ES-DE/external/CImg/plugins/bayer.h

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/*
#
# File : bayer.h
# ( C++ header file - CImg plug-in )
#
# Description : CImg plugin that implements the conversion of a color image to a
# Bayer-coded matrix, and its reverse transform.
#
# Copyright : David Tschumperlé
# ( https://tschumperle.users.greyc.fr/ )
#
# This software is governed by the CeCILL license under French law and
# abiding by the rules of distribution of free software. You can use,
# modify and/or redistribute the software under the terms of the CeCILL
# license as circulated by CEA, CNRS and INRIA at the following URL
# "http://www.cecill.info".
#
# As a counterpart to the access to the source code and rights to copy,
# modify and redistribute granted by the license, users are provided only
# with a limited warranty and the software's author, the holder of the
# economic rights, and the successive licensors have only limited
# liability.
#
# In this respect, the user's attention is drawn to the risks associated
# with loading, using, modifying and/or developing or reproducing the
# software by the user in light of its specific status of free software,
# that may mean that it is complicated to manipulate, and that also
# therefore means that it is reserved for developers and experienced
# professionals having in-depth computer knowledge. Users are therefore
# encouraged to load and test the software's suitability as regards their
# requirements in conditions enabling the security of their systems and/or
# data to be ensured and, more generally, to use and operate it in the
# same conditions as regards security.
#
# The fact that you are presently reading this means that you have had
# knowledge of the CeCILL license and that you accept its terms.
#
*/
#ifndef cimg_plugin_bayer
#define cimg_plugin_bayer
//! Convert RGB color image to a Bayer-coded scalar image.
/**
\note First (upper-left) pixel if the red component of the pixel color.
**/
CImg<T>& RGBtoBayer() {
return get_RGBtoBayer().move_to(*this);
}
//! Convert RGB color image to a Bayer-coded scalar image \newinstance.
CImg<T> get_RGBtoBayer() const {
if (_spectrum!=3)
throw CImgInstanceException(_cimg_instance
"RGBtoBayer(): Instance is not a RGB image.",
cimg_instance);
CImg<T> res(_width,_height,_depth,1);
const T *ptr_r = data(0,0,0,0), *ptr_g = data(0,0,0,1), *ptr_b = data(0,0,0,2);
T *ptrd = res._data;
cimg_forXYZ(*this,x,y,z) {
if (y%2) {
if (x%2) *(ptrd++) = *ptr_b;
else *(ptrd++) = *ptr_g;
} else {
if (x%2) *(ptrd++) = *ptr_g;
else *(ptrd++) = *ptr_r;
}
++ptr_r; ++ptr_g; ++ptr_b;
}
return res;
}
//! Convert Bayer-coded scalar image to a RGB color image.
CImg<T>& BayertoRGB(const unsigned int interpolation_type=3) {
return get_BayertoRGB(interpolation_type).move_to(*this);
}
//! Convert Bayer-coded scalar image to a RGB color image \newinstance.
CImg<Tuchar> get_BayertoRGB(const unsigned int interpolation_type=3) const {
if (_spectrum!=1)
throw CImgInstanceException(_cimg_instance
"BayertoRGB(): Instance is not a Bayer image.",
cimg_instance);
CImg<Tuchar> res(_width,_height,_depth,3);
CImg_3x3(I,T);
Tuchar *ptr_r = res.data(0,0,0,0), *ptr_g = res.data(0,0,0,1), *ptr_b = res.data(0,0,0,2);
switch (interpolation_type) {
case 3 : { // Edge-directed
CImg_3x3(R,T);
CImg_3x3(G,T);
CImg_3x3(B,T);
cimg_forXYZ(*this,x,y,z) {
const int _p1x = x?x - 1:1, _p1y = y?y - 1:1, _n1x = x<width() - 1?x + 1:x - 1, _n1y = y<height() - 1?y + 1:y - 1;
cimg_get3x3(*this,x,y,z,0,I,T);
if (y%2) {
if (x%2) {
const Tfloat
alpha = cimg::sqr((Tfloat)Inc - Ipc),
beta = cimg::sqr((Tfloat)Icn - Icp),
cx = 1/(1 + alpha), cy = 1/(1 + beta);
*ptr_g = (Tuchar)((cx*(Inc + Ipc) + cy*(Icn + Icp))/(2*(cx + cy)));
} else *ptr_g = (Tuchar)Icc;
} else {
if (x%2) *ptr_g = (Tuchar)Icc;
else {
const Tfloat
alpha = cimg::sqr((Tfloat)Inc - Ipc),
beta = cimg::sqr((Tfloat)Icn - Icp),
cx = 1/(1 + alpha), cy = 1/(1 + beta);
*ptr_g = (Tuchar)((cx*(Inc + Ipc) + cy*(Icn + Icp))/(2*(cx + cy)));
}
}
++ptr_g;
}
cimg_forXYZ(*this,x,y,z) {
const int _p1x = x?x - 1:1, _p1y = y?y - 1:1, _n1x = x<width() - 1?x + 1:x - 1, _n1y = y<height() - 1?y + 1:y - 1;
cimg_get3x3(*this,x,y,z,0,I,T);
cimg_get3x3(res,x,y,z,1,G,T);
if (y%2) {
if (x%2) *ptr_b = (Tuchar)Icc;
else { *ptr_r = (Tuchar)((Icn + Icp)/2); *ptr_b = (Tuchar)((Inc + Ipc)/2); }
} else {
if (x%2) { *ptr_r = (Tuchar)((Inc + Ipc)/2); *ptr_b = (Tuchar)((Icn + Icp)/2); }
else *ptr_r = (Tuchar)Icc;
}
++ptr_r; ++ptr_b;
}
ptr_r = res.data(0,0,0,0);
ptr_g = res.data(0,0,0,1);
ptr_b = res.data(0,0,0,2);
cimg_forXYZ(*this,x,y,z) {
const int _p1x = x?x - 1:1, _p1y = y?y - 1:1, _n1x = x<width() - 1?x + 1:x - 1, _n1y = y<height() - 1?y + 1:y - 1;
cimg_get3x3(res,x,y,z,0,R,T);
cimg_get3x3(res,x,y,z,1,G,T);
cimg_get3x3(res,x,y,z,2,B,T);
if (y%2) {
if (x%2) {
const float
alpha = (float)cimg::sqr(Rnc - Rpc),
beta = (float)cimg::sqr(Rcn - Rcp),
cx = 1/(1 + alpha), cy = 1/(1 + beta);
*ptr_r = (Tuchar)((cx*(Rnc + Rpc) + cy*(Rcn + Rcp))/(2*(cx + cy)));
}
} else {
if (!(x%2)) {
const float
alpha = (float)cimg::sqr(Bnc - Bpc),
beta = (float)cimg::sqr(Bcn - Bcp),
cx = 1/(1 + alpha), cy = 1/(1 + beta);
*ptr_b = (Tuchar)((cx*(Bnc + Bpc) + cy*(Bcn + Bcp))/(2*(cx + cy)));
}
}
++ptr_r; ++ptr_g; ++ptr_b;
}
} break;
case 2 : { // Linear interpolation
cimg_forXYZ(*this,x,y,z) {
const int _p1x = x?x - 1:1, _p1y = y?y - 1:1, _n1x = x<width() - 1?x + 1:x - 1, _n1y = y<height() - 1?y + 1:y - 1;
cimg_get3x3(*this,x,y,z,0,I,T);
if (y%2) {
if (x%2) {
*ptr_r = (Tuchar)((Ipp + Inn + Ipn + Inp)/4);
*ptr_g = (Tuchar)((Inc + Ipc + Icn + Icp)/4);
*ptr_b = (Tuchar)Icc;
} else { *ptr_r = (Tuchar)((Icp + Icn)/2); *ptr_g = (Tuchar)Icc; *ptr_b = (Tuchar)((Inc + Ipc)/2); }
} else {
if (x%2) { *ptr_r = (Tuchar)((Ipc + Inc)/2); *ptr_g = (Tuchar)Icc; *ptr_b = (Tuchar)((Icn + Icp)/2); }
else {
*ptr_r = (Tuchar)Icc;
*ptr_g = (Tuchar)((Inc + Ipc + Icn + Icp)/4);
*ptr_b = (Tuchar)((Ipp + Inn + Ipn + Inp)/4);
}
}
++ptr_r; ++ptr_g; ++ptr_b;
}
} break;
case 1 : { // Nearest neighbor interpolation
cimg_forXYZ(*this,x,y,z) {
const int _p1x = x?x - 1:1, _p1y = y?y - 1:1, _n1x = x<width() - 1?x + 1:x - 1, _n1y = y<height() - 1?y + 1:y - 1;
cimg_get3x3(*this,x,y,z,0,I,T);
if (y%2) {
if (x%2) {
*ptr_r = (Tuchar)cimg::min(Ipp,Inn,Ipn,Inp);
*ptr_g = (Tuchar)cimg::min(Inc,Ipc,Icn,Icp);
*ptr_b = (Tuchar)Icc;
} else { *ptr_r = (Tuchar)cimg::min(Icn,Icp); *ptr_g = (Tuchar)Icc; *ptr_b = (Tuchar)cimg::min(Inc,Ipc); }
} else {
if (x%2) { *ptr_r = (Tuchar)cimg::min(Inc,Ipc); *ptr_g = (Tuchar)Icc; *ptr_b = (Tuchar)cimg::min(Icn,Icp); }
else {
*ptr_r = (Tuchar)Icc;
*ptr_g = (Tuchar)cimg::min(Inc,Ipc,Icn,Icp);
*ptr_b = (Tuchar)cimg::min(Ipp,Inn,Ipn,Inp);
}
}
++ptr_r; ++ptr_g; ++ptr_b;
}
} break;
default : { // 0-filling interpolation
const T *ptrs = _data;
res.fill(0);
cimg_forXYZ(*this,x,y,z) {
const T val = *(ptrs++);
if (y%2) { if (x%2) *ptr_b = val; else *ptr_g = val; } else { if (x%2) *ptr_g = val; else *ptr_r = val; }
++ptr_r; ++ptr_g; ++ptr_b;
}
}
}
return res;
}
#endif /* cimg_plugin_bayer */