test_conformance/images/samplerlessReads/test_read_1D_array.cpp - external/github.com/KhronosGroup/OpenCL-CTS - Git at Google

 //
 // 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 <float.h>

 #if defined( __APPLE__ )
     #include <signal.h>
     #include <sys/signal.h>
     #include <setjmp.h>
 #endif

 extern bool gDeviceLt20;
 extern bool gTestReadWrite;

 const char *read1DArrayKernelSourcePattern =
 "__kernel void sample_kernel( read_only image1d_array_t input, sampler_t sampler, __global int *results )\n"
 "{\n"
 "   int tidX = get_global_id(0), tidY = get_global_id(1);\n"
 "   int offset = tidY*get_image_width(input) + tidX;\n"
 "   int2 coords = (int2)(tidX, tidY);\n"
 "   %s clr = read_image%s( input, coords );\n"
 "   int4 test = (clr != read_image%s( input, sampler, coords ));\n"
 "   if ( test.x || test.y || test.z || test.w )\n"
 "      results[offset] = -1;\n"
 "   else\n"
 "      results[offset] = 0;\n"
 "}";

 const char *read_write1DArrayKernelSourcePattern =
 "__kernel void sample_kernel( read_only image1d_array_t read_only_image, read_write image1d_array_t read_write_image, sampler_t sampler, __global int *results )\n"
 "{\n"
 "   int tidX = get_global_id(0), tidY = get_global_id(1);\n"
 "   int offset = tidY*get_image_width(read_only_image) + tidX;\n"
 "   int2 coords = (int2)(tidX, tidY);\n"
 "   %s clr = read_image%s( read_only_image, sampler, coords );\n"
 "   write_image%s(read_write_image, coords, clr);\n"
 "   atomic_work_item_fence(CLK_IMAGE_MEM_FENCE, memory_order_acq_rel, memory_scope_work_item);\n"
 "   int4 test = (clr != read_image%s( read_write_image, coords ));\n"
 "   if ( test.x || test.y || test.z || test.w )\n"
 "      results[offset] = -1;\n"
 "   else\n"
 "      results[offset] = 0;\n"
 "}";

 int test_read_image_1D_array( cl_context context, cl_command_queue queue, cl_kernel kernel,
                         image_descriptor *imageInfo, image_sampler_data *imageSampler,
                         ExplicitType outputType, MTdata d )
 {
     int error;
     size_t threads[2];
     cl_sampler actualSampler;

     // generate_random_image_data allocates with malloc, so we use a MallocDataBuffer here
     BufferOwningPtr<char> imageValues;
     generate_random_image_data( imageInfo, imageValues, d );

     if ( gDebugTrace )
         log_info( " - Creating image %d by %d...\n", (int)imageInfo->width, (int)imageInfo->arraySize );

     // Construct testing sources
     cl_mem read_only_image, read_write_image;
     cl_image_desc image_desc;

     memset(&image_desc, 0x0, sizeof(cl_image_desc));
     image_desc.image_type = CL_MEM_OBJECT_IMAGE1D_ARRAY;
     image_desc.image_width = imageInfo->width;
     image_desc.image_height = imageInfo->height;
     image_desc.image_array_size = imageInfo->arraySize;
     image_desc.image_row_pitch = ( gEnablePitch ? imageInfo->rowPitch : 0 );
     image_desc.image_slice_pitch = 0;
     image_desc.num_mip_levels = 0;
     read_only_image = clCreateImage( context, CL_MEM_READ_ONLY | CL_MEM_COPY_HOST_PTR, imageInfo->format,
                                        &image_desc, imageValues, &error );
     if ( error != CL_SUCCESS )
     {
         log_error( "ERROR: Unable to create read_only 1D image array of size %d x %d pitch %d (%s)\n", (int)imageInfo->width, (int)imageInfo->arraySize, (int)imageInfo->rowPitch, IGetErrorString( error ) );
         return error;
     }

     if(gTestReadWrite)
     {
         read_write_image = clCreateImage(context,
                                         CL_MEM_READ_WRITE,
                                         imageInfo->format,
                                         &image_desc,
                                         NULL,
                                         &error );
         if ( error != CL_SUCCESS )
         {
             log_error( "ERROR: Unable to create read_write 1D image array of size %d x %d pitch %d (%s)\n", (int)imageInfo->width, (int)imageInfo->arraySize, (int)imageInfo->rowPitch, IGetErrorString( error ) );
             return error;
         }
     }
     if ( gDebugTrace )
         log_info( " - Creating kernel arguments...\n" );

     // Create sampler to use
     actualSampler = clCreateSampler( context, CL_FALSE, CL_ADDRESS_NONE, CL_FILTER_NEAREST, &error );
     test_error( error, "Unable to create image sampler" );

     // Create results buffer
     cl_mem results = clCreateBuffer( context, 0, imageInfo->width * imageInfo->arraySize * sizeof(cl_int), NULL, &error);
     test_error( error, "Unable to create results buffer" );

     size_t resultValuesSize = imageInfo->width * imageInfo->arraySize * sizeof(cl_int);
     BufferOwningPtr<int> resultValues(malloc( resultValuesSize ));
     memset( resultValues, 0xff, resultValuesSize );
     clEnqueueWriteBuffer( queue, results, CL_TRUE, 0, resultValuesSize, resultValues, 0, NULL, NULL );

     // Set arguments
     int idx = 0;
     error = clSetKernelArg( kernel, idx++, sizeof( cl_mem ), &read_only_image );
     test_error( error, "Unable to set kernel arguments" );
     if(gTestReadWrite)
     {
         error = clSetKernelArg( kernel, idx++, sizeof( cl_mem ), &read_write_image );
         test_error( error, "Unable to set kernel arguments" );
     }
     error = clSetKernelArg( kernel, idx++, sizeof( cl_sampler ), &actualSampler );
     test_error( error, "Unable to set kernel arguments" );
     error = clSetKernelArg( kernel, idx++, sizeof( cl_mem ), &results );
     test_error( error, "Unable to set kernel arguments" );

     // Run the kernel
     threads[0] = (size_t)imageInfo->width;
     threads[1] = (size_t)imageInfo->arraySize;

     error = clEnqueueNDRangeKernel( queue, kernel, 2, NULL, threads, NULL, 0, NULL, NULL );
     test_error( error, "Unable to run kernel" );

     if ( gDebugTrace )
         log_info( "    reading results, %ld kbytes\n", (unsigned long)( imageInfo->width * imageInfo->arraySize * sizeof(cl_int) / 1024 ) );

     error = clEnqueueReadBuffer( queue, results, CL_TRUE, 0, resultValuesSize, resultValues, 0, NULL, NULL );
     test_error( error, "Unable to read results from kernel" );
     if ( gDebugTrace )
         log_info( "    results read\n" );

     // Check for non-zero comps
     bool allZeroes = true;
     size_t ic;
     for ( ic = 0; ic < imageInfo->width * imageInfo->arraySize; ++ic )
     {
         if ( resultValues[ic] ) {
             allZeroes = false;
             break;
         }
     }
     if ( !allZeroes )
     {
         log_error( " Sampler-less reads differ from reads with sampler at index %lu.\n", ic );
         return -1;
     }

     clReleaseSampler(actualSampler);
     clReleaseMemObject(results);
     clReleaseMemObject(read_only_image);

     if(gTestReadWrite)
     {
         clReleaseMemObject(read_write_image);
     }
     return 0;
 }

 int test_read_image_set_1D_array( cl_device_id device, cl_context context, cl_command_queue queue, cl_image_format *format, image_sampler_data *imageSampler,
                             ExplicitType outputType )
 {
     char programSrc[10240];
     const char *ptr;
     const char *readFormat;
     const char *dataType;
     clProgramWrapper program;
     clKernelWrapper kernel;
     RandomSeed seed( gRandomSeed );
     int error;

     // Get our operating params
     size_t maxWidth, maxArraySize;
     cl_ulong maxAllocSize, memSize;
     image_descriptor imageInfo = { 0 };
     size_t pixelSize;

     if (gTestReadWrite && checkForReadWriteImageSupport(device))
     {
         return TEST_SKIPPED_ITSELF;
     }

     imageInfo.format = format;
     imageInfo.height = imageInfo.depth = 0;
     imageInfo.type = CL_MEM_OBJECT_IMAGE1D_ARRAY;
     pixelSize = get_pixel_size( imageInfo.format );

     error = clGetDeviceInfo( device, CL_DEVICE_IMAGE2D_MAX_WIDTH, sizeof( maxWidth ), &maxWidth, NULL );
     error |= clGetDeviceInfo( device, CL_DEVICE_IMAGE_MAX_ARRAY_SIZE, sizeof( maxArraySize ), &maxArraySize, NULL );
     error |= clGetDeviceInfo( device, CL_DEVICE_MAX_MEM_ALLOC_SIZE, sizeof( maxAllocSize ), &maxAllocSize, NULL );
     error |= clGetDeviceInfo( device, CL_DEVICE_GLOBAL_MEM_SIZE, sizeof( memSize ), &memSize, NULL );
     test_error( error, "Unable to get max image 2D size from device" );

     if (memSize > (cl_ulong)SIZE_MAX) {
       memSize = (cl_ulong)SIZE_MAX;
     }

     // Determine types
     if ( outputType == kInt )
     {
         readFormat = "i";
         dataType = "int4";
     }
     else if ( outputType == kUInt )
     {
         readFormat = "ui";
         dataType = "uint4";
     }
     else // kFloat
     {
         readFormat = "f";
         dataType = "float4";
     }

     if(gTestReadWrite)
     {
         sprintf( programSrc,
                  read_write1DArrayKernelSourcePattern,
                  dataType,
                  readFormat,
                  readFormat,
                  readFormat);
     }
     else
     {
         sprintf( programSrc,
                  read1DArrayKernelSourcePattern,
                  dataType,
                  readFormat,
                  readFormat );
     }


     ptr = programSrc;
     error = create_single_kernel_helper_with_build_options( context, &program, &kernel, 1, &ptr, "sample_kernel", gDeviceLt20 ? "" : "-cl-std=CL2.0" );
     test_error( error, "Unable to create testing kernel" );

     if ( gTestSmallImages )
     {
         for ( imageInfo.width = 1; imageInfo.width < 13; imageInfo.width++ )
         {
             imageInfo.rowPitch = imageInfo.width * pixelSize;
             imageInfo.slicePitch = imageInfo.rowPitch;
             for ( imageInfo.arraySize = 2; imageInfo.arraySize < 9; imageInfo.arraySize++ )
             {
                 if ( gDebugTrace )
                     log_info( "   at size %d,%d\n", (int)imageInfo.width, (int)imageInfo.arraySize );

                 int retCode = test_read_image_1D_array( context, queue, kernel, &imageInfo, imageSampler, outputType, seed );
                 if ( retCode )
                     return retCode;
             }
         }
     }
     else if ( gTestMaxImages )
     {
         // Try a specific set of maximum sizes
         size_t numbeOfSizes;
         size_t sizes[100][3];

         get_max_sizes(&numbeOfSizes, 100, sizes, maxWidth, 1, 1, maxArraySize, maxAllocSize, memSize, CL_MEM_OBJECT_IMAGE1D_ARRAY, imageInfo.format);

         for ( size_t idx = 0; idx < numbeOfSizes; idx++ )
         {
             imageInfo.width = sizes[ idx ][ 0 ];
             imageInfo.arraySize = sizes[ idx ][ 2 ];
             imageInfo.rowPitch = imageInfo.width * pixelSize;
             imageInfo.slicePitch = imageInfo.rowPitch;
             log_info("Testing %d x %d\n", (int)sizes[ idx ][ 0 ], (int)sizes[ idx ][ 2 ]);
             if ( gDebugTrace )
                 log_info( "   at max size %d,%d\n", (int)sizes[ idx ][ 0 ], (int)sizes[ idx ][ 2 ] );
             int retCode = test_read_image_1D_array( context, queue, kernel, &imageInfo, imageSampler, outputType, seed );
             if ( retCode )
                 return retCode;
         }
     }
     else
     {
         for ( int i = 0; i < NUM_IMAGE_ITERATIONS; i++ )
         {
             cl_ulong size;
             // Loop until we get a size that a) will fit in the max alloc size and b) that an allocation of that
             // image, the result array, plus offset arrays, will fit in the global ram space
             do
             {
                 imageInfo.width = (size_t)random_log_in_range( 16, (int)maxWidth / 32, seed );
                 imageInfo.arraySize = (size_t)random_log_in_range( 16, (int)maxArraySize / 32, seed );

                 imageInfo.rowPitch = imageInfo.width * pixelSize;
                 if ( gEnablePitch )
                 {
                     size_t extraWidth = (int)random_log_in_range( 0, 64, seed );
                     imageInfo.rowPitch += extraWidth * pixelSize;
                 }

                 imageInfo.slicePitch = imageInfo.rowPitch;

                 size = (size_t)imageInfo.rowPitch * (size_t)imageInfo.arraySize * 4;
             } while (  size > maxAllocSize || ( size * 3 ) > memSize );

             if ( gDebugTrace )
                 log_info( "   at size %d,%d (row pitch %d) out of %d,%d\n", (int)imageInfo.width, (int)imageInfo.arraySize, (int)imageInfo.rowPitch, (int)maxWidth, (int)maxArraySize );
             int retCode = test_read_image_1D_array( context, queue, kernel, &imageInfo, imageSampler, outputType, seed );
             if ( retCode )
                 return retCode;
         }
     }

     return 0;
 }
	//
	// 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 <float.h>

	#if defined( __APPLE__ )
	#include <signal.h>
	#include <sys/signal.h>
	#include <setjmp.h>
	#endif

	extern bool gDeviceLt20;
	extern bool gTestReadWrite;

	const char *read1DArrayKernelSourcePattern =
	"__kernel void sample_kernel( read_only image1d_array_t input, sampler_t sampler, __global int *results )\n"
	"{\n"
	" int tidX = get_global_id(0), tidY = get_global_id(1);\n"
	" int offset = tidY*get_image_width(input) + tidX;\n"
	" int2 coords = (int2)(tidX, tidY);\n"
	" %s clr = read_image%s( input, coords );\n"
	" int4 test = (clr != read_image%s( input, sampler, coords ));\n"
	" if ( test.x \|\| test.y \|\| test.z \|\| test.w )\n"
	" results[offset] = -1;\n"
	" else\n"
	" results[offset] = 0;\n"
	"}";

	const char *read_write1DArrayKernelSourcePattern =
	"__kernel void sample_kernel( read_only image1d_array_t read_only_image, read_write image1d_array_t read_write_image, sampler_t sampler, __global int *results )\n"
	"{\n"
	" int tidX = get_global_id(0), tidY = get_global_id(1);\n"
	" int offset = tidY*get_image_width(read_only_image) + tidX;\n"
	" int2 coords = (int2)(tidX, tidY);\n"
	" %s clr = read_image%s( read_only_image, sampler, coords );\n"
	" write_image%s(read_write_image, coords, clr);\n"
	" atomic_work_item_fence(CLK_IMAGE_MEM_FENCE, memory_order_acq_rel, memory_scope_work_item);\n"
	" int4 test = (clr != read_image%s( read_write_image, coords ));\n"
	" if ( test.x \|\| test.y \|\| test.z \|\| test.w )\n"
	" results[offset] = -1;\n"
	" else\n"
	" results[offset] = 0;\n"
	"}";

	int test_read_image_1D_array( cl_context context, cl_command_queue queue, cl_kernel kernel,
	image_descriptor imageInfo, image_sampler_data imageSampler,
	ExplicitType outputType, MTdata d )
	{
	int error;
	size_t threads[2];
	cl_sampler actualSampler;

	// generate_random_image_data allocates with malloc, so we use a MallocDataBuffer here
	BufferOwningPtr<char> imageValues;
	generate_random_image_data( imageInfo, imageValues, d );

	if ( gDebugTrace )
	log_info( " - Creating image %d by %d...\n", (int)imageInfo->width, (int)imageInfo->arraySize );

	// Construct testing sources
	cl_mem read_only_image, read_write_image;
	cl_image_desc image_desc;

	memset(&image_desc, 0x0, sizeof(cl_image_desc));
	image_desc.image_type = CL_MEM_OBJECT_IMAGE1D_ARRAY;
	image_desc.image_width = imageInfo->width;
	image_desc.image_height = imageInfo->height;
	image_desc.image_array_size = imageInfo->arraySize;
	image_desc.image_row_pitch = ( gEnablePitch ? imageInfo->rowPitch : 0 );
	image_desc.image_slice_pitch = 0;
	image_desc.num_mip_levels = 0;
	read_only_image = clCreateImage( context, CL_MEM_READ_ONLY \| CL_MEM_COPY_HOST_PTR, imageInfo->format,
	&image_desc, imageValues, &error );
	if ( error != CL_SUCCESS )
	{
	log_error( "ERROR: Unable to create read_only 1D image array of size %d x %d pitch %d (%s)\n", (int)imageInfo->width, (int)imageInfo->arraySize, (int)imageInfo->rowPitch, IGetErrorString( error ) );
	return error;
	}

	if(gTestReadWrite)
	{
	read_write_image = clCreateImage(context,
	CL_MEM_READ_WRITE,
	imageInfo->format,
	&image_desc,
	NULL,
	&error );
	if ( error != CL_SUCCESS )
	{
	log_error( "ERROR: Unable to create read_write 1D image array of size %d x %d pitch %d (%s)\n", (int)imageInfo->width, (int)imageInfo->arraySize, (int)imageInfo->rowPitch, IGetErrorString( error ) );
	return error;
	}
	}
	if ( gDebugTrace )
	log_info( " - Creating kernel arguments...\n" );

	// Create sampler to use
	actualSampler = clCreateSampler( context, CL_FALSE, CL_ADDRESS_NONE, CL_FILTER_NEAREST, &error );
	test_error( error, "Unable to create image sampler" );

	// Create results buffer
	cl_mem results = clCreateBuffer( context, 0, imageInfo->width * imageInfo->arraySize * sizeof(cl_int), NULL, &error);
	test_error( error, "Unable to create results buffer" );

	size_t resultValuesSize = imageInfo->width * imageInfo->arraySize * sizeof(cl_int);
	BufferOwningPtr<int> resultValues(malloc( resultValuesSize ));
	memset( resultValues, 0xff, resultValuesSize );
	clEnqueueWriteBuffer( queue, results, CL_TRUE, 0, resultValuesSize, resultValues, 0, NULL, NULL );

	// Set arguments
	int idx = 0;
	error = clSetKernelArg( kernel, idx++, sizeof( cl_mem ), &read_only_image );
	test_error( error, "Unable to set kernel arguments" );
	if(gTestReadWrite)
	{
	error = clSetKernelArg( kernel, idx++, sizeof( cl_mem ), &read_write_image );
	test_error( error, "Unable to set kernel arguments" );
	}
	error = clSetKernelArg( kernel, idx++, sizeof( cl_sampler ), &actualSampler );
	test_error( error, "Unable to set kernel arguments" );
	error = clSetKernelArg( kernel, idx++, sizeof( cl_mem ), &results );
	test_error( error, "Unable to set kernel arguments" );

	// Run the kernel
	threads[0] = (size_t)imageInfo->width;
	threads[1] = (size_t)imageInfo->arraySize;

	error = clEnqueueNDRangeKernel( queue, kernel, 2, NULL, threads, NULL, 0, NULL, NULL );
	test_error( error, "Unable to run kernel" );

	if ( gDebugTrace )
	log_info( " reading results, %ld kbytes\n", (unsigned long)( imageInfo->width * imageInfo->arraySize * sizeof(cl_int) / 1024 ) );

	error = clEnqueueReadBuffer( queue, results, CL_TRUE, 0, resultValuesSize, resultValues, 0, NULL, NULL );
	test_error( error, "Unable to read results from kernel" );
	if ( gDebugTrace )
	log_info( " results read\n" );

	// Check for non-zero comps
	bool allZeroes = true;
	size_t ic;
	for ( ic = 0; ic < imageInfo->width * imageInfo->arraySize; ++ic )
	{
	if ( resultValues[ic] ) {
	allZeroes = false;
	break;
	}
	}
	if ( !allZeroes )
	{
	log_error( " Sampler-less reads differ from reads with sampler at index %lu.\n", ic );
	return -1;
	}

	clReleaseSampler(actualSampler);
	clReleaseMemObject(results);
	clReleaseMemObject(read_only_image);

	if(gTestReadWrite)
	{
	clReleaseMemObject(read_write_image);
	}
	return 0;
	}

	int test_read_image_set_1D_array( cl_device_id device, cl_context context, cl_command_queue queue, cl_image_format format, image_sampler_data imageSampler,
	ExplicitType outputType )
	{
	char programSrc[10240];
	const char *ptr;
	const char *readFormat;
	const char *dataType;
	clProgramWrapper program;
	clKernelWrapper kernel;
	RandomSeed seed( gRandomSeed );
	int error;

	// Get our operating params
	size_t maxWidth, maxArraySize;
	cl_ulong maxAllocSize, memSize;
	image_descriptor imageInfo = { 0 };
	size_t pixelSize;

	if (gTestReadWrite && checkForReadWriteImageSupport(device))
	{
	return TEST_SKIPPED_ITSELF;
	}

	imageInfo.format = format;
	imageInfo.height = imageInfo.depth = 0;
	imageInfo.type = CL_MEM_OBJECT_IMAGE1D_ARRAY;
	pixelSize = get_pixel_size( imageInfo.format );

	error = clGetDeviceInfo( device, CL_DEVICE_IMAGE2D_MAX_WIDTH, sizeof( maxWidth ), &maxWidth, NULL );
	error \|= clGetDeviceInfo( device, CL_DEVICE_IMAGE_MAX_ARRAY_SIZE, sizeof( maxArraySize ), &maxArraySize, NULL );
	error \|= clGetDeviceInfo( device, CL_DEVICE_MAX_MEM_ALLOC_SIZE, sizeof( maxAllocSize ), &maxAllocSize, NULL );
	error \|= clGetDeviceInfo( device, CL_DEVICE_GLOBAL_MEM_SIZE, sizeof( memSize ), &memSize, NULL );
	test_error( error, "Unable to get max image 2D size from device" );

	if (memSize > (cl_ulong)SIZE_MAX) {
	memSize = (cl_ulong)SIZE_MAX;
	}

	// Determine types
	if ( outputType == kInt )
	{
	readFormat = "i";
	dataType = "int4";
	}
	else if ( outputType == kUInt )
	{
	readFormat = "ui";
	dataType = "uint4";
	}
	else // kFloat
	{
	readFormat = "f";
	dataType = "float4";
	}

	if(gTestReadWrite)
	{
	sprintf( programSrc,
	read_write1DArrayKernelSourcePattern,
	dataType,
	readFormat,
	readFormat,
	readFormat);
	}
	else
	{
	sprintf( programSrc,
	read1DArrayKernelSourcePattern,
	dataType,
	readFormat,
	readFormat );
	}


	ptr = programSrc;
	error = create_single_kernel_helper_with_build_options( context, &program, &kernel, 1, &ptr, "sample_kernel", gDeviceLt20 ? "" : "-cl-std=CL2.0" );
	test_error( error, "Unable to create testing kernel" );

	if ( gTestSmallImages )
	{
	for ( imageInfo.width = 1; imageInfo.width < 13; imageInfo.width++ )
	{
	imageInfo.rowPitch = imageInfo.width * pixelSize;
	imageInfo.slicePitch = imageInfo.rowPitch;
	for ( imageInfo.arraySize = 2; imageInfo.arraySize < 9; imageInfo.arraySize++ )
	{
	if ( gDebugTrace )
	log_info( " at size %d,%d\n", (int)imageInfo.width, (int)imageInfo.arraySize );

	int retCode = test_read_image_1D_array( context, queue, kernel, &imageInfo, imageSampler, outputType, seed );
	if ( retCode )
	return retCode;
	}
	}
	}
	else if ( gTestMaxImages )
	{
	// Try a specific set of maximum sizes
	size_t numbeOfSizes;
	size_t sizes[100][3];

	get_max_sizes(&numbeOfSizes, 100, sizes, maxWidth, 1, 1, maxArraySize, maxAllocSize, memSize, CL_MEM_OBJECT_IMAGE1D_ARRAY, imageInfo.format);

	for ( size_t idx = 0; idx < numbeOfSizes; idx++ )
	{
	imageInfo.width = sizes[ idx ][ 0 ];
	imageInfo.arraySize = sizes[ idx ][ 2 ];
	imageInfo.rowPitch = imageInfo.width * pixelSize;
	imageInfo.slicePitch = imageInfo.rowPitch;
	log_info("Testing %d x %d\n", (int)sizes[ idx ][ 0 ], (int)sizes[ idx ][ 2 ]);
	if ( gDebugTrace )
	log_info( " at max size %d,%d\n", (int)sizes[ idx ][ 0 ], (int)sizes[ idx ][ 2 ] );
	int retCode = test_read_image_1D_array( context, queue, kernel, &imageInfo, imageSampler, outputType, seed );
	if ( retCode )
	return retCode;
	}
	}
	else
	{
	for ( int i = 0; i < NUM_IMAGE_ITERATIONS; i++ )
	{
	cl_ulong size;
	// Loop until we get a size that a) will fit in the max alloc size and b) that an allocation of that
	// image, the result array, plus offset arrays, will fit in the global ram space
	do
	{
	imageInfo.width = (size_t)random_log_in_range( 16, (int)maxWidth / 32, seed );
	imageInfo.arraySize = (size_t)random_log_in_range( 16, (int)maxArraySize / 32, seed );

	imageInfo.rowPitch = imageInfo.width * pixelSize;
	if ( gEnablePitch )
	{
	size_t extraWidth = (int)random_log_in_range( 0, 64, seed );
	imageInfo.rowPitch += extraWidth * pixelSize;
	}

	imageInfo.slicePitch = imageInfo.rowPitch;

	size = (size_t)imageInfo.rowPitch * (size_t)imageInfo.arraySize * 4;
	} while ( size > maxAllocSize \|\| ( size * 3 ) > memSize );

	if ( gDebugTrace )
	log_info( " at size %d,%d (row pitch %d) out of %d,%d\n", (int)imageInfo.width, (int)imageInfo.arraySize, (int)imageInfo.rowPitch, (int)maxWidth, (int)maxArraySize );
	int retCode = test_read_image_1D_array( context, queue, kernel, &imageInfo, imageSampler, outputType, seed );
	if ( retCode )
	return retCode;
	}
	}

	return 0;
	}