/* * cry1.c Copyright Codemist Ltd. 2002 * * * This is an experimental and not properly validated cipher. The idea * is that of a feedback shift register. It observes that in any single bit * position and for so long as one ignored carries, ADD, SUBTRACT and XOR * all behave the same. So it runs a fibonacci-style generator but with the * processing written out in-line so it can use these three operations * in turn. The pattern of their use was derived from bits of the value * of pi or some such and is "random". Next it make output words by combining * (again using mixtures of arithmetic and logical operators) fields from * within the raw shift register. It discards some values or bits from the * main shift register. It then shuffles the resulting output words in * 4K word buffer so it will be harder to work out which came from where. * This HAS NOT been subject to serious crypto-analysis so should at most * be used in places where confusion is enough... */ /* * This code may be used and modified, and redistributed in binary * or source form, subject to the "CCL Public License", which should * accompany it. This license is a variant on the BSD license, and thus * permits use of code derived from this in either open and commercial * projects: but it does require that updates to this code be made * available back to the originators of the package. * Before merging other code in with this or linking this code * with other packages or libraries please check that the license terms * of the other material are compatible with those of this. */ /* * shift register length = 65 * tap at position 18 * shuffle-buffer size = 4096 */ /* Signature: 71cbef8a 21-Apr-2002 */ #ifdef TIME_TEST #include <stdio.h> #include <time.h> #define N 10000000 /* parameters for time test */ #define NSTARTS 4000 #define NTINY 50000000 #define KEY "Arthurs's sample key" typedef unsigned int unsigned32; #endif /* TIME_TEST */ static unsigned32 lf[65], mix[4096]; #define R(x) ((x) >> 20) #define S(x) ((x) >> 9) #define T(x) ((x) << 13) static unsigned char byte_order_test[] = {1, 0, 0, 0}; #define CRYPT_BLOCK_SIZE 128 void crypt_get_block(unsigned char block[CRYPT_BLOCK_SIZE]) { unsigned32 *b = (unsigned32 *)block; int n; lf[0] -= lf[18]; lf[1] ^= lf[19]; lf[2] -= lf[20]; lf[3] += lf[21]; lf[4] += lf[22]; lf[5] -= lf[23]; lf[6] ^= lf[24]; lf[7] -= lf[25]; lf[8] += lf[26]; lf[9] ^= lf[27]; lf[10] -= lf[28]; lf[11] -= lf[29]; lf[12] += lf[30]; lf[13] += lf[31]; lf[14] -= lf[32]; lf[15] ^= lf[33]; lf[16] -= lf[34]; lf[17] += lf[35]; lf[18] += lf[36]; lf[19] += lf[37]; lf[20] -= lf[38]; lf[21] -= lf[39]; lf[22] ^= lf[40]; lf[23] += lf[41]; lf[24] -= lf[42]; lf[25] -= lf[43]; lf[26] += lf[44]; lf[27] += lf[45]; lf[28] -= lf[46]; lf[29] ^= lf[47]; lf[30] -= lf[48]; lf[31] += lf[49]; lf[32] -= lf[50]; lf[33] ^= lf[51]; lf[34] -= lf[52]; lf[35] ^= lf[53]; lf[36] += lf[54]; lf[37] += lf[55]; lf[38] ^= lf[56]; lf[39] ^= lf[57]; lf[40] += lf[58]; lf[41] -= lf[59]; lf[42] ^= lf[60]; lf[43] += lf[61]; lf[44] += lf[62]; lf[45] ^= lf[63]; lf[46] ^= lf[64]; lf[47] -= lf[0]; lf[48] ^= lf[1]; lf[49] ^= lf[2]; lf[50] ^= lf[3]; lf[51] ^= lf[4]; lf[52] ^= lf[5]; lf[53] ^= lf[6]; lf[54] += lf[7]; lf[55] -= lf[8]; lf[56] -= lf[9]; lf[57] ^= lf[10]; lf[58] -= lf[11]; lf[59] -= lf[12]; lf[60] ^= lf[13]; lf[61] += lf[14]; lf[62] ^= lf[15]; lf[63] -= lf[16]; lf[64] -= lf[17]; n = R(lf[0]); b[0] = mix[n]; mix[n] = (lf[54] + S(lf[29])) ^ T(lf[5]); n = R(lf[1]); b[1] = mix[n]; mix[n] = (lf[39] + S(lf[47])) + T(lf[15]); n = R(lf[2]); b[2] = mix[n]; mix[n] = (lf[25] + S(lf[14])) + T(lf[38]); n = R(lf[4]); b[3] = mix[n]; mix[n] = (lf[48] - S(lf[40])) ^ T(lf[10]); n = R(lf[5]); b[4] = mix[n]; mix[n] = (lf[44] - S(lf[55])) - T(lf[49]); n = R(lf[6]); b[5] = mix[n]; mix[n] = (lf[9] ^ S(lf[37])) + T(lf[50]); n = R(lf[8]); b[6] = mix[n]; mix[n] = (lf[64] ^ S(lf[51])) + T(lf[8]); n = R(lf[9]); b[7] = mix[n]; mix[n] = (lf[11] - S(lf[35])) - T(lf[21]); n = R(lf[10]); b[8] = mix[n]; mix[n] = (lf[20] ^ S(lf[21])) ^ T(lf[3]); n = R(lf[12]); b[9] = mix[n]; mix[n] = (lf[6] ^ S(lf[31])) - T(lf[61]); n = R(lf[13]); b[10] = mix[n]; mix[n] = (lf[3] - S(lf[16])) ^ T(lf[16]); n = R(lf[14]); b[11] = mix[n]; mix[n] = (lf[17] - S(lf[53])) - T(lf[2]); n = R(lf[16]); b[12] = mix[n]; mix[n] = (lf[27] + S(lf[42])) - T(lf[33]); n = R(lf[17]); b[13] = mix[n]; mix[n] = (lf[28] + S(lf[63])) - T(lf[46]); n = R(lf[18]); b[14] = mix[n]; mix[n] = (lf[10] - S(lf[46])) + T(lf[35]); n = R(lf[20]); b[15] = mix[n]; mix[n] = (lf[53] - S(lf[10])) - T(lf[27]); n = R(lf[21]); b[16] = mix[n]; mix[n] = (lf[4] + S(lf[18])) - T(lf[7]); n = R(lf[22]); b[17] = mix[n]; mix[n] = (lf[43] + S(lf[64])) ^ T(lf[45]); n = R(lf[24]); b[18] = mix[n]; mix[n] = (lf[14] + S(lf[26])) + T(lf[44]); n = R(lf[25]); b[19] = mix[n]; mix[n] = (lf[23] ^ S(lf[38])) + T(lf[58]); n = R(lf[26]); b[20] = mix[n]; mix[n] = (lf[47] + S(lf[59])) ^ T(lf[47]); n = R(lf[28]); b[21] = mix[n]; mix[n] = (lf[63] - S(lf[36])) - T(lf[57]); n = R(lf[29]); b[22] = mix[n]; mix[n] = (lf[56] + S(lf[4])) + T(lf[19]); n = R(lf[30]); b[23] = mix[n]; mix[n] = (lf[42] - S(lf[52])) - T(lf[56]); n = R(lf[32]); b[24] = mix[n]; mix[n] = (lf[37] + S(lf[3])) - T(lf[63]); n = R(lf[33]); b[25] = mix[n]; mix[n] = (lf[32] + S(lf[1])) - T(lf[12]); n = R(lf[34]); b[26] = mix[n]; mix[n] = (lf[62] - S(lf[39])) - T(lf[31]); n = R(lf[36]); b[27] = mix[n]; mix[n] = (lf[2] ^ S(lf[44])) ^ T(lf[18]); n = R(lf[37]); b[28] = mix[n]; mix[n] = (lf[24] ^ S(lf[50])) ^ T(lf[55]); n = R(lf[38]); b[29] = mix[n]; mix[n] = (lf[22] + S(lf[27])) - T(lf[32]); n = R(lf[40]); b[30] = mix[n]; mix[n] = (lf[51] + S(lf[33])) + T(lf[0]); n = R(lf[41]); b[31] = mix[n]; mix[n] = (lf[52] ^ S(lf[19])) - T(lf[26]); n = R(lf[42]); mix[n] = (lf[5] ^ S(lf[41])) + T(lf[28]); n = R(lf[44]); mix[n] = (lf[30] ^ S(lf[15])) - T(lf[30]); n = R(lf[45]); mix[n] = (lf[45] + S(lf[24])) ^ T(lf[51]); n = R(lf[46]); mix[n] = (lf[13] + S(lf[49])) - T(lf[11]); n = R(lf[48]); mix[n] = (lf[16] + S(lf[11])) - T(lf[39]); n = R(lf[49]); mix[n] = (lf[57] - S(lf[43])) - T(lf[60]); n = R(lf[50]); mix[n] = (lf[49] + S(lf[48])) ^ T(lf[25]); n = R(lf[52]); mix[n] = (lf[34] - S(lf[22])) ^ T(lf[23]); n = R(lf[53]); mix[n] = (lf[18] + S(lf[6])) + T(lf[1]); n = R(lf[54]); mix[n] = (lf[29] + S(lf[61])) - T(lf[64]); n = R(lf[56]); mix[n] = (lf[59] ^ S(lf[45])) - T(lf[41]); n = R(lf[57]); mix[n] = (lf[36] - S(lf[32])) + T(lf[37]); n = R(lf[58]); mix[n] = (lf[40] + S(lf[60])) + T(lf[14]); n = R(lf[60]); mix[n] = (lf[1] + S(lf[56])) ^ T(lf[36]); n = R(lf[61]); mix[n] = (lf[8] ^ S(lf[5])) ^ T(lf[17]); n = R(lf[62]); mix[n] = (lf[31] ^ S(lf[17])) ^ T(lf[52]); /* The test this way around favours Intel etc byte order */ if (((unsigned32 *)byte_order_test)[0] != 1) { int i; for (i=0; i<32; i++) { unsigned32 w = b[i]; unsigned32 b0, b1, b2, b3; b0 = (w >> 24) & 0xffU; b1 = (w >> 8) & 0xff00U; b2 = (w << 8) & 0xff0000U; b3 = (w << 24) & 0xff000000U; b[i] = b0 | b1 | b2 | b3; } } return; } void crypt_init(char *key) { char *pk = key; unsigned char junk[128]; int i, j; unsigned32 w = 0; for (i=0; i<260; i++) { int k = *pk++; if (k == 0) pk = key; /* Cycle key (inc. terminating 0) */ w = (w << 8) | (k & 0xff); if ((i % 4) == 3) lf[i/4] = w; } for (i=0; i<4096; i++) mix[i] = 0; for (i=0; i<8; i++) { for (j=0; j<65; j++) lf[j] = (lf[j] << 10) | (lf[j] >> 22); lf[0] |= 1; for (j=0; j<64; j++) crypt_get_block(junk); } for (i=0; i<4096;) { int j; crypt_get_block(junk); for (j=0; j<32; j++) { unsigned32 r = junk[4*j]; r = (r << 8) | junk[4*j+1]; r = (r << 8) | junk[4*j+2]; r = (r << 8) | junk[4*j+3]; if (r == 0) continue; mix[i++] ^= junk[j]; if (i == 4096) break; } } for (i=0; i<192; i++) crypt_get_block(junk); return; } #ifdef TIME_TEST /* * The main program here does not do anything of real interest. It * runs both the key-setup and the main loop lots of times and reports * how long it all takes. * * Here is some sample output from a Pentium-II 400Mhz system * * 1.23 milliseconds to startup * rate = 106.43 megabytes per second * 9a cb fe 7f 5b 10 0b ce f6 49 89 b2 b7 17 f1 c7 * 29 39 70 f0 ff 4b ec 8a 98 af 41 38 52 85 c9 88 * 91 c7 18 46 68 3c 92 04 b2 21 ed 5e 30 6e e0 d9 * cd ba d9 a6 86 9a 65 35 5c 65 61 e6 45 00 ac 88 * 41 8a 5e 76 cb 2c 0c fb 62 3b 1b 31 37 cf 1f 97 * 81 6c 53 73 3a fe 4f df b6 a4 00 45 59 ab 58 48 * ce e7 08 81 67 17 07 f3 d3 88 34 4b 8a ec 8c 43 * e9 4e 65 f5 f2 21 1e a9 44 6d a1 ad ac d5 f9 ac * */ int main(int argc, char *argv[]) { clock_t c0, c1; unsigned char r[CRYPT_BLOCK_SIZE]; int i, j = 0; double rate; c0 = clock(); for (i=0; i<(NTINY+1); i++) j ^= i; c1 = clock(); printf("[%.8x] %.2f nanoseconds to do tiny loop\n", j, 1.0e9*(double)(c1-c0)/((double)CLOCKS_PER_SEC*(double)(NTINY+1))); c0 = clock(); for (i=0; i<NSTARTS; i++) crypt_init(KEY); c1 = clock(); printf("%.2f milliseconds to startup\n", 1000.0*(double)(c1-c0)/((double)CLOCKS_PER_SEC*(double)NSTARTS)); c0 = clock(); for (i=0; i<N; i++) crypt_get_block(r); c1 = clock(); rate = (double)N*(double)CRYPT_BLOCK_SIZE*(double)CLOCKS_PER_SEC/ ((double)(c1-c0)*1.0e6); printf("rate = %.2f megabytes per second\n", rate); for (i=0; i<128; i++) { printf("%.2x ", r[i]); if ((i % 16) == 15) printf("\n"); } return 0; } #endif /* TIME_TEST */ #undef R #undef S #undef T