/*M/////////////////////////////////////////////////////////////////////////////////////// // // IMPORTANT: READ BEFORE DOWNLOADING, COPYING, INSTALLING OR USING. // // By downloading, copying, installing or using the software you agree to this license. // If you do not agree to this license, do not download, install, // copy or use the software. // // // Intel License Agreement // For Open Source Computer Vision Library // // Copyright (C) 2000, Intel Corporation, all rights reserved. // Copyright (C) 2014, Itseez, Inc, all rights reserved. // Third party copyrights are property of their respective owners. // // Redistribution and use in source and binary forms, with or without modification, // are permitted provided that the following conditions are met: // // * Redistribution's of source code must retain the above copyright notice, // this list of conditions and the following disclaimer. // // * Redistribution's in binary form must reproduce the above copyright notice, // this list of conditions and the following disclaimer in the documentation // and/or other materials provided with the distribution. // // * The name of Intel Corporation may not be used to endorse or promote products // derived from this software without specific prior written permission. // // This software is provided by the copyright holders and contributors "as is" and // any express or implied warranties, including, but not limited to, the implied // warranties of merchantability and fitness for a particular purpose are disclaimed. // In no event shall the Intel Corporation or contributors be liable for any direct, // indirect, incidental, special, exemplary, or consequential damages // (including, but not limited to, procurement of substitute goods or services; // loss of use, data, or profits; or business interruption) however caused // and on any theory of liability, whether in contract, strict liability, // or tort (including negligence or otherwise) arising in any way out of // the use of this software, even if advised of the possibility of such damage. // //M*/ #include "precomp.hpp" #include "opencl_kernels_imgproc.hpp" #if defined (HAVE_IPP) && (IPP_VERSION_MAJOR >= 7) static IppStatus sts = ippInit(); #endif /****************************************************************************************\ Sobel & Scharr Derivative Filters \****************************************************************************************/ namespace cv { static void getScharrKernels( OutputArray _kx, OutputArray _ky, int dx, int dy, bool normalize, int ktype ) { const int ksize = 3; CV_Assert( ktype == CV_32F || ktype == CV_64F ); _kx.create(ksize, 1, ktype, -1, true); _ky.create(ksize, 1, ktype, -1, true); Mat kx = _kx.getMat(); Mat ky = _ky.getMat(); CV_Assert( dx >= 0 && dy >= 0 && dx+dy == 1 ); for( int k = 0; k < 2; k++ ) { Mat* kernel = k == 0 ? &kx : &ky; int order = k == 0 ? dx : dy; int kerI[3]; if( order == 0 ) kerI[0] = 3, kerI[1] = 10, kerI[2] = 3; else if( order == 1 ) kerI[0] = -1, kerI[1] = 0, kerI[2] = 1; Mat temp(kernel->rows, kernel->cols, CV_32S, &kerI[0]); double scale = !normalize || order == 1 ? 1. : 1./32; temp.convertTo(*kernel, ktype, scale); } } static void getSobelKernels( OutputArray _kx, OutputArray _ky, int dx, int dy, int _ksize, bool normalize, int ktype ) { int i, j, ksizeX = _ksize, ksizeY = _ksize; if( ksizeX == 1 && dx > 0 ) ksizeX = 3; if( ksizeY == 1 && dy > 0 ) ksizeY = 3; CV_Assert( ktype == CV_32F || ktype == CV_64F ); _kx.create(ksizeX, 1, ktype, -1, true); _ky.create(ksizeY, 1, ktype, -1, true); Mat kx = _kx.getMat(); Mat ky = _ky.getMat(); if( _ksize % 2 == 0 || _ksize > 31 ) CV_Error( CV_StsOutOfRange, "The kernel size must be odd and not larger than 31" ); std::vector kerI(std::max(ksizeX, ksizeY) + 1); CV_Assert( dx >= 0 && dy >= 0 && dx+dy > 0 ); for( int k = 0; k < 2; k++ ) { Mat* kernel = k == 0 ? &kx : &ky; int order = k == 0 ? dx : dy; int ksize = k == 0 ? ksizeX : ksizeY; CV_Assert( ksize > order ); if( ksize == 1 ) kerI[0] = 1; else if( ksize == 3 ) { if( order == 0 ) kerI[0] = 1, kerI[1] = 2, kerI[2] = 1; else if( order == 1 ) kerI[0] = -1, kerI[1] = 0, kerI[2] = 1; else kerI[0] = 1, kerI[1] = -2, kerI[2] = 1; } else { int oldval, newval; kerI[0] = 1; for( i = 0; i < ksize; i++ ) kerI[i+1] = 0; for( i = 0; i < ksize - order - 1; i++ ) { oldval = kerI[0]; for( j = 1; j <= ksize; j++ ) { newval = kerI[j]+kerI[j-1]; kerI[j-1] = oldval; oldval = newval; } } for( i = 0; i < order; i++ ) { oldval = -kerI[0]; for( j = 1; j <= ksize; j++ ) { newval = kerI[j-1] - kerI[j]; kerI[j-1] = oldval; oldval = newval; } } } Mat temp(kernel->rows, kernel->cols, CV_32S, &kerI[0]); double scale = !normalize ? 1. : 1./(1 << (ksize-order-1)); temp.convertTo(*kernel, ktype, scale); } } } void cv::getDerivKernels( OutputArray kx, OutputArray ky, int dx, int dy, int ksize, bool normalize, int ktype ) { if( ksize <= 0 ) getScharrKernels( kx, ky, dx, dy, normalize, ktype ); else getSobelKernels( kx, ky, dx, dy, ksize, normalize, ktype ); } cv::Ptr cv::createDerivFilter(int srcType, int dstType, int dx, int dy, int ksize, int borderType ) { Mat kx, ky; getDerivKernels( kx, ky, dx, dy, ksize, false, CV_32F ); return createSeparableLinearFilter(srcType, dstType, kx, ky, Point(-1,-1), 0, borderType ); } #if defined (HAVE_IPP) && (IPP_VERSION_MAJOR >= 7) #define IPP_RETURN_ERROR {setIppErrorStatus(); return false;} namespace cv { #if IPP_VERSION_X100 >= 801 static bool IPPDerivScharr(InputArray _src, OutputArray _dst, int ddepth, int dx, int dy, double scale, double delta, int borderType) { if ((0 > dx) || (0 > dy) || (1 != dx + dy)) return false; if (fabs(delta) > FLT_EPSILON) return false; IppiBorderType ippiBorderType = ippiGetBorderType(borderType & (~BORDER_ISOLATED)); if ((int)ippiBorderType < 0) return false; int stype = _src.type(), sdepth = CV_MAT_DEPTH(stype), cn = CV_MAT_CN(stype); if (ddepth < 0) ddepth = sdepth; int dtype = CV_MAKETYPE(ddepth, cn); Mat src = _src.getMat(); if (0 == (BORDER_ISOLATED & borderType)) { Size size; Point offset; src.locateROI(size, offset); if (0 < offset.x) ippiBorderType = (IppiBorderType)(ippiBorderType | ippBorderInMemLeft); if (0 < offset.y) ippiBorderType = (IppiBorderType)(ippiBorderType | ippBorderInMemTop); if (offset.x + src.cols < size.width) ippiBorderType = (IppiBorderType)(ippiBorderType | ippBorderInMemRight); if (offset.y + src.rows < size.height) ippiBorderType = (IppiBorderType)(ippiBorderType | ippBorderInMemBottom); } bool horz = (0 == dx) && (1 == dy); IppiSize roiSize = {src.cols, src.rows}; _dst.create( _src.size(), dtype); Mat dst = _dst.getMat(); IppStatus sts = ippStsErr; if ((CV_8U == stype) && (CV_16S == dtype)) { int bufferSize = 0; Ipp8u *pBuffer; if (horz) { if (0 > ippiFilterScharrHorizMaskBorderGetBufferSize(roiSize, ippMskSize3x3, ipp8u, ipp16s, 1, &bufferSize)) IPP_RETURN_ERROR pBuffer = ippsMalloc_8u(bufferSize); if (NULL == pBuffer) IPP_RETURN_ERROR sts = ippiFilterScharrHorizMaskBorder_8u16s_C1R(src.ptr(), (int)src.step, dst.ptr(), (int)dst.step, roiSize, ippMskSize3x3, ippiBorderType, 0, pBuffer); } else { if (0 > ippiFilterScharrVertMaskBorderGetBufferSize(roiSize, ippMskSize3x3, ipp8u, ipp16s, 1, &bufferSize)) IPP_RETURN_ERROR pBuffer = ippsMalloc_8u(bufferSize); if (NULL == pBuffer) IPP_RETURN_ERROR sts = ippiFilterScharrVertMaskBorder_8u16s_C1R(src.ptr(), (int)src.step, dst.ptr(), (int)dst.step, roiSize, ippMskSize3x3, ippiBorderType, 0, pBuffer); } ippsFree(pBuffer); } else if ((CV_16S == stype) && (CV_16S == dtype)) { int bufferSize = 0; Ipp8u *pBuffer; if (horz) { if (0 > ippiFilterScharrHorizMaskBorderGetBufferSize(roiSize, ippMskSize3x3, ipp16s, ipp16s, 1, &bufferSize)) IPP_RETURN_ERROR pBuffer = ippsMalloc_8u(bufferSize); if (NULL == pBuffer) IPP_RETURN_ERROR sts = ippiFilterScharrHorizMaskBorder_16s_C1R(src.ptr(), (int)src.step, dst.ptr(), (int)dst.step, roiSize, ippMskSize3x3, ippiBorderType, 0, pBuffer); } else { if (0 > ippiFilterScharrVertMaskBorderGetBufferSize(roiSize, ippMskSize3x3, ipp16s, ipp16s, 1, &bufferSize)) IPP_RETURN_ERROR pBuffer = ippsMalloc_8u(bufferSize); if (NULL == pBuffer) IPP_RETURN_ERROR sts = ippiFilterScharrVertMaskBorder_16s_C1R(src.ptr(), (int)src.step, dst.ptr(), (int)dst.step, roiSize, ippMskSize3x3, ippiBorderType, 0, pBuffer); } ippsFree(pBuffer); } else if ((CV_32F == stype) && (CV_32F == dtype)) { int bufferSize = 0; Ipp8u *pBuffer; if (horz) { if (0 > ippiFilterScharrHorizMaskBorderGetBufferSize(roiSize, ippMskSize3x3, ipp32f, ipp32f, 1, &bufferSize)) IPP_RETURN_ERROR pBuffer = ippsMalloc_8u(bufferSize); if (NULL == pBuffer) IPP_RETURN_ERROR sts = ippiFilterScharrHorizMaskBorder_32f_C1R(src.ptr(), (int)src.step, dst.ptr(), (int)dst.step, roiSize, ippMskSize3x3, ippiBorderType, 0, pBuffer); } else { if (0 > ippiFilterScharrVertMaskBorderGetBufferSize(roiSize, ippMskSize3x3, ipp32f, ipp32f, 1, &bufferSize)) IPP_RETURN_ERROR pBuffer = ippsMalloc_8u(bufferSize); if (NULL == pBuffer) IPP_RETURN_ERROR sts = ippiFilterScharrVertMaskBorder_32f_C1R(src.ptr(), (int)src.step, dst.ptr(), (int)dst.step, roiSize, ippMskSize3x3, ippiBorderType, 0, pBuffer); } ippsFree(pBuffer); if (sts < 0) IPP_RETURN_ERROR; if (FLT_EPSILON < fabs(scale - 1.0)) sts = ippiMulC_32f_C1R(dst.ptr(), (int)dst.step, (Ipp32f)scale, dst.ptr(), (int)dst.step, roiSize); } return (0 <= sts); } #elif IPP_VERSION_X100 >= 700 static bool IPPDerivScharr(InputArray _src, OutputArray _dst, int ddepth, int dx, int dy, double scale, double delta, int borderType) { if (BORDER_REPLICATE != borderType) return false; if ((0 > dx) || (0 > dy) || (1 != dx + dy)) return false; if (fabs(delta) > FLT_EPSILON) return false; Mat src = _src.getMat(), dst = _dst.getMat(); int bufSize = 0; cv::AutoBuffer buffer; IppiSize roi = ippiSize(src.cols, src.rows); if( ddepth < 0 ) ddepth = src.depth(); dst.create( src.size(), CV_MAKETYPE(ddepth, src.channels()) ); switch(src.type()) { case CV_8UC1: { if(scale != 1) return false; switch(dst.type()) { case CV_16S: { if ((dx == 1) && (dy == 0)) { if (0 > ippiFilterScharrVertGetBufferSize_8u16s_C1R(roi,&bufSize)) return false; buffer.allocate(bufSize); return (0 <= ippiFilterScharrVertBorder_8u16s_C1R(src.ptr(), (int)src.step, dst.ptr(), (int)dst.step, roi, ippBorderRepl, 0, (Ipp8u*)(char*)buffer)); } if ((dx == 0) && (dy == 1)) { if (0 > ippiFilterScharrHorizGetBufferSize_8u16s_C1R(roi,&bufSize)) return false; buffer.allocate(bufSize); return (0 <= ippiFilterScharrHorizBorder_8u16s_C1R(src.ptr(), (int)src.step, dst.ptr(), (int)dst.step, roi, ippBorderRepl, 0, (Ipp8u*)(char*)buffer)); } return false; } default: return false; } } case CV_32FC1: { switch(dst.type()) { case CV_32FC1: { if ((dx == 1) && (dy == 0)) { if (0 > ippiFilterScharrVertGetBufferSize_32f_C1R(ippiSize(src.cols, src.rows),&bufSize)) return false; buffer.allocate(bufSize); if (0 > ippiFilterScharrVertBorder_32f_C1R(src.ptr(), (int)src.step, dst.ptr(), (int)dst.step, ippiSize(src.cols, src.rows), ippBorderRepl, 0, (Ipp8u*)(char*)buffer)) { return false; } if (scale != 1) /* IPP is fast, so MulC produce very little perf degradation.*/ //ippiMulC_32f_C1IR((Ipp32f)scale, dst.ptr(), (int)dst.step, ippiSize(dst.cols*dst.channels(), dst.rows)); ippiMulC_32f_C1R(dst.ptr(), (int)dst.step, (Ipp32f)scale, dst.ptr(), (int)dst.step, ippiSize(dst.cols*dst.channels(), dst.rows)); return true; } if ((dx == 0) && (dy == 1)) { if (0 > ippiFilterScharrHorizGetBufferSize_32f_C1R(ippiSize(src.cols, src.rows),&bufSize)) return false; buffer.allocate(bufSize); if (0 > ippiFilterScharrHorizBorder_32f_C1R(src.ptr(), (int)src.step, dst.ptr(), (int)dst.step, ippiSize(src.cols, src.rows), ippBorderRepl, 0, (Ipp8u*)(char*)buffer)) return false; if (scale != 1) ippiMulC_32f_C1R(dst.ptr(), (int)dst.step, (Ipp32f)scale, dst.ptr(), (int)dst.step, ippiSize(dst.cols*dst.channels(), dst.rows)); return true; } } default: return false; } } default: return false; } } #endif static bool IPPDerivSobel(InputArray _src, OutputArray _dst, int ddepth, int dx, int dy, int ksize, double scale, double delta, int borderType) { if ((borderType != BORDER_REPLICATE) || ((3 != ksize) && (5 != ksize))) return false; if (fabs(delta) > FLT_EPSILON) return false; if (1 != _src.channels()) return false; int bufSize = 0; cv::AutoBuffer buffer; Mat src = _src.getMat(), dst = _dst.getMat(); if ( ddepth < 0 ) ddepth = src.depth(); if (src.type() == CV_8U && dst.type() == CV_16S && scale == 1) { if ((dx == 1) && (dy == 0)) { if (0 > ippiFilterSobelNegVertGetBufferSize_8u16s_C1R(ippiSize(src.cols, src.rows), (IppiMaskSize)(ksize*10+ksize),&bufSize)) IPP_RETURN_ERROR buffer.allocate(bufSize); if (0 > ippiFilterSobelNegVertBorder_8u16s_C1R(src.ptr(), (int)src.step, dst.ptr(), (int)dst.step, ippiSize(src.cols, src.rows), (IppiMaskSize)(ksize*10+ksize), ippBorderRepl, 0, (Ipp8u*)(char*)buffer)) IPP_RETURN_ERROR return true; } if ((dx == 0) && (dy == 1)) { if (0 > ippiFilterSobelHorizGetBufferSize_8u16s_C1R(ippiSize(src.cols, src.rows), (IppiMaskSize)(ksize*10+ksize),&bufSize)) IPP_RETURN_ERROR buffer.allocate(bufSize); if (0 > ippiFilterSobelHorizBorder_8u16s_C1R(src.ptr(), (int)src.step, dst.ptr(), (int)dst.step, ippiSize(src.cols, src.rows), (IppiMaskSize)(ksize*10+ksize), ippBorderRepl, 0, (Ipp8u*)(char*)buffer)) IPP_RETURN_ERROR return true; } #if !defined(HAVE_IPP_ICV_ONLY) if ((dx == 2) && (dy == 0)) { if (0 > ippiFilterSobelVertSecondGetBufferSize_8u16s_C1R(ippiSize(src.cols, src.rows), (IppiMaskSize)(ksize*10+ksize),&bufSize)) IPP_RETURN_ERROR buffer.allocate(bufSize); if (0 > ippiFilterSobelVertSecondBorder_8u16s_C1R(src.ptr(), (int)src.step, dst.ptr(), (int)dst.step, ippiSize(src.cols, src.rows), (IppiMaskSize)(ksize*10+ksize), ippBorderRepl, 0, (Ipp8u*)(char*)buffer)) IPP_RETURN_ERROR return true; } if ((dx == 0) && (dy == 2)) { if (0 > ippiFilterSobelHorizSecondGetBufferSize_8u16s_C1R(ippiSize(src.cols, src.rows), (IppiMaskSize)(ksize*10+ksize),&bufSize)) IPP_RETURN_ERROR buffer.allocate(bufSize); if (0 > ippiFilterSobelHorizSecondBorder_8u16s_C1R(src.ptr(), (int)src.step, dst.ptr(), (int)dst.step, ippiSize(src.cols, src.rows), (IppiMaskSize)(ksize*10+ksize), ippBorderRepl, 0, (Ipp8u*)(char*)buffer)) IPP_RETURN_ERROR return true; } #endif } if (src.type() == CV_32F && dst.type() == CV_32F) { #if 0 if ((dx == 1) && (dy == 0)) { if (0 > ippiFilterSobelNegVertGetBufferSize_32f_C1R(ippiSize(src.cols, src.rows), (IppiMaskSize)(ksize*10+ksize), &bufSize)) IPP_RETURN_ERROR buffer.allocate(bufSize); if (0 > ippiFilterSobelNegVertBorder_32f_C1R(src.ptr(), (int)src.step, dst.ptr(), (int)dst.step, ippiSize(src.cols, src.rows), (IppiMaskSize)(ksize*10+ksize), ippBorderRepl, 0, (Ipp8u*)(char*)buffer)) IPP_RETURN_ERROR if(scale != 1) ippiMulC_32f_C1R(dst.ptr(), (int)dst.step, (Ipp32f)scale, dst.ptr(), (int)dst.step, ippiSize(dst.cols*dst.channels(), dst.rows)); return true; } if ((dx == 0) && (dy == 1)) { if (0 > ippiFilterSobelHorizGetBufferSize_32f_C1R(ippiSize(src.cols, src.rows), (IppiMaskSize)(ksize*10+ksize),&bufSize)) IPP_RETURN_ERROR buffer.allocate(bufSize); if (0 > ippiFilterSobelHorizBorder_32f_C1R(src.ptr(), (int)src.step, dst.ptr(), (int)dst.step, ippiSize(src.cols, src.rows), (IppiMaskSize)(ksize*10+ksize), ippBorderRepl, 0, (Ipp8u*)(char*)buffer)) IPP_RETURN_ERROR if(scale != 1) ippiMulC_32f_C1R(dst.ptr(), (int)dst.step, (Ipp32f)scale, dst.ptr(), (int)dst.step, ippiSize(dst.cols*dst.channels(), dst.rows)); return true; } #endif #if !defined(HAVE_IPP_ICV_ONLY) if((dx == 2) && (dy == 0)) { if (0 > ippiFilterSobelVertSecondGetBufferSize_32f_C1R(ippiSize(src.cols, src.rows), (IppiMaskSize)(ksize*10+ksize),&bufSize)) IPP_RETURN_ERROR buffer.allocate(bufSize); if (0 > ippiFilterSobelVertSecondBorder_32f_C1R(src.ptr(), (int)src.step, dst.ptr(), (int)dst.step, ippiSize(src.cols, src.rows), (IppiMaskSize)(ksize*10+ksize), ippBorderRepl, 0, (Ipp8u*)(char*)buffer)) IPP_RETURN_ERROR if(scale != 1) ippiMulC_32f_C1R(dst.ptr(), (int)dst.step, (Ipp32f)scale, dst.ptr(), (int)dst.step, ippiSize(dst.cols*dst.channels(), dst.rows)); return true; } if((dx == 0) && (dy == 2)) { if (0 > ippiFilterSobelHorizSecondGetBufferSize_32f_C1R(ippiSize(src.cols, src.rows), (IppiMaskSize)(ksize*10+ksize),&bufSize)) IPP_RETURN_ERROR buffer.allocate(bufSize); if (0 > ippiFilterSobelHorizSecondBorder_32f_C1R(src.ptr(), (int)src.step, dst.ptr(), (int)dst.step, ippiSize(src.cols, src.rows), (IppiMaskSize)(ksize*10+ksize), ippBorderRepl, 0, (Ipp8u*)(char*)buffer)) IPP_RETURN_ERROR if(scale != 1) ippiMulC_32f_C1R(dst.ptr(), (int)dst.step, (Ipp32f)scale, dst.ptr(), (int)dst.step, ippiSize(dst.cols*dst.channels(), dst.rows)); return true; } #endif } return false; } } #endif void cv::Sobel( InputArray _src, OutputArray _dst, int ddepth, int dx, int dy, int ksize, double scale, double delta, int borderType ) { int stype = _src.type(), sdepth = CV_MAT_DEPTH(stype), cn = CV_MAT_CN(stype); if (ddepth < 0) ddepth = sdepth; int dtype = CV_MAKE_TYPE(ddepth, cn); _dst.create( _src.size(), dtype ); #ifdef HAVE_TEGRA_OPTIMIZATION if (tegra::useTegra() && scale == 1.0 && delta == 0) { Mat src = _src.getMat(), dst = _dst.getMat(); if (ksize == 3 && tegra::sobel3x3(src, dst, dx, dy, borderType)) return; if (ksize == -1 && tegra::scharr(src, dst, dx, dy, borderType)) return; } #endif #ifdef HAVE_IPP CV_IPP_CHECK() { if (ksize < 0) { if (IPPDerivScharr(_src, _dst, ddepth, dx, dy, scale, delta, borderType)) { CV_IMPL_ADD(CV_IMPL_IPP); return; } } else if (0 < ksize) { if (IPPDerivSobel(_src, _dst, ddepth, dx, dy, ksize, scale, delta, borderType)) { CV_IMPL_ADD(CV_IMPL_IPP); return; } } } #endif int ktype = std::max(CV_32F, std::max(ddepth, sdepth)); Mat kx, ky; getDerivKernels( kx, ky, dx, dy, ksize, false, ktype ); if( scale != 1 ) { // usually the smoothing part is the slowest to compute, // so try to scale it instead of the faster differenciating part if( dx == 0 ) kx *= scale; else ky *= scale; } sepFilter2D( _src, _dst, ddepth, kx, ky, Point(-1, -1), delta, borderType ); } void cv::Scharr( InputArray _src, OutputArray _dst, int ddepth, int dx, int dy, double scale, double delta, int borderType ) { int stype = _src.type(), sdepth = CV_MAT_DEPTH(stype), cn = CV_MAT_CN(stype); if (ddepth < 0) ddepth = sdepth; int dtype = CV_MAKETYPE(ddepth, cn); _dst.create( _src.size(), dtype ); #ifdef HAVE_TEGRA_OPTIMIZATION if (tegra::useTegra() && scale == 1.0 && delta == 0) { Mat src = _src.getMat(), dst = _dst.getMat(); if (tegra::scharr(src, dst, dx, dy, borderType)) return; } #endif #if defined (HAVE_IPP) && (IPP_VERSION_MAJOR >= 7) CV_IPP_CHECK() { if (IPPDerivScharr(_src, _dst, ddepth, dx, dy, scale, delta, borderType)) { CV_IMPL_ADD(CV_IMPL_IPP); return; } } #endif int ktype = std::max(CV_32F, std::max(ddepth, sdepth)); Mat kx, ky; getScharrKernels( kx, ky, dx, dy, false, ktype ); if( scale != 1 ) { // usually the smoothing part is the slowest to compute, // so try to scale it instead of the faster differenciating part if( dx == 0 ) kx *= scale; else ky *= scale; } sepFilter2D( _src, _dst, ddepth, kx, ky, Point(-1, -1), delta, borderType ); } #ifdef HAVE_OPENCL namespace cv { #define LAPLACIAN_LOCAL_MEM(tileX, tileY, ksize, elsize) (((tileX) + 2 * (int)((ksize) / 2)) * (3 * (tileY) + 2 * (int)((ksize) / 2)) * elsize) static bool ocl_Laplacian5(InputArray _src, OutputArray _dst, const Mat & kd, const Mat & ks, double scale, double delta, int borderType, int depth, int ddepth) { const size_t tileSizeX = 16; const size_t tileSizeYmin = 8; const ocl::Device dev = ocl::Device::getDefault(); int stype = _src.type(); int sdepth = CV_MAT_DEPTH(stype), cn = CV_MAT_CN(stype), esz = CV_ELEM_SIZE(stype); bool doubleSupport = dev.doubleFPConfig() > 0; if (!doubleSupport && (sdepth == CV_64F || ddepth == CV_64F)) return false; Mat kernelX = kd.reshape(1, 1); if (kernelX.cols % 2 != 1) return false; Mat kernelY = ks.reshape(1, 1); if (kernelY.cols % 2 != 1) return false; CV_Assert(kernelX.cols == kernelY.cols); size_t wgs = dev.maxWorkGroupSize(); size_t lmsz = dev.localMemSize(); size_t src_step = _src.step(), src_offset = _src.offset(); const size_t tileSizeYmax = wgs / tileSizeX; // workaround for Nvidia: 3 channel vector type takes 4*elem_size in local memory int loc_mem_cn = dev.vendorID() == ocl::Device::VENDOR_NVIDIA && cn == 3 ? 4 : cn; if (((src_offset % src_step) % esz == 0) && ( (borderType == BORDER_CONSTANT || borderType == BORDER_REPLICATE) || ((borderType == BORDER_REFLECT || borderType == BORDER_WRAP || borderType == BORDER_REFLECT_101) && (_src.cols() >= (int) (kernelX.cols + tileSizeX) && _src.rows() >= (int) (kernelY.cols + tileSizeYmax))) ) && (tileSizeX * tileSizeYmin <= wgs) && (LAPLACIAN_LOCAL_MEM(tileSizeX, tileSizeYmin, kernelX.cols, loc_mem_cn * 4) <= lmsz) ) { Size size = _src.size(), wholeSize; Point origin; int dtype = CV_MAKE_TYPE(ddepth, cn); int wdepth = CV_32F; size_t tileSizeY = tileSizeYmax; while ((tileSizeX * tileSizeY > wgs) || (LAPLACIAN_LOCAL_MEM(tileSizeX, tileSizeY, kernelX.cols, loc_mem_cn * 4) > lmsz)) { tileSizeY /= 2; } size_t lt2[2] = { tileSizeX, tileSizeY}; size_t gt2[2] = { lt2[0] * (1 + (size.width - 1) / lt2[0]), lt2[1] }; char cvt[2][40]; const char * const borderMap[] = { "BORDER_CONSTANT", "BORDER_REPLICATE", "BORDER_REFLECT", "BORDER_WRAP", "BORDER_REFLECT_101" }; String opts = cv::format("-D BLK_X=%d -D BLK_Y=%d -D RADIUS=%d%s%s" " -D convertToWT=%s -D convertToDT=%s" " -D %s -D srcT1=%s -D dstT1=%s -D WT1=%s" " -D srcT=%s -D dstT=%s -D WT=%s" " -D CN=%d ", (int)lt2[0], (int)lt2[1], kernelX.cols / 2, ocl::kernelToStr(kernelX, wdepth, "KERNEL_MATRIX_X").c_str(), ocl::kernelToStr(kernelY, wdepth, "KERNEL_MATRIX_Y").c_str(), ocl::convertTypeStr(sdepth, wdepth, cn, cvt[0]), ocl::convertTypeStr(wdepth, ddepth, cn, cvt[1]), borderMap[borderType], ocl::typeToStr(sdepth), ocl::typeToStr(ddepth), ocl::typeToStr(wdepth), ocl::typeToStr(CV_MAKETYPE(sdepth, cn)), ocl::typeToStr(CV_MAKETYPE(ddepth, cn)), ocl::typeToStr(CV_MAKETYPE(wdepth, cn)), cn); ocl::Kernel k("laplacian", ocl::imgproc::laplacian5_oclsrc, opts); if (k.empty()) return false; UMat src = _src.getUMat(); _dst.create(size, dtype); UMat dst = _dst.getUMat(); int src_offset_x = static_cast((src_offset % src_step) / esz); int src_offset_y = static_cast(src_offset / src_step); src.locateROI(wholeSize, origin); k.args(ocl::KernelArg::PtrReadOnly(src), (int)src_step, src_offset_x, src_offset_y, wholeSize.height, wholeSize.width, ocl::KernelArg::WriteOnly(dst), static_cast(scale), static_cast(delta)); return k.run(2, gt2, lt2, false); } int iscale = cvRound(scale), idelta = cvRound(delta); bool floatCoeff = std::fabs(delta - idelta) > DBL_EPSILON || std::fabs(scale - iscale) > DBL_EPSILON; int wdepth = std::max(depth, floatCoeff ? CV_32F : CV_32S), kercn = 1; if (!doubleSupport && wdepth == CV_64F) return false; char cvt[2][40]; ocl::Kernel k("sumConvert", ocl::imgproc::laplacian5_oclsrc, format("-D ONLY_SUM_CONVERT " "-D srcT=%s -D WT=%s -D dstT=%s -D coeffT=%s -D wdepth=%d " "-D convertToWT=%s -D convertToDT=%s%s", ocl::typeToStr(CV_MAKE_TYPE(depth, kercn)), ocl::typeToStr(CV_MAKE_TYPE(wdepth, kercn)), ocl::typeToStr(CV_MAKE_TYPE(ddepth, kercn)), ocl::typeToStr(wdepth), wdepth, ocl::convertTypeStr(depth, wdepth, kercn, cvt[0]), ocl::convertTypeStr(wdepth, ddepth, kercn, cvt[1]), doubleSupport ? " -D DOUBLE_SUPPORT" : "")); if (k.empty()) return false; UMat d2x, d2y; sepFilter2D(_src, d2x, depth, kd, ks, Point(-1, -1), 0, borderType); sepFilter2D(_src, d2y, depth, ks, kd, Point(-1, -1), 0, borderType); UMat dst = _dst.getUMat(); ocl::KernelArg d2xarg = ocl::KernelArg::ReadOnlyNoSize(d2x), d2yarg = ocl::KernelArg::ReadOnlyNoSize(d2y), dstarg = ocl::KernelArg::WriteOnly(dst, cn, kercn); if (wdepth >= CV_32F) k.args(d2xarg, d2yarg, dstarg, (float)scale, (float)delta); else k.args(d2xarg, d2yarg, dstarg, iscale, idelta); size_t globalsize[] = { dst.cols * cn / kercn, dst.rows }; return k.run(2, globalsize, NULL, false); } } #endif void cv::Laplacian( InputArray _src, OutputArray _dst, int ddepth, int ksize, double scale, double delta, int borderType ) { int stype = _src.type(), sdepth = CV_MAT_DEPTH(stype), cn = CV_MAT_CN(stype); if (ddepth < 0) ddepth = sdepth; _dst.create( _src.size(), CV_MAKETYPE(ddepth, cn) ); #ifdef HAVE_IPP CV_IPP_CHECK() { if ((ksize == 3 || ksize == 5) && ((borderType & BORDER_ISOLATED) != 0 || !_src.isSubmatrix()) && ((stype == CV_8UC1 && ddepth == CV_16S) || (ddepth == CV_32F && stype == CV_32FC1)) && !ocl::useOpenCL()) { int iscale = saturate_cast(scale), idelta = saturate_cast(delta); bool floatScale = std::fabs(scale - iscale) > DBL_EPSILON, needScale = iscale != 1; bool floatDelta = std::fabs(delta - idelta) > DBL_EPSILON, needDelta = delta != 0; int borderTypeNI = borderType & ~BORDER_ISOLATED; Mat src = _src.getMat(), dst = _dst.getMat(); if (src.data != dst.data) { Ipp32s bufsize; IppStatus status = (IppStatus)-1; IppiSize roisize = { src.cols, src.rows }; IppiMaskSize masksize = ksize == 3 ? ippMskSize3x3 : ippMskSize5x5; IppiBorderType borderTypeIpp = ippiGetBorderType(borderTypeNI); #define IPP_FILTER_LAPLACIAN(ippsrctype, ippdsttype, ippfavor) \ do \ { \ if (borderTypeIpp >= 0 && ippiFilterLaplacianGetBufferSize_##ippfavor##_C1R(roisize, masksize, &bufsize) >= 0) \ { \ Ipp8u * buffer = ippsMalloc_8u(bufsize); \ status = ippiFilterLaplacianBorder_##ippfavor##_C1R(src.ptr(), (int)src.step, dst.ptr(), \ (int)dst.step, roisize, masksize, borderTypeIpp, 0, buffer); \ ippsFree(buffer); \ } \ } while ((void)0, 0) CV_SUPPRESS_DEPRECATED_START if (sdepth == CV_8U && ddepth == CV_16S && !floatScale && !floatDelta) { IPP_FILTER_LAPLACIAN(Ipp8u, Ipp16s, 8u16s); if (needScale && status >= 0) status = ippiMulC_16s_C1IRSfs((Ipp16s)iscale, dst.ptr(), (int)dst.step, roisize, 0); if (needDelta && status >= 0) status = ippiAddC_16s_C1IRSfs((Ipp16s)idelta, dst.ptr(), (int)dst.step, roisize, 0); } else if (sdepth == CV_32F && ddepth == CV_32F) { IPP_FILTER_LAPLACIAN(Ipp32f, Ipp32f, 32f); if (needScale && status >= 0) status = ippiMulC_32f_C1IR((Ipp32f)scale, dst.ptr(), (int)dst.step, roisize); if (needDelta && status >= 0) status = ippiAddC_32f_C1IR((Ipp32f)delta, dst.ptr(), (int)dst.step, roisize); } CV_SUPPRESS_DEPRECATED_END if (status >= 0) { CV_IMPL_ADD(CV_IMPL_IPP); return; } setIppErrorStatus(); } } #undef IPP_FILTER_LAPLACIAN } #endif #ifdef HAVE_TEGRA_OPTIMIZATION if (tegra::useTegra() && scale == 1.0 && delta == 0) { Mat src = _src.getMat(), dst = _dst.getMat(); if (ksize == 1 && tegra::laplace1(src, dst, borderType)) return; if (ksize == 3 && tegra::laplace3(src, dst, borderType)) return; if (ksize == 5 && tegra::laplace5(src, dst, borderType)) return; } #endif if( ksize == 1 || ksize == 3 ) { float K[2][9] = { { 0, 1, 0, 1, -4, 1, 0, 1, 0 }, { 2, 0, 2, 0, -8, 0, 2, 0, 2 } }; Mat kernel(3, 3, CV_32F, K[ksize == 3]); if( scale != 1 ) kernel *= scale; filter2D( _src, _dst, ddepth, kernel, Point(-1, -1), delta, borderType ); } else { int ktype = std::max(CV_32F, std::max(ddepth, sdepth)); int wdepth = sdepth == CV_8U && ksize <= 5 ? CV_16S : sdepth <= CV_32F ? CV_32F : CV_64F; int wtype = CV_MAKETYPE(wdepth, cn); Mat kd, ks; getSobelKernels( kd, ks, 2, 0, ksize, false, ktype ); CV_OCL_RUN(_dst.isUMat(), ocl_Laplacian5(_src, _dst, kd, ks, scale, delta, borderType, wdepth, ddepth)) const size_t STRIPE_SIZE = 1 << 14; Ptr fx = createSeparableLinearFilter(stype, wtype, kd, ks, Point(-1,-1), 0, borderType, borderType, Scalar() ); Ptr fy = createSeparableLinearFilter(stype, wtype, ks, kd, Point(-1,-1), 0, borderType, borderType, Scalar() ); Mat src = _src.getMat(), dst = _dst.getMat(); int y = fx->start(src), dsty = 0, dy = 0; fy->start(src); const uchar* sptr = src.ptr(y); int dy0 = std::min(std::max((int)(STRIPE_SIZE/(CV_ELEM_SIZE(stype)*src.cols)), 1), src.rows); Mat d2x( dy0 + kd.rows - 1, src.cols, wtype ); Mat d2y( dy0 + kd.rows - 1, src.cols, wtype ); for( ; dsty < src.rows; sptr += dy0*src.step, dsty += dy ) { fx->proceed( sptr, (int)src.step, dy0, d2x.ptr(), (int)d2x.step ); dy = fy->proceed( sptr, (int)src.step, dy0, d2y.ptr(), (int)d2y.step ); if( dy > 0 ) { Mat dstripe = dst.rowRange(dsty, dsty + dy); d2x.rows = d2y.rows = dy; // modify the headers, which should work d2x += d2y; d2x.convertTo( dstripe, ddepth, scale, delta ); } } } } ///////////////////////////////////////////////////////////////////////////////////////// CV_IMPL void cvSobel( const void* srcarr, void* dstarr, int dx, int dy, int aperture_size ) { cv::Mat src = cv::cvarrToMat(srcarr), dst = cv::cvarrToMat(dstarr); CV_Assert( src.size() == dst.size() && src.channels() == dst.channels() ); cv::Sobel( src, dst, dst.depth(), dx, dy, aperture_size, 1, 0, cv::BORDER_REPLICATE ); if( CV_IS_IMAGE(srcarr) && ((IplImage*)srcarr)->origin && dy % 2 != 0 ) dst *= -1; } CV_IMPL void cvLaplace( const void* srcarr, void* dstarr, int aperture_size ) { cv::Mat src = cv::cvarrToMat(srcarr), dst = cv::cvarrToMat(dstarr); CV_Assert( src.size() == dst.size() && src.channels() == dst.channels() ); cv::Laplacian( src, dst, dst.depth(), aperture_size, 1, 0, cv::BORDER_REPLICATE ); } /* End of file. */