/* ============================================================ * * This file is a part of digiKam project * http://www.digikam.org * * Date : 2004-06-06 * Description : Red eyes correction tool for image editor * * Copyright (C) 2004-2005 by Renchi Raju * Copyright (C) 2004-2008 by Gilles Caulier * * This program is free software; you can redistribute it * and/or modify it under the terms of the GNU General * Public License as published by the Free Software Foundation; * either version 2, or (at your option) * any later version. * * This program 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. * * ============================================================ */ // TQt includes. #include #include #include #include #include #include #include #include #include #include #include #include #include #include // KDE includes. #include #include #include #include #include #include #include #include // Digikam includes. #include "bcgmodifier.h" #include "colorgradientwidget.h" #include "dimg.h" #include "dimgimagefilters.h" #include "editortoolsettings.h" #include "histogramwidget.h" #include "imageiface.h" #include "imagewidget.h" // LibKDcraw includes. #include // Local includes. #include "redeyetool.h" #include "redeyetool.moc" using namespace KDcrawIface; using namespace Digikam; namespace DigikamImagesPluginCore { RedEyeTool::RedEyeTool(TQObject* parent) : EditorTool(parent) { setName("redeye"); setToolName(i18n("Red Eye")); setToolIcon(SmallIcon("redeyes")); setToolHelp("redeyecorrectiontool.anchor"); m_destinationPreviewData = 0; m_previewWidget = new ImageWidget("redeye Tool", 0, i18n("

Here you can see the image selection preview with " "red eye reduction applied."), true, ImageGuideWidget::PickColorMode, true, true); setToolView(m_previewWidget); // ------------------------------------------------------------- EditorToolSettings *gboxSettings = new EditorToolSettings(EditorToolSettings::Default| EditorToolSettings::Ok| EditorToolSettings::Cancel); TQGridLayout* gridSettings = new TQGridLayout(gboxSettings->plainPage(), 11, 4); TQLabel *label1 = new TQLabel(i18n("Channel:"), gboxSettings->plainPage()); label1->setAlignment(TQt::AlignRight | TQt::AlignVCenter); m_channelCB = new TQComboBox(false, gboxSettings->plainPage()); m_channelCB->insertItem(i18n("Luminosity")); m_channelCB->insertItem(i18n("Red")); m_channelCB->insertItem(i18n("Green")); m_channelCB->insertItem(i18n("Blue")); TQWhatsThis::add( m_channelCB, i18n("

Select the histogram channel to display here:

" "Luminosity: display the image's luminosity values.

" "Red: display the red image channel values.

" "Green: display the green image channel values.

" "Blue: display the blue image channel values.

")); m_scaleBG = new TQHButtonGroup(gboxSettings->plainPage()); m_scaleBG->setExclusive(true); m_scaleBG->setFrameShape(TQFrame::NoFrame); m_scaleBG->setInsideMargin(0); TQWhatsThis::add( m_scaleBG, i18n("

Select the histogram scale here.

" "If the image's maximum counts are small, you can use the linear scale.

" "The logarithmic scale can be used when the maximal counts are big " "to show all values (small and large) on the graph.")); TQPushButton *linHistoButton = new TQPushButton(m_scaleBG); TQToolTip::add(linHistoButton, i18n("

Linear")); m_scaleBG->insert(linHistoButton, HistogramWidget::LinScaleHistogram); TDEGlobal::dirs()->addResourceType("histogram-lin", TDEGlobal::dirs()->kde_default("data") + "digikam/data"); TQString directory = TDEGlobal::dirs()->findResourceDir("histogram-lin", "histogram-lin.png"); linHistoButton->setPixmap(TQPixmap(directory + "histogram-lin.png")); linHistoButton->setToggleButton(true); TQPushButton *logHistoButton = new TQPushButton(m_scaleBG); TQToolTip::add(logHistoButton, i18n("

Logarithmic")); m_scaleBG->insert(logHistoButton, HistogramWidget::LogScaleHistogram); TDEGlobal::dirs()->addResourceType("histogram-log", TDEGlobal::dirs()->kde_default("data") + "digikam/data"); directory = TDEGlobal::dirs()->findResourceDir("histogram-log", "histogram-log.png"); logHistoButton->setPixmap(TQPixmap(directory + "histogram-log.png")); logHistoButton->setToggleButton(true); TQHBoxLayout* l1 = new TQHBoxLayout(); l1->addWidget(label1); l1->addWidget(m_channelCB); l1->addStretch(10); l1->addWidget(m_scaleBG); // ------------------------------------------------------------- TQVBox *histoBox = new TQVBox(gboxSettings->plainPage()); m_histogramWidget = new HistogramWidget(256, 140, histoBox, false, true, true); TQWhatsThis::add( m_histogramWidget, i18n("

Here you can see the target preview image histogram " "of the selected image channel. It is " "updated upon setting changes.")); TQLabel *space = new TQLabel(histoBox); space->setFixedHeight(1); m_hGradient = new ColorGradientWidget(ColorGradientWidget::Horizontal, 10, histoBox); m_hGradient->setColors(TQColor("black"), TQColor("white")); // ------------------------------------------------------------- m_thresholdLabel = new TQLabel(i18n("Sensitivity:"), gboxSettings->plainPage()); m_redThreshold = new RIntNumInput(gboxSettings->plainPage()); m_redThreshold->setRange(10, 90, 1); m_redThreshold->setDefaultValue(20); TQWhatsThis::add(m_redThreshold, i18n("

Sets the red color pixels selection threshold. " "Low values will select more red color pixels (agressive correction), high " "values less (mild correction). Use low value if eye have been selected " "exactly. Use high value if other parts of the face are also selected.")); m_smoothLabel = new TQLabel(i18n("Smooth:"), gboxSettings->plainPage()); m_smoothLevel = new RIntNumInput(gboxSettings->plainPage()); m_smoothLevel->setRange(0, 5, 1); m_smoothLevel->setDefaultValue(1); TQWhatsThis::add(m_smoothLevel, i18n("

Sets the smoothness value when blurring the border " "of the changed pixels. " "This leads to a more naturally looking pupil.")); TQLabel *label3 = new TQLabel(i18n("Coloring Tint:"), gboxSettings->plainPage()); m_HSSelector = new KHSSelector(gboxSettings->plainPage()); m_VSelector = new KValueSelector(gboxSettings->plainPage()); m_HSSelector->setMinimumSize(200, 142); m_VSelector->setMinimumSize(26, 142); TQWhatsThis::add(m_HSSelector, i18n("

Sets a custom color to re-colorize the eyes.")); TQLabel *label4 = new TQLabel(i18n("Tint Level:"), gboxSettings->plainPage()); m_tintLevel = new RIntNumInput(gboxSettings->plainPage()); m_tintLevel->setRange(1, 200, 1); m_tintLevel->setDefaultValue(128); TQWhatsThis::add(m_tintLevel, i18n("

Set the tint level to adjust the luminosity of " "the new color of the pupil.")); gridSettings->addMultiCellLayout(l1, 0, 0, 0, 4); gridSettings->addMultiCellWidget(histoBox, 1, 2, 0, 4); gridSettings->addMultiCellWidget(m_thresholdLabel, 3, 3, 0, 4); gridSettings->addMultiCellWidget(m_redThreshold, 4, 4, 0, 4); gridSettings->addMultiCellWidget(m_smoothLabel, 5, 5, 0, 4); gridSettings->addMultiCellWidget(m_smoothLevel, 6, 6, 0, 4); gridSettings->addMultiCellWidget(label3, 7, 7, 0, 4); gridSettings->addMultiCellWidget(m_HSSelector, 8, 8, 0, 3); gridSettings->addMultiCellWidget(m_VSelector, 8, 8, 4, 4); gridSettings->addMultiCellWidget(label4, 9, 9, 0, 4); gridSettings->addMultiCellWidget(m_tintLevel, 10, 10, 0, 4); gridSettings->setRowStretch(11, 10); gridSettings->setColStretch(3, 10); setToolSettings(gboxSettings); init(); // ------------------------------------------------------------- connect(m_channelCB, TQT_SIGNAL(activated(int)), this, TQT_SLOT(slotChannelChanged(int))); connect(m_scaleBG, TQT_SIGNAL(released(int)), this, TQT_SLOT(slotScaleChanged(int))); connect(m_previewWidget, TQT_SIGNAL(spotPositionChangedFromTarget(const Digikam::DColor&, const TQPoint&)), this, TQT_SLOT(slotColorSelectedFromTarget(const Digikam::DColor&))); connect(m_previewWidget, TQT_SIGNAL(signalResized()), this, TQT_SLOT(slotEffect())); connect(m_redThreshold, TQT_SIGNAL(valueChanged(int)), this, TQT_SLOT(slotTimer())); connect(m_smoothLevel, TQT_SIGNAL(valueChanged(int)), this, TQT_SLOT(slotTimer())); connect(m_HSSelector, TQT_SIGNAL(valueChanged(int, int)), this, TQT_SLOT(slotHSChanged(int, int))); connect(m_VSelector, TQT_SIGNAL(valueChanged(int)), this, TQT_SLOT(slotTimer())); connect(m_tintLevel, TQT_SIGNAL(valueChanged(int)), this, TQT_SLOT(slotTimer())); } RedEyeTool::~RedEyeTool() { if (m_destinationPreviewData) delete [] m_destinationPreviewData; } void RedEyeTool::slotHSChanged(int h, int s) { m_VSelector->blockSignals(true); m_VSelector->setHue(h); m_VSelector->setSaturation(s); m_VSelector->updateContents(); m_VSelector->repaint(false); m_VSelector->blockSignals(false); slotTimer(); } void RedEyeTool::slotChannelChanged(int channel) { switch (channel) { case LuminosityChannel: m_histogramWidget->m_channelType = HistogramWidget::ValueHistogram; m_hGradient->setColors(TQColor("black"), TQColor("white")); break; case RedChannel: m_histogramWidget->m_channelType = HistogramWidget::RedChannelHistogram; m_hGradient->setColors(TQColor("black"), TQColor("red")); break; case GreenChannel: m_histogramWidget->m_channelType = HistogramWidget::GreenChannelHistogram; m_hGradient->setColors(TQColor("black"), TQColor("green")); break; case BlueChannel: m_histogramWidget->m_channelType = HistogramWidget::BlueChannelHistogram; m_hGradient->setColors(TQColor("black"), TQColor("blue")); break; } m_histogramWidget->repaint(false); } void RedEyeTool::slotScaleChanged(int scale) { m_histogramWidget->m_scaleType = scale; m_histogramWidget->repaint(false); } void RedEyeTool::slotColorSelectedFromTarget(const DColor& color) { m_histogramWidget->setHistogramGuideByColor(color); } void RedEyeTool::readSettings() { TDEConfig* config = kapp->config(); config->setGroup("redeye Tool"); m_channelCB->setCurrentItem(config->readNumEntry("Histogram Channel", 0)); // Luminosity. m_scaleBG->setButton(config->readNumEntry("Histogram Scale", HistogramWidget::LogScaleHistogram)); m_redThreshold->setValue(config->readNumEntry("RedThreshold", m_redThreshold->defaultValue())); m_smoothLevel->setValue(config->readNumEntry("SmoothLevel", m_smoothLevel->defaultValue())); m_HSSelector->setXValue(config->readNumEntry("HueColoringTint", 0)); m_HSSelector->setYValue(config->readNumEntry("SatColoringTint", 0)); m_VSelector->setValue(config->readNumEntry("ValColoringTint", 0)); m_tintLevel->setValue(config->readNumEntry("TintLevel", m_tintLevel->defaultValue())); slotHSChanged(m_HSSelector->xValue(), m_HSSelector->yValue()); m_histogramWidget->reset(); slotChannelChanged(m_channelCB->currentItem()); slotScaleChanged(m_scaleBG->selectedId()); } void RedEyeTool::writeSettings() { TDEConfig* config = kapp->config(); config->setGroup("redeye Tool"); config->writeEntry("Histogram Channel", m_channelCB->currentItem()); config->writeEntry("Histogram Scale", m_scaleBG->selectedId()); config->writeEntry("RedThreshold", m_redThreshold->value()); config->writeEntry("SmoothLevel", m_smoothLevel->value()); config->writeEntry("HueColoringTint", m_HSSelector->xValue()); config->writeEntry("SatColoringTint", m_HSSelector->yValue()); config->writeEntry("ValColoringTint", m_VSelector->value()); config->writeEntry("TintLevel", m_tintLevel->value()); m_previewWidget->writeSettings(); config->sync(); } void RedEyeTool::slotResetSettings() { m_redThreshold->blockSignals(true); m_HSSelector->blockSignals(true); m_VSelector->blockSignals(true); m_tintLevel->blockSignals(true); m_redThreshold->slotReset(); m_smoothLevel->slotReset(); // Black color by default m_HSSelector->setXValue(0); m_HSSelector->setYValue(0); m_VSelector->setValue(0); m_tintLevel->slotReset(); m_redThreshold->blockSignals(false); m_HSSelector->blockSignals(false); m_VSelector->blockSignals(false); m_tintLevel->blockSignals(false); } void RedEyeTool::slotEffect() { kapp->setOverrideCursor(KCursor::waitCursor()); m_histogramWidget->stopHistogramComputation(); if (m_destinationPreviewData) delete [] m_destinationPreviewData; // Here, we need to use the real selection image data because we will apply // a Gaussian blur filter on pixels and we cannot use directly the preview scaled image // else the blur radius will not give the same result between preview and final rendering. ImageIface* iface = m_previewWidget->imageIface(); m_destinationPreviewData = iface->getImageSelection(); int w = iface->selectedWidth(); int h = iface->selectedHeight(); bool sb = iface->originalSixteenBit(); bool a = iface->originalHasAlpha(); DImg selection(w, h, sb, a, m_destinationPreviewData); redEyeFilter(selection); DImg preview = selection.smoothScale(iface->previewWidth(), iface->previewHeight()); iface->putPreviewImage(preview.bits()); m_previewWidget->updatePreview(); // Update histogram. memcpy(m_destinationPreviewData, selection.bits(), selection.numBytes()); m_histogramWidget->updateData(m_destinationPreviewData, w, h, sb, 0, 0, 0, false); kapp->restoreOverrideCursor(); } void RedEyeTool::finalRendering() { kapp->setOverrideCursor( KCursor::waitCursor() ); ImageIface* iface = m_previewWidget->imageIface(); uchar *data = iface->getImageSelection(); int w = iface->selectedWidth(); int h = iface->selectedHeight(); bool sixteenBit = iface->originalSixteenBit(); bool hasAlpha = iface->originalHasAlpha(); DImg selection(w, h, sixteenBit, hasAlpha, data); delete [] data; redEyeFilter(selection); iface->putImageSelection(i18n("Red Eyes Correction"), selection.bits()); kapp->restoreOverrideCursor(); } void RedEyeTool::redEyeFilter(DImg& selection) { DImg mask(selection.width(), selection.height(), selection.sixteenBit(), true, selection.bits(), true); selection = mask.copy(); float redThreshold = m_redThreshold->value()/10.0; int hue = m_HSSelector->xValue(); int sat = m_HSSelector->yValue(); int val = m_VSelector->value(); KColor coloring; coloring.setHsv(hue, sat, val); struct channel { float red_gain; float green_gain; float blue_gain; }; channel red_chan, green_chan, blue_chan; red_chan.red_gain = 0.1; red_chan.green_gain = 0.6; red_chan.blue_gain = 0.3; green_chan.red_gain = 0.0; green_chan.green_gain = 1.0; green_chan.blue_gain = 0.0; blue_chan.red_gain = 0.0; blue_chan.green_gain = 0.0; blue_chan.blue_gain = 1.0; float red_norm, green_norm, blue_norm; int level = 201 - m_tintLevel->value(); red_norm = 1.0 / (red_chan.red_gain + red_chan.green_gain + red_chan.blue_gain); green_norm = 1.0 / (green_chan.red_gain + green_chan.green_gain + green_chan.blue_gain); blue_norm = 1.0 / (blue_chan.red_gain + blue_chan.green_gain + blue_chan.blue_gain); red_norm *= coloring.red() / level; green_norm *= coloring.green() / level; blue_norm *= coloring.blue() / level; // Perform a red color pixels detection in selection image and create a correction mask using an alpha channel. if (!selection.sixteenBit()) // 8 bits image. { uchar* ptr = selection.bits(); uchar* mptr = mask.bits(); uchar r, g, b, r1, g1, b1; for (uint i = 0 ; i < selection.width() * selection.height() ; i++) { b = ptr[0]; g = ptr[1]; r = ptr[2]; mptr[3] = 255; if (r >= ( redThreshold * g)) { r1 = TQMIN(255, (int)(red_norm * (red_chan.red_gain * r + red_chan.green_gain * g + red_chan.blue_gain * b))); g1 = TQMIN(255, (int)(green_norm * (green_chan.red_gain * r + green_chan.green_gain * g + green_chan.blue_gain * b))); b1 = TQMIN(255, (int)(blue_norm * (blue_chan.red_gain * r + blue_chan.green_gain * g + blue_chan.blue_gain * b))); mptr[0] = b1; mptr[1] = g1; mptr[2] = r1; mptr[3] = TQMIN( (int)((r-g) / 150.0 * 255.0), 255); } ptr += 4; mptr+= 4; } } else // 16 bits image. { unsigned short* ptr = (unsigned short*)selection.bits(); unsigned short* mptr = (unsigned short*)mask.bits(); unsigned short r, g, b, r1, g1, b1; for (uint i = 0 ; i < selection.width() * selection.height() ; i++) { b = ptr[0]; g = ptr[1]; r = ptr[2]; mptr[3] = 65535; if (r >= ( redThreshold * g)) { r1 = TQMIN(65535, (int)(red_norm * (red_chan.red_gain * r + red_chan.green_gain * g + red_chan.blue_gain * b))); g1 = TQMIN(65535, (int)(green_norm * (green_chan.red_gain * r + green_chan.green_gain * g + green_chan.blue_gain * b))); b1 = TQMIN(65535, (int)(blue_norm * (blue_chan.red_gain * r + blue_chan.green_gain * g + blue_chan.blue_gain * b))); mptr[0] = b1; mptr[1] = g1; mptr[2] = r1; mptr[3] = TQMIN( (int)((r-g) / 38400.0 * 65535.0), 65535);; } ptr += 4; mptr+= 4; } } // Now, we will blur only the transparency pixels from the mask. DImg mask2 = mask.copy(); DImgImageFilters filter; filter.gaussianBlurImage(mask2.bits(), mask2.width(), mask2.height(), mask2.sixteenBit(), m_smoothLevel->value()); if (!selection.sixteenBit()) // 8 bits image. { uchar* mptr = mask.bits(); uchar* mptr2 = mask2.bits(); for (uint i = 0 ; i < mask2.width() * mask2.height() ; i++) { if (mptr2[3] < 255) { mptr[0] = mptr2[0]; mptr[1] = mptr2[1]; mptr[2] = mptr2[2]; mptr[3] = mptr2[3]; } mptr += 4; mptr2+= 4; } } else // 16 bits image. { unsigned short* mptr = (unsigned short*)mask.bits(); unsigned short* mptr2 = (unsigned short*)mask2.bits(); for (uint i = 0 ; i < mask2.width() * mask2.height() ; i++) { if (mptr2[3] < 65535) { mptr[0] = mptr2[0]; mptr[1] = mptr2[1]; mptr[2] = mptr2[2]; mptr[3] = mptr2[3]; } mptr += 4; mptr2+= 4; } } // - Perform pixels blending using alpha channel between the mask and the selection. DColorComposer *composer = DColorComposer::getComposer(DColorComposer::PorterDuffSrcOver); // NOTE: 'mask' is the Source image, 'selection' is the Destination image. selection.bitBlendImage(composer, &mask, 0, 0, mask.width(), mask.height(), 0, 0); } } // NameSpace DigikamImagesPluginCore