neobytes/qa/rpc-tests/addressindex.py

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#!/usr/bin/env python2
# Copyright (c) 2014-2015 The Bitcoin Core developers
# Distributed under the MIT software license, see the accompanying
# file COPYING or http://www.opensource.org/licenses/mit-license.php.
#
# Test addressindex generation and fetching
#
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import time
from test_framework.test_framework import BitcoinTestFramework
from test_framework.util import *
from test_framework.script import *
from test_framework.mininode import *
import binascii
class AddressIndexTest(BitcoinTestFramework):
def setup_chain(self):
print("Initializing test directory "+self.options.tmpdir)
initialize_chain_clean(self.options.tmpdir, 4)
def setup_network(self):
self.nodes = []
# Nodes 0/1 are "wallet" nodes
self.nodes.append(start_node(0, self.options.tmpdir, ["-debug", "-relaypriority=0"]))
self.nodes.append(start_node(1, self.options.tmpdir, ["-debug", "-addressindex"]))
# Nodes 2/3 are used for testing
self.nodes.append(start_node(2, self.options.tmpdir, ["-debug", "-addressindex", "-relaypriority=0"]))
self.nodes.append(start_node(3, self.options.tmpdir, ["-debug", "-addressindex"]))
connect_nodes(self.nodes[0], 1)
connect_nodes(self.nodes[0], 2)
connect_nodes(self.nodes[0], 3)
self.is_network_split = False
self.sync_all()
def run_test(self):
print "Mining blocks..."
self.nodes[0].generate(105)
self.sync_all()
chain_height = self.nodes[1].getblockcount()
assert_equal(chain_height, 105)
assert_equal(self.nodes[1].getbalance(), 0)
assert_equal(self.nodes[2].getbalance(), 0)
# Check that balances are correct
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balance0 = self.nodes[1].getaddressbalance("93bVhahvUKmQu8gu9g3QnPPa2cxFK98pMB")
assert_equal(balance0["balance"], 0)
# Check p2pkh and p2sh address indexes
print "Testing p2pkh and p2sh address index..."
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txid0 = self.nodes[0].sendtoaddress("yMNJePdcKvXtWWQnFYHNeJ5u8TF2v1dfK4", 10)
self.nodes[0].generate(1)
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txidb0 = self.nodes[0].sendtoaddress("93bVhahvUKmQu8gu9g3QnPPa2cxFK98pMB", 10)
self.nodes[0].generate(1)
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txid1 = self.nodes[0].sendtoaddress("yMNJePdcKvXtWWQnFYHNeJ5u8TF2v1dfK4", 15)
self.nodes[0].generate(1)
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txidb1 = self.nodes[0].sendtoaddress("93bVhahvUKmQu8gu9g3QnPPa2cxFK98pMB", 15)
self.nodes[0].generate(1)
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txid2 = self.nodes[0].sendtoaddress("yMNJePdcKvXtWWQnFYHNeJ5u8TF2v1dfK4", 20)
self.nodes[0].generate(1)
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txidb2 = self.nodes[0].sendtoaddress("93bVhahvUKmQu8gu9g3QnPPa2cxFK98pMB", 20)
self.nodes[0].generate(1)
self.sync_all()
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txids = self.nodes[1].getaddresstxids("yMNJePdcKvXtWWQnFYHNeJ5u8TF2v1dfK4")
assert_equal(len(txids), 3)
assert_equal(txids[0], txid0)
assert_equal(txids[1], txid1)
assert_equal(txids[2], txid2)
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txidsb = self.nodes[1].getaddresstxids("93bVhahvUKmQu8gu9g3QnPPa2cxFK98pMB")
assert_equal(len(txidsb), 3)
assert_equal(txidsb[0], txidb0)
assert_equal(txidsb[1], txidb1)
assert_equal(txidsb[2], txidb2)
# Check that limiting by height works
print "Testing querying txids by range of block heights.."
height_txids = self.nodes[1].getaddresstxids({
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"addresses": ["93bVhahvUKmQu8gu9g3QnPPa2cxFK98pMB"],
"start": 105,
"end": 110
})
assert_equal(len(height_txids), 2)
assert_equal(height_txids[0], txidb0)
assert_equal(height_txids[1], txidb1)
# Check that multiple addresses works
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multitxids = self.nodes[1].getaddresstxids({"addresses": ["93bVhahvUKmQu8gu9g3QnPPa2cxFK98pMB", "yMNJePdcKvXtWWQnFYHNeJ5u8TF2v1dfK4"]})
assert_equal(len(multitxids), 6)
assert_equal(multitxids[0], txid0)
assert_equal(multitxids[1], txidb0)
assert_equal(multitxids[2], txid1)
assert_equal(multitxids[3], txidb1)
assert_equal(multitxids[4], txid2)
assert_equal(multitxids[5], txidb2)
# Check that balances are correct
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balance0 = self.nodes[1].getaddressbalance("93bVhahvUKmQu8gu9g3QnPPa2cxFK98pMB")
assert_equal(balance0["balance"], 45 * 100000000)
# Check that outputs with the same address will only return one txid
print "Testing for txid uniqueness..."
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addressHash = "FE30B718DCF0BF8A2A686BF1820C073F8B2C3B37".decode("hex")
scriptPubKey = CScript([OP_HASH160, addressHash, OP_EQUAL])
unspent = self.nodes[0].listunspent()
tx = CTransaction()
tx.vin = [CTxIn(COutPoint(int(unspent[0]["txid"], 16), unspent[0]["vout"]))]
tx.vout = [CTxOut(10, scriptPubKey), CTxOut(11, scriptPubKey)]
tx.rehash()
signed_tx = self.nodes[0].signrawtransaction(binascii.hexlify(tx.serialize()).decode("utf-8"))
sent_txid = self.nodes[0].sendrawtransaction(signed_tx["hex"], True)
self.nodes[0].generate(1)
self.sync_all()
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txidsmany = self.nodes[1].getaddresstxids("93bVhahvUKmQu8gu9g3QnPPa2cxFK98pMB")
assert_equal(len(txidsmany), 4)
assert_equal(txidsmany[3], sent_txid)
# Check that balances are correct
print "Testing balances..."
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balance0 = self.nodes[1].getaddressbalance("93bVhahvUKmQu8gu9g3QnPPa2cxFK98pMB")
assert_equal(balance0["balance"], 45 * 100000000 + 21)
# Check that balances are correct after spending
print "Testing balances after spending..."
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privkey2 = "cU4zhap7nPJAWeMFu4j6jLrfPmqakDAzy8zn8Fhb3oEevdm4e5Lc"
address2 = "yeMpGzMj3rhtnz48XsfpB8itPHhHtgxLc3"
addressHash2 = "C5E4FB9171C22409809A3E8047A29C83886E325D".decode("hex")
scriptPubKey2 = CScript([OP_DUP, OP_HASH160, addressHash2, OP_EQUALVERIFY, OP_CHECKSIG])
self.nodes[0].importprivkey(privkey2)
unspent = self.nodes[0].listunspent()
tx = CTransaction()
tx.vin = [CTxIn(COutPoint(int(unspent[0]["txid"], 16), unspent[0]["vout"]))]
amount = unspent[0]["amount"] * 100000000
tx.vout = [CTxOut(amount, scriptPubKey2)]
tx.rehash()
signed_tx = self.nodes[0].signrawtransaction(binascii.hexlify(tx.serialize()).decode("utf-8"))
spending_txid = self.nodes[0].sendrawtransaction(signed_tx["hex"], True)
self.nodes[0].generate(1)
self.sync_all()
balance1 = self.nodes[1].getaddressbalance(address2)
assert_equal(balance1["balance"], amount)
tx = CTransaction()
tx.vin = [CTxIn(COutPoint(int(spending_txid, 16), 0))]
send_amount = 1 * 100000000 + 12840
change_amount = amount - send_amount - 10000
tx.vout = [CTxOut(change_amount, scriptPubKey2), CTxOut(send_amount, scriptPubKey)]
tx.rehash()
signed_tx = self.nodes[0].signrawtransaction(binascii.hexlify(tx.serialize()).decode("utf-8"))
sent_txid = self.nodes[0].sendrawtransaction(signed_tx["hex"], True)
self.nodes[0].generate(1)
self.sync_all()
balance2 = self.nodes[1].getaddressbalance(address2)
assert_equal(balance2["balance"], change_amount)
# Check that deltas are returned correctly
deltas = self.nodes[1].getaddressdeltas({"addresses": [address2], "start": 0, "end": 200})
balance3 = 0
for delta in deltas:
balance3 += delta["satoshis"]
assert_equal(balance3, change_amount)
assert_equal(deltas[0]["address"], address2)
assert_equal(deltas[0]["blockindex"], 1)
# Check that entire range will be queried
deltasAll = self.nodes[1].getaddressdeltas({"addresses": [address2]})
assert_equal(len(deltasAll), len(deltas))
# Check that deltas can be returned from range of block heights
deltas = self.nodes[1].getaddressdeltas({"addresses": [address2], "start": 113, "end": 113})
assert_equal(len(deltas), 1)
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# Check that unspent outputs can be queried
print "Testing utxos..."
utxos = self.nodes[1].getaddressutxos({"addresses": [address2]})
assert_equal(len(utxos), 1)
assert_equal(utxos[0]["satoshis"], change_amount)
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# Check that indexes will be updated with a reorg
print "Testing reorg..."
best_hash = self.nodes[0].getbestblockhash()
self.nodes[0].invalidateblock(best_hash)
self.nodes[1].invalidateblock(best_hash)
self.nodes[2].invalidateblock(best_hash)
self.nodes[3].invalidateblock(best_hash)
# Allow some time for the reorg to start
time.sleep(2)
self.sync_all()
balance4 = self.nodes[1].getaddressbalance(address2)
assert_equal(balance4, balance1)
utxos2 = self.nodes[1].getaddressutxos({"addresses": [address2]})
assert_equal(len(utxos2), 1)
assert_equal(utxos2[0]["satoshis"], amount)
# Check sorting of utxos
self.nodes[2].generate(150)
txidsort1 = self.nodes[2].sendtoaddress(address2, 50)
self.nodes[2].generate(1)
txidsort2 = self.nodes[2].sendtoaddress(address2, 50)
self.nodes[2].generate(1)
self.sync_all()
utxos3 = self.nodes[1].getaddressutxos({"addresses": [address2]})
assert_equal(len(utxos3), 3)
assert_equal(utxos3[0]["height"], 114)
assert_equal(utxos3[1]["height"], 264)
assert_equal(utxos3[2]["height"], 265)
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# Check mempool indexing
print "Testing mempool indexing..."
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privKey3 = "cRyrMvvqi1dmpiCmjmmATqjAwo6Wu7QTjKu1ABMYW5aFG4VXW99K"
address3 = "yWB15aAdpeKuSaQHFVJpBDPbNSLZJSnDLA"
addressHash3 = "6C186B3A308A77C779A9BB71C3B5A7EC28232A13".decode("hex")
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scriptPubKey3 = CScript([OP_DUP, OP_HASH160, addressHash3, OP_EQUALVERIFY, OP_CHECKSIG])
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# address4 = "2N8oFVB2vThAKury4vnLquW2zVjsYjjAkYQ"
scriptPubKey4 = CScript([OP_HASH160, addressHash3, OP_EQUAL])
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unspent = self.nodes[2].listunspent()
tx = CTransaction()
tx.vin = [CTxIn(COutPoint(int(unspent[0]["txid"], 16), unspent[0]["vout"]))]
amount = unspent[0]["amount"] * 100000000
tx.vout = [CTxOut(amount, scriptPubKey3)]
tx.rehash()
signed_tx = self.nodes[2].signrawtransaction(binascii.hexlify(tx.serialize()).decode("utf-8"))
memtxid1 = self.nodes[2].sendrawtransaction(signed_tx["hex"], True)
time.sleep(2)
tx2 = CTransaction()
tx2.vin = [CTxIn(COutPoint(int(unspent[1]["txid"], 16), unspent[1]["vout"]))]
amount = unspent[1]["amount"] * 100000000
tx2.vout = [
CTxOut(amount / 4, scriptPubKey3),
CTxOut(amount / 4, scriptPubKey3),
CTxOut(amount / 4, scriptPubKey4),
CTxOut(amount / 4, scriptPubKey4)
]
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tx2.rehash()
signed_tx2 = self.nodes[2].signrawtransaction(binascii.hexlify(tx2.serialize()).decode("utf-8"))
memtxid2 = self.nodes[2].sendrawtransaction(signed_tx2["hex"], True)
time.sleep(2)
mempool = self.nodes[2].getaddressmempool({"addresses": [address3]})
assert_equal(len(mempool), 3)
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assert_equal(mempool[0]["txid"], memtxid1)
assert_equal(mempool[0]["address"], address3)
assert_equal(mempool[0]["index"], 0)
assert_equal(mempool[1]["txid"], memtxid2)
assert_equal(mempool[1]["index"], 0)
assert_equal(mempool[2]["txid"], memtxid2)
assert_equal(mempool[2]["index"], 1)
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self.nodes[2].generate(1);
self.sync_all();
mempool2 = self.nodes[2].getaddressmempool({"addresses": [address3]})
assert_equal(len(mempool2), 0)
tx = CTransaction()
tx.vin = [
CTxIn(COutPoint(int(memtxid2, 16), 0)),
CTxIn(COutPoint(int(memtxid2, 16), 1))
]
tx.vout = [CTxOut(amount / 2 - 10000, scriptPubKey2)]
tx.rehash()
self.nodes[2].importprivkey(privKey3)
signed_tx3 = self.nodes[2].signrawtransaction(binascii.hexlify(tx.serialize()).decode("utf-8"))
memtxid3 = self.nodes[2].sendrawtransaction(signed_tx3["hex"], True)
time.sleep(2)
mempool3 = self.nodes[2].getaddressmempool({"addresses": [address3]})
assert_equal(len(mempool3), 2)
assert_equal(mempool3[0]["prevtxid"], memtxid2)
assert_equal(mempool3[0]["prevout"], 0)
assert_equal(mempool3[1]["prevtxid"], memtxid2)
assert_equal(mempool3[1]["prevout"], 1)
# sending and receiving to the same address
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privkey1 = "cMvZn1pVWntTEcsK36ZteGQXRAcZ8CoTbMXF1QasxBLdnTwyVQCc"
address1 = "yM9Eed1bxjy7tYxD3yZDHxjcVT48WdRoB1"
address1hash = "0909C84A817651502E020AAD0FBCAE5F656E7D8A".decode("hex")
address1script = CScript([OP_DUP, OP_HASH160, address1hash, OP_EQUALVERIFY, OP_CHECKSIG])
self.nodes[0].sendtoaddress(address1, 10)
self.nodes[0].generate(1)
self.sync_all()
utxos = self.nodes[1].getaddressutxos({"addresses": [address1]})
assert_equal(len(utxos), 1)
tx = CTransaction()
tx.vin = [
CTxIn(COutPoint(int(utxos[0]["txid"], 16), utxos[0]["outputIndex"]))
]
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amount = utxos[0]["satoshis"] - 10000
tx.vout = [CTxOut(amount, address1script)]
tx.rehash()
self.nodes[0].importprivkey(privkey1)
signed_tx = self.nodes[0].signrawtransaction(binascii.hexlify(tx.serialize()).decode("utf-8"))
mem_txid = self.nodes[0].sendrawtransaction(signed_tx["hex"], True)
self.sync_all()
mempool_deltas = self.nodes[2].getaddressmempool({"addresses": [address1]})
assert_equal(len(mempool_deltas), 2)
print "Passed\n"
if __name__ == '__main__':
AddressIndexTest().main()