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xmr: dont use shared mem hack, windows dont like

master
Tanguy Pruvot 8 years ago
parent
commit
588c7ba361
  1. 1
      crypto/cryptolight.h
  2. 25
      crypto/cryptonight-core.cu
  3. 2
      crypto/cryptonight.cu
  4. 3
      crypto/cryptonight.h

1
crypto/cryptolight.h

@ -14,6 +14,7 @@ struct uint3 blockDim;
#define atomicExch(p,y) (*p) = y #define atomicExch(p,y) (*p) = y
#define __funnelshift_r(a,b,c) 1 #define __funnelshift_r(a,b,c) 1
#define __syncthreads() #define __syncthreads()
#define __threadfence_block()
#define asm(x) #define asm(x)
#define __shfl(a,b,c) 1 #define __shfl(a,b,c) 1
#define __umul64hi(a,b) a*b #define __umul64hi(a,b) a*b

25
crypto/cryptonight-core.cu

@ -32,12 +32,14 @@ void cryptonight_core_gpu_phase1(const uint32_t threads, uint32_t * long_state,
for (uint32_t i = 0; i < 40U; i += 4U) for (uint32_t i = 0; i < 40U; i += 4U)
AS_UINT4(&key[i]) = AS_UINT4(&ctx_key[i]); AS_UINT4(&key[i]) = AS_UINT4(&ctx_key[i]);
__threadfence_block(); __syncthreads();
for(uint32_t i = 0; i < LONG_LOOPS32; i += 32U) { for(uint32_t i = 0; i < LONG_LOOPS32; i += 32U) {
cn_aes_pseudo_round_mut(sharedMemory, (uint32_t*) &text, key); cn_aes_pseudo_round_mut(sharedMemory, (uint32_t*) &text, key);
AS_UL2(&long_state[long_oft + i]) = text; AS_UL2(&long_state[long_oft + i]) = text;
} }
} else {
__syncthreads();
} }
} }
@ -79,8 +81,8 @@ void cryptonight_core_gpu_phase2(const uint32_t threads, const uint32_t bfactor,
{ {
__shared__ __align__(16) uint32_t sharedMemory[1024]; __shared__ __align__(16) uint32_t sharedMemory[1024];
// cn_aes_gpu_init(sharedMemory); cn_aes_gpu_init(sharedMemory);
// __syncthreads(); __syncthreads();
const uint32_t thread = blockDim.x * blockIdx.x + threadIdx.x; const uint32_t thread = blockDim.x * blockIdx.x + threadIdx.x;
@ -125,7 +127,7 @@ void cryptonight_core_gpu_phase3(const uint32_t threads, const uint32_t * __rest
{ {
__shared__ __align__(16) uint32_t sharedMemory[1024]; __shared__ __align__(16) uint32_t sharedMemory[1024];
//cn_aes_gpu_init(sharedMemory); cn_aes_gpu_init(sharedMemory);
const uint32_t thread = (blockDim.x * blockIdx.x + threadIdx.x) >> 3U; const uint32_t thread = (blockDim.x * blockIdx.x + threadIdx.x) >> 3U;
const uint32_t sub = (threadIdx.x & 7U) << 2U; const uint32_t sub = (threadIdx.x & 7U) << 2U;
@ -144,7 +146,7 @@ void cryptonight_core_gpu_phase3(const uint32_t threads, const uint32_t * __rest
for (uint32_t i = 0; i < 40U; i += 4U) for (uint32_t i = 0; i < 40U; i += 4U)
AS_UL2(&key[i]) = AS_UL2(&ctx_key[i]); AS_UL2(&key[i]) = AS_UL2(&ctx_key[i]);
//__syncthreads(); __syncthreads();
for(uint32_t i = 0; i < LONG_LOOPS32; i += 32U) for(uint32_t i = 0; i < LONG_LOOPS32; i += 32U)
{ {
ulonglong2 st = AS_UL2(&long_state[long_oft + i]); ulonglong2 st = AS_UL2(&long_state[long_oft + i]);
@ -153,13 +155,15 @@ void cryptonight_core_gpu_phase3(const uint32_t threads, const uint32_t * __rest
} }
AS_UL2(&ctx_state[st_oft]) = text; AS_UL2(&ctx_state[st_oft]) = text;
} else {
__syncthreads();
} }
} }
extern int device_bfactor[MAX_GPUS]; extern int device_bfactor[MAX_GPUS];
__host__ __host__
void cryptonight_core_cpu_hash(int thr_id, int blocks, int threads, uint32_t *d_long_state, uint64_t *d_ctx_state, void cryptonight_core_cuda(int thr_id, int blocks, int threads, uint32_t *d_long_state, uint64_t *d_ctx_state,
uint32_t *d_ctx_a, uint32_t *d_ctx_b, uint32_t *d_ctx_key1, uint32_t *d_ctx_key2) uint32_t *d_ctx_a, uint32_t *d_ctx_b, uint32_t *d_ctx_key1, uint32_t *d_ctx_key2)
{ {
dim3 grid(blocks); dim3 grid(blocks);
@ -174,20 +178,19 @@ void cryptonight_core_cpu_hash(int thr_id, int blocks, int threads, uint32_t *d_
const int bsleep = bfactor ? 100 : 0; const int bsleep = bfactor ? 100 : 0;
const int dev_id = device_map[thr_id]; const int dev_id = device_map[thr_id];
int i;
cryptonight_core_gpu_phase1 <<<grid, block8, 4096>>> (throughput, d_long_state, (uint32_t*)d_ctx_state, d_ctx_key1); cryptonight_core_gpu_phase1 <<<grid, block8>>> (throughput, d_long_state, (uint32_t*)d_ctx_state, d_ctx_key1);
exit_if_cudaerror(thr_id, __FUNCTION__, __LINE__); exit_if_cudaerror(thr_id, __FUNCTION__, __LINE__);
if(partcount > 1) usleep(bsleep); if(partcount > 1) usleep(bsleep);
for(i = 0; i < partcount; i++) for (uint32_t i = 0; i < partcount; i++)
{ {
dim3 b = device_sm[dev_id] >= 300 ? block4 : block; dim3 b = device_sm[dev_id] >= 300 ? block4 : block;
cryptonight_core_gpu_phase2 <<<grid, b, 4096>>> (throughput, bfactor, i, d_long_state, d_ctx_a, d_ctx_b); cryptonight_core_gpu_phase2 <<<grid, b>>> (throughput, bfactor, i, d_long_state, d_ctx_a, d_ctx_b);
exit_if_cudaerror(thr_id, __FUNCTION__, __LINE__); exit_if_cudaerror(thr_id, __FUNCTION__, __LINE__);
if(partcount > 1) usleep(bsleep); if(partcount > 1) usleep(bsleep);
} }
cryptonight_core_gpu_phase3 <<<grid, block8, 4096>>> (throughput, d_long_state, (uint32_t*)d_ctx_state, d_ctx_key2); cryptonight_core_gpu_phase3 <<<grid, block8>>> (throughput, d_long_state, (uint32_t*)d_ctx_state, d_ctx_key2);
exit_if_cudaerror(thr_id, __FUNCTION__, __LINE__); exit_if_cudaerror(thr_id, __FUNCTION__, __LINE__);
} }

2
crypto/cryptonight.cu

@ -92,7 +92,7 @@ extern "C" int scanhash_cryptonight(int thr_id, struct work* work, uint32_t max_
cryptonight_extra_cpu_setData(thr_id, pdata, ptarget); cryptonight_extra_cpu_setData(thr_id, pdata, ptarget);
cryptonight_extra_cpu_prepare(thr_id, throughput, nonce, d_ctx_state[thr_id], d_ctx_a[thr_id], d_ctx_b[thr_id], d_ctx_key1[thr_id], d_ctx_key2[thr_id]); cryptonight_extra_cpu_prepare(thr_id, throughput, nonce, d_ctx_state[thr_id], d_ctx_a[thr_id], d_ctx_b[thr_id], d_ctx_key1[thr_id], d_ctx_key2[thr_id]);
cryptonight_core_cpu_hash(thr_id, cn_blocks, cn_threads, d_long_state[thr_id], d_ctx_state[thr_id], d_ctx_a[thr_id], d_ctx_b[thr_id], d_ctx_key1[thr_id], d_ctx_key2[thr_id]); cryptonight_core_cuda(thr_id, cn_blocks, cn_threads, d_long_state[thr_id], d_ctx_state[thr_id], d_ctx_a[thr_id], d_ctx_b[thr_id], d_ctx_key1[thr_id], d_ctx_key2[thr_id]);
cryptonight_extra_cpu_final(thr_id, throughput, nonce, resNonces, d_ctx_state[thr_id]); cryptonight_extra_cpu_final(thr_id, throughput, nonce, resNonces, d_ctx_state[thr_id]);
*hashes_done = nonce - first_nonce + throughput; *hashes_done = nonce - first_nonce + throughput;

3
crypto/cryptonight.h

@ -14,6 +14,7 @@ struct uint3 blockDim;
#define atomicExch(p,y) (*p) = y #define atomicExch(p,y) (*p) = y
#define __funnelshift_r(a,b,c) 1 #define __funnelshift_r(a,b,c) 1
#define __syncthreads() #define __syncthreads()
#define __threadfence_block()
#define asm(x) #define asm(x)
#define __shfl(a,b,c) 1 #define __shfl(a,b,c) 1
#define __umul64hi(a,b) a*b #define __umul64hi(a,b) a*b
@ -136,7 +137,7 @@ static inline void exit_if_cudaerror(int thr_id, const char *src, int line)
exit(1); exit(1);
} }
} }
void cryptonight_core_cpu_hash(int thr_id, int blocks, int threads, uint32_t *d_long_state, uint64_t *d_ctx_state, uint32_t *d_ctx_a, uint32_t *d_ctx_b, uint32_t *d_ctx_key1, uint32_t *d_ctx_key2); void cryptonight_core_cuda(int thr_id, int blocks, int threads, uint32_t *d_long_state, uint64_t *d_ctx_state, uint32_t *d_ctx_a, uint32_t *d_ctx_b, uint32_t *d_ctx_key1, uint32_t *d_ctx_key2);
void cryptonight_extra_cpu_setData(int thr_id, const void *data, const void *pTargetIn); void cryptonight_extra_cpu_setData(int thr_id, const void *data, const void *pTargetIn);
void cryptonight_extra_cpu_init(int thr_id, uint32_t threads); void cryptonight_extra_cpu_init(int thr_id, uint32_t threads);

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