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crypto.cc
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/***************************************************************************
* crypto.cc -- crypto functions like LM, NTLM etc reside here *
* *
***********************IMPORTANT NMAP LICENSE TERMS************************
* *
* The Nmap Security Scanner is (C) 1996-2021 Insecure.Com LLC ("The Nmap *
* Project"). Nmap is also a registered trademark of the Nmap Project. *
* This program is free software; you may redistribute and/or modify it *
* under the terms of the GNU General Public License as published by the *
* Free Software Foundation; Version 2 ("GPL"), BUT ONLY WITH ALL OF THE *
* CLARIFICATIONS AND EXCEPTIONS DESCRIBED HEREIN. This guarantees your *
* right to use, modify, and redistribute this software under certain *
* conditions. If you wish to embed Nmap technology into proprietary *
* software, we sell alternative licenses (contact [email protected]). *
* Dozens of software vendors already license Nmap technology such as *
* host discovery, port scanning, OS detection, version detection, and *
* the Nmap Scripting Engine. *
* *
* Note that the GPL places important restrictions on "derivative works", *
* yet it does not provide a detailed definition of that term. To avoid *
* misunderstandings, we interpret that term as broadly as copyright law *
* allows. For example, we consider an application to constitute a *
* derivative work for the purpose of this license if it does any of the *
* following with any software or content covered by this license *
* ("Covered Software"): *
* *
* o Integrates source code from Covered Software. *
* *
* o Reads or includes copyrighted data files, such as Nmap's nmap-os-db *
* or nmap-service-probes. *
* *
* o Is designed specifically to execute Covered Software and parse the *
* results (as opposed to typical shell or execution-menu apps, which will *
* execute anything you tell them to). *
* *
* o Includes Covered Software in a proprietary executable installer. The *
* installers produced by InstallShield are an example of this. Including *
* Nmap with other software in compressed or archival form does not *
* trigger this provision, provided appropriate open source decompression *
* or de-archiving software is widely available for no charge. For the *
* purposes of this license, an installer is considered to include Covered *
* Software even if it actually retrieves a copy of Covered Software from *
* another source during runtime (such as by downloading it from the *
* Internet). *
* *
* o Links (statically or dynamically) to a library which does any of the *
* above. *
* *
* o Executes a helper program, module, or script to do any of the above. *
* *
* This list is not exclusive, but is meant to clarify our interpretation *
* of derived works with some common examples. Other people may interpret *
* the plain GPL differently, so we consider this a special exception to *
* the GPL that we apply to Covered Software. Works which meet any of *
* these conditions must conform to all of the terms of this license, *
* particularly including the GPL Section 3 requirements of providing *
* source code and allowing free redistribution of the work as a whole. *
* *
* As another special exception to the GPL terms, the Nmap Project grants *
* permission to link the code of this program with any version of the *
* OpenSSL library which is distributed under a license identical to that *
* listed in the included docs/licenses/OpenSSL.txt file, and distribute *
* linked combinations including the two. *
* *
* The Nmap Project has permission to redistribute Npcap, a packet *
* capturing driver and library for the Microsoft Windows platform. *
* Npcap is a separate work with it's own license rather than this Nmap *
* license. Since the Npcap license does not permit redistribution *
* without special permission, our Nmap Windows binary packages which *
* contain Npcap may not be redistributed without special permission. *
* *
* Any redistribution of Covered Software, including any derived works, *
* must obey and carry forward all of the terms of this license, including *
* obeying all GPL rules and restrictions. For example, source code of *
* the whole work must be provided and free redistribution must be *
* allowed. All GPL references to "this License", are to be treated as *
* including the terms and conditions of this license text as well. *
* *
* Because this license imposes special exceptions to the GPL, Covered *
* Work may not be combined (even as part of a larger work) with plain GPL *
* software. The terms, conditions, and exceptions of this license must *
* be included as well. This license is incompatible with some other open *
* source licenses as well. In some cases we can relicense portions of *
* Nmap or grant special permissions to use it in other open source *
* software. Please contact [email protected] with any such requests. *
* Similarly, we don't incorporate incompatible open source software into *
* Covered Software without special permission from the copyright holders. *
* *
* If you have any questions about the licensing restrictions on using *
* Nmap in other works, we are happy to help. As mentioned above, we also *
* offer an alternative license to integrate Nmap into proprietary *
* applications and appliances. These contracts have been sold to dozens *
* of software vendors, and generally include a perpetual license as well *
* as providing support and updates. They also fund the continued *
* development of Nmap. Please email [email protected] for further *
* information. *
* *
* If you have received a written license agreement or contract for *
* Covered Software stating terms other than these, you may choose to use *
* and redistribute Covered Software under those terms instead of these. *
* *
* Source is provided to this software because we believe users have a *
* right to know exactly what a program is going to do before they run it. *
* This also allows you to audit the software for security holes. *
* *
* Source code also allows you to port Nmap to new platforms, fix bugs, *
* and add new features. You are highly encouraged to send your changes *
* to the [email protected] mailing list for possible incorporation into the *
* main distribution. By sending these changes to Fyodor or one of the *
* Insecure.Org development mailing lists, or checking them into the Nmap *
* source code repository, it is understood (unless you specify *
* otherwise) that you are offering the Nmap Project the unlimited, *
* non-exclusive right to reuse, modify, and relicense the code. Nmap *
* will always be available Open Source, but this is important because *
* the inability to relicense code has caused devastating problems for *
* other Free Software projects (such as KDE and NASM). We also *
* occasionally relicense the code to third parties as discussed above. *
* If you wish to specify special license conditions of your *
* contributions, just say so when you send them. *
* *
* This program is distributed in the hope that it will be useful, but *
* WITHOUT ANY WARRANTY; without even the implied warranty of *
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the Nmap *
* license file for more details (it's in a COPYING file included with *
* Nmap, and also available from https://svn.nmap.org/nmap/COPYING) *
* *
***************************************************************************/
#include "ncrack.h"
#include "crypto.h"
#if HAVE_OPENSSL
#include <openssl/des.h>
#include <openssl/hmac.h>
#include <openssl/md4.h>
#include <openssl/md5.h>
#include <openssl/sha.h>
#include <openssl/bn.h>
#ifndef WIN32
#include <stdint.h>
#endif
#include "ncrack_error.h"
#include "utils.h"
static void password_to_key(const uint8_t password[7], uint8_t key[8])
{
/* make room for parity bits */
key[0] = (password[0] >> 0);
key[1] = ((password[0]) << 7) | (password[1] >> 1);
key[2] = ((password[1]) << 6) | (password[2] >> 2);
key[3] = ((password[2]) << 5) | (password[3] >> 3);
key[4] = ((password[3]) << 4) | (password[4] >> 4);
key[5] = ((password[4]) << 3) | (password[5] >> 5);
key[6] = ((password[5]) << 2) | (password[6] >> 6);
key[7] = ((password[6]) << 1);
}
static void
des(const uint8_t password[7], const uint8_t data[8], uint8_t result[])
{
DES_cblock key;
DES_key_schedule schedule;
password_to_key(password, key);
DES_set_odd_parity(&key);
DES_set_key_unchecked(&key, &schedule);
DES_ecb_encrypt((DES_cblock*)data, (DES_cblock*)result, &schedule, DES_ENCRYPT);
}
/* Generate the Lanman v1 hash (LMv1). The generated hash is incredibly easy to
* reverse, because the input is padded or truncated to 14 characters, then
* split into two 7-character strings. Each of these strings are used as a key
* to encrypt the string, "KGS!@#$%" in DES. Because the keys are no longer
* than 7-characters long, it's pretty trivial to bruteforce them.
*/
void
lm_create_hash(const char *password, uint8_t result[16])
{
size_t i;
uint8_t password1[7];
uint8_t password2[7];
uint8_t kgs[] = "KGS!@#$%";
uint8_t hash1[8];
uint8_t hash2[8];
/* Initialize passwords to NULLs. */
memset(password1, 0, 7);
memset(password2, 0, 7);
/* Copy passwords over, convert to uppercase, they're automatically padded with NULLs. */
for (i = 0; i < 7; i++) {
if (i < strlen(password))
password1[i] = toupper(password[i]);
if (i + 7 < strlen(password))
password2[i] = toupper(password[i + 7]);
}
/* Do the encryption. */
des(password1, kgs, hash1);
des(password2, kgs, hash2);
/* Copy the result to the return parameter. */
memcpy(result + 0, hash1, 8);
memcpy(result + 8, hash2, 8);
}
/* Create the Lanman response to send back to the server. To do this, the
* Lanman password is padded to 21 characters and split into three
* 7-character strings. Each of those strings is used as a key to encrypt
* the server challenge. The three encrypted strings are concatenated and
* returned.
*/
void
lm_create_response(const uint8_t lanman[16], const uint8_t challenge[8], uint8_t result[24])
{
size_t i;
uint8_t password1[7];
uint8_t password2[7];
uint8_t password3[7];
uint8_t hash1[8];
uint8_t hash2[8];
uint8_t hash3[8];
/* Initialize passwords. */
memset(password1, 0, 7);
memset(password2, 0, 7);
memset(password3, 0, 7);
/* Copy data over. */
for (i = 0; i < 7; i++) {
password1[i] = lanman[i];
password2[i] = lanman[i + 7];
password3[i] = (i + 14 < 16) ? lanman[i + 14] : 0;
}
/* do the encryption. */
des(password1, challenge, hash1);
des(password2, challenge, hash2);
des(password3, challenge, hash3);
/* Copy the result to the return parameter. */
memcpy(result + 0, hash1, 8);
memcpy(result + 8, hash2, 8);
memcpy(result + 16, hash3, 8);
}
/* Generate the NTLMv1 hash. This hash is quite a bit better than LMv1, and is
* far easier to generate. Basically, it's the MD4 of the Unicode password.
*/
void
ntlm_create_hash(const char *password, uint8_t result[16])
{
char *unicode = unicode_alloc(password);
MD4_CTX ntlm;
if(!unicode)
fatal("%s non unicode", __func__);
MD4_Init(&ntlm);
MD4_Update(&ntlm, unicode, strlen(password) * 2);
MD4_Final(result, &ntlm);
free(unicode);
}
/* Create the NTLM response to send back to the server. This is actually done
* the exact same way as the Lanman hash, so we call the Lanman function.
*/
void
ntlm_create_response(const uint8_t ntlm[16], const uint8_t challenge[8],
uint8_t result[24])
{
lm_create_response(ntlm, challenge, result);
}
/* Create the NTLMv2 hash, which is based on the NTLMv1 hash (for easy
* upgrading), the username, and the domain. Essentially, the NTLM hash
* is used as a HMAC-MD5 key, which is used to hash the unicode domain
* concatenated with the unicode username.
*/
void
ntlmv2_create_hash(const uint8_t ntlm[16], const char *username,
const char *domain, uint8_t hash[16])
{
/* Convert username to unicode. */
size_t username_length = strlen(username);
size_t domain_length = strlen(domain);
char *combined;
uint8_t *combined_unicode;
/* Probably shouldn't do this, but this is all prototype so eh? */
if (username_length > 256 || domain_length > 256)
fatal("username or domain too long.");
/* Combine the username and domain into one string. */
combined = (char *)safe_malloc(username_length + domain_length + 1);
memset(combined, 0, username_length + domain_length + 1);
memcpy(combined, username, username_length);
memcpy(combined + username_length, domain, domain_length);
/* Convert to Unicode. */
combined_unicode = (uint8_t*)unicode_alloc_upper(combined);
if (!combined_unicode)
fatal("Out of memory");
/* Perform the Hmac-MD5. */
HMAC(EVP_md5(), ntlm, 16, combined_unicode, (username_length + domain_length) * 2, hash, NULL);
free(combined_unicode);
free(combined);
}
/* Create the LMv2 response, which can be sent back to the server. This is
* identical to the NTLMv2 function, except that it uses an 8-byte client
* challenge. The reason for LMv2 is a long and twisted story. Well,
* not really. The reason is basically that the v1 hashes are always 24-bytes,
* and some servers expect 24 bytes, but the NTLMv2 hash is more than 24 bytes.
* So, the only way to keep pass-through compatibility was to have a v2-hash
* that was guaranteed to be 24 bytes. So LMv1 was born: it has a 16-byte hash
* followed by the 8-byte client challenge, for a total of 24 bytes.
*/
void
lmv2_create_response(const uint8_t ntlm[16], const char *username,
const char *domain, const uint8_t challenge[8], uint8_t *result,
uint8_t *result_size)
{
ntlmv2_create_response(ntlm, username, domain, challenge, result, result_size);
}
/* Create the NTLMv2 response, which can be sent back to the server. This is
* done by using the HMAC-MD5 algorithm with the NTLMv2 hash as a key, and
* the server challenge concatenated with the client challenge for the data.
* The resulting hash is concatenated with the client challenge and returned.
*/
void
ntlmv2_create_response(const uint8_t ntlm[16], const char *username,
const char *domain, const uint8_t challenge[8], uint8_t *result,
uint8_t *result_size)
{
size_t i;
uint8_t v2hash[16];
uint8_t *data;
uint8_t blip[8];
uint8_t *blob = NULL;
uint8_t blob_length = 0;
/* Create the 'blip'. TODO: Do I care if this is random? */
for (i = 0; i < 8; i++)
blip[i] = i;
if (*result_size < 24)
{
/* Result can't be less than 24 bytes. */
fatal("Result size is too low!");
} else if (*result_size == 24) {
/* If they're looking for 24 bytes, then it's just the raw blob. */
blob = (uint8_t *)safe_malloc(8);
memcpy(blob, blip, 8);
blob_length = 8;
} else {
blob = (uint8_t *)safe_malloc(24);
for (i = 0; i < 24; i++)
blob[i] = i;
blob_length = 24;
}
/* Allocate room enough for the server challenge and the client blob. */
data = (uint8_t *)safe_malloc(8 + blob_length);
/* Copy the challenge into the memory. */
memcpy(data, challenge, 8);
/* Copy the blob into the memory. */
memcpy(data + 8, blob, blob_length);
/* Get the v2 hash. */
ntlmv2_create_hash(ntlm, username, domain, v2hash);
/* Generate the v2 response. */
HMAC(EVP_md5(), v2hash, 16, data, 8 + blob_length, result, NULL);
/* Copy the blob onto the end of the v2 response. */
memcpy(result + 16, blob, blob_length);
/* Store the result size. */
*result_size = blob_length + 16;
/* Finally, free up some memory. */
free(data);
free(blob);
}
/*
* Uses the RSA algorithm to encrypt the input into the output.
*/
void rsa_encrypt(uint8_t *input, uint8_t *output, int length,
uint8_t *mod_bin, uint32_t mod_size, uint8_t *exp_bin)
{
uint8_t input_temp[256];
BIGNUM *val1 = BN_new(), *val2 = BN_new(), *bn_mod = BN_new(), *bn_exp = BN_new();
BN_CTX *bn_ctx = BN_CTX_new();
memcpy(input_temp, input, length);
mem_reverse(input_temp, length);
mem_reverse(mod_bin, mod_size);
mem_reverse(exp_bin, 4);
BN_bin2bn(input_temp, length, val1);
BN_bin2bn(exp_bin, 4, bn_exp);
BN_bin2bn(mod_bin, mod_size, bn_mod);
BN_mod_exp(val2, val1, bn_exp, bn_mod, bn_ctx);
int output_length = BN_bn2bin(val2, output);
mem_reverse(output, output_length);
if (output_length < (int) mod_size)
memset(output + output_length, 0, mod_size - output_length);
BN_CTX_free(bn_ctx);
BN_clear_free(val1);
BN_free(val2);
BN_free(bn_mod);
BN_free(bn_exp);
}
/*
* Uses MD5 and SHA1 hash functions, using 3 salts to compute a message
* digest (saved into 'output')
*/
void
hash48(uint8_t *output, uint8_t *input, uint8_t salt, uint8_t *sha_salt1,
uint8_t *sha_salt2)
{
SHA_CTX sha1_ctx;
MD5_CTX md5_ctx;
u_char padding[4];
u_char sig[20];
for (int i = 0; i < 3; i++) {
memset(padding, salt + i, i +1);
SHA1_Init(&sha1_ctx);
MD5_Init(&md5_ctx);
SHA1_Update(&sha1_ctx, padding, i + 1);
SHA1_Update(&sha1_ctx, input, 48);
SHA1_Update(&sha1_ctx, sha_salt1, 32);
SHA1_Update(&sha1_ctx, sha_salt2, 32);
SHA1_Final(sig, &sha1_ctx);
MD5_Update(&md5_ctx, input, 48);
MD5_Update(&md5_ctx, sig, 20);
MD5_Final(&output[i*16], &md5_ctx);
}
}
/*
* MD5 crypt 'input' into 'output' by using 2 salts
*/
void
hash16(uint8_t *output, uint8_t *input, uint8_t *md5_salt1, uint8_t *md5_salt2)
{
MD5_CTX md5_ctx;
MD5_Init(&md5_ctx);
MD5_Update(&md5_ctx, input, 16);
MD5_Update(&md5_ctx, md5_salt1, 32);
MD5_Update(&md5_ctx, md5_salt2, 32);
MD5_Final(output, &md5_ctx);
}
#endif /* HAVE_OPENSSL */
/*
* This is D3DES (V5.09) by Richard Outerbridge with the double and
* triple-length support removed for use in VNC. Also the bytebit[] array
* has been reversed so that the most significant bit in each byte of the
* key is ignored, not the least significant.
*
* These changes are:
* Copyright (C) 1999 AT&T Laboratories Cambridge. All Rights Reserved.
*
* This software is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
*/
/* D3DES (V5.09) -
*
* A portable, public domain, version of the Data Encryption Standard.
*
* Written with Symantec's THINK (Lightspeed) C by Richard Outerbridge.
* Thanks to: Dan Hoey for his excellent Initial and Inverse permutation
* code; Jim Gillogly & Phil Karn for the DES key schedule code; Dennis
* Ferguson, Eric Young and Dana How for comparing notes; and Ray Lau,
* for humouring me on.
*
* Copyright (c) 1988,1989,1990,1991,1992 by Richard Outerbridge.
* (GEnie : OUTER; CIS : [71755,204]) Graven Imagery, 1992.
*/
static void scrunch(unsigned char *, unsigned long *);
static void unscrun(unsigned long *, unsigned char *);
static void desfunc(unsigned long *, unsigned long *);
static void cookey(unsigned long *);
static unsigned long KnL[32] = { 0L };
//static unsigned long KnR[32] = { 0L };
//static unsigned long Kn3[32] = { 0L };
/*static unsigned char Df_Key[24] = {
0x01,0x23,0x45,0x67,0x89,0xab,0xcd,0xef,
0xfe,0xdc,0xba,0x98,0x76,0x54,0x32,0x10,
0x89,0xab,0xcd,0xef,0x01,0x23,0x45,0x67 };
*/
static unsigned short bytebit[8] = {
01, 02, 04, 010, 020, 040, 0100, 0200 };
static unsigned long bigbyte[24] = {
0x800000L, 0x400000L, 0x200000L, 0x100000L,
0x80000L, 0x40000L, 0x20000L, 0x10000L,
0x8000L, 0x4000L, 0x2000L, 0x1000L,
0x800L, 0x400L, 0x200L, 0x100L,
0x80L, 0x40L, 0x20L, 0x10L,
0x8L, 0x4L, 0x2L, 0x1L };
/* Use the key schedule specified in the Standard (ANSI X3.92-1981). */
static unsigned char pc1[56] = {
56, 48, 40, 32, 24, 16, 8, 0, 57, 49, 41, 33, 25, 17,
9, 1, 58, 50, 42, 34, 26, 18, 10, 2, 59, 51, 43, 35,
62, 54, 46, 38, 30, 22, 14, 6, 61, 53, 45, 37, 29, 21,
13, 5, 60, 52, 44, 36, 28, 20, 12, 4, 27, 19, 11, 3 };
static unsigned char totrot[16] = {
1,2,4,6,8,10,12,14,15,17,19,21,23,25,27,28 };
static unsigned char pc2[48] = {
13, 16, 10, 23, 0, 4, 2, 27, 14, 5, 20, 9,
22, 18, 11, 3, 25, 7, 15, 6, 26, 19, 12, 1,
40, 51, 30, 36, 46, 54, 29, 39, 50, 44, 32, 47,
43, 48, 38, 55, 33, 52, 45, 41, 49, 35, 28, 31 };
//void deskey(key, edf) /* Thanks to James Gillogly & Phil Karn! */
//unsigned char *key;
//int edf;
void deskey( /* Thanks to James Gillogly & Phil Karn! */
unsigned char *key,
int edf
)
{
register int i, j, l, m, n;
unsigned char pc1m[56], pcr[56];
unsigned long kn[32];
for ( j = 0; j < 56; j++ ) {
l = pc1[j];
m = l & 07;
pc1m[j] = (key[l >> 3] & bytebit[m]) ? 1 : 0;
}
for( i = 0; i < 16; i++ ) {
if( edf == DE1 ) m = (15 - i) << 1;
else m = i << 1;
n = m + 1;
kn[m] = kn[n] = 0L;
for( j = 0; j < 28; j++ ) {
l = j + totrot[i];
if( l < 28 ) pcr[j] = pc1m[l];
else pcr[j] = pc1m[l - 28];
}
for( j = 28; j < 56; j++ ) {
l = j + totrot[i];
if( l < 56 ) pcr[j] = pc1m[l];
else pcr[j] = pc1m[l - 28];
}
for( j = 0; j < 24; j++ ) {
if( pcr[pc2[j]] ) kn[m] |= bigbyte[j];
if( pcr[pc2[j+24]] ) kn[n] |= bigbyte[j];
}
}
cookey(kn);
return;
}
//static void cookey(raw1)
//register unsigned long *raw1;
static void cookey(
register unsigned long *raw1
)
{
register unsigned long *cook, *raw0;
unsigned long dough[32];
register int i;
cook = dough;
for( i = 0; i < 16; i++, raw1++ ) {
raw0 = raw1++;
*cook = (*raw0 & 0x00fc0000L) << 6;
*cook |= (*raw0 & 0x00000fc0L) << 10;
*cook |= (*raw1 & 0x00fc0000L) >> 10;
*cook++ |= (*raw1 & 0x00000fc0L) >> 6;
*cook = (*raw0 & 0x0003f000L) << 12;
*cook |= (*raw0 & 0x0000003fL) << 16;
*cook |= (*raw1 & 0x0003f000L) >> 4;
*cook++ |= (*raw1 & 0x0000003fL);
}
usekey(dough);
return;
}
//void cpkey(into)
//register unsigned long *into;
void cpkey(
register unsigned long *into
)
{
register unsigned long *from, *endp;
from = KnL, endp = &KnL[32];
while( from < endp ) *into++ = *from++;
return;
}
//void usekey(from)
//register unsigned long *from;
void usekey(
register unsigned long *from
)
{
register unsigned long *to, *endp;
to = KnL, endp = &KnL[32];
while( to < endp ) *to++ = *from++;
return;
}
//void des(inblock, outblock)
//unsigned char *inblock, *outblock;
void des(
unsigned char *inblock, unsigned char *outblock
)
{
unsigned long work[2];
scrunch(inblock, work);
desfunc(work, KnL);
unscrun(work, outblock);
return;
}
//static void scrunch(outof, into)
//register unsigned char *outof;
//register unsigned long *into;
static void scrunch(
register unsigned char *outof,
register unsigned long *into
)
{
*into = (*outof++ & 0xffL) << 24;
*into |= (*outof++ & 0xffL) << 16;
*into |= (*outof++ & 0xffL) << 8;
*into++ |= (*outof++ & 0xffL);
*into = (*outof++ & 0xffL) << 24;
*into |= (*outof++ & 0xffL) << 16;
*into |= (*outof++ & 0xffL) << 8;
*into |= (*outof & 0xffL);
return;
}
//static void unscrun(outof, into)
//register unsigned long *outof;
//register unsigned char *into;
static void unscrun(
register unsigned long *outof,
register unsigned char *into
)
{
*into++ = (*outof >> 24) & 0xffL;
*into++ = (*outof >> 16) & 0xffL;
*into++ = (*outof >> 8) & 0xffL;
*into++ = *outof++ & 0xffL;
*into++ = (*outof >> 24) & 0xffL;
*into++ = (*outof >> 16) & 0xffL;
*into++ = (*outof >> 8) & 0xffL;
*into = *outof & 0xffL;
return;
}
static unsigned long SP1[64] = {
0x01010400L, 0x00000000L, 0x00010000L, 0x01010404L,
0x01010004L, 0x00010404L, 0x00000004L, 0x00010000L,
0x00000400L, 0x01010400L, 0x01010404L, 0x00000400L,
0x01000404L, 0x01010004L, 0x01000000L, 0x00000004L,
0x00000404L, 0x01000400L, 0x01000400L, 0x00010400L,
0x00010400L, 0x01010000L, 0x01010000L, 0x01000404L,
0x00010004L, 0x01000004L, 0x01000004L, 0x00010004L,
0x00000000L, 0x00000404L, 0x00010404L, 0x01000000L,
0x00010000L, 0x01010404L, 0x00000004L, 0x01010000L,
0x01010400L, 0x01000000L, 0x01000000L, 0x00000400L,
0x01010004L, 0x00010000L, 0x00010400L, 0x01000004L,
0x00000400L, 0x00000004L, 0x01000404L, 0x00010404L,
0x01010404L, 0x00010004L, 0x01010000L, 0x01000404L,
0x01000004L, 0x00000404L, 0x00010404L, 0x01010400L,
0x00000404L, 0x01000400L, 0x01000400L, 0x00000000L,
0x00010004L, 0x00010400L, 0x00000000L, 0x01010004L };
static unsigned long SP2[64] = {
0x80108020L, 0x80008000L, 0x00008000L, 0x00108020L,
0x00100000L, 0x00000020L, 0x80100020L, 0x80008020L,
0x80000020L, 0x80108020L, 0x80108000L, 0x80000000L,
0x80008000L, 0x00100000L, 0x00000020L, 0x80100020L,
0x00108000L, 0x00100020L, 0x80008020L, 0x00000000L,
0x80000000L, 0x00008000L, 0x00108020L, 0x80100000L,
0x00100020L, 0x80000020L, 0x00000000L, 0x00108000L,
0x00008020L, 0x80108000L, 0x80100000L, 0x00008020L,
0x00000000L, 0x00108020L, 0x80100020L, 0x00100000L,
0x80008020L, 0x80100000L, 0x80108000L, 0x00008000L,
0x80100000L, 0x80008000L, 0x00000020L, 0x80108020L,
0x00108020L, 0x00000020L, 0x00008000L, 0x80000000L,
0x00008020L, 0x80108000L, 0x00100000L, 0x80000020L,
0x00100020L, 0x80008020L, 0x80000020L, 0x00100020L,
0x00108000L, 0x00000000L, 0x80008000L, 0x00008020L,
0x80000000L, 0x80100020L, 0x80108020L, 0x00108000L };
static unsigned long SP3[64] = {
0x00000208L, 0x08020200L, 0x00000000L, 0x08020008L,
0x08000200L, 0x00000000L, 0x00020208L, 0x08000200L,
0x00020008L, 0x08000008L, 0x08000008L, 0x00020000L,
0x08020208L, 0x00020008L, 0x08020000L, 0x00000208L,
0x08000000L, 0x00000008L, 0x08020200L, 0x00000200L,
0x00020200L, 0x08020000L, 0x08020008L, 0x00020208L,
0x08000208L, 0x00020200L, 0x00020000L, 0x08000208L,
0x00000008L, 0x08020208L, 0x00000200L, 0x08000000L,
0x08020200L, 0x08000000L, 0x00020008L, 0x00000208L,
0x00020000L, 0x08020200L, 0x08000200L, 0x00000000L,
0x00000200L, 0x00020008L, 0x08020208L, 0x08000200L,
0x08000008L, 0x00000200L, 0x00000000L, 0x08020008L,
0x08000208L, 0x00020000L, 0x08000000L, 0x08020208L,
0x00000008L, 0x00020208L, 0x00020200L, 0x08000008L,
0x08020000L, 0x08000208L, 0x00000208L, 0x08020000L,
0x00020208L, 0x00000008L, 0x08020008L, 0x00020200L };
static unsigned long SP4[64] = {
0x00802001L, 0x00002081L, 0x00002081L, 0x00000080L,
0x00802080L, 0x00800081L, 0x00800001L, 0x00002001L,
0x00000000L, 0x00802000L, 0x00802000L, 0x00802081L,
0x00000081L, 0x00000000L, 0x00800080L, 0x00800001L,
0x00000001L, 0x00002000L, 0x00800000L, 0x00802001L,
0x00000080L, 0x00800000L, 0x00002001L, 0x00002080L,
0x00800081L, 0x00000001L, 0x00002080L, 0x00800080L,
0x00002000L, 0x00802080L, 0x00802081L, 0x00000081L,
0x00800080L, 0x00800001L, 0x00802000L, 0x00802081L,
0x00000081L, 0x00000000L, 0x00000000L, 0x00802000L,
0x00002080L, 0x00800080L, 0x00800081L, 0x00000001L,
0x00802001L, 0x00002081L, 0x00002081L, 0x00000080L,
0x00802081L, 0x00000081L, 0x00000001L, 0x00002000L,
0x00800001L, 0x00002001L, 0x00802080L, 0x00800081L,
0x00002001L, 0x00002080L, 0x00800000L, 0x00802001L,
0x00000080L, 0x00800000L, 0x00002000L, 0x00802080L };
static unsigned long SP5[64] = {
0x00000100L, 0x02080100L, 0x02080000L, 0x42000100L,
0x00080000L, 0x00000100L, 0x40000000L, 0x02080000L,
0x40080100L, 0x00080000L, 0x02000100L, 0x40080100L,
0x42000100L, 0x42080000L, 0x00080100L, 0x40000000L,
0x02000000L, 0x40080000L, 0x40080000L, 0x00000000L,
0x40000100L, 0x42080100L, 0x42080100L, 0x02000100L,
0x42080000L, 0x40000100L, 0x00000000L, 0x42000000L,
0x02080100L, 0x02000000L, 0x42000000L, 0x00080100L,
0x00080000L, 0x42000100L, 0x00000100L, 0x02000000L,
0x40000000L, 0x02080000L, 0x42000100L, 0x40080100L,
0x02000100L, 0x40000000L, 0x42080000L, 0x02080100L,
0x40080100L, 0x00000100L, 0x02000000L, 0x42080000L,
0x42080100L, 0x00080100L, 0x42000000L, 0x42080100L,
0x02080000L, 0x00000000L, 0x40080000L, 0x42000000L,
0x00080100L, 0x02000100L, 0x40000100L, 0x00080000L,
0x00000000L, 0x40080000L, 0x02080100L, 0x40000100L };
static unsigned long SP6[64] = {
0x20000010L, 0x20400000L, 0x00004000L, 0x20404010L,
0x20400000L, 0x00000010L, 0x20404010L, 0x00400000L,
0x20004000L, 0x00404010L, 0x00400000L, 0x20000010L,
0x00400010L, 0x20004000L, 0x20000000L, 0x00004010L,
0x00000000L, 0x00400010L, 0x20004010L, 0x00004000L,
0x00404000L, 0x20004010L, 0x00000010L, 0x20400010L,
0x20400010L, 0x00000000L, 0x00404010L, 0x20404000L,
0x00004010L, 0x00404000L, 0x20404000L, 0x20000000L,
0x20004000L, 0x00000010L, 0x20400010L, 0x00404000L,
0x20404010L, 0x00400000L, 0x00004010L, 0x20000010L,
0x00400000L, 0x20004000L, 0x20000000L, 0x00004010L,
0x20000010L, 0x20404010L, 0x00404000L, 0x20400000L,
0x00404010L, 0x20404000L, 0x00000000L, 0x20400010L,
0x00000010L, 0x00004000L, 0x20400000L, 0x00404010L,
0x00004000L, 0x00400010L, 0x20004010L, 0x00000000L,
0x20404000L, 0x20000000L, 0x00400010L, 0x20004010L };
static unsigned long SP7[64] = {
0x00200000L, 0x04200002L, 0x04000802L, 0x00000000L,
0x00000800L, 0x04000802L, 0x00200802L, 0x04200800L,
0x04200802L, 0x00200000L, 0x00000000L, 0x04000002L,
0x00000002L, 0x04000000L, 0x04200002L, 0x00000802L,
0x04000800L, 0x00200802L, 0x00200002L, 0x04000800L,
0x04000002L, 0x04200000L, 0x04200800L, 0x00200002L,
0x04200000L, 0x00000800L, 0x00000802L, 0x04200802L,
0x00200800L, 0x00000002L, 0x04000000L, 0x00200800L,
0x04000000L, 0x00200800L, 0x00200000L, 0x04000802L,
0x04000802L, 0x04200002L, 0x04200002L, 0x00000002L,
0x00200002L, 0x04000000L, 0x04000800L, 0x00200000L,
0x04200800L, 0x00000802L, 0x00200802L, 0x04200800L,
0x00000802L, 0x04000002L, 0x04200802L, 0x04200000L,
0x00200800L, 0x00000000L, 0x00000002L, 0x04200802L,
0x00000000L, 0x00200802L, 0x04200000L, 0x00000800L,
0x04000002L, 0x04000800L, 0x00000800L, 0x00200002L };
static unsigned long SP8[64] = {
0x10001040L, 0x00001000L, 0x00040000L, 0x10041040L,
0x10000000L, 0x10001040L, 0x00000040L, 0x10000000L,
0x00040040L, 0x10040000L, 0x10041040L, 0x00041000L,
0x10041000L, 0x00041040L, 0x00001000L, 0x00000040L,
0x10040000L, 0x10000040L, 0x10001000L, 0x00001040L,
0x00041000L, 0x00040040L, 0x10040040L, 0x10041000L,
0x00001040L, 0x00000000L, 0x00000000L, 0x10040040L,
0x10000040L, 0x10001000L, 0x00041040L, 0x00040000L,
0x00041040L, 0x00040000L, 0x10041000L, 0x00001000L,
0x00000040L, 0x10040040L, 0x00001000L, 0x00041040L,
0x10001000L, 0x00000040L, 0x10000040L, 0x10040000L,
0x10040040L, 0x10000000L, 0x00040000L, 0x10001040L,
0x00000000L, 0x10041040L, 0x00040040L, 0x10000040L,
0x10040000L, 0x10001000L, 0x10001040L, 0x00000000L,
0x10041040L, 0x00041000L, 0x00041000L, 0x00001040L,
0x00001040L, 0x00040040L, 0x10000000L, 0x10041000L };
//static void desfunc(block, keys)
//register unsigned long *block, *keys;
static void desfunc(
register unsigned long *block, register unsigned long *keys
)
{
register unsigned long fval, work, right, leftt;
register int round;
leftt = block[0];
right = block[1];
work = ((leftt >> 4) ^ right) & 0x0f0f0f0fL;
right ^= work;
leftt ^= (work << 4);
work = ((leftt >> 16) ^ right) & 0x0000ffffL;
right ^= work;
leftt ^= (work << 16);
work = ((right >> 2) ^ leftt) & 0x33333333L;
leftt ^= work;
right ^= (work << 2);
work = ((right >> 8) ^ leftt) & 0x00ff00ffL;
leftt ^= work;
right ^= (work << 8);
right = ((right << 1) | ((right >> 31) & 1L)) & 0xffffffffL;
work = (leftt ^ right) & 0xaaaaaaaaL;
leftt ^= work;
right ^= work;
leftt = ((leftt << 1) | ((leftt >> 31) & 1L)) & 0xffffffffL;
for( round = 0; round < 8; round++ ) {
work = (right << 28) | (right >> 4);
work ^= *keys++;
fval = SP7[ work & 0x3fL];
fval |= SP5[(work >> 8) & 0x3fL];
fval |= SP3[(work >> 16) & 0x3fL];
fval |= SP1[(work >> 24) & 0x3fL];
work = right ^ *keys++;
fval |= SP8[ work & 0x3fL];
fval |= SP6[(work >> 8) & 0x3fL];
fval |= SP4[(work >> 16) & 0x3fL];
fval |= SP2[(work >> 24) & 0x3fL];
leftt ^= fval;
work = (leftt << 28) | (leftt >> 4);
work ^= *keys++;
fval = SP7[ work & 0x3fL];
fval |= SP5[(work >> 8) & 0x3fL];
fval |= SP3[(work >> 16) & 0x3fL];
fval |= SP1[(work >> 24) & 0x3fL];
work = leftt ^ *keys++;
fval |= SP8[ work & 0x3fL];
fval |= SP6[(work >> 8) & 0x3fL];
fval |= SP4[(work >> 16) & 0x3fL];
fval |= SP2[(work >> 24) & 0x3fL];
right ^= fval;
}
right = (right << 31) | (right >> 1);
work = (leftt ^ right) & 0xaaaaaaaaL;
leftt ^= work;
right ^= work;
leftt = (leftt << 31) | (leftt >> 1);
work = ((leftt >> 8) ^ right) & 0x00ff00ffL;
right ^= work;
leftt ^= (work << 8);
work = ((leftt >> 2) ^ right) & 0x33333333L;
right ^= work;
leftt ^= (work << 2);
work = ((right >> 16) ^ leftt) & 0x0000ffffL;
leftt ^= work;
right ^= (work << 16);
work = ((right >> 4) ^ leftt) & 0x0f0f0f0fL;
leftt ^= work;
right ^= (work << 4);
*block++ = right;
*block = leftt;
return;
}
/* Validation sets:
*
* Single-length key, single-length plaintext -
* Key : 0123 4567 89ab cdef
* Plain : 0123 4567 89ab cde7
* Cipher : c957 4425 6a5e d31d
*
* Double-length key, single-length plaintext -
* Key : 0123 4567 89ab cdef fedc ba98 7654 3210
* Plain : 0123 4567 89ab cde7
* Cipher : 7f1d 0a77 826b 8aff
*
* Double-length key, double-length plaintext -
* Key : 0123 4567 89ab cdef fedc ba98 7654 3210
* Plain : 0123 4567 89ab cdef 0123 4567 89ab cdff
* Cipher : 27a0 8440 406a df60 278f 47cf 42d6 15d7
*
* Triple-length key, single-length plaintext -
* Key : 0123 4567 89ab cdef fedc ba98 7654 3210 89ab cdef 0123 4567
* Plain : 0123 4567 89ab cde7
* Cipher : de0b 7c06 ae5e 0ed5
*
* Triple-length key, double-length plaintext -
* Key : 0123 4567 89ab cdef fedc ba98 7654 3210 89ab cdef 0123 4567
* Plain : 0123 4567 89ab cdef 0123 4567 89ab cdff
* Cipher : ad0d 1b30 ac17 cf07 0ed1 1c63 81e4 4de5
*
* d3des V5.0a rwo 9208.07 18:44 Graven Imagery
**********************************************************************/