diff --git a/libs/widgets/KisVisualColorSelector.cpp b/libs/widgets/KisVisualColorSelector.cpp index 0393d9b44d..d87947a2e1 100644 --- a/libs/widgets/KisVisualColorSelector.cpp +++ b/libs/widgets/KisVisualColorSelector.cpp @@ -1,520 +1,566 @@ /* * Copyright (C) Wolthera van Hovell tot Westerflier , (C) 2016 * * 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 of the License, 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. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. */ #include "KisVisualColorSelector.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "KoColorConversions.h" #include "KoColorDisplayRendererInterface.h" +#include "KoColorProfile.h" #include "KoChannelInfo.h" #include #include #include "kis_signal_compressor.h" #include "kis_debug.h" #include "KisVisualColorSelectorShape.h" #include "KisVisualRectangleSelectorShape.h" #include "KisVisualTriangleSelectorShape.h" #include "KisVisualEllipticalSelectorShape.h" struct KisVisualColorSelector::Private { KoColor currentcolor; const KoColorSpace *currentCS {0}; QList widgetlist; bool updateLonesome {false}; // currently redundant; remove? bool circular {false}; bool exposureSupported = false; bool isRGBA = false; + bool isLinear = false; int displayPosition[4]; // map channel index to storage index for display int colorChannelCount; QVector4D channelValues; + QVector4D channelMaxValues; ColorModel model; const KoColorDisplayRendererInterface *displayRenderer {0}; KisColorSelectorConfiguration acs_config; KisSignalCompressor *updateTimer {0}; }; KisVisualColorSelector::KisVisualColorSelector(QWidget *parent) : KisColorSelectorInterface(parent) , m_d(new Private) { this->setSizePolicy(QSizePolicy::Expanding,QSizePolicy::Expanding); KConfigGroup cfg = KSharedConfig::openConfig()->group("advancedColorSelector"); m_d->acs_config = KisColorSelectorConfiguration::fromString(cfg.readEntry("colorSelectorConfiguration", KisColorSelectorConfiguration().toString())); m_d->updateTimer = new KisSignalCompressor(100 /* ms */, KisSignalCompressor::POSTPONE); connect(m_d->updateTimer, SIGNAL(timeout()), SLOT(slotRebuildSelectors()), Qt::UniqueConnection); } KisVisualColorSelector::~KisVisualColorSelector() { delete m_d->updateTimer; } void KisVisualColorSelector::slotSetColor(const KoColor &c) { m_d->currentcolor = c; if (m_d->currentCS != c.colorSpace()) { slotsetColorSpace(c.colorSpace()); } else { m_d->channelValues = convertKoColorToShapeCoordinates(m_d->currentcolor); Q_FOREACH (KisVisualColorSelectorShape *shape, m_d->widgetlist) { shape->setChannelValues(m_d->channelValues, true); } } } void KisVisualColorSelector::slotsetColorSpace(const KoColorSpace *cs) { if (m_d->currentCS != cs) { m_d->currentCS = cs; slotRebuildSelectors(); } } void KisVisualColorSelector::setConfig(bool forceCircular, bool forceSelfUpdate) { m_d->circular = forceCircular; m_d->updateLonesome = forceSelfUpdate; } KoColor KisVisualColorSelector::getCurrentColor() const { return m_d->currentcolor; } QVector4D KisVisualColorSelector::getChannelValues() const { return m_d->channelValues; } KoColor KisVisualColorSelector::convertShapeCoordsToKoColor(const QVector4D &coordinates) const { KoColor c(m_d->currentCS); QVector4D baseValues(coordinates); QVector channelValues(c.colorSpace()->channelCount()); channelValues.fill(1.0); if (m_d->model != ColorModel::Channel && m_d->isRGBA == true) { if (m_d->model == ColorModel::HSV) { HSVToRGB(coordinates.x()*360, coordinates.y(), coordinates.z(), &baseValues[0], &baseValues[1], &baseValues[2]); } else if (m_d->model == ColorModel::HSL) { HSLToRGB(coordinates.x()*360, coordinates.y(), coordinates.z(), &baseValues[0], &baseValues[1], &baseValues[2]); } else if (m_d->model == ColorModel::HSI) { // why suddenly qreal? qreal temp[3]; HSIToRGB(coordinates.x(), coordinates.y(), coordinates.z(), &temp[0], &temp[1], &temp[2]); baseValues.setX(temp[0]); baseValues.setY(temp[1]); baseValues.setZ(temp[2]); } else /*if (m_d->model == ColorModel::HSY)*/ { QVector luma= m_d->currentCS->lumaCoefficients(); qreal temp[3]; HSYToRGB(coordinates.x(), coordinates.y(), coordinates.z(), &temp[0], &temp[1], &temp[2], luma[0], luma[1], luma[2]); baseValues.setX(temp[0]); baseValues.setY(temp[1]); baseValues.setZ(temp[2]); } + if (m_d->isLinear) { + for (int i=0; i<3; i++) { + baseValues[i] = pow(baseValues[i], 2.2); + } + } + } + + if (m_d->exposureSupported) { + baseValues *= m_d->channelMaxValues; } for (int i=0; icolorChannelCount; i++) { // TODO: proper exposure control channelValues[m_d->displayPosition[i]] = baseValues[i] /* *(maxvalue[i]) */; } c.colorSpace()->fromNormalisedChannelsValue(c.data(), channelValues); return c; } QVector4D KisVisualColorSelector::convertKoColorToShapeCoordinates(KoColor c) const { if (c.colorSpace() != m_d->currentCS) { c.convertTo(m_d->currentCS); } QVector channelValues (c.colorSpace()->channelCount()); channelValues.fill(1.0); m_d->currentCS->normalisedChannelsValue(c.data(), channelValues); QVector4D channelValuesDisplay(0, 0, 0, 0), coordinates(0, 0, 0, 0); - // TODO: proper exposure control // TODO: L*a*b is apparently not [0, 1]^3 as "normalized" values, needs extra transform (old bug) for (int i =0; icolorChannelCount; i++) { - channelValuesDisplay[i] = qBound(0.f, channelValues[m_d->displayPosition[i]], 1.f); + channelValuesDisplay[i] = channelValues[m_d->displayPosition[i]]; + } + + if (m_d->exposureSupported) { + channelValuesDisplay /= m_d->channelMaxValues; } if (m_d->model != ColorModel::Channel && m_d->isRGBA == true) { if (m_d->isRGBA == true) { + if (m_d->isLinear) { + for (int i=0; i<3; i++) { + channelValuesDisplay[i] = pow(channelValuesDisplay[i], 1/2.2); + } + } if (m_d->model == ColorModel::HSV){ QVector3D hsv; // TODO: handle undefined hue case (returns -1) RGBToHSV(channelValuesDisplay[0], channelValuesDisplay[1], channelValuesDisplay[2], &hsv[0], &hsv[1], &hsv[2]); hsv[0] /= 360; coordinates = QVector4D(hsv, 0.f); } else if (m_d->model == ColorModel::HSL) { QVector3D hsl; RGBToHSL(channelValuesDisplay[0], channelValuesDisplay[1], channelValuesDisplay[2], &hsl[0], &hsl[1], &hsl[2]); hsl[0] /= 360; coordinates = QVector4D(hsl, 0.f); } else if (m_d->model == ColorModel::HSI) { qreal hsi[3]; RGBToHSI(channelValuesDisplay[0], channelValuesDisplay[1], channelValuesDisplay[2], &hsi[0], &hsi[1], &hsi[2]); coordinates = QVector4D(hsi[0], hsi[1], hsi[2], 0.f); } else if (m_d->model == ColorModel::HSY) { QVector luma = m_d->currentCS->lumaCoefficients(); qreal hsy[3]; RGBToHSY(channelValuesDisplay[0], channelValuesDisplay[1], channelValuesDisplay[2], &hsy[0], &hsy[1], &hsy[2], luma[0], luma[1], luma[2]); coordinates = QVector4D(hsy[0], hsy[1], hsy[2], 0.f); } + for (int i=0; i<3; i++) { + coordinates[i] = qBound(0.f, coordinates[i], 1.f); + } } } else { - for (int i=0; i<4; i++) - { + for (int i=0; i<4; i++) { coordinates[i] = qBound(0.f, channelValuesDisplay[i], 1.f); } } return coordinates; } void KisVisualColorSelector::configurationChanged() { if (m_d->updateTimer) { m_d->updateTimer->start(); } } +void KisVisualColorSelector::slotDisplayConfigurationChanged() +{ + Q_ASSERT(m_d->displayRenderer); + + if (m_d->currentCS) + { + m_d->channelMaxValues = QVector4D(1, 1, 1, 1); + QList channels = m_d->currentCS->channels(); + for (int i=0; icolorChannelCount; ++i) + { + m_d->channelMaxValues[i] = m_d->displayRenderer->maxVisibleFloatValue(channels[m_d->displayPosition[i]]); + } + // need to re-scale our normalized channel values on exposure changes: + m_d->channelValues = convertKoColorToShapeCoordinates(m_d->currentcolor); + Q_FOREACH (KisVisualColorSelectorShape *shape, m_d->widgetlist) { + shape->setChannelValues(m_d->channelValues, true); + } + } +} + void KisVisualColorSelector::slotRebuildSelectors() { KConfigGroup cfg = KSharedConfig::openConfig()->group("advancedColorSelector"); m_d->acs_config = KisColorSelectorConfiguration::fromString(cfg.readEntry("colorSelectorConfiguration", KisColorSelectorConfiguration().toString())); QList channelList = m_d->currentCS->channels(); int cCount = 0; Q_FOREACH(const KoChannelInfo *channel, channelList) { if (channel->channelType() != KoChannelInfo::ALPHA) { m_d->displayPosition[cCount] = channel->displayPosition(); ++cCount; } } Q_ASSERT_X(cCount < 5, "", "unsupported channel count!"); m_d->colorChannelCount = cCount; // TODO: The following is done because the IDs are actually strings. Ideally, in the future, we // refactor everything so that the IDs are actually proper enums or something faster. if (m_d->displayRenderer && (m_d->currentCS->colorDepthId() == Float16BitsColorDepthID || m_d->currentCS->colorDepthId() == Float32BitsColorDepthID || m_d->currentCS->colorDepthId() == Float64BitsColorDepthID) && m_d->currentCS->colorModelId() != LABAColorModelID && m_d->currentCS->colorModelId() != CMYKAColorModelID) { m_d->exposureSupported = true; } else { m_d->exposureSupported = false; } - if (m_d->currentCS->colorModelId() == RGBAColorModelID) { - m_d->isRGBA = true; - } else { - m_d->isRGBA = false; - } + m_d->isRGBA = (m_d->currentCS->colorModelId() == RGBAColorModelID); + const KoColorProfile *profile = m_d->currentCS->profile(); + m_d->isLinear = (profile && profile->isLinear()); qDeleteAll(children()); m_d->widgetlist.clear(); // TODO: Layout only used for monochrome selector currently, but always present QLayout *layout = new QHBoxLayout; //recreate all the widgets. m_d->model = KisVisualColorSelector::Channel; if (m_d->currentCS->colorChannelCount() == 1) { KisVisualColorSelectorShape *bar; if (m_d->circular==false) { bar = new KisVisualRectangleSelectorShape(this, KisVisualColorSelectorShape::onedimensional, m_d->currentCS, 0, 0,m_d->displayRenderer, 20); bar->setMaximumWidth(width()*0.1); bar->setMaximumHeight(height()); } else { bar = new KisVisualEllipticalSelectorShape(this, KisVisualColorSelectorShape::onedimensional, m_d->currentCS, 0, 0,m_d->displayRenderer, 20, KisVisualEllipticalSelectorShape::borderMirrored); layout->setMargin(0); } connect(bar, SIGNAL(sigCursorMoved(QPointF)), SLOT(slotCursorMoved(QPointF))); layout->addWidget(bar); m_d->widgetlist.append(bar); } else if (m_d->currentCS->colorChannelCount() == 3) { KisVisualColorSelector::ColorModel modelS = KisVisualColorSelector::HSV; int channel1 = 0; int channel2 = 1; int channel3 = 2; switch(m_d->acs_config.subTypeParameter) { case KisColorSelectorConfiguration::H: channel1 = 0; break; case KisColorSelectorConfiguration::hsyS: case KisColorSelectorConfiguration::hsiS: case KisColorSelectorConfiguration::hslS: case KisColorSelectorConfiguration::hsvS: channel1 = 1; break; case KisColorSelectorConfiguration::V: case KisColorSelectorConfiguration::L: case KisColorSelectorConfiguration::I: case KisColorSelectorConfiguration::Y: channel1 = 2; break; default: Q_ASSERT_X(false, "", "Invalid acs_config.subTypeParameter"); } switch(m_d->acs_config.mainTypeParameter) { case KisColorSelectorConfiguration::hsySH: modelS = KisVisualColorSelector::HSY; channel2 = 0; channel3 = 1; break; case KisColorSelectorConfiguration::hsiSH: modelS = KisVisualColorSelector::HSI; channel2 = 0; channel3 = 1; break; case KisColorSelectorConfiguration::hslSH: modelS = KisVisualColorSelector::HSL; channel2 = 0; channel3 = 1; break; case KisColorSelectorConfiguration::hsvSH: modelS = KisVisualColorSelector::HSV; channel2 = 0; channel3 = 1; break; case KisColorSelectorConfiguration::YH: modelS = KisVisualColorSelector::HSY; channel2 = 0; channel3 = 2; break; case KisColorSelectorConfiguration::LH: modelS = KisVisualColorSelector::HSL; channel2 = 0; channel3 = 2; break; case KisColorSelectorConfiguration::IH: modelS = KisVisualColorSelector::HSL; channel2 = 0; channel3 = 2; break; case KisColorSelectorConfiguration::VH: modelS = KisVisualColorSelector::HSV; channel2 = 0; channel3 = 2; break; case KisColorSelectorConfiguration::SY: modelS = KisVisualColorSelector::HSY; channel2 = 1; channel3 = 2; break; case KisColorSelectorConfiguration::SI: modelS = KisVisualColorSelector::HSI; channel2 = 1; channel3 = 2; break; case KisColorSelectorConfiguration::SL: modelS = KisVisualColorSelector::HSL; channel2 = 1; channel3 = 2; break; case KisColorSelectorConfiguration::SV: case KisColorSelectorConfiguration::SV2: modelS = KisVisualColorSelector::HSV; channel2 = 1; channel3 = 2; break; default: Q_ASSERT_X(false, "", "Invalid acs_config.mainTypeParameter"); } if (m_d->acs_config.mainType == KisColorSelectorConfiguration::Triangle) { modelS = KisVisualColorSelector::HSV; //Triangle only really works in HSV mode. } m_d->model = modelS; KisVisualColorSelectorShape *bar; if (m_d->acs_config.subType == KisColorSelectorConfiguration::Ring) { bar = new KisVisualEllipticalSelectorShape(this, KisVisualColorSelectorShape::onedimensional, m_d->currentCS, channel1, channel1, m_d->displayRenderer, 20,KisVisualEllipticalSelectorShape::border); } else if (m_d->acs_config.subType == KisColorSelectorConfiguration::Slider && m_d->circular == false) { bar = new KisVisualRectangleSelectorShape(this, KisVisualColorSelectorShape::onedimensional, m_d->currentCS, channel1, channel1, m_d->displayRenderer, 20); } else if (m_d->acs_config.subType == KisColorSelectorConfiguration::Slider && m_d->circular == true) { bar = new KisVisualEllipticalSelectorShape(this, KisVisualColorSelectorShape::onedimensional, m_d->currentCS, channel1, channel1, m_d->displayRenderer, 20, KisVisualEllipticalSelectorShape::borderMirrored); } else { // Accessing bar below would crash since it's not initialized. // Hopefully this can never happen. warnUI << "Invalid subType, cannot initialize KisVisualColorSelectorShape"; Q_ASSERT_X(false, "", "Invalid subType, cannot initialize KisVisualColorSelectorShape"); return; } m_d->widgetlist.append(bar); KisVisualColorSelectorShape *block; if (m_d->acs_config.mainType == KisColorSelectorConfiguration::Triangle) { block = new KisVisualTriangleSelectorShape(this, KisVisualColorSelectorShape::twodimensional, m_d->currentCS, channel2, channel3, m_d->displayRenderer); } else if (m_d->acs_config.mainType == KisColorSelectorConfiguration::Square) { block = new KisVisualRectangleSelectorShape(this, KisVisualColorSelectorShape::twodimensional, m_d->currentCS, channel2, channel3, m_d->displayRenderer); } else { block = new KisVisualEllipticalSelectorShape(this, KisVisualColorSelectorShape::twodimensional, m_d->currentCS, channel2, channel3, m_d->displayRenderer); } connect(bar, SIGNAL(sigCursorMoved(QPointF)), SLOT(slotCursorMoved(QPointF))); connect(block, SIGNAL(sigCursorMoved(QPointF)), SLOT(slotCursorMoved(QPointF))); m_d->widgetlist.append(block); } else if (m_d->currentCS->colorChannelCount() == 4) { KisVisualRectangleSelectorShape *block = new KisVisualRectangleSelectorShape(this, KisVisualRectangleSelectorShape::twodimensional, m_d->currentCS, 0, 1); KisVisualRectangleSelectorShape *block2 = new KisVisualRectangleSelectorShape(this, KisVisualRectangleSelectorShape::twodimensional, m_d->currentCS, 2, 3); connect(block, SIGNAL(sigCursorMoved(QPointF)), SLOT(slotCursorMoved(QPointF))); connect(block2, SIGNAL(sigCursorMoved(QPointF)), SLOT(slotCursorMoved(QPointF))); m_d->widgetlist.append(block); m_d->widgetlist.append(block2); } this->setLayout(layout); // make sure we call "our" resize function KisVisualColorSelector::resizeEvent(0); // finally recalculate channel values and update widgets + if (m_d->displayRenderer) { + slotDisplayConfigurationChanged(); + } m_d->channelValues = convertKoColorToShapeCoordinates(m_d->currentcolor); Q_FOREACH (KisVisualColorSelectorShape *shape, m_d->widgetlist) { shape->setChannelValues(m_d->channelValues, true); // if this widget is currently visible, new children are hidden by default shape->show(); } } void KisVisualColorSelector::setDisplayRenderer (const KoColorDisplayRendererInterface *displayRenderer) { m_d->displayRenderer = displayRenderer; if (m_d->widgetlist.size()>0) { Q_FOREACH (KisVisualColorSelectorShape *shape, m_d->widgetlist) { shape->setDisplayRenderer(displayRenderer); } } + connect(m_d->displayRenderer, SIGNAL(displayConfigurationChanged()), + SLOT(slotDisplayConfigurationChanged()), Qt::UniqueConnection); + slotDisplayConfigurationChanged(); } void KisVisualColorSelector::slotCursorMoved(QPointF pos) { const KisVisualColorSelectorShape *shape = qobject_cast(sender()); Q_ASSERT(shape); QVector channels = shape->getChannels(); m_d->channelValues[channels.at(0)] = pos.x(); if (shape->getDimensions() == KisVisualColorSelectorShape::twodimensional) { m_d->channelValues[channels.at(1)] = pos.y(); } KoColor newColor = convertShapeCoordsToKoColor(m_d->channelValues); if (newColor != m_d->currentcolor) { m_d->currentcolor = newColor; Q_FOREACH (KisVisualColorSelectorShape *widget, m_d->widgetlist) { if (widget != shape){ widget->setChannelValues(m_d->channelValues, false); } } emit sigNewColor(m_d->currentcolor); } } void KisVisualColorSelector::resizeEvent(QResizeEvent *) { int sizeValue = qMin(width(), height()); int borderWidth = qMax(sizeValue*0.1, 20.0); QRect newrect(0,0, this->geometry().width(), this->geometry().height()); if (!m_d->currentCS) { slotsetColorSpace(m_d->currentcolor.colorSpace()); } if (m_d->currentCS->colorChannelCount()==3) { // set border width first, else the resized painting may have happened already, and we'd have to re-render m_d->widgetlist.at(0)->setBorderWidth(borderWidth); if (m_d->acs_config.subType == KisColorSelectorConfiguration::Ring) { m_d->widgetlist.at(0)->resize(sizeValue,sizeValue); } else if (m_d->acs_config.subType == KisColorSelectorConfiguration::Slider && m_d->circular==false) { m_d->widgetlist.at(0)->resize(borderWidth, sizeValue); } else if (m_d->acs_config.subType == KisColorSelectorConfiguration::Slider && m_d->circular==true) { m_d->widgetlist.at(0)->resize(sizeValue,sizeValue); } if (m_d->acs_config.mainType == KisColorSelectorConfiguration::Triangle) { m_d->widgetlist.at(1)->setGeometry(m_d->widgetlist.at(0)->getSpaceForTriangle(newrect)); } else if (m_d->acs_config.mainType == KisColorSelectorConfiguration::Square) { m_d->widgetlist.at(1)->setGeometry(m_d->widgetlist.at(0)->getSpaceForSquare(newrect)); } else if (m_d->acs_config.mainType == KisColorSelectorConfiguration::Wheel) { m_d->widgetlist.at(1)->setGeometry(m_d->widgetlist.at(0)->getSpaceForCircle(newrect)); } } else if (m_d->currentCS->colorChannelCount() == 4) { int sizeBlock = qMin(width()/2 - 8, height()); m_d->widgetlist.at(0)->setGeometry(0, 0, sizeBlock, sizeBlock); m_d->widgetlist.at(1)->setGeometry(sizeBlock + 8, 0, sizeBlock, sizeBlock); } } diff --git a/libs/widgets/KisVisualColorSelector.h b/libs/widgets/KisVisualColorSelector.h index e4ba453772..fe5eb1c40b 100644 --- a/libs/widgets/KisVisualColorSelector.h +++ b/libs/widgets/KisVisualColorSelector.h @@ -1,87 +1,88 @@ /* * Copyright (C) Wolthera van Hovell tot Westerflier , (C) 2016 * * 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 of the License, 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. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. */ #ifndef KIS_VISUAL_COLOR_SELECTOR_H #define KIS_VISUAL_COLOR_SELECTOR_H #include #include #include #include #include #include #include #include "KoColorDisplayRendererInterface.h" #include "KisColorSelectorConfiguration.h" #include "KisColorSelectorInterface.h" #include "kritawidgets_export.h" /** * @brief The KisVisualColorSelector class * * This gives a color selector box that draws gradients and everything. * * Unlike other color selectors, this one draws the full gamut of the given * colorspace. */ class KRITAWIDGETS_EXPORT KisVisualColorSelector : public KisColorSelectorInterface { Q_OBJECT public: enum ColorModel{Channel, HSV, HSL, HSI, HSY, YUV}; explicit KisVisualColorSelector(QWidget *parent = 0); ~KisVisualColorSelector() override; /** * @brief setConfig * @param forceCircular * Force circular is for space where you only have room for a circular selector. * @param forceSelfUpdate * force self-update is for making it update itself when using a modal dialog. */ void setConfig(bool forceCircular, bool forceSelfUpdate) override; KoColor getCurrentColor() const override; QVector4D getChannelValues() const; KoColor convertShapeCoordsToKoColor(const QVector4D &coordinates) const; QVector4D convertKoColorToShapeCoordinates(KoColor c) const; public Q_SLOTS: void slotSetColor(const KoColor &c) override; void slotsetColorSpace(const KoColorSpace *cs); - void slotRebuildSelectors(); void configurationChanged(); void setDisplayRenderer (const KoColorDisplayRendererInterface *displayRenderer) override; private Q_SLOTS: void slotCursorMoved(QPointF pos); + void slotDisplayConfigurationChanged(); + void slotRebuildSelectors(); protected: void resizeEvent(QResizeEvent *) override; private: struct Private; const QScopedPointer m_d; void drawGradients(); }; #endif diff --git a/libs/widgets/KisVisualColorSelectorShape.cpp b/libs/widgets/KisVisualColorSelectorShape.cpp index e6e860d705..045c5fc642 100644 --- a/libs/widgets/KisVisualColorSelectorShape.cpp +++ b/libs/widgets/KisVisualColorSelectorShape.cpp @@ -1,295 +1,286 @@ /* * Copyright (C) Wolthera van Hovell tot Westerflier , (C) 2016 * * 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 of the License, 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. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. */ #include "KisVisualColorSelectorShape.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include "KoColorConversions.h" #include "KoColorDisplayRendererInterface.h" #include "KoChannelInfo.h" #include #include #include "kis_signal_compressor.h" #include "kis_debug.h" struct KisVisualColorSelectorShape::Private { QImage gradient; QImage fullSelector; bool imagesNeedUpdate {true}; QPointF currentCoordinates; // somewhat redundant? QVector4D currentChannelValues; Dimensions dimension; const KoColorSpace *colorSpace; int channel1; int channel2; bool mousePressActive = false; const KoColorDisplayRendererInterface *displayRenderer = 0; }; KisVisualColorSelectorShape::KisVisualColorSelectorShape(QWidget *parent, KisVisualColorSelectorShape::Dimensions dimension, const KoColorSpace *cs, int channel1, int channel2, const KoColorDisplayRendererInterface *displayRenderer): QWidget(parent), m_d(new Private) { m_d->dimension = dimension; m_d->colorSpace = cs; int maxchannel = m_d->colorSpace->colorChannelCount()-1; m_d->channel1 = qBound(0, channel1, maxchannel); m_d->channel2 = qBound(0, channel2, maxchannel); this->setSizePolicy(QSizePolicy::Expanding, QSizePolicy::Expanding); setDisplayRenderer(displayRenderer); } KisVisualColorSelectorShape::~KisVisualColorSelectorShape() { } QPointF KisVisualColorSelectorShape::getCursorPosition() { return m_d->currentCoordinates; } void KisVisualColorSelectorShape::setCursorPosition(QPointF position, bool signal) { QPointF newPos(qBound(0.0, position.x(), 1.0), qBound(0.0, position.y(), 1.0)); if (newPos != m_d->currentCoordinates) { m_d->currentCoordinates = newPos; // for internal consistency, because we have a bit of redundancy here m_d->currentChannelValues[m_d->channel1] = newPos.x(); if (m_d->dimension == Dimensions::twodimensional){ m_d->currentChannelValues[m_d->channel2] = newPos.y(); } update(); if (signal){ emit sigCursorMoved(newPos); } } } void KisVisualColorSelectorShape::setChannelValues(QVector4D channelValues, bool setCursor) { //qDebug() << this << "setChannelValues"; m_d->currentChannelValues = channelValues; if (setCursor) { - m_d->currentCoordinates = QPointF(channelValues[m_d->channel1], channelValues[m_d->channel2]); + m_d->currentCoordinates = QPointF(qBound(0.f, channelValues[m_d->channel1], 1.f), + qBound(0.f, channelValues[m_d->channel2], 1.f)); } else { // for internal consistency, because we have a bit of redundancy here m_d->currentChannelValues[m_d->channel1] = m_d->currentCoordinates.x(); if (m_d->dimension == Dimensions::twodimensional){ m_d->currentChannelValues[m_d->channel2] = m_d->currentCoordinates.y(); } } m_d->imagesNeedUpdate = true; update(); } void KisVisualColorSelectorShape::setDisplayRenderer (const KoColorDisplayRendererInterface *displayRenderer) { if (displayRenderer) { if (m_d->displayRenderer) { m_d->displayRenderer->disconnect(this); } m_d->displayRenderer = displayRenderer; } else { m_d->displayRenderer = KoDumbColorDisplayRenderer::instance(); } - connect(m_d->displayRenderer, SIGNAL(displayConfigurationChanged()), - SLOT(updateFromChangedDisplayRenderer()), Qt::UniqueConnection); - -} - -void KisVisualColorSelectorShape::updateFromChangedDisplayRenderer() -{ - //qDebug() << this << "updateFromChangedDisplayRenderer();"; - m_d->imagesNeedUpdate = true; - update(); } void KisVisualColorSelectorShape::forceImageUpdate() { //qDebug() << this << "forceImageUpdate"; m_d->imagesNeedUpdate = true; } QColor KisVisualColorSelectorShape::getColorFromConverter(KoColor c){ QColor col; KoColor color = c; if (m_d->displayRenderer) { color.convertTo(m_d->displayRenderer->getPaintingColorSpace()); col = m_d->displayRenderer->toQColor(c); } else { col = c.toQColor(); } return col; } // currently unused? void KisVisualColorSelectorShape::slotSetActiveChannels(int channel1, int channel2) { //qDebug() << this << "slotSetActiveChannels"; int maxchannel = m_d->colorSpace->colorChannelCount()-1; m_d->channel1 = qBound(0, channel1, maxchannel); m_d->channel2 = qBound(0, channel2, maxchannel); m_d->imagesNeedUpdate = true; update(); } bool KisVisualColorSelectorShape::imagesNeedUpdate() const { return m_d->imagesNeedUpdate; } QImage KisVisualColorSelectorShape::getImageMap() { //qDebug() << this << ">>>>>>>>> getImageMap()" << m_d->imagesNeedUpdate; if (m_d->imagesNeedUpdate) { // Fill a buffer with the right kocolors m_d->gradient = renderBackground(m_d->currentChannelValues, m_d->colorSpace->pixelSize()); m_d->imagesNeedUpdate = false; } return m_d->gradient; } QImage KisVisualColorSelectorShape::convertImageMap(const quint8 *rawColor, quint32 size) const { Q_ASSERT(size == width()*height()*m_d->colorSpace->pixelSize()); QImage image; // Convert the buffer to a qimage if (m_d->displayRenderer) { image = m_d->displayRenderer->convertToQImage(m_d->colorSpace, rawColor, width(), height()); } else { image = m_d->colorSpace->convertToQImage(rawColor, width(), height(), 0, KoColorConversionTransformation::internalRenderingIntent(), KoColorConversionTransformation::internalConversionFlags()); } // safeguard: if (image.isNull()) { image = QImage(width(), height(), QImage::Format_ARGB32); image.fill(Qt::black); } return image; } QImage KisVisualColorSelectorShape::renderBackground(const QVector4D &channelValues, quint32 pixelSize) const { const KisVisualColorSelector *selector = qobject_cast(parent()); Q_ASSERT(selector); quint32 imageSize = width() * height() * m_d->colorSpace->pixelSize(); QScopedArrayPointer raw(new quint8[imageSize] {}); quint8 *dataPtr = raw.data(); QVector4D coordinates = channelValues; for (int y = 0; y < height(); y++) { for (int x=0; x < width(); x++) { QPointF newcoordinate = convertWidgetCoordinateToShapeCoordinate(QPoint(x, y)); coordinates[m_d->channel1] = newcoordinate.x(); if (m_d->dimension == Dimensions::twodimensional){ coordinates[m_d->channel2] = newcoordinate.y(); } KoColor c = selector->convertShapeCoordsToKoColor(coordinates); memcpy(dataPtr, c.data(), pixelSize); dataPtr += pixelSize; } } return convertImageMap(raw.data(), imageSize); } void KisVisualColorSelectorShape::mousePressEvent(QMouseEvent *e) { if (e->button()==Qt::LeftButton) { m_d->mousePressActive = true; QPointF coordinates = convertWidgetCoordinateToShapeCoordinate(e->pos()); setCursorPosition(coordinates, true); } } void KisVisualColorSelectorShape::mouseMoveEvent(QMouseEvent *e) { if (m_d->mousePressActive==true) { QPointF coordinates = convertWidgetCoordinateToShapeCoordinate(e->pos()); setCursorPosition(coordinates, true); } else { e->ignore(); } } void KisVisualColorSelectorShape::mouseReleaseEvent(QMouseEvent *e) { if (e->button()==Qt::LeftButton) { m_d->mousePressActive = false; } } void KisVisualColorSelectorShape::paintEvent(QPaintEvent*) { QPainter painter(this); drawCursor(); painter.drawImage(0,0,m_d->fullSelector); } void KisVisualColorSelectorShape::resizeEvent(QResizeEvent *) { forceImageUpdate(); setMask(getMaskMap()); } KisVisualColorSelectorShape::Dimensions KisVisualColorSelectorShape::getDimensions() const { return m_d->dimension; } void KisVisualColorSelectorShape::setFullImage(QImage full) { m_d->fullSelector = full; } KoColor KisVisualColorSelectorShape::getCurrentColor() { const KisVisualColorSelector *selector = qobject_cast(parent()); if (selector) { return selector->convertShapeCoordsToKoColor(m_d->currentChannelValues); } return KoColor(m_d->colorSpace); } QVector KisVisualColorSelectorShape::getChannels() const { QVector channels(2); channels[0] = m_d->channel1; channels[1] = m_d->channel2; return channels; } diff --git a/libs/widgets/KisVisualColorSelectorShape.h b/libs/widgets/KisVisualColorSelectorShape.h index 5f596a200f..5852f2333f 100644 --- a/libs/widgets/KisVisualColorSelectorShape.h +++ b/libs/widgets/KisVisualColorSelectorShape.h @@ -1,225 +1,220 @@ /* * Copyright (C) Wolthera van Hovell tot Westerflier , (C) 2016 * * 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 of the License, 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. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. */ #ifndef KIS_VISUAL_COLOR_SELECTOR_SHAPE_H #define KIS_VISUAL_COLOR_SELECTOR_SHAPE_H #include #include #include #include #include #include #include #include "KoColorDisplayRendererInterface.h" #include "KisVisualColorSelector.h" #include "KisColorSelectorConfiguration.h" /** * @brief The KisVisualColorSelectorShape class * A 2d widget can represent at maximum 2 coordinates. * So first decide howmany coordinates you need. (onedimensional, or twodimensional) * Then the model, (Channel, HSV, HSL, HSI, YUV). Channel is the raw color channels. * When it finds a non-implemented feature it'll return to Channel. * Then, select the channels you wish to be affected. This uses the model, so for cmyk * the channel is c=0, m=1, y=2, k=3, but for hsv, hue=0, sat=1, and val=2 * These can also be set with 'slotsetactive channels'. * Then finally, connect the displayrenderer, you can also do this with 'setdisplayrenderer' * * Either way, this class is made to be subclassed, with a few virtuals so that the geometry * can be calculated properly. */ class KisVisualColorSelectorShape : public QWidget { Q_OBJECT public: /** * @brief The Dimensions enum * Whether or not the shape is single or two dimensional. **/ enum Dimensions{onedimensional, twodimensional}; enum ColorModel{Channel, HSV, HSL, HSI, HSY, YUV}; explicit KisVisualColorSelectorShape(QWidget *parent, KisVisualColorSelectorShape::Dimensions dimension, const KoColorSpace *cs, int channel1, int channel2, const KoColorDisplayRendererInterface *displayRenderer = KoDumbColorDisplayRenderer::instance()); ~KisVisualColorSelectorShape() override; /** * @brief getCursorPosition * @return current cursor position in shape-coordinates. */ QPointF getCursorPosition(); /** * @brief getDimensions * @return whether this is a single or twodimensional widget. */ Dimensions getDimensions() const; /** * @brief getPixmap * @return the pixmap of the gradient, for drawing on with a subclass. * the pixmap will not change unless 'm_d->setPixmap=true' which is toggled by * refresh and update functions. */ bool imagesNeedUpdate() const; QImage getImageMap(); /** * @brief setFullImage * Set the full widget image to be painted. * @param full this should be the full image. */ void setFullImage(QImage full); /** * @brief getCurrentColor * @return the current kocolor */ KoColor getCurrentColor(); /** * @brief setDisplayRenderer * disconnect the old display renderer if needed and connect the new one. * @param displayRenderer */ void setDisplayRenderer (const KoColorDisplayRendererInterface *displayRenderer); /** * @brief getColorFromConverter * @param c a koColor. * @return get the qcolor from the given kocolorusing this widget's display renderer. */ QColor getColorFromConverter(KoColor c); /** * @brief getSpaceForSquare * @param geom the full widget rectangle * @return rectangle with enough space for second widget */ virtual QRect getSpaceForSquare(QRect geom) = 0; virtual QRect getSpaceForCircle(QRect geom) = 0; virtual QRect getSpaceForTriangle(QRect geom) = 0; /** * @brief forceImageUpdate * force the image to recache. */ void forceImageUpdate(); /** * @brief setBorderWidth * set the border of the single dimensional selector. * @param width */ virtual void setBorderWidth(int width) = 0; /** * @brief getChannels * get used channels * @return */ QVector getChannels() const; /** * @brief setCursorPosition * Set the cursor to normalized shape coordinates. This will only repaint the cursor. * @param position normalized shape coordinates ([0,1] range, not yet transformed to actual channel values!) * @param signal if true, emit a sigCursorMoved signal */ void setCursorPosition(QPointF position, bool signal = false); /** * @brief setChannelValues * Set the current channel values; * Note that channel values controlled by the shape itself have no effect unless setCursor is true. * This will trigger a full widget repaint. * @param position normalized shape coordinates ([0,1] range) * these are not yet transformed to color space specific ranges! * @param setCursor if true, sets the cursor too, otherwise the shape-controlled channels are not set */ void setChannelValues(QVector4D channelValues, bool setCursor); Q_SIGNALS: void sigCursorMoved(QPointF pos); public Q_SLOTS: /** * @brief slotSetActiveChannels * Change the active channels if necessary. * @param channel1 used by single and twodimensional widgets. * @param channel2 only used by twodimensional widgets. */ void slotSetActiveChannels(int channel1, int channel2); - /** - * @brief updateFromChangedDisplayRenderer - * for updating from the display renderer... not sure why this one is public. - */ - void updateFromChangedDisplayRenderer(); protected: /** * @brief convertImageMap * convert image data containing raw KoColor data into a QImage * @param data must point to memory of size width()*height()*pixelSize * @param size the number of bytes to read from data, must match aforementioned cirteria * @return the converted QImage guaranteed to match the widget size (black content on failure) */ QImage convertImageMap(const quint8 *rawColor, quint32 size) const; /** * @brief renderBackground * Render the widget background visible inside the widget's mask in current color space * Rendering shall be done with the conversion functions of KisVisualColorSelector * @param data points to zero-initialized memory of size width()*height()*pixelSize * @param pixelSize the data size to transfer from KoColor::data() to data per pixel * in the current color space * @param channelValues the normalized channel values of the currently picked color */ virtual QImage renderBackground(const QVector4D &channelValues, quint32 pixelSize) const; void mousePressEvent(QMouseEvent *e) override; void mouseMoveEvent(QMouseEvent *e) override; void mouseReleaseEvent(QMouseEvent *e) override; void paintEvent(QPaintEvent*) override; void resizeEvent(QResizeEvent *) override; private: struct Private; const QScopedPointer m_d; /** * @brief convertShapeCoordinateToWidgetCoordinate * @return take the position in the shape and convert it to screen coordinates. */ virtual QPointF convertShapeCoordinateToWidgetCoordinate(QPointF) const = 0; /** * @brief convertWidgetCoordinateToShapeCoordinate * Convert a coordinate in the widget's height/width to a shape coordinate. * @param coordinate the position your wish to have the shape coordinates of. */ virtual QPointF convertWidgetCoordinateToShapeCoordinate(QPoint coordinate) const = 0; /** * @brief getPixmap * @return the pixmap of this shape. */ virtual QRegion getMaskMap() = 0; virtual void drawCursor() = 0; }; #endif