diff --git a/libs/image/kis_image.cc b/libs/image/kis_image.cc index cf0c812bb7..5c975c50b8 100644 --- a/libs/image/kis_image.cc +++ b/libs/image/kis_image.cc @@ -1,1729 +1,1726 @@ /* * Copyright (c) 2002 Patrick Julien * Copyright (c) 2007 Boudewijn Rempt * * 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 "kis_image.h" #include // WORDS_BIGENDIAN #include #include #include #include #include #include #include #include #include #include #include "KoColorSpaceRegistry.h" #include "KoColor.h" #include "KoColorProfile.h" #include #include "KisProofingConfiguration.h" #include "recorder/kis_action_recorder.h" #include "kis_adjustment_layer.h" #include "kis_annotation.h" #include "kis_change_profile_visitor.h" #include "kis_colorspace_convert_visitor.h" #include "kis_count_visitor.h" #include "kis_filter_strategy.h" #include "kis_group_layer.h" #include "commands/kis_image_commands.h" #include "kis_layer.h" #include "kis_meta_data_merge_strategy_registry.h" #include "kis_name_server.h" #include "kis_paint_layer.h" #include "kis_painter.h" #include "kis_selection.h" #include "kis_transaction.h" #include "kis_meta_data_merge_strategy.h" #include "kis_memory_statistics_server.h" #include "kis_image_config.h" #include "kis_update_scheduler.h" #include "kis_image_signal_router.h" #include "kis_image_animation_interface.h" #include "kis_stroke_strategy.h" #include "kis_image_barrier_locker.h" #include "kis_undo_stores.h" #include "kis_legacy_undo_adapter.h" #include "kis_post_execution_undo_adapter.h" #include "kis_transform_worker.h" #include "kis_processing_applicator.h" #include "processing/kis_crop_processing_visitor.h" #include "processing/kis_crop_selections_processing_visitor.h" #include "processing/kis_transform_processing_visitor.h" #include "commands_new/kis_image_resize_command.h" #include "commands_new/kis_image_set_resolution_command.h" #include "commands_new/kis_activate_selection_mask_command.h" #include "kis_composite_progress_proxy.h" #include "kis_layer_composition.h" #include "kis_wrapped_rect.h" #include "kis_crop_saved_extra_data.h" #include "kis_layer_utils.h" #include "kis_lod_transform.h" #include "kis_suspend_projection_updates_stroke_strategy.h" #include "kis_sync_lod_cache_stroke_strategy.h" #include "kis_projection_updates_filter.h" #include "kis_layer_projection_plane.h" #include "kis_update_time_monitor.h" #include "kis_image_barrier_locker.h" #include #include #include "kis_time_range.h" // #define SANITY_CHECKS #ifdef SANITY_CHECKS #define SANITY_CHECK_LOCKED(name) \ if (!locked()) warnKrita() << "Locking policy failed:" << name \ << "has been called without the image" \ "being locked"; #else #define SANITY_CHECK_LOCKED(name) #endif struct KisImageSPStaticRegistrar { KisImageSPStaticRegistrar() { qRegisterMetaType("KisImageSP"); } }; static KisImageSPStaticRegistrar __registrar; class KisImage::KisImagePrivate { public: KisImagePrivate(KisImage *_q, qint32 w, qint32 h, const KoColorSpace *c, KisUndoStore *undo, KisImageAnimationInterface *_animationInterface) : q(_q) , lockedForReadOnly(false) , width(w) , height(h) , colorSpace(c ? c : KoColorSpaceRegistry::instance()->rgb8()) , nserver(1) , undoStore(undo ? undo : new KisDumbUndoStore()) , legacyUndoAdapter(undoStore.data(), _q) , postExecutionUndoAdapter(undoStore.data(), _q) , recorder(_q) , signalRouter(_q) , animationInterface(_animationInterface) , scheduler(_q, _q) , axesCenter(QPointF(0.5, 0.5)) { { KisImageConfig cfg; if (cfg.enableProgressReporting()) { scheduler.setProgressProxy(&compositeProgressProxy); } // Each of these lambdas defines a new factory function. scheduler.setLod0ToNStrokeStrategyFactory( [=](bool forgettable) { return KisLodSyncPair( new KisSyncLodCacheStrokeStrategy(KisImageWSP(q), forgettable), KisSyncLodCacheStrokeStrategy::createJobsData(KisImageWSP(q))); }); scheduler.setSuspendUpdatesStrokeStrategyFactory( [=]() { return KisSuspendResumePair( new KisSuspendProjectionUpdatesStrokeStrategy(KisImageWSP(q), true), KisSuspendProjectionUpdatesStrokeStrategy::createSuspendJobsData(KisImageWSP(q))); }); scheduler.setResumeUpdatesStrokeStrategyFactory( [=]() { return KisSuspendResumePair( new KisSuspendProjectionUpdatesStrokeStrategy(KisImageWSP(q), false), KisSuspendProjectionUpdatesStrokeStrategy::createResumeJobsData(KisImageWSP(q))); }); } connect(q, SIGNAL(sigImageModified()), KisMemoryStatisticsServer::instance(), SLOT(notifyImageChanged())); } ~KisImagePrivate() { /** * Stop animation interface. It may use the rootLayer. */ delete animationInterface; /** * First delete the nodes, while strokes * and undo are still alive */ rootLayer.clear(); } KisImage *q; quint32 lockCount = 0; bool lockedForReadOnly; qint32 width; qint32 height; double xres = 1.0; double yres = 1.0; const KoColorSpace * colorSpace; KisProofingConfigurationSP proofingConfig; KisSelectionSP deselectedGlobalSelection; KisGroupLayerSP rootLayer; // The layers are contained in here QList compositions; KisNodeSP isolatedRootNode; bool wrapAroundModePermitted = false; KisNameServer nserver; QScopedPointer undoStore; KisLegacyUndoAdapter legacyUndoAdapter; KisPostExecutionUndoAdapter postExecutionUndoAdapter; KisActionRecorder recorder; vKisAnnotationSP annotations; QAtomicInt disableUIUpdateSignals; KisProjectionUpdatesFilterSP projectionUpdatesFilter; KisImageSignalRouter signalRouter; KisImageAnimationInterface *animationInterface; KisUpdateScheduler scheduler; QAtomicInt disableDirtyRequests; KisCompositeProgressProxy compositeProgressProxy; bool blockLevelOfDetail = false; QPointF axesCenter; bool tryCancelCurrentStrokeAsync(); void notifyProjectionUpdatedInPatches(const QRect &rc); }; KisImage::KisImage(KisUndoStore *undoStore, qint32 width, qint32 height, const KoColorSpace * colorSpace, const QString& name) : QObject(0) , KisShared() , m_d(new KisImagePrivate(this, width, height, colorSpace, undoStore, new KisImageAnimationInterface(this))) { // make sure KisImage belongs to the GUI thread moveToThread(qApp->thread()); setObjectName(name); setRootLayer(new KisGroupLayer(this, "root", OPACITY_OPAQUE_U8)); } KisImage::~KisImage() { dbgImage << "deleting kisimage" << objectName(); /** * Request the tools to end currently running strokes */ waitForDone(); delete m_d; disconnect(); // in case Qt gets confused } KisImage *KisImage::clone(bool exactCopy) { return new KisImage(*this, 0, exactCopy); } KisImage::KisImage(const KisImage& rhs, KisUndoStore *undoStore, bool exactCopy) : KisNodeFacade(), KisNodeGraphListener(), KisShared(), m_d(new KisImagePrivate(this, rhs.width(), rhs.height(), rhs.colorSpace(), undoStore ? undoStore : new KisDumbUndoStore(), new KisImageAnimationInterface(*rhs.animationInterface(), this))) { // make sure KisImage belongs to the GUI thread moveToThread(qApp->thread()); setObjectName(rhs.objectName()); m_d->xres = rhs.m_d->xres; m_d->yres = rhs.m_d->yres; if (rhs.m_d->proofingConfig) { m_d->proofingConfig = toQShared(new KisProofingConfiguration(*rhs.m_d->proofingConfig)); } KisNodeSP newRoot = rhs.root()->clone(); newRoot->setGraphListener(this); newRoot->setImage(this); m_d->rootLayer = dynamic_cast(newRoot.data()); setRoot(newRoot); if (exactCopy) { QQueue linearizedNodes; KisLayerUtils::recursiveApplyNodes(rhs.root(), [&linearizedNodes](KisNodeSP node) { linearizedNodes.enqueue(node); }); KisLayerUtils::recursiveApplyNodes(newRoot, [&linearizedNodes](KisNodeSP node) { KisNodeSP refNode = linearizedNodes.dequeue(); node->setUuid(refNode->uuid()); }); } Q_FOREACH (KisLayerCompositionSP comp, rhs.m_d->compositions) { m_d->compositions << toQShared(new KisLayerComposition(*comp, this)); } rhs.m_d->nserver = KisNameServer(rhs.m_d->nserver); vKisAnnotationSP newAnnotations; Q_FOREACH (KisAnnotationSP annotation, rhs.m_d->annotations) { newAnnotations << annotation->clone(); } m_d->annotations = newAnnotations; KIS_ASSERT_RECOVER_NOOP(!rhs.m_d->projectionUpdatesFilter); KIS_ASSERT_RECOVER_NOOP(!rhs.m_d->disableUIUpdateSignals); KIS_ASSERT_RECOVER_NOOP(!rhs.m_d->disableDirtyRequests); m_d->blockLevelOfDetail = rhs.m_d->blockLevelOfDetail; } void KisImage::aboutToAddANode(KisNode *parent, int index) { KisNodeGraphListener::aboutToAddANode(parent, index); SANITY_CHECK_LOCKED("aboutToAddANode"); } void KisImage::nodeHasBeenAdded(KisNode *parent, int index) { KisNodeGraphListener::nodeHasBeenAdded(parent, index); SANITY_CHECK_LOCKED("nodeHasBeenAdded"); m_d->signalRouter.emitNodeHasBeenAdded(parent, index); KisNodeSP newNode = parent->at(index); if (!dynamic_cast(newNode.data())) { stopIsolatedMode(); } } void KisImage::aboutToRemoveANode(KisNode *parent, int index) { KisNodeSP deletedNode = parent->at(index); if (!dynamic_cast(deletedNode.data())) { stopIsolatedMode(); } KisNodeGraphListener::aboutToRemoveANode(parent, index); SANITY_CHECK_LOCKED("aboutToRemoveANode"); m_d->signalRouter.emitAboutToRemoveANode(parent, index); } void KisImage::nodeChanged(KisNode* node) { KisNodeGraphListener::nodeChanged(node); requestStrokeEnd(); m_d->signalRouter.emitNodeChanged(node); } void KisImage::invalidateAllFrames() { invalidateFrames(KisTimeRange::infinite(0), QRect()); } KisSelectionSP KisImage::globalSelection() const { KisSelectionMaskSP selectionMask = m_d->rootLayer->selectionMask(); if (selectionMask) { return selectionMask->selection(); } else { return 0; } } void KisImage::setGlobalSelection(KisSelectionSP globalSelection) { KisSelectionMaskSP selectionMask = m_d->rootLayer->selectionMask(); if (!globalSelection) { if (selectionMask) { removeNode(selectionMask); } } else { if (!selectionMask) { selectionMask = new KisSelectionMask(this); selectionMask->initSelection(m_d->rootLayer); addNode(selectionMask); // If we do not set the selection now, the setActive call coming next // can be very, very expensive, depending on the size of the image. selectionMask->setSelection(globalSelection); selectionMask->setActive(true); } else { selectionMask->setSelection(globalSelection); } Q_ASSERT(m_d->rootLayer->childCount() > 0); Q_ASSERT(m_d->rootLayer->selectionMask()); } m_d->deselectedGlobalSelection = 0; m_d->legacyUndoAdapter.emitSelectionChanged(); } void KisImage::deselectGlobalSelection() { KisSelectionSP savedSelection = globalSelection(); setGlobalSelection(0); m_d->deselectedGlobalSelection = savedSelection; } bool KisImage::canReselectGlobalSelection() { return m_d->deselectedGlobalSelection; } void KisImage::reselectGlobalSelection() { if(m_d->deselectedGlobalSelection) { setGlobalSelection(m_d->deselectedGlobalSelection); } } QString KisImage::nextLayerName(const QString &_baseName) const { QString baseName = _baseName; if (m_d->nserver.currentSeed() == 0) { m_d->nserver.number(); return i18n("background"); } if (baseName.isEmpty()) { baseName = i18n("Layer"); } return QString("%1 %2").arg(baseName).arg(m_d->nserver.number()); } void KisImage::rollBackLayerName() { m_d->nserver.rollback(); } KisCompositeProgressProxy* KisImage::compositeProgressProxy() { return &m_d->compositeProgressProxy; } bool KisImage::locked() const { return m_d->lockCount != 0; } void KisImage::barrierLock(bool readOnly) { if (!locked()) { requestStrokeEnd(); m_d->scheduler.barrierLock(); m_d->lockedForReadOnly = readOnly; } else { m_d->lockedForReadOnly &= readOnly; } m_d->lockCount++; } bool KisImage::tryBarrierLock(bool readOnly) { bool result = true; if (!locked()) { result = m_d->scheduler.tryBarrierLock(); m_d->lockedForReadOnly = readOnly; } if (result) { m_d->lockCount++; m_d->lockedForReadOnly &= readOnly; } return result; } bool KisImage::isIdle(bool allowLocked) { return (allowLocked || !locked()) && m_d->scheduler.isIdle(); } void KisImage::lock() { if (!locked()) { requestStrokeEnd(); m_d->scheduler.lock(); } m_d->lockCount++; m_d->lockedForReadOnly = false; } void KisImage::unlock() { Q_ASSERT(locked()); if (locked()) { m_d->lockCount--; if (m_d->lockCount == 0) { m_d->scheduler.unlock(!m_d->lockedForReadOnly); } } } void KisImage::blockUpdates() { m_d->scheduler.blockUpdates(); } void KisImage::unblockUpdates() { m_d->scheduler.unblockUpdates(); } void KisImage::setSize(const QSize& size) { m_d->width = size.width(); m_d->height = size.height(); } void KisImage::resizeImageImpl(const QRect& newRect, bool cropLayers) { if (newRect == bounds() && !cropLayers) return; KUndo2MagicString actionName = cropLayers ? kundo2_i18n("Crop Image") : kundo2_i18n("Resize Image"); KisImageSignalVector emitSignals; emitSignals << ComplexSizeChangedSignal(newRect, newRect.size()); emitSignals << ModifiedSignal; KisCropSavedExtraData *extraData = new KisCropSavedExtraData(cropLayers ? KisCropSavedExtraData::CROP_IMAGE : KisCropSavedExtraData::RESIZE_IMAGE, newRect); KisProcessingApplicator applicator(this, m_d->rootLayer, KisProcessingApplicator::RECURSIVE | KisProcessingApplicator::NO_UI_UPDATES, emitSignals, actionName, extraData); if (cropLayers || !newRect.topLeft().isNull()) { KisProcessingVisitorSP visitor = new KisCropProcessingVisitor(newRect, cropLayers, true); applicator.applyVisitorAllFrames(visitor, KisStrokeJobData::CONCURRENT); } applicator.applyCommand(new KisImageResizeCommand(this, newRect.size())); applicator.end(); } void KisImage::resizeImage(const QRect& newRect) { resizeImageImpl(newRect, false); } void KisImage::cropImage(const QRect& newRect) { resizeImageImpl(newRect, true); } void KisImage::cropNode(KisNodeSP node, const QRect& newRect) { bool isLayer = qobject_cast(node.data()); KUndo2MagicString actionName = isLayer ? kundo2_i18n("Crop Layer") : kundo2_i18n("Crop Mask"); KisImageSignalVector emitSignals; emitSignals << ModifiedSignal; KisCropSavedExtraData *extraData = new KisCropSavedExtraData(KisCropSavedExtraData::CROP_LAYER, newRect, node); KisProcessingApplicator applicator(this, node, KisProcessingApplicator::RECURSIVE, emitSignals, actionName, extraData); KisProcessingVisitorSP visitor = new KisCropProcessingVisitor(newRect, true, false); applicator.applyVisitorAllFrames(visitor, KisStrokeJobData::CONCURRENT); applicator.end(); } void KisImage::scaleImage(const QSize &size, qreal xres, qreal yres, KisFilterStrategy *filterStrategy) { bool resolutionChanged = xres != xRes() && yres != yRes(); bool sizeChanged = size != this->size(); if (!resolutionChanged && !sizeChanged) return; KisImageSignalVector emitSignals; if (resolutionChanged) emitSignals << ResolutionChangedSignal; if (sizeChanged) emitSignals << ComplexSizeChangedSignal(bounds(), size); emitSignals << ModifiedSignal; KUndo2MagicString actionName = sizeChanged ? kundo2_i18n("Scale Image") : kundo2_i18n("Change Image Resolution"); KisProcessingApplicator::ProcessingFlags signalFlags = (resolutionChanged || sizeChanged) ? KisProcessingApplicator::NO_UI_UPDATES : KisProcessingApplicator::NONE; KisProcessingApplicator applicator(this, m_d->rootLayer, KisProcessingApplicator::RECURSIVE | signalFlags, emitSignals, actionName); qreal sx = qreal(size.width()) / this->size().width(); qreal sy = qreal(size.height()) / this->size().height(); QTransform shapesCorrection; if (resolutionChanged) { shapesCorrection = QTransform::fromScale(xRes() / xres, yRes() / yres); } KisProcessingVisitorSP visitor = new KisTransformProcessingVisitor(sx, sy, 0, 0, QPointF(), 0, 0, 0, filterStrategy, shapesCorrection); applicator.applyVisitorAllFrames(visitor, KisStrokeJobData::CONCURRENT); if (resolutionChanged) { KUndo2Command *parent = new KisResetShapesCommand(m_d->rootLayer); new KisImageSetResolutionCommand(this, xres, yres, parent); applicator.applyCommand(parent); } if (sizeChanged) { applicator.applyCommand(new KisImageResizeCommand(this, size)); } applicator.end(); } void KisImage::scaleNode(KisNodeSP node, qreal scaleX, qreal scaleY, KisFilterStrategy *filterStrategy) { KUndo2MagicString actionName(kundo2_i18n("Scale Layer")); KisImageSignalVector emitSignals; emitSignals << ModifiedSignal; KisProcessingApplicator applicator(this, node, KisProcessingApplicator::RECURSIVE, emitSignals, actionName); KisProcessingVisitorSP visitor = new KisTransformProcessingVisitor(scaleX, scaleY, 0, 0, QPointF(), 0, 0, 0, filterStrategy); applicator.applyVisitorAllFrames(visitor, KisStrokeJobData::CONCURRENT); applicator.end(); } void KisImage::rotateImpl(const KUndo2MagicString &actionName, KisNodeSP rootNode, bool resizeImage, double radians) { QPointF offset; QSize newSize; { KisTransformWorker worker(0, 1.0, 1.0, 0, 0, 0, 0, radians, 0, 0, 0, 0); QTransform transform = worker.transform(); if (resizeImage) { QRect newRect = transform.mapRect(bounds()); newSize = newRect.size(); offset = -newRect.topLeft(); } else { QPointF origin = QRectF(rootNode->exactBounds()).center(); newSize = size(); offset = -(transform.map(origin) - origin); } } bool sizeChanged = resizeImage && (newSize.width() != width() || newSize.height() != height()); // These signals will be emitted after processing is done KisImageSignalVector emitSignals; if (sizeChanged) emitSignals << ComplexSizeChangedSignal(bounds(), newSize); emitSignals << ModifiedSignal; // These flags determine whether updates are transferred to the UI during processing KisProcessingApplicator::ProcessingFlags signalFlags = sizeChanged ? KisProcessingApplicator::NO_UI_UPDATES : KisProcessingApplicator::NONE; KisProcessingApplicator applicator(this, rootNode, KisProcessingApplicator::RECURSIVE | signalFlags, emitSignals, actionName); KisFilterStrategy *filter = KisFilterStrategyRegistry::instance()->value("Bicubic"); KisProcessingVisitorSP visitor = new KisTransformProcessingVisitor(1.0, 1.0, 0.0, 0.0, QPointF(), radians, offset.x(), offset.y(), filter); applicator.applyVisitorAllFrames(visitor, KisStrokeJobData::CONCURRENT); if (sizeChanged) { applicator.applyCommand(new KisImageResizeCommand(this, newSize)); } applicator.end(); } void KisImage::rotateImage(double radians) { rotateImpl(kundo2_i18n("Rotate Image"), root(), true, radians); } void KisImage::rotateNode(KisNodeSP node, double radians) { if (node->inherits("KisMask")) { rotateImpl(kundo2_i18n("Rotate Mask"), node, false, radians); } else { rotateImpl(kundo2_i18n("Rotate Layer"), node, false, radians); } } void KisImage::shearImpl(const KUndo2MagicString &actionName, KisNodeSP rootNode, bool resizeImage, double angleX, double angleY, const QPointF &origin) { //angleX, angleY are in degrees const qreal pi = 3.1415926535897932385; const qreal deg2rad = pi / 180.0; qreal tanX = tan(angleX * deg2rad); qreal tanY = tan(angleY * deg2rad); QPointF offset; QSize newSize; { KisTransformWorker worker(0, 1.0, 1.0, tanX, tanY, origin.x(), origin.y(), 0, 0, 0, 0, 0); QRect newRect = worker.transform().mapRect(bounds()); newSize = newRect.size(); if (resizeImage) offset = -newRect.topLeft(); } if (newSize == size()) return; KisImageSignalVector emitSignals; if (resizeImage) emitSignals << ComplexSizeChangedSignal(bounds(), newSize); emitSignals << ModifiedSignal; KisProcessingApplicator::ProcessingFlags signalFlags = KisProcessingApplicator::RECURSIVE; if (resizeImage) signalFlags |= KisProcessingApplicator::NO_UI_UPDATES; KisProcessingApplicator applicator(this, rootNode, signalFlags, emitSignals, actionName); KisFilterStrategy *filter = KisFilterStrategyRegistry::instance()->value("Bilinear"); KisProcessingVisitorSP visitor = new KisTransformProcessingVisitor(1.0, 1.0, tanX, tanY, origin, 0, offset.x(), offset.y(), filter); applicator.applyVisitorAllFrames(visitor, KisStrokeJobData::CONCURRENT); if (resizeImage) { applicator.applyCommand(new KisImageResizeCommand(this, newSize)); } applicator.end(); } void KisImage::shearNode(KisNodeSP node, double angleX, double angleY) { QPointF shearOrigin = QRectF(bounds()).center(); if (node->inherits("KisMask")) { shearImpl(kundo2_i18n("Shear Mask"), node, false, angleX, angleY, shearOrigin); } else { shearImpl(kundo2_i18n("Shear Layer"), node, false, angleX, angleY, shearOrigin); } } void KisImage::shear(double angleX, double angleY) { shearImpl(kundo2_i18n("Shear Image"), m_d->rootLayer, true, angleX, angleY, QPointF()); } void KisImage::convertImageColorSpace(const KoColorSpace *dstColorSpace, KoColorConversionTransformation::Intent renderingIntent, KoColorConversionTransformation::ConversionFlags conversionFlags) { if (!dstColorSpace) return; const KoColorSpace *srcColorSpace = m_d->colorSpace; undoAdapter()->beginMacro(kundo2_i18n("Convert Image Color Space")); undoAdapter()->addCommand(new KisImageLockCommand(KisImageWSP(this), true)); undoAdapter()->addCommand(new KisImageSetProjectionColorSpaceCommand(KisImageWSP(this), dstColorSpace)); KisColorSpaceConvertVisitor visitor(this, srcColorSpace, dstColorSpace, renderingIntent, conversionFlags); m_d->rootLayer->accept(visitor); undoAdapter()->addCommand(new KisImageLockCommand(KisImageWSP(this), false)); undoAdapter()->endMacro(); setModified(); } bool KisImage::assignImageProfile(const KoColorProfile *profile) { if (!profile) return false; const KoColorSpace *dstCs = KoColorSpaceRegistry::instance()->colorSpace(colorSpace()->colorModelId().id(), colorSpace()->colorDepthId().id(), profile); const KoColorSpace *srcCs = colorSpace(); if (!dstCs) return false; m_d->colorSpace = dstCs; KisChangeProfileVisitor visitor(srcCs, dstCs); bool retval = m_d->rootLayer->accept(visitor); m_d->signalRouter.emitNotification(ProfileChangedSignal); return retval; } void KisImage::convertProjectionColorSpace(const KoColorSpace *dstColorSpace) { if (*m_d->colorSpace == *dstColorSpace) return; undoAdapter()->beginMacro(kundo2_i18n("Convert Projection Color Space")); undoAdapter()->addCommand(new KisImageLockCommand(KisImageWSP(this), true)); undoAdapter()->addCommand(new KisImageSetProjectionColorSpaceCommand(KisImageWSP(this), dstColorSpace)); undoAdapter()->addCommand(new KisImageLockCommand(KisImageWSP(this), false)); undoAdapter()->endMacro(); setModified(); } void KisImage::setProjectionColorSpace(const KoColorSpace * colorSpace) { m_d->colorSpace = colorSpace; m_d->rootLayer->resetCache(); m_d->signalRouter.emitNotification(ColorSpaceChangedSignal); } const KoColorSpace * KisImage::colorSpace() const { return m_d->colorSpace; } const KoColorProfile * KisImage::profile() const { return colorSpace()->profile(); } double KisImage::xRes() const { return m_d->xres; } double KisImage::yRes() const { return m_d->yres; } void KisImage::setResolution(double xres, double yres) { m_d->xres = xres; m_d->yres = yres; m_d->signalRouter.emitNotification(ResolutionChangedSignal); } QPointF KisImage::documentToPixel(const QPointF &documentCoord) const { return QPointF(documentCoord.x() * xRes(), documentCoord.y() * yRes()); } QPoint KisImage::documentToIntPixel(const QPointF &documentCoord) const { QPointF pixelCoord = documentToPixel(documentCoord); return QPoint((int)pixelCoord.x(), (int)pixelCoord.y()); } QRectF KisImage::documentToPixel(const QRectF &documentRect) const { return QRectF(documentToPixel(documentRect.topLeft()), documentToPixel(documentRect.bottomRight())); } QRect KisImage::documentToIntPixel(const QRectF &documentRect) const { return documentToPixel(documentRect).toAlignedRect(); } QPointF KisImage::pixelToDocument(const QPointF &pixelCoord) const { return QPointF(pixelCoord.x() / xRes(), pixelCoord.y() / yRes()); } QPointF KisImage::pixelToDocument(const QPoint &pixelCoord) const { return QPointF((pixelCoord.x() + 0.5) / xRes(), (pixelCoord.y() + 0.5) / yRes()); } QRectF KisImage::pixelToDocument(const QRectF &pixelCoord) const { return QRectF(pixelToDocument(pixelCoord.topLeft()), pixelToDocument(pixelCoord.bottomRight())); } qint32 KisImage::width() const { return m_d->width; } qint32 KisImage::height() const { return m_d->height; } KisGroupLayerSP KisImage::rootLayer() const { Q_ASSERT(m_d->rootLayer); return m_d->rootLayer; } KisPaintDeviceSP KisImage::projection() const { if (m_d->isolatedRootNode) { return m_d->isolatedRootNode->projection(); } Q_ASSERT(m_d->rootLayer); KisPaintDeviceSP projection = m_d->rootLayer->projection(); Q_ASSERT(projection); return projection; } qint32 KisImage::nlayers() const { QStringList list; list << "KisLayer"; KisCountVisitor visitor(list, KoProperties()); m_d->rootLayer->accept(visitor); return visitor.count(); } qint32 KisImage::nHiddenLayers() const { QStringList list; list << "KisLayer"; KoProperties properties; properties.setProperty("visible", false); KisCountVisitor visitor(list, properties); m_d->rootLayer->accept(visitor); return visitor.count(); } void KisImage::flatten() { KisLayerUtils::flattenImage(this); } void KisImage::mergeMultipleLayers(QList mergedNodes, KisNodeSP putAfter) { if (!KisLayerUtils::tryMergeSelectionMasks(this, mergedNodes, putAfter)) { KisLayerUtils::mergeMultipleLayers(this, mergedNodes, putAfter); } } void KisImage::mergeDown(KisLayerSP layer, const KisMetaData::MergeStrategy* strategy) { KisLayerUtils::mergeDown(this, layer, strategy); } void KisImage::flattenLayer(KisLayerSP layer) { KisLayerUtils::flattenLayer(this, layer); } void KisImage::setModified() { m_d->signalRouter.emitNotification(ModifiedSignal); } QImage KisImage::convertToQImage(QRect imageRect, const KoColorProfile * profile) { qint32 x; qint32 y; qint32 w; qint32 h; imageRect.getRect(&x, &y, &w, &h); return convertToQImage(x, y, w, h, profile); } QImage KisImage::convertToQImage(qint32 x, qint32 y, qint32 w, qint32 h, const KoColorProfile * profile) { KisPaintDeviceSP dev = projection(); if (!dev) return QImage(); QImage image = dev->convertToQImage(const_cast(profile), x, y, w, h, KoColorConversionTransformation::internalRenderingIntent(), KoColorConversionTransformation::internalConversionFlags()); return image; } QImage KisImage::convertToQImage(const QSize& scaledImageSize, const KoColorProfile *profile) { if (scaledImageSize.isEmpty()) { return QImage(); } KisPaintDeviceSP dev = new KisPaintDevice(colorSpace()); KisPainter gc; gc.copyAreaOptimized(QPoint(0, 0), projection(), dev, bounds()); gc.end(); double scaleX = qreal(scaledImageSize.width()) / width(); double scaleY = qreal(scaledImageSize.height()) / height(); QPointer updater = new KoDummyUpdater(); KisTransformWorker worker(dev, scaleX, scaleY, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0, updater, KisFilterStrategyRegistry::instance()->value("Bicubic")); worker.run(); delete updater; return dev->convertToQImage(profile); } void KisImage::notifyLayersChanged() { m_d->signalRouter.emitNotification(LayersChangedSignal); } QRect KisImage::bounds() const { return QRect(0, 0, width(), height()); } QRect KisImage::effectiveLodBounds() const { QRect boundRect = bounds(); const int lod = currentLevelOfDetail(); if (lod > 0) { KisLodTransform t(lod); boundRect = t.map(boundRect); } return boundRect; } KisPostExecutionUndoAdapter* KisImage::postExecutionUndoAdapter() const { const int lod = currentLevelOfDetail(); return lod > 0 ? m_d->scheduler.lodNPostExecutionUndoAdapter() : &m_d->postExecutionUndoAdapter; } void KisImage::setUndoStore(KisUndoStore *undoStore) { m_d->legacyUndoAdapter.setUndoStore(undoStore); m_d->postExecutionUndoAdapter.setUndoStore(undoStore); m_d->undoStore.reset(undoStore); } KisUndoStore* KisImage::undoStore() { return m_d->undoStore.data(); } KisUndoAdapter* KisImage::undoAdapter() const { return &m_d->legacyUndoAdapter; } KisActionRecorder* KisImage::actionRecorder() const { return &m_d->recorder; } void KisImage::setDefaultProjectionColor(const KoColor &color) { KIS_ASSERT_RECOVER_RETURN(m_d->rootLayer); m_d->rootLayer->setDefaultProjectionColor(color); } KoColor KisImage::defaultProjectionColor() const { KIS_ASSERT_RECOVER(m_d->rootLayer) { return KoColor(Qt::transparent, m_d->colorSpace); } return m_d->rootLayer->defaultProjectionColor(); } void KisImage::setRootLayer(KisGroupLayerSP rootLayer) { stopIsolatedMode(); KoColor defaultProjectionColor(Qt::transparent, m_d->colorSpace); if (m_d->rootLayer) { m_d->rootLayer->setGraphListener(0); m_d->rootLayer->disconnect(); KisPaintDeviceSP original = m_d->rootLayer->original(); defaultProjectionColor = original->defaultPixel(); } m_d->rootLayer = rootLayer; m_d->rootLayer->disconnect(); m_d->rootLayer->setGraphListener(this); m_d->rootLayer->setImage(this); KisPaintDeviceSP newOriginal = m_d->rootLayer->original(); newOriginal->setDefaultPixel(defaultProjectionColor); setRoot(m_d->rootLayer.data()); } void KisImage::addAnnotation(KisAnnotationSP annotation) { // Find the icc annotation, if there is one vKisAnnotationSP_it it = m_d->annotations.begin(); while (it != m_d->annotations.end()) { if ((*it)->type() == annotation->type()) { *it = annotation; return; } ++it; } m_d->annotations.push_back(annotation); } KisAnnotationSP KisImage::annotation(const QString& type) { vKisAnnotationSP_it it = m_d->annotations.begin(); while (it != m_d->annotations.end()) { if ((*it)->type() == type) { return *it; } ++it; } return KisAnnotationSP(0); } void KisImage::removeAnnotation(const QString& type) { vKisAnnotationSP_it it = m_d->annotations.begin(); while (it != m_d->annotations.end()) { if ((*it)->type() == type) { m_d->annotations.erase(it); return; } ++it; } } vKisAnnotationSP_it KisImage::beginAnnotations() { return m_d->annotations.begin(); } vKisAnnotationSP_it KisImage::endAnnotations() { return m_d->annotations.end(); } void KisImage::notifyAboutToBeDeleted() { emit sigAboutToBeDeleted(); } KisImageSignalRouter* KisImage::signalRouter() { return &m_d->signalRouter; } void KisImage::waitForDone() { requestStrokeEnd(); m_d->scheduler.waitForDone(); } KisStrokeId KisImage::startStroke(KisStrokeStrategy *strokeStrategy) { /** * Ask open strokes to end gracefully. All the strokes clients * (including the one calling this method right now) will get * a notification that they should probably end their strokes. * However this is purely their choice whether to end a stroke * or not. */ if (strokeStrategy->requestsOtherStrokesToEnd()) { requestStrokeEnd(); } /** * Some of the strokes can cancel their work with undoing all the * changes they did to the paint devices. The problem is that undo * stack will know nothing about it. Therefore, just notify it * explicitly */ if (strokeStrategy->clearsRedoOnStart()) { m_d->undoStore->purgeRedoState(); } return m_d->scheduler.startStroke(strokeStrategy); } void KisImage::KisImagePrivate::notifyProjectionUpdatedInPatches(const QRect &rc) { KisImageConfig imageConfig; int patchWidth = imageConfig.updatePatchWidth(); int patchHeight = imageConfig.updatePatchHeight(); for (int y = 0; y < rc.height(); y += patchHeight) { for (int x = 0; x < rc.width(); x += patchWidth) { QRect patchRect(x, y, patchWidth, patchHeight); patchRect &= rc; QtConcurrent::run(std::bind(&KisImage::notifyProjectionUpdated, q, patchRect)); } } } bool KisImage::startIsolatedMode(KisNodeSP node) { if (!tryBarrierLock()) return false; unlock(); m_d->isolatedRootNode = node; emit sigIsolatedModeChanged(); // the GUI uses our thread to do the color space conversion so we // need to emit this signal in multiple threads m_d->notifyProjectionUpdatedInPatches(bounds()); invalidateAllFrames(); return true; } void KisImage::stopIsolatedMode() { if (!m_d->isolatedRootNode) return; KisNodeSP oldRootNode = m_d->isolatedRootNode; m_d->isolatedRootNode = 0; emit sigIsolatedModeChanged(); // the GUI uses our thread to do the color space conversion so we // need to emit this signal in multiple threads m_d->notifyProjectionUpdatedInPatches(bounds()); invalidateAllFrames(); // TODO: Substitute notifyProjectionUpdated() with this code // when update optimization is implemented // // QRect updateRect = bounds() | oldRootNode->extent(); // oldRootNode->setDirty(updateRect); } KisNodeSP KisImage::isolatedModeRoot() const { return m_d->isolatedRootNode; } void KisImage::addJob(KisStrokeId id, KisStrokeJobData *data) { KisUpdateTimeMonitor::instance()->reportJobStarted(data); m_d->scheduler.addJob(id, data); } void KisImage::endStroke(KisStrokeId id) { m_d->scheduler.endStroke(id); } bool KisImage::cancelStroke(KisStrokeId id) { return m_d->scheduler.cancelStroke(id); } bool KisImage::KisImagePrivate::tryCancelCurrentStrokeAsync() { return scheduler.tryCancelCurrentStrokeAsync(); } void KisImage::requestUndoDuringStroke() { emit sigUndoDuringStrokeRequested(); } void KisImage::requestStrokeCancellation() { if (!m_d->tryCancelCurrentStrokeAsync()) { emit sigStrokeCancellationRequested(); } } UndoResult KisImage::tryUndoUnfinishedLod0Stroke() { return m_d->scheduler.tryUndoLastStrokeAsync(); } void KisImage::requestStrokeEnd() { emit sigStrokeEndRequested(); emit sigStrokeEndRequestedActiveNodeFiltered(); } void KisImage::requestStrokeEndActiveNode() { emit sigStrokeEndRequested(); } void KisImage::refreshGraph(KisNodeSP root) { refreshGraph(root, bounds(), bounds()); } void KisImage::refreshGraph(KisNodeSP root, const QRect &rc, const QRect &cropRect) { if (!root) root = m_d->rootLayer; m_d->animationInterface->notifyNodeChanged(root.data(), rc, true); m_d->scheduler.fullRefresh(root, rc, cropRect); } void KisImage::initialRefreshGraph() { /** * NOTE: Tricky part. We set crop rect to null, so the clones * will not rely on precalculated projections of their sources */ refreshGraphAsync(0, bounds(), QRect()); waitForDone(); } void KisImage::refreshGraphAsync(KisNodeSP root) { refreshGraphAsync(root, bounds(), bounds()); } void KisImage::refreshGraphAsync(KisNodeSP root, const QRect &rc) { refreshGraphAsync(root, rc, bounds()); } void KisImage::refreshGraphAsync(KisNodeSP root, const QRect &rc, const QRect &cropRect) { if (!root) root = m_d->rootLayer; m_d->animationInterface->notifyNodeChanged(root.data(), rc, true); m_d->scheduler.fullRefreshAsync(root, rc, cropRect); } void KisImage::requestProjectionUpdateNoFilthy(KisNodeSP pseudoFilthy, const QRect &rc, const QRect &cropRect) { KIS_ASSERT_RECOVER_RETURN(pseudoFilthy); m_d->animationInterface->notifyNodeChanged(pseudoFilthy.data(), rc, false); m_d->scheduler.updateProjectionNoFilthy(pseudoFilthy, rc, cropRect); } void KisImage::addSpontaneousJob(KisSpontaneousJob *spontaneousJob) { m_d->scheduler.addSpontaneousJob(spontaneousJob); } void KisImage::setProjectionUpdatesFilter(KisProjectionUpdatesFilterSP filter) { // udpate filters are *not* recursive! KIS_ASSERT_RECOVER_NOOP(!filter || !m_d->projectionUpdatesFilter); m_d->projectionUpdatesFilter = filter; } KisProjectionUpdatesFilterSP KisImage::projectionUpdatesFilter() const { return m_d->projectionUpdatesFilter; } void KisImage::disableDirtyRequests() { setProjectionUpdatesFilter(KisProjectionUpdatesFilterSP(new KisDropAllProjectionUpdatesFilter())); } void KisImage::enableDirtyRequests() { setProjectionUpdatesFilter(KisProjectionUpdatesFilterSP()); } void KisImage::disableUIUpdates() { m_d->disableUIUpdateSignals.ref(); } void KisImage::enableUIUpdates() { m_d->disableUIUpdateSignals.deref(); } void KisImage::notifyProjectionUpdated(const QRect &rc) { KisUpdateTimeMonitor::instance()->reportUpdateFinished(rc); if (!m_d->disableUIUpdateSignals) { int lod = currentLevelOfDetail(); QRect dirtyRect = !lod ? rc : KisLodTransform::upscaledRect(rc, lod); if (dirtyRect.isEmpty()) return; emit sigImageUpdated(dirtyRect); } } void KisImage::setWorkingThreadsLimit(int value) { m_d->scheduler.setThreadsLimit(value); } int KisImage::workingThreadsLimit() const { return m_d->scheduler.threadsLimit(); } void KisImage::notifySelectionChanged() { /** * The selection is calculated asynchromously, so it is not * handled by disableUIUpdates() and other special signals of * KisImageSignalRouter */ m_d->legacyUndoAdapter.emitSelectionChanged(); /** * Editing of selection masks doesn't necessary produce a * setDirty() call, so in the end of the stroke we need to request * direct update of the UI's cache. */ if (m_d->isolatedRootNode && dynamic_cast(m_d->isolatedRootNode.data())) { notifyProjectionUpdated(bounds()); } } void KisImage::requestProjectionUpdateImpl(KisNode *node, const QVector &rects, const QRect &cropRect) { if (rects.isEmpty()) return; m_d->scheduler.updateProjection(node, rects, cropRect); } void KisImage::requestProjectionUpdate(KisNode *node, const QVector &rects, bool resetAnimationCache) { if (m_d->projectionUpdatesFilter && m_d->projectionUpdatesFilter->filter(this, node, rects, resetAnimationCache)) { return; } if (resetAnimationCache) { m_d->animationInterface->notifyNodeChanged(node, rects, false); } /** * Here we use 'permitted' instead of 'active' intentively, * because the updates may come after the actual stroke has been * finished. And having some more updates for the stroke not * supporting the wrap-around mode will not make much harm. */ if (m_d->wrapAroundModePermitted) { QVector allSplitRects; const QRect boundRect = effectiveLodBounds(); Q_FOREACH (const QRect &rc, rects) { KisWrappedRect splitRect(rc, boundRect); allSplitRects.append(splitRect); } requestProjectionUpdateImpl(node, allSplitRects, boundRect); } else { requestProjectionUpdateImpl(node, rects, bounds()); } KisNodeGraphListener::requestProjectionUpdate(node, rects, resetAnimationCache); } void KisImage::invalidateFrames(const KisTimeRange &range, const QRect &rect) { m_d->animationInterface->invalidateFrames(range, rect); } void KisImage::requestTimeSwitch(int time) { m_d->animationInterface->requestTimeSwitchNonGUI(time); } QList KisImage::compositions() { return m_d->compositions; } void KisImage::addComposition(KisLayerCompositionSP composition) { m_d->compositions.append(composition); } void KisImage::removeComposition(KisLayerCompositionSP composition) { m_d->compositions.removeAll(composition); } bool checkMasksNeedConversion(KisNodeSP root, const QRect &bounds) { KisSelectionMask *mask = dynamic_cast(root.data()); if (mask && (!bounds.contains(mask->paintDevice()->exactBounds()) || mask->selection()->hasShapeSelection())) { return true; } KisNodeSP node = root->firstChild(); while (node) { if (checkMasksNeedConversion(node, bounds)) { return true; } node = node->nextSibling(); } return false; } void KisImage::setWrapAroundModePermitted(bool value) { if (m_d->wrapAroundModePermitted != value) { requestStrokeEnd(); } m_d->wrapAroundModePermitted = value; if (m_d->wrapAroundModePermitted && checkMasksNeedConversion(root(), bounds())) { KisProcessingApplicator applicator(this, root(), KisProcessingApplicator::RECURSIVE, KisImageSignalVector() << ModifiedSignal, kundo2_i18n("Crop Selections")); KisProcessingVisitorSP visitor = new KisCropSelectionsProcessingVisitor(bounds()); applicator.applyVisitor(visitor, KisStrokeJobData::CONCURRENT); applicator.end(); } } bool KisImage::wrapAroundModePermitted() const { return m_d->wrapAroundModePermitted; } bool KisImage::wrapAroundModeActive() const { return m_d->wrapAroundModePermitted && m_d->scheduler.wrapAroundModeSupported(); } void KisImage::setDesiredLevelOfDetail(int lod) { if (m_d->blockLevelOfDetail) { qWarning() << "WARNING: KisImage::setDesiredLevelOfDetail()" << "was called while LoD functionality was being blocked!"; return; } m_d->scheduler.setDesiredLevelOfDetail(lod); } int KisImage::currentLevelOfDetail() const { if (m_d->blockLevelOfDetail) { return 0; } return m_d->scheduler.currentLevelOfDetail(); } void KisImage::setLevelOfDetailBlocked(bool value) { KisImageBarrierLockerRaw l(this); if (value && !m_d->blockLevelOfDetail) { m_d->scheduler.setDesiredLevelOfDetail(0); } m_d->blockLevelOfDetail = value; } void KisImage::explicitRegenerateLevelOfDetail() { if (!m_d->blockLevelOfDetail) { m_d->scheduler.explicitRegenerateLevelOfDetail(); } } bool KisImage::levelOfDetailBlocked() const { return m_d->blockLevelOfDetail; } void KisImage::notifyNodeCollpasedChanged() { emit sigNodeCollapsedChanged(); } KisImageAnimationInterface* KisImage::animationInterface() const { return m_d->animationInterface; } void KisImage::setProofingConfiguration(KisProofingConfigurationSP proofingConfig) { m_d->proofingConfig = proofingConfig; emit sigProofingConfigChanged(); } KisProofingConfigurationSP KisImage::proofingConfiguration() const { - if (m_d->proofingConfig) { - return m_d->proofingConfig; - } - return 0; + return m_d->proofingConfig; } QPointF KisImage::mirrorAxesCenter() const { return m_d->axesCenter; } void KisImage::setMirrorAxesCenter(const QPointF &value) const { m_d->axesCenter = value; } diff --git a/libs/ui/canvas/kis_canvas2.cpp b/libs/ui/canvas/kis_canvas2.cpp index ed546469ad..4de130fa7a 100644 --- a/libs/ui/canvas/kis_canvas2.cpp +++ b/libs/ui/canvas/kis_canvas2.cpp @@ -1,1043 +1,1043 @@ /* This file is part of the KDE project * * Copyright (C) 2006, 2010 Boudewijn Rempt * Copyright (C) Lukáš Tvrdý , (C) 2010 * Copyright (C) 2011 Silvio Heinrich * * 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 "kis_canvas2.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "kis_tool_proxy.h" #include "kis_coordinates_converter.h" #include "kis_prescaled_projection.h" #include "kis_image.h" #include "kis_image_barrier_locker.h" #include "kis_undo_adapter.h" #include "KisDocument.h" #include "flake/kis_shape_layer.h" #include "kis_canvas_resource_provider.h" #include "KisViewManager.h" #include "kis_config.h" #include "kis_config_notifier.h" #include "kis_abstract_canvas_widget.h" #include "kis_qpainter_canvas.h" #include "kis_group_layer.h" #include "flake/kis_shape_controller.h" #include "kis_node_manager.h" #include "kis_selection.h" #include "kis_selection_component.h" #include "flake/kis_shape_selection.h" #include "kis_image_config.h" #include "kis_infinity_manager.h" #include "kis_signal_compressor.h" #include "kis_display_color_converter.h" #include "kis_exposure_gamma_correction_interface.h" #include "KisView.h" #include "kis_canvas_controller.h" #include "kis_grid_config.h" #include "kis_animation_player.h" #include "kis_animation_frame_cache.h" #include "opengl/kis_opengl_canvas2.h" #include "opengl/kis_opengl.h" #include "kis_fps_decoration.h" #include "KoColorConversionTransformation.h" #include "KisProofingConfiguration.h" #include #include #include "input/kis_input_manager.h" #include "kis_painting_assistants_decoration.h" #include "kis_canvas_updates_compressor.h" #include "KoZoomController.h" #include #include "opengl/kis_opengl_canvas_debugger.h" class Q_DECL_HIDDEN KisCanvas2::KisCanvas2Private { public: KisCanvas2Private(KoCanvasBase *parent, KisCoordinatesConverter* coordConverter, QPointer view, KoCanvasResourceManager* resourceManager) : coordinatesConverter(coordConverter) , view(view) , shapeManager(parent) , selectedShapesProxy(&shapeManager) , toolProxy(parent) , displayColorConverter(resourceManager, view) { } KisCoordinatesConverter *coordinatesConverter; QPointerview; KisAbstractCanvasWidget *canvasWidget = 0; KoShapeManager shapeManager; KisSelectedShapesProxy selectedShapesProxy; bool currentCanvasIsOpenGL; int openGLFilterMode; KisToolProxy toolProxy; KisPrescaledProjectionSP prescaledProjection; bool vastScrolling; KisSignalCompressor updateSignalCompressor; QRect savedUpdateRect; QBitArray channelFlags; KisProofingConfigurationSP proofingConfig; bool softProofing = false; bool gamutCheck = false; bool proofingConfigUpdated = false; KisPopupPalette *popupPalette = 0; KisDisplayColorConverter displayColorConverter; KisCanvasUpdatesCompressor projectionUpdatesCompressor; KisAnimationPlayer *animationPlayer; KisAnimationFrameCacheSP frameCache; bool lodAllowedInCanvas; bool bootstrapLodBlocked; QPointer currentlyActiveShapeManager; bool effectiveLodAllowedInCanvas() { return lodAllowedInCanvas && !bootstrapLodBlocked; } }; namespace { KoShapeManager* fetchShapeManagerFromNode(KisNodeSP node) { KoShapeManager *shapeManager = 0; KisLayer *layer = dynamic_cast(node.data()); if (layer) { KisShapeLayer *shapeLayer = dynamic_cast(layer); if (shapeLayer) { shapeManager = shapeLayer->shapeManager(); } else { KisSelectionSP selection = layer->selection(); if (selection && selection->hasShapeSelection()) { KisShapeSelection *shapeSelection = dynamic_cast(selection->shapeSelection()); KIS_ASSERT_RECOVER_RETURN_VALUE(shapeSelection, 0); shapeManager = shapeSelection->shapeManager(); } } } return shapeManager; } } KisCanvas2::KisCanvas2(KisCoordinatesConverter *coordConverter, KoCanvasResourceManager *resourceManager, KisView *view, KoShapeBasedDocumentBase *sc) : KoCanvasBase(sc, resourceManager) , m_d(new KisCanvas2Private(this, coordConverter, view, resourceManager)) { /** * While loading LoD should be blocked. Only when GUI has finished * loading and zoom level settled down, LoD is given a green * light. */ m_d->bootstrapLodBlocked = true; connect(view->mainWindow(), SIGNAL(guiLoadingFinished()), SLOT(bootstrapFinished())); KisImageConfig config; m_d->updateSignalCompressor.setDelay(1000 / config.fpsLimit()); m_d->updateSignalCompressor.setMode(KisSignalCompressor::FIRST_ACTIVE); } void KisCanvas2::setup() { // a bit of duplication from slotConfigChanged() KisConfig cfg; m_d->vastScrolling = cfg.vastScrolling(); m_d->lodAllowedInCanvas = cfg.levelOfDetailEnabled(); createCanvas(cfg.useOpenGL()); setLodAllowedInCanvas(m_d->lodAllowedInCanvas); m_d->animationPlayer = new KisAnimationPlayer(this); connect(m_d->view->canvasController()->proxyObject, SIGNAL(moveDocumentOffset(QPoint)), SLOT(documentOffsetMoved(QPoint))); connect(KisConfigNotifier::instance(), SIGNAL(configChanged()), SLOT(slotConfigChanged())); /** * We switch the shape manager every time vector layer or * shape selection is activated. Flake does not expect this * and connects all the signals of the global shape manager * to the clients in the constructor. To workaround this we * forward the signals of local shape managers stored in the * vector layers to the signals of global shape manager. So the * sequence of signal deliveries is the following: * * shapeLayer.m_d.canvas.m_shapeManager.selection() -> * shapeLayer -> * shapeController -> * globalShapeManager.selection() */ KisShapeController *kritaShapeController = static_cast(shapeController()->documentBase()); connect(kritaShapeController, SIGNAL(selectionChanged()), this, SLOT(slotSelectionChanged())); connect(kritaShapeController, SIGNAL(selectionContentChanged()), globalShapeManager(), SIGNAL(selectionContentChanged())); connect(kritaShapeController, SIGNAL(currentLayerChanged(const KoShapeLayer*)), globalShapeManager()->selection(), SIGNAL(currentLayerChanged(const KoShapeLayer*))); connect(&m_d->updateSignalCompressor, SIGNAL(timeout()), SLOT(slotDoCanvasUpdate())); initializeFpsDecoration(); } void KisCanvas2::initializeFpsDecoration() { KisConfig cfg; const bool shouldShowDebugOverlay = (canvasIsOpenGL() && cfg.enableOpenGLFramerateLogging()) || cfg.enableBrushSpeedLogging(); if (shouldShowDebugOverlay && !decoration(KisFpsDecoration::idTag)) { addDecoration(new KisFpsDecoration(imageView())); if (cfg.enableBrushSpeedLogging()) { connect(KisStrokeSpeedMonitor::instance(), SIGNAL(sigStatsUpdated()), this, SLOT(updateCanvas())); } } else if (!shouldShowDebugOverlay && decoration(KisFpsDecoration::idTag)) { m_d->canvasWidget->removeDecoration(KisFpsDecoration::idTag); disconnect(KisStrokeSpeedMonitor::instance(), SIGNAL(sigStatsUpdated()), this, SLOT(updateCanvas())); } } KisCanvas2::~KisCanvas2() { if (m_d->animationPlayer->isPlaying()) { m_d->animationPlayer->forcedStopOnExit(); } delete m_d; } void KisCanvas2::setCanvasWidget(QWidget * widget) { KisAbstractCanvasWidget *tmp = dynamic_cast(widget); Q_ASSERT_X(tmp, "setCanvasWidget", "Cannot cast the widget to a KisAbstractCanvasWidget"); if (m_d->popupPalette) { m_d->popupPalette->setParent(widget); } if(m_d->canvasWidget != 0) { tmp->setDecorations(m_d->canvasWidget->decorations()); // Redundant check for the constructor case, see below if(viewManager() != 0) viewManager()->inputManager()->removeTrackedCanvas(this); } m_d->canvasWidget = tmp; // Either tmp was null or we are being called by KisCanvas2 constructor that is called by KisView // constructor, so the view manager still doesn't exists. if(m_d->canvasWidget != 0 && viewManager() != 0) viewManager()->inputManager()->addTrackedCanvas(this); if (!m_d->canvasWidget->decoration(INFINITY_DECORATION_ID)) { KisInfinityManager *manager = new KisInfinityManager(m_d->view, this); manager->setVisible(true); m_d->canvasWidget->addDecoration(manager); } widget->setAutoFillBackground(false); widget->setAttribute(Qt::WA_OpaquePaintEvent); widget->setMouseTracking(true); widget->setAcceptDrops(true); KoCanvasControllerWidget *controller = dynamic_cast(canvasController()); if (controller) { Q_ASSERT(controller->canvas() == this); controller->changeCanvasWidget(widget); } } bool KisCanvas2::canvasIsOpenGL() const { return m_d->currentCanvasIsOpenGL; } KisOpenGL::FilterMode KisCanvas2::openGLFilterMode() const { return KisOpenGL::FilterMode(m_d->openGLFilterMode); } void KisCanvas2::gridSize(QPointF *offset, QSizeF *spacing) const { QTransform transform = coordinatesConverter()->imageToDocumentTransform(); const QPoint intSpacing = m_d->view->document()->gridConfig().spacing(); const QPoint intOffset = m_d->view->document()->gridConfig().offset(); QPointF size = transform.map(QPointF(intSpacing)); spacing->rwidth() = size.x(); spacing->rheight() = size.y(); *offset = transform.map(QPointF(intOffset)); } bool KisCanvas2::snapToGrid() const { return m_d->view->document()->gridConfig().snapToGrid(); } qreal KisCanvas2::rotationAngle() const { return m_d->coordinatesConverter->rotationAngle(); } bool KisCanvas2::xAxisMirrored() const { return m_d->coordinatesConverter->xAxisMirrored(); } bool KisCanvas2::yAxisMirrored() const { return m_d->coordinatesConverter->yAxisMirrored(); } void KisCanvas2::channelSelectionChanged() { KisImageSP image = this->image(); m_d->channelFlags = image->rootLayer()->channelFlags(); m_d->view->viewManager()->blockUntilOperationsFinishedForced(image); image->barrierLock(); m_d->canvasWidget->channelSelectionChanged(m_d->channelFlags); startUpdateInPatches(image->bounds()); image->unlock(); } void KisCanvas2::addCommand(KUndo2Command *command) { // This method exists to support flake-related operations m_d->view->document()->addCommand(command); } KoShapeManager* KisCanvas2::shapeManager() const { KisNodeSP node = m_d->view->currentNode(); KoShapeManager *localShapeManager = fetchShapeManagerFromNode(node); // sanity check for consistency of the local shape manager KIS_SAFE_ASSERT_RECOVER (localShapeManager == m_d->currentlyActiveShapeManager) { localShapeManager = globalShapeManager(); } return localShapeManager ? localShapeManager : globalShapeManager(); } KoSelectedShapesProxy* KisCanvas2::selectedShapesProxy() const { return &m_d->selectedShapesProxy; } KoShapeManager* KisCanvas2::globalShapeManager() const { return &m_d->shapeManager; } void KisCanvas2::updateInputMethodInfo() { // TODO call (the protected) QWidget::updateMicroFocus() on the proper canvas widget... } const KisCoordinatesConverter* KisCanvas2::coordinatesConverter() const { return m_d->coordinatesConverter; } KoViewConverter* KisCanvas2::viewConverter() const { return m_d->coordinatesConverter; } KisInputManager* KisCanvas2::globalInputManager() const { return m_d->view->globalInputManager(); } QWidget* KisCanvas2::canvasWidget() { return m_d->canvasWidget->widget(); } const QWidget* KisCanvas2::canvasWidget() const { return m_d->canvasWidget->widget(); } KoUnit KisCanvas2::unit() const { KoUnit unit(KoUnit::Pixel); KisImageWSP image = m_d->view->image(); if (image) { if (!qFuzzyCompare(image->xRes(), image->yRes())) { warnKrita << "WARNING: resolution of the image is anisotropic" << ppVar(image->xRes()) << ppVar(image->yRes()); } const qreal resolution = image->xRes(); unit.setFactor(resolution); } return unit; } KoToolProxy * KisCanvas2::toolProxy() const { return &m_d->toolProxy; } void KisCanvas2::createQPainterCanvas() { m_d->currentCanvasIsOpenGL = false; KisQPainterCanvas * canvasWidget = new KisQPainterCanvas(this, m_d->coordinatesConverter, m_d->view); m_d->prescaledProjection = new KisPrescaledProjection(); m_d->prescaledProjection->setCoordinatesConverter(m_d->coordinatesConverter); m_d->prescaledProjection->setMonitorProfile(m_d->displayColorConverter.monitorProfile(), m_d->displayColorConverter.renderingIntent(), m_d->displayColorConverter.conversionFlags()); m_d->prescaledProjection->setDisplayFilter(m_d->displayColorConverter.displayFilter()); canvasWidget->setPrescaledProjection(m_d->prescaledProjection); setCanvasWidget(canvasWidget); } void KisCanvas2::createOpenGLCanvas() { KisConfig cfg; m_d->openGLFilterMode = cfg.openGLFilteringMode(); m_d->currentCanvasIsOpenGL = true; KisOpenGLCanvas2 *canvasWidget = new KisOpenGLCanvas2(this, m_d->coordinatesConverter, 0, m_d->view->image(), &m_d->displayColorConverter); m_d->frameCache = KisAnimationFrameCache::getFrameCache(canvasWidget->openGLImageTextures()); setCanvasWidget(canvasWidget); } void KisCanvas2::createCanvas(bool useOpenGL) { // deinitialize previous canvas structures m_d->prescaledProjection = 0; m_d->frameCache = 0; KisConfig cfg; QDesktopWidget dw; const KoColorProfile *profile = cfg.displayProfile(dw.screenNumber(imageView())); m_d->displayColorConverter.setMonitorProfile(profile); if (useOpenGL) { if (KisOpenGL::hasOpenGL()) { createOpenGLCanvas(); if (cfg.canvasState() == "OPENGL_FAILED") { // Creating the opengl canvas failed, fall back warnKrita << "OpenGL Canvas initialization returned OPENGL_FAILED. Falling back to QPainter."; createQPainterCanvas(); } } else { warnKrita << "Tried to create OpenGL widget when system doesn't have OpenGL\n"; createQPainterCanvas(); } } else { createQPainterCanvas(); } if (m_d->popupPalette) { m_d->popupPalette->setParent(m_d->canvasWidget->widget()); } } void KisCanvas2::initializeImage() { KisImageSP image = m_d->view->image(); m_d->coordinatesConverter->setImage(image); m_d->toolProxy.initializeImage(image); connect(image, SIGNAL(sigImageUpdated(QRect)), SLOT(startUpdateCanvasProjection(QRect)), Qt::DirectConnection); connect(this, SIGNAL(sigCanvasCacheUpdated()), SLOT(updateCanvasProjection())); connect(image, SIGNAL(sigProofingConfigChanged()), SLOT(slotChangeProofingConfig())); connect(image, SIGNAL(sigSizeChanged(const QPointF&, const QPointF&)), SLOT(startResizingImage()), Qt::DirectConnection); connect(this, SIGNAL(sigContinueResizeImage(qint32,qint32)), SLOT(finishResizingImage(qint32,qint32))); connect(image->undoAdapter(), SIGNAL(selectionChanged()), SLOT(slotTrySwitchShapeManager())); connectCurrentCanvas(); } void KisCanvas2::connectCurrentCanvas() { KisImageWSP image = m_d->view->image(); if (!m_d->currentCanvasIsOpenGL) { Q_ASSERT(m_d->prescaledProjection); m_d->prescaledProjection->setImage(image); } startResizingImage(); emit imageChanged(image); setLodAllowedInCanvas(m_d->lodAllowedInCanvas); } void KisCanvas2::resetCanvas(bool useOpenGL) { // we cannot reset the canvas before it's created, but this method might be called, // for instance when setting the monitor profile. if (!m_d->canvasWidget) { return; } KisConfig cfg; bool needReset = (m_d->currentCanvasIsOpenGL != useOpenGL) || (m_d->currentCanvasIsOpenGL && m_d->openGLFilterMode != cfg.openGLFilteringMode()); if (needReset) { createCanvas(useOpenGL); connectCurrentCanvas(); notifyZoomChanged(); } updateCanvasWidgetImpl(); } void KisCanvas2::startUpdateInPatches(const QRect &imageRect) { if (m_d->currentCanvasIsOpenGL) { startUpdateCanvasProjection(imageRect); } else { KisImageConfig imageConfig; int patchWidth = imageConfig.updatePatchWidth(); int patchHeight = imageConfig.updatePatchHeight(); for (int y = 0; y < imageRect.height(); y += patchHeight) { for (int x = 0; x < imageRect.width(); x += patchWidth) { QRect patchRect(x, y, patchWidth, patchHeight); startUpdateCanvasProjection(patchRect); } } } } void KisCanvas2::setDisplayFilter(QSharedPointer displayFilter) { m_d->displayColorConverter.setDisplayFilter(displayFilter); KisImageSP image = this->image(); m_d->view->viewManager()->blockUntilOperationsFinishedForced(image); image->barrierLock(); m_d->canvasWidget->setDisplayFilter(displayFilter); image->unlock(); } QSharedPointer KisCanvas2::displayFilter() const { return m_d->displayColorConverter.displayFilter(); } KisDisplayColorConverter* KisCanvas2::displayColorConverter() const { return &m_d->displayColorConverter; } KisExposureGammaCorrectionInterface* KisCanvas2::exposureGammaCorrectionInterface() const { QSharedPointer displayFilter = m_d->displayColorConverter.displayFilter(); return displayFilter ? displayFilter->correctionInterface() : KisDumbExposureGammaCorrectionInterface::instance(); } void KisCanvas2::setProofingOptions(bool softProof, bool gamutCheck) { m_d->proofingConfig = this->image()->proofingConfiguration(); if (!m_d->proofingConfig) { qDebug()<<"Canvas: No proofing config found, generating one."; KisImageConfig cfg; m_d->proofingConfig = cfg.defaultProofingconfiguration(); } KoColorConversionTransformation::ConversionFlags conversionFlags = m_d->proofingConfig->conversionFlags; -#if QT_VERSION >= 0x07000 +#if QT_VERSION >= 0x070000 if (this->image()->colorSpace()->colorDepthId().id().contains("U")) { conversionFlags.setFlag(KoColorConversionTransformation::SoftProofing, softProof); if (softProof) { conversionFlags.setFlag(KoColorConversionTransformation::GamutCheck, gamutCheck); } } #else if (this->image()->colorSpace()->colorDepthId().id().contains("U")) { conversionFlags |= KoColorConversionTransformation::SoftProofing; } else { conversionFlags = conversionFlags & ~KoColorConversionTransformation::SoftProofing; } if (gamutCheck && softProof && this->image()->colorSpace()->colorDepthId().id().contains("U")) { conversionFlags |= KoColorConversionTransformation::GamutCheck; } else { conversionFlags = conversionFlags & ~KoColorConversionTransformation::GamutCheck; } -#endif; +#endif m_d->proofingConfig->conversionFlags = conversionFlags; m_d->proofingConfigUpdated = true; startUpdateInPatches(this->image()->bounds()); } void KisCanvas2::slotSoftProofing(bool softProofing) { m_d->softProofing = softProofing; setProofingOptions(m_d->softProofing, m_d->gamutCheck); } void KisCanvas2::slotGamutCheck(bool gamutCheck) { m_d->gamutCheck = gamutCheck; setProofingOptions(m_d->softProofing, m_d->gamutCheck); } void KisCanvas2::slotChangeProofingConfig() { setProofingOptions(m_d->softProofing, m_d->gamutCheck); } void KisCanvas2::setProofingConfigUpdated(bool updated) { m_d->proofingConfigUpdated = updated; } bool KisCanvas2::proofingConfigUpdated() { return m_d->proofingConfigUpdated; } KisProofingConfigurationSP KisCanvas2::proofingConfiguration() const { if (!m_d->proofingConfig) { m_d->proofingConfig = this->image()->proofingConfiguration(); if (!m_d->proofingConfig) { m_d->proofingConfig = KisImageConfig().defaultProofingconfiguration(); } } return m_d->proofingConfig; } void KisCanvas2::startResizingImage() { KisImageWSP image = this->image(); qint32 w = image->width(); qint32 h = image->height(); emit sigContinueResizeImage(w, h); QRect imageBounds(0, 0, w, h); startUpdateInPatches(imageBounds); } void KisCanvas2::finishResizingImage(qint32 w, qint32 h) { m_d->canvasWidget->finishResizingImage(w, h); } void KisCanvas2::startUpdateCanvasProjection(const QRect & rc) { KisUpdateInfoSP info = m_d->canvasWidget->startUpdateCanvasProjection(rc, m_d->channelFlags); if (m_d->projectionUpdatesCompressor.putUpdateInfo(info)) { emit sigCanvasCacheUpdated(); } } void KisCanvas2::updateCanvasProjection() { while (KisUpdateInfoSP info = m_d->projectionUpdatesCompressor.takeUpdateInfo()) { QRect vRect = m_d->canvasWidget->updateCanvasProjection(info); if (!vRect.isEmpty()) { updateCanvasWidgetImpl(m_d->coordinatesConverter->viewportToWidget(vRect).toAlignedRect()); } } // TODO: Implement info->dirtyViewportRect() for KisOpenGLCanvas2 to avoid updating whole canvas if (m_d->currentCanvasIsOpenGL) { updateCanvasWidgetImpl(); } } void KisCanvas2::slotDoCanvasUpdate() { if (m_d->canvasWidget->isBusy()) { // just restarting the timer updateCanvasWidgetImpl(m_d->savedUpdateRect); return; } if (m_d->savedUpdateRect.isEmpty()) { m_d->canvasWidget->widget()->update(); emit updateCanvasRequested(m_d->canvasWidget->widget()->rect()); } else { emit updateCanvasRequested(m_d->savedUpdateRect); m_d->canvasWidget->widget()->update(m_d->savedUpdateRect); } m_d->savedUpdateRect = QRect(); } void KisCanvas2::updateCanvasWidgetImpl(const QRect &rc) { if (!m_d->updateSignalCompressor.isActive() || !m_d->savedUpdateRect.isEmpty()) { m_d->savedUpdateRect |= rc; } m_d->updateSignalCompressor.start(); } void KisCanvas2::updateCanvas() { updateCanvasWidgetImpl(); } void KisCanvas2::updateCanvas(const QRectF& documentRect) { if (m_d->currentCanvasIsOpenGL && m_d->canvasWidget->decorations().size() > 0) { updateCanvasWidgetImpl(); } else { // updateCanvas is called from tools, never from the projection // updates, so no need to prescale! QRect widgetRect = m_d->coordinatesConverter->documentToWidget(documentRect).toAlignedRect(); widgetRect.adjust(-2, -2, 2, 2); if (!widgetRect.isEmpty()) { updateCanvasWidgetImpl(widgetRect); } } } void KisCanvas2::disconnectCanvasObserver(QObject *object) { KoCanvasBase::disconnectCanvasObserver(object); m_d->view->disconnect(object); } void KisCanvas2::notifyZoomChanged() { if (!m_d->currentCanvasIsOpenGL) { Q_ASSERT(m_d->prescaledProjection); m_d->prescaledProjection->notifyZoomChanged(); } notifyLevelOfDetailChange(); updateCanvas(); // update the canvas, because that isn't done when zooming using KoZoomAction } void KisCanvas2::slotTrySwitchShapeManager() { QPointer oldManager = m_d->currentlyActiveShapeManager; KisNodeSP node = m_d->view->currentNode(); QPointer newManager; newManager = fetchShapeManagerFromNode(node); if (newManager != oldManager) { m_d->currentlyActiveShapeManager = newManager; m_d->selectedShapesProxy.setShapeManager(newManager); } } void KisCanvas2::notifyLevelOfDetailChange() { if (!m_d->effectiveLodAllowedInCanvas()) return; KisImageSP image = this->image(); const qreal effectiveZoom = m_d->coordinatesConverter->effectiveZoom(); KisConfig cfg; const int maxLod = cfg.numMipmapLevels(); int lod = KisLodTransform::scaleToLod(effectiveZoom, maxLod); image->setDesiredLevelOfDetail(lod); } const KoColorProfile * KisCanvas2::monitorProfile() { return m_d->displayColorConverter.monitorProfile(); } KisViewManager* KisCanvas2::viewManager() const { if (m_d->view) { return m_d->view->viewManager(); } return 0; } QPointerKisCanvas2::imageView() const { return m_d->view; } KisImageWSP KisCanvas2::image() const { return m_d->view->image(); } KisImageWSP KisCanvas2::currentImage() const { return m_d->view->image(); } void KisCanvas2::documentOffsetMoved(const QPoint &documentOffset) { QPointF offsetBefore = m_d->coordinatesConverter->imageRectInViewportPixels().topLeft(); m_d->coordinatesConverter->setDocumentOffset(documentOffset); QPointF offsetAfter = m_d->coordinatesConverter->imageRectInViewportPixels().topLeft(); QPointF moveOffset = offsetAfter - offsetBefore; if (!m_d->currentCanvasIsOpenGL) m_d->prescaledProjection->viewportMoved(moveOffset); emit documentOffsetUpdateFinished(); updateCanvas(); } void KisCanvas2::slotConfigChanged() { KisConfig cfg; m_d->vastScrolling = cfg.vastScrolling(); resetCanvas(cfg.useOpenGL()); slotSetDisplayProfile(cfg.displayProfile(QApplication::desktop()->screenNumber(this->canvasWidget()))); initializeFpsDecoration(); } void KisCanvas2::refetchDataFromImage() { KisImageSP image = this->image(); KisImageBarrierLocker l(image); startUpdateInPatches(image->bounds()); } void KisCanvas2::slotSetDisplayProfile(const KoColorProfile *monitorProfile) { if (m_d->displayColorConverter.monitorProfile() == monitorProfile) return; m_d->displayColorConverter.setMonitorProfile(monitorProfile); { KisImageSP image = this->image(); KisImageBarrierLocker l(image); m_d->canvasWidget->setDisplayProfile(&m_d->displayColorConverter); } refetchDataFromImage(); } void KisCanvas2::addDecoration(KisCanvasDecorationSP deco) { m_d->canvasWidget->addDecoration(deco); } KisCanvasDecorationSP KisCanvas2::decoration(const QString& id) const { return m_d->canvasWidget->decoration(id); } QPoint KisCanvas2::documentOrigin() const { /** * In Krita we don't use document origin anymore. * All the centering when needed (vastScrolling < 0.5) is done * automatically by the KisCoordinatesConverter. */ return QPoint(); } QPoint KisCanvas2::documentOffset() const { return m_d->coordinatesConverter->documentOffset(); } void KisCanvas2::setFavoriteResourceManager(KisFavoriteResourceManager* favoriteResourceManager) { m_d->popupPalette = new KisPopupPalette(viewManager(), m_d->coordinatesConverter, favoriteResourceManager, displayColorConverter()->displayRendererInterface(), m_d->view->resourceProvider(), m_d->canvasWidget->widget()); connect(m_d->popupPalette, SIGNAL(zoomLevelChanged(int)), this, SLOT(slotZoomChanged(int))); connect(m_d->popupPalette, SIGNAL(sigUpdateCanvas()), this, SLOT(updateCanvas())); m_d->popupPalette->showPopupPalette(false); } void KisCanvas2::slotZoomChanged(int zoom ) { m_d->view->viewManager()->zoomController()->setZoom(KoZoomMode::ZOOM_CONSTANT, (qreal)(zoom/100.0)); // 1.0 is 100% zoom notifyZoomChanged(); } void KisCanvas2::setCursor(const QCursor &cursor) { canvasWidget()->setCursor(cursor); } KisAnimationFrameCacheSP KisCanvas2::frameCache() const { return m_d->frameCache; } KisAnimationPlayer *KisCanvas2::animationPlayer() const { return m_d->animationPlayer; } void KisCanvas2::slotSelectionChanged() { KisShapeLayer* shapeLayer = dynamic_cast(viewManager()->activeLayer().data()); if (!shapeLayer) { return; } m_d->shapeManager.selection()->deselectAll(); Q_FOREACH (KoShape* shape, shapeLayer->shapeManager()->selection()->selectedShapes()) { m_d->shapeManager.selection()->select(shape); } } bool KisCanvas2::isPopupPaletteVisible() const { if (!m_d->popupPalette) { return false; } return m_d->popupPalette->isVisible(); } void KisCanvas2::setWrapAroundViewingMode(bool value) { KisCanvasDecorationSP infinityDecoration = m_d->canvasWidget->decoration(INFINITY_DECORATION_ID); if (infinityDecoration) { infinityDecoration->setVisible(!value); } m_d->canvasWidget->setWrapAroundViewingMode(value); } bool KisCanvas2::wrapAroundViewingMode() const { KisCanvasDecorationSP infinityDecoration = m_d->canvasWidget->decoration(INFINITY_DECORATION_ID); if (infinityDecoration) { return !(infinityDecoration->visible()); } return false; } void KisCanvas2::bootstrapFinished() { if (!m_d->bootstrapLodBlocked) return; m_d->bootstrapLodBlocked = false; setLodAllowedInCanvas(m_d->lodAllowedInCanvas); } void KisCanvas2::setLodAllowedInCanvas(bool value) { if (!KisOpenGL::supportsLoD()) { qWarning() << "WARNING: Level of Detail functionality is available only with openGL + GLSL 1.3 support"; } m_d->lodAllowedInCanvas = value && m_d->currentCanvasIsOpenGL && KisOpenGL::supportsLoD() && (m_d->openGLFilterMode == KisOpenGL::TrilinearFilterMode || m_d->openGLFilterMode == KisOpenGL::HighQualityFiltering); KisImageSP image = this->image(); if (m_d->effectiveLodAllowedInCanvas() != !image->levelOfDetailBlocked()) { image->setLevelOfDetailBlocked(!m_d->effectiveLodAllowedInCanvas()); notifyLevelOfDetailChange(); } KisConfig cfg; cfg.setLevelOfDetailEnabled(m_d->lodAllowedInCanvas); } bool KisCanvas2::lodAllowedInCanvas() const { return m_d->lodAllowedInCanvas; } void KisCanvas2::slotShowPopupPalette(const QPoint &p) { if (!m_d->popupPalette) { return; } m_d->popupPalette->showPopupPalette(p); } KisPaintingAssistantsDecorationSP KisCanvas2::paintingAssistantsDecoration() const { KisCanvasDecorationSP deco = decoration("paintingAssistantsDecoration"); return qobject_cast(deco.data()); } diff --git a/libs/ui/dialogs/kis_dlg_image_properties.cc b/libs/ui/dialogs/kis_dlg_image_properties.cc index 16f8eb7d93..b218a48218 100644 --- a/libs/ui/dialogs/kis_dlg_image_properties.cc +++ b/libs/ui/dialogs/kis_dlg_image_properties.cc @@ -1,203 +1,203 @@ /* * Copyright (c) 2004 Boudewijn Rempt * * 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 "kis_dlg_image_properties.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "widgets/kis_cmb_idlist.h" #include "widgets/squeezedcombobox.h" #include "kis_layer_utils.h" KisDlgImageProperties::KisDlgImageProperties(KisImageWSP image, QWidget *parent, const char *name) : KoDialog(parent) { setButtons(Ok | Cancel); setDefaultButton(Ok); setObjectName(name); setCaption(i18n("Image Properties")); m_page = new WdgImageProperties(this); m_image = image; setMainWidget(m_page); resize(m_page->sizeHint()); KisConfig cfg; m_page->lblWidthValue->setText(QString::number(image->width())); m_page->lblHeightValue->setText(QString::number(image->height())); m_page->lblResolutionValue->setText(QLocale().toString(image->xRes()*72, 2)); // XXX: separate values for x & y? //Set the canvas projection color: backgroundColor KoColor background = m_image->defaultProjectionColor(); background.setOpacity(1.0); m_page->bnBackgroundColor->setColor(background); m_page->sldBackgroundColor->setRange(0.0,1.0,2); m_page->sldBackgroundColor->setSingleStep(0.05); m_page->sldBackgroundColor->setValue(m_image->defaultProjectionColor().opacityF()); KisSignalCompressor *compressor = new KisSignalCompressor(500 /* ms */, KisSignalCompressor::POSTPONE, this); connect(m_page->bnBackgroundColor, SIGNAL(changed(KoColor)), compressor, SLOT(start())); connect(m_page->sldBackgroundColor, SIGNAL(valueChanged(qreal)), compressor, SLOT(start())); connect(compressor, SIGNAL(timeout()), this, SLOT(setCurrentColor())); //Set the color space m_page->colorSpaceSelector->setCurrentColorSpace(image->colorSpace()); //set the proofing space m_proofingConfig = m_image->proofingConfiguration(); if (!m_proofingConfig) { m_page->chkSaveProofing->setChecked(false); m_proofingConfig = KisImageConfig().defaultProofingconfiguration(); } else { m_page->chkSaveProofing->setChecked(true); } m_page->proofSpaceSelector->setCurrentColorSpace(KoColorSpaceRegistry::instance()->colorSpace(m_proofingConfig->proofingModel, m_proofingConfig->proofingDepth, m_proofingConfig->proofingProfile)); m_page->cmbIntent->setCurrentIndex((int)m_proofingConfig->intent); m_page->ckbBlackPointComp->setChecked(m_proofingConfig->conversionFlags.testFlag(KoColorConversionTransformation::BlackpointCompensation)); m_page->gamutAlarm->setColor(m_proofingConfig->warningColor); m_page->gamutAlarm->setToolTip(i18n("Set color used for warning")); m_page->sldAdaptationState->setMaximum(20); m_page->sldAdaptationState->setMinimum(0); m_page->sldAdaptationState->setValue((int)m_proofingConfig->adaptationState*20); KisSignalCompressor *softProofConfigCompressor = new KisSignalCompressor(500, KisSignalCompressor::POSTPONE,this); connect(m_page->gamutAlarm, SIGNAL(changed(KoColor)), softProofConfigCompressor, SLOT(start())); connect(m_page->proofSpaceSelector, SIGNAL(colorSpaceChanged(const KoColorSpace*)), softProofConfigCompressor, SLOT(start())); connect(m_page->cmbIntent, SIGNAL(currentIndexChanged(int)), softProofConfigCompressor, SLOT(start())); connect(m_page->ckbBlackPointComp, SIGNAL(stateChanged(int)), softProofConfigCompressor, SLOT(start())); connect(m_page->sldAdaptationState, SIGNAL(valueChanged(int)), softProofConfigCompressor, SLOT(start())); connect(softProofConfigCompressor, SIGNAL(timeout()), this, SLOT(setProofingConfig())); //annotations vKisAnnotationSP_it beginIt = image->beginAnnotations(); vKisAnnotationSP_it endIt = image->endAnnotations(); vKisAnnotationSP_it it = beginIt; while (it != endIt) { if (!(*it) || (*it)->type().isEmpty()) { dbgFile << "Warning: empty annotation"; it++; continue; } m_page->cmbAnnotations->addItem((*it) -> type()); it++; } connect(m_page->cmbAnnotations, SIGNAL(activated(QString)), SLOT(setAnnotation(QString))); setAnnotation(m_page->cmbAnnotations->currentText()); } KisDlgImageProperties::~KisDlgImageProperties() { delete m_page; } const KoColorSpace * KisDlgImageProperties::colorSpace() { return m_page->colorSpaceSelector->currentColorSpace(); } void KisDlgImageProperties::setCurrentColor() { KoColor background = m_page->bnBackgroundColor->color(); background.setOpacity(m_page->sldBackgroundColor->value()); KisLayerUtils::changeImageDefaultProjectionColor(m_image, background); } void KisDlgImageProperties::setProofingConfig() { if (m_firstProofingConfigChange) { m_page->chkSaveProofing->setChecked(true); m_firstProofingConfigChange = false; } if (m_page->chkSaveProofing->isChecked()) { m_proofingConfig->conversionFlags = KoColorConversionTransformation::HighQuality; -#if QT_VERSION >= 0x07000 +#if QT_VERSION >= 0x070000 m_proofingConfig->conversionFlags.setFlag(KoColorConversionTransformation::BlackpointCompensation, m_page->ckbBlackPointComp->isChecked()); #else - m_page->chkBlackPointComp->isChecked() ? + m_page->ckbBlackPointComp->isChecked() ? m_proofingConfig->conversionFlags |= KoColorConversionTransformation::BlackpointCompensation : m_proofingConfig->conversionFlags = m_proofingConfig->conversionFlags & ~KoColorConversionTransformation::BlackpointCompensation; #endif m_proofingConfig->intent = (KoColorConversionTransformation::Intent)m_page->cmbIntent->currentIndex(); m_proofingConfig->proofingProfile = m_page->proofSpaceSelector->currentColorSpace()->profile()->name(); m_proofingConfig->proofingModel = m_page->proofSpaceSelector->currentColorSpace()->colorModelId().id(); m_proofingConfig->proofingDepth = "U8";//default to this m_proofingConfig->warningColor = m_page->gamutAlarm->color(); m_proofingConfig->adaptationState = (double)m_page->sldAdaptationState->value()/20.0; m_image->setProofingConfiguration(m_proofingConfig); } else { - m_image->setProofingConfiguration(0); + m_image->setProofingConfiguration(KisProofingConfigurationSP()); } } void KisDlgImageProperties::setAnnotation(const QString &type) { KisAnnotationSP annotation = m_image->annotation(type); if (annotation) { m_page->lblDescription->clear(); m_page->txtAnnotation->clear(); m_page->lblDescription->setText(annotation->description()); m_page->txtAnnotation->appendPlainText(annotation->displayText()); } else { m_page->lblDescription->clear(); m_page->txtAnnotation->clear(); } }