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|
#!/usr/bin/env python3
# Copyright (c) 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.
import argparse
import base64
import json
import logging
import math
import os
import re
import struct
import sys
import time
import subprocess
from io import BytesIO
PATH_BASE_CONTRIB_SIGNET = os.path.abspath(os.path.dirname(os.path.realpath(__file__)))
PATH_BASE_TEST_FUNCTIONAL = os.path.abspath(os.path.join(PATH_BASE_CONTRIB_SIGNET, "..", "..", "test", "functional"))
sys.path.insert(0, PATH_BASE_TEST_FUNCTIONAL)
from test_framework.blocktools import WITNESS_COMMITMENT_HEADER, script_BIP34_coinbase_height # noqa: E402
from test_framework.messages import CBlock, CBlockHeader, COutPoint, CTransaction, CTxIn, CTxInWitness, CTxOut, from_hex, deser_string, hash256, ser_compact_size, ser_string, ser_uint256, tx_from_hex, uint256_from_str # noqa: E402
from test_framework.script import CScriptOp # noqa: E402
logging.basicConfig(
format='%(asctime)s %(levelname)s %(message)s',
level=logging.INFO,
datefmt='%Y-%m-%d %H:%M:%S')
SIGNET_HEADER = b"\xec\xc7\xda\xa2"
PSBT_SIGNET_BLOCK = b"\xfc\x06signetb" # proprietary PSBT global field holding the block being signed
RE_MULTIMINER = re.compile("^(\d+)(-(\d+))?/(\d+)$")
# #### some helpers that could go into test_framework
# like from_hex, but without the hex part
def FromBinary(cls, stream):
"""deserialize a binary stream (or bytes object) into an object"""
# handle bytes object by turning it into a stream
was_bytes = isinstance(stream, bytes)
if was_bytes:
stream = BytesIO(stream)
obj = cls()
obj.deserialize(stream)
if was_bytes:
assert len(stream.read()) == 0
return obj
class PSBTMap:
"""Class for serializing and deserializing PSBT maps"""
def __init__(self, map=None):
self.map = map if map is not None else {}
def deserialize(self, f):
m = {}
while True:
k = deser_string(f)
if len(k) == 0:
break
v = deser_string(f)
if len(k) == 1:
k = k[0]
assert k not in m
m[k] = v
self.map = m
def serialize(self):
m = b""
for k,v in self.map.items():
if isinstance(k, int) and 0 <= k and k <= 255:
k = bytes([k])
m += ser_compact_size(len(k)) + k
m += ser_compact_size(len(v)) + v
m += b"\x00"
return m
class PSBT:
"""Class for serializing and deserializing PSBTs"""
def __init__(self):
self.g = PSBTMap()
self.i = []
self.o = []
self.tx = None
def deserialize(self, f):
assert f.read(5) == b"psbt\xff"
self.g = FromBinary(PSBTMap, f)
assert 0 in self.g.map
self.tx = FromBinary(CTransaction, self.g.map[0])
self.i = [FromBinary(PSBTMap, f) for _ in self.tx.vin]
self.o = [FromBinary(PSBTMap, f) for _ in self.tx.vout]
return self
def serialize(self):
assert isinstance(self.g, PSBTMap)
assert isinstance(self.i, list) and all(isinstance(x, PSBTMap) for x in self.i)
assert isinstance(self.o, list) and all(isinstance(x, PSBTMap) for x in self.o)
assert 0 in self.g.map
tx = FromBinary(CTransaction, self.g.map[0])
assert len(tx.vin) == len(self.i)
assert len(tx.vout) == len(self.o)
psbt = [x.serialize() for x in [self.g] + self.i + self.o]
return b"psbt\xff" + b"".join(psbt)
def to_base64(self):
return base64.b64encode(self.serialize()).decode("utf8")
@classmethod
def from_base64(cls, b64psbt):
return FromBinary(cls, base64.b64decode(b64psbt))
# #####
def create_coinbase(height, value, spk):
cb = CTransaction()
cb.vin = [CTxIn(COutPoint(0, 0xffffffff), script_BIP34_coinbase_height(height), 0xffffffff)]
cb.vout = [CTxOut(value, spk)]
return cb
def get_witness_script(witness_root, witness_nonce):
commitment = uint256_from_str(hash256(ser_uint256(witness_root) + ser_uint256(witness_nonce)))
return b"\x6a" + CScriptOp.encode_op_pushdata(WITNESS_COMMITMENT_HEADER + ser_uint256(commitment))
def signet_txs(block, challenge):
# assumes signet solution has not been added yet so does not need
# to be removed
txs = block.vtx[:]
txs[0] = CTransaction(txs[0])
txs[0].vout[-1].scriptPubKey += CScriptOp.encode_op_pushdata(SIGNET_HEADER)
hashes = []
for tx in txs:
tx.rehash()
hashes.append(ser_uint256(tx.sha256))
mroot = block.get_merkle_root(hashes)
sd = b""
sd += struct.pack("<i", block.nVersion)
sd += ser_uint256(block.hashPrevBlock)
sd += ser_uint256(mroot)
sd += struct.pack("<I", block.nTime)
to_spend = CTransaction()
to_spend.nVersion = 0
to_spend.nLockTime = 0
to_spend.vin = [CTxIn(COutPoint(0, 0xFFFFFFFF), b"\x00" + CScriptOp.encode_op_pushdata(sd), 0)]
to_spend.vout = [CTxOut(0, challenge)]
to_spend.rehash()
spend = CTransaction()
spend.nVersion = 0
spend.nLockTime = 0
spend.vin = [CTxIn(COutPoint(to_spend.sha256, 0), b"", 0)]
spend.vout = [CTxOut(0, b"\x6a")]
return spend, to_spend
def do_createpsbt(block, signme, spendme):
psbt = PSBT()
psbt.g = PSBTMap( {0: signme.serialize(),
PSBT_SIGNET_BLOCK: block.serialize()
} )
psbt.i = [ PSBTMap( {0: spendme.serialize(),
3: bytes([1,0,0,0])})
]
psbt.o = [ PSBTMap() ]
return psbt.to_base64()
def do_decode_psbt(b64psbt):
psbt = PSBT.from_base64(b64psbt)
assert len(psbt.tx.vin) == 1
assert len(psbt.tx.vout) == 1
assert PSBT_SIGNET_BLOCK in psbt.g.map
scriptSig = psbt.i[0].map.get(7, b"")
scriptWitness = psbt.i[0].map.get(8, b"\x00")
return FromBinary(CBlock, psbt.g.map[PSBT_SIGNET_BLOCK]), ser_string(scriptSig) + scriptWitness
def finish_block(block, signet_solution, grind_cmd):
block.vtx[0].vout[-1].scriptPubKey += CScriptOp.encode_op_pushdata(SIGNET_HEADER + signet_solution)
block.vtx[0].rehash()
block.hashMerkleRoot = block.calc_merkle_root()
if grind_cmd is None:
block.solve()
else:
headhex = CBlockHeader.serialize(block).hex()
cmd = grind_cmd.split(" ") + [headhex]
newheadhex = subprocess.run(cmd, stdout=subprocess.PIPE, input=b"", check=True).stdout.strip()
newhead = from_hex(CBlockHeader(), newheadhex.decode('utf8'))
block.nNonce = newhead.nNonce
block.rehash()
return block
def generate_psbt(tmpl, reward_spk, *, blocktime=None):
signet_spk = tmpl["signet_challenge"]
signet_spk_bin = bytes.fromhex(signet_spk)
cbtx = create_coinbase(height=tmpl["height"], value=tmpl["coinbasevalue"], spk=reward_spk)
cbtx.vin[0].nSequence = 2**32-2
cbtx.rehash()
block = CBlock()
block.nVersion = tmpl["version"]
block.hashPrevBlock = int(tmpl["previousblockhash"], 16)
block.nTime = tmpl["curtime"] if blocktime is None else blocktime
if block.nTime < tmpl["mintime"]:
block.nTime = tmpl["mintime"]
block.nBits = int(tmpl["bits"], 16)
block.nNonce = 0
block.vtx = [cbtx] + [tx_from_hex(t["data"]) for t in tmpl["transactions"]]
witnonce = 0
witroot = block.calc_witness_merkle_root()
cbwit = CTxInWitness()
cbwit.scriptWitness.stack = [ser_uint256(witnonce)]
block.vtx[0].wit.vtxinwit = [cbwit]
block.vtx[0].vout.append(CTxOut(0, get_witness_script(witroot, witnonce)))
signme, spendme = signet_txs(block, signet_spk_bin)
return do_createpsbt(block, signme, spendme)
def get_reward_address(args, height):
if args.address is not None:
return args.address
if '*' not in args.descriptor:
addr = json.loads(args.bcli("deriveaddresses", args.descriptor))[0]
args.address = addr
return addr
remove = [k for k in args.derived_addresses.keys() if k+20 <= height]
for k in remove:
del args.derived_addresses[k]
addr = args.derived_addresses.get(height, None)
if addr is None:
addrs = json.loads(args.bcli("deriveaddresses", args.descriptor, "[%d,%d]" % (height, height+20)))
addr = addrs[0]
for k, a in enumerate(addrs):
args.derived_addresses[height+k] = a
return addr
def get_reward_addr_spk(args, height):
assert args.address is not None or args.descriptor is not None
if hasattr(args, "reward_spk"):
return args.address, args.reward_spk
reward_addr = get_reward_address(args, height)
reward_spk = bytes.fromhex(json.loads(args.bcli("getaddressinfo", reward_addr))["scriptPubKey"])
if args.address is not None:
# will always be the same, so cache
args.reward_spk = reward_spk
return reward_addr, reward_spk
def do_genpsbt(args):
tmpl = json.load(sys.stdin)
_, reward_spk = get_reward_addr_spk(args, tmpl["height"])
psbt = generate_psbt(tmpl, reward_spk)
print(psbt)
def do_solvepsbt(args):
block, signet_solution = do_decode_psbt(sys.stdin.read())
block = finish_block(block, signet_solution, args.grind_cmd)
print(block.serialize().hex())
def nbits_to_target(nbits):
shift = (nbits >> 24) & 0xff
return (nbits & 0x00ffffff) * 2**(8*(shift - 3))
def target_to_nbits(target):
tstr = "{0:x}".format(target)
if len(tstr) < 6:
tstr = ("000000"+tstr)[-6:]
if len(tstr) % 2 != 0:
tstr = "0" + tstr
if int(tstr[0],16) >= 0x8:
# avoid "negative"
tstr = "00" + tstr
fix = int(tstr[:6], 16)
sz = len(tstr)//2
if tstr[6:] != "0"*(sz*2-6):
fix += 1
return int("%02x%06x" % (sz,fix), 16)
def seconds_to_hms(s):
if s == 0:
return "0s"
neg = (s < 0)
if neg:
s = -s
out = ""
if s % 60 > 0:
out = "%ds" % (s % 60)
s //= 60
if s % 60 > 0:
out = "%dm%s" % (s % 60, out)
s //= 60
if s > 0:
out = "%dh%s" % (s, out)
if neg:
out = "-" + out
return out
def next_block_delta(last_nbits, last_hash, ultimate_target, do_poisson):
# strategy:
# 1) work out how far off our desired target we are
# 2) cap it to a factor of 4 since that's the best we can do in a single retarget period
# 3) use that to work out the desired average interval in this retarget period
# 4) if doing poisson, use the last hash to pick a uniformly random number in [0,1), and work out a random multiplier to vary the average by
# 5) cap the resulting interval between 1 second and 1 hour to avoid extremes
INTERVAL = 600.0*2016/2015 # 10 minutes, adjusted for the off-by-one bug
current_target = nbits_to_target(last_nbits)
retarget_factor = ultimate_target / current_target
retarget_factor = max(0.25, min(retarget_factor, 4.0))
avg_interval = INTERVAL * retarget_factor
if do_poisson:
det_rand = int(last_hash[-8:], 16) * 2**-32
this_interval_variance = -math.log1p(-det_rand)
else:
this_interval_variance = 1
this_interval = avg_interval * this_interval_variance
this_interval = max(1, min(this_interval, 3600))
return this_interval
def next_block_is_mine(last_hash, my_blocks):
det_rand = int(last_hash[-16:-8], 16)
return my_blocks[0] <= (det_rand % my_blocks[2]) < my_blocks[1]
def do_generate(args):
if args.max_blocks is not None:
if args.ongoing:
logging.error("Cannot specify both --ongoing and --max-blocks")
return 1
if args.max_blocks < 1:
logging.error("N must be a positive integer")
return 1
max_blocks = args.max_blocks
elif args.ongoing:
max_blocks = None
else:
max_blocks = 1
if args.set_block_time is not None and max_blocks != 1:
logging.error("Cannot specify --ongoing or --max-blocks > 1 when using --set-block-time")
return 1
if args.set_block_time is not None and args.set_block_time < 0:
args.set_block_time = time.time()
logging.info("Treating negative block time as current time (%d)" % (args.set_block_time))
if args.min_nbits:
if args.nbits is not None:
logging.error("Cannot specify --nbits and --min-nbits")
return 1
args.nbits = "1e0377ae"
logging.info("Using nbits=%s" % (args.nbits))
if args.set_block_time is None:
if args.nbits is None or len(args.nbits) != 8:
logging.error("Must specify --nbits (use calibrate command to determine value)")
return 1
if args.multiminer is None:
my_blocks = (0,1,1)
else:
if not args.ongoing:
logging.error("Cannot specify --multiminer without --ongoing")
return 1
m = RE_MULTIMINER.match(args.multiminer)
if m is None:
logging.error("--multiminer argument must be k/m or j-k/m")
return 1
start,_,stop,total = m.groups()
if stop is None:
stop = start
start, stop, total = map(int, (start, stop, total))
if stop < start or start <= 0 or total < stop or total == 0:
logging.error("Inconsistent values for --multiminer")
return 1
my_blocks = (start-1, stop, total)
ultimate_target = nbits_to_target(int(args.nbits,16))
mined_blocks = 0
bestheader = {"hash": None}
lastheader = None
while max_blocks is None or mined_blocks < max_blocks:
# current status?
bci = json.loads(args.bcli("getblockchaininfo"))
if bestheader["hash"] != bci["bestblockhash"]:
bestheader = json.loads(args.bcli("getblockheader", bci["bestblockhash"]))
if lastheader is None:
lastheader = bestheader["hash"]
elif bestheader["hash"] != lastheader:
next_delta = next_block_delta(int(bestheader["bits"], 16), bestheader["hash"], ultimate_target, args.poisson)
next_delta += bestheader["time"] - time.time()
next_is_mine = next_block_is_mine(bestheader["hash"], my_blocks)
logging.info("Received new block at height %d; next in %s (%s)", bestheader["height"], seconds_to_hms(next_delta), ("mine" if next_is_mine else "backup"))
lastheader = bestheader["hash"]
# when is the next block due to be mined?
now = time.time()
if args.set_block_time is not None:
logging.debug("Setting start time to %d", args.set_block_time)
mine_time = args.set_block_time
action_time = now
is_mine = True
elif bestheader["height"] == 0:
time_delta = next_block_delta(int(bestheader["bits"], 16), bci["bestblockhash"], ultimate_target, args.poisson)
time_delta *= 100 # 100 blocks
logging.info("Backdating time for first block to %d minutes ago" % (time_delta/60))
mine_time = now - time_delta
action_time = now
is_mine = True
else:
time_delta = next_block_delta(int(bestheader["bits"], 16), bci["bestblockhash"], ultimate_target, args.poisson)
mine_time = bestheader["time"] + time_delta
is_mine = next_block_is_mine(bci["bestblockhash"], my_blocks)
action_time = mine_time
if not is_mine:
action_time += args.backup_delay
if args.standby_delay > 0:
action_time += args.standby_delay
elif mined_blocks == 0:
# for non-standby, always mine immediately on startup,
# even if the next block shouldn't be ours
action_time = now
# don't want fractional times so round down
mine_time = int(mine_time)
action_time = int(action_time)
# can't mine a block 2h in the future; 1h55m for some safety
action_time = max(action_time, mine_time - 6900)
# ready to go? otherwise sleep and check for new block
if now < action_time:
sleep_for = min(action_time - now, 60)
if mine_time < now:
# someone else might have mined the block,
# so check frequently, so we don't end up late
# mining the next block if it's ours
sleep_for = min(20, sleep_for)
minestr = "mine" if is_mine else "backup"
logging.debug("Sleeping for %s, next block due in %s (%s)" % (seconds_to_hms(sleep_for), seconds_to_hms(mine_time - now), minestr))
time.sleep(sleep_for)
continue
# gbt
tmpl = json.loads(args.bcli("getblocktemplate", '{"rules":["signet","segwit"]}'))
if tmpl["previousblockhash"] != bci["bestblockhash"]:
logging.warning("GBT based off unexpected block (%s not %s), retrying", tmpl["previousblockhash"], bci["bestblockhash"])
time.sleep(1)
continue
logging.debug("GBT template: %s", tmpl)
if tmpl["mintime"] > mine_time:
logging.info("Updating block time from %d to %d", mine_time, tmpl["mintime"])
mine_time = tmpl["mintime"]
if mine_time > now:
logging.error("GBT mintime is in the future: %d is %d seconds later than %d", mine_time, (mine_time-now), now)
return 1
# address for reward
reward_addr, reward_spk = get_reward_addr_spk(args, tmpl["height"])
# mine block
logging.debug("Mining block delta=%s start=%s mine=%s", seconds_to_hms(mine_time-bestheader["time"]), mine_time, is_mine)
mined_blocks += 1
psbt = generate_psbt(tmpl, reward_spk, blocktime=mine_time)
input_stream = os.linesep.join([psbt, "true", "ALL"]).encode('utf8')
psbt_signed = json.loads(args.bcli("-stdin", "walletprocesspsbt", input=input_stream))
if not psbt_signed.get("complete",False):
logging.debug("Generated PSBT: %s" % (psbt,))
sys.stderr.write("PSBT signing failed\n")
return 1
block, signet_solution = do_decode_psbt(psbt_signed["psbt"])
block = finish_block(block, signet_solution, args.grind_cmd)
# submit block
r = args.bcli("-stdin", "submitblock", input=block.serialize().hex().encode('utf8'))
# report
bstr = "block" if is_mine else "backup block"
next_delta = next_block_delta(block.nBits, block.hash, ultimate_target, args.poisson)
next_delta += block.nTime - time.time()
next_is_mine = next_block_is_mine(block.hash, my_blocks)
logging.debug("Block hash %s payout to %s", block.hash, reward_addr)
logging.info("Mined %s at height %d; next in %s (%s)", bstr, tmpl["height"], seconds_to_hms(next_delta), ("mine" if next_is_mine else "backup"))
if r != "":
logging.warning("submitblock returned %s for height %d hash %s", r, tmpl["height"], block.hash)
lastheader = block.hash
def do_calibrate(args):
if args.nbits is not None and args.seconds is not None:
sys.stderr.write("Can only specify one of --nbits or --seconds\n")
return 1
if args.nbits is not None and len(args.nbits) != 8:
sys.stderr.write("Must specify 8 hex digits for --nbits\n")
return 1
TRIALS = 600 # gets variance down pretty low
TRIAL_BITS = 0x1e3ea75f # takes about 5m to do 600 trials
header = CBlockHeader()
header.nBits = TRIAL_BITS
targ = nbits_to_target(header.nBits)
start = time.time()
count = 0
for i in range(TRIALS):
header.nTime = i
header.nNonce = 0
headhex = header.serialize().hex()
cmd = args.grind_cmd.split(" ") + [headhex]
newheadhex = subprocess.run(cmd, stdout=subprocess.PIPE, input=b"", check=True).stdout.strip()
avg = (time.time() - start) * 1.0 / TRIALS
if args.nbits is not None:
want_targ = nbits_to_target(int(args.nbits,16))
want_time = avg*targ/want_targ
else:
want_time = args.seconds if args.seconds is not None else 25
want_targ = int(targ*(avg/want_time))
print("nbits=%08x for %ds average mining time" % (target_to_nbits(want_targ), want_time))
return 0
def bitcoin_cli(basecmd, args, **kwargs):
cmd = basecmd + ["-signet"] + args
logging.debug("Calling bitcoin-cli: %r", cmd)
out = subprocess.run(cmd, stdout=subprocess.PIPE, **kwargs, check=True).stdout
if isinstance(out, bytes):
out = out.decode('utf8')
return out.strip()
def main():
parser = argparse.ArgumentParser()
parser.add_argument("--cli", default="bitcoin-cli", type=str, help="bitcoin-cli command")
parser.add_argument("--debug", action="store_true", help="Print debugging info")
parser.add_argument("--quiet", action="store_true", help="Only print warnings/errors")
cmds = parser.add_subparsers(help="sub-commands")
genpsbt = cmds.add_parser("genpsbt", help="Generate a block PSBT for signing")
genpsbt.set_defaults(fn=do_genpsbt)
solvepsbt = cmds.add_parser("solvepsbt", help="Solve a signed block PSBT")
solvepsbt.set_defaults(fn=do_solvepsbt)
generate = cmds.add_parser("generate", help="Mine blocks")
generate.set_defaults(fn=do_generate)
generate.add_argument("--ongoing", action="store_true", help="Keep mining blocks")
generate.add_argument("--max-blocks", default=None, type=int, help="Max blocks to mine (default=1)")
generate.add_argument("--set-block-time", default=None, type=int, help="Set block time (unix timestamp)")
generate.add_argument("--nbits", default=None, type=str, help="Target nBits (specify difficulty)")
generate.add_argument("--min-nbits", action="store_true", help="Target minimum nBits (use min difficulty)")
generate.add_argument("--poisson", action="store_true", help="Simulate randomised block times")
generate.add_argument("--multiminer", default=None, type=str, help="Specify which set of blocks to mine (eg: 1-40/100 for the first 40%%, 2/3 for the second 3rd)")
generate.add_argument("--backup-delay", default=300, type=int, help="Seconds to delay before mining blocks reserved for other miners (default=300)")
generate.add_argument("--standby-delay", default=0, type=int, help="Seconds to delay before mining blocks (default=0)")
calibrate = cmds.add_parser("calibrate", help="Calibrate difficulty")
calibrate.set_defaults(fn=do_calibrate)
calibrate.add_argument("--nbits", type=str, default=None)
calibrate.add_argument("--seconds", type=int, default=None)
for sp in [genpsbt, generate]:
sp.add_argument("--address", default=None, type=str, help="Address for block reward payment")
sp.add_argument("--descriptor", default=None, type=str, help="Descriptor for block reward payment")
for sp in [solvepsbt, generate, calibrate]:
sp.add_argument("--grind-cmd", default=None, type=str, required=(sp==calibrate), help="Command to grind a block header for proof-of-work")
args = parser.parse_args(sys.argv[1:])
args.bcli = lambda *a, input=b"", **kwargs: bitcoin_cli(args.cli.split(" "), list(a), input=input, **kwargs)
if hasattr(args, "address") and hasattr(args, "descriptor"):
if args.address is None and args.descriptor is None:
sys.stderr.write("Must specify --address or --descriptor\n")
return 1
elif args.address is not None and args.descriptor is not None:
sys.stderr.write("Only specify one of --address or --descriptor\n")
return 1
args.derived_addresses = {}
if args.debug:
logging.getLogger().setLevel(logging.DEBUG)
elif args.quiet:
logging.getLogger().setLevel(logging.WARNING)
else:
logging.getLogger().setLevel(logging.INFO)
if hasattr(args, "fn"):
return args.fn(args)
else:
logging.error("Must specify command")
return 1
if __name__ == "__main__":
main()
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