/*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. // Copyright (C) 2013, OpenCV Foundation, 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*/ /* This is a variation of "Stereo Processing by Semiglobal Matching and Mutual Information" by Heiko Hirschmuller. We match blocks rather than individual pixels, thus the algorithm is called SGBM (Semi-global block matching) */ #include "precomp.hpp" #include #include "opencv2/core/hal/intrin.hpp" namespace cv { typedef uchar PixType; typedef short CostType; typedef short DispType; // NR - the number of directions. the loop on x that computes Lr assumes that NR == 8. // if you change NR, please, modify the loop as well. enum { NR = 8, NR2 = NR/2 }; struct StereoSGBMParams { StereoSGBMParams() { minDisparity = numDisparities = 0; SADWindowSize = 0; P1 = P2 = 0; disp12MaxDiff = 0; preFilterCap = 0; uniquenessRatio = 0; speckleWindowSize = 0; speckleRange = 0; mode = StereoSGBM::MODE_SGBM; } StereoSGBMParams( int _minDisparity, int _numDisparities, int _SADWindowSize, int _P1, int _P2, int _disp12MaxDiff, int _preFilterCap, int _uniquenessRatio, int _speckleWindowSize, int _speckleRange, int _mode ) { minDisparity = _minDisparity; numDisparities = _numDisparities; SADWindowSize = _SADWindowSize; P1 = _P1; P2 = _P2; disp12MaxDiff = _disp12MaxDiff; preFilterCap = _preFilterCap; uniquenessRatio = _uniquenessRatio; speckleWindowSize = _speckleWindowSize; speckleRange = _speckleRange; mode = _mode; } int minDisparity; int numDisparities; int SADWindowSize; int preFilterCap; int uniquenessRatio; int P1; int P2; int speckleWindowSize; int speckleRange; int disp12MaxDiff; int mode; }; #if CV_SIMD #if CV_SIMD_WIDTH == 16 static inline v_int16 vx_setseq_s16() { return v_int16(0, 1, 2, 3, 4, 5, 6, 7); } #elif CV_SIMD_WIDTH == 32 static inline v_int16 vx_setseq_s16() { return v_int16(0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15); } #elif CV_SIMD_WIDTH == 64 static inline v_int16 vx_setseq_s16() { return v_int16(0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31); } #else struct vseq_s16 { short data[v_int16::nlanes]; vseq_s16() { for (int i = 0; i < v_int16::nlanes; i++) data[i] = i; } }; static inline v_int16 vx_setseq_s16() { static vseq_s16 vseq; return vx_load(vseq.data); } #endif // define some additional reduce operations: static inline void min_pos(const v_int16& val, const v_int16& pos, short &min_val, short &min_pos) { min_val = v_reduce_min(val); v_int16 v_mask = (vx_setall_s16(min_val) == val); min_pos = v_reduce_min(((pos+vx_setseq_s16()) & v_mask) | (vx_setall_s16(SHRT_MAX) & ~v_mask)); } #endif static const int DEFAULT_RIGHT_BORDER = -1; /* For each pixel row1[x], max(maxD, 0) <= minX <= x < maxX <= width - max(0, -minD), and for each disparity minD<=d width1) ? width1 : xrange_max; maxX1 = minX1 + xrange_max; minX1 += xrange_min; width1 = maxX1 - minX1; int minX2 = std::max(minX1 - maxD, 0), maxX2 = std::min(maxX1 - minD, width); int width2 = maxX2 - minX2; const PixType *row1 = img1.ptr(y), *row2 = img2.ptr(y); PixType *prow1 = buffer + width2*2, *prow2 = prow1 + width*cn*2; tab += tabOfs; for( c = 0; c < cn*2; c++ ) { prow1[width*c] = prow1[width*c + width-1] = prow2[width*c] = prow2[width*c + width-1] = tab[0]; } int n1 = y > 0 ? -(int)img1.step : 0, s1 = y < img1.rows-1 ? (int)img1.step : 0; int n2 = y > 0 ? -(int)img2.step : 0, s2 = y < img2.rows-1 ? (int)img2.step : 0; int minX_cmn = std::min(minX1,minX2)-1; int maxX_cmn = std::max(maxX1,maxX2)+1; minX_cmn = std::max(minX_cmn, 1); maxX_cmn = std::min(maxX_cmn, width - 1); if( cn == 1 ) { for( x = minX_cmn; x < maxX_cmn; x++ ) { prow1[x] = tab[(row1[x+1] - row1[x-1])*2 + row1[x+n1+1] - row1[x+n1-1] + row1[x+s1+1] - row1[x+s1-1]]; prow2[width-1-x] = tab[(row2[x+1] - row2[x-1])*2 + row2[x+n2+1] - row2[x+n2-1] + row2[x+s2+1] - row2[x+s2-1]]; prow1[x+width] = row1[x]; prow2[width-1-x+width] = row2[x]; } } else { for( x = minX_cmn; x < maxX_cmn; x++ ) { prow1[x] = tab[(row1[x*3+3] - row1[x*3-3])*2 + row1[x*3+n1+3] - row1[x*3+n1-3] + row1[x*3+s1+3] - row1[x*3+s1-3]]; prow1[x+width] = tab[(row1[x*3+4] - row1[x*3-2])*2 + row1[x*3+n1+4] - row1[x*3+n1-2] + row1[x*3+s1+4] - row1[x*3+s1-2]]; prow1[x+width*2] = tab[(row1[x*3+5] - row1[x*3-1])*2 + row1[x*3+n1+5] - row1[x*3+n1-1] + row1[x*3+s1+5] - row1[x*3+s1-1]]; prow2[width-1-x] = tab[(row2[x*3+3] - row2[x*3-3])*2 + row2[x*3+n2+3] - row2[x*3+n2-3] + row2[x*3+s2+3] - row2[x*3+s2-3]]; prow2[width-1-x+width] = tab[(row2[x*3+4] - row2[x*3-2])*2 + row2[x*3+n2+4] - row2[x*3+n2-2] + row2[x*3+s2+4] - row2[x*3+s2-2]]; prow2[width-1-x+width*2] = tab[(row2[x*3+5] - row2[x*3-1])*2 + row2[x*3+n2+5] - row2[x*3+n2-1] + row2[x*3+s2+5] - row2[x*3+s2-1]]; prow1[x+width*3] = row1[x*3]; prow1[x+width*4] = row1[x*3+1]; prow1[x+width*5] = row1[x*3+2]; prow2[width-1-x+width*3] = row2[x*3]; prow2[width-1-x+width*4] = row2[x*3+1]; prow2[width-1-x+width*5] = row2[x*3+2]; } } memset( cost + xrange_min*D, 0, width1*D*sizeof(cost[0]) ); buffer -= width-maxX2; cost -= (minX1-xrange_min)*D + minD; // simplify the cost indices inside the loop for( c = 0; c < cn*2; c++, prow1 += width, prow2 += width ) { int diff_scale = c < cn ? 0 : 2; // precompute // v0 = min(row2[x-1/2], row2[x], row2[x+1/2]) and // v1 = max(row2[x-1/2], row2[x], row2[x+1/2]) and // to process values from [minX2, maxX2) we should check memory location (width - 1 - maxX2, width - 1 - minX2] // so iterate through [width - maxX2, width - minX2) for( x = width-maxX2; x < width-minX2; x++ ) { int v = prow2[x]; int vl = x > 0 ? (v + prow2[x-1])/2 : v; int vr = x < width-1 ? (v + prow2[x+1])/2 : v; int v0 = std::min(vl, vr); v0 = std::min(v0, v); int v1 = std::max(vl, vr); v1 = std::max(v1, v); buffer[x] = (PixType)v0; buffer[x + width2] = (PixType)v1; } for( x = minX1; x < maxX1; x++ ) { int u = prow1[x]; int ul = x > 0 ? (u + prow1[x-1])/2 : u; int ur = x < width-1 ? (u + prow1[x+1])/2 : u; int u0 = std::min(ul, ur); u0 = std::min(u0, u); int u1 = std::max(ul, ur); u1 = std::max(u1, u); int d = minD; #if CV_SIMD v_uint8 _u = vx_setall_u8((uchar)u), _u0 = vx_setall_u8((uchar)u0); v_uint8 _u1 = vx_setall_u8((uchar)u1); for( ; d <= maxD - 2*v_int16::nlanes; d += 2*v_int16::nlanes ) { v_uint8 _v = vx_load(prow2 + width-x-1 + d); v_uint8 _v0 = vx_load(buffer + width-x-1 + d); v_uint8 _v1 = vx_load(buffer + width-x-1 + d + width2); v_uint8 c0 = v_max(_u - _v1, _v0 - _u); v_uint8 c1 = v_max(_v - _u1, _u0 - _v); v_uint8 diff = v_min(c0, c1); v_int16 _c0 = vx_load_aligned(cost + x*D + d); v_int16 _c1 = vx_load_aligned(cost + x*D + d + v_int16::nlanes); v_uint16 diff1,diff2; v_expand(diff,diff1,diff2); v_store_aligned(cost + x*D + d, _c0 + v_reinterpret_as_s16(diff1 >> diff_scale)); v_store_aligned(cost + x*D + d + v_int16::nlanes, _c1 + v_reinterpret_as_s16(diff2 >> diff_scale)); } #endif for( ; d < maxD; d++ ) { int v = prow2[width-x-1 + d]; int v0 = buffer[width-x-1 + d]; int v1 = buffer[width-x-1 + d + width2]; int c0 = std::max(0, u - v1); c0 = std::max(c0, v0 - u); int c1 = std::max(0, v - u1); c1 = std::max(c1, u0 - v); cost[x*D + d] = (CostType)(cost[x*D+d] + (std::min(c0, c1) >> diff_scale)); } } } } /* computes disparity for "roi" in img1 w.r.t. img2 and write it to disp1buf. that is, disp1buf(x, y)=d means that img1(x+roi.x, y+roi.y) ~ img2(x+roi.x-d, y+roi.y). minD <= d < maxD. disp2full is the reverse disparity map, that is: disp2full(x+roi.x,y+roi.y)=d means that img2(x+roi.x, y+roi.y) ~ img1(x+roi.x+d, y+roi.y) note that disp1buf will have the same size as the roi and disp2full will have the same size as img1 (or img2). On exit disp2buf is not the final disparity, it is an intermediate result that becomes final after all the tiles are processed. the disparity in disp1buf is written with sub-pixel accuracy (4 fractional bits, see StereoSGBM::DISP_SCALE), using quadratic interpolation, while the disparity in disp2buf is written as is, without interpolation. disp2cost also has the same size as img1 (or img2). It contains the minimum current cost, used to find the best disparity, corresponding to the minimal cost. */ static void computeDisparitySGBM( const Mat& img1, const Mat& img2, Mat& disp1, const StereoSGBMParams& params, Mat& buffer ) { const int DISP_SHIFT = StereoMatcher::DISP_SHIFT; const int DISP_SCALE = (1 << DISP_SHIFT); const CostType MAX_COST = SHRT_MAX; int minD = params.minDisparity, maxD = minD + params.numDisparities; Size SADWindowSize; SADWindowSize.width = SADWindowSize.height = params.SADWindowSize > 0 ? params.SADWindowSize : 5; int ftzero = std::max(params.preFilterCap, 15) | 1; int uniquenessRatio = params.uniquenessRatio >= 0 ? params.uniquenessRatio : 10; int disp12MaxDiff = params.disp12MaxDiff > 0 ? params.disp12MaxDiff : 1; int P1 = params.P1 > 0 ? params.P1 : 2, P2 = std::max(params.P2 > 0 ? params.P2 : 5, P1+1); int k, width = disp1.cols, height = disp1.rows; int minX1 = std::max(maxD, 0), maxX1 = width + std::min(minD, 0); int D = maxD - minD, width1 = maxX1 - minX1; int Da = (int)alignSize(D, v_int16::nlanes); int Dlra = Da + v_int16::nlanes;//Additional memory is necessary to store disparity values(MAX_COST) for d=-1 and d=D int INVALID_DISP = minD - 1, INVALID_DISP_SCALED = INVALID_DISP*DISP_SCALE; int SW2 = SADWindowSize.width/2, SH2 = SADWindowSize.height/2; bool fullDP = params.mode == StereoSGBM::MODE_HH; int npasses = fullDP ? 2 : 1; const int TAB_OFS = 256*4, TAB_SIZE = 256 + TAB_OFS*2; PixType clipTab[TAB_SIZE]; for( k = 0; k < TAB_SIZE; k++ ) clipTab[k] = (PixType)(std::min(std::max(k - TAB_OFS, -ftzero), ftzero) + ftzero); if( minX1 >= maxX1 ) { disp1 = Scalar::all(INVALID_DISP_SCALED); return; } // for each possible stereo match (img1(x,y) <=> img2(x-d,y)) // we keep pixel difference cost (C) and the summary cost over NR directions (S). // we also keep all the partial costs for the previous line L_r(x,d) and also min_k L_r(x, k) size_t costBufSize = width1*Da; size_t CSBufSize = costBufSize*(fullDP ? height : 1); size_t minLrSize = (width1 + 2)*NR2, LrSize = minLrSize*Dlra; int hsumBufNRows = SH2*2 + 2; // the number of L_r(.,.) and min_k L_r(.,.) lines in the buffer: // for 8-way dynamic programming we need the current row and // the previous row, i.e. 2 rows in total size_t totalBufSize = CV_SIMD_WIDTH + CSBufSize * 2 * sizeof(CostType) + // alignment, C, S costBufSize*(hsumBufNRows + 1)*sizeof(CostType) + // hsumBuf, pixdiff ((LrSize + minLrSize)*2 + v_int16::nlanes) * sizeof(CostType) + // minLr[] and Lr[] width*(sizeof(CostType) + sizeof(DispType)) + // disp2cost + disp2 width * (4*img1.channels() + 2) * sizeof(PixType); // temp buffer for computing per-pixel cost if( buffer.empty() || !buffer.isContinuous() || buffer.cols*buffer.rows*buffer.elemSize() < totalBufSize ) buffer.reserveBuffer(totalBufSize); // summary cost over different (nDirs) directions CostType* Cbuf = (CostType*)alignPtr(buffer.ptr(), CV_SIMD_WIDTH); CostType* Sbuf = Cbuf + CSBufSize; CostType* hsumBuf = Sbuf + CSBufSize; CostType* pixDiff = hsumBuf + costBufSize*hsumBufNRows; CostType* disp2cost = pixDiff + costBufSize + ((LrSize + minLrSize)*2 + v_int16::nlanes); DispType* disp2ptr = (DispType*)(disp2cost + width); PixType* tempBuf = (PixType*)(disp2ptr + width); // add P2 to every C(x,y). it saves a few operations in the inner loops for(k = 0; k < (int)CSBufSize; k++ ) Cbuf[k] = (CostType)P2; for( int pass = 1; pass <= npasses; pass++ ) { int x1, y1, x2, y2, dx, dy; if( pass == 1 ) { y1 = 0; y2 = height; dy = 1; x1 = 0; x2 = width1; dx = 1; } else { y1 = height-1; y2 = -1; dy = -1; x1 = width1-1; x2 = -1; dx = -1; } CostType *Lr[2]={0}, *minLr[2]={0}; for( k = 0; k < 2; k++ ) { // shift Lr[k] and minLr[k] pointers, because we allocated them with the borders, // and will occasionally use negative indices with the arrays // we need to shift Lr[k] pointers by 1, to give the space for d=-1. // however, then the alignment will be imperfect, i.e. bad for SSE, // thus we shift the pointers by SIMD vector size Lr[k] = pixDiff + costBufSize + v_int16::nlanes + LrSize*k + NR2*Dlra; memset( Lr[k] - NR2*Dlra, 0, LrSize*sizeof(CostType) ); minLr[k] = pixDiff + costBufSize + v_int16::nlanes + LrSize*2 + minLrSize*k + NR2; memset( minLr[k] - NR2, 0, minLrSize*sizeof(CostType) ); } for( int y = y1; y != y2; y += dy ) { int x, d; DispType* disp1ptr = disp1.ptr(y); CostType* C = Cbuf + (!fullDP ? 0 : y*costBufSize); CostType* S = Sbuf + (!fullDP ? 0 : y*costBufSize); if( pass == 1 ) // compute C on the first pass, and reuse it on the second pass, if any. { int dy1 = y == 0 ? 0 : y + SH2, dy2 = y == 0 ? SH2 : dy1; for( k = dy1; k <= dy2; k++ ) { CostType* hsumAdd = hsumBuf + (std::min(k, height-1) % hsumBufNRows)*costBufSize; if( k < height ) { calcPixelCostBT( img1, img2, k, minD, maxD, pixDiff, tempBuf, clipTab, TAB_OFS, ftzero ); memset(hsumAdd, 0, Da*sizeof(CostType)); #if CV_SIMD v_int16 h_scale = vx_setall_s16((short)SW2 + 1); for( d = 0; d < Da; d += v_int16::nlanes ) { v_int16 v_hsumAdd = vx_load_aligned(pixDiff + d) * h_scale; for( x = Da; x <= SW2*Da; x += Da ) v_hsumAdd += vx_load_aligned(pixDiff + x + d); v_store_aligned(hsumAdd + d, v_hsumAdd); } #else for (d = 0; d < D; d++) { hsumAdd[d] = (CostType)(pixDiff[d] * (SW2 + 1)); for( x = Da; x <= SW2*Da; x += Da ) hsumAdd[d] = (CostType)(hsumAdd[d] + pixDiff[x + d]); } #endif if( y > 0 ) { const CostType* hsumSub = hsumBuf + (std::max(y - SH2 - 1, 0) % hsumBufNRows)*costBufSize; const CostType* Cprev = !fullDP || y == 0 ? C : C - costBufSize; #if CV_SIMD for (d = 0; d < Da; d += v_int16::nlanes) v_store_aligned(C + d, vx_load_aligned(Cprev + d) + vx_load_aligned(hsumAdd + d) - vx_load_aligned(hsumSub + d)); #else for (d = 0; d < D; d++) C[d] = (CostType)(Cprev[d] + hsumAdd[d] - hsumSub[d]); #endif for( x = Da; x < width1*Da; x += Da ) { const CostType* pixAdd = pixDiff + std::min(x + SW2*Da, (width1-1)*Da); const CostType* pixSub = pixDiff + std::max(x - (SW2+1)*Da, 0); #if CV_SIMD for( d = 0; d < Da; d += v_int16::nlanes ) { v_int16 hv = vx_load_aligned(hsumAdd + x - Da + d) - vx_load_aligned(pixSub + d) + vx_load_aligned(pixAdd + d); v_store_aligned(hsumAdd + x + d, hv); v_store_aligned(C + x + d, vx_load_aligned(Cprev + x + d) - vx_load_aligned(hsumSub + x + d) + hv); } #else for( d = 0; d < D; d++ ) { int hv = hsumAdd[x + d] = (CostType)(hsumAdd[x - Da + d] + pixAdd[d] - pixSub[d]); C[x + d] = (CostType)(Cprev[x + d] + hv - hsumSub[x + d]); } #endif } } else { #if CV_SIMD v_int16 v_scale = vx_setall_s16(k == 0 ? (short)SH2 + 1 : 1); for (d = 0; d < Da; d += v_int16::nlanes) v_store_aligned(C + d, vx_load_aligned(C + d) + vx_load_aligned(hsumAdd + d) * v_scale); #else int scale = k == 0 ? SH2 + 1 : 1; for (d = 0; d < D; d++) C[d] = (CostType)(C[d] + hsumAdd[d] * scale); #endif for( x = Da; x < width1*Da; x += Da ) { const CostType* pixAdd = pixDiff + std::min(x + SW2*Da, (width1-1)*Da); const CostType* pixSub = pixDiff + std::max(x - (SW2+1)*Da, 0); #if CV_SIMD for (d = 0; d < Da; d += v_int16::nlanes) { v_int16 hv = vx_load_aligned(hsumAdd + x - Da + d) + vx_load_aligned(pixAdd + d) - vx_load_aligned(pixSub + d); v_store_aligned(hsumAdd + x + d, hv); v_store_aligned(C + x + d, vx_load_aligned(C + x + d) + hv * v_scale); } #else for( d = 0; d < D; d++ ) { CostType hv = (CostType)(hsumAdd[x - Da + d] + pixAdd[d] - pixSub[d]); hsumAdd[x + d] = hv; C[x + d] = (CostType)(C[x + d] + hv * scale); } #endif } } } else { if( y > 0 ) { const CostType* hsumSub = hsumBuf + (std::max(y - SH2 - 1, 0) % hsumBufNRows)*costBufSize; const CostType* Cprev = !fullDP || y == 0 ? C : C - costBufSize; #if CV_SIMD for (x = 0; x < width1*Da; x += v_int16::nlanes) v_store_aligned(C + x, vx_load_aligned(Cprev + x) - vx_load_aligned(hsumSub + x) + vx_load_aligned(hsumAdd + x)); #else for (x = 0; x < width1*Da; x++) C[x] = (CostType)(Cprev[x] + hsumAdd[x] - hsumSub[x]); #endif } else { #if CV_SIMD for (x = 0; x < width1*Da; x += v_int16::nlanes) v_store_aligned(C + x, vx_load_aligned(C + x) + vx_load_aligned(hsumAdd + x)); #else for (x = 0; x < width1*Da; x++) C[x] = (CostType)(C[x] + hsumAdd[x]); #endif } } } // also, clear the S buffer memset(S, 0, width1*Da * sizeof(CostType)); } /* [formula 13 in the paper] compute L_r(p, d) = C(p, d) + min(L_r(p-r, d), L_r(p-r, d-1) + P1, L_r(p-r, d+1) + P1, min_k L_r(p-r, k) + P2) - min_k L_r(p-r, k) where p = (x,y), r is one of the directions. we process all the directions at once: 0: r=(-dx, 0) 1: r=(-1, -dy) 2: r=(0, -dy) 3: r=(1, -dy) !!!Note that only directions 0 to 3 are processed 4: r=(-2, -dy) 5: r=(-1, -dy*2) 6: r=(1, -dy*2) 7: r=(2, -dy) */ for( x = x1; x != x2; x += dx ) { int xm = x*NR2, xd = xm*Dlra; int delta0 = minLr[0][xm - dx*NR2] + P2, delta1 = minLr[1][xm - NR2 + 1] + P2; int delta2 = minLr[1][xm + 2] + P2, delta3 = minLr[1][xm + NR2 + 3] + P2; CostType* Lr_p0 = Lr[0] + xd - dx*NR2*Dlra; CostType* Lr_p1 = Lr[1] + xd - NR2*Dlra + Dlra; CostType* Lr_p2 = Lr[1] + xd + Dlra*2; CostType* Lr_p3 = Lr[1] + xd + NR2*Dlra + Dlra*3; Lr_p0[-1] = Lr_p0[D] = Lr_p1[-1] = Lr_p1[D] = Lr_p2[-1] = Lr_p2[D] = Lr_p3[-1] = Lr_p3[D] = MAX_COST; CostType* Lr_p = Lr[0] + xd; const CostType* Cp = C + x*Da; CostType* Sp = S + x*Da; CostType* minL = minLr[0] + xm; d = 0; #if CV_SIMD v_int16 _P1 = vx_setall_s16((short)P1); v_int16 _delta0 = vx_setall_s16((short)delta0); v_int16 _delta1 = vx_setall_s16((short)delta1); v_int16 _delta2 = vx_setall_s16((short)delta2); v_int16 _delta3 = vx_setall_s16((short)delta3); v_int16 _minL0 = vx_setall_s16((short)MAX_COST); v_int16 _minL1 = vx_setall_s16((short)MAX_COST); v_int16 _minL2 = vx_setall_s16((short)MAX_COST); v_int16 _minL3 = vx_setall_s16((short)MAX_COST); for( ; d <= D - v_int16::nlanes; d += v_int16::nlanes ) { v_int16 Cpd = vx_load_aligned(Cp + d); v_int16 Spd = vx_load_aligned(Sp + d); v_int16 L; L = v_min(v_min(v_min(vx_load_aligned(Lr_p0 + d), vx_load(Lr_p0 + d - 1) + _P1), vx_load(Lr_p0 + d + 1) + _P1), _delta0) - _delta0 + Cpd; v_store_aligned(Lr_p + d, L); _minL0 = v_min(_minL0, L); Spd += L; L = v_min(v_min(v_min(vx_load_aligned(Lr_p1 + d), vx_load(Lr_p1 + d - 1) + _P1), vx_load(Lr_p1 + d + 1) + _P1), _delta1) - _delta1 + Cpd; v_store_aligned(Lr_p + d + Dlra, L); _minL1 = v_min(_minL1, L); Spd += L; L = v_min(v_min(v_min(vx_load_aligned(Lr_p2 + d), vx_load(Lr_p2 + d - 1) + _P1), vx_load(Lr_p2 + d + 1) + _P1), _delta2) - _delta2 + Cpd; v_store_aligned(Lr_p + d + Dlra*2, L); _minL2 = v_min(_minL2, L); Spd += L; L = v_min(v_min(v_min(vx_load_aligned(Lr_p3 + d), vx_load(Lr_p3 + d - 1) + _P1), vx_load(Lr_p3 + d + 1) + _P1), _delta3) - _delta3 + Cpd; v_store_aligned(Lr_p + d + Dlra*3, L); _minL3 = v_min(_minL3, L); Spd += L; v_store_aligned(Sp + d, Spd); } #if CV_SIMD_WIDTH > 32 minL[0] = v_reduce_min(_minL0); minL[1] = v_reduce_min(_minL1); minL[2] = v_reduce_min(_minL2); minL[3] = v_reduce_min(_minL3); #else // Get minimum for L0-L3 v_int16 t0, t1, t2, t3; v_zip(_minL0, _minL2, t0, t2); v_zip(_minL1, _minL3, t1, t3); v_zip(v_min(t0, t2), v_min(t1, t3), t0, t1); t0 = v_min(t0, t1); t0 = v_min(t0, v_rotate_right<4>(t0)); #if CV_SIMD_WIDTH == 32 CostType buf[v_int16::nlanes]; v_store_low(buf, v_min(t0, v_rotate_right<8>(t0))); minL[0] = buf[0]; minL[1] = buf[1]; minL[2] = buf[2]; minL[3] = buf[3]; #else v_store_low(minL, t0); #endif #endif #else minL[0] = MAX_COST; minL[1] = MAX_COST; minL[2] = MAX_COST; minL[3] = MAX_COST; #endif for( ; d < D; d++ ) { int Cpd = Cp[d], L; int Spd = Sp[d]; L = Cpd + std::min((int)Lr_p0[d], std::min(Lr_p0[d - 1] + P1, std::min(Lr_p0[d + 1] + P1, delta0))) - delta0; Lr_p[d] = (CostType)L; minL[0] = std::min(minL[0], (CostType)L); Spd += L; L = Cpd + std::min((int)Lr_p1[d], std::min(Lr_p1[d - 1] + P1, std::min(Lr_p1[d + 1] + P1, delta1))) - delta1; Lr_p[d + Dlra] = (CostType)L; minL[1] = std::min(minL[1], (CostType)L); Spd += L; L = Cpd + std::min((int)Lr_p2[d], std::min(Lr_p2[d - 1] + P1, std::min(Lr_p2[d + 1] + P1, delta2))) - delta2; Lr_p[d + Dlra*2] = (CostType)L; minL[2] = std::min(minL[2], (CostType)L); Spd += L; L = Cpd + std::min((int)Lr_p3[d], std::min(Lr_p3[d - 1] + P1, std::min(Lr_p3[d + 1] + P1, delta3))) - delta3; Lr_p[d + Dlra*3] = (CostType)L; minL[3] = std::min(minL[3], (CostType)L); Spd += L; Sp[d] = saturate_cast(Spd); } } if( pass == npasses ) { x = 0; #if CV_SIMD v_int16 v_inv_dist = vx_setall_s16((DispType)INVALID_DISP_SCALED); v_int16 v_max_cost = vx_setall_s16(MAX_COST); for( ; x <= width - v_int16::nlanes; x += v_int16::nlanes ) { v_store(disp1ptr + x, v_inv_dist); v_store(disp2ptr + x, v_inv_dist); v_store(disp2cost + x, v_max_cost); } #endif for( ; x < width; x++ ) { disp1ptr[x] = disp2ptr[x] = (DispType)INVALID_DISP_SCALED; disp2cost[x] = MAX_COST; } for( x = width1 - 1; x >= 0; x-- ) { CostType* Sp = S + x*Da; CostType minS = MAX_COST; short bestDisp = -1; if( npasses == 1 ) { int xm = x*NR2, xd = xm*Dlra; CostType* Lr_p0 = Lr[0] + xd + NR2*Dlra; Lr_p0[-1] = Lr_p0[D] = MAX_COST; CostType* Lr_p = Lr[0] + xd; const CostType* Cp = C + x*Da; d = 0; int delta0 = minLr[0][xm + NR2] + P2; int minL0 = MAX_COST; #if CV_SIMD v_int16 _P1 = vx_setall_s16((short)P1); v_int16 _delta0 = vx_setall_s16((short)delta0); v_int16 _minL0 = vx_setall_s16((short)MAX_COST); v_int16 _minS = vx_setall_s16(MAX_COST), _bestDisp = vx_setall_s16(-1); for( ; d <= D - v_int16::nlanes; d += v_int16::nlanes ) { v_int16 Cpd = vx_load_aligned(Cp + d); v_int16 L0 = v_min(v_min(v_min(vx_load_aligned(Lr_p0 + d), vx_load(Lr_p0 + d - 1) + _P1), vx_load(Lr_p0 + d + 1) + _P1), _delta0) - _delta0 + Cpd; v_store_aligned(Lr_p + d, L0); _minL0 = v_min(_minL0, L0); L0 += vx_load_aligned(Sp + d); v_store_aligned(Sp + d, L0); _bestDisp = v_select(_minS > L0, vx_setall_s16((short)d), _bestDisp); _minS = v_min(_minS, L0); } minL0 = (CostType)v_reduce_min(_minL0); min_pos(_minS, _bestDisp, minS, bestDisp); #endif for( ; d < D; d++ ) { int L0 = Cp[d] + std::min((int)Lr_p0[d], std::min(Lr_p0[d-1] + P1, std::min(Lr_p0[d+1] + P1, delta0))) - delta0; Lr_p[d] = (CostType)L0; minL0 = std::min(minL0, L0); CostType Sval = Sp[d] = saturate_cast(Sp[d] + L0); if( Sval < minS ) { minS = Sval; bestDisp = (short)d; } } minLr[0][xm] = (CostType)minL0; } else { d = 0; #if CV_SIMD v_int16 _minS = vx_setall_s16(MAX_COST), _bestDisp = vx_setall_s16(-1); for( ; d <= D - v_int16::nlanes; d+= v_int16::nlanes ) { v_int16 L0 = vx_load_aligned(Sp + d); _bestDisp = v_select(_minS > L0, vx_setall_s16((short)d), _bestDisp); _minS = v_min( L0, _minS ); } min_pos(_minS, _bestDisp, minS, bestDisp); #endif for( ; d < D; d++ ) { int Sval = Sp[d]; if( Sval < minS ) { minS = (CostType)Sval; bestDisp = (short)d; } } } for( d = 0; d < D; d++ ) { if( Sp[d]*(100 - uniquenessRatio) < minS*100 && std::abs(bestDisp - d) > 1 ) break; } if( d < D ) continue; d = bestDisp; int _x2 = x + minX1 - d - minD; if( disp2cost[_x2] > minS ) { disp2cost[_x2] = (CostType)minS; disp2ptr[_x2] = (DispType)(d + minD); } if( 0 < d && d < D-1 ) { // do subpixel quadratic interpolation: // fit parabola into (x1=d-1, y1=Sp[d-1]), (x2=d, y2=Sp[d]), (x3=d+1, y3=Sp[d+1]) // then find minimum of the parabola. int denom2 = std::max(Sp[d-1] + Sp[d+1] - 2*Sp[d], 1); d = d*DISP_SCALE + ((Sp[d-1] - Sp[d+1])*DISP_SCALE + denom2)/(denom2*2); } else d *= DISP_SCALE; disp1ptr[x + minX1] = (DispType)(d + minD*DISP_SCALE); } for( x = minX1; x < maxX1; x++ ) { // we round the computed disparity both towards -inf and +inf and check // if either of the corresponding disparities in disp2 is consistent. // This is to give the computed disparity a chance to look valid if it is. int d1 = disp1ptr[x]; if( d1 == INVALID_DISP_SCALED ) continue; int _d = d1 >> DISP_SHIFT; int d_ = (d1 + DISP_SCALE-1) >> DISP_SHIFT; int _x = x - _d, x_ = x - d_; if( 0 <= _x && _x < width && disp2ptr[_x] >= minD && std::abs(disp2ptr[_x] - _d) > disp12MaxDiff && 0 <= x_ && x_ < width && disp2ptr[x_] >= minD && std::abs(disp2ptr[x_] - d_) > disp12MaxDiff ) disp1ptr[x] = (DispType)INVALID_DISP_SCALED; } } // now shift the cyclic buffers std::swap( Lr[0], Lr[1] ); std::swap( minLr[0], minLr[1] ); } } } //////////////////////////////////////////////////////////////////////////////////////////// struct CalcVerticalSums: public ParallelLoopBody { CalcVerticalSums(const Mat& _img1, const Mat& _img2, const StereoSGBMParams& params, CostType* alignedBuf, PixType* _clipTab): img1(_img1), img2(_img2), clipTab(_clipTab) { minD = params.minDisparity; maxD = minD + params.numDisparities; SW2 = SH2 = (params.SADWindowSize > 0 ? params.SADWindowSize : 5)/2; ftzero = std::max(params.preFilterCap, 15) | 1; P1 = params.P1 > 0 ? params.P1 : 2; P2 = std::max(params.P2 > 0 ? params.P2 : 5, P1+1); height = img1.rows; width = img1.cols; int minX1 = std::max(maxD, 0), maxX1 = width + std::min(minD, 0); D = maxD - minD; Da = (int)alignSize(D, v_int16::nlanes); Dlra = Da + v_int16::nlanes;//Additional memory is necessary to store disparity values(MAX_COST) for d=-1 and d=D width1 = maxX1 - minX1; costBufSize = width1*Da; CSBufSize = costBufSize*height; minLrSize = width1; LrSize = minLrSize*Dlra; hsumBufNRows = SH2*2 + 2; Cbuf = alignedBuf; Sbuf = Cbuf + CSBufSize; hsumBuf = Sbuf + CSBufSize; } void operator()(const Range& range) const CV_OVERRIDE { static const CostType MAX_COST = SHRT_MAX; static const int TAB_OFS = 256*4; static const int npasses = 2; int x1 = range.start, x2 = range.end, k; size_t pixDiffSize = ((x2 - x1) + 2*SW2)*Da; size_t auxBufsSize = CV_SIMD_WIDTH + pixDiffSize*sizeof(CostType) + //alignment and pixdiff size width*(4*img1.channels()+2)*sizeof(PixType); //tempBuf Mat auxBuff; auxBuff.create(1, (int)auxBufsSize, CV_8U); CostType* pixDiff = (CostType*)alignPtr(auxBuff.ptr(), CV_SIMD_WIDTH); PixType* tempBuf = (PixType*)(pixDiff + pixDiffSize); // Simplification of index calculation pixDiff -= (x1>SW2 ? (x1 - SW2): 0)*Da; for( int pass = 1; pass <= npasses; pass++ ) { int y1, y2, dy; if( pass == 1 ) { y1 = 0; y2 = height; dy = 1; } else { y1 = height-1; y2 = -1; dy = -1; } CostType *Lr[2]={0}, *minLr[2]={0}; for( k = 0; k < 2; k++ ) { // shift Lr[k] and minLr[k] pointers, because we allocated them with the borders, // and will occasionally use negative indices with the arrays // we need to shift Lr[k] pointers by 1, to give the space for d=-1. // however, then the alignment will be imperfect, i.e. bad for SSE, // thus we shift the pointers by SIMD vector size Lr[k] = hsumBuf + costBufSize*hsumBufNRows + v_int16::nlanes + LrSize*k; memset( Lr[k] + x1*Dlra, 0, (x2-x1)*Dlra*sizeof(CostType) ); minLr[k] = hsumBuf + costBufSize*hsumBufNRows + v_int16::nlanes + LrSize*2 + minLrSize*k; memset( minLr[k] + x1, 0, (x2-x1)*sizeof(CostType) ); } for( int y = y1; y != y2; y += dy ) { int x, d; CostType* C = Cbuf + y*costBufSize; CostType* S = Sbuf + y*costBufSize; if( pass == 1 ) // compute C on the first pass, and reuse it on the second pass, if any. { int dy1 = y == 0 ? 0 : y + SH2, dy2 = y == 0 ? SH2 : dy1; for( k = dy1; k <= dy2; k++ ) { CostType* hsumAdd = hsumBuf + (std::min(k, height-1) % hsumBufNRows)*costBufSize; if( k < height ) { calcPixelCostBT( img1, img2, k, minD, maxD, pixDiff, tempBuf, clipTab, TAB_OFS, ftzero, x1 - SW2, x2 + SW2); memset(hsumAdd + x1*Da, 0, Da*sizeof(CostType)); for( x = (x1 - SW2)*Da; x <= (x1 + SW2)*Da; x += Da ) { int xbord = x <= 0 ? 0 : (x > (width1 - 1)*Da ? (width1 - 1)*Da : x); #if CV_SIMD for( d = 0; d < Da; d += v_int16::nlanes ) v_store_aligned(hsumAdd + x1*Da + d, vx_load_aligned(hsumAdd + x1*Da + d) + vx_load_aligned(pixDiff + xbord + d)); #else for( d = 0; d < D; d++ ) hsumAdd[x1*Da + d] = (CostType)(hsumAdd[x1*Da + d] + pixDiff[xbord + d]); #endif } if( y > 0 ) { const CostType* hsumSub = hsumBuf + (std::max(y - SH2 - 1, 0) % hsumBufNRows)*costBufSize; const CostType* Cprev = C - costBufSize; #if CV_SIMD for( d = 0; d < Da; d += v_int16::nlanes ) v_store_aligned(C + x1*Da + d, vx_load_aligned(Cprev + x1*Da + d) + vx_load_aligned(hsumAdd + x1*Da + d) - vx_load_aligned(hsumSub + x1*Da + d)); #else for( d = 0; d < D; d++ ) C[x1*Da + d] = (CostType)(Cprev[x1*Da + d] + hsumAdd[x1*Da + d] - hsumSub[x1*Da + d]); #endif for( x = (x1+1)*Da; x < x2*Da; x += Da ) { const CostType* pixAdd = pixDiff + std::min(x + SW2*Da, (width1-1)*Da); const CostType* pixSub = pixDiff + std::max(x - (SW2+1)*Da, 0); #if CV_SIMD for( d = 0; d < Da; d += v_int16::nlanes ) { v_int16 hv = vx_load_aligned(hsumAdd + x - Da + d) - vx_load_aligned(pixSub + d) + vx_load_aligned(pixAdd + d); v_store_aligned(hsumAdd + x + d, hv); v_store_aligned(C + x + d, vx_load_aligned(Cprev + x + d) - vx_load_aligned(hsumSub + x + d) + hv); } #else for( d = 0; d < D; d++ ) { int hv = hsumAdd[x + d] = (CostType)(hsumAdd[x - Da + d] + pixAdd[d] - pixSub[d]); C[x + d] = (CostType)(Cprev[x + d] + hv - hsumSub[x + d]); } #endif } } else { #if CV_SIMD v_int16 v_scale = vx_setall_s16(k == 0 ? (short)SH2 + 1 : 1); for (d = 0; d < Da; d += v_int16::nlanes) v_store_aligned(C + x1*Da + d, vx_load_aligned(C + x1*Da + d) + vx_load_aligned(hsumAdd + x1*Da + d) * v_scale); #else int scale = k == 0 ? SH2 + 1 : 1; for (d = 0; d < D; d++) C[x1*Da + d] = (CostType)(C[x1*Da + d] + hsumAdd[x1*Da + d] * scale); #endif for( x = (x1+1)*Da; x < x2*Da; x += Da ) { const CostType* pixAdd = pixDiff + std::min(x + SW2*Da, (width1-1)*Da); const CostType* pixSub = pixDiff + std::max(x - (SW2+1)*Da, 0); #if CV_SIMD for (d = 0; d < Da; d += v_int16::nlanes) { v_int16 hv = vx_load_aligned(hsumAdd + x - Da + d) + vx_load_aligned(pixAdd + d) - vx_load_aligned(pixSub + d); v_store_aligned(hsumAdd + x + d, hv); v_store_aligned(C + x + d, vx_load_aligned(C + x + d) + hv * v_scale); } #else for( d = 0; d < D; d++ ) { CostType hv = (CostType)(hsumAdd[x - Da + d] + pixAdd[d] - pixSub[d]); hsumAdd[x + d] = hv; C[x + d] = (CostType)(C[x + d] + hv * scale); } #endif } } } else { /* if (y > 0) { const CostType* hsumSub = hsumBuf + (std::max(y - SH2 - 1, 0) % hsumBufNRows)*costBufSize; const CostType* Cprev = C - costBufSize; #if CV_SIMD for( x = x1*Da; x < x2*Da; x += v_int16::nlanes ) v_store_aligned(C + x, vx_load_aligned(Cprev + x) - vx_load_aligned(hsumSub + x) + vx_load_aligned(hsumAdd + x)); #else for( x = x1*Da; x < x2*Da; x++ ) C[x] = (CostType)(Cprev[x] + hsumAdd[x] - hsumSub[x]); #endif } else*/ if(y == 0) { #if CV_SIMD for( x = x1*Da; x < x2*Da; x += v_int16::nlanes ) v_store_aligned(C + x, vx_load_aligned(C + x) + vx_load_aligned(hsumAdd + x)); #else for( x = x1*Da; x < x2*Da; x++ ) C[x] = (CostType)(C[x] + hsumAdd[x]); #endif } } } // also, clear the S buffer memset(S + x1*Da, 0, (x2-x1)*Da*sizeof(CostType)); } // [formula 13 in the paper] // compute L_r(p, d) = C(p, d) + // min(L_r(p-r, d), // L_r(p-r, d-1) + P1, // L_r(p-r, d+1) + P1, // min_k L_r(p-r, k) + P2) - min_k L_r(p-r, k) // where p = (x,y), r is one of the directions. // we process one directions on first pass and other on second: // r=(0, dy), where dy=1 on first pass and dy=-1 on second for( x = x1; x != x2; x++ ) { int xd = x*Dlra; int delta = minLr[1][x] + P2; CostType* Lr_ppr = Lr[1] + xd; Lr_ppr[-1] = Lr_ppr[D] = MAX_COST; CostType* Lr_p = Lr[0] + xd; const CostType* Cp = C + x*Da; CostType* Sp = S + x*Da; CostType& minL = minLr[0][x]; d = 0; #if CV_SIMD v_int16 _P1 = vx_setall_s16((short)P1); v_int16 _delta = vx_setall_s16((short)delta); v_int16 _minL = vx_setall_s16((short)MAX_COST); for( ; d <= D - v_int16::nlanes; d += v_int16::nlanes ) { v_int16 Cpd = vx_load_aligned(Cp + d); v_int16 L = v_min(v_min(v_min(vx_load_aligned(Lr_ppr + d), vx_load(Lr_ppr + d - 1) + _P1), vx_load(Lr_ppr + d + 1) + _P1), _delta) - _delta + Cpd; v_store_aligned(Lr_p + d, L); _minL = v_min(_minL, L); v_store_aligned(Sp + d, vx_load_aligned(Sp + d) + L); } minL = v_reduce_min(_minL); #else minL = MAX_COST; #endif for( ; d < D; d++ ) { int Cpd = Cp[d], L; L = Cpd + std::min((int)Lr_ppr[d], std::min(Lr_ppr[d-1] + P1, std::min(Lr_ppr[d+1] + P1, delta))) - delta; Lr_p[d] = (CostType)L; minL = std::min(minL, (CostType)L); Sp[d] = saturate_cast(Sp[d] + L); } } // now shift the cyclic buffers std::swap( Lr[0], Lr[1] ); std::swap( minLr[0], minLr[1] ); } } } const Mat& img1; const Mat& img2; CostType* Cbuf; CostType* Sbuf; CostType* hsumBuf; PixType* clipTab; int minD; int maxD; int D, Da, Dlra; int SH2; int SW2; int width; int width1; int height; int P1; int P2; size_t costBufSize; size_t CSBufSize; size_t minLrSize; size_t LrSize; size_t hsumBufNRows; int ftzero; }; struct CalcHorizontalSums: public ParallelLoopBody { CalcHorizontalSums(const Mat& _img1, const Mat& _img2, Mat& _disp1, const StereoSGBMParams& params, CostType* alignedBuf): img1(_img1), img2(_img2), disp1(_disp1) { minD = params.minDisparity; maxD = minD + params.numDisparities; P1 = params.P1 > 0 ? params.P1 : 2; P2 = std::max(params.P2 > 0 ? params.P2 : 5, P1+1); uniquenessRatio = params.uniquenessRatio >= 0 ? params.uniquenessRatio : 10; disp12MaxDiff = params.disp12MaxDiff > 0 ? params.disp12MaxDiff : 1; height = img1.rows; width = img1.cols; minX1 = std::max(maxD, 0); maxX1 = width + std::min(minD, 0); INVALID_DISP = minD - 1; INVALID_DISP_SCALED = INVALID_DISP*DISP_SCALE; D = maxD - minD; Da = (int)alignSize(D, v_int16::nlanes); Dlra = Da + v_int16::nlanes;//Additional memory is necessary to store disparity values(MAX_COST) for d=-1 and d=D width1 = maxX1 - minX1; costBufSize = width1*Da; CSBufSize = costBufSize*height; LrSize = 2 * Dlra; Cbuf = alignedBuf; Sbuf = Cbuf + CSBufSize; } void operator()(const Range& range) const CV_OVERRIDE { int y1 = range.start, y2 = range.end; size_t auxBufsSize = CV_SIMD_WIDTH + (v_int16::nlanes + LrSize) * sizeof(CostType) + width*(sizeof(CostType) + sizeof(DispType)); Mat auxBuff; auxBuff.create(1, (int)auxBufsSize, CV_8U); CostType *Lr = ((CostType*)alignPtr(auxBuff.ptr(), CV_SIMD_WIDTH)) + v_int16::nlanes; CostType* disp2cost = Lr + LrSize; DispType* disp2ptr = (DispType*)(disp2cost + width); CostType minLr; for( int y = y1; y != y2; y++) { int x, d; DispType* disp1ptr = disp1.ptr(y); CostType* C = Cbuf + y*costBufSize; CostType* S = Sbuf + y*costBufSize; x = 0; #if CV_SIMD v_int16 v_inv_dist = vx_setall_s16((DispType)INVALID_DISP_SCALED); v_int16 v_max_cost = vx_setall_s16(MAX_COST); for (; x <= width - v_int16::nlanes; x += v_int16::nlanes) { v_store(disp1ptr + x, v_inv_dist); v_store(disp2ptr + x, v_inv_dist); v_store(disp2cost + x, v_max_cost); } #endif for( ; x < width; x++ ) { disp1ptr[x] = disp2ptr[x] = (DispType)INVALID_DISP_SCALED; disp2cost[x] = MAX_COST; } // clear buffers memset( Lr, 0, LrSize*sizeof(CostType) ); Lr[-1] = Lr[D] = Lr[Dlra - 1] = Lr[Dlra + D] = MAX_COST; minLr = 0; // [formula 13 in the paper] // compute L_r(p, d) = C(p, d) + // min(L_r(p-r, d), // L_r(p-r, d-1) + P1, // L_r(p-r, d+1) + P1, // min_k L_r(p-r, k) + P2) - min_k L_r(p-r, k) // where p = (x,y), r is one of the directions. // we process all the directions at once: // we process one directions on first pass and other on second: // r=(dx, 0), where dx=1 on first pass and dx=-1 on second for( x = 0; x != width1; x++) { int delta = minLr + P2; CostType* Lr_ppr = Lr + ((x&1)? 0 : Dlra); CostType* Lr_p = Lr + ((x&1)? Dlra :0); const CostType* Cp = C + x*Da; CostType* Sp = S + x*Da; d = 0; #if CV_SIMD v_int16 _P1 = vx_setall_s16((short)P1); v_int16 _delta = vx_setall_s16((short)delta); v_int16 _minL = vx_setall_s16((short)MAX_COST); for( ; d <= D - v_int16::nlanes; d += v_int16::nlanes) { v_int16 Cpd = vx_load_aligned(Cp + d); v_int16 L = v_min(v_min(v_min(vx_load_aligned(Lr_ppr + d), vx_load(Lr_ppr + d - 1) + _P1), vx_load(Lr_ppr + d + 1) + _P1), _delta) - _delta + Cpd; v_store_aligned(Lr_p + d, L); _minL = v_min(_minL, L); v_store_aligned(Sp + d, vx_load_aligned(Sp + d) + L); } minLr = v_reduce_min(_minL); #else minLr = MAX_COST; #endif for( ; d < D; d++ ) { int Cpd = Cp[d], L; L = Cpd + std::min((int)Lr_ppr[d], std::min(Lr_ppr[d-1] + P1, std::min(Lr_ppr[d+1] + P1, delta))) - delta; Lr_p[d] = (CostType)L; minLr = std::min(minLr, (CostType)L); Sp[d] = saturate_cast(Sp[d] + L); } } memset( Lr, 0, LrSize*sizeof(CostType) ); Lr[-1] = Lr[D] = Lr[Dlra - 1] = Lr[Dlra + D] = MAX_COST; minLr = 0; for( x = width1-1; x != -1; x--) { int delta = minLr + P2; CostType* Lr_ppr = Lr + ((x&1)? 0 :Dlra); CostType* Lr_p = Lr + ((x&1)? Dlra :0); const CostType* Cp = C + x*Da; CostType* Sp = S + x*Da; CostType minS = MAX_COST; short bestDisp = -1; minLr = MAX_COST; d = 0; #if CV_SIMD v_int16 _P1 = vx_setall_s16((short)P1); v_int16 _delta = vx_setall_s16((short)delta); v_int16 _minL = vx_setall_s16((short)MAX_COST); v_int16 _minS = vx_setall_s16(MAX_COST), _bestDisp = vx_setall_s16(-1); for( ; d <= D - v_int16::nlanes; d += v_int16::nlanes ) { v_int16 Cpd = vx_load_aligned(Cp + d); v_int16 L = v_min(v_min(v_min(vx_load_aligned(Lr_ppr + d), vx_load(Lr_ppr + d - 1) + _P1), vx_load(Lr_ppr + d + 1) + _P1), _delta) - _delta + Cpd; v_store_aligned(Lr_p + d, L); _minL = v_min(_minL, L); L += vx_load_aligned(Sp + d); v_store_aligned(Sp + d, L); _bestDisp = v_select(_minS > L, vx_setall_s16((short)d), _bestDisp); _minS = v_min( L, _minS ); } minLr = v_reduce_min(_minL); min_pos(_minS, _bestDisp, minS, bestDisp); #endif for( ; d < D; d++ ) { int Cpd = Cp[d], L; L = Cpd + std::min((int)Lr_ppr[d], std::min(Lr_ppr[d-1] + P1, std::min(Lr_ppr[d+1] + P1, delta))) - delta; Lr_p[d] = (CostType)L; minLr = std::min(minLr, (CostType)L); Sp[d] = saturate_cast(Sp[d] + L); if( Sp[d] < minS ) { minS = Sp[d]; bestDisp = (short)d; } } //Some postprocessing procedures and saving for( d = 0; d < D; d++ ) { if( Sp[d]*(100 - uniquenessRatio) < minS*100 && std::abs(bestDisp - d) > 1 ) break; } if( d < D ) continue; d = bestDisp; int _x2 = x + minX1 - d - minD; if( disp2cost[_x2] > minS ) { disp2cost[_x2] = (CostType)minS; disp2ptr[_x2] = (DispType)(d + minD); } if( 0 < d && d < D-1 ) { // do subpixel quadratic interpolation: // fit parabola into (x1=d-1, y1=Sp[d-1]), (x2=d, y2=Sp[d]), (x3=d+1, y3=Sp[d+1]) // then find minimum of the parabola. int denom2 = std::max(Sp[d-1] + Sp[d+1] - 2*Sp[d], 1); d = d*DISP_SCALE + ((Sp[d-1] - Sp[d+1])*DISP_SCALE + denom2)/(denom2*2); } else d *= DISP_SCALE; disp1ptr[x + minX1] = (DispType)(d + minD*DISP_SCALE); } //Left-right check sanity procedure for( x = minX1; x < maxX1; x++ ) { // we round the computed disparity both towards -inf and +inf and check // if either of the corresponding disparities in disp2 is consistent. // This is to give the computed disparity a chance to look valid if it is. int d1 = disp1ptr[x]; if( d1 == INVALID_DISP_SCALED ) continue; int _d = d1 >> DISP_SHIFT; int d_ = (d1 + DISP_SCALE-1) >> DISP_SHIFT; int _x = x - _d, x_ = x - d_; if( 0 <= _x && _x < width && disp2ptr[_x] >= minD && std::abs(disp2ptr[_x] - _d) > disp12MaxDiff && 0 <= x_ && x_ < width && disp2ptr[x_] >= minD && std::abs(disp2ptr[x_] - d_) > disp12MaxDiff ) disp1ptr[x] = (DispType)INVALID_DISP_SCALED; } } } static const int DISP_SHIFT = StereoMatcher::DISP_SHIFT; static const int DISP_SCALE = (1 << DISP_SHIFT); static const CostType MAX_COST = SHRT_MAX; const Mat& img1; const Mat& img2; Mat& disp1; CostType* Cbuf; CostType* Sbuf; int minD; int maxD; int D, Da, Dlra; int width; int width1; int height; int P1; int P2; int minX1; int maxX1; size_t costBufSize; size_t CSBufSize; size_t LrSize; int INVALID_DISP; int INVALID_DISP_SCALED; int uniquenessRatio; int disp12MaxDiff; }; /* computes disparity for "roi" in img1 w.r.t. img2 and write it to disp1buf. that is, disp1buf(x, y)=d means that img1(x+roi.x, y+roi.y) ~ img2(x+roi.x-d, y+roi.y). minD <= d < maxD. note that disp1buf will have the same size as the roi and On exit disp1buf is not the final disparity, it is an intermediate result that becomes final after all the tiles are processed. the disparity in disp1buf is written with sub-pixel accuracy (4 fractional bits, see StereoSGBM::DISP_SCALE), using quadratic interpolation, while the disparity in disp2buf is written as is, without interpolation. */ static void computeDisparitySGBM_HH4( const Mat& img1, const Mat& img2, Mat& disp1, const StereoSGBMParams& params, Mat& buffer ) { const int DISP_SHIFT = StereoMatcher::DISP_SHIFT; const int DISP_SCALE = (1 << DISP_SHIFT); int minD = params.minDisparity, maxD = minD + params.numDisparities; Size SADWindowSize; SADWindowSize.width = SADWindowSize.height = params.SADWindowSize > 0 ? params.SADWindowSize : 5; int ftzero = std::max(params.preFilterCap, 15) | 1; int P1 = params.P1 > 0 ? params.P1 : 2, P2 = std::max(params.P2 > 0 ? params.P2 : 5, P1+1); int k, width = disp1.cols, height = disp1.rows; int minX1 = std::max(maxD, 0), maxX1 = width + std::min(minD, 0); int D = (int)alignSize(maxD - minD, v_int16::nlanes), width1 = maxX1 - minX1; int Dlra = D + v_int16::nlanes;//Additional memory is necessary to store disparity values(MAX_COST) for d=-1 and d=D int SH2 = SADWindowSize.height/2; int INVALID_DISP = minD - 1; int INVALID_DISP_SCALED = INVALID_DISP*DISP_SCALE; const int TAB_OFS = 256*4, TAB_SIZE = 256 + TAB_OFS*2; PixType clipTab[TAB_SIZE]; for( k = 0; k < TAB_SIZE; k++ ) clipTab[k] = (PixType)(std::min(std::max(k - TAB_OFS, -ftzero), ftzero) + ftzero); if( minX1 >= maxX1 ) { disp1 = Scalar::all(INVALID_DISP_SCALED); return; } // for each possible stereo match (img1(x,y) <=> img2(x-d,y)) // we keep pixel difference cost (C) and the summary cost over 4 directions (S). // we also keep all the partial costs for the previous line L_r(x,d) and also min_k L_r(x, k) // the number of L_r(.,.) and min_k L_r(.,.) lines in the buffer: // for dynamic programming we need the current row and // the previous row, i.e. 2 rows in total size_t costBufSize = width1*D; size_t CSBufSize = costBufSize*height; size_t minLrSize = width1 , LrSize = minLrSize*Dlra; int hsumBufNRows = SH2*2 + 2; size_t totalBufSize = CV_SIMD_WIDTH + CSBufSize * 2 * sizeof(CostType) + // Alignment, C, S costBufSize*hsumBufNRows * sizeof(CostType) + // hsumBuf ((LrSize + minLrSize)*2 + v_int16::nlanes) * sizeof(CostType); // minLr[] and Lr[] if( buffer.empty() || !buffer.isContinuous() || buffer.cols*buffer.rows*buffer.elemSize() < totalBufSize ) { buffer.reserveBuffer(totalBufSize); } // summary cost over different (nDirs) directions CostType* Cbuf = (CostType*)alignPtr(buffer.ptr(), CV_SIMD_WIDTH); // add P2 to every C(x,y). it saves a few operations in the inner loops for(k = 0; k < (int)CSBufSize; k++ ) Cbuf[k] = (CostType)P2; parallel_for_(Range(0,width1),CalcVerticalSums(img1, img2, params, Cbuf, clipTab),8); parallel_for_(Range(0,height),CalcHorizontalSums(img1, img2, disp1, params, Cbuf),8); } ////////////////////////////////////////////////////////////////////////////////////////////////////// void getBufferPointers(Mat& buffer, int width, int width1, int Da, int num_ch, int SH2, int P2, CostType*& curCostVolumeLine, CostType*& hsumBuf, CostType*& pixDiff, PixType*& tmpBuf, CostType*& horPassCostVolume, CostType*& vertPassCostVolume, CostType*& vertPassMin, CostType*& rightPassBuf, CostType*& disp2CostBuf, short*& disp2Buf); struct SGBM3WayMainLoop : public ParallelLoopBody { Mat* buffers; const Mat *img1, *img2; Mat* dst_disp; int nstripes, stripe_sz; int stripe_overlap; int width,height; int minD, maxD, D, Da; int minX1, maxX1, width1; int SW2, SH2; int P1, P2; int uniquenessRatio, disp12MaxDiff; int costBufSize, hsumBufNRows; int TAB_OFS, ftzero; PixType* clipTab; #if CV_SIMD short idx_row[v_int16::nlanes]; #endif SGBM3WayMainLoop(Mat *_buffers, const Mat& _img1, const Mat& _img2, Mat* _dst_disp, const StereoSGBMParams& params, PixType* _clipTab, int _nstripes, int _stripe_overlap); void getRawMatchingCost(CostType* C, CostType* hsumBuf, CostType* pixDiff, PixType* tmpBuf, int y, int src_start_idx) const; void operator () (const Range& range) const CV_OVERRIDE; template void impl(const Range& range) const; }; SGBM3WayMainLoop::SGBM3WayMainLoop(Mat *_buffers, const Mat& _img1, const Mat& _img2, Mat* _dst_disp, const StereoSGBMParams& params, PixType* _clipTab, int _nstripes, int _stripe_overlap): buffers(_buffers), img1(&_img1), img2(&_img2), dst_disp(_dst_disp), clipTab(_clipTab) { nstripes = _nstripes; stripe_overlap = _stripe_overlap; stripe_sz = (int)ceil(img1->rows/(double)nstripes); width = img1->cols; height = img1->rows; minD = params.minDisparity; maxD = minD + params.numDisparities; D = maxD - minD; minX1 = std::max(maxD, 0); maxX1 = width + std::min(minD, 0); width1 = maxX1 - minX1; Da = (int)alignSize(D, v_int16::nlanes); SW2 = SH2 = params.SADWindowSize > 0 ? params.SADWindowSize/2 : 1; P1 = params.P1 > 0 ? params.P1 : 2; P2 = std::max(params.P2 > 0 ? params.P2 : 5, P1+1); uniquenessRatio = params.uniquenessRatio >= 0 ? params.uniquenessRatio : 10; disp12MaxDiff = params.disp12MaxDiff > 0 ? params.disp12MaxDiff : 1; costBufSize = width1*Da; hsumBufNRows = SH2*2 + 2; TAB_OFS = 256*4; ftzero = std::max(params.preFilterCap, 15) | 1; #if CV_SIMD for(short i = 0; i < v_int16::nlanes; ++i) idx_row[i] = i; #endif } void getBufferPointers(Mat& buffer, int width, int width1, int Da, int num_ch, int SH2, int P2, CostType*& curCostVolumeLine, CostType*& hsumBuf, CostType*& pixDiff, PixType*& tmpBuf, CostType*& horPassCostVolume, CostType*& vertPassCostVolume, CostType*& vertPassMin, CostType*& rightPassBuf, CostType*& disp2CostBuf, short*& disp2Buf) { // allocating all the required memory: int costVolumeLineSize = width1*Da; int width1_ext = width1+2; int costVolumeLineSize_ext = width1_ext*Da; int hsumBufNRows = SH2*2 + 2; // main buffer to store matching costs for the current line: int curCostVolumeLineSize = costVolumeLineSize*sizeof(CostType); // auxiliary buffers for the raw matching cost computation: int hsumBufSize = costVolumeLineSize*hsumBufNRows*sizeof(CostType); int pixDiffSize = costVolumeLineSize*sizeof(CostType); int tmpBufSize = width * (4 * num_ch + 2) * sizeof(PixType); // auxiliary buffers for the matching cost aggregation: int horPassCostVolumeSize = costVolumeLineSize_ext*sizeof(CostType); // buffer for the 2-pass horizontal cost aggregation int vertPassCostVolumeSize = costVolumeLineSize_ext*sizeof(CostType); // buffer for the vertical cost aggregation int rightPassBufSize = Da * sizeof(CostType); // additional small buffer for the right-to-left pass int vertPassMinSize = width1_ext*sizeof(CostType); // buffer for storing minimum costs from the previous line // buffers for the pseudo-LRC check: int disp2CostBufSize = width*sizeof(CostType); int disp2BufSize = width*sizeof(short); // sum up the sizes of all the buffers: size_t totalBufSize = CV_SIMD_WIDTH + curCostVolumeLineSize + hsumBufSize + pixDiffSize + horPassCostVolumeSize + vertPassCostVolumeSize + rightPassBufSize + vertPassMinSize + disp2CostBufSize + disp2BufSize + tmpBufSize; if( buffer.empty() || !buffer.isContinuous() || buffer.cols*buffer.rows*buffer.elemSize() < totalBufSize ) buffer.reserveBuffer(totalBufSize); // set up all the pointers: curCostVolumeLine = (CostType*)alignPtr(buffer.ptr(), CV_SIMD_WIDTH); hsumBuf = curCostVolumeLine + costVolumeLineSize; pixDiff = hsumBuf + costVolumeLineSize*hsumBufNRows; horPassCostVolume = pixDiff + costVolumeLineSize; vertPassCostVolume = horPassCostVolume + costVolumeLineSize_ext; rightPassBuf = vertPassCostVolume + costVolumeLineSize_ext; vertPassMin = rightPassBuf + Da; disp2CostBuf = vertPassMin + width1_ext; disp2Buf = disp2CostBuf + width; tmpBuf = (PixType*)(disp2Buf + width); // initialize memory: memset(buffer.ptr(),0,totalBufSize); int i = 0; #if CV_SIMD v_int16 _P2 = vx_setall_s16((CostType)P2); for (; i<=costVolumeLineSize-v_int16::nlanes; i+=v_int16::nlanes) v_store_aligned(curCostVolumeLine + i, _P2); #endif for(;i src_start_idx ) { const CostType* hsumSub = hsumBuf + (std::max(y - SH2 - 1, src_start_idx) % hsumBufNRows)*costBufSize; #if CV_SIMD for (d = 0; d < Da; d += v_int16::nlanes) v_store_aligned(C + d, vx_load_aligned(C + d) + vx_load_aligned(hsumAdd + d) - vx_load_aligned(hsumSub + d)); #else for (d = 0; d < D; d++) C[d] = (CostType)(C[d] + hsumAdd[d] - hsumSub[d]); #endif for( x = Da; x < width1*Da; x += Da ) { const CostType* pixAdd = pixDiff + std::min(x + SW2*Da, (width1-1)*Da); const CostType* pixSub = pixDiff + std::max(x - (SW2+1)*Da, 0); #if CV_SIMD v_int16 hv_reg; for( d = 0; d < Da; d+=v_int16::nlanes ) { hv_reg = vx_load_aligned(hsumAdd+x-Da+d) + vx_load_aligned(pixAdd+d) - vx_load_aligned(pixSub+d); v_store_aligned(hsumAdd+x+d,hv_reg); v_store_aligned(C+x+d,vx_load_aligned(C+x+d)+hv_reg-vx_load_aligned(hsumSub+x+d)); } #else for( d = 0; d < D; d++ ) { int hv = hsumAdd[x + d] = (CostType)(hsumAdd[x - D + d] + pixAdd[d] - pixSub[d]); C[x + d] = (CostType)(C[x + d] + hv - hsumSub[x + d]); } #endif } } else { #if CV_SIMD v_int16 v_scale = vx_setall_s16(k == src_start_idx ? (short)SH2 + 1 : 1); for (d = 0; d < Da; d += v_int16::nlanes) v_store_aligned(C + d, vx_load_aligned(C + d) + vx_load_aligned(hsumAdd + d) * v_scale); #else int scale = k == src_start_idx ? SH2 + 1 : 1; for (d = 0; d < D; d++) C[d] = (CostType)(C[d] + hsumAdd[d] * scale); #endif for( x = Da; x < width1*Da; x += Da ) { const CostType* pixAdd = pixDiff + std::min(x + SW2*Da, (width1-1)*Da); const CostType* pixSub = pixDiff + std::max(x - (SW2+1)*Da, 0); #if CV_SIMD for (d = 0; d < Da; d += v_int16::nlanes) { v_int16 hv = vx_load_aligned(hsumAdd + x - Da + d) + vx_load_aligned(pixAdd + d) - vx_load_aligned(pixSub + d); v_store_aligned(hsumAdd + x + d, hv); v_store_aligned(C + x + d, vx_load_aligned(C + x + d) + hv * v_scale); } #else for (d = 0; d < D; d++) { CostType hv = (CostType)(hsumAdd[x - Da + d] + pixAdd[d] - pixSub[d]); hsumAdd[x + d] = hv; C[x + d] = (CostType)(C[x + d] + hv * scale); } #endif } } } else { if( y > src_start_idx ) { const CostType* hsumSub = hsumBuf + (std::max(y - SH2 - 1, src_start_idx) % hsumBufNRows)*costBufSize; #if CV_SIMD for( x = 0; x < width1*Da; x += v_int16::nlanes) v_store_aligned(C + x, vx_load_aligned(C + x) + vx_load_aligned(hsumAdd + x) - vx_load_aligned(hsumSub + x)); #else for( x = 0; x < width1*Da; x++ ) C[x] = (CostType)(C[x] + hsumAdd[x] - hsumSub[x]); #endif } else { #if CV_SIMD for( x = 0; x < width1*Da; x += v_int16::nlanes) v_store_aligned(C + x, vx_load_aligned(C + x) + vx_load_aligned(hsumAdd + x)); #else for( x = 0; x < width1*Da; x++ ) C[x] = (CostType)(C[x] + hsumAdd[x]); #endif } } } } // performing SGM cost accumulation from left to right (result is stored in leftBuf) and // in-place cost accumulation from top to bottom (result is stored in topBuf) template inline void accumulateCostsLeftTop(CostType* leftBuf, CostType* leftBuf_prev, CostType* topBuf, CostType* costs, CostType& leftMinCost, CostType& topMinCost, int D, int P1, int P2) { int i = 0; #if CV_SIMD int Da = (int)alignSize(D, v_int16::nlanes); v_int16 P1_reg = vx_setall_s16(cv::saturate_cast(P1)); v_int16 leftMinCostP2_reg = vx_setall_s16(cv::saturate_cast(leftMinCost+P2)); v_int16 leftMinCost_new_reg = vx_setall_s16(SHRT_MAX); v_int16 src0_leftBuf = vx_setall_s16(SHRT_MAX); v_int16 src1_leftBuf = vx_load_aligned(leftBuf_prev); v_int16 topMinCostP2_reg = vx_setall_s16(cv::saturate_cast(topMinCost+P2)); v_int16 topMinCost_new_reg = vx_setall_s16(SHRT_MAX); v_int16 src0_topBuf = vx_setall_s16(SHRT_MAX); v_int16 src1_topBuf = vx_load_aligned(topBuf); v_int16 src2; v_int16 src_shifted_left,src_shifted_right; v_int16 res; for(;i (src1_leftBuf,src0_leftBuf); src_shifted_right = v_rotate_right<1> (src1_leftBuf,src2 ); // process and save current block: res = vx_load_aligned(costs+i) + (v_min(v_min(src_shifted_left,src_shifted_right) + P1_reg,v_min(src1_leftBuf,leftMinCostP2_reg))-leftMinCostP2_reg); leftMinCost_new_reg = v_min(leftMinCost_new_reg,res); v_store_aligned(leftBuf+i, res); //update src buffers: src0_leftBuf = src1_leftBuf; src1_leftBuf = src2; //process topBuf: //lookahead load: src2 = vx_load_aligned(topBuf+i+v_int16::nlanes); //get shifted versions of the current block and add P1: src_shifted_left = v_rotate_left<1> (src1_topBuf,src0_topBuf); src_shifted_right = v_rotate_right<1> (src1_topBuf,src2 ); // process and save current block: res = vx_load_aligned(costs+i) + (v_min(v_min(src_shifted_left,src_shifted_right) + P1_reg,v_min(src1_topBuf,topMinCostP2_reg))-topMinCostP2_reg); topMinCost_new_reg = v_min(topMinCost_new_reg,res); v_store_aligned(topBuf+i, res); //update src buffers: src0_topBuf = src1_topBuf; src1_topBuf = src2; } // a bit different processing for the last cycle of the loop: if(x_nlanes) { src2 = vx_setall_s16(SHRT_MAX); //process leftBuf: src_shifted_left = v_rotate_left<1> (src1_leftBuf,src0_leftBuf); src_shifted_right = v_rotate_right<1> (src1_leftBuf,src2 ); res = vx_load_aligned(costs+Da-v_int16::nlanes) + (v_min(v_min(src_shifted_left,src_shifted_right) + P1_reg,v_min(src1_leftBuf,leftMinCostP2_reg))-leftMinCostP2_reg); leftMinCost = v_reduce_min(v_min(leftMinCost_new_reg,res)); v_store_aligned(leftBuf+Da-v_int16::nlanes, res); //process topBuf: src_shifted_left = v_rotate_left<1> (src1_topBuf,src0_topBuf); src_shifted_right = v_rotate_right<1> (src1_topBuf,src2 ); res = vx_load_aligned(costs+Da-v_int16::nlanes) + (v_min(v_min(src_shifted_left,src_shifted_right) + P1_reg,v_min(src1_topBuf,topMinCostP2_reg))-topMinCostP2_reg); topMinCost = v_reduce_min(v_min(topMinCost_new_reg,res)); v_store_aligned(topBuf+Da-v_int16::nlanes, res); } else { CostType leftMinCost_new = v_reduce_min(leftMinCost_new_reg); CostType topMinCost_new = v_reduce_min(topMinCost_new_reg); CostType leftBuf_prev_i_minus_1 = i > 0 ? leftBuf_prev[i-1] : SHRT_MAX; CostType topBuf_i_minus_1 = i > 0 ? topBuf[i-1] : SHRT_MAX; #else { CostType leftMinCost_new = SHRT_MAX; CostType topMinCost_new = SHRT_MAX; CostType leftBuf_prev_i_minus_1 = SHRT_MAX; CostType topBuf_i_minus_1 = SHRT_MAX; #endif int leftMinCost_P2 = leftMinCost + P2; int topMinCost_P2 = topMinCost + P2; CostType tmp; for(;i(costs[i] + std::min(std::min(leftBuf_prev_i_minus_1+P1,leftBuf_prev[i+1]+P1),std::min((int)leftBuf_prev[i],leftMinCost_P2))-leftMinCost_P2); leftBuf_prev_i_minus_1 = leftBuf_prev[i]; leftMinCost_new = std::min(leftMinCost_new,leftBuf[i]); tmp = topBuf[i]; topBuf[i] = cv::saturate_cast(costs[i] + std::min(std::min(topBuf_i_minus_1+P1,topBuf[i+1]+P1),std::min((int)topBuf[i],topMinCost_P2))-topMinCost_P2); topBuf_i_minus_1 = tmp; topMinCost_new = std::min(topMinCost_new,topBuf[i]); } leftBuf[D-1] = cv::saturate_cast(costs[D-1] + std::min(leftBuf_prev_i_minus_1+P1,std::min((int)leftBuf_prev[D-1],leftMinCost_P2))-leftMinCost_P2); leftMinCost = std::min(leftMinCost_new,leftBuf[D-1]); topBuf[D-1] = cv::saturate_cast(costs[D-1] + std::min(topBuf_i_minus_1+P1,std::min((int)topBuf[D-1],topMinCost_P2))-topMinCost_P2); topMinCost = std::min(topMinCost_new,topBuf[D-1]); } } // performing in-place SGM cost accumulation from right to left (the result is stored in rightBuf) and // summing rightBuf, topBuf, leftBuf together (the result is stored in leftBuf), as well as finding the // optimal disparity value with minimum accumulated cost template inline void accumulateCostsRight(CostType* rightBuf, CostType* topBuf, CostType* leftBuf, CostType* costs, CostType& rightMinCost, int D, int P1, int P2, short& optimal_disp, CostType& min_cost) { int i = 0; #if CV_SIMD int Da = (int)alignSize(D, v_int16::nlanes); v_int16 P1_reg = vx_setall_s16(cv::saturate_cast(P1)); v_int16 rightMinCostP2_reg = vx_setall_s16(cv::saturate_cast(rightMinCost+P2)); v_int16 rightMinCost_new_reg = vx_setall_s16(SHRT_MAX); v_int16 src0_rightBuf = vx_setall_s16(SHRT_MAX); v_int16 src1_rightBuf = vx_load(rightBuf); v_int16 src2; v_int16 src_shifted_left,src_shifted_right; v_int16 res; v_int16 min_sum_cost_reg = vx_setall_s16(SHRT_MAX); v_int16 min_sum_pos_reg = vx_setall_s16(0); for(;i (src1_rightBuf,src0_rightBuf); src_shifted_right = v_rotate_right<1> (src1_rightBuf,src2 ); // process and save current block: res = vx_load_aligned(costs+i) + (v_min(v_min(src_shifted_left,src_shifted_right) + P1_reg,v_min(src1_rightBuf,rightMinCostP2_reg))-rightMinCostP2_reg); rightMinCost_new_reg = v_min(rightMinCost_new_reg,res); v_store_aligned(rightBuf+i, res); // compute and save total cost: res = res + vx_load_aligned(leftBuf+i) + vx_load_aligned(topBuf+i); v_store_aligned(leftBuf+i, res); // track disparity value with the minimum cost: min_sum_cost_reg = v_min(min_sum_cost_reg,res); min_sum_pos_reg = min_sum_pos_reg + ((min_sum_cost_reg == res) & (vx_setall_s16((short)i) - min_sum_pos_reg)); //update src: src0_rightBuf = src1_rightBuf; src1_rightBuf = src2; } // a bit different processing for the last cycle of the loop: if(x_nlanes) { src2 = vx_setall_s16(SHRT_MAX); src_shifted_left = v_rotate_left<1> (src1_rightBuf,src0_rightBuf); src_shifted_right = v_rotate_right<1> (src1_rightBuf,src2 ); res = vx_load_aligned(costs+D-v_int16::nlanes) + (v_min(v_min(src_shifted_left,src_shifted_right) + P1_reg,v_min(src1_rightBuf,rightMinCostP2_reg))-rightMinCostP2_reg); rightMinCost = v_reduce_min(v_min(rightMinCost_new_reg,res)); v_store_aligned(rightBuf+D-v_int16::nlanes, res); res = res + vx_load_aligned(leftBuf+D-v_int16::nlanes) + vx_load_aligned(topBuf+D-v_int16::nlanes); v_store_aligned(leftBuf+D-v_int16::nlanes, res); min_sum_cost_reg = v_min(min_sum_cost_reg,res); min_sum_pos_reg = min_sum_pos_reg + ((min_sum_cost_reg == res) & (vx_setall_s16((short)D-v_int16::nlanes) - min_sum_pos_reg)); min_pos(min_sum_cost_reg,min_sum_pos_reg, min_cost, optimal_disp); } else { CostType rightMinCost_new = v_reduce_min(rightMinCost_new_reg); CostType rightBuf_i_minus_1 = i > 0 ? rightBuf[i] : SHRT_MAX; min_pos(min_sum_cost_reg,min_sum_pos_reg, min_cost, optimal_disp); #else { CostType rightMinCost_new = SHRT_MAX; CostType rightBuf_i_minus_1 = SHRT_MAX; min_cost = SHRT_MAX; #endif int rightMinCost_P2 = rightMinCost + P2; CostType tmp; for(;i(costs[i] + std::min(std::min(rightBuf_i_minus_1+P1,rightBuf[i+1]+P1),std::min((int)rightBuf[i],rightMinCost_P2))-rightMinCost_P2); rightBuf_i_minus_1 = tmp; rightMinCost_new = std::min(rightMinCost_new,rightBuf[i]); leftBuf[i] = cv::saturate_cast((int)leftBuf[i]+rightBuf[i]+topBuf[i]); if(leftBuf[i](costs[D-1] + std::min(rightBuf_i_minus_1+P1,std::min((int)rightBuf[D-1],rightMinCost_P2))-rightMinCost_P2); rightMinCost = std::min(rightMinCost_new,rightBuf[D-1]); leftBuf[D-1] = cv::saturate_cast((int)leftBuf[D-1]+rightBuf[D-1]+topBuf[D-1]); if(leftBuf[D-1](range); else impl(range); } template void SGBM3WayMainLoop::impl(const Range& range) const { // force separate processing of stripes: if(range.end>range.start+1) { for(int n=range.start;nchannels(),SH2,P2, curCostVolumeLine,hsumBuf,pixDiff,tmpBuf,horPassCostVolume, vertPassCostVolume,vertPassMin,rightPassBuf,disp2CostBuf,disp2Buf); // start real processing: for(int y=src_start_idx;y(horPassCostVolume+x,horPassCostVolume+x-Da,vertPassCostVolume+x,C+x,prev_min,vertPassMin[x/Da],D,P1,P2); //backward pass memset(rightPassBuf,0,Da*sizeof(CostType)); prev_min=0; for (int x=width1*Da;x>=Da;x-=Da) { accumulateCostsRight(rightPassBuf,vertPassCostVolume+x,horPassCostVolume+x,C+x,prev_min,D,P1,P2,best_d,min_cost); if(uniquenessRatio>0) { d = 0; #if CV_SIMD horPassCostVolume+=x; int thresh = (100*min_cost)/(100-uniquenessRatio); v_int16 thresh_reg = vx_setall_s16((short)(thresh+1)); v_int16 d1 = vx_setall_s16((short)(best_d-1)); v_int16 d2 = vx_setall_s16((short)(best_d+1)); v_int16 eight_reg = vx_setall_s16(v_int16::nlanes); v_int16 cur_d = vx_load(idx_row); v_int16 mask; for( ; d <= D - 2*v_int16::nlanes; d+=2*v_int16::nlanes ) { mask = (vx_load_aligned(horPassCostVolume + d) < thresh_reg) & ( (cur_dd2) ); cur_d = cur_d+eight_reg; if( v_check_any(mask) ) break; mask = (vx_load_aligned(horPassCostVolume + d + v_int16::nlanes) < thresh_reg) & ( (cur_dd2) ); cur_d = cur_d+eight_reg; if( v_check_any(mask) ) break; } if( d <= D - 2*v_int16::nlanes ) { horPassCostVolume-=x; continue; } if( d <= D - v_int16::nlanes ) { if( v_check_any((vx_load_aligned(horPassCostVolume + d) < thresh_reg) & ((cur_d < d1) | (cur_d > d2))) ) { horPassCostVolume-=x; continue; } d+=v_int16::nlanes; } horPassCostVolume-=x; #endif for( ; d < D; d++ ) { if( horPassCostVolume[x+d]*(100 - uniquenessRatio) < min_cost*100 && std::abs(d - best_d) > 1 ) break; } if( d < D ) continue; } d = best_d; int _x2 = x/Da - 1 + minX1 - d - minD; if( _x2>=0 && _x2 min_cost ) { disp2CostBuf[_x2] = min_cost; disp2Buf[_x2] = (short)(d + minD); } if( 0 < d && d < D-1 ) { // do subpixel quadratic interpolation: // fit parabola into (x1=d-1, y1=Sp[d-1]), (x2=d, y2=Sp[d]), (x3=d+1, y3=Sp[d+1]) // then find minimum of the parabola. int denom2 = std::max(horPassCostVolume[x+d-1] + horPassCostVolume[x+d+1] - 2*horPassCostVolume[x+d], 1); d = d*DISP_SCALE + ((horPassCostVolume[x+d-1] - horPassCostVolume[x+d+1])*DISP_SCALE + denom2)/(denom2*2); } else d *= DISP_SCALE; disp_row[(x/Da)-1 + minX1] = (DispType)(d + minD*DISP_SCALE); } for(int x = minX1; x < maxX1; x++ ) { // pseudo LRC consistency check using only one disparity map; // pixels with difference more than disp12MaxDiff are invalidated int d1 = disp_row[x]; if( d1 == INVALID_DISP_SCALED ) continue; int _d = d1 >> StereoMatcher::DISP_SHIFT; int d_ = (d1 + DISP_SCALE-1) >> StereoMatcher::DISP_SHIFT; int _x = x - _d, x_ = x - d_; if( 0 <= _x && _x < width && disp2Buf[_x] >= minD && std::abs(disp2Buf[_x] - _d) > disp12MaxDiff && 0 <= x_ && x_ < width && disp2Buf[x_] >= minD && std::abs(disp2Buf[x_] - d_) > disp12MaxDiff ) disp_row[x] = (short)INVALID_DISP_SCALED; } } } static void computeDisparity3WaySGBM( const Mat& img1, const Mat& img2, Mat& disp1, const StereoSGBMParams& params, Mat* buffers, int nstripes ) { // precompute a lookup table for the raw matching cost computation: const int TAB_OFS = 256*4, TAB_SIZE = 256 + TAB_OFS*2; PixType* clipTab = new PixType[TAB_SIZE]; int ftzero = std::max(params.preFilterCap, 15) | 1; for(int k = 0; k < TAB_SIZE; k++ ) clipTab[k] = (PixType)(std::min(std::max(k - TAB_OFS, -ftzero), ftzero) + ftzero); // allocate separate dst_disp arrays to avoid conflicts due to stripe overlap: int stripe_sz = (int)ceil(img1.rows/(double)nstripes); int stripe_overlap = (params.SADWindowSize/2+1) + (int)ceil(0.1*stripe_sz); Mat* dst_disp = new Mat[nstripes]; for(int i=0;i 0 ) filterSpeckles(disp, (params.minDisparity - 1)*StereoMatcher::DISP_SCALE, params.speckleWindowSize, StereoMatcher::DISP_SCALE*params.speckleRange, buffer); } int getMinDisparity() const CV_OVERRIDE { return params.minDisparity; } void setMinDisparity(int minDisparity) CV_OVERRIDE { params.minDisparity = minDisparity; } int getNumDisparities() const CV_OVERRIDE { return params.numDisparities; } void setNumDisparities(int numDisparities) CV_OVERRIDE { params.numDisparities = numDisparities; } int getBlockSize() const CV_OVERRIDE { return params.SADWindowSize; } void setBlockSize(int blockSize) CV_OVERRIDE { params.SADWindowSize = blockSize; } int getSpeckleWindowSize() const CV_OVERRIDE { return params.speckleWindowSize; } void setSpeckleWindowSize(int speckleWindowSize) CV_OVERRIDE { params.speckleWindowSize = speckleWindowSize; } int getSpeckleRange() const CV_OVERRIDE { return params.speckleRange; } void setSpeckleRange(int speckleRange) CV_OVERRIDE { params.speckleRange = speckleRange; } int getDisp12MaxDiff() const CV_OVERRIDE { return params.disp12MaxDiff; } void setDisp12MaxDiff(int disp12MaxDiff) CV_OVERRIDE { params.disp12MaxDiff = disp12MaxDiff; } int getPreFilterCap() const CV_OVERRIDE { return params.preFilterCap; } void setPreFilterCap(int preFilterCap) CV_OVERRIDE { params.preFilterCap = preFilterCap; } int getUniquenessRatio() const CV_OVERRIDE { return params.uniquenessRatio; } void setUniquenessRatio(int uniquenessRatio) CV_OVERRIDE { params.uniquenessRatio = uniquenessRatio; } int getP1() const CV_OVERRIDE { return params.P1; } void setP1(int P1) CV_OVERRIDE { params.P1 = P1; } int getP2() const CV_OVERRIDE { return params.P2; } void setP2(int P2) CV_OVERRIDE { params.P2 = P2; } int getMode() const CV_OVERRIDE { return params.mode; } void setMode(int mode) CV_OVERRIDE { params.mode = mode; } void write(FileStorage& fs) const CV_OVERRIDE { writeFormat(fs); fs << "name" << name_ << "minDisparity" << params.minDisparity << "numDisparities" << params.numDisparities << "blockSize" << params.SADWindowSize << "speckleWindowSize" << params.speckleWindowSize << "speckleRange" << params.speckleRange << "disp12MaxDiff" << params.disp12MaxDiff << "preFilterCap" << params.preFilterCap << "uniquenessRatio" << params.uniquenessRatio << "P1" << params.P1 << "P2" << params.P2 << "mode" << params.mode; } void read(const FileNode& fn) CV_OVERRIDE { FileNode n = fn["name"]; CV_Assert( n.isString() && String(n) == name_ ); params.minDisparity = (int)fn["minDisparity"]; params.numDisparities = (int)fn["numDisparities"]; params.SADWindowSize = (int)fn["blockSize"]; params.speckleWindowSize = (int)fn["speckleWindowSize"]; params.speckleRange = (int)fn["speckleRange"]; params.disp12MaxDiff = (int)fn["disp12MaxDiff"]; params.preFilterCap = (int)fn["preFilterCap"]; params.uniquenessRatio = (int)fn["uniquenessRatio"]; params.P1 = (int)fn["P1"]; params.P2 = (int)fn["P2"]; params.mode = (int)fn["mode"]; } StereoSGBMParams params; Mat buffer; // the number of stripes is fixed, disregarding the number of threads/processors // to make the results fully reproducible: static const int num_stripes = 4; Mat buffers[num_stripes]; static const char* name_; }; const char* StereoSGBMImpl::name_ = "StereoMatcher.SGBM"; Ptr StereoSGBM::create(int minDisparity, int numDisparities, int SADWindowSize, int P1, int P2, int disp12MaxDiff, int preFilterCap, int uniquenessRatio, int speckleWindowSize, int speckleRange, int mode) { return Ptr( new StereoSGBMImpl(minDisparity, numDisparities, SADWindowSize, P1, P2, disp12MaxDiff, preFilterCap, uniquenessRatio, speckleWindowSize, speckleRange, mode)); } Rect getValidDisparityROI( Rect roi1, Rect roi2, int minDisparity, int numberOfDisparities, int SADWindowSize ) { int SW2 = SADWindowSize/2; int maxD = minDisparity + numberOfDisparities - 1; int xmin = std::max(roi1.x, roi2.x + maxD) + SW2; int xmax = std::min(roi1.x + roi1.width, roi2.x + roi2.width) - SW2; int ymin = std::max(roi1.y, roi2.y) + SW2; int ymax = std::min(roi1.y + roi1.height, roi2.y + roi2.height) - SW2; Rect r(xmin, ymin, xmax - xmin, ymax - ymin); return r.width > 0 && r.height > 0 ? r : Rect(); } typedef cv::Point_ Point2s; template void filterSpecklesImpl(cv::Mat& img, int newVal, int maxSpeckleSize, int maxDiff, cv::Mat& _buf) { using namespace cv; int width = img.cols, height = img.rows, npixels = width*height; size_t bufSize = npixels*(int)(sizeof(Point2s) + sizeof(int) + sizeof(uchar)); if( !_buf.isContinuous() || _buf.empty() || _buf.cols*_buf.rows*_buf.elemSize() < bufSize ) _buf.reserveBuffer(bufSize); uchar* buf = _buf.ptr(); int i, j, dstep = (int)(img.step/sizeof(T)); int* labels = (int*)buf; buf += npixels*sizeof(labels[0]); Point2s* wbuf = (Point2s*)buf; buf += npixels*sizeof(wbuf[0]); uchar* rtype = (uchar*)buf; int curlabel = 0; // clear out label assignments memset(labels, 0, npixels*sizeof(labels[0])); for( i = 0; i < height; i++ ) { T* ds = img.ptr(i); int* ls = labels + width*i; for( j = 0; j < width; j++ ) { if( ds[j] != newVal ) // not a bad disparity { if( ls[j] ) // has a label, check for bad label { if( rtype[ls[j]] ) // small region, zero out disparity ds[j] = (T)newVal; } // no label, assign and propagate else { Point2s* ws = wbuf; // initialize wavefront Point2s p((short)j, (short)i); // current pixel curlabel++; // next label int count = 0; // current region size ls[j] = curlabel; // wavefront propagation while( ws >= wbuf ) // wavefront not empty { count++; // put neighbors onto wavefront T* dpp = &img.at(p.y, p.x); T dp = *dpp; int* lpp = labels + width*p.y + p.x; if( p.y < height-1 && !lpp[+width] && dpp[+dstep] != newVal && std::abs(dp - dpp[+dstep]) <= maxDiff ) { lpp[+width] = curlabel; *ws++ = Point2s(p.x, p.y+1); } if( p.y > 0 && !lpp[-width] && dpp[-dstep] != newVal && std::abs(dp - dpp[-dstep]) <= maxDiff ) { lpp[-width] = curlabel; *ws++ = Point2s(p.x, p.y-1); } if( p.x < width-1 && !lpp[+1] && dpp[+1] != newVal && std::abs(dp - dpp[+1]) <= maxDiff ) { lpp[+1] = curlabel; *ws++ = Point2s(p.x+1, p.y); } if( p.x > 0 && !lpp[-1] && dpp[-1] != newVal && std::abs(dp - dpp[-1]) <= maxDiff ) { lpp[-1] = curlabel; *ws++ = Point2s(p.x-1, p.y); } // pop most recent and propagate // NB: could try least recent, maybe better convergence p = *--ws; } // assign label type if( count <= maxSpeckleSize ) // speckle region { rtype[ls[j]] = 1; // small region label ds[j] = (T)newVal; } else rtype[ls[j]] = 0; // large region label } } } } } #ifdef HAVE_IPP static bool ipp_filterSpeckles(Mat &img, int maxSpeckleSize, int newVal, int maxDiff, Mat &buffer) { #if IPP_VERSION_X100 >= 810 CV_INSTRUMENT_REGION_IPP(); IppDataType dataType = ippiGetDataType(img.depth()); IppiSize size = ippiSize(img.size()); int bufferSize; if(img.channels() != 1) return false; if(dataType != ipp8u && dataType != ipp16s) return false; if(ippiMarkSpecklesGetBufferSize(size, dataType, 1, &bufferSize) < 0) return false; if(bufferSize && (buffer.empty() || (int)(buffer.step*buffer.rows) < bufferSize)) buffer.create(1, (int)bufferSize, CV_8U); switch(dataType) { case ipp8u: return CV_INSTRUMENT_FUN_IPP(ippiMarkSpeckles_8u_C1IR, img.ptr(), (int)img.step, size, (Ipp8u)newVal, maxSpeckleSize, (Ipp8u)maxDiff, ippiNormL1, buffer.ptr()) >= 0; case ipp16s: return CV_INSTRUMENT_FUN_IPP(ippiMarkSpeckles_16s_C1IR, img.ptr(), (int)img.step, size, (Ipp16s)newVal, maxSpeckleSize, (Ipp16s)maxDiff, ippiNormL1, buffer.ptr()) >= 0; default: return false; } #else CV_UNUSED(img); CV_UNUSED(maxSpeckleSize); CV_UNUSED(newVal); CV_UNUSED(maxDiff); CV_UNUSED(buffer); return false; #endif } #endif } void cv::filterSpeckles( InputOutputArray _img, double _newval, int maxSpeckleSize, double _maxDiff, InputOutputArray __buf ) { CV_INSTRUMENT_REGION(); Mat img = _img.getMat(); int type = img.type(); Mat temp, &_buf = __buf.needed() ? __buf.getMatRef() : temp; CV_Assert( type == CV_8UC1 || type == CV_16SC1 ); int newVal = cvRound(_newval), maxDiff = cvRound(_maxDiff); CV_IPP_RUN_FAST(ipp_filterSpeckles(img, maxSpeckleSize, newVal, maxDiff, _buf)); if (type == CV_8UC1) filterSpecklesImpl(img, newVal, maxSpeckleSize, maxDiff, _buf); else filterSpecklesImpl(img, newVal, maxSpeckleSize, maxDiff, _buf); } void cv::validateDisparity( InputOutputArray _disp, InputArray _cost, int minDisparity, int numberOfDisparities, int disp12MaxDiff ) { CV_INSTRUMENT_REGION(); Mat disp = _disp.getMat(), cost = _cost.getMat(); int cols = disp.cols, rows = disp.rows; int minD = minDisparity, maxD = minDisparity + numberOfDisparities; int x, minX1 = std::max(maxD, 0), maxX1 = cols + std::min(minD, 0); AutoBuffer _disp2buf(cols*2); int* disp2buf = _disp2buf.data(); int* disp2cost = disp2buf + cols; const int DISP_SHIFT = 4, DISP_SCALE = 1 << DISP_SHIFT; int INVALID_DISP = minD - 1, INVALID_DISP_SCALED = INVALID_DISP*DISP_SCALE; int costType = cost.type(); disp12MaxDiff *= DISP_SCALE; CV_Assert( numberOfDisparities > 0 && disp.type() == CV_16S && (costType == CV_16S || costType == CV_32S) && disp.size() == cost.size() ); for( int y = 0; y < rows; y++ ) { short* dptr = disp.ptr(y); for( x = 0; x < cols; x++ ) { disp2buf[x] = INVALID_DISP_SCALED; disp2cost[x] = INT_MAX; } if( costType == CV_16S ) { const short* cptr = cost.ptr(y); for( x = minX1; x < maxX1; x++ ) { int d = dptr[x], c = cptr[x]; if( d == INVALID_DISP_SCALED ) continue; int x2 = x - ((d + DISP_SCALE/2) >> DISP_SHIFT); if( disp2cost[x2] > c ) { disp2cost[x2] = c; disp2buf[x2] = d; } } } else { const int* cptr = cost.ptr(y); for( x = minX1; x < maxX1; x++ ) { int d = dptr[x], c = cptr[x]; if( d == INVALID_DISP_SCALED ) continue; int x2 = x - ((d + DISP_SCALE/2) >> DISP_SHIFT); if( disp2cost[x2] > c ) { disp2cost[x2] = c; disp2buf[x2] = d; } } } for( x = minX1; x < maxX1; x++ ) { // we round the computed disparity both towards -inf and +inf and check // if either of the corresponding disparities in disp2 is consistent. // This is to give the computed disparity a chance to look valid if it is. int d = dptr[x]; if( d == INVALID_DISP_SCALED ) continue; int d0 = d >> DISP_SHIFT; int d1 = (d + DISP_SCALE-1) >> DISP_SHIFT; int x0 = x - d0, x1 = x - d1; if( (0 <= x0 && x0 < cols && disp2buf[x0] > INVALID_DISP_SCALED && std::abs(disp2buf[x0] - d) > disp12MaxDiff) && (0 <= x1 && x1 < cols && disp2buf[x1] > INVALID_DISP_SCALED && std::abs(disp2buf[x1] - d) > disp12MaxDiff) ) dptr[x] = (short)INVALID_DISP_SCALED; } } }