/* * alg2268.c - implementation of the algorithm in RFC 2268 * * This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ #ifdef FREEBL_NO_DEPEND #include "stubs.h" #endif #include "blapi.h" #include "secerr.h" #ifdef XP_UNIX_XXX #include /* for ptrdiff_t */ #endif /* ** RC2 symmetric block cypher */ typedef SECStatus (rc2Func)(RC2Context *cx, unsigned char *output, const unsigned char *input, unsigned int inputLen); /* forward declarations */ static rc2Func rc2_EncryptECB; static rc2Func rc2_DecryptECB; static rc2Func rc2_EncryptCBC; static rc2Func rc2_DecryptCBC; typedef union { PRUint32 l[2]; PRUint16 s[4]; PRUint8 b[8]; } RC2Block; struct RC2ContextStr { union { PRUint8 Kb[128]; PRUint16 Kw[64]; } u; RC2Block iv; rc2Func *enc; rc2Func *dec; }; #define B u.Kb #define K u.Kw #define BYTESWAP(x) ((x) << 8 | (x) >> 8) #define SWAPK(i) cx->K[i] = (tmpS = cx->K[i], BYTESWAP(tmpS)) #define RC2_BLOCK_SIZE 8 #define LOAD_HARD(R) \ R[0] = (PRUint16)input[1] << 8 | input[0]; \ R[1] = (PRUint16)input[3] << 8 | input[2]; \ R[2] = (PRUint16)input[5] << 8 | input[4]; \ R[3] = (PRUint16)input[7] << 8 | input[6]; #define LOAD_EASY(R) \ R[0] = ((PRUint16 *)input)[0]; \ R[1] = ((PRUint16 *)input)[1]; \ R[2] = ((PRUint16 *)input)[2]; \ R[3] = ((PRUint16 *)input)[3]; #define STORE_HARD(R) \ output[0] = (PRUint8)(R[0]); output[1] = (PRUint8)(R[0] >> 8); \ output[2] = (PRUint8)(R[1]); output[3] = (PRUint8)(R[1] >> 8); \ output[4] = (PRUint8)(R[2]); output[5] = (PRUint8)(R[2] >> 8); \ output[6] = (PRUint8)(R[3]); output[7] = (PRUint8)(R[3] >> 8); #define STORE_EASY(R) \ ((PRUint16 *)output)[0] = R[0]; \ ((PRUint16 *)output)[1] = R[1]; \ ((PRUint16 *)output)[2] = R[2]; \ ((PRUint16 *)output)[3] = R[3]; #if defined (NSS_X86_OR_X64) #define LOAD(R) LOAD_EASY(R) #define STORE(R) STORE_EASY(R) #elif !defined(IS_LITTLE_ENDIAN) #define LOAD(R) LOAD_HARD(R) #define STORE(R) STORE_HARD(R) #else #define LOAD(R) if ((ptrdiff_t)input & 1) { LOAD_HARD(R) } else { LOAD_EASY(R) } #define STORE(R) if ((ptrdiff_t)input & 1) { STORE_HARD(R) } else { STORE_EASY(R) } #endif static const PRUint8 S[256] = { 0331,0170,0371,0304,0031,0335,0265,0355,0050,0351,0375,0171,0112,0240,0330,0235, 0306,0176,0067,0203,0053,0166,0123,0216,0142,0114,0144,0210,0104,0213,0373,0242, 0027,0232,0131,0365,0207,0263,0117,0023,0141,0105,0155,0215,0011,0201,0175,0062, 0275,0217,0100,0353,0206,0267,0173,0013,0360,0225,0041,0042,0134,0153,0116,0202, 0124,0326,0145,0223,0316,0140,0262,0034,0163,0126,0300,0024,0247,0214,0361,0334, 0022,0165,0312,0037,0073,0276,0344,0321,0102,0075,0324,0060,0243,0074,0266,0046, 0157,0277,0016,0332,0106,0151,0007,0127,0047,0362,0035,0233,0274,0224,0103,0003, 0370,0021,0307,0366,0220,0357,0076,0347,0006,0303,0325,0057,0310,0146,0036,0327, 0010,0350,0352,0336,0200,0122,0356,0367,0204,0252,0162,0254,0065,0115,0152,0052, 0226,0032,0322,0161,0132,0025,0111,0164,0113,0237,0320,0136,0004,0030,0244,0354, 0302,0340,0101,0156,0017,0121,0313,0314,0044,0221,0257,0120,0241,0364,0160,0071, 0231,0174,0072,0205,0043,0270,0264,0172,0374,0002,0066,0133,0045,0125,0227,0061, 0055,0135,0372,0230,0343,0212,0222,0256,0005,0337,0051,0020,0147,0154,0272,0311, 0323,0000,0346,0317,0341,0236,0250,0054,0143,0026,0001,0077,0130,0342,0211,0251, 0015,0070,0064,0033,0253,0063,0377,0260,0273,0110,0014,0137,0271,0261,0315,0056, 0305,0363,0333,0107,0345,0245,0234,0167,0012,0246,0040,0150,0376,0177,0301,0255 }; RC2Context * RC2_AllocateContext(void) { return PORT_ZNew(RC2Context); } SECStatus RC2_InitContext(RC2Context *cx, const unsigned char *key, unsigned int len, const unsigned char *input, int mode, unsigned int efLen8, unsigned int unused) { PRUint8 *L,*L2; int i; #if !defined(IS_LITTLE_ENDIAN) PRUint16 tmpS; #endif PRUint8 tmpB; if (!key || !cx || !len || len > (sizeof cx->B) || efLen8 > (sizeof cx->B)) { PORT_SetError(SEC_ERROR_INVALID_ARGS); return SECFailure; } if (mode == NSS_RC2) { /* groovy */ } else if (mode == NSS_RC2_CBC) { if (!input) { PORT_SetError(SEC_ERROR_INVALID_ARGS); return SECFailure; } } else { PORT_SetError(SEC_ERROR_INVALID_ARGS); return SECFailure; } if (mode == NSS_RC2_CBC) { cx->enc = & rc2_EncryptCBC; cx->dec = & rc2_DecryptCBC; LOAD(cx->iv.s); } else { cx->enc = & rc2_EncryptECB; cx->dec = & rc2_DecryptECB; } /* Step 0. Copy key into table. */ memcpy(cx->B, key, len); /* Step 1. Compute all values to the right of the key. */ L2 = cx->B; L = L2 + len; tmpB = L[-1]; for (i = (sizeof cx->B) - len; i > 0; --i) { *L++ = tmpB = S[ (PRUint8)(tmpB + *L2++) ]; } /* step 2. Adjust left most byte of effective key. */ i = (sizeof cx->B) - efLen8; L = cx->B + i; *L = tmpB = S[*L]; /* mask is always 0xff */ /* step 3. Recompute all values to the left of effective key. */ L2 = --L + efLen8; while(L >= cx->B) { *L-- = tmpB = S[ tmpB ^ *L2-- ]; } #if !defined(IS_LITTLE_ENDIAN) for (i = 63; i >= 0; --i) { SWAPK(i); /* candidate for unrolling */ } #endif return SECSuccess; } /* ** Create a new RC2 context suitable for RC2 encryption/decryption. ** "key" raw key data ** "len" the number of bytes of key data ** "iv" is the CBC initialization vector (if mode is NSS_RC2_CBC) ** "mode" one of NSS_RC2 or NSS_RC2_CBC ** "effectiveKeyLen" in bytes, not bits. ** ** When mode is set to NSS_RC2_CBC the RC2 cipher is run in "cipher block ** chaining" mode. */ RC2Context * RC2_CreateContext(const unsigned char *key, unsigned int len, const unsigned char *iv, int mode, unsigned efLen8) { RC2Context *cx = PORT_ZNew(RC2Context); if (cx) { SECStatus rv = RC2_InitContext(cx, key, len, iv, mode, efLen8, 0); if (rv != SECSuccess) { RC2_DestroyContext(cx, PR_TRUE); cx = NULL; } } return cx; } /* ** Destroy an RC2 encryption/decryption context. ** "cx" the context ** "freeit" if PR_TRUE then free the object as well as its sub-objects */ void RC2_DestroyContext(RC2Context *cx, PRBool freeit) { if (cx) { memset(cx, 0, sizeof *cx); if (freeit) { PORT_Free(cx); } } } #define ROL(x,k) (x << k | x >> (16-k)) #define MIX(j) \ R0 = R0 + cx->K[ 4*j+0] + (R3 & R2) + (~R3 & R1); R0 = ROL(R0,1);\ R1 = R1 + cx->K[ 4*j+1] + (R0 & R3) + (~R0 & R2); R1 = ROL(R1,2);\ R2 = R2 + cx->K[ 4*j+2] + (R1 & R0) + (~R1 & R3); R2 = ROL(R2,3);\ R3 = R3 + cx->K[ 4*j+3] + (R2 & R1) + (~R2 & R0); R3 = ROL(R3,5) #define MASH \ R0 = R0 + cx->K[R3 & 63];\ R1 = R1 + cx->K[R0 & 63];\ R2 = R2 + cx->K[R1 & 63];\ R3 = R3 + cx->K[R2 & 63] /* Encrypt one block */ static void rc2_Encrypt1Block(RC2Context *cx, RC2Block *output, RC2Block *input) { register PRUint16 R0, R1, R2, R3; /* step 1. Initialize input. */ R0 = input->s[0]; R1 = input->s[1]; R2 = input->s[2]; R3 = input->s[3]; /* step 2. Expand Key (already done, in context) */ /* step 3. j = 0 */ /* step 4. Perform 5 mixing rounds. */ MIX(0); MIX(1); MIX(2); MIX(3); MIX(4); /* step 5. Perform 1 mashing round. */ MASH; /* step 6. Perform 6 mixing rounds. */ MIX(5); MIX(6); MIX(7); MIX(8); MIX(9); MIX(10); /* step 7. Perform 1 mashing round. */ MASH; /* step 8. Perform 5 mixing rounds. */ MIX(11); MIX(12); MIX(13); MIX(14); MIX(15); /* output results */ output->s[0] = R0; output->s[1] = R1; output->s[2] = R2; output->s[3] = R3; } #define ROR(x,k) (x >> k | x << (16-k)) #define R_MIX(j) \ R3 = ROR(R3,5); R3 = R3 - cx->K[ 4*j+3] - (R2 & R1) - (~R2 & R0); \ R2 = ROR(R2,3); R2 = R2 - cx->K[ 4*j+2] - (R1 & R0) - (~R1 & R3); \ R1 = ROR(R1,2); R1 = R1 - cx->K[ 4*j+1] - (R0 & R3) - (~R0 & R2); \ R0 = ROR(R0,1); R0 = R0 - cx->K[ 4*j+0] - (R3 & R2) - (~R3 & R1) #define R_MASH \ R3 = R3 - cx->K[R2 & 63];\ R2 = R2 - cx->K[R1 & 63];\ R1 = R1 - cx->K[R0 & 63];\ R0 = R0 - cx->K[R3 & 63] /* Encrypt one block */ static void rc2_Decrypt1Block(RC2Context *cx, RC2Block *output, RC2Block *input) { register PRUint16 R0, R1, R2, R3; /* step 1. Initialize input. */ R0 = input->s[0]; R1 = input->s[1]; R2 = input->s[2]; R3 = input->s[3]; /* step 2. Expand Key (already done, in context) */ /* step 3. j = 63 */ /* step 4. Perform 5 r_mixing rounds. */ R_MIX(15); R_MIX(14); R_MIX(13); R_MIX(12); R_MIX(11); /* step 5. Perform 1 r_mashing round. */ R_MASH; /* step 6. Perform 6 r_mixing rounds. */ R_MIX(10); R_MIX(9); R_MIX(8); R_MIX(7); R_MIX(6); R_MIX(5); /* step 7. Perform 1 r_mashing round. */ R_MASH; /* step 8. Perform 5 r_mixing rounds. */ R_MIX(4); R_MIX(3); R_MIX(2); R_MIX(1); R_MIX(0); /* output results */ output->s[0] = R0; output->s[1] = R1; output->s[2] = R2; output->s[3] = R3; } static SECStatus rc2_EncryptECB(RC2Context *cx, unsigned char *output, const unsigned char *input, unsigned int inputLen) { RC2Block iBlock; while (inputLen > 0) { LOAD(iBlock.s) rc2_Encrypt1Block(cx, &iBlock, &iBlock); STORE(iBlock.s) output += RC2_BLOCK_SIZE; input += RC2_BLOCK_SIZE; inputLen -= RC2_BLOCK_SIZE; } return SECSuccess; } static SECStatus rc2_DecryptECB(RC2Context *cx, unsigned char *output, const unsigned char *input, unsigned int inputLen) { RC2Block iBlock; while (inputLen > 0) { LOAD(iBlock.s) rc2_Decrypt1Block(cx, &iBlock, &iBlock); STORE(iBlock.s) output += RC2_BLOCK_SIZE; input += RC2_BLOCK_SIZE; inputLen -= RC2_BLOCK_SIZE; } return SECSuccess; } static SECStatus rc2_EncryptCBC(RC2Context *cx, unsigned char *output, const unsigned char *input, unsigned int inputLen) { RC2Block iBlock; while (inputLen > 0) { LOAD(iBlock.s) iBlock.l[0] ^= cx->iv.l[0]; iBlock.l[1] ^= cx->iv.l[1]; rc2_Encrypt1Block(cx, &iBlock, &iBlock); cx->iv = iBlock; STORE(iBlock.s) output += RC2_BLOCK_SIZE; input += RC2_BLOCK_SIZE; inputLen -= RC2_BLOCK_SIZE; } return SECSuccess; } static SECStatus rc2_DecryptCBC(RC2Context *cx, unsigned char *output, const unsigned char *input, unsigned int inputLen) { RC2Block iBlock; RC2Block oBlock; while (inputLen > 0) { LOAD(iBlock.s) rc2_Decrypt1Block(cx, &oBlock, &iBlock); oBlock.l[0] ^= cx->iv.l[0]; oBlock.l[1] ^= cx->iv.l[1]; cx->iv = iBlock; STORE(oBlock.s) output += RC2_BLOCK_SIZE; input += RC2_BLOCK_SIZE; inputLen -= RC2_BLOCK_SIZE; } return SECSuccess; } /* ** Perform RC2 encryption. ** "cx" the context ** "output" the output buffer to store the encrypted data. ** "outputLen" how much data is stored in "output". Set by the routine ** after some data is stored in output. ** "maxOutputLen" the maximum amount of data that can ever be ** stored in "output" ** "input" the input data ** "inputLen" the amount of input data */ SECStatus RC2_Encrypt(RC2Context *cx, unsigned char *output, unsigned int *outputLen, unsigned int maxOutputLen, const unsigned char *input, unsigned int inputLen) { SECStatus rv = SECSuccess; if (inputLen) { if (inputLen % RC2_BLOCK_SIZE) { PORT_SetError(SEC_ERROR_INPUT_LEN); return SECFailure; } if (maxOutputLen < inputLen) { PORT_SetError(SEC_ERROR_OUTPUT_LEN); return SECFailure; } rv = (*cx->enc)(cx, output, input, inputLen); } if (rv == SECSuccess) { *outputLen = inputLen; } return rv; } /* ** Perform RC2 decryption. ** "cx" the context ** "output" the output buffer to store the decrypted data. ** "outputLen" how much data is stored in "output". Set by the routine ** after some data is stored in output. ** "maxOutputLen" the maximum amount of data that can ever be ** stored in "output" ** "input" the input data ** "inputLen" the amount of input data */ SECStatus RC2_Decrypt(RC2Context *cx, unsigned char *output, unsigned int *outputLen, unsigned int maxOutputLen, const unsigned char *input, unsigned int inputLen) { SECStatus rv = SECSuccess; if (inputLen) { if (inputLen % RC2_BLOCK_SIZE) { PORT_SetError(SEC_ERROR_INPUT_LEN); return SECFailure; } if (maxOutputLen < inputLen) { PORT_SetError(SEC_ERROR_OUTPUT_LEN); return SECFailure; } rv = (*cx->dec)(cx, output, input, inputLen); } if (rv == SECSuccess) { *outputLen = inputLen; } return rv; }