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cl22: Convert images/kernel_read_write to testHarness (#86)

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Signed-off-by: Radek Szymanski <radek.szymanski@arm.com>
This commit is contained in:
Radek Szymanski
2019-03-18 09:56:00 +00:00
committed by Kévin Petit
parent f6d6f6b3cc
commit a0ef00101f
1 changed files with 279 additions and 310 deletions
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589
test_conformance/images/kernel_read_write/main.cpp
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@@ -50,67 +50,14 @@ bool gEnablePitch = false;
cl_device_type gDeviceType = CL_DEVICE_TYPE_DEFAULT;
int gtestTypesToRun = 0;
static int testTypesToRun;
cl_command_queue queue;
cl_context context;
static cl_device_id device;
#define MAX_ALLOWED_STD_DEVIATION_IN_MB 8.0
void printUsage( const char *execName )
{
const char *p = strrchr( execName, '/' );
if( p != NULL )
execName = p + 1;
log_info( "Usage: %s [read] [write] [CL_FILTER_LINEAR|CL_FILTER_NEAREST] [no_offsets] [debug_trace] [small_images]\n", execName );
log_info( "Where:\n" );
log_info( "\n" );
log_info( "\tThe following flags specify what kinds of operations to test. They can be combined; if none are specified, all are tested:\n" );
log_info( "\t\tread - Tests reading from an image\n" );
log_info( "\t\twrite - Tests writing to an image (can be specified with read to run both; default is both)\n" );
log_info( "\n" );
log_info( "\tThe following flags specify the types to test. They can be combined; if none are specified, all are tested:\n" );
log_info( "\t\tint - Test integer I/O (read_imagei, write_imagei)\n" );
log_info( "\t\tuint - Test unsigned integer I/O (read_imageui, write_imageui)\n" );
log_info( "\t\tfloat - Test float I/O (read_imagef, write_imagef)\n" );
log_info( "\n" );
log_info( "\tCL_FILTER_LINEAR - Only tests formats with CL_FILTER_LINEAR filtering\n" );
log_info( "\tCL_FILTER_NEAREST - Only tests formats with CL_FILTER_NEAREST filtering\n" );
log_info( "\n" );
log_info( "\tNORMALIZED - Only tests formats with NORMALIZED coordinates\n" );
log_info( "\tUNNORMALIZED - Only tests formats with UNNORMALIZED coordinates\n" );
log_info( "\n" );
log_info( "\tCL_ADDRESS_CLAMP - Only tests formats with CL_ADDRESS_CLAMP addressing\n" );
log_info( "\tCL_ADDRESS_CLAMP_TO_EDGE - Only tests formats with CL_ADDRESS_CLAMP_TO_EDGE addressing\n" );
log_info( "\tCL_ADDRESS_REPEAT - Only tests formats with CL_ADDRESS_REPEAT addressing\n" );
log_info( "\tCL_ADDRESS_MIRRORED_REPEAT - Only tests formats with CL_ADDRESS_MIRRORED_REPEAT addressing\n" );
log_info( "\n" );
log_info( "You may also use appropriate CL_ channel type and ordering constants.\n" );
log_info( "\n" );
log_info( "\t1D - Only test 1D images\n" );
log_info( "\t2D - Only test 2D images\n" );
log_info( "\t3D - Only test 3D images\n" );
log_info( "\t1Darray - Only test 1D image arrays\n" );
log_info( "\t2Darray - Only test 2D image arrays\n" );
log_info( "\n" );
log_info( "\tlocal_samplers - Use samplers declared in the kernel functions instead of passed in as arguments\n" );
log_info( "\n" );
log_info( "\tThe following specify to use the specific flag to allocate images to use in the tests:\n" );
log_info( "\t\tCL_MEM_COPY_HOST_PTR\n" );
log_info( "\t\tCL_MEM_USE_HOST_PTR (default)\n" );
log_info( "\t\tCL_MEM_ALLOC_HOST_PTR\n" );
log_info( "\t\tNO_HOST_PTR - Specifies to use none of the above flags\n" );
log_info( "\n" );
log_info( "\tThe following modify the types of images tested:\n" );
log_info( "\t\tsmall_images - Runs every format through a loop of widths 1-13 and heights 1-9, instead of random sizes\n" );
log_info( "\t\tmax_images - Runs every format through a set of size combinations with the max values, max values - 1, and max values / 128\n" );
log_info( "\t\trounding - Runs every format through a single image filled with every possible value for that image format, to verify rounding works properly\n" );
log_info( "\n" );
log_info( "\tno_offsets - Disables offsets when testing reads (can be good for diagnosing address repeating/clamping problems)\n" );
log_info( "\tdebug_trace - Enables additional debug info logging\n" );
log_info( "\textra_validate - Enables additional validation failure debug information\n" );
log_info( "\tuse_pitches - Enables row and slice pitches\n" );
log_info( "\ttest_mipmaps - Enables mipmapped images\n");
}
static void printUsage( const char *execName );
extern int test_image_set( cl_device_id device, test_format_set_fn formatTestFn, cl_mem_object_type imageType );
@@ -159,21 +106,176 @@ static void recover_global_params_from_read_write_test(bool tTestMipm
gFilterModeToUse = tFilterModeToUse;
}
int main(int argc, const char *argv[])
static int doTest( cl_mem_object_type imageType )
{
cl_platform_id platform;
cl_device_id device;
cl_channel_type chanType;
cl_channel_order chanOrder;
char str[ 128 ];
int testTypesToRun = 0;
int testMethods = 0;
bool randomize = false;
int ret = 0;
bool is_2d_image = imageType == CL_MEM_OBJECT_IMAGE2D;
bool tTestMipMaps = false;
bool tDisableOffsets = false;
bool tNormalizedModeToUse = false;
cl_filter_mode tFilterModeToUse = (cl_filter_mode)-1;
if( testTypesToRun & kReadTests )
{
gtestTypesToRun = kReadTests;
ret += test_image_set( device, test_read_image_formats, imageType );
if( is_2d_image && is_extension_available( device, "cl_khr_image2d_from_buffer" ) )
{
log_info( "Testing read_image{f | i | ui} for 2D image from buffer\n" );
// NOTE: for 2D image from buffer test, gTestSmallImages, gTestMaxImages, gTestRounding and gTestMipmaps must be false
if( gTestSmallImages == false && gTestMaxImages == false && gTestRounding == false && gTestMipmaps == false )
{
cl_mem_flags saved_gMemFlagsToUse = gMemFlagsToUse;
gTestImage2DFromBuffer = true;
// disable CL_MEM_USE_HOST_PTR for 1.2 extension but enable this for 2.0
gMemFlagsToUse = CL_MEM_COPY_HOST_PTR;
ret += test_image_set( device, test_read_image_formats, imageType );
gTestImage2DFromBuffer = false;
gMemFlagsToUse = saved_gMemFlagsToUse;
}
}
}
if( testTypesToRun & kWriteTests )
{
gtestTypesToRun = kWriteTests;
ret += test_image_set( device, test_write_image_formats, imageType );
if( is_2d_image && is_extension_available( device, "cl_khr_image2d_from_buffer" ) )
{
log_info( "Testing write_image{f | i | ui} for 2D image from buffer\n" );
// NOTE: for 2D image from buffer test, gTestSmallImages, gTestMaxImages,gTestRounding and gTestMipmaps must be false
if( gTestSmallImages == false && gTestMaxImages == false && gTestRounding == false && gTestMipmaps == false )
{
bool saved_gEnablePitch = gEnablePitch;
cl_mem_flags saved_gMemFlagsToUse = gMemFlagsToUse;
gEnablePitch = true;
// disable CL_MEM_USE_HOST_PTR for 1.2 extension but enable this for 2.0
gMemFlagsToUse = CL_MEM_COPY_HOST_PTR;
gTestImage2DFromBuffer = true;
ret += test_image_set( device, test_write_image_formats, imageType );
gTestImage2DFromBuffer = false;
gMemFlagsToUse = saved_gMemFlagsToUse;
gEnablePitch = saved_gEnablePitch;
}
}
}
if( ( testTypesToRun & kReadWriteTests ) && !gTestMipmaps )
{
gtestTypesToRun = kReadWriteTests;
overwrite_global_params_for_read_write_test(&tTestMipMaps, &tDisableOffsets, &tNormalizedModeToUse, &tFilterModeToUse);
ret += test_image_set( device, test_read_image_formats, imageType );
if( is_2d_image && is_extension_available( device, "cl_khr_image2d_from_buffer" ) )
{
log_info("Testing read_image{f | i | ui} for 2D image from buffer\n");
// NOTE: for 2D image from buffer test, gTestSmallImages, gTestMaxImages, gTestRounding and gTestMipmaps must be false
if( gTestSmallImages == false && gTestMaxImages == false && gTestRounding == false && gTestMipmaps == false )
{
cl_mem_flags saved_gMemFlagsToUse = gMemFlagsToUse;
gTestImage2DFromBuffer = true;
// disable CL_MEM_USE_HOST_PTR for 1.2 extension but enable this for 2.0
gMemFlagsToUse = CL_MEM_COPY_HOST_PTR;
ret += test_image_set( device, test_read_image_formats, imageType );
gTestImage2DFromBuffer = false;
gMemFlagsToUse = saved_gMemFlagsToUse;
}
}
ret += test_image_set( device, test_write_image_formats, imageType );
if( is_2d_image && is_extension_available( device, "cl_khr_image2d_from_buffer" ) )
{
log_info("Testing write_image{f | i | ui} for 2D image from buffer\n");
// NOTE: for 2D image from buffer test, gTestSmallImages, gTestMaxImages,gTestRounding and gTestMipmaps must be false
if( gTestSmallImages == false && gTestMaxImages == false && gTestRounding == false && gTestMipmaps == false )
{
bool saved_gEnablePitch = gEnablePitch;
cl_mem_flags saved_gMemFlagsToUse = gMemFlagsToUse;
gEnablePitch = true;
// disable CL_MEM_USE_HOST_PTR for 1.2 extension but enable this for 2.0
gMemFlagsToUse = CL_MEM_COPY_HOST_PTR;
gTestImage2DFromBuffer = true;
ret += test_image_set( device, test_write_image_formats, imageType );
gTestImage2DFromBuffer = false;
gMemFlagsToUse = saved_gMemFlagsToUse;
gEnablePitch = saved_gEnablePitch;
}
}
recover_global_params_from_read_write_test( tTestMipMaps, tDisableOffsets, tNormalizedModeToUse, tFilterModeToUse );
}
return ret;
}
int test_1D(cl_device_id deviceID, cl_context context, cl_command_queue queue, int num_elements)
{
return doTest( CL_MEM_OBJECT_IMAGE1D );
}
int test_2D(cl_device_id deviceID, cl_context context, cl_command_queue queue, int num_elements)
{
return doTest( CL_MEM_OBJECT_IMAGE2D );
}
int test_3D(cl_device_id deviceID, cl_context context, cl_command_queue queue, int num_elements)
{
return doTest( CL_MEM_OBJECT_IMAGE3D );
}
int test_1Darray(cl_device_id deviceID, cl_context context, cl_command_queue queue, int num_elements)
{
return doTest( CL_MEM_OBJECT_IMAGE1D_ARRAY );
}
int test_2Darray(cl_device_id deviceID, cl_context context, cl_command_queue queue, int num_elements)
{
return doTest( CL_MEM_OBJECT_IMAGE2D_ARRAY );
}
basefn basefn_list[] = {
test_1D,
test_2D,
test_3D,
test_1Darray,
test_2Darray,
};
const char *basefn_names[] = {
"1D",
"2D",
"3D",
"1Darray",
"2Darray",
};
ct_assert((sizeof(basefn_names) / sizeof(basefn_names[0])) == (sizeof(basefn_list) / sizeof(basefn_list[0])));
int num_fns = sizeof(basefn_names) / sizeof(char *);
int main(int argc, const char *argv[])
{
cl_platform_id platform;
cl_channel_type chanType;
cl_channel_order chanOrder;
bool randomize = false;
test_start();
argc = parseCustomParam(argc, argv);
@@ -186,127 +288,122 @@ int main(int argc, const char *argv[])
//Check CL_DEVICE_TYPE environment variable
checkDeviceTypeOverride( &gDeviceType );
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++ )
{
strncpy( str, argv[ i ], sizeof( str ) - 1 );
if( strcmp( str, "cpu" ) == 0 || strcmp( str, "CL_DEVICE_TYPE_CPU" ) == 0 )
if( strcmp( argv[i], "cpu" ) == 0 || strcmp( argv[i], "CL_DEVICE_TYPE_CPU" ) == 0 )
gDeviceType = CL_DEVICE_TYPE_CPU;
else if( strcmp( str, "gpu" ) == 0 || strcmp( str, "CL_DEVICE_TYPE_GPU" ) == 0 )
else if( strcmp( argv[i], "gpu" ) == 0 || strcmp( argv[i], "CL_DEVICE_TYPE_GPU" ) == 0 )
gDeviceType = CL_DEVICE_TYPE_GPU;
else if( strcmp( str, "accelerator" ) == 0 || strcmp( str, "CL_DEVICE_TYPE_ACCELERATOR" ) == 0 )
else if( strcmp( argv[i], "accelerator" ) == 0 || strcmp( argv[i], "CL_DEVICE_TYPE_ACCELERATOR" ) == 0 )
gDeviceType = CL_DEVICE_TYPE_ACCELERATOR;
else if( strcmp( str, "CL_DEVICE_TYPE_DEFAULT" ) == 0 )
else if( strcmp( argv[i], "CL_DEVICE_TYPE_DEFAULT" ) == 0 )
gDeviceType = CL_DEVICE_TYPE_DEFAULT;
else if( strcmp( str, "debug_trace" ) == 0 )
else if( strcmp( argv[i], "debug_trace" ) == 0 )
gDebugTrace = true;
else if( strcmp( str, "CL_FILTER_NEAREST" ) == 0 || strcmp( str, "NEAREST" ) == 0 )
else if( strcmp( argv[i], "CL_FILTER_NEAREST" ) == 0 || strcmp( argv[i], "NEAREST" ) == 0 )
gFilterModeToUse = CL_FILTER_NEAREST;
else if( strcmp( str, "CL_FILTER_LINEAR" ) == 0 || strcmp( str, "LINEAR" ) == 0 )
else if( strcmp( argv[i], "CL_FILTER_LINEAR" ) == 0 || strcmp( argv[i], "LINEAR" ) == 0 )
gFilterModeToUse = CL_FILTER_LINEAR;
else if( strcmp( str, "CL_ADDRESS_NONE" ) == 0 )
else if( strcmp( argv[i], "CL_ADDRESS_NONE" ) == 0 )
gAddressModeToUse = CL_ADDRESS_NONE;
else if( strcmp( str, "CL_ADDRESS_CLAMP" ) == 0 )
else if( strcmp( argv[i], "CL_ADDRESS_CLAMP" ) == 0 )
gAddressModeToUse = CL_ADDRESS_CLAMP;
else if( strcmp( str, "CL_ADDRESS_CLAMP_TO_EDGE" ) == 0 )
else if( strcmp( argv[i], "CL_ADDRESS_CLAMP_TO_EDGE" ) == 0 )
gAddressModeToUse = CL_ADDRESS_CLAMP_TO_EDGE;
else if( strcmp( str, "CL_ADDRESS_REPEAT" ) == 0 )
else if( strcmp( argv[i], "CL_ADDRESS_REPEAT" ) == 0 )
gAddressModeToUse = CL_ADDRESS_REPEAT;
else if( strcmp( str, "CL_ADDRESS_MIRRORED_REPEAT" ) == 0 )
else if( strcmp( argv[i], "CL_ADDRESS_MIRRORED_REPEAT" ) == 0 )
gAddressModeToUse = CL_ADDRESS_MIRRORED_REPEAT;
else if( strcmp( str, "NORMALIZED" ) == 0 )
else if( strcmp( argv[i], "NORMALIZED" ) == 0 )
gNormalizedModeToUse = true;
else if( strcmp( str, "UNNORMALIZED" ) == 0 )
else if( strcmp( argv[i], "UNNORMALIZED" ) == 0 )
gNormalizedModeToUse = false;
else if( strcmp( str, "no_offsets" ) == 0 )
else if( strcmp( argv[i], "no_offsets" ) == 0 )
gDisableOffsets = true;
else if( strcmp( str, "small_images" ) == 0 )
else if( strcmp( argv[i], "small_images" ) == 0 )
gTestSmallImages = true;
else if( strcmp( str, "max_images" ) == 0 )
else if( strcmp( argv[i], "max_images" ) == 0 )
gTestMaxImages = true;
else if( strcmp( str, "use_pitches" ) == 0 )
else if( strcmp( argv[i], "use_pitches" ) == 0 )
gEnablePitch = true;
else if( strcmp( str, "rounding" ) == 0 )
else if( strcmp( argv[i], "rounding" ) == 0 )
gTestRounding = true;
else if( strcmp( str, "extra_validate" ) == 0 )
else if( strcmp( argv[i], "extra_validate" ) == 0 )
gExtraValidateInfo = true;
else if( strcmp( str, "test_mipmaps" ) == 0 ) {
else if( strcmp( argv[i], "test_mipmaps" ) == 0 ) {
// 2.0 Spec does not allow using mem flags, unnormalized coordinates with mipmapped images
gTestMipmaps = true;
gMemFlagsToUse = 0;
gNormalizedModeToUse = true;
}
else if( strcmp( str, "read" ) == 0 )
else if( strcmp( argv[i], "read" ) == 0 )
testTypesToRun |= kReadTests;
else if( strcmp( str, "write" ) == 0 )
else if( strcmp( argv[i], "write" ) == 0 )
testTypesToRun |= kWriteTests;
else if( strcmp( str, "read_write" ) == 0 )
else if( strcmp( argv[i], "read_write" ) == 0 )
{
testTypesToRun |= kReadWriteTests;
}
else if( strcmp( str, "local_samplers" ) == 0 )
else if( strcmp( argv[i], "local_samplers" ) == 0 )
gUseKernelSamplers = true;
else if( strcmp( str, "int" ) == 0 )
else if( strcmp( argv[i], "int" ) == 0 )
gTypesToTest |= kTestInt;
else if( strcmp( str, "uint" ) == 0 )
else if( strcmp( argv[i], "uint" ) == 0 )
gTypesToTest |= kTestUInt;
else if( strcmp( str, "float" ) == 0 )
else if( strcmp( argv[i], "float" ) == 0 )
gTypesToTest |= kTestFloat;
else if( strcmp( str, "randomize" ) == 0 )
else if( strcmp( argv[i], "randomize" ) == 0 )
randomize = true;
else if ( strcmp( str, "1D" ) == 0 )
testMethods |= k1D;
else if( strcmp( str, "2D" ) == 0 )
testMethods |= k2D;
else if( strcmp( str, "3D" ) == 0 )
testMethods |= k3D;
else if( strcmp( str, "1Darray" ) == 0 )
testMethods |= k1DArray;
else if( strcmp( str, "2Darray" ) == 0 )
testMethods |= k2DArray;
else if( strcmp( str, "CL_MEM_COPY_HOST_PTR" ) == 0 || strcmp( str, "COPY_HOST_PTR" ) == 0 )
else if( strcmp( argv[i], "CL_MEM_COPY_HOST_PTR" ) == 0 || strcmp( argv[i], "COPY_HOST_PTR" ) == 0 )
gMemFlagsToUse = CL_MEM_COPY_HOST_PTR;
else if( strcmp( str, "CL_MEM_USE_HOST_PTR" ) == 0 || strcmp( str, "USE_HOST_PTR" ) == 0 )
else if( strcmp( argv[i], "CL_MEM_USE_HOST_PTR" ) == 0 || strcmp( argv[i], "USE_HOST_PTR" ) == 0 )
gMemFlagsToUse = CL_MEM_USE_HOST_PTR;
else if( strcmp( str, "CL_MEM_ALLOC_HOST_PTR" ) == 0 || strcmp( str, "ALLOC_HOST_PTR" ) == 0 )
else if( strcmp( argv[i], "CL_MEM_ALLOC_HOST_PTR" ) == 0 || strcmp( argv[i], "ALLOC_HOST_PTR" ) == 0 )
gMemFlagsToUse = CL_MEM_ALLOC_HOST_PTR;
else if( strcmp( str, "NO_HOST_PTR" ) == 0 )
else if( strcmp( argv[i], "NO_HOST_PTR" ) == 0 )
gMemFlagsToUse = 0;
else if( strcmp( str, "help" ) == 0 || strcmp( str, "?" ) == 0 )
else if( strcmp( argv[i], "--help" ) == 0 || strcmp( argv[i], "-h" ) == 0 )
{
printUsage( argv[ 0 ] );
return -1;
}
else if( ( chanType = get_channel_type_from_name( str ) ) != (cl_channel_type)-1 )
else if( ( chanType = get_channel_type_from_name( argv[i] ) ) != (cl_channel_type)-1 )
gChannelTypeToUse = chanType;
else if( ( chanOrder = get_channel_order_from_name( str ) ) != (cl_channel_order)-1 )
else if( ( chanOrder = get_channel_order_from_name( argv[i] ) ) != (cl_channel_order)-1 )
gChannelOrderToUse = chanOrder;
else
{
log_error( "ERROR: Unknown argument %d: %s. Exiting....\n", i, str );
return -1;
argList[argCount] = argv[i];
argCount++;
}
}
if (testMethods == 0)
testMethods = k1D | k2D | k3D | k1DArray | k2DArray;
if( testTypesToRun == 0 )
testTypesToRun = kAllTests;
if( gTypesToTest == 0 )
@@ -442,190 +539,7 @@ int main(int argc, const char *argv[])
FPU_mode_type oldMode;
DisableFTZ(&oldMode);
// Run the test now
int ret = 0;
if (testMethods & k1D)
{
if (testTypesToRun & kReadTests)
{
gtestTypesToRun = kReadTests;
ret += test_image_set( device, test_read_image_formats, CL_MEM_OBJECT_IMAGE1D );
}
if (testTypesToRun & kWriteTests)
{
gtestTypesToRun = kWriteTests;
ret += test_image_set( device, test_write_image_formats, CL_MEM_OBJECT_IMAGE1D );
}
if ((testTypesToRun & kReadWriteTests) && !gTestMipmaps)
{
gtestTypesToRun = kReadWriteTests;
overwrite_global_params_for_read_write_test(&tTestMipMaps, &tDisableOffsets, &tNormalizedModeToUse, &tFilterModeToUse);
ret += test_image_set( device, test_read_image_formats, CL_MEM_OBJECT_IMAGE1D );
ret += test_image_set( device, test_write_image_formats, CL_MEM_OBJECT_IMAGE1D );
recover_global_params_from_read_write_test(tTestMipMaps, tDisableOffsets, tNormalizedModeToUse, tFilterModeToUse);
}
}
if (testMethods & k2D)
{
if (testTypesToRun & kReadTests)
{
gtestTypesToRun = kReadTests;
ret += test_image_set( device, test_read_image_formats, CL_MEM_OBJECT_IMAGE2D );
if (is_extension_available(device, "cl_khr_image2d_from_buffer"))
{
log_info("Testing read_image{f | i | ui} for 2D image from buffer\n");
// NOTE: for 2D image from buffer test, gTestSmallImages, gTestMaxImages, gTestRounding and gTestMipmaps must be false
if (gTestSmallImages == false && gTestMaxImages == false && gTestRounding == false && gTestMipmaps == false)
{
cl_mem_flags saved_gMemFlagsToUse = gMemFlagsToUse;
gTestImage2DFromBuffer = true;
// disable CL_MEM_USE_HOST_PTR for 1.2 extension but enable this for 2.0
gMemFlagsToUse = CL_MEM_COPY_HOST_PTR;
ret += test_image_set( device, test_read_image_formats, CL_MEM_OBJECT_IMAGE2D );
gTestImage2DFromBuffer = false;
gMemFlagsToUse = saved_gMemFlagsToUse;
}
}
}
if (testTypesToRun & kWriteTests)
{
gtestTypesToRun = kWriteTests;
ret += test_image_set( device, test_write_image_formats, CL_MEM_OBJECT_IMAGE2D );
if (is_extension_available(device, "cl_khr_image2d_from_buffer"))
{
log_info("Testing write_image{f | i | ui} for 2D image from buffer\n");
// NOTE: for 2D image from buffer test, gTestSmallImages, gTestMaxImages,gTestRounding and gTestMipmaps must be false
if (gTestSmallImages == false && gTestMaxImages == false && gTestRounding == false && gTestMipmaps == false)
{
bool saved_gEnablePitch = gEnablePitch;
cl_mem_flags saved_gMemFlagsToUse = gMemFlagsToUse;
gEnablePitch = true;
// disable CL_MEM_USE_HOST_PTR for 1.2 extension but enable this for 2.0
gMemFlagsToUse = CL_MEM_COPY_HOST_PTR;
gTestImage2DFromBuffer = true;
ret += test_image_set( device, test_write_image_formats, CL_MEM_OBJECT_IMAGE2D );
gTestImage2DFromBuffer = false;
gMemFlagsToUse = saved_gMemFlagsToUse;
gEnablePitch = saved_gEnablePitch;
}
}
}
if ((testTypesToRun & kReadWriteTests) && !gTestMipmaps)
{
gtestTypesToRun = kReadWriteTests;
overwrite_global_params_for_read_write_test(&tTestMipMaps, &tDisableOffsets, &tNormalizedModeToUse, &tFilterModeToUse);
ret += test_image_set( device, test_read_image_formats, CL_MEM_OBJECT_IMAGE2D );
if (is_extension_available(device, "cl_khr_image2d_from_buffer"))
{
log_info("Testing read_image{f | i | ui} for 2D image from buffer\n");
// NOTE: for 2D image from buffer test, gTestSmallImages, gTestMaxImages, gTestRounding and gTestMipmaps must be false
if (gTestSmallImages == false && gTestMaxImages == false && gTestRounding == false && gTestMipmaps == false)
{
cl_mem_flags saved_gMemFlagsToUse = gMemFlagsToUse;
gTestImage2DFromBuffer = true;
// disable CL_MEM_USE_HOST_PTR for 1.2 extension but enable this for 2.0
gMemFlagsToUse = CL_MEM_COPY_HOST_PTR;
ret += test_image_set( device, test_read_image_formats, CL_MEM_OBJECT_IMAGE2D );
gTestImage2DFromBuffer = false;
gMemFlagsToUse = saved_gMemFlagsToUse;
}
}
ret += test_image_set( device, test_write_image_formats, CL_MEM_OBJECT_IMAGE2D );
if (is_extension_available(device, "cl_khr_image2d_from_buffer"))
{
log_info("Testing write_image{f | i | ui} for 2D image from buffer\n");
// NOTE: for 2D image from buffer test, gTestSmallImages, gTestMaxImages,gTestRounding and gTestMipmaps must be false
if (gTestSmallImages == false && gTestMaxImages == false && gTestRounding == false && gTestMipmaps == false)
{
bool saved_gEnablePitch = gEnablePitch;
cl_mem_flags saved_gMemFlagsToUse = gMemFlagsToUse;
gEnablePitch = true;
// disable CL_MEM_USE_HOST_PTR for 1.2 extension but enable this for 2.0
gMemFlagsToUse = CL_MEM_COPY_HOST_PTR;
gTestImage2DFromBuffer = true;
ret += test_image_set( device, test_write_image_formats, CL_MEM_OBJECT_IMAGE2D );
gTestImage2DFromBuffer = false;
gMemFlagsToUse = saved_gMemFlagsToUse;
gEnablePitch = saved_gEnablePitch;
}
}
recover_global_params_from_read_write_test(tTestMipMaps, tDisableOffsets, tNormalizedModeToUse, tFilterModeToUse);
}
}
if (testMethods & k3D)
{
if (testTypesToRun & kReadTests)
{
gtestTypesToRun = kReadTests;
ret += test_image_set( device, test_read_image_formats, CL_MEM_OBJECT_IMAGE3D );
}
if (testTypesToRun & kWriteTests)
{
gtestTypesToRun = kWriteTests;
ret += test_image_set( device, test_write_image_formats, CL_MEM_OBJECT_IMAGE3D );
}
if ((testTypesToRun & kReadWriteTests) && !gTestMipmaps)
{
gtestTypesToRun = kReadWriteTests;
overwrite_global_params_for_read_write_test(&tTestMipMaps, &tDisableOffsets, &tNormalizedModeToUse, &tFilterModeToUse);
ret += test_image_set( device, test_read_image_formats, CL_MEM_OBJECT_IMAGE3D );
ret += test_image_set( device, test_write_image_formats, CL_MEM_OBJECT_IMAGE3D );
recover_global_params_from_read_write_test(tTestMipMaps, tDisableOffsets, tNormalizedModeToUse, tFilterModeToUse);
}
}
if (testMethods & k1DArray)
{
if (testTypesToRun & kReadTests)
{
gtestTypesToRun = kReadTests;
ret += test_image_set( device, test_read_image_formats, CL_MEM_OBJECT_IMAGE1D_ARRAY );
}
if (testTypesToRun & kWriteTests)
{
gtestTypesToRun = kWriteTests;
ret += test_image_set( device, test_write_image_formats, CL_MEM_OBJECT_IMAGE1D_ARRAY );
}
if ((testTypesToRun & kReadWriteTests) && !gTestMipmaps)
{
gtestTypesToRun = kReadWriteTests;
overwrite_global_params_for_read_write_test(&tTestMipMaps, &tDisableOffsets, &tNormalizedModeToUse, &tFilterModeToUse);
ret += test_image_set( device, test_read_image_formats, CL_MEM_OBJECT_IMAGE1D_ARRAY );
ret += test_image_set( device, test_write_image_formats, CL_MEM_OBJECT_IMAGE1D_ARRAY );
recover_global_params_from_read_write_test(tTestMipMaps, tDisableOffsets, tNormalizedModeToUse, tFilterModeToUse);
}
}
if (testMethods & k2DArray)
{
if (testTypesToRun & kReadTests)
{
gtestTypesToRun = kReadTests;
ret += test_image_set( device, test_read_image_formats, CL_MEM_OBJECT_IMAGE2D_ARRAY );
}
if (testTypesToRun & kWriteTests)
{
gtestTypesToRun = kWriteTests;
ret += test_image_set( device, test_write_image_formats, CL_MEM_OBJECT_IMAGE2D_ARRAY );
}
if ((testTypesToRun & kReadWriteTests) && !gTestMipmaps)
{
gtestTypesToRun = kReadWriteTests;
overwrite_global_params_for_read_write_test(&tTestMipMaps, &tDisableOffsets, &tNormalizedModeToUse, &tFilterModeToUse);
ret += test_image_set( device, test_read_image_formats, CL_MEM_OBJECT_IMAGE2D_ARRAY );
ret += test_image_set( device, test_write_image_formats, CL_MEM_OBJECT_IMAGE2D_ARRAY );
recover_global_params_from_read_write_test(tTestMipMaps, tDisableOffsets, tNormalizedModeToUse, tFilterModeToUse);
}
}
int ret = parseAndCallCommandLineTests( argCount, argList, NULL, num_fns, basefn_list, basefn_names, true, 0, 0 );
// Restore FP state before leaving
RestoreFPState(&oldMode);
@@ -639,21 +553,76 @@ int main(int argc, const char *argv[])
if (gTestFailure == 0) {
if (gTestCount > 1)
log_info("PASSED %d of %d tests.\n", gTestCount, gTestCount);
log_info("PASSED %d of %d sub-tests.\n", gTestCount, gTestCount);
else
log_info("PASSED test.\n");
log_info("PASSED sub-test.\n");
} else if (gTestFailure > 0) {
if (gTestCount > 1)
log_error("FAILED %d of %d tests.\n", gTestFailure, gTestCount);
log_error("FAILED %d of %d sub-tests.\n", gTestFailure, gTestCount);
else
log_error("FAILED test.\n");
log_error("FAILED sub-test.\n");
}
// Clean up
free(argList);
test_finish();
if (gTestFailure > 0)
return gTestFailure;
return ret;
}
static 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( "\n" );
log_info( "\tThe following flags specify what kinds of operations to test. They can be combined; if none are specified, all are tested:\n" );
log_info( "\t\tread - Tests reading from an image\n" );
log_info( "\t\twrite - Tests writing to an image (can be specified with read to run both; default is both)\n" );
log_info( "\n" );
log_info( "\tThe following flags specify the types to test. They can be combined; if none are specified, all are tested:\n" );
log_info( "\t\tint - Test integer I/O (read_imagei, write_imagei)\n" );
log_info( "\t\tuint - Test unsigned integer I/O (read_imageui, write_imageui)\n" );
log_info( "\t\tfloat - Test float I/O (read_imagef, write_imagef)\n" );
log_info( "\n" );
log_info( "\tCL_FILTER_LINEAR - Only tests formats with CL_FILTER_LINEAR filtering\n" );
log_info( "\tCL_FILTER_NEAREST - Only tests formats with CL_FILTER_NEAREST filtering\n" );
log_info( "\n" );
log_info( "\tNORMALIZED - Only tests formats with NORMALIZED coordinates\n" );
log_info( "\tUNNORMALIZED - Only tests formats with UNNORMALIZED coordinates\n" );
log_info( "\n" );
log_info( "\tCL_ADDRESS_CLAMP - Only tests formats with CL_ADDRESS_CLAMP addressing\n" );
log_info( "\tCL_ADDRESS_CLAMP_TO_EDGE - Only tests formats with CL_ADDRESS_CLAMP_TO_EDGE addressing\n" );
log_info( "\tCL_ADDRESS_REPEAT - Only tests formats with CL_ADDRESS_REPEAT addressing\n" );
log_info( "\tCL_ADDRESS_MIRRORED_REPEAT - Only tests formats with CL_ADDRESS_MIRRORED_REPEAT addressing\n" );
log_info( "\n" );
log_info( "You may also use appropriate CL_ channel type and ordering constants.\n" );
log_info( "\n" );
log_info( "\tlocal_samplers - Use samplers declared in the kernel functions instead of passed in as arguments\n" );
log_info( "\n" );
log_info( "\tThe following specify to use the specific flag to allocate images to use in the tests:\n" );
log_info( "\t\tCL_MEM_COPY_HOST_PTR\n" );
log_info( "\t\tCL_MEM_USE_HOST_PTR (default)\n" );
log_info( "\t\tCL_MEM_ALLOC_HOST_PTR\n" );
log_info( "\t\tNO_HOST_PTR - Specifies to use none of the above flags\n" );
log_info( "\n" );
log_info( "\tThe following modify the types of images tested:\n" );
log_info( "\t\tsmall_images - Runs every format through a loop of widths 1-13 and heights 1-9, instead of random sizes\n" );
log_info( "\t\tmax_images - Runs every format through a set of size combinations with the max values, max values - 1, and max values / 128\n" );
log_info( "\t\trounding - Runs every format through a single image filled with every possible value for that image format, to verify rounding works properly\n" );
log_info( "\n" );
log_info( "\tno_offsets - Disables offsets when testing reads (can be good for diagnosing address repeating/clamping problems)\n" );
log_info( "\tdebug_trace - Enables additional debug info logging\n" );
log_info( "\textra_validate - Enables additional validation failure debug information\n" );
log_info( "\tuse_pitches - Enables row and slice pitches\n" );
log_info( "\ttest_mipmaps - Enables mipmapped images\n");
log_info( "\n" );
log_info( "Test names:\n" );
for( int i = 0; i < num_fns; i++ )
{
log_info( "\t%s\n", basefn_names[i] );
}
}