/*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" // // 2D dense optical flow algorithm from the following paper: // Gunnar Farneback. "Two-Frame Motion Estimation Based on Polynomial Expansion". // Proceedings of the 13th Scandinavian Conference on Image Analysis, Gothenburg, Sweden // namespace cv { static void FarnebackPolyExp( const Mat& src, Mat& dst, int n, double sigma ) { int k, x, y; CV_Assert( src.type() == CV_32FC1 ); int width = src.cols; int height = src.rows; AutoBuffer kbuf(n*6 + 3), _row((width + n*2)*3); float* g = kbuf + n; float* xg = g + n*2 + 1; float* xxg = xg + n*2 + 1; float *row = (float*)_row + n*3; if( sigma < FLT_EPSILON ) sigma = n*0.3; double s = 0.; for( x = -n; x <= n; x++ ) { g[x] = (float)std::exp(-x*x/(2*sigma*sigma)); s += g[x]; } s = 1./s; for( x = -n; x <= n; x++ ) { g[x] = (float)(g[x]*s); xg[x] = (float)(x*g[x]); xxg[x] = (float)(x*x*g[x]); } Mat_ G = Mat_::zeros(6, 6); for( y = -n; y <= n; y++ ) for( x = -n; x <= n; x++ ) { G(0,0) += g[y]*g[x]; G(1,1) += g[y]*g[x]*x*x; G(3,3) += g[y]*g[x]*x*x*x*x; G(5,5) += g[y]*g[x]*x*x*y*y; } //G[0][0] = 1.; G(2,2) = G(0,3) = G(0,4) = G(3,0) = G(4,0) = G(1,1); G(4,4) = G(3,3); G(3,4) = G(4,3) = G(5,5); // invG: // [ x e e ] // [ y ] // [ y ] // [ e z ] // [ e z ] // [ u ] Mat_ invG = G.inv(DECOMP_CHOLESKY); double ig11 = invG(1,1), ig03 = invG(0,3), ig33 = invG(3,3), ig55 = invG(5,5); dst.create( height, width, CV_32FC(5)); for( y = 0; y < height; y++ ) { float g0 = g[0], g1, g2; float *srow0 = (float*)(src.data + src.step*y), *srow1 = 0; float *drow = (float*)(dst.data + dst.step*y); // vertical part of convolution for( x = 0; x < width; x++ ) { row[x*3] = srow0[x]*g0; row[x*3+1] = row[x*3+2] = 0.f; } for( k = 1; k <= n; k++ ) { g0 = g[k]; g1 = xg[k]; g2 = xxg[k]; srow0 = (float*)(src.data + src.step*std::max(y-k,0)); srow1 = (float*)(src.data + src.step*std::min(y+k,height-1)); for( x = 0; x < width; x++ ) { float p = srow0[x] + srow1[x]; float t0 = row[x*3] + g0*p; float t1 = row[x*3+1] + g1*(srow1[x] - srow0[x]); float t2 = row[x*3+2] + g2*p; row[x*3] = t0; row[x*3+1] = t1; row[x*3+2] = t2; } } // horizontal part of convolution for( x = 0; x < n*3; x++ ) { row[-1-x] = row[2-x]; row[width*3+x] = row[width*3+x-3]; } for( x = 0; x < width; x++ ) { g0 = g[0]; // r1 ~ 1, r2 ~ x, r3 ~ y, r4 ~ x^2, r5 ~ y^2, r6 ~ xy double b1 = row[x*3]*g0, b2 = 0, b3 = row[x*3+1]*g0, b4 = 0, b5 = row[x*3+2]*g0, b6 = 0; for( k = 1; k <= n; k++ ) { double tg = row[(x+k)*3] + row[(x-k)*3]; g0 = g[k]; b1 += tg*g0; b4 += tg*xxg[k]; b2 += (row[(x+k)*3] - row[(x-k)*3])*xg[k]; b3 += (row[(x+k)*3+1] + row[(x-k)*3+1])*g0; b6 += (row[(x+k)*3+1] - row[(x-k)*3+1])*xg[k]; b5 += (row[(x+k)*3+2] + row[(x-k)*3+2])*g0; } // do not store r1 drow[x*5+1] = (float)(b2*ig11); drow[x*5] = (float)(b3*ig11); drow[x*5+3] = (float)(b1*ig03 + b4*ig33); drow[x*5+2] = (float)(b1*ig03 + b5*ig33); drow[x*5+4] = (float)(b6*ig55); } } row -= n*3; } /*static void FarnebackPolyExpPyr( const Mat& src0, Vector& pyr, int maxlevel, int n, double sigma ) { Vector imgpyr; buildPyramid( src0, imgpyr, maxlevel ); for( int i = 0; i <= maxlevel; i++ ) FarnebackPolyExp( imgpyr[i], pyr[i], n, sigma ); }*/ static void FarnebackUpdateMatrices( const Mat& _R0, const Mat& _R1, const Mat& _flow, Mat& matM, int _y0, int _y1 ) { const int BORDER = 5; static const float border[BORDER] = {0.14f, 0.14f, 0.4472f, 0.4472f, 0.4472f}; int x, y, width = _flow.cols, height = _flow.rows; const float* R1 = (float*)_R1.data; size_t step1 = _R1.step/sizeof(R1[0]); matM.create(height, width, CV_32FC(5)); for( y = _y0; y < _y1; y++ ) { const float* flow = (float*)(_flow.data + y*_flow.step); const float* R0 = (float*)(_R0.data + y*_R0.step); float* M = (float*)(matM.data + y*matM.step); for( x = 0; x < width; x++ ) { float dx = flow[x*2], dy = flow[x*2+1]; float fx = x + dx, fy = y + dy; #if 1 int x1 = cvFloor(fx), y1 = cvFloor(fy); const float* ptr = R1 + y1*step1 + x1*5; float r2, r3, r4, r5, r6; fx -= x1; fy -= y1; if( (unsigned)x1 < (unsigned)(width-1) && (unsigned)y1 < (unsigned)(height-1) ) { float a00 = (1.f-fx)*(1.f-fy), a01 = fx*(1.f-fy), a10 = (1.f-fx)*fy, a11 = fx*fy; r2 = a00*ptr[0] + a01*ptr[5] + a10*ptr[step1] + a11*ptr[step1+5]; r3 = a00*ptr[1] + a01*ptr[6] + a10*ptr[step1+1] + a11*ptr[step1+6]; r4 = a00*ptr[2] + a01*ptr[7] + a10*ptr[step1+2] + a11*ptr[step1+7]; r5 = a00*ptr[3] + a01*ptr[8] + a10*ptr[step1+3] + a11*ptr[step1+8]; r6 = a00*ptr[4] + a01*ptr[9] + a10*ptr[step1+4] + a11*ptr[step1+9]; r4 = (R0[x*5+2] + r4)*0.5f; r5 = (R0[x*5+3] + r5)*0.5f; r6 = (R0[x*5+4] + r6)*0.25f; } #else int x1 = cvRound(fx), y1 = cvRound(fy); const float* ptr = R1 + y1*step1 + x1*5; float r2, r3, r4, r5, r6; if( (unsigned)x1 < (unsigned)width && (unsigned)y1 < (unsigned)height ) { r2 = ptr[0]; r3 = ptr[1]; r4 = (R0[x*5+2] + ptr[2])*0.5f; r5 = (R0[x*5+3] + ptr[3])*0.5f; r6 = (R0[x*5+4] + ptr[4])*0.25f; } #endif else { r2 = r3 = 0.f; r4 = R0[x*5+2]; r5 = R0[x*5+3]; r6 = R0[x*5+4]*0.5f; } r2 = (R0[x*5] - r2)*0.5f; r3 = (R0[x*5+1] - r3)*0.5f; r2 += r4*dy + r6*dx; r3 += r6*dy + r5*dx; if( (unsigned)(x - BORDER) >= (unsigned)(width - BORDER*2) || (unsigned)(y - BORDER) >= (unsigned)(height - BORDER*2)) { float scale = (x < BORDER ? border[x] : 1.f)* (x >= width - BORDER ? border[width - x - 1] : 1.f)* (y < BORDER ? border[y] : 1.f)* (y >= height - BORDER ? border[height - y - 1] : 1.f); r2 *= scale; r3 *= scale; r4 *= scale; r5 *= scale; r6 *= scale; } M[x*5] = r4*r4 + r6*r6; // G(1,1) M[x*5+1] = (r4 + r5)*r6; // G(1,2)=G(2,1) M[x*5+2] = r5*r5 + r6*r6; // G(2,2) M[x*5+3] = r4*r2 + r6*r3; // h(1) M[x*5+4] = r6*r2 + r5*r3; // h(2) } } } static void FarnebackUpdateFlow_Blur( const Mat& _R0, const Mat& _R1, Mat& _flow, Mat& matM, int block_size, bool update_matrices ) { int x, y, width = _flow.cols, height = _flow.rows; int m = block_size/2; int y0 = 0, y1; int min_update_stripe = std::max((1 << 10)/width, block_size); double scale = 1./(block_size*block_size); AutoBuffer _vsum((width+m*2+2)*5); double* vsum = _vsum + (m+1)*5; // init vsum const float* srow0 = (const float*)matM.data; for( x = 0; x < width*5; x++ ) vsum[x] = srow0[x]*(m+2); for( y = 1; y < m; y++ ) { srow0 = (float*)(matM.data + matM.step*std::min(y,height-1)); for( x = 0; x < width*5; x++ ) vsum[x] += srow0[x]; } // compute blur(G)*flow=blur(h) for( y = 0; y < height; y++ ) { double g11, g12, g22, h1, h2; float* flow = (float*)(_flow.data + _flow.step*y); srow0 = (const float*)(matM.data + matM.step*std::max(y-m-1,0)); const float* srow1 = (const float*)(matM.data + matM.step*std::min(y+m,height-1)); // vertical blur for( x = 0; x < width*5; x++ ) vsum[x] += srow1[x] - srow0[x]; // update borders for( x = 0; x < (m+1)*5; x++ ) { vsum[-1-x] = vsum[4-x]; vsum[width*5+x] = vsum[width*5+x-5]; } // init g** and h* g11 = vsum[0]*(m+2); g12 = vsum[1]*(m+2); g22 = vsum[2]*(m+2); h1 = vsum[3]*(m+2); h2 = vsum[4]*(m+2); for( x = 1; x < m; x++ ) { g11 += vsum[x*5]; g12 += vsum[x*5+1]; g22 += vsum[x*5+2]; h1 += vsum[x*5+3]; h2 += vsum[x*5+4]; } // horizontal blur for( x = 0; x < width; x++ ) { g11 += vsum[(x+m)*5] - vsum[(x-m)*5 - 5]; g12 += vsum[(x+m)*5 + 1] - vsum[(x-m)*5 - 4]; g22 += vsum[(x+m)*5 + 2] - vsum[(x-m)*5 - 3]; h1 += vsum[(x+m)*5 + 3] - vsum[(x-m)*5 - 2]; h2 += vsum[(x+m)*5 + 4] - vsum[(x-m)*5 - 1]; double g11_ = g11*scale; double g12_ = g12*scale; double g22_ = g22*scale; double h1_ = h1*scale; double h2_ = h2*scale; double idet = 1./(g11_*g22_ - g12_*g12_+1e-3); flow[x*2] = (float)((g11_*h2_-g12_*h1_)*idet); flow[x*2+1] = (float)((g22_*h1_-g12_*h2_)*idet); } y1 = y == height - 1 ? height : y - block_size; if( update_matrices && (y1 == height || y1 >= y0 + min_update_stripe) ) { FarnebackUpdateMatrices( _R0, _R1, _flow, matM, y0, y1 ); y0 = y1; } } } static void FarnebackUpdateFlow_GaussianBlur( const Mat& _R0, const Mat& _R1, Mat& _flow, Mat& matM, int block_size, bool update_matrices ) { int x, y, i, width = _flow.cols, height = _flow.rows; int m = block_size/2; int y0 = 0, y1; int min_update_stripe = std::max((1 << 10)/width, block_size); double sigma = m*0.3, s = 1; AutoBuffer _vsum((width+m*2+2)*5 + 16), _hsum(width*5 + 16); AutoBuffer _kernel((m+1)*5 + 16); AutoBuffer _srow(m*2+1); float *vsum = alignPtr((float*)_vsum + (m+1)*5, 16), *hsum = alignPtr((float*)_hsum, 16); float* kernel = (float*)_kernel; const float** srow = (const float**)&_srow[0]; kernel[0] = (float)s; for( i = 1; i <= m; i++ ) { float t = (float)std::exp(-i*i/(2*sigma*sigma) ); kernel[i] = t; s += t*2; } s = 1./s; for( i = 0; i <= m; i++ ) kernel[i] = (float)(kernel[i]*s); #if CV_SSE2 float* simd_kernel = alignPtr(kernel + m+1, 16); volatile bool useSIMD = checkHardwareSupport(CV_CPU_SSE); if( useSIMD ) { for( i = 0; i <= m; i++ ) _mm_store_ps(simd_kernel + i*4, _mm_set1_ps(kernel[i])); } #endif // compute blur(G)*flow=blur(h) for( y = 0; y < height; y++ ) { double g11, g12, g22, h1, h2; float* flow = (float*)(_flow.data + _flow.step*y); // vertical blur for( i = 0; i <= m; i++ ) { srow[m-i] = (const float*)(matM.data + matM.step*std::max(y-i,0)); srow[m+i] = (const float*)(matM.data + matM.step*std::min(y+i,height-1)); } x = 0; #if CV_SSE2 if( useSIMD ) { for( ; x <= width*5 - 16; x += 16 ) { const float *sptr0 = srow[m], *sptr1; __m128 g4 = _mm_load_ps(simd_kernel); __m128 s0, s1, s2, s3; s0 = _mm_mul_ps(_mm_loadu_ps(sptr0 + x), g4); s1 = _mm_mul_ps(_mm_loadu_ps(sptr0 + x + 4), g4); s2 = _mm_mul_ps(_mm_loadu_ps(sptr0 + x + 8), g4); s3 = _mm_mul_ps(_mm_loadu_ps(sptr0 + x + 12), g4); for( i = 1; i <= m; i++ ) { __m128 x0, x1; sptr0 = srow[m+i], sptr1 = srow[m-i]; g4 = _mm_load_ps(simd_kernel + i*4); x0 = _mm_add_ps(_mm_loadu_ps(sptr0 + x), _mm_loadu_ps(sptr1 + x)); x1 = _mm_add_ps(_mm_loadu_ps(sptr0 + x + 4), _mm_loadu_ps(sptr1 + x + 4)); s0 = _mm_add_ps(s0, _mm_mul_ps(x0, g4)); s1 = _mm_add_ps(s1, _mm_mul_ps(x1, g4)); x0 = _mm_add_ps(_mm_loadu_ps(sptr0 + x + 8), _mm_loadu_ps(sptr1 + x + 8)); x1 = _mm_add_ps(_mm_loadu_ps(sptr0 + x + 12), _mm_loadu_ps(sptr1 + x + 12)); s2 = _mm_add_ps(s2, _mm_mul_ps(x0, g4)); s3 = _mm_add_ps(s3, _mm_mul_ps(x1, g4)); } _mm_store_ps(vsum + x, s0); _mm_store_ps(vsum + x + 4, s1); _mm_store_ps(vsum + x + 8, s2); _mm_store_ps(vsum + x + 12, s3); } for( ; x <= width*5 - 4; x += 4 ) { const float *sptr0 = srow[m], *sptr1; __m128 g4 = _mm_load_ps(simd_kernel); __m128 s0 = _mm_mul_ps(_mm_loadu_ps(sptr0 + x), g4); for( i = 1; i <= m; i++ ) { sptr0 = srow[m+i], sptr1 = srow[m-i]; g4 = _mm_load_ps(simd_kernel + i*4); __m128 x0 = _mm_add_ps(_mm_loadu_ps(sptr0 + x), _mm_loadu_ps(sptr1 + x)); s0 = _mm_add_ps(s0, _mm_mul_ps(x0, g4)); } _mm_store_ps(vsum + x, s0); } } #endif for( ; x < width*5; x++ ) { float s0 = srow[m][x]*kernel[0]; for( i = 1; i <= m; i++ ) s0 += (srow[m+i][x] + srow[m-i][x])*kernel[i]; vsum[x] = s0; } // update borders for( x = 0; x < m*5; x++ ) { vsum[-1-x] = vsum[4-x]; vsum[width*5+x] = vsum[width*5+x-5]; } // horizontal blur x = 0; #if CV_SSE2 if( useSIMD ) { for( ; x <= width*5 - 8; x += 8 ) { __m128 g4 = _mm_load_ps(simd_kernel); __m128 s0 = _mm_mul_ps(_mm_loadu_ps(vsum + x), g4); __m128 s1 = _mm_mul_ps(_mm_loadu_ps(vsum + x + 4), g4); for( i = 1; i <= m; i++ ) { g4 = _mm_load_ps(simd_kernel + i*4); __m128 x0 = _mm_add_ps(_mm_loadu_ps(vsum + x - i*5), _mm_loadu_ps(vsum + x + i*5)); __m128 x1 = _mm_add_ps(_mm_loadu_ps(vsum + x - i*5 + 4), _mm_loadu_ps(vsum + x + i*5 + 4)); s0 = _mm_add_ps(s0, _mm_mul_ps(x0, g4)); s1 = _mm_add_ps(s1, _mm_mul_ps(x1, g4)); } _mm_store_ps(hsum + x, s0); _mm_store_ps(hsum + x + 4, s1); } } #endif for( ; x < width*5; x++ ) { float sum = vsum[x]*kernel[0]; for( i = 1; i <= m; i++ ) sum += kernel[i]*(vsum[x - i*5] + vsum[x + i*5]); hsum[x] = sum; } for( x = 0; x < width; x++ ) { g11 = hsum[x*5]; g12 = hsum[x*5+1]; g22 = hsum[x*5+2]; h1 = hsum[x*5+3]; h2 = hsum[x*5+4]; double idet = 1./(g11*g22 - g12*g12 + 1e-3); flow[x*2] = (float)((g11*h2-g12*h1)*idet); flow[x*2+1] = (float)((g22*h1-g12*h2)*idet); } y1 = y == height - 1 ? height : y - block_size; if( update_matrices && (y1 == height || y1 >= y0 + min_update_stripe) ) { FarnebackUpdateMatrices( _R0, _R1, _flow, matM, y0, y1 ); y0 = y1; } } } } void cv::calcOpticalFlowFarneback( InputArray _prev0, InputArray _next0, InputOutputArray _flow0, double pyr_scale, int levels, int winsize, int iterations, int poly_n, double poly_sigma, int flags ) { Mat prev0 = _prev0.getMat(), next0 = _next0.getMat(); const int min_size = 32; const Mat* img[2] = { &prev0, &next0 }; int i, k; double scale; Mat prevFlow, flow, fimg; CV_Assert( prev0.size() == next0.size() && prev0.channels() == next0.channels() && prev0.channels() == 1 && pyr_scale < 1 ); _flow0.create( prev0.size(), CV_32FC2 ); Mat flow0 = _flow0.getMat(); for( k = 0, scale = 1; k < levels; k++ ) { scale *= pyr_scale; if( prev0.cols*scale < min_size || prev0.rows*scale < min_size ) break; } levels = k; for( k = levels; k >= 0; k-- ) { for( i = 0, scale = 1; i < k; i++ ) scale *= pyr_scale; double sigma = (1./scale-1)*0.5; int smooth_sz = cvRound(sigma*5)|1; smooth_sz = std::max(smooth_sz, 3); int width = cvRound(prev0.cols*scale); int height = cvRound(prev0.rows*scale); if( k > 0 ) flow.create( height, width, CV_32FC2 ); else flow = flow0; if( !prevFlow.data ) { if( flags & OPTFLOW_USE_INITIAL_FLOW ) { resize( flow0, flow, Size(width, height), 0, 0, INTER_AREA ); flow *= scale; } else flow = Mat::zeros( height, width, CV_32FC2 ); } else { resize( prevFlow, flow, Size(width, height), 0, 0, INTER_LINEAR ); flow *= 1./pyr_scale; } Mat R[2], I, M; for( i = 0; i < 2; i++ ) { img[i]->convertTo(fimg, CV_32F); GaussianBlur(fimg, fimg, Size(smooth_sz, smooth_sz), sigma, sigma); resize( fimg, I, Size(width, height), INTER_LINEAR ); FarnebackPolyExp( I, R[i], poly_n, poly_sigma ); } FarnebackUpdateMatrices( R[0], R[1], flow, M, 0, flow.rows ); for( i = 0; i < iterations; i++ ) { if( flags & OPTFLOW_FARNEBACK_GAUSSIAN ) FarnebackUpdateFlow_GaussianBlur( R[0], R[1], flow, M, winsize, i < iterations - 1 ); else FarnebackUpdateFlow_Blur( R[0], R[1], flow, M, winsize, i < iterations - 1 ); } prevFlow = flow; } }