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rawTherapee/rtengine/demosaic_algos.cc
Ingo Weyrich 1d51016bdd Fix some lgtm issues
2019-10-30 14:07:49 +01:00

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/*
* This file is part of RawTherapee.
*
* Copyright (c) 2004-2010 Gabor Horvath <hgabor@rawtherapee.com>
*
* RawTherapee is free software: you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* RawTherapee is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with RawTherapee. If not, see <https://www.gnu.org/licenses/>.
*/
#include <cmath>
#include <cassert>
#include "rawimagesource.h"
#include "rawimage.h"
#include "mytime.h"
#include "rt_math.h"
#include "color.h"
#include "../rtgui/multilangmgr.h"
#include "procparams.h"
#include "sleef.c"
#include "opthelper.h"
#include "median.h"
//#define BENCHMARK
#include "StopWatch.h"
#ifdef _OPENMP
#include <omp.h>
#endif
using namespace std;
namespace rtengine
{
extern const Settings* settings;
#undef ABS
#define ABS(a) ((a)<0?-(a):(a))
#define CLIREF(x) LIM(x,-200000.0f,200000.0f) // avoid overflow : do not act directly on image[] or pix[]
#define x1125(a) (a + xdivf(a, 3))
#define x0875(a) (a - xdivf(a, 3))
#define x0250(a) xdivf(a, 2)
#define x00625(a) xdivf(a, 4)
#define x0125(a) xdivf(a, 3)
#undef fc
#define fc(row,col) \
(ri->get_filters() >> ((((row) << 1 & 14) + ((col) & 1)) << 1) & 3)
#define FORCC for (unsigned int c=0; c < colors; c++)
/*
Patterned Pixel Grouping Interpolation by Alain Desbiolles
*/
void RawImageSource::ppg_demosaic()
{
int width = W, height = H;
int dir[5] = { 1, width, -1, -width, 1 };
int row, col, diff[2] = {}, guess[2], c, d, i;
float (*pix)[4];
float (*image)[4];
if (plistener) {
// looks like ppg isn't supported anymore
//plistener->setProgressStr (Glib::ustring::compose(M("TP_RAW_DMETHOD_PROGRESSBAR"), RAWParams::BayerSensor::getMethodString(RAWParams::BayerSensor::ppg)));
plistener->setProgressStr (Glib::ustring::compose(M("TP_RAW_DMETHOD_PROGRESSBAR"), M("GENERAL_NA")));
plistener->setProgress (0.0);
}
image = (float (*)[4]) calloc (static_cast<size_t>(H) * W, sizeof * image);
for (int ii = 0; ii < H; ii++)
for (int jj = 0; jj < W; jj++) {
image[ii * W + jj][fc(ii, jj)] = rawData[ii][jj];
}
border_interpolate(3, image);
/* Fill in the green layer with gradients and pattern recognition: */
for (row = 3; row < height - 3; row++) {
for (col = 3 + (FC(row, 3) & 1), c = FC(row, col); col < width - 3; col += 2) {
pix = image + row * width + col;
for (i = 0; (d = dir[i]) > 0; i++) {
guess[i] = (pix[-d][1] + pix[0][c] + pix[d][1]) * 2
- pix[-2 * d][c] - pix[2 * d][c];
diff[i] = ( ABS(pix[-2 * d][c] - pix[ 0][c]) +
ABS(pix[ 2 * d][c] - pix[ 0][c]) +
ABS(pix[ -d][1] - pix[ d][1]) ) * 3 +
( ABS(pix[ 3 * d][1] - pix[ d][1]) +
ABS(pix[-3 * d][1] - pix[-d][1]) ) * 2;
}
d = dir[i = diff[0] > diff[1]];
pix[0][1] = median(static_cast<float>(guess[i] >> 2), pix[d][1], pix[-d][1]);
}
if(plistener) {
plistener->setProgress(0.33 * row / (height - 3));
}
}
/* Calculate red and blue for each green pixel: */
for (row = 1; row < height - 1; row++) {
for (col = 1 + (FC(row, 2) & 1), c = FC(row, col + 1); col < width - 1; col += 2) {
pix = image + row * width + col;
for (i = 0; (d = dir[i]) > 0; c = 2 - c, i++)
pix[0][c] = CLIP(0.5 * (pix[-d][c] + pix[d][c] + 2 * pix[0][1]
- pix[-d][1] - pix[d][1]) );
}
if(plistener) {
plistener->setProgress(0.33 + 0.33 * row / (height - 1));
}
}
/* Calculate blue for red pixels and vice versa: */
for (row = 1; row < height - 1; row++) {
for (col = 1 + (FC(row, 1) & 1), c = 2 - FC(row, col); col < width - 1; col += 2) {
pix = image + row * width + col;
for (i = 0; (d = dir[i] + dir[i + 1]) > 0; i++) {
diff[i] = ABS(pix[-d][c] - pix[d][c]) +
ABS(pix[-d][1] - pix[0][1]) +
ABS(pix[ d][1] - pix[0][1]);
guess[i] = pix[-d][c] + pix[d][c] + 2 * pix[0][1]
- pix[-d][1] - pix[d][1];
}
if (diff[0] != diff[1]) {
pix[0][c] = CLIP(guess[diff[0] > diff[1]] / 2);
} else {
pix[0][c] = CLIP((guess[0] + guess[1]) / 4);
}
}
if(plistener) {
plistener->setProgress(0.67 + 0.33 * row / (height - 1));
}
}
red(W, H);
for (int i = 0; i < H; i++)
for (int j = 0; j < W; j++) {
red[i][j] = image[i * W + j][0];
}
green(W, H);
for (int i = 0; i < H; i++)
for (int j = 0; j < W; j++) {
green[i][j] = image[i * W + j][1];
}
blue(W, H);
for (int i = 0; i < H; i++)
for (int j = 0; j < W; j++) {
blue[i][j] = image[i * W + j][2];
}
free (image);
}
void RawImageSource::border_interpolate(unsigned int border, float (*image)[4], unsigned int start, unsigned int end)
{
unsigned row, col, y, x, f;
float sum[8];
unsigned int width = W, height = H;
unsigned int colors = 3;
if (end == 0 ) {
end = H;
}
for (row = start; row < end; row++)
for (col = 0; col < width; col++) {
if (col == border && row >= border && row < height - border) {
col = width - border;
}
memset (sum, 0, sizeof sum);
for (y = row - 1; y != row + 2; y++)
for (x = col - 1; x != col + 2; x++)
if (y < height && x < width) {
f = fc(y, x);
sum[f] += image[y * width + x][f];
sum[f + 4]++;
}
f = fc(row, col);
FORCC if (c != f && sum[c + 4]) {
image[row * width + col][c] = sum[c] / sum[c + 4];
}
}
}
void RawImageSource::border_interpolate2( int winw, int winh, int lborders, const array2D<float> &rawData, array2D<float> &red, array2D<float> &green, array2D<float> &blue)
{
int bord = lborders;
int width = winw;
int height = winh;
for (int i = 0; i < height; i++) {
float sum[6];
for (int j = 0; j < bord; j++) { //first few columns
for (int c = 0; c < 6; c++) {
sum[c] = 0;
}
for (int i1 = i - 1; i1 < i + 2; i1++)
for (int j1 = j - 1; j1 < j + 2; j1++) {
if ((i1 > -1) && (i1 < height) && (j1 > -1)) {
int c = FC(i1, j1);
sum[c] += rawData[i1][j1];
sum[c + 3]++;
}
}
int c = FC(i, j);
if (c == 1) {
red[i][j] = sum[0] / sum[3];
green[i][j] = rawData[i][j];
blue[i][j] = sum[2] / sum[5];
} else {
green[i][j] = sum[1] / sum[4];
if (c == 0) {
red[i][j] = rawData[i][j];
blue[i][j] = sum[2] / sum[5];
} else {
red[i][j] = sum[0] / sum[3];
blue[i][j] = rawData[i][j];
}
}
}//j
for (int j = width - bord; j < width; j++) { //last few columns
for (int c = 0; c < 6; c++) {
sum[c] = 0;
}
for (int i1 = i - 1; i1 < i + 2; i1++)
for (int j1 = j - 1; j1 < j + 2; j1++) {
if ((i1 > -1) && (i1 < height ) && (j1 < width)) {
int c = FC(i1, j1);
sum[c] += rawData[i1][j1];
sum[c + 3]++;
}
}
int c = FC(i, j);
if (c == 1) {
red[i][j] = sum[0] / sum[3];
green[i][j] = rawData[i][j];
blue[i][j] = sum[2] / sum[5];
} else {
green[i][j] = sum[1] / sum[4];
if (c == 0) {
red[i][j] = rawData[i][j];
blue[i][j] = sum[2] / sum[5];
} else {
red[i][j] = sum[0] / sum[3];
blue[i][j] = rawData[i][j];
}
}
}//j
}//i
for (int i = 0; i < bord; i++) {
float sum[6];
for (int j = bord; j < width - bord; j++) { //first few rows
for (int c = 0; c < 6; c++) {
sum[c] = 0;
}
for (int i1 = i - 1; i1 < i + 2; i1++)
for (int j1 = j - 1; j1 < j + 2; j1++) {
if ((i1 > -1) && (i1 < height) && (j1 > -1)) {
int c = FC(i1, j1);
sum[c] += rawData[i1][j1];
sum[c + 3]++;
}
}
int c = FC(i, j);
if (c == 1) {
red[i][j] = sum[0] / sum[3];
green[i][j] = rawData[i][j];
blue[i][j] = sum[2] / sum[5];
} else {
green[i][j] = sum[1] / sum[4];
if (c == 0) {
red[i][j] = rawData[i][j];
blue[i][j] = sum[2] / sum[5];
} else {
red[i][j] = sum[0] / sum[3];
blue[i][j] = rawData[i][j];
}
}
}//j
}
for (int i = height - bord; i < height; i++) {
float sum[6];
for (int j = bord; j < width - bord; j++) { //last few rows
for (int c = 0; c < 6; c++) {
sum[c] = 0;
}
for (int i1 = i - 1; i1 < i + 2; i1++)
for (int j1 = j - 1; j1 < j + 2; j1++) {
if ((i1 > -1) && (i1 < height) && (j1 < width)) {
int c = FC(i1, j1);
sum[c] += rawData[i1][j1];
sum[c + 3]++;
}
}
int c = FC(i, j);
if (c == 1) {
red[i][j] = sum[0] / sum[3];
green[i][j] = rawData[i][j];
blue[i][j] = sum[2] / sum[5];
} else {
green[i][j] = sum[1] / sum[4];
if (c == 0) {
red[i][j] = rawData[i][j];
blue[i][j] = sum[2] / sum[5];
} else {
red[i][j] = sum[0] / sum[3];
blue[i][j] = rawData[i][j];
}
}
}//j
}
}
// Joint Demosaicing and Denoising using High Order Interpolation Techniques
// Revision 0.9.1a - 09/02/2010 - Contact info: luis.sanz.rodriguez@gmail.com
// Copyright Luis Sanz Rodriguez 2010
// Adapted to RawTherapee by Jacques Desmis 3/2013
void RawImageSource::jdl_interpolate_omp() // from "Lassus"
{
int width = W, height = H;
int row, col, c, d, i, u = width, v = 2 * u, w = 3 * u, x = 4 * u, y = 5 * u, z = 6 * u, indx, (*dif)[2], (*chr)[2];
float f[4], g[4];
float (*image)[4];
image = (float (*)[4]) calloc (static_cast<size_t>(width) * height, sizeof * image);
dif = (int (*)[2]) calloc(static_cast<size_t>(width) * height, sizeof * dif);
chr = (int (*)[2]) calloc(static_cast<size_t>(width) * height, sizeof * chr);
if (plistener) {
// this function seems to be unused
//plistener->setProgressStr (Glib::ustring::compose(M("TP_RAW_DMETHOD_PROGRESSBAR"), RAWParams::BayerSensor::getMethodString(RAWParams::BayerSensor::jdl)));
plistener->setProgressStr (Glib::ustring::compose(M("TP_RAW_DMETHOD_PROGRESSBAR"), M("GENERAL_NA")));
plistener->setProgress (0.0);
}
#ifdef _OPENMP
#pragma omp parallel shared(image,width,height,u,w,v,y,x,z,dif,chr) private(row,col,f,g,indx,c,d,i)
#endif
{
#ifdef _OPENMP
#pragma omp for
#endif
for (int ii = 0; ii < height; ii++)
for (int jj = 0; jj < width; jj++) {
image[ii * width + jj][fc(ii, jj)] = rawData[ii][jj];
}
border_interpolate(6, image);
#ifdef _OPENMP
#pragma omp for
#endif
for (row = 5; row < height - 5; row++)
for (col = 5 + (FC(row, 1) & 1), indx = row * width + col, c = FC(row, col); col < u - 5; col += 2, indx += 2) {
f[0] = 1.f + abs(image[indx - u][1] - image[indx - w][1]) + abs(image[indx - u][1] - image[indx + u][1]) + abs(image[indx][c] - image[indx - v][c]) + abs(image[indx - v][c] - image[indx - x][c]);
f[1] = 1.f + abs(image[indx + 1][1] - image[indx + 3][1]) + abs(image[indx + 1][1] - image[indx - 1][1]) + abs(image[indx][c] - image[indx + 2][c]) + abs(image[indx + 2][c] - image[indx + 4][c]);
f[2] = 1.f + abs(image[indx - 1][1] - image[indx - 3][1]) + abs(image[indx - 1][1] - image[indx + 1][1]) + abs(image[indx][c] - image[indx - 2][c]) + abs(image[indx - 2][c] - image[indx - 4][c]);
f[3] = 1.f + abs(image[indx + u][1] - image[indx + w][1]) + abs(image[indx + u][1] - image[indx - u][1]) + abs(image[indx][c] - image[indx + v][c]) + abs(image[indx + v][c] - image[indx + x][c]);
g[0] = CLIP((22.f * image[indx - u][1] + 22.f * image[indx - w][1] + 2.f * image[indx - y][1] + 2.f * image[indx + u][1] + 40.f * image[indx][c] - 32.f * image[indx - v][c] - 8.f * image[indx - x][c]) / 48.f);
g[1] = CLIP((22.f * image[indx + 1][1] + 22.f * image[indx + 3][1] + 2.f * image[indx + 5][1] + 2.f * image[indx - 1][1] + 40.f * image[indx][c] - 32.f * image[indx + 2][c] - 8.f * image[indx + 4][c]) / 48.f);
g[2] = CLIP((22.f * image[indx - 1][1] + 22.f * image[indx - 3][1] + 2.f * image[indx - 5][1] + 2.f * image[indx + 1][1] + 40.f * image[indx][c] - 32.f * image[indx - 2][c] - 8.f * image[indx - 4][c]) / 48.f);
g[3] = CLIP((22.f * image[indx + u][1] + 22.f * image[indx + w][1] + 2.f * image[indx + y][1] + 2.f * image[indx - u][1] + 40.f * image[indx][c] - 32.f * image[indx + v][c] - 8.f * image[indx + x][c]) / 48.f);
dif[indx][0] = CLIP((f[3] * g[0] + f[0] * g[3]) / (f[0] + f[3])) - image[indx][c];
dif[indx][1] = CLIP((f[2] * g[1] + f[1] * g[2]) / (f[1] + f[2])) - image[indx][c];
}
#ifdef _OPENMP
#pragma omp for
#endif
for (row = 6; row < height - 6; row++)
for (col = 6 + (FC(row, 2) & 1), indx = row * width + col, c = FC(row, col) / 2; col < u - 6; col += 2, indx += 2) {
f[0] = 1.f + 78.f * SQR((float)dif[indx][0]) + 69.f * (SQR((float) dif[indx - v][0]) + SQR((float)dif[indx + v][0])) + 51.f * (SQR((float)dif[indx - x][0]) + SQR((float)dif[indx + x][0])) + 21.f * (SQR((float)dif[indx - z][0]) + SQR((float)dif[indx + z][0])) - 6.f * SQR((float)dif[indx - v][0] + dif[indx][0] + dif[indx + v][0]) - 10.f * (SQR((float)dif[indx - x][0] + dif[indx - v][0] + dif[indx][0]) + SQR((float)dif[indx][0] + dif[indx + v][0] + dif[indx + x][0])) - 7.f * (SQR((float)dif[indx - z][0] + dif[indx - x][0] + dif[indx - v][0]) + SQR((float)dif[indx + v][0] + dif[indx + x][0] + dif[indx + z][0]));
f[1] = 1.f + 78.f * SQR((float)dif[indx][1]) + 69.f * (SQR((float)dif[indx - 2][1]) + SQR((float)dif[indx + 2][1])) + 51.f * (SQR((float)dif[indx - 4][1]) + SQR((float)dif[indx + 4][1])) + 21.f * (SQR((float)dif[indx - 6][1]) + SQR((float)dif[indx + 6][1])) - 6.f * SQR((float)dif[indx - 2][1] + dif[indx][1] + dif[indx + 2][1]) - 10.f * (SQR((float)dif[indx - 4][1] + dif[indx - 2][1] + dif[indx][1]) + SQR((float)dif[indx][1] + dif[indx + 2][1] + dif[indx + 4][1])) - 7.f * (SQR((float)dif[indx - 6][1] + dif[indx - 4][1] + dif[indx - 2][1]) + SQR((float)dif[indx + 2][1] + dif[indx + 4][1] + dif[indx + 6][1]));
g[0] = median(0.725f * dif[indx][0] + 0.1375f * dif[indx - v][0] + 0.1375f * dif[indx + v][0], static_cast<float>(dif[indx - v][0]), static_cast<float>(dif[indx + v][0]));
g[1] = median(0.725f * dif[indx][1] + 0.1375f * dif[indx - 2][1] + 0.1375f * dif[indx + 2][1], static_cast<float>(dif[indx - 2][1]), static_cast<float>(dif[indx + 2][1]));
chr[indx][c] = (f[1] * g[0] + f[0] * g[1]) / (f[0] + f[1]);
}
#ifdef _OPENMP
#pragma omp for
#endif
for (row = 6; row < height - 6; row++)
for (col = 6 + (FC(row, 2) & 1), indx = row * width + col, c = 1 - FC(row, col) / 2, d = 2 * c; col < u - 6; col += 2, indx += 2) {
f[0] = 1.f / (float)(1.f + fabs((float)chr[indx - u - 1][c] - chr[indx + u + 1][c]) + fabs((float)chr[indx - u - 1][c] - chr[indx - w - 3][c]) + fabs((float)chr[indx + u + 1][c] - chr[indx - w - 3][c]));
f[1] = 1.f / (float)(1.f + fabs((float)chr[indx - u + 1][c] - chr[indx + u - 1][c]) + fabs((float)chr[indx - u + 1][c] - chr[indx - w + 3][c]) + fabs((float)chr[indx + u - 1][c] - chr[indx - w + 3][c]));
f[2] = 1.f / (float)(1.f + fabs((float)chr[indx + u - 1][c] - chr[indx - u + 1][c]) + fabs((float)chr[indx + u - 1][c] - chr[indx + w + 3][c]) + fabs((float)chr[indx - u + 1][c] - chr[indx + w - 3][c]));
f[3] = 1.f / (float)(1.f + fabs((float)chr[indx + u + 1][c] - chr[indx - u - 1][c]) + fabs((float)chr[indx + u + 1][c] - chr[indx + w - 3][c]) + fabs((float)chr[indx - u - 1][c] - chr[indx + w + 3][c]));
g[0] = median(chr[indx - u - 1][c], chr[indx - w - 1][c], chr[indx - u - 3][c]);
g[1] = median(chr[indx - u + 1][c], chr[indx - w + 1][c], chr[indx - u + 3][c]);
g[2] = median(chr[indx + u - 1][c], chr[indx + w - 1][c], chr[indx + u - 3][c]);
g[3] = median(chr[indx + u + 1][c], chr[indx + w + 1][c], chr[indx + u + 3][c]);
chr[indx][c] = (f[0] * g[0] + f[1] * g[1] + f[2] * g[2] + f[3] * g[3]) / (f[0] + f[1] + f[2] + f[3]);
image[indx][1] = CLIP(image[indx][2 - d] + chr[indx][1 - c]);
image[indx][d] = CLIP(image[indx][1] - chr[indx][c]);
}
#ifdef _OPENMP
#pragma omp for
#endif
for (row = 6; row < height - 6; row++)
for (col = 6 + (FC(row, 1) & 1), indx = row * width + col, c = FC(row, col + 1) / 2, d = 2 * c; col < u - 6; col += 2, indx += 2)
for(i = 0; i <= 1; c = 1 - c, d = 2 * c, i++) {
f[0] = 1.f / (float)(1.f + fabs((float)chr[indx - u][c] - chr[indx + u][c]) + fabs((float)chr[indx - u][c] - chr[indx - w][c]) + fabs((float)chr[indx + u][c] - chr[indx - w][c]));
f[1] = 1.f / (float)(1.f + fabs((float)chr[indx + 1][c] - chr[indx - 1][c]) + fabs((float)chr[indx + 1][c] - chr[indx + 3][c]) + fabs((float)chr[indx - 1][c] - chr[indx + 3][c]));
f[2] = 1.f / (float)(1.f + fabs((float)chr[indx - 1][c] - chr[indx + 1][c]) + fabs((float)chr[indx - 1][c] - chr[indx - 3][c]) + fabs((float)chr[indx + 1][c] - chr[indx - 3][c]));
f[3] = 1.f / (float)(1.f + fabs((float)chr[indx + u][c] - chr[indx - u][c]) + fabs((float)chr[indx + u][c] - chr[indx + w][c]) + fabs((float)chr[indx - u][c] - chr[indx + w][c]));
g[0] = 0.875f * chr[indx - u][c] + 0.125f * chr[indx - w][c];
g[1] = 0.875f * chr[indx + 1][c] + 0.125f * chr[indx + 3][c];
g[2] = 0.875f * chr[indx - 1][c] + 0.125f * chr[indx - 3][c];
g[3] = 0.875f * chr[indx + u][c] + 0.125f * chr[indx + w][c];
image[indx][d] = CLIP(image[indx][1] - (f[0] * g[0] + f[1] * g[1] + f[2] * g[2] + f[3] * g[3]) / (f[0] + f[1] + f[2] + f[3]));
}
#ifdef _OPENMP
#pragma omp for
#endif
for (int ii = 0; ii < height; ii++) {
for (int jj = 0; jj < width; jj++) {
red[ii][jj] = CLIP(image[ii * width + jj][0]);
green[ii][jj] = CLIP(image[ii * width + jj][1]);
blue[ii][jj] = CLIP(image[ii * width + jj][2]);
}
}
} // End of parallelization
free (image);
free(dif);
free(chr);
//RawImageSource::refinement_lassus();
}
// LSMME demosaicing algorithm
// L. Zhang and X. Wu,
// Color demozaicing via directional Linear Minimum Mean Square-error Estimation,
// IEEE Trans. on Image Processing, vol. 14, pp. 2167-2178,
// Dec. 2005.
// Adapted to RawTherapee by Jacques Desmis 3/2013
// Improved speed and reduced memory consumption by Ingo Weyrich 2/2015
//TODO Tiles to reduce memory consumption
void RawImageSource::lmmse_interpolate_omp(int winw, int winh, array2D<float> &rawData, array2D<float> &red, array2D<float> &green, array2D<float> &blue, int iterations)
{
const int width = winw, height = winh;
const int ba = 10;
const int rr1 = height + 2 * ba;
const int cc1 = width + 2 * ba;
const int w1 = cc1;
const int w2 = 2 * w1;
const int w3 = 3 * w1;
const int w4 = 4 * w1;
float h0, h1, h2, h3, h4, hs;
h0 = 1.0f;
h1 = exp( -1.0f / 8.0f);
h2 = exp( -4.0f / 8.0f);
h3 = exp( -9.0f / 8.0f);
h4 = exp(-16.0f / 8.0f);
hs = h0 + 2.0f * (h1 + h2 + h3 + h4);
h0 /= hs;
h1 /= hs;
h2 /= hs;
h3 /= hs;
h4 /= hs;
int passref = 0;
int iter = 0;
if(iterations <= 4) {
iter = iterations - 1;
passref = 0;
} else if (iterations <= 6) {
iter = 3;
passref = iterations - 4;
} else if (iterations <= 8) {
iter = 3;
passref = iterations - 6;
}
bool applyGamma = true;
if(iterations == 0) {
applyGamma = false;
iter = 0;
} else {
applyGamma = true;
}
float *rix[5];
float *qix[5];
float *buffer = (float *)calloc(static_cast<size_t>(rr1) * cc1 * 5 * sizeof(float), 1);
if(buffer == nullptr) { // allocation of big block of memory failed, try to get 5 smaller ones
printf("lmmse_interpolate_omp: allocation of big memory block failed, try to get 5 smaller ones now...\n");
bool allocationFailed = false;
for(int i = 0; i < 5; i++) {
qix[i] = (float *)calloc(static_cast<size_t>(rr1) * cc1 * sizeof(float), 1);
if(!qix[i]) { // allocation of at least one small block failed
allocationFailed = true;
}
}
if(allocationFailed) { // fall back to igv_interpolate
printf("lmmse_interpolate_omp: allocation of 5 small memory blocks failed, falling back to igv_interpolate...\n");
for(int i = 0; i < 5; i++) { // free the already allocated buffers
if(qix[i]) {
free(qix[i]);
}
}
igv_interpolate(winw, winh);
return;
}
} else {
qix[0] = buffer;
for(int i = 1; i < 5; i++) {
qix[i] = qix[i - 1] + rr1 * cc1;
}
}
if (plistener) {
plistener->setProgressStr (Glib::ustring::compose(M("TP_RAW_DMETHOD_PROGRESSBAR"), M("TP_RAW_LMMSE")));
plistener->setProgress (0.0);
}
LUTf *gamtab;
if(applyGamma) {
gamtab = &(Color::gammatab_24_17a);
} else {
gamtab = new LUTf(65536, LUT_CLIP_ABOVE | LUT_CLIP_BELOW);
gamtab->makeIdentity(65535.f);
}
#ifdef _OPENMP
#pragma omp parallel private(rix)
#endif
{
#ifdef _OPENMP
#pragma omp for
#endif
for (int rrr = ba; rrr < rr1 - ba; rrr++) {
for (int ccc = ba, row = rrr - ba; ccc < cc1 - ba; ccc++) {
int col = ccc - ba;
float *rix = qix[4] + rrr * cc1 + ccc;
rix[0] = (*gamtab)[rawData[row][col]];
}
}
#ifdef _OPENMP
#pragma omp single
#endif
{
if (plistener) {
plistener->setProgress (0.1);
}
}
// G-R(B)
#ifdef _OPENMP
#pragma omp for schedule(dynamic,16)
#endif
for (int rr = 2; rr < rr1 - 2; rr++) {
// G-R(B) at R(B) location
for (int cc = 2 + (FC(rr, 2) & 1); cc < cc1 - 2; cc += 2) {
rix[4] = qix[4] + rr * cc1 + cc;
float v0 = x00625(rix[4][-w1 - 1] + rix[4][-w1 + 1] + rix[4][w1 - 1] + rix[4][w1 + 1]) + x0250(rix[4][0]);
// horizontal
rix[0] = qix[0] + rr * cc1 + cc;
rix[0][0] = - x0250(rix[4][ -2] + rix[4][ 2]) + xdiv2f(rix[4][ -1] + rix[4][0] + rix[4][ 1]);
float Y = v0 + xdiv2f(rix[0][0]);
if (rix[4][0] > 1.75f * Y) {
rix[0][0] = median(rix[0][0], rix[4][ -1], rix[4][ 1]);
} else {
rix[0][0] = LIM(rix[0][0], 0.0f, 1.0f);
}
rix[0][0] -= rix[4][0];
// vertical
rix[1] = qix[1] + rr * cc1 + cc;
rix[1][0] = -x0250(rix[4][-w2] + rix[4][w2]) + xdiv2f(rix[4][-w1] + rix[4][0] + rix[4][w1]);
Y = v0 + xdiv2f(rix[1][0]);
if (rix[4][0] > 1.75f * Y) {
rix[1][0] = median(rix[1][0], rix[4][-w1], rix[4][w1]);
} else {
rix[1][0] = LIM(rix[1][0], 0.0f, 1.0f);
}
rix[1][0] -= rix[4][0];
}
// G-R(B) at G location
for (int ccc = 2 + (FC(rr, 3) & 1); ccc < cc1 - 2; ccc += 2) {
rix[0] = qix[0] + rr * cc1 + ccc;
rix[1] = qix[1] + rr * cc1 + ccc;
rix[4] = qix[4] + rr * cc1 + ccc;
rix[0][0] = x0250(rix[4][ -2] + rix[4][ 2]) - xdiv2f(rix[4][ -1] + rix[4][0] + rix[4][ 1]);
rix[1][0] = x0250(rix[4][-w2] + rix[4][w2]) - xdiv2f(rix[4][-w1] + rix[4][0] + rix[4][w1]);
rix[0][0] = LIM(rix[0][0], -1.0f, 0.0f) + rix[4][0];
rix[1][0] = LIM(rix[1][0], -1.0f, 0.0f) + rix[4][0];
}
}
#ifdef _OPENMP
#pragma omp single
#endif
{
if (plistener) {
plistener->setProgress (0.2);
}
}
// apply low pass filter on differential colors
#ifdef _OPENMP
#pragma omp for
#endif
for (int rr = 4; rr < rr1 - 4; rr++)
for (int cc = 4; cc < cc1 - 4; cc++) {
rix[0] = qix[0] + rr * cc1 + cc;
rix[2] = qix[2] + rr * cc1 + cc;
rix[2][0] = h0 * rix[0][0] + h1 * (rix[0][ -1] + rix[0][ 1]) + h2 * (rix[0][ -2] + rix[0][ 2]) + h3 * (rix[0][ -3] + rix[0][ 3]) + h4 * (rix[0][ -4] + rix[0][ 4]);
rix[1] = qix[1] + rr * cc1 + cc;
rix[3] = qix[3] + rr * cc1 + cc;
rix[3][0] = h0 * rix[1][0] + h1 * (rix[1][-w1] + rix[1][w1]) + h2 * (rix[1][-w2] + rix[1][w2]) + h3 * (rix[1][-w3] + rix[1][w3]) + h4 * (rix[1][-w4] + rix[1][w4]);
}
#ifdef _OPENMP
#pragma omp single
#endif
{
if (plistener) {
plistener->setProgress (0.3);
}
}
// interpolate G-R(B) at R(B)
#ifdef _OPENMP
#pragma omp for
#endif
for (int rr = 4; rr < rr1 - 4; rr++) {
int cc = 4 + (FC(rr, 4) & 1);
#ifdef __SSE2__
__m128 p1v, p2v, p3v, p4v, p5v, p6v, p7v, p8v, p9v, muv, vxv, vnv, xhv, vhv, xvv, vvv;
__m128 epsv = _mm_set1_ps(1e-7);
__m128 ninev = _mm_set1_ps(9.f);
for (; cc < cc1 - 10; cc += 8) {
rix[0] = qix[0] + rr * cc1 + cc;
rix[1] = qix[1] + rr * cc1 + cc;
rix[2] = qix[2] + rr * cc1 + cc;
rix[3] = qix[3] + rr * cc1 + cc;
rix[4] = qix[4] + rr * cc1 + cc;
// horizontal
p1v = LC2VFU(rix[2][-4]);
p2v = LC2VFU(rix[2][-3]);
p3v = LC2VFU(rix[2][-2]);
p4v = LC2VFU(rix[2][-1]);
p5v = LC2VFU(rix[2][ 0]);
p6v = LC2VFU(rix[2][ 1]);
p7v = LC2VFU(rix[2][ 2]);
p8v = LC2VFU(rix[2][ 3]);
p9v = LC2VFU(rix[2][ 4]);
muv = (p1v + p2v + p3v + p4v + p5v + p6v + p7v + p8v + p9v) / ninev;
vxv = epsv + SQRV(p1v - muv) + SQRV(p2v - muv) + SQRV(p3v - muv) + SQRV(p4v - muv) + SQRV(p5v - muv) + SQRV(p6v - muv) + SQRV(p7v - muv) + SQRV(p8v - muv) + SQRV(p9v - muv);
p1v -= LC2VFU(rix[0][-4]);
p2v -= LC2VFU(rix[0][-3]);
p3v -= LC2VFU(rix[0][-2]);
p4v -= LC2VFU(rix[0][-1]);
p5v -= LC2VFU(rix[0][ 0]);
p6v -= LC2VFU(rix[0][ 1]);
p7v -= LC2VFU(rix[0][ 2]);
p8v -= LC2VFU(rix[0][ 3]);
p9v -= LC2VFU(rix[0][ 4]);
vnv = epsv + SQRV(p1v) + SQRV(p2v) + SQRV(p3v) + SQRV(p4v) + SQRV(p5v) + SQRV(p6v) + SQRV(p7v) + SQRV(p8v) + SQRV(p9v);
xhv = (LC2VFU(rix[0][0]) * vxv + LC2VFU(rix[2][0]) * vnv) / (vxv + vnv);
vhv = vxv * vnv / (vxv + vnv);
// vertical
p1v = LC2VFU(rix[3][-w4]);
p2v = LC2VFU(rix[3][-w3]);
p3v = LC2VFU(rix[3][-w2]);
p4v = LC2VFU(rix[3][-w1]);
p5v = LC2VFU(rix[3][ 0]);
p6v = LC2VFU(rix[3][ w1]);
p7v = LC2VFU(rix[3][ w2]);
p8v = LC2VFU(rix[3][ w3]);
p9v = LC2VFU(rix[3][ w4]);
muv = (p1v + p2v + p3v + p4v + p5v + p6v + p7v + p8v + p9v) / ninev;
vxv = epsv + SQRV(p1v - muv) + SQRV(p2v - muv) + SQRV(p3v - muv) + SQRV(p4v - muv) + SQRV(p5v - muv) + SQRV(p6v - muv) + SQRV(p7v - muv) + SQRV(p8v - muv) + SQRV(p9v - muv);
p1v -= LC2VFU(rix[1][-w4]);
p2v -= LC2VFU(rix[1][-w3]);
p3v -= LC2VFU(rix[1][-w2]);
p4v -= LC2VFU(rix[1][-w1]);
p5v -= LC2VFU(rix[1][ 0]);
p6v -= LC2VFU(rix[1][ w1]);
p7v -= LC2VFU(rix[1][ w2]);
p8v -= LC2VFU(rix[1][ w3]);
p9v -= LC2VFU(rix[1][ w4]);
vnv = epsv + SQRV(p1v) + SQRV(p2v) + SQRV(p3v) + SQRV(p4v) + SQRV(p5v) + SQRV(p6v) + SQRV(p7v) + SQRV(p8v) + SQRV(p9v);
xvv = (LC2VFU(rix[1][0]) * vxv + LC2VFU(rix[3][0]) * vnv) / (vxv + vnv);
vvv = vxv * vnv / (vxv + vnv);
// interpolated G-R(B)
muv = (xhv * vvv + xvv * vhv) / (vhv + vvv);
STC2VFU(rix[4][0], muv);
}
#endif
for (; cc < cc1 - 4; cc += 2) {
rix[0] = qix[0] + rr * cc1 + cc;
rix[1] = qix[1] + rr * cc1 + cc;
rix[2] = qix[2] + rr * cc1 + cc;
rix[3] = qix[3] + rr * cc1 + cc;
rix[4] = qix[4] + rr * cc1 + cc;
// horizontal
float p1 = rix[2][-4];
float p2 = rix[2][-3];
float p3 = rix[2][-2];
float p4 = rix[2][-1];
float p5 = rix[2][ 0];
float p6 = rix[2][ 1];
float p7 = rix[2][ 2];
float p8 = rix[2][ 3];
float p9 = rix[2][ 4];
float mu = (p1 + p2 + p3 + p4 + p5 + p6 + p7 + p8 + p9) / 9.f;
float vx = 1e-7 + SQR(p1 - mu) + SQR(p2 - mu) + SQR(p3 - mu) + SQR(p4 - mu) + SQR(p5 - mu) + SQR(p6 - mu) + SQR(p7 - mu) + SQR(p8 - mu) + SQR(p9 - mu);
p1 -= rix[0][-4];
p2 -= rix[0][-3];
p3 -= rix[0][-2];
p4 -= rix[0][-1];
p5 -= rix[0][ 0];
p6 -= rix[0][ 1];
p7 -= rix[0][ 2];
p8 -= rix[0][ 3];
p9 -= rix[0][ 4];
float vn = 1e-7 + SQR(p1) + SQR(p2) + SQR(p3) + SQR(p4) + SQR(p5) + SQR(p6) + SQR(p7) + SQR(p8) + SQR(p9);
float xh = (rix[0][0] * vx + rix[2][0] * vn) / (vx + vn);
float vh = vx * vn / (vx + vn);
// vertical
p1 = rix[3][-w4];
p2 = rix[3][-w3];
p3 = rix[3][-w2];
p4 = rix[3][-w1];
p5 = rix[3][ 0];
p6 = rix[3][ w1];
p7 = rix[3][ w2];
p8 = rix[3][ w3];
p9 = rix[3][ w4];
mu = (p1 + p2 + p3 + p4 + p5 + p6 + p7 + p8 + p9) / 9.f;
vx = 1e-7 + SQR(p1 - mu) + SQR(p2 - mu) + SQR(p3 - mu) + SQR(p4 - mu) + SQR(p5 - mu) + SQR(p6 - mu) + SQR(p7 - mu) + SQR(p8 - mu) + SQR(p9 - mu);
p1 -= rix[1][-w4];
p2 -= rix[1][-w3];
p3 -= rix[1][-w2];
p4 -= rix[1][-w1];
p5 -= rix[1][ 0];
p6 -= rix[1][ w1];
p7 -= rix[1][ w2];
p8 -= rix[1][ w3];
p9 -= rix[1][ w4];
vn = 1e-7 + SQR(p1) + SQR(p2) + SQR(p3) + SQR(p4) + SQR(p5) + SQR(p6) + SQR(p7) + SQR(p8) + SQR(p9);
float xv = (rix[1][0] * vx + rix[3][0] * vn) / (vx + vn);
float vv = vx * vn / (vx + vn);
// interpolated G-R(B)
rix[4][0] = (xh * vv + xv * vh) / (vh + vv);
}
}
#ifdef _OPENMP
#pragma omp single
#endif
{
if (plistener) {
plistener->setProgress (0.4);
}
}
// copy CFA values
#ifdef _OPENMP
#pragma omp for
#endif
for (int rr = 0; rr < rr1; rr++)
for (int cc = 0, row = rr - ba; cc < cc1; cc++) {
int col = cc - ba;
int c = FC(rr, cc);
rix[c] = qix[c] + rr * cc1 + cc;
if ((row >= 0) & (row < height) & (col >= 0) & (col < width)) {
rix[c][0] = (*gamtab)[rawData[row][col]];
} else {
rix[c][0] = 0.f;
}
if (c != 1) {
rix[1] = qix[1] + rr * cc1 + cc;
rix[4] = qix[4] + rr * cc1 + cc;
rix[1][0] = rix[c][0] + rix[4][0];
}
}
#ifdef _OPENMP
#pragma omp single
#endif
{
if (plistener) {
plistener->setProgress (0.5);
}
}
// bilinear interpolation for R/B
// interpolate R/B at G location
#ifdef _OPENMP
#pragma omp for
#endif
for (int rr = 1; rr < rr1 - 1; rr++)
for (int cc = 1 + (FC(rr, 2) & 1), c = FC(rr, cc + 1); cc < cc1 - 1; cc += 2) {
rix[c] = qix[c] + rr * cc1 + cc;
rix[1] = qix[1] + rr * cc1 + cc;
rix[c][0] = rix[1][0] + xdiv2f(rix[c][ -1] - rix[1][ -1] + rix[c][ 1] - rix[1][ 1]);
c = 2 - c;
rix[c] = qix[c] + rr * cc1 + cc;
rix[c][0] = rix[1][0] + xdiv2f(rix[c][-w1] - rix[1][-w1] + rix[c][w1] - rix[1][w1]);
c = 2 - c;
}
#ifdef _OPENMP
#pragma omp single
#endif
{
if (plistener) {
plistener->setProgress (0.6);
}
}
// interpolate R/B at B/R location
#ifdef _OPENMP
#pragma omp for
#endif
for (int rr = 1; rr < rr1 - 1; rr++)
for (int cc = 1 + (FC(rr, 1) & 1), c = 2 - FC(rr, cc); cc < cc1 - 1; cc += 2) {
rix[c] = qix[c] + rr * cc1 + cc;
rix[1] = qix[1] + rr * cc1 + cc;
rix[c][0] = rix[1][0] + x0250(rix[c][-w1] - rix[1][-w1] + rix[c][ -1] - rix[1][ -1] + rix[c][ 1] - rix[1][ 1] + rix[c][ w1] - rix[1][ w1]);
}
#ifdef _OPENMP
#pragma omp single
#endif
{
if (plistener) {
plistener->setProgress (0.7);
}
}
}// End of parallelization 1
// median filter/
for (int pass = 0; pass < iter; pass++) {
// Apply 3x3 median filter
// Compute median(R-G) and median(B-G)
#ifdef _OPENMP
#pragma omp parallel for private(rix)
#endif
for (int rr = 1; rr < rr1 - 1; rr++) {
for (int c = 0; c < 3; c += 2) {
int d = c + 3 - (c == 0 ? 0 : 1);
int cc = 1;
#ifdef __SSE2__
for (; cc < cc1 - 4; cc += 4) {
rix[d] = qix[d] + rr * cc1 + cc;
rix[c] = qix[c] + rr * cc1 + cc;
rix[1] = qix[1] + rr * cc1 + cc;
// Assign 3x3 differential color values
const std::array<vfloat, 9> p = {
LVFU(rix[c][-w1 - 1]) - LVFU(rix[1][-w1 - 1]),
LVFU(rix[c][-w1]) - LVFU(rix[1][-w1]),
LVFU(rix[c][-w1 + 1]) - LVFU(rix[1][-w1 + 1]),
LVFU(rix[c][ -1]) - LVFU(rix[1][ -1]),
LVFU(rix[c][ 0]) - LVFU(rix[1][ 0]),
LVFU(rix[c][ 1]) - LVFU(rix[1][ 1]),
LVFU(rix[c][ w1 - 1]) - LVFU(rix[1][ w1 - 1]),
LVFU(rix[c][ w1]) - LVFU(rix[1][ w1]),
LVFU(rix[c][ w1 + 1]) - LVFU(rix[1][ w1 + 1])
};
_mm_storeu_ps(&rix[d][0], median(p));
}
#endif
for (; cc < cc1 - 1; cc++) {
rix[d] = qix[d] + rr * cc1 + cc;
rix[c] = qix[c] + rr * cc1 + cc;
rix[1] = qix[1] + rr * cc1 + cc;
// Assign 3x3 differential color values
const std::array<float, 9> p = {
rix[c][-w1 - 1] - rix[1][-w1 - 1],
rix[c][-w1] - rix[1][-w1],
rix[c][-w1 + 1] - rix[1][-w1 + 1],
rix[c][ -1] - rix[1][ -1],
rix[c][ 0] - rix[1][ 0],
rix[c][ 1] - rix[1][ 1],
rix[c][ w1 - 1] - rix[1][ w1 - 1],
rix[c][ w1] - rix[1][ w1],
rix[c][ w1 + 1] - rix[1][ w1 + 1]
};
rix[d][0] = median(p);
}
}
}
// red/blue at GREEN pixel locations & red/blue and green at BLUE/RED pixel locations
#ifdef _OPENMP
#pragma omp parallel for private (rix)
#endif
for (int rr = 0; rr < rr1; rr++) {
rix[0] = qix[0] + rr * cc1;
rix[1] = qix[1] + rr * cc1;
rix[2] = qix[2] + rr * cc1;
rix[3] = qix[3] + rr * cc1;
rix[4] = qix[4] + rr * cc1;
int c0 = FC(rr, 0);
int c1 = FC(rr, 1);
if(c0 == 1) {
c1 = 2 - c1;
int d = c1 + 3 - (c1 == 0 ? 0 : 1);
int cc;
for (cc = 0; cc < cc1 - 1; cc += 2) {
rix[0][0] = rix[1][0] + rix[3][0];
rix[2][0] = rix[1][0] + rix[4][0];
rix[0]++;
rix[1]++;
rix[2]++;
rix[3]++;
rix[4]++;
rix[c1][0] = rix[1][0] + rix[d][0];
rix[1][0] = 0.5f * (rix[0][0] - rix[3][0] + rix[2][0] - rix[4][0]);
rix[0]++;
rix[1]++;
rix[2]++;
rix[3]++;
rix[4]++;
}
if(cc < cc1) { // remaining pixel, only if width is odd
rix[0][0] = rix[1][0] + rix[3][0];
rix[2][0] = rix[1][0] + rix[4][0];
}
} else {
c0 = 2 - c0;
int d = c0 + 3 - (c0 == 0 ? 0 : 1);
int cc;
for (cc = 0; cc < cc1 - 1; cc += 2) {
rix[c0][0] = rix[1][0] + rix[d][0];
rix[1][0] = 0.5f * (rix[0][0] - rix[3][0] + rix[2][0] - rix[4][0]);
rix[0]++;
rix[1]++;
rix[2]++;
rix[3]++;
rix[4]++;
rix[0][0] = rix[1][0] + rix[3][0];
rix[2][0] = rix[1][0] + rix[4][0];
rix[0]++;
rix[1]++;
rix[2]++;
rix[3]++;
rix[4]++;
}
if(cc < cc1) { // remaining pixel, only if width is odd
rix[c0][0] = rix[1][0] + rix[d][0];
rix[1][0] = 0.5f * (rix[0][0] - rix[3][0] + rix[2][0] - rix[4][0]);
}
}
}
}
if (plistener) {
plistener->setProgress (0.8);
}
if(applyGamma) {
gamtab = &(Color::igammatab_24_17);
} else {
gamtab->makeIdentity();
}
array2D<float>* rgb[3];
rgb[0] = &red;
rgb[1] = &green;
rgb[2] = &blue;
// copy result back to image matrix
#ifdef _OPENMP
#pragma omp parallel for
#endif
for (int row = 0; row < height; row++) {
for (int col = 0, rr = row + ba; col < width; col++) {
int cc = col + ba;
int c = FC(row, col);
for (int ii = 0; ii < 3; ii++)
if (ii != c) {
float *rix = qix[ii] + rr * cc1 + cc;
(*(rgb[ii]))[row][col] = (*gamtab)[65535.f * rix[0]];
} else {
(*(rgb[ii]))[row][col] = CLIP(rawData[row][col]);
}
}
}
if (plistener) {
plistener->setProgress (1.0);
}
if(buffer) {
free(buffer);
} else
for(int i = 0; i < 5; i++) {
free(qix[i]);
}
if(!applyGamma) {
delete gamtab;
}
if(iterations > 4 && iterations <= 6) {
refinement(passref);
} else if(iterations > 6) {
refinement_lassus(passref);
}
}
/***
*
* Bayer CFA Demosaicing using Integrated Gaussian Vector on Color Differences
* Revision 1.0 - 2013/02/28
*
* Copyright (c) 2007-2013 Luis Sanz Rodriguez
* Using High Order Interpolation technique by Jim S, Jimmy Li, and Sharmil Randhawa
*
* Contact info: luis.sanz.rodriguez@gmail.com
*
* This code is distributed under a GNU General Public License, version 3.
* Visit <https://www.gnu.org/licenses/> for more information.
*
***/
// Adapted to RawTherapee by Jacques Desmis 3/2013
// SSE version by Ingo Weyrich 5/2013
#ifdef __SSE2__
#define CLIPV(a) vclampf(a,zerov,c65535v)
void RawImageSource::igv_interpolate(int winw, int winh)
{
static const float eps = 1e-5f, epssq = 1e-5f; //mod epssq -10f =>-5f Jacques 3/2013 to prevent artifact (divide by zero)
static const int h1 = 1, h2 = 2, h3 = 3, h5 = 5;
const int width = winw, height = winh;
const int v1 = 1 * width, v2 = 2 * width, v3 = 3 * width, v5 = 5 * width;
float* rgb[2];
float* chr[4];
float *rgbarray, *vdif, *hdif, *chrarray;
rgbarray = (float (*)) malloc((width * height) * sizeof( float ) );
rgb[0] = rgbarray;
rgb[1] = rgbarray + (width * height) / 2;
vdif = (float (*)) calloc( width * height / 2, sizeof * vdif );
hdif = (float (*)) calloc( width * height / 2, sizeof * hdif );
chrarray = (float (*)) calloc(static_cast<size_t>(width) * height, sizeof( float ) );
chr[0] = chrarray;
chr[1] = chrarray + (width * height) / 2;
// mapped chr[2] and chr[3] to hdif and hdif, because these are out of use, when chr[2] and chr[3] are used
chr[2] = hdif;
chr[3] = vdif;
if (plistener) {
plistener->setProgressStr (Glib::ustring::compose(M("TP_RAW_DMETHOD_PROGRESSBAR"), M("TP_RAW_IGV")));
plistener->setProgress (0.0);
}
#ifdef _OPENMP
#pragma omp parallel shared(rgb,vdif,hdif,chr)
#endif
{
__m128 ngv, egv, wgv, sgv, nvv, evv, wvv, svv, nwgv, negv, swgv, segv, nwvv, nevv, swvv, sevv, tempv, temp1v, temp2v, temp3v, temp4v, temp5v, temp6v, temp7v, temp8v;
__m128 epsv = _mm_set1_ps( eps );
__m128 epssqv = _mm_set1_ps( epssq );
__m128 c65535v = _mm_set1_ps( 65535.f );
__m128 c23v = _mm_set1_ps( 23.f );
__m128 c40v = _mm_set1_ps( 40.f );
__m128 c51v = _mm_set1_ps( 51.f );
__m128 c32v = _mm_set1_ps( 32.f );
__m128 c8v = _mm_set1_ps( 8.f );
__m128 c7v = _mm_set1_ps( 7.f );
__m128 c6v = _mm_set1_ps( 6.f );
__m128 c10v = _mm_set1_ps( 10.f );
__m128 c21v = _mm_set1_ps( 21.f );
__m128 c78v = _mm_set1_ps( 78.f );
__m128 c69v = _mm_set1_ps( 69.f );
__m128 c3145680v = _mm_set1_ps( 3145680.f );
__m128 onev = _mm_set1_ps ( 1.f );
__m128 zerov = _mm_set1_ps ( 0.f );
__m128 d725v = _mm_set1_ps ( 0.725f );
__m128 d1375v = _mm_set1_ps ( 0.1375f );
float *dest1, *dest2;
float ng, eg, wg, sg, nv, ev, wv, sv, nwg, neg, swg, seg, nwv, nev, swv, sev;
#ifdef _OPENMP
#pragma omp for
#endif
for (int row = 0; row < height - 0; row++) {
dest1 = rgb[FC(row, 0) & 1];
dest2 = rgb[FC(row, 1) & 1];
int col, indx;
for (col = 0, indx = row * width + col; col < width - 7; col += 8, indx += 8) {
temp1v = LVFU( rawData[row][col] );
temp1v = CLIPV( temp1v );
temp2v = LVFU( rawData[row][col + 4] );
temp2v = CLIPV( temp2v );
tempv = _mm_shuffle_ps( temp1v, temp2v, _MM_SHUFFLE( 2, 0, 2, 0 ) );
_mm_storeu_ps( &dest1[indx >> 1], tempv );
tempv = _mm_shuffle_ps( temp1v, temp2v, _MM_SHUFFLE( 3, 1, 3, 1 ) );
_mm_storeu_ps( &dest2[indx >> 1], tempv );
}
for (; col < width; col++, indx += 2) {
dest1[indx >> 1] = CLIP(rawData[row][col]); //rawData = RT data
col++;
if(col < width)
dest2[indx >> 1] = CLIP(rawData[row][col]); //rawData = RT data
}
}
#ifdef _OPENMP
#pragma omp single
#endif
{
if (plistener) {
plistener->setProgress (0.13);
}
}
#ifdef _OPENMP
#pragma omp for
#endif
for (int row = 5; row < height - 5; row++) {
int col, indx, indx1;
for (col = 5 + (FC(row, 1) & 1), indx = row * width + col, indx1 = indx >> 1; col < width - 12; col += 8, indx += 8, indx1 += 4) {
//N,E,W,S Gradients
ngv = (epsv + (vabsf(LVFU(rgb[1][(indx - v1) >> 1]) - LVFU(rgb[1][(indx - v3) >> 1])) + vabsf(LVFU(rgb[0][indx1]) - LVFU(rgb[0][(indx1 - v1)]))) / c65535v);
egv = (epsv + (vabsf(LVFU(rgb[1][(indx + h1) >> 1]) - LVFU(rgb[1][(indx + h3) >> 1])) + vabsf(LVFU(rgb[0][indx1]) - LVFU(rgb[0][(indx1 + h1)]))) / c65535v);
wgv = (epsv + (vabsf(LVFU(rgb[1][(indx - h1) >> 1]) - LVFU(rgb[1][(indx - h3) >> 1])) + vabsf(LVFU(rgb[0][indx1]) - LVFU(rgb[0][(indx1 - h1)]))) / c65535v);
sgv = (epsv + (vabsf(LVFU(rgb[1][(indx + v1) >> 1]) - LVFU(rgb[1][(indx + v3) >> 1])) + vabsf(LVFU(rgb[0][indx1]) - LVFU(rgb[0][(indx1 + v1)]))) / c65535v);
//N,E,W,S High Order Interpolation (Li & Randhawa)
//N,E,W,S Hamilton Adams Interpolation
// (48.f * 65535.f) = 3145680.f
tempv = c40v * LVFU(rgb[0][indx1]);
nvv = vclampf(((c23v * LVFU(rgb[1][(indx - v1) >> 1]) + c23v * LVFU(rgb[1][(indx - v3) >> 1]) + LVFU(rgb[1][(indx - v5) >> 1]) + LVFU(rgb[1][(indx + v1) >> 1]) + tempv - c32v * LVFU(rgb[0][(indx1 - v1)]) - c8v * LVFU(rgb[0][(indx1 - v2)]))) / c3145680v, zerov, onev);
evv = vclampf(((c23v * LVFU(rgb[1][(indx + h1) >> 1]) + c23v * LVFU(rgb[1][(indx + h3) >> 1]) + LVFU(rgb[1][(indx + h5) >> 1]) + LVFU(rgb[1][(indx - h1) >> 1]) + tempv - c32v * LVFU(rgb[0][(indx1 + h1)]) - c8v * LVFU(rgb[0][(indx1 + h2)]))) / c3145680v, zerov, onev);
wvv = vclampf(((c23v * LVFU(rgb[1][(indx - h1) >> 1]) + c23v * LVFU(rgb[1][(indx - h3) >> 1]) + LVFU(rgb[1][(indx - h5) >> 1]) + LVFU(rgb[1][(indx + h1) >> 1]) + tempv - c32v * LVFU(rgb[0][(indx1 - h1)]) - c8v * LVFU(rgb[0][(indx1 - h2)]))) / c3145680v, zerov, onev);
svv = vclampf(((c23v * LVFU(rgb[1][(indx + v1) >> 1]) + c23v * LVFU(rgb[1][(indx + v3) >> 1]) + LVFU(rgb[1][(indx + v5) >> 1]) + LVFU(rgb[1][(indx - v1) >> 1]) + tempv - c32v * LVFU(rgb[0][(indx1 + v1)]) - c8v * LVFU(rgb[0][(indx1 + v2)]))) / c3145680v, zerov, onev);
//Horizontal and vertical color differences
tempv = LVFU( rgb[0][indx1] ) / c65535v;
_mm_storeu_ps( &vdif[indx1], (sgv * nvv + ngv * svv) / (ngv + sgv) - tempv );
_mm_storeu_ps( &hdif[indx1], (wgv * evv + egv * wvv) / (egv + wgv) - tempv );
}
// borders without SSE
for (; col < width - 5; col += 2, indx += 2, indx1++) {
//N,E,W,S Gradients
ng = (eps + (fabsf(rgb[1][(indx - v1) >> 1] - rgb[1][(indx - v3) >> 1]) + fabsf(rgb[0][indx1] - rgb[0][(indx1 - v1)])) / 65535.f);;
eg = (eps + (fabsf(rgb[1][(indx + h1) >> 1] - rgb[1][(indx + h3) >> 1]) + fabsf(rgb[0][indx1] - rgb[0][(indx1 + h1)])) / 65535.f);
wg = (eps + (fabsf(rgb[1][(indx - h1) >> 1] - rgb[1][(indx - h3) >> 1]) + fabsf(rgb[0][indx1] - rgb[0][(indx1 - h1)])) / 65535.f);
sg = (eps + (fabsf(rgb[1][(indx + v1) >> 1] - rgb[1][(indx + v3) >> 1]) + fabsf(rgb[0][indx1] - rgb[0][(indx1 + v1)])) / 65535.f);
//N,E,W,S High Order Interpolation (Li & Randhawa)
//N,E,W,S Hamilton Adams Interpolation
// (48.f * 65535.f) = 3145680.f
nv = LIM(((23.0f * rgb[1][(indx - v1) >> 1] + 23.0f * rgb[1][(indx - v3) >> 1] + rgb[1][(indx - v5) >> 1] + rgb[1][(indx + v1) >> 1] + 40.0f * rgb[0][indx1] - 32.0f * rgb[0][(indx1 - v1)] - 8.0f * rgb[0][(indx1 - v2)])) / 3145680.f, 0.0f, 1.0f);
ev = LIM(((23.0f * rgb[1][(indx + h1) >> 1] + 23.0f * rgb[1][(indx + h3) >> 1] + rgb[1][(indx + h5) >> 1] + rgb[1][(indx - h1) >> 1] + 40.0f * rgb[0][indx1] - 32.0f * rgb[0][(indx1 + h1)] - 8.0f * rgb[0][(indx1 + h2)])) / 3145680.f, 0.0f, 1.0f);
wv = LIM(((23.0f * rgb[1][(indx - h1) >> 1] + 23.0f * rgb[1][(indx - h3) >> 1] + rgb[1][(indx - h5) >> 1] + rgb[1][(indx + h1) >> 1] + 40.0f * rgb[0][indx1] - 32.0f * rgb[0][(indx1 - h1)] - 8.0f * rgb[0][(indx1 - h2)])) / 3145680.f, 0.0f, 1.0f);
sv = LIM(((23.0f * rgb[1][(indx + v1) >> 1] + 23.0f * rgb[1][(indx + v3) >> 1] + rgb[1][(indx + v5) >> 1] + rgb[1][(indx - v1) >> 1] + 40.0f * rgb[0][indx1] - 32.0f * rgb[0][(indx1 + v1)] - 8.0f * rgb[0][(indx1 + v2)])) / 3145680.f, 0.0f, 1.0f);
//Horizontal and vertical color differences
vdif[indx1] = (sg * nv + ng * sv) / (ng + sg) - (rgb[0][indx1]) / 65535.f;
hdif[indx1] = (wg * ev + eg * wv) / (eg + wg) - (rgb[0][indx1]) / 65535.f;
}
}
#ifdef _OPENMP
#pragma omp single
#endif
{
if (plistener) {
plistener->setProgress (0.26);
}
}
#ifdef _OPENMP
#pragma omp for
#endif
for (int row = 7; row < height - 7; row++) {
int col, d, indx1;
for (col = 7 + (FC(row, 1) & 1), indx1 = (row * width + col) >> 1, d = FC(row, col) / 2; col < width - 14; col += 8, indx1 += 4) {
//H&V integrated gaussian vector over variance on color differences
//Mod Jacques 3/2013
ngv = vclampf(epssqv + c78v * SQRV(LVFU(vdif[indx1])) + c69v * (SQRV(LVFU(vdif[indx1 - v1])) + SQRV(LVFU(vdif[indx1 + v1]))) + c51v * (SQRV(LVFU(vdif[indx1 - v2])) + SQRV(LVFU(vdif[indx1 + v2]))) + c21v * (SQRV(LVFU(vdif[indx1 - v3])) + SQRV(LVFU(vdif[indx1 + v3]))) - c6v * SQRV(LVFU(vdif[indx1 - v1]) + LVFU(vdif[indx1]) + LVFU(vdif[indx1 + v1]))
- c10v * (SQRV(LVFU(vdif[indx1 - v2]) + LVFU(vdif[indx1 - v1]) + LVFU(vdif[indx1])) + SQRV(LVFU(vdif[indx1]) + LVFU(vdif[indx1 + v1]) + LVFU(vdif[indx1 + v2]))) - c7v * (SQRV(LVFU(vdif[indx1 - v3]) + LVFU(vdif[indx1 - v2]) + LVFU(vdif[indx1 - v1])) + SQRV(LVFU(vdif[indx1 + v1]) + LVFU(vdif[indx1 + v2]) + LVFU(vdif[indx1 + v3]))), zerov, onev);
egv = vclampf(epssqv + c78v * SQRV(LVFU(hdif[indx1])) + c69v * (SQRV(LVFU(hdif[indx1 - h1])) + SQRV(LVFU(hdif[indx1 + h1]))) + c51v * (SQRV(LVFU(hdif[indx1 - h2])) + SQRV(LVFU(hdif[indx1 + h2]))) + c21v * (SQRV(LVFU(hdif[indx1 - h3])) + SQRV(LVFU(hdif[indx1 + h3]))) - c6v * SQRV(LVFU(hdif[indx1 - h1]) + LVFU(hdif[indx1]) + LVFU(hdif[indx1 + h1]))
- c10v * (SQRV(LVFU(hdif[indx1 - h2]) + LVFU(hdif[indx1 - h1]) + LVFU(hdif[indx1])) + SQRV(LVFU(hdif[indx1]) + LVFU(hdif[indx1 + h1]) + LVFU(hdif[indx1 + h2]))) - c7v * (SQRV(LVFU(hdif[indx1 - h3]) + LVFU(hdif[indx1 - h2]) + LVFU(hdif[indx1 - h1])) + SQRV(LVFU(hdif[indx1 + h1]) + LVFU(hdif[indx1 + h2]) + LVFU(hdif[indx1 + h3]))), zerov, onev);
//Limit chrominance using H/V neighbourhood
nvv = median(d725v * LVFU(vdif[indx1]) + d1375v * LVFU(vdif[indx1 - v1]) + d1375v * LVFU(vdif[indx1 + v1]), LVFU(vdif[indx1 - v1]), LVFU(vdif[indx1 + v1]));
evv = median(d725v * LVFU(hdif[indx1]) + d1375v * LVFU(hdif[indx1 - h1]) + d1375v * LVFU(hdif[indx1 + h1]), LVFU(hdif[indx1 - h1]), LVFU(hdif[indx1 + h1]));
//Chrominance estimation
tempv = (egv * nvv + ngv * evv) / (ngv + egv);
_mm_storeu_ps(&(chr[d][indx1]), tempv);
//Green channel population
temp1v = c65535v * tempv + LVFU(rgb[0][indx1]);
_mm_storeu_ps( &(rgb[0][indx1]), temp1v );
}
for (; col < width - 7; col += 2, indx1++) {
//H&V integrated gaussian vector over variance on color differences
//Mod Jacques 3/2013
ng = LIM(epssq + 78.0f * SQR(vdif[indx1]) + 69.0f * (SQR(vdif[indx1 - v1]) + SQR(vdif[indx1 + v1])) + 51.0f * (SQR(vdif[indx1 - v2]) + SQR(vdif[indx1 + v2])) + 21.0f * (SQR(vdif[indx1 - v3]) + SQR(vdif[indx1 + v3])) - 6.0f * SQR(vdif[indx1 - v1] + vdif[indx1] + vdif[indx1 + v1])
- 10.0f * (SQR(vdif[indx1 - v2] + vdif[indx1 - v1] + vdif[indx1]) + SQR(vdif[indx1] + vdif[indx1 + v1] + vdif[indx1 + v2])) - 7.0f * (SQR(vdif[indx1 - v3] + vdif[indx1 - v2] + vdif[indx1 - v1]) + SQR(vdif[indx1 + v1] + vdif[indx1 + v2] + vdif[indx1 + v3])), 0.f, 1.f);
eg = LIM(epssq + 78.0f * SQR(hdif[indx1]) + 69.0f * (SQR(hdif[indx1 - h1]) + SQR(hdif[indx1 + h1])) + 51.0f * (SQR(hdif[indx1 - h2]) + SQR(hdif[indx1 + h2])) + 21.0f * (SQR(hdif[indx1 - h3]) + SQR(hdif[indx1 + h3])) - 6.0f * SQR(hdif[indx1 - h1] + hdif[indx1] + hdif[indx1 + h1])
- 10.0f * (SQR(hdif[indx1 - h2] + hdif[indx1 - h1] + hdif[indx1]) + SQR(hdif[indx1] + hdif[indx1 + h1] + hdif[indx1 + h2])) - 7.0f * (SQR(hdif[indx1 - h3] + hdif[indx1 - h2] + hdif[indx1 - h1]) + SQR(hdif[indx1 + h1] + hdif[indx1 + h2] + hdif[indx1 + h3])), 0.f, 1.f);
//Limit chrominance using H/V neighbourhood
nv = median(0.725f * vdif[indx1] + 0.1375f * vdif[indx1 - v1] + 0.1375f * vdif[indx1 + v1], vdif[indx1 - v1], vdif[indx1 + v1]);
ev = median(0.725f * hdif[indx1] + 0.1375f * hdif[indx1 - h1] + 0.1375f * hdif[indx1 + h1], hdif[indx1 - h1], hdif[indx1 + h1]);
//Chrominance estimation
chr[d][indx1] = (eg * nv + ng * ev) / (ng + eg);
//Green channel population
rgb[0][indx1] = rgb[0][indx1] + 65535.f * chr[d][indx1];
}
}
#ifdef _OPENMP
#pragma omp single
#endif
{
if (plistener) {
plistener->setProgress (0.39);
}
}
#ifdef _OPENMP
#pragma omp for
#endif
for (int row = 7; row < height - 7; row++) {
int col, indx, c;
for (col = 7 + (FC(row, 1) & 1), indx = row * width + col, c = 1 - FC(row, col) / 2; col < width - 14; col += 8, indx += 8) {
//NW,NE,SW,SE Gradients
nwgv = onev / (epsv + vabsf(LVFU(chr[c][(indx - v1 - h1) >> 1]) - LVFU(chr[c][(indx - v3 - h3) >> 1])) + vabsf(LVFU(chr[c][(indx + v1 + h1) >> 1]) - LVFU(chr[c][(indx - v3 - h3) >> 1])));
negv = onev / (epsv + vabsf(LVFU(chr[c][(indx - v1 + h1) >> 1]) - LVFU(chr[c][(indx - v3 + h3) >> 1])) + vabsf(LVFU(chr[c][(indx + v1 - h1) >> 1]) - LVFU(chr[c][(indx - v3 + h3) >> 1])));
swgv = onev / (epsv + vabsf(LVFU(chr[c][(indx + v1 - h1) >> 1]) - LVFU(chr[c][(indx + v3 + h3) >> 1])) + vabsf(LVFU(chr[c][(indx - v1 + h1) >> 1]) - LVFU(chr[c][(indx + v3 - h3) >> 1])));
segv = onev / (epsv + vabsf(LVFU(chr[c][(indx + v1 + h1) >> 1]) - LVFU(chr[c][(indx + v3 - h3) >> 1])) + vabsf(LVFU(chr[c][(indx - v1 - h1) >> 1]) - LVFU(chr[c][(indx + v3 + h3) >> 1])));
//Limit NW,NE,SW,SE Color differences
nwvv = median(LVFU(chr[c][(indx - v1 - h1) >> 1]), LVFU(chr[c][(indx - v3 - h1) >> 1]), LVFU(chr[c][(indx - v1 - h3) >> 1]));
nevv = median(LVFU(chr[c][(indx - v1 + h1) >> 1]), LVFU(chr[c][(indx - v3 + h1) >> 1]), LVFU(chr[c][(indx - v1 + h3) >> 1]));
swvv = median(LVFU(chr[c][(indx + v1 - h1) >> 1]), LVFU(chr[c][(indx + v3 - h1) >> 1]), LVFU(chr[c][(indx + v1 - h3) >> 1]));
sevv = median(LVFU(chr[c][(indx + v1 + h1) >> 1]), LVFU(chr[c][(indx + v3 + h1) >> 1]), LVFU(chr[c][(indx + v1 + h3) >> 1]));
//Interpolate chrominance: R@B and B@R
tempv = (nwgv * nwvv + negv * nevv + swgv * swvv + segv * sevv) / (nwgv + negv + swgv + segv);
_mm_storeu_ps( &(chr[c][indx >> 1]), tempv);
}
for (; col < width - 7; col += 2, indx += 2) {
//NW,NE,SW,SE Gradients
nwg = 1.0f / (eps + fabsf(chr[c][(indx - v1 - h1) >> 1] - chr[c][(indx - v3 - h3) >> 1]) + fabsf(chr[c][(indx + v1 + h1) >> 1] - chr[c][(indx - v3 - h3) >> 1]));
neg = 1.0f / (eps + fabsf(chr[c][(indx - v1 + h1) >> 1] - chr[c][(indx - v3 + h3) >> 1]) + fabsf(chr[c][(indx + v1 - h1) >> 1] - chr[c][(indx - v3 + h3) >> 1]));
swg = 1.0f / (eps + fabsf(chr[c][(indx + v1 - h1) >> 1] - chr[c][(indx + v3 + h3) >> 1]) + fabsf(chr[c][(indx - v1 + h1) >> 1] - chr[c][(indx + v3 - h3) >> 1]));
seg = 1.0f / (eps + fabsf(chr[c][(indx + v1 + h1) >> 1] - chr[c][(indx + v3 - h3) >> 1]) + fabsf(chr[c][(indx - v1 - h1) >> 1] - chr[c][(indx + v3 + h3) >> 1]));
//Limit NW,NE,SW,SE Color differences
nwv = median(chr[c][(indx - v1 - h1) >> 1], chr[c][(indx - v3 - h1) >> 1], chr[c][(indx - v1 - h3) >> 1]);
nev = median(chr[c][(indx - v1 + h1) >> 1], chr[c][(indx - v3 + h1) >> 1], chr[c][(indx - v1 + h3) >> 1]);
swv = median(chr[c][(indx + v1 - h1) >> 1], chr[c][(indx + v3 - h1) >> 1], chr[c][(indx + v1 - h3) >> 1]);
sev = median(chr[c][(indx + v1 + h1) >> 1], chr[c][(indx + v3 + h1) >> 1], chr[c][(indx + v1 + h3) >> 1]);
//Interpolate chrominance: R@B and B@R
chr[c][indx >> 1] = (nwg * nwv + neg * nev + swg * swv + seg * sev) / (nwg + neg + swg + seg);
}
}
#ifdef _OPENMP
#pragma omp single
#endif
{
if (plistener) {
plistener->setProgress (0.65);
}
}
#ifdef _OPENMP
#pragma omp for
#endif
for (int row = 7; row < height - 7; row++) {
int col, indx;
for (col = 7 + (FC(row, 0) & 1), indx = row * width + col; col < width - 14; col += 8, indx += 8) {
//N,E,W,S Gradients
ngv = onev / (epsv + vabsf(LVFU(chr[0][(indx - v1) >> 1]) - LVFU(chr[0][(indx - v3) >> 1])) + vabsf(LVFU(chr[0][(indx + v1) >> 1]) - LVFU(chr[0][(indx - v3) >> 1])));
egv = onev / (epsv + vabsf(LVFU(chr[0][(indx + h1) >> 1]) - LVFU(chr[0][(indx + h3) >> 1])) + vabsf(LVFU(chr[0][(indx - h1) >> 1]) - LVFU(chr[0][(indx + h3) >> 1])));
wgv = onev / (epsv + vabsf(LVFU(chr[0][(indx - h1) >> 1]) - LVFU(chr[0][(indx - h3) >> 1])) + vabsf(LVFU(chr[0][(indx + h1) >> 1]) - LVFU(chr[0][(indx - h3) >> 1])));
sgv = onev / (epsv + vabsf(LVFU(chr[0][(indx + v1) >> 1]) - LVFU(chr[0][(indx + v3) >> 1])) + vabsf(LVFU(chr[0][(indx - v1) >> 1]) - LVFU(chr[0][(indx + v3) >> 1])));
//Interpolate chrominance: R@G and B@G
tempv = ((ngv * LVFU(chr[0][(indx - v1) >> 1]) + egv * LVFU(chr[0][(indx + h1) >> 1]) + wgv * LVFU(chr[0][(indx - h1) >> 1]) + sgv * LVFU(chr[0][(indx + v1) >> 1])) / (ngv + egv + wgv + sgv));
_mm_storeu_ps( &chr[0 + 2][indx >> 1], tempv);
}
for (; col < width - 7; col += 2, indx += 2) {
//N,E,W,S Gradients
ng = 1.0f / (eps + fabsf(chr[0][(indx - v1) >> 1] - chr[0][(indx - v3) >> 1]) + fabsf(chr[0][(indx + v1) >> 1] - chr[0][(indx - v3) >> 1]));
eg = 1.0f / (eps + fabsf(chr[0][(indx + h1) >> 1] - chr[0][(indx + h3) >> 1]) + fabsf(chr[0][(indx - h1) >> 1] - chr[0][(indx + h3) >> 1]));
wg = 1.0f / (eps + fabsf(chr[0][(indx - h1) >> 1] - chr[0][(indx - h3) >> 1]) + fabsf(chr[0][(indx + h1) >> 1] - chr[0][(indx - h3) >> 1]));
sg = 1.0f / (eps + fabsf(chr[0][(indx + v1) >> 1] - chr[0][(indx + v3) >> 1]) + fabsf(chr[0][(indx - v1) >> 1] - chr[0][(indx + v3) >> 1]));
//Interpolate chrominance: R@G and B@G
chr[0 + 2][indx >> 1] = ((ng * chr[0][(indx - v1) >> 1] + eg * chr[0][(indx + h1) >> 1] + wg * chr[0][(indx - h1) >> 1] + sg * chr[0][(indx + v1) >> 1]) / (ng + eg + wg + sg));
}
}
#ifdef _OPENMP
#pragma omp single
#endif
{
if (plistener) {
plistener->setProgress (0.78);
}
}
#ifdef _OPENMP
#pragma omp for
#endif
for (int row = 7; row < height - 7; row++) {
int col, indx;
for (col = 7 + (FC(row, 0) & 1), indx = row * width + col; col < width - 14; col += 8, indx += 8) {
//N,E,W,S Gradients
ngv = onev / (epsv + vabsf(LVFU(chr[1][(indx - v1) >> 1]) - LVFU(chr[1][(indx - v3) >> 1])) + vabsf(LVFU(chr[1][(indx + v1) >> 1]) - LVFU(chr[1][(indx - v3) >> 1])));
egv = onev / (epsv + vabsf(LVFU(chr[1][(indx + h1) >> 1]) - LVFU(chr[1][(indx + h3) >> 1])) + vabsf(LVFU(chr[1][(indx - h1) >> 1]) - LVFU(chr[1][(indx + h3) >> 1])));
wgv = onev / (epsv + vabsf(LVFU(chr[1][(indx - h1) >> 1]) - LVFU(chr[1][(indx - h3) >> 1])) + vabsf(LVFU(chr[1][(indx + h1) >> 1]) - LVFU(chr[1][(indx - h3) >> 1])));
sgv = onev / (epsv + vabsf(LVFU(chr[1][(indx + v1) >> 1]) - LVFU(chr[1][(indx + v3) >> 1])) + vabsf(LVFU(chr[1][(indx - v1) >> 1]) - LVFU(chr[1][(indx + v3) >> 1])));
//Interpolate chrominance: R@G and B@G
tempv = ((ngv * LVFU(chr[1][(indx - v1) >> 1]) + egv * LVFU(chr[1][(indx + h1) >> 1]) + wgv * LVFU(chr[1][(indx - h1) >> 1]) + sgv * LVFU(chr[1][(indx + v1) >> 1])) / (ngv + egv + wgv + sgv));
_mm_storeu_ps( &chr[1 + 2][indx >> 1], tempv);
}
for (; col < width - 7; col += 2, indx += 2) {
//N,E,W,S Gradients
ng = 1.0f / (eps + fabsf(chr[1][(indx - v1) >> 1] - chr[1][(indx - v3) >> 1]) + fabsf(chr[1][(indx + v1) >> 1] - chr[1][(indx - v3) >> 1]));
eg = 1.0f / (eps + fabsf(chr[1][(indx + h1) >> 1] - chr[1][(indx + h3) >> 1]) + fabsf(chr[1][(indx - h1) >> 1] - chr[1][(indx + h3) >> 1]));
wg = 1.0f / (eps + fabsf(chr[1][(indx - h1) >> 1] - chr[1][(indx - h3) >> 1]) + fabsf(chr[1][(indx + h1) >> 1] - chr[1][(indx - h3) >> 1]));
sg = 1.0f / (eps + fabsf(chr[1][(indx + v1) >> 1] - chr[1][(indx + v3) >> 1]) + fabsf(chr[1][(indx - v1) >> 1] - chr[1][(indx + v3) >> 1]));
//Interpolate chrominance: R@G and B@G
chr[1 + 2][indx >> 1] = ((ng * chr[1][(indx - v1) >> 1] + eg * chr[1][(indx + h1) >> 1] + wg * chr[1][(indx - h1) >> 1] + sg * chr[1][(indx + v1) >> 1]) / (ng + eg + wg + sg));
}
}
#ifdef _OPENMP
#pragma omp single
#endif
{
if (plistener) {
plistener->setProgress (0.91);
}
}
float *src1, *src2, *redsrc0, *redsrc1, *bluesrc0, *bluesrc1;
#ifdef _OPENMP
#pragma omp for
#endif
for(int row = 7; row < height - 7; row++) {
int col, indx, fc;
fc = FC(row, 7) & 1;
src1 = rgb[fc];
src2 = rgb[fc ^ 1];
redsrc0 = chr[fc << 1];
redsrc1 = chr[(fc ^ 1) << 1];
bluesrc0 = chr[(fc << 1) + 1];
bluesrc1 = chr[((fc ^ 1) << 1) + 1];
for(col = 7, indx = row * width + col; col < width - 14; col += 8, indx += 8) {
temp1v = LVFU( src1[indx >> 1] );
temp2v = LVFU( src2[(indx + 1) >> 1] );
tempv = _mm_shuffle_ps( temp1v, temp2v, _MM_SHUFFLE( 1, 0, 1, 0 ) );
tempv = _mm_shuffle_ps( tempv, tempv, _MM_SHUFFLE( 3, 1, 2, 0 ) );
_mm_storeu_ps( &green[row][col], CLIPV( tempv ));
temp5v = LVFU(redsrc0[indx >> 1]);
temp6v = LVFU(redsrc1[(indx + 1) >> 1]);
temp3v = _mm_shuffle_ps( temp5v, temp6v, _MM_SHUFFLE( 1, 0, 1, 0 ) );
temp3v = _mm_shuffle_ps( temp3v, temp3v, _MM_SHUFFLE( 3, 1, 2, 0 ) );
temp3v = CLIPV( tempv - c65535v * temp3v );
_mm_storeu_ps( &red[row][col], temp3v);
temp7v = LVFU(bluesrc0[indx >> 1]);
temp8v = LVFU(bluesrc1[(indx + 1) >> 1]);
temp4v = _mm_shuffle_ps( temp7v, temp8v, _MM_SHUFFLE( 1, 0, 1, 0 ) );
temp4v = _mm_shuffle_ps( temp4v, temp4v, _MM_SHUFFLE( 3, 1, 2, 0 ) );
temp4v = CLIPV( tempv - c65535v * temp4v );
_mm_storeu_ps( &blue[row][col], temp4v);
tempv = _mm_shuffle_ps( temp1v, temp2v, _MM_SHUFFLE( 3, 2, 3, 2 ) );
tempv = _mm_shuffle_ps( tempv, tempv, _MM_SHUFFLE( 3, 1, 2, 0 ) );
_mm_storeu_ps( &green[row][col + 4], CLIPV( tempv ));
temp3v = _mm_shuffle_ps( temp5v, temp6v, _MM_SHUFFLE( 3, 2, 3, 2 ) );
temp3v = _mm_shuffle_ps( temp3v, temp3v, _MM_SHUFFLE( 3, 1, 2, 0 ) );
temp3v = CLIPV( tempv - c65535v * temp3v );
_mm_storeu_ps( &red[row][col + 4], temp3v);
temp4v = _mm_shuffle_ps( temp7v, temp8v, _MM_SHUFFLE( 3, 2, 3, 2 ) );
temp4v = _mm_shuffle_ps( temp4v, temp4v, _MM_SHUFFLE( 3, 1, 2, 0 ) );
temp4v = CLIPV( tempv - c65535v * temp4v );
_mm_storeu_ps( &blue[row][col + 4], temp4v);
}
for(; col < width - 7; col++, indx += 2) {
red [row][col] = CLIP(src1[indx >> 1] - 65535.f * redsrc0[indx >> 1]);
green[row][col] = CLIP(src1[indx >> 1]);
blue [row][col] = CLIP(src1[indx >> 1] - 65535.f * bluesrc0[indx >> 1]);
col++;
red [row][col] = CLIP(src2[(indx + 1) >> 1] - 65535.f * redsrc1[(indx + 1) >> 1]);
green[row][col] = CLIP(src2[(indx + 1) >> 1]);
blue [row][col] = CLIP(src2[(indx + 1) >> 1] - 65535.f * bluesrc1[(indx + 1) >> 1]);
}
}
}// End of parallelization
border_interpolate2(winw, winh, 8, rawData, red, green, blue);
if (plistener) {
plistener->setProgress (1.0);
}
free(chrarray);
free(rgbarray);
free(vdif);
free(hdif);
}
#undef CLIPV
#else
void RawImageSource::igv_interpolate(int winw, int winh)
{
static const float eps = 1e-5f, epssq = 1e-5f; //mod epssq -10f =>-5f Jacques 3/2013 to prevent artifact (divide by zero)
static const int h1 = 1, h2 = 2, h3 = 3, h4 = 4, h5 = 5, h6 = 6;
const int width = winw, height = winh;
const int v1 = 1 * width, v2 = 2 * width, v3 = 3 * width, v4 = 4 * width, v5 = 5 * width, v6 = 6 * width;
float* rgb[3];
float* chr[2];
float *rgbarray, *vdif, *hdif, *chrarray;
rgbarray = (float (*)) calloc(width * height * 3, sizeof( float));
rgb[0] = rgbarray;
rgb[1] = rgbarray + (width * height);
rgb[2] = rgbarray + 2 * (width * height);
chrarray = (float (*)) calloc(width * height * 2, sizeof( float));
chr[0] = chrarray;
chr[1] = chrarray + (width * height);
vdif = (float (*)) calloc(width * height / 2, sizeof * vdif);
hdif = (float (*)) calloc(width * height / 2, sizeof * hdif);
if (plistener) {
plistener->setProgressStr (Glib::ustring::compose(M("TP_RAW_DMETHOD_PROGRESSBAR"), M("TP_RAW_IGV")));
plistener->setProgress (0.0);
}
#ifdef _OPENMP
#pragma omp parallel shared(rgb,vdif,hdif,chr)
#endif
{
float ng, eg, wg, sg, nv, ev, wv, sv, nwg, neg, swg, seg, nwv, nev, swv, sev;
#ifdef _OPENMP
#pragma omp for
#endif
for (int row = 0; row < height - 0; row++)
for (int col = 0, indx = row * width + col; col < width - 0; col++, indx++) {
int c = FC(row, col);
rgb[c][indx] = CLIP(rawData[row][col]); //rawData = RT data
}
// border_interpolate2(7, rgb);
#ifdef _OPENMP
#pragma omp single
#endif
{
if (plistener) {
plistener->setProgress (0.13);
}
}
#ifdef _OPENMP
#pragma omp for
#endif
for (int row = 5; row < height - 5; row++)
for (int col = 5 + (FC(row, 1) & 1), indx = row * width + col, c = FC(row, col); col < width - 5; col += 2, indx += 2) {
//N,E,W,S Gradients
ng = (eps + (fabsf(rgb[1][indx - v1] - rgb[1][indx - v3]) + fabsf(rgb[c][indx] - rgb[c][indx - v2])) / 65535.f);;
eg = (eps + (fabsf(rgb[1][indx + h1] - rgb[1][indx + h3]) + fabsf(rgb[c][indx] - rgb[c][indx + h2])) / 65535.f);
wg = (eps + (fabsf(rgb[1][indx - h1] - rgb[1][indx - h3]) + fabsf(rgb[c][indx] - rgb[c][indx - h2])) / 65535.f);
sg = (eps + (fabsf(rgb[1][indx + v1] - rgb[1][indx + v3]) + fabsf(rgb[c][indx] - rgb[c][indx + v2])) / 65535.f);
//N,E,W,S High Order Interpolation (Li & Randhawa)
//N,E,W,S Hamilton Adams Interpolation
// (48.f * 65535.f) = 3145680.f
nv = LIM(((23.0f * rgb[1][indx - v1] + 23.0f * rgb[1][indx - v3] + rgb[1][indx - v5] + rgb[1][indx + v1] + 40.0f * rgb[c][indx] - 32.0f * rgb[c][indx - v2] - 8.0f * rgb[c][indx - v4])) / 3145680.f, 0.0f, 1.0f);
ev = LIM(((23.0f * rgb[1][indx + h1] + 23.0f * rgb[1][indx + h3] + rgb[1][indx + h5] + rgb[1][indx - h1] + 40.0f * rgb[c][indx] - 32.0f * rgb[c][indx + h2] - 8.0f * rgb[c][indx + h4])) / 3145680.f, 0.0f, 1.0f);
wv = LIM(((23.0f * rgb[1][indx - h1] + 23.0f * rgb[1][indx - h3] + rgb[1][indx - h5] + rgb[1][indx + h1] + 40.0f * rgb[c][indx] - 32.0f * rgb[c][indx - h2] - 8.0f * rgb[c][indx - h4])) / 3145680.f, 0.0f, 1.0f);
sv = LIM(((23.0f * rgb[1][indx + v1] + 23.0f * rgb[1][indx + v3] + rgb[1][indx + v5] + rgb[1][indx - v1] + 40.0f * rgb[c][indx] - 32.0f * rgb[c][indx + v2] - 8.0f * rgb[c][indx + v4])) / 3145680.f, 0.0f, 1.0f);
//Horizontal and vertical color differences
vdif[indx >> 1] = (sg * nv + ng * sv) / (ng + sg) - (rgb[c][indx]) / 65535.f;
hdif[indx >> 1] = (wg * ev + eg * wv) / (eg + wg) - (rgb[c][indx]) / 65535.f;
}
#ifdef _OPENMP
#pragma omp single
#endif
{
if (plistener) {
plistener->setProgress (0.26);
}
}
#ifdef _OPENMP
#pragma omp for
#endif
for (int row = 7; row < height - 7; row++)
for (int col = 7 + (FC(row, 1) & 1), indx = row * width + col, c = FC(row, col), d = c / 2; col < width - 7; col += 2, indx += 2) {
//H&V integrated gaussian vector over variance on color differences
//Mod Jacques 3/2013
ng = LIM(epssq + 78.0f * SQR(vdif[indx >> 1]) + 69.0f * (SQR(vdif[(indx - v2) >> 1]) + SQR(vdif[(indx + v2) >> 1])) + 51.0f * (SQR(vdif[(indx - v4) >> 1]) + SQR(vdif[(indx + v4) >> 1])) + 21.0f * (SQR(vdif[(indx - v6) >> 1]) + SQR(vdif[(indx + v6) >> 1])) - 6.0f * SQR(vdif[(indx - v2) >> 1] + vdif[indx >> 1] + vdif[(indx + v2) >> 1])
- 10.0f * (SQR(vdif[(indx - v4) >> 1] + vdif[(indx - v2) >> 1] + vdif[indx >> 1]) + SQR(vdif[indx >> 1] + vdif[(indx + v2) >> 1] + vdif[(indx + v4) >> 1])) - 7.0f * (SQR(vdif[(indx - v6) >> 1] + vdif[(indx - v4) >> 1] + vdif[(indx - v2) >> 1]) + SQR(vdif[(indx + v2) >> 1] + vdif[(indx + v4) >> 1] + vdif[(indx + v6) >> 1])), 0.f, 1.f);
eg = LIM(epssq + 78.0f * SQR(hdif[indx >> 1]) + 69.0f * (SQR(hdif[(indx - h2) >> 1]) + SQR(hdif[(indx + h2) >> 1])) + 51.0f * (SQR(hdif[(indx - h4) >> 1]) + SQR(hdif[(indx + h4) >> 1])) + 21.0f * (SQR(hdif[(indx - h6) >> 1]) + SQR(hdif[(indx + h6) >> 1])) - 6.0f * SQR(hdif[(indx - h2) >> 1] + hdif[indx >> 1] + hdif[(indx + h2) >> 1])
- 10.0f * (SQR(hdif[(indx - h4) >> 1] + hdif[(indx - h2) >> 1] + hdif[indx >> 1]) + SQR(hdif[indx >> 1] + hdif[(indx + h2) >> 1] + hdif[(indx + h4) >> 1])) - 7.0f * (SQR(hdif[(indx - h6) >> 1] + hdif[(indx - h4) >> 1] + hdif[(indx - h2) >> 1]) + SQR(hdif[(indx + h2) >> 1] + hdif[(indx + h4) >> 1] + hdif[(indx + h6) >> 1])), 0.f, 1.f);
//Limit chrominance using H/V neighbourhood
nv = median(0.725f * vdif[indx >> 1] + 0.1375f * vdif[(indx - v2) >> 1] + 0.1375f * vdif[(indx + v2) >> 1], vdif[(indx - v2) >> 1], vdif[(indx + v2) >> 1]);
ev = median(0.725f * hdif[indx >> 1] + 0.1375f * hdif[(indx - h2) >> 1] + 0.1375f * hdif[(indx + h2) >> 1], hdif[(indx - h2) >> 1], hdif[(indx + h2) >> 1]);
//Chrominance estimation
chr[d][indx] = (eg * nv + ng * ev) / (ng + eg);
//Green channel population
rgb[1][indx] = rgb[c][indx] + 65535.f * chr[d][indx];
}
#ifdef _OPENMP
#pragma omp single
#endif
{
if (plistener) {
plistener->setProgress (0.39);
}
}
// free(vdif); free(hdif);
#ifdef _OPENMP
#pragma omp for
#endif
for (int row = 7; row < height - 7; row += 2)
for (int col = 7 + (FC(row, 1) & 1), indx = row * width + col, c = 1 - FC(row, col) / 2; col < width - 7; col += 2, indx += 2) {
//NW,NE,SW,SE Gradients
nwg = 1.0f / (eps + fabsf(chr[c][indx - v1 - h1] - chr[c][indx - v3 - h3]) + fabsf(chr[c][indx + v1 + h1] - chr[c][indx - v3 - h3]));
neg = 1.0f / (eps + fabsf(chr[c][indx - v1 + h1] - chr[c][indx - v3 + h3]) + fabsf(chr[c][indx + v1 - h1] - chr[c][indx - v3 + h3]));
swg = 1.0f / (eps + fabsf(chr[c][indx + v1 - h1] - chr[c][indx + v3 + h3]) + fabsf(chr[c][indx - v1 + h1] - chr[c][indx + v3 - h3]));
seg = 1.0f / (eps + fabsf(chr[c][indx + v1 + h1] - chr[c][indx + v3 - h3]) + fabsf(chr[c][indx - v1 - h1] - chr[c][indx + v3 + h3]));
//Limit NW,NE,SW,SE Color differences
nwv = median(chr[c][indx - v1 - h1], chr[c][indx - v3 - h1], chr[c][indx - v1 - h3]);
nev = median(chr[c][indx - v1 + h1], chr[c][indx - v3 + h1], chr[c][indx - v1 + h3]);
swv = median(chr[c][indx + v1 - h1], chr[c][indx + v3 - h1], chr[c][indx + v1 - h3]);
sev = median(chr[c][indx + v1 + h1], chr[c][indx + v3 + h1], chr[c][indx + v1 + h3]);
//Interpolate chrominance: R@B and B@R
chr[c][indx] = (nwg * nwv + neg * nev + swg * swv + seg * sev) / (nwg + neg + swg + seg);
}
#ifdef _OPENMP
#pragma omp single
#endif
{
if (plistener) {
plistener->setProgress (0.52);
}
}
#ifdef _OPENMP
#pragma omp for
#endif
for (int row = 8; row < height - 7; row += 2)
for (int col = 7 + (FC(row, 1) & 1), indx = row * width + col, c = 1 - FC(row, col) / 2; col < width - 7; col += 2, indx += 2) {
//NW,NE,SW,SE Gradients
nwg = 1.0f / (eps + fabsf(chr[c][indx - v1 - h1] - chr[c][indx - v3 - h3]) + fabsf(chr[c][indx + v1 + h1] - chr[c][indx - v3 - h3]));
neg = 1.0f / (eps + fabsf(chr[c][indx - v1 + h1] - chr[c][indx - v3 + h3]) + fabsf(chr[c][indx + v1 - h1] - chr[c][indx - v3 + h3]));
swg = 1.0f / (eps + fabsf(chr[c][indx + v1 - h1] - chr[c][indx + v3 + h3]) + fabsf(chr[c][indx - v1 + h1] - chr[c][indx + v3 - h3]));
seg = 1.0f / (eps + fabsf(chr[c][indx + v1 + h1] - chr[c][indx + v3 - h3]) + fabsf(chr[c][indx - v1 - h1] - chr[c][indx + v3 + h3]));
//Limit NW,NE,SW,SE Color differences
nwv = median(chr[c][indx - v1 - h1], chr[c][indx - v3 - h1], chr[c][indx - v1 - h3]);
nev = median(chr[c][indx - v1 + h1], chr[c][indx - v3 + h1], chr[c][indx - v1 + h3]);
swv = median(chr[c][indx + v1 - h1], chr[c][indx + v3 - h1], chr[c][indx + v1 - h3]);
sev = median(chr[c][indx + v1 + h1], chr[c][indx + v3 + h1], chr[c][indx + v1 + h3]);
//Interpolate chrominance: R@B and B@R
chr[c][indx] = (nwg * nwv + neg * nev + swg * swv + seg * sev) / (nwg + neg + swg + seg);
}
#ifdef _OPENMP
#pragma omp single
#endif
{
if (plistener) {
plistener->setProgress (0.65);
}
}
#ifdef _OPENMP
#pragma omp for
#endif
for (int row = 7; row < height - 7; row++)
for (int col = 7 + (FC(row, 0) & 1), indx = row * width + col; col < width - 7; col += 2, indx += 2) {
//N,E,W,S Gradients
ng = 1.0f / (eps + fabsf(chr[0][indx - v1] - chr[0][indx - v3]) + fabsf(chr[0][indx + v1] - chr[0][indx - v3]));
eg = 1.0f / (eps + fabsf(chr[0][indx + h1] - chr[0][indx + h3]) + fabsf(chr[0][indx - h1] - chr[0][indx + h3]));
wg = 1.0f / (eps + fabsf(chr[0][indx - h1] - chr[0][indx - h3]) + fabsf(chr[0][indx + h1] - chr[0][indx - h3]));
sg = 1.0f / (eps + fabsf(chr[0][indx + v1] - chr[0][indx + v3]) + fabsf(chr[0][indx - v1] - chr[0][indx + v3]));
//Interpolate chrominance: R@G and B@G
chr[0][indx] = ((ng * chr[0][indx - v1] + eg * chr[0][indx + h1] + wg * chr[0][indx - h1] + sg * chr[0][indx + v1]) / (ng + eg + wg + sg));
}
#ifdef _OPENMP
#pragma omp single
#endif
{
if (plistener) {
plistener->setProgress (0.78);
}
}
#ifdef _OPENMP
#pragma omp for
#endif
for (int row = 7; row < height - 7; row++)
for (int col = 7 + (FC(row, 0) & 1), indx = row * width + col; col < width - 7; col += 2, indx += 2) {
//N,E,W,S Gradients
ng = 1.0f / (eps + fabsf(chr[1][indx - v1] - chr[1][indx - v3]) + fabsf(chr[1][indx + v1] - chr[1][indx - v3]));
eg = 1.0f / (eps + fabsf(chr[1][indx + h1] - chr[1][indx + h3]) + fabsf(chr[1][indx - h1] - chr[1][indx + h3]));
wg = 1.0f / (eps + fabsf(chr[1][indx - h1] - chr[1][indx - h3]) + fabsf(chr[1][indx + h1] - chr[1][indx - h3]));
sg = 1.0f / (eps + fabsf(chr[1][indx + v1] - chr[1][indx + v3]) + fabsf(chr[1][indx - v1] - chr[1][indx + v3]));
//Interpolate chrominance: R@G and B@G
chr[1][indx] = ((ng * chr[1][indx - v1] + eg * chr[1][indx + h1] + wg * chr[1][indx - h1] + sg * chr[1][indx + v1]) / (ng + eg + wg + sg));
}
#ifdef _OPENMP
#pragma omp single
#endif
{
if (plistener) {
plistener->setProgress (0.91);
}
//Interpolate borders
// border_interpolate2(7, rgb);
}
/*
#ifdef _OPENMP
#pragma omp for
#endif
for (int row=0; row < height; row++) //borders
for (int col=0; col < width; col++) {
if (col==7 && row >= 7 && row < height-7)
col = width-7;
int indxc=row*width+col;
red [row][col] = rgb[indxc][0];
green[row][col] = rgb[indxc][1];
blue [row][col] = rgb[indxc][2];
}
*/
#ifdef _OPENMP
#pragma omp for
#endif
for(int row = 7; row < height - 7; row++)
for(int col = 7, indx = row * width + col; col < width - 7; col++, indx++) {
red [row][col] = CLIP(rgb[1][indx] - 65535.f * chr[0][indx]);
green[row][col] = CLIP(rgb[1][indx]);
blue [row][col] = CLIP(rgb[1][indx] - 65535.f * chr[1][indx]);
}
}// End of parallelization
border_interpolate2(winw, winh, 8, rawData, red, green, blue);
if (plistener) {
plistener->setProgress (1.0);
}
free(chrarray);
free(rgbarray);
free(vdif);
free(hdif);
}
#endif
void RawImageSource::nodemosaic(bool bw)
{
red(W, H);
green(W, H);
blue(W, H);
#ifdef _OPENMP
#pragma omp parallel for
#endif
for (int i = 0; i < H; i++) {
for (int j = 0; j < W; j++) {
if (bw) {
red[i][j] = green[i][j] = blue[i][j] = rawData[i][j];
} else if(ri->getSensorType() != ST_FUJI_XTRANS) {
switch( FC(i, j)) {
case 0:
red[i][j] = rawData[i][j];
green[i][j] = blue[i][j] = 0;
break;
case 1:
green[i][j] = rawData[i][j];
red[i][j] = blue[i][j] = 0;
break;
case 2:
blue[i][j] = rawData[i][j];
red[i][j] = green[i][j] = 0;
break;
}
} else {
switch( ri->XTRANSFC(i, j)) {
case 0:
red[i][j] = rawData[i][j];
green[i][j] = blue[i][j] = 0;
break;
case 1:
green[i][j] = rawData[i][j];
red[i][j] = blue[i][j] = 0;
break;
case 2:
blue[i][j] = rawData[i][j];
red[i][j] = green[i][j] = 0;
break;
}
}
}
}
}
/*
Refinement based on EECI demosaicing algorithm by L. Chang and Y.P. Tan
Paul Lee
Adapted for RawTherapee - Jacques Desmis 04/2013
*/
#ifdef __SSE2__
#define CLIPV(a) vclampf(a,ZEROV,c65535v)
#endif
void RawImageSource::refinement(int PassCount)
{
MyTime t1e, t2e;
t1e.set();
int width = W;
int height = H;
int w1 = width;
int w2 = 2 * w1;
if (plistener) {
plistener->setProgressStr (M("TP_RAW_DMETHOD_PROGRESSBAR_REFINE"));
}
array2D<float> *rgb[3];
rgb[0] = &red;
rgb[1] = &green;
rgb[2] = &blue;
for (int b = 0; b < PassCount; b++) {
if (plistener) {
plistener->setProgress ((float)b / PassCount);
}
#ifdef _OPENMP
#pragma omp parallel
#endif
{
float *pix[3];
/* Reinforce interpolated green pixels on RED/BLUE pixel locations */
#ifdef _OPENMP
#pragma omp for
#endif
for (int row = 2; row < height - 2; row++) {
int col = 2 + (FC(row, 2) & 1);
int c = FC(row, col);
#ifdef __SSE2__
__m128 dLv, dRv, dUv, dDv, v0v;
__m128 onev = _mm_set1_ps(1.f);
__m128 zd5v = _mm_set1_ps(0.5f);
__m128 c65535v = _mm_set1_ps(65535.f);
for (; col < width - 8; col += 8) {
int indx = row * width + col;
pix[c] = (float*)(*rgb[c]) + indx;
pix[1] = (float*)(*rgb[1]) + indx;
dLv = onev / (onev + vabsf(LC2VFU(pix[c][ -2]) - LC2VFU(pix[c][0])) + vabsf(LC2VFU(pix[1][ 1]) - LC2VFU(pix[1][ -1])));
dRv = onev / (onev + vabsf(LC2VFU(pix[c][ 2]) - LC2VFU(pix[c][0])) + vabsf(LC2VFU(pix[1][ 1]) - LC2VFU(pix[1][ -1])));
dUv = onev / (onev + vabsf(LC2VFU(pix[c][-w2]) - LC2VFU(pix[c][0])) + vabsf(LC2VFU(pix[1][w1]) - LC2VFU(pix[1][-w1])));
dDv = onev / (onev + vabsf(LC2VFU(pix[c][ w2]) - LC2VFU(pix[c][0])) + vabsf(LC2VFU(pix[1][w1]) - LC2VFU(pix[1][-w1])));
v0v = CLIPV(LC2VFU(pix[c][0]) + zd5v + ((LC2VFU(pix[1][-1]) - LC2VFU(pix[c][-1])) * dLv + (LC2VFU(pix[1][1]) - LC2VFU(pix[c][1])) * dRv + (LC2VFU(pix[1][-w1]) - LC2VFU(pix[c][-w1])) * dUv + (LC2VFU(pix[1][w1]) - LC2VFU(pix[c][w1])) * dDv ) / (dLv + dRv + dUv + dDv));
STC2VFU(pix[1][0], v0v);
}
#endif
for (; col < width - 2; col += 2) {
int indx = row * width + col;
pix[c] = (float*)(*rgb[c]) + indx;
pix[1] = (float*)(*rgb[1]) + indx;
float dL = 1.f / (1.f + fabsf(pix[c][ -2] - pix[c][0]) + fabsf(pix[1][ 1] - pix[1][ -1]));
float dR = 1.f / (1.f + fabsf(pix[c][ 2] - pix[c][0]) + fabsf(pix[1][ 1] - pix[1][ -1]));
float dU = 1.f / (1.f + fabsf(pix[c][-w2] - pix[c][0]) + fabsf(pix[1][w1] - pix[1][-w1]));
float dD = 1.f / (1.f + fabsf(pix[c][ w2] - pix[c][0]) + fabsf(pix[1][w1] - pix[1][-w1]));
float v0 = (pix[c][0] + 0.5f + ((pix[1][ -1] - pix[c][ -1]) * dL + (pix[1][ 1] - pix[c][ 1]) * dR + (pix[1][-w1] - pix[c][-w1]) * dU + (pix[1][ w1] - pix[c][ w1]) * dD ) / (dL + dR + dU + dD));
pix[1][0] = CLIP(v0);
}
}
/* Reinforce interpolated red/blue pixels on GREEN pixel locations */
#ifdef _OPENMP
#pragma omp for
#endif
for (int row = 2; row < height - 2; row++) {
int col = 2 + (FC(row, 3) & 1);
int c = FC(row, col + 1);
#ifdef __SSE2__
__m128 dLv, dRv, dUv, dDv, v0v;
__m128 onev = _mm_set1_ps(1.f);
__m128 zd5v = _mm_set1_ps(0.5f);
__m128 c65535v = _mm_set1_ps(65535.f);
for (; col < width - 8; col += 8) {
int indx = row * width + col;
pix[1] = (float*)(*rgb[1]) + indx;
for (int i = 0; i < 2; c = 2 - c, i++) {
pix[c] = (float*)(*rgb[c]) + indx;
dLv = onev / (onev + vabsf(LC2VFU(pix[1][ -2]) - LC2VFU(pix[1][0])) + vabsf(LC2VFU(pix[c][ 1]) - LC2VFU(pix[c][ -1])));
dRv = onev / (onev + vabsf(LC2VFU(pix[1][ 2]) - LC2VFU(pix[1][0])) + vabsf(LC2VFU(pix[c][ 1]) - LC2VFU(pix[c][ -1])));
dUv = onev / (onev + vabsf(LC2VFU(pix[1][-w2]) - LC2VFU(pix[1][0])) + vabsf(LC2VFU(pix[c][w1]) - LC2VFU(pix[c][-w1])));
dDv = onev / (onev + vabsf(LC2VFU(pix[1][ w2]) - LC2VFU(pix[1][0])) + vabsf(LC2VFU(pix[c][w1]) - LC2VFU(pix[c][-w1])));
v0v = CLIPV(LC2VFU(pix[1][0]) + zd5v - ((LC2VFU(pix[1][-1]) - LC2VFU(pix[c][-1])) * dLv + (LC2VFU(pix[1][1]) - LC2VFU(pix[c][1])) * dRv + (LC2VFU(pix[1][-w1]) - LC2VFU(pix[c][-w1])) * dUv + (LC2VFU(pix[1][w1]) - LC2VFU(pix[c][w1])) * dDv ) / (dLv + dRv + dUv + dDv));
STC2VFU(pix[c][0], v0v);
}
}
#endif
for (; col < width - 2; col += 2) {
int indx = row * width + col;
pix[1] = (float*)(*rgb[1]) + indx;
for (int i = 0; i < 2; c = 2 - c, i++) {
pix[c] = (float*)(*rgb[c]) + indx;
float dL = 1.f / (1.f + fabsf(pix[1][ -2] - pix[1][0]) + fabsf(pix[c][ 1] - pix[c][ -1]));
float dR = 1.f / (1.f + fabsf(pix[1][ 2] - pix[1][0]) + fabsf(pix[c][ 1] - pix[c][ -1]));
float dU = 1.f / (1.f + fabsf(pix[1][-w2] - pix[1][0]) + fabsf(pix[c][w1] - pix[c][-w1]));
float dD = 1.f / (1.f + fabsf(pix[1][ w2] - pix[1][0]) + fabsf(pix[c][w1] - pix[c][-w1]));
float v0 = (pix[1][0] + 0.5f - ((pix[1][ -1] - pix[c][ -1]) * dL + (pix[1][ 1] - pix[c][ 1]) * dR + (pix[1][-w1] - pix[c][-w1]) * dU + (pix[1][ w1] - pix[c][ w1]) * dD ) / (dL + dR + dU + dD));
pix[c][0] = CLIP(v0);
}
}
}
/* Reinforce integrated red/blue pixels on BLUE/RED pixel locations */
#ifdef _OPENMP
#pragma omp for
#endif
for (int row = 2; row < height - 2; row++) {
int col = 2 + (FC(row, 2) & 1);
int c = 2 - FC(row, col);
#ifdef __SSE2__
__m128 dLv, dRv, dUv, dDv, v0v;
__m128 onev = _mm_set1_ps(1.f);
__m128 zd5v = _mm_set1_ps(0.5f);
__m128 c65535v = _mm_set1_ps(65535.f);
for (; col < width - 8; col += 8) {
int indx = row * width + col;
pix[0] = (float*)(*rgb[0]) + indx;
pix[1] = (float*)(*rgb[1]) + indx;
pix[2] = (float*)(*rgb[2]) + indx;
int d = 2 - c;
dLv = onev / (onev + vabsf(LC2VFU(pix[d][ -2]) - LC2VFU(pix[d][0])) + vabsf(LC2VFU(pix[1][ 1]) - LC2VFU(pix[1][ -1])));
dRv = onev / (onev + vabsf(LC2VFU(pix[d][ 2]) - LC2VFU(pix[d][0])) + vabsf(LC2VFU(pix[1][ 1]) - LC2VFU(pix[1][ -1])));
dUv = onev / (onev + vabsf(LC2VFU(pix[d][-w2]) - LC2VFU(pix[d][0])) + vabsf(LC2VFU(pix[1][w1]) - LC2VFU(pix[1][-w1])));
dDv = onev / (onev + vabsf(LC2VFU(pix[d][ w2]) - LC2VFU(pix[d][0])) + vabsf(LC2VFU(pix[1][w1]) - LC2VFU(pix[1][-w1])));
v0v = CLIPV(LC2VFU(pix[1][0]) + zd5v - ((LC2VFU(pix[1][-1]) - LC2VFU(pix[c][-1])) * dLv + (LC2VFU(pix[1][1]) - LC2VFU(pix[c][1])) * dRv + (LC2VFU(pix[1][-w1]) - LC2VFU(pix[c][-w1])) * dUv + (LC2VFU(pix[1][w1]) - LC2VFU(pix[c][w1])) * dDv ) / (dLv + dRv + dUv + dDv));
STC2VFU(pix[c][0], v0v);
}
#endif
for (; col < width - 2; col += 2) {
int indx = row * width + col;
pix[0] = (float*)(*rgb[0]) + indx;
pix[1] = (float*)(*rgb[1]) + indx;
pix[2] = (float*)(*rgb[2]) + indx;
int d = 2 - c;
float dL = 1.f / (1.f + fabsf(pix[d][ -2] - pix[d][0]) + fabsf(pix[1][ 1] - pix[1][ -1]));
float dR = 1.f / (1.f + fabsf(pix[d][ 2] - pix[d][0]) + fabsf(pix[1][ 1] - pix[1][ -1]));
float dU = 1.f / (1.f + fabsf(pix[d][-w2] - pix[d][0]) + fabsf(pix[1][w1] - pix[1][-w1]));
float dD = 1.f / (1.f + fabsf(pix[d][ w2] - pix[d][0]) + fabsf(pix[1][w1] - pix[1][-w1]));
float v0 = (pix[1][0] + 0.5f - ((pix[1][ -1] - pix[c][ -1]) * dL + (pix[1][ 1] - pix[c][ 1]) * dR + (pix[1][-w1] - pix[c][-w1]) * dU + (pix[1][ w1] - pix[c][ w1]) * dD ) / (dL + dR + dU + dD));
pix[c][0] = CLIP(v0);
}
}
} // end parallel
}
t2e.set();
if (settings->verbose) {
printf("Refinement Lee %d usec\n", t2e.etime(t1e));
}
}
#ifdef __SSE2__
#undef CLIPV
#endif
// Refinement based on EECI demozaicing algorithm by L. Chang and Y.P. Tan
// from "Lassus" : Luis Sanz Rodriguez, adapted by Jacques Desmis - JDC - and Oliver Duis for RawTherapee
// increases the signal to noise ratio (PSNR) # +1 to +2 dB : tested with Dcraw :
// eg: Lighthouse + AMaZE : without refinement:39.96 dB, with refinement:41.86 dB
// reduce color artifacts, improves the interpolation
// but it's relatively slow
//
// Should be DISABLED if it decreases image quality by increases some image noise and generates blocky edges
void RawImageSource::refinement_lassus(int PassCount)
{
// const int PassCount=1;
// if (settings->verbose) printf("Refinement\n");
MyTime t1e, t2e;
t1e.set();
int u = W, v = 2 * u, w = 3 * u, x = 4 * u, y = 5 * u;
float (*image)[3];
image = (float(*)[3]) calloc(static_cast<size_t>(W) * H, sizeof * image);
#ifdef _OPENMP
#pragma omp parallel shared(image)
#endif
{
// convert red, blue, green to image
#ifdef _OPENMP
#pragma omp for
#endif
for (int i = 0; i < H; i++) {
for (int j = 0; j < W; j++) {
image[i * W + j][0] = red [i][j];
image[i * W + j][1] = green[i][j];
image[i * W + j][2] = blue [i][j];
}
}
for (int b = 0; b < PassCount; b++) {
if (plistener) {
plistener->setProgressStr (M("TP_RAW_DMETHOD_PROGRESSBAR_REFINE"));
plistener->setProgress ((float)b / PassCount);
}
// Reinforce interpolated green pixels on RED/BLUE pixel locations
#ifdef _OPENMP
#pragma omp for
#endif
for (int row = 6; row < H - 6; row++) {
for (int col = 6 + (FC(row, 2) & 1), c = FC(row, col); col < W - 6; col += 2) {
float (*pix)[3] = image + row * W + col;
// Cubic Spline Interpolation by Li and Randhawa, modified by Luis Sanz Rodriguez
float f[4];
f[0] = 1.0f / (1.0f + xmul2f(fabs(x1125(pix[-v][c]) - x0875(pix[0][c]) - x0250(pix[-x][c]))) + fabs(x0875(pix[u][1]) - x1125(pix[-u][1]) + x0250(pix[-w][1])) + fabs(x0875(pix[-w][1]) - x1125(pix[-u][1]) + x0250(pix[-y][1])));
f[1] = 1.0f / (1.0f + xmul2f(fabs(x1125(pix[+2][c]) - x0875(pix[0][c]) - x0250(pix[+4][c]))) + fabs(x0875(pix[1][1]) - x1125(pix[-1][1]) + x0250(pix[+3][1])) + fabs(x0875(pix[+3][1]) - x1125(pix[+1][1]) + x0250(pix[+5][1])));
f[2] = 1.0f / (1.0f + xmul2f(fabs(x1125(pix[-2][c]) - x0875(pix[0][c]) - x0250(pix[-4][c]))) + fabs(x0875(pix[1][1]) - x1125(pix[-1][1]) + x0250(pix[-3][1])) + fabs(x0875(pix[-3][1]) - x1125(pix[-1][1]) + x0250(pix[-5][1])));
f[3] = 1.0f / (1.0f + xmul2f(fabs(x1125(pix[+v][c]) - x0875(pix[0][c]) - x0250(pix[+x][c]))) + fabs(x0875(pix[u][1]) - x1125(pix[-u][1]) + x0250(pix[+w][1])) + fabs(x0875(pix[+w][1]) - x1125(pix[+u][1]) + x0250(pix[+y][1])));
float g[4];//CLIREF avoid overflow
g[0] = pix[0][c] + (x0875(CLIREF(pix[-u][1] - pix[-u][c])) + x0125(CLIREF(pix[+u][1] - pix[+u][c])));
g[1] = pix[0][c] + (x0875(CLIREF(pix[+1][1] - pix[+1][c])) + x0125(CLIREF(pix[-1][1] - pix[-1][c])));
g[2] = pix[0][c] + (x0875(CLIREF(pix[-1][1] - pix[-1][c])) + x0125(CLIREF(pix[+1][1] - pix[+1][c])));
g[3] = pix[0][c] + (x0875(CLIREF(pix[+u][1] - pix[+u][c])) + x0125(CLIREF(pix[-u][1] - pix[-u][c])));
pix[0][1] = (f[0] * g[0] + f[1] * g[1] + f[2] * g[2] + f[3] * g[3]) / (f[0] + f[1] + f[2] + f[3]);
}
}
// Reinforce interpolated red/blue pixels on GREEN pixel locations
#ifdef _OPENMP
#pragma omp for
#endif
for (int row = 6; row < H - 6; row++) {
for (int col = 6 + (FC(row, 3) & 1), c = FC(row, col + 1); col < W - 6; col += 2) {
float (*pix)[3] = image + row * W + col;
for (int i = 0; i < 2; c = 2 - c, i++) {
float f[4];
f[0] = 1.0f / (1.0f + xmul2f(fabs(x0875(pix[-v][1]) - x1125(pix[0][1]) + x0250(pix[-x][1]))) + fabs(pix[u] [c] - pix[-u][c]) + fabs(pix[-w][c] - pix[-u][c]));
f[1] = 1.0f / (1.0f + xmul2f(fabs(x0875(pix[+2][1]) - x1125(pix[0][1]) + x0250(pix[+4][1]))) + fabs(pix[+1][c] - pix[-1][c]) + fabs(pix[+3][c] - pix[+1][c]));
f[2] = 1.0f / (1.0f + xmul2f(fabs(x0875(pix[-2][1]) - x1125(pix[0][1]) + x0250(pix[-4][1]))) + fabs(pix[+1][c] - pix[-1][c]) + fabs(pix[-3][c] - pix[-1][c]));
f[3] = 1.0f / (1.0f + xmul2f(fabs(x0875(pix[+v][1]) - x1125(pix[0][1]) + x0250(pix[+x][1]))) + fabs(pix[u] [c] - pix[-u][c]) + fabs(pix[+w][c] - pix[+u][c]));
float g[5];//CLIREF avoid overflow
g[0] = CLIREF(pix[-u][1] - pix[-u][c]);
g[1] = CLIREF(pix[+1][1] - pix[+1][c]);
g[2] = CLIREF(pix[-1][1] - pix[-1][c]);
g[3] = CLIREF(pix[+u][1] - pix[+u][c]);
g[4] = ((f[0] * g[0] + f[1] * g[1] + f[2] * g[2] + f[3] * g[3]) / (f[0] + f[1] + f[2] + f[3]));
pix[0][c] = pix[0][1] - (0.65f * g[4] + 0.35f * CLIREF(pix[0][1] - pix[0][c]));
}
}
}
// Reinforce integrated red/blue pixels on BLUE/RED pixel locations
#ifdef _OPENMP
#pragma omp for
#endif
for (int row = 6; row < H - 6; row++) {
for (int col = 6 + (FC(row, 2) & 1), c = 2 - FC(row, col), d = 2 - c; col < W - 6; col += 2) {
float (*pix)[3] = image + row * W + col;
float f[4];
f[0] = 1.0f / (1.0f + xmul2f(fabs(x1125(pix[-v][d]) - x0875(pix[0][d]) - x0250(pix[-x][d]))) + fabs(x0875(pix[u][1]) - x1125(pix[-u][1]) + x0250(pix[-w][1])) + fabs(x0875(pix[-w][1]) - x1125(pix[-u][1]) + x0250(pix[-y][1])));
f[1] = 1.0f / (1.0f + xmul2f(fabs(x1125(pix[+2][d]) - x0875(pix[0][d]) - x0250(pix[+4][d]))) + fabs(x0875(pix[1][1]) - x1125(pix[-1][1]) + x0250(pix[+3][1])) + fabs(x0875(pix[+3][1]) - x1125(pix[+1][1]) + x0250(pix[+5][1])));
f[2] = 1.0f / (1.0f + xmul2f(fabs(x1125(pix[-2][d]) - x0875(pix[0][d]) - x0250(pix[-4][d]))) + fabs(x0875(pix[1][1]) - x1125(pix[-1][1]) + x0250(pix[-3][1])) + fabs(x0875(pix[-3][1]) - x1125(pix[-1][1]) + x0250(pix[-5][1])));
f[3] = 1.0f / (1.0f + xmul2f(fabs(x1125(pix[+v][d]) - x0875(pix[0][d]) - x0250(pix[+x][d]))) + fabs(x0875(pix[u][1]) - x1125(pix[-u][1]) + x0250(pix[+w][1])) + fabs(x0875(pix[+w][1]) - x1125(pix[+u][1]) + x0250(pix[+y][1])));
float g[5];
g[0] = (x0875((pix[-u][1] - pix[-u][c])) + x0125((pix[-v][1] - pix[-v][c])));
g[1] = (x0875((pix[+1][1] - pix[+1][c])) + x0125((pix[+2][1] - pix[+2][c])));
g[2] = (x0875((pix[-1][1] - pix[-1][c])) + x0125((pix[-2][1] - pix[-2][c])));
g[3] = (x0875((pix[+u][1] - pix[+u][c])) + x0125((pix[+v][1] - pix[+v][c])));
g[4] = (f[0] * g[0] + f[1] * g[1] + f[2] * g[2] + f[3] * g[3]) / (f[0] + f[1] + f[2] + f[3]);
const std::array<float, 9> p = {
pix[-u - 1][1] - pix[-u - 1][c],
pix[-u + 0][1] - pix[-u + 0][c],
pix[-u + 1][1] - pix[-u + 1][c],
pix[+0 - 1][1] - pix[+0 - 1][c],
pix[+0 + 0][1] - pix[+0 + 0][c],
pix[+0 + 1][1] - pix[+0 + 1][c],
pix[+u - 1][1] - pix[+u - 1][c],
pix[+u + 0][1] - pix[+u + 0][c],
pix[+u + 1][1] - pix[+u + 1][c]
};
const float med = median(p);
pix[0][c] = LIM(pix[0][1] - (1.30f * g[4] - 0.30f * (pix[0][1] - pix[0][c])), 0.99f * (pix[0][1] - med), 1.01f * (pix[0][1] - med));
}
}
}
// put modified values to red, green, blue
#ifdef _OPENMP
#pragma omp for
#endif
for (int i = 0; i < H; i++) {
for (int j = 0; j < W; j++) {
red [i][j] = image[i * W + j][0];
green[i][j] = image[i * W + j][1];
blue [i][j] = image[i * W + j][2];
}
}
}
free(image);
t2e.set();
if (settings->verbose) {
printf("Refinement Lassus %d usec\n", t2e.etime(t1e));
}
}
/*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are
* met:
*
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions 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.
* * Neither the name of the author nor the names of its
* contributors may 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 COPYRIGHT
* OWNER 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.
*/
// If you want to use the code, you need to display name of the original authors in
// your software!
/* DCB demosaicing by Jacek Gozdz (cuniek@kft.umcs.lublin.pl)
* the code is open source (BSD licence)
*/
#define TILESIZE 192
#define TILEBORDER 10
#define CACHESIZE (TILESIZE+2*TILEBORDER)
inline void RawImageSource::dcb_initTileLimits(int &colMin, int &rowMin, int &colMax, int &rowMax, int x0, int y0, int border)
{
rowMin = border;
colMin = border;
rowMax = CACHESIZE - border;
colMax = CACHESIZE - border;
if(!y0 ) {
rowMin = TILEBORDER + border;
}
if(!x0 ) {
colMin = TILEBORDER + border;
}
if( y0 + TILESIZE + TILEBORDER >= H - border) {
rowMax = TILEBORDER + H - border - y0;
}
if( x0 + TILESIZE + TILEBORDER >= W - border) {
colMax = TILEBORDER + W - border - x0;
}
}
void RawImageSource::fill_raw( float (*cache )[3], int x0, int y0, float** rawData)
{
int rowMin, colMin, rowMax, colMax;
dcb_initTileLimits(colMin, rowMin, colMax, rowMax, x0, y0, 0);
for (int row = rowMin, y = y0 - TILEBORDER + rowMin; row < rowMax; row++, y++)
for (int col = colMin, x = x0 - TILEBORDER + colMin, indx = row * CACHESIZE + col; col < colMax; col++, x++, indx++) {
cache[indx][fc(y, x)] = rawData[y][x];
}
}
void RawImageSource::fill_border( float (*cache )[3], int border, int x0, int y0)
{
unsigned f;
float sum[8];
constexpr unsigned int colors = 3; // used in FORCC
for (int row = y0; row < y0 + TILESIZE + TILEBORDER && row < H; row++) {
for (int col = x0; col < x0 + TILESIZE + TILEBORDER && col < W; col++) {
if (col >= border && col < W - border && row >= border && row < H - border) {
col = W - border;
if(col >= x0 + TILESIZE + TILEBORDER ) {
break;
}
}
memset(sum, 0, sizeof sum);
for (int y = row - 1; y != row + 2; y++)
for (int x = col - 1; x != col + 2; x++)
if (y < H && y < y0 + TILESIZE + TILEBORDER && x < W && x < x0 + TILESIZE + TILEBORDER) {
f = fc(y, x);
sum[f] += cache[(y - y0 + TILEBORDER) * CACHESIZE + TILEBORDER + x - x0][f];
sum[f + 4]++;
}
f = fc(row, col);
FORCC
if (c != f && sum[c + 4] > 0) {
cache[(row - y0 + TILEBORDER) * CACHESIZE + TILEBORDER + col - x0][c] = sum[c] / sum[c + 4];
}
}
}
}
// saves red and blue
// change buffer[3] -> buffer[2], possibly to buffer[1] if split
// into two loops, one for R and another for B, could also be smaller because
// there is no need for green pixels pass
// this would decrease the amount of needed memory
// from megapixels*2 records to megapixels*0.5
// also don't know if float is needed as data is 1-65536 integer (I believe!!)
// comment from Ingo: float is needed because rawdata in rt is float
void RawImageSource::copy_to_buffer( float (*buffer)[2], float (*image)[3])
{
for (int indx = 0; indx < CACHESIZE * CACHESIZE; indx++) {
buffer[indx][0] = image[indx][0]; //R
buffer[indx][1] = image[indx][2]; //B
}
}
// restores red and blue
// other comments like in copy_to_buffer
void RawImageSource::restore_from_buffer(float (*image)[3], float (*buffer)[2])
{
for (int indx = 0; indx < CACHESIZE * CACHESIZE; indx++) {
image[indx][0] = buffer[indx][0]; //R
image[indx][2] = buffer[indx][1]; //B
}
}
// First pass green interpolation
// remove entirely: bufferH and bufferV
void RawImageSource::dcb_hid(float (*image)[3], int x0, int y0)
{
const int u = CACHESIZE;
int rowMin, colMin, rowMax, colMax;
dcb_initTileLimits(colMin, rowMin, colMax, rowMax, x0, y0, 2);
// simple green bilinear in R and B pixels
for (int row = rowMin; row < rowMax; row++)
for (int col = colMin + (FC(y0 - TILEBORDER + row, x0 - TILEBORDER + colMin) & 1), indx = row * CACHESIZE + col; col < colMax; col += 2, indx += 2) {
assert(indx - u - 1 >= 0 && indx + u + 1 < u * u);
image[indx][1] = 0.25*(image[indx-1][1]+image[indx+1][1]+image[indx-u][1]+image[indx+u][1]);
}
}
// missing colours are interpolated
void RawImageSource::dcb_color(float (*image)[3], int x0, int y0)
{
const int u = CACHESIZE;
int rowMin, colMin, rowMax, colMax;
dcb_initTileLimits(colMin, rowMin, colMax, rowMax, x0, y0, 1);
// red in blue pixel, blue in red pixel
for (int row = rowMin; row < rowMax; row++)
for (int col = colMin + (FC(y0 - TILEBORDER + row, x0 - TILEBORDER + colMin) & 1), indx = row * CACHESIZE + col, c = 2 - FC(y0 - TILEBORDER + row, x0 - TILEBORDER + col); col < colMax; col += 2, indx += 2) {
assert(indx >= 0 && indx < u * u && c >= 0 && c < 4);
//Jacek comment: one multiplication less
image[indx][c] = image[indx][1] +
( image[indx + u + 1][c] + image[indx + u - 1][c] + image[indx - u + 1][c] + image[indx - u - 1][c]
- (image[indx + u + 1][1] + image[indx + u - 1][1] + image[indx - u + 1][1] + image[indx - u - 1][1]) ) * 0.25f;
/* original
image[indx][c] = ( 4.f * image[indx][1]
- image[indx + u + 1][1] - image[indx + u - 1][1] - image[indx - u + 1][1] - image[indx - u - 1][1]
+ image[indx + u + 1][c] + image[indx + u - 1][c] + image[indx - u + 1][c] + image[indx - u - 1][c] ) * 0.25f;
*/
}
// red or blue in green pixels
for (int row = rowMin; row < rowMax; row++)
for (int col = colMin + (FC(y0 - TILEBORDER + row, x0 - TILEBORDER + colMin + 1) & 1), indx = row * CACHESIZE + col, c = FC(y0 - TILEBORDER + row, x0 - TILEBORDER + col + 1), d = 2 - c; col < colMax; col += 2, indx += 2) {
assert(indx >= 0 && indx < u * u && c >= 0 && c < 4);
//Jacek comment: two multiplications (in total) less
image[indx][c] = image[indx][1] + (image[indx + 1][c] + image[indx - 1][c] - (image[indx + 1][1] + image[indx - 1][1])) * 0.5f;
image[indx][d] = image[indx][1] + (image[indx + u][d] + image[indx - u][d] - (image[indx + u][1] + image[indx - u][1])) * 0.5f;
/* original
image[indx][c] = (2.f * image[indx][1] - image[indx + 1][1] - image[indx - 1][1] + image[indx + 1][c] + image[indx - 1][c]) * 0.5f;
image[indx][d] = (2.f * image[indx][1] - image[indx + u][1] - image[indx - u][1] + image[indx + u][d] + image[indx - u][d]) * 0.5f;
*/
}
}
// green correction
void RawImageSource::dcb_hid2(float (*image)[3], int x0, int y0)
{
const int v = 2 * CACHESIZE;
int rowMin, colMin, rowMax, colMax;
dcb_initTileLimits(colMin, rowMin, colMax, rowMax, x0, y0, 2);
for (int row = rowMin; row < rowMax; row++) {
for (int col = colMin + (FC(y0 - TILEBORDER + row, x0 - TILEBORDER + colMin) & 1), indx = row * CACHESIZE + col, c = FC(y0 - TILEBORDER + row, x0 - TILEBORDER + col); col < colMax; col += 2, indx += 2) {
assert(indx - v >= 0 && indx + v < CACHESIZE * CACHESIZE);
//Jacek comment: one multiplication less
image[indx][1] = image[indx][c] +
(image[indx + v][1] + image[indx - v][1] + image[indx - 2][1] + image[indx + 2][1]
- (image[indx + v][c] + image[indx - v][c] + image[indx - 2][c] + image[indx + 2][c])) * 0.25f;
/* original
image[indx][1] = (image[indx + v][1] + image[indx - v][1] + image[indx - 2][1] + image[indx + 2][1]) * 0.25f +
image[indx][c] - ( image[indx + v][c] + image[indx - v][c] + image[indx - 2][c] + image[indx + 2][c]) * 0.25f;
*/
}
}
}
// green is used to create
// an interpolation direction map
// 1 = vertical
// 0 = horizontal
// saved in image[][3]
// seems at least 2 persons implemented some code, as this one has different coding style, could be unified
// I don't know if *pix is faster than a loop working on image[] directly
void RawImageSource::dcb_map(float (*image)[3], uint8_t *map, int x0, int y0)
{
const int u = 3 * CACHESIZE;
int rowMin, colMin, rowMax, colMax;
dcb_initTileLimits(colMin, rowMin, colMax, rowMax, x0, y0, 2);
for (int row = rowMin; row < rowMax; row++) {
for (int col = colMin, indx = row * CACHESIZE + col; col < colMax; col++, indx++) {
float *pix = &(image[indx][1]);
assert(indx >= 0 && indx < u * u);
// comparing 4 * a to (b+c+d+e) instead of a to (b+c+d+e)/4 is faster because divisions are slow
if ( 4 * (*pix) > ( (pix[-3] + pix[+3]) + (pix[-u] + pix[+u])) ) {
map[indx] = ((min(pix[-3], pix[+3]) + (pix[-3] + pix[+3]) ) < (min(pix[-u], pix[+u]) + (pix[-u] + pix[+u])));
} else {
map[indx] = ((max(pix[-3], pix[+3]) + (pix[-3] + pix[+3]) ) > (max(pix[-u], pix[+u]) + (pix[-u] + pix[+u])));
}
}
}
}
// interpolated green pixels are corrected using the map
void RawImageSource::dcb_correction(float (*image)[3], uint8_t *map, int x0, int y0)
{
const int u = CACHESIZE, v = 2 * CACHESIZE;
int rowMin, colMin, rowMax, colMax;
dcb_initTileLimits(colMin, rowMin, colMax, rowMax, x0, y0, 2);
for (int row = rowMin; row < rowMax; row++) {
for (int indx = row * CACHESIZE + colMin + (FC(y0 - TILEBORDER + row, x0 - TILEBORDER + colMin) & 1); indx < row * CACHESIZE + colMax; indx += 2) {
// for (int col = colMin + (FC(y0 - TILEBORDER + row, x0 - TILEBORDER + colMin) & 1), indx = row * CACHESIZE + col; col < colMax; col += 2, indx += 2) {
float current = 4 * map[indx] +
2 * (map[indx + u] + map[indx - u] + map[indx + 1] + map[indx - 1]) +
map[indx + v] + map[indx - v] + map[indx + 2] + map[indx - 2];
assert(indx >= 0 && indx < u * u);
image[indx][1] = ((16.f - current) * (image[indx - 1][1] + image[indx + 1][1]) + current * (image[indx - u][1] + image[indx + u][1]) ) * 0.03125f;
// image[indx][1] = ((16.f - current) * (image[indx - 1][1] + image[indx + 1][1]) * 0.5f + current * (image[indx - u][1] + image[indx + u][1]) * 0.5f ) * 0.0625f;
}
}
}
// R and B smoothing using green contrast, all pixels except 2 pixel wide border
// again code with *pix, is this kind of calculating faster in C, than this what was commented?
void RawImageSource::dcb_pp(float (*image)[3], int x0, int y0)
{
const int u = CACHESIZE;
int rowMin, colMin, rowMax, colMax;
dcb_initTileLimits(colMin, rowMin, colMax, rowMax, x0, y0, 2);
for (int row = rowMin; row < rowMax; row++)
for (int col = colMin, indx = row * CACHESIZE + col; col < colMax; col++, indx++) {
// float r1 = image[indx-1][0] + image[indx+1][0] + image[indx-u][0] + image[indx+u][0] + image[indx-u-1][0] + image[indx+u+1][0] + image[indx-u+1][0] + image[indx+u-1][0];
// float g1 = image[indx-1][1] + image[indx+1][1] + image[indx-u][1] + image[indx+u][1] + image[indx-u-1][1] + image[indx+u+1][1] + image[indx-u+1][1] + image[indx+u-1][1];
// float b1 = image[indx-1][2] + image[indx+1][2] + image[indx-u][2] + image[indx+u][2] + image[indx-u-1][2] + image[indx+u+1][2] + image[indx-u+1][2] + image[indx+u-1][2];
float (*pix)[3] = image + (indx - u - 1);
float r1 = (*pix)[0];
float g1 = (*pix)[1];
float b1 = (*pix)[2];
pix++;
r1 += (*pix)[0];
g1 += (*pix)[1];
b1 += (*pix)[2];
pix++;
r1 += (*pix)[0];
g1 += (*pix)[1];
b1 += (*pix)[2];
pix += CACHESIZE - 2;
r1 += (*pix)[0];
g1 += (*pix)[1];
b1 += (*pix)[2];
pix += 2;
r1 += (*pix)[0];
g1 += (*pix)[1];
b1 += (*pix)[2];
pix += CACHESIZE - 2;
r1 += (*pix)[0];
g1 += (*pix)[1];
b1 += (*pix)[2];
pix++;
r1 += (*pix)[0];
g1 += (*pix)[1];
b1 += (*pix)[2];
pix++;
r1 += (*pix)[0];
g1 += (*pix)[1];
b1 += (*pix)[2];
r1 *= 0.125f;
g1 *= 0.125f;
b1 *= 0.125f;
r1 += ( image[indx][1] - g1 );
b1 += ( image[indx][1] - g1 );
assert(indx >= 0 && indx < u * u);
image[indx][0] = r1;
image[indx][2] = b1;
}
}
// interpolated green pixels are corrected using the map
// with correction
void RawImageSource::dcb_correction2(float (*image)[3], uint8_t *map, int x0, int y0)
{
const int u = CACHESIZE, v = 2 * CACHESIZE;
int rowMin, colMin, rowMax, colMax;
dcb_initTileLimits(colMin, rowMin, colMax, rowMax, x0, y0, 4);
for (int row = rowMin; row < rowMax; row++) {
for (int indx = row * CACHESIZE + colMin + (FC(y0 - TILEBORDER + row, x0 - TILEBORDER + colMin) & 1), c = FC(y0 - TILEBORDER + row, x0 - TILEBORDER + colMin + (FC(y0 - TILEBORDER + row, x0 - TILEBORDER + colMin) & 1)); indx < row * CACHESIZE + colMax; indx += 2) {
// map values are uint8_t either 0 or 1. Adding them using integer instructions is perfectly valid and fast. Final result is converted to float then
float current = 4 * map[indx] +
2 * (map[indx + u] + map[indx - u] + map[indx + 1] + map[indx - 1]) +
map[indx + v] + map[indx - v] + map[indx + 2] + map[indx - 2];
assert(indx >= 0 && indx < u * u);
// Jacek comment: works now, and has 3 float mults and 9 float adds
image[indx][1] = image[indx][c] +
((16.f - current) * (image[indx - 1][1] + image[indx + 1][1] - (image[indx + 2][c] + image[indx - 2][c]))
+ current * (image[indx - u][1] + image[indx + u][1] - (image[indx + v][c] + image[indx - v][c]))) * 0.03125f;
// 4 float mults and 9 float adds
// Jacek comment: not mathematically identical to original
/* image[indx][1] = 16.f * image[indx][c] +
((16.f - current) * ((image[indx - 1][1] + image[indx + 1][1])
- (image[indx + 2][c] + image[indx - 2][c]))
+ current * ((image[indx - u][1] + image[indx + u][1]) - (image[indx + v][c] + image[indx - v][c]))) * 0.03125f;
*/
// 7 float mults and 10 float adds
// original code
/*
image[indx][1] = ((16.f - current) * ((image[indx - 1][1] + image[indx + 1][1]) * 0.5f
+ image[indx][c] - (image[indx + 2][c] + image[indx - 2][c]) * 0.5f)
+ current * ((image[indx - u][1] + image[indx + u][1]) * 0.5f + image[indx][c] - (image[indx + v][c] + image[indx - v][c]) * 0.5f)) * 0.0625f;
*/
}
}
}
// image refinement
void RawImageSource::dcb_refinement(float (*image)[3], uint8_t *map, int x0, int y0)
{
const int u = CACHESIZE, v = 2 * CACHESIZE;
int rowMin, colMin, rowMax, colMax;
dcb_initTileLimits(colMin, rowMin, colMax, rowMax, x0, y0, 4);
float f0, f1, f2, g1, h0, h1, h2, g2;
for (int row = rowMin; row < rowMax; row++)
for (int col = colMin + (FC(y0 - TILEBORDER + row, x0 - TILEBORDER + colMin) & 1), indx = row * CACHESIZE + col, c = FC(y0 - TILEBORDER + row, x0 - TILEBORDER + col); col < colMax; col += 2, indx += 2) {
float current = 4 * map[indx] +
2 * (map[indx + u] + map[indx - u] + map[indx + 1] + map[indx - 1])
+ map[indx + v] + map[indx - v] + map[indx - 2] + map[indx + 2];
float currPix = image[indx][c];
f0 = (float)(image[indx - u][1] + image[indx + u][1]) / (1.f + 2.f * currPix);
f1 = 2.f * image[indx - u][1] / (1.f + image[indx - v][c] + currPix);
f2 = 2.f * image[indx + u][1] / (1.f + image[indx + v][c] + currPix);
g1 = f0 + f1 + f2;
h0 = (float)(image[indx - 1][1] + image[indx + 1][1]) / (1.f + 2.f * currPix);
h1 = 2.f * image[indx - 1][1] / (1.f + image[indx - 2][c] + currPix);
h2 = 2.f * image[indx + 1][1] / (1.f + image[indx + 2][c] + currPix);
g2 = h0 + h1 + h2;
// new green value
assert(indx >= 0 && indx < u * u);
currPix *= (current * g1 + (16.f - current) * g2) / 48.f;
// get rid of the overshot pixels
float minVal = min(image[indx - 1][1], min(image[indx + 1][1], min(image[indx - u][1], image[indx + u][1])));
float maxVal = max(image[indx - 1][1], max(image[indx + 1][1], max(image[indx - u][1], image[indx + u][1])));
image[indx][1] = LIM(currPix, minVal, maxVal);
}
}
// missing colours are interpolated using high quality algorithm by Luis Sanz Rodriguez
void RawImageSource::dcb_color_full(float (*image)[3], int x0, int y0, float (*chroma)[2])
{
const int u = CACHESIZE, w = 3 * CACHESIZE;
int rowMin, colMin, rowMax, colMax;
dcb_initTileLimits(colMin, rowMin, colMax, rowMax, x0, y0, 3);
float f[4], g[4];
for (int row = 1; row < CACHESIZE - 1; row++)
for (int col = 1 + (FC(y0 - TILEBORDER + row, x0 - TILEBORDER + 1) & 1), indx = row * CACHESIZE + col, c = FC(y0 - TILEBORDER + row, x0 - TILEBORDER + col), d = c / 2; col < CACHESIZE - 1; col += 2, indx += 2) {
assert(indx >= 0 && indx < u * u && c >= 0 && c < 4);
chroma[indx][d] = image[indx][c] - image[indx][1];
}
for (int row = rowMin; row < rowMax; row++)
for (int col = colMin + (FC(y0 - TILEBORDER + row, x0 - TILEBORDER + colMin) & 1), indx = row * CACHESIZE + col, c = 1 - FC(y0 - TILEBORDER + row, x0 - TILEBORDER + col) / 2; col < colMax; col += 2, indx += 2) {
f[0] = 1.f / (float)(1.f + fabs(chroma[indx - u - 1][c] - chroma[indx + u + 1][c]) + fabs(chroma[indx - u - 1][c] - chroma[indx - w - 3][c]) + fabs(chroma[indx + u + 1][c] - chroma[indx - w - 3][c]));
f[1] = 1.f / (float)(1.f + fabs(chroma[indx - u + 1][c] - chroma[indx + u - 1][c]) + fabs(chroma[indx - u + 1][c] - chroma[indx - w + 3][c]) + fabs(chroma[indx + u - 1][c] - chroma[indx - w + 3][c]));
f[2] = 1.f / (float)(1.f + fabs(chroma[indx + u - 1][c] - chroma[indx - u + 1][c]) + fabs(chroma[indx + u - 1][c] - chroma[indx + w + 3][c]) + fabs(chroma[indx - u + 1][c] - chroma[indx + w - 3][c]));
f[3] = 1.f / (float)(1.f + fabs(chroma[indx + u + 1][c] - chroma[indx - u - 1][c]) + fabs(chroma[indx + u + 1][c] - chroma[indx + w - 3][c]) + fabs(chroma[indx - u - 1][c] - chroma[indx + w + 3][c]));
g[0] = 1.325f * chroma[indx - u - 1][c] - 0.175f * chroma[indx - w - 3][c] - 0.075f * (chroma[indx - w - 1][c] + chroma[indx - u - 3][c]);
g[1] = 1.325f * chroma[indx - u + 1][c] - 0.175f * chroma[indx - w + 3][c] - 0.075f * (chroma[indx - w + 1][c] + chroma[indx - u + 3][c]);
g[2] = 1.325f * chroma[indx + u - 1][c] - 0.175f * chroma[indx + w - 3][c] - 0.075f * (chroma[indx + w - 1][c] + chroma[indx + u - 3][c]);
g[3] = 1.325f * chroma[indx + u + 1][c] - 0.175f * chroma[indx + w + 3][c] - 0.075f * (chroma[indx + w + 1][c] + chroma[indx + u + 3][c]);
// g[0] = 1.325f * chroma[indx - u - 1][c] - 0.175f * chroma[indx - w - 3][c] - 0.075f * chroma[indx - w - 1][c] - 0.075f * chroma[indx - u - 3][c];
// g[1] = 1.325f * chroma[indx - u + 1][c] - 0.175f * chroma[indx - w + 3][c] - 0.075f * chroma[indx - w + 1][c] - 0.075f * chroma[indx - u + 3][c];
// g[2] = 1.325f * chroma[indx + u - 1][c] - 0.175f * chroma[indx + w - 3][c] - 0.075f * chroma[indx + w - 1][c] - 0.075f * chroma[indx + u - 3][c];
// g[3] = 1.325f * chroma[indx + u + 1][c] - 0.175f * chroma[indx + w + 3][c] - 0.075f * chroma[indx + w + 1][c] - 0.075f * chroma[indx + u + 3][c];
assert(indx >= 0 && indx < u * u && c >= 0 && c < 2);
chroma[indx][c] = (f[0] * g[0] + f[1] * g[1] + f[2] * g[2] + f[3] * g[3]) / (f[0] + f[1] + f[2] + f[3]);
}
for (int row = rowMin; row < rowMax; row++)
for (int col = colMin + (FC(y0 - TILEBORDER + row, x0 - TILEBORDER + colMin + 1) & 1), indx = row * CACHESIZE + col, c = FC(y0 - TILEBORDER + row, x0 - TILEBORDER + col + 1) / 2; col < colMax; col += 2, indx += 2)
for(int d = 0; d <= 1; c = 1 - c, d++) {
f[0] = 1.f / (1.f + fabs(chroma[indx - u][c] - chroma[indx + u][c]) + fabs(chroma[indx - u][c] - chroma[indx - w][c]) + fabs(chroma[indx + u][c] - chroma[indx - w][c]));
f[1] = 1.f / (1.f + fabs(chroma[indx + 1][c] - chroma[indx - 1][c]) + fabs(chroma[indx + 1][c] - chroma[indx + 3][c]) + fabs(chroma[indx - 1][c] - chroma[indx + 3][c]));
f[2] = 1.f / (1.f + fabs(chroma[indx - 1][c] - chroma[indx + 1][c]) + fabs(chroma[indx - 1][c] - chroma[indx - 3][c]) + fabs(chroma[indx + 1][c] - chroma[indx - 3][c]));
f[3] = 1.f / (1.f + fabs(chroma[indx + u][c] - chroma[indx - u][c]) + fabs(chroma[indx + u][c] - chroma[indx + w][c]) + fabs(chroma[indx - u][c] - chroma[indx + w][c]));
g[0] = intp(0.875f, chroma[indx - u][c], chroma[indx - w][c]);
g[1] = intp(0.875f, chroma[indx + 1][c], chroma[indx + 3][c]);
g[2] = intp(0.875f, chroma[indx - 1][c], chroma[indx - 3][c]);
g[3] = intp(0.875f, chroma[indx + u][c], chroma[indx + w][c]);
// g[0] = 0.875f * chroma[indx - u][c] + 0.125f * chroma[indx - w][c];
// g[1] = 0.875f * chroma[indx + 1][c] + 0.125f * chroma[indx + 3][c];
// g[2] = 0.875f * chroma[indx - 1][c] + 0.125f * chroma[indx - 3][c];
// g[3] = 0.875f * chroma[indx + u][c] + 0.125f * chroma[indx + w][c];
assert(indx >= 0 && indx < u * u && c >= 0 && c < 2);
chroma[indx][c] = (f[0] * g[0] + f[1] * g[1] + f[2] * g[2] + f[3] * g[3]) / (f[0] + f[1] + f[2] + f[3]);
}
for(int row = rowMin; row < rowMax; row++)
for(int col = colMin, indx = row * CACHESIZE + col; col < colMax; col++, indx++) {
assert(indx >= 0 && indx < u * u);
image[indx][0] = chroma[indx][0] + image[indx][1];
image[indx][2] = chroma[indx][1] + image[indx][1];
}
}
// DCB demosaicing main routine
void RawImageSource::dcb_demosaic(int iterations, bool dcb_enhance)
{
BENCHFUN
double currentProgress = 0.0;
if(plistener) {
plistener->setProgressStr (Glib::ustring::compose(M("TP_RAW_DMETHOD_PROGRESSBAR"), M("TP_RAW_DCB")));
plistener->setProgress (currentProgress);
}
int wTiles = W / TILESIZE + (W % TILESIZE ? 1 : 0);
int hTiles = H / TILESIZE + (H % TILESIZE ? 1 : 0);
int numTiles = wTiles * hTiles;
int tilesDone = 0;
constexpr int cldf = 2; // factor to multiply cache line distance. 1 = 64 bytes, 2 = 128 bytes ...
#ifdef _OPENMP
#pragma omp parallel
#endif
{
// assign working space
char *buffer0 = (char *) malloc(5 * sizeof(float) * CACHESIZE * CACHESIZE + sizeof(uint8_t) * CACHESIZE * CACHESIZE + 3 * cldf * 64 + 63);
// aligned to 64 byte boundary
char *data = (char*)( ( uintptr_t(buffer0) + uintptr_t(63)) / 64 * 64);
float (*tile)[3] = (float(*)[3]) data;
float (*buffer)[2] = (float(*)[2]) ((char*)tile + sizeof(float) * CACHESIZE * CACHESIZE * 3 + cldf * 64);
float (*chrm)[2] = (float(*)[2]) (buffer); // No overlap in usage of buffer and chrm means we can reuse buffer
uint8_t *map = (uint8_t*) ((char*)buffer + sizeof(float) * CACHESIZE * CACHESIZE * 2 + cldf * 64);
#ifdef _OPENMP
#pragma omp for schedule(dynamic) nowait
#endif
for( int iTile = 0; iTile < numTiles; iTile++) {
int xTile = iTile % wTiles;
int yTile = iTile / wTiles;
int x0 = xTile * TILESIZE;
int y0 = yTile * TILESIZE;
memset(tile, 0, CACHESIZE * CACHESIZE * sizeof * tile);
memset(map, 0, CACHESIZE * CACHESIZE * sizeof * map);
fill_raw( tile, x0, y0, rawData );
if( !xTile || !yTile || xTile == wTiles - 1 || yTile == hTiles - 1) {
fill_border(tile, 6, x0, y0);
}
copy_to_buffer(buffer, tile);
dcb_hid(tile, x0, y0);
for (int i = iterations; i > 0; i--) {
dcb_hid2(tile, x0, y0);
dcb_hid2(tile, x0, y0);
dcb_hid2(tile, x0, y0);
dcb_map(tile, map, x0, y0);
dcb_correction(tile, map, x0, y0);
}
dcb_color(tile, x0, y0);
dcb_pp(tile, x0, y0);
dcb_map(tile, map, x0, y0);
dcb_correction2(tile, map, x0, y0);
dcb_map(tile, map, x0, y0);
dcb_correction(tile, map, x0, y0);
dcb_color(tile, x0, y0);
dcb_map(tile, map, x0, y0);
dcb_correction(tile, map, x0, y0);
dcb_map(tile, map, x0, y0);
dcb_correction(tile, map, x0, y0);
dcb_map(tile, map, x0, y0);
restore_from_buffer(tile, buffer);
if (!dcb_enhance)
dcb_color(tile, x0, y0);
else
{
memset(chrm, 0, CACHESIZE * CACHESIZE * sizeof * chrm);
dcb_refinement(tile, map, x0, y0);
dcb_color_full(tile, x0, y0, chrm);
}
/*
dcb_hid(tile, buffer, buffer2, x0, y0);
dcb_color(tile, x0, y0);
copy_to_buffer(buffer, tile);
for (int i = iterations; i > 0; i--) {
dcb_hid2(tile, x0, y0);
dcb_hid2(tile, x0, y0);
dcb_hid2(tile, x0, y0);
dcb_map(tile, x0, y0);
dcb_correction(tile, x0, y0);
}
dcb_color(tile, x0, y0);
dcb_pp(tile, x0, y0);
dcb_map(tile, x0, y0);
dcb_correction2(tile, x0, y0);
dcb_map(tile, x0, y0);
dcb_correction(tile, x0, y0);
dcb_color(tile, x0, y0);
dcb_map(tile, x0, y0);
dcb_correction(tile, x0, y0);
dcb_map(tile, x0, y0);
dcb_correction(tile, x0, y0);
dcb_map(tile, x0, y0);
restore_from_buffer(tile, buffer);
dcb_color_full(tile, x0, y0, chrm);
if (dcb_enhance) {
dcb_refinement(tile, x0, y0);
dcb_color_full(tile, x0, y0, chrm);
}
*/
for(int y = 0; y < TILESIZE && y0 + y < H; y++) {
for (int j = 0; j < TILESIZE && x0 + j < W; j++) {
red[y0 + y][x0 + j] = tile[(y + TILEBORDER) * CACHESIZE + TILEBORDER + j][0];
green[y0 + y][x0 + j] = tile[(y + TILEBORDER) * CACHESIZE + TILEBORDER + j][1];
blue[y0 + y][x0 + j] = tile[(y + TILEBORDER) * CACHESIZE + TILEBORDER + j][2];
}
}
#ifdef _OPENMP
if(omp_get_thread_num() == 0)
#endif
{
if( plistener && double(tilesDone) / numTiles > currentProgress) {
currentProgress += 0.1; // Show progress each 10%
plistener->setProgress (currentProgress);
}
}
#ifdef _OPENMP
#pragma omp atomic
#endif
tilesDone++;
}
free(buffer0);
}
border_interpolate2(W, H, 1, rawData, red, green, blue);
if(plistener) {
plistener->setProgress (1.0);
}
}
#undef TILEBORDER
#undef TILESIZE
#undef CACHESIZE
} /* namespace */
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