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485 lines
16 KiB
485 lines
16 KiB
/*
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* Copyright (c) 2005 Bart Coppens <kde@bartcoppens.be>
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*
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* This program is free software; you can redistribute it and/or modify
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* it under the terms of the GNU General Public License as published by
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* the Free Software Foundation; either version 2 of the License, or
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* (at your option) any later version.
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*
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* This program is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with this program; if not, write to the Free Software
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* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
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*/
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#include <tqstring.h>
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#include <tdelocale.h>
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#include "config.h"
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#ifdef HAVE_OPENEXR
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#include <half.h>
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#endif
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#include "kis_global.h"
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#include "kis_basic_histogram_producers.h"
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#include "kis_integer_maths.h"
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#include "kis_channelinfo.h"
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#include "kis_colorspace.h"
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#include "kis_lab_colorspace.h"
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KisLabColorSpace* KisGenericLabHistogramProducer::m_labCs = 0;
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KisBasicHistogramProducer::KisBasicHistogramProducer(const KisID& id, int channels, int nrOfBins, KisColorSpace *cs)
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: m_channels(channels),
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m_nrOfBins(nrOfBins),
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m_colorSpace(cs),
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m_id(id)
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{
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m_bins.resize(m_channels);
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for (int i = 0; i < m_channels; i++)
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m_bins.at(i).resize(m_nrOfBins);
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m_outLeft.resize(m_channels);
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m_outRight.resize(m_channels);
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m_count = 0;
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m_from = 0.0;
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m_width = 1.0;
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}
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void KisBasicHistogramProducer::clear() {
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m_count = 0;
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for (int i = 0; i < m_channels; i++) {
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for (int j = 0; j < m_nrOfBins; j++) {
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m_bins.at(i).at(j) = 0;
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}
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m_outRight.at(i) = 0;
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m_outLeft.at(i) = 0;
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}
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}
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void KisBasicHistogramProducer::makeExternalToInternal() {
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// This function assumes that the pixel is has no 'gaps'. That is to say: if we start
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// at byte 0, we can get to the end of the pixel by adding consecutive size()s of
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// the channels
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TQValueVector<KisChannelInfo *> c = channels();
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uint count = c.count();
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int currentPos = 0;
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for (uint i = 0; i < count; i++) {
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for (uint j = 0; j < count; j++) {
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if (c.at(j)->pos() == currentPos) {
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m_external.append(j);
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break;
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}
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}
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currentPos += c.at(m_external.at(m_external.count() - 1))->size();
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}
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}
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// ------------ U8 ---------------------
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KisBasicU8HistogramProducer::KisBasicU8HistogramProducer(const KisID& id, KisColorSpace *cs)
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: KisBasicHistogramProducer(id, cs->nChannels(), 256, cs)
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{
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}
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TQString KisBasicU8HistogramProducer::positionToString(double pos) const {
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return TQString("%1").arg(static_cast<TQ_UINT8>(pos * UINT8_MAX));
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}
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void KisBasicU8HistogramProducer::addRegionToBin(TQ_UINT8 * pixels, TQ_UINT8 * selectionMask, TQ_UINT32 nPixels, KisColorSpace *cs)
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{
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if (!pixels) return;
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if (!cs) return;
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if (nPixels == 0) return;
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TQ_INT32 pSize = cs->pixelSize();
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if ( selectionMask ) {
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while (nPixels > 0) {
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if ( ! (m_skipUnselected && *selectionMask == 0) || (m_skipTransparent && cs->getAlpha(pixels) == OPACITY_TRANSPARENT) ) {
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for (int i = 0; i < m_channels; i++) {
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m_bins.at(i).at(pixels[i])++;
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}
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m_count++;
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}
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pixels += pSize;
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selectionMask++;
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nPixels--;
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}
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}
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else {
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while (nPixels > 0) {
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if ( ! (m_skipTransparent && cs->getAlpha(pixels) == OPACITY_TRANSPARENT) ) {
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for (int i = 0; i < m_channels; i++) {
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m_bins.at(i).at(pixels[i])++;
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}
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m_count++;
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}
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pixels += pSize;
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nPixels--;
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}
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}
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}
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// ------------ U16 ---------------------
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KisBasicU16HistogramProducer::KisBasicU16HistogramProducer(const KisID& id, KisColorSpace *cs)
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: KisBasicHistogramProducer(id, cs->nChannels(), 256, cs)
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{
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}
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TQString KisBasicU16HistogramProducer::positionToString(double pos) const
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{
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return TQString("%1").arg(static_cast<TQ_UINT8>(pos * UINT8_MAX));
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}
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double KisBasicU16HistogramProducer::maximalZoom() const
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{
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return 1.0 / 255.0;
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}
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void KisBasicU16HistogramProducer::addRegionToBin(TQ_UINT8 * pixels, TQ_UINT8 * selectionMask, TQ_UINT32 nPixels, KisColorSpace *cs)
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{
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// The view
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TQ_UINT16 from = static_cast<TQ_UINT16>(m_from * UINT16_MAX);
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TQ_UINT16 width = static_cast<TQ_UINT16>(m_width * UINT16_MAX + 0.5); // We include the end
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TQ_UINT16 to = from + width;
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double factor = 255.0 / width;
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TQ_INT32 pSize = cs->pixelSize();
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if ( selectionMask ) {
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TQ_UINT16* pixel = reinterpret_cast<TQ_UINT16*>(pixels);
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while (nPixels > 0) {
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if ( ! ((m_skipUnselected && *selectionMask == 0) || (m_skipTransparent && cs->getAlpha(pixels) == OPACITY_TRANSPARENT)) ) {
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for (int i = 0; i < m_channels; i++) {
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TQ_UINT16 value = pixel[i];
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if (value > to)
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m_outRight.at(i)++;
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else if (value < from)
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m_outLeft.at(i)++;
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else
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m_bins.at(i).at(static_cast<TQ_UINT8>((value - from) * factor))++;
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}
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m_count++;
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}
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pixels += pSize;
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selectionMask++;
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nPixels--;
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}
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}
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else {
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while (nPixels > 0) {
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TQ_UINT16* pixel = reinterpret_cast<TQ_UINT16*>(pixels);
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if ( ! (m_skipTransparent && cs->getAlpha(pixels) == OPACITY_TRANSPARENT)) {
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for (int i = 0; i < m_channels; i++) {
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TQ_UINT16 value = pixel[i];
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if (value > to)
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m_outRight.at(i)++;
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else if (value < from)
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m_outLeft.at(i)++;
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else
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m_bins.at(i).at(static_cast<TQ_UINT8>((value - from) * factor))++;
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}
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m_count++;
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}
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pixels += pSize;
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nPixels--;
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}
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}
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}
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// ------------ Float32 ---------------------
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KisBasicF32HistogramProducer::KisBasicF32HistogramProducer(const KisID& id, KisColorSpace *cs)
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: KisBasicHistogramProducer(id, cs->nChannels(), 256, cs)
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{
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}
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TQString KisBasicF32HistogramProducer::positionToString(double pos) const {
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return TQString("%1").arg(static_cast<float>(pos)); // XXX I doubt this is correct!
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}
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double KisBasicF32HistogramProducer::maximalZoom() const {
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// XXX What _is_ the maximal zoom here? I don't think there is one with floats, so this seems a fine compromis for the moment
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return 1.0 / 255.0;
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}
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void KisBasicF32HistogramProducer::addRegionToBin(TQ_UINT8 * pixels, TQ_UINT8 * selectionMask, TQ_UINT32 nPixels, KisColorSpace *cs) {
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// The view
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float from = static_cast<float>(m_from);
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float width = static_cast<float>(m_width);
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float to = from + width;
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float factor = 255.0 / width;
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TQ_INT32 pSize = cs->pixelSize();
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if ( selectionMask ) {
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while (nPixels > 0) {
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float* pixel = reinterpret_cast<float*>(pixels);
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if ( !((m_skipUnselected && *selectionMask == 0) || (m_skipTransparent && cs->getAlpha(pixels) == OPACITY_TRANSPARENT)) ) {
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for (int i = 0; i < m_channels; i++) {
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float value = pixel[i];
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if (value > to)
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m_outRight.at(i)++;
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else if (value < from)
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m_outLeft.at(i)++;
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else
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m_bins.at(i).at(static_cast<TQ_UINT8>((value - from) * factor))++;
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}
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m_count++;
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}
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pixels += pSize;
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selectionMask++;
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nPixels--;
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}
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}
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else {
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while (nPixels > 0) {
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float* pixel = reinterpret_cast<float*>(pixels);
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if ( !(m_skipTransparent && cs->getAlpha(pixels) == OPACITY_TRANSPARENT)) {
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for (int i = 0; i < m_channels; i++) {
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float value = pixel[i];
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if (value > to)
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m_outRight.at(i)++;
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else if (value < from)
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m_outLeft.at(i)++;
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else
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m_bins.at(i).at(static_cast<TQ_UINT8>((value - from) * factor))++;
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}
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m_count++;
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}
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pixels += pSize;
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nPixels--;
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}
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}
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}
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#ifdef HAVE_OPENEXR
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// ------------ Float16 Half ---------------------
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KisBasicF16HalfHistogramProducer::KisBasicF16HalfHistogramProducer(const KisID& id,
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KisColorSpace *cs)
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: KisBasicHistogramProducer(id, cs->nChannels(), 256, cs) {
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}
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TQString KisBasicF16HalfHistogramProducer::positionToString(double pos) const {
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return TQString("%1").arg(static_cast<float>(pos)); // XXX I doubt this is correct!
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}
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double KisBasicF16HalfHistogramProducer::maximalZoom() const {
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// XXX What _is_ the maximal zoom here? I don't think there is one with floats, so this seems a fine compromis for the moment
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return 1.0 / 255.0;
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}
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void KisBasicF16HalfHistogramProducer::addRegionToBin(TQ_UINT8 * pixels, TQ_UINT8 * selectionMask, TQ_UINT32 nPixels, KisColorSpace *cs) {
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// The view
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float from = static_cast<float>(m_from);
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float width = static_cast<float>(m_width);
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float to = from + width;
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float factor = 255.0 / width;
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TQ_INT32 pSize = cs->pixelSize();
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if ( selectionMask ) {
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while (nPixels > 0) {
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half* pixel = reinterpret_cast<half*>(pixels);
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if ( !((m_skipUnselected && *selectionMask == 0) || (m_skipTransparent && cs->getAlpha(pixels) == OPACITY_TRANSPARENT)) ) {
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for (int i = 0; i < m_channels; i++) {
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float value = pixel[i];
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if (value > to)
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m_outRight.at(i)++;
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else if (value < from)
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m_outLeft.at(i)++;
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else
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m_bins.at(i).at(static_cast<TQ_UINT8>((value - from) * factor))++;
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}
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m_count++;
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}
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pixels += pSize;
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selectionMask++;
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nPixels--;
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}
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}
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else {
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while (nPixels > 0) {
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half* pixel = reinterpret_cast<half*>(pixels);
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if ( !(m_skipTransparent && cs->getAlpha(pixels) == OPACITY_TRANSPARENT)) {
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for (int i = 0; i < m_channels; i++) {
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float value = pixel[i];
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if (value > to)
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m_outRight.at(i)++;
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else if (value < from)
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m_outLeft.at(i)++;
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else
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m_bins.at(i).at(static_cast<TQ_UINT8>((value - from) * factor))++;
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}
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m_count++;
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}
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pixels += pSize;
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nPixels--;
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}
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}
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}
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#endif
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// ------------ Generic RGB ---------------------
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KisGenericRGBHistogramProducer::KisGenericRGBHistogramProducer()
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: KisBasicHistogramProducer(KisID("GENRGBHISTO", i18n("Generic RGB Histogram")),
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3, 256, 0) {
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/* we set 0 as colorspece, because we are not based on a specific colorspace. This
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is no problem for the superclass since we override channels() */
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m_channelsList.append(new KisChannelInfo(i18n("R"), i18n("R"), 0, KisChannelInfo::COLOR, KisChannelInfo::UINT8, 1, TQColor(255,0,0)));
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m_channelsList.append(new KisChannelInfo(i18n("G"), i18n("G"), 1, KisChannelInfo::COLOR, KisChannelInfo::UINT8, 1, TQColor(0,255,0)));
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m_channelsList.append(new KisChannelInfo(i18n("B"), i18n("B"), 2, KisChannelInfo::COLOR, KisChannelInfo::UINT8, 1, TQColor(0,0,255)));
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}
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TQValueVector<KisChannelInfo *> KisGenericRGBHistogramProducer::channels() {
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return m_channelsList;
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}
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TQString KisGenericRGBHistogramProducer::positionToString(double pos) const {
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return TQString("%1").arg(static_cast<TQ_UINT8>(pos * UINT8_MAX));
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}
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double KisGenericRGBHistogramProducer::maximalZoom() const {
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return 1.0;
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}
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void KisGenericRGBHistogramProducer::addRegionToBin(TQ_UINT8 * pixels, TQ_UINT8 * selectionMask, TQ_UINT32 nPixels, KisColorSpace *cs)
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{
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for (int i = 0; i < m_channels; i++) {
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m_outRight.at(i) = 0;
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m_outLeft.at(i) = 0;
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}
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TQColor c;
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TQ_INT32 pSize = cs->pixelSize();
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if (selectionMask) {
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while (nPixels > 0) {
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if ( !((m_skipUnselected && *selectionMask == 0) || (m_skipTransparent && cs->getAlpha(pixels) == OPACITY_TRANSPARENT)) ) {
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cs->toTQColor(pixels, &c);
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m_bins.at(0).at(c.red())++;
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m_bins.at(1).at(c.green())++;
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m_bins.at(2).at(c.blue())++;
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m_count++;
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}
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pixels += pSize;
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selectionMask++;
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nPixels--;
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}
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}
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else {
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while (nPixels > 0) {
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if ( !(m_skipTransparent && cs->getAlpha(pixels) == OPACITY_TRANSPARENT)) {
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cs->toTQColor(pixels, &c);
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m_bins.at(0).at(c.red())++;
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m_bins.at(1).at(c.green())++;
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m_bins.at(2).at(c.blue())++;
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m_count++;
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}
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pixels += pSize;
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nPixels--;
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}
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}
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}
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// ------------ Generic L*a*b* ---------------------
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KisGenericLabHistogramProducer::KisGenericLabHistogramProducer()
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: KisBasicHistogramProducer(KisID("GENLABHISTO", i18n("L*a*b* Histogram")), 3, 256, 0) {
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/* we set 0 as colorspace, because we are not based on a specific colorspace. This
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is no problem for the superclass since we override channels() */
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m_channelsList.append(new KisChannelInfo(i18n("L*"), i18n("L"), 0, KisChannelInfo::COLOR, KisChannelInfo::UINT8));
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m_channelsList.append(new KisChannelInfo(i18n("a*"), i18n("a"), 1, KisChannelInfo::COLOR, KisChannelInfo::UINT8));
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m_channelsList.append(new KisChannelInfo(i18n("b*"), i18n("b"), 2, KisChannelInfo::COLOR, KisChannelInfo::UINT8));
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if (!m_labCs) {
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KisProfile *labProfile = new KisProfile(cmsCreateLabProfile(NULL));
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m_labCs = new KisLabColorSpace(0, labProfile);
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}
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m_colorSpace = m_labCs;
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}
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KisGenericLabHistogramProducer::~KisGenericLabHistogramProducer()
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{
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delete m_channelsList[0];
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delete m_channelsList[1];
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delete m_channelsList[2];
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}
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TQValueVector<KisChannelInfo *> KisGenericLabHistogramProducer::channels() {
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return m_channelsList;
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}
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TQString KisGenericLabHistogramProducer::positionToString(double pos) const {
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return TQString("%1").arg(static_cast<TQ_UINT16>(pos * UINT16_MAX));
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}
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double KisGenericLabHistogramProducer::maximalZoom() const {
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return 1.0;
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}
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void KisGenericLabHistogramProducer::addRegionToBin(TQ_UINT8 * pixels, TQ_UINT8 * selectionMask, TQ_UINT32 nPixels, KisColorSpace *cs)
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{
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for (int i = 0; i < m_channels; i++) {
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m_outRight.at(i) = 0;
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m_outLeft.at(i) = 0;
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}
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TQ_UINT8 dst[8];
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TQ_INT32 pSize = cs->pixelSize();
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if (selectionMask) {
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while (nPixels > 0) {
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if ( !((m_skipUnselected && *selectionMask == 0) || (m_skipTransparent && cs->getAlpha(pixels) == OPACITY_TRANSPARENT)) ) {
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/*
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cs->toTQColor(pixels, &c);
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m_bins.at(0).at(c.red())++;
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*/
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m_count++;
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}
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pixels += pSize;
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selectionMask++;
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nPixels--;
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}
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}
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else {
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while (nPixels > 0) {
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if ( !(m_skipTransparent && cs->getAlpha(pixels) == OPACITY_TRANSPARENT)) {
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cs->convertPixelsTo(pixels, dst, m_colorSpace, 1);
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m_bins.at(0).at(m_colorSpace->scaleToU8(dst, 0))++;
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m_bins.at(1).at(m_colorSpace->scaleToU8(dst, 1))++;
|
|
m_bins.at(2).at(m_colorSpace->scaleToU8(dst, 2))++;
|
|
|
|
m_count++;
|
|
}
|
|
pixels += pSize;
|
|
nPixels--;
|
|
}
|
|
}
|
|
}
|
|
|