// // 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 "testBase.h" #include "allocation_functions.h" #include "allocation_fill.h" #include "allocation_execute.h" #include "harness/testHarness.h" #include "harness/parseParameters.h" #include typedef long long unsigned llu; int g_repetition_count = 1; int g_reduction_percentage = 100; int g_write_allocations = 1; int g_multiple_allocations = 0; int g_execute_kernel = 1; static size_t g_max_size; static RandomSeed g_seed( gRandomSeed ); cl_long g_max_individual_allocation_size; cl_long g_global_mem_size; cl_uint checksum; static void printUsage( const char *execName ); test_status init_cl( cl_device_id device ) { int error; error = clGetDeviceInfo( device, CL_DEVICE_MAX_MEM_ALLOC_SIZE, sizeof(g_max_individual_allocation_size), &g_max_individual_allocation_size, NULL ); if ( error ) { print_error( error, "clGetDeviceInfo failed for CL_DEVICE_MAX_MEM_ALLOC_SIZE"); return TEST_FAIL; } error = clGetDeviceInfo( device, CL_DEVICE_GLOBAL_MEM_SIZE, sizeof(g_global_mem_size), &g_global_mem_size, NULL ); if ( error ) { print_error( error, "clGetDeviceInfo failed for CL_DEVICE_GLOBAL_MEM_SIZE"); return TEST_FAIL; } log_info("Device reports CL_DEVICE_MAX_MEM_ALLOC_SIZE=%llu bytes (%gMB), CL_DEVICE_GLOBAL_MEM_SIZE=%llu bytes (%gMB).\n", llu( g_max_individual_allocation_size ), toMB( g_max_individual_allocation_size ), llu( g_global_mem_size ), toMB( g_global_mem_size ) ); if( g_global_mem_size > (cl_ulong)SIZE_MAX ) { g_global_mem_size = (cl_ulong)SIZE_MAX; } if( g_max_individual_allocation_size > g_global_mem_size ) { log_error( "FAILURE: CL_DEVICE_MAX_MEM_ALLOC_SIZE (%llu) is greater than the CL_DEVICE_GLOBAL_MEM_SIZE (%llu)\n", llu( g_max_individual_allocation_size ), llu( g_global_mem_size ) ); return TEST_FAIL; } // We may need to back off the global_mem_size on unified memory devices to leave room for application and operating system code // and associated data in the working set, so we dont start pathologically paging. // Check to see if we are a unified memory device cl_bool hasUnifiedMemory = CL_FALSE; if( ( error = clGetDeviceInfo( device, CL_DEVICE_HOST_UNIFIED_MEMORY, sizeof( hasUnifiedMemory ), &hasUnifiedMemory, NULL ) ) ) { print_error( error, "clGetDeviceInfo failed for CL_DEVICE_HOST_UNIFIED_MEMORY"); return TEST_FAIL; } // we share unified memory so back off to 1/2 the global memory size. if( CL_TRUE == hasUnifiedMemory ) { g_global_mem_size -= g_global_mem_size /2; log_info( "Device shares memory with the host, so backing off the maximum combined allocation size to be %gMB to avoid rampant paging.\n", toMB( g_global_mem_size ) ); } else { // Lets just use 60% of total available memory as framework/driver may not allow using all of it // e.g. vram on GPU is used by window server and even for this test, we need some space for context, // queue, kernel code on GPU. g_global_mem_size *= 0.60; } if( gReSeed ) { g_seed = RandomSeed( gRandomSeed ); } return TEST_PASS; } int doTest( cl_device_id device, cl_context context, cl_command_queue queue, AllocType alloc_type ) { int error; int failure_counts = 0; size_t final_size; size_t current_test_size; cl_mem mems[MAX_NUMBER_TO_ALLOCATE]; int number_of_mems_used; cl_ulong max_individual_allocation_size = g_max_individual_allocation_size; cl_ulong global_mem_size = g_global_mem_size ; static const char* alloc_description[] = { "buffer(s)", "read-only image(s)", "write-only image(s)", "buffer(s)", "read-only image(s)", "write-only image(s)", }; // Skip image tests if we don't support images on the device if( alloc_type > BUFFER && checkForImageSupport( device ) ) { log_info( "Can not test image allocation because device does not support images.\n" ); return 0; } // This section was added in order to fix a bug in the test // If CL_DEVICE_MAX_MEM_ALLOC_SIZE is much grater than CL_DEVICE_IMAGE2D_MAX_WIDTH * CL_DEVICE_IMAGE2D_MAX_HEIGHT // The test will fail in image allocations as the size requested for the allocation will be much grater than the maximum size allowed for image if( ( alloc_type != BUFFER ) && ( alloc_type != BUFFER_NON_BLOCKING ) ) { size_t max_width, max_height; error = clGetDeviceInfo( device, CL_DEVICE_IMAGE2D_MAX_WIDTH, sizeof( max_width ), &max_width, NULL ); test_error_abort( error, "clGetDeviceInfo failed for CL_DEVICE_IMAGE2D_MAX_WIDTH" ); error = clGetDeviceInfo( device, CL_DEVICE_IMAGE2D_MAX_HEIGHT, sizeof( max_height ), &max_height, NULL ); test_error_abort( error, "clGetDeviceInfo failed for CL_DEVICE_IMAGE2D_MAX_HEIGHT" ); cl_ulong max_image2d_size = (cl_ulong)max_height * max_width * 4 * sizeof(cl_uint); if( max_individual_allocation_size > max_image2d_size ) { max_individual_allocation_size = max_image2d_size; } } // Pick the baseline size based on whether we are doing a single large or multiple allocations g_max_size = g_multiple_allocations ? (size_t)global_mem_size : (size_t)max_individual_allocation_size; // Adjust based on the percentage if( g_reduction_percentage != 100 ) { log_info( "NOTE: reducing max allocations to %d%%.\n", g_reduction_percentage ); g_max_size = (size_t)( (double)g_max_size * (double)g_reduction_percentage / 100.0 ); } // Round to nearest MB. g_max_size &= (size_t)(0xFFFFFFFFFF00000ULL); log_info( "** Target allocation size (rounded to nearest MB) is: %llu bytes (%gMB).\n", llu( g_max_size ), toMB( g_max_size ) ); log_info( "** Allocating %s to size %gMB.\n", alloc_description[alloc_type], toMB( g_max_size ) ); for( int count = 0; count < g_repetition_count; count++ ) { current_test_size = g_max_size; error = FAILED_TOO_BIG; log_info( " => Allocation %d\n", count + 1 ); while( ( error == FAILED_TOO_BIG ) && ( current_test_size > g_max_size / 8 ) ) { // Reset our checksum for each allocation checksum = 0; // Do the allocation error = allocate_size( context, &queue, device, g_multiple_allocations, current_test_size, alloc_type, mems, &number_of_mems_used, &final_size, g_write_allocations, g_seed ); // If we succeeded and we're supposed to execute a kernel, do so. if( error == SUCCEEDED && g_execute_kernel ) { log_info( "\tExecuting kernel with memory objects.\n" ); error = execute_kernel( context, &queue, device, alloc_type, mems, number_of_mems_used, g_write_allocations ); } // If we failed to allocate more than 1/8th of the requested amount return a failure. if( final_size < (size_t)g_max_size / 8 ) { log_error( "===> Allocation %d failed to allocate more than 1/8th of the requested size.\n", count + 1 ); failure_counts++; } // Clean up. for( int i = 0; i < number_of_mems_used; i++ ) { clReleaseMemObject( mems[i] ); } if( error == FAILED_ABORT ) { log_error( " => Allocation %d failed.\n", count + 1 ); failure_counts++; } if( error == FAILED_TOO_BIG ) { current_test_size -= g_max_size / 16; log_info( "\tFailed at this size; trying a smaller size of %gMB.\n", toMB( current_test_size ) ); } } if( error == SUCCEEDED && current_test_size == g_max_size ) { log_info("\tPASS: Allocation succeeded.\n"); } else if( error == SUCCEEDED && current_test_size > g_max_size / 8 ) { log_info("\tPASS: Allocation succeeded at reduced size.\n"); } else { log_error("\tFAIL: Allocation failed.\n"); failure_counts++; } } return failure_counts; } int test_buffer(cl_device_id device, cl_context context, cl_command_queue queue, int num_elements) { return doTest( device, context, queue, BUFFER ); } int test_image2d_read(cl_device_id device, cl_context context, cl_command_queue queue, int num_elements) { return doTest( device, context, queue, IMAGE_READ ); } int test_image2d_write(cl_device_id device, cl_context context, cl_command_queue queue, int num_elements) { return doTest( device, context, queue, IMAGE_WRITE ); } int test_buffer_non_blocking(cl_device_id device, cl_context context, cl_command_queue queue, int num_elements) { return doTest( device, context, queue, BUFFER_NON_BLOCKING ); } int test_image2d_read_non_blocking(cl_device_id device, cl_context context, cl_command_queue queue, int num_elements) { return doTest( device, context, queue, IMAGE_READ_NON_BLOCKING ); } int test_image2d_write_non_blocking(cl_device_id device, cl_context context, cl_command_queue queue, int num_elements) { return doTest( device, context, queue, IMAGE_WRITE_NON_BLOCKING ); } test_definition test_list[] = { ADD_TEST( buffer ), ADD_TEST( image2d_read ), ADD_TEST( image2d_write ), ADD_TEST( buffer_non_blocking ), ADD_TEST( image2d_read_non_blocking ), ADD_TEST( image2d_write_non_blocking ), }; const int test_num = ARRAY_SIZE( test_list ); int main(int argc, const char *argv[]) { char *endPtr; int r; argc = parseCustomParam(argc, argv); if (argc == -1) { return 1; } const char ** argList = (const char **)calloc( argc, sizeof( char*) ); if( NULL == argList ) { log_error( "Failed to allocate memory for argList array.\n" ); return 1; } argList[0] = argv[0]; size_t argCount = 1; // Parse arguments for( int i = 1; i < argc; i++ ) { if( strcmp( argv[i], "multiple" ) == 0 ) g_multiple_allocations = 1; else if( strcmp( argv[i], "single" ) == 0 ) g_multiple_allocations = 0; else if( ( r = (int)strtol( argv[i], &endPtr, 10 ) ) && ( endPtr != argv[i] ) && ( *endPtr == 0 ) ) { // By spec, that means the entire string was an integer, so take it as a repetition count g_repetition_count = r; } else if( strchr( argv[i], '%' ) != NULL ) { // Reduction percentage (let strtol ignore the percentage) g_reduction_percentage = (int)strtol( argv[i], NULL, 10 ); } else if( strcmp( argv[i], "do_not_force_fill" ) == 0 ) { g_write_allocations = 0; } else if( strcmp( argv[i], "do_not_execute" ) == 0 ) { g_execute_kernel = 0; } else if ( strcmp( argv[i], "--help" ) == 0 || strcmp( argv[i], "-h" ) == 0 ) { printUsage( argv[0] ); return -1; } else { argList[argCount] = argv[i]; argCount++; } } int ret = runTestHarnessWithCheck( argCount, argList, test_num, test_list, false, 0, init_cl ); free(argList); return ret; } void printUsage( const char *execName ) { const char *p = strrchr( execName, '/' ); if( p != NULL ) execName = p + 1; log_info( "Usage: %s [options] [test_names]\n", execName ); log_info( "Options:\n" ); log_info( "\trandomize - Uses random seed\n" ); log_info( "\tsingle - Tests using a single allocation as large as possible\n" ); log_info( "\tmultiple - Tests using as many allocations as possible\n" ); log_info( "\n" ); log_info( "\tnumReps - Optional integer specifying the number of repetitions to run and average the result (defaults to 1)\n" ); log_info( "\treduction%% - Optional integer, followed by a %% sign, that acts as a multiplier for the target amount of memory.\n" ); log_info( "\t Example: target amount of 512MB and a reduction of 75%% will result in a target of 384MB.\n" ); log_info( "\n" ); log_info( "\tdo_not_force_fill - Disable explicitly write data to all memory objects after creating them.\n" ); log_info( "\t Without this, the kernel execution can not verify its checksum.\n" ); log_info( "\tdo_not_execute - Disable executing a kernel that accesses all of the memory objects.\n" ); log_info( "\n" ); log_info( "Test names (Allocation Types):\n" ); for( int i = 0; i < test_num; i++ ) { log_info( "\t%s\n", test_list[i].name ); } }