/* * Noekeon in SIMD * (C) 2010 Jack Lloyd * * Botan is released under the Simplified BSD License (see license.txt) */ #include #include #include namespace Botan { BOTAN_REGISTER_BLOCK_CIPHER_NOARGS_IF(SIMD_32::enabled(), Noekeon_SIMD, "Noekeon", "simd32"); /* * Noekeon's Theta Operation */ #define NOK_SIMD_THETA(A0, A1, A2, A3, K0, K1, K2, K3) \ do { \ SIMD_32 T = A0 ^ A2; \ SIMD_32 T_l8 = T; \ SIMD_32 T_r8 = T; \ T_l8.rotate_left(8); \ T_r8.rotate_right(8); \ T ^= T_l8; \ T ^= T_r8; \ A1 ^= T; \ A3 ^= T; \ \ A0 ^= K0; \ A1 ^= K1; \ A2 ^= K2; \ A3 ^= K3; \ \ T = A1 ^ A3; \ T_l8 = T; \ T_r8 = T; \ T_l8.rotate_left(8); \ T_r8.rotate_right(8); \ T ^= T_l8; \ T ^= T_r8; \ A0 ^= T; \ A2 ^= T; \ } while(0) /* * Noekeon's Gamma S-Box Layer */ #define NOK_SIMD_GAMMA(A0, A1, A2, A3) \ do \ { \ A1 ^= A3.andc(~A2); \ A0 ^= A2 & A1; \ \ SIMD_32 T = A3; \ A3 = A0; \ A0 = T; \ \ A2 ^= A0 ^ A1 ^ A3; \ \ A1 ^= A3.andc(~A2); \ A0 ^= A2 & A1; \ } while(0) /* * Noekeon Encryption */ void Noekeon_SIMD::encrypt_n(const byte in[], byte out[], size_t blocks) const { const secure_vector& EK = this->get_EK(); SIMD_32 K0 = SIMD_32(EK[0]); SIMD_32 K1 = SIMD_32(EK[1]); SIMD_32 K2 = SIMD_32(EK[2]); SIMD_32 K3 = SIMD_32(EK[3]); while(blocks >= 4) { SIMD_32 A0 = SIMD_32::load_be(in ); SIMD_32 A1 = SIMD_32::load_be(in + 16); SIMD_32 A2 = SIMD_32::load_be(in + 32); SIMD_32 A3 = SIMD_32::load_be(in + 48); SIMD_32::transpose(A0, A1, A2, A3); for(size_t i = 0; i != 16; ++i) { A0 ^= SIMD_32(RC[i]); NOK_SIMD_THETA(A0, A1, A2, A3, K0, K1, K2, K3); A1.rotate_left(1); A2.rotate_left(5); A3.rotate_left(2); NOK_SIMD_GAMMA(A0, A1, A2, A3); A1.rotate_right(1); A2.rotate_right(5); A3.rotate_right(2); } A0 ^= SIMD_32(RC[16]); NOK_SIMD_THETA(A0, A1, A2, A3, K0, K1, K2, K3); SIMD_32::transpose(A0, A1, A2, A3); A0.store_be(out); A1.store_be(out + 16); A2.store_be(out + 32); A3.store_be(out + 48); in += 64; out += 64; blocks -= 4; } if(blocks) Noekeon::encrypt_n(in, out, blocks); } /* * Noekeon Encryption */ void Noekeon_SIMD::decrypt_n(const byte in[], byte out[], size_t blocks) const { const secure_vector& DK = this->get_DK(); SIMD_32 K0 = SIMD_32(DK[0]); SIMD_32 K1 = SIMD_32(DK[1]); SIMD_32 K2 = SIMD_32(DK[2]); SIMD_32 K3 = SIMD_32(DK[3]); while(blocks >= 4) { SIMD_32 A0 = SIMD_32::load_be(in ); SIMD_32 A1 = SIMD_32::load_be(in + 16); SIMD_32 A2 = SIMD_32::load_be(in + 32); SIMD_32 A3 = SIMD_32::load_be(in + 48); SIMD_32::transpose(A0, A1, A2, A3); for(size_t i = 0; i != 16; ++i) { NOK_SIMD_THETA(A0, A1, A2, A3, K0, K1, K2, K3); A0 ^= SIMD_32(RC[16-i]); A1.rotate_left(1); A2.rotate_left(5); A3.rotate_left(2); NOK_SIMD_GAMMA(A0, A1, A2, A3); A1.rotate_right(1); A2.rotate_right(5); A3.rotate_right(2); } NOK_SIMD_THETA(A0, A1, A2, A3, K0, K1, K2, K3); A0 ^= SIMD_32(RC[0]); SIMD_32::transpose(A0, A1, A2, A3); A0.store_be(out); A1.store_be(out + 16); A2.store_be(out + 32); A3.store_be(out + 48); in += 64; out += 64; blocks -= 4; } if(blocks) Noekeon::decrypt_n(in, out, blocks); } }