class TransactionInput(base.Base):
transaction = base.UInt128()
index = base.UInt16()
signature = base.UInt512()
def verify(self):
try:
output = BlockChain().get_output_from_input(self)
pubkey = ECC.import_key(bytes.fromhex(output.wallet))
except Exception as error:
raise InvalidOutputReferenceError from error
verifier = DSS.new(pubkey, "fips-186-3")
# privkey = ECC.import_key(key)
# signer = DSS.new(privkey, "fips-186-3")
hash_ = SHA256.new(output.serialize())
try:
verifier.verify(hash_, self.signature.to_bytes(64, "little"))
except ValueError as check_fail:
raise SecretError from check_fail
def sign(self, wallet):
private_key = ECC.import_key(bytes.fromhex(wallet.private_key))
signer = DSS.new(private_key, 'fips-186-3')
output = BlockChain().get_output_from_input(self)
hash_ = SHA256.new(output.serialize())
self.signature = int.from_bytes(signer.sign(hash_), "little")
class TransactionOutput(base.Base):
ID = base.UInt128()
wallet = base.String()
amount = base.UInt64()
extra_data = base.String()
def __init__(self, **kwargs):
kwargs.setdefault("ID", int(uuid.uuid4()))
super().__init__(**kwargs)
class Transaction(base.Base):
ID = base.UInt128()
inputs = base.SequenceField(TransactionInput)
outputs = base.SequenceField(TransactionOutput)
signature = base.UInt512()
transaction_type = base.UInt8()
def __init__(self, **kwargs):
kwargs.setdefault("ID", int(uuid.uuid4()))
kwargs.setdefault(
"transaction_type",
0) # 0 indicates normal transaction. 1 is for reward transaction
self.blockchain = BlockChain()
super().__init__(**kwargs)
def get_fee(self):
self.verify()
if self.transaction_type == 1:
# Reward transaction - balance comes out of thin air
return 0
bl = BlockChain()
input_amount = sum(
bl.get_output_from_input(inp).amount for inp in self.inputs)
output_amount = sum(out.amount for out in self.outputs)
if output_amount > input_amount:
raise AmountError(
f"Total fee is negative '{output_amount - input_amount}'")
return input_amount - output_amount
def verify(self):
for input in self.inputs:
input.verify()
self.verify_transaction_signature()
def verify_transaction_signature(self):
if self.transaction_type == 1:
return
wallet = BlockChain().get_output_from_input(self.inputs[0]).wallet
pubkey = ECC.import_key(bytes.fromhex(wallet))
verifier = DSS.new(pubkey, "fips-186-3")
signature = self.signature
self.signature = 0
hash_ = SHA256.new(self.serialize())
self.signature = signature
try:
verifier.verify(hash_, signature.to_bytes(64, "little"))
except ValueError as check_fail:
raise SecretError("Invalid transaction signature")
def sign_transaction(self, wallets):
"""
Sign transaction with private key
# based on https://github.com/adilmoujahid/blockchain-python-tutorial/blob/master/blockchain_client/blockchain_client.py
"""
from .wallet import Wallet
if isinstance(wallets, (Sequence, Iterable)):
wallets = {wallet.public_key: wallet for wallet in wallets}
elif isinstance(wallets, Wallet):
wallets = {wallets.public_key: wallets}
for input in self.inputs:
output = BlockChain().get_output_from_input(input)
try:
input.sign(wallets[output.wallet])
except KeyError as error:
raise WalletError from error
# Use the wallet used for the first input to sign the whole transaction
if self.inputs:
signer_wallet = BlockChain().get_output_from_input(
self.inputs[0]).wallet
wallet = wallets[signer_wallet]
elif self.transaction_type == 1: # we have input if we are a reward transaction
wallet = next(iter(wallets.values()))
else:
raise TransactionError("Trying to sign transaction with no input")
private_key = ECC.import_key(bytes.fromhex(wallet.private_key))
signer = DSS.new(private_key, 'fips-186-3')
self.signature = 0
hash_ = SHA256.new(self.serialize())
self.signature = int.from_bytes(signer.sign(hash_), "little")
class Block(base.Base):
number = base.UInt32()
previous_block = base.UInt256()
transactions = base.SequenceField(Transaction)
nonce = base.UInt128()
difficulty = base.UInt256()
def __init__(self, **kwargs):
kwargs.setdefault("difficulty", registry["network_difficulty"])
super().__init__(**kwargs)
self.state = "new"
def prepare(self):
"""Prepares block acording to current chain so
that it gets ready to be mined.
If no transactions have been manually added prior to calling
this, will pick all transactions in the blockchain pool.
"""
if not self.transactions:
self.fetch_transactions()
previous_block = BlockChain()[-1]
self.previous_block = int.from_bytes(previous_block.hash(), "big")
self.number = previous_block.number + 1
self.make_reward()
def fetch_transactions(self):
bl = BlockChain()
self.transactions.fill(bl.transaction_pool.values())
def set_previous(self, block):
self.previous_block = sha256(block.serialize()).digest()
def make_reward(self):
from .wallet import Wallet
reward = registry["coin_reward"]
target_wallet = registry["miner_public_key"]
server_wallet = Wallet.from_data(registry["server_wallet"])
fees = sum(transaction.get_fee() for transaction in self.transactions)
out1 = TransactionOutput(wallet=target_wallet,
amount=reward * TOKENMULTIPLIER,
extra_data="Mining Reward")
out2 = TransactionOutput(wallet=target_wallet,
amount=fees,
extra_data="Mining Fees")
tr = Transaction()
tr.transaction_type = 1 # Reward transaction
tr.outputs.append(out1)
tr.outputs.append(out2)
tr.sign_transaction(server_wallet)
self.transactions.append(tr)
def check_difficulty(self):
difficulty = (2**256 - 1) // self.difficulty
return int.from_bytes(self.hash(), "big") <= difficulty
def hash(self):
# This is what makes one "mining attempt"
hash_ = SHA256.new(self.serialize())
return hash_.digest()
def __hash__(self):
# Python coerces the return value of this to Int64
return self.hash()
def verify(self):
first = True
for transaction in reversed(self.transactions):
if transaction.transaction_type == 1 and not first:
raise BlockError(
"Reward transaction not as last of transactions list")
transaction.verify()
first = False
if not self.check_difficulty():
raise BlockError("Block hash do not match its set difficulty")
