// // Copyright (c) 2017 The Khronos Group Inc. // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. // #include "common.h" #include "harness/mt19937.h" #include #include #if !defined(_WIN32) #include #endif typedef struct { std::atomic status; cl_uint num_svm_pointers; std::vector svm_pointers; } CallbackData; void generate_data(std::vector &data, size_t size, MTdata seed) { cl_uint randomData = genrand_int32(seed); cl_uint bitsLeft = 32; for( size_t i = 0; i < size; i++ ) { if( 0 == bitsLeft) { randomData = genrand_int32(seed); bitsLeft = 32; } data[i] = (cl_uchar)( randomData & 255 ); randomData >>= 8; randomData -= 8; } } //callback which will be passed to clEnqueueSVMFree command void CL_CALLBACK callback_svm_free(cl_command_queue queue, cl_uint num_svm_pointers, void * svm_pointers[], void * user_data) { CallbackData *data = (CallbackData *)user_data; data->num_svm_pointers = num_svm_pointers; data->svm_pointers.resize(num_svm_pointers, 0); cl_context context; if(clGetCommandQueueInfo(queue, CL_QUEUE_CONTEXT, sizeof(cl_context), &context, 0) != CL_SUCCESS) { log_error("clGetCommandQueueInfo failed in the callback\n"); return; } for (size_t i = 0; i < num_svm_pointers; ++i) { data->svm_pointers[i] = svm_pointers[i]; clSVMFree(context, svm_pointers[i]); } data->status.store(1, std::memory_order_release); } int test_svm_enqueue_api(cl_device_id deviceID, cl_context c, cl_command_queue queue, int num_elements) { clContextWrapper context = NULL; clCommandQueueWrapper queues[MAXQ]; cl_uint num_devices = 0; const size_t elementNum = 1024; const size_t numSVMBuffers = 32; cl_int error = CL_SUCCESS; RandomSeed seed(0); error = create_cl_objects(deviceID, NULL, &context, NULL, &queues[0], &num_devices, CL_DEVICE_SVM_COARSE_GRAIN_BUFFER); if(error) return TEST_FAIL; queue = queues[0]; //all possible sizes of vectors and scalars size_t typeSizes[] = { sizeof(cl_uchar), sizeof(cl_uchar2), sizeof(cl_uchar3), sizeof(cl_uchar4), sizeof(cl_uchar8), sizeof(cl_uchar16), sizeof(cl_ushort), sizeof(cl_ushort2), sizeof(cl_ushort3), sizeof(cl_ushort4), sizeof(cl_ushort8), sizeof(cl_ushort16), sizeof(cl_uint), sizeof(cl_uint2), sizeof(cl_uint3), sizeof(cl_uint4), sizeof(cl_uint8), sizeof(cl_uint16), sizeof(cl_ulong), sizeof(cl_ulong2), sizeof(cl_ulong3), sizeof(cl_ulong4), sizeof(cl_ulong8), sizeof(cl_ulong16), }; enum allocationTypes { host, svm }; struct TestType { allocationTypes srcAlloc; allocationTypes dstAlloc; TestType(allocationTypes type1, allocationTypes type2): srcAlloc(type1), dstAlloc(type2){} }; std::vector testTypes; testTypes.push_back(TestType(host, host)); testTypes.push_back(TestType(host, svm)); testTypes.push_back(TestType(svm, host)); testTypes.push_back(TestType(svm, svm)); for (const auto test_case : testTypes) { log_info("clEnqueueSVMMemcpy case: src_alloc = %s, dst_alloc = %s\n", test_case.srcAlloc == svm ? "svm" : "host", test_case.dstAlloc == svm ? "svm" : "host"); for (size_t i = 0; i < ARRAY_SIZE(typeSizes); ++i) { //generate initial data std::vector fillData0(typeSizes[i]), fillData1(typeSizes[i]); generate_data(fillData0, typeSizes[i], seed); generate_data(fillData1, typeSizes[i], seed); size_t data_size = elementNum * typeSizes[i]; std::vector srcHostData(data_size, 0); std::vector dstHostData(data_size, 0); generate_data(srcHostData, srcHostData.size(), seed); generate_data(dstHostData, dstHostData.size(), seed); cl_uchar *srcBuffer = (cl_uchar *)clSVMAlloc(context, CL_MEM_READ_WRITE, data_size, 0); cl_uchar *dstBuffer = (cl_uchar *)clSVMAlloc(context, CL_MEM_READ_WRITE, data_size, 0); clEventWrapper userEvent = clCreateUserEvent(context, &error); test_error(error, "clCreateUserEvent failed"); clEventWrapper eventMemFillList[2]; error = clEnqueueSVMMemFill(queue, srcBuffer, &fillData0[0], typeSizes[i], data_size, 1, &userEvent, &eventMemFillList[0]); test_error(error, "clEnqueueSVMMemFill failed"); error = clEnqueueSVMMemFill(queue, dstBuffer, &fillData1[0], typeSizes[i], data_size, 1, &userEvent, &eventMemFillList[1]); test_error(error, "clEnqueueSVMMemFill failed"); error = clSetUserEventStatus(userEvent, CL_COMPLETE); test_error(error, "clSetUserEventStatus failed"); cl_uchar * src_ptr; cl_uchar * dst_ptr; if (test_case.srcAlloc == host) { src_ptr = srcHostData.data(); } else if (test_case.srcAlloc == svm) { src_ptr = srcBuffer; } if (test_case.dstAlloc == host) { dst_ptr = dstHostData.data(); } else if (test_case.dstAlloc == svm) { dst_ptr = dstBuffer; } clEventWrapper eventMemcpy; error = clEnqueueSVMMemcpy(queue, CL_FALSE, dst_ptr, src_ptr, data_size, 2, &eventMemFillList[0], &eventMemcpy); test_error(error, "clEnqueueSVMMemcpy failed"); //coarse grain only supported. Synchronization required using map clEventWrapper eventMap[2]; error = clEnqueueSVMMap(queue, CL_FALSE, CL_MAP_READ, srcBuffer, data_size, 1, &eventMemcpy, &eventMap[0]); test_error(error, "clEnqueueSVMMap srcBuffer failed"); error = clEnqueueSVMMap(queue, CL_FALSE, CL_MAP_READ, dstBuffer, data_size, 1, &eventMemcpy, &eventMap[1]); test_error(error, "clEnqueueSVMMap dstBuffer failed"); error = clWaitForEvents(2, &eventMap[0]); test_error(error, "clWaitForEvents failed"); //data verification for (size_t j = 0; j < data_size; ++j) { if (dst_ptr[j] != src_ptr[j]) { log_error("Invalid data at index %ld, dst_ptr %d, src_ptr %d\n", j, dst_ptr[j], src_ptr[j]); return TEST_FAIL; } } clEventWrapper eventUnmap[2]; error = clEnqueueSVMUnmap(queue, srcBuffer, 0, nullptr, &eventUnmap[0]); test_error(error, "clEnqueueSVMUnmap srcBuffer failed"); error = clEnqueueSVMUnmap(queue, dstBuffer, 0, nullptr, &eventUnmap[1]); test_error(error, "clEnqueueSVMUnmap dstBuffer failed"); error = clEnqueueSVMMemFill(queue, srcBuffer, &fillData1[0], typeSizes[i], data_size / 2, 0, 0, 0); test_error(error, "clEnqueueSVMMemFill failed"); error = clEnqueueSVMMemFill(queue, dstBuffer + data_size / 2, &fillData1[0], typeSizes[i], data_size / 2, 0, 0, 0); test_error(error, "clEnqueueSVMMemFill failed"); error = clEnqueueSVMMemcpy(queue, CL_FALSE, dstBuffer, srcBuffer, data_size / 2, 0, 0, 0); test_error(error, "clEnqueueSVMMemcpy failed"); error = clEnqueueSVMMemcpy(queue, CL_TRUE, dstBuffer + data_size / 2, srcBuffer + data_size / 2, data_size / 2, 0, 0, 0); test_error(error, "clEnqueueSVMMemcpy failed"); void *ptrs[] = { (void *)srcBuffer, (void *)dstBuffer }; clEventWrapper eventFree; error = clEnqueueSVMFree(queue, 2, ptrs, 0, 0, 0, 0, &eventFree); test_error(error, "clEnqueueSVMFree failed"); error = clWaitForEvents(1, &eventFree); test_error(error, "clWaitForEvents failed"); //event info verification for new SVM commands cl_command_type commandType; for (auto &check_event : eventMemFillList) { error = clGetEventInfo(check_event, CL_EVENT_COMMAND_TYPE, sizeof(cl_command_type), &commandType, NULL); test_error(error, "clGetEventInfo failed"); if (commandType != CL_COMMAND_SVM_MEMFILL) { log_error("Invalid command type returned for clEnqueueSVMMemFill\n"); return TEST_FAIL; } } error = clGetEventInfo(eventMemcpy, CL_EVENT_COMMAND_TYPE, sizeof(cl_command_type), &commandType, NULL); test_error(error, "clGetEventInfo failed"); if (commandType != CL_COMMAND_SVM_MEMCPY) { log_error("Invalid command type returned for clEnqueueSVMMemcpy\n"); return TEST_FAIL; } for (size_t map_id = 0; map_id < ARRAY_SIZE(eventMap); map_id++) { error = clGetEventInfo(eventMap[map_id], CL_EVENT_COMMAND_TYPE, sizeof(cl_command_type), &commandType, NULL); test_error(error, "clGetEventInfo failed"); if (commandType != CL_COMMAND_SVM_MAP) { log_error("Invalid command type returned for clEnqueueSVMMap\n"); return TEST_FAIL; } error = clGetEventInfo(eventUnmap[map_id], CL_EVENT_COMMAND_TYPE, sizeof(cl_command_type), &commandType, NULL); test_error(error, "clGetEventInfo failed"); if (commandType != CL_COMMAND_SVM_UNMAP) { log_error("Invalid command type returned for clEnqueueSVMUnmap\n"); return TEST_FAIL; } } error = clGetEventInfo(eventFree, CL_EVENT_COMMAND_TYPE, sizeof(cl_command_type), &commandType, NULL); test_error(error, "clGetEventInfo failed"); if (commandType != CL_COMMAND_SVM_FREE) { log_error("Invalid command type returned for clEnqueueSVMFree\n"); return TEST_FAIL; } } } std::vector buffers(numSVMBuffers, 0); for(size_t i = 0; i < numSVMBuffers; ++i) buffers[i] = clSVMAlloc(context, CL_MEM_READ_WRITE, elementNum, 0); //verify if callback is triggered correctly CallbackData data; data.status = 0; error = clEnqueueSVMFree(queue, buffers.size(), &buffers[0], callback_svm_free, &data, 0, 0, 0); test_error(error, "clEnqueueSVMFree failed"); error = clFinish(queue); test_error(error, "clFinish failed"); //wait for the callback while(data.status.load(std::memory_order_acquire) == 0) { usleep(1); } //check if number of SVM pointers returned in the callback matches with expected if (data.num_svm_pointers != buffers.size()) { log_error("Invalid number of SVM pointers returned in the callback, expected: %ld, got: %d\n", buffers.size(), data.num_svm_pointers); return TEST_FAIL; } //check if pointers returned in callback are correct for (size_t i = 0; i < buffers.size(); ++i) { if (data.svm_pointers[i] != buffers[i]) { log_error("Invalid SVM pointer returned in the callback, idx: %ld\n", i); return TEST_FAIL; } } return 0; }