#include "x14-gate.h" #include #include #include #include #include "algo/blake/blake-hash-4way.h" #include "algo/bmw/bmw-hash-4way.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/cubehash/cubehash_sse2.h" #include "algo/shavite/sph_shavite.h" #include "algo/simd/simd-hash-2way.h" #include "algo/echo/aes_ni/hash_api.h" #include "algo/echo/sph_echo.h" #include "algo/hamsi/hamsi-hash-4way.h" #include "algo/fugue/sph_fugue.h" #include "algo/shabal/shabal-hash-4way.h" #if defined(X14_8WAY) typedef struct { blake512_8way_context blake; bmw512_8way_context bmw; hashState_groestl groestl; skein512_8way_context skein; jh512_8way_context jh; keccak512_8way_context keccak; luffa_4way_context luffa; cube_4way_context cube; sph_shavite512_context shavite; simd_4way_context simd; hashState_echo echo; hamsi512_8way_context hamsi; sph_fugue512_context fugue; shabal512_8way_context shabal; } x14_8way_ctx_holder; x14_8way_ctx_holder x14_8way_ctx __attribute__ ((aligned (64))); void init_x14_8way_ctx() { blake512_8way_init( &x14_8way_ctx.blake ); bmw512_8way_init( &x14_8way_ctx.bmw ); init_groestl( &x14_8way_ctx.groestl, 64 ); skein512_8way_init( &x14_8way_ctx.skein ); jh512_8way_init( &x14_8way_ctx.jh ); keccak512_8way_init( &x14_8way_ctx.keccak ); luffa_4way_init( &x14_8way_ctx.luffa, 512 ); cube_4way_init( &x14_8way_ctx.cube, 512, 16, 32 ); sph_shavite512_init( &x14_8way_ctx.shavite ); simd_4way_init( &x14_8way_ctx.simd, 512 ); init_echo( &x14_8way_ctx.echo, 512 ); hamsi512_8way_init( &x14_8way_ctx.hamsi ); sph_fugue512_init( &x14_8way_ctx.fugue ); shabal512_8way_init( &x14_8way_ctx.shabal ); }; void x14_8way_hash( void *state, const void *input ) { uint64_t vhash[8*8] __attribute__ ((aligned (128))); uint64_t hash0[8] __attribute__ ((aligned (64))); uint64_t hash1[8] __attribute__ ((aligned (64))); uint64_t hash2[8] __attribute__ ((aligned (64))); uint64_t hash3[8] __attribute__ ((aligned (64))); uint64_t hash4[8] __attribute__ ((aligned (64))); uint64_t hash5[8] __attribute__ ((aligned (64))); uint64_t hash6[8] __attribute__ ((aligned (64))); uint64_t hash7[8] __attribute__ ((aligned (64))); x14_8way_ctx_holder ctx; memcpy( &ctx, &x14_8way_ctx, sizeof(x14_8way_ctx) ); blake512_8way_update( &ctx.blake, input, 80 ); blake512_8way_close( &ctx.blake, vhash ); bmw512_8way_update( &ctx.bmw, vhash, 64 ); bmw512_8way_close( &ctx.bmw, vhash ); dintrlv_8x64_512( hash0, hash1, hash2, hash3, hash4, hash5, hash6, hash7, vhash ); update_and_final_groestl( &ctx.groestl, (char*)hash0, (char*)hash0, 512 ); memcpy( &ctx.groestl, &x14_8way_ctx.groestl, sizeof(hashState_groestl) ); update_and_final_groestl( &ctx.groestl, (char*)hash1, (char*)hash1, 512 ); memcpy( &ctx.groestl, &x14_8way_ctx.groestl, sizeof(hashState_groestl) ); update_and_final_groestl( &ctx.groestl, (char*)hash2, (char*)hash2, 512 ); memcpy( &ctx.groestl, &x14_8way_ctx.groestl, sizeof(hashState_groestl) ); update_and_final_groestl( &ctx.groestl, (char*)hash3, (char*)hash3, 512 ); memcpy( &ctx.groestl, &x14_8way_ctx.groestl, sizeof(hashState_groestl) ); update_and_final_groestl( &ctx.groestl, (char*)hash4, (char*)hash4, 512 ); memcpy( &ctx.groestl, &x14_8way_ctx.groestl, sizeof(hashState_groestl) ); update_and_final_groestl( &ctx.groestl, (char*)hash5, (char*)hash5, 512 ); memcpy( &ctx.groestl, &x14_8way_ctx.groestl, sizeof(hashState_groestl) ); update_and_final_groestl( &ctx.groestl, (char*)hash6, (char*)hash6, 512 ); memcpy( &ctx.groestl, &x14_8way_ctx.groestl, sizeof(hashState_groestl) ); update_and_final_groestl( &ctx.groestl, (char*)hash7, (char*)hash7, 512 ); intrlv_8x64_512( vhash, hash0, hash1, hash2, hash3, hash4, hash5, hash6, hash7 ); skein512_8way_update( &ctx.skein, vhash, 64 ); skein512_8way_close( &ctx.skein, vhash ); jh512_8way_update( &ctx.jh, vhash, 64 ); jh512_8way_close( &ctx.jh, vhash ); keccak512_8way_update( &ctx.keccak, vhash, 64 ); keccak512_8way_close( &ctx.keccak, vhash ); dintrlv_8x64_512( hash0, hash1, hash2, hash3, hash4, hash5, hash6, hash7, vhash ); // Luffa + Cube intrlv_4x128_512( vhash, hash0, hash1, hash2, hash3 ); luffa_4way_update_close( &ctx.luffa, vhash, vhash, 64 ); cube_4way_update_close( &ctx.cube, vhash, vhash, 64 ); dintrlv_4x128_512( hash0, hash1, hash2, hash3, vhash ); intrlv_4x128_512( vhash, hash4, hash5, hash6, hash7 ); luffa_4way_init( &ctx.luffa, 512 ); cube_4way_init( &ctx.cube, 512, 16, 32 ); luffa_4way_update_close( &ctx.luffa, vhash, vhash, 64 ); cube_4way_update_close( &ctx.cube, vhash, vhash, 64 ); dintrlv_4x128_512( hash4, hash5, hash6, hash7, vhash ); sph_shavite512( &ctx.shavite, hash0, 64 ); sph_shavite512_close( &ctx.shavite, hash0 ); memcpy( &ctx.shavite, &x14_8way_ctx.shavite, sizeof(sph_shavite512_context) ); sph_shavite512( &ctx.shavite, hash1, 64 ); sph_shavite512_close( &ctx.shavite, hash1 ); memcpy( &ctx.shavite, &x14_8way_ctx.shavite, sizeof(sph_shavite512_context) ); sph_shavite512( &ctx.shavite, hash2, 64 ); sph_shavite512_close( &ctx.shavite, hash2 ); memcpy( &ctx.shavite, &x14_8way_ctx.shavite, sizeof(sph_shavite512_context) ); sph_shavite512( &ctx.shavite, hash3, 64 ); sph_shavite512_close( &ctx.shavite, hash3 ); memcpy( &ctx.shavite, &x14_8way_ctx.shavite, sizeof(sph_shavite512_context) ); sph_shavite512( &ctx.shavite, hash4, 64 ); sph_shavite512_close( &ctx.shavite, hash4 ); memcpy( &ctx.shavite, &x14_8way_ctx.shavite, sizeof(sph_shavite512_context) ); sph_shavite512( &ctx.shavite, hash5, 64 ); sph_shavite512_close( &ctx.shavite, hash5 ); memcpy( &ctx.shavite, &x14_8way_ctx.shavite, sizeof(sph_shavite512_context) ); sph_shavite512( &ctx.shavite, hash6, 64 ); sph_shavite512_close( &ctx.shavite, hash6 ); memcpy( &ctx.shavite, &x14_8way_ctx.shavite, sizeof(sph_shavite512_context) ); sph_shavite512( &ctx.shavite, hash7, 64 ); sph_shavite512_close( &ctx.shavite, hash7 ); intrlv_4x128_512( vhash, hash0, hash1, hash2, hash3 ); simd_4way_update_close( &ctx.simd, vhash, vhash, 512 ); dintrlv_4x128_512( hash0, hash1, hash2, hash3, vhash ); intrlv_4x128_512( vhash, hash4, hash5, hash6, hash7 ); simd_4way_init( &ctx.simd, 512 ); simd_4way_update_close( &ctx.simd, vhash, vhash, 512 ); dintrlv_4x128_512( hash4, hash5, hash6, hash7, vhash ); update_final_echo( &ctx.echo, (BitSequence *)hash0, (const BitSequence *) hash0, 512 ); memcpy( &ctx.echo, &x14_8way_ctx.echo, sizeof(hashState_echo) ); update_final_echo( &ctx.echo, (BitSequence *)hash1, (const BitSequence *) hash1, 512 ); memcpy( &ctx.echo, &x14_8way_ctx.echo, sizeof(hashState_echo) ); update_final_echo( &ctx.echo, (BitSequence *)hash2, (const BitSequence *) hash2, 512 ); memcpy( &ctx.echo, &x14_8way_ctx.echo, sizeof(hashState_echo) ); update_final_echo( &ctx.echo, (BitSequence *)hash3, (const BitSequence *) hash3, 512 ); memcpy( &ctx.echo, &x14_8way_ctx.echo, sizeof(hashState_echo) ); update_final_echo( &ctx.echo, (BitSequence *)hash4, (const BitSequence *) hash4, 512 ); memcpy( &ctx.echo, &x14_8way_ctx.echo, sizeof(hashState_echo) ); update_final_echo( &ctx.echo, (BitSequence *)hash5, (const BitSequence *) hash5, 512 ); memcpy( &ctx.echo, &x14_8way_ctx.echo, sizeof(hashState_echo) ); update_final_echo( &ctx.echo, (BitSequence *)hash6, (const BitSequence *) hash6, 512 ); memcpy( &ctx.echo, &x14_8way_ctx.echo, sizeof(hashState_echo) ); update_final_echo( &ctx.echo, (BitSequence *)hash7, (const BitSequence *) hash7, 512 ); intrlv_8x64_512( vhash, hash0, hash1, hash2, hash3, hash4, hash5, hash6, hash7 ); 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 ); // 13 Fugue serial sph_fugue512( &ctx.fugue, hash0, 64 ); sph_fugue512_close( &ctx.fugue, hash0 ); memcpy( &ctx.fugue, &x14_8way_ctx.fugue, sizeof(sph_fugue512_context) ); sph_fugue512( &ctx.fugue, hash1, 64 ); sph_fugue512_close( &ctx.fugue, hash1 ); memcpy( &ctx.fugue, &x14_8way_ctx.fugue, sizeof(sph_fugue512_context) ); sph_fugue512( &ctx.fugue, hash2, 64 ); sph_fugue512_close( &ctx.fugue, hash2 ); memcpy( &ctx.fugue, &x14_8way_ctx.fugue, sizeof(sph_fugue512_context) ); sph_fugue512( &ctx.fugue, hash3, 64 ); sph_fugue512_close( &ctx.fugue, hash3 ); memcpy( &ctx.fugue, &x14_8way_ctx.fugue, sizeof(sph_fugue512_context) ); sph_fugue512( &ctx.fugue, hash4, 64 ); sph_fugue512_close( &ctx.fugue, hash4 ); memcpy( &ctx.fugue, &x14_8way_ctx.fugue, sizeof(sph_fugue512_context) ); sph_fugue512( &ctx.fugue, hash5, 64 ); sph_fugue512_close( &ctx.fugue, hash5 ); memcpy( &ctx.fugue, &x14_8way_ctx.fugue, sizeof(sph_fugue512_context) ); sph_fugue512( &ctx.fugue, hash6, 64 ); sph_fugue512_close( &ctx.fugue, hash6 ); memcpy( &ctx.fugue, &x14_8way_ctx.fugue, sizeof(sph_fugue512_context) ); sph_fugue512( &ctx.fugue, hash7, 64 ); sph_fugue512_close( &ctx.fugue, hash7 ); // 14 Shabal, parallel 32 bit intrlv_8x32_512( vhash, hash0, hash1, hash2, hash3, hash4, hash5, hash6, hash7 ); shabal512_8way_update( &ctx.shabal, vhash, 64 ); shabal512_8way_close( &ctx.shabal, state ); } int scanhash_x14_8way( struct work *work, uint32_t max_nonce, uint64_t *hashes_done, struct thr_info *mythr ) { uint32_t hash[8*16] __attribute__ ((aligned (64))); uint32_t vdata[24*8] __attribute__ ((aligned (64))); uint32_t *pdata = work->data; uint32_t *ptarget = work->target; uint32_t n = pdata[19]; const uint32_t first_nonce = pdata[19]; const uint32_t last_nonce = max_nonce - 8; __m512i *noncev = (__m512i*)vdata + 9; // aligned const uint32_t Htarg = ptarget[7]; int thr_id = mythr->id; mm512_bswap32_intrlv80_8x64( vdata, pdata ); do { *noncev = mm512_intrlv_blend_32( mm512_bswap_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 ); x14_8way_hash( hash, vdata ); pdata[19] = n; uint32_t *hash7 = &(hash[7<<3]); for ( int lane = 0; lane < 8; lane++ ) if ( hash7[ lane ] < Htarg ) { uint32_t lane_hash[8] __attribute__ ((aligned (64))); extr_lane_8x32( lane_hash, hash, lane, 256 ); if ( fulltest( lane_hash, ptarget ) && !opt_benchmark ) { pdata[19] = n + lane; submit_lane_solution( work, lane_hash, mythr, lane ); } } n += 8; } while ( ( n < last_nonce ) && !work_restart[thr_id].restart ); *hashes_done = n - first_nonce; return 0; } #elif defined(X14_4WAY) typedef struct { blake512_4way_context blake; bmw512_4way_context bmw; hashState_groestl groestl; skein512_4way_context skein; jh512_4way_context jh; keccak512_4way_context keccak; luffa_2way_context luffa; cubehashParam cube; sph_shavite512_context shavite; simd_2way_context simd; hashState_echo echo; hamsi512_4way_context hamsi; sph_fugue512_context fugue; shabal512_4way_context shabal; } x14_4way_ctx_holder; x14_4way_ctx_holder x14_4way_ctx __attribute__ ((aligned (64))); void init_x14_4way_ctx() { blake512_4way_init( &x14_4way_ctx.blake ); bmw512_4way_init( &x14_4way_ctx.bmw ); init_groestl( &x14_4way_ctx.groestl, 64 ); skein512_4way_init( &x14_4way_ctx.skein ); jh512_4way_init( &x14_4way_ctx.jh ); keccak512_4way_init( &x14_4way_ctx.keccak ); luffa_2way_init( &x14_4way_ctx.luffa, 512 ); cubehashInit( &x14_4way_ctx.cube, 512, 16, 32 ); sph_shavite512_init( &x14_4way_ctx.shavite ); simd_2way_init( &x14_4way_ctx.simd, 512 ); init_echo( &x14_4way_ctx.echo, 512 ); hamsi512_4way_init( &x14_4way_ctx.hamsi ); sph_fugue512_init( &x14_4way_ctx.fugue ); shabal512_4way_init( &x14_4way_ctx.shabal ); }; void x14_4way_hash( void *state, const void *input ) { uint64_t vhash[8*4] __attribute__ ((aligned (128))); uint64_t hash0[8] __attribute__ ((aligned (64))); uint64_t hash1[8] __attribute__ ((aligned (64))); uint64_t hash2[8] __attribute__ ((aligned (64))); uint64_t hash3[8] __attribute__ ((aligned (64))); x14_4way_ctx_holder ctx; memcpy( &ctx, &x14_4way_ctx, sizeof(x14_4way_ctx) ); // 1 Blake blake512_4way( &ctx.blake, input, 80 ); blake512_4way_close( &ctx.blake, vhash ); // 2 Bmw bmw512_4way( &ctx.bmw, vhash, 64 ); bmw512_4way_close( &ctx.bmw, vhash ); // Serial dintrlv_4x64( hash0, hash1, hash2, hash3, vhash, 512 ); // 3 Groestl update_and_final_groestl( &ctx.groestl, (char*)hash0, (char*)hash0, 512 ); memcpy( &ctx.groestl, &x14_4way_ctx.groestl, sizeof(hashState_groestl) ); update_and_final_groestl( &ctx.groestl, (char*)hash1, (char*)hash1, 512 ); memcpy( &ctx.groestl, &x14_4way_ctx.groestl, sizeof(hashState_groestl) ); update_and_final_groestl( &ctx.groestl, (char*)hash2, (char*)hash2, 512 ); memcpy( &ctx.groestl, &x14_4way_ctx.groestl, sizeof(hashState_groestl) ); update_and_final_groestl( &ctx.groestl, (char*)hash3, (char*)hash3, 512 ); // Parallel 4way intrlv_4x64( vhash, hash0, hash1, hash2, hash3, 512 ); // 4 Skein skein512_4way( &ctx.skein, vhash, 64 ); skein512_4way_close( &ctx.skein, vhash ); // 5 JH jh512_4way( &ctx.jh, vhash, 64 ); jh512_4way_close( &ctx.jh, vhash ); // 6 Keccak keccak512_4way( &ctx.keccak, vhash, 64 ); keccak512_4way_close( &ctx.keccak, vhash ); // Serial dintrlv_4x64( hash0, hash1, hash2, hash3, vhash, 512 ); // 7 Luffa intrlv_2x128( vhash, hash0, hash1, 512 ); luffa_2way_update_close( &ctx.luffa, vhash, vhash, 64 ); dintrlv_2x128( hash0, hash1, vhash, 512 ); intrlv_2x128( vhash, hash2, hash3, 512 ); luffa_2way_init( &ctx.luffa, 512 ); luffa_2way_update_close( &ctx.luffa, vhash, vhash, 64 ); dintrlv_2x128( hash2, hash3, vhash, 512 ); // 8 Cubehash cubehashUpdateDigest( &ctx.cube, (byte*)hash0, (const byte*) hash0, 64 ); memcpy( &ctx.cube, &x14_4way_ctx.cube, sizeof(cubehashParam) ); cubehashUpdateDigest( &ctx.cube, (byte*)hash1, (const byte*) hash1, 64 ); memcpy( &ctx.cube, &x14_4way_ctx.cube, sizeof(cubehashParam) ); cubehashUpdateDigest( &ctx.cube, (byte*)hash2, (const byte*) hash2, 64 ); memcpy( &ctx.cube, &x14_4way_ctx.cube, sizeof(cubehashParam) ); cubehashUpdateDigest( &ctx.cube, (byte*)hash3, (const byte*) hash3, 64 ); // 9 Shavite sph_shavite512( &ctx.shavite, hash0, 64 ); sph_shavite512_close( &ctx.shavite, hash0 ); memcpy( &ctx.shavite, &x14_4way_ctx.shavite, sizeof(sph_shavite512_context) ); sph_shavite512( &ctx.shavite, hash1, 64 ); sph_shavite512_close( &ctx.shavite, hash1 ); memcpy( &ctx.shavite, &x14_4way_ctx.shavite, sizeof(sph_shavite512_context) ); sph_shavite512( &ctx.shavite, hash2, 64 ); sph_shavite512_close( &ctx.shavite, hash2 ); memcpy( &ctx.shavite, &x14_4way_ctx.shavite, sizeof(sph_shavite512_context) ); sph_shavite512( &ctx.shavite, hash3, 64 ); sph_shavite512_close( &ctx.shavite, hash3 ); // 10 Simd intrlv_2x128( vhash, hash0, hash1, 512 ); simd_2way_update_close( &ctx.simd, vhash, vhash, 512 ); dintrlv_2x128( hash0, hash1, vhash, 512 ); intrlv_2x128( vhash, hash2, hash3, 512 ); simd_2way_init( &ctx.simd, 512 ); simd_2way_update_close( &ctx.simd, vhash, vhash, 512 ); dintrlv_2x128( hash2, hash3, vhash, 512 ); // 11 Echo update_final_echo( &ctx.echo, (BitSequence *)hash0, (const BitSequence *) hash0, 512 ); memcpy( &ctx.echo, &x14_4way_ctx.echo, sizeof(hashState_echo) ); update_final_echo( &ctx.echo, (BitSequence *)hash1, (const BitSequence *) hash1, 512 ); memcpy( &ctx.echo, &x14_4way_ctx.echo, sizeof(hashState_echo) ); update_final_echo( &ctx.echo, (BitSequence *)hash2, (const BitSequence *) hash2, 512 ); memcpy( &ctx.echo, &x14_4way_ctx.echo, sizeof(hashState_echo) ); update_final_echo( &ctx.echo, (BitSequence *)hash3, (const BitSequence *) hash3, 512 ); // 12 Hamsi parallel 4way 32 bit intrlv_4x64( vhash, hash0, hash1, hash2, hash3, 512 ); hamsi512_4way( &ctx.hamsi, vhash, 64 ); hamsi512_4way_close( &ctx.hamsi, vhash ); dintrlv_4x64( hash0, hash1, hash2, hash3, vhash, 512 ); // 13 Fugue serial sph_fugue512( &ctx.fugue, hash0, 64 ); sph_fugue512_close( &ctx.fugue, hash0 ); memcpy( &ctx.fugue, &x14_4way_ctx.fugue, sizeof(sph_fugue512_context) ); sph_fugue512( &ctx.fugue, hash1, 64 ); sph_fugue512_close( &ctx.fugue, hash1 ); memcpy( &ctx.fugue, &x14_4way_ctx.fugue, sizeof(sph_fugue512_context) ); sph_fugue512( &ctx.fugue, hash2, 64 ); sph_fugue512_close( &ctx.fugue, hash2 ); memcpy( &ctx.fugue, &x14_4way_ctx.fugue, sizeof(sph_fugue512_context) ); sph_fugue512( &ctx.fugue, hash3, 64 ); sph_fugue512_close( &ctx.fugue, hash3 ); // 14 Shabal, parallel 32 bit intrlv_4x32( vhash, hash0, hash1, hash2, hash3, 512 ); shabal512_4way_update( &ctx.shabal, vhash, 64 ); shabal512_4way_close( &ctx.shabal, state ); } int scanhash_x14_4way( struct work *work, uint32_t max_nonce, uint64_t *hashes_done, struct thr_info *mythr ) { uint32_t hash[4*16] __attribute__ ((aligned (128))); uint32_t vdata[24*4] __attribute__ ((aligned (64))); uint32_t *pdata = work->data; uint32_t *ptarget = work->target; const uint32_t first_nonce = pdata[19]; uint32_t n = first_nonce; const uint32_t last_nonce = max_nonce - 4; __m256i *noncev = (__m256i*)vdata + 9; // aligned const uint32_t Htarg = ptarget[7]; int thr_id = mythr->id; mm256_bswap32_intrlv80_4x64( vdata, pdata ); do { *noncev = mm256_intrlv_blend_32( mm256_bswap_32( _mm256_set_epi32( n+3, 0, n+2, 0, n+1, 0, n, 0 ) ), *noncev ); x14_4way_hash( hash, vdata ); pdata[19] = n; uint32_t *hash7 = &(hash[7<<2]); for ( int lane = 0; lane < 4; lane++ ) if ( hash7[ lane ] < Htarg ) { uint32_t lane_hash[8]; extr_lane_4x32( lane_hash, hash, lane, 256 ); if ( fulltest( lane_hash, ptarget ) && !opt_benchmark ) { pdata[19] = n + lane; submit_lane_solution( work, lane_hash, mythr, lane ); } } n += 4; } while ( ( n < last_nonce ) && !work_restart[thr_id].restart ); *hashes_done = n - first_nonce; return 0; } #endif