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/usr/bin/keyart is in signing-party 1.1.10-3.

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#! /usr/bin/python
"""This script takes a key ID, fingerprint, email address, publicly exported
key, or a keyring, and prints the random ASCII art visualization of the key
as per the Drunken Bishop algorithm as applied to OpenSSH keys by Dirk Loss."""

import argparse
import os
import subprocess
import sys

PARSER = argparse.ArgumentParser(
    description='Creates ASCII art from OpenPGP keys.')
PARSER.add_argument('-c', '--color', help='Print the art with ANSI color.',
                    action='store_true')
PARSER.add_argument('-l', '--longid', action='store_true',
                    help='Print the 16-character long ID of a key.')
PARSER.add_argument('-f', '--fingerprint', type=str, metavar=('HEX'),
                    action='append',
                    help='A hexadecimal string representing a fingerprint.')
PARSER.add_argument('-k', '--keyring', type=str, metavar=('KEYRING'),
                    action='append',
                    help='A publicly exported OpenPGP key or keyring.')
PARSER.add_argument('keyid', type=str, nargs='*', metavar=('KEYID'),
                    help='A key identifier (email, ID, fingerprint, etc.).')
ARGS = PARSER.parse_args()

def test_env():
    """Test if and where GPG is installed."""
    try:
        if os.access('/usr/bin/gpg', os.X_OK):
            gnupg = '/usr/bin/gpg'
        else:
            gnupg = '/usr/bin/gpg2'
        return gnupg
    except OSError:
        print("Please install GnuPG before using this script.")
        sys.exit(1)

def draw_art(key_size, key_algo, key_fpr):
    """Execute the Drunken Bishop algorithm on a key."""
    art = ''
    f_bytes = []
    pos = 104
    walk = [pos]
    visits = [0]*209
    temp = ''

    try:
        key_bin = bin(int(key_fpr, 16))[2:].zfill(len(key_fpr)*4)
    except ValueError:
        print("The supplied fingerprint is not a hexadecimal string.")
        sys.exit(3)

    for i, char in enumerate(key_bin):
        temp += char
        if i % 2 == 1:
            f_bytes.append(temp)
            temp = ''

    # create a little-endian bit-pair array
    for i in range(0, len(f_bytes), 4):
        f_bytes[i], f_bytes[i+3] = f_bytes[i+3], f_bytes[i]
        f_bytes[i+1], f_bytes[i+2] = f_bytes[i+2], f_bytes[i+1]

    for pair in f_bytes:
        if (20 <= pos <= 36 or 39 <= pos <= 55 or 58 <= pos <= 74 or
                77 <= pos <= 93 or 96 <= pos <= 112 or 115 <= pos <= 131 or
                134 <= pos <= 150 or 153 <= pos <= 169 or 172 <= pos <= 188):
            if   pair == '00':
                pos -= 20 # Square 'M'
            elif pair == '01':
                pos -= 18
            elif pair == '10':
                pos += 18
            else:
                pos += 20
        elif 1 <= pos <= 17: # Square 'T'
            if pair == '00':
                pos -= 1
            elif pair == '01':
                pos += 1
            elif pair == '10':
                pos += 18
            else:
                pos += 20
        elif 191 <= pos <= 207: # Square 'B'
            if pair == '00':
                pos -= 20
            elif pair == '01':
                pos -= 18
            elif pair == '10':
                pos -= 1
            else:
                pos += 1
        elif pos in [19, 38, 57, 76, 95, 114, 133, 152, 171]: # Square 'L'
            if pair == '00':
                pos -= 19
            elif pair == '01':
                pos -= 18
            elif pair == '10':
                pos += 19
            else:
                pos += 20
        elif pos in [37, 56, 75, 94, 113, 132, 151, 170, 189]: # Square 'R'
            if pair == '00':
                pos -= 20
            elif pair == '01':
                pos -= 19
            elif pair == '10':
                pos += 18
            else:
                pos += 19
        elif pos == 0: # Square 'a'
            if pair == '01':
                pos += 1
            elif pair == '10':
                pos += 19
            elif pair == '11':
                pos += 20
        elif pos == 18: # Square 'b'
            if pair == '00':
                pos -= 1
            elif pair == '10':
                pos += 18
            elif pair == '11':
                pos += 19
        elif pos == 190: # Square 'c'
            if pair == '00':
                pos -= 19
            elif pair == '01':
                pos -= 18
            elif pair == '11':
                pos += 1
        else: # Square 'd'
            if pair == '00':
                pos -= 20
            elif pair == '01':
                pos -= 19
            elif pair == '10':
                pos -= 1
        walk.append(pos)

    for square in walk:
        visits[square] += 1
        if visits[square] > 18:
            visits[square] = 18

    # See https://tools.ietf.org/html/rfc4880#section-9.1
    # Also https://tools.ietf.org/html/rfc6637#section4
    if key_algo == '17':
        key_algo = 'DSA'
    elif key_algo == '1' or key_algo == '2' or key_algo == '3':
        key_algo = 'RSA'
    elif key_algo == '16' or key_algo == '20':
        key_algo = 'Elg'
    elif key_algo == '18':
        key_algo = 'ECDH'
    elif key_algo == '19':
        key_algo = 'ECDSA'
    elif key_algo == '21':
        key_algo = 'X9.42'
    else:
        key_algo = 'N/A'

    if key_size:
        header = "["+key_algo+" "+key_size+"]"
    else:
        header = ''

    if len(header) > 19:
        header = ''
    art += '+' + header.center(19, '-') + '+\n'

    for i, visit in enumerate(visits):
        # Build up the art with the boundaries and newlines
        if i % 19 == 0:
            art += "|{}"
        elif i % 19 == 18:
            art += "{}|\n"
        else:
            art += '{}'

        # Insert the 'coin' into the art at this position
        if i == 104: # Starting position
            art = art.format(_get_coin(visit, ARGS.color, coin='S'))
        elif i == walk[len(walk)-1]: # Ending position
            art = art.format(_get_coin(visit, ARGS.color, coin='E'))
        else:
            art = art.format(_get_coin(visit, ARGS.color))

    if key_size and ARGS.longid:
        footer = "["+key_fpr[-16:]+"]"
    elif key_size:
        footer = "["+key_fpr[-8:]+"]"
    else:
        footer = ''

    art += '+' + footer.center(19, '-') + '+'

    return art

def _get_coin(num_of_hits, ansi_art=False, coin=None):
    """Returns the coin for this humber of hits. If ansi_art is enabled the coin
    will be colorized with ansi codes. If coin is not None, it will use that
    coin instead of the default (used for the 'S' and 'E', start end coins)."""
    coins = [' ', '.', '^', ':', 'l', 'i', '?', '(', 'f', 'x', 'X', 'Z', '#',
             'M', 'W', '&', '8', '%', '@']
    colors = ['', '', '', '', '', '', '', '', '', '', '', '', '', '', '', '',
              '', '', '']
    reset = ''
    if ansi_art:
        colors = [
            '', # no coin
            '\033[38;5;21m', # blue (cold)
            '\033[38;5;39m',
            '\033[38;5;50m',
            '\033[38;5;48m',
            '\033[38;5;46m', # green
            '\033[38;5;118m',
            '\033[38;5;190m',
            '\033[38;5;226m', # yellow
            '\033[38;5;220m',
            '\033[38;5;214m', # orange
            '\033[38;5;208m',
            '\033[38;5;202m',
            '\033[38;5;196m', # red
            '\033[38;5;203m',
            '\033[38;5;210m',
            '\033[38;5;217m', # pink
            '\033[38;5;224m',
            '\033[38;5;231m'  # white (hot)
        ]
        reset = '\033[0m'

    color = colors[num_of_hits]
    if not coin:
        coin = coins[num_of_hits]
    return '{}{}{}'.format(color, coin, reset)

def gpg_cmd(cmd):
    gpg = subprocess.Popen(cmd, stdout=subprocess.PIPE)
    for lines in gpg.communicate()[0].decode('ascii').split('\n'):
        colons = lines.split(':')
        if colons[0] == 'pub':
            size = colons[2]
            algo = colons[3]
        elif colons[0] == 'fpr':
            print(draw_art(size, algo, colons[9]))
            size = None
            algo = None

if __name__ == '__main__':
    gpg_bin = test_env()

    cmd = [gpg_bin, '--no-options', '--with-colons', '--fingerprint']
    if ARGS.fingerprint:
        for fpr in ARGS.fingerprint:
            if len(fpr) % 8 != 0:
                print("Hex string must be a multiple of 8 bytes.")
                sys.exit(2)
            print(draw_art(None, None, fpr))

    if ARGS.keyring:
        cmd.append('--no-default-keyring')
        cmd.extend(['--keyring=%s' % os.path.abspath(keyring)
                    for keyring in ARGS.keyring])
        gpg_cmd(cmd)

    if ARGS.keyid:
        cmd.append('--')
        cmd.extend(ARGS.keyid)
        gpg_cmd(cmd)