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rawTherapee/rtengine/dcrop.cc
heckflosse c45ec6f16e Speedup and bugfix for new Sh/Hl tool
2018-04-26 14:32:43 +02:00

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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
* 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 <http://www.gnu.org/licenses/>.
*/
#include "dcrop.h"
#include "curves.h"
#include "mytime.h"
#include "refreshmap.h"
#include "rt_math.h"
namespace
{
// "ceil" rounding
template<typename T>
constexpr T skips (T a, T b)
{
return a / b + static_cast<bool> (a % b);
}
}
namespace rtengine
{
extern const Settings* settings;
Crop::Crop (ImProcCoordinator* parent, EditDataProvider *editDataProvider, bool isDetailWindow)
: PipetteBuffer (editDataProvider), origCrop (nullptr), laboCrop (nullptr), labnCrop (nullptr),
cropImg (nullptr), cbuf_real (nullptr), transCrop (nullptr), cieCrop (nullptr), cbuffer (nullptr),
updating (false), newUpdatePending (false), skip (10),
cropx (0), cropy (0), cropw (-1), croph (-1),
trafx (0), trafy (0), trafw (-1), trafh (-1),
rqcropx (0), rqcropy (0), rqcropw (-1), rqcroph (-1),
borderRequested (32), upperBorder (0), leftBorder (0),
cropAllocated (false),
cropImageListener (nullptr), parent (parent), isDetailWindow (isDetailWindow)
{
parent->crops.push_back (this);
}
Crop::~Crop ()
{
MyMutex::MyLock cropLock (cropMutex);
std::vector<Crop*>::iterator i = std::find (parent->crops.begin(), parent->crops.end(), this);
if (i != parent->crops.end ()) {
parent->crops.erase (i);
}
MyMutex::MyLock processingLock (parent->mProcessing);
freeAll ();
}
void Crop::destroy ()
{
MyMutex::MyLock lock (cropMutex);
MyMutex::MyLock processingLock (parent->mProcessing);
freeAll();
}
void Crop::setListener (DetailedCropListener* il)
{
// We can make reads in the IF, because the mProcessing lock is only needed for change
if (cropImageListener != il) {
MyMutex::MyLock lock (cropMutex);
cropImageListener = il;
}
}
EditUniqueID Crop::getCurrEditID()
{
EditSubscriber *subscriber = PipetteBuffer::dataProvider ? PipetteBuffer::dataProvider->getCurrSubscriber() : nullptr;
return subscriber ? subscriber->getEditID() : EUID_None;
}
/*
* Delete the edit image buffer if there's no subscriber anymore.
* If allocation has to be done, it is deferred to Crop::update
*/
void Crop::setEditSubscriber (EditSubscriber* newSubscriber)
{
MyMutex::MyLock lock (cropMutex);
// At this point, editCrop.dataProvider->currSubscriber is the old subscriber
EditSubscriber *oldSubscriber = PipetteBuffer::dataProvider ? PipetteBuffer::dataProvider->getCurrSubscriber() : nullptr;
if (newSubscriber == nullptr || (oldSubscriber != nullptr && oldSubscriber->getPipetteBufferType() != newSubscriber->getPipetteBufferType())) {
if (PipetteBuffer::imgFloatBuffer != nullptr) {
delete PipetteBuffer::imgFloatBuffer;
PipetteBuffer::imgFloatBuffer = nullptr;
}
if (PipetteBuffer::LabBuffer != nullptr) {
delete PipetteBuffer::LabBuffer;
PipetteBuffer::LabBuffer = nullptr;
}
if (PipetteBuffer::singlePlaneBuffer.getWidth() != -1) {
PipetteBuffer::singlePlaneBuffer.flushData();
}
}
// If oldSubscriber == NULL && newSubscriber != NULL && newSubscriber->getEditingType() == ET_PIPETTE-> the image will be allocated when necessary
}
bool Crop::hasListener()
{
MyMutex::MyLock cropLock (cropMutex);
return cropImageListener;
}
void Crop::update (int todo)
{
MyMutex::MyLock cropLock (cropMutex);
ProcParams& params = parent->params;
// CropGUIListener* cropgl;
// No need to update todo here, since it has already been changed in ImprocCoordinator::updatePreviewImage,
// and Crop::update ask to do ALL anyway
// give possibility to the listener to modify crop window (as the full image dimensions are already known at this point)
int wx, wy, ww, wh, ws;
bool overrideWindow = false;
if (cropImageListener) {
overrideWindow = cropImageListener->getWindow (wx, wy, ww, wh, ws);
}
// re-allocate sub-images and arrays if their dimensions changed
bool needsinitupdate = false;
if (!overrideWindow) {
needsinitupdate = setCropSizes (rqcropx, rqcropy, rqcropw, rqcroph, skip, true);
} else {
needsinitupdate = setCropSizes (wx, wy, ww, wh, ws, true); // this set skip=ws
}
// it something has been reallocated, all processing steps have to be performed
if (needsinitupdate || (todo & M_HIGHQUAL)) {
todo = ALL;
}
// Tells to the ImProcFunctions' tool what is the preview scale, which may lead to some simplifications
parent->ipf.setScale (skip);
Imagefloat* baseCrop = origCrop;
int widIm = parent->fw;//full image
int heiIm = parent->fh;
bool needstransform = parent->ipf.needsTransform();
if (todo & (M_INIT | M_LINDENOISE | M_HDR)) {
MyMutex::MyLock lock (parent->minit); // Also used in improccoord
int tr = getCoarseBitMask (params.coarse);
if (!needsinitupdate) {
setCropSizes (rqcropx, rqcropy, rqcropw, rqcroph, skip, true);
}
// printf("x=%d y=%d crow=%d croh=%d skip=%d\n",rqcropx, rqcropy, rqcropw, rqcroph, skip);
// printf("trafx=%d trafyy=%d trafwsk=%d trafHs=%d \n",trafx, trafy, trafw*skip, trafh*skip);
Imagefloat *calclum = nullptr;//for Luminance denoise curve
NoiseCurve noiseLCurve;
NoiseCurve noiseCCurve;
float autoNR = (float) settings->nrauto;//
float autoNRmax = (float) settings->nrautomax;//
params.dirpyrDenoise.getCurves (noiseLCurve, noiseCCurve);
int tilesize;
int overlap;
if (settings->leveldnti == 0) {
tilesize = 1024;
overlap = 128;
}
if (settings->leveldnti == 1) {
tilesize = 768;
overlap = 96;
}
int numtiles_W, numtiles_H, tilewidth, tileheight, tileWskip, tileHskip;
int kall = 2;
parent->ipf.Tile_calc (tilesize, overlap, kall, widIm, heiIm, numtiles_W, numtiles_H, tilewidth, tileheight, tileWskip, tileHskip);
kall = 0;
float *min_b = new float [9];
float *min_r = new float [9];
float *lumL = new float [9];
float *chromC = new float [9];
float *ry = new float [9];
float *sk = new float [9];
float *pcsk = new float [9];
int *centerTile_X = new int [numtiles_W];
int *centerTile_Y = new int [numtiles_H];
for (int cX = 0; cX < numtiles_W; cX++) {
centerTile_X[cX] = tileWskip / 2 + tileWskip * cX;
}
for (int cY = 0; cY < numtiles_H; cY++) {
centerTile_Y[cY] = tileHskip / 2 + tileHskip * cY;
}
if (settings->leveldnautsimpl == 1) {
if (params.dirpyrDenoise.Cmethod == "MAN" || params.dirpyrDenoise.Cmethod == "PON" ) {
PreviewProps pp (trafx, trafy, trafw * skip, trafh * skip, skip);
parent->imgsrc->getImage (parent->currWB, tr, origCrop, pp, params.toneCurve, params.raw );
}
} else {
if (params.dirpyrDenoise.C2method == "MANU") {
PreviewProps pp (trafx, trafy, trafw * skip, trafh * skip, skip);
parent->imgsrc->getImage (parent->currWB, tr, origCrop, pp, params.toneCurve, params.raw );
}
}
if ((settings->leveldnautsimpl == 1 && params.dirpyrDenoise.Cmethod == "PRE") || (settings->leveldnautsimpl == 0 && params.dirpyrDenoise.C2method == "PREV")) {
PreviewProps pp (trafx, trafy, trafw * skip, trafh * skip, skip);
parent->imgsrc->getImage (parent->currWB, tr, origCrop, pp, params.toneCurve, params.raw );
if ((!isDetailWindow) && parent->adnListener && skip == 1 && params.dirpyrDenoise.enabled) {
float lowdenoise = 1.f;
int levaut = settings->leveldnaut;
if (levaut == 1) { //Standard
lowdenoise = 0.7f;
}
int CenterPreview_X = trafx + (trafw * skip) / 2;
int CenterPreview_Y = trafy + (trafh * skip) / 2;
int minimuX = 20000;
int minimuY = 20000;
int poscenterX = 0;
int poscenterY = 0;
for (int cc = 0; cc < numtiles_W; cc++) {
if (abs (centerTile_X[cc] - CenterPreview_X) < minimuX) {
minimuX = abs (centerTile_X[cc] - CenterPreview_X);
poscenterX = cc;
}
}
for (int cc = 0; cc < numtiles_H; cc++) {
if (abs (centerTile_Y[cc] - CenterPreview_Y) < minimuY) {
minimuY = abs (centerTile_Y[cc] - CenterPreview_Y);
poscenterY = cc;
}
}
// printf("TileCX=%d TileCY=%d prevX=%d prevY=%d \n",centerTile_X[poscenterX],centerTile_Y[poscenterY],CenterPreview_X,CenterPreview_Y);
int crW;
if (settings->leveldnv == 0) {
crW = 100;
}
if (settings->leveldnv == 1) {
crW = 250;
}
// if(settings->leveldnv ==2) {crW=int(tileWskip/2);crH=int((tileWskip/2));}//adapted to scale of preview
if (settings->leveldnv == 2) {
crW = int (tileWskip / 2);
}
if (settings->leveldnv == 3) {
crW = tileWskip - 10;
}
float adjustr = 1.f;
if (params.icm.working == "ProPhoto") {
adjustr = 1.f;
} else if (params.icm.working == "Adobe RGB") {
adjustr = 1.f / 1.3f;
} else if (params.icm.working == "sRGB") {
adjustr = 1.f / 1.3f;
} else if (params.icm.working == "WideGamut") {
adjustr = 1.f / 1.1f;
} else if (params.icm.working == "Beta RGB") {
adjustr = 1.f / 1.2f;
} else if (params.icm.working == "BestRGB") {
adjustr = 1.f / 1.2f;
} else if (params.icm.working == "BruceRGB") {
adjustr = 1.f / 1.2f;
}
if (parent->adnListener) {
parent->adnListener->noiseTilePrev (centerTile_X[poscenterX], centerTile_Y[poscenterY], CenterPreview_X, CenterPreview_Y, crW, trafw * skip);
}
// I have tried "blind" some solutions..to move review ...but GUI is not my truc !
// int W,H;
// cropgl->cropMoved (centerTile_X[poscenterX],centerTile_Y[poscenterY] , W, H);
// cropImageListener->setPosition (int x, int y, bool update=true);
// bool update;
// cropImageListener->setPosition (centerTile_X[poscenterX],centerTile_Y[poscenterY] , true);
//setCropSizes (centerTile_X[poscenterX], centerTile_Y[poscenterY], trafw*skip,trafh*skip , skip, true);
// we only need image reduced to 1/4 here
int W = origCrop->getWidth();
int H = origCrop->getHeight();
Imagefloat *provicalc = new Imagefloat ((W + 1) / 2, (H + 1) / 2); //for denoise curves
for (int ii = 0; ii < H; ii += 2) {
for (int jj = 0; jj < W; jj += 2) {
provicalc->r (ii >> 1, jj >> 1) = origCrop->r (ii, jj);
provicalc->g (ii >> 1, jj >> 1) = origCrop->g (ii, jj);
provicalc->b (ii >> 1, jj >> 1) = origCrop->b (ii, jj);
}
}
parent->imgsrc->convertColorSpace (provicalc, params.icm, parent->currWB); //for denoise luminance curve
float maxr = 0.f;
float maxb = 0.f;
float chaut, redaut, blueaut, maxredaut, maxblueaut, minredaut, minblueaut, chromina, sigma, lumema, sigma_L, redyel, skinc, nsknc;
int Nb;
chaut = 0.f;
redaut = 0.f;
blueaut = 0.f;
maxredaut = 0.f;
maxblueaut = 0.f;
minredaut = 0.f;
minblueaut = 0.f;
LUTf gamcurve (65536, 0);
float gam, gamthresh, gamslope;
parent->ipf.RGB_denoise_infoGamCurve (params.dirpyrDenoise, parent->imgsrc->isRAW(), gamcurve, gam, gamthresh, gamslope);
parent->ipf.RGB_denoise_info (origCrop, provicalc, parent->imgsrc->isRAW(), gamcurve, gam, gamthresh, gamslope, params.dirpyrDenoise, parent->imgsrc->getDirPyrDenoiseExpComp(), chaut, Nb, redaut, blueaut, maxredaut, maxblueaut, minredaut, minblueaut, chromina, sigma, lumema, sigma_L, redyel, skinc, nsknc, true);
// printf("redy=%f skin=%f pcskin=%f\n",redyel, skinc,nsknc);
// printf("DCROP skip=%d cha=%4.0f Nb=%d red=%4.0f bl=%4.0f redM=%4.0f bluM=%4.0f L=%4.0f sigL=%4.0f Ch=%4.0f Si=%4.0f\n",skip, chaut,Nb, redaut,blueaut, maxredaut, maxblueaut, lumema, sigma_L, chromina, sigma);
float multip = 1.f;
if (!parent->imgsrc->isRAW()) {
multip = 2.f; //take into account gamma for TIF / JPG approximate value...not good for gamma=1
}
float maxmax = max (maxredaut, maxblueaut);
float delta;
int mode = 0;
// float redyel, skinc, nsknc;
int lissage = settings->leveldnliss;
parent->ipf.calcautodn_info (chaut, delta, Nb, levaut, maxmax, lumema, chromina, mode, lissage, redyel, skinc, nsknc);
if (maxredaut > maxblueaut) {
// maxr=(maxredaut-chaut)/((autoNRmax*multip*adjustr)/2.f);
maxr = (delta) / ((autoNRmax * multip * adjustr * lowdenoise) / 2.f);
if (minblueaut <= minredaut && minblueaut < chaut) {
maxb = (-chaut + minblueaut) / (autoNRmax * multip * adjustr * lowdenoise);
}
} else {
// maxb=(maxblueaut-chaut)/((autoNRmax*multip*adjustr)/2.f);
maxb = (delta) / ((autoNRmax * multip * adjustr * lowdenoise) / 2.f);
if (minredaut <= minblueaut && minredaut < chaut) {
maxr = (-chaut + minredaut) / (autoNRmax * multip * adjustr * lowdenoise);
}
}//maxb mxr - empirical evaluation red / blue
params.dirpyrDenoise.chroma = chaut / (autoNR * multip * adjustr * lowdenoise);
params.dirpyrDenoise.redchro = maxr;
params.dirpyrDenoise.bluechro = maxb;
parent->adnListener->chromaChanged (params.dirpyrDenoise.chroma, params.dirpyrDenoise.redchro, params.dirpyrDenoise.bluechro);
delete provicalc;
}
}
if (skip == 1 && params.dirpyrDenoise.enabled && !parent->denoiseInfoStore.valid && ((settings->leveldnautsimpl == 1 && params.dirpyrDenoise.Cmethod == "AUT") || (settings->leveldnautsimpl == 0 && params.dirpyrDenoise.C2method == "AUTO"))) {
MyTime t1aue, t2aue;
t1aue.set();
int crW = 100; // settings->leveldnv == 0
int crH = 100; // settings->leveldnv == 0
if (settings->leveldnv == 1) {
crW = 250;
crH = 250;
}
// if(settings->leveldnv ==2) {crW=int(tileWskip/2);crH=int((tileWskip/2));}//adapted to scale of preview
if (settings->leveldnv == 2) {
crW = int (tileWskip / 2);
crH = int (tileHskip / 2);
}
if (settings->leveldnv == 3) {
crW = tileWskip - 10;
crH = tileHskip - 10;
}
float lowdenoise = 1.f;
int levaut = settings->leveldnaut;
if (levaut == 1) { //Standard
lowdenoise = 0.7f;
}
LUTf gamcurve (65536, 0);
float gam, gamthresh, gamslope;
parent->ipf.RGB_denoise_infoGamCurve (params.dirpyrDenoise, parent->imgsrc->isRAW(), gamcurve, gam, gamthresh, gamslope);
int Nb[9];
#ifdef _OPENMP
#pragma omp parallel
#endif
{
Imagefloat *origCropPart = new Imagefloat (crW, crH);//allocate memory
Imagefloat *provicalc = new Imagefloat ((crW + 1) / 2, (crH + 1) / 2); //for denoise curves
int coordW[3];//coordinate of part of image to measure noise
int coordH[3];
int begW = 50;
int begH = 50;
coordW[0] = begW;
coordW[1] = widIm / 2 - crW / 2;
coordW[2] = widIm - crW - begW;
coordH[0] = begH;
coordH[1] = heiIm / 2 - crH / 2;
coordH[2] = heiIm - crH - begH;
#ifdef _OPENMP
#pragma omp for schedule(dynamic) collapse(2) nowait
#endif
for (int wcr = 0; wcr <= 2; wcr++) {
for (int hcr = 0; hcr <= 2; hcr++) {
PreviewProps ppP (coordW[wcr], coordH[hcr], crW, crH, 1);
parent->imgsrc->getImage (parent->currWB, tr, origCropPart, ppP, params.toneCurve, params.raw );
// we only need image reduced to 1/4 here
for (int ii = 0; ii < crH; ii += 2) {
for (int jj = 0; jj < crW; jj += 2) {
provicalc->r (ii >> 1, jj >> 1) = origCropPart->r (ii, jj);
provicalc->g (ii >> 1, jj >> 1) = origCropPart->g (ii, jj);
provicalc->b (ii >> 1, jj >> 1) = origCropPart->b (ii, jj);
}
}
parent->imgsrc->convertColorSpace (provicalc, params.icm, parent->currWB); //for denoise luminance curve
float pondcorrec = 1.0f;
float chaut = 0.f, redaut = 0.f, blueaut = 0.f, maxredaut = 0.f, maxblueaut = 0.f, minredaut = 0.f, minblueaut = 0.f, chromina = 0.f, sigma = 0.f, lumema = 0.f, sigma_L = 0.f, redyel = 0.f, skinc = 0.f, nsknc = 0.f;
int nb = 0;
parent->ipf.RGB_denoise_info (origCropPart, provicalc, parent->imgsrc->isRAW(), gamcurve, gam, gamthresh, gamslope, params.dirpyrDenoise, parent->imgsrc->getDirPyrDenoiseExpComp(), chaut, nb, redaut, blueaut, maxredaut, maxblueaut, minredaut, minblueaut, chromina, sigma, lumema, sigma_L, redyel, skinc, nsknc);
//printf("DCROP skip=%d cha=%f red=%f bl=%f redM=%f bluM=%f chrom=%f sigm=%f lum=%f\n",skip, chaut,redaut,blueaut, maxredaut, maxblueaut, chromina, sigma, lumema);
Nb[hcr * 3 + wcr] = nb;
parent->denoiseInfoStore.ch_M[hcr * 3 + wcr] = pondcorrec * chaut;
parent->denoiseInfoStore.max_r[hcr * 3 + wcr] = pondcorrec * maxredaut;
parent->denoiseInfoStore.max_b[hcr * 3 + wcr] = pondcorrec * maxblueaut;
min_r[hcr * 3 + wcr] = pondcorrec * minredaut;
min_b[hcr * 3 + wcr] = pondcorrec * minblueaut;
lumL[hcr * 3 + wcr] = lumema;
chromC[hcr * 3 + wcr] = chromina;
ry[hcr * 3 + wcr] = redyel;
sk[hcr * 3 + wcr] = skinc;
pcsk[hcr * 3 + wcr] = nsknc;
}
}
delete provicalc;
delete origCropPart;
}
float chM = 0.f;
float MaxR = 0.f;
float MaxB = 0.f;
float MinR = 100000000000.f;
float MinB = 100000000000.f;
float maxr = 0.f;
float maxb = 0.f;
float Max_R[9] = {0.f, 0.f, 0.f, 0.f, 0.f, 0.f, 0.f, 0.f, 0.f};
float Max_B[9] = {0.f, 0.f, 0.f, 0.f, 0.f, 0.f, 0.f, 0.f, 0.f};
float Min_R[9];
float Min_B[9];
float MaxRMoy = 0.f;
float MaxBMoy = 0.f;
float MinRMoy = 0.f;
float MinBMoy = 0.f;
float multip = 1.f;
if (!parent->imgsrc->isRAW()) {
multip = 2.f; //take into account gamma for TIF / JPG approximate value...not good for gamma=1
}
float adjustr = 1.f;
if (params.icm.working == "ProPhoto") {
adjustr = 1.f; //
} else if (params.icm.working == "Adobe RGB") {
adjustr = 1.f / 1.3f;
} else if (params.icm.working == "sRGB") {
adjustr = 1.f / 1.3f;
} else if (params.icm.working == "WideGamut") {
adjustr = 1.f / 1.1f;
} else if (params.icm.working == "Beta RGB") {
adjustr = 1.f / 1.2f;
} else if (params.icm.working == "BestRGB") {
adjustr = 1.f / 1.2f;
} else if (params.icm.working == "BruceRGB") {
adjustr = 1.f / 1.2f;
}
float delta[9];
int mode = 1;
int lissage = settings->leveldnliss;
for (int k = 0; k < 9; k++) {
float maxmax = max (parent->denoiseInfoStore.max_r[k], parent->denoiseInfoStore.max_b[k]);
parent->ipf.calcautodn_info (parent->denoiseInfoStore.ch_M[k], delta[k], Nb[k], levaut, maxmax, lumL[k], chromC[k], mode, lissage, ry[k], sk[k], pcsk[k]);
// printf("ch_M=%f delta=%f\n",ch_M[k], delta[k]);
}
for (int k = 0; k < 9; k++) {
if (parent->denoiseInfoStore.max_r[k] > parent->denoiseInfoStore.max_b[k]) {
Max_R[k] = (delta[k]) / ((autoNRmax * multip * adjustr * lowdenoise) / 2.f);
Min_B[k] = - (parent->denoiseInfoStore.ch_M[k] - min_b[k]) / (autoNRmax * multip * adjustr * lowdenoise);
Max_B[k] = 0.f;
Min_R[k] = 0.f;
} else {
Max_B[k] = (delta[k]) / ((autoNRmax * multip * adjustr * lowdenoise) / 2.f);
Min_R[k] = - (parent->denoiseInfoStore.ch_M[k] - min_r[k]) / (autoNRmax * multip * adjustr * lowdenoise);
Min_B[k] = 0.f;
Max_R[k] = 0.f;
}
}
for (int k = 0; k < 9; k++) {
// printf("ch_M= %f Max_R=%f Max_B=%f min_r=%f min_b=%f\n",ch_M[k],Max_R[k], Max_B[k],Min_R[k], Min_B[k]);
chM += parent->denoiseInfoStore.ch_M[k];
MaxBMoy += Max_B[k];
MaxRMoy += Max_R[k];
MinRMoy += Min_R[k];
MinBMoy += Min_B[k];
if (Max_R[k] > MaxR) {
MaxR = Max_R[k];
}
if (Max_B[k] > MaxB) {
MaxB = Max_B[k];
}
if (Min_R[k] < MinR) {
MinR = Min_R[k];
}
if (Min_B[k] < MinB) {
MinB = Min_B[k];
}
}
chM /= 9;
MaxBMoy /= 9;
MaxRMoy /= 9;
MinBMoy /= 9;
MinRMoy /= 9;
if (MaxR > MaxB) {
maxr = MaxRMoy + (MaxR - MaxRMoy) * 0.66f; //#std Dev
//maxb=MinB;
maxb = MinBMoy + (MinB - MinBMoy) * 0.66f;
} else {
maxb = MaxBMoy + (MaxB - MaxBMoy) * 0.66f;
maxr = MinRMoy + (MinR - MinRMoy) * 0.66f;
}
// printf("DCROP skip=%d cha=%f red=%f bl=%f \n",skip, chM,maxr,maxb);
params.dirpyrDenoise.chroma = chM / (autoNR * multip * adjustr);
params.dirpyrDenoise.redchro = maxr;
params.dirpyrDenoise.bluechro = maxb;
parent->denoiseInfoStore.valid = true;
if (parent->adnListener) {
parent->adnListener->chromaChanged (params.dirpyrDenoise.chroma, params.dirpyrDenoise.redchro, params.dirpyrDenoise.bluechro);
}
if (settings->verbose) {
t2aue.set();
printf ("Info denoise auto performed in %d usec:\n", t2aue.etime (t1aue));
}
//end evaluate noise
}
// if(params.dirpyrDenoise.Cmethod=="AUT" || params.dirpyrDenoise.Cmethod=="PON") {//reinit origCrop after Auto
if ((settings->leveldnautsimpl == 1 && params.dirpyrDenoise.Cmethod == "AUT") || (settings->leveldnautsimpl == 0 && params.dirpyrDenoise.C2method == "AUTO")) { //reinit origCrop after Auto
PreviewProps pp (trafx, trafy, trafw * skip, trafh * skip, skip);
parent->imgsrc->getImage (parent->currWB, tr, origCrop, pp, params.toneCurve, params.raw );
}
DirPyrDenoiseParams denoiseParams = params.dirpyrDenoise;
if (params.dirpyrDenoise.Lmethod == "CUR") {
if (noiseLCurve) {
denoiseParams.luma = 0.5f; //very small value to init process - select curve or slider
} else {
denoiseParams.luma = 0.0f;
}
} else if (denoiseParams.Lmethod == "SLI") {
noiseLCurve.Reset();
}
if ((noiseLCurve || noiseCCurve ) && skip == 1 && denoiseParams.enabled) { //only allocate memory if enabled and skip
// we only need image reduced to 1/4 here
int W = origCrop->getWidth();
int H = origCrop->getHeight();
calclum = new Imagefloat ((W + 1) / 2, (H + 1) / 2); //for denoise curves
for (int ii = 0; ii < H; ii += 2) {
for (int jj = 0; jj < W; jj += 2) {
calclum->r (ii >> 1, jj >> 1) = origCrop->r (ii, jj);
calclum->g (ii >> 1, jj >> 1) = origCrop->g (ii, jj);
calclum->b (ii >> 1, jj >> 1) = origCrop->b (ii, jj);
}
}
parent->imgsrc->convertColorSpace (calclum, params.icm, parent->currWB); //for denoise luminance curve
}
if (skip != 1) if (parent->adnListener) {
parent->adnListener->noiseChanged (0.f, 0.f);
}
if (todo & M_LINDENOISE) {
if (skip == 1 && denoiseParams.enabled) {
int kall = 0;
float nresi, highresi;
parent->ipf.RGB_denoise (kall, origCrop, origCrop, calclum, parent->denoiseInfoStore.ch_M, parent->denoiseInfoStore.max_r, parent->denoiseInfoStore.max_b, parent->imgsrc->isRAW(), /*Roffset,*/ denoiseParams, parent->imgsrc->getDirPyrDenoiseExpComp(), noiseLCurve, noiseCCurve, nresi, highresi);
if (parent->adnListener) {
parent->adnListener->noiseChanged (nresi, highresi);
}
if (settings->leveldnautsimpl == 1) {
if ((denoiseParams.Cmethod == "AUT" || denoiseParams.Cmethod == "PRE") && (parent->adnListener)) { // force display value of sliders
parent->adnListener->chromaChanged (denoiseParams.chroma, denoiseParams.redchro, denoiseParams.bluechro);
}
} else {
if ((denoiseParams.C2method == "AUTO" || denoiseParams.C2method == "PREV") && (parent->adnListener)) { // force display value of sliders
parent->adnListener->chromaChanged (denoiseParams.chroma, denoiseParams.redchro, denoiseParams.bluechro);
}
}
}
}
parent->imgsrc->convertColorSpace (origCrop, params.icm, parent->currWB);
delete [] min_r;
delete [] min_b;
delete [] lumL;
delete [] chromC;
delete [] ry;
delete [] sk;
delete [] pcsk;
delete [] centerTile_X;
delete [] centerTile_Y;
}
// has to be called after setCropSizes! Tools prior to this point can't handle the Edit mechanism, but that shouldn't be a problem.
createBuffer (cropw, croph);
std::unique_ptr<Imagefloat> fattalCrop;
if ((todo & M_HDR) && params.fattal.enabled) {
Imagefloat *f = origCrop;
int fw = skips(parent->fw, skip);
int fh = skips(parent->fh, skip);
bool need_cropping = false;
bool need_fattal = true;
if (trafx || trafy || trafw != fw || trafh != fh) {
need_cropping = true;
// fattal needs to work on the full image. So here we get the full
// image from imgsrc, and replace the denoised crop in case
if (!params.dirpyrDenoise.enabled && skip == 1 && parent->fattal_11_dcrop_cache) {
f = parent->fattal_11_dcrop_cache;
need_fattal = false;
} else {
f = new Imagefloat(fw, fh);
fattalCrop.reset(f);
PreviewProps pp (0, 0, parent->fw, parent->fh, skip);
int tr = getCoarseBitMask(params.coarse);
parent->imgsrc->getImage(parent->currWB, tr, f, pp, params.toneCurve, params.raw);
parent->imgsrc->convertColorSpace(f, params.icm, parent->currWB);
if (params.dirpyrDenoise.enabled) {
// copy the denoised crop
int oy = trafy / skip;
int ox = trafx / skip;
#ifdef _OPENMP
#pragma omp parallel for
#endif
for (int y = 0; y < baseCrop->getHeight(); ++y) {
int dy = oy + y;
for (int x = 0; x < baseCrop->getWidth(); ++x) {
int dx = ox + x;
f->r(dy, dx) = baseCrop->r(y, x);
f->g(dy, dx) = baseCrop->g(y, x);
f->b(dy, dx) = baseCrop->b(y, x);
}
}
} else if (skip == 1) {
parent->fattal_11_dcrop_cache = f; // cache this globally
fattalCrop.release();
}
}
}
if (need_fattal) {
parent->ipf.ToneMapFattal02(f);
}
// crop back to the size expected by the rest of the pipeline
if (need_cropping) {
Imagefloat *c = origCrop;
int oy = trafy / skip;
int ox = trafx / skip;
#ifdef _OPENMP
#pragma omp parallel for
#endif
for (int y = 0; y < trafh; ++y) {
int cy = y + oy;
for (int x = 0; x < trafw; ++x) {
int cx = x + ox;
c->r(y, x) = f->r(cy, cx);
c->g(y, x) = f->g(cy, cx);
c->b(y, x) = f->b(cy, cx);
}
}
baseCrop = c;
} else {
baseCrop = f;
}
}
// transform
if (needstransform || ((todo & (M_TRANSFORM | M_RGBCURVE)) && params.dirpyrequalizer.cbdlMethod == "bef" && params.dirpyrequalizer.enabled && !params.colorappearance.enabled)) {
if (!transCrop) {
transCrop = new Imagefloat (cropw, croph);
}
if (needstransform)
parent->ipf.transform (baseCrop, transCrop, cropx / skip, cropy / skip, trafx / skip, trafy / skip, skips (parent->fw, skip), skips (parent->fh, skip), parent->getFullWidth(), parent->getFullHeight(),
parent->imgsrc->getMetaData(),
parent->imgsrc->getRotateDegree(), false);
else {
baseCrop->copyData (transCrop);
}
if (transCrop) {
baseCrop = transCrop;
}
} else {
if (transCrop) {
delete transCrop;
}
transCrop = nullptr;
}
if ((todo & (M_TRANSFORM | M_RGBCURVE)) && params.dirpyrequalizer.cbdlMethod == "bef" && params.dirpyrequalizer.enabled && !params.colorappearance.enabled) {
const int W = baseCrop->getWidth();
const int H = baseCrop->getHeight();
LabImage labcbdl (W, H);
parent->ipf.rgb2lab (*baseCrop, labcbdl, params.icm.working);
parent->ipf.dirpyrequalizer (&labcbdl, skip);
parent->ipf.lab2rgb (labcbdl, *baseCrop, params.icm.working);
}
if (todo & M_RGBCURVE) {
double rrm, ggm, bbm;
DCPProfile::ApplyState as;
DCPProfile *dcpProf = parent->imgsrc->getDCP (params.icm, as);
LUTu histToneCurve;
parent->ipf.rgbProc (baseCrop, laboCrop, this, parent->hltonecurve, parent->shtonecurve, parent->tonecurve,
params.toneCurve.saturation, parent->rCurve, parent->gCurve, parent->bCurve, parent->colourToningSatLimit, parent->colourToningSatLimitOpacity, parent->ctColorCurve, parent->ctOpacityCurve, parent->opautili, parent->clToningcurve, parent->cl2Toningcurve,
parent->customToneCurve1, parent->customToneCurve2, parent->beforeToneCurveBW, parent->afterToneCurveBW, rrm, ggm, bbm,
parent->bwAutoR, parent->bwAutoG, parent->bwAutoB, dcpProf, as, histToneCurve);
}
/*xref=000;yref=000;
if (colortest && cropw>115 && croph>115)
for(int j=1;j<5;j++){
xref+=j*30;yref+=j*30;
if (settings->verbose) {
printf("after rgbProc RGB Xr%i Yr%i Skip=%d R=%f G=%f B=%f \n",xref,yref,skip,
baseCrop->r[(int)(xref/skip)][(int)(yref/skip)]/256,
baseCrop->g[(int)(xref/skip)][(int)(yref/skip)]/256,
baseCrop->b[(int)(xref/skip)][(int)(yref/skip)]/256);
printf("after rgbProc Lab Xr%i Yr%i Skip=%d l=%f a=%f b=%f \n",xref,yref,skip,
laboCrop->L[(int)(xref/skip)][(int)(yref/skip)]/327,
laboCrop->a[(int)(xref/skip)][(int)(yref/skip)]/327,
laboCrop->b[(int)(xref/skip)][(int)(yref/skip)]/327);
}
}*/
// apply luminance operations
if (todo & (M_LUMINANCE + M_COLOR)) {
//I made a little change here. Rather than have luminanceCurve (and others) use in/out lab images, we can do more if we copy right here.
labnCrop->CopyFrom (laboCrop);
//parent->ipf.luminanceCurve (labnCrop, labnCrop, parent->lumacurve);
bool utili = parent->utili;
bool autili = parent->autili;
bool butili = parent->butili;
bool ccutili = parent->ccutili;
bool clcutili = parent->clcutili;
bool cclutili = parent->cclutili;
LUTu dummy;
// parent->ipf.MSR(labnCrop, labnCrop->W, labnCrop->H, 1);
parent->ipf.chromiLuminanceCurve (this, 1, labnCrop, labnCrop, parent->chroma_acurve, parent->chroma_bcurve, parent->satcurve, parent->lhskcurve, parent->clcurve, parent->lumacurve, utili, autili, butili, ccutili, cclutili, clcutili, dummy, dummy);
parent->ipf.vibrance (labnCrop);
if ((params.colorappearance.enabled && !params.colorappearance.tonecie) || (!params.colorappearance.enabled)) {
parent->ipf.EPDToneMap (labnCrop, 5, skip);
}
//parent->ipf.EPDToneMap(labnCrop, 5, 1); //Go with much fewer than normal iterates for fast redisplay.
// for all treatments Defringe, Sharpening, Contrast detail , Microcontrast they are activated if "CIECAM" function are disabled
if (skip == 1) {
if ((params.colorappearance.enabled && !settings->autocielab) || (!params.colorappearance.enabled)) {
parent->ipf.impulsedenoise (labnCrop);
}
if ((params.colorappearance.enabled && !settings->autocielab) || (!params.colorappearance.enabled) ) {
parent->ipf.defringe (labnCrop);
}
parent->ipf.MLsharpen (labnCrop);
if ((params.colorappearance.enabled && !settings->autocielab) || (!params.colorappearance.enabled)) {
parent->ipf.MLmicrocontrast (labnCrop);
parent->ipf.sharpening (labnCrop, (float**)cbuffer, params.sharpening);
}
}
// if (skip==1) {
WaveletParams WaveParams = params.wavelet;
if (params.dirpyrequalizer.cbdlMethod == "aft") {
if (((params.colorappearance.enabled && !settings->autocielab) || (!params.colorappearance.enabled))) {
parent->ipf.dirpyrequalizer (labnCrop, skip);
// parent->ipf.Lanczoslab (labnCrop,labnCrop , 1.f/skip);
}
}
int kall = 0;
int minwin = min (labnCrop->W, labnCrop->H);
int maxlevelcrop = 10;
// if(cp.mul[9]!=0)maxlevelcrop=10;
// adap maximum level wavelet to size of crop
if (minwin * skip < 1024) {
maxlevelcrop = 9; //sampling wavelet 512
}
if (minwin * skip < 512) {
maxlevelcrop = 8; //sampling wavelet 256
}
if (minwin * skip < 256) {
maxlevelcrop = 7; //sampling 128
}
if (minwin * skip < 128) {
maxlevelcrop = 6;
}
if (minwin < 64) {
maxlevelcrop = 5;
}
int realtile;
if (params.wavelet.Tilesmethod == "big") {
realtile = 22;
}
if (params.wavelet.Tilesmethod == "lit") {
realtile = 12;
}
int tilesize = 128 * realtile;
int overlap = (int) tilesize * 0.125f;
int numtiles_W, numtiles_H, tilewidth, tileheight, tileWskip, tileHskip;
parent->ipf.Tile_calc (tilesize, overlap, kall, labnCrop->W, labnCrop->H, numtiles_W, numtiles_H, tilewidth, tileheight, tileWskip, tileHskip);
//now we have tile dimensions, overlaps
//%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
int minsizetile = min (tilewidth, tileheight);
int maxlev2 = 10;
if (minsizetile < 1024 && maxlevelcrop == 10) {
maxlev2 = 9;
}
if (minsizetile < 512) {
maxlev2 = 8;
}
if (minsizetile < 256) {
maxlev2 = 7;
}
if (minsizetile < 128) {
maxlev2 = 6;
}
int maxL = min (maxlev2, maxlevelcrop);
if (parent->awavListener) {
parent->awavListener->wavChanged (float (maxL));
}
if ((params.wavelet.enabled)) {
WavCurve wavCLVCurve;
WavOpacityCurveRG waOpacityCurveRG;
WavOpacityCurveBY waOpacityCurveBY;
WavOpacityCurveW waOpacityCurveW;
WavOpacityCurveWL waOpacityCurveWL;
LUTf wavclCurve;
LUTu dummy;
params.wavelet.getCurves (wavCLVCurve, waOpacityCurveRG, waOpacityCurveBY, waOpacityCurveW, waOpacityCurveWL);
parent->ipf.ip_wavelet (labnCrop, labnCrop, kall, WaveParams, wavCLVCurve, waOpacityCurveRG, waOpacityCurveBY, waOpacityCurveW, waOpacityCurveWL, parent->wavclCurve, skip);
}
// }
// }
if (params.colorappearance.enabled) {
float fnum = parent->imgsrc->getMetaData()->getFNumber (); // F number
float fiso = parent->imgsrc->getMetaData()->getISOSpeed () ; // ISO
float fspeed = parent->imgsrc->getMetaData()->getShutterSpeed () ; // Speed
double fcomp = parent->imgsrc->getMetaData()->getExpComp (); // Compensation +/-
double adap; // Scene's luminosity adaptation factor
if (fnum < 0.3f || fiso < 5.f || fspeed < 0.00001f) { //if no exif data or wrong
adap = 2000.;
} else {
double E_V = fcomp + log2 (double ((fnum * fnum) / fspeed / (fiso / 100.f)));
E_V += params.toneCurve.expcomp;// exposure compensation in tonecurve ==> direct EV
E_V += log2 (params.raw.expos); // exposure raw white point ; log2 ==> linear to EV
adap = pow (2., E_V - 3.); // cd / m2
// end calculation adaptation scene luminosity
}
bool execsharp = false;
if (skip == 1) {
execsharp = true;
}
if (!cieCrop) {
cieCrop = new CieImage (cropw, croph);
}
float d, dj, yb; // not used after this block
parent->ipf.ciecam_02float (cieCrop, float (adap), 1, 2, labnCrop, &params, parent->customColCurve1, parent->customColCurve2, parent->customColCurve3,
dummy, dummy, parent->CAMBrightCurveJ, parent->CAMBrightCurveQ, parent->CAMMean, 5, skip, execsharp, d, dj, yb, 1);
} else {
// CIECAM is disabled, we free up its image buffer to save some space
if (cieCrop) {
delete cieCrop;
}
cieCrop = nullptr;
}
}
// all pipette buffer processing should be finished now
PipetteBuffer::setReady();
// Computing the preview image, i.e. converting from lab->Monitor color space (soft-proofing disabled) or lab->Output profile->Monitor color space (soft-proofing enabled)
parent->ipf.lab2monitorRgb (labnCrop, cropImg);
if (cropImageListener) {
// Computing the internal image for analysis, i.e. conversion from lab->Output profile (rtSettings.HistogramWorking disabled) or lab->WCS (rtSettings.HistogramWorking enabled)
// internal image in output color space for analysis
Image8 *cropImgtrue = parent->ipf.lab2rgb (labnCrop, 0, 0, cropw, croph, params.icm);
int finalW = rqcropw;
if (cropImg->getWidth() - leftBorder < finalW) {
finalW = cropImg->getWidth() - leftBorder;
}
int finalH = rqcroph;
if (cropImg->getHeight() - upperBorder < finalH) {
finalH = cropImg->getHeight() - upperBorder;
}
Image8* final = new Image8 (finalW, finalH);
Image8* finaltrue = new Image8 (finalW, finalH);
for (int i = 0; i < finalH; i++) {
memcpy (final->data + 3 * i * finalW, cropImg->data + 3 * (i + upperBorder)*cropw + 3 * leftBorder, 3 * finalW);
memcpy (finaltrue->data + 3 * i * finalW, cropImgtrue->data + 3 * (i + upperBorder)*cropw + 3 * leftBorder, 3 * finalW);
}
cropImageListener->setDetailedCrop (final, finaltrue, params.icm, params.crop, rqcropx, rqcropy, rqcropw, rqcroph, skip);
delete final;
delete finaltrue;
delete cropImgtrue;
}
}
void Crop::freeAll ()
{
if (settings->verbose) {
printf ("freeallcrop starts %d\n", (int)cropAllocated);
}
if (cropAllocated) {
if (origCrop ) {
delete origCrop;
origCrop = nullptr;
}
if (transCrop) {
delete transCrop;
transCrop = nullptr;
}
if (laboCrop ) {
delete laboCrop;
laboCrop = nullptr;
}
if (labnCrop ) {
delete labnCrop;
labnCrop = nullptr;
}
if (cropImg ) {
delete cropImg;
cropImg = nullptr;
}
if (cieCrop ) {
delete cieCrop;
cieCrop = nullptr;
}
if (cbuf_real) {
delete [] cbuf_real;
cbuf_real = nullptr;
}
if (cbuffer ) {
delete [] cbuffer;
cbuffer = nullptr;
}
PipetteBuffer::flush();
}
cropAllocated = false;
}
namespace
{
bool check_need_larger_crop_for_lcp_distortion (int fw, int fh, int x, int y, int w, int h, const ProcParams &params)
{
if (x == 0 && y == 0 && w == fw && h == fh) {
return false;
}
return (params.lensProf.useDist && (params.lensProf.useLensfun() || params.lensProf.useLcp()));
}
} // namespace
/** @brief Handles crop's image buffer reallocation and trigger sizeChanged of SizeListener[s]
* If the scale changes, this method will free all buffers and reallocate ones of the new size.
* It will then tell to the SizeListener that size has changed (sizeChanged)
*/
bool Crop::setCropSizes (int rcx, int rcy, int rcw, int rch, int skip, bool internal)
{
if (settings->verbose) {
printf ("setcropsizes before lock\n");
}
if (!internal) {
cropMutex.lock ();
}
bool changed = false;
rqcropx = rcx;
rqcropy = rcy;
rqcropw = rcw;
rqcroph = rch;
// store and set requested crop size
int rqx1 = LIM (rqcropx, 0, parent->fullw - 1);
int rqy1 = LIM (rqcropy, 0, parent->fullh - 1);
int rqx2 = rqx1 + rqcropw - 1;
int rqy2 = rqy1 + rqcroph - 1;
rqx2 = LIM (rqx2, 0, parent->fullw - 1);
rqy2 = LIM (rqy2, 0, parent->fullh - 1);
this->skip = skip;
// add border, if possible
int bx1 = rqx1 - skip * borderRequested;
int by1 = rqy1 - skip * borderRequested;
int bx2 = rqx2 + skip * borderRequested;
int by2 = rqy2 + skip * borderRequested;
// clip it to fit into image area
bx1 = LIM (bx1, 0, parent->fullw - 1);
by1 = LIM (by1, 0, parent->fullh - 1);
bx2 = LIM (bx2, 0, parent->fullw - 1);
by2 = LIM (by2, 0, parent->fullh - 1);
int bw = bx2 - bx1 + 1;
int bh = by2 - by1 + 1;
// determine which part of the source image is required to compute the crop rectangle
int orx, ory, orw, orh;
orx = bx1;
ory = by1;
orw = bw;
orh = bh;
parent->ipf.transCoord (parent->fw, parent->fh, bx1, by1, bw, bh, orx, ory, orw, orh);
if (check_need_larger_crop_for_lcp_distortion (parent->fw, parent->fh, orx, ory, orw, orh, parent->params)) {
// TODO - this is an estimate of the max distortion relative to the image size. ATM it is hardcoded to be 15%, which seems enough. If not, need to revise
int dW = int (double (parent->fw) * 0.15 / (2 * skip));
int dH = int (double (parent->fh) * 0.15 / (2 * skip));
int x1 = orx - dW;
int x2 = orx + orw + dW;
int y1 = ory - dH;
int y2 = ory + orh + dH;
if (x1 < 0) {
x2 += -x1;
x1 = 0;
}
if (x2 > parent->fw) {
x1 -= x2 - parent->fw;
x2 = parent->fw;
}
if (y1 < 0) {
y2 += -y1;
y1 = 0;
}
if (y2 > parent->fh) {
y1 -= y2 - parent->fh;
y2 = parent->fh;
}
orx = max (x1, 0);
ory = max (y1, 0);
orw = min (x2 - x1, parent->fw - orx);
orh = min (y2 - y1, parent->fh - ory);
}
leftBorder = skips (rqx1 - bx1, skip);
upperBorder = skips (rqy1 - by1, skip);
PreviewProps cp (orx, ory, orw, orh, skip);
int orW, orH;
parent->imgsrc->getSize (cp, orW, orH);
trafx = orx;
trafy = ory;
int cw = skips (bw, skip);
int ch = skips (bh, skip);
if (settings->verbose) {
printf ("setsizes starts (%d, %d, %d, %d, %d, %d)\n", orW, orH, trafw, trafh, cw, ch);
}
EditType editType = ET_PIPETTE;
if (const auto editProvider = PipetteBuffer::getDataProvider ()) {
if (const auto editSubscriber = editProvider->getCurrSubscriber ()) {
editType = editSubscriber->getEditingType ();
}
}
if (cw != cropw || ch != croph || orW != trafw || orH != trafh) {
cropw = cw;
croph = ch;
trafw = orW;
trafh = orH;
if (!origCrop) {
origCrop = new Imagefloat;
}
origCrop->allocate (trafw, trafh); // Resizing the buffer (optimization)
// if transCrop doesn't exist yet, it'll be created where necessary
if (transCrop) {
transCrop->allocate (cropw, croph);
}
if (laboCrop) {
delete laboCrop; // laboCrop can't be resized
}
laboCrop = new LabImage (cropw, croph);
if (labnCrop) {
delete labnCrop; // labnCrop can't be resized
}
labnCrop = new LabImage (cropw, croph);
if (!cropImg) {
cropImg = new Image8;
}
cropImg->allocate (cropw, croph); // Resizing the buffer (optimization)
//cieCrop is only used in Crop::update, it is destroyed now but will be allocated on first use
if (cieCrop) {
delete cieCrop;
cieCrop = nullptr;
}
if (cbuffer ) {
delete [] cbuffer;
}
if (cbuf_real) {
delete [] cbuf_real;
}
cbuffer = new float*[croph];
cbuf_real = new float[ (croph + 2)*cropw];
for (int i = 0; i < croph; i++) {
cbuffer[i] = cbuf_real + cropw * i + cropw;
}
if (editType == ET_PIPETTE) {
PipetteBuffer::resize (cropw, croph);
} else if (PipetteBuffer::bufferCreated()) {
PipetteBuffer::flush();
}
cropAllocated = true;
changed = true;
}
cropx = bx1;
cropy = by1;
if (settings->verbose) {
printf ("setsizes ends\n");
}
if (!internal) {
cropMutex.unlock ();
}
return changed;
}
/** @brief Look out if a new thread has to be started to process the update
*
* @return If true, a new updating thread has to be created. If false, the current updating thread will be used
*/
bool Crop::tryUpdate()
{
bool needsNewThread = true;
if (updating) {
// tells to the updater thread that a new update is pending
newUpdatePending = true;
// no need for a new thread, the current one will do the job
needsNewThread = false;
} else
// the crop is now being updated ...well, when fullUpdate will be called
{
updating = true;
}
return needsNewThread;
}
/* @brief Handles Crop updating in its own thread
*
* This method will cycle updates as long as Crop::newUpdatePending will be true. During the processing,
* intermediary update will be automatically flushed by Crop::tryUpdate.
*
* This method is called when the visible part of the crop has changed (resize, zoom, etc..), so it needs a full update
*/
void Crop::fullUpdate ()
{
parent->updaterThreadStart.lock ();
if (parent->updaterRunning && parent->thread) {
// Do NOT reset changes here, since in a long chain of events it will lead to chroma_scale not being updated,
// causing Color::lab2rgb to return a black image on some opens
//parent->changeSinceLast = 0;
parent->thread->join ();
}
if (parent->plistener) {
parent->plistener->setProgressState (true);
}
// If there are more update request, the following WHILE will collect it
newUpdatePending = true;
while (newUpdatePending) {
newUpdatePending = false;
update (ALL);
}
updating = false; // end of crop update
if (parent->plistener) {
parent->plistener->setProgressState (false);
}
parent->updaterThreadStart.unlock ();
}
int Crop::get_skip()
{
MyMutex::MyLock lock (cropMutex);
return skip;
}
int Crop::getLeftBorder()
{
MyMutex::MyLock lock (cropMutex);
return leftBorder;
}
int Crop::getUpperBorder()
{
MyMutex::MyLock lock (cropMutex);
return upperBorder;
}
}
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