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https://github.com/hashcat/hashcat.git
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285 lines
6.4 KiB
Perl
285 lines
6.4 KiB
Perl
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#!/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::PBKDF2;
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use Crypt::OpenSSL::EC;
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use Crypt::OpenSSL::Bignum::CTX;
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use Digest::SHA qw (sha256 sha512);
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use Digest::HMAC qw (hmac_hex);
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use Crypt::CBC;
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use Compress::Zlib;
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sub module_constraints { [[0, 256], [-1, -1], [-1, -1], [-1, -1], [-1, -1]] }
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my $MAX_DATA_LEN = 16384;
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# helper function: key derivation from password and one point on the curve (public key)
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sub generate_key
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{
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my $word = shift;
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my $ephemeral_pubkey = shift;
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my $pbkdf2 = Crypt::PBKDF2->new
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(
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hasher => Crypt::PBKDF2->hasher_from_algorithm ('HMACSHA2', 512),
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iterations => 1024,
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output_len => 64
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);
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my $private_key = $pbkdf2->PBKDF2 ("", $word);
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my $method = Crypt::OpenSSL::EC::EC_GFp_simple_method (); # or Crypt::OpenSSL::EC::EC_GFp_mont_method ()
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my $group = Crypt::OpenSSL::EC::EC_GROUP::new ($method);
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# secp256k1 elliptic curve parameters
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my $p = Crypt::OpenSSL::Bignum->new_from_hex ("fffffffffffffffffffffffffffffffffffffffffffffffffffffffefffffc2f");
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my $a = Crypt::OpenSSL::Bignum->new_from_hex ("0000000000000000000000000000000000000000000000000000000000000000");
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my $b = Crypt::OpenSSL::Bignum->new_from_hex ("0000000000000000000000000000000000000000000000000000000000000007");
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my $ctx = Crypt::OpenSSL::Bignum::CTX->new ();
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Crypt::OpenSSL::EC::EC_GROUP::set_curve_GFp ($group, $p, $a, $b, $ctx);
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my $Gx = Crypt::OpenSSL::Bignum->new_from_hex ("79be667ef9dcbbac55a06295ce870b07029bfcdb2dce28d959f2815b16f81798");
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my $Gy = Crypt::OpenSSL::Bignum->new_from_hex ("483ada7726a3c4655da4fbfc0e1108a8fd17b448a68554199c47d08ffb10d4b8");
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my $G = Crypt::OpenSSL::EC::EC_POINT::new ($group);
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Crypt::OpenSSL::EC::EC_POINT::set_affine_coordinates_GFp ($group, $G, $Gx, $Gy, $ctx);
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my $order = Crypt::OpenSSL::Bignum->new_from_hex ("fffffffffffffffffffffffffffffffebaaedce6af48a03bbfd25e8cd0364141");
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my $cofactor = Crypt::OpenSSL::Bignum->new_from_hex ("0000000000000000000000000000000000000000000000000000000000000001");
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Crypt::OpenSSL::EC::EC_GROUP::set_generator ($group, $G, $order, $cofactor); # or cofactor = Crypt::OpenSSL::Bignum->one ()
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# scalar
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# hash mod GROUP_ORDER
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my $m = Crypt::OpenSSL::Bignum->new_from_hex (unpack ("H*", $private_key));
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# point (public key, ephemeral_pubkey)
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my $Q = Crypt::OpenSSL::EC::EC_POINT::new ($group);
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my $ret = Crypt::OpenSSL::EC::EC_POINT::oct2point ($group, $Q, $ephemeral_pubkey, $ctx);
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if ($ret == 0)
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{
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return;
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}
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# multiply
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my $result = Crypt::OpenSSL::EC::EC_POINT::new ($group);
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my $n = Crypt::OpenSSL::Bignum->zero ();
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Crypt::OpenSSL::EC::EC_POINT::mul ($group, $result, $n, $Q, $m, $ctx);
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# get compressed public/shared key format
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my $public_key = Crypt::OpenSSL::EC::EC_POINT::point2oct ($group, $result, &Crypt::OpenSSL::EC::POINT_CONVERSION_COMPRESSED, $ctx);
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# hash the compressed public key with sha512 ()
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return sha512 ($public_key);
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}
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sub module_generate_hash
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{
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my $word = shift;
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my $ephemeral_pubkey = "";
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my $key = "";
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my $valid_point = 0;
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while ($valid_point == 0)
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{
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my $sign_of_curve_point = int (rand (2)); # 2 possibilities: 02... or 03... ephemeral public keys
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$ephemeral_pubkey = pack ("H*", "0" . ($sign_of_curve_point + 2) . random_hex_string (64));
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$key = generate_key ($word, $ephemeral_pubkey);
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if (defined ($key))
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{
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$valid_point = 1;
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}
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}
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my $valid_compression_rate = 0;
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my $compressed_data = "";
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while ($valid_compression_rate == 0)
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{
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my $data_buf = "{\r\n \"";
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if (int (rand (2)) == 1) # alternative with different line break
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{
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$data_buf = "{\n \"";
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}
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# we assume a compression rate of 30% (smaller if compressed)
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my $data_length = 64 + int (rand (int ($MAX_DATA_LEN * 1.30 + 1)));
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my $random_length = $data_length - length ($data_buf);
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if ($random_length > 0)
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{
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$data_buf .= random_string ($random_length); # or random_bytes ($random_length);
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}
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# compress/deflate the data:
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my $deflator = deflateInit (-WindowBits => MAX_WBITS);
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my $header = $deflator->deflate ($data_buf);
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$compressed_data = $deflator->flush ();
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$compressed_data = $header . $compressed_data;
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# check if data is valid:
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my $compressed_data_len = length ($compressed_data);
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if ($compressed_data_len < 64) # minimum length required by hashcat's tokenizer
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{
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next;
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}
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if (($compressed_data_len + 15) > $MAX_DATA_LEN) # version 5 is not supported in -m 21700
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{
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next;
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}
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$valid_compression_rate = 1;
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}
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# encrypt the data with AES128:
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my $iv = substr ($key, 0, 16);
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my $aes_key = substr ($key, 16, 16);
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my $aes = Crypt::CBC->new ({
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cipher => "Crypt::Rijndael",
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keysize => 16,
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literal_key => 1,
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header => "none",
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iv => $iv,
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key => $aes_key
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});
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my $encrypted_data = $aes->encrypt ($compressed_data);
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# MAC:
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my $hmac_key = substr ($key, 32, 32);
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my $mac = hmac_hex ($encrypted_data, $hmac_key, \&sha256);
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# format the hash:
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my $hash = sprintf ("\$electrum\$4*%s*%s*%s",
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unpack ("H*", $ephemeral_pubkey),
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unpack ("H*", $encrypted_data),
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$mac
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);
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return $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 $index1 = index ($line, ":");
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return if $index1 < 1;
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my $hash_in = substr ($line, 0, $index1);
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my $word = substr ($line, $index1 + 1);
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return if (substr ($hash_in, 0, 10) ne "\$electrum\$");
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# version:
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my $index2 = index ($hash_in, "*");
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return if $index2 < 1;
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my $version = substr ($hash_in, 10, $index2 - 10);
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return if ($version ne "4");
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# public key:
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$index1 = index ($line, "*", $index2 + 1);
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return if $index1 < 1;
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my $ephemeral_pubkey = substr ($hash_in, $index2 + 1, $index1 - $index2 - 1);
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$ephemeral_pubkey = pack ("H*", $ephemeral_pubkey);
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# data:
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$index2 = index ($hash_in, "*", $index1 + 1);
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return if $index2 < 1;
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my $data_buf = substr ($hash_in, $index1 + 1, $index2 - $index1 - 1);
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$data_buf = pack ("H*", $data_buf);
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# MAC:
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my $mac = substr ($hash_in, $index2 + 1);
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# Start:
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my $new_hash = "";
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my $key = generate_key ($word, $ephemeral_pubkey);
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my $hmac_key = substr ($key, 32, 32);
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my $mac_gen = hmac_hex ($data_buf, $hmac_key, \&sha256);
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if ($mac_gen eq $mac)
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{
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$new_hash = $hash_in;
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}
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return ($new_hash, $word);
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}
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1;
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