Feat:reworked script

2024-02-22 03:23:42 -08:00 · 2024-02-22 03:23:42 -08:00 · 4a4f579070
commit 4a4f579070
parent 2d5f75e6a0
15 changed files with 701 additions and 76 deletions
--- a/8
+++ b/8
@ -2,19 +2,17 @@
 FROM ubuntu
 # Install runtime dependencies
-RUN apt-get update && apt-get install -y \
+RUN apt-get update && apt-get install -y jq
 python3 libssl-dev libevent-dev libboost-system-dev libboost-filesystem-dev \
 libboost-chrono-dev libboost-test-dev libboost-thread-dev libdb-dev libdb++-dev python3-pip jq
 # Copy and prepare script for signet configurations
-COPY generate_signet.sh /usr/local/bin
+COPY generate_signet.sh /usr/local/bin/generate_signet.sh
 RUN chmod +x /usr/local/bin/generate_signet.sh
 # Copy Bitcoin.conf file
 COPY bitcoin.conf /root/.bitcoin/bitcoin.conf
 # Copy the logtail.sh script
-COPY logtail.sh /usr/local/bin/
+COPY logtail.sh /usr/local/bin/logtail.sh
 RUN chmod +x /usr/local/bin/logtail.sh
 # Copy the .bashrc file to the container's root directory
--- a/bitcoin.conf
+++ b/bitcoin.conf
@ -1,5 +1,5 @@
-signet=1
+regtest=1
-[signet]
+[regtest]
 daemon=1
 # Custom Signet challenge
--- a/docker-compose.yml
+++ b/docker-compose.yml
@ -1,29 +0,0 @@
 version: '3'
 services:
  bitcoind:
    image: lncm/bitcoind:v26.0
    container_name: easepay-bitcoind
    command: -conf=/bitcoin/.bitcoin/bitcoin.conf
    volumes:
      - ./bitcoin.conf:/bitcoin/.bitcoin/bitcoin.conf
      - bitcoind-data:/bitcoin/.bitcoin
    ports:
      - "18443:18443" # RPC port
      - "48333:38333" # P2P port for Signet
    restart: unless-stopped
  fulcrum:
    image: cculianu/fulcrum:latest # Replace with the desired Fulcrum version
    container_name: easepay-fulcrum
    volumes:
      - fulcrum-data:/data
    ports:
      - "50002:50002" # Electrum server port
    restart: unless-stopped
    depends_on:
      - bitcoind
 volumes:
  bitcoind-data:
  fulcrum-data:
--- a/docker-entrypoint.sh
+++ b/docker-entrypoint.sh
--- a/gen-bitcoind-conf.sh
+++ b/gen-bitcoind-conf.sh
--- a/gen-signet-keys.sh
+++ b/gen-signet-keys.sh
--- a/generate_signet.sh
+++ b/generate_signet.sh
@ -1,25 +0,0 @@
 #!/bin/sh
 # Define container name = should match name in docker-compose
 BICOIND_CONTAINER_NAME="easepay-bitcoind"
 # Start Bitcoind in Regtest mode
 docker exec -it $BITCOIND_CONTAINER_NAME bitcoind -regtest -daemon
 # Wait for Bitcoind to start running
 sleep 5
 # Generate a new address and get the private key and public key
 ADDR=$(docker exec $BITCOIND_CONTAINER bitcoin-cli -regtest getnewaddress)
 PRIVKEY=$(docker exec $BITCOIND_CONTAINER bitcoin-cli -regtest dumpprivkey $ADDR)
 PUBKEY=$(docker exec $BITCOIND_CONTAINER bitcoin-cli -regtest getaddressinfo $ADDR | jq -r '.pubkey')
 # Echo the generated values
 echo "Address: $ADDR"
 echo "Private Key: $PRIVKEY"
 echo "Public Key: $PUBKEY"
 # Optionally, stop the regtest node
 # docker exec $BITCOIND_CONTAINER bitcoin-cli -regtest stop
--- a/install.sh
+++ b/install.sh
--- a/mine-genesis.sh
+++ b/mine-genesis.sh
--- a/mine.sh
+++ b/mine.sh
@ -0,0 +1,19 @@
 #!/bin/bash
 NBITS=${NBITS:-"1e0377ae"} #minimum difficulty in signet
 while true; do
    ADDR=${MINETO:-$(bitcoin-cli getnewaddress)}
    if [[ -f "${BITCOIN_DIR}/BLOCKPRODUCTIONDELAY.txt" ]]; then
        BLOCKPRODUCTIONDELAY_OVERRIDE=$(cat ~/.bitcoin/BLOCKPRODUCTIONDELAY.txt)
        echo "Delay OVERRIDE before next block" $BLOCKPRODUCTIONDELAY_OVERRIDE "seconds."
        sleep $BLOCKPRODUCTIONDELAY_OVERRIDE
    else
        BLOCKPRODUCTIONDELAY=${BLOCKPRODUCTIONDELAY:="0"}
        if [[ BLOCKPRODUCTIONDELAY -gt 0 ]]; then
            echo "Delay before next block" $BLOCKPRODUCTIONDELAY "seconds."
            sleep $BLOCKPRODUCTIONDELAY
        fi
    fi
    echo "Mine To:" $ADDR
    miner --cli="bitcoin-cli" generate --grind-cmd="bitcoin-util grind" --address=$ADDR --nbits=$NBITS --set-block-time=$(date +%s)
 done
--- a/606
+++ b/606
@ -0,0 +1,606 @@
 #!/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.
 # Modified for quick blocks and run in leaner docker container
 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, "miner_imports"))
 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):
    this_interval = 0.000001  
    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()
--- a/rpcauth.py
+++ b/rpcauth.py
@ -0,0 +1,43 @@
 #!/usr/bin/env python3
 # Copyright (c) 2015-2021 The Bitcoin Core developers
 # Distributed under the MIT software license, see the accompanying
 # file COPYING or http://www.opensource.org/licenses/mit-license.php.
 from argparse import ArgumentParser
 from base64 import urlsafe_b64encode
 from getpass import getpass
 from os import urandom
 import hmac
 def generate_salt(size):
    """Create size byte hex salt"""
    return urandom(size).hex()
 def generate_password():
    """Create 32 byte b64 password"""
    return urlsafe_b64encode(urandom(32)).decode('utf-8')
 def password_to_hmac(salt, password):
    m = hmac.new(bytearray(salt, 'utf-8'), bytearray(password, 'utf-8'), 'SHA256')
    return m.hexdigest()
 def main():
    parser = ArgumentParser(description='Create login credentials for a JSON-RPC user')
    parser.add_argument('username', help='the username for authentication')
    parser.add_argument('password', help='leave empty to generate a random password or specify "-" to prompt for password', nargs='?')
    args = parser.parse_args()
    if not args.password:
        args.password = generate_password()
    elif args.password == '-':
        args.password = getpass()
    # Create 16 byte hex salt
    salt = generate_salt(16)
    password_hmac = password_to_hmac(salt, args.password)
    print('{0}:{1}${2}'.format(args.username, salt, password_hmac))
 if __name__ == '__main__':
    main()
--- a/run.sh
+++ b/run.sh
@ -0,0 +1,14 @@
 #!/bin/bash
 # run bitcoind
 bitcoind --daemonwait
 sleep 5
 echo "get magic"
 magic=$(cat /root/.bitcoin/signet/debug.log | grep -m1 magic)  
 magic=${magic:(-8)}
 echo $magic > /root/.bitcoin/MAGIC.txt
 # if in mining mode
 if [[ "$MINERENABLED" == "1" ]]; then
    mine.sh
 fi
--- a/setup-signet.sh
+++ b/setup-signet.sh
@ -0,0 +1,14 @@
 PRIVKEY=${PRIVKEY:-$(cat ~/.bitcoin/PRIVKEY.txt)}
 DATADIR=${DATADIR:-~/.bitcoin/}
 bitcoind -datadir=$DATADIR --daemonwait -persistmempool
 bitcoin-cli -datadir=$DATADIR -named createwallet wallet_name="custom_signet" load_on_startup=true descriptors=false
 #only used in case of mining node
 if [[ "$MINERENABLED" == "1" ]]; then
    bitcoin-cli -datadir=$DATADIR importprivkey $PRIVKEY
    ## for future with descriptor wallets, cannot seem to get it working yet
    # descinfo=$(bitcoin-cli getdescriptorinfo "wpkh(${PRIVKEY})")
    # checksum=$(echo "$descinfo" | jq .checksum | tr -d '"' | tr -d "\n")
    # desc='[{"desc":"wpkh('$PRIVKEY')#'$checksum'","timestamp":0,"internal":false}]'
    # bitcoin-cli -datadir=$DATADIR importdescriptors $desc
 fi
--- a/signet_challenge.sh
+++ b/signet_challenge.sh
@ -1,15 +0,0 @@
 #!/bin/bash
 # Create a new wallet
 WALLET_NAME="custom_signet_wallet"
 bitcoin-cli -signet createwallet "$WALLET_NAME"
 # Generate a new address and retrieve the public key
 ADDRESS=$(bitcoin-cli -signet -rpcwallet="$WALLET_NAME" getnewaddress)
 PUBKEY=$(bitcoin-cli -signet -rpcwallet="$WALLET_NAME" getaddressinfo "$ADDRESS" | jq -r .pubkey)
 # Construct the signetchallenge script
 SIGNETCHALLENGE="5121${PUBKEY}51ae"
 # Output the signetchallenge
 echo "signetchallenge: $SIGNETCHALLENGE"