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OpenCL-CTS/test_conformance/images/clCopyImage/test_copy_generic.cpp
John Kesapides 4984196bcb Fix CopyImage verification for 1D/2D images (#1791) 
The verification uses a common function with nested loops to verify
the result of the copy operation. The upper loop limits thirdDim and
SecondDim should be set according to the image type under test. Previously
for 1D/2D they were set from dstImageInfo->depth and dstImageInfo->height.
The issue is that the depth and height are set to 0 when unused. This
caused the verification loop to be skipped.

Signed-off-by: John Kesapides <john.kesapides@arm.com>
2023-10-03 09:30:46 -07:00

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//
// 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"
static void CL_CALLBACK free_pitch_buffer( cl_mem image, void *buf )
{
free( buf );
}
cl_mem create_image( cl_context context, cl_command_queue queue, BufferOwningPtr<char>& data, image_descriptor *imageInfo, int *error )
{
cl_mem img;
cl_image_desc imageDesc;
cl_mem_flags mem_flags = CL_MEM_READ_ONLY;
void *host_ptr = NULL;
memset(&imageDesc, 0x0, sizeof(cl_image_desc));
imageDesc.image_type = imageInfo->type;
imageDesc.image_width = imageInfo->width;
imageDesc.image_height = imageInfo->height;
imageDesc.image_depth = imageInfo->depth;
imageDesc.image_array_size = imageInfo->arraySize;
imageDesc.image_row_pitch = gEnablePitch ? imageInfo->rowPitch : 0;
imageDesc.image_slice_pitch = gEnablePitch ? imageInfo->slicePitch : 0;
imageDesc.num_mip_levels = gTestMipmaps ? imageInfo->num_mip_levels : 0;
switch (imageInfo->type)
{
case CL_MEM_OBJECT_IMAGE1D:
if ( gDebugTrace )
log_info( " - Creating 1D image %d ...\n", (int)imageInfo->width );
if ( gEnablePitch )
host_ptr = malloc( imageInfo->rowPitch );
break;
case CL_MEM_OBJECT_IMAGE2D:
if ( gDebugTrace )
log_info( " - Creating 2D image %d by %d ...\n", (int)imageInfo->width, (int)imageInfo->height );
if ( gEnablePitch )
host_ptr = malloc( imageInfo->height * imageInfo->rowPitch );
break;
case CL_MEM_OBJECT_IMAGE3D:
if ( gDebugTrace )
log_info( " - Creating 3D image %d by %d by %d...\n", (int)imageInfo->width, (int)imageInfo->height, (int)imageInfo->depth );
if ( gEnablePitch )
host_ptr = malloc( imageInfo->depth * imageInfo->slicePitch );
break;
case CL_MEM_OBJECT_IMAGE1D_ARRAY:
if ( gDebugTrace )
log_info( " - Creating 1D image array %d by %d...\n", (int)imageInfo->width, (int)imageInfo->arraySize );
if ( gEnablePitch )
host_ptr = malloc( imageInfo->arraySize * imageInfo->slicePitch );
break;
case CL_MEM_OBJECT_IMAGE2D_ARRAY:
if ( gDebugTrace )
log_info( " - Creating 2D image array %d by %d by %d...\n", (int)imageInfo->width, (int)imageInfo->height, (int)imageInfo->arraySize );
if ( gEnablePitch )
host_ptr = malloc( imageInfo->arraySize * imageInfo->slicePitch );
break;
}
if ( gDebugTrace && gTestMipmaps )
log_info(" - with %llu mip levels\n", (unsigned long long) imageInfo->num_mip_levels);
if (gEnablePitch)
{
if ( NULL == host_ptr )
{
log_error( "ERROR: Unable to create backing store for pitched 3D image. %ld bytes\n", imageInfo->depth * imageInfo->slicePitch );
return NULL;
}
mem_flags = CL_MEM_READ_ONLY | CL_MEM_USE_HOST_PTR;
}
img = clCreateImage(context, mem_flags, imageInfo->format, &imageDesc, host_ptr, error);
if (gEnablePitch)
{
if ( *error == CL_SUCCESS )
{
int callbackError = clSetMemObjectDestructorCallback( img, free_pitch_buffer, host_ptr );
if ( CL_SUCCESS != callbackError )
{
free( host_ptr );
log_error( "ERROR: Unable to attach destructor callback to pitched 3D image. Err: %d\n", callbackError );
clReleaseMemObject( img );
return NULL;
}
}
else
free(host_ptr);
}
if ( *error != CL_SUCCESS )
{
long long unsigned imageSize = get_image_size_mb(imageInfo);
switch (imageInfo->type)
{
case CL_MEM_OBJECT_IMAGE1D:
log_error("ERROR: Unable to create 1D image of size %d (%llu "
"MB):(%s)",
(int)imageInfo->width, imageSize,
IGetErrorString(*error));
break;
case CL_MEM_OBJECT_IMAGE2D:
log_error("ERROR: Unable to create 2D image of size %d x %d "
"(%llu MB):(%s)",
(int)imageInfo->width, (int)imageInfo->height,
imageSize, IGetErrorString(*error));
break;
case CL_MEM_OBJECT_IMAGE3D:
log_error("ERROR: Unable to create 3D image of size %d x %d x "
"%d (%llu MB):(%s)",
(int)imageInfo->width, (int)imageInfo->height,
(int)imageInfo->depth, imageSize,
IGetErrorString(*error));
break;
case CL_MEM_OBJECT_IMAGE1D_ARRAY:
log_error("ERROR: Unable to create 1D image array of size %d x "
"%d (%llu MB):(%s)",
(int)imageInfo->width, (int)imageInfo->arraySize,
imageSize, IGetErrorString(*error));
break;
break;
case CL_MEM_OBJECT_IMAGE2D_ARRAY:
log_error("ERROR: Unable to create 2D image array of size %d x "
"%d x %d (%llu MB):(%s)",
(int)imageInfo->width, (int)imageInfo->height,
(int)imageInfo->arraySize, imageSize,
IGetErrorString(*error));
break;
}
log_error("ERROR: and %llu mip levels\n", (unsigned long long) imageInfo->num_mip_levels);
return NULL;
}
// Copy the specified data to the image via a Map operation.
size_t mappedRow, mappedSlice;
size_t width = imageInfo->width;
size_t height = 1;
size_t depth = 1;
size_t row_pitch_lod, slice_pitch_lod;
row_pitch_lod = imageInfo->rowPitch;
slice_pitch_lod = imageInfo->slicePitch;
switch (imageInfo->type)
{
case CL_MEM_OBJECT_IMAGE1D_ARRAY:
height = imageInfo->arraySize;
depth = 1;
break;
case CL_MEM_OBJECT_IMAGE1D:
height = depth = 1;
break;
case CL_MEM_OBJECT_IMAGE2D:
height = imageInfo->height;
depth = 1;
break;
case CL_MEM_OBJECT_IMAGE2D_ARRAY:
height = imageInfo->height;
depth = imageInfo->arraySize;
break;
case CL_MEM_OBJECT_IMAGE3D:
height = imageInfo->height;
depth = imageInfo->depth;
break;
}
size_t origin[ 4 ] = { 0, 0, 0, 0 };
size_t region[ 3 ] = { imageInfo->width, height, depth };
for ( size_t lod = 0; (gTestMipmaps && (lod < imageInfo->num_mip_levels)) || (!gTestMipmaps && (lod < 1)); lod++)
{
// Map the appropriate miplevel to copy the specified data.
if(gTestMipmaps)
{
switch (imageInfo->type)
{
case CL_MEM_OBJECT_IMAGE3D:
case CL_MEM_OBJECT_IMAGE2D_ARRAY:
origin[ 3 ] = lod;
break;
case CL_MEM_OBJECT_IMAGE2D:
case CL_MEM_OBJECT_IMAGE1D_ARRAY:
origin[ 2 ] = lod;
break;
case CL_MEM_OBJECT_IMAGE1D:
origin[ 1 ] = lod;
break;
}
//Adjust image dimensions as per miplevel
switch (imageInfo->type)
{
case CL_MEM_OBJECT_IMAGE3D:
depth = ( imageInfo->depth >> lod ) ? (imageInfo->depth >> lod) : 1;
case CL_MEM_OBJECT_IMAGE2D_ARRAY:
case CL_MEM_OBJECT_IMAGE2D:
height = ( imageInfo->height >> lod ) ? (imageInfo->height >> lod) : 1;
case CL_MEM_OBJECT_IMAGE1D_ARRAY:
case CL_MEM_OBJECT_IMAGE1D:
width = ( imageInfo->width >> lod ) ? (imageInfo->width >> lod) : 1;
}
row_pitch_lod = width * get_pixel_size(imageInfo->format);
slice_pitch_lod = row_pitch_lod * height;
region[0] = width;
region[1] = height;
region[2] = depth;
}
void* mapped = (char*)clEnqueueMapImage(queue, img, CL_TRUE, CL_MAP_WRITE, origin, region, &mappedRow, &mappedSlice, 0, NULL, NULL, error);
if (*error != CL_SUCCESS)
{
log_error( "ERROR: Unable to map image for writing: %s\n", IGetErrorString( *error ) );
return NULL;
}
size_t mappedSlicePad = mappedSlice - (mappedRow * height);
// For 1Darray, the height variable actually contains the arraysize,
// so it can't be used for calculating the slice padding.
if (imageInfo->type == CL_MEM_OBJECT_IMAGE1D_ARRAY)
mappedSlicePad = mappedSlice - (mappedRow * 1);
// Copy the image.
size_t scanlineSize = row_pitch_lod;
size_t sliceSize = slice_pitch_lod - scanlineSize * height;
size_t imageSize = scanlineSize * height * depth;
size_t data_lod_offset = 0;
if( gTestMipmaps )
data_lod_offset = compute_mip_level_offset(imageInfo, lod);
char* src = (char*)data + data_lod_offset;
char* dst = (char*)mapped;
if ((mappedRow == scanlineSize) && (mappedSlicePad==0 || (imageInfo->depth==0 && imageInfo->arraySize==0))) {
// Copy the whole image.
memcpy( dst, src, imageSize );
}
else {
// Else copy one scan line at a time.
size_t dstPitch2D = 0;
switch (imageInfo->type)
{
case CL_MEM_OBJECT_IMAGE3D:
case CL_MEM_OBJECT_IMAGE2D_ARRAY:
case CL_MEM_OBJECT_IMAGE2D:
dstPitch2D = mappedRow;
break;
case CL_MEM_OBJECT_IMAGE1D_ARRAY:
case CL_MEM_OBJECT_IMAGE1D:
dstPitch2D = mappedSlice;
break;
}
for ( size_t z = 0; z < depth; z++ )
{
for ( size_t y = 0; y < height; y++ )
{
memcpy( dst, src, scanlineSize );
dst += dstPitch2D;
src += scanlineSize;
}
// mappedSlicePad is incorrect for 2D images here, but we will exit the z loop before this is a problem.
dst += mappedSlicePad;
src += sliceSize;
}
}
// Unmap the image.
*error = clEnqueueUnmapMemObject(queue, img, mapped, 0, NULL, NULL);
if (*error != CL_SUCCESS)
{
log_error( "ERROR: Unable to unmap image after writing: %s\n", IGetErrorString( *error ) );
return NULL;
}
}
return img;
}
int test_copy_image_generic( cl_context context, cl_command_queue queue, image_descriptor *srcImageInfo, image_descriptor *dstImageInfo,
const size_t sourcePos[], const size_t destPos[], const size_t regionSize[], MTdata d )
{
int error;
clMemWrapper srcImage, dstImage;
BufferOwningPtr<char> srcData;
BufferOwningPtr<char> dstData;
BufferOwningPtr<char> srcHost;
BufferOwningPtr<char> dstHost;
if( gDebugTrace )
log_info( " ++ Entering inner test loop...\n" );
// Generate some data to test against
size_t srcBytes = 0;
if( gTestMipmaps )
{
srcBytes = (size_t)compute_mipmapped_image_size( *srcImageInfo );
}
else
{
srcBytes = get_image_size(srcImageInfo);
}
if (srcBytes > srcData.getSize())
{
if( gDebugTrace )
log_info( " - Resizing random image data...\n" );
generate_random_image_data( srcImageInfo, srcData, d );
// Update the host verification copy of the data.
srcHost.reset(malloc(srcBytes),NULL,0,srcBytes);
if (srcHost == NULL) {
log_error( "ERROR: Unable to malloc %lu bytes for srcHost\n", srcBytes );
return -1;
}
memcpy(srcHost,srcData,srcBytes);
}
// Construct testing sources
if( gDebugTrace )
log_info( " - Writing source image...\n" );
srcImage = create_image( context, queue, srcData, srcImageInfo, &error );
if( srcImage == NULL )
return error;
// Initialize the destination to empty
size_t destImageSize = 0;
if( gTestMipmaps )
{
destImageSize = (size_t)compute_mipmapped_image_size( *dstImageInfo );
}
else
{
destImageSize = get_image_size(dstImageInfo);
}
if (destImageSize > dstData.getSize())
{
if( gDebugTrace )
log_info( " - Resizing destination buffer...\n" );
dstData.reset(malloc(destImageSize),NULL,0,destImageSize);
if (dstData == NULL) {
log_error( "ERROR: Unable to malloc %lu bytes for dstData\n", destImageSize );
return -1;
}
}
if (destImageSize > dstHost.getSize())
{
dstHost.reset(NULL);
dstHost.reset(malloc(destImageSize),NULL,0,destImageSize);
if (dstHost == NULL) {
dstData.reset(NULL);
log_error( "ERROR: Unable to malloc %lu bytes for dstHost\n", destImageSize );
return -1;
}
}
memset( dstData, 0xff, destImageSize );
memset( dstHost, 0xff, destImageSize );
if( gDebugTrace )
log_info( " - Writing destination image...\n" );
dstImage = create_image( context, queue, dstData, dstImageInfo, &error );
if( dstImage == NULL )
return error;
size_t dstRegion[ 3 ] = { dstImageInfo->width, 1, 1};
size_t dst_lod = 0;
size_t origin[ 4 ] = { 0, 0, 0, 0 };
if(gTestMipmaps)
{
switch(dstImageInfo->type)
{
case CL_MEM_OBJECT_IMAGE1D:
dst_lod = destPos[1];
break;
case CL_MEM_OBJECT_IMAGE1D_ARRAY:
case CL_MEM_OBJECT_IMAGE2D:
dst_lod = destPos[2];
break;
case CL_MEM_OBJECT_IMAGE2D_ARRAY:
case CL_MEM_OBJECT_IMAGE3D:
dst_lod = destPos[3];
break;
}
dstRegion[ 0 ] = (dstImageInfo->width >> dst_lod)?(dstImageInfo->width >> dst_lod) : 1;
}
switch (dstImageInfo->type)
{
case CL_MEM_OBJECT_IMAGE1D:
if( gTestMipmaps )
origin[ 1 ] = dst_lod;
break;
case CL_MEM_OBJECT_IMAGE2D:
dstRegion[ 1 ] = dstImageInfo->height;
if( gTestMipmaps )
{
dstRegion[ 1 ] = (dstImageInfo->height >> dst_lod) ?(dstImageInfo->height >> dst_lod): 1;
origin[ 2 ] = dst_lod;
}
break;
case CL_MEM_OBJECT_IMAGE3D:
dstRegion[ 1 ] = dstImageInfo->height;
dstRegion[ 2 ] = dstImageInfo->depth;
if( gTestMipmaps )
{
dstRegion[ 1 ] = (dstImageInfo->height >> dst_lod) ?(dstImageInfo->height >> dst_lod): 1;
dstRegion[ 2 ] = (dstImageInfo->depth >> dst_lod) ?(dstImageInfo->depth >> dst_lod): 1;
origin[ 3 ] = dst_lod;
}
break;
case CL_MEM_OBJECT_IMAGE1D_ARRAY:
dstRegion[ 1 ] = dstImageInfo->arraySize;
if( gTestMipmaps )
origin[ 2 ] = dst_lod;
break;
case CL_MEM_OBJECT_IMAGE2D_ARRAY:
dstRegion[ 1 ] = dstImageInfo->height;
dstRegion[ 2 ] = dstImageInfo->arraySize;
if( gTestMipmaps )
{
dstRegion[ 1 ] = (dstImageInfo->height >> dst_lod) ?(dstImageInfo->height >> dst_lod): 1;
origin[ 3 ] = dst_lod;
}
break;
}
size_t region[ 3 ] = { dstRegion[ 0 ], dstRegion[ 1 ], dstRegion[ 2 ] };
// Now copy a subset to the destination image. This is the meat of what we're testing
if( gDebugTrace )
{
if( gTestMipmaps )
{
log_info( " - Copying from %d,%d,%d,%d to %d,%d,%d,%d size %d,%d,%d\n", (int)sourcePos[ 0 ], (int)sourcePos[ 1 ], (int)sourcePos[ 2 ],(int)sourcePos[ 3 ],
(int)destPos[ 0 ], (int)destPos[ 1 ], (int)destPos[ 2 ],(int)destPos[ 3 ],
(int)regionSize[ 0 ], (int)regionSize[ 1 ], (int)regionSize[ 2 ] );
}
else
{
log_info( " - Copying from %d,%d,%d to %d,%d,%d size %d,%d,%d\n", (int)sourcePos[ 0 ], (int)sourcePos[ 1 ], (int)sourcePos[ 2 ],
(int)destPos[ 0 ], (int)destPos[ 1 ], (int)destPos[ 2 ],
(int)regionSize[ 0 ], (int)regionSize[ 1 ], (int)regionSize[ 2 ] );
}
}
error = clEnqueueCopyImage( queue, srcImage, dstImage, sourcePos, destPos, regionSize, 0, NULL, NULL );
if( error != CL_SUCCESS )
{
log_error( "ERROR: Unable to copy image from pos %d,%d,%d to %d,%d,%d size %d,%d,%d! (%s)\n",
(int)sourcePos[ 0 ], (int)sourcePos[ 1 ], (int)sourcePos[ 2 ], (int)destPos[ 0 ], (int)destPos[ 1 ], (int)destPos[ 2 ],
(int)regionSize[ 0 ], (int)regionSize[ 1 ], (int)regionSize[ 2 ], IGetErrorString( error ) );
return error;
}
// Construct the final dest image values to test against
if( gDebugTrace )
log_info( " - Host verification copy...\n" );
copy_image_data( srcImageInfo, dstImageInfo, srcHost, dstHost, sourcePos, destPos, regionSize );
// Map the destination image to verify the results with the host
// copy. The contents of the entire buffer are compared.
if( gDebugTrace )
log_info( " - Mapping results...\n" );
size_t mappedRow, mappedSlice;
void* mapped = (char*)clEnqueueMapImage(queue, dstImage, CL_TRUE, CL_MAP_READ, origin, region, &mappedRow, &mappedSlice, 0, NULL, NULL, &error);
if (error != CL_SUCCESS)
{
log_error( "ERROR: Unable to map image for verification: %s\n", IGetErrorString( error ) );
return error;
}
// Verify scanline by scanline, since the pitches are different
char *sourcePtr = dstHost;
size_t cur_lod_offset = 0;
char *destPtr = (char*)mapped;
if( gTestMipmaps )
{
cur_lod_offset = compute_mip_level_offset(dstImageInfo, dst_lod);
sourcePtr += cur_lod_offset;
}
size_t scanlineSize = dstImageInfo->width * get_pixel_size( dstImageInfo->format );
size_t rowPitch = dstImageInfo->rowPitch;
size_t slicePitch = dstImageInfo->slicePitch;
size_t dst_height_lod = dstImageInfo->height;
if(gTestMipmaps)
{
size_t dst_width_lod = (dstImageInfo->width >> dst_lod)?(dstImageInfo->width >> dst_lod) : 1;
dst_height_lod = (dstImageInfo->height >> dst_lod)?(dstImageInfo->height >> dst_lod) : 1;
scanlineSize = dst_width_lod * get_pixel_size(dstImageInfo->format);
rowPitch = scanlineSize;
slicePitch = rowPitch * dst_height_lod;
}
if( gDebugTrace )
log_info( " - Scanline verification...\n" );
size_t thirdDim = 1;
size_t secondDim = 1;
switch (dstImageInfo->type)
{
case CL_MEM_OBJECT_IMAGE1D_ARRAY: {
secondDim = dstImageInfo->arraySize;
break;
}
case CL_MEM_OBJECT_IMAGE2D_ARRAY: {
secondDim = dstImageInfo->height;
thirdDim = dstImageInfo->arraySize;
break;
}
case CL_MEM_OBJECT_IMAGE3D: {
secondDim = dstImageInfo->height;
thirdDim = dstImageInfo->depth;
break;
}
case CL_MEM_OBJECT_IMAGE2D: {
secondDim = dstImageInfo->height;
break;
}
case CL_MEM_OBJECT_IMAGE1D: {
break;
}
default: {
log_error("ERROR: Unsupported Image type. \n");
return error;
break;
}
}
if (gTestMipmaps)
{
switch (dstImageInfo->type)
{
case CL_MEM_OBJECT_IMAGE3D:
thirdDim = (dstImageInfo->depth >> dst_lod) ? (dstImageInfo->depth >> dst_lod):1;
/* Fallthrough */
case CL_MEM_OBJECT_IMAGE2D:
case CL_MEM_OBJECT_IMAGE2D_ARRAY:
secondDim = (dstImageInfo->height >> dst_lod)
? (dstImageInfo->height >> dst_lod)
: 1;
break;
}
}
for( size_t z = 0; z < thirdDim; z++ )
{
for( size_t y = 0; y < secondDim; y++ )
{
if( memcmp( sourcePtr, destPtr, scanlineSize ) != 0 )
{
// Find the first differing pixel
size_t pixel_size = get_pixel_size( dstImageInfo->format );
size_t where =
compare_scanlines(dstImageInfo, sourcePtr, destPtr);
if (where < dstImageInfo->width)
{
print_first_pixel_difference_error(
where, sourcePtr + pixel_size * where,
destPtr + pixel_size * where, dstImageInfo, y,
dstImageInfo->depth);
return -1;
}
}
sourcePtr += rowPitch;
if((dstImageInfo->type == CL_MEM_OBJECT_IMAGE1D_ARRAY || dstImageInfo->type == CL_MEM_OBJECT_IMAGE1D))
destPtr += mappedSlice;
else
destPtr += mappedRow;
}
sourcePtr += slicePitch - rowPitch * dst_height_lod;
destPtr += mappedSlice - mappedRow * dst_height_lod;
}
// Unmap the image.
error = clEnqueueUnmapMemObject(queue, dstImage, mapped, 0, NULL, NULL);
if (error != CL_SUCCESS)
{
log_error( "ERROR: Unable to unmap image after verify: %s\n", IGetErrorString( error ) );
return error;
}
// Ensure the unmap call completes.
error = clFinish(queue);
if (error != CL_SUCCESS)
{
log_error("ERROR: clFinish() failed to return CL_SUCCESS: %s\n",
IGetErrorString(error));
return error;
}
return 0;
}
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