dash/test/functional/test_framework/blocktools.py
2024-10-05 17:10:03 +00:00

338 lines
12 KiB
Python

#!/usr/bin/env python3
# Copyright (c) 2015-2020 The Bitcoin Core developers
# Distributed under the MIT software license, see the accompanying
# file COPYING or http://www.opensource.org/licenses/mit-license.php.
"""Utilities for manipulating blocks and transactions."""
from decimal import Decimal
import io
import struct
import time
import unittest
from .messages import (
CBlock,
CCbTx,
COIN,
COutPoint,
CTransaction,
CTxIn,
CTxOut,
tx_from_hex,
from_hex,
uint256_to_string,
)
from .script import CScript, CScriptNum, CScriptOp, OP_TRUE, OP_CHECKSIG
from .util import assert_equal
from io import BytesIO
MAX_BLOCK_SIGOPS = 40000
# Genesis block time (regtest)
TIME_GENESIS_BLOCK = 1417713337
MAX_FUTURE_BLOCK_TIME = 2 * 60 * 60
# Coinbase transaction outputs can only be spent after this number of new blocks (network rule)
COINBASE_MATURITY = 100
NORMAL_GBT_REQUEST_PARAMS = {"rules": []} # type: ignore[var-annotated]
VERSIONBITS_LAST_OLD_BLOCK_VERSION = 4
def create_block(hashprev=None, coinbase=None, ntime=None, *, version=None, tmpl=None, txlist=None, dip4_activated=False, v20_activated=False):
"""Create a block (with regtest difficulty)."""
block = CBlock()
if tmpl is None:
tmpl = {}
block.nVersion = version or tmpl.get('version') or VERSIONBITS_LAST_OLD_BLOCK_VERSION
block.nTime = ntime or tmpl.get('curtime') or int(time.time() + 600)
block.hashPrevBlock = hashprev or int(tmpl['previousblockhash'], 0x10)
if tmpl and not tmpl.get('bits') is None:
block.nBits = struct.unpack('>I', bytes.fromhex(tmpl['bits']))[0]
else:
block.nBits = 0x207fffff # difficulty retargeting is disabled in REGTEST chainparams
if coinbase is None:
coinbase = create_coinbase(height=tmpl['height'], dip4_activated=dip4_activated, v20_activated=v20_activated)
block.vtx.append(coinbase)
if txlist:
for tx in txlist:
if not hasattr(tx, 'calc_sha256'):
txo = CTransaction()
txo.deserialize(io.BytesIO(tx))
tx = txo
block.vtx.append(tx)
block.hashMerkleRoot = block.calc_merkle_root()
block.calc_sha256()
return block
# TODO: imlement MN_RR support here or remove it
def create_block_with_mnpayments(mninfo, node, vtx=None, mn_payee=None, mn_amount=None):
if vtx is None:
vtx = []
bt = node.getblocktemplate()
height = bt['height']
tip_hash = bt['previousblockhash']
coinbasevalue = bt['coinbasevalue']
assert len(bt['masternode']) <= 2
if mn_payee is None:
mn_payee = bt['masternode'][0]['payee']
mn_operator_payee = None
if len(bt['masternode']) == 2:
mn_operator_payee = bt['masternode'][1]['payee']
# we can't take the masternode payee amount from the template here as we might have additional fees in vtx
# calculate fees that the block template included (we'll have to remove it from the coinbase as we won't
# include the template's transactions
bt_fees = 0
for tx in bt['transactions']:
bt_fees += tx['fee']
new_fees = 0
for tx in vtx:
in_value = 0
out_value = 0
for txin in tx.vin:
txout = node.gettxout(uint256_to_string(txin.prevout.hash), txin.prevout.n, False)
in_value += int(txout['value'] * COIN)
for txout in tx.vout:
out_value += txout.nValue
new_fees += in_value - out_value
# fix fees
coinbasevalue -= bt_fees
coinbasevalue += new_fees
operator_reward = 0
if mn_operator_payee is not None:
for mn in mninfo:
if mn.rewards_address == mn_payee:
operator_reward = mn.operator_reward
break
assert operator_reward > 0
mn_operator_amount = 0
if mn_amount is None:
v20_info = node.getblockchaininfo()['softforks']['v20']
mn_amount_total = get_masternode_payment(height, coinbasevalue, v20_info['active'])
mn_operator_amount = mn_amount_total * operator_reward // 100
mn_amount = mn_amount_total - mn_operator_amount
miner_amount = coinbasevalue - mn_amount - mn_operator_amount
miner_address = node.get_deterministic_priv_key().address
outputs = {miner_address: str(Decimal(miner_amount) / COIN)}
if mn_amount > 0:
outputs[mn_payee] = str(Decimal(mn_amount) / COIN)
if mn_operator_amount > 0:
outputs[mn_operator_payee] = str(Decimal(mn_operator_amount) / COIN)
coinbase = tx_from_hex(node.createrawtransaction([], outputs))
coinbase.vin = create_coinbase(height).vin
# We can't really use this one as it would result in invalid merkle roots for masternode lists
if len(bt['coinbase_payload']) != 0:
tip_block = node.getblock(tip_hash)
cbtx = from_hex(CCbTx(version=1), bt['coinbase_payload'])
if 'cbTx' in tip_block:
cbtx.merkleRootMNList = int(tip_block['cbTx']['merkleRootMNList'], 16)
else:
cbtx.merkleRootMNList = 0
coinbase.nVersion = 3
coinbase.nType = 5 # CbTx
coinbase.vExtraPayload = cbtx.serialize()
coinbase.calc_sha256()
block = create_block(int(tip_hash, 16), coinbase, ntime=bt['curtime'], version=bt['version'])
block.vtx += vtx
# Add quorum commitments from template
for tx in bt['transactions']:
tx2 = tx_from_hex(tx['data'])
if tx2.nType == 6:
block.vtx.append(tx2)
block.hashMerkleRoot = block.calc_merkle_root()
block.solve()
return block
def script_BIP34_coinbase_height(height):
if height <= 16:
res = CScriptOp.encode_op_n(height)
# Append dummy to increase scriptSig size above 2 (see bad-cb-length consensus rule)
return CScript([res, OP_TRUE])
return CScript([CScriptNum(height)])
def create_coinbase(height, pubkey=None, dip4_activated=False, v20_activated=False, nValue=500):
"""Create a coinbase transaction, assuming no miner fees.
If pubkey is passed in, the coinbase output will be a P2PK output;
otherwise an anyone-can-spend output."""
coinbase = CTransaction()
coinbase.vin.append(CTxIn(COutPoint(0, 0xffffffff), script_BIP34_coinbase_height(height), 0xffffffff))
coinbaseoutput = CTxOut()
coinbaseoutput.nValue = nValue * COIN
if nValue == 500:
halvings = int(height / 150) # regtest
coinbaseoutput.nValue >>= halvings
if (pubkey is not None):
coinbaseoutput.scriptPubKey = CScript([pubkey, OP_CHECKSIG])
else:
coinbaseoutput.scriptPubKey = CScript([OP_TRUE])
coinbase.vout = [coinbaseoutput]
if dip4_activated:
coinbase.nVersion = 3
coinbase.nType = 5
cbtx_version = 3 if v20_activated else 2
cbtx_payload = CCbTx(cbtx_version, height, 0, 0, 0)
coinbase.vExtraPayload = cbtx_payload.serialize()
coinbase.calc_sha256()
return coinbase
def create_tx_with_script(prevtx, n, script_sig=b"", *, amount, script_pub_key=CScript()):
"""Return one-input, one-output transaction object
spending the prevtx's n-th output with the given amount.
Can optionally pass scriptPubKey and scriptSig, default is anyone-can-spend output.
"""
tx = CTransaction()
assert n < len(prevtx.vout)
tx.vin.append(CTxIn(COutPoint(prevtx.sha256, n), script_sig, 0xffffffff))
tx.vout.append(CTxOut(amount, script_pub_key))
tx.calc_sha256()
return tx
def create_transaction(node, txid, to_address, *, amount):
""" Return signed transaction spending the first output of the
input txid. Note that the node must have a wallet that can
sign for the output that is being spent.
"""
raw_tx = create_raw_transaction(node, txid, to_address, amount=amount)
tx = CTransaction()
tx.deserialize(BytesIO(bytes.fromhex(raw_tx)))
return tx
def create_raw_transaction(node, txid, to_address, *, amount):
""" Return raw signed transaction spending the first output of the
input txid. Note that the node must have a wallet that can sign
for the output that is being spent.
"""
psbt = node.createpsbt(inputs=[{"txid": txid, "vout": 0}], outputs={to_address: amount})
for _ in range(2):
for w in node.listwallets():
wrpc = node.get_wallet_rpc(w)
signed_psbt = wrpc.walletprocesspsbt(psbt)
psbt = signed_psbt['psbt']
final_psbt = node.finalizepsbt(psbt)
assert_equal(final_psbt["complete"], True)
return final_psbt['hex']
def get_legacy_sigopcount_block(block, accurate=True):
count = 0
for tx in block.vtx:
count += get_legacy_sigopcount_tx(tx, accurate)
return count
def get_legacy_sigopcount_tx(tx, accurate=True):
count = 0
for i in tx.vout:
count += i.scriptPubKey.GetSigOpCount(accurate)
for j in tx.vin:
# scriptSig might be of type bytes, so convert to CScript for the moment
count += CScript(j.scriptSig).GetSigOpCount(accurate)
return count
"""
Dash chaintips rpc returns extra info in each tip (difficulty, chainwork, and
forkpoint). Filter down to relevant ones checked in this test.
"""
def filter_tip_keys(chaintips):
check_keys = ["hash", "height", "branchlen", "status"]
filtered_tips = []
for tip in chaintips:
filtered_tips.append({k: tip[k] for k in check_keys})
return filtered_tips
# Identical to GetMasternodePayment in C++ code
# TODO: remove it or make **proper** tests for various height
def get_masternode_payment(nHeight, blockValue, fV20Active):
ret = int(blockValue / 5)
nMNPIBlock = 350
nMNPIPeriod = 10
nReallocActivationHeight = 1
if nHeight > nMNPIBlock:
ret += int(blockValue / 20)
if nHeight > nMNPIBlock+(nMNPIPeriod* 1):
ret += int(blockValue / 20)
if nHeight > nMNPIBlock+(nMNPIPeriod* 2):
ret += int(blockValue / 20)
if nHeight > nMNPIBlock+(nMNPIPeriod* 3):
ret += int(blockValue / 40)
if nHeight > nMNPIBlock+(nMNPIPeriod* 4):
ret += int(blockValue / 40)
if nHeight > nMNPIBlock+(nMNPIPeriod* 5):
ret += int(blockValue / 40)
if nHeight > nMNPIBlock+(nMNPIPeriod* 6):
ret += int(blockValue / 40)
if nHeight > nMNPIBlock+(nMNPIPeriod* 7):
ret += int(blockValue / 40)
if nHeight > nMNPIBlock+(nMNPIPeriod* 9):
ret += int(blockValue / 40)
if nHeight < nReallocActivationHeight:
# Block Reward Realocation is not activated yet, nothing to do
return ret
nSuperblockCycle = 20
# Actual realocation starts in the cycle next to one activation happens in
nReallocStart = nReallocActivationHeight - nReallocActivationHeight % nSuperblockCycle + nSuperblockCycle
if nHeight < nReallocStart:
# Activated but we have to wait for the next cycle to start realocation, nothing to do
return ret
if fV20Active:
# Once MNRewardReallocated activates, block reward is 80% of block subsidy (+ tx fees) since treasury is 20%
# Since the MN reward needs to be equal to 60% of the block subsidy (according to the proposal), MN reward is set to 75% of the block reward.
# Previous reallocation periods are dropped.
return blockValue * 3 // 4
# Periods used to reallocate the masternode reward from 50% to 60%
vecPeriods = [
513, # Period 1: 51.3%
526, # Period 2: 52.6%
533, # Period 3: 53.3%
540, # Period 4: 54%
546, # Period 5: 54.6%
552, # Period 6: 55.2%
557, # Period 7: 55.7%
562, # Period 8: 56.2%
567, # Period 9: 56.7%
572, # Period 10: 57.2%
577, # Period 11: 57.7%
582, # Period 12: 58.2%
585, # Period 13: 58.5%
588, # Period 14: 58.8%
591, # Period 15: 59.1%
594, # Period 16: 59.4%
597, # Period 17: 59.7%
599, # Period 18: 59.9%
600 # Period 19: 60%
]
nReallocCycle = nSuperblockCycle * 3
nCurrentPeriod = min(int((nHeight - nReallocStart) / nReallocCycle), len(vecPeriods) - 1)
return int(blockValue * vecPeriods[nCurrentPeriod] / 1000)
class TestFrameworkBlockTools(unittest.TestCase):
def test_create_coinbase(self):
height = 20
coinbase_tx = create_coinbase(height=height)
assert_equal(CScriptNum.decode(coinbase_tx.vin[0].scriptSig), height)