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#include <memory.h>
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#define SPH_C32(x) ((uint32_t)(x ## U))
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#define SPH_T32(x) ((x) & SPH_C32(0xFFFFFFFF))
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#include "cuda_helper.h"
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static uint32_t *h_GNonces[MAX_GPUS];
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static uint32_t *d_GNonces[MAX_GPUS];
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__constant__ uint32_t pTarget[8];
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#define C32e(x) \
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((SPH_C32(x) >> 24) \
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| ((SPH_C32(x) >> 8) & SPH_C32(0x0000FF00)) \
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| ((SPH_C32(x) << 8) & SPH_C32(0x00FF0000)) \
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| ((SPH_C32(x) << 24) & SPH_C32(0xFF000000)))
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#define PC32up(j, r) ((uint32_t)((j) + (r)))
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#define PC32dn(j, r) 0
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#define QC32up(j, r) 0xFFFFFFFF
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#define QC32dn(j, r) (((uint32_t)(r) << 24) ^ SPH_T32(~((uint32_t)(j) << 24)))
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#define B32_0(x) __byte_perm(x, 0, 0x4440)
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//((x) & 0xFF)
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#define B32_1(x) __byte_perm(x, 0, 0x4441)
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//(((x) >> 8) & 0xFF)
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#define B32_2(x) __byte_perm(x, 0, 0x4442)
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//(((x) >> 16) & 0xFF)
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#define B32_3(x) __byte_perm(x, 0, 0x4443)
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//((x) >> 24)
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#define MAXWELL_OR_FERMI 1
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#if MAXWELL_OR_FERMI
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#define USE_SHARED 1
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// Maxwell and Fermi cards get the best speed with SHARED access it seems.
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#if USE_SHARED
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#define T0up(x) (*((uint32_t*)mixtabs + ( (x))))
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#define T0dn(x) (*((uint32_t*)mixtabs + (256+(x))))
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#define T1up(x) (*((uint32_t*)mixtabs + (512+(x))))
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#define T1dn(x) (*((uint32_t*)mixtabs + (768+(x))))
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#define T2up(x) (*((uint32_t*)mixtabs + (1024+(x))))
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#define T2dn(x) (*((uint32_t*)mixtabs + (1280+(x))))
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#define T3up(x) (*((uint32_t*)mixtabs + (1536+(x))))
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#define T3dn(x) (*((uint32_t*)mixtabs + (1792+(x))))
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#else
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#define T0up(x) tex1Dfetch(t0up2, x)
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#define T0dn(x) tex1Dfetch(t0dn2, x)
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#define T1up(x) tex1Dfetch(t1up2, x)
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#define T1dn(x) tex1Dfetch(t1dn2, x)
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#define T2up(x) tex1Dfetch(t2up2, x)
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#define T2dn(x) tex1Dfetch(t2dn2, x)
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#define T3up(x) tex1Dfetch(t3up2, x)
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#define T3dn(x) tex1Dfetch(t3dn2, x)
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#endif
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#else
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#define USE_SHARED 1
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// a healthy mix between shared and textured access provides the highest speed on Compute 3.0 and 3.5!
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#define T0up(x) (*((uint32_t*)mixtabs + ( (x))))
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#define T0dn(x) tex1Dfetch(t0dn2, x)
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#define T1up(x) tex1Dfetch(t1up2, x)
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#define T1dn(x) (*((uint32_t*)mixtabs + (768+(x))))
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#define T2up(x) tex1Dfetch(t2up2, x)
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#define T2dn(x) (*((uint32_t*)mixtabs + (1280+(x))))
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#define T3up(x) (*((uint32_t*)mixtabs + (1536+(x))))
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#define T3dn(x) tex1Dfetch(t3dn2, x)
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#endif
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texture<unsigned int, 1, cudaReadModeElementType> t0up2;
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texture<unsigned int, 1, cudaReadModeElementType> t0dn2;
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texture<unsigned int, 1, cudaReadModeElementType> t1up2;
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texture<unsigned int, 1, cudaReadModeElementType> t1dn2;
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texture<unsigned int, 1, cudaReadModeElementType> t2up2;
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texture<unsigned int, 1, cudaReadModeElementType> t2dn2;
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texture<unsigned int, 1, cudaReadModeElementType> t3up2;
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texture<unsigned int, 1, cudaReadModeElementType> t3dn2;
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#define RSTT(d0, d1, a, b0, b1, b2, b3, b4, b5, b6, b7) do { \
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t[d0] = T0up(B32_0(a[b0])) \
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^ T1up(B32_1(a[b1])) \
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^ T2up(B32_2(a[b2])) \
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^ T3up(B32_3(a[b3])) \
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^ T0dn(B32_0(a[b4])) \
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^ T1dn(B32_1(a[b5])) \
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^ T2dn(B32_2(a[b6])) \
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^ T3dn(B32_3(a[b7])); \
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t[d1] = T0dn(B32_0(a[b0])) \
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^ T1dn(B32_1(a[b1])) \
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^ T2dn(B32_2(a[b2])) \
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^ T3dn(B32_3(a[b3])) \
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^ T0up(B32_0(a[b4])) \
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^ T1up(B32_1(a[b5])) \
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^ T2up(B32_2(a[b6])) \
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^ T3up(B32_3(a[b7])); \
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} while (0)
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extern uint32_t T0up_cpu[];
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extern uint32_t T0dn_cpu[];
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extern uint32_t T1up_cpu[];
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extern uint32_t T1dn_cpu[];
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extern uint32_t T2up_cpu[];
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extern uint32_t T2dn_cpu[];
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extern uint32_t T3up_cpu[];
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extern uint32_t T3dn_cpu[];
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__device__ __forceinline__
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void groestl256_perm_P(uint32_t thread,uint32_t *a, char *mixtabs)
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{
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#pragma unroll 10
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for (int r = 0; r<10; r++)
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{
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uint32_t t[16];
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a[0x0] ^= PC32up(0x00, r);
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a[0x2] ^= PC32up(0x10, r);
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a[0x4] ^= PC32up(0x20, r);
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a[0x6] ^= PC32up(0x30, r);
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a[0x8] ^= PC32up(0x40, r);
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a[0xA] ^= PC32up(0x50, r);
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a[0xC] ^= PC32up(0x60, r);
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a[0xE] ^= PC32up(0x70, r);
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RSTT(0x0, 0x1, a, 0x0, 0x2, 0x4, 0x6, 0x9, 0xB, 0xD, 0xF);
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RSTT(0x2, 0x3, a, 0x2, 0x4, 0x6, 0x8, 0xB, 0xD, 0xF, 0x1);
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RSTT(0x4, 0x5, a, 0x4, 0x6, 0x8, 0xA, 0xD, 0xF, 0x1, 0x3);
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RSTT(0x6, 0x7, a, 0x6, 0x8, 0xA, 0xC, 0xF, 0x1, 0x3, 0x5);
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RSTT(0x8, 0x9, a, 0x8, 0xA, 0xC, 0xE, 0x1, 0x3, 0x5, 0x7);
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RSTT(0xA, 0xB, a, 0xA, 0xC, 0xE, 0x0, 0x3, 0x5, 0x7, 0x9);
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RSTT(0xC, 0xD, a, 0xC, 0xE, 0x0, 0x2, 0x5, 0x7, 0x9, 0xB);
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RSTT(0xE, 0xF, a, 0xE, 0x0, 0x2, 0x4, 0x7, 0x9, 0xB, 0xD);
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#pragma unroll 16
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for (int k = 0; k<16; k++)
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a[k] = t[k];
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}
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}
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__device__ __forceinline__
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void groestl256_perm_Q(uint32_t thread, uint32_t *a, char *mixtabs)
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{
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#pragma unroll
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for (int r = 0; r<10; r++)
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{
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uint32_t t[16];
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a[0x0] ^= QC32up(0x00, r);
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a[0x1] ^= QC32dn(0x00, r);
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a[0x2] ^= QC32up(0x10, r);
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a[0x3] ^= QC32dn(0x10, r);
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a[0x4] ^= QC32up(0x20, r);
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a[0x5] ^= QC32dn(0x20, r);
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a[0x6] ^= QC32up(0x30, r);
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a[0x7] ^= QC32dn(0x30, r);
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a[0x8] ^= QC32up(0x40, r);
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a[0x9] ^= QC32dn(0x40, r);
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a[0xA] ^= QC32up(0x50, r);
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a[0xB] ^= QC32dn(0x50, r);
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a[0xC] ^= QC32up(0x60, r);
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a[0xD] ^= QC32dn(0x60, r);
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a[0xE] ^= QC32up(0x70, r);
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a[0xF] ^= QC32dn(0x70, r);
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RSTT(0x0, 0x1, a, 0x2, 0x6, 0xA, 0xE, 0x1, 0x5, 0x9, 0xD);
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RSTT(0x2, 0x3, a, 0x4, 0x8, 0xC, 0x0, 0x3, 0x7, 0xB, 0xF);
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RSTT(0x4, 0x5, a, 0x6, 0xA, 0xE, 0x2, 0x5, 0x9, 0xD, 0x1);
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RSTT(0x6, 0x7, a, 0x8, 0xC, 0x0, 0x4, 0x7, 0xB, 0xF, 0x3);
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RSTT(0x8, 0x9, a, 0xA, 0xE, 0x2, 0x6, 0x9, 0xD, 0x1, 0x5);
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RSTT(0xA, 0xB, a, 0xC, 0x0, 0x4, 0x8, 0xB, 0xF, 0x3, 0x7);
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RSTT(0xC, 0xD, a, 0xE, 0x2, 0x6, 0xA, 0xD, 0x1, 0x5, 0x9);
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RSTT(0xE, 0xF, a, 0x0, 0x4, 0x8, 0xC, 0xF, 0x3, 0x7, 0xB);
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#pragma unroll
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for (int k = 0; k<16; k++)
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a[k] = t[k];
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}
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}
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__global__ __launch_bounds__(256,1)
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void groestl256_gpu_hash32(uint32_t threads, uint32_t startNounce, uint64_t *outputHash, uint32_t *resNonces)
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{
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#if USE_SHARED
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extern __shared__ char mixtabs[];
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if (threadIdx.x < 256) {
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*((uint32_t*)mixtabs + (threadIdx.x)) = tex1Dfetch(t0up2, threadIdx.x);
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*((uint32_t*)mixtabs + (256 + threadIdx.x)) = tex1Dfetch(t0dn2, threadIdx.x);
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*((uint32_t*)mixtabs + (512 + threadIdx.x)) = tex1Dfetch(t1up2, threadIdx.x);
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*((uint32_t*)mixtabs + (768 + threadIdx.x)) = tex1Dfetch(t1dn2, threadIdx.x);
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*((uint32_t*)mixtabs + (1024 + threadIdx.x)) = tex1Dfetch(t2up2, threadIdx.x);
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*((uint32_t*)mixtabs + (1280 + threadIdx.x)) = tex1Dfetch(t2dn2, threadIdx.x);
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*((uint32_t*)mixtabs + (1536 + threadIdx.x)) = tex1Dfetch(t3up2, threadIdx.x);
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*((uint32_t*)mixtabs + (1792 + threadIdx.x)) = tex1Dfetch(t3dn2, threadIdx.x);
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}
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__syncthreads();
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#endif
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uint32_t thread = (blockDim.x * blockIdx.x + threadIdx.x);
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if (thread < threads)
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{
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// GROESTL
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uint32_t message[16];
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uint32_t state[16];
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#pragma unroll
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for (int k = 0; k<4; k++)
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LOHI(message[2*k], message[2*k+1], outputHash[k*threads+thread]);
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#pragma unroll
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for (int k = 9; k<15; k++)
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message[k] = 0;
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message[8] = 0x80;
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message[15] = 0x01000000;
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#pragma unroll 16
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for (int u = 0; u<16; u++)
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state[u] = message[u];
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state[15] ^= 0x10000;
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// Perm
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#if USE_SHARED
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groestl256_perm_P(thread, state, mixtabs);
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state[15] ^= 0x10000;
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groestl256_perm_Q(thread, message, mixtabs);
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#else
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groestl256_perm_P(thread, state, NULL);
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state[15] ^= 0x10000;
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groestl256_perm_P(thread, message, NULL);
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#endif
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#pragma unroll 16
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for (int u = 0; u<16; u++) state[u] ^= message[u];
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#pragma unroll 16
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for (int u = 0; u<16; u++) message[u] = state[u];
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#if USE_SHARED
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groestl256_perm_P(thread, message, mixtabs);
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#else
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groestl256_perm_P(thread, message, NULL);
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#endif
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state[14] ^= message[14];
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state[15] ^= message[15];
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uint32_t nonce = startNounce + thread;
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if (state[15] <= pTarget[7]) {
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atomicMin(&resNonces[1], resNonces[0]);
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atomicMin(&resNonces[0], nonce);
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}
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}
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}
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#define texDef(texname, texmem, texsource, texsize) \
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unsigned int *texmem; \
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cudaMalloc(&texmem, texsize); \
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cudaMemcpy(texmem, texsource, texsize, cudaMemcpyHostToDevice); \
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texname.normalized = 0; \
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texname.filterMode = cudaFilterModePoint; \
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texname.addressMode[0] = cudaAddressModeClamp; \
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{ cudaChannelFormatDesc channelDesc = cudaCreateChannelDesc<unsigned int>(); \
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cudaBindTexture(NULL, &texname, texmem, &channelDesc, texsize ); } \
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__host__
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void groestl256_cpu_init(int thr_id, uint32_t threads)
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{
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// Texturen mit obigem Makro initialisieren
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texDef(t0up2, d_T0up, T0up_cpu, sizeof(uint32_t) * 256);
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texDef(t0dn2, d_T0dn, T0dn_cpu, sizeof(uint32_t) * 256);
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texDef(t1up2, d_T1up, T1up_cpu, sizeof(uint32_t) * 256);
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texDef(t1dn2, d_T1dn, T1dn_cpu, sizeof(uint32_t) * 256);
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texDef(t2up2, d_T2up, T2up_cpu, sizeof(uint32_t) * 256);
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texDef(t2dn2, d_T2dn, T2dn_cpu, sizeof(uint32_t) * 256);
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texDef(t3up2, d_T3up, T3up_cpu, sizeof(uint32_t) * 256);
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texDef(t3dn2, d_T3dn, T3dn_cpu, sizeof(uint32_t) * 256);
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cudaMalloc(&d_GNonces[thr_id], 2*sizeof(uint32_t));
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cudaMallocHost(&h_GNonces[thr_id], 2*sizeof(uint32_t));
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}
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__host__
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void groestl256_cpu_free(int thr_id)
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{
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cudaFree(d_GNonces[thr_id]);
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cudaFreeHost(h_GNonces[thr_id]);
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}
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__host__
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uint32_t groestl256_cpu_hash_32(int thr_id, uint32_t threads, uint32_t startNounce, uint64_t *d_outputHash, int order)
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{
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uint32_t result = UINT32_MAX;
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cudaMemset(d_GNonces[thr_id], 0xff, 2*sizeof(uint32_t));
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const uint32_t threadsperblock = 256;
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// berechne wie viele Thread Blocks wir brauchen
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dim3 grid((threads + threadsperblock-1)/threadsperblock);
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dim3 block(threadsperblock);
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#if USE_SHARED
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size_t shared_size = 8 * 256 * sizeof(uint32_t);
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#else
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size_t shared_size = 0;
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#endif
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groestl256_gpu_hash32<<<grid, block, shared_size>>>(threads, startNounce, d_outputHash, d_GNonces[thr_id]);
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MyStreamSynchronize(NULL, order, thr_id);
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// get first found nonce
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cudaMemcpy(h_GNonces[thr_id], d_GNonces[thr_id], 1*sizeof(uint32_t), cudaMemcpyDeviceToHost);
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result = *h_GNonces[thr_id];
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return result;
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}
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__host__
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uint32_t groestl256_getSecNonce(int thr_id, int num)
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{
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uint32_t results[2];
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memset(results, 0xFF, sizeof(results));
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cudaMemcpy(results, d_GNonces[thr_id], sizeof(results), cudaMemcpyDeviceToHost);
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if (results[1] == results[0])
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return UINT32_MAX;
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return results[num];
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}
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__host__
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void groestl256_setTarget(const void *pTargetIn)
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{
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cudaMemcpyToSymbol(pTarget, pTargetIn, 32, 0, cudaMemcpyHostToDevice);
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}
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