// // 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 "compat.h" #include #include #include #include "errorHelpers.h" #include "parseParameters.h" const char *IGetErrorString( int clErrorCode ) { switch( clErrorCode ) { case CL_SUCCESS: return "CL_SUCCESS"; case CL_DEVICE_NOT_FOUND: return "CL_DEVICE_NOT_FOUND"; case CL_DEVICE_NOT_AVAILABLE: return "CL_DEVICE_NOT_AVAILABLE"; case CL_COMPILER_NOT_AVAILABLE: return "CL_COMPILER_NOT_AVAILABLE"; case CL_MEM_OBJECT_ALLOCATION_FAILURE: return "CL_MEM_OBJECT_ALLOCATION_FAILURE"; case CL_OUT_OF_RESOURCES: return "CL_OUT_OF_RESOURCES"; case CL_OUT_OF_HOST_MEMORY: return "CL_OUT_OF_HOST_MEMORY"; case CL_PROFILING_INFO_NOT_AVAILABLE: return "CL_PROFILING_INFO_NOT_AVAILABLE"; case CL_MEM_COPY_OVERLAP: return "CL_MEM_COPY_OVERLAP"; case CL_IMAGE_FORMAT_MISMATCH: return "CL_IMAGE_FORMAT_MISMATCH"; case CL_IMAGE_FORMAT_NOT_SUPPORTED: return "CL_IMAGE_FORMAT_NOT_SUPPORTED"; case CL_BUILD_PROGRAM_FAILURE: return "CL_BUILD_PROGRAM_FAILURE"; case CL_MAP_FAILURE: return "CL_MAP_FAILURE"; case CL_MISALIGNED_SUB_BUFFER_OFFSET: return "CL_MISALIGNED_SUB_BUFFER_OFFSET"; case CL_EXEC_STATUS_ERROR_FOR_EVENTS_IN_WAIT_LIST: return "CL_EXEC_STATUS_ERROR_FOR_EVENTS_IN_WAIT_LIST"; case CL_COMPILE_PROGRAM_FAILURE: return "CL_COMPILE_PROGRAM_FAILURE"; case CL_LINKER_NOT_AVAILABLE: return "CL_LINKER_NOT_AVAILABLE"; case CL_LINK_PROGRAM_FAILURE: return "CL_LINK_PROGRAM_FAILURE"; case CL_DEVICE_PARTITION_FAILED: return "CL_DEVICE_PARTITION_FAILED"; case CL_KERNEL_ARG_INFO_NOT_AVAILABLE: return "CL_KERNEL_ARG_INFO_NOT_AVAILABLE"; case CL_INVALID_VALUE: return "CL_INVALID_VALUE"; case CL_INVALID_DEVICE_TYPE: return "CL_INVALID_DEVICE_TYPE"; case CL_INVALID_DEVICE: return "CL_INVALID_DEVICE"; case CL_INVALID_CONTEXT: return "CL_INVALID_CONTEXT"; case CL_INVALID_QUEUE_PROPERTIES: return "CL_INVALID_QUEUE_PROPERTIES"; case CL_INVALID_COMMAND_QUEUE: return "CL_INVALID_COMMAND_QUEUE"; case CL_INVALID_HOST_PTR: return "CL_INVALID_HOST_PTR"; case CL_INVALID_MEM_OBJECT: return "CL_INVALID_MEM_OBJECT"; case CL_INVALID_IMAGE_FORMAT_DESCRIPTOR: return "CL_INVALID_IMAGE_FORMAT_DESCRIPTOR"; case CL_INVALID_IMAGE_SIZE: return "CL_INVALID_IMAGE_SIZE"; case CL_INVALID_SAMPLER: return "CL_INVALID_SAMPLER"; case CL_INVALID_BINARY: return "CL_INVALID_BINARY"; case CL_INVALID_BUILD_OPTIONS: return "CL_INVALID_BUILD_OPTIONS"; case CL_INVALID_PROGRAM: return "CL_INVALID_PROGRAM"; case CL_INVALID_PROGRAM_EXECUTABLE: return "CL_INVALID_PROGRAM_EXECUTABLE"; case CL_INVALID_KERNEL_NAME: return "CL_INVALID_KERNEL_NAME"; case CL_INVALID_KERNEL_DEFINITION: return "CL_INVALID_KERNEL_DEFINITION"; case CL_INVALID_KERNEL: return "CL_INVALID_KERNEL"; case CL_INVALID_ARG_INDEX: return "CL_INVALID_ARG_INDEX"; case CL_INVALID_ARG_VALUE: return "CL_INVALID_ARG_VALUE"; case CL_INVALID_ARG_SIZE: return "CL_INVALID_ARG_SIZE"; case CL_INVALID_KERNEL_ARGS: return "CL_INVALID_KERNEL_ARGS"; case CL_INVALID_WORK_DIMENSION: return "CL_INVALID_WORK_DIMENSION"; case CL_INVALID_WORK_GROUP_SIZE: return "CL_INVALID_WORK_GROUP_SIZE"; case CL_INVALID_WORK_ITEM_SIZE: return "CL_INVALID_WORK_ITEM_SIZE"; case CL_INVALID_GLOBAL_OFFSET: return "CL_INVALID_GLOBAL_OFFSET"; case CL_INVALID_EVENT_WAIT_LIST: return "CL_INVALID_EVENT_WAIT_LIST"; case CL_INVALID_EVENT: return "CL_INVALID_EVENT"; case CL_INVALID_OPERATION: return "CL_INVALID_OPERATION"; case CL_INVALID_GL_OBJECT: return "CL_INVALID_GL_OBJECT"; case CL_INVALID_BUFFER_SIZE: return "CL_INVALID_BUFFER_SIZE"; case CL_INVALID_MIP_LEVEL: return "CL_INVALID_MIP_LEVEL"; case CL_INVALID_GLOBAL_WORK_SIZE: return "CL_INVALID_GLOBAL_WORK_SIZE"; case CL_INVALID_PROPERTY: return "CL_INVALID_PROPERTY"; case CL_INVALID_IMAGE_DESCRIPTOR: return "CL_INVALID_IMAGE_DESCRIPTOR"; case CL_INVALID_COMPILER_OPTIONS: return "CL_INVALID_COMPILER_OPTIONS"; case CL_INVALID_LINKER_OPTIONS: return "CL_INVALID_LINKER_OPTIONS"; case CL_INVALID_DEVICE_PARTITION_COUNT: return "CL_INVALID_DEVICE_PARTITION_COUNT"; default: return "(unknown)"; } } const char *GetChannelOrderName( cl_channel_order order ) { switch( order ) { case CL_R: return "CL_R"; case CL_A: return "CL_A"; case CL_Rx: return "CL_Rx"; case CL_RG: return "CL_RG"; case CL_RA: return "CL_RA"; case CL_RGx: return "CL_RGx"; case CL_RGB: return "CL_RGB"; case CL_RGBx: return "CL_RGBx"; case CL_RGBA: return "CL_RGBA"; case CL_ARGB: return "CL_ARGB"; case CL_BGRA: return "CL_BGRA"; case CL_INTENSITY: return "CL_INTENSITY"; case CL_LUMINANCE: return "CL_LUMINANCE"; #if defined CL_1RGB_APPLE case CL_1RGB_APPLE: return "CL_1RGB_APPLE"; #endif #if defined CL_BGR1_APPLE case CL_BGR1_APPLE: return "CL_BGR1_APPLE"; #endif #if defined CL_ABGR_APPLE case CL_ABGR_APPLE: return "CL_ABGR_APPLE"; #endif case CL_DEPTH: return "CL_DEPTH"; case CL_DEPTH_STENCIL: return "CL_DEPTH_STENCIL"; case CL_sRGB: return "CL_sRGB"; case CL_sRGBA: return "CL_sRGBA"; case CL_sRGBx: return "CL_sRGBx"; case CL_sBGRA: return "CL_sBGRA"; case CL_ABGR: return "CL_ABGR"; default: return NULL; } } int IsChannelOrderSupported( cl_channel_order order ) { switch( order ) { case CL_R: case CL_A: case CL_Rx: case CL_RG: case CL_RA: case CL_RGx: case CL_RGB: case CL_RGBx: case CL_RGBA: case CL_ARGB: case CL_BGRA: case CL_INTENSITY: case CL_LUMINANCE: case CL_ABGR: case CL_sRGB: case CL_sRGBx: case CL_sBGRA: case CL_sRGBA: case CL_DEPTH: return 1; #if defined CL_1RGB_APPLE case CL_1RGB_APPLE: return 1; #endif #if defined CL_BGR1_APPLE case CL_BGR1_APPLE: return 1; #endif default: return 0; } } const char *GetChannelTypeName( cl_channel_type type ) { switch( type ) { case CL_SNORM_INT8: return "CL_SNORM_INT8"; case CL_SNORM_INT16: return "CL_SNORM_INT16"; case CL_UNORM_INT8: return "CL_UNORM_INT8"; case CL_UNORM_INT16: return "CL_UNORM_INT16"; case CL_UNORM_SHORT_565: return "CL_UNORM_SHORT_565"; case CL_UNORM_SHORT_555: return "CL_UNORM_SHORT_555"; case CL_UNORM_INT_101010: return "CL_UNORM_INT_101010"; case CL_SIGNED_INT8: return "CL_SIGNED_INT8"; case CL_SIGNED_INT16: return "CL_SIGNED_INT16"; case CL_SIGNED_INT32: return "CL_SIGNED_INT32"; case CL_UNSIGNED_INT8: return "CL_UNSIGNED_INT8"; case CL_UNSIGNED_INT16: return "CL_UNSIGNED_INT16"; case CL_UNSIGNED_INT32: return "CL_UNSIGNED_INT32"; case CL_HALF_FLOAT: return "CL_HALF_FLOAT"; case CL_FLOAT: return "CL_FLOAT"; #ifdef CL_SFIXED14_APPLE case CL_SFIXED14_APPLE: return "CL_SFIXED14_APPLE"; #endif case CL_UNORM_INT24: return "CL_UNORM_INT24"; default: return NULL; } } int IsChannelTypeSupported( cl_channel_type type ) { switch( type ) { case CL_SNORM_INT8: case CL_SNORM_INT16: case CL_UNORM_INT8: case CL_UNORM_INT16: case CL_UNORM_INT24: case CL_UNORM_SHORT_565: case CL_UNORM_SHORT_555: case CL_UNORM_INT_101010: case CL_SIGNED_INT8: case CL_SIGNED_INT16: case CL_SIGNED_INT32: case CL_UNSIGNED_INT8: case CL_UNSIGNED_INT16: case CL_UNSIGNED_INT32: case CL_HALF_FLOAT: case CL_FLOAT: return 1; #ifdef CL_SFIXED14_APPLE case CL_SFIXED14_APPLE: return 1; #endif default: return 0; } } const char *GetAddressModeName( cl_addressing_mode mode ) { switch( mode ) { case CL_ADDRESS_NONE: return "CL_ADDRESS_NONE"; case CL_ADDRESS_CLAMP_TO_EDGE: return "CL_ADDRESS_CLAMP_TO_EDGE"; case CL_ADDRESS_CLAMP: return "CL_ADDRESS_CLAMP"; case CL_ADDRESS_REPEAT: return "CL_ADDRESS_REPEAT"; case CL_ADDRESS_MIRRORED_REPEAT: return "CL_ADDRESS_MIRRORED_REPEAT"; default: return NULL; } } const char *GetDeviceTypeName( cl_device_type type ) { switch( type ) { case CL_DEVICE_TYPE_GPU: return "CL_DEVICE_TYPE_GPU"; case CL_DEVICE_TYPE_CPU: return "CL_DEVICE_TYPE_CPU"; case CL_DEVICE_TYPE_ACCELERATOR: return "CL_DEVICE_TYPE_ACCELERATOR"; case CL_DEVICE_TYPE_ALL: return "CL_DEVICE_TYPE_ALL"; default: return NULL; } } const char *GetDataVectorString( void *dataBuffer, size_t typeSize, size_t vecSize, char *buffer ) { static char scratch[ 1024 ]; size_t i, j; if( buffer == NULL ) buffer = scratch; unsigned char *p = (unsigned char *)dataBuffer; char *bPtr; buffer[ 0 ] = 0; bPtr = buffer; for( i = 0; i < vecSize; i++ ) { if( i > 0 ) { bPtr[ 0 ] = ' '; bPtr++; } for( j = 0; j < typeSize; j++ ) { sprintf( bPtr, "%02x", (unsigned int)p[ typeSize - j - 1 ] ); bPtr += 2; } p += typeSize; } bPtr[ 0 ] = 0; return buffer; } #ifndef MAX #define MAX( _a, _b ) ((_a) > (_b) ? (_a) : (_b)) #endif #if defined( _MSC_VER ) #define scalbnf(_a, _i ) ldexpf( _a, _i ) #define scalbn(_a, _i ) ldexp( _a, _i ) #define scalbnl(_a, _i ) ldexpl( _a, _i ) #endif static float Ulp_Error_Half_Float( float test, double reference ); static inline float half2float( cl_ushort half ); // taken from math tests #define HALF_MIN_EXP -13 #define HALF_MANT_DIG 11 static float Ulp_Error_Half_Float( float test, double reference ) { union{ double d; uint64_t u; }u; u.d = reference; // Note: This function presumes that someone has already tested whether the result is correctly, // rounded before calling this function. That test: // // if( (float) reference == test ) // return 0.0f; // // would ensure that cases like fabs(reference) > FLT_MAX are weeded out before we get here. // Otherwise, we'll return inf ulp error here, for what are otherwise correctly rounded // results. double testVal = test; if( u.u & 0x000fffffffffffffULL ) { // Non-power of two and NaN if( isnan( reference ) && isnan( test ) ) return 0.0f; // if we are expecting a NaN, any NaN is fine // The unbiased exponent of the ulp unit place int ulp_exp = HALF_MANT_DIG - 1 - MAX( ilogb( reference), HALF_MIN_EXP-1 ); // Scale the exponent of the error return (float) scalbn( testVal - reference, ulp_exp ); } if( isinf( reference ) ) { if( (double) test == reference ) return 0.0f; return (float) (testVal - reference ); } // reference is a normal power of two or a zero int ulp_exp = HALF_MANT_DIG - 1 - MAX( ilogb( reference) - 1, HALF_MIN_EXP-1 ); // Scale the exponent of the error return (float) scalbn( testVal - reference, ulp_exp ); } // Taken from vLoadHalf test static inline float half2float( cl_ushort us ) { uint32_t u = us; uint32_t sign = (u << 16) & 0x80000000; int32_t exponent = (u & 0x7c00) >> 10; uint32_t mantissa = (u & 0x03ff) << 13; union{ unsigned int u; float f;}uu; if( exponent == 0 ) { if( mantissa == 0 ) return sign ? -0.0f : 0.0f; int shift = __builtin_clz( mantissa ) - 8; exponent -= shift-1; mantissa <<= shift; mantissa &= 0x007fffff; } else if( exponent == 31) { uu.u = mantissa | sign; if( mantissa ) uu.u |= 0x7fc00000; else uu.u |= 0x7f800000; return uu.f; } exponent += 127 - 15; exponent <<= 23; exponent |= mantissa; uu.u = exponent | sign; return uu.f; } float Ulp_Error_Half( cl_ushort test, float reference ) { return Ulp_Error_Half_Float( half2float(test), reference ); } float Ulp_Error( float test, double reference ) { union{ double d; uint64_t u; }u; u.d = reference; double testVal = test; // Note: This function presumes that someone has already tested whether the result is correctly, // rounded before calling this function. That test: // // if( (float) reference == test ) // return 0.0f; // // would ensure that cases like fabs(reference) > FLT_MAX are weeded out before we get here. // Otherwise, we'll return inf ulp error here, for what are otherwise correctly rounded // results. if( isinf( reference ) ) { if( testVal == reference ) return 0.0f; return (float) (testVal - reference ); } if( isinf( testVal) ) { // infinite test value, but finite (but possibly overflowing in float) reference. // // The function probably overflowed prematurely here. Formally, the spec says this is // an infinite ulp error and should not be tolerated. Unfortunately, this would mean // that the internal precision of some half_pow implementations would have to be 29+ bits // at half_powr( 0x1.fffffep+31, 4) to correctly determine that 4*log2( 0x1.fffffep+31 ) // is not exactly 128.0. You might represent this for example as 4*(32 - ~2**-24), which // after rounding to single is 4*32 = 128, which will ultimately result in premature // overflow, even though a good faith representation would be correct to within 2**-29 // interally. // In the interest of not requiring the implementation go to extraordinary lengths to // deliver a half precision function, we allow premature overflow within the limit // of the allowed ulp error. Towards, that end, we "pretend" the test value is actually // 2**128, the next value that would appear in the number line if float had sufficient range. testVal = copysign( MAKE_HEX_DOUBLE(0x1.0p128, 0x1LL, 128), testVal ); // Note that the same hack may not work in long double, which is not guaranteed to have // more range than double. It is not clear that premature overflow should be tolerated for // double. } if( u.u & 0x000fffffffffffffULL ) { // Non-power of two and NaN if( isnan( reference ) && isnan( test ) ) return 0.0f; // if we are expecting a NaN, any NaN is fine // The unbiased exponent of the ulp unit place int ulp_exp = FLT_MANT_DIG - 1 - MAX( ilogb( reference), FLT_MIN_EXP-1 ); // Scale the exponent of the error return (float) scalbn( testVal - reference, ulp_exp ); } // reference is a normal power of two or a zero // The unbiased exponent of the ulp unit place int ulp_exp = FLT_MANT_DIG - 1 - MAX( ilogb( reference) - 1, FLT_MIN_EXP-1 ); // Scale the exponent of the error return (float) scalbn( testVal - reference, ulp_exp ); } float Ulp_Error_Double( double test, long double reference ) { // Deal with long double = double // On most systems long double is a higher precision type than double. They provide either // a 80-bit or greater floating point type, or they provide a head-tail double double format. // That is sufficient to represent the accuracy of a floating point result to many more bits // than double and we can calculate sub-ulp errors. This is the standard system for which this // test suite is designed. // // On some systems double and long double are the same thing. Then we run into a problem, // because our representation of the infinitely precise result (passed in as reference above) // can be off by as much as a half double precision ulp itself. In this case, we inflate the // reported error by half an ulp to take this into account. A more correct and permanent fix // would be to undertake refactoring the reference code to return results in this format: // // typedef struct DoubleReference // { // true value = correctlyRoundedResult + ulps * ulp(correctlyRoundedResult) (infinitely precise) // double correctlyRoundedResult; // as best we can // double ulps; // plus a fractional amount to account for the difference // }DoubleReference; // between infinitely precise result and correctlyRoundedResult, in units of ulps. // // This would provide a useful higher-than-double precision format for everyone that we can use, // and would solve a few problems with representing absolute errors below DBL_MIN and over DBL_MAX for systems // that use a head to tail double double for long double. // Note: This function presumes that someone has already tested whether the result is correctly, // rounded before calling this function. That test: // // if( (float) reference == test ) // return 0.0f; // // would ensure that cases like fabs(reference) > FLT_MAX are weeded out before we get here. // Otherwise, we'll return inf ulp error here, for what are otherwise correctly rounded // results. int x; long double testVal = test; if( 0.5L != frexpl( reference, &x) ) { // Non-power of two and NaN if( isinf( reference ) ) { if( testVal == reference ) return 0.0f; return (float) ( testVal - reference ); } if( isnan( reference ) && isnan( test ) ) return 0.0f; // if we are expecting a NaN, any NaN is fine // The unbiased exponent of the ulp unit place int ulp_exp = DBL_MANT_DIG - 1 - MAX( ilogbl( reference), DBL_MIN_EXP-1 ); // Scale the exponent of the error float result = (float) scalbnl( testVal - reference, ulp_exp ); // account for rounding error in reference result on systems that do not have a higher precision floating point type (see above) if( sizeof(long double) == sizeof( double ) ) result += copysignf( 0.5f, result); return result; } // reference is a normal power of two or a zero // The unbiased exponent of the ulp unit place int ulp_exp = DBL_MANT_DIG - 1 - MAX( ilogbl( reference) - 1, DBL_MIN_EXP-1 ); // Scale the exponent of the error float result = (float) scalbnl( testVal - reference, ulp_exp ); // account for rounding error in reference result on systems that do not have a higher precision floating point type (see above) if( sizeof(long double) == sizeof( double ) ) result += copysignf( 0.5f, result); return result; } cl_int OutputBuildLogs(cl_program program, cl_uint num_devices, cl_device_id *device_list) { int error; size_t size_ret; // Does the program object exist? if (program != NULL) { // Was the number of devices given if (num_devices == 0) { // If zero devices were specified then allocate and query the device list from the context cl_context context; error = clGetProgramInfo(program, CL_PROGRAM_CONTEXT, sizeof(context), &context, NULL); test_error( error, "Unable to query program's context" ); error = clGetContextInfo(context, CL_CONTEXT_DEVICES, 0, NULL, &size_ret); test_error( error, "Unable to query context's device size" ); num_devices = size_ret / sizeof(cl_device_id); device_list = (cl_device_id *) malloc(size_ret); if (device_list == NULL) { print_error( error, "malloc failed" ); return CL_OUT_OF_HOST_MEMORY; } error = clGetContextInfo(context, CL_CONTEXT_DEVICES, size_ret, device_list, NULL); test_error( error, "Unable to query context's devices" ); } // For each device in the device_list unsigned int i; for (i = 0; i < num_devices; i++) { // Get the build status cl_build_status build_status; error = clGetProgramBuildInfo(program, device_list[i], CL_PROGRAM_BUILD_STATUS, sizeof(build_status), &build_status, &size_ret); test_error( error, "Unable to query build status" ); // If the build failed then log the status, and allocate the build log, log it and free it if (build_status != CL_BUILD_SUCCESS) { log_error("ERROR: CL_PROGRAM_BUILD_STATUS=%d\n", (int) build_status); error = clGetProgramBuildInfo(program, device_list[i], CL_PROGRAM_BUILD_LOG, 0, NULL, &size_ret); test_error( error, "Unable to query build log size" ); char *build_log = (char *) malloc(size_ret); error = clGetProgramBuildInfo(program, device_list[i], CL_PROGRAM_BUILD_LOG, size_ret, build_log, &size_ret); test_error( error, "Unable to query build log" ); log_error("ERROR: CL_PROGRAM_BUILD_LOG:\n%s\n", build_log); free(build_log); } } // Was the number of devices given if (num_devices == 0) { // If zero devices were specified then free the device list free(device_list); } } return CL_SUCCESS; } const char * subtests_requiring_opencl_1_2[] = { "device_partition_equally", "device_partition_by_counts", "device_partition_by_affinity_domain_numa", "device_partition_by_affinity_domain_l4_cache", "device_partition_by_affinity_domain_l3_cache", "device_partition_by_affinity_domain_l2_cache", "device_partition_by_affinity_domain_l1_cache", "device_partition_by_affinity_domain_next_partitionable", "device_partition_all", "buffer_fill_int", "buffer_fill_uint", "buffer_fill_short", "buffer_fill_ushort", "buffer_fill_char", "buffer_fill_uchar", "buffer_fill_long", "buffer_fill_ulong", "buffer_fill_float", "buffer_fill_struct", "test_mem_host_write_only_buffer", "test_mem_host_write_only_subbuffer", "test_mem_host_no_access_buffer", "test_mem_host_no_access_subbuffer", "test_mem_host_read_only_image", "test_mem_host_write_only_image", "test_mem_host_no_access_image", // CL_MEM_HOST_{READ|WRITE}_ONLY api/ "get_buffer_info", "get_image1d_info", "get_image1d_array_info", "get_image2d_array_info", // gl/ "images_read_1D", "images_write_1D", "images_1D_getinfo", "images_read_1Darray", "images_write_1Darray", "images_1Darray_getinfo", "images_read_2Darray", "images_write_2Darray", "images_2Darray_getinfo", "buffer_migrate", "image_migrate", // compiler/ "load_program_source", "load_multistring_source", "load_two_kernel_source", "load_null_terminated_source", "load_null_terminated_multi_line_source", "load_null_terminated_partial_multi_line_source", "load_discreet_length_source", "get_program_source", "get_program_build_info", "get_program_info", "large_compile", "async_build", "options_build_optimizations", "options_build_macro", "options_build_macro_existence", "options_include_directory", "options_denorm_cache", "preprocessor_define_udef", "preprocessor_include", "preprocessor_line_error", "preprocessor_pragma", "compiler_defines_for_extensions", "image_macro", "simple_compile_only", "simple_static_compile_only", "simple_extern_compile_only", "simple_compile_with_callback", "simple_embedded_header_compile", "simple_link_only", "two_file_regular_variable_access", "two_file_regular_struct_access", "two_file_regular_function_access", "simple_link_with_callback", "simple_embedded_header_link", "execute_after_simple_compile_and_link", "execute_after_simple_compile_and_link_no_device_info", "execute_after_simple_compile_and_link_with_defines", "execute_after_simple_compile_and_link_with_callbacks", "execute_after_simple_library_with_link", "execute_after_two_file_link", "execute_after_two_file_link", "execute_after_embedded_header_link", "execute_after_included_header_link", "execute_after_serialize_reload_object", "execute_after_serialize_reload_library", "simple_library_only", "simple_library_with_callback", "simple_library_with_link", "two_file_link", "multi_file_libraries", "multiple_files", "multiple_libraries", "multiple_files_multiple_libraries", "multiple_embedded_headers", "program_binary_type", "compile_and_link_status_options_log", // CL_PROGRAM_NUM_KERNELS, in api/ "get_kernel_arg_info", "create_kernels_in_program", // clEnqueue..WithWaitList, in events/ "event_enqueue_marker_with_event_list", "event_enqueue_barrier_with_event_list", "popcount" }; const char * subtests_to_skip_with_offline_compiler[] = { "get_kernel_arg_info", "binary_create", "load_program_source", "load_multistring_source", "load_two_kernel_source", "load_null_terminated_source", "load_null_terminated_multi_line_source", "load_null_terminated_partial_multi_line_source", "load_discreet_length_source", "get_program_source", "get_program_build_info", "options_build_optimizations", "options_build_macro", "options_build_macro_existence", "options_include_directory", "options_denorm_cache", "preprocessor_define_udef", "preprocessor_include", "preprocessor_line_error", "preprocessor_pragma", "compiler_defines_for_extensions", "image_macro", "simple_extern_compile_only", "simple_embedded_header_compile", "two_file_regular_variable_access", "two_file_regular_struct_access", "two_file_regular_function_access", "simple_embedded_header_link", "execute_after_simple_compile_and_link_with_defines", "execute_after_simple_compile_and_link_with_callbacks", "execute_after_embedded_header_link", "execute_after_included_header_link", "multi_file_libraries", "multiple_files", "multiple_libraries", "multiple_files_multiple_libraries", "multiple_embedded_headers", "program_binary_type", "compile_and_link_status_options_log", "kernel_preprocessor_macros", }; int check_functions_for_offline_compiler(const char *subtestname, cl_device_id device) { if (gCompilationMode != kOnline) { int nNotRequiredWithOfflineCompiler = sizeof(subtests_to_skip_with_offline_compiler)/sizeof(char *); size_t i; for(i=0; i < nNotRequiredWithOfflineCompiler; ++i) { if(!strcmp(subtestname, subtests_to_skip_with_offline_compiler[i])) { return 1; } } } return 0; }