diff --git a/libs/image/kis_group_layer.cc b/libs/image/kis_group_layer.cc index 9ccaf0deea..07a63e5d4e 100644 --- a/libs/image/kis_group_layer.cc +++ b/libs/image/kis_group_layer.cc @@ -1,400 +1,402 @@ /* * Copyright (c) 2005 C. Boemann * Copyright (c) 2007 Boudewijn Rempt * Copyright (c) 2009 Dmitry Kazakov * * 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_group_layer.h" #include #include #include #include #include #include "kis_node_visitor.h" #include "kis_processing_visitor.h" #include "kis_debug.h" #include "kis_image.h" #include "kis_paint_device.h" #include "kis_default_bounds.h" #include "kis_clone_layer.h" #include "kis_selection_mask.h" #include "kis_psd_layer_style.h" #include "kis_layer_properties_icons.h" struct Q_DECL_HIDDEN KisGroupLayer::Private { public: Private() : paintDevice(0) , x(0) , y(0) , passThroughMode(false) { } KisPaintDeviceSP paintDevice; qint32 x; qint32 y; bool passThroughMode; }; KisGroupLayer::KisGroupLayer(KisImageWSP image, const QString &name, quint8 opacity) : KisLayer(image, name, opacity), m_d(new Private()) { resetCache(); } KisGroupLayer::KisGroupLayer(const KisGroupLayer &rhs) : KisLayer(rhs), m_d(new Private()) { m_d->paintDevice = new KisPaintDevice(*rhs.m_d->paintDevice.data()); m_d->x = rhs.m_d->x; m_d->y = rhs.m_d->y; m_d->paintDevice->setDefaultPixel(const_cast(&rhs)->m_d->paintDevice->defaultPixel()); m_d->paintDevice->setProjectionDevice(true); m_d->passThroughMode = rhs.passThroughMode(); } KisGroupLayer::~KisGroupLayer() { delete m_d; } bool KisGroupLayer::checkCloneLayer(KisCloneLayerSP clone) const { KisNodeSP source = clone->copyFrom(); if (source) { if(!allowAsChild(source)) return false; if (source->inherits("KisGroupLayer")) { KisNodeSP newParent = const_cast(this); while (newParent) { if (newParent == source) { return false; } newParent = newParent->parent(); } } } return true; } bool KisGroupLayer::checkNodeRecursively(KisNodeSP node) const { KisCloneLayerSP cloneLayer = dynamic_cast(node.data()); if(cloneLayer) { return checkCloneLayer(cloneLayer); } else if (node->inherits("KisGroupLayer")) { KisNodeSP child = node->firstChild(); while (child) { if (!checkNodeRecursively(child)) { return false; } child = child->nextSibling(); } } return true; } bool KisGroupLayer::allowAsChild(KisNodeSP node) const { return checkNodeRecursively(node) && (parent() || (node->inherits("KisSelectionMask") && !selectionMask()) || !node->inherits("KisMask")); } const KoColorSpace * KisGroupLayer::colorSpace() const { return m_d->paintDevice->colorSpace(); } QIcon KisGroupLayer::icon() const { return KisIconUtils::loadIcon("groupLayer"); } void KisGroupLayer::setImage(KisImageWSP image) { m_d->paintDevice->setDefaultBounds(new KisDefaultBounds(image)); KisLayer::setImage(image); } KisLayerSP KisGroupLayer::createMergedLayerTemplate(KisLayerSP prevLayer) { KisGroupLayer *prevGroup = dynamic_cast(prevLayer.data()); if (prevGroup && canMergeAndKeepBlendOptions(prevLayer)) { KisSharedPtr merged(new KisGroupLayer(*prevGroup)); KisNodeSP child, cloned; for (child = firstChild(); child; child = child->nextSibling()) { cloned = child->clone(); image()->addNode(cloned, merged); } - image()->refreshGraphAsync(merged); + if (!merged->passThroughMode()) { + image()->refreshGraphAsync(merged); + } return merged; } else return KisLayer::createMergedLayerTemplate(prevLayer); } void KisGroupLayer::fillMergedLayerTemplate(KisLayerSP dstLayer, KisLayerSP prevLayer) { if (!dynamic_cast(dstLayer.data())) { KisLayer::fillMergedLayerTemplate(dstLayer, prevLayer); } } void KisGroupLayer::resetCache(const KoColorSpace *colorSpace) { if (!colorSpace) colorSpace = image()->colorSpace(); Q_ASSERT(colorSpace); if (!m_d->paintDevice) { KisPaintDeviceSP dev = new KisPaintDevice(this, colorSpace, new KisDefaultBounds(image())); dev->setX(this->x()); dev->setY(this->y()); m_d->paintDevice = dev; m_d->paintDevice->setProjectionDevice(true); } else if(*m_d->paintDevice->colorSpace() != *colorSpace) { KisPaintDeviceSP dev = new KisPaintDevice(this, colorSpace, new KisDefaultBounds(image())); dev->setX(this->x()); dev->setY(this->y()); dev->setDefaultPixel(m_d->paintDevice->defaultPixel()); m_d->paintDevice = dev; m_d->paintDevice->setProjectionDevice(true); } else { m_d->paintDevice->clear(); } } KisLayer* KisGroupLayer::onlyMeaningfulChild() const { KisNode *child = firstChild().data(); KisLayer *onlyLayer = 0; while (child) { KisLayer *layer = qobject_cast(child); if (layer) { if (onlyLayer) return 0; onlyLayer = layer; } child = child->nextSibling().data(); } return onlyLayer; } KisPaintDeviceSP KisGroupLayer::tryObligeChild() const { const KisLayer *child = onlyMeaningfulChild(); if (child && child->channelFlags().isEmpty() && child->projection() && child->visible() && (child->compositeOpId() == COMPOSITE_OVER || child->compositeOpId() == COMPOSITE_ALPHA_DARKEN || child->compositeOpId() == COMPOSITE_COPY) && child->opacity() == OPACITY_OPAQUE_U8 && *child->projection()->colorSpace() == *colorSpace() && !child->layerStyle()) { quint8 defaultOpacity = m_d->paintDevice->defaultPixel().opacityU8(); if(defaultOpacity == OPACITY_TRANSPARENT_U8) { return child->projection(); } } return 0; } KisPaintDeviceSP KisGroupLayer::original() const { /** * We are too lazy! Let's our children work for us. * Try to use children's paintDevice if it's the only * one in stack and meets some conditions */ KisPaintDeviceSP realOriginal = tryObligeChild(); if (!realOriginal) { if (!childCount() && !m_d->paintDevice->extent().isEmpty()) { m_d->paintDevice->clear(); } realOriginal = m_d->paintDevice; } return realOriginal; } KisPaintDeviceSP KisGroupLayer::paintDevice() const { return 0; } bool KisGroupLayer::projectionIsValid() const { return !tryObligeChild(); } void KisGroupLayer::setDefaultProjectionColor(KoColor color) { m_d->paintDevice->setDefaultPixel(color); } KoColor KisGroupLayer::defaultProjectionColor() const { KoColor color(m_d->paintDevice->defaultPixel(), m_d->paintDevice->colorSpace()); return color; } bool KisGroupLayer::passThroughMode() const { return m_d->passThroughMode; } void KisGroupLayer::setPassThroughMode(bool value) { if (m_d->passThroughMode == value) return; m_d->passThroughMode = value; baseNodeChangedCallback(); baseNodeInvalidateAllFramesCallback(); } KisBaseNode::PropertyList KisGroupLayer::sectionModelProperties() const { KisBaseNode::PropertyList l = KisLayer::sectionModelProperties(); l << KisLayerPropertiesIcons::getProperty(KisLayerPropertiesIcons::passThrough, passThroughMode()); return l; } void KisGroupLayer::setSectionModelProperties(const KisBaseNode::PropertyList &properties) { Q_FOREACH (const KisBaseNode::Property &property, properties) { if (property.name == i18n("Pass Through")) { setPassThroughMode(property.state.toBool()); } } KisLayer::setSectionModelProperties(properties); } bool KisGroupLayer::accept(KisNodeVisitor &v) { return v.visit(this); } void KisGroupLayer::accept(KisProcessingVisitor &visitor, KisUndoAdapter *undoAdapter) { return visitor.visit(this, undoAdapter); } qint32 KisGroupLayer::x() const { return m_d->paintDevice ? m_d->paintDevice->x() : m_d->x; } qint32 KisGroupLayer::y() const { return m_d->paintDevice ? m_d->paintDevice->y() : m_d->y; } void KisGroupLayer::setX(qint32 x) { m_d->x = x; if(m_d->paintDevice) { m_d->paintDevice->setX(x); } } void KisGroupLayer::setY(qint32 y) { m_d->y = y; if(m_d->paintDevice) { m_d->paintDevice->setY(y); } } struct ExtentPolicy { inline QRect operator() (const KisNode *node) { return node->extent(); } }; struct ExactBoundsPolicy { inline QRect operator() (const KisNode *node) { return node->exactBounds(); } }; template QRect collectRects(const KisNode *node, MetricPolicy policy) { QRect accumulator; const KisNode *child = node->firstChild(); while (child) { if (!qobject_cast(child)) { accumulator |= policy(child); } child = child->nextSibling(); } return accumulator; } QRect KisGroupLayer::extent() const { return m_d->passThroughMode ? collectRects(this, ExtentPolicy()) : KisLayer::extent(); } QRect KisGroupLayer::exactBounds() const { return m_d->passThroughMode ? collectRects(this, ExactBoundsPolicy()) : KisLayer::exactBounds(); } diff --git a/libs/image/kis_layer_utils.cpp b/libs/image/kis_layer_utils.cpp index da96b08674..a6aa2ab531 100644 --- a/libs/image/kis_layer_utils.cpp +++ b/libs/image/kis_layer_utils.cpp @@ -1,1304 +1,1344 @@ /* * Copyright (c) 2015 Dmitry Kazakov * * 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_layer_utils.h" #include #include #include #include "kis_painter.h" #include "kis_image.h" #include "kis_node.h" #include "kis_layer.h" #include "kis_paint_layer.h" #include "kis_clone_layer.h" #include "kis_group_layer.h" #include "kis_selection.h" #include "kis_selection_mask.h" #include "kis_meta_data_merge_strategy.h" #include #include "commands/kis_image_layer_add_command.h" #include "commands/kis_image_layer_remove_command.h" #include "commands/kis_image_layer_move_command.h" #include "commands/kis_image_change_layers_command.h" #include "commands_new/kis_activate_selection_mask_command.h" #include "kis_abstract_projection_plane.h" #include "kis_processing_applicator.h" #include "kis_image_animation_interface.h" #include "kis_keyframe_channel.h" #include "kis_command_utils.h" #include "kis_processing_applicator.h" #include "commands_new/kis_change_projection_color_command.h" #include "kis_layer_properties_icons.h" #include "lazybrush/kis_colorize_mask.h" #include "commands/kis_node_property_list_command.h" #include namespace KisLayerUtils { void fetchSelectionMasks(KisNodeList mergedNodes, QVector &selectionMasks) { foreach (KisNodeSP node, mergedNodes) { KisLayerSP layer = qobject_cast(node.data()); KisSelectionMaskSP mask; if (layer && (mask = layer->selectionMask())) { selectionMasks.append(mask); } } } struct MergeDownInfoBase { MergeDownInfoBase(KisImageSP _image) : image(_image), storage(new SwitchFrameCommand::SharedStorage()) { } virtual ~MergeDownInfoBase() {} KisImageWSP image; QVector selectionMasks; KisNodeSP dstNode; SwitchFrameCommand::SharedStorageSP storage; QSet frames; virtual KisNodeList allSrcNodes() = 0; virtual KisLayerSP dstLayer() { return 0; } }; struct MergeDownInfo : public MergeDownInfoBase { MergeDownInfo(KisImageSP _image, KisLayerSP _prevLayer, KisLayerSP _currLayer) : MergeDownInfoBase(_image), prevLayer(_prevLayer), currLayer(_currLayer) { frames = fetchLayerFramesRecursive(prevLayer) | fetchLayerFramesRecursive(currLayer); } KisLayerSP prevLayer; KisLayerSP currLayer; KisNodeList allSrcNodes() override { KisNodeList mergedNodes; mergedNodes << currLayer; mergedNodes << prevLayer; return mergedNodes; } KisLayerSP dstLayer() override { return qobject_cast(dstNode.data()); } }; struct MergeMultipleInfo : public MergeDownInfoBase { MergeMultipleInfo(KisImageSP _image, KisNodeList _mergedNodes) : MergeDownInfoBase(_image), mergedNodes(_mergedNodes) { foreach (KisNodeSP node, mergedNodes) { frames |= fetchLayerFramesRecursive(node); } } KisNodeList mergedNodes; KisNodeList allSrcNodes() override { return mergedNodes; } }; typedef QSharedPointer MergeDownInfoBaseSP; typedef QSharedPointer MergeDownInfoSP; typedef QSharedPointer MergeMultipleInfoSP; struct FillSelectionMasks : public KUndo2Command { FillSelectionMasks(MergeDownInfoBaseSP info) : m_info(info) {} void redo() override { fetchSelectionMasks(m_info->allSrcNodes(), m_info->selectionMasks); } private: MergeDownInfoBaseSP m_info; }; struct DisableColorizeKeyStrokes : public KisCommandUtils::AggregateCommand { DisableColorizeKeyStrokes(MergeDownInfoBaseSP info) : m_info(info) {} void populateChildCommands() override { Q_FOREACH (KisNodeSP node, m_info->allSrcNodes()) { recursiveApplyNodes(node, [this] (KisNodeSP node) { if (dynamic_cast(node.data()) && KisLayerPropertiesIcons::nodeProperty(node, KisLayerPropertiesIcons::colorizeEditKeyStrokes, true).toBool()) { KisBaseNode::PropertyList props = node->sectionModelProperties(); KisLayerPropertiesIcons::setNodeProperty(&props, KisLayerPropertiesIcons::colorizeEditKeyStrokes, false); addCommand(new KisNodePropertyListCommand(node, props)); } }); } } private: MergeDownInfoBaseSP m_info; }; struct DisableOnionSkins : public KisCommandUtils::AggregateCommand { DisableOnionSkins(MergeDownInfoBaseSP info) : m_info(info) {} void populateChildCommands() override { Q_FOREACH (KisNodeSP node, m_info->allSrcNodes()) { recursiveApplyNodes(node, [this] (KisNodeSP node) { if (KisLayerPropertiesIcons::nodeProperty(node, KisLayerPropertiesIcons::onionSkins, false).toBool()) { KisBaseNode::PropertyList props = node->sectionModelProperties(); KisLayerPropertiesIcons::setNodeProperty(&props, KisLayerPropertiesIcons::onionSkins, false); addCommand(new KisNodePropertyListCommand(node, props)); } }); } } private: MergeDownInfoBaseSP m_info; }; + struct DisablePassThroughForHeadsOnly : public KisCommandUtils::AggregateCommand { + DisablePassThroughForHeadsOnly(MergeDownInfoBaseSP info, bool skipIfDstIsGroup = false) + : m_info(info), + m_skipIfDstIsGroup(skipIfDstIsGroup) + { + } + + void populateChildCommands() override { + if (m_skipIfDstIsGroup && + m_info->dstLayer() && + m_info->dstLayer()->inherits("KisGroupLayer")) { + + return; + } + + + Q_FOREACH (KisNodeSP node, m_info->allSrcNodes()) { + if (KisLayerPropertiesIcons::nodeProperty(node, KisLayerPropertiesIcons::passThrough, false).toBool()) { + + KisBaseNode::PropertyList props = node->sectionModelProperties(); + KisLayerPropertiesIcons::setNodeProperty(&props, + KisLayerPropertiesIcons::passThrough, + false); + + addCommand(new KisNodePropertyListCommand(node, props)); + } + } + } + + private: + MergeDownInfoBaseSP m_info; + bool m_skipIfDstIsGroup; + }; + struct RefreshHiddenAreas : public KUndo2Command { RefreshHiddenAreas(MergeDownInfoBaseSP info) : m_info(info) {} void redo() override { KisImageAnimationInterface *interface = m_info->image->animationInterface(); const QRect preparedRect = !interface->externalFrameActive() ? m_info->image->bounds() : QRect(); foreach (KisNodeSP node, m_info->allSrcNodes()) { refreshHiddenAreaAsync(node, preparedRect); } } private: QRect realNodeExactBounds(KisNodeSP rootNode, QRect currentRect = QRect()) { KisNodeSP node = rootNode->firstChild(); while(node) { currentRect |= realNodeExactBounds(node, currentRect); node = node->nextSibling(); } // TODO: it would be better to count up changeRect inside // node's extent() method currentRect |= rootNode->projectionPlane()->changeRect(rootNode->exactBounds()); return currentRect; } void refreshHiddenAreaAsync(KisNodeSP rootNode, const QRect &preparedArea) { QRect realNodeRect = realNodeExactBounds(rootNode); if (!preparedArea.contains(realNodeRect)) { QRegion dirtyRegion = realNodeRect; dirtyRegion -= preparedArea; foreach(const QRect &rc, dirtyRegion.rects()) { m_info->image->refreshGraphAsync(rootNode, rc, realNodeRect); } } } private: MergeDownInfoBaseSP m_info; }; struct RefreshDelayedUpdateLayers : public KUndo2Command { RefreshDelayedUpdateLayers(MergeDownInfoBaseSP info) : m_info(info) {} void redo() override { foreach (KisNodeSP node, m_info->allSrcNodes()) { recursiveApplyNodes(node, [] (KisNodeSP node) { KisDelayedUpdateNodeInterface *delayedUpdate = dynamic_cast(node.data()); if (delayedUpdate) { delayedUpdate->forceUpdateTimedNode(); } }); } } private: MergeDownInfoBaseSP m_info; }; struct KeepMergedNodesSelected : public KisCommandUtils::AggregateCommand { KeepMergedNodesSelected(MergeDownInfoSP info, bool finalizing) : m_singleInfo(info), m_finalizing(finalizing) {} KeepMergedNodesSelected(MergeMultipleInfoSP info, KisNodeSP putAfter, bool finalizing) : m_multipleInfo(info), m_finalizing(finalizing), m_putAfter(putAfter) {} void populateChildCommands() override { KisNodeSP prevNode; KisNodeSP nextNode; KisNodeList prevSelection; KisNodeList nextSelection; KisImageSP image; if (m_singleInfo) { prevNode = m_singleInfo->currLayer; nextNode = m_singleInfo->dstNode; image = m_singleInfo->image; } else if (m_multipleInfo) { prevNode = m_putAfter; nextNode = m_multipleInfo->dstNode; prevSelection = m_multipleInfo->allSrcNodes(); image = m_multipleInfo->image; } if (!m_finalizing) { addCommand(new KeepNodesSelectedCommand(prevSelection, KisNodeList(), prevNode, KisNodeSP(), image, false)); } else { addCommand(new KeepNodesSelectedCommand(KisNodeList(), nextSelection, KisNodeSP(), nextNode, image, true)); } } private: MergeDownInfoSP m_singleInfo; MergeMultipleInfoSP m_multipleInfo; bool m_finalizing; KisNodeSP m_putAfter; }; struct CreateMergedLayer : public KisCommandUtils::AggregateCommand { CreateMergedLayer(MergeDownInfoSP info) : m_info(info) {} void populateChildCommands() override { // actual merging done by KisLayer::createMergedLayer (or specialized decendant) m_info->dstNode = m_info->currLayer->createMergedLayerTemplate(m_info->prevLayer); if (m_info->frames.size() > 0) { m_info->dstNode->enableAnimation(); m_info->dstNode->getKeyframeChannel(KisKeyframeChannel::Content.id(), true); } } private: MergeDownInfoSP m_info; }; struct CreateMergedLayerMultiple : public KisCommandUtils::AggregateCommand { CreateMergedLayerMultiple(MergeMultipleInfoSP info, const QString name = QString() ) : m_info(info), m_name(name) {} void populateChildCommands() override { QString mergedLayerName; if (m_name.isEmpty()){ const QString mergedLayerSuffix = i18n("Merged"); mergedLayerName = m_info->mergedNodes.first()->name(); if (!mergedLayerName.endsWith(mergedLayerSuffix)) { mergedLayerName = QString("%1 %2") .arg(mergedLayerName).arg(mergedLayerSuffix); } } else { mergedLayerName = m_name; } m_info->dstNode = new KisPaintLayer(m_info->image, mergedLayerName, OPACITY_OPAQUE_U8); if (m_info->frames.size() > 0) { m_info->dstNode->enableAnimation(); m_info->dstNode->getKeyframeChannel(KisKeyframeChannel::Content.id(), true); } QString compositeOpId; QBitArray channelFlags; bool compositionVaries = false; foreach (KisNodeSP node, m_info->allSrcNodes()) { if (compositeOpId.isEmpty()) { compositeOpId = node->compositeOpId(); } else if (compositeOpId != node->compositeOpId()) { compositionVaries = true; break; } KisLayerSP layer = qobject_cast(node.data()); if (layer && layer->layerStyle()) { compositionVaries = true; break; } } if (!compositionVaries) { if (!compositeOpId.isEmpty()) { m_info->dstNode->setCompositeOpId(compositeOpId); } if (m_info->dstLayer() && !channelFlags.isEmpty()) { m_info->dstLayer()->setChannelFlags(channelFlags); } } } private: MergeMultipleInfoSP m_info; QString m_name; }; struct MergeLayers : public KisCommandUtils::AggregateCommand { MergeLayers(MergeDownInfoSP info) : m_info(info) {} void populateChildCommands() override { // actual merging done by KisLayer::createMergedLayer (or specialized decendant) m_info->currLayer->fillMergedLayerTemplate(m_info->dstLayer(), m_info->prevLayer); } private: MergeDownInfoSP m_info; }; struct MergeLayersMultiple : public KisCommandUtils::AggregateCommand { MergeLayersMultiple(MergeMultipleInfoSP info) : m_info(info) {} void populateChildCommands() override { KisPainter gc(m_info->dstNode->paintDevice()); foreach (KisNodeSP node, m_info->allSrcNodes()) { QRect rc = node->exactBounds() | m_info->image->bounds(); node->projectionPlane()->apply(&gc, rc); } } private: MergeMultipleInfoSP m_info; }; struct MergeMetaData : public KUndo2Command { MergeMetaData(MergeDownInfoSP info, const KisMetaData::MergeStrategy* strategy) : m_info(info), m_strategy(strategy) {} void redo() override { QRect layerProjectionExtent = m_info->currLayer->projection()->extent(); QRect prevLayerProjectionExtent = m_info->prevLayer->projection()->extent(); int prevLayerArea = prevLayerProjectionExtent.width() * prevLayerProjectionExtent.height(); int layerArea = layerProjectionExtent.width() * layerProjectionExtent.height(); QList scores; double norm = qMax(prevLayerArea, layerArea); scores.append(prevLayerArea / norm); scores.append(layerArea / norm); QList srcs; srcs.append(m_info->prevLayer->metaData()); srcs.append(m_info->currLayer->metaData()); m_strategy->merge(m_info->dstLayer()->metaData(), srcs, scores); } private: MergeDownInfoSP m_info; const KisMetaData::MergeStrategy *m_strategy; }; KeepNodesSelectedCommand::KeepNodesSelectedCommand(const KisNodeList &selectedBefore, const KisNodeList &selectedAfter, KisNodeSP activeBefore, KisNodeSP activeAfter, KisImageSP image, bool finalize, KUndo2Command *parent) : FlipFlopCommand(finalize, parent), m_selectedBefore(selectedBefore), m_selectedAfter(selectedAfter), m_activeBefore(activeBefore), m_activeAfter(activeAfter), m_image(image) { } void KeepNodesSelectedCommand::end() { KisImageSignalType type; if (isFinalizing()) { type = ComplexNodeReselectionSignal(m_activeAfter, m_selectedAfter); } else { type = ComplexNodeReselectionSignal(m_activeBefore, m_selectedBefore); } m_image->signalRouter()->emitNotification(type); } KisLayerSP constructDefaultLayer(KisImageSP image) { return new KisPaintLayer(image.data(), image->nextLayerName(), OPACITY_OPAQUE_U8, image->colorSpace()); } RemoveNodeHelper::~RemoveNodeHelper() { } /** * The removal of two nodes in one go may be a bit tricky, because one * of them may be the clone of another. If we remove the source of a * clone layer, it will reincarnate into a paint layer. In this case * the pointer to the second layer will be lost. * * That's why we need to care about the order of the nodes removal: * the clone --- first, the source --- last. */ void RemoveNodeHelper::safeRemoveMultipleNodes(KisNodeList nodes, KisImageSP image) { const bool lastLayer = scanForLastLayer(image, nodes); while (!nodes.isEmpty()) { KisNodeList::iterator it = nodes.begin(); while (it != nodes.end()) { if (!checkIsSourceForClone(*it, nodes)) { KisNodeSP node = *it; addCommandImpl(new KisImageLayerRemoveCommand(image, node, false, true)); it = nodes.erase(it); } else { ++it; } } } if (lastLayer) { KisLayerSP newLayer = constructDefaultLayer(image); addCommandImpl(new KisImageLayerAddCommand(image, newLayer, image->root(), KisNodeSP(), false, false)); } } bool RemoveNodeHelper::checkIsSourceForClone(KisNodeSP src, const KisNodeList &nodes) { foreach (KisNodeSP node, nodes) { if (node == src) continue; KisCloneLayer *clone = dynamic_cast(node.data()); if (clone && KisNodeSP(clone->copyFrom()) == src) { return true; } } return false; } bool RemoveNodeHelper::scanForLastLayer(KisImageWSP image, KisNodeList nodesToRemove) { bool removeLayers = false; Q_FOREACH(KisNodeSP nodeToRemove, nodesToRemove) { if (qobject_cast(nodeToRemove.data())) { removeLayers = true; break; } } if (!removeLayers) return false; bool lastLayer = true; KisNodeSP node = image->root()->firstChild(); while (node) { if (!nodesToRemove.contains(node) && qobject_cast(node.data())) { lastLayer = false; break; } node = node->nextSibling(); } return lastLayer; } SimpleRemoveLayers::SimpleRemoveLayers(const KisNodeList &nodes, KisImageSP image) : m_nodes(nodes), m_image(image) { } void SimpleRemoveLayers::populateChildCommands() { if (m_nodes.isEmpty()) return; safeRemoveMultipleNodes(m_nodes, m_image); } void SimpleRemoveLayers::addCommandImpl(KUndo2Command *cmd) { addCommand(cmd); } struct InsertNode : public KisCommandUtils::AggregateCommand { InsertNode(MergeDownInfoBaseSP info, KisNodeSP putAfter) : m_info(info), m_putAfter(putAfter) {} void populateChildCommands() override { addCommand(new KisImageLayerAddCommand(m_info->image, m_info->dstNode, m_putAfter->parent(), m_putAfter, true, false)); } private: virtual void addCommandImpl(KUndo2Command *cmd) { addCommand(cmd); } private: MergeDownInfoBaseSP m_info; KisNodeSP m_putAfter; }; struct CleanUpNodes : private RemoveNodeHelper, public KisCommandUtils::AggregateCommand { CleanUpNodes(MergeDownInfoBaseSP info, KisNodeSP putAfter) : m_info(info), m_putAfter(putAfter) {} static void findPerfectParent(KisNodeList nodesToDelete, KisNodeSP &putAfter, KisNodeSP &parent) { if (!putAfter) { putAfter = nodesToDelete.last(); } // Add the new merged node on top of the active node -- checking // whether the parent is going to be deleted parent = putAfter->parent(); while (parent && nodesToDelete.contains(parent)) { parent = parent->parent(); } } void populateChildCommands() override { KisNodeList nodesToDelete = m_info->allSrcNodes(); KisNodeSP parent; findPerfectParent(nodesToDelete, m_putAfter, parent); if (!parent) { KisNodeSP oldRoot = m_info->image->root(); KisNodeSP newRoot(new KisGroupLayer(m_info->image, "root", OPACITY_OPAQUE_U8)); addCommand(new KisImageLayerAddCommand(m_info->image, m_info->dstNode, newRoot, KisNodeSP(), true, false)); addCommand(new KisImageChangeLayersCommand(m_info->image, oldRoot, newRoot)); } else { if (parent == m_putAfter->parent()) { addCommand(new KisImageLayerAddCommand(m_info->image, m_info->dstNode, parent, m_putAfter, true, false)); } else { addCommand(new KisImageLayerAddCommand(m_info->image, m_info->dstNode, parent, parent->lastChild(), true, false)); } reparentSelectionMasks(m_info->image, m_info->dstLayer(), m_info->selectionMasks); safeRemoveMultipleNodes(m_info->allSrcNodes(), m_info->image); } } private: void addCommandImpl(KUndo2Command *cmd) override { addCommand(cmd); } void reparentSelectionMasks(KisImageSP image, KisLayerSP newLayer, const QVector &selectionMasks) { foreach (KisSelectionMaskSP mask, selectionMasks) { addCommand(new KisImageLayerMoveCommand(image, mask, newLayer, newLayer->lastChild())); addCommand(new KisActivateSelectionMaskCommand(mask, false)); } } private: MergeDownInfoBaseSP m_info; KisNodeSP m_putAfter; }; SwitchFrameCommand::SharedStorage::~SharedStorage() { } SwitchFrameCommand::SwitchFrameCommand(KisImageSP image, int time, bool finalize, SharedStorageSP storage) : FlipFlopCommand(finalize), m_image(image), m_newTime(time), m_storage(storage) {} SwitchFrameCommand::~SwitchFrameCommand() {} void SwitchFrameCommand::init() { KisImageAnimationInterface *interface = m_image->animationInterface(); const int currentTime = interface->currentTime(); if (currentTime == m_newTime) { m_storage->value = m_newTime; return; } interface->image()->disableUIUpdates(); interface->saveAndResetCurrentTime(m_newTime, &m_storage->value); } void SwitchFrameCommand::end() { KisImageAnimationInterface *interface = m_image->animationInterface(); const int currentTime = interface->currentTime(); if (currentTime == m_storage->value) { return; } interface->restoreCurrentTime(&m_storage->value); interface->image()->enableUIUpdates(); } struct AddNewFrame : public KisCommandUtils::AggregateCommand { AddNewFrame(MergeDownInfoBaseSP info, int frame) : m_info(info), m_frame(frame) {} void populateChildCommands() override { KUndo2Command *cmd = new KisCommandUtils::SkipFirstRedoWrapper(); KisKeyframeChannel *channel = m_info->dstNode->getKeyframeChannel(KisKeyframeChannel::Content.id()); channel->addKeyframe(m_frame, cmd); addCommand(cmd); } private: MergeDownInfoBaseSP m_info; int m_frame; }; QSet fetchLayerFrames(KisNodeSP node) { KisKeyframeChannel *channel = node->getKeyframeChannel(KisKeyframeChannel::Content.id()); if (!channel) return QSet(); return channel->allKeyframeIds(); } QSet fetchLayerFramesRecursive(KisNodeSP rootNode) { QSet frames = fetchLayerFrames(rootNode); KisNodeSP node = rootNode->firstChild(); while(node) { frames |= fetchLayerFramesRecursive(node); node = node->nextSibling(); } return frames; } void updateFrameJobs(FrameJobs *jobs, KisNodeSP node) { QSet frames = fetchLayerFrames(node); if (frames.isEmpty()) { (*jobs)[0].insert(node); } else { foreach (int frame, frames) { (*jobs)[frame].insert(node); } } } void updateFrameJobsRecursive(FrameJobs *jobs, KisNodeSP rootNode) { updateFrameJobs(jobs, rootNode); KisNodeSP node = rootNode->firstChild(); while(node) { updateFrameJobsRecursive(jobs, node); node = node->nextSibling(); } } void mergeDown(KisImageSP image, KisLayerSP layer, const KisMetaData::MergeStrategy* strategy) { if (!layer->prevSibling()) return; // XXX: this breaks if we allow free mixing of masks and layers KisLayerSP prevLayer = qobject_cast(layer->prevSibling().data()); if (!prevLayer) return; if (!layer->visible() && !prevLayer->visible()) { return; } KisImageSignalVector emitSignals; emitSignals << ModifiedSignal; KisProcessingApplicator applicator(image, 0, KisProcessingApplicator::NONE, emitSignals, kundo2_i18n("Merge Down")); if (layer->visible() && prevLayer->visible()) { MergeDownInfoSP info(new MergeDownInfo(image, prevLayer, layer)); // disable key strokes on all colorize masks, all onion skins on // paint layers and wait until update is finished with a barrier applicator.applyCommand(new DisableColorizeKeyStrokes(info)); applicator.applyCommand(new DisableOnionSkins(info)); applicator.applyCommand(new KUndo2Command(), KisStrokeJobData::BARRIER); applicator.applyCommand(new KeepMergedNodesSelected(info, false)); applicator.applyCommand(new FillSelectionMasks(info)); applicator.applyCommand(new CreateMergedLayer(info), KisStrokeJobData::BARRIER); + // in two-layer mode we disable pass trhough only when the destination layer + // is not a group layer + applicator.applyCommand(new DisablePassThroughForHeadsOnly(info, true)); + applicator.applyCommand(new KUndo2Command(), KisStrokeJobData::BARRIER); + if (info->frames.size() > 0) { foreach (int frame, info->frames) { applicator.applyCommand(new SwitchFrameCommand(info->image, frame, false, info->storage)); applicator.applyCommand(new AddNewFrame(info, frame)); applicator.applyCommand(new RefreshHiddenAreas(info)); applicator.applyCommand(new RefreshDelayedUpdateLayers(info), KisStrokeJobData::BARRIER); applicator.applyCommand(new MergeLayers(info), KisStrokeJobData::BARRIER); applicator.applyCommand(new SwitchFrameCommand(info->image, frame, true, info->storage)); } } else { applicator.applyCommand(new RefreshHiddenAreas(info)); applicator.applyCommand(new RefreshDelayedUpdateLayers(info), KisStrokeJobData::BARRIER); applicator.applyCommand(new MergeLayers(info), KisStrokeJobData::BARRIER); } applicator.applyCommand(new MergeMetaData(info, strategy), KisStrokeJobData::BARRIER); applicator.applyCommand(new CleanUpNodes(info, layer), KisStrokeJobData::SEQUENTIAL, KisStrokeJobData::EXCLUSIVE); applicator.applyCommand(new KeepMergedNodesSelected(info, true)); } else if (layer->visible()) { applicator.applyCommand(new KeepNodesSelectedCommand(KisNodeList(), KisNodeList(), layer, KisNodeSP(), image, false)); applicator.applyCommand( new SimpleRemoveLayers(KisNodeList() << prevLayer, image), KisStrokeJobData::SEQUENTIAL, KisStrokeJobData::EXCLUSIVE); applicator.applyCommand(new KeepNodesSelectedCommand(KisNodeList(), KisNodeList(), KisNodeSP(), layer, image, true)); } else if (prevLayer->visible()) { applicator.applyCommand(new KeepNodesSelectedCommand(KisNodeList(), KisNodeList(), layer, KisNodeSP(), image, false)); applicator.applyCommand( new SimpleRemoveLayers(KisNodeList() << layer, image), KisStrokeJobData::SEQUENTIAL, KisStrokeJobData::EXCLUSIVE); applicator.applyCommand(new KeepNodesSelectedCommand(KisNodeList(), KisNodeList(), KisNodeSP(), prevLayer, image, true)); } applicator.end(); } bool checkIsChildOf(KisNodeSP node, const KisNodeList &parents) { KisNodeList nodeParents; KisNodeSP parent = node->parent(); while (parent) { nodeParents << parent; parent = parent->parent(); } foreach(KisNodeSP perspectiveParent, parents) { if (nodeParents.contains(perspectiveParent)) { return true; } } return false; } bool checkIsCloneOf(KisNodeSP node, const KisNodeList &nodes) { bool result = false; KisCloneLayer *clone = dynamic_cast(node.data()); if (clone) { KisNodeSP cloneSource = KisNodeSP(clone->copyFrom()); Q_FOREACH(KisNodeSP subtree, nodes) { result = recursiveFindNode(subtree, [cloneSource](KisNodeSP node) -> bool { return node == cloneSource; }); if (!result) { result = checkIsCloneOf(cloneSource, nodes); } if (result) { break; } } } return result; } void filterMergableNodes(KisNodeList &nodes, bool allowMasks) { KisNodeList::iterator it = nodes.begin(); while (it != nodes.end()) { if ((!allowMasks && !qobject_cast(it->data())) || checkIsChildOf(*it, nodes)) { qDebug() << "Skipping node" << ppVar((*it)->name()); it = nodes.erase(it); } else { ++it; } } } void sortMergableNodes(KisNodeSP root, KisNodeList &inputNodes, KisNodeList &outputNodes) { KisNodeList::iterator it = std::find(inputNodes.begin(), inputNodes.end(), root); if (it != inputNodes.end()) { outputNodes << *it; inputNodes.erase(it); } if (inputNodes.isEmpty()) { return; } KisNodeSP child = root->firstChild(); while (child) { sortMergableNodes(child, inputNodes, outputNodes); child = child->nextSibling(); } /** * By the end of recursion \p inputNodes must be empty */ KIS_ASSERT_RECOVER_NOOP(root->parent() || inputNodes.isEmpty()); } KisNodeList sortMergableNodes(KisNodeSP root, KisNodeList nodes) { KisNodeList result; sortMergableNodes(root, nodes, result); return result; } KisNodeList sortAndFilterMergableInternalNodes(KisNodeList nodes, bool allowMasks) { KIS_ASSERT_RECOVER(!nodes.isEmpty()) { return nodes; } KisNodeSP root; Q_FOREACH(KisNodeSP node, nodes) { KisNodeSP localRoot = node; while (localRoot->parent()) { localRoot = localRoot->parent(); } if (!root) { root = localRoot; } KIS_ASSERT_RECOVER(root == localRoot) { return nodes; } } KisNodeList result; sortMergableNodes(root, nodes, result); filterMergableNodes(result, allowMasks); return result; } void addCopyOfNameTag(KisNodeSP node) { const QString prefix = i18n("Copy of"); QString newName = node->name(); if (!newName.startsWith(prefix)) { newName = QString("%1 %2").arg(prefix).arg(newName); node->setName(newName); } } KisNodeList findNodesWithProps(KisNodeSP root, const KoProperties &props, bool excludeRoot) { KisNodeList nodes; if ((!excludeRoot || root->parent()) && root->check(props)) { nodes << root; } KisNodeSP node = root->firstChild(); while (node) { nodes += findNodesWithProps(node, props, excludeRoot); node = node->nextSibling(); } return nodes; } KisNodeList filterInvisibleNodes(const KisNodeList &nodes, KisNodeList *invisibleNodes, KisNodeSP *putAfter) { KIS_ASSERT_RECOVER(invisibleNodes) { return nodes; } KIS_ASSERT_RECOVER(putAfter) { return nodes; } KisNodeList visibleNodes; int putAfterIndex = -1; Q_FOREACH(KisNodeSP node, nodes) { if (node->visible()) { visibleNodes << node; } else { *invisibleNodes << node; if (node == *putAfter) { putAfterIndex = visibleNodes.size() - 1; } } } if (!visibleNodes.isEmpty() && putAfterIndex >= 0) { putAfterIndex = qBound(0, putAfterIndex, visibleNodes.size() - 1); *putAfter = visibleNodes[putAfterIndex]; } return visibleNodes; } void changeImageDefaultProjectionColor(KisImageSP image, const KoColor &color) { KisImageSignalVector emitSignals; emitSignals << ModifiedSignal; KisProcessingApplicator applicator(image, image->root(), KisProcessingApplicator::RECURSIVE, emitSignals, kundo2_i18n("Change projection color"), 0, 142857 + 1); applicator.applyCommand(new KisChangeProjectionColorCommand(image, color), KisStrokeJobData::BARRIER, KisStrokeJobData::EXCLUSIVE); applicator.end(); } void mergeMultipleLayersImpl(KisImageSP image, KisNodeList mergedNodes, KisNodeSP putAfter, bool flattenSingleLayer, const KUndo2MagicString &actionName, bool cleanupNodes = true, const QString layerName = QString()) { if (!putAfter) { putAfter = mergedNodes.first(); } filterMergableNodes(mergedNodes); { KisNodeList tempNodes; qSwap(mergedNodes, tempNodes); sortMergableNodes(image->root(), tempNodes, mergedNodes); } if (mergedNodes.size() <= 1 && (!flattenSingleLayer && mergedNodes.size() == 1)) return; KisImageSignalVector emitSignals; emitSignals << ModifiedSignal; emitSignals << ComplexNodeReselectionSignal(KisNodeSP(), KisNodeList(), KisNodeSP(), mergedNodes); KisProcessingApplicator applicator(image, 0, KisProcessingApplicator::NONE, emitSignals, actionName); KisNodeList originalNodes = mergedNodes; KisNodeList invisibleNodes; mergedNodes = filterInvisibleNodes(originalNodes, &invisibleNodes, &putAfter); if (!invisibleNodes.isEmpty()) { applicator.applyCommand( new SimpleRemoveLayers(invisibleNodes, image), KisStrokeJobData::SEQUENTIAL, KisStrokeJobData::EXCLUSIVE); } if (mergedNodes.size() > 1 || invisibleNodes.isEmpty()) { MergeMultipleInfoSP info(new MergeMultipleInfo(image, mergedNodes)); // disable key strokes on all colorize masks, all onion skins on // paint layers and wait until update is finished with a barrier applicator.applyCommand(new DisableColorizeKeyStrokes(info)); applicator.applyCommand(new DisableOnionSkins(info)); + applicator.applyCommand(new DisablePassThroughForHeadsOnly(info)); applicator.applyCommand(new KUndo2Command(), KisStrokeJobData::BARRIER); applicator.applyCommand(new KeepMergedNodesSelected(info, putAfter, false)); applicator.applyCommand(new FillSelectionMasks(info)); applicator.applyCommand(new CreateMergedLayerMultiple(info, layerName), KisStrokeJobData::BARRIER); if (info->frames.size() > 0) { foreach (int frame, info->frames) { applicator.applyCommand(new SwitchFrameCommand(info->image, frame, false, info->storage)); applicator.applyCommand(new AddNewFrame(info, frame)); applicator.applyCommand(new RefreshHiddenAreas(info)); applicator.applyCommand(new RefreshDelayedUpdateLayers(info), KisStrokeJobData::BARRIER); applicator.applyCommand(new MergeLayersMultiple(info), KisStrokeJobData::BARRIER); applicator.applyCommand(new SwitchFrameCommand(info->image, frame, true, info->storage)); } } else { applicator.applyCommand(new RefreshHiddenAreas(info)); applicator.applyCommand(new RefreshDelayedUpdateLayers(info), KisStrokeJobData::BARRIER); applicator.applyCommand(new MergeLayersMultiple(info), KisStrokeJobData::BARRIER); } //applicator.applyCommand(new MergeMetaData(info, strategy), KisStrokeJobData::BARRIER); if (cleanupNodes){ applicator.applyCommand(new CleanUpNodes(info, putAfter), KisStrokeJobData::SEQUENTIAL, KisStrokeJobData::EXCLUSIVE); } else { applicator.applyCommand(new InsertNode(info, putAfter), KisStrokeJobData::SEQUENTIAL, KisStrokeJobData::EXCLUSIVE); } applicator.applyCommand(new KeepMergedNodesSelected(info, putAfter, true)); } applicator.end(); } void mergeMultipleLayers(KisImageSP image, KisNodeList mergedNodes, KisNodeSP putAfter) { mergeMultipleLayersImpl(image, mergedNodes, putAfter, false, kundo2_i18n("Merge Selected Nodes")); } void newLayerFromVisible(KisImageSP image, KisNodeSP putAfter) { KisNodeList mergedNodes; mergedNodes << image->root(); mergeMultipleLayersImpl(image, mergedNodes, putAfter, true, kundo2_i18n("New From Visible"), false, i18nc("New layer created from all the visible layers", "Visible")); } struct MergeSelectionMasks : public KisCommandUtils::AggregateCommand { MergeSelectionMasks(MergeDownInfoBaseSP info, KisNodeSP putAfter) : m_info(info), m_putAfter(putAfter){} void populateChildCommands() override { KisNodeSP parent; CleanUpNodes::findPerfectParent(m_info->allSrcNodes(), m_putAfter, parent); KisLayerSP parentLayer; do { parentLayer = qobject_cast(parent.data()); parent = parent->parent(); } while(!parentLayer && parent); KisSelectionSP selection = new KisSelection(); foreach (KisNodeSP node, m_info->allSrcNodes()) { KisMaskSP mask = dynamic_cast(node.data()); if (!mask) continue; selection->pixelSelection()->applySelection( mask->selection()->pixelSelection(), SELECTION_ADD); } KisSelectionMaskSP mergedMask = new KisSelectionMask(m_info->image); mergedMask->initSelection(parentLayer); mergedMask->setSelection(selection); m_info->dstNode = mergedMask; } private: MergeDownInfoBaseSP m_info; KisNodeSP m_putAfter; }; struct ActivateSelectionMask : public KisCommandUtils::AggregateCommand { ActivateSelectionMask(MergeDownInfoBaseSP info) : m_info(info) {} void populateChildCommands() override { KisSelectionMaskSP mergedMask = dynamic_cast(m_info->dstNode.data()); addCommand(new KisActivateSelectionMaskCommand(mergedMask, true)); } private: MergeDownInfoBaseSP m_info; }; bool tryMergeSelectionMasks(KisImageSP image, KisNodeList mergedNodes, KisNodeSP putAfter) { QList selectionMasks; for (auto it = mergedNodes.begin(); it != mergedNodes.end(); /*noop*/) { KisSelectionMaskSP mask = dynamic_cast(it->data()); if (!mask) { it = mergedNodes.erase(it); } else { selectionMasks.append(mask); ++it; } } if (mergedNodes.isEmpty()) return false; KisLayerSP parentLayer = qobject_cast(selectionMasks.first()->parent().data()); KIS_ASSERT_RECOVER(parentLayer) { return 0; } KisImageSignalVector emitSignals; emitSignals << ModifiedSignal; KisProcessingApplicator applicator(image, 0, KisProcessingApplicator::NONE, emitSignals, kundo2_i18n("Merge Selection Masks")); MergeMultipleInfoSP info(new MergeMultipleInfo(image, mergedNodes)); applicator.applyCommand(new MergeSelectionMasks(info, putAfter)); applicator.applyCommand(new CleanUpNodes(info, putAfter), KisStrokeJobData::SEQUENTIAL, KisStrokeJobData::EXCLUSIVE); applicator.applyCommand(new ActivateSelectionMask(info)); applicator.end(); return true; } void flattenLayer(KisImageSP image, KisLayerSP layer) { if (!layer->childCount() && !layer->layerStyle()) return; KisNodeList mergedNodes; mergedNodes << layer; mergeMultipleLayersImpl(image, mergedNodes, layer, true, kundo2_i18n("Flatten Layer")); } void flattenImage(KisImageSP image) { KisNodeList mergedNodes; mergedNodes << image->root(); mergeMultipleLayersImpl(image, mergedNodes, 0, true, kundo2_i18n("Flatten Image")); } KisSimpleUpdateCommand::KisSimpleUpdateCommand(KisNodeList nodes, bool finalize, KUndo2Command *parent) : FlipFlopCommand(finalize, parent), m_nodes(nodes) { } void KisSimpleUpdateCommand::end() { updateNodes(m_nodes); } void KisSimpleUpdateCommand::updateNodes(const KisNodeList &nodes) { Q_FOREACH(KisNodeSP node, nodes) { node->setDirty(node->extent()); } } void recursiveApplyNodes(KisNodeSP node, std::function func) { func(node); node = node->firstChild(); while (node) { recursiveApplyNodes(node, func); node = node->nextSibling(); } } KisNodeSP recursiveFindNode(KisNodeSP node, std::function func) { if (func(node)) { return node; } node = node->firstChild(); while (node) { KisNodeSP resultNode = recursiveFindNode(node, func); if (resultNode) { return resultNode; } node = node->nextSibling(); } return 0; } KisNodeSP findNodeByUuid(KisNodeSP root, const QUuid &uuid) { return recursiveFindNode(root, [uuid] (KisNodeSP node) { return node->uuid() == uuid; }); } } diff --git a/libs/image/tests/kis_image_test.cpp b/libs/image/tests/kis_image_test.cpp index 88d781b6a8..a51bbe0954 100644 --- a/libs/image/tests/kis_image_test.cpp +++ b/libs/image/tests/kis_image_test.cpp @@ -1,1016 +1,1159 @@ /* * Copyright (c) 2005 Adrian Page * * 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_test.h" #include #include #include #include #include "filter/kis_filter.h" #include "filter/kis_filter_configuration.h" #include "filter/kis_filter_registry.h" #include "kis_image.h" #include "kis_paint_layer.h" #include "kis_group_layer.h" #include "kis_adjustment_layer.h" #include "kis_selection.h" #include #include #include "kis_keyframe_channel.h" #include "kis_selection_mask.h" #include "kis_layer_utils.h" #include "kis_annotation.h" #include "KisProofingConfiguration.h" #include "kis_undo_stores.h" #define IMAGE_WIDTH 128 #define IMAGE_HEIGHT 128 void KisImageTest::layerTests() { KisImageSP image = new KisImage(0, IMAGE_WIDTH, IMAGE_WIDTH, 0, "layer tests"); QVERIFY(image->rootLayer() != 0); QVERIFY(image->rootLayer()->firstChild() == 0); KisLayerSP layer = new KisPaintLayer(image, "layer 1", OPACITY_OPAQUE_U8); image->addNode(layer); QVERIFY(image->rootLayer()->firstChild()->objectName() == layer->objectName()); } void KisImageTest::benchmarkCreation() { const QRect imageRect(0,0,3000,2000); const KoColorSpace * cs = KoColorSpaceRegistry::instance()->rgb8(); QList images; QList stores; QBENCHMARK { for (int i = 0; i < 10; i++) { stores << new KisSurrogateUndoStore(); } for (int i = 0; i < 10; i++) { KisImageSP image = new KisImage(stores.takeLast(), imageRect.width(), imageRect.height(), cs, "test image"); images << image; } } } #include "testutil.h" #include "kis_stroke_strategy.h" #include class ForbiddenLodStrokeStrategy : public KisStrokeStrategy { public: ForbiddenLodStrokeStrategy(std::function lodCallback) : m_lodCallback(lodCallback) { } KisStrokeStrategy* createLodClone(int levelOfDetail) override { Q_UNUSED(levelOfDetail); m_lodCallback(); return 0; } private: std::function m_lodCallback; }; void notifyVar(bool *value) { *value = true; } void KisImageTest::testBlockLevelOfDetail() { TestUtil::MaskParent p; QCOMPARE(p.image->currentLevelOfDetail(), 0); p.image->setDesiredLevelOfDetail(1); p.image->waitForDone(); QCOMPARE(p.image->currentLevelOfDetail(), 0); { bool lodCreated = false; KisStrokeId id = p.image->startStroke( new ForbiddenLodStrokeStrategy( std::bind(¬ifyVar, &lodCreated))); p.image->endStroke(id); p.image->waitForDone(); QVERIFY(lodCreated); } p.image->setLevelOfDetailBlocked(true); { bool lodCreated = false; KisStrokeId id = p.image->startStroke( new ForbiddenLodStrokeStrategy( std::bind(¬ifyVar, &lodCreated))); p.image->endStroke(id); p.image->waitForDone(); QVERIFY(!lodCreated); } p.image->setLevelOfDetailBlocked(false); p.image->setDesiredLevelOfDetail(1); { bool lodCreated = false; KisStrokeId id = p.image->startStroke( new ForbiddenLodStrokeStrategy( std::bind(¬ifyVar, &lodCreated))); p.image->endStroke(id); p.image->waitForDone(); QVERIFY(lodCreated); } } void KisImageTest::testConvertImageColorSpace() { const KoColorSpace *cs8 = KoColorSpaceRegistry::instance()->rgb8(); KisImageSP image = new KisImage(0, 1000, 1000, cs8, "stest"); KisPaintDeviceSP device1 = new KisPaintDevice(cs8); KisLayerSP paint1 = new KisPaintLayer(image, "paint1", OPACITY_OPAQUE_U8, device1); KisFilterSP filter = KisFilterRegistry::instance()->value("blur"); Q_ASSERT(filter); KisFilterConfigurationSP configuration = filter->defaultConfiguration(); Q_ASSERT(configuration); KisLayerSP blur1 = new KisAdjustmentLayer(image, "blur1", configuration, 0); image->addNode(paint1, image->root()); image->addNode(blur1, image->root()); image->refreshGraph(); const KoColorSpace *cs16 = KoColorSpaceRegistry::instance()->rgb16(); image->lock(); image->convertImageColorSpace(cs16, KoColorConversionTransformation::internalRenderingIntent(), KoColorConversionTransformation::internalConversionFlags()); image->unlock(); QVERIFY(*cs16 == *image->colorSpace()); QVERIFY(*cs16 == *image->root()->colorSpace()); QVERIFY(*cs16 == *paint1->colorSpace()); QVERIFY(*cs16 == *blur1->colorSpace()); QVERIFY(!image->root()->compositeOp()); QVERIFY(*cs16 == *paint1->compositeOp()->colorSpace()); QVERIFY(*cs16 == *blur1->compositeOp()->colorSpace()); image->refreshGraph(); } void KisImageTest::testGlobalSelection() { const KoColorSpace *cs8 = KoColorSpaceRegistry::instance()->rgb8(); KisImageSP image = new KisImage(0, 1000, 1000, cs8, "stest"); QCOMPARE(image->globalSelection(), KisSelectionSP(0)); QCOMPARE(image->canReselectGlobalSelection(), false); QCOMPARE(image->root()->childCount(), 0U); KisSelectionSP selection1 = new KisSelection(new KisDefaultBounds(image)); KisSelectionSP selection2 = new KisSelection(new KisDefaultBounds(image)); image->setGlobalSelection(selection1); QCOMPARE(image->globalSelection(), selection1); QCOMPARE(image->canReselectGlobalSelection(), false); QCOMPARE(image->root()->childCount(), 1U); image->setGlobalSelection(selection2); QCOMPARE(image->globalSelection(), selection2); QCOMPARE(image->canReselectGlobalSelection(), false); QCOMPARE(image->root()->childCount(), 1U); image->deselectGlobalSelection(); QCOMPARE(image->globalSelection(), KisSelectionSP(0)); QCOMPARE(image->canReselectGlobalSelection(), true); QCOMPARE(image->root()->childCount(), 0U); image->reselectGlobalSelection(); QCOMPARE(image->globalSelection(), selection2); QCOMPARE(image->canReselectGlobalSelection(), false); QCOMPARE(image->root()->childCount(), 1U); // mixed deselecting/setting/reselecting image->deselectGlobalSelection(); QCOMPARE(image->globalSelection(), KisSelectionSP(0)); QCOMPARE(image->canReselectGlobalSelection(), true); QCOMPARE(image->root()->childCount(), 0U); image->setGlobalSelection(selection1); QCOMPARE(image->globalSelection(), selection1); QCOMPARE(image->canReselectGlobalSelection(), false); QCOMPARE(image->root()->childCount(), 1U); } void KisImageTest::testCloneImage() { KisImageSP image = new KisImage(0, IMAGE_WIDTH, IMAGE_WIDTH, 0, "layer tests"); QVERIFY(image->rootLayer() != 0); QVERIFY(image->rootLayer()->firstChild() == 0); KisAnnotationSP annotation = new KisAnnotation("mytype", "mydescription", QByteArray()); image->addAnnotation(annotation); QVERIFY(image->annotation("mytype")); KisProofingConfigurationSP proofing = toQShared(new KisProofingConfiguration()); image->setProofingConfiguration(proofing); QVERIFY(image->proofingConfiguration()); const KoColor defaultColor(Qt::green, image->colorSpace()); image->setDefaultProjectionColor(defaultColor); QCOMPARE(image->defaultProjectionColor(), defaultColor); KisLayerSP layer = new KisPaintLayer(image, "layer1", OPACITY_OPAQUE_U8); image->addNode(layer); KisLayerSP layer2 = new KisPaintLayer(image, "layer2", OPACITY_OPAQUE_U8); image->addNode(layer2); QVERIFY(layer->visible()); QVERIFY(layer2->visible()); QVERIFY(TestUtil::findNode(image->root(), "layer1")); QVERIFY(TestUtil::findNode(image->root(), "layer2")); QUuid uuid1 = layer->uuid(); QUuid uuid2 = layer2->uuid(); { KisImageSP newImage = image->clone(); KisNodeSP newLayer1 = TestUtil::findNode(newImage->root(), "layer1"); KisNodeSP newLayer2 = TestUtil::findNode(newImage->root(), "layer2"); QVERIFY(newLayer1); QVERIFY(newLayer2); QVERIFY(newLayer1->uuid() != uuid1); QVERIFY(newLayer2->uuid() != uuid2); KisAnnotationSP newAnnotation = newImage->annotation("mytype"); QVERIFY(newAnnotation); QVERIFY(newAnnotation != annotation); KisProofingConfigurationSP newProofing = newImage->proofingConfiguration(); QVERIFY(newProofing); QVERIFY(newProofing != proofing); QCOMPARE(newImage->defaultProjectionColor(), defaultColor); } { KisImageSP newImage = image->clone(true); KisNodeSP newLayer1 = TestUtil::findNode(newImage->root(), "layer1"); KisNodeSP newLayer2 = TestUtil::findNode(newImage->root(), "layer2"); QVERIFY(newLayer1); QVERIFY(newLayer2); QVERIFY(newLayer1->uuid() == uuid1); QVERIFY(newLayer2->uuid() == uuid2); } } void KisImageTest::testLayerComposition() { KisImageSP image = new KisImage(0, IMAGE_WIDTH, IMAGE_WIDTH, 0, "layer tests"); QVERIFY(image->rootLayer() != 0); QVERIFY(image->rootLayer()->firstChild() == 0); KisLayerSP layer = new KisPaintLayer(image, "layer1", OPACITY_OPAQUE_U8); image->addNode(layer); KisLayerSP layer2 = new KisPaintLayer(image, "layer2", OPACITY_OPAQUE_U8); image->addNode(layer2); QVERIFY(layer->visible()); QVERIFY(layer2->visible()); KisLayerComposition comp(image, "comp 1"); comp.store(); layer2->setVisible(false); QVERIFY(layer->visible()); QVERIFY(!layer2->visible()); KisLayerComposition comp2(image, "comp 2"); comp2.store(); KisLayerCompositionSP comp3 = toQShared(new KisLayerComposition(image, "comp 3")); comp3->store(); image->addComposition(comp3); comp.apply(); QVERIFY(layer->visible()); QVERIFY(layer2->visible()); comp2.apply(); QVERIFY(layer->visible()); QVERIFY(!layer2->visible()); comp.apply(); QVERIFY(layer->visible()); QVERIFY(layer2->visible()); KisImageSP newImage = image->clone(); KisNodeSP newLayer1 = TestUtil::findNode(newImage->root(), "layer1"); KisNodeSP newLayer2 = TestUtil::findNode(newImage->root(), "layer2"); QVERIFY(newLayer1); QVERIFY(newLayer2); QVERIFY(newLayer1->visible()); QVERIFY(newLayer2->visible()); KisLayerComposition newComp1(comp, newImage); newComp1.apply(); QVERIFY(newLayer1->visible()); QVERIFY(newLayer2->visible()); KisLayerComposition newComp2(comp2, newImage); newComp2.apply(); QVERIFY(newLayer1->visible()); QVERIFY(!newLayer2->visible()); newComp1.apply(); QVERIFY(newLayer1->visible()); QVERIFY(newLayer2->visible()); QVERIFY(!newImage->compositions().isEmpty()); KisLayerCompositionSP newComp3 = newImage->compositions().first(); newComp3->apply(); QVERIFY(newLayer1->visible()); QVERIFY(!newLayer2->visible()); } #include "testutil.h" #include "kis_group_layer.h" #include "kis_transparency_mask.h" #include "kis_psd_layer_style.h" struct FlattenTestImage { FlattenTestImage() : refRect(0,0,512,512) , p(refRect) { image = p.image; undoStore = p.undoStore; layer1 = p.layer; layer5 = new KisPaintLayer(p.image, "paint5", 0.4 * OPACITY_OPAQUE_U8); layer5->disableAlphaChannel(true); layer2 = new KisPaintLayer(p.image, "paint2", OPACITY_OPAQUE_U8); tmask = new KisTransparencyMask(); // check channel flags // make addition composite op group1 = new KisGroupLayer(p.image, "group1", OPACITY_OPAQUE_U8); layer3 = new KisPaintLayer(p.image, "paint3", OPACITY_OPAQUE_U8); layer4 = new KisPaintLayer(p.image, "paint4", OPACITY_OPAQUE_U8); layer6 = new KisPaintLayer(p.image, "paint6", OPACITY_OPAQUE_U8); layer7 = new KisPaintLayer(p.image, "paint7", OPACITY_OPAQUE_U8); layer8 = new KisPaintLayer(p.image, "paint8", OPACITY_OPAQUE_U8); layer7->setCompositeOpId(COMPOSITE_ADD); layer8->setCompositeOpId(COMPOSITE_ADD); QRect rect1(100, 100, 100, 100); QRect rect2(150, 150, 150, 150); QRect tmaskRect(200,200,100,100); QRect rect3(400, 100, 100, 100); QRect rect4(500, 100, 100, 100); QRect rect5(50, 50, 100, 100); QRect rect6(50, 250, 100, 100); QRect rect7(50, 350, 50, 50); QRect rect8(50, 400, 50, 50); layer1->paintDevice()->fill(rect1, KoColor(Qt::red, p.image->colorSpace())); layer2->paintDevice()->fill(rect2, KoColor(Qt::green, p.image->colorSpace())); tmask->testingInitSelection(tmaskRect, layer2); layer3->paintDevice()->fill(rect3, KoColor(Qt::blue, p.image->colorSpace())); layer4->paintDevice()->fill(rect4, KoColor(Qt::yellow, p.image->colorSpace())); layer5->paintDevice()->fill(rect5, KoColor(Qt::green, p.image->colorSpace())); layer6->paintDevice()->fill(rect6, KoColor(Qt::cyan, p.image->colorSpace())); layer7->paintDevice()->fill(rect7, KoColor(Qt::red, p.image->colorSpace())); layer8->paintDevice()->fill(rect8, KoColor(Qt::green, p.image->colorSpace())); KisPSDLayerStyleSP style(new KisPSDLayerStyle()); style->dropShadow()->setEffectEnabled(true); style->dropShadow()->setDistance(10.0); style->dropShadow()->setSpread(80.0); style->dropShadow()->setSize(10); style->dropShadow()->setNoise(0); style->dropShadow()->setKnocksOut(false); style->dropShadow()->setOpacity(80.0); layer2->setLayerStyle(style); layer2->setCompositeOpId(COMPOSITE_ADD); group1->setCompositeOpId(COMPOSITE_ADD); p.image->addNode(layer5); p.image->addNode(layer2); p.image->addNode(tmask, layer2); p.image->addNode(group1); p.image->addNode(layer3, group1); p.image->addNode(layer4, group1); p.image->addNode(layer6); p.image->addNode(layer7); p.image->addNode(layer8); p.image->initialRefreshGraph(); // dbgKrita << ppVar(layer1->exactBounds()); // dbgKrita << ppVar(layer5->exactBounds()); // dbgKrita << ppVar(layer2->exactBounds()); // dbgKrita << ppVar(group1->exactBounds()); // dbgKrita << ppVar(layer3->exactBounds()); // dbgKrita << ppVar(layer4->exactBounds()); TestUtil::ExternalImageChecker chk("flatten", "imagetest"); QVERIFY(chk.checkDevice(p.image->projection(), p.image, "00_initial")); } QRect refRect; TestUtil::MaskParent p; KisImageSP image; KisSurrogateUndoStore *undoStore; KisPaintLayerSP layer1; KisPaintLayerSP layer2; KisTransparencyMaskSP tmask; KisGroupLayerSP group1; KisPaintLayerSP layer3; KisPaintLayerSP layer4; KisPaintLayerSP layer5; KisPaintLayerSP layer6; KisPaintLayerSP layer7; KisPaintLayerSP layer8; }; template KisLayerSP flattenLayerHelper(ContainerTest &p, KisLayerSP layer, bool nothingHappens = false) { QSignalSpy spy(p.image.data(), SIGNAL(sigNodeAddedAsync(KisNodeSP))); //p.image->flattenLayer(layer); KisLayerUtils::flattenLayer(p.image, layer); p.image->waitForDone(); if (nothingHappens) { Q_ASSERT(!spy.count()); return layer; } Q_ASSERT(spy.count() == 1); QList arguments = spy.takeFirst(); KisNodeSP newNode = arguments.first().value(); KisLayerSP newLayer = qobject_cast(newNode.data()); return newLayer; } void KisImageTest::testFlattenLayer() { FlattenTestImage p; TestUtil::ExternalImageChecker chk("flatten", "imagetest"); { QCOMPARE(p.layer2->compositeOpId(), COMPOSITE_ADD); KisLayerSP newLayer = flattenLayerHelper(p, p.layer2); //KisLayerSP newLayer = p.image->flattenLayer(p.layer2); //p.image->waitForDone(); QVERIFY(chk.checkDevice(p.image->projection(), p.image, "00_initial")); QVERIFY(chk.checkDevice(newLayer->projection(), p.image, "01_layer2_layerproj")); QCOMPARE(newLayer->compositeOpId(), COMPOSITE_OVER); } { QCOMPARE(p.group1->compositeOpId(), COMPOSITE_ADD); KisLayerSP newLayer = flattenLayerHelper(p, p.group1); //KisLayerSP newLayer = p.image->flattenLayer(p.group1); //p.image->waitForDone(); QVERIFY(chk.checkDevice(p.image->projection(), p.image, "00_initial")); QVERIFY(chk.checkDevice(newLayer->projection(), p.image, "02_group1_layerproj")); QCOMPARE(newLayer->compositeOpId(), COMPOSITE_ADD); QCOMPARE(newLayer->exactBounds(), QRect(400, 100, 200, 100)); } { QCOMPARE(p.layer5->compositeOpId(), COMPOSITE_OVER); QCOMPARE(p.layer5->alphaChannelDisabled(), true); KisLayerSP newLayer = flattenLayerHelper(p, p.layer5, true); //KisLayerSP newLayer = p.image->flattenLayer(p.layer5); //p.image->waitForDone(); QVERIFY(chk.checkDevice(p.image->projection(), p.image, "00_initial")); QVERIFY(chk.checkDevice(newLayer->projection(), p.image, "03_layer5_layerproj")); QCOMPARE(newLayer->compositeOpId(), COMPOSITE_OVER); QCOMPARE(newLayer->exactBounds(), QRect(50, 50, 100, 100)); QCOMPARE(newLayer->alphaChannelDisabled(), true); } } #include template KisLayerSP mergeHelper(ContainerTest &p, KisLayerSP layer) { KisNodeSP parent = layer->parent(); const int newIndex = parent->index(layer) - 1; p.image->mergeDown(layer, KisMetaData::MergeStrategyRegistry::instance()->get("Drop")); //KisLayerUtils::mergeDown(p.image, layer, KisMetaData::MergeStrategyRegistry::instance()->get("Drop")); p.image->waitForDone(); KisLayerSP newLayer = qobject_cast(parent->at(newIndex).data()); return newLayer; } void KisImageTest::testMergeDown() { FlattenTestImage p; TestUtil::ExternalImageChecker img("flatten", "imagetest"); TestUtil::ExternalImageChecker chk("mergedown_simple", "imagetest"); { QCOMPARE(p.layer5->compositeOpId(), COMPOSITE_OVER); QCOMPARE(p.layer5->alphaChannelDisabled(), true); KisLayerSP newLayer = mergeHelper(p, p.layer5); QVERIFY(img.checkDevice(p.image->projection(), p.image, "00_initial")); QVERIFY(chk.checkDevice(newLayer->projection(), p.image, "01_layer5_layerproj")); QCOMPARE(newLayer->compositeOpId(), COMPOSITE_OVER); QCOMPARE(newLayer->alphaChannelDisabled(), false); } { QCOMPARE(p.layer2->compositeOpId(), COMPOSITE_ADD); QCOMPARE(p.layer2->alphaChannelDisabled(), false); KisLayerSP newLayer = mergeHelper(p, p.layer2); QVERIFY(img.checkDevice(p.image->projection(), p.image, "00_initial")); QVERIFY(chk.checkDevice(newLayer->projection(), p.image, "02_layer2_layerproj")); QCOMPARE(newLayer->compositeOpId(), COMPOSITE_OVER); QCOMPARE(newLayer->exactBounds(), QRect(100, 100, 213, 217)); QCOMPARE(newLayer->alphaChannelDisabled(), false); } { QCOMPARE(p.group1->compositeOpId(), COMPOSITE_ADD); QCOMPARE(p.group1->alphaChannelDisabled(), false); KisLayerSP newLayer = mergeHelper(p, p.group1); QVERIFY(img.checkDevice(p.image->projection(), p.image, "00_initial")); QVERIFY(chk.checkDevice(newLayer->projection(), p.image, "03_group1_mergedown_layerproj")); QCOMPARE(newLayer->compositeOpId(), COMPOSITE_OVER); QCOMPARE(newLayer->exactBounds(), QRect(100, 100, 500, 217)); QCOMPARE(newLayer->alphaChannelDisabled(), false); } } void KisImageTest::testMergeDownDestinationInheritsAlpha() { FlattenTestImage p; TestUtil::ExternalImageChecker img("flatten", "imagetest"); TestUtil::ExternalImageChecker chk("mergedown_dst_inheritsalpha", "imagetest"); { QCOMPARE(p.layer2->compositeOpId(), COMPOSITE_ADD); QCOMPARE(p.layer2->alphaChannelDisabled(), false); KisLayerSP newLayer = mergeHelper(p, p.layer2); // WARN: this check is suspicious! QVERIFY(img.checkDevice(p.image->projection(), p.image, "00_proj_merged_layer2_over_layer5_IA")); QVERIFY(chk.checkDevice(newLayer->projection(), p.image, "01_layer2_layerproj")); QCOMPARE(newLayer->compositeOpId(), COMPOSITE_OVER); QCOMPARE(newLayer->exactBounds(), QRect(50,50, 263, 267)); QCOMPARE(newLayer->alphaChannelDisabled(), false); } } void KisImageTest::testMergeDownDestinationCustomCompositeOp() { FlattenTestImage p; TestUtil::ExternalImageChecker img("flatten", "imagetest"); TestUtil::ExternalImageChecker chk("mergedown_dst_customop", "imagetest"); { QCOMPARE(p.layer6->compositeOpId(), COMPOSITE_OVER); QCOMPARE(p.layer6->alphaChannelDisabled(), false); QCOMPARE(p.group1->compositeOpId(), COMPOSITE_ADD); QCOMPARE(p.group1->alphaChannelDisabled(), false); KisLayerSP newLayer = mergeHelper(p, p.layer6); QVERIFY(img.checkDevice(p.image->projection(), p.image, "00_initial")); QVERIFY(chk.checkDevice(newLayer->projection(), p.image, "01_layer6_layerproj")); QCOMPARE(newLayer->compositeOpId(), COMPOSITE_OVER); QCOMPARE(newLayer->exactBounds(), QRect(50, 100, 550, 250)); QCOMPARE(newLayer->alphaChannelDisabled(), false); } } void KisImageTest::testMergeDownDestinationSameCompositeOpLayerStyle() { FlattenTestImage p; TestUtil::ExternalImageChecker img("flatten", "imagetest"); TestUtil::ExternalImageChecker chk("mergedown_sameop_ls", "imagetest"); { QCOMPARE(p.group1->compositeOpId(), COMPOSITE_ADD); QCOMPARE(p.group1->alphaChannelDisabled(), false); QCOMPARE(p.layer2->compositeOpId(), COMPOSITE_ADD); QCOMPARE(p.layer2->alphaChannelDisabled(), false); KisLayerSP newLayer = mergeHelper(p, p.group1); QVERIFY(img.checkDevice(p.image->projection(), p.image, "00_initial")); QVERIFY(chk.checkDevice(newLayer->projection(), p.image, "01_group1_layerproj")); QCOMPARE(newLayer->compositeOpId(), COMPOSITE_OVER); QCOMPARE(newLayer->exactBounds(), QRect(197, 100, 403, 217)); QCOMPARE(newLayer->alphaChannelDisabled(), false); } } void KisImageTest::testMergeDownDestinationSameCompositeOp() { FlattenTestImage p; TestUtil::ExternalImageChecker img("flatten", "imagetest"); TestUtil::ExternalImageChecker chk("mergedown_sameop_fastpath", "imagetest"); { QCOMPARE(p.layer8->compositeOpId(), COMPOSITE_ADD); QCOMPARE(p.layer8->alphaChannelDisabled(), false); QCOMPARE(p.layer7->compositeOpId(), COMPOSITE_ADD); QCOMPARE(p.layer7->alphaChannelDisabled(), false); KisLayerSP newLayer = mergeHelper(p, p.layer8); QVERIFY(img.checkDevice(p.image->projection(), p.image, "00_initial")); QVERIFY(chk.checkDevice(newLayer->projection(), p.image, "01_layer8_layerproj")); QCOMPARE(newLayer->compositeOpId(), COMPOSITE_ADD); QCOMPARE(newLayer->exactBounds(), QRect(50, 350, 50, 100)); QCOMPARE(newLayer->alphaChannelDisabled(), false); } } #include "kis_image_animation_interface.h" void KisImageTest::testMergeDownMultipleFrames() { FlattenTestImage p; TestUtil::ExternalImageChecker img("flatten", "imagetest"); TestUtil::ExternalImageChecker chk("mergedown_simple", "imagetest"); QSet initialFrames; { KisLayerSP l = p.layer5; l->enableAnimation(); KisKeyframeChannel *channel = l->getKeyframeChannel(KisKeyframeChannel::Content.id(), true); channel->addKeyframe(10); channel->addKeyframe(20); channel->addKeyframe(30); QCOMPARE(channel->keyframeCount(), 4); initialFrames = KisLayerUtils::fetchLayerFramesRecursive(l); QCOMPARE(initialFrames.size(), 4); } { QCOMPARE(p.layer5->compositeOpId(), COMPOSITE_OVER); QCOMPARE(p.layer5->alphaChannelDisabled(), true); KisLayerSP newLayer = mergeHelper(p, p.layer5); QVERIFY(img.checkDevice(p.image->projection(), p.image, "00_initial")); QVERIFY(chk.checkDevice(newLayer->projection(), p.image, "01_layer5_layerproj")); QCOMPARE(newLayer->compositeOpId(), COMPOSITE_OVER); QCOMPARE(newLayer->alphaChannelDisabled(), false); QVERIFY(newLayer->isAnimated()); QSet newFrames = KisLayerUtils::fetchLayerFramesRecursive(newLayer); QCOMPARE(newFrames, initialFrames); foreach (int frame, newFrames) { KisImageAnimationInterface *interface = p.image->animationInterface(); int savedSwitchedTime = 0; interface->saveAndResetCurrentTime(frame, &savedSwitchedTime); QCOMPARE(newLayer->exactBounds(), QRect(100,100,100,100)); interface->restoreCurrentTime(&savedSwitchedTime); } p.undoStore->undo(); p.image->waitForDone(); QVERIFY(img.checkDevice(p.image->projection(), p.image, "00_initial")); } } template KisNodeSP mergeMultipleHelper(ContainerTest &p, QList selectedNodes, KisNodeSP putAfter) { QSignalSpy spy(p.image.data(), SIGNAL(sigNodeAddedAsync(KisNodeSP))); p.image->mergeMultipleLayers(selectedNodes, putAfter); //KisLayerUtils::mergeMultipleLayers(p.image, selectedNodes, putAfter); p.image->waitForDone(); Q_ASSERT(spy.count() == 1); QList arguments = spy.takeFirst(); KisNodeSP newNode = arguments.first().value(); return newNode; } void KisImageTest::testMergeMultiple() { FlattenTestImage p; TestUtil::ExternalImageChecker img("flatten", "imagetest"); TestUtil::ExternalImageChecker chk("mergemultiple", "imagetest"); { QList selectedNodes; selectedNodes << p.layer2 << p.group1 << p.layer6; { KisNodeSP newLayer = mergeMultipleHelper(p, selectedNodes, 0); //KisNodeSP newLayer = p.image->mergeMultipleLayers(selectedNodes, 0); //p.image->waitForDone(); QVERIFY(img.checkDevice(p.image->projection(), p.image, "00_initial")); QVERIFY(chk.checkDevice(newLayer->projection(), p.image, "01_layer8_layerproj")); QCOMPARE(newLayer->compositeOpId(), COMPOSITE_OVER); QCOMPARE(newLayer->exactBounds(), QRect(50, 100, 550, 250)); } } p.p.undoStore->undo(); p.image->waitForDone(); // Test reversed order, the result must be the same { QList selectedNodes; selectedNodes << p.layer6 << p.group1 << p.layer2; { KisNodeSP newLayer = mergeMultipleHelper(p, selectedNodes, 0); //KisNodeSP newLayer = p.image->mergeMultipleLayers(selectedNodes, 0); //p.image->waitForDone(); QVERIFY(img.checkDevice(p.image->projection(), p.image, "00_initial")); QVERIFY(chk.checkDevice(newLayer->projection(), p.image, "01_layer8_layerproj")); QCOMPARE(newLayer->compositeOpId(), COMPOSITE_OVER); QCOMPARE(newLayer->exactBounds(), QRect(50, 100, 550, 250)); } } } void testMergeCrossColorSpaceImpl(bool useProjectionColorSpace, bool swapSpaces) { QRect refRect; TestUtil::MaskParent p; KisPaintLayerSP layer1; KisPaintLayerSP layer2; KisPaintLayerSP layer3; const KoColorSpace *cs2 = useProjectionColorSpace ? p.image->colorSpace() : KoColorSpaceRegistry::instance()->lab16(); const KoColorSpace *cs3 = KoColorSpaceRegistry::instance()->rgb16(); if (swapSpaces) { qSwap(cs2, cs3); } dbgKrita << "Testing testMergeCrossColorSpaceImpl:"; dbgKrita << " " << ppVar(cs2); dbgKrita << " " << ppVar(cs3); layer1 = p.layer; layer2 = new KisPaintLayer(p.image, "paint2", OPACITY_OPAQUE_U8, cs2); layer3 = new KisPaintLayer(p.image, "paint3", OPACITY_OPAQUE_U8, cs3); QRect rect1(100, 100, 100, 100); QRect rect2(150, 150, 150, 150); QRect rect3(250, 250, 200, 200); layer1->paintDevice()->fill(rect1, KoColor(Qt::red, layer1->colorSpace())); layer2->paintDevice()->fill(rect2, KoColor(Qt::green, layer2->colorSpace())); layer3->paintDevice()->fill(rect3, KoColor(Qt::blue, layer3->colorSpace())); p.image->addNode(layer2); p.image->addNode(layer3); p.image->initialRefreshGraph(); { KisLayerSP newLayer = mergeHelper(p, layer3); QCOMPARE(newLayer->colorSpace(), p.image->colorSpace()); p.undoStore->undo(); p.image->waitForDone(); } { layer2->disableAlphaChannel(true); KisLayerSP newLayer = mergeHelper(p, layer3); QCOMPARE(newLayer->colorSpace(), p.image->colorSpace()); p.undoStore->undo(); p.image->waitForDone(); } } void KisImageTest::testMergeCrossColorSpace() { testMergeCrossColorSpaceImpl(true, false); testMergeCrossColorSpaceImpl(true, true); testMergeCrossColorSpaceImpl(false, false); testMergeCrossColorSpaceImpl(false, true); } void KisImageTest::testMergeSelectionMasks() { QRect refRect; TestUtil::MaskParent p; QRect rect1(100, 100, 100, 100); QRect rect2(150, 150, 150, 150); QRect rect3(50, 50, 100, 100); KisPaintLayerSP layer1 = p.layer; layer1->paintDevice()->fill(rect1, KoColor(Qt::red, layer1->colorSpace())); p.image->initialRefreshGraph(); KisSelectionSP sel = new KisSelection(layer1->paintDevice()->defaultBounds()); sel->pixelSelection()->select(rect2, MAX_SELECTED); KisSelectionMaskSP mask1 = new KisSelectionMask(p.image); mask1->initSelection(sel, layer1); p.image->addNode(mask1, layer1); QVERIFY(!layer1->selection()); mask1->setActive(true); QCOMPARE(layer1->selection()->selectedExactRect(), QRect(150,150,150,150)); sel->pixelSelection()->select(rect3, MAX_SELECTED); KisSelectionMaskSP mask2 = new KisSelectionMask(p.image); mask2->initSelection(sel, layer1); p.image->addNode(mask2, layer1); QCOMPARE(layer1->selection()->selectedExactRect(), QRect(150,150,150,150)); mask2->setActive(true); QCOMPARE(layer1->selection()->selectedExactRect(), QRect(50,50,250,250)); QList selectedNodes; selectedNodes << mask2 << mask1; { KisNodeSP newLayer = mergeMultipleHelper(p, selectedNodes, 0); QCOMPARE(newLayer->parent(), KisNodeSP(layer1)); QCOMPARE((int)layer1->childCount(), 1); QCOMPARE(layer1->selection()->selectedExactRect(), QRect(50,50,250,250)); } } void KisImageTest::testFlattenImage() { FlattenTestImage p; KisImageSP image = p.image; TestUtil::ExternalImageChecker img("flatten", "imagetest"); { KisLayerUtils::flattenImage(p.image); QVERIFY(img.checkDevice(p.image->projection(), p.image, "00_initial")); p.undoStore->undo(); p.image->waitForDone(); QVERIFY(img.checkDevice(p.image->projection(), p.image, "00_initial")); } } +struct FlattenPassThroughTestImage +{ + FlattenPassThroughTestImage() + : refRect(0,0,512,512) + , p(refRect) + { + + image = p.image; + undoStore = p.undoStore; + + group1 = new KisGroupLayer(p.image, "group1", OPACITY_OPAQUE_U8); + layer2 = new KisPaintLayer(p.image, "paint2", OPACITY_OPAQUE_U8); + layer3 = new KisPaintLayer(p.image, "paint3", OPACITY_OPAQUE_U8); + + group4 = new KisGroupLayer(p.image, "group4", OPACITY_OPAQUE_U8); + layer5 = new KisPaintLayer(p.image, "paint5", OPACITY_OPAQUE_U8); + layer6 = new KisPaintLayer(p.image, "paint6", OPACITY_OPAQUE_U8); + + QRect rect2(100, 100, 100, 100); + QRect rect3(150, 150, 100, 100); + + QRect rect5(200, 200, 100, 100); + QRect rect6(250, 250, 100, 100); + + group1->setPassThroughMode(true); + layer2->paintDevice()->fill(rect2, KoColor(Qt::red, p.image->colorSpace())); + layer3->paintDevice()->fill(rect3, KoColor(Qt::green, p.image->colorSpace())); + + group4->setPassThroughMode(true); + layer5->paintDevice()->fill(rect5, KoColor(Qt::blue, p.image->colorSpace())); + layer6->paintDevice()->fill(rect6, KoColor(Qt::yellow, p.image->colorSpace())); + + + p.image->addNode(group1); + p.image->addNode(layer2, group1); + p.image->addNode(layer3, group1); + + p.image->addNode(group4); + p.image->addNode(layer5, group4); + p.image->addNode(layer6, group4); + + p.image->initialRefreshGraph(); + + TestUtil::ExternalImageChecker chk("passthrough", "imagetest"); + QVERIFY(chk.checkDevice(p.image->projection(), p.image, "00_initial")); + } + + QRect refRect; + TestUtil::MaskParent p; + + KisImageSP image; + KisSurrogateUndoStore *undoStore; + + KisGroupLayerSP group1; + KisPaintLayerSP layer2; + KisPaintLayerSP layer3; + + KisGroupLayerSP group4; + KisPaintLayerSP layer5; + KisPaintLayerSP layer6; +}; + +void KisImageTest::testFlattenPassThroughLayer() +{ + FlattenPassThroughTestImage p; + + TestUtil::ExternalImageChecker chk("passthrough", "imagetest"); + + { + QCOMPARE(p.group1->compositeOpId(), COMPOSITE_OVER); + QCOMPARE(p.group1->passThroughMode(), true); + + KisLayerSP newLayer = flattenLayerHelper(p, p.group1); + + QVERIFY(chk.checkDevice(p.image->projection(), p.image, "00_initial")); + QVERIFY(chk.checkDevice(newLayer->projection(), p.image, "01_group1_layerproj")); + + QCOMPARE(newLayer->compositeOpId(), COMPOSITE_OVER); + QVERIFY(newLayer->inherits("KisPaintLayer")); + } +} + +void KisImageTest::testMergeTwoPassThroughLayers() +{ + FlattenPassThroughTestImage p; + + TestUtil::ExternalImageChecker chk("passthrough", "imagetest"); + + { + QCOMPARE(p.group1->compositeOpId(), COMPOSITE_OVER); + QCOMPARE(p.group1->passThroughMode(), true); + + KisLayerSP newLayer = mergeHelper(p, p.group4); + + QVERIFY(chk.checkDevice(p.image->projection(), p.image, "00_initial")); + + QCOMPARE(newLayer->compositeOpId(), COMPOSITE_OVER); + QVERIFY(newLayer->inherits("KisGroupLayer")); + } +} + +void KisImageTest::testMergePaintOverPassThroughLayer() +{ + FlattenPassThroughTestImage p; + + TestUtil::ExternalImageChecker chk("passthrough", "imagetest"); + + { + QCOMPARE(p.group1->compositeOpId(), COMPOSITE_OVER); + QCOMPARE(p.group1->passThroughMode(), true); + + KisLayerSP newLayer = flattenLayerHelper(p, p.group4); + QVERIFY(chk.checkDevice(p.image->projection(), p.image, "00_initial")); + QVERIFY(newLayer->inherits("KisPaintLayer")); + + newLayer = mergeHelper(p, newLayer); + QVERIFY(chk.checkDevice(p.image->projection(), p.image, "00_initial")); + QVERIFY(newLayer->inherits("KisPaintLayer")); + } +} + +void KisImageTest::testMergePassThroughOverPaintLayer() +{ + FlattenPassThroughTestImage p; + + TestUtil::ExternalImageChecker chk("passthrough", "imagetest"); + + { + QCOMPARE(p.group1->compositeOpId(), COMPOSITE_OVER); + QCOMPARE(p.group1->passThroughMode(), true); + + KisLayerSP newLayer = flattenLayerHelper(p, p.group1); + QVERIFY(chk.checkDevice(p.image->projection(), p.image, "00_initial")); + QVERIFY(newLayer->inherits("KisPaintLayer")); + + newLayer = mergeHelper(p, p.group4); + QVERIFY(chk.checkDevice(p.image->projection(), p.image, "00_initial")); + QVERIFY(newLayer->inherits("KisPaintLayer")); + } +} + + + QTEST_MAIN(KisImageTest) diff --git a/libs/image/tests/kis_image_test.h b/libs/image/tests/kis_image_test.h index 5d098a246d..ce55321227 100644 --- a/libs/image/tests/kis_image_test.h +++ b/libs/image/tests/kis_image_test.h @@ -1,56 +1,62 @@ /* * Copyright (c) 2005 Adrian Page * 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_TESTER_H #define KIS_IMAGE_TESTER_H #include class KisImageTest : public QObject { Q_OBJECT private Q_SLOTS: void layerTests(); void benchmarkCreation(); void testBlockLevelOfDetail(); void testConvertImageColorSpace(); void testGlobalSelection(); void testCloneImage(); void testLayerComposition(); void testFlattenLayer(); void testMergeDown(); void testMergeDownDestinationInheritsAlpha(); void testMergeDownDestinationCustomCompositeOp(); void testMergeDownDestinationSameCompositeOpLayerStyle(); void testMergeDownDestinationSameCompositeOp(); void testMergeDownMultipleFrames(); void testMergeMultiple(); void testMergeCrossColorSpace(); void testMergeSelectionMasks(); void testFlattenImage(); + + void testFlattenPassThroughLayer(); + void testMergeTwoPassThroughLayers(); + + void testMergePaintOverPassThroughLayer(); + void testMergePassThroughOverPaintLayer(); }; #endif