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270 lines
7.4 KiB
270 lines
7.4 KiB
/* Based on djm code */ |
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extern "C" { |
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#include "miner.h" |
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} |
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#include <stdint.h> |
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static uint32_t *d_hash[MAX_GPUS] ; |
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extern void pluck_setBlockTarget(const void* data, const void *ptarget); |
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extern void pluck_cpu_init(int thr_id, uint32_t threads, uint32_t *d_outputHash); |
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extern uint32_t pluck_cpu_hash(int thr_id, uint32_t threads, uint32_t startNounce, int order); |
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extern float tp_coef[MAX_GPUS]; |
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#define ROTL(a, b) (((a) << (b)) | ((a) >> (32 - (b)))) |
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//note, this is 64 bytes |
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static inline void xor_salsa8(uint32_t B[16], const uint32_t Bx[16]) |
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{ |
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#define ROTL(a, b) (((a) << (b)) | ((a) >> (32 - (b)))) |
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uint32_t x00, x01, x02, x03, x04, x05, x06, x07, x08, x09, x10, x11, x12, x13, x14, x15; |
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int i; |
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x00 = (B[0] ^= Bx[0]); |
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x01 = (B[1] ^= Bx[1]); |
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x02 = (B[2] ^= Bx[2]); |
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x03 = (B[3] ^= Bx[3]); |
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x04 = (B[4] ^= Bx[4]); |
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x05 = (B[5] ^= Bx[5]); |
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x06 = (B[6] ^= Bx[6]); |
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x07 = (B[7] ^= Bx[7]); |
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x08 = (B[8] ^= Bx[8]); |
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x09 = (B[9] ^= Bx[9]); |
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x10 = (B[10] ^= Bx[10]); |
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x11 = (B[11] ^= Bx[11]); |
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x12 = (B[12] ^= Bx[12]); |
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x13 = (B[13] ^= Bx[13]); |
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x14 = (B[14] ^= Bx[14]); |
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x15 = (B[15] ^= Bx[15]); |
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for (i = 0; i < 8; i += 2) { |
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/* Operate on columns. */ |
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x04 ^= ROTL(x00 + x12, 7); x09 ^= ROTL(x05 + x01, 7); |
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x14 ^= ROTL(x10 + x06, 7); x03 ^= ROTL(x15 + x11, 7); |
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x08 ^= ROTL(x04 + x00, 9); x13 ^= ROTL(x09 + x05, 9); |
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x02 ^= ROTL(x14 + x10, 9); x07 ^= ROTL(x03 + x15, 9); |
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x12 ^= ROTL(x08 + x04, 13); x01 ^= ROTL(x13 + x09, 13); |
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x06 ^= ROTL(x02 + x14, 13); x11 ^= ROTL(x07 + x03, 13); |
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x00 ^= ROTL(x12 + x08, 18); x05 ^= ROTL(x01 + x13, 18); |
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x10 ^= ROTL(x06 + x02, 18); x15 ^= ROTL(x11 + x07, 18); |
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/* Operate on rows. */ |
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x01 ^= ROTL(x00 + x03, 7); x06 ^= ROTL(x05 + x04, 7); |
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x11 ^= ROTL(x10 + x09, 7); x12 ^= ROTL(x15 + x14, 7); |
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x02 ^= ROTL(x01 + x00, 9); x07 ^= ROTL(x06 + x05, 9); |
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x08 ^= ROTL(x11 + x10, 9); x13 ^= ROTL(x12 + x15, 9); |
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x03 ^= ROTL(x02 + x01, 13); x04 ^= ROTL(x07 + x06, 13); |
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x09 ^= ROTL(x08 + x11, 13); x14 ^= ROTL(x13 + x12, 13); |
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x00 ^= ROTL(x03 + x02, 18); x05 ^= ROTL(x04 + x07, 18); |
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x10 ^= ROTL(x09 + x08, 18); x15 ^= ROTL(x14 + x13, 18); |
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} |
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B[0] += x00; |
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B[1] += x01; |
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B[2] += x02; |
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B[3] += x03; |
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B[4] += x04; |
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B[5] += x05; |
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B[6] += x06; |
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B[7] += x07; |
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B[8] += x08; |
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B[9] += x09; |
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B[10] += x10; |
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B[11] += x11; |
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B[12] += x12; |
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B[13] += x13; |
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B[14] += x14; |
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B[15] += x15; |
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#undef ROTL |
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} |
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static void sha256_hash(unsigned char *hash, const unsigned char *data, int len) |
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{ |
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uint32_t S[16], T[16]; |
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int i, r; |
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sha256_init(S); |
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for (r = len; r > -9; r -= 64) { |
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if (r < 64) |
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memset(T, 0, 64); |
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memcpy(T, data + len - r, r > 64 ? 64 : (r < 0 ? 0 : r)); |
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if (r >= 0 && r < 64) |
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((unsigned char *)T)[r] = 0x80; |
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for (i = 0; i < 16; i++) |
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T[i] = be32dec(T + i); |
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if (r < 56) |
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T[15] = 8 * len; |
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sha256_transform(S, T, 0); |
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} |
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for (i = 0; i < 8; i++) |
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be32enc((uint32_t *)hash + i, S[i]); |
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} |
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static void sha256_hash512(unsigned char *hash, const unsigned char *data) |
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{ |
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uint32_t S[16], T[16]; |
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int i; |
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sha256_init(S); |
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memcpy(T, data, 64); |
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for (i = 0; i < 16; i++) |
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T[i] = be32dec(T + i); |
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sha256_transform(S, T, 0); |
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memset(T, 0, 64); |
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//memcpy(T, data + 64, 0); |
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((unsigned char *)T)[0] = 0x80; |
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for (i = 0; i < 16; i++) |
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T[i] = be32dec(T + i); |
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T[15] = 8 * 64; |
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sha256_transform(S, T, 0); |
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for (i = 0; i < 8; i++) |
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be32enc((uint32_t *)hash + i, S[i]); |
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} |
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void pluckhash(uint32_t *hash, uint32_t *input) |
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{ |
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uint32_t data[20]; |
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//uint32_t midstate[8]; |
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const int HASH_MEMORY = 128 * 1024; |
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uint8_t * scratchbuf = (uint8_t*)malloc(HASH_MEMORY); |
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for (int k = 0; k<20; k++) { data[k] = input[k]; } |
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uint8_t *hashbuffer = scratchbuf; //don't allocate this on stack, since it's huge.. |
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int size = HASH_MEMORY; |
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memset(hashbuffer, 0, 64); |
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sha256_hash(&hashbuffer[0], (uint8_t*)data, 80); |
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for (int i = 64; i < size - 32; i += 32) |
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{ |
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//i-4 because we use integers for all references against this, and we don't want to go 3 bytes over the defined area |
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int randmax = i - 4; //we could use size here, but then it's probable to use 0 as the value in most cases |
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uint32_t joint[16]; |
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uint32_t randbuffer[16]; |
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uint32_t randseed[16]; |
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memcpy(randseed, &hashbuffer[i - 64], 64); |
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if (i>128) |
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{ |
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memcpy(randbuffer, &hashbuffer[i - 128], 64); |
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} |
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else |
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{ |
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memset(&randbuffer, 0, 64); |
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} |
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xor_salsa8(randbuffer, randseed); |
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memcpy(joint, &hashbuffer[i - 32], 32); |
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//use the last hash value as the seed |
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for (int j = 32; j < 64; j += 4) |
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{ |
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uint32_t rand = randbuffer[(j - 32) / 4] % (randmax - 32); //randmax - 32 as otherwise we go beyond memory that's already been written to |
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joint[j / 4] = *((uint32_t*)&hashbuffer[rand]); |
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} |
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sha256_hash512(&hashbuffer[i], (uint8_t*)joint); |
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// for (int k = 0; k<8; k++) { printf("sha hashbuffer %d %08x\n", k, ((uint32_t*)(hashbuffer+i))[k]); } |
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memcpy(randseed, &hashbuffer[i - 32], 64); //use last hash value and previous hash value(post-mixing) |
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if (i>128) |
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{ |
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memcpy(randbuffer, &hashbuffer[i - 128], 64); |
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} |
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else |
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{ |
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memset(randbuffer, 0, 64); |
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} |
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xor_salsa8(randbuffer, randseed); |
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for (int j = 0; j < 32; j += 2) |
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{ |
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uint32_t rand = randbuffer[j / 2] % randmax; |
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*((uint32_t*)&hashbuffer[rand]) = *((uint32_t*)&hashbuffer[j + i - 4]); |
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} |
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} |
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// for (int k = 0; k<8; k++) { printf("cpu final hash %d %08x\n", k, ((uint32_t*)hashbuffer)[k]); } |
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//note: off-by-one error is likely here... |
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/* |
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for (int i = size - 64 - 1; i >= 64; i -= 64) |
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{ |
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sha256_hash512(&hashbuffer[i - 64], &hashbuffer[i]); |
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} |
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for (int k = 0; k<8; k++) { printf("cpu after of by one final hash %d %08x\n", k, ((uint32_t*)hashbuffer)[k]); } |
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*/ |
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memcpy((unsigned char*)hash, hashbuffer, 32); |
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} |
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static bool init[MAX_GPUS] = { 0 }; |
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extern "C" int scanhash_pluck(int thr_id, uint32_t *pdata, const uint32_t *ptarget, |
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uint32_t max_nonce, unsigned long *hashes_done) |
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{ |
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const uint32_t first_nonce = pdata[19]; |
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uint32_t endiandata[20]; |
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int intensity = 18; /* beware > 20 could work and create diff problems later */ |
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uint32_t throughput = device_intensity(thr_id, __func__, 1U << intensity); |
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// divide by 128 for this algo which require a lot of memory |
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throughput = throughput / 128 - 256; |
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throughput = min(throughput, max_nonce - first_nonce + 1); |
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if (opt_benchmark) |
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((uint32_t*)ptarget)[7] = 0x0000ff; |
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if (!init[thr_id]) |
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{ |
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cudaSetDevice(device_map[thr_id]); |
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//cudaDeviceReset(); |
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//cudaSetDeviceFlags(cudaDeviceScheduleBlockingSync); |
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//cudaDeviceSetCacheConfig(cudaFuncCachePreferL1); |
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cudaMalloc(&d_hash[thr_id], 32 * 1024 * sizeof(uint32_t) * throughput); |
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pluck_cpu_init(thr_id, throughput, d_hash[thr_id]); |
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init[thr_id] = true; |
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} |
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for (int k = 0; k < 20; k++) |
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be32enc(&endiandata[k], ((uint32_t*)pdata)[k]); |
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pluck_setBlockTarget(endiandata,ptarget); |
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do { |
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uint32_t foundNonce = pluck_cpu_hash(thr_id, throughput, pdata[19], 0); |
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if (foundNonce != UINT32_MAX) |
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{ |
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// const uint32_t Htarg = ptarget[7]; |
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// uint32_t vhash64[8]; |
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// be32enc(&endiandata[19], foundNonce); |
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// pluckhash(vhash64,endiandata); |
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// printf("target %08x vhash64 %08x", ptarget[7], vhash64[7]); |
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// if (vhash64[7] <= Htarg) { // && fulltest(vhash64, ptarget)) { |
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*hashes_done = pdata[19] - first_nonce + throughput; |
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pdata[19] = foundNonce; |
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return 1; |
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// } else { |
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// applog(LOG_INFO, "GPU #%d: result for %08x does not validate on CPU!", thr_id, foundNonce); |
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// } |
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} |
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pdata[19] += throughput; |
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} while (pdata[19] < max_nonce && !work_restart[thr_id].restart); |
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*hashes_done = pdata[19] - first_nonce; |
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return 0; |
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}
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