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rawTherapee/rtengine/rawimage.cc
Alberto Griggio 655bdfd7e7 merged branch 'floatdng'
2018-11-22 08:50:35 +01:00

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/*
* This file is part of RawTherapee.
*
* Created on: 20/nov/2010
*/
#include <strings.h>
#ifdef WIN32
#include <winsock2.h>
#else
#include <netinet/in.h>
#endif
#include "rawimage.h"
#include "settings.h"
#include "camconst.h"
#include "utils.h"
namespace rtengine
{
extern const Settings* settings;
RawImage::RawImage( const Glib::ustring &name )
: data(nullptr)
, prefilters(0)
, filename(name)
, rotate_deg(0)
, profile_data(nullptr)
, allocation(nullptr)
{
memset(maximum_c4, 0, sizeof(maximum_c4));
RT_matrix_from_constant = ThreeValBool::X;
RT_blacklevel_from_constant = ThreeValBool::X;
RT_whitelevel_from_constant = ThreeValBool::X;
}
RawImage::~RawImage()
{
if(ifp) {
fclose(ifp);
ifp = nullptr;
}
if( image ) {
free(image);
}
if(allocation) {
delete [] allocation;
allocation = nullptr;
}
if(float_raw_image) {
delete [] float_raw_image;
float_raw_image = nullptr;
}
if(data) {
delete [] data;
data = nullptr;
}
if(profile_data) {
delete [] profile_data;
profile_data = nullptr;
}
}
eSensorType RawImage::getSensorType()
{
if (isBayer()) {
return ST_BAYER;
} else if (isXtrans()) {
return ST_FUJI_XTRANS;
} else if (isFoveon()) {
return ST_FOVEON;
}
return ST_NONE;
}
/* Similar to dcraw scale_colors for coeff. calculation, but without actual pixels scaling.
* need pixels in data[][] available
*/
void RawImage::get_colorsCoeff( float *pre_mul_, float *scale_mul_, float *cblack_, bool forceAutoWB)
{
unsigned sum[8], c;
unsigned W = this->get_width();
unsigned H = this->get_height();
float val;
double dsum[8], dmin, dmax;
if(isXtrans()) {
// for xtrans files dcraw stores black levels in cblack[6] .. cblack[41], but all are equal, so we just use cblack[6]
for (int c = 0; c < 4; c++) {
cblack_[c] = (float) this->get_cblack(6);
pre_mul_[c] = this->get_pre_mul(c);
}
} else if ((this->get_cblack(4) + 1) / 2 == 1 && (this->get_cblack(5) + 1) / 2 == 1) {
for (int c = 0; c < 4; c++) {
cblack_[c] = this->get_cblack(c);
}
for (int c = 0; c < 4; c++) {
cblack_[FC(c / 2, c % 2)] = this->get_cblack(6 + c / 2 % this->get_cblack(4) * this->get_cblack(5) + c % 2 % this->get_cblack(5));
pre_mul_[c] = this->get_pre_mul(c);
}
} else {
for (int c = 0; c < 4; c++) {
cblack_[c] = (float) this->get_cblack(c);
pre_mul_[c] = this->get_pre_mul(c);
}
}
if (this->get_cam_mul(0) == -1 || forceAutoWB) {
if(!data) { // this happens only for thumbnail creation when get_cam_mul(0) == -1
compress_image(0, false);
}
memset(dsum, 0, sizeof dsum);
constexpr float blackThreshold = 8.f;
constexpr float whiteThreshold = 25.f;
if (this->isBayer()) {
// calculate number of pixels per color
dsum[FC(0, 0) + 4] += (int)(((W + 1) / 2) * ((H + 1) / 2));
dsum[FC(0, 1) + 4] += (int)(((W / 2) * ((H + 1) / 2)));
dsum[FC(1, 0) + 4] += (int)(((W + 1) / 2) * (H / 2));
dsum[FC(1, 1) + 4] += (int)((W / 2) * (H / 2));
#pragma omp parallel private(val)
{
double dsumthr[8];
memset(dsumthr, 0, sizeof dsumthr);
float sum[4];
// make local copies of the black and white values to avoid calculations and conversions
float cblackfloat[4];
float whitefloat[4];
for (int c = 0; c < 4; c++) {
cblackfloat[c] = cblack_[c] + blackThreshold;
whitefloat[c] = this->get_white(c) - whiteThreshold;
}
float *tempdata = data[0];
#pragma omp for nowait
for (size_t row = 0; row < H; row += 8) {
size_t ymax = row + 8 < H ? row + 8 : H;
for (size_t col = 0; col < W ; col += 8) {
size_t xmax = col + 8 < W ? col + 8 : W;
memset(sum, 0, sizeof sum);
for (size_t y = row; y < ymax; y++)
for (size_t x = col; x < xmax; x++) {
int c = FC(y, x);
val = tempdata[y * W + x];
if (val > whitefloat[c] || val < cblackfloat[c]) { // calculate number of pixels to be subtracted from sum and skip the block
dsumthr[FC(row, col) + 4] += (int)(((xmax - col + 1) / 2) * ((ymax - row + 1) / 2));
dsumthr[FC(row, col + 1) + 4] += (int)(((xmax - col) / 2) * ((ymax - row + 1) / 2));
dsumthr[FC(row + 1, col) + 4] += (int)(((xmax - col + 1) / 2) * ((ymax - row) / 2));
dsumthr[FC(row + 1, col + 1) + 4] += (int)(((xmax - col) / 2) * ((ymax - row) / 2));
goto skip_block2;
}
sum[c] += val;
}
for (int c = 0; c < 4; c++) {
dsumthr[c] += sum[c];
}
skip_block2:
;
}
}
#pragma omp critical
{
for (int c = 0; c < 4; c++) {
dsum[c] += dsumthr[c];
}
for (int c = 4; c < 8; c++) {
dsum[c] -= dsumthr[c];
}
}
}
for(int c = 0; c < 4; c++) {
dsum[c] -= cblack_[c] * dsum[c + 4];
}
} else if(isXtrans()) {
#pragma omp parallel
{
double dsumthr[8];
memset(dsumthr, 0, sizeof dsumthr);
float sum[8];
// make local copies of the black and white values to avoid calculations and conversions
float cblackfloat[4];
float whitefloat[4];
for (int c = 0; c < 4; c++)
{
cblackfloat[c] = cblack_[c] + blackThreshold;
whitefloat[c] = this->get_white(c) - whiteThreshold;
}
#pragma omp for nowait
for (size_t row = 0; row < H; row += 8)
for (size_t col = 0; col < W ; col += 8)
{
memset(sum, 0, sizeof sum);
for (size_t y = row; y < row + 8 && y < H; y++)
for (size_t x = col; x < col + 8 && x < W; x++) {
int c = XTRANSFC(y, x);
float val = data[y][x];
if (val > whitefloat[c] || val < cblackfloat[c]) {
goto skip_block3;
}
val -= cblack_[c];
sum[c] += val;
sum[c + 4]++;
}
for (int c = 0; c < 8; c++) {
dsumthr[c] += sum[c];
}
skip_block3:
;
}
#pragma omp critical
{
for (int c = 0; c < 8; c++)
{
dsum[c] += dsumthr[c];
}
}
}
} else if (colors == 1) {
for (int c = 0; c < 4; c++) {
pre_mul_[c] = 1;
}
} else {
for (size_t row = 0; row < H; row += 8)
for (size_t col = 0; col < W ; col += 8) {
memset(sum, 0, sizeof sum);
for (size_t y = row; y < row + 8 && y < H; y++)
for (size_t x = col; x < col + 8 && x < W; x++)
for (int c = 0; c < 3; c++) {
val = data[y][3 * x + c];
if (val > this->get_white(c) - whiteThreshold || val < cblack_[c] + blackThreshold) {
goto skip_block;
}
val -= cblack_[c];
sum[c] += val;
sum[c + 4]++;
}
for (c = 0; c < 8; c++) {
dsum[c] += sum[c];
}
skip_block:
;
}
}
for (int c = 0; c < 4; c++)
if (dsum[c]) {
pre_mul_[c] = dsum[c + 4] / dsum[c];
}
} else {
memset(sum, 0, sizeof sum);
for (size_t row = 0; row < 8; row++)
for (size_t col = 0; col < 8; col++) {
int c = FC(row, col);
if ((val = white[row][col] - cblack_[c]) > 0) {
sum[c] += val;
}
sum[c + 4]++;
}
if (sum[0] && sum[1] && sum[2] && sum[3])
for (int c = 0; c < 4; c++) {
pre_mul_[c] = (float) sum[c + 4] / sum[c];
}
else if (this->get_cam_mul(0) && this->get_cam_mul(2)) {
pre_mul_[0] = this->get_cam_mul(0);
pre_mul_[1] = this->get_cam_mul(1);
pre_mul_[2] = this->get_cam_mul(2);
pre_mul_[3] = this->get_cam_mul(3);
} else {
fprintf(stderr, "Cannot use camera white balance.\n");
}
}
if (pre_mul_[3] == 0) {
pre_mul_[3] = this->get_colors() < 4 ? pre_mul_[1] : 1;
} else if (this->get_colors() < 4) {
pre_mul_[3] = pre_mul_[1] = (pre_mul_[3] + pre_mul_[1]) / 2;
}
if (colors == 1) {
// there are monochrome cameras with wrong matrix. We just replace with this one.
rgb_cam[0][0] = 1; rgb_cam[1][0] = 0; rgb_cam[2][0] = 0;
rgb_cam[0][1] = 0; rgb_cam[1][1] = 1; rgb_cam[2][1] = 0;
rgb_cam[0][2] = 0; rgb_cam[1][2] = 0; rgb_cam[2][2] = 1;
for (c = 1; c < 4; c++) {
cblack_[c] = cblack_[0];
}
}
bool multiple_whites = false;
int largest_white = this->get_white(0);
for (c = 1; c < 4; c++) {
if (this->get_white(c) != this->get_white(0)) {
multiple_whites = true;
if (this->get_white(c) > largest_white) {
largest_white = this->get_white(c);
}
}
}
if (multiple_whites) {
// dcraw's pre_mul/cam_mul expects a single white, so if we have provided multiple whites we need
// to adapt scaling to avoid color shifts.
for (c = 0; c < 4; c++) {
// we don't really need to do the largest_white division but do so just to keep pre_mul in similar
// range as before adjustment so they don't look strangely large if someone would print them
pre_mul_[c] *= (float)this->get_white(c) / largest_white;
}
}
for (dmin = DBL_MAX, dmax = c = 0; c < 4; c++) {
if (dmin > pre_mul_[c]) {
dmin = pre_mul_[c];
}
if (dmax < pre_mul_[c]) {
dmax = pre_mul_[c];
}
}
for (c = 0; c < 4; c++) {
int sat = this->get_white(c) - cblack_[c];
scale_mul_[c] = (pre_mul_[c] /= dmax) * 65535.0 / sat;
}
if (settings->verbose) {
float asn[4] = { 1 / cam_mul[0], 1 / cam_mul[1], 1 / cam_mul[2], 1 / cam_mul[3] };
for (dmax = c = 0; c < 4; c++) {
if (cam_mul[c] == 0) {
asn[c] = 0;
}
if (asn[c] > dmax) {
dmax = asn[c];
}
}
for (c = 0; c < 4; c++) {
asn[c] /= dmax;
}
printf("cam_mul:[%f %f %f %f], AsShotNeutral:[%f %f %f %f]\n",
cam_mul[0], cam_mul[1], cam_mul[2], cam_mul[3], asn[0], asn[1], asn[2], asn[3]);
printf("pre_mul:[%f %f %f %f], scale_mul:[%f %f %f %f], cblack:[%f %f %f %f]\n",
pre_mul_[0], pre_mul_[1], pre_mul_[2], pre_mul_[3],
scale_mul_[0], scale_mul_[1], scale_mul_[2], scale_mul_[3],
cblack_[0], cblack_[1], cblack_[2], cblack_[3]);
printf("rgb_cam:[ [ %f %f %f], [%f %f %f], [%f %f %f] ]%s\n",
rgb_cam[0][0], rgb_cam[1][0], rgb_cam[2][0],
rgb_cam[0][1], rgb_cam[1][1], rgb_cam[2][1],
rgb_cam[0][2], rgb_cam[1][2], rgb_cam[2][2],
(!this->isBayer()) ? " (not bayer)" : "");
}
}
int RawImage::loadRaw (bool loadData, unsigned int imageNum, bool closeFile, ProgressListener *plistener, double progressRange)
{
ifname = filename.c_str();
image = nullptr;
verbose = settings->verbose;
oprof = nullptr;
if(!ifp) {
ifp = gfopen (ifname); // Maps to either file map or direct fopen
} else {
fseek (ifp, 0, SEEK_SET);
}
if (!ifp) {
return 3;
}
imfile_set_plistener(ifp, plistener, 0.9 * progressRange);
thumb_length = 0;
thumb_offset = 0;
thumb_load_raw = nullptr;
use_camera_wb = 0;
highlight = 1;
half_size = 0;
raw_image = nullptr;
//***************** Read ALL raw file info
// set the number of the frame to extract. If the number is larger then number of existing frames - 1, dcraw will handle that correctly
shot_select = imageNum;
identify();
// in case dcraw didn't handle the above mentioned case...
shot_select = std::min(shot_select, std::max(is_raw, 1u) - 1);
if (!is_raw) {
fclose(ifp);
ifp = nullptr;
if (plistener) {
plistener->setProgress(1.0 * progressRange);
}
return 2;
}
if(!strcmp(make,"Fujifilm") && raw_height * raw_width * 2u != raw_size) {
if (raw_width * raw_height * 7u / 4u == raw_size) {
load_raw = &RawImage::fuji_14bit_load_raw;
} else {
parse_fuji_compressed_header();
}
}
if (flip == 5) {
this->rotate_deg = 270;
} else if (flip == 3) {
this->rotate_deg = 180;
} else if (flip == 6) {
this->rotate_deg = 90;
} else if (flip % 90 == 0 && flip < 360) {
this->rotate_deg = flip;
} else {
this->rotate_deg = 0;
}
if( loadData ) {
use_camera_wb = 1;
shrink = 0;
if (settings->verbose) {
printf ("Loading %s %s image from %s...\n", make, model, filename.c_str());
}
iheight = height;
iwidth = width;
if (filters || colors == 1) {
raw_image = (ushort *) calloc ((static_cast<unsigned int>(raw_height) + 7u) * static_cast<unsigned int>(raw_width), 2);
merror (raw_image, "main()");
}
// dcraw needs this global variable to hold pixel data
image = (dcrawImage_t)calloc (static_cast<unsigned int>(height) * static_cast<unsigned int>(width) * sizeof * image + meta_length, 1);
meta_data = (char *) (image + static_cast<unsigned int>(height) * static_cast<unsigned int>(width));
if(!image) {
return 200;
}
/* Issue 2467
if (setjmp (failure)) {
if (image) { free (image); image=NULL; }
if (raw_image) { free(raw_image); raw_image=NULL; }
fclose(ifp); ifp=NULL;
return 100;
}
*/
// Load raw pixels data
fseek (ifp, data_offset, SEEK_SET);
(this->*load_raw)();
if (!float_raw_image) { // apply baseline exposure only for float DNGs
RT_baseline_exposure = 0;
}
if (plistener) {
plistener->setProgress(0.9 * progressRange);
}
CameraConstantsStore* ccs = CameraConstantsStore::getInstance();
CameraConst *cc = ccs->get(make, model);
if (raw_image) {
if (cc && cc->has_rawCrop()) {
int lm, tm, w, h;
cc->get_rawCrop(lm, tm, w, h);
if(isXtrans()) {
shiftXtransMatrix(6 - ((top_margin - tm)%6), 6 - ((left_margin - lm)%6));
} else {
if(((int)top_margin - tm) & 1) { // we have an odd border difference
filters = (filters << 4) | (filters >> 28); // left rotate filters by 4 bits
}
}
left_margin = lm;
top_margin = tm;
if (w < 0) {
iwidth += w;
iwidth -= left_margin;
width += w;
width -= left_margin;
} else if (w > 0) {
iwidth = width = min((int)width, w);
}
if (h < 0) {
iheight += h;
iheight -= top_margin;
height += h;
height -= top_margin;
} else if (h > 0) {
iheight = height = min((int)height, h);
}
}
if (cc && cc->has_rawMask(0)) {
for (int i = 0; i < 8 && cc->has_rawMask(i); i++) {
cc->get_rawMask(i, mask[i][0], mask[i][1], mask[i][2], mask[i][3]);
}
}
crop_masked_pixels();
free (raw_image);
raw_image = nullptr;
} else {
if (get_maker() == "Sigma" && cc && cc->has_rawCrop()) { // foveon images
int lm, tm, w, h;
cc->get_rawCrop(lm, tm, w, h);
left_margin = lm;
top_margin = tm;
if (w < 0) {
width += w;
width -= left_margin;
} else if (w > 0) {
width = min((int)width, w);
}
if (h < 0) {
height += h;
height -= top_margin;
} else if (h > 0) {
height = min((int)height, h);
}
}
}
// Load embedded profile
if (profile_length) {
profile_data = new char[profile_length];
fseek ( ifp, profile_offset, SEEK_SET);
fread ( profile_data, 1, profile_length, ifp);
}
/*
Setting the black level, there are three sources:
dcraw single value 'black' or multi-value 'cblack', can be calculated or come
from a hard-coded table or come from a stored value in the raw file, and
finally there's 'black_c4' which are table values provided by RT camera constants.
Any of these may or may not be set.
We reduce these sources to one four channel black level, and do this by picking
the highest found.
*/
int black_c4[4] = { -1, -1, -1, -1 };
bool white_from_cc = false;
bool black_from_cc = false;
if (cc) {
for (int i = 0; i < 4; i++) {
if (RT_blacklevel_from_constant == ThreeValBool::T) {
int blackFromCc = cc->get_BlackLevel(i, iso_speed);
// if black level from camconst > 0xffff it is an absolute value.
black_c4[i] = blackFromCc > 0xffff ? (blackFromCc & 0xffff) : blackFromCc + cblack[i];
}
// load 4 channel white level here, will be used if available
if (RT_whitelevel_from_constant == ThreeValBool::T) {
maximum_c4[i] = cc->get_WhiteLevel(i, iso_speed, aperture);
if(tiff_bps > 0 && maximum_c4[i] > 0 && !isFoveon()) {
unsigned compare = ((uint64_t)1 << tiff_bps) - 1; // use uint64_t to avoid overflow if tiff_bps == 32
while(static_cast<uint64_t>(maximum_c4[i]) > compare) {
maximum_c4[i] >>= 1;
}
}
}
}
}
if (black_c4[0] == -1) {
if(isXtrans())
for (int c = 0; c < 4; c++) {
black_c4[c] = cblack[6];
}
else
// RT constants not set, bring in the DCRAW single channel black constant
for (int c = 0; c < 4; c++) {
black_c4[c] = black + cblack[c];
}
} else {
black_from_cc = true;
}
if (maximum_c4[0] > 0) {
white_from_cc = true;
}
for (int c = 0; c < 4; c++) {
if (static_cast<int>(cblack[c]) < black_c4[c]) {
cblack[c] = black_c4[c];
}
}
if (settings->verbose) {
if (cc) {
printf("constants exists for \"%s %s\" in camconst.json\n", make, model);
} else {
printf("no constants in camconst.json exists for \"%s %s\" (relying only on dcraw defaults)\n", make, model);
}
printf("black levels: R:%d G1:%d B:%d G2:%d (%s)\n", get_cblack(0), get_cblack(1), get_cblack(2), get_cblack(3),
black_from_cc ? "provided by camconst.json" : "provided by dcraw");
printf("white levels: R:%d G1:%d B:%d G2:%d (%s)\n", get_white(0), get_white(1), get_white(2), get_white(3),
white_from_cc ? "provided by camconst.json" : "provided by dcraw");
printf("raw crop: %d %d %d %d (provided by %s)\n", left_margin, top_margin, iwidth, iheight, (cc && cc->has_rawCrop()) ? "camconst.json" : "dcraw");
printf("color matrix provided by %s\n", (cc && cc->has_dcrawMatrix()) ? "camconst.json" : "dcraw");
}
}
if ( closeFile ) {
fclose(ifp);
ifp = nullptr;
}
if (plistener) {
plistener->setProgress(1.0 * progressRange);
}
return 0;
}
float** RawImage::compress_image(unsigned int frameNum, bool freeImage)
{
if( !image ) {
return nullptr;
}
if (isBayer() || isXtrans()) {
if (!allocation) {
// shift the beginning of all frames but the first by 32 floats to avoid cache miss conflicts on CPUs which have <= 4-way associative L1-Cache
allocation = new float[static_cast<unsigned int>(height) * static_cast<unsigned int>(width) + frameNum * 32u];
data = new float*[height];
for (int i = 0; i < height; i++) {
data[i] = allocation + i * width + frameNum * 32;
}
}
} else if (colors == 1) {
// Monochrome
if (!allocation) {
allocation = new float[static_cast<unsigned long>(height) * static_cast<unsigned long>(width)];
data = new float*[height];
for (int i = 0; i < height; i++) {
data[i] = allocation + i * width;
}
}
} else {
if (!allocation) {
allocation = new float[3UL * static_cast<unsigned long>(height) * static_cast<unsigned long>(width)];
data = new float*[height];
for (int i = 0; i < height; i++) {
data[i] = allocation + 3 * i * width;
}
}
}
// copy pixel raw data: the compressed format earns space
if( float_raw_image ) {
#pragma omp parallel for
for (int row = 0; row < height; row++)
for (int col = 0; col < width; col++) {
this->data[row][col] = float_raw_image[(row + top_margin) * raw_width + col + left_margin];
}
delete [] float_raw_image;
float_raw_image = nullptr;
} else if (filters != 0 && !isXtrans()) {
#pragma omp parallel for
for (int row = 0; row < height; row++)
for (int col = 0; col < width; col++) {
this->data[row][col] = image[row * width + col][FC(row, col)];
}
} else if (isXtrans()) {
#pragma omp parallel for
for (int row = 0; row < height; row++)
for (int col = 0; col < width; col++) {
this->data[row][col] = image[row * width + col][XTRANSFC(row, col)];
}
} else if (colors == 1) {
#pragma omp parallel for
for (int row = 0; row < height; row++)
for (int col = 0; col < width; col++) {
this->data[row][col] = image[row * width + col][0];
}
} else {
if(get_maker() == "Sigma" && dng_version) { // Hack to prevent sigma dng files from crashing
height -= top_margin;
width -= left_margin;
}
#pragma omp parallel for
for (int row = 0; row < height; row++)
for (int col = 0; col < width; col++) {
this->data[row][3 * col + 0] = image[(row + top_margin) * iwidth + col + left_margin][0];
this->data[row][3 * col + 1] = image[(row + top_margin) * iwidth + col + left_margin][1];
this->data[row][3 * col + 2] = image[(row + top_margin) * iwidth + col + left_margin][2];
}
}
if(freeImage) {
free(image); // we don't need this anymore
image = nullptr;
}
return data;
}
bool
RawImage::is_supportedThumb() const
{
return ( (thumb_width * thumb_height) > 0 &&
( write_thumb == &rtengine::RawImage::jpeg_thumb ||
write_thumb == &rtengine::RawImage::ppm_thumb) &&
!thumb_load_raw );
}
bool
RawImage::is_jpegThumb() const
{
return ( (thumb_width * thumb_height) > 0 &&
write_thumb == &rtengine::RawImage::jpeg_thumb &&
!thumb_load_raw );
}
bool
RawImage::is_ppmThumb() const
{
return ( (thumb_width * thumb_height) > 0 &&
write_thumb == &rtengine::RawImage::ppm_thumb &&
!thumb_load_raw );
}
void RawImage::getXtransMatrix( int XtransMatrix[6][6])
{
for(int row = 0; row < 6; row++)
for(int col = 0; col < 6; col++) {
XtransMatrix[row][col] = xtrans[row][col];
}
}
void RawImage::getRgbCam (float rgbcam[3][4])
{
for(int row = 0; row < 3; row++)
for(int col = 0; col < 4; col++) {
rgbcam[row][col] = rgb_cam[row][col];
}
}
bool
RawImage::get_thumbSwap() const
{
return (order == 0x4949) == (ntohs(0x1234) == 0x1234);
}
} //namespace rtengine
bool
DCraw::dcraw_coeff_overrides(const char make[], const char model[], const int iso_speed, short trans[12], int *black_level, int *white_level)
{
static const int dcraw_arw2_scaling_bugfix_shift = 2;
static const struct {
const char *prefix;
int black_level, white_level; // set to -1 for no change
short trans[12]; // set first value to 0 for no change
} table[] = {
{
"Canon EOS 5D Mark III", -1, 0x3a98, /* RT */
{ 6722, -635, -963, -4287, 12460, 2028, -908, 2162, 5668 }
},
{
"Canon EOS 5D", -1, 0xe6c, /* RT */
{ 6319, -793, -614, -5809, 13342, 2738, -1132, 1559, 7971 }
},
{
"Canon EOS 6D", -1, 0x3c82,
{ 7034, -804, -1014, -4420, 12564, 2058, -851, 1994, 5758 }
},
{
"Canon EOS 7D", -1, 0x3510, /* RT - Colin Walker */
{ 5962, -171, -732, -4189, 12307, 2099, -911, 1981, 6304 }
},
{
"Canon EOS 20D", -1, 0xfff, /* RT */
{ 7590, -1646, -673, -4697, 12411, 2568, -627, 1118, 7295 }
},
{
"Canon EOS 40D", -1, 0x3f60, /* RT */
{ 6070, -531, -883, -5763, 13647, 2315, -1533, 2582, 6801 }
},
{
"Canon EOS 60D", -1, 0x2ff7, /* RT - Colin Walker */
{ 5678, -179, -718, -4389, 12381, 2243, -869, 1819, 6380 }
},
{
"Canon EOS 450D", -1, 0x390d, /* RT */
{ 6246, -1272, -523, -5075, 12357, 3075, -1035, 1825, 7333 }
},
{
"Canon EOS 550D", -1, 0x3dd7, /* RT - Lebedev*/
{ 6519, -772, -703, -4994, 12737, 2519, -1387, 2492, 6175 }
},
{
"Canon EOS-1D Mark III", 0, 0x3bb0, /* RT */
{ 7406, -1592, -646, -4856, 12457, 2698, -432, 726, 7921 }
},
{
"Canon PowerShot G10", -1, -1, /* RT */
{ 12535, -5030, -796, -2711, 10134, 3006, -413, 1605, 5264 }
},
{
"Canon PowerShot G12", -1, -1, /* RT */
{ 12222, -4097, -1380, -2876, 11016, 2130, -888, 1630, 4434 }
},
{
"Fujifilm X100", -1, -1, /* RT - Colin Walker */
{ 10841, -3288, -807, -4652, 12552, 2344, -642, 1355, 7206 }
},
{
"Nikon D200", -1, 0xfbc, /* RT */
{ 8498, -2633, -295, -5423, 12869, 2860, -777, 1077, 8124 }
},
{
"Nikon D3000", -1, -1, /* RT */
{ 9211, -2521, -104, -6487, 14280, 2394, -754, 1122, 8033 }
},
{
"Nikon D3100", -1, -1, /* RT */
{ 7729, -2212, -481, -5709, 13148, 2858, -1295, 1908, 8936 }
},
{
"Nikon D3S", -1, -1, /* RT */
{ 8792, -2663, -344, -5221, 12764, 2752, -1491, 2165, 8121 }
},
{
"Nikon D5200", -1, -1, // color matrix copied from D5200 DNG D65 matrix
{ 8322, -3112, -1047, -6367, 14342, 2179, -988, 1638, 6394 }
},
{
"Nikon D7000", -1, -1, /* RT - Tanveer(tsk1979) */
{ 7530, -1942, -255, -4318, 11390, 3362, -926, 1694, 7649 }
},
{
"Nikon D7100", -1, -1, // color matrix and WP copied from D7100 DNG D65 matrix
{ 8322, -3112, -1047, -6367, 14342, 2179, -988, 1638, 6394 }
},
{
"Nikon D700", -1, -1, /* RT */
{ 8364, -2503, -352, -6307, 14026, 2492, -1134, 1512, 8156 }
},
{
"Nikon COOLPIX A", -1, 0x3e00, // color matrix and WP copied from "COOLPIX A" DNG D65 matrix
{ 8198, -2239, -724, -4871, 12389, 2798, -1043, 205, 7181 }
},
{
"Olympus E-30", -1, 0xfbc, /* RT - Colin Walker */
{ 8510, -2355, -693, -4819, 12520, 2578, -1029, 2067, 7752 }
},
{
"Olympus E-5", -1, 0xeec, /* RT - Colin Walker */
{ 9732, -2629, -999, -4899, 12931, 2173, -1243, 2353, 7457 }
},
{
"Olympus E-P1", -1, 0xffd, /* RT - Colin Walker */
{ 8834, -2344, -804, -4691, 12503, 2448, -978, 1919, 7603 }
},
{
"Olympus E-P2", -1, 0xffd, /* RT - Colin Walker */
{ 7758, -1619, -800, -5002, 12886, 2349, -985, 1964, 8305 }
},
{
"Olympus E-P3", -1, -1, /* RT - Colin Walker */
{ 7041, -1794, -336, -3790, 11192, 2984, -1364, 2625, 6217 }
},
{
"Olympus E-PL1s", -1, -1, /* RT - Colin Walker */
{ 9010, -2271, -838, -4792, 12753, 2263, -1059, 2058, 7589 }
},
{
"Olympus E-PL1", -1, -1, /* RT - Colin Walker */
{ 9010, -2271, -838, -4792, 12753, 2263, -1059, 2058, 7589 }
},
{
"Olympus E-PL2", -1, -1, /* RT - Colin Walker */
{ 11975, -3351, -1184, -4500, 12639, 2061, -1230, 2353, 7009 }
},
{
"Olympus E-PL3", -1, -1, /* RT - Colin Walker */
{ 7041, -1794, -336, -3790, 11192, 2984, -1364, 2625, 6217 }
},
{
"Olympus XZ-1", -1, -1, /* RT - Colin Walker */
{ 8665, -2247, -762, -2424, 10372, 2382, -1011, 2286, 5189 }
},
/* since Dcraw_v9.21 Panasonic BlackLevel is read from exif (tags 0x001c BlackLevelRed, 0x001d BlackLevelGreen, 0x001e BlackLevelBlue
and we define here the needed offset of around 15. The total BL is BL + BLoffset (cblack + black) */
{
"Panasonic DMC-FZ150", 15, 0xfd2, /* RT */
{ 10435, -3208, -72, -2293, 10506, 2067, -486, 1725, 4682 }
},
{
"Panasonic DMC-G10", 15, 0xf50, /* RT - Colin Walker - variable WL 3920 - 4080 */
{ 8310, -1811, -960, -4941, 12990, 2151, -1378, 2468, 6860 }
},
{
"Panasonic DMC-G1", 15, 0xf50, /* RT - Colin Walker - variable WL 3920 - 4080 */
{ 7477, -1615, -651, -5016, 12769, 2506, -1380, 2475, 7240 }
},
{
"Panasonic DMC-G2", 15, 0xf50, /* RT - Colin Walker - variable WL 3920 - 4080 */
{ 8310, -1811, -960, -4941, 12990, 2151, -1378, 2468, 6860 }
},
{
"Panasonic DMC-G3", 15, 0xfdc, /* RT - Colin Walker - WL 4060 */
{ 6051, -1406, -671, -4015, 11505, 2868, -1654, 2667, 6219 }
},
{
"Panasonic DMC-G5", 15, 0xfdc, /* RT - WL 4060 */
{ 7122, -2092, -419, -4643, 11769, 3283, -1363, 2413, 5944 }
},
{
"Panasonic DMC-GF1", 15, 0xf50, /* RT - Colin Walker - Variable WL 3920 - 4080 */
{ 7863, -2080, -668, -4623, 12331, 2578, -1020, 2066, 7266 }
},
{
"Panasonic DMC-GF2", 15, 0xfd2, /* RT - Colin Walker - WL 4050 */
{ 7694, -1791, -745, -4917, 12818, 2332, -1221, 2322, 7197 }
},
{
"Panasonic DMC-GF3", 15, 0xfd2, /* RT - Colin Walker - WL 4050 */
{ 8074, -1846, -861, -5026, 12999, 2239, -1320, 2375, 7422 }
},
{
"Panasonic DMC-GH1", 15, 0xf5a, /* RT - Colin Walker - variable WL 3930 - 4080 */
{ 6360, -1557, -375, -4201, 11504, 3086, -1378, 2518, 5843 }
},
{
"Panasonic DMC-GH2", 15, 0xf5a, /* RT - Colin Walker - variable WL 3930 - 4080 */
// { 6855,-1765,-456,-4223,11600,2996,-1450,2602,5761 } }, disabled due to problems with underwater WB
{ 7780, -2410, -806, -3913, 11724, 2484, -1018, 2390, 5298 }
}, // dcraw original
{
"Pentax K200D", -1, -1, /* RT */
{ 10962, -4428, -542, -5486, 13023, 2748, -569, 842, 8390 }
},
{
"Leica Camera AG M9 Digital Camera", -1, -1, /* RT */
{ 7181, -1706, -55, -3557, 11409, 2450, -621, 2072, 7533 }
},
{
"SONY NEX-3", 128 << dcraw_arw2_scaling_bugfix_shift, -1, /* RT - Colin Walker */
{ 5145, -741, -123, -4915, 12310, 2945, -794, 1489, 6906 }
},
{
"SONY NEX-5", 128 << dcraw_arw2_scaling_bugfix_shift, -1, /* RT - Colin Walker */
{ 5154, -716, -115, -5065, 12506, 2882, -988, 1715, 6800 }
},
{
"Sony NEX-5N", 128 << dcraw_arw2_scaling_bugfix_shift, -1, /* RT - Colin Walker */
{ 5130, -1055, -269, -4473, 11797, 3050, -701, 1310, 7121 }
},
{
"Sony NEX-5R", 128 << dcraw_arw2_scaling_bugfix_shift, -1,
{ 6129, -1545, -418, -4930, 12490, 2743, -977, 1693, 6615 }
},
{
"SONY NEX-C3", 128 << dcraw_arw2_scaling_bugfix_shift, -1, /* RT - Colin Walker */
{ 5130, -1055, -269, -4473, 11797, 3050, -701, 1310, 7121 }
},
{
"Sony SLT-A77", 128 << dcraw_arw2_scaling_bugfix_shift, -1, /* RT - Colin Walker */
{ 5126, -830, -261, -4788, 12196, 2934, -948, 1602, 7068 }
},
};
*black_level = -1;
*white_level = -1;
const bool is_pentax_dng = dng_version && !strncmp(RT_software.c_str(), "PENTAX", 6);
if (RT_blacklevel_from_constant == ThreeValBool::F && !is_pentax_dng) {
*black_level = black;
}
if (RT_whitelevel_from_constant == ThreeValBool::F && !is_pentax_dng) {
*white_level = maximum;
}
memset(trans, 0, sizeof(*trans) * 12);
// // indicate that DCRAW wants these from constants (rather than having loaded these from RAW file
// // note: this is simplified so far, in some cases dcraw calls this when it has say the black level
// // from file, but then we will not provide any black level in the tables. This case is mainly just
// // to avoid loading table values if we have loaded a DNG conversion of a raw file (which already
// // have constants stored in the file).
// if (RT_whitelevel_from_constant == ThreeValBool::X || is_pentax_dng) {
// RT_whitelevel_from_constant = ThreeValBool::T;
// }
// if (RT_blacklevel_from_constant == ThreeValBool::X || is_pentax_dng) {
// RT_blacklevel_from_constant = ThreeValBool::T;
// }
// if (RT_matrix_from_constant == ThreeValBool::X) {
// RT_matrix_from_constant = ThreeValBool::T;
// }
{
// test if we have any information in the camera constants store, if so we take that.
rtengine::CameraConstantsStore* ccs = rtengine::CameraConstantsStore::getInstance();
rtengine::CameraConst *cc = ccs->get(make, model);
if (cc) {
if (RT_blacklevel_from_constant == ThreeValBool::T) {
*black_level = cc->get_BlackLevel(0, iso_speed);
}
if (RT_whitelevel_from_constant == ThreeValBool::T) {
*white_level = cc->get_WhiteLevel(0, iso_speed, aperture);
}
if (RT_matrix_from_constant == ThreeValBool::T && cc->has_dcrawMatrix()) {
const short *mx = cc->get_dcrawMatrix();
for (int j = 0; j < 12; j++) {
trans[j] = mx[j];
}
}
return true;
}
}
char name[strlen(make) + strlen(model) + 32];
sprintf(name, "%s %s", make, model);
for (size_t i = 0; i < sizeof table / sizeof(table[0]); i++) {
if (strcasecmp(name, table[i].prefix) == 0) {
if (RT_blacklevel_from_constant == ThreeValBool::T) {
*black_level = table[i].black_level;
}
if (RT_whitelevel_from_constant == ThreeValBool::T) {
*white_level = table[i].white_level;
}
for (int j = 0; j < 12; j++) {
trans[j] = table[i].trans[j];
}
return true;
}
}
return false;
}
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