void OpenCLMomentumV9::find_collisions(uint8_t* message, collision_struct* collisions, size_t* collision_count) {
// temp storage
*collision_count = 0;
uint32_t ht_size = 1<<HASH_BITS;
SHA512_Context c512_avxsse;
SHA512_Init(&c512_avxsse);
uint8_t midhash[32+4];
memcpy(midhash+4, message, 32);
*((uint32_t*)midhash) = 0;
SHA512_Update_Simple(&c512_avxsse, midhash, 32+4);
SHA512_PreFinal(&c512_avxsse);
*(uint32_t *)(&c512_avxsse.buffer.bytes[0]) = 0;
uint64_t * swap_helper = (uint64_t*)(&c512_avxsse.buffer.bytes[0]);
for (int i = 1; i < 5; i++) {
swap_helper[i] = SWAP64(swap_helper[i]);
}
OpenCLContext *context = OpenCLMain::getInstance().getDevice(device_num)->getContext();
OpenCLProgram *program = context->getProgram(0);
OpenCLKernel *kernel = program->getKernel("kernel_sha512");
OpenCLKernel *kernel_cleanup = program->getKernel("kernel_clean_hash_table");
assert(kernel != NULL);
//size_t BLOCKSIZE = main.getPlatform(0)->getDevice(0)->getMaxWorkGroupSize();
size_t BLOCKSIZE = kernel->getWorkGroupSize(OpenCLMain::getInstance().getDevice(device_num));
//has to be a power of 2
BLOCKSIZE = 1<<log2(BLOCKSIZE);
size_t BLOCKSIZE_CLEAN = kernel_cleanup->getWorkGroupSize(OpenCLMain::getInstance().getDevice(device_num));
BLOCKSIZE_CLEAN = 1<<log2(BLOCKSIZE_CLEAN);
// printf("BLOCKSIZE = %ld\n", BLOCKSIZE);
// printf("BLOCKSIZE_CLEAN = %ld\n", BLOCKSIZE_CLEAN);
// cleans up the hash table
queue->enqueueKernel1D(kernel_cleanup, 1<<HASH_BITS, BLOCKSIZE_CLEAN);
queue->enqueueWriteBuffer(cl_message, c512_avxsse.buffer.bytes, sizeof(uint8_t)*SHA512_BLOCK_SIZE);
queue->enqueueWriteBuffer(temp_collisions_count, collision_count, sizeof(size_t));
queue->enqueueKernel1D(kernel, MAX_MOMENTUM_NONCE/8, BLOCKSIZE);
queue->enqueueReadBuffer(temp_collisions_count, collision_count, sizeof(size_t));
queue->enqueueReadBuffer(temp_collisions, collisions, sizeof(collision_struct)*getCollisionCeiling());
queue->finish();
}
void OpenCLMomentumV3::find_collisions(uint8_t* message, collision_struct* collisions, size_t* collision_count) {
// temp storage
*collision_count = 0;
OpenCLContext *context = OpenCLMain::getInstance().getDevice(device_num)->getContext();
OpenCLProgram *program = context->getProgram(0);
OpenCLKernel *kernel = program->getKernel("kernel_sha512");
OpenCLKernel *kernel_cleanup = program->getKernel("kernel_clean_hash_table");
assert(kernel != NULL);
//size_t BLOCKSIZE = main.getPlatform(0)->getDevice(0)->getMaxWorkGroupSize();
size_t BLOCKSIZE = kernel->getWorkGroupSize(OpenCLMain::getInstance().getDevice(device_num));
//has to be a power of 2
BLOCKSIZE = 1<<log2(BLOCKSIZE);
size_t BLOCKSIZE_CLEAN = kernel_cleanup->getWorkGroupSize(OpenCLMain::getInstance().getDevice(device_num));
BLOCKSIZE_CLEAN = 1<<log2(BLOCKSIZE_CLEAN);
// printf("BLOCKSIZE = %ld\n", BLOCKSIZE);
// printf("BLOCKSIZE_CLEAN = %ld\n", BLOCKSIZE_CLEAN);
// cleans up the hash table
queue->enqueueKernel1D(kernel_cleanup, 1<<HASH_BITS, BLOCKSIZE_CLEAN);
queue->enqueueWriteBuffer(cl_message, message, sizeof(uint8_t)*32);
queue->enqueueWriteBuffer(temp_collisions_count, collision_count, sizeof(size_t));
queue->enqueueKernel1D(kernel, MAX_MOMENTUM_NONCE/8, BLOCKSIZE);
queue->enqueueReadBuffer(temp_collisions_count, collision_count, sizeof(size_t));
queue->enqueueReadBuffer(temp_collisions, collisions, sizeof(collision_struct)*getCollisionCeiling());
queue->finish();
}
void OpenCLMomentumV8::find_collisions(uint8_t* message, collision_struct* out_buff, size_t* out_count) {
// temp storage
*out_count = 0;
uint32_t ht_size = 1<<HASH_BITS;
SHA512_Context c512_avxsse;
SHA512_Init(&c512_avxsse);
uint8_t midhash[32+4];
memcpy(midhash+4, message, 32);
*((uint32_t*)midhash) = 0;
SHA512_Update_Simple(&c512_avxsse, midhash, 32+4);
SHA512_PreFinal(&c512_avxsse);
*(uint32_t *)(&c512_avxsse.buffer.bytes[0]) = 0;
uint64_t * swap_helper = (uint64_t*)(&c512_avxsse.buffer.bytes[0]);
for (int i = 1; i < 5; i++) {
swap_helper[i] = SWAP64(swap_helper[i]);
}
OpenCLContext *context = OpenCLMain::getInstance().getDevice(device_num)->getContext();
OpenCLProgram *program = context->getProgram(0);
OpenCLKernel *kernel_calculate_all_hashes = program->getKernel("calculate_all_hashes");
OpenCLKernel *kernel_fill_table = program->getKernel("fill_table");
OpenCLKernel *kernel_find_collisions = program->getKernel("find_collisions");
OpenCLKernel *kernel_cleanup = program->getKernel("kernel_clean_hash_table");
OpenCLDevice * device = OpenCLMain::getInstance().getDevice(device_num);
// cleans up the hash table
size_t kc_wgsize = kernel_cleanup->getWorkGroupSize(device);
kc_wgsize = 1<<log2(kc_wgsize);
queue->enqueueKernel1D(kernel_cleanup, 1<<HASH_BITS, kc_wgsize);
// printf("Cleaning the HT\n");
// queue->finish();
queue->enqueueWriteBuffer(cl_message, c512_avxsse.buffer.bytes, sizeof(uint8_t)*SHA512_BLOCK_SIZE);
// step 1, calculate hashes
size_t kcah_wgsize = kernel_calculate_all_hashes->getWorkGroupSize(device);
kcah_wgsize = 1<<log2(kcah_wgsize);
queue->enqueueKernel1D(kernel_calculate_all_hashes, MAX_MOMENTUM_NONCE/8,
kcah_wgsize);
// uint64_t * apa = new uint64_t[MAX_MOMENTUM_NONCE];
// queue->enqueueReadBuffer(hashes, apa, sizeof(uint64_t)*MAX_MOMENTUM_NONCE);
// queue->finish();
//
// printf("testing hashes\n");
// uint64_t count = 0;
// for (int i = 0; i < MAX_MOMENTUM_NONCE; i++) {
// if (apa[i] == 0) {
// count++;
// printf("BAD HASH AT: %d %X\n", i, apa[i]);
// }
// }
// printf("counted %X bad hashes\n", count);
// printf("NOW REALLY TEST THEM hashes\n");
// count = 0;
// for (uint32_t i = 0; i < MAX_MOMENTUM_NONCE/8; i+=8) {
// sph_sha512_context c512_sph; //SPH
// sph_sha512_init(&c512_sph);
// sph_sha512(&c512_sph, &i, 4);
// sph_sha512(&c512_sph, message, 32);
// uint64_t out[8];
// sph_sha512_close(&c512_sph, out);
// for (int j =0; j < 8; j++) {
// if (apa[i+j] != out[j]) {
// count++;
// uint64_t xxx = apa[i+j];
// printf("BAD HASH AT: %d => %X != %X\n", i, apa[i+j], out[j]);
// }
// }
// }
// printf("counted %X bad hashes\n", count);
// step 2, populate hashtable
size_t kft_wgsize = kernel_fill_table->getWorkGroupSize(device);
kft_wgsize = 1<<log2(kft_wgsize);
queue->enqueueKernel1D(kernel_fill_table, MAX_MOMENTUM_NONCE,
kft_wgsize);
// printf("step 2, populate hashtable\n");
// queue->finish();
queue->enqueueWriteBuffer(collisions_count, out_count, sizeof(size_t));
// step 3, find collisions
size_t kfc_wgsize = kernel_find_collisions->getWorkGroupSize(device);
kfc_wgsize = 1<<log2(kfc_wgsize);
queue->enqueueKernel1D(kernel_find_collisions, MAX_MOMENTUM_NONCE,
kfc_wgsize);
// printf("step 3, find collisions\n");
// queue->finish();
queue->enqueueReadBuffer(collisions_count, out_count, sizeof(size_t));
queue->enqueueReadBuffer(collisions, out_buff, sizeof(collision_struct)*getCollisionCeiling());
// printf("step 4, copy output\n");
queue->finish();
#ifdef DEBUG
printf("Collision Count = %d\n", (*out_count));
#endif
}
