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hashcat/tools/test_modules/m07401.pm

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#!/usr/bin/env perl
##
## Author......: See docs/credits.txt
## License.....: MIT
##
use strict;
use warnings;
use Digest::SHA qw (sha256);
sub module_constraints { [[0, 256], [20, 20], [0, 15], [20, 20], [-1, -1]] }
my $ITERATION_MULTIPLIER = 1000;
sub module_generate_hash
{
my $word = shift;
my $salt = shift;
my $cost = shift // 5; # => cost * $ITERATION_MULTIPLIER
my $lower = shift // 0;
my $dgst = sha_crypts (\&sha256, 256, $word, $salt, $cost * $ITERATION_MULTIPLIER);
my $salt_hex = unpack ("H*", $salt);
my $dgst_hex = unpack ("H*", $dgst);
# default for MySQL is upper-case hexadecimals:
if ($lower == 0)
{
$salt_hex = uc ($salt_hex);
$dgst_hex = uc ($dgst_hex);
}
my $hash = sprintf ("\$mysql\$A\$%03i*%s*%s",
$cost,
$salt_hex,
$dgst_hex);
return $hash;
}
sub module_verify_hash
{
my $line = shift;
my $idx = index ($line, ':');
return unless ($idx >= 0);
my $hash = substr ($line, 0, $idx);
my $word = substr ($line, $idx + 1);
return unless defined $hash;
return unless defined $word;
return unless (substr ($hash, 0, 9) eq '$mysql$A$');
$idx = index ($hash, '*');
return unless ($idx == 12);
# iter:
my $cost_factor = substr ($hash, 9, 3);
$cost_factor = int ($cost_factor);
return unless ($cost_factor > 0);
# salt:
$idx = index ($hash, '*', 13);
return unless ($idx == 53);
my $salt = substr ($hash, 13, 40);
$salt = pack ("H*", $salt);
# check for lower/upper case:
my $digest = substr ($hash, 54);
my $is_lower = 0;
$is_lower = 1 if (uc ($digest) ne $digest);
# verify:
$word = pack_if_HEX_notation ($word);
my $new_hash = module_generate_hash ($word, $salt, $cost_factor, $is_lower);
return ($new_hash, $word);
}
# This is a modified sha_crypts () function of pass_gen.pl from
# https://github.com/magnumripper/JohnTheRipper/blob/bleeding-jumbo/run/pass_gen.pl
# Copyright: https://github.com/magnumripper/JohnTheRipper/blob/bleeding-jumbo/doc/pass_gen.Manifest
# public domain
# written by Jim Fougeron
# updated for new MySQL hashes by philsmd
# modified date: February 2020
# license: public domain
my @i64 = ('.', '/', '0'..'9', 'A'..'Z', 'a'..'z');
sub to64
{
my $v = shift;
my $n = shift;
my $str;
while (--$n >= 0)
{
$str .= $i64[$v & 0x3F];
$v >>= 6;
}
return $str;
}
sub sha_crypts
{
my ($func, $bits, $key, $salt, $loops) = @_;
my $bytes = $bits / 8;
my $b = $func->($key . $salt . $key);
# Add for any character in the key one byte of the alternate sum.
my $tmp = $key . $salt;
for (my $i = length ($key); $i > 0; $i -= $bytes)
{
if ($i > $bytes)
{
$tmp .= $b;
}
else
{
$tmp .= substr ($b, 0, $i);
}
}
# Take the binary representation of the length of the key and for every 1 add the alternate sum, for every 0 the key.
for (my $i = length ($key); $i > 0; $i >>= 1)
{
if (($i & 1) != 0)
{
$tmp .= $b;
}
else
{
$tmp .= $key;
}
}
my $a = $func->($tmp);
# NOTE, this will be the 'initial' $c value in the inner loop.
# For every character in the password add the entire password. produces DP
$tmp = "";
for (my $i = 0; $i < length ($key); $i++)
{
$tmp .= $key;
}
my $dp = $func->($tmp);
# Create byte sequence P
my $p = "";
for (my $i = length ($key); $i > 0; $i -= $bytes)
{
if ($i > $bytes)
{
$p .= $dp;
}
else
{
$p .= substr ($dp, 0, $i);
}
}
# produce ds
$tmp = "";
my $til = 16 + ord (substr ($a, 0, 1));
for (my $i = 0; $i < $til; $i++)
{
$tmp .= $salt;
}
my $ds = $func->($tmp);
# Create byte sequence S
my $s = "";
for (my $i = length ($salt); $i > 0; $i -= $bytes)
{
if ($i > $bytes)
{
$s .= $ds;
}
else
{
$s .= substr ($ds, 0, $i);
}
}
my $c = $a; # Ok, we saved this, which will 'seed' our crypt value here in the loop.
# now we do 5000 iterations of SHA2 (256 or 512)
for (my $i = 0; $i < $loops; $i++)
{
if ($i & 1) { $tmp = $p; }
else { $tmp = $c; }
if ($i % 3) { $tmp .= $s; }
if ($i % 7) { $tmp .= $p; }
if ($i & 1) { $tmp .= $c; }
else { $tmp .= $p; }
$c = $func->($tmp);
}
my $inc1; my $inc2; my $mod; my $end;
if ($bits == 256) { $inc1 = 10; $inc2 = 21; $mod = 30; $end = 0; }
else { $inc1 = 21; $inc2 = 22; $mod = 63; $end = 21; }
my $i = 0;
$tmp = "";
do
{
$tmp .= to64 ((ord (substr ($c, $i, 1)) << 16) | (ord (substr ($c, ($i + $inc1) % $mod, 1)) << 8) | ord (substr ($c, ($i + $inc1 * 2) % $mod, 1)), 4);
$i = ($i + $inc2) % $mod;
} while ($i != $end);
if ($bits == 256) { $tmp .= to64 ((ord (substr ($c, 31, 1)) << 8) | ord (substr ($c, 30, 1)), 3); }
else { $tmp .= to64 (ord (substr ($c, 63, 1)), 2); }
return $tmp;
}
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