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324 lines
13 KiB
C
324 lines
13 KiB
C
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/*
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#
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# File : chlpca.cpp
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# ( C++ source file )
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#
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# Description : Example of use for the CImg plugin 'plugins/chlpca.h'.
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# This file is a part of the CImg Library project.
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# ( http://cimg.eu )
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#
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# Copyright : Jerome Boulanger
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# ( http://www.irisa.fr/vista/Equipe/People/Jerome.Boulanger.html )
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#
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#
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# License : CeCILL v2.0
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# ( http://www.cecill.info/licences/Licence_CeCILL_V2-en.html )
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#
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# This software is governed by the CeCILL license under French law and
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# abiding by the rules of distribution of free software. You can use,
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# modify and/ or redistribute the software under the terms of the CeCILL
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# license as circulated by CEA, CNRS and INRIA at the following URL
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# "http://www.cecill.info".
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#
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# As a counterpart to the access to the source code and rights to copy,
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# modify and redistribute granted by the license, users are provided only
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# with a limited warranty and the software's author, the holder of the
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# economic rights, and the successive licensors have only limited
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# liability.
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#
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# In this respect, the user's attention is drawn to the risks associated
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# with loading, using, modifying and/or developing or reproducing the
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# software by the user in light of its specific status of free software,
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# that may mean that it is complicated to manipulate, and that also
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# therefore means that it is reserved for developers and experienced
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# professionals having in-depth computer knowledge. Users are therefore
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# encouraged to load and test the software's suitability as regards their
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# requirements in conditions enabling the security of their systems and/or
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# data to be ensured and, more generally, to use and operate it in the
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# same conditions as regards security.
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#
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# The fact that you are presently reading this means that you have had
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# knowledge of the CeCILL license and that you accept its terms.
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#
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*/
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#ifndef cimg_plugin_chlpca
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#define cimg_plugin_chlpca
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// Define some useful macros.
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//! Some loops
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#define cimg_for_step1(bound,i,step) for (int i = 0; i<(int)(bound); i+=step)
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#define cimg_for_stepX(img,x,step) cimg_for_step1((img)._width,x,step)
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#define cimg_for_stepY(img,y,step) cimg_for_step1((img)._height,y,step)
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#define cimg_for_stepZ(img,z,step) cimg_for_step1((img)._depth,z,step)
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#define cimg_for_stepXY(img,x,y,step) cimg_for_stepY(img,y,step) cimg_for_stepX(img,x,step)
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#define cimg_for_stepXYZ(img,x,y,step) cimg_for_stepZ(img,z,step) cimg_for_stepY(img,y,step) cimg_for_stepX(img,x,step)
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//! Loop for point J(xj,yj) in the neighborhood of a point I(xi,yi) of size (2*rx+1,2*ry+1)
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/**
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Point J is kept inside the boundaries of the image img.
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example of summing the pixels values in a neighborhood 11x11
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cimg_forXY(img,xi,yi) cimg_for_windowXY(img,xi,yi,xj,yj,5,5) dest(yi,yi) += src(xj,yj);
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**/
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#define cimg_forXY_window(img,xi,yi,xj,yj,rx,ry) \
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for (int yi0 = std::max(0,yi-ry), yi1=std::min(yi + ry,(int)img.height() - 1), yj=yi0;yj<=yi1;++yj) \
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for (int xi0 = std::max(0,xi-rx), xi1=std::min(xi + rx,(int)img.width() - 1), xj=xi0;xj<=xi1;++xj)
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#define cimg_forXYZ_window(img,xi,yi,zi,xj,yj,zj,rx,ry,rz) \
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for (int zi0 = std::max(0,zi-rz), zi1=std::min(zi + rz,(int)img.depth() - 1) , zj=zi0;zj<=zi1;++zj) \
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for (int yi0 = std::max(0,yi-ry), yi1=std::min(yi + ry,(int)img.height() - 1), yj=yi0;yj<=yi1;++yj) \
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for (int xi0 = std::max(0,xi-rx), xi1=std::min(xi + rx,(int)img.width() - 1) , xj=xi0;xj<=xi1;++xj)
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//! Crop a patch in the image around position x,y,z and return a column vector
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/**
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\param x x-coordinate of the center of the patch
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\param y y-coordinate of the center of the patch
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\param z z-coordinate of the center of the patch
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\param px the patch half width
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\param px the patch half height
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\param px the patch half depth
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\return img.get_crop(x0,y0,z0,x1,y1,z1).unroll('y');
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**/
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CImg<T> get_patch(int x, int y, int z,
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int px, int py, int pz) const {
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if (depth() == 1){
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const int x0 = x - px, y0 = y - py, x1 = x + px, y1 = y + py;
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return get_crop(x0, y0, x1, y1).unroll('y');
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} else {
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const int
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x0 = x - px, y0 = y - py, z0 = z - pz,
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x1 = x + px, y1 = y + py, z1 = z + pz;
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return get_crop(x0, y0, z0, x1, y1, z1).unroll('y');
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}
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}
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//! Extract a local patch dictionnary around point xi,yi,zi
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CImg<T> get_patch_dictionnary(const int xi, const int yi, const int zi,
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const int px, const int py, const int pz,
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const int wx, const int wy, const int wz,
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int & idc) const {
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const int
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n = (2*wx + 1) * (2*wy + 1) * (2 * (depth()==1?0:wz) + 1),
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d = (2*px + 1) * (2*py + 1) * (2 * (depth()==1?0:px) + 1) * spectrum();
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CImg<> S(n, d);
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int idx = 0;
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if (depth() == 1) {
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cimg_forXY_window((*this), xi, yi, xj, yj, wx, wy){
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CImg<T> patch = get_patch(xj, yj, 0, px, py, 1);
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cimg_forY(S,y) S(idx,y) = patch(y);
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if (xj==xi && yj==yi) idc = idx;
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idx++;
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}
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} else {
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cimg_forXYZ_window((*this), xi,yi,zi,xj,yj,zj,wx,wy,wz){
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CImg<T> patch = get_patch(xj, yj, zj, px, py, pz);
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cimg_forY(S,y) S(idx,y) = patch(y);
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if (xj==xi && yj==yi && zj==zi) idc = idx;
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idx++;
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}
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}
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S.columns(0, idx - 1);
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return S;
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}
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//! Add a patch to the image
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/**
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\param x x-coordinate of the center of the patch
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\param y y-coordinate of the center of the patch
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\param z z-coordinate of the center of the patch
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\param img the patch as a 1D column vector
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\param px the patch half width
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\param px the patch half height
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\param px the patch half depth
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**/
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CImg<T> & add_patch(const int xi, const int yi, const int zi,
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const CImg<T> & patch,
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const int px, const int py, const int pz) {
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const int
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x0 = xi - px, y0 = yi - py, z0 = (depth() == 1 ? 0 : zi - pz),
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sx = 2 * px + 1, sy = 2 * py + 1, sz = (depth() == 1 ? 1 : 2 * pz +1);
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draw_image(x0, y0, z0, 0, patch.get_resize(sx, sy, sz, spectrum(), -1), -1);
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return (*this);
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}
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//! Add a constant patch to the image
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/**
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\param x x-coordinate of the center of the patch
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\param y y-coordinate of the center of the patch
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\param z z-coordinate of the center of the patch
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\param value in the patch
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\param px the patch half width
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\param px the patch half height
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\param px the patch half depth
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**/
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CImg<T> & add_patch(const int xi, const int yi, const int zi, const T value,
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const int px, const int py, const int pz) {
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const int
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x0 = xi - px, y0 = yi - py, z0 = (depth() == 1 ? 0 : zi - pz),
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x1 = xi + px, y1 = yi + py, z1 = (depth() == 1 ? 0 : zi + pz);
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draw_rectangle(x0, y0, z0, 0, x1, y1, z1, spectrum()-1, value, -1);
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return (*this);
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}
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//! CHLPCA denoising from the PhD thesis of Hu Haijuan
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/**
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\param px the patch half width
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\param py the patch half height
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\param pz the patch half depth
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\param wx the training region half width
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\param wy the training region half height
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\param wz the training region half depth
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\param nstep the subsampling of the image domain
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\param nsim the number of patches used for training as a factor of the patch size
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\param lambda_min the threshold on the eigen values of the PCA for dimension reduction
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\param threshold the threshold on the value of the coefficients
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\param pca_use_svd if true use the svd approach to perform the pca otherwise use the covariance method
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\note please cite the PhD thesis of Hu Haijuan http://www.univ-ubs.fr/soutenance-de-these-hu-haijuan-337653.kjsp?RH=1318498222799
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**/
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CImg<T> get_chlpca(const int px, const int py, const int pz,
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const int wx, const int wy, const int wz,
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const int nstep, const float nsim,
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const float lambda_min, const float threshold,
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const float noise_std, const bool pca_use_svd) const {
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const int
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nd = (2*px + 1) * (2*py + 1) * (depth()==1?1:2*pz + 1) * spectrum(),
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K = (int)(nsim * nd);
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#ifdef DEBUG
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fprintf(stderr,"chlpca: p:%dx%dx%d,w:%dx%dx%d,nd:%d,K:%d\n",
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2*px + 1,2*py + 1,2*pz + 1,2*wx + 1,2*wy + 1,2*wz + 1,nd,K);
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#endif
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float sigma;
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if (noise_std<0) sigma = (float)std::sqrt(variance_noise());
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else sigma = noise_std;
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CImg<T> dest(*this), count(*this);
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dest.fill(0);
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count.fill(0);
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cimg_for_stepZ(*this,zi,(depth()==1||pz==0)?1:nstep){
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#ifdef cimg_use_openmp
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cimg_pragma_openmp(parallel for)
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#endif
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cimg_for_stepXY((*this),xi,yi,nstep){
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// extract the training region X
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int idc = 0;
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CImg<T> S = get_patch_dictionnary(xi,yi,zi,px,py,pz,wx,wy,wz,idc);
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// select the K most similar patches within the training set
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CImg<T> Sk(S);
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CImg<unsigned int> a_index(S.width());
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if (K < Sk.width() - 1){
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CImg<T> mse(S.width());
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CImg<unsigned int> perms;
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cimg_forX(S,x) { mse(x) = (T)S.get_column(idc).MSE(S.get_column(x)); }
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mse.sort(perms,true);
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cimg_foroff(perms,i) {
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cimg_forY(S,j) Sk(i,j) = S(perms(i),j);
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a_index(perms(i)) = i;
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}
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Sk.columns(0, K);
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perms.threshold(K);
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} else {
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cimg_foroff(a_index,i) a_index(i)=i;
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}
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// centering the patches
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CImg<T> M(1, Sk.height(), 1, 1, 0);
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cimg_forXY(Sk,x,y) { M(y) += Sk(x,y); }
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M /= (T)Sk.width();
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cimg_forXY(Sk,x,y) { Sk(x,y) -= M(y); }
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// compute the principal component of the training set S
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CImg<T> P, lambda;
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if (pca_use_svd) {
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CImg<T> V;
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Sk.get_transpose().SVD(V,lambda,P,true,100);
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} else {
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(Sk * Sk.get_transpose()).symmetric_eigen(lambda, P);
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lambda.sqrt();
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}
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// dimension reduction
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int s = 0;
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const T tx = (T)(std::sqrt((double)Sk.width()-1.0) * lambda_min * sigma);
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while((lambda(s) > tx) && (s < ((int)lambda.size() - 1))) { s++; }
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P.columns(0,s);
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// project all the patches on the basis (compute scalar product)
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Sk = P.get_transpose() * Sk;
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// threshold the coefficients
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if (threshold > 0) { Sk.threshold(threshold, 1); }
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// project back to pixel space
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Sk = P * Sk;
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// recenter the patches
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cimg_forXY(Sk,x,y) { Sk(x,y) += M(y); }
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int j = 0;
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cimg_forXYZ_window((*this),xi,yi,zi,xj,yj,zj,wx,wy,wz){
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const int id = a_index(j);
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if (id < Sk.width()) {
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dest.add_patch(xj, yj, zj, Sk.get_column(id), px, py, pz);
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count.add_patch(xj, yj, zj, (T)1, px, py, pz);
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}
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j++;
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}
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}
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}
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cimg_foroff(dest, i) {
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if(count(i) != 0) { dest(i) /= count(i); }
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else { dest(i) = (*this)(i); }
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}
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return dest;
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}
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//! CHLPCA denoising from the PhD thesis of Hu Haijuan
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/**
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\param px the patch half width
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\param px the patch half height
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\param px the patch half depth
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\param wx the training region half width
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\param wy the training region half height
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\param wz the training region half depth
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\param nstep the subsampling of the image domain
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\param nsim the number of patches used for training as a factor of the patch size
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\param lambda_min the threshold on the eigen values of the PCA for dimension reduction
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\param threshold the threshold on the value of the coefficients
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\param pca_use_svd if true use the svd approach to perform the pca otherwise use the covariance method
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\note please cite the PhD thesis of Hu Haijuan http://www.univ-ubs.fr/soutenance-de-these-hu-haijuan-337653.kjsp?RH=1318498222799
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**/
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CImg<T> & chlpca(const int px, const int py, const int pz,
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const int wx, const int wy, const int wz,
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const int nstep, const float nsim,
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const float lambda_min, const float threshold,
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const float noise_std, const bool pca_use_svd) {
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(*this) = get_chlpca(px, py, pz, wx, wy, wz, nstep, nsim, lambda_min,
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threshold, noise_std, pca_use_svd);
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return (*this);
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}
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//! CHLPCA denoising from the PhD thesis of Hu Haijuan
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/**
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\param p the patch half size
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\param w the training region half size
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\param nstep the subsampling of the image domain
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\param nsim the number of patches used for training as a factor of the patch size
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\param lambda_min the threshold on the eigen values of the PCA for dimension reduction
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\param threshold the threshold on the value of the coefficients
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\param pca_use_svd if true use the svd approach to perform the pca otherwise use the covariance method
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\note please cite the PhD thesis of Hu Haijuan http://www.univ-ubs.fr/soutenance-de-these-hu-haijuan-337653.kjsp?RH=1318498222799
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**/
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CImg<T> get_chlpca(const int p=3, const int w=10,
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const int nstep=5, const float nsim=10,
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const float lambda_min=2, const float threshold = -1,
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const float noise_std=-1, const bool pca_use_svd=true) const {
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if (depth()==1) return get_chlpca(p, p, 0, w, w, 0, nstep, nsim, lambda_min,
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threshold, noise_std, pca_use_svd);
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else return get_chlpca(p, p, p, w, w, w, nstep, nsim, lambda_min,
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threshold, noise_std, pca_use_svd);
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}
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CImg<T> chlpca(const int p=3, const int w=10,
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const int nstep=5, const float nsim=10,
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const float lambda_min=2, const float threshold = -1,
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const float noise_std=-1, const bool pca_use_svd=true) {
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(*this) = get_chlpca(p, w, nstep, nsim, lambda_min,
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threshold, noise_std, pca_use_svd);
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return (*this);
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}
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#endif /* cimg_plugin_chlpca */
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