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hashcat/tools/test_modules/m19800.pm
2021-06-21 07:47:22 -08:00

206 lines
5.5 KiB
Perl

#!/usr/bin/env perl
##
## Author......: See docs/credits.txt
## License.....: MIT
##
use strict;
use warnings;
use Digest::SHA qw (hmac_sha1);
use Crypt::Mode::CBC;
use Crypt::PBKDF2;
use Encode;
use POSIX qw (strftime);
sub byte2hex
{
my $input = shift;
return unpack ("H*", $input);
}
sub hex2byte
{
my $input = shift;
return pack ("H*", $input);
}
sub pad
{
my $n = shift;
my $size = shift;
return (~$n + 1) & ($size - 1);
}
sub module_constraints { [[0, 256], [16, 16], [-1, -1], [-1, -1], [-1, -1]] }
sub module_generate_hash
{
my $word = shift;
my $salt = shift;
my $user = shift // "user";
my $realm = shift // "realm";
my $checksum = shift;
my $enc_timestamp = shift;
my $mysalt = uc $realm;
$mysalt = $mysalt . $user;
# first we generate the 'seed'
my $iter = 4096;
my $pbkdf2 = Crypt::PBKDF2->new
(
hash_class => 'HMACSHA1',
iterations => $iter,
output_len => 16
);
my $b_seed = $pbkdf2->PBKDF2 ($mysalt, $word);
# we can precompute this
my $b_kerberos_nfolded = hex2byte ('6b65726265726f737b9b5b2b93132b93');
my $b_iv = hex2byte ('0' x 32);
# 'key_bytes' will be the AES key used to generate 'ki' (for final hmac-sha1)
# and 'ke' (AES key to decrypt/encrypt the ticket)
my $cbc = Crypt::Mode::CBC->new ('AES', 0);
my $b_key_bytes = $cbc->encrypt ($b_kerberos_nfolded, $b_seed, $b_iv);
# precomputed stuff
# nfold 0x0000000155 to 16 bytes
my $b_nfolded1 = hex2byte ('5b582c160a5aa80556ab55aad5402ab5');
# nfold 0x00000001aa to 16 bytes
my $b_nfolded2 = hex2byte ('ae2c160b04ad5006ab55aad56a80355a');
my $b_ki = $cbc->encrypt ($b_nfolded1, $b_key_bytes, $b_iv);
my $b_ke = $cbc->encrypt ($b_nfolded2, $b_key_bytes, $b_iv);
my $cleartext_ticket = '';
my $check_correct = 0;
if (defined $enc_timestamp)
{
# Do CTS Decryption https://en.wikipedia.org/wiki/Ciphertext_stealing
# Decrypt n-1 block
my $len_last_block = length ($enc_timestamp) % 32;
my $len_last_2_blocks = $len_last_block + 32;
my $b_n_1_block = hex2byte (substr ($enc_timestamp, -$len_last_2_blocks, 32));
my $b_n_1_decrypted = $cbc->decrypt ($b_n_1_block, $b_ke, $b_iv);
# Pad the last block with last bytes from the decrypted n-1
my $b_padded_enc_ticket = hex2byte ($enc_timestamp) . (substr $b_n_1_decrypted, -(16 - $len_last_block / 2));
# Swap the last two blocks
my $b_cbc_enc_ticket = (substr $b_padded_enc_ticket, 0, -32) . (substr $b_padded_enc_ticket, -16, 16).
(substr $b_padded_enc_ticket, -32, 16);
# Decrypt and truncate
my $b_dec_ticket_padded = $cbc->decrypt ($b_cbc_enc_ticket, $b_ke, $b_iv);
my $b_cleartext_ticket = substr $b_dec_ticket_padded, 0, length ($enc_timestamp) / 2;
$cleartext_ticket = byte2hex ($b_cleartext_ticket);
my $check_correct = ((substr ($b_cleartext_ticket, 22, 2) eq "20") &&
(substr ($b_cleartext_ticket, 36, 1) eq "Z"));
if ($check_correct == 1 && defined $checksum)
{
my $b_checksum = hmac_sha1 (hex2byte ($cleartext_ticket), $b_ki);
$check_correct = ($checksum eq byte2hex (substr $b_checksum, 0, 12));
}
}
if ($check_correct != 1)
{
# fake/wrong ticket (otherwise if we just decrypt/encrypt we end
#up with false positives all the time)
$cleartext_ticket = '68c8459f3f10c851b8827118bb459c6e301aa011180f323031'.
'32313131363134323835355aa10502030c28a2';
# we have what is required to compute checksum
$checksum = hmac_sha1 (hex2byte ($cleartext_ticket), $b_ki);
$checksum = byte2hex (substr $checksum, 0, 12);
}
# CTS Encrypt our new block
my $len_cleartext_last_block = length ($cleartext_ticket) % 32;
my $cleartext_last_block = substr $cleartext_ticket, -$len_cleartext_last_block;
my $padding = pad (length ($cleartext_ticket), 32);
my $b_cleartext_last_block_padded = hex2byte ($cleartext_last_block . '0' x $padding);
# we will encrypt until n-1 block (included)
my $truncated_cleartext_ticket = substr $cleartext_ticket, 0, -$len_cleartext_last_block;
my $b_truncated_enc_ticket = $cbc->encrypt (hex2byte ($truncated_cleartext_ticket), $b_ke, $b_iv);
my $b_enc_ticket_n_1_block= substr $b_truncated_enc_ticket, -16;
my $b_enc_last_block = substr $b_enc_ticket_n_1_block, 0, $len_cleartext_last_block / 2;
# we now craft the new n-1 block
my $tmp = $b_enc_ticket_n_1_block ^ $b_cleartext_last_block_padded;
$b_enc_ticket_n_1_block = $cbc->encrypt ($tmp, $b_ke, $b_iv);
$tmp = substr $b_truncated_enc_ticket, 0, -16;
$enc_timestamp = $tmp . $b_enc_ticket_n_1_block . $b_enc_last_block;
my $tmp_hash = sprintf ('$krb5pa$17$%s$%s$%s%s', $user, $realm, unpack ("H*", $enc_timestamp), $checksum);
return $tmp_hash;
}
sub module_verify_hash
{
my $line = shift;
my ($hash, $word) = split (':', $line);
return unless defined $hash;
return unless defined $word;
my @data = split ('\$', $hash);
return unless scalar @data == 6;
shift @data;
my $signature = shift @data;
my $algorithm = shift @data;
my $user = shift @data;
my $realm = shift @data;
my $edata = shift @data;
return unless ($signature eq "krb5pa");
return unless ($algorithm eq "17");
return unless (length ($edata) >= 88);
return unless (length ($edata) <= 112);
my $checksum = substr $edata, -24;
my $enc_timestamp = substr $edata, 0, -24;
my $word_packed = pack_if_HEX_notation ($word);
my $new_hash = module_generate_hash ($word_packed, undef, $user, $realm, $checksum, $enc_timestamp);
return ($new_hash, $word);
}
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