/* DESC.C - Data Encryption Standard routines for RSAREF Based on "Karn/Hoey/Outerbridge" implementation (KHODES) */ #include "global.h" #include "rsaref.h" #include "des.h" static UINT2 BYTE_BIT[8] = { 0200, 0100, 040, 020, 010, 04, 02, 01 }; static UINT4 BIG_BYTE[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 }; 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 TOTAL_ROTATIONS[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 }; static UINT4 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 UINT4 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 UINT4 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 UINT4 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 UINT4 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 UINT4 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 UINT4 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 UINT4 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 Unpack PROTO_LIST ((unsigned char *, UINT4 *)); static void Pack PROTO_LIST ((UINT4 *, unsigned char *)); static void DESKey PROTO_LIST ((UINT4 *, unsigned char *, int)); static void CookKey PROTO_LIST ((UINT4 *, UINT4 *, int)); static void DESFunction PROTO_LIST ((UINT4 *, UINT4 *)); /* Initialize context. Caller must zeroize the context when finished. */ void DES_CBCInit (context, key, iv, encrypt) DES_CBC_CTX *context; /* context */ unsigned char key[8]; /* key */ unsigned char iv[8]; /* initializing vector */ int encrypt; /* encrypt flag (1 = encrypt, 0 = decrypt) */ { /* Copy encrypt flag to context. */ context->encrypt = encrypt; /* Pack initializing vector into context. */ Pack (context->iv, iv); /* Save the IV for use in Restart */ context->originalIV[0] = context->iv[0]; context->originalIV[1] = context->iv[1]; /* Precompute key schedule */ DESKey (context->subkeys, key, encrypt); } /* DES-CBC block update operation. Continues a DES-CBC encryption operation, processing eight-byte message blocks, and updating the context. */ int DES_CBCUpdate (context, output, input, len) DES_CBC_CTX *context; /* context */ unsigned char *output; /* output block */ unsigned char *input; /* input block */ unsigned int len; /* length of input and output blocks */ { UINT4 inputBlock[2], work[2]; unsigned int i; if (len % 8) return (RE_LEN); for (i = 0; i < len/8; i++) { Pack (inputBlock, &input[8*i]); /* Chain if encrypting. */ if (context->encrypt) { work[0] = inputBlock[0] ^ context->iv[0]; work[1] = inputBlock[1] ^ context->iv[1]; } else { work[0] = inputBlock[0]; work[1] = inputBlock[1]; } DESFunction (work, context->subkeys); /* Chain if decrypting, then update IV. */ if (context->encrypt) { context->iv[0] = work[0]; context->iv[1] = work[1]; } else { work[0] ^= context->iv[0]; work[1] ^= context->iv[1]; context->iv[0] = inputBlock[0]; context->iv[1] = inputBlock[1]; } Unpack (&output[8*i], work); } /* Zeroize sensitive information. */ R_memset ((POINTER)inputBlock, 0, sizeof (inputBlock)); R_memset ((POINTER)work, 0, sizeof (work)); return (0); } void DES_CBCRestart (context) DES_CBC_CTX *context; { /* Reset to the original IV */ context->iv[0] = context->originalIV[0]; context->iv[1] = context->originalIV[1]; } /* Initialize context. Caller must zeroize the context when finished. The key has the DES key, input whitener and output whitener concatenated. */ void DESX_CBCInit (context, key, iv, encrypt) DESX_CBC_CTX *context; unsigned char key[24]; /* DES key and whiteners */ unsigned char iv[8]; /* DES initializing vector */ int encrypt; /* encrypt flag (1 = encrypt, 0 = decrypt) */ { /* Copy encrypt flag to context. */ context->encrypt = encrypt; /* Pack initializing vector and whiteners into context. */ Pack (context->iv, iv); Pack (context->inputWhitener, key + 8); Pack (context->outputWhitener, key + 16); /* Save the IV for use in Restart */ context->originalIV[0] = context->iv[0]; context->originalIV[1] = context->iv[1]; /* Precompute key schedule. */ DESKey (context->subkeys, key, encrypt); } /* DESX-CBC block update operation. Continues a DESX-CBC encryption operation, processing eight-byte message blocks, and updating the context. */ int DESX_CBCUpdate (context, output, input, len) DESX_CBC_CTX *context; /* context */ unsigned char *output; /* output block */ unsigned char *input; /* input block */ unsigned int len; /* length of input and output blocks */ { UINT4 inputBlock[2], work[2]; unsigned int i; if (len % 8) return (RE_LEN); for (i = 0; i < len/8; i++) { Pack (inputBlock, &input[8*i]); /* Chain if encrypting, and xor with whitener. */ if (context->encrypt) { work[0] = inputBlock[0] ^ context->iv[0] ^ context->inputWhitener[0]; work[1] = inputBlock[1] ^ context->iv[1] ^ context->inputWhitener[1]; } else { work[0] = inputBlock[0] ^ context->outputWhitener[0]; work[1] = inputBlock[1] ^ context->outputWhitener[1]; } DESFunction (work, context->subkeys); /* Xor with whitener, chain if decrypting, then update IV. */ if (context->encrypt) { work[0] ^= context->outputWhitener[0]; work[1] ^= context->outputWhitener[1]; context->iv[0] = work[0]; context->iv[1] = work[1]; } else { work[0] ^= context->iv[0] ^ context->inputWhitener[0]; work[1] ^= context->iv[1] ^ context->inputWhitener[1]; context->iv[0] = inputBlock[0]; context->iv[1] = inputBlock[1]; } Unpack (&output[8*i], work); } /* Zeroize sensitive information. */ R_memset ((POINTER)inputBlock, 0, sizeof (inputBlock)); R_memset ((POINTER)work, 0, sizeof (work)); return (0); } void DESX_CBCRestart (context) DESX_CBC_CTX *context; { /* Reset to the original IV */ context->iv[0] = context->originalIV[0]; context->iv[1] = context->originalIV[1]; } /* Initialize context. Caller must zeroize the context when finished. */ void DES3_CBCInit(context, key, iv, encrypt) DES3_CBC_CTX *context; /* context */ unsigned char key[24]; /* key */ unsigned char iv[8]; /* initializing vector */ int encrypt; /* encrypt flag (1 = encrypt, 0 = decrypt) */ { /* Copy encrypt flag to context. */ context->encrypt = encrypt; /* Pack initializing vector into context. */ Pack (context->iv, iv); /* Save the IV for use in Restart */ context->originalIV[0] = context->iv[0]; context->originalIV[1] = context->iv[1]; /* Precompute key schedules. */ DESKey (context->subkeys[0], encrypt ? key : &key[16], encrypt); DESKey (context->subkeys[1], &key[8], !encrypt); DESKey (context->subkeys[2], encrypt ? &key[16] : key, encrypt); } int DES3_CBCUpdate (context, output, input, len) DES3_CBC_CTX *context; /* context */ unsigned char *output; /* output block */ unsigned char *input; /* input block */ unsigned int len; /* length of input and output blocks */ { UINT4 inputBlock[2], work[2]; unsigned int i; if (len % 8) return (RE_LEN); for (i = 0; i < len/8; i++) { Pack (inputBlock, &input[8*i]); /* Chain if encrypting. */ if (context->encrypt) { work[0] = inputBlock[0] ^ context->iv[0]; work[1] = inputBlock[1] ^ context->iv[1]; } else { work[0] = inputBlock[0]; work[1] = inputBlock[1]; } DESFunction (work, context->subkeys[0]); DESFunction (work, context->subkeys[1]); DESFunction (work, context->subkeys[2]); /* Chain if decrypting, then update IV. */ if (context->encrypt) { context->iv[0] = work[0]; context->iv[1] = work[1]; } else { work[0] ^= context->iv[0]; work[1] ^= context->iv[1]; context->iv[0] = inputBlock[0]; context->iv[1] = inputBlock[1]; } Unpack (&output[8*i], work); } /* Zeroize sensitive information. */ R_memset ((POINTER)inputBlock, 0, sizeof (inputBlock)); R_memset ((POINTER)work, 0, sizeof (work)); return (0); } void DES3_CBCRestart (context) DES3_CBC_CTX *context; { /* Reset to the original IV */ context->iv[0] = context->originalIV[0]; context->iv[1] = context->originalIV[1]; } static void Pack (into, outof) UINT4 *into; unsigned char *outof; { *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); } static void Unpack (into, outof) unsigned char *into; UINT4 *outof; { *into++ = (unsigned char)((*outof >> 24) & 0xffL); *into++ = (unsigned char)((*outof >> 16) & 0xffL); *into++ = (unsigned char)((*outof >> 8) & 0xffL); *into++ = (unsigned char)( *outof++ & 0xffL); *into++ = (unsigned char)((*outof >> 24) & 0xffL); *into++ = (unsigned char)((*outof >> 16) & 0xffL); *into++ = (unsigned char)((*outof >> 8) & 0xffL); *into = (unsigned char)( *outof & 0xffL); } static void DESKey (subkeys, key, encrypt) UINT4 subkeys[32]; unsigned char key[8]; int encrypt; { UINT4 kn[32]; int i, j, l, m, n; unsigned char pc1m[56], pcr[56]; for (j = 0; j < 56; j++) { l = PC1[j]; m = l & 07; pc1m[j] = (unsigned char)((key[l >> 3] & BYTE_BIT[m]) ? 1 : 0); } for (i = 0; i < 16; i++) { m = i << 1; n = m + 1; kn[m] = kn[n] = 0L; for (j = 0; j < 28; j++) { l = j + TOTAL_ROTATIONS[i]; if (l < 28) pcr[j] = pc1m[l]; else pcr[j] = pc1m[l - 28]; } for (j = 28; j < 56; j++) { l = j + TOTAL_ROTATIONS[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] |= BIG_BYTE[j]; if (pcr[PC2[j+24]]) kn[n] |= BIG_BYTE[j]; } } CookKey (subkeys, kn, encrypt); /* Zeroize sensitive information. */ R_memset ((POINTER)pc1m, 0, sizeof (pc1m)); R_memset ((POINTER)pcr, 0, sizeof (pcr)); R_memset ((POINTER)kn, 0, sizeof (kn)); } static void CookKey (subkeys, kn, encrypt) UINT4 *subkeys; UINT4 *kn; int encrypt; { UINT4 *cooked, *raw0, *raw1; int increment; unsigned int i; raw1 = kn; cooked = encrypt ? subkeys : &subkeys[30]; increment = encrypt ? 1 : -3; for (i = 0; i < 16; i++, raw1++) { raw0 = raw1++; *cooked = (*raw0 & 0x00fc0000L) << 6; *cooked |= (*raw0 & 0x00000fc0L) << 10; *cooked |= (*raw1 & 0x00fc0000L) >> 10; *cooked++ |= (*raw1 & 0x00000fc0L) >> 6; *cooked = (*raw0 & 0x0003f000L) << 12; *cooked |= (*raw0 & 0x0000003fL) << 16; *cooked |= (*raw1 & 0x0003f000L) >> 4; *cooked |= (*raw1 & 0x0000003fL); cooked += increment; } } static void DESFunction (block, subkeys) UINT4 *block; UINT4 *subkeys; { register UINT4 fval, work, right, left; register int round; left = block[0]; right = block[1]; work = ((left >> 4) ^ right) & 0x0f0f0f0fL; right ^= work; left ^= (work << 4); work = ((left >> 16) ^ right) & 0x0000ffffL; right ^= work; left ^= (work << 16); work = ((right >> 2) ^ left) & 0x33333333L; left ^= work; right ^= (work << 2); work = ((right >> 8) ^ left) & 0x00ff00ffL; left ^= work; right ^= (work << 8); right = ((right << 1) | ((right >> 31) & 1L)) & 0xffffffffL; work = (left ^ right) & 0xaaaaaaaaL; left ^= work; right ^= work; left = ((left << 1) | ((left >> 31) & 1L)) & 0xffffffffL; for (round = 0; round < 8; round++) { work = (right << 28) | (right >> 4); work ^= *subkeys++; fval = SP7[ work & 0x3fL]; fval |= SP5[(work >> 8) & 0x3fL]; fval |= SP3[(work >> 16) & 0x3fL]; fval |= SP1[(work >> 24) & 0x3fL]; work = right ^ *subkeys++; fval |= SP8[ work & 0x3fL]; fval |= SP6[(work >> 8) & 0x3fL]; fval |= SP4[(work >> 16) & 0x3fL]; fval |= SP2[(work >> 24) & 0x3fL]; left ^= fval; work = (left << 28) | (left >> 4); work ^= *subkeys++; fval = SP7[ work & 0x3fL]; fval |= SP5[(work >> 8) & 0x3fL]; fval |= SP3[(work >> 16) & 0x3fL]; fval |= SP1[(work >> 24) & 0x3fL]; work = left ^ *subkeys++; 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 = (left ^ right) & 0xaaaaaaaaL; left ^= work; right ^= work; left = (left << 31) | (left >> 1); work = ((left >> 8) ^ right) & 0x00ff00ffL; right ^= work; left ^= (work << 8); work = ((left >> 2) ^ right) & 0x33333333L; right ^= work; left ^= (work << 2); work = ((right >> 16) ^ left) & 0x0000ffffL; left ^= work; right ^= (work << 16); work = ((right >> 4) ^ left) & 0x0f0f0f0fL; left ^= work; right ^= (work << 4); *block++ = right; *block = left; }