mirror of
https://github.com/0glabs/0g-storage-node.git
synced 2024-12-24 23:35:18 +00:00
616 lines
14 KiB
Python
616 lines
14 KiB
Python
import coincurve
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import random
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import rlp
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import sha3 as _sha3
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from eth_utils import decode_hex, int_to_big_endian, big_endian_to_int
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from eth_utils import encode_hex as encode_hex_0x
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from py_ecc.secp256k1 import privtopub, ecdsa_raw_sign, ecdsa_raw_recover
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from rlp.sedes import big_endian_int, BigEndianInt, Binary
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from rlp.utils import ALL_BYTES
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def sha3_256(x):
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return _sha3.keccak_256(x).digest()
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class Memoize:
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def __init__(self, fn):
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self.fn = fn
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self.memo = {}
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def __call__(self, *args):
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if args not in self.memo:
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self.memo[args] = self.fn(*args)
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return self.memo[args]
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TT256 = 2**256
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TT256M1 = 2**256 - 1
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TT255 = 2**255
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SECP256K1P = 2**256 - 4294968273
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def is_numeric(x):
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return isinstance(x, int)
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def is_string(x):
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return isinstance(x, bytes)
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def to_string(value):
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if isinstance(value, bytes):
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return value
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if isinstance(value, str):
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return bytes(value, "utf-8")
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if isinstance(value, int):
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return bytes(str(value), "utf-8")
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def int_to_bytes(value):
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if isinstance(value, bytes):
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return value
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return int_to_big_endian(value)
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def to_string_for_regexp(value):
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return str(to_string(value), "utf-8")
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unicode = str
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def bytearray_to_bytestr(value):
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return bytes(value)
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def encode_int32(v):
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return v.to_bytes(32, byteorder="big")
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def bytes_to_int(value):
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return int.from_bytes(value, byteorder="big")
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def str_to_bytes(value):
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if isinstance(value, bytearray):
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value = bytes(value)
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if isinstance(value, bytes):
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return value
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return bytes(value, "utf-8")
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def ascii_chr(n):
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return ALL_BYTES[n]
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def encode_hex(n):
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if isinstance(n, str):
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return encode_hex(n.encode("ascii"))
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return encode_hex_0x(n)[2:]
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def ecrecover_to_pub(rawhash, v, r, s):
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if coincurve and hasattr(coincurve, "PublicKey"):
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try:
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pk = coincurve.PublicKey.from_signature_and_message(
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zpad(bytearray_to_bytestr(int_to_32bytearray(r)), 32)
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+ zpad(bytearray_to_bytestr(int_to_32bytearray(s)), 32)
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+ ascii_chr(v - 27),
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rawhash,
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hasher=None,
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)
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pub = pk.format(compressed=False)[1:]
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x, y = pk.point()
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except BaseException:
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x, y = 0, 0
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pub = b"\x00" * 64
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else:
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result = ecdsa_raw_recover(rawhash, (v, r, s))
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if result:
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x, y = result
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pub = encode_int32(x) + encode_int32(y)
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else:
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raise ValueError("Invalid VRS")
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assert len(pub) == 64
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return pub, x, y
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def ecsign(rawhash, key):
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if coincurve and hasattr(coincurve, "PrivateKey"):
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pk = coincurve.PrivateKey(key)
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signature = pk.sign_recoverable(rawhash, hasher=None)
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v = safe_ord(signature[64]) + 27
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r = big_endian_to_int(signature[0:32])
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s = big_endian_to_int(signature[32:64])
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else:
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v, r, s = ecdsa_raw_sign(rawhash, key)
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return v, r, s
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def ec_random_keys():
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priv_key = random.randint(0, 2**256).to_bytes(32, "big")
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pub_key = privtopub(priv_key)
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return priv_key, pub_key
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def convert_to_nodeid(signature, challenge):
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r = big_endian_to_int(signature[:32])
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s = big_endian_to_int(signature[32:64])
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v = big_endian_to_int(signature[64:]) + 27
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signed = int_to_bytes(challenge)
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h_signed = sha3_256(signed)
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return ecrecover_to_pub(h_signed, v, r, s)
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def get_nodeid(node):
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challenge = random.randint(0, 2**32 - 1)
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signature = node.getnodeid(list(int_to_bytes(challenge)))
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return convert_to_nodeid(signature, challenge)
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def mk_contract_address(sender, nonce):
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return sha3(rlp.encode([normalize_address(sender), nonce]))[12:]
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def mk_metropolis_contract_address(sender, initcode):
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return sha3(normalize_address(sender) + initcode)[12:]
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def safe_ord(value):
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if isinstance(value, int):
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return value
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else:
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return ord(value)
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# decorator
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def debug(label):
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def deb(f):
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def inner(*args, **kwargs):
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i = random.randrange(1000000)
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print(label, i, "start", args)
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x = f(*args, **kwargs)
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print(label, i, "end", x)
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return x
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return inner
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return deb
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def flatten(li):
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o = []
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for l in li:
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o.extend(l)
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return o
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def bytearray_to_int(arr):
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o = 0
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for a in arr:
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o = (o << 8) + a
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return o
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def int_to_32bytearray(i):
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o = [0] * 32
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for x in range(32):
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o[31 - x] = i & 0xFF
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i >>= 8
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return o
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# sha3_count = [0]
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def sha3(seed):
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return sha3_256(to_string(seed))
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assert (
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encode_hex(sha3(b""))
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== "c5d2460186f7233c927e7db2dcc703c0e500b653ca82273b7bfad8045d85a470"
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)
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assert (
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encode_hex(sha3(b"\x00" * 256))
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== "d397b3b043d87fcd6fad1291ff0bfd16401c274896d8c63a923727f077b8e0b5"
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)
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@Memoize
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def priv_to_addr(k):
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k = normalize_key(k)
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x, y = privtopub(k)
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addr = bytearray(sha3(encode_int32(x) + encode_int32(y))[12:])
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addr[0] &= 0x0F
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addr[0] |= 0x10
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return bytes(addr)
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def priv_to_pub(k):
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k = normalize_key(k)
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x, y = privtopub(k)
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return bytes(encode_int32(x) + encode_int32(y))
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def pub_to_addr(k):
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x = big_endian_to_int(decode_hex(k[2:34]))
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y = big_endian_to_int(decode_hex(k[34:66]))
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addr = sha3(encode_int32(x) + encode_int32(y))[12:]
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addr[0] &= 0x0F
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addr[0] |= 0x10
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return bytes(addr)
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def checksum_encode(addr): # Takes a 20-byte binary address as input
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addr = normalize_address(addr)
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o = ""
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v = big_endian_to_int(sha3(encode_hex(addr)))
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for i, c in enumerate(encode_hex(addr)):
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if c in "0123456789":
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o += c
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else:
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o += c.upper() if (v & (2 ** (255 - 4 * i))) else c.lower()
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return "0x" + o
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def check_checksum(addr):
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return checksum_encode(normalize_address(addr)) == addr
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def normalize_address(x, allow_blank=False):
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if is_numeric(x):
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return int_to_addr(x)
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if allow_blank and x in {"", b""}:
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return b""
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if len(x) in (42, 50) and x[:2] in {"0x", b"0x"}:
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x = x[2:]
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if len(x) in (40, 48):
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x = decode_hex(x)
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if len(x) == 24:
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assert len(x) == 24 and sha3(x[:20])[:4] == x[-4:]
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x = x[:20]
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if len(x) != 20:
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raise Exception("Invalid address format: %r" % x)
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return x
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def normalize_key(key):
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if is_numeric(key):
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o = encode_int32(key)
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elif len(key) == 32:
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o = key
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elif len(key) == 64:
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o = decode_hex(key)
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elif len(key) == 66 and key[:2] == "0x":
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o = decode_hex(key[2:])
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else:
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raise Exception("Invalid key format: %r" % key)
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if o == b"\x00" * 32:
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raise Exception("Zero privkey invalid")
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return o
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def zpad(x, l):
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"""Left zero pad value `x` at least to length `l`.
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>>> zpad('', 1)
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'\x00'
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>>> zpad('\xca\xfe', 4)
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'\x00\x00\xca\xfe'
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>>> zpad('\xff', 1)
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'\xff'
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>>> zpad('\xca\xfe', 2)
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'\xca\xfe'
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"""
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return b"\x00" * max(0, l - len(x)) + x
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def rzpad(value, total_length):
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"""Right zero pad value `x` at least to length `l`.
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>>> zpad('', 1)
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'\x00'
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>>> zpad('\xca\xfe', 4)
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'\xca\xfe\x00\x00'
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>>> zpad('\xff', 1)
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'\xff'
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>>> zpad('\xca\xfe', 2)
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'\xca\xfe'
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"""
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return value + b"\x00" * max(0, total_length - len(value))
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def int_to_addr(x):
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o = [b""] * 20
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for i in range(20):
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o[19 - i] = ascii_chr(x & 0xFF)
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x >>= 8
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return b"".join(o)
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def coerce_addr_to_bin(x):
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if is_numeric(x):
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return encode_hex(zpad(big_endian_int.serialize(x), 20))
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elif len(x) == 40 or len(x) == 0:
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return decode_hex(x)
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else:
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return zpad(x, 20)[-20:]
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def coerce_addr_to_hex(x):
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if is_numeric(x):
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return encode_hex(zpad(big_endian_int.serialize(x), 20))
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elif len(x) == 40 or len(x) == 0:
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return x
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else:
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return encode_hex(zpad(x, 20)[-20:])
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def coerce_to_int(x):
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if is_numeric(x):
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return x
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elif len(x) == 40:
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return big_endian_to_int(decode_hex(x))
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else:
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return big_endian_to_int(x)
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def coerce_to_bytes(x):
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if is_numeric(x):
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return big_endian_int.serialize(x)
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elif len(x) == 40:
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return decode_hex(x)
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else:
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return x
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def parse_int_or_hex(s):
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if is_numeric(s):
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return s
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elif s[:2] in (b"0x", "0x"):
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s = to_string(s)
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tail = (b"0" if len(s) % 2 else b"") + s[2:]
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return big_endian_to_int(decode_hex(tail))
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else:
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return int(s)
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def ceil32(x):
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return x if x % 32 == 0 else x + 32 - (x % 32)
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def to_signed(i):
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return i if i < TT255 else i - TT256
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def sha3rlp(x):
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return sha3(rlp.encode(x))
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# Format encoders/decoders for bin, addr, int
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def decode_bin(v):
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"""decodes a bytearray from serialization"""
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if not is_string(v):
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raise Exception("Value must be binary, not RLP array")
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return v
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def decode_addr(v):
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"""decodes an address from serialization"""
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if len(v) not in [0, 20]:
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raise Exception("Serialized addresses must be empty or 20 bytes long!")
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return encode_hex(v)
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def decode_int(v):
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"""decodes and integer from serialization"""
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if len(v) > 0 and (v[0] == b"\x00" or v[0] == 0):
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raise Exception("No leading zero bytes allowed for integers")
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return big_endian_to_int(v)
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def decode_int256(v):
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return big_endian_to_int(v)
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def encode_bin(v):
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"""encodes a bytearray into serialization"""
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return v
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def encode_root(v):
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"""encodes a trie root into serialization"""
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return v
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def encode_int(v):
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"""encodes an integer into serialization"""
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if not is_numeric(v) or v < 0 or v >= TT256:
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raise Exception("Integer invalid or out of range: %r" % v)
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return int_to_big_endian(v)
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def encode_int256(v):
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return zpad(int_to_big_endian(v), 256)
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def scan_bin(v):
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if v[:2] in ("0x", b"0x"):
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return decode_hex(v[2:])
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else:
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return decode_hex(v)
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def scan_int(v):
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if v[:2] in ("0x", b"0x"):
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return big_endian_to_int(decode_hex(v[2:]))
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else:
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return int(v)
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# Decoding from RLP serialization
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decoders = {
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"bin": decode_bin,
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"addr": decode_addr,
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"int": decode_int,
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"int256b": decode_int256,
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}
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# Encoding to RLP serialization
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encoders = {
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"bin": encode_bin,
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"int": encode_int,
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"trie_root": encode_root,
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"int256b": encode_int256,
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}
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# Encoding to printable format
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printers = {
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"bin": lambda v: "0x" + encode_hex(v),
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"addr": lambda v: v,
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"int": lambda v: to_string(v),
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"trie_root": lambda v: encode_hex(v),
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"int256b": lambda x: encode_hex(zpad(encode_int256(x), 256)),
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}
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# Decoding from printable format
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scanners = {
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"bin": scan_bin,
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"addr": lambda x: x[2:] if x[:2] in (b"0x", "0x") else x,
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"int": scan_int,
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"trie_root": lambda x: scan_bin,
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"int256b": lambda x: big_endian_to_int(decode_hex(x)),
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}
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def int_to_hex(x):
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o = encode_hex(encode_int(x))
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return "0x" + (o[1:] if (len(o) > 0 and o[0] == b"0") else o)
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def remove_0x_head(s):
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return s[2:] if s[:2] in (b"0x", "0x") else s
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def parse_as_bin(s):
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return decode_hex(s[2:] if s[:2] == "0x" else s)
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def parse_as_int(s):
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return s if is_numeric(s) else int("0" + s[2:], 16) if s[:2] == "0x" else int(s)
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def print_func_call(ignore_first_arg=False, max_call_number=100):
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"""utility function to facilitate debug, it will print input args before
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function call, and print return value after function call
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usage:
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@print_func_call
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def some_func_to_be_debu():
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pass
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:param ignore_first_arg: whether print the first arg or not.
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useful when ignore the `self` parameter of an object method call
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"""
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from functools import wraps
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def display(x):
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x = to_string(x)
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try:
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x.decode("ascii")
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except BaseException:
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return "NON_PRINTABLE"
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return x
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local = {"call_number": 0}
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def inner(f):
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@wraps(f)
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def wrapper(*args, **kwargs):
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local["call_number"] += 1
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tmp_args = args[1:] if ignore_first_arg and len(args) else args
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this_call_number = local["call_number"]
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print(
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(
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"{0}#{1} args: {2}, {3}".format(
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f.__name__,
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this_call_number,
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", ".join([display(x) for x in tmp_args]),
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", ".join(
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display(key) + "=" + to_string(value)
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for key, value in kwargs.items()
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),
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)
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)
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)
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res = f(*args, **kwargs)
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print(
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(
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"{0}#{1} return: {2}".format(
|
|
f.__name__, this_call_number, display(res)
|
|
)
|
|
)
|
|
)
|
|
|
|
if local["call_number"] > 100:
|
|
raise Exception("Touch max call number!")
|
|
return res
|
|
|
|
return wrapper
|
|
|
|
return inner
|
|
|
|
|
|
def dump_state(trie):
|
|
res = ""
|
|
for k, v in list(trie.to_dict().items()):
|
|
res += "%r:%r\n" % (encode_hex(k), encode_hex(v))
|
|
return res
|
|
|
|
|
|
class Denoms:
|
|
def __init__(self):
|
|
self.wei = 1
|
|
self.babbage = 10**3
|
|
self.ada = 10**3
|
|
self.kwei = 10**3
|
|
self.lovelace = 10**6
|
|
self.mwei = 10**6
|
|
self.shannon = 10**9
|
|
self.gwei = 10**9
|
|
self.szabo = 10**12
|
|
self.finney = 10**15
|
|
self.mether = 10**15
|
|
self.ether = 10**18
|
|
self.turing = 2**256 - 1
|
|
|
|
|
|
denoms = Denoms()
|
|
|
|
address = Binary.fixed_length(20, allow_empty=True)
|
|
int20 = BigEndianInt(20)
|
|
int32 = BigEndianInt(32)
|
|
int256 = BigEndianInt(256)
|
|
hash32 = Binary.fixed_length(32)
|
|
hash20 = Binary.fixed_length(20)
|
|
trie_root = Binary.fixed_length(32, allow_empty=True)
|
|
|
|
|
|
class bcolors:
|
|
HEADER = "\033[95m"
|
|
OKBLUE = "\033[94m"
|
|
OKGREEN = "\033[92m"
|
|
WARNING = "\033[91m"
|
|
FAIL = "\033[91m"
|
|
ENDC = "\033[0m"
|
|
BOLD = "\033[1m"
|
|
UNDERLINE = "\033[4m"
|