#include "x22i-gate.h" #include "algo/blake/blake-hash-4way.h" #include "algo/bmw/bmw-hash-4way.h" #include "algo/echo/aes_ni/hash_api.h" #include "algo/groestl/aes_ni/hash-groestl.h" #include "algo/skein/skein-hash-4way.h" #include "algo/jh/jh-hash-4way.h" #include "algo/keccak/keccak-hash-4way.h" #include "algo/luffa/luffa-hash-2way.h" #include "algo/cubehash/cube-hash-2way.h" #include "algo/shavite/shavite-hash-2way.h" #include "algo/shavite/sph_shavite.h" #include "algo/simd/simd-hash-2way.h" #include "algo/shavite/shavite-hash-2way.h" #include "algo/hamsi/hamsi-hash-4way.h" #include "algo/fugue/fugue-aesni.h" #include "algo/shabal/shabal-hash-4way.h" #include "algo/whirlpool/sph_whirlpool.h" #include "algo/sha/sha-hash-4way.h" #include "algo/haval/haval-hash-4way.h" #include "algo/tiger/sph_tiger.h" #include "algo/lyra2/lyra2.h" #include "algo/gost/sph_gost.h" #include "algo/swifftx/swifftx.h" #if defined(__VAES__) #include "algo/groestl/groestl512-hash-4way.h" #include "algo/shavite/shavite-hash-4way.h" #include "algo/echo/echo-hash-4way.h" #endif #if defined(__SHA__) #include "algo/sha/sph_sha2.h" #endif #if defined(X22I_8WAY) union _x22i_8way_ctx_overlay { blake512_8way_context blake; bmw512_8way_context bmw; skein512_8way_context skein; jh512_8way_context jh; keccak512_8way_context keccak; luffa_4way_context luffa; cube_4way_context cube; simd_4way_context simd; hamsi512_8way_context hamsi; hashState_fugue fugue; shabal512_8way_context shabal; sph_whirlpool_context whirlpool; sha512_8way_context sha512; haval256_5_8way_context haval; sph_tiger_context tiger; sph_gost512_context gost; #if defined(X22I_8WAY_SHA) sph_sha256_context sha256; #else sha256_8way_context sha256; #endif #if defined(__VAES__) groestl512_4way_context groestl; shavite512_4way_context shavite; echo_4way_context echo; #else hashState_groestl groestl; sph_shavite512_context shavite; hashState_echo echo; #endif }; typedef union _x22i_8way_ctx_overlay x22i_8way_ctx_overlay; int x22i_8way_hash( void *output, const void *input, int thrid ) { uint64_t vhash[8*8] __attribute__ ((aligned (128))); uint64_t vhashA[8*8] __attribute__ ((aligned (64))); uint64_t vhashB[8*8] __attribute__ ((aligned (64))); uint64_t hash0[8*4] __attribute__ ((aligned (64))); uint64_t hash1[8*4] __attribute__ ((aligned (64))); uint64_t hash2[8*4] __attribute__ ((aligned (64))); uint64_t hash3[8*4] __attribute__ ((aligned (64))); uint64_t hash4[8*4] __attribute__ ((aligned (64))); uint64_t hash5[8*4] __attribute__ ((aligned (64))); uint64_t hash6[8*4] __attribute__ ((aligned (64))); uint64_t hash7[8*4] __attribute__ ((aligned (64))); // unsigned char hash[64 * 4] __attribute__((aligned(64))) = {0}; unsigned char hashA0[64] __attribute__((aligned(64))) = {0}; unsigned char hashA1[64] __attribute__((aligned(32))) = {0}; unsigned char hashA2[64] __attribute__((aligned(32))) = {0}; unsigned char hashA3[64] __attribute__((aligned(32))) = {0}; unsigned char hashA4[64] __attribute__((aligned(64))) = {0}; unsigned char hashA5[64] __attribute__((aligned(32))) = {0}; unsigned char hashA6[64] __attribute__((aligned(32))) = {0}; unsigned char hashA7[64] __attribute__((aligned(32))) = {0}; x22i_8way_ctx_overlay ctx; blake512_8way_full( &ctx.blake, vhash, input, 80 ); bmw512_8way_full( &ctx.bmw, vhash, vhash, 64 ); #if defined(__VAES__) rintrlv_8x64_4x128( vhashA, vhashB, vhash, 512 ); groestl512_4way_full( &ctx.groestl, vhashA, vhashA, 64 ); groestl512_4way_full( &ctx.groestl, vhashB, vhashB, 64 ); rintrlv_4x128_8x64( vhash, vhashA, vhashB, 512 ); #else dintrlv_8x64_512( hash0, hash1, hash2, hash3, hash4, hash5, hash6, hash7, vhash ); groestl512_full( &ctx.groestl, (char*)hash0, (char*)hash0, 512 ); groestl512_full( &ctx.groestl, (char*)hash1, (char*)hash1, 512 ); groestl512_full( &ctx.groestl, (char*)hash2, (char*)hash2, 512 ); groestl512_full( &ctx.groestl, (char*)hash3, (char*)hash3, 512 ); groestl512_full( &ctx.groestl, (char*)hash4, (char*)hash4, 512 ); groestl512_full( &ctx.groestl, (char*)hash5, (char*)hash5, 512 ); groestl512_full( &ctx.groestl, (char*)hash6, (char*)hash6, 512 ); groestl512_full( &ctx.groestl, (char*)hash7, (char*)hash7, 512 ); intrlv_8x64_512( vhash, hash0, hash1, hash2, hash3, hash4, hash5, hash6, hash7 ); #endif skein512_8way_full( &ctx.skein, vhash, vhash, 64 ); jh512_8way_init( &ctx.jh ); jh512_8way_update( &ctx.jh, vhash, 64 ); jh512_8way_close( &ctx.jh, vhash ); keccak512_8way_init( &ctx.keccak ); keccak512_8way_update( &ctx.keccak, vhash, 64 ); keccak512_8way_close( &ctx.keccak, vhash ); if ( work_restart[thrid].restart ) return 0; rintrlv_8x64_4x128( vhashA, vhashB, vhash, 512 ); luffa512_4way_full( &ctx.luffa, vhashA, vhashA, 64 ); luffa512_4way_full( &ctx.luffa, vhashB, vhashB, 64 ); cube_4way_full( &ctx.cube, vhashA, 512, vhashA, 64 ); cube_4way_full( &ctx.cube, vhashB, 512, vhashB, 64 ); #if defined(__VAES__) shavite512_4way_full( &ctx.shavite, vhashA, vhashA, 64 ); shavite512_4way_full( &ctx.shavite, vhashB, vhashB, 64 ); #else dintrlv_4x128_512( hash0, hash1, hash2, hash3, vhashA ); dintrlv_4x128_512( hash4, hash5, hash6, hash7, vhashB ); sph_shavite512_init( &ctx.shavite ); sph_shavite512( &ctx.shavite, hash0, 64 ); sph_shavite512_close( &ctx.shavite, hash0 ); sph_shavite512_init( &ctx.shavite ); sph_shavite512( &ctx.shavite, hash1, 64 ); sph_shavite512_close( &ctx.shavite, hash1 ); sph_shavite512_init( &ctx.shavite ); sph_shavite512( &ctx.shavite, hash2, 64 ); sph_shavite512_close( &ctx.shavite, hash2 ); sph_shavite512_init( &ctx.shavite ); sph_shavite512( &ctx.shavite, hash3, 64 ); sph_shavite512_close( &ctx.shavite, hash3 ); sph_shavite512_init( &ctx.shavite ); sph_shavite512( &ctx.shavite, hash4, 64 ); sph_shavite512_close( &ctx.shavite, hash4 ); sph_shavite512_init( &ctx.shavite ); sph_shavite512( &ctx.shavite, hash5, 64 ); sph_shavite512_close( &ctx.shavite, hash5 ); sph_shavite512_init( &ctx.shavite ); sph_shavite512( &ctx.shavite, hash6, 64 ); sph_shavite512_close( &ctx.shavite, hash6 ); sph_shavite512_init( &ctx.shavite ); sph_shavite512( &ctx.shavite, hash7, 64 ); sph_shavite512_close( &ctx.shavite, hash7 ); intrlv_4x128_512( vhashA, hash0, hash1, hash2, hash3 ); intrlv_4x128_512( vhashB, hash4, hash5, hash6, hash7 ); #endif simd512_4way_full( &ctx.simd, vhashA, vhashA, 64 ); simd512_4way_full( &ctx.simd, vhashB, vhashB, 64 ); #if defined(__VAES__) echo_4way_full( &ctx.echo, vhashA, 512, vhashA, 64 ); echo_4way_full( &ctx.echo, vhashB, 512, vhashB, 64 ); rintrlv_4x128_8x64( vhash, vhashA, vhashB, 512 ); #else dintrlv_4x128_512( hash0, hash1, hash2, hash3, vhashA ); dintrlv_4x128_512( hash4, hash5, hash6, hash7, vhashB ); echo_full( &ctx.echo, (BitSequence *)hash0, 512, (const BitSequence *)hash0, 64 ); echo_full( &ctx.echo, (BitSequence *)hash1, 512, (const BitSequence *)hash1, 64 ); echo_full( &ctx.echo, (BitSequence *)hash2, 512, (const BitSequence *)hash2, 64 ); echo_full( &ctx.echo, (BitSequence *)hash3, 512, (const BitSequence *)hash3, 64 ); echo_full( &ctx.echo, (BitSequence *)hash4, 512, (const BitSequence *)hash4, 64 ); echo_full( &ctx.echo, (BitSequence *)hash5, 512, (const BitSequence *)hash5, 64 ); echo_full( &ctx.echo, (BitSequence *)hash6, 512, (const BitSequence *)hash6, 64 ); echo_full( &ctx.echo, (BitSequence *)hash7, 512, (const BitSequence *)hash7, 64 ); intrlv_8x64_512( vhash, hash0, hash1, hash2, hash3, hash4, hash5, hash6, hash7 ); #endif if ( work_restart[thrid].restart ) return 0; hamsi512_8way_init( &ctx.hamsi ); hamsi512_8way_update( &ctx.hamsi, vhash, 64 ); hamsi512_8way_close( &ctx.hamsi, vhash ); dintrlv_8x64_512( hash0, hash1, hash2, hash3, hash4, hash5, hash6, hash7, vhash ); fugue512_full( &ctx.fugue, hash0, hash0, 64 ); fugue512_full( &ctx.fugue, hash1, hash1, 64 ); fugue512_full( &ctx.fugue, hash2, hash2, 64 ); fugue512_full( &ctx.fugue, hash3, hash3, 64 ); fugue512_full( &ctx.fugue, hash4, hash4, 64 ); fugue512_full( &ctx.fugue, hash5, hash5, 64 ); fugue512_full( &ctx.fugue, hash6, hash6, 64 ); fugue512_full( &ctx.fugue, hash7, hash7, 64 ); intrlv_8x32_512( vhash, hash0, hash1, hash2, hash3, hash4, hash5, hash6, hash7 ); shabal512_8way_init( &ctx.shabal ); shabal512_8way_update( &ctx.shabal, vhash, 64 ); shabal512_8way_close( &ctx.shabal, vhash ); dintrlv_8x32_512( &hash0[8], &hash1[8], &hash2[8], &hash3[8], &hash4[8], &hash5[8], &hash6[8], &hash7[8], vhash ); sph_whirlpool_init( &ctx.whirlpool ); sph_whirlpool( &ctx.whirlpool, &hash0[8], 64 ); sph_whirlpool_close( &ctx.whirlpool, &hash0[16] ); sph_whirlpool_init( &ctx.whirlpool ); sph_whirlpool( &ctx.whirlpool, &hash1[8], 64 ); sph_whirlpool_close( &ctx.whirlpool, &hash1[16] ); sph_whirlpool_init( &ctx.whirlpool ); sph_whirlpool( &ctx.whirlpool, &hash2[8], 64 ); sph_whirlpool_close( &ctx.whirlpool, &hash2[16] ); sph_whirlpool_init( &ctx.whirlpool ); sph_whirlpool( &ctx.whirlpool, &hash3[8], 64 ); sph_whirlpool_close( &ctx.whirlpool, &hash3[16] ); sph_whirlpool_init( &ctx.whirlpool ); sph_whirlpool( &ctx.whirlpool, &hash4[8], 64 ); sph_whirlpool_close( &ctx.whirlpool, &hash4[16] ); sph_whirlpool_init( &ctx.whirlpool ); sph_whirlpool( &ctx.whirlpool, &hash5[8], 64 ); sph_whirlpool_close( &ctx.whirlpool, &hash5[16] ); sph_whirlpool_init( &ctx.whirlpool ); sph_whirlpool( &ctx.whirlpool, &hash6[8], 64 ); sph_whirlpool_close( &ctx.whirlpool, &hash6[16] ); sph_whirlpool_init( &ctx.whirlpool ); sph_whirlpool( &ctx.whirlpool, &hash7[8], 64 ); sph_whirlpool_close( &ctx.whirlpool, &hash7[16] ); intrlv_8x64_512( vhash, &hash0[16], &hash1[16], &hash2[16], &hash3[16], &hash4[16], &hash5[16], &hash6[16], &hash7[16] ); sha512_8way_init( &ctx.sha512 ); sha512_8way_update( &ctx.sha512, vhash, 64 ); sha512_8way_close( &ctx.sha512, vhash ); dintrlv_8x64_512( &hash0[24], &hash1[24], &hash2[24], &hash3[24], &hash4[24], &hash5[24], &hash6[24], &hash7[24], vhash ); ComputeSingleSWIFFTX((unsigned char*)hash0, (unsigned char*)hashA0); ComputeSingleSWIFFTX((unsigned char*)hash1, (unsigned char*)hashA1); ComputeSingleSWIFFTX((unsigned char*)hash2, (unsigned char*)hashA2); ComputeSingleSWIFFTX((unsigned char*)hash3, (unsigned char*)hashA3); ComputeSingleSWIFFTX((unsigned char*)hash4, (unsigned char*)hashA4); ComputeSingleSWIFFTX((unsigned char*)hash5, (unsigned char*)hashA5); ComputeSingleSWIFFTX((unsigned char*)hash6, (unsigned char*)hashA6); ComputeSingleSWIFFTX((unsigned char*)hash7, (unsigned char*)hashA7); intrlv_8x32_512( vhashA, hashA0, hashA1, hashA2, hashA3, hashA4, hashA5, hashA6, hashA7 ); memset( vhash, 0, 64*8 ); haval256_5_8way_init( &ctx.haval ); haval256_5_8way_update( &ctx.haval, vhashA, 64 ); haval256_5_8way_close( &ctx.haval, vhash ); dintrlv_8x32_512( hash0, hash1, hash2, hash3, hash4, hash5, hash6, hash7, vhash ); memset( hashA0, 0, 64 ); memset( hashA1, 0, 64 ); memset( hashA2, 0, 64 ); memset( hashA3, 0, 64 ); memset( hashA4, 0, 64 ); memset( hashA5, 0, 64 ); memset( hashA6, 0, 64 ); memset( hashA7, 0, 64 ); sph_tiger_init(&ctx.tiger); sph_tiger (&ctx.tiger, (const void*) hash0, 64); sph_tiger_close(&ctx.tiger, (void*) hashA0); sph_tiger_init(&ctx.tiger); sph_tiger (&ctx.tiger, (const void*) hash1, 64); sph_tiger_close(&ctx.tiger, (void*) hashA1); sph_tiger_init(&ctx.tiger); sph_tiger (&ctx.tiger, (const void*) hash2, 64); sph_tiger_close(&ctx.tiger, (void*) hashA2); sph_tiger_init(&ctx.tiger); sph_tiger (&ctx.tiger, (const void*) hash3, 64); sph_tiger_close(&ctx.tiger, (void*) hashA3); sph_tiger_init(&ctx.tiger); sph_tiger (&ctx.tiger, (const void*) hash4, 64); sph_tiger_close(&ctx.tiger, (void*) hashA4); sph_tiger_init(&ctx.tiger); sph_tiger (&ctx.tiger, (const void*) hash5, 64); sph_tiger_close(&ctx.tiger, (void*) hashA5); sph_tiger_init(&ctx.tiger); sph_tiger (&ctx.tiger, (const void*) hash6, 64); sph_tiger_close(&ctx.tiger, (void*) hashA6); sph_tiger_init(&ctx.tiger); sph_tiger (&ctx.tiger, (const void*) hash7, 64); sph_tiger_close(&ctx.tiger, (void*) hashA7); if ( work_restart[thrid].restart ) return 0; memset( hash0, 0, 64 ); memset( hash1, 0, 64 ); memset( hash2, 0, 64 ); memset( hash3, 0, 64 ); memset( hash4, 0, 64 ); memset( hash5, 0, 64 ); memset( hash6, 0, 64 ); memset( hash7, 0, 64 ); intrlv_2x256( vhash, hashA0, hashA1, 256 ); LYRA2X_2WAY( vhash, 32, vhash, 32, 1, 4, 4 ); dintrlv_2x256( hash0, hash1, vhash, 256 ); intrlv_2x256( vhash, hashA2, hashA3, 256 ); LYRA2X_2WAY( vhash, 32, vhash, 32, 1, 4, 4 ); dintrlv_2x256( hash2, hash3, vhash, 256 ); intrlv_2x256( vhash, hashA4, hashA5, 256 ); LYRA2X_2WAY( vhash, 32, vhash, 32, 1, 4, 4 ); dintrlv_2x256( hash4, hash5, vhash, 256 ); intrlv_2x256( vhash, hashA6, hashA7, 256 ); LYRA2X_2WAY( vhash, 32, vhash, 32, 1, 4, 4 ); dintrlv_2x256( hash6, hash7, vhash, 256 ); sph_gost512_init( &ctx.gost ); sph_gost512 ( &ctx.gost, (const void*) hash0, 64 ); sph_gost512_close( &ctx.gost, (void*) hash0 ); sph_gost512_init( &ctx.gost ); sph_gost512 ( &ctx.gost, (const void*) hash1, 64 ); sph_gost512_close( &ctx.gost, (void*) hash1 ); sph_gost512_init( &ctx.gost ); sph_gost512 ( &ctx.gost, (const void*) hash2, 64 ); sph_gost512_close( &ctx.gost, (void*) hash2 ); sph_gost512_init( &ctx.gost ); sph_gost512 ( &ctx.gost, (const void*) hash3, 64 ); sph_gost512_close( &ctx.gost, (void*) hash3 ); sph_gost512_init( &ctx.gost ); sph_gost512 ( &ctx.gost, (const void*) hash4, 64 ); sph_gost512_close( &ctx.gost, (void*) hash4 ); sph_gost512_init( &ctx.gost ); sph_gost512 ( &ctx.gost, (const void*) hash5, 64 ); sph_gost512_close( &ctx.gost, (void*) hash5 ); sph_gost512_init( &ctx.gost ); sph_gost512 ( &ctx.gost, (const void*) hash6, 64 ); sph_gost512_close( &ctx.gost, (void*) hash6 ); sph_gost512_init( &ctx.gost ); sph_gost512 ( &ctx.gost, (const void*) hash7, 64 ); sph_gost512_close( &ctx.gost, (void*) hash7 ); #if defined(X22I_8WAY_SHA) sph_sha256_init( &ctx.sha256 ); sph_sha256( &ctx.sha256, hash0, 64 ); sph_sha256_close( &ctx.sha256, output ); sph_sha256_init( &ctx.sha256 ); sph_sha256( &ctx.sha256, hash1, 64 ); sph_sha256_close( &ctx.sha256, output+32 ); sph_sha256_init( &ctx.sha256 ); sph_sha256( &ctx.sha256, hash2, 64 ); sph_sha256_close( &ctx.sha256, output+64 ); sph_sha256_init( &ctx.sha256 ); sph_sha256( &ctx.sha256, hash3, 64 ); sph_sha256_close( &ctx.sha256, output+96 ); sph_sha256_init( &ctx.sha256 ); sph_sha256( &ctx.sha256, hash4, 64 ); sph_sha256_close( &ctx.sha256, output+128 ); sph_sha256_init( &ctx.sha256 ); sph_sha256( &ctx.sha256, hash5, 64 ); sph_sha256_close( &ctx.sha256, output+160 ); sph_sha256_init( &ctx.sha256 ); sph_sha256( &ctx.sha256, hash6, 64 ); sph_sha256_close( &ctx.sha256, output+192 ); sph_sha256_init( &ctx.sha256 ); sph_sha256( &ctx.sha256, hash7, 64 ); sph_sha256_close( &ctx.sha256, output+224 ); #else intrlv_8x32_512( vhash, hash0, hash1, hash2, hash3, hash4, hash5, hash6, hash7 ); sha256_8way_init( &ctx.sha256 ); sha256_8way_update( &ctx.sha256, vhash, 64 ); sha256_8way_close( &ctx.sha256, output ); #endif return 1; } #if defined(X22I_8WAY_SHA) int scanhash_x22i_8way_sha( struct work *work, uint32_t max_nonce, uint64_t *hashes_done, struct thr_info *mythr ) { uint32_t hash[8*8] __attribute__ ((aligned (128))); uint32_t vdata[20*8] __attribute__ ((aligned (64))); uint32_t *pdata = work->data; uint32_t *ptarget = work->target; const uint32_t first_nonce = pdata[19]; const uint32_t last_nonce = max_nonce - 8; __m512i *noncev = (__m512i*)vdata + 9; uint32_t n = first_nonce; const int thr_id = mythr->id; const bool bench = opt_benchmark; if ( bench ) ptarget[7] = 0x08ff; InitializeSWIFFTX(); mm512_bswap32_intrlv80_8x64( vdata, pdata ); *noncev = mm512_intrlv_blend_32( _mm512_set_epi32( n+7, 0, n+6, 0, n+5, 0, n+4, 0, n+3, 0, n+2, 0, n+1, 0, n, 0 ), *noncev ); do { if ( x22i_8way_hash( hash, vdata, thr_id ) ) for ( int i = 0; i < 8; i++ ) if ( unlikely( valid_hash( hash + (i<<3), ptarget ) && !bench ) ) { pdata[19] = bswap_32( n+i ); submit_solution( work, hash+(i<<3), mythr ); } *noncev = _mm512_add_epi32( *noncev, m512_const1_64( 0x0000000800000000 ) ); n += 8; } while ( likely( ( n < last_nonce ) && !work_restart[thr_id].restart ) ); pdata[19] = n; *hashes_done = n - first_nonce; return 0; } #else int scanhash_x22i_8way( struct work *work, uint32_t max_nonce, uint64_t *hashes_done, struct thr_info *mythr ) { uint32_t hash[8*8] __attribute__ ((aligned (128))); uint32_t vdata[20*8] __attribute__ ((aligned (64))); uint32_t lane_hash[8] __attribute__ ((aligned (64))); uint32_t *hashd7 = &(hash[7*8]); uint32_t *pdata = work->data; uint32_t *ptarget = work->target; const uint32_t first_nonce = pdata[19]; const uint32_t last_nonce = max_nonce - 8; __m512i *noncev = (__m512i*)vdata + 9; uint32_t n = first_nonce; const int thr_id = mythr->id; const uint32_t targ32 = ptarget[7]; const bool bench = opt_benchmark; if ( bench ) ptarget[7] = 0x08ff; InitializeSWIFFTX(); mm512_bswap32_intrlv80_8x64( vdata, pdata ); *noncev = mm512_intrlv_blend_32( _mm512_set_epi32( n+7, 0, n+6, 0, n+5, 0, n+4, 0, n+3, 0, n+2, 0, n+1, 0, n, 0 ), *noncev ); do { if ( x22i_8way_hash( hash, vdata, thr_id ) ) for ( int lane = 0; lane < 8; lane++ ) if ( unlikely( ( hashd7[ lane ] <= targ32 ) && !bench ) ) { extr_lane_8x32( lane_hash, hash, lane, 256 ); if ( likely( valid_hash( lane_hash, ptarget ) ) ) { pdata[19] = bswap_32( n + lane ); submit_solution( work, lane_hash, mythr ); } } *noncev = _mm512_add_epi32( *noncev, m512_const1_64( 0x0000000800000000 ) ); n += 8; } while ( likely( ( n < last_nonce ) && !work_restart[thr_id].restart ) ); pdata[19] = n; *hashes_done = n - first_nonce; return 0; } #endif #elif defined(X22I_4WAY) union _x22i_4way_ctx_overlay { blake512_4way_context blake; bmw512_4way_context bmw; #if defined(__VAES__) groestl512_2way_context groestl; echo_2way_context echo; #else hashState_groestl groestl; hashState_echo echo; #endif shavite512_2way_context shavite; skein512_4way_context skein; jh512_4way_context jh; keccak512_4way_context keccak; luffa_2way_context luffa; cube_2way_context cube; simd_2way_context simd; hamsi512_4way_context hamsi; hashState_fugue fugue; shabal512_4way_context shabal; sph_whirlpool_context whirlpool; sha512_4way_context sha512; haval256_5_4way_context haval; sph_tiger_context tiger; sph_gost512_context gost; #if defined(X22I_4WAY_SHA) sph_sha256_context sha256; #else sha256_4way_context sha256; #endif }; typedef union _x22i_4way_ctx_overlay x22i_ctx_overlay; int x22i_4way_hash( void *output, const void *input, int thrid ) { uint64_t hash0[8*4] __attribute__ ((aligned (64))); uint64_t hash1[8*4] __attribute__ ((aligned (64))); uint64_t hash2[8*4] __attribute__ ((aligned (64))); uint64_t hash3[8*4] __attribute__ ((aligned (64))); uint64_t vhash[8*4] __attribute__ ((aligned (64))); uint64_t vhashA[8*4] __attribute__ ((aligned (64))); uint64_t vhashB[8*4] __attribute__ ((aligned (64))); unsigned char hashA0[64] __attribute__((aligned(64))) = {0}; unsigned char hashA1[64] __attribute__((aligned(32))) = {0}; unsigned char hashA2[64] __attribute__((aligned(32))) = {0}; unsigned char hashA3[64] __attribute__((aligned(32))) = {0}; x22i_ctx_overlay ctx; blake512_4way_full( &ctx.blake, vhash, input, 80 ); bmw512_4way_init( &ctx.bmw ); bmw512_4way_update( &ctx.bmw, vhash, 64 ); bmw512_4way_close( &ctx.bmw, vhash ); #if defined(__VAES__) rintrlv_4x64_2x128( vhashA, vhashB, vhash, 512 ); groestl512_2way_full( &ctx.groestl, vhashA, vhashA, 64 ); groestl512_2way_full( &ctx.groestl, vhashB, vhashB, 64 ); rintrlv_2x128_4x64( vhash, vhashA, vhashB, 512 ); #else dintrlv_4x64_512( hash0, hash1, hash2, hash3, vhash ); groestl512_full( &ctx.groestl, (char*)hash0, (char*)hash0, 512 ); groestl512_full( &ctx.groestl, (char*)hash1, (char*)hash1, 512 ); groestl512_full( &ctx.groestl, (char*)hash2, (char*)hash2, 512 ); groestl512_full( &ctx.groestl, (char*)hash3, (char*)hash3, 512 ); intrlv_4x64_512( vhash, hash0, hash1, hash2, hash3 ); #endif skein512_4way_full( &ctx.skein, vhash, vhash, 64 ); jh512_4way_init( &ctx.jh ); jh512_4way_update( &ctx.jh, vhash, 64 ); jh512_4way_close( &ctx.jh, vhash ); keccak512_4way_init( &ctx.keccak ); keccak512_4way_update( &ctx.keccak, vhash, 64 ); keccak512_4way_close( &ctx.keccak, vhash ); if ( work_restart[thrid].restart ) return false; rintrlv_4x64_2x128( vhashA, vhashB, vhash, 512 ); luffa512_2way_full( &ctx.luffa, vhashA, vhashA, 64 ); luffa512_2way_full( &ctx.luffa, vhashB, vhashB, 64 ); cube_2way_full( &ctx.cube, vhashA, 512, vhashA, 64 ); cube_2way_full( &ctx.cube, vhashB, 512, vhashB, 64 ); shavite512_2way_full( &ctx.shavite, vhashA, vhashA, 64 ); shavite512_2way_full( &ctx.shavite, vhashB, vhashB, 64 ); simd512_2way_full( &ctx.simd, vhashA, vhashA, 64 ); simd512_2way_full( &ctx.simd, vhashB, vhashB, 64 ); #if defined(__VAES__) echo_2way_full( &ctx.echo, vhashA, 512, vhashA, 64 ); echo_2way_full( &ctx.echo, vhashB, 512, vhashB, 64 ); rintrlv_2x128_4x64( vhash, vhashA, vhashB, 512 ); #else dintrlv_2x128_512( hash0, hash1, vhashA ); dintrlv_2x128_512( hash2, hash3, vhashB ); echo_full( &ctx.echo, (BitSequence *)hash0, 512, (const BitSequence *)hash0, 64 ); echo_full( &ctx.echo, (BitSequence *)hash1, 512, (const BitSequence *)hash1, 64 ); echo_full( &ctx.echo, (BitSequence *)hash2, 512, (const BitSequence *)hash2, 64 ); echo_full( &ctx.echo, (BitSequence *)hash3, 512, (const BitSequence *)hash3, 64 ); intrlv_4x64_512( vhash, hash0, hash1, hash2, hash3 ); #endif if ( work_restart[thrid].restart ) return false; hamsi512_4way_init( &ctx.hamsi ); hamsi512_4way_update( &ctx.hamsi, vhash, 64 ); hamsi512_4way_close( &ctx.hamsi, vhash ); dintrlv_4x64_512( hash0, hash1, hash2, hash3, vhash ); fugue512_full( &ctx.fugue, hash0, hash0, 64 ); fugue512_full( &ctx.fugue, hash1, hash1, 64 ); fugue512_full( &ctx.fugue, hash2, hash2, 64 ); fugue512_full( &ctx.fugue, hash3, hash3, 64 ); intrlv_4x32_512( vhash, hash0, hash1, hash2, hash3 ); shabal512_4way_init( &ctx.shabal ); shabal512_4way_update( &ctx.shabal, vhash, 64 ); shabal512_4way_close( &ctx.shabal, vhash ); dintrlv_4x32_512( &hash0[8], &hash1[8], &hash2[8], &hash3[8], vhash ); sph_whirlpool_init( &ctx.whirlpool ); sph_whirlpool( &ctx.whirlpool, &hash0[8], 64 ); sph_whirlpool_close( &ctx.whirlpool, &hash0[16] ); sph_whirlpool_init( &ctx.whirlpool ); sph_whirlpool( &ctx.whirlpool, &hash1[8], 64 ); sph_whirlpool_close( &ctx.whirlpool, &hash1[16] ); sph_whirlpool_init( &ctx.whirlpool ); sph_whirlpool( &ctx.whirlpool, &hash2[8], 64 ); sph_whirlpool_close( &ctx.whirlpool, &hash2[16] ); sph_whirlpool_init( &ctx.whirlpool ); sph_whirlpool( &ctx.whirlpool, &hash3[8], 64 ); sph_whirlpool_close( &ctx.whirlpool, &hash3[16] ); intrlv_4x64_512( vhash, &hash0[16], &hash1[16], &hash2[16], &hash3[16] ); sha512_4way_init( &ctx.sha512 ); sha512_4way_update( &ctx.sha512, vhash, 64 ); sha512_4way_close( &ctx.sha512, vhash ); dintrlv_4x64_512( &hash0[24], &hash1[24], &hash2[24], &hash3[24], vhash ); if ( work_restart[thrid].restart ) return false; ComputeSingleSWIFFTX((unsigned char*)hash0, (unsigned char*)hashA0); ComputeSingleSWIFFTX((unsigned char*)hash1, (unsigned char*)hashA1); ComputeSingleSWIFFTX((unsigned char*)hash2, (unsigned char*)hashA2); ComputeSingleSWIFFTX((unsigned char*)hash3, (unsigned char*)hashA3); intrlv_4x32_512( vhashA, hashA0, hashA1, hashA2, hashA3 ); memset( vhash, 0, 64*4 ); haval256_5_4way_init( &ctx.haval ); haval256_5_4way_update( &ctx.haval, vhashA, 64 ); haval256_5_4way_close( &ctx.haval, vhash ); dintrlv_4x32_512( hash0, hash1, hash2, hash3, vhash ); memset( hashA0, 0, 64 ); memset( hashA1, 0, 64 ); memset( hashA2, 0, 64 ); memset( hashA3, 0, 64 ); sph_tiger_init(&ctx.tiger); sph_tiger (&ctx.tiger, (const void*) hash0, 64); sph_tiger_close(&ctx.tiger, (void*) hashA0); sph_tiger_init(&ctx.tiger); sph_tiger (&ctx.tiger, (const void*) hash1, 64); sph_tiger_close(&ctx.tiger, (void*) hashA1); sph_tiger_init(&ctx.tiger); sph_tiger (&ctx.tiger, (const void*) hash2, 64); sph_tiger_close(&ctx.tiger, (void*) hashA2); sph_tiger_init(&ctx.tiger); sph_tiger (&ctx.tiger, (const void*) hash3, 64); sph_tiger_close(&ctx.tiger, (void*) hashA3); if ( work_restart[thrid].restart ) return false; memset( hash0, 0, 64 ); memset( hash1, 0, 64 ); memset( hash2, 0, 64 ); memset( hash3, 0, 64 ); LYRA2RE( (void*) hash0, 32, (const void*) hashA0, 32, (const void*) hashA0, 32, 1, 4, 4 ); LYRA2RE( (void*) hash1, 32, (const void*) hashA1, 32, (const void*) hashA1, 32, 1, 4, 4 ); LYRA2RE( (void*) hash2, 32, (const void*) hashA2, 32, (const void*) hashA2, 32, 1, 4, 4 ); LYRA2RE( (void*) hash3, 32, (const void*) hashA3, 32, (const void*) hashA3, 32, 1, 4, 4 ); sph_gost512_init(&ctx.gost); sph_gost512 (&ctx.gost, (const void*) hash0, 64); sph_gost512_close(&ctx.gost, (void*) hash0); sph_gost512_init(&ctx.gost); sph_gost512 (&ctx.gost, (const void*) hash1, 64); sph_gost512_close(&ctx.gost, (void*) hash1); sph_gost512_init(&ctx.gost); sph_gost512 (&ctx.gost, (const void*) hash2, 64); sph_gost512_close(&ctx.gost, (void*) hash2); sph_gost512_init(&ctx.gost); sph_gost512 (&ctx.gost, (const void*) hash3, 64); sph_gost512_close(&ctx.gost, (void*) hash3); #if defined(X22I_4WAY_SHA) sph_sha256_init( &ctx.sha256 ); sph_sha256( &ctx.sha256, hash0, 64 ); sph_sha256_close( &ctx.sha256, output ); sph_sha256_init( &ctx.sha256 ); sph_sha256( &ctx.sha256, hash1, 64 ); sph_sha256_close( &ctx.sha256, output+32 ); sph_sha256_init( &ctx.sha256 ); sph_sha256( &ctx.sha256, hash2, 64 ); sph_sha256_close( &ctx.sha256, output+64 ); sph_sha256_init( &ctx.sha256 ); sph_sha256( &ctx.sha256, hash3, 64 ); sph_sha256_close( &ctx.sha256, output+96 ); #else intrlv_4x32_512( vhash, hash0, hash1, hash2, hash3 ); sha256_4way_init( &ctx.sha256 ); sha256_4way_update( &ctx.sha256, vhash, 64 ); sha256_4way_close( &ctx.sha256, output ); #endif return 1; } #if defined(X22I_4WAY_SHA) int scanhash_x22i_4way_sha( struct work* work, uint32_t max_nonce, uint64_t *hashes_done, struct thr_info *mythr ) { uint32_t hash[8*4] __attribute__ ((aligned (64))); uint32_t vdata[20*4] __attribute__ ((aligned (64))); uint32_t *pdata = work->data; uint32_t *ptarget = work->target; const uint32_t first_nonce = pdata[19]; const uint32_t last_nonce = max_nonce - 4; __m256i *noncev = (__m256i*)vdata + 9; uint32_t n = first_nonce; const int thr_id = mythr->id; const bool bench = opt_benchmark; if ( bench ) ptarget[7] = 0x08ff; InitializeSWIFFTX(); mm256_bswap32_intrlv80_4x64( vdata, pdata ); *noncev = mm256_intrlv_blend_32( _mm256_set_epi32( n+3, 0, n+2, 0, n+1, 0, n, 0 ), *noncev ); do { if ( x22i_4way_hash( hash, vdata, thr_id ) ) for ( int i = 0; i < 4; i++ ) if ( unlikely( valid_hash( hash + (i<<3), ptarget ) && !bench ) ) { pdata[19] = bswap_32( n+i ); submit_solution( work, hash+(i<<3), mythr ); } *noncev = _mm256_add_epi32( *noncev, m256_const1_64( 0x0000000400000000 ) ); n += 4; } while ( likely( ( n < last_nonce ) && !work_restart[thr_id].restart ) ); pdata[19] = n; *hashes_done = n - first_nonce; return 0; } #else int scanhash_x22i_4way( struct work* work, uint32_t max_nonce, uint64_t *hashes_done, struct thr_info *mythr ) { uint32_t hash[8*4] __attribute__ ((aligned (64))); uint32_t vdata[20*4] __attribute__ ((aligned (64))); uint32_t lane_hash[8] __attribute__ ((aligned (64))); uint32_t *hashd7 = &(hash[ 7*4 ]); uint32_t *pdata = work->data; uint32_t *ptarget = work->target; const uint32_t first_nonce = pdata[19]; const uint32_t last_nonce = max_nonce - 4; __m256i *noncev = (__m256i*)vdata + 9; uint32_t n = first_nonce; const int thr_id = mythr->id; const uint32_t targ32 = ptarget[7]; const bool bench = opt_benchmark; if ( bench ) ptarget[7] = 0x08ff; InitializeSWIFFTX(); mm256_bswap32_intrlv80_4x64( vdata, pdata ); *noncev = mm256_intrlv_blend_32( _mm256_set_epi32( n+3, 0, n+2, 0, n+1, 0, n, 0 ), *noncev ); do { if ( x22i_4way_hash( hash, vdata, thr_id ) ) for ( int lane = 0; lane < 4; lane++ ) if ( unlikely( hashd7[ lane ] <= targ32 && !bench ) ) { extr_lane_4x32( lane_hash, hash, lane, 256 ); if ( valid_hash( lane_hash, ptarget ) ) { pdata[19] = bswap_32( n + lane ); submit_solution( work, lane_hash, mythr ); } } *noncev = _mm256_add_epi32( *noncev, m256_const1_64( 0x0000000400000000 ) ); n += 4; } while ( likely( ( n <= last_nonce ) && !work_restart[thr_id].restart ) ); pdata[19] = n; *hashes_done = n - first_nonce; return 0; } #endif #endif // X22I_4WAY