/*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. // // // License Agreement // For Open Source Computer Vision Library // // Copyright (C) 2000-2008, Intel Corporation, all rights reserved. // Copyright (C) 2009, Willow Garage 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 the copyright holders 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.hpp" /* * This file includes the code, contributed by Simon Perreault * (the function icvMedianBlur_8u_O1) * * Constant-time median filtering -- http://nomis80.org/ctmf.html * Copyright (C) 2006 Simon Perreault * * Contact: * Laboratoire de vision et systemes numeriques * Pavillon Adrien-Pouliot * Universite Laval * Sainte-Foy, Quebec, Canada * G1K 7P4 * * perreaul@gel.ulaval.ca */ namespace cv { /****************************************************************************************\ Box Filter \****************************************************************************************/ template struct RowSum : public BaseRowFilter { RowSum( int _ksize, int _anchor ) : BaseRowFilter() { ksize = _ksize; anchor = _anchor; } virtual void operator()(const uchar* src, uchar* dst, int width, int cn) { const T* S = (const T*)src; ST* D = (ST*)dst; int i = 0, k, ksz_cn = ksize*cn; width = (width - 1)*cn; for( k = 0; k < cn; k++, S++, D++ ) { ST s = 0; for( i = 0; i < ksz_cn; i += cn ) s += S[i]; D[0] = s; for( i = 0; i < width; i += cn ) { s += S[i + ksz_cn] - S[i]; D[i+cn] = s; } } } }; template struct ColumnSum : public BaseColumnFilter { ColumnSum( int _ksize, int _anchor, double _scale ) : BaseColumnFilter() { ksize = _ksize; anchor = _anchor; scale = _scale; sumCount = 0; } virtual void reset() { sumCount = 0; } virtual void operator()(const uchar** src, uchar* dst, int dststep, int count, int width) { int i; ST* SUM; bool haveScale = scale != 1; double _scale = scale; if( width != (int)sum.size() ) { sum.resize(width); sumCount = 0; } SUM = &sum[0]; if( sumCount == 0 ) { for( i = 0; i < width; i++ ) SUM[i] = 0; for( ; sumCount < ksize - 1; sumCount++, src++ ) { const ST* Sp = (const ST*)src[0]; for( i = 0; i <= width - 2; i += 2 ) { ST s0 = SUM[i] + Sp[i], s1 = SUM[i+1] + Sp[i+1]; SUM[i] = s0; SUM[i+1] = s1; } for( ; i < width; i++ ) SUM[i] += Sp[i]; } } else { CV_Assert( sumCount == ksize-1 ); src += ksize-1; } for( ; count--; src++ ) { const ST* Sp = (const ST*)src[0]; const ST* Sm = (const ST*)src[1-ksize]; T* D = (T*)dst; if( haveScale ) { for( i = 0; i <= width - 2; i += 2 ) { ST s0 = SUM[i] + Sp[i], s1 = SUM[i+1] + Sp[i+1]; D[i] = saturate_cast(s0*_scale); D[i+1] = saturate_cast(s1*_scale); s0 -= Sm[i]; s1 -= Sm[i+1]; SUM[i] = s0; SUM[i+1] = s1; } for( ; i < width; i++ ) { ST s0 = SUM[i] + Sp[i]; D[i] = saturate_cast(s0*_scale); SUM[i] = s0 - Sm[i]; } } else { for( i = 0; i <= width - 2; i += 2 ) { ST s0 = SUM[i] + Sp[i], s1 = SUM[i+1] + Sp[i+1]; D[i] = saturate_cast(s0); D[i+1] = saturate_cast(s1); s0 -= Sm[i]; s1 -= Sm[i+1]; SUM[i] = s0; SUM[i+1] = s1; } for( ; i < width; i++ ) { ST s0 = SUM[i] + Sp[i]; D[i] = saturate_cast(s0); SUM[i] = s0 - Sm[i]; } } dst += dststep; } } double scale; int sumCount; std::vector sum; }; template<> struct ColumnSum : public BaseColumnFilter { ColumnSum( int _ksize, int _anchor, double _scale ) : BaseColumnFilter() { ksize = _ksize; anchor = _anchor; scale = _scale; sumCount = 0; } virtual void reset() { sumCount = 0; } virtual void operator()(const uchar** src, uchar* dst, int dststep, int count, int width) { int i; int* SUM; bool haveScale = scale != 1; double _scale = scale; #if CV_SSE2 bool haveSSE2 = checkHardwareSupport(CV_CPU_SSE2); #endif if( width != (int)sum.size() ) { sum.resize(width); sumCount = 0; } SUM = &sum[0]; if( sumCount == 0 ) { memset((void*)SUM, 0, width*sizeof(int)); for( ; sumCount < ksize - 1; sumCount++, src++ ) { const int* Sp = (const int*)src[0]; i = 0; #if CV_SSE2 if(haveSSE2) { for( ; i < width-4; i+=4 ) { __m128i _sum = _mm_loadu_si128((const __m128i*)(SUM+i)); __m128i _sp = _mm_loadu_si128((const __m128i*)(Sp+i)); _mm_storeu_si128((__m128i*)(SUM+i),_mm_add_epi32(_sum, _sp)); } } #endif for( ; i < width; i++ ) SUM[i] += Sp[i]; } } else { CV_Assert( sumCount == ksize-1 ); src += ksize-1; } for( ; count--; src++ ) { const int* Sp = (const int*)src[0]; const int* Sm = (const int*)src[1-ksize]; uchar* D = (uchar*)dst; if( haveScale ) { i = 0; #if CV_SSE2 if(haveSSE2) { const __m128 scale4 = _mm_set1_ps((float)_scale); for( ; i < width-8; i+=8 ) { __m128i _sm = _mm_loadu_si128((const __m128i*)(Sm+i)); __m128i _sm1 = _mm_loadu_si128((const __m128i*)(Sm+i+4)); __m128i _s0 = _mm_add_epi32(_mm_loadu_si128((const __m128i*)(SUM+i)), _mm_loadu_si128((const __m128i*)(Sp+i))); __m128i _s01 = _mm_add_epi32(_mm_loadu_si128((const __m128i*)(SUM+i+4)), _mm_loadu_si128((const __m128i*)(Sp+i+4))); __m128i _s0T = _mm_cvtps_epi32(_mm_mul_ps(scale4, _mm_cvtepi32_ps(_s0))); __m128i _s0T1 = _mm_cvtps_epi32(_mm_mul_ps(scale4, _mm_cvtepi32_ps(_s01))); _s0T = _mm_packs_epi32(_s0T, _s0T1); _mm_storel_epi64((__m128i*)(D+i), _mm_packus_epi16(_s0T, _s0T)); _mm_storeu_si128((__m128i*)(SUM+i), _mm_sub_epi32(_s0,_sm)); _mm_storeu_si128((__m128i*)(SUM+i+4),_mm_sub_epi32(_s01,_sm1)); } } #endif for( ; i < width; i++ ) { int s0 = SUM[i] + Sp[i]; D[i] = saturate_cast(s0*_scale); SUM[i] = s0 - Sm[i]; } } else { i = 0; #if CV_SSE2 if(haveSSE2) { for( ; i < width-8; i+=8 ) { __m128i _sm = _mm_loadu_si128((const __m128i*)(Sm+i)); __m128i _sm1 = _mm_loadu_si128((const __m128i*)(Sm+i+4)); __m128i _s0 = _mm_add_epi32(_mm_loadu_si128((const __m128i*)(SUM+i)), _mm_loadu_si128((const __m128i*)(Sp+i))); __m128i _s01 = _mm_add_epi32(_mm_loadu_si128((const __m128i*)(SUM+i+4)), _mm_loadu_si128((const __m128i*)(Sp+i+4))); __m128i _s0T = _mm_packs_epi32(_s0, _s01); _mm_storel_epi64((__m128i*)(D+i), _mm_packus_epi16(_s0T, _s0T)); _mm_storeu_si128((__m128i*)(SUM+i), _mm_sub_epi32(_s0,_sm)); _mm_storeu_si128((__m128i*)(SUM+i+4),_mm_sub_epi32(_s01,_sm1)); } } #endif for( ; i < width; i++ ) { int s0 = SUM[i] + Sp[i]; D[i] = saturate_cast(s0); SUM[i] = s0 - Sm[i]; } } dst += dststep; } } double scale; int sumCount; std::vector sum; }; template<> struct ColumnSum : public BaseColumnFilter { ColumnSum( int _ksize, int _anchor, double _scale ) : BaseColumnFilter() { ksize = _ksize; anchor = _anchor; scale = _scale; sumCount = 0; } virtual void reset() { sumCount = 0; } virtual void operator()(const uchar** src, uchar* dst, int dststep, int count, int width) { int i; int* SUM; bool haveScale = scale != 1; double _scale = scale; #if CV_SSE2 bool haveSSE2 = checkHardwareSupport(CV_CPU_SSE2); #endif if( width != (int)sum.size() ) { sum.resize(width); sumCount = 0; } SUM = &sum[0]; if( sumCount == 0 ) { memset((void*)SUM, 0, width*sizeof(int)); for( ; sumCount < ksize - 1; sumCount++, src++ ) { const int* Sp = (const int*)src[0]; i = 0; #if CV_SSE2 if(haveSSE2) { for( ; i < width-4; i+=4 ) { __m128i _sum = _mm_loadu_si128((const __m128i*)(SUM+i)); __m128i _sp = _mm_loadu_si128((const __m128i*)(Sp+i)); _mm_storeu_si128((__m128i*)(SUM+i),_mm_add_epi32(_sum, _sp)); } } #endif for( ; i < width; i++ ) SUM[i] += Sp[i]; } } else { CV_Assert( sumCount == ksize-1 ); src += ksize-1; } for( ; count--; src++ ) { const int* Sp = (const int*)src[0]; const int* Sm = (const int*)src[1-ksize]; short* D = (short*)dst; if( haveScale ) { i = 0; #if CV_SSE2 if(haveSSE2) { const __m128 scale4 = _mm_set1_ps((float)_scale); for( ; i < width-8; i+=8 ) { __m128i _sm = _mm_loadu_si128((const __m128i*)(Sm+i)); __m128i _sm1 = _mm_loadu_si128((const __m128i*)(Sm+i+4)); __m128i _s0 = _mm_add_epi32(_mm_loadu_si128((const __m128i*)(SUM+i)), _mm_loadu_si128((const __m128i*)(Sp+i))); __m128i _s01 = _mm_add_epi32(_mm_loadu_si128((const __m128i*)(SUM+i+4)), _mm_loadu_si128((const __m128i*)(Sp+i+4))); __m128i _s0T = _mm_cvtps_epi32(_mm_mul_ps(scale4, _mm_cvtepi32_ps(_s0))); __m128i _s0T1 = _mm_cvtps_epi32(_mm_mul_ps(scale4, _mm_cvtepi32_ps(_s01))); _mm_storeu_si128((__m128i*)(D+i), _mm_packs_epi32(_s0T, _s0T1)); _mm_storeu_si128((__m128i*)(SUM+i),_mm_sub_epi32(_s0,_sm)); _mm_storeu_si128((__m128i*)(SUM+i+4), _mm_sub_epi32(_s01,_sm1)); } } #endif for( ; i < width; i++ ) { int s0 = SUM[i] + Sp[i]; D[i] = saturate_cast(s0*_scale); SUM[i] = s0 - Sm[i]; } } else { i = 0; #if CV_SSE2 if(haveSSE2) { for( ; i < width-8; i+=8 ) { __m128i _sm = _mm_loadu_si128((const __m128i*)(Sm+i)); __m128i _sm1 = _mm_loadu_si128((const __m128i*)(Sm+i+4)); __m128i _s0 = _mm_add_epi32(_mm_loadu_si128((const __m128i*)(SUM+i)), _mm_loadu_si128((const __m128i*)(Sp+i))); __m128i _s01 = _mm_add_epi32(_mm_loadu_si128((const __m128i*)(SUM+i+4)), _mm_loadu_si128((const __m128i*)(Sp+i+4))); _mm_storeu_si128((__m128i*)(D+i), _mm_packs_epi32(_s0, _s01)); _mm_storeu_si128((__m128i*)(SUM+i), _mm_sub_epi32(_s0,_sm)); _mm_storeu_si128((__m128i*)(SUM+i+4),_mm_sub_epi32(_s01,_sm1)); } } #endif for( ; i < width; i++ ) { int s0 = SUM[i] + Sp[i]; D[i] = saturate_cast(s0); SUM[i] = s0 - Sm[i]; } } dst += dststep; } } double scale; int sumCount; std::vector sum; }; template<> struct ColumnSum : public BaseColumnFilter { ColumnSum( int _ksize, int _anchor, double _scale ) : BaseColumnFilter() { ksize = _ksize; anchor = _anchor; scale = _scale; sumCount = 0; } virtual void reset() { sumCount = 0; } virtual void operator()(const uchar** src, uchar* dst, int dststep, int count, int width) { int i; int* SUM; bool haveScale = scale != 1; double _scale = scale; #if CV_SSE2 bool haveSSE2 = checkHardwareSupport(CV_CPU_SSE2); #endif if( width != (int)sum.size() ) { sum.resize(width); sumCount = 0; } SUM = &sum[0]; if( sumCount == 0 ) { memset((void*)SUM, 0, width*sizeof(int)); for( ; sumCount < ksize - 1; sumCount++, src++ ) { const int* Sp = (const int*)src[0]; i = 0; #if CV_SSE2 if(haveSSE2) { for( ; i < width-4; i+=4 ) { __m128i _sum = _mm_loadu_si128((const __m128i*)(SUM+i)); __m128i _sp = _mm_loadu_si128((const __m128i*)(Sp+i)); _mm_storeu_si128((__m128i*)(SUM+i), _mm_add_epi32(_sum, _sp)); } } #endif for( ; i < width; i++ ) SUM[i] += Sp[i]; } } else { CV_Assert( sumCount == ksize-1 ); src += ksize-1; } for( ; count--; src++ ) { const int* Sp = (const int*)src[0]; const int* Sm = (const int*)src[1-ksize]; ushort* D = (ushort*)dst; if( haveScale ) { i = 0; #if CV_SSE2 if(haveSSE2) { const __m128 scale4 = _mm_set1_ps((float)_scale); const __m128i delta0 = _mm_set1_epi32(0x8000); const __m128i delta1 = _mm_set1_epi32(0x80008000); for( ; i < width-4; i+=4) { __m128i _sm = _mm_loadu_si128((const __m128i*)(Sm+i)); __m128i _s0 = _mm_add_epi32(_mm_loadu_si128((const __m128i*)(SUM+i)), _mm_loadu_si128((const __m128i*)(Sp+i))); __m128i _res = _mm_cvtps_epi32(_mm_mul_ps(scale4, _mm_cvtepi32_ps(_s0))); _res = _mm_sub_epi32(_res, delta0); _res = _mm_add_epi16(_mm_packs_epi32(_res, _res), delta1); _mm_storel_epi64((__m128i*)(D+i), _res); _mm_storeu_si128((__m128i*)(SUM+i), _mm_sub_epi32(_s0,_sm)); } } #endif for( ; i < width; i++ ) { int s0 = SUM[i] + Sp[i]; D[i] = saturate_cast(s0*_scale); SUM[i] = s0 - Sm[i]; } } else { i = 0; #if CV_SSE2 if(haveSSE2) { const __m128i delta0 = _mm_set1_epi32(0x8000); const __m128i delta1 = _mm_set1_epi32(0x80008000); for( ; i < width-4; i+=4 ) { __m128i _sm = _mm_loadu_si128((const __m128i*)(Sm+i)); __m128i _s0 = _mm_add_epi32(_mm_loadu_si128((const __m128i*)(SUM+i)), _mm_loadu_si128((const __m128i*)(Sp+i))); __m128i _res = _mm_sub_epi32(_s0, delta0); _res = _mm_add_epi16(_mm_packs_epi32(_res, _res), delta1); _mm_storel_epi64((__m128i*)(D+i), _res); _mm_storeu_si128((__m128i*)(SUM+i), _mm_sub_epi32(_s0,_sm)); } } #endif for( ; i < width; i++ ) { int s0 = SUM[i] + Sp[i]; D[i] = saturate_cast(s0); SUM[i] = s0 - Sm[i]; } } dst += dststep; } } double scale; int sumCount; std::vector sum; }; #ifdef HAVE_OPENCL #define DIVUP(total, grain) ((total + grain - 1) / (grain)) #define ROUNDUP(sz, n) ((sz) + (n) - 1 - (((sz) + (n) - 1) % (n))) static bool ocl_boxFilter( InputArray _src, OutputArray _dst, int ddepth, Size ksize, Point anchor, int borderType, bool normalize, bool sqr = false ) { const ocl::Device & dev = ocl::Device::getDefault(); int type = _src.type(), sdepth = CV_MAT_DEPTH(type), cn = CV_MAT_CN(type), esz = CV_ELEM_SIZE(type); bool doubleSupport = dev.doubleFPConfig() > 0; if (ddepth < 0) ddepth = sdepth; if (cn > 4 || (!doubleSupport && (sdepth == CV_64F || ddepth == CV_64F)) || _src.offset() % esz != 0 || _src.step() % esz != 0) return false; if (anchor.x < 0) anchor.x = ksize.width / 2; if (anchor.y < 0) anchor.y = ksize.height / 2; int computeUnits = ocl::Device::getDefault().maxComputeUnits(); float alpha = 1.0f / (ksize.height * ksize.width); Size size = _src.size(), wholeSize; bool isolated = (borderType & BORDER_ISOLATED) != 0; borderType &= ~BORDER_ISOLATED; int wdepth = std::max(CV_32F, std::max(ddepth, sdepth)), wtype = CV_MAKE_TYPE(wdepth, cn), dtype = CV_MAKE_TYPE(ddepth, cn); const char * const borderMap[] = { "BORDER_CONSTANT", "BORDER_REPLICATE", "BORDER_REFLECT", 0, "BORDER_REFLECT_101" }; size_t globalsize[2] = { size.width, size.height }; size_t localsize_general[2] = { 0, 1 }, * localsize = NULL; UMat src = _src.getUMat(); if (!isolated) { Point ofs; src.locateROI(wholeSize, ofs); } int h = isolated ? size.height : wholeSize.height; int w = isolated ? size.width : wholeSize.width; size_t maxWorkItemSizes[32]; ocl::Device::getDefault().maxWorkItemSizes(maxWorkItemSizes); int tryWorkItems = (int)maxWorkItemSizes[0]; ocl::Kernel kernel; if (dev.isIntel() && !(dev.type() & ocl::Device::TYPE_CPU) && ((ksize.width < 5 && ksize.height < 5 && esz <= 4) || (ksize.width == 5 && ksize.height == 5 && cn == 1))) { if (w < ksize.width || h < ksize.height) return false; // Figure out what vector size to use for loading the pixels. int pxLoadNumPixels = cn != 1 || size.width % 4 ? 1 : 4; int pxLoadVecSize = cn * pxLoadNumPixels; // Figure out how many pixels per work item to compute in X and Y // directions. Too many and we run out of registers. int pxPerWorkItemX = 1, pxPerWorkItemY = 1; if (cn <= 2 && ksize.width <= 4 && ksize.height <= 4) { pxPerWorkItemX = size.width % 8 ? size.width % 4 ? size.width % 2 ? 1 : 2 : 4 : 8; pxPerWorkItemY = size.height % 2 ? 1 : 2; } else if (cn < 4 || (ksize.width <= 4 && ksize.height <= 4)) { pxPerWorkItemX = size.width % 2 ? 1 : 2; pxPerWorkItemY = size.height % 2 ? 1 : 2; } globalsize[0] = size.width / pxPerWorkItemX; globalsize[1] = size.height / pxPerWorkItemY; // Need some padding in the private array for pixels int privDataWidth = ROUNDUP(pxPerWorkItemX + ksize.width - 1, pxLoadNumPixels); // Make the global size a nice round number so the runtime can pick // from reasonable choices for the workgroup size const int wgRound = 256; globalsize[0] = ROUNDUP(globalsize[0], wgRound); char build_options[1024], cvt[2][40]; sprintf(build_options, "-D cn=%d " "-D ANCHOR_X=%d -D ANCHOR_Y=%d -D KERNEL_SIZE_X=%d -D KERNEL_SIZE_Y=%d " "-D PX_LOAD_VEC_SIZE=%d -D PX_LOAD_NUM_PX=%d " "-D PX_PER_WI_X=%d -D PX_PER_WI_Y=%d -D PRIV_DATA_WIDTH=%d -D %s -D %s " "-D PX_LOAD_X_ITERATIONS=%d -D PX_LOAD_Y_ITERATIONS=%d " "-D srcT=%s -D srcT1=%s -D dstT=%s -D dstT1=%s -D WT=%s -D WT1=%s " "-D convertToWT=%s -D convertToDstT=%s%s%s -D OP_BOX_FILTER", cn, anchor.x, anchor.y, ksize.width, ksize.height, pxLoadVecSize, pxLoadNumPixels, pxPerWorkItemX, pxPerWorkItemY, privDataWidth, borderMap[borderType], isolated ? "BORDER_ISOLATED" : "NO_BORDER_ISOLATED", privDataWidth / pxLoadNumPixels, pxPerWorkItemY + ksize.height - 1, ocl::typeToStr(type), ocl::typeToStr(sdepth), ocl::typeToStr(dtype), ocl::typeToStr(ddepth), ocl::typeToStr(wtype), ocl::typeToStr(wdepth), ocl::convertTypeStr(sdepth, wdepth, cn, cvt[0]), ocl::convertTypeStr(wdepth, ddepth, cn, cvt[1]), normalize ? " -D NORMALIZE" : "", sqr ? " -D SQR" : ""); if (!kernel.create("filterSmall", cv::ocl::imgproc::filterSmall_oclsrc, build_options)) return false; } else { localsize = localsize_general; for ( ; ; ) { int BLOCK_SIZE_X = tryWorkItems, BLOCK_SIZE_Y = std::min(ksize.height * 10, size.height); while (BLOCK_SIZE_X > 32 && BLOCK_SIZE_X >= ksize.width * 2 && BLOCK_SIZE_X > size.width * 2) BLOCK_SIZE_X /= 2; while (BLOCK_SIZE_Y < BLOCK_SIZE_X / 8 && BLOCK_SIZE_Y * computeUnits * 32 < size.height) BLOCK_SIZE_Y *= 2; if (ksize.width > BLOCK_SIZE_X || w < ksize.width || h < ksize.height) return false; char cvt[2][50]; String opts = format("-D LOCAL_SIZE_X=%d -D BLOCK_SIZE_Y=%d -D ST=%s -D DT=%s -D WT=%s -D convertToDT=%s -D convertToWT=%s" " -D ANCHOR_X=%d -D ANCHOR_Y=%d -D KERNEL_SIZE_X=%d -D KERNEL_SIZE_Y=%d -D %s%s%s%s%s" " -D ST1=%s -D DT1=%s -D cn=%d", BLOCK_SIZE_X, BLOCK_SIZE_Y, ocl::typeToStr(type), ocl::typeToStr(CV_MAKE_TYPE(ddepth, cn)), ocl::typeToStr(CV_MAKE_TYPE(wdepth, cn)), ocl::convertTypeStr(wdepth, ddepth, cn, cvt[0]), ocl::convertTypeStr(sdepth, wdepth, cn, cvt[1]), anchor.x, anchor.y, ksize.width, ksize.height, borderMap[borderType], isolated ? " -D BORDER_ISOLATED" : "", doubleSupport ? " -D DOUBLE_SUPPORT" : "", normalize ? " -D NORMALIZE" : "", sqr ? " -D SQR" : "", ocl::typeToStr(sdepth), ocl::typeToStr(ddepth), cn); localsize[0] = BLOCK_SIZE_X; globalsize[0] = DIVUP(size.width, BLOCK_SIZE_X - (ksize.width - 1)) * BLOCK_SIZE_X; globalsize[1] = DIVUP(size.height, BLOCK_SIZE_Y); kernel.create("boxFilter", cv::ocl::imgproc::boxFilter_oclsrc, opts); if (kernel.empty()) return false; size_t kernelWorkGroupSize = kernel.workGroupSize(); if (localsize[0] <= kernelWorkGroupSize) break; if (BLOCK_SIZE_X < (int)kernelWorkGroupSize) return false; tryWorkItems = (int)kernelWorkGroupSize; } } _dst.create(size, CV_MAKETYPE(ddepth, cn)); UMat dst = _dst.getUMat(); int idxArg = kernel.set(0, ocl::KernelArg::PtrReadOnly(src)); idxArg = kernel.set(idxArg, (int)src.step); int srcOffsetX = (int)((src.offset % src.step) / src.elemSize()); int srcOffsetY = (int)(src.offset / src.step); int srcEndX = isolated ? srcOffsetX + size.width : wholeSize.width; int srcEndY = isolated ? srcOffsetY + size.height : wholeSize.height; idxArg = kernel.set(idxArg, srcOffsetX); idxArg = kernel.set(idxArg, srcOffsetY); idxArg = kernel.set(idxArg, srcEndX); idxArg = kernel.set(idxArg, srcEndY); idxArg = kernel.set(idxArg, ocl::KernelArg::WriteOnly(dst)); if (normalize) idxArg = kernel.set(idxArg, (float)alpha); return kernel.run(2, globalsize, localsize, false); } #undef ROUNDUP #endif } cv::Ptr cv::getRowSumFilter(int srcType, int sumType, int ksize, int anchor) { int sdepth = CV_MAT_DEPTH(srcType), ddepth = CV_MAT_DEPTH(sumType); CV_Assert( CV_MAT_CN(sumType) == CV_MAT_CN(srcType) ); if( anchor < 0 ) anchor = ksize/2; if( sdepth == CV_8U && ddepth == CV_32S ) return makePtr >(ksize, anchor); if( sdepth == CV_8U && ddepth == CV_64F ) return makePtr >(ksize, anchor); if( sdepth == CV_16U && ddepth == CV_32S ) return makePtr >(ksize, anchor); if( sdepth == CV_16U && ddepth == CV_64F ) return makePtr >(ksize, anchor); if( sdepth == CV_16S && ddepth == CV_32S ) return makePtr >(ksize, anchor); if( sdepth == CV_32S && ddepth == CV_32S ) return makePtr >(ksize, anchor); if( sdepth == CV_16S && ddepth == CV_64F ) return makePtr >(ksize, anchor); if( sdepth == CV_32F && ddepth == CV_64F ) return makePtr >(ksize, anchor); if( sdepth == CV_64F && ddepth == CV_64F ) return makePtr >(ksize, anchor); CV_Error_( CV_StsNotImplemented, ("Unsupported combination of source format (=%d), and buffer format (=%d)", srcType, sumType)); return Ptr(); } cv::Ptr cv::getColumnSumFilter(int sumType, int dstType, int ksize, int anchor, double scale) { int sdepth = CV_MAT_DEPTH(sumType), ddepth = CV_MAT_DEPTH(dstType); CV_Assert( CV_MAT_CN(sumType) == CV_MAT_CN(dstType) ); if( anchor < 0 ) anchor = ksize/2; if( ddepth == CV_8U && sdepth == CV_32S ) return makePtr >(ksize, anchor, scale); if( ddepth == CV_8U && sdepth == CV_64F ) return makePtr >(ksize, anchor, scale); if( ddepth == CV_16U && sdepth == CV_32S ) return makePtr >(ksize, anchor, scale); if( ddepth == CV_16U && sdepth == CV_64F ) return makePtr >(ksize, anchor, scale); if( ddepth == CV_16S && sdepth == CV_32S ) return makePtr >(ksize, anchor, scale); if( ddepth == CV_16S && sdepth == CV_64F ) return makePtr >(ksize, anchor, scale); if( ddepth == CV_32S && sdepth == CV_32S ) return makePtr >(ksize, anchor, scale); if( ddepth == CV_32F && sdepth == CV_32S ) return makePtr >(ksize, anchor, scale); if( ddepth == CV_32F && sdepth == CV_64F ) return makePtr >(ksize, anchor, scale); if( ddepth == CV_64F && sdepth == CV_32S ) return makePtr >(ksize, anchor, scale); if( ddepth == CV_64F && sdepth == CV_64F ) return makePtr >(ksize, anchor, scale); CV_Error_( CV_StsNotImplemented, ("Unsupported combination of sum format (=%d), and destination format (=%d)", sumType, dstType)); return Ptr(); } cv::Ptr cv::createBoxFilter( int srcType, int dstType, Size ksize, Point anchor, bool normalize, int borderType ) { int sdepth = CV_MAT_DEPTH(srcType); int cn = CV_MAT_CN(srcType), sumType = CV_64F; if( sdepth <= CV_32S && (!normalize || ksize.width*ksize.height <= (sdepth == CV_8U ? (1<<23) : sdepth == CV_16U ? (1 << 15) : (1 << 16))) ) sumType = CV_32S; sumType = CV_MAKETYPE( sumType, cn ); Ptr rowFilter = getRowSumFilter(srcType, sumType, ksize.width, anchor.x ); Ptr columnFilter = getColumnSumFilter(sumType, dstType, ksize.height, anchor.y, normalize ? 1./(ksize.width*ksize.height) : 1); return makePtr(Ptr(), rowFilter, columnFilter, srcType, dstType, sumType, borderType ); } void cv::boxFilter( InputArray _src, OutputArray _dst, int ddepth, Size ksize, Point anchor, bool normalize, int borderType ) { CV_OCL_RUN(_dst.isUMat(), ocl_boxFilter(_src, _dst, ddepth, ksize, anchor, borderType, normalize)) Mat src = _src.getMat(); 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) ); Mat dst = _dst.getMat(); if( borderType != BORDER_CONSTANT && normalize && (borderType & BORDER_ISOLATED) != 0 ) { if( src.rows == 1 ) ksize.height = 1; if( src.cols == 1 ) ksize.width = 1; } #ifdef HAVE_TEGRA_OPTIMIZATION if ( tegra::box(src, dst, ksize, anchor, normalize, borderType) ) return; #endif #if defined(HAVE_IPP) int ippBorderType = borderType & ~BORDER_ISOLATED; Point ocvAnchor, ippAnchor; ocvAnchor.x = anchor.x < 0 ? ksize.width / 2 : anchor.x; ocvAnchor.y = anchor.y < 0 ? ksize.height / 2 : anchor.y; ippAnchor.x = ksize.width / 2 - (ksize.width % 2 == 0 ? 1 : 0); ippAnchor.y = ksize.height / 2 - (ksize.height % 2 == 0 ? 1 : 0); if (normalize && !src.isSubmatrix() && ddepth == sdepth && (/*ippBorderType == BORDER_REPLICATE ||*/ /* returns ippStsStepErr: Step value is not valid */ ippBorderType == BORDER_CONSTANT) && ocvAnchor == ippAnchor ) { Ipp32s bufSize = 0; IppiSize roiSize = { dst.cols, dst.rows }, maskSize = { ksize.width, ksize.height }; #define IPP_FILTER_BOX_BORDER(ippType, ippDataType, flavor) \ do \ { \ if (ippiFilterBoxBorderGetBufferSize(roiSize, maskSize, ippDataType, cn, &bufSize) >= 0) \ { \ Ipp8u * buffer = ippsMalloc_8u(bufSize); \ ippType borderValue[4] = { 0, 0, 0, 0 }; \ ippBorderType = ippBorderType == BORDER_CONSTANT ? ippBorderConst : ippBorderRepl; \ IppStatus status = ippiFilterBoxBorder_##flavor((const ippType *)src.data, (int)src.step, (ippType *)dst.data, \ (int)dst.step, roiSize, maskSize, \ (IppiBorderType)ippBorderType, borderValue, buffer); \ ippsFree(buffer); \ if (status >= 0) \ return; \ } \ setIppErrorStatus(); \ } while ((void)0, 0) if (stype == CV_8UC1) IPP_FILTER_BOX_BORDER(Ipp8u, ipp8u, 8u_C1R); else if (stype == CV_8UC3) IPP_FILTER_BOX_BORDER(Ipp8u, ipp8u, 8u_C3R); else if (stype == CV_8UC4) IPP_FILTER_BOX_BORDER(Ipp8u, ipp8u, 8u_C4R); else if (stype == CV_16UC1) IPP_FILTER_BOX_BORDER(Ipp16u, ipp16u, 16u_C1R); else if (stype == CV_16UC3) IPP_FILTER_BOX_BORDER(Ipp16u, ipp16u, 16u_C3R); else if (stype == CV_16UC4) IPP_FILTER_BOX_BORDER(Ipp16u, ipp16u, 16u_C4R); else if (stype == CV_16SC1) IPP_FILTER_BOX_BORDER(Ipp16s, ipp16s, 16s_C1R); else if (stype == CV_16SC3) IPP_FILTER_BOX_BORDER(Ipp16s, ipp16s, 16s_C3R); else if (stype == CV_16SC4) IPP_FILTER_BOX_BORDER(Ipp16s, ipp16s, 16s_C4R); else if (stype == CV_32FC1) IPP_FILTER_BOX_BORDER(Ipp32f, ipp32f, 32f_C1R); else if (stype == CV_32FC3) IPP_FILTER_BOX_BORDER(Ipp32f, ipp32f, 32f_C3R); else if (stype == CV_32FC4) IPP_FILTER_BOX_BORDER(Ipp32f, ipp32f, 32f_C4R); } #undef IPP_FILTER_BOX_BORDER #endif Ptr f = createBoxFilter( src.type(), dst.type(), ksize, anchor, normalize, borderType ); f->apply( src, dst ); } void cv::blur( InputArray src, OutputArray dst, Size ksize, Point anchor, int borderType ) { boxFilter( src, dst, -1, ksize, anchor, true, borderType ); } /****************************************************************************************\ Squared Box Filter \****************************************************************************************/ namespace cv { template struct SqrRowSum : public BaseRowFilter { SqrRowSum( int _ksize, int _anchor ) : BaseRowFilter() { ksize = _ksize; anchor = _anchor; } virtual void operator()(const uchar* src, uchar* dst, int width, int cn) { const T* S = (const T*)src; ST* D = (ST*)dst; int i = 0, k, ksz_cn = ksize*cn; width = (width - 1)*cn; for( k = 0; k < cn; k++, S++, D++ ) { ST s = 0; for( i = 0; i < ksz_cn; i += cn ) { ST val = (ST)S[i]; s += val*val; } D[0] = s; for( i = 0; i < width; i += cn ) { ST val0 = (ST)S[i], val1 = (ST)S[i + ksz_cn]; s += val1*val1 - val0*val0; D[i+cn] = s; } } } }; static Ptr getSqrRowSumFilter(int srcType, int sumType, int ksize, int anchor) { int sdepth = CV_MAT_DEPTH(srcType), ddepth = CV_MAT_DEPTH(sumType); CV_Assert( CV_MAT_CN(sumType) == CV_MAT_CN(srcType) ); if( anchor < 0 ) anchor = ksize/2; if( sdepth == CV_8U && ddepth == CV_32S ) return makePtr >(ksize, anchor); if( sdepth == CV_8U && ddepth == CV_64F ) return makePtr >(ksize, anchor); if( sdepth == CV_16U && ddepth == CV_64F ) return makePtr >(ksize, anchor); if( sdepth == CV_16S && ddepth == CV_64F ) return makePtr >(ksize, anchor); if( sdepth == CV_32F && ddepth == CV_64F ) return makePtr >(ksize, anchor); if( sdepth == CV_64F && ddepth == CV_64F ) return makePtr >(ksize, anchor); CV_Error_( CV_StsNotImplemented, ("Unsupported combination of source format (=%d), and buffer format (=%d)", srcType, sumType)); return Ptr(); } } void cv::sqrBoxFilter( InputArray _src, OutputArray _dst, int ddepth, Size ksize, Point anchor, bool normalize, int borderType ) { int srcType = _src.type(), sdepth = CV_MAT_DEPTH(srcType), cn = CV_MAT_CN(srcType); Size size = _src.size(); if( ddepth < 0 ) ddepth = sdepth < CV_32F ? CV_32F : CV_64F; if( borderType != BORDER_CONSTANT && normalize ) { if( size.height == 1 ) ksize.height = 1; if( size.width == 1 ) ksize.width = 1; } CV_OCL_RUN(_dst.isUMat() && _src.dims() <= 2, ocl_boxFilter(_src, _dst, ddepth, ksize, anchor, borderType, normalize, true)) int sumDepth = CV_64F; if( sdepth == CV_8U ) sumDepth = CV_32S; int sumType = CV_MAKETYPE( sumDepth, cn ), dstType = CV_MAKETYPE(ddepth, cn); Mat src = _src.getMat(); _dst.create( size, dstType ); Mat dst = _dst.getMat(); Ptr rowFilter = getSqrRowSumFilter(srcType, sumType, ksize.width, anchor.x ); Ptr columnFilter = getColumnSumFilter(sumType, dstType, ksize.height, anchor.y, normalize ? 1./(ksize.width*ksize.height) : 1); Ptr f = makePtr(Ptr(), rowFilter, columnFilter, srcType, dstType, sumType, borderType ); f->apply( src, dst ); } /****************************************************************************************\ Gaussian Blur \****************************************************************************************/ cv::Mat cv::getGaussianKernel( int n, double sigma, int ktype ) { const int SMALL_GAUSSIAN_SIZE = 7; static const float small_gaussian_tab[][SMALL_GAUSSIAN_SIZE] = { {1.f}, {0.25f, 0.5f, 0.25f}, {0.0625f, 0.25f, 0.375f, 0.25f, 0.0625f}, {0.03125f, 0.109375f, 0.21875f, 0.28125f, 0.21875f, 0.109375f, 0.03125f} }; const float* fixed_kernel = n % 2 == 1 && n <= SMALL_GAUSSIAN_SIZE && sigma <= 0 ? small_gaussian_tab[n>>1] : 0; CV_Assert( ktype == CV_32F || ktype == CV_64F ); Mat kernel(n, 1, ktype); float* cf = (float*)kernel.data; double* cd = (double*)kernel.data; double sigmaX = sigma > 0 ? sigma : ((n-1)*0.5 - 1)*0.3 + 0.8; double scale2X = -0.5/(sigmaX*sigmaX); double sum = 0; int i; for( i = 0; i < n; i++ ) { double x = i - (n-1)*0.5; double t = fixed_kernel ? (double)fixed_kernel[i] : std::exp(scale2X*x*x); if( ktype == CV_32F ) { cf[i] = (float)t; sum += cf[i]; } else { cd[i] = t; sum += cd[i]; } } sum = 1./sum; for( i = 0; i < n; i++ ) { if( ktype == CV_32F ) cf[i] = (float)(cf[i]*sum); else cd[i] *= sum; } return kernel; } namespace cv { static void createGaussianKernels( Mat & kx, Mat & ky, int type, Size ksize, double sigma1, double sigma2 ) { int depth = CV_MAT_DEPTH(type); if( sigma2 <= 0 ) sigma2 = sigma1; // automatic detection of kernel size from sigma if( ksize.width <= 0 && sigma1 > 0 ) ksize.width = cvRound(sigma1*(depth == CV_8U ? 3 : 4)*2 + 1)|1; if( ksize.height <= 0 && sigma2 > 0 ) ksize.height = cvRound(sigma2*(depth == CV_8U ? 3 : 4)*2 + 1)|1; CV_Assert( ksize.width > 0 && ksize.width % 2 == 1 && ksize.height > 0 && ksize.height % 2 == 1 ); sigma1 = std::max( sigma1, 0. ); sigma2 = std::max( sigma2, 0. ); kx = getGaussianKernel( ksize.width, sigma1, std::max(depth, CV_32F) ); if( ksize.height == ksize.width && std::abs(sigma1 - sigma2) < DBL_EPSILON ) ky = kx; else ky = getGaussianKernel( ksize.height, sigma2, std::max(depth, CV_32F) ); } } cv::Ptr cv::createGaussianFilter( int type, Size ksize, double sigma1, double sigma2, int borderType ) { Mat kx, ky; createGaussianKernels(kx, ky, type, ksize, sigma1, sigma2); return createSeparableLinearFilter( type, type, kx, ky, Point(-1,-1), 0, borderType ); } void cv::GaussianBlur( InputArray _src, OutputArray _dst, Size ksize, double sigma1, double sigma2, int borderType ) { int type = _src.type(); Size size = _src.size(); _dst.create( size, type ); if( borderType != BORDER_CONSTANT && (borderType & BORDER_ISOLATED) != 0 ) { if( size.height == 1 ) ksize.height = 1; if( size.width == 1 ) ksize.width = 1; } if( ksize.width == 1 && ksize.height == 1 ) { _src.copyTo(_dst); return; } #ifdef HAVE_TEGRA_OPTIMIZATION if(sigma1 == 0 && sigma2 == 0 && tegra::gaussian(_src.getMat(), _dst.getMat(), ksize, borderType)) return; #endif #if IPP_VERSION_X100 >= 801 && 0 // these functions are slower in IPP 8.1 int depth = CV_MAT_DEPTH(type), cn = CV_MAT_CN(type); if ((depth == CV_8U || depth == CV_16U || depth == CV_16S || depth == CV_32F) && (cn == 1 || cn == 3) && sigma1 == sigma2 && ksize.width == ksize.height && sigma1 != 0.0 ) { IppiBorderType ippBorder = ippiGetBorderType(borderType); if (ippBorderConst == ippBorder || ippBorderRepl == ippBorder) { Mat src = _src.getMat(), dst = _dst.getMat(); IppiSize roiSize = { src.cols, src.rows }; IppDataType dataType = ippiGetDataType(depth); Ipp32s specSize = 0, bufferSize = 0; if (ippiFilterGaussianGetBufferSize(roiSize, (Ipp32u)ksize.width, dataType, cn, &specSize, &bufferSize) >= 0) { IppFilterGaussianSpec * pSpec = (IppFilterGaussianSpec *)ippMalloc(specSize); Ipp8u * pBuffer = (Ipp8u*)ippMalloc(bufferSize); if (ippiFilterGaussianInit(roiSize, (Ipp32u)ksize.width, (Ipp32f)sigma1, ippBorder, dataType, 1, pSpec, pBuffer) >= 0) { #define IPP_FILTER_GAUSS(ippfavor, ippcn) \ do \ { \ typedef Ipp##ippfavor ippType; \ ippType borderValues[] = { 0, 0, 0 }; \ IppStatus status = ippcn == 1 ? \ ippiFilterGaussianBorder_##ippfavor##_C1R((const ippType *)src.data, (int)src.step, \ (ippType *)dst.data, (int)dst.step, roiSize, borderValues[0], pSpec, pBuffer) : \ ippiFilterGaussianBorder_##ippfavor##_C3R((const ippType *)src.data, (int)src.step, \ (ippType *)dst.data, (int)dst.step, roiSize, borderValues, pSpec, pBuffer); \ ippFree(pBuffer); \ ippFree(pSpec); \ if (status >= 0) \ return; \ } while ((void)0, 0) if (type == CV_8UC1) IPP_FILTER_GAUSS(8u, 1); else if (type == CV_8UC3) IPP_FILTER_GAUSS(8u, 3); else if (type == CV_16UC1) IPP_FILTER_GAUSS(16u, 1); else if (type == CV_16UC3) IPP_FILTER_GAUSS(16u, 3); else if (type == CV_16SC1) IPP_FILTER_GAUSS(16s, 1); else if (type == CV_16SC3) IPP_FILTER_GAUSS(16s, 3); else if (type == CV_32FC1) IPP_FILTER_GAUSS(32f, 1); else if (type == CV_32FC3) IPP_FILTER_GAUSS(32f, 3); #undef IPP_FILTER_GAUSS } } setIppErrorStatus(); } } #endif Mat kx, ky; createGaussianKernels(kx, ky, type, ksize, sigma1, sigma2); sepFilter2D(_src, _dst, CV_MAT_DEPTH(type), kx, ky, Point(-1,-1), 0, borderType ); } /****************************************************************************************\ Median Filter \****************************************************************************************/ namespace cv { typedef ushort HT; /** * This structure represents a two-tier histogram. The first tier (known as the * "coarse" level) is 4 bit wide and the second tier (known as the "fine" level) * is 8 bit wide. Pixels inserted in the fine level also get inserted into the * coarse bucket designated by the 4 MSBs of the fine bucket value. * * The structure is aligned on 16 bits, which is a prerequisite for SIMD * instructions. Each bucket is 16 bit wide, which means that extra care must be * taken to prevent overflow. */ typedef struct { HT coarse[16]; HT fine[16][16]; } Histogram; #if CV_SSE2 #define MEDIAN_HAVE_SIMD 1 static inline void histogram_add_simd( const HT x[16], HT y[16] ) { const __m128i* rx = (const __m128i*)x; __m128i* ry = (__m128i*)y; __m128i r0 = _mm_add_epi16(_mm_load_si128(ry+0),_mm_load_si128(rx+0)); __m128i r1 = _mm_add_epi16(_mm_load_si128(ry+1),_mm_load_si128(rx+1)); _mm_store_si128(ry+0, r0); _mm_store_si128(ry+1, r1); } static inline void histogram_sub_simd( const HT x[16], HT y[16] ) { const __m128i* rx = (const __m128i*)x; __m128i* ry = (__m128i*)y; __m128i r0 = _mm_sub_epi16(_mm_load_si128(ry+0),_mm_load_si128(rx+0)); __m128i r1 = _mm_sub_epi16(_mm_load_si128(ry+1),_mm_load_si128(rx+1)); _mm_store_si128(ry+0, r0); _mm_store_si128(ry+1, r1); } #else #define MEDIAN_HAVE_SIMD 0 #endif static inline void histogram_add( const HT x[16], HT y[16] ) { int i; for( i = 0; i < 16; ++i ) y[i] = (HT)(y[i] + x[i]); } static inline void histogram_sub( const HT x[16], HT y[16] ) { int i; for( i = 0; i < 16; ++i ) y[i] = (HT)(y[i] - x[i]); } static inline void histogram_muladd( int a, const HT x[16], HT y[16] ) { for( int i = 0; i < 16; ++i ) y[i] = (HT)(y[i] + a * x[i]); } static void medianBlur_8u_O1( const Mat& _src, Mat& _dst, int ksize ) { /** * HOP is short for Histogram OPeration. This macro makes an operation \a op on * histogram \a h for pixel value \a x. It takes care of handling both levels. */ #define HOP(h,x,op) \ h.coarse[x>>4] op, \ *((HT*)h.fine + x) op #define COP(c,j,x,op) \ h_coarse[ 16*(n*c+j) + (x>>4) ] op, \ h_fine[ 16 * (n*(16*c+(x>>4)) + j) + (x & 0xF) ] op int cn = _dst.channels(), m = _dst.rows, r = (ksize-1)/2; size_t sstep = _src.step, dstep = _dst.step; Histogram CV_DECL_ALIGNED(16) H[4]; HT CV_DECL_ALIGNED(16) luc[4][16]; int STRIPE_SIZE = std::min( _dst.cols, 512/cn ); std::vector _h_coarse(1 * 16 * (STRIPE_SIZE + 2*r) * cn + 16); std::vector _h_fine(16 * 16 * (STRIPE_SIZE + 2*r) * cn + 16); HT* h_coarse = alignPtr(&_h_coarse[0], 16); HT* h_fine = alignPtr(&_h_fine[0], 16); #if MEDIAN_HAVE_SIMD volatile bool useSIMD = checkHardwareSupport(CV_CPU_SSE2); #endif for( int x = 0; x < _dst.cols; x += STRIPE_SIZE ) { int i, j, k, c, n = std::min(_dst.cols - x, STRIPE_SIZE) + r*2; const uchar* src = _src.data + x*cn; uchar* dst = _dst.data + (x - r)*cn; memset( h_coarse, 0, 16*n*cn*sizeof(h_coarse[0]) ); memset( h_fine, 0, 16*16*n*cn*sizeof(h_fine[0]) ); // First row initialization for( c = 0; c < cn; c++ ) { for( j = 0; j < n; j++ ) COP( c, j, src[cn*j+c], += (cv::HT)(r+2) ); for( i = 1; i < r; i++ ) { const uchar* p = src + sstep*std::min(i, m-1); for ( j = 0; j < n; j++ ) COP( c, j, p[cn*j+c], ++ ); } } for( i = 0; i < m; i++ ) { const uchar* p0 = src + sstep * std::max( 0, i-r-1 ); const uchar* p1 = src + sstep * std::min( m-1, i+r ); memset( H, 0, cn*sizeof(H[0]) ); memset( luc, 0, cn*sizeof(luc[0]) ); for( c = 0; c < cn; c++ ) { // Update column histograms for the entire row. for( j = 0; j < n; j++ ) { COP( c, j, p0[j*cn + c], -- ); COP( c, j, p1[j*cn + c], ++ ); } // First column initialization for( k = 0; k < 16; ++k ) histogram_muladd( 2*r+1, &h_fine[16*n*(16*c+k)], &H[c].fine[k][0] ); #if MEDIAN_HAVE_SIMD if( useSIMD ) { for( j = 0; j < 2*r; ++j ) histogram_add_simd( &h_coarse[16*(n*c+j)], H[c].coarse ); for( j = r; j < n-r; j++ ) { int t = 2*r*r + 2*r, b, sum = 0; HT* segment; histogram_add_simd( &h_coarse[16*(n*c + std::min(j+r,n-1))], H[c].coarse ); // Find median at coarse level for ( k = 0; k < 16 ; ++k ) { sum += H[c].coarse[k]; if ( sum > t ) { sum -= H[c].coarse[k]; break; } } assert( k < 16 ); /* Update corresponding histogram segment */ if ( luc[c][k] <= j-r ) { memset( &H[c].fine[k], 0, 16 * sizeof(HT) ); for ( luc[c][k] = cv::HT(j-r); luc[c][k] < MIN(j+r+1,n); ++luc[c][k] ) histogram_add_simd( &h_fine[16*(n*(16*c+k)+luc[c][k])], H[c].fine[k] ); if ( luc[c][k] < j+r+1 ) { histogram_muladd( j+r+1 - n, &h_fine[16*(n*(16*c+k)+(n-1))], &H[c].fine[k][0] ); luc[c][k] = (HT)(j+r+1); } } else { for ( ; luc[c][k] < j+r+1; ++luc[c][k] ) { histogram_sub_simd( &h_fine[16*(n*(16*c+k)+MAX(luc[c][k]-2*r-1,0))], H[c].fine[k] ); histogram_add_simd( &h_fine[16*(n*(16*c+k)+MIN(luc[c][k],n-1))], H[c].fine[k] ); } } histogram_sub_simd( &h_coarse[16*(n*c+MAX(j-r,0))], H[c].coarse ); /* Find median in segment */ segment = H[c].fine[k]; for ( b = 0; b < 16 ; b++ ) { sum += segment[b]; if ( sum > t ) { dst[dstep*i+cn*j+c] = (uchar)(16*k + b); break; } } assert( b < 16 ); } } else #endif { for( j = 0; j < 2*r; ++j ) histogram_add( &h_coarse[16*(n*c+j)], H[c].coarse ); for( j = r; j < n-r; j++ ) { int t = 2*r*r + 2*r, b, sum = 0; HT* segment; histogram_add( &h_coarse[16*(n*c + std::min(j+r,n-1))], H[c].coarse ); // Find median at coarse level for ( k = 0; k < 16 ; ++k ) { sum += H[c].coarse[k]; if ( sum > t ) { sum -= H[c].coarse[k]; break; } } assert( k < 16 ); /* Update corresponding histogram segment */ if ( luc[c][k] <= j-r ) { memset( &H[c].fine[k], 0, 16 * sizeof(HT) ); for ( luc[c][k] = cv::HT(j-r); luc[c][k] < MIN(j+r+1,n); ++luc[c][k] ) histogram_add( &h_fine[16*(n*(16*c+k)+luc[c][k])], H[c].fine[k] ); if ( luc[c][k] < j+r+1 ) { histogram_muladd( j+r+1 - n, &h_fine[16*(n*(16*c+k)+(n-1))], &H[c].fine[k][0] ); luc[c][k] = (HT)(j+r+1); } } else { for ( ; luc[c][k] < j+r+1; ++luc[c][k] ) { histogram_sub( &h_fine[16*(n*(16*c+k)+MAX(luc[c][k]-2*r-1,0))], H[c].fine[k] ); histogram_add( &h_fine[16*(n*(16*c+k)+MIN(luc[c][k],n-1))], H[c].fine[k] ); } } histogram_sub( &h_coarse[16*(n*c+MAX(j-r,0))], H[c].coarse ); /* Find median in segment */ segment = H[c].fine[k]; for ( b = 0; b < 16 ; b++ ) { sum += segment[b]; if ( sum > t ) { dst[dstep*i+cn*j+c] = (uchar)(16*k + b); break; } } assert( b < 16 ); } } } } } #undef HOP #undef COP } static void medianBlur_8u_Om( const Mat& _src, Mat& _dst, int m ) { #define N 16 int zone0[4][N]; int zone1[4][N*N]; int x, y; int n2 = m*m/2; Size size = _dst.size(); const uchar* src = _src.data; uchar* dst = _dst.data; int src_step = (int)_src.step, dst_step = (int)_dst.step; int cn = _src.channels(); const uchar* src_max = src + size.height*src_step; #define UPDATE_ACC01( pix, cn, op ) \ { \ int p = (pix); \ zone1[cn][p] op; \ zone0[cn][p >> 4] op; \ } //CV_Assert( size.height >= nx && size.width >= nx ); for( x = 0; x < size.width; x++, src += cn, dst += cn ) { uchar* dst_cur = dst; const uchar* src_top = src; const uchar* src_bottom = src; int k, c; int src_step1 = src_step, dst_step1 = dst_step; if( x % 2 != 0 ) { src_bottom = src_top += src_step*(size.height-1); dst_cur += dst_step*(size.height-1); src_step1 = -src_step1; dst_step1 = -dst_step1; } // init accumulator memset( zone0, 0, sizeof(zone0[0])*cn ); memset( zone1, 0, sizeof(zone1[0])*cn ); for( y = 0; y <= m/2; y++ ) { for( c = 0; c < cn; c++ ) { if( y > 0 ) { for( k = 0; k < m*cn; k += cn ) UPDATE_ACC01( src_bottom[k+c], c, ++ ); } else { for( k = 0; k < m*cn; k += cn ) UPDATE_ACC01( src_bottom[k+c], c, += m/2+1 ); } } if( (src_step1 > 0 && y < size.height-1) || (src_step1 < 0 && size.height-y-1 > 0) ) src_bottom += src_step1; } for( y = 0; y < size.height; y++, dst_cur += dst_step1 ) { // find median for( c = 0; c < cn; c++ ) { int s = 0; for( k = 0; ; k++ ) { int t = s + zone0[c][k]; if( t > n2 ) break; s = t; } for( k *= N; ;k++ ) { s += zone1[c][k]; if( s > n2 ) break; } dst_cur[c] = (uchar)k; } if( y+1 == size.height ) break; if( cn == 1 ) { for( k = 0; k < m; k++ ) { int p = src_top[k]; int q = src_bottom[k]; zone1[0][p]--; zone0[0][p>>4]--; zone1[0][q]++; zone0[0][q>>4]++; } } else if( cn == 3 ) { for( k = 0; k < m*3; k += 3 ) { UPDATE_ACC01( src_top[k], 0, -- ); UPDATE_ACC01( src_top[k+1], 1, -- ); UPDATE_ACC01( src_top[k+2], 2, -- ); UPDATE_ACC01( src_bottom[k], 0, ++ ); UPDATE_ACC01( src_bottom[k+1], 1, ++ ); UPDATE_ACC01( src_bottom[k+2], 2, ++ ); } } else { assert( cn == 4 ); for( k = 0; k < m*4; k += 4 ) { UPDATE_ACC01( src_top[k], 0, -- ); UPDATE_ACC01( src_top[k+1], 1, -- ); UPDATE_ACC01( src_top[k+2], 2, -- ); UPDATE_ACC01( src_top[k+3], 3, -- ); UPDATE_ACC01( src_bottom[k], 0, ++ ); UPDATE_ACC01( src_bottom[k+1], 1, ++ ); UPDATE_ACC01( src_bottom[k+2], 2, ++ ); UPDATE_ACC01( src_bottom[k+3], 3, ++ ); } } if( (src_step1 > 0 && src_bottom + src_step1 < src_max) || (src_step1 < 0 && src_bottom + src_step1 >= src) ) src_bottom += src_step1; if( y >= m/2 ) src_top += src_step1; } } #undef N #undef UPDATE_ACC } struct MinMax8u { typedef uchar value_type; typedef int arg_type; enum { SIZE = 1 }; arg_type load(const uchar* ptr) { return *ptr; } void store(uchar* ptr, arg_type val) { *ptr = (uchar)val; } void operator()(arg_type& a, arg_type& b) const { int t = CV_FAST_CAST_8U(a - b); b += t; a -= t; } }; struct MinMax16u { typedef ushort value_type; typedef int arg_type; enum { SIZE = 1 }; arg_type load(const ushort* ptr) { return *ptr; } void store(ushort* ptr, arg_type val) { *ptr = (ushort)val; } void operator()(arg_type& a, arg_type& b) const { arg_type t = a; a = std::min(a, b); b = std::max(b, t); } }; struct MinMax16s { typedef short value_type; typedef int arg_type; enum { SIZE = 1 }; arg_type load(const short* ptr) { return *ptr; } void store(short* ptr, arg_type val) { *ptr = (short)val; } void operator()(arg_type& a, arg_type& b) const { arg_type t = a; a = std::min(a, b); b = std::max(b, t); } }; struct MinMax32f { typedef float value_type; typedef float arg_type; enum { SIZE = 1 }; arg_type load(const float* ptr) { return *ptr; } void store(float* ptr, arg_type val) { *ptr = val; } void operator()(arg_type& a, arg_type& b) const { arg_type t = a; a = std::min(a, b); b = std::max(b, t); } }; #if CV_SSE2 struct MinMaxVec8u { typedef uchar value_type; typedef __m128i arg_type; enum { SIZE = 16 }; arg_type load(const uchar* ptr) { return _mm_loadu_si128((const __m128i*)ptr); } void store(uchar* ptr, arg_type val) { _mm_storeu_si128((__m128i*)ptr, val); } void operator()(arg_type& a, arg_type& b) const { arg_type t = a; a = _mm_min_epu8(a, b); b = _mm_max_epu8(b, t); } }; struct MinMaxVec16u { typedef ushort value_type; typedef __m128i arg_type; enum { SIZE = 8 }; arg_type load(const ushort* ptr) { return _mm_loadu_si128((const __m128i*)ptr); } void store(ushort* ptr, arg_type val) { _mm_storeu_si128((__m128i*)ptr, val); } void operator()(arg_type& a, arg_type& b) const { arg_type t = _mm_subs_epu16(a, b); a = _mm_subs_epu16(a, t); b = _mm_adds_epu16(b, t); } }; struct MinMaxVec16s { typedef short value_type; typedef __m128i arg_type; enum { SIZE = 8 }; arg_type load(const short* ptr) { return _mm_loadu_si128((const __m128i*)ptr); } void store(short* ptr, arg_type val) { _mm_storeu_si128((__m128i*)ptr, val); } void operator()(arg_type& a, arg_type& b) const { arg_type t = a; a = _mm_min_epi16(a, b); b = _mm_max_epi16(b, t); } }; struct MinMaxVec32f { typedef float value_type; typedef __m128 arg_type; enum { SIZE = 4 }; arg_type load(const float* ptr) { return _mm_loadu_ps(ptr); } void store(float* ptr, arg_type val) { _mm_storeu_ps(ptr, val); } void operator()(arg_type& a, arg_type& b) const { arg_type t = a; a = _mm_min_ps(a, b); b = _mm_max_ps(b, t); } }; #else typedef MinMax8u MinMaxVec8u; typedef MinMax16u MinMaxVec16u; typedef MinMax16s MinMaxVec16s; typedef MinMax32f MinMaxVec32f; #endif template static void medianBlur_SortNet( const Mat& _src, Mat& _dst, int m ) { typedef typename Op::value_type T; typedef typename Op::arg_type WT; typedef typename VecOp::arg_type VT; const T* src = (const T*)_src.data; T* dst = (T*)_dst.data; int sstep = (int)(_src.step/sizeof(T)); int dstep = (int)(_dst.step/sizeof(T)); Size size = _dst.size(); int i, j, k, cn = _src.channels(); Op op; VecOp vop; volatile bool useSIMD = checkHardwareSupport(CV_CPU_SSE2); if( m == 3 ) { if( size.width == 1 || size.height == 1 ) { int len = size.width + size.height - 1; int sdelta = size.height == 1 ? cn : sstep; int sdelta0 = size.height == 1 ? 0 : sstep - cn; int ddelta = size.height == 1 ? cn : dstep; for( i = 0; i < len; i++, src += sdelta0, dst += ddelta ) for( j = 0; j < cn; j++, src++ ) { WT p0 = src[i > 0 ? -sdelta : 0]; WT p1 = src[0]; WT p2 = src[i < len - 1 ? sdelta : 0]; op(p0, p1); op(p1, p2); op(p0, p1); dst[j] = (T)p1; } return; } size.width *= cn; for( i = 0; i < size.height; i++, dst += dstep ) { const T* row0 = src + std::max(i - 1, 0)*sstep; const T* row1 = src + i*sstep; const T* row2 = src + std::min(i + 1, size.height-1)*sstep; int limit = useSIMD ? cn : size.width; for(j = 0;; ) { for( ; j < limit; j++ ) { int j0 = j >= cn ? j - cn : j; int j2 = j < size.width - cn ? j + cn : j; WT p0 = row0[j0], p1 = row0[j], p2 = row0[j2]; WT p3 = row1[j0], p4 = row1[j], p5 = row1[j2]; WT p6 = row2[j0], p7 = row2[j], p8 = row2[j2]; op(p1, p2); op(p4, p5); op(p7, p8); op(p0, p1); op(p3, p4); op(p6, p7); op(p1, p2); op(p4, p5); op(p7, p8); op(p0, p3); op(p5, p8); op(p4, p7); op(p3, p6); op(p1, p4); op(p2, p5); op(p4, p7); op(p4, p2); op(p6, p4); op(p4, p2); dst[j] = (T)p4; } if( limit == size.width ) break; for( ; j <= size.width - VecOp::SIZE - cn; j += VecOp::SIZE ) { VT p0 = vop.load(row0+j-cn), p1 = vop.load(row0+j), p2 = vop.load(row0+j+cn); VT p3 = vop.load(row1+j-cn), p4 = vop.load(row1+j), p5 = vop.load(row1+j+cn); VT p6 = vop.load(row2+j-cn), p7 = vop.load(row2+j), p8 = vop.load(row2+j+cn); vop(p1, p2); vop(p4, p5); vop(p7, p8); vop(p0, p1); vop(p3, p4); vop(p6, p7); vop(p1, p2); vop(p4, p5); vop(p7, p8); vop(p0, p3); vop(p5, p8); vop(p4, p7); vop(p3, p6); vop(p1, p4); vop(p2, p5); vop(p4, p7); vop(p4, p2); vop(p6, p4); vop(p4, p2); vop.store(dst+j, p4); } limit = size.width; } } } else if( m == 5 ) { if( size.width == 1 || size.height == 1 ) { int len = size.width + size.height - 1; int sdelta = size.height == 1 ? cn : sstep; int sdelta0 = size.height == 1 ? 0 : sstep - cn; int ddelta = size.height == 1 ? cn : dstep; for( i = 0; i < len; i++, src += sdelta0, dst += ddelta ) for( j = 0; j < cn; j++, src++ ) { int i1 = i > 0 ? -sdelta : 0; int i0 = i > 1 ? -sdelta*2 : i1; int i3 = i < len-1 ? sdelta : 0; int i4 = i < len-2 ? sdelta*2 : i3; WT p0 = src[i0], p1 = src[i1], p2 = src[0], p3 = src[i3], p4 = src[i4]; op(p0, p1); op(p3, p4); op(p2, p3); op(p3, p4); op(p0, p2); op(p2, p4); op(p1, p3); op(p1, p2); dst[j] = (T)p2; } return; } size.width *= cn; for( i = 0; i < size.height; i++, dst += dstep ) { const T* row[5]; row[0] = src + std::max(i - 2, 0)*sstep; row[1] = src + std::max(i - 1, 0)*sstep; row[2] = src + i*sstep; row[3] = src + std::min(i + 1, size.height-1)*sstep; row[4] = src + std::min(i + 2, size.height-1)*sstep; int limit = useSIMD ? cn*2 : size.width; for(j = 0;; ) { for( ; j < limit; j++ ) { WT p[25]; int j1 = j >= cn ? j - cn : j; int j0 = j >= cn*2 ? j - cn*2 : j1; int j3 = j < size.width - cn ? j + cn : j; int j4 = j < size.width - cn*2 ? j + cn*2 : j3; for( k = 0; k < 5; k++ ) { const T* rowk = row[k]; p[k*5] = rowk[j0]; p[k*5+1] = rowk[j1]; p[k*5+2] = rowk[j]; p[k*5+3] = rowk[j3]; p[k*5+4] = rowk[j4]; } op(p[1], p[2]); op(p[0], p[1]); op(p[1], p[2]); op(p[4], p[5]); op(p[3], p[4]); op(p[4], p[5]); op(p[0], p[3]); op(p[2], p[5]); op(p[2], p[3]); op(p[1], p[4]); op(p[1], p[2]); op(p[3], p[4]); op(p[7], p[8]); op(p[6], p[7]); op(p[7], p[8]); op(p[10], p[11]); op(p[9], p[10]); op(p[10], p[11]); op(p[6], p[9]); op(p[8], p[11]); op(p[8], p[9]); op(p[7], p[10]); op(p[7], p[8]); op(p[9], p[10]); op(p[0], p[6]); op(p[4], p[10]); op(p[4], p[6]); op(p[2], p[8]); op(p[2], p[4]); op(p[6], p[8]); op(p[1], p[7]); op(p[5], p[11]); op(p[5], p[7]); op(p[3], p[9]); op(p[3], p[5]); op(p[7], p[9]); op(p[1], p[2]); op(p[3], p[4]); op(p[5], p[6]); op(p[7], p[8]); op(p[9], p[10]); op(p[13], p[14]); op(p[12], p[13]); op(p[13], p[14]); op(p[16], p[17]); op(p[15], p[16]); op(p[16], p[17]); op(p[12], p[15]); op(p[14], p[17]); op(p[14], p[15]); op(p[13], p[16]); op(p[13], p[14]); op(p[15], p[16]); op(p[19], p[20]); op(p[18], p[19]); op(p[19], p[20]); op(p[21], p[22]); op(p[23], p[24]); op(p[21], p[23]); op(p[22], p[24]); op(p[22], p[23]); op(p[18], p[21]); op(p[20], p[23]); op(p[20], p[21]); op(p[19], p[22]); op(p[22], p[24]); op(p[19], p[20]); op(p[21], p[22]); op(p[23], p[24]); op(p[12], p[18]); op(p[16], p[22]); op(p[16], p[18]); op(p[14], p[20]); op(p[20], p[24]); op(p[14], p[16]); op(p[18], p[20]); op(p[22], p[24]); op(p[13], p[19]); op(p[17], p[23]); op(p[17], p[19]); op(p[15], p[21]); op(p[15], p[17]); op(p[19], p[21]); op(p[13], p[14]); op(p[15], p[16]); op(p[17], p[18]); op(p[19], p[20]); op(p[21], p[22]); op(p[23], p[24]); op(p[0], p[12]); op(p[8], p[20]); op(p[8], p[12]); op(p[4], p[16]); op(p[16], p[24]); op(p[12], p[16]); op(p[2], p[14]); op(p[10], p[22]); op(p[10], p[14]); op(p[6], p[18]); op(p[6], p[10]); op(p[10], p[12]); op(p[1], p[13]); op(p[9], p[21]); op(p[9], p[13]); op(p[5], p[17]); op(p[13], p[17]); op(p[3], p[15]); op(p[11], p[23]); op(p[11], p[15]); op(p[7], p[19]); op(p[7], p[11]); op(p[11], p[13]); op(p[11], p[12]); dst[j] = (T)p[12]; } if( limit == size.width ) break; for( ; j <= size.width - VecOp::SIZE - cn*2; j += VecOp::SIZE ) { VT p[25]; for( k = 0; k < 5; k++ ) { const T* rowk = row[k]; p[k*5] = vop.load(rowk+j-cn*2); p[k*5+1] = vop.load(rowk+j-cn); p[k*5+2] = vop.load(rowk+j); p[k*5+3] = vop.load(rowk+j+cn); p[k*5+4] = vop.load(rowk+j+cn*2); } vop(p[1], p[2]); vop(p[0], p[1]); vop(p[1], p[2]); vop(p[4], p[5]); vop(p[3], p[4]); vop(p[4], p[5]); vop(p[0], p[3]); vop(p[2], p[5]); vop(p[2], p[3]); vop(p[1], p[4]); vop(p[1], p[2]); vop(p[3], p[4]); vop(p[7], p[8]); vop(p[6], p[7]); vop(p[7], p[8]); vop(p[10], p[11]); vop(p[9], p[10]); vop(p[10], p[11]); vop(p[6], p[9]); vop(p[8], p[11]); vop(p[8], p[9]); vop(p[7], p[10]); vop(p[7], p[8]); vop(p[9], p[10]); vop(p[0], p[6]); vop(p[4], p[10]); vop(p[4], p[6]); vop(p[2], p[8]); vop(p[2], p[4]); vop(p[6], p[8]); vop(p[1], p[7]); vop(p[5], p[11]); vop(p[5], p[7]); vop(p[3], p[9]); vop(p[3], p[5]); vop(p[7], p[9]); vop(p[1], p[2]); vop(p[3], p[4]); vop(p[5], p[6]); vop(p[7], p[8]); vop(p[9], p[10]); vop(p[13], p[14]); vop(p[12], p[13]); vop(p[13], p[14]); vop(p[16], p[17]); vop(p[15], p[16]); vop(p[16], p[17]); vop(p[12], p[15]); vop(p[14], p[17]); vop(p[14], p[15]); vop(p[13], p[16]); vop(p[13], p[14]); vop(p[15], p[16]); vop(p[19], p[20]); vop(p[18], p[19]); vop(p[19], p[20]); vop(p[21], p[22]); vop(p[23], p[24]); vop(p[21], p[23]); vop(p[22], p[24]); vop(p[22], p[23]); vop(p[18], p[21]); vop(p[20], p[23]); vop(p[20], p[21]); vop(p[19], p[22]); vop(p[22], p[24]); vop(p[19], p[20]); vop(p[21], p[22]); vop(p[23], p[24]); vop(p[12], p[18]); vop(p[16], p[22]); vop(p[16], p[18]); vop(p[14], p[20]); vop(p[20], p[24]); vop(p[14], p[16]); vop(p[18], p[20]); vop(p[22], p[24]); vop(p[13], p[19]); vop(p[17], p[23]); vop(p[17], p[19]); vop(p[15], p[21]); vop(p[15], p[17]); vop(p[19], p[21]); vop(p[13], p[14]); vop(p[15], p[16]); vop(p[17], p[18]); vop(p[19], p[20]); vop(p[21], p[22]); vop(p[23], p[24]); vop(p[0], p[12]); vop(p[8], p[20]); vop(p[8], p[12]); vop(p[4], p[16]); vop(p[16], p[24]); vop(p[12], p[16]); vop(p[2], p[14]); vop(p[10], p[22]); vop(p[10], p[14]); vop(p[6], p[18]); vop(p[6], p[10]); vop(p[10], p[12]); vop(p[1], p[13]); vop(p[9], p[21]); vop(p[9], p[13]); vop(p[5], p[17]); vop(p[13], p[17]); vop(p[3], p[15]); vop(p[11], p[23]); vop(p[11], p[15]); vop(p[7], p[19]); vop(p[7], p[11]); vop(p[11], p[13]); vop(p[11], p[12]); vop.store(dst+j, p[12]); } limit = size.width; } } } } #ifdef HAVE_OPENCL static bool ocl_medianFilter(InputArray _src, OutputArray _dst, int m) { size_t localsize[2] = { 16, 16 }; size_t globalsize[2]; int type = _src.type(), depth = CV_MAT_DEPTH(type), cn = CV_MAT_CN(type); if ( !((depth == CV_8U || depth == CV_16U || depth == CV_16S || depth == CV_32F) && cn <= 4 && (m == 3 || m == 5)) ) return false; Size imgSize = _src.size(); bool useOptimized = (1 == cn) && (size_t)imgSize.width >= localsize[0] * 8 && (size_t)imgSize.height >= localsize[1] * 8 && imgSize.width % 4 == 0 && imgSize.height % 4 == 0 && (ocl::Device::getDefault().isIntel()); cv::String kname = format( useOptimized ? "medianFilter%d_u" : "medianFilter%d", m) ; cv::String kdefs = useOptimized ? format("-D T=%s -D T1=%s -D T4=%s%d -D cn=%d -D USE_4OPT", ocl::typeToStr(type), ocl::typeToStr(depth), ocl::typeToStr(depth), cn*4, cn) : format("-D T=%s -D T1=%s -D cn=%d", ocl::typeToStr(type), ocl::typeToStr(depth), cn) ; ocl::Kernel k(kname.c_str(), ocl::imgproc::medianFilter_oclsrc, kdefs.c_str() ); if (k.empty()) return false; UMat src = _src.getUMat(); _dst.create(src.size(), type); UMat dst = _dst.getUMat(); k.args(ocl::KernelArg::ReadOnlyNoSize(src), ocl::KernelArg::WriteOnly(dst)); if( useOptimized ) { globalsize[0] = DIVUP(src.cols / 4, localsize[0]) * localsize[0]; globalsize[1] = DIVUP(src.rows / 4, localsize[1]) * localsize[1]; } else { globalsize[0] = (src.cols + localsize[0] + 2) / localsize[0] * localsize[0]; globalsize[1] = (src.rows + localsize[1] - 1) / localsize[1] * localsize[1]; } return k.run(2, globalsize, localsize, false); } #endif } void cv::medianBlur( InputArray _src0, OutputArray _dst, int ksize ) { CV_Assert( (ksize % 2 == 1) && (_src0.dims() <= 2 )); if( ksize <= 1 ) { _src0.copyTo(_dst); return; } CV_OCL_RUN(_dst.isUMat(), ocl_medianFilter(_src0,_dst, ksize)) Mat src0 = _src0.getMat(); _dst.create( src0.size(), src0.type() ); Mat dst = _dst.getMat(); #if IPP_VERSION_X100 >= 801 #define IPP_FILTER_MEDIAN_BORDER(ippType, ippDataType, flavor) \ do \ { \ if (ippiFilterMedianBorderGetBufferSize(dstRoiSize, maskSize, \ ippDataType, CV_MAT_CN(type), &bufSize) >= 0) \ { \ Ipp8u * buffer = ippsMalloc_8u(bufSize); \ IppStatus status = ippiFilterMedianBorder_##flavor((const ippType *)src0.data, (int)src0.step, \ (ippType *)dst.data, (int)dst.step, dstRoiSize, maskSize, \ ippBorderRepl, (ippType)0, buffer); \ ippsFree(buffer); \ if (status >= 0) \ return; \ } \ setIppErrorStatus(); \ } \ while ((void)0, 0) Ipp32s bufSize; IppiSize dstRoiSize = ippiSize(dst.cols, dst.rows), maskSize = ippiSize(ksize, ksize); int type = src0.type(); if (type == CV_8UC1) IPP_FILTER_MEDIAN_BORDER(Ipp8u, ipp8u, 8u_C1R); else if (type == CV_16UC1) IPP_FILTER_MEDIAN_BORDER(Ipp16u, ipp16u, 16u_C1R); else if (type == CV_16SC1) IPP_FILTER_MEDIAN_BORDER(Ipp16s, ipp16s, 16s_C1R); else if (type == CV_32FC1) IPP_FILTER_MEDIAN_BORDER(Ipp32f, ipp32f, 32f_C1R); #undef IPP_FILTER_MEDIAN_BORDER #endif #ifdef HAVE_TEGRA_OPTIMIZATION if (tegra::medianBlur(src0, dst, ksize)) return; #endif bool useSortNet = ksize == 3 || (ksize == 5 #if !CV_SSE2 && src0.depth() > CV_8U #endif ); Mat src; if( useSortNet ) { if( dst.data != src0.data ) src = src0; else src0.copyTo(src); if( src.depth() == CV_8U ) medianBlur_SortNet( src, dst, ksize ); else if( src.depth() == CV_16U ) medianBlur_SortNet( src, dst, ksize ); else if( src.depth() == CV_16S ) medianBlur_SortNet( src, dst, ksize ); else if( src.depth() == CV_32F ) medianBlur_SortNet( src, dst, ksize ); else CV_Error(CV_StsUnsupportedFormat, ""); return; } else { cv::copyMakeBorder( src0, src, 0, 0, ksize/2, ksize/2, BORDER_REPLICATE ); int cn = src0.channels(); CV_Assert( src.depth() == CV_8U && (cn == 1 || cn == 3 || cn == 4) ); double img_size_mp = (double)(src0.total())/(1 << 20); if( ksize <= 3 + (img_size_mp < 1 ? 12 : img_size_mp < 4 ? 6 : 2)*(MEDIAN_HAVE_SIMD && checkHardwareSupport(CV_CPU_SSE2) ? 1 : 3)) medianBlur_8u_Om( src, dst, ksize ); else medianBlur_8u_O1( src, dst, ksize ); } } /****************************************************************************************\ Bilateral Filtering \****************************************************************************************/ namespace cv { class BilateralFilter_8u_Invoker : public ParallelLoopBody { public: BilateralFilter_8u_Invoker(Mat& _dest, const Mat& _temp, int _radius, int _maxk, int* _space_ofs, float *_space_weight, float *_color_weight) : temp(&_temp), dest(&_dest), radius(_radius), maxk(_maxk), space_ofs(_space_ofs), space_weight(_space_weight), color_weight(_color_weight) { } virtual void operator() (const Range& range) const { int i, j, cn = dest->channels(), k; Size size = dest->size(); #if CV_SSE3 int CV_DECL_ALIGNED(16) buf[4]; float CV_DECL_ALIGNED(16) bufSum[4]; static const int CV_DECL_ALIGNED(16) bufSignMask[] = { 0x80000000, 0x80000000, 0x80000000, 0x80000000 }; bool haveSSE3 = checkHardwareSupport(CV_CPU_SSE3); #endif for( i = range.start; i < range.end; i++ ) { const uchar* sptr = temp->ptr(i+radius) + radius*cn; uchar* dptr = dest->ptr(i); if( cn == 1 ) { for( j = 0; j < size.width; j++ ) { float sum = 0, wsum = 0; int val0 = sptr[j]; k = 0; #if CV_SSE3 if( haveSSE3 ) { __m128 _val0 = _mm_set1_ps(static_cast(val0)); const __m128 _signMask = _mm_load_ps((const float*)bufSignMask); for( ; k <= maxk - 4; k += 4 ) { __m128 _valF = _mm_set_ps(sptr[j + space_ofs[k+3]], sptr[j + space_ofs[k+2]], sptr[j + space_ofs[k+1]], sptr[j + space_ofs[k]]); __m128 _val = _mm_andnot_ps(_signMask, _mm_sub_ps(_valF, _val0)); _mm_store_si128((__m128i*)buf, _mm_cvtps_epi32(_val)); __m128 _cw = _mm_set_ps(color_weight[buf[3]],color_weight[buf[2]], color_weight[buf[1]],color_weight[buf[0]]); __m128 _sw = _mm_loadu_ps(space_weight+k); __m128 _w = _mm_mul_ps(_cw, _sw); _cw = _mm_mul_ps(_w, _valF); _sw = _mm_hadd_ps(_w, _cw); _sw = _mm_hadd_ps(_sw, _sw); _mm_storel_pi((__m64*)bufSum, _sw); sum += bufSum[1]; wsum += bufSum[0]; } } #endif for( ; k < maxk; k++ ) { int val = sptr[j + space_ofs[k]]; float w = space_weight[k]*color_weight[std::abs(val - val0)]; sum += val*w; wsum += w; } // overflow is not possible here => there is no need to use cv::saturate_cast dptr[j] = (uchar)cvRound(sum/wsum); } } else { assert( cn == 3 ); for( j = 0; j < size.width*3; j += 3 ) { float sum_b = 0, sum_g = 0, sum_r = 0, wsum = 0; int b0 = sptr[j], g0 = sptr[j+1], r0 = sptr[j+2]; k = 0; #if CV_SSE3 if( haveSSE3 ) { const __m128i izero = _mm_setzero_si128(); const __m128 _b0 = _mm_set1_ps(static_cast(b0)); const __m128 _g0 = _mm_set1_ps(static_cast(g0)); const __m128 _r0 = _mm_set1_ps(static_cast(r0)); const __m128 _signMask = _mm_load_ps((const float*)bufSignMask); for( ; k <= maxk - 4; k += 4 ) { const int* const sptr_k0 = reinterpret_cast(sptr + j + space_ofs[k]); const int* const sptr_k1 = reinterpret_cast(sptr + j + space_ofs[k+1]); const int* const sptr_k2 = reinterpret_cast(sptr + j + space_ofs[k+2]); const int* const sptr_k3 = reinterpret_cast(sptr + j + space_ofs[k+3]); __m128 _b = _mm_cvtepi32_ps(_mm_unpacklo_epi16(_mm_unpacklo_epi8(_mm_cvtsi32_si128(sptr_k0[0]), izero), izero)); __m128 _g = _mm_cvtepi32_ps(_mm_unpacklo_epi16(_mm_unpacklo_epi8(_mm_cvtsi32_si128(sptr_k1[0]), izero), izero)); __m128 _r = _mm_cvtepi32_ps(_mm_unpacklo_epi16(_mm_unpacklo_epi8(_mm_cvtsi32_si128(sptr_k2[0]), izero), izero)); __m128 _z = _mm_cvtepi32_ps(_mm_unpacklo_epi16(_mm_unpacklo_epi8(_mm_cvtsi32_si128(sptr_k3[0]), izero), izero)); _MM_TRANSPOSE4_PS(_b, _g, _r, _z); __m128 bt = _mm_andnot_ps(_signMask, _mm_sub_ps(_b,_b0)); __m128 gt = _mm_andnot_ps(_signMask, _mm_sub_ps(_g,_g0)); __m128 rt = _mm_andnot_ps(_signMask, _mm_sub_ps(_r,_r0)); bt =_mm_add_ps(rt, _mm_add_ps(bt, gt)); _mm_store_si128((__m128i*)buf, _mm_cvtps_epi32(bt)); __m128 _w = _mm_set_ps(color_weight[buf[3]],color_weight[buf[2]], color_weight[buf[1]],color_weight[buf[0]]); __m128 _sw = _mm_loadu_ps(space_weight+k); _w = _mm_mul_ps(_w,_sw); _b = _mm_mul_ps(_b, _w); _g = _mm_mul_ps(_g, _w); _r = _mm_mul_ps(_r, _w); _w = _mm_hadd_ps(_w, _b); _g = _mm_hadd_ps(_g, _r); _w = _mm_hadd_ps(_w, _g); _mm_store_ps(bufSum, _w); wsum += bufSum[0]; sum_b += bufSum[1]; sum_g += bufSum[2]; sum_r += bufSum[3]; } } #endif for( ; k < maxk; k++ ) { const uchar* sptr_k = sptr + j + space_ofs[k]; int b = sptr_k[0], g = sptr_k[1], r = sptr_k[2]; float w = space_weight[k]*color_weight[std::abs(b - b0) + std::abs(g - g0) + std::abs(r - r0)]; sum_b += b*w; sum_g += g*w; sum_r += r*w; wsum += w; } wsum = 1.f/wsum; b0 = cvRound(sum_b*wsum); g0 = cvRound(sum_g*wsum); r0 = cvRound(sum_r*wsum); dptr[j] = (uchar)b0; dptr[j+1] = (uchar)g0; dptr[j+2] = (uchar)r0; } } } } private: const Mat *temp; Mat *dest; int radius, maxk, *space_ofs; float *space_weight, *color_weight; }; #if defined (HAVE_IPP) && !defined(HAVE_IPP_ICV_ONLY) && 0 class IPPBilateralFilter_8u_Invoker : public ParallelLoopBody { public: IPPBilateralFilter_8u_Invoker(Mat &_src, Mat &_dst, double _sigma_color, double _sigma_space, int _radius, bool *_ok) : ParallelLoopBody(), src(_src), dst(_dst), sigma_color(_sigma_color), sigma_space(_sigma_space), radius(_radius), ok(_ok) { *ok = true; } virtual void operator() (const Range& range) const { int d = radius * 2 + 1; IppiSize kernel = {d, d}; IppiSize roi={dst.cols, range.end - range.start}; int bufsize=0; if (0 > ippiFilterBilateralGetBufSize_8u_C1R( ippiFilterBilateralGauss, roi, kernel, &bufsize)) { *ok = false; return; } AutoBuffer buf(bufsize); IppiFilterBilateralSpec *pSpec = (IppiFilterBilateralSpec *)alignPtr(&buf[0], 32); if (0 > ippiFilterBilateralInit_8u_C1R( ippiFilterBilateralGauss, kernel, (Ipp32f)sigma_color, (Ipp32f)sigma_space, 1, pSpec )) { *ok = false; return; } if (0 > ippiFilterBilateral_8u_C1R( src.ptr(range.start) + radius * ((int)src.step[0] + 1), (int)src.step[0], dst.ptr(range.start), (int)dst.step[0], roi, kernel, pSpec )) *ok = false; } private: Mat &src; Mat &dst; double sigma_color; double sigma_space; int radius; bool *ok; const IPPBilateralFilter_8u_Invoker& operator= (const IPPBilateralFilter_8u_Invoker&); }; #endif #ifdef HAVE_OPENCL static bool ocl_bilateralFilter_8u(InputArray _src, OutputArray _dst, int d, double sigma_color, double sigma_space, int borderType) { int type = _src.type(), depth = CV_MAT_DEPTH(type), cn = CV_MAT_CN(type); int i, j, maxk, radius; if (depth != CV_8U || cn > 4) return false; if (sigma_color <= 0) sigma_color = 1; if (sigma_space <= 0) sigma_space = 1; double gauss_color_coeff = -0.5 / (sigma_color * sigma_color); double gauss_space_coeff = -0.5 / (sigma_space * sigma_space); if ( d <= 0 ) radius = cvRound(sigma_space * 1.5); else radius = d / 2; radius = MAX(radius, 1); d = radius * 2 + 1; UMat src = _src.getUMat(), dst = _dst.getUMat(), temp; if (src.u == dst.u) return false; copyMakeBorder(src, temp, radius, radius, radius, radius, borderType); std::vector _space_weight(d * d); std::vector _space_ofs(d * d); float * const space_weight = &_space_weight[0]; int * const space_ofs = &_space_ofs[0]; // initialize space-related bilateral filter coefficients for( i = -radius, maxk = 0; i <= radius; i++ ) for( j = -radius; j <= radius; j++ ) { double r = std::sqrt((double)i * i + (double)j * j); if ( r > radius ) continue; space_weight[maxk] = (float)std::exp(r * r * gauss_space_coeff); space_ofs[maxk++] = (int)(i * temp.step + j * cn); } char cvt[3][40]; String cnstr = cn > 1 ? format("%d", cn) : ""; String kernelName("bilateral"); size_t sizeDiv = 1; if ((ocl::Device::getDefault().isIntel()) && (ocl::Device::getDefault().type() == ocl::Device::TYPE_GPU)) { //Intel GPU if (dst.cols % 4 == 0 && cn == 1) // For single channel x4 sized images. { kernelName = "bilateral_float4"; sizeDiv = 4; } } ocl::Kernel k(kernelName.c_str(), ocl::imgproc::bilateral_oclsrc, format("-D radius=%d -D maxk=%d -D cn=%d -D int_t=%s -D uint_t=uint%s -D convert_int_t=%s" " -D uchar_t=%s -D float_t=%s -D convert_float_t=%s -D convert_uchar_t=%s -D gauss_color_coeff=%f", radius, maxk, cn, ocl::typeToStr(CV_32SC(cn)), cnstr.c_str(), ocl::convertTypeStr(CV_8U, CV_32S, cn, cvt[0]), ocl::typeToStr(type), ocl::typeToStr(CV_32FC(cn)), ocl::convertTypeStr(CV_32S, CV_32F, cn, cvt[1]), ocl::convertTypeStr(CV_32F, CV_8U, cn, cvt[2]), gauss_color_coeff)); if (k.empty()) return false; Mat mspace_weight(1, d * d, CV_32FC1, space_weight); Mat mspace_ofs(1, d * d, CV_32SC1, space_ofs); UMat ucolor_weight, uspace_weight, uspace_ofs; mspace_weight.copyTo(uspace_weight); mspace_ofs.copyTo(uspace_ofs); k.args(ocl::KernelArg::ReadOnlyNoSize(temp), ocl::KernelArg::WriteOnly(dst), ocl::KernelArg::PtrReadOnly(uspace_weight), ocl::KernelArg::PtrReadOnly(uspace_ofs)); size_t globalsize[2] = { dst.cols / sizeDiv, dst.rows }; return k.run(2, globalsize, NULL, false); } #endif static void bilateralFilter_8u( const Mat& src, Mat& dst, int d, double sigma_color, double sigma_space, int borderType ) { int cn = src.channels(); int i, j, maxk, radius; Size size = src.size(); CV_Assert( (src.type() == CV_8UC1 || src.type() == CV_8UC3) && src.data != dst.data ); if( sigma_color <= 0 ) sigma_color = 1; if( sigma_space <= 0 ) sigma_space = 1; double gauss_color_coeff = -0.5/(sigma_color*sigma_color); double gauss_space_coeff = -0.5/(sigma_space*sigma_space); if( d <= 0 ) radius = cvRound(sigma_space*1.5); else radius = d/2; radius = MAX(radius, 1); d = radius*2 + 1; Mat temp; copyMakeBorder( src, temp, radius, radius, radius, radius, borderType ); #if defined HAVE_IPP && (IPP_VERSION_MAJOR >= 7) && 0 if( cn == 1 ) { bool ok; IPPBilateralFilter_8u_Invoker body(temp, dst, sigma_color * sigma_color, sigma_space * sigma_space, radius, &ok ); parallel_for_(Range(0, dst.rows), body, dst.total()/(double)(1<<16)); if( ok ) return; setIppErrorStatus(); } #endif std::vector _color_weight(cn*256); std::vector _space_weight(d*d); std::vector _space_ofs(d*d); float* color_weight = &_color_weight[0]; float* space_weight = &_space_weight[0]; int* space_ofs = &_space_ofs[0]; // initialize color-related bilateral filter coefficients for( i = 0; i < 256*cn; i++ ) color_weight[i] = (float)std::exp(i*i*gauss_color_coeff); // initialize space-related bilateral filter coefficients for( i = -radius, maxk = 0; i <= radius; i++ ) { j = -radius; for( ; j <= radius; j++ ) { double r = std::sqrt((double)i*i + (double)j*j); if( r > radius ) continue; space_weight[maxk] = (float)std::exp(r*r*gauss_space_coeff); space_ofs[maxk++] = (int)(i*temp.step + j*cn); } } BilateralFilter_8u_Invoker body(dst, temp, radius, maxk, space_ofs, space_weight, color_weight); parallel_for_(Range(0, size.height), body, dst.total()/(double)(1<<16)); } class BilateralFilter_32f_Invoker : public ParallelLoopBody { public: BilateralFilter_32f_Invoker(int _cn, int _radius, int _maxk, int *_space_ofs, const Mat& _temp, Mat& _dest, float _scale_index, float *_space_weight, float *_expLUT) : cn(_cn), radius(_radius), maxk(_maxk), space_ofs(_space_ofs), temp(&_temp), dest(&_dest), scale_index(_scale_index), space_weight(_space_weight), expLUT(_expLUT) { } virtual void operator() (const Range& range) const { int i, j, k; Size size = dest->size(); #if CV_SSE3 int CV_DECL_ALIGNED(16) idxBuf[4]; float CV_DECL_ALIGNED(16) bufSum32[4]; static const int CV_DECL_ALIGNED(16) bufSignMask[] = { 0x80000000, 0x80000000, 0x80000000, 0x80000000 }; bool haveSSE3 = checkHardwareSupport(CV_CPU_SSE3); #endif for( i = range.start; i < range.end; i++ ) { const float* sptr = temp->ptr(i+radius) + radius*cn; float* dptr = dest->ptr(i); if( cn == 1 ) { for( j = 0; j < size.width; j++ ) { float sum = 0, wsum = 0; float val0 = sptr[j]; k = 0; #if CV_SSE3 if( haveSSE3 ) { __m128 psum = _mm_setzero_ps(); const __m128 _val0 = _mm_set1_ps(sptr[j]); const __m128 _scale_index = _mm_set1_ps(scale_index); const __m128 _signMask = _mm_load_ps((const float*)bufSignMask); for( ; k <= maxk - 4 ; k += 4 ) { __m128 _sw = _mm_loadu_ps(space_weight + k); __m128 _val = _mm_set_ps(sptr[j + space_ofs[k+3]], sptr[j + space_ofs[k+2]], sptr[j + space_ofs[k+1]], sptr[j + space_ofs[k]]); __m128 _alpha = _mm_mul_ps(_mm_andnot_ps( _signMask, _mm_sub_ps(_val,_val0)), _scale_index); __m128i _idx = _mm_cvtps_epi32(_alpha); _mm_store_si128((__m128i*)idxBuf, _idx); _alpha = _mm_sub_ps(_alpha, _mm_cvtepi32_ps(_idx)); __m128 _explut = _mm_set_ps(expLUT[idxBuf[3]], expLUT[idxBuf[2]], expLUT[idxBuf[1]], expLUT[idxBuf[0]]); __m128 _explut1 = _mm_set_ps(expLUT[idxBuf[3]+1], expLUT[idxBuf[2]+1], expLUT[idxBuf[1]+1], expLUT[idxBuf[0]+1]); __m128 _w = _mm_mul_ps(_sw, _mm_add_ps(_explut, _mm_mul_ps(_alpha, _mm_sub_ps(_explut1, _explut)))); _val = _mm_mul_ps(_w, _val); _sw = _mm_hadd_ps(_w, _val); _sw = _mm_hadd_ps(_sw, _sw); psum = _mm_add_ps(_sw, psum); } _mm_storel_pi((__m64*)bufSum32, psum); sum = bufSum32[1]; wsum = bufSum32[0]; } #endif for( ; k < maxk; k++ ) { float val = sptr[j + space_ofs[k]]; float alpha = (float)(std::abs(val - val0)*scale_index); int idx = cvFloor(alpha); alpha -= idx; float w = space_weight[k]*(expLUT[idx] + alpha*(expLUT[idx+1] - expLUT[idx])); sum += val*w; wsum += w; } dptr[j] = (float)(sum/wsum); } } else { CV_Assert( cn == 3 ); for( j = 0; j < size.width*3; j += 3 ) { float sum_b = 0, sum_g = 0, sum_r = 0, wsum = 0; float b0 = sptr[j], g0 = sptr[j+1], r0 = sptr[j+2]; k = 0; #if CV_SSE3 if( haveSSE3 ) { __m128 sum = _mm_setzero_ps(); const __m128 _b0 = _mm_set1_ps(b0); const __m128 _g0 = _mm_set1_ps(g0); const __m128 _r0 = _mm_set1_ps(r0); const __m128 _scale_index = _mm_set1_ps(scale_index); const __m128 _signMask = _mm_load_ps((const float*)bufSignMask); for( ; k <= maxk-4; k += 4 ) { __m128 _sw = _mm_loadu_ps(space_weight + k); const float* const sptr_k0 = sptr + j + space_ofs[k]; const float* const sptr_k1 = sptr + j + space_ofs[k+1]; const float* const sptr_k2 = sptr + j + space_ofs[k+2]; const float* const sptr_k3 = sptr + j + space_ofs[k+3]; __m128 _b = _mm_loadu_ps(sptr_k0); __m128 _g = _mm_loadu_ps(sptr_k1); __m128 _r = _mm_loadu_ps(sptr_k2); __m128 _z = _mm_loadu_ps(sptr_k3); _MM_TRANSPOSE4_PS(_b, _g, _r, _z); __m128 _bt = _mm_andnot_ps(_signMask,_mm_sub_ps(_b,_b0)); __m128 _gt = _mm_andnot_ps(_signMask,_mm_sub_ps(_g,_g0)); __m128 _rt = _mm_andnot_ps(_signMask,_mm_sub_ps(_r,_r0)); __m128 _alpha = _mm_mul_ps(_scale_index, _mm_add_ps(_rt,_mm_add_ps(_bt, _gt))); __m128i _idx = _mm_cvtps_epi32(_alpha); _mm_store_si128((__m128i*)idxBuf, _idx); _alpha = _mm_sub_ps(_alpha, _mm_cvtepi32_ps(_idx)); __m128 _explut = _mm_set_ps(expLUT[idxBuf[3]], expLUT[idxBuf[2]], expLUT[idxBuf[1]], expLUT[idxBuf[0]]); __m128 _explut1 = _mm_set_ps(expLUT[idxBuf[3]+1], expLUT[idxBuf[2]+1], expLUT[idxBuf[1]+1], expLUT[idxBuf[0]+1]); __m128 _w = _mm_mul_ps(_sw, _mm_add_ps(_explut, _mm_mul_ps(_alpha, _mm_sub_ps(_explut1, _explut)))); _b = _mm_mul_ps(_b, _w); _g = _mm_mul_ps(_g, _w); _r = _mm_mul_ps(_r, _w); _w = _mm_hadd_ps(_w, _b); _g = _mm_hadd_ps(_g, _r); _w = _mm_hadd_ps(_w, _g); sum = _mm_add_ps(sum, _w); } _mm_store_ps(bufSum32, sum); wsum = bufSum32[0]; sum_b = bufSum32[1]; sum_g = bufSum32[2]; sum_r = bufSum32[3]; } #endif for(; k < maxk; k++ ) { const float* sptr_k = sptr + j + space_ofs[k]; float b = sptr_k[0], g = sptr_k[1], r = sptr_k[2]; float alpha = (float)((std::abs(b - b0) + std::abs(g - g0) + std::abs(r - r0))*scale_index); int idx = cvFloor(alpha); alpha -= idx; float w = space_weight[k]*(expLUT[idx] + alpha*(expLUT[idx+1] - expLUT[idx])); sum_b += b*w; sum_g += g*w; sum_r += r*w; wsum += w; } wsum = 1.f/wsum; b0 = sum_b*wsum; g0 = sum_g*wsum; r0 = sum_r*wsum; dptr[j] = b0; dptr[j+1] = g0; dptr[j+2] = r0; } } } } private: int cn, radius, maxk, *space_ofs; const Mat* temp; Mat *dest; float scale_index, *space_weight, *expLUT; }; static void bilateralFilter_32f( const Mat& src, Mat& dst, int d, double sigma_color, double sigma_space, int borderType ) { int cn = src.channels(); int i, j, maxk, radius; double minValSrc=-1, maxValSrc=1; const int kExpNumBinsPerChannel = 1 << 12; int kExpNumBins = 0; float lastExpVal = 1.f; float len, scale_index; Size size = src.size(); CV_Assert( (src.type() == CV_32FC1 || src.type() == CV_32FC3) && src.data != dst.data ); if( sigma_color <= 0 ) sigma_color = 1; if( sigma_space <= 0 ) sigma_space = 1; double gauss_color_coeff = -0.5/(sigma_color*sigma_color); double gauss_space_coeff = -0.5/(sigma_space*sigma_space); if( d <= 0 ) radius = cvRound(sigma_space*1.5); else radius = d/2; radius = MAX(radius, 1); d = radius*2 + 1; // compute the min/max range for the input image (even if multichannel) minMaxLoc( src.reshape(1), &minValSrc, &maxValSrc ); if(std::abs(minValSrc - maxValSrc) < FLT_EPSILON) { src.copyTo(dst); return; } // temporary copy of the image with borders for easy processing Mat temp; copyMakeBorder( src, temp, radius, radius, radius, radius, borderType ); const double insteadNaNValue = -5. * sigma_color; patchNaNs( temp, insteadNaNValue ); // this replacement of NaNs makes the assumption that depth values are nonnegative // TODO: make insteadNaNValue avalible in the outside function interface to control the cases breaking the assumption // allocate lookup tables std::vector _space_weight(d*d); std::vector _space_ofs(d*d); float* space_weight = &_space_weight[0]; int* space_ofs = &_space_ofs[0]; // assign a length which is slightly more than needed len = (float)(maxValSrc - minValSrc) * cn; kExpNumBins = kExpNumBinsPerChannel * cn; std::vector _expLUT(kExpNumBins+2); float* expLUT = &_expLUT[0]; scale_index = kExpNumBins/len; // initialize the exp LUT for( i = 0; i < kExpNumBins+2; i++ ) { if( lastExpVal > 0.f ) { double val = i / scale_index; expLUT[i] = (float)std::exp(val * val * gauss_color_coeff); lastExpVal = expLUT[i]; } else expLUT[i] = 0.f; } // initialize space-related bilateral filter coefficients for( i = -radius, maxk = 0; i <= radius; i++ ) for( j = -radius; j <= radius; j++ ) { double r = std::sqrt((double)i*i + (double)j*j); if( r > radius ) continue; space_weight[maxk] = (float)std::exp(r*r*gauss_space_coeff); space_ofs[maxk++] = (int)(i*(temp.step/sizeof(float)) + j*cn); } // parallel_for usage BilateralFilter_32f_Invoker body(cn, radius, maxk, space_ofs, temp, dst, scale_index, space_weight, expLUT); parallel_for_(Range(0, size.height), body, dst.total()/(double)(1<<16)); } } void cv::bilateralFilter( InputArray _src, OutputArray _dst, int d, double sigmaColor, double sigmaSpace, int borderType ) { _dst.create( _src.size(), _src.type() ); CV_OCL_RUN(_src.dims() <= 2 && _dst.isUMat(), ocl_bilateralFilter_8u(_src, _dst, d, sigmaColor, sigmaSpace, borderType)) Mat src = _src.getMat(), dst = _dst.getMat(); if( src.depth() == CV_8U ) bilateralFilter_8u( src, dst, d, sigmaColor, sigmaSpace, borderType ); else if( src.depth() == CV_32F ) bilateralFilter_32f( src, dst, d, sigmaColor, sigmaSpace, borderType ); else CV_Error( CV_StsUnsupportedFormat, "Bilateral filtering is only implemented for 8u and 32f images" ); } ////////////////////////////////////////////////////////////////////////////////////////// CV_IMPL void cvSmooth( const void* srcarr, void* dstarr, int smooth_type, int param1, int param2, double param3, double param4 ) { cv::Mat src = cv::cvarrToMat(srcarr), dst0 = cv::cvarrToMat(dstarr), dst = dst0; CV_Assert( dst.size() == src.size() && (smooth_type == CV_BLUR_NO_SCALE || dst.type() == src.type()) ); if( param2 <= 0 ) param2 = param1; if( smooth_type == CV_BLUR || smooth_type == CV_BLUR_NO_SCALE ) cv::boxFilter( src, dst, dst.depth(), cv::Size(param1, param2), cv::Point(-1,-1), smooth_type == CV_BLUR, cv::BORDER_REPLICATE ); else if( smooth_type == CV_GAUSSIAN ) cv::GaussianBlur( src, dst, cv::Size(param1, param2), param3, param4, cv::BORDER_REPLICATE ); else if( smooth_type == CV_MEDIAN ) cv::medianBlur( src, dst, param1 ); else cv::bilateralFilter( src, dst, param1, param3, param4, cv::BORDER_REPLICATE ); if( dst.data != dst0.data ) CV_Error( CV_StsUnmatchedFormats, "The destination image does not have the proper type" ); } /* End of file. */