/* Modified for SILC. -Pekka */ /* This is an independent implementation of the encryption algorithm: */ /* */ /* CRYPTON by Chae Hoon Lim of Future Systms Inc */ /* */ /* 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 the algorithm place on its exploitation. */ /* */ /* Dr Brian Gladman (gladman@seven77.demon.co.uk) 14th January 1999 */ /* Timing data for CRYPTON (crypton.c) 128 bit key: Key Setup: 531/1369 cycles (encrypt/decrypt) Encrypt: 474 cycles = 54.0 mbits/sec Decrypt: 474 cycles = 54.0 mbits/sec Mean: 474 cycles = 54.0 mbits/sec 192 bit key: Key Setup: 539/1381 cycles (encrypt/decrypt) Encrypt: 473 cycles = 54.1 mbits/sec Decrypt: 470 cycles = 54.5 mbits/sec Mean: 472 cycles = 54.3 mbits/sec 256 bit key: Key Setup: 552/1392 cycles (encrypt/decrypt) Encrypt: 469 cycles = 54.6 mbits/sec Decrypt: 483 cycles = 53.0 mbits/sec Mean: 476 cycles = 53.8 mbits/sec */ #include "silcincludes.h" #include "crypton.h" #define gamma_tau(x,b,m,p,q) \ (x) = (((u4byte)s_box[p][byte(b[0],m)] ) | \ ((u4byte)s_box[q][byte(b[1],m)] << 8) | \ ((u4byte)s_box[p][byte(b[2],m)] << 16) | \ ((u4byte)s_box[q][byte(b[3],m)] << 24)) #define ma_0 0x3fcff3fc #define ma_1 0xfc3fcff3 #define ma_2 0xf3fc3fcf #define ma_3 0xcff3fc3f #define mb_0 0xcffccffc #define mb_1 0xf33ff33f #define mb_2 0xfccffccf #define mb_3 0x3ff33ff3 #define pi(b,n0,n1,n2,n3) \ (((b)[0] & ma_##n0) ^ \ ((b)[1] & ma_##n1) ^ \ ((b)[2] & ma_##n2) ^ \ ((b)[3] & ma_##n3)) #define phi_n(x,n0,n1,n2,n3) \ ( (x) & mb_##n0) ^ \ (rotl((x), 8) & mb_##n1) ^ \ (rotl((x), 16) & mb_##n2) ^ \ (rotl((x), 24) & mb_##n3) #define phi_00(x) phi_n(x,0,1,2,3) #define phi_01(x) phi_n(x,3,0,1,2) #define phi_02(x) phi_n(x,2,3,0,1) #define phi_03(x) phi_n(x,1,2,3,0) #define phi_10(x) phi_n(x,3,0,1,2) #define phi_11(x) phi_n(x,2,3,0,1) #define phi_12(x) phi_n(x,1,2,3,0) #define phi_13(x) phi_n(x,0,1,2,3) #define phi0(x,y) \ (y)[0] = phi_00((x)[0]); \ (y)[1] = phi_01((x)[1]); \ (y)[2] = phi_02((x)[2]); \ (y)[3] = phi_03((x)[3]) #define phi1(x,y) \ (y)[0] = phi_10((x)[0]); \ (y)[1] = phi_11((x)[1]); \ (y)[2] = phi_12((x)[2]); \ (y)[3] = phi_13((x)[3]) u1byte p_box[3][16] = { { 15, 9, 6, 8, 9, 9, 4, 12, 6, 2, 6, 10, 1, 3, 5, 15 }, { 10, 15, 4, 7, 5, 2, 14, 6, 9, 3, 12, 8, 13, 1, 11, 0 }, { 0, 4, 8, 4, 2, 15, 8, 13, 1, 1, 15, 7, 2, 11, 14, 15 } }; u4byte tab_gen = 0; u1byte s_box[2][256]; u4byte s_tab[4][256]; void gen_tab(void) { u4byte i, xl, xr, yl, yr; for(i = 0; i < 256; ++i) { xl = (i & 0xf0) >> 4; xr = i & 15; yr = xr ^ p_box[1][xl ^ p_box[0][xr]]; yl = xl ^ p_box[0][xr] ^ p_box[2][yr]; yr |= (yl << 4); s_box[0][i] = (u1byte)yr; s_box[1][yr] = (u1byte)i; xr = yr * 0x01010101; xl = i * 0x01010101; s_tab[0][ i] = xr & 0x3fcff3fc; s_tab[1][yr] = xl & 0xfc3fcff3; s_tab[2][ i] = xr & 0xf3fc3fcf; s_tab[3][yr] = xl & 0xcff3fc3f; } }; /* initialise the key schedule from the user supplied key */ u4byte kp[4] = { 0xbb67ae85, 0x3c6ef372, 0xa54ff53a, 0x510e527f }; u4byte kq[4] = { 0x9b05688c, 0x1f83d9ab, 0x5be0cd19, 0xcbbb9d5d }; #define h0_block(n,r0,r1) \ e_key[4 * n + 8] = rotl(e_key[4 * n + 0], r0); \ e_key[4 * n + 9] = rc ^ e_key[4 * n + 1]; \ e_key[4 * n + 10] = rotl(e_key[4 * n + 2], r1); \ e_key[4 * n + 11] = rc ^ e_key[4 * n + 3] #define h1_block(n,r0,r1) \ e_key[4 * n + 8] = rc ^ e_key[4 * n + 0]; \ e_key[4 * n + 9] = rotl(e_key[4 * n + 1], r0); \ e_key[4 * n + 10] = rc ^ e_key[4 * n + 2]; \ e_key[4 * n + 11] = rotl(e_key[4 * n + 3], r1) u4byte *crypton_set_key(CryptonContext *ctx, const u4byte in_key[], const u4byte key_len) { u4byte i, rc, t0, t1, tmp[4]; u4byte *e_key = ctx->l_key + 52; u4byte *d_key = ctx->l_key; if(!tab_gen) { gen_tab(); tab_gen = 1; } e_key[2] = e_key[3] = e_key[6] = e_key[7] = 0; switch((key_len + 63) / 64) { case 4: e_key[3] = in_key[6]; e_key[7] = in_key[7]; case 3: e_key[2] = in_key[4]; e_key[6] = in_key[5]; case 2: e_key[0] = in_key[0]; e_key[4] = in_key[1]; e_key[1] = in_key[2]; e_key[5] = in_key[3]; } tmp[0] = pi(e_key, 0, 1, 2, 3) ^ kp[0]; tmp[1] = pi(e_key, 1, 2, 3, 0) ^ kp[1]; tmp[2] = pi(e_key, 2, 3, 0, 1) ^ kp[2]; tmp[3] = pi(e_key, 3, 0, 1, 2) ^ kp[3]; gamma_tau(e_key[0], tmp, 0, 0, 1); gamma_tau(e_key[1], tmp, 1, 1, 0); gamma_tau(e_key[2], tmp, 2, 0, 1); gamma_tau(e_key[3], tmp, 3, 1, 0); tmp[0] = pi(e_key + 4, 1, 2, 3, 0) ^ kq[0]; tmp[1] = pi(e_key + 4, 2, 3, 0, 1) ^ kq[1]; tmp[2] = pi(e_key + 4, 3, 0, 1, 2) ^ kq[2]; tmp[3] = pi(e_key + 4, 0, 1, 2, 3) ^ kq[3]; gamma_tau(e_key[4], tmp, 0, 1, 0); gamma_tau(e_key[5], tmp, 1, 0, 1); gamma_tau(e_key[6], tmp, 2, 1, 0); gamma_tau(e_key[7], tmp, 3, 0, 1); t0 = e_key[0] ^ e_key[1] ^ e_key[2] ^ e_key[3]; t1 = e_key[4] ^ e_key[5] ^ e_key[6] ^ e_key[7]; e_key[0] ^= t1; e_key[1] ^= t1; e_key[2] ^= t1; e_key[3] ^= t1; e_key[4] ^= t0; e_key[5] ^= t0; e_key[6] ^= t0; e_key[7] ^= t0; rc = 0x01010101; h0_block( 0, 8, 16); h1_block(1, 16, 24); rc <<= 1; h1_block( 2, 24, 8); h0_block(3, 8, 16); rc <<= 1; h0_block( 4, 16, 24); h1_block(5, 24, 8); rc <<= 1; h1_block( 6, 8, 16); h0_block(7, 16, 24); rc <<= 1; h0_block( 8, 24, 8); h1_block(9, 8, 16); rc <<= 1; h1_block(10, 16, 24); for(i = 0; i < 13; ++i) { if(i & 1) { phi0(e_key + 4 * i, d_key + 48 - 4 * i); } else { phi1(e_key + 4 * i, d_key + 48 - 4 * i); } } phi1(d_key + 48, d_key + 48); phi1(e_key + 48, e_key + 48); return l_key; }; /* encrypt a block of text */ #define fr0(i,k) \ b1[i] = s_tab[ (i) ][byte(b0[0],i)] ^ \ s_tab[((i) + 1) & 3][byte(b0[1],i)] ^ \ s_tab[((i) + 2) & 3][byte(b0[2],i)] ^ \ s_tab[((i) + 3) & 3][byte(b0[3],i)] ^ (k) #define fr1(i,k) \ b0[i] = s_tab[((i) + 1) & 3][byte(b1[0],i)] ^ \ s_tab[((i) + 2) & 3][byte(b1[1],i)] ^ \ s_tab[((i) + 3) & 3][byte(b1[2],i)] ^ \ s_tab[(i) ][byte(b1[3],i)] ^ (k) #define f0_rnd(kp) \ fr0(0,(kp)[0]); fr0(1,(kp)[1]); \ fr0(2,(kp)[2]); fr0(3,(kp)[3]) #define f1_rnd(kp) \ fr1(0,(kp)[0]); fr1(1,(kp)[1]); \ fr1(2,(kp)[2]); fr1(3,(kp)[3]) void crypton_encrypt(CryptonContext *ctx, const u4byte in_blk[4], u4byte out_blk[4]) { u4byte b0[4], b1[4]; u4byte *e_key = ctx->l_key + 52; u4byte *d_key = ctx->l_key; b0[0] = in_blk[0] ^ e_key[0]; b0[1] = in_blk[1] ^ e_key[1]; b0[2] = in_blk[2] ^ e_key[2]; b0[3] = in_blk[3] ^ e_key[3]; f0_rnd(e_key + 4); f1_rnd(e_key + 8); f0_rnd(e_key + 12); f1_rnd(e_key + 16); f0_rnd(e_key + 20); f1_rnd(e_key + 24); f0_rnd(e_key + 28); f1_rnd(e_key + 32); f0_rnd(e_key + 36); f1_rnd(e_key + 40); f0_rnd(e_key + 44); gamma_tau(b0[0], b1, 0, 1, 0); gamma_tau(b0[1], b1, 1, 0, 1); gamma_tau(b0[2], b1, 2, 1, 0); gamma_tau(b0[3], b1, 3, 0, 1); out_blk[0] = b0[0] ^ e_key[48]; out_blk[1] = b0[1] ^ e_key[49]; out_blk[2] = b0[2] ^ e_key[50]; out_blk[3] = b0[3] ^ e_key[51]; }; /* decrypt a block of text */ void crypton_decrypt(CryptonContext *ctx, const u4byte in_blk[4], u4byte out_blk[4]) { u4byte b0[4], b1[4]; u4byte *e_key = ctx->l_key + 52; u4byte *d_key = ctx->l_key; b0[0] = in_blk[0] ^ d_key[0]; b0[1] = in_blk[1] ^ d_key[1]; b0[2] = in_blk[2] ^ d_key[2]; b0[3] = in_blk[3] ^ d_key[3]; f0_rnd(d_key + 4); f1_rnd(d_key + 8); f0_rnd(d_key + 12); f1_rnd(d_key + 16); f0_rnd(d_key + 20); f1_rnd(d_key + 24); f0_rnd(d_key + 28); f1_rnd(d_key + 32); f0_rnd(d_key + 36); f1_rnd(d_key + 40); f0_rnd(d_key + 44); gamma_tau(b0[0], b1, 0, 1, 0); gamma_tau(b0[1], b1, 1, 0, 1); gamma_tau(b0[2], b1, 2, 1, 0); gamma_tau(b0[3], b1, 3, 0, 1); out_blk[0] = b0[0] ^ d_key[48]; out_blk[1] = b0[1] ^ d_key[49]; out_blk[2] = b0[2] ^ d_key[50]; out_blk[3] = b0[3] ^ d_key[51]; };