def refund(proxy, refundGuy, contract):
redeemScript = CScript(x(contract['redeemScript']))
txin = CMutableTxIn(fundtx['outpoint'])
txout = CMutableTxOut(fundtx['amount'] - FEE,
refundGuy['addr'].to_scriptPubKey())
tx = CMutableTransaction([txin], [txout])
txin.nSequence = 0
tx.nLockTime = contract['redeemblocknum']
sighash = SignatureHash(redeemScript, tx, 0, SIGHASH_ALL)
sig = refundGuy['key'].sign(sighash) + bytes([SIGHASH_ALL])
txin.scriptSig = CScript([sig, refundGuy['key'].pub, OP_FALSE, redeemScript])
txin_scriptPubKey = redeemScript.to_p2sh_scriptPubKey()
print('Raw redeem transaction hex: {0}'.format(b2x(tx.serialize())))
res = VerifyScript(txin.scriptSig, txin_scriptPubKey,
tx, 0, (SCRIPT_VERIFY_P2SH,))
print("Script verified, sending raw transaction... (NOT)", res)
txid = proxy.sendrawtransaction(tx)
refund_tx = b2x(lx(b2x(txid)))
fund_tx = str(fundtx['outpoint'])
return {"refund_tx": refund_tx, "fund_tx": fund_tx}
def refund(self, contract):
fundtx = self.find_transaction_to_address(contract.p2sh)
print("Fund tx found in refund: ", fundtx)
refundPubKey = self.find_refundAddr(contract)
print('refundPubKey: {0}'.format(refundPubKey))
redeemScript = CScript(x(contract.redeemScript))
txin = CMutableTxIn(fundtx['outpoint'])
txout = CMutableTxOut(fundtx['amount'] - FEE,
refundPubKey.to_scriptPubKey())
# Create the unsigned raw transaction.
tx = CMutableTransaction([txin], [txout])
# Set nSequence and nLockTime
txin.nSequence = 0
tx.nLockTime = contract.redeemblocknum
sighash = SignatureHash(redeemScript, tx, 0, SIGHASH_ALL)
privkey = self.bitcoind.dumpprivkey(refundPubKey)
sig = privkey.sign(sighash) + bytes([SIGHASH_ALL])
# Sign without secret
txin.scriptSig = CScript([sig, privkey.pub, OP_FALSE, redeemScript])
# txin.nSequence = 2185
txin_scriptPubKey = redeemScript.to_p2sh_scriptPubKey()
print('Raw redeem transaction hex: {0}'.format(b2x(tx.serialize())))
res = VerifyScript(txin.scriptSig, txin_scriptPubKey,
tx, 0, (SCRIPT_VERIFY_P2SH,))
print("Script verified, sending raw transaction... (NOT)", res)
txid = self.bitcoind.sendrawtransaction(tx)
refund_tx = b2x(lx(b2x(txid)))
fund_tx = str(fundtx['outpoint'])
return {"refund_tx": refund_tx, "fund_tx": fund_tx}
def redeem_after_timelock(contract):
p2sh = contract.p2sh
fundtx = find_transaction_to_address(p2sh)
amount = fundtx['amount'] / COIN
if (fundtx['address'].__str__() != p2sh):
print("no fund transaction found to the contract p2sh address ", p2sh)
quit()
print("Found fundtx:", fundtx)
# Parsing redeemblocknum from the redeemscript of the p2sh
redeemblocknum = find_redeemblocknum(contract)
blockcount = bitcoind.getblockcount()
print("Current block:", blockcount, "Can redeem from block:",
redeemblocknum)
if (still_locked(contract)):
print("too early for redeeming with timelock try again at block",
redeemblocknum, "or later")
return 0
print("Found {0} in p2sh {1}, redeeming...".format(amount, p2sh))
redeemPubKey = find_refundAddr(contract)
print('refundPubKey', redeemPubKey)
redeemScript = CScript(x(contract.redeemScript))
txin = CMutableTxIn(fundtx['outpoint'])
txout = CMutableTxOut(fundtx['amount'] - FEE,
redeemPubKey.to_scriptPubKey())
# Create the unsigned raw transaction.
txin.nSequence = 0
tx = CMutableTransaction([txin], [txout])
tx.nLockTime = redeemblocknum
sighash = SignatureHash(redeemScript, tx, 0, SIGHASH_ALL)
# TODO: figure out how to better protect privkey
privkey = bitcoind.dumpprivkey(redeemPubKey)
sig = privkey.sign(sighash) + bytes([SIGHASH_ALL])
txin.scriptSig = CScript([sig, privkey.pub, OP_FALSE, redeemScript])
# exit()
# print("txin.scriptSig", b2x(txin.scriptSig))
txin_scriptPubKey = redeemScript.to_p2sh_scriptPubKey()
# print('Redeem txhex', b2x(tx.serialize()))
VerifyScript(txin.scriptSig, txin_scriptPubKey, tx, 0,
(SCRIPT_VERIFY_P2SH, ))
print("script verified, sending raw tx")
txid = bitcoind.sendrawtransaction(tx)
print("Txid of submitted redeem tx: ", b2x(lx(b2x(txid))))
return b2x(lx(b2x(txid)))
# Create the txin structure, which includes the outpoint. The scriptSig
# defaults to being empty.
txin = CMutableTxIn(COutPoint(txid, vout))
binzero = 2**32
txin.nSequence = binzero - 3
# Create the txout. This time we create the scriptPubKey from a Bitcoin
# address.
txout = CMutableTxOut(
amount_less_fees,
CBitcoinAddress(
'tb1qv9hg20f0g08d460l67ph6p4ukwt7m0ttqzj7mk').to_scriptPubKey())
# Create the unsigned transaction.
tx = CMutableTransaction([txin], [txout])
tx.nLockTime = nLockTime
# Calculate the signature hash for that transaction. Note how the script we use
# is the redeemScript, not the scriptPubKey. That's because when the CHECKSIG
# operation happens EvalScript() will be evaluating the redeemScript, so the
# corresponding SignatureHash() function will use that same script when it
# replaces the scriptSig in the transaction being hashed with the script being
# executed.
sighash = SignatureHash(txin_redeemScript, tx, 0, SIGHASH_ALL)
print("hash:", b2x(sighash))
print(b2x(bytes([SIGHASH_ALL])))
# Now sign it. We have to append the type of signature we want to the end, in
# this case the usual SIGHASH_ALL.
sig = seckey.sign(sighash) + bytes([SIGHASH_ALL])
# Create the txin structure. scriptSig defaults to being empty.
# The input is the p2sh funding transaction txid, vout is its index
txin = CMutableTxIn(COutPoint(fund_tx, vout))
# The default nSequence of FFFFFFFF won't let you redeem when there's a CHECKTIMELOCKVERIFY
txin.nSequence = 0
# Create the txout. Pays out to recipient, so uses recipient's pubkey
# Withdraw full amount minus fee
default_fee = 0.001 * COIN
txout = CMutableTxOut(amount - default_fee, senderpubkey.to_scriptPubKey())
# Create the unsigned raw transaction.
tx = CMutableTransaction([txin], [txout])
# nLockTime needs to be at least as large as parameter of CHECKLOCKTIMEVERIFY for script to verify
tx.nLockTime = redeemblocknum
# Calculate the signature hash for that transaction. Note how the script we use
# is the redeemScript, not the scriptPubKey. EvalScript() will be evaluating the redeemScript
sighash = SignatureHash(txin_redeemScript, tx, 0, SIGHASH_ALL)
# Now sign it. We have to append the type of signature we want to the end, in
# this case the usual SIGHASH_ALL.
sig = seckey.sign(sighash) + bytes([SIGHASH_ALL])
# Set the scriptSig of our transaction input appropriately.
txin.scriptSig = CScript([sig, seckey.pub, OP_FALSE, txin_redeemScript])
print("Redeem tx hex:", b2x(tx.serialize()))
# Verify the signature worked.