def test_muhash_implementation(self):
self.log.info("Test MuHash implementation consistency")
node = self.nodes[0]
wallet = MiniWallet(node)
mocktime = node.getblockheader(node.getblockhash(0))['time'] + 1
node.setmocktime(mocktime)
# Generate 100 blocks and remove the first since we plan to spend its
# coinbase
block_hashes = self.generate(wallet, 1) + self.generate(node, 99)
blocks = list(
map(lambda block: from_hex(CBlock(), node.getblock(block, False)),
block_hashes))
blocks.pop(0)
# Create a spending transaction and mine a block which includes it
txid = wallet.send_self_transfer(from_node=node)['txid']
tx_block = self.generateblock(node,
output=wallet.get_address(),
transactions=[txid])
blocks.append(
from_hex(CBlock(), node.getblock(tx_block['hash'], False)))
# Serialize the outputs that should be in the UTXO set and add them to
# a MuHash object
muhash = MuHash3072()
for height, block in enumerate(blocks):
# The Genesis block coinbase is not part of the UTXO set and we
# spent the first mined block
height += 2
for tx in block.vtx:
for n, tx_out in enumerate(tx.vout):
coinbase = 1 if not tx.vin[0].prevout.hash else 0
# Skip witness commitment
if (coinbase and n > 0):
continue
data = COutPoint(int(tx.rehash(), 16), n).serialize()
data += struct.pack("<i", height * 2 + coinbase)
data += tx_out.serialize()
muhash.insert(data)
finalized = muhash.digest()
node_muhash = node.gettxoutsetinfo("muhash")['muhash']
assert_equal(finalized[::-1].hex(), node_muhash)
self.log.info("Test deterministic UTXO set hash results")
assert_equal(
node.gettxoutsetinfo()['hash_serialized_2'],
"1ec3e58b0be79fca5917c7c30b9761f12adb609d0233cf2b42fa17ec419f0056")
assert_equal(
node.gettxoutsetinfo("muhash")['muhash'],
"faee25ca4765facb643b7a2d96531c568cb52ad84de5ae3d420a92967621ec17")
def test_muhash_implementation(self):
self.log.info("Test MuHash implementation consistency")
node = self.nodes[0]
wallet = MiniWallet(node)
mocktime = node.getblockheader(node.getblockhash(0))['time'] + 1
node.setmocktime(mocktime)
# Generate 100 blocks and remove the first since we plan to spend its
# coinbase
block_hashes = self.generate(wallet, 1) + self.generate(node, 99)
blocks = list(
map(lambda block: from_hex(CBlock(), node.getblock(block, False)),
block_hashes))
blocks.pop(0)
# Create a spending transaction and mine a block which includes it
txid = wallet.send_self_transfer(from_node=node)['txid']
tx_block = self.generateblock(node,
output=wallet.get_address(),
transactions=[txid])
blocks.append(
from_hex(CBlock(), node.getblock(tx_block['hash'], False)))
# Serialize the outputs that should be in the UTXO set and add them to
# a MuHash object
muhash = MuHash3072()
for height, block in enumerate(blocks):
# The Genesis block coinbase is not part of the UTXO set and we
# spent the first mined block
height += 2
for tx in block.vtx:
for n, tx_out in enumerate(tx.vout):
coinbase = 1 if not tx.vin[0].prevout.hash else 0
# Skip witness commitment
if (coinbase and n > 0):
continue
data = COutPoint(int(tx.rehash(), 16), n).serialize()
data += struct.pack("<i", height * 2 + coinbase)
data += tx_out.serialize()
muhash.insert(data)
finalized = muhash.digest()
node_muhash = node.gettxoutsetinfo("muhash")['muhash']
assert_equal(finalized[::-1].hex(), node_muhash)
self.log.info("Test deterministic UTXO set hash results")
assert_equal(
node.gettxoutsetinfo()['hash_serialized_2'],
"221f245cf4c9010eeb7f5183d342c002ae6c1c27e98aa357dccb788c21d98049")
assert_equal(
node.gettxoutsetinfo("muhash")['muhash'],
"7c0890c68501f7630d36aeb3999dc924e63af084ae1bbfba11dd462144637635")
def test_muhash_implementation(self):
self.log.info("Test MuHash implementation consistency")
node = self.nodes[0]
wallet = MiniWallet(node)
mocktime = node.getblockheader(node.getblockhash(0))['time'] + 1
node.setmocktime(mocktime)
# Generate 100 blocks and remove the first since we plan to spend its
# coinbase
block_hashes = self.generate(wallet, 1) + self.generate(node, 99)
blocks = list(
map(lambda block: from_hex(CBlock(), node.getblock(block, False)),
block_hashes))
blocks.pop(0)
# Create a spending transaction and mine a block which includes it
txid = wallet.send_self_transfer(from_node=node)['txid']
tx_block = self.generateblock(node,
output=wallet.get_address(),
transactions=[txid])
blocks.append(
from_hex(CBlock(), node.getblock(tx_block['hash'], False)))
# Serialize the outputs that should be in the UTXO set and add them to
# a MuHash object
muhash = MuHash3072()
for height, block in enumerate(blocks):
# The Genesis block coinbase is not part of the UTXO set and we
# spent the first mined block
height += 2
for tx in block.vtx:
for n, tx_out in enumerate(tx.vout):
coinbase = 1 if not tx.vin[0].prevout.hash else 0
# Skip witness commitment
if (coinbase and n > 0):
continue
data = COutPoint(int(tx.rehash(), 16), n).serialize()
data += struct.pack("<i", height * 2 + coinbase)
data += tx_out.serialize()
muhash.insert(data)
finalized = muhash.digest()
node_muhash = node.gettxoutsetinfo("muhash")['muhash']
assert_equal(finalized[::-1].hex(), node_muhash)
self.log.info("Test deterministic UTXO set hash results")
assert_equal(
node.gettxoutsetinfo()['hash_serialized_2'],
"3a570529b4c32e77268de1f81b903c75cc2da53c48df0d125c1e697ba7c8c7b7")
assert_equal(
node.gettxoutsetinfo("muhash")['muhash'],
"a13e0e70eb8acc786549596e3bc154623f1a5a622ba2f70715f6773ec745f435")
def test_muhash_implementation(self):
self.log.info("Test MuHash implementation consistency")
node = self.nodes[0]
wallet = MiniWallet(node)
mocktime = node.getblockheader(node.getblockhash(0))['time'] + 1
node.setmocktime(mocktime)
# Generate 100 blocks and remove the first since we plan to spend its
# coinbase
block_hashes = self.generate(wallet, 1) + self.generate(node, 99)
blocks = list(
map(lambda block: from_hex(CBlock(), node.getblock(block, False)),
block_hashes))
blocks.pop(0)
# Create a spending transaction and mine a block which includes it
txid = wallet.send_self_transfer(from_node=node)['txid']
tx_block = self.generateblock(node,
output=wallet.get_address(),
transactions=[txid])
blocks.append(
from_hex(CBlock(), node.getblock(tx_block['hash'], False)))
# Serialize the outputs that should be in the UTXO set and add them to
# a MuHash object
muhash = MuHash3072()
for height, block in enumerate(blocks):
# The Genesis block coinbase is not part of the UTXO set and we
# spent the first mined block
height += 2
for tx in block.vtx:
for n, tx_out in enumerate(tx.vout):
coinbase = 1 if not tx.vin[0].prevout.hash else 0
# Skip witness commitment
if (coinbase and n > 0):
continue
data = COutPoint(int(tx.rehash(), 16), n).serialize()
data += struct.pack("<i", height * 2 + coinbase)
data += tx_out.serialize()
muhash.insert(data)
finalized = muhash.digest()
node_muhash = node.gettxoutsetinfo("muhash")['muhash']
assert_equal(finalized[::-1].hex(), node_muhash)
self.log.info("Test deterministic UTXO set hash results")
assert_equal(
node.gettxoutsetinfo()['hash_serialized_2'],
"5b1b44097406226c0eb8e1362cd17a1f346522cf9390a8175a57a5262cb1963f")
assert_equal(
node.gettxoutsetinfo("muhash")['muhash'],
"4b8803075d7151d06fad3e88b68ba726886794873fbfa841d12aefb2cc2b881b")
def test_muhash_implementation(self):
self.log.info("Test MuHash implementation consistency")
node = self.nodes[0]
wallet = MiniWallet(node)
mocktime = node.getblockheader(node.getblockhash(0))['time'] + 1
node.setmocktime(mocktime)
# Generate 100 blocks and remove the first since we plan to spend its
# coinbase
block_hashes = wallet.generate(1) + node.generate(99)
blocks = list(
map(lambda block: from_hex(CBlock(), node.getblock(block, False)),
block_hashes))
blocks.pop(0)
# Create a spending transaction and mine a block which includes it
txid = wallet.send_self_transfer(from_node=node)['txid']
tx_block = node.generateblock(output=wallet.get_address(),
transactions=[txid])
blocks.append(
from_hex(CBlock(), node.getblock(tx_block['hash'], False)))
# Serialize the outputs that should be in the UTXO set and add them to
# a MuHash object
muhash = MuHash3072()
for height, block in enumerate(blocks):
# The Genesis block coinbase is not part of the UTXO set and we
# spent the first mined block
height += 2
for tx in block.vtx:
for n, tx_out in enumerate(tx.vout):
coinbase = 1 if not tx.vin[0].prevout.hash else 0
# Skip witness commitment
if (coinbase and n > 0):
continue
data = COutPoint(int(tx.rehash(), 16), n).serialize()
data += struct.pack("<i", height * 2 + coinbase)
data += tx_out.serialize()
muhash.insert(data)
finalized = muhash.digest()
node_muhash = node.gettxoutsetinfo("muhash")['muhash']
assert_equal(finalized[::-1].hex(), node_muhash)
self.log.info("Test deterministic UTXO set hash results")
assert_equal(
node.gettxoutsetinfo()['hash_serialized_2'],
"03f3bedef7a3e64686e13b57ec08b1ada40528d8e01f64e077750e225ddb8c07")
assert_equal(
node.gettxoutsetinfo("muhash")['muhash'],
"69ebd7142d443a89c227637ef9a21c05287a98f0acdd40ba7e3ef79d1f4e412d")
def test_muhash_implementation(self):
self.log.info("Test MuHash implementation consistency")
node = self.nodes[0]
wallet = MiniWallet(node)
mocktime = node.getblockheader(node.getblockhash(0))['time'] + 1
node.setmocktime(mocktime)
# Generate 100 blocks and remove the first since we plan to spend its
# coinbase
block_hashes = self.generate(wallet, 1) + self.generate(node, 99)
blocks = list(map(lambda block: from_hex(CBlock(), node.getblock(block, False)), block_hashes))
blocks.pop(0)
# Create a spending transaction and mine a block which includes it
txid = wallet.send_self_transfer(from_node=node)['txid']
tx_block = self.generateblock(node, output=wallet.get_address(), transactions=[txid])
blocks.append(from_hex(CBlock(), node.getblock(tx_block['hash'], False)))
# Serialize the outputs that should be in the UTXO set and add them to
# a MuHash object
muhash = MuHash3072()
for height, block in enumerate(blocks):
# The Genesis block coinbase is not part of the UTXO set and we
# spent the first mined block
height += 2
for tx in block.vtx:
for n, tx_out in enumerate(tx.vout):
coinbase = 1 if not tx.vin[0].prevout.hash else 0
# Skip witness commitment
if (coinbase and n > 0):
continue
data = COutPoint(int(tx.rehash(), 16), n).serialize()
data += struct.pack("<i", height * 2 + coinbase)
data += tx_out.serialize()
muhash.insert(data)
finalized = muhash.digest()
node_muhash = node.gettxoutsetinfo("muhash")['muhash']
assert_equal(finalized[::-1].hex(), node_muhash)
self.log.info("Test deterministic UTXO set hash results")
assert_equal(node.gettxoutsetinfo()['hash_serialized_2'], "f9aa4fb5ffd10489b9a6994e70ccf1de8a8bfa2d5f201d9857332e9954b0855d")
assert_equal(node.gettxoutsetinfo("muhash")['muhash'], "d1725b2fe3ef43e55aa4907480aea98d406fc9e0bf8f60169e2305f1fbf5961b")
def test_bumpfee_with_descendant_fails(self, rbf_node, rbf_node_address, dest_address):
self.log.info('Test that fee cannot be bumped when it has descendant')
# parent is send-to-self, so we don't have to check which output is change when creating the child tx
parent_id = spend_one_input(rbf_node, rbf_node_address)
tx = rbf_node.createrawtransaction([{"txid": parent_id, "vout": 0}], {dest_address: 0.00020000})
tx = rbf_node.signrawtransactionwithwallet(tx)
rbf_node.sendrawtransaction(tx["hex"])
assert_raises_rpc_error(-8, "Transaction has descendants in the wallet", rbf_node.bumpfee, parent_id)
# create tx with descendant in the mempool by using MiniWallet
miniwallet = MiniWallet(rbf_node)
parent_id = spend_one_input(rbf_node, miniwallet.get_address())
tx = rbf_node.gettransaction(txid=parent_id, verbose=True)['decoded']
miniwallet.scan_tx(tx)
miniwallet.send_self_transfer(from_node=rbf_node)
assert_raises_rpc_error(-8, "Transaction has descendants in the mempool", rbf_node.bumpfee, parent_id)
self.clear_mempool()
class BlockchainTest(BitcoinTestFramework):
def set_test_params(self):
self.setup_clean_chain = True
self.num_nodes = 1
self.supports_cli = False
def run_test(self):
self.wallet = MiniWallet(self.nodes[0])
self.mine_chain()
self._test_max_future_block_time()
self.restart_node(0, extra_args=['-stopatheight=207', '-prune=1']) # Set extra args with pruning after rescan is complete
self._test_getblockchaininfo()
self._test_getchaintxstats()
self._test_gettxoutsetinfo()
self._test_getblockheader()
self._test_getdifficulty()
self._test_getnetworkhashps()
self._test_stopatheight()
self._test_waitforblockheight()
self._test_getblock()
self._test_getdeploymentinfo()
assert self.nodes[0].verifychain(4, 0)
def mine_chain(self):
self.log.info(f"Generate {HEIGHT} blocks after the genesis block in ten-minute steps")
for t in range(TIME_GENESIS_BLOCK, TIME_RANGE_END, TIME_RANGE_STEP):
self.nodes[0].setmocktime(t)
self.generate(self.wallet, 1)
assert_equal(self.nodes[0].getblockchaininfo()['blocks'], HEIGHT)
def _test_max_future_block_time(self):
self.stop_node(0)
self.log.info("A block tip of more than MAX_FUTURE_BLOCK_TIME in the future raises an error")
self.nodes[0].assert_start_raises_init_error(
extra_args=[f"-mocktime={TIME_RANGE_TIP - MAX_FUTURE_BLOCK_TIME - 1}"],
expected_msg=": The block database contains a block which appears to be from the future."
" This may be due to your computer's date and time being set incorrectly."
f" Only rebuild the block database if you are sure that your computer's date and time are correct.{os.linesep}"
"Please restart with -reindex or -reindex-chainstate to recover.",
)
self.log.info("A block tip of MAX_FUTURE_BLOCK_TIME in the future is fine")
self.start_node(0, extra_args=[f"-mocktime={TIME_RANGE_TIP - MAX_FUTURE_BLOCK_TIME}"])
def _test_getblockchaininfo(self):
self.log.info("Test getblockchaininfo")
keys = [
'bestblockhash',
'blocks',
'chain',
'chainwork',
'difficulty',
'headers',
'initialblockdownload',
'mediantime',
'pruned',
'size_on_disk',
'time',
'verificationprogress',
'warnings',
]
res = self.nodes[0].getblockchaininfo()
assert_equal(res['time'], TIME_RANGE_END - TIME_RANGE_STEP)
assert_equal(res['mediantime'], TIME_RANGE_MTP)
# result should have these additional pruning keys if manual pruning is enabled
assert_equal(sorted(res.keys()), sorted(['pruneheight', 'automatic_pruning'] + keys))
# size_on_disk should be > 0
assert_greater_than(res['size_on_disk'], 0)
# pruneheight should be greater or equal to 0
assert_greater_than_or_equal(res['pruneheight'], 0)
# check other pruning fields given that prune=1
assert res['pruned']
assert not res['automatic_pruning']
self.restart_node(0, ['-stopatheight=207'])
res = self.nodes[0].getblockchaininfo()
# should have exact keys
assert_equal(sorted(res.keys()), keys)
self.stop_node(0)
self.nodes[0].assert_start_raises_init_error(
extra_args=['-testactivationheight=name@2'],
expected_msg='Error: Invalid name (name@2) for -testactivationheight=name@height.',
)
self.nodes[0].assert_start_raises_init_error(
extra_args=['-testactivationheight=bip34@-2'],
expected_msg='Error: Invalid height value (bip34@-2) for -testactivationheight=name@height.',
)
self.nodes[0].assert_start_raises_init_error(
extra_args=['-testactivationheight='],
expected_msg='Error: Invalid format () for -testactivationheight=name@height.',
)
self.start_node(0, extra_args=[
'-stopatheight=207',
'-prune=550',
])
res = self.nodes[0].getblockchaininfo()
# result should have these additional pruning keys if prune=550
assert_equal(sorted(res.keys()), sorted(['pruneheight', 'automatic_pruning', 'prune_target_size'] + keys))
# check related fields
assert res['pruned']
assert_equal(res['pruneheight'], 0)
assert res['automatic_pruning']
assert_equal(res['prune_target_size'], 576716800)
assert_greater_than(res['size_on_disk'], 0)
def check_signalling_deploymentinfo_result(self, gdi_result, height, blockhash, status_next):
assert height >= 144 and height <= 287
assert_equal(gdi_result, {
"hash": blockhash,
"height": height,
"deployments": {
'bip34': {'type': 'buried', 'active': True, 'height': 2},
'bip66': {'type': 'buried', 'active': True, 'height': 3},
'bip65': {'type': 'buried', 'active': True, 'height': 4},
'csv': {'type': 'buried', 'active': True, 'height': 5},
'segwit': {'type': 'buried', 'active': True, 'height': 6},
'testdummy': {
'type': 'bip9',
'bip9': {
'bit': 28,
'start_time': 0,
'timeout': 0x7fffffffffffffff, # testdummy does not have a timeout so is set to the max int64 value
'min_activation_height': 0,
'status': 'started',
'status-next': status_next,
'since': 144,
'statistics': {
'period': 144,
'threshold': 108,
'elapsed': height - 143,
'count': height - 143,
'possible': True,
},
'signalling': '#'*(height-143),
},
'active': False
},
'taproot': {
'type': 'bip9',
'bip9': {
'start_time': -1,
'timeout': 9223372036854775807,
'min_activation_height': 0,
'status': 'active',
'status-next': 'active',
'since': 0,
},
'height': 0,
'active': True
}
}
})
def _test_getdeploymentinfo(self):
# Note: continues past -stopatheight height, so must be invoked
# after _test_stopatheight
self.log.info("Test getdeploymentinfo")
self.stop_node(0)
self.start_node(0, extra_args=[
'-testactivationheight=bip34@2',
'-testactivationheight=dersig@3',
'-testactivationheight=cltv@4',
'-testactivationheight=csv@5',
'-testactivationheight=segwit@6',
])
gbci207 = self.nodes[0].getblockchaininfo()
self.check_signalling_deploymentinfo_result(self.nodes[0].getdeploymentinfo(), gbci207["blocks"], gbci207["bestblockhash"], "started")
# block just prior to lock in
self.generate(self.wallet, 287 - gbci207["blocks"])
gbci287 = self.nodes[0].getblockchaininfo()
self.check_signalling_deploymentinfo_result(self.nodes[0].getdeploymentinfo(), gbci287["blocks"], gbci287["bestblockhash"], "locked_in")
# calling with an explicit hash works
self.check_signalling_deploymentinfo_result(self.nodes[0].getdeploymentinfo(gbci207["bestblockhash"]), gbci207["blocks"], gbci207["bestblockhash"], "started")
def _test_getchaintxstats(self):
self.log.info("Test getchaintxstats")
# Test `getchaintxstats` invalid extra parameters
assert_raises_rpc_error(-1, 'getchaintxstats', self.nodes[0].getchaintxstats, 0, '', 0)
# Test `getchaintxstats` invalid `nblocks`
assert_raises_rpc_error(-1, "JSON value is not an integer as expected", self.nodes[0].getchaintxstats, '')
assert_raises_rpc_error(-8, "Invalid block count: should be between 0 and the block's height - 1", self.nodes[0].getchaintxstats, -1)
assert_raises_rpc_error(-8, "Invalid block count: should be between 0 and the block's height - 1", self.nodes[0].getchaintxstats, self.nodes[0].getblockcount())
# Test `getchaintxstats` invalid `blockhash`
assert_raises_rpc_error(-1, "JSON value is not a string as expected", self.nodes[0].getchaintxstats, blockhash=0)
assert_raises_rpc_error(-8, "blockhash must be of length 64 (not 1, for '0')", self.nodes[0].getchaintxstats, blockhash='0')
assert_raises_rpc_error(-8, "blockhash must be hexadecimal string (not 'ZZZ0000000000000000000000000000000000000000000000000000000000000')", self.nodes[0].getchaintxstats, blockhash='ZZZ0000000000000000000000000000000000000000000000000000000000000')
assert_raises_rpc_error(-5, "Block not found", self.nodes[0].getchaintxstats, blockhash='0000000000000000000000000000000000000000000000000000000000000000')
blockhash = self.nodes[0].getblockhash(HEIGHT)
self.nodes[0].invalidateblock(blockhash)
assert_raises_rpc_error(-8, "Block is not in main chain", self.nodes[0].getchaintxstats, blockhash=blockhash)
self.nodes[0].reconsiderblock(blockhash)
chaintxstats = self.nodes[0].getchaintxstats(nblocks=1)
# 200 txs plus genesis tx
assert_equal(chaintxstats['txcount'], HEIGHT + 1)
# tx rate should be 1 per 10 minutes, or 1/600
# we have to round because of binary math
assert_equal(round(chaintxstats['txrate'] * TIME_RANGE_STEP, 10), Decimal(1))
b1_hash = self.nodes[0].getblockhash(1)
b1 = self.nodes[0].getblock(b1_hash)
b200_hash = self.nodes[0].getblockhash(HEIGHT)
b200 = self.nodes[0].getblock(b200_hash)
time_diff = b200['mediantime'] - b1['mediantime']
chaintxstats = self.nodes[0].getchaintxstats()
assert_equal(chaintxstats['time'], b200['time'])
assert_equal(chaintxstats['txcount'], HEIGHT + 1)
assert_equal(chaintxstats['window_final_block_hash'], b200_hash)
assert_equal(chaintxstats['window_final_block_height'], HEIGHT )
assert_equal(chaintxstats['window_block_count'], HEIGHT - 1)
assert_equal(chaintxstats['window_tx_count'], HEIGHT - 1)
assert_equal(chaintxstats['window_interval'], time_diff)
assert_equal(round(chaintxstats['txrate'] * time_diff, 10), Decimal(HEIGHT - 1))
chaintxstats = self.nodes[0].getchaintxstats(blockhash=b1_hash)
assert_equal(chaintxstats['time'], b1['time'])
assert_equal(chaintxstats['txcount'], 2)
assert_equal(chaintxstats['window_final_block_hash'], b1_hash)
assert_equal(chaintxstats['window_final_block_height'], 1)
assert_equal(chaintxstats['window_block_count'], 0)
assert 'window_tx_count' not in chaintxstats
assert 'window_interval' not in chaintxstats
assert 'txrate' not in chaintxstats
def _test_gettxoutsetinfo(self):
node = self.nodes[0]
res = node.gettxoutsetinfo()
assert_equal(res['total_amount'], Decimal('8725.00000000'))
assert_equal(res['transactions'], HEIGHT)
assert_equal(res['height'], HEIGHT)
assert_equal(res['txouts'], HEIGHT)
assert_equal(res['bogosize'], 16800),
assert_equal(res['bestblock'], node.getblockhash(HEIGHT))
size = res['disk_size']
assert size > 6400
assert size < 64000
assert_equal(len(res['bestblock']), 64)
assert_equal(len(res['hash_serialized_2']), 64)
self.log.info("Test gettxoutsetinfo works for blockchain with just the genesis block")
b1hash = node.getblockhash(1)
node.invalidateblock(b1hash)
res2 = node.gettxoutsetinfo()
assert_equal(res2['transactions'], 0)
assert_equal(res2['total_amount'], Decimal('0'))
assert_equal(res2['height'], 0)
assert_equal(res2['txouts'], 0)
assert_equal(res2['bogosize'], 0),
assert_equal(res2['bestblock'], node.getblockhash(0))
assert_equal(len(res2['hash_serialized_2']), 64)
self.log.info("Test gettxoutsetinfo returns the same result after invalidate/reconsider block")
node.reconsiderblock(b1hash)
res3 = node.gettxoutsetinfo()
# The field 'disk_size' is non-deterministic and can thus not be
# compared between res and res3. Everything else should be the same.
del res['disk_size'], res3['disk_size']
assert_equal(res, res3)
self.log.info("Test gettxoutsetinfo hash_type option")
# Adding hash_type 'hash_serialized_2', which is the default, should
# not change the result.
res4 = node.gettxoutsetinfo(hash_type='hash_serialized_2')
del res4['disk_size']
assert_equal(res, res4)
# hash_type none should not return a UTXO set hash.
res5 = node.gettxoutsetinfo(hash_type='none')
assert 'hash_serialized_2' not in res5
# hash_type muhash should return a different UTXO set hash.
res6 = node.gettxoutsetinfo(hash_type='muhash')
assert 'muhash' in res6
assert(res['hash_serialized_2'] != res6['muhash'])
# muhash should not be returned unless requested.
for r in [res, res2, res3, res4, res5]:
assert 'muhash' not in r
# Unknown hash_type raises an error
assert_raises_rpc_error(-8, "'foo hash' is not a valid hash_type", node.gettxoutsetinfo, "foo hash")
def _test_getblockheader(self):
self.log.info("Test getblockheader")
node = self.nodes[0]
assert_raises_rpc_error(-8, "hash must be of length 64 (not 8, for 'nonsense')", node.getblockheader, "nonsense")
assert_raises_rpc_error(-8, "hash must be hexadecimal string (not 'ZZZ7bb8b1697ea987f3b223ba7819250cae33efacb068d23dc24859824a77844')", node.getblockheader, "ZZZ7bb8b1697ea987f3b223ba7819250cae33efacb068d23dc24859824a77844")
assert_raises_rpc_error(-5, "Block not found", node.getblockheader, "0cf7bb8b1697ea987f3b223ba7819250cae33efacb068d23dc24859824a77844")
besthash = node.getbestblockhash()
secondbesthash = node.getblockhash(HEIGHT - 1)
header = node.getblockheader(blockhash=besthash)
assert_equal(header['hash'], besthash)
assert_equal(header['height'], HEIGHT)
assert_equal(header['confirmations'], 1)
assert_equal(header['previousblockhash'], secondbesthash)
assert_is_hex_string(header['chainwork'])
assert_equal(header['nTx'], 1)
assert_is_hash_string(header['hash'])
assert_is_hash_string(header['previousblockhash'])
assert_is_hash_string(header['merkleroot'])
assert_is_hash_string(header['bits'], length=None)
assert isinstance(header['time'], int)
assert_equal(header['mediantime'], TIME_RANGE_MTP)
assert isinstance(header['nonce'], int)
assert isinstance(header['version'], int)
assert isinstance(int(header['versionHex'], 16), int)
assert isinstance(header['difficulty'], Decimal)
# Test with verbose=False, which should return the header as hex.
header_hex = node.getblockheader(blockhash=besthash, verbose=False)
assert_is_hex_string(header_hex)
header = from_hex(CBlockHeader(), header_hex)
header.calc_sha256()
assert_equal(header.hash, besthash)
assert 'previousblockhash' not in node.getblockheader(node.getblockhash(0))
assert 'nextblockhash' not in node.getblockheader(node.getbestblockhash())
def _test_getdifficulty(self):
self.log.info("Test getdifficulty")
difficulty = self.nodes[0].getdifficulty()
# 1 hash in 2 should be valid, so difficulty should be 1/2**31
# binary => decimal => binary math is why we do this check
assert abs(difficulty * 2**31 - 1) < 0.0001
def _test_getnetworkhashps(self):
self.log.info("Test getnetworkhashps")
hashes_per_second = self.nodes[0].getnetworkhashps()
# This should be 2 hashes every 10 minutes or 1/300
assert abs(hashes_per_second * 300 - 1) < 0.0001
def _test_stopatheight(self):
self.log.info("Test stopping at height")
assert_equal(self.nodes[0].getblockcount(), HEIGHT)
self.generate(self.wallet, 6)
assert_equal(self.nodes[0].getblockcount(), HEIGHT + 6)
self.log.debug('Node should not stop at this height')
assert_raises(subprocess.TimeoutExpired, lambda: self.nodes[0].process.wait(timeout=3))
try:
self.generatetoaddress(self.nodes[0], 1, self.wallet.get_address(), sync_fun=self.no_op)
except (ConnectionError, http.client.BadStatusLine):
pass # The node already shut down before response
self.log.debug('Node should stop at this height...')
self.nodes[0].wait_until_stopped()
self.start_node(0)
assert_equal(self.nodes[0].getblockcount(), HEIGHT + 7)
def _test_waitforblockheight(self):
self.log.info("Test waitforblockheight")
node = self.nodes[0]
peer = node.add_p2p_connection(P2PInterface())
current_height = node.getblock(node.getbestblockhash())['height']
# Create a fork somewhere below our current height, invalidate the tip
# of that fork, and then ensure that waitforblockheight still
# works as expected.
#
# (Previously this was broken based on setting
# `rpc/blockchain.cpp:latestblock` incorrectly.)
#
b20hash = node.getblockhash(20)
b20 = node.getblock(b20hash)
def solve_and_send_block(prevhash, height, time):
b = create_block(prevhash, create_coinbase(height), time)
b.solve()
peer.send_and_ping(msg_block(b))
return b
b21f = solve_and_send_block(int(b20hash, 16), 21, b20['time'] + 1)
b22f = solve_and_send_block(b21f.sha256, 22, b21f.nTime + 1)
node.invalidateblock(b22f.hash)
def assert_waitforheight(height, timeout=2):
assert_equal(
node.waitforblockheight(height=height, timeout=timeout)['height'],
current_height)
assert_waitforheight(0)
assert_waitforheight(current_height - 1)
assert_waitforheight(current_height)
assert_waitforheight(current_height + 1)
def _test_getblock(self):
node = self.nodes[0]
fee_per_byte = Decimal('0.00000010')
fee_per_kb = 1000 * fee_per_byte
self.wallet.send_self_transfer(fee_rate=fee_per_kb, from_node=node)
blockhash = self.generate(node, 1)[0]
def assert_fee_not_in_block(verbosity):
block = node.getblock(blockhash, verbosity)
assert 'fee' not in block['tx'][1]
def assert_fee_in_block(verbosity):
block = node.getblock(blockhash, verbosity)
tx = block['tx'][1]
assert 'fee' in tx
assert_equal(tx['fee'], tx['vsize'] * fee_per_byte)
def assert_vin_contains_prevout(verbosity):
block = node.getblock(blockhash, verbosity)
tx = block["tx"][1]
total_vin = Decimal("0.00000000")
total_vout = Decimal("0.00000000")
for vin in tx["vin"]:
assert "prevout" in vin
assert_equal(set(vin["prevout"].keys()), set(("value", "height", "generated", "scriptPubKey")))
assert_equal(vin["prevout"]["generated"], True)
total_vin += vin["prevout"]["value"]
for vout in tx["vout"]:
total_vout += vout["value"]
assert_equal(total_vin, total_vout + tx["fee"])
def assert_vin_does_not_contain_prevout(verbosity):
block = node.getblock(blockhash, verbosity)
tx = block["tx"][1]
if isinstance(tx, str):
# In verbosity level 1, only the transaction hashes are written
pass
else:
for vin in tx["vin"]:
assert "prevout" not in vin
self.log.info("Test that getblock with verbosity 1 doesn't include fee")
assert_fee_not_in_block(1)
self.log.info('Test that getblock with verbosity 2 and 3 includes expected fee')
assert_fee_in_block(2)
assert_fee_in_block(3)
self.log.info("Test that getblock with verbosity 1 and 2 does not include prevout")
assert_vin_does_not_contain_prevout(1)
assert_vin_does_not_contain_prevout(2)
self.log.info("Test that getblock with verbosity 3 includes prevout")
assert_vin_contains_prevout(3)
self.log.info("Test that getblock with verbosity 2 and 3 still works with pruned Undo data")
datadir = get_datadir_path(self.options.tmpdir, 0)
self.log.info("Test getblock with invalid verbosity type returns proper error message")
assert_raises_rpc_error(-1, "JSON value is not an integer as expected", node.getblock, blockhash, "2")
def move_block_file(old, new):
old_path = os.path.join(datadir, self.chain, 'blocks', old)
new_path = os.path.join(datadir, self.chain, 'blocks', new)
os.rename(old_path, new_path)
# Move instead of deleting so we can restore chain state afterwards
move_block_file('rev00000.dat', 'rev_wrong')
assert_fee_not_in_block(2)
assert_fee_not_in_block(3)
assert_vin_does_not_contain_prevout(2)
assert_vin_does_not_contain_prevout(3)
# Restore chain state
move_block_file('rev_wrong', 'rev00000.dat')
assert 'previousblockhash' not in node.getblock(node.getblockhash(0))
assert 'nextblockhash' not in node.getblock(node.getbestblockhash())
def run_test(self):
node = self.nodes[0]
miniwallet = MiniWallet(node)
miniwallet.rescan_utxos()
self.log.info('Generate an empty block to address')
address = miniwallet.get_address()
hash = self.generateblock(node, output=address,
transactions=[])['hash']
block = node.getblock(blockhash=hash, verbose=2)
assert_equal(len(block['tx']), 1)
assert_equal(block['tx'][0]['vout'][0]['scriptPubKey']['address'],
address)
self.log.info('Generate an empty block to a descriptor')
hash = self.generateblock(node, 'addr(' + address + ')', [])['hash']
block = node.getblock(blockhash=hash, verbosity=2)
assert_equal(len(block['tx']), 1)
assert_equal(block['tx'][0]['vout'][0]['scriptPubKey']['address'],
address)
self.log.info(
'Generate an empty block to a combo descriptor with compressed pubkey'
)
combo_key = '0279be667ef9dcbbac55a06295ce870b07029bfcdb2dce28d959f2815b16f81798'
combo_address = 'bcrt1qw508d6qejxtdg4y5r3zarvary0c5xw7kygt080'
hash = self.generateblock(node, 'combo(' + combo_key + ')', [])['hash']
block = node.getblock(hash, 2)
assert_equal(len(block['tx']), 1)
assert_equal(block['tx'][0]['vout'][0]['scriptPubKey']['address'],
combo_address)
self.log.info(
'Generate an empty block to a combo descriptor with uncompressed pubkey'
)
combo_key = '0408ef68c46d20596cc3f6ddf7c8794f71913add807f1dc55949fa805d764d191c0b7ce6894c126fce0babc6663042f3dde9b0cf76467ea315514e5a6731149c67'
combo_address = 'mkc9STceoCcjoXEXe6cm66iJbmjM6zR9B2'
hash = self.generateblock(node, 'combo(' + combo_key + ')', [])['hash']
block = node.getblock(hash, 2)
assert_equal(len(block['tx']), 1)
assert_equal(block['tx'][0]['vout'][0]['scriptPubKey']['address'],
combo_address)
# Generate some extra mempool transactions to verify they don't get mined
for _ in range(10):
miniwallet.send_self_transfer(from_node=node)
self.log.info('Generate block with txid')
txid = miniwallet.send_self_transfer(from_node=node)['txid']
hash = self.generateblock(node, address, [txid])['hash']
block = node.getblock(hash, 1)
assert_equal(len(block['tx']), 2)
assert_equal(block['tx'][1], txid)
self.log.info('Generate block with raw tx')
rawtx = miniwallet.create_self_transfer(from_node=node)['hex']
hash = self.generateblock(node, address, [rawtx])['hash']
block = node.getblock(hash, 1)
assert_equal(len(block['tx']), 2)
txid = block['tx'][1]
assert_equal(
node.getrawtransaction(txid=txid, verbose=False, blockhash=hash),
rawtx)
self.log.info('Fail to generate block with out of order txs')
txid1 = miniwallet.send_self_transfer(from_node=node)['txid']
utxo1 = miniwallet.get_utxo(txid=txid1)
rawtx2 = miniwallet.create_self_transfer(from_node=node,
utxo_to_spend=utxo1)['hex']
assert_raises_rpc_error(
-25, 'TestBlockValidity failed: bad-txns-inputs-missingorspent',
self.generateblock, node, address, [rawtx2, txid1])
self.log.info('Fail to generate block with txid not in mempool')
missing_txid = '0000000000000000000000000000000000000000000000000000000000000000'
assert_raises_rpc_error(
-5, 'Transaction ' + missing_txid + ' not in mempool.',
self.generateblock, node, address, [missing_txid])
self.log.info('Fail to generate block with invalid raw tx')
invalid_raw_tx = '0000'
assert_raises_rpc_error(
-22, 'Transaction decode failed for ' + invalid_raw_tx,
self.generateblock, node, address, [invalid_raw_tx])
self.log.info('Fail to generate block with invalid address/descriptor')
assert_raises_rpc_error(-5, 'Invalid address or descriptor',
self.generateblock, node, '1234', [])
self.log.info('Fail to generate block with a ranged descriptor')
ranged_descriptor = 'pkh(tpubD6NzVbkrYhZ4XgiXtGrdW5XDAPFCL9h7we1vwNCpn8tGbBcgfVYjXyhWo4E1xkh56hjod1RhGjxbaTLV3X4FyWuejifB9jusQ46QzG87VKp/0/*)'
assert_raises_rpc_error(
-8,
'Ranged descriptor not accepted. Maybe pass through deriveaddresses first?',
self.generateblock, node, ranged_descriptor, [])
self.log.info(
'Fail to generate block with a descriptor missing a private key')
child_descriptor = 'pkh(tpubD6NzVbkrYhZ4XgiXtGrdW5XDAPFCL9h7we1vwNCpn8tGbBcgfVYjXyhWo4E1xkh56hjod1RhGjxbaTLV3X4FyWuejifB9jusQ46QzG87VKp/0\'/0)'
assert_raises_rpc_error(-5,
'Cannot derive script without private keys',
self.generateblock, node, child_descriptor, [])
def test_muhash_implementation(self):
self.log.info("Test MuHash implementation consistency")
node = self.nodes[0]
wallet = MiniWallet(node)
mocktime = node.getblockheader(node.getblockhash(0))['time'] + 1
node.setmocktime(mocktime)
# Generate 100 blocks and remove the first since we plan to spend its
# coinbase
block_hashes = wallet.generate(1) + node.generate(99)
blocks = list(
map(lambda block: FromHex(CBlock(), node.getblock(block, False)),
block_hashes))
blocks.pop(0)
# Create a spending transaction and mine a block which includes it
txid = wallet.send_self_transfer(from_node=node)['txid']
tx_block = node.generateblock(output=wallet.get_address(),
transactions=[txid])
blocks.append(FromHex(CBlock(), node.getblock(tx_block['hash'],
False)))
# Unlike upstream, Xaya allows spending the genesis block's coinbase,
# so we have to include that into the UTXO set.
genesis = FromHex(CBlock(), node.getblock(node.getblockhash(0), False))
blocks = [genesis] + blocks
# Serialize the outputs that should be in the UTXO set and add them to
# a MuHash object
muhash = MuHash3072()
for height, block in enumerate(blocks):
# We spent the first mined block (after the genesis block).
if height > 0:
height += 1
for tx in block.vtx:
for n, tx_out in enumerate(tx.vout):
coinbase = 1 if not tx.vin[0].prevout.hash else 0
# Skip witness commitment
if (coinbase and n > 0):
continue
data = COutPoint(int(tx.rehash(), 16), n).serialize()
data += struct.pack("<i", height * 2 + coinbase)
data += tx_out.serialize()
muhash.insert(data)
finalized = muhash.digest()
node_muhash = node.gettxoutsetinfo("muhash")['muhash']
assert_equal(finalized[::-1].hex(), node_muhash)
# The values differ from upstream since in Xaya the genesis block's coinbase
# is part of the UTXO set.
self.log.info("Test deterministic UTXO set hash results")
assert_equal(
node.gettxoutsetinfo()['hash_serialized_2'],
"450cb0874edb935d7243d3e83ea2dfe463729a7f08bbe701ab830f3927ce88da")
assert_equal(
node.gettxoutsetinfo("muhash")['muhash'],
"5de773dfb84089156402f41bbfddf27652a3cf136e2bed2986a7ce6bc6db4a80")
