnemonicFileReader()
# Empty mnemonic
mnemonic = []
# Get mnemonic from entropy
for i in range(len(mnemonic_entropy_bin) // Bip39Const.WORD_BITS):
# Get current word index
word_idx = int(
mnemonic_entropy_bin[i * Bip39Const.WORD_BITS:(i + 1) *
Bip39Const.WORD_BITS], 2)
# Get word at given index
mnemonic.append(mnemonic_reader.GetWordAtIdx(word_idx))
# Join to string
return " ".join(mnemonic)
def AddScriptSig(pub_key_bytes):
""" Add script signature to public key and get address bytes.
Args:
pub_key_bytes (bytes) : Public key bytes
Returns:
bytes: Address bytes
"""
# Key hash: Hash160(public_key)
key_hash = CryptoUtils.Hash160(pub_key_bytes)
# Script signature: 0x0014 | Hash160(public_key)
script_sig = binascii.unhexlify(P2SHConst.SCRIPT_BYTES) + key_hash
# Address bytes = Hash160(script_signature)
return CryptoUtils.Hash160(script_sig)
def KeyIdentifier(self):
""" Get key identifier.
Returns:
bytes: Key identifier bytes
"""
return CryptoUtils.Hash160(self.PublicKey().RawCompressed().ToBytes())
def FromSeed(seed_bytes, key_net_ver=Bip32Conf.KEY_NET_VER.Main()):
""" Create a Bip32 object from the specified seed (e.g. BIP39 seed).
Args:
seed_bytes (bytes) : Seed bytes
key_net_ver (KeyNetVersions object, optional): Key net version object (Bip32 main net version by default)
Returns:
Bip32 object: Bip32 object
Raises:
ValueError: If the seed is too short
Bip32KeyError: If the seed is not suitable for master key generation
"""
# Check seed length
if len(seed_bytes) * 8 < Bip32Const.SEED_MIN_BIT_LEN:
raise ValueError(
"Seed length is too small, it shall be at least %d bit" %
Bip32Const.SEED_MIN_BIT_LEN)
# Compute HMAC
hmac = CryptoUtils.HmacSha512(Bip32Const.MASTER_KEY_HMAC_KEY,
seed_bytes)
# Create BIP32 by splitting the HMAC into two 32-byte sequences
return Bip32(secret=hmac[:32],
chain=hmac[32:],
key_net_ver=key_net_ver)
def get_default_coin(private_key):
decoded_wif = WifDecoder.Decode(wif_str=private_key,
net_addr_ver=CLUB_WIF_NET_VER.Main())
bip44_mst = Bip44.FromAddressPrivKey(decoded_wif, Bip44Coins.BITCOIN)
pub_key_bytes = bip44_mst.PublicKey().RawCompressed().ToBytes()
address = Base58Encoder.CheckEncode(CLUB_P2PKH_NET_VER.Main() +
CryptoUtils.Hash160(pub_key_bytes))
return CryptoCoin(address, private_key)
def get_uncompressed_coin(private_key):
print("Warning Uncompressed key")
decoded_wif = WifDecoder.Decode(wif_str=private_key,
net_addr_ver=CLUB_WIF_NET_VER.Main())
bip44_mst = Bip44.FromAddressPrivKey(decoded_wif, Bip44Coins.BITCOIN)
to_hex = bip44_mst.PublicKey().RawUncompressed().ToBytes()
pub_key_bytes = b'\x04' + to_hex
address = Base58Encoder.CheckEncode(CLUB_P2PKH_NET_VER.Main() +
CryptoUtils.Hash160(pub_key_bytes))
return CryptoCoin(address, private_key)
def __ComputeChecksum(self,
mnemonic_bin_str: str) -> str:
""" Compute checksum from mnemonic binary string.
Args:
mnemonic_bin_str (str): Mnemonic binary string
Returns:
str: Computed checksum binary string
"""
# Get entropy bytes
entropy_bytes = self.__GetEntropyBytes(mnemonic_bin_str)
# Convert entropy hash to binary string
entropy_hash_bin = ConvUtils.BytesToBinaryStr(CryptoUtils.Sha256(entropy_bytes),
CryptoUtils.Sha256DigestSize() * 8)
# Compute checksum
checksum_bin = entropy_hash_bin[:self.__GetChecksumLen(mnemonic_bin_str)]
return checksum_bin
def get_uncompressed_coin(private_key):
print("Warning Uncompressed key")
config_alias = DashConf
coin_type = Bip44Coins.DASH
decoded_wif = WifDecoder.Decode(
wif_str=private_key, net_addr_ver=config_alias.WIF_NET_VER.Main())
bip44_mst = Bip44.FromAddressPrivKey(decoded_wif, coin_type)
to_hex = bip44_mst.PublicKey().RawUncompressed().ToBytes()
pub_key_bytes = b'\x04' + to_hex
address = Base58Encoder.CheckEncode(config_alias.P2PKH_NET_VER.Main() +
CryptoUtils.Hash160(pub_key_bytes))
return CryptoCoin(address, private_key)
def __HmacHalves(self, data_bytes):
""" Calculate the HMAC-SHA512 of input data using the chain code as key and returns a tuple of the left and right halves of the HMAC.
Args:
data_bytes (bytes): Data bytes
Returns:
tuple: Left and right halves of the HMAC
"""
# Use chain as HMAC key
hmac = CryptoUtils.HmacSha512(self.m_chain, data_bytes)
return (hmac[:32], hmac[32:])
def get_uncompressed_coin(private_key):
print("Warning Uncompressed key")
config_alias = BitcoinConf
coin_type = Bip44Coins.BITCOIN
decodedWif = WifDecoder.Decode(
wif_str=private_key, net_addr_ver=config_alias.WIF_NET_VER.Main())
bip44_mst = Bip44.FromAddressPrivKey(decodedWif, coin_type)
to_hex = bip44_mst.PublicKey().RawUncompressed().ToBytes()
pub_key_bytes = b'\x04' + to_hex
legacy_address = Base58Encoder.CheckEncode(
config_alias.P2PKH_NET_VER.Main() +
CryptoUtils.Hash160(pub_key_bytes))
address = convert.to_cash_address(legacy_address).replace(
'bitcoincash:', '')
return CryptoCoin(address, private_key)
def Generate(self, passphrase = ""):
""" Generate the seed using the specified passphrase.
Args:
passphrase (str, optional): Passphrase, empty if not specified
Returns:
bytes: Generated seed
"""
# Get salt
salt = Bip39Const.SEED_SALT_MOD + passphrase
# Compute key
key = CryptoUtils.Pbkdf2HmacSha512(AlgoUtils.StringEncode(self.m_mnemonic), AlgoUtils.StringEncode(salt), Bip39Const.SEED_PBKDF2_ROUNDS)
return key[:Bip39Const.SEED_LEN]
def ToAddress(pub_key_bytes: bytes) -> str:
""" Get address in Atom format.
Args:
pub_key_bytes (bytes) : Public key bytes
Returns:
str: Address string
Raises:
ValueError: If key is not a public compressed key
"""
if not KeyUtils.IsPublicCompressed(pub_key_bytes):
raise ValueError(
"Public compressed key is required for Avax address")
return AvaxBech32Encoder.Encode(CryptoUtils.Hash160(pub_key_bytes),
AvaxChainTypes.AVAX_P_CHAIN)
def ToAddress(pub_key_bytes: bytes,
net_addr_ver: str = BitcoinConf.P2WPKH_NET_VER.Main()) -> str:
""" Get address in P2WPKH format.
Args:
pub_key_bytes (bytes) : Public key bytes
net_addr_ver (str, optional): Net address version, default is Bitcoin main network
Returns:
str: Address string
Raises:
ValueError: If key is not a public compressed key
"""
if not KeyUtils.IsPublicCompressed(pub_key_bytes):
raise ValueError("Public compressed key is required for P2WPKH")
return SegwitBech32Encoder.Encode(net_addr_ver, P2WPKHConst.WITNESS_VER, CryptoUtils.Hash160(pub_key_bytes))
def ToAddress(pub_key_bytes: bytes, hrp: str) -> str:
""" Get address in Atom format.
Args:
pub_key_bytes (bytes): Public key bytes
hrp (str) : HRP
Returns:
str: Address string
Raises:
ValueError: If key is not a public compressed key
"""
if not KeyUtils.IsPublicCompressed(pub_key_bytes):
raise ValueError(
"Public compressed key is required for Atom address")
return AtomBech32Encoder.Encode(hrp,
CryptoUtils.Hash160(pub_key_bytes))
def generate(self):
# Generate random mnemonic
mnemonic = Bip39MnemonicGenerator.FromWordsNumber(12)
# Generate seed from mnemonic
seed_bytes = Bip39SeedGenerator(mnemonic).Generate()
# Generate BIP44 master keys
bip_obj_mst = Bip44.FromSeed(seed_bytes, Bip44Coins.BITCOIN)
wif = WifEncoder.Encode(bip_obj_mst.PrivateKey().Raw().ToBytes(), True,
POTE_WIF_NET_VER.Main())
pub_key_bytes = bip_obj_mst.PublicKey().RawCompressed().ToBytes()
address = Base58Encoder.CheckEncode(POTE_P2PKH_NET_VER.Main() +
CryptoUtils.Hash160(pub_key_bytes))
seed = mnemonic
return CryptoCoin(address, wif, seed)
def ToAddress(pub_key_bytes: bytes, hrp: str, net_addr_ver: bytes) -> str:
""" Get address in Bitcoin Cash P2PKH format.
Args:
pub_key_bytes (bytes): Public key bytes
hrp (str) : HRP
net_addr_ver (bytes) : Net address version
Returns:
str: Address string
Raises:
ValueError: If key is not a public compressed key
"""
if not KeyUtils.IsPublicCompressed(pub_key_bytes):
raise ValueError(
"Public compressed key is required for Bitcoin Cash")
return BchBech32Encoder.Encode(hrp, net_addr_ver,
CryptoUtils.Hash160(pub_key_bytes))
def ToAddress(pub_key_bytes,
net_addr_ver=BitcoinConf.P2PKH_NET_VER.Main(),
base58_alph=Base58Alphabets.BITCOIN):
""" Get address in P2PKH format.
Args:
pub_key_bytes (bytes) : Public key bytes
net_addr_ver (bytes, optional) : Net address version, default is Bitcoin main network
base58_alph (Base58Alphabets, optional): Base58 alphabet, Bitcoin by default
Returns:
str: Address string
Raises:
ValueError: If the key is not a public compressed key
"""
if not KeyUtils.IsPublicCompressed(pub_key_bytes):
raise ValueError("Public compressed key is required for P2PKH")
return Base58Encoder.CheckEncode(
net_addr_ver + CryptoUtils.Hash160(pub_key_bytes), base58_alph)
