diff --git a/libs/image/kis_image.cc b/libs/image/kis_image.cc index 0190db01c1..8a769a9484 100644 --- a/libs/image/kis_image.cc +++ b/libs/image/kis_image.cc @@ -1,2375 +1,2386 @@ /* * 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 "KoColorSpaceRegistry.h" #include "KoColor.h" #include "KoColorProfile.h" #include #include "KisProofingConfiguration.h" #include "kis_adjustment_layer.h" #include "kis_annotation.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_projection_leaf.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_node.h" #include "kis_types.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_simple_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 "processing/kis_convert_color_space_processing_visitor.h" #include "processing/kis_assign_profile_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_do_something_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 "tiles3/kis_lockless_stack.h" #include #include #include "kis_time_range.h" #include "KisRunnableBasedStrokeStrategy.h" #include "KisRunnableStrokeJobData.h" #include "KisRunnableStrokeJobUtils.h" #include "KisRunnableStrokeJobsInterface.h" #include "KisBusyWaitBroker.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()) - , currentIsolationMode(IsolationMode::ISOLATE_OFF) + , isolateLayer(false) + , isolateGroup(false) , nserver(1) , undoStore(undo ? undo : new KisDumbUndoStore()) , legacyUndoAdapter(undoStore.data(), _q) , postExecutionUndoAdapter(undoStore.data(), _q) , signalRouter(_q) , animationInterface(_animationInterface) , scheduler(_q, _q) , axesCenter(QPointF(0.5, 0.5)) { { KisImageConfig cfg(true); 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.setSuspendResumeUpdatesStrokeStrategyFactory( [=]() { KisSuspendProjectionUpdatesStrokeStrategy::SharedDataSP data = KisSuspendProjectionUpdatesStrokeStrategy::createSharedData(); KisSuspendResumePair suspend(new KisSuspendProjectionUpdatesStrokeStrategy(KisImageWSP(q), true, data), KisSuspendProjectionUpdatesStrokeStrategy::createSuspendJobsData(KisImageWSP(q))); KisSuspendResumePair resume(new KisSuspendProjectionUpdatesStrokeStrategy(KisImageWSP(q), false, data), KisSuspendProjectionUpdatesStrokeStrategy::createResumeJobsData(KisImageWSP(q))); return std::make_pair(suspend, resume); }); } 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 KisSelectionMaskSP targetOverlaySelectionMask; // the overlay switching stroke will try to switch into this mask KisSelectionMaskSP overlaySelectionMask; QList compositions; KisNodeSP isolationRootNode; - IsolationMode currentIsolationMode; + bool isolateLayer; + bool isolateGroup; bool wrapAroundModePermitted = false; KisNameServer nserver; QScopedPointer undoStore; KisLegacyUndoAdapter legacyUndoAdapter; KisPostExecutionUndoAdapter postExecutionUndoAdapter; vKisAnnotationSP annotations; QAtomicInt disableUIUpdateSignals; KisLocklessStack savedDisabledUIUpdates; // filters are applied in a reversed way, from rbegin() to rend() QVector projectionUpdatesFilters; QStack disabledUpdatesCookies; KisImageSignalRouter signalRouter; KisImageAnimationInterface *animationInterface; KisUpdateScheduler scheduler; QAtomicInt disableDirtyRequests; KisCompositeProgressProxy compositeProgressProxy; bool blockLevelOfDetail = false; QPointF axesCenter; bool allowMasksOnRootNode = false; bool tryCancelCurrentStrokeAsync(); void notifyProjectionUpdatedInPatches(const QRect &rc, QVector &jobs); void convertImageColorSpaceImpl(const KoColorSpace *dstColorSpace, bool convertLayers, KoColorConversionTransformation::Intent renderingIntent, KoColorConversionTransformation::ConversionFlags conversionFlags); struct SetImageProjectionColorSpace; }; 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()); connect(this, SIGNAL(sigInternalStopIsolatedModeRequested()), SLOT(stopIsolatedMode())); setObjectName(name); setRootLayer(new KisGroupLayer(this, "root", OPACITY_OPAQUE_U8)); } KisImage::~KisImage() { /** * Request the tools to end currently running strokes */ waitForDone(); delete m_d; disconnect(); // in case Qt gets confused } KisImageSP KisImage::fromQImage(const QImage &image, KisUndoStore *undoStore) { const KoColorSpace *colorSpace = 0; switch (image.format()) { case QImage::Format_Invalid: case QImage::Format_Mono: case QImage::Format_MonoLSB: colorSpace = KoColorSpaceRegistry::instance()->graya8(); break; case QImage::Format_Indexed8: case QImage::Format_RGB32: case QImage::Format_ARGB32: case QImage::Format_ARGB32_Premultiplied: colorSpace = KoColorSpaceRegistry::instance()->rgb8(); break; case QImage::Format_RGB16: colorSpace = KoColorSpaceRegistry::instance()->rgb16(); break; case QImage::Format_ARGB8565_Premultiplied: case QImage::Format_RGB666: case QImage::Format_ARGB6666_Premultiplied: case QImage::Format_RGB555: case QImage::Format_ARGB8555_Premultiplied: case QImage::Format_RGB888: case QImage::Format_RGB444: case QImage::Format_ARGB4444_Premultiplied: case QImage::Format_RGBX8888: case QImage::Format_RGBA8888: case QImage::Format_RGBA8888_Premultiplied: colorSpace = KoColorSpaceRegistry::instance()->rgb8(); break; case QImage::Format_BGR30: case QImage::Format_A2BGR30_Premultiplied: case QImage::Format_RGB30: case QImage::Format_A2RGB30_Premultiplied: colorSpace = KoColorSpaceRegistry::instance()->rgb8(); break; case QImage::Format_Alpha8: colorSpace = KoColorSpaceRegistry::instance()->alpha8(); break; case QImage::Format_Grayscale8: colorSpace = KoColorSpaceRegistry::instance()->graya8(); break; #if QT_VERSION >= QT_VERSION_CHECK(5, 13, 0) case QImage::Format_Grayscale16: colorSpace = KoColorSpaceRegistry::instance()->graya16(); break; #endif #if QT_VERSION >= QT_VERSION_CHECK(5, 12, 0) case QImage::Format_RGBX64: case QImage::Format_RGBA64: case QImage::Format_RGBA64_Premultiplied: colorSpace = KoColorSpaceRegistry::instance()->colorSpace(RGBAColorModelID.id(), Float32BitsColorDepthID.id(), 0); break; #endif default: colorSpace = 0; } KisImageSP img = new KisImage(undoStore, image.width(), image.height(), colorSpace, i18n("Imported Image")); KisPaintLayerSP layer = new KisPaintLayer(img, img->nextLayerName(), 255); layer->paintDevice()->convertFromQImage(image, 0, 0, 0); img->addNode(layer.data(), img->rootLayer().data()); return img; } KisImage *KisImage::clone(bool exactCopy) { return new KisImage(*this, 0, exactCopy); } void KisImage::copyFromImage(const KisImage &rhs) { copyFromImageImpl(rhs, REPLACE); } void KisImage::copyFromImageImpl(const KisImage &rhs, int policy) { // make sure we choose exactly one from REPLACE and CONSTRUCT KIS_ASSERT_RECOVER_RETURN((policy & REPLACE) != (policy & CONSTRUCT)); // only when replacing do we need to emit signals #define EMIT_IF_NEEDED if (!(policy & REPLACE)) {} else emit if (policy & REPLACE) { // if we are constructing the image, these are already set if (m_d->width != rhs.width() || m_d->height != rhs.height()) { m_d->width = rhs.width(); m_d->height = rhs.height(); emit sigSizeChanged(QPointF(), QPointF()); } if (m_d->colorSpace != rhs.colorSpace()) { m_d->colorSpace = rhs.colorSpace(); emit sigColorSpaceChanged(m_d->colorSpace); } } // from KisImage::KisImage(const KisImage &, KisUndoStore *, bool) setObjectName(rhs.objectName()); if (m_d->xres != rhs.m_d->xres || m_d->yres != rhs.m_d->yres) { m_d->xres = rhs.m_d->xres; m_d->yres = rhs.m_d->yres; EMIT_IF_NEEDED sigResolutionChanged(m_d->xres, m_d->yres); } m_d->allowMasksOnRootNode = rhs.m_d->allowMasksOnRootNode; if (rhs.m_d->proofingConfig) { KisProofingConfigurationSP proofingConfig(new KisProofingConfiguration(*rhs.m_d->proofingConfig)); if (policy & REPLACE) { setProofingConfiguration(proofingConfig); } else { m_d->proofingConfig = proofingConfig; } } KisNodeSP newRoot = rhs.root()->clone(); newRoot->setGraphListener(this); newRoot->setImage(this); m_d->rootLayer = dynamic_cast(newRoot.data()); setRoot(newRoot); bool exactCopy = policy & EXACT_COPY; if (exactCopy || rhs.m_d->isolationRootNode || rhs.m_d->overlaySelectionMask) { - m_d->currentIsolationMode = rhs.m_d->currentIsolationMode; + m_d->isolateLayer = rhs.m_d->isolateLayer; + m_d->isolateGroup = rhs.m_d->isolateGroup; QQueue linearizedNodes; KisLayerUtils::recursiveApplyNodes(rhs.root(), [&linearizedNodes](KisNodeSP node) { linearizedNodes.enqueue(node); }); KisLayerUtils::recursiveApplyNodes(newRoot, [&linearizedNodes, exactCopy, &rhs, this](KisNodeSP node) { KisNodeSP refNode = linearizedNodes.dequeue(); if (exactCopy) { node->setUuid(refNode->uuid()); } if (rhs.m_d->isolationRootNode && rhs.m_d->isolationRootNode == refNode) { m_d->isolationRootNode = node; } if (rhs.m_d->overlaySelectionMask && KisNodeSP(rhs.m_d->overlaySelectionMask) == refNode) { m_d->targetOverlaySelectionMask = dynamic_cast(node.data()); m_d->overlaySelectionMask = m_d->targetOverlaySelectionMask; m_d->rootLayer->notifyChildMaskChanged(); } }); } KisLayerUtils::recursiveApplyNodes(newRoot, [](KisNodeSP node) { dbgImage << "Node: " << (void *)node.data(); }); m_d->compositions.clear(); Q_FOREACH (KisLayerCompositionSP comp, rhs.m_d->compositions) { m_d->compositions << toQShared(new KisLayerComposition(*comp, this)); } EMIT_IF_NEEDED sigLayersChangedAsync(); m_d->nserver = 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->projectionUpdatesFilters.isEmpty()); KIS_ASSERT_RECOVER_NOOP(!rhs.m_d->disableUIUpdateSignals); KIS_ASSERT_RECOVER_NOOP(!rhs.m_d->disableDirtyRequests); m_d->blockLevelOfDetail = rhs.m_d->blockLevelOfDetail; #undef EMIT_IF_NEEDED } 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()); connect(this, SIGNAL(sigInternalStopIsolatedModeRequested()), SLOT(stopIsolatedMode())); copyFromImageImpl(rhs, CONSTRUCT | (exactCopy ? EXACT_COPY : 0)); } 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); } void KisImage::aboutToRemoveANode(KisNode *parent, int index) { KisNodeSP deletedNode = parent->at(index); if (!dynamic_cast(deletedNode.data()) && deletedNode == m_d->isolationRootNode) { emit sigInternalStopIsolatedModeRequested(); } 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()); } void KisImage::setOverlaySelectionMask(KisSelectionMaskSP mask) { if (m_d->targetOverlaySelectionMask == mask) return; m_d->targetOverlaySelectionMask = mask; struct UpdateOverlaySelectionStroke : public KisSimpleStrokeStrategy { UpdateOverlaySelectionStroke(KisImageSP image) : KisSimpleStrokeStrategy(QLatin1String("update-overlay-selection-mask"), kundo2_noi18n("update-overlay-selection-mask")), m_image(image) { this->enableJob(JOB_INIT, true, KisStrokeJobData::BARRIER, KisStrokeJobData::EXCLUSIVE); setClearsRedoOnStart(false); } void initStrokeCallback() { KisSelectionMaskSP oldMask = m_image->m_d->overlaySelectionMask; KisSelectionMaskSP newMask = m_image->m_d->targetOverlaySelectionMask; if (oldMask == newMask) return; KIS_SAFE_ASSERT_RECOVER_RETURN(!newMask || newMask->graphListener() == m_image); m_image->m_d->overlaySelectionMask = newMask; if (oldMask || newMask) { m_image->m_d->rootLayer->notifyChildMaskChanged(); } if (oldMask) { m_image->m_d->rootLayer->setDirtyDontResetAnimationCache(oldMask->extent()); } if (newMask) { newMask->setDirty(); } m_image->undoAdapter()->emitSelectionChanged(); } private: KisImageSP m_image; }; KisStrokeId id = startStroke(new UpdateOverlaySelectionStroke(this)); endStroke(id); } KisSelectionMaskSP KisImage::overlaySelectionMask() const { return m_d->overlaySelectionMask; } bool KisImage::hasOverlaySelectionMask() const { return m_d->overlaySelectionMask; } 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, i18n("Selection Mask")); 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); } KIS_SAFE_ASSERT_RECOVER_NOOP(m_d->rootLayer->childCount() > 0); KIS_SAFE_ASSERT_RECOVER_NOOP(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(); KisBusyWaitBroker::instance()->notifyWaitOnImageStarted(this); m_d->scheduler.barrierLock(); KisBusyWaitBroker::instance()->notifyWaitOnImageEnded(this); 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(); KisBusyWaitBroker::instance()->notifyWaitOnImageStarted(this); m_d->scheduler.lock(); KisBusyWaitBroker::instance()->notifyWaitOnImageEnded(this); } 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::purgeUnusedData(bool isCancellable) { /** * WARNING: don't use this function unless you know what you are doing! * * It breaks undo on layers! Therefore, after calling it, KisImage is not * undo-capable anymore! */ struct PurgeUnusedDataStroke : public KisRunnableBasedStrokeStrategy { PurgeUnusedDataStroke(KisImageSP image, bool isCancellable) : KisRunnableBasedStrokeStrategy(QLatin1String("purge-unused-data"), kundo2_noi18n("purge-unused-data")), m_image(image) { this->enableJob(JOB_INIT, true, KisStrokeJobData::BARRIER, KisStrokeJobData::EXCLUSIVE); this->enableJob(JOB_DOSTROKE, true); setClearsRedoOnStart(false); setRequestsOtherStrokesToEnd(!isCancellable); setCanForgetAboutMe(isCancellable); } void initStrokeCallback() { KisPaintDeviceList deviceList; QVector jobsData; KisLayerUtils::recursiveApplyNodes(m_image->root(), [&deviceList](KisNodeSP node) { deviceList << node->getLodCapableDevices(); }); Q_FOREACH (KisPaintDeviceSP device, deviceList) { if (!device) continue; KritaUtils::addJobConcurrent(jobsData, [device] () { const_cast(device.data())->purgeDefaultPixels(); }); } addMutatedJobs(jobsData); } private: KisImageSP m_image; }; KisStrokeId id = startStroke(new PurgeUnusedDataStroke(this, isCancellable)); endStroke(id); } 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, const QPointF ¢er, qreal scaleX, qreal scaleY, KisFilterStrategy *filterStrategy, KisSelectionSP selection) { KUndo2MagicString actionName(kundo2_i18n("Scale Layer")); KisImageSignalVector emitSignals; emitSignals << ModifiedSignal; QPointF offset; { KisTransformWorker worker(0, scaleX, scaleY, 0, 0, 0, 0, 0.0, 0, 0, 0, 0); QTransform transform = worker.transform(); offset = center - transform.map(center); } KisProcessingApplicator applicator(this, node, KisProcessingApplicator::RECURSIVE, emitSignals, actionName); KisTransformProcessingVisitor *visitor = new KisTransformProcessingVisitor(scaleX, scaleY, 0, 0, QPointF(), 0, offset.x(), offset.y(), filterStrategy); visitor->setSelection(selection); if (selection) { applicator.applyVisitor(visitor, KisStrokeJobData::CONCURRENT); } else { applicator.applyVisitorAllFrames(visitor, KisStrokeJobData::CONCURRENT); } applicator.end(); } void KisImage::rotateImpl(const KUndo2MagicString &actionName, KisNodeSP rootNode, double radians, bool resizeImage, KisSelectionSP selection) { // we can either transform (and resize) the whole image or // transform a selection, we cannot do both at the same time KIS_SAFE_ASSERT_RECOVER(!(bool(selection) && resizeImage)) { selection = 0; } const QRect baseBounds = resizeImage ? bounds() : selection ? selection->selectedExactRect() : rootNode->exactBounds(); 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(baseBounds); newSize = newRect.size(); offset = -newRect.topLeft(); } else { QPointF origin = QRectF(baseBounds).center(); newSize = size(); offset = -(transform.map(origin) - origin); } } bool sizeChanged = resizeImage && (newSize.width() != baseBounds.width() || newSize.height() != baseBounds.height()); // These signals will be emitted after processing is done KisImageSignalVector emitSignals; if (sizeChanged) emitSignals << ComplexSizeChangedSignal(baseBounds, 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"); KisTransformProcessingVisitor *visitor = new KisTransformProcessingVisitor(1.0, 1.0, 0.0, 0.0, QPointF(), radians, offset.x(), offset.y(), filter); if (selection) { visitor->setSelection(selection); } if (selection) { applicator.applyVisitor(visitor, KisStrokeJobData::CONCURRENT); } else { 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(), radians, true, 0); } void KisImage::rotateNode(KisNodeSP node, double radians, KisSelectionSP selection) { if (node->inherits("KisMask")) { rotateImpl(kundo2_i18n("Rotate Mask"), node, radians, false, selection); } else { rotateImpl(kundo2_i18n("Rotate Layer"), node, radians, false, selection); } } void KisImage::shearImpl(const KUndo2MagicString &actionName, KisNodeSP rootNode, bool resizeImage, double angleX, double angleY, KisSelectionSP selection) { const QRect baseBounds = resizeImage ? bounds() : selection ? selection->selectedExactRect() : rootNode->exactBounds(); const QPointF origin = QRectF(baseBounds).center(); //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(baseBounds); newSize = newRect.size(); if (resizeImage) offset = -newRect.topLeft(); } if (newSize == baseBounds.size()) return; KisImageSignalVector emitSignals; if (resizeImage) emitSignals << ComplexSizeChangedSignal(baseBounds, 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"); KisTransformProcessingVisitor *visitor = new KisTransformProcessingVisitor(1.0, 1.0, tanX, tanY, origin, 0, offset.x(), offset.y(), filter); if (selection) { visitor->setSelection(selection); } if (selection) { applicator.applyVisitor(visitor, KisStrokeJobData::CONCURRENT); } else { applicator.applyVisitorAllFrames(visitor, KisStrokeJobData::CONCURRENT); } if (resizeImage) { applicator.applyCommand(new KisImageResizeCommand(this, newSize)); } applicator.end(); } void KisImage::shearNode(KisNodeSP node, double angleX, double angleY, KisSelectionSP selection) { if (node->inherits("KisMask")) { shearImpl(kundo2_i18n("Shear Mask"), node, false, angleX, angleY, selection); } else { shearImpl(kundo2_i18n("Shear Layer"), node, false, angleX, angleY, selection); } } void KisImage::shear(double angleX, double angleY) { shearImpl(kundo2_i18n("Shear Image"), m_d->rootLayer, true, angleX, angleY, 0); } void KisImage::convertLayerColorSpace(KisNodeSP node, const KoColorSpace *dstColorSpace, KoColorConversionTransformation::Intent renderingIntent, KoColorConversionTransformation::ConversionFlags conversionFlags) { if (!node->projectionLeaf()->isLayer()) return; const KoColorSpace *srcColorSpace = node->colorSpace(); if (!dstColorSpace || *srcColorSpace == *dstColorSpace) return; KUndo2MagicString actionName = kundo2_i18n("Convert Layer Color Space"); KisImageSignalVector emitSignals; emitSignals << ModifiedSignal; KisProcessingApplicator applicator(this, node, KisProcessingApplicator::RECURSIVE, emitSignals, actionName); applicator.applyVisitor( new KisConvertColorSpaceProcessingVisitor( srcColorSpace, dstColorSpace, renderingIntent, conversionFlags), KisStrokeJobData::CONCURRENT); applicator.end(); } struct KisImage::KisImagePrivate::SetImageProjectionColorSpace : public KisCommandUtils::FlipFlopCommand { SetImageProjectionColorSpace(const KoColorSpace *cs, KisImageWSP image, State initialState, KUndo2Command *parent = 0) : KisCommandUtils::FlipFlopCommand(initialState, parent), m_cs(cs), m_image(image) { } void partA() override { KisImageSP image = m_image; if (image) { image->setProjectionColorSpace(m_cs); } } private: const KoColorSpace *m_cs; KisImageWSP m_image; }; void KisImage::KisImagePrivate::convertImageColorSpaceImpl(const KoColorSpace *dstColorSpace, bool convertLayers, KoColorConversionTransformation::Intent renderingIntent, KoColorConversionTransformation::ConversionFlags conversionFlags) { const KoColorSpace *srcColorSpace = this->colorSpace; if (!dstColorSpace || *srcColorSpace == *dstColorSpace) return; const KUndo2MagicString actionName = convertLayers ? kundo2_i18n("Convert Image Color Space") : kundo2_i18n("Convert Projection Color Space"); KisImageSignalVector emitSignals; emitSignals << ColorSpaceChangedSignal; emitSignals << ModifiedSignal; KisProcessingApplicator applicator(q, this->rootLayer, KisProcessingApplicator::RECURSIVE | KisProcessingApplicator::NO_UI_UPDATES, emitSignals, actionName); applicator.applyCommand( new KisImagePrivate::SetImageProjectionColorSpace(dstColorSpace, KisImageWSP(q), KisCommandUtils::FlipFlopCommand::INITIALIZING), KisStrokeJobData::BARRIER); if (convertLayers) { applicator.applyVisitor( new KisConvertColorSpaceProcessingVisitor( srcColorSpace, dstColorSpace, renderingIntent, conversionFlags), KisStrokeJobData::CONCURRENT); } else { applicator.applyCommand( new KisDoSomethingCommand< KisDoSomethingCommandOps::ResetOp, KisGroupLayerSP> (this->rootLayer, false)); applicator.applyCommand( new KisDoSomethingCommand< KisDoSomethingCommandOps::ResetOp, KisGroupLayerSP> (this->rootLayer, true)); } applicator.applyCommand( new KisImagePrivate::SetImageProjectionColorSpace(srcColorSpace, KisImageWSP(q), KisCommandUtils::FlipFlopCommand::FINALIZING), KisStrokeJobData::BARRIER); applicator.end(); } void KisImage::convertImageColorSpace(const KoColorSpace *dstColorSpace, KoColorConversionTransformation::Intent renderingIntent, KoColorConversionTransformation::ConversionFlags conversionFlags) { m_d->convertImageColorSpaceImpl(dstColorSpace, true, renderingIntent, conversionFlags); } void KisImage::convertImageProjectionColorSpace(const KoColorSpace *dstColorSpace) { m_d->convertImageColorSpaceImpl(dstColorSpace, false, KoColorConversionTransformation::internalRenderingIntent(), KoColorConversionTransformation::internalConversionFlags()); } bool KisImage::assignLayerProfile(KisNodeSP node, const KoColorProfile *profile) { const KoColorSpace *srcColorSpace = node->colorSpace(); if (!node->projectionLeaf()->isLayer()) return false; if (!profile || *srcColorSpace->profile() == *profile) return false; KUndo2MagicString actionName = kundo2_i18n("Assign Profile to Layer"); KisImageSignalVector emitSignals; emitSignals << ModifiedSignal; const KoColorSpace *dstColorSpace = KoColorSpaceRegistry::instance()->colorSpace(colorSpace()->colorModelId().id(), colorSpace()->colorDepthId().id(), profile); if (!dstColorSpace) return false; KisProcessingApplicator applicator(this, node, KisProcessingApplicator::RECURSIVE | KisProcessingApplicator::NO_UI_UPDATES, emitSignals, actionName); applicator.applyVisitor( new KisAssignProfileProcessingVisitor( srcColorSpace, dstColorSpace), KisStrokeJobData::CONCURRENT); applicator.end(); return true; } bool KisImage::assignImageProfile(const KoColorProfile *profile, bool blockAllUpdates) { if (!profile) return false; const KoColorSpace *srcColorSpace = m_d->colorSpace; bool imageProfileIsSame = *srcColorSpace->profile() == *profile; imageProfileIsSame &= !KisLayerUtils::recursiveFindNode(m_d->rootLayer, [profile] (KisNodeSP node) { return *node->colorSpace()->profile() != *profile; }); if (imageProfileIsSame) { dbgImage << "Trying to set the same image profile again" << ppVar(srcColorSpace->profile()->name()) << ppVar(profile->name()); return true; } KUndo2MagicString actionName = kundo2_i18n("Assign Profile"); KisImageSignalVector emitSignals; emitSignals << ProfileChangedSignal; emitSignals << ModifiedSignal; const KoColorSpace *dstColorSpace = KoColorSpaceRegistry::instance()->colorSpace(colorSpace()->colorModelId().id(), colorSpace()->colorDepthId().id(), profile); if (!dstColorSpace) return false; KisProcessingApplicator applicator(this, m_d->rootLayer, KisProcessingApplicator::RECURSIVE | (!blockAllUpdates ? KisProcessingApplicator::NO_UI_UPDATES : KisProcessingApplicator::NO_IMAGE_UPDATES), emitSignals, actionName); applicator.applyCommand( new KisImagePrivate::SetImageProjectionColorSpace(dstColorSpace, KisImageWSP(this), KisCommandUtils::FlipFlopCommand::INITIALIZING), KisStrokeJobData::BARRIER); applicator.applyVisitor( new KisAssignProfileProcessingVisitor( srcColorSpace, dstColorSpace), KisStrokeJobData::CONCURRENT); applicator.applyCommand( new KisImagePrivate::SetImageProjectionColorSpace(srcColorSpace, KisImageWSP(this), KisCommandUtils::FlipFlopCommand::FINALIZING), KisStrokeJobData::BARRIER); applicator.end(); return true; } void KisImage::setProjectionColorSpace(const KoColorSpace * colorSpace) { m_d->colorSpace = colorSpace; } 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::documentToImagePixelFloored(const QPointF &documentCoord) const { QPointF pixelCoord = documentToPixel(documentCoord); return QPoint(qFloor(pixelCoord.x()), qFloor(pixelCoord.y())); } QRectF KisImage::documentToPixel(const QRectF &documentRect) const { return QRectF(documentToPixel(documentRect.topLeft()), documentToPixel(documentRect.bottomRight())); } 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->isolationRootNode) { return m_d->isolationRootNode->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(KisNodeSP activeNode) { KisLayerUtils::flattenImage(this, activeNode); } 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; } const KUndo2Command* KisImage::lastExecutedCommand() const { return m_d->undoStore->presentCommand(); } 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; } 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) { emit sigInternalStopIsolatedModeRequested(); 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); setRoot(m_d->rootLayer.data()); this->setDefaultProjectionColor(defaultProjectionColor); } 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(); KisBusyWaitBroker::instance()->notifyWaitOnImageStarted(this); m_d->scheduler.waitForDone(); KisBusyWaitBroker::instance()->notifyWaitOnImageEnded(this); } 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, QVector &jobs) { KisImageConfig imageConfig(true); 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; KritaUtils::addJobConcurrent(jobs, std::bind(&KisImage::notifyProjectionUpdated, q, patchRect)); } } } -bool KisImage::startIsolatedMode(KisNodeSP node, IsolationMode mode) +bool KisImage::startIsolatedMode(KisNodeSP node, bool isolateLayer, bool isolateGroup) { - m_d->currentIsolationMode = mode; - if (mode == ISOLATE_OFF) return false; + m_d->isolateLayer = isolateLayer; + m_d->isolateGroup = isolateGroup; + if ((isolateLayer || isolateGroup) == false) return false; struct StartIsolatedModeStroke : public KisRunnableBasedStrokeStrategy { - StartIsolatedModeStroke(KisNodeSP node, KisImageSP image, IsolationMode mode) + StartIsolatedModeStroke(KisNodeSP node, KisImageSP image, bool isolateLayer, bool isolateGroup) : KisRunnableBasedStrokeStrategy(QLatin1String("start-isolated-mode"), kundo2_noi18n("start-isolated-mode")), m_node(node), m_image(image), m_needsFullRefresh(false), - m_mode(mode) + m_isolateLayer(isolateLayer), + m_isolateGroup(isolateGroup) { this->enableJob(JOB_INIT, true, KisStrokeJobData::SEQUENTIAL, KisStrokeJobData::EXCLUSIVE); this->enableJob(JOB_DOSTROKE, true); this->enableJob(JOB_FINISH, true, KisStrokeJobData::BARRIER); setClearsRedoOnStart(false); } void initStrokeCallback() override { - if (m_mode == ISOLATE_GROUP) { + if (m_isolateLayer == false && m_isolateGroup == true) { m_node = m_node->parent(); } // pass-though node don't have any projection prepared, so we should // explicitly regenerate it before activating isolated mode. m_node->projectionLeaf()->explicitlyRegeneratePassThroughProjection(); const bool beforeVisibility = m_node->projectionLeaf()->visible(); m_image->m_d->isolationRootNode = m_node; emit m_image->sigIsolatedModeChanged(); const bool afterVisibility = m_node->projectionLeaf()->visible(); m_needsFullRefresh = (beforeVisibility != afterVisibility); } void finishStrokeCallback() override { // the GUI uses our thread to do the color space conversion so we // need to emit this signal in multiple threads if (m_needsFullRefresh) { m_image->refreshGraphAsync(m_node); } else { QVector jobs; m_image->m_d->notifyProjectionUpdatedInPatches(m_image->bounds(), jobs); this->runnableJobsInterface()->addRunnableJobs(jobs); } m_image->invalidateAllFrames(); } private: KisNodeSP m_node; KisImageSP m_image; bool m_needsFullRefresh; - IsolationMode m_mode; + bool m_isolateLayer; + bool m_isolateGroup; }; - KisStrokeId id = startStroke(new StartIsolatedModeStroke(node, this, mode)); + KisStrokeId id = startStroke(new StartIsolatedModeStroke(node, this, isolateLayer, isolateGroup)); endStroke(id); return true; } void KisImage::stopIsolatedMode() { if (!m_d->isolationRootNode) return; struct StopIsolatedModeStroke : public KisRunnableBasedStrokeStrategy { StopIsolatedModeStroke(KisImageSP image) : KisRunnableBasedStrokeStrategy(QLatin1String("stop-isolated-mode"), kundo2_noi18n("stop-isolated-mode")), m_image(image), m_oldRootNode(nullptr), m_oldNodeNeedsRefresh(false) { this->enableJob(JOB_INIT); this->enableJob(JOB_DOSTROKE, true); this->enableJob(JOB_FINISH, true, KisStrokeJobData::BARRIER); setClearsRedoOnStart(false); } void initStrokeCallback() { if (!m_image->m_d->isolationRootNode) return; m_oldRootNode = m_image->m_d->isolationRootNode; const bool beforeVisibility = m_oldRootNode->projectionLeaf()->visible(); m_image->m_d->isolationRootNode = 0; - m_image->m_d->currentIsolationMode = ISOLATE_OFF; + m_image->m_d->isolateLayer = false; + m_image->m_d->isolateGroup = false; emit m_image->sigIsolatedModeChanged(); const bool afterVisibility = m_oldRootNode->projectionLeaf()->visible(); m_oldNodeNeedsRefresh = (beforeVisibility != afterVisibility); } void finishStrokeCallback() override { m_image->invalidateAllFrames(); if (m_oldNodeNeedsRefresh){ m_oldRootNode->setDirty(m_image->bounds()); } else { // TODO: Substitute notifyProjectionUpdated() with this code // when update optimization is implemented // // QRect updateRect = bounds() | oldRootNode->extent(); //oldRootNode->setDirty(updateRect); QVector jobs; m_image->m_d->notifyProjectionUpdatedInPatches(m_image->bounds(), jobs); this->runnableJobsInterface()->addRunnableJobs(jobs); } } private: KisImageSP m_image; KisNodeSP m_oldRootNode; bool m_oldNodeNeedsRefresh; }; KisStrokeId id = startStroke(new StopIsolatedModeStroke(this)); endStroke(id); } -KisNodeSP KisImage::isolationRootNode() const -{ +KisNodeSP KisImage::isolationRootNode() const { return m_d->isolationRootNode; } -KisImage::IsolationMode KisImage::currentIsolationMode() const +bool KisImage::isIsolatingLayer() const +{ + return m_d->isolateLayer; +} + +bool KisImage::isIsolatingGroup() const { - return m_d->currentIsolationMode; + return m_d->isolateGroup; } 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) { requestProjectionUpdateNoFilthy(pseudoFilthy, rc, cropRect, true); } void KisImage::requestProjectionUpdateNoFilthy(KisNodeSP pseudoFilthy, const QRect &rc, const QRect &cropRect, const bool resetAnimationCache) { KIS_ASSERT_RECOVER_RETURN(pseudoFilthy); if (resetAnimationCache) { 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); } bool KisImage::hasUpdatesRunning() const { return m_d->scheduler.hasUpdatesRunning(); } KisProjectionUpdatesFilterCookie KisImage::addProjectionUpdatesFilter(KisProjectionUpdatesFilterSP filter) { KIS_SAFE_ASSERT_RECOVER_RETURN_VALUE(filter, KisProjectionUpdatesFilterCookie()); m_d->projectionUpdatesFilters.append(filter); return KisProjectionUpdatesFilterCookie(filter.data()); } KisProjectionUpdatesFilterSP KisImage::removeProjectionUpdatesFilter(KisProjectionUpdatesFilterCookie cookie) { KIS_SAFE_ASSERT_RECOVER_NOOP(cookie); KIS_SAFE_ASSERT_RECOVER_NOOP(m_d->projectionUpdatesFilters.last() == cookie); auto it = std::find(m_d->projectionUpdatesFilters.begin(), m_d->projectionUpdatesFilters.end(), cookie); KIS_SAFE_ASSERT_RECOVER_RETURN_VALUE(it != m_d->projectionUpdatesFilters.end(), KisProjectionUpdatesFilterSP()); KisProjectionUpdatesFilterSP filter = *it; m_d->projectionUpdatesFilters.erase(it); return filter; } KisProjectionUpdatesFilterCookie KisImage::currentProjectionUpdatesFilter() const { return !m_d->projectionUpdatesFilters.isEmpty() ? m_d->projectionUpdatesFilters.last().data() : KisProjectionUpdatesFilterCookie(); } void KisImage::disableDirtyRequests() { m_d->disabledUpdatesCookies.push( addProjectionUpdatesFilter(toQShared(new KisDropAllProjectionUpdatesFilter()))); } void KisImage::enableDirtyRequests() { KIS_SAFE_ASSERT_RECOVER_RETURN(!m_d->disabledUpdatesCookies.isEmpty()); removeProjectionUpdatesFilter(m_d->disabledUpdatesCookies.pop()); } void KisImage::disableUIUpdates() { m_d->disableUIUpdateSignals.ref(); } void KisImage::notifyBatchUpdateStarted() { m_d->signalRouter.emitNotifyBatchUpdateStarted(); } void KisImage::notifyBatchUpdateEnded() { m_d->signalRouter.emitNotifyBatchUpdateEnded(); } void KisImage::notifyUIUpdateCompleted(const QRect &rc) { notifyProjectionUpdated(rc); } QVector KisImage::enableUIUpdates() { m_d->disableUIUpdateSignals.deref(); QRect rect; QVector postponedUpdates; while (m_d->savedDisabledUIUpdates.pop(rect)) { postponedUpdates.append(rect); } return postponedUpdates; } 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); } else { m_d->savedDisabledUIUpdates.push(rc); } } 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 asynchronously, 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->isolationRootNode && dynamic_cast(m_d->isolationRootNode.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) { /** * We iterate through the filters in a reversed way. It makes the most nested filters * to execute first. */ for (auto it = m_d->projectionUpdatesFilters.rbegin(); it != m_d->projectionUpdatesFilters.rend(); ++it) { KIS_SAFE_ASSERT_RECOVER(*it) { continue; } if ((*it)->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); } KisNode *KisImage::graphOverlayNode() const { return m_d->overlaySelectionMask.data(); } 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::nodeCollapsedChanged(KisNode * node) { Q_UNUSED(node); 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 KisProofingConfigurationSP(); } QPointF KisImage::mirrorAxesCenter() const { return m_d->axesCenter; } void KisImage::setMirrorAxesCenter(const QPointF &value) const { m_d->axesCenter = value; } void KisImage::setAllowMasksOnRootNode(bool value) { m_d->allowMasksOnRootNode = value; } bool KisImage::allowMasksOnRootNode() const { return m_d->allowMasksOnRootNode; } diff --git a/libs/image/kis_image.h b/libs/image/kis_image.h index 7186a0d25b..02f4d089e5 100644 --- a/libs/image/kis_image.h +++ b/libs/image/kis_image.h @@ -1,1254 +1,1248 @@ /* * 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. */ #ifndef KIS_IMAGE_H_ #define KIS_IMAGE_H_ #include #include #include #include #include #include #include "kis_types.h" #include "kis_shared.h" #include "kis_node_graph_listener.h" #include "kis_node_facade.h" #include "kis_image_interfaces.h" #include "kis_strokes_queue_undo_result.h" #include class KoColorSpace; class KoColor; class KisCompositeProgressProxy; class KisUndoStore; class KisUndoAdapter; class KisImageSignalRouter; class KisPostExecutionUndoAdapter; class KisFilterStrategy; class KoColorProfile; class KisLayerComposition; class KisSpontaneousJob; class KisImageAnimationInterface; class KUndo2MagicString; class KisProofingConfiguration; class KisPaintDevice; namespace KisMetaData { class MergeStrategy; } /** * This is the image class, it contains a tree of KisLayer stack and * meta information about the image. And it also provides some * functions to manipulate the whole image. */ class KRITAIMAGE_EXPORT KisImage : public QObject, public KisStrokesFacade, public KisStrokeUndoFacade, public KisUpdatesFacade, public KisProjectionUpdateListener, public KisNodeFacade, public KisNodeGraphListener, public KisShared { Q_OBJECT public: - enum IsolationMode { - ISOLATE_OFF, - ISOLATE_LAYER, - ISOLATE_GROUP - }; - - /// @p colorSpace can be null. In that case, it will be initialised to a default color space. KisImage(KisUndoStore *undoStore, qint32 width, qint32 height, const KoColorSpace *colorSpace, const QString& name); ~KisImage() override; static KisImageSP fromQImage(const QImage &image, KisUndoStore *undoStore); public: // KisNodeGraphListener implementation void aboutToAddANode(KisNode *parent, int index) override; void nodeHasBeenAdded(KisNode *parent, int index) override; void aboutToRemoveANode(KisNode *parent, int index) override; void nodeChanged(KisNode * node) override; void nodeCollapsedChanged(KisNode *node) override; void invalidateAllFrames() override; void notifySelectionChanged() override; void requestProjectionUpdate(KisNode *node, const QVector &rects, bool resetAnimationCache) override; void invalidateFrames(const KisTimeRange &range, const QRect &rect) override; void requestTimeSwitch(int time) override; KisNode* graphOverlayNode() const override; public: // KisProjectionUpdateListener implementation void notifyProjectionUpdated(const QRect &rc) override; public: /** * Set the number of threads used by the image's working threads */ void setWorkingThreadsLimit(int value); /** * Return the number of threads available to the image's working threads */ int workingThreadsLimit() const; /** * Makes a copy of the image with all the layers. If possible, shallow * copies of the layers are made. * * \p exactCopy shows if the copied image should look *exactly* the same as * the other one (according to it's .kra xml representation). It means that * the layers will have the same UUID keys and, therefore, you are not * expected to use the copied image anywhere except for saving. Don't use * this option if you plan to work with the copied image later. */ KisImage *clone(bool exactCopy = false); void copyFromImage(const KisImage &rhs); private: // must specify exactly one from CONSTRUCT or REPLACE. enum CopyPolicy { CONSTRUCT = 1, ///< we are copy-constructing a new KisImage REPLACE = 2, ///< we are replacing the current KisImage with another EXACT_COPY = 4, /// we need an exact copy of the original image }; void copyFromImageImpl(const KisImage &rhs, int policy); public: /** * Render the projection onto a QImage. */ QImage convertToQImage(qint32 x1, qint32 y1, qint32 width, qint32 height, const KoColorProfile * profile); /** * Render the projection onto a QImage. * (this is an overloaded function) */ QImage convertToQImage(QRect imageRect, const KoColorProfile * profile); /** * Render a thumbnail of the projection onto a QImage. */ QImage convertToQImage(const QSize& scaledImageSize, const KoColorProfile *profile); /** * [low-level] Lock the image without waiting for all the internal job queues are processed * * WARNING: Don't use it unless you really know what you are doing! Use barrierLock() instead! * * Waits for all the **currently running** internal jobs to complete and locks the image * for writing. Please note that this function does **not** wait for all the internal * queues to process, so there might be some non-finished actions pending. It means that * you just postpone these actions until you unlock() the image back. Until then, then image * might easily be frozen in some inconsistent state. * * The only sane usage for this function is to lock the image for **emergency** * processing, when some internal action or scheduler got hung up, and you just want * to fetch some data from the image without races. * * In all other cases, please use barrierLock() instead! */ void lock(); /** * Unlocks the image and starts/resumes all the pending internal jobs. If the image * has been locked for a non-readOnly access, then all the internal caches of the image * (e.g. lod-planes) are reset and regeneration jobs are scheduled. */ void unlock(); /** * @return return true if the image is in a locked state, i.e. all the internal * jobs are blocked from execution by calling wither lock() or barrierLock(). * * When the image is locked, the user can do some modifications to the image * contents safely without a perspective having race conditions with internal * image jobs. */ bool locked() const; /** * Sets the mask (it must be a part of the node hierarchy already) to be paited on * the top of all layers. This method does all the locking and syncing for you. It * is executed asynchronously. */ void setOverlaySelectionMask(KisSelectionMaskSP mask); /** * \see setOverlaySelectionMask */ KisSelectionMaskSP overlaySelectionMask() const; /** * \see setOverlaySelectionMask */ bool hasOverlaySelectionMask() const; /** * @return the global selection object or 0 if there is none. The * global selection is always read-write. */ KisSelectionSP globalSelection() const; /** * Retrieve the next automatic layername (XXX: fix to add option to return Mask X) */ QString nextLayerName(const QString &baseName = "") const; /** * Set the automatic layer name counter one back. */ void rollBackLayerName(); /** * @brief start asynchronous operation on resizing the image * * The method will resize the image to fit the new size without * dropping any pixel data. The GUI will get correct * notification with old and new sizes, so it adjust canvas origin * accordingly and avoid jumping of the canvas on screen * * @param newRect the rectangle of the image which will be visible * after operation is completed * * Please note that the actual operation starts asynchronously in * a background, so you cannot expect the image having new size * right after this call. */ void resizeImage(const QRect& newRect); /** * @brief start asynchronous operation on cropping the image * * The method will **drop** all the image data outside \p newRect * and resize the image to fit the new size. The GUI will get correct * notification with old and new sizes, so it adjust canvas origin * accordingly and avoid jumping of the canvas on screen * * @param newRect the rectangle of the image which will be cut-out * * Please note that the actual operation starts asynchronously in * a background, so you cannot expect the image having new size * right after this call. */ void cropImage(const QRect& newRect); /** * @brief purge all pixels that have default pixel to free up memory * @param isCancellable if true, the scheduler is allower to stop and * cancel purging operation as soon as the user starts any action. * If \p isCancellable is false, then the user will not be allowed to do * anything until purging operation is completed. */ void purgeUnusedData(bool isCancellable); /** * @brief start asynchronous operation on cropping a subtree of nodes starting at \p node * * The method will **drop** all the layer data outside \p newRect. Neither * image nor a layer will be moved anywhere * * @param node node to crop * @param newRect the rectangle of the layer which will be cut-out * * Please note that the actual operation starts asynchronously in * a background, so you cannot expect the image having new size * right after this call. */ void cropNode(KisNodeSP node, const QRect& newRect); /** * @brief start asynchronous operation on scaling the image * @param size new image size in pixels * @param xres new image x-resolution pixels-per-pt * @param yres new image y-resolution pixels-per-pt * @param filterStrategy filtering strategy * * Please note that the actual operation starts asynchronously in * a background, so you cannot expect the image having new size * right after this call. */ void scaleImage(const QSize &size, qreal xres, qreal yres, KisFilterStrategy *filterStrategy); /** * @brief start asynchronous operation on scaling a subtree of nodes starting at \p node * @param node node to scale * @param center the center of the scaling * @param scaleX x-scale coefficient to be applied to the node * @param scaleY y-scale coefficient to be applied to the node * @param filterStrategy filtering strategy * @param selection the selection we based on * * Please note that the actual operation starts asynchronously in * a background, so you cannot expect the image having new size * right after this call. */ void scaleNode(KisNodeSP node, const QPointF ¢er, qreal scaleX, qreal scaleY, KisFilterStrategy *filterStrategy, KisSelectionSP selection); /** * @brief start asynchronous operation on rotating the image * * The image is resized to fit the rotated rectangle * * @param radians rotation angle in radians * * Please note that the actual operation starts asynchronously in * a background, so you cannot expect the operation being completed * right after the call */ void rotateImage(double radians); /** * @brief start asynchronous operation on rotating a subtree of nodes starting at \p node * * The image is not resized! * * @param node the root of the subtree to rotate * @param radians rotation angle in radians * @param selection the selection we based on * * Please note that the actual operation starts asynchronously in * a background, so you cannot expect the operation being completed * right after the call */ void rotateNode(KisNodeSP node, double radians, KisSelectionSP selection); /** * @brief start asynchronous operation on shearing the image * * The image is resized to fit the sheared polygon * * @p angleX, @p angleY are given in degrees. * * Please note that the actual operation starts asynchronously in * a background, so you cannot expect the operation being completed * right after the call */ void shear(double angleX, double angleY); /** * @brief start asynchronous operation on shearing a subtree of nodes starting at \p node * * The image is not resized! * * @param node the root of the subtree to rotate * @param angleX x-shear given in degrees. * @param angleY y-shear given in degrees. * @param selection the selection we based on * * Please note that the actual operation starts asynchronously in * a background, so you cannot expect the operation being completed * right after the call */ void shearNode(KisNodeSP node, double angleX, double angleY, KisSelectionSP selection); /** * Convert image projection to \p dstColorSpace, keeping all the layers intouched. */ void convertImageProjectionColorSpace(const KoColorSpace *dstColorSpace); /** * Convert the image and all its layers to the dstColorSpace */ void convertImageColorSpace(const KoColorSpace *dstColorSpace, KoColorConversionTransformation::Intent renderingIntent, KoColorConversionTransformation::ConversionFlags conversionFlags); /** * Convert layer and all its child layers to dstColorSpace */ void convertLayerColorSpace(KisNodeSP node, const KoColorSpace *dstColorSpace, KoColorConversionTransformation::Intent renderingIntent, KoColorConversionTransformation::ConversionFlags conversionFlags); // Get the profile associated with this image const KoColorProfile * profile() const; /** * Set the profile of the layer and all its children to the new profile. * It doesn't do any pixel conversion. * * This is essential if you have loaded an image that didn't * have an embedded profile to which you want to attach the right profile. * * @returns false if the profile could not be assigned */ bool assignLayerProfile(KisNodeSP node, const KoColorProfile *profile); /** * Set the profile of the image to the new profile and do the same for * all layers that have the same colorspace and profile of the image. * It doesn't do any pixel conversion. * * This is essential if you have loaded an image that didn't * have an embedded profile to which you want to attach the right profile. * * @returns false if the profile could not be assigned */ bool assignImageProfile(const KoColorProfile *profile, bool blockAllUpdates = false); /** * Returns the current undo adapter. You can add new commands to the * undo stack using the adapter. This adapter is used for a backward * compatibility for old commands created before strokes. It blocks * all the porcessing at the scheduler, waits until it's finished * and executes commands exclusively. */ KisUndoAdapter* undoAdapter() const; /** * This adapter is used by the strokes system. The commands are added * to it *after* redo() is done (in the scheduler context). They are * wrapped into a special command and added to the undo stack. redo() * in not called. */ KisPostExecutionUndoAdapter* postExecutionUndoAdapter() const override; /** * Return the lastly executed LoD0 command. It is effectively the same * as to call undoAdapter()->presentCommand(); */ const KUndo2Command* lastExecutedCommand() const override; /** * Replace current undo store with the new one. The old store * will be deleted. * This method is used by KisDocument for dropping all the commands * during file loading. */ void setUndoStore(KisUndoStore *undoStore); /** * Return current undo store of the image */ KisUndoStore* undoStore(); /** * Tell the image it's modified; this emits the sigImageModified * signal. This happens when the image needs to be saved */ void setModified(); /** * The default colorspace of this image: new layers will have this * colorspace and the projection will have this colorspace. */ const KoColorSpace * colorSpace() const; /** * X resolution in pixels per pt */ double xRes() const; /** * Y resolution in pixels per pt */ double yRes() const; /** * Set the resolution in pixels per pt. */ void setResolution(double xres, double yres); /** * Convert a document coordinate to a pixel coordinate. * * @param documentCoord PostScript Pt coordinate to convert. */ QPointF documentToPixel(const QPointF &documentCoord) const; /** * Convert a document coordinate to an integer pixel coordinate rounded down. * * @param documentCoord PostScript Pt coordinate to convert. */ QPoint documentToImagePixelFloored(const QPointF &documentCoord) const; /** * Convert a document rectangle to a pixel rectangle. * * @param documentRect PostScript Pt rectangle to convert. */ QRectF documentToPixel(const QRectF &documentRect) const; /** * Convert a pixel coordinate to a document coordinate. * * @param pixelCoord pixel coordinate to convert. */ QPointF pixelToDocument(const QPointF &pixelCoord) const; /** * Convert an integer pixel coordinate to a document coordinate. * The document coordinate is at the centre of the pixel. * * @param pixelCoord pixel coordinate to convert. */ QPointF pixelToDocument(const QPoint &pixelCoord) const; /** * Convert a document rectangle to an integer pixel rectangle. * * @param pixelCoord pixel coordinate to convert. */ QRectF pixelToDocument(const QRectF &pixelCoord) const; /** * Return the width of the image */ qint32 width() const; /** * Return the height of the image */ qint32 height() const; /** * Return the size of the image */ QSize size() const { return QSize(width(), height()); } /** * @return the root node of the image node graph */ KisGroupLayerSP rootLayer() const; /** * Return the projection; that is, the complete, composited * representation of this image. */ KisPaintDeviceSP projection() const; /** * Return the number of layers (not other nodes) that are in this * image. */ qint32 nlayers() const; /** * Return the number of layers (not other node types) that are in * this image and that are hidden. */ qint32 nHiddenLayers() const; /** * Merge all visible layers and discard hidden ones. */ void flatten(KisNodeSP activeNode); /** * Merge the specified layer with the layer * below this layer, remove the specified layer. */ void mergeDown(KisLayerSP l, const KisMetaData::MergeStrategy* strategy); /** * flatten the layer: that is, the projection becomes the layer * and all subnodes are removed. If this is not a paint layer, it will morph * into a paint layer. */ void flattenLayer(KisLayerSP layer); /** * Merges layers in \p mergedLayers and creates a new layer above * \p putAfter */ void mergeMultipleLayers(QList mergedLayers, KisNodeSP putAfter); /// @return the exact bounds of the image in pixel coordinates. QRect bounds() const override; /** * Returns the actual bounds of the image, taking LevelOfDetail * into account. This value is used as a bounds() value of * KisDefaultBounds object. */ QRect effectiveLodBounds() const; /// use if the layers have changed _completely_ (eg. when flattening) void notifyLayersChanged(); /** * Sets the default color of the root layer projection. All the layers * will be merged on top of this very color */ void setDefaultProjectionColor(const KoColor &color); /** * \see setDefaultProjectionColor() */ KoColor defaultProjectionColor() const; void setRootLayer(KisGroupLayerSP rootLayer); /** * Add an annotation for this image. This can be anything: Gamma, EXIF, etc. * Note that the "icc" annotation is reserved for the color strategies. * If the annotation already exists, overwrite it with this one. */ void addAnnotation(KisAnnotationSP annotation); /** get the annotation with the given type, can return 0 */ KisAnnotationSP annotation(const QString& type); /** delete the annotation, if the image contains it */ void removeAnnotation(const QString& type); /** * Start of an iteration over the annotations of this image (including the ICC Profile) */ vKisAnnotationSP_it beginAnnotations(); /** end of an iteration over the annotations of this image */ vKisAnnotationSP_it endAnnotations(); /** * Called before the image is deleted and sends the sigAboutToBeDeleted signal */ void notifyAboutToBeDeleted(); KisImageSignalRouter* signalRouter(); /** * Returns whether we can reselect current global selection * * \see reselectGlobalSelection() */ bool canReselectGlobalSelection(); /** * Returns the layer compositions for the image */ QList compositions(); /** * Adds a new layer composition, will be saved with the image */ void addComposition(KisLayerCompositionSP composition); /** * Remove the layer compostion */ void removeComposition(KisLayerCompositionSP composition); /** * Permit or deny the wrap-around mode for all the paint devices * of the image. Note that permitting the wraparound mode will not * necessarily activate it right now. To be activated the wrap * around mode should be 1) permitted; 2) supported by the * currently running stroke. */ void setWrapAroundModePermitted(bool value); /** * \return whether the wrap-around mode is permitted for this * image. If the wrap around mode is permitted and the * currently running stroke supports it, the mode will be * activated for all paint devices of the image. * * \see setWrapAroundMode */ bool wrapAroundModePermitted() const; /** * \return whether the wraparound mode is activated for all the * devices of the image. The mode is activated when both * factors are true: the user permitted it and the stroke * supports it */ bool wrapAroundModeActive() const; /** * \return current level of detail which is used when processing the image. * Current working zoom = 2 ^ (- currentLevelOfDetail()). Default value is * null, which means we work on the original image. */ int currentLevelOfDetail() const; /** * Notify KisImage which level of detail should be used in the * lod-mode. Setting the mode does not guarantee the LOD to be * used. It will be activated only when the stokes supports it. */ void setDesiredLevelOfDetail(int lod); /** * Relative position of the mirror axis center * 0,0 - topleft corner of the image * 1,1 - bottomright corner of the image */ QPointF mirrorAxesCenter() const; /** * Sets the relative position of the axes center * \see mirrorAxesCenter() for details */ void setMirrorAxesCenter(const QPointF &value) const; /** * Configure the image to allow masks on the root not (as reported by * root()->allowAsChild()). By default it is not allowed (because it * looks weird from GUI point of view) */ void setAllowMasksOnRootNode(bool value); /** * \see setAllowMasksOnRootNode() */ bool allowMasksOnRootNode() const; public Q_SLOTS: /** * Explicitly start regeneration of LoD planes of all the devices * in the image. This call should be performed when the user is idle, * just to make the quality of image updates better. */ void explicitRegenerateLevelOfDetail(); public: /** * Blocks usage of level of detail functionality. After this method * has been called, no new strokes will use LoD. */ void setLevelOfDetailBlocked(bool value); /** * \see setLevelOfDetailBlocked() */ bool levelOfDetailBlocked() const; KisImageAnimationInterface *animationInterface() const; /** * @brief setProofingConfiguration, this sets the image's proofing configuration, and signals * the proofingConfiguration has changed. * @param proofingConfig - the kis proofing config that will be used instead. */ void setProofingConfiguration(KisProofingConfigurationSP proofingConfig); /** * @brief proofingConfiguration * @return the proofing configuration of the image. */ KisProofingConfigurationSP proofingConfiguration() const; public Q_SLOTS: - bool startIsolatedMode(KisNodeSP node, IsolationMode mode = ISOLATE_LAYER); + bool startIsolatedMode(KisNodeSP node, bool isolateLayer, bool isolateGroup); void stopIsolatedMode(); public: KisNodeSP isolationRootNode() const; - IsolationMode currentIsolationMode() const; + bool isIsolatingLayer() const; + bool isIsolatingGroup() const; Q_SIGNALS: /** * Emitted whenever an action has caused the image to be * recomposited. Parameter is the rect that has been recomposited. */ void sigImageUpdated(const QRect &); /** Emitted whenever the image has been modified, so that it doesn't match with the version saved on disk. */ void sigImageModified(); /** * The signal is emitted when the size of the image is changed. * \p oldStillPoint and \p newStillPoint give the receiver the * hint about how the new and old rect of the image correspond to * each other. They specify the point of the image around which * the conversion was done. This point will stay still on the * user's screen. That is the \p newStillPoint of the new image * will be painted at the same screen position, where \p * oldStillPoint of the old image was painted. * * \param oldStillPoint is a still point represented in *old* * image coordinates * * \param newStillPoint is a still point represented in *new* * image coordinates */ void sigSizeChanged(const QPointF &oldStillPoint, const QPointF &newStillPoint); void sigProfileChanged(const KoColorProfile * profile); void sigColorSpaceChanged(const KoColorSpace* cs); void sigResolutionChanged(double xRes, double yRes); void sigRequestNodeReselection(KisNodeSP activeNode, const KisNodeList &selectedNodes); /** * Inform the model that a node was changed */ void sigNodeChanged(KisNodeSP node); /** * Inform that the image is going to be deleted */ void sigAboutToBeDeleted(); /** * The signal is emitted right after a node has been connected * to the graph of the nodes. * * WARNING: you must not request any graph-related information * about the node being run in a not-scheduler thread. If you need * information about the parent/siblings of the node connect * with Qt::DirectConnection, get needed information and then * emit another Qt::AutoConnection signal to pass this information * to your thread. See details of the implementation * in KisDummiesfacadeBase. */ void sigNodeAddedAsync(KisNodeSP node); /** * This signal is emitted right before a node is going to removed * from the graph of the nodes. * * WARNING: you must not request any graph-related information * about the node being run in a not-scheduler thread. * * \see comment in sigNodeAddedAsync() */ void sigRemoveNodeAsync(KisNodeSP node); /** * Emitted when the root node of the image has changed. * It happens, e.g. when we flatten the image. When * this happens the receiver should reload information * about the image */ void sigLayersChangedAsync(); /** * Emitted when the UI has requested the undo of the last stroke's * operation. The point is, we cannot deal with the internals of * the stroke without its creator knowing about it (which most * probably cause a crash), so we just forward this request from * the UI to the creator of the stroke. * * If your tool supports undoing part of its work, just listen to * this signal and undo when it comes */ void sigUndoDuringStrokeRequested(); /** * Emitted when the UI has requested the cancellation of * the stroke. The point is, we cannot cancel the stroke * without its creator knowing about it (which most probably * cause a crash), so we just forward this request from the UI * to the creator of the stroke. * * If your tool supports cancelling of its work in the middle * of operation, just listen to this signal and cancel * the stroke when it comes */ void sigStrokeCancellationRequested(); /** * Emitted when the image decides that the stroke should better * be ended. The point is, we cannot just end the stroke * without its creator knowing about it (which most probably * cause a crash), so we just forward this request from the UI * to the creator of the stroke. * * If your tool supports long strokes that may involve multiple * mouse actions in one stroke, just listen to this signal and * end the stroke when it comes. */ void sigStrokeEndRequested(); /** * Same as sigStrokeEndRequested() but is not emitted when the active node * is changed. */ void sigStrokeEndRequestedActiveNodeFiltered(); /** * Emitted when the isolated mode status has changed. * * Can be used by the receivers to catch a fact of forcefully * stopping the isolated mode by the image when some complex * action was requested */ void sigIsolatedModeChanged(); /** * Emitted when one or more nodes changed the collapsed state * */ void sigNodeCollapsedChanged(); /** * Emitted when the proofing configuration of the image is being changed. * */ void sigProofingConfigChanged(); /** * Internal signal for asynchronously requesting isolated mode to stop. Don't use it * outside KisImage, use sigIsolatedModeChanged() instead. */ void sigInternalStopIsolatedModeRequested(); public Q_SLOTS: KisCompositeProgressProxy* compositeProgressProxy(); bool isIdle(bool allowLocked = false); /** * @brief Wait until all the queued background jobs are completed and lock the image. * * KisImage object has a local scheduler that executes long-running image * rendering/modifying jobs (we call them "strokes") in a background. Basically, * one should either access the image from the scope of such jobs (strokes) or * just lock the image before using. * * Calling barrierLock() will wait until all the queued operations are finished * and lock the image, so you can start accessing it in a safe way. * * @p readOnly tells the image if the caller is going to modify the image during * holding the lock. Locking with non-readOnly access will reset all * the internal caches of the image (lod-planes) when the lock status * will be lifted. */ void barrierLock(bool readOnly = false); /** * @brief Tries to lock the image without waiting for the jobs to finish * * Same as barrierLock(), but doesn't block execution of the calling thread * until all the background jobs are finished. Instead, in case of presence of * unfinished jobs in the queue, it just returns false * * @return whether the lock has been acquired * @see barrierLock */ bool tryBarrierLock(bool readOnly = false); /** * Wait for all the internal image jobs to complete and return without locking * the image. This function is handly for tests or other synchronous actions, * when one needs to wait for the result of his actions. */ void waitForDone(); KisStrokeId startStroke(KisStrokeStrategy *strokeStrategy) override; void addJob(KisStrokeId id, KisStrokeJobData *data) override; void endStroke(KisStrokeId id) override; bool cancelStroke(KisStrokeId id) override; /** * @brief blockUpdates block updating the image projection */ void blockUpdates() override; /** * @brief unblockUpdates unblock updating the image project. This * only restarts the scheduler and does not schedule a full refresh. */ void unblockUpdates() override; /** * Disables notification of the UI about the changes in the image. * This feature is used by KisProcessingApplicator. It is needed * when we change the size of the image. In this case, the whole * image will be reloaded into UI by sigSizeChanged(), so there is * no need to inform the UI about individual dirty rects. * * The last call to enableUIUpdates() will return the list of updates * that were requested while they were blocked. */ void disableUIUpdates() override; /** * Notify GUI about a bunch of updates planned. GUI is expected to wait * until all the updates are completed, and render them on screen only * in the very and of the batch. */ void notifyBatchUpdateStarted() override; /** * Notify GUI that batch update has been completed. Now GUI can start * showing all of them on screen. */ void notifyBatchUpdateEnded() override; /** * Notify GUI that rect \p rc is now prepared in the image and * GUI can read data from it. * * WARNING: GUI will read the data right in the handler of this * signal, so exclusive access to the area must be guaranteed * by the caller. */ void notifyUIUpdateCompleted(const QRect &rc) override; /** * \see disableUIUpdates */ QVector enableUIUpdates() override; /** * Disables the processing of all the setDirty() requests that * come to the image. The incoming requests are effectively * *dropped*. * * This feature is used by KisProcessingApplicator. For many cases * it provides its own updates interface, which recalculates the * whole subtree of nodes. But while we change any particular * node, it can ask for an update itself. This method is a way of * blocking such intermediate (and excessive) requests. * * NOTE: this is a convenience function for addProjectionUpdatesFilter() * that installs a predefined filter that eats everything. Please * note that these calls are *not* recursive. * * WARNING: The calls to enable/disable must be balanced. */ void disableDirtyRequests() override; /** * \see disableDirtyRequests() */ void enableDirtyRequests() override; /** * Installs a filter object that will filter all the incoming projection update * requests. If the filter return true, the incoming update is dropped. * * NOTE: you can add multiple filters to the image, **but** the calls to add/remove * must be nested and balanced. E.g. * * \code{.cpp} * * auto cookie1 = image->addProjectionUpdatesFilter(filter1); * auto cookie2 = image->addProjectionUpdatesFilter(filter2); * * /// ...do something... * * /// correct: * image->removeProjectionUpdatesFilter(cookie2) * image->removeProjectionUpdatesFilter(cookie1) * * /// incorrect: * // image->removeProjectionUpdatesFilter(cookie1) * // image->removeProjectionUpdatesFilter(cookie2) * \endcode */ KisProjectionUpdatesFilterCookie addProjectionUpdatesFilter(KisProjectionUpdatesFilterSP filter) override; /** * @brief removes already installed filter from the stack of updates filers * @param cookie a cookie object returned by addProjectionUpdatesFilter() on intallation * @return the installed filter. If the cookie is invalid, or nesting rule has been * broken, then removeProjectionUpdatesFilter() may safe-assert and return nullptr. * * NOTE: some weird code (e.g. KisRegenerateFrameStrokeStrategy) needs to temporary remove * all the filters and then install them back. Current implementation ensures that after removal * and the following installation, cookies will be preserved. So this operation is considered * safe. * * \see addProjectionUpdatesFilter() */ KisProjectionUpdatesFilterSP removeProjectionUpdatesFilter(KisProjectionUpdatesFilterCookie cookie) override; /** * Return the cookie of the lastly-installed filter * * \see addProjectionUpdatesFilter() */ KisProjectionUpdatesFilterCookie currentProjectionUpdatesFilter() const override; void refreshGraphAsync(KisNodeSP root = KisNodeSP()) override; void refreshGraphAsync(KisNodeSP root, const QRect &rc) override; void refreshGraphAsync(KisNodeSP root, const QRect &rc, const QRect &cropRect) override; /** * Triggers synchronous recomposition of the projection */ void refreshGraph(KisNodeSP root = KisNodeSP()); void refreshGraph(KisNodeSP root, const QRect& rc, const QRect &cropRect); void initialRefreshGraph(); /** * Initiate a stack regeneration skipping the recalculation of the * filthy node's projection. * * Works exactly as pseudoFilthy->setDirty() with the only * exception that pseudoFilthy::updateProjection() will not be * called. That is used by KisRecalculateTransformMaskJob to avoid * cyclic dependencies. */ void requestProjectionUpdateNoFilthy(KisNodeSP pseudoFilthy, const QRect &rc, const QRect &cropRect); void requestProjectionUpdateNoFilthy(KisNodeSP pseudoFilthy, const QRect &rc, const QRect &cropRect, const bool notifyFrameChange ); /** * Adds a spontaneous job to the updates queue. * * A spontaneous job may do some trivial tasks in the background, * like updating the outline of selection or purging unused tiles * from the existing paint devices. */ void addSpontaneousJob(KisSpontaneousJob *spontaneousJob); /** * \return true if there are some updates in the updates queue * Please note, that is doesn't guarantee that there are no updates * running in in the updater context at the very moment. To guarantee that * there are no updates left at all, please use barrier jobs instead. */ bool hasUpdatesRunning() const override; /** * This method is called by the UI (*not* by the creator of the * stroke) when it thinks the current stroke should undo its last * action, for example, when the user presses Ctrl+Z while some * stroke is active. * * If the creator of the stroke supports undoing of intermediate * actions, it will be notified about this request and can undo * its last action. */ void requestUndoDuringStroke(); /** * This method is called by the UI (*not* by the creator of the * stroke) when it thinks current stroke should be cancelled. If * there is a running stroke that has already been detached from * its creator (ended or cancelled), it will be forcefully * cancelled and reverted. If there is an open stroke present, and * if its creator supports cancelling, it will be notified about * the request and the stroke will be cancelled */ void requestStrokeCancellation(); /** * This method requests the last stroke executed on the image to become undone. * If the stroke is not ended, or if all the Lod0 strokes are completed, the method * returns UNDO_FAIL. If the last Lod0 is going to be finished soon, then UNDO_WAIT * is returned and the caller should just wait for its completion and call global undo * instead. UNDO_OK means one unfinished stroke has been undone. */ UndoResult tryUndoUnfinishedLod0Stroke(); /** * This method is called when image or some other part of Krita * (*not* the creator of the stroke) decides that the stroke * should be ended. If the creator of the stroke supports it, it * will be notified and the stroke will be cancelled */ void requestStrokeEnd(); /** * Same as requestStrokeEnd() but is called by view manager when * the current node is changed. Use to distinguish * sigStrokeEndRequested() and * sigStrokeEndRequestedActiveNodeFiltered() which are used by * KisNodeJugglerCompressed */ void requestStrokeEndActiveNode(); private: KisImage(const KisImage& rhs, KisUndoStore *undoStore, bool exactCopy); KisImage& operator=(const KisImage& rhs); void emitSizeChanged(); void resizeImageImpl(const QRect& newRect, bool cropLayers); void rotateImpl(const KUndo2MagicString &actionName, KisNodeSP rootNode, double radians, bool resizeImage, KisSelectionSP selection); void shearImpl(const KUndo2MagicString &actionName, KisNodeSP rootNode, bool resizeImage, double angleX, double angleY, KisSelectionSP selection); void safeRemoveTwoNodes(KisNodeSP node1, KisNodeSP node2); void refreshHiddenArea(KisNodeSP rootNode, const QRect &preparedArea); void requestProjectionUpdateImpl(KisNode *node, const QVector &rects, const QRect &cropRect); friend class KisImageResizeCommand; void setSize(const QSize& size); void setProjectionColorSpace(const KoColorSpace * colorSpace); friend class KisDeselectGlobalSelectionCommand; friend class KisReselectGlobalSelectionCommand; friend class KisSetGlobalSelectionCommand; friend class KisImageTest; friend class Document; // For libkis /** * Replaces the current global selection with globalSelection. If * \p globalSelection is empty, removes the selection object, so that * \ref globalSelection() will return 0 after that. */ void setGlobalSelection(KisSelectionSP globalSelection); /** * Deselects current global selection. * \ref globalSelection() will return 0 after that. */ void deselectGlobalSelection(); /** * Reselects current deselected selection * * \see deselectGlobalSelection() */ void reselectGlobalSelection(); private: class KisImagePrivate; KisImagePrivate * m_d; }; #endif // KIS_IMAGE_H_ diff --git a/libs/ui/kis_node_manager.cpp b/libs/ui/kis_node_manager.cpp index 711d850be9..3e3a9cde0e 100644 --- a/libs/ui/kis_node_manager.cpp +++ b/libs/ui/kis_node_manager.cpp @@ -1,1627 +1,1611 @@ /* * 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_node_manager.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 #include #include #include #include #include #include "KisPart.h" #include "canvas/kis_canvas2.h" #include "kis_shape_controller.h" #include "kis_canvas_resource_provider.h" #include "KisViewManager.h" #include "KisDocument.h" #include "kis_mask_manager.h" #include "kis_group_layer.h" #include "kis_layer_manager.h" #include "kis_selection_manager.h" #include "kis_node_commands_adapter.h" #include "kis_action.h" #include "kis_action_manager.h" #include "kis_processing_applicator.h" #include "kis_sequential_iterator.h" #include "kis_transaction.h" #include "kis_node_selection_adapter.h" #include "kis_node_insertion_adapter.h" #include "kis_node_juggler_compressed.h" #include "KisNodeDisplayModeAdapter.h" #include "kis_clipboard.h" #include "kis_node_dummies_graph.h" #include "kis_mimedata.h" #include "kis_layer_utils.h" #include "krita_utils.h" #include "kis_shape_layer.h" #include "processing/kis_mirror_processing_visitor.h" #include "KisView.h" #include #include #include struct KisNodeManager::Private { Private(KisNodeManager *_q, KisViewManager *v) : q(_q) , view(v) , imageView(0) , layerManager(v) , maskManager(v) , commandsAdapter(v) , nodeSelectionAdapter(new KisNodeSelectionAdapter(q)) , nodeInsertionAdapter(new KisNodeInsertionAdapter(q)) , nodeDisplayModeAdapter(new KisNodeDisplayModeAdapter()) , lastRequestedIsolatedModeStatus(false) { } KisNodeManager * q; KisViewManager * view; QPointerimageView; KisLayerManager layerManager; KisMaskManager maskManager; KisNodeCommandsAdapter commandsAdapter; QScopedPointer nodeSelectionAdapter; QScopedPointer nodeInsertionAdapter; QScopedPointer nodeDisplayModeAdapter; KisAction *pinToTimeline; KisNodeList selectedNodes; QPointer nodeJuggler; KisNodeWSP previouslyActiveNode; bool activateNodeImpl(KisNodeSP node); KisSignalMapper nodeCreationSignalMapper; KisSignalMapper nodeConversionSignalMapper; bool lastRequestedIsolatedModeStatus; void saveDeviceAsImage(KisPaintDeviceSP device, const QString &defaultName, const QRect &bounds, qreal xRes, qreal yRes, quint8 opacity); void mergeTransparencyMaskAsAlpha(bool writeToLayers); KisNodeJugglerCompressed* lazyGetJuggler(const KUndo2MagicString &actionName); }; bool KisNodeManager::Private::activateNodeImpl(KisNodeSP node) { Q_ASSERT(view); Q_ASSERT(view->canvasBase()); Q_ASSERT(view->canvasBase()->globalShapeManager()); Q_ASSERT(imageView); if (node && node == q->activeNode()) { return false; } // Set the selection on the shape manager to the active layer // and set call KoSelection::setActiveLayer( KoShapeLayer* layer ) // with the parent of the active layer. KoSelection *selection = view->canvasBase()->globalShapeManager()->selection(); Q_ASSERT(selection); selection->deselectAll(); if (!node) { selection->setActiveLayer(0); imageView->setCurrentNode(0); maskManager.activateMask(0); layerManager.activateLayer(0); previouslyActiveNode = q->activeNode(); } else { previouslyActiveNode = q->activeNode(); KoShape * shape = view->document()->shapeForNode(node); //if (!shape) return false; KIS_SAFE_ASSERT_RECOVER_RETURN_VALUE(shape, false); selection->select(shape); KoShapeLayer * shapeLayer = dynamic_cast(shape); //if (!shapeLayer) return false; KIS_SAFE_ASSERT_RECOVER_RETURN_VALUE(shapeLayer, false); // shapeLayer->setGeometryProtected(node->userLocked()); // shapeLayer->setVisible(node->visible()); selection->setActiveLayer(shapeLayer); imageView->setCurrentNode(node); if (KisLayerSP layer = qobject_cast(node.data())) { maskManager.activateMask(0); layerManager.activateLayer(layer); } else if (KisMaskSP mask = dynamic_cast(node.data())) { maskManager.activateMask(mask); // XXX_NODE: for now, masks cannot be nested. layerManager.activateLayer(static_cast(node->parent().data())); } } return true; } KisNodeManager::KisNodeManager(KisViewManager *view) : m_d(new Private(this, view)) { } KisNodeManager::~KisNodeManager() { delete m_d; } void KisNodeManager::setView(QPointerimageView) { m_d->maskManager.setView(imageView); m_d->layerManager.setView(imageView); if (m_d->imageView) { KisShapeController *shapeController = dynamic_cast(m_d->imageView->document()->shapeController()); Q_ASSERT(shapeController); shapeController->disconnect(SIGNAL(sigActivateNode(KisNodeSP)), this); m_d->imageView->image()->disconnect(this); } m_d->imageView = imageView; if (m_d->imageView) { KisShapeController *shapeController = dynamic_cast(m_d->imageView->document()->shapeController()); Q_ASSERT(shapeController); connect(shapeController, SIGNAL(sigActivateNode(KisNodeSP)), SLOT(slotNonUiActivatedNode(KisNodeSP))); connect(m_d->imageView->image(), SIGNAL(sigRequestNodeReselection(KisNodeSP,KisNodeList)),this, SLOT(slotImageRequestNodeReselection(KisNodeSP,KisNodeList))); m_d->imageView->resourceProvider()->slotNodeActivated(m_d->imageView->currentNode()); } } #define NEW_LAYER_ACTION(id, layerType) \ { \ action = actionManager->createAction(id); \ m_d->nodeCreationSignalMapper.setMapping(action, layerType); \ connect(action, SIGNAL(triggered()), \ &m_d->nodeCreationSignalMapper, SLOT(map())); \ } #define CONVERT_NODE_ACTION_2(id, layerType, exclude) \ { \ action = actionManager->createAction(id); \ action->setExcludedNodeTypes(QStringList(exclude)); \ actionManager->addAction(id, action); \ m_d->nodeConversionSignalMapper.setMapping(action, layerType); \ connect(action, SIGNAL(triggered()), \ &m_d->nodeConversionSignalMapper, SLOT(map())); \ } #define CONVERT_NODE_ACTION(id, layerType) \ CONVERT_NODE_ACTION_2(id, layerType, layerType) void KisNodeManager::setup(KActionCollection * actionCollection, KisActionManager* actionManager) { m_d->layerManager.setup(actionManager); m_d->maskManager.setup(actionCollection, actionManager); KisAction * action = 0; action = actionManager->createAction("mirrorNodeX"); connect(action, SIGNAL(triggered()), this, SLOT(mirrorNodeX())); action = actionManager->createAction("mirrorNodeY"); connect(action, SIGNAL(triggered()), this, SLOT(mirrorNodeY())); action = actionManager->createAction("mirrorAllNodesX"); connect(action, SIGNAL(triggered()), this, SLOT(mirrorAllNodesX())); action = actionManager->createAction("mirrorAllNodesY"); connect(action, SIGNAL(triggered()), this, SLOT(mirrorAllNodesY())); action = actionManager->createAction("activateNextLayer"); connect(action, SIGNAL(triggered()), this, SLOT(activateNextNode())); action = actionManager->createAction("activateNextSiblingLayer"); connect(action, SIGNAL(triggered()), this, SLOT(activateNextSiblingNode())); action = actionManager->createAction("activatePreviousLayer"); connect(action, SIGNAL(triggered()), this, SLOT(activatePreviousNode())); action = actionManager->createAction("activatePreviousSiblingLayer"); connect(action, SIGNAL(triggered()), this, SLOT(activatePreviousSiblingNode())); action = actionManager->createAction("switchToPreviouslyActiveNode"); connect(action, SIGNAL(triggered()), this, SLOT(switchToPreviouslyActiveNode())); action = actionManager->createAction("save_node_as_image"); connect(action, SIGNAL(triggered()), this, SLOT(saveNodeAsImage())); action = actionManager->createAction("save_vector_node_to_svg"); connect(action, SIGNAL(triggered()), this, SLOT(saveVectorLayerAsImage())); action->setActivationFlags(KisAction::ACTIVE_SHAPE_LAYER); action = actionManager->createAction("duplicatelayer"); connect(action, SIGNAL(triggered()), this, SLOT(duplicateActiveNode())); action = actionManager->createAction("copy_layer_clipboard"); connect(action, SIGNAL(triggered()), this, SLOT(copyLayersToClipboard())); action = actionManager->createAction("cut_layer_clipboard"); connect(action, SIGNAL(triggered()), this, SLOT(cutLayersToClipboard())); action = actionManager->createAction("paste_layer_from_clipboard"); connect(action, SIGNAL(triggered()), this, SLOT(pasteLayersFromClipboard())); action = actionManager->createAction("create_quick_group"); connect(action, SIGNAL(triggered()), this, SLOT(createQuickGroup())); action = actionManager->createAction("create_quick_clipping_group"); connect(action, SIGNAL(triggered()), this, SLOT(createQuickClippingGroup())); action = actionManager->createAction("quick_ungroup"); connect(action, SIGNAL(triggered()), this, SLOT(quickUngroup())); action = actionManager->createAction("select_all_layers"); connect(action, SIGNAL(triggered()), this, SLOT(selectAllNodes())); action = actionManager->createAction("select_visible_layers"); connect(action, SIGNAL(triggered()), this, SLOT(selectVisibleNodes())); action = actionManager->createAction("select_locked_layers"); connect(action, SIGNAL(triggered()), this, SLOT(selectLockedNodes())); action = actionManager->createAction("select_invisible_layers"); connect(action, SIGNAL(triggered()), this, SLOT(selectInvisibleNodes())); action = actionManager->createAction("select_unlocked_layers"); connect(action, SIGNAL(triggered()), this, SLOT(selectUnlockedNodes())); action = actionManager->createAction("new_from_visible"); connect(action, SIGNAL(triggered()), this, SLOT(createFromVisible())); action = actionManager->createAction("pin_to_timeline"); action->setCheckable(true); connect(action, SIGNAL(toggled(bool)), this, SLOT(slotPinToTimeline(bool))); m_d->pinToTimeline = action; NEW_LAYER_ACTION("add_new_paint_layer", "KisPaintLayer"); NEW_LAYER_ACTION("add_new_group_layer", "KisGroupLayer"); NEW_LAYER_ACTION("add_new_clone_layer", "KisCloneLayer"); NEW_LAYER_ACTION("add_new_shape_layer", "KisShapeLayer"); NEW_LAYER_ACTION("add_new_adjustment_layer", "KisAdjustmentLayer"); NEW_LAYER_ACTION("add_new_fill_layer", "KisGeneratorLayer"); NEW_LAYER_ACTION("add_new_file_layer", "KisFileLayer"); NEW_LAYER_ACTION("add_new_transparency_mask", "KisTransparencyMask"); NEW_LAYER_ACTION("add_new_filter_mask", "KisFilterMask"); NEW_LAYER_ACTION("add_new_colorize_mask", "KisColorizeMask"); NEW_LAYER_ACTION("add_new_transform_mask", "KisTransformMask"); NEW_LAYER_ACTION("add_new_selection_mask", "KisSelectionMask"); connect(&m_d->nodeCreationSignalMapper, SIGNAL(mapped(QString)), this, SLOT(createNode(QString))); CONVERT_NODE_ACTION("convert_to_paint_layer", "KisPaintLayer"); CONVERT_NODE_ACTION_2("convert_to_selection_mask", "KisSelectionMask", QStringList() << "KisSelectionMask" << "KisColorizeMask"); CONVERT_NODE_ACTION_2("convert_to_filter_mask", "KisFilterMask", QStringList() << "KisFilterMask" << "KisColorizeMask"); CONVERT_NODE_ACTION_2("convert_to_transparency_mask", "KisTransparencyMask", QStringList() << "KisTransparencyMask" << "KisColorizeMask"); CONVERT_NODE_ACTION("convert_to_animated", "animated"); CONVERT_NODE_ACTION_2("convert_to_file_layer", "KisFileLayer", QStringList() << "KisFileLayer" << "KisCloneLayer"); connect(&m_d->nodeConversionSignalMapper, SIGNAL(mapped(QString)), this, SLOT(convertNode(QString))); // Isolation Modes... // Post Qt5.14 this can be replaced with QActionGroup + ExclusionPolicy::ExclusiveOptional. action = actionManager->createAction("isolate_active_layer"); connect(action, SIGNAL(triggered(bool)), this, SLOT(setIsolateActiveLayerMode(bool))); action = actionManager->createAction("isolate_active_group"); connect(action, SIGNAL(triggered(bool)), this, SLOT(setIsolateActiveGroupMode(bool))); connect(this, SIGNAL(sigNodeActivated(KisNodeSP)), SLOT(updateIsolationMode())); action = actionManager->createAction("toggle_layer_visibility"); connect(action, SIGNAL(triggered()), this, SLOT(toggleVisibility())); action = actionManager->createAction("toggle_layer_lock"); connect(action, SIGNAL(triggered()), this, SLOT(toggleLock())); action = actionManager->createAction("toggle_layer_inherit_alpha"); connect(action, SIGNAL(triggered()), this, SLOT(toggleInheritAlpha())); action = actionManager->createAction("toggle_layer_alpha_lock"); connect(action, SIGNAL(triggered()), this, SLOT(toggleAlphaLock())); action = actionManager->createAction("split_alpha_into_mask"); connect(action, SIGNAL(triggered()), this, SLOT(slotSplitAlphaIntoMask())); action = actionManager->createAction("split_alpha_write"); connect(action, SIGNAL(triggered()), this, SLOT(slotSplitAlphaWrite())); // HINT: we can save even when the nodes are not editable action = actionManager->createAction("split_alpha_save_merged"); connect(action, SIGNAL(triggered()), this, SLOT(slotSplitAlphaSaveMerged())); } void KisNodeManager::updateGUI() { // enable/disable all relevant actions m_d->layerManager.updateGUI(); m_d->maskManager.updateGUI(); } KisNodeSP KisNodeManager::activeNode() { if (m_d->imageView) { return m_d->imageView->currentNode(); } return 0; } KisLayerSP KisNodeManager::activeLayer() { return m_d->layerManager.activeLayer(); } const KoColorSpace* KisNodeManager::activeColorSpace() { if (m_d->maskManager.activeDevice()) { return m_d->maskManager.activeDevice()->colorSpace(); } else { Q_ASSERT(m_d->layerManager.activeLayer()); if (m_d->layerManager.activeLayer()->parentLayer()) return m_d->layerManager.activeLayer()->parentLayer()->colorSpace(); else return m_d->view->image()->colorSpace(); } } void KisNodeManager::moveNodeAt(KisNodeSP node, KisNodeSP parent, int index) { if (parent->allowAsChild(node)) { if (node->inherits("KisSelectionMask") && parent->inherits("KisLayer")) { KisSelectionMask *m = dynamic_cast(node.data()); KisLayer *l = qobject_cast(parent.data()); if (m && m->active() && l && l->selectionMask()) { l->selectionMask()->setActive(false); } } m_d->commandsAdapter.moveNode(node, parent, index); } } void KisNodeManager::moveNodesDirect(KisNodeList nodes, KisNodeSP parent, KisNodeSP aboveThis) { KUndo2MagicString actionName = kundo2_i18n("Move Nodes"); KisNodeJugglerCompressed *juggler = m_d->lazyGetJuggler(actionName); juggler->moveNode(nodes, parent, aboveThis); } void KisNodeManager::copyNodesDirect(KisNodeList nodes, KisNodeSP parent, KisNodeSP aboveThis) { KUndo2MagicString actionName = kundo2_i18n("Copy Nodes"); KisNodeJugglerCompressed *juggler = m_d->lazyGetJuggler(actionName); juggler->copyNode(nodes, parent, aboveThis); } void KisNodeManager::addNodesDirect(KisNodeList nodes, KisNodeSP parent, KisNodeSP aboveThis) { KUndo2MagicString actionName = kundo2_i18n("Add Nodes"); KisNodeJugglerCompressed *juggler = m_d->lazyGetJuggler(actionName); juggler->addNode(nodes, parent, aboveThis); } void KisNodeManager::toggleIsolateActiveNode() { + /* KisImageWSP image = m_d->view->image(); KisNodeSP activeNode = this->activeNode(); - KIS_ASSERT_RECOVER_RETURN(activeNode); + KIS_ASSERT_RECOVER_RETURN(activeNode);*/ + +// const bool groupIsolationStatus = image->isIsolatingGroup(); +// if (image->isolationRootNode()) { +// changeIsolationMode(false, groupIsolationStatus); +// reinitializeIsolationActionGroup(); +// } else { +// changeIsolationMode(true, groupIsolationStatus); +// } + QAction* action = m_d->view->actionManager()->actionByName("isolate_active_layer"); + action->toggle(); + action->triggered(action->isChecked()); - if (image->isolationRootNode()) { - changeIsolationMode(KisImage::IsolationMode::ISOLATE_OFF); - reinitializeIsolationActionGroup(); - } else { - changeIsolationMode(KisImage::IsolationMode::ISOLATE_LAYER); - m_d->view->actionManager()->actionByName("isolate_active_layer")->setChecked(true); - } } -/* - * Slots for handling 3-state isolation mode actions. - * Post Qt5.14 this can be replaced with QActionGroup + ExclusionPolicy::ExclusiveOptional. - */ void KisNodeManager::setIsolateActiveLayerMode(bool checked) { - if (checked) { - changeIsolationMode(KisImage::IsolationMode::ISOLATE_LAYER); - } else { - changeIsolationMode(KisImage::IsolationMode::ISOLATE_OFF); - } + KisImageWSP image = m_d->view->image(); + KIS_ASSERT_RECOVER_RETURN(image); + + const bool groupIsolationState = image->isIsolatingGroup(); + changeIsolationMode(checked, groupIsolationState); } + void KisNodeManager::setIsolateActiveGroupMode(bool checked) { - if (checked) { - changeIsolationMode(KisImage::IsolationMode::ISOLATE_GROUP); - } else { - changeIsolationMode(KisImage::IsolationMode::ISOLATE_OFF); - } + KisImageWSP image = m_d->view->image(); + KIS_ASSERT_RECOVER_RETURN(image); + + const bool layerIsolationState = image->isIsolatingLayer(); + changeIsolationMode(layerIsolationState, checked); } -void KisNodeManager::changeIsolationMode(KisImage::IsolationMode mode) +void KisNodeManager::changeIsolationMode(bool isolateActiveLayer, bool isolateActiveGroup) { - ENTER_FUNCTION() << ppVar(mode); - KisImageWSP image = m_d->view->image(); KisNodeSP activeNode = this->activeNode(); KIS_ASSERT_RECOVER_RETURN(image && activeNode); - switch (mode) { - case KisImage::IsolationMode::ISOLATE_LAYER: - // Transform and colorize masks don't have pixel data... - if (activeNode->inherits("KisTransformMask") || - activeNode->inherits("KisColorizeMask")) return; + ENTER_FUNCTION() << ppVar(isolateActiveLayer) << ppVar(isolateActiveGroup); - if (image->startIsolatedMode(activeNode, mode)) { - // Post Qt5.14 this can be replaced with QActionGroup + ExclusionPolicy::ExclusiveOptional. - m_d->view->actionManager()->actionByName("isolate_active_group")->setChecked(false); - } else { + if (isolateActiveLayer || isolateActiveGroup) { + if (image->startIsolatedMode(activeNode, isolateActiveLayer, isolateActiveGroup) == false) { reinitializeIsolationActionGroup(); } - break; - - case KisImage::IsolationMode::ISOLATE_GROUP: - if (image->startIsolatedMode(activeNode, mode)) { - // Post Qt5.14 this can be replaced with QActionGroup + ExclusionPolicy::ExclusiveOptional. - m_d->view->actionManager()->actionByName("isolate_active_layer")->setChecked(false); - } else { - reinitializeIsolationActionGroup(); - } - break; - - case KisImage::IsolationMode::ISOLATE_OFF: + } else { image->stopIsolatedMode(); - reinitializeIsolationActionGroup(); - break; } } void KisNodeManager::updateIsolationMode() { // It might be that we have multiple Krita windows open. In such a case // only the currently active one should restart isolated mode if (!m_d->view->mainWindow()->isActiveWindow()) return; KisImageWSP image = m_d->view->image(); KisNodeSP activeNode = this->activeNode(); - if (!image->startIsolatedMode(activeNode, image->currentIsolationMode())) { + const bool isIsolatingLayer = image->isIsolatingLayer(); + const bool isIsolatingGroup = image->isIsolatingGroup(); + + if (!image->startIsolatedMode(activeNode, isIsolatingLayer, isIsolatingGroup)) { reinitializeIsolationActionGroup(); } } void KisNodeManager::reinitializeIsolationActionGroup() { m_d->view->actionManager()->actionByName("isolate_active_layer")->setChecked(false); m_d->view->actionManager()->actionByName("isolate_active_group")->setChecked(false); } KisNodeSP KisNodeManager::createNode(const QString & nodeType, bool quiet, KisPaintDeviceSP copyFrom) { if (!m_d->view->blockUntilOperationsFinished(m_d->view->image())) { return 0; } KisNodeSP activeNode = this->activeNode(); if (!activeNode) { activeNode = m_d->view->image()->root(); } KIS_ASSERT_RECOVER_RETURN_VALUE(activeNode, 0); // XXX: make factories for this kind of stuff, // with a registry if (nodeType == "KisPaintLayer") { return m_d->layerManager.addPaintLayer(activeNode); } else if (nodeType == "KisGroupLayer") { return m_d->layerManager.addGroupLayer(activeNode); } else if (nodeType == "KisAdjustmentLayer") { return m_d->layerManager.addAdjustmentLayer(activeNode); } else if (nodeType == "KisGeneratorLayer") { return m_d->layerManager.addGeneratorLayer(activeNode); } else if (nodeType == "KisShapeLayer") { return m_d->layerManager.addShapeLayer(activeNode); } else if (nodeType == "KisCloneLayer") { KisNodeList nodes = selectedNodes(); if (nodes.isEmpty()) { nodes.append(activeNode); } return m_d->layerManager.addCloneLayer(nodes); } else if (nodeType == "KisTransparencyMask") { return m_d->maskManager.createTransparencyMask(activeNode, copyFrom, false); } else if (nodeType == "KisFilterMask") { return m_d->maskManager.createFilterMask(activeNode, copyFrom, quiet, false); } else if (nodeType == "KisColorizeMask") { return m_d->maskManager.createColorizeMask(activeNode); } else if (nodeType == "KisTransformMask") { return m_d->maskManager.createTransformMask(activeNode); } else if (nodeType == "KisSelectionMask") { return m_d->maskManager.createSelectionMask(activeNode, copyFrom, false); } else if (nodeType == "KisFileLayer") { return m_d->layerManager.addFileLayer(activeNode); } return 0; } void KisNodeManager::createFromVisible() { KisLayerUtils::newLayerFromVisible(m_d->view->image(), m_d->view->image()->root()->lastChild()); } void KisNodeManager::slotPinToTimeline(bool value) { Q_FOREACH (KisNodeSP node, selectedNodes()) { node->setPinnedToTimeline(value); } } KisLayerSP KisNodeManager::createPaintLayer() { KisNodeSP node = createNode("KisPaintLayer"); return dynamic_cast(node.data()); } void KisNodeManager::convertNode(const QString &nodeType) { if (!m_d->view->blockUntilOperationsFinished(m_d->view->image())) { return; } KisNodeSP activeNode = this->activeNode(); if (!activeNode) return; if (nodeType == "KisPaintLayer") { m_d->layerManager.convertNodeToPaintLayer(activeNode); } else if (nodeType == "KisSelectionMask" || nodeType == "KisFilterMask" || nodeType == "KisTransparencyMask") { KisPaintDeviceSP copyFrom = activeNode->paintDevice() ? activeNode->paintDevice() : activeNode->projection(); m_d->commandsAdapter.beginMacro(kundo2_i18n("Convert to a Selection Mask")); bool result = false; if (nodeType == "KisSelectionMask") { result = !m_d->maskManager.createSelectionMask(activeNode, copyFrom, true).isNull(); } else if (nodeType == "KisFilterMask") { result = !m_d->maskManager.createFilterMask(activeNode, copyFrom, false, true).isNull(); } else if (nodeType == "KisTransparencyMask") { result = !m_d->maskManager.createTransparencyMask(activeNode, copyFrom, true).isNull(); } m_d->commandsAdapter.endMacro(); if (!result) { m_d->view->blockUntilOperationsFinishedForced(m_d->imageView->image()); m_d->commandsAdapter.undoLastCommand(); } } else if (nodeType == "KisFileLayer") { m_d->layerManager.convertLayerToFileLayer(activeNode); } else { warnKrita << "Unsupported node conversion type:" << nodeType; } } void KisNodeManager::slotSomethingActivatedNodeImpl(KisNodeSP node) { KisDummiesFacadeBase *dummiesFacade = dynamic_cast(m_d->imageView->document()->shapeController()); KIS_SAFE_ASSERT_RECOVER_RETURN(dummiesFacade); const bool nodeVisible = !isNodeHidden(node, !m_d->nodeDisplayModeAdapter->showGlobalSelectionMask()); if (!nodeVisible) { return; } KIS_ASSERT_RECOVER_RETURN(node != activeNode()); if (m_d->activateNodeImpl(node)) { emit sigUiNeedChangeActiveNode(node); emit sigNodeActivated(node); nodesUpdated(); if (node) { bool toggled = m_d->view->actionCollection()->action("view_show_canvas_only")->isChecked(); if (toggled) { m_d->view->showFloatingMessage( activeLayer()->name(), QIcon(), 1600, KisFloatingMessage::Medium, Qt::TextSingleLine); } } } } void KisNodeManager::slotNonUiActivatedNode(KisNodeSP node) { // the node must still be in the graph, some asynchronous // signals may easily break this requirement if (node && !node->graphListener()) { node = 0; } if (node == activeNode()) return; slotSomethingActivatedNodeImpl(node); if (node) { bool toggled = m_d->view->actionCollection()->action("view_show_canvas_only")->isChecked(); if (toggled) { m_d->view->showFloatingMessage( activeLayer()->name(), QIcon(), 1600, KisFloatingMessage::Medium, Qt::TextSingleLine); } } } void KisNodeManager::slotUiActivatedNode(KisNodeSP node) { // the node must still be in the graph, some asynchronous // signals may easily break this requirement if (node && !node->graphListener()) { node = 0; } if (node) { QStringList vectorTools = QStringList() << "InteractionTool" << "KarbonPatternTool" << "KarbonGradientTool" << "KarbonCalligraphyTool" << "CreateShapesTool" << "PathTool"; QStringList pixelTools = QStringList() << "KritaShape/KisToolBrush" << "KritaShape/KisToolDyna" << "KritaShape/KisToolMultiBrush" << "KritaFill/KisToolFill" << "KritaFill/KisToolGradient"; KisSelectionMask *selectionMask = dynamic_cast(node.data()); const bool nodeHasVectorAbilities = node->inherits("KisShapeLayer") || (selectionMask && selectionMask->selection()->hasShapeSelection()); if (nodeHasVectorAbilities) { if (pixelTools.contains(KoToolManager::instance()->activeToolId())) { KoToolManager::instance()->switchToolRequested("InteractionTool"); } } else { if (vectorTools.contains(KoToolManager::instance()->activeToolId())) { KoToolManager::instance()->switchToolRequested("KritaShape/KisToolBrush"); } } } if (node == activeNode()) return; slotSomethingActivatedNodeImpl(node); } void KisNodeManager::nodesUpdated() { KisNodeSP node = activeNode(); if (!node) return; m_d->layerManager.layersUpdated(); m_d->maskManager.masksUpdated(); m_d->view->updateGUI(); m_d->view->selectionManager()->selectionChanged(); { KisSignalsBlocker b(m_d->pinToTimeline); m_d->pinToTimeline->setChecked(node->isPinnedToTimeline()); } } KisPaintDeviceSP KisNodeManager::activePaintDevice() { return m_d->maskManager.activeMask() ? m_d->maskManager.activeDevice() : m_d->layerManager.activeDevice(); } void KisNodeManager::nodeProperties(KisNodeSP node) { if ((selectedNodes().size() > 1 && node->inherits("KisLayer")) || node->inherits("KisLayer")) { m_d->layerManager.layerProperties(); } else if (node->inherits("KisMask")) { m_d->maskManager.maskProperties(); } } void KisNodeManager::changeCloneSource() { m_d->layerManager.changeCloneSource(); } qint32 KisNodeManager::convertOpacityToInt(qreal opacity) { /** * Scales opacity from the range 0...100 * to the integer range 0...255 */ return qMin(255, int(opacity * 2.55 + 0.5)); } void KisNodeManager::setNodeName(KisNodeSP node, const QString &name) { if (!node) return; if (node->name() == name) return; m_d->commandsAdapter.setNodeName(node, name); } void KisNodeManager::setNodeOpacity(KisNodeSP node, qint32 opacity) { if (!node) return; if (node->opacity() == opacity) return; m_d->commandsAdapter.setOpacity(node, opacity); } void KisNodeManager::setNodeCompositeOp(KisNodeSP node, const KoCompositeOp* compositeOp) { if (!node) return; if (node->compositeOp() == compositeOp) return; m_d->commandsAdapter.setCompositeOp(node, compositeOp); } void KisNodeManager::slotImageRequestNodeReselection(KisNodeSP activeNode, const KisNodeList &selectedNodes) { if (activeNode) { slotNonUiActivatedNode(activeNode); } if (!selectedNodes.isEmpty()) { slotSetSelectedNodes(selectedNodes); } } void KisNodeManager::slotSetSelectedNodes(const KisNodeList &nodes) { m_d->selectedNodes = nodes; emit sigUiNeedChangeSelectedNodes(nodes); } KisNodeList KisNodeManager::selectedNodes() { return m_d->selectedNodes; } KisNodeSelectionAdapter* KisNodeManager::nodeSelectionAdapter() const { return m_d->nodeSelectionAdapter.data(); } KisNodeInsertionAdapter* KisNodeManager::nodeInsertionAdapter() const { return m_d->nodeInsertionAdapter.data(); } KisNodeDisplayModeAdapter *KisNodeManager::nodeDisplayModeAdapter() const { return m_d->nodeDisplayModeAdapter.data(); } bool KisNodeManager::isNodeHidden(KisNodeSP node, bool isGlobalSelectionHidden) { if (node && node->isFakeNode()) { return true; } if (isGlobalSelectionHidden && dynamic_cast(node.data()) && (!node->parent() || !node->parent()->parent())) { return true; } return false; } bool KisNodeManager::trySetNodeProperties(KisNodeSP node, KisImageSP image, KisBaseNode::PropertyList properties) const { const KisPaintLayer *paintLayer = dynamic_cast(node.data()); if (paintLayer) { const auto onionSkinOn = KisLayerPropertiesIcons::getProperty(KisLayerPropertiesIcons::onionSkins, true); if (properties.contains(onionSkinOn)) { const KisPaintDeviceSP &paintDevice = paintLayer->paintDevice(); if (paintDevice && paintDevice->defaultPixel().opacityU8() == 255) { m_d->view->showFloatingMessage(i18n("Onion skins require a layer with transparent background."), QIcon()); return false; } } } KisNodePropertyListCommand::setNodePropertiesNoUndo(node, image, properties); return true; } void KisNodeManager::nodeOpacityChanged(qreal opacity) { KisNodeSP node = activeNode(); setNodeOpacity(node, convertOpacityToInt(opacity)); } void KisNodeManager::nodeCompositeOpChanged(const KoCompositeOp* op) { KisNodeSP node = activeNode(); setNodeCompositeOp(node, op); } void KisNodeManager::duplicateActiveNode() { KUndo2MagicString actionName = kundo2_i18n("Duplicate Nodes"); KisNodeJugglerCompressed *juggler = m_d->lazyGetJuggler(actionName); juggler->duplicateNode(selectedNodes()); } KisNodeJugglerCompressed* KisNodeManager::Private::lazyGetJuggler(const KUndo2MagicString &actionName) { KisImageWSP image = view->image(); if (!nodeJuggler || (nodeJuggler && (nodeJuggler->isEnded() || !nodeJuggler->canMergeAction(actionName)))) { nodeJuggler = new KisNodeJugglerCompressed(actionName, image, q, 750); nodeJuggler->setAutoDelete(true); } return nodeJuggler; } void KisNodeManager::raiseNode() { KUndo2MagicString actionName = kundo2_i18n("Raise Nodes"); KisNodeJugglerCompressed *juggler = m_d->lazyGetJuggler(actionName); juggler->raiseNode(selectedNodes()); } void KisNodeManager::lowerNode() { KUndo2MagicString actionName = kundo2_i18n("Lower Nodes"); KisNodeJugglerCompressed *juggler = m_d->lazyGetJuggler(actionName); juggler->lowerNode(selectedNodes()); } void KisNodeManager::removeSingleNode(KisNodeSP node) { if (!node || !node->parent()) { return; } KisNodeList nodes; nodes << node; removeSelectedNodes(nodes); } void KisNodeManager::removeSelectedNodes(KisNodeList nodes) { KUndo2MagicString actionName = kundo2_i18n("Remove Nodes"); KisNodeJugglerCompressed *juggler = m_d->lazyGetJuggler(actionName); juggler->removeNode(nodes); } void KisNodeManager::removeNode() { removeSelectedNodes(selectedNodes()); } void KisNodeManager::mirrorNodeX() { KisNodeSP node = activeNode(); KUndo2MagicString commandName; if (node->inherits("KisLayer")) { commandName = kundo2_i18n("Mirror Layer X"); } else if (node->inherits("KisMask")) { commandName = kundo2_i18n("Mirror Mask X"); } mirrorNode(node, commandName, Qt::Horizontal, m_d->view->selection()); } void KisNodeManager::mirrorNodeY() { KisNodeSP node = activeNode(); KUndo2MagicString commandName; if (node->inherits("KisLayer")) { commandName = kundo2_i18n("Mirror Layer Y"); } else if (node->inherits("KisMask")) { commandName = kundo2_i18n("Mirror Mask Y"); } mirrorNode(node, commandName, Qt::Vertical, m_d->view->selection()); } void KisNodeManager::mirrorAllNodesX() { KisNodeSP node = m_d->view->image()->root(); mirrorNode(node, kundo2_i18n("Mirror All Layers X"), Qt::Horizontal, m_d->view->selection()); } void KisNodeManager::mirrorAllNodesY() { KisNodeSP node = m_d->view->image()->root(); mirrorNode(node, kundo2_i18n("Mirror All Layers Y"), Qt::Vertical, m_d->view->selection()); } void KisNodeManager::activateNextNode(bool siblingsOnly) { KisNodeSP activeNode = this->activeNode(); if (!activeNode) return; KisNodeSP nextNode = activeNode->nextSibling(); if (!siblingsOnly) { // Recurse groups... while (nextNode && nextNode->childCount() > 0) { nextNode = nextNode->firstChild(); } // Out of nodes? Back out of group... if (!nextNode && activeNode->parent()) { nextNode = activeNode->parent(); } } // Skip nodes hidden from tree view.. while (nextNode && isNodeHidden(nextNode, m_d->nodeDisplayModeAdapter->showGlobalSelectionMask())) { nextNode = nextNode->nextSibling(); } // Select node, unless root.. if (nextNode && nextNode->parent()) { slotNonUiActivatedNode(nextNode); } } void KisNodeManager::activateNextSiblingNode() { activateNextNode(true); } void KisNodeManager::activatePreviousNode(bool siblingsOnly) { KisNodeSP activeNode = this->activeNode(); if (!activeNode) return; KisNodeSP nextNode = activeNode->prevSibling(); if (!siblingsOnly) { // Enter groups.. if (activeNode->childCount() > 0) { nextNode = activeNode->lastChild(); } // Out of nodes? Back out of group... if (!nextNode && activeNode->parent()) { nextNode = activeNode->parent()->prevSibling(); } } // Skip nodes hidden from tree view.. while (nextNode && isNodeHidden(nextNode, m_d->nodeDisplayModeAdapter->showGlobalSelectionMask())) { nextNode = nextNode->prevSibling(); } // Select node, unless root.. if (nextNode && nextNode->parent()) { slotNonUiActivatedNode(nextNode); } } void KisNodeManager::activatePreviousSiblingNode() { activatePreviousNode(true); } void KisNodeManager::switchToPreviouslyActiveNode() { if (m_d->previouslyActiveNode && m_d->previouslyActiveNode->parent()) { slotNonUiActivatedNode(m_d->previouslyActiveNode); } } void KisNodeManager::mirrorNode(KisNodeSP node, const KUndo2MagicString& actionName, Qt::Orientation orientation, KisSelectionSP selection) { KisImageSignalVector emitSignals; emitSignals << ModifiedSignal; KisProcessingApplicator applicator(m_d->view->image(), node, KisProcessingApplicator::RECURSIVE, emitSignals, actionName); KisProcessingVisitorSP visitor; if (selection) { visitor = new KisMirrorProcessingVisitor(selection, orientation); } else { visitor = new KisMirrorProcessingVisitor(m_d->view->image()->bounds(), orientation); } if (!selection) { applicator.applyVisitorAllFrames(visitor, KisStrokeJobData::CONCURRENT); } else { applicator.applyVisitor(visitor, KisStrokeJobData::CONCURRENT); } applicator.end(); nodesUpdated(); } void KisNodeManager::Private::saveDeviceAsImage(KisPaintDeviceSP device, const QString &defaultName, const QRect &bounds, qreal xRes, qreal yRes, quint8 opacity) { KoFileDialog dialog(view->mainWindow(), KoFileDialog::SaveFile, "savenodeasimage"); dialog.setCaption(i18n("Export \"%1\"", defaultName)); dialog.setDefaultDir(QStandardPaths::writableLocation(QStandardPaths::PicturesLocation)); dialog.setMimeTypeFilters(KisImportExportManager::supportedMimeTypes(KisImportExportManager::Export)); QString filename = dialog.filename(); if (filename.isEmpty()) return; QUrl url = QUrl::fromLocalFile(filename); if (url.isEmpty()) return; QString mimefilter = KisMimeDatabase::mimeTypeForFile(filename, false); QScopedPointer doc(KisPart::instance()->createDocument()); KisImageSP dst = new KisImage(doc->createUndoStore(), bounds.width(), bounds.height(), device->compositionSourceColorSpace(), defaultName); dst->setResolution(xRes, yRes); doc->setCurrentImage(dst); KisPaintLayer* paintLayer = new KisPaintLayer(dst, "paint device", opacity); paintLayer->paintDevice()->makeCloneFrom(device, bounds); dst->addNode(paintLayer, dst->rootLayer(), KisLayerSP(0)); dst->initialRefreshGraph(); if (!doc->exportDocumentSync(url, mimefilter.toLatin1())) { QMessageBox::warning(0, i18nc("@title:window", "Krita"), i18n("Could not save the layer. %1", doc->errorMessage().toUtf8().data()), QMessageBox::Ok); } } void KisNodeManager::saveNodeAsImage() { KisNodeSP node = activeNode(); if (!node) { warnKrita << "BUG: Save Node As Image was called without any node selected"; return; } KisImageWSP image = m_d->view->image(); QRect saveRect = image->bounds() | node->exactBounds(); m_d->saveDeviceAsImage(node->projection(), node->name(), saveRect, image->xRes(), image->yRes(), node->opacity()); } #include "SvgWriter.h" void KisNodeManager::saveVectorLayerAsImage() { KisShapeLayerSP shapeLayer = qobject_cast(activeNode().data()); if (!shapeLayer) { return; } KoFileDialog dialog(m_d->view->mainWindow(), KoFileDialog::SaveFile, "savenodeasimage"); dialog.setCaption(i18nc("@title:window", "Export to SVG")); dialog.setDefaultDir(QStandardPaths::writableLocation(QStandardPaths::PicturesLocation)); dialog.setMimeTypeFilters(QStringList() << "image/svg+xml", "image/svg+xml"); QString filename = dialog.filename(); if (filename.isEmpty()) return; QUrl url = QUrl::fromLocalFile(filename); if (url.isEmpty()) return; const QSizeF sizeInPx = m_d->view->image()->bounds().size(); const QSizeF sizeInPt(sizeInPx.width() / m_d->view->image()->xRes(), sizeInPx.height() / m_d->view->image()->yRes()); QList shapes = shapeLayer->shapes(); std::sort(shapes.begin(), shapes.end(), KoShape::compareShapeZIndex); SvgWriter writer(shapes); if (!writer.save(filename, sizeInPt, true)) { QMessageBox::warning(qApp->activeWindow(), i18nc("@title:window", "Krita"), i18n("Could not save to svg: %1", filename)); } } void KisNodeManager::slotSplitAlphaIntoMask() { KisNodeSP node = activeNode(); // guaranteed by KisActionManager KIS_ASSERT_RECOVER_RETURN(node->hasEditablePaintDevice()); KisPaintDeviceSP srcDevice = node->paintDevice(); const KoColorSpace *srcCS = srcDevice->colorSpace(); const QRect processRect = srcDevice->exactBounds() | srcDevice->defaultBounds()->bounds(); KisPaintDeviceSP selectionDevice = new KisPaintDevice(KoColorSpaceRegistry::instance()->alpha8()); m_d->commandsAdapter.beginMacro(kundo2_i18n("Split Alpha into a Mask")); KisTransaction transaction(kundo2_noi18n("__split_alpha_channel__"), srcDevice); KisSequentialIterator srcIt(srcDevice, processRect); KisSequentialIterator dstIt(selectionDevice, processRect); while (srcIt.nextPixel() && dstIt.nextPixel()) { quint8 *srcPtr = srcIt.rawData(); quint8 *alpha8Ptr = dstIt.rawData(); *alpha8Ptr = srcCS->opacityU8(srcPtr); srcCS->setOpacity(srcPtr, OPACITY_OPAQUE_U8, 1); } m_d->commandsAdapter.addExtraCommand(transaction.endAndTake()); createNode("KisTransparencyMask", false, selectionDevice); m_d->commandsAdapter.endMacro(); } void KisNodeManager::Private::mergeTransparencyMaskAsAlpha(bool writeToLayers) { KisNodeSP node = q->activeNode(); KisNodeSP parentNode = node->parent(); // guaranteed by KisActionManager KIS_ASSERT_RECOVER_RETURN(node->inherits("KisTransparencyMask")); if (writeToLayers && !parentNode->hasEditablePaintDevice()) { QMessageBox::information(view->mainWindow(), i18nc("@title:window", "Layer %1 is not editable", parentNode->name()), i18n("Cannot write alpha channel of " "the parent layer \"%1\".\n" "The operation will be cancelled.", parentNode->name())); return; } KisPaintDeviceSP dstDevice; if (writeToLayers) { KIS_ASSERT_RECOVER_RETURN(parentNode->paintDevice()); dstDevice = parentNode->paintDevice(); } else { KisPaintDeviceSP copyDevice = parentNode->paintDevice(); if (!copyDevice) { copyDevice = parentNode->original(); } dstDevice = new KisPaintDevice(*copyDevice); } const KoColorSpace *dstCS = dstDevice->colorSpace(); KisPaintDeviceSP selectionDevice = node->paintDevice(); KIS_ASSERT_RECOVER_RETURN(selectionDevice->colorSpace()->pixelSize() == 1); const QRect processRect = selectionDevice->exactBounds() | dstDevice->exactBounds() | selectionDevice->defaultBounds()->bounds(); QScopedPointer transaction; if (writeToLayers) { commandsAdapter.beginMacro(kundo2_i18n("Write Alpha into a Layer")); transaction.reset(new KisTransaction(kundo2_noi18n("__write_alpha_channel__"), dstDevice)); } KisSequentialIterator srcIt(selectionDevice, processRect); KisSequentialIterator dstIt(dstDevice, processRect); while (srcIt.nextPixel() && dstIt.nextPixel()) { quint8 *alpha8Ptr = srcIt.rawData(); quint8 *dstPtr = dstIt.rawData(); dstCS->setOpacity(dstPtr, *alpha8Ptr, 1); } if (writeToLayers) { commandsAdapter.addExtraCommand(transaction->endAndTake()); commandsAdapter.removeNode(node); commandsAdapter.endMacro(); } else { KisImageWSP image = view->image(); QRect saveRect = image->bounds(); saveDeviceAsImage(dstDevice, parentNode->name(), saveRect, image->xRes(), image->yRes(), OPACITY_OPAQUE_U8); } } void KisNodeManager::slotSplitAlphaWrite() { m_d->mergeTransparencyMaskAsAlpha(true); } void KisNodeManager::slotSplitAlphaSaveMerged() { m_d->mergeTransparencyMaskAsAlpha(false); } void KisNodeManager::toggleLock() { KisNodeList nodes = this->selectedNodes(); KisNodeSP active = activeNode(); if (nodes.isEmpty() || !active) return; bool isLocked = active->userLocked(); for (auto &node : nodes) { node->setUserLocked(!isLocked); } } void KisNodeManager::toggleVisibility() { KisNodeList nodes = this->selectedNodes(); KisNodeSP active = activeNode(); if (nodes.isEmpty() || !active) return; bool isVisible = active->visible(); for (auto &node : nodes) { node->setVisible(!isVisible); node->setDirty(); } } void KisNodeManager::toggleAlphaLock() { KisNodeList nodes = this->selectedNodes(); KisNodeSP active = activeNode(); if (nodes.isEmpty() || !active) return; auto layer = qobject_cast(active.data()); if (!layer) { return; } bool isAlphaLocked = layer->alphaLocked(); for (auto &node : nodes) { auto layer = qobject_cast(node.data()); if (layer) { layer->setAlphaLocked(!isAlphaLocked); } } } void KisNodeManager::toggleInheritAlpha() { KisNodeList nodes = this->selectedNodes(); KisNodeSP active = activeNode(); if (nodes.isEmpty() || !active) return; auto layer = qobject_cast(active.data()); if (!layer) { return; } bool isAlphaDisabled = layer->alphaChannelDisabled(); for (auto &node : nodes) { auto layer = qobject_cast(node.data()); if (layer) { layer->disableAlphaChannel(!isAlphaDisabled); node->setDirty(); } } } void KisNodeManager::cutLayersToClipboard() { KisNodeList nodes = this->selectedNodes(); if (nodes.isEmpty()) return; KisClipboard::instance()->setLayers(nodes, m_d->view->image(), false); KUndo2MagicString actionName = kundo2_i18n("Cut Nodes"); KisNodeJugglerCompressed *juggler = m_d->lazyGetJuggler(actionName); juggler->removeNode(nodes); } void KisNodeManager::copyLayersToClipboard() { KisNodeList nodes = this->selectedNodes(); KisClipboard::instance()->setLayers(nodes, m_d->view->image(), true); } void KisNodeManager::pasteLayersFromClipboard() { const QMimeData *data = KisClipboard::instance()->layersMimeData(); if (!data) return; KisNodeSP activeNode = this->activeNode(); KisShapeController *shapeController = dynamic_cast(m_d->imageView->document()->shapeController()); Q_ASSERT(shapeController); KisDummiesFacadeBase *dummiesFacade = dynamic_cast(m_d->imageView->document()->shapeController()); Q_ASSERT(dummiesFacade); const bool copyNode = false; KisImageSP image = m_d->view->image(); KisNodeDummy *parentDummy = dummiesFacade->dummyForNode(activeNode); KisNodeDummy *aboveThisDummy = parentDummy ? parentDummy->lastChild() : 0; KisMimeData::insertMimeLayers(data, image, shapeController, parentDummy, aboveThisDummy, copyNode, nodeInsertionAdapter()); } void KisNodeManager::createQuickGroupImpl(KisNodeJugglerCompressed *juggler, const QString &overrideGroupName, KisNodeSP *newGroup, KisNodeSP *newLastChild) { KisNodeSP active = activeNode(); if (!active) return; KisImageSP image = m_d->view->image(); QString groupName = !overrideGroupName.isEmpty() ? overrideGroupName : image->nextLayerName(); KisGroupLayerSP group = new KisGroupLayer(image.data(), groupName, OPACITY_OPAQUE_U8); KisNodeList nodes1; nodes1 << group; KisNodeList nodes2; nodes2 = KisLayerUtils::sortMergableNodes(image->root(), selectedNodes()); KisLayerUtils::filterMergableNodes(nodes2); if (nodes2.size() == 0) return; if (KisLayerUtils::checkIsChildOf(active, nodes2)) { active = nodes2.first(); } KisNodeSP parent = active->parent(); KisNodeSP aboveThis = active; juggler->addNode(nodes1, parent, aboveThis); juggler->moveNode(nodes2, group, 0); *newGroup = group; *newLastChild = nodes2.last(); } void KisNodeManager::createQuickGroup() { KUndo2MagicString actionName = kundo2_i18n("Quick Group"); KisNodeJugglerCompressed *juggler = m_d->lazyGetJuggler(actionName); KisNodeSP parent; KisNodeSP above; createQuickGroupImpl(juggler, "", &parent, &above); } void KisNodeManager::createQuickClippingGroup() { KUndo2MagicString actionName = kundo2_i18n("Quick Clipping Group"); KisNodeJugglerCompressed *juggler = m_d->lazyGetJuggler(actionName); KisNodeSP parent; KisNodeSP above; KisImageSP image = m_d->view->image(); createQuickGroupImpl(juggler, image->nextLayerName(i18nc("default name for a clipping group layer", "Clipping Group")), &parent, &above); KisPaintLayerSP maskLayer = new KisPaintLayer(image.data(), i18nc("default name for quick clip group mask layer", "Mask Layer"), OPACITY_OPAQUE_U8, image->colorSpace()); maskLayer->disableAlphaChannel(true); juggler->addNode(KisNodeList() << maskLayer, parent, above); } void KisNodeManager::quickUngroup() { KisNodeSP active = activeNode(); if (!active) return; KisNodeSP parent = active->parent(); KisNodeSP aboveThis = active; KUndo2MagicString actionName = kundo2_i18n("Quick Ungroup"); if (parent && dynamic_cast(active.data())) { KisNodeList nodes = active->childNodes(QStringList(), KoProperties()); KisNodeJugglerCompressed *juggler = m_d->lazyGetJuggler(actionName); juggler->moveNode(nodes, parent, active); juggler->removeNode(KisNodeList() << active); } else if (parent && parent->parent()) { KisNodeSP grandParent = parent->parent(); KisNodeList allChildNodes = parent->childNodes(QStringList(), KoProperties()); KisNodeList allSelectedNodes = selectedNodes(); const bool removeParent = KritaUtils::compareListsUnordered(allChildNodes, allSelectedNodes); KisNodeJugglerCompressed *juggler = m_d->lazyGetJuggler(actionName); juggler->moveNode(allSelectedNodes, grandParent, parent); if (removeParent) { juggler->removeNode(KisNodeList() << parent); } } } void KisNodeManager::selectLayersImpl(const KoProperties &props, const KoProperties &invertedProps) { KisImageSP image = m_d->view->image(); KisNodeList nodes = KisLayerUtils::findNodesWithProps(image->root(), props, true); KisNodeList selectedNodes = this->selectedNodes(); if (KritaUtils::compareListsUnordered(nodes, selectedNodes)) { nodes = KisLayerUtils::findNodesWithProps(image->root(), invertedProps, true); } if (!nodes.isEmpty()) { slotImageRequestNodeReselection(nodes.last(), nodes); } } void KisNodeManager::selectAllNodes() { KoProperties props; selectLayersImpl(props, props); } void KisNodeManager::selectVisibleNodes() { KoProperties props; props.setProperty("visible", true); KoProperties invertedProps; invertedProps.setProperty("visible", false); selectLayersImpl(props, invertedProps); } void KisNodeManager::selectLockedNodes() { KoProperties props; props.setProperty("locked", true); KoProperties invertedProps; invertedProps.setProperty("locked", false); selectLayersImpl(props, invertedProps); } void KisNodeManager::selectInvisibleNodes() { KoProperties props; props.setProperty("visible", false); KoProperties invertedProps; invertedProps.setProperty("visible", true); selectLayersImpl(props, invertedProps); } void KisNodeManager::selectUnlockedNodes() { KoProperties props; props.setProperty("locked", false); KoProperties invertedProps; invertedProps.setProperty("locked", true); selectLayersImpl(props, invertedProps); } diff --git a/libs/ui/kis_node_manager.h b/libs/ui/kis_node_manager.h index b36d5e60b1..78710fa48d 100644 --- a/libs/ui/kis_node_manager.h +++ b/libs/ui/kis_node_manager.h @@ -1,281 +1,281 @@ /* * 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. */ #ifndef KIS_NODE_MANAGER #define KIS_NODE_MANAGER #include #include #include #include "kis_types.h" #include "kis_base_node.h" #include "kis_image.h" #include class KActionCollection; class KoCompositeOp; class KoColorSpace; class KUndo2MagicString; class KisFilterStrategy; class KisViewManager; class KisActionManager; class KisView; class KisNodeSelectionAdapter; class KisNodeInsertionAdapter; class KisNodeDisplayModeAdapter; class KisNodeJugglerCompressed; class KoProperties; /** * The node manager passes requests for new layers or masks on to the mask and layer * managers. */ class KRITAUI_EXPORT KisNodeManager : public QObject { Q_OBJECT public: KisNodeManager(KisViewManager * view); ~KisNodeManager() override; void setView(QPointerimageView); Q_SIGNALS: /// emitted whenever a node is selected. void sigNodeActivated(KisNodeSP node); /// for the layer box: this sets the current node in the layerbox /// without telling the node manager that the node is activated, /// preventing loops (I think...) void sigUiNeedChangeActiveNode(KisNodeSP node); void sigUiNeedChangeSelectedNodes(const KisNodeList &nodes); public: void setup(KActionCollection * collection, KisActionManager* actionManager); void updateGUI(); /// Convenience function to get the active layer or mask KisNodeSP activeNode(); /// convenience function to get the active layer. If a mask is /// active, it's parent layer is the active layer. KisLayerSP activeLayer(); /// Get the paint device the user wants to paint on now KisPaintDeviceSP activePaintDevice(); /** * @return the active color space used for composition, meaning the color space * of the active mask, or the color space of the parent of the active layer */ const KoColorSpace* activeColorSpace(); /** * Sets the name for the node in a universal way (masks/layers) */ void setNodeName(KisNodeSP node, const QString &name); /** * Sets opacity for the node in a universal way (masks/layers) */ void setNodeOpacity(KisNodeSP node, qint32 opacity); /** * Sets compositeOp for the node in a universal way (masks/layers) */ void setNodeCompositeOp(KisNodeSP node, const KoCompositeOp* compositeOp); KisNodeList selectedNodes(); KisNodeSelectionAdapter* nodeSelectionAdapter() const; KisNodeInsertionAdapter* nodeInsertionAdapter() const; KisNodeDisplayModeAdapter* nodeDisplayModeAdapter() const; static bool isNodeHidden(KisNodeSP node, bool isGlobalSelectionHidden); bool trySetNodeProperties(KisNodeSP node, KisImageSP image, KisBaseNode::PropertyList properties) const; public Q_SLOTS: /** * Explicitly activates \p node * The UI will be noticed that active node has been changed. * Both sigNodeActivated and sigUiNeedChangeActiveNode are emitted. * * WARNING: normally you needn't call this method manually. It is * automatically called when a node is added to the graph. If you * have some special cases when you need to activate a node, consider * adding them to KisDummiesFacadeBase instead. Calling this method * directly should be the last resort. * * \see slotUiActivatedNode for comparison */ void slotNonUiActivatedNode(KisNodeSP node); /** * Activates \p node. * All non-ui listeners are notified with sigNodeActivated, * sigUiNeedChangeActiveNode is *not* emitted. * * \see activateNode */ void slotUiActivatedNode(KisNodeSP node); /** * Adds a list of nodes without searching appropriate position for * it. You *must* ensure that the nodes are allowed to be added * to the parent, otherwise you'll get an assert. */ void addNodesDirect(KisNodeList nodes, KisNodeSP parent, KisNodeSP aboveThis); /** * Moves a list of nodes without searching appropriate position * for it. You *must* ensure that the nodes are allowed to be * added to the parent, otherwise you'll get an assert. */ void moveNodesDirect(KisNodeList nodes, KisNodeSP parent, KisNodeSP aboveThis); /** * Copies a list of nodes without searching appropriate position * for it. You *must* ensure that the nodes are allowed to be * added to the parent, otherwise you'll get an assert. */ void copyNodesDirect(KisNodeList nodes, KisNodeSP parent, KisNodeSP aboveThis); /** * Create new layer from actually visible */ void createFromVisible(); void slotPinToTimeline(bool value); // Isolation Mode.. void toggleIsolateActiveNode(); void setIsolateActiveLayerMode(bool checked); void setIsolateActiveGroupMode(bool checked); - void changeIsolationMode(KisImage::IsolationMode mode); + void changeIsolationMode(bool isolateActiveLayer, bool isolateActiveGroup); /** * Updates the isolation mode as active node context changes. */ void updateIsolationMode(); void reinitializeIsolationActionGroup(); // General Node Management.. void moveNodeAt(KisNodeSP node, KisNodeSP parent, int index); KisNodeSP createNode(const QString& nodeType, bool quiet = false, KisPaintDeviceSP copyFrom = 0); void convertNode(const QString &nodeType); void nodesUpdated(); void nodeProperties(KisNodeSP node); /// pop up a window for changing the source of the selected Clone Layers void changeCloneSource(); void nodeOpacityChanged(qreal opacity); void nodeCompositeOpChanged(const KoCompositeOp* op); void duplicateActiveNode(); void removeNode(); void mirrorNodeX(); void mirrorNodeY(); void mirrorAllNodesX(); void mirrorAllNodesY(); void mirrorNode(KisNodeSP node, const KUndo2MagicString& commandName, Qt::Orientation orientation, KisSelectionSP selection); void activateNextNode(bool siblingsOnly = false); void activateNextSiblingNode(); void activatePreviousNode(bool siblingsOnly = false); void activatePreviousSiblingNode(); void switchToPreviouslyActiveNode(); /** * move the active node up the nodestack. */ void raiseNode(); /** * move the active node down the nodestack */ void lowerNode(); void saveNodeAsImage(); void saveVectorLayerAsImage(); void slotSplitAlphaIntoMask(); void slotSplitAlphaWrite(); void slotSplitAlphaSaveMerged(); void toggleLock(); void toggleVisibility(); void toggleAlphaLock(); void toggleInheritAlpha(); /** * @brief slotSetSelectedNodes set the list of nodes selected in the layerbox. Selected nodes are not necessarily active nodes. * @param nodes the selected nodes */ void slotSetSelectedNodes(const KisNodeList &nodes); void slotImageRequestNodeReselection(KisNodeSP activeNode, const KisNodeList &selectedNodes); void cutLayersToClipboard(); void copyLayersToClipboard(); void pasteLayersFromClipboard(); void createQuickGroup(); void createQuickClippingGroup(); void quickUngroup(); void selectAllNodes(); void selectVisibleNodes(); void selectLockedNodes(); void selectInvisibleNodes(); void selectUnlockedNodes(); public: void removeSingleNode(KisNodeSP node); KisLayerSP createPaintLayer(); private: /** * Scales opacity from the range 0...1 * to the integer range 0...255 */ qint32 convertOpacityToInt(qreal opacity); void removeSelectedNodes(KisNodeList selectedNodes); void slotSomethingActivatedNodeImpl(KisNodeSP node); void createQuickGroupImpl(KisNodeJugglerCompressed *juggler, const QString &overrideGroupName, KisNodeSP *newGroup, KisNodeSP *newLastChild); void selectLayersImpl(const KoProperties &props, const KoProperties &invertedProps); struct Private; Private * const m_d; }; #endif