/*******************************************************************************
* Copyright 2015-2018 Intel Corporation.
*
* This software and the related documents are Intel copyrighted materials, and
* your use of them is governed by the express license under which they were
* provided to you (License). Unless the License provides otherwise, you may not
* use, modify, copy, publish, distribute, disclose or transmit this software or
* the related documents without Intel's prior written permission.
*
* This software and the related documents are provided as is, with no express
* or implied warranties, other than those that are expressly stated in the
* License.
*******************************************************************************/
// A simple example of downsampling of the image with
// 5x5 Gaussian kernel using Intel(R) Integrated Primitives (Intel(R) IPP) functions:
// ippiPyramidGetSize
// ippiPyramidInit
// ippiPyramidLayerDownGetSize_32f_C1R
// ippiPyramidLayerDownInit_32f_C1R
// ippiPyramidLayerDown_32f_C1R
#include <stdio.h>
#include "ipp.h"
#define WIDTH 128 /* Image width */
#define HEIGHT 128 /* Image height */
#define KERSIZE 3 /* Kernel size */
/* Next two defines are created to simplify code reading and understanding */
#define EXIT_MAIN exitLine: /* Label for Exit */
#define check_sts(st) if((st) != ippStsNoErr) goto exitLine; /* Go to Exit if Intel(R) IPP function returned status different from ippStsNoErr */
/* Results of ippMalloc() are not validated because Intel(R) IPP functions perform bad arguments check and will return an appropriate status */
int main(void)
{
IppStatus status = ippStsNoErr;
Ipp32f* pSrc = NULL; /* Pointer to source image */
int srcStep; /* Step, in bytes, through the source image */
IppiSize roiSize = { WIDTH, HEIGHT }; /* Size of source/destination ROI in pixels */
Ipp32f rate = 2.f; /* Neighbor levels ratio */
int level = 1000; /* Maximal number pyramid level */
int i = 0;
int pyrBufferSize = 0;
int pyrStructSize = 0;
IppiPyramid *pPyrStruct = NULL;
Ipp8u *pPyrBuffer = NULL;
Ipp8u *pPyrStrBuffer = NULL;
int pyrLStateSize = 0;
int pyrLBufferSize = 0;
Ipp8u *pPyrLStateBuf = NULL;
Ipp8u *pPyrLBuffer = NULL;
Ipp32f **pPyrImage = NULL;
Ipp32f kernel[KERSIZE] = { 1.f, 1.f, 1.f }; /* Separable symmetric kernel of odd length */
pSrc = ippiMalloc_32f_C1(roiSize.width, roiSize.height, &srcStep);
/* Build Gaussian pyramid */
{
/* Computes the temporary work buffer size */
check_sts( status = ippiPyramidGetSize(&pyrStructSize, &pyrBufferSize, level, roiSize, rate) )
pPyrBuffer = ippsMalloc_8u(pyrBufferSize);
pPyrStrBuffer = ippsMalloc_8u(pyrStructSize);
/* Initializes Gaussian structure for pyramids */
check_sts( status = ippiPyramidInit(&pPyrStruct, level, roiSize, rate, pPyrStrBuffer, pPyrBuffer) )
/* Correct maximum scale level */
level = pPyrStruct->level;
/* Allocate structures to calculate pyramid layers */
check_sts( status = ippiPyramidLayerDownGetSize_32f_C1R(roiSize, rate, KERSIZE, &pyrLStateSize, &pyrLBufferSize) )
pPyrLStateBuf = ippsMalloc_8u(pyrLStateSize);
pPyrLBuffer = ippsMalloc_8u(pyrLBufferSize);
/* Initialize the structure for creating a lower pyramid layer */
check_sts( status = ippiPyramidLayerDownInit_32f_C1R((IppiPyramidDownState_32f_C1R**)&pPyrStruct->pState, roiSize, rate,
kernel, KERSIZE, IPPI_INTER_LINEAR, pPyrLStateBuf, pPyrLBuffer) )
/* Allocate pyramid layers */
pPyrImage = (Ipp32f**)pPyrStruct->pImage;
pPyrImage[0] = pSrc;
pPyrStruct->pStep[0] = srcStep;
for(i = 1; i <= level; i++)
{
pPyrImage[i] = ippiMalloc_32f_C1(pPyrStruct->pRoi[i].width, pPyrStruct->pRoi[i].height, &pPyrStruct->pStep[i]);
}
/* Perform downsampling of the image with 5x5 Gaussian kernel */
for(i = 1; i <= level; i++)
{
check_sts( status = ippiPyramidLayerDown_32f_C1R(pPyrImage[i - 1], pPyrStruct->pStep[i - 1], pPyrStruct->pRoi[i - 1],
pPyrImage[i], pPyrStruct->pStep[i], pPyrStruct->pRoi[i], (IppiPyramidDownState_32f_C1R*)pPyrStruct->pState) )
}
}
EXIT_MAIN
if (pPyrImage)
for(i = 1; i <= level; i++)
ippiFree(pPyrImage[i]);
ippiFree(pPyrLStateBuf);
ippiFree(pPyrLBuffer);
ippiFree(pPyrStrBuffer);
ippiFree(pPyrBuffer);
ippiFree(pSrc);
printf("Exit status %d (%s)\n", (int)status, ippGetStatusString(status));
return status;
}