mirror of
https://github.com/hashcat/hashcat.git
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418 lines
9.6 KiB
Perl
418 lines
9.6 KiB
Perl
#!/usr/bin/env perl
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##
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## Author......: See docs/credits.txt
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## License.....: MIT
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##
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use strict;
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use warnings;
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use Crypt::ECB qw (encrypt);
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use Digest::MD4 qw (md4);
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use Digest::SHA qw (sha1 hmac_sha1);
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use Encode;
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sub module_constraints { [[0, 256], [-1, -1], [-1, -1], [-1, -1], [-1, -1]] }
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sub get_random_dpapimk_salt
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{
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my $version = shift;
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my $salt_buf = "";
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my $context = random_number (1, 2);
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my $cipher_algo = "";
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my $hash_algo = "";
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my $iterations;
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my $SID = sprintf ('S-15-21-%d-%d-%d-%d',
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random_number (400000000,490000000),
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random_number (400000000,490000000),
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random_number (400000000,490000000),
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random_number (1000,1999));
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my $cipher_len = 0;
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if ($version == 1)
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{
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$iterations = random_number (4000, 24000);
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$cipher_algo = "des3";
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$hash_algo = "sha1";
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$cipher_len = 208;
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}
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elsif ($version == 2)
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{
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$iterations = random_number (8000, 17000);
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$cipher_algo = "aes256";
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$hash_algo = "sha512";
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$cipher_len = 288;
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}
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my $iv = random_bytes (16);
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$iv = unpack ("H*", $iv);
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$salt_buf = $version . '*' .
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$context . '*' .
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$SID . '*' .
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$cipher_algo . '*' .
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$hash_algo . '*' .
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$iterations . '*' .
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$iv . '*' .
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$cipher_len . '*';
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return $salt_buf;
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}
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# Thanks to Jochen Hoenicke <hoenicke@gmail.com>
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# (one of the authors of Palm Keyring)
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# for these next two subs.
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sub dpapi_pbkdf2
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{
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my ($password, $salt, $iter, $keylen, $prf) = @_;
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my ($k, $t, $u, $ui, $i);
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$t = "";
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for ($k = 1; length ($t) < $keylen; $k++)
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{
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$u = $ui = &$prf ($salt . pack ('N', $k), $password);
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for ($i = 1; $i < $iter; $i++)
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{
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# modification to fit Microsoft
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# weird pbkdf2 implementation...
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$ui = &$prf ($u, $password);
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$u ^= $ui;
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}
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$t .= $u;
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}
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return substr ($t, 0, $keylen);
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}
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sub module_generate_hash
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{
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my $word_buf = shift;
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my $salt_buf = shift;
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my $dpapimk_salt = shift // get_random_dpapimk_salt (1);
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my $cipher = shift;
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my @salt_arr = split ('\*', $dpapimk_salt);
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my $version = $salt_arr[0];
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my $context = $salt_arr[1];
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my $SID = $salt_arr[2];
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my $cipher_algorithm = $salt_arr[3];
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my $hash_algorithm = $salt_arr[4];
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my $iterations = $salt_arr[5];
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my $salt = pack ("H*", $salt_arr[6]);
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my $cipher_len = $salt_arr[7];
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# intermediate values
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my $user_hash;
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my $user_derivationKey;
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my $encKey;
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my $expected_hmac;
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my $cleartext;
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if ($context == 1)
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{
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$user_hash = sha1 (encode ("UTF-16LE", $word_buf));
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}
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elsif ($context == 2)
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{
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$user_hash = md4 (encode ("UTF-16LE", $word_buf));
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}
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$user_derivationKey = hmac_sha1 (encode ("UTF-16LE", $SID . "\x00"), $user_hash);
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my $hmacSalt = random_bytes (16);
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my $last_key = random_bytes (64);
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if ($version == 1)
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{
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$encKey = hmac_sha1 ($hmacSalt, $user_derivationKey);
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$expected_hmac = hmac_sha1 ($last_key, $encKey);
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# need padding because keyLen is 24 and hashLen 20
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$expected_hmac = $expected_hmac . random_bytes (4);
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}
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elsif ($version == 2)
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{
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$encKey = hmac_sha512 ($hmacSalt, $user_derivationKey);
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$expected_hmac = hmac_sha512 ($last_key, $encKey);
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}
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$cleartext = $hmacSalt . $expected_hmac . $last_key;
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my $derived_key;
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my $key;
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my $iv;
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my $pbkdf2;
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if ($version == 1)
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{
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$derived_key = dpapi_pbkdf2 ($user_derivationKey, $salt, $iterations, 32, \&hmac_sha1);
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}
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elsif ($version == 2)
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{
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$derived_key = dpapi_pbkdf2 ($user_derivationKey, $salt, $iterations, 48, \&hmac_sha512);
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}
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if (defined $cipher)
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{
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$cipher = pack ("H*", $cipher);
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my $computed_hmac = "";
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if ($version == 1)
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{
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$key = substr ($derived_key, 0, 24);
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$iv = substr ($derived_key, 24, 8);
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my $p1 = Crypt::ECB->new ({
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key => substr ($key, 0, 8),
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cipher => "DES",
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literal_key => 1,
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header => "none",
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keysize => 8,
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padding => "null",
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});
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my $p2 = Crypt::ECB->new ({
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key => substr ($key, 8, 8),
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cipher => "DES",
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literal_key => 1,
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header => "none",
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keysize => 8,
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padding => "null",
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});
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my $p3 = Crypt::ECB->new ({
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key => substr ($key, 16, 8),
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cipher => "DES",
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literal_key => 1,
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header => "none",
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keysize => 8,
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padding => "null",
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});
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# let's compute a 3DES-EDE-CBC decryption
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my $out1;
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my $out2;
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my $out3;
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my $expected_cleartext = "";
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# size of cipherlen is 104 bytes
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for (my $k = 0; $k < 13; $k++)
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{
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$out1 = $p3->decrypt (substr ($cipher, $k * 8, 8));
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$out2 = $p2->encrypt ($out1);
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$out3 = $p1->decrypt ($out2);
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$expected_cleartext .= substr ($out3, 0, 8) ^ $iv;
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$iv = substr ($cipher, $k * 8, 8);
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}
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$last_key = substr ($expected_cleartext, length ($expected_cleartext) - 64, 64);
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$hmacSalt = substr ($expected_cleartext, 0, 16);
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$expected_hmac = substr ($expected_cleartext, 16, 20);
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$encKey = hmac_sha1 ($hmacSalt, $user_derivationKey);
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$computed_hmac = hmac_sha1 ($last_key, $encKey);
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$cleartext = $expected_cleartext;
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if (unpack ("H*", $expected_hmac) ne unpack ("H*", $computed_hmac))
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{
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$cleartext = "0" x 104;
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}
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}
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elsif ($version == 2)
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{
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$key = substr ($derived_key, 0, 32);
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$iv = substr ($derived_key, 32, 16);
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my $aes = Crypt::CBC->new ({
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key => $key,
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cipher => "Crypt::Rijndael",
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iv => $iv,
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literal_key => 1,
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header => "none",
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keysize => 32,
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padding => "null",
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});
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my $expected_cleartext = $aes->decrypt ($cipher);
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$last_key = substr ($expected_cleartext, length ($expected_cleartext) - 64, 64);
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$hmacSalt = substr ($expected_cleartext, 0, 16);
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$expected_hmac = substr ($expected_cleartext, 16, 64);
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$encKey = hmac_sha512 ($hmacSalt, $user_derivationKey);
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$computed_hmac = hmac_sha512 ($last_key, $encKey);
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$cleartext = $expected_cleartext;
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if (unpack ("H*", $expected_hmac) ne unpack ("H*", $computed_hmac))
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{
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$cleartext = "0" x 144;
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}
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}
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}
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if ($version == 1)
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{
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$key = substr ($derived_key, 0, 24);
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$iv = substr ($derived_key, 24, 8);
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my $p1 = Crypt::ECB->new ({
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key => substr ($key, 0, 8),
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cipher => "DES",
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literal_key => 1,
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header => "none",
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keysize => 8,
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padding => "null",
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});
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my $p2 = Crypt::ECB->new ({
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key => substr ($key, 8, 8),
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cipher => "DES",
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literal_key => 1,
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header => "none",
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keysize => 8,
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padding => "null",
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});
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my $p3 = Crypt::ECB->new ({
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key => substr ($key, 16, 8),
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cipher => "DES",
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literal_key => 1,
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header => "none",
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keysize => 8,
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padding => "null",
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});
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# let's compute a 3DES-EDE-CBC encryption
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# compute first block
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my $out1 = $p1->encrypt (substr ($cleartext, 0, 8) ^ $iv);
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my $out2 = $p2->decrypt ($out1);
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my $out3 = $p3->encrypt ($out2);
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$cipher = substr ($out3, 0, 8);
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# size of cipherlen is 104 bytes
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for (my $k = 1; $k < 13; $k++)
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{
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$iv = $out3;
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$out1 = $p1->encrypt (substr ($cleartext, $k * 8, 8) ^ $iv);
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$out2 = $p2->decrypt ($out1);
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$out3 = $p3->encrypt ($out2);
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$cipher .= substr ($out3, 0, 8);
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}
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}
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else
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{
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$key = substr ($derived_key, 0, 32);
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$iv = substr ($derived_key, 32, 16);
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my $aes = Crypt::CBC->new ({
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key => $key,
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cipher => "Crypt::Rijndael",
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iv => $iv,
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literal_key => 1,
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header => "none",
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keysize => 32,
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padding => "null",
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});
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$cipher = $aes->encrypt ($cleartext);
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}
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my $tmp_hash = sprintf ('$DPAPImk$%d*%d*%s*%s*%s*%d*%s*%d*%s',
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$version,
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$context,
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$SID,
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$cipher_algorithm,
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$hash_algorithm,
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$iterations,
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unpack ("H*", $salt),
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$cipher_len,
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unpack ("H*", $cipher));
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return $tmp_hash;
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}
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sub module_verify_hash
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{
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my $line = shift;
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my ($hash, $word) = split (':', $line);
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return unless defined $hash;
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return unless defined $word;
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my @tmp_data = split ('\$', $hash);
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my $signature = $tmp_data[1];
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next unless ($signature eq 'DPAPImk');
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my @data = split ('\*', $tmp_data[2]);
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next unless (scalar @data == 9);
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my $version = shift @data;
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next unless ($version == 1 || $version == 2);
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my $context = shift @data;
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my $SID = shift @data;
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my $cipher_algorithm = shift @data;
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my $hash_algorithm = shift @data;
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my $iteration = shift @data;
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my $iv = shift @data;
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my $cipher_len = shift @data;
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my $cipher = shift @data;
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next unless (length ($cipher) == $cipher_len);
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if ($version == 1)
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{
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next unless ($cipher_len == 208);
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}
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elsif ($version == 2)
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{
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next unless ($cipher_len == 288);
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}
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my $dpapimk_salt = substr ($hash, length ('$DPAPImk$'));
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my $word_packed = pack_if_HEX_notation ($word);
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my $new_hash = module_generate_hash ($word_packed, undef, $dpapimk_salt, $cipher);
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return ($new_hash, $word);
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}
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1;
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