def test_signature_hash(filename):
tx, values, pk_scripts = read_json_tx(filename)
correct_hashes = read_signature_hashes(
filename.replace('.txn', '.sig_hashes'))
n = 0
for input_index, (value, pk_script,
txin) in enumerate(zip(values, pk_scripts, tx.inputs)):
for sighash in range(256):
sighash = SigHash(sighash)
if sighash.has_forkid():
signature_hash = tx.signature_hash(input_index, value,
pk_script, sighash)
assert signature_hash == correct_hashes[n]
n += 1
def test_issue(priv_key,
receiver,
new_issuer=issuer,
next_tok_id=curr_token_id + 1,
issued_tok_id=curr_token_id):
context = scryptlib.utils.create_dummy_input_context()
context.utxo.script_pubkey = token.locking_script
context.utxo.value = input_sats
new_data_part = b'\x23' + scryptlib.utils.get_push_int(next_tok_id)[1:] + \
new_issuer.to_bytes() + action_issue
new_locking_script = Script(token.code_part.to_bytes() + new_data_part)
tx_out = TxOutput(value=out_sats, script_pubkey=new_locking_script)
context.tx.outputs.append(tx_out)
new_data_part = b'\x23' + scryptlib.utils.get_push_int(issued_tok_id)[1:] + \
receiver.to_bytes() + action_transfer
new_locking_script = Script(token.code_part.to_bytes() + new_data_part)
tx_out = TxOutput(value=out_sats, script_pubkey=new_locking_script)
context.tx.outputs.append(tx_out)
sighash_flag = SigHash(SigHash.ALL | SigHash.FORKID)
sighash = context.tx.signature_hash(0, input_sats,
token.locking_script, sighash_flag)
sig = priv_key.sign(sighash, hasher=None)
sig = sig + pack_byte(sighash_flag)
preimage = scryptlib.utils.get_preimage_from_input_context(
context, sighash_flag)
return token.issue(Sig(sig), PubKey(receiver), out_sats, out_sats,
SigHashPreimage(preimage)).verify(context)
def preimage_hash(self, txin):
input_index = self.inputs.index(txin)
script_code = bytes.fromhex(self.get_preimage_script(txin))
sighash = SigHash(self.nHashType())
# Original BTC algorithm: https://en.bitcoin.it/wiki/OP_CHECKSIG
# Current algorithm: https://github.com/moneybutton/bips/blob/master/bip-0143.mediawiki
return self.signature_hash(input_index, txin.value, script_code, sighash=sighash)
def test_verify_scenario_2():
context = scryptlib.utils.create_dummy_input_context()
context.utxo.script_pubkey = escrow.locking_script
context.utxo.value = input_sats
change_out = TxOutput(int(input_sats - fee),
P2PKH_Address(pkh_A, Bitcoin).to_script())
context.tx.outputs.append(change_out)
sighash_flag = SigHash(SigHash.ALL | SigHash.FORKID)
sighash = context.tx.signature_hash(0, input_sats, escrow.locking_script,
sighash_flag)
sig_A = key_priv_A.sign(sighash, hasher=None)
sig_A = sig_A + pack_byte(sighash_flag)
sig_E = key_priv_E.sign(sighash, hasher=None)
sig_E = sig_E + pack_byte(sighash_flag)
preimage = scryptlib.utils.get_preimage_from_input_context(
context, sighash_flag)
verify_result = escrow.unlock(SigHashPreimage(preimage), PubKey(key_pub_A),
Sig(sig_A), PubKey(key_pub_E), Sig(sig_E),
Bytes(secret0)).verify(context)
assert verify_result == True
# Wrong secret
with pytest.raises(bitcoinx.VerifyFailed):
verify_result = escrow.unlock(SigHashPreimage(preimage),
PubKey(key_pub_A), Sig(sig_A),
PubKey(key_pub_E), Sig(sig_E),
Bytes(secret1)).verify(context)
def get_preimage(tx, input_index, utxo_value, utxo_script, sighash_flag=None):
if not sighash_flag:
sighash_flag = SigHash(SigHash.ALL | SigHash.FORKID)
txin = tx.inputs[input_index]
hash_prevouts = hash_sequence = hash_outputs = bitcoinx.consts.ZERO
sighash_not_single_none = sighash_flag.base not in (SigHash.SINGLE, SigHash.NONE)
if not sighash_flag.anyone_can_pay:
hash_prevouts = tx._hash_prevouts()
if sighash_not_single_none:
hash_sequence = tx._hash_sequence()
if sighash_not_single_none:
hash_outputs = tx._hash_outputs()
elif (sighash_flag.base == SigHash.SINGLE and input_index < len(tx.outputs)):
hash_outputs = double_sha256(tx.outputs[input_index].to_bytes())
preimage = b''.join((
pack_le_int32(tx.version),
hash_prevouts,
hash_sequence,
txin.to_bytes_for_signature(utxo_value, utxo_script),
hash_outputs,
pack_le_uint32(tx.locktime),
pack_le_uint32(sighash_flag),
))
return preimage
def test_verify_with_change():
deposit_sats = 100000
input_sats = 100000
output_sats = deposit_sats + input_sats
change_sats = 547
faucet.set_data_part(scryptlib.utils.get_push_int(1602553516))
context = scryptlib.utils.create_dummy_input_context()
context.utxo.script_pubkey = faucet.locking_script
context.utxo.value = input_sats
tx_out_0 = TxOutput(value=output_sats, script_pubkey=faucet.locking_script)
context.tx.outputs.append(tx_out_0)
tx_out_1 = TxOutput(value=change_sats,
script_pubkey=P2PKH_Address(pkh, Bitcoin).to_script())
context.tx.outputs.append(tx_out_1)
sighash_flag = SigHash(SigHash.ALL | SigHash.FORKID)
preimage = scryptlib.utils.get_preimage_from_input_context(
context, sighash_flag)
verify_result = faucet.deposit(SigHashPreimage(preimage), deposit_sats,
Ripemd160(pkh), change_sats).verify(context)
assert verify_result == True
with pytest.raises(bitcoinx.VerifyFailed):
faucet.deposit(SigHashPreimage(preimage), deposit_sats, Ripemd160(pkh),
change_sats + 1).verify(context)
def preimage_hash(self, txin):
input_index = self.inputs.index(txin)
script_code = bytes.fromhex(self.get_preimage_script(txin))
sighash = SigHash(self.nHashType())
return self.signature_hash(input_index,
txin.value,
script_code,
sighash=sighash)
def test_verify_p2pkh_correct():
context = scryptlib.utils.create_dummy_input_context()
sighash_flag = SigHash(SigHash.ALL | SigHash.FORKID)
sighash = context.tx.signature_hash(0, context.utxo.value,
asm.locking_script, sighash_flag)
sig = key_priv.sign(sighash, hasher=None)
sig = sig + pack_byte(sighash_flag)
verify_result = asm.p2pkh(Sig(sig), PubKey(key_pub)).verify(context)
assert verify_result == True
def get_preimage_from_input_context(context, sighash_flag=None):
if not sighash_flag:
sighash_flag = SigHash(SigHash.ALL | SigHash.FORKID)
tx = context.tx
input_index = context.input_index
utxo_value = context.utxo.value
utxo_script = context.utxo.script_pubkey
return get_preimage(tx, input_index, utxo_value, utxo_script, sighash_flag)
def increment_counter(counter_obj, prev_txid, prev_out_idx, funding_txid,
funding_out_idx, unlock_key_priv, miner_fee):
# Get data from previous counter tx
r = requests.get('https://api.whatsonchain.com/v1/bsv/main/tx/{}'.format(
prev_txid)).json()
prev_locking_script = Script.from_hex(
r['vout'][prev_out_idx]['scriptPubKey']['hex'])
prev_counter_bytes = list(prev_locking_script.ops())[-1]
prev_counter_val = int.from_bytes(prev_counter_bytes, 'little')
unlocked_satoshis_counter = int(r['vout'][prev_out_idx]['value'] * 10**8)
# Get data from funding tx
r = requests.get('https://api.whatsonchain.com/v1/bsv/main/tx/{}'.format(
funding_txid)).json()
funding_locking_script = Script.from_hex(
r['vout'][funding_out_idx]['scriptPubKey']['hex'])
unlocked_satoshis_funding = int(r['vout'][funding_out_idx]['value'] *
10**8)
# Set data for next iteration
counter_obj.set_data_part(
scryptlib.utils.get_push_int(prev_counter_val + 1))
## Construct tx
n_sequence = 0xffffffff
# Counter input and output
prev_tx_hash = hex_str_to_hash(prev_txid)
counter_in = TxInput(prev_tx_hash, prev_out_idx, None, n_sequence)
out_satoshis = unlocked_satoshis_counter + unlocked_satoshis_funding - miner_fee
contract_out = TxOutput(out_satoshis, counter_obj.locking_script)
# Funding input
funding_tx_hash = hex_str_to_hash(funding_txid)
funding_in = TxInput(funding_tx_hash, funding_out_idx, None, n_sequence)
tx = Tx(2, [counter_in, funding_in], [contract_out], 0x00000000)
# Set input script to unlock previous counter
sighash_flag = SigHash(SigHash.ALL | SigHash.FORKID)
preimage = scryptlib.utils.get_preimage(tx, 0, unlocked_satoshis_counter,
prev_locking_script, sighash_flag)
increment_func_call = counter_obj.increment(SigHashPreimage(preimage),
Int(out_satoshis))
tx.inputs[0].script_sig = increment_func_call.script
# Set input script to unlock funding output
unlock_key_pub = unlock_key_priv.public_key
sighash = tx.signature_hash(1, unlocked_satoshis_funding,
funding_locking_script, sighash_flag)
sig = unlock_key_priv.sign(sighash, hasher=None)
sig = sig + pack_byte(sighash_flag)
unlock_script = Script() << sig << unlock_key_pub.to_bytes()
tx.inputs[1].script_sig = unlock_script
broadcast_tx(tx)
def test_signatures(filename):
tx, values, pk_scripts = read_json_tx(filename)
for input_index, (value, pk_script,
txin) in enumerate(zip(values, pk_scripts, tx.inputs)):
signature, pubkey = txin.script_sig.ops()
pubkey = PublicKey.from_bytes(pubkey)
signature_hash = tx.signature_hash(input_index, value, pk_script,
SigHash(signature[-1]))
assert pubkey.verify_der_signature(signature[:-1], signature_hash,
None)
def test_verify_wrong_output():
context = scryptlib.utils.create_dummy_input_context()
context.utxo.script_pubkey = gol.locking_script
new_locking_script = Script(gol.code_part.to_bytes() + wb1)
tx_out = TxOutput(value=out_amount, script_pubkey=new_locking_script)
context.tx.outputs.append(tx_out)
sighash_flag = SigHash(SigHash.ALL | SigHash.FORKID)
preimage = scryptlib.utils.get_preimage_from_input_context(context, sighash_flag)
verify_result = gol.play(out_amount, SigHashPreimage(preimage)).verify(context)
assert verify_result == False
def test_signature_hash_bad():
tx, _, _ = read_json_tx('503fd37f.txn')
with pytest.raises(IndexError):
tx.signature_hash(-1, 5, b'', SigHash.ALL)
with pytest.raises(IndexError):
tx.signature_hash(2, 5, b'', SigHash.ALL)
with pytest.raises(ValueError):
tx.signature_hash(0, -1, b'', SigHash.ALL)
with pytest.raises(TypeError):
tx.signature_hash(0, 0, b'', 1)
tx.signature_hash(0, 0, b'', SigHash.NONE)
tx.signature_hash(1, 0, b'', SigHash(1))
def test_merge(input_idx, balance0, balance1):
context = scryptlib.utils.create_dummy_input_context()
context.utxo.value = in_sats
context.input_index = input_idx
tx_in = TxInput(context.tx.inputs[0].prev_hash, 1, Script(), 0xffffffff)
context.tx.inputs.append(tx_in)
prev_txid = context.tx.inputs[0].prev_hash
prevouts = prev_txid + b'\x00\x00\x00\x00' + prev_txid + b'\x01\x00\x00\x00'
new_locking_script = Script(token.code_part.to_bytes() + b'\x23' +
key_pub_2.to_bytes() + scryptlib.utils.get_push_int(balance0)[1:] + scryptlib.utils.get_push_int(balance1)[1:])
tx_out = TxOutput(value=out_sats, script_pubkey=new_locking_script)
context.tx.outputs.append(tx_out)
if input_idx == 0:
balance = balance1
context.utxo.script_pubkey = locking_script_0
key_to_sign = key_priv_0
token.set_data_part(b'\x23' + data_part_0)
else:
balance = balance0
context.utxo.script_pubkey = locking_script_1
key_to_sign = key_priv_1
token.set_data_part(b'\x23' + data_part_1)
sighash_flag = SigHash(SigHash.ALL | SigHash.FORKID)
#preimage = scryptlib.utils.get_preimage_from_input_context(context, sighash_flag)
if input_idx == 0:
preimage = scryptlib.utils.get_preimage(context.tx, input_idx, in_sats, locking_script_0, sighash_flag=sighash_flag)
else:
preimage = scryptlib.utils.get_preimage(context.tx, input_idx, in_sats, locking_script_1, sighash_flag=sighash_flag)
if input_idx == 0:
sighash = context.tx.signature_hash(input_idx, in_sats, locking_script_0, sighash_flag)
else:
sighash = context.tx.signature_hash(input_idx, in_sats, locking_script_1, sighash_flag)
sig = key_to_sign.sign(sighash, hasher=None)
sig = sig + pack_byte(sighash_flag)
return token.merge(
Sig(sig),
PubKey(key_pub_2),
Bytes(prevouts),
balance,
out_sats,
SigHashPreimage(preimage)
).verify(context)
def test_verify_incorrect_sat_amount():
context = scryptlib.utils.create_dummy_input_context()
context.utxo.script_pubkey = counter_obj.locking_script
subsequent_counter_val_bytes = scryptlib.utils.get_push_int(COUNTER_INITIAL_VAL + 1)
new_locking_script = counter_obj.code_part << Script(subsequent_counter_val_bytes)
tx_out = TxOutput(value=0, script_pubkey=new_locking_script)
context.tx.outputs.append(tx_out)
sighash_flag = SigHash(SigHash.ALL | SigHash.FORKID)
preimage = scryptlib.utils.get_preimage_from_input_context(context, sighash_flag)
new_output_satoshis = 100
verify_result = counter_obj.increment(SigHashPreimage(preimage), Int(new_output_satoshis)).verify(context)
assert verify_result == False
def test_sighash(execution_count):
'''Tests the original Satoshi signature_hash on random transactions.'''
hash_type = random.randrange(0, 1 << 32)
sighash_type = SigHash(hash_type)
tx = random_tx((hash_type & 0x1f) == SigHash.SINGLE)
script_code = random_script()
input_index = random.randrange(0, len(tx.inputs))
live_hash = tx._original_signature_hash(input_index, script_code,
sighash_type)
# ref_sighash modifies the tx so do it second
ref_hash = ref_sighash(script_code, tx, input_index, hash_type)
assert live_hash == ref_hash
def test_verify_correct_constructor():
context = scryptlib.utils.create_dummy_input_context()
context.utxo.script_pubkey = counter_obj.locking_script
new_locking_script = counter_obj.get_state_script(
{"counter": COUNTER_INITIAL_VAL + 1})
tx_out = TxOutput(value=0, script_pubkey=new_locking_script)
context.tx.outputs.append(tx_out)
sighash_flag = SigHash(SigHash.ALL | SigHash.FORKID)
preimage = scryptlib.utils.get_preimage_from_input_context(
context, sighash_flag)
new_output_satoshis = 0
verify_result = counter_obj.unlock(
SigHashPreimage(preimage), Int(new_output_satoshis)).verify(context)
assert verify_result == True
def test_split(key_priv, balance0, balance1, balance_input0=None, balance_input1=None):
if not balance_input0:
balance_input0 = balance0
if not balance_input1:
balance_input1 = balance1
context = scryptlib.utils.create_dummy_input_context()
context.utxo.script_pubkey = token.locking_script
context.utxo.value = in_sats
new_locking_script = Script(token.code_part.to_bytes() + b'\x23' +
key_pub_1.to_bytes() + b'\x00' + scryptlib.utils.get_push_int(balance0)[1:])
tx_out = TxOutput(value=out_sats, script_pubkey=new_locking_script)
context.tx.outputs.append(tx_out)
if balance1 > 0:
new_locking_script = Script(token.code_part.to_bytes() + b'\x23' +
key_pub_2.to_bytes() + b'\x00' + scryptlib.utils.get_push_int(balance1)[1:])
tx_out = TxOutput(value=out_sats, script_pubkey=new_locking_script)
context.tx.outputs.append(tx_out)
sighash_flag = SigHash(SigHash.ALL | SigHash.FORKID)
preimage = scryptlib.utils.get_preimage_from_input_context(context, sighash_flag)
input_idx = 0
utxo_satoshis = context.utxo.value
sighash = context.tx.signature_hash(input_idx, utxo_satoshis, token.locking_script, sighash_flag)
sig = key_priv.sign(sighash, hasher=None)
sig = sig + pack_byte(sighash_flag)
return token.split(
Sig(sig),
PubKey(key_pub_1),
balance_input0,
out_sats,
PubKey(key_pub_2),
balance_input1,
out_sats,
SigHashPreimage(preimage)
).verify(context)
def initialize_counter(counter_obj, counter_initial_val, funding_txid, funding_out_idx, \
unlock_key_priv, miner_fee, contract_out_sats, change_addr):
counter_obj.set_data_part(
scryptlib.utils.get_push_int(counter_initial_val))
# Funding TX
funding_tx_hash = hex_str_to_hash(funding_txid)
unlock_key_pub = unlock_key_priv.public_key
r = requests.get('https://api.whatsonchain.com/v1/bsv/main/tx/{}'.format(
funding_txid)).json()
funding_locking_script = Script.from_hex(
r['vout'][funding_out_idx]['scriptPubKey']['hex'])
unlocked_satoshis = int(r['vout'][funding_out_idx]['value'] * 10**8)
n_sequence = 0xffffffff
tx_input = TxInput(funding_tx_hash, funding_out_idx, None, n_sequence)
# Output with counter script code
contract_out = TxOutput(contract_out_sats, counter_obj.locking_script)
# Change output
tx_output_script = P2PKH_Address.from_string(change_addr,
Bitcoin).to_script()
change_out = TxOutput(unlocked_satoshis - miner_fee - contract_out_sats,
tx_output_script)
tx = Tx(2, [tx_input], [contract_out, change_out], 0x00000000)
# Create signature for input
sighash_flag = SigHash(SigHash.ALL | SigHash.FORKID)
sighash = tx.signature_hash(0, unlocked_satoshis, funding_locking_script,
sighash_flag)
sig = unlock_key_priv.sign(sighash, hasher=None)
sig = sig + pack_byte(sighash_flag)
# Set script for input
unlock_script = Script() << sig << unlock_key_pub.to_bytes()
tx.inputs[0].script_sig = unlock_script
broadcast_tx(tx)
pubkey_hash = key_pub.hash160()
wrong_key_priv = PrivateKey.from_arbitrary_bytes(b'somethingelse')
wrong_key_pub = wrong_key_priv.public_key
contract = './test/res/p2pkh.scrypt'
compiler_result = scryptlib.utils.compile_contract(contract)
desc = compiler_result.to_desc()
P2PKH = scryptlib.contract.build_contract_class(desc)
p2pkh_obj = P2PKH(PubKeyHash(pubkey_hash))
context = scryptlib.utils.create_dummy_input_context()
sighash_flag = SigHash(SigHash.ALL | SigHash.FORKID)
input_idx = 0
utxo_satoshis = context.utxo.value
sighash = context.tx.signature_hash(input_idx, utxo_satoshis,
p2pkh_obj.locking_script, sighash_flag)
def test_verify_correct_key():
sig = key_priv.sign(sighash, hasher=None)
sig = sig + pack_byte(sighash_flag)
verify_result = p2pkh_obj.unlock(Sig(sig), PubKey(key_pub)).verify(context)
assert verify_result == True
def test_verify_wrong():
sig = wrong_key_priv.sign(sighash, hasher=None)
payout_addr = pkh change_addr = pkh contract = './test/res/merkleToken.scrypt' compiler_result = scryptlib.utils.compile_contract(contract) desc = compiler_result.to_desc() input_sats = 100000 sat_price = 100 Token = scryptlib.contract.build_contract_class(desc) token = Token(sat_price) change_sats = 100 sighash_flag = SigHash(SigHash.ANYONE_CAN_PAY | SigHash.ALL | SigHash.FORKID) #def test_verify_buy_token(): # amount = 1 # new_entry = payout_addr + scryptlib.utils.get_push_int(amount)[1:] # last_entry = b'\x00' * 20 + b'\x01' # # last_entry_hash = hashlib.sha256(last_entry).digest() # new_entry_hash = hashlib.sha256(new_entry).digest() # # mixhash = hashlib.sha256(last_entry_hash + new_entry_hash).digest() # new_locking_script = token.code_part << Script(b'\x23' + scryptlib.utils.get_push_item(mixhash)) # last_merkle_path = Bytes(last_entry_hash + b'\x01') # # last_entry_double_hash = hashlib.sha256(last_entry_hash * 2).digest() # token.set_data_part(scryptlib.utils.get_push_item(last_entry_double_hash))
