/* * file : echo_vperm.c * version : 1.0.208 * date : 14.12.2010 * * - vperm and aes_ni implementations of hash function ECHO * - implements NIST hash api * - assumes that message lenght is multiple of 8-bits * - _ECHO_VPERM_ must be defined if compiling with ../main.c * * Cagdas Calik * ccalik@metu.edu.tr * Institute of Applied Mathematics, Middle East Technical University, Turkey. * */ #if defined(__AES__) #include #include "miner.h" #include "hash_api.h" //#include "vperm.h" #include #include "simd-utils.h" MYALIGN const unsigned int _k_s0F[] = {0x0F0F0F0F, 0x0F0F0F0F, 0x0F0F0F0F, 0x0F0F0F0F}; MYALIGN const unsigned int _k_ipt[] = {0x5A2A7000, 0xC2B2E898, 0x52227808, 0xCABAE090, 0x317C4D00, 0x4C01307D, 0xB0FDCC81, 0xCD80B1FC}; MYALIGN const unsigned int _k_opt[] = {0xD6B66000, 0xFF9F4929, 0xDEBE6808, 0xF7974121, 0x50BCEC00, 0x01EDBD51, 0xB05C0CE0, 0xE10D5DB1}; MYALIGN const unsigned int _k_inv[] = {0x0D080180, 0x0E05060F, 0x0A0B0C02, 0x04070309, 0x0F0B0780, 0x01040A06, 0x02050809, 0x030D0E0C}; MYALIGN const unsigned int _k_sb1[] = {0xCB503E00, 0xB19BE18F, 0x142AF544, 0xA5DF7A6E, 0xFAE22300, 0x3618D415, 0x0D2ED9EF, 0x3BF7CCC1}; MYALIGN const unsigned int _k_sb2[] = {0x0B712400, 0xE27A93C6, 0xBC982FCD, 0x5EB7E955, 0x0AE12900, 0x69EB8840, 0xAB82234A, 0xC2A163C8}; MYALIGN const unsigned int _k_sb3[] = {0xC0211A00, 0x53E17249, 0xA8B2DA89, 0xFB68933B, 0xF0030A00, 0x5FF35C55, 0xA6ACFAA5, 0xF956AF09}; MYALIGN const unsigned int _k_sb4[] = {0x3FD64100, 0xE1E937A0, 0x49087E9F, 0xA876DE97, 0xC393EA00, 0x3D50AED7, 0x876D2914, 0xBA44FE79}; MYALIGN const unsigned int _k_sb5[] = {0xF4867F00, 0x5072D62F, 0x5D228BDB, 0x0DA9A4F9, 0x3971C900, 0x0B487AC2, 0x8A43F0FB, 0x81B332B8}; MYALIGN const unsigned int _k_sb7[] = {0xFFF75B00, 0xB20845E9, 0xE1BAA416, 0x531E4DAC, 0x3390E000, 0x62A3F282, 0x21C1D3B1, 0x43125170}; MYALIGN const unsigned int _k_sbo[] = {0x6FBDC700, 0xD0D26D17, 0xC502A878, 0x15AABF7A, 0x5FBB6A00, 0xCFE474A5, 0x412B35FA, 0x8E1E90D1}; MYALIGN const unsigned int _k_h63[] = {0x63636363, 0x63636363, 0x63636363, 0x63636363}; MYALIGN const unsigned int _k_hc6[] = {0xc6c6c6c6, 0xc6c6c6c6, 0xc6c6c6c6, 0xc6c6c6c6}; MYALIGN const unsigned int _k_h5b[] = {0x5b5b5b5b, 0x5b5b5b5b, 0x5b5b5b5b, 0x5b5b5b5b}; MYALIGN const unsigned int _k_h4e[] = {0x4e4e4e4e, 0x4e4e4e4e, 0x4e4e4e4e, 0x4e4e4e4e}; MYALIGN const unsigned int _k_h0e[] = {0x0e0e0e0e, 0x0e0e0e0e, 0x0e0e0e0e, 0x0e0e0e0e}; MYALIGN const unsigned int _k_h15[] = {0x15151515, 0x15151515, 0x15151515, 0x15151515}; MYALIGN const unsigned int _k_aesmix1[] = {0x0f0a0500, 0x030e0904, 0x07020d08, 0x0b06010c}; MYALIGN const unsigned int _k_aesmix2[] = {0x000f0a05, 0x04030e09, 0x0807020d, 0x0c0b0601}; MYALIGN const unsigned int _k_aesmix3[] = {0x05000f0a, 0x0904030e, 0x0d080702, 0x010c0b06}; MYALIGN const unsigned int _k_aesmix4[] = {0x0a05000f, 0x0e090403, 0x020d0807, 0x06010c0b}; MYALIGN const unsigned int const1[] = {0x00000001, 0x00000000, 0x00000000, 0x00000000}; MYALIGN const unsigned int mul2mask[] = {0x00001b00, 0x00000000, 0x00000000, 0x00000000}; MYALIGN const unsigned int lsbmask[] = {0x01010101, 0x01010101, 0x01010101, 0x01010101}; MYALIGN const unsigned int invshiftrows[] = {0x070a0d00, 0x0b0e0104, 0x0f020508, 0x0306090c}; MYALIGN const unsigned int zero[] = {0x00000000, 0x00000000, 0x00000000, 0x00000000}; MYALIGN const unsigned int mul2ipt[] = {0x728efc00, 0x6894e61a, 0x3fc3b14d, 0x25d9ab57, 0xfd5ba600, 0x2a8c71d7, 0x1eb845e3, 0xc96f9234}; #define ECHO_SUBBYTES(state, i, j) \ state[i][j] = _mm_aesenc_si128(state[i][j], k1);\ state[i][j] = _mm_aesenc_si128(state[i][j], M128(zero));\ k1 = _mm_add_epi32(k1, M128(const1)) #define ECHO_MIXBYTES(state1, state2, j, t1, t2, s2) \ s2 = _mm_add_epi8(state1[0][j], state1[0][j]);\ t1 = _mm_srli_epi16(state1[0][j], 7);\ t1 = _mm_and_si128(t1, M128(lsbmask));\ t2 = _mm_shuffle_epi8(M128(mul2mask), t1);\ s2 = _mm_xor_si128(s2, t2);\ state2[0][j] = s2;\ state2[1][j] = state1[0][j];\ state2[2][j] = state1[0][j];\ state2[3][j] = _mm_xor_si128(s2, state1[0][j]);\ s2 = _mm_add_epi8(state1[1][(j + 1) & 3], state1[1][(j + 1) & 3]);\ t1 = _mm_srli_epi16(state1[1][(j + 1) & 3], 7);\ t1 = _mm_and_si128(t1, M128(lsbmask));\ t2 = _mm_shuffle_epi8(M128(mul2mask), t1);\ s2 = _mm_xor_si128(s2, t2);\ state2[0][j] = _mm_xor_si128(state2[0][j], _mm_xor_si128(s2, state1[1][(j + 1) & 3]));\ state2[1][j] = _mm_xor_si128(state2[1][j], s2);\ state2[2][j] = _mm_xor_si128(state2[2][j], state1[1][(j + 1) & 3]);\ state2[3][j] = _mm_xor_si128(state2[3][j], state1[1][(j + 1) & 3]);\ s2 = _mm_add_epi8(state1[2][(j + 2) & 3], state1[2][(j + 2) & 3]);\ t1 = _mm_srli_epi16(state1[2][(j + 2) & 3], 7);\ t1 = _mm_and_si128(t1, M128(lsbmask));\ t2 = _mm_shuffle_epi8(M128(mul2mask), t1);\ s2 = _mm_xor_si128(s2, t2);\ state2[0][j] = _mm_xor_si128(state2[0][j], state1[2][(j + 2) & 3]);\ state2[1][j] = _mm_xor_si128(state2[1][j], _mm_xor_si128(s2, state1[2][(j + 2) & 3]));\ state2[2][j] = _mm_xor_si128(state2[2][j], s2);\ state2[3][j] = _mm_xor_si128(state2[3][j], state1[2][(j + 2) & 3]);\ s2 = _mm_add_epi8(state1[3][(j + 3) & 3], state1[3][(j + 3) & 3]);\ t1 = _mm_srli_epi16(state1[3][(j + 3) & 3], 7);\ t1 = _mm_and_si128(t1, M128(lsbmask));\ t2 = _mm_shuffle_epi8(M128(mul2mask), t1);\ s2 = _mm_xor_si128(s2, t2);\ state2[0][j] = _mm_xor_si128(state2[0][j], state1[3][(j + 3) & 3]);\ state2[1][j] = _mm_xor_si128(state2[1][j], state1[3][(j + 3) & 3]);\ state2[2][j] = _mm_xor_si128(state2[2][j], _mm_xor_si128(s2, state1[3][(j + 3) & 3]));\ state2[3][j] = _mm_xor_si128(state2[3][j], s2) #define ECHO_ROUND_UNROLL2 \ ECHO_SUBBYTES(_state, 0, 0);\ ECHO_SUBBYTES(_state, 1, 0);\ ECHO_SUBBYTES(_state, 2, 0);\ ECHO_SUBBYTES(_state, 3, 0);\ ECHO_SUBBYTES(_state, 0, 1);\ ECHO_SUBBYTES(_state, 1, 1);\ ECHO_SUBBYTES(_state, 2, 1);\ ECHO_SUBBYTES(_state, 3, 1);\ ECHO_SUBBYTES(_state, 0, 2);\ ECHO_SUBBYTES(_state, 1, 2);\ ECHO_SUBBYTES(_state, 2, 2);\ ECHO_SUBBYTES(_state, 3, 2);\ ECHO_SUBBYTES(_state, 0, 3);\ ECHO_SUBBYTES(_state, 1, 3);\ ECHO_SUBBYTES(_state, 2, 3);\ ECHO_SUBBYTES(_state, 3, 3);\ ECHO_MIXBYTES(_state, _state2, 0, t1, t2, s2);\ ECHO_MIXBYTES(_state, _state2, 1, t1, t2, s2);\ ECHO_MIXBYTES(_state, _state2, 2, t1, t2, s2);\ ECHO_MIXBYTES(_state, _state2, 3, t1, t2, s2);\ ECHO_SUBBYTES(_state2, 0, 0);\ ECHO_SUBBYTES(_state2, 1, 0);\ ECHO_SUBBYTES(_state2, 2, 0);\ ECHO_SUBBYTES(_state2, 3, 0);\ ECHO_SUBBYTES(_state2, 0, 1);\ ECHO_SUBBYTES(_state2, 1, 1);\ ECHO_SUBBYTES(_state2, 2, 1);\ ECHO_SUBBYTES(_state2, 3, 1);\ ECHO_SUBBYTES(_state2, 0, 2);\ ECHO_SUBBYTES(_state2, 1, 2);\ ECHO_SUBBYTES(_state2, 2, 2);\ ECHO_SUBBYTES(_state2, 3, 2);\ ECHO_SUBBYTES(_state2, 0, 3);\ ECHO_SUBBYTES(_state2, 1, 3);\ ECHO_SUBBYTES(_state2, 2, 3);\ ECHO_SUBBYTES(_state2, 3, 3);\ ECHO_MIXBYTES(_state2, _state, 0, t1, t2, s2);\ ECHO_MIXBYTES(_state2, _state, 1, t1, t2, s2);\ ECHO_MIXBYTES(_state2, _state, 2, t1, t2, s2);\ ECHO_MIXBYTES(_state2, _state, 3, t1, t2, s2) #define SAVESTATE(dst, src)\ dst[0][0] = src[0][0];\ dst[0][1] = src[0][1];\ dst[0][2] = src[0][2];\ dst[0][3] = src[0][3];\ dst[1][0] = src[1][0];\ dst[1][1] = src[1][1];\ dst[1][2] = src[1][2];\ dst[1][3] = src[1][3];\ dst[2][0] = src[2][0];\ dst[2][1] = src[2][1];\ dst[2][2] = src[2][2];\ dst[2][3] = src[2][3];\ dst[3][0] = src[3][0];\ dst[3][1] = src[3][1];\ dst[3][2] = src[3][2];\ dst[3][3] = src[3][3] void Compress(hashState_echo *ctx, const unsigned char *pmsg, unsigned int uBlockCount) { unsigned int r, b, i, j; __m128i t1, t2, s2, k1; __m128i _state[4][4], _state2[4][4], _statebackup[4][4]; for(i = 0; i < 4; i++) for(j = 0; j < ctx->uHashSize / 256; j++) _state[i][j] = ctx->state[i][j]; for(b = 0; b < uBlockCount; b++) { ctx->k = _mm_add_epi64(ctx->k, ctx->const1536); // load message for(j = ctx->uHashSize / 256; j < 4; j++) { for(i = 0; i < 4; i++) { _state[i][j] = _mm_load_si128((__m128i*)pmsg + 4 * (j - (ctx->uHashSize / 256)) + i); } } // save state SAVESTATE(_statebackup, _state); k1 = ctx->k; for(r = 0; r < ctx->uRounds / 2; r++) { ECHO_ROUND_UNROLL2; } if(ctx->uHashSize == 256) { for(i = 0; i < 4; i++) { _state[i][0] = _mm_xor_si128(_state[i][0], _state[i][1]); _state[i][0] = _mm_xor_si128(_state[i][0], _state[i][2]); _state[i][0] = _mm_xor_si128(_state[i][0], _state[i][3]); _state[i][0] = _mm_xor_si128(_state[i][0], _statebackup[i][0]); _state[i][0] = _mm_xor_si128(_state[i][0], _statebackup[i][1]); _state[i][0] = _mm_xor_si128(_state[i][0], _statebackup[i][2]); _state[i][0] = _mm_xor_si128(_state[i][0], _statebackup[i][3]); } } else { for(i = 0; i < 4; i++) { _state[i][0] = _mm_xor_si128(_state[i][0], _state[i][2]); _state[i][1] = _mm_xor_si128(_state[i][1], _state[i][3]); _state[i][0] = _mm_xor_si128(_state[i][0], _statebackup[i][0]); _state[i][0] = _mm_xor_si128(_state[i][0], _statebackup[i][2]); _state[i][1] = _mm_xor_si128(_state[i][1], _statebackup[i][1]); _state[i][1] = _mm_xor_si128(_state[i][1], _statebackup[i][3]); } } pmsg += ctx->uBlockLength; } SAVESTATE(ctx->state, _state); } HashReturn init_echo(hashState_echo *ctx, int nHashSize) { int i, j; ctx->k = _mm_setzero_si128(); ctx->processed_bits = 0; ctx->uBufferBytes = 0; switch(nHashSize) { case 256: ctx->uHashSize = 256; ctx->uBlockLength = 192; ctx->uRounds = 8; ctx->hashsize = _mm_set_epi32(0, 0, 0, 0x00000100); ctx->const1536 = _mm_set_epi32(0x00000000, 0x00000000, 0x00000000, 0x00000600); break; case 512: ctx->uHashSize = 512; ctx->uBlockLength = 128; ctx->uRounds = 10; ctx->hashsize = _mm_set_epi32(0, 0, 0, 0x00000200); ctx->const1536 = _mm_set_epi32(0x00000000, 0x00000000, 0x00000000, 0x00000400); break; default: return BAD_HASHBITLEN; } for(i = 0; i < 4; i++) for(j = 0; j < nHashSize / 256; j++) ctx->state[i][j] = ctx->hashsize; for(i = 0; i < 4; i++) for(j = nHashSize / 256; j < 4; j++) ctx->state[i][j] = _mm_set_epi32(0, 0, 0, 0); return SUCCESS; } HashReturn update_echo(hashState_echo *state, const BitSequence *data, DataLength databitlen) { unsigned int uByteLength, uBlockCount, uRemainingBytes; uByteLength = (unsigned int)(databitlen / 8); if((state->uBufferBytes + uByteLength) >= state->uBlockLength) { if(state->uBufferBytes != 0) { // Fill the buffer memcpy(state->buffer + state->uBufferBytes, (void*)data, state->uBlockLength - state->uBufferBytes); // Process buffer Compress(state, state->buffer, 1); state->processed_bits += state->uBlockLength * 8; data += state->uBlockLength - state->uBufferBytes; uByteLength -= state->uBlockLength - state->uBufferBytes; } // buffer now does not contain any unprocessed bytes uBlockCount = uByteLength / state->uBlockLength; uRemainingBytes = uByteLength % state->uBlockLength; if(uBlockCount > 0) { Compress(state, data, uBlockCount); state->processed_bits += uBlockCount * state->uBlockLength * 8; data += uBlockCount * state->uBlockLength; } if(uRemainingBytes > 0) { memcpy(state->buffer, (void*)data, uRemainingBytes); } state->uBufferBytes = uRemainingBytes; } else { memcpy(state->buffer + state->uBufferBytes, (void*)data, uByteLength); state->uBufferBytes += uByteLength; } return SUCCESS; } HashReturn final_echo(hashState_echo *state, BitSequence *hashval) { __m128i remainingbits; // Add remaining bytes in the buffer state->processed_bits += state->uBufferBytes * 8; remainingbits = _mm_set_epi32(0, 0, 0, state->uBufferBytes * 8); // Pad with 0x80 state->buffer[state->uBufferBytes++] = 0x80; // Enough buffer space for padding in this block? if((state->uBlockLength - state->uBufferBytes) >= 18) { // Pad with zeros memset(state->buffer + state->uBufferBytes, 0, state->uBlockLength - (state->uBufferBytes + 18)); // Hash size *((unsigned short*)(state->buffer + state->uBlockLength - 18)) = state->uHashSize; // Processed bits *((DataLength*)(state->buffer + state->uBlockLength - 16)) = state->processed_bits; *((DataLength*)(state->buffer + state->uBlockLength - 8)) = 0; // Last block contains message bits? if(state->uBufferBytes == 1) { state->k = _mm_xor_si128(state->k, state->k); state->k = _mm_sub_epi64(state->k, state->const1536); } else { state->k = _mm_add_epi64(state->k, remainingbits); state->k = _mm_sub_epi64(state->k, state->const1536); } // Compress Compress(state, state->buffer, 1); } else { // Fill with zero and compress memset(state->buffer + state->uBufferBytes, 0, state->uBlockLength - state->uBufferBytes); state->k = _mm_add_epi64(state->k, remainingbits); state->k = _mm_sub_epi64(state->k, state->const1536); Compress(state, state->buffer, 1); // Last block memset(state->buffer, 0, state->uBlockLength - 18); // Hash size *((unsigned short*)(state->buffer + state->uBlockLength - 18)) = state->uHashSize; // Processed bits *((DataLength*)(state->buffer + state->uBlockLength - 16)) = state->processed_bits; *((DataLength*)(state->buffer + state->uBlockLength - 8)) = 0; // Compress the last block state->k = _mm_xor_si128(state->k, state->k); state->k = _mm_sub_epi64(state->k, state->const1536); Compress(state, state->buffer, 1); } // Store the hash value _mm_store_si128((__m128i*)hashval + 0, state->state[0][0]); _mm_store_si128((__m128i*)hashval + 1, state->state[1][0]); if(state->uHashSize == 512) { _mm_store_si128((__m128i*)hashval + 2, state->state[2][0]); _mm_store_si128((__m128i*)hashval + 3, state->state[3][0]); } return SUCCESS; } HashReturn update_final_echo( hashState_echo *state, BitSequence *hashval, const BitSequence *data, DataLength databitlen ) { unsigned int uByteLength, uBlockCount, uRemainingBytes; uByteLength = (unsigned int)(databitlen / 8); if( (state->uBufferBytes + uByteLength) >= state->uBlockLength ) { if( state->uBufferBytes != 0 ) { // Fill the buffer memcpy( state->buffer + state->uBufferBytes, (void*)data, state->uBlockLength - state->uBufferBytes ); // Process buffer Compress( state, state->buffer, 1 ); state->processed_bits += state->uBlockLength * 8; data += state->uBlockLength - state->uBufferBytes; uByteLength -= state->uBlockLength - state->uBufferBytes; } // buffer now does not contain any unprocessed bytes uBlockCount = uByteLength / state->uBlockLength; uRemainingBytes = uByteLength % state->uBlockLength; if( uBlockCount > 0 ) { Compress( state, data, uBlockCount ); state->processed_bits += uBlockCount * state->uBlockLength * 8; data += uBlockCount * state->uBlockLength; } if( uRemainingBytes > 0 ) memcpy(state->buffer, (void*)data, uRemainingBytes); state->uBufferBytes = uRemainingBytes; } else { memcpy( state->buffer + state->uBufferBytes, (void*)data, uByteLength ); state->uBufferBytes += uByteLength; } __m128i remainingbits; // Add remaining bytes in the buffer state->processed_bits += state->uBufferBytes * 8; remainingbits = _mm_set_epi32( 0, 0, 0, state->uBufferBytes * 8 ); // Pad with 0x80 state->buffer[state->uBufferBytes++] = 0x80; // Enough buffer space for padding in this block? if( (state->uBlockLength - state->uBufferBytes) >= 18 ) { // Pad with zeros memset( state->buffer + state->uBufferBytes, 0, state->uBlockLength - (state->uBufferBytes + 18) ); // Hash size *( (unsigned short*)(state->buffer + state->uBlockLength - 18) ) = state->uHashSize; // Processed bits *( (DataLength*)(state->buffer + state->uBlockLength - 16) ) = state->processed_bits; *( (DataLength*)(state->buffer + state->uBlockLength - 8) ) = 0; // Last block contains message bits? if( state->uBufferBytes == 1 ) { state->k = _mm_xor_si128( state->k, state->k ); state->k = _mm_sub_epi64( state->k, state->const1536 ); } else { state->k = _mm_add_epi64( state->k, remainingbits ); state->k = _mm_sub_epi64( state->k, state->const1536 ); } // Compress Compress( state, state->buffer, 1 ); } else { // Fill with zero and compress memset( state->buffer + state->uBufferBytes, 0, state->uBlockLength - state->uBufferBytes ); state->k = _mm_add_epi64( state->k, remainingbits ); state->k = _mm_sub_epi64( state->k, state->const1536 ); Compress( state, state->buffer, 1 ); // Last block memset( state->buffer, 0, state->uBlockLength - 18 ); // Hash size *( (unsigned short*)(state->buffer + state->uBlockLength - 18) ) = state->uHashSize; // Processed bits *( (DataLength*)(state->buffer + state->uBlockLength - 16) ) = state->processed_bits; *( (DataLength*)(state->buffer + state->uBlockLength - 8) ) = 0; // Compress the last block state->k = _mm_xor_si128( state->k, state->k ); state->k = _mm_sub_epi64( state->k, state->const1536 ); Compress( state, state->buffer, 1) ; } // Store the hash value _mm_store_si128( (__m128i*)hashval + 0, state->state[0][0] ); _mm_store_si128( (__m128i*)hashval + 1, state->state[1][0] ); if( state->uHashSize == 512 ) { _mm_store_si128( (__m128i*)hashval + 2, state->state[2][0] ); _mm_store_si128( (__m128i*)hashval + 3, state->state[3][0] ); } return SUCCESS; } HashReturn echo_full( hashState_echo *state, BitSequence *hashval, int nHashSize, const BitSequence *data, DataLength datalen ) { int i, j; state->k = m128_zero; state->processed_bits = 0; state->uBufferBytes = 0; switch( nHashSize ) { case 256: state->uHashSize = 256; state->uBlockLength = 192; state->uRounds = 8; state->hashsize = m128_const_64( 0, 0x100 ); state->const1536 = m128_const_64( 0, 0x600 ); break; case 512: state->uHashSize = 512; state->uBlockLength = 128; state->uRounds = 10; state->hashsize = m128_const_64( 0, 0x200 ); state->const1536 = m128_const_64( 0, 0x400 ); break; default: return BAD_HASHBITLEN; } for(i = 0; i < 4; i++) for(j = 0; j < nHashSize / 256; j++) state->state[i][j] = state->hashsize; for(i = 0; i < 4; i++) for(j = nHashSize / 256; j < 4; j++) state->state[i][j] = m128_zero; unsigned int uBlockCount, uRemainingBytes; if( (state->uBufferBytes + datalen) >= state->uBlockLength ) { if( state->uBufferBytes != 0 ) { // Fill the buffer memcpy( state->buffer + state->uBufferBytes, (void*)data, state->uBlockLength - state->uBufferBytes ); // Process buffer Compress( state, state->buffer, 1 ); state->processed_bits += state->uBlockLength * 8; data += state->uBlockLength - state->uBufferBytes; datalen -= state->uBlockLength - state->uBufferBytes; } // buffer now does not contain any unprocessed bytes uBlockCount = datalen / state->uBlockLength; uRemainingBytes = datalen % state->uBlockLength; if( uBlockCount > 0 ) { Compress( state, data, uBlockCount ); state->processed_bits += uBlockCount * state->uBlockLength * 8; data += uBlockCount * state->uBlockLength; } if( uRemainingBytes > 0 ) memcpy(state->buffer, (void*)data, uRemainingBytes); state->uBufferBytes = uRemainingBytes; } else { memcpy( state->buffer + state->uBufferBytes, (void*)data, datalen ); state->uBufferBytes += datalen; } __m128i remainingbits; // Add remaining bytes in the buffer state->processed_bits += state->uBufferBytes * 8; remainingbits = _mm_set_epi32( 0, 0, 0, state->uBufferBytes * 8 ); // Pad with 0x80 state->buffer[state->uBufferBytes++] = 0x80; // Enough buffer space for padding in this block? if( (state->uBlockLength - state->uBufferBytes) >= 18 ) { // Pad with zeros memset( state->buffer + state->uBufferBytes, 0, state->uBlockLength - (state->uBufferBytes + 18) ); // Hash size *( (unsigned short*)(state->buffer + state->uBlockLength - 18) ) = state->uHashSize; // Processed bits *( (DataLength*)(state->buffer + state->uBlockLength - 16) ) = state->processed_bits; *( (DataLength*)(state->buffer + state->uBlockLength - 8) ) = 0; // Last block contains message bits? if( state->uBufferBytes == 1 ) { state->k = _mm_xor_si128( state->k, state->k ); state->k = _mm_sub_epi64( state->k, state->const1536 ); } else { state->k = _mm_add_epi64( state->k, remainingbits ); state->k = _mm_sub_epi64( state->k, state->const1536 ); } // Compress Compress( state, state->buffer, 1 ); } else { // Fill with zero and compress memset( state->buffer + state->uBufferBytes, 0, state->uBlockLength - state->uBufferBytes ); state->k = _mm_add_epi64( state->k, remainingbits ); state->k = _mm_sub_epi64( state->k, state->const1536 ); Compress( state, state->buffer, 1 ); // Last block memset( state->buffer, 0, state->uBlockLength - 18 ); // Hash size *( (unsigned short*)(state->buffer + state->uBlockLength - 18) ) = state->uHashSize; // Processed bits *( (DataLength*)(state->buffer + state->uBlockLength - 16) ) = state->processed_bits; *( (DataLength*)(state->buffer + state->uBlockLength - 8) ) = 0; // Compress the last block state->k = _mm_xor_si128( state->k, state->k ); state->k = _mm_sub_epi64( state->k, state->const1536 ); Compress( state, state->buffer, 1) ; } // Store the hash value _mm_store_si128( (__m128i*)hashval + 0, state->state[0][0] ); _mm_store_si128( (__m128i*)hashval + 1, state->state[1][0] ); if( state->uHashSize == 512 ) { _mm_store_si128( (__m128i*)hashval + 2, state->state[2][0] ); _mm_store_si128( (__m128i*)hashval + 3, state->state[3][0] ); } return SUCCESS; } HashReturn hash_echo(int hashbitlen, const BitSequence *data, DataLength databitlen, BitSequence *hashval) { HashReturn hRet; hashState_echo hs; ///// /* __m128i a, b, c, d, t[4], u[4], v[4]; a = _mm_set_epi32(0x0f0e0d0c, 0x0b0a0908, 0x07060504, 0x03020100); b = _mm_set_epi32(0x1f1e1d1c, 0x1b1a1918, 0x17161514, 0x13121110); c = _mm_set_epi32(0x2f2e2d2c, 0x2b2a2928, 0x27262524, 0x23222120); d = _mm_set_epi32(0x3f3e3d3c, 0x3b3a3938, 0x37363534, 0x33323130); t[0] = _mm_unpacklo_epi8(a, b); t[1] = _mm_unpackhi_epi8(a, b); t[2] = _mm_unpacklo_epi8(c, d); t[3] = _mm_unpackhi_epi8(c, d); u[0] = _mm_unpacklo_epi16(t[0], t[2]); u[1] = _mm_unpackhi_epi16(t[0], t[2]); u[2] = _mm_unpacklo_epi16(t[1], t[3]); u[3] = _mm_unpackhi_epi16(t[1], t[3]); t[0] = _mm_unpacklo_epi16(u[0], u[1]); t[1] = _mm_unpackhi_epi16(u[0], u[1]); t[2] = _mm_unpacklo_epi16(u[2], u[3]); t[3] = _mm_unpackhi_epi16(u[2], u[3]); u[0] = _mm_unpacklo_epi8(t[0], t[1]); u[1] = _mm_unpackhi_epi8(t[0], t[1]); u[2] = _mm_unpacklo_epi8(t[2], t[3]); u[3] = _mm_unpackhi_epi8(t[2], t[3]); a = _mm_unpacklo_epi8(u[0], u[1]); b = _mm_unpackhi_epi8(u[0], u[1]); c = _mm_unpacklo_epi8(u[2], u[3]); d = _mm_unpackhi_epi8(u[2], u[3]); */ ///// hRet = init_echo(&hs, hashbitlen); if(hRet != SUCCESS) return hRet; hRet = update_echo(&hs, data, databitlen); if(hRet != SUCCESS) return hRet; hRet = final_echo(&hs, hashval); if(hRet != SUCCESS) return hRet; return SUCCESS; } #endif