def setUp(self):
setup('testnet')
self.txin = TxInput(
"76464c2b9e2af4d63ef38a77964b3b77e629dddefc5cb9eb1a3645b1608b790f",
0)
self.from_addr = P2pkhAddress('n4bkvTyU1dVdzsrhWBqBw8fEMbHjJvtmJR')
self.sk = PrivateKey(
'cTALNpTpRbbxTCJ2A5Vq88UxT44w1PE2cYqiB3n4hRvzyCev1Wwo')
self.p2pk_sk = PrivateKey(
'cRvyLwCPLU88jsyj94L7iJjQX5C2f8koG4G2gevN4BeSGcEvfKe9')
self.p2pk_redeem_script = Script(
[self.p2pk_sk.get_public_key().to_hex(), 'OP_CHECKSIG'])
self.txout = TxOutput(to_satoshis(0.09),
self.p2pk_redeem_script.to_p2sh_script_pub_key())
self.create_p2sh_and_send_result = '02000000010f798b60b145361aebb95cfcdedd29e6773b4b96778af33ed6f42a9e2b4c4676000000006b483045022100fd3a3fd4aeec5db0f3f9c5c5ef7f60f37920be7464a80edacbc3b6b9d0624173022031ce309330e60b19d39cec8c5597460c840adcdd66f7dbbf896eef3ec42b472f012102d82c9860e36f15d7b72aa59e29347f951277c21cd4d34822acdeeadbcff8a546ffffffff01405489000000000017a9142910fc0b1b7ab6c9789c5a67c22c5bcde5b903908700000000'
self.txin_spend = TxInput(
'7db363d5a7fabb64ccce154e906588f1936f34481223ea8c1f2c935b0a0c945b',
0)
# self.p2pk_sk , self.p2pk_redeem_script from above
self.to_addr = self.from_addr
self.txout2 = TxOutput(to_satoshis(0.08),
self.to_addr.to_script_pub_key())
self.spend_p2sh_result = '02000000015b940c0a5b932c1f8cea231248346f93f18865904e15cecc64bbfaa7d563b37d000000006c47304402204984c2089bf55d5e24851520ea43c431b0d79f90d464359899f27fb40a11fbd302201cc2099bfdc18c3a412afb2ef1625abad8a2c6b6ae0bf35887b787269a6f2d4d01232103a2fef1829e0742b89c218c51898d9e7cb9d51201ba2bf9d9e9214ebb6af32708acffffffff0100127a00000000001976a914fd337ad3bf81e086d96a68e1f8d6a0a510f8c24a88ac00000000'
# P2SH(CSV+P2PKH)
self.sk_csv_p2pkh = PrivateKey(
'cRvyLwCPLU88jsyj94L7iJjQX5C2f8koG4G2gevN4BeSGcEvfKe9')
self.seq = Sequence(TYPE_RELATIVE_TIMELOCK, 200)
self.txin_seq = TxInput(
'f557c623e55f0affc696b742630770df2342c4aac395e0ed470923247bc51b95',
0,
sequence=self.seq.for_input_sequence())
self.another_addr = P2pkhAddress('n4bkvTyU1dVdzsrhWBqBw8fEMbHjJvtmJR')
self.spend_p2sh_csv_p2pkh_result = '0200000001951bc57b24230947ede095c3aac44223df70076342b796c6ff0a5fe523c657f5000000008a483045022100c123775e69ec27094f7940facb9ad769c09f48a7fc88250a2fce67bd92c9b4cf02204ebdbed84af46e584fe6db9a23c420b7370879e883b555e119465f84bf34d82f012103a2fef1829e0742b89c218c51898d9e7cb9d51201ba2bf9d9e9214ebb6af327081e02c800b27576a914c3f8e5b0f8455a2b02c29c4488a550278209b66988acc80000000100ab9041000000001976a914fd337ad3bf81e086d96a68e1f8d6a0a510f8c24a88ac00000000'
def main():
# always remember to setup the network
setup('testnet')
# create transaction input from tx id of UTXO (contained 0.4 tBTC)
txin = TxInput(
'fb48f4e23bf6ddf606714141ac78c3e921c8c0bebeb7c8abb2c799e9ff96ce6c', 0)
# create transaction output using P2PKH scriptPubKey (locking script)
addr = P2pkhAddress('n4bkvTyU1dVdzsrhWBqBw8fEMbHjJvtmJR')
txout = TxOutput(
to_satoshis(0.1),
Script([
'OP_DUP', 'OP_HASH160',
addr.to_hash160(), 'OP_EQUALVERIFY', 'OP_CHECKSIG'
]))
# create another output to get the change - remaining 0.01 is tx fees
# note that this time we used to_script_pub_key() to create the P2PKH
# script
change_addr = P2pkhAddress('mmYNBho9BWQB2dSniP1NJvnPoj5EVWw89w')
change_txout = TxOutput(to_satoshis(0.29), change_addr.to_script_pub_key())
#change_txout = TxOutput(to_satoshis(0.29), Script(['OP_DUP', 'OP_HASH160',
# change_addr.to_hash160(),
# 'OP_EQUALVERIFY', 'OP_CHECKSIG']))
# create transaction from inputs/outputs -- default locktime is used
tx = Transaction([txin], [txout, change_txout])
# print raw transaction
print("\nRaw unsigned transaction:\n" + tx.serialize())
# use the private key corresponding to the address that contains the
# UTXO we are trying to spend to sign the input
sk = PrivateKey('cRvyLwCPLU88jsyj94L7iJjQX5C2f8koG4G2gevN4BeSGcEvfKe9')
# note that we pass the scriptPubkey as one of the inputs of sign_input
# because it is used to replace the scriptSig of the UTXO we are trying to
# spend when creating the transaction digest
from_addr = P2pkhAddress('myPAE9HwPeKHh8FjKwBNBaHnemApo3dw6e')
sig = sk.sign_input(
tx, 0,
Script([
'OP_DUP', 'OP_HASH160',
from_addr.to_hash160(), 'OP_EQUALVERIFY', 'OP_CHECKSIG'
]))
#print(sig)
# get public key as hex
pk = sk.get_public_key().to_hex()
# set the scriptSig (unlocking script)
txin.script_sig = Script([sig, pk])
signed_tx = tx.serialize()
# print raw signed transaction ready to be broadcasted
print("\nRaw signed transaction:\n" + signed_tx)
def main():
# always remember to setup the network
setup('regtest')
# create transaction input from tx id of UTXO (contained 0.4 tBTC)
txin = TxInput(
'e2d08a63a540000222d6a92440436375d8b1bc89a2638dc5366833804287c83f', 1)
# locking script expects 2 numbers that when added equal 5 (silly example)
txout = TxOutput(to_satoshis(0.9), Script(['OP_ADD', 'OP_5', 'OP_EQUAL']))
# create another output to get the change - remaining 0.01 is tx fees
# note that this time we used to_script_pub_key() to create the P2PKH
# script
change_addr = P2pkhAddress('mrCDrCybB6J1vRfbwM5hemdJz73FwDBC8r')
change_txout = TxOutput(to_satoshis(2), change_addr.to_script_pub_key())
# create transaction from inputs/outputs -- default locktime is used
tx = Transaction([txin], [txout, change_txout])
# print raw transaction
print("\nRaw unsigned transaction:\n" + tx.serialize())
# use the private key corresponding to the address that contains the
# UTXO we are trying to spend to sign the input
sk = PrivateKey('cMahea7zqjxrtgAbB7LSGbcQUr1uX1ojuat9jZodMN87JcbXMTcA')
# note that we pass the scriptPubkey as one of the inputs of sign_input
# because it is used to replace the scriptSig of the UTXO we are trying to
# spend when creating the transaction digest
from_addr = P2pkhAddress('mrCDrCybB6J1vRfbwM5hemdJz73FwDBC8r')
sig = sk.sign_input(
tx, 0,
Script([
'OP_DUP', 'OP_HASH160',
from_addr.to_hash160(), 'OP_EQUALVERIFY', 'OP_CHECKSIG'
]))
#print(sig)
# get public key as hex
pk = sk.get_public_key()
pk = pk.to_hex()
#print (pk)
# set the scriptSig (unlocking script)
txin.script_sig = Script([sig, pk])
signed_tx = tx.serialize()
# print raw signed transaction ready to be broadcasted
print("\nRaw signed transaction:\n" + signed_tx)
def main():
# always remember to setup the network
setup('testnet')
# send 2 P2PKH inputs to 1 P2WPKH output
# create transaction inputs from tx ids of UTXOs (contained 0.002 tBTC)
txin = TxInput('eddfaa3d5a1c9a2a2961638aa4e28871b09ed9620f9077482248f368d46d8205', 1)
txin2 = TxInput('cf4b2987c06b9dd2ba6770af31a4942a4ea3e7194c0d64e8699e9fda03f50551', 1)
# create transaction output using P2WPKH scriptPubKey (locking script)
addr = P2wpkhAddress('tltc1qedur7y052upuzd7wzh60d2f86szgpuspmml8ce')
txout = TxOutput(to_satoshis(0.0019), addr.to_script_pub_key())
#txout = TxOutput(to_satoshis(0.0019), Script([0, addr.to_hash()]) )
# create transaction from inputs/outputs -- default locktime is used
# note that this is not a segwit transaction since we don't spend segwit
tx = Transaction([txin, txin2], [txout]) #, has_segwit=True)
# print raw transaction
print("\nRaw unsigned transaction:\n" + tx.serialize())
# use the private keys corresponding to the address that contains the
# UTXOs we are trying to spend to sign the input
sk = PrivateKey('cTALNpTpRbbxTCJ2A5Vq88UxT44w1PE2cYqiB3n4hRvzyCev1Wwo')
sk2 = PrivateKey('cVf3kGh6552jU2rLaKwXTKq5APHPoZqCP4GQzQirWGHFoHQ9rEVt')
# note that we pass the scriptPubkey as one of the inputs of sign_input
# because it is used to replace the scriptSig of the UTXO we are trying to
# spend when creating the transaction digest
from_addr = P2pkhAddress('n4bkvTyU1dVdzsrhWBqBw8fEMbHjJvtmJR')
sig = sk.sign_input( tx, 0, Script(['OP_DUP', 'OP_HASH160',
from_addr.to_hash160(), 'OP_EQUALVERIFY',
'OP_CHECKSIG']) )
from_addr2 = P2pkhAddress('mmYNBho9BWQB2dSniP1NJvnPoj5EVWw89w')
sig2 = sk2.sign_input( tx, 1, from_addr2.to_script_pub_key() )
# get public key as hex
pk = sk.get_public_key().to_hex()
pk2 = sk2.get_public_key().to_hex()
# set the scriptSig (unlocking script)
txin.script_sig = Script([sig, pk])
txin2.script_sig = Script([sig2, pk2])
signed_tx = tx.serialize()
# print raw signed transaction ready to be broadcasted
print("\nRaw signed transaction:\n" + signed_tx)
def test_send_to_non_std(self):
tx = Transaction([self.txin], [self.txout, self.change_txout])
from_addr = P2pkhAddress('mrCDrCybB6J1vRfbwM5hemdJz73FwDBC8r')
sig = self.sk.sign_input(tx, 0, from_addr.to_script_pub_key())
pk = self.sk.get_public_key().to_hex()
self.txin.script_sig = Script([sig, pk])
self.assertEqual(tx.serialize(), self.create_non_std_tx_result)
def revoke_address(conf, interactive=False):
if(conf.blockchain == 'litecoin'):
from litecoinutils.setup import setup
from litecoinutils.keys import P2pkhAddress, P2wpkhAddress
from litecoinutils.utils import is_address_bech32
else:
from bitcoinutils.setup import setup
from bitcoinutils.keys import P2pkhAddress, P2wpkhAddress
from bitcoinutils.utils import is_address_bech32
# initialize full node connection
if(conf.testnet):
setup('testnet')
else:
setup('mainnet')
if(is_address_bech32(conf.issuing_address)):
address = P2wpkhAddress(conf.issuing_address).to_hash160()
else:
address = P2pkhAddress(conf.issuing_address).to_hash160()
op_return_bstring = cred_protocol.revoke_address_cmd(address)
revoked_txid = publish_hash.issue_op_return(conf, op_return_bstring)
if interactive:
print('\nTx hash: {}'.format(revoked_txid))
else:
return revoked_txid
def main():
# always remember to setup the network
setup('testnet')
#
# This script creates a P2SH address containing a P2PK script and sends
# some funds to it
#
# create transaction input from tx id of UTXO (contained 0.1 tBTC)
txin = TxInput(
'76464c2b9e2af4d63ef38a77964b3b77e629dddefc5cb9eb1a3645b1608b790f', 0)
# address we are spending from
from_addr = P2pkhAddress('n4bkvTyU1dVdzsrhWBqBw8fEMbHjJvtmJR')
# secret key of address that we are trying to spent
sk = PrivateKey('cTALNpTpRbbxTCJ2A5Vq88UxT44w1PE2cYqiB3n4hRvzyCev1Wwo')
#
# create transaction output using P2SH scriptPubKey (locking script)
# (the recipient will give us the final address but for now we create it
# for demonstration purposes)
#
# secret key corresponding to the pubkey needed for the P2SH (P2PK) transaction
p2pk_sk = PrivateKey(
'cRvyLwCPLU88jsyj94L7iJjQX5C2f8koG4G2gevN4BeSGcEvfKe9')
p2pk_pk = p2pk_sk.get_public_key().to_hex()
redeem_script = Script([p2pk_pk, 'OP_CHECKSIG'])
txout = TxOutput(to_satoshis(0.09), redeem_script.to_p2sh_script_pub_key())
# no change address - the remaining 0.01 tBTC will go to miners)
# create transaction from inputs/outputs -- default locktime is used
tx = Transaction([txin], [txout])
# print raw transaction
print("\nRaw unsigned transaction:\n" + tx.serialize())
# use the private key corresponding to the address that contains the
# UTXO we are trying to spend to create the signature for the txin
sig = sk.sign_input(tx, 0, from_addr.to_script_pub_key())
#print(sig)
# get public key as hex
pk = sk.get_public_key()
pk = pk.to_hex()
#print (pk)
# set the scriptSig (unlocking script)
txin.script_sig = Script([sig, pk])
signed_tx = tx.serialize()
# print raw signed transaction ready to be broadcasted
print("\nRaw signed transaction:\n" + signed_tx)
print("\nTxId:", tx.get_txid())
def setUp(self):
setup('testnet')
# values for testing create non std tx
self.txin = TxInput(
"e2d08a63a540000222d6a92440436375d8b1bc89a2638dc5366833804287c83f",
1)
self.to_addr = P2pkhAddress('msXP94TBncQ9usP6oZNpGweE24biWjJs2d')
self.sk = PrivateKey(
'cMahea7zqjxrtgAbB7LSGbcQUr1uX1ojuat9jZodMN87JcbXMTcA')
self.txout = TxOutput(to_satoshis(0.9),
Script(['OP_ADD', 'OP_5', 'OP_EQUAL']))
self.change_addr = P2pkhAddress('mrCDrCybB6J1vRfbwM5hemdJz73FwDBC8r')
self.change_txout = TxOutput(to_satoshis(2),
self.change_addr.to_script_pub_key())
self.create_non_std_tx_result = '02000000013fc8874280336836c58d63a289bcb1d87563434024a9d622020040a5638ad0e2010000006a47304402201febc032331342baaece4b88c7ab42d7148c586b9a48944cbebde95636ac7424022018f0911a4ba664ac8cc21457a58e3a1214ba92b84cb60e57f4119fe655b3a78901210279be667ef9dcbbac55a06295ce870b07029bfcdb2dce28d959f2815b16f81798ffffffff02804a5d05000000000393558700c2eb0b000000001976a914751e76e8199196d454941c45d1b3a323f1433bd688ac00000000'
# values for testing create non std tx
self.txin_spend = TxInput(
"4d9a6baf45d4b57c875fe83d5e0834568eae4b5ef6e61d13720ef6685168e663",
0)
self.txin_spend.script_sig = Script(['OP_2', 'OP_3'])
self.txout_spend = TxOutput(to_satoshis(0.8),
self.change_addr.to_script_pub_key())
self.spend_non_std_tx_result = '020000000163e6685168f60e72131de6f65e4bae8e5634085e3de85f877cb5d445af6b9a4d00000000025253ffffffff0100b4c404000000001976a914751e76e8199196d454941c45d1b3a323f1433bd688ac00000000'
def setUp(self):
setup('testnet')
# values for testing unsigned tx, signed tx all, signed tx with low s,
# sighash none
self.txin = TxInput('fb48f4e23bf6ddf606714141ac78c3e921c8c0bebeb7c8abb2c799e9ff96ce6c', 0)
self.addr = P2pkhAddress('n4bkvTyU1dVdzsrhWBqBw8fEMbHjJvtmJR')
self.txout = TxOutput(to_satoshis(0.1), Script(['OP_DUP', 'OP_HASH160', self.addr.to_hash160(),
'OP_EQUALVERIFY', 'OP_CHECKSIG']) )
self.change_addr = P2pkhAddress('mytmhndz4UbEMeoSZorXXrLpPfeoFUDzEp')
self.change_txout = TxOutput(to_satoshis(0.29), self.change_addr.to_script_pub_key())
self.change_low_s_addr = P2pkhAddress('mmYNBho9BWQB2dSniP1NJvnPoj5EVWw89w')
self.change_low_s_txout = TxOutput(to_satoshis(0.29), self.change_low_s_addr.to_script_pub_key())
self.sk = PrivateKey('cRvyLwCPLU88jsyj94L7iJjQX5C2f8koG4G2gevN4BeSGcEvfKe9')
self.from_addr = P2pkhAddress('myPAE9HwPeKHh8FjKwBNBaHnemApo3dw6e')
self.core_tx_result = '02000000016cce96ffe999c7b2abc8b7bebec0c821e9c378ac41417106f6ddf63be2f448fb0000000000ffffffff0280969800000000001976a914fd337ad3bf81e086d96a68e1f8d6a0a510f8c24a88ac4081ba01000000001976a914c992931350c9ba48538003706953831402ea34ea88ac00000000'
self.core_tx_signed_result = '02000000016cce96ffe999c7b2abc8b7bebec0c821e9c378ac41417106f6ddf63be2f448fb000000006a473044022079dad1afef077fa36dcd3488708dd05ef37888ef550b45eb00cdb04ba3fc980e02207a19f6261e69b604a92e2bffdf6ddbed0c64f55d5003e9dfb58b874b07aef3d7012103a2fef1829e0742b89c218c51898d9e7cb9d51201ba2bf9d9e9214ebb6af32708ffffffff0280969800000000001976a914fd337ad3bf81e086d96a68e1f8d6a0a510f8c24a88ac4081ba01000000001976a914c992931350c9ba48538003706953831402ea34ea88ac00000000'
self.core_tx_signed_low_s_SIGALL_result = '02000000016cce96ffe999c7b2abc8b7bebec0c821e9c378ac41417106f6ddf63be2f448fb000000006a473044022044ef433a24c6010a90af14f7739e7c60ce2c5bc3eab96eaee9fbccfdbb3e272202205372a617cb235d0a0ec2889dbfcadf15e10890500d184c8dda90794ecdf79492012103a2fef1829e0742b89c218c51898d9e7cb9d51201ba2bf9d9e9214ebb6af32708ffffffff0280969800000000001976a914fd337ad3bf81e086d96a68e1f8d6a0a510f8c24a88ac4081ba01000000001976a91442151d0c21442c2b038af0ad5ee64b9d6f4f4e4988ac00000000'
self.core_tx_signed_low_s_SIGNONE_result = '02000000016cce96ffe999c7b2abc8b7bebec0c821e9c378ac41417106f6ddf63be2f448fb000000006b483045022100b4ef8ec12b39b21c4b5d57ce82c0c8762a8e9fbe5322a0f00bd5de0dba5152fe02203edb3128b6df0c891770e377fdc8be5b46a2eab16c63bf57507d075a98557236022103a2fef1829e0742b89c218c51898d9e7cb9d51201ba2bf9d9e9214ebb6af32708ffffffff0280969800000000001976a914fd337ad3bf81e086d96a68e1f8d6a0a510f8c24a88ac4081ba01000000001976a91442151d0c21442c2b038af0ad5ee64b9d6f4f4e4988ac00000000'
self.core_tx_signed_low_s_SIGNONE_txid = '76464c2b9e2af4d63ef38a77964b3b77e629dddefc5cb9eb1a3645b1608b790f'
# values for testing sighash single and sighash all/none/single with
# anyonecanpay
self.sig_txin1 = TxInput("76464c2b9e2af4d63ef38a77964b3b77e629dddefc5cb9eb1a3645b1608b790f", 0)
self.sig_txin2 = TxInput('76464c2b9e2af4d63ef38a77964b3b77e629dddefc5cb9eb1a3645b1608b790f', 1)
self.sig_from_addr1 = P2pkhAddress('n4bkvTyU1dVdzsrhWBqBw8fEMbHjJvtmJR')
self.sig_from_addr2 = P2pkhAddress('mmYNBho9BWQB2dSniP1NJvnPoj5EVWw89w')
self.sig_sk1 = PrivateKey('cTALNpTpRbbxTCJ2A5Vq88UxT44w1PE2cYqiB3n4hRvzyCev1Wwo')
self.sig_sk2 = PrivateKey('cVf3kGh6552jU2rLaKwXTKq5APHPoZqCP4GQzQirWGHFoHQ9rEVt')
self.sig_to_addr1 = P2pkhAddress('myPAE9HwPeKHh8FjKwBNBaHnemApo3dw6e')
self.sig_txout1 = TxOutput(to_satoshis(0.09), Script(['OP_DUP', 'OP_HASH160',
self.sig_to_addr1.to_hash160(),
'OP_EQUALVERIFY',
'OP_CHECKSIG']) )
self.sig_to_addr2 = P2pkhAddress('mmYNBho9BWQB2dSniP1NJvnPoj5EVWw89w')
self.sig_txout2 = TxOutput(to_satoshis(0.009), Script(['OP_DUP', 'OP_HASH160',
self.sig_to_addr2.to_hash160(),
'OP_EQUALVERIFY',
'OP_CHECKSIG']) )
self.sig_sighash_single_result = '02000000010f798b60b145361aebb95cfcdedd29e6773b4b96778af33ed6f42a9e2b4c4676000000006a47304402202cfd7077fe8adfc5a65fb3953fa3482cad1413c28b53f12941c1082898d4935102201d393772c47f0699592268febb5b4f64dabe260f440d5d0f96dae5bc2b53e11e032102d82c9860e36f15d7b72aa59e29347f951277c21cd4d34822acdeeadbcff8a546ffffffff0240548900000000001976a914c3f8e5b0f8455a2b02c29c4488a550278209b66988aca0bb0d00000000001976a91442151d0c21442c2b038af0ad5ee64b9d6f4f4e4988ac00000000'
self.sign_sighash_all_2in_2out_result = '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'
self.sign_sighash_none_2in_2out_result = '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'
self.sign_sighash_single_2in_2out_result = '02000000020f798b60b145361aebb95cfcdedd29e6773b4b96778af33ed6f42a9e2b4c4676000000006a47304402206118d21952932deb8608f772017fe76827ccdc8b750ead0f5636429ab5883a6802207f6ded77e22785b0e6c682c05260c2e073d1e1522d4c02fb78df6cdd2862e853032102d82c9860e36f15d7b72aa59e29347f951277c21cd4d34822acdeeadbcff8a546ffffffff0f798b60b145361aebb95cfcdedd29e6773b4b96778af33ed6f42a9e2b4c4676010000006a47304402205012090ddf07ee2e7767020f09224001360243f8dbe05c5011c54eed9fb90d4802203358e227c891f609c3baf98d975d9ee72666fb511c808419d24ec5cccaf3938e032102364d6f04487a71b5966eae3e14a4dc6f00dbe8e55e61bedd0b880766bfe72b5dffffffff0240548900000000001976a914c3f8e5b0f8455a2b02c29c4488a550278209b66988aca0bb0d00000000001976a91442151d0c21442c2b038af0ad5ee64b9d6f4f4e4988ac00000000'
self.sign_sighash_all_single_anyone_2in_2out_result = '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'
def main():
# always remember to setup the network
setup('testnet')
# the key that corresponds to the P2WPKH address
priv = PrivateKey("cVdte9ei2xsVjmZSPtyucG43YZgNkmKTqhwiUA8M4Fc3LdPJxPmZ")
pub = priv.get_public_key()
fromAddress = pub.get_segwit_address()
print(fromAddress.to_string())
# amount is needed to sign the segwit input
fromAddressAmount = to_satoshis(0.01)
# UTXO of fromAddress
txid = '13d2d30eca974e8fa5da11b9608fa36905a22215e8df895e767fc903889367ff'
vout = 0
toAddress = P2pkhAddress('mrrKUpJnAjvQntPgz2Z4kkyr1gbtHmQv28')
# create transaction input from tx id of UTXO
txin = TxInput(txid, vout)
# the script code required for signing for p2wpkh is the same as p2pkh
script_code = Script([
'OP_DUP', 'OP_HASH160',
pub.to_hash160(), 'OP_EQUALVERIFY', 'OP_CHECKSIG'
])
# create transaction output
txOut = TxOutput(to_satoshis(0.009), toAddress.to_script_pub_key())
# create transaction without change output - if at least a single input is
# segwit we need to set has_segwit=True
tx = Transaction([txin], [txOut], has_segwit=True)
print("\nRaw transaction:\n" + tx.serialize())
sig = priv.sign_segwit_input(tx, 0, script_code, fromAddressAmount)
tx.witnesses.append(Script([sig, pub.to_hex()]))
# print raw signed transaction ready to be broadcasted
print("\nRaw signed transaction:\n" + tx.serialize())
print("\nTxId:", tx.get_txid())
def main():
# always remember to setup the network
setup('testnet')
# the key that corresponds to the P2WPKH address
priv = PrivateKey('cNho8fw3bPfLKT4jPzpANTsxTsP8aTdVBD6cXksBEXt4KhBN7uVk')
pub = priv.get_public_key()
# the p2sh script and the corresponding address
redeem_script = pub.get_segwit_address().to_script_pub_key()
p2sh_addr = P2shAddress.from_script(redeem_script)
# the UTXO of the P2SH-P2WPKH that we are trying to spend
inp = TxInput('95c5cac558a8b47436a3306ba300c8d7af4cd1d1523d35da3874153c66d99b09', 0)
# exact amount of UTXO we try to spent
amount = 0.0014
# the address to send funds to
to_addr = P2pkhAddress('mvBGdiYC8jLumpJ142ghePYuY8kecQgeqS')
# the output sending 0.001 -- 0.0004 goes to miners as fee -- no change
out = TxOutput(to_satoshis(0.001), to_addr.to_script_pub_key())
# create a tx with at least one segwit input
tx = Transaction([inp], [out], has_segwit=True)
# script code is the script that is evaluated for a witness program type; each
# witness program type has a specific template for the script code
# script code that corresponds to P2WPKH (it is the classic P2PKH)
script_code = pub.get_address().to_script_pub_key()
# calculate signature using the appropriate script code
# remember to include the original amount of the UTXO
sig = priv.sign_segwit_input(tx, 0, script_code, to_satoshis(amount))
# script_sig is the redeem script passed as a single element
inp.script_sig = Script([redeem_script.to_hex()])
# finally, the unlocking script is added as a witness
tx.witnesses.append(Script([sig, pub.to_hex()]))
# print raw signed transaction ready to be broadcasted
print("\nRaw signed transaction:\n" + tx.serialize())
def main():
# always remember to setup the network
setup('testnet')
#
# This script spends from a P2SH address containing a P2PK script
#
# create transaction input from tx id of UTXO (contained 0.1 tBTC)
txin = TxInput(
'7db363d5a7fabb64ccce154e906588f1936f34481223ea8c1f2c935b0a0c945b', 0)
# secret key needed to spend P2PK that is wrapped by P2SH
p2pk_sk = PrivateKey(
'cRvyLwCPLU88jsyj94L7iJjQX5C2f8koG4G2gevN4BeSGcEvfKe9')
p2pk_pk = p2pk_sk.get_public_key().to_hex()
# create the redeem script - needed to sign the transaction
redeem_script = Script([p2pk_pk, 'OP_CHECKSIG'])
to_addr = P2pkhAddress('n4bkvTyU1dVdzsrhWBqBw8fEMbHjJvtmJR')
txout = TxOutput(to_satoshis(0.09), to_addr.to_script_pub_key())
# no change address - the remaining 0.01 tBTC will go to miners)
# create transaction from inputs/outputs -- default locktime is used
tx = Transaction([txin], [txout])
# print raw transaction
print("\nRaw unsigned transaction:\n" + tx.serialize())
# use the private key corresponding to the address that contains the
# UTXO we are trying to spend to create the signature for the txin -
# note that the redeem script is passed to replace the scriptSig
sig = p2pk_sk.sign_input(tx, 0, redeem_script)
#print(sig)
# set the scriptSig (unlocking script)
txin.script_sig = Script([sig, redeem_script.to_hex()])
signed_tx = tx.serialize()
# print raw signed transaction ready to be broadcasted
print("\nRaw signed transaction:\n" + signed_tx)
print("\nTxId:", tx.get_txid())
def get_issue_tx_info(conf, op_return_bstring, interactive=False):
# load apropriate blockchain libraries
if (conf.blockchain == 'litecoin'):
from litecoinutils.setup import setup
from litecoinutils.proxy import NodeProxy
from litecoinutils.transactions import Transaction, TxInput, TxOutput
from litecoinutils.keys import P2pkhAddress, P2wpkhAddress
from litecoinutils.script import Script
from litecoinutils.utils import to_satoshis, is_address_bech32
else:
from bitcoinutils.setup import setup
from bitcoinutils.proxy import NodeProxy
from bitcoinutils.transactions import Transaction, TxInput, TxOutput
from bitcoinutils.keys import P2pkhAddress, P2wpkhAddress
from bitcoinutils.script import Script
from bitcoinutils.utils import to_satoshis, is_address_bech32
op_return_hex = binascii.hexlify(op_return_bstring).decode()
if interactive:
print('\nConfigured values are:\n')
print('working_directory:\t{}'.format(conf.working_directory))
print('issuing_address:\t{}'.format(conf.issuing_address))
print('blockchain:\t\t{}'.format(conf.blockchain))
print('full_node_url:\t\t{}'.format(conf.full_node_url))
print('full_node_rpc_user:\t{}'.format(conf.full_node_rpc_user))
print('testnet:\t\t{}'.format(conf.testnet))
print('tx_fee_per_byte:\t{}'.format(conf.tx_fee_per_byte))
print('Bytes for OP_RETURN:\n{}'.format(op_return_bstring))
print('Hex for OP_RETURN:\n{}'.format(op_return_hex))
op_return_cert_protocol = op_return_hex
if interactive:
consent = input('Do you want to continue? [y/N]: ').lower() in ('y',
'yes')
if not consent:
sys.exit()
#import time
#start = time.time()
# test explicitly when non interactive
if not conf.full_node_rpc_password and interactive:
conf.full_node_rpc_password = getpass.getpass(
'\nPlease enter the password for the node\'s RPC user: '******'testnet')
else:
setup('mainnet')
host, port = conf.full_node_url.split(
':') # TODO: update when NodeProxy accepts full url!
proxy = NodeProxy(conf.full_node_rpc_user, conf.full_node_rpc_password,
host, port).get_proxy()
# checks if address is native segwit or not.
is_addr_bech32 = is_address_bech32(conf.issuing_address)
# create transaction
tx_outputs = []
unspent = sorted(proxy.listunspent(1, 9999999, [conf.issuing_address]),
key=lambda x: x['amount'],
reverse=False)
if not unspent:
raise ValueError("No UTXOs found")
issuing_pubkey = proxy.getaddressinfo(conf.issuing_address)['pubkey']
tx = None
tx_inputs = []
tx_input_data = {}
inputs_amount = 0
# coin selection: use smallest UTXO and if not enough satoshis add next
# smallest, etc. until sufficient tx fees are accumulated
# TODO wrt dust instead of adding another UTXO we should just remove the
# change_output and allocate the remaining (<546sats) to fees
for utxo in unspent:
txin = TxInput(utxo['txid'], utxo['vout'])
tx_input_data[utxo['txid']] = utxo['amount']
tx_inputs.append(txin)
inputs_amount += utxo['amount']
# currently bitcoin lib requires explicit instantiation; made method to
# check this; update if/when the library fixes/automates this
change_script_out = None
if is_addr_bech32:
change_script_out = P2wpkhAddress(
conf.issuing_address).to_script_pub_key()
else:
change_script_out = P2pkhAddress(
conf.issuing_address).to_script_pub_key()
change_output = TxOutput(to_satoshis(inputs_amount), change_script_out)
op_return_output = TxOutput(
to_satoshis(0), Script(['OP_RETURN', op_return_cert_protocol]))
tx_outputs = [change_output, op_return_output]
tx = Transaction(tx_inputs, tx_outputs, has_segwit=is_addr_bech32)
# sign transaction to get its size
r = proxy.signrawtransactionwithwallet(tx.serialize())
if r['complete'] == None:
if interactive:
sys.exit("Transaction couldn't be signed by node")
else:
raise RuntimeError("Transaction couldn't be signed by node")
signed_tx = r['hex']
signed_tx_size = proxy.decoderawtransaction(signed_tx)['vsize']
# calculate fees and change in satoshis
tx_fee = signed_tx_size * conf.tx_fee_per_byte
change_amount = to_satoshis(inputs_amount) - tx_fee
# the default Bitcoin (and litecoin) Core node doesn't allow the creation of dust
# UTXOs https://bitcoin.stackexchange.com/questions/10986/what-is-meant-by-bitcoin-dust
# if change is less than 546 (2940 for litecoin) satoshis that is considered dust
# (with the default node parameters) then include another UTXO
if conf.blockchain == 'litecoin':
if change_amount >= 3000:
break
else:
if change_amount >= 550:
break
if (change_amount < 0):
if interactive:
sys.exit(
"Specified address cannot cover the transaction fee of: {} satoshis"
.format(tx_fee))
else:
raise RuntimeError(
"insufficient satoshis, cannot create transaction")
# update tx out for change and re-sign
tx.outputs[0].amount = change_amount
return tx.serialize(), conf.issuing_address, tx_input_data
def test_creation_address(self):
a1 = P2pkhAddress.from_address(self.address)
self.assertEqual(a1.to_hash160(), self.hash160)
a2 = P2pkhAddress.from_address(self.addressc)
self.assertEqual(a2.to_hash160(), self.hash160c)
def test_creation_hash(self):
a1 = P2pkhAddress.from_hash160(self.hash160)
self.assertEqual(a1.to_string(), self.address)
a2 = P2pkhAddress.from_hash160(self.hash160c)
self.assertEqual(a2.to_string(), self.addressc)
def validate_certificate(cert, issuer_identifier, blockchain_services):
filename = os.path.basename(cert)
tmp_filename = '__' + filename
shutil.copy(cert, tmp_filename)
# returned proof can be ignored here but could compare with proof later on
issuer_address, _ = get_issuer_address_and_proof(tmp_filename)
proof = get_and_remove_chainpoint_proof(tmp_filename)
if proof == None:
return False, "no chainpoint_proof in metadata"
# get the hash after removing the metadata
filehash = ''
with open(tmp_filename, 'rb') as pdf_file:
filehash = hashlib.sha256(pdf_file.read()).hexdigest()
# instantiate chainpoint object
cp = ChainPointV2()
chain, testnet, txid = get_chain_testnet_txid_from_chainpoint_proof(
proof, issuer_address)
# make request to get txs regarding this address
# issuance is the first element of data_before_issuance
data_before_issuance, data_after_issuance = \
network_utils.get_all_op_return_hexes(issuer_address, txid,
blockchain_services, chain,
testnet)
# validate receipt
valid, reason = cp.validate_receipt(proof, data_before_issuance[0],
filehash, issuer_identifier)
# display error except when the certificate expired; this is because we want
# revoked certificate error to be displayed before cert expired error
# TODO clean hard-coded reason
if not valid and not reason.startswith("certificate expired"):
return False, reason
# load apropriate blockchain libraries
if (chain == 'litecoin'):
from litecoinutils.setup import setup
from litecoinutils.keys import P2pkhAddress, P2wpkhAddress, PublicKey
from litecoinutils.utils import is_address_bech32
else:
from bitcoinutils.setup import setup
from bitcoinutils.keys import P2pkhAddress, P2wpkhAddress, PublicKey
from litecoinutils.utils import is_address_bech32
# set appropriate network (required for addr->pkh in revoke address)
if testnet:
setup('testnet')
else:
setup('mainnet')
# check if cert's issuance is after a revoke address cmd on that address
# and if yes then the issuance is invalid (address was revoked)
# we check before checking for cert revocations since if the issuance was
# after an address revocation it should show that as an invalid reason
# 0 index is the actual issuance -- ignore it
for i in range(len(data_before_issuance))[1:]:
cred_dict = cred_protocol.parse_op_return_hex(data_before_issuance[i])
if cred_dict:
if cred_dict['cmd'] == cred_protocol.hex_op('op_revoke_address'):
if (is_address_bech32(issuer_address)):
issuer_pkh = P2wpkhAddress(issuer_address).to_hash160()
else:
issuer_pkh = P2pkhAddress(issuer_address).to_hash160()
if issuer_pkh == cred_dict['data']['pkh']:
return False, "address was revoked"
# check if cert or batch was revoked from oldest to newest
for op_return in reversed(data_after_issuance):
cred_dict = cred_protocol.parse_op_return_hex(op_return)
if cred_dict:
if cred_dict['cmd'] == cred_protocol.hex_op('op_revoke_batch'):
if txid == cred_dict['data']['txid']:
return False, "batch was revoked"
elif cred_dict['cmd'] == cred_protocol.hex_op('op_revoke_creds'):
if txid == cred_dict['data']['txid']:
# compare the certificate hash bytes
filehash_bytes = utils.hex_to_bytes(filehash)
ripemd_filehash = utils.ripemd160(filehash_bytes)
ripemd_hex = utils.bytes_to_hex(ripemd_filehash)
if ripemd_hex == cred_dict['data']['hashes'][0]:
return False, "cert hash was revoked"
if len(cred_dict['data']['hashes']) > 1:
if ripemd_hex == cred_dict['data']['hashes'][1]:
return False, "cert hash was revoked"
elif cred_dict['cmd'] == cred_protocol.hex_op('op_revoke_address'):
# if address revocation is found stop looking since all other
# revocations will be invalid
if (is_address_bech32(issuer_address)):
issuer_pkh = P2wpkhAddress(issuer_address).to_hash160()
else:
issuer_pkh = P2pkhAddress(issuer_address).to_hash160()
if issuer_pkh == cred_dict['data']['pkh']:
break
# if not revoked but not valid this means that it was expired; now that we
# checked for revocations we can show the expiry error
if not valid:
return False, reason
# now that the issuer (anchoring) was validated validate the certificate
# with the owner's public key (vpdf v2)
# get owner and owner_proof removing the latter
owner, owner_proof = get_owner_and_remove_owner_proof(tmp_filename)
if owner:
# get public key
pk = PublicKey.from_hex(owner['pk'])
# get file hash
sha256_hash = None
with open(tmp_filename, 'rb') as pdf:
sha256_hash = hashlib.sha256(pdf.read()).hexdigest()
# finally check if owner signature is valid
#print(pk.get_address().to_string(), pk.to_hex(), sha256_hash, owner_proof)
try:
if (pk.verify(owner_proof, sha256_hash)):
pass
except Exception: #BadSignatureError:
return False, 'owner signature could not be validated'
finally:
# cleanup
os.remove(tmp_filename)
else:
# cleanup now that we know it validated
os.remove(tmp_filename)
# in a valid credential the reason could contain an expiry date
return True, reason
def main():
# always remember to setup the network
setup('testnet')
#
# This script spends from a P2SH address containing a CSV+P2PKH script as
# created from examples/create_p2sh_csv_p2pkh.py
#
# We assume that some 11.1 tBTC have been send to that address and that we know
# the txid and the specific UTXO index (or vout).
#
# set values
relative_blocks = 20
txid = '76c102821b916a625bd3f0c3c6e35d5c308b7c23e78b8866b06a3a466041db0a'
vout = 0
seq = Sequence(TYPE_RELATIVE_TIMELOCK, relative_blocks)
# create transaction input from tx id of UTXO (contained 11.1 tBTC)
txin = TxInput(txid, vout, sequence=seq.for_input_sequence())
# secret key needed to spend P2PKH that is wrapped by P2SH
p2pkh_sk = PrivateKey(
'cRvyLwCPLU88jsyj94L7iJjQX5C2f8koG4G2gevN4BeSGcEvfKe9')
p2pkh_pk = p2pkh_sk.get_public_key().to_hex()
p2pkh_addr = p2pkh_sk.get_public_key().get_address()
# create the redeem script - needed to sign the transaction
redeem_script = Script([
seq.for_script(), 'OP_CHECKSEQUENCEVERIFY', 'OP_DROP', 'OP_DUP',
'OP_HASH160',
p2pkh_addr.to_hash160(), 'OP_EQUALVERIFY', 'OP_CHECKSIG'
])
# to confirm that address is the same as the one that the funds were sent
#addr = P2shAddress.from_script(redeem_script)
#print(addr.to_string())
# send/spend to any random address
to_addr = P2pkhAddress('n4bkvTyU1dVdzsrhWBqBw8fEMbHjJvtmJR')
txout = TxOutput(to_satoshis(11), to_addr.to_script_pub_key())
# no change address - the remaining 0.1 tBTC will go to miners)
# create transaction from inputs/outputs
tx = Transaction([txin], [txout])
# print raw transaction
print("\nRaw unsigned transaction:\n" + tx.serialize())
# use the private key corresponding to the address that contains the
# UTXO we are trying to spend to create the signature for the txin -
# note that the redeem script is passed to replace the scriptSig
sig = p2pkh_sk.sign_input(tx, 0, redeem_script)
#print(sig)
# set the scriptSig (unlocking script) -- unlock the P2PKH (sig, pk) plus
# the redeem script, since it is a P2SH
txin.script_sig = Script([sig, p2pkh_pk, redeem_script.to_hex()])
signed_tx = tx.serialize()
# print raw signed transaction ready to be broadcasted
print("\nRaw signed transaction:\n" + signed_tx)
print("\nTxId:", tx.get_txid())
def main():
# always remember to setup the network
setup('testnet')
# create transaction input from tx id of UTXO (contained 0.39 tBTC)
# 0.1 tBTC
txin = TxInput(
'76464c2b9e2af4d63ef38a77964b3b77e629dddefc5cb9eb1a3645b1608b790f', 0)
# 0.29 tBTC
txin2 = TxInput(
'76464c2b9e2af4d63ef38a77964b3b77e629dddefc5cb9eb1a3645b1608b790f', 1)
# create transaction output using P2PKH scriptPubKey (locking script)
addr = P2pkhAddress('myPAE9HwPeKHh8FjKwBNBaHnemApo3dw6e')
txout = TxOutput(
to_satoshis(0.3),
Script([
'OP_DUP', 'OP_HASH160',
addr.to_hash160(), 'OP_EQUALVERIFY', 'OP_CHECKSIG'
]))
# create another output to get the change - remaining 0.01 is tx fees
change_addr = P2pkhAddress('mmYNBho9BWQB2dSniP1NJvnPoj5EVWw89w')
change_txout = TxOutput(
to_satoshis(0.08),
Script([
'OP_DUP', 'OP_HASH160',
change_addr.to_hash160(), 'OP_EQUALVERIFY', 'OP_CHECKSIG'
]))
# create transaction from inputs/outputs -- default locktime is used
tx = Transaction([txin, txin2], [txout, change_txout])
# print raw transaction
print("\nRaw unsigned transaction:\n" + tx.serialize())
#
# use the private keys corresponding to the addresses that contains the
# UTXOs we are trying to spend to create the signatures
#
sk = PrivateKey('cTALNpTpRbbxTCJ2A5Vq88UxT44w1PE2cYqiB3n4hRvzyCev1Wwo')
sk2 = PrivateKey('cVf3kGh6552jU2rLaKwXTKq5APHPoZqCP4GQzQirWGHFoHQ9rEVt')
# we could have derived the addresses from the secret keys
from_addr = P2pkhAddress('n4bkvTyU1dVdzsrhWBqBw8fEMbHjJvtmJR')
from_addr2 = P2pkhAddress('mmYNBho9BWQB2dSniP1NJvnPoj5EVWw89w')
# sign the first input
sig = sk.sign_input(
tx, 0,
Script([
'OP_DUP', 'OP_HASH160',
from_addr.to_hash160(), 'OP_EQUALVERIFY', 'OP_CHECKSIG'
]), SIGHASH_ALL | SIGHASH_ANYONECANPAY)
#print(sig)
# sign the second input
sig2 = sk2.sign_input(
tx, 1,
Script([
'OP_DUP', 'OP_HASH160',
from_addr2.to_hash160(), 'OP_EQUALVERIFY', 'OP_CHECKSIG'
]), SIGHASH_SINGLE | SIGHASH_ANYONECANPAY)
#print(sig2)
# get public key as hex
pk = sk.get_public_key()
pk = pk.to_hex()
#print (pk)
# get public key as hex
pk2 = sk2.get_public_key()
pk2 = pk2.to_hex()
# set the scriptSig (unlocking script)
txin.script_sig = Script([sig, pk])
txin2.script_sig = Script([sig2, pk2])
signed_tx = tx.serialize()
# print raw signed transaction ready to be broadcasted
print("\nRaw signed transaction:\n" + signed_tx)
print("\nTxId:", tx.get_txid())