Visible to Intel only — GUID: GUID-132B79AC-838B-49FD-8EB0-50AEF27511C7
Getting Help and Support
Introducing the Intel® Integrated Performance Primitives for Intel® Architecture
Notational Conventions
Getting Started with Intel® Integrated Performance Primitives
Intel® Integrated Performance Primitives Theory of Operation
Linking Your Application with Intel® Integrated Performance Primitives
Using Intel® Integrated Performance Primitives Platform-Aware Functions
Using Intel® Integrated Performance Primitives Threading Layer (TL) Functions
Using Custom Library Tool for Intel® Integrated Performance Primitives
Using Integration Wrappers for Intel® Integrated Performance Primitives
Programming Considerations
Programming with Intel® Integrated Performance Primitives in the Microsoft* Visual Studio* IDE
Appendix: Performance Test Tool Command-Line Options
Appendix: Intel(R) IPP Threading and OpenMP* Support
Intel® IPP API Reference
Notices and Disclaimers
Intel® Integrated Performance Primitives Concepts
Support Functions
Vector Initialization Functions
Essential Functions
Filtering Functions
Transform Functions
Fixed-Accuracy Arithmetic Functions
Long Term Evolution (LTE) Wireless Support Functions
Data Compression Functions
Appendix A: Handling of Special Cases
Appendix B: Removed Functions for Signal Processing
Bibliography for Signal Processing
Glossary
SortAscend, SortDescend
SortIndexAscend, SortIndexDescend
SortRadixGetBufferSize
SortRadixAscend, SortRadixDescend
SortRadixIndexGetBufferSize
SortRadixIndexAscend, SortRadixIndexDescend
TopKGetBufferSize
TopKInit
TopK
SwapBytes
Convert
Conj
ConjFlip
Magnitude
Phase
PowerSpectr
Real
Imag
RealToCplx
CplxToReal
Threshold
Threshold_LT, Threshold_GT
Threshold_LTAbs, Threshold_GTAbs
Threshold_LTVal, Threshold_LTAbsVal, Threshold_GTVal, Threshold_LTValGTVal
Threshold_LTInv
CartToPolar
PolarToCart
MaxOrder
Flip
FindNearestOne
FindNearest
Special Parameters
Adler32
CRC32, CRC32C
DeflateLZ77
DeflateLZ77Fast
DeflateLZ77Fastest
DeflateLZ77FastestGenHeader
DeflateLZ77FastestGenHuffTable
DeflateLZ77FastestGetStat
DeflateLZ77FastestPrecompHeader
DeflateLZ77Slow
DeflateDictionarySet
DeflateUpdate Hash
DeflateHuff
InflateBuildHuffTable
Inflate
EncodeRLEInit_BZ2
RLEGetSize_BZ2
EncodeRLE_BZ2
EncodeRLEFlush_BZ2
RLEGetInUseTable
DecodeRLEStateInit_BZ2
DecodeRLEState_BZ2
DecodeRLEStateFlush_BZ2
EncodeZ1Z2_BZ2
DecodeZ1Z2_BZ2
ReduceDictionary
ExpandDictionary
CRC32_BZ2
EncodeHuffGetSize_BZ2
EncodeHuffInit_BZ2
PackHuffContext_BZ2
EncodeHuff_BZ2
DecodeHuffGetSize_BZ2
DecodeHuffInit_BZ2
UnpackHuffContext_BZ2
DecodeHuff_BZ2
DecodeBlockGetSize_BZ2
DecodeBlock_BZ2
EncodeZfpGetStateSize
EncodeZfpInit, EncodeZfpInitLong
EncodeZfpSet
EncodeZfpSetAccuracy
EncodeZfp444
EncodeZfpGetCompressedBitSize
EncodeZfpFlush
EncodeZfpGetCompressedSize, EncodeZfpGetCompressedSizeLong
DecodeZfpGetStateSize
DecodeZfpInit, DecodeZfpInitLong
DecodeZfpSet
DecodeZfpSetAccuracy
DecodeZfp444
DecodeZfpGetCompressedSize, DecodeZfpGetCompressedSizeLong
Intel® Integrated Performance Primitives Concepts
Support Functions
Image Data Exchange and Initialization Functions
Image Arithmetic and Logical Operations
Image Color Conversion
Threshold and Compare Operations
Morphological Operations
Filtering Functions
Image Linear Transforms
Image Statistics Functions
Image Geometry Transforms
Miscellaneous Image Transforms
Wavelet Transforms
Computer Vision
3D Data Processing Functions
Appendix A: Handling of Special Cases
Appendix B: Interpolation in Image Geometric Transform Functions
Appendix C: Removed Functions for Image and Video Processing
Bibliography for Image Processing
Glossary
RGBToYUV
YUVToRGB
RGBToYUV422
YUV422ToRGB
RGBToYUV420
YUV420ToRGB
BGRToYUV420
YUV420ToBGR
YUV422v210ToRGB, YUV422v210ToBGR
YUV422v210ToGray
RGBToYCbCr
YCbCrToRGB
YCbCrToBGR
YCbCrToBGR_709CSC
RGBToYCbCr422
YCbCr422ToRGB
RGBToYCrCb422
YCrCb422ToRGB, YCrCb422ToBGR
BGRToYCbCr422
YCbCr422ToBGR
YCbCr422ToGray
RGBToCbYCr422, RGBToCbYCr422Gamma
CbYCr422ToRGB
BGRToCbYCr422
BGRToCbYCr422_709HDTV
CbYCr422ToBGR
CbYCr422ToBGR_709HDTV
RGBToYCbCr420
YCbCr420ToRGB, YCbCr420ToBGR
RGBToYCrCb420
YCrCb420ToRGB, YCrCb420ToBGR
BGRToYCbCr420
BGRToYCbCr420_709CSC
BGRToYCbCr420_709HDTV
BGRToYCrCb420_709CSC
YCbCr420ToBGR
YCbCr420ToBGR_709CSC
YCbCr420ToBGR_709HDTV
BGRToYCrCb420
BGRToYCbCr411
YCbCr411ToBGR
RGBToXYZ
XYZToRGB
RGBToLUV, BGRToLUV
LUVToRGB, LUVToBGR
BGRToLab, RGBToLab
LabToBGR, LabToRGB
RGBToYCC
YCCToRGB
RGBToHLS
HLSToRGB
BGRToHLS
HLSToBGR
RGBToHSV
HSVToRGB
RGBToYCoCg
YCoCgToRGB
BGRToYCoCg
SBGRToYCoCg
YCoCgToBGR
YCoCgToSBGR
BGRToYCoCg_Rev
SBGRToYCoCg_Rev
YCoCgToBGR_Rev
YCoCgToSBGR_Rev
YCbCr422
YCbCr422ToYCrCb422
YCbCr422ToCbYCr422
YCbCr422ToYCbCr420
YCbCr422To420_Interlace
YCbCr422ToYCrCb420
YCbCr422ToYCbCr411
YCrCb422ToYCbCr422
YCrCb422ToYCbCr420
YCrCb422ToYCbCr411
CbYCr422ToYCbCr422
CbYCr422ToYCbCr420
CbYCr422ToYCbCr420_Interlace
CbYCr422ToYCrCb420
CbYCr422ToYCbCr411
YCbCr420
YCbCr420ToYCbCr422
YCbCr420ToYCbCr422_Filter
YCbCr420To422_Interlace
YCbCr420ToCbYCr422
YCbCr420ToCbYCr422_Interlace
YCbCr420ToYCrCb420
YCbCr420ToYCrCb420_Filter
YCbCr420ToYCbCr411
YCrCb420ToYCbCr422
YCrCb420ToYCbCr422_Filter
YCrCb420ToCbYCr422
YCrCb420ToYCbCr420
YCrCb420ToYCbCr411
YCbCr411
YCbCr411ToYCbCr422
YCbCr411ToYCrCb422
YCbCr411ToYCbCr420, YCbCr411To420
YCbCr411ToYCrCb420
Dilate3x3
Dilate
DilateBorder
DilateGetBufferSize
DilateGetSpecSize
DilateInit
Erode3x3
Erode
ErodeBorder
ErodeGetBufferSize
ErodeGetSpecSize
ErodeInit
GrayDilateBorder
GrayErodeBorder
MorphAdvInit
MorphAdvGetSize
MorphGetBufferSize
MorphGetSpecSize
MorphInit
MorphologyBorderGetSize
MorphologyBorderInit
MorphBlackhat
MorphBlackhatBorder
MorphClose
MorphCloseBorder
MorphGradient
MorphGradientBorder
MorphOpen
MorphOpenBorder
MorphTophat
MorphTophatBorder
MorphGrayInit
MorphGrayGetSize
MorphReconstructGetBufferSize
MorphReconstructDilate
MorphReconstructErode
MorphSetMode
FilterBilateral
FilterBilateralGetBufferSize
FilterBilateralInit
FilterBilateralBorderGetBufferSize
FilterBilateralBorderInit
FilterBilateralBorder
FilterBoxBorderGetBufferSize
FilterBoxBorder
FilterBox
FilterGaussianBorder
SumWindow
SumWindowGetBufferSize
SumWindowRow
SumWindowColumn
FilterMaxBorderGetBufferSize, FilterMinBorderGetBufferSize
FilterMaxBorder, FilterMinBorder
DecimateFilterRow, DecimateFilterColumn
FilterRowBorderPipelineGetBufferSize, FilterRowBorderPipelineGetBufferSize_Low
FilterRowBorderPipeline, FilterRowBorderPipeline_Low
FilterColumnPipelineGetBufferSize, FilterColumnPipelineGetBufferSize_Low
FilterColumnPipeline, FilterColumnPipeline_Low
FilterSeparable
FilterSeparableGetBufferSize
FilterSeparableGetSpecSize
FilterSeparableInit
FilterGaussianGetBufferSize
FilterGaussianGetSpecSize
FilterGaussianInit
FilterGaussian
FilterHipassBorderGetBufferSize
FilterHipassBorder
FilterLaplaceBorderGetBufferSize
FilterLaplaceBorder
FilterLaplacianGetBufferSize
FilterLaplacianBorder
FilterLowpassGetBufferSize
FilterLowpassBorder
FilterPrewittHorizBorderGetBufferSize
FilterPrewittHorizBorder
FilterPrewittVertBorderGetBufferSize
FilterPrewittVertBorder
FilterRobertsUpBorderGetBufferSize
FilterRobertsUpBorder
FilterRobertsDownBorderGetBufferSize
FilterRobertsDownBorder
FilterScharrHorizMaskBorderGetBufferSize
FilterScharrHorizMaskBorder
FilterScharrVertMaskBorderGetBufferSize
FilterScharrVertMaskBorder
FilterSharpenBorderGetBufferSize
FilterSharpenBorder
FilterSobelGetBufferSize
FilterSobelInit
FilterSobel
FilterSobelHorizBorderGetBufferSize
FilterSobelHorizBorder
FilterSobelHorizSecondBorderGetBufferSize
FilterSobelHorizSecondBorder
FilterSobelVertBorderGetBufferSize
FilterSobelVertBorder
FilterSobelVertSecondBorderGetBufferSize
FilterSobelNegVertBorderGetBufferSize
FilterSobelNegVertBorder
FilterSobelVertSecondBorder
FilterSobelCrossGetBufferSize
FilterSobelCrossBorder
GenSobelKernel
Sum
Integral
SqrIntegral
TiltedIntegral
TiltedSqrIntegral
Mean
Mean_StdDev
RectStdDev
TiltedRectStdDev
HistogramGetBufferSize
HistogramGetLevels
HistogramInit, HistogramUniformInit
Histogram
CountInRange
BlockMinMax
Min
MinIndx
Max
MaxIndx
MinMax
MinMaxIndx
MaxEvery
MinEvery
FindPeaks3x3GetBufferSize
FindPeaks3x3
Image Moments
Image Norms
Image Quality Index
Image Proximity Measures
Using Intel® IPP Resize Functions with Prior Initialization
ResizeGetSize
ResizeGetBufferSize
ResizeGetBorderSize
ResizeGetSrcOffset
ResizeGetSrcRoi
ResizeSetMode
ResizeNearestInit
ResizeNearest
ResizeLinearInit
ResizeLinear
ResizeCubicInit
ResizeCubic
ResizeLanczosInit
ResizeLanczos
ResizeSuperShiftInit
ResizeSuperInit
ResizeSuper
ResizeAntialiasingLinearInit
ResizeAntialiasingCubicInit
ResizeAntialiasingLanczosInit
ResizeAntialiasing
ResizeFilterGetSize
ResizeFilterInit
ResizeFilter
ResizeYUV420GetSize
ResizeYUV420GetSrcRoi
ResizeYUV420LanczosInit
ResizeYUV420SuperInit
ResizeYUV420GetBorderSize
ResizeYUV420GetSrcOffset
ResizeYUV420GetBufferSize
ResizeYUV420Lanczos
ResizeYUV420Super
ResizeYUV422GetSize
ResizeYUV422GetBorderSize
ResizeYUV422GetSrcOffset
ResizeYUV422GetBufSize
ResizeYUV422GetSrcRoi
ResizeYUV422NearestInit
ResizeYUV422LinearInit
ResizeYUV422Nearest
ResizeYUV422Linear
Using Intel® IPP Warp Affine Functions with Prior Initialization
Edge Smoothing
GetAffineQuad
GetAffineBound
GetAffineSrcRoi
GetAffineTransform
GetRotateTransform
GetRotateShift
WarpAffineGetSize
WarpQuadGetSize
WarpGetBufferSize
WarpAffineNearestInit
WarpQuadNearestInit
WarpAffineNearest
WarpAffineLinearInit
WarpQuadLinearInit
WarpAffineLinear
WarpAffineCubicInit
WarpQuadCubicInit
WarpAffineCubic
GetPerspectiveQuad
GetPerspectiveBound
GetPerspectiveTransform
WarpGetRectInfinite
WarpPerspectiveGetSize
WarpPerspectiveNearestInit
WarpPerspectiveNearest
Syntax
Include Files
Domain Dependencies
Parameters
Description
Return Values
Example
See Also
WarpPerspectiveLinearInit
WarpPerspectiveLinear
WarpPerspectiveCubicInit
WarpPerspectiveCubic
Visible to Intel only — GUID: GUID-132B79AC-838B-49FD-8EB0-50AEF27511C7
WarpPerspectiveNearest
Performs warp perspective transformation of an image using the nearest neighbor interpolation method.
Syntax
IppStatus ippiWarpPerspectiveNearest_<mod>(const Ipp<datatype>* pSrc, int srcStep, Ipp<datatype> pDst, int dstStep, IppiPoint dstRoiOffset, IppiSize dstRoiSize, const IppiWarpSpec* pSpec, Ipp8u* pBuffer);
Supported values for mod:
8u_C1R |
16u_C1R |
16s_C1R |
32f_C1R |
8u_C3R |
16u_C3R |
16s_C3R |
32f_C3R |
8u_C4R |
16u_C4R |
16s_C4R |
32f_C4R |
Include Files
ippi.h
Domain Dependencies
Headers: ippcore.h, ippvm.h, ipps.h
Libraries: ippcore.lib, ippvm.lib, ipps.lib
Parameters
pSrc |
Pointer to the source image. |
srcStep |
Distance, in bytes, between the starting points of consecutive lines in the source image buffer. |
pDst |
Pointer to the destination image ROI. |
dstStep |
Distance, in bytes, between the starting points of consecutive lines in the destination image buffer. |
dstRoiOffset |
Offset of the destination image ROI with respect to the destination image origin. |
dstRoiSize |
Size of the destination image ROI, in pixels. |
pSpec |
Pointer to the specification structure for the warp operation. |
pBuffer |
Pointer to the work buffer. |
Description
This function transforms the source image pixel coordinates (x, y) according to the following formulas:
x' = (c00*x + c01*y + c02)/ (c20*x + c21*y + c22)
y' = (c10*x + c11*y + c12)/(c20*x + c21*y + c22)
where
x' and y' are the pixel coordinates in the transformed image
cij are the affine transform coefficients passed to the coeffs array during initialization
The ippiWarpPerspectiveNearest function operates with ROI (see Regions of Interest in Intel IPP). The transformed part of the source image is resampled with the nearest neighbor interpolation method and stored in the destination image ROI. You need to define the destination image ROI origin by the following parameters: the offset of the destination ROI with respect to the destination image origin and the destination image ROI size. The parameter pDst must point to the processed destination image ROI.
If you initialize the warp specification structure using the WarpPerspectiveNearestInit function, you can specify the source image ROI in the following ways:
Set the srcRoi value to ippRectInfinite, which means that the ROI is not specified. In this case, pSrc must point to the processed source image. Pixels that are outside the source image boundaries are computed according to the specified border type.
Set the srcRoi value to the part of the processed source image. In this case, pSrc must point to the processed source image ROI. The operations take place only inside the specified region of interest srcRoi. It means that the destination image pixels mapped to the outer pixels of the specified source image region are not changed.
If you initialize the warp specification structure using the WarpQuadNearestInit function, set the pSrc value to the processed source image. The operations take place only inside the source quadrangle srcQuad that is specified in the WarpQuadNearestInit function.
To specify the algorithm for borders processing, set the borderType and pBorderValue parameters when initializing the IppiWarpSpec structure. The data type of borderValue is automatically converted from Ipp64f to the data type of the processed images. The function supports the following algorithms for borders processing:
If the border type is equal to ippBorderRepl, the source image outer pixels are replicated from the edge pixels.
If the border type is equal to ippBorderConst, the outer pixels are set to the constant value specified in pBorderValue.
If the border type is equal to ippBorderTransp or ippBorderInMem, destination image pixels mapped to the outer source image pixels are not changed.
Before using the ippiWarpPerspectiveNearest function, you need to initialize the IppiWarpSpec structure using the WarpPerspectiveNearestInit function and compute the size of the external buffer pBuffer using the WarpGetBufferSize function.
To compute the perspective transform parameters, use the GetPerspectiveQuad, GetPerspectiveBound, and GetPerspectiveTransform functions.
Return Values
ippStsNoErr |
Indicates no error. |
ippStsNullPtrErr |
Indicates an error when one of the specified pointers is NULL. |
ippStsNoOperation |
Indicates a warning when width or height of the destination image is equal to zero. |
ippStsContextMatchErr |
Indicates an error when context data is invalid. |
ippStsNotSupportedModeErr |
Indicates an error when the requested mode is not supported. |
ippStsSizeErr |
Indicates an error when width or height of the source or destination image ROI is negative. |
ippStsStepErr |
Indicates an error when the step value is not a multiple of data type. |
ippStsOutOfRangeErr |
Indicates an error when the destination image offset point is outside the destination image origin. |
ippStsSizeWrn |
Indicates a warning when the destination image ROI size is more than the destination image origin size. |
ippStsWrongIntersectQuad |
Indicates a warning that no operation is performed if the transformed source image extended with borders has no intersection with the destination image. |
Example
/*******************************************************************************
* Copyright 2015 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 the warp perspective transform
// using Intel(R) Integrated Performance Primitives (Intel(R) IPP) functions:
// ippiWarpPerspectiveGetSize
// ippiWarpPerspectiveCubicInit
// ippiWarpGetBufferSize
// ippiWarpPerspectiveCubic_8u_C3R
#include <stdio.h>
#include "ipp.h"
#define WIDTH 640 /* Source image width */
#define HEIGHT 480 /* Destination image width */
/* 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 */
static const double coeffs[3][3] = { /* Coefficients for the perspective transform */
{ 2.3439242437790240 , 0.0025160437043002296 , -499.09988916944815, },
{ 0.0058031616363677600 , 1.4997057893818542 , -181.04366815436885, },
{ 1.1527998857985334e-005, 1.9607666631981373e-006, 0.99730924424366529 }
};
/* 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;
Ipp8u* pSrc = NULL, *pDst = NULL; /* Pointers to source/destination images */
int srcStep = 0, dstStep = 0; /* Steps, in bytes, through the source/destination images */
IppiSize srcSize = { WIDTH, HEIGHT }, dstSize = { WIDTH, HEIGHT }; /* Size of source/destination ROI in pixels */
IppiWarpSpec* pSpec = NULL; /* Pointer to the specification structure */
Ipp8u* pInitBuf = NULL; /* Pointer to temporary buffer for transform initialization*/
Ipp8u* pBuffer = NULL; /* Pointer to the work buffer */
pSrc = ippiMalloc_8u_C3(srcSize.width, srcSize.height, &srcStep);
pDst = ippiMalloc_8u_C3(dstSize.width, dstSize.height, &dstStep);
/* Start perspective transform */
{
int specSize = 0; /* Size, in bytes, of the specification structure */
int initSize = 0; /* Size, in bytes, of the temporary buffer */
int bufSize = 0; /* Size, in bytes, of the work buffer */
const Ipp32s numChannels = 3;
IppiPoint dstOffset = { 0, 0 }; /* Offset of the destination image ROI with respect to the destination image origin */
IppStatus status = ippStsNoErr;
IppiBorderType borderType = ippBorderConst;
IppiWarpDirection direction = ippWarpForward; /* Transformation direction */
Ipp64f pBorderValue[3];
Ipp64f valB = 0.0, valC = 0.5; /* Catmull-Rom filter coefficients for cubic interpolation */
IppiRect srcRoi = ippRectInfinite; /* Region of interest is not specified */
int smoothEdge = 0; /* Flag for edge smoothing */
IppiInterpolationType interpolation = ippCubic;
int i = 0;
for (i = 0; i < numChannels; ++i) pBorderValue[i] = 255.0;
/* Computes the size of the specification structure and the size of the external work buffer for the warp perspective transform */
check_sts( status = ippiWarpPerspectiveGetSize(srcSize, srcRoi, dstSize, ipp8u, coeffs, interpolation, direction, borderType, &specSize, &initSize) )
pSpec = (IppiWarpSpec*)ippsMalloc_8u(specSize);
pInitBuf = ippsMalloc_8u(initSize);
/* Initializes the specification structure for image perspective warping with the cubic interpolation method */
check_sts( status = ippiWarpPerspectiveCubicInit(srcSize, srcRoi, dstSize, ipp8u, coeffs, direction, numChannels, valB, valC, borderType, pBorderValue, smoothEdge, pSpec, pInitBuf) )
/* Work buffer size */
check_sts( status = ippiWarpGetBufferSize(pSpec, dstSize, &bufSize) )
pBuffer = ippsMalloc_8u(bufSize);
/* Performs warp perspective transformation of an image using the cubic interpolation method */
check_sts( status = ippiWarpPerspectiveCubic_8u_C3R(pSrc, srcStep, pDst, dstStep, dstOffset, dstSize, pSpec, pBuffer) )
}
EXIT_MAIN
ippsFree(pInitBuf);
ippsFree(pSpec);
ippsFree(pBuffer);
ippiFree(pSrc);
ippiFree(pDst);
printf("Exit status %d (%s)\n", (int)status, ippGetStatusString(status));
return (int)status;
}
Parent topic: Warp Functions with Prior Initialization
See Also
WarpPerspectiveNearestInit Initializes the specification structure for image perspective warping with the nearest neighbor interpolation method.
WarpQuadNearestInit Initializes the specification structure for warping an arbitrary quadrangle in the source image to the quadrangle in the destination image with the nearest neighbor interpolation method.
WarpGetBufferSize Computes the size of the work buffer for the warp transform.
GetPerspectiveBound Computes the bounding rectangle for the source ROI transformed by the ippiWarpPerspective function.
GetPerspectiveQuad Computes vertex coordinates of the quadrangle, to which the source ROI rectangle is mapped by the perspective transform.
GetPerspectiveTransform Computes the perspective transform coefficients to map the source ROI to the quadrangle with the specified vertex coordinates.