/* This is an independent implementation of the encryption algorithm: */ /* */ /* Twofish by Bruce Schneier and colleagues */ /* */ /* which is a candidate algorithm in the Advanced Encryption Standard */ /* programme of the US National Institute of Standards and Technology. */ /* */ /* Copyright in this implementation is held by Dr B R Gladman but I */ /* hereby give permission for its free direct or derivative use subject */ /* to acknowledgment of its origin and compliance with any conditions */ /* that the originators of t he algorithm place on its exploitation. */ /* */ /* My thanks to Doug Whiting and Niels Ferguson for comments that led */ /* to improvements in this implementation. */ /* */ /* Dr Brian Gladman (gladman@seven77.demon.co.uk) 14th January 1999 */ /* modified in order to use the libmcrypt API by Nikos Mavroyanopoulos * All modifications are placed under the license of libmcrypt. */ /* $Id: twofish.c,v 1.16 2003/01/19 17:48:27 nmav Exp $ */ /* Timing data for Twofish (twofish.c) 128 bit key: Key Setup: 8414 cycles Encrypt: 376 cycles = 68.1 mbits/sec Decrypt: 374 cycles = 68.4 mbits/sec Mean: 375 cycles = 68.3 mbits/sec 192 bit key: Key Setup: 11628 cycles Encrypt: 376 cycles = 68.1 mbits/sec Decrypt: 374 cycles = 68.4 mbits/sec Mean: 375 cycles = 68.3 mbits/sec 256 bit key: Key Setup: 15457 cycles Encrypt: 381 cycles = 67.2 mbits/sec Decrypt: 374 cycles = 68.4 mbits/sec Mean: 378 cycles = 67.8 mbits/sec */ #include #include #include "twofish.h" #define _mcrypt_set_key twofish_LTX__mcrypt_set_key #define _mcrypt_encrypt twofish_LTX__mcrypt_encrypt #define _mcrypt_decrypt twofish_LTX__mcrypt_decrypt #define _mcrypt_get_size twofish_LTX__mcrypt_get_size #define _mcrypt_get_block_size twofish_LTX__mcrypt_get_block_size #define _is_block_algorithm twofish_LTX__is_block_algorithm #define _mcrypt_get_key_size twofish_LTX__mcrypt_get_key_size #define _mcrypt_get_supported_key_sizes twofish_LTX__mcrypt_get_supported_key_sizes #define _mcrypt_get_algorithms_name twofish_LTX__mcrypt_get_algorithms_name #define _mcrypt_self_test twofish_LTX__mcrypt_self_test #define _mcrypt_algorithm_version twofish_LTX__mcrypt_algorithm_version /* word32 k_len; * word32 l_key[40]; * word32 s_key[4]; */ /* Extract byte from a 32 bit quantity (little endian notation) */ #define byte(x,n) ((byte)((x) >> (8 * n))) /* finite field arithmetic for GF(2**8) with the modular */ /* polynomial x^8 + x^6 + x^5 + x^3 + 1 (0x169) */ #define G_M 0x0169 byte tab_5b[4] = { 0, G_M >> 2, G_M >> 1, (G_M >> 1) ^ (G_M >> 2) }; byte tab_ef[4] = { 0, (G_M >> 1) ^ (G_M >> 2), G_M >> 1, G_M >> 2 }; #define ffm_01(x) (x) #define ffm_5b(x) ((x) ^ ((x) >> 2) ^ tab_5b[(x) & 3]) #define ffm_ef(x) ((x) ^ ((x) >> 1) ^ ((x) >> 2) ^ tab_ef[(x) & 3]) byte ror4[16] = { 0, 8, 1, 9, 2, 10, 3, 11, 4, 12, 5, 13, 6, 14, 7, 15 }; byte ashx[16] = { 0, 9, 2, 11, 4, 13, 6, 15, 8, 1, 10, 3, 12, 5, 14, 7 }; byte qt0[2][16] = { {8, 1, 7, 13, 6, 15, 3, 2, 0, 11, 5, 9, 14, 12, 10, 4} , {2, 8, 11, 13, 15, 7, 6, 14, 3, 1, 9, 4, 0, 10, 12, 5} }; byte qt1[2][16] = { {14, 12, 11, 8, 1, 2, 3, 5, 15, 4, 10, 6, 7, 0, 9, 13} , {1, 14, 2, 11, 4, 12, 3, 7, 6, 13, 10, 5, 15, 9, 0, 8} }; byte qt2[2][16] = { {11, 10, 5, 14, 6, 13, 9, 0, 12, 8, 15, 3, 2, 4, 7, 1} , {4, 12, 7, 5, 1, 6, 9, 10, 0, 14, 13, 8, 2, 11, 3, 15} }; byte qt3[2][16] = { {13, 7, 15, 4, 1, 2, 6, 14, 9, 11, 3, 0, 8, 5, 12, 10} , {11, 9, 5, 1, 12, 3, 13, 14, 6, 4, 7, 15, 2, 0, 8, 10} }; byte qp(const word32 n, const byte x) { byte a0, a1, a2, a3, a4, b0, b1, b2, b3, b4; a0 = x >> 4; b0 = x & 15; a1 = a0 ^ b0; b1 = ror4[b0] ^ ashx[a0]; a2 = qt0[n][a1]; b2 = qt1[n][b1]; a3 = a2 ^ b2; b3 = ror4[b2] ^ ashx[a2]; a4 = qt2[n][a3]; b4 = qt3[n][b3]; return (b4 << 4) | a4; } #ifdef Q_TABLES #define q(n,x) pkey->q_tab[n][x] void gen_qtab(TWI * pkey) { word32 i; for (i = 0; i < 256; ++i) { q(0, i) = qp(0, (byte) i); q(1, i) = qp(1, (byte) i); } } #else #define q(n,x) qp(n, x) #endif #ifdef M_TABLE void gen_mtab(TWI * pkey) { word32 i, f01, f5b, fef; for (i = 0; i < 256; ++i) { f01 = q(1, i); f5b = ffm_5b(f01); fef = ffm_ef(f01); pkey->m_tab[0][i] = f01 + (f5b << 8) + (fef << 16) + (fef << 24); pkey->m_tab[2][i] = f5b + (fef << 8) + (f01 << 16) + (fef << 24); f01 = q(0, i); f5b = ffm_5b(f01); fef = ffm_ef(f01); pkey->m_tab[1][i] = fef + (fef << 8) + (f5b << 16) + (f01 << 24); pkey->m_tab[3][i] = f5b + (f01 << 8) + (fef << 16) + (f5b << 24); } } #define mds(n,x) pkey->m_tab[n][x] #else #define fm_00 ffm_01 #define fm_10 ffm_5b #define fm_20 ffm_ef #define fm_30 ffm_ef #define q_0(x) q(1,x) #define fm_01 ffm_ef #define fm_11 ffm_ef #define fm_21 ffm_5b #define fm_31 ffm_01 #define q_1(x) q(0,x) #define fm_02 ffm_5b #define fm_12 ffm_ef #define fm_22 ffm_01 #define fm_32 ffm_ef #define q_2(x) q(1,x) #define fm_03 ffm_5b #define fm_13 ffm_01 #define fm_23 ffm_ef #define fm_33 ffm_5b #define q_3(x) q(0,x) #define f_0(n,x) ((word32)fm_0##n(x)) #define f_1(n,x) ((word32)fm_1##n(x) << 8) #define f_2(n,x) ((word32)fm_2##n(x) << 16) #define f_3(n,x) ((word32)fm_3##n(x) << 24) #define mds(n,x) f_0(n,q_##n(x)) ^ f_1(n,q_##n(x)) ^ f_2(n,q_##n(x)) ^ f_3(n,q_##n(x)) #endif word32 h_fun(TWI * pkey, const word32 x, const word32 key[]) { word32 b0, b1, b2, b3; #ifndef M_TABLE word32 m5b_b0, m5b_b1, m5b_b2, m5b_b3; word32 mef_b0, mef_b1, mef_b2, mef_b3; #endif b0 = byte(x, 0); b1 = byte(x, 1); b2 = byte(x, 2); b3 = byte(x, 3); switch (pkey->k_len) { case 4: b0 = q(1, b0) ^ byte(key[3], 0); b1 = q(0, b1) ^ byte(key[3], 1); b2 = q(0, b2) ^ byte(key[3], 2); b3 = q(1, b3) ^ byte(key[3], 3); case 3: b0 = q(1, b0) ^ byte(key[2], 0); b1 = q(1, b1) ^ byte(key[2], 1); b2 = q(0, b2) ^ byte(key[2], 2); b3 = q(0, b3) ^ byte(key[2], 3); case 2: b0 = q(0, q(0, b0) ^ byte(key[1], 0)) ^ byte(key[0], 0); b1 = q(0, q(1, b1) ^ byte(key[1], 1)) ^ byte(key[0], 1); b2 = q(1, q(0, b2) ^ byte(key[1], 2)) ^ byte(key[0], 2); b3 = q(1, q(1, b3) ^ byte(key[1], 3)) ^ byte(key[0], 3); } #ifdef M_TABLE return mds(0, b0) ^ mds(1, b1) ^ mds(2, b2) ^ mds(3, b3); #else b0 = q(1, b0); b1 = q(0, b1); b2 = q(1, b2); b3 = q(0, b3); m5b_b0 = ffm_5b(b0); m5b_b1 = ffm_5b(b1); m5b_b2 = ffm_5b(b2); m5b_b3 = ffm_5b(b3); mef_b0 = ffm_ef(b0); mef_b1 = ffm_ef(b1); mef_b2 = ffm_ef(b2); mef_b3 = ffm_ef(b3); b0 ^= mef_b1 ^ m5b_b2 ^ m5b_b3; b3 ^= m5b_b0 ^ mef_b1 ^ mef_b2; b2 ^= mef_b0 ^ m5b_b1 ^ mef_b3; b1 ^= mef_b0 ^ mef_b2 ^ m5b_b3; return b0 | (b3 << 8) | (b2 << 16) | (b1 << 24); #endif } #ifdef MK_TABLE #define q20(x) q(0,q(0,x) ^ byte(key[1],0)) ^ byte(key[0],0) #define q21(x) q(0,q(1,x) ^ byte(key[1],1)) ^ byte(key[0],1) #define q22(x) q(1,q(0,x) ^ byte(key[1],2)) ^ byte(key[0],2) #define q23(x) q(1,q(1,x) ^ byte(key[1],3)) ^ byte(key[0],3) #define q30(x) q(0,q(0,q(1, x) ^ byte(key[2],0)) ^ byte(key[1],0)) ^ byte(key[0],0) #define q31(x) q(0,q(1,q(1, x) ^ byte(key[2],1)) ^ byte(key[1],1)) ^ byte(key[0],1) #define q32(x) q(1,q(0,q(0, x) ^ byte(key[2],2)) ^ byte(key[1],2)) ^ byte(key[0],2) #define q33(x) q(1,q(1,q(0, x) ^ byte(key[2],3)) ^ byte(key[1],3)) ^ byte(key[0],3) #define q40(x) q(0,q(0,q(1, q(1, x) ^ byte(key[3],0)) ^ byte(key[2],0)) ^ byte(key[1],0)) ^ byte(key[0],0) #define q41(x) q(0,q(1,q(1, q(0, x) ^ byte(key[3],1)) ^ byte(key[2],1)) ^ byte(key[1],1)) ^ byte(key[0],1) #define q42(x) q(1,q(0,q(0, q(0, x) ^ byte(key[3],2)) ^ byte(key[2],2)) ^ byte(key[1],2)) ^ byte(key[0],2) #define q43(x) q(1,q(1,q(0, q(1, x) ^ byte(key[3],3)) ^ byte(key[2],3)) ^ byte(key[1],3)) ^ byte(key[0],3) void gen_mk_tab(TWI * pkey, word32 key[]) { word32 i; byte by; switch (pkey->k_len) { case 2: for (i = 0; i < 256; ++i) { by = (byte) i; #ifdef ONE_STEP pkey->mk_tab[0][i] = mds(0, q20(by)); pkey->mk_tab[1][i] = mds(1, q21(by)); pkey->mk_tab[2][i] = mds(2, q22(by)); pkey->mk_tab[3][i] = mds(3, q23(by)); #else pkey->sb[0][i] = q20(by); pkey->sb[1][i] = q21(by); pkey->sb[2][i] = q22(by); pkey->sb[3][i] = q23(by); #endif } break; case 3: for (i = 0; i < 256; ++i) { by = (byte) i; #ifdef ONE_STEP pkey->mk_tab[0][i] = mds(0, q30(by)); pkey->mk_tab[1][i] = mds(1, q31(by)); pkey->mk_tab[2][i] = mds(2, q32(by)); pkey->mk_tab[3][i] = mds(3, q33(by)); #else pkey->sb[0][i] = q30(by); pkey->sb[1][i] = q31(by); pkey->sb[2][i] = q32(by); pkey->sb[3][i] = q33(by); #endif } break; case 4: for (i = 0; i < 256; ++i) { by = (byte) i; #ifdef ONE_STEP pkey->mk_tab[0][i] = mds(0, q40(by)); pkey->mk_tab[1][i] = mds(1, q41(by)); pkey->mk_tab[2][i] = mds(2, q42(by)); pkey->mk_tab[3][i] = mds(3, q43(by)); #else pkey->sb[0][i] = q40(by); pkey->sb[1][i] = q41(by); pkey->sb[2][i] = q42(by); pkey->sb[3][i] = q43(by); #endif } } } #ifdef ONE_STEP #define g0_fun(x) ( pkey->mk_tab[0][byte(x,0)] ^ pkey->mk_tab[1][byte(x,1)] \ ^ pkey->mk_tab[2][byte(x,2)] ^ pkey->mk_tab[3][byte(x,3)] ) #define g1_fun(x) ( pkey->mk_tab[0][byte(x,3)] ^ pkey->mk_tab[1][byte(x,0)] \ ^ pkey->mk_tab[2][byte(x,1)] ^ pkey->mk_tab[3][byte(x,2)] ) #else #define g0_fun(x) ( mds(0, pkey->sb[0][byte(x,0)]) ^ mds(1, pkey->sb[1][byte(x,1)]) \ ^ mds(2, pkey->sb[2][byte(x,2)]) ^ mds(3, pkey->sb[3][byte(x,3)]) ) #define g1_fun(x) ( mds(0, pkey->sb[0][byte(x,3)]) ^ mds(1, pkey->sb[1][byte(x,0)]) \ ^ mds(2, pkey->sb[2][byte(x,1)]) ^ mds(3, pkey->sb[3][byte(x,2)]) ) #endif #else #define g0_fun(x) h_fun(pkey, x,pkey->s_key) #define g1_fun(x) h_fun(pkey, rotl32(x,8),pkey->s_key) #endif /* The (12,8) Reed Soloman code has the generator polynomial g(x) = x^4 + (a + 1/a) * x^3 + a * x^2 + (a + 1/a) * x + 1 where the coefficients are in the finite field GF(2^8) with a modular polynomial a^8 + a^6 + a^3 + a^2 + 1. To generate the remainder we have to start with a 12th order polynomial with our eight input bytes as the coefficients of the 4th to 11th terms. That is: m[7] * x^11 + m[6] * x^10 ... + m[0] * x^4 + 0 * x^3 +... + 0 We then multiply the generator polynomial by m[7] * x^7 and subtract it - xor in GF(2^8) - from the above to eliminate the x^7 term (the artihmetic on the coefficients is done in GF(2^8). We then multiply the generator polynomial by x^6 * coeff(x^10) and use this to remove the x^10 term. We carry on in this way until the x^4 term is removed so that we are left with: r[3] * x^3 + r[2] * x^2 + r[1] 8 x^1 + r[0] which give the resulting 4 bytes of the remainder. This is equivalent to the matrix multiplication in the Twofish description but much faster to implement. */ #define G_MOD 0x0000014d word32 mds_rem(word32 p0, word32 p1) { word32 i, t, u; for (i = 0; i < 8; ++i) { t = p1 >> 24; /* get most significant coefficient */ p1 = (p1 << 8) | (p0 >> 24); p0 <<= 8; /* shift others up */ /* multiply t by a (the primitive element - i.e. left shift) */ u = (t << 1); if (t & 0x80) /* subtract modular polynomial on overflow */ u ^= G_MOD; p1 ^= t ^ (u << 16); /* remove t * (a * x^2 + 1) */ u ^= (t >> 1); /* form u = a * t + t / a = t * (a + 1 / a); */ if (t & 0x01) /* add the modular polynomial on underflow */ u ^= G_MOD >> 1; p1 ^= (u << 24) | (u << 8); /* remove t * (a + 1/a) * (x^3 + x) */ } return p1; } /* initialise the key schedule from the user supplied key */ WIN32DLL_DEFINE int _mcrypt_set_key(TWI * pkey, const word32 in_key[], const word32 key_len) { word32 i, a, b, me_key[4], mo_key[4]; #ifdef Q_TABLES pkey->qt_gen = 0; if (!pkey->qt_gen) { gen_qtab(pkey); pkey->qt_gen = 1; } #endif #ifdef M_TABLE pkey->mt_gen = 0; if (!pkey->mt_gen) { gen_mtab(pkey); pkey->mt_gen = 1; } #endif pkey->k_len = (key_len * 8) / 64; /* 2, 3 or 4 */ for (i = 0; i < pkey->k_len; ++i) { #ifdef WORDS_BIGENDIAN a = byteswap32(in_key[i + i]); me_key[i] = a; b = byteswap32(in_key[i + i + 1]); #else a = in_key[i + i]; me_key[i] = a; b = in_key[i + i + 1]; #endif mo_key[i] = b; pkey->s_key[pkey->k_len - i - 1] = mds_rem(a, b); } for (i = 0; i < 40; i += 2) { a = 0x01010101 * i; b = a + 0x01010101; a = h_fun(pkey, a, me_key); b = rotl32(h_fun(pkey, b, mo_key), 8); pkey->l_key[i] = a + b; pkey->l_key[i + 1] = rotl32(a + 2 * b, 9); } #ifdef MK_TABLE gen_mk_tab(pkey, pkey->s_key); #endif return 0; } /* This macro was moved to an inline function, because it * was breaking some compilers. */ inline static void f_rnd(int i, word32* blk, TWI* pkey, word32 t0, word32 t1) { t1 = g1_fun(blk[1]); t0 = g0_fun(blk[0]); blk[2] = rotr32(blk[2] ^ (t0 + t1 + pkey->l_key[4 * (i) + 8]), 1); blk[3] = rotl32(blk[3], 1) ^ (t0 + 2 * t1 + pkey->l_key[4 * (i) + 9]); t1 = g1_fun(blk[3]); t0 = g0_fun(blk[2]); blk[0] = rotr32(blk[0] ^ (t0 + t1 + pkey->l_key[4 * (i) + 10]), 1); blk[1] = rotl32(blk[1], 1) ^ (t0 + 2 * t1 + pkey->l_key[4 * (i) + 11]); } /* encrypt a block of text */ WIN32DLL_DEFINE void _mcrypt_encrypt(TWI * pkey, word32 * in_blk) { word32 t0, t1, blk[4]; #ifdef WORDS_BIGENDIAN blk[0] = byteswap32(in_blk[0]) ^ pkey->l_key[0]; blk[1] = byteswap32(in_blk[1]) ^ pkey->l_key[1]; blk[2] = byteswap32(in_blk[2]) ^ pkey->l_key[2]; blk[3] = byteswap32(in_blk[3]) ^ pkey->l_key[3]; #else blk[0] = in_blk[0] ^ pkey->l_key[0]; blk[1] = in_blk[1] ^ pkey->l_key[1]; blk[2] = in_blk[2] ^ pkey->l_key[2]; blk[3] = in_blk[3] ^ pkey->l_key[3]; #endif f_rnd(0, blk, pkey, t0, t1); f_rnd(1, blk, pkey, t0, t1); f_rnd(2, blk, pkey, t0, t1); f_rnd(3, blk, pkey, t0, t1); f_rnd(4, blk, pkey, t0, t1); f_rnd(5, blk, pkey, t0, t1); f_rnd(6, blk, pkey, t0, t1); f_rnd(7, blk, pkey, t0, t1); #ifdef WORDS_BIGENDIAN in_blk[0] = byteswap32(blk[2] ^ pkey->l_key[4]); in_blk[1] = byteswap32(blk[3] ^ pkey->l_key[5]); in_blk[2] = byteswap32(blk[0] ^ pkey->l_key[6]); in_blk[3] = byteswap32(blk[1] ^ pkey->l_key[7]); #else in_blk[0] = blk[2] ^ pkey->l_key[4]; in_blk[1] = blk[3] ^ pkey->l_key[5]; in_blk[2] = blk[0] ^ pkey->l_key[6]; in_blk[3] = blk[1] ^ pkey->l_key[7]; #endif } /* decrypt a block of text */ #define i_rnd(i) \ t1 = g1_fun(blk[1]); t0 = g0_fun(blk[0]); \ blk[2] = rotl32(blk[2], 1) ^ (t0 + t1 + pkey->l_key[4 * (i) + 10]); \ blk[3] = rotr32(blk[3] ^ (t0 + 2 * t1 + pkey->l_key[4 * (i) + 11]), 1); \ t1 = g1_fun(blk[3]); t0 = g0_fun(blk[2]); \ blk[0] = rotl32(blk[0], 1) ^ (t0 + t1 + pkey->l_key[4 * (i) + 8]); \ blk[1] = rotr32(blk[1] ^ (t0 + 2 * t1 + pkey->l_key[4 * (i) + 9]), 1) WIN32DLL_DEFINE void _mcrypt_decrypt(TWI * pkey, word32 * in_blk) { word32 t0, t1, blk[4]; #ifdef WORDS_BIGENDIAN blk[0] = byteswap32(in_blk[0]) ^ pkey->l_key[4]; blk[1] = byteswap32(in_blk[1]) ^ pkey->l_key[5]; blk[2] = byteswap32(in_blk[2]) ^ pkey->l_key[6]; blk[3] = byteswap32(in_blk[3]) ^ pkey->l_key[7]; #else blk[0] = in_blk[0] ^ pkey->l_key[4]; blk[1] = in_blk[1] ^ pkey->l_key[5]; blk[2] = in_blk[2] ^ pkey->l_key[6]; blk[3] = in_blk[3] ^ pkey->l_key[7]; #endif i_rnd(7); i_rnd(6); i_rnd(5); i_rnd(4); i_rnd(3); i_rnd(2); i_rnd(1); i_rnd(0); #ifdef WORDS_BIGENDIAN in_blk[0] = byteswap32(blk[2] ^ pkey->l_key[0]); in_blk[1] = byteswap32(blk[3] ^ pkey->l_key[1]); in_blk[2] = byteswap32(blk[0] ^ pkey->l_key[2]); in_blk[3] = byteswap32(blk[1] ^ pkey->l_key[3]); #else in_blk[0] = blk[2] ^ pkey->l_key[0]; in_blk[1] = blk[3] ^ pkey->l_key[1]; in_blk[2] = blk[0] ^ pkey->l_key[2]; in_blk[3] = blk[1] ^ pkey->l_key[3]; #endif } WIN32DLL_DEFINE int _mcrypt_get_size() { return sizeof(TWI); } WIN32DLL_DEFINE int _mcrypt_get_block_size() { return 16; } WIN32DLL_DEFINE int _is_block_algorithm() { return 1; } WIN32DLL_DEFINE int _mcrypt_get_key_size() { return 32; } static const int key_sizes[] = { 16, 24, 32 }; WIN32DLL_DEFINE const int *_mcrypt_get_supported_key_sizes(int *len) { *len = sizeof(key_sizes)/sizeof(int); return key_sizes; } WIN32DLL_DEFINE const char *_mcrypt_get_algorithms_name() { return "Twofish"; } #define CIPHER "019f9809de1711858faac3a3ba20fbc3" #define PT "\xD4\x91\xDB\x16\xE7\xB1\xC3\x9E\x86\xCB\x08\x6B\x78\x9F\x54\x19" #define KEY "\x9F\x58\x9F\x5C\xF6\x12\x2C\x32\xB6\xBF\xEC\x2F\x2A\xE8\xC3\x5A" WIN32DLL_DEFINE int _mcrypt_self_test() { unsigned char keyword[16]; unsigned char plaintext[16]; unsigned char ciphertext[16]; int blocksize = _mcrypt_get_block_size(), j; void* key; unsigned char cipher_tmp[200]; memcpy( keyword, KEY, 16); memcpy( plaintext, PT, 16); memcpy(ciphertext, plaintext, 16); key = malloc(_mcrypt_get_size()); if (key==NULL) return -1; _mcrypt_set_key(key, (void *) keyword, 16); _mcrypt_encrypt(key, (void *) ciphertext); for (j = 0; j < blocksize; j++) { sprintf(&((char *) cipher_tmp)[2 * j], "%.2x", ciphertext[j]); } if (strcmp((char *) cipher_tmp, CIPHER) != 0) { printf("failed compatibility\n"); printf("Expected: %s\nGot: %s\n", CIPHER, (char *) cipher_tmp); free(key); return -1; } _mcrypt_decrypt(key, (void *) ciphertext); free(key); if (memcmp(ciphertext, plaintext, 16) != 0) { printf("failed internally\n"); return -1; } return 0; } WIN32DLL_DEFINE word32 _mcrypt_algorithm_version() { return 19991129; } #ifdef WIN32 # ifdef USE_LTDL WIN32DLL_DEFINE int main (void) { /* empty main function to avoid linker error (see cygwin FAQ) */ } # endif #endif