First, what you defining as public key and personal key are literally a bitcoin deal with and a personal key encoded in Pockets Import Format (WIF).
As a way to examine that the WIF and the bitcoin addresses are from the identical key pair, we might want to decode the personal key from its WIF format (checking that the encoding is okay), derive the public key from the personal key, and generate the bitcoin deal with utilizing the public key. If the generated bitcoin deal with matches with the supplied one, then the supplied one and the WIF are created from the identical key pair.
As a way to decode the WIF we’ll comply with the steps from the bitcoin wiki.
Lets see how we will do that in python:
from binascii import hexlify, unhexlify
from ecdsa import SigningKey, SECP256k1
from hashlib import sha256
from bitcoin_tools.pockets import generate_btc_addr, WIF, TESTNET_WIF
def wif_to_sk(wif, community='essential'):
if community not in ['main', 'test']:
# Add extra networks if wanted.
elevate Exception('Bad community')
else:
if community is 'essential':
model = WIF
else:
model = TESTNET_WIF
decoded_wif = b58decode(wif)
c = decoded_wif[-4:]
v = decoded_wif[:1]
# The byte defines the model, assert that's appropriate.
assert v == chr(model)
# The 4 final bytes of the WIF are the 4 first bytes of the checksum, examine that it holds
checksum = sha256(sha256(decoded_wif[:-4]).digest()).digest()
assert checksum[:4] == c
# If the personal key within the WIF corresponds to a compressed public key, you should additionally drop the final byte, that may
# be 01. We are able to examine that by checking the size of the present key. 32 bytes wil imply uncompressed, whereas 33 and
# a number one 01 means compressed.
sk = hexlify(decoded_wif[1:-4])
compressed = False
# Discover that since now we have hexlified the sk, the sizes are doubled.
if len(sk) is 66 and sk[-2:] == '01':
sk = unhexlify(sk[:-2])
compressed = True
else:
sk = unhexlify(sk)
return sk, compressed
# Your supplied knowledge
wif="KwfNqMip1ZdgG2o6wYQUBXv8BqkMQ8VWWeScVU5TLPZp31M5EHeq"
btc_addr="13YcHBzsBX8SxHoBftb69cXJkdXLfAVQos"
community = 'essential'
sk, compressed = wif_to_sk(wif, community=community)
# Derive the general public key from the personal key
pk = SigningKey.from_string(sk, curve=SECP256k1).get_verifying_key()
# Assert that the computed bitcoin deal with and the supplied one matches.
assert generate_btc_addr(pk, v=community, compressed=compressed) == btc_addr
To decode the WIF format there’s a few issues that you could be know. First, the model of the community (usually both mainnet or testnet) after which, if the personal key corresponds to a compressed or uncompressed public key. The model of the community will decide the primary byte of the WIF format, whereas whether or not the associated public key is compressed or uncompressed will decide the final byte earlier than the checksum.
Disclaimer: The supplied code makes use of a perform generate_btc_addr, from a python library I’ve developed, that computes a bitcoin deal with from a given public key. Such perform name a bunch of different easy capabilities to derive the bitcoin deal with, however together with all on the reply will make it even longer that what it’s. You may both get the library from GitHub, or get the capabilities from the particular file.