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extract marucoin-modold (for old GPUs like Radeon HD 5xxx, e.g. 5850) as separate kernel and add support for it

djm34
Jan Berdajs 11 years ago
parent
commit
dfaee21023
  1. 65
      algorithm.c
  2. 216
      kernel/marucoin-mod.cl
  3. 985
      kernel/marucoin-modold.cl

65
algorithm.c

@ -159,7 +159,6 @@ static cl_int queue_darkcoin_mod_kernel(struct __clState *clState, struct _dev_b @@ -159,7 +159,6 @@ static cl_int queue_darkcoin_mod_kernel(struct __clState *clState, struct _dev_b
return status;
}
static cl_int queue_marucoin_mod_kernel(struct __clState *clState, struct _dev_blk_ctx *blk, __maybe_unused cl_uint threads)
{
cl_kernel *kernel;
@ -230,6 +229,69 @@ static cl_int queue_marucoin_mod_kernel(struct __clState *clState, struct _dev_b @@ -230,6 +229,69 @@ static cl_int queue_marucoin_mod_kernel(struct __clState *clState, struct _dev_b
return status;
}
static cl_int queue_marucoin_mod_old_kernel(struct __clState *clState, struct _dev_blk_ctx *blk, __maybe_unused cl_uint threads)
{
cl_kernel *kernel;
unsigned int num;
cl_ulong le_target;
cl_int status = 0;
le_target = *(cl_ulong *)(blk->work->device_target + 24);
flip80(clState->cldata, blk->work->data);
status = clEnqueueWriteBuffer(clState->commandQueue, clState->CLbuffer0, true, 0, 80, clState->cldata, 0, NULL,NULL);
// blake - search
kernel = &clState->kernel;
num = 0;
CL_SET_ARG(clState->CLbuffer0);
CL_SET_ARG(clState->padbuffer8);
// bmw - search1
kernel = clState->extra_kernels;
num = 0;
CL_SET_ARG(clState->padbuffer8);
// groestl - search2
kernel++;
num = 0;
CL_SET_ARG(clState->padbuffer8);
// skein - search3
kernel++;
num = 0;
CL_SET_ARG(clState->padbuffer8);
// jh - search4
kernel++;
num = 0;
CL_SET_ARG(clState->padbuffer8);
// keccak - search5
kernel++;
num = 0;
CL_SET_ARG(clState->padbuffer8);
// luffa - search6
kernel++;
num = 0;
CL_SET_ARG(clState->padbuffer8);
// cubehash - search7
kernel++;
num = 0;
CL_SET_ARG(clState->padbuffer8);
// shavite - search8
kernel++;
num = 0;
CL_SET_ARG(clState->padbuffer8);
// simd - search9
kernel++;
num = 0;
CL_SET_ARG(clState->padbuffer8);
// combined echo, hamsi, fugue - search10
kernel++;
num = 0;
CL_SET_ARG(clState->padbuffer8);
CL_SET_ARG(clState->outputBuffer);
CL_SET_ARG(le_target);
return status;
}
typedef struct _algorithm_settings_t {
const char *name; /* Human-readable identifier */
double diff_multiplier1;
@ -283,6 +345,7 @@ static algorithm_settings_t algos[] = { @@ -283,6 +345,7 @@ static algorithm_settings_t algos[] = {
{ "maxcoin", 1, 256, 1, 4, 15, 0x0F, 0x00000000ffff0000ULL, 0xFFFFULL, 0x000000ffUL, 0, 0, CL_QUEUE_OUT_OF_ORDER_EXEC_MODE_ENABLE, maxcoin_regenhash, queue_maxcoin_kernel, sha256},
{ "darkcoin-mod", 1, 1, 1, 0, 0, 0xFF, 0x00000000ffff0000ULL, 0xFFFFULL, 0x0000ffffUL, 10, 8 * 16 * 4194304, 0, darkcoin_regenhash, queue_darkcoin_mod_kernel, gen_hash},
{ "marucoin-mod", 1, 1, 1, 0, 0, 0xFF, 0x00000000ffff0000ULL, 0xFFFFULL, 0x0000ffffUL, 12, 8 * 16 * 4194304, 0, marucoin_regenhash, queue_marucoin_mod_kernel, gen_hash},
{ "marucoin-modold", 1, 1, 1, 0, 0, 0xFF, 0x00000000ffff0000ULL, 0xFFFFULL, 0x0000ffffUL, 10, 8 * 16 * 4194304, 0, marucoin_regenhash, queue_marucoin_mod_old_kernel, gen_hash},
// kernels starting from this will have difficulty calculated by using fuguecoin algorithm
#define A_FUGUE(a, b) \

216
kernel/marucoin-mod.cl

@ -771,8 +771,6 @@ __kernel void search9(__global hash_t* hashes) @@ -771,8 +771,6 @@ __kernel void search9(__global hash_t* hashes)
barrier(CLK_GLOBAL_MEM_FENCE);
}
#ifndef X13MODOLD
__attribute__((reqd_work_group_size(WORKSIZE, 1, 1)))
__kernel void search10(__global hash_t* hashes)
{
@ -999,218 +997,4 @@ __kernel void search12(__global hash_t* hashes, __global uint* output, const ulo @@ -999,218 +997,4 @@ __kernel void search12(__global hash_t* hashes, __global uint* output, const ulo
barrier(CLK_GLOBAL_MEM_FENCE);
}
#else
__attribute__((reqd_work_group_size(WORKSIZE, 1, 1)))
__kernel void search10(__global hash_t* hashes, __global uint* output, const ulong target)
{
uint gid = get_global_id(0);
uint offset = get_global_offset(0);
hash_t hash;
__local sph_u32 AES0[256], AES1[256], AES2[256], AES3[256];
int init = get_local_id(0);
int step = get_local_size(0);
for (int i = init; i < 256; i += step)
{
AES0[i] = AES0_C[i];
AES1[i] = AES1_C[i];
AES2[i] = AES2_C[i];
AES3[i] = AES3_C[i];
}
barrier(CLK_LOCAL_MEM_FENCE);
for (int i = 0; i < 8; i++) {
hash.h8[i] = hashes[gid-offset].h8[i];
}
// echo
{
sph_u64 W00, W01, W10, W11, W20, W21, W30, W31, W40, W41, W50, W51, W60, W61, W70, W71, W80, W81, W90, W91, WA0, WA1, WB0, WB1, WC0, WC1, WD0, WD1, WE0, WE1, WF0, WF1;
sph_u64 Vb00, Vb01, Vb10, Vb11, Vb20, Vb21, Vb30, Vb31, Vb40, Vb41, Vb50, Vb51, Vb60, Vb61, Vb70, Vb71;
Vb00 = Vb10 = Vb20 = Vb30 = Vb40 = Vb50 = Vb60 = Vb70 = 512UL;
Vb01 = Vb11 = Vb21 = Vb31 = Vb41 = Vb51 = Vb61 = Vb71 = 0;
sph_u32 K0 = 512;
sph_u32 K1 = 0;
sph_u32 K2 = 0;
sph_u32 K3 = 0;
W00 = Vb00;
W01 = Vb01;
W10 = Vb10;
W11 = Vb11;
W20 = Vb20;
W21 = Vb21;
W30 = Vb30;
W31 = Vb31;
W40 = Vb40;
W41 = Vb41;
W50 = Vb50;
W51 = Vb51;
W60 = Vb60;
W61 = Vb61;
W70 = Vb70;
W71 = Vb71;
W80 = hash.h8[0];
W81 = hash.h8[1];
W90 = hash.h8[2];
W91 = hash.h8[3];
WA0 = hash.h8[4];
WA1 = hash.h8[5];
WB0 = hash.h8[6];
WB1 = hash.h8[7];
WC0 = 0x80;
WC1 = 0;
WD0 = 0;
WD1 = 0;
WE0 = 0;
WE1 = 0x200000000000000;
WF0 = 0x200;
WF1 = 0;
for (unsigned u = 0; u < 10; u ++) {
BIG_ROUND;
}
hash.h8[0] ^= Vb00 ^ W00 ^ W80;
hash.h8[1] ^= Vb01 ^ W01 ^ W81;
hash.h8[2] ^= Vb10 ^ W10 ^ W90;
hash.h8[3] ^= Vb11 ^ W11 ^ W91;
hash.h8[4] ^= Vb20 ^ W20 ^ WA0;
hash.h8[5] ^= Vb21 ^ W21 ^ WA1;
hash.h8[6] ^= Vb30 ^ W30 ^ WB0;
hash.h8[7] ^= Vb31 ^ W31 ^ WB1;
}
// hamsi
{
sph_u32 c0 = HAMSI_IV512[0], c1 = HAMSI_IV512[1], c2 = HAMSI_IV512[2], c3 = HAMSI_IV512[3];
sph_u32 c4 = HAMSI_IV512[4], c5 = HAMSI_IV512[5], c6 = HAMSI_IV512[6], c7 = HAMSI_IV512[7];
sph_u32 c8 = HAMSI_IV512[8], c9 = HAMSI_IV512[9], cA = HAMSI_IV512[10], cB = HAMSI_IV512[11];
sph_u32 cC = HAMSI_IV512[12], cD = HAMSI_IV512[13], cE = HAMSI_IV512[14], cF = HAMSI_IV512[15];
sph_u32 m0, m1, m2, m3, m4, m5, m6, m7;
sph_u32 m8, m9, mA, mB, mC, mD, mE, mF;
sph_u32 h[16] = { c0, c1, c2, c3, c4, c5, c6, c7, c8, c9, cA, cB, cC, cD, cE, cF };
#define buf(u) hash.h1[i + u]
for(int i = 0; i < 64; i += 8) {
INPUT_BIG;
P_BIG;
T_BIG;
}
#undef buf
#define buf(u) (u == 0 ? 0x80 : 0)
INPUT_BIG;
P_BIG;
T_BIG;
#undef buf
#define buf(u) (u == 6 ? 2 : 0)
INPUT_BIG;
PF_BIG;
T_BIG;
for (unsigned u = 0; u < 16; u ++)
hash.h4[u] = h[u];
}
// fugue
{
sph_u32 S00, S01, S02, S03, S04, S05, S06, S07, S08, S09;
sph_u32 S10, S11, S12, S13, S14, S15, S16, S17, S18, S19;
sph_u32 S20, S21, S22, S23, S24, S25, S26, S27, S28, S29;
sph_u32 S30, S31, S32, S33, S34, S35;
ulong fc_bit_count = (sph_u64) 64 << 3;
S00 = S01 = S02 = S03 = S04 = S05 = S06 = S07 = S08 = S09 = S10 = S11 = S12 = S13 = S14 = S15 = S16 = S17 = S18 = S19 = 0;
S20 = SPH_C32(0x8807a57e); S21 = SPH_C32(0xe616af75); S22 = SPH_C32(0xc5d3e4db); S23 = SPH_C32(0xac9ab027);
S24 = SPH_C32(0xd915f117); S25 = SPH_C32(0xb6eecc54); S26 = SPH_C32(0x06e8020b); S27 = SPH_C32(0x4a92efd1);
S28 = SPH_C32(0xaac6e2c9); S29 = SPH_C32(0xddb21398); S30 = SPH_C32(0xcae65838); S31 = SPH_C32(0x437f203f);
S32 = SPH_C32(0x25ea78e7); S33 = SPH_C32(0x951fddd6); S34 = SPH_C32(0xda6ed11d); S35 = SPH_C32(0xe13e3567);
FUGUE512_3((hash.h4[0x0]), (hash.h4[0x1]), (hash.h4[0x2]));
FUGUE512_3((hash.h4[0x3]), (hash.h4[0x4]), (hash.h4[0x5]));
FUGUE512_3((hash.h4[0x6]), (hash.h4[0x7]), (hash.h4[0x8]));
FUGUE512_3((hash.h4[0x9]), (hash.h4[0xA]), (hash.h4[0xB]));
FUGUE512_3((hash.h4[0xC]), (hash.h4[0xD]), (hash.h4[0xE]));
FUGUE512_3((hash.h4[0xF]), as_uint2(fc_bit_count).y, as_uint2(fc_bit_count).x);
// apply round shift if necessary
int i;
for (i = 0; i < 32; i ++) {
ROR3;
CMIX36(S00, S01, S02, S04, S05, S06, S18, S19, S20);
SMIX(S00, S01, S02, S03);
}
for (i = 0; i < 13; i ++) {
S04 ^= S00;
S09 ^= S00;
S18 ^= S00;
S27 ^= S00;
ROR9;
SMIX(S00, S01, S02, S03);
S04 ^= S00;
S10 ^= S00;
S18 ^= S00;
S27 ^= S00;
ROR9;
SMIX(S00, S01, S02, S03);
S04 ^= S00;
S10 ^= S00;
S19 ^= S00;
S27 ^= S00;
ROR9;
SMIX(S00, S01, S02, S03);
S04 ^= S00;
S10 ^= S00;
S19 ^= S00;
S28 ^= S00;
ROR8;
SMIX(S00, S01, S02, S03);
}
S04 ^= S00;
S09 ^= S00;
S18 ^= S00;
S27 ^= S00;
hash.h4[0] = SWAP4(S01);
hash.h4[1] = SWAP4(S02);
hash.h4[2] = SWAP4(S03);
hash.h4[3] = SWAP4(S04);
hash.h4[4] = SWAP4(S09);
hash.h4[5] = SWAP4(S10);
hash.h4[6] = SWAP4(S11);
hash.h4[7] = SWAP4(S12);
hash.h4[8] = SWAP4(S18);
hash.h4[9] = SWAP4(S19);
hash.h4[10] = SWAP4(S20);
hash.h4[11] = SWAP4(S21);
hash.h4[12] = SWAP4(S27);
hash.h4[13] = SWAP4(S28);
hash.h4[14] = SWAP4(S29);
hash.h4[15] = SWAP4(S30);
}
bool result = (hash.h8[3] <= target);
if (result)
output[atomic_inc(output+0xFF)] = SWAP4(gid);
barrier(CLK_GLOBAL_MEM_FENCE);
}
#endif // X13MODOLD
#endif // X13MOD_CL

985
kernel/marucoin-modold.cl

@ -0,0 +1,985 @@ @@ -0,0 +1,985 @@
/*
* X13 kernel implementation.
*
* ==========================(LICENSE BEGIN)============================
*
* Copyright (c) 2014 phm
* Copyright (c) 2014 Girino Vey
*
* Permission is hereby granted, free of charge, to any person obtaining
* a copy of this software and associated documentation files (the
* "Software"), to deal in the Software without restriction, including
* without limitation the rights to use, copy, modify, merge, publish,
* distribute, sublicense, and/or sell copies of the Software, and to
* permit persons to whom the Software is furnished to do so, subject to
* the following conditions:
*
* The above copyright notice and this permission notice shall be
* included in all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.
* IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY
* CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT,
* TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE
* SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
*
* ===========================(LICENSE END)=============================
*
* @author phm <phm@inbox.com>
*/
#ifndef X13MOD_CL
#define X13MOD_CL
#if __ENDIAN_LITTLE__
#define SPH_LITTLE_ENDIAN 1
#else
#define SPH_BIG_ENDIAN 1
#endif
#define SPH_UPTR sph_u64
typedef unsigned int sph_u32;
typedef int sph_s32;
#ifndef __OPENCL_VERSION__
typedef unsigned long long sph_u64;
typedef long long sph_s64;
#else
typedef unsigned long sph_u64;
typedef long sph_s64;
#endif
#define SPH_64 1
#define SPH_64_TRUE 1
#define SPH_C32(x) ((sph_u32)(x ## U))
#define SPH_T32(x) ((x) & SPH_C32(0xFFFFFFFF))
#define SPH_ROTL32(x, n) SPH_T32(((x) << (n)) | ((x) >> (32 - (n))))
#define SPH_ROTR32(x, n) SPH_ROTL32(x, (32 - (n)))
#define SPH_C64(x) ((sph_u64)(x ## UL))
#define SPH_T64(x) ((x) & SPH_C64(0xFFFFFFFFFFFFFFFF))
#define SPH_ROTL64(x, n) SPH_T64(((x) << (n)) | ((x) >> (64 - (n))))
#define SPH_ROTR64(x, n) SPH_ROTL64(x, (64 - (n)))
#define SPH_ECHO_64 1
#define SPH_KECCAK_64 1
#define SPH_JH_64 1
#define SPH_SIMD_NOCOPY 0
#define SPH_KECCAK_NOCOPY 0
#define SPH_COMPACT_BLAKE_64 0
#define SPH_LUFFA_PARALLEL 0
#define SPH_SMALL_FOOTPRINT_GROESTL 0
#define SPH_GROESTL_BIG_ENDIAN 0
#define SPH_CUBEHASH_UNROLL 0
#define SPH_KECCAK_UNROLL 0
#define SPH_HAMSI_EXPAND_BIG 4
#include "blake.cl"
#include "bmw.cl"
#include "groestl.cl"
#include "jh.cl"
#include "keccak.cl"
#include "skein.cl"
#include "luffa.cl"
#include "cubehash.cl"
#include "shavite.cl"
#include "simd.cl"
#include "echo.cl"
#include "hamsi.cl"
#include "fugue.cl"
#define SWAP4(x) as_uint(as_uchar4(x).wzyx)
#define SWAP8(x) as_ulong(as_uchar8(x).s76543210)
#if SPH_BIG_ENDIAN
#define DEC64E(x) (x)
#define DEC64BE(x) (*(const __global sph_u64 *) (x));
#else
#define DEC64E(x) SWAP8(x)
#define DEC64BE(x) SWAP8(*(const __global sph_u64 *) (x));
#endif
typedef union {
unsigned char h1[64];
uint h4[16];
ulong h8[8];
} hash_t;
__attribute__((reqd_work_group_size(WORKSIZE, 1, 1)))
__kernel void search(__global unsigned char* block, __global hash_t* hashes)
{
uint gid = get_global_id(0);
__global hash_t *hash = &(hashes[gid-get_global_offset(0)]);
// blake
sph_u64 H0 = SPH_C64(0x6A09E667F3BCC908), H1 = SPH_C64(0xBB67AE8584CAA73B);
sph_u64 H2 = SPH_C64(0x3C6EF372FE94F82B), H3 = SPH_C64(0xA54FF53A5F1D36F1);
sph_u64 H4 = SPH_C64(0x510E527FADE682D1), H5 = SPH_C64(0x9B05688C2B3E6C1F);
sph_u64 H6 = SPH_C64(0x1F83D9ABFB41BD6B), H7 = SPH_C64(0x5BE0CD19137E2179);
sph_u64 S0 = 0, S1 = 0, S2 = 0, S3 = 0;
sph_u64 T0 = SPH_C64(0xFFFFFFFFFFFFFC00) + (80 << 3), T1 = 0xFFFFFFFFFFFFFFFF;;
if ((T0 = SPH_T64(T0 + 1024)) < 1024)
{
T1 = SPH_T64(T1 + 1);
}
sph_u64 M0, M1, M2, M3, M4, M5, M6, M7;
sph_u64 M8, M9, MA, MB, MC, MD, ME, MF;
sph_u64 V0, V1, V2, V3, V4, V5, V6, V7;
sph_u64 V8, V9, VA, VB, VC, VD, VE, VF;
M0 = DEC64BE(block + 0);
M1 = DEC64BE(block + 8);
M2 = DEC64BE(block + 16);
M3 = DEC64BE(block + 24);
M4 = DEC64BE(block + 32);
M5 = DEC64BE(block + 40);
M6 = DEC64BE(block + 48);
M7 = DEC64BE(block + 56);
M8 = DEC64BE(block + 64);
M9 = DEC64BE(block + 72);
M9 &= 0xFFFFFFFF00000000;
M9 ^= SWAP4(gid);
MA = 0x8000000000000000;
MB = 0;
MC = 0;
MD = 1;
ME = 0;
MF = 0x280;
COMPRESS64;
hash->h8[0] = H0;
hash->h8[1] = H1;
hash->h8[2] = H2;
hash->h8[3] = H3;
hash->h8[4] = H4;
hash->h8[5] = H5;
hash->h8[6] = H6;
hash->h8[7] = H7;
barrier(CLK_GLOBAL_MEM_FENCE);
}
__attribute__((reqd_work_group_size(WORKSIZE, 1, 1)))
__kernel void search1(__global hash_t* hashes)
{
uint gid = get_global_id(0);
__global hash_t *hash = &(hashes[gid-get_global_offset(0)]);
// bmw
sph_u64 BMW_H[16];
for(unsigned u = 0; u < 16; u++)
BMW_H[u] = BMW_IV512[u];
sph_u64 BMW_h1[16], BMW_h2[16];
sph_u64 mv[16];
mv[ 0] = SWAP8(hash->h8[0]);
mv[ 1] = SWAP8(hash->h8[1]);
mv[ 2] = SWAP8(hash->h8[2]);
mv[ 3] = SWAP8(hash->h8[3]);
mv[ 4] = SWAP8(hash->h8[4]);
mv[ 5] = SWAP8(hash->h8[5]);
mv[ 6] = SWAP8(hash->h8[6]);
mv[ 7] = SWAP8(hash->h8[7]);
mv[ 8] = 0x80;
mv[ 9] = 0;
mv[10] = 0;
mv[11] = 0;
mv[12] = 0;
mv[13] = 0;
mv[14] = 0;
mv[15] = 0x200;
#define M(x) (mv[x])
#define H(x) (BMW_H[x])
#define dH(x) (BMW_h2[x])
FOLDb;
#undef M
#undef H
#undef dH
#define M(x) (BMW_h2[x])
#define H(x) (final_b[x])
#define dH(x) (BMW_h1[x])
FOLDb;
#undef M
#undef H
#undef dH
hash->h8[0] = SWAP8(BMW_h1[8]);
hash->h8[1] = SWAP8(BMW_h1[9]);
hash->h8[2] = SWAP8(BMW_h1[10]);
hash->h8[3] = SWAP8(BMW_h1[11]);
hash->h8[4] = SWAP8(BMW_h1[12]);
hash->h8[5] = SWAP8(BMW_h1[13]);
hash->h8[6] = SWAP8(BMW_h1[14]);
hash->h8[7] = SWAP8(BMW_h1[15]);
barrier(CLK_GLOBAL_MEM_FENCE);
}
__attribute__((reqd_work_group_size(WORKSIZE, 1, 1)))
__kernel void search2(__global hash_t* hashes)
{
uint gid = get_global_id(0);
__global hash_t *hash = &(hashes[gid-get_global_offset(0)]);
__local sph_u64 T0_L[256], T1_L[256], T2_L[256], T3_L[256], T4_L[256], T5_L[256], T6_L[256], T7_L[256];
int init = get_local_id(0);
int step = get_local_size(0);
for (int i = init; i < 256; i += step)
{
T0_L[i] = T0[i];
T1_L[i] = T1[i];
T2_L[i] = T2[i];
T3_L[i] = T3[i];
T4_L[i] = T4[i];
T5_L[i] = T5[i];
T6_L[i] = T6[i];
T7_L[i] = T7[i];
}
barrier(CLK_LOCAL_MEM_FENCE);
#define T0 T0_L
#define T1 T1_L
#define T2 T2_L
#define T3 T3_L
#define T4 T4_L
#define T5 T5_L
#define T6 T6_L
#define T7 T7_L
// groestl
sph_u64 H[16];
for (unsigned int u = 0; u < 15; u ++)
H[u] = 0;
#if USE_LE
H[15] = ((sph_u64)(512 & 0xFF) << 56) | ((sph_u64)(512 & 0xFF00) << 40);
#else
H[15] = (sph_u64)512;
#endif
sph_u64 g[16], m[16];
m[0] = DEC64E(hash->h8[0]);
m[1] = DEC64E(hash->h8[1]);
m[2] = DEC64E(hash->h8[2]);
m[3] = DEC64E(hash->h8[3]);
m[4] = DEC64E(hash->h8[4]);
m[5] = DEC64E(hash->h8[5]);
m[6] = DEC64E(hash->h8[6]);
m[7] = DEC64E(hash->h8[7]);
for (unsigned int u = 0; u < 16; u ++)
g[u] = m[u] ^ H[u];
m[8] = 0x80; g[8] = m[8] ^ H[8];
m[9] = 0; g[9] = m[9] ^ H[9];
m[10] = 0; g[10] = m[10] ^ H[10];
m[11] = 0; g[11] = m[11] ^ H[11];
m[12] = 0; g[12] = m[12] ^ H[12];
m[13] = 0; g[13] = m[13] ^ H[13];
m[14] = 0; g[14] = m[14] ^ H[14];
m[15] = 0x100000000000000; g[15] = m[15] ^ H[15];
PERM_BIG_P(g);
PERM_BIG_Q(m);
for (unsigned int u = 0; u < 16; u ++)
H[u] ^= g[u] ^ m[u];
sph_u64 xH[16];
for (unsigned int u = 0; u < 16; u ++)
xH[u] = H[u];
PERM_BIG_P(xH);
for (unsigned int u = 0; u < 16; u ++)
H[u] ^= xH[u];
for (unsigned int u = 0; u < 8; u ++)
hash->h8[u] = DEC64E(H[u + 8]);
barrier(CLK_GLOBAL_MEM_FENCE);
}
__attribute__((reqd_work_group_size(WORKSIZE, 1, 1)))
__kernel void search3(__global hash_t* hashes)
{
uint gid = get_global_id(0);
__global hash_t *hash = &(hashes[gid-get_global_offset(0)]);
// skein
sph_u64 h0 = SPH_C64(0x4903ADFF749C51CE), h1 = SPH_C64(0x0D95DE399746DF03), h2 = SPH_C64(0x8FD1934127C79BCE), h3 = SPH_C64(0x9A255629FF352CB1), h4 = SPH_C64(0x5DB62599DF6CA7B0), h5 = SPH_C64(0xEABE394CA9D5C3F4), h6 = SPH_C64(0x991112C71A75B523), h7 = SPH_C64(0xAE18A40B660FCC33);
sph_u64 m0, m1, m2, m3, m4, m5, m6, m7;
sph_u64 bcount = 0;
m0 = SWAP8(hash->h8[0]);
m1 = SWAP8(hash->h8[1]);
m2 = SWAP8(hash->h8[2]);
m3 = SWAP8(hash->h8[3]);
m4 = SWAP8(hash->h8[4]);
m5 = SWAP8(hash->h8[5]);
m6 = SWAP8(hash->h8[6]);
m7 = SWAP8(hash->h8[7]);
UBI_BIG(480, 64);
bcount = 0;
m0 = m1 = m2 = m3 = m4 = m5 = m6 = m7 = 0;
UBI_BIG(510, 8);
hash->h8[0] = SWAP8(h0);
hash->h8[1] = SWAP8(h1);
hash->h8[2] = SWAP8(h2);
hash->h8[3] = SWAP8(h3);
hash->h8[4] = SWAP8(h4);
hash->h8[5] = SWAP8(h5);
hash->h8[6] = SWAP8(h6);
hash->h8[7] = SWAP8(h7);
barrier(CLK_GLOBAL_MEM_FENCE);
}
__attribute__((reqd_work_group_size(WORKSIZE, 1, 1)))
__kernel void search4(__global hash_t* hashes)
{
uint gid = get_global_id(0);
__global hash_t *hash = &(hashes[gid-get_global_offset(0)]);
// jh
sph_u64 h0h = C64e(0x6fd14b963e00aa17), h0l = C64e(0x636a2e057a15d543), h1h = C64e(0x8a225e8d0c97ef0b), h1l = C64e(0xe9341259f2b3c361), h2h = C64e(0x891da0c1536f801e), h2l = C64e(0x2aa9056bea2b6d80), h3h = C64e(0x588eccdb2075baa6), h3l = C64e(0xa90f3a76baf83bf7);
sph_u64 h4h = C64e(0x0169e60541e34a69), h4l = C64e(0x46b58a8e2e6fe65a), h5h = C64e(0x1047a7d0c1843c24), h5l = C64e(0x3b6e71b12d5ac199), h6h = C64e(0xcf57f6ec9db1f856), h6l = C64e(0xa706887c5716b156), h7h = C64e(0xe3c2fcdfe68517fb), h7l = C64e(0x545a4678cc8cdd4b);
sph_u64 tmp;
for(int i = 0; i < 2; i++)
{
if (i == 0) {
h0h ^= DEC64E(hash->h8[0]);
h0l ^= DEC64E(hash->h8[1]);
h1h ^= DEC64E(hash->h8[2]);
h1l ^= DEC64E(hash->h8[3]);
h2h ^= DEC64E(hash->h8[4]);
h2l ^= DEC64E(hash->h8[5]);
h3h ^= DEC64E(hash->h8[6]);
h3l ^= DEC64E(hash->h8[7]);
} else if(i == 1) {
h4h ^= DEC64E(hash->h8[0]);
h4l ^= DEC64E(hash->h8[1]);
h5h ^= DEC64E(hash->h8[2]);
h5l ^= DEC64E(hash->h8[3]);
h6h ^= DEC64E(hash->h8[4]);
h6l ^= DEC64E(hash->h8[5]);
h7h ^= DEC64E(hash->h8[6]);
h7l ^= DEC64E(hash->h8[7]);
h0h ^= 0x80;
h3l ^= 0x2000000000000;
}
E8;
}
h4h ^= 0x80;
h7l ^= 0x2000000000000;
hash->h8[0] = DEC64E(h4h);
hash->h8[1] = DEC64E(h4l);
hash->h8[2] = DEC64E(h5h);
hash->h8[3] = DEC64E(h5l);
hash->h8[4] = DEC64E(h6h);
hash->h8[5] = DEC64E(h6l);
hash->h8[6] = DEC64E(h7h);
hash->h8[7] = DEC64E(h7l);
barrier(CLK_GLOBAL_MEM_FENCE);
}
__attribute__((reqd_work_group_size(WORKSIZE, 1, 1)))
__kernel void search5(__global hash_t* hashes)
{
uint gid = get_global_id(0);
__global hash_t *hash = &(hashes[gid-get_global_offset(0)]);
// keccak
sph_u64 a00 = 0, a01 = 0, a02 = 0, a03 = 0, a04 = 0;
sph_u64 a10 = 0, a11 = 0, a12 = 0, a13 = 0, a14 = 0;
sph_u64 a20 = 0, a21 = 0, a22 = 0, a23 = 0, a24 = 0;
sph_u64 a30 = 0, a31 = 0, a32 = 0, a33 = 0, a34 = 0;
sph_u64 a40 = 0, a41 = 0, a42 = 0, a43 = 0, a44 = 0;
a10 = SPH_C64(0xFFFFFFFFFFFFFFFF);
a20 = SPH_C64(0xFFFFFFFFFFFFFFFF);
a31 = SPH_C64(0xFFFFFFFFFFFFFFFF);
a22 = SPH_C64(0xFFFFFFFFFFFFFFFF);
a23 = SPH_C64(0xFFFFFFFFFFFFFFFF);
a04 = SPH_C64(0xFFFFFFFFFFFFFFFF);
a00 ^= SWAP8(hash->h8[0]);
a10 ^= SWAP8(hash->h8[1]);
a20 ^= SWAP8(hash->h8[2]);
a30 ^= SWAP8(hash->h8[3]);
a40 ^= SWAP8(hash->h8[4]);
a01 ^= SWAP8(hash->h8[5]);
a11 ^= SWAP8(hash->h8[6]);
a21 ^= SWAP8(hash->h8[7]);
a31 ^= 0x8000000000000001;
KECCAK_F_1600;
// Finalize the "lane complement"
a10 = ~a10;
a20 = ~a20;
hash->h8[0] = SWAP8(a00);
hash->h8[1] = SWAP8(a10);
hash->h8[2] = SWAP8(a20);
hash->h8[3] = SWAP8(a30);
hash->h8[4] = SWAP8(a40);
hash->h8[5] = SWAP8(a01);
hash->h8[6] = SWAP8(a11);
hash->h8[7] = SWAP8(a21);
barrier(CLK_GLOBAL_MEM_FENCE);
}
__attribute__((reqd_work_group_size(WORKSIZE, 1, 1)))
__kernel void search6(__global hash_t* hashes)
{
uint gid = get_global_id(0);
__global hash_t *hash = &(hashes[gid-get_global_offset(0)]);
// luffa
sph_u32 V00 = SPH_C32(0x6d251e69), V01 = SPH_C32(0x44b051e0), V02 = SPH_C32(0x4eaa6fb4), V03 = SPH_C32(0xdbf78465), V04 = SPH_C32(0x6e292011), V05 = SPH_C32(0x90152df4), V06 = SPH_C32(0xee058139), V07 = SPH_C32(0xdef610bb);
sph_u32 V10 = SPH_C32(0xc3b44b95), V11 = SPH_C32(0xd9d2f256), V12 = SPH_C32(0x70eee9a0), V13 = SPH_C32(0xde099fa3), V14 = SPH_C32(0x5d9b0557), V15 = SPH_C32(0x8fc944b3), V16 = SPH_C32(0xcf1ccf0e), V17 = SPH_C32(0x746cd581);
sph_u32 V20 = SPH_C32(0xf7efc89d), V21 = SPH_C32(0x5dba5781), V22 = SPH_C32(0x04016ce5), V23 = SPH_C32(0xad659c05), V24 = SPH_C32(0x0306194f), V25 = SPH_C32(0x666d1836), V26 = SPH_C32(0x24aa230a), V27 = SPH_C32(0x8b264ae7);
sph_u32 V30 = SPH_C32(0x858075d5), V31 = SPH_C32(0x36d79cce), V32 = SPH_C32(0xe571f7d7), V33 = SPH_C32(0x204b1f67), V34 = SPH_C32(0x35870c6a), V35 = SPH_C32(0x57e9e923), V36 = SPH_C32(0x14bcb808), V37 = SPH_C32(0x7cde72ce);
sph_u32 V40 = SPH_C32(0x6c68e9be), V41 = SPH_C32(0x5ec41e22), V42 = SPH_C32(0xc825b7c7), V43 = SPH_C32(0xaffb4363), V44 = SPH_C32(0xf5df3999), V45 = SPH_C32(0x0fc688f1), V46 = SPH_C32(0xb07224cc), V47 = SPH_C32(0x03e86cea);
DECL_TMP8(M);
M0 = hash->h4[1];
M1 = hash->h4[0];
M2 = hash->h4[3];
M3 = hash->h4[2];
M4 = hash->h4[5];
M5 = hash->h4[4];
M6 = hash->h4[7];
M7 = hash->h4[6];
for(uint i = 0; i < 5; i++)
{
MI5;
LUFFA_P5;
if(i == 0) {
M0 = hash->h4[9];
M1 = hash->h4[8];
M2 = hash->h4[11];
M3 = hash->h4[10];
M4 = hash->h4[13];
M5 = hash->h4[12];
M6 = hash->h4[15];
M7 = hash->h4[14];
} else if(i == 1) {
M0 = 0x80000000;
M1 = M2 = M3 = M4 = M5 = M6 = M7 = 0;
} else if(i == 2) {
M0 = M1 = M2 = M3 = M4 = M5 = M6 = M7 = 0;
} else if(i == 3) {
hash->h4[1] = V00 ^ V10 ^ V20 ^ V30 ^ V40;
hash->h4[0] = V01 ^ V11 ^ V21 ^ V31 ^ V41;
hash->h4[3] = V02 ^ V12 ^ V22 ^ V32 ^ V42;
hash->h4[2] = V03 ^ V13 ^ V23 ^ V33 ^ V43;
hash->h4[5] = V04 ^ V14 ^ V24 ^ V34 ^ V44;
hash->h4[4] = V05 ^ V15 ^ V25 ^ V35 ^ V45;
hash->h4[7] = V06 ^ V16 ^ V26 ^ V36 ^ V46;
hash->h4[6] = V07 ^ V17 ^ V27 ^ V37 ^ V47;
}
}
hash->h4[9] = V00 ^ V10 ^ V20 ^ V30 ^ V40;
hash->h4[8] = V01 ^ V11 ^ V21 ^ V31 ^ V41;
hash->h4[11] = V02 ^ V12 ^ V22 ^ V32 ^ V42;
hash->h4[10] = V03 ^ V13 ^ V23 ^ V33 ^ V43;
hash->h4[13] = V04 ^ V14 ^ V24 ^ V34 ^ V44;
hash->h4[12] = V05 ^ V15 ^ V25 ^ V35 ^ V45;
hash->h4[15] = V06 ^ V16 ^ V26 ^ V36 ^ V46;
hash->h4[14] = V07 ^ V17 ^ V27 ^ V37 ^ V47;
barrier(CLK_GLOBAL_MEM_FENCE);
}
__attribute__((reqd_work_group_size(WORKSIZE, 1, 1)))
__kernel void search7(__global hash_t* hashes)
{
uint gid = get_global_id(0);
__global hash_t *hash = &(hashes[gid-get_global_offset(0)]);
// cubehash.h1
sph_u32 x0 = SPH_C32(0x2AEA2A61), x1 = SPH_C32(0x50F494D4), x2 = SPH_C32(0x2D538B8B), x3 = SPH_C32(0x4167D83E);
sph_u32 x4 = SPH_C32(0x3FEE2313), x5 = SPH_C32(0xC701CF8C), x6 = SPH_C32(0xCC39968E), x7 = SPH_C32(0x50AC5695);
sph_u32 x8 = SPH_C32(0x4D42C787), x9 = SPH_C32(0xA647A8B3), xa = SPH_C32(0x97CF0BEF), xb = SPH_C32(0x825B4537);
sph_u32 xc = SPH_C32(0xEEF864D2), xd = SPH_C32(0xF22090C4), xe = SPH_C32(0xD0E5CD33), xf = SPH_C32(0xA23911AE);
sph_u32 xg = SPH_C32(0xFCD398D9), xh = SPH_C32(0x148FE485), xi = SPH_C32(0x1B017BEF), xj = SPH_C32(0xB6444532);
sph_u32 xk = SPH_C32(0x6A536159), xl = SPH_C32(0x2FF5781C), xm = SPH_C32(0x91FA7934), xn = SPH_C32(0x0DBADEA9);
sph_u32 xo = SPH_C32(0xD65C8A2B), xp = SPH_C32(0xA5A70E75), xq = SPH_C32(0xB1C62456), xr = SPH_C32(0xBC796576);
sph_u32 xs = SPH_C32(0x1921C8F7), xt = SPH_C32(0xE7989AF1), xu = SPH_C32(0x7795D246), xv = SPH_C32(0xD43E3B44);
x0 ^= SWAP4(hash->h4[1]);
x1 ^= SWAP4(hash->h4[0]);
x2 ^= SWAP4(hash->h4[3]);
x3 ^= SWAP4(hash->h4[2]);
x4 ^= SWAP4(hash->h4[5]);
x5 ^= SWAP4(hash->h4[4]);
x6 ^= SWAP4(hash->h4[7]);
x7 ^= SWAP4(hash->h4[6]);
for (int i = 0; i < 13; i ++) {
SIXTEEN_ROUNDS;
if (i == 0) {
x0 ^= SWAP4(hash->h4[9]);
x1 ^= SWAP4(hash->h4[8]);
x2 ^= SWAP4(hash->h4[11]);
x3 ^= SWAP4(hash->h4[10]);
x4 ^= SWAP4(hash->h4[13]);
x5 ^= SWAP4(hash->h4[12]);
x6 ^= SWAP4(hash->h4[15]);
x7 ^= SWAP4(hash->h4[14]);
} else if(i == 1) {
x0 ^= 0x80;
} else if (i == 2) {
xv ^= SPH_C32(1);
}
}
hash->h4[0] = x0;
hash->h4[1] = x1;
hash->h4[2] = x2;
hash->h4[3] = x3;
hash->h4[4] = x4;
hash->h4[5] = x5;
hash->h4[6] = x6;
hash->h4[7] = x7;
hash->h4[8] = x8;
hash->h4[9] = x9;
hash->h4[10] = xa;
hash->h4[11] = xb;
hash->h4[12] = xc;
hash->h4[13] = xd;
hash->h4[14] = xe;
hash->h4[15] = xf;
barrier(CLK_GLOBAL_MEM_FENCE);
}
__attribute__((reqd_work_group_size(WORKSIZE, 1, 1)))
__kernel void search8(__global hash_t* hashes)
{
uint gid = get_global_id(0);
__global hash_t *hash = &(hashes[gid-get_global_offset(0)]);
__local sph_u32 AES0[256], AES1[256], AES2[256], AES3[256];
int init = get_local_id(0);
int step = get_local_size(0);
for (int i = init; i < 256; i += step)
{
AES0[i] = AES0_C[i];
AES1[i] = AES1_C[i];
AES2[i] = AES2_C[i];
AES3[i] = AES3_C[i];
}
barrier(CLK_LOCAL_MEM_FENCE);
// shavite
// IV
sph_u32 h0 = SPH_C32(0x72FCCDD8), h1 = SPH_C32(0x79CA4727), h2 = SPH_C32(0x128A077B), h3 = SPH_C32(0x40D55AEC);
sph_u32 h4 = SPH_C32(0xD1901A06), h5 = SPH_C32(0x430AE307), h6 = SPH_C32(0xB29F5CD1), h7 = SPH_C32(0xDF07FBFC);
sph_u32 h8 = SPH_C32(0x8E45D73D), h9 = SPH_C32(0x681AB538), hA = SPH_C32(0xBDE86578), hB = SPH_C32(0xDD577E47);
sph_u32 hC = SPH_C32(0xE275EADE), hD = SPH_C32(0x502D9FCD), hE = SPH_C32(0xB9357178), hF = SPH_C32(0x022A4B9A);
// state
sph_u32 rk00, rk01, rk02, rk03, rk04, rk05, rk06, rk07;
sph_u32 rk08, rk09, rk0A, rk0B, rk0C, rk0D, rk0E, rk0F;
sph_u32 rk10, rk11, rk12, rk13, rk14, rk15, rk16, rk17;
sph_u32 rk18, rk19, rk1A, rk1B, rk1C, rk1D, rk1E, rk1F;
sph_u32 sc_count0 = (64 << 3), sc_count1 = 0, sc_count2 = 0, sc_count3 = 0;
rk00 = hash->h4[0];
rk01 = hash->h4[1];
rk02 = hash->h4[2];
rk03 = hash->h4[3];
rk04 = hash->h4[4];
rk05 = hash->h4[5];
rk06 = hash->h4[6];
rk07 = hash->h4[7];
rk08 = hash->h4[8];
rk09 = hash->h4[9];
rk0A = hash->h4[10];
rk0B = hash->h4[11];
rk0C = hash->h4[12];
rk0D = hash->h4[13];
rk0E = hash->h4[14];
rk0F = hash->h4[15];
rk10 = 0x80;
rk11 = rk12 = rk13 = rk14 = rk15 = rk16 = rk17 = rk18 = rk19 = rk1A = 0;
rk1B = 0x2000000;
rk1C = rk1D = rk1E = 0;
rk1F = 0x2000000;
c512(buf);
hash->h4[0] = h0;
hash->h4[1] = h1;
hash->h4[2] = h2;
hash->h4[3] = h3;
hash->h4[4] = h4;
hash->h4[5] = h5;
hash->h4[6] = h6;
hash->h4[7] = h7;
hash->h4[8] = h8;
hash->h4[9] = h9;
hash->h4[10] = hA;
hash->h4[11] = hB;
hash->h4[12] = hC;
hash->h4[13] = hD;
hash->h4[14] = hE;
hash->h4[15] = hF;
barrier(CLK_GLOBAL_MEM_FENCE);
}
__attribute__((reqd_work_group_size(WORKSIZE, 1, 1)))
__kernel void search9(__global hash_t* hashes)
{
uint gid = get_global_id(0);
__global hash_t *hash = &(hashes[gid-get_global_offset(0)]);
// simd
s32 q[256];
unsigned char x[128];
for(unsigned int i = 0; i < 64; i++)
x[i] = hash->h1[i];
for(unsigned int i = 64; i < 128; i++)
x[i] = 0;
u32 A0 = C32(0x0BA16B95), A1 = C32(0x72F999AD), A2 = C32(0x9FECC2AE), A3 = C32(0xBA3264FC), A4 = C32(0x5E894929), A5 = C32(0x8E9F30E5), A6 = C32(0x2F1DAA37), A7 = C32(0xF0F2C558);
u32 B0 = C32(0xAC506643), B1 = C32(0xA90635A5), B2 = C32(0xE25B878B), B3 = C32(0xAAB7878F), B4 = C32(0x88817F7A), B5 = C32(0x0A02892B), B6 = C32(0x559A7550), B7 = C32(0x598F657E);
u32 C0 = C32(0x7EEF60A1), C1 = C32(0x6B70E3E8), C2 = C32(0x9C1714D1), C3 = C32(0xB958E2A8), C4 = C32(0xAB02675E), C5 = C32(0xED1C014F), C6 = C32(0xCD8D65BB), C7 = C32(0xFDB7A257);
u32 D0 = C32(0x09254899), D1 = C32(0xD699C7BC), D2 = C32(0x9019B6DC), D3 = C32(0x2B9022E4), D4 = C32(0x8FA14956), D5 = C32(0x21BF9BD3), D6 = C32(0xB94D0943), D7 = C32(0x6FFDDC22);
FFT256(0, 1, 0, ll1);
for (int i = 0; i < 256; i ++) {
s32 tq;
tq = q[i] + yoff_b_n[i];
tq = REDS2(tq);
tq = REDS1(tq);
tq = REDS1(tq);
q[i] = (tq <= 128 ? tq : tq - 257);
}
A0 ^= hash->h4[0];
A1 ^= hash->h4[1];
A2 ^= hash->h4[2];
A3 ^= hash->h4[3];
A4 ^= hash->h4[4];
A5 ^= hash->h4[5];
A6 ^= hash->h4[6];
A7 ^= hash->h4[7];
B0 ^= hash->h4[8];
B1 ^= hash->h4[9];
B2 ^= hash->h4[10];
B3 ^= hash->h4[11];
B4 ^= hash->h4[12];
B5 ^= hash->h4[13];
B6 ^= hash->h4[14];
B7 ^= hash->h4[15];
ONE_ROUND_BIG(0_, 0, 3, 23, 17, 27);
ONE_ROUND_BIG(1_, 1, 28, 19, 22, 7);
ONE_ROUND_BIG(2_, 2, 29, 9, 15, 5);
ONE_ROUND_BIG(3_, 3, 4, 13, 10, 25);
STEP_BIG(
C32(0x0BA16B95), C32(0x72F999AD), C32(0x9FECC2AE), C32(0xBA3264FC),
C32(0x5E894929), C32(0x8E9F30E5), C32(0x2F1DAA37), C32(0xF0F2C558),
IF, 4, 13, PP8_4_);
STEP_BIG(
C32(0xAC506643), C32(0xA90635A5), C32(0xE25B878B), C32(0xAAB7878F),
C32(0x88817F7A), C32(0x0A02892B), C32(0x559A7550), C32(0x598F657E),
IF, 13, 10, PP8_5_);
STEP_BIG(
C32(0x7EEF60A1), C32(0x6B70E3E8), C32(0x9C1714D1), C32(0xB958E2A8),
C32(0xAB02675E), C32(0xED1C014F), C32(0xCD8D65BB), C32(0xFDB7A257),
IF, 10, 25, PP8_6_);
STEP_BIG(
C32(0x09254899), C32(0xD699C7BC), C32(0x9019B6DC), C32(0x2B9022E4),
C32(0x8FA14956), C32(0x21BF9BD3), C32(0xB94D0943), C32(0x6FFDDC22),
IF, 25, 4, PP8_0_);
u32 COPY_A0 = A0, COPY_A1 = A1, COPY_A2 = A2, COPY_A3 = A3, COPY_A4 = A4, COPY_A5 = A5, COPY_A6 = A6, COPY_A7 = A7;
u32 COPY_B0 = B0, COPY_B1 = B1, COPY_B2 = B2, COPY_B3 = B3, COPY_B4 = B4, COPY_B5 = B5, COPY_B6 = B6, COPY_B7 = B7;
u32 COPY_C0 = C0, COPY_C1 = C1, COPY_C2 = C2, COPY_C3 = C3, COPY_C4 = C4, COPY_C5 = C5, COPY_C6 = C6, COPY_C7 = C7;
u32 COPY_D0 = D0, COPY_D1 = D1, COPY_D2 = D2, COPY_D3 = D3, COPY_D4 = D4, COPY_D5 = D5, COPY_D6 = D6, COPY_D7 = D7;
#define q SIMD_Q
A0 ^= 0x200;
ONE_ROUND_BIG(0_, 0, 3, 23, 17, 27);
ONE_ROUND_BIG(1_, 1, 28, 19, 22, 7);
ONE_ROUND_BIG(2_, 2, 29, 9, 15, 5);
ONE_ROUND_BIG(3_, 3, 4, 13, 10, 25);
STEP_BIG(
COPY_A0, COPY_A1, COPY_A2, COPY_A3,
COPY_A4, COPY_A5, COPY_A6, COPY_A7,
IF, 4, 13, PP8_4_);
STEP_BIG(
COPY_B0, COPY_B1, COPY_B2, COPY_B3,
COPY_B4, COPY_B5, COPY_B6, COPY_B7,
IF, 13, 10, PP8_5_);
STEP_BIG(
COPY_C0, COPY_C1, COPY_C2, COPY_C3,
COPY_C4, COPY_C5, COPY_C6, COPY_C7,
IF, 10, 25, PP8_6_);
STEP_BIG(
COPY_D0, COPY_D1, COPY_D2, COPY_D3,
COPY_D4, COPY_D5, COPY_D6, COPY_D7,
IF, 25, 4, PP8_0_);
#undef q
hash->h4[0] = A0;
hash->h4[1] = A1;
hash->h4[2] = A2;
hash->h4[3] = A3;
hash->h4[4] = A4;
hash->h4[5] = A5;
hash->h4[6] = A6;
hash->h4[7] = A7;
hash->h4[8] = B0;
hash->h4[9] = B1;
hash->h4[10] = B2;
hash->h4[11] = B3;
hash->h4[12] = B4;
hash->h4[13] = B5;
hash->h4[14] = B6;
hash->h4[15] = B7;
barrier(CLK_GLOBAL_MEM_FENCE);
}
__attribute__((reqd_work_group_size(WORKSIZE, 1, 1)))
__kernel void search10(__global hash_t* hashes, __global uint* output, const ulong target)
{
uint gid = get_global_id(0);
uint offset = get_global_offset(0);
hash_t hash;
__local sph_u32 AES0[256], AES1[256], AES2[256], AES3[256];
int init = get_local_id(0);
int step = get_local_size(0);
for (int i = init; i < 256; i += step)
{
AES0[i] = AES0_C[i];
AES1[i] = AES1_C[i];
AES2[i] = AES2_C[i];
AES3[i] = AES3_C[i];
}
barrier(CLK_LOCAL_MEM_FENCE);
for (int i = 0; i < 8; i++) {
hash.h8[i] = hashes[gid-offset].h8[i];
}
// echo
{
sph_u64 W00, W01, W10, W11, W20, W21, W30, W31, W40, W41, W50, W51, W60, W61, W70, W71, W80, W81, W90, W91, WA0, WA1, WB0, WB1, WC0, WC1, WD0, WD1, WE0, WE1, WF0, WF1;
sph_u64 Vb00, Vb01, Vb10, Vb11, Vb20, Vb21, Vb30, Vb31, Vb40, Vb41, Vb50, Vb51, Vb60, Vb61, Vb70, Vb71;
Vb00 = Vb10 = Vb20 = Vb30 = Vb40 = Vb50 = Vb60 = Vb70 = 512UL;
Vb01 = Vb11 = Vb21 = Vb31 = Vb41 = Vb51 = Vb61 = Vb71 = 0;
sph_u32 K0 = 512;
sph_u32 K1 = 0;
sph_u32 K2 = 0;
sph_u32 K3 = 0;
W00 = Vb00;
W01 = Vb01;
W10 = Vb10;
W11 = Vb11;
W20 = Vb20;
W21 = Vb21;
W30 = Vb30;
W31 = Vb31;
W40 = Vb40;
W41 = Vb41;
W50 = Vb50;
W51 = Vb51;
W60 = Vb60;
W61 = Vb61;
W70 = Vb70;
W71 = Vb71;
W80 = hash.h8[0];
W81 = hash.h8[1];
W90 = hash.h8[2];
W91 = hash.h8[3];
WA0 = hash.h8[4];
WA1 = hash.h8[5];
WB0 = hash.h8[6];
WB1 = hash.h8[7];
WC0 = 0x80;
WC1 = 0;
WD0 = 0;
WD1 = 0;
WE0 = 0;
WE1 = 0x200000000000000;
WF0 = 0x200;
WF1 = 0;
for (unsigned u = 0; u < 10; u ++) {
BIG_ROUND;
}
hash.h8[0] ^= Vb00 ^ W00 ^ W80;
hash.h8[1] ^= Vb01 ^ W01 ^ W81;
hash.h8[2] ^= Vb10 ^ W10 ^ W90;
hash.h8[3] ^= Vb11 ^ W11 ^ W91;
hash.h8[4] ^= Vb20 ^ W20 ^ WA0;
hash.h8[5] ^= Vb21 ^ W21 ^ WA1;
hash.h8[6] ^= Vb30 ^ W30 ^ WB0;
hash.h8[7] ^= Vb31 ^ W31 ^ WB1;
}
// hamsi
{
sph_u32 c0 = HAMSI_IV512[0], c1 = HAMSI_IV512[1], c2 = HAMSI_IV512[2], c3 = HAMSI_IV512[3];
sph_u32 c4 = HAMSI_IV512[4], c5 = HAMSI_IV512[5], c6 = HAMSI_IV512[6], c7 = HAMSI_IV512[7];
sph_u32 c8 = HAMSI_IV512[8], c9 = HAMSI_IV512[9], cA = HAMSI_IV512[10], cB = HAMSI_IV512[11];
sph_u32 cC = HAMSI_IV512[12], cD = HAMSI_IV512[13], cE = HAMSI_IV512[14], cF = HAMSI_IV512[15];
sph_u32 m0, m1, m2, m3, m4, m5, m6, m7;
sph_u32 m8, m9, mA, mB, mC, mD, mE, mF;
sph_u32 h[16] = { c0, c1, c2, c3, c4, c5, c6, c7, c8, c9, cA, cB, cC, cD, cE, cF };
#define buf(u) hash.h1[i + u]
for(int i = 0; i < 64; i += 8) {
INPUT_BIG;
P_BIG;
T_BIG;
}
#undef buf
#define buf(u) (u == 0 ? 0x80 : 0)
INPUT_BIG;
P_BIG;
T_BIG;
#undef buf
#define buf(u) (u == 6 ? 2 : 0)
INPUT_BIG;
PF_BIG;
T_BIG;
for (unsigned u = 0; u < 16; u ++)
hash.h4[u] = h[u];
}
// fugue
{
sph_u32 S00, S01, S02, S03, S04, S05, S06, S07, S08, S09;
sph_u32 S10, S11, S12, S13, S14, S15, S16, S17, S18, S19;
sph_u32 S20, S21, S22, S23, S24, S25, S26, S27, S28, S29;
sph_u32 S30, S31, S32, S33, S34, S35;
ulong fc_bit_count = (sph_u64) 64 << 3;
S00 = S01 = S02 = S03 = S04 = S05 = S06 = S07 = S08 = S09 = S10 = S11 = S12 = S13 = S14 = S15 = S16 = S17 = S18 = S19 = 0;
S20 = SPH_C32(0x8807a57e); S21 = SPH_C32(0xe616af75); S22 = SPH_C32(0xc5d3e4db); S23 = SPH_C32(0xac9ab027);
S24 = SPH_C32(0xd915f117); S25 = SPH_C32(0xb6eecc54); S26 = SPH_C32(0x06e8020b); S27 = SPH_C32(0x4a92efd1);
S28 = SPH_C32(0xaac6e2c9); S29 = SPH_C32(0xddb21398); S30 = SPH_C32(0xcae65838); S31 = SPH_C32(0x437f203f);
S32 = SPH_C32(0x25ea78e7); S33 = SPH_C32(0x951fddd6); S34 = SPH_C32(0xda6ed11d); S35 = SPH_C32(0xe13e3567);
FUGUE512_3((hash.h4[0x0]), (hash.h4[0x1]), (hash.h4[0x2]));
FUGUE512_3((hash.h4[0x3]), (hash.h4[0x4]), (hash.h4[0x5]));
FUGUE512_3((hash.h4[0x6]), (hash.h4[0x7]), (hash.h4[0x8]));
FUGUE512_3((hash.h4[0x9]), (hash.h4[0xA]), (hash.h4[0xB]));
FUGUE512_3((hash.h4[0xC]), (hash.h4[0xD]), (hash.h4[0xE]));
FUGUE512_3((hash.h4[0xF]), as_uint2(fc_bit_count).y, as_uint2(fc_bit_count).x);
// apply round shift if necessary
int i;
for (i = 0; i < 32; i ++) {
ROR3;
CMIX36(S00, S01, S02, S04, S05, S06, S18, S19, S20);
SMIX(S00, S01, S02, S03);
}
for (i = 0; i < 13; i ++) {
S04 ^= S00;
S09 ^= S00;
S18 ^= S00;
S27 ^= S00;
ROR9;
SMIX(S00, S01, S02, S03);
S04 ^= S00;
S10 ^= S00;
S18 ^= S00;
S27 ^= S00;
ROR9;
SMIX(S00, S01, S02, S03);
S04 ^= S00;
S10 ^= S00;
S19 ^= S00;
S27 ^= S00;
ROR9;
SMIX(S00, S01, S02, S03);
S04 ^= S00;
S10 ^= S00;
S19 ^= S00;
S28 ^= S00;
ROR8;
SMIX(S00, S01, S02, S03);
}
S04 ^= S00;
S09 ^= S00;
S18 ^= S00;
S27 ^= S00;
hash.h4[0] = SWAP4(S01);
hash.h4[1] = SWAP4(S02);
hash.h4[2] = SWAP4(S03);
hash.h4[3] = SWAP4(S04);
hash.h4[4] = SWAP4(S09);
hash.h4[5] = SWAP4(S10);
hash.h4[6] = SWAP4(S11);
hash.h4[7] = SWAP4(S12);
hash.h4[8] = SWAP4(S18);
hash.h4[9] = SWAP4(S19);
hash.h4[10] = SWAP4(S20);
hash.h4[11] = SWAP4(S21);
hash.h4[12] = SWAP4(S27);
hash.h4[13] = SWAP4(S28);
hash.h4[14] = SWAP4(S29);
hash.h4[15] = SWAP4(S30);
}
bool result = (hash.h8[3] <= target);
if (result)
output[atomic_inc(output+0xFF)] = SWAP4(gid);
barrier(CLK_GLOBAL_MEM_FENCE);
}
#endif // X13MOD_CL
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