/* Copyright (c) 2018-2022 Advanced Micro Devices, Inc. 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. */ #include #include #include #ifdef __cplusplus #include using namespace std; #else #include #endif // roctx header file #include // roctracer extension API #include #ifdef __cplusplus static thread_local const size_t msg_size = 512; static thread_local char* msg_buf = NULL; static thread_local char* message = NULL; #else static const size_t msg_size = 512; static char* msg_buf = NULL; static char* message = NULL; #endif void SPRINT(const char* fmt, ...) { if (msg_buf == NULL) { msg_buf = (char*)calloc(msg_size, 1); message = msg_buf; } va_list args; va_start(args, fmt); message += vsnprintf(message, msg_size - (message - msg_buf), fmt, args); va_end(args); } void SFLUSH() { if (msg_buf == NULL) abort(); message = msg_buf; msg_buf[msg_size - 1] = 0; fprintf(stdout, "%s", msg_buf); fflush(stdout); } #if HIP_TEST // hip header file #include // Macro to call HIP API #define HIP_CALL(call) \ do { \ call; \ } while (0) #else #define HIP_CALL(call) \ do { \ } while (0) #endif #ifndef ITERATIONS #define ITERATIONS 101 #endif #define WIDTH 1024 #define NUM (WIDTH * WIDTH) #define THREADS_PER_BLOCK_X 4 #define THREADS_PER_BLOCK_Y 4 #define THREADS_PER_BLOCK_Z 1 #if HIP_TEST // Device (Kernel) function, it must be void __global__ void matrixTranspose(float* out, float* in, const int width) { int x = hipBlockDim_x * hipBlockIdx_x + hipThreadIdx_x; int y = hipBlockDim_y * hipBlockIdx_y + hipThreadIdx_y; out[y * width + x] = in[x * width + y]; } #endif // CPU implementation of matrix transpose void matrixTransposeCPUReference(float* output, float* input, const unsigned int width) { for (unsigned int j = 0; j < width; j++) { for (unsigned int i = 0; i < width; i++) { output[i * width + j] = input[j * width + i]; } } } int iterations = ITERATIONS; void init_tracing(); void start_tracing(); void stop_tracing(); int main() { float* Matrix; float* TransposeMatrix; float* cpuTransposeMatrix; float* gpuMatrix; float* gpuTransposeMatrix; int i; int errors; init_tracing(); #if HIP_TEST int gpuCount = 1; #if MGPU_TEST hipGetDeviceCount(&gpuCount); printf("Number of GPUs: %d\n", gpuCount); #endif iterations *= gpuCount; #endif while (iterations-- > 0) { start_tracing(); #if HIP_TEST // set GPU const int devIndex = iterations % gpuCount; hipSetDevice(devIndex); hipDeviceProp_t devProp; HIP_CALL(hipGetDeviceProperties(&devProp, 0)); printf("Device %d name: %s\n", devIndex, devProp.name); #endif Matrix = (float*)malloc(NUM * sizeof(float)); TransposeMatrix = (float*)malloc(NUM * sizeof(float)); cpuTransposeMatrix = (float*)malloc(NUM * sizeof(float)); // initialize the input data for (i = 0; i < NUM; i++) { Matrix[i] = (float)i * 10.0f; } // allocate the memory on the device side HIP_CALL(hipMalloc((void**)&gpuMatrix, NUM * sizeof(float))); HIP_CALL(hipMalloc((void**)&gpuTransposeMatrix, NUM * sizeof(float))); // correlation reagion32 roctracer_activity_push_external_correlation_id(31); // correlation reagion32 roctracer_activity_push_external_correlation_id(32); // Memory transfer from host to device HIP_CALL(hipMemcpy(gpuMatrix, Matrix, NUM * sizeof(float), hipMemcpyHostToDevice)); // correlation reagion33 roctracer_activity_push_external_correlation_id(33); roctxMark("before hipLaunchKernel"); roctxRangePush("hipLaunchKernel"); // Lauching kernel from host HIP_CALL(hipLaunchKernelGGL(matrixTranspose, dim3(WIDTH / THREADS_PER_BLOCK_X, WIDTH / THREADS_PER_BLOCK_Y), dim3(THREADS_PER_BLOCK_X, THREADS_PER_BLOCK_Y), 0, 0, gpuTransposeMatrix, gpuMatrix, WIDTH)); roctxMark("after hipLaunchKernel"); // correlation reagion end roctracer_activity_pop_external_correlation_id(NULL); // Memory transfer from device to host roctxRangePush("hipMemcpy"); HIP_CALL( hipMemcpy(TransposeMatrix, gpuTransposeMatrix, NUM * sizeof(float), hipMemcpyDeviceToHost)); roctxRangePop(); // for "hipMemcpy" roctxRangePop(); // for "hipLaunchKernel" // correlation reagion end roctracer_activity_pop_external_correlation_id(NULL); // CPU MatrixTranspose computation HIP_CALL(matrixTransposeCPUReference(cpuTransposeMatrix, Matrix, WIDTH)); // verify the results errors = 0; double eps = 1.0E-6; for (i = 0; i < NUM; i++) { if (abs(TransposeMatrix[i] - cpuTransposeMatrix[i]) > eps) { errors++; } } if ((HIP_TEST != 0) && (errors != 0)) { printf("FAILED: %d errors\n", errors); } else { errors = 0; printf("PASSED!\n"); } // free the resources on device side HIP_CALL(hipFree(gpuMatrix)); HIP_CALL(hipFree(gpuTransposeMatrix)); // correlation reagion end roctracer_activity_pop_external_correlation_id(NULL); // correlation reagion end roctracer_activity_pop_external_correlation_id(NULL); // free the resources on host side free(Matrix); free(TransposeMatrix); free(cpuTransposeMatrix); } stop_tracing(); return errors; } //////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// // HIP Callbacks/Activity tracing // #if 1 #include #include #include #include #include #include /* For SYS_xxx definitions */ // Macro to check ROC-tracer calls status #define ROCTRACER_CALL(call) \ do { \ int err = call; \ if (err != 0) { \ fprintf(stderr, "%s\n", roctracer_error_string()); \ abort(); \ } \ } while (0) static inline uint32_t GetTid() { return syscall(__NR_gettid); } static inline uint32_t GetPid() { return syscall(__NR_getpid); } // Runtime API callback function void api_callback(uint32_t domain, uint32_t cid, const void* callback_data, void* arg) { (void)arg; if (domain == ACTIVITY_DOMAIN_ROCTX) { const roctx_api_data_t* data = (const roctx_api_data_t*)(callback_data); fprintf(stdout, "rocTX <\"%s pid(%d) tid(%d)\">\n", data->args.message, GetPid(), GetTid()); return; } const hip_api_data_t* data = (const hip_api_data_t*)(callback_data); SPRINT("<%s id(%u)\tcorrelation_id(%lu) %s pid(%d) tid(%d)> ", roctracer_op_string(ACTIVITY_DOMAIN_HIP_API, cid, 0), cid, data->correlation_id, (data->phase == ACTIVITY_API_PHASE_ENTER) ? "on-enter" : "on-exit", GetPid(), GetTid()); if (data->phase == ACTIVITY_API_PHASE_ENTER) { switch (cid) { case HIP_API_ID_hipMemcpy: SPRINT("dst(%p) src(%p) size(0x%x) kind(%u)", data->args.hipMemcpy.dst, data->args.hipMemcpy.src, (uint32_t)(data->args.hipMemcpy.sizeBytes), (uint32_t)(data->args.hipMemcpy.kind)); break; case HIP_API_ID_hipMalloc: SPRINT("ptr(%p) size(0x%x)", data->args.hipMalloc.ptr, (uint32_t)(data->args.hipMalloc.size)); break; case HIP_API_ID_hipFree: SPRINT("ptr(%p)", data->args.hipFree.ptr); break; case HIP_API_ID_hipModuleLaunchKernel: SPRINT("kernel(\"%s\") stream(%p)", hipKernelNameRef(data->args.hipModuleLaunchKernel.f), data->args.hipModuleLaunchKernel.stream); break; default: break; } } else { switch (cid) { case HIP_API_ID_hipMalloc: SPRINT("*ptr(0x%p)", *(data->args.hipMalloc.ptr)); break; default: break; } } SPRINT("\n"); SFLUSH(); } // Activity tracing callback // hipMalloc id(3) correlation_id(1): begin_ns(1525888652762640464) end_ns(1525888652762877067) void activity_callback(const char* begin, const char* end, void* arg) { const roctracer_record_t* record = (const roctracer_record_t*)(begin); const roctracer_record_t* end_record = (const roctracer_record_t*)(end); SPRINT("\tActivity records:\n"); while (record < end_record) { const char* name = roctracer_op_string(record->domain, record->op, record->kind); SPRINT("\t%s\tcorrelation_id(%lu) time_ns(%lu:%lu)", name, record->correlation_id, record->begin_ns, record->end_ns); if (record->domain == ACTIVITY_DOMAIN_HIP_API) { SPRINT(" process_id(%u) thread_id(%u)", record->process_id, record->thread_id); } else if (record->domain == ACTIVITY_DOMAIN_HCC_OPS) { SPRINT(" device_id(%d) queue_id(%lu)", record->device_id, record->queue_id); if (record->op == HIP_OP_ID_COPY) SPRINT(" bytes(0x%zx)", record->bytes); } else if (record->domain == ACTIVITY_DOMAIN_HSA_OPS) { SPRINT(" se(%u) cycle(%lu) pc(%lx)", record->pc_sample.se, record->pc_sample.cycle, record->pc_sample.pc); } else if (record->domain == ACTIVITY_DOMAIN_EXT_API) { SPRINT(" external_id(%lu)", record->external_id); } else { fprintf(stderr, "Bad domain %d\n\n", record->domain); abort(); } SPRINT("\n"); SFLUSH(); ROCTRACER_CALL(roctracer_next_record(record, &record)); } } // Init tracing routine void init_tracing() { printf("# INIT #############################\n"); // roctracer properties roctracer_set_properties(ACTIVITY_DOMAIN_HIP_API, NULL); // Allocating tracing pool roctracer_properties_t properties; memset(&properties, 0, sizeof(roctracer_properties_t)); properties.buffer_size = 0x1000; properties.buffer_callback_fun = activity_callback; ROCTRACER_CALL(roctracer_open_pool(&properties)); // Enable HIP API callbacks ROCTRACER_CALL(roctracer_enable_domain_callback(ACTIVITY_DOMAIN_HIP_API, api_callback, NULL)); // Enable HIP activity tracing #if HIP_API_ACTIVITY_ON ROCTRACER_CALL(roctracer_enable_domain_activity(ACTIVITY_DOMAIN_HIP_API)); #endif ROCTRACER_CALL(roctracer_enable_domain_activity(ACTIVITY_DOMAIN_HCC_OPS)); // Enable PC sampling ROCTRACER_CALL(roctracer_enable_op_activity(ACTIVITY_DOMAIN_HSA_OPS, HSA_OP_ID_RESERVED1)); // Enable rocTX ROCTRACER_CALL(roctracer_enable_domain_callback(ACTIVITY_DOMAIN_ROCTX, api_callback, NULL)); } // Start tracing routine void start_tracing() { printf("# START (%d) #############################\n", iterations); // Start if ((iterations & 1) == 1) roctracer_start(); else roctracer_stop(); } // Stop tracing routine void stop_tracing() { ROCTRACER_CALL(roctracer_disable_domain_callback(ACTIVITY_DOMAIN_HIP_API)); #if HIP_API_ACTIVITY_ON ROCTRACER_CALL(roctracer_disable_domain_activity(ACTIVITY_DOMAIN_HIP_API)); #endif ROCTRACER_CALL(roctracer_disable_domain_activity(ACTIVITY_DOMAIN_HCC_OPS)); ROCTRACER_CALL(roctracer_disable_domain_activity(ACTIVITY_DOMAIN_HSA_OPS)); ROCTRACER_CALL(roctracer_disable_domain_callback(ACTIVITY_DOMAIN_ROCTX)); ROCTRACER_CALL(roctracer_flush_activity()); printf("# STOP #############################\n"); } #else void init_tracing() {} void start_tracing() {} void stop_tracing() {} #endif ////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////