grub-core/lib/libgcrypt-grub/cipher/rfc2268.c - chromiumos/third_party/grub2 - Git at Google

 /* This file was automatically imported with
    import_gcry.py. Please don't modify it */
 #include <grub/dl.h>
 GRUB_MOD_LICENSE ("GPLv3+");
 /* rfc2268.c  - The cipher described in rfc2268; aka Ron's Cipher 2.
  * Copyright (C) 2003 Nikos Mavroyanopoulos
  * Copyright (C) 2004 Free Software Foundation, Inc.
  *
  * This file is part of Libgcrypt
  *
  * Libgcrypt is free software; you can redistribute it and/or modify
  * it under the terms of the GNU Lesser general Public License as
  * published by the Free Software Foundation; either version 2.1 of
  * the License, or (at your option) any later version.
  *
  * Libgcrypt 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
  * GNU Lesser General Public License for more details.
  *
  * You should have received a copy of the GNU Lesser General Public
  * License along with this program; if not, write to the Free Software
  * Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA
  */

 /* This implementation was written by Nikos Mavroyanopoulos for GNUTLS
  * as a Libgcrypt module (gnutls/lib/x509/rc2.c) and later adapted for
  * direct use by Libgcrypt by Werner Koch.  This implementation is
  * only useful for pkcs#12 descryption.
  *
  * The implementation here is based on Peter Gutmann's RRC.2 paper.
  */


 #include "g10lib.h"
 #include "types.h"
 #include "cipher.h"

 #define RFC2268_BLOCKSIZE 8

 typedef struct
 {
   u16 S[64];
 } RFC2268_context;

 static const unsigned char rfc2268_sbox[] = {
   217, 120, 249, 196,  25, 221, 181, 237,
    40, 233, 253, 121,  74, 160, 216, 157,
   198, 126,  55, 131,  43, 118,  83, 142,
    98,  76, 100, 136,  68, 139, 251, 162,
    23, 154,  89, 245, 135, 179,  79,  19,
    97,  69, 109, 141,   9, 129, 125,  50,
   189, 143,  64, 235, 134, 183, 123,  11,
   240, 149,  33,  34,  92, 107,  78, 130,
    84, 214, 101, 147, 206,  96, 178,  28,
   115,  86, 192,  20, 167, 140, 241, 220,
    18, 117, 202,  31,  59, 190, 228, 209,
    66,  61, 212,  48, 163,  60, 182,  38,
   111, 191,  14, 218,  70, 105,   7,  87,
    39, 242,  29, 155, 188, 148,  67,   3,
   248,  17, 199, 246, 144, 239,  62, 231,
     6, 195, 213,  47, 200, 102,  30, 215,
     8, 232, 234, 222, 128,  82, 238, 247,
   132, 170, 114, 172,  53,  77, 106,  42,
   150,  26, 210, 113,  90,  21,  73, 116,
    75, 159, 208,  94,   4,  24, 164, 236,
   194, 224,  65, 110,  15,  81, 203, 204,
    36, 145, 175,  80, 161, 244, 112,  57,
   153, 124,  58, 133,  35, 184, 180, 122,
   252,   2,  54,  91,  37,  85, 151,  49,
    45,  93, 250, 152, 227, 138, 146, 174,
     5, 223,  41,  16, 103, 108, 186, 201,
   211,   0, 230, 207, 225, 158, 168,  44,
    99,  22,   1,  63,  88, 226, 137, 169,
    13,  56,  52,  27, 171,  51, 255, 176,
   187,  72,  12,  95, 185, 177, 205,  46,
   197, 243, 219,  71, 229, 165, 156, 119,
    10, 166,  32, 104, 254, 127, 193, 173
 };

 #define rotl16(x,n)   (((x) << ((u16)(n))) | ((x) >> (16 - (u16)(n))))
 #define rotr16(x,n)   (((x) >> ((u16)(n))) | ((x) << (16 - (u16)(n))))


 static void
 do_encrypt (void *context, unsigned char *outbuf, const unsigned char *inbuf)
 {
   RFC2268_context *ctx = context;
   register int i, j;
   u16 word0 = 0, word1 = 0, word2 = 0, word3 = 0;

   word0 = (word0 << 8) | inbuf[1];
   word0 = (word0 << 8) | inbuf[0];
   word1 = (word1 << 8) | inbuf[3];
   word1 = (word1 << 8) | inbuf[2];
   word2 = (word2 << 8) | inbuf[5];
   word2 = (word2 << 8) | inbuf[4];
   word3 = (word3 << 8) | inbuf[7];
   word3 = (word3 << 8) | inbuf[6];

   for (i = 0; i < 16; i++)
     {
       j = i * 4;
       /* For some reason I cannot combine those steps. */
       word0 += (word1 & ~word3) + (word2 & word3) + ctx->S[j];
       word0 = rotl16(word0, 1);

       word1 += (word2 & ~word0) + (word3 & word0) + ctx->S[j + 1];
       word1 = rotl16(word1, 2);

       word2 += (word3 & ~word1) + (word0 & word1) + ctx->S[j + 2];
       word2 = rotl16(word2, 3);

       word3 += (word0 & ~word2) + (word1 & word2) + ctx->S[j + 3];
       word3 = rotl16(word3, 5);

       if (i == 4 || i == 10)
         {
           word0 += ctx->S[word3 & 63];
           word1 += ctx->S[word0 & 63];
           word2 += ctx->S[word1 & 63];
           word3 += ctx->S[word2 & 63];
         }

     }

   outbuf[0] = word0 & 255;
   outbuf[1] = word0 >> 8;
   outbuf[2] = word1 & 255;
   outbuf[3] = word1 >> 8;
   outbuf[4] = word2 & 255;
   outbuf[5] = word2 >> 8;
   outbuf[6] = word3 & 255;
   outbuf[7] = word3 >> 8;
 }

 static void
 do_decrypt (void *context, unsigned char *outbuf, const unsigned char *inbuf)
 {
   RFC2268_context *ctx = context;
   register int i, j;
   u16 word0 = 0, word1 = 0, word2 = 0, word3 = 0;

   word0 = (word0 << 8) | inbuf[1];
   word0 = (word0 << 8) | inbuf[0];
   word1 = (word1 << 8) | inbuf[3];
   word1 = (word1 << 8) | inbuf[2];
   word2 = (word2 << 8) | inbuf[5];
   word2 = (word2 << 8) | inbuf[4];
   word3 = (word3 << 8) | inbuf[7];
   word3 = (word3 << 8) | inbuf[6];

   for (i = 15; i >= 0; i--)
     {
       j = i * 4;

       word3 = rotr16(word3, 5);
       word3 -= (word0 & ~word2) + (word1 & word2) + ctx->S[j + 3];

       word2 = rotr16(word2, 3);
       word2 -= (word3 & ~word1) + (word0 & word1) + ctx->S[j + 2];

       word1 = rotr16(word1, 2);
       word1 -= (word2 & ~word0) + (word3 & word0) + ctx->S[j + 1];

       word0 = rotr16(word0, 1);
       word0 -= (word1 & ~word3) + (word2 & word3) + ctx->S[j];

       if (i == 5 || i == 11)
         {
           word3 = word3 - ctx->S[word2 & 63];
           word2 = word2 - ctx->S[word1 & 63];
           word1 = word1 - ctx->S[word0 & 63];
           word0 = word0 - ctx->S[word3 & 63];
         }

     }

   outbuf[0] = word0 & 255;
   outbuf[1] = word0 >> 8;
   outbuf[2] = word1 & 255;
   outbuf[3] = word1 >> 8;
   outbuf[4] = word2 & 255;
   outbuf[5] = word2 >> 8;
   outbuf[6] = word3 & 255;
   outbuf[7] = word3 >> 8;
 }


 static gpg_err_code_t
 setkey_core (void *context, const unsigned char *key, unsigned int keylen, int with_phase2)
 {
   static int initialized;
   static const char *selftest_failed;
   RFC2268_context *ctx = context;
   unsigned int i;
   unsigned char *S, x;
   int len;
   int bits = keylen * 8;

   if (!initialized)
     {
       initialized = 1;
       selftest_failed = selftest ();
       if (selftest_failed)
         log_error ("RFC2268 selftest failed (%s).\n", selftest_failed);
     }
   if (selftest_failed)
     return GPG_ERR_SELFTEST_FAILED;

   if (keylen < 40 / 8)	/* We want at least 40 bits. */
     return GPG_ERR_INV_KEYLEN;

   S = (unsigned char *) ctx->S;

   for (i = 0; i < keylen; i++)
     S[i] = key[i];

   for (i = keylen; i < 128; i++)
     S[i] = rfc2268_sbox[(S[i - keylen] + S[i - 1]) & 255];

   S[0] = rfc2268_sbox[S[0]];

   /* Phase 2 - reduce effective key size to "bits". This was not
    * discussed in Gutmann's paper. I've copied that from the public
    * domain code posted in sci.crypt. */
   if (with_phase2)
     {
       len = (bits + 7) >> 3;
       i = 128 - len;
       x = rfc2268_sbox[S[i] & (255 >> (7 & -bits))];
       S[i] = x;

       while (i--)
         {
           x = rfc2268_sbox[x ^ S[i + len]];
           S[i] = x;
         }
     }

   /* Make the expanded key, endian independent. */
   for (i = 0; i < 64; i++)
     ctx->S[i] = ( (u16) S[i * 2] | (((u16) S[i * 2 + 1]) << 8));

   return 0;
 }

 static gpg_err_code_t
 do_setkey (void *context, const unsigned char *key, unsigned int keylen)
 {
   return setkey_core (context, key, keylen, 1);
 }


 static gcry_cipher_oid_spec_t oids_rfc2268_40[] =
   {
     /*{ "1.2.840.113549.3.2", GCRY_CIPHER_MODE_CBC },*/
     /* pbeWithSHAAnd40BitRC2_CBC */
     { "1.2.840.113549.1.12.1.6", GCRY_CIPHER_MODE_CBC },
     { NULL }
   };

 gcry_cipher_spec_t _gcry_cipher_spec_rfc2268_40 = {
   "RFC2268_40", NULL, oids_rfc2268_40,
   RFC2268_BLOCKSIZE, 40, sizeof(RFC2268_context),
   do_setkey, do_encrypt, do_decrypt
     ,
 #ifdef GRUB_UTIL
     .modname = "gcry_rfc2268",
 #endif
 };


 GRUB_MOD_INIT(gcry_rfc2268)
 {
   grub_cipher_register (&_gcry_cipher_spec_rfc2268_40);
 }

 GRUB_MOD_FINI(gcry_rfc2268)
 {
   grub_cipher_unregister (&_gcry_cipher_spec_rfc2268_40);
 }
	/* This file was automatically imported with
	import_gcry.py. Please don't modify it */
	#include <grub/dl.h>
	GRUB_MOD_LICENSE ("GPLv3+");
	/* rfc2268.c - The cipher described in rfc2268; aka Ron's Cipher 2.
	* Copyright (C) 2003 Nikos Mavroyanopoulos
	* Copyright (C) 2004 Free Software Foundation, Inc.
	*
	* This file is part of Libgcrypt
	*
	* Libgcrypt is free software; you can redistribute it and/or modify
	* it under the terms of the GNU Lesser general Public License as
	* published by the Free Software Foundation; either version 2.1 of
	* the License, or (at your option) any later version.
	*
	* Libgcrypt 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
	* GNU Lesser General Public License for more details.
	*
	* You should have received a copy of the GNU Lesser General Public
	* License along with this program; if not, write to the Free Software
	* Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA
	*/

	/* This implementation was written by Nikos Mavroyanopoulos for GNUTLS
	* as a Libgcrypt module (gnutls/lib/x509/rc2.c) and later adapted for
	* direct use by Libgcrypt by Werner Koch. This implementation is
	* only useful for pkcs#12 descryption.
	*
	* The implementation here is based on Peter Gutmann's RRC.2 paper.
	*/


	#include "g10lib.h"
	#include "types.h"
	#include "cipher.h"

	#define RFC2268_BLOCKSIZE 8

	typedef struct
	{
	u16 S[64];
	} RFC2268_context;

	static const unsigned char rfc2268_sbox[] = {
	217, 120, 249, 196, 25, 221, 181, 237,
	40, 233, 253, 121, 74, 160, 216, 157,
	198, 126, 55, 131, 43, 118, 83, 142,
	98, 76, 100, 136, 68, 139, 251, 162,
	23, 154, 89, 245, 135, 179, 79, 19,
	97, 69, 109, 141, 9, 129, 125, 50,
	189, 143, 64, 235, 134, 183, 123, 11,
	240, 149, 33, 34, 92, 107, 78, 130,
	84, 214, 101, 147, 206, 96, 178, 28,
	115, 86, 192, 20, 167, 140, 241, 220,
	18, 117, 202, 31, 59, 190, 228, 209,
	66, 61, 212, 48, 163, 60, 182, 38,
	111, 191, 14, 218, 70, 105, 7, 87,
	39, 242, 29, 155, 188, 148, 67, 3,
	248, 17, 199, 246, 144, 239, 62, 231,
	6, 195, 213, 47, 200, 102, 30, 215,
	8, 232, 234, 222, 128, 82, 238, 247,
	132, 170, 114, 172, 53, 77, 106, 42,
	150, 26, 210, 113, 90, 21, 73, 116,
	75, 159, 208, 94, 4, 24, 164, 236,
	194, 224, 65, 110, 15, 81, 203, 204,
	36, 145, 175, 80, 161, 244, 112, 57,
	153, 124, 58, 133, 35, 184, 180, 122,
	252, 2, 54, 91, 37, 85, 151, 49,
	45, 93, 250, 152, 227, 138, 146, 174,
	5, 223, 41, 16, 103, 108, 186, 201,
	211, 0, 230, 207, 225, 158, 168, 44,
	99, 22, 1, 63, 88, 226, 137, 169,
	13, 56, 52, 27, 171, 51, 255, 176,
	187, 72, 12, 95, 185, 177, 205, 46,
	197, 243, 219, 71, 229, 165, 156, 119,
	10, 166, 32, 104, 254, 127, 193, 173
	};

	#define rotl16(x,n) (((x) << ((u16)(n))) \| ((x) >> (16 - (u16)(n))))
	#define rotr16(x,n) (((x) >> ((u16)(n))) \| ((x) << (16 - (u16)(n))))



	static void
	do_encrypt (void context, unsigned char outbuf, const unsigned char *inbuf)
	{
	RFC2268_context *ctx = context;
	register int i, j;
	u16 word0 = 0, word1 = 0, word2 = 0, word3 = 0;

	word0 = (word0 << 8) \| inbuf[1];
	word0 = (word0 << 8) \| inbuf[0];
	word1 = (word1 << 8) \| inbuf[3];
	word1 = (word1 << 8) \| inbuf[2];
	word2 = (word2 << 8) \| inbuf[5];
	word2 = (word2 << 8) \| inbuf[4];
	word3 = (word3 << 8) \| inbuf[7];
	word3 = (word3 << 8) \| inbuf[6];

	for (i = 0; i < 16; i++)
	{
	j = i * 4;
	/* For some reason I cannot combine those steps. */
	word0 += (word1 & ~word3) + (word2 & word3) + ctx->S[j];
	word0 = rotl16(word0, 1);

	word1 += (word2 & ~word0) + (word3 & word0) + ctx->S[j + 1];
	word1 = rotl16(word1, 2);

	word2 += (word3 & ~word1) + (word0 & word1) + ctx->S[j + 2];
	word2 = rotl16(word2, 3);

	word3 += (word0 & ~word2) + (word1 & word2) + ctx->S[j + 3];
	word3 = rotl16(word3, 5);

	if (i == 4 \|\| i == 10)
	{
	word0 += ctx->S[word3 & 63];
	word1 += ctx->S[word0 & 63];
	word2 += ctx->S[word1 & 63];
	word3 += ctx->S[word2 & 63];
	}

	}

	outbuf[0] = word0 & 255;
	outbuf[1] = word0 >> 8;
	outbuf[2] = word1 & 255;
	outbuf[3] = word1 >> 8;
	outbuf[4] = word2 & 255;
	outbuf[5] = word2 >> 8;
	outbuf[6] = word3 & 255;
	outbuf[7] = word3 >> 8;
	}

	static void
	do_decrypt (void context, unsigned char outbuf, const unsigned char *inbuf)
	{
	RFC2268_context *ctx = context;
	register int i, j;
	u16 word0 = 0, word1 = 0, word2 = 0, word3 = 0;

	word0 = (word0 << 8) \| inbuf[1];
	word0 = (word0 << 8) \| inbuf[0];
	word1 = (word1 << 8) \| inbuf[3];
	word1 = (word1 << 8) \| inbuf[2];
	word2 = (word2 << 8) \| inbuf[5];
	word2 = (word2 << 8) \| inbuf[4];
	word3 = (word3 << 8) \| inbuf[7];
	word3 = (word3 << 8) \| inbuf[6];

	for (i = 15; i >= 0; i--)
	{
	j = i * 4;

	word3 = rotr16(word3, 5);
	word3 -= (word0 & ~word2) + (word1 & word2) + ctx->S[j + 3];

	word2 = rotr16(word2, 3);
	word2 -= (word3 & ~word1) + (word0 & word1) + ctx->S[j + 2];

	word1 = rotr16(word1, 2);
	word1 -= (word2 & ~word0) + (word3 & word0) + ctx->S[j + 1];

	word0 = rotr16(word0, 1);
	word0 -= (word1 & ~word3) + (word2 & word3) + ctx->S[j];

	if (i == 5 \|\| i == 11)
	{
	word3 = word3 - ctx->S[word2 & 63];
	word2 = word2 - ctx->S[word1 & 63];
	word1 = word1 - ctx->S[word0 & 63];
	word0 = word0 - ctx->S[word3 & 63];
	}

	}

	outbuf[0] = word0 & 255;
	outbuf[1] = word0 >> 8;
	outbuf[2] = word1 & 255;
	outbuf[3] = word1 >> 8;
	outbuf[4] = word2 & 255;
	outbuf[5] = word2 >> 8;
	outbuf[6] = word3 & 255;
	outbuf[7] = word3 >> 8;
	}


	static gpg_err_code_t
	setkey_core (void context, const unsigned char key, unsigned int keylen, int with_phase2)
	{
	static int initialized;
	static const char *selftest_failed;
	RFC2268_context *ctx = context;
	unsigned int i;
	unsigned char *S, x;
	int len;
	int bits = keylen * 8;

	if (!initialized)
	{
	initialized = 1;
	selftest_failed = selftest ();
	if (selftest_failed)
	log_error ("RFC2268 selftest failed (%s).\n", selftest_failed);
	}
	if (selftest_failed)
	return GPG_ERR_SELFTEST_FAILED;

	if (keylen < 40 / 8) /* We want at least 40 bits. */
	return GPG_ERR_INV_KEYLEN;

	S = (unsigned char *) ctx->S;

	for (i = 0; i < keylen; i++)
	S[i] = key[i];

	for (i = keylen; i < 128; i++)
	S[i] = rfc2268_sbox[(S[i - keylen] + S[i - 1]) & 255];

	S[0] = rfc2268_sbox[S[0]];

	/* Phase 2 - reduce effective key size to "bits". This was not
	* discussed in Gutmann's paper. I've copied that from the public
	* domain code posted in sci.crypt. */
	if (with_phase2)
	{
	len = (bits + 7) >> 3;
	i = 128 - len;
	x = rfc2268_sbox[S[i] & (255 >> (7 & -bits))];
	S[i] = x;

	while (i--)
	{
	x = rfc2268_sbox[x ^ S[i + len]];
	S[i] = x;
	}
	}

	/* Make the expanded key, endian independent. */
	for (i = 0; i < 64; i++)
	ctx->S[i] = ( (u16) S[i * 2] \| (((u16) S[i * 2 + 1]) << 8));

	return 0;
	}

	static gpg_err_code_t
	do_setkey (void context, const unsigned char key, unsigned int keylen)
	{
	return setkey_core (context, key, keylen, 1);
	}




	static gcry_cipher_oid_spec_t oids_rfc2268_40[] =
	{
	/{ "1.2.840.113549.3.2", GCRY_CIPHER_MODE_CBC },/
	/* pbeWithSHAAnd40BitRC2_CBC */
	{ "1.2.840.113549.1.12.1.6", GCRY_CIPHER_MODE_CBC },
	{ NULL }
	};

	gcry_cipher_spec_t _gcry_cipher_spec_rfc2268_40 = {
	"RFC2268_40", NULL, oids_rfc2268_40,
	RFC2268_BLOCKSIZE, 40, sizeof(RFC2268_context),
	do_setkey, do_encrypt, do_decrypt
	,
	#ifdef GRUB_UTIL
	.modname = "gcry_rfc2268",
	#endif
	};



	GRUB_MOD_INIT(gcry_rfc2268)
	{
	grub_cipher_register (&_gcry_cipher_spec_rfc2268_40);
	}

	GRUB_MOD_FINI(gcry_rfc2268)
	{
	grub_cipher_unregister (&_gcry_cipher_spec_rfc2268_40);
	}