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 # Create the unsigned raw transaction. sighash = SignatureHash(redeemScript, tx, 0, SIGHASH_ALL) privkey = self.zcashd.dumpprivkey(refundPubKey) sig = privkey.sign(sighash) + bytes([SIGHASH_ALL]) # Sign without secret txin.scriptSig = CScript([sig, privkey.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 = self.zcashd.sendrawtransaction(tx) refund_tx = b2x(lx(b2x(txid))) fund_tx = str(fundtx['outpoint']) return {"refund_tx": refund_tx, "fund_tx": fund_tx}
def redeem(self, contract, fundtx, secret): # TODO: parse the script once, up front. redeemPubKey = self.find_redeemAddr(contract) print('redeemPubKey', redeemPubKey) zec_redeemScript = CScript(x(contract.redeemScript)) txin = CMutableTxIn(fundtx['outpoint']) txout = CMutableTxOut(fundtx['amount'] - FEE, redeemPubKey.to_scriptPubKey()) # Create the unsigned raw transaction. tx = CMutableTransaction([txin], [txout]) sighash = SignatureHash(zec_redeemScript, tx, 0, SIGHASH_ALL) # TODO: figure out how to better protect privkey privkey = self.zcashd.dumpprivkey(redeemPubKey) sig = privkey.sign(sighash) + bytes([SIGHASH_ALL]) print("SECRET", secret) preimage = secret.encode('utf-8') txin.scriptSig = CScript( [sig, privkey.pub, preimage, OP_TRUE, zec_redeemScript]) txin_scriptPubKey = zec_redeemScript.to_p2sh_scriptPubKey() print('Raw redeem transaction hex: ', b2x(tx.serialize())) VerifyScript(txin.scriptSig, txin_scriptPubKey, tx, 0, (SCRIPT_VERIFY_P2SH, )) print("Script verified, sending raw redeem transaction...") txid = self.zcashd.sendrawtransaction(tx) redeem_tx = b2x(lx(b2x(txid))) fund_tx = str(fundtx['outpoint']) return {"redeem_tx": redeem_tx, "fund_tx": fund_tx}
def redeem_with_secret(contract, secret): # How to find redeemScript and redeemblocknum from blockchain? # print("Redeeming contract using secret", contract.__dict__) p2sh = contract['p2sh'] minamount = float(contract['amount']) # checking there are funds in the address amount = check_funds(p2sh) if amount < minamount: print ('address ', p2sh, ' not sufficiently funded') return False fundtx = find_transaction_to_address(p2sh) amount = fundtx['amount'] / COIN p2sh = P2SHBitcoinAddress(p2sh) if fundtx['address'] == p2sh: print 'Found {0} in p2sh {1}, redeeming...'.format(amount, p2sh) redeemPubKey = find_redeemAddr(contract) print ('redeemPubKey', redeemPubKey) redeemScript = CScript(x(contract['redeemScript'])) txin = CMutableTxIn(fundtx['outpoint']) txout = CMutableTxOut(fundtx['amount'] - FEE, redeemPubKey.to_scriptPubKey()) # Create the unsigned raw transaction. tx = CMutableTransaction([txin], [txout]) sighash = SignatureHash(redeemScript, tx, 0, SIGHASH_ALL) # TODO: figure out how to better protect privkey privkey = zcashd.dumpprivkey(redeemPubKey) sig = privkey.sign(sighash) + bytes([SIGHASH_ALL]) print ('SECRET', secret) # secret = get_secret() preimage = secret.encode('utf-8') txin.scriptSig = CScript([sig, privkey.pub, preimage, OP_TRUE, redeemScript]) # 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 = zcashd.sendrawtransaction(tx) print ('Txid of submitted redeem tx: ', b2x(lx(b2x(txid)))) return b2x(lx(b2x(txid))) else: print ('No contract for this p2sh found in database', p2sh)
def redeem_contract(self, contract, secret): # How to find redeemScript and redeemblocknum from blockchain? p2sh = contract.p2sh #checking there are funds in the address amount = self.check_funds(p2sh) if (amount == 0): print("Address ", p2sh, " not funded") quit() fundtx = self.find_transaction_to_address(p2sh) amount = fundtx['amount'] / COIN # print("Found fund_tx: ", fundtx) p2sh = P2SHBitcoinAddress(p2sh) if fundtx['address'] == p2sh: print("Found {0} in p2sh {1}, redeeming...".format(amount, p2sh)) # Where can you find redeemblocknum in the transaction? # redeemblocknum = find_redeemblocknum(contract) blockcount = self.zcashd.getblockcount() print("\nCurrent blocknum at time of redeem on Zcash:", blockcount) if blockcount < contract.redeemblocknum: # TODO: parse the script once, up front. redeemPubKey = self.find_redeemAddr(contract) print('redeemPubKey', redeemPubKey) zec_redeemScript = CScript(x(contract.redeemScript)) txin = CMutableTxIn(fundtx['outpoint']) txout = CMutableTxOut(fundtx['amount'] - FEE, redeemPubKey.to_scriptPubKey()) # Create the unsigned raw transaction. tx = CMutableTransaction([txin], [txout]) sighash = SignatureHash(zec_redeemScript, tx, 0, SIGHASH_ALL) # TODO: figure out how to better protect privkey privkey = self.zcashd.dumpprivkey(redeemPubKey) sig = privkey.sign(sighash) + bytes([SIGHASH_ALL]) print("SECRET", secret) preimage = secret.encode('utf-8') txin.scriptSig = CScript( [sig, privkey.pub, preimage, OP_TRUE, zec_redeemScript]) txin_scriptPubKey = zec_redeemScript.to_p2sh_scriptPubKey() print('Raw redeem transaction hex: ', b2x(tx.serialize())) VerifyScript(txin.scriptSig, txin_scriptPubKey, tx, 0, (SCRIPT_VERIFY_P2SH, )) print("Script verified, sending raw redeem transaction...") txid = self.zcashd.sendrawtransaction(tx) redeem_tx = b2x(lx(b2x(txid))) fund_tx = str(fundtx['outpoint']) return {"redeem_tx": redeem_tx, "fund_tx": fund_tx} else: print("nLocktime exceeded, refunding") refundPubKey = self.find_refundAddr(contract) print('refundPubKey', refundPubKey) txid = self.zcashd.sendtoaddress(refundPubKey, fundtx['amount'] - FEE) refund_tx = b2x(lx(b2x(txid))) fund_tx = str(fundtx['outpoint']) return {"refund_tx": refund_tx, "fund_tx": fund_tx} else: print("No contract for this p2sh found in database", p2sh)
def redeem_after_timelock(contract): print(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 = zcashd.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 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 = zcashd.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 = zcashd.sendrawtransaction(tx) print("Txid of submitted redeem tx: ", b2x(lx(b2x(txid)))) return b2x(lx(b2x(txid)))
if (zcashd.getblockcount() >= redeemblocknum): print( "Alice -- Bob did not redeem the Zcash you put in escrow within the timeout period, so refunding you..... " ) txin = CMutableTxIn(COutPoint(fund_tx, fund_vout)) # The default nSequence of FFFFFFFF won't let you redeem when there's a CHECKTIMELOCKVERIFY txin.nSequence = 0 txout = CMutableTxOut(send_amount - FEE, alicepubkey.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(zec_redeemScript, tx, 0, SIGHASH_ALL) sig = alice_seckey.sign(sighash) + bytes([SIGHASH_ALL]) txin.scriptSig = CScript( [sig, alice_seckey.pub, OP_FALSE, zec_redeemScript]) print("Time lock has passed, Alice redeeming her own tx:") print("Refund tx hex:", b2x(tx.serialize())) VerifyScript(txin.scriptSig, txin_scriptPubKey, tx, 0, (SCRIPT_VERIFY_P2SH, )) txid = zcashd.sendrawtransaction(tx) print("Txid of submitted refund tx: ", b2x(lx(b2x(txid)))) quit() # ================= BEFORE 48 HRS: BOB REDEEMS WITH ALICE'S REVEALED SECRET ========================= print("Bob -- Redeeming tx.....") txin = CMutableTxIn(COutPoint(fund_tx, fund_vout)) txout = CMutableTxOut(send_amount - FEE, bobpubkey.to_scriptPubKey())
# address. regtest_addr = 'tmMDAio4NC4Y3xXgDMGpco8rWh13dPJt1A6' output_val = amount - 0.001 txout = CMutableTxOut(output_val, CBitcoinAddress(regtest_addr).to_scriptPubKey()) # Create the unsigned transaction. tx = CMutableTransaction([txin], [txout]) # 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_ANYONECANPAY) print('sighash', b2x(sighash)) # privkey = CBitcoinSecret('cNUMK7zPWDq8YLFoARbLiFSgJnZ4jDuJzXxdSebNupzHB8ZSbQ4n') # Now sign it. We have to append the type of signature we want to the end, in # this case the usual SIGHASH_ALL. # sig = privkey.sign(sighash) + bytes([SIGHASH_ANYONECANPAY]) # Set the scriptSig of our transaction input appropriately. txin.scriptSig = CScript([preimage, txin_redeemScript]) print('tx', tx) # Verify the signature worked. This calls EvalScript() and actually executes # the opcodes in the scripts to see if everything worked out. If it doesn't an # exception will be raised. VerifyScript(txin.scriptSig, txin_scriptPubKey, tx, 0, (SCRIPT_VERIFY_P2SH, ))
# corresponds to the secret key we generated above. txin_scriptPubKey = CScript( [OP_DUP, OP_HASH160, Hash160(seckey.pub), OP_EQUALVERIFY, OP_CHECKSIG]) # Create the txout. This time we create the scriptPubKey from a Bitcoin # address. txout = CMutableTxOut( 0.001 * COIN, CBitcoinAddress('1C7zdTfnkzmr13HfA2vNm5SJYRK6nEKyq8').to_scriptPubKey()) # Create the unsigned transaction. tx = CMutableTransaction([txin], [txout]) # Calculate the signature hash for that transaction. sighash = SignatureHash(txin_scriptPubKey, 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]) # Verify the signature worked. This calls EvalScript() and actually executes # the opcodes in the scripts to see if everything worked out. If it doesn't an # exception will be raised. VerifyScript(txin.scriptSig, txin_scriptPubKey, tx, 0, (SCRIPT_VERIFY_P2SH, )) # Done! Print the transaction to standard output with the bytes-to-hex # function.
def auto_redeem(contract, secret): # How to find redeemScript and redeemblocknum from blockchain? print("Contract in auto redeem", contract.__dict__) p2sh = contract.p2sh #checking there are funds in the address amount = check_funds(p2sh) if (amount == 0): print("address ", p2sh, " not funded") quit() fundtx = find_transaction_to_address(p2sh) amount = fundtx['amount'] / COIN p2sh = P2SHBitcoinAddress(p2sh) if fundtx['address'] == p2sh: print("Found {0} in p2sh {1}, redeeming...".format(amount, p2sh)) # Parsing redeemblocknum from the redeemscript of the p2sh redeemblocknum = find_redeemblocknum(contract) blockcount = zcashd.getblockcount() print("\nCurrent blocknum at time of redeem on Zcash chain:", blockcount) if blockcount < redeemblocknum: redeemPubKey = find_redeemAddr(contract) print('redeemPubKey', redeemPubKey) else: print("nLocktime exceeded, refunding") redeemPubKey = find_refundAddr(contract) print('refundPubKey', redeemPubKey) # redeemPubKey = CBitcoinAddress.from_scriptPubKey(redeemPubKey) # exit() zec_redeemScript = CScript(x(contract.redeemScript)) txin = CMutableTxIn(fundtx['outpoint']) txout = CMutableTxOut(fundtx['amount'] - FEE, redeemPubKey.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 # TODO: these things like redeemblocknum should really be properties of a tx class... # Need: redeemblocknum, zec_redeemScript, secret (for creator...), txid, redeemer... if blockcount >= redeemblocknum: print("\nLocktime exceeded") tx.nLockTime = redeemblocknum sighash = SignatureHash(zec_redeemScript, tx, 0, SIGHASH_ALL) # TODO: figure out how to better protect privkey privkey = zcashd.dumpprivkey(redeemPubKey) sig = privkey.sign(sighash) + bytes([SIGHASH_ALL]) print("SECRET", secret) preimage = secret.encode('utf-8') txin.scriptSig = CScript( [sig, privkey.pub, preimage, OP_TRUE, zec_redeemScript]) # exit() # print("txin.scriptSig", b2x(txin.scriptSig)) txin_scriptPubKey = zec_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))) else: print("No contract for this p2sh found in database", p2sh)
# Create the txout. This time we create the scriptPubKey from a Bitcoin # address. txout = CMutableTxOut( 0.0005 * COIN, CBitcoinAddress('tmKBPqa8qqKA7vrGq1AaXHSAr9vqa3GczzK').to_scriptPubKey()) # Create the unsigned transaction. tx = CMutableTransaction([txin], [txout]) # 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) # 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, txin_redeemScript]) print(b2x(tx.serialize())) # Verify the signature worked. This calls EvalScript() and actually executes # the opcodes in the scripts to see if everything worked out. If it doesn't an # exception will be raised. VerifyScript(txin.scriptSig, txin_scriptPubKey, tx, 0, (SCRIPT_VERIFY_P2SH, )) # Done! Print the transaction to standard output with the bytes-to-hex