コード例 #1
0
ファイル: fincrypt.py プロジェクト: Fiona1729/FinCrypt
def decrypt_message(k, encrypted_key, encrypted_message):
    """
    Decrypts a message encrypted by the encrypt_message function
    First decrypts the AES key and IV using ECC
    Then decrypts the data using the AES key and IV

    :param k: Private key k
    :param encrypted_key: ECC encrypted key (list of of ints)
    :param encrypted_message: AES encrypted data (bytes
    :return: Decrypted data (bytes)
    """

    ecies = ecc.ECEIS(ecc.CURVE)

    r = ecc.AffineCurvePoint(encrypted_key[0], encrypted_key[1], ecc.CURVE)

    s = ecies.recover(r, ecc.ECPrivateKey(k, ecc.CURVE))

    s = str(s).encode('utf-8')

    key = sha.SHA3_512(s).digest()

    message_decryptor = Decrypter(
        mode=AESModeOfOperationCBC(key[:32], iv=key[32:48]))

    decrypted_message = message_decryptor.feed(encrypted_message)
    decrypted_message += message_decryptor.feed()

    return oaep.oaep_unpad(decrypted_message)
コード例 #2
0
ファイル: fincrypt.py プロジェクト: Fiona1729/FinCrypt
def sign_message(k, message):
    """
    Signs a message using an ECDSA signature private key and a message,

    Computes SHA512 hash of plaintext and then performs ECDSA signature upon it

    :param k: ECC key k
    :param message: Message to sign (bytes)
    :return: Signature (list of ints)
    """

    message_hash = sha.SHA3_512(message).digest()

    block = get_blocks(message_hash, 1024)

    return sign_number(k, block[0])
コード例 #3
0
ファイル: fincrypt.py プロジェクト: Fiona1729/FinCrypt
def authenticate_message(kx, ky, plaintext, signature):
    """
    Authenticates a message when given a plaintext and signature

    Verifies hash with ECDSA public key

    :param kx: ECC Public key kx
    :param ky: ECC Public key ky
    :param plaintext: Decrypted plaintext to verify (bytes)
    :param signature: The signature (list of ints)
    :return: Whether the message signature is valid (boolean)
    """

    message_hash = sha.SHA3_512(plaintext).digest()

    block = get_blocks(message_hash, 1024)

    return validate_number(kx, ky, signature[0], signature[1], block[0])
コード例 #4
0
ファイル: fincrypt.py プロジェクト: Fiona1729/FinCrypt
def enum_keys(arguments):
    """
    Enumerates all keys residing in the public_keys directory.
    Prints to stdout a formatted explanation of the key, with:
    Filename
    User Name
    Email
    Hash
    Randomart

    :param arguments: Argparser arguments object
    :return: None
    """

    key_enum = ''
    for key_file in os.listdir(PUBLIC_PATH):
        with open(os.path.join(PUBLIC_PATH, key_file)) as f:
            key_text = f.read()

        key = read_public_key(key_text)

        key_hash = sha.SHA3_512(key_text.encode('utf-8')).hexdigest()

        key_hash_formatted = ':'.join([
            key_hash[:64][i:i + 2] for i in range(0, len(key_hash[:64]), 2)
        ]).upper()

        # Only use the first 64 characters of the hash so it fills up less of the board.
        key_randomart = randomart.RandomArt(hashalg='FinCrypt',
                                            room_size=(31, 15))

        key_randomart = key_randomart(key_hash)

        formatted_key = f"{key_file}:\nName: {key['name'].decode('utf-8')}\nEmail: {key['email'].decode('utf-8')}" \
                        f"\nHash: {key_hash_formatted}\nKeyArt:\n{key_randomart}"

        key_enum += formatted_key + '\n\n'

    sys.stdout.write(key_enum.strip())
コード例 #5
0
ファイル: fincrypt.py プロジェクト: Fiona1729/FinCrypt
def encrypt_message(kx, ky, message):
    """
    Encrypts a message using ECC and AES-256
    First generates a random AES key and IV with os.urandom()
    Then encrypts the original message with that key
    Then encrypts the AES key with the ECC key

    NOTE:
    This means that plaintext will not have the same ciphertext
    when encrypted twice. Keep this in mind if you require reproducibility behavior

    :param kx: Public key kx (int)
    :param ky: Public key ky (int)
    :param message: Message (bytes)
    :return: Tuple (encrypted key (list of ints), encrypted IV (list of ints),
    and encrypted message (bytes))
    """

    ecies = ecc.ECEIS(ecc.CURVE)

    r, s = ecies.exchange(
        ecc.ECPublicKey(ecc.AffineCurvePoint(kx, ky, ecc.CURVE)))

    s = str(s).encode('utf-8')

    key = sha.SHA3_512(s).digest()

    message_encryptor = Encrypter(
        mode=AESModeOfOperationCBC(key[:32], iv=key[32:48]))

    encrypted_blocks = message_encryptor.feed(oaep.oaep_pad(message))

    encrypted_blocks += message_encryptor.feed()

    encrypted_key = r.x, r.y

    return encrypted_key, encrypted_blocks